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authorjk7744.park <jk7744.park@samsung.com>2015-09-09 02:37:59 +0900
committerjk7744.park <jk7744.park@samsung.com>2015-09-09 02:37:59 +0900
commit22e31e36c087447b38af048f9ea8b556e6326f4e (patch)
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdo11.html">Next Chapter</a> |
-<a href="nasmdoc9.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-10">Chapter 10: Mixing 16 and 32 Bit Code</a></h2>
-<p>This chapter tries to cover some of the issues, largely related to
-unusual forms of addressing and jump instructions, encountered when writing
-operating system code such as protected-mode initialisation routines, which
-require code that operates in mixed segment sizes, such as code in a 16-bit
-segment trying to modify data in a 32-bit one, or jumps between
-different-size segments.
-<h3><a name="section-10.1">10.1 Mixed-Size Jumps</a></h3>
-<p>The most common form of mixed-size instruction is the one used when
-writing a 32-bit OS: having done your setup in 16-bit mode, such as loading
-the kernel, you then have to boot it by switching into protected mode and
-jumping to the 32-bit kernel start address. In a fully 32-bit OS, this
-tends to be the <em>only</em> mixed-size instruction you need, since
-everything before it can be done in pure 16-bit code, and everything after
-it can be pure 32-bit.
-<p>This jump must specify a 48-bit far address, since the target segment is
-a 32-bit one. However, it must be assembled in a 16-bit segment, so just
-coding, for example,
-<p><pre>
- jmp 0x1234:0x56789ABC ; wrong!
-</pre>
-<p>will not work, since the offset part of the address will be truncated to
-<code><nobr>0x9ABC</nobr></code> and the jump will be an ordinary 16-bit
-far one.
-<p>The Linux kernel setup code gets round the inability of
-<code><nobr>as86</nobr></code> to generate the required instruction by
-coding it manually, using <code><nobr>DB</nobr></code> instructions. NASM
-can go one better than that, by actually generating the right instruction
-itself. Here's how to do it right:
-<p><pre>
- jmp dword 0x1234:0x56789ABC ; right
-</pre>
-<p>The <code><nobr>DWORD</nobr></code> prefix (strictly speaking, it should
-come <em>after</em> the colon, since it is declaring the <em>offset</em>
-field to be a doubleword; but NASM will accept either form, since both are
-unambiguous) forces the offset part to be treated as far, in the assumption
-that you are deliberately writing a jump from a 16-bit segment to a 32-bit
-one.
-<p>You can do the reverse operation, jumping from a 32-bit segment to a
-16-bit one, by means of the <code><nobr>WORD</nobr></code> prefix:
-<p><pre>
- jmp word 0x8765:0x4321 ; 32 to 16 bit
-</pre>
-<p>If the <code><nobr>WORD</nobr></code> prefix is specified in 16-bit
-mode, or the <code><nobr>DWORD</nobr></code> prefix in 32-bit mode, they
-will be ignored, since each is explicitly forcing NASM into a mode it was
-in anyway.
-<h3><a name="section-10.2">10.2 Addressing Between Different-Size Segments</a></h3>
-<p>If your OS is mixed 16 and 32-bit, or if you are writing a DOS extender,
-you are likely to have to deal with some 16-bit segments and some 32-bit
-ones. At some point, you will probably end up writing code in a 16-bit
-segment which has to access data in a 32-bit segment, or vice versa.
-<p>If the data you are trying to access in a 32-bit segment lies within the
-first 64K of the segment, you may be able to get away with using an
-ordinary 16-bit addressing operation for the purpose; but sooner or later,
-you will want to do 32-bit addressing from 16-bit mode.
-<p>The easiest way to do this is to make sure you use a register for the
-address, since any effective address containing a 32-bit register is forced
-to be a 32-bit address. So you can do
-<p><pre>
- mov eax,offset_into_32_bit_segment_specified_by_fs
- mov dword [fs:eax],0x11223344
-</pre>
-<p>This is fine, but slightly cumbersome (since it wastes an instruction
-and a register) if you already know the precise offset you are aiming at.
-The x86 architecture does allow 32-bit effective addresses to specify
-nothing but a 4-byte offset, so why shouldn't NASM be able to generate the
-best instruction for the purpose?
-<p>It can. As in <a href="#section-10.1">section 10.1</a>, you need only
-prefix the address with the <code><nobr>DWORD</nobr></code> keyword, and it
-will be forced to be a 32-bit address:
-<p><pre>
- mov dword [fs:dword my_offset],0x11223344
-</pre>
-<p>Also as in <a href="#section-10.1">section 10.1</a>, NASM is not fussy
-about whether the <code><nobr>DWORD</nobr></code> prefix comes before or
-after the segment override, so arguably a nicer-looking way to code the
-above instruction is
-<p><pre>
- mov dword [dword fs:my_offset],0x11223344
-</pre>
-<p>Don't confuse the <code><nobr>DWORD</nobr></code> prefix
-<em>outside</em> the square brackets, which controls the size of the data
-stored at the address, with the one <code><nobr>inside</nobr></code> the
-square brackets which controls the length of the address itself. The two
-can quite easily be different:
-<p><pre>
- mov word [dword 0x12345678],0x9ABC
-</pre>
-<p>This moves 16 bits of data to an address specified by a 32-bit offset.
-<p>You can also specify <code><nobr>WORD</nobr></code> or
-<code><nobr>DWORD</nobr></code> prefixes along with the
-<code><nobr>FAR</nobr></code> prefix to indirect far jumps or calls. For
-example:
-<p><pre>
- call dword far [fs:word 0x4321]
-</pre>
-<p>This instruction contains an address specified by a 16-bit offset; it
-loads a 48-bit far pointer from that (16-bit segment and 32-bit offset),
-and calls that address.
-<h3><a name="section-10.3">10.3 Other Mixed-Size Instructions</a></h3>
-<p>The other way you might want to access data might be using the string
-instructions (<code><nobr>LODSx</nobr></code>,
-<code><nobr>STOSx</nobr></code> and so on) or the
-<code><nobr>XLATB</nobr></code> instruction. These instructions, since they
-take no parameters, might seem to have no easy way to make them perform
-32-bit addressing when assembled in a 16-bit segment.
-<p>This is the purpose of NASM's <code><nobr>a16</nobr></code>,
-<code><nobr>a32</nobr></code> and <code><nobr>a64</nobr></code> prefixes.
-If you are coding <code><nobr>LODSB</nobr></code> in a 16-bit segment but
-it is supposed to be accessing a string in a 32-bit segment, you should
-load the desired address into <code><nobr>ESI</nobr></code> and then code
-<p><pre>
- a32 lodsb
-</pre>
-<p>The prefix forces the addressing size to 32 bits, meaning that
-<code><nobr>LODSB</nobr></code> loads from
-<code><nobr>[DS:ESI]</nobr></code> instead of
-<code><nobr>[DS:SI]</nobr></code>. To access a string in a 16-bit segment
-when coding in a 32-bit one, the corresponding
-<code><nobr>a16</nobr></code> prefix can be used.
-<p>The <code><nobr>a16</nobr></code>, <code><nobr>a32</nobr></code> and
-<code><nobr>a64</nobr></code> prefixes can be applied to any instruction in
-NASM's instruction table, but most of them can generate all the useful
-forms without them. The prefixes are necessary only for instructions with
-implicit addressing: <code><nobr>CMPSx</nobr></code>,
-<code><nobr>SCASx</nobr></code>, <code><nobr>LODSx</nobr></code>,
-<code><nobr>STOSx</nobr></code>, <code><nobr>MOVSx</nobr></code>,
-<code><nobr>INSx</nobr></code>, <code><nobr>OUTSx</nobr></code>, and
-<code><nobr>XLATB</nobr></code>. Also, the various push and pop
-instructions (<code><nobr>PUSHA</nobr></code> and
-<code><nobr>POPF</nobr></code> as well as the more usual
-<code><nobr>PUSH</nobr></code> and <code><nobr>POP</nobr></code>) can
-accept <code><nobr>a16</nobr></code>, <code><nobr>a32</nobr></code> or
-<code><nobr>a64</nobr></code> prefixes to force a particular one of
-<code><nobr>SP</nobr></code>, <code><nobr>ESP</nobr></code> or
-<code><nobr>RSP</nobr></code> to be used as a stack pointer, in case the
-stack segment in use is a different size from the code segment.
-<p><code><nobr>PUSH</nobr></code> and <code><nobr>POP</nobr></code>, when
-applied to segment registers in 32-bit mode, also have the slightly odd
-behaviour that they push and pop 4 bytes at a time, of which the top two
-are ignored and the bottom two give the value of the segment register being
-manipulated. To force the 16-bit behaviour of segment-register push and pop
-instructions, you can use the operand-size prefix
-<code><nobr>o16</nobr></code>:
-<p><pre>
- o16 push ss
- o16 push ds
-</pre>
-<p>This code saves a doubleword of stack space by fitting two segment
-registers into the space which would normally be consumed by pushing one.
-<p>(You can also use the <code><nobr>o32</nobr></code> prefix to force the
-32-bit behaviour when in 16-bit mode, but this seems less useful.)
-<p align=center><a href="nasmdo11.html">Next Chapter</a> |
-<a href="nasmdoc9.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdo11.html b/doc/html/nasmdo11.html
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdo12.html">Next Chapter</a> |
-<a href="nasmdo10.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-11">Chapter 11: Writing 64-bit Code (Unix, Win64)</a></h2>
-<p>This chapter attempts to cover some of the common issues involved when
-writing 64-bit code, to run under Win64 or Unix. It covers how to write
-assembly code to interface with 64-bit C routines, and how to write
-position-independent code for shared libraries.
-<p>All 64-bit code uses a flat memory model, since segmentation is not
-available in 64-bit mode. The one exception is the
-<code><nobr>FS</nobr></code> and <code><nobr>GS</nobr></code> registers,
-which still add their bases.
-<p>Position independence in 64-bit mode is significantly simpler, since the
-processor supports <code><nobr>RIP</nobr></code>-relative addressing
-directly; see the <code><nobr>REL</nobr></code> keyword
-(<a href="nasmdoc3.html#section-3.3">section 3.3</a>). On most 64-bit
-platforms, it is probably desirable to make that the default, using the
-directive <code><nobr>DEFAULT REL</nobr></code>
-(<a href="nasmdoc6.html#section-6.2">section 6.2</a>).
-<p>64-bit programming is relatively similar to 32-bit programming, but of
-course pointers are 64 bits long; additionally, all existing platforms pass
-arguments in registers rather than on the stack. Furthermore, 64-bit
-platforms use SSE2 by default for floating point. Please see the ABI
-documentation for your platform.
-<p>64-bit platforms differ in the sizes of the fundamental datatypes, not
-just from 32-bit platforms but from each other. If a specific size data
-type is desired, it is probably best to use the types defined in the
-Standard C header <code><nobr>&lt;inttypes.h&gt;</nobr></code>.
-<p>In 64-bit mode, the default instruction size is still 32 bits. When
-loading a value into a 32-bit register (but not an 8- or 16-bit register),
-the upper 32 bits of the corresponding 64-bit register are set to zero.
-<h3><a name="section-11.1">11.1 Register Names in 64-bit Mode</a></h3>
-<p>NASM uses the following names for general-purpose registers in 64-bit
-mode, for 8-, 16-, 32- and 64-bit references, respecitively:
-<p><pre>
- AL/AH, CL/CH, DL/DH, BL/BH, SPL, BPL, SIL, DIL, R8B-R15B
- AX, CX, DX, BX, SP, BP, SI, DI, R8W-R15W
- EAX, ECX, EDX, EBX, ESP, EBP, ESI, EDI, R8D-R15D
- RAX, RCX, RDX, RBX, RSP, RBP, RSI, RDI, R8-R15
-</pre>
-<p>This is consistent with the AMD documentation and most other assemblers.
-The Intel documentation, however, uses the names
-<code><nobr>R8L-R15L</nobr></code> for 8-bit references to the higher
-registers. It is possible to use those names by definiting them as macros;
-similarly, if one wants to use numeric names for the low 8 registers,
-define them as macros. The standard macro package
-<code><nobr>altreg</nobr></code> (see
-<a href="nasmdoc5.html#section-5.1">section 5.1</a>) can be used for this
-purpose.
-<h3><a name="section-11.2">11.2 Immediates and Displacements in 64-bit Mode</a></h3>
-<p>In 64-bit mode, immediates and displacements are generally only 32 bits
-wide. NASM will therefore truncate most displacements and immediates to 32
-bits.
-<p>The only instruction which takes a full 64-bit immediate is:
-<p><pre>
- MOV reg64,imm64
-</pre>
-<p>NASM will produce this instruction whenever the programmer uses
-<code><nobr>MOV</nobr></code> with an immediate into a 64-bit register. If
-this is not desirable, simply specify the equivalent 32-bit register, which
-will be automatically zero-extended by the processor, or specify the
-immediate as <code><nobr>DWORD</nobr></code>:
-<p><pre>
- mov rax,foo ; 64-bit immediate
- mov rax,qword foo ; (identical)
- mov eax,foo ; 32-bit immediate, zero-extended
- mov rax,dword foo ; 32-bit immediate, sign-extended
-</pre>
-<p>The length of these instructions are 10, 5 and 7 bytes, respectively.
-<p>The only instructions which take a full 64-bit <em>displacement</em> is
-loading or storing, using <code><nobr>MOV</nobr></code>,
-<code><nobr>AL</nobr></code>, <code><nobr>AX</nobr></code>,
-<code><nobr>EAX</nobr></code> or <code><nobr>RAX</nobr></code> (but no
-other registers) to an absolute 64-bit address. Since this is a relatively
-rarely used instruction (64-bit code generally uses relative addressing),
-the programmer has to explicitly declare the displacement size as
-<code><nobr>QWORD</nobr></code>:
-<p><pre>
- default abs
-
- mov eax,[foo] ; 32-bit absolute disp, sign-extended
- mov eax,[a32 foo] ; 32-bit absolute disp, zero-extended
- mov eax,[qword foo] ; 64-bit absolute disp
-
- default rel
-
- mov eax,[foo] ; 32-bit relative disp
- mov eax,[a32 foo] ; d:o, address truncated to 32 bits(!)
- mov eax,[qword foo] ; error
- mov eax,[abs qword foo] ; 64-bit absolute disp
-</pre>
-<p>A sign-extended absolute displacement can access from -2 GB to +2 GB; a
-zero-extended absolute displacement can access from 0 to 4 GB.
-<h3><a name="section-11.3">11.3 Interfacing to 64-bit C Programs (Unix)</a></h3>
-<p>On Unix, the 64-bit ABI is defined by the document:
-<p>
-<a href="http://www.x86-64.org/documentation/abi.pdf"><code><nobr>http://www.x86-64.org/documentation/abi.pdf</nobr></code></a>
-<p>Although written for AT&amp;T-syntax assembly, the concepts apply
-equally well for NASM-style assembly. What follows is a simplified summary.
-<p>The first six integer arguments (from the left) are passed in
-<code><nobr>RDI</nobr></code>, <code><nobr>RSI</nobr></code>,
-<code><nobr>RDX</nobr></code>, <code><nobr>RCX</nobr></code>,
-<code><nobr>R8</nobr></code>, and <code><nobr>R9</nobr></code>, in that
-order. Additional integer arguments are passed on the stack. These
-registers, plus <code><nobr>RAX</nobr></code>,
-<code><nobr>R10</nobr></code> and <code><nobr>R11</nobr></code> are
-destroyed by function calls, and thus are available for use by the function
-without saving.
-<p>Integer return values are passed in <code><nobr>RAX</nobr></code> and
-<code><nobr>RDX</nobr></code>, in that order.
-<p>Floating point is done using SSE registers, except for
-<code><nobr>long double</nobr></code>. Floating-point arguments are passed
-in <code><nobr>XMM0</nobr></code> to <code><nobr>XMM7</nobr></code>; return
-is <code><nobr>XMM0</nobr></code> and <code><nobr>XMM1</nobr></code>.
-<code><nobr>long double</nobr></code> are passed on the stack, and returned
-in <code><nobr>ST0</nobr></code> and <code><nobr>ST1</nobr></code>.
-<p>All SSE and x87 registers are destroyed by function calls.
-<p>On 64-bit Unix, <code><nobr>long</nobr></code> is 64 bits.
-<p>Integer and SSE register arguments are counted separately, so for the
-case of
-<p><pre>
- void foo(long a, double b, int c)
-</pre>
-<p><code><nobr>a</nobr></code> is passed in <code><nobr>RDI</nobr></code>,
-<code><nobr>b</nobr></code> in <code><nobr>XMM0</nobr></code>, and
-<code><nobr>c</nobr></code> in <code><nobr>ESI</nobr></code>.
-<h3><a name="section-11.4">11.4 Interfacing to 64-bit C Programs (Win64)</a></h3>
-<p>The Win64 ABI is described at:
-<p>
-<a href="http://msdn2.microsoft.com/en-gb/library/ms794533.aspx"><code><nobr>http://msdn2.microsoft.com/en-gb/library/ms794533.aspx</nobr></code></a>
-<p>What follows is a simplified summary.
-<p>The first four integer arguments are passed in
-<code><nobr>RCX</nobr></code>, <code><nobr>RDX</nobr></code>,
-<code><nobr>R8</nobr></code> and <code><nobr>R9</nobr></code>, in that
-order. Additional integer arguments are passed on the stack. These
-registers, plus <code><nobr>RAX</nobr></code>,
-<code><nobr>R10</nobr></code> and <code><nobr>R11</nobr></code> are
-destroyed by function calls, and thus are available for use by the function
-without saving.
-<p>Integer return values are passed in <code><nobr>RAX</nobr></code> only.
-<p>Floating point is done using SSE registers, except for
-<code><nobr>long double</nobr></code>. Floating-point arguments are passed
-in <code><nobr>XMM0</nobr></code> to <code><nobr>XMM3</nobr></code>; return
-is <code><nobr>XMM0</nobr></code> only.
-<p>On Win64, <code><nobr>long</nobr></code> is 32 bits;
-<code><nobr>long long</nobr></code> or <code><nobr>_int64</nobr></code> is
-64 bits.
-<p>Integer and SSE register arguments are counted together, so for the case
-of
-<p><pre>
- void foo(long long a, double b, int c)
-</pre>
-<p><code><nobr>a</nobr></code> is passed in <code><nobr>RCX</nobr></code>,
-<code><nobr>b</nobr></code> in <code><nobr>XMM1</nobr></code>, and
-<code><nobr>c</nobr></code> in <code><nobr>R8D</nobr></code>.
-<p align=center><a href="nasmdo12.html">Next Chapter</a> |
-<a href="nasmdo10.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdo12.html b/doc/html/nasmdo12.html
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoca.html">Next Chapter</a> |
-<a href="nasmdo11.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-12">Chapter 12: Troubleshooting</a></h2>
-<p>This chapter describes some of the common problems that users have been
-known to encounter with NASM, and answers them. It also gives instructions
-for reporting bugs in NASM if you find a difficulty that isn't listed here.
-<h3><a name="section-12.1">12.1 Common Problems</a></h3>
-<h4><a name="section-12.1.1">12.1.1 NASM Generates Inefficient Code</a></h4>
-<p>We sometimes get `bug' reports about NASM generating inefficient, or
-even `wrong', code on instructions such as
-<code><nobr>ADD ESP,8</nobr></code>. This is a deliberate design feature,
-connected to predictability of output: NASM, on seeing
-<code><nobr>ADD ESP,8</nobr></code>, will generate the form of the
-instruction which leaves room for a 32-bit offset. You need to code
-<code><nobr>ADD ESP,BYTE 8</nobr></code> if you want the space-efficient
-form of the instruction. This isn't a bug, it's user error: if you prefer
-to have NASM produce the more efficient code automatically enable
-optimization with the <code><nobr>-O</nobr></code> option (see
-<a href="nasmdoc2.html#section-2.1.22">section 2.1.22</a>).
-<h4><a name="section-12.1.2">12.1.2 My Jumps are Out of Range</a></h4>
-<p>Similarly, people complain that when they issue conditional jumps (which
-are <code><nobr>SHORT</nobr></code> by default) that try to jump too far,
-NASM reports `short jump out of range' instead of making the jumps longer.
-<p>This, again, is partly a predictability issue, but in fact has a more
-practical reason as well. NASM has no means of being told what type of
-processor the code it is generating will be run on; so it cannot decide for
-itself that it should generate <code><nobr>Jcc NEAR</nobr></code> type
-instructions, because it doesn't know that it's working for a 386 or above.
-Alternatively, it could replace the out-of-range short
-<code><nobr>JNE</nobr></code> instruction with a very short
-<code><nobr>JE</nobr></code> instruction that jumps over a
-<code><nobr>JMP NEAR</nobr></code>; this is a sensible solution for
-processors below a 386, but hardly efficient on processors which have good
-branch prediction <em>and</em> could have used
-<code><nobr>JNE NEAR</nobr></code> instead. So, once again, it's up to the
-user, not the assembler, to decide what instructions should be generated.
-See <a href="nasmdoc2.html#section-2.1.22">section 2.1.22</a>.
-<h4><a name="section-12.1.3">12.1.3 <code><nobr>ORG</nobr></code> Doesn't Work</a></h4>
-<p>People writing boot sector programs in the <code><nobr>bin</nobr></code>
-format often complain that <code><nobr>ORG</nobr></code> doesn't work the
-way they'd like: in order to place the <code><nobr>0xAA55</nobr></code>
-signature word at the end of a 512-byte boot sector, people who are used to
-MASM tend to code
-<p><pre>
- ORG 0
-
- ; some boot sector code
-
- ORG 510
- DW 0xAA55
-</pre>
-<p>This is not the intended use of the <code><nobr>ORG</nobr></code>
-directive in NASM, and will not work. The correct way to solve this problem
-in NASM is to use the <code><nobr>TIMES</nobr></code> directive, like this:
-<p><pre>
- ORG 0
-
- ; some boot sector code
-
- TIMES 510-($-$$) DB 0
- DW 0xAA55
-</pre>
-<p>The <code><nobr>TIMES</nobr></code> directive will insert exactly enough
-zero bytes into the output to move the assembly point up to 510. This
-method also has the advantage that if you accidentally fill your boot
-sector too full, NASM will catch the problem at assembly time and report
-it, so you won't end up with a boot sector that you have to disassemble to
-find out what's wrong with it.
-<h4><a name="section-12.1.4">12.1.4 <code><nobr>TIMES</nobr></code> Doesn't Work</a></h4>
-<p>The other common problem with the above code is people who write the
-<code><nobr>TIMES</nobr></code> line as
-<p><pre>
- TIMES 510-$ DB 0
-</pre>
-<p>by reasoning that <code><nobr>$</nobr></code> should be a pure number,
-just like 510, so the difference between them is also a pure number and can
-happily be fed to <code><nobr>TIMES</nobr></code>.
-<p>NASM is a <em>modular</em> assembler: the various component parts are
-designed to be easily separable for re-use, so they don't exchange
-information unnecessarily. In consequence, the
-<code><nobr>bin</nobr></code> output format, even though it has been told
-by the <code><nobr>ORG</nobr></code> directive that the
-<code><nobr>.text</nobr></code> section should start at 0, does not pass
-that information back to the expression evaluator. So from the evaluator's
-point of view, <code><nobr>$</nobr></code> isn't a pure number: it's an
-offset from a section base. Therefore the difference between
-<code><nobr>$</nobr></code> and 510 is also not a pure number, but involves
-a section base. Values involving section bases cannot be passed as
-arguments to <code><nobr>TIMES</nobr></code>.
-<p>The solution, as in the previous section, is to code the
-<code><nobr>TIMES</nobr></code> line in the form
-<p><pre>
- TIMES 510-($-$$) DB 0
-</pre>
-<p>in which <code><nobr>$</nobr></code> and <code><nobr>$$</nobr></code>
-are offsets from the same section base, and so their difference is a pure
-number. This will solve the problem and generate sensible code.
-<h3><a name="section-12.2">12.2 Bugs</a></h3>
-<p>We have never yet released a version of NASM with any <em>known</em>
-bugs. That doesn't usually stop there being plenty we didn't know about,
-though. Any that you find should be reported firstly via the
-<code><nobr>bugtracker</nobr></code> at
-<a href="https://sourceforge.net/projects/nasm/"><code><nobr>https://sourceforge.net/projects/nasm/</nobr></code></a>
-(click on "Bugs"), or if that fails then through one of the contacts in
-<a href="nasmdoc1.html#section-1.2">section 1.2</a>.
-<p>Please read <a href="nasmdoc2.html#section-2.2">section 2.2</a> first,
-and don't report the bug if it's listed in there as a deliberate feature.
-(If you think the feature is badly thought out, feel free to send us
-reasons why you think it should be changed, but don't just send us mail
-saying `This is a bug' if the documentation says we did it on purpose.)
-Then read <a href="#section-12.1">section 12.1</a>, and don't bother
-reporting the bug if it's listed there.
-<p>If you do report a bug, <em>please</em> give us all of the following
-information:
-<ul>
-<li>What operating system you're running NASM under. DOS, Linux, NetBSD,
-Win16, Win32, VMS (I'd be impressed), whatever.
-<li>If you're running NASM under DOS or Win32, tell us whether you've
-compiled your own executable from the DOS source archive, or whether you
-were using the standard distribution binaries out of the archive. If you
-were using a locally built executable, try to reproduce the problem using
-one of the standard binaries, as this will make it easier for us to
-reproduce your problem prior to fixing it.
-<li>Which version of NASM you're using, and exactly how you invoked it.
-Give us the precise command line, and the contents of the
-<code><nobr>NASMENV</nobr></code> environment variable if any.
-<li>Which versions of any supplementary programs you're using, and how you
-invoked them. If the problem only becomes visible at link time, tell us
-what linker you're using, what version of it you've got, and the exact
-linker command line. If the problem involves linking against object files
-generated by a compiler, tell us what compiler, what version, and what
-command line or options you used. (If you're compiling in an IDE, please
-try to reproduce the problem with the command-line version of the
-compiler.)
-<li>If at all possible, send us a NASM source file which exhibits the
-problem. If this causes copyright problems (e.g. you can only reproduce the
-bug in restricted-distribution code) then bear in mind the following two
-points: firstly, we guarantee that any source code sent to us for the
-purposes of debugging NASM will be used <em>only</em> for the purposes of
-debugging NASM, and that we will delete all our copies of it as soon as we
-have found and fixed the bug or bugs in question; and secondly, we would
-prefer <em>not</em> to be mailed large chunks of code anyway. The smaller
-the file, the better. A three-line sample file that does nothing useful
-<em>except</em> demonstrate the problem is much easier to work with than a
-fully fledged ten-thousand-line program. (Of course, some errors
-<em>do</em> only crop up in large files, so this may not be possible.)
-<li>A description of what the problem actually <em>is</em>. `It doesn't
-work' is <em>not</em> a helpful description! Please describe exactly what
-is happening that shouldn't be, or what isn't happening that should.
-Examples might be: `NASM generates an error message saying Line 3 for an
-error that's actually on Line 5'; `NASM generates an error message that I
-believe it shouldn't be generating at all'; `NASM fails to generate an
-error message that I believe it <em>should</em> be generating'; `the object
-file produced from this source code crashes my linker'; `the ninth byte of
-the output file is 66 and I think it should be 77 instead'.
-<li>If you believe the output file from NASM to be faulty, send it to us.
-That allows us to determine whether our own copy of NASM generates the same
-file, or whether the problem is related to portability issues between our
-development platforms and yours. We can handle binary files mailed to us as
-MIME attachments, uuencoded, and even BinHex. Alternatively, we may be able
-to provide an FTP site you can upload the suspect files to; but mailing
-them is easier for us.
-<li>Any other information or data files that might be helpful. If, for
-example, the problem involves NASM failing to generate an object file while
-TASM can generate an equivalent file without trouble, then send us
-<em>both</em> object files, so we can see what TASM is doing differently
-from us.
-</ul>
-<p align=center><a href="nasmdoca.html">Next Chapter</a> |
-<a href="nasmdo11.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p>This manual documents NASM, the Netwide Assembler: an assembler
-targetting the Intel x86 series of processors, with portable source.
-<p><p><a href="nasmdoc1.html">Chapter 1: Introduction</a><br>
-<a href="nasmdoc1.html#section-1.1">Section 1.1: What Is NASM?</a><br>
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1: Why Yet Another Assembler?</a><br>
-<a href="nasmdoc1.html#section-1.1.2">Section 1.1.2: License Conditions</a><br>
-<a href="nasmdoc1.html#section-1.2">Section 1.2: Contact Information</a><br>
-<a href="nasmdoc1.html#section-1.3">Section 1.3: Installation</a><br>
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1: Installing NASM under MS-DOS or Windows</a><br>
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2: Installing NASM under Unix</a><br>
-<p><a href="nasmdoc2.html">Chapter 2: Running NASM</a><br>
-<a href="nasmdoc2.html#section-2.1">Section 2.1: NASM Command-Line Syntax</a><br>
-<a href="nasmdoc2.html#section-2.1.1">Section 2.1.1: The <code><nobr>-o</nobr></code> Option: Specifying the Output File Name</a><br>
-<a href="nasmdoc2.html#section-2.1.2">Section 2.1.2: The <code><nobr>-f</nobr></code> Option: Specifying the Output File Format</a><br>
-<a href="nasmdoc2.html#section-2.1.3">Section 2.1.3: The <code><nobr>-l</nobr></code> Option: Generating a Listing File</a><br>
-<a href="nasmdoc2.html#section-2.1.4">Section 2.1.4: The <code><nobr>-M</nobr></code> Option: Generate Makefile Dependencies</a><br>
-<a href="nasmdoc2.html#section-2.1.5">Section 2.1.5: The <code><nobr>-MG</nobr></code> Option: Generate Makefile Dependencies</a><br>
-<a href="nasmdoc2.html#section-2.1.6">Section 2.1.6: The <code><nobr>-MF</nobr></code> Option: Set Makefile Dependency File</a><br>
-<a href="nasmdoc2.html#section-2.1.7">Section 2.1.7: The <code><nobr>-MD</nobr></code> Option: Assemble and Generate Dependencies</a><br>
-<a href="nasmdoc2.html#section-2.1.8">Section 2.1.8: The <code><nobr>-MT</nobr></code> Option: Dependency Target Name</a><br>
-<a href="nasmdoc2.html#section-2.1.9">Section 2.1.9: The <code><nobr>-MQ</nobr></code> Option: Dependency Target Name (Quoted)</a><br>
-<a href="nasmdoc2.html#section-2.1.10">Section 2.1.10: The <code><nobr>-MP</nobr></code> Option: Emit phony targets</a><br>
-<a href="nasmdoc2.html#section-2.1.11">Section 2.1.11: The <code><nobr>-F</nobr></code> Option: Selecting a Debug Information Format</a><br>
-<a href="nasmdoc2.html#section-2.1.12">Section 2.1.12: The <code><nobr>-g</nobr></code> Option: Enabling Debug Information.</a><br>
-<a href="nasmdoc2.html#section-2.1.13">Section 2.1.13: The <code><nobr>-X</nobr></code> Option: Selecting an Error Reporting Format</a><br>
-<a href="nasmdoc2.html#section-2.1.14">Section 2.1.14: The <code><nobr>-Z</nobr></code> Option: Send Errors to a File</a><br>
-<a href="nasmdoc2.html#section-2.1.15">Section 2.1.15: The <code><nobr>-s</nobr></code> Option: Send Errors to <code><nobr>stdout</nobr></code></a><br>
-<a href="nasmdoc2.html#section-2.1.16">Section 2.1.16: The <code><nobr>-i</nobr></code> Option: Include File Search Directories</a><br>
-<a href="nasmdoc2.html#section-2.1.17">Section 2.1.17: The <code><nobr>-p</nobr></code> Option: Pre-Include a File</a><br>
-<a href="nasmdoc2.html#section-2.1.18">Section 2.1.18: The <code><nobr>-d</nobr></code> Option: Pre-Define a Macro</a><br>
-<a href="nasmdoc2.html#section-2.1.19">Section 2.1.19: The <code><nobr>-u</nobr></code> Option: Undefine a Macro</a><br>
-<a href="nasmdoc2.html#section-2.1.20">Section 2.1.20: The <code><nobr>-E</nobr></code> Option: Preprocess Only</a><br>
-<a href="nasmdoc2.html#section-2.1.21">Section 2.1.21: The <code><nobr>-a</nobr></code> Option: Don't Preprocess At All</a><br>
-<a href="nasmdoc2.html#section-2.1.22">Section 2.1.22: The <code><nobr>-O</nobr></code> Option: Specifying Multipass Optimization</a><br>
-<a href="nasmdoc2.html#section-2.1.23">Section 2.1.23: The <code><nobr>-t</nobr></code> Option: Enable TASM Compatibility Mode</a><br>
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24: The <code><nobr>-w</nobr></code> and <code><nobr>-W</nobr></code> Options: Enable or Disable Assembly Warnings</a><br>
-<a href="nasmdoc2.html#section-2.1.25">Section 2.1.25: The <code><nobr>-v</nobr></code> Option: Display Version Info</a><br>
-<a href="nasmdoc2.html#section-2.1.26">Section 2.1.26: The <code><nobr>-y</nobr></code> Option: Display Available Debug Info Formats</a><br>
-<a href="nasmdoc2.html#section-2.1.27">Section 2.1.27: The <code><nobr>--prefix</nobr></code> and <code><nobr>--postfix</nobr></code> Options.</a><br>
-<a href="nasmdoc2.html#section-2.1.28">Section 2.1.28: The <code><nobr>NASMENV</nobr></code> Environment Variable</a><br>
-<a href="nasmdoc2.html#section-2.2">Section 2.2: Quick Start for MASM Users</a><br>
-<a href="nasmdoc2.html#section-2.2.1">Section 2.2.1: NASM Is Case-Sensitive</a><br>
-<a href="nasmdoc2.html#section-2.2.2">Section 2.2.2: NASM Requires Square Brackets For Memory References</a><br>
-<a href="nasmdoc2.html#section-2.2.3">Section 2.2.3: NASM Doesn't Store Variable Types</a><br>
-<a href="nasmdoc2.html#section-2.2.4">Section 2.2.4: NASM Doesn't <code><nobr>ASSUME</nobr></code></a><br>
-<a href="nasmdoc2.html#section-2.2.5">Section 2.2.5: NASM Doesn't Support Memory Models</a><br>
-<a href="nasmdoc2.html#section-2.2.6">Section 2.2.6: Floating-Point Differences</a><br>
-<a href="nasmdoc2.html#section-2.2.7">Section 2.2.7: Other Differences</a><br>
-<p><a href="nasmdoc3.html">Chapter 3: The NASM Language</a><br>
-<a href="nasmdoc3.html#section-3.1">Section 3.1: Layout of a NASM Source Line</a><br>
-<a href="nasmdoc3.html#section-3.2">Section 3.2: Pseudo-Instructions</a><br>
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1: <code><nobr>DB</nobr></code> and Friends: Declaring Initialized Data</a><br>
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2: <code><nobr>RESB</nobr></code> and Friends: Declaring Uninitialized Data</a><br>
-<a href="nasmdoc3.html#section-3.2.3">Section 3.2.3: <code><nobr>INCBIN</nobr></code>: Including External Binary Files</a><br>
-<a href="nasmdoc3.html#section-3.2.4">Section 3.2.4: <code><nobr>EQU</nobr></code>: Defining Constants</a><br>
-<a href="nasmdoc3.html#section-3.2.5">Section 3.2.5: <code><nobr>TIMES</nobr></code>: Repeating Instructions or Data</a><br>
-<a href="nasmdoc3.html#section-3.3">Section 3.3: Effective Addresses</a><br>
-<a href="nasmdoc3.html#section-3.4">Section 3.4: Constants</a><br>
-<a href="nasmdoc3.html#section-3.4.1">Section 3.4.1: Numeric Constants</a><br>
-<a href="nasmdoc3.html#section-3.4.2">Section 3.4.2: Character Strings</a><br>
-<a href="nasmdoc3.html#section-3.4.3">Section 3.4.3: Character Constants</a><br>
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4: String Constants</a><br>
-<a href="nasmdoc3.html#section-3.4.5">Section 3.4.5: Unicode Strings</a><br>
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6: Floating-Point Constants</a><br>
-<a href="nasmdoc3.html#section-3.4.7">Section 3.4.7: Packed BCD Constants</a><br>
-<a href="nasmdoc3.html#section-3.5">Section 3.5: Expressions</a><br>
-<a href="nasmdoc3.html#section-3.5.1">Section 3.5.1: <code><nobr>|</nobr></code>: Bitwise OR Operator</a><br>
-<a href="nasmdoc3.html#section-3.5.2">Section 3.5.2: <code><nobr>^</nobr></code>: Bitwise XOR Operator</a><br>
-<a href="nasmdoc3.html#section-3.5.3">Section 3.5.3: <code><nobr>&amp;</nobr></code>: Bitwise AND Operator</a><br>
-<a href="nasmdoc3.html#section-3.5.4">Section 3.5.4: <code><nobr>&lt;&lt;</nobr></code> and <code><nobr>&gt;&gt;</nobr></code>: Bit Shift Operators</a><br>
-<a href="nasmdoc3.html#section-3.5.5">Section 3.5.5: <code><nobr>+</nobr></code> and <code><nobr>-</nobr></code>: Addition and Subtraction Operators</a><br>
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6: <code><nobr>*</nobr></code>, <code><nobr>/</nobr></code>, <code><nobr>//</nobr></code>, <code><nobr>%</nobr></code> and <code><nobr>%%</nobr></code>: Multiplication and Division</a><br>
-<a href="nasmdoc3.html#section-3.5.7">Section 3.5.7: Unary Operators: <code><nobr>+</nobr></code>, <code><nobr>-</nobr></code>, <code><nobr>~</nobr></code>, <code><nobr>!</nobr></code> and <code><nobr>SEG</nobr></code></a><br>
-<a href="nasmdoc3.html#section-3.6">Section 3.6: <code><nobr>SEG</nobr></code> and <code><nobr>WRT</nobr></code></a><br>
-<a href="nasmdoc3.html#section-3.7">Section 3.7: <code><nobr>STRICT</nobr></code>: Inhibiting Optimization</a><br>
-<a href="nasmdoc3.html#section-3.8">Section 3.8: Critical Expressions</a><br>
-<a href="nasmdoc3.html#section-3.9">Section 3.9: Local Labels</a><br>
-<p><a href="nasmdoc4.html">Chapter 4: The NASM Preprocessor</a><br>
-<a href="nasmdoc4.html#section-4.1">Section 4.1: Single-Line Macros</a><br>
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1: The Normal Way: <code><nobr>%define</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.2">Section 4.1.2: Resolving <code><nobr>%define</nobr></code>: <code><nobr>%xdefine</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.3">Section 4.1.3: Macro Indirection: <code><nobr>%[...]</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.4">Section 4.1.4: Concatenating Single Line Macro Tokens: <code><nobr>%+</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.5">Section 4.1.5: The Macro Name Itself: <code><nobr>%?</nobr></code> and <code><nobr>%??</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.6">Section 4.1.6: Undefining Single-Line Macros: <code><nobr>%undef</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.7">Section 4.1.7: Preprocessor Variables: <code><nobr>%assign</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.8">Section 4.1.8: Defining Strings: <code><nobr>%defstr</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.1.9">Section 4.1.9: Defining Tokens: <code><nobr>%deftok</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.2">Section 4.2: String Manipulation in Macros</a><br>
-<a href="nasmdoc4.html#section-4.2.1">Section 4.2.1: Concatenating Strings: <code><nobr>%strcat</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.2.2">Section 4.2.2: String Length: <code><nobr>%strlen</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.2.3">Section 4.2.3: Extracting Substrings: <code><nobr>%substr</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.3">Section 4.3: Multi-Line Macros: <code><nobr>%macro</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.3.1">Section 4.3.1: Recursive Multi-Line Macros: <code><nobr>%rmacro</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.3.2">Section 4.3.2: Overloading Multi-Line Macros</a><br>
-<a href="nasmdoc4.html#section-4.3.3">Section 4.3.3: Macro-Local Labels</a><br>
-<a href="nasmdoc4.html#section-4.3.4">Section 4.3.4: Greedy Macro Parameters</a><br>
-<a href="nasmdoc4.html#section-4.3.5">Section 4.3.5: Default Macro Parameters</a><br>
-<a href="nasmdoc4.html#section-4.3.6">Section 4.3.6: <code><nobr>%0</nobr></code>: Macro Parameter Counter</a><br>
-<a href="nasmdoc4.html#section-4.3.7">Section 4.3.7: <code><nobr>%rotate</nobr></code>: Rotating Macro Parameters</a><br>
-<a href="nasmdoc4.html#section-4.3.8">Section 4.3.8: Concatenating Macro Parameters</a><br>
-<a href="nasmdoc4.html#section-4.3.9">Section 4.3.9: Condition Codes as Macro Parameters</a><br>
-<a href="nasmdoc4.html#section-4.3.10">Section 4.3.10: Disabling Listing Expansion</a><br>
-<a href="nasmdoc4.html#section-4.3.11">Section 4.3.11: Undefining Multi-Line Macros: <code><nobr>%unmacro</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.3.12">Section 4.3.12: Exiting Multi-Line Macros: <code><nobr>%exitmacro</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.4">Section 4.4: Conditional Assembly</a><br>
-<a href="nasmdoc4.html#section-4.4.1">Section 4.4.1: <code><nobr>%ifdef</nobr></code>: Testing Single-Line Macro Existence</a><br>
-<a href="nasmdoc4.html#section-4.4.2">Section 4.4.2: <code><nobr>%ifmacro</nobr></code>: Testing Multi-Line Macro Existence</a><br>
-<a href="nasmdoc4.html#section-4.4.3">Section 4.4.3: <code><nobr>%ifctx</nobr></code>: Testing the Context Stack</a><br>
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4: <code><nobr>%if</nobr></code>: Testing Arbitrary Numeric Expressions</a><br>
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5: <code><nobr>%ifidn</nobr></code> and <code><nobr>%ifidni</nobr></code>: Testing Exact Text Identity</a><br>
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6: <code><nobr>%ifid</nobr></code>, <code><nobr>%ifnum</nobr></code>, <code><nobr>%ifstr</nobr></code>: Testing Token Types</a><br>
-<a href="nasmdoc4.html#section-4.4.7">Section 4.4.7: <code><nobr>%iftoken</nobr></code>: Test for a Single Token</a><br>
-<a href="nasmdoc4.html#section-4.4.8">Section 4.4.8: <code><nobr>%ifempty</nobr></code>: Test for Empty Expansion</a><br>
-<a href="nasmdoc4.html#section-4.5">Section 4.5: Preprocessor Loops: <code><nobr>%rep</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.6">Section 4.6: Source Files and Dependencies</a><br>
-<a href="nasmdoc4.html#section-4.6.1">Section 4.6.1: <code><nobr>%include</nobr></code>: Including Other Files</a><br>
-<a href="nasmdoc4.html#section-4.6.2">Section 4.6.2: <code><nobr>%pathsearch</nobr></code>: Search the Include Path</a><br>
-<a href="nasmdoc4.html#section-4.6.3">Section 4.6.3: <code><nobr>%depend</nobr></code>: Add Dependent Files</a><br>
-<a href="nasmdoc4.html#section-4.6.4">Section 4.6.4: <code><nobr>%use</nobr></code>: Include Standard Macro Package</a><br>
-<a href="nasmdoc4.html#section-4.7">Section 4.7: The Context Stack</a><br>
-<a href="nasmdoc4.html#section-4.7.1">Section 4.7.1: <code><nobr>%push</nobr></code> and <code><nobr>%pop</nobr></code>: Creating and Removing Contexts</a><br>
-<a href="nasmdoc4.html#section-4.7.2">Section 4.7.2: Context-Local Labels</a><br>
-<a href="nasmdoc4.html#section-4.7.3">Section 4.7.3: Context-Local Single-Line Macros</a><br>
-<a href="nasmdoc4.html#section-4.7.4">Section 4.7.4: <code><nobr>%repl</nobr></code>: Renaming a Context</a><br>
-<a href="nasmdoc4.html#section-4.7.5">Section 4.7.5: Example Use of the Context Stack: Block IFs</a><br>
-<a href="nasmdoc4.html#section-4.8">Section 4.8: Stack Relative Preprocessor Directives</a><br>
-<a href="nasmdoc4.html#section-4.8.1">Section 4.8.1: <code><nobr>%arg</nobr></code> Directive</a><br>
-<a href="nasmdoc4.html#section-4.8.2">Section 4.8.2: <code><nobr>%stacksize</nobr></code> Directive</a><br>
-<a href="nasmdoc4.html#section-4.8.3">Section 4.8.3: <code><nobr>%local</nobr></code> Directive</a><br>
-<a href="nasmdoc4.html#section-4.9">Section 4.9: Reporting User-Defined Errors: <code><nobr>%error</nobr></code>, <code><nobr>%warning</nobr></code>, <code><nobr>%fatal</nobr></code></a><br>
-<a href="nasmdoc4.html#section-4.10">Section 4.10: Other Preprocessor Directives</a><br>
-<a href="nasmdoc4.html#section-4.10.1">Section 4.10.1: <code><nobr>%line</nobr></code> Directive</a><br>
-<a href="nasmdoc4.html#section-4.10.2">Section 4.10.2: <code><nobr>%!</nobr></code><code><nobr>&lt;env&gt;</nobr></code>: Read an environment variable.</a><br>
-<a href="nasmdoc4.html#section-4.11">Section 4.11: Standard Macros</a><br>
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1: NASM Version Macros</a><br>
-<a href="nasmdoc4.html#section-4.11.2">Section 4.11.2: <code><nobr>__NASM_VERSION_ID__</nobr></code>: NASM Version ID</a><br>
-<a href="nasmdoc4.html#section-4.11.3">Section 4.11.3: <code><nobr>__NASM_VER__</nobr></code>: NASM Version string</a><br>
-<a href="nasmdoc4.html#section-4.11.4">Section 4.11.4: <code><nobr>__FILE__</nobr></code> and <code><nobr>__LINE__</nobr></code>: File Name and Line Number</a><br>
-<a href="nasmdoc4.html#section-4.11.5">Section 4.11.5: <code><nobr>__BITS__</nobr></code>: Current BITS Mode</a><br>
-<a href="nasmdoc4.html#section-4.11.6">Section 4.11.6: <code><nobr>__OUTPUT_FORMAT__</nobr></code>: Current Output Format</a><br>
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7: Assembly Date and Time Macros</a><br>
-<a href="nasmdoc4.html#section-4.11.8">Section 4.11.8: <code><nobr>__USE_</nobr></code><em>package</em><code><nobr>__</nobr></code>: Package Include Test</a><br>
-<a href="nasmdoc4.html#section-4.11.9">Section 4.11.9: <code><nobr>__PASS__</nobr></code>: Assembly Pass</a><br>
-<a href="nasmdoc4.html#section-4.11.10">Section 4.11.10: <code><nobr>STRUC</nobr></code> and <code><nobr>ENDSTRUC</nobr></code>: Declaring Structure Data Types</a><br>
-<a href="nasmdoc4.html#section-4.11.11">Section 4.11.11: <code><nobr>ISTRUC</nobr></code>, <code><nobr>AT</nobr></code> and <code><nobr>IEND</nobr></code>: Declaring Instances of Structures</a><br>
-<a href="nasmdoc4.html#section-4.11.12">Section 4.11.12: <code><nobr>ALIGN</nobr></code> and <code><nobr>ALIGNB</nobr></code>: Data Alignment</a><br>
-<p><a href="nasmdoc5.html">Chapter 5: Standard Macro Packages</a><br>
-<a href="nasmdoc5.html#section-5.1">Section 5.1: <code><nobr>altreg</nobr></code>: Alternate Register Names</a><br>
-<a href="nasmdoc5.html#section-5.2">Section 5.2: <code><nobr>smartalign</nobr></code>: Smart <code><nobr>ALIGN</nobr></code> Macro</a><br>
-<p><a href="nasmdoc6.html">Chapter 6: Assembler Directives</a><br>
-<a href="nasmdoc6.html#section-6.1">Section 6.1: <code><nobr>BITS</nobr></code>: Specifying Target Processor Mode</a><br>
-<a href="nasmdoc6.html#section-6.1.1">Section 6.1.1: <code><nobr>USE16</nobr></code> &amp; <code><nobr>USE32</nobr></code>: Aliases for BITS</a><br>
-<a href="nasmdoc6.html#section-6.2">Section 6.2: <code><nobr>DEFAULT</nobr></code>: Change the assembler defaults</a><br>
-<a href="nasmdoc6.html#section-6.3">Section 6.3: <code><nobr>SECTION</nobr></code> or <code><nobr>SEGMENT</nobr></code>: Changing and Defining Sections</a><br>
-<a href="nasmdoc6.html#section-6.3.1">Section 6.3.1: The <code><nobr>__SECT__</nobr></code> Macro</a><br>
-<a href="nasmdoc6.html#section-6.4">Section 6.4: <code><nobr>ABSOLUTE</nobr></code>: Defining Absolute Labels</a><br>
-<a href="nasmdoc6.html#section-6.5">Section 6.5: <code><nobr>EXTERN</nobr></code>: Importing Symbols from Other Modules</a><br>
-<a href="nasmdoc6.html#section-6.6">Section 6.6: <code><nobr>GLOBAL</nobr></code>: Exporting Symbols to Other Modules</a><br>
-<a href="nasmdoc6.html#section-6.7">Section 6.7: <code><nobr>COMMON</nobr></code>: Defining Common Data Areas</a><br>
-<a href="nasmdoc6.html#section-6.8">Section 6.8: <code><nobr>CPU</nobr></code>: Defining CPU Dependencies</a><br>
-<a href="nasmdoc6.html#section-6.9">Section 6.9: <code><nobr>FLOAT</nobr></code>: Handling of floating-point constants</a><br>
-<p><a href="nasmdoc7.html">Chapter 7: Output Formats</a><br>
-<a href="nasmdoc7.html#section-7.1">Section 7.1: <code><nobr>bin</nobr></code>: Flat-Form Binary Output</a><br>
-<a href="nasmdoc7.html#section-7.1.1">Section 7.1.1: <code><nobr>ORG</nobr></code>: Binary File Program Origin</a><br>
-<a href="nasmdoc7.html#section-7.1.2">Section 7.1.2: <code><nobr>bin</nobr></code> Extensions to the <code><nobr>SECTION</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3: Multisection Support for the <code><nobr>bin</nobr></code> Format</a><br>
-<a href="nasmdoc7.html#section-7.1.4">Section 7.1.4: Map Files</a><br>
-<a href="nasmdoc7.html#section-7.2">Section 7.2: <code><nobr>ith</nobr></code>: Intel Hex Output</a><br>
-<a href="nasmdoc7.html#section-7.3">Section 7.3: <code><nobr>srec</nobr></code>: Motorola S-Records Output</a><br>
-<a href="nasmdoc7.html#section-7.4">Section 7.4: <code><nobr>obj</nobr></code>: Microsoft OMF Object Files</a><br>
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1: <code><nobr>obj</nobr></code> Extensions to the <code><nobr>SEGMENT</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.4.2">Section 7.4.2: <code><nobr>GROUP</nobr></code>: Defining Groups of Segments</a><br>
-<a href="nasmdoc7.html#section-7.4.3">Section 7.4.3: <code><nobr>UPPERCASE</nobr></code>: Disabling Case Sensitivity in Output</a><br>
-<a href="nasmdoc7.html#section-7.4.4">Section 7.4.4: <code><nobr>IMPORT</nobr></code>: Importing DLL Symbols</a><br>
-<a href="nasmdoc7.html#section-7.4.5">Section 7.4.5: <code><nobr>EXPORT</nobr></code>: Exporting DLL Symbols</a><br>
-<a href="nasmdoc7.html#section-7.4.6">Section 7.4.6: <code><nobr>..start</nobr></code>: Defining the Program Entry Point</a><br>
-<a href="nasmdoc7.html#section-7.4.7">Section 7.4.7: <code><nobr>obj</nobr></code> Extensions to the <code><nobr>EXTERN</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.4.8">Section 7.4.8: <code><nobr>obj</nobr></code> Extensions to the <code><nobr>COMMON</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.5">Section 7.5: <code><nobr>win32</nobr></code>: Microsoft Win32 Object Files</a><br>
-<a href="nasmdoc7.html#section-7.5.1">Section 7.5.1: <code><nobr>win32</nobr></code> Extensions to the <code><nobr>SECTION</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.5.2">Section 7.5.2: <code><nobr>win32</nobr></code>: Safe Structured Exception Handling</a><br>
-<a href="nasmdoc7.html#section-7.6">Section 7.6: <code><nobr>win64</nobr></code>: Microsoft Win64 Object Files</a><br>
-<a href="nasmdoc7.html#section-7.6.1">Section 7.6.1: <code><nobr>win64</nobr></code>: Writing Position-Independent Code</a><br>
-<a href="nasmdoc7.html#section-7.6.2">Section 7.6.2: <code><nobr>win64</nobr></code>: Structured Exception Handling</a><br>
-<a href="nasmdoc7.html#section-7.7">Section 7.7: <code><nobr>coff</nobr></code>: Common Object File Format</a><br>
-<a href="nasmdoc7.html#section-7.8">Section 7.8: <code><nobr>macho32</nobr></code> and <code><nobr>macho64</nobr></code>: Mach Object File Format</a><br>
-<a href="nasmdoc7.html#section-7.9">Section 7.9: <code><nobr>elf32</nobr></code> and <code><nobr>elf64</nobr></code>: Executable and Linkable Format Object Files</a><br>
-<a href="nasmdoc7.html#section-7.9.1">Section 7.9.1: ELF specific directive <code><nobr>osabi</nobr></code></a><br>
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2: <code><nobr>elf</nobr></code> Extensions to the <code><nobr>SECTION</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3: Position-Independent Code: <code><nobr>elf</nobr></code> Special Symbols and <code><nobr>WRT</nobr></code></a><br>
-<a href="nasmdoc7.html#section-7.9.4">Section 7.9.4: Thread Local Storage: <code><nobr>elf</nobr></code> Special Symbols and <code><nobr>WRT</nobr></code></a><br>
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5: <code><nobr>elf</nobr></code> Extensions to the <code><nobr>GLOBAL</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.9.6">Section 7.9.6: <code><nobr>elf</nobr></code> Extensions to the <code><nobr>COMMON</nobr></code> Directive </a><br>
-<a href="nasmdoc7.html#section-7.9.7">Section 7.9.7: 16-bit code and ELF </a><br>
-<a href="nasmdoc7.html#section-7.9.8">Section 7.9.8: Debug formats and ELF </a><br>
-<a href="nasmdoc7.html#section-7.10">Section 7.10: <code><nobr>aout</nobr></code>: Linux <code><nobr>a.out</nobr></code> Object Files</a><br>
-<a href="nasmdoc7.html#section-7.11">Section 7.11: <code><nobr>aoutb</nobr></code>: NetBSD/FreeBSD/OpenBSD <code><nobr>a.out</nobr></code> Object Files</a><br>
-<a href="nasmdoc7.html#section-7.12">Section 7.12: <code><nobr>as86</nobr></code>: Minix/Linux <code><nobr>as86</nobr></code> Object Files</a><br>
-<a href="nasmdoc7.html#section-7.13">Section 7.13: <code><nobr>rdf</nobr></code>: Relocatable Dynamic Object File Format</a><br>
-<a href="nasmdoc7.html#section-7.13.1">Section 7.13.1: Requiring a Library: The <code><nobr>LIBRARY</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.13.2">Section 7.13.2: Specifying a Module Name: The <code><nobr>MODULE</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.13.3">Section 7.13.3: <code><nobr>rdf</nobr></code> Extensions to the <code><nobr>GLOBAL</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.13.4">Section 7.13.4: <code><nobr>rdf</nobr></code> Extensions to the <code><nobr>EXTERN</nobr></code> Directive</a><br>
-<a href="nasmdoc7.html#section-7.14">Section 7.14: <code><nobr>dbg</nobr></code>: Debugging Format</a><br>
-<p><a href="nasmdoc8.html">Chapter 8: Writing 16-bit Code (DOS, Windows 3/3.1)</a><br>
-<a href="nasmdoc8.html#section-8.1">Section 8.1: Producing <code><nobr>.EXE</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1: Using the <code><nobr>obj</nobr></code> Format To Generate <code><nobr>.EXE</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.1.2">Section 8.1.2: Using the <code><nobr>bin</nobr></code> Format To Generate <code><nobr>.EXE</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.2">Section 8.2: Producing <code><nobr>.COM</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.2.1">Section 8.2.1: Using the <code><nobr>bin</nobr></code> Format To Generate <code><nobr>.COM</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.2.2">Section 8.2.2: Using the <code><nobr>obj</nobr></code> Format To Generate <code><nobr>.COM</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.3">Section 8.3: Producing <code><nobr>.SYS</nobr></code> Files</a><br>
-<a href="nasmdoc8.html#section-8.4">Section 8.4: Interfacing to 16-bit C Programs</a><br>
-<a href="nasmdoc8.html#section-8.4.1">Section 8.4.1: External Symbol Names</a><br>
-<a href="nasmdoc8.html#section-8.4.2">Section 8.4.2: Memory Models</a><br>
-<a href="nasmdoc8.html#section-8.4.3">Section 8.4.3: Function Definitions and Function Calls</a><br>
-<a href="nasmdoc8.html#section-8.4.4">Section 8.4.4: Accessing Data Items</a><br>
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5: <code><nobr>c16.mac</nobr></code>: Helper Macros for the 16-bit C Interface</a><br>
-<a href="nasmdoc8.html#section-8.5">Section 8.5: Interfacing to Borland Pascal Programs</a><br>
-<a href="nasmdoc8.html#section-8.5.1">Section 8.5.1: The Pascal Calling Convention</a><br>
-<a href="nasmdoc8.html#section-8.5.2">Section 8.5.2: Borland Pascal Segment Name Restrictions</a><br>
-<a href="nasmdoc8.html#section-8.5.3">Section 8.5.3: Using <code><nobr>c16.mac</nobr></code> With Pascal Programs</a><br>
-<p><a href="nasmdoc9.html">Chapter 9: Writing 32-bit Code (Unix, Win32, DJGPP)</a><br>
-<a href="nasmdoc9.html#section-9.1">Section 9.1: Interfacing to 32-bit C Programs</a><br>
-<a href="nasmdoc9.html#section-9.1.1">Section 9.1.1: External Symbol Names</a><br>
-<a href="nasmdoc9.html#section-9.1.2">Section 9.1.2: Function Definitions and Function Calls</a><br>
-<a href="nasmdoc9.html#section-9.1.3">Section 9.1.3: Accessing Data Items</a><br>
-<a href="nasmdoc9.html#section-9.1.4">Section 9.1.4: <code><nobr>c32.mac</nobr></code>: Helper Macros for the 32-bit C Interface</a><br>
-<a href="nasmdoc9.html#section-9.2">Section 9.2: Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries</a><br>
-<a href="nasmdoc9.html#section-9.2.1">Section 9.2.1: Obtaining the Address of the GOT</a><br>
-<a href="nasmdoc9.html#section-9.2.2">Section 9.2.2: Finding Your Local Data Items</a><br>
-<a href="nasmdoc9.html#section-9.2.3">Section 9.2.3: Finding External and Common Data Items</a><br>
-<a href="nasmdoc9.html#section-9.2.4">Section 9.2.4: Exporting Symbols to the Library User</a><br>
-<a href="nasmdoc9.html#section-9.2.5">Section 9.2.5: Calling Procedures Outside the Library</a><br>
-<a href="nasmdoc9.html#section-9.2.6">Section 9.2.6: Generating the Library File</a><br>
-<p><a href="nasmdo10.html">Chapter 10: Mixing 16 and 32 Bit Code</a><br>
-<a href="nasmdo10.html#section-10.1">Section 10.1: Mixed-Size Jumps</a><br>
-<a href="nasmdo10.html#section-10.2">Section 10.2: Addressing Between Different-Size Segments</a><br>
-<a href="nasmdo10.html#section-10.3">Section 10.3: Other Mixed-Size Instructions</a><br>
-<p><a href="nasmdo11.html">Chapter 11: Writing 64-bit Code (Unix, Win64)</a><br>
-<a href="nasmdo11.html#section-11.1">Section 11.1: Register Names in 64-bit Mode</a><br>
-<a href="nasmdo11.html#section-11.2">Section 11.2: Immediates and Displacements in 64-bit Mode</a><br>
-<a href="nasmdo11.html#section-11.3">Section 11.3: Interfacing to 64-bit C Programs (Unix)</a><br>
-<a href="nasmdo11.html#section-11.4">Section 11.4: Interfacing to 64-bit C Programs (Win64)</a><br>
-<p><a href="nasmdo12.html">Chapter 12: Troubleshooting</a><br>
-<a href="nasmdo12.html#section-12.1">Section 12.1: Common Problems</a><br>
-<a href="nasmdo12.html#section-12.1.1">Section 12.1.1: NASM Generates Inefficient Code</a><br>
-<a href="nasmdo12.html#section-12.1.2">Section 12.1.2: My Jumps are Out of Range</a><br>
-<a href="nasmdo12.html#section-12.1.3">Section 12.1.3: <code><nobr>ORG</nobr></code> Doesn't Work</a><br>
-<a href="nasmdo12.html#section-12.1.4">Section 12.1.4: <code><nobr>TIMES</nobr></code> Doesn't Work</a><br>
-<a href="nasmdo12.html#section-12.2">Section 12.2: Bugs</a><br>
-<p><a href="nasmdoca.html">Appendix A: Ndisasm</a><br>
-<a href="nasmdoca.html#section-A.1">Section A.1: Introduction</a><br>
-<a href="nasmdoca.html#section-A.2">Section A.2: Getting Started: Installation</a><br>
-<a href="nasmdoca.html#section-A.3">Section A.3: Running NDISASM</a><br>
-<a href="nasmdoca.html#section-A.3.1">Section A.3.1: COM Files: Specifying an Origin</a><br>
-<a href="nasmdoca.html#section-A.3.2">Section A.3.2: Code Following Data: Synchronisation</a><br>
-<a href="nasmdoca.html#section-A.3.3">Section A.3.3: Mixed Code and Data: Automatic (Intelligent) Synchronisation </a><br>
-<a href="nasmdoca.html#section-A.3.4">Section A.3.4: Other Options</a><br>
-<a href="nasmdoca.html#section-A.4">Section A.4: Bugs and Improvements</a><br>
-<p><a href="nasmdocb.html">Appendix B: Instruction List</a><br>
-<a href="nasmdocb.html#section-B.1">Section B.1: Introduction</a><br>
-<a href="nasmdocb.html#section-B.1.1">Section B.1.1: Special instructions...</a><br>
-<a href="nasmdocb.html#section-B.1.2">Section B.1.2: Conventional instructions</a><br>
-<a href="nasmdocb.html#section-B.1.3">Section B.1.3: Katmai Streaming SIMD instructions (SSE -- a.k.a. KNI, XMM, MMX2)</a><br>
-<a href="nasmdocb.html#section-B.1.4">Section B.1.4: Introduced in Deschutes but necessary for SSE support</a><br>
-<a href="nasmdocb.html#section-B.1.5">Section B.1.5: XSAVE group (AVX and extended state)</a><br>
-<a href="nasmdocb.html#section-B.1.6">Section B.1.6: Generic memory operations</a><br>
-<a href="nasmdocb.html#section-B.1.7">Section B.1.7: New MMX instructions introduced in Katmai</a><br>
-<a href="nasmdocb.html#section-B.1.8">Section B.1.8: AMD Enhanced 3DNow! (Athlon) instructions</a><br>
-<a href="nasmdocb.html#section-B.1.9">Section B.1.9: Willamette SSE2 Cacheability Instructions</a><br>
-<a href="nasmdocb.html#section-B.1.10">Section B.1.10: Willamette MMX instructions (SSE2 SIMD Integer Instructions)</a><br>
-<a href="nasmdocb.html#section-B.1.11">Section B.1.11: Willamette Streaming SIMD instructions (SSE2)</a><br>
-<a href="nasmdocb.html#section-B.1.12">Section B.1.12: Prescott New Instructions (SSE3)</a><br>
-<a href="nasmdocb.html#section-B.1.13">Section B.1.13: VMX Instructions</a><br>
-<a href="nasmdocb.html#section-B.1.14">Section B.1.14: Extended Page Tables VMX instructions</a><br>
-<a href="nasmdocb.html#section-B.1.15">Section B.1.15: Tejas New Instructions (SSSE3)</a><br>
-<a href="nasmdocb.html#section-B.1.16">Section B.1.16: AMD SSE4A</a><br>
-<a href="nasmdocb.html#section-B.1.17">Section B.1.17: New instructions in Barcelona</a><br>
-<a href="nasmdocb.html#section-B.1.18">Section B.1.18: Penryn New Instructions (SSE4.1)</a><br>
-<a href="nasmdocb.html#section-B.1.19">Section B.1.19: Nehalem New Instructions (SSE4.2)</a><br>
-<a href="nasmdocb.html#section-B.1.20">Section B.1.20: Intel SMX</a><br>
-<a href="nasmdocb.html#section-B.1.21">Section B.1.21: Geode (Cyrix) 3DNow! additions</a><br>
-<a href="nasmdocb.html#section-B.1.22">Section B.1.22: Intel new instructions in ???</a><br>
-<a href="nasmdocb.html#section-B.1.23">Section B.1.23: Intel AES instructions</a><br>
-<a href="nasmdocb.html#section-B.1.24">Section B.1.24: Intel AVX AES instructions</a><br>
-<a href="nasmdocb.html#section-B.1.25">Section B.1.25: Intel AVX instructions</a><br>
-<a href="nasmdocb.html#section-B.1.26">Section B.1.26: Intel Carry-Less Multiplication instructions (CLMUL)</a><br>
-<a href="nasmdocb.html#section-B.1.27">Section B.1.27: Intel AVX Carry-Less Multiplication instructions (CLMUL)</a><br>
-<a href="nasmdocb.html#section-B.1.28">Section B.1.28: Intel Fused Multiply-Add instructions (FMA)</a><br>
-<a href="nasmdocb.html#section-B.1.29">Section B.1.29: VIA (Centaur) security instructions</a><br>
-<a href="nasmdocb.html#section-B.1.30">Section B.1.30: AMD Lightweight Profiling (LWP) instructions</a><br>
-<a href="nasmdocb.html#section-B.1.31">Section B.1.31: AMD XOP, FMA4 and CVT16 instructions (SSE5)</a><br>
-<a href="nasmdocb.html#section-B.1.32">Section B.1.32: Systematic names for the hinting nop instructions</a><br>
-<p><a href="nasmdocc.html">Appendix C: NASM Version History</a><br>
-<a href="nasmdocc.html#section-C.1">Section C.1: NASM 2 Series</a><br>
-<a href="nasmdocc.html#section-C.1.1">Section C.1.1: Version 2.08</a><br>
-<a href="nasmdocc.html#section-C.1.2">Section C.1.2: Version 2.07</a><br>
-<a href="nasmdocc.html#section-C.1.3">Section C.1.3: Version 2.06</a><br>
-<a href="nasmdocc.html#section-C.1.4">Section C.1.4: Version 2.05.01</a><br>
-<a href="nasmdocc.html#section-C.1.5">Section C.1.5: Version 2.05</a><br>
-<a href="nasmdocc.html#section-C.1.6">Section C.1.6: Version 2.04</a><br>
-<a href="nasmdocc.html#section-C.1.7">Section C.1.7: Version 2.03.01</a><br>
-<a href="nasmdocc.html#section-C.1.8">Section C.1.8: Version 2.03</a><br>
-<a href="nasmdocc.html#section-C.1.9">Section C.1.9: Version 2.02</a><br>
-<a href="nasmdocc.html#section-C.1.10">Section C.1.10: Version 2.01</a><br>
-<a href="nasmdocc.html#section-C.1.11">Section C.1.11: Version 2.00</a><br>
-<a href="nasmdocc.html#section-C.2">Section C.2: NASM 0.98 Series</a><br>
-<a href="nasmdocc.html#section-C.2.1">Section C.2.1: Version 0.98.39</a><br>
-<a href="nasmdocc.html#section-C.2.2">Section C.2.2: Version 0.98.38</a><br>
-<a href="nasmdocc.html#section-C.2.3">Section C.2.3: Version 0.98.37</a><br>
-<a href="nasmdocc.html#section-C.2.4">Section C.2.4: Version 0.98.36</a><br>
-<a href="nasmdocc.html#section-C.2.5">Section C.2.5: Version 0.98.35</a><br>
-<a href="nasmdocc.html#section-C.2.6">Section C.2.6: Version 0.98.34</a><br>
-<a href="nasmdocc.html#section-C.2.7">Section C.2.7: Version 0.98.33</a><br>
-<a href="nasmdocc.html#section-C.2.8">Section C.2.8: Version 0.98.32</a><br>
-<a href="nasmdocc.html#section-C.2.9">Section C.2.9: Version 0.98.31</a><br>
-<a href="nasmdocc.html#section-C.2.10">Section C.2.10: Version 0.98.30</a><br>
-<a href="nasmdocc.html#section-C.2.11">Section C.2.11: Version 0.98.28</a><br>
-<a href="nasmdocc.html#section-C.2.12">Section C.2.12: Version 0.98.26</a><br>
-<a href="nasmdocc.html#section-C.2.13">Section C.2.13: Version 0.98.25alt</a><br>
-<a href="nasmdocc.html#section-C.2.14">Section C.2.14: Version 0.98.25</a><br>
-<a href="nasmdocc.html#section-C.2.15">Section C.2.15: Version 0.98.24p1</a><br>
-<a href="nasmdocc.html#section-C.2.16">Section C.2.16: Version 0.98.24</a><br>
-<a href="nasmdocc.html#section-C.2.17">Section C.2.17: Version 0.98.23</a><br>
-<a href="nasmdocc.html#section-C.2.18">Section C.2.18: Version 0.98.22</a><br>
-<a href="nasmdocc.html#section-C.2.19">Section C.2.19: Version 0.98.21</a><br>
-<a href="nasmdocc.html#section-C.2.20">Section C.2.20: Version 0.98.20</a><br>
-<a href="nasmdocc.html#section-C.2.21">Section C.2.21: Version 0.98.19</a><br>
-<a href="nasmdocc.html#section-C.2.22">Section C.2.22: Version 0.98.18</a><br>
-<a href="nasmdocc.html#section-C.2.23">Section C.2.23: Version 0.98.17</a><br>
-<a href="nasmdocc.html#section-C.2.24">Section C.2.24: Version 0.98.16</a><br>
-<a href="nasmdocc.html#section-C.2.25">Section C.2.25: Version 0.98.15</a><br>
-<a href="nasmdocc.html#section-C.2.26">Section C.2.26: Version 0.98.14</a><br>
-<a href="nasmdocc.html#section-C.2.27">Section C.2.27: Version 0.98.13</a><br>
-<a href="nasmdocc.html#section-C.2.28">Section C.2.28: Version 0.98.12</a><br>
-<a href="nasmdocc.html#section-C.2.29">Section C.2.29: Version 0.98.11</a><br>
-<a href="nasmdocc.html#section-C.2.30">Section C.2.30: Version 0.98.10</a><br>
-<a href="nasmdocc.html#section-C.2.31">Section C.2.31: Version 0.98.09</a><br>
-<a href="nasmdocc.html#section-C.2.32">Section C.2.32: Version 0.98.08</a><br>
-<a href="nasmdocc.html#section-C.2.33">Section C.2.33: Version 0.98.09b with John Coffman patches released 28-Oct-2001</a><br>
-<a href="nasmdocc.html#section-C.2.34">Section C.2.34: Version 0.98.07 released 01/28/01</a><br>
-<a href="nasmdocc.html#section-C.2.35">Section C.2.35: Version 0.98.06f released 01/18/01</a><br>
-<a href="nasmdocc.html#section-C.2.36">Section C.2.36: Version 0.98.06e released 01/09/01</a><br>
-<a href="nasmdocc.html#section-C.2.37">Section C.2.37: Version 0.98p1</a><br>
-<a href="nasmdocc.html#section-C.2.38">Section C.2.38: Version 0.98bf (bug-fixed)</a><br>
-<a href="nasmdocc.html#section-C.2.39">Section C.2.39: Version 0.98.03 with John Coffman's changes released 27-Jul-2000</a><br>
-<a href="nasmdocc.html#section-C.2.40">Section C.2.40: Version 0.98.03</a><br>
-<a href="nasmdocc.html#section-C.2.41">Section C.2.41: Version 0.98</a><br>
-<a href="nasmdocc.html#section-C.2.42">Section C.2.42: Version 0.98p9</a><br>
-<a href="nasmdocc.html#section-C.2.43">Section C.2.43: Version 0.98p8</a><br>
-<a href="nasmdocc.html#section-C.2.44">Section C.2.44: Version 0.98p7</a><br>
-<a href="nasmdocc.html#section-C.2.45">Section C.2.45: Version 0.98p6</a><br>
-<a href="nasmdocc.html#section-C.2.46">Section C.2.46: Version 0.98p3.7</a><br>
-<a href="nasmdocc.html#section-C.2.47">Section C.2.47: Version 0.98p3.6</a><br>
-<a href="nasmdocc.html#section-C.2.48">Section C.2.48: Version 0.98p3.5</a><br>
-<a href="nasmdocc.html#section-C.2.49">Section C.2.49: Version 0.98p3.4</a><br>
-<a href="nasmdocc.html#section-C.2.50">Section C.2.50: Version 0.98p3.3</a><br>
-<a href="nasmdocc.html#section-C.2.51">Section C.2.51: Version 0.98p3.2</a><br>
-<a href="nasmdocc.html#section-C.2.52">Section C.2.52: Version 0.98p3-hpa</a><br>
-<a href="nasmdocc.html#section-C.2.53">Section C.2.53: Version 0.98 pre-release 3</a><br>
-<a href="nasmdocc.html#section-C.2.54">Section C.2.54: Version 0.98 pre-release 2</a><br>
-<a href="nasmdocc.html#section-C.2.55">Section C.2.55: Version 0.98 pre-release 1</a><br>
-<a href="nasmdocc.html#section-C.3">Section C.3: NASM 0.9 Series</a><br>
-<a href="nasmdocc.html#section-C.3.1">Section C.3.1: Version 0.97 released December 1997</a><br>
-<a href="nasmdocc.html#section-C.3.2">Section C.3.2: Version 0.96 released November 1997</a><br>
-<a href="nasmdocc.html#section-C.3.3">Section C.3.3: Version 0.95 released July 1997</a><br>
-<a href="nasmdocc.html#section-C.3.4">Section C.3.4: Version 0.94 released April 1997</a><br>
-<a href="nasmdocc.html#section-C.3.5">Section C.3.5: Version 0.93 released January 1997</a><br>
-<a href="nasmdocc.html#section-C.3.6">Section C.3.6: Version 0.92 released January 1997</a><br>
-<a href="nasmdocc.html#section-C.3.7">Section C.3.7: Version 0.91 released November 1996</a><br>
-<a href="nasmdocc.html#section-C.3.8">Section C.3.8: Version 0.90 released October 1996</a><br>
-<p><a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdoc1.html b/doc/html/nasmdoc1.html
deleted file mode 100644
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--- a/doc/html/nasmdoc1.html
+++ /dev/null
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc2.html">Next Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-1">Chapter 1: Introduction</a></h2>
-<h3><a name="section-1.1">1.1 What Is NASM?</a></h3>
-<p>The Netwide Assembler, NASM, is an 80x86 and x86-64 assembler designed
-for portability and modularity. It supports a range of object file formats,
-including Linux and <code><nobr>*BSD</nobr></code>
-<code><nobr>a.out</nobr></code>, <code><nobr>ELF</nobr></code>,
-<code><nobr>COFF</nobr></code>, <code><nobr>Mach-O</nobr></code>, Microsoft
-16-bit <code><nobr>OBJ</nobr></code>, <code><nobr>Win32</nobr></code> and
-<code><nobr>Win64</nobr></code>. It will also output plain binary files.
-Its syntax is designed to be simple and easy to understand, similar to
-Intel's but less complex. It supports all currently known x86 architectural
-extensions, and has strong support for macros.
-<h4><a name="section-1.1.1">1.1.1 Why Yet Another Assembler?</a></h4>
-<p>The Netwide Assembler grew out of an idea on
-<code><nobr>comp.lang.asm.x86</nobr></code> (or possibly
-<code><nobr>alt.lang.asm</nobr></code> - I forget which), which was
-essentially that there didn't seem to be a good <em>free</em> x86-series
-assembler around, and that maybe someone ought to write one.
-<ul>
-<li><code><nobr>a86</nobr></code> is good, but not free, and in particular
-you don't get any 32-bit capability until you pay. It's DOS only, too.
-<li><code><nobr>gas</nobr></code> is free, and ports over to DOS and Unix,
-but it's not very good, since it's designed to be a back end to
-<code><nobr>gcc</nobr></code>, which always feeds it correct code. So its
-error checking is minimal. Also, its syntax is horrible, from the point of
-view of anyone trying to actually <em>write</em> anything in it. Plus you
-can't write 16-bit code in it (properly.)
-<li><code><nobr>as86</nobr></code> is specific to Minix and Linux, and (my
-version at least) doesn't seem to have much (or any) documentation.
-<li><code><nobr>MASM</nobr></code> isn't very good, and it's (was)
-expensive, and it runs only under DOS.
-<li><code><nobr>TASM</nobr></code> is better, but still strives for MASM
-compatibility, which means millions of directives and tons of red tape. And
-its syntax is essentially MASM's, with the contradictions and quirks that
-entails (although it sorts out some of those by means of Ideal mode.) It's
-expensive too. And it's DOS-only.
-</ul>
-<p>So here, for your coding pleasure, is NASM. At present it's still in
-prototype stage - we don't promise that it can outperform any of these
-assemblers. But please, <em>please</em> send us bug reports, fixes, helpful
-information, and anything else you can get your hands on (and thanks to the
-many people who've done this already! You all know who you are), and we'll
-improve it out of all recognition. Again.
-<h4><a name="section-1.1.2">1.1.2 License Conditions</a></h4>
-<p>Please see the file <code><nobr>LICENSE</nobr></code>, supplied as part
-of any NASM distribution archive, for the license conditions under which
-you may use NASM. NASM is now under the so-called 2-clause BSD license,
-also known as the simplified BSD license.
-<p>Copyright 1996-2009 the NASM Authors - All rights reserved.
-<p>Redistribution and use in source and binary forms, with or without
-modification, are permitted provided that the following conditions are met:
-<ul>
-<li>Redistributions of source code must retain the above copyright notice,
-this list of conditions and the following disclaimer.
-<li>Redistributions in binary form must reproduce the above copyright
-notice, this list of conditions and the following disclaimer in the
-documentation and/or other materials provided with the distribution.
-</ul>
-<p>THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
-THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
-PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
-CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
-EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
-PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
-OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
-WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
-OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
-ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-<h3><a name="section-1.2">1.2 Contact Information</a></h3>
-<p>The current version of NASM (since about 0.98.08) is maintained by a
-team of developers, accessible through the
-<code><nobr>nasm-devel</nobr></code> mailing list (see below for the link).
-If you want to report a bug, please read
-<a href="nasmdo12.html#section-12.2">section 12.2</a> first.
-<p>NASM has a website at
-<a href="http://www.nasm.us/"><code><nobr>http://www.nasm.us/</nobr></code></a>.
-If it's not there, google for us!
-<p>New releases, release candidates, and daily development snapshots of
-NASM are available from the official web site.
-<p>Announcements are posted to
-<a href="news:comp.lang.asm.x86"><code><nobr>comp.lang.asm.x86</nobr></code></a>,
-and to the web site
-<a href="http://www.freshmeat.net/"><code><nobr>http://www.freshmeat.net/</nobr></code></a>.
-<p>If you want information about the current development status, please
-subscribe to the <code><nobr>nasm-devel</nobr></code> email list; see link
-from the website.
-<h3><a name="section-1.3">1.3 Installation</a></h3>
-<h4><a name="section-1.3.1">1.3.1 Installing NASM under MS-DOS or Windows</a></h4>
-<p>Once you've obtained the appropriate archive for NASM,
-<code><nobr>nasm-XXX-dos.zip</nobr></code> or
-<code><nobr>nasm-XXX-win32.zip</nobr></code> (where
-<code><nobr>XXX</nobr></code> denotes the version number of NASM contained
-in the archive), unpack it into its own directory (for example
-<code><nobr>c:\nasm</nobr></code>).
-<p>The archive will contain a set of executable files: the NASM executable
-file <code><nobr>nasm.exe</nobr></code>, the NDISASM executable file
-<code><nobr>ndisasm.exe</nobr></code>, and possibly additional utilities to
-handle the RDOFF file format.
-<p>The only file NASM needs to run is its own executable, so copy
-<code><nobr>nasm.exe</nobr></code> to a directory on your PATH, or
-alternatively edit <code><nobr>autoexec.bat</nobr></code> to add the
-<code><nobr>nasm</nobr></code> directory to your
-<code><nobr>PATH</nobr></code> (to do that under Windows XP, go to Start
-&gt; Control Panel &gt; System &gt; Advanced &gt; Environment Variables;
-these instructions may work under other versions of Windows as well.)
-<p>That's it - NASM is installed. You don't need the nasm directory to be
-present to run NASM (unless you've added it to your
-<code><nobr>PATH</nobr></code>), so you can delete it if you need to save
-space; however, you may want to keep the documentation or test programs.
-<p>If you've downloaded the DOS source archive,
-<code><nobr>nasm-XXX.zip</nobr></code>, the <code><nobr>nasm</nobr></code>
-directory will also contain the full NASM source code, and a selection of
-Makefiles you can (hopefully) use to rebuild your copy of NASM from
-scratch. See the file <code><nobr>INSTALL</nobr></code> in the source
-archive.
-<p>Note that a number of files are generated from other files by Perl
-scripts. Although the NASM source distribution includes these generated
-files, you will need to rebuild them (and hence, will need a Perl
-interpreter) if you change insns.dat, standard.mac or the documentation. It
-is possible future source distributions may not include these files at all.
-Ports of Perl for a variety of platforms, including DOS and Windows, are
-available from <a href="http://www.cpan.org/ports/">www.cpan.org</a>.
-<h4><a name="section-1.3.2">1.3.2 Installing NASM under Unix</a></h4>
-<p>Once you've obtained the Unix source archive for NASM,
-<code><nobr>nasm-XXX.tar.gz</nobr></code> (where
-<code><nobr>XXX</nobr></code> denotes the version number of NASM contained
-in the archive), unpack it into a directory such as
-<code><nobr>/usr/local/src</nobr></code>. The archive, when unpacked, will
-create its own subdirectory <code><nobr>nasm-XXX</nobr></code>.
-<p>NASM is an auto-configuring package: once you've unpacked it,
-<code><nobr>cd</nobr></code> to the directory it's been unpacked into and
-type <code><nobr>./configure</nobr></code>. This shell script will find the
-best C compiler to use for building NASM and set up Makefiles accordingly.
-<p>Once NASM has auto-configured, you can type
-<code><nobr>make</nobr></code> to build the <code><nobr>nasm</nobr></code>
-and <code><nobr>ndisasm</nobr></code> binaries, and then
-<code><nobr>make install</nobr></code> to install them in
-<code><nobr>/usr/local/bin</nobr></code> and install the man pages
-<code><nobr>nasm.1</nobr></code> and <code><nobr>ndisasm.1</nobr></code> in
-<code><nobr>/usr/local/man/man1</nobr></code>. Alternatively, you can give
-options such as <code><nobr>--prefix</nobr></code> to the configure script
-(see the file <code><nobr>INSTALL</nobr></code> for more details), or
-install the programs yourself.
-<p>NASM also comes with a set of utilities for handling the
-<code><nobr>RDOFF</nobr></code> custom object-file format, which are in the
-<code><nobr>rdoff</nobr></code> subdirectory of the NASM archive. You can
-build these with <code><nobr>make rdf</nobr></code> and install them with
-<code><nobr>make rdf_install</nobr></code>, if you want them.
-<p align=center><a href="nasmdoc2.html">Next Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdoc2.html b/doc/html/nasmdoc2.html
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc3.html">Next Chapter</a> |
-<a href="nasmdoc1.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-2">Chapter 2: Running NASM</a></h2>
-<h3><a name="section-2.1">2.1 NASM Command-Line Syntax</a></h3>
-<p>To assemble a file, you issue a command of the form
-<p><pre>
-nasm -f &lt;format&gt; &lt;filename&gt; [-o &lt;output&gt;]
-</pre>
-<p>For example,
-<p><pre>
-nasm -f elf myfile.asm
-</pre>
-<p>will assemble <code><nobr>myfile.asm</nobr></code> into an
-<code><nobr>ELF</nobr></code> object file
-<code><nobr>myfile.o</nobr></code>. And
-<p><pre>
-nasm -f bin myfile.asm -o myfile.com
-</pre>
-<p>will assemble <code><nobr>myfile.asm</nobr></code> into a raw binary
-file <code><nobr>myfile.com</nobr></code>.
-<p>To produce a listing file, with the hex codes output from NASM displayed
-on the left of the original sources, use the <code><nobr>-l</nobr></code>
-option to give a listing file name, for example:
-<p><pre>
-nasm -f coff myfile.asm -l myfile.lst
-</pre>
-<p>To get further usage instructions from NASM, try typing
-<p><pre>
-nasm -h
-</pre>
-<p>As <code><nobr>-hf</nobr></code>, this will also list the available
-output file formats, and what they are.
-<p>If you use Linux but aren't sure whether your system is
-<code><nobr>a.out</nobr></code> or <code><nobr>ELF</nobr></code>, type
-<p><pre>
-file nasm
-</pre>
-<p>(in the directory in which you put the NASM binary when you installed
-it). If it says something like
-<p><pre>
-nasm: ELF 32-bit LSB executable i386 (386 and up) Version 1
-</pre>
-<p>then your system is <code><nobr>ELF</nobr></code>, and you should use
-the option <code><nobr>-f elf</nobr></code> when you want NASM to produce
-Linux object files. If it says
-<p><pre>
-nasm: Linux/i386 demand-paged executable (QMAGIC)
-</pre>
-<p>or something similar, your system is <code><nobr>a.out</nobr></code>,
-and you should use <code><nobr>-f aout</nobr></code> instead (Linux
-<code><nobr>a.out</nobr></code> systems have long been obsolete, and are
-rare these days.)
-<p>Like Unix compilers and assemblers, NASM is silent unless it goes wrong:
-you won't see any output at all, unless it gives error messages.
-<h4><a name="section-2.1.1">2.1.1 The <code><nobr>-o</nobr></code> Option: Specifying the Output File Name</a></h4>
-<p>NASM will normally choose the name of your output file for you;
-precisely how it does this is dependent on the object file format. For
-Microsoft object file formats (<code><nobr>obj</nobr></code>,
-<code><nobr>win32</nobr></code> and <code><nobr>win64</nobr></code>), it
-will remove the <code><nobr>.asm</nobr></code> extension (or whatever
-extension you like to use - NASM doesn't care) from your source file name
-and substitute <code><nobr>.obj</nobr></code>. For Unix object file formats
-(<code><nobr>aout</nobr></code>, <code><nobr>as86</nobr></code>,
-<code><nobr>coff</nobr></code>, <code><nobr>elf32</nobr></code>,
-<code><nobr>elf64</nobr></code>, <code><nobr>ieee</nobr></code>,
-<code><nobr>macho32</nobr></code> and <code><nobr>macho64</nobr></code>) it
-will substitute <code><nobr>.o</nobr></code>. For
-<code><nobr>dbg</nobr></code>, <code><nobr>rdf</nobr></code>,
-<code><nobr>ith</nobr></code> and <code><nobr>srec</nobr></code>, it will
-use <code><nobr>.dbg</nobr></code>, <code><nobr>.rdf</nobr></code>,
-<code><nobr>.ith</nobr></code> and <code><nobr>.srec</nobr></code>,
-respectively, and for the <code><nobr>bin</nobr></code> format it will
-simply remove the extension, so that <code><nobr>myfile.asm</nobr></code>
-produces the output file <code><nobr>myfile</nobr></code>.
-<p>If the output file already exists, NASM will overwrite it, unless it has
-the same name as the input file, in which case it will give a warning and
-use <code><nobr>nasm.out</nobr></code> as the output file name instead.
-<p>For situations in which this behaviour is unacceptable, NASM provides
-the <code><nobr>-o</nobr></code> command-line option, which allows you to
-specify your desired output file name. You invoke
-<code><nobr>-o</nobr></code> by following it with the name you wish for the
-output file, either with or without an intervening space. For example:
-<p><pre>
-nasm -f bin program.asm -o program.com
-nasm -f bin driver.asm -odriver.sys
-</pre>
-<p>Note that this is a small o, and is different from a capital O , which
-is used to specify the number of optimisation passes required. See
-<a href="#section-2.1.22">section 2.1.22</a>.
-<h4><a name="section-2.1.2">2.1.2 The <code><nobr>-f</nobr></code> Option: Specifying the Output File Format</a></h4>
-<p>If you do not supply the <code><nobr>-f</nobr></code> option to NASM, it
-will choose an output file format for you itself. In the distribution
-versions of NASM, the default is always <code><nobr>bin</nobr></code>; if
-you've compiled your own copy of NASM, you can redefine
-<code><nobr>OF_DEFAULT</nobr></code> at compile time and choose what you
-want the default to be.
-<p>Like <code><nobr>-o</nobr></code>, the intervening space between
-<code><nobr>-f</nobr></code> and the output file format is optional; so
-<code><nobr>-f elf</nobr></code> and <code><nobr>-felf</nobr></code> are
-both valid.
-<p>A complete list of the available output file formats can be given by
-issuing the command <code><nobr>nasm -hf</nobr></code>.
-<h4><a name="section-2.1.3">2.1.3 The <code><nobr>-l</nobr></code> Option: Generating a Listing File</a></h4>
-<p>If you supply the <code><nobr>-l</nobr></code> option to NASM, followed
-(with the usual optional space) by a file name, NASM will generate a
-source-listing file for you, in which addresses and generated code are
-listed on the left, and the actual source code, with expansions of
-multi-line macros (except those which specifically request no expansion in
-source listings: see <a href="nasmdoc4.html#section-4.3.10">section
-4.3.10</a>) on the right. For example:
-<p><pre>
-nasm -f elf myfile.asm -l myfile.lst
-</pre>
-<p>If a list file is selected, you may turn off listing for a section of
-your source with <code><nobr>[list -]</nobr></code>, and turn it back on
-with <code><nobr>[list +]</nobr></code>, (the default, obviously). There is
-no "user form" (without the brackets). This can be used to list only
-sections of interest, avoiding excessively long listings.
-<h4><a name="section-2.1.4">2.1.4 The <code><nobr>-M</nobr></code> Option: Generate Makefile Dependencies</a></h4>
-<p>This option can be used to generate makefile dependencies on stdout.
-This can be redirected to a file for further processing. For example:
-<p><pre>
-nasm -M myfile.asm &gt; myfile.dep
-</pre>
-<h4><a name="section-2.1.5">2.1.5 The <code><nobr>-MG</nobr></code> Option: Generate Makefile Dependencies</a></h4>
-<p>This option can be used to generate makefile dependencies on stdout.
-This differs from the <code><nobr>-M</nobr></code> option in that if a
-nonexisting file is encountered, it is assumed to be a generated file and
-is added to the dependency list without a prefix.
-<h4><a name="section-2.1.6">2.1.6 The <code><nobr>-MF</nobr></code> Option: Set Makefile Dependency File</a></h4>
-<p>This option can be used with the <code><nobr>-M</nobr></code> or
-<code><nobr>-MG</nobr></code> options to send the output to a file, rather
-than to stdout. For example:
-<p><pre>
-nasm -M -MF myfile.dep myfile.asm
-</pre>
-<h4><a name="section-2.1.7">2.1.7 The <code><nobr>-MD</nobr></code> Option: Assemble and Generate Dependencies</a></h4>
-<p>The <code><nobr>-MD</nobr></code> option acts as the combination of the
-<code><nobr>-M</nobr></code> and <code><nobr>-MF</nobr></code> options
-(i.e. a filename has to be specified.) However, unlike the
-<code><nobr>-M</nobr></code> or <code><nobr>-MG</nobr></code> options,
-<code><nobr>-MD</nobr></code> does <em>not</em> inhibit the normal
-operation of the assembler. Use this to automatically generate updated
-dependencies with every assembly session. For example:
-<p><pre>
-nasm -f elf -o myfile.o -MD myfile.dep myfile.asm
-</pre>
-<h4><a name="section-2.1.8">2.1.8 The <code><nobr>-MT</nobr></code> Option: Dependency Target Name</a></h4>
-<p>The <code><nobr>-MT</nobr></code> option can be used to override the
-default name of the dependency target. This is normally the same as the
-output filename, specified by the <code><nobr>-o</nobr></code> option.
-<h4><a name="section-2.1.9">2.1.9 The <code><nobr>-MQ</nobr></code> Option: Dependency Target Name (Quoted)</a></h4>
-<p>The <code><nobr>-MQ</nobr></code> option acts as the
-<code><nobr>-MT</nobr></code> option, except it tries to quote characters
-that have special meaning in Makefile syntax. This is not foolproof, as not
-all characters with special meaning are quotable in Make.
-<h4><a name="section-2.1.10">2.1.10 The <code><nobr>-MP</nobr></code> Option: Emit phony targets</a></h4>
-<p>When used with any of the dependency generation options, the
-<code><nobr>-MP</nobr></code> option causes NASM to emit a phony target
-without dependencies for each header file. This prevents Make from
-complaining if a header file has been removed.
-<h4><a name="section-2.1.11">2.1.11 The <code><nobr>-F</nobr></code> Option: Selecting a Debug Information Format</a></h4>
-<p>This option is used to select the format of the debug information
-emitted into the output file, to be used by a debugger (or <em>will</em>
-be). Prior to version 2.03.01, the use of this switch did <em>not</em>
-enable output of the selected debug info format. Use
-<code><nobr>-g</nobr></code>, see <a href="#section-2.1.12">section
-2.1.12</a>, to enable output. Versions 2.03.01 and later automatically
-enable <code><nobr>-g</nobr></code> if <code><nobr>-F</nobr></code> is
-specified.
-<p>A complete list of the available debug file formats for an output format
-can be seen by issuing the command
-<code><nobr>nasm -f &lt;format&gt; -y</nobr></code>. Not all output formats
-currently support debugging output. See <a href="#section-2.1.26">section
-2.1.26</a>.
-<p>This should not be confused with the <code><nobr>-f dbg</nobr></code>
-output format option which is not built into NASM by default. For
-information on how to enable it when building from the sources, see
-<a href="nasmdoc7.html#section-7.14">section 7.14</a>.
-<h4><a name="section-2.1.12">2.1.12 The <code><nobr>-g</nobr></code> Option: Enabling Debug Information.</a></h4>
-<p>This option can be used to generate debugging information in the
-specified format. See <a href="#section-2.1.11">section 2.1.11</a>. Using
-<code><nobr>-g</nobr></code> without <code><nobr>-F</nobr></code> results
-in emitting debug info in the default format, if any, for the selected
-output format. If no debug information is currently implemented in the
-selected output format, <code><nobr>-g</nobr></code> is <em>silently
-ignored</em>.
-<h4><a name="section-2.1.13">2.1.13 The <code><nobr>-X</nobr></code> Option: Selecting an Error Reporting Format</a></h4>
-<p>This option can be used to select an error reporting format for any
-error messages that might be produced by NASM.
-<p>Currently, two error reporting formats may be selected. They are the
-<code><nobr>-Xvc</nobr></code> option and the
-<code><nobr>-Xgnu</nobr></code> option. The GNU format is the default and
-looks like this:
-<p><pre>
-filename.asm:65: error: specific error message
-</pre>
-<p>where <code><nobr>filename.asm</nobr></code> is the name of the source
-file in which the error was detected, <code><nobr>65</nobr></code> is the
-source file line number on which the error was detected,
-<code><nobr>error</nobr></code> is the severity of the error (this could be
-<code><nobr>warning</nobr></code>), and
-<code><nobr>specific error message</nobr></code> is a more detailed text
-message which should help pinpoint the exact problem.
-<p>The other format, specified by <code><nobr>-Xvc</nobr></code> is the
-style used by Microsoft Visual C++ and some other programs. It looks like
-this:
-<p><pre>
-filename.asm(65) : error: specific error message
-</pre>
-<p>where the only difference is that the line number is in parentheses
-instead of being delimited by colons.
-<p>See also the <code><nobr>Visual C++</nobr></code> output format,
-<a href="nasmdoc7.html#section-7.5">section 7.5</a>.
-<h4><a name="section-2.1.14">2.1.14 The <code><nobr>-Z</nobr></code> Option: Send Errors to a File</a></h4>
-<p>Under <code><nobr>MS-DOS</nobr></code> it can be difficult (though there
-are ways) to redirect the standard-error output of a program to a file.
-Since NASM usually produces its warning and error messages on
-<code><nobr>stderr</nobr></code>, this can make it hard to capture the
-errors if (for example) you want to load them into an editor.
-<p>NASM therefore provides the <code><nobr>-Z</nobr></code> option, taking
-a filename argument which causes errors to be sent to the specified files
-rather than standard error. Therefore you can redirect the errors into a
-file by typing
-<p><pre>
-nasm -Z myfile.err -f obj myfile.asm
-</pre>
-<p>In earlier versions of NASM, this option was called
-<code><nobr>-E</nobr></code>, but it was changed since
-<code><nobr>-E</nobr></code> is an option conventionally used for
-preprocessing only, with disastrous results. See
-<a href="#section-2.1.20">section 2.1.20</a>.
-<h4><a name="section-2.1.15">2.1.15 The <code><nobr>-s</nobr></code> Option: Send Errors to <code><nobr>stdout</nobr></code></a></h4>
-<p>The <code><nobr>-s</nobr></code> option redirects error messages to
-<code><nobr>stdout</nobr></code> rather than
-<code><nobr>stderr</nobr></code>, so it can be redirected under
-<code><nobr>MS-DOS</nobr></code>. To assemble the file
-<code><nobr>myfile.asm</nobr></code> and pipe its output to the
-<code><nobr>more</nobr></code> program, you can type:
-<p><pre>
-nasm -s -f obj myfile.asm | more
-</pre>
-<p>See also the <code><nobr>-Z</nobr></code> option,
-<a href="#section-2.1.14">section 2.1.14</a>.
-<h4><a name="section-2.1.16">2.1.16 The <code><nobr>-i</nobr></code> Option: Include File Search Directories</a></h4>
-<p>When NASM sees the <code><nobr>%include</nobr></code> or
-<code><nobr>%pathsearch</nobr></code> directive in a source file (see
-<a href="nasmdoc4.html#section-4.6.1">section 4.6.1</a>,
-<a href="nasmdoc4.html#section-4.6.2">section 4.6.2</a> or
-<a href="nasmdoc3.html#section-3.2.3">section 3.2.3</a>), it will search
-for the given file not only in the current directory, but also in any
-directories specified on the command line by the use of the
-<code><nobr>-i</nobr></code> option. Therefore you can include files from a
-macro library, for example, by typing
-<p><pre>
-nasm -ic:\macrolib\ -f obj myfile.asm
-</pre>
-<p>(As usual, a space between <code><nobr>-i</nobr></code> and the path
-name is allowed, and optional).
-<p>NASM, in the interests of complete source-code portability, does not
-understand the file naming conventions of the OS it is running on; the
-string you provide as an argument to the <code><nobr>-i</nobr></code>
-option will be prepended exactly as written to the name of the include
-file. Therefore the trailing backslash in the above example is necessary.
-Under Unix, a trailing forward slash is similarly necessary.
-<p>(You can use this to your advantage, if you're really perverse, by
-noting that the option <code><nobr>-ifoo</nobr></code> will cause
-<code><nobr>%include "bar.i"</nobr></code> to search for the file
-<code><nobr>foobar.i</nobr></code>...)
-<p>If you want to define a <em>standard</em> include search path, similar
-to <code><nobr>/usr/include</nobr></code> on Unix systems, you should place
-one or more <code><nobr>-i</nobr></code> directives in the
-<code><nobr>NASMENV</nobr></code> environment variable (see
-<a href="#section-2.1.28">section 2.1.28</a>).
-<p>For Makefile compatibility with many C compilers, this option can also
-be specified as <code><nobr>-I</nobr></code>.
-<h4><a name="section-2.1.17">2.1.17 The <code><nobr>-p</nobr></code> Option: Pre-Include a File</a></h4>
-<p>NASM allows you to specify files to be <em>pre-included</em> into your
-source file, by the use of the <code><nobr>-p</nobr></code> option. So
-running
-<p><pre>
-nasm myfile.asm -p myinc.inc
-</pre>
-<p>is equivalent to running <code><nobr>nasm myfile.asm</nobr></code> and
-placing the directive <code><nobr>%include "myinc.inc"</nobr></code> at the
-start of the file.
-<p>For consistency with the <code><nobr>-I</nobr></code>,
-<code><nobr>-D</nobr></code> and <code><nobr>-U</nobr></code> options, this
-option can also be specified as <code><nobr>-P</nobr></code>.
-<h4><a name="section-2.1.18">2.1.18 The <code><nobr>-d</nobr></code> Option: Pre-Define a Macro</a></h4>
-<p>Just as the <code><nobr>-p</nobr></code> option gives an alternative to
-placing <code><nobr>%include</nobr></code> directives at the start of a
-source file, the <code><nobr>-d</nobr></code> option gives an alternative
-to placing a <code><nobr>%define</nobr></code> directive. You could code
-<p><pre>
-nasm myfile.asm -dFOO=100
-</pre>
-<p>as an alternative to placing the directive
-<p><pre>
-%define FOO 100
-</pre>
-<p>at the start of the file. You can miss off the macro value, as well: the
-option <code><nobr>-dFOO</nobr></code> is equivalent to coding
-<code><nobr>%define FOO</nobr></code>. This form of the directive may be
-useful for selecting assembly-time options which are then tested using
-<code><nobr>%ifdef</nobr></code>, for example
-<code><nobr>-dDEBUG</nobr></code>.
-<p>For Makefile compatibility with many C compilers, this option can also
-be specified as <code><nobr>-D</nobr></code>.
-<h4><a name="section-2.1.19">2.1.19 The <code><nobr>-u</nobr></code> Option: Undefine a Macro</a></h4>
-<p>The <code><nobr>-u</nobr></code> option undefines a macro that would
-otherwise have been pre-defined, either automatically or by a
-<code><nobr>-p</nobr></code> or <code><nobr>-d</nobr></code> option
-specified earlier on the command lines.
-<p>For example, the following command line:
-<p><pre>
-nasm myfile.asm -dFOO=100 -uFOO
-</pre>
-<p>would result in <code><nobr>FOO</nobr></code> <em>not</em> being a
-predefined macro in the program. This is useful to override options
-specified at a different point in a Makefile.
-<p>For Makefile compatibility with many C compilers, this option can also
-be specified as <code><nobr>-U</nobr></code>.
-<h4><a name="section-2.1.20">2.1.20 The <code><nobr>-E</nobr></code> Option: Preprocess Only</a></h4>
-<p>NASM allows the preprocessor to be run on its own, up to a point. Using
-the <code><nobr>-E</nobr></code> option (which requires no arguments) will
-cause NASM to preprocess its input file, expand all the macro references,
-remove all the comments and preprocessor directives, and print the
-resulting file on standard output (or save it to a file, if the
-<code><nobr>-o</nobr></code> option is also used).
-<p>This option cannot be applied to programs which require the preprocessor
-to evaluate expressions which depend on the values of symbols: so code such
-as
-<p><pre>
-%assign tablesize ($-tablestart)
-</pre>
-<p>will cause an error in preprocess-only mode.
-<p>For compatiblity with older version of NASM, this option can also be
-written <code><nobr>-e</nobr></code>. <code><nobr>-E</nobr></code> in older
-versions of NASM was the equivalent of the current
-<code><nobr>-Z</nobr></code> option, <a href="#section-2.1.14">section
-2.1.14</a>.
-<h4><a name="section-2.1.21">2.1.21 The <code><nobr>-a</nobr></code> Option: Don't Preprocess At All</a></h4>
-<p>If NASM is being used as the back end to a compiler, it might be
-desirable to suppress preprocessing completely and assume the compiler has
-already done it, to save time and increase compilation speeds. The
-<code><nobr>-a</nobr></code> option, requiring no argument, instructs NASM
-to replace its powerful preprocessor with a stub preprocessor which does
-nothing.
-<h4><a name="section-2.1.22">2.1.22 The <code><nobr>-O</nobr></code> Option: Specifying Multipass Optimization</a></h4>
-<p>NASM defaults to not optimizing operands which can fit into a signed
-byte. This means that if you want the shortest possible object code, you
-have to enable optimization.
-<p>Using the <code><nobr>-O</nobr></code> option, you can tell NASM to
-carry out different levels of optimization. The syntax is:
-<ul>
-<li><code><nobr>-O0</nobr></code>: No optimization. All operands take their
-long forms, if a short form is not specified, except conditional jumps.
-This is intended to match NASM 0.98 behavior.
-<li><code><nobr>-O1</nobr></code>: Minimal optimization. As above, but
-immediate operands which will fit in a signed byte are optimized, unless
-the long form is specified. Conditional jumps default to the long form
-unless otherwise specified.
-<li><code><nobr>-Ox</nobr></code> (where <code><nobr>x</nobr></code> is the
-actual letter <code><nobr>x</nobr></code>): Multipass optimization.
-Minimize branch offsets and signed immediate bytes, overriding size
-specification unless the <code><nobr>strict</nobr></code> keyword has been
-used (see <a href="nasmdoc3.html#section-3.7">section 3.7</a>). For
-compatability with earlier releases, the letter <code><nobr>x</nobr></code>
-may also be any number greater than one. This number has no effect on the
-actual number of passes.
-</ul>
-<p>The <code><nobr>-Ox</nobr></code> mode is recommended for most uses.
-<p>Note that this is a capital <code><nobr>O</nobr></code>, and is
-different from a small <code><nobr>o</nobr></code>, which is used to
-specify the output file name. See <a href="#section-2.1.1">section
-2.1.1</a>.
-<h4><a name="section-2.1.23">2.1.23 The <code><nobr>-t</nobr></code> Option: Enable TASM Compatibility Mode</a></h4>
-<p>NASM includes a limited form of compatibility with Borland's
-<code><nobr>TASM</nobr></code>. When NASM's <code><nobr>-t</nobr></code>
-option is used, the following changes are made:
-<ul>
-<li>local labels may be prefixed with <code><nobr>@@</nobr></code> instead
-of <code><nobr>.</nobr></code>
-<li>size override is supported within brackets. In TASM compatible mode, a
-size override inside square brackets changes the size of the operand, and
-not the address type of the operand as it does in NASM syntax. E.g.
-<code><nobr>mov eax,[DWORD val]</nobr></code> is valid syntax in TASM
-compatibility mode. Note that you lose the ability to override the default
-address type for the instruction.
-<li>unprefixed forms of some directives supported
-(<code><nobr>arg</nobr></code>, <code><nobr>elif</nobr></code>,
-<code><nobr>else</nobr></code>, <code><nobr>endif</nobr></code>,
-<code><nobr>if</nobr></code>, <code><nobr>ifdef</nobr></code>,
-<code><nobr>ifdifi</nobr></code>, <code><nobr>ifndef</nobr></code>,
-<code><nobr>include</nobr></code>, <code><nobr>local</nobr></code>)
-</ul>
-<h4><a name="section-2.1.24">2.1.24 The <code><nobr>-w</nobr></code> and <code><nobr>-W</nobr></code> Options: Enable or Disable Assembly Warnings</a></h4>
-<p>NASM can observe many conditions during the course of assembly which are
-worth mentioning to the user, but not a sufficiently severe error to
-justify NASM refusing to generate an output file. These conditions are
-reported like errors, but come up with the word `warning' before the
-message. Warnings do not prevent NASM from generating an output file and
-returning a success status to the operating system.
-<p>Some conditions are even less severe than that: they are only sometimes
-worth mentioning to the user. Therefore NASM supports the
-<code><nobr>-w</nobr></code> command-line option, which enables or disables
-certain classes of assembly warning. Such warning classes are described by
-a name, for example <code><nobr>orphan-labels</nobr></code>; you can enable
-warnings of this class by the command-line option
-<code><nobr>-w+orphan-labels</nobr></code> and disable it by
-<code><nobr>-w-orphan-labels</nobr></code>.
-<p>The suppressible warning classes are:
-<ul>
-<li><code><nobr>macro-params</nobr></code> covers warnings about multi-line
-macros being invoked with the wrong number of parameters. This warning
-class is enabled by default; see
-<a href="nasmdoc4.html#section-4.3.2">section 4.3.2</a> for an example of
-why you might want to disable it.
-<li><code><nobr>macro-selfref</nobr></code> warns if a macro references
-itself. This warning class is disabled by default.
-<li><code><nobr>macro-defaults</nobr></code> warns when a macro has more
-default parameters than optional parameters. This warning class is enabled
-by default; see <a href="nasmdoc4.html#section-4.3.5">section 4.3.5</a> for
-why you might want to disable it.
-<li><code><nobr>orphan-labels</nobr></code> covers warnings about source
-lines which contain no instruction but define a label without a trailing
-colon. NASM warns about this somewhat obscure condition by default; see
-<a href="nasmdoc3.html#section-3.1">section 3.1</a> for more information.
-<li><code><nobr>number-overflow</nobr></code> covers warnings about numeric
-constants which don't fit in 64 bits. This warning class is enabled by
-default.
-<li><code><nobr>gnu-elf-extensions</nobr></code> warns if 8-bit or 16-bit
-relocations are used in <code><nobr>-f elf</nobr></code> format. The GNU
-extensions allow this. This warning class is disabled by default.
-<li><code><nobr>float-overflow</nobr></code> warns about floating point
-overflow. Enabled by default.
-<li><code><nobr>float-denorm</nobr></code> warns about floating point
-denormals. Disabled by default.
-<li><code><nobr>float-underflow</nobr></code> warns about floating point
-underflow. Disabled by default.
-<li><code><nobr>float-toolong</nobr></code> warns about too many digits in
-floating-point numbers. Enabled by default.
-<li><code><nobr>user</nobr></code> controls
-<code><nobr>%warning</nobr></code> directives (see
-<a href="nasmdoc4.html#section-4.9">section 4.9</a>). Enabled by default.
-<li><code><nobr>error</nobr></code> causes warnings to be treated as
-errors. Disabled by default.
-<li><code><nobr>all</nobr></code> is an alias for <em>all</em> suppressible
-warning classes (not including <code><nobr>error</nobr></code>). Thus,
-<code><nobr>-w+all</nobr></code> enables all available warnings.
-</ul>
-<p>In addition, you can set warning classes across sections. Warning
-classes may be enabled with
-<code><nobr>[warning +warning-name]</nobr></code>, disabled with
-<code><nobr>[warning -warning-name]</nobr></code> or reset to their
-original value with <code><nobr>[warning *warning-name]</nobr></code>. No
-"user form" (without the brackets) exists.
-<p>Since version 2.00, NASM has also supported the gcc-like syntax
-<code><nobr>-Wwarning</nobr></code> and
-<code><nobr>-Wno-warning</nobr></code> instead of
-<code><nobr>-w+warning</nobr></code> and
-<code><nobr>-w-warning</nobr></code>, respectively.
-<h4><a name="section-2.1.25">2.1.25 The <code><nobr>-v</nobr></code> Option: Display Version Info</a></h4>
-<p>Typing <code><nobr>NASM -v</nobr></code> will display the version of
-NASM which you are using, and the date on which it was compiled.
-<p>You will need the version number if you report a bug.
-<h4><a name="section-2.1.26">2.1.26 The <code><nobr>-y</nobr></code> Option: Display Available Debug Info Formats</a></h4>
-<p>Typing <code><nobr>nasm -f &lt;option&gt; -y</nobr></code> will display
-a list of the available debug info formats for the given output format. The
-default format is indicated by an asterisk. For example:
-<p><pre>
-nasm -f elf -y
-</pre>
-<p><pre>
-valid debug formats for 'elf32' output format are
- ('*' denotes default):
- * stabs ELF32 (i386) stabs debug format for Linux
- dwarf elf32 (i386) dwarf debug format for Linux
-</pre>
-<h4><a name="section-2.1.27">2.1.27 The <code><nobr>--prefix</nobr></code> and <code><nobr>--postfix</nobr></code> Options.</a></h4>
-<p>The <code><nobr>--prefix</nobr></code> and
-<code><nobr>--postfix</nobr></code> options prepend or append
-(respectively) the given argument to all <code><nobr>global</nobr></code>
-or <code><nobr>extern</nobr></code> variables. E.g.
-<code><nobr>--prefix _</nobr></code> will prepend the underscore to all
-global and external variables, as C sometimes (but not always) likes it.
-<h4><a name="section-2.1.28">2.1.28 The <code><nobr>NASMENV</nobr></code> Environment Variable</a></h4>
-<p>If you define an environment variable called
-<code><nobr>NASMENV</nobr></code>, the program will interpret it as a list
-of extra command-line options, which are processed before the real command
-line. You can use this to define standard search directories for include
-files, by putting <code><nobr>-i</nobr></code> options in the
-<code><nobr>NASMENV</nobr></code> variable.
-<p>The value of the variable is split up at white space, so that the value
-<code><nobr>-s -ic:\nasmlib\</nobr></code> will be treated as two separate
-options. However, that means that the value
-<code><nobr>-dNAME="my name"</nobr></code> won't do what you might want,
-because it will be split at the space and the NASM command-line processing
-will get confused by the two nonsensical words
-<code><nobr>-dNAME="my</nobr></code> and <code><nobr>name"</nobr></code>.
-<p>To get round this, NASM provides a feature whereby, if you begin the
-<code><nobr>NASMENV</nobr></code> environment variable with some character
-that isn't a minus sign, then NASM will treat this character as the
-separator character for options. So setting the
-<code><nobr>NASMENV</nobr></code> variable to the value
-<code><nobr>!-s!-ic:\nasmlib\</nobr></code> is equivalent to setting it to
-<code><nobr>-s -ic:\nasmlib\</nobr></code>, but
-<code><nobr>!-dNAME="my name"</nobr></code> will work.
-<p>This environment variable was previously called
-<code><nobr>NASM</nobr></code>. This was changed with version 0.98.31.
-<h3><a name="section-2.2">2.2 Quick Start for MASM Users</a></h3>
-<p>If you're used to writing programs with MASM, or with TASM in
-MASM-compatible (non-Ideal) mode, or with <code><nobr>a86</nobr></code>,
-this section attempts to outline the major differences between MASM's
-syntax and NASM's. If you're not already used to MASM, it's probably worth
-skipping this section.
-<h4><a name="section-2.2.1">2.2.1 NASM Is Case-Sensitive</a></h4>
-<p>One simple difference is that NASM is case-sensitive. It makes a
-difference whether you call your label <code><nobr>foo</nobr></code>,
-<code><nobr>Foo</nobr></code> or <code><nobr>FOO</nobr></code>. If you're
-assembling to <code><nobr>DOS</nobr></code> or
-<code><nobr>OS/2</nobr></code> <code><nobr>.OBJ</nobr></code> files, you
-can invoke the <code><nobr>UPPERCASE</nobr></code> directive (documented in
-<a href="nasmdoc7.html#section-7.4">section 7.4</a>) to ensure that all
-symbols exported to other code modules are forced to be upper case; but
-even then, <em>within</em> a single module, NASM will distinguish between
-labels differing only in case.
-<h4><a name="section-2.2.2">2.2.2 NASM Requires Square Brackets For Memory References</a></h4>
-<p>NASM was designed with simplicity of syntax in mind. One of the design
-goals of NASM is that it should be possible, as far as is practical, for
-the user to look at a single line of NASM code and tell what opcode is
-generated by it. You can't do this in MASM: if you declare, for example,
-<p><pre>
-foo equ 1
-bar dw 2
-</pre>
-<p>then the two lines of code
-<p><pre>
- mov ax,foo
- mov ax,bar
-</pre>
-<p>generate completely different opcodes, despite having identical-looking
-syntaxes.
-<p>NASM avoids this undesirable situation by having a much simpler syntax
-for memory references. The rule is simply that any access to the
-<em>contents</em> of a memory location requires square brackets around the
-address, and any access to the <em>address</em> of a variable doesn't. So
-an instruction of the form <code><nobr>mov ax,foo</nobr></code> will
-<em>always</em> refer to a compile-time constant, whether it's an
-<code><nobr>EQU</nobr></code> or the address of a variable; and to access
-the <em>contents</em> of the variable <code><nobr>bar</nobr></code>, you
-must code <code><nobr>mov ax,[bar]</nobr></code>.
-<p>This also means that NASM has no need for MASM's
-<code><nobr>OFFSET</nobr></code> keyword, since the MASM code
-<code><nobr>mov ax,offset bar</nobr></code> means exactly the same thing as
-NASM's <code><nobr>mov ax,bar</nobr></code>. If you're trying to get large
-amounts of MASM code to assemble sensibly under NASM, you can always code
-<code><nobr>%idefine offset</nobr></code> to make the preprocessor treat
-the <code><nobr>OFFSET</nobr></code> keyword as a no-op.
-<p>This issue is even more confusing in <code><nobr>a86</nobr></code>,
-where declaring a label with a trailing colon defines it to be a `label' as
-opposed to a `variable' and causes <code><nobr>a86</nobr></code> to adopt
-NASM-style semantics; so in <code><nobr>a86</nobr></code>,
-<code><nobr>mov ax,var</nobr></code> has different behaviour depending on
-whether <code><nobr>var</nobr></code> was declared as
-<code><nobr>var: dw 0</nobr></code> (a label) or
-<code><nobr>var dw 0</nobr></code> (a word-size variable). NASM is very
-simple by comparison: <em>everything</em> is a label.
-<p>NASM, in the interests of simplicity, also does not support the hybrid
-syntaxes supported by MASM and its clones, such as
-<code><nobr>mov ax,table[bx]</nobr></code>, where a memory reference is
-denoted by one portion outside square brackets and another portion inside.
-The correct syntax for the above is
-<code><nobr>mov ax,[table+bx]</nobr></code>. Likewise,
-<code><nobr>mov ax,es:[di]</nobr></code> is wrong and
-<code><nobr>mov ax,[es:di]</nobr></code> is right.
-<h4><a name="section-2.2.3">2.2.3 NASM Doesn't Store Variable Types</a></h4>
-<p>NASM, by design, chooses not to remember the types of variables you
-declare. Whereas MASM will remember, on seeing
-<code><nobr>var dw 0</nobr></code>, that you declared
-<code><nobr>var</nobr></code> as a word-size variable, and will then be
-able to fill in the ambiguity in the size of the instruction
-<code><nobr>mov var,2</nobr></code>, NASM will deliberately remember
-nothing about the symbol <code><nobr>var</nobr></code> except where it
-begins, and so you must explicitly code
-<code><nobr>mov word [var],2</nobr></code>.
-<p>For this reason, NASM doesn't support the
-<code><nobr>LODS</nobr></code>, <code><nobr>MOVS</nobr></code>,
-<code><nobr>STOS</nobr></code>, <code><nobr>SCAS</nobr></code>,
-<code><nobr>CMPS</nobr></code>, <code><nobr>INS</nobr></code>, or
-<code><nobr>OUTS</nobr></code> instructions, but only supports the forms
-such as <code><nobr>LODSB</nobr></code>, <code><nobr>MOVSW</nobr></code>,
-and <code><nobr>SCASD</nobr></code>, which explicitly specify the size of
-the components of the strings being manipulated.
-<h4><a name="section-2.2.4">2.2.4 NASM Doesn't <code><nobr>ASSUME</nobr></code></a></h4>
-<p>As part of NASM's drive for simplicity, it also does not support the
-<code><nobr>ASSUME</nobr></code> directive. NASM will not keep track of
-what values you choose to put in your segment registers, and will never
-<em>automatically</em> generate a segment override prefix.
-<h4><a name="section-2.2.5">2.2.5 NASM Doesn't Support Memory Models</a></h4>
-<p>NASM also does not have any directives to support different 16-bit
-memory models. The programmer has to keep track of which functions are
-supposed to be called with a far call and which with a near call, and is
-responsible for putting the correct form of <code><nobr>RET</nobr></code>
-instruction (<code><nobr>RETN</nobr></code> or
-<code><nobr>RETF</nobr></code>; NASM accepts <code><nobr>RET</nobr></code>
-itself as an alternate form for <code><nobr>RETN</nobr></code>); in
-addition, the programmer is responsible for coding CALL FAR instructions
-where necessary when calling <em>external</em> functions, and must also
-keep track of which external variable definitions are far and which are
-near.
-<h4><a name="section-2.2.6">2.2.6 Floating-Point Differences</a></h4>
-<p>NASM uses different names to refer to floating-point registers from
-MASM: where MASM would call them <code><nobr>ST(0)</nobr></code>,
-<code><nobr>ST(1)</nobr></code> and so on, and
-<code><nobr>a86</nobr></code> would call them simply
-<code><nobr>0</nobr></code>, <code><nobr>1</nobr></code> and so on, NASM
-chooses to call them <code><nobr>st0</nobr></code>,
-<code><nobr>st1</nobr></code> etc.
-<p>As of version 0.96, NASM now treats the instructions with `nowait' forms
-in the same way as MASM-compatible assemblers. The idiosyncratic treatment
-employed by 0.95 and earlier was based on a misunderstanding by the
-authors.
-<h4><a name="section-2.2.7">2.2.7 Other Differences</a></h4>
-<p>For historical reasons, NASM uses the keyword
-<code><nobr>TWORD</nobr></code> where MASM and compatible assemblers use
-<code><nobr>TBYTE</nobr></code>.
-<p>NASM does not declare uninitialized storage in the same way as MASM:
-where a MASM programmer might use
-<code><nobr>stack db 64 dup (?)</nobr></code>, NASM requires
-<code><nobr>stack resb 64</nobr></code>, intended to be read as `reserve 64
-bytes'. For a limited amount of compatibility, since NASM treats
-<code><nobr>?</nobr></code> as a valid character in symbol names, you can
-code <code><nobr>? equ 0</nobr></code> and then writing
-<code><nobr>dw ?</nobr></code> will at least do something vaguely useful.
-<code><nobr>DUP</nobr></code> is still not a supported syntax, however.
-<p>In addition to all of this, macros and directives work completely
-differently to MASM. See <a href="nasmdoc4.html">chapter 4</a> and
-<a href="nasmdoc6.html">chapter 6</a> for further details.
-<p align=center><a href="nasmdoc3.html">Next Chapter</a> |
-<a href="nasmdoc1.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc4.html">Next Chapter</a> |
-<a href="nasmdoc2.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-3">Chapter 3: The NASM Language</a></h2>
-<h3><a name="section-3.1">3.1 Layout of a NASM Source Line</a></h3>
-<p>Like most assemblers, each NASM source line contains (unless it is a
-macro, a preprocessor directive or an assembler directive: see
-<a href="nasmdoc4.html">chapter 4</a> and <a href="nasmdoc6.html">chapter
-6</a>) some combination of the four fields
-<p><pre>
-label: instruction operands ; comment
-</pre>
-<p>As usual, most of these fields are optional; the presence or absence of
-any combination of a label, an instruction and a comment is allowed. Of
-course, the operand field is either required or forbidden by the presence
-and nature of the instruction field.
-<p>NASM uses backslash (\) as the line continuation character; if a line
-ends with backslash, the next line is considered to be a part of the
-backslash-ended line.
-<p>NASM places no restrictions on white space within a line: labels may
-have white space before them, or instructions may have no space before
-them, or anything. The colon after a label is also optional. (Note that
-this means that if you intend to code <code><nobr>lodsb</nobr></code> alone
-on a line, and type <code><nobr>lodab</nobr></code> by accident, then
-that's still a valid source line which does nothing but define a label.
-Running NASM with the command-line option
-<code><nobr>-w+orphan-labels</nobr></code> will cause it to warn you if you
-define a label alone on a line without a trailing colon.)
-<p>Valid characters in labels are letters, numbers,
-<code><nobr>_</nobr></code>, <code><nobr>$</nobr></code>,
-<code><nobr>#</nobr></code>, <code><nobr>@</nobr></code>,
-<code><nobr>~</nobr></code>, <code><nobr>.</nobr></code>, and
-<code><nobr>?</nobr></code>. The only characters which may be used as the
-<em>first</em> character of an identifier are letters,
-<code><nobr>.</nobr></code> (with special meaning: see
-<a href="#section-3.9">section 3.9</a>), <code><nobr>_</nobr></code> and
-<code><nobr>?</nobr></code>. An identifier may also be prefixed with a
-<code><nobr>$</nobr></code> to indicate that it is intended to be read as
-an identifier and not a reserved word; thus, if some other module you are
-linking with defines a symbol called <code><nobr>eax</nobr></code>, you can
-refer to <code><nobr>$eax</nobr></code> in NASM code to distinguish the
-symbol from the register. Maximum length of an identifier is 4095
-characters.
-<p>The instruction field may contain any machine instruction: Pentium and
-P6 instructions, FPU instructions, MMX instructions and even undocumented
-instructions are all supported. The instruction may be prefixed by
-<code><nobr>LOCK</nobr></code>, <code><nobr>REP</nobr></code>,
-<code><nobr>REPE</nobr></code>/<code><nobr>REPZ</nobr></code> or
-<code><nobr>REPNE</nobr></code>/<code><nobr>REPNZ</nobr></code>, in the
-usual way. Explicit address-size and operand-size prefixes
-<code><nobr>A16</nobr></code>, <code><nobr>A32</nobr></code>,
-<code><nobr>A64</nobr></code>, <code><nobr>O16</nobr></code> and
-<code><nobr>O32</nobr></code>, <code><nobr>O64</nobr></code> are provided -
-one example of their use is given in <a href="nasmdo10.html">chapter
-10</a>. You can also use the name of a segment register as an instruction
-prefix: coding <code><nobr>es mov [bx],ax</nobr></code> is equivalent to
-coding <code><nobr>mov [es:bx],ax</nobr></code>. We recommend the latter
-syntax, since it is consistent with other syntactic features of the
-language, but for instructions such as <code><nobr>LODSB</nobr></code>,
-which has no operands and yet can require a segment override, there is no
-clean syntactic way to proceed apart from
-<code><nobr>es lodsb</nobr></code>.
-<p>An instruction is not required to use a prefix: prefixes such as
-<code><nobr>CS</nobr></code>, <code><nobr>A32</nobr></code>,
-<code><nobr>LOCK</nobr></code> or <code><nobr>REPE</nobr></code> can appear
-on a line by themselves, and NASM will just generate the prefix bytes.
-<p>In addition to actual machine instructions, NASM also supports a number
-of pseudo-instructions, described in <a href="#section-3.2">section
-3.2</a>.
-<p>Instruction operands may take a number of forms: they can be registers,
-described simply by the register name (e.g. <code><nobr>ax</nobr></code>,
-<code><nobr>bp</nobr></code>, <code><nobr>ebx</nobr></code>,
-<code><nobr>cr0</nobr></code>: NASM does not use the
-<code><nobr>gas</nobr></code>-style syntax in which register names must be
-prefixed by a <code><nobr>%</nobr></code> sign), or they can be effective
-addresses (see <a href="#section-3.3">section 3.3</a>), constants
-(<a href="#section-3.4">section 3.4</a>) or expressions
-(<a href="#section-3.5">section 3.5</a>).
-<p>For x87 floating-point instructions, NASM accepts a wide range of
-syntaxes: you can use two-operand forms like MASM supports, or you can use
-NASM's native single-operand forms in most cases. For example, you can
-code:
-<p><pre>
- fadd st1 ; this sets st0 := st0 + st1
- fadd st0,st1 ; so does this
-
- fadd st1,st0 ; this sets st1 := st1 + st0
- fadd to st1 ; so does this
-</pre>
-<p>Almost any x87 floating-point instruction that references memory must
-use one of the prefixes <code><nobr>DWORD</nobr></code>,
-<code><nobr>QWORD</nobr></code> or <code><nobr>TWORD</nobr></code> to
-indicate what size of memory operand it refers to.
-<h3><a name="section-3.2">3.2 Pseudo-Instructions</a></h3>
-<p>Pseudo-instructions are things which, though not real x86 machine
-instructions, are used in the instruction field anyway because that's the
-most convenient place to put them. The current pseudo-instructions are
-<code><nobr>DB</nobr></code>, <code><nobr>DW</nobr></code>,
-<code><nobr>DD</nobr></code>, <code><nobr>DQ</nobr></code>,
-<code><nobr>DT</nobr></code>, <code><nobr>DO</nobr></code> and
-<code><nobr>DY</nobr></code>; their uninitialized counterparts
-<code><nobr>RESB</nobr></code>, <code><nobr>RESW</nobr></code>,
-<code><nobr>RESD</nobr></code>, <code><nobr>RESQ</nobr></code>,
-<code><nobr>REST</nobr></code>, <code><nobr>RESO</nobr></code> and
-<code><nobr>RESY</nobr></code>; the <code><nobr>INCBIN</nobr></code>
-command, the <code><nobr>EQU</nobr></code> command, and the
-<code><nobr>TIMES</nobr></code> prefix.
-<h4><a name="section-3.2.1">3.2.1 <code><nobr>DB</nobr></code> and Friends: Declaring Initialized Data</a></h4>
-<p><code><nobr>DB</nobr></code>, <code><nobr>DW</nobr></code>,
-<code><nobr>DD</nobr></code>, <code><nobr>DQ</nobr></code>,
-<code><nobr>DT</nobr></code>, <code><nobr>DO</nobr></code> and
-<code><nobr>DY</nobr></code> are used, much as in MASM, to declare
-initialized data in the output file. They can be invoked in a wide range of
-ways:
-<p><pre>
- db 0x55 ; just the byte 0x55
- db 0x55,0x56,0x57 ; three bytes in succession
- db 'a',0x55 ; character constants are OK
- db 'hello',13,10,'$' ; so are string constants
- dw 0x1234 ; 0x34 0x12
- dw 'a' ; 0x61 0x00 (it's just a number)
- dw 'ab' ; 0x61 0x62 (character constant)
- dw 'abc' ; 0x61 0x62 0x63 0x00 (string)
- dd 0x12345678 ; 0x78 0x56 0x34 0x12
- dd 1.234567e20 ; floating-point constant
- dq 0x123456789abcdef0 ; eight byte constant
- dq 1.234567e20 ; double-precision float
- dt 1.234567e20 ; extended-precision float
-</pre>
-<p><code><nobr>DT</nobr></code>, <code><nobr>DO</nobr></code> and
-<code><nobr>DY</nobr></code> do not accept numeric constants as operands.
-<h4><a name="section-3.2.2">3.2.2 <code><nobr>RESB</nobr></code> and Friends: Declaring Uninitialized Data</a></h4>
-<p><code><nobr>RESB</nobr></code>, <code><nobr>RESW</nobr></code>,
-<code><nobr>RESD</nobr></code>, <code><nobr>RESQ</nobr></code>,
-<code><nobr>REST</nobr></code>, <code><nobr>RESO</nobr></code> and
-<code><nobr>RESY</nobr></code> are designed to be used in the BSS section
-of a module: they declare <em>uninitialized</em> storage space. Each takes
-a single operand, which is the number of bytes, words, doublewords or
-whatever to reserve. As stated in
-<a href="nasmdoc2.html#section-2.2.7">section 2.2.7</a>, NASM does not
-support the MASM/TASM syntax of reserving uninitialized space by writing
-<code><nobr>DW ?</nobr></code> or similar things: this is what it does
-instead. The operand to a <code><nobr>RESB</nobr></code>-type
-pseudo-instruction is a <em>critical expression</em>: see
-<a href="#section-3.8">section 3.8</a>.
-<p>For example:
-<p><pre>
-buffer: resb 64 ; reserve 64 bytes
-wordvar: resw 1 ; reserve a word
-realarray resq 10 ; array of ten reals
-ymmval: resy 1 ; one YMM register
-</pre>
-<h4><a name="section-3.2.3">3.2.3 <code><nobr>INCBIN</nobr></code>: Including External Binary Files</a></h4>
-<p><code><nobr>INCBIN</nobr></code> is borrowed from the old Amiga
-assembler DevPac: it includes a binary file verbatim into the output file.
-This can be handy for (for example) including graphics and sound data
-directly into a game executable file. It can be called in one of these
-three ways:
-<p><pre>
- incbin "file.dat" ; include the whole file
- incbin "file.dat",1024 ; skip the first 1024 bytes
- incbin "file.dat",1024,512 ; skip the first 1024, and
- ; actually include at most 512
-</pre>
-<p><code><nobr>INCBIN</nobr></code> is both a directive and a standard
-macro; the standard macro version searches for the file in the include file
-search path and adds the file to the dependency lists. This macro can be
-overridden if desired.
-<h4><a name="section-3.2.4">3.2.4 <code><nobr>EQU</nobr></code>: Defining Constants</a></h4>
-<p><code><nobr>EQU</nobr></code> defines a symbol to a given constant
-value: when <code><nobr>EQU</nobr></code> is used, the source line must
-contain a label. The action of <code><nobr>EQU</nobr></code> is to define
-the given label name to the value of its (only) operand. This definition is
-absolute, and cannot change later. So, for example,
-<p><pre>
-message db 'hello, world'
-msglen equ $-message
-</pre>
-<p>defines <code><nobr>msglen</nobr></code> to be the constant 12.
-<code><nobr>msglen</nobr></code> may not then be redefined later. This is
-not a preprocessor definition either: the value of
-<code><nobr>msglen</nobr></code> is evaluated <em>once</em>, using the
-value of <code><nobr>$</nobr></code> (see <a href="#section-3.5">section
-3.5</a> for an explanation of <code><nobr>$</nobr></code>) at the point of
-definition, rather than being evaluated wherever it is referenced and using
-the value of <code><nobr>$</nobr></code> at the point of reference.
-<h4><a name="section-3.2.5">3.2.5 <code><nobr>TIMES</nobr></code>: Repeating Instructions or Data</a></h4>
-<p>The <code><nobr>TIMES</nobr></code> prefix causes the instruction to be
-assembled multiple times. This is partly present as NASM's equivalent of
-the <code><nobr>DUP</nobr></code> syntax supported by MASM-compatible
-assemblers, in that you can code
-<p><pre>
-zerobuf: times 64 db 0
-</pre>
-<p>or similar things; but <code><nobr>TIMES</nobr></code> is more versatile
-than that. The argument to <code><nobr>TIMES</nobr></code> is not just a
-numeric constant, but a numeric <em>expression</em>, so you can do things
-like
-<p><pre>
-buffer: db 'hello, world'
- times 64-$+buffer db ' '
-</pre>
-<p>which will store exactly enough spaces to make the total length of
-<code><nobr>buffer</nobr></code> up to 64. Finally,
-<code><nobr>TIMES</nobr></code> can be applied to ordinary instructions, so
-you can code trivial unrolled loops in it:
-<p><pre>
- times 100 movsb
-</pre>
-<p>Note that there is no effective difference between
-<code><nobr>times 100 resb 1</nobr></code> and
-<code><nobr>resb 100</nobr></code>, except that the latter will be
-assembled about 100 times faster due to the internal structure of the
-assembler.
-<p>The operand to <code><nobr>TIMES</nobr></code> is a critical expression
-(<a href="#section-3.8">section 3.8</a>).
-<p>Note also that <code><nobr>TIMES</nobr></code> can't be applied to
-macros: the reason for this is that <code><nobr>TIMES</nobr></code> is
-processed after the macro phase, which allows the argument to
-<code><nobr>TIMES</nobr></code> to contain expressions such as
-<code><nobr>64-$+buffer</nobr></code> as above. To repeat more than one
-line of code, or a complex macro, use the preprocessor
-<code><nobr>%rep</nobr></code> directive.
-<h3><a name="section-3.3">3.3 Effective Addresses</a></h3>
-<p>An effective address is any operand to an instruction which references
-memory. Effective addresses, in NASM, have a very simple syntax: they
-consist of an expression evaluating to the desired address, enclosed in
-square brackets. For example:
-<p><pre>
-wordvar dw 123
- mov ax,[wordvar]
- mov ax,[wordvar+1]
- mov ax,[es:wordvar+bx]
-</pre>
-<p>Anything not conforming to this simple system is not a valid memory
-reference in NASM, for example <code><nobr>es:wordvar[bx]</nobr></code>.
-<p>More complicated effective addresses, such as those involving more than
-one register, work in exactly the same way:
-<p><pre>
- mov eax,[ebx*2+ecx+offset]
- mov ax,[bp+di+8]
-</pre>
-<p>NASM is capable of doing algebra on these effective addresses, so that
-things which don't necessarily <em>look</em> legal are perfectly all right:
-<p><pre>
- mov eax,[ebx*5] ; assembles as [ebx*4+ebx]
- mov eax,[label1*2-label2] ; ie [label1+(label1-label2)]
-</pre>
-<p>Some forms of effective address have more than one assembled form; in
-most such cases NASM will generate the smallest form it can. For example,
-there are distinct assembled forms for the 32-bit effective addresses
-<code><nobr>[eax*2+0]</nobr></code> and
-<code><nobr>[eax+eax]</nobr></code>, and NASM will generally generate the
-latter on the grounds that the former requires four bytes to store a zero
-offset.
-<p>NASM has a hinting mechanism which will cause
-<code><nobr>[eax+ebx]</nobr></code> and <code><nobr>[ebx+eax]</nobr></code>
-to generate different opcodes; this is occasionally useful because
-<code><nobr>[esi+ebp]</nobr></code> and <code><nobr>[ebp+esi]</nobr></code>
-have different default segment registers.
-<p>However, you can force NASM to generate an effective address in a
-particular form by the use of the keywords <code><nobr>BYTE</nobr></code>,
-<code><nobr>WORD</nobr></code>, <code><nobr>DWORD</nobr></code> and
-<code><nobr>NOSPLIT</nobr></code>. If you need
-<code><nobr>[eax+3]</nobr></code> to be assembled using a double-word
-offset field instead of the one byte NASM will normally generate, you can
-code <code><nobr>[dword eax+3]</nobr></code>. Similarly, you can force NASM
-to use a byte offset for a small value which it hasn't seen on the first
-pass (see <a href="#section-3.8">section 3.8</a> for an example of such a
-code fragment) by using <code><nobr>[byte eax+offset]</nobr></code>. As
-special cases, <code><nobr>[byte eax]</nobr></code> will code
-<code><nobr>[eax+0]</nobr></code> with a byte offset of zero, and
-<code><nobr>[dword eax]</nobr></code> will code it with a double-word
-offset of zero. The normal form, <code><nobr>[eax]</nobr></code>, will be
-coded with no offset field.
-<p>The form described in the previous paragraph is also useful if you are
-trying to access data in a 32-bit segment from within 16 bit code. For more
-information on this see the section on mixed-size addressing
-(<a href="nasmdo10.html#section-10.2">section 10.2</a>). In particular, if
-you need to access data with a known offset that is larger than will fit in
-a 16-bit value, if you don't specify that it is a dword offset, nasm will
-cause the high word of the offset to be lost.
-<p>Similarly, NASM will split <code><nobr>[eax*2]</nobr></code> into
-<code><nobr>[eax+eax]</nobr></code> because that allows the offset field to
-be absent and space to be saved; in fact, it will also split
-<code><nobr>[eax*2+offset]</nobr></code> into
-<code><nobr>[eax+eax+offset]</nobr></code>. You can combat this behaviour
-by the use of the <code><nobr>NOSPLIT</nobr></code> keyword:
-<code><nobr>[nosplit eax*2]</nobr></code> will force
-<code><nobr>[eax*2+0]</nobr></code> to be generated literally.
-<p>In 64-bit mode, NASM will by default generate absolute addresses. The
-<code><nobr>REL</nobr></code> keyword makes it produce
-<code><nobr>RIP</nobr></code>-relative addresses. Since this is frequently
-the normally desired behaviour, see the <code><nobr>DEFAULT</nobr></code>
-directive (<a href="nasmdoc6.html#section-6.2">section 6.2</a>). The
-keyword <code><nobr>ABS</nobr></code> overrides
-<code><nobr>REL</nobr></code>.
-<h3><a name="section-3.4">3.4 Constants</a></h3>
-<p>NASM understands four different types of constant: numeric, character,
-string and floating-point.
-<h4><a name="section-3.4.1">3.4.1 Numeric Constants</a></h4>
-<p>A numeric constant is simply a number. NASM allows you to specify
-numbers in a variety of number bases, in a variety of ways: you can suffix
-<code><nobr>H</nobr></code> or <code><nobr>X</nobr></code>,
-<code><nobr>Q</nobr></code> or <code><nobr>O</nobr></code>, and
-<code><nobr>B</nobr></code> for hexadecimal, octal and binary respectively,
-or you can prefix <code><nobr>0x</nobr></code> for hexadecimal in the style
-of C, or you can prefix <code><nobr>$</nobr></code> for hexadecimal in the
-style of Borland Pascal. Note, though, that the <code><nobr>$</nobr></code>
-prefix does double duty as a prefix on identifiers (see
-<a href="#section-3.1">section 3.1</a>), so a hex number prefixed with a
-<code><nobr>$</nobr></code> sign must have a digit after the
-<code><nobr>$</nobr></code> rather than a letter. In addition, current
-versions of NASM accept the prefix <code><nobr>0h</nobr></code> for
-hexadecimal, <code><nobr>0o</nobr></code> or <code><nobr>0q</nobr></code>
-for octal, and <code><nobr>0b</nobr></code> for binary. Please note that
-unlike C, a <code><nobr>0</nobr></code> prefix by itself does <em>not</em>
-imply an octal constant!
-<p>Numeric constants can have underscores (<code><nobr>_</nobr></code>)
-interspersed to break up long strings.
-<p>Some examples (all producing exactly the same code):
-<p><pre>
- mov ax,200 ; decimal
- mov ax,0200 ; still decimal
- mov ax,0200d ; explicitly decimal
- mov ax,0d200 ; also decimal
- mov ax,0c8h ; hex
- mov ax,$0c8 ; hex again: the 0 is required
- mov ax,0xc8 ; hex yet again
- mov ax,0hc8 ; still hex
- mov ax,310q ; octal
- mov ax,310o ; octal again
- mov ax,0o310 ; octal yet again
- mov ax,0q310 ; hex yet again
- mov ax,11001000b ; binary
- mov ax,1100_1000b ; same binary constant
- mov ax,0b1100_1000 ; same binary constant yet again
-</pre>
-<h4><a name="section-3.4.2">3.4.2 Character Strings</a></h4>
-<p>A character string consists of up to eight characters enclosed in either
-single quotes (<code><nobr>'...'</nobr></code>), double quotes
-(<code><nobr>"..."</nobr></code>) or backquotes
-(<code><nobr>`...`</nobr></code>). Single or double quotes are equivalent
-to NASM (except of course that surrounding the constant with single quotes
-allows double quotes to appear within it and vice versa); the contents of
-those are represented verbatim. Strings enclosed in backquotes support
-C-style <code><nobr>\</nobr></code>-escapes for special characters.
-<p>The following escape sequences are recognized by backquoted strings:
-<p><pre>
- \' single quote (')
- \" double quote (")
- \` backquote (`)
- \\ backslash (\)
- \? question mark (?)
- \a BEL (ASCII 7)
- \b BS (ASCII 8)
- \t TAB (ASCII 9)
- \n LF (ASCII 10)
- \v VT (ASCII 11)
- \f FF (ASCII 12)
- \r CR (ASCII 13)
- \e ESC (ASCII 27)
- \377 Up to 3 octal digits - literal byte
- \xFF Up to 2 hexadecimal digits - literal byte
- \u1234 4 hexadecimal digits - Unicode character
- \U12345678 8 hexadecimal digits - Unicode character
-</pre>
-<p>All other escape sequences are reserved. Note that
-<code><nobr>\0</nobr></code>, meaning a <code><nobr>NUL</nobr></code>
-character (ASCII 0), is a special case of the octal escape sequence.
-<p>Unicode characters specified with <code><nobr>\u</nobr></code> or
-<code><nobr>\U</nobr></code> are converted to UTF-8. For example, the
-following lines are all equivalent:
-<p><pre>
- db `\u263a` ; UTF-8 smiley face
- db `\xe2\x98\xba` ; UTF-8 smiley face
- db 0E2h, 098h, 0BAh ; UTF-8 smiley face
-</pre>
-<h4><a name="section-3.4.3">3.4.3 Character Constants</a></h4>
-<p>A character constant consists of a string up to eight bytes long, used
-in an expression context. It is treated as if it was an integer.
-<p>A character constant with more than one byte will be arranged with
-little-endian order in mind: if you code
-<p><pre>
- mov eax,'abcd'
-</pre>
-<p>then the constant generated is not <code><nobr>0x61626364</nobr></code>,
-but <code><nobr>0x64636261</nobr></code>, so that if you were then to store
-the value into memory, it would read <code><nobr>abcd</nobr></code> rather
-than <code><nobr>dcba</nobr></code>. This is also the sense of character
-constants understood by the Pentium's <code><nobr>CPUID</nobr></code>
-instruction.
-<h4><a name="section-3.4.4">3.4.4 String Constants</a></h4>
-<p>String constants are character strings used in the context of some
-pseudo-instructions, namely the <code><nobr>DB</nobr></code> family and
-<code><nobr>INCBIN</nobr></code> (where it represents a filename.) They are
-also used in certain preprocessor directives.
-<p>A string constant looks like a character constant, only longer. It is
-treated as a concatenation of maximum-size character constants for the
-conditions. So the following are equivalent:
-<p><pre>
- db 'hello' ; string constant
- db 'h','e','l','l','o' ; equivalent character constants
-</pre>
-<p>And the following are also equivalent:
-<p><pre>
- dd 'ninechars' ; doubleword string constant
- dd 'nine','char','s' ; becomes three doublewords
- db 'ninechars',0,0,0 ; and really looks like this
-</pre>
-<p>Note that when used in a string-supporting context, quoted strings are
-treated as a string constants even if they are short enough to be a
-character constant, because otherwise <code><nobr>db 'ab'</nobr></code>
-would have the same effect as <code><nobr>db 'a'</nobr></code>, which would
-be silly. Similarly, three-character or four-character constants are
-treated as strings when they are operands to <code><nobr>DW</nobr></code>,
-and so forth.
-<h4><a name="section-3.4.5">3.4.5 Unicode Strings</a></h4>
-<p>The special operators <code><nobr>__utf16__</nobr></code> and
-<code><nobr>__utf32__</nobr></code> allows definition of Unicode strings.
-They take a string in UTF-8 format and converts it to (littleendian) UTF-16
-or UTF-32, respectively.
-<p>For example:
-<p><pre>
-%define u(x) __utf16__(x)
-%define w(x) __utf32__(x)
-
- dw u('C:\WINDOWS'), 0 ; Pathname in UTF-16
- dd w(`A + B = \u206a`), 0 ; String in UTF-32
-</pre>
-<p><code><nobr>__utf16__</nobr></code> and
-<code><nobr>__utf32__</nobr></code> can be applied either to strings passed
-to the <code><nobr>DB</nobr></code> family instructions, or to character
-constants in an expression context.
-<h4><a name="section-3.4.6">3.4.6 Floating-Point Constants</a></h4>
-<p>Floating-point constants are acceptable only as arguments to
-<code><nobr>DB</nobr></code>, <code><nobr>DW</nobr></code>,
-<code><nobr>DD</nobr></code>, <code><nobr>DQ</nobr></code>,
-<code><nobr>DT</nobr></code>, and <code><nobr>DO</nobr></code>, or as
-arguments to the special operators <code><nobr>__float8__</nobr></code>,
-<code><nobr>__float16__</nobr></code>,
-<code><nobr>__float32__</nobr></code>,
-<code><nobr>__float64__</nobr></code>,
-<code><nobr>__float80m__</nobr></code>,
-<code><nobr>__float80e__</nobr></code>,
-<code><nobr>__float128l__</nobr></code>, and
-<code><nobr>__float128h__</nobr></code>.
-<p>Floating-point constants are expressed in the traditional form: digits,
-then a period, then optionally more digits, then optionally an
-<code><nobr>E</nobr></code> followed by an exponent. The period is
-mandatory, so that NASM can distinguish between
-<code><nobr>dd 1</nobr></code>, which declares an integer constant, and
-<code><nobr>dd 1.0</nobr></code> which declares a floating-point constant.
-NASM also support C99-style hexadecimal floating-point:
-<code><nobr>0x</nobr></code>, hexadecimal digits, period, optionally more
-hexadeximal digits, then optionally a <code><nobr>P</nobr></code> followed
-by a <em>binary</em> (not hexadecimal) exponent in decimal notation.
-<p>Underscores to break up groups of digits are permitted in floating-point
-constants as well.
-<p>Some examples:
-<p><pre>
- db -0.2 ; "Quarter precision"
- dw -0.5 ; IEEE 754r/SSE5 half precision
- dd 1.2 ; an easy one
- dd 1.222_222_222 ; underscores are permitted
- dd 0x1p+2 ; 1.0x2^2 = 4.0
- dq 0x1p+32 ; 1.0x2^32 = 4 294 967 296.0
- dq 1.e10 ; 10 000 000 000.0
- dq 1.e+10 ; synonymous with 1.e10
- dq 1.e-10 ; 0.000 000 000 1
- dt 3.141592653589793238462 ; pi
- do 1.e+4000 ; IEEE 754r quad precision
-</pre>
-<p>The 8-bit "quarter-precision" floating-point format is
-sign:exponent:mantissa = 1:4:3 with an exponent bias of 7. This appears to
-be the most frequently used 8-bit floating-point format, although it is not
-covered by any formal standard. This is sometimes called a "minifloat."
-<p>The special operators are used to produce floating-point numbers in
-other contexts. They produce the binary representation of a specific
-floating-point number as an integer, and can use anywhere integer constants
-are used in an expression. <code><nobr>__float80m__</nobr></code> and
-<code><nobr>__float80e__</nobr></code> produce the 64-bit mantissa and
-16-bit exponent of an 80-bit floating-point number, and
-<code><nobr>__float128l__</nobr></code> and
-<code><nobr>__float128h__</nobr></code> produce the lower and upper 64-bit
-halves of a 128-bit floating-point number, respectively.
-<p>For example:
-<p><pre>
- mov rax,__float64__(3.141592653589793238462)
-</pre>
-<p>... would assign the binary representation of pi as a 64-bit floating
-point number into <code><nobr>RAX</nobr></code>. This is exactly equivalent
-to:
-<p><pre>
- mov rax,0x400921fb54442d18
-</pre>
-<p>NASM cannot do compile-time arithmetic on floating-point constants. This
-is because NASM is designed to be portable - although it always generates
-code to run on x86 processors, the assembler itself can run on any system
-with an ANSI C compiler. Therefore, the assembler cannot guarantee the
-presence of a floating-point unit capable of handling the Intel number
-formats, and so for NASM to be able to do floating arithmetic it would have
-to include its own complete set of floating-point routines, which would
-significantly increase the size of the assembler for very little benefit.
-<p>The special tokens <code><nobr>__Infinity__</nobr></code>,
-<code><nobr>__QNaN__</nobr></code> (or <code><nobr>__NaN__</nobr></code>)
-and <code><nobr>__SNaN__</nobr></code> can be used to generate infinities,
-quiet NaNs, and signalling NaNs, respectively. These are normally used as
-macros:
-<p><pre>
-%define Inf __Infinity__
-%define NaN __QNaN__
-
- dq +1.5, -Inf, NaN ; Double-precision constants
-</pre>
-<h4><a name="section-3.4.7">3.4.7 Packed BCD Constants</a></h4>
-<p>x87-style packed BCD constants can be used in the same contexts as
-80-bit floating-point numbers. They are suffixed with
-<code><nobr>p</nobr></code> or prefixed with <code><nobr>0p</nobr></code>,
-and can include up to 18 decimal digits.
-<p>As with other numeric constants, underscores can be used to separate
-digits.
-<p>For example:
-<p><pre>
- dt 12_345_678_901_245_678p
- dt -12_345_678_901_245_678p
- dt +0p33
- dt 33p
-</pre>
-<h3><a name="section-3.5">3.5 Expressions</a></h3>
-<p>Expressions in NASM are similar in syntax to those in C. Expressions are
-evaluated as 64-bit integers which are then adjusted to the appropriate
-size.
-<p>NASM supports two special tokens in expressions, allowing calculations
-to involve the current assembly position: the <code><nobr>$</nobr></code>
-and <code><nobr>$$</nobr></code> tokens. <code><nobr>$</nobr></code>
-evaluates to the assembly position at the beginning of the line containing
-the expression; so you can code an infinite loop using
-<code><nobr>JMP $</nobr></code>. <code><nobr>$$</nobr></code> evaluates to
-the beginning of the current section; so you can tell how far into the
-section you are by using <code><nobr>($-$$)</nobr></code>.
-<p>The arithmetic operators provided by NASM are listed here, in increasing
-order of precedence.
-<h4><a name="section-3.5.1">3.5.1 <code><nobr>|</nobr></code>: Bitwise OR Operator</a></h4>
-<p>The <code><nobr>|</nobr></code> operator gives a bitwise OR, exactly as
-performed by the <code><nobr>OR</nobr></code> machine instruction. Bitwise
-OR is the lowest-priority arithmetic operator supported by NASM.
-<h4><a name="section-3.5.2">3.5.2 <code><nobr>^</nobr></code>: Bitwise XOR Operator</a></h4>
-<p><code><nobr>^</nobr></code> provides the bitwise XOR operation.
-<h4><a name="section-3.5.3">3.5.3 <code><nobr>&amp;</nobr></code>: Bitwise AND Operator</a></h4>
-<p><code><nobr>&amp;</nobr></code> provides the bitwise AND operation.
-<h4><a name="section-3.5.4">3.5.4 <code><nobr>&lt;&lt;</nobr></code> and <code><nobr>&gt;&gt;</nobr></code>: Bit Shift Operators</a></h4>
-<p><code><nobr>&lt;&lt;</nobr></code> gives a bit-shift to the left, just
-as it does in C. So <code><nobr>5&lt;&lt;3</nobr></code> evaluates to 5
-times 8, or 40. <code><nobr>&gt;&gt;</nobr></code> gives a bit-shift to the
-right; in NASM, such a shift is <em>always</em> unsigned, so that the bits
-shifted in from the left-hand end are filled with zero rather than a
-sign-extension of the previous highest bit.
-<h4><a name="section-3.5.5">3.5.5 <code><nobr>+</nobr></code> and <code><nobr>-</nobr></code>: Addition and Subtraction Operators</a></h4>
-<p>The <code><nobr>+</nobr></code> and <code><nobr>-</nobr></code>
-operators do perfectly ordinary addition and subtraction.
-<h4><a name="section-3.5.6">3.5.6 <code><nobr>*</nobr></code>, <code><nobr>/</nobr></code>, <code><nobr>//</nobr></code>, <code><nobr>%</nobr></code> and <code><nobr>%%</nobr></code>: Multiplication and Division</a></h4>
-<p><code><nobr>*</nobr></code> is the multiplication operator.
-<code><nobr>/</nobr></code> and <code><nobr>//</nobr></code> are both
-division operators: <code><nobr>/</nobr></code> is unsigned division and
-<code><nobr>//</nobr></code> is signed division. Similarly,
-<code><nobr>%</nobr></code> and <code><nobr>%%</nobr></code> provide
-unsigned and signed modulo operators respectively.
-<p>NASM, like ANSI C, provides no guarantees about the sensible operation
-of the signed modulo operator.
-<p>Since the <code><nobr>%</nobr></code> character is used extensively by
-the macro preprocessor, you should ensure that both the signed and unsigned
-modulo operators are followed by white space wherever they appear.
-<h4><a name="section-3.5.7">3.5.7 Unary Operators: <code><nobr>+</nobr></code>, <code><nobr>-</nobr></code>, <code><nobr>~</nobr></code>, <code><nobr>!</nobr></code> and <code><nobr>SEG</nobr></code></a></h4>
-<p>The highest-priority operators in NASM's expression grammar are those
-which only apply to one argument. <code><nobr>-</nobr></code> negates its
-operand, <code><nobr>+</nobr></code> does nothing (it's provided for
-symmetry with <code><nobr>-</nobr></code>), <code><nobr>~</nobr></code>
-computes the one's complement of its operand, <code><nobr>!</nobr></code>
-is the logical negation operator, and <code><nobr>SEG</nobr></code>
-provides the segment address of its operand (explained in more detail in
-<a href="#section-3.6">section 3.6</a>).
-<h3><a name="section-3.6">3.6 <code><nobr>SEG</nobr></code> and <code><nobr>WRT</nobr></code></a></h3>
-<p>When writing large 16-bit programs, which must be split into multiple
-segments, it is often necessary to be able to refer to the segment part of
-the address of a symbol. NASM supports the <code><nobr>SEG</nobr></code>
-operator to perform this function.
-<p>The <code><nobr>SEG</nobr></code> operator returns the
-<em>preferred</em> segment base of a symbol, defined as the segment base
-relative to which the offset of the symbol makes sense. So the code
-<p><pre>
- mov ax,seg symbol
- mov es,ax
- mov bx,symbol
-</pre>
-<p>will load <code><nobr>ES:BX</nobr></code> with a valid pointer to the
-symbol <code><nobr>symbol</nobr></code>.
-<p>Things can be more complex than this: since 16-bit segments and groups
-may overlap, you might occasionally want to refer to some symbol using a
-different segment base from the preferred one. NASM lets you do this, by
-the use of the <code><nobr>WRT</nobr></code> (With Reference To) keyword.
-So you can do things like
-<p><pre>
- mov ax,weird_seg ; weird_seg is a segment base
- mov es,ax
- mov bx,symbol wrt weird_seg
-</pre>
-<p>to load <code><nobr>ES:BX</nobr></code> with a different, but
-functionally equivalent, pointer to the symbol
-<code><nobr>symbol</nobr></code>.
-<p>NASM supports far (inter-segment) calls and jumps by means of the syntax
-<code><nobr>call segment:offset</nobr></code>, where
-<code><nobr>segment</nobr></code> and <code><nobr>offset</nobr></code> both
-represent immediate values. So to call a far procedure, you could code
-either of
-<p><pre>
- call (seg procedure):procedure
- call weird_seg:(procedure wrt weird_seg)
-</pre>
-<p>(The parentheses are included for clarity, to show the intended parsing
-of the above instructions. They are not necessary in practice.)
-<p>NASM supports the syntax <code><nobr>call far procedure</nobr></code> as
-a synonym for the first of the above usages. <code><nobr>JMP</nobr></code>
-works identically to <code><nobr>CALL</nobr></code> in these examples.
-<p>To declare a far pointer to a data item in a data segment, you must code
-<p><pre>
- dw symbol, seg symbol
-</pre>
-<p>NASM supports no convenient synonym for this, though you can always
-invent one using the macro processor.
-<h3><a name="section-3.7">3.7 <code><nobr>STRICT</nobr></code>: Inhibiting Optimization</a></h3>
-<p>When assembling with the optimizer set to level 2 or higher (see
-<a href="nasmdoc2.html#section-2.1.22">section 2.1.22</a>), NASM will use
-size specifiers (<code><nobr>BYTE</nobr></code>,
-<code><nobr>WORD</nobr></code>, <code><nobr>DWORD</nobr></code>,
-<code><nobr>QWORD</nobr></code>, <code><nobr>TWORD</nobr></code>,
-<code><nobr>OWORD</nobr></code> or <code><nobr>YWORD</nobr></code>), but
-will give them the smallest possible size. The keyword
-<code><nobr>STRICT</nobr></code> can be used to inhibit optimization and
-force a particular operand to be emitted in the specified size. For
-example, with the optimizer on, and in <code><nobr>BITS 16</nobr></code>
-mode,
-<p><pre>
- push dword 33
-</pre>
-<p>is encoded in three bytes <code><nobr>66 6A 21</nobr></code>, whereas
-<p><pre>
- push strict dword 33
-</pre>
-<p>is encoded in six bytes, with a full dword immediate operand
-<code><nobr>66 68 21 00 00 00</nobr></code>.
-<p>With the optimizer off, the same code (six bytes) is generated whether
-the <code><nobr>STRICT</nobr></code> keyword was used or not.
-<h3><a name="section-3.8">3.8 Critical Expressions</a></h3>
-<p>Although NASM has an optional multi-pass optimizer, there are some
-expressions which must be resolvable on the first pass. These are called
-<em>Critical Expressions</em>.
-<p>The first pass is used to determine the size of all the assembled code
-and data, so that the second pass, when generating all the code, knows all
-the symbol addresses the code refers to. So one thing NASM can't handle is
-code whose size depends on the value of a symbol declared after the code in
-question. For example,
-<p><pre>
- times (label-$) db 0
-label: db 'Where am I?'
-</pre>
-<p>The argument to <code><nobr>TIMES</nobr></code> in this case could
-equally legally evaluate to anything at all; NASM will reject this example
-because it cannot tell the size of the <code><nobr>TIMES</nobr></code> line
-when it first sees it. It will just as firmly reject the slightly
-paradoxical code
-<p><pre>
- times (label-$+1) db 0
-label: db 'NOW where am I?'
-</pre>
-<p>in which <em>any</em> value for the <code><nobr>TIMES</nobr></code>
-argument is by definition wrong!
-<p>NASM rejects these examples by means of a concept called a <em>critical
-expression</em>, which is defined to be an expression whose value is
-required to be computable in the first pass, and which must therefore
-depend only on symbols defined before it. The argument to the
-<code><nobr>TIMES</nobr></code> prefix is a critical expression.
-<h3><a name="section-3.9">3.9 Local Labels</a></h3>
-<p>NASM gives special treatment to symbols beginning with a period. A label
-beginning with a single period is treated as a <em>local</em> label, which
-means that it is associated with the previous non-local label. So, for
-example:
-<p><pre>
-label1 ; some code
-
-.loop
- ; some more code
-
- jne .loop
- ret
-
-label2 ; some code
-
-.loop
- ; some more code
-
- jne .loop
- ret
-</pre>
-<p>In the above code fragment, each <code><nobr>JNE</nobr></code>
-instruction jumps to the line immediately before it, because the two
-definitions of <code><nobr>.loop</nobr></code> are kept separate by virtue
-of each being associated with the previous non-local label.
-<p>This form of local label handling is borrowed from the old Amiga
-assembler DevPac; however, NASM goes one step further, in allowing access
-to local labels from other parts of the code. This is achieved by means of
-<em>defining</em> a local label in terms of the previous non-local label:
-the first definition of <code><nobr>.loop</nobr></code> above is really
-defining a symbol called <code><nobr>label1.loop</nobr></code>, and the
-second defines a symbol called <code><nobr>label2.loop</nobr></code>. So,
-if you really needed to, you could write
-<p><pre>
-label3 ; some more code
- ; and some more
-
- jmp label1.loop
-</pre>
-<p>Sometimes it is useful - in a macro, for instance - to be able to define
-a label which can be referenced from anywhere but which doesn't interfere
-with the normal local-label mechanism. Such a label can't be non-local
-because it would interfere with subsequent definitions of, and references
-to, local labels; and it can't be local because the macro that defined it
-wouldn't know the label's full name. NASM therefore introduces a third type
-of label, which is probably only useful in macro definitions: if a label
-begins with the special prefix <code><nobr>..@</nobr></code>, then it does
-nothing to the local label mechanism. So you could code
-<p><pre>
-label1: ; a non-local label
-.local: ; this is really label1.local
-..@foo: ; this is a special symbol
-label2: ; another non-local label
-.local: ; this is really label2.local
-
- jmp ..@foo ; this will jump three lines up
-</pre>
-<p>NASM has the capacity to define other special symbols beginning with a
-double period: for example, <code><nobr>..start</nobr></code> is used to
-specify the entry point in the <code><nobr>obj</nobr></code> output format
-(see <a href="nasmdoc7.html#section-7.4.6">section 7.4.6</a>).
-<p align=center><a href="nasmdoc4.html">Next Chapter</a> |
-<a href="nasmdoc2.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc5.html">Next Chapter</a> |
-<a href="nasmdoc3.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-4">Chapter 4: The NASM Preprocessor</a></h2>
-<p>NASM contains a powerful macro processor, which supports conditional
-assembly, multi-level file inclusion, two forms of macro (single-line and
-multi-line), and a `context stack' mechanism for extra macro power.
-Preprocessor directives all begin with a <code><nobr>%</nobr></code> sign.
-<p>The preprocessor collapses all lines which end with a backslash (\)
-character into a single line. Thus:
-<p><pre>
-%define THIS_VERY_LONG_MACRO_NAME_IS_DEFINED_TO \
- THIS_VALUE
-</pre>
-<p>will work like a single-line macro without the backslash-newline
-sequence.
-<h3><a name="section-4.1">4.1 Single-Line Macros</a></h3>
-<h4><a name="section-4.1.1">4.1.1 The Normal Way: <code><nobr>%define</nobr></code></a></h4>
-<p>Single-line macros are defined using the
-<code><nobr>%define</nobr></code> preprocessor directive. The definitions
-work in a similar way to C; so you can do things like
-<p><pre>
-%define ctrl 0x1F &amp;
-%define param(a,b) ((a)+(a)*(b))
-
- mov byte [param(2,ebx)], ctrl 'D'
-</pre>
-<p>which will expand to
-<p><pre>
- mov byte [(2)+(2)*(ebx)], 0x1F &amp; 'D'
-</pre>
-<p>When the expansion of a single-line macro contains tokens which invoke
-another macro, the expansion is performed at invocation time, not at
-definition time. Thus the code
-<p><pre>
-%define a(x) 1+b(x)
-%define b(x) 2*x
-
- mov ax,a(8)
-</pre>
-<p>will evaluate in the expected way to
-<code><nobr>mov ax,1+2*8</nobr></code>, even though the macro
-<code><nobr>b</nobr></code> wasn't defined at the time of definition of
-<code><nobr>a</nobr></code>.
-<p>Macros defined with <code><nobr>%define</nobr></code> are case
-sensitive: after <code><nobr>%define foo bar</nobr></code>, only
-<code><nobr>foo</nobr></code> will expand to <code><nobr>bar</nobr></code>:
-<code><nobr>Foo</nobr></code> or <code><nobr>FOO</nobr></code> will not. By
-using <code><nobr>%idefine</nobr></code> instead of
-<code><nobr>%define</nobr></code> (the `i' stands for `insensitive') you
-can define all the case variants of a macro at once, so that
-<code><nobr>%idefine foo bar</nobr></code> would cause
-<code><nobr>foo</nobr></code>, <code><nobr>Foo</nobr></code>,
-<code><nobr>FOO</nobr></code>, <code><nobr>fOO</nobr></code> and so on all
-to expand to <code><nobr>bar</nobr></code>.
-<p>There is a mechanism which detects when a macro call has occurred as a
-result of a previous expansion of the same macro, to guard against circular
-references and infinite loops. If this happens, the preprocessor will only
-expand the first occurrence of the macro. Hence, if you code
-<p><pre>
-%define a(x) 1+a(x)
-
- mov ax,a(3)
-</pre>
-<p>the macro <code><nobr>a(3)</nobr></code> will expand once, becoming
-<code><nobr>1+a(3)</nobr></code>, and will then expand no further. This
-behaviour can be useful: see <a href="nasmdoc9.html#section-9.1">section
-9.1</a> for an example of its use.
-<p>You can overload single-line macros: if you write
-<p><pre>
-%define foo(x) 1+x
-%define foo(x,y) 1+x*y
-</pre>
-<p>the preprocessor will be able to handle both types of macro call, by
-counting the parameters you pass; so <code><nobr>foo(3)</nobr></code> will
-become <code><nobr>1+3</nobr></code> whereas
-<code><nobr>foo(ebx,2)</nobr></code> will become
-<code><nobr>1+ebx*2</nobr></code>. However, if you define
-<p><pre>
-%define foo bar
-</pre>
-<p>then no other definition of <code><nobr>foo</nobr></code> will be
-accepted: a macro with no parameters prohibits the definition of the same
-name as a macro <em>with</em> parameters, and vice versa.
-<p>This doesn't prevent single-line macros being <em>redefined</em>: you
-can perfectly well define a macro with
-<p><pre>
-%define foo bar
-</pre>
-<p>and then re-define it later in the same source file with
-<p><pre>
-%define foo baz
-</pre>
-<p>Then everywhere the macro <code><nobr>foo</nobr></code> is invoked, it
-will be expanded according to the most recent definition. This is
-particularly useful when defining single-line macros with
-<code><nobr>%assign</nobr></code> (see <a href="#section-4.1.7">section
-4.1.7</a>).
-<p>You can pre-define single-line macros using the `-d' option on the NASM
-command line: see <a href="nasmdoc2.html#section-2.1.18">section
-2.1.18</a>.
-<h4><a name="section-4.1.2">4.1.2 Resolving <code><nobr>%define</nobr></code>: <code><nobr>%xdefine</nobr></code></a></h4>
-<p>To have a reference to an embedded single-line macro resolved at the
-time that the embedding macro is <em>defined</em>, as opposed to when the
-embedding macro is <em>expanded</em>, you need a different mechanism to the
-one offered by <code><nobr>%define</nobr></code>. The solution is to use
-<code><nobr>%xdefine</nobr></code>, or it's case-insensitive counterpart
-<code><nobr>%ixdefine</nobr></code>.
-<p>Suppose you have the following code:
-<p><pre>
-%define isTrue 1
-%define isFalse isTrue
-%define isTrue 0
-
-val1: db isFalse
-
-%define isTrue 1
-
-val2: db isFalse
-</pre>
-<p>In this case, <code><nobr>val1</nobr></code> is equal to 0, and
-<code><nobr>val2</nobr></code> is equal to 1. This is because, when a
-single-line macro is defined using <code><nobr>%define</nobr></code>, it is
-expanded only when it is called. As <code><nobr>isFalse</nobr></code>
-expands to <code><nobr>isTrue</nobr></code>, the expansion will be the
-current value of <code><nobr>isTrue</nobr></code>. The first time it is
-called that is 0, and the second time it is 1.
-<p>If you wanted <code><nobr>isFalse</nobr></code> to expand to the value
-assigned to the embedded macro <code><nobr>isTrue</nobr></code> at the time
-that <code><nobr>isFalse</nobr></code> was defined, you need to change the
-above code to use <code><nobr>%xdefine</nobr></code>.
-<p><pre>
-%xdefine isTrue 1
-%xdefine isFalse isTrue
-%xdefine isTrue 0
-
-val1: db isFalse
-
-%xdefine isTrue 1
-
-val2: db isFalse
-</pre>
-<p>Now, each time that <code><nobr>isFalse</nobr></code> is called, it
-expands to 1, as that is what the embedded macro
-<code><nobr>isTrue</nobr></code> expanded to at the time that
-<code><nobr>isFalse</nobr></code> was defined.
-<h4><a name="section-4.1.3">4.1.3 Macro Indirection: <code><nobr>%[...]</nobr></code></a></h4>
-<p>The <code><nobr>%[...]</nobr></code> construct can be used to expand
-macros in contexts where macro expansion would otherwise not occur,
-including in the names other macros. For example, if you have a set of
-macros named <code><nobr>Foo16</nobr></code>,
-<code><nobr>Foo32</nobr></code> and <code><nobr>Foo64</nobr></code>, you
-could write:
-<p><pre>
- mov ax,Foo%[__BITS__] ; The Foo value
-</pre>
-<p>to use the builtin macro <code><nobr>__BITS__</nobr></code> (see
-<a href="#section-4.11.5">section 4.11.5</a>) to automatically select
-between them. Similarly, the two statements:
-<p><pre>
-%xdefine Bar Quux ; Expands due to %xdefine
-%define Bar %[Quux] ; Expands due to %[...]
-</pre>
-<p>have, in fact, exactly the same effect.
-<p><code><nobr>%[...]</nobr></code> concatenates to adjacent tokens in the
-same way that multi-line macro parameters do, see
-<a href="#section-4.3.8">section 4.3.8</a> for details.
-<h4><a name="section-4.1.4">4.1.4 Concatenating Single Line Macro Tokens: <code><nobr>%+</nobr></code></a></h4>
-<p>Individual tokens in single line macros can be concatenated, to produce
-longer tokens for later processing. This can be useful if there are several
-similar macros that perform similar functions.
-<p>Please note that a space is required after <code><nobr>%+</nobr></code>,
-in order to disambiguate it from the syntax <code><nobr>%+1</nobr></code>
-used in multiline macros.
-<p>As an example, consider the following:
-<p><pre>
-%define BDASTART 400h ; Start of BIOS data area
-</pre>
-<p><pre>
-struc tBIOSDA ; its structure
- .COM1addr RESW 1
- .COM2addr RESW 1
- ; ..and so on
-endstruc
-</pre>
-<p>Now, if we need to access the elements of tBIOSDA in different places,
-we can end up with:
-<p><pre>
- mov ax,BDASTART + tBIOSDA.COM1addr
- mov bx,BDASTART + tBIOSDA.COM2addr
-</pre>
-<p>This will become pretty ugly (and tedious) if used in many places, and
-can be reduced in size significantly by using the following macro:
-<p><pre>
-; Macro to access BIOS variables by their names (from tBDA):
-</pre>
-<p><pre>
-%define BDA(x) BDASTART + tBIOSDA. %+ x
-</pre>
-<p>Now the above code can be written as:
-<p><pre>
- mov ax,BDA(COM1addr)
- mov bx,BDA(COM2addr)
-</pre>
-<p>Using this feature, we can simplify references to a lot of macros (and,
-in turn, reduce typing errors).
-<h4><a name="section-4.1.5">4.1.5 The Macro Name Itself: <code><nobr>%?</nobr></code> and <code><nobr>%??</nobr></code></a></h4>
-<p>The special symbols <code><nobr>%?</nobr></code> and
-<code><nobr>%??</nobr></code> can be used to reference the macro name
-itself inside a macro expansion, this is supported for both single-and
-multi-line macros. <code><nobr>%?</nobr></code> refers to the macro name as
-<em>invoked</em>, whereas <code><nobr>%??</nobr></code> refers to the macro
-name as <em>declared</em>. The two are always the same for case-sensitive
-macros, but for case-insensitive macros, they can differ.
-<p>For example:
-<p><pre>
-%idefine Foo mov %?,%??
-
- foo
- FOO
-</pre>
-<p>will expand to:
-<p><pre>
- mov foo,Foo
- mov FOO,Foo
-</pre>
-<p>The sequence:
-<p><pre>
-%idefine keyword $%?
-</pre>
-<p>can be used to make a keyword "disappear", for example in case a new
-instruction has been used as a label in older code. For example:
-<p><pre>
-%idefine pause $%? ; Hide the PAUSE instruction
-</pre>
-<h4><a name="section-4.1.6">4.1.6 Undefining Single-Line Macros: <code><nobr>%undef</nobr></code></a></h4>
-<p>Single-line macros can be removed with the
-<code><nobr>%undef</nobr></code> directive. For example, the following
-sequence:
-<p><pre>
-%define foo bar
-%undef foo
-
- mov eax, foo
-</pre>
-<p>will expand to the instruction <code><nobr>mov eax, foo</nobr></code>,
-since after <code><nobr>%undef</nobr></code> the macro
-<code><nobr>foo</nobr></code> is no longer defined.
-<p>Macros that would otherwise be pre-defined can be undefined on the
-command-line using the `-u' option on the NASM command line: see
-<a href="nasmdoc2.html#section-2.1.19">section 2.1.19</a>.
-<h4><a name="section-4.1.7">4.1.7 Preprocessor Variables: <code><nobr>%assign</nobr></code></a></h4>
-<p>An alternative way to define single-line macros is by means of the
-<code><nobr>%assign</nobr></code> command (and its case-insensitive
-counterpart <code><nobr>%iassign</nobr></code>, which differs from
-<code><nobr>%assign</nobr></code> in exactly the same way that
-<code><nobr>%idefine</nobr></code> differs from
-<code><nobr>%define</nobr></code>).
-<p><code><nobr>%assign</nobr></code> is used to define single-line macros
-which take no parameters and have a numeric value. This value can be
-specified in the form of an expression, and it will be evaluated once, when
-the <code><nobr>%assign</nobr></code> directive is processed.
-<p>Like <code><nobr>%define</nobr></code>, macros defined using
-<code><nobr>%assign</nobr></code> can be re-defined later, so you can do
-things like
-<p><pre>
-%assign i i+1
-</pre>
-<p>to increment the numeric value of a macro.
-<p><code><nobr>%assign</nobr></code> is useful for controlling the
-termination of <code><nobr>%rep</nobr></code> preprocessor loops: see
-<a href="#section-4.5">section 4.5</a> for an example of this. Another use
-for <code><nobr>%assign</nobr></code> is given in
-<a href="nasmdoc8.html#section-8.4">section 8.4</a> and
-<a href="nasmdoc9.html#section-9.1">section 9.1</a>.
-<p>The expression passed to <code><nobr>%assign</nobr></code> is a critical
-expression (see <a href="nasmdoc3.html#section-3.8">section 3.8</a>), and
-must also evaluate to a pure number (rather than a relocatable reference
-such as a code or data address, or anything involving a register).
-<h4><a name="section-4.1.8">4.1.8 Defining Strings: <code><nobr>%defstr</nobr></code></a></h4>
-<p><code><nobr>%defstr</nobr></code>, and its case-insensitive counterpart
-<code><nobr>%idefstr</nobr></code>, define or redefine a single-line macro
-without parameters but converts the entire right-hand side, after macro
-expansion, to a quoted string before definition.
-<p>For example:
-<p><pre>
-%defstr test TEST
-</pre>
-<p>is equivalent to
-<p><pre>
-%define test 'TEST'
-</pre>
-<p>This can be used, for example, with the <code><nobr>%!</nobr></code>
-construct (see <a href="#section-4.10.2">section 4.10.2</a>):
-<p><pre>
-%defstr PATH %!PATH ; The operating system PATH variable
-</pre>
-<h4><a name="section-4.1.9">4.1.9 Defining Tokens: <code><nobr>%deftok</nobr></code></a></h4>
-<p><code><nobr>%deftok</nobr></code>, and its case-insensitive counterpart
-<code><nobr>%ideftok</nobr></code>, define or redefine a single-line macro
-without parameters but converts the second parameter, after string
-conversion, to a sequence of tokens.
-<p>For example:
-<p><pre>
-%deftok test 'TEST'
-</pre>
-<p>is equivalent to
-<p><pre>
-%define test TEST
-</pre>
-<h3><a name="section-4.2">4.2 String Manipulation in Macros</a></h3>
-<p>It's often useful to be able to handle strings in macros. NASM supports
-a few simple string handling macro operators from which more complex
-operations can be constructed.
-<p>All the string operators define or redefine a value (either a string or
-a numeric value) to a single-line macro. When producing a string value, it
-may change the style of quoting of the input string or strings, and
-possibly use <code><nobr>\</nobr></code>-escapes inside
-<code><nobr>`</nobr></code>-quoted strings.
-<h4><a name="section-4.2.1">4.2.1 Concatenating Strings: <code><nobr>%strcat</nobr></code></a></h4>
-<p>The <code><nobr>%strcat</nobr></code> operator concatenates quoted
-strings and assign them to a single-line macro.
-<p>For example:
-<p><pre>
-%strcat alpha "Alpha: ", '12" screen'
-</pre>
-<p>... would assign the value <code><nobr>'Alpha: 12" screen'</nobr></code>
-to <code><nobr>alpha</nobr></code>. Similarly:
-<p><pre>
-%strcat beta '"foo"\', "'bar'"
-</pre>
-<p>... would assign the value <code><nobr>`"foo"\\'bar'`</nobr></code> to
-<code><nobr>beta</nobr></code>.
-<p>The use of commas to separate strings is permitted but optional.
-<h4><a name="section-4.2.2">4.2.2 String Length: <code><nobr>%strlen</nobr></code></a></h4>
-<p>The <code><nobr>%strlen</nobr></code> operator assigns the length of a
-string to a macro. For example:
-<p><pre>
-%strlen charcnt 'my string'
-</pre>
-<p>In this example, <code><nobr>charcnt</nobr></code> would receive the
-value 9, just as if an <code><nobr>%assign</nobr></code> had been used. In
-this example, <code><nobr>'my string'</nobr></code> was a literal string
-but it could also have been a single-line macro that expands to a string,
-as in the following example:
-<p><pre>
-%define sometext 'my string'
-%strlen charcnt sometext
-</pre>
-<p>As in the first case, this would result in
-<code><nobr>charcnt</nobr></code> being assigned the value of 9.
-<h4><a name="section-4.2.3">4.2.3 Extracting Substrings: <code><nobr>%substr</nobr></code></a></h4>
-<p>Individual letters or substrings in strings can be extracted using the
-<code><nobr>%substr</nobr></code> operator. An example of its use is
-probably more useful than the description:
-<p><pre>
-%substr mychar 'xyzw' 1 ; equivalent to %define mychar 'x'
-%substr mychar 'xyzw' 2 ; equivalent to %define mychar 'y'
-%substr mychar 'xyzw' 3 ; equivalent to %define mychar 'z'
-%substr mychar 'xyzw' 2,2 ; equivalent to %define mychar 'yz'
-%substr mychar 'xyzw' 2,-1 ; equivalent to %define mychar 'yzw'
-%substr mychar 'xyzw' 2,-2 ; equivalent to %define mychar 'yz'
-</pre>
-<p>As with <code><nobr>%strlen</nobr></code> (see
-<a href="#section-4.2.2">section 4.2.2</a>), the first parameter is the
-single-line macro to be created and the second is the string. The third
-parameter specifies the first character to be selected, and the optional
-fourth parameter preceeded by comma) is the length. Note that the first
-index is 1, not 0 and the last index is equal to the value that
-<code><nobr>%strlen</nobr></code> would assign given the same string. Index
-values out of range result in an empty string. A negative length means
-"until N-1 characters before the end of string", i.e.
-<code><nobr>-1</nobr></code> means until end of string,
-<code><nobr>-2</nobr></code> until one character before, etc.
-<h3><a name="section-4.3">4.3 Multi-Line Macros: <code><nobr>%macro</nobr></code></a></h3>
-<p>Multi-line macros are much more like the type of macro seen in MASM and
-TASM: a multi-line macro definition in NASM looks something like this.
-<p><pre>
-%macro prologue 1
-
- push ebp
- mov ebp,esp
- sub esp,%1
-
-%endmacro
-</pre>
-<p>This defines a C-like function prologue as a macro: so you would invoke
-the macro with a call such as
-<p><pre>
-myfunc: prologue 12
-</pre>
-<p>which would expand to the three lines of code
-<p><pre>
-myfunc: push ebp
- mov ebp,esp
- sub esp,12
-</pre>
-<p>The number <code><nobr>1</nobr></code> after the macro name in the
-<code><nobr>%macro</nobr></code> line defines the number of parameters the
-macro <code><nobr>prologue</nobr></code> expects to receive. The use of
-<code><nobr>%1</nobr></code> inside the macro definition refers to the
-first parameter to the macro call. With a macro taking more than one
-parameter, subsequent parameters would be referred to as
-<code><nobr>%2</nobr></code>, <code><nobr>%3</nobr></code> and so on.
-<p>Multi-line macros, like single-line macros, are case-sensitive, unless
-you define them using the alternative directive
-<code><nobr>%imacro</nobr></code>.
-<p>If you need to pass a comma as <em>part</em> of a parameter to a
-multi-line macro, you can do that by enclosing the entire parameter in
-braces. So you could code things like
-<p><pre>
-%macro silly 2
-
- %2: db %1
-
-%endmacro
-
- silly 'a', letter_a ; letter_a: db 'a'
- silly 'ab', string_ab ; string_ab: db 'ab'
- silly {13,10}, crlf ; crlf: db 13,10
-</pre>
-<h4><a name="section-4.3.1">4.3.1 Recursive Multi-Line Macros: <code><nobr>%rmacro</nobr></code></a></h4>
-<p>A multi-line macro cannot be referenced within itself, in order to
-prevent accidental infinite recursion.
-<p>Recursive multi-line macros allow for self-referencing, with the caveat
-that the user is aware of the existence, use and purpose of recursive
-multi-line macros. There is also a generous, but sane, upper limit to the
-number of recursions, in order to prevent run-away memory consumption in
-case of accidental infinite recursion.
-<p>As with non-recursive multi-line macros, recursive multi-line macros are
-case-sensitive, unless you define them using the alternative directive
-<code><nobr>%irmacro</nobr></code>.
-<h4><a name="section-4.3.2">4.3.2 Overloading Multi-Line Macros</a></h4>
-<p>As with single-line macros, multi-line macros can be overloaded by
-defining the same macro name several times with different numbers of
-parameters. This time, no exception is made for macros with no parameters
-at all. So you could define
-<p><pre>
-%macro prologue 0
-
- push ebp
- mov ebp,esp
-
-%endmacro
-</pre>
-<p>to define an alternative form of the function prologue which allocates
-no local stack space.
-<p>Sometimes, however, you might want to `overload' a machine instruction;
-for example, you might want to define
-<p><pre>
-%macro push 2
-
- push %1
- push %2
-
-%endmacro
-</pre>
-<p>so that you could code
-<p><pre>
- push ebx ; this line is not a macro call
- push eax,ecx ; but this one is
-</pre>
-<p>Ordinarily, NASM will give a warning for the first of the above two
-lines, since <code><nobr>push</nobr></code> is now defined to be a macro,
-and is being invoked with a number of parameters for which no definition
-has been given. The correct code will still be generated, but the assembler
-will give a warning. This warning can be disabled by the use of the
-<code><nobr>-w-macro-params</nobr></code> command-line option (see
-<a href="nasmdoc2.html#section-2.1.24">section 2.1.24</a>).
-<h4><a name="section-4.3.3">4.3.3 Macro-Local Labels</a></h4>
-<p>NASM allows you to define labels within a multi-line macro definition in
-such a way as to make them local to the macro call: so calling the same
-macro multiple times will use a different label each time. You do this by
-prefixing <code><nobr>%%</nobr></code> to the label name. So you can invent
-an instruction which executes a <code><nobr>RET</nobr></code> if the
-<code><nobr>Z</nobr></code> flag is set by doing this:
-<p><pre>
-%macro retz 0
-
- jnz %%skip
- ret
- %%skip:
-
-%endmacro
-</pre>
-<p>You can call this macro as many times as you want, and every time you
-call it NASM will make up a different `real' name to substitute for the
-label <code><nobr>%%skip</nobr></code>. The names NASM invents are of the
-form <code><nobr>..@2345.skip</nobr></code>, where the number 2345 changes
-with every macro call. The <code><nobr>..@</nobr></code> prefix prevents
-macro-local labels from interfering with the local label mechanism, as
-described in <a href="nasmdoc3.html#section-3.9">section 3.9</a>. You
-should avoid defining your own labels in this form (the
-<code><nobr>..@</nobr></code> prefix, then a number, then another period)
-in case they interfere with macro-local labels.
-<h4><a name="section-4.3.4">4.3.4 Greedy Macro Parameters</a></h4>
-<p>Occasionally it is useful to define a macro which lumps its entire
-command line into one parameter definition, possibly after extracting one
-or two smaller parameters from the front. An example might be a macro to
-write a text string to a file in MS-DOS, where you might want to be able to
-write
-<p><pre>
- writefile [filehandle],"hello, world",13,10
-</pre>
-<p>NASM allows you to define the last parameter of a macro to be
-<em>greedy</em>, meaning that if you invoke the macro with more parameters
-than it expects, all the spare parameters get lumped into the last defined
-one along with the separating commas. So if you code:
-<p><pre>
-%macro writefile 2+
-
- jmp %%endstr
- %%str: db %2
- %%endstr:
- mov dx,%%str
- mov cx,%%endstr-%%str
- mov bx,%1
- mov ah,0x40
- int 0x21
-
-%endmacro
-</pre>
-<p>then the example call to <code><nobr>writefile</nobr></code> above will
-work as expected: the text before the first comma,
-<code><nobr>[filehandle]</nobr></code>, is used as the first macro
-parameter and expanded when <code><nobr>%1</nobr></code> is referred to,
-and all the subsequent text is lumped into <code><nobr>%2</nobr></code> and
-placed after the <code><nobr>db</nobr></code>.
-<p>The greedy nature of the macro is indicated to NASM by the use of the
-<code><nobr>+</nobr></code> sign after the parameter count on the
-<code><nobr>%macro</nobr></code> line.
-<p>If you define a greedy macro, you are effectively telling NASM how it
-should expand the macro given <em>any</em> number of parameters from the
-actual number specified up to infinity; in this case, for example, NASM now
-knows what to do when it sees a call to <code><nobr>writefile</nobr></code>
-with 2, 3, 4 or more parameters. NASM will take this into account when
-overloading macros, and will not allow you to define another form of
-<code><nobr>writefile</nobr></code> taking 4 parameters (for example).
-<p>Of course, the above macro could have been implemented as a non-greedy
-macro, in which case the call to it would have had to look like
-<p><pre>
- writefile [filehandle], {"hello, world",13,10}
-</pre>
-<p>NASM provides both mechanisms for putting commas in macro parameters,
-and you choose which one you prefer for each macro definition.
-<p>See <a href="nasmdoc6.html#section-6.3.1">section 6.3.1</a> for a better
-way to write the above macro.
-<h4><a name="section-4.3.5">4.3.5 Default Macro Parameters</a></h4>
-<p>NASM also allows you to define a multi-line macro with a <em>range</em>
-of allowable parameter counts. If you do this, you can specify defaults for
-omitted parameters. So, for example:
-<p><pre>
-%macro die 0-1 "Painful program death has occurred."
-
- writefile 2,%1
- mov ax,0x4c01
- int 0x21
-
-%endmacro
-</pre>
-<p>This macro (which makes use of the <code><nobr>writefile</nobr></code>
-macro defined in <a href="#section-4.3.4">section 4.3.4</a>) can be called
-with an explicit error message, which it will display on the error output
-stream before exiting, or it can be called with no parameters, in which
-case it will use the default error message supplied in the macro
-definition.
-<p>In general, you supply a minimum and maximum number of parameters for a
-macro of this type; the minimum number of parameters are then required in
-the macro call, and then you provide defaults for the optional ones. So if
-a macro definition began with the line
-<p><pre>
-%macro foobar 1-3 eax,[ebx+2]
-</pre>
-<p>then it could be called with between one and three parameters, and
-<code><nobr>%1</nobr></code> would always be taken from the macro call.
-<code><nobr>%2</nobr></code>, if not specified by the macro call, would
-default to <code><nobr>eax</nobr></code>, and <code><nobr>%3</nobr></code>
-if not specified would default to <code><nobr>[ebx+2]</nobr></code>.
-<p>You can provide extra information to a macro by providing too many
-default parameters:
-<p><pre>
-%macro quux 1 something
-</pre>
-<p>This will trigger a warning by default; see
-<a href="nasmdoc2.html#section-2.1.24">section 2.1.24</a> for more
-information. When <code><nobr>quux</nobr></code> is invoked, it receives
-not one but two parameters. <code><nobr>something</nobr></code> can be
-referred to as <code><nobr>%2</nobr></code>. The difference between passing
-<code><nobr>something</nobr></code> this way and writing
-<code><nobr>something</nobr></code> in the macro body is that with this way
-<code><nobr>something</nobr></code> is evaluated when the macro is defined,
-not when it is expanded.
-<p>You may omit parameter defaults from the macro definition, in which case
-the parameter default is taken to be blank. This can be useful for macros
-which can take a variable number of parameters, since the
-<code><nobr>%0</nobr></code> token (see <a href="#section-4.3.6">section
-4.3.6</a>) allows you to determine how many parameters were really passed
-to the macro call.
-<p>This defaulting mechanism can be combined with the greedy-parameter
-mechanism; so the <code><nobr>die</nobr></code> macro above could be made
-more powerful, and more useful, by changing the first line of the
-definition to
-<p><pre>
-%macro die 0-1+ "Painful program death has occurred.",13,10
-</pre>
-<p>The maximum parameter count can be infinite, denoted by
-<code><nobr>*</nobr></code>. In this case, of course, it is impossible to
-provide a <em>full</em> set of default parameters. Examples of this usage
-are shown in <a href="#section-4.3.7">section 4.3.7</a>.
-<h4><a name="section-4.3.6">4.3.6 <code><nobr>%0</nobr></code>: Macro Parameter Counter</a></h4>
-<p>The parameter reference <code><nobr>%0</nobr></code> will return a
-numeric constant giving the number of parameters received, that is, if
-<code><nobr>%0</nobr></code> is n then <code><nobr>%</nobr></code>n is the
-last parameter. <code><nobr>%0</nobr></code> is mostly useful for macros
-that can take a variable number of parameters. It can be used as an
-argument to <code><nobr>%rep</nobr></code> (see
-<a href="#section-4.5">section 4.5</a>) in order to iterate through all the
-parameters of a macro. Examples are given in
-<a href="#section-4.3.7">section 4.3.7</a>.
-<h4><a name="section-4.3.7">4.3.7 <code><nobr>%rotate</nobr></code>: Rotating Macro Parameters</a></h4>
-<p>Unix shell programmers will be familiar with the
-<code><nobr>shift</nobr></code> shell command, which allows the arguments
-passed to a shell script (referenced as <code><nobr>$1</nobr></code>,
-<code><nobr>$2</nobr></code> and so on) to be moved left by one place, so
-that the argument previously referenced as <code><nobr>$2</nobr></code>
-becomes available as <code><nobr>$1</nobr></code>, and the argument
-previously referenced as <code><nobr>$1</nobr></code> is no longer
-available at all.
-<p>NASM provides a similar mechanism, in the form of
-<code><nobr>%rotate</nobr></code>. As its name suggests, it differs from
-the Unix <code><nobr>shift</nobr></code> in that no parameters are lost:
-parameters rotated off the left end of the argument list reappear on the
-right, and vice versa.
-<p><code><nobr>%rotate</nobr></code> is invoked with a single numeric
-argument (which may be an expression). The macro parameters are rotated to
-the left by that many places. If the argument to
-<code><nobr>%rotate</nobr></code> is negative, the macro parameters are
-rotated to the right.
-<p>So a pair of macros to save and restore a set of registers might work as
-follows:
-<p><pre>
-%macro multipush 1-*
-
- %rep %0
- push %1
- %rotate 1
- %endrep
-
-%endmacro
-</pre>
-<p>This macro invokes the <code><nobr>PUSH</nobr></code> instruction on
-each of its arguments in turn, from left to right. It begins by pushing its
-first argument, <code><nobr>%1</nobr></code>, then invokes
-<code><nobr>%rotate</nobr></code> to move all the arguments one place to
-the left, so that the original second argument is now available as
-<code><nobr>%1</nobr></code>. Repeating this procedure as many times as
-there were arguments (achieved by supplying <code><nobr>%0</nobr></code> as
-the argument to <code><nobr>%rep</nobr></code>) causes each argument in
-turn to be pushed.
-<p>Note also the use of <code><nobr>*</nobr></code> as the maximum
-parameter count, indicating that there is no upper limit on the number of
-parameters you may supply to the <code><nobr>multipush</nobr></code> macro.
-<p>It would be convenient, when using this macro, to have a
-<code><nobr>POP</nobr></code> equivalent, which <em>didn't</em> require the
-arguments to be given in reverse order. Ideally, you would write the
-<code><nobr>multipush</nobr></code> macro call, then cut-and-paste the line
-to where the pop needed to be done, and change the name of the called macro
-to <code><nobr>multipop</nobr></code>, and the macro would take care of
-popping the registers in the opposite order from the one in which they were
-pushed.
-<p>This can be done by the following definition:
-<p><pre>
-%macro multipop 1-*
-
- %rep %0
- %rotate -1
- pop %1
- %endrep
-
-%endmacro
-</pre>
-<p>This macro begins by rotating its arguments one place to the
-<em>right</em>, so that the original <em>last</em> argument appears as
-<code><nobr>%1</nobr></code>. This is then popped, and the arguments are
-rotated right again, so the second-to-last argument becomes
-<code><nobr>%1</nobr></code>. Thus the arguments are iterated through in
-reverse order.
-<h4><a name="section-4.3.8">4.3.8 Concatenating Macro Parameters</a></h4>
-<p>NASM can concatenate macro parameters and macro indirection constructs
-on to other text surrounding them. This allows you to declare a family of
-symbols, for example, in a macro definition. If, for example, you wanted to
-generate a table of key codes along with offsets into the table, you could
-code something like
-<p><pre>
-%macro keytab_entry 2
-
- keypos%1 equ $-keytab
- db %2
-
-%endmacro
-
-keytab:
- keytab_entry F1,128+1
- keytab_entry F2,128+2
- keytab_entry Return,13
-</pre>
-<p>which would expand to
-<p><pre>
-keytab:
-keyposF1 equ $-keytab
- db 128+1
-keyposF2 equ $-keytab
- db 128+2
-keyposReturn equ $-keytab
- db 13
-</pre>
-<p>You can just as easily concatenate text on to the other end of a macro
-parameter, by writing <code><nobr>%1foo</nobr></code>.
-<p>If you need to append a <em>digit</em> to a macro parameter, for example
-defining labels <code><nobr>foo1</nobr></code> and
-<code><nobr>foo2</nobr></code> when passed the parameter
-<code><nobr>foo</nobr></code>, you can't code <code><nobr>%11</nobr></code>
-because that would be taken as the eleventh macro parameter. Instead, you
-must code <code><nobr>%{1}1</nobr></code>, which will separate the first
-<code><nobr>1</nobr></code> (giving the number of the macro parameter) from
-the second (literal text to be concatenated to the parameter).
-<p>This concatenation can also be applied to other preprocessor in-line
-objects, such as macro-local labels (<a href="#section-4.3.3">section
-4.3.3</a>) and context-local labels (<a href="#section-4.7.2">section
-4.7.2</a>). In all cases, ambiguities in syntax can be resolved by
-enclosing everything after the <code><nobr>%</nobr></code> sign and before
-the literal text in braces: so <code><nobr>%{%foo}bar</nobr></code>
-concatenates the text <code><nobr>bar</nobr></code> to the end of the real
-name of the macro-local label <code><nobr>%%foo</nobr></code>. (This is
-unnecessary, since the form NASM uses for the real names of macro-local
-labels means that the two usages <code><nobr>%{%foo}bar</nobr></code> and
-<code><nobr>%%foobar</nobr></code> would both expand to the same thing
-anyway; nevertheless, the capability is there.)
-<p>The single-line macro indirection construct,
-<code><nobr>%[...]</nobr></code> (<a href="#section-4.1.3">section
-4.1.3</a>), behaves the same way as macro parameters for the purpose of
-concatenation.
-<p>See also the <code><nobr>%+</nobr></code> operator,
-<a href="#section-4.1.4">section 4.1.4</a>.
-<h4><a name="section-4.3.9">4.3.9 Condition Codes as Macro Parameters</a></h4>
-<p>NASM can give special treatment to a macro parameter which contains a
-condition code. For a start, you can refer to the macro parameter
-<code><nobr>%1</nobr></code> by means of the alternative syntax
-<code><nobr>%+1</nobr></code>, which informs NASM that this macro parameter
-is supposed to contain a condition code, and will cause the preprocessor to
-report an error message if the macro is called with a parameter which is
-<em>not</em> a valid condition code.
-<p>Far more usefully, though, you can refer to the macro parameter by means
-of <code><nobr>%-1</nobr></code>, which NASM will expand as the
-<em>inverse</em> condition code. So the <code><nobr>retz</nobr></code>
-macro defined in <a href="#section-4.3.3">section 4.3.3</a> can be replaced
-by a general conditional-return macro like this:
-<p><pre>
-%macro retc 1
-
- j%-1 %%skip
- ret
- %%skip:
-
-%endmacro
-</pre>
-<p>This macro can now be invoked using calls like
-<code><nobr>retc ne</nobr></code>, which will cause the conditional-jump
-instruction in the macro expansion to come out as
-<code><nobr>JE</nobr></code>, or <code><nobr>retc po</nobr></code> which
-will make the jump a <code><nobr>JPE</nobr></code>.
-<p>The <code><nobr>%+1</nobr></code> macro-parameter reference is quite
-happy to interpret the arguments <code><nobr>CXZ</nobr></code> and
-<code><nobr>ECXZ</nobr></code> as valid condition codes; however,
-<code><nobr>%-1</nobr></code> will report an error if passed either of
-these, because no inverse condition code exists.
-<h4><a name="section-4.3.10">4.3.10 Disabling Listing Expansion</a></h4>
-<p>When NASM is generating a listing file from your program, it will
-generally expand multi-line macros by means of writing the macro call and
-then listing each line of the expansion. This allows you to see which
-instructions in the macro expansion are generating what code; however, for
-some macros this clutters the listing up unnecessarily.
-<p>NASM therefore provides the <code><nobr>.nolist</nobr></code> qualifier,
-which you can include in a macro definition to inhibit the expansion of the
-macro in the listing file. The <code><nobr>.nolist</nobr></code> qualifier
-comes directly after the number of parameters, like this:
-<p><pre>
-%macro foo 1.nolist
-</pre>
-<p>Or like this:
-<p><pre>
-%macro bar 1-5+.nolist a,b,c,d,e,f,g,h
-</pre>
-<h4><a name="section-4.3.11">4.3.11 Undefining Multi-Line Macros: <code><nobr>%unmacro</nobr></code></a></h4>
-<p>Multi-line macros can be removed with the
-<code><nobr>%unmacro</nobr></code> directive. Unlike the
-<code><nobr>%undef</nobr></code> directive, however,
-<code><nobr>%unmacro</nobr></code> takes an argument specification, and
-will only remove exact matches with that argument specification.
-<p>For example:
-<p><pre>
-%macro foo 1-3
- ; Do something
-%endmacro
-%unmacro foo 1-3
-</pre>
-<p>removes the previously defined macro <code><nobr>foo</nobr></code>, but
-<p><pre>
-%macro bar 1-3
- ; Do something
-%endmacro
-%unmacro bar 1
-</pre>
-<p>does <em>not</em> remove the macro <code><nobr>bar</nobr></code>, since
-the argument specification does not match exactly.
-<h4><a name="section-4.3.12">4.3.12 Exiting Multi-Line Macros: <code><nobr>%exitmacro</nobr></code></a></h4>
-<p>Multi-line macro expansions can be arbitrarily terminated with the
-<code><nobr>%exitmacro</nobr></code> directive.
-<p>For example:
-<p><pre>
-%macro foo 1-3
- ; Do something
- %if&lt;condition&gt;
- %exitmacro
- %endif
- ; Do something
-%endmacro
-</pre>
-<h3><a name="section-4.4">4.4 Conditional Assembly</a></h3>
-<p>Similarly to the C preprocessor, NASM allows sections of a source file
-to be assembled only if certain conditions are met. The general syntax of
-this feature looks like this:
-<p><pre>
-%if&lt;condition&gt;
- ; some code which only appears if &lt;condition&gt; is met
-%elif&lt;condition2&gt;
- ; only appears if &lt;condition&gt; is not met but &lt;condition2&gt; is
-%else
- ; this appears if neither &lt;condition&gt; nor &lt;condition2&gt; was met
-%endif
-</pre>
-<p>The inverse forms <code><nobr>%ifn</nobr></code> and
-<code><nobr>%elifn</nobr></code> are also supported.
-<p>The <code><nobr>%else</nobr></code> clause is optional, as is the
-<code><nobr>%elif</nobr></code> clause. You can have more than one
-<code><nobr>%elif</nobr></code> clause as well.
-<p>There are a number of variants of the <code><nobr>%if</nobr></code>
-directive. Each has its corresponding <code><nobr>%elif</nobr></code>,
-<code><nobr>%ifn</nobr></code>, and <code><nobr>%elifn</nobr></code>
-directives; for example, the equivalents to the
-<code><nobr>%ifdef</nobr></code> directive are
-<code><nobr>%elifdef</nobr></code>, <code><nobr>%ifndef</nobr></code>, and
-<code><nobr>%elifndef</nobr></code>.
-<h4><a name="section-4.4.1">4.4.1 <code><nobr>%ifdef</nobr></code>: Testing Single-Line Macro Existence</a></h4>
-<p>Beginning a conditional-assembly block with the line
-<code><nobr>%ifdef MACRO</nobr></code> will assemble the subsequent code
-if, and only if, a single-line macro called <code><nobr>MACRO</nobr></code>
-is defined. If not, then the <code><nobr>%elif</nobr></code> and
-<code><nobr>%else</nobr></code> blocks (if any) will be processed instead.
-<p>For example, when debugging a program, you might want to write code such
-as
-<p><pre>
- ; perform some function
-%ifdef DEBUG
- writefile 2,"Function performed successfully",13,10
-%endif
- ; go and do something else
-</pre>
-<p>Then you could use the command-line option
-<code><nobr>-dDEBUG</nobr></code> to create a version of the program which
-produced debugging messages, and remove the option to generate the final
-release version of the program.
-<p>You can test for a macro <em>not</em> being defined by using
-<code><nobr>%ifndef</nobr></code> instead of
-<code><nobr>%ifdef</nobr></code>. You can also test for macro definitions
-in <code><nobr>%elif</nobr></code> blocks by using
-<code><nobr>%elifdef</nobr></code> and <code><nobr>%elifndef</nobr></code>.
-<h4><a name="section-4.4.2">4.4.2 <code><nobr>%ifmacro</nobr></code>: Testing Multi-Line Macro Existence</a></h4>
-<p>The <code><nobr>%ifmacro</nobr></code> directive operates in the same
-way as the <code><nobr>%ifdef</nobr></code> directive, except that it
-checks for the existence of a multi-line macro.
-<p>For example, you may be working with a large project and not have
-control over the macros in a library. You may want to create a macro with
-one name if it doesn't already exist, and another name if one with that
-name does exist.
-<p>The <code><nobr>%ifmacro</nobr></code> is considered true if defining a
-macro with the given name and number of arguments would cause a definitions
-conflict. For example:
-<p><pre>
-%ifmacro MyMacro 1-3
-
- %error "MyMacro 1-3" causes a conflict with an existing macro.
-
-%else
-
- %macro MyMacro 1-3
-
- ; insert code to define the macro
-
- %endmacro
-
-%endif
-</pre>
-<p>This will create the macro "MyMacro 1-3" if no macro already exists
-which would conflict with it, and emits a warning if there would be a
-definition conflict.
-<p>You can test for the macro not existing by using the
-<code><nobr>%ifnmacro</nobr></code> instead of
-<code><nobr>%ifmacro</nobr></code>. Additional tests can be performed in
-<code><nobr>%elif</nobr></code> blocks by using
-<code><nobr>%elifmacro</nobr></code> and
-<code><nobr>%elifnmacro</nobr></code>.
-<h4><a name="section-4.4.3">4.4.3 <code><nobr>%ifctx</nobr></code>: Testing the Context Stack</a></h4>
-<p>The conditional-assembly construct <code><nobr>%ifctx</nobr></code> will
-cause the subsequent code to be assembled if and only if the top context on
-the preprocessor's context stack has the same name as one of the arguments.
-As with <code><nobr>%ifdef</nobr></code>, the inverse and
-<code><nobr>%elif</nobr></code> forms <code><nobr>%ifnctx</nobr></code>,
-<code><nobr>%elifctx</nobr></code> and <code><nobr>%elifnctx</nobr></code>
-are also supported.
-<p>For more details of the context stack, see
-<a href="#section-4.7">section 4.7</a>. For a sample use of
-<code><nobr>%ifctx</nobr></code>, see <a href="#section-4.7.5">section
-4.7.5</a>.
-<h4><a name="section-4.4.4">4.4.4 <code><nobr>%if</nobr></code>: Testing Arbitrary Numeric Expressions</a></h4>
-<p>The conditional-assembly construct <code><nobr>%if expr</nobr></code>
-will cause the subsequent code to be assembled if and only if the value of
-the numeric expression <code><nobr>expr</nobr></code> is non-zero. An
-example of the use of this feature is in deciding when to break out of a
-<code><nobr>%rep</nobr></code> preprocessor loop: see
-<a href="#section-4.5">section 4.5</a> for a detailed example.
-<p>The expression given to <code><nobr>%if</nobr></code>, and its
-counterpart <code><nobr>%elif</nobr></code>, is a critical expression (see
-<a href="nasmdoc3.html#section-3.8">section 3.8</a>).
-<p><code><nobr>%if</nobr></code> extends the normal NASM expression syntax,
-by providing a set of relational operators which are not normally available
-in expressions. The operators <code><nobr>=</nobr></code>,
-<code><nobr>&lt;</nobr></code>, <code><nobr>&gt;</nobr></code>,
-<code><nobr>&lt;=</nobr></code>, <code><nobr>&gt;=</nobr></code> and
-<code><nobr>&lt;&gt;</nobr></code> test equality, less-than, greater-than,
-less-or-equal, greater-or-equal and not-equal respectively. The C-like
-forms <code><nobr>==</nobr></code> and <code><nobr>!=</nobr></code> are
-supported as alternative forms of <code><nobr>=</nobr></code> and
-<code><nobr>&lt;&gt;</nobr></code>. In addition, low-priority logical
-operators <code><nobr>&amp;&amp;</nobr></code>,
-<code><nobr>^^</nobr></code> and <code><nobr>||</nobr></code> are provided,
-supplying logical AND, logical XOR and logical OR. These work like the C
-logical operators (although C has no logical XOR), in that they always
-return either 0 or 1, and treat any non-zero input as 1 (so that
-<code><nobr>^^</nobr></code>, for example, returns 1 if exactly one of its
-inputs is zero, and 0 otherwise). The relational operators also return 1
-for true and 0 for false.
-<p>Like other <code><nobr>%if</nobr></code> constructs,
-<code><nobr>%if</nobr></code> has a counterpart
-<code><nobr>%elif</nobr></code>, and negative forms
-<code><nobr>%ifn</nobr></code> and <code><nobr>%elifn</nobr></code>.
-<h4><a name="section-4.4.5">4.4.5 <code><nobr>%ifidn</nobr></code> and <code><nobr>%ifidni</nobr></code>: Testing Exact Text Identity</a></h4>
-<p>The construct <code><nobr>%ifidn text1,text2</nobr></code> will cause
-the subsequent code to be assembled if and only if
-<code><nobr>text1</nobr></code> and <code><nobr>text2</nobr></code>, after
-expanding single-line macros, are identical pieces of text. Differences in
-white space are not counted.
-<p><code><nobr>%ifidni</nobr></code> is similar to
-<code><nobr>%ifidn</nobr></code>, but is case-insensitive.
-<p>For example, the following macro pushes a register or number on the
-stack, and allows you to treat <code><nobr>IP</nobr></code> as a real
-register:
-<p><pre>
-%macro pushparam 1
-
- %ifidni %1,ip
- call %%label
- %%label:
- %else
- push %1
- %endif
-
-%endmacro
-</pre>
-<p>Like other <code><nobr>%if</nobr></code> constructs,
-<code><nobr>%ifidn</nobr></code> has a counterpart
-<code><nobr>%elifidn</nobr></code>, and negative forms
-<code><nobr>%ifnidn</nobr></code> and <code><nobr>%elifnidn</nobr></code>.
-Similarly, <code><nobr>%ifidni</nobr></code> has counterparts
-<code><nobr>%elifidni</nobr></code>, <code><nobr>%ifnidni</nobr></code> and
-<code><nobr>%elifnidni</nobr></code>.
-<h4><a name="section-4.4.6">4.4.6 <code><nobr>%ifid</nobr></code>, <code><nobr>%ifnum</nobr></code>, <code><nobr>%ifstr</nobr></code>: Testing Token Types</a></h4>
-<p>Some macros will want to perform different tasks depending on whether
-they are passed a number, a string, or an identifier. For example, a string
-output macro might want to be able to cope with being passed either a
-string constant or a pointer to an existing string.
-<p>The conditional assembly construct <code><nobr>%ifid</nobr></code>,
-taking one parameter (which may be blank), assembles the subsequent code if
-and only if the first token in the parameter exists and is an identifier.
-<code><nobr>%ifnum</nobr></code> works similarly, but tests for the token
-being a numeric constant; <code><nobr>%ifstr</nobr></code> tests for it
-being a string.
-<p>For example, the <code><nobr>writefile</nobr></code> macro defined in
-<a href="#section-4.3.4">section 4.3.4</a> can be extended to take
-advantage of <code><nobr>%ifstr</nobr></code> in the following fashion:
-<p><pre>
-%macro writefile 2-3+
-
- %ifstr %2
- jmp %%endstr
- %if %0 = 3
- %%str: db %2,%3
- %else
- %%str: db %2
- %endif
- %%endstr: mov dx,%%str
- mov cx,%%endstr-%%str
- %else
- mov dx,%2
- mov cx,%3
- %endif
- mov bx,%1
- mov ah,0x40
- int 0x21
-
-%endmacro
-</pre>
-<p>Then the <code><nobr>writefile</nobr></code> macro can cope with being
-called in either of the following two ways:
-<p><pre>
- writefile [file], strpointer, length
- writefile [file], "hello", 13, 10
-</pre>
-<p>In the first, <code><nobr>strpointer</nobr></code> is used as the
-address of an already-declared string, and <code><nobr>length</nobr></code>
-is used as its length; in the second, a string is given to the macro, which
-therefore declares it itself and works out the address and length for
-itself.
-<p>Note the use of <code><nobr>%if</nobr></code> inside the
-<code><nobr>%ifstr</nobr></code>: this is to detect whether the macro was
-passed two arguments (so the string would be a single string constant, and
-<code><nobr>db %2</nobr></code> would be adequate) or more (in which case,
-all but the first two would be lumped together into
-<code><nobr>%3</nobr></code>, and <code><nobr>db %2,%3</nobr></code> would
-be required).
-<p>The usual <code><nobr>%elif</nobr></code>...,
-<code><nobr>%ifn</nobr></code>..., and <code><nobr>%elifn</nobr></code>...
-versions exist for each of <code><nobr>%ifid</nobr></code>,
-<code><nobr>%ifnum</nobr></code> and <code><nobr>%ifstr</nobr></code>.
-<h4><a name="section-4.4.7">4.4.7 <code><nobr>%iftoken</nobr></code>: Test for a Single Token</a></h4>
-<p>Some macros will want to do different things depending on if it is
-passed a single token (e.g. paste it to something else using
-<code><nobr>%+</nobr></code>) versus a multi-token sequence.
-<p>The conditional assembly construct <code><nobr>%iftoken</nobr></code>
-assembles the subsequent code if and only if the expanded parameters
-consist of exactly one token, possibly surrounded by whitespace.
-<p>For example:
-<p><pre>
-%iftoken 1
-</pre>
-<p>will assemble the subsequent code, but
-<p><pre>
-%iftoken -1
-</pre>
-<p>will not, since <code><nobr>-1</nobr></code> contains two tokens: the
-unary minus operator <code><nobr>-</nobr></code>, and the number
-<code><nobr>1</nobr></code>.
-<p>The usual <code><nobr>%eliftoken</nobr></code>,
-<code><nobr>%ifntoken</nobr></code>, and
-<code><nobr>%elifntoken</nobr></code> variants are also provided.
-<h4><a name="section-4.4.8">4.4.8 <code><nobr>%ifempty</nobr></code>: Test for Empty Expansion</a></h4>
-<p>The conditional assembly construct <code><nobr>%ifempty</nobr></code>
-assembles the subsequent code if and only if the expanded parameters do not
-contain any tokens at all, whitespace excepted.
-<p>The usual <code><nobr>%elifempty</nobr></code>,
-<code><nobr>%ifnempty</nobr></code>, and
-<code><nobr>%elifnempty</nobr></code> variants are also provided.
-<h3><a name="section-4.5">4.5 Preprocessor Loops: <code><nobr>%rep</nobr></code></a></h3>
-<p>NASM's <code><nobr>TIMES</nobr></code> prefix, though useful, cannot be
-used to invoke a multi-line macro multiple times, because it is processed
-by NASM after macros have already been expanded. Therefore NASM provides
-another form of loop, this time at the preprocessor level:
-<code><nobr>%rep</nobr></code>.
-<p>The directives <code><nobr>%rep</nobr></code> and
-<code><nobr>%endrep</nobr></code> (<code><nobr>%rep</nobr></code> takes a
-numeric argument, which can be an expression;
-<code><nobr>%endrep</nobr></code> takes no arguments) can be used to
-enclose a chunk of code, which is then replicated as many times as
-specified by the preprocessor:
-<p><pre>
-%assign i 0
-%rep 64
- inc word [table+2*i]
-%assign i i+1
-%endrep
-</pre>
-<p>This will generate a sequence of 64 <code><nobr>INC</nobr></code>
-instructions, incrementing every word of memory from
-<code><nobr>[table]</nobr></code> to <code><nobr>[table+126]</nobr></code>.
-<p>For more complex termination conditions, or to break out of a repeat
-loop part way along, you can use the <code><nobr>%exitrep</nobr></code>
-directive to terminate the loop, like this:
-<p><pre>
-fibonacci:
-%assign i 0
-%assign j 1
-%rep 100
-%if j &gt; 65535
- %exitrep
-%endif
- dw j
-%assign k j+i
-%assign i j
-%assign j k
-%endrep
-
-fib_number equ ($-fibonacci)/2
-</pre>
-<p>This produces a list of all the Fibonacci numbers that will fit in 16
-bits. Note that a maximum repeat count must still be given to
-<code><nobr>%rep</nobr></code>. This is to prevent the possibility of NASM
-getting into an infinite loop in the preprocessor, which (on multitasking
-or multi-user systems) would typically cause all the system memory to be
-gradually used up and other applications to start crashing.
-<h3><a name="section-4.6">4.6 Source Files and Dependencies</a></h3>
-<p>These commands allow you to split your sources into multiple files.
-<h4><a name="section-4.6.1">4.6.1 <code><nobr>%include</nobr></code>: Including Other Files</a></h4>
-<p>Using, once again, a very similar syntax to the C preprocessor, NASM's
-preprocessor lets you include other source files into your code. This is
-done by the use of the <code><nobr>%include</nobr></code> directive:
-<p><pre>
-%include "macros.mac"
-</pre>
-<p>will include the contents of the file
-<code><nobr>macros.mac</nobr></code> into the source file containing the
-<code><nobr>%include</nobr></code> directive.
-<p>Include files are searched for in the current directory (the directory
-you're in when you run NASM, as opposed to the location of the NASM
-executable or the location of the source file), plus any directories
-specified on the NASM command line using the <code><nobr>-i</nobr></code>
-option.
-<p>The standard C idiom for preventing a file being included more than once
-is just as applicable in NASM: if the file
-<code><nobr>macros.mac</nobr></code> has the form
-<p><pre>
-%ifndef MACROS_MAC
- %define MACROS_MAC
- ; now define some macros
-%endif
-</pre>
-<p>then including the file more than once will not cause errors, because
-the second time the file is included nothing will happen because the macro
-<code><nobr>MACROS_MAC</nobr></code> will already be defined.
-<p>You can force a file to be included even if there is no
-<code><nobr>%include</nobr></code> directive that explicitly includes it,
-by using the <code><nobr>-p</nobr></code> option on the NASM command line
-(see <a href="nasmdoc2.html#section-2.1.17">section 2.1.17</a>).
-<h4><a name="section-4.6.2">4.6.2 <code><nobr>%pathsearch</nobr></code>: Search the Include Path</a></h4>
-<p>The <code><nobr>%pathsearch</nobr></code> directive takes a single-line
-macro name and a filename, and declare or redefines the specified
-single-line macro to be the include-path-resolved version of the filename,
-if the file exists (otherwise, it is passed unchanged.)
-<p>For example,
-<p><pre>
-%pathsearch MyFoo "foo.bin"
-</pre>
-<p>... with <code><nobr>-Ibins/</nobr></code> in the include path may end
-up defining the macro <code><nobr>MyFoo</nobr></code> to be
-<code><nobr>"bins/foo.bin"</nobr></code>.
-<h4><a name="section-4.6.3">4.6.3 <code><nobr>%depend</nobr></code>: Add Dependent Files</a></h4>
-<p>The <code><nobr>%depend</nobr></code> directive takes a filename and
-adds it to the list of files to be emitted as dependency generation when
-the <code><nobr>-M</nobr></code> options and its relatives (see
-<a href="nasmdoc2.html#section-2.1.4">section 2.1.4</a>) are used. It
-produces no output.
-<p>This is generally used in conjunction with
-<code><nobr>%pathsearch</nobr></code>. For example, a simplified version of
-the standard macro wrapper for the <code><nobr>INCBIN</nobr></code>
-directive looks like:
-<p><pre>
-%imacro incbin 1-2+ 0
-%pathsearch dep %1
-%depend dep
- incbin dep,%2
-%endmacro
-</pre>
-<p>This first resolves the location of the file into the macro
-<code><nobr>dep</nobr></code>, then adds it to the dependency lists, and
-finally issues the assembler-level <code><nobr>INCBIN</nobr></code>
-directive.
-<h4><a name="section-4.6.4">4.6.4 <code><nobr>%use</nobr></code>: Include Standard Macro Package</a></h4>
-<p>The <code><nobr>%use</nobr></code> directive is similar to
-<code><nobr>%include</nobr></code>, but rather than including the contents
-of a file, it includes a named standard macro package. The standard macro
-packages are part of NASM, and are described in
-<a href="nasmdoc5.html">chapter 5</a>.
-<p>Unlike the <code><nobr>%include</nobr></code> directive, package names
-for the <code><nobr>%use</nobr></code> directive do not require quotes, but
-quotes are permitted. In NASM 2.04 and 2.05 the unquoted form would be
-macro-expanded; this is no longer true. Thus, the following lines are
-equivalent:
-<p><pre>
-%use altreg
-%use 'altreg'
-</pre>
-<p>Standard macro packages are protected from multiple inclusion. When a
-standard macro package is used, a testable single-line macro of the form
-<code><nobr>__USE_</nobr></code><em>package</em><code><nobr>__</nobr></code>
-is also defined, see <a href="#section-4.11.8">section 4.11.8</a>.
-<h3><a name="section-4.7">4.7 The Context Stack</a></h3>
-<p>Having labels that are local to a macro definition is sometimes not
-quite powerful enough: sometimes you want to be able to share labels
-between several macro calls. An example might be a
-<code><nobr>REPEAT</nobr></code> ... <code><nobr>UNTIL</nobr></code> loop,
-in which the expansion of the <code><nobr>REPEAT</nobr></code> macro would
-need to be able to refer to a label which the
-<code><nobr>UNTIL</nobr></code> macro had defined. However, for such a
-macro you would also want to be able to nest these loops.
-<p>NASM provides this level of power by means of a <em>context stack</em>.
-The preprocessor maintains a stack of <em>contexts</em>, each of which is
-characterized by a name. You add a new context to the stack using the
-<code><nobr>%push</nobr></code> directive, and remove one using
-<code><nobr>%pop</nobr></code>. You can define labels that are local to a
-particular context on the stack.
-<h4><a name="section-4.7.1">4.7.1 <code><nobr>%push</nobr></code> and <code><nobr>%pop</nobr></code>: Creating and Removing Contexts</a></h4>
-<p>The <code><nobr>%push</nobr></code> directive is used to create a new
-context and place it on the top of the context stack.
-<code><nobr>%push</nobr></code> takes an optional argument, which is the
-name of the context. For example:
-<p><pre>
-%push foobar
-</pre>
-<p>This pushes a new context called <code><nobr>foobar</nobr></code> on the
-stack. You can have several contexts on the stack with the same name: they
-can still be distinguished. If no name is given, the context is unnamed
-(this is normally used when both the <code><nobr>%push</nobr></code> and
-the <code><nobr>%pop</nobr></code> are inside a single macro definition.)
-<p>The directive <code><nobr>%pop</nobr></code>, taking one optional
-argument, removes the top context from the context stack and destroys it,
-along with any labels associated with it. If an argument is given, it must
-match the name of the current context, otherwise it will issue an error.
-<h4><a name="section-4.7.2">4.7.2 Context-Local Labels</a></h4>
-<p>Just as the usage <code><nobr>%%foo</nobr></code> defines a label which
-is local to the particular macro call in which it is used, the usage
-<code><nobr>%$foo</nobr></code> is used to define a label which is local to
-the context on the top of the context stack. So the
-<code><nobr>REPEAT</nobr></code> and <code><nobr>UNTIL</nobr></code>
-example given above could be implemented by means of:
-<p><pre>
-%macro repeat 0
-
- %push repeat
- %$begin:
-
-%endmacro
-
-%macro until 1
-
- j%-1 %$begin
- %pop
-
-%endmacro
-</pre>
-<p>and invoked by means of, for example,
-<p><pre>
- mov cx,string
- repeat
- add cx,3
- scasb
- until e
-</pre>
-<p>which would scan every fourth byte of a string in search of the byte in
-<code><nobr>AL</nobr></code>.
-<p>If you need to define, or access, labels local to the context
-<em>below</em> the top one on the stack, you can use
-<code><nobr>%$$foo</nobr></code>, or <code><nobr>%$$$foo</nobr></code> for
-the context below that, and so on.
-<h4><a name="section-4.7.3">4.7.3 Context-Local Single-Line Macros</a></h4>
-<p>NASM also allows you to define single-line macros which are local to a
-particular context, in just the same way:
-<p><pre>
-%define %$localmac 3
-</pre>
-<p>will define the single-line macro <code><nobr>%$localmac</nobr></code>
-to be local to the top context on the stack. Of course, after a subsequent
-<code><nobr>%push</nobr></code>, it can then still be accessed by the name
-<code><nobr>%$$localmac</nobr></code>.
-<h4><a name="section-4.7.4">4.7.4 <code><nobr>%repl</nobr></code>: Renaming a Context</a></h4>
-<p>If you need to change the name of the top context on the stack (in
-order, for example, to have it respond differently to
-<code><nobr>%ifctx</nobr></code>), you can execute a
-<code><nobr>%pop</nobr></code> followed by a
-<code><nobr>%push</nobr></code>; but this will have the side effect of
-destroying all context-local labels and macros associated with the context
-that was just popped.
-<p>NASM provides the directive <code><nobr>%repl</nobr></code>, which
-<em>replaces</em> a context with a different name, without touching the
-associated macros and labels. So you could replace the destructive code
-<p><pre>
-%pop
-%push newname
-</pre>
-<p>with the non-destructive version
-<code><nobr>%repl newname</nobr></code>.
-<h4><a name="section-4.7.5">4.7.5 Example Use of the Context Stack: Block IFs</a></h4>
-<p>This example makes use of almost all the context-stack features,
-including the conditional-assembly construct
-<code><nobr>%ifctx</nobr></code>, to implement a block IF statement as a
-set of macros.
-<p><pre>
-%macro if 1
-
- %push if
- j%-1 %$ifnot
-
-%endmacro
-
-%macro else 0
-
- %ifctx if
- %repl else
- jmp %$ifend
- %$ifnot:
- %else
- %error "expected `if' before `else'"
- %endif
-
-%endmacro
-
-%macro endif 0
-
- %ifctx if
- %$ifnot:
- %pop
- %elifctx else
- %$ifend:
- %pop
- %else
- %error "expected `if' or `else' before `endif'"
- %endif
-
-%endmacro
-</pre>
-<p>This code is more robust than the <code><nobr>REPEAT</nobr></code> and
-<code><nobr>UNTIL</nobr></code> macros given in
-<a href="#section-4.7.2">section 4.7.2</a>, because it uses conditional
-assembly to check that the macros are issued in the right order (for
-example, not calling <code><nobr>endif</nobr></code> before
-<code><nobr>if</nobr></code>) and issues a <code><nobr>%error</nobr></code>
-if they're not.
-<p>In addition, the <code><nobr>endif</nobr></code> macro has to be able to
-cope with the two distinct cases of either directly following an
-<code><nobr>if</nobr></code>, or following an
-<code><nobr>else</nobr></code>. It achieves this, again, by using
-conditional assembly to do different things depending on whether the
-context on top of the stack is <code><nobr>if</nobr></code> or
-<code><nobr>else</nobr></code>.
-<p>The <code><nobr>else</nobr></code> macro has to preserve the context on
-the stack, in order to have the <code><nobr>%$ifnot</nobr></code> referred
-to by the <code><nobr>if</nobr></code> macro be the same as the one defined
-by the <code><nobr>endif</nobr></code> macro, but has to change the
-context's name so that <code><nobr>endif</nobr></code> will know there was
-an intervening <code><nobr>else</nobr></code>. It does this by the use of
-<code><nobr>%repl</nobr></code>.
-<p>A sample usage of these macros might look like:
-<p><pre>
- cmp ax,bx
-
- if ae
- cmp bx,cx
-
- if ae
- mov ax,cx
- else
- mov ax,bx
- endif
-
- else
- cmp ax,cx
-
- if ae
- mov ax,cx
- endif
-
- endif
-</pre>
-<p>The block-<code><nobr>IF</nobr></code> macros handle nesting quite
-happily, by means of pushing another context, describing the inner
-<code><nobr>if</nobr></code>, on top of the one describing the outer
-<code><nobr>if</nobr></code>; thus <code><nobr>else</nobr></code> and
-<code><nobr>endif</nobr></code> always refer to the last unmatched
-<code><nobr>if</nobr></code> or <code><nobr>else</nobr></code>.
-<h3><a name="section-4.8">4.8 Stack Relative Preprocessor Directives</a></h3>
-<p>The following preprocessor directives provide a way to use labels to
-refer to local variables allocated on the stack.
-<ul>
-<li><code><nobr>%arg</nobr></code> (see <a href="#section-4.8.1">section
-4.8.1</a>)
-<li><code><nobr>%stacksize</nobr></code> (see
-<a href="#section-4.8.2">section 4.8.2</a>)
-<li><code><nobr>%local</nobr></code> (see <a href="#section-4.8.3">section
-4.8.3</a>)
-</ul>
-<h4><a name="section-4.8.1">4.8.1 <code><nobr>%arg</nobr></code> Directive</a></h4>
-<p>The <code><nobr>%arg</nobr></code> directive is used to simplify the
-handling of parameters passed on the stack. Stack based parameter passing
-is used by many high level languages, including C, C++ and Pascal.
-<p>While NASM has macros which attempt to duplicate this functionality (see
-<a href="nasmdoc8.html#section-8.4.5">section 8.4.5</a>), the syntax is not
-particularly convenient to use. and is not TASM compatible. Here is an
-example which shows the use of <code><nobr>%arg</nobr></code> without any
-external macros:
-<p><pre>
-some_function:
-
- %push mycontext ; save the current context
- %stacksize large ; tell NASM to use bp
- %arg i:word, j_ptr:word
-
- mov ax,[i]
- mov bx,[j_ptr]
- add ax,[bx]
- ret
-
- %pop ; restore original context
-</pre>
-<p>This is similar to the procedure defined in
-<a href="nasmdoc8.html#section-8.4.5">section 8.4.5</a> and adds the value
-in i to the value pointed to by j_ptr and returns the sum in the ax
-register. See <a href="#section-4.7.1">section 4.7.1</a> for an explanation
-of <code><nobr>push</nobr></code> and <code><nobr>pop</nobr></code> and the
-use of context stacks.
-<h4><a name="section-4.8.2">4.8.2 <code><nobr>%stacksize</nobr></code> Directive</a></h4>
-<p>The <code><nobr>%stacksize</nobr></code> directive is used in
-conjunction with the <code><nobr>%arg</nobr></code> (see
-<a href="#section-4.8.1">section 4.8.1</a>) and the
-<code><nobr>%local</nobr></code> (see <a href="#section-4.8.3">section
-4.8.3</a>) directives. It tells NASM the default size to use for subsequent
-<code><nobr>%arg</nobr></code> and <code><nobr>%local</nobr></code>
-directives. The <code><nobr>%stacksize</nobr></code> directive takes one
-required argument which is one of <code><nobr>flat</nobr></code>,
-<code><nobr>flat64</nobr></code>, <code><nobr>large</nobr></code> or
-<code><nobr>small</nobr></code>.
-<p><pre>
-%stacksize flat
-</pre>
-<p>This form causes NASM to use stack-based parameter addressing relative
-to <code><nobr>ebp</nobr></code> and it assumes that a near form of call
-was used to get to this label (i.e. that <code><nobr>eip</nobr></code> is
-on the stack).
-<p><pre>
-%stacksize flat64
-</pre>
-<p>This form causes NASM to use stack-based parameter addressing relative
-to <code><nobr>rbp</nobr></code> and it assumes that a near form of call
-was used to get to this label (i.e. that <code><nobr>rip</nobr></code> is
-on the stack).
-<p><pre>
-%stacksize large
-</pre>
-<p>This form uses <code><nobr>bp</nobr></code> to do stack-based parameter
-addressing and assumes that a far form of call was used to get to this
-address (i.e. that <code><nobr>ip</nobr></code> and
-<code><nobr>cs</nobr></code> are on the stack).
-<p><pre>
-%stacksize small
-</pre>
-<p>This form also uses <code><nobr>bp</nobr></code> to address stack
-parameters, but it is different from <code><nobr>large</nobr></code>
-because it also assumes that the old value of bp is pushed onto the stack
-(i.e. it expects an <code><nobr>ENTER</nobr></code> instruction). In other
-words, it expects that <code><nobr>bp</nobr></code>,
-<code><nobr>ip</nobr></code> and <code><nobr>cs</nobr></code> are on the
-top of the stack, underneath any local space which may have been allocated
-by <code><nobr>ENTER</nobr></code>. This form is probably most useful when
-used in combination with the <code><nobr>%local</nobr></code> directive
-(see <a href="#section-4.8.3">section 4.8.3</a>).
-<h4><a name="section-4.8.3">4.8.3 <code><nobr>%local</nobr></code> Directive</a></h4>
-<p>The <code><nobr>%local</nobr></code> directive is used to simplify the
-use of local temporary stack variables allocated in a stack frame.
-Automatic local variables in C are an example of this kind of variable. The
-<code><nobr>%local</nobr></code> directive is most useful when used with
-the <code><nobr>%stacksize</nobr></code> (see
-<a href="#section-4.8.2">section 4.8.2</a> and is also compatible with the
-<code><nobr>%arg</nobr></code> directive (see
-<a href="#section-4.8.1">section 4.8.1</a>). It allows simplified reference
-to variables on the stack which have been allocated typically by using the
-<code><nobr>ENTER</nobr></code> instruction. An example of its use is the
-following:
-<p><pre>
-silly_swap:
-
- %push mycontext ; save the current context
- %stacksize small ; tell NASM to use bp
- %assign %$localsize 0 ; see text for explanation
- %local old_ax:word, old_dx:word
-
- enter %$localsize,0 ; see text for explanation
- mov [old_ax],ax ; swap ax &amp; bx
- mov [old_dx],dx ; and swap dx &amp; cx
- mov ax,bx
- mov dx,cx
- mov bx,[old_ax]
- mov cx,[old_dx]
- leave ; restore old bp
- ret ;
-
- %pop ; restore original context
-</pre>
-<p>The <code><nobr>%$localsize</nobr></code> variable is used internally by
-the <code><nobr>%local</nobr></code> directive and <em>must</em> be defined
-within the current context before the <code><nobr>%local</nobr></code>
-directive may be used. Failure to do so will result in one expression
-syntax error for each <code><nobr>%local</nobr></code> variable declared.
-It then may be used in the construction of an appropriately sized ENTER
-instruction as shown in the example.
-<h3><a name="section-4.9">4.9 Reporting User-Defined Errors: <code><nobr>%error</nobr></code>, <code><nobr>%warning</nobr></code>, <code><nobr>%fatal</nobr></code></a></h3>
-<p>The preprocessor directive <code><nobr>%error</nobr></code> will cause
-NASM to report an error if it occurs in assembled code. So if other users
-are going to try to assemble your source files, you can ensure that they
-define the right macros by means of code like this:
-<p><pre>
-%ifdef F1
- ; do some setup
-%elifdef F2
- ; do some different setup
-%else
- %error "Neither F1 nor F2 was defined."
-%endif
-</pre>
-<p>Then any user who fails to understand the way your code is supposed to
-be assembled will be quickly warned of their mistake, rather than having to
-wait until the program crashes on being run and then not knowing what went
-wrong.
-<p>Similarly, <code><nobr>%warning</nobr></code> issues a warning, but
-allows assembly to continue:
-<p><pre>
-%ifdef F1
- ; do some setup
-%elifdef F2
- ; do some different setup
-%else
- %warning "Neither F1 nor F2 was defined, assuming F1."
- %define F1
-%endif
-</pre>
-<p><code><nobr>%error</nobr></code> and <code><nobr>%warning</nobr></code>
-are issued only on the final assembly pass. This makes them safe to use in
-conjunction with tests that depend on symbol values.
-<p><code><nobr>%fatal</nobr></code> terminates assembly immediately,
-regardless of pass. This is useful when there is no point in continuing the
-assembly further, and doing so is likely just going to cause a spew of
-confusing error messages.
-<p>It is optional for the message string after
-<code><nobr>%error</nobr></code>, <code><nobr>%warning</nobr></code> or
-<code><nobr>%fatal</nobr></code> to be quoted. If it is <em>not</em>, then
-single-line macros are expanded in it, which can be used to display more
-information to the user. For example:
-<p><pre>
-%if foo &gt; 64
- %assign foo_over foo-64
- %error foo is foo_over bytes too large
-%endif
-</pre>
-<h3><a name="section-4.10">4.10 Other Preprocessor Directives</a></h3>
-<p>NASM also has preprocessor directives which allow access to information
-from external sources. Currently they include:
-<ul>
-<li><code><nobr>%line</nobr></code> enables NASM to correctly handle the
-output of another preprocessor (see <a href="#section-4.10.1">section
-4.10.1</a>).
-<li><code><nobr>%!</nobr></code> enables NASM to read in the value of an
-environment variable, which can then be used in your program (see
-<a href="#section-4.10.2">section 4.10.2</a>).
-</ul>
-<h4><a name="section-4.10.1">4.10.1 <code><nobr>%line</nobr></code> Directive</a></h4>
-<p>The <code><nobr>%line</nobr></code> directive is used to notify NASM
-that the input line corresponds to a specific line number in another file.
-Typically this other file would be an original source file, with the
-current NASM input being the output of a pre-processor. The
-<code><nobr>%line</nobr></code> directive allows NASM to output messages
-which indicate the line number of the original source file, instead of the
-file that is being read by NASM.
-<p>This preprocessor directive is not generally of use to programmers, by
-may be of interest to preprocessor authors. The usage of the
-<code><nobr>%line</nobr></code> preprocessor directive is as follows:
-<p><pre>
-%line nnn[+mmm] [filename]
-</pre>
-<p>In this directive, <code><nobr>nnn</nobr></code> identifies the line of
-the original source file which this line corresponds to.
-<code><nobr>mmm</nobr></code> is an optional parameter which specifies a
-line increment value; each line of the input file read in is considered to
-correspond to <code><nobr>mmm</nobr></code> lines of the original source
-file. Finally, <code><nobr>filename</nobr></code> is an optional parameter
-which specifies the file name of the original source file.
-<p>After reading a <code><nobr>%line</nobr></code> preprocessor directive,
-NASM will report all file name and line numbers relative to the values
-specified therein.
-<h4><a name="section-4.10.2">4.10.2 <code><nobr>%!</nobr></code><code><nobr>&lt;env&gt;</nobr></code>: Read an environment variable.</a></h4>
-<p>The <code><nobr>%!&lt;env&gt;</nobr></code> directive makes it possible
-to read the value of an environment variable at assembly time. This could,
-for example, be used to store the contents of an environment variable into
-a string, which could be used at some other point in your code.
-<p>For example, suppose that you have an environment variable
-<code><nobr>FOO</nobr></code>, and you want the contents of
-<code><nobr>FOO</nobr></code> to be embedded in your program. You could do
-that as follows:
-<p><pre>
-%defstr FOO %!FOO
-</pre>
-<p>See <a href="#section-4.1.8">section 4.1.8</a> for notes on the
-<code><nobr>%defstr</nobr></code> directive.
-<h3><a name="section-4.11">4.11 Standard Macros</a></h3>
-<p>NASM defines a set of standard macros, which are already defined when it
-starts to process any source file. If you really need a program to be
-assembled with no pre-defined macros, you can use the
-<code><nobr>%clear</nobr></code> directive to empty the preprocessor of
-everything but context-local preprocessor variables and single-line macros.
-<p>Most user-level assembler directives (see
-<a href="nasmdoc6.html">chapter 6</a>) are implemented as macros which
-invoke primitive directives; these are described in
-<a href="nasmdoc6.html">chapter 6</a>. The rest of the standard macro set
-is described here.
-<h4><a name="section-4.11.1">4.11.1 NASM Version Macros</a></h4>
-<p>The single-line macros <code><nobr>__NASM_MAJOR__</nobr></code>,
-<code><nobr>__NASM_MINOR__</nobr></code>,
-<code><nobr>__NASM_SUBMINOR__</nobr></code> and
-<code><nobr>___NASM_PATCHLEVEL__</nobr></code> expand to the major, minor,
-subminor and patch level parts of the version number of NASM being used.
-So, under NASM 0.98.32p1 for example,
-<code><nobr>__NASM_MAJOR__</nobr></code> would be defined to be 0,
-<code><nobr>__NASM_MINOR__</nobr></code> would be defined as 98,
-<code><nobr>__NASM_SUBMINOR__</nobr></code> would be defined to 32, and
-<code><nobr>___NASM_PATCHLEVEL__</nobr></code> would be defined as 1.
-<p>Additionally, the macro <code><nobr>__NASM_SNAPSHOT__</nobr></code> is
-defined for automatically generated snapshot releases <em>only</em>.
-<h4><a name="section-4.11.2">4.11.2 <code><nobr>__NASM_VERSION_ID__</nobr></code>: NASM Version ID</a></h4>
-<p>The single-line macro <code><nobr>__NASM_VERSION_ID__</nobr></code>
-expands to a dword integer representing the full version number of the
-version of nasm being used. The value is the equivalent to
-<code><nobr>__NASM_MAJOR__</nobr></code>,
-<code><nobr>__NASM_MINOR__</nobr></code>,
-<code><nobr>__NASM_SUBMINOR__</nobr></code> and
-<code><nobr>___NASM_PATCHLEVEL__</nobr></code> concatenated to produce a
-single doubleword. Hence, for 0.98.32p1, the returned number would be
-equivalent to:
-<p><pre>
- dd 0x00622001
-</pre>
-<p>or
-<p><pre>
- db 1,32,98,0
-</pre>
-<p>Note that the above lines are generate exactly the same code, the second
-line is used just to give an indication of the order that the separate
-values will be present in memory.
-<h4><a name="section-4.11.3">4.11.3 <code><nobr>__NASM_VER__</nobr></code>: NASM Version string</a></h4>
-<p>The single-line macro <code><nobr>__NASM_VER__</nobr></code> expands to
-a string which defines the version number of nasm being used. So, under
-NASM 0.98.32 for example,
-<p><pre>
- db __NASM_VER__
-</pre>
-<p>would expand to
-<p><pre>
- db "0.98.32"
-</pre>
-<h4><a name="section-4.11.4">4.11.4 <code><nobr>__FILE__</nobr></code> and <code><nobr>__LINE__</nobr></code>: File Name and Line Number</a></h4>
-<p>Like the C preprocessor, NASM allows the user to find out the file name
-and line number containing the current instruction. The macro
-<code><nobr>__FILE__</nobr></code> expands to a string constant giving the
-name of the current input file (which may change through the course of
-assembly if <code><nobr>%include</nobr></code> directives are used), and
-<code><nobr>__LINE__</nobr></code> expands to a numeric constant giving the
-current line number in the input file.
-<p>These macros could be used, for example, to communicate debugging
-information to a macro, since invoking <code><nobr>__LINE__</nobr></code>
-inside a macro definition (either single-line or multi-line) will return
-the line number of the macro <em>call</em>, rather than
-<em>definition</em>. So to determine where in a piece of code a crash is
-occurring, for example, one could write a routine
-<code><nobr>stillhere</nobr></code>, which is passed a line number in
-<code><nobr>EAX</nobr></code> and outputs something like `line 155: still
-here'. You could then write a macro
-<p><pre>
-%macro notdeadyet 0
-
- push eax
- mov eax,__LINE__
- call stillhere
- pop eax
-
-%endmacro
-</pre>
-<p>and then pepper your code with calls to
-<code><nobr>notdeadyet</nobr></code> until you find the crash point.
-<h4><a name="section-4.11.5">4.11.5 <code><nobr>__BITS__</nobr></code>: Current BITS Mode</a></h4>
-<p>The <code><nobr>__BITS__</nobr></code> standard macro is updated every
-time that the BITS mode is set using the <code><nobr>BITS XX</nobr></code>
-or <code><nobr>[BITS XX]</nobr></code> directive, where XX is a valid mode
-number of 16, 32 or 64. <code><nobr>__BITS__</nobr></code> receives the
-specified mode number and makes it globally available. This can be very
-useful for those who utilize mode-dependent macros.
-<h4><a name="section-4.11.6">4.11.6 <code><nobr>__OUTPUT_FORMAT__</nobr></code>: Current Output Format</a></h4>
-<p>The <code><nobr>__OUTPUT_FORMAT__</nobr></code> standard macro holds the
-current Output Format, as given by the <code><nobr>-f</nobr></code> option
-or NASM's default. Type <code><nobr>nasm -hf</nobr></code> for a list.
-<p><pre>
-%ifidn __OUTPUT_FORMAT__, win32
- %define NEWLINE 13, 10
-%elifidn __OUTPUT_FORMAT__, elf32
- %define NEWLINE 10
-%endif
-</pre>
-<h4><a name="section-4.11.7">4.11.7 Assembly Date and Time Macros</a></h4>
-<p>NASM provides a variety of macros that represent the timestamp of the
-assembly session.
-<ul>
-<li>The <code><nobr>__DATE__</nobr></code> and
-<code><nobr>__TIME__</nobr></code> macros give the assembly date and time
-as strings, in ISO 8601 format (<code><nobr>"YYYY-MM-DD"</nobr></code> and
-<code><nobr>"HH:MM:SS"</nobr></code>, respectively.)
-<li>The <code><nobr>__DATE_NUM__</nobr></code> and
-<code><nobr>__TIME_NUM__</nobr></code> macros give the assembly date and
-time in numeric form; in the format <code><nobr>YYYYMMDD</nobr></code> and
-<code><nobr>HHMMSS</nobr></code> respectively.
-<li>The <code><nobr>__UTC_DATE__</nobr></code> and
-<code><nobr>__UTC_TIME__</nobr></code> macros give the assembly date and
-time in universal time (UTC) as strings, in ISO 8601 format
-(<code><nobr>"YYYY-MM-DD"</nobr></code> and
-<code><nobr>"HH:MM:SS"</nobr></code>, respectively.) If the host platform
-doesn't provide UTC time, these macros are undefined.
-<li>The <code><nobr>__UTC_DATE_NUM__</nobr></code> and
-<code><nobr>__UTC_TIME_NUM__</nobr></code> macros give the assembly date
-and time universal time (UTC) in numeric form; in the format
-<code><nobr>YYYYMMDD</nobr></code> and <code><nobr>HHMMSS</nobr></code>
-respectively. If the host platform doesn't provide UTC time, these macros
-are undefined.
-<li>The <code><nobr>__POSIX_TIME__</nobr></code> macro is defined as a
-number containing the number of seconds since the POSIX epoch, 1 January
-1970 00:00:00 UTC; excluding any leap seconds. This is computed using UTC
-time if available on the host platform, otherwise it is computed using the
-local time as if it was UTC.
-</ul>
-<p>All instances of time and date macros in the same assembly session
-produce consistent output. For example, in an assembly session started at
-42 seconds after midnight on January 1, 2010 in Moscow (timezone UTC+3)
-these macros would have the following values, assuming, of course, a
-properly configured environment with a correct clock:
-<p><pre>
- __DATE__ "2010-01-01"
- __TIME__ "00:00:42"
- __DATE_NUM__ 20100101
- __TIME_NUM__ 000042
- __UTC_DATE__ "2009-12-31"
- __UTC_TIME__ "21:00:42"
- __UTC_DATE_NUM__ 20091231
- __UTC_TIME_NUM__ 210042
- __POSIX_TIME__ 1262293242
-</pre>
-<h4><a name="section-4.11.8">4.11.8 <code><nobr>__USE_</nobr></code><em>package</em><code><nobr>__</nobr></code>: Package Include Test</a></h4>
-<p>When a standard macro package (see <a href="nasmdoc5.html">chapter
-5</a>) is included with the <code><nobr>%use</nobr></code> directive (see
-<a href="#section-4.6.4">section 4.6.4</a>), a single-line macro of the
-form
-<code><nobr>__USE_</nobr></code><em>package</em><code><nobr>__</nobr></code>
-is automatically defined. This allows testing if a particular package is
-invoked or not.
-<p>For example, if the <code><nobr>altreg</nobr></code> package is included
-(see <a href="nasmdoc5.html#section-5.1">section 5.1</a>), then the macro
-<code><nobr>__USE_ALTREG__</nobr></code> is defined.
-<h4><a name="section-4.11.9">4.11.9 <code><nobr>__PASS__</nobr></code>: Assembly Pass</a></h4>
-<p>The macro <code><nobr>__PASS__</nobr></code> is defined to be
-<code><nobr>1</nobr></code> on preparatory passes, and
-<code><nobr>2</nobr></code> on the final pass. In preprocess-only mode, it
-is set to <code><nobr>3</nobr></code>, and when running only to generate
-dependencies (due to the <code><nobr>-M</nobr></code> or
-<code><nobr>-MG</nobr></code> option, see
-<a href="nasmdoc2.html#section-2.1.4">section 2.1.4</a>) it is set to
-<code><nobr>0</nobr></code>.
-<p><em>Avoid using this macro if at all possible. It is tremendously easy
-to generate very strange errors by misusing it, and the semantics may
-change in future versions of NASM.</em>
-<h4><a name="section-4.11.10">4.11.10 <code><nobr>STRUC</nobr></code> and <code><nobr>ENDSTRUC</nobr></code>: Declaring Structure Data Types</a></h4>
-<p>The core of NASM contains no intrinsic means of defining data
-structures; instead, the preprocessor is sufficiently powerful that data
-structures can be implemented as a set of macros. The macros
-<code><nobr>STRUC</nobr></code> and <code><nobr>ENDSTRUC</nobr></code> are
-used to define a structure data type.
-<p><code><nobr>STRUC</nobr></code> takes one or two parameters. The first
-parameter is the name of the data type. The second, optional parameter is
-the base offset of the structure. The name of the data type is defined as a
-symbol with the value of the base offset, and the name of the data type
-with the suffix <code><nobr>_size</nobr></code> appended to it is defined
-as an <code><nobr>EQU</nobr></code> giving the size of the structure. Once
-<code><nobr>STRUC</nobr></code> has been issued, you are defining the
-structure, and should define fields using the
-<code><nobr>RESB</nobr></code> family of pseudo-instructions, and then
-invoke <code><nobr>ENDSTRUC</nobr></code> to finish the definition.
-<p>For example, to define a structure called
-<code><nobr>mytype</nobr></code> containing a longword, a word, a byte and
-a string of bytes, you might code
-<p><pre>
-struc mytype
-
- mt_long: resd 1
- mt_word: resw 1
- mt_byte: resb 1
- mt_str: resb 32
-
-endstruc
-</pre>
-<p>The above code defines six symbols: <code><nobr>mt_long</nobr></code> as
-0 (the offset from the beginning of a <code><nobr>mytype</nobr></code>
-structure to the longword field), <code><nobr>mt_word</nobr></code> as 4,
-<code><nobr>mt_byte</nobr></code> as 6, <code><nobr>mt_str</nobr></code> as
-7, <code><nobr>mytype_size</nobr></code> as 39, and
-<code><nobr>mytype</nobr></code> itself as zero.
-<p>The reason why the structure type name is defined at zero by default is
-a side effect of allowing structures to work with the local label
-mechanism: if your structure members tend to have the same names in more
-than one structure, you can define the above structure like this:
-<p><pre>
-struc mytype
-
- .long: resd 1
- .word: resw 1
- .byte: resb 1
- .str: resb 32
-
-endstruc
-</pre>
-<p>This defines the offsets to the structure fields as
-<code><nobr>mytype.long</nobr></code>,
-<code><nobr>mytype.word</nobr></code>,
-<code><nobr>mytype.byte</nobr></code> and
-<code><nobr>mytype.str</nobr></code>.
-<p>NASM, since it has no <em>intrinsic</em> structure support, does not
-support any form of period notation to refer to the elements of a structure
-once you have one (except the above local-label notation), so code such as
-<code><nobr>mov ax,[mystruc.mt_word]</nobr></code> is not valid.
-<code><nobr>mt_word</nobr></code> is a constant just like any other
-constant, so the correct syntax is
-<code><nobr>mov ax,[mystruc+mt_word]</nobr></code> or
-<code><nobr>mov ax,[mystruc+mytype.word]</nobr></code>.
-<p>Sometimes you only have the address of the structure displaced by an
-offset. For example, consider this standard stack frame setup:
-<p><pre>
-push ebp
-mov ebp, esp
-sub esp, 40
-</pre>
-<p>In this case, you could access an element by subtracting the offset:
-<p><pre>
-mov [ebp - 40 + mytype.word], ax
-</pre>
-<p>However, if you do not want to repeat this offset, you can use -40 as a
-base offset:
-<p><pre>
-struc mytype, -40
-</pre>
-<p>And access an element this way:
-<p><pre>
-mov [ebp + mytype.word], ax
-</pre>
-<h4><a name="section-4.11.11">4.11.11 <code><nobr>ISTRUC</nobr></code>, <code><nobr>AT</nobr></code> and <code><nobr>IEND</nobr></code>: Declaring Instances of Structures</a></h4>
-<p>Having defined a structure type, the next thing you typically want to do
-is to declare instances of that structure in your data segment. NASM
-provides an easy way to do this in the <code><nobr>ISTRUC</nobr></code>
-mechanism. To declare a structure of type <code><nobr>mytype</nobr></code>
-in a program, you code something like this:
-<p><pre>
-mystruc:
- istruc mytype
-
- at mt_long, dd 123456
- at mt_word, dw 1024
- at mt_byte, db 'x'
- at mt_str, db 'hello, world', 13, 10, 0
-
- iend
-</pre>
-<p>The function of the <code><nobr>AT</nobr></code> macro is to make use of
-the <code><nobr>TIMES</nobr></code> prefix to advance the assembly position
-to the correct point for the specified structure field, and then to declare
-the specified data. Therefore the structure fields must be declared in the
-same order as they were specified in the structure definition.
-<p>If the data to go in a structure field requires more than one source
-line to specify, the remaining source lines can easily come after the
-<code><nobr>AT</nobr></code> line. For example:
-<p><pre>
- at mt_str, db 123,134,145,156,167,178,189
- db 190,100,0
-</pre>
-<p>Depending on personal taste, you can also omit the code part of the
-<code><nobr>AT</nobr></code> line completely, and start the structure field
-on the next line:
-<p><pre>
- at mt_str
- db 'hello, world'
- db 13,10,0
-</pre>
-<h4><a name="section-4.11.12">4.11.12 <code><nobr>ALIGN</nobr></code> and <code><nobr>ALIGNB</nobr></code>: Data Alignment</a></h4>
-<p>The <code><nobr>ALIGN</nobr></code> and <code><nobr>ALIGNB</nobr></code>
-macros provides a convenient way to align code or data on a word, longword,
-paragraph or other boundary. (Some assemblers call this directive
-<code><nobr>EVEN</nobr></code>.) The syntax of the
-<code><nobr>ALIGN</nobr></code> and <code><nobr>ALIGNB</nobr></code> macros
-is
-<p><pre>
- align 4 ; align on 4-byte boundary
- align 16 ; align on 16-byte boundary
- align 8,db 0 ; pad with 0s rather than NOPs
- align 4,resb 1 ; align to 4 in the BSS
- alignb 4 ; equivalent to previous line
-</pre>
-<p>Both macros require their first argument to be a power of two; they both
-compute the number of additional bytes required to bring the length of the
-current section up to a multiple of that power of two, and then apply the
-<code><nobr>TIMES</nobr></code> prefix to their second argument to perform
-the alignment.
-<p>If the second argument is not specified, the default for
-<code><nobr>ALIGN</nobr></code> is <code><nobr>NOP</nobr></code>, and the
-default for <code><nobr>ALIGNB</nobr></code> is
-<code><nobr>RESB 1</nobr></code>. So if the second argument is specified,
-the two macros are equivalent. Normally, you can just use
-<code><nobr>ALIGN</nobr></code> in code and data sections and
-<code><nobr>ALIGNB</nobr></code> in BSS sections, and never need the second
-argument except for special purposes.
-<p><code><nobr>ALIGN</nobr></code> and <code><nobr>ALIGNB</nobr></code>,
-being simple macros, perform no error checking: they cannot warn you if
-their first argument fails to be a power of two, or if their second
-argument generates more than one byte of code. In each of these cases they
-will silently do the wrong thing.
-<p><code><nobr>ALIGNB</nobr></code> (or <code><nobr>ALIGN</nobr></code>
-with a second argument of <code><nobr>RESB 1</nobr></code>) can be used
-within structure definitions:
-<p><pre>
-struc mytype2
-
- mt_byte:
- resb 1
- alignb 2
- mt_word:
- resw 1
- alignb 4
- mt_long:
- resd 1
- mt_str:
- resb 32
-
-endstruc
-</pre>
-<p>This will ensure that the structure members are sensibly aligned
-relative to the base of the structure.
-<p>A final caveat: <code><nobr>ALIGN</nobr></code> and
-<code><nobr>ALIGNB</nobr></code> work relative to the beginning of the
-<em>section</em>, not the beginning of the address space in the final
-executable. Aligning to a 16-byte boundary when the section you're in is
-only guaranteed to be aligned to a 4-byte boundary, for example, is a waste
-of effort. Again, NASM does not check that the section's alignment
-characteristics are sensible for the use of <code><nobr>ALIGN</nobr></code>
-or <code><nobr>ALIGNB</nobr></code>.
-<p>See also the <code><nobr>smartalign</nobr></code> standard macro
-package, <a href="nasmdoc5.html#section-5.2">section 5.2</a>.
-<p align=center><a href="nasmdoc5.html">Next Chapter</a> |
-<a href="nasmdoc3.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdoc5.html b/doc/html/nasmdoc5.html
deleted file mode 100644
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--- a/doc/html/nasmdoc5.html
+++ /dev/null
@@ -1,83 +0,0 @@
-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc6.html">Next Chapter</a> |
-<a href="nasmdoc4.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-5">Chapter 5: Standard Macro Packages</a></h2>
-<p>The <code><nobr>%use</nobr></code> directive (see
-<a href="nasmdoc4.html#section-4.6.4">section 4.6.4</a>) includes one of
-the standard macro packages included with the NASM distribution and
-compiled into the NASM binary. It operates like the
-<code><nobr>%include</nobr></code> directive (see
-<a href="nasmdoc4.html#section-4.6.1">section 4.6.1</a>), but the included
-contents is provided by NASM itself.
-<p>The names of standard macro packages are case insensitive, and can be
-quoted or not.
-<h3><a name="section-5.1">5.1 <code><nobr>altreg</nobr></code>: Alternate Register Names</a></h3>
-<p>The <code><nobr>altreg</nobr></code> standard macro package provides
-alternate register names. It provides numeric register names for all
-registers (not just
-<code><nobr>R8</nobr></code>-<code><nobr>R15</nobr></code>), the
-Intel-defined aliases
-<code><nobr>R8L</nobr></code>-<code><nobr>R15L</nobr></code> for the low
-bytes of register (as opposed to the NASM/AMD standard names
-<code><nobr>R8B</nobr></code>-<code><nobr>R15B</nobr></code>), and the
-names <code><nobr>R0H</nobr></code>-<code><nobr>R3H</nobr></code> (by
-analogy with <code><nobr>R0L</nobr></code>-<code><nobr>R3L</nobr></code>)
-for <code><nobr>AH</nobr></code>, <code><nobr>CH</nobr></code>,
-<code><nobr>DH</nobr></code>, and <code><nobr>BH</nobr></code>.
-<p>Example use:
-<p><pre>
-%use altreg
-
-proc:
- mov r0l,r3h ; mov al,bh
- ret
-</pre>
-<p>See also <a href="nasmdo11.html#section-11.1">section 11.1</a>.
-<h3><a name="section-5.2">5.2 <code><nobr>smartalign</nobr></code>: Smart <code><nobr>ALIGN</nobr></code> Macro</a></h3>
-<p>The <code><nobr>smartalign</nobr></code> standard macro package provides
-for an <code><nobr>ALIGN</nobr></code> macro which is more powerful than
-the default (and backwards-compatible) one (see
-<a href="nasmdoc4.html#section-4.11.12">section 4.11.12</a>). When the
-<code><nobr>smartalign</nobr></code> package is enabled, when
-<code><nobr>ALIGN</nobr></code> is used without a second argument, NASM
-will generate a sequence of instructions more efficient than a series of
-<code><nobr>NOP</nobr></code>. Furthermore, if the padding exceeds a
-specific threshold, then NASM will generate a jump over the entire padding
-sequence.
-<p>The specific instructions generated can be controlled with the new
-<code><nobr>ALIGNMODE</nobr></code> macro. This macro takes two parameters:
-one mode, and an optional jump threshold override. The modes are as
-follows:
-<ul>
-<li><code><nobr>generic</nobr></code>: Works on all x86 CPUs and should
-have reasonable performance. The default jump threshold is 8. This is the
-default.
-<li><code><nobr>nop</nobr></code>: Pad out with
-<code><nobr>NOP</nobr></code> instructions. The only difference compared to
-the standard <code><nobr>ALIGN</nobr></code> macro is that NASM can still
-jump over a large padding area. The default jump threshold is 16.
-<li><code><nobr>k7</nobr></code>: Optimize for the AMD K7 (Athlon/Althon
-XP). These instructions should still work on all x86 CPUs. The default jump
-threshold is 16.
-<li><code><nobr>k8</nobr></code>: Optimize for the AMD K8 (Opteron/Althon
-64). These instructions should still work on all x86 CPUs. The default jump
-threshold is 16.
-<li><code><nobr>p6</nobr></code>: Optimize for Intel CPUs. This uses the
-long <code><nobr>NOP</nobr></code> instructions first introduced in Pentium
-Pro. This is incompatible with all CPUs of family 5 or lower, as well as
-some VIA CPUs and several virtualization solutions. The default jump
-threshold is 16.
-</ul>
-<p>The macro <code><nobr>__ALIGNMODE__</nobr></code> is defined to contain
-the current alignment mode. A number of other macros beginning with
-<code><nobr>__ALIGN_</nobr></code> are used internally by this macro
-package.
-<p align=center><a href="nasmdoc6.html">Next Chapter</a> |
-<a href="nasmdoc4.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdoc6.html b/doc/html/nasmdoc6.html
deleted file mode 100644
index 144a661..0000000
--- a/doc/html/nasmdoc6.html
+++ /dev/null
@@ -1,371 +0,0 @@
-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc7.html">Next Chapter</a> |
-<a href="nasmdoc5.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-6">Chapter 6: Assembler Directives</a></h2>
-<p>NASM, though it attempts to avoid the bureaucracy of assemblers like
-MASM and TASM, is nevertheless forced to support a <em>few</em> directives.
-These are described in this chapter.
-<p>NASM's directives come in two types: <em>user-level</em> directives and
-<em>primitive</em> directives. Typically, each directive has a user-level
-form and a primitive form. In almost all cases, we recommend that users use
-the user-level forms of the directives, which are implemented as macros
-which call the primitive forms.
-<p>Primitive directives are enclosed in square brackets; user-level
-directives are not.
-<p>In addition to the universal directives described in this chapter, each
-object file format can optionally supply extra directives in order to
-control particular features of that file format. These
-<em>format-specific</em> directives are documented along with the formats
-that implement them, in <a href="nasmdoc7.html">chapter 7</a>.
-<h3><a name="section-6.1">6.1 <code><nobr>BITS</nobr></code>: Specifying Target Processor Mode</a></h3>
-<p>The <code><nobr>BITS</nobr></code> directive specifies whether NASM
-should generate code designed to run on a processor operating in 16-bit
-mode, 32-bit mode or 64-bit mode. The syntax is
-<code><nobr>BITS XX</nobr></code>, where XX is 16, 32 or 64.
-<p>In most cases, you should not need to use <code><nobr>BITS</nobr></code>
-explicitly. The <code><nobr>aout</nobr></code>,
-<code><nobr>coff</nobr></code>, <code><nobr>elf</nobr></code>,
-<code><nobr>macho</nobr></code>, <code><nobr>win32</nobr></code> and
-<code><nobr>win64</nobr></code> object formats, which are designed for use
-in 32-bit or 64-bit operating systems, all cause NASM to select 32-bit or
-64-bit mode, respectively, by default. The <code><nobr>obj</nobr></code>
-object format allows you to specify each segment you define as either
-<code><nobr>USE16</nobr></code> or <code><nobr>USE32</nobr></code>, and
-NASM will set its operating mode accordingly, so the use of the
-<code><nobr>BITS</nobr></code> directive is once again unnecessary.
-<p>The most likely reason for using the <code><nobr>BITS</nobr></code>
-directive is to write 32-bit or 64-bit code in a flat binary file; this is
-because the <code><nobr>bin</nobr></code> output format defaults to 16-bit
-mode in anticipation of it being used most frequently to write DOS
-<code><nobr>.COM</nobr></code> programs, DOS <code><nobr>.SYS</nobr></code>
-device drivers and boot loader software.
-<p>You do <em>not</em> need to specify <code><nobr>BITS 32</nobr></code>
-merely in order to use 32-bit instructions in a 16-bit DOS program; if you
-do, the assembler will generate incorrect code because it will be writing
-code targeted at a 32-bit platform, to be run on a 16-bit one.
-<p>When NASM is in <code><nobr>BITS 16</nobr></code> mode, instructions
-which use 32-bit data are prefixed with an 0x66 byte, and those referring
-to 32-bit addresses have an 0x67 prefix. In
-<code><nobr>BITS 32</nobr></code> mode, the reverse is true: 32-bit
-instructions require no prefixes, whereas instructions using 16-bit data
-need an 0x66 and those working on 16-bit addresses need an 0x67.
-<p>When NASM is in <code><nobr>BITS 64</nobr></code> mode, most
-instructions operate the same as they do for
-<code><nobr>BITS 32</nobr></code> mode. However, there are 8 more general
-and SSE registers, and 16-bit addressing is no longer supported.
-<p>The default address size is 64 bits; 32-bit addressing can be selected
-with the 0x67 prefix. The default operand size is still 32 bits, however,
-and the 0x66 prefix selects 16-bit operand size. The
-<code><nobr>REX</nobr></code> prefix is used both to select 64-bit operand
-size, and to access the new registers. NASM automatically inserts REX
-prefixes when necessary.
-<p>When the <code><nobr>REX</nobr></code> prefix is used, the processor
-does not know how to address the AH, BH, CH or DH (high 8-bit legacy)
-registers. Instead, it is possible to access the the low 8-bits of the SP,
-BP SI and DI registers as SPL, BPL, SIL and DIL, respectively; but only
-when the REX prefix is used.
-<p>The <code><nobr>BITS</nobr></code> directive has an exactly equivalent
-primitive form, <code><nobr>[BITS 16]</nobr></code>,
-<code><nobr>[BITS 32]</nobr></code> and
-<code><nobr>[BITS 64]</nobr></code>. The user-level form is a macro which
-has no function other than to call the primitive form.
-<p>Note that the space is neccessary, e.g. <code><nobr>BITS32</nobr></code>
-will <em>not</em> work!
-<h4><a name="section-6.1.1">6.1.1 <code><nobr>USE16</nobr></code> &amp; <code><nobr>USE32</nobr></code>: Aliases for BITS</a></h4>
-<p>The `<code><nobr>USE16</nobr></code>' and
-`<code><nobr>USE32</nobr></code>' directives can be used in place of
-`<code><nobr>BITS 16</nobr></code>' and
-`<code><nobr>BITS 32</nobr></code>', for compatibility with other
-assemblers.
-<h3><a name="section-6.2">6.2 <code><nobr>DEFAULT</nobr></code>: Change the assembler defaults</a></h3>
-<p>The <code><nobr>DEFAULT</nobr></code> directive changes the assembler
-defaults. Normally, NASM defaults to a mode where the programmer is
-expected to explicitly specify most features directly. However, this is
-occationally obnoxious, as the explicit form is pretty much the only one
-one wishes to use.
-<p>Currently, the only <code><nobr>DEFAULT</nobr></code> that is settable
-is whether or not registerless instructions in 64-bit mode are
-<code><nobr>RIP</nobr></code>-relative or not. By default, they are
-absolute unless overridden with the <code><nobr>REL</nobr></code> specifier
-(see <a href="nasmdoc3.html#section-3.3">section 3.3</a>). However, if
-<code><nobr>DEFAULT REL</nobr></code> is specified,
-<code><nobr>REL</nobr></code> is default, unless overridden with the
-<code><nobr>ABS</nobr></code> specifier, <em>except when used with an FS or
-GS segment override</em>.
-<p>The special handling of <code><nobr>FS</nobr></code> and
-<code><nobr>GS</nobr></code> overrides are due to the fact that these
-registers are generally used as thread pointers or other special functions
-in 64-bit mode, and generating <code><nobr>RIP</nobr></code>-relative
-addresses would be extremely confusing.
-<p><code><nobr>DEFAULT REL</nobr></code> is disabled with
-<code><nobr>DEFAULT ABS</nobr></code>.
-<h3><a name="section-6.3">6.3 <code><nobr>SECTION</nobr></code> or <code><nobr>SEGMENT</nobr></code>: Changing and Defining Sections</a></h3>
-<p>The <code><nobr>SECTION</nobr></code> directive
-(<code><nobr>SEGMENT</nobr></code> is an exactly equivalent synonym)
-changes which section of the output file the code you write will be
-assembled into. In some object file formats, the number and names of
-sections are fixed; in others, the user may make up as many as they wish.
-Hence <code><nobr>SECTION</nobr></code> may sometimes give an error
-message, or may define a new section, if you try to switch to a section
-that does not (yet) exist.
-<p>The Unix object formats, and the <code><nobr>bin</nobr></code> object
-format (but see <a href="nasmdoc7.html#section-7.1.3">section 7.1.3</a>,
-all support the standardized section names <code><nobr>.text</nobr></code>,
-<code><nobr>.data</nobr></code> and <code><nobr>.bss</nobr></code> for the
-code, data and uninitialized-data sections. The
-<code><nobr>obj</nobr></code> format, by contrast, does not recognize these
-section names as being special, and indeed will strip off the leading
-period of any section name that has one.
-<h4><a name="section-6.3.1">6.3.1 The <code><nobr>__SECT__</nobr></code> Macro</a></h4>
-<p>The <code><nobr>SECTION</nobr></code> directive is unusual in that its
-user-level form functions differently from its primitive form. The
-primitive form, <code><nobr>[SECTION xyz]</nobr></code>, simply switches
-the current target section to the one given. The user-level form,
-<code><nobr>SECTION xyz</nobr></code>, however, first defines the
-single-line macro <code><nobr>__SECT__</nobr></code> to be the primitive
-<code><nobr>[SECTION]</nobr></code> directive which it is about to issue,
-and then issues it. So the user-level directive
-<p><pre>
- SECTION .text
-</pre>
-<p>expands to the two lines
-<p><pre>
-%define __SECT__ [SECTION .text]
- [SECTION .text]
-</pre>
-<p>Users may find it useful to make use of this in their own macros. For
-example, the <code><nobr>writefile</nobr></code> macro defined in
-<a href="nasmdoc4.html#section-4.3.4">section 4.3.4</a> can be usefully
-rewritten in the following more sophisticated form:
-<p><pre>
-%macro writefile 2+
-
- [section .data]
-
- %%str: db %2
- %%endstr:
-
- __SECT__
-
- mov dx,%%str
- mov cx,%%endstr-%%str
- mov bx,%1
- mov ah,0x40
- int 0x21
-
-%endmacro
-</pre>
-<p>This form of the macro, once passed a string to output, first switches
-temporarily to the data section of the file, using the primitive form of
-the <code><nobr>SECTION</nobr></code> directive so as not to modify
-<code><nobr>__SECT__</nobr></code>. It then declares its string in the data
-section, and then invokes <code><nobr>__SECT__</nobr></code> to switch back
-to <em>whichever</em> section the user was previously working in. It thus
-avoids the need, in the previous version of the macro, to include a
-<code><nobr>JMP</nobr></code> instruction to jump over the data, and also
-does not fail if, in a complicated <code><nobr>OBJ</nobr></code> format
-module, the user could potentially be assembling the code in any of several
-separate code sections.
-<h3><a name="section-6.4">6.4 <code><nobr>ABSOLUTE</nobr></code>: Defining Absolute Labels</a></h3>
-<p>The <code><nobr>ABSOLUTE</nobr></code> directive can be thought of as an
-alternative form of <code><nobr>SECTION</nobr></code>: it causes the
-subsequent code to be directed at no physical section, but at the
-hypothetical section starting at the given absolute address. The only
-instructions you can use in this mode are the
-<code><nobr>RESB</nobr></code> family.
-<p><code><nobr>ABSOLUTE</nobr></code> is used as follows:
-<p><pre>
-absolute 0x1A
-
- kbuf_chr resw 1
- kbuf_free resw 1
- kbuf resw 16
-</pre>
-<p>This example describes a section of the PC BIOS data area, at segment
-address 0x40: the above code defines <code><nobr>kbuf_chr</nobr></code> to
-be 0x1A, <code><nobr>kbuf_free</nobr></code> to be 0x1C, and
-<code><nobr>kbuf</nobr></code> to be 0x1E.
-<p>The user-level form of <code><nobr>ABSOLUTE</nobr></code>, like that of
-<code><nobr>SECTION</nobr></code>, redefines the
-<code><nobr>__SECT__</nobr></code> macro when it is invoked.
-<p><code><nobr>STRUC</nobr></code> and <code><nobr>ENDSTRUC</nobr></code>
-are defined as macros which use <code><nobr>ABSOLUTE</nobr></code> (and
-also <code><nobr>__SECT__</nobr></code>).
-<p><code><nobr>ABSOLUTE</nobr></code> doesn't have to take an absolute
-constant as an argument: it can take an expression (actually, a critical
-expression: see <a href="nasmdoc3.html#section-3.8">section 3.8</a>) and it
-can be a value in a segment. For example, a TSR can re-use its setup code
-as run-time BSS like this:
-<p><pre>
- org 100h ; it's a .COM program
-
- jmp setup ; setup code comes last
-
- ; the resident part of the TSR goes here
-setup:
- ; now write the code that installs the TSR here
-
-absolute setup
-
-runtimevar1 resw 1
-runtimevar2 resd 20
-
-tsr_end:
-</pre>
-<p>This defines some variables `on top of' the setup code, so that after
-the setup has finished running, the space it took up can be re-used as data
-storage for the running TSR. The symbol `tsr_end' can be used to calculate
-the total size of the part of the TSR that needs to be made resident.
-<h3><a name="section-6.5">6.5 <code><nobr>EXTERN</nobr></code>: Importing Symbols from Other Modules</a></h3>
-<p><code><nobr>EXTERN</nobr></code> is similar to the MASM directive
-<code><nobr>EXTRN</nobr></code> and the C keyword
-<code><nobr>extern</nobr></code>: it is used to declare a symbol which is
-not defined anywhere in the module being assembled, but is assumed to be
-defined in some other module and needs to be referred to by this one. Not
-every object-file format can support external variables: the
-<code><nobr>bin</nobr></code> format cannot.
-<p>The <code><nobr>EXTERN</nobr></code> directive takes as many arguments
-as you like. Each argument is the name of a symbol:
-<p><pre>
-extern _printf
-extern _sscanf,_fscanf
-</pre>
-<p>Some object-file formats provide extra features to the
-<code><nobr>EXTERN</nobr></code> directive. In all cases, the extra
-features are used by suffixing a colon to the symbol name followed by
-object-format specific text. For example, the <code><nobr>obj</nobr></code>
-format allows you to declare that the default segment base of an external
-should be the group <code><nobr>dgroup</nobr></code> by means of the
-directive
-<p><pre>
-extern _variable:wrt dgroup
-</pre>
-<p>The primitive form of <code><nobr>EXTERN</nobr></code> differs from the
-user-level form only in that it can take only one argument at a time: the
-support for multiple arguments is implemented at the preprocessor level.
-<p>You can declare the same variable as <code><nobr>EXTERN</nobr></code>
-more than once: NASM will quietly ignore the second and later
-redeclarations. You can't declare a variable as
-<code><nobr>EXTERN</nobr></code> as well as something else, though.
-<h3><a name="section-6.6">6.6 <code><nobr>GLOBAL</nobr></code>: Exporting Symbols to Other Modules</a></h3>
-<p><code><nobr>GLOBAL</nobr></code> is the other end of
-<code><nobr>EXTERN</nobr></code>: if one module declares a symbol as
-<code><nobr>EXTERN</nobr></code> and refers to it, then in order to prevent
-linker errors, some other module must actually <em>define</em> the symbol
-and declare it as <code><nobr>GLOBAL</nobr></code>. Some assemblers use the
-name <code><nobr>PUBLIC</nobr></code> for this purpose.
-<p>The <code><nobr>GLOBAL</nobr></code> directive applying to a symbol must
-appear <em>before</em> the definition of the symbol.
-<p><code><nobr>GLOBAL</nobr></code> uses the same syntax as
-<code><nobr>EXTERN</nobr></code>, except that it must refer to symbols
-which <em>are</em> defined in the same module as the
-<code><nobr>GLOBAL</nobr></code> directive. For example:
-<p><pre>
-global _main
-_main:
- ; some code
-</pre>
-<p><code><nobr>GLOBAL</nobr></code>, like <code><nobr>EXTERN</nobr></code>,
-allows object formats to define private extensions by means of a colon. The
-<code><nobr>elf</nobr></code> object format, for example, lets you specify
-whether global data items are functions or data:
-<p><pre>
-global hashlookup:function, hashtable:data
-</pre>
-<p>Like <code><nobr>EXTERN</nobr></code>, the primitive form of
-<code><nobr>GLOBAL</nobr></code> differs from the user-level form only in
-that it can take only one argument at a time.
-<h3><a name="section-6.7">6.7 <code><nobr>COMMON</nobr></code>: Defining Common Data Areas</a></h3>
-<p>The <code><nobr>COMMON</nobr></code> directive is used to declare
-<em>common variables</em>. A common variable is much like a global variable
-declared in the uninitialized data section, so that
-<p><pre>
-common intvar 4
-</pre>
-<p>is similar in function to
-<p><pre>
-global intvar
-section .bss
-
-intvar resd 1
-</pre>
-<p>The difference is that if more than one module defines the same common
-variable, then at link time those variables will be <em>merged</em>, and
-references to <code><nobr>intvar</nobr></code> in all modules will point at
-the same piece of memory.
-<p>Like <code><nobr>GLOBAL</nobr></code> and
-<code><nobr>EXTERN</nobr></code>, <code><nobr>COMMON</nobr></code> supports
-object-format specific extensions. For example, the
-<code><nobr>obj</nobr></code> format allows common variables to be NEAR or
-FAR, and the <code><nobr>elf</nobr></code> format allows you to specify the
-alignment requirements of a common variable:
-<p><pre>
-common commvar 4:near ; works in OBJ
-common intarray 100:4 ; works in ELF: 4 byte aligned
-</pre>
-<p>Once again, like <code><nobr>EXTERN</nobr></code> and
-<code><nobr>GLOBAL</nobr></code>, the primitive form of
-<code><nobr>COMMON</nobr></code> differs from the user-level form only in
-that it can take only one argument at a time.
-<h3><a name="section-6.8">6.8 <code><nobr>CPU</nobr></code>: Defining CPU Dependencies</a></h3>
-<p>The <code><nobr>CPU</nobr></code> directive restricts assembly to those
-instructions which are available on the specified CPU.
-<p>Options are:
-<ul>
-<li><code><nobr>CPU 8086</nobr></code> Assemble only 8086 instruction set
-<li><code><nobr>CPU 186</nobr></code> Assemble instructions up to the 80186
-instruction set
-<li><code><nobr>CPU 286</nobr></code> Assemble instructions up to the 286
-instruction set
-<li><code><nobr>CPU 386</nobr></code> Assemble instructions up to the 386
-instruction set
-<li><code><nobr>CPU 486</nobr></code> 486 instruction set
-<li><code><nobr>CPU 586</nobr></code> Pentium instruction set
-<li><code><nobr>CPU PENTIUM</nobr></code> Same as 586
-<li><code><nobr>CPU 686</nobr></code> P6 instruction set
-<li><code><nobr>CPU PPRO</nobr></code> Same as 686
-<li><code><nobr>CPU P2</nobr></code> Same as 686
-<li><code><nobr>CPU P3</nobr></code> Pentium III (Katmai) instruction sets
-<li><code><nobr>CPU KATMAI</nobr></code> Same as P3
-<li><code><nobr>CPU P4</nobr></code> Pentium 4 (Willamette) instruction set
-<li><code><nobr>CPU WILLAMETTE</nobr></code> Same as P4
-<li><code><nobr>CPU PRESCOTT</nobr></code> Prescott instruction set
-<li><code><nobr>CPU X64</nobr></code> x86-64 (x64/AMD64/Intel 64)
-instruction set
-<li><code><nobr>CPU IA64</nobr></code> IA64 CPU (in x86 mode) instruction
-set
-</ul>
-<p>All options are case insensitive. All instructions will be selected only
-if they apply to the selected CPU or lower. By default, all instructions
-are available.
-<h3><a name="section-6.9">6.9 <code><nobr>FLOAT</nobr></code>: Handling of floating-point constants</a></h3>
-<p>By default, floating-point constants are rounded to nearest, and IEEE
-denormals are supported. The following options can be set to alter this
-behaviour:
-<ul>
-<li><code><nobr>FLOAT DAZ</nobr></code> Flush denormals to zero
-<li><code><nobr>FLOAT NODAZ</nobr></code> Do not flush denormals to zero
-(default)
-<li><code><nobr>FLOAT NEAR</nobr></code> Round to nearest (default)
-<li><code><nobr>FLOAT UP</nobr></code> Round up (toward +Infinity)
-<li><code><nobr>FLOAT DOWN</nobr></code> Round down (toward -Infinity)
-<li><code><nobr>FLOAT ZERO</nobr></code> Round toward zero
-<li><code><nobr>FLOAT DEFAULT</nobr></code> Restore default settings
-</ul>
-<p>The standard macros <code><nobr>__FLOAT_DAZ__</nobr></code>,
-<code><nobr>__FLOAT_ROUND__</nobr></code>, and
-<code><nobr>__FLOAT__</nobr></code> contain the current state, as long as
-the programmer has avoided the use of the brackeded primitive form,
-(<code><nobr>[FLOAT]</nobr></code>).
-<p><code><nobr>__FLOAT__</nobr></code> contains the full set of
-floating-point settings; this value can be saved away and invoked later to
-restore the setting.
-<p align=center><a href="nasmdoc7.html">Next Chapter</a> |
-<a href="nasmdoc5.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc8.html">Next Chapter</a> |
-<a href="nasmdoc6.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-7">Chapter 7: Output Formats</a></h2>
-<p>NASM is a portable assembler, designed to be able to compile on any ANSI
-C-supporting platform and produce output to run on a variety of Intel x86
-operating systems. For this reason, it has a large number of available
-output formats, selected using the <code><nobr>-f</nobr></code> option on
-the NASM command line. Each of these formats, along with its extensions to
-the base NASM syntax, is detailed in this chapter.
-<p>As stated in <a href="nasmdoc2.html#section-2.1.1">section 2.1.1</a>,
-NASM chooses a default name for your output file based on the input file
-name and the chosen output format. This will be generated by removing the
-extension (<code><nobr>.asm</nobr></code>, <code><nobr>.s</nobr></code>, or
-whatever you like to use) from the input file name, and substituting an
-extension defined by the output format. The extensions are given with each
-format below.
-<h3><a name="section-7.1">7.1 <code><nobr>bin</nobr></code>: Flat-Form Binary Output</a></h3>
-<p>The <code><nobr>bin</nobr></code> format does not produce object files:
-it generates nothing in the output file except the code you wrote. Such
-`pure binary' files are used by MS-DOS: <code><nobr>.COM</nobr></code>
-executables and <code><nobr>.SYS</nobr></code> device drivers are pure
-binary files. Pure binary output is also useful for operating system and
-boot loader development.
-<p>The <code><nobr>bin</nobr></code> format supports multiple section
-names. For details of how NASM handles sections in the
-<code><nobr>bin</nobr></code> format, see <a href="#section-7.1.3">section
-7.1.3</a>.
-<p>Using the <code><nobr>bin</nobr></code> format puts NASM by default into
-16-bit mode (see <a href="nasmdoc6.html#section-6.1">section 6.1</a>). In
-order to use <code><nobr>bin</nobr></code> to write 32-bit or 64-bit code,
-such as an OS kernel, you need to explicitly issue the
-<code><nobr>BITS 32</nobr></code> or <code><nobr>BITS 64</nobr></code>
-directive.
-<p><code><nobr>bin</nobr></code> has no default output file name extension:
-instead, it leaves your file name as it is once the original extension has
-been removed. Thus, the default is for NASM to assemble
-<code><nobr>binprog.asm</nobr></code> into a binary file called
-<code><nobr>binprog</nobr></code>.
-<h4><a name="section-7.1.1">7.1.1 <code><nobr>ORG</nobr></code>: Binary File Program Origin</a></h4>
-<p>The <code><nobr>bin</nobr></code> format provides an additional
-directive to the list given in <a href="nasmdoc6.html">chapter 6</a>:
-<code><nobr>ORG</nobr></code>. The function of the
-<code><nobr>ORG</nobr></code> directive is to specify the origin address
-which NASM will assume the program begins at when it is loaded into memory.
-<p>For example, the following code will generate the longword
-<code><nobr>0x00000104</nobr></code>:
-<p><pre>
- org 0x100
- dd label
-label:
-</pre>
-<p>Unlike the <code><nobr>ORG</nobr></code> directive provided by
-MASM-compatible assemblers, which allows you to jump around in the object
-file and overwrite code you have already generated, NASM's
-<code><nobr>ORG</nobr></code> does exactly what the directive says:
-<em>origin</em>. Its sole function is to specify one offset which is added
-to all internal address references within the section; it does not permit
-any of the trickery that MASM's version does. See
-<a href="nasmdo12.html#section-12.1.3">section 12.1.3</a> for further
-comments.
-<h4><a name="section-7.1.2">7.1.2 <code><nobr>bin</nobr></code> Extensions to the <code><nobr>SECTION</nobr></code> Directive</a></h4>
-<p>The <code><nobr>bin</nobr></code> output format extends the
-<code><nobr>SECTION</nobr></code> (or <code><nobr>SEGMENT</nobr></code>)
-directive to allow you to specify the alignment requirements of segments.
-This is done by appending the <code><nobr>ALIGN</nobr></code> qualifier to
-the end of the section-definition line. For example,
-<p><pre>
-section .data align=16
-</pre>
-<p>switches to the section <code><nobr>.data</nobr></code> and also
-specifies that it must be aligned on a 16-byte boundary.
-<p>The parameter to <code><nobr>ALIGN</nobr></code> specifies how many low
-bits of the section start address must be forced to zero. The alignment
-value given may be any power of two.
-<h4><a name="section-7.1.3">7.1.3 Multisection Support for the <code><nobr>bin</nobr></code> Format</a></h4>
-<p>The <code><nobr>bin</nobr></code> format allows the use of multiple
-sections, of arbitrary names, besides the "known"
-<code><nobr>.text</nobr></code>, <code><nobr>.data</nobr></code>, and
-<code><nobr>.bss</nobr></code> names.
-<ul>
-<li>Sections may be designated <code><nobr>progbits</nobr></code> or
-<code><nobr>nobits</nobr></code>. Default is
-<code><nobr>progbits</nobr></code> (except <code><nobr>.bss</nobr></code>,
-which defaults to <code><nobr>nobits</nobr></code>, of course).
-<li>Sections can be aligned at a specified boundary following the previous
-section with <code><nobr>align=</nobr></code>, or at an arbitrary
-byte-granular position with <code><nobr>start=</nobr></code>.
-<li>Sections can be given a virtual start address, which will be used for
-the calculation of all memory references within that section with
-<code><nobr>vstart=</nobr></code>.
-<li>Sections can be ordered using
-<code><nobr>follows=</nobr></code><code><nobr>&lt;section&gt;</nobr></code>
-or
-<code><nobr>vfollows=</nobr></code><code><nobr>&lt;section&gt;</nobr></code>
-as an alternative to specifying an explicit start address.
-<li>Arguments to <code><nobr>org</nobr></code>,
-<code><nobr>start</nobr></code>, <code><nobr>vstart</nobr></code>, and
-<code><nobr>align=</nobr></code> are critical expressions. See
-<a href="nasmdoc3.html#section-3.8">section 3.8</a>. E.g.
-<code><nobr>align=(1 &lt;&lt; ALIGN_SHIFT)</nobr></code> -
-<code><nobr>ALIGN_SHIFT</nobr></code> must be defined before it is used
-here.
-<li>Any code which comes before an explicit
-<code><nobr>SECTION</nobr></code> directive is directed by default into the
-<code><nobr>.text</nobr></code> section.
-<li>If an <code><nobr>ORG</nobr></code> statement is not given,
-<code><nobr>ORG 0</nobr></code> is used by default.
-<li>The <code><nobr>.bss</nobr></code> section will be placed after the
-last <code><nobr>progbits</nobr></code> section, unless
-<code><nobr>start=</nobr></code>, <code><nobr>vstart=</nobr></code>,
-<code><nobr>follows=</nobr></code>, or <code><nobr>vfollows=</nobr></code>
-has been specified.
-<li>All sections are aligned on dword boundaries, unless a different
-alignment has been specified.
-<li>Sections may not overlap.
-<li>NASM creates the
-<code><nobr>section.&lt;secname&gt;.start</nobr></code> for each section,
-which may be used in your code.
-</ul>
-<h4><a name="section-7.1.4">7.1.4 Map Files</a></h4>
-<p>Map files can be generated in <code><nobr>-f bin</nobr></code> format by
-means of the <code><nobr>[map]</nobr></code> option. Map types of
-<code><nobr>all</nobr></code> (default), <code><nobr>brief</nobr></code>,
-<code><nobr>sections</nobr></code>, <code><nobr>segments</nobr></code>, or
-<code><nobr>symbols</nobr></code> may be specified. Output may be directed
-to <code><nobr>stdout</nobr></code> (default),
-<code><nobr>stderr</nobr></code>, or a specified file. E.g.
-<code><nobr>[map symbols myfile.map]</nobr></code>. No "user form" exists,
-the square brackets must be used.
-<h3><a name="section-7.2">7.2 <code><nobr>ith</nobr></code>: Intel Hex Output</a></h3>
-<p>The <code><nobr>ith</nobr></code> file format produces Intel hex-format
-files. Just as the <code><nobr>bin</nobr></code> format, this is a flat
-memory image format with no support for relocation or linking. It is
-usually used with ROM programmers and similar utilities.
-<p>All extensions supported by the <code><nobr>bin</nobr></code> file
-format is also supported by the <code><nobr>ith</nobr></code> file format.
-<p><code><nobr>ith</nobr></code> provides a default output file-name
-extension of <code><nobr>.ith</nobr></code>.
-<h3><a name="section-7.3">7.3 <code><nobr>srec</nobr></code>: Motorola S-Records Output</a></h3>
-<p>The <code><nobr>srec</nobr></code> file format produces Motorola
-S-records files. Just as the <code><nobr>bin</nobr></code> format, this is
-a flat memory image format with no support for relocation or linking. It is
-usually used with ROM programmers and similar utilities.
-<p>All extensions supported by the <code><nobr>bin</nobr></code> file
-format is also supported by the <code><nobr>srec</nobr></code> file format.
-<p><code><nobr>srec</nobr></code> provides a default output file-name
-extension of <code><nobr>.srec</nobr></code>.
-<h3><a name="section-7.4">7.4 <code><nobr>obj</nobr></code>: Microsoft OMF Object Files</a></h3>
-<p>The <code><nobr>obj</nobr></code> file format (NASM calls it
-<code><nobr>obj</nobr></code> rather than <code><nobr>omf</nobr></code> for
-historical reasons) is the one produced by MASM and TASM, which is
-typically fed to 16-bit DOS linkers to produce
-<code><nobr>.EXE</nobr></code> files. It is also the format used by OS/2.
-<p><code><nobr>obj</nobr></code> provides a default output file-name
-extension of <code><nobr>.obj</nobr></code>.
-<p><code><nobr>obj</nobr></code> is not exclusively a 16-bit format,
-though: NASM has full support for the 32-bit extensions to the format. In
-particular, 32-bit <code><nobr>obj</nobr></code> format files are used by
-Borland's Win32 compilers, instead of using Microsoft's newer
-<code><nobr>win32</nobr></code> object file format.
-<p>The <code><nobr>obj</nobr></code> format does not define any special
-segment names: you can call your segments anything you like. Typical names
-for segments in <code><nobr>obj</nobr></code> format files are
-<code><nobr>CODE</nobr></code>, <code><nobr>DATA</nobr></code> and
-<code><nobr>BSS</nobr></code>.
-<p>If your source file contains code before specifying an explicit
-<code><nobr>SEGMENT</nobr></code> directive, then NASM will invent its own
-segment called <code><nobr>__NASMDEFSEG</nobr></code> for you.
-<p>When you define a segment in an <code><nobr>obj</nobr></code> file, NASM
-defines the segment name as a symbol as well, so that you can access the
-segment address of the segment. So, for example:
-<p><pre>
-segment data
-
-dvar: dw 1234
-
-segment code
-
-function:
- mov ax,data ; get segment address of data
- mov ds,ax ; and move it into DS
- inc word [dvar] ; now this reference will work
- ret
-</pre>
-<p>The <code><nobr>obj</nobr></code> format also enables the use of the
-<code><nobr>SEG</nobr></code> and <code><nobr>WRT</nobr></code> operators,
-so that you can write code which does things like
-<p><pre>
-extern foo
-
- mov ax,seg foo ; get preferred segment of foo
- mov ds,ax
- mov ax,data ; a different segment
- mov es,ax
- mov ax,[ds:foo] ; this accesses `foo'
- mov [es:foo wrt data],bx ; so does this
-</pre>
-<h4><a name="section-7.4.1">7.4.1 <code><nobr>obj</nobr></code> Extensions to the <code><nobr>SEGMENT</nobr></code> Directive</a></h4>
-<p>The <code><nobr>obj</nobr></code> output format extends the
-<code><nobr>SEGMENT</nobr></code> (or <code><nobr>SECTION</nobr></code>)
-directive to allow you to specify various properties of the segment you are
-defining. This is done by appending extra qualifiers to the end of the
-segment-definition line. For example,
-<p><pre>
-segment code private align=16
-</pre>
-<p>defines the segment <code><nobr>code</nobr></code>, but also declares it
-to be a private segment, and requires that the portion of it described in
-this code module must be aligned on a 16-byte boundary.
-<p>The available qualifiers are:
-<ul>
-<li><code><nobr>PRIVATE</nobr></code>, <code><nobr>PUBLIC</nobr></code>,
-<code><nobr>COMMON</nobr></code> and <code><nobr>STACK</nobr></code>
-specify the combination characteristics of the segment.
-<code><nobr>PRIVATE</nobr></code> segments do not get combined with any
-others by the linker; <code><nobr>PUBLIC</nobr></code> and
-<code><nobr>STACK</nobr></code> segments get concatenated together at link
-time; and <code><nobr>COMMON</nobr></code> segments all get overlaid on top
-of each other rather than stuck end-to-end.
-<li><code><nobr>ALIGN</nobr></code> is used, as shown above, to specify how
-many low bits of the segment start address must be forced to zero. The
-alignment value given may be any power of two from 1 to 4096; in reality,
-the only values supported are 1, 2, 4, 16, 256 and 4096, so if 8 is
-specified it will be rounded up to 16, and 32, 64 and 128 will all be
-rounded up to 256, and so on. Note that alignment to 4096-byte boundaries
-is a PharLap extension to the format and may not be supported by all
-linkers.
-<li><code><nobr>CLASS</nobr></code> can be used to specify the segment
-class; this feature indicates to the linker that segments of the same class
-should be placed near each other in the output file. The class name can be
-any word, e.g. <code><nobr>CLASS=CODE</nobr></code>.
-<li><code><nobr>OVERLAY</nobr></code>, like
-<code><nobr>CLASS</nobr></code>, is specified with an arbitrary word as an
-argument, and provides overlay information to an overlay-capable linker.
-<li>Segments can be declared as <code><nobr>USE16</nobr></code> or
-<code><nobr>USE32</nobr></code>, which has the effect of recording the
-choice in the object file and also ensuring that NASM's default assembly
-mode when assembling in that segment is 16-bit or 32-bit respectively.
-<li>When writing OS/2 object files, you should declare 32-bit segments as
-<code><nobr>FLAT</nobr></code>, which causes the default segment base for
-anything in the segment to be the special group
-<code><nobr>FLAT</nobr></code>, and also defines the group if it is not
-already defined.
-<li>The <code><nobr>obj</nobr></code> file format also allows segments to
-be declared as having a pre-defined absolute segment address, although no
-linkers are currently known to make sensible use of this feature;
-nevertheless, NASM allows you to declare a segment such as
-<code><nobr>SEGMENT SCREEN ABSOLUTE=0xB800</nobr></code> if you need to.
-The <code><nobr>ABSOLUTE</nobr></code> and <code><nobr>ALIGN</nobr></code>
-keywords are mutually exclusive.
-</ul>
-<p>NASM's default segment attributes are <code><nobr>PUBLIC</nobr></code>,
-<code><nobr>ALIGN=1</nobr></code>, no class, no overlay, and
-<code><nobr>USE16</nobr></code>.
-<h4><a name="section-7.4.2">7.4.2 <code><nobr>GROUP</nobr></code>: Defining Groups of Segments</a></h4>
-<p>The <code><nobr>obj</nobr></code> format also allows segments to be
-grouped, so that a single segment register can be used to refer to all the
-segments in a group. NASM therefore supplies the
-<code><nobr>GROUP</nobr></code> directive, whereby you can code
-<p><pre>
-segment data
-
- ; some data
-
-segment bss
-
- ; some uninitialized data
-
-group dgroup data bss
-</pre>
-<p>which will define a group called <code><nobr>dgroup</nobr></code> to
-contain the segments <code><nobr>data</nobr></code> and
-<code><nobr>bss</nobr></code>. Like <code><nobr>SEGMENT</nobr></code>,
-<code><nobr>GROUP</nobr></code> causes the group name to be defined as a
-symbol, so that you can refer to a variable <code><nobr>var</nobr></code>
-in the <code><nobr>data</nobr></code> segment as
-<code><nobr>var wrt data</nobr></code> or as
-<code><nobr>var wrt dgroup</nobr></code>, depending on which segment value
-is currently in your segment register.
-<p>If you just refer to <code><nobr>var</nobr></code>, however, and
-<code><nobr>var</nobr></code> is declared in a segment which is part of a
-group, then NASM will default to giving you the offset of
-<code><nobr>var</nobr></code> from the beginning of the <em>group</em>, not
-the <em>segment</em>. Therefore <code><nobr>SEG var</nobr></code>, also,
-will return the group base rather than the segment base.
-<p>NASM will allow a segment to be part of more than one group, but will
-generate a warning if you do this. Variables declared in a segment which is
-part of more than one group will default to being relative to the first
-group that was defined to contain the segment.
-<p>A group does not have to contain any segments; you can still make
-<code><nobr>WRT</nobr></code> references to a group which does not contain
-the variable you are referring to. OS/2, for example, defines the special
-group <code><nobr>FLAT</nobr></code> with no segments in it.
-<h4><a name="section-7.4.3">7.4.3 <code><nobr>UPPERCASE</nobr></code>: Disabling Case Sensitivity in Output</a></h4>
-<p>Although NASM itself is case sensitive, some OMF linkers are not;
-therefore it can be useful for NASM to output single-case object files. The
-<code><nobr>UPPERCASE</nobr></code> format-specific directive causes all
-segment, group and symbol names that are written to the object file to be
-forced to upper case just before being written. Within a source file, NASM
-is still case-sensitive; but the object file can be written entirely in
-upper case if desired.
-<p><code><nobr>UPPERCASE</nobr></code> is used alone on a line; it requires
-no parameters.
-<h4><a name="section-7.4.4">7.4.4 <code><nobr>IMPORT</nobr></code>: Importing DLL Symbols</a></h4>
-<p>The <code><nobr>IMPORT</nobr></code> format-specific directive defines a
-symbol to be imported from a DLL, for use if you are writing a DLL's import
-library in NASM. You still need to declare the symbol as
-<code><nobr>EXTERN</nobr></code> as well as using the
-<code><nobr>IMPORT</nobr></code> directive.
-<p>The <code><nobr>IMPORT</nobr></code> directive takes two required
-parameters, separated by white space, which are (respectively) the name of
-the symbol you wish to import and the name of the library you wish to
-import it from. For example:
-<p><pre>
- import WSAStartup wsock32.dll
-</pre>
-<p>A third optional parameter gives the name by which the symbol is known
-in the library you are importing it from, in case this is not the same as
-the name you wish the symbol to be known by to your code once you have
-imported it. For example:
-<p><pre>
- import asyncsel wsock32.dll WSAAsyncSelect
-</pre>
-<h4><a name="section-7.4.5">7.4.5 <code><nobr>EXPORT</nobr></code>: Exporting DLL Symbols</a></h4>
-<p>The <code><nobr>EXPORT</nobr></code> format-specific directive defines a
-global symbol to be exported as a DLL symbol, for use if you are writing a
-DLL in NASM. You still need to declare the symbol as
-<code><nobr>GLOBAL</nobr></code> as well as using the
-<code><nobr>EXPORT</nobr></code> directive.
-<p><code><nobr>EXPORT</nobr></code> takes one required parameter, which is
-the name of the symbol you wish to export, as it was defined in your source
-file. An optional second parameter (separated by white space from the
-first) gives the <em>external</em> name of the symbol: the name by which
-you wish the symbol to be known to programs using the DLL. If this name is
-the same as the internal name, you may leave the second parameter off.
-<p>Further parameters can be given to define attributes of the exported
-symbol. These parameters, like the second, are separated by white space. If
-further parameters are given, the external name must also be specified,
-even if it is the same as the internal name. The available attributes are:
-<ul>
-<li><code><nobr>resident</nobr></code> indicates that the exported name is
-to be kept resident by the system loader. This is an optimisation for
-frequently used symbols imported by name.
-<li><code><nobr>nodata</nobr></code> indicates that the exported symbol is
-a function which does not make use of any initialized data.
-<li><code><nobr>parm=NNN</nobr></code>, where <code><nobr>NNN</nobr></code>
-is an integer, sets the number of parameter words for the case in which the
-symbol is a call gate between 32-bit and 16-bit segments.
-<li>An attribute which is just a number indicates that the symbol should be
-exported with an identifying number (ordinal), and gives the desired
-number.
-</ul>
-<p>For example:
-<p><pre>
- export myfunc
- export myfunc TheRealMoreFormalLookingFunctionName
- export myfunc myfunc 1234 ; export by ordinal
- export myfunc myfunc resident parm=23 nodata
-</pre>
-<h4><a name="section-7.4.6">7.4.6 <code><nobr>..start</nobr></code>: Defining the Program Entry Point</a></h4>
-<p><code><nobr>OMF</nobr></code> linkers require exactly one of the object
-files being linked to define the program entry point, where execution will
-begin when the program is run. If the object file that defines the entry
-point is assembled using NASM, you specify the entry point by declaring the
-special symbol <code><nobr>..start</nobr></code> at the point where you
-wish execution to begin.
-<h4><a name="section-7.4.7">7.4.7 <code><nobr>obj</nobr></code> Extensions to the <code><nobr>EXTERN</nobr></code> Directive</a></h4>
-<p>If you declare an external symbol with the directive
-<p><pre>
- extern foo
-</pre>
-<p>then references such as <code><nobr>mov ax,foo</nobr></code> will give
-you the offset of <code><nobr>foo</nobr></code> from its preferred segment
-base (as specified in whichever module <code><nobr>foo</nobr></code> is
-actually defined in). So to access the contents of
-<code><nobr>foo</nobr></code> you will usually need to do something like
-<p><pre>
- mov ax,seg foo ; get preferred segment base
- mov es,ax ; move it into ES
- mov ax,[es:foo] ; and use offset `foo' from it
-</pre>
-<p>This is a little unwieldy, particularly if you know that an external is
-going to be accessible from a given segment or group, say
-<code><nobr>dgroup</nobr></code>. So if <code><nobr>DS</nobr></code>
-already contained <code><nobr>dgroup</nobr></code>, you could simply code
-<p><pre>
- mov ax,[foo wrt dgroup]
-</pre>
-<p>However, having to type this every time you want to access
-<code><nobr>foo</nobr></code> can be a pain; so NASM allows you to declare
-<code><nobr>foo</nobr></code> in the alternative form
-<p><pre>
- extern foo:wrt dgroup
-</pre>
-<p>This form causes NASM to pretend that the preferred segment base of
-<code><nobr>foo</nobr></code> is in fact <code><nobr>dgroup</nobr></code>;
-so the expression <code><nobr>seg foo</nobr></code> will now return
-<code><nobr>dgroup</nobr></code>, and the expression
-<code><nobr>foo</nobr></code> is equivalent to
-<code><nobr>foo wrt dgroup</nobr></code>.
-<p>This default-<code><nobr>WRT</nobr></code> mechanism can be used to make
-externals appear to be relative to any group or segment in your program. It
-can also be applied to common variables: see
-<a href="#section-7.4.8">section 7.4.8</a>.
-<h4><a name="section-7.4.8">7.4.8 <code><nobr>obj</nobr></code> Extensions to the <code><nobr>COMMON</nobr></code> Directive</a></h4>
-<p>The <code><nobr>obj</nobr></code> format allows common variables to be
-either near or far; NASM allows you to specify which your variables should
-be by the use of the syntax
-<p><pre>
-common nearvar 2:near ; `nearvar' is a near common
-common farvar 10:far ; and `farvar' is far
-</pre>
-<p>Far common variables may be greater in size than 64Kb, and so the OMF
-specification says that they are declared as a number of <em>elements</em>
-of a given size. So a 10-byte far common variable could be declared as ten
-one-byte elements, five two-byte elements, two five-byte elements or one
-ten-byte element.
-<p>Some <code><nobr>OMF</nobr></code> linkers require the element size, as
-well as the variable size, to match when resolving common variables
-declared in more than one module. Therefore NASM must allow you to specify
-the element size on your far common variables. This is done by the
-following syntax:
-<p><pre>
-common c_5by2 10:far 5 ; two five-byte elements
-common c_2by5 10:far 2 ; five two-byte elements
-</pre>
-<p>If no element size is specified, the default is 1. Also, the
-<code><nobr>FAR</nobr></code> keyword is not required when an element size
-is specified, since only far commons may have element sizes at all. So the
-above declarations could equivalently be
-<p><pre>
-common c_5by2 10:5 ; two five-byte elements
-common c_2by5 10:2 ; five two-byte elements
-</pre>
-<p>In addition to these extensions, the <code><nobr>COMMON</nobr></code>
-directive in <code><nobr>obj</nobr></code> also supports
-default-<code><nobr>WRT</nobr></code> specification like
-<code><nobr>EXTERN</nobr></code> does (explained in
-<a href="#section-7.4.7">section 7.4.7</a>). So you can also declare things
-like
-<p><pre>
-common foo 10:wrt dgroup
-common bar 16:far 2:wrt data
-common baz 24:wrt data:6
-</pre>
-<h3><a name="section-7.5">7.5 <code><nobr>win32</nobr></code>: Microsoft Win32 Object Files</a></h3>
-<p>The <code><nobr>win32</nobr></code> output format generates Microsoft
-Win32 object files, suitable for passing to Microsoft linkers such as
-Visual C++. Note that Borland Win32 compilers do not use this format, but
-use <code><nobr>obj</nobr></code> instead (see
-<a href="#section-7.4">section 7.4</a>).
-<p><code><nobr>win32</nobr></code> provides a default output file-name
-extension of <code><nobr>.obj</nobr></code>.
-<p>Note that although Microsoft say that Win32 object files follow the
-<code><nobr>COFF</nobr></code> (Common Object File Format) standard, the
-object files produced by Microsoft Win32 compilers are not compatible with
-COFF linkers such as DJGPP's, and vice versa. This is due to a difference
-of opinion over the precise semantics of PC-relative relocations. To
-produce COFF files suitable for DJGPP, use NASM's
-<code><nobr>coff</nobr></code> output format; conversely, the
-<code><nobr>coff</nobr></code> format does not produce object files that
-Win32 linkers can generate correct output from.
-<h4><a name="section-7.5.1">7.5.1 <code><nobr>win32</nobr></code> Extensions to the <code><nobr>SECTION</nobr></code> Directive</a></h4>
-<p>Like the <code><nobr>obj</nobr></code> format,
-<code><nobr>win32</nobr></code> allows you to specify additional
-information on the <code><nobr>SECTION</nobr></code> directive line, to
-control the type and properties of sections you declare. Section types and
-properties are generated automatically by NASM for the standard section
-names <code><nobr>.text</nobr></code>, <code><nobr>.data</nobr></code> and
-<code><nobr>.bss</nobr></code>, but may still be overridden by these
-qualifiers.
-<p>The available qualifiers are:
-<ul>
-<li><code><nobr>code</nobr></code>, or equivalently
-<code><nobr>text</nobr></code>, defines the section to be a code section.
-This marks the section as readable and executable, but not writable, and
-also indicates to the linker that the type of the section is code.
-<li><code><nobr>data</nobr></code> and <code><nobr>bss</nobr></code> define
-the section to be a data section, analogously to
-<code><nobr>code</nobr></code>. Data sections are marked as readable and
-writable, but not executable. <code><nobr>data</nobr></code> declares an
-initialized data section, whereas <code><nobr>bss</nobr></code> declares an
-uninitialized data section.
-<li><code><nobr>rdata</nobr></code> declares an initialized data section
-that is readable but not writable. Microsoft compilers use this section to
-place constants in it.
-<li><code><nobr>info</nobr></code> defines the section to be an
-informational section, which is not included in the executable file by the
-linker, but may (for example) pass information <em>to</em> the linker. For
-example, declaring an <code><nobr>info</nobr></code>-type section called
-<code><nobr>.drectve</nobr></code> causes the linker to interpret the
-contents of the section as command-line options.
-<li><code><nobr>align=</nobr></code>, used with a trailing number as in
-<code><nobr>obj</nobr></code>, gives the alignment requirements of the
-section. The maximum you may specify is 64: the Win32 object file format
-contains no means to request a greater section alignment than this. If
-alignment is not explicitly specified, the defaults are 16-byte alignment
-for code sections, 8-byte alignment for rdata sections and 4-byte alignment
-for data (and BSS) sections. Informational sections get a default alignment
-of 1 byte (no alignment), though the value does not matter.
-</ul>
-<p>The defaults assumed by NASM if you do not specify the above qualifiers
-are:
-<p><pre>
-section .text code align=16
-section .data data align=4
-section .rdata rdata align=8
-section .bss bss align=4
-</pre>
-<p>Any other section name is treated by default like
-<code><nobr>.text</nobr></code>.
-<h4><a name="section-7.5.2">7.5.2 <code><nobr>win32</nobr></code>: Safe Structured Exception Handling</a></h4>
-<p>Among other improvements in Windows XP SP2 and Windows Server 2003
-Microsoft has introduced concept of "safe structured exception handling."
-General idea is to collect handlers' entry points in designated read-only
-table and have alleged entry point verified against this table prior
-exception control is passed to the handler. In order for an executable
-module to be equipped with such "safe exception handler table," all object
-modules on linker command line has to comply with certain criteria. If one
-single module among them does not, then the table in question is omitted
-and above mentioned run-time checks will not be performed for application
-in question. Table omission is by default silent and therefore can be
-easily overlooked. One can instruct linker to refuse to produce binary
-without such table by passing <code><nobr>/safeseh</nobr></code> command
-line option.
-<p>Without regard to this run-time check merits it's natural to expect NASM
-to be capable of generating modules suitable for
-<code><nobr>/safeseh</nobr></code> linking. From developer's viewpoint the
-problem is two-fold:
-<ul>
-<li>how to adapt modules not deploying exception handlers of their own;
-<li>how to adapt/develop modules utilizing custom exception handling;
-</ul>
-<p>Former can be easily achieved with any NASM version by adding following
-line to source code:
-<p><pre>
-$@feat.00 equ 1
-</pre>
-<p>As of version 2.03 NASM adds this absolute symbol automatically. If it's
-not already present to be precise. I.e. if for whatever reason developer
-would choose to assign another value in source file, it would still be
-perfectly possible.
-<p>Registering custom exception handler on the other hand requires certain
-"magic." As of version 2.03 additional directive is implemented,
-<code><nobr>safeseh</nobr></code>, which instructs the assembler to produce
-appropriately formatted input data for above mentioned "safe exception
-handler table." Its typical use would be:
-<p><pre>
-section .text
-extern _MessageBoxA@16
-%if __NASM_VERSION_ID__ &gt;= 0x02030000
-safeseh handler ; register handler as "safe handler"
-%endif
-handler:
- push DWORD 1 ; MB_OKCANCEL
- push DWORD caption
- push DWORD text
- push DWORD 0
- call _MessageBoxA@16
- sub eax,1 ; incidentally suits as return value
- ; for exception handler
- ret
-global _main
-_main:
- push DWORD handler
- push DWORD [fs:0]
- mov DWORD [fs:0],esp ; engage exception handler
- xor eax,eax
- mov eax,DWORD[eax] ; cause exception
- pop DWORD [fs:0] ; disengage exception handler
- add esp,4
- ret
-text: db 'OK to rethrow, CANCEL to generate core dump',0
-caption:db 'SEGV',0
-
-section .drectve info
- db '/defaultlib:user32.lib /defaultlib:msvcrt.lib '
-</pre>
-<p>As you might imagine, it's perfectly possible to produce .exe binary
-with "safe exception handler table" and yet engage unregistered exception
-handler. Indeed, handler is engaged by simply manipulating
-<code><nobr>[fs:0]</nobr></code> location at run-time, something linker has
-no power over, run-time that is. It should be explicitly mentioned that
-such failure to register handler's entry point with
-<code><nobr>safeseh</nobr></code> directive has undesired side effect at
-run-time. If exception is raised and unregistered handler is to be
-executed, the application is abruptly terminated without any notification
-whatsoever. One can argue that system could at least have logged some kind
-"non-safe exception handler in x.exe at address n" message in event log,
-but no, literally no notification is provided and user is left with no clue
-on what caused application failure.
-<p>Finally, all mentions of linker in this paragraph refer to Microsoft
-linker version 7.x and later. Presence of
-<code><nobr>@feat.00</nobr></code> symbol and input data for "safe
-exception handler table" causes no backward incompatibilities and "safeseh"
-modules generated by NASM 2.03 and later can still be linked by earlier
-versions or non-Microsoft linkers.
-<h3><a name="section-7.6">7.6 <code><nobr>win64</nobr></code>: Microsoft Win64 Object Files</a></h3>
-<p>The <code><nobr>win64</nobr></code> output format generates Microsoft
-Win64 object files, which is nearly 100% identical to the
-<code><nobr>win32</nobr></code> object format
-(<a href="#section-7.5">section 7.5</a>) with the exception that it is
-meant to target 64-bit code and the x86-64 platform altogether. This object
-file is used exactly the same as the <code><nobr>win32</nobr></code> object
-format (<a href="#section-7.5">section 7.5</a>), in NASM, with regard to
-this exception.
-<h4><a name="section-7.6.1">7.6.1 <code><nobr>win64</nobr></code>: Writing Position-Independent Code</a></h4>
-<p>While <code><nobr>REL</nobr></code> takes good care of RIP-relative
-addressing, there is one aspect that is easy to overlook for a Win64
-programmer: indirect references. Consider a switch dispatch table:
-<p><pre>
- jmp QWORD[dsptch+rax*8]
- ...
-dsptch: dq case0
- dq case1
- ...
-</pre>
-<p>Even novice Win64 assembler programmer will soon realize that the code
-is not 64-bit savvy. Most notably linker will refuse to link it with
-"<code><nobr>'ADDR32' relocation to '.text' invalid without /LARGEADDRESSAWARE:NO</nobr></code>".
-So [s]he will have to split jmp instruction as following:
-<p><pre>
- lea rbx,[rel dsptch]
- jmp QWORD[rbx+rax*8]
-</pre>
-<p>What happens behind the scene is that effective address in
-<code><nobr>lea</nobr></code> is encoded relative to instruction pointer,
-or in perfectly position-independent manner. But this is only part of the
-problem! Trouble is that in .dll context <code><nobr>caseN</nobr></code>
-relocations will make their way to the final module and might have to be
-adjusted at .dll load time. To be specific when it can't be loaded at
-preferred address. And when this occurs, pages with such relocations will
-be rendered private to current process, which kind of undermines the idea
-of sharing .dll. But no worry, it's trivial to fix:
-<p><pre>
- lea rbx,[rel dsptch]
- add rbx,QWORD[rbx+rax*8]
- jmp rbx
- ...
-dsptch: dq case0-dsptch
- dq case1-dsptch
- ...
-</pre>
-<p>NASM version 2.03 and later provides another alternative,
-<code><nobr>wrt ..imagebase</nobr></code> operator, which returns offset
-from base address of the current image, be it .exe or .dll module,
-therefore the name. For those acquainted with PE-COFF format base address
-denotes start of <code><nobr>IMAGE_DOS_HEADER</nobr></code> structure. Here
-is how to implement switch with these image-relative references:
-<p><pre>
- lea rbx,[rel dsptch]
- mov eax,DWORD[rbx+rax*4]
- sub rbx,dsptch wrt ..imagebase
- add rbx,rax
- jmp rbx
- ...
-dsptch: dd case0 wrt ..imagebase
- dd case1 wrt ..imagebase
-</pre>
-<p>One can argue that the operator is redundant. Indeed, snippet before
-last works just fine with any NASM version and is not even Windows
-specific... The real reason for implementing
-<code><nobr>wrt ..imagebase</nobr></code> will become apparent in next
-paragraph.
-<p>It should be noted that <code><nobr>wrt ..imagebase</nobr></code> is
-defined as 32-bit operand only:
-<p><pre>
- dd label wrt ..imagebase ; ok
- dq label wrt ..imagebase ; bad
- mov eax,label wrt ..imagebase ; ok
- mov rax,label wrt ..imagebase ; bad
-</pre>
-<h4><a name="section-7.6.2">7.6.2 <code><nobr>win64</nobr></code>: Structured Exception Handling</a></h4>
-<p>Structured exception handing in Win64 is completely different matter
-from Win32. Upon exception program counter value is noted, and
-linker-generated table comprising start and end addresses of all the
-functions [in given executable module] is traversed and compared to the
-saved program counter. Thus so called <code><nobr>UNWIND_INFO</nobr></code>
-structure is identified. If it's not found, then offending subroutine is
-assumed to be "leaf" and just mentioned lookup procedure is attempted for
-its caller. In Win64 leaf function is such function that does not call any
-other function <em>nor</em> modifies any Win64 non-volatile registers,
-including stack pointer. The latter ensures that it's possible to identify
-leaf function's caller by simply pulling the value from the top of the
-stack.
-<p>While majority of subroutines written in assembler are not calling any
-other function, requirement for non-volatile registers' immutability leaves
-developer with not more than 7 registers and no stack frame, which is not
-necessarily what [s]he counted with. Customarily one would meet the
-requirement by saving non-volatile registers on stack and restoring them
-upon return, so what can go wrong? If [and only if] an exception is raised
-at run-time and no <code><nobr>UNWIND_INFO</nobr></code> structure is
-associated with such "leaf" function, the stack unwind procedure will
-expect to find caller's return address on the top of stack immediately
-followed by its frame. Given that developer pushed caller's non-volatile
-registers on stack, would the value on top point at some code segment or
-even addressable space? Well, developer can attempt copying caller's return
-address to the top of stack and this would actually work in some very
-specific circumstances. But unless developer can guarantee that these
-circumstances are always met, it's more appropriate to assume worst case
-scenario, i.e. stack unwind procedure going berserk. Relevant question is
-what happens then? Application is abruptly terminated without any
-notification whatsoever. Just like in Win32 case, one can argue that system
-could at least have logged "unwind procedure went berserk in x.exe at
-address n" in event log, but no, no trace of failure is left.
-<p>Now, when we understand significance of the
-<code><nobr>UNWIND_INFO</nobr></code> structure, let's discuss what's in it
-and/or how it's processed. First of all it is checked for presence of
-reference to custom language-specific exception handler. If there is one,
-then it's invoked. Depending on the return value, execution flow is resumed
-(exception is said to be "handled"), <em>or</em> rest of
-<code><nobr>UNWIND_INFO</nobr></code> structure is processed as following.
-Beside optional reference to custom handler, it carries information about
-current callee's stack frame and where non-volatile registers are saved.
-Information is detailed enough to be able to reconstruct contents of
-caller's non-volatile registers upon call to current callee. And so
-caller's context is reconstructed, and then unwind procedure is repeated,
-i.e. another <code><nobr>UNWIND_INFO</nobr></code> structure is associated,
-this time, with caller's instruction pointer, which is then checked for
-presence of reference to language-specific handler, etc. The procedure is
-recursively repeated till exception is handled. As last resort system
-"handles" it by generating memory core dump and terminating the
-application.
-<p>As for the moment of this writing NASM unfortunately does not facilitate
-generation of above mentioned detailed information about stack frame
-layout. But as of version 2.03 it implements building blocks for generating
-structures involved in stack unwinding. As simplest example, here is how to
-deploy custom exception handler for leaf function:
-<p><pre>
-default rel
-section .text
-extern MessageBoxA
-handler:
- sub rsp,40
- mov rcx,0
- lea rdx,[text]
- lea r8,[caption]
- mov r9,1 ; MB_OKCANCEL
- call MessageBoxA
- sub eax,1 ; incidentally suits as return value
- ; for exception handler
- add rsp,40
- ret
-global main
-main:
- xor rax,rax
- mov rax,QWORD[rax] ; cause exception
- ret
-main_end:
-text: db 'OK to rethrow, CANCEL to generate core dump',0
-caption:db 'SEGV',0
-
-section .pdata rdata align=4
- dd main wrt ..imagebase
- dd main_end wrt ..imagebase
- dd xmain wrt ..imagebase
-section .xdata rdata align=8
-xmain: db 9,0,0,0
- dd handler wrt ..imagebase
-section .drectve info
- db '/defaultlib:user32.lib /defaultlib:msvcrt.lib '
-</pre>
-<p>What you see in <code><nobr>.pdata</nobr></code> section is element of
-the "table comprising start and end addresses of function" along with
-reference to associated <code><nobr>UNWIND_INFO</nobr></code> structure.
-And what you see in <code><nobr>.xdata</nobr></code> section is
-<code><nobr>UNWIND_INFO</nobr></code> structure describing function with no
-frame, but with designated exception handler. References are
-<em>required</em> to be image-relative (which is the real reason for
-implementing <code><nobr>wrt ..imagebase</nobr></code> operator). It should
-be noted that <code><nobr>rdata align=n</nobr></code>, as well as
-<code><nobr>wrt ..imagebase</nobr></code>, are optional in these two
-segments' contexts, i.e. can be omitted. Latter means that <em>all</em>
-32-bit references, not only above listed required ones, placed into these
-two segments turn out image-relative. Why is it important to understand?
-Developer is allowed to append handler-specific data to
-<code><nobr>UNWIND_INFO</nobr></code> structure, and if [s]he adds a 32-bit
-reference, then [s]he will have to remember to adjust its value to obtain
-the real pointer.
-<p>As already mentioned, in Win64 terms leaf function is one that does not
-call any other function <em>nor</em> modifies any non-volatile register,
-including stack pointer. But it's not uncommon that assembler programmer
-plans to utilize every single register and sometimes even have variable
-stack frame. Is there anything one can do with bare building blocks? I.e.
-besides manually composing fully-fledged
-<code><nobr>UNWIND_INFO</nobr></code> structure, which would surely be
-considered error-prone? Yes, there is. Recall that exception handler is
-called first, before stack layout is analyzed. As it turned out, it's
-perfectly possible to manipulate current callee's context in custom handler
-in manner that permits further stack unwinding. General idea is that
-handler would not actually "handle" the exception, but instead restore
-callee's context, as it was at its entry point and thus mimic leaf
-function. In other words, handler would simply undertake part of unwinding
-procedure. Consider following example:
-<p><pre>
-function:
- mov rax,rsp ; copy rsp to volatile register
- push r15 ; save non-volatile registers
- push rbx
- push rbp
- mov r11,rsp ; prepare variable stack frame
- sub r11,rcx
- and r11,-64
- mov QWORD[r11],rax ; check for exceptions
- mov rsp,r11 ; allocate stack frame
- mov QWORD[rsp],rax ; save original rsp value
-magic_point:
- ...
- mov r11,QWORD[rsp] ; pull original rsp value
- mov rbp,QWORD[r11-24]
- mov rbx,QWORD[r11-16]
- mov r15,QWORD[r11-8]
- mov rsp,r11 ; destroy frame
- ret
-</pre>
-<p>The keyword is that up to <code><nobr>magic_point</nobr></code> original
-<code><nobr>rsp</nobr></code> value remains in chosen volatile register and
-no non-volatile register, except for <code><nobr>rsp</nobr></code>, is
-modified. While past <code><nobr>magic_point</nobr></code>
-<code><nobr>rsp</nobr></code> remains constant till the very end of the
-<code><nobr>function</nobr></code>. In this case custom language-specific
-exception handler would look like this:
-<p><pre>
-EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame,
- CONTEXT *context,DISPATCHER_CONTEXT *disp)
-{ ULONG64 *rsp;
- if (context-&gt;Rip&lt;(ULONG64)magic_point)
- rsp = (ULONG64 *)context-&gt;Rax;
- else
- { rsp = ((ULONG64 **)context-&gt;Rsp)[0];
- context-&gt;Rbp = rsp[-3];
- context-&gt;Rbx = rsp[-2];
- context-&gt;R15 = rsp[-1];
- }
- context-&gt;Rsp = (ULONG64)rsp;
-
- memcpy (disp-&gt;ContextRecord,context,sizeof(CONTEXT));
- RtlVirtualUnwind(UNW_FLAG_NHANDLER,disp-&gt;ImageBase,
- dips-&gt;ControlPc,disp-&gt;FunctionEntry,disp-&gt;ContextRecord,
- &amp;disp-&gt;HandlerData,&amp;disp-&gt;EstablisherFrame,NULL);
- return ExceptionContinueSearch;
-}
-</pre>
-<p>As custom handler mimics leaf function, corresponding
-<code><nobr>UNWIND_INFO</nobr></code> structure does not have to contain
-any information about stack frame and its layout.
-<h3><a name="section-7.7">7.7 <code><nobr>coff</nobr></code>: Common Object File Format</a></h3>
-<p>The <code><nobr>coff</nobr></code> output type produces
-<code><nobr>COFF</nobr></code> object files suitable for linking with the
-DJGPP linker.
-<p><code><nobr>coff</nobr></code> provides a default output file-name
-extension of <code><nobr>.o</nobr></code>.
-<p>The <code><nobr>coff</nobr></code> format supports the same extensions
-to the <code><nobr>SECTION</nobr></code> directive as
-<code><nobr>win32</nobr></code> does, except that the
-<code><nobr>align</nobr></code> qualifier and the
-<code><nobr>info</nobr></code> section type are not supported.
-<h3><a name="section-7.8">7.8 <code><nobr>macho32</nobr></code> and <code><nobr>macho64</nobr></code>: Mach Object File Format</a></h3>
-<p>The <code><nobr>macho32</nobr></code> and
-<code><nobr>macho64</nobr></code> output formts produces
-<code><nobr>Mach-O</nobr></code> object files suitable for linking with the
-MacOS X linker. <code><nobr>macho</nobr></code> is a synonym for
-<code><nobr>macho32</nobr></code>.
-<p><code><nobr>macho</nobr></code> provides a default output file-name
-extension of <code><nobr>.o</nobr></code>.
-<h3><a name="section-7.9">7.9 <code><nobr>elf32</nobr></code> and <code><nobr>elf64</nobr></code>: Executable and Linkable Format Object Files</a></h3>
-<p>The <code><nobr>elf32</nobr></code> and <code><nobr>elf64</nobr></code>
-output formats generate <code><nobr>ELF32 and ELF64</nobr></code>
-(Executable and Linkable Format) object files, as used by Linux as well as
-Unix System V, including Solaris x86, UnixWare and SCO Unix.
-<code><nobr>elf</nobr></code> provides a default output file-name extension
-of <code><nobr>.o</nobr></code>. <code><nobr>elf</nobr></code> is a synonym
-for <code><nobr>elf32</nobr></code>.
-<h4><a name="section-7.9.1">7.9.1 ELF specific directive <code><nobr>osabi</nobr></code></a></h4>
-<p>The ELF header specifies the application binary interface for the target
-operating system (OSABI). This field can be set by using the
-<code><nobr>osabi</nobr></code> directive with the numeric value (0-255) of
-the target system. If this directive is not used, the default value will be
-"UNIX System V ABI" (0) which will work on most systems which support ELF.
-<h4><a name="section-7.9.2">7.9.2 <code><nobr>elf</nobr></code> Extensions to the <code><nobr>SECTION</nobr></code> Directive</a></h4>
-<p>Like the <code><nobr>obj</nobr></code> format,
-<code><nobr>elf</nobr></code> allows you to specify additional information
-on the <code><nobr>SECTION</nobr></code> directive line, to control the
-type and properties of sections you declare. Section types and properties
-are generated automatically by NASM for the standard section names, but may
-still be overridden by these qualifiers.
-<p>The available qualifiers are:
-<ul>
-<li><code><nobr>alloc</nobr></code> defines the section to be one which is
-loaded into memory when the program is run.
-<code><nobr>noalloc</nobr></code> defines it to be one which is not, such
-as an informational or comment section.
-<li><code><nobr>exec</nobr></code> defines the section to be one which
-should have execute permission when the program is run.
-<code><nobr>noexec</nobr></code> defines it as one which should not.
-<li><code><nobr>write</nobr></code> defines the section to be one which
-should be writable when the program is run.
-<code><nobr>nowrite</nobr></code> defines it as one which should not.
-<li><code><nobr>progbits</nobr></code> defines the section to be one with
-explicit contents stored in the object file: an ordinary code or data
-section, for example, <code><nobr>nobits</nobr></code> defines the section
-to be one with no explicit contents given, such as a BSS section.
-<li><code><nobr>align=</nobr></code>, used with a trailing number as in
-<code><nobr>obj</nobr></code>, gives the alignment requirements of the
-section.
-<li><code><nobr>tls</nobr></code> defines the section to be one which
-contains thread local variables.
-</ul>
-<p>The defaults assumed by NASM if you do not specify the above qualifiers
-are:
-<p>
-<p><pre>
-section .text progbits alloc exec nowrite align=16
-section .rodata progbits alloc noexec nowrite align=4
-section .lrodata progbits alloc noexec nowrite align=4
-section .data progbits alloc noexec write align=4
-section .ldata progbits alloc noexec write align=4
-section .bss nobits alloc noexec write align=4
-section .lbss nobits alloc noexec write align=4
-section .tdata progbits alloc noexec write align=4 tls
-section .tbss nobits alloc noexec write align=4 tls
-section .comment progbits noalloc noexec nowrite align=1
-section other progbits alloc noexec nowrite align=1
-</pre>
-<p>(Any section name other than those in the above table is treated by
-default like <code><nobr>other</nobr></code> in the above table. Please
-note that section names are case sensitive.)
-<h4><a name="section-7.9.3">7.9.3 Position-Independent Code: <code><nobr>elf</nobr></code> Special Symbols and <code><nobr>WRT</nobr></code></a></h4>
-<p>The <code><nobr>ELF</nobr></code> specification contains enough features
-to allow position-independent code (PIC) to be written, which makes ELF
-shared libraries very flexible. However, it also means NASM has to be able
-to generate a variety of ELF specific relocation types in ELF object files,
-if it is to be an assembler which can write PIC.
-<p>Since <code><nobr>ELF</nobr></code> does not support segment-base
-references, the <code><nobr>WRT</nobr></code> operator is not used for its
-normal purpose; therefore NASM's <code><nobr>elf</nobr></code> output
-format makes use of <code><nobr>WRT</nobr></code> for a different purpose,
-namely the PIC-specific relocation types.
-<p><code><nobr>elf</nobr></code> defines five special symbols which you can
-use as the right-hand side of the <code><nobr>WRT</nobr></code> operator to
-obtain PIC relocation types. They are <code><nobr>..gotpc</nobr></code>,
-<code><nobr>..gotoff</nobr></code>, <code><nobr>..got</nobr></code>,
-<code><nobr>..plt</nobr></code> and <code><nobr>..sym</nobr></code>. Their
-functions are summarized here:
-<ul>
-<li>Referring to the symbol marking the global offset table base using
-<code><nobr>wrt ..gotpc</nobr></code> will end up giving the distance from
-the beginning of the current section to the global offset table.
-(<code><nobr>_GLOBAL_OFFSET_TABLE_</nobr></code> is the standard symbol
-name used to refer to the GOT.) So you would then need to add
-<code><nobr>$$</nobr></code> to the result to get the real address of the
-GOT.
-<li>Referring to a location in one of your own sections using
-<code><nobr>wrt ..gotoff</nobr></code> will give the distance from the
-beginning of the GOT to the specified location, so that adding on the
-address of the GOT would give the real address of the location you wanted.
-<li>Referring to an external or global symbol using
-<code><nobr>wrt ..got</nobr></code> causes the linker to build an entry
-<em>in</em> the GOT containing the address of the symbol, and the reference
-gives the distance from the beginning of the GOT to the entry; so you can
-add on the address of the GOT, load from the resulting address, and end up
-with the address of the symbol.
-<li>Referring to a procedure name using <code><nobr>wrt ..plt</nobr></code>
-causes the linker to build a procedure linkage table entry for the symbol,
-and the reference gives the address of the PLT entry. You can only use this
-in contexts which would generate a PC-relative relocation normally (i.e. as
-the destination for <code><nobr>CALL</nobr></code> or
-<code><nobr>JMP</nobr></code>), since ELF contains no relocation type to
-refer to PLT entries absolutely.
-<li>Referring to a symbol name using <code><nobr>wrt ..sym</nobr></code>
-causes NASM to write an ordinary relocation, but instead of making the
-relocation relative to the start of the section and then adding on the
-offset to the symbol, it will write a relocation record aimed directly at
-the symbol in question. The distinction is a necessary one due to a
-peculiarity of the dynamic linker.
-</ul>
-<p>A fuller explanation of how to use these relocation types to write
-shared libraries entirely in NASM is given in
-<a href="nasmdoc9.html#section-9.2">section 9.2</a>.
-<h4><a name="section-7.9.4">7.9.4 Thread Local Storage: <code><nobr>elf</nobr></code> Special Symbols and <code><nobr>WRT</nobr></code></a></h4>
-<ul>
-<li>In ELF32 mode, referring to an external or global symbol using
-<code><nobr>wrt ..tlsie</nobr></code> causes the linker to build an entry
-<em>in</em> the GOT containing the offset of the symbol within the TLS
-block, so you can access the value of the symbol with code such as:
-</ul>
-<p><pre>
- mov eax,[tid wrt ..tlsie]
- mov [gs:eax],ebx
-</pre>
-<ul>
-<li>In ELF64 mode, referring to an external or global symbol using
-<code><nobr>wrt ..gottpoff</nobr></code> causes the linker to build an
-entry <em>in</em> the GOT containing the offset of the symbol within the
-TLS block, so you can access the value of the symbol with code such as:
-</ul>
-<p><pre>
- mov rax,[rel tid wrt ..gottpoff]
- mov rcx,[fs:rax]
-</pre>
-<h4><a name="section-7.9.5">7.9.5 <code><nobr>elf</nobr></code> Extensions to the <code><nobr>GLOBAL</nobr></code> Directive</a></h4>
-<p><code><nobr>ELF</nobr></code> object files can contain more information
-about a global symbol than just its address: they can contain the size of
-the symbol and its type as well. These are not merely debugger
-conveniences, but are actually necessary when the program being written is
-a shared library. NASM therefore supports some extensions to the
-<code><nobr>GLOBAL</nobr></code> directive, allowing you to specify these
-features.
-<p>You can specify whether a global variable is a function or a data object
-by suffixing the name with a colon and the word
-<code><nobr>function</nobr></code> or <code><nobr>data</nobr></code>.
-(<code><nobr>object</nobr></code> is a synonym for
-<code><nobr>data</nobr></code>.) For example:
-<p><pre>
-global hashlookup:function, hashtable:data
-</pre>
-<p>exports the global symbol <code><nobr>hashlookup</nobr></code> as a
-function and <code><nobr>hashtable</nobr></code> as a data object.
-<p>Optionally, you can control the ELF visibility of the symbol. Just add
-one of the visibility keywords: <code><nobr>default</nobr></code>,
-<code><nobr>internal</nobr></code>, <code><nobr>hidden</nobr></code>, or
-<code><nobr>protected</nobr></code>. The default is
-<code><nobr>default</nobr></code> of course. For example, to make
-<code><nobr>hashlookup</nobr></code> hidden:
-<p><pre>
-global hashlookup:function hidden
-</pre>
-<p>You can also specify the size of the data associated with the symbol, as
-a numeric expression (which may involve labels, and even forward
-references) after the type specifier. Like this:
-<p><pre>
-global hashtable:data (hashtable.end - hashtable)
-
-hashtable:
- db this,that,theother ; some data here
-.end:
-</pre>
-<p>This makes NASM automatically calculate the length of the table and
-place that information into the <code><nobr>ELF</nobr></code> symbol table.
-<p>Declaring the type and size of global symbols is necessary when writing
-shared library code. For more information, see
-<a href="nasmdoc9.html#section-9.2.4">section 9.2.4</a>.
-<h4><a name="section-7.9.6">7.9.6 <code><nobr>elf</nobr></code> Extensions to the <code><nobr>COMMON</nobr></code> Directive </a></h4>
-<p><code><nobr>ELF</nobr></code> also allows you to specify alignment
-requirements on common variables. This is done by putting a number (which
-must be a power of two) after the name and size of the common variable,
-separated (as usual) by a colon. For example, an array of doublewords would
-benefit from 4-byte alignment:
-<p><pre>
-common dwordarray 128:4
-</pre>
-<p>This declares the total size of the array to be 128 bytes, and requires
-that it be aligned on a 4-byte boundary.
-<h4><a name="section-7.9.7">7.9.7 16-bit code and ELF </a></h4>
-<p>The <code><nobr>ELF32</nobr></code> specification doesn't provide
-relocations for 8- and 16-bit values, but the GNU
-<code><nobr>ld</nobr></code> linker adds these as an extension. NASM can
-generate GNU-compatible relocations, to allow 16-bit code to be linked as
-ELF using GNU <code><nobr>ld</nobr></code>. If NASM is used with the
-<code><nobr>-w+gnu-elf-extensions</nobr></code> option, a warning is issued
-when one of these relocations is generated.
-<h4><a name="section-7.9.8">7.9.8 Debug formats and ELF </a></h4>
-<p><code><nobr>ELF32</nobr></code> and <code><nobr>ELF64</nobr></code>
-provide debug information in <code><nobr>STABS</nobr></code> and
-<code><nobr>DWARF</nobr></code> formats. Line number information is
-generated for all executable sections, but please note that only the
-".text" section is executable by default.
-<h3><a name="section-7.10">7.10 <code><nobr>aout</nobr></code>: Linux <code><nobr>a.out</nobr></code> Object Files</a></h3>
-<p>The <code><nobr>aout</nobr></code> format generates
-<code><nobr>a.out</nobr></code> object files, in the form used by early
-Linux systems (current Linux systems use ELF, see
-<a href="#section-7.9">section 7.9</a>.) These differ from other
-<code><nobr>a.out</nobr></code> object files in that the magic number in
-the first four bytes of the file is different; also, some implementations
-of <code><nobr>a.out</nobr></code>, for example NetBSD's, support
-position-independent code, which Linux's implementation does not.
-<p><code><nobr>a.out</nobr></code> provides a default output file-name
-extension of <code><nobr>.o</nobr></code>.
-<p><code><nobr>a.out</nobr></code> is a very simple object format. It
-supports no special directives, no special symbols, no use of
-<code><nobr>SEG</nobr></code> or <code><nobr>WRT</nobr></code>, and no
-extensions to any standard directives. It supports only the three standard
-section names <code><nobr>.text</nobr></code>,
-<code><nobr>.data</nobr></code> and <code><nobr>.bss</nobr></code>.
-<h3><a name="section-7.11">7.11 <code><nobr>aoutb</nobr></code>: NetBSD/FreeBSD/OpenBSD <code><nobr>a.out</nobr></code> Object Files</a></h3>
-<p>The <code><nobr>aoutb</nobr></code> format generates
-<code><nobr>a.out</nobr></code> object files, in the form used by the
-various free <code><nobr>BSD Unix</nobr></code> clones,
-<code><nobr>NetBSD</nobr></code>, <code><nobr>FreeBSD</nobr></code> and
-<code><nobr>OpenBSD</nobr></code>. For simple object files, this object
-format is exactly the same as <code><nobr>aout</nobr></code> except for the
-magic number in the first four bytes of the file. However, the
-<code><nobr>aoutb</nobr></code> format supports position-independent code
-in the same way as the <code><nobr>elf</nobr></code> format, so you can use
-it to write <code><nobr>BSD</nobr></code> shared libraries.
-<p><code><nobr>aoutb</nobr></code> provides a default output file-name
-extension of <code><nobr>.o</nobr></code>.
-<p><code><nobr>aoutb</nobr></code> supports no special directives, no
-special symbols, and only the three standard section names
-<code><nobr>.text</nobr></code>, <code><nobr>.data</nobr></code> and
-<code><nobr>.bss</nobr></code>. However, it also supports the same use of
-<code><nobr>WRT</nobr></code> as <code><nobr>elf</nobr></code> does, to
-provide position-independent code relocation types. See
-<a href="#section-7.9.3">section 7.9.3</a> for full documentation of this
-feature.
-<p><code><nobr>aoutb</nobr></code> also supports the same extensions to the
-<code><nobr>GLOBAL</nobr></code> directive as <code><nobr>elf</nobr></code>
-does: see <a href="#section-7.9.5">section 7.9.5</a> for documentation of
-this.
-<h3><a name="section-7.12">7.12 <code><nobr>as86</nobr></code>: Minix/Linux <code><nobr>as86</nobr></code> Object Files</a></h3>
-<p>The Minix/Linux 16-bit assembler <code><nobr>as86</nobr></code> has its
-own non-standard object file format. Although its companion linker
-<code><nobr>ld86</nobr></code> produces something close to ordinary
-<code><nobr>a.out</nobr></code> binaries as output, the object file format
-used to communicate between <code><nobr>as86</nobr></code> and
-<code><nobr>ld86</nobr></code> is not itself
-<code><nobr>a.out</nobr></code>.
-<p>NASM supports this format, just in case it is useful, as
-<code><nobr>as86</nobr></code>. <code><nobr>as86</nobr></code> provides a
-default output file-name extension of <code><nobr>.o</nobr></code>.
-<p><code><nobr>as86</nobr></code> is a very simple object format (from the
-NASM user's point of view). It supports no special directives, no use of
-<code><nobr>SEG</nobr></code> or <code><nobr>WRT</nobr></code>, and no
-extensions to any standard directives. It supports only the three standard
-section names <code><nobr>.text</nobr></code>,
-<code><nobr>.data</nobr></code> and <code><nobr>.bss</nobr></code>. The
-only special symbol supported is <code><nobr>..start</nobr></code>.
-<h3><a name="section-7.13">7.13 <code><nobr>rdf</nobr></code>: Relocatable Dynamic Object File Format</a></h3>
-<p>The <code><nobr>rdf</nobr></code> output format produces
-<code><nobr>RDOFF</nobr></code> object files.
-<code><nobr>RDOFF</nobr></code> (Relocatable Dynamic Object File Format) is
-a home-grown object-file format, designed alongside NASM itself and
-reflecting in its file format the internal structure of the assembler.
-<p><code><nobr>RDOFF</nobr></code> is not used by any well-known operating
-systems. Those writing their own systems, however, may well wish to use
-<code><nobr>RDOFF</nobr></code> as their object format, on the grounds that
-it is designed primarily for simplicity and contains very little
-file-header bureaucracy.
-<p>The Unix NASM archive, and the DOS archive which includes sources, both
-contain an <code><nobr>rdoff</nobr></code> subdirectory holding a set of
-RDOFF utilities: an RDF linker, an <code><nobr>RDF</nobr></code>
-static-library manager, an RDF file dump utility, and a program which will
-load and execute an RDF executable under Linux.
-<p><code><nobr>rdf</nobr></code> supports only the standard section names
-<code><nobr>.text</nobr></code>, <code><nobr>.data</nobr></code> and
-<code><nobr>.bss</nobr></code>.
-<h4><a name="section-7.13.1">7.13.1 Requiring a Library: The <code><nobr>LIBRARY</nobr></code> Directive</a></h4>
-<p><code><nobr>RDOFF</nobr></code> contains a mechanism for an object file
-to demand a given library to be linked to the module, either at load time
-or run time. This is done by the <code><nobr>LIBRARY</nobr></code>
-directive, which takes one argument which is the name of the module:
-<p><pre>
- library mylib.rdl
-</pre>
-<h4><a name="section-7.13.2">7.13.2 Specifying a Module Name: The <code><nobr>MODULE</nobr></code> Directive</a></h4>
-<p>Special <code><nobr>RDOFF</nobr></code> header record is used to store
-the name of the module. It can be used, for example, by run-time loader to
-perform dynamic linking. <code><nobr>MODULE</nobr></code> directive takes
-one argument which is the name of current module:
-<p><pre>
- module mymodname
-</pre>
-<p>Note that when you statically link modules and tell linker to strip the
-symbols from output file, all module names will be stripped too. To avoid
-it, you should start module names with <code><nobr>$</nobr></code>, like:
-<p><pre>
- module $kernel.core
-</pre>
-<h4><a name="section-7.13.3">7.13.3 <code><nobr>rdf</nobr></code> Extensions to the <code><nobr>GLOBAL</nobr></code> Directive</a></h4>
-<p><code><nobr>RDOFF</nobr></code> global symbols can contain additional
-information needed by the static linker. You can mark a global symbol as
-exported, thus telling the linker do not strip it from target executable or
-library file. Like in <code><nobr>ELF</nobr></code>, you can also specify
-whether an exported symbol is a procedure (function) or data object.
-<p>Suffixing the name with a colon and the word
-<code><nobr>export</nobr></code> you make the symbol exported:
-<p><pre>
- global sys_open:export
-</pre>
-<p>To specify that exported symbol is a procedure (function), you add the
-word <code><nobr>proc</nobr></code> or <code><nobr>function</nobr></code>
-after declaration:
-<p><pre>
- global sys_open:export proc
-</pre>
-<p>Similarly, to specify exported data object, add the word
-<code><nobr>data</nobr></code> or <code><nobr>object</nobr></code> to the
-directive:
-<p><pre>
- global kernel_ticks:export data
-</pre>
-<h4><a name="section-7.13.4">7.13.4 <code><nobr>rdf</nobr></code> Extensions to the <code><nobr>EXTERN</nobr></code> Directive</a></h4>
-<p>By default the <code><nobr>EXTERN</nobr></code> directive in
-<code><nobr>RDOFF</nobr></code> declares a "pure external" symbol (i.e. the
-static linker will complain if such a symbol is not resolved). To declare
-an "imported" symbol, which must be resolved later during a dynamic linking
-phase, <code><nobr>RDOFF</nobr></code> offers an additional
-<code><nobr>import</nobr></code> modifier. As in
-<code><nobr>GLOBAL</nobr></code>, you can also specify whether an imported
-symbol is a procedure (function) or data object. For example:
-<p><pre>
- library $libc
- extern _open:import
- extern _printf:import proc
- extern _errno:import data
-</pre>
-<p>Here the directive <code><nobr>LIBRARY</nobr></code> is also included,
-which gives the dynamic linker a hint as to where to find requested
-symbols.
-<h3><a name="section-7.14">7.14 <code><nobr>dbg</nobr></code>: Debugging Format</a></h3>
-<p>The <code><nobr>dbg</nobr></code> output format is not built into NASM
-in the default configuration. If you are building your own NASM executable
-from the sources, you can define <code><nobr>OF_DBG</nobr></code> in
-<code><nobr>output/outform.h</nobr></code> or on the compiler command line,
-and obtain the <code><nobr>dbg</nobr></code> output format.
-<p>The <code><nobr>dbg</nobr></code> format does not output an object file
-as such; instead, it outputs a text file which contains a complete list of
-all the transactions between the main body of NASM and the output-format
-back end module. It is primarily intended to aid people who want to write
-their own output drivers, so that they can get a clearer idea of the
-various requests the main program makes of the output driver, and in what
-order they happen.
-<p>For simple files, one can easily use the <code><nobr>dbg</nobr></code>
-format like this:
-<p><pre>
-nasm -f dbg filename.asm
-</pre>
-<p>which will generate a diagnostic file called
-<code><nobr>filename.dbg</nobr></code>. However, this will not work well on
-files which were designed for a different object format, because each
-object format defines its own macros (usually user-level forms of
-directives), and those macros will not be defined in the
-<code><nobr>dbg</nobr></code> format. Therefore it can be useful to run
-NASM twice, in order to do the preprocessing with the native object format
-selected:
-<p><pre>
-nasm -e -f rdf -o rdfprog.i rdfprog.asm
-nasm -a -f dbg rdfprog.i
-</pre>
-<p>This preprocesses <code><nobr>rdfprog.asm</nobr></code> into
-<code><nobr>rdfprog.i</nobr></code>, keeping the
-<code><nobr>rdf</nobr></code> object format selected in order to make sure
-RDF special directives are converted into primitive form correctly. Then
-the preprocessed source is fed through the <code><nobr>dbg</nobr></code>
-format to generate the final diagnostic output.
-<p>This workaround will still typically not work for programs intended for
-<code><nobr>obj</nobr></code> format, because the
-<code><nobr>obj</nobr></code> <code><nobr>SEGMENT</nobr></code> and
-<code><nobr>GROUP</nobr></code> directives have side effects of defining
-the segment and group names as symbols; <code><nobr>dbg</nobr></code> will
-not do this, so the program will not assemble. You will have to work around
-that by defining the symbols yourself (using
-<code><nobr>EXTERN</nobr></code>, for example) if you really need to get a
-<code><nobr>dbg</nobr></code> trace of an
-<code><nobr>obj</nobr></code>-specific source file.
-<p><code><nobr>dbg</nobr></code> accepts any section name and any
-directives at all, and logs them all to its output file.
-<p align=center><a href="nasmdoc8.html">Next Chapter</a> |
-<a href="nasmdoc6.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc9.html">Next Chapter</a> |
-<a href="nasmdoc7.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-8">Chapter 8: Writing 16-bit Code (DOS, Windows 3/3.1)</a></h2>
-<p>This chapter attempts to cover some of the common issues encountered
-when writing 16-bit code to run under <code><nobr>MS-DOS</nobr></code> or
-<code><nobr>Windows 3.x</nobr></code>. It covers how to link programs to
-produce <code><nobr>.EXE</nobr></code> or <code><nobr>.COM</nobr></code>
-files, how to write <code><nobr>.SYS</nobr></code> device drivers, and how
-to interface assembly language code with 16-bit C compilers and with
-Borland Pascal.
-<h3><a name="section-8.1">8.1 Producing <code><nobr>.EXE</nobr></code> Files</a></h3>
-<p>Any large program written under DOS needs to be built as a
-<code><nobr>.EXE</nobr></code> file: only <code><nobr>.EXE</nobr></code>
-files have the necessary internal structure required to span more than one
-64K segment. Windows programs, also, have to be built as
-<code><nobr>.EXE</nobr></code> files, since Windows does not support the
-<code><nobr>.COM</nobr></code> format.
-<p>In general, you generate <code><nobr>.EXE</nobr></code> files by using
-the <code><nobr>obj</nobr></code> output format to produce one or more
-<code><nobr>.OBJ</nobr></code> files, and then linking them together using
-a linker. However, NASM also supports the direct generation of simple DOS
-<code><nobr>.EXE</nobr></code> files using the
-<code><nobr>bin</nobr></code> output format (by using
-<code><nobr>DB</nobr></code> and <code><nobr>DW</nobr></code> to construct
-the <code><nobr>.EXE</nobr></code> file header), and a macro package is
-supplied to do this. Thanks to Yann Guidon for contributing the code for
-this.
-<p>NASM may also support <code><nobr>.EXE</nobr></code> natively as another
-output format in future releases.
-<h4><a name="section-8.1.1">8.1.1 Using the <code><nobr>obj</nobr></code> Format To Generate <code><nobr>.EXE</nobr></code> Files</a></h4>
-<p>This section describes the usual method of generating
-<code><nobr>.EXE</nobr></code> files by linking
-<code><nobr>.OBJ</nobr></code> files together.
-<p>Most 16-bit programming language packages come with a suitable linker;
-if you have none of these, there is a free linker called VAL, available in
-<code><nobr>LZH</nobr></code> archive format from
-<a href="ftp://x2ftp.oulu.fi/pub/msdos/programming/lang/"><code><nobr>x2ftp.oulu.fi</nobr></code></a>.
-An LZH archiver can be found at
-<a href="ftp://ftp.simtel.net/pub/simtelnet/msdos/arcers"><code><nobr>ftp.simtel.net</nobr></code></a>.
-There is another `free' linker (though this one doesn't come with sources)
-called FREELINK, available from
-<a href="http://www.pcorner.com/tpc/old/3-101.html"><code><nobr>www.pcorner.com</nobr></code></a>.
-A third, <code><nobr>djlink</nobr></code>, written by DJ Delorie, is
-available at
-<a href="http://www.delorie.com/djgpp/16bit/djlink/"><code><nobr>www.delorie.com</nobr></code></a>.
-A fourth linker, <code><nobr>ALINK</nobr></code>, written by Anthony A.J.
-Williams, is available at
-<a href="http://alink.sourceforge.net"><code><nobr>alink.sourceforge.net</nobr></code></a>.
-<p>When linking several <code><nobr>.OBJ</nobr></code> files into a
-<code><nobr>.EXE</nobr></code> file, you should ensure that exactly one of
-them has a start point defined (using the <code><nobr>..start</nobr></code>
-special symbol defined by the <code><nobr>obj</nobr></code> format: see
-<a href="nasmdoc7.html#section-7.4.6">section 7.4.6</a>). If no module
-defines a start point, the linker will not know what value to give the
-entry-point field in the output file header; if more than one defines a
-start point, the linker will not know <em>which</em> value to use.
-<p>An example of a NASM source file which can be assembled to a
-<code><nobr>.OBJ</nobr></code> file and linked on its own to a
-<code><nobr>.EXE</nobr></code> is given here. It demonstrates the basic
-principles of defining a stack, initialising the segment registers, and
-declaring a start point. This file is also provided in the
-<code><nobr>test</nobr></code> subdirectory of the NASM archives, under the
-name <code><nobr>objexe.asm</nobr></code>.
-<p><pre>
-segment code
-
-..start:
- mov ax,data
- mov ds,ax
- mov ax,stack
- mov ss,ax
- mov sp,stacktop
-</pre>
-<p>This initial piece of code sets up <code><nobr>DS</nobr></code> to point
-to the data segment, and initializes <code><nobr>SS</nobr></code> and
-<code><nobr>SP</nobr></code> to point to the top of the provided stack.
-Notice that interrupts are implicitly disabled for one instruction after a
-move into <code><nobr>SS</nobr></code>, precisely for this situation, so
-that there's no chance of an interrupt occurring between the loads of
-<code><nobr>SS</nobr></code> and <code><nobr>SP</nobr></code> and not
-having a stack to execute on.
-<p>Note also that the special symbol <code><nobr>..start</nobr></code> is
-defined at the beginning of this code, which means that will be the entry
-point into the resulting executable file.
-<p><pre>
- mov dx,hello
- mov ah,9
- int 0x21
-</pre>
-<p>The above is the main program: load <code><nobr>DS:DX</nobr></code> with
-a pointer to the greeting message (<code><nobr>hello</nobr></code> is
-implicitly relative to the segment <code><nobr>data</nobr></code>, which
-was loaded into <code><nobr>DS</nobr></code> in the setup code, so the full
-pointer is valid), and call the DOS print-string function.
-<p><pre>
- mov ax,0x4c00
- int 0x21
-</pre>
-<p>This terminates the program using another DOS system call.
-<p><pre>
-segment data
-
-hello: db 'hello, world', 13, 10, '$'
-</pre>
-<p>The data segment contains the string we want to display.
-<p><pre>
-segment stack stack
- resb 64
-stacktop:
-</pre>
-<p>The above code declares a stack segment containing 64 bytes of
-uninitialized stack space, and points <code><nobr>stacktop</nobr></code> at
-the top of it. The directive <code><nobr>segment stack stack</nobr></code>
-defines a segment <em>called</em> <code><nobr>stack</nobr></code>, and also
-of <em>type</em> <code><nobr>STACK</nobr></code>. The latter is not
-necessary to the correct running of the program, but linkers are likely to
-issue warnings or errors if your program has no segment of type
-<code><nobr>STACK</nobr></code>.
-<p>The above file, when assembled into a <code><nobr>.OBJ</nobr></code>
-file, will link on its own to a valid <code><nobr>.EXE</nobr></code> file,
-which when run will print `hello, world' and then exit.
-<h4><a name="section-8.1.2">8.1.2 Using the <code><nobr>bin</nobr></code> Format To Generate <code><nobr>.EXE</nobr></code> Files</a></h4>
-<p>The <code><nobr>.EXE</nobr></code> file format is simple enough that
-it's possible to build a <code><nobr>.EXE</nobr></code> file by writing a
-pure-binary program and sticking a 32-byte header on the front. This header
-is simple enough that it can be generated using
-<code><nobr>DB</nobr></code> and <code><nobr>DW</nobr></code> commands by
-NASM itself, so that you can use the <code><nobr>bin</nobr></code> output
-format to directly generate <code><nobr>.EXE</nobr></code> files.
-<p>Included in the NASM archives, in the <code><nobr>misc</nobr></code>
-subdirectory, is a file <code><nobr>exebin.mac</nobr></code> of macros. It
-defines three macros: <code><nobr>EXE_begin</nobr></code>,
-<code><nobr>EXE_stack</nobr></code> and <code><nobr>EXE_end</nobr></code>.
-<p>To produce a <code><nobr>.EXE</nobr></code> file using this method, you
-should start by using <code><nobr>%include</nobr></code> to load the
-<code><nobr>exebin.mac</nobr></code> macro package into your source file.
-You should then issue the <code><nobr>EXE_begin</nobr></code> macro call
-(which takes no arguments) to generate the file header data. Then write
-code as normal for the <code><nobr>bin</nobr></code> format - you can use
-all three standard sections <code><nobr>.text</nobr></code>,
-<code><nobr>.data</nobr></code> and <code><nobr>.bss</nobr></code>. At the
-end of the file you should call the <code><nobr>EXE_end</nobr></code> macro
-(again, no arguments), which defines some symbols to mark section sizes,
-and these symbols are referred to in the header code generated by
-<code><nobr>EXE_begin</nobr></code>.
-<p>In this model, the code you end up writing starts at
-<code><nobr>0x100</nobr></code>, just like a <code><nobr>.COM</nobr></code>
-file - in fact, if you strip off the 32-byte header from the resulting
-<code><nobr>.EXE</nobr></code> file, you will have a valid
-<code><nobr>.COM</nobr></code> program. All the segment bases are the same,
-so you are limited to a 64K program, again just like a
-<code><nobr>.COM</nobr></code> file. Note that an
-<code><nobr>ORG</nobr></code> directive is issued by the
-<code><nobr>EXE_begin</nobr></code> macro, so you should not explicitly
-issue one of your own.
-<p>You can't directly refer to your segment base value, unfortunately,
-since this would require a relocation in the header, and things would get a
-lot more complicated. So you should get your segment base by copying it out
-of <code><nobr>CS</nobr></code> instead.
-<p>On entry to your <code><nobr>.EXE</nobr></code> file,
-<code><nobr>SS:SP</nobr></code> are already set up to point to the top of a
-2Kb stack. You can adjust the default stack size of 2Kb by calling the
-<code><nobr>EXE_stack</nobr></code> macro. For example, to change the stack
-size of your program to 64 bytes, you would call
-<code><nobr>EXE_stack 64</nobr></code>.
-<p>A sample program which generates a <code><nobr>.EXE</nobr></code> file
-in this way is given in the <code><nobr>test</nobr></code> subdirectory of
-the NASM archive, as <code><nobr>binexe.asm</nobr></code>.
-<h3><a name="section-8.2">8.2 Producing <code><nobr>.COM</nobr></code> Files</a></h3>
-<p>While large DOS programs must be written as
-<code><nobr>.EXE</nobr></code> files, small ones are often better written
-as <code><nobr>.COM</nobr></code> files. <code><nobr>.COM</nobr></code>
-files are pure binary, and therefore most easily produced using the
-<code><nobr>bin</nobr></code> output format.
-<h4><a name="section-8.2.1">8.2.1 Using the <code><nobr>bin</nobr></code> Format To Generate <code><nobr>.COM</nobr></code> Files</a></h4>
-<p><code><nobr>.COM</nobr></code> files expect to be loaded at offset
-<code><nobr>100h</nobr></code> into their segment (though the segment may
-change). Execution then begins at <code><nobr>100h</nobr></code>, i.e.
-right at the start of the program. So to write a
-<code><nobr>.COM</nobr></code> program, you would create a source file
-looking like
-<p><pre>
- org 100h
-
-section .text
-
-start:
- ; put your code here
-
-section .data
-
- ; put data items here
-
-section .bss
-
- ; put uninitialized data here
-</pre>
-<p>The <code><nobr>bin</nobr></code> format puts the
-<code><nobr>.text</nobr></code> section first in the file, so you can
-declare data or BSS items before beginning to write code if you want to and
-the code will still end up at the front of the file where it belongs.
-<p>The BSS (uninitialized data) section does not take up space in the
-<code><nobr>.COM</nobr></code> file itself: instead, addresses of BSS items
-are resolved to point at space beyond the end of the file, on the grounds
-that this will be free memory when the program is run. Therefore you should
-not rely on your BSS being initialized to all zeros when you run.
-<p>To assemble the above program, you should use a command line like
-<p><pre>
-nasm myprog.asm -fbin -o myprog.com
-</pre>
-<p>The <code><nobr>bin</nobr></code> format would produce a file called
-<code><nobr>myprog</nobr></code> if no explicit output file name were
-specified, so you have to override it and give the desired file name.
-<h4><a name="section-8.2.2">8.2.2 Using the <code><nobr>obj</nobr></code> Format To Generate <code><nobr>.COM</nobr></code> Files</a></h4>
-<p>If you are writing a <code><nobr>.COM</nobr></code> program as more than
-one module, you may wish to assemble several <code><nobr>.OBJ</nobr></code>
-files and link them together into a <code><nobr>.COM</nobr></code> program.
-You can do this, provided you have a linker capable of outputting
-<code><nobr>.COM</nobr></code> files directly (TLINK does this), or
-alternatively a converter program such as <code><nobr>EXE2BIN</nobr></code>
-to transform the <code><nobr>.EXE</nobr></code> file output from the linker
-into a <code><nobr>.COM</nobr></code> file.
-<p>If you do this, you need to take care of several things:
-<ul>
-<li>The first object file containing code should start its code segment
-with a line like <code><nobr>RESB 100h</nobr></code>. This is to ensure
-that the code begins at offset <code><nobr>100h</nobr></code> relative to
-the beginning of the code segment, so that the linker or converter program
-does not have to adjust address references within the file when generating
-the <code><nobr>.COM</nobr></code> file. Other assemblers use an
-<code><nobr>ORG</nobr></code> directive for this purpose, but
-<code><nobr>ORG</nobr></code> in NASM is a format-specific directive to the
-<code><nobr>bin</nobr></code> output format, and does not mean the same
-thing as it does in MASM-compatible assemblers.
-<li>You don't need to define a stack segment.
-<li>All your segments should be in the same group, so that every time your
-code or data references a symbol offset, all offsets are relative to the
-same segment base. This is because, when a <code><nobr>.COM</nobr></code>
-file is loaded, all the segment registers contain the same value.
-</ul>
-<h3><a name="section-8.3">8.3 Producing <code><nobr>.SYS</nobr></code> Files</a></h3>
-<p>MS-DOS device drivers - <code><nobr>.SYS</nobr></code> files - are pure
-binary files, similar to <code><nobr>.COM</nobr></code> files, except that
-they start at origin zero rather than <code><nobr>100h</nobr></code>.
-Therefore, if you are writing a device driver using the
-<code><nobr>bin</nobr></code> format, you do not need the
-<code><nobr>ORG</nobr></code> directive, since the default origin for
-<code><nobr>bin</nobr></code> is zero. Similarly, if you are using
-<code><nobr>obj</nobr></code>, you do not need the
-<code><nobr>RESB 100h</nobr></code> at the start of your code segment.
-<p><code><nobr>.SYS</nobr></code> files start with a header structure,
-containing pointers to the various routines inside the driver which do the
-work. This structure should be defined at the start of the code segment,
-even though it is not actually code.
-<p>For more information on the format of <code><nobr>.SYS</nobr></code>
-files, and the data which has to go in the header structure, a list of
-books is given in the Frequently Asked Questions list for the newsgroup
-<a href="news:comp.os.msdos.programmer"><code><nobr>comp.os.msdos.programmer</nobr></code></a>.
-<h3><a name="section-8.4">8.4 Interfacing to 16-bit C Programs</a></h3>
-<p>This section covers the basics of writing assembly routines that call,
-or are called from, C programs. To do this, you would typically write an
-assembly module as a <code><nobr>.OBJ</nobr></code> file, and link it with
-your C modules to produce a mixed-language program.
-<h4><a name="section-8.4.1">8.4.1 External Symbol Names</a></h4>
-<p>C compilers have the convention that the names of all global symbols
-(functions or data) they define are formed by prefixing an underscore to
-the name as it appears in the C program. So, for example, the function a C
-programmer thinks of as <code><nobr>printf</nobr></code> appears to an
-assembly language programmer as <code><nobr>_printf</nobr></code>. This
-means that in your assembly programs, you can define symbols without a
-leading underscore, and not have to worry about name clashes with C
-symbols.
-<p>If you find the underscores inconvenient, you can define macros to
-replace the <code><nobr>GLOBAL</nobr></code> and
-<code><nobr>EXTERN</nobr></code> directives as follows:
-<p><pre>
-%macro cglobal 1
-
- global _%1
- %define %1 _%1
-
-%endmacro
-
-%macro cextern 1
-
- extern _%1
- %define %1 _%1
-
-%endmacro
-</pre>
-<p>(These forms of the macros only take one argument at a time; a
-<code><nobr>%rep</nobr></code> construct could solve this.)
-<p>If you then declare an external like this:
-<p><pre>
-cextern printf
-</pre>
-<p>then the macro will expand it as
-<p><pre>
-extern _printf
-%define printf _printf
-</pre>
-<p>Thereafter, you can reference <code><nobr>printf</nobr></code> as if it
-was a symbol, and the preprocessor will put the leading underscore on where
-necessary.
-<p>The <code><nobr>cglobal</nobr></code> macro works similarly. You must
-use <code><nobr>cglobal</nobr></code> before defining the symbol in
-question, but you would have had to do that anyway if you used
-<code><nobr>GLOBAL</nobr></code>.
-<p>Also see <a href="nasmdoc2.html#section-2.1.27">section 2.1.27</a>.
-<h4><a name="section-8.4.2">8.4.2 Memory Models</a></h4>
-<p>NASM contains no mechanism to support the various C memory models
-directly; you have to keep track yourself of which one you are writing for.
-This means you have to keep track of the following things:
-<ul>
-<li>In models using a single code segment (tiny, small and compact),
-functions are near. This means that function pointers, when stored in data
-segments or pushed on the stack as function arguments, are 16 bits long and
-contain only an offset field (the <code><nobr>CS</nobr></code> register
-never changes its value, and always gives the segment part of the full
-function address), and that functions are called using ordinary near
-<code><nobr>CALL</nobr></code> instructions and return using
-<code><nobr>RETN</nobr></code> (which, in NASM, is synonymous with
-<code><nobr>RET</nobr></code> anyway). This means both that you should
-write your own routines to return with <code><nobr>RETN</nobr></code>, and
-that you should call external C routines with near
-<code><nobr>CALL</nobr></code> instructions.
-<li>In models using more than one code segment (medium, large and huge),
-functions are far. This means that function pointers are 32 bits long
-(consisting of a 16-bit offset followed by a 16-bit segment), and that
-functions are called using <code><nobr>CALL FAR</nobr></code> (or
-<code><nobr>CALL seg:offset</nobr></code>) and return using
-<code><nobr>RETF</nobr></code>. Again, you should therefore write your own
-routines to return with <code><nobr>RETF</nobr></code> and use
-<code><nobr>CALL FAR</nobr></code> to call external routines.
-<li>In models using a single data segment (tiny, small and medium), data
-pointers are 16 bits long, containing only an offset field (the
-<code><nobr>DS</nobr></code> register doesn't change its value, and always
-gives the segment part of the full data item address).
-<li>In models using more than one data segment (compact, large and huge),
-data pointers are 32 bits long, consisting of a 16-bit offset followed by a
-16-bit segment. You should still be careful not to modify
-<code><nobr>DS</nobr></code> in your routines without restoring it
-afterwards, but <code><nobr>ES</nobr></code> is free for you to use to
-access the contents of 32-bit data pointers you are passed.
-<li>The huge memory model allows single data items to exceed 64K in size.
-In all other memory models, you can access the whole of a data item just by
-doing arithmetic on the offset field of the pointer you are given, whether
-a segment field is present or not; in huge model, you have to be more
-careful of your pointer arithmetic.
-<li>In most memory models, there is a <em>default</em> data segment, whose
-segment address is kept in <code><nobr>DS</nobr></code> throughout the
-program. This data segment is typically the same segment as the stack, kept
-in <code><nobr>SS</nobr></code>, so that functions' local variables (which
-are stored on the stack) and global data items can both be accessed easily
-without changing <code><nobr>DS</nobr></code>. Particularly large data
-items are typically stored in other segments. However, some memory models
-(though not the standard ones, usually) allow the assumption that
-<code><nobr>SS</nobr></code> and <code><nobr>DS</nobr></code> hold the same
-value to be removed. Be careful about functions' local variables in this
-latter case.
-</ul>
-<p>In models with a single code segment, the segment is called
-<code><nobr>_TEXT</nobr></code>, so your code segment must also go by this
-name in order to be linked into the same place as the main code segment. In
-models with a single data segment, or with a default data segment, it is
-called <code><nobr>_DATA</nobr></code>.
-<h4><a name="section-8.4.3">8.4.3 Function Definitions and Function Calls</a></h4>
-<p>The C calling convention in 16-bit programs is as follows. In the
-following description, the words <em>caller</em> and <em>callee</em> are
-used to denote the function doing the calling and the function which gets
-called.
-<ul>
-<li>The caller pushes the function's parameters on the stack, one after
-another, in reverse order (right to left, so that the first argument
-specified to the function is pushed last).
-<li>The caller then executes a <code><nobr>CALL</nobr></code> instruction
-to pass control to the callee. This <code><nobr>CALL</nobr></code> is
-either near or far depending on the memory model.
-<li>The callee receives control, and typically (although this is not
-actually necessary, in functions which do not need to access their
-parameters) starts by saving the value of <code><nobr>SP</nobr></code> in
-<code><nobr>BP</nobr></code> so as to be able to use
-<code><nobr>BP</nobr></code> as a base pointer to find its parameters on
-the stack. However, the caller was probably doing this too, so part of the
-calling convention states that <code><nobr>BP</nobr></code> must be
-preserved by any C function. Hence the callee, if it is going to set up
-<code><nobr>BP</nobr></code> as a <em>frame pointer</em>, must push the
-previous value first.
-<li>The callee may then access its parameters relative to
-<code><nobr>BP</nobr></code>. The word at <code><nobr>[BP]</nobr></code>
-holds the previous value of <code><nobr>BP</nobr></code> as it was pushed;
-the next word, at <code><nobr>[BP+2]</nobr></code>, holds the offset part
-of the return address, pushed implicitly by <code><nobr>CALL</nobr></code>.
-In a small-model (near) function, the parameters start after that, at
-<code><nobr>[BP+4]</nobr></code>; in a large-model (far) function, the
-segment part of the return address lives at
-<code><nobr>[BP+4]</nobr></code>, and the parameters begin at
-<code><nobr>[BP+6]</nobr></code>. The leftmost parameter of the function,
-since it was pushed last, is accessible at this offset from
-<code><nobr>BP</nobr></code>; the others follow, at successively greater
-offsets. Thus, in a function such as <code><nobr>printf</nobr></code> which
-takes a variable number of parameters, the pushing of the parameters in
-reverse order means that the function knows where to find its first
-parameter, which tells it the number and type of the remaining ones.
-<li>The callee may also wish to decrease <code><nobr>SP</nobr></code>
-further, so as to allocate space on the stack for local variables, which
-will then be accessible at negative offsets from
-<code><nobr>BP</nobr></code>.
-<li>The callee, if it wishes to return a value to the caller, should leave
-the value in <code><nobr>AL</nobr></code>, <code><nobr>AX</nobr></code> or
-<code><nobr>DX:AX</nobr></code> depending on the size of the value.
-Floating-point results are sometimes (depending on the compiler) returned
-in <code><nobr>ST0</nobr></code>.
-<li>Once the callee has finished processing, it restores
-<code><nobr>SP</nobr></code> from <code><nobr>BP</nobr></code> if it had
-allocated local stack space, then pops the previous value of
-<code><nobr>BP</nobr></code>, and returns via
-<code><nobr>RETN</nobr></code> or <code><nobr>RETF</nobr></code> depending
-on memory model.
-<li>When the caller regains control from the callee, the function
-parameters are still on the stack, so it typically adds an immediate
-constant to <code><nobr>SP</nobr></code> to remove them (instead of
-executing a number of slow <code><nobr>POP</nobr></code> instructions).
-Thus, if a function is accidentally called with the wrong number of
-parameters due to a prototype mismatch, the stack will still be returned to
-a sensible state since the caller, which <em>knows</em> how many parameters
-it pushed, does the removing.
-</ul>
-<p>It is instructive to compare this calling convention with that for
-Pascal programs (described in <a href="#section-8.5.1">section 8.5.1</a>).
-Pascal has a simpler convention, since no functions have variable numbers
-of parameters. Therefore the callee knows how many parameters it should
-have been passed, and is able to deallocate them from the stack itself by
-passing an immediate argument to the <code><nobr>RET</nobr></code> or
-<code><nobr>RETF</nobr></code> instruction, so the caller does not have to
-do it. Also, the parameters are pushed in left-to-right order, not
-right-to-left, which means that a compiler can give better guarantees about
-sequence points without performance suffering.
-<p>Thus, you would define a function in C style in the following way. The
-following example is for small model:
-<p><pre>
-global _myfunc
-
-_myfunc:
- push bp
- mov bp,sp
- sub sp,0x40 ; 64 bytes of local stack space
- mov bx,[bp+4] ; first parameter to function
-
- ; some more code
-
- mov sp,bp ; undo "sub sp,0x40" above
- pop bp
- ret
-</pre>
-<p>For a large-model function, you would replace
-<code><nobr>RET</nobr></code> by <code><nobr>RETF</nobr></code>, and look
-for the first parameter at <code><nobr>[BP+6]</nobr></code> instead of
-<code><nobr>[BP+4]</nobr></code>. Of course, if one of the parameters is a
-pointer, then the offsets of <em>subsequent</em> parameters will change
-depending on the memory model as well: far pointers take up four bytes on
-the stack when passed as a parameter, whereas near pointers take up two.
-<p>At the other end of the process, to call a C function from your assembly
-code, you would do something like this:
-<p><pre>
-extern _printf
-
- ; and then, further down...
-
- push word [myint] ; one of my integer variables
- push word mystring ; pointer into my data segment
- call _printf
- add sp,byte 4 ; `byte' saves space
-
- ; then those data items...
-
-segment _DATA
-
-myint dw 1234
-mystring db 'This number -&gt; %d &lt;- should be 1234',10,0
-</pre>
-<p>This piece of code is the small-model assembly equivalent of the C code
-<p><pre>
- int myint = 1234;
- printf("This number -&gt; %d &lt;- should be 1234\n", myint);
-</pre>
-<p>In large model, the function-call code might look more like this. In
-this example, it is assumed that <code><nobr>DS</nobr></code> already holds
-the segment base of the segment <code><nobr>_DATA</nobr></code>. If not,
-you would have to initialize it first.
-<p><pre>
- push word [myint]
- push word seg mystring ; Now push the segment, and...
- push word mystring ; ... offset of "mystring"
- call far _printf
- add sp,byte 6
-</pre>
-<p>The integer value still takes up one word on the stack, since large
-model does not affect the size of the <code><nobr>int</nobr></code> data
-type. The first argument (pushed last) to <code><nobr>printf</nobr></code>,
-however, is a data pointer, and therefore has to contain a segment and
-offset part. The segment should be stored second in memory, and therefore
-must be pushed first. (Of course, <code><nobr>PUSH DS</nobr></code> would
-have been a shorter instruction than
-<code><nobr>PUSH WORD SEG mystring</nobr></code>, if
-<code><nobr>DS</nobr></code> was set up as the above example assumed.) Then
-the actual call becomes a far call, since functions expect far calls in
-large model; and <code><nobr>SP</nobr></code> has to be increased by 6
-rather than 4 afterwards to make up for the extra word of parameters.
-<h4><a name="section-8.4.4">8.4.4 Accessing Data Items</a></h4>
-<p>To get at the contents of C variables, or to declare variables which C
-can access, you need only declare the names as
-<code><nobr>GLOBAL</nobr></code> or <code><nobr>EXTERN</nobr></code>.
-(Again, the names require leading underscores, as stated in
-<a href="#section-8.4.1">section 8.4.1</a>.) Thus, a C variable declared as
-<code><nobr>int i</nobr></code> can be accessed from assembler as
-<p><pre>
-extern _i
-
- mov ax,[_i]
-</pre>
-<p>And to declare your own integer variable which C programs can access as
-<code><nobr>extern int j</nobr></code>, you do this (making sure you are
-assembling in the <code><nobr>_DATA</nobr></code> segment, if necessary):
-<p><pre>
-global _j
-
-_j dw 0
-</pre>
-<p>To access a C array, you need to know the size of the components of the
-array. For example, <code><nobr>int</nobr></code> variables are two bytes
-long, so if a C program declares an array as
-<code><nobr>int a[10]</nobr></code>, you can access
-<code><nobr>a[3]</nobr></code> by coding
-<code><nobr>mov ax,[_a+6]</nobr></code>. (The byte offset 6 is obtained by
-multiplying the desired array index, 3, by the size of the array element,
-2.) The sizes of the C base types in 16-bit compilers are: 1 for
-<code><nobr>char</nobr></code>, 2 for <code><nobr>short</nobr></code> and
-<code><nobr>int</nobr></code>, 4 for <code><nobr>long</nobr></code> and
-<code><nobr>float</nobr></code>, and 8 for
-<code><nobr>double</nobr></code>.
-<p>To access a C data structure, you need to know the offset from the base
-of the structure to the field you are interested in. You can either do this
-by converting the C structure definition into a NASM structure definition
-(using <code><nobr>STRUC</nobr></code>), or by calculating the one offset
-and using just that.
-<p>To do either of these, you should read your C compiler's manual to find
-out how it organizes data structures. NASM gives no special alignment to
-structure members in its own <code><nobr>STRUC</nobr></code> macro, so you
-have to specify alignment yourself if the C compiler generates it.
-Typically, you might find that a structure like
-<p><pre>
-struct {
- char c;
- int i;
-} foo;
-</pre>
-<p>might be four bytes long rather than three, since the
-<code><nobr>int</nobr></code> field would be aligned to a two-byte
-boundary. However, this sort of feature tends to be a configurable option
-in the C compiler, either using command-line options or
-<code><nobr>#pragma</nobr></code> lines, so you have to find out how your
-own compiler does it.
-<h4><a name="section-8.4.5">8.4.5 <code><nobr>c16.mac</nobr></code>: Helper Macros for the 16-bit C Interface</a></h4>
-<p>Included in the NASM archives, in the <code><nobr>misc</nobr></code>
-directory, is a file <code><nobr>c16.mac</nobr></code> of macros. It
-defines three macros: <code><nobr>proc</nobr></code>,
-<code><nobr>arg</nobr></code> and <code><nobr>endproc</nobr></code>. These
-are intended to be used for C-style procedure definitions, and they
-automate a lot of the work involved in keeping track of the calling
-convention.
-<p>(An alternative, TASM compatible form of <code><nobr>arg</nobr></code>
-is also now built into NASM's preprocessor. See
-<a href="nasmdoc4.html#section-4.8">section 4.8</a> for details.)
-<p>An example of an assembly function using the macro set is given here:
-<p><pre>
-proc _nearproc
-
-%$i arg
-%$j arg
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- add ax,[bx]
-
-endproc
-</pre>
-<p>This defines <code><nobr>_nearproc</nobr></code> to be a procedure
-taking two arguments, the first (<code><nobr>i</nobr></code>) an integer
-and the second (<code><nobr>j</nobr></code>) a pointer to an integer. It
-returns <code><nobr>i + *j</nobr></code>.
-<p>Note that the <code><nobr>arg</nobr></code> macro has an
-<code><nobr>EQU</nobr></code> as the first line of its expansion, and since
-the label before the macro call gets prepended to the first line of the
-expanded macro, the <code><nobr>EQU</nobr></code> works, defining
-<code><nobr>%$i</nobr></code> to be an offset from
-<code><nobr>BP</nobr></code>. A context-local variable is used, local to
-the context pushed by the <code><nobr>proc</nobr></code> macro and popped
-by the <code><nobr>endproc</nobr></code> macro, so that the same argument
-name can be used in later procedures. Of course, you don't <em>have</em> to
-do that.
-<p>The macro set produces code for near functions (tiny, small and
-compact-model code) by default. You can have it generate far functions
-(medium, large and huge-model code) by means of coding
-<code><nobr>%define FARCODE</nobr></code>. This changes the kind of return
-instruction generated by <code><nobr>endproc</nobr></code>, and also
-changes the starting point for the argument offsets. The macro set contains
-no intrinsic dependency on whether data pointers are far or not.
-<p><code><nobr>arg</nobr></code> can take an optional parameter, giving the
-size of the argument. If no size is given, 2 is assumed, since it is likely
-that many function parameters will be of type
-<code><nobr>int</nobr></code>.
-<p>The large-model equivalent of the above function would look like this:
-<p><pre>
-%define FARCODE
-
-proc _farproc
-
-%$i arg
-%$j arg 4
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- mov es,[bp + %$j + 2]
- add ax,[bx]
-
-endproc
-</pre>
-<p>This makes use of the argument to the <code><nobr>arg</nobr></code>
-macro to define a parameter of size 4, because <code><nobr>j</nobr></code>
-is now a far pointer. When we load from <code><nobr>j</nobr></code>, we
-must load a segment and an offset.
-<h3><a name="section-8.5">8.5 Interfacing to Borland Pascal Programs</a></h3>
-<p>Interfacing to Borland Pascal programs is similar in concept to
-interfacing to 16-bit C programs. The differences are:
-<ul>
-<li>The leading underscore required for interfacing to C programs is not
-required for Pascal.
-<li>The memory model is always large: functions are far, data pointers are
-far, and no data item can be more than 64K long. (Actually, some functions
-are near, but only those functions that are local to a Pascal unit and
-never called from outside it. All assembly functions that Pascal calls, and
-all Pascal functions that assembly routines are able to call, are far.)
-However, all static data declared in a Pascal program goes into the default
-data segment, which is the one whose segment address will be in
-<code><nobr>DS</nobr></code> when control is passed to your assembly code.
-The only things that do not live in the default data segment are local
-variables (they live in the stack segment) and dynamically allocated
-variables. All data <em>pointers</em>, however, are far.
-<li>The function calling convention is different - described below.
-<li>Some data types, such as strings, are stored differently.
-<li>There are restrictions on the segment names you are allowed to use -
-Borland Pascal will ignore code or data declared in a segment it doesn't
-like the name of. The restrictions are described below.
-</ul>
-<h4><a name="section-8.5.1">8.5.1 The Pascal Calling Convention</a></h4>
-<p>The 16-bit Pascal calling convention is as follows. In the following
-description, the words <em>caller</em> and <em>callee</em> are used to
-denote the function doing the calling and the function which gets called.
-<ul>
-<li>The caller pushes the function's parameters on the stack, one after
-another, in normal order (left to right, so that the first argument
-specified to the function is pushed first).
-<li>The caller then executes a far <code><nobr>CALL</nobr></code>
-instruction to pass control to the callee.
-<li>The callee receives control, and typically (although this is not
-actually necessary, in functions which do not need to access their
-parameters) starts by saving the value of <code><nobr>SP</nobr></code> in
-<code><nobr>BP</nobr></code> so as to be able to use
-<code><nobr>BP</nobr></code> as a base pointer to find its parameters on
-the stack. However, the caller was probably doing this too, so part of the
-calling convention states that <code><nobr>BP</nobr></code> must be
-preserved by any function. Hence the callee, if it is going to set up
-<code><nobr>BP</nobr></code> as a frame pointer, must push the previous
-value first.
-<li>The callee may then access its parameters relative to
-<code><nobr>BP</nobr></code>. The word at <code><nobr>[BP]</nobr></code>
-holds the previous value of <code><nobr>BP</nobr></code> as it was pushed.
-The next word, at <code><nobr>[BP+2]</nobr></code>, holds the offset part
-of the return address, and the next one at <code><nobr>[BP+4]</nobr></code>
-the segment part. The parameters begin at <code><nobr>[BP+6]</nobr></code>.
-The rightmost parameter of the function, since it was pushed last, is
-accessible at this offset from <code><nobr>BP</nobr></code>; the others
-follow, at successively greater offsets.
-<li>The callee may also wish to decrease <code><nobr>SP</nobr></code>
-further, so as to allocate space on the stack for local variables, which
-will then be accessible at negative offsets from
-<code><nobr>BP</nobr></code>.
-<li>The callee, if it wishes to return a value to the caller, should leave
-the value in <code><nobr>AL</nobr></code>, <code><nobr>AX</nobr></code> or
-<code><nobr>DX:AX</nobr></code> depending on the size of the value.
-Floating-point results are returned in <code><nobr>ST0</nobr></code>.
-Results of type <code><nobr>Real</nobr></code> (Borland's own custom
-floating-point data type, not handled directly by the FPU) are returned in
-<code><nobr>DX:BX:AX</nobr></code>. To return a result of type
-<code><nobr>String</nobr></code>, the caller pushes a pointer to a
-temporary string before pushing the parameters, and the callee places the
-returned string value at that location. The pointer is not a parameter, and
-should not be removed from the stack by the <code><nobr>RETF</nobr></code>
-instruction.
-<li>Once the callee has finished processing, it restores
-<code><nobr>SP</nobr></code> from <code><nobr>BP</nobr></code> if it had
-allocated local stack space, then pops the previous value of
-<code><nobr>BP</nobr></code>, and returns via
-<code><nobr>RETF</nobr></code>. It uses the form of
-<code><nobr>RETF</nobr></code> with an immediate parameter, giving the
-number of bytes taken up by the parameters on the stack. This causes the
-parameters to be removed from the stack as a side effect of the return
-instruction.
-<li>When the caller regains control from the callee, the function
-parameters have already been removed from the stack, so it needs to do
-nothing further.
-</ul>
-<p>Thus, you would define a function in Pascal style, taking two
-<code><nobr>Integer</nobr></code>-type parameters, in the following way:
-<p><pre>
-global myfunc
-
-myfunc: push bp
- mov bp,sp
- sub sp,0x40 ; 64 bytes of local stack space
- mov bx,[bp+8] ; first parameter to function
- mov bx,[bp+6] ; second parameter to function
-
- ; some more code
-
- mov sp,bp ; undo "sub sp,0x40" above
- pop bp
- retf 4 ; total size of params is 4
-</pre>
-<p>At the other end of the process, to call a Pascal function from your
-assembly code, you would do something like this:
-<p><pre>
-extern SomeFunc
-
- ; and then, further down...
-
- push word seg mystring ; Now push the segment, and...
- push word mystring ; ... offset of "mystring"
- push word [myint] ; one of my variables
- call far SomeFunc
-</pre>
-<p>This is equivalent to the Pascal code
-<p><pre>
-procedure SomeFunc(String: PChar; Int: Integer);
- SomeFunc(@mystring, myint);
-</pre>
-<h4><a name="section-8.5.2">8.5.2 Borland Pascal Segment Name Restrictions</a></h4>
-<p>Since Borland Pascal's internal unit file format is completely different
-from <code><nobr>OBJ</nobr></code>, it only makes a very sketchy job of
-actually reading and understanding the various information contained in a
-real <code><nobr>OBJ</nobr></code> file when it links that in. Therefore an
-object file intended to be linked to a Pascal program must obey a number of
-restrictions:
-<ul>
-<li>Procedures and functions must be in a segment whose name is either
-<code><nobr>CODE</nobr></code>, <code><nobr>CSEG</nobr></code>, or
-something ending in <code><nobr>_TEXT</nobr></code>.
-<li>initialized data must be in a segment whose name is either
-<code><nobr>CONST</nobr></code> or something ending in
-<code><nobr>_DATA</nobr></code>.
-<li>Uninitialized data must be in a segment whose name is either
-<code><nobr>DATA</nobr></code>, <code><nobr>DSEG</nobr></code>, or
-something ending in <code><nobr>_BSS</nobr></code>.
-<li>Any other segments in the object file are completely ignored.
-<code><nobr>GROUP</nobr></code> directives and segment attributes are also
-ignored.
-</ul>
-<h4><a name="section-8.5.3">8.5.3 Using <code><nobr>c16.mac</nobr></code> With Pascal Programs</a></h4>
-<p>The <code><nobr>c16.mac</nobr></code> macro package, described in
-<a href="#section-8.4.5">section 8.4.5</a>, can also be used to simplify
-writing functions to be called from Pascal programs, if you code
-<code><nobr>%define PASCAL</nobr></code>. This definition ensures that
-functions are far (it implies <code><nobr>FARCODE</nobr></code>), and also
-causes procedure return instructions to be generated with an operand.
-<p>Defining <code><nobr>PASCAL</nobr></code> does not change the code which
-calculates the argument offsets; you must declare your function's arguments
-in reverse order. For example:
-<p><pre>
-%define PASCAL
-
-proc _pascalproc
-
-%$j arg 4
-%$i arg
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- mov es,[bp + %$j + 2]
- add ax,[bx]
-
-endproc
-</pre>
-<p>This defines the same routine, conceptually, as the example in
-<a href="#section-8.4.5">section 8.4.5</a>: it defines a function taking
-two arguments, an integer and a pointer to an integer, which returns the
-sum of the integer and the contents of the pointer. The only difference
-between this code and the large-model C version is that
-<code><nobr>PASCAL</nobr></code> is defined instead of
-<code><nobr>FARCODE</nobr></code>, and that the arguments are declared in
-reverse order.
-<p align=center><a href="nasmdoc9.html">Next Chapter</a> |
-<a href="nasmdoc7.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdo10.html">Next Chapter</a> |
-<a href="nasmdoc8.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="chapter-9">Chapter 9: Writing 32-bit Code (Unix, Win32, DJGPP)</a></h2>
-<p>This chapter attempts to cover some of the common issues involved when
-writing 32-bit code, to run under Win32 or Unix, or to be linked with C
-code generated by a Unix-style C compiler such as DJGPP. It covers how to
-write assembly code to interface with 32-bit C routines, and how to write
-position-independent code for shared libraries.
-<p>Almost all 32-bit code, and in particular all code running under
-<code><nobr>Win32</nobr></code>, <code><nobr>DJGPP</nobr></code> or any of
-the PC Unix variants, runs in <em>flat</em> memory model. This means that
-the segment registers and paging have already been set up to give you the
-same 32-bit 4Gb address space no matter what segment you work relative to,
-and that you should ignore all segment registers completely. When writing
-flat-model application code, you never need to use a segment override or
-modify any segment register, and the code-section addresses you pass to
-<code><nobr>CALL</nobr></code> and <code><nobr>JMP</nobr></code> live in
-the same address space as the data-section addresses you access your
-variables by and the stack-section addresses you access local variables and
-procedure parameters by. Every address is 32 bits long and contains only an
-offset part.
-<h3><a name="section-9.1">9.1 Interfacing to 32-bit C Programs</a></h3>
-<p>A lot of the discussion in <a href="nasmdoc8.html#section-8.4">section
-8.4</a>, about interfacing to 16-bit C programs, still applies when working
-in 32 bits. The absence of memory models or segmentation worries simplifies
-things a lot.
-<h4><a name="section-9.1.1">9.1.1 External Symbol Names</a></h4>
-<p>Most 32-bit C compilers share the convention used by 16-bit compilers,
-that the names of all global symbols (functions or data) they define are
-formed by prefixing an underscore to the name as it appears in the C
-program. However, not all of them do: the <code><nobr>ELF</nobr></code>
-specification states that C symbols do <em>not</em> have a leading
-underscore on their assembly-language names.
-<p>The older Linux <code><nobr>a.out</nobr></code> C compiler, all
-<code><nobr>Win32</nobr></code> compilers, <code><nobr>DJGPP</nobr></code>,
-and <code><nobr>NetBSD</nobr></code> and <code><nobr>FreeBSD</nobr></code>,
-all use the leading underscore; for these compilers, the macros
-<code><nobr>cextern</nobr></code> and <code><nobr>cglobal</nobr></code>, as
-given in <a href="nasmdoc8.html#section-8.4.1">section 8.4.1</a>, will
-still work. For <code><nobr>ELF</nobr></code>, though, the leading
-underscore should not be used.
-<p>See also <a href="nasmdoc2.html#section-2.1.27">section 2.1.27</a>.
-<h4><a name="section-9.1.2">9.1.2 Function Definitions and Function Calls</a></h4>
-<p>The C calling convention in 32-bit programs is as follows. In the
-following description, the words <em>caller</em> and <em>callee</em> are
-used to denote the function doing the calling and the function which gets
-called.
-<ul>
-<li>The caller pushes the function's parameters on the stack, one after
-another, in reverse order (right to left, so that the first argument
-specified to the function is pushed last).
-<li>The caller then executes a near <code><nobr>CALL</nobr></code>
-instruction to pass control to the callee.
-<li>The callee receives control, and typically (although this is not
-actually necessary, in functions which do not need to access their
-parameters) starts by saving the value of <code><nobr>ESP</nobr></code> in
-<code><nobr>EBP</nobr></code> so as to be able to use
-<code><nobr>EBP</nobr></code> as a base pointer to find its parameters on
-the stack. However, the caller was probably doing this too, so part of the
-calling convention states that <code><nobr>EBP</nobr></code> must be
-preserved by any C function. Hence the callee, if it is going to set up
-<code><nobr>EBP</nobr></code> as a frame pointer, must push the previous
-value first.
-<li>The callee may then access its parameters relative to
-<code><nobr>EBP</nobr></code>. The doubleword at
-<code><nobr>[EBP]</nobr></code> holds the previous value of
-<code><nobr>EBP</nobr></code> as it was pushed; the next doubleword, at
-<code><nobr>[EBP+4]</nobr></code>, holds the return address, pushed
-implicitly by <code><nobr>CALL</nobr></code>. The parameters start after
-that, at <code><nobr>[EBP+8]</nobr></code>. The leftmost parameter of the
-function, since it was pushed last, is accessible at this offset from
-<code><nobr>EBP</nobr></code>; the others follow, at successively greater
-offsets. Thus, in a function such as <code><nobr>printf</nobr></code> which
-takes a variable number of parameters, the pushing of the parameters in
-reverse order means that the function knows where to find its first
-parameter, which tells it the number and type of the remaining ones.
-<li>The callee may also wish to decrease <code><nobr>ESP</nobr></code>
-further, so as to allocate space on the stack for local variables, which
-will then be accessible at negative offsets from
-<code><nobr>EBP</nobr></code>.
-<li>The callee, if it wishes to return a value to the caller, should leave
-the value in <code><nobr>AL</nobr></code>, <code><nobr>AX</nobr></code> or
-<code><nobr>EAX</nobr></code> depending on the size of the value.
-Floating-point results are typically returned in
-<code><nobr>ST0</nobr></code>.
-<li>Once the callee has finished processing, it restores
-<code><nobr>ESP</nobr></code> from <code><nobr>EBP</nobr></code> if it had
-allocated local stack space, then pops the previous value of
-<code><nobr>EBP</nobr></code>, and returns via
-<code><nobr>RET</nobr></code> (equivalently,
-<code><nobr>RETN</nobr></code>).
-<li>When the caller regains control from the callee, the function
-parameters are still on the stack, so it typically adds an immediate
-constant to <code><nobr>ESP</nobr></code> to remove them (instead of
-executing a number of slow <code><nobr>POP</nobr></code> instructions).
-Thus, if a function is accidentally called with the wrong number of
-parameters due to a prototype mismatch, the stack will still be returned to
-a sensible state since the caller, which <em>knows</em> how many parameters
-it pushed, does the removing.
-</ul>
-<p>There is an alternative calling convention used by Win32 programs for
-Windows API calls, and also for functions called <em>by</em> the Windows
-API such as window procedures: they follow what Microsoft calls the
-<code><nobr>__stdcall</nobr></code> convention. This is slightly closer to
-the Pascal convention, in that the callee clears the stack by passing a
-parameter to the <code><nobr>RET</nobr></code> instruction. However, the
-parameters are still pushed in right-to-left order.
-<p>Thus, you would define a function in C style in the following way:
-<p><pre>
-global _myfunc
-
-_myfunc:
- push ebp
- mov ebp,esp
- sub esp,0x40 ; 64 bytes of local stack space
- mov ebx,[ebp+8] ; first parameter to function
-
- ; some more code
-
- leave ; mov esp,ebp / pop ebp
- ret
-</pre>
-<p>At the other end of the process, to call a C function from your assembly
-code, you would do something like this:
-<p><pre>
-extern _printf
-
- ; and then, further down...
-
- push dword [myint] ; one of my integer variables
- push dword mystring ; pointer into my data segment
- call _printf
- add esp,byte 8 ; `byte' saves space
-
- ; then those data items...
-
-segment _DATA
-
-myint dd 1234
-mystring db 'This number -&gt; %d &lt;- should be 1234',10,0
-</pre>
-<p>This piece of code is the assembly equivalent of the C code
-<p><pre>
- int myint = 1234;
- printf("This number -&gt; %d &lt;- should be 1234\n", myint);
-</pre>
-<h4><a name="section-9.1.3">9.1.3 Accessing Data Items</a></h4>
-<p>To get at the contents of C variables, or to declare variables which C
-can access, you need only declare the names as
-<code><nobr>GLOBAL</nobr></code> or <code><nobr>EXTERN</nobr></code>.
-(Again, the names require leading underscores, as stated in
-<a href="#section-9.1.1">section 9.1.1</a>.) Thus, a C variable declared as
-<code><nobr>int i</nobr></code> can be accessed from assembler as
-<p><pre>
- extern _i
- mov eax,[_i]
-</pre>
-<p>And to declare your own integer variable which C programs can access as
-<code><nobr>extern int j</nobr></code>, you do this (making sure you are
-assembling in the <code><nobr>_DATA</nobr></code> segment, if necessary):
-<p><pre>
- global _j
-_j dd 0
-</pre>
-<p>To access a C array, you need to know the size of the components of the
-array. For example, <code><nobr>int</nobr></code> variables are four bytes
-long, so if a C program declares an array as
-<code><nobr>int a[10]</nobr></code>, you can access
-<code><nobr>a[3]</nobr></code> by coding
-<code><nobr>mov ax,[_a+12]</nobr></code>. (The byte offset 12 is obtained
-by multiplying the desired array index, 3, by the size of the array
-element, 4.) The sizes of the C base types in 32-bit compilers are: 1 for
-<code><nobr>char</nobr></code>, 2 for <code><nobr>short</nobr></code>, 4
-for <code><nobr>int</nobr></code>, <code><nobr>long</nobr></code> and
-<code><nobr>float</nobr></code>, and 8 for
-<code><nobr>double</nobr></code>. Pointers, being 32-bit addresses, are
-also 4 bytes long.
-<p>To access a C data structure, you need to know the offset from the base
-of the structure to the field you are interested in. You can either do this
-by converting the C structure definition into a NASM structure definition
-(using <code><nobr>STRUC</nobr></code>), or by calculating the one offset
-and using just that.
-<p>To do either of these, you should read your C compiler's manual to find
-out how it organizes data structures. NASM gives no special alignment to
-structure members in its own <code><nobr>STRUC</nobr></code> macro, so you
-have to specify alignment yourself if the C compiler generates it.
-Typically, you might find that a structure like
-<p><pre>
-struct {
- char c;
- int i;
-} foo;
-</pre>
-<p>might be eight bytes long rather than five, since the
-<code><nobr>int</nobr></code> field would be aligned to a four-byte
-boundary. However, this sort of feature is sometimes a configurable option
-in the C compiler, either using command-line options or
-<code><nobr>#pragma</nobr></code> lines, so you have to find out how your
-own compiler does it.
-<h4><a name="section-9.1.4">9.1.4 <code><nobr>c32.mac</nobr></code>: Helper Macros for the 32-bit C Interface</a></h4>
-<p>Included in the NASM archives, in the <code><nobr>misc</nobr></code>
-directory, is a file <code><nobr>c32.mac</nobr></code> of macros. It
-defines three macros: <code><nobr>proc</nobr></code>,
-<code><nobr>arg</nobr></code> and <code><nobr>endproc</nobr></code>. These
-are intended to be used for C-style procedure definitions, and they
-automate a lot of the work involved in keeping track of the calling
-convention.
-<p>An example of an assembly function using the macro set is given here:
-<p><pre>
-proc _proc32
-
-%$i arg
-%$j arg
- mov eax,[ebp + %$i]
- mov ebx,[ebp + %$j]
- add eax,[ebx]
-
-endproc
-</pre>
-<p>This defines <code><nobr>_proc32</nobr></code> to be a procedure taking
-two arguments, the first (<code><nobr>i</nobr></code>) an integer and the
-second (<code><nobr>j</nobr></code>) a pointer to an integer. It returns
-<code><nobr>i + *j</nobr></code>.
-<p>Note that the <code><nobr>arg</nobr></code> macro has an
-<code><nobr>EQU</nobr></code> as the first line of its expansion, and since
-the label before the macro call gets prepended to the first line of the
-expanded macro, the <code><nobr>EQU</nobr></code> works, defining
-<code><nobr>%$i</nobr></code> to be an offset from
-<code><nobr>BP</nobr></code>. A context-local variable is used, local to
-the context pushed by the <code><nobr>proc</nobr></code> macro and popped
-by the <code><nobr>endproc</nobr></code> macro, so that the same argument
-name can be used in later procedures. Of course, you don't <em>have</em> to
-do that.
-<p><code><nobr>arg</nobr></code> can take an optional parameter, giving the
-size of the argument. If no size is given, 4 is assumed, since it is likely
-that many function parameters will be of type <code><nobr>int</nobr></code>
-or pointers.
-<h3><a name="section-9.2">9.2 Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries</a></h3>
-<p><code><nobr>ELF</nobr></code> replaced the older
-<code><nobr>a.out</nobr></code> object file format under Linux because it
-contains support for position-independent code (PIC), which makes writing
-shared libraries much easier. NASM supports the
-<code><nobr>ELF</nobr></code> position-independent code features, so you
-can write Linux <code><nobr>ELF</nobr></code> shared libraries in NASM.
-<p>NetBSD, and its close cousins FreeBSD and OpenBSD, take a different
-approach by hacking PIC support into the <code><nobr>a.out</nobr></code>
-format. NASM supports this as the <code><nobr>aoutb</nobr></code> output
-format, so you can write BSD shared libraries in NASM too.
-<p>The operating system loads a PIC shared library by memory-mapping the
-library file at an arbitrarily chosen point in the address space of the
-running process. The contents of the library's code section must therefore
-not depend on where it is loaded in memory.
-<p>Therefore, you cannot get at your variables by writing code like this:
-<p><pre>
- mov eax,[myvar] ; WRONG
-</pre>
-<p>Instead, the linker provides an area of memory called the <em>global
-offset table</em>, or GOT; the GOT is situated at a constant distance from
-your library's code, so if you can find out where your library is loaded
-(which is typically done using a <code><nobr>CALL</nobr></code> and
-<code><nobr>POP</nobr></code> combination), you can obtain the address of
-the GOT, and you can then load the addresses of your variables out of
-linker-generated entries in the GOT.
-<p>The <em>data</em> section of a PIC shared library does not have these
-restrictions: since the data section is writable, it has to be copied into
-memory anyway rather than just paged in from the library file, so as long
-as it's being copied it can be relocated too. So you can put ordinary types
-of relocation in the data section without too much worry (but see
-<a href="#section-9.2.4">section 9.2.4</a> for a caveat).
-<h4><a name="section-9.2.1">9.2.1 Obtaining the Address of the GOT</a></h4>
-<p>Each code module in your shared library should define the GOT as an
-external symbol:
-<p><pre>
-extern _GLOBAL_OFFSET_TABLE_ ; in ELF
-extern __GLOBAL_OFFSET_TABLE_ ; in BSD a.out
-</pre>
-<p>At the beginning of any function in your shared library which plans to
-access your data or BSS sections, you must first calculate the address of
-the GOT. This is typically done by writing the function in this form:
-<p><pre>
-func: push ebp
- mov ebp,esp
- push ebx
- call .get_GOT
-.get_GOT:
- pop ebx
- add ebx,_GLOBAL_OFFSET_TABLE_+$$-.get_GOT wrt ..gotpc
-
- ; the function body comes here
-
- mov ebx,[ebp-4]
- mov esp,ebp
- pop ebp
- ret
-</pre>
-<p>(For BSD, again, the symbol
-<code><nobr>_GLOBAL_OFFSET_TABLE</nobr></code> requires a second leading
-underscore.)
-<p>The first two lines of this function are simply the standard C prologue
-to set up a stack frame, and the last three lines are standard C function
-epilogue. The third line, and the fourth to last line, save and restore the
-<code><nobr>EBX</nobr></code> register, because PIC shared libraries use
-this register to store the address of the GOT.
-<p>The interesting bit is the <code><nobr>CALL</nobr></code> instruction
-and the following two lines. The <code><nobr>CALL</nobr></code> and
-<code><nobr>POP</nobr></code> combination obtains the address of the label
-<code><nobr>.get_GOT</nobr></code>, without having to know in advance where
-the program was loaded (since the <code><nobr>CALL</nobr></code>
-instruction is encoded relative to the current position). The
-<code><nobr>ADD</nobr></code> instruction makes use of one of the special
-PIC relocation types: GOTPC relocation. With the
-<code><nobr>WRT ..gotpc</nobr></code> qualifier specified, the symbol
-referenced (here <code><nobr>_GLOBAL_OFFSET_TABLE_</nobr></code>, the
-special symbol assigned to the GOT) is given as an offset from the
-beginning of the section. (Actually, <code><nobr>ELF</nobr></code> encodes
-it as the offset from the operand field of the
-<code><nobr>ADD</nobr></code> instruction, but NASM simplifies this
-deliberately, so you do things the same way for both
-<code><nobr>ELF</nobr></code> and <code><nobr>BSD</nobr></code>.) So the
-instruction then <em>adds</em> the beginning of the section, to get the
-real address of the GOT, and subtracts the value of
-<code><nobr>.get_GOT</nobr></code> which it knows is in
-<code><nobr>EBX</nobr></code>. Therefore, by the time that instruction has
-finished, <code><nobr>EBX</nobr></code> contains the address of the GOT.
-<p>If you didn't follow that, don't worry: it's never necessary to obtain
-the address of the GOT by any other means, so you can put those three
-instructions into a macro and safely ignore them:
-<p><pre>
-%macro get_GOT 0
-
- call %%getgot
- %%getgot:
- pop ebx
- add ebx,_GLOBAL_OFFSET_TABLE_+$$-%%getgot wrt ..gotpc
-
-%endmacro
-</pre>
-<h4><a name="section-9.2.2">9.2.2 Finding Your Local Data Items</a></h4>
-<p>Having got the GOT, you can then use it to obtain the addresses of your
-data items. Most variables will reside in the sections you have declared;
-they can be accessed using the <code><nobr>..gotoff</nobr></code> special
-<code><nobr>WRT</nobr></code> type. The way this works is like this:
-<p><pre>
- lea eax,[ebx+myvar wrt ..gotoff]
-</pre>
-<p>The expression <code><nobr>myvar wrt ..gotoff</nobr></code> is
-calculated, when the shared library is linked, to be the offset to the
-local variable <code><nobr>myvar</nobr></code> from the beginning of the
-GOT. Therefore, adding it to <code><nobr>EBX</nobr></code> as above will
-place the real address of <code><nobr>myvar</nobr></code> in
-<code><nobr>EAX</nobr></code>.
-<p>If you declare variables as <code><nobr>GLOBAL</nobr></code> without
-specifying a size for them, they are shared between code modules in the
-library, but do not get exported from the library to the program that
-loaded it. They will still be in your ordinary data and BSS sections, so
-you can access them in the same way as local variables, using the above
-<code><nobr>..gotoff</nobr></code> mechanism.
-<p>Note that due to a peculiarity of the way BSD
-<code><nobr>a.out</nobr></code> format handles this relocation type, there
-must be at least one non-local symbol in the same section as the address
-you're trying to access.
-<h4><a name="section-9.2.3">9.2.3 Finding External and Common Data Items</a></h4>
-<p>If your library needs to get at an external variable (external to the
-<em>library</em>, not just to one of the modules within it), you must use
-the <code><nobr>..got</nobr></code> type to get at it. The
-<code><nobr>..got</nobr></code> type, instead of giving you the offset from
-the GOT base to the variable, gives you the offset from the GOT base to a
-GOT <em>entry</em> containing the address of the variable. The linker will
-set up this GOT entry when it builds the library, and the dynamic linker
-will place the correct address in it at load time. So to obtain the address
-of an external variable <code><nobr>extvar</nobr></code> in
-<code><nobr>EAX</nobr></code>, you would code
-<p><pre>
- mov eax,[ebx+extvar wrt ..got]
-</pre>
-<p>This loads the address of <code><nobr>extvar</nobr></code> out of an
-entry in the GOT. The linker, when it builds the shared library, collects
-together every relocation of type <code><nobr>..got</nobr></code>, and
-builds the GOT so as to ensure it has every necessary entry present.
-<p>Common variables must also be accessed in this way.
-<h4><a name="section-9.2.4">9.2.4 Exporting Symbols to the Library User</a></h4>
-<p>If you want to export symbols to the user of the library, you have to
-declare whether they are functions or data, and if they are data, you have
-to give the size of the data item. This is because the dynamic linker has
-to build procedure linkage table entries for any exported functions, and
-also moves exported data items away from the library's data section in
-which they were declared.
-<p>So to export a function to users of the library, you must use
-<p><pre>
-global func:function ; declare it as a function
-
-func: push ebp
-
- ; etc.
-</pre>
-<p>And to export a data item such as an array, you would have to code
-<p><pre>
-global array:data array.end-array ; give the size too
-
-array: resd 128
-.end:
-</pre>
-<p>Be careful: If you export a variable to the library user, by declaring
-it as <code><nobr>GLOBAL</nobr></code> and supplying a size, the variable
-will end up living in the data section of the main program, rather than in
-your library's data section, where you declared it. So you will have to
-access your own global variable with the <code><nobr>..got</nobr></code>
-mechanism rather than <code><nobr>..gotoff</nobr></code>, as if it were
-external (which, effectively, it has become).
-<p>Equally, if you need to store the address of an exported global in one
-of your data sections, you can't do it by means of the standard sort of
-code:
-<p><pre>
-dataptr: dd global_data_item ; WRONG
-</pre>
-<p>NASM will interpret this code as an ordinary relocation, in which
-<code><nobr>global_data_item</nobr></code> is merely an offset from the
-beginning of the <code><nobr>.data</nobr></code> section (or whatever); so
-this reference will end up pointing at your data section instead of at the
-exported global which resides elsewhere.
-<p>Instead of the above code, then, you must write
-<p><pre>
-dataptr: dd global_data_item wrt ..sym
-</pre>
-<p>which makes use of the special <code><nobr>WRT</nobr></code> type
-<code><nobr>..sym</nobr></code> to instruct NASM to search the symbol table
-for a particular symbol at that address, rather than just relocating by
-section base.
-<p>Either method will work for functions: referring to one of your
-functions by means of
-<p><pre>
-funcptr: dd my_function
-</pre>
-<p>will give the user the address of the code you wrote, whereas
-<p><pre>
-funcptr: dd my_function wrt .sym
-</pre>
-<p>will give the address of the procedure linkage table for the function,
-which is where the calling program will <em>believe</em> the function
-lives. Either address is a valid way to call the function.
-<h4><a name="section-9.2.5">9.2.5 Calling Procedures Outside the Library</a></h4>
-<p>Calling procedures outside your shared library has to be done by means
-of a <em>procedure linkage table</em>, or PLT. The PLT is placed at a known
-offset from where the library is loaded, so the library code can make calls
-to the PLT in a position-independent way. Within the PLT there is code to
-jump to offsets contained in the GOT, so function calls to other shared
-libraries or to routines in the main program can be transparently passed
-off to their real destinations.
-<p>To call an external routine, you must use another special PIC relocation
-type, <code><nobr>WRT ..plt</nobr></code>. This is much easier than the
-GOT-based ones: you simply replace calls such as
-<code><nobr>CALL printf</nobr></code> with the PLT-relative version
-<code><nobr>CALL printf WRT ..plt</nobr></code>.
-<h4><a name="section-9.2.6">9.2.6 Generating the Library File</a></h4>
-<p>Having written some code modules and assembled them to
-<code><nobr>.o</nobr></code> files, you then generate your shared library
-with a command such as
-<p><pre>
-ld -shared -o library.so module1.o module2.o # for ELF
-ld -Bshareable -o library.so module1.o module2.o # for BSD
-</pre>
-<p>For ELF, if your shared library is going to reside in system directories
-such as <code><nobr>/usr/lib</nobr></code> or
-<code><nobr>/lib</nobr></code>, it is usually worth using the
-<code><nobr>-soname</nobr></code> flag to the linker, to store the final
-library file name, with a version number, into the library:
-<p><pre>
-ld -shared -soname library.so.1 -o library.so.1.2 *.o
-</pre>
-<p>You would then copy <code><nobr>library.so.1.2</nobr></code> into the
-library directory, and create <code><nobr>library.so.1</nobr></code> as a
-symbolic link to it.
-<p align=center><a href="nasmdo10.html">Next Chapter</a> |
-<a href="nasmdoc8.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdoca.html b/doc/html/nasmdoca.html
deleted file mode 100644
index fda553d..0000000
--- a/doc/html/nasmdoca.html
+++ /dev/null
@@ -1,165 +0,0 @@
-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdocb.html">Next Chapter</a> |
-<a href="nasmdo12.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="appendix-A">Appendix A: Ndisasm</a></h2>
-<p>The Netwide Disassembler, NDISASM
-<h3><a name="section-A.1">A.1 Introduction</a></h3>
-<p>The Netwide Disassembler is a small companion program to the Netwide
-Assembler, NASM. It seemed a shame to have an x86 assembler, complete with
-a full instruction table, and not make as much use of it as possible, so
-here's a disassembler which shares the instruction table (and some other
-bits of code) with NASM.
-<p>The Netwide Disassembler does nothing except to produce disassemblies of
-<em>binary</em> source files. NDISASM does not have any understanding of
-object file formats, like <code><nobr>objdump</nobr></code>, and it will
-not understand <code><nobr>DOS .EXE</nobr></code> files like
-<code><nobr>debug</nobr></code> will. It just disassembles.
-<h3><a name="section-A.2">A.2 Getting Started: Installation</a></h3>
-<p>See <a href="nasmdoc1.html#section-1.3">section 1.3</a> for installation
-instructions. NDISASM, like NASM, has a <code><nobr>man page</nobr></code>
-which you may want to put somewhere useful, if you are on a Unix system.
-<h3><a name="section-A.3">A.3 Running NDISASM</a></h3>
-<p>To disassemble a file, you will typically use a command of the form
-<p><pre>
- ndisasm -b {16|32|64} filename
-</pre>
-<p>NDISASM can disassemble 16-, 32- or 64-bit code equally easily, provided
-of course that you remember to specify which it is to work with. If no
-<code><nobr>-b</nobr></code> switch is present, NDISASM works in 16-bit
-mode by default. The <code><nobr>-u</nobr></code> switch (for USE32) also
-invokes 32-bit mode.
-<p>Two more command line options are <code><nobr>-r</nobr></code> which
-reports the version number of NDISASM you are running, and
-<code><nobr>-h</nobr></code> which gives a short summary of command line
-options.
-<h4><a name="section-A.3.1">A.3.1 COM Files: Specifying an Origin</a></h4>
-<p>To disassemble a <code><nobr>DOS .COM</nobr></code> file correctly, a
-disassembler must assume that the first instruction in the file is loaded
-at address <code><nobr>0x100</nobr></code>, rather than at zero. NDISASM,
-which assumes by default that any file you give it is loaded at zero, will
-therefore need to be informed of this.
-<p>The <code><nobr>-o</nobr></code> option allows you to declare a
-different origin for the file you are disassembling. Its argument may be
-expressed in any of the NASM numeric formats: decimal by default, if it
-begins with `<code><nobr>$</nobr></code>' or `<code><nobr>0x</nobr></code>'
-or ends in `<code><nobr>H</nobr></code>' it's
-<code><nobr>hex</nobr></code>, if it ends in `<code><nobr>Q</nobr></code>'
-it's <code><nobr>octal</nobr></code>, and if it ends in
-`<code><nobr>B</nobr></code>' it's <code><nobr>binary</nobr></code>.
-<p>Hence, to disassemble a <code><nobr>.COM</nobr></code> file:
-<p><pre>
- ndisasm -o100h filename.com
-</pre>
-<p>will do the trick.
-<h4><a name="section-A.3.2">A.3.2 Code Following Data: Synchronisation</a></h4>
-<p>Suppose you are disassembling a file which contains some data which
-isn't machine code, and <em>then</em> contains some machine code. NDISASM
-will faithfully plough through the data section, producing machine
-instructions wherever it can (although most of them will look bizarre, and
-some may have unusual prefixes, e.g.
-`<code><nobr>FS OR AX,0x240A</nobr></code>'), and generating `DB'
-instructions ever so often if it's totally stumped. Then it will reach the
-code section.
-<p>Supposing NDISASM has just finished generating a strange machine
-instruction from part of the data section, and its file position is now one
-byte <em>before</em> the beginning of the code section. It's entirely
-possible that another spurious instruction will get generated, starting
-with the final byte of the data section, and then the correct first
-instruction in the code section will not be seen because the starting point
-skipped over it. This isn't really ideal.
-<p>To avoid this, you can specify a
-`<code><nobr>synchronisation</nobr></code>' point, or indeed as many
-synchronisation points as you like (although NDISASM can only handle
-2147483647 sync points internally). The definition of a sync point is this:
-NDISASM guarantees to hit sync points exactly during disassembly. If it is
-thinking about generating an instruction which would cause it to jump over
-a sync point, it will discard that instruction and output a
-`<code><nobr>db</nobr></code>' instead. So it <em>will</em> start
-disassembly exactly from the sync point, and so you <em>will</em> see all
-the instructions in your code section.
-<p>Sync points are specified using the <code><nobr>-s</nobr></code> option:
-they are measured in terms of the program origin, not the file position. So
-if you want to synchronize after 32 bytes of a
-<code><nobr>.COM</nobr></code> file, you would have to do
-<p><pre>
- ndisasm -o100h -s120h file.com
-</pre>
-<p>rather than
-<p><pre>
- ndisasm -o100h -s20h file.com
-</pre>
-<p>As stated above, you can specify multiple sync markers if you need to,
-just by repeating the <code><nobr>-s</nobr></code> option.
-<h4><a name="section-A.3.3">A.3.3 Mixed Code and Data: Automatic (Intelligent) Synchronisation </a></h4>
-<p>Suppose you are disassembling the boot sector of a
-<code><nobr>DOS</nobr></code> floppy (maybe it has a virus, and you need to
-understand the virus so that you know what kinds of damage it might have
-done you). Typically, this will contain a <code><nobr>JMP</nobr></code>
-instruction, then some data, then the rest of the code. So there is a very
-good chance of NDISASM being <em>misaligned</em> when the data ends and the
-code begins. Hence a sync point is needed.
-<p>On the other hand, why should you have to specify the sync point
-manually? What you'd do in order to find where the sync point would be,
-surely, would be to read the <code><nobr>JMP</nobr></code> instruction, and
-then to use its target address as a sync point. So can NDISASM do that for
-you?
-<p>The answer, of course, is yes: using either of the synonymous switches
-<code><nobr>-a</nobr></code> (for automatic sync) or
-<code><nobr>-i</nobr></code> (for intelligent sync) will enable
-<code><nobr>auto-sync</nobr></code> mode. Auto-sync mode automatically
-generates a sync point for any forward-referring PC-relative jump or call
-instruction that NDISASM encounters. (Since NDISASM is one-pass, if it
-encounters a PC-relative jump whose target has already been processed,
-there isn't much it can do about it...)
-<p>Only PC-relative jumps are processed, since an absolute jump is either
-through a register (in which case NDISASM doesn't know what the register
-contains) or involves a segment address (in which case the target code
-isn't in the same segment that NDISASM is working in, and so the sync point
-can't be placed anywhere useful).
-<p>For some kinds of file, this mechanism will automatically put sync
-points in all the right places, and save you from having to place any sync
-points manually. However, it should be stressed that auto-sync mode is
-<em>not</em> guaranteed to catch all the sync points, and you may still
-have to place some manually.
-<p>Auto-sync mode doesn't prevent you from declaring manual sync points: it
-just adds automatically generated ones to the ones you provide. It's
-perfectly feasible to specify <code><nobr>-i</nobr></code> <em>and</em>
-some <code><nobr>-s</nobr></code> options.
-<p>Another caveat with auto-sync mode is that if, by some unpleasant fluke,
-something in your data section should disassemble to a PC-relative call or
-jump instruction, NDISASM may obediently place a sync point in a totally
-random place, for example in the middle of one of the instructions in your
-code section. So you may end up with a wrong disassembly even if you use
-auto-sync. Again, there isn't much I can do about this. If you have
-problems, you'll have to use manual sync points, or use the
-<code><nobr>-k</nobr></code> option (documented below) to suppress
-disassembly of the data area.
-<h4><a name="section-A.3.4">A.3.4 Other Options</a></h4>
-<p>The <code><nobr>-e</nobr></code> option skips a header on the file, by
-ignoring the first N bytes. This means that the header is <em>not</em>
-counted towards the disassembly offset: if you give
-<code><nobr>-e10 -o10</nobr></code>, disassembly will start at byte 10 in
-the file, and this will be given offset 10, not 20.
-<p>The <code><nobr>-k</nobr></code> option is provided with two
-comma-separated numeric arguments, the first of which is an assembly offset
-and the second is a number of bytes to skip. This <em>will</em> count the
-skipped bytes towards the assembly offset: its use is to suppress
-disassembly of a data section which wouldn't contain anything you wanted to
-see anyway.
-<h3><a name="section-A.4">A.4 Bugs and Improvements</a></h3>
-<p>There are no known bugs. However, any you find, with patches if
-possible, should be sent to
-<a href="mailto:nasm-bugs@lists.sourceforge.net"><code><nobr>nasm-bugs@lists.sourceforge.net</nobr></code></a>,
-or to the developer's site at
-<a href="https://sourceforge.net/projects/nasm/"><code><nobr>https://sourceforge.net/projects/nasm/</nobr></code></a>
-and we'll try to fix them. Feel free to send contributions and new features
-as well.
-<p align=center><a href="nasmdocb.html">Next Chapter</a> |
-<a href="nasmdo12.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdocb.html b/doc/html/nasmdocb.html
deleted file mode 100644
index 15bca45..0000000
--- a/doc/html/nasmdocb.html
+++ /dev/null
@@ -1,3148 +0,0 @@
-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdocc.html">Next Chapter</a> |
-<a href="nasmdoca.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="appendix-B">Appendix B: Instruction List</a></h2>
-<h3><a name="section-B.1">B.1 Introduction</a></h3>
-<p>The following sections show the instructions which NASM currently
-supports. For each instruction, there is a separate entry for each
-supported addressing mode. The third column shows the processor type in
-which the instruction was introduced and, when appropriate, one or more
-usage flags.
-<h4><a name="section-B.1.1">B.1.1 Special instructions...</a></h4>
-<p><pre>
-DB
-DW
-DD
-DQ
-DT
-DO
-DY
-RESB imm 8086
-RESW
-RESD
-RESQ
-REST
-RESO
-RESY
-</pre>
-<h4><a name="section-B.1.2">B.1.2 Conventional instructions</a></h4>
-<p><pre>
-AAA 8086,NOLONG
-AAD 8086,NOLONG
-AAD imm 8086,NOLONG
-AAM 8086,NOLONG
-AAM imm 8086,NOLONG
-AAS 8086,NOLONG
-ADC mem,reg8 8086
-ADC reg8,reg8 8086
-ADC mem,reg16 8086
-ADC reg16,reg16 8086
-ADC mem,reg32 386
-ADC reg32,reg32 386
-ADC mem,reg64 X64
-ADC reg64,reg64 X64
-ADC reg8,mem 8086
-ADC reg8,reg8 8086
-ADC reg16,mem 8086
-ADC reg16,reg16 8086
-ADC reg32,mem 386
-ADC reg32,reg32 386
-ADC reg64,mem X64
-ADC reg64,reg64 X64
-ADC rm16,imm8 8086
-ADC rm32,imm8 386
-ADC rm64,imm8 X64
-ADC reg_al,imm 8086
-ADC reg_ax,sbyte16 8086
-ADC reg_ax,imm 8086
-ADC reg_eax,sbyte32 386
-ADC reg_eax,imm 386
-ADC reg_rax,sbyte64 X64
-ADC reg_rax,imm X64
-ADC rm8,imm 8086
-ADC rm16,imm 8086
-ADC rm32,imm 386
-ADC rm64,imm X64
-ADC mem,imm8 8086
-ADC mem,imm16 8086
-ADC mem,imm32 386
-ADD mem,reg8 8086
-ADD reg8,reg8 8086
-ADD mem,reg16 8086
-ADD reg16,reg16 8086
-ADD mem,reg32 386
-ADD reg32,reg32 386
-ADD mem,reg64 X64
-ADD reg64,reg64 X64
-ADD reg8,mem 8086
-ADD reg8,reg8 8086
-ADD reg16,mem 8086
-ADD reg16,reg16 8086
-ADD reg32,mem 386
-ADD reg32,reg32 386
-ADD reg64,mem X64
-ADD reg64,reg64 X64
-ADD rm16,imm8 8086
-ADD rm32,imm8 386
-ADD rm64,imm8 X64
-ADD reg_al,imm 8086
-ADD reg_ax,sbyte16 8086
-ADD reg_ax,imm 8086
-ADD reg_eax,sbyte32 386
-ADD reg_eax,imm 386
-ADD reg_rax,sbyte64 X64
-ADD reg_rax,imm X64
-ADD rm8,imm 8086
-ADD rm16,imm 8086
-ADD rm32,imm 386
-ADD rm64,imm X64
-ADD mem,imm8 8086
-ADD mem,imm16 8086
-ADD mem,imm32 386
-AND mem,reg8 8086
-AND reg8,reg8 8086
-AND mem,reg16 8086
-AND reg16,reg16 8086
-AND mem,reg32 386
-AND reg32,reg32 386
-AND mem,reg64 X64
-AND reg64,reg64 X64
-AND reg8,mem 8086
-AND reg8,reg8 8086
-AND reg16,mem 8086
-AND reg16,reg16 8086
-AND reg32,mem 386
-AND reg32,reg32 386
-AND reg64,mem X64
-AND reg64,reg64 X64
-AND rm16,imm8 8086
-AND rm32,imm8 386
-AND rm64,imm8 X64
-AND reg_al,imm 8086
-AND reg_ax,sbyte16 8086
-AND reg_ax,imm 8086
-AND reg_eax,sbyte32 386
-AND reg_eax,imm 386
-AND reg_rax,sbyte64 X64
-AND reg_rax,imm X64
-AND rm8,imm 8086
-AND rm16,imm 8086
-AND rm32,imm 386
-AND rm64,imm X64
-AND mem,imm8 8086
-AND mem,imm16 8086
-AND mem,imm32 386
-ARPL mem,reg16 286,PROT,NOLONG
-ARPL reg16,reg16 286,PROT,NOLONG
-BB0_RESET PENT,CYRIX,ND
-BB1_RESET PENT,CYRIX,ND
-BOUND reg16,mem 186,NOLONG
-BOUND reg32,mem 386,NOLONG
-BSF reg16,mem 386
-BSF reg16,reg16 386
-BSF reg32,mem 386
-BSF reg32,reg32 386
-BSF reg64,mem X64
-BSF reg64,reg64 X64
-BSR reg16,mem 386
-BSR reg16,reg16 386
-BSR reg32,mem 386
-BSR reg32,reg32 386
-BSR reg64,mem X64
-BSR reg64,reg64 X64
-BSWAP reg32 486
-BSWAP reg64 X64
-BT mem,reg16 386
-BT reg16,reg16 386
-BT mem,reg32 386
-BT reg32,reg32 386
-BT mem,reg64 X64
-BT reg64,reg64 X64
-BT rm16,imm 386
-BT rm32,imm 386
-BT rm64,imm X64
-BTC mem,reg16 386
-BTC reg16,reg16 386
-BTC mem,reg32 386
-BTC reg32,reg32 386
-BTC mem,reg64 X64
-BTC reg64,reg64 X64
-BTC rm16,imm 386
-BTC rm32,imm 386
-BTC rm64,imm X64
-BTR mem,reg16 386
-BTR reg16,reg16 386
-BTR mem,reg32 386
-BTR reg32,reg32 386
-BTR mem,reg64 X64
-BTR reg64,reg64 X64
-BTR rm16,imm 386
-BTR rm32,imm 386
-BTR rm64,imm X64
-BTS mem,reg16 386
-BTS reg16,reg16 386
-BTS mem,reg32 386
-BTS reg32,reg32 386
-BTS mem,reg64 X64
-BTS reg64,reg64 X64
-BTS rm16,imm 386
-BTS rm32,imm 386
-BTS rm64,imm X64
-CALL imm 8086
-CALL imm|near 8086
-CALL imm|far 8086,ND,NOLONG
-CALL imm16 8086
-CALL imm16|near 8086
-CALL imm16|far 8086,ND,NOLONG
-CALL imm32 386
-CALL imm32|near 386
-CALL imm32|far 386,ND,NOLONG
-CALL imm:imm 8086,NOLONG
-CALL imm16:imm 8086,NOLONG
-CALL imm:imm16 8086,NOLONG
-CALL imm32:imm 386,NOLONG
-CALL imm:imm32 386,NOLONG
-CALL mem|far 8086,NOLONG
-CALL mem|far X64
-CALL mem16|far 8086
-CALL mem32|far 386
-CALL mem64|far X64
-CALL mem|near 8086
-CALL mem16|near 8086
-CALL mem32|near 386,NOLONG
-CALL mem64|near X64
-CALL reg16 8086
-CALL reg32 386,NOLONG
-CALL reg64 X64
-CALL mem 8086
-CALL mem16 8086
-CALL mem32 386,NOLONG
-CALL mem64 X64
-CBW 8086
-CDQ 386
-CDQE X64
-CLC 8086
-CLD 8086
-CLGI X64,AMD
-CLI 8086
-CLTS 286,PRIV
-CMC 8086
-CMP mem,reg8 8086
-CMP reg8,reg8 8086
-CMP mem,reg16 8086
-CMP reg16,reg16 8086
-CMP mem,reg32 386
-CMP reg32,reg32 386
-CMP mem,reg64 X64
-CMP reg64,reg64 X64
-CMP reg8,mem 8086
-CMP reg8,reg8 8086
-CMP reg16,mem 8086
-CMP reg16,reg16 8086
-CMP reg32,mem 386
-CMP reg32,reg32 386
-CMP reg64,mem X64
-CMP reg64,reg64 X64
-CMP rm16,imm8 8086
-CMP rm32,imm8 386
-CMP rm64,imm8 X64
-CMP reg_al,imm 8086
-CMP reg_ax,sbyte16 8086
-CMP reg_ax,imm 8086
-CMP reg_eax,sbyte32 386
-CMP reg_eax,imm 386
-CMP reg_rax,sbyte64 X64
-CMP reg_rax,imm X64
-CMP rm8,imm 8086
-CMP rm16,imm 8086
-CMP rm32,imm 386
-CMP rm64,imm X64
-CMP mem,imm8 8086
-CMP mem,imm16 8086
-CMP mem,imm32 386
-CMPSB 8086
-CMPSD 386
-CMPSQ X64
-CMPSW 8086
-CMPXCHG mem,reg8 PENT
-CMPXCHG reg8,reg8 PENT
-CMPXCHG mem,reg16 PENT
-CMPXCHG reg16,reg16 PENT
-CMPXCHG mem,reg32 PENT
-CMPXCHG reg32,reg32 PENT
-CMPXCHG mem,reg64 X64
-CMPXCHG reg64,reg64 X64
-CMPXCHG486 mem,reg8 486,UNDOC,ND
-CMPXCHG486 reg8,reg8 486,UNDOC,ND
-CMPXCHG486 mem,reg16 486,UNDOC,ND
-CMPXCHG486 reg16,reg16 486,UNDOC,ND
-CMPXCHG486 mem,reg32 486,UNDOC,ND
-CMPXCHG486 reg32,reg32 486,UNDOC,ND
-CMPXCHG8B mem PENT
-CMPXCHG16B mem X64
-CPUID PENT
-CPU_READ PENT,CYRIX
-CPU_WRITE PENT,CYRIX
-CQO X64
-CWD 8086
-CWDE 386
-DAA 8086,NOLONG
-DAS 8086,NOLONG
-DEC reg16 8086,NOLONG
-DEC reg32 386,NOLONG
-DEC rm8 8086
-DEC rm16 8086
-DEC rm32 386
-DEC rm64 X64
-DIV rm8 8086
-DIV rm16 8086
-DIV rm32 386
-DIV rm64 X64
-DMINT P6,CYRIX
-EMMS PENT,MMX
-ENTER imm,imm 186
-EQU imm 8086
-EQU imm:imm 8086
-F2XM1 8086,FPU
-FABS 8086,FPU
-FADD mem32 8086,FPU
-FADD mem64 8086,FPU
-FADD fpureg|to 8086,FPU
-FADD fpureg 8086,FPU
-FADD fpureg,fpu0 8086,FPU
-FADD fpu0,fpureg 8086,FPU
-FADD 8086,FPU,ND
-FADDP fpureg 8086,FPU
-FADDP fpureg,fpu0 8086,FPU
-FADDP 8086,FPU,ND
-FBLD mem80 8086,FPU
-FBLD mem 8086,FPU
-FBSTP mem80 8086,FPU
-FBSTP mem 8086,FPU
-FCHS 8086,FPU
-FCLEX 8086,FPU
-FCMOVB fpureg P6,FPU
-FCMOVB fpu0,fpureg P6,FPU
-FCMOVB P6,FPU,ND
-FCMOVBE fpureg P6,FPU
-FCMOVBE fpu0,fpureg P6,FPU
-FCMOVBE P6,FPU,ND
-FCMOVE fpureg P6,FPU
-FCMOVE fpu0,fpureg P6,FPU
-FCMOVE P6,FPU,ND
-FCMOVNB fpureg P6,FPU
-FCMOVNB fpu0,fpureg P6,FPU
-FCMOVNB P6,FPU,ND
-FCMOVNBE fpureg P6,FPU
-FCMOVNBE fpu0,fpureg P6,FPU
-FCMOVNBE P6,FPU,ND
-FCMOVNE fpureg P6,FPU
-FCMOVNE fpu0,fpureg P6,FPU
-FCMOVNE P6,FPU,ND
-FCMOVNU fpureg P6,FPU
-FCMOVNU fpu0,fpureg P6,FPU
-FCMOVNU P6,FPU,ND
-FCMOVU fpureg P6,FPU
-FCMOVU fpu0,fpureg P6,FPU
-FCMOVU P6,FPU,ND
-FCOM mem32 8086,FPU
-FCOM mem64 8086,FPU
-FCOM fpureg 8086,FPU
-FCOM fpu0,fpureg 8086,FPU
-FCOM 8086,FPU,ND
-FCOMI fpureg P6,FPU
-FCOMI fpu0,fpureg P6,FPU
-FCOMI P6,FPU,ND
-FCOMIP fpureg P6,FPU
-FCOMIP fpu0,fpureg P6,FPU
-FCOMIP P6,FPU,ND
-FCOMP mem32 8086,FPU
-FCOMP mem64 8086,FPU
-FCOMP fpureg 8086,FPU
-FCOMP fpu0,fpureg 8086,FPU
-FCOMP 8086,FPU,ND
-FCOMPP 8086,FPU
-FCOS 386,FPU
-FDECSTP 8086,FPU
-FDISI 8086,FPU
-FDIV mem32 8086,FPU
-FDIV mem64 8086,FPU
-FDIV fpureg|to 8086,FPU
-FDIV fpureg 8086,FPU
-FDIV fpureg,fpu0 8086,FPU
-FDIV fpu0,fpureg 8086,FPU
-FDIV 8086,FPU,ND
-FDIVP fpureg 8086,FPU
-FDIVP fpureg,fpu0 8086,FPU
-FDIVP 8086,FPU,ND
-FDIVR mem32 8086,FPU
-FDIVR mem64 8086,FPU
-FDIVR fpureg|to 8086,FPU
-FDIVR fpureg,fpu0 8086,FPU
-FDIVR fpureg 8086,FPU
-FDIVR fpu0,fpureg 8086,FPU
-FDIVR 8086,FPU,ND
-FDIVRP fpureg 8086,FPU
-FDIVRP fpureg,fpu0 8086,FPU
-FDIVRP 8086,FPU,ND
-FEMMS PENT,3DNOW
-FENI 8086,FPU
-FFREE fpureg 8086,FPU
-FFREE 8086,FPU
-FFREEP fpureg 286,FPU,UNDOC
-FFREEP 286,FPU,UNDOC
-FIADD mem32 8086,FPU
-FIADD mem16 8086,FPU
-FICOM mem32 8086,FPU
-FICOM mem16 8086,FPU
-FICOMP mem32 8086,FPU
-FICOMP mem16 8086,FPU
-FIDIV mem32 8086,FPU
-FIDIV mem16 8086,FPU
-FIDIVR mem32 8086,FPU
-FIDIVR mem16 8086,FPU
-FILD mem32 8086,FPU
-FILD mem16 8086,FPU
-FILD mem64 8086,FPU
-FIMUL mem32 8086,FPU
-FIMUL mem16 8086,FPU
-FINCSTP 8086,FPU
-FINIT 8086,FPU
-FIST mem32 8086,FPU
-FIST mem16 8086,FPU
-FISTP mem32 8086,FPU
-FISTP mem16 8086,FPU
-FISTP mem64 8086,FPU
-FISTTP mem16 PRESCOTT,FPU
-FISTTP mem32 PRESCOTT,FPU
-FISTTP mem64 PRESCOTT,FPU
-FISUB mem32 8086,FPU
-FISUB mem16 8086,FPU
-FISUBR mem32 8086,FPU
-FISUBR mem16 8086,FPU
-FLD mem32 8086,FPU
-FLD mem64 8086,FPU
-FLD mem80 8086,FPU
-FLD fpureg 8086,FPU
-FLD 8086,FPU,ND
-FLD1 8086,FPU
-FLDCW mem 8086,FPU,SW
-FLDENV mem 8086,FPU
-FLDL2E 8086,FPU
-FLDL2T 8086,FPU
-FLDLG2 8086,FPU
-FLDLN2 8086,FPU
-FLDPI 8086,FPU
-FLDZ 8086,FPU
-FMUL mem32 8086,FPU
-FMUL mem64 8086,FPU
-FMUL fpureg|to 8086,FPU
-FMUL fpureg,fpu0 8086,FPU
-FMUL fpureg 8086,FPU
-FMUL fpu0,fpureg 8086,FPU
-FMUL 8086,FPU,ND
-FMULP fpureg 8086,FPU
-FMULP fpureg,fpu0 8086,FPU
-FMULP 8086,FPU,ND
-FNCLEX 8086,FPU
-FNDISI 8086,FPU
-FNENI 8086,FPU
-FNINIT 8086,FPU
-FNOP 8086,FPU
-FNSAVE mem 8086,FPU
-FNSTCW mem 8086,FPU,SW
-FNSTENV mem 8086,FPU
-FNSTSW mem 8086,FPU,SW
-FNSTSW reg_ax 286,FPU
-FPATAN 8086,FPU
-FPREM 8086,FPU
-FPREM1 386,FPU
-FPTAN 8086,FPU
-FRNDINT 8086,FPU
-FRSTOR mem 8086,FPU
-FSAVE mem 8086,FPU
-FSCALE 8086,FPU
-FSETPM 286,FPU
-FSIN 386,FPU
-FSINCOS 386,FPU
-FSQRT 8086,FPU
-FST mem32 8086,FPU
-FST mem64 8086,FPU
-FST fpureg 8086,FPU
-FST 8086,FPU,ND
-FSTCW mem 8086,FPU,SW
-FSTENV mem 8086,FPU
-FSTP mem32 8086,FPU
-FSTP mem64 8086,FPU
-FSTP mem80 8086,FPU
-FSTP fpureg 8086,FPU
-FSTP 8086,FPU,ND
-FSTSW mem 8086,FPU,SW
-FSTSW reg_ax 286,FPU
-FSUB mem32 8086,FPU
-FSUB mem64 8086,FPU
-FSUB fpureg|to 8086,FPU
-FSUB fpureg,fpu0 8086,FPU
-FSUB fpureg 8086,FPU
-FSUB fpu0,fpureg 8086,FPU
-FSUB 8086,FPU,ND
-FSUBP fpureg 8086,FPU
-FSUBP fpureg,fpu0 8086,FPU
-FSUBP 8086,FPU,ND
-FSUBR mem32 8086,FPU
-FSUBR mem64 8086,FPU
-FSUBR fpureg|to 8086,FPU
-FSUBR fpureg,fpu0 8086,FPU
-FSUBR fpureg 8086,FPU
-FSUBR fpu0,fpureg 8086,FPU
-FSUBR 8086,FPU,ND
-FSUBRP fpureg 8086,FPU
-FSUBRP fpureg,fpu0 8086,FPU
-FSUBRP 8086,FPU,ND
-FTST 8086,FPU
-FUCOM fpureg 386,FPU
-FUCOM fpu0,fpureg 386,FPU
-FUCOM 386,FPU,ND
-FUCOMI fpureg P6,FPU
-FUCOMI fpu0,fpureg P6,FPU
-FUCOMI P6,FPU,ND
-FUCOMIP fpureg P6,FPU
-FUCOMIP fpu0,fpureg P6,FPU
-FUCOMIP P6,FPU,ND
-FUCOMP fpureg 386,FPU
-FUCOMP fpu0,fpureg 386,FPU
-FUCOMP 386,FPU,ND
-FUCOMPP 386,FPU
-FXAM 8086,FPU
-FXCH fpureg 8086,FPU
-FXCH fpureg,fpu0 8086,FPU
-FXCH fpu0,fpureg 8086,FPU
-FXCH 8086,FPU,ND
-FXTRACT 8086,FPU
-FYL2X 8086,FPU
-FYL2XP1 8086,FPU
-HLT 8086,PRIV
-IBTS mem,reg16 386,SW,UNDOC,ND
-IBTS reg16,reg16 386,UNDOC,ND
-IBTS mem,reg32 386,SD,UNDOC,ND
-IBTS reg32,reg32 386,UNDOC,ND
-ICEBP 386,ND
-IDIV rm8 8086
-IDIV rm16 8086
-IDIV rm32 386
-IDIV rm64 X64
-IMUL rm8 8086
-IMUL rm16 8086
-IMUL rm32 386
-IMUL rm64 X64
-IMUL reg16,mem 386
-IMUL reg16,reg16 386
-IMUL reg32,mem 386
-IMUL reg32,reg32 386
-IMUL reg64,mem X64
-IMUL reg64,reg64 X64
-IMUL reg16,mem,imm8 186
-IMUL reg16,mem,sbyte16 186,ND
-IMUL reg16,mem,imm16 186
-IMUL reg16,mem,imm 186,ND
-IMUL reg16,reg16,imm8 186
-IMUL reg16,reg16,sbyte16 186,ND
-IMUL reg16,reg16,imm16 186
-IMUL reg16,reg16,imm 186,ND
-IMUL reg32,mem,imm8 386
-IMUL reg32,mem,sbyte32 386,ND
-IMUL reg32,mem,imm32 386
-IMUL reg32,mem,imm 386,ND
-IMUL reg32,reg32,imm8 386
-IMUL reg32,reg32,sbyte32 386,ND
-IMUL reg32,reg32,imm32 386
-IMUL reg32,reg32,imm 386,ND
-IMUL reg64,mem,imm8 X64
-IMUL reg64,mem,sbyte64 X64,ND
-IMUL reg64,mem,imm32 X64
-IMUL reg64,mem,imm X64,ND
-IMUL reg64,reg64,imm8 X64
-IMUL reg64,reg64,sbyte64 X64,ND
-IMUL reg64,reg64,imm32 X64
-IMUL reg64,reg64,imm X64,ND
-IMUL reg16,imm8 186
-IMUL reg16,sbyte16 186,ND
-IMUL reg16,imm16 186
-IMUL reg16,imm 186,ND
-IMUL reg32,imm8 386
-IMUL reg32,sbyte32 386,ND
-IMUL reg32,imm32 386
-IMUL reg32,imm 386,ND
-IMUL reg64,imm8 X64
-IMUL reg64,sbyte64 X64,ND
-IMUL reg64,imm32 X64
-IMUL reg64,imm X64,ND
-IN reg_al,imm 8086
-IN reg_ax,imm 8086
-IN reg_eax,imm 386
-IN reg_al,reg_dx 8086
-IN reg_ax,reg_dx 8086
-IN reg_eax,reg_dx 386
-INC reg16 8086,NOLONG
-INC reg32 386,NOLONG
-INC rm8 8086
-INC rm16 8086
-INC rm32 386
-INC rm64 X64
-INCBIN
-INSB 186
-INSD 386
-INSW 186
-INT imm 8086
-INT01 386,ND
-INT1 386
-INT03 8086,ND
-INT3 8086
-INTO 8086,NOLONG
-INVD 486,PRIV
-INVLPG mem 486,PRIV
-INVLPGA reg_ax,reg_ecx X86_64,AMD,NOLONG
-INVLPGA reg_eax,reg_ecx X86_64,AMD
-INVLPGA reg_rax,reg_ecx X64,AMD
-INVLPGA X86_64,AMD
-IRET 8086
-IRETD 386
-IRETQ X64
-IRETW 8086
-JCXZ imm 8086,NOLONG
-JECXZ imm 386
-JRCXZ imm X64
-JMP imm|short 8086
-JMP imm 8086,ND
-JMP imm 8086
-JMP imm|near 8086,ND
-JMP imm|far 8086,ND,NOLONG
-JMP imm16 8086
-JMP imm16|near 8086,ND
-JMP imm16|far 8086,ND,NOLONG
-JMP imm32 386
-JMP imm32|near 386,ND
-JMP imm32|far 386,ND,NOLONG
-JMP imm:imm 8086,NOLONG
-JMP imm16:imm 8086,NOLONG
-JMP imm:imm16 8086,NOLONG
-JMP imm32:imm 386,NOLONG
-JMP imm:imm32 386,NOLONG
-JMP mem|far 8086,NOLONG
-JMP mem|far X64
-JMP mem16|far 8086
-JMP mem32|far 386
-JMP mem64|far X64
-JMP mem|near 8086
-JMP mem16|near 8086
-JMP mem32|near 386,NOLONG
-JMP mem64|near X64
-JMP reg16 8086
-JMP reg32 386,NOLONG
-JMP reg64 X64
-JMP mem 8086
-JMP mem16 8086
-JMP mem32 386,NOLONG
-JMP mem64 X64
-JMPE imm IA64
-JMPE imm16 IA64
-JMPE imm32 IA64
-JMPE rm16 IA64
-JMPE rm32 IA64
-LAHF 8086
-LAR reg16,mem 286,PROT,SW
-LAR reg16,reg16 286,PROT
-LAR reg16,reg32 386,PROT
-LAR reg16,reg64 X64,PROT,ND
-LAR reg32,mem 386,PROT,SW
-LAR reg32,reg16 386,PROT
-LAR reg32,reg32 386,PROT
-LAR reg32,reg64 X64,PROT,ND
-LAR reg64,mem X64,PROT,SW
-LAR reg64,reg16 X64,PROT
-LAR reg64,reg32 X64,PROT
-LAR reg64,reg64 X64,PROT
-LDS reg16,mem 8086,NOLONG
-LDS reg32,mem 386,NOLONG
-LEA reg16,mem 8086
-LEA reg32,mem 386
-LEA reg64,mem X64
-LEAVE 186
-LES reg16,mem 8086,NOLONG
-LES reg32,mem 386,NOLONG
-LFENCE X64,AMD
-LFS reg16,mem 386
-LFS reg32,mem 386
-LGDT mem 286,PRIV
-LGS reg16,mem 386
-LGS reg32,mem 386
-LIDT mem 286,PRIV
-LLDT mem 286,PROT,PRIV
-LLDT mem16 286,PROT,PRIV
-LLDT reg16 286,PROT,PRIV
-LMSW mem 286,PRIV
-LMSW mem16 286,PRIV
-LMSW reg16 286,PRIV
-LOADALL 386,UNDOC
-LOADALL286 286,UNDOC
-LODSB 8086
-LODSD 386
-LODSQ X64
-LODSW 8086
-LOOP imm 8086
-LOOP imm,reg_cx 8086,NOLONG
-LOOP imm,reg_ecx 386
-LOOP imm,reg_rcx X64
-LOOPE imm 8086
-LOOPE imm,reg_cx 8086,NOLONG
-LOOPE imm,reg_ecx 386
-LOOPE imm,reg_rcx X64
-LOOPNE imm 8086
-LOOPNE imm,reg_cx 8086,NOLONG
-LOOPNE imm,reg_ecx 386
-LOOPNE imm,reg_rcx X64
-LOOPNZ imm 8086
-LOOPNZ imm,reg_cx 8086,NOLONG
-LOOPNZ imm,reg_ecx 386
-LOOPNZ imm,reg_rcx X64
-LOOPZ imm 8086
-LOOPZ imm,reg_cx 8086,NOLONG
-LOOPZ imm,reg_ecx 386
-LOOPZ imm,reg_rcx X64
-LSL reg16,mem 286,PROT,SW
-LSL reg16,reg16 286,PROT
-LSL reg16,reg32 386,PROT
-LSL reg16,reg64 X64,PROT,ND
-LSL reg32,mem 386,PROT,SW
-LSL reg32,reg16 386,PROT
-LSL reg32,reg32 386,PROT
-LSL reg32,reg64 X64,PROT,ND
-LSL reg64,mem X64,PROT,SW
-LSL reg64,reg16 X64,PROT
-LSL reg64,reg32 X64,PROT
-LSL reg64,reg64 X64,PROT
-LSS reg16,mem 386
-LSS reg32,mem 386
-LTR mem 286,PROT,PRIV
-LTR mem16 286,PROT,PRIV
-LTR reg16 286,PROT,PRIV
-MFENCE X64,AMD
-MONITOR PRESCOTT
-MONITOR reg_eax,reg_ecx,reg_edx PRESCOTT,ND
-MONITOR reg_rax,reg_ecx,reg_edx X64,ND
-MOV mem,reg_sreg 8086
-MOV reg16,reg_sreg 8086
-MOV reg32,reg_sreg 386
-MOV reg_sreg,mem 8086
-MOV reg_sreg,reg16 8086
-MOV reg_sreg,reg32 386
-MOV reg_al,mem_offs 8086
-MOV reg_ax,mem_offs 8086
-MOV reg_eax,mem_offs 386
-MOV reg_rax,mem_offs X64
-MOV mem_offs,reg_al 8086
-MOV mem_offs,reg_ax 8086
-MOV mem_offs,reg_eax 386
-MOV mem_offs,reg_rax X64
-MOV reg32,reg_creg 386,PRIV,NOLONG
-MOV reg64,reg_creg X64,PRIV
-MOV reg_creg,reg32 386,PRIV,NOLONG
-MOV reg_creg,reg64 X64,PRIV
-MOV reg32,reg_dreg 386,PRIV,NOLONG
-MOV reg64,reg_dreg X64,PRIV
-MOV reg_dreg,reg32 386,PRIV,NOLONG
-MOV reg_dreg,reg64 X64,PRIV
-MOV reg32,reg_treg 386,NOLONG,ND
-MOV reg_treg,reg32 386,NOLONG,ND
-MOV mem,reg8 8086
-MOV reg8,reg8 8086
-MOV mem,reg16 8086
-MOV reg16,reg16 8086
-MOV mem,reg32 386
-MOV reg32,reg32 386
-MOV mem,reg64 X64
-MOV reg64,reg64 X64
-MOV reg8,mem 8086
-MOV reg8,reg8 8086
-MOV reg16,mem 8086
-MOV reg16,reg16 8086
-MOV reg32,mem 386
-MOV reg32,reg32 386
-MOV reg64,mem X64
-MOV reg64,reg64 X64
-MOV reg8,imm 8086
-MOV reg16,imm 8086
-MOV reg32,imm 386
-MOV reg64,imm X64
-MOV reg64,imm32 X64
-MOV rm8,imm 8086
-MOV rm16,imm 8086
-MOV rm32,imm 386
-MOV rm64,imm X64
-MOV mem,imm8 8086
-MOV mem,imm16 8086
-MOV mem,imm32 386
-MOVD mmxreg,mem PENT,MMX,SD
-MOVD mmxreg,reg32 PENT,MMX
-MOVD mem,mmxreg PENT,MMX,SD
-MOVD reg32,mmxreg PENT,MMX
-MOVD xmmreg,mem X64,SD
-MOVD xmmreg,reg32 X64
-MOVD mem,xmmreg X64,SD
-MOVD reg32,xmmreg X64,SSE
-MOVQ mmxreg,mmxrm PENT,MMX
-MOVQ mmxrm,mmxreg PENT,MMX
-MOVQ mmxreg,rm64 X64,MMX
-MOVQ rm64,mmxreg X64,MMX
-MOVSB 8086
-MOVSD 386
-MOVSQ X64
-MOVSW 8086
-MOVSX reg16,mem 386
-MOVSX reg16,reg8 386
-MOVSX reg32,rm8 386
-MOVSX reg32,rm16 386
-MOVSX reg64,rm8 X64
-MOVSX reg64,rm16 X64
-MOVSXD reg64,rm32 X64
-MOVSX reg64,rm32 X64,ND
-MOVZX reg16,mem 386
-MOVZX reg16,reg8 386
-MOVZX reg32,rm8 386
-MOVZX reg32,rm16 386
-MOVZX reg64,rm8 X64
-MOVZX reg64,rm16 X64
-MUL rm8 8086
-MUL rm16 8086
-MUL rm32 386
-MUL rm64 X64
-MWAIT PRESCOTT
-MWAIT reg_eax,reg_ecx PRESCOTT,ND
-NEG rm8 8086
-NEG rm16 8086
-NEG rm32 386
-NEG rm64 X64
-NOP 8086
-NOP rm16 P6
-NOP rm32 P6
-NOP rm64 X64
-NOT rm8 8086
-NOT rm16 8086
-NOT rm32 386
-NOT rm64 X64
-OR mem,reg8 8086
-OR reg8,reg8 8086
-OR mem,reg16 8086
-OR reg16,reg16 8086
-OR mem,reg32 386
-OR reg32,reg32 386
-OR mem,reg64 X64
-OR reg64,reg64 X64
-OR reg8,mem 8086
-OR reg8,reg8 8086
-OR reg16,mem 8086
-OR reg16,reg16 8086
-OR reg32,mem 386
-OR reg32,reg32 386
-OR reg64,mem X64
-OR reg64,reg64 X64
-OR rm16,imm8 8086
-OR rm32,imm8 386
-OR rm64,imm8 X64
-OR reg_al,imm 8086
-OR reg_ax,sbyte16 8086
-OR reg_ax,imm 8086
-OR reg_eax,sbyte32 386
-OR reg_eax,imm 386
-OR reg_rax,sbyte64 X64
-OR reg_rax,imm X64
-OR rm8,imm 8086
-OR rm16,imm 8086
-OR rm32,imm 386
-OR rm64,imm X64
-OR mem,imm8 8086
-OR mem,imm16 8086
-OR mem,imm32 386
-OUT imm,reg_al 8086
-OUT imm,reg_ax 8086
-OUT imm,reg_eax 386
-OUT reg_dx,reg_al 8086
-OUT reg_dx,reg_ax 8086
-OUT reg_dx,reg_eax 386
-OUTSB 186
-OUTSD 386
-OUTSW 186
-PACKSSDW mmxreg,mmxrm PENT,MMX
-PACKSSWB mmxreg,mmxrm PENT,MMX
-PACKUSWB mmxreg,mmxrm PENT,MMX
-PADDB mmxreg,mmxrm PENT,MMX
-PADDD mmxreg,mmxrm PENT,MMX
-PADDSB mmxreg,mmxrm PENT,MMX
-PADDSIW mmxreg,mmxrm PENT,MMX,CYRIX
-PADDSW mmxreg,mmxrm PENT,MMX
-PADDUSB mmxreg,mmxrm PENT,MMX
-PADDUSW mmxreg,mmxrm PENT,MMX
-PADDW mmxreg,mmxrm PENT,MMX
-PAND mmxreg,mmxrm PENT,MMX
-PANDN mmxreg,mmxrm PENT,MMX
-PAUSE 8086
-PAVEB mmxreg,mmxrm PENT,MMX,CYRIX
-PAVGUSB mmxreg,mmxrm PENT,3DNOW
-PCMPEQB mmxreg,mmxrm PENT,MMX
-PCMPEQD mmxreg,mmxrm PENT,MMX
-PCMPEQW mmxreg,mmxrm PENT,MMX
-PCMPGTB mmxreg,mmxrm PENT,MMX
-PCMPGTD mmxreg,mmxrm PENT,MMX
-PCMPGTW mmxreg,mmxrm PENT,MMX
-PDISTIB mmxreg,mem PENT,MMX,CYRIX
-PF2ID mmxreg,mmxrm PENT,3DNOW
-PFACC mmxreg,mmxrm PENT,3DNOW
-PFADD mmxreg,mmxrm PENT,3DNOW
-PFCMPEQ mmxreg,mmxrm PENT,3DNOW
-PFCMPGE mmxreg,mmxrm PENT,3DNOW
-PFCMPGT mmxreg,mmxrm PENT,3DNOW
-PFMAX mmxreg,mmxrm PENT,3DNOW
-PFMIN mmxreg,mmxrm PENT,3DNOW
-PFMUL mmxreg,mmxrm PENT,3DNOW
-PFRCP mmxreg,mmxrm PENT,3DNOW
-PFRCPIT1 mmxreg,mmxrm PENT,3DNOW
-PFRCPIT2 mmxreg,mmxrm PENT,3DNOW
-PFRSQIT1 mmxreg,mmxrm PENT,3DNOW
-PFRSQRT mmxreg,mmxrm PENT,3DNOW
-PFSUB mmxreg,mmxrm PENT,3DNOW
-PFSUBR mmxreg,mmxrm PENT,3DNOW
-PI2FD mmxreg,mmxrm PENT,3DNOW
-PMACHRIW mmxreg,mem PENT,MMX,CYRIX
-PMADDWD mmxreg,mmxrm PENT,MMX
-PMAGW mmxreg,mmxrm PENT,MMX,CYRIX
-PMULHRIW mmxreg,mmxrm PENT,MMX,CYRIX
-PMULHRWA mmxreg,mmxrm PENT,3DNOW
-PMULHRWC mmxreg,mmxrm PENT,MMX,CYRIX
-PMULHW mmxreg,mmxrm PENT,MMX
-PMULLW mmxreg,mmxrm PENT,MMX
-PMVGEZB mmxreg,mem PENT,MMX,CYRIX
-PMVLZB mmxreg,mem PENT,MMX,CYRIX
-PMVNZB mmxreg,mem PENT,MMX,CYRIX
-PMVZB mmxreg,mem PENT,MMX,CYRIX
-POP reg16 8086
-POP reg32 386,NOLONG
-POP reg64 X64
-POP rm16 8086
-POP rm32 386,NOLONG
-POP rm64 X64
-POP reg_cs 8086,UNDOC,ND
-POP reg_dess 8086,NOLONG
-POP reg_fsgs 386
-POPA 186,NOLONG
-POPAD 386,NOLONG
-POPAW 186,NOLONG
-POPF 8086
-POPFD 386,NOLONG
-POPFQ X64
-POPFW 8086
-POR mmxreg,mmxrm PENT,MMX
-PREFETCH mem PENT,3DNOW
-PREFETCHW mem PENT,3DNOW
-PSLLD mmxreg,mmxrm PENT,MMX
-PSLLD mmxreg,imm PENT,MMX
-PSLLQ mmxreg,mmxrm PENT,MMX
-PSLLQ mmxreg,imm PENT,MMX
-PSLLW mmxreg,mmxrm PENT,MMX
-PSLLW mmxreg,imm PENT,MMX
-PSRAD mmxreg,mmxrm PENT,MMX
-PSRAD mmxreg,imm PENT,MMX
-PSRAW mmxreg,mmxrm PENT,MMX
-PSRAW mmxreg,imm PENT,MMX
-PSRLD mmxreg,mmxrm PENT,MMX
-PSRLD mmxreg,imm PENT,MMX
-PSRLQ mmxreg,mmxrm PENT,MMX
-PSRLQ mmxreg,imm PENT,MMX
-PSRLW mmxreg,mmxrm PENT,MMX
-PSRLW mmxreg,imm PENT,MMX
-PSUBB mmxreg,mmxrm PENT,MMX
-PSUBD mmxreg,mmxrm PENT,MMX
-PSUBSB mmxreg,mmxrm PENT,MMX
-PSUBSIW mmxreg,mmxrm PENT,MMX,CYRIX
-PSUBSW mmxreg,mmxrm PENT,MMX
-PSUBUSB mmxreg,mmxrm PENT,MMX
-PSUBUSW mmxreg,mmxrm PENT,MMX
-PSUBW mmxreg,mmxrm PENT,MMX
-PUNPCKHBW mmxreg,mmxrm PENT,MMX
-PUNPCKHDQ mmxreg,mmxrm PENT,MMX
-PUNPCKHWD mmxreg,mmxrm PENT,MMX
-PUNPCKLBW mmxreg,mmxrm PENT,MMX
-PUNPCKLDQ mmxreg,mmxrm PENT,MMX
-PUNPCKLWD mmxreg,mmxrm PENT,MMX
-PUSH reg16 8086
-PUSH reg32 386,NOLONG
-PUSH reg64 X64
-PUSH rm16 8086
-PUSH rm32 386,NOLONG
-PUSH rm64 X64
-PUSH reg_cs 8086,NOLONG
-PUSH reg_dess 8086,NOLONG
-PUSH reg_fsgs 386
-PUSH imm8 186
-PUSH imm16 186,AR0,SZ
-PUSH imm32 386,NOLONG,AR0,SZ
-PUSH imm32 386,NOLONG,SD
-PUSH imm64 X64,AR0,SZ
-PUSHA 186,NOLONG
-PUSHAD 386,NOLONG
-PUSHAW 186,NOLONG
-PUSHF 8086
-PUSHFD 386,NOLONG
-PUSHFQ X64
-PUSHFW 8086
-PXOR mmxreg,mmxrm PENT,MMX
-RCL rm8,unity 8086
-RCL rm8,reg_cl 8086
-RCL rm8,imm 186
-RCL rm16,unity 8086
-RCL rm16,reg_cl 8086
-RCL rm16,imm 186
-RCL rm32,unity 386
-RCL rm32,reg_cl 386
-RCL rm32,imm 386
-RCL rm64,unity X64
-RCL rm64,reg_cl X64
-RCL rm64,imm X64
-RCR rm8,unity 8086
-RCR rm8,reg_cl 8086
-RCR rm8,imm 186
-RCR rm16,unity 8086
-RCR rm16,reg_cl 8086
-RCR rm16,imm 186
-RCR rm32,unity 386
-RCR rm32,reg_cl 386
-RCR rm32,imm 386
-RCR rm64,unity X64
-RCR rm64,reg_cl X64
-RCR rm64,imm X64
-RDSHR rm32 P6,CYRIXM
-RDMSR PENT,PRIV
-RDPMC P6
-RDTSC PENT
-RDTSCP X86_64
-RET 8086
-RET imm 8086,SW
-RETF 8086
-RETF imm 8086,SW
-RETN 8086
-RETN imm 8086,SW
-ROL rm8,unity 8086
-ROL rm8,reg_cl 8086
-ROL rm8,imm 186
-ROL rm16,unity 8086
-ROL rm16,reg_cl 8086
-ROL rm16,imm 186
-ROL rm32,unity 386
-ROL rm32,reg_cl 386
-ROL rm32,imm 386
-ROL rm64,unity X64
-ROL rm64,reg_cl X64
-ROL rm64,imm X64
-ROR rm8,unity 8086
-ROR rm8,reg_cl 8086
-ROR rm8,imm 186
-ROR rm16,unity 8086
-ROR rm16,reg_cl 8086
-ROR rm16,imm 186
-ROR rm32,unity 386
-ROR rm32,reg_cl 386
-ROR rm32,imm 386
-ROR rm64,unity X64
-ROR rm64,reg_cl X64
-ROR rm64,imm X64
-RDM P6,CYRIX,ND
-RSDC reg_sreg,mem80 486,CYRIXM
-RSLDT mem80 486,CYRIXM
-RSM PENTM
-RSTS mem80 486,CYRIXM
-SAHF 8086
-SAL rm8,unity 8086,ND
-SAL rm8,reg_cl 8086,ND
-SAL rm8,imm 186,ND
-SAL rm16,unity 8086,ND
-SAL rm16,reg_cl 8086,ND
-SAL rm16,imm 186,ND
-SAL rm32,unity 386,ND
-SAL rm32,reg_cl 386,ND
-SAL rm32,imm 386,ND
-SAL rm64,unity X64,ND
-SAL rm64,reg_cl X64,ND
-SAL rm64,imm X64,ND
-SALC 8086,UNDOC
-SAR rm8,unity 8086
-SAR rm8,reg_cl 8086
-SAR rm8,imm 186
-SAR rm16,unity 8086
-SAR rm16,reg_cl 8086
-SAR rm16,imm 186
-SAR rm32,unity 386
-SAR rm32,reg_cl 386
-SAR rm32,imm 386
-SAR rm64,unity X64
-SAR rm64,reg_cl X64
-SAR rm64,imm X64
-SBB mem,reg8 8086
-SBB reg8,reg8 8086
-SBB mem,reg16 8086
-SBB reg16,reg16 8086
-SBB mem,reg32 386
-SBB reg32,reg32 386
-SBB mem,reg64 X64
-SBB reg64,reg64 X64
-SBB reg8,mem 8086
-SBB reg8,reg8 8086
-SBB reg16,mem 8086
-SBB reg16,reg16 8086
-SBB reg32,mem 386
-SBB reg32,reg32 386
-SBB reg64,mem X64
-SBB reg64,reg64 X64
-SBB rm16,imm8 8086
-SBB rm32,imm8 386
-SBB rm64,imm8 X64
-SBB reg_al,imm 8086
-SBB reg_ax,sbyte16 8086
-SBB reg_ax,imm 8086
-SBB reg_eax,sbyte32 386
-SBB reg_eax,imm 386
-SBB reg_rax,sbyte64 X64
-SBB reg_rax,imm X64
-SBB rm8,imm 8086
-SBB rm16,imm 8086
-SBB rm32,imm 386
-SBB rm64,imm X64
-SBB mem,imm8 8086
-SBB mem,imm16 8086
-SBB mem,imm32 386
-SCASB 8086
-SCASD 386
-SCASQ X64
-SCASW 8086
-SFENCE X64,AMD
-SGDT mem 286
-SHL rm8,unity 8086
-SHL rm8,reg_cl 8086
-SHL rm8,imm 186
-SHL rm16,unity 8086
-SHL rm16,reg_cl 8086
-SHL rm16,imm 186
-SHL rm32,unity 386
-SHL rm32,reg_cl 386
-SHL rm32,imm 386
-SHL rm64,unity X64
-SHL rm64,reg_cl X64
-SHL rm64,imm X64
-SHLD mem,reg16,imm 3862
-SHLD reg16,reg16,imm 3862
-SHLD mem,reg32,imm 3862
-SHLD reg32,reg32,imm 3862
-SHLD mem,reg64,imm X642
-SHLD reg64,reg64,imm X642
-SHLD mem,reg16,reg_cl 386
-SHLD reg16,reg16,reg_cl 386
-SHLD mem,reg32,reg_cl 386
-SHLD reg32,reg32,reg_cl 386
-SHLD mem,reg64,reg_cl X64
-SHLD reg64,reg64,reg_cl X64
-SHR rm8,unity 8086
-SHR rm8,reg_cl 8086
-SHR rm8,imm 186
-SHR rm16,unity 8086
-SHR rm16,reg_cl 8086
-SHR rm16,imm 186
-SHR rm32,unity 386
-SHR rm32,reg_cl 386
-SHR rm32,imm 386
-SHR rm64,unity X64
-SHR rm64,reg_cl X64
-SHR rm64,imm X64
-SHRD mem,reg16,imm 3862
-SHRD reg16,reg16,imm 3862
-SHRD mem,reg32,imm 3862
-SHRD reg32,reg32,imm 3862
-SHRD mem,reg64,imm X642
-SHRD reg64,reg64,imm X642
-SHRD mem,reg16,reg_cl 386
-SHRD reg16,reg16,reg_cl 386
-SHRD mem,reg32,reg_cl 386
-SHRD reg32,reg32,reg_cl 386
-SHRD mem,reg64,reg_cl X64
-SHRD reg64,reg64,reg_cl X64
-SIDT mem 286
-SLDT mem 286
-SLDT mem16 286
-SLDT reg16 286
-SLDT reg32 386
-SLDT reg64 X64,ND
-SLDT reg64 X64
-SKINIT X64
-SMI 386,UNDOC
-SMINT P6,CYRIX,ND
-SMINTOLD 486,CYRIX,ND
-SMSW mem 286
-SMSW mem16 286
-SMSW reg16 286
-SMSW reg32 386
-STC 8086
-STD 8086
-STGI X64
-STI 8086
-STOSB 8086
-STOSD 386
-STOSQ X64
-STOSW 8086
-STR mem 286,PROT
-STR mem16 286,PROT
-STR reg16 286,PROT
-STR reg32 386,PROT
-STR reg64 X64
-SUB mem,reg8 8086
-SUB reg8,reg8 8086
-SUB mem,reg16 8086
-SUB reg16,reg16 8086
-SUB mem,reg32 386
-SUB reg32,reg32 386
-SUB mem,reg64 X64
-SUB reg64,reg64 X64
-SUB reg8,mem 8086
-SUB reg8,reg8 8086
-SUB reg16,mem 8086
-SUB reg16,reg16 8086
-SUB reg32,mem 386
-SUB reg32,reg32 386
-SUB reg64,mem X64
-SUB reg64,reg64 X64
-SUB rm16,imm8 8086
-SUB rm32,imm8 386
-SUB rm64,imm8 X64
-SUB reg_al,imm 8086
-SUB reg_ax,sbyte16 8086
-SUB reg_ax,imm 8086
-SUB reg_eax,sbyte32 386
-SUB reg_eax,imm 386
-SUB reg_rax,sbyte64 X64
-SUB reg_rax,imm X64
-SUB rm8,imm 8086
-SUB rm16,imm 8086
-SUB rm32,imm 386
-SUB rm64,imm X64
-SUB mem,imm8 8086
-SUB mem,imm16 8086
-SUB mem,imm32 386
-SVDC mem80,reg_sreg 486,CYRIXM
-SVLDT mem80 486,CYRIXM,ND
-SVTS mem80 486,CYRIXM
-SWAPGS X64
-SYSCALL P6,AMD
-SYSENTER P6
-SYSEXIT P6,PRIV
-SYSRET P6,PRIV,AMD
-TEST mem,reg8 8086
-TEST reg8,reg8 8086
-TEST mem,reg16 8086
-TEST reg16,reg16 8086
-TEST mem,reg32 386
-TEST reg32,reg32 386
-TEST mem,reg64 X64
-TEST reg64,reg64 X64
-TEST reg8,mem 8086
-TEST reg16,mem 8086
-TEST reg32,mem 386
-TEST reg64,mem X64
-TEST reg_al,imm 8086
-TEST reg_ax,imm 8086
-TEST reg_eax,imm 386
-TEST reg_rax,imm X64
-TEST rm8,imm 8086
-TEST rm16,imm 8086
-TEST rm32,imm 386
-TEST rm64,imm X64
-TEST mem,imm8 8086
-TEST mem,imm16 8086
-TEST mem,imm32 386
-UD0 186,UNDOC
-UD1 186,UNDOC
-UD2B 186,UNDOC,ND
-UD2 186
-UD2A 186,ND
-UMOV mem,reg8 386,UNDOC,ND
-UMOV reg8,reg8 386,UNDOC,ND
-UMOV mem,reg16 386,UNDOC,ND
-UMOV reg16,reg16 386,UNDOC,ND
-UMOV mem,reg32 386,UNDOC,ND
-UMOV reg32,reg32 386,UNDOC,ND
-UMOV reg8,mem 386,UNDOC,ND
-UMOV reg8,reg8 386,UNDOC,ND
-UMOV reg16,mem 386,UNDOC,ND
-UMOV reg16,reg16 386,UNDOC,ND
-UMOV reg32,mem 386,UNDOC,ND
-UMOV reg32,reg32 386,UNDOC,ND
-VERR mem 286,PROT
-VERR mem16 286,PROT
-VERR reg16 286,PROT
-VERW mem 286,PROT
-VERW mem16 286,PROT
-VERW reg16 286,PROT
-FWAIT 8086
-WBINVD 486,PRIV
-WRSHR rm32 P6,CYRIXM
-WRMSR PENT,PRIV
-XADD mem,reg8 486
-XADD reg8,reg8 486
-XADD mem,reg16 486
-XADD reg16,reg16 486
-XADD mem,reg32 486
-XADD reg32,reg32 486
-XADD mem,reg64 X64
-XADD reg64,reg64 X64
-XBTS reg16,mem 386,SW,UNDOC,ND
-XBTS reg16,reg16 386,UNDOC,ND
-XBTS reg32,mem 386,SD,UNDOC,ND
-XBTS reg32,reg32 386,UNDOC,ND
-XCHG reg_ax,reg16 8086
-XCHG reg_eax,reg32na 386
-XCHG reg_rax,reg64 X64
-XCHG reg16,reg_ax 8086
-XCHG reg32na,reg_eax 386
-XCHG reg64,reg_rax X64
-XCHG reg_eax,reg_eax 386,NOLONG
-XCHG reg8,mem 8086
-XCHG reg8,reg8 8086
-XCHG reg16,mem 8086
-XCHG reg16,reg16 8086
-XCHG reg32,mem 386
-XCHG reg32,reg32 386
-XCHG reg64,mem X64
-XCHG reg64,reg64 X64
-XCHG mem,reg8 8086
-XCHG reg8,reg8 8086
-XCHG mem,reg16 8086
-XCHG reg16,reg16 8086
-XCHG mem,reg32 386
-XCHG reg32,reg32 386
-XCHG mem,reg64 X64
-XCHG reg64,reg64 X64
-XLATB 8086
-XLAT 8086
-XOR mem,reg8 8086
-XOR reg8,reg8 8086
-XOR mem,reg16 8086
-XOR reg16,reg16 8086
-XOR mem,reg32 386
-XOR reg32,reg32 386
-XOR mem,reg64 X64
-XOR reg64,reg64 X64
-XOR reg8,mem 8086
-XOR reg8,reg8 8086
-XOR reg16,mem 8086
-XOR reg16,reg16 8086
-XOR reg32,mem 386
-XOR reg32,reg32 386
-XOR reg64,mem X64
-XOR reg64,reg64 X64
-XOR rm16,imm8 8086
-XOR rm32,imm8 386
-XOR rm64,imm8 X64
-XOR reg_al,imm 8086
-XOR reg_ax,sbyte16 8086
-XOR reg_ax,imm 8086
-XOR reg_eax,sbyte32 386
-XOR reg_eax,imm 386
-XOR reg_rax,sbyte64 X64
-XOR reg_rax,imm X64
-XOR rm8,imm 8086
-XOR rm16,imm 8086
-XOR rm32,imm 386
-XOR rm64,imm X64
-XOR mem,imm8 8086
-XOR mem,imm16 8086
-XOR mem,imm32 386
-CMOVcc reg16,mem P6
-CMOVcc reg16,reg16 P6
-CMOVcc reg32,mem P6
-CMOVcc reg32,reg32 P6
-CMOVcc reg64,mem X64
-CMOVcc reg64,reg64 X64
-Jcc imm|near 386
-Jcc imm16|near 386
-Jcc imm32|near 386
-Jcc imm|short 8086,ND
-Jcc imm 8086,ND
-Jcc imm 386,ND
-Jcc imm 8086,ND
-Jcc imm 8086
-SETcc mem 386
-SETcc reg8 386
-</pre>
-<h4><a name="section-B.1.3">B.1.3 Katmai Streaming SIMD instructions (SSE -- a.k.a. KNI, XMM, MMX2)</a></h4>
-<p><pre>
-ADDPS xmmreg,xmmrm KATMAI,SSE
-ADDSS xmmreg,xmmrm KATMAI,SSE,SD
-ANDNPS xmmreg,xmmrm KATMAI,SSE
-ANDPS xmmreg,xmmrm KATMAI,SSE
-CMPEQPS xmmreg,xmmrm KATMAI,SSE
-CMPEQSS xmmreg,xmmrm KATMAI,SSE
-CMPLEPS xmmreg,xmmrm KATMAI,SSE
-CMPLESS xmmreg,xmmrm KATMAI,SSE
-CMPLTPS xmmreg,xmmrm KATMAI,SSE
-CMPLTSS xmmreg,xmmrm KATMAI,SSE
-CMPNEQPS xmmreg,xmmrm KATMAI,SSE
-CMPNEQSS xmmreg,xmmrm KATMAI,SSE
-CMPNLEPS xmmreg,xmmrm KATMAI,SSE
-CMPNLESS xmmreg,xmmrm KATMAI,SSE
-CMPNLTPS xmmreg,xmmrm KATMAI,SSE
-CMPNLTSS xmmreg,xmmrm KATMAI,SSE
-CMPORDPS xmmreg,xmmrm KATMAI,SSE
-CMPORDSS xmmreg,xmmrm KATMAI,SSE
-CMPUNORDPS xmmreg,xmmrm KATMAI,SSE
-CMPUNORDSS xmmreg,xmmrm KATMAI,SSE
-CMPPS xmmreg,mem,imm KATMAI,SSE
-CMPPS xmmreg,xmmreg,imm KATMAI,SSE
-CMPSS xmmreg,mem,imm KATMAI,SSE
-CMPSS xmmreg,xmmreg,imm KATMAI,SSE
-COMISS xmmreg,xmmrm KATMAI,SSE
-CVTPI2PS xmmreg,mmxrm KATMAI,SSE,MMX
-CVTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
-CVTSI2SS xmmreg,mem KATMAI,SSE,SD,AR1,ND
-CVTSI2SS xmmreg,rm32 KATMAI,SSE,SD,AR1
-CVTSI2SS xmmreg,rm64 X64,SSE,AR1
-CVTSS2SI reg32,xmmreg KATMAI,SSE,SD,AR1
-CVTSS2SI reg32,mem KATMAI,SSE,SD,AR1
-CVTSS2SI reg64,xmmreg X64,SSE,SD,AR1
-CVTSS2SI reg64,mem X64,SSE,SD,AR1
-CVTTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
-CVTTSS2SI reg32,xmmrm KATMAI,SSE,SD,AR1
-CVTTSS2SI reg64,xmmrm X64,SSE,SD,AR1
-DIVPS xmmreg,xmmrm KATMAI,SSE
-DIVSS xmmreg,xmmrm KATMAI,SSE
-LDMXCSR mem KATMAI,SSE,SD
-MAXPS xmmreg,xmmrm KATMAI,SSE
-MAXSS xmmreg,xmmrm KATMAI,SSE
-MINPS xmmreg,xmmrm KATMAI,SSE
-MINSS xmmreg,xmmrm KATMAI,SSE
-MOVAPS xmmreg,mem KATMAI,SSE
-MOVAPS mem,xmmreg KATMAI,SSE
-MOVAPS xmmreg,xmmreg KATMAI,SSE
-MOVAPS xmmreg,xmmreg KATMAI,SSE
-MOVHPS xmmreg,mem KATMAI,SSE
-MOVHPS mem,xmmreg KATMAI,SSE
-MOVLHPS xmmreg,xmmreg KATMAI,SSE
-MOVLPS xmmreg,mem KATMAI,SSE
-MOVLPS mem,xmmreg KATMAI,SSE
-MOVHLPS xmmreg,xmmreg KATMAI,SSE
-MOVMSKPS reg32,xmmreg KATMAI,SSE
-MOVMSKPS reg64,xmmreg X64,SSE
-MOVNTPS mem,xmmreg KATMAI,SSE
-MOVSS xmmreg,mem KATMAI,SSE
-MOVSS mem,xmmreg KATMAI,SSE
-MOVSS xmmreg,xmmreg KATMAI,SSE
-MOVSS xmmreg,xmmreg KATMAI,SSE
-MOVUPS xmmreg,mem KATMAI,SSE
-MOVUPS mem,xmmreg KATMAI,SSE
-MOVUPS xmmreg,xmmreg KATMAI,SSE
-MOVUPS xmmreg,xmmreg KATMAI,SSE
-MULPS xmmreg,xmmrm KATMAI,SSE
-MULSS xmmreg,xmmrm KATMAI,SSE
-ORPS xmmreg,xmmrm KATMAI,SSE
-RCPPS xmmreg,xmmrm KATMAI,SSE
-RCPSS xmmreg,xmmrm KATMAI,SSE
-RSQRTPS xmmreg,xmmrm KATMAI,SSE
-RSQRTSS xmmreg,xmmrm KATMAI,SSE
-SHUFPS xmmreg,mem,imm KATMAI,SSE
-SHUFPS xmmreg,xmmreg,imm KATMAI,SSE
-SQRTPS xmmreg,xmmrm KATMAI,SSE
-SQRTSS xmmreg,xmmrm KATMAI,SSE
-STMXCSR mem KATMAI,SSE,SD
-SUBPS xmmreg,xmmrm KATMAI,SSE
-SUBSS xmmreg,xmmrm KATMAI,SSE
-UCOMISS xmmreg,xmmrm KATMAI,SSE
-UNPCKHPS xmmreg,xmmrm KATMAI,SSE
-UNPCKLPS xmmreg,xmmrm KATMAI,SSE
-XORPS xmmreg,xmmrm KATMAI,SSE
-</pre>
-<h4><a name="section-B.1.4">B.1.4 Introduced in Deschutes but necessary for SSE support</a></h4>
-<p><pre>
-FXRSTOR mem P6,SSE,FPU
-FXSAVE mem P6,SSE,FPU
-</pre>
-<h4><a name="section-B.1.5">B.1.5 XSAVE group (AVX and extended state)</a></h4>
-<p><pre>
-XGETBV NEHALEM
-XSETBV NEHALEM,PRIV
-XSAVE mem NEHALEM
-XRSTOR mem NEHALEM
-</pre>
-<h4><a name="section-B.1.6">B.1.6 Generic memory operations</a></h4>
-<p><pre>
-PREFETCHNTA mem KATMAI
-PREFETCHT0 mem KATMAI
-PREFETCHT1 mem KATMAI
-PREFETCHT2 mem KATMAI
-SFENCE KATMAI
-</pre>
-<h4><a name="section-B.1.7">B.1.7 New MMX instructions introduced in Katmai</a></h4>
-<p><pre>
-MASKMOVQ mmxreg,mmxreg KATMAI,MMX
-MOVNTQ mem,mmxreg KATMAI,MMX
-PAVGB mmxreg,mmxrm KATMAI,MMX
-PAVGW mmxreg,mmxrm KATMAI,MMX
-PEXTRW reg32,mmxreg,imm KATMAI,MMX
-PINSRW mmxreg,mem,imm KATMAI,MMX
-PINSRW mmxreg,rm16,imm KATMAI,MMX
-PINSRW mmxreg,reg32,imm KATMAI,MMX
-PMAXSW mmxreg,mmxrm KATMAI,MMX
-PMAXUB mmxreg,mmxrm KATMAI,MMX
-PMINSW mmxreg,mmxrm KATMAI,MMX
-PMINUB mmxreg,mmxrm KATMAI,MMX
-PMOVMSKB reg32,mmxreg KATMAI,MMX
-PMULHUW mmxreg,mmxrm KATMAI,MMX
-PSADBW mmxreg,mmxrm KATMAI,MMX
-PSHUFW mmxreg,mmxrm,imm KATMAI,MMX2
-</pre>
-<h4><a name="section-B.1.8">B.1.8 AMD Enhanced 3DNow! (Athlon) instructions</a></h4>
-<p><pre>
-PF2IW mmxreg,mmxrm PENT,3DNOW
-PFNACC mmxreg,mmxrm PENT,3DNOW
-PFPNACC mmxreg,mmxrm PENT,3DNOW
-PI2FW mmxreg,mmxrm PENT,3DNOW
-PSWAPD mmxreg,mmxrm PENT,3DNOW
-</pre>
-<h4><a name="section-B.1.9">B.1.9 Willamette SSE2 Cacheability Instructions</a></h4>
-<p><pre>
-MASKMOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
-CLFLUSH mem WILLAMETTE,SSE2
-MOVNTDQ mem,xmmreg WILLAMETTE,SSE2,SO
-MOVNTI mem,reg32 WILLAMETTE,SD
-MOVNTI mem,reg64 X64
-MOVNTPD mem,xmmreg WILLAMETTE,SSE2,SO
-LFENCE WILLAMETTE,SSE2
-MFENCE WILLAMETTE,SSE2
-</pre>
-<h4><a name="section-B.1.10">B.1.10 Willamette MMX instructions (SSE2 SIMD Integer Instructions)</a></h4>
-<p><pre>
-MOVD mem,xmmreg WILLAMETTE,SSE2,SD
-MOVD xmmreg,mem WILLAMETTE,SSE2,SD
-MOVD xmmreg,rm32 WILLAMETTE,SSE2
-MOVD rm32,xmmreg WILLAMETTE,SSE2
-MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
-MOVDQA mem,xmmreg WILLAMETTE,SSE2,SO
-MOVDQA xmmreg,mem WILLAMETTE,SSE2,SO
-MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
-MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
-MOVDQU mem,xmmreg WILLAMETTE,SSE2,SO
-MOVDQU xmmreg,mem WILLAMETTE,SSE2,SO
-MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
-MOVDQ2Q mmxreg,xmmreg WILLAMETTE,SSE2
-MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
-MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
-MOVQ mem,xmmreg WILLAMETTE,SSE2
-MOVQ xmmreg,mem WILLAMETTE,SSE2
-MOVQ xmmreg,rm64 X64,SSE2
-MOVQ rm64,xmmreg X64,SSE2
-MOVQ2DQ xmmreg,mmxreg WILLAMETTE,SSE2
-PACKSSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PACKSSDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PACKUSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDQ mmxreg,mmxrm WILLAMETTE,MMX
-PADDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PADDUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PAND xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PANDN xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PAVGB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PAVGW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PCMPEQB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PCMPEQW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PCMPEQD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PCMPGTB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PCMPGTW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PCMPGTD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PEXTRW reg32,xmmreg,imm WILLAMETTE,SSE2
-PINSRW xmmreg,reg16,imm WILLAMETTE,SSE2
-PINSRW xmmreg,reg32,imm WILLAMETTE,SSE2,ND
-PINSRW xmmreg,mem,imm WILLAMETTE,SSE2
-PINSRW xmmreg,mem16,imm WILLAMETTE,SSE2
-PMADDWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMAXSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMAXUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMINSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMINUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMOVMSKB reg32,xmmreg WILLAMETTE,SSE2
-PMULHUW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMULHW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMULLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PMULUDQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
-PMULUDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-POR xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSADBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSHUFD xmmreg,xmmreg,imm WILLAMETTE,SSE2
-PSHUFD xmmreg,mem,imm WILLAMETTE,SSE22
-PSHUFHW xmmreg,xmmreg,imm WILLAMETTE,SSE2
-PSHUFHW xmmreg,mem,imm WILLAMETTE,SSE22
-PSHUFLW xmmreg,xmmreg,imm WILLAMETTE,SSE2
-PSHUFLW xmmreg,mem,imm WILLAMETTE,SSE22
-PSLLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
-PSLLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSLLW xmmreg,imm WILLAMETTE,SSE2,AR1
-PSLLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSLLD xmmreg,imm WILLAMETTE,SSE2,AR1
-PSLLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSLLQ xmmreg,imm WILLAMETTE,SSE2,AR1
-PSRAW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSRAW xmmreg,imm WILLAMETTE,SSE2,AR1
-PSRAD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSRAD xmmreg,imm WILLAMETTE,SSE2,AR1
-PSRLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
-PSRLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSRLW xmmreg,imm WILLAMETTE,SSE2,AR1
-PSRLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSRLD xmmreg,imm WILLAMETTE,SSE2,AR1
-PSRLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSRLQ xmmreg,imm WILLAMETTE,SSE2,AR1
-PSUBB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
-PSUBQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PSUBUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKHBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKHWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKHDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKHQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKLBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKLWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKLDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PUNPCKLQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-PXOR xmmreg,xmmrm WILLAMETTE,SSE2,SO
-</pre>
-<h4><a name="section-B.1.11">B.1.11 Willamette Streaming SIMD instructions (SSE2)</a></h4>
-<p><pre>
-ADDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-ADDSD xmmreg,xmmrm WILLAMETTE,SSE2
-ANDNPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-ANDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPEQSD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPLESD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPLTSD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPNEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPNEQSD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPNLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPNLESD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPNLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPNLTSD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPORDSD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPUNORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CMPUNORDSD xmmreg,xmmrm WILLAMETTE,SSE2
-CMPPD xmmreg,xmmrm,imm WILLAMETTE,SSE22
-CMPSD xmmreg,xmmrm,imm WILLAMETTE,SSE2
-COMISD xmmreg,xmmrm WILLAMETTE,SSE2
-CVTDQ2PD xmmreg,xmmrm WILLAMETTE,SSE2
-CVTDQ2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CVTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CVTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
-CVTPD2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CVTPI2PD xmmreg,mmxrm WILLAMETTE,SSE2
-CVTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CVTPS2PD xmmreg,xmmrm WILLAMETTE,SSE2
-CVTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
-CVTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
-CVTSD2SI reg64,xmmreg X64,SSE2,AR1
-CVTSD2SI reg64,mem X64,SSE2,AR1
-CVTSD2SS xmmreg,xmmrm WILLAMETTE,SSE2
-CVTSI2SD xmmreg,mem WILLAMETTE,SSE2,SD,AR1,ND
-CVTSI2SD xmmreg,rm32 WILLAMETTE,SSE2,SD,AR1
-CVTSI2SD xmmreg,rm64 X64,SSE2,AR1
-CVTSS2SD xmmreg,xmmrm WILLAMETTE,SSE2,SD
-CVTTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
-CVTTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CVTTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-CVTTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
-CVTTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
-CVTTSD2SI reg64,xmmreg X64,SSE2,AR1
-CVTTSD2SI reg64,mem X64,SSE2,AR1
-DIVPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-DIVSD xmmreg,xmmrm WILLAMETTE,SSE2
-MAXPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-MAXSD xmmreg,xmmrm WILLAMETTE,SSE2
-MINPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-MINSD xmmreg,xmmrm WILLAMETTE,SSE2
-MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
-MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
-MOVAPD mem,xmmreg WILLAMETTE,SSE2,SO
-MOVAPD xmmreg,mem WILLAMETTE,SSE2,SO
-MOVHPD mem,xmmreg WILLAMETTE,SSE2
-MOVHPD xmmreg,mem WILLAMETTE,SSE2
-MOVLPD mem,xmmreg WILLAMETTE,SSE2
-MOVLPD xmmreg,mem WILLAMETTE,SSE2
-MOVMSKPD reg32,xmmreg WILLAMETTE,SSE2
-MOVMSKPD reg64,xmmreg X64,SSE2
-MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
-MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
-MOVSD mem,xmmreg WILLAMETTE,SSE2
-MOVSD xmmreg,mem WILLAMETTE,SSE2
-MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
-MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
-MOVUPD mem,xmmreg WILLAMETTE,SSE2,SO
-MOVUPD xmmreg,mem WILLAMETTE,SSE2,SO
-MULPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-MULSD xmmreg,xmmrm WILLAMETTE,SSE2
-ORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-SHUFPD xmmreg,xmmreg,imm WILLAMETTE,SSE2
-SHUFPD xmmreg,mem,imm WILLAMETTE,SSE2
-SQRTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-SQRTSD xmmreg,xmmrm WILLAMETTE,SSE2
-SUBPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-SUBSD xmmreg,xmmrm WILLAMETTE,SSE2
-UCOMISD xmmreg,xmmrm WILLAMETTE,SSE2
-UNPCKHPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-UNPCKLPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-XORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-</pre>
-<h4><a name="section-B.1.12">B.1.12 Prescott New Instructions (SSE3)</a></h4>
-<p><pre>
-ADDSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
-ADDSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
-HADDPD xmmreg,xmmrm PRESCOTT,SSE3,SO
-HADDPS xmmreg,xmmrm PRESCOTT,SSE3,SO
-HSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
-HSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
-LDDQU xmmreg,mem PRESCOTT,SSE3,SO
-MOVDDUP xmmreg,xmmrm PRESCOTT,SSE3
-MOVSHDUP xmmreg,xmmrm PRESCOTT,SSE3
-MOVSLDUP xmmreg,xmmrm PRESCOTT,SSE3
-</pre>
-<h4><a name="section-B.1.13">B.1.13 VMX Instructions</a></h4>
-<p><pre>
-VMCALL VMX
-VMCLEAR mem VMX
-VMLAUNCH VMX
-VMLOAD X64,VMX
-VMMCALL X64,VMX
-VMPTRLD mem VMX
-VMPTRST mem VMX
-VMREAD rm32,reg32 VMX,NOLONG,SD
-VMREAD rm64,reg64 X64,VMX
-VMRESUME VMX
-VMRUN X64,VMX
-VMSAVE X64,VMX
-VMWRITE reg32,rm32 VMX,NOLONG,SD
-VMWRITE reg64,rm64 X64,VMX
-VMXOFF VMX
-VMXON mem VMX
-</pre>
-<h4><a name="section-B.1.14">B.1.14 Extended Page Tables VMX instructions</a></h4>
-<p><pre>
-INVEPT reg32,mem VMX,SO,NOLONG
-INVEPT reg64,mem VMX,SO,LONG
-INVVPID reg32,mem VMX,SO,NOLONG
-INVVPID reg64,mem VMX,SO,LONG
-</pre>
-<h4><a name="section-B.1.15">B.1.15 Tejas New Instructions (SSSE3)</a></h4>
-<p><pre>
-PABSB mmxreg,mmxrm SSSE3,MMX
-PABSB xmmreg,xmmrm SSSE3
-PABSW mmxreg,mmxrm SSSE3,MMX
-PABSW xmmreg,xmmrm SSSE3
-PABSD mmxreg,mmxrm SSSE3,MMX
-PABSD xmmreg,xmmrm SSSE3
-PALIGNR mmxreg,mmxrm,imm SSSE3,MMX
-PALIGNR xmmreg,xmmrm,imm SSSE3
-PHADDW mmxreg,mmxrm SSSE3,MMX
-PHADDW xmmreg,xmmrm SSSE3
-PHADDD mmxreg,mmxrm SSSE3,MMX
-PHADDD xmmreg,xmmrm SSSE3
-PHADDSW mmxreg,mmxrm SSSE3,MMX
-PHADDSW xmmreg,xmmrm SSSE3
-PHSUBW mmxreg,mmxrm SSSE3,MMX
-PHSUBW xmmreg,xmmrm SSSE3
-PHSUBD mmxreg,mmxrm SSSE3,MMX
-PHSUBD xmmreg,xmmrm SSSE3
-PHSUBSW mmxreg,mmxrm SSSE3,MMX
-PHSUBSW xmmreg,xmmrm SSSE3
-PMADDUBSW mmxreg,mmxrm SSSE3,MMX
-PMADDUBSW xmmreg,xmmrm SSSE3
-PMULHRSW mmxreg,mmxrm SSSE3,MMX
-PMULHRSW xmmreg,xmmrm SSSE3
-PSHUFB mmxreg,mmxrm SSSE3,MMX
-PSHUFB xmmreg,xmmrm SSSE3
-PSIGNB mmxreg,mmxrm SSSE3,MMX
-PSIGNB xmmreg,xmmrm SSSE3
-PSIGNW mmxreg,mmxrm SSSE3,MMX
-PSIGNW xmmreg,xmmrm SSSE3
-PSIGND mmxreg,mmxrm SSSE3,MMX
-PSIGND xmmreg,xmmrm SSSE3
-</pre>
-<h4><a name="section-B.1.16">B.1.16 AMD SSE4A</a></h4>
-<p><pre>
-EXTRQ xmmreg,imm,imm SSE4A,AMD
-EXTRQ xmmreg,xmmreg SSE4A,AMD
-INSERTQ xmmreg,xmmreg,imm,imm SSE4A,AMD
-INSERTQ xmmreg,xmmreg SSE4A,AMD
-MOVNTSD mem,xmmreg SSE4A,AMD
-MOVNTSS mem,xmmreg SSE4A,AMD,SD
-</pre>
-<h4><a name="section-B.1.17">B.1.17 New instructions in Barcelona</a></h4>
-<p><pre>
-LZCNT reg16,rm16 P6,AMD
-LZCNT reg32,rm32 P6,AMD
-LZCNT reg64,rm64 X64,AMD
-</pre>
-<h4><a name="section-B.1.18">B.1.18 Penryn New Instructions (SSE4.1)</a></h4>
-<p><pre>
-BLENDPD xmmreg,xmmrm,imm SSE41
-BLENDPS xmmreg,xmmrm,imm SSE41
-BLENDVPD xmmreg,xmmrm,xmm0 SSE41
-BLENDVPS xmmreg,xmmrm,xmm0 SSE41
-DPPD xmmreg,xmmrm,imm SSE41
-DPPS xmmreg,xmmrm,imm SSE41
-EXTRACTPS rm32,xmmreg,imm SSE41
-EXTRACTPS reg64,xmmreg,imm SSE41,X64
-INSERTPS xmmreg,xmmrm,imm SSE41,SD
-MOVNTDQA xmmreg,mem SSE41
-MPSADBW xmmreg,xmmrm,imm SSE41
-PACKUSDW xmmreg,xmmrm SSE41
-PBLENDVB xmmreg,xmmrm,xmm0 SSE41
-PBLENDW xmmreg,xmmrm,imm SSE41
-PCMPEQQ xmmreg,xmmrm SSE41
-PEXTRB reg32,xmmreg,imm SSE41
-PEXTRB mem8,xmmreg,imm SSE41
-PEXTRB reg64,xmmreg,imm SSE41,X64
-PEXTRD rm32,xmmreg,imm SSE41
-PEXTRQ rm64,xmmreg,imm SSE41,X64
-PEXTRW reg32,xmmreg,imm SSE41
-PEXTRW mem16,xmmreg,imm SSE41
-PEXTRW reg64,xmmreg,imm SSE41,X64
-PHMINPOSUW xmmreg,xmmrm SSE41
-PINSRB xmmreg,mem,imm SSE41
-PINSRB xmmreg,rm8,imm SSE41
-PINSRB xmmreg,reg32,imm SSE41
-PINSRD xmmreg,mem,imm SSE41
-PINSRD xmmreg,rm32,imm SSE41
-PINSRQ xmmreg,mem,imm SSE41,X64
-PINSRQ xmmreg,rm64,imm SSE41,X64
-PMAXSB xmmreg,xmmrm SSE41
-PMAXSD xmmreg,xmmrm SSE41
-PMAXUD xmmreg,xmmrm SSE41
-PMAXUW xmmreg,xmmrm SSE41
-PMINSB xmmreg,xmmrm SSE41
-PMINSD xmmreg,xmmrm SSE41
-PMINUD xmmreg,xmmrm SSE41
-PMINUW xmmreg,xmmrm SSE41
-PMOVSXBW xmmreg,xmmrm SSE41
-PMOVSXBD xmmreg,xmmrm SSE41,SD
-PMOVSXBQ xmmreg,xmmrm SSE41,SW
-PMOVSXWD xmmreg,xmmrm SSE41
-PMOVSXWQ xmmreg,xmmrm SSE41,SD
-PMOVSXDQ xmmreg,xmmrm SSE41
-PMOVZXBW xmmreg,xmmrm SSE41
-PMOVZXBD xmmreg,xmmrm SSE41,SD
-PMOVZXBQ xmmreg,xmmrm SSE41,SW
-PMOVZXWD xmmreg,xmmrm SSE41
-PMOVZXWQ xmmreg,xmmrm SSE41,SD
-PMOVZXDQ xmmreg,xmmrm SSE41
-PMULDQ xmmreg,xmmrm SSE41
-PMULLD xmmreg,xmmrm SSE41
-PTEST xmmreg,xmmrm SSE41
-ROUNDPD xmmreg,xmmrm,imm SSE41
-ROUNDPS xmmreg,xmmrm,imm SSE41
-ROUNDSD xmmreg,xmmrm,imm SSE41
-ROUNDSS xmmreg,xmmrm,imm SSE41
-</pre>
-<h4><a name="section-B.1.19">B.1.19 Nehalem New Instructions (SSE4.2)</a></h4>
-<p><pre>
-CRC32 reg32,rm8 SSE42
-CRC32 reg32,rm16 SSE42
-CRC32 reg32,rm32 SSE42
-CRC32 reg64,rm8 SSE42,X64
-CRC32 reg64,rm64 SSE42,X64
-PCMPESTRI xmmreg,xmmrm,imm SSE42
-PCMPESTRM xmmreg,xmmrm,imm SSE42
-PCMPISTRI xmmreg,xmmrm,imm SSE42
-PCMPISTRM xmmreg,xmmrm,imm SSE42
-PCMPGTQ xmmreg,xmmrm SSE42
-POPCNT reg16,rm16 NEHALEM,SW
-POPCNT reg32,rm32 NEHALEM,SD
-POPCNT reg64,rm64 NEHALEM,X64
-</pre>
-<h4><a name="section-B.1.20">B.1.20 Intel SMX</a></h4>
-<p><pre>
-GETSEC KATMAI
-</pre>
-<h4><a name="section-B.1.21">B.1.21 Geode (Cyrix) 3DNow! additions</a></h4>
-<p><pre>
-PFRCPV mmxreg,mmxrm PENT,3DNOW,CYRIX
-PFRSQRTV mmxreg,mmxrm PENT,3DNOW,CYRIX
-</pre>
-<h4><a name="section-B.1.22">B.1.22 Intel new instructions in ???</a></h4>
-<p><pre>
-MOVBE reg16,mem16 NEHALEM
-MOVBE reg32,mem32 NEHALEM
-MOVBE reg64,mem64 NEHALEM
-MOVBE mem16,reg16 NEHALEM
-MOVBE mem32,reg32 NEHALEM
-MOVBE mem64,reg64 NEHALEM
-</pre>
-<h4><a name="section-B.1.23">B.1.23 Intel AES instructions</a></h4>
-<p><pre>
-AESENC xmmreg,xmmrm128 SSE,WESTMERE
-AESENCLAST xmmreg,xmmrm128 SSE,WESTMERE
-AESDEC xmmreg,xmmrm128 SSE,WESTMERE
-AESDECLAST xmmreg,xmmrm128 SSE,WESTMERE
-AESIMC xmmreg,xmmrm128 SSE,WESTMERE
-AESKEYGENASSIST xmmreg,xmmrm128,imm8 SSE,WESTMERE
-</pre>
-<h4><a name="section-B.1.24">B.1.24 Intel AVX AES instructions</a></h4>
-<p><pre>
-VAESENC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VAESENCLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VAESDEC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VAESDECLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VAESIMC xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VAESKEYGENASSIST xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-</pre>
-<h4><a name="section-B.1.25">B.1.25 Intel AVX instructions</a></h4>
-<p><pre>
-VADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VADDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VADDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VADDSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VADDSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VADDSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VADDSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VANDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VANDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VANDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VANDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VANDNPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VANDNPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VANDNPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VANDNPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VBLENDPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VBLENDPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VBLENDPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VBLENDPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VBLENDVPD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VBLENDVPD xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
-VBLENDVPD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
-VBLENDVPS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VBLENDVPS xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
-VBLENDVPS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
-VBROADCASTSS xmmreg,mem32 AVX,SANDYBRIDGE
-VBROADCASTSS ymmreg,mem32 AVX,SANDYBRIDGE
-VBROADCASTSD ymmreg,mem64 AVX,SANDYBRIDGE
-VBROADCASTF128 ymmreg,mem128 AVX,SANDYBRIDGE
-VCMPEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPUNORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPUNORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPEQ_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQ_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPFALSEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPFALSEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQ_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQ_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPTRUEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPTRUEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPUNORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPUNORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPFALSE_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPFALSE_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPTRUE_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPTRUE_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VCMPPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VCMPEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPUNORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPUNORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPEQ_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQ_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPFALSEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPFALSEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQ_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQ_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPTRUEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPTRUEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPLE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPLE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPUNORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPUNORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNLE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNLE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNGT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNGT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPFALSE_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPFALSE_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPNEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPNEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPGT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPGT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPTRUE_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VCMPTRUE_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VCMPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VCMPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VCMPEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPUNORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPEQ_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPFALSESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNEQ_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPTRUESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPLT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPLE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPUNORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNLT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNLE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNGE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNGT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPFALSE_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPNEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPGE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPGT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPTRUE_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCMPSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
-VCMPEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPUNORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPEQ_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPFALSESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNEQ_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPTRUESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPLT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPLE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPUNORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNLT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNLE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNGE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNGT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPFALSE_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPNEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPGE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPGT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPTRUE_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCMPSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
-VCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
-VCVTDQ2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VCVTDQ2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
-VCVTDQ2PS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VCVTDQ2PS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VCVTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
-VCVTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
-VCVTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
-VCVTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
-VCVTPD2PS xmmreg,xmmreg AVX,SANDYBRIDGE
-VCVTPD2PS xmmreg,mem128 AVX,SANDYBRIDGE,SO
-VCVTPD2PS xmmreg,ymmreg AVX,SANDYBRIDGE
-VCVTPD2PS xmmreg,mem256 AVX,SANDYBRIDGE,SY
-VCVTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VCVTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VCVTPS2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VCVTPS2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
-VCVTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
-VCVTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
-VCVTSD2SS xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VCVTSI2SD xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
-VCVTSI2SD xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
-VCVTSI2SD xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
-VCVTSI2SS xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
-VCVTSI2SS xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
-VCVTSI2SS xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
-VCVTSS2SD xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VCVTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
-VCVTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
-VCVTTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
-VCVTTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
-VCVTTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
-VCVTTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
-VCVTTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VCVTTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VCVTTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
-VCVTTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
-VCVTTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
-VCVTTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
-VDIVPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VDIVPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VDIVPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VDIVPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VDIVSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VDIVSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VDPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VDPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VDPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VEXTRACTF128 xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
-VEXTRACTPS rm32,xmmreg,imm8 AVX,SANDYBRIDGE
-VHADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VHADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VHADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VHADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VHSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VHSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VHSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VHSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VINSERTF128 ymmreg,ymmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VINSERTPS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
-VLDDQU xmmreg,mem128 AVX,SANDYBRIDGE
-VLDQQU ymmreg,mem256 AVX,SANDYBRIDGE
-VLDDQU ymmreg,mem256 AVX,SANDYBRIDGE
-VLDMXCSR mem32 AVX,SANDYBRIDGE
-VMASKMOVDQU xmmreg,xmmreg AVX,SANDYBRIDGE
-VMASKMOVPS xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
-VMASKMOVPS ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
-VMASKMOVPS mem128,xmmreg,xmmreg AVX,SANDYBRIDGE,SO
-VMASKMOVPS mem256,xmmreg,xmmreg AVX,SANDYBRIDGE,SY
-VMASKMOVPD xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
-VMASKMOVPD ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
-VMASKMOVPD mem128,xmmreg,xmmreg AVX,SANDYBRIDGE
-VMASKMOVPD mem256,ymmreg,ymmreg AVX,SANDYBRIDGE
-VMAXPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VMAXPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VMAXPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VMAXPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VMAXSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VMAXSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VMINPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VMINPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VMINPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VMINPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VMINSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VMINSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VMOVAPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVAPD xmmrm128,xmmreg AVX,SANDYBRIDGE
-VMOVAPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVAPD ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVAPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVAPS xmmrm128,xmmreg AVX,SANDYBRIDGE
-VMOVAPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVAPS ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VMOVQ xmmrm64,xmmreg AVX,SANDYBRIDGE
-VMOVQ xmmreg,rm64 AVX,SANDYBRIDGE,LONG
-VMOVQ rm64,xmmreg AVX,SANDYBRIDGE,LONG
-VMOVD xmmreg,rm32 AVX,SANDYBRIDGE
-VMOVD rm32,xmmreg AVX,SANDYBRIDGE
-VMOVDDUP xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VMOVDDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVDQA xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVDQA xmmrm128,xmmreg AVX,SANDYBRIDGE
-VMOVQQA ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVQQA ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVDQA ymmreg,ymmrm AVX,SANDYBRIDGE
-VMOVDQA ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVDQU xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVDQU xmmrm128,xmmreg AVX,SANDYBRIDGE
-VMOVQQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVQQU ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVDQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVDQU ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVHLPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-VMOVHPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-VMOVHPD mem64,xmmreg AVX,SANDYBRIDGE
-VMOVHPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-VMOVHPS mem64,xmmreg AVX,SANDYBRIDGE
-VMOVLHPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-VMOVLPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-VMOVLPD mem64,xmmreg AVX,SANDYBRIDGE
-VMOVLPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-VMOVLPS mem64,xmmreg AVX,SANDYBRIDGE
-VMOVMSKPD reg64,xmmreg AVX,SANDYBRIDGE,LONG
-VMOVMSKPD reg32,xmmreg AVX,SANDYBRIDGE
-VMOVMSKPD reg64,ymmreg AVX,SANDYBRIDGE,LONG
-VMOVMSKPD reg32,ymmreg AVX,SANDYBRIDGE
-VMOVMSKPS reg64,xmmreg AVX,SANDYBRIDGE,LONG
-VMOVMSKPS reg32,xmmreg AVX,SANDYBRIDGE
-VMOVMSKPS reg64,ymmreg AVX,SANDYBRIDGE,LONG
-VMOVMSKPS reg32,ymmreg AVX,SANDYBRIDGE
-VMOVNTDQ mem128,xmmreg AVX,SANDYBRIDGE
-VMOVNTQQ mem256,ymmreg AVX,SANDYBRIDGE
-VMOVNTDQ mem256,ymmreg AVX,SANDYBRIDGE
-VMOVNTDQA xmmreg,mem128 AVX,SANDYBRIDGE
-VMOVNTPD mem128,xmmreg AVX,SANDYBRIDGE
-VMOVNTPD mem256,ymmreg AVX,SANDYBRIDGE
-VMOVNTPS mem128,xmmreg AVX,SANDYBRIDGE
-VMOVNTPS mem128,ymmreg AVX,SANDYBRIDGE
-VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-VMOVSD xmmreg,mem64 AVX,SANDYBRIDGE
-VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-VMOVSD mem64,xmmreg AVX,SANDYBRIDGE
-VMOVSHDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVSHDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVSLDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVSLDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-VMOVSS xmmreg,mem64 AVX,SANDYBRIDGE
-VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-VMOVSS mem64,xmmreg AVX,SANDYBRIDGE
-VMOVUPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVUPD xmmrm128,xmmreg AVX,SANDYBRIDGE
-VMOVUPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVUPD ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMOVUPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VMOVUPS xmmrm128,xmmreg AVX,SANDYBRIDGE
-VMOVUPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VMOVUPS ymmrm256,ymmreg AVX,SANDYBRIDGE
-VMPSADBW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VMULPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VMULPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VMULPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VMULPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VMULSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VMULSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VPABSB xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPABSW xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPABSD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPACKSSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPACKSSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPACKUSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPACKUSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPADDUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPALIGNR xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPAND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPANDN xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPAVGB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPAVGW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPBLENDVB xmmreg,xmmreg*,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPBLENDW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPCMPESTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPCMPESTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPCMPISTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPCMPISTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPCMPEQB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPEQW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPEQD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPEQQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPGTB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPGTW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPGTD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCMPGTQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPERMILPD xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILPD ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMILPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPERMILPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VPERMILTD2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPERMILTD2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILTD2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VPERMILTD2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMILMO2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPERMILMO2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILMO2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VPERMILMO2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMILMZ2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPERMILMZ2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILMZ2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VPERMILMZ2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMIL2PD xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
-VPERMIL2PD xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPERMIL2PD ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
-VPERMIL2PD ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VPERMILPS xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILPS ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMILPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPERMILPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VPERMILTD2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPERMILTD2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILTD2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VPERMILTD2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMILMO2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPERMILMO2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILMO2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VPERMILMO2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMILMZ2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-VPERMILMZ2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPERMILMZ2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-VPERMILMZ2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPERMIL2PS xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
-VPERMIL2PS xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPERMIL2PS ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
-VPERMIL2PS ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VPERM2F128 ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VPEXTRB reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-VPEXTRB reg32,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRB mem8,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRD reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-VPEXTRD rm32,xmmreg,imm8 AVX,SANDYBRIDGE
-VPEXTRQ rm64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-VPHADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPHADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPHADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPHMINPOSUW xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPHSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPHSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPHSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPINSRB xmmreg,xmmreg*,mem8,imm8 AVX,SANDYBRIDGE
-VPINSRB xmmreg,xmmreg*,rm8,imm8 AVX,SANDYBRIDGE
-VPINSRB xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
-VPINSRW xmmreg,xmmreg*,mem16,imm8 AVX,SANDYBRIDGE
-VPINSRW xmmreg,xmmreg*,rm16,imm8 AVX,SANDYBRIDGE
-VPINSRW xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
-VPINSRD xmmreg,xmmreg*,mem32,imm8 AVX,SANDYBRIDGE
-VPINSRD xmmreg,xmmreg*,rm32,imm8 AVX,SANDYBRIDGE
-VPINSRQ xmmreg,xmmreg*,mem64,imm8 AVX,SANDYBRIDGE,LONG
-VPINSRQ xmmreg,xmmreg*,rm64,imm8 AVX,SANDYBRIDGE,LONG
-VPMADDWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMADDUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMAXSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMAXSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMAXSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMAXUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMAXUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMAXUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMINSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMINSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMINSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMINUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMINUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMINUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMOVMSKB reg64,xmmreg AVX,SANDYBRIDGE,LONG
-VPMOVMSKB reg32,xmmreg AVX,SANDYBRIDGE
-VPMOVSXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VPMOVSXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
-VPMOVSXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
-VPMOVSXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VPMOVSXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
-VPMOVSXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VPMOVZXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VPMOVZXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
-VPMOVZXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
-VPMOVZXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VPMOVZXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
-VPMOVZXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VPMULHUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMULHRSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMULHW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMULLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMULLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMULUDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPMULDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSADBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSHUFB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSHUFD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPSHUFHW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPSHUFLW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VPSIGNB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSIGNW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSIGND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSLLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSRLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSLLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSLLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSLLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSLLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSLLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSLLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSRAW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSRAW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSRAD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSRAD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSRLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSRLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSRLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSRLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPSRLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSRLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-VPTEST xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VPTEST ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VPSUBB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPSUBUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKHBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKHWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKHDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKLBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKLWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKLDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPUNPCKLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPXOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VRCPPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VRCPPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VRCPSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VRSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VRSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VRSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VROUNDPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VROUNDPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VROUNDPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-VROUNDPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-VROUNDSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
-VROUNDSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
-VSHUFPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VSHUFPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VSHUFPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-VSHUFPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-VSQRTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VSQRTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VSQRTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VSTMXCSR mem32 AVX,SANDYBRIDGE
-VSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VSUBSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-VSUBSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-VTESTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VTESTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VTESTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-VTESTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-VUCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-VUCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
-VUNPCKHPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VUNPCKHPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VUNPCKHPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VUNPCKHPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VUNPCKLPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VUNPCKLPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VUNPCKLPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VUNPCKLPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VXORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VXORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VXORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VXORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-VZEROALL AVX,SANDYBRIDGE
-VZEROUPPER AVX,SANDYBRIDGE
-</pre>
-<h4><a name="section-B.1.26">B.1.26 Intel Carry-Less Multiplication instructions (CLMUL)</a></h4>
-<p><pre>
-PCLMULLQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
-PCLMULHQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
-PCLMULLQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
-PCLMULHQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
-PCLMULQDQ xmmreg,xmmrm128,imm8 SSE,WESTMERE
-</pre>
-<h4><a name="section-B.1.27">B.1.27 Intel AVX Carry-Less Multiplication instructions (CLMUL)</a></h4>
-<p><pre>
-VPCLMULLQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCLMULHQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCLMULLQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCLMULHQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-VPCLMULQDQ xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-</pre>
-<h4><a name="section-B.1.28">B.1.28 Intel Fused Multiply-Add instructions (FMA)</a></h4>
-<p><pre>
-VFMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADDSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMADDSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMSUBADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFMSUBADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFNMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-VFNMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-VFMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-VFNMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-VFNMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-</pre>
-<h4><a name="section-B.1.29">B.1.29 VIA (Centaur) security instructions</a></h4>
-<p><pre>
-XSTORE PENT,CYRIX
-XCRYPTECB PENT,CYRIX
-XCRYPTCBC PENT,CYRIX
-XCRYPTCTR PENT,CYRIX
-XCRYPTCFB PENT,CYRIX
-XCRYPTOFB PENT,CYRIX
-MONTMUL PENT,CYRIX
-XSHA1 PENT,CYRIX
-XSHA256 PENT,CYRIX
-</pre>
-<h4><a name="section-B.1.30">B.1.30 AMD Lightweight Profiling (LWP) instructions</a></h4>
-<p><pre>
-LLWPCB reg16 AMD
-LLWPCB reg32 AMD,386
-LLWPCB reg64 AMD,X64
-SLWPCB reg16 AMD
-SLWPCB reg32 AMD,386
-SLWPCB reg64 AMD,X64
-LWPVAL reg16,rm32,imm16 AMD,386
-LWPVAL reg32,rm32,imm32 AMD,386
-LWPVAL reg64,rm32,imm32 AMD,X64
-LWPINS reg16,rm32,imm16 AMD,386
-LWPINS reg32,rm32,imm32 AMD,386
-LWPINS reg64,rm32,imm32 AMD,X64
-</pre>
-<h4><a name="section-B.1.31">B.1.31 AMD XOP, FMA4 and CVT16 instructions (SSE5)</a></h4>
-<p><pre>
-VCVTPH2PS xmmreg,xmmrm64*,imm8 AMD,SSE5
-VCVTPH2PS ymmreg,xmmrm128,imm8 AMD,SSE5
-VCVTPH2PS ymmreg,ymmrm128*,imm8 AMD,SSE5
-VCVTPS2PH xmmrm64,xmmreg*,imm8 AMD,SSE5
-VCVTPS2PH xmmrm128,ymmreg,imm8 AMD,SSE5
-VCVTPS2PH ymmrm128,ymmreg*,imm8 AMD,SSE5
-VFMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-VFMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-VFMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-VFMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-VFMADDSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMADDSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMADDSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMADDSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMADDSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMADDSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMADDSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMADDSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMSUBADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMSUBADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMSUBADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMSUBADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMSUBADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMSUBADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMSUBADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMSUBADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-VFMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-VFMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-VFMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-VFNMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFNMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFNMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFNMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFNMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFNMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFNMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFNMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFNMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-VFNMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-VFNMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-VFNMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-VFNMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFNMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFNMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFNMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFNMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VFNMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VFNMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VFNMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VFNMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-VFNMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-VFNMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-VFNMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-VFRCZPD xmmreg,xmmrm128* AMD,SSE5
-VFRCZPD ymmreg,ymmrm256* AMD,SSE5
-VFRCZPS xmmreg,xmmrm128* AMD,SSE5
-VFRCZPS ymmreg,ymmrm256* AMD,SSE5
-VFRCZSD xmmreg,xmmrm64* AMD,SSE5
-VFRCZSS xmmreg,xmmrm32* AMD,SSE5
-VPCMOV xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPCMOV ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-VPCMOV xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VPCMOV ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-VPCOMB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMUB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMUD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMUQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMUW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPCOMW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-VPHADDBD xmmreg,xmmrm128* AMD,SSE5
-VPHADDBQ xmmreg,xmmrm128* AMD,SSE5
-VPHADDBW xmmreg,xmmrm128* AMD,SSE5
-VPHADDDQ xmmreg,xmmrm128* AMD,SSE5
-VPHADDUBD xmmreg,xmmrm128* AMD,SSE5
-VPHADDUBQ xmmreg,xmmrm128* AMD,SSE5
-VPHADDUBW xmmreg,xmmrm128* AMD,SSE5
-VPHADDUDQ xmmreg,xmmrm128* AMD,SSE5
-VPHADDUWD xmmreg,xmmrm128* AMD,SSE5
-VPHADDUWQ xmmreg,xmmrm128* AMD,SSE5
-VPHADDWD xmmreg,xmmrm128* AMD,SSE5
-VPHADDWQ xmmreg,xmmrm128* AMD,SSE5
-VPHSUBBW xmmreg,xmmrm128* AMD,SSE5
-VPHSUBDQ xmmreg,xmmrm128* AMD,SSE5
-VPHSUBWD xmmreg,xmmrm128* AMD,SSE5
-VPMACSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMACSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMADCSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPMADCSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPPERM xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-VPPERM xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-VPROTB xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPROTB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPROTB xmmreg,xmmrm128*,imm8 AMD,SSE5
-VPROTD xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPROTD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPROTD xmmreg,xmmrm128*,imm8 AMD,SSE5
-VPROTQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPROTQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPROTQ xmmreg,xmmrm128*,imm8 AMD,SSE5
-VPROTW xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPROTW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPROTW xmmreg,xmmrm128*,imm8 AMD,SSE5
-VPSHAB xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHAB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHAD xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHAD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHAQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHAQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHAW xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHAW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHLB xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHLB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHLD xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHLD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHLQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHLQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-VPSHLW xmmreg,xmmrm128*,xmmreg AMD,SSE5
-VPSHLW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-</pre>
-<h4><a name="section-B.1.32">B.1.32 Systematic names for the hinting nop instructions</a></h4>
-<p><pre>
-HINT_NOP0 rm16 P6,UNDOC
-HINT_NOP0 rm32 P6,UNDOC
-HINT_NOP0 rm64 X64,UNDOC
-HINT_NOP1 rm16 P6,UNDOC
-HINT_NOP1 rm32 P6,UNDOC
-HINT_NOP1 rm64 X64,UNDOC
-HINT_NOP2 rm16 P6,UNDOC
-HINT_NOP2 rm32 P6,UNDOC
-HINT_NOP2 rm64 X64,UNDOC
-HINT_NOP3 rm16 P6,UNDOC
-HINT_NOP3 rm32 P6,UNDOC
-HINT_NOP3 rm64 X64,UNDOC
-HINT_NOP4 rm16 P6,UNDOC
-HINT_NOP4 rm32 P6,UNDOC
-HINT_NOP4 rm64 X64,UNDOC
-HINT_NOP5 rm16 P6,UNDOC
-HINT_NOP5 rm32 P6,UNDOC
-HINT_NOP5 rm64 X64,UNDOC
-HINT_NOP6 rm16 P6,UNDOC
-HINT_NOP6 rm32 P6,UNDOC
-HINT_NOP6 rm64 X64,UNDOC
-HINT_NOP7 rm16 P6,UNDOC
-HINT_NOP7 rm32 P6,UNDOC
-HINT_NOP7 rm64 X64,UNDOC
-HINT_NOP8 rm16 P6,UNDOC
-HINT_NOP8 rm32 P6,UNDOC
-HINT_NOP8 rm64 X64,UNDOC
-HINT_NOP9 rm16 P6,UNDOC
-HINT_NOP9 rm32 P6,UNDOC
-HINT_NOP9 rm64 X64,UNDOC
-HINT_NOP10 rm16 P6,UNDOC
-HINT_NOP10 rm32 P6,UNDOC
-HINT_NOP10 rm64 X64,UNDOC
-HINT_NOP11 rm16 P6,UNDOC
-HINT_NOP11 rm32 P6,UNDOC
-HINT_NOP11 rm64 X64,UNDOC
-HINT_NOP12 rm16 P6,UNDOC
-HINT_NOP12 rm32 P6,UNDOC
-HINT_NOP12 rm64 X64,UNDOC
-HINT_NOP13 rm16 P6,UNDOC
-HINT_NOP13 rm32 P6,UNDOC
-HINT_NOP13 rm64 X64,UNDOC
-HINT_NOP14 rm16 P6,UNDOC
-HINT_NOP14 rm32 P6,UNDOC
-HINT_NOP14 rm64 X64,UNDOC
-HINT_NOP15 rm16 P6,UNDOC
-HINT_NOP15 rm32 P6,UNDOC
-HINT_NOP15 rm64 X64,UNDOC
-HINT_NOP16 rm16 P6,UNDOC
-HINT_NOP16 rm32 P6,UNDOC
-HINT_NOP16 rm64 X64,UNDOC
-HINT_NOP17 rm16 P6,UNDOC
-HINT_NOP17 rm32 P6,UNDOC
-HINT_NOP17 rm64 X64,UNDOC
-HINT_NOP18 rm16 P6,UNDOC
-HINT_NOP18 rm32 P6,UNDOC
-HINT_NOP18 rm64 X64,UNDOC
-HINT_NOP19 rm16 P6,UNDOC
-HINT_NOP19 rm32 P6,UNDOC
-HINT_NOP19 rm64 X64,UNDOC
-HINT_NOP20 rm16 P6,UNDOC
-HINT_NOP20 rm32 P6,UNDOC
-HINT_NOP20 rm64 X64,UNDOC
-HINT_NOP21 rm16 P6,UNDOC
-HINT_NOP21 rm32 P6,UNDOC
-HINT_NOP21 rm64 X64,UNDOC
-HINT_NOP22 rm16 P6,UNDOC
-HINT_NOP22 rm32 P6,UNDOC
-HINT_NOP22 rm64 X64,UNDOC
-HINT_NOP23 rm16 P6,UNDOC
-HINT_NOP23 rm32 P6,UNDOC
-HINT_NOP23 rm64 X64,UNDOC
-HINT_NOP24 rm16 P6,UNDOC
-HINT_NOP24 rm32 P6,UNDOC
-HINT_NOP24 rm64 X64,UNDOC
-HINT_NOP25 rm16 P6,UNDOC
-HINT_NOP25 rm32 P6,UNDOC
-HINT_NOP25 rm64 X64,UNDOC
-HINT_NOP26 rm16 P6,UNDOC
-HINT_NOP26 rm32 P6,UNDOC
-HINT_NOP26 rm64 X64,UNDOC
-HINT_NOP27 rm16 P6,UNDOC
-HINT_NOP27 rm32 P6,UNDOC
-HINT_NOP27 rm64 X64,UNDOC
-HINT_NOP28 rm16 P6,UNDOC
-HINT_NOP28 rm32 P6,UNDOC
-HINT_NOP28 rm64 X64,UNDOC
-HINT_NOP29 rm16 P6,UNDOC
-HINT_NOP29 rm32 P6,UNDOC
-HINT_NOP29 rm64 X64,UNDOC
-HINT_NOP30 rm16 P6,UNDOC
-HINT_NOP30 rm32 P6,UNDOC
-HINT_NOP30 rm64 X64,UNDOC
-HINT_NOP31 rm16 P6,UNDOC
-HINT_NOP31 rm32 P6,UNDOC
-HINT_NOP31 rm64 X64,UNDOC
-HINT_NOP32 rm16 P6,UNDOC
-HINT_NOP32 rm32 P6,UNDOC
-HINT_NOP32 rm64 X64,UNDOC
-HINT_NOP33 rm16 P6,UNDOC
-HINT_NOP33 rm32 P6,UNDOC
-HINT_NOP33 rm64 X64,UNDOC
-HINT_NOP34 rm16 P6,UNDOC
-HINT_NOP34 rm32 P6,UNDOC
-HINT_NOP34 rm64 X64,UNDOC
-HINT_NOP35 rm16 P6,UNDOC
-HINT_NOP35 rm32 P6,UNDOC
-HINT_NOP35 rm64 X64,UNDOC
-HINT_NOP36 rm16 P6,UNDOC
-HINT_NOP36 rm32 P6,UNDOC
-HINT_NOP36 rm64 X64,UNDOC
-HINT_NOP37 rm16 P6,UNDOC
-HINT_NOP37 rm32 P6,UNDOC
-HINT_NOP37 rm64 X64,UNDOC
-HINT_NOP38 rm16 P6,UNDOC
-HINT_NOP38 rm32 P6,UNDOC
-HINT_NOP38 rm64 X64,UNDOC
-HINT_NOP39 rm16 P6,UNDOC
-HINT_NOP39 rm32 P6,UNDOC
-HINT_NOP39 rm64 X64,UNDOC
-HINT_NOP40 rm16 P6,UNDOC
-HINT_NOP40 rm32 P6,UNDOC
-HINT_NOP40 rm64 X64,UNDOC
-HINT_NOP41 rm16 P6,UNDOC
-HINT_NOP41 rm32 P6,UNDOC
-HINT_NOP41 rm64 X64,UNDOC
-HINT_NOP42 rm16 P6,UNDOC
-HINT_NOP42 rm32 P6,UNDOC
-HINT_NOP42 rm64 X64,UNDOC
-HINT_NOP43 rm16 P6,UNDOC
-HINT_NOP43 rm32 P6,UNDOC
-HINT_NOP43 rm64 X64,UNDOC
-HINT_NOP44 rm16 P6,UNDOC
-HINT_NOP44 rm32 P6,UNDOC
-HINT_NOP44 rm64 X64,UNDOC
-HINT_NOP45 rm16 P6,UNDOC
-HINT_NOP45 rm32 P6,UNDOC
-HINT_NOP45 rm64 X64,UNDOC
-HINT_NOP46 rm16 P6,UNDOC
-HINT_NOP46 rm32 P6,UNDOC
-HINT_NOP46 rm64 X64,UNDOC
-HINT_NOP47 rm16 P6,UNDOC
-HINT_NOP47 rm32 P6,UNDOC
-HINT_NOP47 rm64 X64,UNDOC
-HINT_NOP48 rm16 P6,UNDOC
-HINT_NOP48 rm32 P6,UNDOC
-HINT_NOP48 rm64 X64,UNDOC
-HINT_NOP49 rm16 P6,UNDOC
-HINT_NOP49 rm32 P6,UNDOC
-HINT_NOP49 rm64 X64,UNDOC
-HINT_NOP50 rm16 P6,UNDOC
-HINT_NOP50 rm32 P6,UNDOC
-HINT_NOP50 rm64 X64,UNDOC
-HINT_NOP51 rm16 P6,UNDOC
-HINT_NOP51 rm32 P6,UNDOC
-HINT_NOP51 rm64 X64,UNDOC
-HINT_NOP52 rm16 P6,UNDOC
-HINT_NOP52 rm32 P6,UNDOC
-HINT_NOP52 rm64 X64,UNDOC
-HINT_NOP53 rm16 P6,UNDOC
-HINT_NOP53 rm32 P6,UNDOC
-HINT_NOP53 rm64 X64,UNDOC
-HINT_NOP54 rm16 P6,UNDOC
-HINT_NOP54 rm32 P6,UNDOC
-HINT_NOP54 rm64 X64,UNDOC
-HINT_NOP55 rm16 P6,UNDOC
-HINT_NOP55 rm32 P6,UNDOC
-HINT_NOP55 rm64 X64,UNDOC
-HINT_NOP56 rm16 P6,UNDOC
-HINT_NOP56 rm32 P6,UNDOC
-HINT_NOP56 rm64 X64,UNDOC
-HINT_NOP57 rm16 P6,UNDOC
-HINT_NOP57 rm32 P6,UNDOC
-HINT_NOP57 rm64 X64,UNDOC
-HINT_NOP58 rm16 P6,UNDOC
-HINT_NOP58 rm32 P6,UNDOC
-HINT_NOP58 rm64 X64,UNDOC
-HINT_NOP59 rm16 P6,UNDOC
-HINT_NOP59 rm32 P6,UNDOC
-HINT_NOP59 rm64 X64,UNDOC
-HINT_NOP60 rm16 P6,UNDOC
-HINT_NOP60 rm32 P6,UNDOC
-HINT_NOP60 rm64 X64,UNDOC
-HINT_NOP61 rm16 P6,UNDOC
-HINT_NOP61 rm32 P6,UNDOC
-HINT_NOP61 rm64 X64,UNDOC
-HINT_NOP62 rm16 P6,UNDOC
-HINT_NOP62 rm32 P6,UNDOC
-HINT_NOP62 rm64 X64,UNDOC
-HINT_NOP63 rm16 P6,UNDOC
-HINT_NOP63 rm32 P6,UNDOC
-HINT_NOP63 rm64 X64,UNDOC
-</pre>
-<p align=center><a href="nasmdocc.html">Next Chapter</a> |
-<a href="nasmdoca.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdocc.html b/doc/html/nasmdocc.html
deleted file mode 100644
index b7ec3b2..0000000
--- a/doc/html/nasmdocc.html
+++ /dev/null
@@ -1,1468 +0,0 @@
-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdocb.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-<h2><a name="appendix-C">Appendix C: NASM Version History</a></h2>
-<h3><a name="section-C.1">C.1 NASM 2 Series</a></h3>
-<p>The NASM 2 series support x86-64, and is the production version of NASM
-since 2007.
-<h4><a name="section-C.1.1">C.1.1 Version 2.08</a></h4>
-<ul>
-<li>A number of enhancements/fixes in macros area.
-<li>Support for arbitrarily terminating macro expansions
-<code><nobr>%exitmacro</nobr></code>. See
-<a href="nasmdoc4.html#section-4.3.12">section 4.3.12</a>.
-<li>Support for recursive macro expansion
-<code><nobr>%rmacro/irmacro</nobr></code>. See
-<a href="nasmdoc4.html#section-4.3.1">section 4.3.1</a>.
-<li>Support for converting strings to tokens. See
-<a href="nasmdoc4.html#section-4.1.9">section 4.1.9</a>.
-<li>Fuzzy operand size logic introduced.
-<li>Fix COFF stack overrun on too long export identifiers.
-<li>Fix Macho-O alignment bug.
-<li>Fix crashes with -fwin32 on file with many exports.
-<li>Fix stack overrun for too long [DEBUG id].
-<li>Fix incorrect sbyte usage in IMUL (hit only if optimization flag
-passed).
-<li>Append ending token for <code><nobr>.stabs</nobr></code> records in the
-ELF output format.
-<li>New NSIS script which uses ModernUI and MultiUser approach.
-<li>Visual Studio 2008 NASM integration (rules file).
-<li>Warn a user if a constant is too long (and as result will be stripped).
-<li>The obsoleted pre-XOP AMD SSE5 instruction set which was never
-actualized was removed.
-<li>Fix stack overrun on too long error file name passed from the command
-line.
-<li>Bind symbols to the .text section by default (ie in case if SECTION
-directive was omitted) in the ELF output format.
-<li>Fix sync points array index wrapping.
-<li>A few fixes for FMA4 and XOP instruction templates.
-<li>Add AMD Lightweight Profiling (LWP) instructions.
-</ul>
-<h4><a name="section-C.1.2">C.1.2 Version 2.07</a></h4>
-<ul>
-<li>NASM is now under the 2-clause BSD license. See
-<a href="nasmdoc1.html#section-1.1.2">section 1.1.2</a>.
-<li>Fix the section type for the <code><nobr>.strtab</nobr></code> section
-in the <code><nobr>elf64</nobr></code> output format.
-<li>Fix the handling of <code><nobr>COMMON</nobr></code> directives in the
-<code><nobr>obj</nobr></code> output format.
-<li>New <code><nobr>ith</nobr></code> and <code><nobr>srec</nobr></code>
-output formats; these are variants of the <code><nobr>bin</nobr></code>
-output format which output Intel hex and Motorola S-records, respectively.
-See <a href="nasmdoc7.html#section-7.2">section 7.2</a> and
-<a href="nasmdoc7.html#section-7.3">section 7.3</a>.
-<li><code><nobr>rdf2ihx</nobr></code> replaced with an enhanced
-<code><nobr>rdf2bin</nobr></code>, which can output binary, COM, Intel hex
-or Motorola S-records.
-<li>The Windows installer now puts the NASM directory first in the
-<code><nobr>PATH</nobr></code> of the "NASM Shell".
-<li>Revert the early expansion behavior of <code><nobr>%+</nobr></code> to
-pre-2.06 behavior: <code><nobr>%+</nobr></code> is only expanded late.
-<li>Yet another Mach-O alignment fix.
-<li>Don't delete the list file on errors. Also, include error and warning
-information in the list file.
-<li>Support for 64-bit Mach-O output, see
-<a href="nasmdoc7.html#section-7.8">section 7.8</a>.
-<li>Fix assert failure on certain operations that involve strings with
-high-bit bytes.
-</ul>
-<h4><a name="section-C.1.3">C.1.3 Version 2.06</a></h4>
-<ul>
-<li>This release is dedicated to the memory of Charles A. Crayne, long time
-NASM developer as well as moderator of
-<code><nobr>comp.lang.asm.x86</nobr></code> and author of the book
-<em>Serious Assembler</em>. We miss you, Chuck.
-<li>Support for indirect macro expansion
-(<code><nobr>%[...]</nobr></code>). See
-<a href="nasmdoc4.html#section-4.1.3">section 4.1.3</a>.
-<li><code><nobr>%pop</nobr></code> can now take an argument, see
-<a href="nasmdoc4.html#section-4.7.1">section 4.7.1</a>.
-<li>The argument to <code><nobr>%use</nobr></code> is no longer
-macro-expanded. Use <code><nobr>%[...]</nobr></code> if macro expansion is
-desired.
-<li>Support for thread-local storage in ELF32 and ELF64. See
-<a href="nasmdoc7.html#section-7.9.4">section 7.9.4</a>.
-<li>Fix crash on <code><nobr>%ifmacro</nobr></code> without an argument.
-<li>Correct the arguments to the <code><nobr>POPCNT</nobr></code>
-instruction.
-<li>Fix section alignment in the Mach-O format.
-<li>Update AVX support to version 5 of the Intel specification.
-<li>Fix the handling of accesses to context-local macros from higher levels
-in the context stack.
-<li>Treat <code><nobr>WAIT</nobr></code> as a prefix rather than as an
-instruction, thereby allowing constructs like
-<code><nobr>O16 FSAVE</nobr></code> to work correctly.
-<li>Support for structures with a non-zero base offset. See
-<a href="nasmdoc4.html#section-4.11.10">section 4.11.10</a>.
-<li>Correctly handle preprocessor token concatenation (see
-<a href="nasmdoc4.html#section-4.3.8">section 4.3.8</a>) involving
-floating-point numbers.
-<li>The <code><nobr>PINSR</nobr></code> series of instructions have been
-corrected and rationalized.
-<li>Removed AMD SSE5, replaced with the new XOP/FMA4/CVT16 (rev 3.03) spec.
-<li>The ELF backends no longer automatically generate a
-<code><nobr>.comment</nobr></code> section.
-<li>Add additional "well-known" ELF sections with default attributes. See
-<a href="nasmdoc7.html#section-7.9.2">section 7.9.2</a>.
-</ul>
-<h4><a name="section-C.1.4">C.1.4 Version 2.05.01</a></h4>
-<ul>
-<li>Fix the <code><nobr>-w</nobr></code>/<code><nobr>-W</nobr></code>
-option parsing, which was broken in NASM 2.05.
-</ul>
-<h4><a name="section-C.1.5">C.1.5 Version 2.05</a></h4>
-<ul>
-<li>Fix redundant REX.W prefix on <code><nobr>JMP reg64</nobr></code>.
-<li>Make the behaviour of <code><nobr>-O0</nobr></code> match NASM 0.98
-legacy behavior. See <a href="nasmdoc2.html#section-2.1.22">section
-2.1.22</a>.
-<li><code><nobr>-w-user</nobr></code> can be used to suppress the output of
-<code><nobr>%warning</nobr></code> directives. See
-<a href="nasmdoc2.html#section-2.1.24">section 2.1.24</a>.
-<li>Fix bug where <code><nobr>ALIGN</nobr></code> would issue a full
-alignment datum instead of zero bytes.
-<li>Fix offsets in list files.
-<li>Fix <code><nobr>%include</nobr></code> inside multi-line macros or
-loops.
-<li>Fix error where NASM would generate a spurious warning on valid
-optimizations of immediate values.
-<li>Fix arguments to a number of the <code><nobr>CVT</nobr></code> SSE
-instructions.
-<li>Fix RIP-relative offsets when the instruction carries an immediate.
-<li>Massive overhaul of the ELF64 backend for spec compliance.
-<li>Fix the Geode <code><nobr>PFRCPV</nobr></code> and
-<code><nobr>PFRSQRTV</nobr></code> instruction.
-<li>Fix the SSE 4.2 <code><nobr>CRC32</nobr></code> instruction.
-</ul>
-<h4><a name="section-C.1.6">C.1.6 Version 2.04</a></h4>
-<ul>
-<li>Sanitize macro handing in the <code><nobr>%error</nobr></code>
-directive.
-<li>New <code><nobr>%warning</nobr></code> directive to issue
-user-controlled warnings.
-<li><code><nobr>%error</nobr></code> directives are now deferred to the
-final assembly phase.
-<li>New <code><nobr>%fatal</nobr></code> directive to immediately terminate
-assembly.
-<li>New <code><nobr>%strcat</nobr></code> directive to join quoted strings
-together.
-<li>New <code><nobr>%use</nobr></code> macro directive to support standard
-macro directives. See <a href="nasmdoc4.html#section-4.6.4">section
-4.6.4</a>.
-<li>Excess default parameters to <code><nobr>%macro</nobr></code> now
-issues a warning by default. See
-<a href="nasmdoc4.html#section-4.3">section 4.3</a>.
-<li>Fix <code><nobr>%ifn</nobr></code> and
-<code><nobr>%elifn</nobr></code>.
-<li>Fix nested <code><nobr>%else</nobr></code> clauses.
-<li>Correct the handling of nested <code><nobr>%rep</nobr></code>s.
-<li>New <code><nobr>%unmacro</nobr></code> directive to undeclare a
-multi-line macro. See <a href="nasmdoc4.html#section-4.3.11">section
-4.3.11</a>.
-<li>Builtin macro <code><nobr>__PASS__</nobr></code> which expands to the
-current assembly pass. See <a href="nasmdoc4.html#section-4.11.9">section
-4.11.9</a>.
-<li><code><nobr>__utf16__</nobr></code> and
-<code><nobr>__utf32__</nobr></code> operators to generate UTF-16 and UTF-32
-strings. See <a href="nasmdoc3.html#section-3.4.5">section 3.4.5</a>.
-<li>Fix bug in case-insensitive matching when compiled on platforms that
-don't use the <code><nobr>configure</nobr></code> script. Of the official
-release binaries, that only affected the OS/2 binary.
-<li>Support for x87 packed BCD constants. See
-<a href="nasmdoc3.html#section-3.4.7">section 3.4.7</a>.
-<li>Correct the <code><nobr>LTR</nobr></code> and
-<code><nobr>SLDT</nobr></code> instructions in 64-bit mode.
-<li>Fix unnecessary REX.W prefix on indirect jumps in 64-bit mode.
-<li>Add AVX versions of the AES instructions
-(<code><nobr>VAES</nobr></code>...).
-<li>Fix the 256-bit FMA instructions.
-<li>Add 256-bit AVX stores per the latest AVX spec.
-<li>VIA XCRYPT instructions can now be written either with or without
-<code><nobr>REP</nobr></code>, apparently different versions of the VIA
-spec wrote them differently.
-<li>Add missing 64-bit <code><nobr>MOVNTI</nobr></code> instruction.
-<li>Fix the operand size of <code><nobr>VMREAD</nobr></code> and
-<code><nobr>VMWRITE</nobr></code>.
-<li>Numerous bug fixes, especially to the AES, AVX and VTX instructions.
-<li>The optimizer now always runs until it converges. It also runs even
-when disabled, but doesn't optimize. This allows most forward references to
-be resolved properly.
-<li><code><nobr>%push</nobr></code> no longer needs a context identifier;
-omitting the context identifier results in an anonymous context.
-</ul>
-<h4><a name="section-C.1.7">C.1.7 Version 2.03.01</a></h4>
-<ul>
-<li>Fix buffer overflow in the listing module.
-<li>Fix the handling of hexadecimal escape codes in `...` strings.
-<li>The Postscript/PDF documentation has been reformatted.
-<li>The <code><nobr>-F</nobr></code> option now implies
-<code><nobr>-g</nobr></code>.
-</ul>
-<h4><a name="section-C.1.8">C.1.8 Version 2.03</a></h4>
-<ul>
-<li>Add support for Intel AVX, CLMUL and FMA instructions, including YMM
-registers.
-<li><code><nobr>dy</nobr></code>, <code><nobr>resy</nobr></code> and
-<code><nobr>yword</nobr></code> for 32-byte operands.
-<li>Fix some SSE5 instructions.
-<li>Intel <code><nobr>INVEPT</nobr></code>,
-<code><nobr>INVVPID</nobr></code> and <code><nobr>MOVBE</nobr></code>
-instructions.
-<li>Fix checking for critical expressions when the optimizer is enabled.
-<li>Support the DWARF debugging format for ELF targets.
-<li>Fix optimizations of signed bytes.
-<li>Fix operation on bigendian machines.
-<li>Fix buffer overflow in the preprocessor.
-<li><code><nobr>SAFESEH</nobr></code> support for Win32,
-<code><nobr>IMAGEREL</nobr></code> for Win64 (SEH).
-<li><code><nobr>%?</nobr></code> and <code><nobr>%??</nobr></code> to refer
-to the name of a macro itself. In particular,
-<code><nobr>%idefine keyword $%?</nobr></code> can be used to make a
-keyword "disappear".
-<li>New options for dependency generation: <code><nobr>-MD</nobr></code>,
-<code><nobr>-MF</nobr></code>, <code><nobr>-MP</nobr></code>,
-<code><nobr>-MT</nobr></code>, <code><nobr>-MQ</nobr></code>.
-<li>New preprocessor directives <code><nobr>%pathsearch</nobr></code> and
-<code><nobr>%depend</nobr></code>; INCBIN reimplemented as a macro.
-<li><code><nobr>%include</nobr></code> now resolves macros in a sane
-manner.
-<li><code><nobr>%substr</nobr></code> can now be used to get other than
-one-character substrings.
-<li>New type of character/string constants, using backquotes
-(<code><nobr>`...`</nobr></code>), which support C-style escape sequences.
-<li><code><nobr>%defstr</nobr></code> and
-<code><nobr>%idefstr</nobr></code> to stringize macro definitions before
-creation.
-<li>Fix forward references used in <code><nobr>EQU</nobr></code>
-statements.
-</ul>
-<h4><a name="section-C.1.9">C.1.9 Version 2.02</a></h4>
-<ul>
-<li>Additional fixes for MMX operands with explicit
-<code><nobr>qword</nobr></code>, as well as (hopefully) SSE operands with
-<code><nobr>oword</nobr></code>.
-<li>Fix handling of truncated strings with <code><nobr>DO</nobr></code>.
-<li>Fix segfaults due to memory overwrites when floating-point constants
-were used.
-<li>Fix segfaults due to missing include files.
-<li>Fix OpenWatcom Makefiles for DOS and OS/2.
-<li>Add autogenerated instruction list back into the documentation.
-<li>ELF: Fix segfault when generating stabs, and no symbols have been
-defined.
-<li>ELF: Experimental support for DWARF debugging information.
-<li>New compile date and time standard macros.
-<li><code><nobr>%ifnum</nobr></code> now returns true for negative numbers.
-<li>New <code><nobr>%iftoken</nobr></code> test for a single token.
-<li>New <code><nobr>%ifempty</nobr></code> test for empty expansion.
-<li>Add support for the <code><nobr>XSAVE</nobr></code> instruction group.
-<li>Makefile for Netware/gcc.
-<li>Fix issue with some warnings getting emitted way too many times.
-<li>Autogenerated instruction list added to the documentation.
-</ul>
-<h4><a name="section-C.1.10">C.1.10 Version 2.01</a></h4>
-<ul>
-<li>Fix the handling of MMX registers with explicit
-<code><nobr>qword</nobr></code> tags on memory (broken in 2.00 due to
-64-bit changes.)
-<li>Fix the PREFETCH instructions.
-<li>Fix the documentation.
-<li>Fix debugging info when using <code><nobr>-f elf</nobr></code>
-(backwards compatibility alias for <code><nobr>-f elf32</nobr></code>).
-<li>Man pages for rdoff tools (from the Debian project.)
-<li>ELF: handle large numbers of sections.
-<li>Fix corrupt output when the optimizer runs out of passes.
-</ul>
-<h4><a name="section-C.1.11">C.1.11 Version 2.00</a></h4>
-<ul>
-<li>Added c99 data-type compliance.
-<li>Added general x86-64 support.
-<li>Added win64 (x86-64 COFF) output format.
-<li>Added <code><nobr>__BITS__</nobr></code> standard macro.
-<li>Renamed the <code><nobr>elf</nobr></code> output format to
-<code><nobr>elf32</nobr></code> for clarity.
-<li>Added <code><nobr>elf64</nobr></code> and
-<code><nobr>macho</nobr></code> (MacOS X) output formats.
-<li>Added Numeric constants in <code><nobr>dq</nobr></code> directive.
-<li>Added <code><nobr>oword</nobr></code>, <code><nobr>do</nobr></code> and
-<code><nobr>reso</nobr></code> pseudo operands.
-<li>Allow underscores in numbers.
-<li>Added 8-, 16- and 128-bit floating-point formats.
-<li>Added binary, octal and hexadecimal floating-point.
-<li>Correct the generation of floating-point constants.
-<li>Added floating-point option control.
-<li>Added Infinity and NaN floating point support.
-<li>Added ELF Symbol Visibility support.
-<li>Added setting OSABI value in ELF header directive.
-<li>Added Generate Makefile Dependencies option.
-<li>Added Unlimited Optimization Passes option.
-<li>Added <code><nobr>%IFN</nobr></code> and
-<code><nobr>%ELIFN</nobr></code> support.
-<li>Added Logical Negation Operator.
-<li>Enhanced Stack Relative Preprocessor Directives.
-<li>Enhanced ELF Debug Formats.
-<li>Enhanced Send Errors to a File option.
-<li>Added SSSE3, SSE4.1, SSE4.2, SSE5 support.
-<li>Added a large number of additional instructions.
-<li>Significant performance improvements.
-<li><code><nobr>-w+warning</nobr></code> and
-<code><nobr>-w-warning</nobr></code> can now be written as -Wwarning and
--Wno-warning, respectively. See
-<a href="nasmdoc2.html#section-2.1.24">section 2.1.24</a>.
-<li>Add <code><nobr>-w+error</nobr></code> to treat warnings as errors. See
-<a href="nasmdoc2.html#section-2.1.24">section 2.1.24</a>.
-<li>Add <code><nobr>-w+all</nobr></code> and
-<code><nobr>-w-all</nobr></code> to enable or disable all suppressible
-warnings. See <a href="nasmdoc2.html#section-2.1.24">section 2.1.24</a>.
-</ul>
-<h3><a name="section-C.2">C.2 NASM 0.98 Series</a></h3>
-<p>The 0.98 series was the production versions of NASM from 1999 to 2007.
-<h4><a name="section-C.2.1">C.2.1 Version 0.98.39</a></h4>
-<ul>
-<li>fix buffer overflow
-<li>fix outas86's <code><nobr>.bss</nobr></code> handling
-<li>"make spotless" no longer deletes config.h.in.
-<li><code><nobr>%(el)if(n)idn</nobr></code> insensitivity to string quotes
-difference (#809300).
-<li>(nasm.c)<code><nobr>__OUTPUT_FORMAT__</nobr></code> changed to string
-value instead of symbol.
-</ul>
-<h4><a name="section-C.2.2">C.2.2 Version 0.98.38</a></h4>
-<ul>
-<li>Add Makefile for 16-bit DOS binaries under OpenWatcom, and modify
-<code><nobr>mkdep.pl</nobr></code> to be able to generate completely
-pathless dependencies, as required by OpenWatcom wmake (it supports path
-searches, but not explicit paths.)
-<li>Fix the <code><nobr>STR</nobr></code> instruction.
-<li>Fix the ELF output format, which was broken under certain circumstances
-due to the addition of stabs support.
-<li>Quick-fix Borland format debug-info for
-<code><nobr>-f obj</nobr></code>
-<li>Fix for <code><nobr>%rep</nobr></code> with no arguments (#560568)
-<li>Fix concatenation of preprocessor function call (#794686)
-<li>Fix long label causes coredump (#677841)
-<li>Use autoheader as well as autoconf to keep configure from generating
-ridiculously long command lines.
-<li>Make sure that all of the formats which support debugging output
-actually will suppress debugging output when <code><nobr>-g</nobr></code>
-not specified.
-</ul>
-<h4><a name="section-C.2.3">C.2.3 Version 0.98.37</a></h4>
-<ul>
-<li>Paths given in <code><nobr>-I</nobr></code> switch searched for
-<code><nobr>incbin</nobr></code>-ed as well as
-<code><nobr>%include</nobr></code>-ed files.
-<li>Added stabs debugging for the ELF output format, patch from Martin
-Wawro.
-<li>Fix <code><nobr>output/outbin.c</nobr></code> to allow origin &gt;
-80000000h.
-<li>Make <code><nobr>-U</nobr></code> switch work.
-<li>Fix the use of relative offsets with explicit prefixes, e.g.
-<code><nobr>a32 loop foo</nobr></code>.
-<li>Remove <code><nobr>backslash()</nobr></code>.
-<li>Fix the <code><nobr>SMSW</nobr></code> and
-<code><nobr>SLDT</nobr></code> instructions.
-<li><code><nobr>-O2</nobr></code> and <code><nobr>-O3</nobr></code> are no
-longer aliases for <code><nobr>-O10</nobr></code> and
-<code><nobr>-O15</nobr></code>. If you mean the latter, please say so! :)
-</ul>
-<h4><a name="section-C.2.4">C.2.4 Version 0.98.36</a></h4>
-<ul>
-<li>Update rdoff - librarian/archiver - common rec - docs!
-<li>Fix signed/unsigned problems.
-<li>Fix <code><nobr>JMP FAR label</nobr></code> and
-<code><nobr>CALL FAR label</nobr></code>.
-<li>Add new multisection support - map files - fix align bug
-<li>Fix sysexit, movhps/movlps reg,reg bugs in insns.dat
-<li><code><nobr>Q</nobr></code> or <code><nobr>O</nobr></code> suffixes
-indicate octal
-<li>Support Prescott new instructions (PNI).
-<li>Cyrix <code><nobr>XSTORE</nobr></code> instruction.
-</ul>
-<h4><a name="section-C.2.5">C.2.5 Version 0.98.35</a></h4>
-<ul>
-<li>Fix build failure on 16-bit DOS (Makefile.bc3 workaround for compiler
-bug.)
-<li>Fix dependencies and compiler warnings.
-<li>Add "const" in a number of places.
-<li>Add -X option to specify error reporting format (use -Xvc to integrate
-with Microsoft Visual Studio.)
-<li>Minor changes for code legibility.
-<li>Drop use of tmpnam() in rdoff (security fix.)
-</ul>
-<h4><a name="section-C.2.6">C.2.6 Version 0.98.34</a></h4>
-<ul>
-<li>Correct additional address-size vs. operand-size confusions.
-<li>Generate dependencies for all Makefiles automatically.
-<li>Add support for unimplemented (but theoretically available) registers
-such as tr0 and cr5. Segment registers 6 and 7 are called segr6 and segr7
-for the operations which they can be represented.
-<li>Correct some disassembler bugs related to redundant address-size
-prefixes. Some work still remains in this area.
-<li>Correctly generate an error for things like "SEG eax".
-<li>Add the JMPE instruction, enabled by "CPU IA64".
-<li>Correct compilation on newer gcc/glibc platforms.
-<li>Issue an error on things like "jmp far eax".
-</ul>
-<h4><a name="section-C.2.7">C.2.7 Version 0.98.33</a></h4>
-<ul>
-<li>New __NASM_PATCHLEVEL__ and __NASM_VERSION_ID__ standard macros to
-round out the version-query macros. version.pl now understands X.YYplWW or
-X.YY.ZZplWW as a version number, equivalent to X.YY.ZZ.WW (or X.YY.0.WW, as
-appropriate).
-<li>New keyword "strict" to disable the optimization of specific operands.
-<li>Fix the handing of size overrides with JMP instructions (instructions
-such as "jmp dword foo".)
-<li>Fix the handling of "ABSOLUTE label", where "label" points into a
-relocatable segment.
-<li>Fix OBJ output format with lots of externs.
-<li>More documentation updates.
-<li>Add -Ov option to get verbose information about optimizations.
-<li>Undo a braindead change which broke <code><nobr>%elif</nobr></code>
-directives.
-<li>Makefile updates.
-</ul>
-<h4><a name="section-C.2.8">C.2.8 Version 0.98.32</a></h4>
-<ul>
-<li>Fix NASM crashing when <code><nobr>%macro</nobr></code> directives were
-left unterminated.
-<li>Lots of documentation updates.
-<li>Complete rewrite of the PostScript/PDF documentation generator.
-<li>The MS Visual C++ Makefile was updated and corrected.
-<li>Recognize .rodata as a standard section name in ELF.
-<li>Fix some obsolete Perl4-isms in Perl scripts.
-<li>Fix configure.in to work with autoconf 2.5x.
-<li>Fix a couple of "make cleaner" misses.
-<li>Make the normal "./configure &amp;&amp; make" work with Cygwin.
-</ul>
-<h4><a name="section-C.2.9">C.2.9 Version 0.98.31</a></h4>
-<ul>
-<li>Correctly build in a separate object directory again.
-<li>Derive all references to the version number from the version file.
-<li>New standard macros __NASM_SUBMINOR__ and __NASM_VER__ macros.
-<li>Lots of Makefile updates and bug fixes.
-<li>New <code><nobr>%ifmacro</nobr></code> directive to test for multiline
-macros.
-<li>Documentation updates.
-<li>Fixes for 16-bit OBJ format output.
-<li>Changed the NASM environment variable to NASMENV.
-</ul>
-<h4><a name="section-C.2.10">C.2.10 Version 0.98.30</a></h4>
-<ul>
-<li>Changed doc files a lot: completely removed old READMExx and Wishlist
-files, incorporating all information in CHANGES and TODO.
-<li>I waited a long time to rename zoutieee.c to (original) outieee.c
-<li>moved all output modules to output/ subdirectory.
-<li>Added 'make strip' target to strip debug info from nasm &amp; ndisasm.
-<li>Added INSTALL file with installation instructions.
-<li>Added -v option description to nasm man.
-<li>Added dist makefile target to produce source distributions.
-<li>16-bit support for ELF output format (GNU extension, but useful.)
-</ul>
-<h4><a name="section-C.2.11">C.2.11 Version 0.98.28</a></h4>
-<ul>
-<li>Fastcooked this for Debian's Woody release: Frank applied the INCBIN
-bug patch to 0.98.25alt and called it 0.98.28 to not confuse poor little
-apt-get.
-</ul>
-<h4><a name="section-C.2.12">C.2.12 Version 0.98.26</a></h4>
-<ul>
-<li>Reorganised files even better from 0.98.25alt
-</ul>
-<h4><a name="section-C.2.13">C.2.13 Version 0.98.25alt</a></h4>
-<ul>
-<li>Prettified the source tree. Moved files to more reasonable places.
-<li>Added findleak.pl script to misc/ directory.
-<li>Attempted to fix doc.
-</ul>
-<h4><a name="section-C.2.14">C.2.14 Version 0.98.25</a></h4>
-<ul>
-<li>Line continuation character <code><nobr>\</nobr></code>.
-<li>Docs inadvertantly reverted - "dos packaging".
-</ul>
-<h4><a name="section-C.2.15">C.2.15 Version 0.98.24p1</a></h4>
-<ul>
-<li>FIXME: Someone, document this please.
-</ul>
-<h4><a name="section-C.2.16">C.2.16 Version 0.98.24</a></h4>
-<ul>
-<li>Documentation - Ndisasm doc added to Nasm.doc.
-</ul>
-<h4><a name="section-C.2.17">C.2.17 Version 0.98.23</a></h4>
-<ul>
-<li>Attempted to remove rdoff version1
-<li>Lino Mastrodomenico's patches to preproc.c (%$$ bug?).
-</ul>
-<h4><a name="section-C.2.18">C.2.18 Version 0.98.22</a></h4>
-<ul>
-<li>Update rdoff2 - attempt to remove v1.
-</ul>
-<h4><a name="section-C.2.19">C.2.19 Version 0.98.21</a></h4>
-<ul>
-<li>Optimization fixes.
-</ul>
-<h4><a name="section-C.2.20">C.2.20 Version 0.98.20</a></h4>
-<ul>
-<li>Optimization fixes.
-</ul>
-<h4><a name="section-C.2.21">C.2.21 Version 0.98.19</a></h4>
-<ul>
-<li>H. J. Lu's patch back out.
-</ul>
-<h4><a name="section-C.2.22">C.2.22 Version 0.98.18</a></h4>
-<ul>
-<li>Added ".rdata" to "-f win32".
-</ul>
-<h4><a name="section-C.2.23">C.2.23 Version 0.98.17</a></h4>
-<ul>
-<li>H. J. Lu's "bogus elf" patch. (Red Hat problem?)
-</ul>
-<h4><a name="section-C.2.24">C.2.24 Version 0.98.16</a></h4>
-<ul>
-<li>Fix whitespace before "[section ..." bug.
-</ul>
-<h4><a name="section-C.2.25">C.2.25 Version 0.98.15</a></h4>
-<ul>
-<li>Rdoff changes (?).
-<li>Fix fixes to memory leaks.
-</ul>
-<h4><a name="section-C.2.26">C.2.26 Version 0.98.14</a></h4>
-<ul>
-<li>Fix memory leaks.
-</ul>
-<h4><a name="section-C.2.27">C.2.27 Version 0.98.13</a></h4>
-<ul>
-<li>There was no 0.98.13
-</ul>
-<h4><a name="section-C.2.28">C.2.28 Version 0.98.12</a></h4>
-<ul>
-<li>Update optimization (new function of "-O1")
-<li>Changes to test/bintest.asm (?).
-</ul>
-<h4><a name="section-C.2.29">C.2.29 Version 0.98.11</a></h4>
-<ul>
-<li>Optimization changes.
-<li>Ndisasm fixed.
-</ul>
-<h4><a name="section-C.2.30">C.2.30 Version 0.98.10</a></h4>
-<ul>
-<li>There was no 0.98.10
-</ul>
-<h4><a name="section-C.2.31">C.2.31 Version 0.98.09</a></h4>
-<ul>
-<li>Add multiple sections support to "-f bin".
-<li>Changed GLOBAL_TEMP_BASE in outelf.c from 6 to 15.
-<li>Add "-v" as an alias to the "-r" switch.
-<li>Remove "#ifdef" from Tasm compatibility options.
-<li>Remove redundant size-overrides on "mov ds, ex", etc.
-<li>Fixes to SSE2, other insns.dat (?).
-<li>Enable uppercase "I" and "P" switches.
-<li>Case insinsitive "seg" and "wrt".
-<li>Update install.sh (?).
-<li>Allocate tokens in blocks.
-<li>Improve "invalid effective address" messages.
-</ul>
-<h4><a name="section-C.2.32">C.2.32 Version 0.98.08</a></h4>
-<ul>
-<li>Add "<code><nobr>%strlen</nobr></code>" and
-"<code><nobr>%substr</nobr></code>" macro operators
-<li>Fixed broken c16.mac.
-<li>Unterminated string error reported.
-<li>Fixed bugs as per 0.98bf
-</ul>
-<h4><a name="section-C.2.33">C.2.33 Version 0.98.09b with John Coffman patches released 28-Oct-2001</a></h4>
-<p>Changes from 0.98.07 release to 98.09b as of 28-Oct-2001
-<ul>
-<li>More closely compatible with 0.98 when -O0 is implied or specified. Not
-strictly identical, since backward branches in range of short offsets are
-recognized, and signed byte values with no explicit size specification will
-be assembled as a single byte.
-<li>More forgiving with the PUSH instruction. 0.98 requires a size to be
-specified always. 0.98.09b will imply the size from the current BITS
-setting (16 or 32).
-<li>Changed definition of the optimization flag:
-</ul>
-<p>-O0 strict two-pass assembly, JMP and Jcc are handled more like 0.98,
-except that back- ward JMPs are short, if possible.
-<p>-O1 strict two-pass assembly, but forward branches are assembled with
-code guaranteed to reach; may produce larger code than -O0, but will
-produce successful assembly more often if branch offset sizes are not
-specified.
-<p>-O2 multi-pass optimization, minimize branch offsets; also will minimize
-signed immed- iate bytes, overriding size specification.
-<p>-O3 like -O2, but more passes taken, if needed
-<h4><a name="section-C.2.34">C.2.34 Version 0.98.07 released 01/28/01</a></h4>
-<ul>
-<li>Added Stepane Denis' SSE2 instructions to a *working* version of the
-code - some earlier versions were based on broken code - sorry 'bout that.
-version "0.98.07"
-</ul>
-<p>01/28/01
-<ul>
-<li>Cosmetic modifications to nasm.c, nasm.h, AUTHORS, MODIFIED
-</ul>
-<h4><a name="section-C.2.35">C.2.35 Version 0.98.06f released 01/18/01</a></h4>
-<ul>
-<li>- Add "metalbrain"s jecxz bug fix in insns.dat - alter nasmdoc.src to
-match - version "0.98.06f"
-</ul>
-<h4><a name="section-C.2.36">C.2.36 Version 0.98.06e released 01/09/01</a></h4>
-<ul>
-<li>Removed the "outforms.h" file - it appears to be someone's old backup
-of "outform.h". version "0.98.06e"
-</ul>
-<p>01/09/01
-<ul>
-<li>fbk - finally added the fix for the "multiple %includes bug", known
-since 7/27/99 - reported originally (?) and sent to us by Austin Lunnen -
-he reports that John Fine had a fix within the day. Here it is...
-<li>Nelson Rush resigns from the group. Big thanks to Nelson for his
-leadership and enthusiasm in getting these changes incorporated into Nasm!
-<li>fbk - [list +], [list -] directives - ineptly implemented, should be
-re-written or removed, perhaps.
-<li>Brian Raiter / fbk - "elfso bug" fix - applied to aoutb format as well
-- testing might be desirable...
-</ul>
-<p>08/07/00
-<ul>
-<li>James Seter - -postfix, -prefix command line switches.
-<li>Yuri Zaporogets - rdoff utility changes.
-</ul>
-<h4><a name="section-C.2.37">C.2.37 Version 0.98p1</a></h4>
-<ul>
-<li>GAS-like palign (Panos Minos)
-<li>FIXME: Someone, fill this in with details
-</ul>
-<h4><a name="section-C.2.38">C.2.38 Version 0.98bf (bug-fixed)</a></h4>
-<ul>
-<li>Fixed - elf and aoutb bug - shared libraries - multiple "%include" bug
-in "-f obj" - jcxz, jecxz bug - unrecognized option bug in ndisasm
-</ul>
-<h4><a name="section-C.2.39">C.2.39 Version 0.98.03 with John Coffman's changes released 27-Jul-2000</a></h4>
-<ul>
-<li>Added signed byte optimizations for the 0x81/0x83 class of
-instructions: ADC, ADD, AND, CMP, OR, SBB, SUB, XOR: when used as 'ADD
-reg16,imm' or 'ADD reg32,imm.' Also optimization of signed byte form of
-'PUSH imm' and 'IMUL reg,imm'/'IMUL reg,reg,imm.' No size specification is
-needed.
-<li>Added multi-pass JMP and Jcc offset optimization. Offsets on forward
-references will preferentially use the short form, without the need to code
-a specific size (short or near) for the branch. Added instructions for 'Jcc
-label' to use the form 'Jnotcc $+3/JMP label', in cases where a short
-offset is out of bounds. If compiling for a 386 or higher CPU, then the 386
-form of Jcc will be used instead.
-</ul>
-<p>This feature is controlled by a new command-line switch: "O", (upper
-case letter O). "-O0" reverts the assembler to no extra optimization
-passes, "-O1" allows up to 5 extra passes, and "-O2"(default), allows up to
-10 extra optimization passes.
-<ul>
-<li>Added a new directive: 'cpu XXX', where XXX is any of: 8086, 186, 286,
-386, 486, 586, pentium, 686, PPro, P2, P3 or Katmai. All are case
-insensitive. All instructions will be selected only if they apply to the
-selected cpu or lower. Corrected a couple of bugs in cpu-dependence in
-'insns.dat'.
-<li>Added to 'standard.mac', the "use16" and "use32" forms of the "bits
-16/32" directive. This is nothing new, just conforms to a lot of other
-assemblers. (minor)
-<li>Changed label allocation from 320/32 (10000 labels @ 200K+) to 32/37
-(1000 labels); makes running under DOS much easier. Since additional label
-space is allocated dynamically, this should have no effect on large
-programs with lots of labels. The 37 is a prime, believed to be better for
-hashing. (minor)
-</ul>
-<h4><a name="section-C.2.40">C.2.40 Version 0.98.03</a></h4>
-<p>"Integrated patchfile 0.98-0.98.01. I call this version 0.98.03 for
-historical reasons: 0.98.02 was trashed." --John Coffman
-&lt;johninsd@san.rr.com&gt;, 27-Jul-2000
-<ul>
-<li>Kendall Bennett's SciTech MGL changes
-<li>Note that you must define "TASM_COMPAT" at compile-time to get the Tasm
-Ideal Mode compatibility.
-<li>All changes can be compiled in and out using the TASM_COMPAT macros,
-and when compiled without TASM_COMPAT defined we get the exact same binary
-as the unmodified 0.98 sources.
-<li>standard.mac, macros.c: Added macros to ignore TASM directives before
-first include
-<li>nasm.h: Added extern declaration for tasm_compatible_mode
-<li>nasm.c: Added global variable tasm_compatible_mode
-<li>Added command line switch for TASM compatible mode (-t)
-<li>Changed version command line to reflect when compiled with TASM
-additions
-<li>Added response file processing to allow all arguments on a single line
-(response file is @resp rather than -@resp for NASM format).
-<li>labels.c: Changes islocal() macro to support TASM style @@local labels.
-<li>Added islocalchar() macro to support TASM style @@local labels.
-<li>parser.c: Added support for TASM style memory references (ie: mov
-[DWORD eax],10 rather than the NASM style mov DWORD [eax],10).
-<li>preproc.c: Added new directives, <code><nobr>%arg</nobr></code>,
-<code><nobr>%local</nobr></code>, <code><nobr>%stacksize</nobr></code> to
-directives table
-<li>Added support for TASM style directives without a leading % symbol.
-<li>Integrated a block of changes from Andrew Zabolotny
-&lt;bit@eltech.ru&gt;:
-<li>A new keyword <code><nobr>%xdefine</nobr></code> and its
-case-insensitive counterpart <code><nobr>%ixdefine</nobr></code>. They work
-almost the same way as <code><nobr>%define</nobr></code> and
-<code><nobr>%idefine</nobr></code> but expand the definition immediately,
-not on the invocation. Something like a cross between
-<code><nobr>%define</nobr></code> and <code><nobr>%assign</nobr></code>.
-The "x" suffix stands for "eXpand", so "xdefine" can be deciphered as
-"expand-and-define". Thus you can do things like this:
-</ul>
-<p><pre>
- %assign ofs 0
-
- %macro arg 1
- %xdefine %1 dword [esp+ofs]
- %assign ofs ofs+4
- %endmacro
-</pre>
-<ul>
-<li>Changed the place where the expansion of %$name macros are expanded.
-Now they are converted into ..@ctxnum.name form when detokenizing, so there
-are no quirks as before when using %$name arguments to macros, in macros
-etc. For example:
-</ul>
-<p><pre>
- %macro abc 1
- %define %1 hello
- %endm
-
- abc %$here
- %$here
-</pre>
-<p>Now last line will be expanded into "hello" as expected. This also
-allows for lots of goodies, a good example are extended "proc" macros
-included in this archive.
-<ul>
-<li>Added a check for "cstk" in smacro_defined() before calling get_ctx() -
-this allows for things like:
-</ul>
-<p><pre>
- %ifdef %$abc
- %endif
-</pre>
-<p>to work without warnings even in no context.
-<ul>
-<li>Added a check for "cstk" in %if*ctx and %elif*ctx directives - this
-allows to use <code><nobr>%ifctx</nobr></code> without excessive warnings.
-If there is no active context, <code><nobr>%ifctx</nobr></code> goes
-through "false" branch.
-<li>Removed "user error: " prefix with <code><nobr>%error</nobr></code>
-directive: it just clobbers the output and has absolutely no functionality.
-Besides, this allows to write macros that does not differ from built-in
-functions in any way.
-<li>Added expansion of string that is output by
-<code><nobr>%error</nobr></code> directive. Now you can do things like:
-</ul>
-<p><pre>
- %define hello(x) Hello, x!
-
- %define %$name andy
- %error "hello(%$name)"
-</pre>
-<p>Same happened with <code><nobr>%include</nobr></code> directive.
-<ul>
-<li>Now all directives that expect an identifier will try to expand and
-concatenate everything without whitespaces in between before usage. For
-example, with "unfixed" nasm the commands
-</ul>
-<p><pre>
- %define %$abc hello
- %define __%$abc goodbye
- __%$abc
-</pre>
-<p>would produce "incorrect" output: last line will expand to
-<p><pre>
- hello goodbyehello
-</pre>
-<p>Not quite what you expected, eh? :-) The answer is that preprocessor
-treats the <code><nobr>%define</nobr></code> construct as if it would be
-<p><pre>
- %define __ %$abc goodbye
-</pre>
-<p>(note the white space between __ and %$abc). After my "fix" it will
-"correctly" expand into
-<p><pre>
- goodbye
-</pre>
-<p>as expected. Note that I use quotes around words "correct", "incorrect"
-etc because this is rather a feature not a bug; however current behaviour
-is more logical (and allows more advanced macro usage :-).
-<p>Same change was applied to:
-<code><nobr>%push</nobr></code>,<code><nobr>%macro</nobr></code>,<code><nobr>%imacro</nobr></code>,<code><nobr>%define</nobr></code>,<code><nobr>%idefine</nobr></code>,<code><nobr>%xdefine</nobr></code>,<code><nobr>%ixdefine</nobr></code>,
-<code><nobr>%assign</nobr></code>,<code><nobr>%iassign</nobr></code>,<code><nobr>%undef</nobr></code>
-<ul>
-<li>A new directive [WARNING {+|-}warning-id] have been added. It works
-only if the assembly phase is enabled (i.e. it doesn't work with nasm -e).
-<li>A new warning type: macro-selfref. By default this warning is disabled;
-when enabled NASM warns when a macro self-references itself; for example
-the following source:
-</ul>
-<p><pre>
- [WARNING macro-selfref]
-
- %macro push 1-*
- %rep %0
- push %1
- %rotate 1
- %endrep
- %endmacro
-
- push eax,ebx,ecx
-</pre>
-<p>will produce a warning, but if we remove the first line we won't see it
-anymore (which is The Right Thing To Do {tm} IMHO since C preprocessor eats
-such constructs without warnings at all).
-<ul>
-<li>Added a "error" routine to preprocessor which always will set ERR_PASS1
-bit in severity_code. This removes annoying repeated errors on first and
-second passes from preprocessor.
-<li>Added the %+ operator in single-line macros for concatenating two
-identifiers. Usage example:
-</ul>
-<p><pre>
- %define _myfunc _otherfunc
- %define cextern(x) _ %+ x
- cextern (myfunc)
-</pre>
-<p>After first expansion, third line will become "_myfunc". After this
-expansion is performed again so it becomes "_otherunc".
-<ul>
-<li>Now if preprocessor is in a non-emitting state, no warning or error
-will be emitted. Example:
-</ul>
-<p><pre>
- %if 1
- mov eax,ebx
- %else
- put anything you want between these two brackets,
- even macro-parameter references %1 or local
- labels %$zz or macro-local labels %%zz - no
- warning will be emitted.
- %endif
-</pre>
-<ul>
-<li>Context-local variables on expansion as a last resort are looked up in
-outer contexts. For example, the following piece:
-</ul>
-<p><pre>
- %push outer
- %define %$a [esp]
-
- %push inner
- %$a
- %pop
- %pop
-</pre>
-<p>will expand correctly the fourth line to [esp]; if we'll define another
-%$a inside the "inner" context, it will take precedence over outer
-definition. However, this modification has been applied only to
-expand_smacro and not to smacro_define: as a consequence expansion looks in
-outer contexts, but <code><nobr>%ifdef</nobr></code> won't look in outer
-contexts.
-<p>This behaviour is needed because we don't want nested contexts to act on
-already defined local macros. Example:
-<p><pre>
- %define %$arg1 [esp+4]
- test eax,eax
- if nz
- mov eax,%$arg1
- endif
-</pre>
-<p>In this example the "if" mmacro enters into the "if" context, so %$arg1
-is not valid anymore inside "if". Of course it could be worked around by
-using explicitely %$$arg1 but this is ugly IMHO.
-<ul>
-<li>Fixed memory leak in <code><nobr>%undef</nobr></code>. The origline
-wasn't freed before exiting on success.
-<li>Fixed trap in preprocessor when line expanded to empty set of tokens.
-This happens, for example, in the following case:
-</ul>
-<p><pre>
- #define SOMETHING
- SOMETHING
-</pre>
-<h4><a name="section-C.2.41">C.2.41 Version 0.98</a></h4>
-<p>All changes since NASM 0.98p3 have been produced by H. Peter Anvin
-&lt;hpa@zytor.com&gt;.
-<ul>
-<li>The documentation comment delimiter is
-<li>Allow EQU definitions to refer to external labels; reported by Pedro
-Gimeno.
-<li>Re-enable support for RDOFF v1; reported by Pedro Gimeno.
-<li>Updated License file per OK from Simon and Julian.
-</ul>
-<h4><a name="section-C.2.42">C.2.42 Version 0.98p9</a></h4>
-<ul>
-<li>Update documentation (although the instruction set reference will have
-to wait; I don't want to hold up the 0.98 release for it.)
-<li>Verified that the NASM implementation of the PEXTRW and PMOVMSKB
-instructions is correct. The encoding differs from what the Intel manuals
-document, but the Pentium III behaviour matches NASM, not the Intel
-manuals.
-<li>Fix handling of implicit sizes in PSHUFW and PINSRW, reported by Stefan
-Hoffmeister.
-<li>Resurrect the -s option, which was removed when changing the diagnostic
-output to stdout.
-</ul>
-<h4><a name="section-C.2.43">C.2.43 Version 0.98p8</a></h4>
-<ul>
-<li>Fix for "DB" when NASM is running on a bigendian machine.
-<li>Invoke insns.pl once for each output script, making Makefile.in legal
-for "make -j".
-<li>Improve the Unix configure-based makefiles to make package creation
-easier.
-<li>Included an RPM .spec file for building RPM (RedHat Package Manager)
-packages on Linux or Unix systems.
-<li>Fix Makefile dependency problems.
-<li>Change src/rdsrc.pl to include sectioning information in info output;
-required for install-info to work.
-<li>Updated the RDOFF distribution to version 2 from Jules; minor massaging
-to make it compile in my environment.
-<li>Split doc files that can be built by anyone with a Perl interpreter off
-into a separate archive.
-<li>"Dress rehearsal" release!
-</ul>
-<h4><a name="section-C.2.44">C.2.44 Version 0.98p7</a></h4>
-<ul>
-<li>Fixed opcodes with a third byte-sized immediate argument to not
-complain if given "byte" on the immediate.
-<li>Allow <code><nobr>%undef</nobr></code> to remove single-line macros
-with arguments. This matches the behaviour of #undef in the C preprocessor.
-<li>Allow -d, -u, -i and -p to be specified as -D, -U, -I and -P for
-compatibility with most C compilers and preprocessors. This allows Makefile
-options to be shared between cc and nasm, for example.
-<li>Minor cleanups.
-<li>Went through the list of Katmai instructions and hopefully fixed the
-(rather few) mistakes in it.
-<li>(Hopefully) fixed a number of disassembler bugs related to ambiguous
-instructions (disambiguated by -p) and SSE instructions with REP.
-<li>Fix for bug reported by Mark Junger: "call dword 0x12345678" should
-work and may add an OSP (affected CALL, JMP, Jcc).
-<li>Fix for environments when "stderr" isn't a compile-time constant.
-</ul>
-<h4><a name="section-C.2.45">C.2.45 Version 0.98p6</a></h4>
-<ul>
-<li>Took officially over coordination of the 0.98 release; so drop the p3.x
-notation. Skipped p4 and p5 to avoid confusion with John Fine's J4 and J5
-releases.
-<li>Update the documentation; however, it still doesn't include
-documentation for the various new instructions. I somehow wonder if it
-makes sense to have an instruction set reference in the assembler manual
-when Intel et al have PDF versions of their manuals online.
-<li>Recognize "idt" or "centaur" for the -p option to ndisasm.
-<li>Changed error messages back to stderr where they belong, but add an -E
-option to redirect them elsewhere (the DOS shell cannot redirect stderr.)
-<li>-M option to generate Makefile dependencies (based on code from Alex
-Verstak.)
-<li><code><nobr>%undef</nobr></code> preprocessor directive, and -u option,
-that undefines a single-line macro.
-<li>OS/2 Makefile (Mkfiles/Makefile.os2) for Borland under OS/2; from Chuck
-Crayne.
-<li>Various minor bugfixes (reported by): - Dangling
-<code><nobr>%s</nobr></code> in preproc.c (Martin Junker)
-<li>THERE ARE KNOWN BUGS IN SSE AND THE OTHER KATMAI INSTRUCTIONS. I am on
-a trip and didn't bring the Katmai instruction reference, so I can't work
-on them right now.
-<li>Updated the License file per agreement with Simon and Jules to include
-a GPL distribution clause.
-</ul>
-<h4><a name="section-C.2.46">C.2.46 Version 0.98p3.7</a></h4>
-<ul>
-<li>(Hopefully) fixed the canned Makefiles to include the outrdf2 and
-zoutieee modules.
-<li>Renamed changes.asm to changed.asm.
-</ul>
-<h4><a name="section-C.2.47">C.2.47 Version 0.98p3.6</a></h4>
-<ul>
-<li>Fixed a bunch of instructions that were added in 0.98p3.5 which had
-memory operands, and the address-size prefix was missing from the
-instruction pattern.
-</ul>
-<h4><a name="section-C.2.48">C.2.48 Version 0.98p3.5</a></h4>
-<ul>
-<li>Merged in changes from John S. Fine's 0.98-J5 release. John's based
-0.98-J5 on my 0.98p3.3 release; this merges the changes.
-<li>Expanded the instructions flag field to a long so we can fit more
-flags; mark SSE (KNI) and AMD or Katmai-specific instructions as such.
-<li>Fix the "PRIV" flag on a bunch of instructions, and create new "PROT"
-flag for protected-mode-only instructions (orthogonal to if the instruction
-is privileged!) and new "SMM" flag for SMM-only instructions.
-<li>Added AMD-only SYSCALL and SYSRET instructions.
-<li>Make SSE actually work, and add new Katmai MMX instructions.
-<li>Added a -p (preferred vendor) option to ndisasm so that it can
-distinguish e.g. Cyrix opcodes also used in SSE. For example:
-</ul>
-<p><pre>
- ndisasm -p cyrix aliased.bin
- 00000000 670F514310 paddsiw mm0,[ebx+0x10]
- 00000005 670F514320 paddsiw mm0,[ebx+0x20]
- ndisasm -p intel aliased.bin
- 00000000 670F514310 sqrtps xmm0,[ebx+0x10]
- 00000005 670F514320 sqrtps xmm0,[ebx+0x20]
-</pre>
-<ul>
-<li>Added a bunch of Cyrix-specific instructions.
-</ul>
-<h4><a name="section-C.2.49">C.2.49 Version 0.98p3.4</a></h4>
-<ul>
-<li>Made at least an attempt to modify all the additional Makefiles (in the
-Mkfiles directory). I can't test it, but this was the best I could do.
-<li>DOS DJGPP+"Opus Make" Makefile from John S. Fine.
-<li>changes.asm changes from John S. Fine.
-</ul>
-<h4><a name="section-C.2.50">C.2.50 Version 0.98p3.3</a></h4>
-<ul>
-<li>Patch from Conan Brink to allow nesting of
-<code><nobr>%rep</nobr></code> directives.
-<li>If we're going to allow INT01 as an alias for INT1/ICEBP (one of Jules
-0.98p3 changes), then we should allow INT03 as an alias for INT3 as well.
-<li>Updated changes.asm to include the latest changes.
-<li>Tried to clean up the &lt;CR&gt;s that had snuck in from a DOS/Windows
-environment into my Unix environment, and try to make sure than DOS/Windows
-users get them back.
-<li>We would silently generate broken tools if insns.dat wasn't sorted
-properly. Change insns.pl so that the order doesn't matter.
-<li>Fix bug in insns.pl (introduced by me) which would cause conditional
-instructions to have an extra "cc" in disassembly, e.g. "jnz" disassembled
-as "jccnz".
-</ul>
-<h4><a name="section-C.2.51">C.2.51 Version 0.98p3.2</a></h4>
-<ul>
-<li>Merged in John S. Fine's changes from his 0.98-J4 prerelease; see
-http://www.csoft.net/cz/johnfine/
-<li>Changed previous "spotless" Makefile target (appropriate for
-distribution) to "distclean", and added "cleaner" target which is same as
-"clean" except deletes files generated by Perl scripts; "spotless" is
-union.
-<li>Removed BASIC programs from distribution. Get a Perl interpreter
-instead (see below.)
-<li>Calling this "pre-release 3.2" rather than "p3-hpa2" because of John's
-contributions.
-<li>Actually link in the IEEE output format (zoutieee.c); fix a bunch of
-compiler warnings in that file. Note I don't know what IEEE output is
-supposed to look like, so these changes were made "blind".
-</ul>
-<h4><a name="section-C.2.52">C.2.52 Version 0.98p3-hpa</a></h4>
-<ul>
-<li>Merged nasm098p3.zip with nasm-0.97.tar.gz to create a fully buildable
-version for Unix systems (Makefile.in updates, etc.)
-<li>Changed insns.pl to create the instruction tables in nasm.h and
-names.c, so that a new instruction can be added by adding it *only* to
-insns.dat.
-<li>Added the following new instructions: SYSENTER, SYSEXIT, FXSAVE,
-FXRSTOR, UD1, UD2 (the latter two are two opcodes that Intel guarantee will
-never be used; one of them is documented as UD2 in Intel documentation, the
-other one just as "Undefined Opcode" -- calling it UD1 seemed to make
-sense.)
-<li>MAX_SYMBOL was defined to be 9, but LOADALL286 and LOADALL386 are 10
-characters long. Now MAX_SYMBOL is derived from insns.dat.
-<li>A note on the BASIC programs included: forget them. insns.bas is
-already out of date. Get yourself a Perl interpreter for your platform of
-choice at
-<a href="http://www.cpan.org/ports/index.html">http://www.cpan.org/ports/index.html</a>.
-</ul>
-<h4><a name="section-C.2.53">C.2.53 Version 0.98 pre-release 3</a></h4>
-<ul>
-<li>added response file support, improved command line handling, new layout
-help screen
-<li>fixed limit checking bug, 'OUT byte nn, reg' bug, and a couple of rdoff
-related bugs, updated Wishlist; 0.98 Prerelease 3.
-</ul>
-<h4><a name="section-C.2.54">C.2.54 Version 0.98 pre-release 2</a></h4>
-<ul>
-<li>fixed bug in outcoff.c to do with truncating section names longer than
-8 characters, referencing beyond end of string; 0.98 pre-release 2
-</ul>
-<h4><a name="section-C.2.55">C.2.55 Version 0.98 pre-release 1</a></h4>
-<ul>
-<li>Fixed a bug whereby STRUC didn't work at all in RDF.
-<li>Fixed a problem with group specification in PUBDEFs in OBJ.
-<li>Improved ease of adding new output formats. Contribution due to Fox
-Cutter.
-<li>Fixed a bug in relocations in the `bin' format: was showing up when a
-relocatable reference crossed an 8192-byte boundary in any output section.
-<li>Fixed a bug in local labels: local-label lookups were inconsistent
-between passes one and two if an EQU occurred between the definition of a
-global label and the subsequent use of a local label local to that global.
-<li>Fixed a seg-fault in the preprocessor (again) which happened when you
-use a blank line as the first line of a multi-line macro definition and
-then defined a label on the same line as a call to that macro.
-<li>Fixed a stale-pointer bug in the handling of the NASM environment
-variable. Thanks to Thomas McWilliams.
-<li>ELF had a hard limit on the number of sections which caused segfaults
-when transgressed. Fixed.
-<li>Added ability for ndisasm to read from stdin by using `-' as the
-filename.
-<li>ndisasm wasn't outputting the TO keyword. Fixed.
-<li>Fixed error cascade on bogus expression in
-<code><nobr>%if</nobr></code> - an error in evaluation was causing the
-entire <code><nobr>%if</nobr></code> to be discarded, thus creating trouble
-later when the <code><nobr>%else</nobr></code> or
-<code><nobr>%endif</nobr></code> was encountered.
-<li>Forward reference tracking was instruction-granular not operand-
-granular, which was causing 286-specific code to be generated needlessly on
-code of the form `shr word [forwardref],1'. Thanks to Jim Hague for sending
-a patch.
-<li>All messages now appear on stdout, as sending them to stderr serves no
-useful purpose other than to make redirection difficult.
-<li>Fixed the problem with EQUs pointing to an external symbol - this now
-generates an error message.
-<li>Allowed multiple size prefixes to an operand, of which only the first
-is taken into account.
-<li>Incorporated John Fine's changes, including fixes of a large number of
-preprocessor bugs, some small problems in OBJ, and a reworking of label
-handling to define labels before their line is assembled, rather than
-after.
-<li>Reformatted a lot of the source code to be more readable. Included
-'coding.txt' as a guideline for how to format code for contributors.
-<li>Stopped nested <code><nobr>%reps</nobr></code> causing a panic - they
-now cause a slightly more friendly error message instead.
-<li>Fixed floating point constant problems (patch by Pedro Gimeno)
-<li>Fixed the return value of insn_size() not being checked for -1,
-indicating an error.
-<li>Incorporated 3Dnow! instructions.
-<li>Fixed the 'mov eax, eax + ebx' bug.
-<li>Fixed the GLOBAL EQU bug in ELF. Released developers release 3.
-<li>Incorporated John Fine's command line parsing changes
-<li>Incorporated David Lindauer's OMF debug support
-<li>Made changes for LCC 4.0 support
-(<code><nobr>__NASM_CDecl__</nobr></code>, removed register size
-specification warning when sizes agree).
-</ul>
-<h3><a name="section-C.3">C.3 NASM 0.9 Series</a></h3>
-<p>Revisions before 0.98.
-<h4><a name="section-C.3.1">C.3.1 Version 0.97 released December 1997</a></h4>
-<ul>
-<li>This was entirely a bug-fix release to 0.96, which seems to have got
-cursed. Silly me.
-<li>Fixed stupid mistake in OBJ which caused `MOV EAX,&lt;constant&gt;' to
-fail. Caused by an error in the `MOV EAX,&lt;segment&gt;' support.
-<li>ndisasm hung at EOF when compiled with lcc on Linux because lcc on
-Linux somehow breaks feof(). ndisasm now does not rely on feof().
-<li>A heading in the documentation was missing due to a markup error in the
-indexing. Fixed.
-<li>Fixed failure to update all pointers on realloc() within extended-
-operand code in parser.c. Was causing wrong behaviour and seg faults on
-lines such as `dd 0.0,0.0,0.0,0.0,...'
-<li>Fixed a subtle preprocessor bug whereby invoking one multi-line macro
-on the first line of the expansion of another, when the second had been
-invoked with a label defined before it, didn't expand the inner macro.
-<li>Added internal.doc back in to the distribution archives - it was
-missing in 0.96 *blush*
-<li>Fixed bug causing 0.96 to be unable to assemble its own test files,
-specifically objtest.asm. *blush again*
-<li>Fixed seg-faults and bogus error messages caused by mismatching
-<code><nobr>%rep</nobr></code> and <code><nobr>%endrep</nobr></code> within
-multi-line macro definitions.
-<li>Fixed a problem with buffer overrun in OBJ, which was causing
-corruption at ends of long PUBDEF records.
-<li>Separated DOS archives into main-program and documentation to reduce
-download size.
-</ul>
-<h4><a name="section-C.3.2">C.3.2 Version 0.96 released November 1997</a></h4>
-<ul>
-<li>Fixed a bug whereby, if `nasm sourcefile' would cause a filename
-collision warning and put output into `nasm.out', then `nasm sourcefile -o
-outputfile' still gave the warning even though the `-o' was honoured. Fixed
-name pollution under Digital UNIX: one of its header files defined R_SP,
-which broke the enum in nasm.h.
-<li>Fixed minor instruction table problems: FUCOM and FUCOMP didn't have
-two-operand forms; NDISASM didn't recognise the longer register forms of
-PUSH and POP (eg FF F3 for PUSH BX); TEST mem,imm32 was flagged as
-undocumented; the 32-bit forms of CMOV had 16-bit operand size prefixes;
-`AAD imm' and `AAM imm' are no longer flagged as undocumented because the
-Intel Architecture reference documents them.
-<li>Fixed a problem with the local-label mechanism, whereby strange types
-of symbol (EQUs, auto-defined OBJ segment base symbols) interfered with the
-`previous global label' value and screwed up local labels.
-<li>Fixed a bug whereby the stub preprocessor didn't communicate with the
-listing file generator, so that the -a and -l options in conjunction would
-produce a useless listing file.
-<li>Merged `os2' object file format back into `obj', after discovering that
-`obj' _also_ shouldn't have a link pass separator in a module containing a
-non-trivial MODEND. Flat segments are now declared using the FLAT
-attribute. `os2' is no longer a valid object format name: use `obj'.
-<li>Removed the fixed-size temporary storage in the evaluator. Very very
-long expressions (like `mov ax,1+1+1+1+...' for two hundred 1s or so)
-should now no longer crash NASM.
-<li>Fixed a bug involving segfaults on disassembly of MMX instructions, by
-changing the meaning of one of the operand-type flags in nasm.h. This may
-cause other apparently unrelated MMX problems; it needs to be tested
-thoroughly.
-<li>Fixed some buffer overrun problems with large OBJ output files. Thanks
-to DJ Delorie for the bug report and fix.
-<li>Made preprocess-only mode actually listen to the
-<code><nobr>%line</nobr></code> markers as it prints them, so that it can
-report errors more sanely.
-<li>Re-designed the evaluator to keep more sensible track of expressions
-involving forward references: can now cope with previously-nightmare
-situations such as:
-</ul>
-<p><pre>
- mov ax,foo | bar
- foo equ 1
- bar equ 2
-</pre>
-<ul>
-<li>Added the ALIGN and ALIGNB standard macros.
-<li>Added PIC support in ELF: use of WRT to obtain the four extra
-relocation types needed.
-<li>Added the ability for output file formats to define their own
-extensions to the GLOBAL, COMMON and EXTERN directives.
-<li>Implemented common-variable alignment, and global-symbol type and size
-declarations, in ELF.
-<li>Implemented NEAR and FAR keywords for common variables, plus far-common
-element size specification, in OBJ.
-<li>Added a feature whereby EXTERNs and COMMONs in OBJ can be given a
-default WRT specification (either a segment or a group).
-<li>Transformed the Unix NASM archive into an auto-configuring package.
-<li>Added a sanity-check for people applying SEG to things which are
-already segment bases: this previously went unnoticed by the SEG processing
-and caused OBJ-driver panics later.
-<li>Added the ability, in OBJ format, to deal with `MOV
-EAX,&lt;segment&gt;' type references: OBJ doesn't directly support
-dword-size segment base fixups, but as long as the low two bytes of the
-constant term are zero, a word-size fixup can be generated instead and it
-will work.
-<li>Added the ability to specify sections' alignment requirements in Win32
-object files and pure binary files.
-<li>Added preprocess-time expression evaluation: the
-<code><nobr>%assign</nobr></code> (and <code><nobr>%iassign</nobr></code>)
-directive and the bare <code><nobr>%if</nobr></code> (and
-<code><nobr>%elif</nobr></code>) conditional. Added relational operators to
-the evaluator, for use only in <code><nobr>%if</nobr></code> constructs:
-the standard relationals = &lt; &gt; &lt;= &gt;= &lt;&gt; (and C-like
-synonyms == and !=) plus low-precedence logical operators &amp;&amp;, ^^
-and ||.
-<li>Added a preprocessor repeat construct: <code><nobr>%rep</nobr></code> /
-<code><nobr>%exitrep</nobr></code> / <code><nobr>%endrep</nobr></code>.
-<li>Added the __FILE__ and __LINE__ standard macros.
-<li>Added a sanity check for number constants being greater than
-0xFFFFFFFF. The warning can be disabled.
-<li>Added the %0 token whereby a variadic multi-line macro can tell how
-many parameters it's been given in a specific invocation.
-<li>Added <code><nobr>%rotate</nobr></code>, allowing multi-line macro
-parameters to be cycled.
-<li>Added the `*' option for the maximum parameter count on multi-line
-macros, allowing them to take arbitrarily many parameters.
-<li>Added the ability for the user-level forms of EXTERN, GLOBAL and COMMON
-to take more than one argument.
-<li>Added the IMPORT and EXPORT directives in OBJ format, to deal with
-Windows DLLs.
-<li>Added some more preprocessor <code><nobr>%if</nobr></code> constructs:
-<code><nobr>%ifidn</nobr></code> / <code><nobr>%ifidni</nobr></code> (exact
-textual identity), and <code><nobr>%ifid</nobr></code> /
-<code><nobr>%ifnum</nobr></code> / <code><nobr>%ifstr</nobr></code> (token
-type testing).
-<li>Added the ability to distinguish SHL AX,1 (the 8086 version) from SHL
-AX,BYTE 1 (the 286-and-upwards version whose constant happens to be 1).
-<li>Added NetBSD/FreeBSD/OpenBSD's variant of a.out format, complete with
-PIC shared library features.
-<li>Changed NASM's idiosyncratic handling of FCLEX, FDISI, FENI, FINIT,
-FSAVE, FSTCW, FSTENV, and FSTSW to bring it into line with the otherwise
-accepted standard. The previous behaviour, though it was a deliberate
-feature, was a deliberate feature based on a misunderstanding. Apologies
-for the inconvenience.
-<li>Improved the flexibility of ABSOLUTE: you can now give it an expression
-rather than being restricted to a constant, and it can take relocatable
-arguments as well.
-<li>Added the ability for a variable to be declared as EXTERN multiple
-times, and the subsequent definitions are just ignored.
-<li>We now allow instruction prefixes (CS, DS, LOCK, REPZ etc) to be alone
-on a line (without a following instruction).
-<li>Improved sanity checks on whether the arguments to EXTERN, GLOBAL and
-COMMON are valid identifiers.
-<li>Added misc/exebin.mac to allow direct generation of .EXE files by
-hacking up an EXE header using DB and DW; also added test/binexe.asm to
-demonstrate the use of this. Thanks to Yann Guidon for contributing the EXE
-header code.
-<li>ndisasm forgot to check whether the input file had been successfully
-opened. Now it does. Doh!
-<li>Added the Cyrix extensions to the MMX instruction set.
-<li>Added a hinting mechanism to allow [EAX+EBX] and [EBX+EAX] to be
-assembled differently. This is important since [ESI+EBP] and [EBP+ESI] have
-different default base segment registers.
-<li>Added support for the PharLap OMF extension for 4096-byte segment
-alignment.
-</ul>
-<h4><a name="section-C.3.3">C.3.3 Version 0.95 released July 1997</a></h4>
-<ul>
-<li>Fixed yet another ELF bug. This one manifested if the user relied on
-the default segment, and attempted to define global symbols without first
-explicitly declaring the target segment.
-<li>Added makefiles (for NASM and the RDF tools) to build Win32 console
-apps under Symantec C++. Donated by Mark Junker.
-<li>Added `macros.bas' and `insns.bas', QBasic versions of the Perl scripts
-that convert `standard.mac' to `macros.c' and convert `insns.dat' to
-`insnsa.c' and `insnsd.c'. Also thanks to Mark Junker.
-<li>Changed the diassembled forms of the conditional instructions so that
-JB is now emitted as JC, and other similar changes. Suggested list by
-Ulrich Doewich.
-<li>Added `@' to the list of valid characters to begin an identifier with.
-<li>Documentary changes, notably the addition of the `Common Problems'
-section in nasm.doc.
-<li>Fixed a bug relating to 32-bit PC-relative fixups in OBJ.
-<li>Fixed a bug in perm_copy() in labels.c which was causing exceptions in
-cleanup_labels() on some systems.
-<li>Positivity sanity check in TIMES argument changed from a warning to an
-error following a further complaint.
-<li>Changed the acceptable limits on byte and word operands to allow things
-like `~10111001b' to work.
-<li>Fixed a major problem in the preprocessor which caused seg-faults if
-macro definitions contained blank lines or comment-only lines.
-<li>Fixed inadequate error checking on the commas separating the arguments
-to `db', `dw' etc.
-<li>Fixed a crippling bug in the handling of macros with operand counts
-defined with a `+' modifier.
-<li>Fixed a bug whereby object file formats which stored the input file
-name in the output file (such as OBJ and COFF) weren't doing so correctly
-when the output file name was specified on the command line.
-<li>Removed [INC] and [INCLUDE] support for good, since they were obsolete
-anyway.
-<li>Fixed a bug in OBJ which caused all fixups to be output in 16-bit
-(old-format) FIXUPP records, rather than putting the 32-bit ones in
-FIXUPP32 (new-format) records.
-<li>Added, tentatively, OS/2 object file support (as a minor variant on
-OBJ).
-<li>Updates to Fox Cutter's Borland C makefile, Makefile.bc2.
-<li>Removed a spurious second fclose() on the output file.
-<li>Added the `-s' command line option to redirect all messages which would
-go to stderr (errors, help text) to stdout instead.
-<li>Added the `-w' command line option to selectively suppress some classes
-of assembly warning messages.
-<li>Added the `-p' pre-include and `-d' pre-define command-line options.
-<li>Added an include file search path: the `-i' command line option.
-<li>Fixed a silly little preprocessor bug whereby starting a line with a
-`%!' environment-variable reference caused an `unknown directive' error.
-<li>Added the long-awaited listing file support: the `-l' command line
-option.
-<li>Fixed a problem with OBJ format whereby, in the absence of any explicit
-segment definition, non-global symbols declared in the implicit default
-segment generated spurious EXTDEF records in the output.
-<li>Added the NASM environment variable.
-<li>From this version forward, Win32 console-mode binaries will be included
-in the DOS distribution in addition to the 16-bit binaries. Added
-Makefile.vc for this purpose.
-<li>Added `return 0;' to test/objlink.c to prevent compiler warnings.
-<li>Added the __NASM_MAJOR__ and __NASM_MINOR__ standard defines.
-<li>Added an alternative memory-reference syntax in which prefixing an
-operand with `&amp;' is equivalent to enclosing it in square brackets, at
-the request of Fox Cutter.
-<li>Errors in pass two now cause the program to return a non-zero error
-code, which they didn't before.
-<li>Fixed the single-line macro cycle detection, which didn't work at all
-on macros with no parameters (caused an infinite loop). Also changed the
-behaviour of single-line macro cycle detection to work like cpp, so that
-macros like `extrn' as given in the documentation can be implemented.
-<li>Fixed the implementation of WRT, which was too restrictive in that you
-couldn't do `mov ax,[di+abc wrt dgroup]' because (di+abc) wasn't a
-relocatable reference.
-</ul>
-<h4><a name="section-C.3.4">C.3.4 Version 0.94 released April 1997</a></h4>
-<ul>
-<li>Major item: added the macro processor.
-<li>Added undocumented instructions SMI, IBTS, XBTS and LOADALL286. Also
-reorganised CMPXCHG instruction into early-486 and Pentium forms. Thanks to
-Thobias Jones for the information.
-<li>Fixed two more stupid bugs in ELF, which were causing `ld' to continue
-to seg-fault in a lot of non-trivial cases.
-<li>Fixed a seg-fault in the label manager.
-<li>Stopped FBLD and FBSTP from _requiring_ the TWORD keyword, which is the
-only option for BCD loads/stores in any case.
-<li>Ensured FLDCW, FSTCW and FSTSW can cope with the WORD keyword, if
-anyone bothers to provide it. Previously they complained unless no keyword
-at all was present.
-<li>Some forms of FDIV/FDIVR and FSUB/FSUBR were still inverted: a vestige
-of a bug that I thought had been fixed in 0.92. This was fixed, hopefully
-for good this time...
-<li>Another minor phase error (insofar as a phase error can _ever_ be
-minor) fixed, this one occurring in code of the form
-</ul>
-<p><pre>
- rol ax,forward_reference
- forward_reference equ 1
-</pre>
-<ul>
-<li>The number supplied to TIMES is now sanity-checked for positivity, and
-also may be greater than 64K (which previously didn't work on 16-bit
-systems).
-<li>Added Watcom C makefiles, and misc/pmw.bat, donated by Dominik Behr.
-<li>Added the INCBIN pseudo-opcode.
-<li>Due to the advent of the preprocessor, the [INCLUDE] and [INC]
-directives have become obsolete. They are still supported in this version,
-with a warning, but won't be in the next.
-<li>Fixed a bug in OBJ format, which caused incorrect object records to be
-output when absolute labels were made global.
-<li>Updates to RDOFF subdirectory, and changes to outrdf.c.
-</ul>
-<h4><a name="section-C.3.5">C.3.5 Version 0.93 released January 1997</a></h4>
-<p>This release went out in a great hurry after semi-crippling bugs were
-found in 0.92.
-<ul>
-<li>Really <em>did</em> fix the stack overflows this time. *blush*
-<li>Had problems with EA instruction sizes changing between passes, when an
-offset contained a forward reference and so 4 bytes were allocated for the
-offset in pass one; by pass two the symbol had been defined and happened to
-be a small absolute value, so only 1 byte got allocated, causing
-instruction size mismatch between passes and hence incorrect address
-calculations. Fixed.
-<li>Stupid bug in the revised ELF section generation fixed (associated
-string-table section for .symtab was hard-coded as 7, even when this didn't
-fit with the real section table). Was causing `ld' to seg-fault under
-Linux.
-<li>Included a new Borland C makefile, Makefile.bc2, donated by Fox Cutter
-&lt;lmb@comtch.iea.com&gt;.
-</ul>
-<h4><a name="section-C.3.6">C.3.6 Version 0.92 released January 1997</a></h4>
-<ul>
-<li>The FDIVP/FDIVRP and FSUBP/FSUBRP pairs had been inverted: this was
-fixed. This also affected the LCC driver.
-<li>Fixed a bug regarding 32-bit effective addresses of the form
-<code><nobr>[other_register+ESP]</nobr></code>.
-<li>Documentary changes, notably documentation of the fact that Borland
-Win32 compilers use `obj' rather than `win32' object format.
-<li>Fixed the COMENT record in OBJ files, which was formatted incorrectly.
-<li>Fixed a bug causing segfaults in large RDF files.
-<li>OBJ format now strips initial periods from segment and group
-definitions, in order to avoid complications with the local label syntax.
-<li>Fixed a bug in disassembling far calls and jumps in NDISASM.
-<li>Added support for user-defined sections in COFF and ELF files.
-<li>Compiled the DOS binaries with a sensible amount of stack, to prevent
-stack overflows on any arithmetic expression containing parentheses.
-<li>Fixed a bug in handling of files that do not terminate in a newline.
-</ul>
-<h4><a name="section-C.3.7">C.3.7 Version 0.91 released November 1996</a></h4>
-<ul>
-<li>Loads of bug fixes.
-<li>Support for RDF added.
-<li>Support for DBG debugging format added.
-<li>Support for 32-bit extensions to Microsoft OBJ format added.
-<li>Revised for Borland C: some variable names changed, makefile added.
-<li>LCC support revised to actually work.
-<li>JMP/CALL NEAR/FAR notation added.
-<li>`a16', `o16', `a32' and `o32' prefixes added.
-<li>Range checking on short jumps implemented.
-<li>MMX instruction support added.
-<li>Negative floating point constant support added.
-<li>Memory handling improved to bypass 64K barrier under DOS.
-<li><code><nobr>$</nobr></code> prefix to force treatment of reserved words
-as identifiers added.
-<li>Default-size mechanism for object formats added.
-<li>Compile-time configurability added.
-<li><code><nobr>#</nobr></code>, <code><nobr>@</nobr></code>,
-<code><nobr>~</nobr></code> and c{?} are now valid characters in labels.
-<li><code><nobr>-e</nobr></code> and <code><nobr>-k</nobr></code> options
-in NDISASM added.
-</ul>
-<h4><a name="section-C.3.8">C.3.8 Version 0.90 released October 1996</a></h4>
-<p>First release version. First support for object file output. Other
-changes from previous version (0.3x) too numerous to document.
-<p align=center><a href="nasmdocb.html">Previous Chapter</a> |
-<a href="nasmdoc0.html">Contents</a> |
-<a href="nasmdoci.html">Index</a>
-</body></html>
diff --git a/doc/html/nasmdoci.html b/doc/html/nasmdoci.html
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-<html><head><title>NASM Manual</title></head>
-<body><h1 align=center>The Netwide Assembler: NASM</h1>
-
-<p align=center><a href="nasmdoc0.html">Contents</a>
-<p><code><nobr>!</nobr></code> operator, unary:
-<a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-<code><nobr>!=</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>$$</nobr></code> token:
-<a href="nasmdoc3.html#section-3.5">Section 3.5</a>,
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-<code><nobr>$</nobr></code>, Here token:
-<a href="nasmdoc3.html#section-3.5">Section 3.5</a>
-<br>
-<code><nobr>$</nobr></code>, prefix:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>,
-<a href="nasmdoc3.html#section-3.4.1">Section 3.4.1</a>,
-<a href="nasmdoc7.html#section-7.13.2">Section 7.13.2</a>
-<br>
-<code><nobr>%</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-<code><nobr>%!</nobr></code>:
-<a href="nasmdoc4.html#section-4.10.2">Section 4.10.2</a>
-<br>
-<code><nobr>%$</nobr></code> and <code><nobr>%$$</nobr></code> prefixes:
-<a href="nasmdoc4.html#section-4.7.2">Section 4.7.2</a>
-<br>
-<code><nobr>%%</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>,
-<a href="nasmdoc4.html#section-4.3.3">Section 4.3.3</a>
-<br>
-<code><nobr>%+</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.4">Section 4.1.4</a>
-<br>
-<code><nobr>%?</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.5">Section 4.1.5</a>
-<br>
-<code><nobr>%??</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.5">Section 4.1.5</a>
-<br>
-<code><nobr>%[</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.3">Section 4.1.3</a>
-<br>
-<code><nobr>&amp;</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.3">Section 3.5.3</a>
-<br>
-<code><nobr>&amp;&amp;</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>*</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-<code><nobr>+</nobr></code> modifier:
-<a href="nasmdoc4.html#section-4.3.4">Section 4.3.4</a>
-<br>
-<code><nobr>+</nobr></code> operator, binary:
-<a href="nasmdoc3.html#section-3.5.5">Section 3.5.5</a>
-<br>
-<code><nobr>+</nobr></code> operator, unary:
-<a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-<code><nobr>-</nobr></code> operator, binary:
-<a href="nasmdoc3.html#section-3.5.5">Section 3.5.5</a>
-<br>
-<code><nobr>-</nobr></code> operator, unary:
-<a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-<code><nobr>..@</nobr></code> symbol prefix:
-<a href="nasmdoc3.html#section-3.9">Section 3.9</a>,
-<a href="nasmdoc4.html#section-4.3.3">Section 4.3.3</a>
-<br>
-<code><nobr>/</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-<code><nobr>//</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-<code><nobr>&lt;</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>&lt;&lt;</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.4">Section 3.5.4</a>
-<br>
-<code><nobr>&lt;=</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>&lt;&gt;</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>=</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>==</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>&gt;</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>&gt;=</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>&gt;&gt;</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.4">Section 3.5.4</a>
-<br>
-<code><nobr>?</nobr></code> MASM syntax:
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>^</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.2">Section 3.5.2</a>
-<br>
-<code><nobr>^^</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>|</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.1">Section 3.5.1</a>
-<br>
-<code><nobr>||</nobr></code> operator:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>~</nobr></code> operator:
-<a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-<code><nobr>%0</nobr></code> parameter count:
-<a href="nasmdoc4.html#section-4.3.5">Section 4.3.5</a>,
-<a href="nasmdoc4.html#section-4.3.6">Section 4.3.6</a>
-<br>
-<code><nobr>%+1</nobr></code> and <code><nobr>%-1</nobr></code> syntax:
-<a href="nasmdoc4.html#section-4.3.9">Section 4.3.9</a>
-<br>
-16-bit mode, versus 32-bit mode:
-<a href="nasmdoc6.html#section-6.1">Section 6.1</a>
-<br>
-64-bit displacement: <a href="nasmdo11.html#section-11.2">Section 11.2</a>
-<br>
-64-bit immediate: <a href="nasmdo11.html#section-11.2">Section 11.2</a>
-<br>
-<code><nobr>-a</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.21">Section 2.1.21</a>,
-<a href="nasmdoca.html#section-A.3.3">Section A.3.3</a>
-<br>
-<code><nobr>A16</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>a16</nobr></code>:
-<a href="nasmdo10.html#section-10.3">Section 10.3</a>
-<br>
-<code><nobr>A32</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>a32</nobr></code>:
-<a href="nasmdo10.html#section-10.3">Section 10.3</a>
-<br>
-<code><nobr>A64</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>a64</nobr></code>:
-<a href="nasmdo10.html#section-10.3">Section 10.3</a>
-<br>
-<code><nobr>a86</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>,
-<a href="nasmdoc2.html#section-2.2">Section 2.2</a>,
-<a href="nasmdoc2.html#section-2.2.2">Section 2.2.2</a>,
-<a href="nasmdoc2.html#section-2.2.6">Section 2.2.6</a>
-<br>
-<code><nobr>ABS</nobr></code>:
-<a href="nasmdoc3.html#section-3.3">Section 3.3</a>
-<br>
-<code><nobr>ABSOLUTE</nobr></code>:
-<a href="nasmdoc6.html#section-6.4">Section 6.4</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-addition: <a href="nasmdoc3.html#section-3.5.5">Section 3.5.5</a>
-<br>
-addressing, mixed-size:
-<a href="nasmdo10.html#section-10.2">Section 10.2</a>
-<br>
-address-size prefixes: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-algebra: <a href="nasmdoc3.html#section-3.3">Section 3.3</a>
-<br>
-<code><nobr>ALIGN</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.12">Section 4.11.12</a>,
-<a href="nasmdoc5.html#section-5.2">Section 5.2</a>,
-<a href="nasmdoc7.html#section-7.1.2">Section 7.1.2</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>ALIGN</nobr></code>, smart:
-<a href="nasmdoc5.html#section-5.2">Section 5.2</a>
-<br>
-<code><nobr>ALIGNB</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.12">Section 4.11.12</a>
-<br>
-alignment, in <code><nobr>bin</nobr></code> sections:
-<a href="nasmdoc7.html#section-7.1.2">Section 7.1.2</a>
-<br>
-alignment, in <code><nobr>elf</nobr></code> sections:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-alignment, in <code><nobr>obj</nobr></code> sections:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-alignment, in <code><nobr>win32</nobr></code> sections:
-<a href="nasmdoc7.html#section-7.5.1">Section 7.5.1</a>
-<br>
-alignment, of <code><nobr>elf</nobr></code> common variables:
-<a href="nasmdoc7.html#section-7.9.6">Section 7.9.6</a>
-<br>
-<code><nobr>ALIGNMODE</nobr></code>:
-<a href="nasmdoc5.html#section-5.2">Section 5.2</a>
-<br>
-<code><nobr>__ALIGNMODE__</nobr></code>:
-<a href="nasmdoc5.html#section-5.2">Section 5.2</a>
-<br>
-<code><nobr>ALINK</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>alink.sourceforge.net</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>all</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>alloc</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-alternate register names:
-<a href="nasmdoc5.html#section-5.1">Section 5.1</a>
-<br>
-<code><nobr>alt.lang.asm</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>
-<br>
-<code><nobr>altreg</nobr></code>:
-<a href="nasmdoc5.html#section-5.1">Section 5.1</a>
-<br>
-ambiguity: <a href="nasmdoc2.html#section-2.2.3">Section 2.2.3</a>
-<br>
-<code><nobr>a.out</nobr></code>, BSD version:
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>
-<br>
-<code><nobr>a.out</nobr></code>, Linux version:
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>
-<br>
-<code><nobr>aout</nobr></code>:
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>
-<br>
-<code><nobr>aoutb</nobr></code>:
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-<code><nobr>%arg</nobr></code>:
-<a href="nasmdoc4.html#section-4.8.1">Section 4.8.1</a>
-<br>
-<code><nobr>arg</nobr></code>:
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5</a>,
-<a href="nasmdoc9.html#section-9.1.4">Section 9.1.4</a>
-<br>
-<code><nobr>as86</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>,
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>
-<br>
-assembler directives: <a href="nasmdoc6.html">Chapter 6</a>
-<br>
-assembly-time options:
-<a href="nasmdoc2.html#section-2.1.18">Section 2.1.18</a>
-<br>
-<code><nobr>%assign</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.7">Section 4.1.7</a>
-<br>
-<code><nobr>ASSUME</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.4">Section 2.2.4</a>
-<br>
-<code><nobr>AT</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.11">Section 4.11.11</a>
-<br>
-Autoconf: <a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-<code><nobr>autoexec.bat</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>auto-sync</nobr></code>:
-<a href="nasmdoca.html#section-A.3.3">Section A.3.3</a>
-<br>
-<code><nobr>-b</nobr></code>:
-<a href="nasmdoca.html#section-A.3">Section A.3</a>
-<br>
-bin: <a href="nasmdoc2.html#section-2.1.2">Section 2.1.2</a>,
-<a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-bin, multisection: <a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>
-<br>
-binary: <a href="nasmdoc3.html#section-3.4.1">Section 3.4.1</a>
-<br>
-binary files: <a href="nasmdoc3.html#section-3.2.3">Section 3.2.3</a>
-<br>
-bit shift: <a href="nasmdoc3.html#section-3.5.4">Section 3.5.4</a>
-<br>
-<code><nobr>BITS</nobr></code>:
-<a href="nasmdoc6.html#section-6.1">Section 6.1</a>,
-<a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-<code><nobr>__BITS__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.5">Section 4.11.5</a>
-<br>
-bitwise AND: <a href="nasmdoc3.html#section-3.5.3">Section 3.5.3</a>
-<br>
-bitwise OR: <a href="nasmdoc3.html#section-3.5.1">Section 3.5.1</a>
-<br>
-bitwise XOR: <a href="nasmdoc3.html#section-3.5.2">Section 3.5.2</a>
-<br>
-block IFs: <a href="nasmdoc4.html#section-4.7.5">Section 4.7.5</a>
-<br>
-boot loader: <a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-boot sector: <a href="nasmdo12.html#section-12.1.3">Section 12.1.3</a>
-<br>
-Borland, Pascal: <a href="nasmdoc8.html#section-8.5">Section 8.5</a>
-<br>
-Borland, Win32 compilers:
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-braces, after <code><nobr>%</nobr></code> sign:
-<a href="nasmdoc4.html#section-4.3.8">Section 4.3.8</a>
-<br>
-braces, around macro parameters:
-<a href="nasmdoc4.html#section-4.3">Section 4.3</a>
-<br>
-BSD: <a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-<code><nobr>.bss</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>,
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>,
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-bugs: <a href="nasmdo12.html#section-12.2">Section 12.2</a>
-<br>
-<code><nobr>bugtracker</nobr></code>:
-<a href="nasmdo12.html#section-12.2">Section 12.2</a>
-<br>
-<code><nobr>BYTE</nobr></code>:
-<a href="nasmdo12.html#section-12.1.1">Section 12.1.1</a>
-<br>
-C calling convention:
-<a href="nasmdoc8.html#section-8.4.3">Section 8.4.3</a>,
-<a href="nasmdoc9.html#section-9.1.2">Section 9.1.2</a>
-<br>
-C symbol names: <a href="nasmdoc8.html#section-8.4.1">Section 8.4.1</a>
-<br>
-<code><nobr>c16.mac</nobr></code>:
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5</a>,
-<a href="nasmdoc8.html#section-8.5.3">Section 8.5.3</a>
-<br>
-<code><nobr>c32.mac</nobr></code>:
-<a href="nasmdoc9.html#section-9.1.4">Section 9.1.4</a>
-<br>
-<code><nobr>CALL FAR</nobr></code>:
-<a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-case sensitivity: <a href="nasmdoc2.html#section-2.2.1">Section 2.2.1</a>,
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1</a>,
-<a href="nasmdoc4.html#section-4.1.2">Section 4.1.2</a>,
-<a href="nasmdoc4.html#section-4.1.7">Section 4.1.7</a>,
-<a href="nasmdoc4.html#section-4.3">Section 4.3</a>,
-<a href="nasmdoc4.html#section-4.3.1">Section 4.3.1</a>,
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>,
-<a href="nasmdoc7.html#section-7.4.3">Section 7.4.3</a>
-<br>
-changing sections: <a href="nasmdoc6.html#section-6.3">Section 6.3</a>
-<br>
-character constant:
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.3">Section 3.4.3</a>
-<br>
-character strings: <a href="nasmdoc3.html#section-3.4.2">Section 3.4.2</a>
-<br>
-circular references:
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1</a>
-<br>
-<code><nobr>CLASS</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>%clear</nobr></code>:
-<a href="nasmdoc4.html#section-4.11">Section 4.11</a>
-<br>
-<code><nobr>coff</nobr></code>:
-<a href="nasmdoc7.html#section-7.7">Section 7.7</a>
-<br>
-colon: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>.COM</nobr></code>:
-<a href="nasmdoc7.html#section-7.1">Section 7.1</a>,
-<a href="nasmdoc8.html#section-8.2">Section 8.2</a>
-<br>
-command-line: <a href="nasmdoc2.html#section-2.1">Section 2.1</a>,
-<a href="nasmdoc7.html">Chapter 7</a>
-<br>
-commas in macro parameters:
-<a href="nasmdoc4.html#section-4.3.4">Section 4.3.4</a>
-<br>
-<code><nobr>.comment</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>COMMON</nobr></code>:
-<a href="nasmdoc6.html#section-6.7">Section 6.7</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>COMMON</nobr></code>, <code><nobr>elf</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.9.6">Section 7.9.6</a>
-<br>
-<code><nobr>COMMON</nobr></code>, <code><nobr>obj</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.4.8">Section 7.4.8</a>
-<br>
-Common Object File Format:
-<a href="nasmdoc7.html#section-7.7">Section 7.7</a>
-<br>
-common variables: <a href="nasmdoc6.html#section-6.7">Section 6.7</a>
-<br>
-common variables, alignment in <code><nobr>elf</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.6">Section 7.9.6</a>
-<br>
-common variables, element size:
-<a href="nasmdoc7.html#section-7.4.8">Section 7.4.8</a>
-<br>
-<code><nobr>comp.lang.asm.x86</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>,
-<a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-<code><nobr>comp.os.msdos.programmer</nobr></code>:
-<a href="nasmdoc8.html#section-8.3">Section 8.3</a>
-<br>
-concatenating macro parameters:
-<a href="nasmdoc4.html#section-4.3.8">Section 4.3.8</a>
-<br>
-concatenating strings:
-<a href="nasmdoc4.html#section-4.2.1">Section 4.2.1</a>
-<br>
-condition codes as macro parameters:
-<a href="nasmdoc4.html#section-4.3.9">Section 4.3.9</a>
-<br>
-conditional assembly: <a href="nasmdoc4.html#section-4.4">Section 4.4</a>
-<br>
-conditional jumps:
-<a href="nasmdo12.html#section-12.1.2">Section 12.1.2</a>
-<br>
-conditional-return macro:
-<a href="nasmdoc4.html#section-4.3.9">Section 4.3.9</a>
-<br>
-<code><nobr>configure</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-constants: <a href="nasmdoc3.html#section-3.4">Section 3.4</a>
-<br>
-context stack: <a href="nasmdoc4.html#section-4.7">Section 4.7</a>,
-<a href="nasmdoc4.html#section-4.7.5">Section 4.7.5</a>
-<br>
-context-local labels:
-<a href="nasmdoc4.html#section-4.7.2">Section 4.7.2</a>
-<br>
-context-local single-line macros:
-<a href="nasmdoc4.html#section-4.7.3">Section 4.7.3</a>
-<br>
-counting macro parameters:
-<a href="nasmdoc4.html#section-4.3.6">Section 4.3.6</a>
-<br>
-<code><nobr>CPU</nobr></code>:
-<a href="nasmdoc6.html#section-6.8">Section 6.8</a>
-<br>
-<code><nobr>CPUID</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.3">Section 3.4.3</a>
-<br>
-creating contexts: <a href="nasmdoc4.html#section-4.7.1">Section 4.7.1</a>
-<br>
-critical expression:
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>,
-<a href="nasmdoc3.html#section-3.8">Section 3.8</a>,
-<a href="nasmdoc4.html#section-4.1.7">Section 4.1.7</a>,
-<a href="nasmdoc6.html#section-6.4">Section 6.4</a>
-<br>
-<code><nobr>-D</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.18">Section 2.1.18</a>
-<br>
-<code><nobr>-d</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.18">Section 2.1.18</a>
-<br>
-daily development snapshots:
-<a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-<code><nobr>.data</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>,
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>,
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-<code><nobr>_DATA</nobr></code>:
-<a href="nasmdoc8.html#section-8.4.2">Section 8.4.2</a>
-<br>
-<code><nobr>data</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>,
-<a href="nasmdoc7.html#section-7.13.3">Section 7.13.3</a>
-<br>
-data structure: <a href="nasmdoc8.html#section-8.4.4">Section 8.4.4</a>,
-<a href="nasmdoc9.html#section-9.1.3">Section 9.1.3</a>
-<br>
-<code><nobr>__DATE__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>__DATE_NUM__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>DB</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>dbg</nobr></code>:
-<a href="nasmdoc7.html#section-7.14">Section 7.14</a>
-<br>
-<code><nobr>DD</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-debug information:
-<a href="nasmdoc2.html#section-2.1.12">Section 2.1.12</a>
-<br>
-debug information format:
-<a href="nasmdoc2.html#section-2.1.11">Section 2.1.11</a>
-<br>
-declaring structures:
-<a href="nasmdoc4.html#section-4.11.10">Section 4.11.10</a>
-<br>
-<code><nobr>DEFAULT</nobr></code>:
-<a href="nasmdoc6.html#section-6.2">Section 6.2</a>
-<br>
-<code><nobr>default</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-default macro parameters:
-<a href="nasmdoc4.html#section-4.3.5">Section 4.3.5</a>
-<br>
-default name: <a href="nasmdoc7.html">Chapter 7</a>
-<br>
-default-<code><nobr>WRT</nobr></code> mechanism:
-<a href="nasmdoc7.html#section-7.4.7">Section 7.4.7</a>
-<br>
-<code><nobr>%define</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.18">Section 2.1.18</a>,
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1</a>
-<br>
-defining sections: <a href="nasmdoc6.html#section-6.3">Section 6.3</a>
-<br>
-<code><nobr>%defstr</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.8">Section 4.1.8</a>
-<br>
-<code><nobr>%deftok</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.9">Section 4.1.9</a>
-<br>
-<code><nobr>%depend</nobr></code>:
-<a href="nasmdoc4.html#section-4.6.3">Section 4.6.3</a>
-<br>
-design goals: <a href="nasmdoc2.html#section-2.2.2">Section 2.2.2</a>
-<br>
-DevPac: <a href="nasmdoc3.html#section-3.2.3">Section 3.2.3</a>,
-<a href="nasmdoc3.html#section-3.9">Section 3.9</a>
-<br>
-disabling listing expansion:
-<a href="nasmdoc4.html#section-4.3.10">Section 4.3.10</a>
-<br>
-division: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-DJGPP: <a href="nasmdoc7.html#section-7.7">Section 7.7</a>,
-<a href="nasmdoc9.html">Chapter 9</a>
-<br>
-<code><nobr>djlink</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-DLL symbols, exporting:
-<a href="nasmdoc7.html#section-7.4.5">Section 7.4.5</a>
-<br>
-DLL symbols, importing:
-<a href="nasmdoc7.html#section-7.4.4">Section 7.4.4</a>
-<br>
-<code><nobr>DO</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-DOS: <a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>,
-<a href="nasmdoc2.html#section-2.1.14">Section 2.1.14</a>,
-<a href="nasmdoc2.html#section-2.1.15">Section 2.1.15</a>
-<br>
-DOS archive:
-<br>
-DOS source archive: <a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>DQ</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>.drectve</nobr></code>:
-<a href="nasmdoc7.html#section-7.5.1">Section 7.5.1</a>
-<br>
-<code><nobr>DT</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>DUP</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.7">Section 2.2.7</a>,
-<a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>
-<br>
-<code><nobr>DW</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>DWORD</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>DY</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>
-<br>
-<code><nobr>-E</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.20">Section 2.1.20</a>
-<br>
-<code><nobr>-e</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.20">Section 2.1.20</a>,
-<a href="nasmdoca.html#section-A.3.4">Section A.3.4</a>
-<br>
-effective addresses: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>,
-<a href="nasmdoc3.html#section-3.3">Section 3.3</a>
-<br>
-element size, in common variables:
-<a href="nasmdoc7.html#section-7.4.8">Section 7.4.8</a>
-<br>
-ELF: <a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-ELF, shared libraries:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-ELF, 16-bit code and:
-<a href="nasmdoc7.html#section-7.9.7">Section 7.9.7</a>
-<br>
-elf, debug formats and:
-<a href="nasmdoc7.html#section-7.9.8">Section 7.9.8</a>
-<br>
-<code><nobr>elf32</nobr></code>:
-<a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-<code><nobr>elf64</nobr></code>:
-<a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-<code><nobr>%elif</nobr></code>:
-<a href="nasmdoc4.html#section-4.4">Section 4.4</a>,
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>%elifctx</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.3">Section 4.4.3</a>
-<br>
-<code><nobr>%elifdef</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.1">Section 4.4.1</a>
-<br>
-<code><nobr>%elifempty</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.8">Section 4.4.8</a>
-<br>
-<code><nobr>%elifid</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%elifidn</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%elifidni</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%elifmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.2">Section 4.4.2</a>
-<br>
-<code><nobr>%elifn</nobr></code>:
-<a href="nasmdoc4.html#section-4.4">Section 4.4</a>,
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>%elifnctx</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.3">Section 4.4.3</a>
-<br>
-<code><nobr>%elifndef</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.1">Section 4.4.1</a>
-<br>
-<code><nobr>%elifnempty</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.8">Section 4.4.8</a>
-<br>
-<code><nobr>%elifnid</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%elifnidn</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%elifnidni</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%elifnmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.2">Section 4.4.2</a>
-<br>
-<code><nobr>%elifnnum</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%elifnstr</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%elifntoken</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.7">Section 4.4.7</a>
-<br>
-<code><nobr>%elifnum</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%elifstr</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%eliftoken</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.7">Section 4.4.7</a>
-<br>
-<code><nobr>%else</nobr></code>:
-<a href="nasmdoc4.html#section-4.4">Section 4.4</a>
-<br>
-<code><nobr>endproc</nobr></code>:
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5</a>,
-<a href="nasmdoc9.html#section-9.1.4">Section 9.1.4</a>
-<br>
-<code><nobr>%endrep</nobr></code>:
-<a href="nasmdoc4.html#section-4.5">Section 4.5</a>
-<br>
-<code><nobr>ENDSTRUC</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.10">Section 4.11.10</a>,
-<a href="nasmdoc6.html#section-6.4">Section 6.4</a>
-<br>
-environment: <a href="nasmdoc2.html#section-2.1.28">Section 2.1.28</a>
-<br>
-<code><nobr>EQU</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.4">Section 3.2.4</a>
-<br>
-<code><nobr>%error</nobr></code>:
-<a href="nasmdoc4.html#section-4.9">Section 4.9</a>
-<br>
-<code><nobr>error</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-error messages: <a href="nasmdoc2.html#section-2.1.14">Section 2.1.14</a>,
-<a href="nasmdoc2.html#section-2.1.15">Section 2.1.15</a>
-<br>
-error reporting format:
-<a href="nasmdoc2.html#section-2.1.13">Section 2.1.13</a>
-<br>
-escape sequences: <a href="nasmdoc3.html#section-3.4.2">Section 3.4.2</a>
-<br>
-<code><nobr>EVEN</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.12">Section 4.11.12</a>
-<br>
-exact matches: <a href="nasmdoc4.html#section-4.3.11">Section 4.3.11</a>
-<br>
-<code><nobr>.EXE</nobr></code>:
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>,
-<a href="nasmdoc8.html#section-8.1">Section 8.1</a>
-<br>
-<code><nobr>EXE2BIN</nobr></code>:
-<a href="nasmdoc8.html#section-8.2.2">Section 8.2.2</a>
-<br>
-<code><nobr>EXE_begin</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.2">Section 8.1.2</a>
-<br>
-<code><nobr>exebin.mac</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.2">Section 8.1.2</a>
-<br>
-<code><nobr>exec</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-Executable and Linkable Format:
-<a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-<code><nobr>EXE_end</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.2">Section 8.1.2</a>
-<br>
-<code><nobr>EXE_stack</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.2">Section 8.1.2</a>
-<br>
-<code><nobr>%exitmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.3.12">Section 4.3.12</a>
-<br>
-<code><nobr>%exitrep</nobr></code>:
-<a href="nasmdoc4.html#section-4.5">Section 4.5</a>
-<br>
-<code><nobr>EXPORT</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.5">Section 7.4.5</a>
-<br>
-<code><nobr>export</nobr></code>:
-<a href="nasmdoc7.html#section-7.13.3">Section 7.13.3</a>
-<br>
-exporting symbols: <a href="nasmdoc6.html#section-6.6">Section 6.6</a>
-<br>
-expressions: <a href="nasmdoc2.html#section-2.1.20">Section 2.1.20</a>,
-<a href="nasmdoc3.html#section-3.5">Section 3.5</a>
-<br>
-extension: <a href="nasmdoc2.html#section-2.1.1">Section 2.1.1</a>,
-<a href="nasmdoc7.html">Chapter 7</a>
-<br>
-<code><nobr>EXTERN</nobr></code>:
-<a href="nasmdoc6.html#section-6.5">Section 6.5</a>
-<br>
-<code><nobr>EXTERN</nobr></code>, <code><nobr>obj</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.4.7">Section 7.4.7</a>
-<br>
-<code><nobr>EXTERN</nobr></code>, <code><nobr>rdf</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.13.4">Section 7.13.4</a>
-<br>
-extracting substrings:
-<a href="nasmdoc4.html#section-4.2.3">Section 4.2.3</a>
-<br>
-<code><nobr>-F</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.11">Section 2.1.11</a>
-<br>
-<code><nobr>-f</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.2">Section 2.1.2</a>,
-<a href="nasmdoc7.html">Chapter 7</a>
-<br>
-far call: <a href="nasmdoc2.html#section-2.2.5">Section 2.2.5</a>
-<br>
-far common variables:
-<a href="nasmdoc7.html#section-7.4.8">Section 7.4.8</a>
-<br>
-far pointer: <a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-<code><nobr>FARCODE</nobr></code>:
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5</a>,
-<a href="nasmdoc8.html#section-8.5.3">Section 8.5.3</a>
-<br>
-<code><nobr>%fatal</nobr></code>:
-<a href="nasmdoc4.html#section-4.9">Section 4.9</a>
-<br>
-<code><nobr>__FILE__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.4">Section 4.11.4</a>
-<br>
-<code><nobr>FLAT</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-flat memory model: <a href="nasmdoc9.html">Chapter 9</a>
-<br>
-flat-form binary: <a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-<code><nobr>FLOAT</nobr></code>:
-<a href="nasmdoc6.html#section-6.9">Section 6.9</a>
-<br>
-<code><nobr>__FLOAT__</nobr></code>:
-<a href="nasmdoc6.html#section-6.9">Section 6.9</a>
-<br>
-<code><nobr>__float128h__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float128l__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float16__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float32__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float64__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float8__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float80e__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__float80m__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>__FLOAT_DAZ__</nobr></code>:
-<a href="nasmdoc6.html#section-6.9">Section 6.9</a>
-<br>
-<code><nobr>float-denorm</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-floating-point, constants:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>,
-<a href="nasmdoc6.html#section-6.9">Section 6.9</a>
-<br>
-floating-point, packed BCD constants:
-<a href="nasmdoc3.html#section-3.4.7">Section 3.4.7</a>
-<br>
-floating-point: <a href="nasmdoc2.html#section-2.2.6">Section 2.2.6</a>,
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>,
-<a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>float-overflow</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>__FLOAT_ROUND__</nobr></code>:
-<a href="nasmdoc6.html#section-6.9">Section 6.9</a>
-<br>
-<code><nobr>float-toolong</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>float-underflow</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>follows=</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>
-<br>
-format-specific directives: <a href="nasmdoc6.html">Chapter 6</a>
-<br>
-frame pointer: <a href="nasmdoc8.html#section-8.4.3">Section 8.4.3</a>,
-<a href="nasmdoc8.html#section-8.5.1">Section 8.5.1</a>,
-<a href="nasmdoc9.html#section-9.1.2">Section 9.1.2</a>
-<br>
-FreeBSD: <a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-FreeLink: <a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>ftp.simtel.net</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>function</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>,
-<a href="nasmdoc7.html#section-7.13.3">Section 7.13.3</a>
-<br>
-functions, C calling convention:
-<a href="nasmdoc8.html#section-8.4.3">Section 8.4.3</a>,
-<a href="nasmdoc9.html#section-9.1.2">Section 9.1.2</a>
-<br>
-functions, Pascal calling convention:
-<a href="nasmdoc8.html#section-8.5.1">Section 8.5.1</a>
-<br>
-<code><nobr>-g</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.12">Section 2.1.12</a>
-<br>
-<code><nobr>gas</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>
-<br>
-<code><nobr>gcc</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>
-<br>
-<code><nobr>GLOBAL</nobr></code>:
-<a href="nasmdoc6.html#section-6.6">Section 6.6</a>
-<br>
-<code><nobr>GLOBAL</nobr></code>, <code><nobr>aoutb</nobr></code>
-extensions to: <a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-<code><nobr>GLOBAL</nobr></code>, <code><nobr>elf</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-<code><nobr>GLOBAL</nobr></code>, <code><nobr>rdf</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.13.3">Section 7.13.3</a>
-<br>
-global offset table: <a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-<code><nobr>_GLOBAL_OFFSET_TABLE_</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-<code><nobr>gnu-elf-extensions</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>..got</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-<code><nobr>GOT</nobr></code> relocations:
-<a href="nasmdoc9.html#section-9.2.3">Section 9.2.3</a>
-<br>
-GOT: <a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-<code><nobr>..gotoff</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-<code><nobr>GOTOFF</nobr></code> relocations:
-<a href="nasmdoc9.html#section-9.2.2">Section 9.2.2</a>
-<br>
-<code><nobr>..gotpc</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-<code><nobr>GOTPC</nobr></code> relocations:
-<a href="nasmdoc9.html#section-9.2.1">Section 9.2.1</a>
-<br>
-<code><nobr>..gottpoff</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.4">Section 7.9.4</a>
-<br>
-graphics: <a href="nasmdoc3.html#section-3.2.3">Section 3.2.3</a>
-<br>
-greedy macro parameters:
-<a href="nasmdoc4.html#section-4.3.4">Section 4.3.4</a>
-<br>
-<code><nobr>GROUP</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.2">Section 7.4.2</a>
-<br>
-groups: <a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-<code><nobr>-h</nobr></code>:
-<a href="nasmdoca.html#section-A.3">Section A.3</a>
-<br>
-hexadecimal: <a href="nasmdoc3.html#section-3.4.1">Section 3.4.1</a>
-<br>
-<code><nobr>hidden</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-hybrid syntaxes: <a href="nasmdoc2.html#section-2.2.2">Section 2.2.2</a>
-<br>
-<code><nobr>-I</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>
-<br>
-<code><nobr>-i</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>,
-<a href="nasmdoca.html#section-A.3.3">Section A.3.3</a>
-<br>
-<code><nobr>%iassign</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.7">Section 4.1.7</a>
-<br>
-<code><nobr>%idefine</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1</a>
-<br>
-<code><nobr>%idefstr</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.8">Section 4.1.8</a>
-<br>
-<code><nobr>%ideftok</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.9">Section 4.1.9</a>
-<br>
-<code><nobr>IEND</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.11">Section 4.11.11</a>
-<br>
-<code><nobr>%if</nobr></code>:
-<a href="nasmdoc4.html#section-4.4">Section 4.4</a>,
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>%ifctx</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.3">Section 4.4.3</a>,
-<a href="nasmdoc4.html#section-4.7.5">Section 4.7.5</a>
-<br>
-<code><nobr>%ifdef</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.1">Section 4.4.1</a>
-<br>
-<code><nobr>%ifempty</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.8">Section 4.4.8</a>
-<br>
-<code><nobr>%ifid</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%ifidn</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%ifidni</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%ifmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.2">Section 4.4.2</a>
-<br>
-<code><nobr>%ifn</nobr></code>:
-<a href="nasmdoc4.html#section-4.4">Section 4.4</a>,
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>%ifnctx</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.3">Section 4.4.3</a>
-<br>
-<code><nobr>%ifndef</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.1">Section 4.4.1</a>
-<br>
-<code><nobr>%ifnempty</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.8">Section 4.4.8</a>
-<br>
-<code><nobr>%ifnid</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%ifnidn</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%ifnidni</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-<code><nobr>%ifnmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.2">Section 4.4.2</a>
-<br>
-<code><nobr>%ifnnum</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%ifnstr</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%ifntoken</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.7">Section 4.4.7</a>
-<br>
-<code><nobr>%ifnum</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%ifstr</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>%iftoken</nobr></code>:
-<a href="nasmdoc4.html#section-4.4.7">Section 4.4.7</a>
-<br>
-<code><nobr>%imacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.3">Section 4.3</a>
-<br>
-<code><nobr>IMPORT</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.4">Section 7.4.4</a>
-<br>
-import library: <a href="nasmdoc7.html#section-7.4.4">Section 7.4.4</a>
-<br>
-importing symbols: <a href="nasmdoc6.html#section-6.5">Section 6.5</a>
-<br>
-<code><nobr>INCBIN</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.3">Section 3.2.3</a>,
-<a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>
-<br>
-<code><nobr>%include</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>,
-<a href="nasmdoc2.html#section-2.1.17">Section 2.1.17</a>,
-<a href="nasmdoc4.html#section-4.6.1">Section 4.6.1</a>
-<br>
-include search path:
-<a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>
-<br>
-including other files:
-<a href="nasmdoc4.html#section-4.6.1">Section 4.6.1</a>
-<br>
-inefficient code: <a href="nasmdo12.html#section-12.1.1">Section 12.1.1</a>
-<br>
-infinite loop: <a href="nasmdoc3.html#section-3.5">Section 3.5</a>
-<br>
-<code><nobr>__Infinity__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-infinity: <a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-informational section:
-<a href="nasmdoc7.html#section-7.5.1">Section 7.5.1</a>
-<br>
-<code><nobr>INSTALL</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-installing: <a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-instances of structures:
-<a href="nasmdoc4.html#section-4.11.11">Section 4.11.11</a>
-<br>
-instruction list: <a href="nasmdocb.html">Appendix B</a>
-<br>
-intel hex: <a href="nasmdoc7.html#section-7.2">Section 7.2</a>
-<br>
-Intel number formats:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-<code><nobr>internal</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-<code><nobr>%irmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.3.1">Section 4.3.1</a>
-<br>
-<code><nobr>ISTRUC</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.11">Section 4.11.11</a>
-<br>
-iterating over macro parameters:
-<a href="nasmdoc4.html#section-4.3.7">Section 4.3.7</a>
-<br>
-<code><nobr>ith</nobr></code>:
-<a href="nasmdoc7.html#section-7.2">Section 7.2</a>
-<br>
-<code><nobr>%ixdefine</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.2">Section 4.1.2</a>
-<br>
-<code><nobr>Jcc NEAR</nobr></code>:
-<a href="nasmdo12.html#section-12.1.2">Section 12.1.2</a>
-<br>
-<code><nobr>JMP DWORD</nobr></code>:
-<a href="nasmdo10.html#section-10.1">Section 10.1</a>
-<br>
-jumps, mixed-size: <a href="nasmdo10.html#section-10.1">Section 10.1</a>
-<br>
-<code><nobr>-k</nobr></code>:
-<a href="nasmdoca.html#section-A.3.4">Section A.3.4</a>
-<br>
-<code><nobr>-l</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.3">Section 2.1.3</a>
-<br>
-label prefix: <a href="nasmdoc3.html#section-3.9">Section 3.9</a>
-<br>
-<code><nobr>.lbss</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>ld86</nobr></code>:
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>
-<br>
-<code><nobr>.ldata</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>LIBRARY</nobr></code>:
-<a href="nasmdoc7.html#section-7.13.1">Section 7.13.1</a>
-<br>
-license: <a href="nasmdoc1.html#section-1.1.2">Section 1.1.2</a>
-<br>
-<code><nobr>%line</nobr></code>:
-<a href="nasmdoc4.html#section-4.10.1">Section 4.10.1</a>
-<br>
-<code><nobr>__LINE__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.4">Section 4.11.4</a>
-<br>
-linker, free: <a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-Linux, <code><nobr>a.out</nobr></code>:
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>
-<br>
-Linux, <code><nobr>as86</nobr></code>:
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>
-<br>
-Linux, ELF: <a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-listing file: <a href="nasmdoc2.html#section-2.1.3">Section 2.1.3</a>
-<br>
-little-endian: <a href="nasmdoc3.html#section-3.4.3">Section 3.4.3</a>
-<br>
-<code><nobr>%local</nobr></code>:
-<a href="nasmdoc4.html#section-4.8.3">Section 4.8.3</a>
-<br>
-local labels: <a href="nasmdoc3.html#section-3.9">Section 3.9</a>
-<br>
-logical AND: <a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-logical negation: <a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-logical OR: <a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-logical XOR: <a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-<code><nobr>.lrodata</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>-M</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.4">Section 2.1.4</a>
-<br>
-Mach, object file format:
-<a href="nasmdoc7.html#section-7.8">Section 7.8</a>
-<br>
-Mach-O: <a href="nasmdoc7.html#section-7.8">Section 7.8</a>
-<br>
-<code><nobr>macho</nobr></code>:
-<a href="nasmdoc7.html#section-7.8">Section 7.8</a>
-<br>
-<code><nobr>macho32</nobr></code>:
-<a href="nasmdoc7.html#section-7.8">Section 7.8</a>
-<br>
-<code><nobr>macho64</nobr></code>:
-<a href="nasmdoc7.html#section-7.8">Section 7.8</a>
-<br>
-MacOS X: <a href="nasmdoc7.html#section-7.8">Section 7.8</a>
-<br>
-<code><nobr>%macro</nobr></code>:
-<a href="nasmdoc4.html#section-4.3">Section 4.3</a>
-<br>
-macro indirection: <a href="nasmdoc4.html#section-4.1.3">Section 4.1.3</a>
-<br>
-macro library: <a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>
-<br>
-macro processor: <a href="nasmdoc4.html">Chapter 4</a>
-<br>
-<code><nobr>macro-defaults</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-macro-local labels: <a href="nasmdoc4.html#section-4.3.3">Section 4.3.3</a>
-<br>
-<code><nobr>macro-params</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-macros: <a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>
-<br>
-<code><nobr>macro-selfref</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>make</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-makefile dependencies:
-<a href="nasmdoc2.html#section-2.1.4">Section 2.1.4</a>,
-<a href="nasmdoc2.html#section-2.1.5">Section 2.1.5</a>
-<br>
-makefiles: <a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>,
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-man pages: <a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-map files: <a href="nasmdoc7.html#section-7.1.4">Section 7.1.4</a>
-<br>
-<code><nobr>MASM</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>
-<br>
-MASM: <a href="nasmdoc2.html#section-2.2">Section 2.2</a>,
-<a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>,
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-<code><nobr>-MD</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.7">Section 2.1.7</a>
-<br>
-memory models: <a href="nasmdoc2.html#section-2.2.5">Section 2.2.5</a>,
-<a href="nasmdoc8.html#section-8.4.2">Section 8.4.2</a>
-<br>
-memory operand: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-memory references: <a href="nasmdoc2.html#section-2.2.2">Section 2.2.2</a>,
-<a href="nasmdoc3.html#section-3.3">Section 3.3</a>
-<br>
-<code><nobr>-MF</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.6">Section 2.1.6</a>
-<br>
-<code><nobr>-MG</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.5">Section 2.1.5</a>
-<br>
-Microsoft OMF: <a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-minifloat: <a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-Minix: <a href="nasmdoc7.html#section-7.12">Section 7.12</a>
-<br>
-<code><nobr>misc</nobr></code> subdirectory:
-<a href="nasmdoc8.html#section-8.1.2">Section 8.1.2</a>,
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5</a>,
-<a href="nasmdoc9.html#section-9.1.4">Section 9.1.4</a>
-<br>
-mixed-language program: <a href="nasmdoc8.html#section-8.4">Section 8.4</a>
-<br>
-mixed-size addressing:
-<a href="nasmdo10.html#section-10.2">Section 10.2</a>
-<br>
-mixed-size instruction:
-<a href="nasmdo10.html#section-10.1">Section 10.1</a>
-<br>
-MMX registers:
-<br>
-ModR/M byte:
-<br>
-<code><nobr>MODULE</nobr></code>:
-<a href="nasmdoc7.html#section-7.13.2">Section 7.13.2</a>
-<br>
-modulo operators: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-motorola s-records: <a href="nasmdoc7.html#section-7.3">Section 7.3</a>
-<br>
-<code><nobr>-MP</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.10">Section 2.1.10</a>
-<br>
-<code><nobr>-MQ</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.9">Section 2.1.9</a>
-<br>
-MS-DOS: <a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-MS-DOS device drivers: <a href="nasmdoc8.html#section-8.3">Section 8.3</a>
-<br>
-<code><nobr>-MT</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.8">Section 2.1.8</a>
-<br>
-multi-line macros:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>,
-<a href="nasmdoc4.html#section-4.3">Section 4.3</a>
-<br>
-multipass optimization:
-<a href="nasmdoc2.html#section-2.1.22">Section 2.1.22</a>
-<br>
-multiple section names: <a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-multiplication: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-<code><nobr>multipush</nobr></code> macro:
-<a href="nasmdoc4.html#section-4.3.7">Section 4.3.7</a>
-<br>
-multisection: <a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>
-<br>
-<code><nobr>__NaN__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-NaN: <a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-NASM version: <a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-nasm version history: <a href="nasmdocc.html">Appendix C</a>
-<br>
-nasm version id: <a href="nasmdoc4.html#section-4.11.2">Section 4.11.2</a>
-<br>
-nasm version string:
-<a href="nasmdoc4.html#section-4.11.3">Section 4.11.3</a>
-<br>
-<code><nobr>nasm.1</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-<code><nobr>__NASMDEFSEG</nobr></code>:
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-<code><nobr>nasm-devel</nobr></code>:
-<a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-<code><nobr>NASMENV</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.28">Section 2.1.28</a>
-<br>
-<code><nobr>nasm.exe</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>nasm -hf</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.2">Section 2.1.2</a>
-<br>
-<code><nobr>__NASM_MAJOR__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-<code><nobr>__NASM_MINOR__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-<code><nobr>nasm.out</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.1">Section 2.1.1</a>
-<br>
-<code><nobr>___NASM_PATCHLEVEL__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-<code><nobr>__NASM_SNAPSHOT__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-<code><nobr>__NASM_SUBMINOR__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-<code><nobr>__NASM_VER__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.3">Section 4.11.3</a>
-<br>
-<code><nobr>__NASM_VERSION_ID__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.2">Section 4.11.2</a>
-<br>
-<code><nobr>nasm-XXX-dos.zip</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>nasm-XXX.tar.gz</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-<code><nobr>nasm-XXX-win32.zip</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>nasm-XXX.zip</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-ndisasm: <a href="nasmdoca.html">Appendix A</a>
-<br>
-<code><nobr>ndisasm.1</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-<code><nobr>ndisasm.exe</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-near call: <a href="nasmdoc2.html#section-2.2.5">Section 2.2.5</a>
-<br>
-near common variables:
-<a href="nasmdoc7.html#section-7.4.8">Section 7.4.8</a>
-<br>
-NetBSD: <a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-new releases: <a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-<code><nobr>noalloc</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>nobits</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>,
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>noexec</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>.nolist</nobr></code>:
-<a href="nasmdoc4.html#section-4.3.10">Section 4.3.10</a>
-<br>
-`nowait': <a href="nasmdoc2.html#section-2.2.6">Section 2.2.6</a>
-<br>
-<code><nobr>nowrite</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>number-overflow</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-numeric constants: <a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>,
-<a href="nasmdoc3.html#section-3.4.1">Section 3.4.1</a>
-<br>
-<code><nobr>-O</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.22">Section 2.1.22</a>
-<br>
-<code><nobr>-o</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.1">Section 2.1.1</a>,
-<a href="nasmdoca.html#section-A.3.1">Section A.3.1</a>
-<br>
-<code><nobr>O16</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>o16</nobr></code>:
-<a href="nasmdo10.html#section-10.3">Section 10.3</a>
-<br>
-<code><nobr>O32</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>o32</nobr></code>:
-<a href="nasmdo10.html#section-10.3">Section 10.3</a>
-<br>
-<code><nobr>O64</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>.OBJ</nobr></code>:
-<a href="nasmdoc8.html#section-8.1">Section 8.1</a>
-<br>
-<code><nobr>obj</nobr></code>:
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-<code><nobr>object</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>,
-<a href="nasmdoc7.html#section-7.13.3">Section 7.13.3</a>
-<br>
-octal: <a href="nasmdoc3.html#section-3.4.1">Section 3.4.1</a>
-<br>
-<code><nobr>OF_DBG</nobr></code>:
-<a href="nasmdoc7.html#section-7.14">Section 7.14</a>
-<br>
-<code><nobr>OF_DEFAULT</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.2">Section 2.1.2</a>
-<br>
-<code><nobr>OFFSET</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.2">Section 2.2.2</a>
-<br>
-OMF: <a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-omitted parameters: <a href="nasmdoc4.html#section-4.3.5">Section 4.3.5</a>
-<br>
-one's complement: <a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-OpenBSD: <a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-operands: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-operand-size prefixes: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-operating system: <a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-operating system, writing:
-<a href="nasmdo10.html#section-10.1">Section 10.1</a>
-<br>
-operators: <a href="nasmdoc3.html#section-3.5">Section 3.5</a>
-<br>
-<code><nobr>ORG</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.1">Section 7.1.1</a>,
-<a href="nasmdoc8.html#section-8.2.1">Section 8.2.1</a>,
-<a href="nasmdoc8.html#section-8.2.2">Section 8.2.2</a>,
-<a href="nasmdo12.html#section-12.1.3">Section 12.1.3</a>
-<br>
-<code><nobr>orphan-labels</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>,
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-OS/2: <a href="nasmdoc7.html#section-7.4">Section 7.4</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>osabi</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.1">Section 7.9.1</a>
-<br>
-other preprocessor directives:
-<a href="nasmdoc4.html#section-4.10">Section 4.10</a>
-<br>
-out of range, jumps:
-<a href="nasmdo12.html#section-12.1.2">Section 12.1.2</a>
-<br>
-output file format: <a href="nasmdoc2.html#section-2.1.2">Section 2.1.2</a>
-<br>
-output formats: <a href="nasmdoc7.html">Chapter 7</a>
-<br>
-<code><nobr>__OUTPUT_FORMAT__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.6">Section 4.11.6</a>
-<br>
-overlapping segments: <a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-<code><nobr>OVERLAY</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-overloading, multi-line macros:
-<a href="nasmdoc4.html#section-4.3.2">Section 4.3.2</a>
-<br>
-overloading, single-line macros:
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1</a>
-<br>
-<code><nobr>-P</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.17">Section 2.1.17</a>
-<br>
-<code><nobr>-p</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.17">Section 2.1.17</a>,
-<a href="nasmdoc4.html#section-4.6.1">Section 4.6.1</a>
-<br>
-paradox: <a href="nasmdoc3.html#section-3.8">Section 3.8</a>
-<br>
-<code><nobr>PASCAL</nobr></code>:
-<a href="nasmdoc8.html#section-8.5.3">Section 8.5.3</a>
-<br>
-Pascal calling convention:
-<a href="nasmdoc8.html#section-8.5.1">Section 8.5.1</a>
-<br>
-<code><nobr>__PASS__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.9">Section 4.11.9</a>
-<br>
-passes, assembly:
-<br>
-<code><nobr>PATH</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>%pathsearch</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>,
-<a href="nasmdoc4.html#section-4.6.2">Section 4.6.2</a>
-<br>
-period: <a href="nasmdoc3.html#section-3.9">Section 3.9</a>
-<br>
-Perl: <a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-perverse: <a href="nasmdoc2.html#section-2.1.16">Section 2.1.16</a>
-<br>
-PharLap: <a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-PIC: <a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-<code><nobr>..plt</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-<code><nobr>PLT</nobr></code> relocations:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>,
-<a href="nasmdoc9.html#section-9.2.4">Section 9.2.4</a>,
-<a href="nasmdoc9.html#section-9.2.5">Section 9.2.5</a>
-<br>
-plt relocations: <a href="nasmdoc9.html#section-9.2.5">Section 9.2.5</a>
-<br>
-<code><nobr>%pop</nobr></code>:
-<a href="nasmdoc4.html#section-4.7">Section 4.7</a>,
-<a href="nasmdoc4.html#section-4.7.1">Section 4.7.1</a>
-<br>
-position-independent code:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-<code><nobr>--postfix</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.27">Section 2.1.27</a>
-<br>
-precedence: <a href="nasmdoc3.html#section-3.5">Section 3.5</a>
-<br>
-pre-defining macros:
-<a href="nasmdoc2.html#section-2.1.18">Section 2.1.18</a>,
-<a href="nasmdoc4.html#section-4.1.1">Section 4.1.1</a>
-<br>
-preferred: <a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-<code><nobr>--prefix</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.27">Section 2.1.27</a>
-<br>
-pre-including files:
-<a href="nasmdoc2.html#section-2.1.17">Section 2.1.17</a>
-<br>
-preprocess-only mode:
-<a href="nasmdoc2.html#section-2.1.20">Section 2.1.20</a>
-<br>
-preprocessor: <a href="nasmdoc2.html#section-2.1.20">Section 2.1.20</a>,
-<a href="nasmdoc2.html#section-2.1.21">Section 2.1.21</a>,
-<a href="nasmdoc3.html#section-3.2.4">Section 3.2.4</a>,
-<a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>,
-<a href="nasmdoc4.html">Chapter 4</a>
-<br>
-preprocessor expressions:
-<a href="nasmdoc2.html#section-2.1.20">Section 2.1.20</a>
-<br>
-preprocessor loops: <a href="nasmdoc4.html#section-4.5">Section 4.5</a>
-<br>
-preprocessor variables:
-<a href="nasmdoc4.html#section-4.1.7">Section 4.1.7</a>
-<br>
-primitive directives: <a href="nasmdoc6.html">Chapter 6</a>
-<br>
-<code><nobr>PRIVATE</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>proc</nobr></code>:
-<a href="nasmdoc7.html#section-7.13.3">Section 7.13.3</a>,
-<a href="nasmdoc8.html#section-8.4.5">Section 8.4.5</a>,
-<a href="nasmdoc9.html#section-9.1.4">Section 9.1.4</a>
-<br>
-procedure linkage table:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>,
-<a href="nasmdoc9.html#section-9.2.4">Section 9.2.4</a>,
-<a href="nasmdoc9.html#section-9.2.5">Section 9.2.5</a>
-<br>
-processor mode: <a href="nasmdoc6.html#section-6.1">Section 6.1</a>
-<br>
-<code><nobr>progbits</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>,
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-program entry point:
-<a href="nasmdoc7.html#section-7.4.6">Section 7.4.6</a>,
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-program origin: <a href="nasmdoc7.html#section-7.1.1">Section 7.1.1</a>
-<br>
-<code><nobr>protected</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-pseudo-instructions: <a href="nasmdoc3.html#section-3.2">Section 3.2</a>
-<br>
-<code><nobr>PUBLIC</nobr></code>:
-<a href="nasmdoc6.html#section-6.6">Section 6.6</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-pure binary: <a href="nasmdoc7.html#section-7.1">Section 7.1</a>
-<br>
-<code><nobr>%push</nobr></code>:
-<a href="nasmdoc4.html#section-4.7">Section 4.7</a>,
-<a href="nasmdoc4.html#section-4.7.1">Section 4.7.1</a>
-<br>
-<code><nobr>__QNaN__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-quick start: <a href="nasmdoc2.html#section-2.2">Section 2.2</a>
-<br>
-<code><nobr>QWORD</nobr></code>:
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>-r</nobr></code>:
-<a href="nasmdoca.html#section-A.3">Section A.3</a>
-<br>
-<code><nobr>rdf</nobr></code>:
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-<code><nobr>rdoff</nobr></code> subdirectory:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>,
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-recursive multi-line macros:
-<a href="nasmdoc4.html#section-4.3.1">Section 4.3.1</a>
-<br>
-redirecting errors:
-<a href="nasmdoc2.html#section-2.1.14">Section 2.1.14</a>
-<br>
-<code><nobr>REL</nobr></code>:
-<a href="nasmdoc3.html#section-3.3">Section 3.3</a>,
-<a href="nasmdoc6.html#section-6.2">Section 6.2</a>
-<br>
-relational operators:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-release candidates: <a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-Relocatable Dynamic Object File Format:
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-relocations, PIC-specific:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-removing contexts: <a href="nasmdoc4.html#section-4.7.1">Section 4.7.1</a>
-<br>
-renaming contexts: <a href="nasmdoc4.html#section-4.7.4">Section 4.7.4</a>
-<br>
-<code><nobr>%rep</nobr></code>:
-<a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>,
-<a href="nasmdoc4.html#section-4.5">Section 4.5</a>
-<br>
-repeating: <a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>,
-<a href="nasmdoc4.html#section-4.5">Section 4.5</a>
-<br>
-<code><nobr>%repl</nobr></code>:
-<a href="nasmdoc4.html#section-4.7.4">Section 4.7.4</a>
-<br>
-reporting bugs: <a href="nasmdo12.html#section-12.2">Section 12.2</a>
-<br>
-<code><nobr>RESB</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.7">Section 2.2.7</a>,
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>RESD</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>RESO</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>RESQ</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>REST</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>RESW</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>RESY</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-<code><nobr>%rmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.3.1">Section 4.3.1</a>
-<br>
-<code><nobr>.rodata</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>%rotate</nobr></code>:
-<a href="nasmdoc4.html#section-4.3.7">Section 4.3.7</a>
-<br>
-rotating macro parameters:
-<a href="nasmdoc4.html#section-4.3.7">Section 4.3.7</a>
-<br>
-<code><nobr>-s</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.15">Section 2.1.15</a>,
-<a href="nasmdoca.html#section-A.3.2">Section A.3.2</a>
-<br>
-searching for include files:
-<a href="nasmdoc4.html#section-4.6.1">Section 4.6.1</a>
-<br>
-<code><nobr>__SECT__</nobr></code>:
-<a href="nasmdoc6.html#section-6.3.1">Section 6.3.1</a>,
-<a href="nasmdoc6.html#section-6.4">Section 6.4</a>
-<br>
-<code><nobr>SECTION</nobr></code>:
-<a href="nasmdoc6.html#section-6.3">Section 6.3</a>
-<br>
-<code><nobr>SECTION</nobr></code>, <code><nobr>elf</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>SECTION</nobr></code>, <code><nobr>win32</nobr></code>
-extensions to: <a href="nasmdoc7.html#section-7.5.1">Section 7.5.1</a>
-<br>
-section alignment, in <code><nobr>bin</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.2">Section 7.1.2</a>
-<br>
-section alignment, in <code><nobr>elf</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-section alignment, in <code><nobr>obj</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-section alignment, in <code><nobr>win32</nobr></code>:
-<a href="nasmdoc7.html#section-7.5.1">Section 7.5.1</a>
-<br>
-section, bin extensions to:
-<a href="nasmdoc7.html#section-7.1.2">Section 7.1.2</a>
-<br>
-<code><nobr>SEG</nobr></code>:
-<a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>,
-<a href="nasmdoc3.html#section-3.6">Section 3.6</a>,
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-<code><nobr>SEGMENT</nobr></code>:
-<a href="nasmdoc6.html#section-6.3">Section 6.3</a>
-<br>
-<code><nobr>SEGMENT</nobr></code>, <code><nobr>elf</nobr></code> extensions
-to: <a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-segment address: <a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>,
-<a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-segment alignment, in <code><nobr>bin</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.2">Section 7.1.2</a>
-<br>
-segment alignment, in <code><nobr>obj</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-segment names, Borland Pascal:
-<a href="nasmdoc8.html#section-8.5.2">Section 8.5.2</a>
-<br>
-segment override: <a href="nasmdoc2.html#section-2.2.4">Section 2.2.4</a>,
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-segments: <a href="nasmdoc3.html#section-3.6">Section 3.6</a>
-<br>
-segments, groups of:
-<a href="nasmdoc7.html#section-7.4.2">Section 7.4.2</a>
-<br>
-separator character:
-<a href="nasmdoc2.html#section-2.1.28">Section 2.1.28</a>
-<br>
-shared libraries: <a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc9.html#section-9.2">Section 9.2</a>
-<br>
-shared library: <a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-<code><nobr>shift</nobr></code> command:
-<a href="nasmdoc4.html#section-4.3.7">Section 4.3.7</a>
-<br>
-SIB byte:
-<br>
-signed division: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-signed modulo: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-single-line macros: <a href="nasmdoc4.html#section-4.1">Section 4.1</a>
-<br>
-size, of symbols: <a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-<code><nobr>smartalign</nobr></code>:
-<a href="nasmdoc5.html#section-5.2">Section 5.2</a>
-<br>
-<code><nobr>__SNaN__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.6">Section 3.4.6</a>
-<br>
-snapshots, daily development:
-<a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-Solaris x86: <a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-<code><nobr>-soname</nobr></code>:
-<a href="nasmdoc9.html#section-9.2.6">Section 9.2.6</a>
-<br>
-sound: <a href="nasmdoc3.html#section-3.2.3">Section 3.2.3</a>
-<br>
-source code: <a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-source-listing file:
-<a href="nasmdoc2.html#section-2.1.3">Section 2.1.3</a>
-<br>
-square brackets: <a href="nasmdoc2.html#section-2.2.2">Section 2.2.2</a>,
-<a href="nasmdoc3.html#section-3.3">Section 3.3</a>
-<br>
-<code><nobr>srec</nobr></code>:
-<a href="nasmdoc7.html#section-7.3">Section 7.3</a>
-<br>
-<code><nobr>STACK</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-stack relative preprocessor directives:
-<a href="nasmdoc4.html#section-4.8">Section 4.8</a>
-<br>
-<code><nobr>%stacksize</nobr></code>:
-<a href="nasmdoc4.html#section-4.8.2">Section 4.8.2</a>
-<br>
-standard macro packages: <a href="nasmdoc5.html">Chapter 5</a>
-<br>
-standard macros: <a href="nasmdoc4.html#section-4.11">Section 4.11</a>
-<br>
-standardized section names:
-<a href="nasmdoc6.html#section-6.3">Section 6.3</a>,
-<a href="nasmdoc7.html#section-7.5.1">Section 7.5.1</a>,
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>,
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>,
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-<code><nobr>..start</nobr></code>:
-<a href="nasmdoc7.html#section-7.4.6">Section 7.4.6</a>,
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>start=</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>
-<br>
-<code><nobr>stderr</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.14">Section 2.1.14</a>
-<br>
-<code><nobr>stdout</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.15">Section 2.1.15</a>
-<br>
-<code><nobr>%strcat</nobr></code>:
-<a href="nasmdoc4.html#section-4.2.1">Section 4.2.1</a>
-<br>
-<code><nobr>STRICT</nobr></code>:
-<a href="nasmdoc3.html#section-3.7">Section 3.7</a>
-<br>
-string constant: <a href="nasmdoc3.html#section-3.2.1">Section 3.2.1</a>
-<br>
-string constants: <a href="nasmdoc3.html#section-3.4.4">Section 3.4.4</a>
-<br>
-string length: <a href="nasmdoc4.html#section-4.2.2">Section 4.2.2</a>
-<br>
-string manipulation in macros:
-<a href="nasmdoc4.html#section-4.2">Section 4.2</a>
-<br>
-strings: <a href="nasmdoc3.html#section-3.4.2">Section 3.4.2</a>
-<br>
-<code><nobr>%strlen</nobr></code>:
-<a href="nasmdoc4.html#section-4.2.2">Section 4.2.2</a>
-<br>
-<code><nobr>STRUC</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.10">Section 4.11.10</a>,
-<a href="nasmdoc6.html#section-6.4">Section 6.4</a>,
-<a href="nasmdoc8.html#section-8.4.4">Section 8.4.4</a>,
-<a href="nasmdoc9.html#section-9.1.3">Section 9.1.3</a>
-<br>
-stub preprocessor:
-<a href="nasmdoc2.html#section-2.1.21">Section 2.1.21</a>
-<br>
-<code><nobr>%substr</nobr></code>:
-<a href="nasmdoc4.html#section-4.2.3">Section 4.2.3</a>
-<br>
-subtraction: <a href="nasmdoc3.html#section-3.5.5">Section 3.5.5</a>
-<br>
-suppressible warning:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-suppressing preprocessing:
-<a href="nasmdoc2.html#section-2.1.21">Section 2.1.21</a>
-<br>
-switching between sections:
-<a href="nasmdoc6.html#section-6.3">Section 6.3</a>
-<br>
-<code><nobr>..sym</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>
-<br>
-symbol sizes, specifying:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-symbol types, specifying:
-<a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-symbols, exporting from DLLs:
-<a href="nasmdoc7.html#section-7.4.5">Section 7.4.5</a>
-<br>
-symbols, importing from DLLs:
-<a href="nasmdoc7.html#section-7.4.4">Section 7.4.4</a>
-<br>
-<code><nobr>synchronisation</nobr></code>:
-<a href="nasmdoca.html#section-A.3.2">Section A.3.2</a>
-<br>
-<code><nobr>.SYS</nobr></code>:
-<a href="nasmdoc7.html#section-7.1">Section 7.1</a>,
-<a href="nasmdoc8.html#section-8.3">Section 8.3</a>
-<br>
-<code><nobr>-t</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.23">Section 2.1.23</a>
-<br>
-<code><nobr>TASM</nobr></code>:
-<a href="nasmdoc1.html#section-1.1.1">Section 1.1.1</a>,
-<a href="nasmdoc2.html#section-2.1.23">Section 2.1.23</a>
-<br>
-tasm: <a href="nasmdoc2.html#section-2.2">Section 2.2</a>,
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>
-<br>
-<code><nobr>.tbss</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>TBYTE</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.7">Section 2.2.7</a>
-<br>
-<code><nobr>.tdata</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-<code><nobr>test</nobr></code> subdirectory:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-testing, arbitrary numeric expressions:
-<a href="nasmdoc4.html#section-4.4.4">Section 4.4.4</a>
-<br>
-testing, context stack:
-<a href="nasmdoc4.html#section-4.4.3">Section 4.4.3</a>
-<br>
-testing, exact text identity:
-<a href="nasmdoc4.html#section-4.4.5">Section 4.4.5</a>
-<br>
-testing, multi-line macro existence:
-<a href="nasmdoc4.html#section-4.4.2">Section 4.4.2</a>
-<br>
-testing, single-line macro existence:
-<a href="nasmdoc4.html#section-4.4.1">Section 4.4.1</a>
-<br>
-testing, token types:
-<a href="nasmdoc4.html#section-4.4.6">Section 4.4.6</a>
-<br>
-<code><nobr>.text</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>,
-<a href="nasmdoc7.html#section-7.10">Section 7.10</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>,
-<a href="nasmdoc7.html#section-7.12">Section 7.12</a>,
-<a href="nasmdoc7.html#section-7.13">Section 7.13</a>
-<br>
-<code><nobr>_TEXT</nobr></code>:
-<a href="nasmdoc8.html#section-8.4.2">Section 8.4.2</a>
-<br>
-thread local storage:
-<a href="nasmdoc7.html#section-7.9.4">Section 7.9.4</a>
-<br>
-<code><nobr>__TIME__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>__TIME_NUM__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>TIMES</nobr></code>:
-<a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>,
-<a href="nasmdoc3.html#section-3.8">Section 3.8</a>,
-<a href="nasmdo12.html#section-12.1.3">Section 12.1.3</a>,
-<a href="nasmdo12.html#section-12.1.4">Section 12.1.4</a>
-<br>
-<code><nobr>TLINK</nobr></code>:
-<a href="nasmdoc8.html#section-8.2.2">Section 8.2.2</a>
-<br>
-<code><nobr>tls</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>,
-<a href="nasmdoc7.html#section-7.9.4">Section 7.9.4</a>
-<br>
-<code><nobr>..tlsie</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.4">Section 7.9.4</a>
-<br>
-trailing colon: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-<code><nobr>TWORD</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.7">Section 2.2.7</a>,
-<a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-type, of symbols: <a href="nasmdoc7.html#section-7.9.5">Section 7.9.5</a>
-<br>
-<code><nobr>-U</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.19">Section 2.1.19</a>
-<br>
-<code><nobr>-u</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.19">Section 2.1.19</a>,
-<a href="nasmdoca.html#section-A.3">Section A.3</a>
-<br>
-unary operators: <a href="nasmdoc3.html#section-3.5.7">Section 3.5.7</a>
-<br>
-<code><nobr>%undef</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.19">Section 2.1.19</a>,
-<a href="nasmdoc4.html#section-4.1.6">Section 4.1.6</a>
-<br>
-undefining macros:
-<a href="nasmdoc2.html#section-2.1.19">Section 2.1.19</a>
-<br>
-underscore, in C symbols:
-<a href="nasmdoc8.html#section-8.4.1">Section 8.4.1</a>
-<br>
-Unicode: <a href="nasmdoc3.html#section-3.4.2">Section 3.4.2</a>,
-<a href="nasmdoc3.html#section-3.4.5">Section 3.4.5</a>
-<br>
-uninitialized: <a href="nasmdoc3.html#section-3.2">Section 3.2</a>,
-<a href="nasmdoc3.html#section-3.2.2">Section 3.2.2</a>
-<br>
-uninitialized storage:
-<a href="nasmdoc2.html#section-2.2.7">Section 2.2.7</a>
-<br>
-Unix: <a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-Unix, SCO: <a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-Unix, source archive:
-<a href="nasmdoc1.html#section-1.3.2">Section 1.3.2</a>
-<br>
-Unix, System V: <a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-UnixWare: <a href="nasmdoc7.html#section-7.9">Section 7.9</a>
-<br>
-<code><nobr>%unmacro</nobr></code>:
-<a href="nasmdoc4.html#section-4.3.11">Section 4.3.11</a>
-<br>
-unrolled loops: <a href="nasmdoc3.html#section-3.2.5">Section 3.2.5</a>
-<br>
-unsigned division: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-unsigned modulo: <a href="nasmdoc3.html#section-3.5.6">Section 3.5.6</a>
-<br>
-<code><nobr>UPPERCASE</nobr></code>:
-<a href="nasmdoc2.html#section-2.2.1">Section 2.2.1</a>,
-<a href="nasmdoc7.html#section-7.4.3">Section 7.4.3</a>
-<br>
-<code><nobr>%use</nobr></code>:
-<a href="nasmdoc4.html#section-4.6.4">Section 4.6.4</a>,
-<a href="nasmdoc5.html">Chapter 5</a>
-<br>
-<code><nobr>__USE_*__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.8">Section 4.11.8</a>
-<br>
-<code><nobr>USE16</nobr></code>:
-<a href="nasmdoc6.html#section-6.1.1">Section 6.1.1</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>USE32</nobr></code>:
-<a href="nasmdoc6.html#section-6.1.1">Section 6.1.1</a>,
-<a href="nasmdoc7.html#section-7.4.1">Section 7.4.1</a>
-<br>
-<code><nobr>user</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-user-defined errors: <a href="nasmdoc4.html#section-4.9">Section 4.9</a>
-<br>
-user-level assembler directives:
-<a href="nasmdoc4.html#section-4.11">Section 4.11</a>
-<br>
-user-level directives: <a href="nasmdoc6.html">Chapter 6</a>
-<br>
-<code><nobr>__UTC_DATE__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>__UTC_DATE_NUM__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>__UTC_TIME__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-<code><nobr>__UTC_TIME_NUM__</nobr></code>:
-<a href="nasmdoc4.html#section-4.11.7">Section 4.11.7</a>
-<br>
-UTF-16: <a href="nasmdoc3.html#section-3.4.5">Section 3.4.5</a>
-<br>
-UTF-32: <a href="nasmdoc3.html#section-3.4.5">Section 3.4.5</a>
-<br>
-UTF-8: <a href="nasmdoc3.html#section-3.4.2">Section 3.4.2</a>
-<br>
-<code><nobr>__utf16__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.5">Section 3.4.5</a>
-<br>
-<code><nobr>__utf32__</nobr></code>:
-<a href="nasmdoc3.html#section-3.4.5">Section 3.4.5</a>
-<br>
-<code><nobr>-v</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.25">Section 2.1.25</a>
-<br>
-VAL: <a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-valid characters: <a href="nasmdoc3.html#section-3.1">Section 3.1</a>
-<br>
-variable types: <a href="nasmdoc2.html#section-2.2.3">Section 2.2.3</a>
-<br>
-version: <a href="nasmdoc2.html#section-2.1.25">Section 2.1.25</a>
-<br>
-version number of NASM:
-<a href="nasmdoc4.html#section-4.11.1">Section 4.11.1</a>
-<br>
-<code><nobr>vfollows=</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>
-<br>
-Visual C++: <a href="nasmdoc7.html#section-7.5">Section 7.5</a>
-<br>
-<code><nobr>vstart=</nobr></code>:
-<a href="nasmdoc7.html#section-7.1.3">Section 7.1.3</a>
-<br>
-<code><nobr>-W</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>-w</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>%warning</nobr></code>:
-<a href="nasmdoc4.html#section-4.9">Section 4.9</a>
-<br>
-warnings: <a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>[warning *warning-name]</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>[warning +warning-name]</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-<code><nobr>[warning -warning-name]</nobr></code>:
-<a href="nasmdoc2.html#section-2.1.24">Section 2.1.24</a>
-<br>
-website: <a href="nasmdoc1.html#section-1.2">Section 1.2</a>
-<br>
-<code><nobr>win64</nobr></code>:
-<a href="nasmdoc7.html#section-7.6">Section 7.6</a>,
-<a href="nasmdo11.html">Chapter 11</a>
-<br>
-Win64: <a href="nasmdoc7.html#section-7.4">Section 7.4</a>,
-<a href="nasmdoc7.html#section-7.5">Section 7.5</a>,
-<a href="nasmdoc9.html">Chapter 9</a>
-<br>
-Windows: <a href="nasmdoc8.html#section-8.1">Section 8.1</a>
-<br>
-Windows 95:
-<br>
-Windows NT:
-<br>
-<code><nobr>write</nobr></code>:
-<a href="nasmdoc7.html#section-7.9.2">Section 7.9.2</a>
-<br>
-writing operating systems:
-<a href="nasmdo10.html#section-10.1">Section 10.1</a>
-<br>
-<code><nobr>WRT</nobr></code>:
-<a href="nasmdoc3.html#section-3.6">Section 3.6</a>,
-<a href="nasmdoc7.html#section-7.4">Section 7.4</a>,
-<a href="nasmdoc7.html#section-7.9.3">Section 7.9.3</a>,
-<a href="nasmdoc7.html#section-7.9.4">Section 7.9.4</a>,
-<a href="nasmdoc7.html#section-7.11">Section 7.11</a>
-<br>
-<code><nobr>WRT ..got</nobr></code>:
-<a href="nasmdoc9.html#section-9.2.3">Section 9.2.3</a>
-<br>
-<code><nobr>WRT ..gotoff</nobr></code>:
-<a href="nasmdoc9.html#section-9.2.2">Section 9.2.2</a>
-<br>
-<code><nobr>WRT ..gotpc</nobr></code>:
-<a href="nasmdoc9.html#section-9.2.1">Section 9.2.1</a>
-<br>
-<code><nobr>WRT ..plt</nobr></code>:
-<a href="nasmdoc9.html#section-9.2.5">Section 9.2.5</a>
-<br>
-<code><nobr>WRT ..sym</nobr></code>:
-<a href="nasmdoc9.html#section-9.2.4">Section 9.2.4</a>
-<br>
-WWW page:
-<br>
-<code><nobr>www.cpan.org</nobr></code>:
-<a href="nasmdoc1.html#section-1.3.1">Section 1.3.1</a>
-<br>
-<code><nobr>www.delorie.com</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>www.pcorner.com</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>-X</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.13">Section 2.1.13</a>
-<br>
-<code><nobr>x2ftp.oulu.fi</nobr></code>:
-<a href="nasmdoc8.html#section-8.1.1">Section 8.1.1</a>
-<br>
-<code><nobr>%xdefine</nobr></code>:
-<a href="nasmdoc4.html#section-4.1.2">Section 4.1.2</a>
-<br>
-<code><nobr>-y</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.26">Section 2.1.26</a>
-<br>
-<code><nobr>-Z</nobr></code> option:
-<a href="nasmdoc2.html#section-2.1.14">Section 2.1.14</a>
-<br>
-<p align=center><a href="nasmdoc0.html">Contents</a>
-</body></html>
diff --git a/doc/info/nasm.info b/doc/info/nasm.info
deleted file mode 100644
index 64ae230..0000000
--- a/doc/info/nasm.info
+++ /dev/null
@@ -1,398 +0,0 @@
-This is nasm.info, produced by makeinfo version 4.13 from nasmdoc.texi.
-
-INFO-DIR-SECTION Programming
-START-INFO-DIR-ENTRY
-* NASM: (nasm). The Netwide Assembler for x86.
-END-INFO-DIR-ENTRY
-
- This file documents NASM, the Netwide Assembler: an assembler
-targetting the Intel x86 series of processors, with portable source.
-
- Copyright 1996-2009 The NASM Development Team
-
- This document is redistributable under the license given in the file
-"COPYING" distributed in the NASM archive.
-
-
-Indirect:
-nasm.info-1: 506
-nasm.info-2: 299030
-nasm.info-3: 597272
-
-Tag Table:
-(Indirect)
-Node: Top506
-Node: Chapter 11340
-Node: Section 1.11573
-Node: Section 1.1.12288
-Node: Section 1.1.24165
-Node: Section 1.25885
-Node: Section 1.36714
-Node: Section 1.3.16961
-Node: Section 1.3.28939
-Node: Chapter 210269
-Node: Section 2.110501
-Node: Section 2.1.113922
-Node: Section 2.1.215572
-Node: Section 2.1.316326
-Node: Section 2.1.417278
-Node: Section 2.1.517670
-Node: Section 2.1.618127
-Node: Section 2.1.718501
-Node: Section 2.1.819097
-Node: Section 2.1.919462
-Node: Section 2.1.1019895
-Node: Section 2.1.1120315
-Node: Section 2.1.1221351
-Node: Section 2.1.1321902
-Node: Section 2.1.1423151
-Node: Section 2.1.1524104
-Node: Section 2.1.1624609
-Node: Section 2.1.1726221
-Node: Section 2.1.1826794
-Node: Section 2.1.1927652
-Node: Section 2.1.2028346
-Node: Section 2.1.2129324
-Node: Section 2.1.2229870
-Node: Section 2.1.2331394
-Node: Section 2.1.2432358
-Node: Section 2.1.2535726
-Node: Section 2.1.2636094
-Node: Section 2.1.2736730
-Node: Section 2.1.2837190
-Node: Section 2.238528
-Node: Section 2.2.139321
-Node: Section 2.2.239931
-Node: Section 2.2.342292
-Node: Section 2.2.443155
-Node: Section 2.2.543559
-Node: Section 2.2.644319
-Node: Section 2.2.744947
-Node: Chapter 345799
-Node: Section 3.146276
-Node: Section 3.250446
-Node: Section 3.2.151310
-Node: Section 3.2.252567
-Node: Section 3.2.353598
-Node: Section 3.2.454561
-Node: Section 3.2.555471
-Node: Section 3.356970
-Node: Section 3.460459
-Node: Section 3.4.160957
-Node: Section 3.4.262817
-Node: Section 3.4.364681
-Node: Section 3.4.465383
-Node: Section 3.4.566694
-Node: Section 3.4.667390
-Node: Section 3.4.771120
-Node: Section 3.571682
-Node: Section 3.5.172876
-Node: Section 3.5.273207
-Node: Section 3.5.373418
-Node: Section 3.5.473629
-Node: Section 3.5.574128
-Node: Section 3.5.674417
-Node: Section 3.5.775167
-Node: Section 3.675754
-Node: Section 3.777833
-Node: Section 3.878736
-Node: Section 3.980161
-Node: Chapter 482743
-Node: Section 4.183935
-Node: Section 4.1.184549
-Node: Section 4.1.287390
-Node: Section 4.1.388934
-Node: Section 4.1.489843
-Node: Section 4.1.591349
-Node: Section 4.1.692319
-Node: Section 4.1.792959
-Node: Section 4.1.894230
-Node: Section 4.1.994874
-Node: Section 4.295336
-Node: Section 4.2.196105
-Node: Section 4.2.296681
-Node: Section 4.2.397368
-Node: Section 4.398741
-Node: Section 4.3.1100959
-Node: Section 4.3.2101752
-Node: Section 4.3.3103123
-Node: Section 4.3.4104286
-Node: Section 4.3.5106612
-Node: Section 4.3.6109310
-Node: Section 4.3.7109896
-Node: Section 4.3.8112639
-Node: Section 4.3.9114996
-Node: Section 4.3.10116387
-Node: Section 4.3.11117234
-Node: Section 4.3.12117992
-Node: Section 4.4118457
-Node: Section 4.4.1119961
-Node: Section 4.4.2121062
-Node: Section 4.4.3122377
-Node: Section 4.4.4123000
-Node: Section 4.4.5124560
-Node: Section 4.4.6125561
-Node: Section 4.4.7127864
-Node: Section 4.4.8128682
-Node: Section 4.5129130
-Node: Section 4.6130826
-Node: Section 4.6.1131288
-Node: Section 4.6.2132695
-Node: Section 4.6.3133293
-Node: Section 4.6.4134133
-Node: Section 4.7135063
-Node: Section 4.7.1136233
-Node: Section 4.7.2137224
-Node: Section 4.7.3138261
-Node: Section 4.7.4138778
-Node: Section 4.7.5139538
-Node: Section 4.8142039
-Node: Section 4.8.1142600
-Node: Section 4.8.2143809
-Node: Section 4.8.3145438
-Node: Section 4.9147193
-Node: Section 4.10149062
-Node: Section 4.10.1149732
-Node: Section 4.10.2151046
-Node: Section 4.11151773
-Node: Section 4.11.1153179
-Node: Section 4.11.2153878
-Node: Section 4.11.3154703
-Node: Section 4.11.4155133
-Node: Section 4.11.5156498
-Node: Section 4.11.6157004
-Node: Section 4.11.7157505
-Node: Section 4.11.8159693
-Node: Section 4.11.9160294
-Node: Section 4.11.10160911
-Node: Section 4.11.11163932
-Node: Section 4.11.12165536
-Node: Chapter 5168133
-Node: Section 5.1168785
-Node: Section 5.2169475
-Node: Chapter 6171420
-Node: Section 6.1173000
-Node: Section 6.1.1175976
-Node: Section 6.2176296
-Node: Section 6.3177453
-Node: Section 6.3.1178524
-Node: Section 6.4180364
-Node: Section 6.5182293
-Node: Section 6.6183787
-Node: Section 6.7184971
-Node: Section 6.8186170
-Node: Section 6.9187418
-Node: Chapter 7188427
-Node: Section 7.1190123
-Node: Section 7.1.1191429
-Node: Section 7.1.2192457
-Node: Section 7.1.3193198
-Node: Section 7.1.4194959
-Node: Section 7.2195436
-Node: Section 7.3195980
-Node: Section 7.4196548
-Node: Section 7.4.1199011
-Node: Section 7.4.2201987
-Node: Section 7.4.3203656
-Node: Section 7.4.4204379
-Node: Section 7.4.5205355
-Node: Section 7.4.6207319
-Node: Section 7.4.7207871
-Node: Section 7.4.8209425
-Node: Section 7.5211274
-Node: Section 7.5.1212425
-Node: Section 7.5.2214883
-Node: Section 7.6219189
-Node: Section 7.6.1219880
-Node: Section 7.6.2222750
-Node: Section 7.7231628
-Node: Section 7.8232143
-Node: Section 7.9232570
-Node: Section 7.9.1233574
-Node: Section 7.9.2234090
-Node: Section 7.9.3236574
-Node: Section 7.9.4239580
-Node: Section 7.9.5240492
-Node: Section 7.9.6242295
-Node: Section 7.9.7242944
-Node: Section 7.9.8243460
-Node: Section 7.10243838
-Node: Section 7.11244741
-Node: Section 7.12245917
-Node: Section 7.13246833
-Node: Section 7.13.1248187
-Node: Section 7.13.2248663
-Node: Section 7.13.3249368
-Node: Section 7.13.4250315
-Node: Section 7.14251192
-Node: Chapter 8253473
-Node: Section 8.1254227
-Node: Section 8.1.1255319
-Node: Section 8.1.2258921
-Node: Section 8.2261299
-Node: Section 8.2.1261805
-Node: Section 8.2.2263314
-Node: Section 8.3264893
-Node: Section 8.4265899
-Node: Section 8.4.1266570
-Node: Section 8.4.2268084
-Node: Section 8.4.3271540
-Node: Section 8.4.4278288
-Node: Section 8.4.5280465
-Node: Section 8.5283090
-Node: Section 8.5.1284827
-Node: Section 8.5.2289081
-Node: Section 8.5.3290107
-Node: Chapter 9291435
-Node: Section 9.1292896
-Node: Section 9.1.1293491
-Node: Section 9.1.2294359
-Node: Section 9.1.3299030
-Node: Section 9.1.4301283
-Node: Section 9.2302862
-Node: Section 9.2.1305149
-Node: Section 9.2.2307928
-Node: Section 9.2.3309212
-Node: Section 9.2.4310327
-Node: Section 9.2.5312918
-Node: Section 9.2.6313825
-Node: Chapter 10314685
-Node: Section 10.1315390
-Node: Section 10.2317375
-Node: Section 10.3319959
-Node: Chapter 11322252
-Node: Section 11.1324207
-Node: Section 11.2325177
-Node: Section 11.3327200
-Node: Section 11.4328551
-Node: Chapter 12329634
-Node: Section 12.1330070
-Node: Section 12.1.1330398
-Node: Section 12.1.2331166
-Node: Section 12.1.3332323
-Node: Section 12.1.4333493
-Node: Section 12.2334851
-Node: Appendix A339510
-Node: Section A.1339830
-Node: Section A.2340543
-Node: Section A.3340876
-Node: Section A.3.1341789
-Node: Section A.3.2342678
-Node: Section A.3.3344784
-Node: Section A.3.4347578
-Node: Section A.4348326
-Node: Appendix B348762
-Node: Section B.1348948
-Node: Section B.1.1351150
-Node: Section B.1.2351483
-Node: Section B.1.3424168
-Node: Section B.1.4429304
-Node: Section B.1.5429647
-Node: Section B.1.6430065
-Node: Section B.1.7430506
-Node: Section B.1.8431638
-Node: Section B.1.9432131
-Node: Section B.1.10432831
-Node: Section B.1.11439728
-Node: Section B.1.12445350
-Node: Section B.1.13446171
-Node: Section B.1.14447189
-Node: Section B.1.15447629
-Node: Section B.1.16449575
-Node: Section B.1.17450064
-Node: Section B.1.18450411
-Node: Section B.1.19453720
-Node: Section B.1.20454625
-Node: Section B.1.21454823
-Node: Section B.1.22455137
-Node: Section B.1.23455651
-Node: Section B.1.24456181
-Node: Section B.1.25456737
-Node: Section B.1.26497504
-Node: Section B.1.27498034
-Node: Section B.1.28498591
-Node: Section B.1.29509939
-Node: Section B.1.30510657
-Node: Section B.1.31511523
-Node: Section B.1.32520363
-Node: Appendix C531399
-Node: Section C.1531662
-Node: Section C.1.1532242
-Node: Section C.1.2533796
-Node: Section C.1.3535031
-Node: Section C.1.4536766
-Node: Section C.1.5536987
-Node: Section C.1.6537982
-Node: Section C.1.7540282
-Node: Section C.1.8540651
-Node: Section C.1.9542095
-Node: Section C.1.10543237
-Node: Section C.1.11543839
-Node: Section C.2545564
-Node: Section C.2.1547911
-Node: Section C.2.2548336
-Node: Section C.2.3549349
-Node: Section C.2.4550042
-Node: Section C.2.5550581
-Node: Section C.2.6551111
-Node: Section C.2.7551952
-Node: Section C.2.8552881
-Node: Section C.2.9553540
-Node: Section C.2.10554127
-Node: Section C.2.11554863
-Node: Section C.2.12555186
-Node: Section C.2.13555393
-Node: Section C.2.14555706
-Node: Section C.2.15555953
-Node: Section C.2.16556156
-Node: Section C.2.17556364
-Node: Section C.2.18556621
-Node: Section C.2.19556820
-Node: Section C.2.20557001
-Node: Section C.2.21557182
-Node: Section C.2.22557370
-Node: Section C.2.23557561
-Node: Section C.2.24557771
-Node: Section C.2.25557974
-Node: Section C.2.26558187
-Node: Section C.2.27558366
-Node: Section C.2.28558548
-Node: Section C.2.29558792
-Node: Section C.2.30558996
-Node: Section C.2.31559178
-Node: Section C.2.32559842
-Node: Section C.2.33560152
-Node: Section C.2.34561495
-Node: Section C.2.35561944
-Node: Section C.2.36562245
-Node: Section C.2.37563300
-Node: Section C.2.38563537
-Node: Section C.2.39563868
-Node: Section C.2.40565946
-Node: Section C.2.41573822
-Node: Section C.2.42574310
-Node: Section C.2.43575038
-Node: Section C.2.44575971
-Node: Section C.2.45577069
-Node: Section C.2.46578569
-Node: Section C.2.47578863
-Node: Section C.2.48579191
-Node: Section C.2.49580498
-Node: Section C.2.50580915
-Node: Section C.2.51581846
-Node: Section C.2.52582760
-Node: Section C.2.53583882
-Node: Section C.2.54584288
-Node: Section C.2.55584619
-Node: Section C.3587873
-Node: Section C.3.1588473
-Node: Section C.3.2590132
-Node: Section C.3.3597272
-Node: Section C.3.4601832
-Node: Section C.3.5603782
-Node: Section C.3.6604873
-Node: Section C.3.7606084
-Node: Section C.3.8607145
-Node: Index607442
-
-End Tag Table
diff --git a/doc/info/nasm.info-1 b/doc/info/nasm.info-1
deleted file mode 100644
index d1896f8..0000000
--- a/doc/info/nasm.info-1
+++ /dev/null
@@ -1,7484 +0,0 @@
-This is nasm.info, produced by makeinfo version 4.13 from nasmdoc.texi.
-
-INFO-DIR-SECTION Programming
-START-INFO-DIR-ENTRY
-* NASM: (nasm). The Netwide Assembler for x86.
-END-INFO-DIR-ENTRY
-
- This file documents NASM, the Netwide Assembler: an assembler
-targetting the Intel x86 series of processors, with portable source.
-
- Copyright 1996-2009 The NASM Development Team
-
- This document is redistributable under the license given in the file
-"COPYING" distributed in the NASM archive.
-
-
-File: nasm.info, Node: Top, Next: Chapter 1, Prev: (dir), Up: (dir)
-
-The Netwide Assembler for x86
-*****************************
-
-This file documents NASM, the Netwide Assembler: an assembler
-targetting the Intel x86 series of processors, with portable source.
-
-* Menu:
-
-* Chapter 1:: Introduction
-* Chapter 2:: Running NASM
-* Chapter 3:: The NASM Language
-* Chapter 4:: The NASM Preprocessor
-* Chapter 5:: Standard Macro Packages
-* Chapter 6:: Assembler Directives
-* Chapter 7:: Output Formats
-* Chapter 8:: Writing 16-bit Code (DOS, Windows 3/3.1)
-* Chapter 9:: Writing 32-bit Code (Unix, Win32, DJGPP)
-* Chapter 10:: Mixing 16 and 32 Bit Code
-* Chapter 11:: Writing 64-bit Code (Unix, Win64)
-* Chapter 12:: Troubleshooting
-* Appendix A:: Ndisasm
-* Appendix B:: Instruction List
-* Appendix C:: NASM Version History
-* Index::
-
-
-File: nasm.info, Node: Chapter 1, Next: Section 1.1, Prev: Top, Up: Top
-
-Chapter 1: Introduction
-***********************
-
-* Menu:
-
-* Section 1.1:: What Is NASM?
-* Section 1.2:: Contact Information
-* Section 1.3:: Installation
-
-
-File: nasm.info, Node: Section 1.1, Next: Section 1.1.1, Prev: Chapter 1, Up: Chapter 1
-
-1.1. What Is NASM?
-==================
-
-The Netwide Assembler, NASM, is an 80x86 and x86-64 assembler designed
-for portability and modularity. It supports a range of object file
-formats, including Linux and `*BSD' `a.out', `ELF', `COFF', `Mach-O',
-Microsoft 16-bit `OBJ', `Win32' and `Win64'. It will also output plain
-binary files. Its syntax is designed to be simple and easy to
-understand, similar to Intel's but less complex. It supports all
-currently known x86 architectural extensions, and has strong support
-for macros.
-
-* Menu:
-
-* Section 1.1.1:: Why Yet Another Assembler?
-* Section 1.1.2:: License Conditions
-
-
-File: nasm.info, Node: Section 1.1.1, Next: Section 1.1.2, Prev: Section 1.1, Up: Section 1.1
-
-1.1.1. Why Yet Another Assembler?
----------------------------------
-
-The Netwide Assembler grew out of an idea on `comp.lang.asm.x86' (or
-possibly `alt.lang.asm' - I forget which), which was essentially that
-there didn't seem to be a good _free_ x86-series assembler around, and
-that maybe someone ought to write one.
-
- * `a86' is good, but not free, and in particular you don't get any
- 32- bit capability until you pay. It's DOS only, too.
-
- * `gas' is free, and ports over to DOS and Unix, but it's not very
- good, since it's designed to be a back end to `gcc', which always
- feeds it correct code. So its error checking is minimal. Also, its
- syntax is horrible, from the point of view of anyone trying to
- actually _write_ anything in it. Plus you can't write 16-bit code
- in it (properly.)
-
- * `as86' is specific to Minix and Linux, and (my version at least)
- doesn't seem to have much (or any) documentation.
-
- * `MASM' isn't very good, and it's (was) expensive, and it runs only
- under DOS.
-
- * `TASM' is better, but still strives for MASM compatibility, which
- means millions of directives and tons of red tape. And its syntax
- is essentially MASM's, with the contradictions and quirks that
- entails (although it sorts out some of those by means of Ideal
- mode.) It's expensive too. And it's DOS-only.
-
- So here, for your coding pleasure, is NASM. At present it's still in
-prototype stage - we don't promise that it can outperform any of these
-assemblers. But please, _please_ send us bug reports, fixes, helpful
-information, and anything else you can get your hands on (and thanks to
-the many people who've done this already! You all know who you are),
-and we'll improve it out of all recognition. Again.
-
-
-File: nasm.info, Node: Section 1.1.2, Next: Section 1.2, Prev: Section 1.1.1, Up: Section 1.1
-
-1.1.2. License Conditions
--------------------------
-
-Please see the file `LICENSE', supplied as part of any NASM
-distribution archive, for the license conditions under which you may use
-NASM. NASM is now under the so-called 2-clause BSD license, also known
-as the simplified BSD license.
-
- Copyright 1996-2009 the NASM Authors - All rights reserved.
-
- Redistribution and use in source and binary forms, with or without
-modification, are permitted provided that the following conditions are
-met:
-
- * Redistributions of source code must retain the above copyright
- notice, this list of conditions and the following disclaimer.
-
- * Redistributions in binary form must reproduce the above copyright
- notice, this list of conditions and the following disclaimer in
- the documentation and/or other materials provided with the
- distribution.
-
- THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
-"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
-LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
-LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
-DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
-THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
-(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
-OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-
-
-File: nasm.info, Node: Section 1.2, Next: Section 1.3, Prev: Section 1.1.2, Up: Chapter 1
-
-1.2. Contact Information
-========================
-
-The current version of NASM (since about 0.98.08) is maintained by a
-team of developers, accessible through the `nasm-devel' mailing list
-(see below for the link). If you want to report a bug, please read
-*note Section 12.2:: first.
-
- NASM has a website at `http://www.nasm.us/'. If it's not there,
-google for us!
-
- New releases, release candidates, and daily development snapshots of
-NASM are available from the official web site.
-
- Announcements are posted to `comp.lang.asm.x86', and to the web site
-`http://www.freshmeat.net/'.
-
- If you want information about the current development status, please
-subscribe to the `nasm-devel' email list; see link from the website.
-
-
-File: nasm.info, Node: Section 1.3, Next: Section 1.3.1, Prev: Section 1.2, Up: Chapter 1
-
-1.3. Installation
-=================
-
-* Menu:
-
-* Section 1.3.1:: Installing NASM under MS-DOS or Windows
-* Section 1.3.2:: Installing NASM under Unix
-
-
-File: nasm.info, Node: Section 1.3.1, Next: Section 1.3.2, Prev: Section 1.3, Up: Section 1.3
-
-1.3.1. Installing NASM under MS-DOS or Windows
-----------------------------------------------
-
-Once you've obtained the appropriate archive for NASM,
-`nasm-XXX-dos.zip' or `nasm-XXX-win32.zip' (where `XXX' denotes the
-version number of NASM contained in the archive), unpack it into its
-own directory (for example `c:\nasm').
-
- The archive will contain a set of executable files: the NASM
-executable file `nasm.exe', the NDISASM executable file `ndisasm.exe',
-and possibly additional utilities to handle the RDOFF file format.
-
- The only file NASM needs to run is its own executable, so copy
-`nasm.exe' to a directory on your PATH, or alternatively edit
-`autoexec.bat' to add the `nasm' directory to your `PATH' (to do that
-under Windows XP, go to Start > Control Panel > System > Advanced >
-Environment Variables; these instructions may work under other versions
-of Windows as well.)
-
- That's it - NASM is installed. You don't need the nasm directory to
-be present to run NASM (unless you've added it to your `PATH'), so you
-can delete it if you need to save space; however, you may want to keep
-the documentation or test programs.
-
- If you've downloaded the DOS source archive, `nasm-XXX.zip', the
-`nasm' directory will also contain the full NASM source code, and a
-selection of Makefiles you can (hopefully) use to rebuild your copy of
-NASM from scratch. See the file `INSTALL' in the source archive.
-
- Note that a number of files are generated from other files by Perl
-scripts. Although the NASM source distribution includes these
-generated files, you will need to rebuild them (and hence, will need a
-Perl interpreter) if you change insns.dat, standard.mac or the
-documentation. It is possible future source distributions may not
-include these files at all. Ports of Perl for a variety of platforms,
-including DOS and Windows, are available from www.cpan.org.
-
-
-File: nasm.info, Node: Section 1.3.2, Next: Chapter 2, Prev: Section 1.3.1, Up: Section 1.3
-
-1.3.2. Installing NASM under Unix
----------------------------------
-
-Once you've obtained the Unix source archive for NASM,
-`nasm-XXX.tar.gz' (where `XXX' denotes the version number of NASM
-contained in the archive), unpack it into a directory such as
-`/usr/local/src'. The archive, when unpacked, will create its own
-subdirectory `nasm-XXX'.
-
- NASM is an auto-configuring package: once you've unpacked it, `cd' to
-the directory it's been unpacked into and type `./configure'. This
-shell script will find the best C compiler to use for building NASM and
-set up Makefiles accordingly.
-
- Once NASM has auto-configured, you can type `make' to build the
-`nasm' and `ndisasm' binaries, and then `make install' to install them
-in `/usr/local/bin' and install the man pages `nasm.1' and `ndisasm.1'
-in `/usr/local/man/man1'. Alternatively, you can give options such as
-`--prefix' to the configure script (see the file `INSTALL' for more
-details), or install the programs yourself.
-
- NASM also comes with a set of utilities for handling the `RDOFF'
-custom object-file format, which are in the `rdoff' subdirectory of the
-NASM archive. You can build these with `make rdf' and install them with
-`make rdf_install', if you want them.
-
-
-File: nasm.info, Node: Chapter 2, Next: Section 2.1, Prev: Section 1.3.2, Up: Top
-
-Chapter 2: Running NASM
-***********************
-
-* Menu:
-
-* Section 2.1:: NASM Command-Line Syntax
-* Section 2.2:: Quick Start for MASM Users
-
-
-File: nasm.info, Node: Section 2.1, Next: Section 2.1.1, Prev: Chapter 2, Up: Chapter 2
-
-2.1. NASM Command-Line Syntax
-=============================
-
-To assemble a file, you issue a command of the form
-
- nasm -f <format> <filename> [-o <output>]
-
- For example,
-
- nasm -f elf myfile.asm
-
- will assemble `myfile.asm' into an `ELF' object file `myfile.o'. And
-
- nasm -f bin myfile.asm -o myfile.com
-
- will assemble `myfile.asm' into a raw binary file `myfile.com'.
-
- To produce a listing file, with the hex codes output from NASM
-displayed on the left of the original sources, use the `-l' option to
-give a listing file name, for example:
-
- nasm -f coff myfile.asm -l myfile.lst
-
- To get further usage instructions from NASM, try typing
-
- nasm -h
-
- As `-hf', this will also list the available output file formats, and
-what they are.
-
- If you use Linux but aren't sure whether your system is `a.out' or
-`ELF', type
-
- file nasm
-
- (in the directory in which you put the NASM binary when you
-installed it). If it says something like
-
- nasm: ELF 32-bit LSB executable i386 (386 and up) Version 1
-
- then your system is `ELF', and you should use the option `-f elf'
-when you want NASM to produce Linux object files. If it says
-
- nasm: Linux/i386 demand-paged executable (QMAGIC)
-
- or something similar, your system is `a.out', and you should use `-f
-aout' instead (Linux `a.out' systems have long been obsolete, and are
-rare these days.)
-
- Like Unix compilers and assemblers, NASM is silent unless it goes
-wrong: you won't see any output at all, unless it gives error messages.
-
-* Menu:
-
-* Section 2.1.1:: The `-o' Option: Specifying the Output File Name
-* Section 2.1.2:: The `-f' Option: Specifying the Output File Format
-* Section 2.1.3:: The `-l' Option: Generating a Listing File
-* Section 2.1.4:: The `-M' Option: Generate Makefile Dependencies
-* Section 2.1.5:: The `-MG' Option: Generate Makefile Dependencies
-* Section 2.1.6:: The `-MF' Option: Set Makefile Dependency File
-* Section 2.1.7:: The `-MD' Option: Assemble and Generate Dependencies
-* Section 2.1.8:: The `-MT' Option: Dependency Target Name
-* Section 2.1.9:: The `-MQ' Option: Dependency Target Name (Quoted)
-* Section 2.1.10:: The `-MP' Option: Emit phony targets
-* Section 2.1.11:: The `-F' Option: Selecting a Debug Information Format
-* Section 2.1.12:: The `-g' Option: Enabling Debug Information.
-* Section 2.1.13:: The `-X' Option: Selecting an Error Reporting Format
-* Section 2.1.14:: The `-Z' Option: Send Errors to a File
-* Section 2.1.15:: The `-s' Option: Send Errors to `stdout'
-* Section 2.1.16:: The `-i' Option: Include File Search Directories
-* Section 2.1.17:: The `-p' Option: Pre-Include a File
-* Section 2.1.18:: The `-d' Option: Pre-Define a Macro
-* Section 2.1.19:: The `-u' Option: Undefine a Macro
-* Section 2.1.20:: The `-E' Option: Preprocess Only
-* Section 2.1.21:: The `-a' Option: Don't Preprocess At All
-* Section 2.1.22:: The `-O' Option: Specifying Multipass Optimization
-* Section 2.1.23:: The `-t' Option: Enable TASM Compatibility Mode
-* Section 2.1.24:: The `-w' and `-W' Options: Enable or Disable Assembly Warnings
-* Section 2.1.25:: The `-v' Option: Display Version Info
-* Section 2.1.26:: The `-y' Option: Display Available Debug Info Formats
-* Section 2.1.27:: The `--prefix' and `--postfix' Options.
-* Section 2.1.28:: The `NASMENV' Environment Variable
-
-
-File: nasm.info, Node: Section 2.1.1, Next: Section 2.1.2, Prev: Section 2.1, Up: Section 2.1
-
-2.1.1. The `-o' Option: Specifying the Output File Name
--------------------------------------------------------
-
-NASM will normally choose the name of your output file for you;
-precisely how it does this is dependent on the object file format. For
-Microsoft object file formats (`obj', `win32' and `win64'), it will
-remove the `.asm' extension (or whatever extension you like to use -
-NASM doesn't care) from your source file name and substitute `.obj'.
-For Unix object file formats (`aout', `as86', `coff', `elf32', `elf64',
-`ieee', `macho32' and `macho64') it will substitute `.o'. For `dbg',
-`rdf', `ith' and `srec', it will use `.dbg', `.rdf', `.ith' and
-`.srec', respectively, and for the `bin' format it will simply remove
-the extension, so that `myfile.asm' produces the output file `myfile'.
-
- If the output file already exists, NASM will overwrite it, unless it
-has the same name as the input file, in which case it will give a
-warning and use `nasm.out' as the output file name instead.
-
- For situations in which this behaviour is unacceptable, NASM
-provides the `-o' command-line option, which allows you to specify your
-desired output file name. You invoke `-o' by following it with the name
-you wish for the output file, either with or without an intervening
-space. For example:
-
- nasm -f bin program.asm -o program.com
- nasm -f bin driver.asm -odriver.sys
-
- Note that this is a small o, and is different from a capital O ,
-which is used to specify the number of optimisation passes required. See
-*note Section 2.1.22::.
-
-
-File: nasm.info, Node: Section 2.1.2, Next: Section 2.1.3, Prev: Section 2.1.1, Up: Section 2.1
-
-2.1.2. The `-f' Option: Specifying the Output File Format
----------------------------------------------------------
-
-If you do not supply the `-f' option to NASM, it will choose an output
-file format for you itself. In the distribution versions of NASM, the
-default is always `bin'; if you've compiled your own copy of NASM, you
-can redefine `OF_DEFAULT' at compile time and choose what you want the
-default to be.
-
- Like `-o', the intervening space between `-f' and the output file
-format is optional; so `-f elf' and `-felf' are both valid.
-
- A complete list of the available output file formats can be given by
-issuing the command `nasm -hf'.
-
-
-File: nasm.info, Node: Section 2.1.3, Next: Section 2.1.4, Prev: Section 2.1.2, Up: Section 2.1
-
-2.1.3. The `-l' Option: Generating a Listing File
--------------------------------------------------
-
-If you supply the `-l' option to NASM, followed (with the usual
-optional space) by a file name, NASM will generate a source-listing file
-for you, in which addresses and generated code are listed on the left,
-and the actual source code, with expansions of multi-line macros
-(except those which specifically request no expansion in source
-listings: see *note Section 4.3.10::) on the right. For example:
-
- nasm -f elf myfile.asm -l myfile.lst
-
- If a list file is selected, you may turn off listing for a section
-of your source with `[list -]', and turn it back on with `[list +]',
-(the default, obviously). There is no "user form" (without the
-brackets). This can be used to list only sections of interest, avoiding
-excessively long listings.
-
-
-File: nasm.info, Node: Section 2.1.4, Next: Section 2.1.5, Prev: Section 2.1.3, Up: Section 2.1
-
-2.1.4. The `-M' Option: Generate Makefile Dependencies
-------------------------------------------------------
-
-This option can be used to generate makefile dependencies on stdout.
-This can be redirected to a file for further processing. For example:
-
- nasm -M myfile.asm > myfile.dep
-
-
-File: nasm.info, Node: Section 2.1.5, Next: Section 2.1.6, Prev: Section 2.1.4, Up: Section 2.1
-
-2.1.5. The `-MG' Option: Generate Makefile Dependencies
--------------------------------------------------------
-
-This option can be used to generate makefile dependencies on stdout.
-This differs from the `-M' option in that if a nonexisting file is
-encountered, it is assumed to be a generated file and is added to the
-dependency list without a prefix.
-
-
-File: nasm.info, Node: Section 2.1.6, Next: Section 2.1.7, Prev: Section 2.1.5, Up: Section 2.1
-
-2.1.6. The `-MF' Option: Set Makefile Dependency File
------------------------------------------------------
-
-This option can be used with the `-M' or `-MG' options to send the
-output to a file, rather than to stdout. For example:
-
- nasm -M -MF myfile.dep myfile.asm
-
-
-File: nasm.info, Node: Section 2.1.7, Next: Section 2.1.8, Prev: Section 2.1.6, Up: Section 2.1
-
-2.1.7. The `-MD' Option: Assemble and Generate Dependencies
------------------------------------------------------------
-
-The `-MD' option acts as the combination of the `-M' and `-MF' options
-(i.e. a filename has to be specified.) However, unlike the `-M' or
-`-MG' options, `-MD' does _not_ inhibit the normal operation of the
-assembler. Use this to automatically generate updated dependencies with
-every assembly session. For example:
-
- nasm -f elf -o myfile.o -MD myfile.dep myfile.asm
-
-
-File: nasm.info, Node: Section 2.1.8, Next: Section 2.1.9, Prev: Section 2.1.7, Up: Section 2.1
-
-2.1.8. The `-MT' Option: Dependency Target Name
------------------------------------------------
-
-The `-MT' option can be used to override the default name of the
-dependency target. This is normally the same as the output filename,
-specified by the `-o' option.
-
-
-File: nasm.info, Node: Section 2.1.9, Next: Section 2.1.10, Prev: Section 2.1.8, Up: Section 2.1
-
-2.1.9. The `-MQ' Option: Dependency Target Name (Quoted)
---------------------------------------------------------
-
-The `-MQ' option acts as the `-MT' option, except it tries to quote
-characters that have special meaning in Makefile syntax. This is not
-foolproof, as not all characters with special meaning are quotable in
-Make.
-
-
-File: nasm.info, Node: Section 2.1.10, Next: Section 2.1.11, Prev: Section 2.1.9, Up: Section 2.1
-
-2.1.10. The `-MP' Option: Emit phony targets
---------------------------------------------
-
-When used with any of the dependency generation options, the `-MP'
-option causes NASM to emit a phony target without dependencies for each
-header file. This prevents Make from complaining if a header file has
-been removed.
-
-
-File: nasm.info, Node: Section 2.1.11, Next: Section 2.1.12, Prev: Section 2.1.10, Up: Section 2.1
-
-2.1.11. The `-F' Option: Selecting a Debug Information Format
--------------------------------------------------------------
-
-This option is used to select the format of the debug information
-emitted into the output file, to be used by a debugger (or _will_ be).
-Prior to version 2.03.01, the use of this switch did _not_ enable
-output of the selected debug info format. Use `-g', see *note Section
-2.1.12::, to enable output. Versions 2.03.01 and later automatically
-enable `-g' if `-F' is specified.
-
- A complete list of the available debug file formats for an output
-format can be seen by issuing the command `nasm -f <format> -y'. Not all
-output formats currently support debugging output. See *note Section
-2.1.26::.
-
- This should not be confused with the `-f dbg' output format option
-which is not built into NASM by default. For information on how to
-enable it when building from the sources, see *note Section 7.14::.
-
-
-File: nasm.info, Node: Section 2.1.12, Next: Section 2.1.13, Prev: Section 2.1.11, Up: Section 2.1
-
-2.1.12. The `-g' Option: Enabling Debug Information.
-----------------------------------------------------
-
-This option can be used to generate debugging information in the
-specified format. See *note Section 2.1.11::. Using `-g' without `-F'
-results in emitting debug info in the default format, if any, for the
-selected output format. If no debug information is currently
-implemented in the selected output format, `-g' is _silently ignored_.
-
-
-File: nasm.info, Node: Section 2.1.13, Next: Section 2.1.14, Prev: Section 2.1.12, Up: Section 2.1
-
-2.1.13. The `-X' Option: Selecting an Error Reporting Format
-------------------------------------------------------------
-
-This option can be used to select an error reporting format for any
-error messages that might be produced by NASM.
-
- Currently, two error reporting formats may be selected. They are the
-`-Xvc' option and the `-Xgnu' option. The GNU format is the default and
-looks like this:
-
- filename.asm:65: error: specific error message
-
- where `filename.asm' is the name of the source file in which the
-error was detected, `65' is the source file line number on which the
-error was detected, `error' is the severity of the error (this could be
-`warning'), and `specific error message' is a more detailed text
-message which should help pinpoint the exact problem.
-
- The other format, specified by `-Xvc' is the style used by Microsoft
-Visual C++ and some other programs. It looks like this:
-
- filename.asm(65) : error: specific error message
-
- where the only difference is that the line number is in parentheses
-instead of being delimited by colons.
-
- See also the `Visual C++' output format, *note Section 7.5::.
-
-
-File: nasm.info, Node: Section 2.1.14, Next: Section 2.1.15, Prev: Section 2.1.13, Up: Section 2.1
-
-2.1.14. The `-Z' Option: Send Errors to a File
-----------------------------------------------
-
-Under `MS-DOS' it can be difficult (though there are ways) to redirect
-the standard-error output of a program to a file. Since NASM usually
-produces its warning and error messages on `stderr', this can make it
-hard to capture the errors if (for example) you want to load them into
-an editor.
-
- NASM therefore provides the `-Z' option, taking a filename argument
-which causes errors to be sent to the specified files rather than
-standard error. Therefore you can redirect the errors into a file by
-typing
-
- nasm -Z myfile.err -f obj myfile.asm
-
- In earlier versions of NASM, this option was called `-E', but it was
-changed since `-E' is an option conventionally used for preprocessing
-only, with disastrous results. See *note Section 2.1.20::.
-
-
-File: nasm.info, Node: Section 2.1.15, Next: Section 2.1.16, Prev: Section 2.1.14, Up: Section 2.1
-
-2.1.15. The `-s' Option: Send Errors to `stdout'
-------------------------------------------------
-
-The `-s' option redirects error messages to `stdout' rather than
-`stderr', so it can be redirected under `MS-DOS'. To assemble the file
-`myfile.asm' and pipe its output to the `more' program, you can type:
-
- nasm -s -f obj myfile.asm | more
-
- See also the `-Z' option, *note Section 2.1.14::.
-
-
-File: nasm.info, Node: Section 2.1.16, Next: Section 2.1.17, Prev: Section 2.1.15, Up: Section 2.1
-
-2.1.16. The `-i' Option: Include File Search Directories
---------------------------------------------------------
-
-When NASM sees the `%include' or `%pathsearch' directive in a source
-file (see *note Section 4.6.1::, *note Section 4.6.2:: or *note Section
-3.2.3::), it will search for the given file not only in the current
-directory, but also in any directories specified on the command line by
-the use of the `-i' option. Therefore you can include files from a macro
-library, for example, by typing
-
- nasm -ic:\macrolib\ -f obj myfile.asm
-
- (As usual, a space between `-i' and the path name is allowed, and
-optional).
-
- NASM, in the interests of complete source-code portability, does not
-understand the file naming conventions of the OS it is running on; the
-string you provide as an argument to the `-i' option will be prepended
-exactly as written to the name of the include file. Therefore the
-trailing backslash in the above example is necessary. Under Unix, a
-trailing forward slash is similarly necessary.
-
- (You can use this to your advantage, if you're really perverse, by
-noting that the option `-ifoo' will cause `%include "bar.i"' to search
-for the file `foobar.i'...)
-
- If you want to define a _standard_ include search path, similar to
-`/usr/include' on Unix systems, you should place one or more `-i'
-directives in the `NASMENV' environment variable (see *note Section
-2.1.28::).
-
- For Makefile compatibility with many C compilers, this option can
-also be specified as `-I'.
-
-
-File: nasm.info, Node: Section 2.1.17, Next: Section 2.1.18, Prev: Section 2.1.16, Up: Section 2.1
-
-2.1.17. The `-p' Option: Pre-Include a File
--------------------------------------------
-
-NASM allows you to specify files to be _pre-included_ into your source
-file, by the use of the `-p' option. So running
-
- nasm myfile.asm -p myinc.inc
-
- is equivalent to running `nasm myfile.asm' and placing the directive
-`%include "myinc.inc"' at the start of the file.
-
- For consistency with the `-I', `-D' and `-U' options, this option
-can also be specified as `-P'.
-
-
-File: nasm.info, Node: Section 2.1.18, Next: Section 2.1.19, Prev: Section 2.1.17, Up: Section 2.1
-
-2.1.18. The `-d' Option: Pre-Define a Macro
--------------------------------------------
-
-Just as the `-p' option gives an alternative to placing `%include'
-directives at the start of a source file, the `-d' option gives an
-alternative to placing a `%define' directive. You could code
-
- nasm myfile.asm -dFOO=100
-
- as an alternative to placing the directive
-
- %define FOO 100
-
- at the start of the file. You can miss off the macro value, as well:
-the option `-dFOO' is equivalent to coding `%define FOO'. This form of
-the directive may be useful for selecting assembly-time options which
-are then tested using `%ifdef', for example `-dDEBUG'.
-
- For Makefile compatibility with many C compilers, this option can
-also be specified as `-D'.
-
-
-File: nasm.info, Node: Section 2.1.19, Next: Section 2.1.20, Prev: Section 2.1.18, Up: Section 2.1
-
-2.1.19. The `-u' Option: Undefine a Macro
------------------------------------------
-
-The `-u' option undefines a macro that would otherwise have been pre-
-defined, either automatically or by a `-p' or `-d' option specified
-earlier on the command lines.
-
- For example, the following command line:
-
- nasm myfile.asm -dFOO=100 -uFOO
-
- would result in `FOO' _not_ being a predefined macro in the program.
-This is useful to override options specified at a different point in a
-Makefile.
-
- For Makefile compatibility with many C compilers, this option can
-also be specified as `-U'.
-
-
-File: nasm.info, Node: Section 2.1.20, Next: Section 2.1.21, Prev: Section 2.1.19, Up: Section 2.1
-
-2.1.20. The `-E' Option: Preprocess Only
-----------------------------------------
-
-NASM allows the preprocessor to be run on its own, up to a point. Using
-the `-E' option (which requires no arguments) will cause NASM to
-preprocess its input file, expand all the macro references, remove all
-the comments and preprocessor directives, and print the resulting file
-on standard output (or save it to a file, if the `-o' option is also
-used).
-
- This option cannot be applied to programs which require the
-preprocessor to evaluate expressions which depend on the values of
-symbols: so code such as
-
- %assign tablesize ($-tablestart)
-
- will cause an error in preprocess-only mode.
-
- For compatiblity with older version of NASM, this option can also be
-written `-e'. `-E' in older versions of NASM was the equivalent of the
-current `-Z' option, *note Section 2.1.14::.
-
-
-File: nasm.info, Node: Section 2.1.21, Next: Section 2.1.22, Prev: Section 2.1.20, Up: Section 2.1
-
-2.1.21. The `-a' Option: Don't Preprocess At All
-------------------------------------------------
-
-If NASM is being used as the back end to a compiler, it might be
-desirable to suppress preprocessing completely and assume the compiler
-has already done it, to save time and increase compilation speeds. The
-`-a' option, requiring no argument, instructs NASM to replace its
-powerful preprocessor with a stub preprocessor which does nothing.
-
-
-File: nasm.info, Node: Section 2.1.22, Next: Section 2.1.23, Prev: Section 2.1.21, Up: Section 2.1
-
-2.1.22. The `-O' Option: Specifying Multipass Optimization
-----------------------------------------------------------
-
-NASM defaults to not optimizing operands which can fit into a signed
-byte. This means that if you want the shortest possible object code,
-you have to enable optimization.
-
- Using the `-O' option, you can tell NASM to carry out different
-levels of optimization. The syntax is:
-
- * `-O0': No optimization. All operands take their long forms, if a
- short form is not specified, except conditional jumps. This is
- intended to match NASM 0.98 behavior.
-
- * `-O1': Minimal optimization. As above, but immediate operands which
- will fit in a signed byte are optimized, unless the long form is
- specified. Conditional jumps default to the long form unless
- otherwise specified.
-
- * `-Ox' (where `x' is the actual letter `x'): Multipass
- optimization. Minimize branch offsets and signed immediate bytes,
- overriding size specification unless the `strict' keyword has been
- used (see *note Section 3.7::). For compatability with earlier
- releases, the letter `x' may also be any number greater than one.
- This number has no effect on the actual number of passes.
-
- The `-Ox' mode is recommended for most uses.
-
- Note that this is a capital `O', and is different from a small `o',
-which is used to specify the output file name. See *note Section
-2.1.1::.
-
-
-File: nasm.info, Node: Section 2.1.23, Next: Section 2.1.24, Prev: Section 2.1.22, Up: Section 2.1
-
-2.1.23. The `-t' Option: Enable TASM Compatibility Mode
--------------------------------------------------------
-
-NASM includes a limited form of compatibility with Borland's `TASM'.
-When NASM's `-t' option is used, the following changes are made:
-
- * local labels may be prefixed with `@@' instead of `.'
-
- * size override is supported within brackets. In TASM compatible
- mode, a size override inside square brackets changes the size of
- the operand, and not the address type of the operand as it does in
- NASM syntax. E.g. `mov eax,[DWORD val]' is valid syntax in TASM
- compatibility mode. Note that you lose the ability to override the
- default address type for the instruction.
-
- * unprefixed forms of some directives supported (`arg', `elif',
- `else', `endif', `if', `ifdef', `ifdifi', `ifndef', `include',
- `local')
-
-
-File: nasm.info, Node: Section 2.1.24, Next: Section 2.1.25, Prev: Section 2.1.23, Up: Section 2.1
-
-2.1.24. The `-w' and `-W' Options: Enable or Disable Assembly Warnings
-----------------------------------------------------------------------
-
-NASM can observe many conditions during the course of assembly which are
-worth mentioning to the user, but not a sufficiently severe error to
-justify NASM refusing to generate an output file. These conditions are
-reported like errors, but come up with the word `warning' before the
-message. Warnings do not prevent NASM from generating an output file and
-returning a success status to the operating system.
-
- Some conditions are even less severe than that: they are only
-sometimes worth mentioning to the user. Therefore NASM supports the `-w'
-command-line option, which enables or disables certain classes of
-assembly warning. Such warning classes are described by a name, for
-example `orphan-labels'; you can enable warnings of this class by the
-command- line option `-w+orphan-labels' and disable it by
-`-w-orphan-labels'.
-
- The suppressible warning classes are:
-
- * `macro-params' covers warnings about multi-line macros being
- invoked with the wrong number of parameters. This warning class is
- enabled by default; see *note Section 4.3.2:: for an example of
- why you might want to disable it.
-
- * `macro-selfref' warns if a macro references itself. This warning
- class is disabled by default.
-
- * `macro-defaults' warns when a macro has more default parameters
- than optional parameters. This warning class is enabled by
- default; see *note Section 4.3.5:: for why you might want to
- disable it.
-
- * `orphan-labels' covers warnings about source lines which contain no
- instruction but define a label without a trailing colon. NASM
- warns about this somewhat obscure condition by default; see *note
- Section 3.1:: for more information.
-
- * `number-overflow' covers warnings about numeric constants which
- don't fit in 64 bits. This warning class is enabled by default.
-
- * `gnu-elf-extensions' warns if 8-bit or 16-bit relocations are used
- in `-f elf' format. The GNU extensions allow this. This warning
- class is disabled by default.
-
- * `float-overflow' warns about floating point overflow. Enabled by
- default.
-
- * `float-denorm' warns about floating point denormals. Disabled by
- default.
-
- * `float-underflow' warns about floating point underflow. Disabled by
- default.
-
- * `float-toolong' warns about too many digits in floating-point
- numbers. Enabled by default.
-
- * `user' controls `%warning' directives (see *note Section 4.9::).
- Enabled by default.
-
- * `error' causes warnings to be treated as errors. Disabled by
- default.
-
- * `all' is an alias for _all_ suppressible warning classes (not
- including `error'). Thus, `-w+all' enables all available warnings.
-
- In addition, you can set warning classes across sections. Warning
-classes may be enabled with `[warning +warning-name]', disabled with
-`[warning -warning-name]' or reset to their original value with
-`[warning *warning-name]'. No "user form" (without the brackets) exists.
-
- Since version 2.00, NASM has also supported the gcc-like syntax
-`-Wwarning' and `-Wno-warning' instead of `-w+warning' and
-`-w-warning', respectively.
-
-
-File: nasm.info, Node: Section 2.1.25, Next: Section 2.1.26, Prev: Section 2.1.24, Up: Section 2.1
-
-2.1.25. The `-v' Option: Display Version Info
----------------------------------------------
-
-Typing `NASM -v' will display the version of NASM which you are using,
-and the date on which it was compiled.
-
- You will need the version number if you report a bug.
-
-
-File: nasm.info, Node: Section 2.1.26, Next: Section 2.1.27, Prev: Section 2.1.25, Up: Section 2.1
-
-2.1.26. The `-y' Option: Display Available Debug Info Formats
--------------------------------------------------------------
-
-Typing `nasm -f <option> -y' will display a list of the available debug
-info formats for the given output format. The default format is
-indicated by an asterisk. For example:
-
- nasm -f elf -y
-
- valid debug formats for 'elf32' output format are
- ('*' denotes default):
- * stabs ELF32 (i386) stabs debug format for Linux
- dwarf elf32 (i386) dwarf debug format for Linux
-
-
-File: nasm.info, Node: Section 2.1.27, Next: Section 2.1.28, Prev: Section 2.1.26, Up: Section 2.1
-
-2.1.27. The `--prefix' and `--postfix' Options.
------------------------------------------------
-
-The `--prefix' and `--postfix' options prepend or append (respectively)
-the given argument to all `global' or `extern' variables. E.g.
-`--prefix _' will prepend the underscore to all global and external
-variables, as C sometimes (but not always) likes it.
-
-
-File: nasm.info, Node: Section 2.1.28, Next: Section 2.2, Prev: Section 2.1.27, Up: Section 2.1
-
-2.1.28. The `NASMENV' Environment Variable
-------------------------------------------
-
-If you define an environment variable called `NASMENV', the program
-will interpret it as a list of extra command-line options, which are
-processed before the real command line. You can use this to define
-standard search directories for include files, by putting `-i' options
-in the `NASMENV' variable.
-
- The value of the variable is split up at white space, so that the
-value `-s -ic:\nasmlib\' will be treated as two separate options.
-However, that means that the value `-dNAME="my name"' won't do what you
-might want, because it will be split at the space and the NASM
-command-line processing will get confused by the two nonsensical words
-`-dNAME="my' and `name"'.
-
- To get round this, NASM provides a feature whereby, if you begin the
-`NASMENV' environment variable with some character that isn't a minus
-sign, then NASM will treat this character as the separator character for
-options. So setting the `NASMENV' variable to the value
-`!-s!-ic:\nasmlib\' is equivalent to setting it to `-s -ic:\nasmlib\',
-but `!-dNAME="my name"' will work.
-
- This environment variable was previously called `NASM'. This was
-changed with version 0.98.31.
-
-
-File: nasm.info, Node: Section 2.2, Next: Section 2.2.1, Prev: Section 2.1.28, Up: Chapter 2
-
-2.2. Quick Start for MASM Users
-===============================
-
-If you're used to writing programs with MASM, or with TASM in MASM-
-compatible (non-Ideal) mode, or with `a86', this section attempts to
-outline the major differences between MASM's syntax and NASM's. If
-you're not already used to MASM, it's probably worth skipping this
-section.
-
-* Menu:
-
-* Section 2.2.1:: NASM Is Case-Sensitive
-* Section 2.2.2:: NASM Requires Square Brackets For Memory References
-* Section 2.2.3:: NASM Doesn't Store Variable Types
-* Section 2.2.4:: NASM Doesn't `ASSUME'
-* Section 2.2.5:: NASM Doesn't Support Memory Models
-* Section 2.2.6:: Floating-Point Differences
-* Section 2.2.7:: Other Differences
-
-
-File: nasm.info, Node: Section 2.2.1, Next: Section 2.2.2, Prev: Section 2.2, Up: Section 2.2
-
-2.2.1. NASM Is Case-Sensitive
------------------------------
-
-One simple difference is that NASM is case-sensitive. It makes a
-difference whether you call your label `foo', `Foo' or `FOO'. If you're
-assembling to `DOS' or `OS/2' `.OBJ' files, you can invoke the
-`UPPERCASE' directive (documented in *note Section 7.4::) to ensure
-that all symbols exported to other code modules are forced to be upper
-case; but even then, _within_ a single module, NASM will distinguish
-between labels differing only in case.
-
-
-File: nasm.info, Node: Section 2.2.2, Next: Section 2.2.3, Prev: Section 2.2.1, Up: Section 2.2
-
-2.2.2. NASM Requires Square Brackets For Memory References
-----------------------------------------------------------
-
-NASM was designed with simplicity of syntax in mind. One of the design
-goals of NASM is that it should be possible, as far as is practical, for
-the user to look at a single line of NASM code and tell what opcode is
-generated by it. You can't do this in MASM: if you declare, for example,
-
- foo equ 1
- bar dw 2
-
- then the two lines of code
-
- mov ax,foo
- mov ax,bar
-
- generate completely different opcodes, despite having
-identical-looking syntaxes.
-
- NASM avoids this undesirable situation by having a much simpler
-syntax for memory references. The rule is simply that any access to the
-_contents_ of a memory location requires square brackets around the
-address, and any access to the _address_ of a variable doesn't. So an
-instruction of the form `mov ax,foo' will _always_ refer to a
-compile-time constant, whether it's an `EQU' or the address of a
-variable; and to access the _contents_ of the variable `bar', you must
-code `mov ax,[bar]'.
-
- This also means that NASM has no need for MASM's `OFFSET' keyword,
-since the MASM code `mov ax,offset bar' means exactly the same thing as
-NASM's `mov ax,bar'. If you're trying to get large amounts of MASM code
-to assemble sensibly under NASM, you can always code `%idefine offset'
-to make the preprocessor treat the `OFFSET' keyword as a no-op.
-
- This issue is even more confusing in `a86', where declaring a label
-with a trailing colon defines it to be a `label' as opposed to a
-`variable' and causes `a86' to adopt NASM-style semantics; so in `a86',
-`mov ax,var' has different behaviour depending on whether `var' was
-declared as `var: dw 0' (a label) or `var dw 0' (a word-size variable).
-NASM is very simple by comparison: _everything_ is a label.
-
- NASM, in the interests of simplicity, also does not support the
-hybrid syntaxes supported by MASM and its clones, such as `mov
-ax,table[bx]', where a memory reference is denoted by one portion
-outside square brackets and another portion inside. The correct syntax
-for the above is `mov ax,[table+bx]'. Likewise, `mov ax,es:[di]' is
-wrong and `mov ax,[es:di]' is right.
-
-
-File: nasm.info, Node: Section 2.2.3, Next: Section 2.2.4, Prev: Section 2.2.2, Up: Section 2.2
-
-2.2.3. NASM Doesn't Store Variable Types
-----------------------------------------
-
-NASM, by design, chooses not to remember the types of variables you
-declare. Whereas MASM will remember, on seeing `var dw 0', that you
-declared `var' as a word-size variable, and will then be able to fill
-in the ambiguity in the size of the instruction `mov var,2', NASM will
-deliberately remember nothing about the symbol `var' except where it
-begins, and so you must explicitly code `mov word [var],2'.
-
- For this reason, NASM doesn't support the `LODS', `MOVS', `STOS',
-`SCAS', `CMPS', `INS', or `OUTS' instructions, but only supports the
-forms such as `LODSB', `MOVSW', and `SCASD', which explicitly specify
-the size of the components of the strings being manipulated.
-
-
-File: nasm.info, Node: Section 2.2.4, Next: Section 2.2.5, Prev: Section 2.2.3, Up: Section 2.2
-
-2.2.4. NASM Doesn't `ASSUME'
-----------------------------
-
-As part of NASM's drive for simplicity, it also does not support the
-`ASSUME' directive. NASM will not keep track of what values you choose
-to put in your segment registers, and will never _automatically_
-generate a segment override prefix.
-
-
-File: nasm.info, Node: Section 2.2.5, Next: Section 2.2.6, Prev: Section 2.2.4, Up: Section 2.2
-
-2.2.5. NASM Doesn't Support Memory Models
------------------------------------------
-
-NASM also does not have any directives to support different 16-bit
-memory models. The programmer has to keep track of which functions are
-supposed to be called with a far call and which with a near call, and
-is responsible for putting the correct form of `RET' instruction
-(`RETN' or `RETF'; NASM accepts `RET' itself as an alternate form for
-`RETN'); in addition, the programmer is responsible for coding CALL FAR
-instructions where necessary when calling _external_ functions, and
-must also keep track of which external variable definitions are far and
-which are near.
-
-
-File: nasm.info, Node: Section 2.2.6, Next: Section 2.2.7, Prev: Section 2.2.5, Up: Section 2.2
-
-2.2.6. Floating-Point Differences
----------------------------------
-
-NASM uses different names to refer to floating-point registers from
-MASM: where MASM would call them `ST(0)', `ST(1)' and so on, and `a86'
-would call them simply `0', `1' and so on, NASM chooses to call them
-`st0', `st1' etc.
-
- As of version 0.96, NASM now treats the instructions with `nowait'
-forms in the same way as MASM-compatible assemblers. The idiosyncratic
-treatment employed by 0.95 and earlier was based on a misunderstanding
-by the authors.
-
-
-File: nasm.info, Node: Section 2.2.7, Next: Chapter 3, Prev: Section 2.2.6, Up: Section 2.2
-
-2.2.7. Other Differences
-------------------------
-
-For historical reasons, NASM uses the keyword `TWORD' where MASM and
-compatible assemblers use `TBYTE'.
-
- NASM does not declare uninitialized storage in the same way as MASM:
-where a MASM programmer might use `stack db 64 dup (?)', NASM requires
-`stack resb 64', intended to be read as `reserve 64 bytes'. For a
-limited amount of compatibility, since NASM treats `?' as a valid
-character in symbol names, you can code `? equ 0' and then writing `dw
-?' will at least do something vaguely useful. `DUP' is still not a
-supported syntax, however.
-
- In addition to all of this, macros and directives work completely
-differently to MASM. See *note Chapter 4:: and *note Chapter 6:: for
-further details.
-
-
-File: nasm.info, Node: Chapter 3, Next: Section 3.1, Prev: Section 2.2.7, Up: Top
-
-Chapter 3: The NASM Language
-****************************
-
-* Menu:
-
-* Section 3.1:: Layout of a NASM Source Line
-* Section 3.2:: Pseudo-Instructions
-* Section 3.3:: Effective Addresses
-* Section 3.4:: Constants
-* Section 3.5:: Expressions
-* Section 3.6:: `SEG' and `WRT'
-* Section 3.7:: `STRICT': Inhibiting Optimization
-* Section 3.8:: Critical Expressions
-* Section 3.9:: Local Labels
-
-
-File: nasm.info, Node: Section 3.1, Next: Section 3.2, Prev: Chapter 3, Up: Chapter 3
-
-3.1. Layout of a NASM Source Line
-=================================
-
-Like most assemblers, each NASM source line contains (unless it is a
-macro, a preprocessor directive or an assembler directive: see *note
-Chapter 4:: and *note Chapter 6::) some combination of the four fields
-
- label: instruction operands ; comment
-
- As usual, most of these fields are optional; the presence or absence
-of any combination of a label, an instruction and a comment is allowed.
-Of course, the operand field is either required or forbidden by the
-presence and nature of the instruction field.
-
- NASM uses backslash (\) as the line continuation character; if a
-line ends with backslash, the next line is considered to be a part of
-the backslash- ended line.
-
- NASM places no restrictions on white space within a line: labels may
-have white space before them, or instructions may have no space before
-them, or anything. The colon after a label is also optional. (Note that
-this means that if you intend to code `lodsb' alone on a line, and type
-`lodab' by accident, then that's still a valid source line which does
-nothing but define a label. Running NASM with the command-line option
-`-w+orphan-labels' will cause it to warn you if you define a label
-alone on a line without a trailing colon.)
-
- Valid characters in labels are letters, numbers, `_', `$', `#', `@',
-`~', `.', and `?'. The only characters which may be used as the _first_
-character of an identifier are letters, `.' (with special meaning: see
-*note Section 3.9::), `_' and `?'. An identifier may also be prefixed
-with a `$' to indicate that it is intended to be read as an identifier
-and not a reserved word; thus, if some other module you are linking
-with defines a symbol called `eax', you can refer to `$eax' in NASM
-code to distinguish the symbol from the register. Maximum length of an
-identifier is 4095 characters.
-
- The instruction field may contain any machine instruction: Pentium
-and P6 instructions, FPU instructions, MMX instructions and even
-undocumented instructions are all supported. The instruction may be
-prefixed by `LOCK', `REP', `REPE'/`REPZ' or `REPNE'/`REPNZ', in the
-usual way. Explicit address-size and operand-size prefixes `A16',
-`A32', `A64', `O16' and `O32', `O64' are provided - one example of
-their use is given in *note Chapter 10::. You can also use the name of
-a segment register as an instruction prefix: coding `es mov [bx],ax' is
-equivalent to coding `mov [es:bx],ax'. We recommend the latter syntax,
-since it is consistent with other syntactic features of the language,
-but for instructions such as `LODSB', which has no operands and yet can
-require a segment override, there is no clean syntactic way to proceed
-apart from `es lodsb'.
-
- An instruction is not required to use a prefix: prefixes such as
-`CS', `A32', `LOCK' or `REPE' can appear on a line by themselves, and
-NASM will just generate the prefix bytes.
-
- In addition to actual machine instructions, NASM also supports a
-number of pseudo-instructions, described in *note Section 3.2::.
-
- Instruction operands may take a number of forms: they can be
-registers, described simply by the register name (e.g. `ax', `bp',
-`ebx', `cr0': NASM does not use the `gas'-style syntax in which
-register names must be prefixed by a `%' sign), or they can be
-effective addresses (see *note Section 3.3::), constants (*note Section
-3.4::) or expressions (*note Section 3.5::).
-
- For x87 floating-point instructions, NASM accepts a wide range of
-syntaxes: you can use two-operand forms like MASM supports, or you can
-use NASM's native single-operand forms in most cases. For example, you
-can code:
-
- fadd st1 ; this sets st0 := st0 + st1
- fadd st0,st1 ; so does this
-
- fadd st1,st0 ; this sets st1 := st1 + st0
- fadd to st1 ; so does this
-
- Almost any x87 floating-point instruction that references memory
-must use one of the prefixes `DWORD', `QWORD' or `TWORD' to indicate
-what size of memory operand it refers to.
-
-
-File: nasm.info, Node: Section 3.2, Next: Section 3.2.1, Prev: Section 3.1, Up: Chapter 3
-
-3.2. Pseudo-Instructions
-========================
-
-Pseudo-instructions are things which, though not real x86 machine
-instructions, are used in the instruction field anyway because that's
-the most convenient place to put them. The current pseudo-instructions
-are `DB', `DW', `DD', `DQ', `DT', `DO' and `DY'; their uninitialized
-counterparts `RESB', `RESW', `RESD', `RESQ', `REST', `RESO' and `RESY';
-the `INCBIN' command, the `EQU' command, and the `TIMES' prefix.
-
-* Menu:
-
-* Section 3.2.1:: `DB' and Friends: Declaring Initialized Data
-* Section 3.2.2:: `RESB' and Friends: Declaring Uninitialized Data
-* Section 3.2.3:: `INCBIN': Including External Binary Files
-* Section 3.2.4:: `EQU': Defining Constants
-* Section 3.2.5:: `TIMES': Repeating Instructions or Data
-
-
-File: nasm.info, Node: Section 3.2.1, Next: Section 3.2.2, Prev: Section 3.2, Up: Section 3.2
-
-3.2.1. `DB' and Friends: Declaring Initialized Data
----------------------------------------------------
-
-`DB', `DW', `DD', `DQ', `DT', `DO' and `DY' are used, much as in MASM,
-to declare initialized data in the output file. They can be invoked in
-a wide range of ways:
-
- db 0x55 ; just the byte 0x55
- db 0x55,0x56,0x57 ; three bytes in succession
- db 'a',0x55 ; character constants are OK
- db 'hello',13,10,'$' ; so are string constants
- dw 0x1234 ; 0x34 0x12
- dw 'a' ; 0x61 0x00 (it's just a number)
- dw 'ab' ; 0x61 0x62 (character constant)
- dw 'abc' ; 0x61 0x62 0x63 0x00 (string)
- dd 0x12345678 ; 0x78 0x56 0x34 0x12
- dd 1.234567e20 ; floating-point constant
- dq 0x123456789abcdef0 ; eight byte constant
- dq 1.234567e20 ; double-precision float
- dt 1.234567e20 ; extended-precision float
-
- `DT', `DO' and `DY' do not accept numeric constants as operands.
-
-
-File: nasm.info, Node: Section 3.2.2, Next: Section 3.2.3, Prev: Section 3.2.1, Up: Section 3.2
-
-3.2.2. `RESB' and Friends: Declaring Uninitialized Data
--------------------------------------------------------
-
-`RESB', `RESW', `RESD', `RESQ', `REST', `RESO' and `RESY' are designed
-to be used in the BSS section of a module: they declare _uninitialized_
-storage space. Each takes a single operand, which is the number of
-bytes, words, doublewords or whatever to reserve. As stated in *note
-Section 2.2.7::, NASM does not support the MASM/TASM syntax of
-reserving uninitialized space by writing `DW ?' or similar things: this
-is what it does instead. The operand to a `RESB'-type
-pseudo-instruction is a _critical expression_: see *note Section 3.8::.
-
- For example:
-
- buffer: resb 64 ; reserve 64 bytes
- wordvar: resw 1 ; reserve a word
- realarray resq 10 ; array of ten reals
- ymmval: resy 1 ; one YMM register
-
-
-File: nasm.info, Node: Section 3.2.3, Next: Section 3.2.4, Prev: Section 3.2.2, Up: Section 3.2
-
-3.2.3. `INCBIN': Including External Binary Files
-------------------------------------------------
-
-`INCBIN' is borrowed from the old Amiga assembler DevPac: it includes a
-binary file verbatim into the output file. This can be handy for (for
-example) including graphics and sound data directly into a game
-executable file. It can be called in one of these three ways:
-
- incbin "file.dat" ; include the whole file
- incbin "file.dat",1024 ; skip the first 1024 bytes
- incbin "file.dat",1024,512 ; skip the first 1024, and
- ; actually include at most 512
-
- `INCBIN' is both a directive and a standard macro; the standard macro
-version searches for the file in the include file search path and adds
-the file to the dependency lists. This macro can be overridden if
-desired.
-
-
-File: nasm.info, Node: Section 3.2.4, Next: Section 3.2.5, Prev: Section 3.2.3, Up: Section 3.2
-
-3.2.4. `EQU': Defining Constants
---------------------------------
-
-`EQU' defines a symbol to a given constant value: when `EQU' is used,
-the source line must contain a label. The action of `EQU' is to define
-the given label name to the value of its (only) operand. This
-definition is absolute, and cannot change later. So, for example,
-
- message db 'hello, world'
- msglen equ $-message
-
- defines `msglen' to be the constant 12. `msglen' may not then be
-redefined later. This is not a preprocessor definition either: the
-value of `msglen' is evaluated _once_, using the value of `$' (see
-*note Section 3.5:: for an explanation of `$') at the point of
-definition, rather than being evaluated wherever it is referenced and
-using the value of `$' at the point of reference.
-
-
-File: nasm.info, Node: Section 3.2.5, Next: Section 3.3, Prev: Section 3.2.4, Up: Section 3.2
-
-3.2.5. `TIMES': Repeating Instructions or Data
-----------------------------------------------
-
-The `TIMES' prefix causes the instruction to be assembled multiple
-times. This is partly present as NASM's equivalent of the `DUP' syntax
-supported by MASM-compatible assemblers, in that you can code
-
- zerobuf: times 64 db 0
-
- or similar things; but `TIMES' is more versatile than that. The
-argument to `TIMES' is not just a numeric constant, but a numeric
-_expression_, so you can do things like
-
- buffer: db 'hello, world'
- times 64-$+buffer db ' '
-
- which will store exactly enough spaces to make the total length of
-`buffer' up to 64. Finally, `TIMES' can be applied to ordinary
-instructions, so you can code trivial unrolled loops in it:
-
- times 100 movsb
-
- Note that there is no effective difference between `times 100 resb 1'
-and `resb 100', except that the latter will be assembled about 100
-times faster due to the internal structure of the assembler.
-
- The operand to `TIMES' is a critical expression (*note Section
-3.8::).
-
- Note also that `TIMES' can't be applied to macros: the reason for
-this is that `TIMES' is processed after the macro phase, which allows
-the argument to `TIMES' to contain expressions such as `64-$+buffer' as
-above. To repeat more than one line of code, or a complex macro, use the
-preprocessor `%rep' directive.
-
-
-File: nasm.info, Node: Section 3.3, Next: Section 3.4, Prev: Section 3.2.5, Up: Chapter 3
-
-3.3. Effective Addresses
-========================
-
-An effective address is any operand to an instruction which references
-memory. Effective addresses, in NASM, have a very simple syntax: they
-consist of an expression evaluating to the desired address, enclosed in
-square brackets. For example:
-
- wordvar dw 123
- mov ax,[wordvar]
- mov ax,[wordvar+1]
- mov ax,[es:wordvar+bx]
-
- Anything not conforming to this simple system is not a valid memory
-reference in NASM, for example `es:wordvar[bx]'.
-
- More complicated effective addresses, such as those involving more
-than one register, work in exactly the same way:
-
- mov eax,[ebx*2+ecx+offset]
- mov ax,[bp+di+8]
-
- NASM is capable of doing algebra on these effective addresses, so
-that things which don't necessarily _look_ legal are perfectly all
-right:
-
- mov eax,[ebx*5] ; assembles as [ebx*4+ebx]
- mov eax,[label1*2-label2] ; ie [label1+(label1-label2)]
-
- Some forms of effective address have more than one assembled form;
-in most such cases NASM will generate the smallest form it can. For
-example, there are distinct assembled forms for the 32-bit effective
-addresses `[eax*2+0]' and `[eax+eax]', and NASM will generally generate
-the latter on the grounds that the former requires four bytes to store
-a zero offset.
-
- NASM has a hinting mechanism which will cause `[eax+ebx]' and
-`[ebx+eax]' to generate different opcodes; this is occasionally useful
-because `[esi+ebp]' and `[ebp+esi]' have different default segment
-registers.
-
- However, you can force NASM to generate an effective address in a
-particular form by the use of the keywords `BYTE', `WORD', `DWORD' and
-`NOSPLIT'. If you need `[eax+3]' to be assembled using a double-word
-offset field instead of the one byte NASM will normally generate, you
-can code `[dword eax+3]'. Similarly, you can force NASM to use a byte
-offset for a small value which it hasn't seen on the first pass (see
-*note Section 3.8:: for an example of such a code fragment) by using
-`[byte eax+offset]'. As special cases, `[byte eax]' will code `[eax+0]'
-with a byte offset of zero, and `[dword eax]' will code it with a
-double-word offset of zero. The normal form, `[eax]', will be coded
-with no offset field.
-
- The form described in the previous paragraph is also useful if you
-are trying to access data in a 32-bit segment from within 16 bit code.
-For more information on this see the section on mixed-size addressing
-(*note Section 10.2::). In particular, if you need to access data with
-a known offset that is larger than will fit in a 16-bit value, if you
-don't specify that it is a dword offset, nasm will cause the high word
-of the offset to be lost.
-
- Similarly, NASM will split `[eax*2]' into `[eax+eax]' because that
-allows the offset field to be absent and space to be saved; in fact, it
-will also split `[eax*2+offset]' into `[eax+eax+offset]'. You can
-combat this behaviour by the use of the `NOSPLIT' keyword: `[nosplit
-eax*2]' will force `[eax*2+0]' to be generated literally.
-
- In 64-bit mode, NASM will by default generate absolute addresses. The
-`REL' keyword makes it produce `RIP'-relative addresses. Since this is
-frequently the normally desired behaviour, see the `DEFAULT' directive
-(*note Section 6.2::). The keyword `ABS' overrides `REL'.
-
-
-File: nasm.info, Node: Section 3.4, Next: Section 3.4.1, Prev: Section 3.3, Up: Chapter 3
-
-3.4. Constants
-==============
-
-NASM understands four different types of constant: numeric, character,
-string and floating-point.
-
-* Menu:
-
-* Section 3.4.1:: Numeric Constants
-* Section 3.4.2:: Character Strings
-* Section 3.4.3:: Character Constants
-* Section 3.4.4:: String Constants
-* Section 3.4.5:: Unicode Strings
-* Section 3.4.6:: Floating-Point Constants
-* Section 3.4.7:: Packed BCD Constants
-
-
-File: nasm.info, Node: Section 3.4.1, Next: Section 3.4.2, Prev: Section 3.4, Up: Section 3.4
-
-3.4.1. Numeric Constants
-------------------------
-
-A numeric constant is simply a number. NASM allows you to specify
-numbers in a variety of number bases, in a variety of ways: you can
-suffix `H' or `X', `Q' or `O', and `B' for hexadecimal, octal and
-binary respectively, or you can prefix `0x' for hexadecimal in the
-style of C, or you can prefix `$' for hexadecimal in the style of
-Borland Pascal. Note, though, that the `$' prefix does double duty as a
-prefix on identifiers (see *note Section 3.1::), so a hex number
-prefixed with a `$' sign must have a digit after the `$' rather than a
-letter. In addition, current versions of NASM accept the prefix `0h'
-for hexadecimal, `0o' or `0q' for octal, and `0b' for binary. Please
-note that unlike C, a `0' prefix by itself does _not_ imply an octal
-constant!
-
- Numeric constants can have underscores (`_') interspersed to break up
-long strings.
-
- Some examples (all producing exactly the same code):
-
- mov ax,200 ; decimal
- mov ax,0200 ; still decimal
- mov ax,0200d ; explicitly decimal
- mov ax,0d200 ; also decimal
- mov ax,0c8h ; hex
- mov ax,$0c8 ; hex again: the 0 is required
- mov ax,0xc8 ; hex yet again
- mov ax,0hc8 ; still hex
- mov ax,310q ; octal
- mov ax,310o ; octal again
- mov ax,0o310 ; octal yet again
- mov ax,0q310 ; hex yet again
- mov ax,11001000b ; binary
- mov ax,1100_1000b ; same binary constant
- mov ax,0b1100_1000 ; same binary constant yet again
-
-
-File: nasm.info, Node: Section 3.4.2, Next: Section 3.4.3, Prev: Section 3.4.1, Up: Section 3.4
-
-3.4.2. Character Strings
-------------------------
-
-A character string consists of up to eight characters enclosed in either
-single quotes (`'...''), double quotes (`"..."') or backquotes
-(``...`'). Single or double quotes are equivalent to NASM (except of
-course that surrounding the constant with single quotes allows double
-quotes to appear within it and vice versa); the contents of those are
-represented verbatim. Strings enclosed in backquotes support C-style
-`\'-escapes for special characters.
-
- The following escape sequences are recognized by backquoted strings:
-
- \' single quote (')
- \" double quote (")
- \` backquote (`)
- \\ backslash (\)
- \? question mark (?)
- \a BEL (ASCII 7)
- \b BS (ASCII 8)
- \t TAB (ASCII 9)
- \n LF (ASCII 10)
- \v VT (ASCII 11)
- \f FF (ASCII 12)
- \r CR (ASCII 13)
- \e ESC (ASCII 27)
- \377 Up to 3 octal digits - literal byte
- \xFF Up to 2 hexadecimal digits - literal byte
- \u1234 4 hexadecimal digits - Unicode character
- \U12345678 8 hexadecimal digits - Unicode character
-
- All other escape sequences are reserved. Note that `\0', meaning a
-`NUL' character (ASCII 0), is a special case of the octal escape
-sequence.
-
- Unicode characters specified with `\u' or `\U' are converted to
-UTF-8. For example, the following lines are all equivalent:
-
- db `\u263a` ; UTF-8 smiley face
- db `\xe2\x98\xba` ; UTF-8 smiley face
- db 0E2h, 098h, 0BAh ; UTF-8 smiley face
-
-
-File: nasm.info, Node: Section 3.4.3, Next: Section 3.4.4, Prev: Section 3.4.2, Up: Section 3.4
-
-3.4.3. Character Constants
---------------------------
-
-A character constant consists of a string up to eight bytes long, used
-in an expression context. It is treated as if it was an integer.
-
- A character constant with more than one byte will be arranged with
-little-endian order in mind: if you code
-
- mov eax,'abcd'
-
- then the constant generated is not `0x61626364', but `0x64636261',
-so that if you were then to store the value into memory, it would read
-`abcd' rather than `dcba'. This is also the sense of character
-constants understood by the Pentium's `CPUID' instruction.
-
-
-File: nasm.info, Node: Section 3.4.4, Next: Section 3.4.5, Prev: Section 3.4.3, Up: Section 3.4
-
-3.4.4. String Constants
------------------------
-
-String constants are character strings used in the context of some
-pseudo- instructions, namely the `DB' family and `INCBIN' (where it
-represents a filename.) They are also used in certain preprocessor
-directives.
-
- A string constant looks like a character constant, only longer. It is
-treated as a concatenation of maximum-size character constants for the
-conditions. So the following are equivalent:
-
- db 'hello' ; string constant
- db 'h','e','l','l','o' ; equivalent character constants
-
- And the following are also equivalent:
-
- dd 'ninechars' ; doubleword string constant
- dd 'nine','char','s' ; becomes three doublewords
- db 'ninechars',0,0,0 ; and really looks like this
-
- Note that when used in a string-supporting context, quoted strings
-are treated as a string constants even if they are short enough to be a
-character constant, because otherwise `db 'ab'' would have the same
-effect as `db 'a'', which would be silly. Similarly, three-character or
-four-character constants are treated as strings when they are operands
-to `DW', and so forth.
-
-
-File: nasm.info, Node: Section 3.4.5, Next: Section 3.4.6, Prev: Section 3.4.4, Up: Section 3.4
-
-3.4.5. Unicode Strings
-----------------------
-
-The special operators `__utf16__' and `__utf32__' allows definition of
-Unicode strings. They take a string in UTF-8 format and converts it to
-(littleendian) UTF-16 or UTF-32, respectively.
-
- For example:
-
- %define u(x) __utf16__(x)
- %define w(x) __utf32__(x)
-
- dw u('C:\WINDOWS'), 0 ; Pathname in UTF-16
- dd w(`A + B = \u206a`), 0 ; String in UTF-32
-
- `__utf16__' and `__utf32__' can be applied either to strings passed
-to the `DB' family instructions, or to character constants in an
-expression context.
-
-
-File: nasm.info, Node: Section 3.4.6, Next: Section 3.4.7, Prev: Section 3.4.5, Up: Section 3.4
-
-3.4.6. Floating-Point Constants
--------------------------------
-
-Floating-point constants are acceptable only as arguments to `DB',
-`DW', `DD', `DQ', `DT', and `DO', or as arguments to the special
-operators `__float8__', `__float16__', `__float32__', `__float64__',
-`__float80m__', `__float80e__', `__float128l__', and `__float128h__'.
-
- Floating-point constants are expressed in the traditional form:
-digits, then a period, then optionally more digits, then optionally an
-`E' followed by an exponent. The period is mandatory, so that NASM can
-distinguish between `dd 1', which declares an integer constant, and `dd
-1.0' which declares a floating-point constant. NASM also support
-C99-style hexadecimal floating-point: `0x', hexadecimal digits, period,
-optionally more hexadeximal digits, then optionally a `P' followed by a
-_binary_ (not hexadecimal) exponent in decimal notation.
-
- Underscores to break up groups of digits are permitted in
-floating-point constants as well.
-
- Some examples:
-
- db -0.2 ; "Quarter precision"
- dw -0.5 ; IEEE 754r/SSE5 half precision
- dd 1.2 ; an easy one
- dd 1.222_222_222 ; underscores are permitted
- dd 0x1p+2 ; 1.0x2^2 = 4.0
- dq 0x1p+32 ; 1.0x2^32 = 4 294 967 296.0
- dq 1.e10 ; 10 000 000 000.0
- dq 1.e+10 ; synonymous with 1.e10
- dq 1.e-10 ; 0.000 000 000 1
- dt 3.141592653589793238462 ; pi
- do 1.e+4000 ; IEEE 754r quad precision
-
- The 8-bit "quarter-precision" floating-point format is
-sign:exponent:mantissa = 1:4:3 with an exponent bias of 7. This appears
-to be the most frequently used 8-bit floating-point format, although it
-is not covered by any formal standard. This is sometimes called a
-"minifloat."
-
- The special operators are used to produce floating-point numbers in
-other contexts. They produce the binary representation of a specific
-floating- point number as an integer, and can use anywhere integer
-constants are used in an expression. `__float80m__' and `__float80e__'
-produce the 64-bit mantissa and 16-bit exponent of an 80-bit
-floating-point number, and `__float128l__' and `__float128h__' produce
-the lower and upper 64-bit halves of a 128-bit floating-point number,
-respectively.
-
- For example:
-
- mov rax,__float64__(3.141592653589793238462)
-
- ... would assign the binary representation of pi as a 64-bit
-floating point number into `RAX'. This is exactly equivalent to:
-
- mov rax,0x400921fb54442d18
-
- NASM cannot do compile-time arithmetic on floating-point constants.
-This is because NASM is designed to be portable - although it always
-generates code to run on x86 processors, the assembler itself can run
-on any system with an ANSI C compiler. Therefore, the assembler cannot
-guarantee the presence of a floating-point unit capable of handling the
-Intel number formats, and so for NASM to be able to do floating
-arithmetic it would have to include its own complete set of
-floating-point routines, which would significantly increase the size of
-the assembler for very little benefit.
-
- The special tokens `__Infinity__', `__QNaN__' (or `__NaN__') and
-`__SNaN__' can be used to generate infinities, quiet NaNs, and
-signalling NaNs, respectively. These are normally used as macros:
-
- %define Inf __Infinity__
- %define NaN __QNaN__
-
- dq +1.5, -Inf, NaN ; Double-precision constants
-
-
-File: nasm.info, Node: Section 3.4.7, Next: Section 3.5, Prev: Section 3.4.6, Up: Section 3.4
-
-3.4.7. Packed BCD Constants
----------------------------
-
-x87-style packed BCD constants can be used in the same contexts as
-80-bit floating-point numbers. They are suffixed with `p' or prefixed
-with `0p', and can include up to 18 decimal digits.
-
- As with other numeric constants, underscores can be used to separate
-digits.
-
- For example:
-
- dt 12_345_678_901_245_678p
- dt -12_345_678_901_245_678p
- dt +0p33
- dt 33p
-
-
-File: nasm.info, Node: Section 3.5, Next: Section 3.5.1, Prev: Section 3.4.7, Up: Chapter 3
-
-3.5. Expressions
-================
-
-Expressions in NASM are similar in syntax to those in C. Expressions are
-evaluated as 64-bit integers which are then adjusted to the appropriate
-size.
-
- NASM supports two special tokens in expressions, allowing
-calculations to involve the current assembly position: the `$' and `$$'
-tokens. `$' evaluates to the assembly position at the beginning of the
-line containing the expression; so you can code an infinite loop using
-`JMP $'. `$$' evaluates to the beginning of the current section; so you
-can tell how far into the section you are by using `($-$$)'.
-
- The arithmetic operators provided by NASM are listed here, in
-increasing order of precedence.
-
-* Menu:
-
-* Section 3.5.1:: `|': Bitwise OR Operator
-* Section 3.5.2:: `^': Bitwise XOR Operator
-* Section 3.5.3:: `&': Bitwise AND Operator
-* Section 3.5.4:: `<<' and `>>': Bit Shift Operators
-* Section 3.5.5:: `+' and `-': Addition and Subtraction Operators
-* Section 3.5.6:: `*', `/', `//', `%' and `%%': Multiplication and Division
-* Section 3.5.7:: Unary Operators: `+', `-', `~', `!' and `SEG'
-
-
-File: nasm.info, Node: Section 3.5.1, Next: Section 3.5.2, Prev: Section 3.5, Up: Section 3.5
-
-3.5.1. `|': Bitwise OR Operator
--------------------------------
-
-The `|' operator gives a bitwise OR, exactly as performed by the `OR'
-machine instruction. Bitwise OR is the lowest-priority arithmetic
-operator supported by NASM.
-
-
-File: nasm.info, Node: Section 3.5.2, Next: Section 3.5.3, Prev: Section 3.5.1, Up: Section 3.5
-
-3.5.2. `^': Bitwise XOR Operator
---------------------------------
-
-`^' provides the bitwise XOR operation.
-
-
-File: nasm.info, Node: Section 3.5.3, Next: Section 3.5.4, Prev: Section 3.5.2, Up: Section 3.5
-
-3.5.3. `&': Bitwise AND Operator
---------------------------------
-
-`&' provides the bitwise AND operation.
-
-
-File: nasm.info, Node: Section 3.5.4, Next: Section 3.5.5, Prev: Section 3.5.3, Up: Section 3.5
-
-3.5.4. `<<' and `>>': Bit Shift Operators
------------------------------------------
-
-`<<' gives a bit-shift to the left, just as it does in C. So `5<<3'
-evaluates to 5 times 8, or 40. `>>' gives a bit-shift to the right; in
-NASM, such a shift is _always_ unsigned, so that the bits shifted in
-from the left-hand end are filled with zero rather than a
-sign-extension of the previous highest bit.
-
-
-File: nasm.info, Node: Section 3.5.5, Next: Section 3.5.6, Prev: Section 3.5.4, Up: Section 3.5
-
-3.5.5. `+' and `-': Addition and Subtraction Operators
-------------------------------------------------------
-
-The `+' and `-' operators do perfectly ordinary addition and
-subtraction.
-
-
-File: nasm.info, Node: Section 3.5.6, Next: Section 3.5.7, Prev: Section 3.5.5, Up: Section 3.5
-
-3.5.6. `*', `/', `//', `%' and `%%': Multiplication and Division
-----------------------------------------------------------------
-
-`*' is the multiplication operator. `/' and `//' are both division
-operators: `/' is unsigned division and `//' is signed division.
-Similarly, `%' and `%%' provide unsigned and signed modulo operators
-respectively.
-
- NASM, like ANSI C, provides no guarantees about the sensible
-operation of the signed modulo operator.
-
- Since the `%' character is used extensively by the macro
-preprocessor, you should ensure that both the signed and unsigned
-modulo operators are followed by white space wherever they appear.
-
-
-File: nasm.info, Node: Section 3.5.7, Next: Section 3.6, Prev: Section 3.5.6, Up: Section 3.5
-
-3.5.7. Unary Operators: `+', `-', `~', `!' and `SEG'
-----------------------------------------------------
-
-The highest-priority operators in NASM's expression grammar are those
-which only apply to one argument. `-' negates its operand, `+' does
-nothing (it's provided for symmetry with `-'), `~' computes the one's
-complement of its operand, `!' is the logical negation operator, and
-`SEG' provides the segment address of its operand (explained in more
-detail in *note Section 3.6::).
-
-
-File: nasm.info, Node: Section 3.6, Next: Section 3.7, Prev: Section 3.5.7, Up: Chapter 3
-
-3.6. `SEG' and `WRT'
-====================
-
-When writing large 16-bit programs, which must be split into multiple
-segments, it is often necessary to be able to refer to the segment part
-of the address of a symbol. NASM supports the `SEG' operator to perform
-this function.
-
- The `SEG' operator returns the _preferred_ segment base of a symbol,
-defined as the segment base relative to which the offset of the symbol
-makes sense. So the code
-
- mov ax,seg symbol
- mov es,ax
- mov bx,symbol
-
- will load `ES:BX' with a valid pointer to the symbol `symbol'.
-
- Things can be more complex than this: since 16-bit segments and
-groups may overlap, you might occasionally want to refer to some symbol
-using a different segment base from the preferred one. NASM lets you do
-this, by the use of the `WRT' (With Reference To) keyword. So you can
-do things like
-
- mov ax,weird_seg ; weird_seg is a segment base
- mov es,ax
- mov bx,symbol wrt weird_seg
-
- to load `ES:BX' with a different, but functionally equivalent,
-pointer to the symbol `symbol'.
-
- NASM supports far (inter-segment) calls and jumps by means of the
-syntax `call segment:offset', where `segment' and `offset' both
-represent immediate values. So to call a far procedure, you could code
-either of
-
- call (seg procedure):procedure
- call weird_seg:(procedure wrt weird_seg)
-
- (The parentheses are included for clarity, to show the intended
-parsing of the above instructions. They are not necessary in practice.)
-
- NASM supports the syntax `call far procedure' as a synonym for the
-first of the above usages. `JMP' works identically to `CALL' in these
-examples.
-
- To declare a far pointer to a data item in a data segment, you must
-code
-
- dw symbol, seg symbol
-
- NASM supports no convenient synonym for this, though you can always
-invent one using the macro processor.
-
-
-File: nasm.info, Node: Section 3.7, Next: Section 3.8, Prev: Section 3.6, Up: Chapter 3
-
-3.7. `STRICT': Inhibiting Optimization
-======================================
-
-When assembling with the optimizer set to level 2 or higher (see *note
-Section 2.1.22::), NASM will use size specifiers (`BYTE', `WORD',
-`DWORD', `QWORD', `TWORD', `OWORD' or `YWORD'), but will give them the
-smallest possible size. The keyword `STRICT' can be used to inhibit
-optimization and force a particular operand to be emitted in the
-specified size. For example, with the optimizer on, and in `BITS 16'
-mode,
-
- push dword 33
-
- is encoded in three bytes `66 6A 21', whereas
-
- push strict dword 33
-
- is encoded in six bytes, with a full dword immediate operand `66 68
-21 00 00 00'.
-
- With the optimizer off, the same code (six bytes) is generated
-whether the `STRICT' keyword was used or not.
-
-
-File: nasm.info, Node: Section 3.8, Next: Section 3.9, Prev: Section 3.7, Up: Chapter 3
-
-3.8. Critical Expressions
-=========================
-
-Although NASM has an optional multi-pass optimizer, there are some
-expressions which must be resolvable on the first pass. These are called
-_Critical Expressions_.
-
- The first pass is used to determine the size of all the assembled
-code and data, so that the second pass, when generating all the code,
-knows all the symbol addresses the code refers to. So one thing NASM
-can't handle is code whose size depends on the value of a symbol
-declared after the code in question. For example,
-
- times (label-$) db 0
- label: db 'Where am I?'
-
- The argument to `TIMES' in this case could equally legally evaluate
-to anything at all; NASM will reject this example because it cannot
-tell the size of the `TIMES' line when it first sees it. It will just
-as firmly reject the slightly paradoxical code
-
- times (label-$+1) db 0
- label: db 'NOW where am I?'
-
- in which _any_ value for the `TIMES' argument is by definition wrong!
-
- NASM rejects these examples by means of a concept called a _critical
-expression_, which is defined to be an expression whose value is
-required to be computable in the first pass, and which must therefore
-depend only on symbols defined before it. The argument to the `TIMES'
-prefix is a critical expression.
-
-
-File: nasm.info, Node: Section 3.9, Next: Chapter 4, Prev: Section 3.8, Up: Chapter 3
-
-3.9. Local Labels
-=================
-
-NASM gives special treatment to symbols beginning with a period. A label
-beginning with a single period is treated as a _local_ label, which
-means that it is associated with the previous non-local label. So, for
-example:
-
- label1 ; some code
-
- .loop
- ; some more code
-
- jne .loop
- ret
-
- label2 ; some code
-
- .loop
- ; some more code
-
- jne .loop
- ret
-
- In the above code fragment, each `JNE' instruction jumps to the line
-immediately before it, because the two definitions of `.loop' are kept
-separate by virtue of each being associated with the previous non-local
-label.
-
- This form of local label handling is borrowed from the old Amiga
-assembler DevPac; however, NASM goes one step further, in allowing
-access to local labels from other parts of the code. This is achieved
-by means of _defining_ a local label in terms of the previous non-local
-label: the first definition of `.loop' above is really defining a
-symbol called `label1.loop', and the second defines a symbol called
-`label2.loop'. So, if you really needed to, you could write
-
- label3 ; some more code
- ; and some more
-
- jmp label1.loop
-
- Sometimes it is useful - in a macro, for instance - to be able to
-define a label which can be referenced from anywhere but which doesn't
-interfere with the normal local-label mechanism. Such a label can't be
-non-local because it would interfere with subsequent definitions of,
-and references to, local labels; and it can't be local because the
-macro that defined it wouldn't know the label's full name. NASM
-therefore introduces a third type of label, which is probably only
-useful in macro definitions: if a label begins with the special prefix
-`..@', then it does nothing to the local label mechanism. So you could
-code
-
- label1: ; a non-local label
- .local: ; this is really label1.local
- ..@foo: ; this is a special symbol
- label2: ; another non-local label
- .local: ; this is really label2.local
-
- jmp ..@foo ; this will jump three lines up
-
- NASM has the capacity to define other special symbols beginning with
-a double period: for example, `..start' is used to specify the entry
-point in the `obj' output format (see *note Section 7.4.6::).
-
-
-File: nasm.info, Node: Chapter 4, Next: Section 4.1, Prev: Section 3.9, Up: Top
-
-Chapter 4: The NASM Preprocessor
-********************************
-
-NASM contains a powerful macro processor, which supports conditional
-assembly, multi-level file inclusion, two forms of macro (single-line
-and multi-line), and a `context stack' mechanism for extra macro power.
-Preprocessor directives all begin with a `%' sign.
-
- The preprocessor collapses all lines which end with a backslash (\)
-character into a single line. Thus:
-
- %define THIS_VERY_LONG_MACRO_NAME_IS_DEFINED_TO \
- THIS_VALUE
-
- will work like a single-line macro without the backslash-newline
-sequence.
-
-* Menu:
-
-* Section 4.1:: Single-Line Macros
-* Section 4.2:: String Manipulation in Macros
-* Section 4.3:: Multi-Line Macros: `%macro'
-* Section 4.4:: Conditional Assembly
-* Section 4.5:: Preprocessor Loops: `%rep'
-* Section 4.6:: Source Files and Dependencies
-* Section 4.7:: The Context Stack
-* Section 4.8:: Stack Relative Preprocessor Directives
-* Section 4.9:: Reporting User-Defined Errors: `%error', `%warning', `%fatal'
-* Section 4.10:: Other Preprocessor Directives
-* Section 4.11:: Standard Macros
-
-
-File: nasm.info, Node: Section 4.1, Next: Section 4.1.1, Prev: Chapter 4, Up: Chapter 4
-
-4.1. Single-Line Macros
-=======================
-
-* Menu:
-
-* Section 4.1.1:: The Normal Way: `%define'
-* Section 4.1.2:: Resolving `%define': `%xdefine'
-* Section 4.1.3:: Macro Indirection: `%[...]'
-* Section 4.1.4:: Concatenating Single Line Macro Tokens: `%+'
-* Section 4.1.5:: The Macro Name Itself: `%?' and `%??'
-* Section 4.1.6:: Undefining Single-Line Macros: `%undef'
-* Section 4.1.7:: Preprocessor Variables: `%assign'
-* Section 4.1.8:: Defining Strings: `%defstr'
-* Section 4.1.9:: Defining Tokens: `%deftok'
-
-
-File: nasm.info, Node: Section 4.1.1, Next: Section 4.1.2, Prev: Section 4.1, Up: Section 4.1
-
-4.1.1. The Normal Way: `%define'
---------------------------------
-
-Single-line macros are defined using the `%define' preprocessor
-directive. The definitions work in a similar way to C; so you can do
-things like
-
- %define ctrl 0x1F &
- %define param(a,b) ((a)+(a)*(b))
-
- mov byte [param(2,ebx)], ctrl 'D'
-
- which will expand to
-
- mov byte [(2)+(2)*(ebx)], 0x1F & 'D'
-
- When the expansion of a single-line macro contains tokens which
-invoke another macro, the expansion is performed at invocation time,
-not at definition time. Thus the code
-
- %define a(x) 1+b(x)
- %define b(x) 2*x
-
- mov ax,a(8)
-
- will evaluate in the expected way to `mov ax,1+2*8', even though the
-macro `b' wasn't defined at the time of definition of `a'.
-
- Macros defined with `%define' are case sensitive: after `%define foo
-bar', only `foo' will expand to `bar': `Foo' or `FOO' will not. By
-using `%idefine' instead of `%define' (the `i' stands for
-`insensitive') you can define all the case variants of a macro at once,
-so that `%idefine foo bar' would cause `foo', `Foo', `FOO', `fOO' and
-so on all to expand to `bar'.
-
- There is a mechanism which detects when a macro call has occurred as
-a result of a previous expansion of the same macro, to guard against
-circular references and infinite loops. If this happens, the
-preprocessor will only expand the first occurrence of the macro. Hence,
-if you code
-
- %define a(x) 1+a(x)
-
- mov ax,a(3)
-
- the macro `a(3)' will expand once, becoming `1+a(3)', and will then
-expand no further. This behaviour can be useful: see *note Section 9.1::
-for an example of its use.
-
- You can overload single-line macros: if you write
-
- %define foo(x) 1+x
- %define foo(x,y) 1+x*y
-
- the preprocessor will be able to handle both types of macro call, by
-counting the parameters you pass; so `foo(3)' will become `1+3' whereas
-`foo(ebx,2)' will become `1+ebx*2'. However, if you define
-
- %define foo bar
-
- then no other definition of `foo' will be accepted: a macro with no
-parameters prohibits the definition of the same name as a macro _with_
-parameters, and vice versa.
-
- This doesn't prevent single-line macros being _redefined_: you can
-perfectly well define a macro with
-
- %define foo bar
-
- and then re-define it later in the same source file with
-
- %define foo baz
-
- Then everywhere the macro `foo' is invoked, it will be expanded
-according to the most recent definition. This is particularly useful
-when defining single-line macros with `%assign' (see *note Section
-4.1.7::).
-
- You can pre-define single-line macros using the `-d' option on the
-NASM command line: see *note Section 2.1.18::.
-
-
-File: nasm.info, Node: Section 4.1.2, Next: Section 4.1.3, Prev: Section 4.1.1, Up: Section 4.1
-
-4.1.2. Resolving `%define': `%xdefine'
---------------------------------------
-
-To have a reference to an embedded single-line macro resolved at the
-time that the embedding macro is _defined_, as opposed to when the
-embedding macro is _expanded_, you need a different mechanism to the
-one offered by `%define'. The solution is to use `%xdefine', or it's
-case-insensitive counterpart `%ixdefine'.
-
- Suppose you have the following code:
-
- %define isTrue 1
- %define isFalse isTrue
- %define isTrue 0
-
- val1: db isFalse
-
- %define isTrue 1
-
- val2: db isFalse
-
- In this case, `val1' is equal to 0, and `val2' is equal to 1. This
-is because, when a single-line macro is defined using `%define', it is
-expanded only when it is called. As `isFalse' expands to `isTrue', the
-expansion will be the current value of `isTrue'. The first time it is
-called that is 0, and the second time it is 1.
-
- If you wanted `isFalse' to expand to the value assigned to the
-embedded macro `isTrue' at the time that `isFalse' was defined, you
-need to change the above code to use `%xdefine'.
-
- %xdefine isTrue 1
- %xdefine isFalse isTrue
- %xdefine isTrue 0
-
- val1: db isFalse
-
- %xdefine isTrue 1
-
- val2: db isFalse
-
- Now, each time that `isFalse' is called, it expands to 1, as that is
-what the embedded macro `isTrue' expanded to at the time that `isFalse'
-was defined.
-
-
-File: nasm.info, Node: Section 4.1.3, Next: Section 4.1.4, Prev: Section 4.1.2, Up: Section 4.1
-
-4.1.3. Macro Indirection: `%[...]'
-----------------------------------
-
-The `%[...]' construct can be used to expand macros in contexts where
-macro expansion would otherwise not occur, including in the names other
-macros. For example, if you have a set of macros named `Foo16', `Foo32'
-and `Foo64', you could write:
-
- mov ax,Foo%[__BITS__] ; The Foo value
-
- to use the builtin macro `__BITS__' (see *note Section 4.11.5::) to
-automatically select between them. Similarly, the two statements:
-
- %xdefine Bar Quux ; Expands due to %xdefine
- %define Bar %[Quux] ; Expands due to %[...]
-
- have, in fact, exactly the same effect.
-
- `%[...]' concatenates to adjacent tokens in the same way that multi-
-line macro parameters do, see *note Section 4.3.8:: for details.
-
-
-File: nasm.info, Node: Section 4.1.4, Next: Section 4.1.5, Prev: Section 4.1.3, Up: Section 4.1
-
-4.1.4. Concatenating Single Line Macro Tokens: `%+'
----------------------------------------------------
-
-Individual tokens in single line macros can be concatenated, to produce
-longer tokens for later processing. This can be useful if there are
-several similar macros that perform similar functions.
-
- Please note that a space is required after `%+', in order to
-disambiguate it from the syntax `%+1' used in multiline macros.
-
- As an example, consider the following:
-
- %define BDASTART 400h ; Start of BIOS data area
-
- struc tBIOSDA ; its structure
- .COM1addr RESW 1
- .COM2addr RESW 1
- ; ..and so on
- endstruc
-
- Now, if we need to access the elements of tBIOSDA in different
-places, we can end up with:
-
- mov ax,BDASTART + tBIOSDA.COM1addr
- mov bx,BDASTART + tBIOSDA.COM2addr
-
- This will become pretty ugly (and tedious) if used in many places,
-and can be reduced in size significantly by using the following macro:
-
- ; Macro to access BIOS variables by their names (from tBDA):
-
- %define BDA(x) BDASTART + tBIOSDA. %+ x
-
- Now the above code can be written as:
-
- mov ax,BDA(COM1addr)
- mov bx,BDA(COM2addr)
-
- Using this feature, we can simplify references to a lot of macros
-(and, in turn, reduce typing errors).
-
-
-File: nasm.info, Node: Section 4.1.5, Next: Section 4.1.6, Prev: Section 4.1.4, Up: Section 4.1
-
-4.1.5. The Macro Name Itself: `%?' and `%??'
---------------------------------------------
-
-The special symbols `%?' and `%??' can be used to reference the macro
-name itself inside a macro expansion, this is supported for both
-single-and multi-line macros. `%?' refers to the macro name as
-_invoked_, whereas `%??' refers to the macro name as _declared_. The
-two are always the same for case-sensitive macros, but for
-case-insensitive macros, they can differ.
-
- For example:
-
- %idefine Foo mov %?,%??
-
- foo
- FOO
-
- will expand to:
-
- mov foo,Foo
- mov FOO,Foo
-
- The sequence:
-
- %idefine keyword $%?
-
- can be used to make a keyword "disappear", for example in case a new
-instruction has been used as a label in older code. For example:
-
- %idefine pause $%? ; Hide the PAUSE instruction
-
-
-File: nasm.info, Node: Section 4.1.6, Next: Section 4.1.7, Prev: Section 4.1.5, Up: Section 4.1
-
-4.1.6. Undefining Single-Line Macros: `%undef'
-----------------------------------------------
-
-Single-line macros can be removed with the `%undef' directive. For
-example, the following sequence:
-
- %define foo bar
- %undef foo
-
- mov eax, foo
-
- will expand to the instruction `mov eax, foo', since after `%undef'
-the macro `foo' is no longer defined.
-
- Macros that would otherwise be pre-defined can be undefined on the
-command- line using the `-u' option on the NASM command line: see *note
-Section 2.1.19::.
-
-
-File: nasm.info, Node: Section 4.1.7, Next: Section 4.1.8, Prev: Section 4.1.6, Up: Section 4.1
-
-4.1.7. Preprocessor Variables: `%assign'
-----------------------------------------
-
-An alternative way to define single-line macros is by means of the
-`%assign' command (and its case-insensitive counterpart `%iassign',
-which differs from `%assign' in exactly the same way that `%idefine'
-differs from `%define').
-
- `%assign' is used to define single-line macros which take no
-parameters and have a numeric value. This value can be specified in the
-form of an expression, and it will be evaluated once, when the
-`%assign' directive is processed.
-
- Like `%define', macros defined using `%assign' can be re-defined
-later, so you can do things like
-
- %assign i i+1
-
- to increment the numeric value of a macro.
-
- `%assign' is useful for controlling the termination of `%rep'
-preprocessor loops: see *note Section 4.5:: for an example of this.
-Another use for `%assign' is given in *note Section 8.4:: and *note
-Section 9.1::.
-
- The expression passed to `%assign' is a critical expression (see
-*note Section 3.8::), and must also evaluate to a pure number (rather
-than a relocatable reference such as a code or data address, or
-anything involving a register).
-
-
-File: nasm.info, Node: Section 4.1.8, Next: Section 4.1.9, Prev: Section 4.1.7, Up: Section 4.1
-
-4.1.8. Defining Strings: `%defstr'
-----------------------------------
-
-`%defstr', and its case-insensitive counterpart `%idefstr', define or
-redefine a single-line macro without parameters but converts the entire
-right-hand side, after macro expansion, to a quoted string before
-definition.
-
- For example:
-
- %defstr test TEST
-
- is equivalent to
-
- %define test 'TEST'
-
- This can be used, for example, with the `%!' construct (see *note
-Section 4.10.2::):
-
- %defstr PATH %!PATH ; The operating system PATH variable
-
-
-File: nasm.info, Node: Section 4.1.9, Next: Section 4.2, Prev: Section 4.1.8, Up: Section 4.1
-
-4.1.9. Defining Tokens: `%deftok'
----------------------------------
-
-`%deftok', and its case-insensitive counterpart `%ideftok', define or
-redefine a single-line macro without parameters but converts the second
-parameter, after string conversion, to a sequence of tokens.
-
- For example:
-
- %deftok test 'TEST'
-
- is equivalent to
-
- %define test TEST
-
-
-File: nasm.info, Node: Section 4.2, Next: Section 4.2.1, Prev: Section 4.1.9, Up: Chapter 4
-
-4.2. String Manipulation in Macros
-==================================
-
-It's often useful to be able to handle strings in macros. NASM supports
-a few simple string handling macro operators from which more complex
-operations can be constructed.
-
- All the string operators define or redefine a value (either a string
-or a numeric value) to a single-line macro. When producing a string
-value, it may change the style of quoting of the input string or
-strings, and possibly use `\'-escapes inside ``'-quoted strings.
-
-* Menu:
-
-* Section 4.2.1:: Concatenating Strings: `%strcat'
-* Section 4.2.2:: String Length: `%strlen'
-* Section 4.2.3:: Extracting Substrings: `%substr'
-
-
-File: nasm.info, Node: Section 4.2.1, Next: Section 4.2.2, Prev: Section 4.2, Up: Section 4.2
-
-4.2.1. Concatenating Strings: `%strcat'
----------------------------------------
-
-The `%strcat' operator concatenates quoted strings and assign them to a
-single-line macro.
-
- For example:
-
- %strcat alpha "Alpha: ", '12" screen'
-
- ... would assign the value `'Alpha: 12" screen'' to `alpha'.
-Similarly:
-
- %strcat beta '"foo"\', "'bar'"
-
- ... would assign the value ``"foo"\\'bar'`' to `beta'.
-
- The use of commas to separate strings is permitted but optional.
-
-
-File: nasm.info, Node: Section 4.2.2, Next: Section 4.2.3, Prev: Section 4.2.1, Up: Section 4.2
-
-4.2.2. String Length: `%strlen'
--------------------------------
-
-The `%strlen' operator assigns the length of a string to a macro. For
-example:
-
- %strlen charcnt 'my string'
-
- In this example, `charcnt' would receive the value 9, just as if an
-`%assign' had been used. In this example, `'my string'' was a literal
-string but it could also have been a single-line macro that expands to
-a string, as in the following example:
-
- %define sometext 'my string'
- %strlen charcnt sometext
-
- As in the first case, this would result in `charcnt' being assigned
-the value of 9.
-
-
-File: nasm.info, Node: Section 4.2.3, Next: Section 4.3, Prev: Section 4.2.2, Up: Section 4.2
-
-4.2.3. Extracting Substrings: `%substr'
----------------------------------------
-
-Individual letters or substrings in strings can be extracted using the
-`%substr' operator. An example of its use is probably more useful than
-the description:
-
- %substr mychar 'xyzw' 1 ; equivalent to %define mychar 'x'
- %substr mychar 'xyzw' 2 ; equivalent to %define mychar 'y'
- %substr mychar 'xyzw' 3 ; equivalent to %define mychar 'z'
- %substr mychar 'xyzw' 2,2 ; equivalent to %define mychar 'yz'
- %substr mychar 'xyzw' 2,-1 ; equivalent to %define mychar 'yzw'
- %substr mychar 'xyzw' 2,-2 ; equivalent to %define mychar 'yz'
-
- As with `%strlen' (see *note Section 4.2.2::), the first parameter is
-the single-line macro to be created and the second is the string. The
-third parameter specifies the first character to be selected, and the
-optional fourth parameter preceeded by comma) is the length. Note that
-the first index is 1, not 0 and the last index is equal to the value
-that `%strlen' would assign given the same string. Index values out of
-range result in an empty string. A negative length means "until N-1
-characters before the end of string", i.e. `-1' means until end of
-string, `-2' until one character before, etc.
-
-
-File: nasm.info, Node: Section 4.3, Next: Section 4.3.1, Prev: Section 4.2.3, Up: Chapter 4
-
-4.3. Multi-Line Macros: `%macro'
-================================
-
-Multi-line macros are much more like the type of macro seen in MASM and
-TASM: a multi-line macro definition in NASM looks something like this.
-
- %macro prologue 1
-
- push ebp
- mov ebp,esp
- sub esp,%1
-
- %endmacro
-
- This defines a C-like function prologue as a macro: so you would
-invoke the macro with a call such as
-
- myfunc: prologue 12
-
- which would expand to the three lines of code
-
- myfunc: push ebp
- mov ebp,esp
- sub esp,12
-
- The number `1' after the macro name in the `%macro' line defines the
-number of parameters the macro `prologue' expects to receive. The use
-of `%1' inside the macro definition refers to the first parameter to
-the macro call. With a macro taking more than one parameter, subsequent
-parameters would be referred to as `%2', `%3' and so on.
-
- Multi-line macros, like single-line macros, are case-sensitive,
-unless you define them using the alternative directive `%imacro'.
-
- If you need to pass a comma as _part_ of a parameter to a multi-line
-macro, you can do that by enclosing the entire parameter in braces. So
-you could code things like
-
- %macro silly 2
-
- %2: db %1
-
- %endmacro
-
- silly 'a', letter_a ; letter_a: db 'a'
- silly 'ab', string_ab ; string_ab: db 'ab'
- silly {13,10}, crlf ; crlf: db 13,10
-
-* Menu:
-
-* Section 4.3.1:: Recursive Multi-Line Macros: `%rmacro'
-* Section 4.3.2:: Overloading Multi-Line Macros
-* Section 4.3.3:: Macro-Local Labels
-* Section 4.3.4:: Greedy Macro Parameters
-* Section 4.3.5:: Default Macro Parameters
-* Section 4.3.6:: `%0': Macro Parameter Counter
-* Section 4.3.7:: `%rotate': Rotating Macro Parameters
-* Section 4.3.8:: Concatenating Macro Parameters
-* Section 4.3.9:: Condition Codes as Macro Parameters
-* Section 4.3.10:: Disabling Listing Expansion
-* Section 4.3.11:: Undefining Multi-Line Macros: `%unmacro'
-* Section 4.3.12:: Exiting Multi-Line Macros: `%exitmacro'
-
-
-File: nasm.info, Node: Section 4.3.1, Next: Section 4.3.2, Prev: Section 4.3, Up: Section 4.3
-
-4.3.1. Recursive Multi-Line Macros: `%rmacro'
----------------------------------------------
-
-A multi-line macro cannot be referenced within itself, in order to
-prevent accidental infinite recursion.
-
- Recursive multi-line macros allow for self-referencing, with the
-caveat that the user is aware of the existence, use and purpose of
-recursive multi-line macros. There is also a generous, but sane, upper
-limit to the number of recursions, in order to prevent run-away memory
-consumption in case of accidental infinite recursion.
-
- As with non-recursive multi-line macros, recursive multi-line macros
-are case-sensitive, unless you define them using the alternative
-directive `%irmacro'.
-
-
-File: nasm.info, Node: Section 4.3.2, Next: Section 4.3.3, Prev: Section 4.3.1, Up: Section 4.3
-
-4.3.2. Overloading Multi-Line Macros
-------------------------------------
-
-As with single-line macros, multi-line macros can be overloaded by
-defining the same macro name several times with different numbers of
-parameters. This time, no exception is made for macros with no
-parameters at all. So you could define
-
- %macro prologue 0
-
- push ebp
- mov ebp,esp
-
- %endmacro
-
- to define an alternative form of the function prologue which
-allocates no local stack space.
-
- Sometimes, however, you might want to `overload' a machine
-instruction; for example, you might want to define
-
- %macro push 2
-
- push %1
- push %2
-
- %endmacro
-
- so that you could code
-
- push ebx ; this line is not a macro call
- push eax,ecx ; but this one is
-
- Ordinarily, NASM will give a warning for the first of the above two
-lines, since `push' is now defined to be a macro, and is being invoked
-with a number of parameters for which no definition has been given. The
-correct code will still be generated, but the assembler will give a
-warning. This warning can be disabled by the use of the
-`-w-macro-params' command- line option (see *note Section 2.1.24::).
-
-
-File: nasm.info, Node: Section 4.3.3, Next: Section 4.3.4, Prev: Section 4.3.2, Up: Section 4.3
-
-4.3.3. Macro-Local Labels
--------------------------
-
-NASM allows you to define labels within a multi-line macro definition in
-such a way as to make them local to the macro call: so calling the same
-macro multiple times will use a different label each time. You do this
-by prefixing `%%' to the label name. So you can invent an instruction
-which executes a `RET' if the `Z' flag is set by doing this:
-
- %macro retz 0
-
- jnz %%skip
- ret
- %%skip:
-
- %endmacro
-
- You can call this macro as many times as you want, and every time
-you call it NASM will make up a different `real' name to substitute for
-the label `%%skip'. The names NASM invents are of the form
-`..@2345.skip', where the number 2345 changes with every macro call.
-The `..@' prefix prevents macro-local labels from interfering with the
-local label mechanism, as described in *note Section 3.9::. You should
-avoid defining your own labels in this form (the `..@' prefix, then a
-number, then another period) in case they interfere with macro-local
-labels.
-
-
-File: nasm.info, Node: Section 4.3.4, Next: Section 4.3.5, Prev: Section 4.3.3, Up: Section 4.3
-
-4.3.4. Greedy Macro Parameters
-------------------------------
-
-Occasionally it is useful to define a macro which lumps its entire
-command line into one parameter definition, possibly after extracting
-one or two smaller parameters from the front. An example might be a
-macro to write a text string to a file in MS-DOS, where you might want
-to be able to write
-
- writefile [filehandle],"hello, world",13,10
-
- NASM allows you to define the last parameter of a macro to be
-_greedy_, meaning that if you invoke the macro with more parameters
-than it expects, all the spare parameters get lumped into the last
-defined one along with the separating commas. So if you code:
-
- %macro writefile 2+
-
- jmp %%endstr
- %%str: db %2
- %%endstr:
- mov dx,%%str
- mov cx,%%endstr-%%str
- mov bx,%1
- mov ah,0x40
- int 0x21
-
- %endmacro
-
- then the example call to `writefile' above will work as expected: the
-text before the first comma, `[filehandle]', is used as the first macro
-parameter and expanded when `%1' is referred to, and all the subsequent
-text is lumped into `%2' and placed after the `db'.
-
- The greedy nature of the macro is indicated to NASM by the use of the
-`+' sign after the parameter count on the `%macro' line.
-
- If you define a greedy macro, you are effectively telling NASM how it
-should expand the macro given _any_ number of parameters from the
-actual number specified up to infinity; in this case, for example, NASM
-now knows what to do when it sees a call to `writefile' with 2, 3, 4 or
-more parameters. NASM will take this into account when overloading
-macros, and will not allow you to define another form of `writefile'
-taking 4 parameters (for example).
-
- Of course, the above macro could have been implemented as a
-non-greedy macro, in which case the call to it would have had to look
-like
-
- writefile [filehandle], {"hello, world",13,10}
-
- NASM provides both mechanisms for putting commas in macro
-parameters, and you choose which one you prefer for each macro
-definition.
-
- See *note Section 6.3.1:: for a better way to write the above macro.
-
-
-File: nasm.info, Node: Section 4.3.5, Next: Section 4.3.6, Prev: Section 4.3.4, Up: Section 4.3
-
-4.3.5. Default Macro Parameters
--------------------------------
-
-NASM also allows you to define a multi-line macro with a _range_ of
-allowable parameter counts. If you do this, you can specify defaults for
-omitted parameters. So, for example:
-
- %macro die 0-1 "Painful program death has occurred."
-
- writefile 2,%1
- mov ax,0x4c01
- int 0x21
-
- %endmacro
-
- This macro (which makes use of the `writefile' macro defined in
-*note Section 4.3.4::) can be called with an explicit error message,
-which it will display on the error output stream before exiting, or it
-can be called with no parameters, in which case it will use the default
-error message supplied in the macro definition.
-
- In general, you supply a minimum and maximum number of parameters
-for a macro of this type; the minimum number of parameters are then
-required in the macro call, and then you provide defaults for the
-optional ones. So if a macro definition began with the line
-
- %macro foobar 1-3 eax,[ebx+2]
-
- then it could be called with between one and three parameters, and
-`%1' would always be taken from the macro call. `%2', if not specified
-by the macro call, would default to `eax', and `%3' if not specified
-would default to `[ebx+2]'.
-
- You can provide extra information to a macro by providing too many
-default parameters:
-
- %macro quux 1 something
-
- This will trigger a warning by default; see *note Section 2.1.24::
-for more information. When `quux' is invoked, it receives not one but
-two parameters. `something' can be referred to as `%2'. The difference
-between passing `something' this way and writing `something' in the
-macro body is that with this way `something' is evaluated when the
-macro is defined, not when it is expanded.
-
- You may omit parameter defaults from the macro definition, in which
-case the parameter default is taken to be blank. This can be useful for
-macros which can take a variable number of parameters, since the `%0'
-token (see *note Section 4.3.6::) allows you to determine how many
-parameters were really passed to the macro call.
-
- This defaulting mechanism can be combined with the greedy-parameter
-mechanism; so the `die' macro above could be made more powerful, and
-more useful, by changing the first line of the definition to
-
- %macro die 0-1+ "Painful program death has occurred.",13,10
-
- The maximum parameter count can be infinite, denoted by `*'. In this
-case, of course, it is impossible to provide a _full_ set of default
-parameters. Examples of this usage are shown in *note Section 4.3.7::.
-
-
-File: nasm.info, Node: Section 4.3.6, Next: Section 4.3.7, Prev: Section 4.3.5, Up: Section 4.3
-
-4.3.6. `%0': Macro Parameter Counter
-------------------------------------
-
-The parameter reference `%0' will return a numeric constant giving the
-number of parameters received, that is, if `%0' is n then `%'n is the
-last parameter. `%0' is mostly useful for macros that can take a
-variable number of parameters. It can be used as an argument to `%rep'
-(see *note Section 4.5::) in order to iterate through all the
-parameters of a macro. Examples are given in *note Section 4.3.7::.
-
-
-File: nasm.info, Node: Section 4.3.7, Next: Section 4.3.8, Prev: Section 4.3.6, Up: Section 4.3
-
-4.3.7. `%rotate': Rotating Macro Parameters
--------------------------------------------
-
-Unix shell programmers will be familiar with the `shift' shell command,
-which allows the arguments passed to a shell script (referenced as
-`$1', `$2' and so on) to be moved left by one place, so that the
-argument previously referenced as `$2' becomes available as `$1', and
-the argument previously referenced as `$1' is no longer available at
-all.
-
- NASM provides a similar mechanism, in the form of `%rotate'. As its
-name suggests, it differs from the Unix `shift' in that no parameters
-are lost: parameters rotated off the left end of the argument list
-reappear on the right, and vice versa.
-
- `%rotate' is invoked with a single numeric argument (which may be an
-expression). The macro parameters are rotated to the left by that many
-places. If the argument to `%rotate' is negative, the macro parameters
-are rotated to the right.
-
- So a pair of macros to save and restore a set of registers might
-work as follows:
-
- %macro multipush 1-*
-
- %rep %0
- push %1
- %rotate 1
- %endrep
-
- %endmacro
-
- This macro invokes the `PUSH' instruction on each of its arguments in
-turn, from left to right. It begins by pushing its first argument,
-`%1', then invokes `%rotate' to move all the arguments one place to the
-left, so that the original second argument is now available as `%1'.
-Repeating this procedure as many times as there were arguments
-(achieved by supplying `%0' as the argument to `%rep') causes each
-argument in turn to be pushed.
-
- Note also the use of `*' as the maximum parameter count, indicating
-that there is no upper limit on the number of parameters you may supply
-to the `multipush' macro.
-
- It would be convenient, when using this macro, to have a `POP'
-equivalent, which _didn't_ require the arguments to be given in reverse
-order. Ideally, you would write the `multipush' macro call, then
-cut-and-paste the line to where the pop needed to be done, and change
-the name of the called macro to `multipop', and the macro would take
-care of popping the registers in the opposite order from the one in
-which they were pushed.
-
- This can be done by the following definition:
-
- %macro multipop 1-*
-
- %rep %0
- %rotate -1
- pop %1
- %endrep
-
- %endmacro
-
- This macro begins by rotating its arguments one place to the _right_,
-so that the original _last_ argument appears as `%1'. This is then
-popped, and the arguments are rotated right again, so the second-to-
-last argument becomes `%1'. Thus the arguments are iterated through in
-reverse order.
-
-
-File: nasm.info, Node: Section 4.3.8, Next: Section 4.3.9, Prev: Section 4.3.7, Up: Section 4.3
-
-4.3.8. Concatenating Macro Parameters
--------------------------------------
-
-NASM can concatenate macro parameters and macro indirection constructs
-on to other text surrounding them. This allows you to declare a family
-of symbols, for example, in a macro definition. If, for example, you
-wanted to generate a table of key codes along with offsets into the
-table, you could code something like
-
- %macro keytab_entry 2
-
- keypos%1 equ $-keytab
- db %2
-
- %endmacro
-
- keytab:
- keytab_entry F1,128+1
- keytab_entry F2,128+2
- keytab_entry Return,13
-
- which would expand to
-
- keytab:
- keyposF1 equ $-keytab
- db 128+1
- keyposF2 equ $-keytab
- db 128+2
- keyposReturn equ $-keytab
- db 13
-
- You can just as easily concatenate text on to the other end of a
-macro parameter, by writing `%1foo'.
-
- If you need to append a _digit_ to a macro parameter, for example
-defining labels `foo1' and `foo2' when passed the parameter `foo', you
-can't code `%11' because that would be taken as the eleventh macro
-parameter. Instead, you must code `%{1}1', which will separate the
-first `1' (giving the number of the macro parameter) from the second
-(literal text to be concatenated to the parameter).
-
- This concatenation can also be applied to other preprocessor in-line
-objects, such as macro-local labels (*note Section 4.3.3::) and
-context-local labels (*note Section 4.7.2::). In all cases, ambiguities
-in syntax can be resolved by enclosing everything after the `%' sign
-and before the literal text in braces: so `%{%foo}bar' concatenates the
-text `bar' to the end of the real name of the macro-local label
-`%%foo'. (This is unnecessary, since the form NASM uses for the real
-names of macro-local labels means that the two usages `%{%foo}bar' and
-`%%foobar' would both expand to the same thing anyway; nevertheless,
-the capability is there.)
-
- The single-line macro indirection construct, `%[...]' (*note Section
-4.1.3::), behaves the same way as macro parameters for the purpose of
-concatenation.
-
- See also the `%+' operator, *note Section 4.1.4::.
-
-
-File: nasm.info, Node: Section 4.3.9, Next: Section 4.3.10, Prev: Section 4.3.8, Up: Section 4.3
-
-4.3.9. Condition Codes as Macro Parameters
-------------------------------------------
-
-NASM can give special treatment to a macro parameter which contains a
-condition code. For a start, you can refer to the macro parameter `%1'
-by means of the alternative syntax `%+1', which informs NASM that this
-macro parameter is supposed to contain a condition code, and will cause
-the preprocessor to report an error message if the macro is called with
-a parameter which is _not_ a valid condition code.
-
- Far more usefully, though, you can refer to the macro parameter by
-means of `%-1', which NASM will expand as the _inverse_ condition code.
-So the `retz' macro defined in *note Section 4.3.3:: can be replaced by
-a general conditional-return macro like this:
-
- %macro retc 1
-
- j%-1 %%skip
- ret
- %%skip:
-
- %endmacro
-
- This macro can now be invoked using calls like `retc ne', which will
-cause the conditional-jump instruction in the macro expansion to come
-out as `JE', or `retc po' which will make the jump a `JPE'.
-
- The `%+1' macro-parameter reference is quite happy to interpret the
-arguments `CXZ' and `ECXZ' as valid condition codes; however, `%-1'
-will report an error if passed either of these, because no inverse
-condition code exists.
-
-
-File: nasm.info, Node: Section 4.3.10, Next: Section 4.3.11, Prev: Section 4.3.9, Up: Section 4.3
-
-4.3.10. Disabling Listing Expansion
------------------------------------
-
-When NASM is generating a listing file from your program, it will
-generally expand multi-line macros by means of writing the macro call
-and then listing each line of the expansion. This allows you to see
-which instructions in the macro expansion are generating what code;
-however, for some macros this clutters the listing up unnecessarily.
-
- NASM therefore provides the `.nolist' qualifier, which you can
-include in a macro definition to inhibit the expansion of the macro in
-the listing file. The `.nolist' qualifier comes directly after the
-number of parameters, like this:
-
- %macro foo 1.nolist
-
- Or like this:
-
- %macro bar 1-5+.nolist a,b,c,d,e,f,g,h
-
-
-File: nasm.info, Node: Section 4.3.11, Next: Section 4.3.12, Prev: Section 4.3.10, Up: Section 4.3
-
-4.3.11. Undefining Multi-Line Macros: `%unmacro'
-------------------------------------------------
-
-Multi-line macros can be removed with the `%unmacro' directive. Unlike
-the `%undef' directive, however, `%unmacro' takes an argument
-specification, and will only remove exact matches with that argument
-specification.
-
- For example:
-
- %macro foo 1-3
- ; Do something
- %endmacro
- %unmacro foo 1-3
-
- removes the previously defined macro `foo', but
-
- %macro bar 1-3
- ; Do something
- %endmacro
- %unmacro bar 1
-
- does _not_ remove the macro `bar', since the argument specification
-does not match exactly.
-
-
-File: nasm.info, Node: Section 4.3.12, Next: Section 4.4, Prev: Section 4.3.11, Up: Section 4.3
-
-4.3.12. Exiting Multi-Line Macros: `%exitmacro'
------------------------------------------------
-
-Multi-line macro expansions can be arbitrarily terminated with the
-`%exitmacro' directive.
-
- For example:
-
- %macro foo 1-3
- ; Do something
- %if<condition>
- %exitmacro
- %endif
- ; Do something
- %endmacro
-
-
-File: nasm.info, Node: Section 4.4, Next: Section 4.4.1, Prev: Section 4.3.12, Up: Chapter 4
-
-4.4. Conditional Assembly
-=========================
-
-Similarly to the C preprocessor, NASM allows sections of a source file
-to be assembled only if certain conditions are met. The general syntax
-of this feature looks like this:
-
- %if<condition>
- ; some code which only appears if <condition> is met
- %elif<condition2>
- ; only appears if <condition> is not met but <condition2> is
- %else
- ; this appears if neither <condition> nor <condition2> was met
- %endif
-
- The inverse forms `%ifn' and `%elifn' are also supported.
-
- The `%else' clause is optional, as is the `%elif' clause. You can
-have more than one `%elif' clause as well.
-
- There are a number of variants of the `%if' directive. Each has its
-corresponding `%elif', `%ifn', and `%elifn' directives; for example,
-the equivalents to the `%ifdef' directive are `%elifdef', `%ifndef',
-and `%elifndef'.
-
-* Menu:
-
-* Section 4.4.1:: `%ifdef': Testing Single-Line Macro Existence
-* Section 4.4.2:: `%ifmacro': Testing Multi-Line Macro Existence
-* Section 4.4.3:: `%ifctx': Testing the Context Stack
-* Section 4.4.4:: `%if': Testing Arbitrary Numeric Expressions
-* Section 4.4.5:: `%ifidn' and `%ifidni': Testing Exact Text Identity
-* Section 4.4.6:: `%ifid', `%ifnum', `%ifstr': Testing Token Types
-* Section 4.4.7:: `%iftoken': Test for a Single Token
-* Section 4.4.8:: `%ifempty': Test for Empty Expansion
-
-
-File: nasm.info, Node: Section 4.4.1, Next: Section 4.4.2, Prev: Section 4.4, Up: Section 4.4
-
-4.4.1. `%ifdef': Testing Single-Line Macro Existence
-----------------------------------------------------
-
-Beginning a conditional-assembly block with the line `%ifdef MACRO'
-will assemble the subsequent code if, and only if, a single-line macro
-called `MACRO' is defined. If not, then the `%elif' and `%else' blocks
-(if any) will be processed instead.
-
- For example, when debugging a program, you might want to write code
-such as
-
- ; perform some function
- %ifdef DEBUG
- writefile 2,"Function performed successfully",13,10
- %endif
- ; go and do something else
-
- Then you could use the command-line option `-dDEBUG' to create a
-version of the program which produced debugging messages, and remove the
-option to generate the final release version of the program.
-
- You can test for a macro _not_ being defined by using `%ifndef'
-instead of `%ifdef'. You can also test for macro definitions in `%elif'
-blocks by using `%elifdef' and `%elifndef'.
-
-
-File: nasm.info, Node: Section 4.4.2, Next: Section 4.4.3, Prev: Section 4.4.1, Up: Section 4.4
-
-4.4.2. `%ifmacro': Testing Multi-Line Macro Existence
------------------------------------------------------
-
-The `%ifmacro' directive operates in the same way as the `%ifdef'
-directive, except that it checks for the existence of a multi-line
-macro.
-
- For example, you may be working with a large project and not have
-control over the macros in a library. You may want to create a macro
-with one name if it doesn't already exist, and another name if one with
-that name does exist.
-
- The `%ifmacro' is considered true if defining a macro with the given
-name and number of arguments would cause a definitions conflict. For
-example:
-
- %ifmacro MyMacro 1-3
-
- %error "MyMacro 1-3" causes a conflict with an existing macro.
-
- %else
-
- %macro MyMacro 1-3
-
- ; insert code to define the macro
-
- %endmacro
-
- %endif
-
- This will create the macro "MyMacro 1-3" if no macro already exists
-which would conflict with it, and emits a warning if there would be a
-definition conflict.
-
- You can test for the macro not existing by using the `%ifnmacro'
-instead of `%ifmacro'. Additional tests can be performed in `%elif'
-blocks by using `%elifmacro' and `%elifnmacro'.
-
-
-File: nasm.info, Node: Section 4.4.3, Next: Section 4.4.4, Prev: Section 4.4.2, Up: Section 4.4
-
-4.4.3. `%ifctx': Testing the Context Stack
-------------------------------------------
-
-The conditional-assembly construct `%ifctx' will cause the subsequent
-code to be assembled if and only if the top context on the
-preprocessor's context stack has the same name as one of the arguments.
-As with `%ifdef', the inverse and `%elif' forms `%ifnctx', `%elifctx'
-and `%elifnctx' are also supported.
-
- For more details of the context stack, see *note Section 4.7::. For
-a sample use of `%ifctx', see *note Section 4.7.5::.
-
-
-File: nasm.info, Node: Section 4.4.4, Next: Section 4.4.5, Prev: Section 4.4.3, Up: Section 4.4
-
-4.4.4. `%if': Testing Arbitrary Numeric Expressions
----------------------------------------------------
-
-The conditional-assembly construct `%if expr' will cause the subsequent
-code to be assembled if and only if the value of the numeric expression
-`expr' is non-zero. An example of the use of this feature is in
-deciding when to break out of a `%rep' preprocessor loop: see *note
-Section 4.5:: for a detailed example.
-
- The expression given to `%if', and its counterpart `%elif', is a
-critical expression (see *note Section 3.8::).
-
- `%if' extends the normal NASM expression syntax, by providing a set
-of relational operators which are not normally available in
-expressions. The operators `=', `<', `>', `<=', `>=' and `<>' test
-equality, less-than, greater-than, less-or-equal, greater-or-equal and
-not-equal respectively. The C-like forms `==' and `!=' are supported as
-alternative forms of `=' and `<>'. In addition, low- priority logical
-operators `&&', `^^' and `||' are provided, supplying logical AND,
-logical XOR and logical OR. These work like the C logical operators
-(although C has no logical XOR), in that they always return either 0 or
-1, and treat any non-zero input as 1 (so that `^^', for example,
-returns 1 if exactly one of its inputs is zero, and 0 otherwise). The
-relational operators also return 1 for true and 0 for false.
-
- Like other `%if' constructs, `%if' has a counterpart `%elif', and
-negative forms `%ifn' and `%elifn'.
-
-
-File: nasm.info, Node: Section 4.4.5, Next: Section 4.4.6, Prev: Section 4.4.4, Up: Section 4.4
-
-4.4.5. `%ifidn' and `%ifidni': Testing Exact Text Identity
-----------------------------------------------------------
-
-The construct `%ifidn text1,text2' will cause the subsequent code to be
-assembled if and only if `text1' and `text2', after expanding
-single-line macros, are identical pieces of text. Differences in white
-space are not counted.
-
- `%ifidni' is similar to `%ifidn', but is case-insensitive.
-
- For example, the following macro pushes a register or number on the
-stack, and allows you to treat `IP' as a real register:
-
- %macro pushparam 1
-
- %ifidni %1,ip
- call %%label
- %%label:
- %else
- push %1
- %endif
-
- %endmacro
-
- Like other `%if' constructs, `%ifidn' has a counterpart `%elifidn',
-and negative forms `%ifnidn' and `%elifnidn'. Similarly, `%ifidni' has
-counterparts `%elifidni', `%ifnidni' and `%elifnidni'.
-
-
-File: nasm.info, Node: Section 4.4.6, Next: Section 4.4.7, Prev: Section 4.4.5, Up: Section 4.4
-
-4.4.6. `%ifid', `%ifnum', `%ifstr': Testing Token Types
--------------------------------------------------------
-
-Some macros will want to perform different tasks depending on whether
-they are passed a number, a string, or an identifier. For example, a
-string output macro might want to be able to cope with being passed
-either a string constant or a pointer to an existing string.
-
- The conditional assembly construct `%ifid', taking one parameter
-(which may be blank), assembles the subsequent code if and only if the
-first token in the parameter exists and is an identifier. `%ifnum'
-works similarly, but tests for the token being a numeric constant;
-`%ifstr' tests for it being a string.
-
- For example, the `writefile' macro defined in *note Section 4.3.4::
-can be extended to take advantage of `%ifstr' in the following fashion:
-
- %macro writefile 2-3+
-
- %ifstr %2
- jmp %%endstr
- %if %0 = 3
- %%str: db %2,%3
- %else
- %%str: db %2
- %endif
- %%endstr: mov dx,%%str
- mov cx,%%endstr-%%str
- %else
- mov dx,%2
- mov cx,%3
- %endif
- mov bx,%1
- mov ah,0x40
- int 0x21
-
- %endmacro
-
- Then the `writefile' macro can cope with being called in either of
-the following two ways:
-
- writefile [file], strpointer, length
- writefile [file], "hello", 13, 10
-
- In the first, `strpointer' is used as the address of an already-
-declared string, and `length' is used as its length; in the second, a
-string is given to the macro, which therefore declares it itself and
-works out the address and length for itself.
-
- Note the use of `%if' inside the `%ifstr': this is to detect whether
-the macro was passed two arguments (so the string would be a single
-string constant, and `db %2' would be adequate) or more (in which case,
-all but the first two would be lumped together into `%3', and `db
-%2,%3' would be required).
-
- The usual `%elif'..., `%ifn'..., and `%elifn'... versions exist for
-each of `%ifid', `%ifnum' and `%ifstr'.
-
-
-File: nasm.info, Node: Section 4.4.7, Next: Section 4.4.8, Prev: Section 4.4.6, Up: Section 4.4
-
-4.4.7. `%iftoken': Test for a Single Token
-------------------------------------------
-
-Some macros will want to do different things depending on if it is
-passed a single token (e.g. paste it to something else using `%+')
-versus a multi-token sequence.
-
- The conditional assembly construct `%iftoken' assembles the
-subsequent code if and only if the expanded parameters consist of
-exactly one token, possibly surrounded by whitespace.
-
- For example:
-
- %iftoken 1
-
- will assemble the subsequent code, but
-
- %iftoken -1
-
- will not, since `-1' contains two tokens: the unary minus operator
-`-', and the number `1'.
-
- The usual `%eliftoken', `%ifntoken', and `%elifntoken' variants are
-also provided.
-
-
-File: nasm.info, Node: Section 4.4.8, Next: Section 4.5, Prev: Section 4.4.7, Up: Section 4.4
-
-4.4.8. `%ifempty': Test for Empty Expansion
--------------------------------------------
-
-The conditional assembly construct `%ifempty' assembles the subsequent
-code if and only if the expanded parameters do not contain any tokens at
-all, whitespace excepted.
-
- The usual `%elifempty', `%ifnempty', and `%elifnempty' variants are
-also provided.
-
-
-File: nasm.info, Node: Section 4.5, Next: Section 4.6, Prev: Section 4.4.8, Up: Chapter 4
-
-4.5. Preprocessor Loops: `%rep'
-===============================
-
-NASM's `TIMES' prefix, though useful, cannot be used to invoke a
-multi-line macro multiple times, because it is processed by NASM after
-macros have already been expanded. Therefore NASM provides another form
-of loop, this time at the preprocessor level: `%rep'.
-
- The directives `%rep' and `%endrep' (`%rep' takes a numeric
-argument, which can be an expression; `%endrep' takes no arguments) can
-be used to enclose a chunk of code, which is then replicated as many
-times as specified by the preprocessor:
-
- %assign i 0
- %rep 64
- inc word [table+2*i]
- %assign i i+1
- %endrep
-
- This will generate a sequence of 64 `INC' instructions, incrementing
-every word of memory from `[table]' to `[table+126]'.
-
- For more complex termination conditions, or to break out of a repeat
-loop part way along, you can use the `%exitrep' directive to terminate
-the loop, like this:
-
- fibonacci:
- %assign i 0
- %assign j 1
- %rep 100
- %if j > 65535
- %exitrep
- %endif
- dw j
- %assign k j+i
- %assign i j
- %assign j k
- %endrep
-
- fib_number equ ($-fibonacci)/2
-
- This produces a list of all the Fibonacci numbers that will fit in
-16 bits. Note that a maximum repeat count must still be given to
-`%rep'. This is to prevent the possibility of NASM getting into an
-infinite loop in the preprocessor, which (on multitasking or multi-user
-systems) would typically cause all the system memory to be gradually
-used up and other applications to start crashing.
-
-
-File: nasm.info, Node: Section 4.6, Next: Section 4.6.1, Prev: Section 4.5, Up: Chapter 4
-
-4.6. Source Files and Dependencies
-==================================
-
-These commands allow you to split your sources into multiple files.
-
-* Menu:
-
-* Section 4.6.1:: `%include': Including Other Files
-* Section 4.6.2:: `%pathsearch': Search the Include Path
-* Section 4.6.3:: `%depend': Add Dependent Files
-* Section 4.6.4:: `%use': Include Standard Macro Package
-
-
-File: nasm.info, Node: Section 4.6.1, Next: Section 4.6.2, Prev: Section 4.6, Up: Section 4.6
-
-4.6.1. `%include': Including Other Files
-----------------------------------------
-
-Using, once again, a very similar syntax to the C preprocessor, NASM's
-preprocessor lets you include other source files into your code. This is
-done by the use of the `%include' directive:
-
- %include "macros.mac"
-
- will include the contents of the file `macros.mac' into the source
-file containing the `%include' directive.
-
- Include files are searched for in the current directory (the
-directory you're in when you run NASM, as opposed to the location of
-the NASM executable or the location of the source file), plus any
-directories specified on the NASM command line using the `-i' option.
-
- The standard C idiom for preventing a file being included more than
-once is just as applicable in NASM: if the file `macros.mac' has the
-form
-
- %ifndef MACROS_MAC
- %define MACROS_MAC
- ; now define some macros
- %endif
-
- then including the file more than once will not cause errors,
-because the second time the file is included nothing will happen
-because the macro `MACROS_MAC' will already be defined.
-
- You can force a file to be included even if there is no `%include'
-directive that explicitly includes it, by using the `-p' option on the
-NASM command line (see *note Section 2.1.17::).
-
-
-File: nasm.info, Node: Section 4.6.2, Next: Section 4.6.3, Prev: Section 4.6.1, Up: Section 4.6
-
-4.6.2. `%pathsearch': Search the Include Path
----------------------------------------------
-
-The `%pathsearch' directive takes a single-line macro name and a
-filename, and declare or redefines the specified single-line macro to be
-the include-path-resolved version of the filename, if the file exists
-(otherwise, it is passed unchanged.)
-
- For example,
-
- %pathsearch MyFoo "foo.bin"
-
- ... with `-Ibins/' in the include path may end up defining the macro
-`MyFoo' to be `"bins/foo.bin"'.
-
-
-File: nasm.info, Node: Section 4.6.3, Next: Section 4.6.4, Prev: Section 4.6.2, Up: Section 4.6
-
-4.6.3. `%depend': Add Dependent Files
--------------------------------------
-
-The `%depend' directive takes a filename and adds it to the list of
-files to be emitted as dependency generation when the `-M' options and
-its relatives (see *note Section 2.1.4::) are used. It produces no
-output.
-
- This is generally used in conjunction with `%pathsearch'. For
-example, a simplified version of the standard macro wrapper for the
-`INCBIN' directive looks like:
-
- %imacro incbin 1-2+ 0
- %pathsearch dep %1
- %depend dep
- incbin dep,%2
- %endmacro
-
- This first resolves the location of the file into the macro `dep',
-then adds it to the dependency lists, and finally issues the assembler-
-level `INCBIN' directive.
-
-
-File: nasm.info, Node: Section 4.6.4, Next: Section 4.7, Prev: Section 4.6.3, Up: Section 4.6
-
-4.6.4. `%use': Include Standard Macro Package
----------------------------------------------
-
-The `%use' directive is similar to `%include', but rather than
-including the contents of a file, it includes a named standard macro
-package. The standard macro packages are part of NASM, and are
-described in *note Chapter 5::.
-
- Unlike the `%include' directive, package names for the `%use'
-directive do not require quotes, but quotes are permitted. In NASM 2.04
-and 2.05 the unquoted form would be macro-expanded; this is no longer
-true. Thus, the following lines are equivalent:
-
- %use altreg
- %use 'altreg'
-
- Standard macro packages are protected from multiple inclusion. When a
-standard macro package is used, a testable single-line macro of the form
-`__USE_'_package_`__' is also defined, see *note Section 4.11.8::.
-
-
-File: nasm.info, Node: Section 4.7, Next: Section 4.7.1, Prev: Section 4.6.4, Up: Chapter 4
-
-4.7. The Context Stack
-======================
-
-Having labels that are local to a macro definition is sometimes not
-quite powerful enough: sometimes you want to be able to share labels
-between several macro calls. An example might be a `REPEAT' ... `UNTIL'
-loop, in which the expansion of the `REPEAT' macro would need to be
-able to refer to a label which the `UNTIL' macro had defined. However,
-for such a macro you would also want to be able to nest these loops.
-
- NASM provides this level of power by means of a _context stack_. The
-preprocessor maintains a stack of _contexts_, each of which is
-characterized by a name. You add a new context to the stack using the
-`%push' directive, and remove one using `%pop'. You can define labels
-that are local to a particular context on the stack.
-
-* Menu:
-
-* Section 4.7.1:: `%push' and `%pop': Creating and Removing Contexts
-* Section 4.7.2:: Context-Local Labels
-* Section 4.7.3:: Context-Local Single-Line Macros
-* Section 4.7.4:: `%repl': Renaming a Context
-* Section 4.7.5:: Example Use of the Context Stack: Block IFs
-
-
-File: nasm.info, Node: Section 4.7.1, Next: Section 4.7.2, Prev: Section 4.7, Up: Section 4.7
-
-4.7.1. `%push' and `%pop': Creating and Removing Contexts
----------------------------------------------------------
-
-The `%push' directive is used to create a new context and place it on
-the top of the context stack. `%push' takes an optional argument, which
-is the name of the context. For example:
-
- %push foobar
-
- This pushes a new context called `foobar' on the stack. You can have
-several contexts on the stack with the same name: they can still be
-distinguished. If no name is given, the context is unnamed (this is
-normally used when both the `%push' and the `%pop' are inside a single
-macro definition.)
-
- The directive `%pop', taking one optional argument, removes the top
-context from the context stack and destroys it, along with any labels
-associated with it. If an argument is given, it must match the name of
-the current context, otherwise it will issue an error.
-
-
-File: nasm.info, Node: Section 4.7.2, Next: Section 4.7.3, Prev: Section 4.7.1, Up: Section 4.7
-
-4.7.2. Context-Local Labels
----------------------------
-
-Just as the usage `%%foo' defines a label which is local to the
-particular macro call in which it is used, the usage `%$foo' is used to
-define a label which is local to the context on the top of the context
-stack. So the `REPEAT' and `UNTIL' example given above could be
-implemented by means of:
-
- %macro repeat 0
-
- %push repeat
- %$begin:
-
- %endmacro
-
- %macro until 1
-
- j%-1 %$begin
- %pop
-
- %endmacro
-
- and invoked by means of, for example,
-
- mov cx,string
- repeat
- add cx,3
- scasb
- until e
-
- which would scan every fourth byte of a string in search of the byte
-in `AL'.
-
- If you need to define, or access, labels local to the context _below_
-the top one on the stack, you can use `%$$foo', or `%$$$foo' for the
-context below that, and so on.
-
-
-File: nasm.info, Node: Section 4.7.3, Next: Section 4.7.4, Prev: Section 4.7.2, Up: Section 4.7
-
-4.7.3. Context-Local Single-Line Macros
----------------------------------------
-
-NASM also allows you to define single-line macros which are local to a
-particular context, in just the same way:
-
- %define %$localmac 3
-
- will define the single-line macro `%$localmac' to be local to the top
-context on the stack. Of course, after a subsequent `%push', it can
-then still be accessed by the name `%$$localmac'.
-
-
-File: nasm.info, Node: Section 4.7.4, Next: Section 4.7.5, Prev: Section 4.7.3, Up: Section 4.7
-
-4.7.4. `%repl': Renaming a Context
-----------------------------------
-
-If you need to change the name of the top context on the stack (in
-order, for example, to have it respond differently to `%ifctx'), you can
-execute a `%pop' followed by a `%push'; but this will have the side
-effect of destroying all context-local labels and macros associated
-with the context that was just popped.
-
- NASM provides the directive `%repl', which _replaces_ a context with
-a different name, without touching the associated macros and labels.
-So you could replace the destructive code
-
- %pop
- %push newname
-
- with the non-destructive version `%repl newname'.
-
-
-File: nasm.info, Node: Section 4.7.5, Next: Section 4.8, Prev: Section 4.7.4, Up: Section 4.7
-
-4.7.5. Example Use of the Context Stack: Block IFs
---------------------------------------------------
-
-This example makes use of almost all the context-stack features,
-including the conditional-assembly construct `%ifctx', to implement a
-block IF statement as a set of macros.
-
- %macro if 1
-
- %push if
- j%-1 %$ifnot
-
- %endmacro
-
- %macro else 0
-
- %ifctx if
- %repl else
- jmp %$ifend
- %$ifnot:
- %else
- %error "expected `if' before `else'"
- %endif
-
- %endmacro
-
- %macro endif 0
-
- %ifctx if
- %$ifnot:
- %pop
- %elifctx else
- %$ifend:
- %pop
- %else
- %error "expected `if' or `else' before `endif'"
- %endif
-
- %endmacro
-
- This code is more robust than the `REPEAT' and `UNTIL' macros given
-in *note Section 4.7.2::, because it uses conditional assembly to check
-that the macros are issued in the right order (for example, not calling
-`endif' before `if') and issues a `%error' if they're not.
-
- In addition, the `endif' macro has to be able to cope with the two
-distinct cases of either directly following an `if', or following an
-`else'. It achieves this, again, by using conditional assembly to do
-different things depending on whether the context on top of the stack is
-`if' or `else'.
-
- The `else' macro has to preserve the context on the stack, in order
-to have the `%$ifnot' referred to by the `if' macro be the same as the
-one defined by the `endif' macro, but has to change the context's name
-so that `endif' will know there was an intervening `else'. It does
-this by the use of `%repl'.
-
- A sample usage of these macros might look like:
-
- cmp ax,bx
-
- if ae
- cmp bx,cx
-
- if ae
- mov ax,cx
- else
- mov ax,bx
- endif
-
- else
- cmp ax,cx
-
- if ae
- mov ax,cx
- endif
-
- endif
-
- The block-`IF' macros handle nesting quite happily, by means of
-pushing another context, describing the inner `if', on top of the one
-describing the outer `if'; thus `else' and `endif' always refer to the
-last unmatched `if' or `else'.
-
-
-File: nasm.info, Node: Section 4.8, Next: Section 4.8.1, Prev: Section 4.7.5, Up: Chapter 4
-
-4.8. Stack Relative Preprocessor Directives
-===========================================
-
-The following preprocessor directives provide a way to use labels to
-refer to local variables allocated on the stack.
-
- * `%arg' (see *note Section 4.8.1::)
-
- * `%stacksize' (see *note Section 4.8.2::)
-
- * `%local' (see *note Section 4.8.3::)
-
-* Menu:
-
-* Section 4.8.1:: `%arg' Directive
-* Section 4.8.2:: `%stacksize' Directive
-* Section 4.8.3:: `%local' Directive
-
-
-File: nasm.info, Node: Section 4.8.1, Next: Section 4.8.2, Prev: Section 4.8, Up: Section 4.8
-
-4.8.1. `%arg' Directive
------------------------
-
-The `%arg' directive is used to simplify the handling of parameters
-passed on the stack. Stack based parameter passing is used by many high
-level languages, including C, C++ and Pascal.
-
- While NASM has macros which attempt to duplicate this functionality
-(see *note Section 8.4.5::), the syntax is not particularly convenient
-to use. and is not TASM compatible. Here is an example which shows the
-use of `%arg' without any external macros:
-
- some_function:
-
- %push mycontext ; save the current context
- %stacksize large ; tell NASM to use bp
- %arg i:word, j_ptr:word
-
- mov ax,[i]
- mov bx,[j_ptr]
- add ax,[bx]
- ret
-
- %pop ; restore original context
-
- This is similar to the procedure defined in *note Section 8.4.5::
-and adds the value in i to the value pointed to by j_ptr and returns
-the sum in the ax register. See *note Section 4.7.1:: for an
-explanation of `push' and `pop' and the use of context stacks.
-
-
-File: nasm.info, Node: Section 4.8.2, Next: Section 4.8.3, Prev: Section 4.8.1, Up: Section 4.8
-
-4.8.2. `%stacksize' Directive
------------------------------
-
-The `%stacksize' directive is used in conjunction with the `%arg' (see
-*note Section 4.8.1::) and the `%local' (see *note Section 4.8.3::)
-directives. It tells NASM the default size to use for subsequent `%arg'
-and `%local' directives. The `%stacksize' directive takes one required
-argument which is one of `flat', `flat64', `large' or `small'.
-
- %stacksize flat
-
- This form causes NASM to use stack-based parameter addressing
-relative to `ebp' and it assumes that a near form of call was used to
-get to this label (i.e. that `eip' is on the stack).
-
- %stacksize flat64
-
- This form causes NASM to use stack-based parameter addressing
-relative to `rbp' and it assumes that a near form of call was used to
-get to this label (i.e. that `rip' is on the stack).
-
- %stacksize large
-
- This form uses `bp' to do stack-based parameter addressing and
-assumes that a far form of call was used to get to this address (i.e.
-that `ip' and `cs' are on the stack).
-
- %stacksize small
-
- This form also uses `bp' to address stack parameters, but it is
-different from `large' because it also assumes that the old value of bp
-is pushed onto the stack (i.e. it expects an `ENTER' instruction). In
-other words, it expects that `bp', `ip' and `cs' are on the top of the
-stack, underneath any local space which may have been allocated by
-`ENTER'. This form is probably most useful when used in combination
-with the `%local' directive (see *note Section 4.8.3::).
-
-
-File: nasm.info, Node: Section 4.8.3, Next: Section 4.9, Prev: Section 4.8.2, Up: Section 4.8
-
-4.8.3. `%local' Directive
--------------------------
-
-The `%local' directive is used to simplify the use of local temporary
-stack variables allocated in a stack frame. Automatic local variables
-in C are an example of this kind of variable. The `%local' directive is
-most useful when used with the `%stacksize' (see *note Section 4.8.2::
-and is also compatible with the `%arg' directive (see *note Section
-4.8.1::). It allows simplified reference to variables on the stack which
-have been allocated typically by using the `ENTER' instruction. An
-example of its use is the following:
-
- silly_swap:
-
- %push mycontext ; save the current context
- %stacksize small ; tell NASM to use bp
- %assign %$localsize 0 ; see text for explanation
- %local old_ax:word, old_dx:word
-
- enter %$localsize,0 ; see text for explanation
- mov [old_ax],ax ; swap ax & bx
- mov [old_dx],dx ; and swap dx & cx
- mov ax,bx
- mov dx,cx
- mov bx,[old_ax]
- mov cx,[old_dx]
- leave ; restore old bp
- ret ;
-
- %pop ; restore original context
-
- The `%$localsize' variable is used internally by the `%local'
-directive and _must_ be defined within the current context before the
-`%local' directive may be used. Failure to do so will result in one
-expression syntax error for each `%local' variable declared. It then
-may be used in the construction of an appropriately sized ENTER
-instruction as shown in the example.
-
-
-File: nasm.info, Node: Section 4.9, Next: Section 4.10, Prev: Section 4.8.3, Up: Chapter 4
-
-4.9. Reporting User-Defined Errors: `%error', `%warning', `%fatal'
-==================================================================
-
-The preprocessor directive `%error' will cause NASM to report an error
-if it occurs in assembled code. So if other users are going to try to
-assemble your source files, you can ensure that they define the right
-macros by means of code like this:
-
- %ifdef F1
- ; do some setup
- %elifdef F2
- ; do some different setup
- %else
- %error "Neither F1 nor F2 was defined."
- %endif
-
- Then any user who fails to understand the way your code is supposed
-to be assembled will be quickly warned of their mistake, rather than
-having to wait until the program crashes on being run and then not
-knowing what went wrong.
-
- Similarly, `%warning' issues a warning, but allows assembly to
-continue:
-
- %ifdef F1
- ; do some setup
- %elifdef F2
- ; do some different setup
- %else
- %warning "Neither F1 nor F2 was defined, assuming F1."
- %define F1
- %endif
-
- `%error' and `%warning' are issued only on the final assembly pass.
-This makes them safe to use in conjunction with tests that depend on
-symbol values.
-
- `%fatal' terminates assembly immediately, regardless of pass. This is
-useful when there is no point in continuing the assembly further, and
-doing so is likely just going to cause a spew of confusing error
-messages.
-
- It is optional for the message string after `%error', `%warning' or
-`%fatal' to be quoted. If it is _not_, then single-line macros are
-expanded in it, which can be used to display more information to the
-user. For example:
-
- %if foo > 64
- %assign foo_over foo-64
- %error foo is foo_over bytes too large
- %endif
-
-
-File: nasm.info, Node: Section 4.10, Next: Section 4.10.1, Prev: Section 4.9, Up: Chapter 4
-
-4.10. Other Preprocessor Directives
-===================================
-
-NASM also has preprocessor directives which allow access to information
-from external sources. Currently they include:
-
- * `%line' enables NASM to correctly handle the output of another
- preprocessor (see *note Section 4.10.1::).
-
- * `%!' enables NASM to read in the value of an environment variable,
- which can then be used in your program (see *note Section
- 4.10.2::).
-
-* Menu:
-
-* Section 4.10.1:: `%line' Directive
-* Section 4.10.2:: `%!'`<env>': Read an environment variable.
-
-
-File: nasm.info, Node: Section 4.10.1, Next: Section 4.10.2, Prev: Section 4.10, Up: Section 4.10
-
-4.10.1. `%line' Directive
--------------------------
-
-The `%line' directive is used to notify NASM that the input line
-corresponds to a specific line number in another file. Typically this
-other file would be an original source file, with the current NASM
-input being the output of a pre-processor. The `%line' directive allows
-NASM to output messages which indicate the line number of the original
-source file, instead of the file that is being read by NASM.
-
- This preprocessor directive is not generally of use to programmers,
-by may be of interest to preprocessor authors. The usage of the `%line'
-preprocessor directive is as follows:
-
- %line nnn[+mmm] [filename]
-
- In this directive, `nnn' identifies the line of the original source
-file which this line corresponds to. `mmm' is an optional parameter
-which specifies a line increment value; each line of the input file
-read in is considered to correspond to `mmm' lines of the original
-source file. Finally, `filename' is an optional parameter which
-specifies the file name of the original source file.
-
- After reading a `%line' preprocessor directive, NASM will report all
-file name and line numbers relative to the values specified therein.
-
-
-File: nasm.info, Node: Section 4.10.2, Next: Section 4.11, Prev: Section 4.10.1, Up: Section 4.10
-
-4.10.2. `%!'`<env>': Read an environment variable.
---------------------------------------------------
-
-The `%!<env>' directive makes it possible to read the value of an
-environment variable at assembly time. This could, for example, be used
-to store the contents of an environment variable into a string, which
-could be used at some other point in your code.
-
- For example, suppose that you have an environment variable `FOO', and
-you want the contents of `FOO' to be embedded in your program. You
-could do that as follows:
-
- %defstr FOO %!FOO
-
- See *note Section 4.1.8:: for notes on the `%defstr' directive.
-
-
-File: nasm.info, Node: Section 4.11, Next: Section 4.11.1, Prev: Section 4.10.2, Up: Chapter 4
-
-4.11. Standard Macros
-=====================
-
-NASM defines a set of standard macros, which are already defined when it
-starts to process any source file. If you really need a program to be
-assembled with no pre-defined macros, you can use the `%clear'
-directive to empty the preprocessor of everything but context-local
-preprocessor variables and single-line macros.
-
- Most user-level assembler directives (see *note Chapter 6::) are
-implemented as macros which invoke primitive directives; these are
-described in *note Chapter 6::. The rest of the standard macro set is
-described here.
-
-* Menu:
-
-* Section 4.11.1:: NASM Version Macros
-* Section 4.11.2:: `__NASM_VERSION_ID__': NASM Version ID
-* Section 4.11.3:: `__NASM_VER__': NASM Version string
-* Section 4.11.4:: `__FILE__' and `__LINE__': File Name and Line Number
-* Section 4.11.5:: `__BITS__': Current BITS Mode
-* Section 4.11.6:: `__OUTPUT_FORMAT__': Current Output Format
-* Section 4.11.7:: Assembly Date and Time Macros
-* Section 4.11.8:: `__USE_'_package_`__': Package Include Test
-* Section 4.11.9:: `__PASS__': Assembly Pass
-* Section 4.11.10:: `STRUC' and `ENDSTRUC': Declaring Structure Data Types
-* Section 4.11.11:: `ISTRUC', `AT' and `IEND': Declaring Instances of Structures
-* Section 4.11.12:: `ALIGN' and `ALIGNB': Data Alignment
-
-
-File: nasm.info, Node: Section 4.11.1, Next: Section 4.11.2, Prev: Section 4.11, Up: Section 4.11
-
-4.11.1. NASM Version Macros
----------------------------
-
-The single-line macros `__NASM_MAJOR__', `__NASM_MINOR__',
-`__NASM_SUBMINOR__' and `___NASM_PATCHLEVEL__' expand to the major,
-minor, subminor and patch level parts of the version number of NASM
-being used. So, under NASM 0.98.32p1 for example, `__NASM_MAJOR__'
-would be defined to be 0, `__NASM_MINOR__' would be defined as 98,
-`__NASM_SUBMINOR__' would be defined to 32, and `___NASM_PATCHLEVEL__'
-would be defined as 1.
-
- Additionally, the macro `__NASM_SNAPSHOT__' is defined for
-automatically generated snapshot releases _only_.
-
-
-File: nasm.info, Node: Section 4.11.2, Next: Section 4.11.3, Prev: Section 4.11.1, Up: Section 4.11
-
-4.11.2. `__NASM_VERSION_ID__': NASM Version ID
-----------------------------------------------
-
-The single-line macro `__NASM_VERSION_ID__' expands to a dword integer
-representing the full version number of the version of nasm being used.
-The value is the equivalent to `__NASM_MAJOR__', `__NASM_MINOR__',
-`__NASM_SUBMINOR__' and `___NASM_PATCHLEVEL__' concatenated to produce
-a single doubleword. Hence, for 0.98.32p1, the returned number would be
-equivalent to:
-
- dd 0x00622001
-
- or
-
- db 1,32,98,0
-
- Note that the above lines are generate exactly the same code, the
-second line is used just to give an indication of the order that the
-separate values will be present in memory.
-
-
-File: nasm.info, Node: Section 4.11.3, Next: Section 4.11.4, Prev: Section 4.11.2, Up: Section 4.11
-
-4.11.3. `__NASM_VER__': NASM Version string
--------------------------------------------
-
-The single-line macro `__NASM_VER__' expands to a string which defines
-the version number of nasm being used. So, under NASM 0.98.32 for
-example,
-
- db __NASM_VER__
-
- would expand to
-
- db "0.98.32"
-
-
-File: nasm.info, Node: Section 4.11.4, Next: Section 4.11.5, Prev: Section 4.11.3, Up: Section 4.11
-
-4.11.4. `__FILE__' and `__LINE__': File Name and Line Number
-------------------------------------------------------------
-
-Like the C preprocessor, NASM allows the user to find out the file name
-and line number containing the current instruction. The macro `__FILE__'
-expands to a string constant giving the name of the current input file
-(which may change through the course of assembly if `%include'
-directives are used), and `__LINE__' expands to a numeric constant
-giving the current line number in the input file.
-
- These macros could be used, for example, to communicate debugging
-information to a macro, since invoking `__LINE__' inside a macro
-definition (either single-line or multi-line) will return the line
-number of the macro _call_, rather than _definition_. So to determine
-where in a piece of code a crash is occurring, for example, one could
-write a routine `stillhere', which is passed a line number in `EAX' and
-outputs something like `line 155: still here'. You could then write a
-macro
-
- %macro notdeadyet 0
-
- push eax
- mov eax,__LINE__
- call stillhere
- pop eax
-
- %endmacro
-
- and then pepper your code with calls to `notdeadyet' until you find
-the crash point.
-
-
-File: nasm.info, Node: Section 4.11.5, Next: Section 4.11.6, Prev: Section 4.11.4, Up: Section 4.11
-
-4.11.5. `__BITS__': Current BITS Mode
--------------------------------------
-
-The `__BITS__' standard macro is updated every time that the BITS mode
-is set using the `BITS XX' or `[BITS XX]' directive, where XX is a
-valid mode number of 16, 32 or 64. `__BITS__' receives the specified
-mode number and makes it globally available. This can be very useful for
-those who utilize mode-dependent macros.
-
-
-File: nasm.info, Node: Section 4.11.6, Next: Section 4.11.7, Prev: Section 4.11.5, Up: Section 4.11
-
-4.11.6. `__OUTPUT_FORMAT__': Current Output Format
---------------------------------------------------
-
-The `__OUTPUT_FORMAT__' standard macro holds the current Output Format,
-as given by the `-f' option or NASM's default. Type `nasm -hf' for a
-list.
-
- %ifidn __OUTPUT_FORMAT__, win32
- %define NEWLINE 13, 10
- %elifidn __OUTPUT_FORMAT__, elf32
- %define NEWLINE 10
- %endif
-
-
-File: nasm.info, Node: Section 4.11.7, Next: Section 4.11.8, Prev: Section 4.11.6, Up: Section 4.11
-
-4.11.7. Assembly Date and Time Macros
--------------------------------------
-
-NASM provides a variety of macros that represent the timestamp of the
-assembly session.
-
- * The `__DATE__' and `__TIME__' macros give the assembly date and
- time as strings, in ISO 8601 format (`"YYYY-MM-DD"' and
- `"HH:MM:SS"', respectively.)
-
- * The `__DATE_NUM__' and `__TIME_NUM__' macros give the assembly
- date and time in numeric form; in the format `YYYYMMDD' and
- `HHMMSS' respectively.
-
- * The `__UTC_DATE__' and `__UTC_TIME__' macros give the assembly
- date and time in universal time (UTC) as strings, in ISO 8601
- format (`"YYYY-MM-DD"' and `"HH:MM:SS"', respectively.) If the host
- platform doesn't provide UTC time, these macros are undefined.
-
- * The `__UTC_DATE_NUM__' and `__UTC_TIME_NUM__' macros give the
- assembly date and time universal time (UTC) in numeric form; in
- the format `YYYYMMDD' and `HHMMSS' respectively. If the host
- platform doesn't provide UTC time, these macros are undefined.
-
- * The `__POSIX_TIME__' macro is defined as a number containing the
- number of seconds since the POSIX epoch, 1 January 1970 00:00:00
- UTC; excluding any leap seconds. This is computed using UTC time
- if available on the host platform, otherwise it is computed using
- the local time as if it was UTC.
-
- All instances of time and date macros in the same assembly session
-produce consistent output. For example, in an assembly session started
-at 42 seconds after midnight on January 1, 2010 in Moscow (timezone
-UTC+3) these macros would have the following values, assuming, of
-course, a properly configured environment with a correct clock:
-
- __DATE__ "2010-01-01"
- __TIME__ "00:00:42"
- __DATE_NUM__ 20100101
- __TIME_NUM__ 000042
- __UTC_DATE__ "2009-12-31"
- __UTC_TIME__ "21:00:42"
- __UTC_DATE_NUM__ 20091231
- __UTC_TIME_NUM__ 210042
- __POSIX_TIME__ 1262293242
-
-
-File: nasm.info, Node: Section 4.11.8, Next: Section 4.11.9, Prev: Section 4.11.7, Up: Section 4.11
-
-4.11.8. `__USE_'_package_`__': Package Include Test
----------------------------------------------------
-
-When a standard macro package (see *note Chapter 5::) is included with
-the `%use' directive (see *note Section 4.6.4::), a single-line macro
-of the form `__USE_'_package_`__' is automatically defined. This allows
-testing if a particular package is invoked or not.
-
- For example, if the `altreg' package is included (see *note Section
-5.1::), then the macro `__USE_ALTREG__' is defined.
-
-
-File: nasm.info, Node: Section 4.11.9, Next: Section 4.11.10, Prev: Section 4.11.8, Up: Section 4.11
-
-4.11.9. `__PASS__': Assembly Pass
----------------------------------
-
-The macro `__PASS__' is defined to be `1' on preparatory passes, and
-`2' on the final pass. In preprocess-only mode, it is set to `3', and
-when running only to generate dependencies (due to the `-M' or `-MG'
-option, see *note Section 2.1.4::) it is set to `0'.
-
- _Avoid using this macro if at all possible. It is tremendously easy
-to generate very strange errors by misusing it, and the semantics may
-change in future versions of NASM._
-
-
-File: nasm.info, Node: Section 4.11.10, Next: Section 4.11.11, Prev: Section 4.11.9, Up: Section 4.11
-
-4.11.10. `STRUC' and `ENDSTRUC': Declaring Structure Data Types
----------------------------------------------------------------
-
-The core of NASM contains no intrinsic means of defining data
-structures; instead, the preprocessor is sufficiently powerful that
-data structures can be implemented as a set of macros. The macros
-`STRUC' and `ENDSTRUC' are used to define a structure data type.
-
- `STRUC' takes one or two parameters. The first parameter is the name
-of the data type. The second, optional parameter is the base offset of
-the structure. The name of the data type is defined as a symbol with
-the value of the base offset, and the name of the data type with the
-suffix `_size' appended to it is defined as an `EQU' giving the size of
-the structure. Once `STRUC' has been issued, you are defining the
-structure, and should define fields using the `RESB' family of pseudo-
-instructions, and then invoke `ENDSTRUC' to finish the definition.
-
- For example, to define a structure called `mytype' containing a
-longword, a word, a byte and a string of bytes, you might code
-
- struc mytype
-
- mt_long: resd 1
- mt_word: resw 1
- mt_byte: resb 1
- mt_str: resb 32
-
- endstruc
-
- The above code defines six symbols: `mt_long' as 0 (the offset from
-the beginning of a `mytype' structure to the longword field), `mt_word'
-as 4, `mt_byte' as 6, `mt_str' as 7, `mytype_size' as 39, and `mytype'
-itself as zero.
-
- The reason why the structure type name is defined at zero by default
-is a side effect of allowing structures to work with the local label
-mechanism: if your structure members tend to have the same names in
-more than one structure, you can define the above structure like this:
-
- struc mytype
-
- .long: resd 1
- .word: resw 1
- .byte: resb 1
- .str: resb 32
-
- endstruc
-
- This defines the offsets to the structure fields as `mytype.long',
-`mytype.word', `mytype.byte' and `mytype.str'.
-
- NASM, since it has no _intrinsic_ structure support, does not support
-any form of period notation to refer to the elements of a structure once
-you have one (except the above local-label notation), so code such as
-`mov ax,[mystruc.mt_word]' is not valid. `mt_word' is a constant just
-like any other constant, so the correct syntax is `mov
-ax,[mystruc+mt_word]' or `mov ax,[mystruc+mytype.word]'.
-
- Sometimes you only have the address of the structure displaced by an
-offset. For example, consider this standard stack frame setup:
-
- push ebp
- mov ebp, esp
- sub esp, 40
-
- In this case, you could access an element by subtracting the offset:
-
- mov [ebp - 40 + mytype.word], ax
-
- However, if you do not want to repeat this offset, you can use -40
-as a base offset:
-
- struc mytype, -40
-
- And access an element this way:
-
- mov [ebp + mytype.word], ax
-
-
-File: nasm.info, Node: Section 4.11.11, Next: Section 4.11.12, Prev: Section 4.11.10, Up: Section 4.11
-
-4.11.11. `ISTRUC', `AT' and `IEND': Declaring Instances of Structures
----------------------------------------------------------------------
-
-Having defined a structure type, the next thing you typically want to
-do is to declare instances of that structure in your data segment. NASM
-provides an easy way to do this in the `ISTRUC' mechanism. To declare a
-structure of type `mytype' in a program, you code something like this:
-
- mystruc:
- istruc mytype
-
- at mt_long, dd 123456
- at mt_word, dw 1024
- at mt_byte, db 'x'
- at mt_str, db 'hello, world', 13, 10, 0
-
- iend
-
- The function of the `AT' macro is to make use of the `TIMES' prefix
-to advance the assembly position to the correct point for the specified
-structure field, and then to declare the specified data. Therefore the
-structure fields must be declared in the same order as they were
-specified in the structure definition.
-
- If the data to go in a structure field requires more than one source
-line to specify, the remaining source lines can easily come after the
-`AT' line. For example:
-
- at mt_str, db 123,134,145,156,167,178,189
- db 190,100,0
-
- Depending on personal taste, you can also omit the code part of the
-`AT' line completely, and start the structure field on the next line:
-
- at mt_str
- db 'hello, world'
- db 13,10,0
-
-
-File: nasm.info, Node: Section 4.11.12, Next: Chapter 5, Prev: Section 4.11.11, Up: Section 4.11
-
-4.11.12. `ALIGN' and `ALIGNB': Data Alignment
----------------------------------------------
-
-The `ALIGN' and `ALIGNB' macros provides a convenient way to align code
-or data on a word, longword, paragraph or other boundary. (Some
-assemblers call this directive `EVEN'.) The syntax of the `ALIGN' and
-`ALIGNB' macros is
-
- align 4 ; align on 4-byte boundary
- align 16 ; align on 16-byte boundary
- align 8,db 0 ; pad with 0s rather than NOPs
- align 4,resb 1 ; align to 4 in the BSS
- alignb 4 ; equivalent to previous line
-
- Both macros require their first argument to be a power of two; they
-both compute the number of additional bytes required to bring the
-length of the current section up to a multiple of that power of two,
-and then apply the `TIMES' prefix to their second argument to perform
-the alignment.
-
- If the second argument is not specified, the default for `ALIGN' is
-`NOP', and the default for `ALIGNB' is `RESB 1'. So if the second
-argument is specified, the two macros are equivalent. Normally, you can
-just use `ALIGN' in code and data sections and `ALIGNB' in BSS
-sections, and never need the second argument except for special
-purposes.
-
- `ALIGN' and `ALIGNB', being simple macros, perform no error
-checking: they cannot warn you if their first argument fails to be a
-power of two, or if their second argument generates more than one byte
-of code. In each of these cases they will silently do the wrong thing.
-
- `ALIGNB' (or `ALIGN' with a second argument of `RESB 1') can be used
-within structure definitions:
-
- struc mytype2
-
- mt_byte:
- resb 1
- alignb 2
- mt_word:
- resw 1
- alignb 4
- mt_long:
- resd 1
- mt_str:
- resb 32
-
- endstruc
-
- This will ensure that the structure members are sensibly aligned
-relative to the base of the structure.
-
- A final caveat: `ALIGN' and `ALIGNB' work relative to the beginning
-of the _section_, not the beginning of the address space in the final
-executable. Aligning to a 16-byte boundary when the section you're in
-is only guaranteed to be aligned to a 4-byte boundary, for example, is
-a waste of effort. Again, NASM does not check that the section's
-alignment characteristics are sensible for the use of `ALIGN' or
-`ALIGNB'.
-
- See also the `smartalign' standard macro package, *note Section
-5.2::.
-
-
-File: nasm.info, Node: Chapter 5, Next: Section 5.1, Prev: Section 4.11.12, Up: Top
-
-Chapter 5: Standard Macro Packages
-**********************************
-
-The `%use' directive (see *note Section 4.6.4::) includes one of the
-standard macro packages included with the NASM distribution and compiled
-into the NASM binary. It operates like the `%include' directive (see
-*note Section 4.6.1::), but the included contents is provided by NASM
-itself.
-
- The names of standard macro packages are case insensitive, and can be
-quoted or not.
-
-* Menu:
-
-* Section 5.1:: `altreg': Alternate Register Names
-* Section 5.2:: `smartalign': Smart `ALIGN' Macro
-
-
-File: nasm.info, Node: Section 5.1, Next: Section 5.2, Prev: Chapter 5, Up: Chapter 5
-
-5.1. `altreg': Alternate Register Names
-=======================================
-
-The `altreg' standard macro package provides alternate register names.
-It provides numeric register names for all registers (not just `R8'-
-`R15'), the Intel-defined aliases `R8L'-`R15L' for the low bytes of
-register (as opposed to the NASM/AMD standard names `R8B'- `R15B'), and
-the names `R0H'-`R3H' (by analogy with `R0L'-`R3L') for `AH', `CH',
-`DH', and `BH'.
-
- Example use:
-
- %use altreg
-
- proc:
- mov r0l,r3h ; mov al,bh
- ret
-
- See also *note Section 11.1::.
-
-
-File: nasm.info, Node: Section 5.2, Next: Chapter 6, Prev: Section 5.1, Up: Chapter 5
-
-5.2. `smartalign': Smart `ALIGN' Macro
-======================================
-
-The `smartalign' standard macro package provides for an `ALIGN' macro
-which is more powerful than the default (and backwards-compatible) one
-(see *note Section 4.11.12::). When the `smartalign' package is
-enabled, when `ALIGN' is used without a second argument, NASM will
-generate a sequence of instructions more efficient than a series of
-`NOP'. Furthermore, if the padding exceeds a specific threshold, then
-NASM will generate a jump over the entire padding sequence.
-
- The specific instructions generated can be controlled with the new
-`ALIGNMODE' macro. This macro takes two parameters: one mode, and an
-optional jump threshold override. The modes are as follows:
-
- * `generic': Works on all x86 CPUs and should have reasonable
- performance. The default jump threshold is 8. This is the default.
-
- * `nop': Pad out with `NOP' instructions. The only difference
- compared to the standard `ALIGN' macro is that NASM can still jump
- over a large padding area. The default jump threshold is 16.
-
- * `k7': Optimize for the AMD K7 (Athlon/Althon XP). These
- instructions should still work on all x86 CPUs. The default jump
- threshold is 16.
-
- * `k8': Optimize for the AMD K8 (Opteron/Althon 64). These
- instructions should still work on all x86 CPUs. The default jump
- threshold is 16.
-
- * `p6': Optimize for Intel CPUs. This uses the long `NOP'
- instructions first introduced in Pentium Pro. This is incompatible
- with all CPUs of family 5 or lower, as well as some VIA CPUs and
- several virtualization solutions. The default jump threshold is 16.
-
- The macro `__ALIGNMODE__' is defined to contain the current alignment
-mode. A number of other macros beginning with `__ALIGN_' are used
-internally by this macro package.
-
-
-File: nasm.info, Node: Chapter 6, Next: Section 6.1, Prev: Section 5.2, Up: Top
-
-Chapter 6: Assembler Directives
-*******************************
-
-NASM, though it attempts to avoid the bureaucracy of assemblers like
-MASM and TASM, is nevertheless forced to support a _few_ directives.
-These are described in this chapter.
-
- NASM's directives come in two types: _user-level_ directives and
-_primitive_ directives. Typically, each directive has a user-level form
-and a primitive form. In almost all cases, we recommend that users use
-the user-level forms of the directives, which are implemented as macros
-which call the primitive forms.
-
- Primitive directives are enclosed in square brackets; user-level
-directives are not.
-
- In addition to the universal directives described in this chapter,
-each object file format can optionally supply extra directives in order
-to control particular features of that file format. These
-_format-specific_ directives are documented along with the formats that
-implement them, in *note Chapter 7::.
-
-* Menu:
-
-* Section 6.1:: `BITS': Specifying Target Processor Mode
-* Section 6.2:: `DEFAULT': Change the assembler defaults
-* Section 6.3:: `SECTION' or `SEGMENT': Changing and Defining Sections
-* Section 6.4:: `ABSOLUTE': Defining Absolute Labels
-* Section 6.5:: `EXTERN': Importing Symbols from Other Modules
-* Section 6.6:: `GLOBAL': Exporting Symbols to Other Modules
-* Section 6.7:: `COMMON': Defining Common Data Areas
-* Section 6.8:: `CPU': Defining CPU Dependencies
-* Section 6.9:: `FLOAT': Handling of floating-point constants
-
-
-File: nasm.info, Node: Section 6.1, Next: Section 6.1.1, Prev: Chapter 6, Up: Chapter 6
-
-6.1. `BITS': Specifying Target Processor Mode
-=============================================
-
-The `BITS' directive specifies whether NASM should generate code
-designed to run on a processor operating in 16-bit mode, 32-bit mode or
-64- bit mode. The syntax is `BITS XX', where XX is 16, 32 or 64.
-
- In most cases, you should not need to use `BITS' explicitly. The
-`aout', `coff', `elf', `macho', `win32' and `win64' object formats,
-which are designed for use in 32-bit or 64-bit operating systems, all
-cause NASM to select 32-bit or 64-bit mode, respectively, by default.
-The `obj' object format allows you to specify each segment you define
-as either `USE16' or `USE32', and NASM will set its operating mode
-accordingly, so the use of the `BITS' directive is once again
-unnecessary.
-
- The most likely reason for using the `BITS' directive is to write 32-
-bit or 64-bit code in a flat binary file; this is because the `bin'
-output format defaults to 16-bit mode in anticipation of it being used
-most frequently to write DOS `.COM' programs, DOS `.SYS' device drivers
-and boot loader software.
-
- You do _not_ need to specify `BITS 32' merely in order to use 32-
-bit instructions in a 16-bit DOS program; if you do, the assembler will
-generate incorrect code because it will be writing code targeted at a
-32- bit platform, to be run on a 16-bit one.
-
- When NASM is in `BITS 16' mode, instructions which use 32-bit data
-are prefixed with an 0x66 byte, and those referring to 32-bit addresses
-have an 0x67 prefix. In `BITS 32' mode, the reverse is true: 32-bit
-instructions require no prefixes, whereas instructions using 16-bit data
-need an 0x66 and those working on 16-bit addresses need an 0x67.
-
- When NASM is in `BITS 64' mode, most instructions operate the same as
-they do for `BITS 32' mode. However, there are 8 more general and SSE
-registers, and 16-bit addressing is no longer supported.
-
- The default address size is 64 bits; 32-bit addressing can be
-selected with the 0x67 prefix. The default operand size is still 32
-bits, however, and the 0x66 prefix selects 16-bit operand size. The
-`REX' prefix is used both to select 64-bit operand size, and to access
-the new registers. NASM automatically inserts REX prefixes when
-necessary.
-
- When the `REX' prefix is used, the processor does not know how to
-address the AH, BH, CH or DH (high 8-bit legacy) registers. Instead, it
-is possible to access the the low 8-bits of the SP, BP SI and DI
-registers as SPL, BPL, SIL and DIL, respectively; but only when the REX
-prefix is used.
-
- The `BITS' directive has an exactly equivalent primitive form,
-`[BITS 16]', `[BITS 32]' and `[BITS 64]'. The user-level form is a
-macro which has no function other than to call the primitive form.
-
- Note that the space is neccessary, e.g. `BITS32' will _not_ work!
-
-* Menu:
-
-* Section 6.1.1:: `USE16' & `USE32': Aliases for BITS
-
-
-File: nasm.info, Node: Section 6.1.1, Next: Section 6.2, Prev: Section 6.1, Up: Section 6.1
-
-6.1.1. `USE16' & `USE32': Aliases for BITS
-------------------------------------------
-
-The ``USE16'' and ``USE32'' directives can be used in place of ``BITS
-16'' and ``BITS 32'', for compatibility with other assemblers.
-
-
-File: nasm.info, Node: Section 6.2, Next: Section 6.3, Prev: Section 6.1.1, Up: Chapter 6
-
-6.2. `DEFAULT': Change the assembler defaults
-=============================================
-
-The `DEFAULT' directive changes the assembler defaults. Normally, NASM
-defaults to a mode where the programmer is expected to explicitly
-specify most features directly. However, this is occationally
-obnoxious, as the explicit form is pretty much the only one one wishes
-to use.
-
- Currently, the only `DEFAULT' that is settable is whether or not
-registerless instructions in 64-bit mode are `RIP'-relative or not. By
-default, they are absolute unless overridden with the `REL' specifier
-(see *note Section 3.3::). However, if `DEFAULT REL' is specified,
-`REL' is default, unless overridden with the `ABS' specifier, _except
-when used with an FS or GS segment override_.
-
- The special handling of `FS' and `GS' overrides are due to the fact
-that these registers are generally used as thread pointers or other
-special functions in 64-bit mode, and generating `RIP'-relative
-addresses would be extremely confusing.
-
- `DEFAULT REL' is disabled with `DEFAULT ABS'.
-
-
-File: nasm.info, Node: Section 6.3, Next: Section 6.3.1, Prev: Section 6.2, Up: Chapter 6
-
-6.3. `SECTION' or `SEGMENT': Changing and Defining Sections
-===========================================================
-
-The `SECTION' directive (`SEGMENT' is an exactly equivalent synonym)
-changes which section of the output file the code you write will be
-assembled into. In some object file formats, the number and names of
-sections are fixed; in others, the user may make up as many as they
-wish. Hence `SECTION' may sometimes give an error message, or may
-define a new section, if you try to switch to a section that does not
-(yet) exist.
-
- The Unix object formats, and the `bin' object format (but see *note
-Section 7.1.3::, all support the standardized section names `.text',
-`.data' and `.bss' for the code, data and uninitialized-data sections.
-The `obj' format, by contrast, does not recognize these section names
-as being special, and indeed will strip off the leading period of any
-section name that has one.
-
-* Menu:
-
-* Section 6.3.1:: The `__SECT__' Macro
-
-
-File: nasm.info, Node: Section 6.3.1, Next: Section 6.4, Prev: Section 6.3, Up: Section 6.3
-
-6.3.1. The `__SECT__' Macro
----------------------------
-
-The `SECTION' directive is unusual in that its user-level form
-functions differently from its primitive form. The primitive form,
-`[SECTION xyz]', simply switches the current target section to the one
-given. The user-level form, `SECTION xyz', however, first defines the
-single-line macro `__SECT__' to be the primitive `[SECTION]' directive
-which it is about to issue, and then issues it. So the user-level
-directive
-
- SECTION .text
-
- expands to the two lines
-
- %define __SECT__ [SECTION .text]
- [SECTION .text]
-
- Users may find it useful to make use of this in their own macros. For
-example, the `writefile' macro defined in *note Section 4.3.4:: can be
-usefully rewritten in the following more sophisticated form:
-
- %macro writefile 2+
-
- [section .data]
-
- %%str: db %2
- %%endstr:
-
- __SECT__
-
- mov dx,%%str
- mov cx,%%endstr-%%str
- mov bx,%1
- mov ah,0x40
- int 0x21
-
- %endmacro
-
- This form of the macro, once passed a string to output, first
-switches temporarily to the data section of the file, using the
-primitive form of the `SECTION' directive so as not to modify
-`__SECT__'. It then declares its string in the data section, and then
-invokes `__SECT__' to switch back to _whichever_ section the user was
-previously working in. It thus avoids the need, in the previous version
-of the macro, to include a `JMP' instruction to jump over the data, and
-also does not fail if, in a complicated `OBJ' format module, the user
-could potentially be assembling the code in any of several separate code
-sections.
-
-
-File: nasm.info, Node: Section 6.4, Next: Section 6.5, Prev: Section 6.3.1, Up: Chapter 6
-
-6.4. `ABSOLUTE': Defining Absolute Labels
-=========================================
-
-The `ABSOLUTE' directive can be thought of as an alternative form of
-`SECTION': it causes the subsequent code to be directed at no physical
-section, but at the hypothetical section starting at the given absolute
-address. The only instructions you can use in this mode are the `RESB'
-family.
-
- `ABSOLUTE' is used as follows:
-
- absolute 0x1A
-
- kbuf_chr resw 1
- kbuf_free resw 1
- kbuf resw 16
-
- This example describes a section of the PC BIOS data area, at segment
-address 0x40: the above code defines `kbuf_chr' to be 0x1A, `kbuf_free'
-to be 0x1C, and `kbuf' to be 0x1E.
-
- The user-level form of `ABSOLUTE', like that of `SECTION', redefines
-the `__SECT__' macro when it is invoked.
-
- `STRUC' and `ENDSTRUC' are defined as macros which use `ABSOLUTE'
-(and also `__SECT__').
-
- `ABSOLUTE' doesn't have to take an absolute constant as an argument:
-it can take an expression (actually, a critical expression: see *note
-Section 3.8::) and it can be a value in a segment. For example, a TSR
-can re-use its setup code as run-time BSS like this:
-
- org 100h ; it's a .COM program
-
- jmp setup ; setup code comes last
-
- ; the resident part of the TSR goes here
- setup:
- ; now write the code that installs the TSR here
-
- absolute setup
-
- runtimevar1 resw 1
- runtimevar2 resd 20
-
- tsr_end:
-
- This defines some variables `on top of' the setup code, so that
-after the setup has finished running, the space it took up can be
-re-used as data storage for the running TSR. The symbol `tsr_end' can
-be used to calculate the total size of the part of the TSR that needs
-to be made resident.
-
-
-File: nasm.info, Node: Section 6.5, Next: Section 6.6, Prev: Section 6.4, Up: Chapter 6
-
-6.5. `EXTERN': Importing Symbols from Other Modules
-===================================================
-
-`EXTERN' is similar to the MASM directive `EXTRN' and the C keyword
-`extern': it is used to declare a symbol which is not defined anywhere
-in the module being assembled, but is assumed to be defined in some
-other module and needs to be referred to by this one. Not every
-object-file format can support external variables: the `bin' format
-cannot.
-
- The `EXTERN' directive takes as many arguments as you like. Each
-argument is the name of a symbol:
-
- extern _printf
- extern _sscanf,_fscanf
-
- Some object-file formats provide extra features to the `EXTERN'
-directive. In all cases, the extra features are used by suffixing a
-colon to the symbol name followed by object-format specific text. For
-example, the `obj' format allows you to declare that the default
-segment base of an external should be the group `dgroup' by means of
-the directive
-
- extern _variable:wrt dgroup
-
- The primitive form of `EXTERN' differs from the user-level form only
-in that it can take only one argument at a time: the support for
-multiple arguments is implemented at the preprocessor level.
-
- You can declare the same variable as `EXTERN' more than once: NASM
-will quietly ignore the second and later redeclarations. You can't
-declare a variable as `EXTERN' as well as something else, though.
-
-
-File: nasm.info, Node: Section 6.6, Next: Section 6.7, Prev: Section 6.5, Up: Chapter 6
-
-6.6. `GLOBAL': Exporting Symbols to Other Modules
-=================================================
-
-`GLOBAL' is the other end of `EXTERN': if one module declares a symbol
-as `EXTERN' and refers to it, then in order to prevent linker errors,
-some other module must actually _define_ the symbol and declare it as
-`GLOBAL'. Some assemblers use the name `PUBLIC' for this purpose.
-
- The `GLOBAL' directive applying to a symbol must appear _before_ the
-definition of the symbol.
-
- `GLOBAL' uses the same syntax as `EXTERN', except that it must refer
-to symbols which _are_ defined in the same module as the `GLOBAL'
-directive. For example:
-
- global _main
- _main:
- ; some code
-
- `GLOBAL', like `EXTERN', allows object formats to define private
-extensions by means of a colon. The `elf' object format, for example,
-lets you specify whether global data items are functions or data:
-
- global hashlookup:function, hashtable:data
-
- Like `EXTERN', the primitive form of `GLOBAL' differs from the
-user-level form only in that it can take only one argument at a time.
-
-
-File: nasm.info, Node: Section 6.7, Next: Section 6.8, Prev: Section 6.6, Up: Chapter 6
-
-6.7. `COMMON': Defining Common Data Areas
-=========================================
-
-The `COMMON' directive is used to declare _common variables_. A common
-variable is much like a global variable declared in the uninitialized
-data section, so that
-
- common intvar 4
-
- is similar in function to
-
- global intvar
- section .bss
-
- intvar resd 1
-
- The difference is that if more than one module defines the same
-common variable, then at link time those variables will be _merged_, and
-references to `intvar' in all modules will point at the same piece of
-memory.
-
- Like `GLOBAL' and `EXTERN', `COMMON' supports object-format specific
-extensions. For example, the `obj' format allows common variables to be
-NEAR or FAR, and the `elf' format allows you to specify the alignment
-requirements of a common variable:
-
- common commvar 4:near ; works in OBJ
- common intarray 100:4 ; works in ELF: 4 byte aligned
-
- Once again, like `EXTERN' and `GLOBAL', the primitive form of
-`COMMON' differs from the user-level form only in that it can take only
-one argument at a time.
-
-
-File: nasm.info, Node: Section 6.8, Next: Section 6.9, Prev: Section 6.7, Up: Chapter 6
-
-6.8. `CPU': Defining CPU Dependencies
-=====================================
-
-The `CPU' directive restricts assembly to those instructions which are
-available on the specified CPU.
-
- Options are:
-
- * `CPU 8086' Assemble only 8086 instruction set
-
- * `CPU 186' Assemble instructions up to the 80186 instruction set
-
- * `CPU 286' Assemble instructions up to the 286 instruction set
-
- * `CPU 386' Assemble instructions up to the 386 instruction set
-
- * `CPU 486' 486 instruction set
-
- * `CPU 586' Pentium instruction set
-
- * `CPU PENTIUM' Same as 586
-
- * `CPU 686' P6 instruction set
-
- * `CPU PPRO' Same as 686
-
- * `CPU P2' Same as 686
-
- * `CPU P3' Pentium III (Katmai) instruction sets
-
- * `CPU KATMAI' Same as P3
-
- * `CPU P4' Pentium 4 (Willamette) instruction set
-
- * `CPU WILLAMETTE' Same as P4
-
- * `CPU PRESCOTT' Prescott instruction set
-
- * `CPU X64' x86-64 (x64/AMD64/Intel 64) instruction set
-
- * `CPU IA64' IA64 CPU (in x86 mode) instruction set
-
- All options are case insensitive. All instructions will be selected
-only if they apply to the selected CPU or lower. By default, all
-instructions are available.
-
-
-File: nasm.info, Node: Section 6.9, Next: Chapter 7, Prev: Section 6.8, Up: Chapter 6
-
-6.9. `FLOAT': Handling of floating-point constants
-==================================================
-
-By default, floating-point constants are rounded to nearest, and IEEE
-denormals are supported. The following options can be set to alter this
-behaviour:
-
- * `FLOAT DAZ' Flush denormals to zero
-
- * `FLOAT NODAZ' Do not flush denormals to zero (default)
-
- * `FLOAT NEAR' Round to nearest (default)
-
- * `FLOAT UP' Round up (toward +Infinity)
-
- * `FLOAT DOWN' Round down (toward -Infinity)
-
- * `FLOAT ZERO' Round toward zero
-
- * `FLOAT DEFAULT' Restore default settings
-
- The standard macros `__FLOAT_DAZ__', `__FLOAT_ROUND__', and
-`__FLOAT__' contain the current state, as long as the programmer has
-avoided the use of the brackeded primitive form, (`[FLOAT]').
-
- `__FLOAT__' contains the full set of floating-point settings; this
-value can be saved away and invoked later to restore the setting.
-
-
-File: nasm.info, Node: Chapter 7, Next: Section 7.1, Prev: Section 6.9, Up: Top
-
-Chapter 7: Output Formats
-*************************
-
-NASM is a portable assembler, designed to be able to compile on any
-ANSI C- supporting platform and produce output to run on a variety of
-Intel x86 operating systems. For this reason, it has a large number of
-available output formats, selected using the `-f' option on the NASM
-command line. Each of these formats, along with its extensions to the
-base NASM syntax, is detailed in this chapter.
-
- As stated in *note Section 2.1.1::, NASM chooses a default name for
-your output file based on the input file name and the chosen output
-format. This will be generated by removing the extension (`.asm', `.s',
-or whatever you like to use) from the input file name, and substituting
-an extension defined by the output format. The extensions are given
-with each format below.
-
-* Menu:
-
-* Section 7.1:: `bin': Flat-Form Binary Output
-* Section 7.2:: `ith': Intel Hex Output
-* Section 7.3:: `srec': Motorola S-Records Output
-* Section 7.4:: `obj': Microsoft OMF Object Files
-* Section 7.5:: `win32': Microsoft Win32 Object Files
-* Section 7.6:: `win64': Microsoft Win64 Object Files
-* Section 7.7:: `coff': Common Object File Format
-* Section 7.8:: `macho32' and `macho64': Mach Object File Format
-* Section 7.9:: `elf32' and `elf64': Executable and Linkable Format Object Files
-* Section 7.10:: `aout': Linux `a.out' Object Files
-* Section 7.11:: `aoutb': NetBSD/FreeBSD/OpenBSD `a.out' Object Files
-* Section 7.12:: `as86': Minix/Linux `as86' Object Files
-* Section 7.13:: `rdf': Relocatable Dynamic Object File Format
-* Section 7.14:: `dbg': Debugging Format
-
-
-File: nasm.info, Node: Section 7.1, Next: Section 7.1.1, Prev: Chapter 7, Up: Chapter 7
-
-7.1. `bin': Flat-Form Binary Output
-===================================
-
-The `bin' format does not produce object files: it generates nothing in
-the output file except the code you wrote. Such `pure binary' files are
-used by MS-DOS: `.COM' executables and `.SYS' device drivers are pure
-binary files. Pure binary output is also useful for operating system
-and boot loader development.
-
- The `bin' format supports multiple section names. For details of how
-NASM handles sections in the `bin' format, see *note Section 7.1.3::.
-
- Using the `bin' format puts NASM by default into 16-bit mode (see
-*note Section 6.1::). In order to use `bin' to write 32-bit or 64-bit
-code, such as an OS kernel, you need to explicitly issue the `BITS 32'
-or `BITS 64' directive.
-
- `bin' has no default output file name extension: instead, it leaves
-your file name as it is once the original extension has been removed.
-Thus, the default is for NASM to assemble `binprog.asm' into a binary
-file called `binprog'.
-
-* Menu:
-
-* Section 7.1.1:: `ORG': Binary File Program Origin
-* Section 7.1.2:: `bin' Extensions to the `SECTION' Directive
-* Section 7.1.3:: Multisection Support for the `bin' Format
-* Section 7.1.4:: Map Files
-
-
-File: nasm.info, Node: Section 7.1.1, Next: Section 7.1.2, Prev: Section 7.1, Up: Section 7.1
-
-7.1.1. `ORG': Binary File Program Origin
-----------------------------------------
-
-The `bin' format provides an additional directive to the list given in
-*note Chapter 6::: `ORG'. The function of the `ORG' directive is to
-specify the origin address which NASM will assume the program begins at
-when it is loaded into memory.
-
- For example, the following code will generate the longword
-`0x00000104':
-
- org 0x100
- dd label
- label:
-
- Unlike the `ORG' directive provided by MASM-compatible assemblers,
-which allows you to jump around in the object file and overwrite code
-you have already generated, NASM's `ORG' does exactly what the directive
-says: _origin_. Its sole function is to specify one offset which is
-added to all internal address references within the section; it does not
-permit any of the trickery that MASM's version does. See *note Section
-12.1.3:: for further comments.
-
-
-File: nasm.info, Node: Section 7.1.2, Next: Section 7.1.3, Prev: Section 7.1.1, Up: Section 7.1
-
-7.1.2. `bin' Extensions to the `SECTION' Directive
---------------------------------------------------
-
-The `bin' output format extends the `SECTION' (or `SEGMENT') directive
-to allow you to specify the alignment requirements of segments. This
-is done by appending the `ALIGN' qualifier to the end of the
-section-definition line. For example,
-
- section .data align=16
-
- switches to the section `.data' and also specifies that it must be
-aligned on a 16-byte boundary.
-
- The parameter to `ALIGN' specifies how many low bits of the section
-start address must be forced to zero. The alignment value given may be
-any power of two.
-
-
-File: nasm.info, Node: Section 7.1.3, Next: Section 7.1.4, Prev: Section 7.1.2, Up: Section 7.1
-
-7.1.3. Multisection Support for the `bin' Format
-------------------------------------------------
-
-The `bin' format allows the use of multiple sections, of arbitrary
-names, besides the "known" `.text', `.data', and `.bss' names.
-
- * Sections may be designated `progbits' or `nobits'. Default is
- `progbits' (except `.bss', which defaults to `nobits', of course).
-
- * Sections can be aligned at a specified boundary following the
- previous section with `align=', or at an arbitrary byte-granular
- position with `start='.
-
- * Sections can be given a virtual start address, which will be used
- for the calculation of all memory references within that section
- with `vstart='.
-
- * Sections can be ordered using `follows='`<section>' or
- `vfollows='`<section>' as an alternative to specifying an explicit
- start address.
-
- * Arguments to `org', `start', `vstart', and `align=' are critical
- expressions. See *note Section 3.8::. E.g. `align=(1 <<
- ALIGN_SHIFT)' - `ALIGN_SHIFT' must be defined before it is used
- here.
-
- * Any code which comes before an explicit `SECTION' directive is
- directed by default into the `.text' section.
-
- * If an `ORG' statement is not given, `ORG 0' is used by default.
-
- * The `.bss' section will be placed after the last `progbits'
- section, unless `start=', `vstart=', `follows=', or `vfollows='
- has been specified.
-
- * All sections are aligned on dword boundaries, unless a different
- alignment has been specified.
-
- * Sections may not overlap.
-
- * NASM creates the `section.<secname>.start' for each section, which
- may be used in your code.
-
-
-File: nasm.info, Node: Section 7.1.4, Next: Section 7.2, Prev: Section 7.1.3, Up: Section 7.1
-
-7.1.4. Map Files
-----------------
-
-Map files can be generated in `-f bin' format by means of the `[map]'
-option. Map types of `all' (default), `brief', `sections', `segments',
-or `symbols' may be specified. Output may be directed to `stdout'
-(default), `stderr', or a specified file. E.g. `[map symbols
-myfile.map]'. No "user form" exists, the square brackets must be used.
-
-
-File: nasm.info, Node: Section 7.2, Next: Section 7.3, Prev: Section 7.1.4, Up: Chapter 7
-
-7.2. `ith': Intel Hex Output
-============================
-
-The `ith' file format produces Intel hex-format files. Just as the
-`bin' format, this is a flat memory image format with no support for
-relocation or linking. It is usually used with ROM programmers and
-similar utilities.
-
- All extensions supported by the `bin' file format is also supported
-by the `ith' file format.
-
- `ith' provides a default output file-name extension of `.ith'.
-
-
-File: nasm.info, Node: Section 7.3, Next: Section 7.4, Prev: Section 7.2, Up: Chapter 7
-
-7.3. `srec': Motorola S-Records Output
-======================================
-
-The `srec' file format produces Motorola S-records files. Just as the
-`bin' format, this is a flat memory image format with no support for
-relocation or linking. It is usually used with ROM programmers and
-similar utilities.
-
- All extensions supported by the `bin' file format is also supported
-by the `srec' file format.
-
- `srec' provides a default output file-name extension of `.srec'.
-
-
-File: nasm.info, Node: Section 7.4, Next: Section 7.4.1, Prev: Section 7.3, Up: Chapter 7
-
-7.4. `obj': Microsoft OMF Object Files
-======================================
-
-The `obj' file format (NASM calls it `obj' rather than `omf' for
-historical reasons) is the one produced by MASM and TASM, which is
-typically fed to 16-bit DOS linkers to produce `.EXE' files. It is also
-the format used by OS/2.
-
- `obj' provides a default output file-name extension of `.obj'.
-
- `obj' is not exclusively a 16-bit format, though: NASM has full
-support for the 32-bit extensions to the format. In particular, 32-bit
-`obj' format files are used by Borland's Win32 compilers, instead of
-using Microsoft's newer `win32' object file format.
-
- The `obj' format does not define any special segment names: you can
-call your segments anything you like. Typical names for segments in
-`obj' format files are `CODE', `DATA' and `BSS'.
-
- If your source file contains code before specifying an explicit
-`SEGMENT' directive, then NASM will invent its own segment called
-`__NASMDEFSEG' for you.
-
- When you define a segment in an `obj' file, NASM defines the segment
-name as a symbol as well, so that you can access the segment address of
-the segment. So, for example:
-
- segment data
-
- dvar: dw 1234
-
- segment code
-
- function:
- mov ax,data ; get segment address of data
- mov ds,ax ; and move it into DS
- inc word [dvar] ; now this reference will work
- ret
-
- The `obj' format also enables the use of the `SEG' and `WRT'
-operators, so that you can write code which does things like
-
- extern foo
-
- mov ax,seg foo ; get preferred segment of foo
- mov ds,ax
- mov ax,data ; a different segment
- mov es,ax
- mov ax,[ds:foo] ; this accesses `foo'
- mov [es:foo wrt data],bx ; so does this
-
-* Menu:
-
-* Section 7.4.1:: `obj' Extensions to the `SEGMENT' Directive
-* Section 7.4.2:: `GROUP': Defining Groups of Segments
-* Section 7.4.3:: `UPPERCASE': Disabling Case Sensitivity in Output
-* Section 7.4.4:: `IMPORT': Importing DLL Symbols
-* Section 7.4.5:: `EXPORT': Exporting DLL Symbols
-* Section 7.4.6:: `..start': Defining the Program Entry Point
-* Section 7.4.7:: `obj' Extensions to the `EXTERN' Directive
-* Section 7.4.8:: `obj' Extensions to the `COMMON' Directive
-
-
-File: nasm.info, Node: Section 7.4.1, Next: Section 7.4.2, Prev: Section 7.4, Up: Section 7.4
-
-7.4.1. `obj' Extensions to the `SEGMENT' Directive
---------------------------------------------------
-
-The `obj' output format extends the `SEGMENT' (or `SECTION') directive
-to allow you to specify various properties of the segment you are
-defining. This is done by appending extra qualifiers to the end of the
-segment-definition line. For example,
-
- segment code private align=16
-
- defines the segment `code', but also declares it to be a private
-segment, and requires that the portion of it described in this code
-module must be aligned on a 16-byte boundary.
-
- The available qualifiers are:
-
- * `PRIVATE', `PUBLIC', `COMMON' and `STACK' specify the combination
- characteristics of the segment. `PRIVATE' segments do not get
- combined with any others by the linker; `PUBLIC' and `STACK'
- segments get concatenated together at link time; and `COMMON'
- segments all get overlaid on top of each other rather than stuck
- end-to-end.
-
- * `ALIGN' is used, as shown above, to specify how many low bits of
- the segment start address must be forced to zero. The alignment
- value given may be any power of two from 1 to 4096; in reality,
- the only values supported are 1, 2, 4, 16, 256 and 4096, so if 8
- is specified it will be rounded up to 16, and 32, 64 and 128 will
- all be rounded up to 256, and so on. Note that alignment to
- 4096-byte boundaries is a PharLap extension to the format and may
- not be supported by all linkers.
-
- * `CLASS' can be used to specify the segment class; this feature
- indicates to the linker that segments of the same class should be
- placed near each other in the output file. The class name can be
- any word, e.g. `CLASS=CODE'.
-
- * `OVERLAY', like `CLASS', is specified with an arbitrary word as an
- argument, and provides overlay information to an overlay-capable
- linker.
-
- * Segments can be declared as `USE16' or `USE32', which has the
- effect of recording the choice in the object file and also
- ensuring that NASM's default assembly mode when assembling in that
- segment is 16-bit or 32-bit respectively.
-
- * When writing OS/2 object files, you should declare 32-bit segments
- as `FLAT', which causes the default segment base for anything in
- the segment to be the special group `FLAT', and also defines the
- group if it is not already defined.
-
- * The `obj' file format also allows segments to be declared as
- having a pre-defined absolute segment address, although no linkers
- are currently known to make sensible use of this feature;
- nevertheless, NASM allows you to declare a segment such as
- `SEGMENT SCREEN ABSOLUTE=0xB800' if you need to. The `ABSOLUTE'
- and `ALIGN' keywords are mutually exclusive.
-
- NASM's default segment attributes are `PUBLIC', `ALIGN=1', no class,
-no overlay, and `USE16'.
-
-
-File: nasm.info, Node: Section 7.4.2, Next: Section 7.4.3, Prev: Section 7.4.1, Up: Section 7.4
-
-7.4.2. `GROUP': Defining Groups of Segments
--------------------------------------------
-
-The `obj' format also allows segments to be grouped, so that a single
-segment register can be used to refer to all the segments in a group.
-NASM therefore supplies the `GROUP' directive, whereby you can code
-
- segment data
-
- ; some data
-
- segment bss
-
- ; some uninitialized data
-
- group dgroup data bss
-
- which will define a group called `dgroup' to contain the segments
-`data' and `bss'. Like `SEGMENT', `GROUP' causes the group name to be
-defined as a symbol, so that you can refer to a variable `var' in the
-`data' segment as `var wrt data' or as `var wrt dgroup', depending on
-which segment value is currently in your segment register.
-
- If you just refer to `var', however, and `var' is declared in a
-segment which is part of a group, then NASM will default to giving you
-the offset of `var' from the beginning of the _group_, not the
-_segment_. Therefore `SEG var', also, will return the group base rather
-than the segment base.
-
- NASM will allow a segment to be part of more than one group, but will
-generate a warning if you do this. Variables declared in a segment
-which is part of more than one group will default to being relative to
-the first group that was defined to contain the segment.
-
- A group does not have to contain any segments; you can still make
-`WRT' references to a group which does not contain the variable you are
-referring to. OS/2, for example, defines the special group `FLAT' with
-no segments in it.
-
-
-File: nasm.info, Node: Section 7.4.3, Next: Section 7.4.4, Prev: Section 7.4.2, Up: Section 7.4
-
-7.4.3. `UPPERCASE': Disabling Case Sensitivity in Output
---------------------------------------------------------
-
-Although NASM itself is case sensitive, some OMF linkers are not;
-therefore it can be useful for NASM to output single-case object files.
-The `UPPERCASE' format-specific directive causes all segment, group and
-symbol names that are written to the object file to be forced to upper
-case just before being written. Within a source file, NASM is still
-case- sensitive; but the object file can be written entirely in upper
-case if desired.
-
- `UPPERCASE' is used alone on a line; it requires no parameters.
-
-
-File: nasm.info, Node: Section 7.4.4, Next: Section 7.4.5, Prev: Section 7.4.3, Up: Section 7.4
-
-7.4.4. `IMPORT': Importing DLL Symbols
---------------------------------------
-
-The `IMPORT' format-specific directive defines a symbol to be imported
-from a DLL, for use if you are writing a DLL's import library in NASM.
-You still need to declare the symbol as `EXTERN' as well as using the
-`IMPORT' directive.
-
- The `IMPORT' directive takes two required parameters, separated by
-white space, which are (respectively) the name of the symbol you wish to
-import and the name of the library you wish to import it from. For
-example:
-
- import WSAStartup wsock32.dll
-
- A third optional parameter gives the name by which the symbol is
-known in the library you are importing it from, in case this is not the
-same as the name you wish the symbol to be known by to your code once
-you have imported it. For example:
-
- import asyncsel wsock32.dll WSAAsyncSelect
-
-
-File: nasm.info, Node: Section 7.4.5, Next: Section 7.4.6, Prev: Section 7.4.4, Up: Section 7.4
-
-7.4.5. `EXPORT': Exporting DLL Symbols
---------------------------------------
-
-The `EXPORT' format-specific directive defines a global symbol to be
-exported as a DLL symbol, for use if you are writing a DLL in NASM. You
-still need to declare the symbol as `GLOBAL' as well as using the
-`EXPORT' directive.
-
- `EXPORT' takes one required parameter, which is the name of the
-symbol you wish to export, as it was defined in your source file. An
-optional second parameter (separated by white space from the first)
-gives the _external_ name of the symbol: the name by which you wish the
-symbol to be known to programs using the DLL. If this name is the same
-as the internal name, you may leave the second parameter off.
-
- Further parameters can be given to define attributes of the exported
-symbol. These parameters, like the second, are separated by white
-space. If further parameters are given, the external name must also be
-specified, even if it is the same as the internal name. The available
-attributes are:
-
- * `resident' indicates that the exported name is to be kept resident
- by the system loader. This is an optimisation for frequently used
- symbols imported by name.
-
- * `nodata' indicates that the exported symbol is a function which
- does not make use of any initialized data.
-
- * `parm=NNN', where `NNN' is an integer, sets the number of
- parameter words for the case in which the symbol is a call gate
- between 32- bit and 16-bit segments.
-
- * An attribute which is just a number indicates that the symbol
- should be exported with an identifying number (ordinal), and gives
- the desired number.
-
- For example:
-
- export myfunc
- export myfunc TheRealMoreFormalLookingFunctionName
- export myfunc myfunc 1234 ; export by ordinal
- export myfunc myfunc resident parm=23 nodata
-
-
-File: nasm.info, Node: Section 7.4.6, Next: Section 7.4.7, Prev: Section 7.4.5, Up: Section 7.4
-
-7.4.6. `..start': Defining the Program Entry Point
---------------------------------------------------
-
-`OMF' linkers require exactly one of the object files being linked to
-define the program entry point, where execution will begin when the
-program is run. If the object file that defines the entry point is
-assembled using NASM, you specify the entry point by declaring the
-special symbol `..start' at the point where you wish execution to begin.
-
-
-File: nasm.info, Node: Section 7.4.7, Next: Section 7.4.8, Prev: Section 7.4.6, Up: Section 7.4
-
-7.4.7. `obj' Extensions to the `EXTERN' Directive
--------------------------------------------------
-
-If you declare an external symbol with the directive
-
- extern foo
-
- then references such as `mov ax,foo' will give you the offset of
-`foo' from its preferred segment base (as specified in whichever module
-`foo' is actually defined in). So to access the contents of `foo' you
-will usually need to do something like
-
- mov ax,seg foo ; get preferred segment base
- mov es,ax ; move it into ES
- mov ax,[es:foo] ; and use offset `foo' from it
-
- This is a little unwieldy, particularly if you know that an external
-is going to be accessible from a given segment or group, say `dgroup'.
-So if `DS' already contained `dgroup', you could simply code
-
- mov ax,[foo wrt dgroup]
-
- However, having to type this every time you want to access `foo' can
-be a pain; so NASM allows you to declare `foo' in the alternative form
-
- extern foo:wrt dgroup
-
- This form causes NASM to pretend that the preferred segment base of
-`foo' is in fact `dgroup'; so the expression `seg foo' will now return
-`dgroup', and the expression `foo' is equivalent to `foo wrt dgroup'.
-
- This default-`WRT' mechanism can be used to make externals appear to
-be relative to any group or segment in your program. It can also be
-applied to common variables: see *note Section 7.4.8::.
-
-
-File: nasm.info, Node: Section 7.4.8, Next: Section 7.5, Prev: Section 7.4.7, Up: Section 7.4
-
-7.4.8. `obj' Extensions to the `COMMON' Directive
--------------------------------------------------
-
-The `obj' format allows common variables to be either near or far; NASM
-allows you to specify which your variables should be by the use of the
-syntax
-
- common nearvar 2:near ; `nearvar' is a near common
- common farvar 10:far ; and `farvar' is far
-
- Far common variables may be greater in size than 64Kb, and so the OMF
-specification says that they are declared as a number of _elements_ of
-a given size. So a 10-byte far common variable could be declared as ten
-one-byte elements, five two-byte elements, two five-byte elements or one
-ten-byte element.
-
- Some `OMF' linkers require the element size, as well as the variable
-size, to match when resolving common variables declared in more than one
-module. Therefore NASM must allow you to specify the element size on
-your far common variables. This is done by the following syntax:
-
- common c_5by2 10:far 5 ; two five-byte elements
- common c_2by5 10:far 2 ; five two-byte elements
-
- If no element size is specified, the default is 1. Also, the `FAR'
-keyword is not required when an element size is specified, since only
-far commons may have element sizes at all. So the above declarations
-could equivalently be
-
- common c_5by2 10:5 ; two five-byte elements
- common c_2by5 10:2 ; five two-byte elements
-
- In addition to these extensions, the `COMMON' directive in `obj'
-also supports default-`WRT' specification like `EXTERN' does (explained
-in *note Section 7.4.7::). So you can also declare things like
-
- common foo 10:wrt dgroup
- common bar 16:far 2:wrt data
- common baz 24:wrt data:6
-
-
-File: nasm.info, Node: Section 7.5, Next: Section 7.5.1, Prev: Section 7.4.8, Up: Chapter 7
-
-7.5. `win32': Microsoft Win32 Object Files
-==========================================
-
-The `win32' output format generates Microsoft Win32 object files,
-suitable for passing to Microsoft linkers such as Visual C++. Note that
-Borland Win32 compilers do not use this format, but use `obj' instead
-(see *note Section 7.4::).
-
- `win32' provides a default output file-name extension of `.obj'.
-
- Note that although Microsoft say that Win32 object files follow the
-`COFF' (Common Object File Format) standard, the object files produced
-by Microsoft Win32 compilers are not compatible with COFF linkers such
-as DJGPP's, and vice versa. This is due to a difference of opinion over
-the precise semantics of PC-relative relocations. To produce COFF files
-suitable for DJGPP, use NASM's `coff' output format; conversely, the
-`coff' format does not produce object files that Win32 linkers can
-generate correct output from.
-
-* Menu:
-
-* Section 7.5.1:: `win32' Extensions to the `SECTION' Directive
-* Section 7.5.2:: `win32': Safe Structured Exception Handling
-
-
-File: nasm.info, Node: Section 7.5.1, Next: Section 7.5.2, Prev: Section 7.5, Up: Section 7.5
-
-7.5.1. `win32' Extensions to the `SECTION' Directive
-----------------------------------------------------
-
-Like the `obj' format, `win32' allows you to specify additional
-information on the `SECTION' directive line, to control the type and
-properties of sections you declare. Section types and properties are
-generated automatically by NASM for the standard section names `.text',
-`.data' and `.bss', but may still be overridden by these qualifiers.
-
- The available qualifiers are:
-
- * `code', or equivalently `text', defines the section to be a code
- section. This marks the section as readable and executable, but not
- writable, and also indicates to the linker that the type of the
- section is code.
-
- * `data' and `bss' define the section to be a data section,
- analogously to `code'. Data sections are marked as readable and
- writable, but not executable. `data' declares an initialized data
- section, whereas `bss' declares an uninitialized data section.
-
- * `rdata' declares an initialized data section that is readable but
- not writable. Microsoft compilers use this section to place
- constants in it.
-
- * `info' defines the section to be an informational section, which is
- not included in the executable file by the linker, but may (for
- example) pass information _to_ the linker. For example, declaring
- an `info'-type section called `.drectve' causes the linker to
- interpret the contents of the section as command-line options.
-
- * `align=', used with a trailing number as in `obj', gives the
- alignment requirements of the section. The maximum you may specify
- is 64: the Win32 object file format contains no means to request a
- greater section alignment than this. If alignment is not
- explicitly specified, the defaults are 16-byte alignment for code
- sections, 8-byte alignment for rdata sections and 4-byte alignment
- for data (and BSS) sections. Informational sections get a default
- alignment of 1 byte (no alignment), though the value does not
- matter.
-
- The defaults assumed by NASM if you do not specify the above
-qualifiers are:
-
- section .text code align=16
- section .data data align=4
- section .rdata rdata align=8
- section .bss bss align=4
-
- Any other section name is treated by default like `.text'.
-
-
-File: nasm.info, Node: Section 7.5.2, Next: Section 7.6, Prev: Section 7.5.1, Up: Section 7.5
-
-7.5.2. `win32': Safe Structured Exception Handling
---------------------------------------------------
-
-Among other improvements in Windows XP SP2 and Windows Server 2003
-Microsoft has introduced concept of "safe structured exception
-handling." General idea is to collect handlers' entry points in
-designated read-only table and have alleged entry point verified
-against this table prior exception control is passed to the handler. In
-order for an executable module to be equipped with such "safe exception
-handler table," all object modules on linker command line has to comply
-with certain criteria. If one single module among them does not, then
-the table in question is omitted and above mentioned run-time checks
-will not be performed for application in question. Table omission is by
-default silent and therefore can be easily overlooked. One can instruct
-linker to refuse to produce binary without such table by passing
-`/safeseh' command line option.
-
- Without regard to this run-time check merits it's natural to expect
-NASM to be capable of generating modules suitable for `/safeseh'
-linking. From developer's viewpoint the problem is two-fold:
-
- * how to adapt modules not deploying exception handlers of their own;
-
- * how to adapt/develop modules utilizing custom exception handling;
-
- Former can be easily achieved with any NASM version by adding
-following line to source code:
-
- $@feat.00 equ 1
-
- As of version 2.03 NASM adds this absolute symbol automatically. If
-it's not already present to be precise. I.e. if for whatever reason
-developer would choose to assign another value in source file, it would
-still be perfectly possible.
-
- Registering custom exception handler on the other hand requires
-certain "magic." As of version 2.03 additional directive is implemented,
-`safeseh', which instructs the assembler to produce appropriately
-formatted input data for above mentioned "safe exception handler table."
-Its typical use would be:
-
- section .text
- extern _MessageBoxA@16
- %if __NASM_VERSION_ID__ >= 0x02030000
- safeseh handler ; register handler as "safe handler"
- %endif
- handler:
- push DWORD 1 ; MB_OKCANCEL
- push DWORD caption
- push DWORD text
- push DWORD 0
- call _MessageBoxA@16
- sub eax,1 ; incidentally suits as return value
- ; for exception handler
- ret
- global _main
- _main:
- push DWORD handler
- push DWORD [fs:0]
- mov DWORD [fs:0],esp ; engage exception handler
- xor eax,eax
- mov eax,DWORD[eax] ; cause exception
- pop DWORD [fs:0] ; disengage exception handler
- add esp,4
- ret
- text: db 'OK to rethrow, CANCEL to generate core dump',0
- caption:db 'SEGV',0
-
- section .drectve info
- db '/defaultlib:user32.lib /defaultlib:msvcrt.lib '
-
- As you might imagine, it's perfectly possible to produce .exe binary
-with "safe exception handler table" and yet engage unregistered
-exception handler. Indeed, handler is engaged by simply manipulating
-`[fs:0]' location at run-time, something linker has no power over,
-run-time that is. It should be explicitly mentioned that such failure
-to register handler's entry point with `safeseh' directive has
-undesired side effect at run- time. If exception is raised and
-unregistered handler is to be executed, the application is abruptly
-terminated without any notification whatsoever. One can argue that
-system could at least have logged some kind "non-safe exception handler
-in x.exe at address n" message in event log, but no, literally no
-notification is provided and user is left with no clue on what caused
-application failure.
-
- Finally, all mentions of linker in this paragraph refer to Microsoft
-linker version 7.x and later. Presence of `@feat.00' symbol and input
-data for "safe exception handler table" causes no backward
-incompatibilities and "safeseh" modules generated by NASM 2.03 and
-later can still be linked by earlier versions or non-Microsoft linkers.
-
-
-File: nasm.info, Node: Section 7.6, Next: Section 7.6.1, Prev: Section 7.5.2, Up: Chapter 7
-
-7.6. `win64': Microsoft Win64 Object Files
-==========================================
-
-The `win64' output format generates Microsoft Win64 object files, which
-is nearly 100% identical to the `win32' object format (*note Section
-7.5::) with the exception that it is meant to target 64-bit code and
-the x86-64 platform altogether. This object file is used exactly the
-same as the `win32' object format (*note Section 7.5::), in NASM, with
-regard to this exception.
-
-* Menu:
-
-* Section 7.6.1:: `win64': Writing Position-Independent Code
-* Section 7.6.2:: `win64': Structured Exception Handling
-
-
-File: nasm.info, Node: Section 7.6.1, Next: Section 7.6.2, Prev: Section 7.6, Up: Section 7.6
-
-7.6.1. `win64': Writing Position-Independent Code
--------------------------------------------------
-
-While `REL' takes good care of RIP-relative addressing, there is one
-aspect that is easy to overlook for a Win64 programmer: indirect
-references. Consider a switch dispatch table:
-
- jmp QWORD[dsptch+rax*8]
- ...
- dsptch: dq case0
- dq case1
- ...
-
- Even novice Win64 assembler programmer will soon realize that the
-code is not 64-bit savvy. Most notably linker will refuse to link it
-with "`'ADDR32' relocation to '.text' invalid without
-/LARGEADDRESSAWARE:NO'". So [s]he will have to split jmp instruction
-as following:
-
- lea rbx,[rel dsptch]
- jmp QWORD[rbx+rax*8]
-
- What happens behind the scene is that effective address in `lea' is
-encoded relative to instruction pointer, or in perfectly position-
-independent manner. But this is only part of the problem! Trouble is
-that in .dll context `caseN' relocations will make their way to the
-final module and might have to be adjusted at .dll load time. To be
-specific when it can't be loaded at preferred address. And when this
-occurs, pages with such relocations will be rendered private to current
-process, which kind of undermines the idea of sharing .dll. But no
-worry, it's trivial to fix:
-
- lea rbx,[rel dsptch]
- add rbx,QWORD[rbx+rax*8]
- jmp rbx
- ...
- dsptch: dq case0-dsptch
- dq case1-dsptch
- ...
-
- NASM version 2.03 and later provides another alternative, `wrt
-..imagebase' operator, which returns offset from base address of the
-current image, be it .exe or .dll module, therefore the name. For those
-acquainted with PE-COFF format base address denotes start of
-`IMAGE_DOS_HEADER' structure. Here is how to implement switch with
-these image-relative references:
-
- lea rbx,[rel dsptch]
- mov eax,DWORD[rbx+rax*4]
- sub rbx,dsptch wrt ..imagebase
- add rbx,rax
- jmp rbx
- ...
- dsptch: dd case0 wrt ..imagebase
- dd case1 wrt ..imagebase
-
- One can argue that the operator is redundant. Indeed, snippet before
-last works just fine with any NASM version and is not even Windows
-specific... The real reason for implementing `wrt ..imagebase' will
-become apparent in next paragraph.
-
- It should be noted that `wrt ..imagebase' is defined as 32-bit
-operand only:
-
- dd label wrt ..imagebase ; ok
- dq label wrt ..imagebase ; bad
- mov eax,label wrt ..imagebase ; ok
- mov rax,label wrt ..imagebase ; bad
-
-
-File: nasm.info, Node: Section 7.6.2, Next: Section 7.7, Prev: Section 7.6.1, Up: Section 7.6
-
-7.6.2. `win64': Structured Exception Handling
----------------------------------------------
-
-Structured exception handing in Win64 is completely different matter
-from Win32. Upon exception program counter value is noted, and
-linker-generated table comprising start and end addresses of all the
-functions [in given executable module] is traversed and compared to the
-saved program counter. Thus so called `UNWIND_INFO' structure is
-identified. If it's not found, then offending subroutine is assumed to
-be "leaf" and just mentioned lookup procedure is attempted for its
-caller. In Win64 leaf function is such function that does not call any
-other function _nor_ modifies any Win64 non-volatile registers,
-including stack pointer. The latter ensures that it's possible to
-identify leaf function's caller by simply pulling the value from the
-top of the stack.
-
- While majority of subroutines written in assembler are not calling
-any other function, requirement for non-volatile registers'
-immutability leaves developer with not more than 7 registers and no
-stack frame, which is not necessarily what [s]he counted with.
-Customarily one would meet the requirement by saving non-volatile
-registers on stack and restoring them upon return, so what can go
-wrong? If [and only if] an exception is raised at run-time and no
-`UNWIND_INFO' structure is associated with such "leaf" function, the
-stack unwind procedure will expect to find caller's return address on
-the top of stack immediately followed by its frame. Given that
-developer pushed caller's non-volatile registers on stack, would the
-value on top point at some code segment or even addressable space? Well,
-developer can attempt copying caller's return address to the top of
-stack and this would actually work in some very specific circumstances.
-But unless developer can guarantee that these circumstances are always
-met, it's more appropriate to assume worst case scenario, i.e. stack
-unwind procedure going berserk. Relevant question is what happens then?
-Application is abruptly terminated without any notification whatsoever.
-Just like in Win32 case, one can argue that system could at least have
-logged "unwind procedure went berserk in x.exe at address n" in event
-log, but no, no trace of failure is left.
-
- Now, when we understand significance of the `UNWIND_INFO' structure,
-let's discuss what's in it and/or how it's processed. First of all it is
-checked for presence of reference to custom language-specific exception
-handler. If there is one, then it's invoked. Depending on the return
-value, execution flow is resumed (exception is said to be "handled"),
-_or_ rest of `UNWIND_INFO' structure is processed as following. Beside
-optional reference to custom handler, it carries information about
-current callee's stack frame and where non-volatile registers are saved.
-Information is detailed enough to be able to reconstruct contents of
-caller's non-volatile registers upon call to current callee. And so
-caller's context is reconstructed, and then unwind procedure is
-repeated, i.e. another `UNWIND_INFO' structure is associated, this
-time, with caller's instruction pointer, which is then checked for
-presence of reference to language-specific handler, etc. The procedure
-is recursively repeated till exception is handled. As last resort
-system "handles" it by generating memory core dump and terminating the
-application.
-
- As for the moment of this writing NASM unfortunately does not
-facilitate generation of above mentioned detailed information about
-stack frame layout. But as of version 2.03 it implements building
-blocks for generating structures involved in stack unwinding. As
-simplest example, here is how to deploy custom exception handler for
-leaf function:
-
- default rel
- section .text
- extern MessageBoxA
- handler:
- sub rsp,40
- mov rcx,0
- lea rdx,[text]
- lea r8,[caption]
- mov r9,1 ; MB_OKCANCEL
- call MessageBoxA
- sub eax,1 ; incidentally suits as return value
- ; for exception handler
- add rsp,40
- ret
- global main
- main:
- xor rax,rax
- mov rax,QWORD[rax] ; cause exception
- ret
- main_end:
- text: db 'OK to rethrow, CANCEL to generate core dump',0
- caption:db 'SEGV',0
-
- section .pdata rdata align=4
- dd main wrt ..imagebase
- dd main_end wrt ..imagebase
- dd xmain wrt ..imagebase
- section .xdata rdata align=8
- xmain: db 9,0,0,0
- dd handler wrt ..imagebase
- section .drectve info
- db '/defaultlib:user32.lib /defaultlib:msvcrt.lib '
-
- What you see in `.pdata' section is element of the "table comprising
-start and end addresses of function" along with reference to associated
-`UNWIND_INFO' structure. And what you see in `.xdata' section is
-`UNWIND_INFO' structure describing function with no frame, but with
-designated exception handler. References are _required_ to be image-
-relative (which is the real reason for implementing `wrt ..imagebase'
-operator). It should be noted that `rdata align=n', as well as `wrt
-..imagebase', are optional in these two segments' contexts, i.e. can
-be omitted. Latter means that _all_ 32-bit references, not only above
-listed required ones, placed into these two segments turn out image-
-relative. Why is it important to understand? Developer is allowed to
-append handler-specific data to `UNWIND_INFO' structure, and if [s]he
-adds a 32-bit reference, then [s]he will have to remember to adjust its
-value to obtain the real pointer.
-
- As already mentioned, in Win64 terms leaf function is one that does
-not call any other function _nor_ modifies any non-volatile register,
-including stack pointer. But it's not uncommon that assembler programmer
-plans to utilize every single register and sometimes even have variable
-stack frame. Is there anything one can do with bare building blocks?
-I.e. besides manually composing fully-fledged `UNWIND_INFO' structure,
-which would surely be considered error-prone? Yes, there is. Recall that
-exception handler is called first, before stack layout is analyzed. As
-it turned out, it's perfectly possible to manipulate current callee's
-context in custom handler in manner that permits further stack
-unwinding. General idea is that handler would not actually "handle" the
-exception, but instead restore callee's context, as it was at its entry
-point and thus mimic leaf function. In other words, handler would
-simply undertake part of unwinding procedure. Consider following
-example:
-
- function:
- mov rax,rsp ; copy rsp to volatile register
- push r15 ; save non-volatile registers
- push rbx
- push rbp
- mov r11,rsp ; prepare variable stack frame
- sub r11,rcx
- and r11,-64
- mov QWORD[r11],rax ; check for exceptions
- mov rsp,r11 ; allocate stack frame
- mov QWORD[rsp],rax ; save original rsp value
- magic_point:
- ...
- mov r11,QWORD[rsp] ; pull original rsp value
- mov rbp,QWORD[r11-24]
- mov rbx,QWORD[r11-16]
- mov r15,QWORD[r11-8]
- mov rsp,r11 ; destroy frame
- ret
-
- The keyword is that up to `magic_point' original `rsp' value remains
-in chosen volatile register and no non-volatile register, except for
-`rsp', is modified. While past `magic_point' `rsp' remains constant
-till the very end of the `function'. In this case custom
-language-specific exception handler would look like this:
-
- EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame,
- CONTEXT *context,DISPATCHER_CONTEXT *disp)
- { ULONG64 *rsp;
- if (context->Rip<(ULONG64)magic_point)
- rsp = (ULONG64 *)context->Rax;
- else
- { rsp = ((ULONG64 **)context->Rsp)[0];
- context->Rbp = rsp[-3];
- context->Rbx = rsp[-2];
- context->R15 = rsp[-1];
- }
- context->Rsp = (ULONG64)rsp;
-
- memcpy (disp->ContextRecord,context,sizeof(CONTEXT));
- RtlVirtualUnwind(UNW_FLAG_NHANDLER,disp->ImageBase,
- dips->ControlPc,disp->FunctionEntry,disp->ContextRecord,
- &disp->HandlerData,&disp->EstablisherFrame,NULL);
- return ExceptionContinueSearch;
- }
-
- As custom handler mimics leaf function, corresponding `UNWIND_INFO'
-structure does not have to contain any information about stack frame and
-its layout.
-
-
-File: nasm.info, Node: Section 7.7, Next: Section 7.8, Prev: Section 7.6.2, Up: Chapter 7
-
-7.7. `coff': Common Object File Format
-======================================
-
-The `coff' output type produces `COFF' object files suitable for
-linking with the DJGPP linker.
-
- `coff' provides a default output file-name extension of `.o'.
-
- The `coff' format supports the same extensions to the `SECTION'
-directive as `win32' does, except that the `align' qualifier and the
-`info' section type are not supported.
-
-
-File: nasm.info, Node: Section 7.8, Next: Section 7.9, Prev: Section 7.7, Up: Chapter 7
-
-7.8. `macho32' and `macho64': Mach Object File Format
-=====================================================
-
-The `macho32' and `macho64' output formts produces `Mach-O' object
-files suitable for linking with the MacOS X linker. `macho' is a
-synonym for `macho32'.
-
- `macho' provides a default output file-name extension of `.o'.
-
-
-File: nasm.info, Node: Section 7.9, Next: Section 7.9.1, Prev: Section 7.8, Up: Chapter 7
-
-7.9. `elf32' and `elf64': Executable and Linkable Format Object Files
-=====================================================================
-
-The `elf32' and `elf64' output formats generate `ELF32 and ELF64'
-(Executable and Linkable Format) object files, as used by Linux as well
-as Unix System V, including Solaris x86, UnixWare and SCO Unix. `elf'
-provides a default output file-name extension of `.o'. `elf' is a
-synonym for `elf32'.
-
-* Menu:
-
-* Section 7.9.1:: ELF specific directive `osabi'
-* Section 7.9.2:: `elf' Extensions to the `SECTION' Directive
-* Section 7.9.3:: Position-Independent Code: `elf' Special Symbols and `WRT'
-* Section 7.9.4:: Thread Local Storage: `elf' Special Symbols and `WRT'
-* Section 7.9.5:: `elf' Extensions to the `GLOBAL' Directive
-* Section 7.9.6:: `elf' Extensions to the `COMMON' Directive
-* Section 7.9.7:: 16-bit code and ELF
-* Section 7.9.8:: Debug formats and ELF
-
-
-File: nasm.info, Node: Section 7.9.1, Next: Section 7.9.2, Prev: Section 7.9, Up: Section 7.9
-
-7.9.1. ELF specific directive `osabi'
--------------------------------------
-
-The ELF header specifies the application binary interface for the target
-operating system (OSABI). This field can be set by using the `osabi'
-directive with the numeric value (0-255) of the target system. If this
-directive is not used, the default value will be "UNIX System V ABI" (0)
-which will work on most systems which support ELF.
-
-
-File: nasm.info, Node: Section 7.9.2, Next: Section 7.9.3, Prev: Section 7.9.1, Up: Section 7.9
-
-7.9.2. `elf' Extensions to the `SECTION' Directive
---------------------------------------------------
-
-Like the `obj' format, `elf' allows you to specify additional
-information on the `SECTION' directive line, to control the type and
-properties of sections you declare. Section types and properties are
-generated automatically by NASM for the standard section names, but may
-still be overridden by these qualifiers.
-
- The available qualifiers are:
-
- * `alloc' defines the section to be one which is loaded into memory
- when the program is run. `noalloc' defines it to be one which is
- not, such as an informational or comment section.
-
- * `exec' defines the section to be one which should have execute
- permission when the program is run. `noexec' defines it as one
- which should not.
-
- * `write' defines the section to be one which should be writable when
- the program is run. `nowrite' defines it as one which should not.
-
- * `progbits' defines the section to be one with explicit contents
- stored in the object file: an ordinary code or data section, for
- example, `nobits' defines the section to be one with no explicit
- contents given, such as a BSS section.
-
- * `align=', used with a trailing number as in `obj', gives the
- alignment requirements of the section.
-
- * `tls' defines the section to be one which contains thread local
- variables.
-
- The defaults assumed by NASM if you do not specify the above
-qualifiers are:
-
- section .text progbits alloc exec nowrite align=16
- section .rodata progbits alloc noexec nowrite align=4
- section .lrodata progbits alloc noexec nowrite align=4
- section .data progbits alloc noexec write align=4
- section .ldata progbits alloc noexec write align=4
- section .bss nobits alloc noexec write align=4
- section .lbss nobits alloc noexec write align=4
- section .tdata progbits alloc noexec write align=4 tls
- section .tbss nobits alloc noexec write align=4 tls
- section .comment progbits noalloc noexec nowrite align=1
- section other progbits alloc noexec nowrite align=1
-
- (Any section name other than those in the above table is treated by
-default like `other' in the above table. Please note that section names
-are case sensitive.)
-
-
-File: nasm.info, Node: Section 7.9.3, Next: Section 7.9.4, Prev: Section 7.9.2, Up: Section 7.9
-
-7.9.3. Position-Independent Code: `elf' Special Symbols and `WRT'
------------------------------------------------------------------
-
-The `ELF' specification contains enough features to allow position-
-independent code (PIC) to be written, which makes ELF shared libraries
-very flexible. However, it also means NASM has to be able to generate a
-variety of ELF specific relocation types in ELF object files, if it is
-to be an assembler which can write PIC.
-
- Since `ELF' does not support segment-base references, the `WRT'
-operator is not used for its normal purpose; therefore NASM's `elf'
-output format makes use of `WRT' for a different purpose, namely the
-PIC-specific relocation types.
-
- `elf' defines five special symbols which you can use as the
-right-hand side of the `WRT' operator to obtain PIC relocation types.
-They are `..gotpc', `..gotoff', `..got', `..plt' and `..sym'. Their
-functions are summarized here:
-
- * Referring to the symbol marking the global offset table base using
- `wrt ..gotpc' will end up giving the distance from the beginning of
- the current section to the global offset table.
- (`_GLOBAL_OFFSET_TABLE_' is the standard symbol name used to refer
- to the GOT.) So you would then need to add `$$' to the result to
- get the real address of the GOT.
-
- * Referring to a location in one of your own sections using `wrt
- ..gotoff' will give the distance from the beginning of the GOT to
- the specified location, so that adding on the address of the GOT
- would give the real address of the location you wanted.
-
- * Referring to an external or global symbol using `wrt ..got' causes
- the linker to build an entry _in_ the GOT containing the address
- of the symbol, and the reference gives the distance from the
- beginning of the GOT to the entry; so you can add on the address
- of the GOT, load from the resulting address, and end up with the
- address of the symbol.
-
- * Referring to a procedure name using `wrt ..plt' causes the linker
- to build a procedure linkage table entry for the symbol, and the
- reference gives the address of the PLT entry. You can only use
- this in contexts which would generate a PC-relative relocation
- normally (i.e. as the destination for `CALL' or `JMP'), since ELF
- contains no relocation type to refer to PLT entries absolutely.
-
- * Referring to a symbol name using `wrt ..sym' causes NASM to write
- an ordinary relocation, but instead of making the relocation
- relative to the start of the section and then adding on the offset
- to the symbol, it will write a relocation record aimed directly at
- the symbol in question. The distinction is a necessary one due to
- a peculiarity of the dynamic linker.
-
- A fuller explanation of how to use these relocation types to write
-shared libraries entirely in NASM is given in *note Section 9.2::.
-
-
-File: nasm.info, Node: Section 7.9.4, Next: Section 7.9.5, Prev: Section 7.9.3, Up: Section 7.9
-
-7.9.4. Thread Local Storage: `elf' Special Symbols and `WRT'
-------------------------------------------------------------
-
- * In ELF32 mode, referring to an external or global symbol using
- `wrt ..tlsie' causes the linker to build an entry _in_ the GOT
- containing the offset of the symbol within the TLS block, so you
- can access the value of the symbol with code such as:
-
- mov eax,[tid wrt ..tlsie]
- mov [gs:eax],ebx
-
- * In ELF64 mode, referring to an external or global symbol using
- `wrt ..gottpoff' causes the linker to build an entry _in_ the GOT
- containing the offset of the symbol within the TLS block, so you
- can access the value of the symbol with code such as:
-
- mov rax,[rel tid wrt ..gottpoff]
- mov rcx,[fs:rax]
-
-
-File: nasm.info, Node: Section 7.9.5, Next: Section 7.9.6, Prev: Section 7.9.4, Up: Section 7.9
-
-7.9.5. `elf' Extensions to the `GLOBAL' Directive
--------------------------------------------------
-
-`ELF' object files can contain more information about a global symbol
-than just its address: they can contain the size of the symbol and its
-type as well. These are not merely debugger conveniences, but are
-actually necessary when the program being written is a shared library.
-NASM therefore supports some extensions to the `GLOBAL' directive,
-allowing you to specify these features.
-
- You can specify whether a global variable is a function or a data
-object by suffixing the name with a colon and the word `function' or
-`data'. (`object' is a synonym for `data'.) For example:
-
- global hashlookup:function, hashtable:data
-
- exports the global symbol `hashlookup' as a function and `hashtable'
-as a data object.
-
- Optionally, you can control the ELF visibility of the symbol. Just
-add one of the visibility keywords: `default', `internal', `hidden', or
-`protected'. The default is `default' of course. For example, to make
-`hashlookup' hidden:
-
- global hashlookup:function hidden
-
- You can also specify the size of the data associated with the
-symbol, as a numeric expression (which may involve labels, and even
-forward references) after the type specifier. Like this:
-
- global hashtable:data (hashtable.end - hashtable)
-
- hashtable:
- db this,that,theother ; some data here
- .end:
-
- This makes NASM automatically calculate the length of the table and
-place that information into the `ELF' symbol table.
-
- Declaring the type and size of global symbols is necessary when
-writing shared library code. For more information, see *note Section
-9.2.4::.
-
-
-File: nasm.info, Node: Section 7.9.6, Next: Section 7.9.7, Prev: Section 7.9.5, Up: Section 7.9
-
-7.9.6. `elf' Extensions to the `COMMON' Directive
--------------------------------------------------
-
-`ELF' also allows you to specify alignment requirements on common
-variables. This is done by putting a number (which must be a power of
-two) after the name and size of the common variable, separated (as
-usual) by a colon. For example, an array of doublewords would benefit
-from 4-byte alignment:
-
- common dwordarray 128:4
-
- This declares the total size of the array to be 128 bytes, and
-requires that it be aligned on a 4-byte boundary.
-
-
-File: nasm.info, Node: Section 7.9.7, Next: Section 7.9.8, Prev: Section 7.9.6, Up: Section 7.9
-
-7.9.7. 16-bit code and ELF
---------------------------
-
-The `ELF32' specification doesn't provide relocations for 8- and 16-
-bit values, but the GNU `ld' linker adds these as an extension. NASM
-can generate GNU-compatible relocations, to allow 16-bit code to be
-linked as ELF using GNU `ld'. If NASM is used with the
-`-w+gnu-elf-extensions' option, a warning is issued when one of these
-relocations is generated.
-
-
-File: nasm.info, Node: Section 7.9.8, Next: Section 7.10, Prev: Section 7.9.7, Up: Section 7.9
-
-7.9.8. Debug formats and ELF
-----------------------------
-
-`ELF32' and `ELF64' provide debug information in `STABS' and `DWARF'
-formats. Line number information is generated for all executable
-sections, but please note that only the ".text" section is executable
-by default.
-
-
-File: nasm.info, Node: Section 7.10, Next: Section 7.11, Prev: Section 7.9.8, Up: Chapter 7
-
-7.10. `aout': Linux `a.out' Object Files
-========================================
-
-The `aout' format generates `a.out' object files, in the form used by
-early Linux systems (current Linux systems use ELF, see *note Section
-7.9::.) These differ from other `a.out' object files in that the magic
-number in the first four bytes of the file is different; also, some
-implementations of `a.out', for example NetBSD's, support
-position-independent code, which Linux's implementation does not.
-
- `a.out' provides a default output file-name extension of `.o'.
-
- `a.out' is a very simple object format. It supports no special
-directives, no special symbols, no use of `SEG' or `WRT', and no
-extensions to any standard directives. It supports only the three
-standard section names `.text', `.data' and `.bss'.
-
-
-File: nasm.info, Node: Section 7.11, Next: Section 7.12, Prev: Section 7.10, Up: Chapter 7
-
-7.11. `aoutb': NetBSD/FreeBSD/OpenBSD `a.out' Object Files
-==========================================================
-
-The `aoutb' format generates `a.out' object files, in the form used by
-the various free `BSD Unix' clones, `NetBSD', `FreeBSD' and `OpenBSD'.
-For simple object files, this object format is exactly the same as
-`aout' except for the magic number in the first four bytes of the file.
-However, the `aoutb' format supports position-independent code in the
-same way as the `elf' format, so you can use it to write `BSD' shared
-libraries.
-
- `aoutb' provides a default output file-name extension of `.o'.
-
- `aoutb' supports no special directives, no special symbols, and only
-the three standard section names `.text', `.data' and `.bss'. However,
-it also supports the same use of `WRT' as `elf' does, to provide
-position-independent code relocation types. See *note Section 7.9.3::
-for full documentation of this feature.
-
- `aoutb' also supports the same extensions to the `GLOBAL' directive
-as `elf' does: see *note Section 7.9.5:: for documentation of this.
-
-
-File: nasm.info, Node: Section 7.12, Next: Section 7.13, Prev: Section 7.11, Up: Chapter 7
-
-7.12. `as86': Minix/Linux `as86' Object Files
-=============================================
-
-The Minix/Linux 16-bit assembler `as86' has its own non-standard object
-file format. Although its companion linker `ld86' produces something
-close to ordinary `a.out' binaries as output, the object file format
-used to communicate between `as86' and `ld86' is not itself `a.out'.
-
- NASM supports this format, just in case it is useful, as `as86'.
-`as86' provides a default output file-name extension of `.o'.
-
- `as86' is a very simple object format (from the NASM user's point of
-view). It supports no special directives, no use of `SEG' or `WRT', and
-no extensions to any standard directives. It supports only the three
-standard section names `.text', `.data' and `.bss'. The only special
-symbol supported is `..start'.
-
-
-File: nasm.info, Node: Section 7.13, Next: Section 7.13.1, Prev: Section 7.12, Up: Chapter 7
-
-7.13. `rdf': Relocatable Dynamic Object File Format
-===================================================
-
-The `rdf' output format produces `RDOFF' object files. `RDOFF'
-(Relocatable Dynamic Object File Format) is a home-grown object-file
-format, designed alongside NASM itself and reflecting in its file
-format the internal structure of the assembler.
-
- `RDOFF' is not used by any well-known operating systems. Those
-writing their own systems, however, may well wish to use `RDOFF' as
-their object format, on the grounds that it is designed primarily for
-simplicity and contains very little file-header bureaucracy.
-
- The Unix NASM archive, and the DOS archive which includes sources,
-both contain an `rdoff' subdirectory holding a set of RDOFF utilities:
-an RDF linker, an `RDF' static-library manager, an RDF file dump
-utility, and a program which will load and execute an RDF executable
-under Linux.
-
- `rdf' supports only the standard section names `.text', `.data' and
-`.bss'.
-
-* Menu:
-
-* Section 7.13.1:: Requiring a Library: The `LIBRARY' Directive
-* Section 7.13.2:: Specifying a Module Name: The `MODULE' Directive
-* Section 7.13.3:: `rdf' Extensions to the `GLOBAL' Directive
-* Section 7.13.4:: `rdf' Extensions to the `EXTERN' Directive
-
-
-File: nasm.info, Node: Section 7.13.1, Next: Section 7.13.2, Prev: Section 7.13, Up: Section 7.13
-
-7.13.1. Requiring a Library: The `LIBRARY' Directive
-----------------------------------------------------
-
-`RDOFF' contains a mechanism for an object file to demand a given
-library to be linked to the module, either at load time or run time.
-This is done by the `LIBRARY' directive, which takes one argument which
-is the name of the module:
-
- library mylib.rdl
-
-
-File: nasm.info, Node: Section 7.13.2, Next: Section 7.13.3, Prev: Section 7.13.1, Up: Section 7.13
-
-7.13.2. Specifying a Module Name: The `MODULE' Directive
---------------------------------------------------------
-
-Special `RDOFF' header record is used to store the name of the module.
-It can be used, for example, by run-time loader to perform dynamic
-linking. `MODULE' directive takes one argument which is the name of
-current module:
-
- module mymodname
-
- Note that when you statically link modules and tell linker to strip
-the symbols from output file, all module names will be stripped too. To
-avoid it, you should start module names with `$', like:
-
- module $kernel.core
-
-
-File: nasm.info, Node: Section 7.13.3, Next: Section 7.13.4, Prev: Section 7.13.2, Up: Section 7.13
-
-7.13.3. `rdf' Extensions to the `GLOBAL' Directive
---------------------------------------------------
-
-`RDOFF' global symbols can contain additional information needed by the
-static linker. You can mark a global symbol as exported, thus telling
-the linker do not strip it from target executable or library file. Like
-in `ELF', you can also specify whether an exported symbol is a procedure
-(function) or data object.
-
- Suffixing the name with a colon and the word `export' you make the
-symbol exported:
-
- global sys_open:export
-
- To specify that exported symbol is a procedure (function), you add
-the word `proc' or `function' after declaration:
-
- global sys_open:export proc
-
- Similarly, to specify exported data object, add the word `data' or
-`object' to the directive:
-
- global kernel_ticks:export data
-
-
-File: nasm.info, Node: Section 7.13.4, Next: Section 7.14, Prev: Section 7.13.3, Up: Section 7.13
-
-7.13.4. `rdf' Extensions to the `EXTERN' Directive
---------------------------------------------------
-
-By default the `EXTERN' directive in `RDOFF' declares a "pure external"
-symbol (i.e. the static linker will complain if such a symbol is not
-resolved). To declare an "imported" symbol, which must be resolved
-later during a dynamic linking phase, `RDOFF' offers an additional
-`import' modifier. As in `GLOBAL', you can also specify whether an
-imported symbol is a procedure (function) or data object. For example:
-
- library $libc
- extern _open:import
- extern _printf:import proc
- extern _errno:import data
-
- Here the directive `LIBRARY' is also included, which gives the
-dynamic linker a hint as to where to find requested symbols.
-
-
-File: nasm.info, Node: Section 7.14, Next: Chapter 8, Prev: Section 7.13.4, Up: Chapter 7
-
-7.14. `dbg': Debugging Format
-=============================
-
-The `dbg' output format is not built into NASM in the default
-configuration. If you are building your own NASM executable from the
-sources, you can define `OF_DBG' in `output/outform.h' or on the
-compiler command line, and obtain the `dbg' output format.
-
- The `dbg' format does not output an object file as such; instead, it
-outputs a text file which contains a complete list of all the
-transactions between the main body of NASM and the output-format back
-end module. It is primarily intended to aid people who want to write
-their own output drivers, so that they can get a clearer idea of the
-various requests the main program makes of the output driver, and in
-what order they happen.
-
- For simple files, one can easily use the `dbg' format like this:
-
- nasm -f dbg filename.asm
-
- which will generate a diagnostic file called `filename.dbg'. However,
-this will not work well on files which were designed for a different
-object format, because each object format defines its own macros
-(usually user- level forms of directives), and those macros will not be
-defined in the `dbg' format. Therefore it can be useful to run NASM
-twice, in order to do the preprocessing with the native object format
-selected:
-
- nasm -e -f rdf -o rdfprog.i rdfprog.asm
- nasm -a -f dbg rdfprog.i
-
- This preprocesses `rdfprog.asm' into `rdfprog.i', keeping the `rdf'
-object format selected in order to make sure RDF special directives are
-converted into primitive form correctly. Then the preprocessed source
-is fed through the `dbg' format to generate the final diagnostic output.
-
- This workaround will still typically not work for programs intended
-for `obj' format, because the `obj' `SEGMENT' and `GROUP' directives
-have side effects of defining the segment and group names as symbols;
-`dbg' will not do this, so the program will not assemble. You will have
-to work around that by defining the symbols yourself (using `EXTERN',
-for example) if you really need to get a `dbg' trace of an
-`obj'-specific source file.
-
- `dbg' accepts any section name and any directives at all, and logs
-them all to its output file.
-
-
-File: nasm.info, Node: Chapter 8, Next: Section 8.1, Prev: Section 7.14, Up: Top
-
-Chapter 8: Writing 16-bit Code (DOS, Windows 3/3.1)
-***************************************************
-
-This chapter attempts to cover some of the common issues encountered
-when writing 16-bit code to run under `MS-DOS' or `Windows 3.x'. It
-covers how to link programs to produce `.EXE' or `.COM' files, how to
-write `.SYS' device drivers, and how to interface assembly language
-code with 16-bit C compilers and with Borland Pascal.
-
-* Menu:
-
-* Section 8.1:: Producing `.EXE' Files
-* Section 8.2:: Producing `.COM' Files
-* Section 8.3:: Producing `.SYS' Files
-* Section 8.4:: Interfacing to 16-bit C Programs
-* Section 8.5:: Interfacing to Borland Pascal Programs
-
-
-File: nasm.info, Node: Section 8.1, Next: Section 8.1.1, Prev: Chapter 8, Up: Chapter 8
-
-8.1. Producing `.EXE' Files
-===========================
-
-Any large program written under DOS needs to be built as a `.EXE' file:
-only `.EXE' files have the necessary internal structure required to
-span more than one 64K segment. Windows programs, also, have to be built
-as `.EXE' files, since Windows does not support the `.COM' format.
-
- In general, you generate `.EXE' files by using the `obj' output
-format to produce one or more `.OBJ' files, and then linking them
-together using a linker. However, NASM also supports the direct
-generation of simple DOS `.EXE' files using the `bin' output format (by
-using `DB' and `DW' to construct the `.EXE' file header), and a macro
-package is supplied to do this. Thanks to Yann Guidon for contributing
-the code for this.
-
- NASM may also support `.EXE' natively as another output format in
-future releases.
-
-* Menu:
-
-* Section 8.1.1:: Using the `obj' Format To Generate `.EXE' Files
-* Section 8.1.2:: Using the `bin' Format To Generate `.EXE' Files
-
-
-File: nasm.info, Node: Section 8.1.1, Next: Section 8.1.2, Prev: Section 8.1, Up: Section 8.1
-
-8.1.1. Using the `obj' Format To Generate `.EXE' Files
-------------------------------------------------------
-
-This section describes the usual method of generating `.EXE' files by
-linking `.OBJ' files together.
-
- Most 16-bit programming language packages come with a suitable
-linker; if you have none of these, there is a free linker called VAL,
-available in `LZH' archive format from `x2ftp.oulu.fi'. An LZH archiver
-can be found at `ftp.simtel.net'. There is another `free' linker
-(though this one doesn't come with sources) called FREELINK, available
-from `www.pcorner.com'. A third, `djlink', written by DJ Delorie, is
-available at `www.delorie.com'. A fourth linker, `ALINK', written by
-Anthony A.J. Williams, is available at `alink.sourceforge.net'.
-
- When linking several `.OBJ' files into a `.EXE' file, you should
-ensure that exactly one of them has a start point defined (using the
-`..start' special symbol defined by the `obj' format: see *note Section
-7.4.6::). If no module defines a start point, the linker will not know
-what value to give the entry-point field in the output file header; if
-more than one defines a start point, the linker will not know _which_
-value to use.
-
- An example of a NASM source file which can be assembled to a `.OBJ'
-file and linked on its own to a `.EXE' is given here. It demonstrates
-the basic principles of defining a stack, initialising the segment
-registers, and declaring a start point. This file is also provided in
-the `test' subdirectory of the NASM archives, under the name
-`objexe.asm'.
-
- segment code
-
- ..start:
- mov ax,data
- mov ds,ax
- mov ax,stack
- mov ss,ax
- mov sp,stacktop
-
- This initial piece of code sets up `DS' to point to the data segment,
-and initializes `SS' and `SP' to point to the top of the provided
-stack. Notice that interrupts are implicitly disabled for one
-instruction after a move into `SS', precisely for this situation, so
-that there's no chance of an interrupt occurring between the loads of
-`SS' and `SP' and not having a stack to execute on.
-
- Note also that the special symbol `..start' is defined at the
-beginning of this code, which means that will be the entry point into
-the resulting executable file.
-
- mov dx,hello
- mov ah,9
- int 0x21
-
- The above is the main program: load `DS:DX' with a pointer to the
-greeting message (`hello' is implicitly relative to the segment `data',
-which was loaded into `DS' in the setup code, so the full pointer is
-valid), and call the DOS print-string function.
-
- mov ax,0x4c00
- int 0x21
-
- This terminates the program using another DOS system call.
-
- segment data
-
- hello: db 'hello, world', 13, 10, '$'
-
- The data segment contains the string we want to display.
-
- segment stack stack
- resb 64
- stacktop:
-
- The above code declares a stack segment containing 64 bytes of
-uninitialized stack space, and points `stacktop' at the top of it. The
-directive `segment stack stack' defines a segment _called_ `stack', and
-also of _type_ `STACK'. The latter is not necessary to the correct
-running of the program, but linkers are likely to issue warnings or
-errors if your program has no segment of type `STACK'.
-
- The above file, when assembled into a `.OBJ' file, will link on its
-own to a valid `.EXE' file, which when run will print `hello, world'
-and then exit.
-
-
-File: nasm.info, Node: Section 8.1.2, Next: Section 8.2, Prev: Section 8.1.1, Up: Section 8.1
-
-8.1.2. Using the `bin' Format To Generate `.EXE' Files
-------------------------------------------------------
-
-The `.EXE' file format is simple enough that it's possible to build a
-`.EXE' file by writing a pure-binary program and sticking a 32-byte
-header on the front. This header is simple enough that it can be
-generated using `DB' and `DW' commands by NASM itself, so that you can
-use the `bin' output format to directly generate `.EXE' files.
-
- Included in the NASM archives, in the `misc' subdirectory, is a file
-`exebin.mac' of macros. It defines three macros: `EXE_begin',
-`EXE_stack' and `EXE_end'.
-
- To produce a `.EXE' file using this method, you should start by using
-`%include' to load the `exebin.mac' macro package into your source
-file. You should then issue the `EXE_begin' macro call (which takes no
-arguments) to generate the file header data. Then write code as normal
-for the `bin' format - you can use all three standard sections `.text',
-`.data' and `.bss'. At the end of the file you should call the
-`EXE_end' macro (again, no arguments), which defines some symbols to
-mark section sizes, and these symbols are referred to in the header
-code generated by `EXE_begin'.
-
- In this model, the code you end up writing starts at `0x100', just
-like a `.COM' file - in fact, if you strip off the 32-byte header from
-the resulting `.EXE' file, you will have a valid `.COM' program. All
-the segment bases are the same, so you are limited to a 64K program,
-again just like a `.COM' file. Note that an `ORG' directive is issued
-by the `EXE_begin' macro, so you should not explicitly issue one of
-your own.
-
- You can't directly refer to your segment base value, unfortunately,
-since this would require a relocation in the header, and things would
-get a lot more complicated. So you should get your segment base by
-copying it out of `CS' instead.
-
- On entry to your `.EXE' file, `SS:SP' are already set up to point to
-the top of a 2Kb stack. You can adjust the default stack size of 2Kb by
-calling the `EXE_stack' macro. For example, to change the stack size of
-your program to 64 bytes, you would call `EXE_stack 64'.
-
- A sample program which generates a `.EXE' file in this way is given
-in the `test' subdirectory of the NASM archive, as `binexe.asm'.
-
-
-File: nasm.info, Node: Section 8.2, Next: Section 8.2.1, Prev: Section 8.1.2, Up: Chapter 8
-
-8.2. Producing `.COM' Files
-===========================
-
-While large DOS programs must be written as `.EXE' files, small ones
-are often better written as `.COM' files. `.COM' files are pure binary,
-and therefore most easily produced using the `bin' output format.
-
-* Menu:
-
-* Section 8.2.1:: Using the `bin' Format To Generate `.COM' Files
-* Section 8.2.2:: Using the `obj' Format To Generate `.COM' Files
-
-
-File: nasm.info, Node: Section 8.2.1, Next: Section 8.2.2, Prev: Section 8.2, Up: Section 8.2
-
-8.2.1. Using the `bin' Format To Generate `.COM' Files
-------------------------------------------------------
-
-`.COM' files expect to be loaded at offset `100h' into their segment
-(though the segment may change). Execution then begins at `100h', i.e.
-right at the start of the program. So to write a `.COM' program, you
-would create a source file looking like
-
- org 100h
-
- section .text
-
- start:
- ; put your code here
-
- section .data
-
- ; put data items here
-
- section .bss
-
- ; put uninitialized data here
-
- The `bin' format puts the `.text' section first in the file, so you
-can declare data or BSS items before beginning to write code if you
-want to and the code will still end up at the front of the file where it
-belongs.
-
- The BSS (uninitialized data) section does not take up space in the
-`.COM' file itself: instead, addresses of BSS items are resolved to
-point at space beyond the end of the file, on the grounds that this
-will be free memory when the program is run. Therefore you should not
-rely on your BSS being initialized to all zeros when you run.
-
- To assemble the above program, you should use a command line like
-
- nasm myprog.asm -fbin -o myprog.com
-
- The `bin' format would produce a file called `myprog' if no explicit
-output file name were specified, so you have to override it and give
-the desired file name.
-
-
-File: nasm.info, Node: Section 8.2.2, Next: Section 8.3, Prev: Section 8.2.1, Up: Section 8.2
-
-8.2.2. Using the `obj' Format To Generate `.COM' Files
-------------------------------------------------------
-
-If you are writing a `.COM' program as more than one module, you may
-wish to assemble several `.OBJ' files and link them together into a
-`.COM' program. You can do this, provided you have a linker capable of
-outputting `.COM' files directly (TLINK does this), or alternatively a
-converter program such as `EXE2BIN' to transform the `.EXE' file output
-from the linker into a `.COM' file.
-
- If you do this, you need to take care of several things:
-
- * The first object file containing code should start its code
- segment with a line like `RESB 100h'. This is to ensure that the
- code begins at offset `100h' relative to the beginning of the code
- segment, so that the linker or converter program does not have to
- adjust address references within the file when generating the
- `.COM' file. Other assemblers use an `ORG' directive for this
- purpose, but `ORG' in NASM is a format-specific directive to the
- `bin' output format, and does not mean the same thing as it does
- in MASM-compatible assemblers.
-
- * You don't need to define a stack segment.
-
- * All your segments should be in the same group, so that every time
- your code or data references a symbol offset, all offsets are
- relative to the same segment base. This is because, when a `.COM'
- file is loaded, all the segment registers contain the same value.
-
-
-File: nasm.info, Node: Section 8.3, Next: Section 8.4, Prev: Section 8.2.2, Up: Chapter 8
-
-8.3. Producing `.SYS' Files
-===========================
-
-MS-DOS device drivers - `.SYS' files - are pure binary files, similar
-to `.COM' files, except that they start at origin zero rather than
-`100h'. Therefore, if you are writing a device driver using the `bin'
-format, you do not need the `ORG' directive, since the default origin
-for `bin' is zero. Similarly, if you are using `obj', you do not need
-the `RESB 100h' at the start of your code segment.
-
- `.SYS' files start with a header structure, containing pointers to
-the various routines inside the driver which do the work. This
-structure should be defined at the start of the code segment, even
-though it is not actually code.
-
- For more information on the format of `.SYS' files, and the data
-which has to go in the header structure, a list of books is given in the
-Frequently Asked Questions list for the newsgroup
-`comp.os.msdos.programmer'.
-
-
-File: nasm.info, Node: Section 8.4, Next: Section 8.4.1, Prev: Section 8.3, Up: Chapter 8
-
-8.4. Interfacing to 16-bit C Programs
-=====================================
-
-This section covers the basics of writing assembly routines that call,
-or are called from, C programs. To do this, you would typically write an
-assembly module as a `.OBJ' file, and link it with your C modules to
-produce a mixed-language program.
-
-* Menu:
-
-* Section 8.4.1:: External Symbol Names
-* Section 8.4.2:: Memory Models
-* Section 8.4.3:: Function Definitions and Function Calls
-* Section 8.4.4:: Accessing Data Items
-* Section 8.4.5:: `c16.mac': Helper Macros for the 16-bit C Interface
-
-
-File: nasm.info, Node: Section 8.4.1, Next: Section 8.4.2, Prev: Section 8.4, Up: Section 8.4
-
-8.4.1. External Symbol Names
-----------------------------
-
-C compilers have the convention that the names of all global symbols
-(functions or data) they define are formed by prefixing an underscore to
-the name as it appears in the C program. So, for example, the function
-a C programmer thinks of as `printf' appears to an assembly language
-programmer as `_printf'. This means that in your assembly programs, you
-can define symbols without a leading underscore, and not have to worry
-about name clashes with C symbols.
-
- If you find the underscores inconvenient, you can define macros to
-replace the `GLOBAL' and `EXTERN' directives as follows:
-
- %macro cglobal 1
-
- global _%1
- %define %1 _%1
-
- %endmacro
-
- %macro cextern 1
-
- extern _%1
- %define %1 _%1
-
- %endmacro
-
- (These forms of the macros only take one argument at a time; a `%rep'
-construct could solve this.)
-
- If you then declare an external like this:
-
- cextern printf
-
- then the macro will expand it as
-
- extern _printf
- %define printf _printf
-
- Thereafter, you can reference `printf' as if it was a symbol, and the
-preprocessor will put the leading underscore on where necessary.
-
- The `cglobal' macro works similarly. You must use `cglobal' before
-defining the symbol in question, but you would have had to do that
-anyway if you used `GLOBAL'.
-
- Also see *note Section 2.1.27::.
-
-
-File: nasm.info, Node: Section 8.4.2, Next: Section 8.4.3, Prev: Section 8.4.1, Up: Section 8.4
-
-8.4.2. Memory Models
---------------------
-
-NASM contains no mechanism to support the various C memory models
-directly; you have to keep track yourself of which one you are writing
-for. This means you have to keep track of the following things:
-
- * In models using a single code segment (tiny, small and compact),
- functions are near. This means that function pointers, when stored
- in data segments or pushed on the stack as function arguments, are
- 16 bits long and contain only an offset field (the `CS' register
- never changes its value, and always gives the segment part of the
- full function address), and that functions are called using
- ordinary near `CALL' instructions and return using `RETN' (which,
- in NASM, is synonymous with `RET' anyway). This means both that
- you should write your own routines to return with `RETN', and that
- you should call external C routines with near `CALL' instructions.
-
- * In models using more than one code segment (medium, large and
- huge), functions are far. This means that function pointers are 32
- bits long (consisting of a 16-bit offset followed by a 16-bit
- segment), and that functions are called using `CALL FAR' (or `CALL
- seg:offset') and return using `RETF'. Again, you should therefore
- write your own routines to return with `RETF' and use `CALL FAR'
- to call external routines.
-
- * In models using a single data segment (tiny, small and medium),
- data pointers are 16 bits long, containing only an offset field
- (the `DS' register doesn't change its value, and always gives the
- segment part of the full data item address).
-
- * In models using more than one data segment (compact, large and
- huge), data pointers are 32 bits long, consisting of a 16-bit
- offset followed by a 16- bit segment. You should still be careful
- not to modify `DS' in your routines without restoring it
- afterwards, but `ES' is free for you to use to access the contents
- of 32-bit data pointers you are passed.
-
- * The huge memory model allows single data items to exceed 64K in
- size. In all other memory models, you can access the whole of a
- data item just by doing arithmetic on the offset field of the
- pointer you are given, whether a segment field is present or not;
- in huge model, you have to be more careful of your pointer
- arithmetic.
-
- * In most memory models, there is a _default_ data segment, whose
- segment address is kept in `DS' throughout the program. This data
- segment is typically the same segment as the stack, kept in `SS',
- so that functions' local variables (which are stored on the stack)
- and global data items can both be accessed easily without changing
- `DS'. Particularly large data items are typically stored in other
- segments. However, some memory models (though not the standard
- ones, usually) allow the assumption that `SS' and `DS' hold the
- same value to be removed. Be careful about functions' local
- variables in this latter case.
-
- In models with a single code segment, the segment is called `_TEXT',
-so your code segment must also go by this name in order to be linked
-into the same place as the main code segment. In models with a single
-data segment, or with a default data segment, it is called `_DATA'.
-
-
-File: nasm.info, Node: Section 8.4.3, Next: Section 8.4.4, Prev: Section 8.4.2, Up: Section 8.4
-
-8.4.3. Function Definitions and Function Calls
-----------------------------------------------
-
-The C calling convention in 16-bit programs is as follows. In the
-following description, the words _caller_ and _callee_ are used to
-denote the function doing the calling and the function which gets
-called.
-
- * The caller pushes the function's parameters on the stack, one after
- another, in reverse order (right to left, so that the first
- argument specified to the function is pushed last).
-
- * The caller then executes a `CALL' instruction to pass control to
- the callee. This `CALL' is either near or far depending on the
- memory model.
-
- * The callee receives control, and typically (although this is not
- actually necessary, in functions which do not need to access their
- parameters) starts by saving the value of `SP' in `BP' so as to be
- able to use `BP' as a base pointer to find its parameters on the
- stack. However, the caller was probably doing this too, so part
- of the calling convention states that `BP' must be preserved by
- any C function. Hence the callee, if it is going to set up `BP' as
- a _frame pointer_, must push the previous value first.
-
- * The callee may then access its parameters relative to `BP'. The
- word at `[BP]' holds the previous value of `BP' as it was pushed;
- the next word, at `[BP+2]', holds the offset part of the return
- address, pushed implicitly by `CALL'. In a small-model (near)
- function, the parameters start after that, at `[BP+4]'; in a
- large-model (far) function, the segment part of the return address
- lives at `[BP+4]', and the parameters begin at `[BP+6]'. The
- leftmost parameter of the function, since it was pushed last, is
- accessible at this offset from `BP'; the others follow, at
- successively greater offsets. Thus, in a function such as `printf'
- which takes a variable number of parameters, the pushing of the
- parameters in reverse order means that the function knows where to
- find its first parameter, which tells it the number and type of
- the remaining ones.
-
- * The callee may also wish to decrease `SP' further, so as to
- allocate space on the stack for local variables, which will then
- be accessible at negative offsets from `BP'.
-
- * The callee, if it wishes to return a value to the caller, should
- leave the value in `AL', `AX' or `DX:AX' depending on the size of
- the value. Floating-point results are sometimes (depending on the
- compiler) returned in `ST0'.
-
- * Once the callee has finished processing, it restores `SP' from
- `BP' if it had allocated local stack space, then pops the previous
- value of `BP', and returns via `RETN' or `RETF' depending on
- memory model.
-
- * When the caller regains control from the callee, the function
- parameters are still on the stack, so it typically adds an
- immediate constant to `SP' to remove them (instead of executing a
- number of slow `POP' instructions). Thus, if a function is
- accidentally called with the wrong number of parameters due to a
- prototype mismatch, the stack will still be returned to a sensible
- state since the caller, which _knows_ how many parameters it
- pushed, does the removing.
-
- It is instructive to compare this calling convention with that for
-Pascal programs (described in *note Section 8.5.1::). Pascal has a
-simpler convention, since no functions have variable numbers of
-parameters. Therefore the callee knows how many parameters it should
-have been passed, and is able to deallocate them from the stack itself
-by passing an immediate argument to the `RET' or `RETF' instruction, so
-the caller does not have to do it. Also, the parameters are pushed in
-left-to- right order, not right-to-left, which means that a compiler
-can give better guarantees about sequence points without performance
-suffering.
-
- Thus, you would define a function in C style in the following way.
-The following example is for small model:
-
- global _myfunc
-
- _myfunc:
- push bp
- mov bp,sp
- sub sp,0x40 ; 64 bytes of local stack space
- mov bx,[bp+4] ; first parameter to function
-
- ; some more code
-
- mov sp,bp ; undo "sub sp,0x40" above
- pop bp
- ret
-
- For a large-model function, you would replace `RET' by `RETF', and
-look for the first parameter at `[BP+6]' instead of `[BP+4]'. Of
-course, if one of the parameters is a pointer, then the offsets of
-_subsequent_ parameters will change depending on the memory model as
-well: far pointers take up four bytes on the stack when passed as a
-parameter, whereas near pointers take up two.
-
- At the other end of the process, to call a C function from your
-assembly code, you would do something like this:
-
- extern _printf
-
- ; and then, further down...
-
- push word [myint] ; one of my integer variables
- push word mystring ; pointer into my data segment
- call _printf
- add sp,byte 4 ; `byte' saves space
-
- ; then those data items...
-
- segment _DATA
-
- myint dw 1234
- mystring db 'This number -> %d <- should be 1234',10,0
-
- This piece of code is the small-model assembly equivalent of the C
-code
-
- int myint = 1234;
- printf("This number -> %d <- should be 1234\n", myint);
-
- In large model, the function-call code might look more like this. In
-this example, it is assumed that `DS' already holds the segment base of
-the segment `_DATA'. If not, you would have to initialize it first.
-
- push word [myint]
- push word seg mystring ; Now push the segment, and...
- push word mystring ; ... offset of "mystring"
- call far _printf
- add sp,byte 6
-
- The integer value still takes up one word on the stack, since large
-model does not affect the size of the `int' data type. The first
-argument (pushed last) to `printf', however, is a data pointer, and
-therefore has to contain a segment and offset part. The segment should
-be stored second in memory, and therefore must be pushed first. (Of
-course, `PUSH DS' would have been a shorter instruction than `PUSH WORD
-SEG mystring', if `DS' was set up as the above example assumed.) Then
-the actual call becomes a far call, since functions expect far calls in
-large model; and `SP' has to be increased by 6 rather than 4 afterwards
-to make up for the extra word of parameters.
-
-
-File: nasm.info, Node: Section 8.4.4, Next: Section 8.4.5, Prev: Section 8.4.3, Up: Section 8.4
-
-8.4.4. Accessing Data Items
----------------------------
-
-To get at the contents of C variables, or to declare variables which C
-can access, you need only declare the names as `GLOBAL' or `EXTERN'.
-(Again, the names require leading underscores, as stated in *note
-Section 8.4.1::.) Thus, a C variable declared as `int i' can be
-accessed from assembler as
-
- extern _i
-
- mov ax,[_i]
-
- And to declare your own integer variable which C programs can access
-as `extern int j', you do this (making sure you are assembling in the
-`_DATA' segment, if necessary):
-
- global _j
-
- _j dw 0
-
- To access a C array, you need to know the size of the components of
-the array. For example, `int' variables are two bytes long, so if a C
-program declares an array as `int a[10]', you can access `a[3]' by
-coding `mov ax,[_a+6]'. (The byte offset 6 is obtained by multiplying
-the desired array index, 3, by the size of the array element, 2.) The
-sizes of the C base types in 16-bit compilers are: 1 for `char', 2 for
-`short' and `int', 4 for `long' and `float', and 8 for `double'.
-
- To access a C data structure, you need to know the offset from the
-base of the structure to the field you are interested in. You can
-either do this by converting the C structure definition into a NASM
-structure definition (using `STRUC'), or by calculating the one offset
-and using just that.
-
- To do either of these, you should read your C compiler's manual to
-find out how it organizes data structures. NASM gives no special
-alignment to structure members in its own `STRUC' macro, so you have to
-specify alignment yourself if the C compiler generates it. Typically,
-you might find that a structure like
-
- struct {
- char c;
- int i;
- } foo;
-
- might be four bytes long rather than three, since the `int' field
-would be aligned to a two-byte boundary. However, this sort of feature
-tends to be a configurable option in the C compiler, either using
-command- line options or `#pragma' lines, so you have to find out how
-your own compiler does it.
-
-
-File: nasm.info, Node: Section 8.4.5, Next: Section 8.5, Prev: Section 8.4.4, Up: Section 8.4
-
-8.4.5. `c16.mac': Helper Macros for the 16-bit C Interface
-----------------------------------------------------------
-
-Included in the NASM archives, in the `misc' directory, is a file
-`c16.mac' of macros. It defines three macros: `proc', `arg' and
-`endproc'. These are intended to be used for C-style procedure
-definitions, and they automate a lot of the work involved in keeping
-track of the calling convention.
-
- (An alternative, TASM compatible form of `arg' is also now built into
-NASM's preprocessor. See *note Section 4.8:: for details.)
-
- An example of an assembly function using the macro set is given here:
-
- proc _nearproc
-
- %$i arg
- %$j arg
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- add ax,[bx]
-
- endproc
-
- This defines `_nearproc' to be a procedure taking two arguments, the
-first (`i') an integer and the second (`j') a pointer to an integer. It
-returns `i + *j'.
-
- Note that the `arg' macro has an `EQU' as the first line of its
-expansion, and since the label before the macro call gets prepended to
-the first line of the expanded macro, the `EQU' works, defining `%$i'
-to be an offset from `BP'. A context-local variable is used, local to
-the context pushed by the `proc' macro and popped by the `endproc'
-macro, so that the same argument name can be used in later procedures.
-Of course, you don't _have_ to do that.
-
- The macro set produces code for near functions (tiny, small and
-compact- model code) by default. You can have it generate far functions
-(medium, large and huge-model code) by means of coding `%define
-FARCODE'. This changes the kind of return instruction generated by
-`endproc', and also changes the starting point for the argument
-offsets. The macro set contains no intrinsic dependency on whether data
-pointers are far or not.
-
- `arg' can take an optional parameter, giving the size of the
-argument. If no size is given, 2 is assumed, since it is likely that
-many function parameters will be of type `int'.
-
- The large-model equivalent of the above function would look like
-this:
-
- %define FARCODE
-
- proc _farproc
-
- %$i arg
- %$j arg 4
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- mov es,[bp + %$j + 2]
- add ax,[bx]
-
- endproc
-
- This makes use of the argument to the `arg' macro to define a
-parameter of size 4, because `j' is now a far pointer. When we load
-from `j', we must load a segment and an offset.
-
-
-File: nasm.info, Node: Section 8.5, Next: Section 8.5.1, Prev: Section 8.4.5, Up: Chapter 8
-
-8.5. Interfacing to Borland Pascal Programs
-===========================================
-
-Interfacing to Borland Pascal programs is similar in concept to
-interfacing to 16-bit C programs. The differences are:
-
- * The leading underscore required for interfacing to C programs is
- not required for Pascal.
-
- * The memory model is always large: functions are far, data pointers
- are far, and no data item can be more than 64K long. (Actually,
- some functions are near, but only those functions that are local
- to a Pascal unit and never called from outside it. All assembly
- functions that Pascal calls, and all Pascal functions that
- assembly routines are able to call, are far.) However, all static
- data declared in a Pascal program goes into the default data
- segment, which is the one whose segment address will be in `DS'
- when control is passed to your assembly code. The only things that
- do not live in the default data segment are local variables (they
- live in the stack segment) and dynamically allocated variables.
- All data _pointers_, however, are far.
-
- * The function calling convention is different - described below.
-
- * Some data types, such as strings, are stored differently.
-
- * There are restrictions on the segment names you are allowed to use
- - Borland Pascal will ignore code or data declared in a segment it
- doesn't like the name of. The restrictions are described below.
-
-* Menu:
-
-* Section 8.5.1:: The Pascal Calling Convention
-* Section 8.5.2:: Borland Pascal Segment Name Restrictions
-* Section 8.5.3:: Using `c16.mac' With Pascal Programs
-
-
-File: nasm.info, Node: Section 8.5.1, Next: Section 8.5.2, Prev: Section 8.5, Up: Section 8.5
-
-8.5.1. The Pascal Calling Convention
-------------------------------------
-
-The 16-bit Pascal calling convention is as follows. In the following
-description, the words _caller_ and _callee_ are used to denote the
-function doing the calling and the function which gets called.
-
- * The caller pushes the function's parameters on the stack, one after
- another, in normal order (left to right, so that the first argument
- specified to the function is pushed first).
-
- * The caller then executes a far `CALL' instruction to pass control
- to the callee.
-
- * The callee receives control, and typically (although this is not
- actually necessary, in functions which do not need to access their
- parameters) starts by saving the value of `SP' in `BP' so as to be
- able to use `BP' as a base pointer to find its parameters on the
- stack. However, the caller was probably doing this too, so part
- of the calling convention states that `BP' must be preserved by
- any function. Hence the callee, if it is going to set up `BP' as a
- frame pointer, must push the previous value first.
-
- * The callee may then access its parameters relative to `BP'. The
- word at `[BP]' holds the previous value of `BP' as it was pushed.
- The next word, at `[BP+2]', holds the offset part of the return
- address, and the next one at `[BP+4]' the segment part. The
- parameters begin at `[BP+6]'. The rightmost parameter of the
- function, since it was pushed last, is accessible at this offset
- from `BP'; the others follow, at successively greater offsets.
-
- * The callee may also wish to decrease `SP' further, so as to
- allocate space on the stack for local variables, which will then
- be accessible at negative offsets from `BP'.
-
- * The callee, if it wishes to return a value to the caller, should
- leave the value in `AL', `AX' or `DX:AX' depending on the size of
- the value. Floating-point results are returned in `ST0'. Results
- of type `Real' (Borland's own custom floating-point data type, not
- handled directly by the FPU) are returned in `DX:BX:AX'. To return
- a result of type `String', the caller pushes a pointer to a
- temporary string before pushing the parameters, and the callee
- places the returned string value at that location. The pointer is
- not a parameter, and should not be removed from the stack by the
- `RETF' instruction.
-
- * Once the callee has finished processing, it restores `SP' from
- `BP' if it had allocated local stack space, then pops the previous
- value of `BP', and returns via `RETF'. It uses the form of `RETF'
- with an immediate parameter, giving the number of bytes taken up
- by the parameters on the stack. This causes the parameters to be
- removed from the stack as a side effect of the return instruction.
-
- * When the caller regains control from the callee, the function
- parameters have already been removed from the stack, so it needs
- to do nothing further.
-
- Thus, you would define a function in Pascal style, taking two
-`Integer'-type parameters, in the following way:
-
- global myfunc
-
- myfunc: push bp
- mov bp,sp
- sub sp,0x40 ; 64 bytes of local stack space
- mov bx,[bp+8] ; first parameter to function
- mov bx,[bp+6] ; second parameter to function
-
- ; some more code
-
- mov sp,bp ; undo "sub sp,0x40" above
- pop bp
- retf 4 ; total size of params is 4
-
- At the other end of the process, to call a Pascal function from your
-assembly code, you would do something like this:
-
- extern SomeFunc
-
- ; and then, further down...
-
- push word seg mystring ; Now push the segment, and...
- push word mystring ; ... offset of "mystring"
- push word [myint] ; one of my variables
- call far SomeFunc
-
- This is equivalent to the Pascal code
-
- procedure SomeFunc(String: PChar; Int: Integer);
- SomeFunc(@mystring, myint);
-
-
-File: nasm.info, Node: Section 8.5.2, Next: Section 8.5.3, Prev: Section 8.5.1, Up: Section 8.5
-
-8.5.2. Borland Pascal Segment Name Restrictions
------------------------------------------------
-
-Since Borland Pascal's internal unit file format is completely different
-from `OBJ', it only makes a very sketchy job of actually reading and
-understanding the various information contained in a real `OBJ' file
-when it links that in. Therefore an object file intended to be linked
-to a Pascal program must obey a number of restrictions:
-
- * Procedures and functions must be in a segment whose name is either
- `CODE', `CSEG', or something ending in `_TEXT'.
-
- * initialized data must be in a segment whose name is either `CONST'
- or something ending in `_DATA'.
-
- * Uninitialized data must be in a segment whose name is either
- `DATA', `DSEG', or something ending in `_BSS'.
-
- * Any other segments in the object file are completely ignored.
- `GROUP' directives and segment attributes are also ignored.
-
-
-File: nasm.info, Node: Section 8.5.3, Next: Chapter 9, Prev: Section 8.5.2, Up: Section 8.5
-
-8.5.3. Using `c16.mac' With Pascal Programs
--------------------------------------------
-
-The `c16.mac' macro package, described in *note Section 8.4.5::, can
-also be used to simplify writing functions to be called from Pascal
-programs, if you code `%define PASCAL'. This definition ensures that
-functions are far (it implies `FARCODE'), and also causes procedure
-return instructions to be generated with an operand.
-
- Defining `PASCAL' does not change the code which calculates the
-argument offsets; you must declare your function's arguments in reverse
-order. For example:
-
- %define PASCAL
-
- proc _pascalproc
-
- %$j arg 4
- %$i arg
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- mov es,[bp + %$j + 2]
- add ax,[bx]
-
- endproc
-
- This defines the same routine, conceptually, as the example in *note
-Section 8.4.5::: it defines a function taking two arguments, an integer
-and a pointer to an integer, which returns the sum of the integer and
-the contents of the pointer. The only difference between this code and
-the large-model C version is that `PASCAL' is defined instead of
-`FARCODE', and that the arguments are declared in reverse order.
-
-
-File: nasm.info, Node: Chapter 9, Next: Section 9.1, Prev: Section 8.5.3, Up: Top
-
-Chapter 9: Writing 32-bit Code (Unix, Win32, DJGPP)
-***************************************************
-
-This chapter attempts to cover some of the common issues involved when
-writing 32-bit code, to run under Win32 or Unix, or to be linked with C
-code generated by a Unix-style C compiler such as DJGPP. It covers how
-to write assembly code to interface with 32-bit C routines, and how to
-write position-independent code for shared libraries.
-
- Almost all 32-bit code, and in particular all code running under
-`Win32', `DJGPP' or any of the PC Unix variants, runs in _flat_ memory
-model. This means that the segment registers and paging have already
-been set up to give you the same 32-bit 4Gb address space no matter
-what segment you work relative to, and that you should ignore all
-segment registers completely. When writing flat-model application code,
-you never need to use a segment override or modify any segment
-register, and the code-section addresses you pass to `CALL' and `JMP'
-live in the same address space as the data-section addresses you access
-your variables by and the stack-section addresses you access local
-variables and procedure parameters by. Every address is 32 bits long
-and contains only an offset part.
-
-* Menu:
-
-* Section 9.1:: Interfacing to 32-bit C Programs
-* Section 9.2:: Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries
-
-
-File: nasm.info, Node: Section 9.1, Next: Section 9.1.1, Prev: Chapter 9, Up: Chapter 9
-
-9.1. Interfacing to 32-bit C Programs
-=====================================
-
-A lot of the discussion in *note Section 8.4::, about interfacing to
-16-bit C programs, still applies when working in 32 bits. The absence
-of memory models or segmentation worries simplifies things a lot.
-
-* Menu:
-
-* Section 9.1.1:: External Symbol Names
-* Section 9.1.2:: Function Definitions and Function Calls
-* Section 9.1.3:: Accessing Data Items
-* Section 9.1.4:: `c32.mac': Helper Macros for the 32-bit C Interface
-
-
-File: nasm.info, Node: Section 9.1.1, Next: Section 9.1.2, Prev: Section 9.1, Up: Section 9.1
-
-9.1.1. External Symbol Names
-----------------------------
-
-Most 32-bit C compilers share the convention used by 16-bit compilers,
-that the names of all global symbols (functions or data) they define
-are formed by prefixing an underscore to the name as it appears in the
-C program. However, not all of them do: the `ELF' specification states
-that C symbols do _not_ have a leading underscore on their
-assembly-language names.
-
- The older Linux `a.out' C compiler, all `Win32' compilers, `DJGPP',
-and `NetBSD' and `FreeBSD', all use the leading underscore; for these
-compilers, the macros `cextern' and `cglobal', as given in *note
-Section 8.4.1::, will still work. For `ELF', though, the leading
-underscore should not be used.
-
- See also *note Section 2.1.27::.
-
-
-File: nasm.info, Node: Section 9.1.2, Next: Section 9.1.3, Prev: Section 9.1.1, Up: Section 9.1
-
-9.1.2. Function Definitions and Function Calls
-----------------------------------------------
-
-The C calling convention in 32-bit programs is as follows. In the
-following description, the words _caller_ and _callee_ are used to
-denote the function doing the calling and the function which gets
-called.
-
- * The caller pushes the function's parameters on the stack, one after
- another, in reverse order (right to left, so that the first
- argument specified to the function is pushed last).
-
- * The caller then executes a near `CALL' instruction to pass control
- to the callee.
-
- * The callee receives control, and typically (although this is not
- actually necessary, in functions which do not need to access their
- parameters) starts by saving the value of `ESP' in `EBP' so as to
- be able to use `EBP' as a base pointer to find its parameters on
- the stack. However, the caller was probably doing this too, so
- part of the calling convention states that `EBP' must be preserved
- by any C function. Hence the callee, if it is going to set up
- `EBP' as a frame pointer, must push the previous value first.
-
- * The callee may then access its parameters relative to `EBP'. The
- doubleword at `[EBP]' holds the previous value of `EBP' as it was
- pushed; the next doubleword, at `[EBP+4]', holds the return
- address, pushed implicitly by `CALL'. The parameters start after
- that, at `[EBP+8]'. The leftmost parameter of the function, since
- it was pushed last, is accessible at this offset from `EBP'; the
- others follow, at successively greater offsets. Thus, in a
- function such as `printf' which takes a variable number of
- parameters, the pushing of the parameters in reverse order means
- that the function knows where to find its first parameter, which
- tells it the number and type of the remaining ones.
-
- * The callee may also wish to decrease `ESP' further, so as to
- allocate space on the stack for local variables, which will then
- be accessible at negative offsets from `EBP'.
-
- * The callee, if it wishes to return a value to the caller, should
- leave the value in `AL', `AX' or `EAX' depending on the size of the
- value. Floating-point results are typically returned in `ST0'.
-
- * Once the callee has finished processing, it restores `ESP' from
- `EBP' if it had allocated local stack space, then pops the previous
- value of `EBP', and returns via `RET' (equivalently, `RETN').
-
- * When the caller regains control from the callee, the function
- parameters are still on the stack, so it typically adds an
- immediate constant to `ESP' to remove them (instead of executing a
- number of slow `POP' instructions). Thus, if a function is
- accidentally called with the wrong number of parameters due to a
- prototype mismatch, the stack will still be returned to a sensible
- state since the caller, which _knows_ how many parameters it
- pushed, does the removing.
-
- There is an alternative calling convention used by Win32 programs for
-Windows API calls, and also for functions called _by_ the Windows API
-such as window procedures: they follow what Microsoft calls the
-`__stdcall' convention. This is slightly closer to the Pascal
-convention, in that the callee clears the stack by passing a parameter
-to the `RET' instruction. However, the parameters are still pushed in
-right-to-left order.
-
- Thus, you would define a function in C style in the following way:
-
- global _myfunc
-
- _myfunc:
- push ebp
- mov ebp,esp
- sub esp,0x40 ; 64 bytes of local stack space
- mov ebx,[ebp+8] ; first parameter to function
-
- ; some more code
-
- leave ; mov esp,ebp / pop ebp
- ret
-
- At the other end of the process, to call a C function from your
-assembly code, you would do something like this:
-
- extern _printf
-
- ; and then, further down...
-
- push dword [myint] ; one of my integer variables
- push dword mystring ; pointer into my data segment
- call _printf
- add esp,byte 8 ; `byte' saves space
-
- ; then those data items...
-
- segment _DATA
-
- myint dd 1234
- mystring db 'This number -> %d <- should be 1234',10,0
-
- This piece of code is the assembly equivalent of the C code
-
- int myint = 1234;
- printf("This number -> %d <- should be 1234\n", myint);
-
diff --git a/doc/info/nasm.info-2 b/doc/info/nasm.info-2
deleted file mode 100644
index dd66a29..0000000
--- a/doc/info/nasm.info-2
+++ /dev/null
@@ -1,6521 +0,0 @@
-This is nasm.info, produced by makeinfo version 4.13 from nasmdoc.texi.
-
-INFO-DIR-SECTION Programming
-START-INFO-DIR-ENTRY
-* NASM: (nasm). The Netwide Assembler for x86.
-END-INFO-DIR-ENTRY
-
- This file documents NASM, the Netwide Assembler: an assembler
-targetting the Intel x86 series of processors, with portable source.
-
- Copyright 1996-2009 The NASM Development Team
-
- This document is redistributable under the license given in the file
-"COPYING" distributed in the NASM archive.
-
-
-File: nasm.info, Node: Section 9.1.3, Next: Section 9.1.4, Prev: Section 9.1.2, Up: Section 9.1
-
-9.1.3. Accessing Data Items
----------------------------
-
-To get at the contents of C variables, or to declare variables which C
-can access, you need only declare the names as `GLOBAL' or `EXTERN'.
-(Again, the names require leading underscores, as stated in *note
-Section 9.1.1::.) Thus, a C variable declared as `int i' can be
-accessed from assembler as
-
- extern _i
- mov eax,[_i]
-
- And to declare your own integer variable which C programs can access
-as `extern int j', you do this (making sure you are assembling in the
-`_DATA' segment, if necessary):
-
- global _j
- _j dd 0
-
- To access a C array, you need to know the size of the components of
-the array. For example, `int' variables are four bytes long, so if a C
-program declares an array as `int a[10]', you can access `a[3]' by
-coding `mov ax,[_a+12]'. (The byte offset 12 is obtained by multiplying
-the desired array index, 3, by the size of the array element, 4.) The
-sizes of the C base types in 32-bit compilers are: 1 for `char', 2 for
-`short', 4 for `int', `long' and `float', and 8 for `double'. Pointers,
-being 32-bit addresses, are also 4 bytes long.
-
- To access a C data structure, you need to know the offset from the
-base of the structure to the field you are interested in. You can
-either do this by converting the C structure definition into a NASM
-structure definition (using `STRUC'), or by calculating the one offset
-and using just that.
-
- To do either of these, you should read your C compiler's manual to
-find out how it organizes data structures. NASM gives no special
-alignment to structure members in its own `STRUC' macro, so you have to
-specify alignment yourself if the C compiler generates it. Typically,
-you might find that a structure like
-
- struct {
- char c;
- int i;
- } foo;
-
- might be eight bytes long rather than five, since the `int' field
-would be aligned to a four-byte boundary. However, this sort of feature
-is sometimes a configurable option in the C compiler, either using
-command- line options or `#pragma' lines, so you have to find out how
-your own compiler does it.
-
-
-File: nasm.info, Node: Section 9.1.4, Next: Section 9.2, Prev: Section 9.1.3, Up: Section 9.1
-
-9.1.4. `c32.mac': Helper Macros for the 32-bit C Interface
-----------------------------------------------------------
-
-Included in the NASM archives, in the `misc' directory, is a file
-`c32.mac' of macros. It defines three macros: `proc', `arg' and
-`endproc'. These are intended to be used for C-style procedure
-definitions, and they automate a lot of the work involved in keeping
-track of the calling convention.
-
- An example of an assembly function using the macro set is given here:
-
- proc _proc32
-
- %$i arg
- %$j arg
- mov eax,[ebp + %$i]
- mov ebx,[ebp + %$j]
- add eax,[ebx]
-
- endproc
-
- This defines `_proc32' to be a procedure taking two arguments, the
-first (`i') an integer and the second (`j') a pointer to an integer. It
-returns `i + *j'.
-
- Note that the `arg' macro has an `EQU' as the first line of its
-expansion, and since the label before the macro call gets prepended to
-the first line of the expanded macro, the `EQU' works, defining `%$i'
-to be an offset from `BP'. A context-local variable is used, local to
-the context pushed by the `proc' macro and popped by the `endproc'
-macro, so that the same argument name can be used in later procedures.
-Of course, you don't _have_ to do that.
-
- `arg' can take an optional parameter, giving the size of the
-argument. If no size is given, 4 is assumed, since it is likely that
-many function parameters will be of type `int' or pointers.
-
-
-File: nasm.info, Node: Section 9.2, Next: Section 9.2.1, Prev: Section 9.1.4, Up: Chapter 9
-
-9.2. Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries
-==================================================================
-
-`ELF' replaced the older `a.out' object file format under Linux because
-it contains support for position-independent code (PIC), which makes
-writing shared libraries much easier. NASM supports the `ELF'
-position-independent code features, so you can write Linux `ELF' shared
-libraries in NASM.
-
- NetBSD, and its close cousins FreeBSD and OpenBSD, take a different
-approach by hacking PIC support into the `a.out' format. NASM supports
-this as the `aoutb' output format, so you can write BSD shared
-libraries in NASM too.
-
- The operating system loads a PIC shared library by memory-mapping the
-library file at an arbitrarily chosen point in the address space of the
-running process. The contents of the library's code section must
-therefore not depend on where it is loaded in memory.
-
- Therefore, you cannot get at your variables by writing code like
-this:
-
- mov eax,[myvar] ; WRONG
-
- Instead, the linker provides an area of memory called the _global
-offset table_, or GOT; the GOT is situated at a constant distance from
-your library's code, so if you can find out where your library is
-loaded (which is typically done using a `CALL' and `POP' combination),
-you can obtain the address of the GOT, and you can then load the
-addresses of your variables out of linker-generated entries in the GOT.
-
- The _data_ section of a PIC shared library does not have these
-restrictions: since the data section is writable, it has to be copied
-into memory anyway rather than just paged in from the library file, so
-as long as it's being copied it can be relocated too. So you can put
-ordinary types of relocation in the data section without too much worry
-(but see *note Section 9.2.4:: for a caveat).
-
-* Menu:
-
-* Section 9.2.1:: Obtaining the Address of the GOT
-* Section 9.2.2:: Finding Your Local Data Items
-* Section 9.2.3:: Finding External and Common Data Items
-* Section 9.2.4:: Exporting Symbols to the Library User
-* Section 9.2.5:: Calling Procedures Outside the Library
-* Section 9.2.6:: Generating the Library File
-
-
-File: nasm.info, Node: Section 9.2.1, Next: Section 9.2.2, Prev: Section 9.2, Up: Section 9.2
-
-9.2.1. Obtaining the Address of the GOT
----------------------------------------
-
-Each code module in your shared library should define the GOT as an
-external symbol:
-
- extern _GLOBAL_OFFSET_TABLE_ ; in ELF
- extern __GLOBAL_OFFSET_TABLE_ ; in BSD a.out
-
- At the beginning of any function in your shared library which plans
-to access your data or BSS sections, you must first calculate the
-address of the GOT. This is typically done by writing the function in
-this form:
-
- func: push ebp
- mov ebp,esp
- push ebx
- call .get_GOT
- .get_GOT:
- pop ebx
- add ebx,_GLOBAL_OFFSET_TABLE_+$$-.get_GOT wrt ..gotpc
-
- ; the function body comes here
-
- mov ebx,[ebp-4]
- mov esp,ebp
- pop ebp
- ret
-
- (For BSD, again, the symbol `_GLOBAL_OFFSET_TABLE' requires a second
-leading underscore.)
-
- The first two lines of this function are simply the standard C
-prologue to set up a stack frame, and the last three lines are standard
-C function epilogue. The third line, and the fourth to last line, save
-and restore the `EBX' register, because PIC shared libraries use this
-register to store the address of the GOT.
-
- The interesting bit is the `CALL' instruction and the following two
-lines. The `CALL' and `POP' combination obtains the address of the
-label `.get_GOT', without having to know in advance where the program
-was loaded (since the `CALL' instruction is encoded relative to the
-current position). The `ADD' instruction makes use of one of the
-special PIC relocation types: GOTPC relocation. With the `WRT ..gotpc'
-qualifier specified, the symbol referenced (here
-`_GLOBAL_OFFSET_TABLE_', the special symbol assigned to the GOT) is
-given as an offset from the beginning of the section. (Actually, `ELF'
-encodes it as the offset from the operand field of the `ADD'
-instruction, but NASM simplifies this deliberately, so you do things the
-same way for both `ELF' and `BSD'.) So the instruction then _adds_ the
-beginning of the section, to get the real address of the GOT, and
-subtracts the value of `.get_GOT' which it knows is in `EBX'.
-Therefore, by the time that instruction has finished, `EBX' contains
-the address of the GOT.
-
- If you didn't follow that, don't worry: it's never necessary to
-obtain the address of the GOT by any other means, so you can put those
-three instructions into a macro and safely ignore them:
-
- %macro get_GOT 0
-
- call %%getgot
- %%getgot:
- pop ebx
- add ebx,_GLOBAL_OFFSET_TABLE_+$$-%%getgot wrt ..gotpc
-
- %endmacro
-
-
-File: nasm.info, Node: Section 9.2.2, Next: Section 9.2.3, Prev: Section 9.2.1, Up: Section 9.2
-
-9.2.2. Finding Your Local Data Items
-------------------------------------
-
-Having got the GOT, you can then use it to obtain the addresses of your
-data items. Most variables will reside in the sections you have
-declared; they can be accessed using the `..gotoff' special `WRT' type.
-The way this works is like this:
-
- lea eax,[ebx+myvar wrt ..gotoff]
-
- The expression `myvar wrt ..gotoff' is calculated, when the shared
-library is linked, to be the offset to the local variable `myvar' from
-the beginning of the GOT. Therefore, adding it to `EBX' as above will
-place the real address of `myvar' in `EAX'.
-
- If you declare variables as `GLOBAL' without specifying a size for
-them, they are shared between code modules in the library, but do not
-get exported from the library to the program that loaded it. They will
-still be in your ordinary data and BSS sections, so you can access them
-in the same way as local variables, using the above `..gotoff'
-mechanism.
-
- Note that due to a peculiarity of the way BSD `a.out' format handles
-this relocation type, there must be at least one non-local symbol in the
-same section as the address you're trying to access.
-
-
-File: nasm.info, Node: Section 9.2.3, Next: Section 9.2.4, Prev: Section 9.2.2, Up: Section 9.2
-
-9.2.3. Finding External and Common Data Items
----------------------------------------------
-
-If your library needs to get at an external variable (external to the
-_library_, not just to one of the modules within it), you must use the
-`..got' type to get at it. The `..got' type, instead of giving you the
-offset from the GOT base to the variable, gives you the offset from the
-GOT base to a GOT _entry_ containing the address of the variable. The
-linker will set up this GOT entry when it builds the library, and the
-dynamic linker will place the correct address in it at load time. So to
-obtain the address of an external variable `extvar' in `EAX', you would
-code
-
- mov eax,[ebx+extvar wrt ..got]
-
- This loads the address of `extvar' out of an entry in the GOT. The
-linker, when it builds the shared library, collects together every
-relocation of type `..got', and builds the GOT so as to ensure it has
-every necessary entry present.
-
- Common variables must also be accessed in this way.
-
-
-File: nasm.info, Node: Section 9.2.4, Next: Section 9.2.5, Prev: Section 9.2.3, Up: Section 9.2
-
-9.2.4. Exporting Symbols to the Library User
---------------------------------------------
-
-If you want to export symbols to the user of the library, you have to
-declare whether they are functions or data, and if they are data, you
-have to give the size of the data item. This is because the dynamic
-linker has to build procedure linkage table entries for any exported
-functions, and also moves exported data items away from the library's
-data section in which they were declared.
-
- So to export a function to users of the library, you must use
-
- global func:function ; declare it as a function
-
- func: push ebp
-
- ; etc.
-
- And to export a data item such as an array, you would have to code
-
- global array:data array.end-array ; give the size too
-
- array: resd 128
- .end:
-
- Be careful: If you export a variable to the library user, by
-declaring it as `GLOBAL' and supplying a size, the variable will end up
-living in the data section of the main program, rather than in your
-library's data section, where you declared it. So you will have to
-access your own global variable with the `..got' mechanism rather than
-`..gotoff', as if it were external (which, effectively, it has become).
-
- Equally, if you need to store the address of an exported global in
-one of your data sections, you can't do it by means of the standard
-sort of code:
-
- dataptr: dd global_data_item ; WRONG
-
- NASM will interpret this code as an ordinary relocation, in which
-`global_data_item' is merely an offset from the beginning of the
-`.data' section (or whatever); so this reference will end up pointing
-at your data section instead of at the exported global which resides
-elsewhere.
-
- Instead of the above code, then, you must write
-
- dataptr: dd global_data_item wrt ..sym
-
- which makes use of the special `WRT' type `..sym' to instruct NASM
-to search the symbol table for a particular symbol at that address,
-rather than just relocating by section base.
-
- Either method will work for functions: referring to one of your
-functions by means of
-
- funcptr: dd my_function
-
- will give the user the address of the code you wrote, whereas
-
- funcptr: dd my_function wrt .sym
-
- will give the address of the procedure linkage table for the
-function, which is where the calling program will _believe_ the
-function lives. Either address is a valid way to call the function.
-
-
-File: nasm.info, Node: Section 9.2.5, Next: Section 9.2.6, Prev: Section 9.2.4, Up: Section 9.2
-
-9.2.5. Calling Procedures Outside the Library
----------------------------------------------
-
-Calling procedures outside your shared library has to be done by means
-of a _procedure linkage table_, or PLT. The PLT is placed at a known
-offset from where the library is loaded, so the library code can make
-calls to the PLT in a position-independent way. Within the PLT there is
-code to jump to offsets contained in the GOT, so function calls to
-other shared libraries or to routines in the main program can be
-transparently passed off to their real destinations.
-
- To call an external routine, you must use another special PIC
-relocation type, `WRT ..plt'. This is much easier than the GOT-based
-ones: you simply replace calls such as `CALL printf' with the
-PLT-relative version `CALL printf WRT ..plt'.
-
-
-File: nasm.info, Node: Section 9.2.6, Next: Chapter 10, Prev: Section 9.2.5, Up: Section 9.2
-
-9.2.6. Generating the Library File
-----------------------------------
-
-Having written some code modules and assembled them to `.o' files, you
-then generate your shared library with a command such as
-
- ld -shared -o library.so module1.o module2.o # for ELF
- ld -Bshareable -o library.so module1.o module2.o # for BSD
-
- For ELF, if your shared library is going to reside in system
-directories such as `/usr/lib' or `/lib', it is usually worth using the
-`-soname' flag to the linker, to store the final library file name,
-with a version number, into the library:
-
- ld -shared -soname library.so.1 -o library.so.1.2 *.o
-
- You would then copy `library.so.1.2' into the library directory, and
-create `library.so.1' as a symbolic link to it.
-
-
-File: nasm.info, Node: Chapter 10, Next: Section 10.1, Prev: Section 9.2.6, Up: Top
-
-Chapter 10: Mixing 16 and 32 Bit Code
-*************************************
-
-This chapter tries to cover some of the issues, largely related to
-unusual forms of addressing and jump instructions, encountered when
-writing operating system code such as protected-mode initialisation
-routines, which require code that operates in mixed segment sizes, such
-as code in a 16-bit segment trying to modify data in a 32-bit one, or
-jumps between different- size segments.
-
-* Menu:
-
-* Section 10.1:: Mixed-Size Jumps
-* Section 10.2:: Addressing Between Different-Size Segments
-* Section 10.3:: Other Mixed-Size Instructions
-
-
-File: nasm.info, Node: Section 10.1, Next: Section 10.2, Prev: Chapter 10, Up: Chapter 10
-
-10.1. Mixed-Size Jumps
-======================
-
-The most common form of mixed-size instruction is the one used when
-writing a 32-bit OS: having done your setup in 16-bit mode, such as
-loading the kernel, you then have to boot it by switching into
-protected mode and jumping to the 32-bit kernel start address. In a
-fully 32-bit OS, this tends to be the _only_ mixed-size instruction you
-need, since everything before it can be done in pure 16-bit code, and
-everything after it can be pure 32-bit.
-
- This jump must specify a 48-bit far address, since the target
-segment is a 32-bit one. However, it must be assembled in a 16-bit
-segment, so just coding, for example,
-
- jmp 0x1234:0x56789ABC ; wrong!
-
- will not work, since the offset part of the address will be
-truncated to `0x9ABC' and the jump will be an ordinary 16-bit far one.
-
- The Linux kernel setup code gets round the inability of `as86' to
-generate the required instruction by coding it manually, using `DB'
-instructions. NASM can go one better than that, by actually generating
-the right instruction itself. Here's how to do it right:
-
- jmp dword 0x1234:0x56789ABC ; right
-
- The `DWORD' prefix (strictly speaking, it should come _after_ the
-colon, since it is declaring the _offset_ field to be a doubleword; but
-NASM will accept either form, since both are unambiguous) forces the
-offset part to be treated as far, in the assumption that you are
-deliberately writing a jump from a 16-bit segment to a 32-bit one.
-
- You can do the reverse operation, jumping from a 32-bit segment to a
-16-bit one, by means of the `WORD' prefix:
-
- jmp word 0x8765:0x4321 ; 32 to 16 bit
-
- If the `WORD' prefix is specified in 16-bit mode, or the `DWORD'
-prefix in 32-bit mode, they will be ignored, since each is explicitly
-forcing NASM into a mode it was in anyway.
-
-
-File: nasm.info, Node: Section 10.2, Next: Section 10.3, Prev: Section 10.1, Up: Chapter 10
-
-10.2. Addressing Between Different-Size Segments
-================================================
-
-If your OS is mixed 16 and 32-bit, or if you are writing a DOS extender,
-you are likely to have to deal with some 16-bit segments and some 32-bit
-ones. At some point, you will probably end up writing code in a 16-bit
-segment which has to access data in a 32-bit segment, or vice versa.
-
- If the data you are trying to access in a 32-bit segment lies within
-the first 64K of the segment, you may be able to get away with using an
-ordinary 16-bit addressing operation for the purpose; but sooner or
-later, you will want to do 32-bit addressing from 16-bit mode.
-
- The easiest way to do this is to make sure you use a register for the
-address, since any effective address containing a 32-bit register is
-forced to be a 32-bit address. So you can do
-
- mov eax,offset_into_32_bit_segment_specified_by_fs
- mov dword [fs:eax],0x11223344
-
- This is fine, but slightly cumbersome (since it wastes an
-instruction and a register) if you already know the precise offset you
-are aiming at. The x86 architecture does allow 32-bit effective
-addresses to specify nothing but a 4-byte offset, so why shouldn't NASM
-be able to generate the best instruction for the purpose?
-
- It can. As in *note Section 10.1::, you need only prefix the address
-with the `DWORD' keyword, and it will be forced to be a 32-bit address:
-
- mov dword [fs:dword my_offset],0x11223344
-
- Also as in *note Section 10.1::, NASM is not fussy about whether the
-`DWORD' prefix comes before or after the segment override, so arguably
-a nicer-looking way to code the above instruction is
-
- mov dword [dword fs:my_offset],0x11223344
-
- Don't confuse the `DWORD' prefix _outside_ the square brackets,
-which controls the size of the data stored at the address, with the one
-`inside' the square brackets which controls the length of the address
-itself. The two can quite easily be different:
-
- mov word [dword 0x12345678],0x9ABC
-
- This moves 16 bits of data to an address specified by a 32-bit
-offset.
-
- You can also specify `WORD' or `DWORD' prefixes along with the `FAR'
-prefix to indirect far jumps or calls. For example:
-
- call dword far [fs:word 0x4321]
-
- This instruction contains an address specified by a 16-bit offset;
-it loads a 48-bit far pointer from that (16-bit segment and 32-bit
-offset), and calls that address.
-
-
-File: nasm.info, Node: Section 10.3, Next: Chapter 11, Prev: Section 10.2, Up: Chapter 10
-
-10.3. Other Mixed-Size Instructions
-===================================
-
-The other way you might want to access data might be using the string
-instructions (`LODSx', `STOSx' and so on) or the `XLATB' instruction.
-These instructions, since they take no parameters, might seem to have
-no easy way to make them perform 32-bit addressing when assembled in a
-16-bit segment.
-
- This is the purpose of NASM's `a16', `a32' and `a64' prefixes. If
-you are coding `LODSB' in a 16-bit segment but it is supposed to be
-accessing a string in a 32-bit segment, you should load the desired
-address into `ESI' and then code
-
- a32 lodsb
-
- The prefix forces the addressing size to 32 bits, meaning that
-`LODSB' loads from `[DS:ESI]' instead of `[DS:SI]'. To access a string
-in a 16-bit segment when coding in a 32-bit one, the corresponding `a16'
-prefix can be used.
-
- The `a16', `a32' and `a64' prefixes can be applied to any
-instruction in NASM's instruction table, but most of them can generate
-all the useful forms without them. The prefixes are necessary only for
-instructions with implicit addressing: `CMPSx', `SCASx', `LODSx',
-`STOSx', `MOVSx', `INSx', `OUTSx', and `XLATB'. Also, the various push
-and pop instructions (`PUSHA' and `POPF' as well as the more usual
-`PUSH' and `POP') can accept `a16', `a32' or `a64' prefixes to force a
-particular one of `SP', `ESP' or `RSP' to be used as a stack pointer,
-in case the stack segment in use is a different size from the code
-segment.
-
- `PUSH' and `POP', when applied to segment registers in 32-bit mode,
-also have the slightly odd behaviour that they push and pop 4 bytes at
-a time, of which the top two are ignored and the bottom two give the
-value of the segment register being manipulated. To force the 16-bit
-behaviour of segment-register push and pop instructions, you can use the
-operand-size prefix `o16':
-
- o16 push ss
- o16 push ds
-
- This code saves a doubleword of stack space by fitting two segment
-registers into the space which would normally be consumed by pushing
-one.
-
- (You can also use the `o32' prefix to force the 32-bit behaviour when
-in 16-bit mode, but this seems less useful.)
-
-
-File: nasm.info, Node: Chapter 11, Next: Section 11.1, Prev: Section 10.3, Up: Top
-
-Chapter 11: Writing 64-bit Code (Unix, Win64)
-*********************************************
-
-This chapter attempts to cover some of the common issues involved when
-writing 64-bit code, to run under Win64 or Unix. It covers how to write
-assembly code to interface with 64-bit C routines, and how to write
-position-independent code for shared libraries.
-
- All 64-bit code uses a flat memory model, since segmentation is not
-available in 64-bit mode. The one exception is the `FS' and `GS'
-registers, which still add their bases.
-
- Position independence in 64-bit mode is significantly simpler, since
-the processor supports `RIP'-relative addressing directly; see the
-`REL' keyword (*note Section 3.3::). On most 64-bit platforms, it is
-probably desirable to make that the default, using the directive
-`DEFAULT REL' (*note Section 6.2::).
-
- 64-bit programming is relatively similar to 32-bit programming, but
-of course pointers are 64 bits long; additionally, all existing
-platforms pass arguments in registers rather than on the stack.
-Furthermore, 64-bit platforms use SSE2 by default for floating point.
-Please see the ABI documentation for your platform.
-
- 64-bit platforms differ in the sizes of the fundamental datatypes,
-not just from 32-bit platforms but from each other. If a specific size
-data type is desired, it is probably best to use the types defined in
-the Standard C header `<inttypes.h>'.
-
- In 64-bit mode, the default instruction size is still 32 bits. When
-loading a value into a 32-bit register (but not an 8- or 16-bit
-register), the upper 32 bits of the corresponding 64-bit register are
-set to zero.
-
-* Menu:
-
-* Section 11.1:: Register Names in 64-bit Mode
-* Section 11.2:: Immediates and Displacements in 64-bit Mode
-* Section 11.3:: Interfacing to 64-bit C Programs (Unix)
-* Section 11.4:: Interfacing to 64-bit C Programs (Win64)
-
-
-File: nasm.info, Node: Section 11.1, Next: Section 11.2, Prev: Chapter 11, Up: Chapter 11
-
-11.1. Register Names in 64-bit Mode
-===================================
-
-NASM uses the following names for general-purpose registers in 64-bit
-mode, for 8-, 16-, 32- and 64-bit references, respecitively:
-
- AL/AH, CL/CH, DL/DH, BL/BH, SPL, BPL, SIL, DIL, R8B-R15B
- AX, CX, DX, BX, SP, BP, SI, DI, R8W-R15W
- EAX, ECX, EDX, EBX, ESP, EBP, ESI, EDI, R8D-R15D
- RAX, RCX, RDX, RBX, RSP, RBP, RSI, RDI, R8-R15
-
- This is consistent with the AMD documentation and most other
-assemblers. The Intel documentation, however, uses the names
-`R8L-R15L' for 8-bit references to the higher registers. It is possible
-to use those names by definiting them as macros; similarly, if one
-wants to use numeric names for the low 8 registers, define them as
-macros. The standard macro package `altreg' (see *note Section 5.1::)
-can be used for this purpose.
-
-
-File: nasm.info, Node: Section 11.2, Next: Section 11.3, Prev: Section 11.1, Up: Chapter 11
-
-11.2. Immediates and Displacements in 64-bit Mode
-=================================================
-
-In 64-bit mode, immediates and displacements are generally only 32 bits
-wide. NASM will therefore truncate most displacements and immediates to
-32 bits.
-
- The only instruction which takes a full 64-bit immediate is:
-
- MOV reg64,imm64
-
- NASM will produce this instruction whenever the programmer uses `MOV'
-with an immediate into a 64-bit register. If this is not desirable,
-simply specify the equivalent 32-bit register, which will be
-automatically zero- extended by the processor, or specify the immediate
-as `DWORD':
-
- mov rax,foo ; 64-bit immediate
- mov rax,qword foo ; (identical)
- mov eax,foo ; 32-bit immediate, zero-extended
- mov rax,dword foo ; 32-bit immediate, sign-extended
-
- The length of these instructions are 10, 5 and 7 bytes, respectively.
-
- The only instructions which take a full 64-bit _displacement_ is
-loading or storing, using `MOV', `AL', `AX', `EAX' or `RAX' (but no
-other registers) to an absolute 64-bit address. Since this is a
-relatively rarely used instruction (64-bit code generally uses relative
-addressing), the programmer has to explicitly declare the displacement
-size as `QWORD':
-
- default abs
-
- mov eax,[foo] ; 32-bit absolute disp, sign-extended
- mov eax,[a32 foo] ; 32-bit absolute disp, zero-extended
- mov eax,[qword foo] ; 64-bit absolute disp
-
- default rel
-
- mov eax,[foo] ; 32-bit relative disp
- mov eax,[a32 foo] ; d:o, address truncated to 32 bits(!)
- mov eax,[qword foo] ; error
- mov eax,[abs qword foo] ; 64-bit absolute disp
-
- A sign-extended absolute displacement can access from -2 GB to +2
-GB; a zero-extended absolute displacement can access from 0 to 4 GB.
-
-
-File: nasm.info, Node: Section 11.3, Next: Section 11.4, Prev: Section 11.2, Up: Chapter 11
-
-11.3. Interfacing to 64-bit C Programs (Unix)
-=============================================
-
-On Unix, the 64-bit ABI is defined by the document:
-
- `http://www.x86-64.org/documentation/abi.pdf'
-
- Although written for AT&T-syntax assembly, the concepts apply
-equally well for NASM-style assembly. What follows is a simplified
-summary.
-
- The first six integer arguments (from the left) are passed in `RDI',
-`RSI', `RDX', `RCX', `R8', and `R9', in that order. Additional integer
-arguments are passed on the stack. These registers, plus `RAX', `R10'
-and `R11' are destroyed by function calls, and thus are available for
-use by the function without saving.
-
- Integer return values are passed in `RAX' and `RDX', in that order.
-
- Floating point is done using SSE registers, except for `long double'.
-Floating-point arguments are passed in `XMM0' to `XMM7'; return is
-`XMM0' and `XMM1'. `long double' are passed on the stack, and returned
-in `ST0' and `ST1'.
-
- All SSE and x87 registers are destroyed by function calls.
-
- On 64-bit Unix, `long' is 64 bits.
-
- Integer and SSE register arguments are counted separately, so for
-the case of
-
- void foo(long a, double b, int c)
-
- `a' is passed in `RDI', `b' in `XMM0', and `c' in `ESI'.
-
-
-File: nasm.info, Node: Section 11.4, Next: Chapter 12, Prev: Section 11.3, Up: Chapter 11
-
-11.4. Interfacing to 64-bit C Programs (Win64)
-==============================================
-
-The Win64 ABI is described at:
-
- `http://msdn2.microsoft.com/en-gb/library/ms794533.aspx'
-
- What follows is a simplified summary.
-
- The first four integer arguments are passed in `RCX', `RDX', `R8'
-and `R9', in that order. Additional integer arguments are passed on the
-stack. These registers, plus `RAX', `R10' and `R11' are destroyed by
-function calls, and thus are available for use by the function without
-saving.
-
- Integer return values are passed in `RAX' only.
-
- Floating point is done using SSE registers, except for `long double'.
-Floating-point arguments are passed in `XMM0' to `XMM3'; return is
-`XMM0' only.
-
- On Win64, `long' is 32 bits; `long long' or `_int64' is 64 bits.
-
- Integer and SSE register arguments are counted together, so for the
-case of
-
- void foo(long long a, double b, int c)
-
- `a' is passed in `RCX', `b' in `XMM1', and `c' in `R8D'.
-
-
-File: nasm.info, Node: Chapter 12, Next: Section 12.1, Prev: Section 11.4, Up: Top
-
-Chapter 12: Troubleshooting
-***************************
-
-This chapter describes some of the common problems that users have been
-known to encounter with NASM, and answers them. It also gives
-instructions for reporting bugs in NASM if you find a difficulty that
-isn't listed here.
-
-* Menu:
-
-* Section 12.1:: Common Problems
-* Section 12.2:: Bugs
-
-
-File: nasm.info, Node: Section 12.1, Next: Section 12.1.1, Prev: Chapter 12, Up: Chapter 12
-
-12.1. Common Problems
-=====================
-
-* Menu:
-
-* Section 12.1.1:: NASM Generates Inefficient Code
-* Section 12.1.2:: My Jumps are Out of Range
-* Section 12.1.3:: `ORG' Doesn't Work
-* Section 12.1.4:: `TIMES' Doesn't Work
-
-
-File: nasm.info, Node: Section 12.1.1, Next: Section 12.1.2, Prev: Section 12.1, Up: Section 12.1
-
-12.1.1. NASM Generates Inefficient Code
----------------------------------------
-
-We sometimes get `bug' reports about NASM generating inefficient, or
-even `wrong', code on instructions such as `ADD ESP,8'. This is a
-deliberate design feature, connected to predictability of output: NASM,
-on seeing `ADD ESP,8', will generate the form of the instruction which
-leaves room for a 32-bit offset. You need to code `ADD ESP,BYTE 8' if
-you want the space-efficient form of the instruction. This isn't a bug,
-it's user error: if you prefer to have NASM produce the more efficient
-code automatically enable optimization with the `-O' option (see *note
-Section 2.1.22::).
-
-
-File: nasm.info, Node: Section 12.1.2, Next: Section 12.1.3, Prev: Section 12.1.1, Up: Section 12.1
-
-12.1.2. My Jumps are Out of Range
----------------------------------
-
-Similarly, people complain that when they issue conditional jumps (which
-are `SHORT' by default) that try to jump too far, NASM reports `short
-jump out of range' instead of making the jumps longer.
-
- This, again, is partly a predictability issue, but in fact has a more
-practical reason as well. NASM has no means of being told what type of
-processor the code it is generating will be run on; so it cannot decide
-for itself that it should generate `Jcc NEAR' type instructions, because
-it doesn't know that it's working for a 386 or above. Alternatively, it
-could replace the out-of-range short `JNE' instruction with a very
-short `JE' instruction that jumps over a `JMP NEAR'; this is a sensible
-solution for processors below a 386, but hardly efficient on processors
-which have good branch prediction _and_ could have used `JNE NEAR'
-instead. So, once again, it's up to the user, not the assembler, to
-decide what instructions should be generated. See *note Section
-2.1.22::.
-
-
-File: nasm.info, Node: Section 12.1.3, Next: Section 12.1.4, Prev: Section 12.1.2, Up: Section 12.1
-
-12.1.3. `ORG' Doesn't Work
---------------------------
-
-People writing boot sector programs in the `bin' format often complain
-that `ORG' doesn't work the way they'd like: in order to place the
-`0xAA55' signature word at the end of a 512-byte boot sector, people
-who are used to MASM tend to code
-
- ORG 0
-
- ; some boot sector code
-
- ORG 510
- DW 0xAA55
-
- This is not the intended use of the `ORG' directive in NASM, and will
-not work. The correct way to solve this problem in NASM is to use the
-`TIMES' directive, like this:
-
- ORG 0
-
- ; some boot sector code
-
- TIMES 510-($-$$) DB 0
- DW 0xAA55
-
- The `TIMES' directive will insert exactly enough zero bytes into the
-output to move the assembly point up to 510. This method also has the
-advantage that if you accidentally fill your boot sector too full, NASM
-will catch the problem at assembly time and report it, so you won't end
-up with a boot sector that you have to disassemble to find out what's
-wrong with it.
-
-
-File: nasm.info, Node: Section 12.1.4, Next: Section 12.2, Prev: Section 12.1.3, Up: Section 12.1
-
-12.1.4. `TIMES' Doesn't Work
-----------------------------
-
-The other common problem with the above code is people who write the
-`TIMES' line as
-
- TIMES 510-$ DB 0
-
- by reasoning that `$' should be a pure number, just like 510, so the
-difference between them is also a pure number and can happily be fed to
-`TIMES'.
-
- NASM is a _modular_ assembler: the various component parts are
-designed to be easily separable for re-use, so they don't exchange
-information unnecessarily. In consequence, the `bin' output format,
-even though it has been told by the `ORG' directive that the `.text'
-section should start at 0, does not pass that information back to the
-expression evaluator. So from the evaluator's point of view, `$' isn't
-a pure number: it's an offset from a section base. Therefore the
-difference between `$' and 510 is also not a pure number, but involves
-a section base. Values involving section bases cannot be passed as
-arguments to `TIMES'.
-
- The solution, as in the previous section, is to code the `TIMES' line
-in the form
-
- TIMES 510-($-$$) DB 0
-
- in which `$' and `$$' are offsets from the same section base, and so
-their difference is a pure number. This will solve the problem and
-generate sensible code.
-
-
-File: nasm.info, Node: Section 12.2, Next: Appendix A, Prev: Section 12.1.4, Up: Chapter 12
-
-12.2. Bugs
-==========
-
-We have never yet released a version of NASM with any _known_ bugs.
-That doesn't usually stop there being plenty we didn't know about,
-though. Any that you find should be reported firstly via the
-`bugtracker' at `https://sourceforge.net/projects/nasm/' (click on
-"Bugs"), or if that fails then through one of the contacts in *note
-Section 1.2::.
-
- Please read *note Section 2.2:: first, and don't report the bug if
-it's listed in there as a deliberate feature. (If you think the feature
-is badly thought out, feel free to send us reasons why you think it
-should be changed, but don't just send us mail saying `This is a bug'
-if the documentation says we did it on purpose.) Then read *note
-Section 12.1::, and don't bother reporting the bug if it's listed there.
-
- If you do report a bug, _please_ give us all of the following
-information:
-
- * What operating system you're running NASM under. DOS, Linux,
- NetBSD, Win16, Win32, VMS (I'd be impressed), whatever.
-
- * If you're running NASM under DOS or Win32, tell us whether you've
- compiled your own executable from the DOS source archive, or
- whether you were using the standard distribution binaries out of
- the archive. If you were using a locally built executable, try to
- reproduce the problem using one of the standard binaries, as this
- will make it easier for us to reproduce your problem prior to
- fixing it.
-
- * Which version of NASM you're using, and exactly how you invoked
- it. Give us the precise command line, and the contents of the
- `NASMENV' environment variable if any.
-
- * Which versions of any supplementary programs you're using, and how
- you invoked them. If the problem only becomes visible at link
- time, tell us what linker you're using, what version of it you've
- got, and the exact linker command line. If the problem involves
- linking against object files generated by a compiler, tell us what
- compiler, what version, and what command line or options you used.
- (If you're compiling in an IDE, please try to reproduce the
- problem with the command-line version of the compiler.)
-
- * If at all possible, send us a NASM source file which exhibits the
- problem. If this causes copyright problems (e.g. you can only
- reproduce the bug in restricted-distribution code) then bear in
- mind the following two points: firstly, we guarantee that any
- source code sent to us for the purposes of debugging NASM will be
- used _only_ for the purposes of debugging NASM, and that we will
- delete all our copies of it as soon as we have found and fixed the
- bug or bugs in question; and secondly, we would prefer _not_ to be
- mailed large chunks of code anyway. The smaller the file, the
- better. A three-line sample file that does nothing useful
- _except_ demonstrate the problem is much easier to work with than
- a fully fledged ten-thousand- line program. (Of course, some
- errors _do_ only crop up in large files, so this may not be
- possible.)
-
- * A description of what the problem actually _is_. `It doesn't work'
- is _not_ a helpful description! Please describe exactly what is
- happening that shouldn't be, or what isn't happening that should.
- Examples might be: `NASM generates an error message saying Line 3
- for an error that's actually on Line 5'; `NASM generates an error
- message that I believe it shouldn't be generating at all'; `NASM
- fails to generate an error message that I believe it _should_ be
- generating'; `the object file produced from this source code
- crashes my linker'; `the ninth byte of the output file is 66 and I
- think it should be 77 instead'.
-
- * If you believe the output file from NASM to be faulty, send it to
- us. That allows us to determine whether our own copy of NASM
- generates the same file, or whether the problem is related to
- portability issues between our development platforms and yours. We
- can handle binary files mailed to us as MIME attachments,
- uuencoded, and even BinHex. Alternatively, we may be able to
- provide an FTP site you can upload the suspect files to; but
- mailing them is easier for us.
-
- * Any other information or data files that might be helpful. If, for
- example, the problem involves NASM failing to generate an object
- file while TASM can generate an equivalent file without trouble,
- then send us _both_ object files, so we can see what TASM is doing
- differently from us.
-
-
-File: nasm.info, Node: Appendix A, Next: Section A.1, Prev: Section 12.2, Up: Top
-
-Appendix A: Ndisasm
-*******************
-
-The Netwide Disassembler, NDISASM
-
-* Menu:
-
-* Section A.1:: Introduction
-* Section A.2:: Getting Started: Installation
-* Section A.3:: Running NDISASM
-* Section A.4:: Bugs and Improvements
-
-
-File: nasm.info, Node: Section A.1, Next: Section A.2, Prev: Appendix A, Up: Appendix A
-
-A.1. Introduction
-=================
-
-The Netwide Disassembler is a small companion program to the Netwide
-Assembler, NASM. It seemed a shame to have an x86 assembler, complete
-with a full instruction table, and not make as much use of it as
-possible, so here's a disassembler which shares the instruction table
-(and some other bits of code) with NASM.
-
- The Netwide Disassembler does nothing except to produce
-disassemblies of _binary_ source files. NDISASM does not have any
-understanding of object file formats, like `objdump', and it will not
-understand `DOS .EXE' files like `debug' will. It just disassembles.
-
-
-File: nasm.info, Node: Section A.2, Next: Section A.3, Prev: Section A.1, Up: Appendix A
-
-A.2. Getting Started: Installation
-==================================
-
-See *note Section 1.3:: for installation instructions. NDISASM, like
-NASM, has a `man page' which you may want to put somewhere useful, if
-you are on a Unix system.
-
-
-File: nasm.info, Node: Section A.3, Next: Section A.3.1, Prev: Section A.2, Up: Appendix A
-
-A.3. Running NDISASM
-====================
-
-To disassemble a file, you will typically use a command of the form
-
- ndisasm -b {16|32|64} filename
-
- NDISASM can disassemble 16-, 32- or 64-bit code equally easily,
-provided of course that you remember to specify which it is to work
-with. If no `-b' switch is present, NDISASM works in 16-bit mode by
-default. The `-u' switch (for USE32) also invokes 32-bit mode.
-
- Two more command line options are `-r' which reports the version
-number of NDISASM you are running, and `-h' which gives a short summary
-of command line options.
-
-* Menu:
-
-* Section A.3.1:: COM Files: Specifying an Origin
-* Section A.3.2:: Code Following Data: Synchronisation
-* Section A.3.3:: Mixed Code and Data: Automatic (Intelligent) Synchronisation
-* Section A.3.4:: Other Options
-
-
-File: nasm.info, Node: Section A.3.1, Next: Section A.3.2, Prev: Section A.3, Up: Section A.3
-
-A.3.1. COM Files: Specifying an Origin
---------------------------------------
-
-To disassemble a `DOS .COM' file correctly, a disassembler must assume
-that the first instruction in the file is loaded at address `0x100',
-rather than at zero. NDISASM, which assumes by default that any file you
-give it is loaded at zero, will therefore need to be informed of this.
-
- The `-o' option allows you to declare a different origin for the file
-you are disassembling. Its argument may be expressed in any of the NASM
-numeric formats: decimal by default, if it begins with ``$'' or ``0x''
-or ends in ``H'' it's `hex', if it ends in ``Q'' it's `octal', and if
-it ends in ``B'' it's `binary'.
-
- Hence, to disassemble a `.COM' file:
-
- ndisasm -o100h filename.com
-
- will do the trick.
-
-
-File: nasm.info, Node: Section A.3.2, Next: Section A.3.3, Prev: Section A.3.1, Up: Section A.3
-
-A.3.2. Code Following Data: Synchronisation
--------------------------------------------
-
-Suppose you are disassembling a file which contains some data which
-isn't machine code, and _then_ contains some machine code. NDISASM will
-faithfully plough through the data section, producing machine
-instructions wherever it can (although most of them will look bizarre,
-and some may have unusual prefixes, e.g. ``FS OR AX,0x240A''), and
-generating `DB' instructions ever so often if it's totally stumped.
-Then it will reach the code section.
-
- Supposing NDISASM has just finished generating a strange machine
-instruction from part of the data section, and its file position is now
-one byte _before_ the beginning of the code section. It's entirely
-possible that another spurious instruction will get generated, starting
-with the final byte of the data section, and then the correct first
-instruction in the code section will not be seen because the starting
-point skipped over it. This isn't really ideal.
-
- To avoid this, you can specify a ``synchronisation'' point, or indeed
-as many synchronisation points as you like (although NDISASM can only
-handle 2147483647 sync points internally). The definition of a sync
-point is this: NDISASM guarantees to hit sync points exactly during
-disassembly. If it is thinking about generating an instruction which
-would cause it to jump over a sync point, it will discard that
-instruction and output a ``db'' instead. So it _will_ start disassembly
-exactly from the sync point, and so you _will_ see all the instructions
-in your code section.
-
- Sync points are specified using the `-s' option: they are measured in
-terms of the program origin, not the file position. So if you want to
-synchronize after 32 bytes of a `.COM' file, you would have to do
-
- ndisasm -o100h -s120h file.com
-
- rather than
-
- ndisasm -o100h -s20h file.com
-
- As stated above, you can specify multiple sync markers if you need
-to, just by repeating the `-s' option.
-
-
-File: nasm.info, Node: Section A.3.3, Next: Section A.3.4, Prev: Section A.3.2, Up: Section A.3
-
-A.3.3. Mixed Code and Data: Automatic (Intelligent) Synchronisation
--------------------------------------------------------------------
-
-Suppose you are disassembling the boot sector of a `DOS' floppy (maybe
-it has a virus, and you need to understand the virus so that you know
-what kinds of damage it might have done you). Typically, this will
-contain a `JMP' instruction, then some data, then the rest of the code.
-So there is a very good chance of NDISASM being _misaligned_ when the
-data ends and the code begins. Hence a sync point is needed.
-
- On the other hand, why should you have to specify the sync point
-manually? What you'd do in order to find where the sync point would
-be, surely, would be to read the `JMP' instruction, and then to use its
-target address as a sync point. So can NDISASM do that for you?
-
- The answer, of course, is yes: using either of the synonymous
-switches `-a' (for automatic sync) or `-i' (for intelligent sync) will
-enable `auto-sync' mode. Auto-sync mode automatically generates a sync
-point for any forward-referring PC-relative jump or call instruction
-that NDISASM encounters. (Since NDISASM is one-pass, if it encounters a
-PC- relative jump whose target has already been processed, there isn't
-much it can do about it...)
-
- Only PC-relative jumps are processed, since an absolute jump is
-either through a register (in which case NDISASM doesn't know what the
-register contains) or involves a segment address (in which case the
-target code isn't in the same segment that NDISASM is working in, and
-so the sync point can't be placed anywhere useful).
-
- For some kinds of file, this mechanism will automatically put sync
-points in all the right places, and save you from having to place any
-sync points manually. However, it should be stressed that auto-sync
-mode is _not_ guaranteed to catch all the sync points, and you may
-still have to place some manually.
-
- Auto-sync mode doesn't prevent you from declaring manual sync
-points: it just adds automatically generated ones to the ones you
-provide. It's perfectly feasible to specify `-i' _and_ some `-s'
-options.
-
- Another caveat with auto-sync mode is that if, by some unpleasant
-fluke, something in your data section should disassemble to a
-PC-relative call or jump instruction, NDISASM may obediently place a
-sync point in a totally random place, for example in the middle of one
-of the instructions in your code section. So you may end up with a
-wrong disassembly even if you use auto-sync. Again, there isn't much I
-can do about this. If you have problems, you'll have to use manual sync
-points, or use the `-k' option (documented below) to suppress
-disassembly of the data area.
-
-
-File: nasm.info, Node: Section A.3.4, Next: Section A.4, Prev: Section A.3.3, Up: Section A.3
-
-A.3.4. Other Options
---------------------
-
-The `-e' option skips a header on the file, by ignoring the first N
-bytes. This means that the header is _not_ counted towards the
-disassembly offset: if you give `-e10 -o10', disassembly will start at
-byte 10 in the file, and this will be given offset 10, not 20.
-
- The `-k' option is provided with two comma-separated numeric
-arguments, the first of which is an assembly offset and the second is a
-number of bytes to skip. This _will_ count the skipped bytes towards
-the assembly offset: its use is to suppress disassembly of a data
-section which wouldn't contain anything you wanted to see anyway.
-
-
-File: nasm.info, Node: Section A.4, Next: Appendix B, Prev: Section A.3.4, Up: Appendix A
-
-A.4. Bugs and Improvements
-==========================
-
-There are no known bugs. However, any you find, with patches if
-possible, should be sent to `nasm-bugs@lists.sourceforge.net', or to the
-developer's site at `https://sourceforge.net/projects/nasm/' and we'll
-try to fix them. Feel free to send contributions and new features as
-well.
-
-
-File: nasm.info, Node: Appendix B, Next: Section B.1, Prev: Section A.4, Up: Top
-
-Appendix B: Instruction List
-****************************
-
-* Menu:
-
-* Section B.1:: Introduction
-
-
-File: nasm.info, Node: Section B.1, Next: Section B.1.1, Prev: Appendix B, Up: Appendix B
-
-B.1. Introduction
-=================
-
-The following sections show the instructions which NASM currently
-supports. For each instruction, there is a separate entry for each
-supported addressing mode. The third column shows the processor type in
-which the instruction was introduced and, when appropriate, one or more
-usage flags.
-
-* Menu:
-
-* Section B.1.1:: Special instructions...
-* Section B.1.2:: Conventional instructions
-* Section B.1.3:: Katmai Streaming SIMD instructions (SSE ---- a.k.a. KNI, XMM, MMX2)
-* Section B.1.4:: Introduced in Deschutes but necessary for SSE support
-* Section B.1.5:: XSAVE group (AVX and extended state)
-* Section B.1.6:: Generic memory operations
-* Section B.1.7:: New MMX instructions introduced in Katmai
-* Section B.1.8:: AMD Enhanced 3DNow! (Athlon) instructions
-* Section B.1.9:: Willamette SSE2 Cacheability Instructions
-* Section B.1.10:: Willamette MMX instructions (SSE2 SIMD Integer Instructions)
-* Section B.1.11:: Willamette Streaming SIMD instructions (SSE2)
-* Section B.1.12:: Prescott New Instructions (SSE3)
-* Section B.1.13:: VMX Instructions
-* Section B.1.14:: Extended Page Tables VMX instructions
-* Section B.1.15:: Tejas New Instructions (SSSE3)
-* Section B.1.16:: AMD SSE4A
-* Section B.1.17:: New instructions in Barcelona
-* Section B.1.18:: Penryn New Instructions (SSE4.1)
-* Section B.1.19:: Nehalem New Instructions (SSE4.2)
-* Section B.1.20:: Intel SMX
-* Section B.1.21:: Geode (Cyrix) 3DNow! additions
-* Section B.1.22:: Intel new instructions in ???
-* Section B.1.23:: Intel AES instructions
-* Section B.1.24:: Intel AVX AES instructions
-* Section B.1.25:: Intel AVX instructions
-* Section B.1.26:: Intel Carry-Less Multiplication instructions (CLMUL)
-* Section B.1.27:: Intel AVX Carry-Less Multiplication instructions (CLMUL)
-* Section B.1.28:: Intel Fused Multiply-Add instructions (FMA)
-* Section B.1.29:: VIA (Centaur) security instructions
-* Section B.1.30:: AMD Lightweight Profiling (LWP) instructions
-* Section B.1.31:: AMD XOP, FMA4 and CVT16 instructions (SSE5)
-* Section B.1.32:: Systematic names for the hinting nop instructions
-
-
-File: nasm.info, Node: Section B.1.1, Next: Section B.1.2, Prev: Section B.1, Up: Section B.1
-
-B.1.1. Special instructions...
-------------------------------
-
- DB
- DW
- DD
- DQ
- DT
- DO
- DY
- RESB imm 8086
- RESW
- RESD
- RESQ
- REST
- RESO
- RESY
-
-
-File: nasm.info, Node: Section B.1.2, Next: Section B.1.3, Prev: Section B.1.1, Up: Section B.1
-
-B.1.2. Conventional instructions
---------------------------------
-
- AAA 8086,NOLONG
- AAD 8086,NOLONG
- AAD imm 8086,NOLONG
- AAM 8086,NOLONG
- AAM imm 8086,NOLONG
- AAS 8086,NOLONG
- ADC mem,reg8 8086
- ADC reg8,reg8 8086
- ADC mem,reg16 8086
- ADC reg16,reg16 8086
- ADC mem,reg32 386
- ADC reg32,reg32 386
- ADC mem,reg64 X64
- ADC reg64,reg64 X64
- ADC reg8,mem 8086
- ADC reg8,reg8 8086
- ADC reg16,mem 8086
- ADC reg16,reg16 8086
- ADC reg32,mem 386
- ADC reg32,reg32 386
- ADC reg64,mem X64
- ADC reg64,reg64 X64
- ADC rm16,imm8 8086
- ADC rm32,imm8 386
- ADC rm64,imm8 X64
- ADC reg_al,imm 8086
- ADC reg_ax,sbyte16 8086
- ADC reg_ax,imm 8086
- ADC reg_eax,sbyte32 386
- ADC reg_eax,imm 386
- ADC reg_rax,sbyte64 X64
- ADC reg_rax,imm X64
- ADC rm8,imm 8086
- ADC rm16,imm 8086
- ADC rm32,imm 386
- ADC rm64,imm X64
- ADC mem,imm8 8086
- ADC mem,imm16 8086
- ADC mem,imm32 386
- ADD mem,reg8 8086
- ADD reg8,reg8 8086
- ADD mem,reg16 8086
- ADD reg16,reg16 8086
- ADD mem,reg32 386
- ADD reg32,reg32 386
- ADD mem,reg64 X64
- ADD reg64,reg64 X64
- ADD reg8,mem 8086
- ADD reg8,reg8 8086
- ADD reg16,mem 8086
- ADD reg16,reg16 8086
- ADD reg32,mem 386
- ADD reg32,reg32 386
- ADD reg64,mem X64
- ADD reg64,reg64 X64
- ADD rm16,imm8 8086
- ADD rm32,imm8 386
- ADD rm64,imm8 X64
- ADD reg_al,imm 8086
- ADD reg_ax,sbyte16 8086
- ADD reg_ax,imm 8086
- ADD reg_eax,sbyte32 386
- ADD reg_eax,imm 386
- ADD reg_rax,sbyte64 X64
- ADD reg_rax,imm X64
- ADD rm8,imm 8086
- ADD rm16,imm 8086
- ADD rm32,imm 386
- ADD rm64,imm X64
- ADD mem,imm8 8086
- ADD mem,imm16 8086
- ADD mem,imm32 386
- AND mem,reg8 8086
- AND reg8,reg8 8086
- AND mem,reg16 8086
- AND reg16,reg16 8086
- AND mem,reg32 386
- AND reg32,reg32 386
- AND mem,reg64 X64
- AND reg64,reg64 X64
- AND reg8,mem 8086
- AND reg8,reg8 8086
- AND reg16,mem 8086
- AND reg16,reg16 8086
- AND reg32,mem 386
- AND reg32,reg32 386
- AND reg64,mem X64
- AND reg64,reg64 X64
- AND rm16,imm8 8086
- AND rm32,imm8 386
- AND rm64,imm8 X64
- AND reg_al,imm 8086
- AND reg_ax,sbyte16 8086
- AND reg_ax,imm 8086
- AND reg_eax,sbyte32 386
- AND reg_eax,imm 386
- AND reg_rax,sbyte64 X64
- AND reg_rax,imm X64
- AND rm8,imm 8086
- AND rm16,imm 8086
- AND rm32,imm 386
- AND rm64,imm X64
- AND mem,imm8 8086
- AND mem,imm16 8086
- AND mem,imm32 386
- ARPL mem,reg16 286,PROT,NOLONG
- ARPL reg16,reg16 286,PROT,NOLONG
- BB0_RESET PENT,CYRIX,ND
- BB1_RESET PENT,CYRIX,ND
- BOUND reg16,mem 186,NOLONG
- BOUND reg32,mem 386,NOLONG
- BSF reg16,mem 386
- BSF reg16,reg16 386
- BSF reg32,mem 386
- BSF reg32,reg32 386
- BSF reg64,mem X64
- BSF reg64,reg64 X64
- BSR reg16,mem 386
- BSR reg16,reg16 386
- BSR reg32,mem 386
- BSR reg32,reg32 386
- BSR reg64,mem X64
- BSR reg64,reg64 X64
- BSWAP reg32 486
- BSWAP reg64 X64
- BT mem,reg16 386
- BT reg16,reg16 386
- BT mem,reg32 386
- BT reg32,reg32 386
- BT mem,reg64 X64
- BT reg64,reg64 X64
- BT rm16,imm 386
- BT rm32,imm 386
- BT rm64,imm X64
- BTC mem,reg16 386
- BTC reg16,reg16 386
- BTC mem,reg32 386
- BTC reg32,reg32 386
- BTC mem,reg64 X64
- BTC reg64,reg64 X64
- BTC rm16,imm 386
- BTC rm32,imm 386
- BTC rm64,imm X64
- BTR mem,reg16 386
- BTR reg16,reg16 386
- BTR mem,reg32 386
- BTR reg32,reg32 386
- BTR mem,reg64 X64
- BTR reg64,reg64 X64
- BTR rm16,imm 386
- BTR rm32,imm 386
- BTR rm64,imm X64
- BTS mem,reg16 386
- BTS reg16,reg16 386
- BTS mem,reg32 386
- BTS reg32,reg32 386
- BTS mem,reg64 X64
- BTS reg64,reg64 X64
- BTS rm16,imm 386
- BTS rm32,imm 386
- BTS rm64,imm X64
- CALL imm 8086
- CALL imm|near 8086
- CALL imm|far 8086,ND,NOLONG
- CALL imm16 8086
- CALL imm16|near 8086
- CALL imm16|far 8086,ND,NOLONG
- CALL imm32 386
- CALL imm32|near 386
- CALL imm32|far 386,ND,NOLONG
- CALL imm:imm 8086,NOLONG
- CALL imm16:imm 8086,NOLONG
- CALL imm:imm16 8086,NOLONG
- CALL imm32:imm 386,NOLONG
- CALL imm:imm32 386,NOLONG
- CALL mem|far 8086,NOLONG
- CALL mem|far X64
- CALL mem16|far 8086
- CALL mem32|far 386
- CALL mem64|far X64
- CALL mem|near 8086
- CALL mem16|near 8086
- CALL mem32|near 386,NOLONG
- CALL mem64|near X64
- CALL reg16 8086
- CALL reg32 386,NOLONG
- CALL reg64 X64
- CALL mem 8086
- CALL mem16 8086
- CALL mem32 386,NOLONG
- CALL mem64 X64
- CBW 8086
- CDQ 386
- CDQE X64
- CLC 8086
- CLD 8086
- CLGI X64,AMD
- CLI 8086
- CLTS 286,PRIV
- CMC 8086
- CMP mem,reg8 8086
- CMP reg8,reg8 8086
- CMP mem,reg16 8086
- CMP reg16,reg16 8086
- CMP mem,reg32 386
- CMP reg32,reg32 386
- CMP mem,reg64 X64
- CMP reg64,reg64 X64
- CMP reg8,mem 8086
- CMP reg8,reg8 8086
- CMP reg16,mem 8086
- CMP reg16,reg16 8086
- CMP reg32,mem 386
- CMP reg32,reg32 386
- CMP reg64,mem X64
- CMP reg64,reg64 X64
- CMP rm16,imm8 8086
- CMP rm32,imm8 386
- CMP rm64,imm8 X64
- CMP reg_al,imm 8086
- CMP reg_ax,sbyte16 8086
- CMP reg_ax,imm 8086
- CMP reg_eax,sbyte32 386
- CMP reg_eax,imm 386
- CMP reg_rax,sbyte64 X64
- CMP reg_rax,imm X64
- CMP rm8,imm 8086
- CMP rm16,imm 8086
- CMP rm32,imm 386
- CMP rm64,imm X64
- CMP mem,imm8 8086
- CMP mem,imm16 8086
- CMP mem,imm32 386
- CMPSB 8086
- CMPSD 386
- CMPSQ X64
- CMPSW 8086
- CMPXCHG mem,reg8 PENT
- CMPXCHG reg8,reg8 PENT
- CMPXCHG mem,reg16 PENT
- CMPXCHG reg16,reg16 PENT
- CMPXCHG mem,reg32 PENT
- CMPXCHG reg32,reg32 PENT
- CMPXCHG mem,reg64 X64
- CMPXCHG reg64,reg64 X64
- CMPXCHG486 mem,reg8 486,UNDOC,ND
- CMPXCHG486 reg8,reg8 486,UNDOC,ND
- CMPXCHG486 mem,reg16 486,UNDOC,ND
- CMPXCHG486 reg16,reg16 486,UNDOC,ND
- CMPXCHG486 mem,reg32 486,UNDOC,ND
- CMPXCHG486 reg32,reg32 486,UNDOC,ND
- CMPXCHG8B mem PENT
- CMPXCHG16B mem X64
- CPUID PENT
- CPU_READ PENT,CYRIX
- CPU_WRITE PENT,CYRIX
- CQO X64
- CWD 8086
- CWDE 386
- DAA 8086,NOLONG
- DAS 8086,NOLONG
- DEC reg16 8086,NOLONG
- DEC reg32 386,NOLONG
- DEC rm8 8086
- DEC rm16 8086
- DEC rm32 386
- DEC rm64 X64
- DIV rm8 8086
- DIV rm16 8086
- DIV rm32 386
- DIV rm64 X64
- DMINT P6,CYRIX
- EMMS PENT,MMX
- ENTER imm,imm 186
- EQU imm 8086
- EQU imm:imm 8086
- F2XM1 8086,FPU
- FABS 8086,FPU
- FADD mem32 8086,FPU
- FADD mem64 8086,FPU
- FADD fpureg|to 8086,FPU
- FADD fpureg 8086,FPU
- FADD fpureg,fpu0 8086,FPU
- FADD fpu0,fpureg 8086,FPU
- FADD 8086,FPU,ND
- FADDP fpureg 8086,FPU
- FADDP fpureg,fpu0 8086,FPU
- FADDP 8086,FPU,ND
- FBLD mem80 8086,FPU
- FBLD mem 8086,FPU
- FBSTP mem80 8086,FPU
- FBSTP mem 8086,FPU
- FCHS 8086,FPU
- FCLEX 8086,FPU
- FCMOVB fpureg P6,FPU
- FCMOVB fpu0,fpureg P6,FPU
- FCMOVB P6,FPU,ND
- FCMOVBE fpureg P6,FPU
- FCMOVBE fpu0,fpureg P6,FPU
- FCMOVBE P6,FPU,ND
- FCMOVE fpureg P6,FPU
- FCMOVE fpu0,fpureg P6,FPU
- FCMOVE P6,FPU,ND
- FCMOVNB fpureg P6,FPU
- FCMOVNB fpu0,fpureg P6,FPU
- FCMOVNB P6,FPU,ND
- FCMOVNBE fpureg P6,FPU
- FCMOVNBE fpu0,fpureg P6,FPU
- FCMOVNBE P6,FPU,ND
- FCMOVNE fpureg P6,FPU
- FCMOVNE fpu0,fpureg P6,FPU
- FCMOVNE P6,FPU,ND
- FCMOVNU fpureg P6,FPU
- FCMOVNU fpu0,fpureg P6,FPU
- FCMOVNU P6,FPU,ND
- FCMOVU fpureg P6,FPU
- FCMOVU fpu0,fpureg P6,FPU
- FCMOVU P6,FPU,ND
- FCOM mem32 8086,FPU
- FCOM mem64 8086,FPU
- FCOM fpureg 8086,FPU
- FCOM fpu0,fpureg 8086,FPU
- FCOM 8086,FPU,ND
- FCOMI fpureg P6,FPU
- FCOMI fpu0,fpureg P6,FPU
- FCOMI P6,FPU,ND
- FCOMIP fpureg P6,FPU
- FCOMIP fpu0,fpureg P6,FPU
- FCOMIP P6,FPU,ND
- FCOMP mem32 8086,FPU
- FCOMP mem64 8086,FPU
- FCOMP fpureg 8086,FPU
- FCOMP fpu0,fpureg 8086,FPU
- FCOMP 8086,FPU,ND
- FCOMPP 8086,FPU
- FCOS 386,FPU
- FDECSTP 8086,FPU
- FDISI 8086,FPU
- FDIV mem32 8086,FPU
- FDIV mem64 8086,FPU
- FDIV fpureg|to 8086,FPU
- FDIV fpureg 8086,FPU
- FDIV fpureg,fpu0 8086,FPU
- FDIV fpu0,fpureg 8086,FPU
- FDIV 8086,FPU,ND
- FDIVP fpureg 8086,FPU
- FDIVP fpureg,fpu0 8086,FPU
- FDIVP 8086,FPU,ND
- FDIVR mem32 8086,FPU
- FDIVR mem64 8086,FPU
- FDIVR fpureg|to 8086,FPU
- FDIVR fpureg,fpu0 8086,FPU
- FDIVR fpureg 8086,FPU
- FDIVR fpu0,fpureg 8086,FPU
- FDIVR 8086,FPU,ND
- FDIVRP fpureg 8086,FPU
- FDIVRP fpureg,fpu0 8086,FPU
- FDIVRP 8086,FPU,ND
- FEMMS PENT,3DNOW
- FENI 8086,FPU
- FFREE fpureg 8086,FPU
- FFREE 8086,FPU
- FFREEP fpureg 286,FPU,UNDOC
- FFREEP 286,FPU,UNDOC
- FIADD mem32 8086,FPU
- FIADD mem16 8086,FPU
- FICOM mem32 8086,FPU
- FICOM mem16 8086,FPU
- FICOMP mem32 8086,FPU
- FICOMP mem16 8086,FPU
- FIDIV mem32 8086,FPU
- FIDIV mem16 8086,FPU
- FIDIVR mem32 8086,FPU
- FIDIVR mem16 8086,FPU
- FILD mem32 8086,FPU
- FILD mem16 8086,FPU
- FILD mem64 8086,FPU
- FIMUL mem32 8086,FPU
- FIMUL mem16 8086,FPU
- FINCSTP 8086,FPU
- FINIT 8086,FPU
- FIST mem32 8086,FPU
- FIST mem16 8086,FPU
- FISTP mem32 8086,FPU
- FISTP mem16 8086,FPU
- FISTP mem64 8086,FPU
- FISTTP mem16 PRESCOTT,FPU
- FISTTP mem32 PRESCOTT,FPU
- FISTTP mem64 PRESCOTT,FPU
- FISUB mem32 8086,FPU
- FISUB mem16 8086,FPU
- FISUBR mem32 8086,FPU
- FISUBR mem16 8086,FPU
- FLD mem32 8086,FPU
- FLD mem64 8086,FPU
- FLD mem80 8086,FPU
- FLD fpureg 8086,FPU
- FLD 8086,FPU,ND
- FLD1 8086,FPU
- FLDCW mem 8086,FPU,SW
- FLDENV mem 8086,FPU
- FLDL2E 8086,FPU
- FLDL2T 8086,FPU
- FLDLG2 8086,FPU
- FLDLN2 8086,FPU
- FLDPI 8086,FPU
- FLDZ 8086,FPU
- FMUL mem32 8086,FPU
- FMUL mem64 8086,FPU
- FMUL fpureg|to 8086,FPU
- FMUL fpureg,fpu0 8086,FPU
- FMUL fpureg 8086,FPU
- FMUL fpu0,fpureg 8086,FPU
- FMUL 8086,FPU,ND
- FMULP fpureg 8086,FPU
- FMULP fpureg,fpu0 8086,FPU
- FMULP 8086,FPU,ND
- FNCLEX 8086,FPU
- FNDISI 8086,FPU
- FNENI 8086,FPU
- FNINIT 8086,FPU
- FNOP 8086,FPU
- FNSAVE mem 8086,FPU
- FNSTCW mem 8086,FPU,SW
- FNSTENV mem 8086,FPU
- FNSTSW mem 8086,FPU,SW
- FNSTSW reg_ax 286,FPU
- FPATAN 8086,FPU
- FPREM 8086,FPU
- FPREM1 386,FPU
- FPTAN 8086,FPU
- FRNDINT 8086,FPU
- FRSTOR mem 8086,FPU
- FSAVE mem 8086,FPU
- FSCALE 8086,FPU
- FSETPM 286,FPU
- FSIN 386,FPU
- FSINCOS 386,FPU
- FSQRT 8086,FPU
- FST mem32 8086,FPU
- FST mem64 8086,FPU
- FST fpureg 8086,FPU
- FST 8086,FPU,ND
- FSTCW mem 8086,FPU,SW
- FSTENV mem 8086,FPU
- FSTP mem32 8086,FPU
- FSTP mem64 8086,FPU
- FSTP mem80 8086,FPU
- FSTP fpureg 8086,FPU
- FSTP 8086,FPU,ND
- FSTSW mem 8086,FPU,SW
- FSTSW reg_ax 286,FPU
- FSUB mem32 8086,FPU
- FSUB mem64 8086,FPU
- FSUB fpureg|to 8086,FPU
- FSUB fpureg,fpu0 8086,FPU
- FSUB fpureg 8086,FPU
- FSUB fpu0,fpureg 8086,FPU
- FSUB 8086,FPU,ND
- FSUBP fpureg 8086,FPU
- FSUBP fpureg,fpu0 8086,FPU
- FSUBP 8086,FPU,ND
- FSUBR mem32 8086,FPU
- FSUBR mem64 8086,FPU
- FSUBR fpureg|to 8086,FPU
- FSUBR fpureg,fpu0 8086,FPU
- FSUBR fpureg 8086,FPU
- FSUBR fpu0,fpureg 8086,FPU
- FSUBR 8086,FPU,ND
- FSUBRP fpureg 8086,FPU
- FSUBRP fpureg,fpu0 8086,FPU
- FSUBRP 8086,FPU,ND
- FTST 8086,FPU
- FUCOM fpureg 386,FPU
- FUCOM fpu0,fpureg 386,FPU
- FUCOM 386,FPU,ND
- FUCOMI fpureg P6,FPU
- FUCOMI fpu0,fpureg P6,FPU
- FUCOMI P6,FPU,ND
- FUCOMIP fpureg P6,FPU
- FUCOMIP fpu0,fpureg P6,FPU
- FUCOMIP P6,FPU,ND
- FUCOMP fpureg 386,FPU
- FUCOMP fpu0,fpureg 386,FPU
- FUCOMP 386,FPU,ND
- FUCOMPP 386,FPU
- FXAM 8086,FPU
- FXCH fpureg 8086,FPU
- FXCH fpureg,fpu0 8086,FPU
- FXCH fpu0,fpureg 8086,FPU
- FXCH 8086,FPU,ND
- FXTRACT 8086,FPU
- FYL2X 8086,FPU
- FYL2XP1 8086,FPU
- HLT 8086,PRIV
- IBTS mem,reg16 386,SW,UNDOC,ND
- IBTS reg16,reg16 386,UNDOC,ND
- IBTS mem,reg32 386,SD,UNDOC,ND
- IBTS reg32,reg32 386,UNDOC,ND
- ICEBP 386,ND
- IDIV rm8 8086
- IDIV rm16 8086
- IDIV rm32 386
- IDIV rm64 X64
- IMUL rm8 8086
- IMUL rm16 8086
- IMUL rm32 386
- IMUL rm64 X64
- IMUL reg16,mem 386
- IMUL reg16,reg16 386
- IMUL reg32,mem 386
- IMUL reg32,reg32 386
- IMUL reg64,mem X64
- IMUL reg64,reg64 X64
- IMUL reg16,mem,imm8 186
- IMUL reg16,mem,sbyte16 186,ND
- IMUL reg16,mem,imm16 186
- IMUL reg16,mem,imm 186,ND
- IMUL reg16,reg16,imm8 186
- IMUL reg16,reg16,sbyte16 186,ND
- IMUL reg16,reg16,imm16 186
- IMUL reg16,reg16,imm 186,ND
- IMUL reg32,mem,imm8 386
- IMUL reg32,mem,sbyte32 386,ND
- IMUL reg32,mem,imm32 386
- IMUL reg32,mem,imm 386,ND
- IMUL reg32,reg32,imm8 386
- IMUL reg32,reg32,sbyte32 386,ND
- IMUL reg32,reg32,imm32 386
- IMUL reg32,reg32,imm 386,ND
- IMUL reg64,mem,imm8 X64
- IMUL reg64,mem,sbyte64 X64,ND
- IMUL reg64,mem,imm32 X64
- IMUL reg64,mem,imm X64,ND
- IMUL reg64,reg64,imm8 X64
- IMUL reg64,reg64,sbyte64 X64,ND
- IMUL reg64,reg64,imm32 X64
- IMUL reg64,reg64,imm X64,ND
- IMUL reg16,imm8 186
- IMUL reg16,sbyte16 186,ND
- IMUL reg16,imm16 186
- IMUL reg16,imm 186,ND
- IMUL reg32,imm8 386
- IMUL reg32,sbyte32 386,ND
- IMUL reg32,imm32 386
- IMUL reg32,imm 386,ND
- IMUL reg64,imm8 X64
- IMUL reg64,sbyte64 X64,ND
- IMUL reg64,imm32 X64
- IMUL reg64,imm X64,ND
- IN reg_al,imm 8086
- IN reg_ax,imm 8086
- IN reg_eax,imm 386
- IN reg_al,reg_dx 8086
- IN reg_ax,reg_dx 8086
- IN reg_eax,reg_dx 386
- INC reg16 8086,NOLONG
- INC reg32 386,NOLONG
- INC rm8 8086
- INC rm16 8086
- INC rm32 386
- INC rm64 X64
- INCBIN
- INSB 186
- INSD 386
- INSW 186
- INT imm 8086
- INT01 386,ND
- INT1 386
- INT03 8086,ND
- INT3 8086
- INTO 8086,NOLONG
- INVD 486,PRIV
- INVLPG mem 486,PRIV
- INVLPGA reg_ax,reg_ecx X86_64,AMD,NOLONG
- INVLPGA reg_eax,reg_ecx X86_64,AMD
- INVLPGA reg_rax,reg_ecx X64,AMD
- INVLPGA X86_64,AMD
- IRET 8086
- IRETD 386
- IRETQ X64
- IRETW 8086
- JCXZ imm 8086,NOLONG
- JECXZ imm 386
- JRCXZ imm X64
- JMP imm|short 8086
- JMP imm 8086,ND
- JMP imm 8086
- JMP imm|near 8086,ND
- JMP imm|far 8086,ND,NOLONG
- JMP imm16 8086
- JMP imm16|near 8086,ND
- JMP imm16|far 8086,ND,NOLONG
- JMP imm32 386
- JMP imm32|near 386,ND
- JMP imm32|far 386,ND,NOLONG
- JMP imm:imm 8086,NOLONG
- JMP imm16:imm 8086,NOLONG
- JMP imm:imm16 8086,NOLONG
- JMP imm32:imm 386,NOLONG
- JMP imm:imm32 386,NOLONG
- JMP mem|far 8086,NOLONG
- JMP mem|far X64
- JMP mem16|far 8086
- JMP mem32|far 386
- JMP mem64|far X64
- JMP mem|near 8086
- JMP mem16|near 8086
- JMP mem32|near 386,NOLONG
- JMP mem64|near X64
- JMP reg16 8086
- JMP reg32 386,NOLONG
- JMP reg64 X64
- JMP mem 8086
- JMP mem16 8086
- JMP mem32 386,NOLONG
- JMP mem64 X64
- JMPE imm IA64
- JMPE imm16 IA64
- JMPE imm32 IA64
- JMPE rm16 IA64
- JMPE rm32 IA64
- LAHF 8086
- LAR reg16,mem 286,PROT,SW
- LAR reg16,reg16 286,PROT
- LAR reg16,reg32 386,PROT
- LAR reg16,reg64 X64,PROT,ND
- LAR reg32,mem 386,PROT,SW
- LAR reg32,reg16 386,PROT
- LAR reg32,reg32 386,PROT
- LAR reg32,reg64 X64,PROT,ND
- LAR reg64,mem X64,PROT,SW
- LAR reg64,reg16 X64,PROT
- LAR reg64,reg32 X64,PROT
- LAR reg64,reg64 X64,PROT
- LDS reg16,mem 8086,NOLONG
- LDS reg32,mem 386,NOLONG
- LEA reg16,mem 8086
- LEA reg32,mem 386
- LEA reg64,mem X64
- LEAVE 186
- LES reg16,mem 8086,NOLONG
- LES reg32,mem 386,NOLONG
- LFENCE X64,AMD
- LFS reg16,mem 386
- LFS reg32,mem 386
- LGDT mem 286,PRIV
- LGS reg16,mem 386
- LGS reg32,mem 386
- LIDT mem 286,PRIV
- LLDT mem 286,PROT,PRIV
- LLDT mem16 286,PROT,PRIV
- LLDT reg16 286,PROT,PRIV
- LMSW mem 286,PRIV
- LMSW mem16 286,PRIV
- LMSW reg16 286,PRIV
- LOADALL 386,UNDOC
- LOADALL286 286,UNDOC
- LODSB 8086
- LODSD 386
- LODSQ X64
- LODSW 8086
- LOOP imm 8086
- LOOP imm,reg_cx 8086,NOLONG
- LOOP imm,reg_ecx 386
- LOOP imm,reg_rcx X64
- LOOPE imm 8086
- LOOPE imm,reg_cx 8086,NOLONG
- LOOPE imm,reg_ecx 386
- LOOPE imm,reg_rcx X64
- LOOPNE imm 8086
- LOOPNE imm,reg_cx 8086,NOLONG
- LOOPNE imm,reg_ecx 386
- LOOPNE imm,reg_rcx X64
- LOOPNZ imm 8086
- LOOPNZ imm,reg_cx 8086,NOLONG
- LOOPNZ imm,reg_ecx 386
- LOOPNZ imm,reg_rcx X64
- LOOPZ imm 8086
- LOOPZ imm,reg_cx 8086,NOLONG
- LOOPZ imm,reg_ecx 386
- LOOPZ imm,reg_rcx X64
- LSL reg16,mem 286,PROT,SW
- LSL reg16,reg16 286,PROT
- LSL reg16,reg32 386,PROT
- LSL reg16,reg64 X64,PROT,ND
- LSL reg32,mem 386,PROT,SW
- LSL reg32,reg16 386,PROT
- LSL reg32,reg32 386,PROT
- LSL reg32,reg64 X64,PROT,ND
- LSL reg64,mem X64,PROT,SW
- LSL reg64,reg16 X64,PROT
- LSL reg64,reg32 X64,PROT
- LSL reg64,reg64 X64,PROT
- LSS reg16,mem 386
- LSS reg32,mem 386
- LTR mem 286,PROT,PRIV
- LTR mem16 286,PROT,PRIV
- LTR reg16 286,PROT,PRIV
- MFENCE X64,AMD
- MONITOR PRESCOTT
- MONITOR reg_eax,reg_ecx,reg_edx PRESCOTT,ND
- MONITOR reg_rax,reg_ecx,reg_edx X64,ND
- MOV mem,reg_sreg 8086
- MOV reg16,reg_sreg 8086
- MOV reg32,reg_sreg 386
- MOV reg_sreg,mem 8086
- MOV reg_sreg,reg16 8086
- MOV reg_sreg,reg32 386
- MOV reg_al,mem_offs 8086
- MOV reg_ax,mem_offs 8086
- MOV reg_eax,mem_offs 386
- MOV reg_rax,mem_offs X64
- MOV mem_offs,reg_al 8086
- MOV mem_offs,reg_ax 8086
- MOV mem_offs,reg_eax 386
- MOV mem_offs,reg_rax X64
- MOV reg32,reg_creg 386,PRIV,NOLONG
- MOV reg64,reg_creg X64,PRIV
- MOV reg_creg,reg32 386,PRIV,NOLONG
- MOV reg_creg,reg64 X64,PRIV
- MOV reg32,reg_dreg 386,PRIV,NOLONG
- MOV reg64,reg_dreg X64,PRIV
- MOV reg_dreg,reg32 386,PRIV,NOLONG
- MOV reg_dreg,reg64 X64,PRIV
- MOV reg32,reg_treg 386,NOLONG,ND
- MOV reg_treg,reg32 386,NOLONG,ND
- MOV mem,reg8 8086
- MOV reg8,reg8 8086
- MOV mem,reg16 8086
- MOV reg16,reg16 8086
- MOV mem,reg32 386
- MOV reg32,reg32 386
- MOV mem,reg64 X64
- MOV reg64,reg64 X64
- MOV reg8,mem 8086
- MOV reg8,reg8 8086
- MOV reg16,mem 8086
- MOV reg16,reg16 8086
- MOV reg32,mem 386
- MOV reg32,reg32 386
- MOV reg64,mem X64
- MOV reg64,reg64 X64
- MOV reg8,imm 8086
- MOV reg16,imm 8086
- MOV reg32,imm 386
- MOV reg64,imm X64
- MOV reg64,imm32 X64
- MOV rm8,imm 8086
- MOV rm16,imm 8086
- MOV rm32,imm 386
- MOV rm64,imm X64
- MOV mem,imm8 8086
- MOV mem,imm16 8086
- MOV mem,imm32 386
- MOVD mmxreg,mem PENT,MMX,SD
- MOVD mmxreg,reg32 PENT,MMX
- MOVD mem,mmxreg PENT,MMX,SD
- MOVD reg32,mmxreg PENT,MMX
- MOVD xmmreg,mem X64,SD
- MOVD xmmreg,reg32 X64
- MOVD mem,xmmreg X64,SD
- MOVD reg32,xmmreg X64,SSE
- MOVQ mmxreg,mmxrm PENT,MMX
- MOVQ mmxrm,mmxreg PENT,MMX
- MOVQ mmxreg,rm64 X64,MMX
- MOVQ rm64,mmxreg X64,MMX
- MOVSB 8086
- MOVSD 386
- MOVSQ X64
- MOVSW 8086
- MOVSX reg16,mem 386
- MOVSX reg16,reg8 386
- MOVSX reg32,rm8 386
- MOVSX reg32,rm16 386
- MOVSX reg64,rm8 X64
- MOVSX reg64,rm16 X64
- MOVSXD reg64,rm32 X64
- MOVSX reg64,rm32 X64,ND
- MOVZX reg16,mem 386
- MOVZX reg16,reg8 386
- MOVZX reg32,rm8 386
- MOVZX reg32,rm16 386
- MOVZX reg64,rm8 X64
- MOVZX reg64,rm16 X64
- MUL rm8 8086
- MUL rm16 8086
- MUL rm32 386
- MUL rm64 X64
- MWAIT PRESCOTT
- MWAIT reg_eax,reg_ecx PRESCOTT,ND
- NEG rm8 8086
- NEG rm16 8086
- NEG rm32 386
- NEG rm64 X64
- NOP 8086
- NOP rm16 P6
- NOP rm32 P6
- NOP rm64 X64
- NOT rm8 8086
- NOT rm16 8086
- NOT rm32 386
- NOT rm64 X64
- OR mem,reg8 8086
- OR reg8,reg8 8086
- OR mem,reg16 8086
- OR reg16,reg16 8086
- OR mem,reg32 386
- OR reg32,reg32 386
- OR mem,reg64 X64
- OR reg64,reg64 X64
- OR reg8,mem 8086
- OR reg8,reg8 8086
- OR reg16,mem 8086
- OR reg16,reg16 8086
- OR reg32,mem 386
- OR reg32,reg32 386
- OR reg64,mem X64
- OR reg64,reg64 X64
- OR rm16,imm8 8086
- OR rm32,imm8 386
- OR rm64,imm8 X64
- OR reg_al,imm 8086
- OR reg_ax,sbyte16 8086
- OR reg_ax,imm 8086
- OR reg_eax,sbyte32 386
- OR reg_eax,imm 386
- OR reg_rax,sbyte64 X64
- OR reg_rax,imm X64
- OR rm8,imm 8086
- OR rm16,imm 8086
- OR rm32,imm 386
- OR rm64,imm X64
- OR mem,imm8 8086
- OR mem,imm16 8086
- OR mem,imm32 386
- OUT imm,reg_al 8086
- OUT imm,reg_ax 8086
- OUT imm,reg_eax 386
- OUT reg_dx,reg_al 8086
- OUT reg_dx,reg_ax 8086
- OUT reg_dx,reg_eax 386
- OUTSB 186
- OUTSD 386
- OUTSW 186
- PACKSSDW mmxreg,mmxrm PENT,MMX
- PACKSSWB mmxreg,mmxrm PENT,MMX
- PACKUSWB mmxreg,mmxrm PENT,MMX
- PADDB mmxreg,mmxrm PENT,MMX
- PADDD mmxreg,mmxrm PENT,MMX
- PADDSB mmxreg,mmxrm PENT,MMX
- PADDSIW mmxreg,mmxrm PENT,MMX,CYRIX
- PADDSW mmxreg,mmxrm PENT,MMX
- PADDUSB mmxreg,mmxrm PENT,MMX
- PADDUSW mmxreg,mmxrm PENT,MMX
- PADDW mmxreg,mmxrm PENT,MMX
- PAND mmxreg,mmxrm PENT,MMX
- PANDN mmxreg,mmxrm PENT,MMX
- PAUSE 8086
- PAVEB mmxreg,mmxrm PENT,MMX,CYRIX
- PAVGUSB mmxreg,mmxrm PENT,3DNOW
- PCMPEQB mmxreg,mmxrm PENT,MMX
- PCMPEQD mmxreg,mmxrm PENT,MMX
- PCMPEQW mmxreg,mmxrm PENT,MMX
- PCMPGTB mmxreg,mmxrm PENT,MMX
- PCMPGTD mmxreg,mmxrm PENT,MMX
- PCMPGTW mmxreg,mmxrm PENT,MMX
- PDISTIB mmxreg,mem PENT,MMX,CYRIX
- PF2ID mmxreg,mmxrm PENT,3DNOW
- PFACC mmxreg,mmxrm PENT,3DNOW
- PFADD mmxreg,mmxrm PENT,3DNOW
- PFCMPEQ mmxreg,mmxrm PENT,3DNOW
- PFCMPGE mmxreg,mmxrm PENT,3DNOW
- PFCMPGT mmxreg,mmxrm PENT,3DNOW
- PFMAX mmxreg,mmxrm PENT,3DNOW
- PFMIN mmxreg,mmxrm PENT,3DNOW
- PFMUL mmxreg,mmxrm PENT,3DNOW
- PFRCP mmxreg,mmxrm PENT,3DNOW
- PFRCPIT1 mmxreg,mmxrm PENT,3DNOW
- PFRCPIT2 mmxreg,mmxrm PENT,3DNOW
- PFRSQIT1 mmxreg,mmxrm PENT,3DNOW
- PFRSQRT mmxreg,mmxrm PENT,3DNOW
- PFSUB mmxreg,mmxrm PENT,3DNOW
- PFSUBR mmxreg,mmxrm PENT,3DNOW
- PI2FD mmxreg,mmxrm PENT,3DNOW
- PMACHRIW mmxreg,mem PENT,MMX,CYRIX
- PMADDWD mmxreg,mmxrm PENT,MMX
- PMAGW mmxreg,mmxrm PENT,MMX,CYRIX
- PMULHRIW mmxreg,mmxrm PENT,MMX,CYRIX
- PMULHRWA mmxreg,mmxrm PENT,3DNOW
- PMULHRWC mmxreg,mmxrm PENT,MMX,CYRIX
- PMULHW mmxreg,mmxrm PENT,MMX
- PMULLW mmxreg,mmxrm PENT,MMX
- PMVGEZB mmxreg,mem PENT,MMX,CYRIX
- PMVLZB mmxreg,mem PENT,MMX,CYRIX
- PMVNZB mmxreg,mem PENT,MMX,CYRIX
- PMVZB mmxreg,mem PENT,MMX,CYRIX
- POP reg16 8086
- POP reg32 386,NOLONG
- POP reg64 X64
- POP rm16 8086
- POP rm32 386,NOLONG
- POP rm64 X64
- POP reg_cs 8086,UNDOC,ND
- POP reg_dess 8086,NOLONG
- POP reg_fsgs 386
- POPA 186,NOLONG
- POPAD 386,NOLONG
- POPAW 186,NOLONG
- POPF 8086
- POPFD 386,NOLONG
- POPFQ X64
- POPFW 8086
- POR mmxreg,mmxrm PENT,MMX
- PREFETCH mem PENT,3DNOW
- PREFETCHW mem PENT,3DNOW
- PSLLD mmxreg,mmxrm PENT,MMX
- PSLLD mmxreg,imm PENT,MMX
- PSLLQ mmxreg,mmxrm PENT,MMX
- PSLLQ mmxreg,imm PENT,MMX
- PSLLW mmxreg,mmxrm PENT,MMX
- PSLLW mmxreg,imm PENT,MMX
- PSRAD mmxreg,mmxrm PENT,MMX
- PSRAD mmxreg,imm PENT,MMX
- PSRAW mmxreg,mmxrm PENT,MMX
- PSRAW mmxreg,imm PENT,MMX
- PSRLD mmxreg,mmxrm PENT,MMX
- PSRLD mmxreg,imm PENT,MMX
- PSRLQ mmxreg,mmxrm PENT,MMX
- PSRLQ mmxreg,imm PENT,MMX
- PSRLW mmxreg,mmxrm PENT,MMX
- PSRLW mmxreg,imm PENT,MMX
- PSUBB mmxreg,mmxrm PENT,MMX
- PSUBD mmxreg,mmxrm PENT,MMX
- PSUBSB mmxreg,mmxrm PENT,MMX
- PSUBSIW mmxreg,mmxrm PENT,MMX,CYRIX
- PSUBSW mmxreg,mmxrm PENT,MMX
- PSUBUSB mmxreg,mmxrm PENT,MMX
- PSUBUSW mmxreg,mmxrm PENT,MMX
- PSUBW mmxreg,mmxrm PENT,MMX
- PUNPCKHBW mmxreg,mmxrm PENT,MMX
- PUNPCKHDQ mmxreg,mmxrm PENT,MMX
- PUNPCKHWD mmxreg,mmxrm PENT,MMX
- PUNPCKLBW mmxreg,mmxrm PENT,MMX
- PUNPCKLDQ mmxreg,mmxrm PENT,MMX
- PUNPCKLWD mmxreg,mmxrm PENT,MMX
- PUSH reg16 8086
- PUSH reg32 386,NOLONG
- PUSH reg64 X64
- PUSH rm16 8086
- PUSH rm32 386,NOLONG
- PUSH rm64 X64
- PUSH reg_cs 8086,NOLONG
- PUSH reg_dess 8086,NOLONG
- PUSH reg_fsgs 386
- PUSH imm8 186
- PUSH imm16 186,AR0,SZ
- PUSH imm32 386,NOLONG,AR0,SZ
- PUSH imm32 386,NOLONG,SD
- PUSH imm64 X64,AR0,SZ
- PUSHA 186,NOLONG
- PUSHAD 386,NOLONG
- PUSHAW 186,NOLONG
- PUSHF 8086
- PUSHFD 386,NOLONG
- PUSHFQ X64
- PUSHFW 8086
- PXOR mmxreg,mmxrm PENT,MMX
- RCL rm8,unity 8086
- RCL rm8,reg_cl 8086
- RCL rm8,imm 186
- RCL rm16,unity 8086
- RCL rm16,reg_cl 8086
- RCL rm16,imm 186
- RCL rm32,unity 386
- RCL rm32,reg_cl 386
- RCL rm32,imm 386
- RCL rm64,unity X64
- RCL rm64,reg_cl X64
- RCL rm64,imm X64
- RCR rm8,unity 8086
- RCR rm8,reg_cl 8086
- RCR rm8,imm 186
- RCR rm16,unity 8086
- RCR rm16,reg_cl 8086
- RCR rm16,imm 186
- RCR rm32,unity 386
- RCR rm32,reg_cl 386
- RCR rm32,imm 386
- RCR rm64,unity X64
- RCR rm64,reg_cl X64
- RCR rm64,imm X64
- RDSHR rm32 P6,CYRIXM
- RDMSR PENT,PRIV
- RDPMC P6
- RDTSC PENT
- RDTSCP X86_64
- RET 8086
- RET imm 8086,SW
- RETF 8086
- RETF imm 8086,SW
- RETN 8086
- RETN imm 8086,SW
- ROL rm8,unity 8086
- ROL rm8,reg_cl 8086
- ROL rm8,imm 186
- ROL rm16,unity 8086
- ROL rm16,reg_cl 8086
- ROL rm16,imm 186
- ROL rm32,unity 386
- ROL rm32,reg_cl 386
- ROL rm32,imm 386
- ROL rm64,unity X64
- ROL rm64,reg_cl X64
- ROL rm64,imm X64
- ROR rm8,unity 8086
- ROR rm8,reg_cl 8086
- ROR rm8,imm 186
- ROR rm16,unity 8086
- ROR rm16,reg_cl 8086
- ROR rm16,imm 186
- ROR rm32,unity 386
- ROR rm32,reg_cl 386
- ROR rm32,imm 386
- ROR rm64,unity X64
- ROR rm64,reg_cl X64
- ROR rm64,imm X64
- RDM P6,CYRIX,ND
- RSDC reg_sreg,mem80 486,CYRIXM
- RSLDT mem80 486,CYRIXM
- RSM PENTM
- RSTS mem80 486,CYRIXM
- SAHF 8086
- SAL rm8,unity 8086,ND
- SAL rm8,reg_cl 8086,ND
- SAL rm8,imm 186,ND
- SAL rm16,unity 8086,ND
- SAL rm16,reg_cl 8086,ND
- SAL rm16,imm 186,ND
- SAL rm32,unity 386,ND
- SAL rm32,reg_cl 386,ND
- SAL rm32,imm 386,ND
- SAL rm64,unity X64,ND
- SAL rm64,reg_cl X64,ND
- SAL rm64,imm X64,ND
- SALC 8086,UNDOC
- SAR rm8,unity 8086
- SAR rm8,reg_cl 8086
- SAR rm8,imm 186
- SAR rm16,unity 8086
- SAR rm16,reg_cl 8086
- SAR rm16,imm 186
- SAR rm32,unity 386
- SAR rm32,reg_cl 386
- SAR rm32,imm 386
- SAR rm64,unity X64
- SAR rm64,reg_cl X64
- SAR rm64,imm X64
- SBB mem,reg8 8086
- SBB reg8,reg8 8086
- SBB mem,reg16 8086
- SBB reg16,reg16 8086
- SBB mem,reg32 386
- SBB reg32,reg32 386
- SBB mem,reg64 X64
- SBB reg64,reg64 X64
- SBB reg8,mem 8086
- SBB reg8,reg8 8086
- SBB reg16,mem 8086
- SBB reg16,reg16 8086
- SBB reg32,mem 386
- SBB reg32,reg32 386
- SBB reg64,mem X64
- SBB reg64,reg64 X64
- SBB rm16,imm8 8086
- SBB rm32,imm8 386
- SBB rm64,imm8 X64
- SBB reg_al,imm 8086
- SBB reg_ax,sbyte16 8086
- SBB reg_ax,imm 8086
- SBB reg_eax,sbyte32 386
- SBB reg_eax,imm 386
- SBB reg_rax,sbyte64 X64
- SBB reg_rax,imm X64
- SBB rm8,imm 8086
- SBB rm16,imm 8086
- SBB rm32,imm 386
- SBB rm64,imm X64
- SBB mem,imm8 8086
- SBB mem,imm16 8086
- SBB mem,imm32 386
- SCASB 8086
- SCASD 386
- SCASQ X64
- SCASW 8086
- SFENCE X64,AMD
- SGDT mem 286
- SHL rm8,unity 8086
- SHL rm8,reg_cl 8086
- SHL rm8,imm 186
- SHL rm16,unity 8086
- SHL rm16,reg_cl 8086
- SHL rm16,imm 186
- SHL rm32,unity 386
- SHL rm32,reg_cl 386
- SHL rm32,imm 386
- SHL rm64,unity X64
- SHL rm64,reg_cl X64
- SHL rm64,imm X64
- SHLD mem,reg16,imm 3862
- SHLD reg16,reg16,imm 3862
- SHLD mem,reg32,imm 3862
- SHLD reg32,reg32,imm 3862
- SHLD mem,reg64,imm X642
- SHLD reg64,reg64,imm X642
- SHLD mem,reg16,reg_cl 386
- SHLD reg16,reg16,reg_cl 386
- SHLD mem,reg32,reg_cl 386
- SHLD reg32,reg32,reg_cl 386
- SHLD mem,reg64,reg_cl X64
- SHLD reg64,reg64,reg_cl X64
- SHR rm8,unity 8086
- SHR rm8,reg_cl 8086
- SHR rm8,imm 186
- SHR rm16,unity 8086
- SHR rm16,reg_cl 8086
- SHR rm16,imm 186
- SHR rm32,unity 386
- SHR rm32,reg_cl 386
- SHR rm32,imm 386
- SHR rm64,unity X64
- SHR rm64,reg_cl X64
- SHR rm64,imm X64
- SHRD mem,reg16,imm 3862
- SHRD reg16,reg16,imm 3862
- SHRD mem,reg32,imm 3862
- SHRD reg32,reg32,imm 3862
- SHRD mem,reg64,imm X642
- SHRD reg64,reg64,imm X642
- SHRD mem,reg16,reg_cl 386
- SHRD reg16,reg16,reg_cl 386
- SHRD mem,reg32,reg_cl 386
- SHRD reg32,reg32,reg_cl 386
- SHRD mem,reg64,reg_cl X64
- SHRD reg64,reg64,reg_cl X64
- SIDT mem 286
- SLDT mem 286
- SLDT mem16 286
- SLDT reg16 286
- SLDT reg32 386
- SLDT reg64 X64,ND
- SLDT reg64 X64
- SKINIT X64
- SMI 386,UNDOC
- SMINT P6,CYRIX,ND
- SMINTOLD 486,CYRIX,ND
- SMSW mem 286
- SMSW mem16 286
- SMSW reg16 286
- SMSW reg32 386
- STC 8086
- STD 8086
- STGI X64
- STI 8086
- STOSB 8086
- STOSD 386
- STOSQ X64
- STOSW 8086
- STR mem 286,PROT
- STR mem16 286,PROT
- STR reg16 286,PROT
- STR reg32 386,PROT
- STR reg64 X64
- SUB mem,reg8 8086
- SUB reg8,reg8 8086
- SUB mem,reg16 8086
- SUB reg16,reg16 8086
- SUB mem,reg32 386
- SUB reg32,reg32 386
- SUB mem,reg64 X64
- SUB reg64,reg64 X64
- SUB reg8,mem 8086
- SUB reg8,reg8 8086
- SUB reg16,mem 8086
- SUB reg16,reg16 8086
- SUB reg32,mem 386
- SUB reg32,reg32 386
- SUB reg64,mem X64
- SUB reg64,reg64 X64
- SUB rm16,imm8 8086
- SUB rm32,imm8 386
- SUB rm64,imm8 X64
- SUB reg_al,imm 8086
- SUB reg_ax,sbyte16 8086
- SUB reg_ax,imm 8086
- SUB reg_eax,sbyte32 386
- SUB reg_eax,imm 386
- SUB reg_rax,sbyte64 X64
- SUB reg_rax,imm X64
- SUB rm8,imm 8086
- SUB rm16,imm 8086
- SUB rm32,imm 386
- SUB rm64,imm X64
- SUB mem,imm8 8086
- SUB mem,imm16 8086
- SUB mem,imm32 386
- SVDC mem80,reg_sreg 486,CYRIXM
- SVLDT mem80 486,CYRIXM,ND
- SVTS mem80 486,CYRIXM
- SWAPGS X64
- SYSCALL P6,AMD
- SYSENTER P6
- SYSEXIT P6,PRIV
- SYSRET P6,PRIV,AMD
- TEST mem,reg8 8086
- TEST reg8,reg8 8086
- TEST mem,reg16 8086
- TEST reg16,reg16 8086
- TEST mem,reg32 386
- TEST reg32,reg32 386
- TEST mem,reg64 X64
- TEST reg64,reg64 X64
- TEST reg8,mem 8086
- TEST reg16,mem 8086
- TEST reg32,mem 386
- TEST reg64,mem X64
- TEST reg_al,imm 8086
- TEST reg_ax,imm 8086
- TEST reg_eax,imm 386
- TEST reg_rax,imm X64
- TEST rm8,imm 8086
- TEST rm16,imm 8086
- TEST rm32,imm 386
- TEST rm64,imm X64
- TEST mem,imm8 8086
- TEST mem,imm16 8086
- TEST mem,imm32 386
- UD0 186,UNDOC
- UD1 186,UNDOC
- UD2B 186,UNDOC,ND
- UD2 186
- UD2A 186,ND
- UMOV mem,reg8 386,UNDOC,ND
- UMOV reg8,reg8 386,UNDOC,ND
- UMOV mem,reg16 386,UNDOC,ND
- UMOV reg16,reg16 386,UNDOC,ND
- UMOV mem,reg32 386,UNDOC,ND
- UMOV reg32,reg32 386,UNDOC,ND
- UMOV reg8,mem 386,UNDOC,ND
- UMOV reg8,reg8 386,UNDOC,ND
- UMOV reg16,mem 386,UNDOC,ND
- UMOV reg16,reg16 386,UNDOC,ND
- UMOV reg32,mem 386,UNDOC,ND
- UMOV reg32,reg32 386,UNDOC,ND
- VERR mem 286,PROT
- VERR mem16 286,PROT
- VERR reg16 286,PROT
- VERW mem 286,PROT
- VERW mem16 286,PROT
- VERW reg16 286,PROT
- FWAIT 8086
- WBINVD 486,PRIV
- WRSHR rm32 P6,CYRIXM
- WRMSR PENT,PRIV
- XADD mem,reg8 486
- XADD reg8,reg8 486
- XADD mem,reg16 486
- XADD reg16,reg16 486
- XADD mem,reg32 486
- XADD reg32,reg32 486
- XADD mem,reg64 X64
- XADD reg64,reg64 X64
- XBTS reg16,mem 386,SW,UNDOC,ND
- XBTS reg16,reg16 386,UNDOC,ND
- XBTS reg32,mem 386,SD,UNDOC,ND
- XBTS reg32,reg32 386,UNDOC,ND
- XCHG reg_ax,reg16 8086
- XCHG reg_eax,reg32na 386
- XCHG reg_rax,reg64 X64
- XCHG reg16,reg_ax 8086
- XCHG reg32na,reg_eax 386
- XCHG reg64,reg_rax X64
- XCHG reg_eax,reg_eax 386,NOLONG
- XCHG reg8,mem 8086
- XCHG reg8,reg8 8086
- XCHG reg16,mem 8086
- XCHG reg16,reg16 8086
- XCHG reg32,mem 386
- XCHG reg32,reg32 386
- XCHG reg64,mem X64
- XCHG reg64,reg64 X64
- XCHG mem,reg8 8086
- XCHG reg8,reg8 8086
- XCHG mem,reg16 8086
- XCHG reg16,reg16 8086
- XCHG mem,reg32 386
- XCHG reg32,reg32 386
- XCHG mem,reg64 X64
- XCHG reg64,reg64 X64
- XLATB 8086
- XLAT 8086
- XOR mem,reg8 8086
- XOR reg8,reg8 8086
- XOR mem,reg16 8086
- XOR reg16,reg16 8086
- XOR mem,reg32 386
- XOR reg32,reg32 386
- XOR mem,reg64 X64
- XOR reg64,reg64 X64
- XOR reg8,mem 8086
- XOR reg8,reg8 8086
- XOR reg16,mem 8086
- XOR reg16,reg16 8086
- XOR reg32,mem 386
- XOR reg32,reg32 386
- XOR reg64,mem X64
- XOR reg64,reg64 X64
- XOR rm16,imm8 8086
- XOR rm32,imm8 386
- XOR rm64,imm8 X64
- XOR reg_al,imm 8086
- XOR reg_ax,sbyte16 8086
- XOR reg_ax,imm 8086
- XOR reg_eax,sbyte32 386
- XOR reg_eax,imm 386
- XOR reg_rax,sbyte64 X64
- XOR reg_rax,imm X64
- XOR rm8,imm 8086
- XOR rm16,imm 8086
- XOR rm32,imm 386
- XOR rm64,imm X64
- XOR mem,imm8 8086
- XOR mem,imm16 8086
- XOR mem,imm32 386
- CMOVcc reg16,mem P6
- CMOVcc reg16,reg16 P6
- CMOVcc reg32,mem P6
- CMOVcc reg32,reg32 P6
- CMOVcc reg64,mem X64
- CMOVcc reg64,reg64 X64
- Jcc imm|near 386
- Jcc imm16|near 386
- Jcc imm32|near 386
- Jcc imm|short 8086,ND
- Jcc imm 8086,ND
- Jcc imm 386,ND
- Jcc imm 8086,ND
- Jcc imm 8086
- SETcc mem 386
- SETcc reg8 386
-
-
-File: nasm.info, Node: Section B.1.3, Next: Section B.1.4, Prev: Section B.1.2, Up: Section B.1
-
-B.1.3. Katmai Streaming SIMD instructions (SSE --- a.k.a. KNI, XMM, MMX2)
--------------------------------------------------------------------------
-
- ADDPS xmmreg,xmmrm KATMAI,SSE
- ADDSS xmmreg,xmmrm KATMAI,SSE,SD
- ANDNPS xmmreg,xmmrm KATMAI,SSE
- ANDPS xmmreg,xmmrm KATMAI,SSE
- CMPEQPS xmmreg,xmmrm KATMAI,SSE
- CMPEQSS xmmreg,xmmrm KATMAI,SSE
- CMPLEPS xmmreg,xmmrm KATMAI,SSE
- CMPLESS xmmreg,xmmrm KATMAI,SSE
- CMPLTPS xmmreg,xmmrm KATMAI,SSE
- CMPLTSS xmmreg,xmmrm KATMAI,SSE
- CMPNEQPS xmmreg,xmmrm KATMAI,SSE
- CMPNEQSS xmmreg,xmmrm KATMAI,SSE
- CMPNLEPS xmmreg,xmmrm KATMAI,SSE
- CMPNLESS xmmreg,xmmrm KATMAI,SSE
- CMPNLTPS xmmreg,xmmrm KATMAI,SSE
- CMPNLTSS xmmreg,xmmrm KATMAI,SSE
- CMPORDPS xmmreg,xmmrm KATMAI,SSE
- CMPORDSS xmmreg,xmmrm KATMAI,SSE
- CMPUNORDPS xmmreg,xmmrm KATMAI,SSE
- CMPUNORDSS xmmreg,xmmrm KATMAI,SSE
- CMPPS xmmreg,mem,imm KATMAI,SSE
- CMPPS xmmreg,xmmreg,imm KATMAI,SSE
- CMPSS xmmreg,mem,imm KATMAI,SSE
- CMPSS xmmreg,xmmreg,imm KATMAI,SSE
- COMISS xmmreg,xmmrm KATMAI,SSE
- CVTPI2PS xmmreg,mmxrm KATMAI,SSE,MMX
- CVTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
- CVTSI2SS xmmreg,mem KATMAI,SSE,SD,AR1,ND
- CVTSI2SS xmmreg,rm32 KATMAI,SSE,SD,AR1
- CVTSI2SS xmmreg,rm64 X64,SSE,AR1
- CVTSS2SI reg32,xmmreg KATMAI,SSE,SD,AR1
- CVTSS2SI reg32,mem KATMAI,SSE,SD,AR1
- CVTSS2SI reg64,xmmreg X64,SSE,SD,AR1
- CVTSS2SI reg64,mem X64,SSE,SD,AR1
- CVTTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
- CVTTSS2SI reg32,xmmrm KATMAI,SSE,SD,AR1
- CVTTSS2SI reg64,xmmrm X64,SSE,SD,AR1
- DIVPS xmmreg,xmmrm KATMAI,SSE
- DIVSS xmmreg,xmmrm KATMAI,SSE
- LDMXCSR mem KATMAI,SSE,SD
- MAXPS xmmreg,xmmrm KATMAI,SSE
- MAXSS xmmreg,xmmrm KATMAI,SSE
- MINPS xmmreg,xmmrm KATMAI,SSE
- MINSS xmmreg,xmmrm KATMAI,SSE
- MOVAPS xmmreg,mem KATMAI,SSE
- MOVAPS mem,xmmreg KATMAI,SSE
- MOVAPS xmmreg,xmmreg KATMAI,SSE
- MOVAPS xmmreg,xmmreg KATMAI,SSE
- MOVHPS xmmreg,mem KATMAI,SSE
- MOVHPS mem,xmmreg KATMAI,SSE
- MOVLHPS xmmreg,xmmreg KATMAI,SSE
- MOVLPS xmmreg,mem KATMAI,SSE
- MOVLPS mem,xmmreg KATMAI,SSE
- MOVHLPS xmmreg,xmmreg KATMAI,SSE
- MOVMSKPS reg32,xmmreg KATMAI,SSE
- MOVMSKPS reg64,xmmreg X64,SSE
- MOVNTPS mem,xmmreg KATMAI,SSE
- MOVSS xmmreg,mem KATMAI,SSE
- MOVSS mem,xmmreg KATMAI,SSE
- MOVSS xmmreg,xmmreg KATMAI,SSE
- MOVSS xmmreg,xmmreg KATMAI,SSE
- MOVUPS xmmreg,mem KATMAI,SSE
- MOVUPS mem,xmmreg KATMAI,SSE
- MOVUPS xmmreg,xmmreg KATMAI,SSE
- MOVUPS xmmreg,xmmreg KATMAI,SSE
- MULPS xmmreg,xmmrm KATMAI,SSE
- MULSS xmmreg,xmmrm KATMAI,SSE
- ORPS xmmreg,xmmrm KATMAI,SSE
- RCPPS xmmreg,xmmrm KATMAI,SSE
- RCPSS xmmreg,xmmrm KATMAI,SSE
- RSQRTPS xmmreg,xmmrm KATMAI,SSE
- RSQRTSS xmmreg,xmmrm KATMAI,SSE
- SHUFPS xmmreg,mem,imm KATMAI,SSE
- SHUFPS xmmreg,xmmreg,imm KATMAI,SSE
- SQRTPS xmmreg,xmmrm KATMAI,SSE
- SQRTSS xmmreg,xmmrm KATMAI,SSE
- STMXCSR mem KATMAI,SSE,SD
- SUBPS xmmreg,xmmrm KATMAI,SSE
- SUBSS xmmreg,xmmrm KATMAI,SSE
- UCOMISS xmmreg,xmmrm KATMAI,SSE
- UNPCKHPS xmmreg,xmmrm KATMAI,SSE
- UNPCKLPS xmmreg,xmmrm KATMAI,SSE
- XORPS xmmreg,xmmrm KATMAI,SSE
-
-
-File: nasm.info, Node: Section B.1.4, Next: Section B.1.5, Prev: Section B.1.3, Up: Section B.1
-
-B.1.4. Introduced in Deschutes but necessary for SSE support
-------------------------------------------------------------
-
- FXRSTOR mem P6,SSE,FPU
- FXSAVE mem P6,SSE,FPU
-
-
-File: nasm.info, Node: Section B.1.5, Next: Section B.1.6, Prev: Section B.1.4, Up: Section B.1
-
-B.1.5. XSAVE group (AVX and extended state)
--------------------------------------------
-
- XGETBV NEHALEM
- XSETBV NEHALEM,PRIV
- XSAVE mem NEHALEM
- XRSTOR mem NEHALEM
-
-
-File: nasm.info, Node: Section B.1.6, Next: Section B.1.7, Prev: Section B.1.5, Up: Section B.1
-
-B.1.6. Generic memory operations
---------------------------------
-
- PREFETCHNTA mem KATMAI
- PREFETCHT0 mem KATMAI
- PREFETCHT1 mem KATMAI
- PREFETCHT2 mem KATMAI
- SFENCE KATMAI
-
-
-File: nasm.info, Node: Section B.1.7, Next: Section B.1.8, Prev: Section B.1.6, Up: Section B.1
-
-B.1.7. New MMX instructions introduced in Katmai
-------------------------------------------------
-
- MASKMOVQ mmxreg,mmxreg KATMAI,MMX
- MOVNTQ mem,mmxreg KATMAI,MMX
- PAVGB mmxreg,mmxrm KATMAI,MMX
- PAVGW mmxreg,mmxrm KATMAI,MMX
- PEXTRW reg32,mmxreg,imm KATMAI,MMX
- PINSRW mmxreg,mem,imm KATMAI,MMX
- PINSRW mmxreg,rm16,imm KATMAI,MMX
- PINSRW mmxreg,reg32,imm KATMAI,MMX
- PMAXSW mmxreg,mmxrm KATMAI,MMX
- PMAXUB mmxreg,mmxrm KATMAI,MMX
- PMINSW mmxreg,mmxrm KATMAI,MMX
- PMINUB mmxreg,mmxrm KATMAI,MMX
- PMOVMSKB reg32,mmxreg KATMAI,MMX
- PMULHUW mmxreg,mmxrm KATMAI,MMX
- PSADBW mmxreg,mmxrm KATMAI,MMX
- PSHUFW mmxreg,mmxrm,imm KATMAI,MMX2
-
-
-File: nasm.info, Node: Section B.1.8, Next: Section B.1.9, Prev: Section B.1.7, Up: Section B.1
-
-B.1.8. AMD Enhanced 3DNow! (Athlon) instructions
-------------------------------------------------
-
- PF2IW mmxreg,mmxrm PENT,3DNOW
- PFNACC mmxreg,mmxrm PENT,3DNOW
- PFPNACC mmxreg,mmxrm PENT,3DNOW
- PI2FW mmxreg,mmxrm PENT,3DNOW
- PSWAPD mmxreg,mmxrm PENT,3DNOW
-
-
-File: nasm.info, Node: Section B.1.9, Next: Section B.1.10, Prev: Section B.1.8, Up: Section B.1
-
-B.1.9. Willamette SSE2 Cacheability Instructions
-------------------------------------------------
-
- MASKMOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
- CLFLUSH mem WILLAMETTE,SSE2
- MOVNTDQ mem,xmmreg WILLAMETTE,SSE2,SO
- MOVNTI mem,reg32 WILLAMETTE,SD
- MOVNTI mem,reg64 X64
- MOVNTPD mem,xmmreg WILLAMETTE,SSE2,SO
- LFENCE WILLAMETTE,SSE2
- MFENCE WILLAMETTE,SSE2
-
-
-File: nasm.info, Node: Section B.1.10, Next: Section B.1.11, Prev: Section B.1.9, Up: Section B.1
-
-B.1.10. Willamette MMX instructions (SSE2 SIMD Integer Instructions)
---------------------------------------------------------------------
-
- MOVD mem,xmmreg WILLAMETTE,SSE2,SD
- MOVD xmmreg,mem WILLAMETTE,SSE2,SD
- MOVD xmmreg,rm32 WILLAMETTE,SSE2
- MOVD rm32,xmmreg WILLAMETTE,SSE2
- MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQA mem,xmmreg WILLAMETTE,SSE2,SO
- MOVDQA xmmreg,mem WILLAMETTE,SSE2,SO
- MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQU mem,xmmreg WILLAMETTE,SSE2,SO
- MOVDQU xmmreg,mem WILLAMETTE,SSE2,SO
- MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQ2Q mmxreg,xmmreg WILLAMETTE,SSE2
- MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
- MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
- MOVQ mem,xmmreg WILLAMETTE,SSE2
- MOVQ xmmreg,mem WILLAMETTE,SSE2
- MOVQ xmmreg,rm64 X64,SSE2
- MOVQ rm64,xmmreg X64,SSE2
- MOVQ2DQ xmmreg,mmxreg WILLAMETTE,SSE2
- PACKSSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PACKSSDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PACKUSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDQ mmxreg,mmxrm WILLAMETTE,MMX
- PADDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PAND xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PANDN xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PAVGB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PAVGW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPEQB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPEQW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPEQD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPGTB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPGTW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPGTD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PEXTRW reg32,xmmreg,imm WILLAMETTE,SSE2
- PINSRW xmmreg,reg16,imm WILLAMETTE,SSE2
- PINSRW xmmreg,reg32,imm WILLAMETTE,SSE2,ND
- PINSRW xmmreg,mem,imm WILLAMETTE,SSE2
- PINSRW xmmreg,mem16,imm WILLAMETTE,SSE2
- PMADDWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMAXSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMAXUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMINSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMINUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMOVMSKB reg32,xmmreg WILLAMETTE,SSE2
- PMULHUW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMULHW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMULLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMULUDQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
- PMULUDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- POR xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSADBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSHUFD xmmreg,xmmreg,imm WILLAMETTE,SSE2
- PSHUFD xmmreg,mem,imm WILLAMETTE,SSE22
- PSHUFHW xmmreg,xmmreg,imm WILLAMETTE,SSE2
- PSHUFHW xmmreg,mem,imm WILLAMETTE,SSE22
- PSHUFLW xmmreg,xmmreg,imm WILLAMETTE,SSE2
- PSHUFLW xmmreg,mem,imm WILLAMETTE,SSE22
- PSLLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSLLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSLLW xmmreg,imm WILLAMETTE,SSE2,AR1
- PSLLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSLLD xmmreg,imm WILLAMETTE,SSE2,AR1
- PSLLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSLLQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRAW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRAW xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRAD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRAD xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRLW xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRLD xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRLQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSUBB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
- PSUBQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PXOR xmmreg,xmmrm WILLAMETTE,SSE2,SO
-
-
-File: nasm.info, Node: Section B.1.11, Next: Section B.1.12, Prev: Section B.1.10, Up: Section B.1
-
-B.1.11. Willamette Streaming SIMD instructions (SSE2)
------------------------------------------------------
-
- ADDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- ADDSD xmmreg,xmmrm WILLAMETTE,SSE2
- ANDNPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- ANDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPEQSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPLESD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPLTSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPNEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPNEQSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPNLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPNLESD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPNLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPNLTSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPORDSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPUNORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPUNORDSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPPD xmmreg,xmmrm,imm WILLAMETTE,SSE22
- CMPSD xmmreg,xmmrm,imm WILLAMETTE,SSE2
- COMISD xmmreg,xmmrm WILLAMETTE,SSE2
- CVTDQ2PD xmmreg,xmmrm WILLAMETTE,SSE2
- CVTDQ2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPD2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPI2PD xmmreg,mmxrm WILLAMETTE,SSE2
- CVTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPS2PD xmmreg,xmmrm WILLAMETTE,SSE2
- CVTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
- CVTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
- CVTSD2SI reg64,xmmreg X64,SSE2,AR1
- CVTSD2SI reg64,mem X64,SSE2,AR1
- CVTSD2SS xmmreg,xmmrm WILLAMETTE,SSE2
- CVTSI2SD xmmreg,mem WILLAMETTE,SSE2,SD,AR1,ND
- CVTSI2SD xmmreg,rm32 WILLAMETTE,SSE2,SD,AR1
- CVTSI2SD xmmreg,rm64 X64,SSE2,AR1
- CVTSS2SD xmmreg,xmmrm WILLAMETTE,SSE2,SD
- CVTTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
- CVTTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
- CVTTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
- CVTTSD2SI reg64,xmmreg X64,SSE2,AR1
- CVTTSD2SI reg64,mem X64,SSE2,AR1
- DIVPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- DIVSD xmmreg,xmmrm WILLAMETTE,SSE2
- MAXPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- MAXSD xmmreg,xmmrm WILLAMETTE,SSE2
- MINPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- MINSD xmmreg,xmmrm WILLAMETTE,SSE2
- MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVAPD mem,xmmreg WILLAMETTE,SSE2,SO
- MOVAPD xmmreg,mem WILLAMETTE,SSE2,SO
- MOVHPD mem,xmmreg WILLAMETTE,SSE2
- MOVHPD xmmreg,mem WILLAMETTE,SSE2
- MOVLPD mem,xmmreg WILLAMETTE,SSE2
- MOVLPD xmmreg,mem WILLAMETTE,SSE2
- MOVMSKPD reg32,xmmreg WILLAMETTE,SSE2
- MOVMSKPD reg64,xmmreg X64,SSE2
- MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVSD mem,xmmreg WILLAMETTE,SSE2
- MOVSD xmmreg,mem WILLAMETTE,SSE2
- MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVUPD mem,xmmreg WILLAMETTE,SSE2,SO
- MOVUPD xmmreg,mem WILLAMETTE,SSE2,SO
- MULPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- MULSD xmmreg,xmmrm WILLAMETTE,SSE2
- ORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- SHUFPD xmmreg,xmmreg,imm WILLAMETTE,SSE2
- SHUFPD xmmreg,mem,imm WILLAMETTE,SSE2
- SQRTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- SQRTSD xmmreg,xmmrm WILLAMETTE,SSE2
- SUBPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- SUBSD xmmreg,xmmrm WILLAMETTE,SSE2
- UCOMISD xmmreg,xmmrm WILLAMETTE,SSE2
- UNPCKHPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- UNPCKLPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- XORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-
-
-File: nasm.info, Node: Section B.1.12, Next: Section B.1.13, Prev: Section B.1.11, Up: Section B.1
-
-B.1.12. Prescott New Instructions (SSE3)
-----------------------------------------
-
- ADDSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
- ADDSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
- HADDPD xmmreg,xmmrm PRESCOTT,SSE3,SO
- HADDPS xmmreg,xmmrm PRESCOTT,SSE3,SO
- HSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
- HSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
- LDDQU xmmreg,mem PRESCOTT,SSE3,SO
- MOVDDUP xmmreg,xmmrm PRESCOTT,SSE3
- MOVSHDUP xmmreg,xmmrm PRESCOTT,SSE3
- MOVSLDUP xmmreg,xmmrm PRESCOTT,SSE3
-
-
-File: nasm.info, Node: Section B.1.13, Next: Section B.1.14, Prev: Section B.1.12, Up: Section B.1
-
-B.1.13. VMX Instructions
-------------------------
-
- VMCALL VMX
- VMCLEAR mem VMX
- VMLAUNCH VMX
- VMLOAD X64,VMX
- VMMCALL X64,VMX
- VMPTRLD mem VMX
- VMPTRST mem VMX
- VMREAD rm32,reg32 VMX,NOLONG,SD
- VMREAD rm64,reg64 X64,VMX
- VMRESUME VMX
- VMRUN X64,VMX
- VMSAVE X64,VMX
- VMWRITE reg32,rm32 VMX,NOLONG,SD
- VMWRITE reg64,rm64 X64,VMX
- VMXOFF VMX
- VMXON mem VMX
-
-
-File: nasm.info, Node: Section B.1.14, Next: Section B.1.15, Prev: Section B.1.13, Up: Section B.1
-
-B.1.14. Extended Page Tables VMX instructions
----------------------------------------------
-
- INVEPT reg32,mem VMX,SO,NOLONG
- INVEPT reg64,mem VMX,SO,LONG
- INVVPID reg32,mem VMX,SO,NOLONG
- INVVPID reg64,mem VMX,SO,LONG
-
-
-File: nasm.info, Node: Section B.1.15, Next: Section B.1.16, Prev: Section B.1.14, Up: Section B.1
-
-B.1.15. Tejas New Instructions (SSSE3)
---------------------------------------
-
- PABSB mmxreg,mmxrm SSSE3,MMX
- PABSB xmmreg,xmmrm SSSE3
- PABSW mmxreg,mmxrm SSSE3,MMX
- PABSW xmmreg,xmmrm SSSE3
- PABSD mmxreg,mmxrm SSSE3,MMX
- PABSD xmmreg,xmmrm SSSE3
- PALIGNR mmxreg,mmxrm,imm SSSE3,MMX
- PALIGNR xmmreg,xmmrm,imm SSSE3
- PHADDW mmxreg,mmxrm SSSE3,MMX
- PHADDW xmmreg,xmmrm SSSE3
- PHADDD mmxreg,mmxrm SSSE3,MMX
- PHADDD xmmreg,xmmrm SSSE3
- PHADDSW mmxreg,mmxrm SSSE3,MMX
- PHADDSW xmmreg,xmmrm SSSE3
- PHSUBW mmxreg,mmxrm SSSE3,MMX
- PHSUBW xmmreg,xmmrm SSSE3
- PHSUBD mmxreg,mmxrm SSSE3,MMX
- PHSUBD xmmreg,xmmrm SSSE3
- PHSUBSW mmxreg,mmxrm SSSE3,MMX
- PHSUBSW xmmreg,xmmrm SSSE3
- PMADDUBSW mmxreg,mmxrm SSSE3,MMX
- PMADDUBSW xmmreg,xmmrm SSSE3
- PMULHRSW mmxreg,mmxrm SSSE3,MMX
- PMULHRSW xmmreg,xmmrm SSSE3
- PSHUFB mmxreg,mmxrm SSSE3,MMX
- PSHUFB xmmreg,xmmrm SSSE3
- PSIGNB mmxreg,mmxrm SSSE3,MMX
- PSIGNB xmmreg,xmmrm SSSE3
- PSIGNW mmxreg,mmxrm SSSE3,MMX
- PSIGNW xmmreg,xmmrm SSSE3
- PSIGND mmxreg,mmxrm SSSE3,MMX
- PSIGND xmmreg,xmmrm SSSE3
-
-
-File: nasm.info, Node: Section B.1.16, Next: Section B.1.17, Prev: Section B.1.15, Up: Section B.1
-
-B.1.16. AMD SSE4A
------------------
-
- EXTRQ xmmreg,imm,imm SSE4A,AMD
- EXTRQ xmmreg,xmmreg SSE4A,AMD
- INSERTQ xmmreg,xmmreg,imm,imm SSE4A,AMD
- INSERTQ xmmreg,xmmreg SSE4A,AMD
- MOVNTSD mem,xmmreg SSE4A,AMD
- MOVNTSS mem,xmmreg SSE4A,AMD,SD
-
-
-File: nasm.info, Node: Section B.1.17, Next: Section B.1.18, Prev: Section B.1.16, Up: Section B.1
-
-B.1.17. New instructions in Barcelona
--------------------------------------
-
- LZCNT reg16,rm16 P6,AMD
- LZCNT reg32,rm32 P6,AMD
- LZCNT reg64,rm64 X64,AMD
-
-
-File: nasm.info, Node: Section B.1.18, Next: Section B.1.19, Prev: Section B.1.17, Up: Section B.1
-
-B.1.18. Penryn New Instructions (SSE4.1)
-----------------------------------------
-
- BLENDPD xmmreg,xmmrm,imm SSE41
- BLENDPS xmmreg,xmmrm,imm SSE41
- BLENDVPD xmmreg,xmmrm,xmm0 SSE41
- BLENDVPS xmmreg,xmmrm,xmm0 SSE41
- DPPD xmmreg,xmmrm,imm SSE41
- DPPS xmmreg,xmmrm,imm SSE41
- EXTRACTPS rm32,xmmreg,imm SSE41
- EXTRACTPS reg64,xmmreg,imm SSE41,X64
- INSERTPS xmmreg,xmmrm,imm SSE41,SD
- MOVNTDQA xmmreg,mem SSE41
- MPSADBW xmmreg,xmmrm,imm SSE41
- PACKUSDW xmmreg,xmmrm SSE41
- PBLENDVB xmmreg,xmmrm,xmm0 SSE41
- PBLENDW xmmreg,xmmrm,imm SSE41
- PCMPEQQ xmmreg,xmmrm SSE41
- PEXTRB reg32,xmmreg,imm SSE41
- PEXTRB mem8,xmmreg,imm SSE41
- PEXTRB reg64,xmmreg,imm SSE41,X64
- PEXTRD rm32,xmmreg,imm SSE41
- PEXTRQ rm64,xmmreg,imm SSE41,X64
- PEXTRW reg32,xmmreg,imm SSE41
- PEXTRW mem16,xmmreg,imm SSE41
- PEXTRW reg64,xmmreg,imm SSE41,X64
- PHMINPOSUW xmmreg,xmmrm SSE41
- PINSRB xmmreg,mem,imm SSE41
- PINSRB xmmreg,rm8,imm SSE41
- PINSRB xmmreg,reg32,imm SSE41
- PINSRD xmmreg,mem,imm SSE41
- PINSRD xmmreg,rm32,imm SSE41
- PINSRQ xmmreg,mem,imm SSE41,X64
- PINSRQ xmmreg,rm64,imm SSE41,X64
- PMAXSB xmmreg,xmmrm SSE41
- PMAXSD xmmreg,xmmrm SSE41
- PMAXUD xmmreg,xmmrm SSE41
- PMAXUW xmmreg,xmmrm SSE41
- PMINSB xmmreg,xmmrm SSE41
- PMINSD xmmreg,xmmrm SSE41
- PMINUD xmmreg,xmmrm SSE41
- PMINUW xmmreg,xmmrm SSE41
- PMOVSXBW xmmreg,xmmrm SSE41
- PMOVSXBD xmmreg,xmmrm SSE41,SD
- PMOVSXBQ xmmreg,xmmrm SSE41,SW
- PMOVSXWD xmmreg,xmmrm SSE41
- PMOVSXWQ xmmreg,xmmrm SSE41,SD
- PMOVSXDQ xmmreg,xmmrm SSE41
- PMOVZXBW xmmreg,xmmrm SSE41
- PMOVZXBD xmmreg,xmmrm SSE41,SD
- PMOVZXBQ xmmreg,xmmrm SSE41,SW
- PMOVZXWD xmmreg,xmmrm SSE41
- PMOVZXWQ xmmreg,xmmrm SSE41,SD
- PMOVZXDQ xmmreg,xmmrm SSE41
- PMULDQ xmmreg,xmmrm SSE41
- PMULLD xmmreg,xmmrm SSE41
- PTEST xmmreg,xmmrm SSE41
- ROUNDPD xmmreg,xmmrm,imm SSE41
- ROUNDPS xmmreg,xmmrm,imm SSE41
- ROUNDSD xmmreg,xmmrm,imm SSE41
- ROUNDSS xmmreg,xmmrm,imm SSE41
-
-
-File: nasm.info, Node: Section B.1.19, Next: Section B.1.20, Prev: Section B.1.18, Up: Section B.1
-
-B.1.19. Nehalem New Instructions (SSE4.2)
------------------------------------------
-
- CRC32 reg32,rm8 SSE42
- CRC32 reg32,rm16 SSE42
- CRC32 reg32,rm32 SSE42
- CRC32 reg64,rm8 SSE42,X64
- CRC32 reg64,rm64 SSE42,X64
- PCMPESTRI xmmreg,xmmrm,imm SSE42
- PCMPESTRM xmmreg,xmmrm,imm SSE42
- PCMPISTRI xmmreg,xmmrm,imm SSE42
- PCMPISTRM xmmreg,xmmrm,imm SSE42
- PCMPGTQ xmmreg,xmmrm SSE42
- POPCNT reg16,rm16 NEHALEM,SW
- POPCNT reg32,rm32 NEHALEM,SD
- POPCNT reg64,rm64 NEHALEM,X64
-
-
-File: nasm.info, Node: Section B.1.20, Next: Section B.1.21, Prev: Section B.1.19, Up: Section B.1
-
-B.1.20. Intel SMX
------------------
-
- GETSEC KATMAI
-
-
-File: nasm.info, Node: Section B.1.21, Next: Section B.1.22, Prev: Section B.1.20, Up: Section B.1
-
-B.1.21. Geode (Cyrix) 3DNow! additions
---------------------------------------
-
- PFRCPV mmxreg,mmxrm PENT,3DNOW,CYRIX
- PFRSQRTV mmxreg,mmxrm PENT,3DNOW,CYRIX
-
-
-File: nasm.info, Node: Section B.1.22, Next: Section B.1.23, Prev: Section B.1.21, Up: Section B.1
-
-B.1.22. Intel new instructions in ???
--------------------------------------
-
- MOVBE reg16,mem16 NEHALEM
- MOVBE reg32,mem32 NEHALEM
- MOVBE reg64,mem64 NEHALEM
- MOVBE mem16,reg16 NEHALEM
- MOVBE mem32,reg32 NEHALEM
- MOVBE mem64,reg64 NEHALEM
-
-
-File: nasm.info, Node: Section B.1.23, Next: Section B.1.24, Prev: Section B.1.22, Up: Section B.1
-
-B.1.23. Intel AES instructions
-------------------------------
-
- AESENC xmmreg,xmmrm128 SSE,WESTMERE
- AESENCLAST xmmreg,xmmrm128 SSE,WESTMERE
- AESDEC xmmreg,xmmrm128 SSE,WESTMERE
- AESDECLAST xmmreg,xmmrm128 SSE,WESTMERE
- AESIMC xmmreg,xmmrm128 SSE,WESTMERE
- AESKEYGENASSIST xmmreg,xmmrm128,imm8 SSE,WESTMERE
-
-
-File: nasm.info, Node: Section B.1.24, Next: Section B.1.25, Prev: Section B.1.23, Up: Section B.1
-
-B.1.24. Intel AVX AES instructions
-----------------------------------
-
- VAESENC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESENCLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESDEC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESDECLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESIMC xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VAESKEYGENASSIST xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-
-
-File: nasm.info, Node: Section B.1.25, Next: Section B.1.26, Prev: Section B.1.24, Up: Section B.1
-
-B.1.25. Intel AVX instructions
-------------------------------
-
- VADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VADDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VADDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VADDSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VADDSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDNPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDNPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDNPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDNPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VBLENDPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VBLENDPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VBLENDPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VBLENDPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VBLENDVPD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VBLENDVPD xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
- VBLENDVPD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
- VBLENDVPS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VBLENDVPS xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
- VBLENDVPS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
- VBROADCASTSS xmmreg,mem32 AVX,SANDYBRIDGE
- VBROADCASTSS ymmreg,mem32 AVX,SANDYBRIDGE
- VBROADCASTSD ymmreg,mem64 AVX,SANDYBRIDGE
- VBROADCASTF128 ymmreg,mem128 AVX,SANDYBRIDGE
- VCMPEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSE_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSE_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUE_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUE_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VCMPPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VCMPEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSE_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSE_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUE_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUE_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VCMPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VCMPEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPUNORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPEQ_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPFALSESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQ_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPTRUESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPUNORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPFALSE_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPTRUE_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
- VCMPEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPUNORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPEQ_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPFALSESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQ_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPTRUESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPUNORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPFALSE_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPTRUE_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
- VCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VCVTDQ2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VCVTDQ2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTDQ2PS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTDQ2PS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VCVTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
- VCVTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
- VCVTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
- VCVTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
- VCVTPD2PS xmmreg,xmmreg AVX,SANDYBRIDGE
- VCVTPD2PS xmmreg,mem128 AVX,SANDYBRIDGE,SO
- VCVTPD2PS xmmreg,ymmreg AVX,SANDYBRIDGE
- VCVTPD2PS xmmreg,mem256 AVX,SANDYBRIDGE,SY
- VCVTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VCVTPS2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VCVTPS2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
- VCVTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
- VCVTSD2SS xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCVTSI2SD xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
- VCVTSI2SD xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
- VCVTSI2SD xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
- VCVTSI2SS xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
- VCVTSI2SS xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
- VCVTSI2SS xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
- VCVTSS2SD xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCVTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
- VCVTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
- VCVTTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
- VCVTTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
- VCVTTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
- VCVTTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
- VCVTTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VCVTTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
- VCVTTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
- VCVTTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
- VCVTTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
- VDIVPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VDIVPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VDIVPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VDIVPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VDIVSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VDIVSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VDPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VDPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VDPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VEXTRACTF128 xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
- VEXTRACTPS rm32,xmmreg,imm8 AVX,SANDYBRIDGE
- VHADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VHADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VHSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VHSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VINSERTF128 ymmreg,ymmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VINSERTPS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
- VLDDQU xmmreg,mem128 AVX,SANDYBRIDGE
- VLDQQU ymmreg,mem256 AVX,SANDYBRIDGE
- VLDDQU ymmreg,mem256 AVX,SANDYBRIDGE
- VLDMXCSR mem32 AVX,SANDYBRIDGE
- VMASKMOVDQU xmmreg,xmmreg AVX,SANDYBRIDGE
- VMASKMOVPS xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
- VMASKMOVPS ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
- VMASKMOVPS mem128,xmmreg,xmmreg AVX,SANDYBRIDGE,SO
- VMASKMOVPS mem256,xmmreg,xmmreg AVX,SANDYBRIDGE,SY
- VMASKMOVPD xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
- VMASKMOVPD ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
- VMASKMOVPD mem128,xmmreg,xmmreg AVX,SANDYBRIDGE
- VMASKMOVPD mem256,ymmreg,ymmreg AVX,SANDYBRIDGE
- VMAXPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMAXPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMAXPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMAXPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMAXSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VMAXSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VMINPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMINPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMINPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMINPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMINSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VMINSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VMOVAPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVAPD xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVAPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVAPD ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVAPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVAPS xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVAPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVAPS ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VMOVQ xmmrm64,xmmreg AVX,SANDYBRIDGE
- VMOVQ xmmreg,rm64 AVX,SANDYBRIDGE,LONG
- VMOVQ rm64,xmmreg AVX,SANDYBRIDGE,LONG
- VMOVD xmmreg,rm32 AVX,SANDYBRIDGE
- VMOVD rm32,xmmreg AVX,SANDYBRIDGE
- VMOVDDUP xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VMOVDDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVDQA xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVDQA xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVQQA ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVQQA ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVDQA ymmreg,ymmrm AVX,SANDYBRIDGE
- VMOVDQA ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVDQU xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVDQU xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVQQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVQQU ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVDQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVDQU ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVHLPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVHPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVHPD mem64,xmmreg AVX,SANDYBRIDGE
- VMOVHPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVHPS mem64,xmmreg AVX,SANDYBRIDGE
- VMOVLHPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVLPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVLPD mem64,xmmreg AVX,SANDYBRIDGE
- VMOVLPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVLPS mem64,xmmreg AVX,SANDYBRIDGE
- VMOVMSKPD reg64,xmmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPD reg32,xmmreg AVX,SANDYBRIDGE
- VMOVMSKPD reg64,ymmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPD reg32,ymmreg AVX,SANDYBRIDGE
- VMOVMSKPS reg64,xmmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPS reg32,xmmreg AVX,SANDYBRIDGE
- VMOVMSKPS reg64,ymmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPS reg32,ymmreg AVX,SANDYBRIDGE
- VMOVNTDQ mem128,xmmreg AVX,SANDYBRIDGE
- VMOVNTQQ mem256,ymmreg AVX,SANDYBRIDGE
- VMOVNTDQ mem256,ymmreg AVX,SANDYBRIDGE
- VMOVNTDQA xmmreg,mem128 AVX,SANDYBRIDGE
- VMOVNTPD mem128,xmmreg AVX,SANDYBRIDGE
- VMOVNTPD mem256,ymmreg AVX,SANDYBRIDGE
- VMOVNTPS mem128,xmmreg AVX,SANDYBRIDGE
- VMOVNTPS mem128,ymmreg AVX,SANDYBRIDGE
- VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSD xmmreg,mem64 AVX,SANDYBRIDGE
- VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSD mem64,xmmreg AVX,SANDYBRIDGE
- VMOVSHDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVSHDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVSLDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVSLDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSS xmmreg,mem64 AVX,SANDYBRIDGE
- VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSS mem64,xmmreg AVX,SANDYBRIDGE
- VMOVUPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVUPD xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVUPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVUPD ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVUPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVUPS xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVUPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVUPS ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMPSADBW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VMULPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMULPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMULPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMULPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMULSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VMULSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VPABSB xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPABSW xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPABSD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPACKSSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPACKSSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPACKUSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPACKUSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPALIGNR xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPAND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPANDN xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPAVGB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPAVGW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPBLENDVB xmmreg,xmmreg*,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPBLENDW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPESTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPESTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPISTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPISTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPEQB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPEQW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPEQD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPEQQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPERMILPD xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILPD ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMILPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERMILTD2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILTD2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILTD2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILTD2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMO2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMO2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMO2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMO2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMZ2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMZ2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMZ2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMZ2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMIL2PD xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PD xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMIL2PD ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PD ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERMILPS xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILPS ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMILPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERMILTD2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILTD2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILTD2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILTD2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMO2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMO2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMO2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMO2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMZ2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMZ2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMZ2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMZ2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMIL2PS xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PS xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMIL2PS ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PS ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERM2F128 ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPEXTRB reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRB reg32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRB mem8,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRD reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRD rm32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRQ rm64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPHADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHMINPOSUW xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPHSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPINSRB xmmreg,xmmreg*,mem8,imm8 AVX,SANDYBRIDGE
- VPINSRB xmmreg,xmmreg*,rm8,imm8 AVX,SANDYBRIDGE
- VPINSRB xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
- VPINSRW xmmreg,xmmreg*,mem16,imm8 AVX,SANDYBRIDGE
- VPINSRW xmmreg,xmmreg*,rm16,imm8 AVX,SANDYBRIDGE
- VPINSRW xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
- VPINSRD xmmreg,xmmreg*,mem32,imm8 AVX,SANDYBRIDGE
- VPINSRD xmmreg,xmmreg*,rm32,imm8 AVX,SANDYBRIDGE
- VPINSRQ xmmreg,xmmreg*,mem64,imm8 AVX,SANDYBRIDGE,LONG
- VPINSRQ xmmreg,xmmreg*,rm64,imm8 AVX,SANDYBRIDGE,LONG
- VPMADDWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMADDUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMOVMSKB reg64,xmmreg AVX,SANDYBRIDGE,LONG
- VPMOVMSKB reg32,xmmreg AVX,SANDYBRIDGE
- VPMOVSXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVSXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVSXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
- VPMOVSXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVSXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVSXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVZXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVZXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVZXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
- VPMOVZXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVZXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVZXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMULHUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULHRSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULHW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULUDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSADBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSHUFB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSHUFD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPSHUFHW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPSHUFLW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPSIGNB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSIGNW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSIGND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSLLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSLLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSLLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRAW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRAW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRAD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRAD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPTEST xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPTEST ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPSUBB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPXOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VRCPPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VRCPPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VRCPSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VRSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VRSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VRSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VROUNDPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VROUNDPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VROUNDPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VROUNDPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VROUNDSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
- VROUNDSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
- VSHUFPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VSHUFPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VSHUFPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VSHUFPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VSQRTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VSQRTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VSQRTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VSTMXCSR mem32 AVX,SANDYBRIDGE
- VSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VSUBSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VSUBSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VTESTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VTESTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VTESTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VTESTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VUCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VUCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VUNPCKHPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKHPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VUNPCKHPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKHPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VUNPCKLPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKLPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VUNPCKLPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKLPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VXORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VXORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VXORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VXORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VZEROALL AVX,SANDYBRIDGE
- VZEROUPPER AVX,SANDYBRIDGE
-
-
-File: nasm.info, Node: Section B.1.26, Next: Section B.1.27, Prev: Section B.1.25, Up: Section B.1
-
-B.1.26. Intel Carry-Less Multiplication instructions (CLMUL)
-------------------------------------------------------------
-
- PCLMULLQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULHQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULLQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULHQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULQDQ xmmreg,xmmrm128,imm8 SSE,WESTMERE
-
-
-File: nasm.info, Node: Section B.1.27, Next: Section B.1.28, Prev: Section B.1.26, Up: Section B.1
-
-B.1.27. Intel AVX Carry-Less Multiplication instructions (CLMUL)
-----------------------------------------------------------------
-
- VPCLMULLQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULHQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULLQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULHQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULQDQ xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-
-
-File: nasm.info, Node: Section B.1.28, Next: Section B.1.29, Prev: Section B.1.27, Up: Section B.1
-
-B.1.28. Intel Fused Multiply-Add instructions (FMA)
----------------------------------------------------
-
- VFMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-
-
-File: nasm.info, Node: Section B.1.29, Next: Section B.1.30, Prev: Section B.1.28, Up: Section B.1
-
-B.1.29. VIA (Centaur) security instructions
--------------------------------------------
-
- XSTORE PENT,CYRIX
- XCRYPTECB PENT,CYRIX
- XCRYPTCBC PENT,CYRIX
- XCRYPTCTR PENT,CYRIX
- XCRYPTCFB PENT,CYRIX
- XCRYPTOFB PENT,CYRIX
- MONTMUL PENT,CYRIX
- XSHA1 PENT,CYRIX
- XSHA256 PENT,CYRIX
-
-
-File: nasm.info, Node: Section B.1.30, Next: Section B.1.31, Prev: Section B.1.29, Up: Section B.1
-
-B.1.30. AMD Lightweight Profiling (LWP) instructions
-----------------------------------------------------
-
- LLWPCB reg16 AMD
- LLWPCB reg32 AMD,386
- LLWPCB reg64 AMD,X64
- SLWPCB reg16 AMD
- SLWPCB reg32 AMD,386
- SLWPCB reg64 AMD,X64
- LWPVAL reg16,rm32,imm16 AMD,386
- LWPVAL reg32,rm32,imm32 AMD,386
- LWPVAL reg64,rm32,imm32 AMD,X64
- LWPINS reg16,rm32,imm16 AMD,386
- LWPINS reg32,rm32,imm32 AMD,386
- LWPINS reg64,rm32,imm32 AMD,X64
-
-
-File: nasm.info, Node: Section B.1.31, Next: Section B.1.32, Prev: Section B.1.30, Up: Section B.1
-
-B.1.31. AMD XOP, FMA4 and CVT16 instructions (SSE5)
----------------------------------------------------
-
- VCVTPH2PS xmmreg,xmmrm64*,imm8 AMD,SSE5
- VCVTPH2PS ymmreg,xmmrm128,imm8 AMD,SSE5
- VCVTPH2PS ymmreg,ymmrm128*,imm8 AMD,SSE5
- VCVTPS2PH xmmrm64,xmmreg*,imm8 AMD,SSE5
- VCVTPS2PH xmmrm128,ymmreg,imm8 AMD,SSE5
- VCVTPS2PH ymmrm128,ymmreg*,imm8 AMD,SSE5
- VFMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFMADDSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMADDSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFNMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFNMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFNMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFNMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFNMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFNMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFNMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFNMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFRCZPD xmmreg,xmmrm128* AMD,SSE5
- VFRCZPD ymmreg,ymmrm256* AMD,SSE5
- VFRCZPS xmmreg,xmmrm128* AMD,SSE5
- VFRCZPS ymmreg,ymmrm256* AMD,SSE5
- VFRCZSD xmmreg,xmmrm64* AMD,SSE5
- VFRCZSS xmmreg,xmmrm32* AMD,SSE5
- VPCMOV xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPCMOV ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VPCMOV xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VPCMOV ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VPCOMB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPHADDBD xmmreg,xmmrm128* AMD,SSE5
- VPHADDBQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDBW xmmreg,xmmrm128* AMD,SSE5
- VPHADDDQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDUBD xmmreg,xmmrm128* AMD,SSE5
- VPHADDUBQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDUBW xmmreg,xmmrm128* AMD,SSE5
- VPHADDUDQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDUWD xmmreg,xmmrm128* AMD,SSE5
- VPHADDUWQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDWD xmmreg,xmmrm128* AMD,SSE5
- VPHADDWQ xmmreg,xmmrm128* AMD,SSE5
- VPHSUBBW xmmreg,xmmrm128* AMD,SSE5
- VPHSUBDQ xmmreg,xmmrm128* AMD,SSE5
- VPHSUBWD xmmreg,xmmrm128* AMD,SSE5
- VPMACSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMADCSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMADCSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPPERM xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VPPERM xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPROTB xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTB xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPROTD xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTD xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPROTQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTQ xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPROTW xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTW xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPSHAB xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHAD xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHAQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHAW xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLB xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLD xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLW xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-
-
-File: nasm.info, Node: Section B.1.32, Next: Appendix C, Prev: Section B.1.31, Up: Section B.1
-
-B.1.32. Systematic names for the hinting nop instructions
----------------------------------------------------------
-
- HINT_NOP0 rm16 P6,UNDOC
- HINT_NOP0 rm32 P6,UNDOC
- HINT_NOP0 rm64 X64,UNDOC
- HINT_NOP1 rm16 P6,UNDOC
- HINT_NOP1 rm32 P6,UNDOC
- HINT_NOP1 rm64 X64,UNDOC
- HINT_NOP2 rm16 P6,UNDOC
- HINT_NOP2 rm32 P6,UNDOC
- HINT_NOP2 rm64 X64,UNDOC
- HINT_NOP3 rm16 P6,UNDOC
- HINT_NOP3 rm32 P6,UNDOC
- HINT_NOP3 rm64 X64,UNDOC
- HINT_NOP4 rm16 P6,UNDOC
- HINT_NOP4 rm32 P6,UNDOC
- HINT_NOP4 rm64 X64,UNDOC
- HINT_NOP5 rm16 P6,UNDOC
- HINT_NOP5 rm32 P6,UNDOC
- HINT_NOP5 rm64 X64,UNDOC
- HINT_NOP6 rm16 P6,UNDOC
- HINT_NOP6 rm32 P6,UNDOC
- HINT_NOP6 rm64 X64,UNDOC
- HINT_NOP7 rm16 P6,UNDOC
- HINT_NOP7 rm32 P6,UNDOC
- HINT_NOP7 rm64 X64,UNDOC
- HINT_NOP8 rm16 P6,UNDOC
- HINT_NOP8 rm32 P6,UNDOC
- HINT_NOP8 rm64 X64,UNDOC
- HINT_NOP9 rm16 P6,UNDOC
- HINT_NOP9 rm32 P6,UNDOC
- HINT_NOP9 rm64 X64,UNDOC
- HINT_NOP10 rm16 P6,UNDOC
- HINT_NOP10 rm32 P6,UNDOC
- HINT_NOP10 rm64 X64,UNDOC
- HINT_NOP11 rm16 P6,UNDOC
- HINT_NOP11 rm32 P6,UNDOC
- HINT_NOP11 rm64 X64,UNDOC
- HINT_NOP12 rm16 P6,UNDOC
- HINT_NOP12 rm32 P6,UNDOC
- HINT_NOP12 rm64 X64,UNDOC
- HINT_NOP13 rm16 P6,UNDOC
- HINT_NOP13 rm32 P6,UNDOC
- HINT_NOP13 rm64 X64,UNDOC
- HINT_NOP14 rm16 P6,UNDOC
- HINT_NOP14 rm32 P6,UNDOC
- HINT_NOP14 rm64 X64,UNDOC
- HINT_NOP15 rm16 P6,UNDOC
- HINT_NOP15 rm32 P6,UNDOC
- HINT_NOP15 rm64 X64,UNDOC
- HINT_NOP16 rm16 P6,UNDOC
- HINT_NOP16 rm32 P6,UNDOC
- HINT_NOP16 rm64 X64,UNDOC
- HINT_NOP17 rm16 P6,UNDOC
- HINT_NOP17 rm32 P6,UNDOC
- HINT_NOP17 rm64 X64,UNDOC
- HINT_NOP18 rm16 P6,UNDOC
- HINT_NOP18 rm32 P6,UNDOC
- HINT_NOP18 rm64 X64,UNDOC
- HINT_NOP19 rm16 P6,UNDOC
- HINT_NOP19 rm32 P6,UNDOC
- HINT_NOP19 rm64 X64,UNDOC
- HINT_NOP20 rm16 P6,UNDOC
- HINT_NOP20 rm32 P6,UNDOC
- HINT_NOP20 rm64 X64,UNDOC
- HINT_NOP21 rm16 P6,UNDOC
- HINT_NOP21 rm32 P6,UNDOC
- HINT_NOP21 rm64 X64,UNDOC
- HINT_NOP22 rm16 P6,UNDOC
- HINT_NOP22 rm32 P6,UNDOC
- HINT_NOP22 rm64 X64,UNDOC
- HINT_NOP23 rm16 P6,UNDOC
- HINT_NOP23 rm32 P6,UNDOC
- HINT_NOP23 rm64 X64,UNDOC
- HINT_NOP24 rm16 P6,UNDOC
- HINT_NOP24 rm32 P6,UNDOC
- HINT_NOP24 rm64 X64,UNDOC
- HINT_NOP25 rm16 P6,UNDOC
- HINT_NOP25 rm32 P6,UNDOC
- HINT_NOP25 rm64 X64,UNDOC
- HINT_NOP26 rm16 P6,UNDOC
- HINT_NOP26 rm32 P6,UNDOC
- HINT_NOP26 rm64 X64,UNDOC
- HINT_NOP27 rm16 P6,UNDOC
- HINT_NOP27 rm32 P6,UNDOC
- HINT_NOP27 rm64 X64,UNDOC
- HINT_NOP28 rm16 P6,UNDOC
- HINT_NOP28 rm32 P6,UNDOC
- HINT_NOP28 rm64 X64,UNDOC
- HINT_NOP29 rm16 P6,UNDOC
- HINT_NOP29 rm32 P6,UNDOC
- HINT_NOP29 rm64 X64,UNDOC
- HINT_NOP30 rm16 P6,UNDOC
- HINT_NOP30 rm32 P6,UNDOC
- HINT_NOP30 rm64 X64,UNDOC
- HINT_NOP31 rm16 P6,UNDOC
- HINT_NOP31 rm32 P6,UNDOC
- HINT_NOP31 rm64 X64,UNDOC
- HINT_NOP32 rm16 P6,UNDOC
- HINT_NOP32 rm32 P6,UNDOC
- HINT_NOP32 rm64 X64,UNDOC
- HINT_NOP33 rm16 P6,UNDOC
- HINT_NOP33 rm32 P6,UNDOC
- HINT_NOP33 rm64 X64,UNDOC
- HINT_NOP34 rm16 P6,UNDOC
- HINT_NOP34 rm32 P6,UNDOC
- HINT_NOP34 rm64 X64,UNDOC
- HINT_NOP35 rm16 P6,UNDOC
- HINT_NOP35 rm32 P6,UNDOC
- HINT_NOP35 rm64 X64,UNDOC
- HINT_NOP36 rm16 P6,UNDOC
- HINT_NOP36 rm32 P6,UNDOC
- HINT_NOP36 rm64 X64,UNDOC
- HINT_NOP37 rm16 P6,UNDOC
- HINT_NOP37 rm32 P6,UNDOC
- HINT_NOP37 rm64 X64,UNDOC
- HINT_NOP38 rm16 P6,UNDOC
- HINT_NOP38 rm32 P6,UNDOC
- HINT_NOP38 rm64 X64,UNDOC
- HINT_NOP39 rm16 P6,UNDOC
- HINT_NOP39 rm32 P6,UNDOC
- HINT_NOP39 rm64 X64,UNDOC
- HINT_NOP40 rm16 P6,UNDOC
- HINT_NOP40 rm32 P6,UNDOC
- HINT_NOP40 rm64 X64,UNDOC
- HINT_NOP41 rm16 P6,UNDOC
- HINT_NOP41 rm32 P6,UNDOC
- HINT_NOP41 rm64 X64,UNDOC
- HINT_NOP42 rm16 P6,UNDOC
- HINT_NOP42 rm32 P6,UNDOC
- HINT_NOP42 rm64 X64,UNDOC
- HINT_NOP43 rm16 P6,UNDOC
- HINT_NOP43 rm32 P6,UNDOC
- HINT_NOP43 rm64 X64,UNDOC
- HINT_NOP44 rm16 P6,UNDOC
- HINT_NOP44 rm32 P6,UNDOC
- HINT_NOP44 rm64 X64,UNDOC
- HINT_NOP45 rm16 P6,UNDOC
- HINT_NOP45 rm32 P6,UNDOC
- HINT_NOP45 rm64 X64,UNDOC
- HINT_NOP46 rm16 P6,UNDOC
- HINT_NOP46 rm32 P6,UNDOC
- HINT_NOP46 rm64 X64,UNDOC
- HINT_NOP47 rm16 P6,UNDOC
- HINT_NOP47 rm32 P6,UNDOC
- HINT_NOP47 rm64 X64,UNDOC
- HINT_NOP48 rm16 P6,UNDOC
- HINT_NOP48 rm32 P6,UNDOC
- HINT_NOP48 rm64 X64,UNDOC
- HINT_NOP49 rm16 P6,UNDOC
- HINT_NOP49 rm32 P6,UNDOC
- HINT_NOP49 rm64 X64,UNDOC
- HINT_NOP50 rm16 P6,UNDOC
- HINT_NOP50 rm32 P6,UNDOC
- HINT_NOP50 rm64 X64,UNDOC
- HINT_NOP51 rm16 P6,UNDOC
- HINT_NOP51 rm32 P6,UNDOC
- HINT_NOP51 rm64 X64,UNDOC
- HINT_NOP52 rm16 P6,UNDOC
- HINT_NOP52 rm32 P6,UNDOC
- HINT_NOP52 rm64 X64,UNDOC
- HINT_NOP53 rm16 P6,UNDOC
- HINT_NOP53 rm32 P6,UNDOC
- HINT_NOP53 rm64 X64,UNDOC
- HINT_NOP54 rm16 P6,UNDOC
- HINT_NOP54 rm32 P6,UNDOC
- HINT_NOP54 rm64 X64,UNDOC
- HINT_NOP55 rm16 P6,UNDOC
- HINT_NOP55 rm32 P6,UNDOC
- HINT_NOP55 rm64 X64,UNDOC
- HINT_NOP56 rm16 P6,UNDOC
- HINT_NOP56 rm32 P6,UNDOC
- HINT_NOP56 rm64 X64,UNDOC
- HINT_NOP57 rm16 P6,UNDOC
- HINT_NOP57 rm32 P6,UNDOC
- HINT_NOP57 rm64 X64,UNDOC
- HINT_NOP58 rm16 P6,UNDOC
- HINT_NOP58 rm32 P6,UNDOC
- HINT_NOP58 rm64 X64,UNDOC
- HINT_NOP59 rm16 P6,UNDOC
- HINT_NOP59 rm32 P6,UNDOC
- HINT_NOP59 rm64 X64,UNDOC
- HINT_NOP60 rm16 P6,UNDOC
- HINT_NOP60 rm32 P6,UNDOC
- HINT_NOP60 rm64 X64,UNDOC
- HINT_NOP61 rm16 P6,UNDOC
- HINT_NOP61 rm32 P6,UNDOC
- HINT_NOP61 rm64 X64,UNDOC
- HINT_NOP62 rm16 P6,UNDOC
- HINT_NOP62 rm32 P6,UNDOC
- HINT_NOP62 rm64 X64,UNDOC
- HINT_NOP63 rm16 P6,UNDOC
- HINT_NOP63 rm32 P6,UNDOC
- HINT_NOP63 rm64 X64,UNDOC
-
-
-File: nasm.info, Node: Appendix C, Next: Section C.1, Prev: Section B.1.32, Up: Top
-
-Appendix C: NASM Version History
-********************************
-
-* Menu:
-
-* Section C.1:: NASM 2 Series
-* Section C.2:: NASM 0.98 Series
-* Section C.3:: NASM 0.9 Series
-
-
-File: nasm.info, Node: Section C.1, Next: Section C.1.1, Prev: Appendix C, Up: Appendix C
-
-C.1. NASM 2 Series
-==================
-
-The NASM 2 series support x86-64, and is the production version of NASM
-since 2007.
-
-* Menu:
-
-* Section C.1.1:: Version 2.08
-* Section C.1.2:: Version 2.07
-* Section C.1.3:: Version 2.06
-* Section C.1.4:: Version 2.05.01
-* Section C.1.5:: Version 2.05
-* Section C.1.6:: Version 2.04
-* Section C.1.7:: Version 2.03.01
-* Section C.1.8:: Version 2.03
-* Section C.1.9:: Version 2.02
-* Section C.1.10:: Version 2.01
-* Section C.1.11:: Version 2.00
-
-
-File: nasm.info, Node: Section C.1.1, Next: Section C.1.2, Prev: Section C.1, Up: Section C.1
-
-C.1.1. Version 2.08
--------------------
-
- * A number of enhancements/fixes in macros area.
-
- * Support for arbitrarily terminating macro expansions `%exitmacro'.
- See *note Section 4.3.12::.
-
- * Support for recursive macro expansion `%rmacro/irmacro'. See *note
- Section 4.3.1::.
-
- * Support for converting strings to tokens. See *note Section
- 4.1.9::.
-
- * Fuzzy operand size logic introduced.
-
- * Fix COFF stack overrun on too long export identifiers.
-
- * Fix Macho-O alignment bug.
-
- * Fix crashes with -fwin32 on file with many exports.
-
- * Fix stack overrun for too long [DEBUG id].
-
- * Fix incorrect sbyte usage in IMUL (hit only if optimization flag
- passed).
-
- * Append ending token for `.stabs' records in the ELF output format.
-
- * New NSIS script which uses ModernUI and MultiUser approach.
-
- * Visual Studio 2008 NASM integration (rules file).
-
- * Warn a user if a constant is too long (and as result will be
- stripped).
-
- * The obsoleted pre-XOP AMD SSE5 instruction set which was never
- actualized was removed.
-
- * Fix stack overrun on too long error file name passed from the
- command line.
-
- * Bind symbols to the .text section by default (ie in case if SECTION
- directive was omitted) in the ELF output format.
-
- * Fix sync points array index wrapping.
-
- * A few fixes for FMA4 and XOP instruction templates.
-
- * Add AMD Lightweight Profiling (LWP) instructions.
-
-
-File: nasm.info, Node: Section C.1.2, Next: Section C.1.3, Prev: Section C.1.1, Up: Section C.1
-
-C.1.2. Version 2.07
--------------------
-
- * NASM is now under the 2-clause BSD license. See *note Section
- 1.1.2::.
-
- * Fix the section type for the `.strtab' section in the `elf64'
- output format.
-
- * Fix the handling of `COMMON' directives in the `obj' output format.
-
- * New `ith' and `srec' output formats; these are variants of the
- `bin' output format which output Intel hex and Motorola S-records,
- respectively. See *note Section 7.2:: and *note Section 7.3::.
-
- * `rdf2ihx' replaced with an enhanced `rdf2bin', which can output
- binary, COM, Intel hex or Motorola S-records.
-
- * The Windows installer now puts the NASM directory first in the
- `PATH' of the "NASM Shell".
-
- * Revert the early expansion behavior of `%+' to pre-2.06 behavior:
- `%+' is only expanded late.
-
- * Yet another Mach-O alignment fix.
-
- * Don't delete the list file on errors. Also, include error and
- warning information in the list file.
-
- * Support for 64-bit Mach-O output, see *note Section 7.8::.
-
- * Fix assert failure on certain operations that involve strings with
- high-bit bytes.
-
-
-File: nasm.info, Node: Section C.1.3, Next: Section C.1.4, Prev: Section C.1.2, Up: Section C.1
-
-C.1.3. Version 2.06
--------------------
-
- * This release is dedicated to the memory of Charles A. Crayne, long
- time NASM developer as well as moderator of `comp.lang.asm.x86'
- and author of the book _Serious Assembler_. We miss you, Chuck.
-
- * Support for indirect macro expansion (`%[...]'). See *note Section
- 4.1.3::.
-
- * `%pop' can now take an argument, see *note Section 4.7.1::.
-
- * The argument to `%use' is no longer macro-expanded. Use `%[...]'
- if macro expansion is desired.
-
- * Support for thread-local storage in ELF32 and ELF64. See *note
- Section 7.9.4::.
-
- * Fix crash on `%ifmacro' without an argument.
-
- * Correct the arguments to the `POPCNT' instruction.
-
- * Fix section alignment in the Mach-O format.
-
- * Update AVX support to version 5 of the Intel specification.
-
- * Fix the handling of accesses to context-local macros from higher
- levels in the context stack.
-
- * Treat `WAIT' as a prefix rather than as an instruction, thereby
- allowing constructs like `O16 FSAVE' to work correctly.
-
- * Support for structures with a non-zero base offset. See *note
- Section 4.11.10::.
-
- * Correctly handle preprocessor token concatenation (see *note
- Section 4.3.8::) involving floating-point numbers.
-
- * The `PINSR' series of instructions have been corrected and
- rationalized.
-
- * Removed AMD SSE5, replaced with the new XOP/FMA4/CVT16 (rev 3.03)
- spec.
-
- * The ELF backends no longer automatically generate a `.comment'
- section.
-
- * Add additional "well-known" ELF sections with default attributes.
- See *note Section 7.9.2::.
-
-
-File: nasm.info, Node: Section C.1.4, Next: Section C.1.5, Prev: Section C.1.3, Up: Section C.1
-
-C.1.4. Version 2.05.01
-----------------------
-
- * Fix the `-w'/`-W' option parsing, which was broken in NASM 2.05.
-
-
-File: nasm.info, Node: Section C.1.5, Next: Section C.1.6, Prev: Section C.1.4, Up: Section C.1
-
-C.1.5. Version 2.05
--------------------
-
- * Fix redundant REX.W prefix on `JMP reg64'.
-
- * Make the behaviour of `-O0' match NASM 0.98 legacy behavior. See
- *note Section 2.1.22::.
-
- * `-w-user' can be used to suppress the output of `%warning'
- directives. See *note Section 2.1.24::.
-
- * Fix bug where `ALIGN' would issue a full alignment datum instead of
- zero bytes.
-
- * Fix offsets in list files.
-
- * Fix `%include' inside multi-line macros or loops.
-
- * Fix error where NASM would generate a spurious warning on valid
- optimizations of immediate values.
-
- * Fix arguments to a number of the `CVT' SSE instructions.
-
- * Fix RIP-relative offsets when the instruction carries an immediate.
-
- * Massive overhaul of the ELF64 backend for spec compliance.
-
- * Fix the Geode `PFRCPV' and `PFRSQRTV' instruction.
-
- * Fix the SSE 4.2 `CRC32' instruction.
-
-
-File: nasm.info, Node: Section C.1.6, Next: Section C.1.7, Prev: Section C.1.5, Up: Section C.1
-
-C.1.6. Version 2.04
--------------------
-
- * Sanitize macro handing in the `%error' directive.
-
- * New `%warning' directive to issue user-controlled warnings.
-
- * `%error' directives are now deferred to the final assembly phase.
-
- * New `%fatal' directive to immediately terminate assembly.
-
- * New `%strcat' directive to join quoted strings together.
-
- * New `%use' macro directive to support standard macro directives.
- See *note Section 4.6.4::.
-
- * Excess default parameters to `%macro' now issues a warning by
- default. See *note Section 4.3::.
-
- * Fix `%ifn' and `%elifn'.
-
- * Fix nested `%else' clauses.
-
- * Correct the handling of nested `%rep's.
-
- * New `%unmacro' directive to undeclare a multi-line macro. See
- *note Section 4.3.11::.
-
- * Builtin macro `__PASS__' which expands to the current assembly
- pass. See *note Section 4.11.9::.
-
- * `__utf16__' and `__utf32__' operators to generate UTF-16 and UTF-
- 32 strings. See *note Section 3.4.5::.
-
- * Fix bug in case-insensitive matching when compiled on platforms
- that don't use the `configure' script. Of the official release
- binaries, that only affected the OS/2 binary.
-
- * Support for x87 packed BCD constants. See *note Section 3.4.7::.
-
- * Correct the `LTR' and `SLDT' instructions in 64-bit mode.
-
- * Fix unnecessary REX.W prefix on indirect jumps in 64-bit mode.
-
- * Add AVX versions of the AES instructions (`VAES'...).
-
- * Fix the 256-bit FMA instructions.
-
- * Add 256-bit AVX stores per the latest AVX spec.
-
- * VIA XCRYPT instructions can now be written either with or without
- `REP', apparently different versions of the VIA spec wrote them
- differently.
-
- * Add missing 64-bit `MOVNTI' instruction.
-
- * Fix the operand size of `VMREAD' and `VMWRITE'.
-
- * Numerous bug fixes, especially to the AES, AVX and VTX
- instructions.
-
- * The optimizer now always runs until it converges. It also runs
- even when disabled, but doesn't optimize. This allows most forward
- references to be resolved properly.
-
- * `%push' no longer needs a context identifier; omitting the context
- identifier results in an anonymous context.
-
-
-File: nasm.info, Node: Section C.1.7, Next: Section C.1.8, Prev: Section C.1.6, Up: Section C.1
-
-C.1.7. Version 2.03.01
-----------------------
-
- * Fix buffer overflow in the listing module.
-
- * Fix the handling of hexadecimal escape codes in `...` strings.
-
- * The Postscript/PDF documentation has been reformatted.
-
- * The `-F' option now implies `-g'.
-
-
-File: nasm.info, Node: Section C.1.8, Next: Section C.1.9, Prev: Section C.1.7, Up: Section C.1
-
-C.1.8. Version 2.03
--------------------
-
- * Add support for Intel AVX, CLMUL and FMA instructions, including
- YMM registers.
-
- * `dy', `resy' and `yword' for 32-byte operands.
-
- * Fix some SSE5 instructions.
-
- * Intel `INVEPT', `INVVPID' and `MOVBE' instructions.
-
- * Fix checking for critical expressions when the optimizer is
- enabled.
-
- * Support the DWARF debugging format for ELF targets.
-
- * Fix optimizations of signed bytes.
-
- * Fix operation on bigendian machines.
-
- * Fix buffer overflow in the preprocessor.
-
- * `SAFESEH' support for Win32, `IMAGEREL' for Win64 (SEH).
-
- * `%?' and `%??' to refer to the name of a macro itself. In
- particular, `%idefine keyword $%?' can be used to make a keyword
- "disappear".
-
- * New options for dependency generation: `-MD', `-MF', `-MP', `-MT',
- `-MQ'.
-
- * New preprocessor directives `%pathsearch' and `%depend'; INCBIN
- reimplemented as a macro.
-
- * `%include' now resolves macros in a sane manner.
-
- * `%substr' can now be used to get other than one-character
- substrings.
-
- * New type of character/string constants, using backquotes (``...`'),
- which support C-style escape sequences.
-
- * `%defstr' and `%idefstr' to stringize macro definitions before
- creation.
-
- * Fix forward references used in `EQU' statements.
-
-
-File: nasm.info, Node: Section C.1.9, Next: Section C.1.10, Prev: Section C.1.8, Up: Section C.1
-
-C.1.9. Version 2.02
--------------------
-
- * Additional fixes for MMX operands with explicit `qword', as well as
- (hopefully) SSE operands with `oword'.
-
- * Fix handling of truncated strings with `DO'.
-
- * Fix segfaults due to memory overwrites when floating-point
- constants were used.
-
- * Fix segfaults due to missing include files.
-
- * Fix OpenWatcom Makefiles for DOS and OS/2.
-
- * Add autogenerated instruction list back into the documentation.
-
- * ELF: Fix segfault when generating stabs, and no symbols have been
- defined.
-
- * ELF: Experimental support for DWARF debugging information.
-
- * New compile date and time standard macros.
-
- * `%ifnum' now returns true for negative numbers.
-
- * New `%iftoken' test for a single token.
-
- * New `%ifempty' test for empty expansion.
-
- * Add support for the `XSAVE' instruction group.
-
- * Makefile for Netware/gcc.
-
- * Fix issue with some warnings getting emitted way too many times.
-
- * Autogenerated instruction list added to the documentation.
-
-
-File: nasm.info, Node: Section C.1.10, Next: Section C.1.11, Prev: Section C.1.9, Up: Section C.1
-
-C.1.10. Version 2.01
---------------------
-
- * Fix the handling of MMX registers with explicit `qword' tags on
- memory (broken in 2.00 due to 64-bit changes.)
-
- * Fix the PREFETCH instructions.
-
- * Fix the documentation.
-
- * Fix debugging info when using `-f elf' (backwards compatibility
- alias for `-f elf32').
-
- * Man pages for rdoff tools (from the Debian project.)
-
- * ELF: handle large numbers of sections.
-
- * Fix corrupt output when the optimizer runs out of passes.
-
-
-File: nasm.info, Node: Section C.1.11, Next: Section C.2, Prev: Section C.1.10, Up: Section C.1
-
-C.1.11. Version 2.00
---------------------
-
- * Added c99 data-type compliance.
-
- * Added general x86-64 support.
-
- * Added win64 (x86-64 COFF) output format.
-
- * Added `__BITS__' standard macro.
-
- * Renamed the `elf' output format to `elf32' for clarity.
-
- * Added `elf64' and `macho' (MacOS X) output formats.
-
- * Added Numeric constants in `dq' directive.
-
- * Added `oword', `do' and `reso' pseudo operands.
-
- * Allow underscores in numbers.
-
- * Added 8-, 16- and 128-bit floating-point formats.
-
- * Added binary, octal and hexadecimal floating-point.
-
- * Correct the generation of floating-point constants.
-
- * Added floating-point option control.
-
- * Added Infinity and NaN floating point support.
-
- * Added ELF Symbol Visibility support.
-
- * Added setting OSABI value in ELF header directive.
-
- * Added Generate Makefile Dependencies option.
-
- * Added Unlimited Optimization Passes option.
-
- * Added `%IFN' and `%ELIFN' support.
-
- * Added Logical Negation Operator.
-
- * Enhanced Stack Relative Preprocessor Directives.
-
- * Enhanced ELF Debug Formats.
-
- * Enhanced Send Errors to a File option.
-
- * Added SSSE3, SSE4.1, SSE4.2, SSE5 support.
-
- * Added a large number of additional instructions.
-
- * Significant performance improvements.
-
- * `-w+warning' and `-w-warning' can now be written as -Wwarning and
- -Wno-warning, respectively. See *note Section 2.1.24::.
-
- * Add `-w+error' to treat warnings as errors. See *note Section
- 2.1.24::.
-
- * Add `-w+all' and `-w-all' to enable or disable all suppressible
- warnings. See *note Section 2.1.24::.
-
-
-File: nasm.info, Node: Section C.2, Next: Section C.2.1, Prev: Section C.1.11, Up: Appendix C
-
-C.2. NASM 0.98 Series
-=====================
-
-The 0.98 series was the production versions of NASM from 1999 to 2007.
-
-* Menu:
-
-* Section C.2.1:: Version 0.98.39
-* Section C.2.2:: Version 0.98.38
-* Section C.2.3:: Version 0.98.37
-* Section C.2.4:: Version 0.98.36
-* Section C.2.5:: Version 0.98.35
-* Section C.2.6:: Version 0.98.34
-* Section C.2.7:: Version 0.98.33
-* Section C.2.8:: Version 0.98.32
-* Section C.2.9:: Version 0.98.31
-* Section C.2.10:: Version 0.98.30
-* Section C.2.11:: Version 0.98.28
-* Section C.2.12:: Version 0.98.26
-* Section C.2.13:: Version 0.98.25alt
-* Section C.2.14:: Version 0.98.25
-* Section C.2.15:: Version 0.98.24p1
-* Section C.2.16:: Version 0.98.24
-* Section C.2.17:: Version 0.98.23
-* Section C.2.18:: Version 0.98.22
-* Section C.2.19:: Version 0.98.21
-* Section C.2.20:: Version 0.98.20
-* Section C.2.21:: Version 0.98.19
-* Section C.2.22:: Version 0.98.18
-* Section C.2.23:: Version 0.98.17
-* Section C.2.24:: Version 0.98.16
-* Section C.2.25:: Version 0.98.15
-* Section C.2.26:: Version 0.98.14
-* Section C.2.27:: Version 0.98.13
-* Section C.2.28:: Version 0.98.12
-* Section C.2.29:: Version 0.98.11
-* Section C.2.30:: Version 0.98.10
-* Section C.2.31:: Version 0.98.09
-* Section C.2.32:: Version 0.98.08
-* Section C.2.33:: Version 0.98.09b with John Coffman patches released 28-Oct-2001
-* Section C.2.34:: Version 0.98.07 released 01/28/01
-* Section C.2.35:: Version 0.98.06f released 01/18/01
-* Section C.2.36:: Version 0.98.06e released 01/09/01
-* Section C.2.37:: Version 0.98p1
-* Section C.2.38:: Version 0.98bf (bug-fixed)
-* Section C.2.39:: Version 0.98.03 with John Coffman's changes released 27-Jul-2000
-* Section C.2.40:: Version 0.98.03
-* Section C.2.41:: Version 0.98
-* Section C.2.42:: Version 0.98p9
-* Section C.2.43:: Version 0.98p8
-* Section C.2.44:: Version 0.98p7
-* Section C.2.45:: Version 0.98p6
-* Section C.2.46:: Version 0.98p3.7
-* Section C.2.47:: Version 0.98p3.6
-* Section C.2.48:: Version 0.98p3.5
-* Section C.2.49:: Version 0.98p3.4
-* Section C.2.50:: Version 0.98p3.3
-* Section C.2.51:: Version 0.98p3.2
-* Section C.2.52:: Version 0.98p3-hpa
-* Section C.2.53:: Version 0.98 pre-release 3
-* Section C.2.54:: Version 0.98 pre-release 2
-* Section C.2.55:: Version 0.98 pre-release 1
-
-
-File: nasm.info, Node: Section C.2.1, Next: Section C.2.2, Prev: Section C.2, Up: Section C.2
-
-C.2.1. Version 0.98.39
-----------------------
-
- * fix buffer overflow
-
- * fix outas86's `.bss' handling
-
- * "make spotless" no longer deletes config.h.in.
-
- * `%(el)if(n)idn' insensitivity to string quotes difference
- (#809300).
-
- * (nasm.c)`__OUTPUT_FORMAT__' changed to string value instead of
- symbol.
-
-
-File: nasm.info, Node: Section C.2.2, Next: Section C.2.3, Prev: Section C.2.1, Up: Section C.2
-
-C.2.2. Version 0.98.38
-----------------------
-
- * Add Makefile for 16-bit DOS binaries under OpenWatcom, and modify
- `mkdep.pl' to be able to generate completely pathless
- dependencies, as required by OpenWatcom wmake (it supports path
- searches, but not explicit paths.)
-
- * Fix the `STR' instruction.
-
- * Fix the ELF output format, which was broken under certain
- circumstances due to the addition of stabs support.
-
- * Quick-fix Borland format debug-info for `-f obj'
-
- * Fix for `%rep' with no arguments (#560568)
-
- * Fix concatenation of preprocessor function call (#794686)
-
- * Fix long label causes coredump (#677841)
-
- * Use autoheader as well as autoconf to keep configure from
- generating ridiculously long command lines.
-
- * Make sure that all of the formats which support debugging output
- actually will suppress debugging output when `-g' not specified.
-
-
-File: nasm.info, Node: Section C.2.3, Next: Section C.2.4, Prev: Section C.2.2, Up: Section C.2
-
-C.2.3. Version 0.98.37
-----------------------
-
- * Paths given in `-I' switch searched for `incbin'-ed as well as
- `%include'-ed files.
-
- * Added stabs debugging for the ELF output format, patch from Martin
- Wawro.
-
- * Fix `output/outbin.c' to allow origin > 80000000h.
-
- * Make `-U' switch work.
-
- * Fix the use of relative offsets with explicit prefixes, e.g. `a32
- loop foo'.
-
- * Remove `backslash()'.
-
- * Fix the `SMSW' and `SLDT' instructions.
-
- * `-O2' and `-O3' are no longer aliases for `-O10' and `-O15'. If
- you mean the latter, please say so! :)
-
-
-File: nasm.info, Node: Section C.2.4, Next: Section C.2.5, Prev: Section C.2.3, Up: Section C.2
-
-C.2.4. Version 0.98.36
-----------------------
-
- * Update rdoff - librarian/archiver - common rec - docs!
-
- * Fix signed/unsigned problems.
-
- * Fix `JMP FAR label' and `CALL FAR label'.
-
- * Add new multisection support - map files - fix align bug
-
- * Fix sysexit, movhps/movlps reg,reg bugs in insns.dat
-
- * `Q' or `O' suffixes indicate octal
-
- * Support Prescott new instructions (PNI).
-
- * Cyrix `XSTORE' instruction.
-
-
-File: nasm.info, Node: Section C.2.5, Next: Section C.2.6, Prev: Section C.2.4, Up: Section C.2
-
-C.2.5. Version 0.98.35
-----------------------
-
- * Fix build failure on 16-bit DOS (Makefile.bc3 workaround for
- compiler bug.)
-
- * Fix dependencies and compiler warnings.
-
- * Add "const" in a number of places.
-
- * Add -X option to specify error reporting format (use -Xvc to
- integrate with Microsoft Visual Studio.)
-
- * Minor changes for code legibility.
-
- * Drop use of tmpnam() in rdoff (security fix.)
-
-
-File: nasm.info, Node: Section C.2.6, Next: Section C.2.7, Prev: Section C.2.5, Up: Section C.2
-
-C.2.6. Version 0.98.34
-----------------------
-
- * Correct additional address-size vs. operand-size confusions.
-
- * Generate dependencies for all Makefiles automatically.
-
- * Add support for unimplemented (but theoretically available)
- registers such as tr0 and cr5. Segment registers 6 and 7 are
- called segr6 and segr7 for the operations which they can be
- represented.
-
- * Correct some disassembler bugs related to redundant address-size
- prefixes. Some work still remains in this area.
-
- * Correctly generate an error for things like "SEG eax".
-
- * Add the JMPE instruction, enabled by "CPU IA64".
-
- * Correct compilation on newer gcc/glibc platforms.
-
- * Issue an error on things like "jmp far eax".
-
-
-File: nasm.info, Node: Section C.2.7, Next: Section C.2.8, Prev: Section C.2.6, Up: Section C.2
-
-C.2.7. Version 0.98.33
-----------------------
-
- * New __NASM_PATCHLEVEL__ and __NASM_VERSION_ID__ standard macros to
- round out the version-query macros. version.pl now understands
- X.YYplWW or X.YY.ZZplWW as a version number, equivalent to
- X.YY.ZZ.WW (or X.YY.0.WW, as appropriate).
-
- * New keyword "strict" to disable the optimization of specific
- operands.
-
- * Fix the handing of size overrides with JMP instructions
- (instructions such as "jmp dword foo".)
-
- * Fix the handling of "ABSOLUTE label", where "label" points into a
- relocatable segment.
-
- * Fix OBJ output format with lots of externs.
-
- * More documentation updates.
-
- * Add -Ov option to get verbose information about optimizations.
-
- * Undo a braindead change which broke `%elif' directives.
-
- * Makefile updates.
-
-
-File: nasm.info, Node: Section C.2.8, Next: Section C.2.9, Prev: Section C.2.7, Up: Section C.2
-
-C.2.8. Version 0.98.32
-----------------------
-
- * Fix NASM crashing when `%macro' directives were left unterminated.
-
- * Lots of documentation updates.
-
- * Complete rewrite of the PostScript/PDF documentation generator.
-
- * The MS Visual C++ Makefile was updated and corrected.
-
- * Recognize .rodata as a standard section name in ELF.
-
- * Fix some obsolete Perl4-isms in Perl scripts.
-
- * Fix configure.in to work with autoconf 2.5x.
-
- * Fix a couple of "make cleaner" misses.
-
- * Make the normal "./configure && make" work with Cygwin.
-
-
-File: nasm.info, Node: Section C.2.9, Next: Section C.2.10, Prev: Section C.2.8, Up: Section C.2
-
-C.2.9. Version 0.98.31
-----------------------
-
- * Correctly build in a separate object directory again.
-
- * Derive all references to the version number from the version file.
-
- * New standard macros __NASM_SUBMINOR__ and __NASM_VER__ macros.
-
- * Lots of Makefile updates and bug fixes.
-
- * New `%ifmacro' directive to test for multiline macros.
-
- * Documentation updates.
-
- * Fixes for 16-bit OBJ format output.
-
- * Changed the NASM environment variable to NASMENV.
-
-
-File: nasm.info, Node: Section C.2.10, Next: Section C.2.11, Prev: Section C.2.9, Up: Section C.2
-
-C.2.10. Version 0.98.30
------------------------
-
- * Changed doc files a lot: completely removed old READMExx and
- Wishlist files, incorporating all information in CHANGES and TODO.
-
- * I waited a long time to rename zoutieee.c to (original) outieee.c
-
- * moved all output modules to output/ subdirectory.
-
- * Added 'make strip' target to strip debug info from nasm & ndisasm.
-
- * Added INSTALL file with installation instructions.
-
- * Added -v option description to nasm man.
-
- * Added dist makefile target to produce source distributions.
-
- * 16-bit support for ELF output format (GNU extension, but useful.)
-
-
-File: nasm.info, Node: Section C.2.11, Next: Section C.2.12, Prev: Section C.2.10, Up: Section C.2
-
-C.2.11. Version 0.98.28
------------------------
-
- * Fastcooked this for Debian's Woody release: Frank applied the
- INCBIN bug patch to 0.98.25alt and called it 0.98.28 to not
- confuse poor little apt- get.
-
-
-File: nasm.info, Node: Section C.2.12, Next: Section C.2.13, Prev: Section C.2.11, Up: Section C.2
-
-C.2.12. Version 0.98.26
------------------------
-
- * Reorganised files even better from 0.98.25alt
-
-
-File: nasm.info, Node: Section C.2.13, Next: Section C.2.14, Prev: Section C.2.12, Up: Section C.2
-
-C.2.13. Version 0.98.25alt
---------------------------
-
- * Prettified the source tree. Moved files to more reasonable places.
-
- * Added findleak.pl script to misc/ directory.
-
- * Attempted to fix doc.
-
-
-File: nasm.info, Node: Section C.2.14, Next: Section C.2.15, Prev: Section C.2.13, Up: Section C.2
-
-C.2.14. Version 0.98.25
------------------------
-
- * Line continuation character `\'.
-
- * Docs inadvertantly reverted - "dos packaging".
-
-
-File: nasm.info, Node: Section C.2.15, Next: Section C.2.16, Prev: Section C.2.14, Up: Section C.2
-
-C.2.15. Version 0.98.24p1
--------------------------
-
- * FIXME: Someone, document this please.
-
-
-File: nasm.info, Node: Section C.2.16, Next: Section C.2.17, Prev: Section C.2.15, Up: Section C.2
-
-C.2.16. Version 0.98.24
------------------------
-
- * Documentation - Ndisasm doc added to Nasm.doc.
-
-
-File: nasm.info, Node: Section C.2.17, Next: Section C.2.18, Prev: Section C.2.16, Up: Section C.2
-
-C.2.17. Version 0.98.23
------------------------
-
- * Attempted to remove rdoff version1
-
- * Lino Mastrodomenico's patches to preproc.c (%$$ bug?).
-
-
-File: nasm.info, Node: Section C.2.18, Next: Section C.2.19, Prev: Section C.2.17, Up: Section C.2
-
-C.2.18. Version 0.98.22
------------------------
-
- * Update rdoff2 - attempt to remove v1.
-
-
-File: nasm.info, Node: Section C.2.19, Next: Section C.2.20, Prev: Section C.2.18, Up: Section C.2
-
-C.2.19. Version 0.98.21
------------------------
-
- * Optimization fixes.
-
-
-File: nasm.info, Node: Section C.2.20, Next: Section C.2.21, Prev: Section C.2.19, Up: Section C.2
-
-C.2.20. Version 0.98.20
------------------------
-
- * Optimization fixes.
-
-
-File: nasm.info, Node: Section C.2.21, Next: Section C.2.22, Prev: Section C.2.20, Up: Section C.2
-
-C.2.21. Version 0.98.19
------------------------
-
- * H. J. Lu's patch back out.
-
-
-File: nasm.info, Node: Section C.2.22, Next: Section C.2.23, Prev: Section C.2.21, Up: Section C.2
-
-C.2.22. Version 0.98.18
------------------------
-
- * Added ".rdata" to "-f win32".
-
-
-File: nasm.info, Node: Section C.2.23, Next: Section C.2.24, Prev: Section C.2.22, Up: Section C.2
-
-C.2.23. Version 0.98.17
------------------------
-
- * H. J. Lu's "bogus elf" patch. (Red Hat problem?)
-
-
-File: nasm.info, Node: Section C.2.24, Next: Section C.2.25, Prev: Section C.2.23, Up: Section C.2
-
-C.2.24. Version 0.98.16
------------------------
-
- * Fix whitespace before "[section ..." bug.
-
-
-File: nasm.info, Node: Section C.2.25, Next: Section C.2.26, Prev: Section C.2.24, Up: Section C.2
-
-C.2.25. Version 0.98.15
------------------------
-
- * Rdoff changes (?).
-
- * Fix fixes to memory leaks.
-
-
-File: nasm.info, Node: Section C.2.26, Next: Section C.2.27, Prev: Section C.2.25, Up: Section C.2
-
-C.2.26. Version 0.98.14
------------------------
-
- * Fix memory leaks.
-
-
-File: nasm.info, Node: Section C.2.27, Next: Section C.2.28, Prev: Section C.2.26, Up: Section C.2
-
-C.2.27. Version 0.98.13
------------------------
-
- * There was no 0.98.13
-
-
-File: nasm.info, Node: Section C.2.28, Next: Section C.2.29, Prev: Section C.2.27, Up: Section C.2
-
-C.2.28. Version 0.98.12
------------------------
-
- * Update optimization (new function of "-O1")
-
- * Changes to test/bintest.asm (?).
-
-
-File: nasm.info, Node: Section C.2.29, Next: Section C.2.30, Prev: Section C.2.28, Up: Section C.2
-
-C.2.29. Version 0.98.11
------------------------
-
- * Optimization changes.
-
- * Ndisasm fixed.
-
-
-File: nasm.info, Node: Section C.2.30, Next: Section C.2.31, Prev: Section C.2.29, Up: Section C.2
-
-C.2.30. Version 0.98.10
------------------------
-
- * There was no 0.98.10
-
-
-File: nasm.info, Node: Section C.2.31, Next: Section C.2.32, Prev: Section C.2.30, Up: Section C.2
-
-C.2.31. Version 0.98.09
------------------------
-
- * Add multiple sections support to "-f bin".
-
- * Changed GLOBAL_TEMP_BASE in outelf.c from 6 to 15.
-
- * Add "-v" as an alias to the "-r" switch.
-
- * Remove "#ifdef" from Tasm compatibility options.
-
- * Remove redundant size-overrides on "mov ds, ex", etc.
-
- * Fixes to SSE2, other insns.dat (?).
-
- * Enable uppercase "I" and "P" switches.
-
- * Case insinsitive "seg" and "wrt".
-
- * Update install.sh (?).
-
- * Allocate tokens in blocks.
-
- * Improve "invalid effective address" messages.
-
-
-File: nasm.info, Node: Section C.2.32, Next: Section C.2.33, Prev: Section C.2.31, Up: Section C.2
-
-C.2.32. Version 0.98.08
------------------------
-
- * Add "`%strlen'" and "`%substr'" macro operators
-
- * Fixed broken c16.mac.
-
- * Unterminated string error reported.
-
- * Fixed bugs as per 0.98bf
-
-
-File: nasm.info, Node: Section C.2.33, Next: Section C.2.34, Prev: Section C.2.32, Up: Section C.2
-
-C.2.33. Version 0.98.09b with John Coffman patches released 28-Oct-2001
------------------------------------------------------------------------
-
-Changes from 0.98.07 release to 98.09b as of 28-Oct-2001
-
- * More closely compatible with 0.98 when -O0 is implied or
- specified. Not strictly identical, since backward branches in
- range of short offsets are recognized, and signed byte values with
- no explicit size specification will be assembled as a single byte.
-
- * More forgiving with the PUSH instruction. 0.98 requires a size to
- be specified always. 0.98.09b will imply the size from the current
- BITS setting (16 or 32).
-
- * Changed definition of the optimization flag:
-
- -O0 strict two-pass assembly, JMP and Jcc are handled more like 0.98,
-except that back- ward JMPs are short, if possible.
-
- -O1 strict two-pass assembly, but forward branches are assembled
-with code guaranteed to reach; may produce larger code than -O0, but
-will produce successful assembly more often if branch offset sizes are
-not specified.
-
- -O2 multi-pass optimization, minimize branch offsets; also will
-minimize signed immed- iate bytes, overriding size specification.
-
- -O3 like -O2, but more passes taken, if needed
-
-
-File: nasm.info, Node: Section C.2.34, Next: Section C.2.35, Prev: Section C.2.33, Up: Section C.2
-
-C.2.34. Version 0.98.07 released 01/28/01
------------------------------------------
-
- * Added Stepane Denis' SSE2 instructions to a *working* version of
- the code - some earlier versions were based on broken code - sorry
- 'bout that. version "0.98.07"
-
- 01/28/01
-
- * Cosmetic modifications to nasm.c, nasm.h, AUTHORS, MODIFIED
-
-
-File: nasm.info, Node: Section C.2.35, Next: Section C.2.36, Prev: Section C.2.34, Up: Section C.2
-
-C.2.35. Version 0.98.06f released 01/18/01
-------------------------------------------
-
- * - Add "metalbrain"s jecxz bug fix in insns.dat - alter nasmdoc.src
- to match - version "0.98.06f"
-
-
-File: nasm.info, Node: Section C.2.36, Next: Section C.2.37, Prev: Section C.2.35, Up: Section C.2
-
-C.2.36. Version 0.98.06e released 01/09/01
-------------------------------------------
-
- * Removed the "outforms.h" file - it appears to be someone's old
- backup of "outform.h". version "0.98.06e"
-
- 01/09/01
-
- * fbk - finally added the fix for the "multiple %includes bug",
- known since 7/27/99 - reported originally (?) and sent to us by
- Austin Lunnen - he reports that John Fine had a fix within the
- day. Here it is...
-
- * Nelson Rush resigns from the group. Big thanks to Nelson for his
- leadership and enthusiasm in getting these changes incorporated
- into Nasm!
-
- * fbk - [list +], [list -] directives - ineptly implemented, should
- be re- written or removed, perhaps.
-
- * Brian Raiter / fbk - "elfso bug" fix - applied to aoutb format as
- well - testing might be desirable...
-
- 08/07/00
-
- * James Seter - -postfix, -prefix command line switches.
-
- * Yuri Zaporogets - rdoff utility changes.
-
-
-File: nasm.info, Node: Section C.2.37, Next: Section C.2.38, Prev: Section C.2.36, Up: Section C.2
-
-C.2.37. Version 0.98p1
-----------------------
-
- * GAS-like palign (Panos Minos)
-
- * FIXME: Someone, fill this in with details
-
-
-File: nasm.info, Node: Section C.2.38, Next: Section C.2.39, Prev: Section C.2.37, Up: Section C.2
-
-C.2.38. Version 0.98bf (bug-fixed)
-----------------------------------
-
- * Fixed - elf and aoutb bug - shared libraries - multiple "%include"
- bug in "-f obj" - jcxz, jecxz bug - unrecognized option bug in
- ndisasm
-
-
-File: nasm.info, Node: Section C.2.39, Next: Section C.2.40, Prev: Section C.2.38, Up: Section C.2
-
-C.2.39. Version 0.98.03 with John Coffman's changes released 27-Jul-2000
-------------------------------------------------------------------------
-
- * Added signed byte optimizations for the 0x81/0x83 class of
- instructions: ADC, ADD, AND, CMP, OR, SBB, SUB, XOR: when used as
- 'ADD reg16,imm' or 'ADD reg32,imm.' Also optimization of signed
- byte form of 'PUSH imm' and 'IMUL reg,imm'/'IMUL reg,reg,imm.' No
- size specification is needed.
-
- * Added multi-pass JMP and Jcc offset optimization. Offsets on
- forward references will preferentially use the short form, without
- the need to code a specific size (short or near) for the branch.
- Added instructions for 'Jcc label' to use the form 'Jnotcc $+3/JMP
- label', in cases where a short offset is out of bounds. If
- compiling for a 386 or higher CPU, then the 386 form of Jcc will
- be used instead.
-
- This feature is controlled by a new command-line switch: "O", (upper
-case letter O). "-O0" reverts the assembler to no extra optimization
-passes, "- O1" allows up to 5 extra passes, and "-O2"(default), allows
-up to 10 extra optimization passes.
-
- * Added a new directive: 'cpu XXX', where XXX is any of: 8086, 186,
- 286, 386, 486, 586, pentium, 686, PPro, P2, P3 or Katmai. All are
- case insensitive. All instructions will be selected only if they
- apply to the selected cpu or lower. Corrected a couple of bugs in
- cpu-dependence in 'insns.dat'.
-
- * Added to 'standard.mac', the "use16" and "use32" forms of the
- "bits 16/32" directive. This is nothing new, just conforms to a
- lot of other assemblers. (minor)
-
- * Changed label allocation from 320/32 (10000 labels @ 200K+) to
- 32/37 (1000 labels); makes running under DOS much easier. Since
- additional label space is allocated dynamically, this should have
- no effect on large programs with lots of labels. The 37 is a
- prime, believed to be better for hashing. (minor)
-
-
-File: nasm.info, Node: Section C.2.40, Next: Section C.2.41, Prev: Section C.2.39, Up: Section C.2
-
-C.2.40. Version 0.98.03
------------------------
-
-"Integrated patchfile 0.98-0.98.01. I call this version 0.98.03 for
-historical reasons: 0.98.02 was trashed." ---John Coffman
-<johninsd@san.rr.com>, 27-Jul-2000
-
- * Kendall Bennett's SciTech MGL changes
-
- * Note that you must define "TASM_COMPAT" at compile-time to get the
- Tasm Ideal Mode compatibility.
-
- * All changes can be compiled in and out using the TASM_COMPAT
- macros, and when compiled without TASM_COMPAT defined we get the
- exact same binary as the unmodified 0.98 sources.
-
- * standard.mac, macros.c: Added macros to ignore TASM directives
- before first include
-
- * nasm.h: Added extern declaration for tasm_compatible_mode
-
- * nasm.c: Added global variable tasm_compatible_mode
-
- * Added command line switch for TASM compatible mode (-t)
-
- * Changed version command line to reflect when compiled with TASM
- additions
-
- * Added response file processing to allow all arguments on a single
- line (response file is @resp rather than -@resp for NASM format).
-
- * labels.c: Changes islocal() macro to support TASM style @@local
- labels.
-
- * Added islocalchar() macro to support TASM style @@local labels.
-
- * parser.c: Added support for TASM style memory references (ie: mov
- [DWORD eax],10 rather than the NASM style mov DWORD [eax],10).
-
- * preproc.c: Added new directives, `%arg', `%local', `%stacksize' to
- directives table
-
- * Added support for TASM style directives without a leading % symbol.
-
- * Integrated a block of changes from Andrew Zabolotny
- <bit@eltech.ru>:
-
- * A new keyword `%xdefine' and its case-insensitive counterpart
- `%ixdefine'. They work almost the same way as `%define' and
- `%idefine' but expand the definition immediately, not on the
- invocation. Something like a cross between `%define' and
- `%assign'. The "x" suffix stands for "eXpand", so "xdefine" can be
- deciphered as "expand-and-define". Thus you can do things like
- this:
-
- %assign ofs 0
-
- %macro arg 1
- %xdefine %1 dword [esp+ofs]
- %assign ofs ofs+4
- %endmacro
-
- * Changed the place where the expansion of %$name macros are
- expanded. Now they are converted into ..@ctxnum.name form when
- detokenizing, so there are no quirks as before when using %$name
- arguments to macros, in macros etc. For example:
-
- %macro abc 1
- %define %1 hello
- %endm
-
- abc %$here
- %$here
-
- Now last line will be expanded into "hello" as expected. This also
-allows for lots of goodies, a good example are extended "proc" macros
-included in this archive.
-
- * Added a check for "cstk" in smacro_defined() before calling
- get_ctx() - this allows for things like:
-
- %ifdef %$abc
- %endif
-
- to work without warnings even in no context.
-
- * Added a check for "cstk" in %if*ctx and %elif*ctx directives -
- this allows to use `%ifctx' without excessive warnings. If there
- is no active context, `%ifctx' goes through "false" branch.
-
- * Removed "user error: " prefix with `%error' directive: it just
- clobbers the output and has absolutely no functionality. Besides,
- this allows to write macros that does not differ from built-in
- functions in any way.
-
- * Added expansion of string that is output by `%error' directive. Now
- you can do things like:
-
- %define hello(x) Hello, x!
-
- %define %$name andy
- %error "hello(%$name)"
-
- Same happened with `%include' directive.
-
- * Now all directives that expect an identifier will try to expand and
- concatenate everything without whitespaces in between before
- usage. For example, with "unfixed" nasm the commands
-
- %define %$abc hello
- %define __%$abc goodbye
- __%$abc
-
- would produce "incorrect" output: last line will expand to
-
- hello goodbyehello
-
- Not quite what you expected, eh? :-) The answer is that preprocessor
-treats the `%define' construct as if it would be
-
- %define __ %$abc goodbye
-
- (note the white space between __ and %$abc). After my "fix" it will
-"correctly" expand into
-
- goodbye
-
- as expected. Note that I use quotes around words "correct",
-"incorrect" etc because this is rather a feature not a bug; however
-current behaviour is more logical (and allows more advanced macro usage
-:-).
-
- Same change was applied to:
-`%push',`%macro',`%imacro',`%define',`%idefine',`%xdefine',`%ixdefine',
-`%assign',`%iassign',`%undef'
-
- * A new directive [WARNING {+|-}warning-id] have been added. It
- works only if the assembly phase is enabled (i.e. it doesn't work
- with nasm -e).
-
- * A new warning type: macro-selfref. By default this warning is
- disabled; when enabled NASM warns when a macro self-references
- itself; for example the following source:
-
- [WARNING macro-selfref]
-
- %macro push 1-*
- %rep %0
- push %1
- %rotate 1
- %endrep
- %endmacro
-
- push eax,ebx,ecx
-
- will produce a warning, but if we remove the first line we won't see
-it anymore (which is The Right Thing To Do {tm} IMHO since C
-preprocessor eats such constructs without warnings at all).
-
- * Added a "error" routine to preprocessor which always will set
- ERR_PASS1 bit in severity_code. This removes annoying repeated
- errors on first and second passes from preprocessor.
-
- * Added the %+ operator in single-line macros for concatenating two
- identifiers. Usage example:
-
- %define _myfunc _otherfunc
- %define cextern(x) _ %+ x
- cextern (myfunc)
-
- After first expansion, third line will become "_myfunc". After this
-expansion is performed again so it becomes "_otherunc".
-
- * Now if preprocessor is in a non-emitting state, no warning or
- error will be emitted. Example:
-
- %if 1
- mov eax,ebx
- %else
- put anything you want between these two brackets,
- even macro-parameter references %1 or local
- labels %$zz or macro-local labels %%zz - no
- warning will be emitted.
- %endif
-
- * Context-local variables on expansion as a last resort are looked
- up in outer contexts. For example, the following piece:
-
- %push outer
- %define %$a [esp]
-
- %push inner
- %$a
- %pop
- %pop
-
- will expand correctly the fourth line to [esp]; if we'll define
-another %$a inside the "inner" context, it will take precedence over
-outer definition. However, this modification has been applied only to
-expand_smacro and not to smacro_define: as a consequence expansion
-looks in outer contexts, but `%ifdef' won't look in outer contexts.
-
- This behaviour is needed because we don't want nested contexts to
-act on already defined local macros. Example:
-
- %define %$arg1 [esp+4]
- test eax,eax
- if nz
- mov eax,%$arg1
- endif
-
- In this example the "if" mmacro enters into the "if" context, so
-%$arg1 is not valid anymore inside "if". Of course it could be worked
-around by using explicitely %$$arg1 but this is ugly IMHO.
-
- * Fixed memory leak in `%undef'. The origline wasn't freed before
- exiting on success.
-
- * Fixed trap in preprocessor when line expanded to empty set of
- tokens. This happens, for example, in the following case:
-
- #define SOMETHING
- SOMETHING
-
-
-File: nasm.info, Node: Section C.2.41, Next: Section C.2.42, Prev: Section C.2.40, Up: Section C.2
-
-C.2.41. Version 0.98
---------------------
-
-All changes since NASM 0.98p3 have been produced by H. Peter Anvin
-<hpa@zytor.com>.
-
- * The documentation comment delimiter is
-
- * Allow EQU definitions to refer to external labels; reported by
- Pedro Gimeno.
-
- * Re-enable support for RDOFF v1; reported by Pedro Gimeno.
-
- * Updated License file per OK from Simon and Julian.
-
-
-File: nasm.info, Node: Section C.2.42, Next: Section C.2.43, Prev: Section C.2.41, Up: Section C.2
-
-C.2.42. Version 0.98p9
-----------------------
-
- * Update documentation (although the instruction set reference will
- have to wait; I don't want to hold up the 0.98 release for it.)
-
- * Verified that the NASM implementation of the PEXTRW and PMOVMSKB
- instructions is correct. The encoding differs from what the Intel
- manuals document, but the Pentium III behaviour matches NASM, not
- the Intel manuals.
-
- * Fix handling of implicit sizes in PSHUFW and PINSRW, reported by
- Stefan Hoffmeister.
-
- * Resurrect the -s option, which was removed when changing the
- diagnostic output to stdout.
-
-
-File: nasm.info, Node: Section C.2.43, Next: Section C.2.44, Prev: Section C.2.42, Up: Section C.2
-
-C.2.43. Version 0.98p8
-----------------------
-
- * Fix for "DB" when NASM is running on a bigendian machine.
-
- * Invoke insns.pl once for each output script, making Makefile.in
- legal for "make -j".
-
- * Improve the Unix configure-based makefiles to make package
- creation easier.
-
- * Included an RPM .spec file for building RPM (RedHat Package
- Manager) packages on Linux or Unix systems.
-
- * Fix Makefile dependency problems.
-
- * Change src/rdsrc.pl to include sectioning information in info
- output; required for install-info to work.
-
- * Updated the RDOFF distribution to version 2 from Jules; minor
- massaging to make it compile in my environment.
-
- * Split doc files that can be built by anyone with a Perl
- interpreter off into a separate archive.
-
- * "Dress rehearsal" release!
-
-
-File: nasm.info, Node: Section C.2.44, Next: Section C.2.45, Prev: Section C.2.43, Up: Section C.2
-
-C.2.44. Version 0.98p7
-----------------------
-
- * Fixed opcodes with a third byte-sized immediate argument to not
- complain if given "byte" on the immediate.
-
- * Allow `%undef' to remove single-line macros with arguments. This
- matches the behaviour of #undef in the C preprocessor.
-
- * Allow -d, -u, -i and -p to be specified as -D, -U, -I and -P for
- compatibility with most C compilers and preprocessors. This allows
- Makefile options to be shared between cc and nasm, for example.
-
- * Minor cleanups.
-
- * Went through the list of Katmai instructions and hopefully fixed
- the (rather few) mistakes in it.
-
- * (Hopefully) fixed a number of disassembler bugs related to
- ambiguous instructions (disambiguated by -p) and SSE instructions
- with REP.
-
- * Fix for bug reported by Mark Junger: "call dword 0x12345678"
- should work and may add an OSP (affected CALL, JMP, Jcc).
-
- * Fix for environments when "stderr" isn't a compile-time constant.
-
-
-File: nasm.info, Node: Section C.2.45, Next: Section C.2.46, Prev: Section C.2.44, Up: Section C.2
-
-C.2.45. Version 0.98p6
-----------------------
-
- * Took officially over coordination of the 0.98 release; so drop the
- p3.x notation. Skipped p4 and p5 to avoid confusion with John
- Fine's J4 and J5 releases.
-
- * Update the documentation; however, it still doesn't include
- documentation for the various new instructions. I somehow wonder
- if it makes sense to have an instruction set reference in the
- assembler manual when Intel et al have PDF versions of their
- manuals online.
-
- * Recognize "idt" or "centaur" for the -p option to ndisasm.
-
- * Changed error messages back to stderr where they belong, but add
- an -E option to redirect them elsewhere (the DOS shell cannot
- redirect stderr.)
-
- * -M option to generate Makefile dependencies (based on code from
- Alex Verstak.)
-
- * `%undef' preprocessor directive, and -u option, that undefines a
- single-line macro.
-
- * OS/2 Makefile (Mkfiles/Makefile.os2) for Borland under OS/2; from
- Chuck Crayne.
-
- * Various minor bugfixes (reported by): - Dangling `%s' in preproc.c
- (Martin Junker)
-
- * THERE ARE KNOWN BUGS IN SSE AND THE OTHER KATMAI INSTRUCTIONS. I
- am on a trip and didn't bring the Katmai instruction reference, so
- I can't work on them right now.
-
- * Updated the License file per agreement with Simon and Jules to
- include a GPL distribution clause.
-
-
-File: nasm.info, Node: Section C.2.46, Next: Section C.2.47, Prev: Section C.2.45, Up: Section C.2
-
-C.2.46. Version 0.98p3.7
-------------------------
-
- * (Hopefully) fixed the canned Makefiles to include the outrdf2 and
- zoutieee modules.
-
- * Renamed changes.asm to changed.asm.
-
-
-File: nasm.info, Node: Section C.2.47, Next: Section C.2.48, Prev: Section C.2.46, Up: Section C.2
-
-C.2.47. Version 0.98p3.6
-------------------------
-
- * Fixed a bunch of instructions that were added in 0.98p3.5 which
- had memory operands, and the address-size prefix was missing from
- the instruction pattern.
-
-
-File: nasm.info, Node: Section C.2.48, Next: Section C.2.49, Prev: Section C.2.47, Up: Section C.2
-
-C.2.48. Version 0.98p3.5
-------------------------
-
- * Merged in changes from John S. Fine's 0.98-J5 release. John's
- based 0.98-J5 on my 0.98p3.3 release; this merges the changes.
-
- * Expanded the instructions flag field to a long so we can fit more
- flags; mark SSE (KNI) and AMD or Katmai-specific instructions as
- such.
-
- * Fix the "PRIV" flag on a bunch of instructions, and create new
- "PROT" flag for protected-mode-only instructions (orthogonal to if
- the instruction is privileged!) and new "SMM" flag for SMM-only
- instructions.
-
- * Added AMD-only SYSCALL and SYSRET instructions.
-
- * Make SSE actually work, and add new Katmai MMX instructions.
-
- * Added a -p (preferred vendor) option to ndisasm so that it can
- distinguish e.g. Cyrix opcodes also used in SSE. For example:
-
- ndisasm -p cyrix aliased.bin
- 00000000 670F514310 paddsiw mm0,[ebx+0x10]
- 00000005 670F514320 paddsiw mm0,[ebx+0x20]
- ndisasm -p intel aliased.bin
- 00000000 670F514310 sqrtps xmm0,[ebx+0x10]
- 00000005 670F514320 sqrtps xmm0,[ebx+0x20]
-
- * Added a bunch of Cyrix-specific instructions.
-
-
-File: nasm.info, Node: Section C.2.49, Next: Section C.2.50, Prev: Section C.2.48, Up: Section C.2
-
-C.2.49. Version 0.98p3.4
-------------------------
-
- * Made at least an attempt to modify all the additional Makefiles
- (in the Mkfiles directory). I can't test it, but this was the best
- I could do.
-
- * DOS DJGPP+"Opus Make" Makefile from John S. Fine.
-
- * changes.asm changes from John S. Fine.
-
-
-File: nasm.info, Node: Section C.2.50, Next: Section C.2.51, Prev: Section C.2.49, Up: Section C.2
-
-C.2.50. Version 0.98p3.3
-------------------------
-
- * Patch from Conan Brink to allow nesting of `%rep' directives.
-
- * If we're going to allow INT01 as an alias for INT1/ICEBP (one of
- Jules 0.98p3 changes), then we should allow INT03 as an alias for
- INT3 as well.
-
- * Updated changes.asm to include the latest changes.
-
- * Tried to clean up the <CR>s that had snuck in from a DOS/Windows
- environment into my Unix environment, and try to make sure than
- DOS/Windows users get them back.
-
- * We would silently generate broken tools if insns.dat wasn't sorted
- properly. Change insns.pl so that the order doesn't matter.
-
- * Fix bug in insns.pl (introduced by me) which would cause
- conditional instructions to have an extra "cc" in disassembly,
- e.g. "jnz" disassembled as "jccnz".
-
-
-File: nasm.info, Node: Section C.2.51, Next: Section C.2.52, Prev: Section C.2.50, Up: Section C.2
-
-C.2.51. Version 0.98p3.2
-------------------------
-
- * Merged in John S. Fine's changes from his 0.98-J4 prerelease; see
- http://www.csoft.net/cz/johnfine/
-
- * Changed previous "spotless" Makefile target (appropriate for
- distribution) to "distclean", and added "cleaner" target which is
- same as "clean" except deletes files generated by Perl scripts;
- "spotless" is union.
-
- * Removed BASIC programs from distribution. Get a Perl interpreter
- instead (see below.)
-
- * Calling this "pre-release 3.2" rather than "p3-hpa2" because of
- John's contributions.
-
- * Actually link in the IEEE output format (zoutieee.c); fix a bunch
- of compiler warnings in that file. Note I don't know what IEEE
- output is supposed to look like, so these changes were made
- "blind".
-
-
-File: nasm.info, Node: Section C.2.52, Next: Section C.2.53, Prev: Section C.2.51, Up: Section C.2
-
-C.2.52. Version 0.98p3-hpa
---------------------------
-
- * Merged nasm098p3.zip with nasm-0.97.tar.gz to create a fully
- buildable version for Unix systems (Makefile.in updates, etc.)
-
- * Changed insns.pl to create the instruction tables in nasm.h and
- names.c, so that a new instruction can be added by adding it
- *only* to insns.dat.
-
- * Added the following new instructions: SYSENTER, SYSEXIT, FXSAVE,
- FXRSTOR, UD1, UD2 (the latter two are two opcodes that Intel
- guarantee will never be used; one of them is documented as UD2 in
- Intel documentation, the other one just as "Undefined Opcode" ---
- calling it UD1 seemed to make sense.)
-
- * MAX_SYMBOL was defined to be 9, but LOADALL286 and LOADALL386 are
- 10 characters long. Now MAX_SYMBOL is derived from insns.dat.
-
- * A note on the BASIC programs included: forget them. insns.bas is
- already out of date. Get yourself a Perl interpreter for your
- platform of choice at http://www.cpan.org/ports/index.html.
-
-
-File: nasm.info, Node: Section C.2.53, Next: Section C.2.54, Prev: Section C.2.52, Up: Section C.2
-
-C.2.53. Version 0.98 pre-release 3
-----------------------------------
-
- * added response file support, improved command line handling, new
- layout help screen
-
- * fixed limit checking bug, 'OUT byte nn, reg' bug, and a couple of
- rdoff related bugs, updated Wishlist; 0.98 Prerelease 3.
-
-
-File: nasm.info, Node: Section C.2.54, Next: Section C.2.55, Prev: Section C.2.53, Up: Section C.2
-
-C.2.54. Version 0.98 pre-release 2
-----------------------------------
-
- * fixed bug in outcoff.c to do with truncating section names longer
- than 8 characters, referencing beyond end of string; 0.98
- pre-release 2
-
-
-File: nasm.info, Node: Section C.2.55, Next: Section C.3, Prev: Section C.2.54, Up: Section C.2
-
-C.2.55. Version 0.98 pre-release 1
-----------------------------------
-
- * Fixed a bug whereby STRUC didn't work at all in RDF.
-
- * Fixed a problem with group specification in PUBDEFs in OBJ.
-
- * Improved ease of adding new output formats. Contribution due to
- Fox Cutter.
-
- * Fixed a bug in relocations in the `bin' format: was showing up
- when a relocatable reference crossed an 8192-byte boundary in any
- output section.
-
- * Fixed a bug in local labels: local-label lookups were inconsistent
- between passes one and two if an EQU occurred between the
- definition of a global label and the subsequent use of a local
- label local to that global.
-
- * Fixed a seg-fault in the preprocessor (again) which happened when
- you use a blank line as the first line of a multi-line macro
- definition and then defined a label on the same line as a call to
- that macro.
-
- * Fixed a stale-pointer bug in the handling of the NASM environment
- variable. Thanks to Thomas McWilliams.
-
- * ELF had a hard limit on the number of sections which caused
- segfaults when transgressed. Fixed.
-
- * Added ability for ndisasm to read from stdin by using `-' as the
- filename.
-
- * ndisasm wasn't outputting the TO keyword. Fixed.
-
- * Fixed error cascade on bogus expression in `%if' - an error in
- evaluation was causing the entire `%if' to be discarded, thus
- creating trouble later when the `%else' or `%endif' was
- encountered.
-
- * Forward reference tracking was instruction-granular not operand-
- granular, which was causing 286-specific code to be generated
- needlessly on code of the form `shr word [forwardref],1'. Thanks
- to Jim Hague for sending a patch.
-
- * All messages now appear on stdout, as sending them to stderr
- serves no useful purpose other than to make redirection difficult.
-
- * Fixed the problem with EQUs pointing to an external symbol - this
- now generates an error message.
-
- * Allowed multiple size prefixes to an operand, of which only the
- first is taken into account.
-
- * Incorporated John Fine's changes, including fixes of a large
- number of preprocessor bugs, some small problems in OBJ, and a
- reworking of label handling to define labels before their line is
- assembled, rather than after.
-
- * Reformatted a lot of the source code to be more readable. Included
- 'coding.txt' as a guideline for how to format code for
- contributors.
-
- * Stopped nested `%reps' causing a panic - they now cause a slightly
- more friendly error message instead.
-
- * Fixed floating point constant problems (patch by Pedro Gimeno)
-
- * Fixed the return value of insn_size() not being checked for -1,
- indicating an error.
-
- * Incorporated 3Dnow! instructions.
-
- * Fixed the 'mov eax, eax + ebx' bug.
-
- * Fixed the GLOBAL EQU bug in ELF. Released developers release 3.
-
- * Incorporated John Fine's command line parsing changes
-
- * Incorporated David Lindauer's OMF debug support
-
- * Made changes for LCC 4.0 support (`__NASM_CDecl__', removed
- register size specification warning when sizes agree).
-
-
-File: nasm.info, Node: Section C.3, Next: Section C.3.1, Prev: Section C.2.55, Up: Appendix C
-
-C.3. NASM 0.9 Series
-====================
-
-Revisions before 0.98.
-
-* Menu:
-
-* Section C.3.1:: Version 0.97 released December 1997
-* Section C.3.2:: Version 0.96 released November 1997
-* Section C.3.3:: Version 0.95 released July 1997
-* Section C.3.4:: Version 0.94 released April 1997
-* Section C.3.5:: Version 0.93 released January 1997
-* Section C.3.6:: Version 0.92 released January 1997
-* Section C.3.7:: Version 0.91 released November 1996
-* Section C.3.8:: Version 0.90 released October 1996
-
-
-File: nasm.info, Node: Section C.3.1, Next: Section C.3.2, Prev: Section C.3, Up: Section C.3
-
-C.3.1. Version 0.97 released December 1997
-------------------------------------------
-
- * This was entirely a bug-fix release to 0.96, which seems to have
- got cursed. Silly me.
-
- * Fixed stupid mistake in OBJ which caused `MOV EAX,<constant>' to
- fail. Caused by an error in the `MOV EAX,<segment>' support.
-
- * ndisasm hung at EOF when compiled with lcc on Linux because lcc on
- Linux somehow breaks feof(). ndisasm now does not rely on feof().
-
- * A heading in the documentation was missing due to a markup error
- in the indexing. Fixed.
-
- * Fixed failure to update all pointers on realloc() within extended-
- operand code in parser.c. Was causing wrong behaviour and seg
- faults on lines such as `dd 0.0,0.0,0.0,0.0,...'
-
- * Fixed a subtle preprocessor bug whereby invoking one multi-line
- macro on the first line of the expansion of another, when the
- second had been invoked with a label defined before it, didn't
- expand the inner macro.
-
- * Added internal.doc back in to the distribution archives - it was
- missing in 0.96 *blush*
-
- * Fixed bug causing 0.96 to be unable to assemble its own test files,
- specifically objtest.asm. *blush again*
-
- * Fixed seg-faults and bogus error messages caused by mismatching
- `%rep' and `%endrep' within multi-line macro definitions.
-
- * Fixed a problem with buffer overrun in OBJ, which was causing
- corruption at ends of long PUBDEF records.
-
- * Separated DOS archives into main-program and documentation to
- reduce download size.
-
-
-File: nasm.info, Node: Section C.3.2, Next: Section C.3.3, Prev: Section C.3.1, Up: Section C.3
-
-C.3.2. Version 0.96 released November 1997
-------------------------------------------
-
- * Fixed a bug whereby, if `nasm sourcefile' would cause a filename
- collision warning and put output into `nasm.out', then `nasm
- sourcefile -o outputfile' still gave the warning even though the
- `-o' was honoured. Fixed name pollution under Digital UNIX: one of
- its header files defined R_SP, which broke the enum in nasm.h.
-
- * Fixed minor instruction table problems: FUCOM and FUCOMP didn't
- have two- operand forms; NDISASM didn't recognise the longer
- register forms of PUSH and POP (eg FF F3 for PUSH BX); TEST
- mem,imm32 was flagged as undocumented; the 32-bit forms of CMOV
- had 16-bit operand size prefixes; `AAD imm' and `AAM imm' are no
- longer flagged as undocumented because the Intel Architecture
- reference documents them.
-
- * Fixed a problem with the local-label mechanism, whereby strange
- types of symbol (EQUs, auto-defined OBJ segment base symbols)
- interfered with the `previous global label' value and screwed up
- local labels.
-
- * Fixed a bug whereby the stub preprocessor didn't communicate with
- the listing file generator, so that the -a and -l options in
- conjunction would produce a useless listing file.
-
- * Merged `os2' object file format back into `obj', after discovering
- that `obj' _also_ shouldn't have a link pass separator in a module
- containing a non-trivial MODEND. Flat segments are now declared
- using the FLAT attribute. `os2' is no longer a valid object format
- name: use `obj'.
-
- * Removed the fixed-size temporary storage in the evaluator. Very
- very long expressions (like `mov ax,1+1+1+1+...' for two hundred
- 1s or so) should now no longer crash NASM.
-
- * Fixed a bug involving segfaults on disassembly of MMX
- instructions, by changing the meaning of one of the operand-type
- flags in nasm.h. This may cause other apparently unrelated MMX
- problems; it needs to be tested thoroughly.
-
- * Fixed some buffer overrun problems with large OBJ output files.
- Thanks to DJ Delorie for the bug report and fix.
-
- * Made preprocess-only mode actually listen to the `%line' markers
- as it prints them, so that it can report errors more sanely.
-
- * Re-designed the evaluator to keep more sensible track of
- expressions involving forward references: can now cope with
- previously-nightmare situations such as:
-
- mov ax,foo | bar
- foo equ 1
- bar equ 2
-
- * Added the ALIGN and ALIGNB standard macros.
-
- * Added PIC support in ELF: use of WRT to obtain the four extra
- relocation types needed.
-
- * Added the ability for output file formats to define their own
- extensions to the GLOBAL, COMMON and EXTERN directives.
-
- * Implemented common-variable alignment, and global-symbol type and
- size declarations, in ELF.
-
- * Implemented NEAR and FAR keywords for common variables, plus
- far-common element size specification, in OBJ.
-
- * Added a feature whereby EXTERNs and COMMONs in OBJ can be given a
- default WRT specification (either a segment or a group).
-
- * Transformed the Unix NASM archive into an auto-configuring package.
-
- * Added a sanity-check for people applying SEG to things which are
- already segment bases: this previously went unnoticed by the SEG
- processing and caused OBJ-driver panics later.
-
- * Added the ability, in OBJ format, to deal with `MOV EAX,<segment>'
- type references: OBJ doesn't directly support dword-size segment
- base fixups, but as long as the low two bytes of the constant term
- are zero, a word-size fixup can be generated instead and it will
- work.
-
- * Added the ability to specify sections' alignment requirements in
- Win32 object files and pure binary files.
-
- * Added preprocess-time expression evaluation: the `%assign' (and
- `%iassign') directive and the bare `%if' (and `%elif')
- conditional. Added relational operators to the evaluator, for use
- only in `%if' constructs: the standard relationals = < > <= >= <>
- (and C-like synonyms == and !=) plus low-precedence logical
- operators &&, ^^ and ||.
-
- * Added a preprocessor repeat construct: `%rep' / `%exitrep' /
- `%endrep'.
-
- * Added the __FILE__ and __LINE__ standard macros.
-
- * Added a sanity check for number constants being greater than
- 0xFFFFFFFF. The warning can be disabled.
-
- * Added the %0 token whereby a variadic multi-line macro can tell
- how many parameters it's been given in a specific invocation.
-
- * Added `%rotate', allowing multi-line macro parameters to be cycled.
-
- * Added the `*' option for the maximum parameter count on multi-line
- macros, allowing them to take arbitrarily many parameters.
-
- * Added the ability for the user-level forms of EXTERN, GLOBAL and
- COMMON to take more than one argument.
-
- * Added the IMPORT and EXPORT directives in OBJ format, to deal with
- Windows DLLs.
-
- * Added some more preprocessor `%if' constructs: `%ifidn' /
- `%ifidni' (exact textual identity), and `%ifid' / `%ifnum' /
- `%ifstr' (token type testing).
-
- * Added the ability to distinguish SHL AX,1 (the 8086 version) from
- SHL AX,BYTE 1 (the 286-and-upwards version whose constant happens
- to be 1).
-
- * Added NetBSD/FreeBSD/OpenBSD's variant of a.out format, complete
- with PIC shared library features.
-
- * Changed NASM's idiosyncratic handling of FCLEX, FDISI, FENI,
- FINIT, FSAVE, FSTCW, FSTENV, and FSTSW to bring it into line with
- the otherwise accepted standard. The previous behaviour, though it
- was a deliberate feature, was a deliberate feature based on a
- misunderstanding. Apologies for the inconvenience.
-
- * Improved the flexibility of ABSOLUTE: you can now give it an
- expression rather than being restricted to a constant, and it can
- take relocatable arguments as well.
-
- * Added the ability for a variable to be declared as EXTERN multiple
- times, and the subsequent definitions are just ignored.
-
- * We now allow instruction prefixes (CS, DS, LOCK, REPZ etc) to be
- alone on a line (without a following instruction).
-
- * Improved sanity checks on whether the arguments to EXTERN, GLOBAL
- and COMMON are valid identifiers.
-
- * Added misc/exebin.mac to allow direct generation of .EXE files by
- hacking up an EXE header using DB and DW; also added
- test/binexe.asm to demonstrate the use of this. Thanks to Yann
- Guidon for contributing the EXE header code.
-
- * ndisasm forgot to check whether the input file had been
- successfully opened. Now it does. Doh!
-
- * Added the Cyrix extensions to the MMX instruction set.
-
- * Added a hinting mechanism to allow [EAX+EBX] and [EBX+EAX] to be
- assembled differently. This is important since [ESI+EBP] and
- [EBP+ESI] have different default base segment registers.
-
- * Added support for the PharLap OMF extension for 4096-byte segment
- alignment.
-
diff --git a/doc/info/nasm.info-3 b/doc/info/nasm.info-3
deleted file mode 100644
index f70d131..0000000
--- a/doc/info/nasm.info-3
+++ /dev/null
@@ -1,1284 +0,0 @@
-This is nasm.info, produced by makeinfo version 4.13 from nasmdoc.texi.
-
-INFO-DIR-SECTION Programming
-START-INFO-DIR-ENTRY
-* NASM: (nasm). The Netwide Assembler for x86.
-END-INFO-DIR-ENTRY
-
- This file documents NASM, the Netwide Assembler: an assembler
-targetting the Intel x86 series of processors, with portable source.
-
- Copyright 1996-2009 The NASM Development Team
-
- This document is redistributable under the license given in the file
-"COPYING" distributed in the NASM archive.
-
-
-File: nasm.info, Node: Section C.3.3, Next: Section C.3.4, Prev: Section C.3.2, Up: Section C.3
-
-C.3.3. Version 0.95 released July 1997
---------------------------------------
-
- * Fixed yet another ELF bug. This one manifested if the user relied
- on the default segment, and attempted to define global symbols
- without first explicitly declaring the target segment.
-
- * Added makefiles (for NASM and the RDF tools) to build Win32
- console apps under Symantec C++. Donated by Mark Junker.
-
- * Added `macros.bas' and `insns.bas', QBasic versions of the Perl
- scripts that convert `standard.mac' to `macros.c' and convert
- `insns.dat' to `insnsa.c' and `insnsd.c'. Also thanks to Mark
- Junker.
-
- * Changed the diassembled forms of the conditional instructions so
- that JB is now emitted as JC, and other similar changes. Suggested
- list by Ulrich Doewich.
-
- * Added `@' to the list of valid characters to begin an identifier
- with.
-
- * Documentary changes, notably the addition of the `Common Problems'
- section in nasm.doc.
-
- * Fixed a bug relating to 32-bit PC-relative fixups in OBJ.
-
- * Fixed a bug in perm_copy() in labels.c which was causing
- exceptions in cleanup_labels() on some systems.
-
- * Positivity sanity check in TIMES argument changed from a warning
- to an error following a further complaint.
-
- * Changed the acceptable limits on byte and word operands to allow
- things like `~10111001b' to work.
-
- * Fixed a major problem in the preprocessor which caused seg-faults
- if macro definitions contained blank lines or comment-only lines.
-
- * Fixed inadequate error checking on the commas separating the
- arguments to `db', `dw' etc.
-
- * Fixed a crippling bug in the handling of macros with operand
- counts defined with a `+' modifier.
-
- * Fixed a bug whereby object file formats which stored the input
- file name in the output file (such as OBJ and COFF) weren't doing
- so correctly when the output file name was specified on the
- command line.
-
- * Removed [INC] and [INCLUDE] support for good, since they were
- obsolete anyway.
-
- * Fixed a bug in OBJ which caused all fixups to be output in 16-bit
- (old- format) FIXUPP records, rather than putting the 32-bit ones
- in FIXUPP32 (new-format) records.
-
- * Added, tentatively, OS/2 object file support (as a minor variant
- on OBJ).
-
- * Updates to Fox Cutter's Borland C makefile, Makefile.bc2.
-
- * Removed a spurious second fclose() on the output file.
-
- * Added the `-s' command line option to redirect all messages which
- would go to stderr (errors, help text) to stdout instead.
-
- * Added the `-w' command line option to selectively suppress some
- classes of assembly warning messages.
-
- * Added the `-p' pre-include and `-d' pre-define command-line
- options.
-
- * Added an include file search path: the `-i' command line option.
-
- * Fixed a silly little preprocessor bug whereby starting a line with
- a `%!' environment-variable reference caused an `unknown
- directive' error.
-
- * Added the long-awaited listing file support: the `-l' command line
- option.
-
- * Fixed a problem with OBJ format whereby, in the absence of any
- explicit segment definition, non-global symbols declared in the
- implicit default segment generated spurious EXTDEF records in the
- output.
-
- * Added the NASM environment variable.
-
- * From this version forward, Win32 console-mode binaries will be
- included in the DOS distribution in addition to the 16-bit
- binaries. Added Makefile.vc for this purpose.
-
- * Added `return 0;' to test/objlink.c to prevent compiler warnings.
-
- * Added the __NASM_MAJOR__ and __NASM_MINOR__ standard defines.
-
- * Added an alternative memory-reference syntax in which prefixing an
- operand with `&' is equivalent to enclosing it in square brackets,
- at the request of Fox Cutter.
-
- * Errors in pass two now cause the program to return a non-zero
- error code, which they didn't before.
-
- * Fixed the single-line macro cycle detection, which didn't work at
- all on macros with no parameters (caused an infinite loop). Also
- changed the behaviour of single-line macro cycle detection to work
- like cpp, so that macros like `extrn' as given in the
- documentation can be implemented.
-
- * Fixed the implementation of WRT, which was too restrictive in that
- you couldn't do `mov ax,[di+abc wrt dgroup]' because (di+abc)
- wasn't a relocatable reference.
-
-
-File: nasm.info, Node: Section C.3.4, Next: Section C.3.5, Prev: Section C.3.3, Up: Section C.3
-
-C.3.4. Version 0.94 released April 1997
----------------------------------------
-
- * Major item: added the macro processor.
-
- * Added undocumented instructions SMI, IBTS, XBTS and LOADALL286.
- Also reorganised CMPXCHG instruction into early-486 and Pentium
- forms. Thanks to Thobias Jones for the information.
-
- * Fixed two more stupid bugs in ELF, which were causing `ld' to
- continue to seg-fault in a lot of non-trivial cases.
-
- * Fixed a seg-fault in the label manager.
-
- * Stopped FBLD and FBSTP from _requiring_ the TWORD keyword, which
- is the only option for BCD loads/stores in any case.
-
- * Ensured FLDCW, FSTCW and FSTSW can cope with the WORD keyword, if
- anyone bothers to provide it. Previously they complained unless no
- keyword at all was present.
-
- * Some forms of FDIV/FDIVR and FSUB/FSUBR were still inverted: a
- vestige of a bug that I thought had been fixed in 0.92. This was
- fixed, hopefully for good this time...
-
- * Another minor phase error (insofar as a phase error can _ever_ be
- minor) fixed, this one occurring in code of the form
-
- rol ax,forward_reference
- forward_reference equ 1
-
- * The number supplied to TIMES is now sanity-checked for positivity,
- and also may be greater than 64K (which previously didn't work on
- 16-bit systems).
-
- * Added Watcom C makefiles, and misc/pmw.bat, donated by Dominik
- Behr.
-
- * Added the INCBIN pseudo-opcode.
-
- * Due to the advent of the preprocessor, the [INCLUDE] and [INC]
- directives have become obsolete. They are still supported in this
- version, with a warning, but won't be in the next.
-
- * Fixed a bug in OBJ format, which caused incorrect object records
- to be output when absolute labels were made global.
-
- * Updates to RDOFF subdirectory, and changes to outrdf.c.
-
-
-File: nasm.info, Node: Section C.3.5, Next: Section C.3.6, Prev: Section C.3.4, Up: Section C.3
-
-C.3.5. Version 0.93 released January 1997
------------------------------------------
-
-This release went out in a great hurry after semi-crippling bugs were
-found in 0.92.
-
- * Really _did_ fix the stack overflows this time. *blush*
-
- * Had problems with EA instruction sizes changing between passes,
- when an offset contained a forward reference and so 4 bytes were
- allocated for the offset in pass one; by pass two the symbol had
- been defined and happened to be a small absolute value, so only 1
- byte got allocated, causing instruction size mismatch between
- passes and hence incorrect address calculations. Fixed.
-
- * Stupid bug in the revised ELF section generation fixed (associated
- string- table section for .symtab was hard-coded as 7, even when
- this didn't fit with the real section table). Was causing `ld' to
- seg-fault under Linux.
-
- * Included a new Borland C makefile, Makefile.bc2, donated by Fox
- Cutter <lmb@comtch.iea.com>.
-
-
-File: nasm.info, Node: Section C.3.6, Next: Section C.3.7, Prev: Section C.3.5, Up: Section C.3
-
-C.3.6. Version 0.92 released January 1997
------------------------------------------
-
- * The FDIVP/FDIVRP and FSUBP/FSUBRP pairs had been inverted: this
- was fixed. This also affected the LCC driver.
-
- * Fixed a bug regarding 32-bit effective addresses of the form
- `[other_register+ESP]'.
-
- * Documentary changes, notably documentation of the fact that
- Borland Win32 compilers use `obj' rather than `win32' object
- format.
-
- * Fixed the COMENT record in OBJ files, which was formatted
- incorrectly.
-
- * Fixed a bug causing segfaults in large RDF files.
-
- * OBJ format now strips initial periods from segment and group
- definitions, in order to avoid complications with the local label
- syntax.
-
- * Fixed a bug in disassembling far calls and jumps in NDISASM.
-
- * Added support for user-defined sections in COFF and ELF files.
-
- * Compiled the DOS binaries with a sensible amount of stack, to
- prevent stack overflows on any arithmetic expression containing
- parentheses.
-
- * Fixed a bug in handling of files that do not terminate in a
- newline.
-
-
-File: nasm.info, Node: Section C.3.7, Next: Section C.3.8, Prev: Section C.3.6, Up: Section C.3
-
-C.3.7. Version 0.91 released November 1996
-------------------------------------------
-
- * Loads of bug fixes.
-
- * Support for RDF added.
-
- * Support for DBG debugging format added.
-
- * Support for 32-bit extensions to Microsoft OBJ format added.
-
- * Revised for Borland C: some variable names changed, makefile added.
-
- * LCC support revised to actually work.
-
- * JMP/CALL NEAR/FAR notation added.
-
- * `a16', `o16', `a32' and `o32' prefixes added.
-
- * Range checking on short jumps implemented.
-
- * MMX instruction support added.
-
- * Negative floating point constant support added.
-
- * Memory handling improved to bypass 64K barrier under DOS.
-
- * `$' prefix to force treatment of reserved words as identifiers
- added.
-
- * Default-size mechanism for object formats added.
-
- * Compile-time configurability added.
-
- * `#', `@', `~' and c{?} are now valid characters in labels.
-
- * `-e' and `-k' options in NDISASM added.
-
-
-File: nasm.info, Node: Section C.3.8, Prev: Section C.3.7, Up: Section C.3
-
-C.3.8. Version 0.90 released October 1996
------------------------------------------
-
-First release version. First support for object file output. Other
-changes from previous version (0.3x) too numerous to document.
-
-
-File: nasm.info, Node: Index, Up: Top
-
-Index
-*****
-
-* Menu:
-
-* `!' operator, unary (1): Section 3.5.7.
-* `!=' operator (1): Section 4.4.4.
-* `$$' token (1): Section 3.5.
-* `$$' token (2): Section 7.9.3.
-* `$', Here token (1): Section 3.5.
-* `$', prefix (1): Section 3.1.
-* `$', prefix (2): Section 3.4.1.
-* `$', prefix (3): Section 7.13.2.
-* `%' operator (1): Section 3.5.6.
-* `%!' (1): Section 4.10.2.
-* `%$' and `%$$' prefixes (1): Section 4.7.2.
-* `%%' operator (1): Section 3.5.6.
-* `%%' operator (2): Section 4.3.3.
-* `%+' (1): Section 4.1.4.
-* `%?' (1): Section 4.1.5.
-* `%??' (1): Section 4.1.5.
-* `%[' (1): Section 4.1.3.
-* `&' operator (1): Section 3.5.3.
-* `&&' operator (1): Section 4.4.4.
-* `*' operator (1): Section 3.5.6.
-* `+' modifier (1): Section 4.3.4.
-* `+' operator, binary (1): Section 3.5.5.
-* `+' operator, unary (1): Section 3.5.7.
-* `-' operator, binary (1): Section 3.5.5.
-* `-' operator, unary (1): Section 3.5.7.
-* `..@' symbol prefix (1): Section 3.9.
-* `..@' symbol prefix (2): Section 4.3.3.
-* `/' operator (1): Section 3.5.6.
-* `//' operator (1): Section 3.5.6.
-* `<' operator (1): Section 4.4.4.
-* `<<' operator (1): Section 3.5.4.
-* `<=' operator (1): Section 4.4.4.
-* `<>' operator (1): Section 4.4.4.
-* `=' operator (1): Section 4.4.4.
-* `==' operator (1): Section 4.4.4.
-* `>' operator (1): Section 4.4.4.
-* `>=' operator (1): Section 4.4.4.
-* `>>' operator (1): Section 3.5.4.
-* `?' MASM syntax (1): Section 3.2.2.
-* `^' operator (1): Section 3.5.2.
-* `^^' operator (1): Section 4.4.4.
-* `|' operator (1): Section 3.5.1.
-* `||' operator (1): Section 4.4.4.
-* `~' operator (1): Section 3.5.7.
-* `%0' parameter count (1): Section 4.3.5.
-* `%0' parameter count (2): Section 4.3.6.
-* `%+1' and `%-1' syntax (1): Section 4.3.9.
-* 16-bit mode, versus 32-bit mode (1): Section 6.1.
-* 64-bit displacement (1): Section 11.2.
-* 64-bit immediate (1): Section 11.2.
-* `-a' option (1): Section 2.1.21.
-* `-a' option (2): Section A.3.3.
-* `A16' (1): Section 3.1.
-* `a16' (1): Section 10.3.
-* `A32' (1): Section 3.1.
-* `a32' (1): Section 10.3.
-* `A64' (1): Section 3.1.
-* `a64' (1): Section 10.3.
-* `a86' (1): Section 1.1.1.
-* `a86' (2): Section 2.2.
-* `a86' (3): Section 2.2.2.
-* `a86' (4): Section 2.2.6.
-* `ABS' (1): Section 3.3.
-* `ABSOLUTE' (1): Section 6.4.
-* `ABSOLUTE' (2): Section 7.4.1.
-* addition (1): Section 3.5.5.
-* addressing, mixed-size (1): Section 10.2.
-* address-size prefixes (1): Section 3.1.
-* algebra (1): Section 3.3.
-* `ALIGN' (1): Section 4.11.12.
-* `ALIGN' (2): Section 5.2.
-* `ALIGN' (3): Section 7.1.2.
-* `ALIGN' (4): Section 7.4.1.
-* `ALIGN', smart (1): Section 5.2.
-* `ALIGNB' (1): Section 4.11.12.
-* alignment, in `bin' sections (1): Section 7.1.2.
-* alignment, in `elf' sections (1): Section 7.9.2.
-* alignment, in `obj' sections (1): Section 7.4.1.
-* alignment, in `win32' sections (1): Section 7.5.1.
-* alignment, of `elf' common variables (1): Section 7.9.6.
-* `ALIGNMODE' (1): Section 5.2.
-* `__ALIGNMODE__' (1): Section 5.2.
-* `ALINK' (1): Section 8.1.1.
-* `alink.sourceforge.net' (1): Section 8.1.1.
-* `all' (1): Section 2.1.24.
-* `alloc' (1): Section 7.9.2.
-* alternate register names (1): Section 5.1.
-* `alt.lang.asm' (1): Section 1.1.1.
-* `altreg' (1): Section 5.1.
-* ambiguity (1): Section 2.2.3.
-* `a.out', BSD version (1): Section 7.11.
-* `a.out', Linux version (1): Section 7.10.
-* `aout' (1): Section 7.10.
-* `aoutb' (1): Section 7.11.
-* `aoutb' (2): Section 9.2.
-* `%arg' (1): Section 4.8.1.
-* `arg' (1): Section 8.4.5.
-* `arg' (2): Section 9.1.4.
-* `as86' (1): Section 1.1.1.
-* `as86' (2): Section 7.12.
-* assembler directives (1): Chapter 6.
-* assembly-time options (1): Section 2.1.18.
-* `%assign' (1): Section 4.1.7.
-* `ASSUME' (1): Section 2.2.4.
-* `AT' (1): Section 4.11.11.
-* Autoconf (1): Section 1.3.2.
-* `autoexec.bat' (1): Section 1.3.1.
-* `auto-sync' (1): Section A.3.3.
-* `-b' (1): Section A.3.
-* bin (1): Section 2.1.2.
-* bin (2): Section 7.1.
-* bin, multisection (1): Section 7.1.3.
-* binary (1): Section 3.4.1.
-* binary files (1): Section 3.2.3.
-* bit shift (1): Section 3.5.4.
-* `BITS' (1): Section 6.1.
-* `BITS' (2): Section 7.1.
-* `__BITS__' (1): Section 4.11.5.
-* bitwise AND (1): Section 3.5.3.
-* bitwise OR (1): Section 3.5.1.
-* bitwise XOR (1): Section 3.5.2.
-* block IFs (1): Section 4.7.5.
-* boot loader (1): Section 7.1.
-* boot sector (1): Section 12.1.3.
-* Borland, Pascal (1): Section 8.5.
-* Borland, Win32 compilers (1): Section 7.4.
-* braces, after `%' sign (1): Section 4.3.8.
-* braces, around macro parameters (1): Section 4.3.
-* BSD (1): Section 9.2.
-* `.bss' (1): Section 7.9.2.
-* `.bss' (2): Section 7.10.
-* `.bss' (3): Section 7.11.
-* `.bss' (4): Section 7.12.
-* `.bss' (5): Section 7.13.
-* bugs (1): Section 12.2.
-* `bugtracker' (1): Section 12.2.
-* `BYTE' (1): Section 12.1.1.
-* C calling convention (1): Section 8.4.3.
-* C calling convention (2): Section 9.1.2.
-* C symbol names (1): Section 8.4.1.
-* `c16.mac' (1): Section 8.4.5.
-* `c16.mac' (2): Section 8.5.3.
-* `c32.mac' (1): Section 9.1.4.
-* `CALL FAR' (1): Section 3.6.
-* case sensitivity (1): Section 2.2.1.
-* case sensitivity (2): Section 4.1.1.
-* case sensitivity (3): Section 4.1.2.
-* case sensitivity (4): Section 4.1.7.
-* case sensitivity (5): Section 4.3.
-* case sensitivity (6): Section 4.3.1.
-* case sensitivity (7): Section 4.4.5.
-* case sensitivity (8): Section 7.4.3.
-* changing sections (1): Section 6.3.
-* character constant (1): Section 3.2.1.
-* character constant (2): Section 3.4.3.
-* character strings (1): Section 3.4.2.
-* circular references (1): Section 4.1.1.
-* `CLASS' (1): Section 7.4.1.
-* `%clear' (1): Section 4.11.
-* `coff' (1): Section 7.7.
-* colon (1): Section 3.1.
-* `.COM' (1): Section 7.1.
-* `.COM' (2): Section 8.2.
-* command-line (1): Section 2.1.
-* command-line (2): Chapter 7.
-* commas in macro parameters (1): Section 4.3.4.
-* `.comment' (1): Section 7.9.2.
-* `COMMON' (1): Section 6.7.
-* `COMMON' (2): Section 7.4.1.
-* `COMMON', `elf' extensions to (1): Section 7.9.6.
-* `COMMON', `obj' extensions to (1): Section 7.4.8.
-* Common Object File Format (1): Section 7.7.
-* common variables (1): Section 6.7.
-* common variables, alignment in `elf' (1): Section 7.9.6.
-* common variables, element size (1): Section 7.4.8.
-* `comp.lang.asm.x86' (1): Section 1.1.1.
-* `comp.lang.asm.x86' (2): Section 1.2.
-* `comp.os.msdos.programmer' (1): Section 8.3.
-* concatenating macro parameters (1): Section 4.3.8.
-* concatenating strings (1): Section 4.2.1.
-* condition codes as macro parameters (1): Section 4.3.9.
-* conditional assembly (1): Section 4.4.
-* conditional jumps (1): Section 12.1.2.
-* conditional-return macro (1): Section 4.3.9.
-* `configure' (1): Section 1.3.2.
-* constants (1): Section 3.4.
-* context stack (1): Section 4.7.
-* context stack (2): Section 4.7.5.
-* context-local labels (1): Section 4.7.2.
-* context-local single-line macros (1): Section 4.7.3.
-* counting macro parameters (1): Section 4.3.6.
-* `CPU' (1): Section 6.8.
-* `CPUID' (1): Section 3.4.3.
-* creating contexts (1): Section 4.7.1.
-* critical expression (1): Section 3.2.2.
-* critical expression (2): Section 3.8.
-* critical expression (3): Section 4.1.7.
-* critical expression (4): Section 6.4.
-* `-D' option (1): Section 2.1.18.
-* `-d' option (1): Section 2.1.18.
-* daily development snapshots (1): Section 1.2.
-* `.data' (1): Section 7.9.2.
-* `.data' (2): Section 7.10.
-* `.data' (3): Section 7.11.
-* `.data' (4): Section 7.12.
-* `.data' (5): Section 7.13.
-* `_DATA' (1): Section 8.4.2.
-* `data' (1): Section 7.9.5.
-* `data' (2): Section 7.13.3.
-* data structure (1): Section 8.4.4.
-* data structure (2): Section 9.1.3.
-* `__DATE__' (1): Section 4.11.7.
-* `__DATE_NUM__' (1): Section 4.11.7.
-* `DB' (1): Section 3.2.
-* `DB' (2): Section 3.2.1.
-* `DB' (3): Section 3.4.4.
-* `DB' (4): Section 3.4.6.
-* `dbg' (1): Section 7.14.
-* `DD' (1): Section 3.2.
-* `DD' (2): Section 3.2.1.
-* `DD' (3): Section 3.4.4.
-* `DD' (4): Section 3.4.6.
-* debug information (1): Section 2.1.12.
-* debug information format (1): Section 2.1.11.
-* declaring structures (1): Section 4.11.10.
-* `DEFAULT' (1): Section 6.2.
-* `default' (1): Section 7.9.5.
-* default macro parameters (1): Section 4.3.5.
-* default name (1): Chapter 7.
-* default-`WRT' mechanism (1): Section 7.4.7.
-* `%define' (1): Section 2.1.18.
-* `%define' (2): Section 4.1.1.
-* defining sections (1): Section 6.3.
-* `%defstr' (1): Section 4.1.8.
-* `%deftok' (1): Section 4.1.9.
-* `%depend' (1): Section 4.6.3.
-* design goals (1): Section 2.2.2.
-* DevPac (1): Section 3.2.3.
-* DevPac (2): Section 3.9.
-* disabling listing expansion (1): Section 4.3.10.
-* division (1): Section 3.5.6.
-* DJGPP (1): Section 7.7.
-* DJGPP (2): Chapter 9.
-* `djlink' (1): Section 8.1.1.
-* DLL symbols, exporting (1): Section 7.4.5.
-* DLL symbols, importing (1): Section 7.4.4.
-* `DO' (1): Section 3.2.
-* `DO' (2): Section 3.2.1.
-* `DO' (3): Section 3.4.4.
-* `DO' (4): Section 3.4.6.
-* DOS (1): Section 1.3.1.
-* DOS (2): Section 2.1.14.
-* DOS (3): Section 2.1.15.
-* DOS source archive (1): Section 1.3.1.
-* `DQ' (1): Section 3.2.
-* `DQ' (2): Section 3.2.1.
-* `DQ' (3): Section 3.4.4.
-* `DQ' (4): Section 3.4.6.
-* `.drectve' (1): Section 7.5.1.
-* `DT' (1): Section 3.2.
-* `DT' (2): Section 3.2.1.
-* `DT' (3): Section 3.4.4.
-* `DT' (4): Section 3.4.6.
-* `DUP' (1): Section 2.2.7.
-* `DUP' (2): Section 3.2.5.
-* `DW' (1): Section 3.2.
-* `DW' (2): Section 3.2.1.
-* `DW' (3): Section 3.4.4.
-* `DW' (4): Section 3.4.6.
-* `DWORD' (1): Section 3.1.
-* `DY' (1): Section 3.2.
-* `DY' (2): Section 3.2.1.
-* `DY' (3): Section 3.4.4.
-* `-E' option (1): Section 2.1.20.
-* `-e' option (1): Section 2.1.20.
-* `-e' option (2): Section A.3.4.
-* effective addresses (1): Section 3.1.
-* effective addresses (2): Section 3.3.
-* element size, in common variables (1): Section 7.4.8.
-* ELF (1): Section 7.9.
-* ELF, shared libraries (1): Section 7.9.3.
-* ELF, 16-bit code and (1): Section 7.9.7.
-* elf, debug formats and (1): Section 7.9.8.
-* `elf32' (1): Section 7.9.
-* `elf64' (1): Section 7.9.
-* `%elif' (1): Section 4.4.
-* `%elif' (2): Section 4.4.4.
-* `%elifctx' (1): Section 4.4.3.
-* `%elifdef' (1): Section 4.4.1.
-* `%elifempty' (1): Section 4.4.8.
-* `%elifid' (1): Section 4.4.6.
-* `%elifidn' (1): Section 4.4.5.
-* `%elifidni' (1): Section 4.4.5.
-* `%elifmacro' (1): Section 4.4.2.
-* `%elifn' (1): Section 4.4.
-* `%elifn' (2): Section 4.4.4.
-* `%elifnctx' (1): Section 4.4.3.
-* `%elifndef' (1): Section 4.4.1.
-* `%elifnempty' (1): Section 4.4.8.
-* `%elifnid' (1): Section 4.4.6.
-* `%elifnidn' (1): Section 4.4.5.
-* `%elifnidni' (1): Section 4.4.5.
-* `%elifnmacro' (1): Section 4.4.2.
-* `%elifnnum' (1): Section 4.4.6.
-* `%elifnstr' (1): Section 4.4.6.
-* `%elifntoken' (1): Section 4.4.7.
-* `%elifnum' (1): Section 4.4.6.
-* `%elifstr' (1): Section 4.4.6.
-* `%eliftoken' (1): Section 4.4.7.
-* `%else' (1): Section 4.4.
-* `endproc' (1): Section 8.4.5.
-* `endproc' (2): Section 9.1.4.
-* `%endrep' (1): Section 4.5.
-* `ENDSTRUC' (1): Section 4.11.10.
-* `ENDSTRUC' (2): Section 6.4.
-* environment (1): Section 2.1.28.
-* `EQU' (1): Section 3.2.
-* `EQU' (2): Section 3.2.4.
-* `%error' (1): Section 4.9.
-* `error' (1): Section 2.1.24.
-* error messages (1): Section 2.1.14.
-* error messages (2): Section 2.1.15.
-* error reporting format (1): Section 2.1.13.
-* escape sequences (1): Section 3.4.2.
-* `EVEN' (1): Section 4.11.12.
-* exact matches (1): Section 4.3.11.
-* `.EXE' (1): Section 7.4.
-* `.EXE' (2): Section 8.1.
-* `EXE2BIN' (1): Section 8.2.2.
-* `EXE_begin' (1): Section 8.1.2.
-* `exebin.mac' (1): Section 8.1.2.
-* `exec' (1): Section 7.9.2.
-* Executable and Linkable Format (1): Section 7.9.
-* `EXE_end' (1): Section 8.1.2.
-* `EXE_stack' (1): Section 8.1.2.
-* `%exitmacro' (1): Section 4.3.12.
-* `%exitrep' (1): Section 4.5.
-* `EXPORT' (1): Section 7.4.5.
-* `export' (1): Section 7.13.3.
-* exporting symbols (1): Section 6.6.
-* expressions (1): Section 2.1.20.
-* expressions (2): Section 3.5.
-* extension (1): Section 2.1.1.
-* extension (2): Chapter 7.
-* `EXTERN' (1): Section 6.5.
-* `EXTERN', `obj' extensions to (1): Section 7.4.7.
-* `EXTERN', `rdf' extensions to (1): Section 7.13.4.
-* extracting substrings (1): Section 4.2.3.
-* `-F' option (1): Section 2.1.11.
-* `-f' option (1): Section 2.1.2.
-* `-f' option (2): Chapter 7.
-* far call (1): Section 2.2.5.
-* far common variables (1): Section 7.4.8.
-* far pointer (1): Section 3.6.
-* `FARCODE' (1): Section 8.4.5.
-* `FARCODE' (2): Section 8.5.3.
-* `%fatal' (1): Section 4.9.
-* `__FILE__' (1): Section 4.11.4.
-* `FLAT' (1): Section 7.4.1.
-* flat memory model (1): Chapter 9.
-* flat-form binary (1): Section 7.1.
-* `FLOAT' (1): Section 6.9.
-* `__FLOAT__' (1): Section 6.9.
-* `__float128h__' (1): Section 3.4.6.
-* `__float128l__' (1): Section 3.4.6.
-* `__float16__' (1): Section 3.4.6.
-* `__float32__' (1): Section 3.4.6.
-* `__float64__' (1): Section 3.4.6.
-* `__float8__' (1): Section 3.4.6.
-* `__float80e__' (1): Section 3.4.6.
-* `__float80m__' (1): Section 3.4.6.
-* `__FLOAT_DAZ__' (1): Section 6.9.
-* `float-denorm' (1): Section 2.1.24.
-* floating-point, constants (1): Section 3.4.6.
-* floating-point, constants (2): Section 6.9.
-* floating-point, packed BCD constants (1): Section 3.4.7.
-* floating-point (1): Section 2.2.6.
-* floating-point (2): Section 3.1.
-* floating-point (3): Section 3.2.1.
-* floating-point (4): Section 3.4.6.
-* `float-overflow' (1): Section 2.1.24.
-* `__FLOAT_ROUND__' (1): Section 6.9.
-* `float-toolong' (1): Section 2.1.24.
-* `float-underflow' (1): Section 2.1.24.
-* `follows=' (1): Section 7.1.3.
-* format-specific directives (1): Chapter 6.
-* frame pointer (1): Section 8.4.3.
-* frame pointer (2): Section 8.5.1.
-* frame pointer (3): Section 9.1.2.
-* FreeBSD (1): Section 7.11.
-* FreeBSD (2): Section 9.2.
-* FreeLink (1): Section 8.1.1.
-* `ftp.simtel.net' (1): Section 8.1.1.
-* `function' (1): Section 7.9.5.
-* `function' (2): Section 7.13.3.
-* functions, C calling convention (1): Section 8.4.3.
-* functions, C calling convention (2): Section 9.1.2.
-* functions, Pascal calling convention (1): Section 8.5.1.
-* `-g' option (1): Section 2.1.12.
-* `gas' (1): Section 1.1.1.
-* `gcc' (1): Section 1.1.1.
-* `GLOBAL' (1): Section 6.6.
-* `GLOBAL', `aoutb' extensions to (1): Section 7.9.5.
-* `GLOBAL', `elf' extensions to (1): Section 7.9.5.
-* `GLOBAL', `rdf' extensions to (1): Section 7.13.3.
-* global offset table (1): Section 9.2.
-* `_GLOBAL_OFFSET_TABLE_' (1): Section 7.9.3.
-* `gnu-elf-extensions' (1): Section 2.1.24.
-* `..got' (1): Section 7.9.3.
-* `GOT' relocations (1): Section 9.2.3.
-* GOT (1): Section 7.9.3.
-* GOT (2): Section 9.2.
-* `..gotoff' (1): Section 7.9.3.
-* `GOTOFF' relocations (1): Section 9.2.2.
-* `..gotpc' (1): Section 7.9.3.
-* `GOTPC' relocations (1): Section 9.2.1.
-* `..gottpoff' (1): Section 7.9.4.
-* graphics (1): Section 3.2.3.
-* greedy macro parameters (1): Section 4.3.4.
-* `GROUP' (1): Section 7.4.2.
-* groups (1): Section 3.6.
-* `-h' (1): Section A.3.
-* hexadecimal (1): Section 3.4.1.
-* `hidden' (1): Section 7.9.5.
-* hybrid syntaxes (1): Section 2.2.2.
-* `-I' option (1): Section 2.1.16.
-* `-i' option (1): Section 2.1.16.
-* `-i' option (2): Section A.3.3.
-* `%iassign' (1): Section 4.1.7.
-* `%idefine' (1): Section 4.1.1.
-* `%idefstr' (1): Section 4.1.8.
-* `%ideftok' (1): Section 4.1.9.
-* `IEND' (1): Section 4.11.11.
-* `%if' (1): Section 4.4.
-* `%if' (2): Section 4.4.4.
-* `%ifctx' (1): Section 4.4.3.
-* `%ifctx' (2): Section 4.7.5.
-* `%ifdef' (1): Section 4.4.1.
-* `%ifempty' (1): Section 4.4.8.
-* `%ifid' (1): Section 4.4.6.
-* `%ifidn' (1): Section 4.4.5.
-* `%ifidni' (1): Section 4.4.5.
-* `%ifmacro' (1): Section 4.4.2.
-* `%ifn' (1): Section 4.4.
-* `%ifn' (2): Section 4.4.4.
-* `%ifnctx' (1): Section 4.4.3.
-* `%ifndef' (1): Section 4.4.1.
-* `%ifnempty' (1): Section 4.4.8.
-* `%ifnid' (1): Section 4.4.6.
-* `%ifnidn' (1): Section 4.4.5.
-* `%ifnidni' (1): Section 4.4.5.
-* `%ifnmacro' (1): Section 4.4.2.
-* `%ifnnum' (1): Section 4.4.6.
-* `%ifnstr' (1): Section 4.4.6.
-* `%ifntoken' (1): Section 4.4.7.
-* `%ifnum' (1): Section 4.4.6.
-* `%ifstr' (1): Section 4.4.6.
-* `%iftoken' (1): Section 4.4.7.
-* `%imacro' (1): Section 4.3.
-* `IMPORT' (1): Section 7.4.4.
-* import library (1): Section 7.4.4.
-* importing symbols (1): Section 6.5.
-* `INCBIN' (1): Section 3.2.
-* `INCBIN' (2): Section 3.2.3.
-* `INCBIN' (3): Section 3.4.4.
-* `%include' (1): Section 2.1.16.
-* `%include' (2): Section 2.1.17.
-* `%include' (3): Section 4.6.1.
-* include search path (1): Section 2.1.16.
-* including other files (1): Section 4.6.1.
-* inefficient code (1): Section 12.1.1.
-* infinite loop (1): Section 3.5.
-* `__Infinity__' (1): Section 3.4.6.
-* infinity (1): Section 3.4.6.
-* informational section (1): Section 7.5.1.
-* `INSTALL' (1): Section 1.3.2.
-* installing (1): Section 1.3.1.
-* instances of structures (1): Section 4.11.11.
-* instruction list (1): Appendix B.
-* intel hex (1): Section 7.2.
-* Intel number formats (1): Section 3.4.6.
-* `internal' (1): Section 7.9.5.
-* `%irmacro' (1): Section 4.3.1.
-* `ISTRUC' (1): Section 4.11.11.
-* iterating over macro parameters (1): Section 4.3.7.
-* `ith' (1): Section 7.2.
-* `%ixdefine' (1): Section 4.1.2.
-* `Jcc NEAR' (1): Section 12.1.2.
-* `JMP DWORD' (1): Section 10.1.
-* jumps, mixed-size (1): Section 10.1.
-* `-k' (1): Section A.3.4.
-* `-l' option (1): Section 2.1.3.
-* label prefix (1): Section 3.9.
-* `.lbss' (1): Section 7.9.2.
-* `ld86' (1): Section 7.12.
-* `.ldata' (1): Section 7.9.2.
-* `LIBRARY' (1): Section 7.13.1.
-* license (1): Section 1.1.2.
-* `%line' (1): Section 4.10.1.
-* `__LINE__' (1): Section 4.11.4.
-* linker, free (1): Section 8.1.1.
-* Linux, `a.out' (1): Section 7.10.
-* Linux, `as86' (1): Section 7.12.
-* Linux, ELF (1): Section 7.9.
-* listing file (1): Section 2.1.3.
-* little-endian (1): Section 3.4.3.
-* `%local' (1): Section 4.8.3.
-* local labels (1): Section 3.9.
-* logical AND (1): Section 4.4.4.
-* logical negation (1): Section 3.5.7.
-* logical OR (1): Section 4.4.4.
-* logical XOR (1): Section 4.4.4.
-* `.lrodata' (1): Section 7.9.2.
-* `-M' option (1): Section 2.1.4.
-* Mach, object file format (1): Section 7.8.
-* Mach-O (1): Section 7.8.
-* `macho' (1): Section 7.8.
-* `macho32' (1): Section 7.8.
-* `macho64' (1): Section 7.8.
-* MacOS X (1): Section 7.8.
-* `%macro' (1): Section 4.3.
-* macro indirection (1): Section 4.1.3.
-* macro library (1): Section 2.1.16.
-* macro processor (1): Chapter 4.
-* `macro-defaults' (1): Section 2.1.24.
-* macro-local labels (1): Section 4.3.3.
-* `macro-params' (1): Section 2.1.24.
-* macros (1): Section 3.2.5.
-* `macro-selfref' (1): Section 2.1.24.
-* `make' (1): Section 1.3.2.
-* makefile dependencies (1): Section 2.1.4.
-* makefile dependencies (2): Section 2.1.5.
-* makefiles (1): Section 1.3.1.
-* makefiles (2): Section 1.3.2.
-* man pages (1): Section 1.3.2.
-* map files (1): Section 7.1.4.
-* `MASM' (1): Section 1.1.1.
-* MASM (1): Section 2.2.
-* MASM (2): Section 3.2.5.
-* MASM (3): Section 7.4.
-* `-MD' option (1): Section 2.1.7.
-* memory models (1): Section 2.2.5.
-* memory models (2): Section 8.4.2.
-* memory operand (1): Section 3.1.
-* memory references (1): Section 2.2.2.
-* memory references (2): Section 3.3.
-* `-MF' option (1): Section 2.1.6.
-* `-MG' option (1): Section 2.1.5.
-* Microsoft OMF (1): Section 7.4.
-* minifloat (1): Section 3.4.6.
-* Minix (1): Section 7.12.
-* `misc' subdirectory (1): Section 8.1.2.
-* `misc' subdirectory (2): Section 8.4.5.
-* `misc' subdirectory (3): Section 9.1.4.
-* mixed-language program (1): Section 8.4.
-* mixed-size addressing (1): Section 10.2.
-* mixed-size instruction (1): Section 10.1.
-* `MODULE' (1): Section 7.13.2.
-* modulo operators (1): Section 3.5.6.
-* motorola s-records (1): Section 7.3.
-* `-MP' option (1): Section 2.1.10.
-* `-MQ' option (1): Section 2.1.9.
-* MS-DOS (1): Section 7.1.
-* MS-DOS device drivers (1): Section 8.3.
-* `-MT' option (1): Section 2.1.8.
-* multi-line macros (1): Section 2.1.24.
-* multi-line macros (2): Section 4.3.
-* multipass optimization (1): Section 2.1.22.
-* multiple section names (1): Section 7.1.
-* multiplication (1): Section 3.5.6.
-* `multipush' macro (1): Section 4.3.7.
-* multisection (1): Section 7.1.3.
-* `__NaN__' (1): Section 3.4.6.
-* NaN (1): Section 3.4.6.
-* NASM version (1): Section 4.11.1.
-* nasm version history (1): Appendix C.
-* nasm version id (1): Section 4.11.2.
-* nasm version string (1): Section 4.11.3.
-* `nasm.1' (1): Section 1.3.2.
-* `__NASMDEFSEG' (1): Section 7.4.
-* `nasm-devel' (1): Section 1.2.
-* `NASMENV' (1): Section 2.1.28.
-* `nasm.exe' (1): Section 1.3.1.
-* `nasm -hf' (1): Section 2.1.2.
-* `__NASM_MAJOR__' (1): Section 4.11.1.
-* `__NASM_MINOR__' (1): Section 4.11.1.
-* `nasm.out' (1): Section 2.1.1.
-* `___NASM_PATCHLEVEL__' (1): Section 4.11.1.
-* `__NASM_SNAPSHOT__' (1): Section 4.11.1.
-* `__NASM_SUBMINOR__' (1): Section 4.11.1.
-* `__NASM_VER__' (1): Section 4.11.3.
-* `__NASM_VERSION_ID__' (1): Section 4.11.2.
-* `nasm-XXX-dos.zip' (1): Section 1.3.1.
-* `nasm-XXX.tar.gz' (1): Section 1.3.2.
-* `nasm-XXX-win32.zip' (1): Section 1.3.1.
-* `nasm-XXX.zip' (1): Section 1.3.1.
-* ndisasm (1): Appendix A.
-* `ndisasm.1' (1): Section 1.3.2.
-* `ndisasm.exe' (1): Section 1.3.1.
-* near call (1): Section 2.2.5.
-* near common variables (1): Section 7.4.8.
-* NetBSD (1): Section 7.11.
-* NetBSD (2): Section 9.2.
-* new releases (1): Section 1.2.
-* `noalloc' (1): Section 7.9.2.
-* `nobits' (1): Section 7.1.3.
-* `nobits' (2): Section 7.9.2.
-* `noexec' (1): Section 7.9.2.
-* `.nolist' (1): Section 4.3.10.
-* `nowait' (1): Section 2.2.6.
-* `nowrite' (1): Section 7.9.2.
-* `number-overflow' (1): Section 2.1.24.
-* numeric constants (1): Section 3.2.1.
-* numeric constants (2): Section 3.4.1.
-* `-O' option (1): Section 2.1.22.
-* `-o' option (1): Section 2.1.1.
-* `-o' option (2): Section A.3.1.
-* `O16' (1): Section 3.1.
-* `o16' (1): Section 10.3.
-* `O32' (1): Section 3.1.
-* `o32' (1): Section 10.3.
-* `O64' (1): Section 3.1.
-* `.OBJ' (1): Section 8.1.
-* `obj' (1): Section 7.4.
-* `object' (1): Section 7.9.5.
-* `object' (2): Section 7.13.3.
-* octal (1): Section 3.4.1.
-* `OF_DBG' (1): Section 7.14.
-* `OF_DEFAULT' (1): Section 2.1.2.
-* `OFFSET' (1): Section 2.2.2.
-* OMF (1): Section 7.4.
-* omitted parameters (1): Section 4.3.5.
-* one's complement (1): Section 3.5.7.
-* OpenBSD (1): Section 7.11.
-* OpenBSD (2): Section 9.2.
-* operands (1): Section 3.1.
-* operand-size prefixes (1): Section 3.1.
-* operating system (1): Section 7.1.
-* operating system, writing (1): Section 10.1.
-* operators (1): Section 3.5.
-* `ORG' (1): Section 7.1.1.
-* `ORG' (2): Section 8.2.1.
-* `ORG' (3): Section 8.2.2.
-* `ORG' (4): Section 12.1.3.
-* `orphan-labels' (1): Section 2.1.24.
-* `orphan-labels' (2): Section 3.1.
-* OS/2 (1): Section 7.4.
-* OS/2 (2): Section 7.4.1.
-* `osabi' (1): Section 7.9.1.
-* other preprocessor directives (1): Section 4.10.
-* out of range, jumps (1): Section 12.1.2.
-* output file format (1): Section 2.1.2.
-* output formats (1): Chapter 7.
-* `__OUTPUT_FORMAT__' (1): Section 4.11.6.
-* overlapping segments (1): Section 3.6.
-* `OVERLAY' (1): Section 7.4.1.
-* overloading, multi-line macros (1): Section 4.3.2.
-* overloading, single-line macros (1): Section 4.1.1.
-* `-P' option (1): Section 2.1.17.
-* `-p' option (1): Section 2.1.17.
-* `-p' option (2): Section 4.6.1.
-* paradox (1): Section 3.8.
-* `PASCAL' (1): Section 8.5.3.
-* Pascal calling convention (1): Section 8.5.1.
-* `__PASS__' (1): Section 4.11.9.
-* `PATH' (1): Section 1.3.1.
-* `%pathsearch' (1): Section 2.1.16.
-* `%pathsearch' (2): Section 4.6.2.
-* period (1): Section 3.9.
-* Perl (1): Section 1.3.1.
-* perverse (1): Section 2.1.16.
-* PharLap (1): Section 7.4.1.
-* PIC (1): Section 7.9.3.
-* PIC (2): Section 7.11.
-* PIC (3): Section 9.2.
-* `..plt' (1): Section 7.9.3.
-* `PLT' relocations (1): Section 7.9.3.
-* `PLT' relocations (2): Section 9.2.4.
-* `PLT' relocations (3): Section 9.2.5.
-* plt relocations (1): Section 9.2.5.
-* `%pop' (1): Section 4.7.
-* `%pop' (2): Section 4.7.1.
-* position-independent code (1): Section 7.9.3.
-* position-independent code (2): Section 7.11.
-* position-independent code (3): Section 9.2.
-* `--postfix' (1): Section 2.1.27.
-* precedence (1): Section 3.5.
-* pre-defining macros (1): Section 2.1.18.
-* pre-defining macros (2): Section 4.1.1.
-* preferred (1): Section 3.6.
-* `--prefix' (1): Section 2.1.27.
-* pre-including files (1): Section 2.1.17.
-* preprocess-only mode (1): Section 2.1.20.
-* preprocessor (1): Section 2.1.20.
-* preprocessor (2): Section 2.1.21.
-* preprocessor (3): Section 3.2.4.
-* preprocessor (4): Section 3.5.6.
-* preprocessor (5): Chapter 4.
-* preprocessor expressions (1): Section 2.1.20.
-* preprocessor loops (1): Section 4.5.
-* preprocessor variables (1): Section 4.1.7.
-* primitive directives (1): Chapter 6.
-* `PRIVATE' (1): Section 7.4.1.
-* `proc' (1): Section 7.13.3.
-* `proc' (2): Section 8.4.5.
-* `proc' (3): Section 9.1.4.
-* procedure linkage table (1): Section 7.9.3.
-* procedure linkage table (2): Section 9.2.4.
-* procedure linkage table (3): Section 9.2.5.
-* processor mode (1): Section 6.1.
-* `progbits' (1): Section 7.1.3.
-* `progbits' (2): Section 7.9.2.
-* program entry point (1): Section 7.4.6.
-* program entry point (2): Section 8.1.1.
-* program origin (1): Section 7.1.1.
-* `protected' (1): Section 7.9.5.
-* pseudo-instructions (1): Section 3.2.
-* `PUBLIC' (1): Section 6.6.
-* `PUBLIC' (2): Section 7.4.1.
-* pure binary (1): Section 7.1.
-* `%push' (1): Section 4.7.
-* `%push' (2): Section 4.7.1.
-* `__QNaN__' (1): Section 3.4.6.
-* quick start (1): Section 2.2.
-* `QWORD' (1): Section 3.1.
-* `-r' (1): Section A.3.
-* `rdf' (1): Section 7.13.
-* `rdoff' subdirectory (1): Section 1.3.2.
-* `rdoff' subdirectory (2): Section 7.13.
-* recursive multi-line macros (1): Section 4.3.1.
-* redirecting errors (1): Section 2.1.14.
-* `REL' (1): Section 3.3.
-* `REL' (2): Section 6.2.
-* relational operators (1): Section 4.4.4.
-* release candidates (1): Section 1.2.
-* Relocatable Dynamic Object File Format (1): Section 7.13.
-* relocations, PIC-specific (1): Section 7.9.3.
-* removing contexts (1): Section 4.7.1.
-* renaming contexts (1): Section 4.7.4.
-* `%rep' (1): Section 3.2.5.
-* `%rep' (2): Section 4.5.
-* repeating (1): Section 3.2.5.
-* repeating (2): Section 4.5.
-* `%repl' (1): Section 4.7.4.
-* reporting bugs (1): Section 12.2.
-* `RESB' (1): Section 2.2.7.
-* `RESB' (2): Section 3.2.
-* `RESB' (3): Section 3.2.2.
-* `RESD' (1): Section 3.2.
-* `RESD' (2): Section 3.2.2.
-* `RESO' (1): Section 3.2.
-* `RESO' (2): Section 3.2.2.
-* `RESQ' (1): Section 3.2.
-* `RESQ' (2): Section 3.2.2.
-* `REST' (1): Section 3.2.
-* `REST' (2): Section 3.2.2.
-* `RESW' (1): Section 3.2.
-* `RESW' (2): Section 3.2.2.
-* `RESY' (1): Section 3.2.
-* `RESY' (2): Section 3.2.2.
-* `%rmacro' (1): Section 4.3.1.
-* `.rodata' (1): Section 7.9.2.
-* `%rotate' (1): Section 4.3.7.
-* rotating macro parameters (1): Section 4.3.7.
-* `-s' option (1): Section 2.1.15.
-* `-s' option (2): Section A.3.2.
-* searching for include files (1): Section 4.6.1.
-* `__SECT__' (1): Section 6.3.1.
-* `__SECT__' (2): Section 6.4.
-* `SECTION' (1): Section 6.3.
-* `SECTION', `elf' extensions to (1): Section 7.9.2.
-* `SECTION', `win32' extensions to (1): Section 7.5.1.
-* section alignment, in `bin' (1): Section 7.1.2.
-* section alignment, in `elf' (1): Section 7.9.2.
-* section alignment, in `obj' (1): Section 7.4.1.
-* section alignment, in `win32' (1): Section 7.5.1.
-* section, bin extensions to (1): Section 7.1.2.
-* `SEG' (1): Section 3.5.7.
-* `SEG' (2): Section 3.6.
-* `SEG' (3): Section 7.4.
-* `SEGMENT' (1): Section 6.3.
-* `SEGMENT', `elf' extensions to (1): Section 7.4.1.
-* segment address (1): Section 3.5.7.
-* segment address (2): Section 3.6.
-* segment alignment, in `bin' (1): Section 7.1.2.
-* segment alignment, in `obj' (1): Section 7.4.1.
-* segment names, Borland Pascal (1): Section 8.5.2.
-* segment override (1): Section 2.2.4.
-* segment override (2): Section 3.1.
-* segments (1): Section 3.6.
-* segments, groups of (1): Section 7.4.2.
-* separator character (1): Section 2.1.28.
-* shared libraries (1): Section 7.11.
-* shared libraries (2): Section 9.2.
-* shared library (1): Section 7.9.5.
-* `shift' command (1): Section 4.3.7.
-* signed division (1): Section 3.5.6.
-* signed modulo (1): Section 3.5.6.
-* single-line macros (1): Section 4.1.
-* size, of symbols (1): Section 7.9.5.
-* `smartalign' (1): Section 5.2.
-* `__SNaN__' (1): Section 3.4.6.
-* snapshots, daily development (1): Section 1.2.
-* Solaris x86 (1): Section 7.9.
-* `-soname' (1): Section 9.2.6.
-* sound (1): Section 3.2.3.
-* source code (1): Section 1.3.1.
-* source-listing file (1): Section 2.1.3.
-* square brackets (1): Section 2.2.2.
-* square brackets (2): Section 3.3.
-* `srec' (1): Section 7.3.
-* `STACK' (1): Section 7.4.1.
-* stack relative preprocessor directives (1): Section 4.8.
-* `%stacksize' (1): Section 4.8.2.
-* standard macro packages (1): Chapter 5.
-* standard macros (1): Section 4.11.
-* standardized section names (1): Section 6.3.
-* standardized section names (2): Section 7.5.1.
-* standardized section names (3): Section 7.9.2.
-* standardized section names (4): Section 7.10.
-* standardized section names (5): Section 7.11.
-* standardized section names (6): Section 7.12.
-* standardized section names (7): Section 7.13.
-* `..start' (1): Section 7.4.6.
-* `..start' (2): Section 8.1.1.
-* `start=' (1): Section 7.1.3.
-* `stderr' (1): Section 2.1.14.
-* `stdout' (1): Section 2.1.15.
-* `%strcat' (1): Section 4.2.1.
-* `STRICT' (1): Section 3.7.
-* string constant (1): Section 3.2.1.
-* string constants (1): Section 3.4.4.
-* string length (1): Section 4.2.2.
-* string manipulation in macros (1): Section 4.2.
-* strings (1): Section 3.4.2.
-* `%strlen' (1): Section 4.2.2.
-* `STRUC' (1): Section 4.11.10.
-* `STRUC' (2): Section 6.4.
-* `STRUC' (3): Section 8.4.4.
-* `STRUC' (4): Section 9.1.3.
-* stub preprocessor (1): Section 2.1.21.
-* `%substr' (1): Section 4.2.3.
-* subtraction (1): Section 3.5.5.
-* suppressible warning (1): Section 2.1.24.
-* suppressing preprocessing (1): Section 2.1.21.
-* switching between sections (1): Section 6.3.
-* `..sym' (1): Section 7.9.3.
-* symbol sizes, specifying (1): Section 7.9.5.
-* symbol types, specifying (1): Section 7.9.5.
-* symbols, exporting from DLLs (1): Section 7.4.5.
-* symbols, importing from DLLs (1): Section 7.4.4.
-* `synchronisation' (1): Section A.3.2.
-* `.SYS' (1): Section 7.1.
-* `.SYS' (2): Section 8.3.
-* `-t' (1): Section 2.1.23.
-* `TASM' (1): Section 1.1.1.
-* `TASM' (2): Section 2.1.23.
-* tasm (1): Section 2.2.
-* tasm (2): Section 7.4.
-* `.tbss' (1): Section 7.9.2.
-* `TBYTE' (1): Section 2.2.7.
-* `.tdata' (1): Section 7.9.2.
-* `test' subdirectory (1): Section 8.1.1.
-* testing, arbitrary numeric expressions (1): Section 4.4.4.
-* testing, context stack (1): Section 4.4.3.
-* testing, exact text identity (1): Section 4.4.5.
-* testing, multi-line macro existence (1): Section 4.4.2.
-* testing, single-line macro existence (1): Section 4.4.1.
-* testing, token types (1): Section 4.4.6.
-* `.text' (1): Section 7.9.2.
-* `.text' (2): Section 7.10.
-* `.text' (3): Section 7.11.
-* `.text' (4): Section 7.12.
-* `.text' (5): Section 7.13.
-* `_TEXT' (1): Section 8.4.2.
-* thread local storage (1): Section 7.9.4.
-* `__TIME__' (1): Section 4.11.7.
-* `__TIME_NUM__' (1): Section 4.11.7.
-* `TIMES' (1): Section 3.2.
-* `TIMES' (2): Section 3.2.5.
-* `TIMES' (3): Section 3.8.
-* `TIMES' (4): Section 12.1.3.
-* `TIMES' (5): Section 12.1.4.
-* `TLINK' (1): Section 8.2.2.
-* `tls' (1): Section 7.9.2.
-* `tls' (2): Section 7.9.4.
-* `..tlsie' (1): Section 7.9.4.
-* trailing colon (1): Section 3.1.
-* `TWORD' (1): Section 2.2.7.
-* `TWORD' (2): Section 3.1.
-* type, of symbols (1): Section 7.9.5.
-* `-U' option (1): Section 2.1.19.
-* `-u' option (1): Section 2.1.19.
-* `-u' option (2): Section A.3.
-* unary operators (1): Section 3.5.7.
-* `%undef' (1): Section 2.1.19.
-* `%undef' (2): Section 4.1.6.
-* undefining macros (1): Section 2.1.19.
-* underscore, in C symbols (1): Section 8.4.1.
-* Unicode (1): Section 3.4.2.
-* Unicode (2): Section 3.4.5.
-* uninitialized (1): Section 3.2.
-* uninitialized (2): Section 3.2.2.
-* uninitialized storage (1): Section 2.2.7.
-* Unix (1): Section 1.3.2.
-* Unix, SCO (1): Section 7.9.
-* Unix, source archive (1): Section 1.3.2.
-* Unix, System V (1): Section 7.9.
-* UnixWare (1): Section 7.9.
-* `%unmacro' (1): Section 4.3.11.
-* unrolled loops (1): Section 3.2.5.
-* unsigned division (1): Section 3.5.6.
-* unsigned modulo (1): Section 3.5.6.
-* `UPPERCASE' (1): Section 2.2.1.
-* `UPPERCASE' (2): Section 7.4.3.
-* `%use' (1): Section 4.6.4.
-* `%use' (2): Chapter 5.
-* `__USE_*__' (1): Section 4.11.8.
-* `USE16' (1): Section 6.1.1.
-* `USE16' (2): Section 7.4.1.
-* `USE32' (1): Section 6.1.1.
-* `USE32' (2): Section 7.4.1.
-* `user' (1): Section 2.1.24.
-* user-defined errors (1): Section 4.9.
-* user-level assembler directives (1): Section 4.11.
-* user-level directives (1): Chapter 6.
-* `__UTC_DATE__' (1): Section 4.11.7.
-* `__UTC_DATE_NUM__' (1): Section 4.11.7.
-* `__UTC_TIME__' (1): Section 4.11.7.
-* `__UTC_TIME_NUM__' (1): Section 4.11.7.
-* UTF-16 (1): Section 3.4.5.
-* UTF-32 (1): Section 3.4.5.
-* UTF-8 (1): Section 3.4.2.
-* `__utf16__' (1): Section 3.4.5.
-* `__utf32__' (1): Section 3.4.5.
-* `-v' option (1): Section 2.1.25.
-* VAL (1): Section 8.1.1.
-* valid characters (1): Section 3.1.
-* variable types (1): Section 2.2.3.
-* version (1): Section 2.1.25.
-* version number of NASM (1): Section 4.11.1.
-* `vfollows=' (1): Section 7.1.3.
-* Visual C++ (1): Section 7.5.
-* `vstart=' (1): Section 7.1.3.
-* `-W' option (1): Section 2.1.24.
-* `-w' option (1): Section 2.1.24.
-* `%warning' (1): Section 4.9.
-* warnings (1): Section 2.1.24.
-* `[warning *warning-name]' (1): Section 2.1.24.
-* `[warning +warning-name]' (1): Section 2.1.24.
-* `[warning -warning-name]' (1): Section 2.1.24.
-* website (1): Section 1.2.
-* `win64' (1): Section 7.6.
-* `win64' (2): Chapter 11.
-* Win64 (1): Section 7.4.
-* Win64 (2): Section 7.5.
-* Win64 (3): Chapter 9.
-* Windows (1): Section 8.1.
-* `write' (1): Section 7.9.2.
-* writing operating systems (1): Section 10.1.
-* `WRT' (1): Section 3.6.
-* `WRT' (2): Section 7.4.
-* `WRT' (3): Section 7.9.3.
-* `WRT' (4): Section 7.9.4.
-* `WRT' (5): Section 7.11.
-* `WRT ..got' (1): Section 9.2.3.
-* `WRT ..gotoff' (1): Section 9.2.2.
-* `WRT ..gotpc' (1): Section 9.2.1.
-* `WRT ..plt' (1): Section 9.2.5.
-* `WRT ..sym' (1): Section 9.2.4.
-* `www.cpan.org' (1): Section 1.3.1.
-* `www.delorie.com' (1): Section 8.1.1.
-* `www.pcorner.com' (1): Section 8.1.1.
-* `-X' option (1): Section 2.1.13.
-* `x2ftp.oulu.fi' (1): Section 8.1.1.
-* `%xdefine' (1): Section 4.1.2.
-* `-y' option (1): Section 2.1.26.
-* `-Z' option (1): Section 2.1.14.
-
-
diff --git a/doc/inslist.src b/doc/inslist.src
deleted file mode 100644
index a5c7155..0000000
--- a/doc/inslist.src
+++ /dev/null
@@ -1,3130 +0,0 @@
-
-\S{} Special instructions...
-
-\c DB
-\c DW
-\c DD
-\c DQ
-\c DT
-\c DO
-\c DY
-\c RESB imm 8086
-\c RESW
-\c RESD
-\c RESQ
-\c REST
-\c RESO
-\c RESY
-
-\S{} Conventional instructions
-
-\c AAA 8086,NOLONG
-\c AAD 8086,NOLONG
-\c AAD imm 8086,NOLONG
-\c AAM 8086,NOLONG
-\c AAM imm 8086,NOLONG
-\c AAS 8086,NOLONG
-\c ADC mem,reg8 8086
-\c ADC reg8,reg8 8086
-\c ADC mem,reg16 8086
-\c ADC reg16,reg16 8086
-\c ADC mem,reg32 386
-\c ADC reg32,reg32 386
-\c ADC mem,reg64 X64
-\c ADC reg64,reg64 X64
-\c ADC reg8,mem 8086
-\c ADC reg8,reg8 8086
-\c ADC reg16,mem 8086
-\c ADC reg16,reg16 8086
-\c ADC reg32,mem 386
-\c ADC reg32,reg32 386
-\c ADC reg64,mem X64
-\c ADC reg64,reg64 X64
-\c ADC rm16,imm8 8086
-\c ADC rm32,imm8 386
-\c ADC rm64,imm8 X64
-\c ADC reg_al,imm 8086
-\c ADC reg_ax,sbyte16 8086
-\c ADC reg_ax,imm 8086
-\c ADC reg_eax,sbyte32 386
-\c ADC reg_eax,imm 386
-\c ADC reg_rax,sbyte64 X64
-\c ADC reg_rax,imm X64
-\c ADC rm8,imm 8086
-\c ADC rm16,imm 8086
-\c ADC rm32,imm 386
-\c ADC rm64,imm X64
-\c ADC mem,imm8 8086
-\c ADC mem,imm16 8086
-\c ADC mem,imm32 386
-\c ADD mem,reg8 8086
-\c ADD reg8,reg8 8086
-\c ADD mem,reg16 8086
-\c ADD reg16,reg16 8086
-\c ADD mem,reg32 386
-\c ADD reg32,reg32 386
-\c ADD mem,reg64 X64
-\c ADD reg64,reg64 X64
-\c ADD reg8,mem 8086
-\c ADD reg8,reg8 8086
-\c ADD reg16,mem 8086
-\c ADD reg16,reg16 8086
-\c ADD reg32,mem 386
-\c ADD reg32,reg32 386
-\c ADD reg64,mem X64
-\c ADD reg64,reg64 X64
-\c ADD rm16,imm8 8086
-\c ADD rm32,imm8 386
-\c ADD rm64,imm8 X64
-\c ADD reg_al,imm 8086
-\c ADD reg_ax,sbyte16 8086
-\c ADD reg_ax,imm 8086
-\c ADD reg_eax,sbyte32 386
-\c ADD reg_eax,imm 386
-\c ADD reg_rax,sbyte64 X64
-\c ADD reg_rax,imm X64
-\c ADD rm8,imm 8086
-\c ADD rm16,imm 8086
-\c ADD rm32,imm 386
-\c ADD rm64,imm X64
-\c ADD mem,imm8 8086
-\c ADD mem,imm16 8086
-\c ADD mem,imm32 386
-\c AND mem,reg8 8086
-\c AND reg8,reg8 8086
-\c AND mem,reg16 8086
-\c AND reg16,reg16 8086
-\c AND mem,reg32 386
-\c AND reg32,reg32 386
-\c AND mem,reg64 X64
-\c AND reg64,reg64 X64
-\c AND reg8,mem 8086
-\c AND reg8,reg8 8086
-\c AND reg16,mem 8086
-\c AND reg16,reg16 8086
-\c AND reg32,mem 386
-\c AND reg32,reg32 386
-\c AND reg64,mem X64
-\c AND reg64,reg64 X64
-\c AND rm16,imm8 8086
-\c AND rm32,imm8 386
-\c AND rm64,imm8 X64
-\c AND reg_al,imm 8086
-\c AND reg_ax,sbyte16 8086
-\c AND reg_ax,imm 8086
-\c AND reg_eax,sbyte32 386
-\c AND reg_eax,imm 386
-\c AND reg_rax,sbyte64 X64
-\c AND reg_rax,imm X64
-\c AND rm8,imm 8086
-\c AND rm16,imm 8086
-\c AND rm32,imm 386
-\c AND rm64,imm X64
-\c AND mem,imm8 8086
-\c AND mem,imm16 8086
-\c AND mem,imm32 386
-\c ARPL mem,reg16 286,PROT,NOLONG
-\c ARPL reg16,reg16 286,PROT,NOLONG
-\c BB0_RESET PENT,CYRIX,ND
-\c BB1_RESET PENT,CYRIX,ND
-\c BOUND reg16,mem 186,NOLONG
-\c BOUND reg32,mem 386,NOLONG
-\c BSF reg16,mem 386
-\c BSF reg16,reg16 386
-\c BSF reg32,mem 386
-\c BSF reg32,reg32 386
-\c BSF reg64,mem X64
-\c BSF reg64,reg64 X64
-\c BSR reg16,mem 386
-\c BSR reg16,reg16 386
-\c BSR reg32,mem 386
-\c BSR reg32,reg32 386
-\c BSR reg64,mem X64
-\c BSR reg64,reg64 X64
-\c BSWAP reg32 486
-\c BSWAP reg64 X64
-\c BT mem,reg16 386
-\c BT reg16,reg16 386
-\c BT mem,reg32 386
-\c BT reg32,reg32 386
-\c BT mem,reg64 X64
-\c BT reg64,reg64 X64
-\c BT rm16,imm 386
-\c BT rm32,imm 386
-\c BT rm64,imm X64
-\c BTC mem,reg16 386
-\c BTC reg16,reg16 386
-\c BTC mem,reg32 386
-\c BTC reg32,reg32 386
-\c BTC mem,reg64 X64
-\c BTC reg64,reg64 X64
-\c BTC rm16,imm 386
-\c BTC rm32,imm 386
-\c BTC rm64,imm X64
-\c BTR mem,reg16 386
-\c BTR reg16,reg16 386
-\c BTR mem,reg32 386
-\c BTR reg32,reg32 386
-\c BTR mem,reg64 X64
-\c BTR reg64,reg64 X64
-\c BTR rm16,imm 386
-\c BTR rm32,imm 386
-\c BTR rm64,imm X64
-\c BTS mem,reg16 386
-\c BTS reg16,reg16 386
-\c BTS mem,reg32 386
-\c BTS reg32,reg32 386
-\c BTS mem,reg64 X64
-\c BTS reg64,reg64 X64
-\c BTS rm16,imm 386
-\c BTS rm32,imm 386
-\c BTS rm64,imm X64
-\c CALL imm 8086
-\c CALL imm|near 8086
-\c CALL imm|far 8086,ND,NOLONG
-\c CALL imm16 8086
-\c CALL imm16|near 8086
-\c CALL imm16|far 8086,ND,NOLONG
-\c CALL imm32 386
-\c CALL imm32|near 386
-\c CALL imm32|far 386,ND,NOLONG
-\c CALL imm:imm 8086,NOLONG
-\c CALL imm16:imm 8086,NOLONG
-\c CALL imm:imm16 8086,NOLONG
-\c CALL imm32:imm 386,NOLONG
-\c CALL imm:imm32 386,NOLONG
-\c CALL mem|far 8086,NOLONG
-\c CALL mem|far X64
-\c CALL mem16|far 8086
-\c CALL mem32|far 386
-\c CALL mem64|far X64
-\c CALL mem|near 8086
-\c CALL mem16|near 8086
-\c CALL mem32|near 386,NOLONG
-\c CALL mem64|near X64
-\c CALL reg16 8086
-\c CALL reg32 386,NOLONG
-\c CALL reg64 X64
-\c CALL mem 8086
-\c CALL mem16 8086
-\c CALL mem32 386,NOLONG
-\c CALL mem64 X64
-\c CBW 8086
-\c CDQ 386
-\c CDQE X64
-\c CLC 8086
-\c CLD 8086
-\c CLGI X64,AMD
-\c CLI 8086
-\c CLTS 286,PRIV
-\c CMC 8086
-\c CMP mem,reg8 8086
-\c CMP reg8,reg8 8086
-\c CMP mem,reg16 8086
-\c CMP reg16,reg16 8086
-\c CMP mem,reg32 386
-\c CMP reg32,reg32 386
-\c CMP mem,reg64 X64
-\c CMP reg64,reg64 X64
-\c CMP reg8,mem 8086
-\c CMP reg8,reg8 8086
-\c CMP reg16,mem 8086
-\c CMP reg16,reg16 8086
-\c CMP reg32,mem 386
-\c CMP reg32,reg32 386
-\c CMP reg64,mem X64
-\c CMP reg64,reg64 X64
-\c CMP rm16,imm8 8086
-\c CMP rm32,imm8 386
-\c CMP rm64,imm8 X64
-\c CMP reg_al,imm 8086
-\c CMP reg_ax,sbyte16 8086
-\c CMP reg_ax,imm 8086
-\c CMP reg_eax,sbyte32 386
-\c CMP reg_eax,imm 386
-\c CMP reg_rax,sbyte64 X64
-\c CMP reg_rax,imm X64
-\c CMP rm8,imm 8086
-\c CMP rm16,imm 8086
-\c CMP rm32,imm 386
-\c CMP rm64,imm X64
-\c CMP mem,imm8 8086
-\c CMP mem,imm16 8086
-\c CMP mem,imm32 386
-\c CMPSB 8086
-\c CMPSD 386
-\c CMPSQ X64
-\c CMPSW 8086
-\c CMPXCHG mem,reg8 PENT
-\c CMPXCHG reg8,reg8 PENT
-\c CMPXCHG mem,reg16 PENT
-\c CMPXCHG reg16,reg16 PENT
-\c CMPXCHG mem,reg32 PENT
-\c CMPXCHG reg32,reg32 PENT
-\c CMPXCHG mem,reg64 X64
-\c CMPXCHG reg64,reg64 X64
-\c CMPXCHG486 mem,reg8 486,UNDOC,ND
-\c CMPXCHG486 reg8,reg8 486,UNDOC,ND
-\c CMPXCHG486 mem,reg16 486,UNDOC,ND
-\c CMPXCHG486 reg16,reg16 486,UNDOC,ND
-\c CMPXCHG486 mem,reg32 486,UNDOC,ND
-\c CMPXCHG486 reg32,reg32 486,UNDOC,ND
-\c CMPXCHG8B mem PENT
-\c CMPXCHG16B mem X64
-\c CPUID PENT
-\c CPU_READ PENT,CYRIX
-\c CPU_WRITE PENT,CYRIX
-\c CQO X64
-\c CWD 8086
-\c CWDE 386
-\c DAA 8086,NOLONG
-\c DAS 8086,NOLONG
-\c DEC reg16 8086,NOLONG
-\c DEC reg32 386,NOLONG
-\c DEC rm8 8086
-\c DEC rm16 8086
-\c DEC rm32 386
-\c DEC rm64 X64
-\c DIV rm8 8086
-\c DIV rm16 8086
-\c DIV rm32 386
-\c DIV rm64 X64
-\c DMINT P6,CYRIX
-\c EMMS PENT,MMX
-\c ENTER imm,imm 186
-\c EQU imm 8086
-\c EQU imm:imm 8086
-\c F2XM1 8086,FPU
-\c FABS 8086,FPU
-\c FADD mem32 8086,FPU
-\c FADD mem64 8086,FPU
-\c FADD fpureg|to 8086,FPU
-\c FADD fpureg 8086,FPU
-\c FADD fpureg,fpu0 8086,FPU
-\c FADD fpu0,fpureg 8086,FPU
-\c FADD 8086,FPU,ND
-\c FADDP fpureg 8086,FPU
-\c FADDP fpureg,fpu0 8086,FPU
-\c FADDP 8086,FPU,ND
-\c FBLD mem80 8086,FPU
-\c FBLD mem 8086,FPU
-\c FBSTP mem80 8086,FPU
-\c FBSTP mem 8086,FPU
-\c FCHS 8086,FPU
-\c FCLEX 8086,FPU
-\c FCMOVB fpureg P6,FPU
-\c FCMOVB fpu0,fpureg P6,FPU
-\c FCMOVB P6,FPU,ND
-\c FCMOVBE fpureg P6,FPU
-\c FCMOVBE fpu0,fpureg P6,FPU
-\c FCMOVBE P6,FPU,ND
-\c FCMOVE fpureg P6,FPU
-\c FCMOVE fpu0,fpureg P6,FPU
-\c FCMOVE P6,FPU,ND
-\c FCMOVNB fpureg P6,FPU
-\c FCMOVNB fpu0,fpureg P6,FPU
-\c FCMOVNB P6,FPU,ND
-\c FCMOVNBE fpureg P6,FPU
-\c FCMOVNBE fpu0,fpureg P6,FPU
-\c FCMOVNBE P6,FPU,ND
-\c FCMOVNE fpureg P6,FPU
-\c FCMOVNE fpu0,fpureg P6,FPU
-\c FCMOVNE P6,FPU,ND
-\c FCMOVNU fpureg P6,FPU
-\c FCMOVNU fpu0,fpureg P6,FPU
-\c FCMOVNU P6,FPU,ND
-\c FCMOVU fpureg P6,FPU
-\c FCMOVU fpu0,fpureg P6,FPU
-\c FCMOVU P6,FPU,ND
-\c FCOM mem32 8086,FPU
-\c FCOM mem64 8086,FPU
-\c FCOM fpureg 8086,FPU
-\c FCOM fpu0,fpureg 8086,FPU
-\c FCOM 8086,FPU,ND
-\c FCOMI fpureg P6,FPU
-\c FCOMI fpu0,fpureg P6,FPU
-\c FCOMI P6,FPU,ND
-\c FCOMIP fpureg P6,FPU
-\c FCOMIP fpu0,fpureg P6,FPU
-\c FCOMIP P6,FPU,ND
-\c FCOMP mem32 8086,FPU
-\c FCOMP mem64 8086,FPU
-\c FCOMP fpureg 8086,FPU
-\c FCOMP fpu0,fpureg 8086,FPU
-\c FCOMP 8086,FPU,ND
-\c FCOMPP 8086,FPU
-\c FCOS 386,FPU
-\c FDECSTP 8086,FPU
-\c FDISI 8086,FPU
-\c FDIV mem32 8086,FPU
-\c FDIV mem64 8086,FPU
-\c FDIV fpureg|to 8086,FPU
-\c FDIV fpureg 8086,FPU
-\c FDIV fpureg,fpu0 8086,FPU
-\c FDIV fpu0,fpureg 8086,FPU
-\c FDIV 8086,FPU,ND
-\c FDIVP fpureg 8086,FPU
-\c FDIVP fpureg,fpu0 8086,FPU
-\c FDIVP 8086,FPU,ND
-\c FDIVR mem32 8086,FPU
-\c FDIVR mem64 8086,FPU
-\c FDIVR fpureg|to 8086,FPU
-\c FDIVR fpureg,fpu0 8086,FPU
-\c FDIVR fpureg 8086,FPU
-\c FDIVR fpu0,fpureg 8086,FPU
-\c FDIVR 8086,FPU,ND
-\c FDIVRP fpureg 8086,FPU
-\c FDIVRP fpureg,fpu0 8086,FPU
-\c FDIVRP 8086,FPU,ND
-\c FEMMS PENT,3DNOW
-\c FENI 8086,FPU
-\c FFREE fpureg 8086,FPU
-\c FFREE 8086,FPU
-\c FFREEP fpureg 286,FPU,UNDOC
-\c FFREEP 286,FPU,UNDOC
-\c FIADD mem32 8086,FPU
-\c FIADD mem16 8086,FPU
-\c FICOM mem32 8086,FPU
-\c FICOM mem16 8086,FPU
-\c FICOMP mem32 8086,FPU
-\c FICOMP mem16 8086,FPU
-\c FIDIV mem32 8086,FPU
-\c FIDIV mem16 8086,FPU
-\c FIDIVR mem32 8086,FPU
-\c FIDIVR mem16 8086,FPU
-\c FILD mem32 8086,FPU
-\c FILD mem16 8086,FPU
-\c FILD mem64 8086,FPU
-\c FIMUL mem32 8086,FPU
-\c FIMUL mem16 8086,FPU
-\c FINCSTP 8086,FPU
-\c FINIT 8086,FPU
-\c FIST mem32 8086,FPU
-\c FIST mem16 8086,FPU
-\c FISTP mem32 8086,FPU
-\c FISTP mem16 8086,FPU
-\c FISTP mem64 8086,FPU
-\c FISTTP mem16 PRESCOTT,FPU
-\c FISTTP mem32 PRESCOTT,FPU
-\c FISTTP mem64 PRESCOTT,FPU
-\c FISUB mem32 8086,FPU
-\c FISUB mem16 8086,FPU
-\c FISUBR mem32 8086,FPU
-\c FISUBR mem16 8086,FPU
-\c FLD mem32 8086,FPU
-\c FLD mem64 8086,FPU
-\c FLD mem80 8086,FPU
-\c FLD fpureg 8086,FPU
-\c FLD 8086,FPU,ND
-\c FLD1 8086,FPU
-\c FLDCW mem 8086,FPU,SW
-\c FLDENV mem 8086,FPU
-\c FLDL2E 8086,FPU
-\c FLDL2T 8086,FPU
-\c FLDLG2 8086,FPU
-\c FLDLN2 8086,FPU
-\c FLDPI 8086,FPU
-\c FLDZ 8086,FPU
-\c FMUL mem32 8086,FPU
-\c FMUL mem64 8086,FPU
-\c FMUL fpureg|to 8086,FPU
-\c FMUL fpureg,fpu0 8086,FPU
-\c FMUL fpureg 8086,FPU
-\c FMUL fpu0,fpureg 8086,FPU
-\c FMUL 8086,FPU,ND
-\c FMULP fpureg 8086,FPU
-\c FMULP fpureg,fpu0 8086,FPU
-\c FMULP 8086,FPU,ND
-\c FNCLEX 8086,FPU
-\c FNDISI 8086,FPU
-\c FNENI 8086,FPU
-\c FNINIT 8086,FPU
-\c FNOP 8086,FPU
-\c FNSAVE mem 8086,FPU
-\c FNSTCW mem 8086,FPU,SW
-\c FNSTENV mem 8086,FPU
-\c FNSTSW mem 8086,FPU,SW
-\c FNSTSW reg_ax 286,FPU
-\c FPATAN 8086,FPU
-\c FPREM 8086,FPU
-\c FPREM1 386,FPU
-\c FPTAN 8086,FPU
-\c FRNDINT 8086,FPU
-\c FRSTOR mem 8086,FPU
-\c FSAVE mem 8086,FPU
-\c FSCALE 8086,FPU
-\c FSETPM 286,FPU
-\c FSIN 386,FPU
-\c FSINCOS 386,FPU
-\c FSQRT 8086,FPU
-\c FST mem32 8086,FPU
-\c FST mem64 8086,FPU
-\c FST fpureg 8086,FPU
-\c FST 8086,FPU,ND
-\c FSTCW mem 8086,FPU,SW
-\c FSTENV mem 8086,FPU
-\c FSTP mem32 8086,FPU
-\c FSTP mem64 8086,FPU
-\c FSTP mem80 8086,FPU
-\c FSTP fpureg 8086,FPU
-\c FSTP 8086,FPU,ND
-\c FSTSW mem 8086,FPU,SW
-\c FSTSW reg_ax 286,FPU
-\c FSUB mem32 8086,FPU
-\c FSUB mem64 8086,FPU
-\c FSUB fpureg|to 8086,FPU
-\c FSUB fpureg,fpu0 8086,FPU
-\c FSUB fpureg 8086,FPU
-\c FSUB fpu0,fpureg 8086,FPU
-\c FSUB 8086,FPU,ND
-\c FSUBP fpureg 8086,FPU
-\c FSUBP fpureg,fpu0 8086,FPU
-\c FSUBP 8086,FPU,ND
-\c FSUBR mem32 8086,FPU
-\c FSUBR mem64 8086,FPU
-\c FSUBR fpureg|to 8086,FPU
-\c FSUBR fpureg,fpu0 8086,FPU
-\c FSUBR fpureg 8086,FPU
-\c FSUBR fpu0,fpureg 8086,FPU
-\c FSUBR 8086,FPU,ND
-\c FSUBRP fpureg 8086,FPU
-\c FSUBRP fpureg,fpu0 8086,FPU
-\c FSUBRP 8086,FPU,ND
-\c FTST 8086,FPU
-\c FUCOM fpureg 386,FPU
-\c FUCOM fpu0,fpureg 386,FPU
-\c FUCOM 386,FPU,ND
-\c FUCOMI fpureg P6,FPU
-\c FUCOMI fpu0,fpureg P6,FPU
-\c FUCOMI P6,FPU,ND
-\c FUCOMIP fpureg P6,FPU
-\c FUCOMIP fpu0,fpureg P6,FPU
-\c FUCOMIP P6,FPU,ND
-\c FUCOMP fpureg 386,FPU
-\c FUCOMP fpu0,fpureg 386,FPU
-\c FUCOMP 386,FPU,ND
-\c FUCOMPP 386,FPU
-\c FXAM 8086,FPU
-\c FXCH fpureg 8086,FPU
-\c FXCH fpureg,fpu0 8086,FPU
-\c FXCH fpu0,fpureg 8086,FPU
-\c FXCH 8086,FPU,ND
-\c FXTRACT 8086,FPU
-\c FYL2X 8086,FPU
-\c FYL2XP1 8086,FPU
-\c HLT 8086,PRIV
-\c IBTS mem,reg16 386,SW,UNDOC,ND
-\c IBTS reg16,reg16 386,UNDOC,ND
-\c IBTS mem,reg32 386,SD,UNDOC,ND
-\c IBTS reg32,reg32 386,UNDOC,ND
-\c ICEBP 386,ND
-\c IDIV rm8 8086
-\c IDIV rm16 8086
-\c IDIV rm32 386
-\c IDIV rm64 X64
-\c IMUL rm8 8086
-\c IMUL rm16 8086
-\c IMUL rm32 386
-\c IMUL rm64 X64
-\c IMUL reg16,mem 386
-\c IMUL reg16,reg16 386
-\c IMUL reg32,mem 386
-\c IMUL reg32,reg32 386
-\c IMUL reg64,mem X64
-\c IMUL reg64,reg64 X64
-\c IMUL reg16,mem,imm8 186
-\c IMUL reg16,mem,sbyte16 186,ND
-\c IMUL reg16,mem,imm16 186
-\c IMUL reg16,mem,imm 186,ND
-\c IMUL reg16,reg16,imm8 186
-\c IMUL reg16,reg16,sbyte16 186,ND
-\c IMUL reg16,reg16,imm16 186
-\c IMUL reg16,reg16,imm 186,ND
-\c IMUL reg32,mem,imm8 386
-\c IMUL reg32,mem,sbyte32 386,ND
-\c IMUL reg32,mem,imm32 386
-\c IMUL reg32,mem,imm 386,ND
-\c IMUL reg32,reg32,imm8 386
-\c IMUL reg32,reg32,sbyte32 386,ND
-\c IMUL reg32,reg32,imm32 386
-\c IMUL reg32,reg32,imm 386,ND
-\c IMUL reg64,mem,imm8 X64
-\c IMUL reg64,mem,sbyte64 X64,ND
-\c IMUL reg64,mem,imm32 X64
-\c IMUL reg64,mem,imm X64,ND
-\c IMUL reg64,reg64,imm8 X64
-\c IMUL reg64,reg64,sbyte64 X64,ND
-\c IMUL reg64,reg64,imm32 X64
-\c IMUL reg64,reg64,imm X64,ND
-\c IMUL reg16,imm8 186
-\c IMUL reg16,sbyte16 186,ND
-\c IMUL reg16,imm16 186
-\c IMUL reg16,imm 186,ND
-\c IMUL reg32,imm8 386
-\c IMUL reg32,sbyte32 386,ND
-\c IMUL reg32,imm32 386
-\c IMUL reg32,imm 386,ND
-\c IMUL reg64,imm8 X64
-\c IMUL reg64,sbyte64 X64,ND
-\c IMUL reg64,imm32 X64
-\c IMUL reg64,imm X64,ND
-\c IN reg_al,imm 8086
-\c IN reg_ax,imm 8086
-\c IN reg_eax,imm 386
-\c IN reg_al,reg_dx 8086
-\c IN reg_ax,reg_dx 8086
-\c IN reg_eax,reg_dx 386
-\c INC reg16 8086,NOLONG
-\c INC reg32 386,NOLONG
-\c INC rm8 8086
-\c INC rm16 8086
-\c INC rm32 386
-\c INC rm64 X64
-\c INCBIN
-\c INSB 186
-\c INSD 386
-\c INSW 186
-\c INT imm 8086
-\c INT01 386,ND
-\c INT1 386
-\c INT03 8086,ND
-\c INT3 8086
-\c INTO 8086,NOLONG
-\c INVD 486,PRIV
-\c INVLPG mem 486,PRIV
-\c INVLPGA reg_ax,reg_ecx X86_64,AMD,NOLONG
-\c INVLPGA reg_eax,reg_ecx X86_64,AMD
-\c INVLPGA reg_rax,reg_ecx X64,AMD
-\c INVLPGA X86_64,AMD
-\c IRET 8086
-\c IRETD 386
-\c IRETQ X64
-\c IRETW 8086
-\c JCXZ imm 8086,NOLONG
-\c JECXZ imm 386
-\c JRCXZ imm X64
-\c JMP imm|short 8086
-\c JMP imm 8086,ND
-\c JMP imm 8086
-\c JMP imm|near 8086,ND
-\c JMP imm|far 8086,ND,NOLONG
-\c JMP imm16 8086
-\c JMP imm16|near 8086,ND
-\c JMP imm16|far 8086,ND,NOLONG
-\c JMP imm32 386
-\c JMP imm32|near 386,ND
-\c JMP imm32|far 386,ND,NOLONG
-\c JMP imm:imm 8086,NOLONG
-\c JMP imm16:imm 8086,NOLONG
-\c JMP imm:imm16 8086,NOLONG
-\c JMP imm32:imm 386,NOLONG
-\c JMP imm:imm32 386,NOLONG
-\c JMP mem|far 8086,NOLONG
-\c JMP mem|far X64
-\c JMP mem16|far 8086
-\c JMP mem32|far 386
-\c JMP mem64|far X64
-\c JMP mem|near 8086
-\c JMP mem16|near 8086
-\c JMP mem32|near 386,NOLONG
-\c JMP mem64|near X64
-\c JMP reg16 8086
-\c JMP reg32 386,NOLONG
-\c JMP reg64 X64
-\c JMP mem 8086
-\c JMP mem16 8086
-\c JMP mem32 386,NOLONG
-\c JMP mem64 X64
-\c JMPE imm IA64
-\c JMPE imm16 IA64
-\c JMPE imm32 IA64
-\c JMPE rm16 IA64
-\c JMPE rm32 IA64
-\c LAHF 8086
-\c LAR reg16,mem 286,PROT,SW
-\c LAR reg16,reg16 286,PROT
-\c LAR reg16,reg32 386,PROT
-\c LAR reg16,reg64 X64,PROT,ND
-\c LAR reg32,mem 386,PROT,SW
-\c LAR reg32,reg16 386,PROT
-\c LAR reg32,reg32 386,PROT
-\c LAR reg32,reg64 X64,PROT,ND
-\c LAR reg64,mem X64,PROT,SW
-\c LAR reg64,reg16 X64,PROT
-\c LAR reg64,reg32 X64,PROT
-\c LAR reg64,reg64 X64,PROT
-\c LDS reg16,mem 8086,NOLONG
-\c LDS reg32,mem 386,NOLONG
-\c LEA reg16,mem 8086
-\c LEA reg32,mem 386
-\c LEA reg64,mem X64
-\c LEAVE 186
-\c LES reg16,mem 8086,NOLONG
-\c LES reg32,mem 386,NOLONG
-\c LFENCE X64,AMD
-\c LFS reg16,mem 386
-\c LFS reg32,mem 386
-\c LGDT mem 286,PRIV
-\c LGS reg16,mem 386
-\c LGS reg32,mem 386
-\c LIDT mem 286,PRIV
-\c LLDT mem 286,PROT,PRIV
-\c LLDT mem16 286,PROT,PRIV
-\c LLDT reg16 286,PROT,PRIV
-\c LMSW mem 286,PRIV
-\c LMSW mem16 286,PRIV
-\c LMSW reg16 286,PRIV
-\c LOADALL 386,UNDOC
-\c LOADALL286 286,UNDOC
-\c LODSB 8086
-\c LODSD 386
-\c LODSQ X64
-\c LODSW 8086
-\c LOOP imm 8086
-\c LOOP imm,reg_cx 8086,NOLONG
-\c LOOP imm,reg_ecx 386
-\c LOOP imm,reg_rcx X64
-\c LOOPE imm 8086
-\c LOOPE imm,reg_cx 8086,NOLONG
-\c LOOPE imm,reg_ecx 386
-\c LOOPE imm,reg_rcx X64
-\c LOOPNE imm 8086
-\c LOOPNE imm,reg_cx 8086,NOLONG
-\c LOOPNE imm,reg_ecx 386
-\c LOOPNE imm,reg_rcx X64
-\c LOOPNZ imm 8086
-\c LOOPNZ imm,reg_cx 8086,NOLONG
-\c LOOPNZ imm,reg_ecx 386
-\c LOOPNZ imm,reg_rcx X64
-\c LOOPZ imm 8086
-\c LOOPZ imm,reg_cx 8086,NOLONG
-\c LOOPZ imm,reg_ecx 386
-\c LOOPZ imm,reg_rcx X64
-\c LSL reg16,mem 286,PROT,SW
-\c LSL reg16,reg16 286,PROT
-\c LSL reg16,reg32 386,PROT
-\c LSL reg16,reg64 X64,PROT,ND
-\c LSL reg32,mem 386,PROT,SW
-\c LSL reg32,reg16 386,PROT
-\c LSL reg32,reg32 386,PROT
-\c LSL reg32,reg64 X64,PROT,ND
-\c LSL reg64,mem X64,PROT,SW
-\c LSL reg64,reg16 X64,PROT
-\c LSL reg64,reg32 X64,PROT
-\c LSL reg64,reg64 X64,PROT
-\c LSS reg16,mem 386
-\c LSS reg32,mem 386
-\c LTR mem 286,PROT,PRIV
-\c LTR mem16 286,PROT,PRIV
-\c LTR reg16 286,PROT,PRIV
-\c MFENCE X64,AMD
-\c MONITOR PRESCOTT
-\c MONITOR reg_eax,reg_ecx,reg_edx PRESCOTT,ND
-\c MONITOR reg_rax,reg_ecx,reg_edx X64,ND
-\c MOV mem,reg_sreg 8086
-\c MOV reg16,reg_sreg 8086
-\c MOV reg32,reg_sreg 386
-\c MOV reg_sreg,mem 8086
-\c MOV reg_sreg,reg16 8086
-\c MOV reg_sreg,reg32 386
-\c MOV reg_al,mem_offs 8086
-\c MOV reg_ax,mem_offs 8086
-\c MOV reg_eax,mem_offs 386
-\c MOV reg_rax,mem_offs X64
-\c MOV mem_offs,reg_al 8086
-\c MOV mem_offs,reg_ax 8086
-\c MOV mem_offs,reg_eax 386
-\c MOV mem_offs,reg_rax X64
-\c MOV reg32,reg_creg 386,PRIV,NOLONG
-\c MOV reg64,reg_creg X64,PRIV
-\c MOV reg_creg,reg32 386,PRIV,NOLONG
-\c MOV reg_creg,reg64 X64,PRIV
-\c MOV reg32,reg_dreg 386,PRIV,NOLONG
-\c MOV reg64,reg_dreg X64,PRIV
-\c MOV reg_dreg,reg32 386,PRIV,NOLONG
-\c MOV reg_dreg,reg64 X64,PRIV
-\c MOV reg32,reg_treg 386,NOLONG,ND
-\c MOV reg_treg,reg32 386,NOLONG,ND
-\c MOV mem,reg8 8086
-\c MOV reg8,reg8 8086
-\c MOV mem,reg16 8086
-\c MOV reg16,reg16 8086
-\c MOV mem,reg32 386
-\c MOV reg32,reg32 386
-\c MOV mem,reg64 X64
-\c MOV reg64,reg64 X64
-\c MOV reg8,mem 8086
-\c MOV reg8,reg8 8086
-\c MOV reg16,mem 8086
-\c MOV reg16,reg16 8086
-\c MOV reg32,mem 386
-\c MOV reg32,reg32 386
-\c MOV reg64,mem X64
-\c MOV reg64,reg64 X64
-\c MOV reg8,imm 8086
-\c MOV reg16,imm 8086
-\c MOV reg32,imm 386
-\c MOV reg64,imm X64
-\c MOV reg64,imm32 X64
-\c MOV rm8,imm 8086
-\c MOV rm16,imm 8086
-\c MOV rm32,imm 386
-\c MOV rm64,imm X64
-\c MOV mem,imm8 8086
-\c MOV mem,imm16 8086
-\c MOV mem,imm32 386
-\c MOVD mmxreg,mem PENT,MMX,SD
-\c MOVD mmxreg,reg32 PENT,MMX
-\c MOVD mem,mmxreg PENT,MMX,SD
-\c MOVD reg32,mmxreg PENT,MMX
-\c MOVD xmmreg,mem X64,SD
-\c MOVD xmmreg,reg32 X64
-\c MOVD mem,xmmreg X64,SD
-\c MOVD reg32,xmmreg X64,SSE
-\c MOVQ mmxreg,mmxrm PENT,MMX
-\c MOVQ mmxrm,mmxreg PENT,MMX
-\c MOVQ mmxreg,rm64 X64,MMX
-\c MOVQ rm64,mmxreg X64,MMX
-\c MOVSB 8086
-\c MOVSD 386
-\c MOVSQ X64
-\c MOVSW 8086
-\c MOVSX reg16,mem 386
-\c MOVSX reg16,reg8 386
-\c MOVSX reg32,rm8 386
-\c MOVSX reg32,rm16 386
-\c MOVSX reg64,rm8 X64
-\c MOVSX reg64,rm16 X64
-\c MOVSXD reg64,rm32 X64
-\c MOVSX reg64,rm32 X64,ND
-\c MOVZX reg16,mem 386
-\c MOVZX reg16,reg8 386
-\c MOVZX reg32,rm8 386
-\c MOVZX reg32,rm16 386
-\c MOVZX reg64,rm8 X64
-\c MOVZX reg64,rm16 X64
-\c MUL rm8 8086
-\c MUL rm16 8086
-\c MUL rm32 386
-\c MUL rm64 X64
-\c MWAIT PRESCOTT
-\c MWAIT reg_eax,reg_ecx PRESCOTT,ND
-\c NEG rm8 8086
-\c NEG rm16 8086
-\c NEG rm32 386
-\c NEG rm64 X64
-\c NOP 8086
-\c NOP rm16 P6
-\c NOP rm32 P6
-\c NOP rm64 X64
-\c NOT rm8 8086
-\c NOT rm16 8086
-\c NOT rm32 386
-\c NOT rm64 X64
-\c OR mem,reg8 8086
-\c OR reg8,reg8 8086
-\c OR mem,reg16 8086
-\c OR reg16,reg16 8086
-\c OR mem,reg32 386
-\c OR reg32,reg32 386
-\c OR mem,reg64 X64
-\c OR reg64,reg64 X64
-\c OR reg8,mem 8086
-\c OR reg8,reg8 8086
-\c OR reg16,mem 8086
-\c OR reg16,reg16 8086
-\c OR reg32,mem 386
-\c OR reg32,reg32 386
-\c OR reg64,mem X64
-\c OR reg64,reg64 X64
-\c OR rm16,imm8 8086
-\c OR rm32,imm8 386
-\c OR rm64,imm8 X64
-\c OR reg_al,imm 8086
-\c OR reg_ax,sbyte16 8086
-\c OR reg_ax,imm 8086
-\c OR reg_eax,sbyte32 386
-\c OR reg_eax,imm 386
-\c OR reg_rax,sbyte64 X64
-\c OR reg_rax,imm X64
-\c OR rm8,imm 8086
-\c OR rm16,imm 8086
-\c OR rm32,imm 386
-\c OR rm64,imm X64
-\c OR mem,imm8 8086
-\c OR mem,imm16 8086
-\c OR mem,imm32 386
-\c OUT imm,reg_al 8086
-\c OUT imm,reg_ax 8086
-\c OUT imm,reg_eax 386
-\c OUT reg_dx,reg_al 8086
-\c OUT reg_dx,reg_ax 8086
-\c OUT reg_dx,reg_eax 386
-\c OUTSB 186
-\c OUTSD 386
-\c OUTSW 186
-\c PACKSSDW mmxreg,mmxrm PENT,MMX
-\c PACKSSWB mmxreg,mmxrm PENT,MMX
-\c PACKUSWB mmxreg,mmxrm PENT,MMX
-\c PADDB mmxreg,mmxrm PENT,MMX
-\c PADDD mmxreg,mmxrm PENT,MMX
-\c PADDSB mmxreg,mmxrm PENT,MMX
-\c PADDSIW mmxreg,mmxrm PENT,MMX,CYRIX
-\c PADDSW mmxreg,mmxrm PENT,MMX
-\c PADDUSB mmxreg,mmxrm PENT,MMX
-\c PADDUSW mmxreg,mmxrm PENT,MMX
-\c PADDW mmxreg,mmxrm PENT,MMX
-\c PAND mmxreg,mmxrm PENT,MMX
-\c PANDN mmxreg,mmxrm PENT,MMX
-\c PAUSE 8086
-\c PAVEB mmxreg,mmxrm PENT,MMX,CYRIX
-\c PAVGUSB mmxreg,mmxrm PENT,3DNOW
-\c PCMPEQB mmxreg,mmxrm PENT,MMX
-\c PCMPEQD mmxreg,mmxrm PENT,MMX
-\c PCMPEQW mmxreg,mmxrm PENT,MMX
-\c PCMPGTB mmxreg,mmxrm PENT,MMX
-\c PCMPGTD mmxreg,mmxrm PENT,MMX
-\c PCMPGTW mmxreg,mmxrm PENT,MMX
-\c PDISTIB mmxreg,mem PENT,MMX,CYRIX
-\c PF2ID mmxreg,mmxrm PENT,3DNOW
-\c PFACC mmxreg,mmxrm PENT,3DNOW
-\c PFADD mmxreg,mmxrm PENT,3DNOW
-\c PFCMPEQ mmxreg,mmxrm PENT,3DNOW
-\c PFCMPGE mmxreg,mmxrm PENT,3DNOW
-\c PFCMPGT mmxreg,mmxrm PENT,3DNOW
-\c PFMAX mmxreg,mmxrm PENT,3DNOW
-\c PFMIN mmxreg,mmxrm PENT,3DNOW
-\c PFMUL mmxreg,mmxrm PENT,3DNOW
-\c PFRCP mmxreg,mmxrm PENT,3DNOW
-\c PFRCPIT1 mmxreg,mmxrm PENT,3DNOW
-\c PFRCPIT2 mmxreg,mmxrm PENT,3DNOW
-\c PFRSQIT1 mmxreg,mmxrm PENT,3DNOW
-\c PFRSQRT mmxreg,mmxrm PENT,3DNOW
-\c PFSUB mmxreg,mmxrm PENT,3DNOW
-\c PFSUBR mmxreg,mmxrm PENT,3DNOW
-\c PI2FD mmxreg,mmxrm PENT,3DNOW
-\c PMACHRIW mmxreg,mem PENT,MMX,CYRIX
-\c PMADDWD mmxreg,mmxrm PENT,MMX
-\c PMAGW mmxreg,mmxrm PENT,MMX,CYRIX
-\c PMULHRIW mmxreg,mmxrm PENT,MMX,CYRIX
-\c PMULHRWA mmxreg,mmxrm PENT,3DNOW
-\c PMULHRWC mmxreg,mmxrm PENT,MMX,CYRIX
-\c PMULHW mmxreg,mmxrm PENT,MMX
-\c PMULLW mmxreg,mmxrm PENT,MMX
-\c PMVGEZB mmxreg,mem PENT,MMX,CYRIX
-\c PMVLZB mmxreg,mem PENT,MMX,CYRIX
-\c PMVNZB mmxreg,mem PENT,MMX,CYRIX
-\c PMVZB mmxreg,mem PENT,MMX,CYRIX
-\c POP reg16 8086
-\c POP reg32 386,NOLONG
-\c POP reg64 X64
-\c POP rm16 8086
-\c POP rm32 386,NOLONG
-\c POP rm64 X64
-\c POP reg_cs 8086,UNDOC,ND
-\c POP reg_dess 8086,NOLONG
-\c POP reg_fsgs 386
-\c POPA 186,NOLONG
-\c POPAD 386,NOLONG
-\c POPAW 186,NOLONG
-\c POPF 8086
-\c POPFD 386,NOLONG
-\c POPFQ X64
-\c POPFW 8086
-\c POR mmxreg,mmxrm PENT,MMX
-\c PREFETCH mem PENT,3DNOW
-\c PREFETCHW mem PENT,3DNOW
-\c PSLLD mmxreg,mmxrm PENT,MMX
-\c PSLLD mmxreg,imm PENT,MMX
-\c PSLLQ mmxreg,mmxrm PENT,MMX
-\c PSLLQ mmxreg,imm PENT,MMX
-\c PSLLW mmxreg,mmxrm PENT,MMX
-\c PSLLW mmxreg,imm PENT,MMX
-\c PSRAD mmxreg,mmxrm PENT,MMX
-\c PSRAD mmxreg,imm PENT,MMX
-\c PSRAW mmxreg,mmxrm PENT,MMX
-\c PSRAW mmxreg,imm PENT,MMX
-\c PSRLD mmxreg,mmxrm PENT,MMX
-\c PSRLD mmxreg,imm PENT,MMX
-\c PSRLQ mmxreg,mmxrm PENT,MMX
-\c PSRLQ mmxreg,imm PENT,MMX
-\c PSRLW mmxreg,mmxrm PENT,MMX
-\c PSRLW mmxreg,imm PENT,MMX
-\c PSUBB mmxreg,mmxrm PENT,MMX
-\c PSUBD mmxreg,mmxrm PENT,MMX
-\c PSUBSB mmxreg,mmxrm PENT,MMX
-\c PSUBSIW mmxreg,mmxrm PENT,MMX,CYRIX
-\c PSUBSW mmxreg,mmxrm PENT,MMX
-\c PSUBUSB mmxreg,mmxrm PENT,MMX
-\c PSUBUSW mmxreg,mmxrm PENT,MMX
-\c PSUBW mmxreg,mmxrm PENT,MMX
-\c PUNPCKHBW mmxreg,mmxrm PENT,MMX
-\c PUNPCKHDQ mmxreg,mmxrm PENT,MMX
-\c PUNPCKHWD mmxreg,mmxrm PENT,MMX
-\c PUNPCKLBW mmxreg,mmxrm PENT,MMX
-\c PUNPCKLDQ mmxreg,mmxrm PENT,MMX
-\c PUNPCKLWD mmxreg,mmxrm PENT,MMX
-\c PUSH reg16 8086
-\c PUSH reg32 386,NOLONG
-\c PUSH reg64 X64
-\c PUSH rm16 8086
-\c PUSH rm32 386,NOLONG
-\c PUSH rm64 X64
-\c PUSH reg_cs 8086,NOLONG
-\c PUSH reg_dess 8086,NOLONG
-\c PUSH reg_fsgs 386
-\c PUSH imm8 186
-\c PUSH imm16 186,AR0,SZ
-\c PUSH imm32 386,NOLONG,AR0,SZ
-\c PUSH imm32 386,NOLONG,SD
-\c PUSH imm64 X64,AR0,SZ
-\c PUSHA 186,NOLONG
-\c PUSHAD 386,NOLONG
-\c PUSHAW 186,NOLONG
-\c PUSHF 8086
-\c PUSHFD 386,NOLONG
-\c PUSHFQ X64
-\c PUSHFW 8086
-\c PXOR mmxreg,mmxrm PENT,MMX
-\c RCL rm8,unity 8086
-\c RCL rm8,reg_cl 8086
-\c RCL rm8,imm 186
-\c RCL rm16,unity 8086
-\c RCL rm16,reg_cl 8086
-\c RCL rm16,imm 186
-\c RCL rm32,unity 386
-\c RCL rm32,reg_cl 386
-\c RCL rm32,imm 386
-\c RCL rm64,unity X64
-\c RCL rm64,reg_cl X64
-\c RCL rm64,imm X64
-\c RCR rm8,unity 8086
-\c RCR rm8,reg_cl 8086
-\c RCR rm8,imm 186
-\c RCR rm16,unity 8086
-\c RCR rm16,reg_cl 8086
-\c RCR rm16,imm 186
-\c RCR rm32,unity 386
-\c RCR rm32,reg_cl 386
-\c RCR rm32,imm 386
-\c RCR rm64,unity X64
-\c RCR rm64,reg_cl X64
-\c RCR rm64,imm X64
-\c RDSHR rm32 P6,CYRIXM
-\c RDMSR PENT,PRIV
-\c RDPMC P6
-\c RDTSC PENT
-\c RDTSCP X86_64
-\c RET 8086
-\c RET imm 8086,SW
-\c RETF 8086
-\c RETF imm 8086,SW
-\c RETN 8086
-\c RETN imm 8086,SW
-\c ROL rm8,unity 8086
-\c ROL rm8,reg_cl 8086
-\c ROL rm8,imm 186
-\c ROL rm16,unity 8086
-\c ROL rm16,reg_cl 8086
-\c ROL rm16,imm 186
-\c ROL rm32,unity 386
-\c ROL rm32,reg_cl 386
-\c ROL rm32,imm 386
-\c ROL rm64,unity X64
-\c ROL rm64,reg_cl X64
-\c ROL rm64,imm X64
-\c ROR rm8,unity 8086
-\c ROR rm8,reg_cl 8086
-\c ROR rm8,imm 186
-\c ROR rm16,unity 8086
-\c ROR rm16,reg_cl 8086
-\c ROR rm16,imm 186
-\c ROR rm32,unity 386
-\c ROR rm32,reg_cl 386
-\c ROR rm32,imm 386
-\c ROR rm64,unity X64
-\c ROR rm64,reg_cl X64
-\c ROR rm64,imm X64
-\c RDM P6,CYRIX,ND
-\c RSDC reg_sreg,mem80 486,CYRIXM
-\c RSLDT mem80 486,CYRIXM
-\c RSM PENTM
-\c RSTS mem80 486,CYRIXM
-\c SAHF 8086
-\c SAL rm8,unity 8086,ND
-\c SAL rm8,reg_cl 8086,ND
-\c SAL rm8,imm 186,ND
-\c SAL rm16,unity 8086,ND
-\c SAL rm16,reg_cl 8086,ND
-\c SAL rm16,imm 186,ND
-\c SAL rm32,unity 386,ND
-\c SAL rm32,reg_cl 386,ND
-\c SAL rm32,imm 386,ND
-\c SAL rm64,unity X64,ND
-\c SAL rm64,reg_cl X64,ND
-\c SAL rm64,imm X64,ND
-\c SALC 8086,UNDOC
-\c SAR rm8,unity 8086
-\c SAR rm8,reg_cl 8086
-\c SAR rm8,imm 186
-\c SAR rm16,unity 8086
-\c SAR rm16,reg_cl 8086
-\c SAR rm16,imm 186
-\c SAR rm32,unity 386
-\c SAR rm32,reg_cl 386
-\c SAR rm32,imm 386
-\c SAR rm64,unity X64
-\c SAR rm64,reg_cl X64
-\c SAR rm64,imm X64
-\c SBB mem,reg8 8086
-\c SBB reg8,reg8 8086
-\c SBB mem,reg16 8086
-\c SBB reg16,reg16 8086
-\c SBB mem,reg32 386
-\c SBB reg32,reg32 386
-\c SBB mem,reg64 X64
-\c SBB reg64,reg64 X64
-\c SBB reg8,mem 8086
-\c SBB reg8,reg8 8086
-\c SBB reg16,mem 8086
-\c SBB reg16,reg16 8086
-\c SBB reg32,mem 386
-\c SBB reg32,reg32 386
-\c SBB reg64,mem X64
-\c SBB reg64,reg64 X64
-\c SBB rm16,imm8 8086
-\c SBB rm32,imm8 386
-\c SBB rm64,imm8 X64
-\c SBB reg_al,imm 8086
-\c SBB reg_ax,sbyte16 8086
-\c SBB reg_ax,imm 8086
-\c SBB reg_eax,sbyte32 386
-\c SBB reg_eax,imm 386
-\c SBB reg_rax,sbyte64 X64
-\c SBB reg_rax,imm X64
-\c SBB rm8,imm 8086
-\c SBB rm16,imm 8086
-\c SBB rm32,imm 386
-\c SBB rm64,imm X64
-\c SBB mem,imm8 8086
-\c SBB mem,imm16 8086
-\c SBB mem,imm32 386
-\c SCASB 8086
-\c SCASD 386
-\c SCASQ X64
-\c SCASW 8086
-\c SFENCE X64,AMD
-\c SGDT mem 286
-\c SHL rm8,unity 8086
-\c SHL rm8,reg_cl 8086
-\c SHL rm8,imm 186
-\c SHL rm16,unity 8086
-\c SHL rm16,reg_cl 8086
-\c SHL rm16,imm 186
-\c SHL rm32,unity 386
-\c SHL rm32,reg_cl 386
-\c SHL rm32,imm 386
-\c SHL rm64,unity X64
-\c SHL rm64,reg_cl X64
-\c SHL rm64,imm X64
-\c SHLD mem,reg16,imm 3862
-\c SHLD reg16,reg16,imm 3862
-\c SHLD mem,reg32,imm 3862
-\c SHLD reg32,reg32,imm 3862
-\c SHLD mem,reg64,imm X642
-\c SHLD reg64,reg64,imm X642
-\c SHLD mem,reg16,reg_cl 386
-\c SHLD reg16,reg16,reg_cl 386
-\c SHLD mem,reg32,reg_cl 386
-\c SHLD reg32,reg32,reg_cl 386
-\c SHLD mem,reg64,reg_cl X64
-\c SHLD reg64,reg64,reg_cl X64
-\c SHR rm8,unity 8086
-\c SHR rm8,reg_cl 8086
-\c SHR rm8,imm 186
-\c SHR rm16,unity 8086
-\c SHR rm16,reg_cl 8086
-\c SHR rm16,imm 186
-\c SHR rm32,unity 386
-\c SHR rm32,reg_cl 386
-\c SHR rm32,imm 386
-\c SHR rm64,unity X64
-\c SHR rm64,reg_cl X64
-\c SHR rm64,imm X64
-\c SHRD mem,reg16,imm 3862
-\c SHRD reg16,reg16,imm 3862
-\c SHRD mem,reg32,imm 3862
-\c SHRD reg32,reg32,imm 3862
-\c SHRD mem,reg64,imm X642
-\c SHRD reg64,reg64,imm X642
-\c SHRD mem,reg16,reg_cl 386
-\c SHRD reg16,reg16,reg_cl 386
-\c SHRD mem,reg32,reg_cl 386
-\c SHRD reg32,reg32,reg_cl 386
-\c SHRD mem,reg64,reg_cl X64
-\c SHRD reg64,reg64,reg_cl X64
-\c SIDT mem 286
-\c SLDT mem 286
-\c SLDT mem16 286
-\c SLDT reg16 286
-\c SLDT reg32 386
-\c SLDT reg64 X64,ND
-\c SLDT reg64 X64
-\c SKINIT X64
-\c SMI 386,UNDOC
-\c SMINT P6,CYRIX,ND
-\c SMINTOLD 486,CYRIX,ND
-\c SMSW mem 286
-\c SMSW mem16 286
-\c SMSW reg16 286
-\c SMSW reg32 386
-\c STC 8086
-\c STD 8086
-\c STGI X64
-\c STI 8086
-\c STOSB 8086
-\c STOSD 386
-\c STOSQ X64
-\c STOSW 8086
-\c STR mem 286,PROT
-\c STR mem16 286,PROT
-\c STR reg16 286,PROT
-\c STR reg32 386,PROT
-\c STR reg64 X64
-\c SUB mem,reg8 8086
-\c SUB reg8,reg8 8086
-\c SUB mem,reg16 8086
-\c SUB reg16,reg16 8086
-\c SUB mem,reg32 386
-\c SUB reg32,reg32 386
-\c SUB mem,reg64 X64
-\c SUB reg64,reg64 X64
-\c SUB reg8,mem 8086
-\c SUB reg8,reg8 8086
-\c SUB reg16,mem 8086
-\c SUB reg16,reg16 8086
-\c SUB reg32,mem 386
-\c SUB reg32,reg32 386
-\c SUB reg64,mem X64
-\c SUB reg64,reg64 X64
-\c SUB rm16,imm8 8086
-\c SUB rm32,imm8 386
-\c SUB rm64,imm8 X64
-\c SUB reg_al,imm 8086
-\c SUB reg_ax,sbyte16 8086
-\c SUB reg_ax,imm 8086
-\c SUB reg_eax,sbyte32 386
-\c SUB reg_eax,imm 386
-\c SUB reg_rax,sbyte64 X64
-\c SUB reg_rax,imm X64
-\c SUB rm8,imm 8086
-\c SUB rm16,imm 8086
-\c SUB rm32,imm 386
-\c SUB rm64,imm X64
-\c SUB mem,imm8 8086
-\c SUB mem,imm16 8086
-\c SUB mem,imm32 386
-\c SVDC mem80,reg_sreg 486,CYRIXM
-\c SVLDT mem80 486,CYRIXM,ND
-\c SVTS mem80 486,CYRIXM
-\c SWAPGS X64
-\c SYSCALL P6,AMD
-\c SYSENTER P6
-\c SYSEXIT P6,PRIV
-\c SYSRET P6,PRIV,AMD
-\c TEST mem,reg8 8086
-\c TEST reg8,reg8 8086
-\c TEST mem,reg16 8086
-\c TEST reg16,reg16 8086
-\c TEST mem,reg32 386
-\c TEST reg32,reg32 386
-\c TEST mem,reg64 X64
-\c TEST reg64,reg64 X64
-\c TEST reg8,mem 8086
-\c TEST reg16,mem 8086
-\c TEST reg32,mem 386
-\c TEST reg64,mem X64
-\c TEST reg_al,imm 8086
-\c TEST reg_ax,imm 8086
-\c TEST reg_eax,imm 386
-\c TEST reg_rax,imm X64
-\c TEST rm8,imm 8086
-\c TEST rm16,imm 8086
-\c TEST rm32,imm 386
-\c TEST rm64,imm X64
-\c TEST mem,imm8 8086
-\c TEST mem,imm16 8086
-\c TEST mem,imm32 386
-\c UD0 186,UNDOC
-\c UD1 186,UNDOC
-\c UD2B 186,UNDOC,ND
-\c UD2 186
-\c UD2A 186,ND
-\c UMOV mem,reg8 386,UNDOC,ND
-\c UMOV reg8,reg8 386,UNDOC,ND
-\c UMOV mem,reg16 386,UNDOC,ND
-\c UMOV reg16,reg16 386,UNDOC,ND
-\c UMOV mem,reg32 386,UNDOC,ND
-\c UMOV reg32,reg32 386,UNDOC,ND
-\c UMOV reg8,mem 386,UNDOC,ND
-\c UMOV reg8,reg8 386,UNDOC,ND
-\c UMOV reg16,mem 386,UNDOC,ND
-\c UMOV reg16,reg16 386,UNDOC,ND
-\c UMOV reg32,mem 386,UNDOC,ND
-\c UMOV reg32,reg32 386,UNDOC,ND
-\c VERR mem 286,PROT
-\c VERR mem16 286,PROT
-\c VERR reg16 286,PROT
-\c VERW mem 286,PROT
-\c VERW mem16 286,PROT
-\c VERW reg16 286,PROT
-\c FWAIT 8086
-\c WBINVD 486,PRIV
-\c WRSHR rm32 P6,CYRIXM
-\c WRMSR PENT,PRIV
-\c XADD mem,reg8 486
-\c XADD reg8,reg8 486
-\c XADD mem,reg16 486
-\c XADD reg16,reg16 486
-\c XADD mem,reg32 486
-\c XADD reg32,reg32 486
-\c XADD mem,reg64 X64
-\c XADD reg64,reg64 X64
-\c XBTS reg16,mem 386,SW,UNDOC,ND
-\c XBTS reg16,reg16 386,UNDOC,ND
-\c XBTS reg32,mem 386,SD,UNDOC,ND
-\c XBTS reg32,reg32 386,UNDOC,ND
-\c XCHG reg_ax,reg16 8086
-\c XCHG reg_eax,reg32na 386
-\c XCHG reg_rax,reg64 X64
-\c XCHG reg16,reg_ax 8086
-\c XCHG reg32na,reg_eax 386
-\c XCHG reg64,reg_rax X64
-\c XCHG reg_eax,reg_eax 386,NOLONG
-\c XCHG reg8,mem 8086
-\c XCHG reg8,reg8 8086
-\c XCHG reg16,mem 8086
-\c XCHG reg16,reg16 8086
-\c XCHG reg32,mem 386
-\c XCHG reg32,reg32 386
-\c XCHG reg64,mem X64
-\c XCHG reg64,reg64 X64
-\c XCHG mem,reg8 8086
-\c XCHG reg8,reg8 8086
-\c XCHG mem,reg16 8086
-\c XCHG reg16,reg16 8086
-\c XCHG mem,reg32 386
-\c XCHG reg32,reg32 386
-\c XCHG mem,reg64 X64
-\c XCHG reg64,reg64 X64
-\c XLATB 8086
-\c XLAT 8086
-\c XOR mem,reg8 8086
-\c XOR reg8,reg8 8086
-\c XOR mem,reg16 8086
-\c XOR reg16,reg16 8086
-\c XOR mem,reg32 386
-\c XOR reg32,reg32 386
-\c XOR mem,reg64 X64
-\c XOR reg64,reg64 X64
-\c XOR reg8,mem 8086
-\c XOR reg8,reg8 8086
-\c XOR reg16,mem 8086
-\c XOR reg16,reg16 8086
-\c XOR reg32,mem 386
-\c XOR reg32,reg32 386
-\c XOR reg64,mem X64
-\c XOR reg64,reg64 X64
-\c XOR rm16,imm8 8086
-\c XOR rm32,imm8 386
-\c XOR rm64,imm8 X64
-\c XOR reg_al,imm 8086
-\c XOR reg_ax,sbyte16 8086
-\c XOR reg_ax,imm 8086
-\c XOR reg_eax,sbyte32 386
-\c XOR reg_eax,imm 386
-\c XOR reg_rax,sbyte64 X64
-\c XOR reg_rax,imm X64
-\c XOR rm8,imm 8086
-\c XOR rm16,imm 8086
-\c XOR rm32,imm 386
-\c XOR rm64,imm X64
-\c XOR mem,imm8 8086
-\c XOR mem,imm16 8086
-\c XOR mem,imm32 386
-\c CMOVcc reg16,mem P6
-\c CMOVcc reg16,reg16 P6
-\c CMOVcc reg32,mem P6
-\c CMOVcc reg32,reg32 P6
-\c CMOVcc reg64,mem X64
-\c CMOVcc reg64,reg64 X64
-\c Jcc imm|near 386
-\c Jcc imm16|near 386
-\c Jcc imm32|near 386
-\c Jcc imm|short 8086,ND
-\c Jcc imm 8086,ND
-\c Jcc imm 386,ND
-\c Jcc imm 8086,ND
-\c Jcc imm 8086
-\c SETcc mem 386
-\c SETcc reg8 386
-
-\S{} Katmai Streaming SIMD instructions (SSE -- a.k.a. KNI, XMM, MMX2)
-
-\c ADDPS xmmreg,xmmrm KATMAI,SSE
-\c ADDSS xmmreg,xmmrm KATMAI,SSE,SD
-\c ANDNPS xmmreg,xmmrm KATMAI,SSE
-\c ANDPS xmmreg,xmmrm KATMAI,SSE
-\c CMPEQPS xmmreg,xmmrm KATMAI,SSE
-\c CMPEQSS xmmreg,xmmrm KATMAI,SSE
-\c CMPLEPS xmmreg,xmmrm KATMAI,SSE
-\c CMPLESS xmmreg,xmmrm KATMAI,SSE
-\c CMPLTPS xmmreg,xmmrm KATMAI,SSE
-\c CMPLTSS xmmreg,xmmrm KATMAI,SSE
-\c CMPNEQPS xmmreg,xmmrm KATMAI,SSE
-\c CMPNEQSS xmmreg,xmmrm KATMAI,SSE
-\c CMPNLEPS xmmreg,xmmrm KATMAI,SSE
-\c CMPNLESS xmmreg,xmmrm KATMAI,SSE
-\c CMPNLTPS xmmreg,xmmrm KATMAI,SSE
-\c CMPNLTSS xmmreg,xmmrm KATMAI,SSE
-\c CMPORDPS xmmreg,xmmrm KATMAI,SSE
-\c CMPORDSS xmmreg,xmmrm KATMAI,SSE
-\c CMPUNORDPS xmmreg,xmmrm KATMAI,SSE
-\c CMPUNORDSS xmmreg,xmmrm KATMAI,SSE
-\c CMPPS xmmreg,mem,imm KATMAI,SSE
-\c CMPPS xmmreg,xmmreg,imm KATMAI,SSE
-\c CMPSS xmmreg,mem,imm KATMAI,SSE
-\c CMPSS xmmreg,xmmreg,imm KATMAI,SSE
-\c COMISS xmmreg,xmmrm KATMAI,SSE
-\c CVTPI2PS xmmreg,mmxrm KATMAI,SSE,MMX
-\c CVTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
-\c CVTSI2SS xmmreg,mem KATMAI,SSE,SD,AR1,ND
-\c CVTSI2SS xmmreg,rm32 KATMAI,SSE,SD,AR1
-\c CVTSI2SS xmmreg,rm64 X64,SSE,AR1
-\c CVTSS2SI reg32,xmmreg KATMAI,SSE,SD,AR1
-\c CVTSS2SI reg32,mem KATMAI,SSE,SD,AR1
-\c CVTSS2SI reg64,xmmreg X64,SSE,SD,AR1
-\c CVTSS2SI reg64,mem X64,SSE,SD,AR1
-\c CVTTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
-\c CVTTSS2SI reg32,xmmrm KATMAI,SSE,SD,AR1
-\c CVTTSS2SI reg64,xmmrm X64,SSE,SD,AR1
-\c DIVPS xmmreg,xmmrm KATMAI,SSE
-\c DIVSS xmmreg,xmmrm KATMAI,SSE
-\c LDMXCSR mem KATMAI,SSE,SD
-\c MAXPS xmmreg,xmmrm KATMAI,SSE
-\c MAXSS xmmreg,xmmrm KATMAI,SSE
-\c MINPS xmmreg,xmmrm KATMAI,SSE
-\c MINSS xmmreg,xmmrm KATMAI,SSE
-\c MOVAPS xmmreg,mem KATMAI,SSE
-\c MOVAPS mem,xmmreg KATMAI,SSE
-\c MOVAPS xmmreg,xmmreg KATMAI,SSE
-\c MOVAPS xmmreg,xmmreg KATMAI,SSE
-\c MOVHPS xmmreg,mem KATMAI,SSE
-\c MOVHPS mem,xmmreg KATMAI,SSE
-\c MOVLHPS xmmreg,xmmreg KATMAI,SSE
-\c MOVLPS xmmreg,mem KATMAI,SSE
-\c MOVLPS mem,xmmreg KATMAI,SSE
-\c MOVHLPS xmmreg,xmmreg KATMAI,SSE
-\c MOVMSKPS reg32,xmmreg KATMAI,SSE
-\c MOVMSKPS reg64,xmmreg X64,SSE
-\c MOVNTPS mem,xmmreg KATMAI,SSE
-\c MOVSS xmmreg,mem KATMAI,SSE
-\c MOVSS mem,xmmreg KATMAI,SSE
-\c MOVSS xmmreg,xmmreg KATMAI,SSE
-\c MOVSS xmmreg,xmmreg KATMAI,SSE
-\c MOVUPS xmmreg,mem KATMAI,SSE
-\c MOVUPS mem,xmmreg KATMAI,SSE
-\c MOVUPS xmmreg,xmmreg KATMAI,SSE
-\c MOVUPS xmmreg,xmmreg KATMAI,SSE
-\c MULPS xmmreg,xmmrm KATMAI,SSE
-\c MULSS xmmreg,xmmrm KATMAI,SSE
-\c ORPS xmmreg,xmmrm KATMAI,SSE
-\c RCPPS xmmreg,xmmrm KATMAI,SSE
-\c RCPSS xmmreg,xmmrm KATMAI,SSE
-\c RSQRTPS xmmreg,xmmrm KATMAI,SSE
-\c RSQRTSS xmmreg,xmmrm KATMAI,SSE
-\c SHUFPS xmmreg,mem,imm KATMAI,SSE
-\c SHUFPS xmmreg,xmmreg,imm KATMAI,SSE
-\c SQRTPS xmmreg,xmmrm KATMAI,SSE
-\c SQRTSS xmmreg,xmmrm KATMAI,SSE
-\c STMXCSR mem KATMAI,SSE,SD
-\c SUBPS xmmreg,xmmrm KATMAI,SSE
-\c SUBSS xmmreg,xmmrm KATMAI,SSE
-\c UCOMISS xmmreg,xmmrm KATMAI,SSE
-\c UNPCKHPS xmmreg,xmmrm KATMAI,SSE
-\c UNPCKLPS xmmreg,xmmrm KATMAI,SSE
-\c XORPS xmmreg,xmmrm KATMAI,SSE
-
-\S{} Introduced in Deschutes but necessary for SSE support
-
-\c FXRSTOR mem P6,SSE,FPU
-\c FXSAVE mem P6,SSE,FPU
-
-\S{} XSAVE group (AVX and extended state)
-
-\c XGETBV NEHALEM
-\c XSETBV NEHALEM,PRIV
-\c XSAVE mem NEHALEM
-\c XRSTOR mem NEHALEM
-
-\S{} Generic memory operations
-
-\c PREFETCHNTA mem KATMAI
-\c PREFETCHT0 mem KATMAI
-\c PREFETCHT1 mem KATMAI
-\c PREFETCHT2 mem KATMAI
-\c SFENCE KATMAI
-
-\S{} New MMX instructions introduced in Katmai
-
-\c MASKMOVQ mmxreg,mmxreg KATMAI,MMX
-\c MOVNTQ mem,mmxreg KATMAI,MMX
-\c PAVGB mmxreg,mmxrm KATMAI,MMX
-\c PAVGW mmxreg,mmxrm KATMAI,MMX
-\c PEXTRW reg32,mmxreg,imm KATMAI,MMX
-\c PINSRW mmxreg,mem,imm KATMAI,MMX
-\c PINSRW mmxreg,rm16,imm KATMAI,MMX
-\c PINSRW mmxreg,reg32,imm KATMAI,MMX
-\c PMAXSW mmxreg,mmxrm KATMAI,MMX
-\c PMAXUB mmxreg,mmxrm KATMAI,MMX
-\c PMINSW mmxreg,mmxrm KATMAI,MMX
-\c PMINUB mmxreg,mmxrm KATMAI,MMX
-\c PMOVMSKB reg32,mmxreg KATMAI,MMX
-\c PMULHUW mmxreg,mmxrm KATMAI,MMX
-\c PSADBW mmxreg,mmxrm KATMAI,MMX
-\c PSHUFW mmxreg,mmxrm,imm KATMAI,MMX2
-
-\S{} AMD Enhanced 3DNow! (Athlon) instructions
-
-\c PF2IW mmxreg,mmxrm PENT,3DNOW
-\c PFNACC mmxreg,mmxrm PENT,3DNOW
-\c PFPNACC mmxreg,mmxrm PENT,3DNOW
-\c PI2FW mmxreg,mmxrm PENT,3DNOW
-\c PSWAPD mmxreg,mmxrm PENT,3DNOW
-
-\S{} Willamette SSE2 Cacheability Instructions
-
-\c MASKMOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
-\c CLFLUSH mem WILLAMETTE,SSE2
-\c MOVNTDQ mem,xmmreg WILLAMETTE,SSE2,SO
-\c MOVNTI mem,reg32 WILLAMETTE,SD
-\c MOVNTI mem,reg64 X64
-\c MOVNTPD mem,xmmreg WILLAMETTE,SSE2,SO
-\c LFENCE WILLAMETTE,SSE2
-\c MFENCE WILLAMETTE,SSE2
-
-\S{} Willamette MMX instructions (SSE2 SIMD Integer Instructions)
-
-\c MOVD mem,xmmreg WILLAMETTE,SSE2,SD
-\c MOVD xmmreg,mem WILLAMETTE,SSE2,SD
-\c MOVD xmmreg,rm32 WILLAMETTE,SSE2
-\c MOVD rm32,xmmreg WILLAMETTE,SSE2
-\c MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVDQA mem,xmmreg WILLAMETTE,SSE2,SO
-\c MOVDQA xmmreg,mem WILLAMETTE,SSE2,SO
-\c MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVDQU mem,xmmreg WILLAMETTE,SSE2,SO
-\c MOVDQU xmmreg,mem WILLAMETTE,SSE2,SO
-\c MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVDQ2Q mmxreg,xmmreg WILLAMETTE,SSE2
-\c MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVQ mem,xmmreg WILLAMETTE,SSE2
-\c MOVQ xmmreg,mem WILLAMETTE,SSE2
-\c MOVQ xmmreg,rm64 X64,SSE2
-\c MOVQ rm64,xmmreg X64,SSE2
-\c MOVQ2DQ xmmreg,mmxreg WILLAMETTE,SSE2
-\c PACKSSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PACKSSDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PACKUSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDQ mmxreg,mmxrm WILLAMETTE,MMX
-\c PADDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PADDUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PAND xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PANDN xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PAVGB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PAVGW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PCMPEQB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PCMPEQW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PCMPEQD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PCMPGTB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PCMPGTW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PCMPGTD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PEXTRW reg32,xmmreg,imm WILLAMETTE,SSE2
-\c PINSRW xmmreg,reg16,imm WILLAMETTE,SSE2
-\c PINSRW xmmreg,reg32,imm WILLAMETTE,SSE2,ND
-\c PINSRW xmmreg,mem,imm WILLAMETTE,SSE2
-\c PINSRW xmmreg,mem16,imm WILLAMETTE,SSE2
-\c PMADDWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMAXSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMAXUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMINSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMINUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMOVMSKB reg32,xmmreg WILLAMETTE,SSE2
-\c PMULHUW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMULHW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMULLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PMULUDQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
-\c PMULUDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c POR xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSADBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSHUFD xmmreg,xmmreg,imm WILLAMETTE,SSE2
-\c PSHUFD xmmreg,mem,imm WILLAMETTE,SSE22
-\c PSHUFHW xmmreg,xmmreg,imm WILLAMETTE,SSE2
-\c PSHUFHW xmmreg,mem,imm WILLAMETTE,SSE22
-\c PSHUFLW xmmreg,xmmreg,imm WILLAMETTE,SSE2
-\c PSHUFLW xmmreg,mem,imm WILLAMETTE,SSE22
-\c PSLLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSLLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSLLW xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSLLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSLLD xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSLLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSLLQ xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSRAW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSRAW xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSRAD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSRAD xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSRLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSRLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSRLW xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSRLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSRLD xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSRLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSRLQ xmmreg,imm WILLAMETTE,SSE2,AR1
-\c PSUBB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
-\c PSUBQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PSUBUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKHBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKHWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKHDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKHQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKLBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKLWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKLDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PUNPCKLQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c PXOR xmmreg,xmmrm WILLAMETTE,SSE2,SO
-
-\S{} Willamette Streaming SIMD instructions (SSE2)
-
-\c ADDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c ADDSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c ANDNPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c ANDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPEQSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPLESD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPLTSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPNEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPNEQSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPNLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPNLESD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPNLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPNLTSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPORDSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPUNORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CMPUNORDSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CMPPD xmmreg,xmmrm,imm WILLAMETTE,SSE22
-\c CMPSD xmmreg,xmmrm,imm WILLAMETTE,SSE2
-\c COMISD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CVTDQ2PD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CVTDQ2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTPD2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTPI2PD xmmreg,mmxrm WILLAMETTE,SSE2
-\c CVTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTPS2PD xmmreg,xmmrm WILLAMETTE,SSE2
-\c CVTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
-\c CVTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
-\c CVTSD2SI reg64,xmmreg X64,SSE2,AR1
-\c CVTSD2SI reg64,mem X64,SSE2,AR1
-\c CVTSD2SS xmmreg,xmmrm WILLAMETTE,SSE2
-\c CVTSI2SD xmmreg,mem WILLAMETTE,SSE2,SD,AR1,ND
-\c CVTSI2SD xmmreg,rm32 WILLAMETTE,SSE2,SD,AR1
-\c CVTSI2SD xmmreg,rm64 X64,SSE2,AR1
-\c CVTSS2SD xmmreg,xmmrm WILLAMETTE,SSE2,SD
-\c CVTTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c CVTTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
-\c CVTTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
-\c CVTTSD2SI reg64,xmmreg X64,SSE2,AR1
-\c CVTTSD2SI reg64,mem X64,SSE2,AR1
-\c DIVPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c DIVSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c MAXPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c MAXSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c MINPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c MINSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVAPD mem,xmmreg WILLAMETTE,SSE2,SO
-\c MOVAPD xmmreg,mem WILLAMETTE,SSE2,SO
-\c MOVHPD mem,xmmreg WILLAMETTE,SSE2
-\c MOVHPD xmmreg,mem WILLAMETTE,SSE2
-\c MOVLPD mem,xmmreg WILLAMETTE,SSE2
-\c MOVLPD xmmreg,mem WILLAMETTE,SSE2
-\c MOVMSKPD reg32,xmmreg WILLAMETTE,SSE2
-\c MOVMSKPD reg64,xmmreg X64,SSE2
-\c MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVSD mem,xmmreg WILLAMETTE,SSE2
-\c MOVSD xmmreg,mem WILLAMETTE,SSE2
-\c MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
-\c MOVUPD mem,xmmreg WILLAMETTE,SSE2,SO
-\c MOVUPD xmmreg,mem WILLAMETTE,SSE2,SO
-\c MULPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c MULSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c ORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c SHUFPD xmmreg,xmmreg,imm WILLAMETTE,SSE2
-\c SHUFPD xmmreg,mem,imm WILLAMETTE,SSE2
-\c SQRTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c SQRTSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c SUBPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c SUBSD xmmreg,xmmrm WILLAMETTE,SSE2
-\c UCOMISD xmmreg,xmmrm WILLAMETTE,SSE2
-\c UNPCKHPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c UNPCKLPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-\c XORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-
-\S{} Prescott New Instructions (SSE3)
-
-\c ADDSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
-\c ADDSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
-\c HADDPD xmmreg,xmmrm PRESCOTT,SSE3,SO
-\c HADDPS xmmreg,xmmrm PRESCOTT,SSE3,SO
-\c HSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
-\c HSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
-\c LDDQU xmmreg,mem PRESCOTT,SSE3,SO
-\c MOVDDUP xmmreg,xmmrm PRESCOTT,SSE3
-\c MOVSHDUP xmmreg,xmmrm PRESCOTT,SSE3
-\c MOVSLDUP xmmreg,xmmrm PRESCOTT,SSE3
-
-\S{} VMX Instructions
-
-\c VMCALL VMX
-\c VMCLEAR mem VMX
-\c VMLAUNCH VMX
-\c VMLOAD X64,VMX
-\c VMMCALL X64,VMX
-\c VMPTRLD mem VMX
-\c VMPTRST mem VMX
-\c VMREAD rm32,reg32 VMX,NOLONG,SD
-\c VMREAD rm64,reg64 X64,VMX
-\c VMRESUME VMX
-\c VMRUN X64,VMX
-\c VMSAVE X64,VMX
-\c VMWRITE reg32,rm32 VMX,NOLONG,SD
-\c VMWRITE reg64,rm64 X64,VMX
-\c VMXOFF VMX
-\c VMXON mem VMX
-
-\S{} Extended Page Tables VMX instructions
-
-\c INVEPT reg32,mem VMX,SO,NOLONG
-\c INVEPT reg64,mem VMX,SO,LONG
-\c INVVPID reg32,mem VMX,SO,NOLONG
-\c INVVPID reg64,mem VMX,SO,LONG
-
-\S{} Tejas New Instructions (SSSE3)
-
-\c PABSB mmxreg,mmxrm SSSE3,MMX
-\c PABSB xmmreg,xmmrm SSSE3
-\c PABSW mmxreg,mmxrm SSSE3,MMX
-\c PABSW xmmreg,xmmrm SSSE3
-\c PABSD mmxreg,mmxrm SSSE3,MMX
-\c PABSD xmmreg,xmmrm SSSE3
-\c PALIGNR mmxreg,mmxrm,imm SSSE3,MMX
-\c PALIGNR xmmreg,xmmrm,imm SSSE3
-\c PHADDW mmxreg,mmxrm SSSE3,MMX
-\c PHADDW xmmreg,xmmrm SSSE3
-\c PHADDD mmxreg,mmxrm SSSE3,MMX
-\c PHADDD xmmreg,xmmrm SSSE3
-\c PHADDSW mmxreg,mmxrm SSSE3,MMX
-\c PHADDSW xmmreg,xmmrm SSSE3
-\c PHSUBW mmxreg,mmxrm SSSE3,MMX
-\c PHSUBW xmmreg,xmmrm SSSE3
-\c PHSUBD mmxreg,mmxrm SSSE3,MMX
-\c PHSUBD xmmreg,xmmrm SSSE3
-\c PHSUBSW mmxreg,mmxrm SSSE3,MMX
-\c PHSUBSW xmmreg,xmmrm SSSE3
-\c PMADDUBSW mmxreg,mmxrm SSSE3,MMX
-\c PMADDUBSW xmmreg,xmmrm SSSE3
-\c PMULHRSW mmxreg,mmxrm SSSE3,MMX
-\c PMULHRSW xmmreg,xmmrm SSSE3
-\c PSHUFB mmxreg,mmxrm SSSE3,MMX
-\c PSHUFB xmmreg,xmmrm SSSE3
-\c PSIGNB mmxreg,mmxrm SSSE3,MMX
-\c PSIGNB xmmreg,xmmrm SSSE3
-\c PSIGNW mmxreg,mmxrm SSSE3,MMX
-\c PSIGNW xmmreg,xmmrm SSSE3
-\c PSIGND mmxreg,mmxrm SSSE3,MMX
-\c PSIGND xmmreg,xmmrm SSSE3
-
-\S{} AMD SSE4A
-
-\c EXTRQ xmmreg,imm,imm SSE4A,AMD
-\c EXTRQ xmmreg,xmmreg SSE4A,AMD
-\c INSERTQ xmmreg,xmmreg,imm,imm SSE4A,AMD
-\c INSERTQ xmmreg,xmmreg SSE4A,AMD
-\c MOVNTSD mem,xmmreg SSE4A,AMD
-\c MOVNTSS mem,xmmreg SSE4A,AMD,SD
-
-\S{} New instructions in Barcelona
-
-\c LZCNT reg16,rm16 P6,AMD
-\c LZCNT reg32,rm32 P6,AMD
-\c LZCNT reg64,rm64 X64,AMD
-
-\S{} Penryn New Instructions (SSE4.1)
-
-\c BLENDPD xmmreg,xmmrm,imm SSE41
-\c BLENDPS xmmreg,xmmrm,imm SSE41
-\c BLENDVPD xmmreg,xmmrm,xmm0 SSE41
-\c BLENDVPS xmmreg,xmmrm,xmm0 SSE41
-\c DPPD xmmreg,xmmrm,imm SSE41
-\c DPPS xmmreg,xmmrm,imm SSE41
-\c EXTRACTPS rm32,xmmreg,imm SSE41
-\c EXTRACTPS reg64,xmmreg,imm SSE41,X64
-\c INSERTPS xmmreg,xmmrm,imm SSE41,SD
-\c MOVNTDQA xmmreg,mem SSE41
-\c MPSADBW xmmreg,xmmrm,imm SSE41
-\c PACKUSDW xmmreg,xmmrm SSE41
-\c PBLENDVB xmmreg,xmmrm,xmm0 SSE41
-\c PBLENDW xmmreg,xmmrm,imm SSE41
-\c PCMPEQQ xmmreg,xmmrm SSE41
-\c PEXTRB reg32,xmmreg,imm SSE41
-\c PEXTRB mem8,xmmreg,imm SSE41
-\c PEXTRB reg64,xmmreg,imm SSE41,X64
-\c PEXTRD rm32,xmmreg,imm SSE41
-\c PEXTRQ rm64,xmmreg,imm SSE41,X64
-\c PEXTRW reg32,xmmreg,imm SSE41
-\c PEXTRW mem16,xmmreg,imm SSE41
-\c PEXTRW reg64,xmmreg,imm SSE41,X64
-\c PHMINPOSUW xmmreg,xmmrm SSE41
-\c PINSRB xmmreg,mem,imm SSE41
-\c PINSRB xmmreg,rm8,imm SSE41
-\c PINSRB xmmreg,reg32,imm SSE41
-\c PINSRD xmmreg,mem,imm SSE41
-\c PINSRD xmmreg,rm32,imm SSE41
-\c PINSRQ xmmreg,mem,imm SSE41,X64
-\c PINSRQ xmmreg,rm64,imm SSE41,X64
-\c PMAXSB xmmreg,xmmrm SSE41
-\c PMAXSD xmmreg,xmmrm SSE41
-\c PMAXUD xmmreg,xmmrm SSE41
-\c PMAXUW xmmreg,xmmrm SSE41
-\c PMINSB xmmreg,xmmrm SSE41
-\c PMINSD xmmreg,xmmrm SSE41
-\c PMINUD xmmreg,xmmrm SSE41
-\c PMINUW xmmreg,xmmrm SSE41
-\c PMOVSXBW xmmreg,xmmrm SSE41
-\c PMOVSXBD xmmreg,xmmrm SSE41,SD
-\c PMOVSXBQ xmmreg,xmmrm SSE41,SW
-\c PMOVSXWD xmmreg,xmmrm SSE41
-\c PMOVSXWQ xmmreg,xmmrm SSE41,SD
-\c PMOVSXDQ xmmreg,xmmrm SSE41
-\c PMOVZXBW xmmreg,xmmrm SSE41
-\c PMOVZXBD xmmreg,xmmrm SSE41,SD
-\c PMOVZXBQ xmmreg,xmmrm SSE41,SW
-\c PMOVZXWD xmmreg,xmmrm SSE41
-\c PMOVZXWQ xmmreg,xmmrm SSE41,SD
-\c PMOVZXDQ xmmreg,xmmrm SSE41
-\c PMULDQ xmmreg,xmmrm SSE41
-\c PMULLD xmmreg,xmmrm SSE41
-\c PTEST xmmreg,xmmrm SSE41
-\c ROUNDPD xmmreg,xmmrm,imm SSE41
-\c ROUNDPS xmmreg,xmmrm,imm SSE41
-\c ROUNDSD xmmreg,xmmrm,imm SSE41
-\c ROUNDSS xmmreg,xmmrm,imm SSE41
-
-\S{} Nehalem New Instructions (SSE4.2)
-
-\c CRC32 reg32,rm8 SSE42
-\c CRC32 reg32,rm16 SSE42
-\c CRC32 reg32,rm32 SSE42
-\c CRC32 reg64,rm8 SSE42,X64
-\c CRC32 reg64,rm64 SSE42,X64
-\c PCMPESTRI xmmreg,xmmrm,imm SSE42
-\c PCMPESTRM xmmreg,xmmrm,imm SSE42
-\c PCMPISTRI xmmreg,xmmrm,imm SSE42
-\c PCMPISTRM xmmreg,xmmrm,imm SSE42
-\c PCMPGTQ xmmreg,xmmrm SSE42
-\c POPCNT reg16,rm16 NEHALEM,SW
-\c POPCNT reg32,rm32 NEHALEM,SD
-\c POPCNT reg64,rm64 NEHALEM,X64
-
-\S{} Intel SMX
-
-\c GETSEC KATMAI
-
-\S{} Geode (Cyrix) 3DNow! additions
-
-\c PFRCPV mmxreg,mmxrm PENT,3DNOW,CYRIX
-\c PFRSQRTV mmxreg,mmxrm PENT,3DNOW,CYRIX
-
-\S{} Intel new instructions in ???
-
-\c MOVBE reg16,mem16 NEHALEM
-\c MOVBE reg32,mem32 NEHALEM
-\c MOVBE reg64,mem64 NEHALEM
-\c MOVBE mem16,reg16 NEHALEM
-\c MOVBE mem32,reg32 NEHALEM
-\c MOVBE mem64,reg64 NEHALEM
-
-\S{} Intel AES instructions
-
-\c AESENC xmmreg,xmmrm128 SSE,WESTMERE
-\c AESENCLAST xmmreg,xmmrm128 SSE,WESTMERE
-\c AESDEC xmmreg,xmmrm128 SSE,WESTMERE
-\c AESDECLAST xmmreg,xmmrm128 SSE,WESTMERE
-\c AESIMC xmmreg,xmmrm128 SSE,WESTMERE
-\c AESKEYGENASSIST xmmreg,xmmrm128,imm8 SSE,WESTMERE
-
-\S{} Intel AVX AES instructions
-
-\c VAESENC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VAESENCLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VAESDEC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VAESDECLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VAESIMC xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VAESKEYGENASSIST xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-
-\S{} Intel AVX instructions
-
-\c VADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VADDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VADDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VADDSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VADDSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VADDSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VADDSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VANDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VANDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VANDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VANDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VANDNPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VANDNPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VANDNPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VANDNPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VBLENDPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VBLENDPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VBLENDPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VBLENDPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VBLENDVPD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VBLENDVPD xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
-\c VBLENDVPD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
-\c VBLENDVPS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VBLENDVPS xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
-\c VBLENDVPS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
-\c VBROADCASTSS xmmreg,mem32 AVX,SANDYBRIDGE
-\c VBROADCASTSS ymmreg,mem32 AVX,SANDYBRIDGE
-\c VBROADCASTSD ymmreg,mem64 AVX,SANDYBRIDGE
-\c VBROADCASTF128 ymmreg,mem128 AVX,SANDYBRIDGE
-\c VCMPEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPUNORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPUNORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPEQ_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQ_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPFALSEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPFALSEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQ_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQ_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPTRUEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPTRUEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPUNORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPUNORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPFALSE_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPFALSE_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPTRUE_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPTRUE_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VCMPPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VCMPEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPUNORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPUNORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPEQ_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQ_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPFALSEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPFALSEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQ_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQ_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPTRUEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPTRUEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPLE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPLE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPUNORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPUNORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNLE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNLE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNGT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNGT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPFALSE_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPFALSE_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPNEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPNEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPGT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPGT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPTRUE_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VCMPTRUE_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VCMPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VCMPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VCMPEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPUNORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPEQ_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPFALSESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNEQ_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPTRUESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPLT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPLE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPUNORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNLT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNLE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNGE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNGT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPFALSE_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPNEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPGE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPGT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPTRUE_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCMPSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
-\c VCMPEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPUNORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPEQ_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPFALSESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNEQ_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPTRUESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPLT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPLE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPUNORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNLT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNLE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNGE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNGT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPFALSE_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPNEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPGE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPGT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPTRUE_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCMPSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
-\c VCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
-\c VCVTDQ2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VCVTDQ2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VCVTDQ2PS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VCVTDQ2PS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VCVTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
-\c VCVTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
-\c VCVTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
-\c VCVTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
-\c VCVTPD2PS xmmreg,xmmreg AVX,SANDYBRIDGE
-\c VCVTPD2PS xmmreg,mem128 AVX,SANDYBRIDGE,SO
-\c VCVTPD2PS xmmreg,ymmreg AVX,SANDYBRIDGE
-\c VCVTPD2PS xmmreg,mem256 AVX,SANDYBRIDGE,SY
-\c VCVTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VCVTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VCVTPS2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VCVTPS2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VCVTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
-\c VCVTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
-\c VCVTSD2SS xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VCVTSI2SD xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
-\c VCVTSI2SD xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
-\c VCVTSI2SD xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
-\c VCVTSI2SS xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
-\c VCVTSI2SS xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
-\c VCVTSI2SS xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
-\c VCVTSS2SD xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VCVTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
-\c VCVTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
-\c VCVTTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
-\c VCVTTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
-\c VCVTTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
-\c VCVTTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
-\c VCVTTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VCVTTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VCVTTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
-\c VCVTTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
-\c VCVTTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
-\c VCVTTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
-\c VDIVPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VDIVPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VDIVPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VDIVPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VDIVSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VDIVSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VDPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VDPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VDPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VEXTRACTF128 xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VEXTRACTPS rm32,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VHADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VHADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VHADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VHADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VHSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VHSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VHSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VHSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VINSERTF128 ymmreg,ymmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VINSERTPS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
-\c VLDDQU xmmreg,mem128 AVX,SANDYBRIDGE
-\c VLDQQU ymmreg,mem256 AVX,SANDYBRIDGE
-\c VLDDQU ymmreg,mem256 AVX,SANDYBRIDGE
-\c VLDMXCSR mem32 AVX,SANDYBRIDGE
-\c VMASKMOVDQU xmmreg,xmmreg AVX,SANDYBRIDGE
-\c VMASKMOVPS xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
-\c VMASKMOVPS ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
-\c VMASKMOVPS mem128,xmmreg,xmmreg AVX,SANDYBRIDGE,SO
-\c VMASKMOVPS mem256,xmmreg,xmmreg AVX,SANDYBRIDGE,SY
-\c VMASKMOVPD xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
-\c VMASKMOVPD ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
-\c VMASKMOVPD mem128,xmmreg,xmmreg AVX,SANDYBRIDGE
-\c VMASKMOVPD mem256,ymmreg,ymmreg AVX,SANDYBRIDGE
-\c VMAXPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VMAXPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VMAXPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VMAXPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VMAXSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VMAXSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VMINPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VMINPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VMINPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VMINPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VMINSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VMINSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VMOVAPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVAPD xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VMOVAPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVAPD ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVAPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVAPS xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VMOVAPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVAPS ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VMOVQ xmmrm64,xmmreg AVX,SANDYBRIDGE
-\c VMOVQ xmmreg,rm64 AVX,SANDYBRIDGE,LONG
-\c VMOVQ rm64,xmmreg AVX,SANDYBRIDGE,LONG
-\c VMOVD xmmreg,rm32 AVX,SANDYBRIDGE
-\c VMOVD rm32,xmmreg AVX,SANDYBRIDGE
-\c VMOVDDUP xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VMOVDDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVDQA xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVDQA xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VMOVQQA ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVQQA ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVDQA ymmreg,ymmrm AVX,SANDYBRIDGE
-\c VMOVDQA ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVDQU xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVDQU xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VMOVQQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVQQU ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVDQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVDQU ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVHLPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-\c VMOVHPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-\c VMOVHPD mem64,xmmreg AVX,SANDYBRIDGE
-\c VMOVHPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-\c VMOVHPS mem64,xmmreg AVX,SANDYBRIDGE
-\c VMOVLHPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-\c VMOVLPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-\c VMOVLPD mem64,xmmreg AVX,SANDYBRIDGE
-\c VMOVLPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
-\c VMOVLPS mem64,xmmreg AVX,SANDYBRIDGE
-\c VMOVMSKPD reg64,xmmreg AVX,SANDYBRIDGE,LONG
-\c VMOVMSKPD reg32,xmmreg AVX,SANDYBRIDGE
-\c VMOVMSKPD reg64,ymmreg AVX,SANDYBRIDGE,LONG
-\c VMOVMSKPD reg32,ymmreg AVX,SANDYBRIDGE
-\c VMOVMSKPS reg64,xmmreg AVX,SANDYBRIDGE,LONG
-\c VMOVMSKPS reg32,xmmreg AVX,SANDYBRIDGE
-\c VMOVMSKPS reg64,ymmreg AVX,SANDYBRIDGE,LONG
-\c VMOVMSKPS reg32,ymmreg AVX,SANDYBRIDGE
-\c VMOVNTDQ mem128,xmmreg AVX,SANDYBRIDGE
-\c VMOVNTQQ mem256,ymmreg AVX,SANDYBRIDGE
-\c VMOVNTDQ mem256,ymmreg AVX,SANDYBRIDGE
-\c VMOVNTDQA xmmreg,mem128 AVX,SANDYBRIDGE
-\c VMOVNTPD mem128,xmmreg AVX,SANDYBRIDGE
-\c VMOVNTPD mem256,ymmreg AVX,SANDYBRIDGE
-\c VMOVNTPS mem128,xmmreg AVX,SANDYBRIDGE
-\c VMOVNTPS mem128,ymmreg AVX,SANDYBRIDGE
-\c VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-\c VMOVSD xmmreg,mem64 AVX,SANDYBRIDGE
-\c VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-\c VMOVSD mem64,xmmreg AVX,SANDYBRIDGE
-\c VMOVSHDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVSHDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVSLDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVSLDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-\c VMOVSS xmmreg,mem64 AVX,SANDYBRIDGE
-\c VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
-\c VMOVSS mem64,xmmreg AVX,SANDYBRIDGE
-\c VMOVUPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVUPD xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VMOVUPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVUPD ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMOVUPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VMOVUPS xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VMOVUPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VMOVUPS ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VMPSADBW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VMULPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VMULPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VMULPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VMULPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VMULSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VMULSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VPABSB xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPABSW xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPABSD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPACKSSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPACKSSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPACKUSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPACKUSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPADDUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPALIGNR xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPAND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPANDN xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPAVGB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPAVGW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPBLENDVB xmmreg,xmmreg*,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPBLENDW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPCMPESTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPCMPESTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPCMPISTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPCMPISTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPCMPEQB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPEQW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPEQD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPEQQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPGTB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPGTW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPGTD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCMPGTQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILPD xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILPD ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMILPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPERMILPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VPERMILTD2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPERMILTD2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILTD2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VPERMILTD2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMILMO2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPERMILMO2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILMO2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VPERMILMO2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMILMZ2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPERMILMZ2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILMZ2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VPERMILMZ2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMIL2PD xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPERMIL2PD xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPERMIL2PD ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
-\c VPERMIL2PD ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VPERMILPS xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILPS ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMILPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPERMILPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VPERMILTD2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPERMILTD2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILTD2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VPERMILTD2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMILMO2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPERMILMO2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILMO2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VPERMILMO2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMILMZ2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
-\c VPERMILMZ2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPERMILMZ2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
-\c VPERMILMZ2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPERMIL2PS xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPERMIL2PS xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPERMIL2PS ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
-\c VPERMIL2PS ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VPERM2F128 ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VPEXTRB reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-\c VPEXTRB reg32,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRB mem8,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-\c VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-\c VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRD reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-\c VPEXTRD rm32,xmmreg,imm8 AVX,SANDYBRIDGE
-\c VPEXTRQ rm64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
-\c VPHADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPHADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPHADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPHMINPOSUW xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPHSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPHSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPHSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPINSRB xmmreg,xmmreg*,mem8,imm8 AVX,SANDYBRIDGE
-\c VPINSRB xmmreg,xmmreg*,rm8,imm8 AVX,SANDYBRIDGE
-\c VPINSRB xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
-\c VPINSRW xmmreg,xmmreg*,mem16,imm8 AVX,SANDYBRIDGE
-\c VPINSRW xmmreg,xmmreg*,rm16,imm8 AVX,SANDYBRIDGE
-\c VPINSRW xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
-\c VPINSRD xmmreg,xmmreg*,mem32,imm8 AVX,SANDYBRIDGE
-\c VPINSRD xmmreg,xmmreg*,rm32,imm8 AVX,SANDYBRIDGE
-\c VPINSRQ xmmreg,xmmreg*,mem64,imm8 AVX,SANDYBRIDGE,LONG
-\c VPINSRQ xmmreg,xmmreg*,rm64,imm8 AVX,SANDYBRIDGE,LONG
-\c VPMADDWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMADDUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMAXSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMAXSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMAXSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMAXUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMAXUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMAXUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMINSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMINSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMINSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMINUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMINUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMINUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMOVMSKB reg64,xmmreg AVX,SANDYBRIDGE,LONG
-\c VPMOVMSKB reg32,xmmreg AVX,SANDYBRIDGE
-\c VPMOVSXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VPMOVSXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
-\c VPMOVSXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
-\c VPMOVSXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VPMOVSXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
-\c VPMOVSXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VPMOVZXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VPMOVZXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
-\c VPMOVZXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
-\c VPMOVZXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VPMOVZXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
-\c VPMOVZXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VPMULHUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMULHRSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMULHW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMULLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMULLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMULUDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPMULDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSADBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSHUFB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSHUFD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPSHUFHW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPSHUFLW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VPSIGNB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSIGNW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSIGND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSLLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSRLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSLLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSLLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSLLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSLLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSLLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSLLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSRAW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSRAW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSRAD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSRAD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSRLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSRLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSRLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSRLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPSRLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSRLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
-\c VPTEST xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VPTEST ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VPSUBB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPSUBUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKHBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKHWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKHDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKLBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKLWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKLDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPUNPCKLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPXOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VRCPPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VRCPPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VRCPSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VRSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VRSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VRSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VROUNDPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VROUNDPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VROUNDPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VROUNDPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VROUNDSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
-\c VROUNDSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
-\c VSHUFPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VSHUFPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VSHUFPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-\c VSHUFPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
-\c VSQRTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VSQRTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VSQRTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VSTMXCSR mem32 AVX,SANDYBRIDGE
-\c VSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VSUBSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
-\c VSUBSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
-\c VTESTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VTESTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VTESTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
-\c VTESTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
-\c VUCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
-\c VUCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
-\c VUNPCKHPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VUNPCKHPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VUNPCKHPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VUNPCKHPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VUNPCKLPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VUNPCKLPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VUNPCKLPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VUNPCKLPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VXORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VXORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VXORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VXORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
-\c VZEROALL AVX,SANDYBRIDGE
-\c VZEROUPPER AVX,SANDYBRIDGE
-
-\S{} Intel Carry-Less Multiplication instructions (CLMUL)
-
-\c PCLMULLQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
-\c PCLMULHQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
-\c PCLMULLQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
-\c PCLMULHQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
-\c PCLMULQDQ xmmreg,xmmrm128,imm8 SSE,WESTMERE
-
-\S{} Intel AVX Carry-Less Multiplication instructions (CLMUL)
-
-\c VPCLMULLQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCLMULHQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCLMULLQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCLMULHQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
-\c VPCLMULQDQ xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-
-\S{} Intel Fused Multiply-Add instructions (FMA)
-
-\c VFMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADDSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMADDSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMSUBADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFMSUBADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFNMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
-\c VFNMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
-\c VFMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-\c VFNMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
-\c VFNMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-
-\S{} VIA (Centaur) security instructions
-
-\c XSTORE PENT,CYRIX
-\c XCRYPTECB PENT,CYRIX
-\c XCRYPTCBC PENT,CYRIX
-\c XCRYPTCTR PENT,CYRIX
-\c XCRYPTCFB PENT,CYRIX
-\c XCRYPTOFB PENT,CYRIX
-\c MONTMUL PENT,CYRIX
-\c XSHA1 PENT,CYRIX
-\c XSHA256 PENT,CYRIX
-
-\S{} AMD Lightweight Profiling (LWP) instructions
-
-\c LLWPCB reg16 AMD
-\c LLWPCB reg32 AMD,386
-\c LLWPCB reg64 AMD,X64
-\c SLWPCB reg16 AMD
-\c SLWPCB reg32 AMD,386
-\c SLWPCB reg64 AMD,X64
-\c LWPVAL reg16,rm32,imm16 AMD,386
-\c LWPVAL reg32,rm32,imm32 AMD,386
-\c LWPVAL reg64,rm32,imm32 AMD,X64
-\c LWPINS reg16,rm32,imm16 AMD,386
-\c LWPINS reg32,rm32,imm32 AMD,386
-\c LWPINS reg64,rm32,imm32 AMD,X64
-
-\S{} AMD XOP, FMA4 and CVT16 instructions (SSE5)
-
-\c VCVTPH2PS xmmreg,xmmrm64*,imm8 AMD,SSE5
-\c VCVTPH2PS ymmreg,xmmrm128,imm8 AMD,SSE5
-\c VCVTPH2PS ymmreg,ymmrm128*,imm8 AMD,SSE5
-\c VCVTPS2PH xmmrm64,xmmreg*,imm8 AMD,SSE5
-\c VCVTPS2PH xmmrm128,ymmreg,imm8 AMD,SSE5
-\c VCVTPS2PH ymmrm128,ymmreg*,imm8 AMD,SSE5
-\c VFMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-\c VFMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-\c VFMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-\c VFMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-\c VFMADDSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMADDSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMADDSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMADDSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMADDSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMADDSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMADDSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMADDSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMSUBADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMSUBADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMSUBADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMSUBADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMSUBADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMSUBADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMSUBADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMSUBADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-\c VFMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-\c VFMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-\c VFMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-\c VFNMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFNMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFNMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFNMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFNMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFNMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFNMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFNMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFNMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-\c VFNMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-\c VFNMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-\c VFNMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-\c VFNMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFNMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFNMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFNMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFNMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VFNMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VFNMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VFNMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VFNMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
-\c VFNMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
-\c VFNMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
-\c VFNMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
-\c VFRCZPD xmmreg,xmmrm128* AMD,SSE5
-\c VFRCZPD ymmreg,ymmrm256* AMD,SSE5
-\c VFRCZPS xmmreg,xmmrm128* AMD,SSE5
-\c VFRCZPS ymmreg,ymmrm256* AMD,SSE5
-\c VFRCZSD xmmreg,xmmrm64* AMD,SSE5
-\c VFRCZSS xmmreg,xmmrm32* AMD,SSE5
-\c VPCMOV xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPCMOV ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
-\c VPCMOV xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VPCMOV ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
-\c VPCOMB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMUB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMUD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMUQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMUW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPCOMW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
-\c VPHADDBD xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDBQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDBW xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDDQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDUBD xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDUBQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDUBW xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDUDQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDUWD xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDUWQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDWD xmmreg,xmmrm128* AMD,SSE5
-\c VPHADDWQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHSUBBW xmmreg,xmmrm128* AMD,SSE5
-\c VPHSUBDQ xmmreg,xmmrm128* AMD,SSE5
-\c VPHSUBWD xmmreg,xmmrm128* AMD,SSE5
-\c VPMACSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMACSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMADCSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPMADCSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPPERM xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
-\c VPPERM xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
-\c VPROTB xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPROTB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPROTB xmmreg,xmmrm128*,imm8 AMD,SSE5
-\c VPROTD xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPROTD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPROTD xmmreg,xmmrm128*,imm8 AMD,SSE5
-\c VPROTQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPROTQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPROTQ xmmreg,xmmrm128*,imm8 AMD,SSE5
-\c VPROTW xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPROTW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPROTW xmmreg,xmmrm128*,imm8 AMD,SSE5
-\c VPSHAB xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHAB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHAD xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHAD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHAQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHAQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHAW xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHAW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHLB xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHLB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHLD xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHLD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHLQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHLQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-\c VPSHLW xmmreg,xmmrm128*,xmmreg AMD,SSE5
-\c VPSHLW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-
-\S{} Systematic names for the hinting nop instructions
-
-\c HINT_NOP0 rm16 P6,UNDOC
-\c HINT_NOP0 rm32 P6,UNDOC
-\c HINT_NOP0 rm64 X64,UNDOC
-\c HINT_NOP1 rm16 P6,UNDOC
-\c HINT_NOP1 rm32 P6,UNDOC
-\c HINT_NOP1 rm64 X64,UNDOC
-\c HINT_NOP2 rm16 P6,UNDOC
-\c HINT_NOP2 rm32 P6,UNDOC
-\c HINT_NOP2 rm64 X64,UNDOC
-\c HINT_NOP3 rm16 P6,UNDOC
-\c HINT_NOP3 rm32 P6,UNDOC
-\c HINT_NOP3 rm64 X64,UNDOC
-\c HINT_NOP4 rm16 P6,UNDOC
-\c HINT_NOP4 rm32 P6,UNDOC
-\c HINT_NOP4 rm64 X64,UNDOC
-\c HINT_NOP5 rm16 P6,UNDOC
-\c HINT_NOP5 rm32 P6,UNDOC
-\c HINT_NOP5 rm64 X64,UNDOC
-\c HINT_NOP6 rm16 P6,UNDOC
-\c HINT_NOP6 rm32 P6,UNDOC
-\c HINT_NOP6 rm64 X64,UNDOC
-\c HINT_NOP7 rm16 P6,UNDOC
-\c HINT_NOP7 rm32 P6,UNDOC
-\c HINT_NOP7 rm64 X64,UNDOC
-\c HINT_NOP8 rm16 P6,UNDOC
-\c HINT_NOP8 rm32 P6,UNDOC
-\c HINT_NOP8 rm64 X64,UNDOC
-\c HINT_NOP9 rm16 P6,UNDOC
-\c HINT_NOP9 rm32 P6,UNDOC
-\c HINT_NOP9 rm64 X64,UNDOC
-\c HINT_NOP10 rm16 P6,UNDOC
-\c HINT_NOP10 rm32 P6,UNDOC
-\c HINT_NOP10 rm64 X64,UNDOC
-\c HINT_NOP11 rm16 P6,UNDOC
-\c HINT_NOP11 rm32 P6,UNDOC
-\c HINT_NOP11 rm64 X64,UNDOC
-\c HINT_NOP12 rm16 P6,UNDOC
-\c HINT_NOP12 rm32 P6,UNDOC
-\c HINT_NOP12 rm64 X64,UNDOC
-\c HINT_NOP13 rm16 P6,UNDOC
-\c HINT_NOP13 rm32 P6,UNDOC
-\c HINT_NOP13 rm64 X64,UNDOC
-\c HINT_NOP14 rm16 P6,UNDOC
-\c HINT_NOP14 rm32 P6,UNDOC
-\c HINT_NOP14 rm64 X64,UNDOC
-\c HINT_NOP15 rm16 P6,UNDOC
-\c HINT_NOP15 rm32 P6,UNDOC
-\c HINT_NOP15 rm64 X64,UNDOC
-\c HINT_NOP16 rm16 P6,UNDOC
-\c HINT_NOP16 rm32 P6,UNDOC
-\c HINT_NOP16 rm64 X64,UNDOC
-\c HINT_NOP17 rm16 P6,UNDOC
-\c HINT_NOP17 rm32 P6,UNDOC
-\c HINT_NOP17 rm64 X64,UNDOC
-\c HINT_NOP18 rm16 P6,UNDOC
-\c HINT_NOP18 rm32 P6,UNDOC
-\c HINT_NOP18 rm64 X64,UNDOC
-\c HINT_NOP19 rm16 P6,UNDOC
-\c HINT_NOP19 rm32 P6,UNDOC
-\c HINT_NOP19 rm64 X64,UNDOC
-\c HINT_NOP20 rm16 P6,UNDOC
-\c HINT_NOP20 rm32 P6,UNDOC
-\c HINT_NOP20 rm64 X64,UNDOC
-\c HINT_NOP21 rm16 P6,UNDOC
-\c HINT_NOP21 rm32 P6,UNDOC
-\c HINT_NOP21 rm64 X64,UNDOC
-\c HINT_NOP22 rm16 P6,UNDOC
-\c HINT_NOP22 rm32 P6,UNDOC
-\c HINT_NOP22 rm64 X64,UNDOC
-\c HINT_NOP23 rm16 P6,UNDOC
-\c HINT_NOP23 rm32 P6,UNDOC
-\c HINT_NOP23 rm64 X64,UNDOC
-\c HINT_NOP24 rm16 P6,UNDOC
-\c HINT_NOP24 rm32 P6,UNDOC
-\c HINT_NOP24 rm64 X64,UNDOC
-\c HINT_NOP25 rm16 P6,UNDOC
-\c HINT_NOP25 rm32 P6,UNDOC
-\c HINT_NOP25 rm64 X64,UNDOC
-\c HINT_NOP26 rm16 P6,UNDOC
-\c HINT_NOP26 rm32 P6,UNDOC
-\c HINT_NOP26 rm64 X64,UNDOC
-\c HINT_NOP27 rm16 P6,UNDOC
-\c HINT_NOP27 rm32 P6,UNDOC
-\c HINT_NOP27 rm64 X64,UNDOC
-\c HINT_NOP28 rm16 P6,UNDOC
-\c HINT_NOP28 rm32 P6,UNDOC
-\c HINT_NOP28 rm64 X64,UNDOC
-\c HINT_NOP29 rm16 P6,UNDOC
-\c HINT_NOP29 rm32 P6,UNDOC
-\c HINT_NOP29 rm64 X64,UNDOC
-\c HINT_NOP30 rm16 P6,UNDOC
-\c HINT_NOP30 rm32 P6,UNDOC
-\c HINT_NOP30 rm64 X64,UNDOC
-\c HINT_NOP31 rm16 P6,UNDOC
-\c HINT_NOP31 rm32 P6,UNDOC
-\c HINT_NOP31 rm64 X64,UNDOC
-\c HINT_NOP32 rm16 P6,UNDOC
-\c HINT_NOP32 rm32 P6,UNDOC
-\c HINT_NOP32 rm64 X64,UNDOC
-\c HINT_NOP33 rm16 P6,UNDOC
-\c HINT_NOP33 rm32 P6,UNDOC
-\c HINT_NOP33 rm64 X64,UNDOC
-\c HINT_NOP34 rm16 P6,UNDOC
-\c HINT_NOP34 rm32 P6,UNDOC
-\c HINT_NOP34 rm64 X64,UNDOC
-\c HINT_NOP35 rm16 P6,UNDOC
-\c HINT_NOP35 rm32 P6,UNDOC
-\c HINT_NOP35 rm64 X64,UNDOC
-\c HINT_NOP36 rm16 P6,UNDOC
-\c HINT_NOP36 rm32 P6,UNDOC
-\c HINT_NOP36 rm64 X64,UNDOC
-\c HINT_NOP37 rm16 P6,UNDOC
-\c HINT_NOP37 rm32 P6,UNDOC
-\c HINT_NOP37 rm64 X64,UNDOC
-\c HINT_NOP38 rm16 P6,UNDOC
-\c HINT_NOP38 rm32 P6,UNDOC
-\c HINT_NOP38 rm64 X64,UNDOC
-\c HINT_NOP39 rm16 P6,UNDOC
-\c HINT_NOP39 rm32 P6,UNDOC
-\c HINT_NOP39 rm64 X64,UNDOC
-\c HINT_NOP40 rm16 P6,UNDOC
-\c HINT_NOP40 rm32 P6,UNDOC
-\c HINT_NOP40 rm64 X64,UNDOC
-\c HINT_NOP41 rm16 P6,UNDOC
-\c HINT_NOP41 rm32 P6,UNDOC
-\c HINT_NOP41 rm64 X64,UNDOC
-\c HINT_NOP42 rm16 P6,UNDOC
-\c HINT_NOP42 rm32 P6,UNDOC
-\c HINT_NOP42 rm64 X64,UNDOC
-\c HINT_NOP43 rm16 P6,UNDOC
-\c HINT_NOP43 rm32 P6,UNDOC
-\c HINT_NOP43 rm64 X64,UNDOC
-\c HINT_NOP44 rm16 P6,UNDOC
-\c HINT_NOP44 rm32 P6,UNDOC
-\c HINT_NOP44 rm64 X64,UNDOC
-\c HINT_NOP45 rm16 P6,UNDOC
-\c HINT_NOP45 rm32 P6,UNDOC
-\c HINT_NOP45 rm64 X64,UNDOC
-\c HINT_NOP46 rm16 P6,UNDOC
-\c HINT_NOP46 rm32 P6,UNDOC
-\c HINT_NOP46 rm64 X64,UNDOC
-\c HINT_NOP47 rm16 P6,UNDOC
-\c HINT_NOP47 rm32 P6,UNDOC
-\c HINT_NOP47 rm64 X64,UNDOC
-\c HINT_NOP48 rm16 P6,UNDOC
-\c HINT_NOP48 rm32 P6,UNDOC
-\c HINT_NOP48 rm64 X64,UNDOC
-\c HINT_NOP49 rm16 P6,UNDOC
-\c HINT_NOP49 rm32 P6,UNDOC
-\c HINT_NOP49 rm64 X64,UNDOC
-\c HINT_NOP50 rm16 P6,UNDOC
-\c HINT_NOP50 rm32 P6,UNDOC
-\c HINT_NOP50 rm64 X64,UNDOC
-\c HINT_NOP51 rm16 P6,UNDOC
-\c HINT_NOP51 rm32 P6,UNDOC
-\c HINT_NOP51 rm64 X64,UNDOC
-\c HINT_NOP52 rm16 P6,UNDOC
-\c HINT_NOP52 rm32 P6,UNDOC
-\c HINT_NOP52 rm64 X64,UNDOC
-\c HINT_NOP53 rm16 P6,UNDOC
-\c HINT_NOP53 rm32 P6,UNDOC
-\c HINT_NOP53 rm64 X64,UNDOC
-\c HINT_NOP54 rm16 P6,UNDOC
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-\c HINT_NOP54 rm64 X64,UNDOC
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-\c HINT_NOP55 rm64 X64,UNDOC
-\c HINT_NOP56 rm16 P6,UNDOC
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-\c HINT_NOP56 rm64 X64,UNDOC
-\c HINT_NOP57 rm16 P6,UNDOC
-\c HINT_NOP57 rm32 P6,UNDOC
-\c HINT_NOP57 rm64 X64,UNDOC
-\c HINT_NOP58 rm16 P6,UNDOC
-\c HINT_NOP58 rm32 P6,UNDOC
-\c HINT_NOP58 rm64 X64,UNDOC
-\c HINT_NOP59 rm16 P6,UNDOC
-\c HINT_NOP59 rm32 P6,UNDOC
-\c HINT_NOP59 rm64 X64,UNDOC
-\c HINT_NOP60 rm16 P6,UNDOC
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-\c HINT_NOP60 rm64 X64,UNDOC
-\c HINT_NOP61 rm16 P6,UNDOC
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-\c HINT_NOP61 rm64 X64,UNDOC
-\c HINT_NOP62 rm16 P6,UNDOC
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-\c HINT_NOP62 rm64 X64,UNDOC
-\c HINT_NOP63 rm16 P6,UNDOC
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-\c HINT_NOP63 rm64 X64,UNDOC
-
diff --git a/doc/nasmdoc.pdf b/doc/nasmdoc.pdf
deleted file mode 100644
index 0dbf46a..0000000
--- a/doc/nasmdoc.pdf
+++ /dev/null
Binary files differ
diff --git a/doc/nasmdoc.ps b/doc/nasmdoc.ps
deleted file mode 100644
index e7d0040..0000000
--- a/doc/nasmdoc.ps
+++ /dev/null
@@ -1,12251 +0,0 @@
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-[/Title (Title)
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-[/Title (Introduction)
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-[/Title (What Is NASM?)
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-[/Title (Why Yet Another Assembler?)
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-[/Title (License Conditions)
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-[/Title (Contact Information)
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-[/Title (Installing NASM under Unix)
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-[/Title (NASM Command-Line Syntax)
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-[/Title (The -o Option: Specifying the Output File Name)
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-[/Title (The -l Option: Generating a Listing File)
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-[/Title (The -M Option: Generate Makefile Dependencies)
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-[/Title (The -MG Option: Generate Makefile Dependencies)
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-[/Title (The -MF Option: Set Makefile Dependency File)
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-[/Title (The -MD Option: Assemble and Generate Dependencies)
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-[/Title (The -MT Option: Dependency Target Name)
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-[/Title (The -MQ Option: Dependency Target Name \(Quoted\))
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-[/Title (The -MP Option: Emit phony targets)
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-[/Title (The -F Option: Selecting a Debug Information Format)
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-[/Title (The -O Option: Specifying Multipass Optimization)
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-[/Title (The -t Option: Enable TASM Compatibility Mode)
-/Dest /section-2.1.23 /OUT pdfmark
-[/Title (The -w and -W Options: Enable or Disable Assembly Warnings)
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-[/Title (The -v Option: Display Version Info)
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-[/Title (The -y Option: Display Available Debug Info Formats)
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-[/Title (The --prefix and --postfix Options.)
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-[/Title (The NASMENV Environment Variable)
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-[/Title (Quick Start for MASM Users)
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-[/Title (NASM Is Case-Sensitive)
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-[/Title (NASM Requires Square Brackets For Memory References)
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-[/Title (NASM Doesn't Store Variable Types)
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-[/Title (NASM Doesn't ASSUME)
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-[/Title (NASM Doesn't Support Memory Models)
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-[/Title (Floating-Point Differences)
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-[/Title (Other Differences)
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-[/Title (The NASM Language)
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-[/Title (RESB and Friends: Declaring Uninitialized Data)
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-[/Title (INCBIN: Including External Binary Files)
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-[/Title (EQU: Defining Constants)
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-[/Title (TIMES: Repeating Instructions or Data)
-/Dest /section-3.2.5 /OUT pdfmark
-[/Title (Effective Addresses)
-/Dest /section-3.3 /OUT pdfmark
-[/Title (Constants)
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-[/Title (Numeric Constants)
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-[/Title (Character Strings)
-/Dest /section-3.4.2 /OUT pdfmark
-[/Title (Character Constants)
-/Dest /section-3.4.3 /OUT pdfmark
-[/Title (String Constants)
-/Dest /section-3.4.4 /OUT pdfmark
-[/Title (Unicode Strings)
-/Dest /section-3.4.5 /OUT pdfmark
-[/Title (Floating-Point Constants)
-/Dest /section-3.4.6 /OUT pdfmark
-[/Title (Packed BCD Constants)
-/Dest /section-3.4.7 /OUT pdfmark
-[/Title (Expressions)
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-[/Title (|: Bitwise OR Operator)
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-[/Title (^: Bitwise XOR Operator)
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-[/Title (&: Bitwise AND Operator)
-/Dest /section-3.5.3 /OUT pdfmark
-[/Title (<< and >>: Bit Shift Operators)
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-[/Title (+ and -: Addition and Subtraction Operators)
-/Dest /section-3.5.5 /OUT pdfmark
-[/Title (*, /, //, % and %%: Multiplication and Division)
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-[/Title (Unary Operators: +, -, ~, ! and SEG)
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-[/Title (SEG and WRT)
-/Dest /section-3.6 /OUT pdfmark
-[/Title (STRICT: Inhibiting Optimization)
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-[/Title (Critical Expressions)
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-[/Title (Local Labels)
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-[/Title (The NASM Preprocessor)
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-[/Title (Single-Line Macros)
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-[/Title (The Normal Way: %define)
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-[/Title (Resolving %define: %xdefine)
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-[/Title (Macro Indirection: %[...])
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-[/Title (Concatenating Single Line Macro Tokens: %+)
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-[/Title (The Macro Name Itself: %? and %??)
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-[/Title (String Manipulation in Macros)
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-[/Title (Macro-Local Labels)
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-[/Title (Greedy Macro Parameters)
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-[/Title (Default Macro Parameters)
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-[/Title (Conditional Assembly)
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-[/Title (%ifctx: Testing the Context Stack)
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-[/Title (%if: Testing Arbitrary Numeric Expressions)
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-[/Title (%ifidn and %ifidni: Testing Exact Text Identity)
-/Dest /section-4.4.5 /OUT pdfmark
-[/Title (%ifid, %ifnum, %ifstr: Testing Token Types)
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-[/Title (%iftoken: Test for a Single Token)
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-[/Title (%ifempty: Test for Empty Expansion)
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-[/Title (Preprocessor Loops: %rep)
-/Dest /section-4.5 /OUT pdfmark
-[/Title (Source Files and Dependencies)
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-[/Title (%include: Including Other Files)
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-[/Title (%pathsearch: Search the Include Path)
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-[/Title (%depend: Add Dependent Files)
-/Dest /section-4.6.3 /OUT pdfmark
-[/Title (%use: Include Standard Macro Package)
-/Dest /section-4.6.4 /OUT pdfmark
-[/Title (The Context Stack)
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-[/Title (%push and %pop: Creating and Removing Contexts)
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-[/Title (Context-Local Labels)
-/Dest /section-4.7.2 /OUT pdfmark
-[/Title (Context-Local Single-Line Macros)
-/Dest /section-4.7.3 /OUT pdfmark
-[/Title (%repl: Renaming a Context)
-/Dest /section-4.7.4 /OUT pdfmark
-[/Title (Example Use of the Context Stack: Block IFs)
-/Dest /section-4.7.5 /OUT pdfmark
-[/Title (Stack Relative Preprocessor Directives)
-/Count -3 /Dest /section-4.8 /OUT pdfmark
-[/Title (%arg Directive)
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-[/Title (%stacksize Directive)
-/Dest /section-4.8.2 /OUT pdfmark
-[/Title (%local Directive)
-/Dest /section-4.8.3 /OUT pdfmark
-[/Title (Reporting User-Defined Errors: %error, %warning, %fatal)
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-[/Title (Other Preprocessor Directives)
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-[/Title (%line Directive)
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-[/Title (%!<env>: Read an environment variable.)
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-[/Title (Standard Macros)
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-[/Title (NASM Version Macros)
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-[/Title (__NASM_VERSION_ID__: NASM Version ID)
-/Dest /section-4.11.2 /OUT pdfmark
-[/Title (__NASM_VER__: NASM Version string)
-/Dest /section-4.11.3 /OUT pdfmark
-[/Title (__FILE__ and __LINE__: File Name and Line Number)
-/Dest /section-4.11.4 /OUT pdfmark
-[/Title (__BITS__: Current BITS Mode)
-/Dest /section-4.11.5 /OUT pdfmark
-[/Title (__OUTPUT_FORMAT__: Current Output Format)
-/Dest /section-4.11.6 /OUT pdfmark
-[/Title (Assembly Date and Time Macros)
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-[/Title (__USE_package__: Package Include Test)
-/Dest /section-4.11.8 /OUT pdfmark
-[/Title (__PASS__: Assembly Pass)
-/Dest /section-4.11.9 /OUT pdfmark
-[/Title (STRUC and ENDSTRUC: Declaring Structure Data Types)
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-[/Title (ISTRUC, AT and IEND: Declaring Instances of Structures)
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-[/Title (ALIGN and ALIGNB: Data Alignment)
-/Dest /section-4.11.12 /OUT pdfmark
-[/Title (Standard Macro Packages)
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-[/Title (altreg: Alternate Register Names)
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-[/Title (smartalign: Smart ALIGN Macro)
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-[/Title (Assembler Directives)
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-[/Title (BITS: Specifying Target Processor Mode)
-/Count -1 /Dest /section-6.1 /OUT pdfmark
-[/Title (USE16 & USE32: Aliases for BITS)
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-[/Title (DEFAULT: Change the assembler defaults)
-/Dest /section-6.2 /OUT pdfmark
-[/Title (SECTION or SEGMENT: Changing and Defining Sections)
-/Count -1 /Dest /section-6.3 /OUT pdfmark
-[/Title (The __SECT__ Macro)
-/Dest /section-6.3.1 /OUT pdfmark
-[/Title (ABSOLUTE: Defining Absolute Labels)
-/Dest /section-6.4 /OUT pdfmark
-[/Title (EXTERN: Importing Symbols from Other Modules)
-/Dest /section-6.5 /OUT pdfmark
-[/Title (GLOBAL: Exporting Symbols to Other Modules)
-/Dest /section-6.6 /OUT pdfmark
-[/Title (COMMON: Defining Common Data Areas)
-/Dest /section-6.7 /OUT pdfmark
-[/Title (CPU: Defining CPU Dependencies)
-/Dest /section-6.8 /OUT pdfmark
-[/Title (FLOAT: Handling of floating-point constants)
-/Dest /section-6.9 /OUT pdfmark
-[/Title (Output Formats)
-/Count -14 /Dest /chapter-7 /OUT pdfmark
-[/Title (bin: Flat-Form Binary Output)
-/Count -4 /Dest /section-7.1 /OUT pdfmark
-[/Title (ORG: Binary File Program Origin)
-/Dest /section-7.1.1 /OUT pdfmark
-[/Title (bin Extensions to the SECTION Directive)
-/Dest /section-7.1.2 /OUT pdfmark
-[/Title (Multisection Support for the bin Format)
-/Dest /section-7.1.3 /OUT pdfmark
-[/Title (Map Files)
-/Dest /section-7.1.4 /OUT pdfmark
-[/Title (ith: Intel Hex Output)
-/Dest /section-7.2 /OUT pdfmark
-[/Title (srec: Motorola S-Records Output)
-/Dest /section-7.3 /OUT pdfmark
-[/Title (obj: Microsoft OMF Object Files)
-/Count -8 /Dest /section-7.4 /OUT pdfmark
-[/Title (obj Extensions to the SEGMENT Directive)
-/Dest /section-7.4.1 /OUT pdfmark
-[/Title (GROUP: Defining Groups of Segments)
-/Dest /section-7.4.2 /OUT pdfmark
-[/Title (UPPERCASE: Disabling Case Sensitivity in Output)
-/Dest /section-7.4.3 /OUT pdfmark
-[/Title (IMPORT: Importing DLL Symbols)
-/Dest /section-7.4.4 /OUT pdfmark
-[/Title (EXPORT: Exporting DLL Symbols)
-/Dest /section-7.4.5 /OUT pdfmark
-[/Title (..start: Defining the Program Entry Point)
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-[/Title (obj Extensions to the EXTERN Directive)
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-[/Title (obj Extensions to the COMMON Directive)
-/Dest /section-7.4.8 /OUT pdfmark
-[/Title (win32: Microsoft Win32 Object Files)
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-[/Title (win32 Extensions to the SECTION Directive)
-/Dest /section-7.5.1 /OUT pdfmark
-[/Title (win32: Safe Structured Exception Handling)
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-[/Title (win64: Microsoft Win64 Object Files)
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-[/Title (win64: Writing Position-Independent Code)
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-[/Title (win64: Structured Exception Handling)
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-[/Title (coff: Common Object File Format)
-/Dest /section-7.7 /OUT pdfmark
-[/Title (macho32 and macho64: Mach Object File Format)
-/Dest /section-7.8 /OUT pdfmark
-[/Title (elf32 and elf64: Executable and Linkable Format Object Files)
-/Count -8 /Dest /section-7.9 /OUT pdfmark
-[/Title (ELF specific directive osabi)
-/Dest /section-7.9.1 /OUT pdfmark
-[/Title (elf Extensions to the SECTION Directive)
-/Dest /section-7.9.2 /OUT pdfmark
-[/Title (Position-Independent Code: elf Special Symbols and WRT)
-/Dest /section-7.9.3 /OUT pdfmark
-[/Title (Thread Local Storage: elf Special Symbols and WRT)
-/Dest /section-7.9.4 /OUT pdfmark
-[/Title (elf Extensions to the GLOBAL Directive)
-/Dest /section-7.9.5 /OUT pdfmark
-[/Title (elf Extensions to the COMMON Directive )
-/Dest /section-7.9.6 /OUT pdfmark
-[/Title (16-bit code and ELF )
-/Dest /section-7.9.7 /OUT pdfmark
-[/Title (Debug formats and ELF )
-/Dest /section-7.9.8 /OUT pdfmark
-[/Title (aout: Linux a.out Object Files)
-/Dest /section-7.10 /OUT pdfmark
-[/Title (aoutb: NetBSD/FreeBSD/OpenBSD a.out Object Files)
-/Dest /section-7.11 /OUT pdfmark
-[/Title (as86: Minix/Linux as86 Object Files)
-/Dest /section-7.12 /OUT pdfmark
-[/Title (rdf: Relocatable Dynamic Object File Format)
-/Count -4 /Dest /section-7.13 /OUT pdfmark
-[/Title (Requiring a Library: The LIBRARY Directive)
-/Dest /section-7.13.1 /OUT pdfmark
-[/Title (Specifying a Module Name: The MODULE Directive)
-/Dest /section-7.13.2 /OUT pdfmark
-[/Title (rdf Extensions to the GLOBAL Directive)
-/Dest /section-7.13.3 /OUT pdfmark
-[/Title (rdf Extensions to the EXTERN Directive)
-/Dest /section-7.13.4 /OUT pdfmark
-[/Title (dbg: Debugging Format)
-/Dest /section-7.14 /OUT pdfmark
-[/Title (Writing 16-bit Code \(DOS, Windows 3/3.1\))
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-[/Title (Producing .EXE Files)
-/Count -2 /Dest /section-8.1 /OUT pdfmark
-[/Title (Using the obj Format To Generate .EXE Files)
-/Dest /section-8.1.1 /OUT pdfmark
-[/Title (Using the bin Format To Generate .EXE Files)
-/Dest /section-8.1.2 /OUT pdfmark
-[/Title (Producing .COM Files)
-/Count -2 /Dest /section-8.2 /OUT pdfmark
-[/Title (Using the bin Format To Generate .COM Files)
-/Dest /section-8.2.1 /OUT pdfmark
-[/Title (Using the obj Format To Generate .COM Files)
-/Dest /section-8.2.2 /OUT pdfmark
-[/Title (Producing .SYS Files)
-/Dest /section-8.3 /OUT pdfmark
-[/Title (Interfacing to 16-bit C Programs)
-/Count -5 /Dest /section-8.4 /OUT pdfmark
-[/Title (External Symbol Names)
-/Dest /section-8.4.1 /OUT pdfmark
-[/Title (Memory Models)
-/Dest /section-8.4.2 /OUT pdfmark
-[/Title (Function Definitions and Function Calls)
-/Dest /section-8.4.3 /OUT pdfmark
-[/Title (Accessing Data Items)
-/Dest /section-8.4.4 /OUT pdfmark
-[/Title (c16.mac: Helper Macros for the 16-bit C Interface)
-/Dest /section-8.4.5 /OUT pdfmark
-[/Title (Interfacing to Borland Pascal Programs)
-/Count -3 /Dest /section-8.5 /OUT pdfmark
-[/Title (The Pascal Calling Convention)
-/Dest /section-8.5.1 /OUT pdfmark
-[/Title (Borland Pascal Segment Name Restrictions)
-/Dest /section-8.5.2 /OUT pdfmark
-[/Title (Using c16.mac With Pascal Programs)
-/Dest /section-8.5.3 /OUT pdfmark
-[/Title (Writing 32-bit Code \(Unix, Win32, DJGPP\))
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-[/Title (Interfacing to 32-bit C Programs)
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-[/Title (Function Definitions and Function Calls)
-/Dest /section-9.1.2 /OUT pdfmark
-[/Title (Accessing Data Items)
-/Dest /section-9.1.3 /OUT pdfmark
-[/Title (c32.mac: Helper Macros for the 32-bit C Interface)
-/Dest /section-9.1.4 /OUT pdfmark
-[/Title (Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries)
-/Count -6 /Dest /section-9.2 /OUT pdfmark
-[/Title (Obtaining the Address of the GOT)
-/Dest /section-9.2.1 /OUT pdfmark
-[/Title (Finding Your Local Data Items)
-/Dest /section-9.2.2 /OUT pdfmark
-[/Title (Finding External and Common Data Items)
-/Dest /section-9.2.3 /OUT pdfmark
-[/Title (Exporting Symbols to the Library User)
-/Dest /section-9.2.4 /OUT pdfmark
-[/Title (Calling Procedures Outside the Library)
-/Dest /section-9.2.5 /OUT pdfmark
-[/Title (Generating the Library File)
-/Dest /section-9.2.6 /OUT pdfmark
-[/Title (Mixing 16 and 32 Bit Code)
-/Count -3 /Dest /chapter-10 /OUT pdfmark
-[/Title (Mixed-Size Jumps)
-/Dest /section-10.1 /OUT pdfmark
-[/Title (Addressing Between Different-Size Segments)
-/Dest /section-10.2 /OUT pdfmark
-[/Title (Other Mixed-Size Instructions)
-/Dest /section-10.3 /OUT pdfmark
-[/Title (Writing 64-bit Code \(Unix, Win64\))
-/Count -4 /Dest /chapter-11 /OUT pdfmark
-[/Title (Register Names in 64-bit Mode)
-/Dest /section-11.1 /OUT pdfmark
-[/Title (Immediates and Displacements in 64-bit Mode)
-/Dest /section-11.2 /OUT pdfmark
-[/Title (Interfacing to 64-bit C Programs \(Unix\))
-/Dest /section-11.3 /OUT pdfmark
-[/Title (Interfacing to 64-bit C Programs \(Win64\))
-/Dest /section-11.4 /OUT pdfmark
-[/Title (Troubleshooting)
-/Count -2 /Dest /chapter-12 /OUT pdfmark
-[/Title (Common Problems)
-/Count -4 /Dest /section-12.1 /OUT pdfmark
-[/Title (NASM Generates Inefficient Code)
-/Dest /section-12.1.1 /OUT pdfmark
-[/Title (My Jumps are Out of Range)
-/Dest /section-12.1.2 /OUT pdfmark
-[/Title (ORG Doesn't Work)
-/Dest /section-12.1.3 /OUT pdfmark
-[/Title (TIMES Doesn't Work)
-/Dest /section-12.1.4 /OUT pdfmark
-[/Title (Bugs)
-/Dest /section-12.2 /OUT pdfmark
-[/Title (Ndisasm)
-/Count -4 /Dest /appendix-A /OUT pdfmark
-[/Title (Introduction)
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-[/Title (Getting Started: Installation)
-/Dest /section-A.2 /OUT pdfmark
-[/Title (Running NDISASM)
-/Count -4 /Dest /section-A.3 /OUT pdfmark
-[/Title (COM Files: Specifying an Origin)
-/Dest /section-A.3.1 /OUT pdfmark
-[/Title (Code Following Data: Synchronisation)
-/Dest /section-A.3.2 /OUT pdfmark
-[/Title (Mixed Code and Data: Automatic \(Intelligent\) Synchronisation )
-/Dest /section-A.3.3 /OUT pdfmark
-[/Title (Other Options)
-/Dest /section-A.3.4 /OUT pdfmark
-[/Title (Bugs and Improvements)
-/Dest /section-A.4 /OUT pdfmark
-[/Title (Instruction List)
-/Count -1 /Dest /appendix-B /OUT pdfmark
-[/Title (Introduction)
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-[/Title (Special instructions...)
-/Dest /section-B.1.1 /OUT pdfmark
-[/Title (Conventional instructions)
-/Dest /section-B.1.2 /OUT pdfmark
-[/Title (Katmai Streaming SIMD instructions \(SSE \226\226 a.k.a. KNI, XMM, MMX2\))
-/Dest /section-B.1.3 /OUT pdfmark
-[/Title (Introduced in Deschutes but necessary for SSE support)
-/Dest /section-B.1.4 /OUT pdfmark
-[/Title (XSAVE group \(AVX and extended state\))
-/Dest /section-B.1.5 /OUT pdfmark
-[/Title (Generic memory operations)
-/Dest /section-B.1.6 /OUT pdfmark
-[/Title (New MMX instructions introduced in Katmai)
-/Dest /section-B.1.7 /OUT pdfmark
-[/Title (AMD Enhanced 3DNow! \(Athlon\) instructions)
-/Dest /section-B.1.8 /OUT pdfmark
-[/Title (Willamette SSE2 Cacheability Instructions)
-/Dest /section-B.1.9 /OUT pdfmark
-[/Title (Willamette MMX instructions \(SSE2 SIMD Integer Instructions\))
-/Dest /section-B.1.10 /OUT pdfmark
-[/Title (Willamette Streaming SIMD instructions \(SSE2\))
-/Dest /section-B.1.11 /OUT pdfmark
-[/Title (Prescott New Instructions \(SSE3\))
-/Dest /section-B.1.12 /OUT pdfmark
-[/Title (VMX Instructions)
-/Dest /section-B.1.13 /OUT pdfmark
-[/Title (Extended Page Tables VMX instructions)
-/Dest /section-B.1.14 /OUT pdfmark
-[/Title (Tejas New Instructions \(SSSE3\))
-/Dest /section-B.1.15 /OUT pdfmark
-[/Title (AMD SSE4A)
-/Dest /section-B.1.16 /OUT pdfmark
-[/Title (New instructions in Barcelona)
-/Dest /section-B.1.17 /OUT pdfmark
-[/Title (Penryn New Instructions \(SSE4.1\))
-/Dest /section-B.1.18 /OUT pdfmark
-[/Title (Nehalem New Instructions \(SSE4.2\))
-/Dest /section-B.1.19 /OUT pdfmark
-[/Title (Intel SMX)
-/Dest /section-B.1.20 /OUT pdfmark
-[/Title (Geode \(Cyrix\) 3DNow! additions)
-/Dest /section-B.1.21 /OUT pdfmark
-[/Title (Intel new instructions in ???)
-/Dest /section-B.1.22 /OUT pdfmark
-[/Title (Intel AES instructions)
-/Dest /section-B.1.23 /OUT pdfmark
-[/Title (Intel AVX AES instructions)
-/Dest /section-B.1.24 /OUT pdfmark
-[/Title (Intel AVX instructions)
-/Dest /section-B.1.25 /OUT pdfmark
-[/Title (Intel Carry-Less Multiplication instructions \(CLMUL\))
-/Dest /section-B.1.26 /OUT pdfmark
-[/Title (Intel AVX Carry-Less Multiplication instructions \(CLMUL\))
-/Dest /section-B.1.27 /OUT pdfmark
-[/Title (Intel Fused Multiply-Add instructions \(FMA\))
-/Dest /section-B.1.28 /OUT pdfmark
-[/Title (VIA \(Centaur\) security instructions)
-/Dest /section-B.1.29 /OUT pdfmark
-[/Title (AMD Lightweight Profiling \(LWP\) instructions)
-/Dest /section-B.1.30 /OUT pdfmark
-[/Title (AMD XOP, FMA4 and CVT16 instructions \(SSE5\))
-/Dest /section-B.1.31 /OUT pdfmark
-[/Title (Systematic names for the hinting nop instructions)
-/Dest /section-B.1.32 /OUT pdfmark
-[/Title (NASM Version History)
-/Count -3 /Dest /appendix-C /OUT pdfmark
-[/Title (NASM 2 Series)
-/Count -11 /Dest /section-C.1 /OUT pdfmark
-[/Title (Version 2.08)
-/Dest /section-C.1.1 /OUT pdfmark
-[/Title (Version 2.07)
-/Dest /section-C.1.2 /OUT pdfmark
-[/Title (Version 2.06)
-/Dest /section-C.1.3 /OUT pdfmark
-[/Title (Version 2.05.01)
-/Dest /section-C.1.4 /OUT pdfmark
-[/Title (Version 2.05)
-/Dest /section-C.1.5 /OUT pdfmark
-[/Title (Version 2.04)
-/Dest /section-C.1.6 /OUT pdfmark
-[/Title (Version 2.03.01)
-/Dest /section-C.1.7 /OUT pdfmark
-[/Title (Version 2.03)
-/Dest /section-C.1.8 /OUT pdfmark
-[/Title (Version 2.02)
-/Dest /section-C.1.9 /OUT pdfmark
-[/Title (Version 2.01)
-/Dest /section-C.1.10 /OUT pdfmark
-[/Title (Version 2.00)
-/Dest /section-C.1.11 /OUT pdfmark
-[/Title (NASM 0.98 Series)
-/Count -55 /Dest /section-C.2 /OUT pdfmark
-[/Title (Version 0.98.39)
-/Dest /section-C.2.1 /OUT pdfmark
-[/Title (Version 0.98.38)
-/Dest /section-C.2.2 /OUT pdfmark
-[/Title (Version 0.98.37)
-/Dest /section-C.2.3 /OUT pdfmark
-[/Title (Version 0.98.36)
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-[/Title (Version 0.98.09b with John Coffman patches released 28-Oct-2001)
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-[/Title (Version 0.98.07 released 01/28/01)
-/Dest /section-C.2.34 /OUT pdfmark
-[/Title (Version 0.98.06f released 01/18/01)
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-[/Title (Version 0.98.06e released 01/09/01)
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-[/Title (Version 0.98p1)
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-[/Title (Version 0.98bf \(bug-fixed\))
-/Dest /section-C.2.38 /OUT pdfmark
-[/Title (Version 0.98.03 with John Coffman's changes released 27-Jul-2000)
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-[/Title (Version 0.98p3.7)
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-[/Title (NASM 0.9 Series)
-/Count -8 /Dest /section-C.3 /OUT pdfmark
-[/Title (Version 0.97 released December 1997)
-/Dest /section-C.3.1 /OUT pdfmark
-[/Title (Version 0.96 released November 1997)
-/Dest /section-C.3.2 /OUT pdfmark
-[/Title (Version 0.95 released July 1997)
-/Dest /section-C.3.3 /OUT pdfmark
-[/Title (Version 0.94 released April 1997)
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-[/Title (Version 0.93 released January 1997)
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-[/Title (Version 0.92 released January 1997)
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-[/Title (Version 0.91 released November 1996)
-/Dest /section-C.3.7 /OUT pdfmark
-[/Title (Version 0.90 released October 1996)
-/Dest /section-C.3.8 /OUT pdfmark
-[/Title (Index)
-/Dest /index /OUT pdfmark
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-/ti (NASM \227 The Netwide Assembler) def
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-[(\251 1996-2009 The NASM Development Team \227 All Rights Reserved)]164 norm3
-[(This document is redistributable under the license given in the file "COPYING" distributed in the NASM)]147 norm1
-[(archive.)]136 norm2
-[(This release is dedicated to the memory of Charles A. Crayne. We miss you, Chuck.)]119 norm3
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-[{/contents xa}(Contents)]642.8 chap3
-[(Introduction)](Chapter 1: )/chapter-1 (14)607.8 toc03
-[(What Is NASM?)](1.1 )/section-1.1 (14)590.8 toc13
-[(Why Yet Another Assembler?)](1.1.1 )/section-1.1.1 (14)573.8 toc23
-[(License Conditions)](1.1.2 )/section-1.1.2 (14)556.8 toc23
-[(Contact Information)](1.2 )/section-1.2 (15)539.8 toc13
-[(Installation)](1.3 )/section-1.3 (15)522.8 toc13
-[(Installing NASM under MS-DOS or Windows)](1.3.1 )/section-1.3.1 (15)505.8 toc23
-[(Installing NASM under Unix)](1.3.2 )/section-1.3.2 (16)488.8 toc23
-[(Running NASM)](Chapter 2: )/chapter-2 (17)471.8 toc03
-[(NASM Command-Line Syntax)](2.1 )/section-2.1 (17)454.8 toc13
-[(The )2(-o)0( Option: Specifying the Output File Name)](2.1.1 )/section-2.1.1 (17)437.8 toc23
-[(The )2(-f)0( Option: Specifying the Output File Format)](2.1.2 )/section-2.1.2 (18)420.8 toc23
-[(The )2(-l)0( Option: Generating a Listing File)](2.1.3 )/section-2.1.3 (18)403.8 toc23
-[(The )2(-M)0( Option: Generate Makefile Dependencies)](2.1.4 )/section-2.1.4 (18)386.8 toc23
-[(The )2(-MG)0( Option: Generate Makefile Dependencies)](2.1.5 )/section-2.1.5 (18)369.8 toc23
-[(The )2(-MF)0( Option: Set Makefile Dependency File)](2.1.6 )/section-2.1.6 (18)352.8 toc23
-[(The )2(-MD)0( Option: Assemble and Generate Dependencies)](2.1.7 )/section-2.1.7 (18)335.8 toc23
-[(The )2(-MT)0( Option: Dependency Target Name)](2.1.8 )/section-2.1.8 (19)318.8 toc23
-[(The )2(-MQ)0( Option: Dependency Target Name \(Quoted\))](2.1.9 )/section-2.1.9 (19)301.8 toc23
-[(The )2(-MP)0( Option: Emit phony targets)](2.1.10 )/section-2.1.10 (19)284.8 toc23
-[(The )2(-F)0( Option: Selecting a Debug Information Format)](2.1.11 )/section-2.1.11 (19)267.8 toc23
-[(The )2(-g)0( Option: Enabling Debug Information.)](2.1.12 )/section-2.1.12 (19)250.8 toc23
-[(The )2(-X)0( Option: Selecting an Error Reporting Format)](2.1.13 )/section-2.1.13 (19)233.8 toc23
-[(The )2(-Z)0( Option: Send Errors to a File)](2.1.14 )/section-2.1.14 (20)216.8 toc23
-[(The )2(-s)0( Option: Send Errors to )2(stdout)](2.1.15 )/section-2.1.15 (20)199.8 toc23
-[(The )2(-i)0( Option: Include File Search Directories)](2.1.16 )/section-2.1.16 (20)182.8 toc23
-[(The )2(-p)0( Option: Pre-Include a File)](2.1.17 )/section-2.1.17 (20)165.8 toc23
-[(The )2(-d)0( Option: Pre-Define a Macro)](2.1.18 )/section-2.1.18 (20)148.8 toc23
-[(The )2(-u)0( Option: Undefine a Macro)](2.1.19 )/section-2.1.19 (21)131.8 toc23
-[(The )2(-E)0( Option: Preprocess Only)](2.1.20 )/section-2.1.20 (21)114.8 toc23
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-[(The )2(-a)0( Option: Don't Preprocess At All)](2.1.21 )/section-2.1.21 (21)681 toc23
-[(The )2(-O)0( Option: Specifying Multipass Optimization)](2.1.22 )/section-2.1.22 (21)664 toc23
-[(The )2(-t)0( Option: Enable TASM Compatibility Mode)](2.1.23 )/section-2.1.23 (22)647 toc23
-[(The )2(-w)0( and )2(-W)0( Options: Enable or Disable Assembly Warnings)](2.1.24 )/section-2.1.24 (22)630 toc23
-[(The )2(-v)0( Option: Display Version Info)](2.1.25 )/section-2.1.25 (23)613 toc23
-[(The )2(-y)0( Option: Display Available Debug Info Formats)](2.1.26 )/section-2.1.26 (23)596 toc23
-[(The )2(--prefix)0( and )2(--postfix)0( Options.)](2.1.27 )/section-2.1.27 (23)579 toc23
-[(The )2(NASMENV)0( Environment Variable)](2.1.28 )/section-2.1.28 (23)562 toc23
-[(Quick Start for MASM Users)](2.2 )/section-2.2 (24)545 toc13
-[(NASM Is Case-Sensitive)](2.2.1 )/section-2.2.1 (24)528 toc23
-[(NASM Requires Square Brackets For Memory References)](2.2.2 )/section-2.2.2 (24)511 toc23
-[(NASM Doesn't Store Variable Types)](2.2.3 )/section-2.2.3 (24)494 toc23
-[(NASM Doesn't )2(ASSUME)](2.2.4 )/section-2.2.4 (25)477 toc23
-[(NASM Doesn't Support Memory Models)](2.2.5 )/section-2.2.5 (25)460 toc23
-[(Floating-Point Differences)](2.2.6 )/section-2.2.6 (25)443 toc23
-[(Other Differences)](2.2.7 )/section-2.2.7 (25)426 toc23
-[(The NASM Language)](Chapter 3: )/chapter-3 (26)409 toc03
-[(Layout of a NASM Source Line)](3.1 )/section-3.1 (26)392 toc13
-[(Pseudo-Instructions)](3.2 )/section-3.2 (27)375 toc13
-[2(DB)0( and Friends: Declaring Initialized Data)](3.2.1 )/section-3.2.1 (27)358 toc23
-[2(RESB)0( and Friends: Declaring Uninitialized Data)](3.2.2 )/section-3.2.2 (27)341 toc23
-[2(INCBIN)0(: Including External Binary Files)](3.2.3 )/section-3.2.3 (27)324 toc23
-[2(EQU)0(: Defining Constants)](3.2.4 )/section-3.2.4 (28)307 toc23
-[2(TIMES)0(: Repeating Instructions or Data)](3.2.5 )/section-3.2.5 (28)290 toc23
-[(Effective Addresses)](3.3 )/section-3.3 (28)273 toc13
-[(Constants)](3.4 )/section-3.4 (29)256 toc13
-[(Numeric Constants)](3.4.1 )/section-3.4.1 (29)239 toc23
-[(Character Strings)](3.4.2 )/section-3.4.2 (30)222 toc23
-[(Character Constants)](3.4.3 )/section-3.4.3 (31)205 toc23
-[(String Constants)](3.4.4 )/section-3.4.4 (31)188 toc23
-[(Unicode Strings)](3.4.5 )/section-3.4.5 (31)171 toc23
-[(Floating-Point Constants)](3.4.6 )/section-3.4.6 (31)154 toc23
-[(Packed BCD Constants)](3.4.7 )/section-3.4.7 (33)137 toc23
-[(Expressions)](3.5 )/section-3.5 (33)120 toc13
-[2(|)0(: Bitwise OR Operator)](3.5.1 )/section-3.5.1 (33)103 toc23
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-[2(^)0(: Bitwise XOR Operator)](3.5.2 )/section-3.5.2 (33)681 toc23
-[2(&)0(: Bitwise AND Operator)](3.5.3 )/section-3.5.3 (33)664 toc23
-[2(<<)0( and )2(>>)0(: Bit Shift Operators)](3.5.4 )/section-3.5.4 (33)647 toc23
-[2(+)0( and )2(-)0(: Addition and Subtraction Operators)](3.5.5 )/section-3.5.5 (33)630 toc23
-[2(*)0(, )2(/)0(, )2(//)0(, )2(%)0( and )2(%%)0(: Multiplication and Division)](3.5.6 )/section-3.5.6 (33)613 toc23
-[(Unary Operators: )2(+)0(, )2(-)0(, )2(~)0(, )2(!)0( and )2(SEG)](3.5.7 )/section-3.5.7 (34)596 toc23
-[2(SEG)0( and )2(WRT)](3.6 )/section-3.6 (34)579 toc13
-[2(STRICT)0(: Inhibiting Optimization)](3.7 )/section-3.7 (34)562 toc13
-[(Critical Expressions)](3.8 )/section-3.8 (35)545 toc13
-[(Local Labels)](3.9 )/section-3.9 (35)528 toc13
-[(The NASM Preprocessor)](Chapter 4: )/chapter-4 (37)511 toc03
-[(Single-Line Macros)](4.1 )/section-4.1 (37)494 toc13
-[(The Normal Way: )2(%define)](4.1.1 )/section-4.1.1 (37)477 toc23
-[(Resolving )2(%define)0(: )2(%xdefine)](4.1.2 )/section-4.1.2 (38)460 toc23
-[(Macro Indirection: )2(%[...])](4.1.3 )/section-4.1.3 (39)443 toc23
-[(Concatenating Single Line Macro Tokens: )2(%+)](4.1.4 )/section-4.1.4 (39)426 toc23
-[(The Macro Name Itself: )2(%?)0( and )2(%??)](4.1.5 )/section-4.1.5 (39)409 toc23
-[(Undefining Single-Line Macros: )2(%undef)](4.1.6 )/section-4.1.6 (40)392 toc23
-[(Preprocessor Variables: )2(%assign)](4.1.7 )/section-4.1.7 (40)375 toc23
-[(Defining Strings: )2(%defstr)](4.1.8 )/section-4.1.8 (41)358 toc23
-[(Defining Tokens: )2(%deftok)](4.1.9 )/section-4.1.9 (41)341 toc23
-[(String Manipulation in Macros)](4.2 )/section-4.2 (41)324 toc13
-[(Concatenating Strings: )2(%strcat)](4.2.1 )/section-4.2.1 (41)307 toc23
-[(String Length: )2(%strlen)](4.2.2 )/section-4.2.2 (41)290 toc23
-[(Extracting Substrings: )2(%substr)](4.2.3 )/section-4.2.3 (42)273 toc23
-[(Multi-Line Macros: )2(%macro)](4.3 )/section-4.3 (42)256 toc13
-[(Recursive Multi-Line Macros: )2(%rmacro)](4.3.1 )/section-4.3.1 (43)239 toc23
-[(Overloading Multi-Line Macros)](4.3.2 )/section-4.3.2 (43)222 toc23
-[(Macro-Local Labels)](4.3.3 )/section-4.3.3 (43)205 toc23
-[(Greedy Macro Parameters)](4.3.4 )/section-4.3.4 (44)188 toc23
-[(Default Macro Parameters)](4.3.5 )/section-4.3.5 (45)171 toc23
-[2(%0)0(: Macro Parameter Counter)](4.3.6 )/section-4.3.6 (45)154 toc23
-[2(%rotate)0(: Rotating Macro Parameters)](4.3.7 )/section-4.3.7 (46)137 toc23
-[(Concatenating Macro Parameters)](4.3.8 )/section-4.3.8 (46)120 toc23
-[(Condition Codes as Macro Parameters)](4.3.9 )/section-4.3.9 (47)103 toc23
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-[(Disabling Listing Expansion)](4.3.10 )/section-4.3.10 (48)681 toc23
-[(Undefining Multi-Line Macros: )2(%unmacro)](4.3.11 )/section-4.3.11 (48)664 toc23
-[(Exiting Multi-Line Macros: )2(%exitmacro)](4.3.12 )/section-4.3.12 (48)647 toc23
-[(Conditional Assembly)](4.4 )/section-4.4 (49)630 toc13
-[2(%ifdef)0(: Testing Single-Line Macro Existence)](4.4.1 )/section-4.4.1 (49)613 toc23
-[2(%ifmacro)0(: Testing Multi-Line Macro Existence)](4.4.2 )/section-4.4.2 (49)596 toc23
-[2(%ifctx)0(: Testing the Context Stack)](4.4.3 )/section-4.4.3 (50)579 toc23
-[2(%if)0(: Testing Arbitrary Numeric Expressions)](4.4.4 )/section-4.4.4 (50)562 toc23
-[2(%ifidn)0( and )2(%ifidni)0(: Testing Exact Text Identity)](4.4.5 )/section-4.4.5 (50)545 toc23
-[2(%ifid)0(, )2(%ifnum)0(, )2(%ifstr)0(: Testing Token Types)](4.4.6 )/section-4.4.6 (51)528 toc23
-[2(%iftoken)0(: Test for a Single Token)](4.4.7 )/section-4.4.7 (52)511 toc23
-[2(%ifempty)0(: Test for Empty Expansion)](4.4.8 )/section-4.4.8 (52)494 toc23
-[(Preprocessor Loops: )2(%rep)](4.5 )/section-4.5 (52)477 toc13
-[(Source Files and Dependencies)](4.6 )/section-4.6 (53)460 toc13
-[2(%include)0(: Including Other Files)](4.6.1 )/section-4.6.1 (53)443 toc23
-[2(%pathsearch)0(: Search the Include Path)](4.6.2 )/section-4.6.2 (53)426 toc23
-[2(%depend)0(: Add Dependent Files)](4.6.3 )/section-4.6.3 (53)409 toc23
-[2(%use)0(: Include Standard Macro Package)](4.6.4 )/section-4.6.4 (54)392 toc23
-[(The Context Stack)](4.7 )/section-4.7 (54)375 toc13
-[2(%push)0( and )2(%pop)0(: Creating and Removing Contexts)](4.7.1 )/section-4.7.1 (54)358 toc23
-[(Context-Local Labels)](4.7.2 )/section-4.7.2 (54)341 toc23
-[(Context-Local Single-Line Macros)](4.7.3 )/section-4.7.3 (55)324 toc23
-[2(%repl)0(: Renaming a Context)](4.7.4 )/section-4.7.4 (55)307 toc23
-[(Example Use of the Context Stack: Block IFs)](4.7.5 )/section-4.7.5 (55)290 toc23
-[(Stack Relative Preprocessor Directives)](4.8 )/section-4.8 (57)273 toc13
-[2(%arg)0( Directive)](4.8.1 )/section-4.8.1 (57)256 toc23
-[2(%stacksize)0( Directive)](4.8.2 )/section-4.8.2 (57)239 toc23
-[2(%local)0( Directive)](4.8.3 )/section-4.8.3 (58)222 toc23
-[(Reporting User-Defined Errors: )2(%error)0(, )2(%warning)0(, )2(%fatal)](4.9 )/section-4.9 (58)205 toc13
-[(Other Preprocessor Directives)](4.10 )/section-4.10 (59)188 toc13
-[2(%line)0( Directive)](4.10.1 )/section-4.10.1 (59)171 toc23
-[2(%!<env>)0(: Read an environment variable.)](4.10.2 )/section-4.10.2 (60)154 toc23
-[(Standard Macros)](4.11 )/section-4.11 (60)137 toc13
-[(NASM Version Macros)](4.11.1 )/section-4.11.1 (60)120 toc23
-[2(__NASM_VERSION_ID__)0(: NASM Version ID)](4.11.2 )/section-4.11.2 (60)103 toc23
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-[2(__NASM_VER__)0(: NASM Version string)](4.11.3 )/section-4.11.3 (60)681 toc23
-[2(__FILE__)0( and )2(__LINE__)0(: File Name and Line Number)](4.11.4 )/section-4.11.4 (61)664 toc23
-[2(__BITS__)0(: Current BITS Mode)](4.11.5 )/section-4.11.5 (61)647 toc23
-[2(__OUTPUT_FORMAT__)0(: Current Output Format)](4.11.6 )/section-4.11.6 (61)630 toc23
-[(Assembly Date and Time Macros)](4.11.7 )/section-4.11.7 (61)613 toc23
-[2(__USE_)1(package)2(__)0(: Package Include Test)](4.11.8 )/section-4.11.8 (62)596 toc23
-[2(__PASS__)0(: Assembly Pass)](4.11.9 )/section-4.11.9 (62)579 toc23
-[2(STRUC)0( and )2(ENDSTRUC)0(: Declaring Structure Data Types)](4.11.10 )/section-4.11.10 (62)562 toc23
-[2(ISTRUC)0(, )2(AT)0( and )2(IEND)0(: Declaring Instances of Structures)](4.11.11 )/section-4.11.11 (63)545 toc23
-[2(ALIGN)0( and )2(ALIGNB)0(: Data Alignment)](4.11.12 )/section-4.11.12 (64)528 toc23
-[(Standard Macro Packages)](Chapter 5: )/chapter-5 (66)511 toc03
-[2(altreg)0(: Alternate Register Names)](5.1 )/section-5.1 (66)494 toc13
-[2(smartalign)0(: Smart )2(ALIGN)0( Macro)](5.2 )/section-5.2 (66)477 toc13
-[(Assembler Directives)](Chapter 6: )/chapter-6 (67)460 toc03
-[2(BITS)0(: Specifying Target Processor Mode)](6.1 )/section-6.1 (67)443 toc13
-[2(USE16)0( & )2(USE32)0(: Aliases for BITS)](6.1.1 )/section-6.1.1 (68)426 toc23
-[2(DEFAULT)0(: Change the assembler defaults)](6.2 )/section-6.2 (68)409 toc13
-[2(SECTION)0( or )2(SEGMENT)0(: Changing and Defining Sections)](6.3 )/section-6.3 (68)392 toc13
-[(The )2(__SECT__)0( Macro)](6.3.1 )/section-6.3.1 (68)375 toc23
-[2(ABSOLUTE)0(: Defining Absolute Labels)](6.4 )/section-6.4 (69)358 toc13
-[2(EXTERN)0(: Importing Symbols from Other Modules)](6.5 )/section-6.5 (70)341 toc13
-[2(GLOBAL)0(: Exporting Symbols to Other Modules)](6.6 )/section-6.6 (70)324 toc13
-[2(COMMON)0(: Defining Common Data Areas)](6.7 )/section-6.7 (70)307 toc13
-[2(CPU)0(: Defining CPU Dependencies)](6.8 )/section-6.8 (71)290 toc13
-[2(FLOAT)0(: Handling of floating-point constants)](6.9 )/section-6.9 (71)273 toc13
-[(Output Formats)](Chapter 7: )/chapter-7 (73)256 toc03
-[2(bin)0(: Flat-Form Binary Output)](7.1 )/section-7.1 (73)239 toc13
-[2(ORG)0(: Binary File Program Origin)](7.1.1 )/section-7.1.1 (73)222 toc23
-[2(bin)0( Extensions to the )2(SECTION)0( Directive)](7.1.2 )/section-7.1.2 (73)205 toc23
-[(Multisection Support for the )2(bin)0( Format)](7.1.3 )/section-7.1.3 (74)188 toc23
-[(Map Files)](7.1.4 )/section-7.1.4 (74)171 toc23
-[2(ith)0(: Intel Hex Output)](7.2 )/section-7.2 (74)154 toc13
-[2(srec)0(: Motorola S-Records Output)](7.3 )/section-7.3 (74)137 toc13
-[2(obj)0(: Microsoft OMF Object Files)](7.4 )/section-7.4 (75)120 toc13
-[2(obj)0( Extensions to the )2(SEGMENT)0( Directive)](7.4.1 )/section-7.4.1 (75)103 toc23
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-[2(GROUP)0(: Defining Groups of Segments)](7.4.2 )/section-7.4.2 (76)681 toc23
-[2(UPPERCASE)0(: Disabling Case Sensitivity in Output)](7.4.3 )/section-7.4.3 (77)664 toc23
-[2(IMPORT)0(: Importing DLL Symbols)](7.4.4 )/section-7.4.4 (77)647 toc23
-[2(EXPORT)0(: Exporting DLL Symbols)](7.4.5 )/section-7.4.5 (77)630 toc23
-[2(..start)0(: Defining the Program Entry Point)](7.4.6 )/section-7.4.6 (78)613 toc23
-[2(obj)0( Extensions to the )2(EXTERN)0( Directive)](7.4.7 )/section-7.4.7 (78)596 toc23
-[2(obj)0( Extensions to the )2(COMMON)0( Directive)](7.4.8 )/section-7.4.8 (78)579 toc23
-[2(win32)0(: Microsoft Win32 Object Files)](7.5 )/section-7.5 (79)562 toc13
-[2(win32)0( Extensions to the )2(SECTION)0( Directive)](7.5.1 )/section-7.5.1 (79)545 toc23
-[2(win32)0(: Safe Structured Exception Handling)](7.5.2 )/section-7.5.2 (80)528 toc23
-[2(win64)0(: Microsoft Win64 Object Files)](7.6 )/section-7.6 (81)511 toc13
-[2(win64)0(: Writing Position-Independent Code)](7.6.1 )/section-7.6.1 (81)494 toc23
-[2(win64)0(: Structured Exception Handling)](7.6.2 )/section-7.6.2 (82)477 toc23
-[2(coff)0(: Common Object File Format)](7.7 )/section-7.7 (85)460 toc13
-[2(macho32)0( and )2(macho64)0(: Mach Object File Format)](7.8 )/section-7.8 (85)443 toc13
-[2(elf32)0( and )2(elf64)0(: Executable and Linkable Format Object Files)](7.9 )/section-7.9 (85)426 toc13
-[(ELF specific directive )2(osabi)](7.9.1 )/section-7.9.1 (85)409 toc23
-[2(elf)0( Extensions to the )2(SECTION)0( Directive)](7.9.2 )/section-7.9.2 (85)392 toc23
-[(Position-Independent Code: )2(elf)0( Special Symbols and )2(WRT)](7.9.3 )/section-7.9.3 (86)375 toc23
-[(Thread Local Storage: )2(elf)0( Special Symbols and )2(WRT)](7.9.4 )/section-7.9.4 (87)358 toc23
-[2(elf)0( Extensions to the )2(GLOBAL)0( Directive)](7.9.5 )/section-7.9.5 (87)341 toc23
-[2(elf)0( Extensions to the )2(COMMON)0( Directive )](7.9.6 )/section-7.9.6 (87)324 toc23
-[(16-bit code and ELF )](7.9.7 )/section-7.9.7 (88)307 toc23
-[(Debug formats and ELF )](7.9.8 )/section-7.9.8 (88)290 toc23
-[2(aout)0(: Linux )2(a.out)0( Object Files)](7.10 )/section-7.10 (88)273 toc13
-[2(aoutb)0(: NetBSD/FreeBSD/OpenBSD )2(a.out)0( Object Files)](7.11 )/section-7.11 (88)256 toc13
-[2(as86)0(: Minix/Linux )2(as86)0( Object Files)](7.12 )/section-7.12 (88)239 toc13
-[2(rdf)0(: Relocatable Dynamic Object File Format)](7.13 )/section-7.13 (88)222 toc13
-[(Requiring a Library: The )2(LIBRARY)0( Directive)](7.13.1 )/section-7.13.1 (89)205 toc23
-[(Specifying a Module Name: The )2(MODULE)0( Directive)](7.13.2 )/section-7.13.2 (89)188 toc23
-[2(rdf)0( Extensions to the )2(GLOBAL)0( Directive)](7.13.3 )/section-7.13.3 (89)171 toc23
-[2(rdf)0( Extensions to the )2(EXTERN)0( Directive)](7.13.4 )/section-7.13.4 (89)154 toc23
-[2(dbg)0(: Debugging Format)](7.14 )/section-7.14 (90)137 toc13
-[(Writing 16-bit Code \(DOS, Windows 3/3.1\))](Chapter 8: )/chapter-8 (91)120 toc03
-[(Producing )2(.EXE)0( Files)](8.1 )/section-8.1 (91)103 toc13
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-[(Using the )2(obj)0( Format To Generate )2(.EXE)0( Files)](8.1.1 )/section-8.1.1 (91)681 toc23
-[(Using the )2(bin)0( Format To Generate )2(.EXE)0( Files)](8.1.2 )/section-8.1.2 (92)664 toc23
-[(Producing )2(.COM)0( Files)](8.2 )/section-8.2 (93)647 toc13
-[(Using the )2(bin)0( Format To Generate )2(.COM)0( Files)](8.2.1 )/section-8.2.1 (93)630 toc23
-[(Using the )2(obj)0( Format To Generate )2(.COM)0( Files)](8.2.2 )/section-8.2.2 (93)613 toc23
-[(Producing )2(.SYS)0( Files)](8.3 )/section-8.3 (94)596 toc13
-[(Interfacing to 16-bit C Programs)](8.4 )/section-8.4 (94)579 toc13
-[(External Symbol Names)](8.4.1 )/section-8.4.1 (94)562 toc23
-[(Memory Models)](8.4.2 )/section-8.4.2 (95)545 toc23
-[(Function Definitions and Function Calls)](8.4.3 )/section-8.4.3 (96)528 toc23
-[(Accessing Data Items)](8.4.4 )/section-8.4.4 (98)511 toc23
-[2(c16.mac)0(: Helper Macros for the 16-bit C Interface)](8.4.5 )/section-8.4.5 (98)494 toc23
-[(Interfacing to Borland Pascal Programs)](8.5 )/section-8.5 (99)477 toc13
-[(The Pascal Calling Convention)](8.5.1 )/section-8.5.1 (100)460 toc23
-[(Borland Pascal Segment Name Restrictions)](8.5.2 )/section-8.5.2 (101)443 toc23
-[(Using )2(c16.mac)0( With Pascal Programs)](8.5.3 )/section-8.5.3 (101)426 toc23
-[(Writing 32-bit Code \(Unix, Win32, DJGPP\))](Chapter 9: )/chapter-9 (103)409 toc03
-[(Interfacing to 32-bit C Programs)](9.1 )/section-9.1 (103)392 toc13
-[(External Symbol Names)](9.1.1 )/section-9.1.1 (103)375 toc23
-[(Function Definitions and Function Calls)](9.1.2 )/section-9.1.2 (103)358 toc23
-[(Accessing Data Items)](9.1.3 )/section-9.1.3 (105)341 toc23
-[2(c32.mac)0(: Helper Macros for the 32-bit C Interface)](9.1.4 )/section-9.1.4 (105)324 toc23
-[(Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries)](9.2 )/section-9.2 (106)307 toc13
-[(Obtaining the Address of the GOT)](9.2.1 )/section-9.2.1 (106)290 toc23
-[(Finding Your Local Data Items)](9.2.2 )/section-9.2.2 (107)273 toc23
-[(Finding External and Common Data Items)](9.2.3 )/section-9.2.3 (107)256 toc23
-[(Exporting Symbols to the Library User)](9.2.4 )/section-9.2.4 (108)239 toc23
-[(Calling Procedures Outside the Library)](9.2.5 )/section-9.2.5 (109)222 toc23
-[(Generating the Library File)](9.2.6 )/section-9.2.6 (109)205 toc23
-[(Mixing 16 and 32 Bit Code)](Chapter 10: )/chapter-10 (110)188 toc03
-[(Mixed-Size Jumps)](10.1 )/section-10.1 (110)171 toc13
-[(Addressing Between Different-Size Segments)](10.2 )/section-10.2 (110)154 toc13
-[(Other Mixed-Size Instructions)](10.3 )/section-10.3 (111)137 toc13
-[(Writing 64-bit Code \(Unix, Win64\))](Chapter 11: )/chapter-11 (113)120 toc03
-[(Register Names in 64-bit Mode)](11.1 )/section-11.1 (113)103 toc13
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-[(Immediates and Displacements in 64-bit Mode)](11.2 )/section-11.2 (113)681 toc13
-[(Interfacing to 64-bit C Programs \(Unix\))](11.3 )/section-11.3 (114)664 toc13
-[(Interfacing to 64-bit C Programs \(Win64\))](11.4 )/section-11.4 (114)647 toc13
-[(Troubleshooting)](Chapter 12: )/chapter-12 (116)630 toc03
-[(Common Problems)](12.1 )/section-12.1 (116)613 toc13
-[(NASM Generates Inefficient Code)](12.1.1 )/section-12.1.1 (116)596 toc23
-[(My Jumps are Out of Range)](12.1.2 )/section-12.1.2 (116)579 toc23
-[2(ORG)0( Doesn't Work)](12.1.3 )/section-12.1.3 (116)562 toc23
-[2(TIMES)0( Doesn't Work)](12.1.4 )/section-12.1.4 (117)545 toc23
-[(Bugs)](12.2 )/section-12.2 (117)528 toc13
-[(Ndisasm)](Appendix A: )/appendix-A (119)511 toc03
-[(Introduction)](A.1 )/section-A.1 (119)494 toc13
-[(Getting Started: Installation)](A.2 )/section-A.2 (119)477 toc13
-[(Running NDISASM)](A.3 )/section-A.3 (119)460 toc13
-[(COM Files: Specifying an Origin)](A.3.1 )/section-A.3.1 (119)443 toc23
-[(Code Following Data: Synchronisation)](A.3.2 )/section-A.3.2 (119)426 toc23
-[(Mixed Code and Data: Automatic \(Intelligent\) Synchronisation )](A.3.3 )/section-A.3.3 (120)409 toc23
-[(Other Options)](A.3.4 )/section-A.3.4 (121)392 toc23
-[(Bugs and Improvements)](A.4 )/section-A.4 (121)375 toc13
-[(Instruction List)](Appendix B: )/appendix-B (122)358 toc03
-[(Introduction)](B.1 )/section-B.1 (122)341 toc13
-[(Special instructions...)](B.1.1 )/section-B.1.1 (122)324 toc23
-[(Conventional instructions)](B.1.2 )/section-B.1.2 (122)307 toc23
-[(Katmai Streaming SIMD instructions \(SSE \226\226 a.k.a. KNI, XMM, MMX2\))](B.1.3 )/section-B.1.3 (148)290 toc23
-[(Introduced in Deschutes but necessary for SSE support)](B.1.4 )/section-B.1.4 (149)273 toc23
-[(XSAVE group \(AVX and extended state\))](B.1.5 )/section-B.1.5 (149)256 toc23
-[(Generic memory operations)](B.1.6 )/section-B.1.6 (149)239 toc23
-[(New MMX instructions introduced in Katmai)](B.1.7 )/section-B.1.7 (150)222 toc23
-[(AMD Enhanced 3DNow! \(Athlon\) instructions)](B.1.8 )/section-B.1.8 (150)205 toc23
-[(Willamette SSE2 Cacheability Instructions)](B.1.9 )/section-B.1.9 (150)188 toc23
-[(Willamette MMX instructions \(SSE2 SIMD Integer Instructions\))](B.1.10 )/section-B.1.10 (150)171 toc23
-[(Willamette Streaming SIMD instructions \(SSE2\))](B.1.11 )/section-B.1.11 (152)154 toc23
-[(Prescott New Instructions \(SSE3\))](B.1.12 )/section-B.1.12 (154)137 toc23
-[(VMX Instructions)](B.1.13 )/section-B.1.13 (154)120 toc23
-[(Extended Page Tables VMX instructions)](B.1.14 )/section-B.1.14 (154)103 toc23
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-[(Tejas New Instructions \(SSSE3\))](B.1.15 )/section-B.1.15 (155)681 toc23
-[(AMD SSE4A)](B.1.16 )/section-B.1.16 (155)664 toc23
-[(New instructions in Barcelona)](B.1.17 )/section-B.1.17 (155)647 toc23
-[(Penryn New Instructions \(SSE4.1\))](B.1.18 )/section-B.1.18 (155)630 toc23
-[(Nehalem New Instructions \(SSE4.2\))](B.1.19 )/section-B.1.19 (157)613 toc23
-[(Intel SMX)](B.1.20 )/section-B.1.20 (157)596 toc23
-[(Geode \(Cyrix\) 3DNow! additions)](B.1.21 )/section-B.1.21 (157)579 toc23
-[(Intel new instructions in ???)](B.1.22 )/section-B.1.22 (157)562 toc23
-[(Intel AES instructions)](B.1.23 )/section-B.1.23 (157)545 toc23
-[(Intel AVX AES instructions)](B.1.24 )/section-B.1.24 (157)528 toc23
-[(Intel AVX instructions)](B.1.25 )/section-B.1.25 (158)511 toc23
-[(Intel Carry-Less Multiplication instructions \(CLMUL\))](B.1.26 )/section-B.1.26 (170)494 toc23
-[(Intel AVX Carry-Less Multiplication instructions \(CLMUL\))](B.1.27 )/section-B.1.27 (170)477 toc23
-[(Intel Fused Multiply-Add instructions \(FMA\))](B.1.28 )/section-B.1.28 (170)460 toc23
-[(VIA \(Centaur\) security instructions)](B.1.29 )/section-B.1.29 (174)443 toc23
-[(AMD Lightweight Profiling \(LWP\) instructions)](B.1.30 )/section-B.1.30 (174)426 toc23
-[(AMD XOP, FMA4 and CVT16 instructions \(SSE5\))](B.1.31 )/section-B.1.31 (174)409 toc23
-[(Systematic names for the hinting nop instructions)](B.1.32 )/section-B.1.32 (177)392 toc23
-[(NASM Version History)](Appendix C: )/appendix-C (181)375 toc03
-[(NASM 2 Series)](C.1 )/section-C.1 (181)358 toc13
-[(Version 2.08)](C.1.1 )/section-C.1.1 (181)341 toc23
-[(Version 2.07)](C.1.2 )/section-C.1.2 (181)324 toc23
-[(Version 2.06)](C.1.3 )/section-C.1.3 (182)307 toc23
-[(Version 2.05.01)](C.1.4 )/section-C.1.4 (182)290 toc23
-[(Version 2.05)](C.1.5 )/section-C.1.5 (182)273 toc23
-[(Version 2.04)](C.1.6 )/section-C.1.6 (183)256 toc23
-[(Version 2.03.01)](C.1.7 )/section-C.1.7 (184)239 toc23
-[(Version 2.03)](C.1.8 )/section-C.1.8 (184)222 toc23
-[(Version 2.02)](C.1.9 )/section-C.1.9 (184)205 toc23
-[(Version 2.01)](C.1.10 )/section-C.1.10 (185)188 toc23
-[(Version 2.00)](C.1.11 )/section-C.1.11 (185)171 toc23
-[(NASM 0.98 Series)](C.2 )/section-C.2 (186)154 toc13
-[(Version 0.98.39)](C.2.1 )/section-C.2.1 (186)137 toc23
-[(Version 0.98.38)](C.2.2 )/section-C.2.2 (186)120 toc23
-[(Version 0.98.37)](C.2.3 )/section-C.2.3 (187)103 toc23
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-[(Version 0.98.36)](C.2.4 )/section-C.2.4 (187)681 toc23
-[(Version 0.98.35)](C.2.5 )/section-C.2.5 (187)664 toc23
-[(Version 0.98.34)](C.2.6 )/section-C.2.6 (187)647 toc23
-[(Version 0.98.33)](C.2.7 )/section-C.2.7 (188)630 toc23
-[(Version 0.98.32)](C.2.8 )/section-C.2.8 (188)613 toc23
-[(Version 0.98.31)](C.2.9 )/section-C.2.9 (188)596 toc23
-[(Version 0.98.30)](C.2.10 )/section-C.2.10 (189)579 toc23
-[(Version 0.98.28)](C.2.11 )/section-C.2.11 (189)562 toc23
-[(Version 0.98.26)](C.2.12 )/section-C.2.12 (189)545 toc23
-[(Version 0.98.25alt)](C.2.13 )/section-C.2.13 (189)528 toc23
-[(Version 0.98.25)](C.2.14 )/section-C.2.14 (189)511 toc23
-[(Version 0.98.24p1)](C.2.15 )/section-C.2.15 (189)494 toc23
-[(Version 0.98.24)](C.2.16 )/section-C.2.16 (189)477 toc23
-[(Version 0.98.23)](C.2.17 )/section-C.2.17 (189)460 toc23
-[(Version 0.98.22)](C.2.18 )/section-C.2.18 (189)443 toc23
-[(Version 0.98.21)](C.2.19 )/section-C.2.19 (189)426 toc23
-[(Version 0.98.20)](C.2.20 )/section-C.2.20 (190)409 toc23
-[(Version 0.98.19)](C.2.21 )/section-C.2.21 (190)392 toc23
-[(Version 0.98.18)](C.2.22 )/section-C.2.22 (190)375 toc23
-[(Version 0.98.17)](C.2.23 )/section-C.2.23 (190)358 toc23
-[(Version 0.98.16)](C.2.24 )/section-C.2.24 (190)341 toc23
-[(Version 0.98.15)](C.2.25 )/section-C.2.25 (190)324 toc23
-[(Version 0.98.14)](C.2.26 )/section-C.2.26 (190)307 toc23
-[(Version 0.98.13)](C.2.27 )/section-C.2.27 (190)290 toc23
-[(Version 0.98.12)](C.2.28 )/section-C.2.28 (190)273 toc23
-[(Version 0.98.11)](C.2.29 )/section-C.2.29 (190)256 toc23
-[(Version 0.98.10)](C.2.30 )/section-C.2.30 (190)239 toc23
-[(Version 0.98.09)](C.2.31 )/section-C.2.31 (190)222 toc23
-[(Version 0.98.08)](C.2.32 )/section-C.2.32 (191)205 toc23
-[(Version 0.98.09b with John Coffman patches released 28-Oct-2001)](C.2.33 )/section-C.2.33 (191)188 toc23
-[(Version 0.98.07 released 01/28/01)](C.2.34 )/section-C.2.34 (191)171 toc23
-[(Version 0.98.06f released 01/18/01)](C.2.35 )/section-C.2.35 (191)154 toc23
-[(Version 0.98.06e released 01/09/01)](C.2.36 )/section-C.2.36 (191)137 toc23
-[(Version 0.98p1)](C.2.37 )/section-C.2.37 (192)120 toc23
-[(Version 0.98bf \(bug-fixed\))](C.2.38 )/section-C.2.38 (192)103 toc23
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-[(Version 0.98.03 with John Coffman's changes released 27-Jul-2000)](C.2.39 )/section-C.2.39 (192)681 toc23
-[(Version 0.98.03)](C.2.40 )/section-C.2.40 (192)664 toc23
-[(Version 0.98)](C.2.41 )/section-C.2.41 (195)647 toc23
-[(Version 0.98p9)](C.2.42 )/section-C.2.42 (196)630 toc23
-[(Version 0.98p8)](C.2.43 )/section-C.2.43 (196)613 toc23
-[(Version 0.98p7)](C.2.44 )/section-C.2.44 (196)596 toc23
-[(Version 0.98p6)](C.2.45 )/section-C.2.45 (197)579 toc23
-[(Version 0.98p3.7)](C.2.46 )/section-C.2.46 (197)562 toc23
-[(Version 0.98p3.6)](C.2.47 )/section-C.2.47 (197)545 toc23
-[(Version 0.98p3.5)](C.2.48 )/section-C.2.48 (197)528 toc23
-[(Version 0.98p3.4)](C.2.49 )/section-C.2.49 (198)511 toc23
-[(Version 0.98p3.3)](C.2.50 )/section-C.2.50 (198)494 toc23
-[(Version 0.98p3.2)](C.2.51 )/section-C.2.51 (198)477 toc23
-[(Version 0.98p3-hpa)](C.2.52 )/section-C.2.52 (198)460 toc23
-[(Version 0.98 pre-release 3)](C.2.53 )/section-C.2.53 (198)443 toc23
-[(Version 0.98 pre-release 2)](C.2.54 )/section-C.2.54 (199)426 toc23
-[(Version 0.98 pre-release 1)](C.2.55 )/section-C.2.55 (199)409 toc23
-[(NASM 0.9 Series)](C.3 )/section-C.3 (200)392 toc13
-[(Version 0.97 released December 1997)](C.3.1 )/section-C.3.1 (200)375 toc23
-[(Version 0.96 released November 1997)](C.3.2 )/section-C.3.2 (200)358 toc23
-[(Version 0.95 released July 1997)](C.3.3 )/section-C.3.3 (202)341 toc23
-[(Version 0.94 released April 1997)](C.3.4 )/section-C.3.4 (204)324 toc23
-[(Version 0.93 released January 1997)](C.3.5 )/section-C.3.5 (204)307 toc23
-[(Version 0.92 released January 1997)](C.3.6 )/section-C.3.6 (205)290 toc23
-[(Version 0.91 released November 1996)](C.3.7 )/section-C.3.7 (205)273 toc23
-[(Version 0.90 released October 1996)](C.3.8 )/section-C.3.8 (205)256 toc23
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-[{/chapter-1 xa}(Chapter 1: Introduction)]642.8 chap3
-[{/section-1.1 xa}(What Is NASM?)](1.1)603.4 head3
-[(The Netwide Assembler, NASM, is an 80x86 and x86-64 assembler designed for portability and modularity.)]586.4 norm1
-[(It supports a range of object file formats, including Linux and )2(*BSD)0( )2(a.out)0(, )2(ELF)0(, )2(COFF)0(, )2(Mach-O)0(,)]575.4 norm0
-[(Microsoft 16-bit )2(OBJ)0(, )2(Win32)0( and )2(Win64)0(. It will also output plain binary files. Its syntax is designed to be)]564.4 norm0
-[(simple and easy to understand, similar to Intel's but less complex. It supports all currently known x86)]553.4 norm0
-[(architectural extensions, and has strong support for macros.)]542.4 norm2
-[{/section-1.1.1 xa}(Why Yet Another Assembler?)](1.1.1)523.2 subh3
-[(The Netwide Assembler grew out of an idea on )2(comp.lang.asm.x86)0( \(or possibly )2(alt.lang.asm)0( \226 I)]506.2 norm1
-[(forget which\), which was essentially that there didn't seem to be a good )1(free)0( x86-series assembler around,)]495.2 norm0
-[(and that maybe someone ought to write one.)]484.2 norm2
-[2(a86)0( is good, but not free, and in particular you don't get any 32-bit capability until you pay. It's DOS)]467.2 bull1
-[(only, too.)]456.2 bull2
-[2(gas)0( is free, and ports over to DOS and Unix, but it's not very good, since it's designed to be a back end to)]439.2 bull1
-[2(gcc)0(, which always feeds it correct code. So its error checking is minimal. Also, its syntax is horrible, from)]428.2 bull0
-[(the point of view of anyone trying to actually )1(write)0( anything in it. Plus you can't write 16-bit code in it)]417.2 bull0
-[(\(properly.\))]406.2 bull2
-[2(as86)0( is specific to Minix and Linux, and \(my version at least\) doesn't seem to have much \(or any\))]389.2 bull1
-[(documentation.)]378.2 bull2
-[2(MASM)0( isn't very good, and it's \(was\) expensive, and it runs only under DOS.)]361.2 bull3
-[2(TASM)0( is better, but still strives for MASM compatibility, which means millions of directives and tons of)]344.2 bull1
-[(red tape. And its syntax is essentially MASM's, with the contradictions and quirks that entails \(although it)]333.2 bull0
-[(sorts out some of those by means of Ideal mode.\) It's expensive too. And it's DOS-only.)]322.2 bull2
-[(So here, for your coding pleasure, is NASM. At present it's still in prototype stage \226 we don't promise that it)]305.2 norm1
-[(can outperform any of these assemblers. But please, )1(please)0( send us bug reports, fixes, helpful information,)]294.2 norm0
-[(and anything else you can get your hands on \(and thanks to the many people who've done this already! You)]283.2 norm0
-[(all know who you are\), and we'll improve it out of all recognition. Again.)]272.2 norm2
-[{/section-1.1.2 xa}(License Conditions)](1.1.2)253 subh3
-[(Please see the file )2(LICENSE)0(, supplied as part of any NASM distribution archive, for the license conditions)]236 norm1
-[(under which you may use NASM. NASM is now under the so-called 2-clause BSD license, also known as)]225 norm0
-[(the simplified BSD license.)]214 norm2
-[(Copyright 1996-2009 the NASM Authors \226 All rights reserved.)]197 norm3
-[(Redistribution and use in source and binary forms, with or without modification, are permitted provided that)]180 norm1
-[(the following conditions are met:)]169 norm2
-[(Redistributions of source code must retain the above copyright notice, this list of conditions and the)]152 bull1
-[(following disclaimer.)]141 bull2
-[(Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the)]124 bull1
-[(following disclaimer in the documentation and/or other materials provided with the distribution.)]113 bull2
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-[(THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS")]681 norm1
-[(AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE)]670 norm0
-[(IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE)]659 norm0
-[(ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE)]648 norm0
-[(LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR)]637 norm0
-[(CONSEQUENTIAL DAMAGES \(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF)]626 norm0
-[(SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS)]615 norm0
-[(INTERRUPTION\) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN)]604 norm0
-[(CONTRACT, STRICT LIABILITY, OR TORT \(INCLUDING NEGLIGENCE OR OTHERWISE\))]593 norm0
-[(ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE)]582 norm0
-[(POSSIBILITY OF SUCH DAMAGE.)]571 norm2
-[{/section-1.2 xa}(Contact Information)](1.2)549.6 head3
-[(The current version of NASM \(since about 0.98.08\) is maintained by a team of developers, accessible through)]532.6 norm1
-[(the )2(nasm-devel)0( mailing list \(see below for the link\). If you want to report a bug, please read ){/section-12.2 xl}(section 12.2){el}]521.6 norm0
-[(first.)]510.6 norm2
-[(NASM has a )(website at ){(http://www.nasm.us/)wl}2(http://www.nasm.us/){el}0(. If it's not there, google for us!)]493.6 norm3
-[(New releases, )(release candidates, and )(daily development snapshots of NASM are available from the official)]476.6 norm1
-[(web site.)]465.6 norm2
-[(Announcements are posted to ){(news:comp.lang.asm.x86)wl}2(comp.lang.asm.x86){el}0(, and to the web site)]448.6 norm1
-[{(http://www.freshmeat.net/)wl}2(http://www.freshmeat.net/){el}0(.)]437.6 norm2
-[(If you want information about the current development status, please subscribe to the )2(nasm-devel)0( email)]420.6 norm1
-[(list; see link from the website.)]409.6 norm2
-[{/section-1.3 xa}(Installation)](1.3)388.2 head3
-[{/section-1.3.1 xa}(Installing NASM under MS-)(DOS or Windows)](1.3.1)369 subh3
-[(Once you've obtained the appropriate archive for NASM, )2(nasm-XXX-dos.zip)0( or)]352 norm1
-[2(nasm-XXX-win32.zip)0( \(where )2(XXX)0( denotes the version number of NASM contained in the archive\),)]341 norm0
-[(unpack it into its own directory \(for example )2(c:\\nasm)0(\).)]330 norm2
-[(The archive will contain a set of executable files: the NASM executable file )2(nasm.exe)0(, the NDISASM)]313 norm1
-[(executable file )2(ndisasm.exe)0(, and possibly additional utilities to handle the RDOFF file format.)]302 norm2
-[(The only file NASM needs to run is its own executable, so copy )2(nasm.exe)0( to a directory on your PATH, or)]285 norm1
-[(alternatively edit )2(autoexec.bat)0( to add the )2(nasm)0( directory to your )2(PATH)0( \(to do that under Windows XP,)]274 norm0
-[(go to Start > Control Panel > System > Advanced > Environment Variables; these instructions may work)]263 norm0
-[(under other versions of Windows as well.\))]252 norm2
-[(That's it \226 NASM is installed. You don't need the nasm directory to be present to run NASM \(unless you've)]235 norm1
-[(added it to your )2(PATH)0(\), so you can delete it if you need to save space; however, you may want to keep the)]224 norm0
-[(documentation or test programs.)]213 norm2
-[(If you've downloaded the )(DOS source archive, )2(nasm-XXX.zip)0(, the )2(nasm)0( directory will also contain the)]196 norm1
-[(full NASM )(source code, and a selection of )(Makefiles you can \(hopefully\) use to rebuild your copy of NASM)]185 norm0
-[(from scratch. See the file )2(INSTALL)0( in the source archive.)]174 norm2
-[(Note that a number of files are generated from other files by Perl scripts. Although the NASM source)]157 norm1
-[(distribution includes these generated files, you will need to rebuild them \(and hence, will need a Perl)]146 norm0
-[(interpreter\) if you change insns.dat, standard.mac or the documentation. It is possible future source)]135 norm0
-[(distributions may not include these files at all. Ports of )(Perl for a variety of platforms, including DOS and)]124 norm0
-[(Windows, are available from ){(http://www.cpan.org/ports/)wl}(www.cpan.org){el}(.)]113 norm2
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-[{/section-1.3.2 xa}(Installing NASM under )(Unix)](1.3.2)678.8 subh3
-[(Once you've obtained the )(Unix source archive for NASM, )2(nasm-XXX.tar.gz)0( \(where )2(XXX)0( denotes the)]661.8 norm1
-[(version number of NASM contained in the archive\), unpack it into a directory such as )2(/usr/local/src)0(.)]650.8 norm0
-[(The archive, when unpacked, will create its own subdirectory )2(nasm-XXX)0(.)]639.8 norm2
-[(NASM is an )(auto-configuring package: once you've unpacked it, )2(cd)0( to the directory it's been unpacked into)]622.8 norm1
-[(and type )2(./configure)0(. This shell script will find the best C compiler to use for building NASM and set up)]611.8 norm0
-[(Makefiles accordingly.)]600.8 norm2
-[(Once NASM has auto-configured, you can type )2(make)0( to build the )2(nasm)0( and )2(ndisasm)0( binaries, and then)]583.8 norm1
-[2(make install)0( to install them in )2(/usr/local/bin)0( and install the )(man pages )2(nasm.1)0( and)]572.8 norm0
-[2(ndisasm.1)0( in )2(/usr/local/man/man1)0(. Alternatively, you can give options such as )2(--prefix)0( to the)]561.8 norm0
-[(configure script \(see the file )2(INSTALL)0( for more details\), or install the programs yourself.)]550.8 norm2
-[(NASM also comes with a set of utilities for handling the )2(RDOFF)0( custom object-file format, which are in the)]533.8 norm1
-[2(rdoff)0( subdirectory of the NASM archive. You can build these with )2(make rdf)0( and install them with)]522.8 norm0
-[2(make rdf_install)0(, if you want them.)]511.8 norm2
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-[{/chapter-2 xa}(Chapter 2: Running NASM)]642.8 chap3
-[{/section-2.1 xa}(NASM )(Command-Line Syntax)](2.1)603.4 head3
-[(To assemble a file, you issue a command of the form)]586.4 norm3
-[2(nasm -f <format> <filename> [-o <output>])]569.4 code3
-[(For example,)]552.4 norm3
-[2(nasm -f elf myfile.asm)]535.4 code3
-[(will assemble )2(myfile.asm)0( into an )2(ELF)0( object file )2(myfile.o)0(. And)]518.4 norm3
-[2(nasm -f bin myfile.asm -o myfile.com)]501.4 code3
-[(will assemble )2(myfile.asm)0( into a raw binary file )2(myfile.com)0(.)]484.4 norm3
-[(To produce a listing file, with the hex codes output from NASM displayed on the left of the original sources,)]467.4 norm1
-[(use the )2(-l)0( option to give a listing file name, for example:)]456.4 norm2
-[2(nasm -f coff myfile.asm -l myfile.lst)]439.4 code3
-[(To get further usage instructions from NASM, try typing)]422.4 norm3
-[2(nasm -h)]405.4 code3
-[(As )2(-hf)0(, this will also list the available output file formats, and what they are.)]388.4 norm3
-[(If you use Linux but aren't sure whether your system is )2(a.out)0( or )2(ELF)0(, type)]371.4 norm3
-[2(file nasm)]354.4 code3
-[(\(in the directory in which you put the NASM binary when you installed it\). If it says something like)]337.4 norm3
-[2(nasm: ELF 32-bit LSB executable i386 \(386 and up\) Version 1)]320.4 code3
-[(then your system is )2(ELF)0(, and you should use the option )2(-f elf)0( when you want NASM to produce Linux)]303.4 norm1
-[(object files. If it says)]292.4 norm2
-[2(nasm: Linux/i386 demand-paged executable \(QMAGIC\))]275.4 code3
-[(or something similar, your system is )2(a.out)0(, and you should use )2(-f aout)0( instead \(Linux )2(a.out)0( systems)]258.4 norm1
-[(have long been obsolete, and are rare these days.\))]247.4 norm2
-[(Like Unix compilers and assemblers, NASM is silent unless it goes wrong: you won't see any output at all,)]230.4 norm1
-[(unless it gives error messages.)]219.4 norm2
-[{/section-2.1.1 xa}(The )2(-o)0( Option: Specifying the Output File Name)](2.1.1)200.2 subh3
-[(NASM will normally choose the name of your output file for you; precisely how it does this is dependent on)]183.2 norm1
-[(the object file format. For Microsoft object file formats \()2(obj)0(, )2(win32)0( and )2(win64)0(\), it will remove the )2(.asm)]172.2 norm0
-[(extension \(or whatever extension you like to use \226 NASM doesn't care\) from your source file name and)]161.2 norm0
-[(substitute )2(.obj)0(. For Unix object file formats \()2(aout)0(, )2(as86)0(, )2(coff)0(, )2(elf32)0(, )2(elf64)0(, )2(ieee)0(, )2(macho32)0( and)]150.2 norm0
-[2(macho64)0(\) it will substitute )2(.o)0(. For )2(dbg)0(, )2(rdf)0(, )2(ith)0( and )2(srec)0(, it will use )2(.dbg)0(, )2(.rdf)0(, )2(.ith)0( and )2(.srec)0(,)]139.2 norm0
-[(respectively, and for the )2(bin)0( format it will simply remove the extension, so that )2(myfile.asm)0( produces the)]128.2 norm0
-[(output file )2(myfile)0(.)]117.2 norm2
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-[(If the output file already exists, NASM will overwrite it, unless it has the same name as the input file, in)]681 norm1
-[(which case it will give a warning and use )2(nasm.out)0( as the output file name instead.)]670 norm2
-[(For situations in which this behaviour is unacceptable, NASM provides the )2(-o)0( command-line option, which)]653 norm1
-[(allows you to specify your desired output file name. You invoke )2(-o)0( by following it with the name you wish)]642 norm0
-[(for the output file, either with or without an intervening space. For example:)]631 norm2
-[2(nasm -f bin program.asm -o program.com )]614 code1
-[2(nasm -f bin driver.asm -odriver.sys)]603 code2
-[(Note that this is a small o, and is different from a capital O , which is used to specify the number of)]586 norm1
-[(optimisation passes required. See ){/section-2.1.22 xl}(section 2.1.22){el}(.)]575 norm2
-[{/section-2.1.2 xa}(The )2(-f)0( Option: Specifying the )(Output File Format)](2.1.2)555.8 subh3
-[(If you do not supply the )2(-f)0( option to NASM, it will choose an output file format for you itself. In the)]538.8 norm1
-[(distribution versions of NASM, the default is always )2(bin)0(; if you've compiled your own copy of NASM, you)]527.8 norm0
-[(can redefine )2(OF_DEFAULT)0( at compile time and choose what you want the default to be.)]516.8 norm2
-[(Like )2(-o)0(, the intervening space between )2(-f)0( and the output file format is optional; so )2(-f elf)0( and )2(-felf)0( are)]499.8 norm1
-[(both valid.)]488.8 norm2
-[(A complete list of the available output file formats can be given by issuing the command )2(nasm -hf)0(.)]471.8 norm3
-[{/section-2.1.3 xa}(The )2(-l)0( Option: Generating a )(Listing File)](2.1.3)452.6 subh3
-[(If you supply the )2(-l)0( option to NASM, followed \(with the usual optional space\) by a file name, NASM will)]435.6 norm1
-[(generate a )(source-listing file for you, in which addresses and generated code are listed on the left, and the)]424.6 norm0
-[(actual source code, with expansions of multi-line macros \(except those which specifically request no)]413.6 norm0
-[(expansion in source listings: see ){/section-4.3.10 xl}(section 4.3.10){el}(\) on the right. For example:)]402.6 norm2
-[2(nasm -f elf myfile.asm -l myfile.lst)]385.6 code3
-[(If a list file is selected, you may turn off listing for a section of your source with )2([list -])0(, and turn it back)]368.6 norm1
-[(on with )2([list +])0(, \(the default, obviously\). There is no "user form" \(without the brackets\). This can be used)]357.6 norm0
-[(to list only sections of interest, avoiding excessively long listings.)]346.6 norm2
-[{/section-2.1.4 xa}(The )2(-M)0( Option: Generate )(Makefile Dependencies)](2.1.4)327.4 subh3
-[(This option can be used to generate makefile dependencies on stdout. This can be redirected to a file for)]310.4 norm1
-[(further processing. For example:)]299.4 norm2
-[2(nasm -M myfile.asm > myfile.dep)]282.4 code3
-[{/section-2.1.5 xa}(The )2(-MG)0( Option: Generate )(Makefile Dependencies)](2.1.5)263.2 subh3
-[(This option can be used to generate makefile dependencies on stdout. This differs from the )2(-M)0( option in that if)]246.2 norm1
-[(a nonexisting file is encountered, it is assumed to be a generated file and is added to the dependency list)]235.2 norm0
-[(without a prefix.)]224.2 norm2
-[{/section-2.1.6 xa}(The )2(-MF)0( Option: Set Makefile Dependency File)](2.1.6)205 subh3
-[(This option can be used with the )2(-M)0( or )2(-MG)0( options to send the output to a file, rather than to stdout. For)]188 norm1
-[(example:)]177 norm2
-[2(nasm -M -MF myfile.dep myfile.asm)]160 code3
-[{/section-2.1.7 xa}(The )2(-MD)0( Option: Assemble and Generate Dependencies)](2.1.7)140.8 subh3
-[(The )2(-MD)0( option acts as the combination of the )2(-M)0( and )2(-MF)0( options \(i.e. a filename has to be specified.\))]123.8 norm1
-[(However, unlike the )2(-M)0( or )2(-MG)0( options, )2(-MD)0( does )1(not)0( inhibit the normal operation of the assembler. Use this)]112.8 norm0
-[(to automatically generate updated dependencies with every assembly session. For example:)]101.8 norm2
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-[2(nasm -f elf -o myfile.o -MD myfile.dep myfile.asm)]681 code3
-[{/section-2.1.8 xa}(The )2(-MT)0( Option: Dependency Target Name)](2.1.8)661.8 subh3
-[(The )2(-MT)0( option can be used to override the default name of the dependency target. This is normally the same)]644.8 norm1
-[(as the output filename, specified by the )2(-o)0( option.)]633.8 norm2
-[{/section-2.1.9 xa}(The )2(-MQ)0( Option: Dependency Target Name \(Quoted\))](2.1.9)614.6 subh3
-[(The )2(-MQ)0( option acts as the )2(-MT)0( option, except it tries to quote characters that have special meaning in)]597.6 norm1
-[(Makefile syntax. This is not foolproof, as not all characters with special meaning are quotable in Make.)]586.6 norm2
-[{/section-2.1.10 xa}(The )2(-MP)0( Option: Emit phony targets)](2.1.10)567.4 subh3
-[(When used with any of the dependency generation options, the )2(-MP)0( option causes NASM to emit a phony)]550.4 norm1
-[(target without dependencies for each header file. This prevents Make from complaining if a header file has)]539.4 norm0
-[(been removed.)]528.4 norm2
-[{/section-2.1.11 xa}(The )2(-F)0( Option: Selecting a )(Debug Information Format)](2.1.11)509.2 subh3
-[(This option is used to select the format of the debug information emitted into the output file, to be used by a)]492.2 norm1
-[(debugger \(or )1(will)0( be\). Prior to version 2.03.01, the use of this switch did )1(not)0( enable output of the selected)]481.2 norm0
-[(debug info format. Use )2(-g)0(, see ){/section-2.1.12 xl}(section 2.1.12){el}(, to enable output. Versions 2.03.01 and later automatically)]470.2 norm0
-[(enable )2(-g)0( if )2(-F)0( is specified.)]459.2 norm2
-[(A complete list of the available debug file formats for an output format can be seen by issuing the command)]442.2 norm1
-[2(nasm -f <format> -y)0(. Not all output formats currently support debugging output. See ){/section-2.1.26 xl}(section 2.1.26){el}(.)]431.2 norm2
-[(This should not be confused with the )2(-f dbg)0( output format option which is not built into NASM by default.)]414.2 norm1
-[(For information on how to enable it when building from the sources, see ){/section-7.14 xl}(section 7.14){el}(.)]403.2 norm2
-[{/section-2.1.12 xa}(The )2(-g)0( Option: Enabling )(Debug Information.)](2.1.12)384 subh3
-[(This option can be used to generate debugging information in the specified format. See ){/section-2.1.11 xl}(section 2.1.11){el}(. Using)]367 norm1
-[2(-g)0( without )2(-F)0( results in emitting debug info in the default format, if any, for the selected output format. If no)]356 norm0
-[(debug information is currently implemented in the selected output format, )2(-g)0( is )1(silently ignored)0(.)]345 norm2
-[{/section-2.1.13 xa}(The )2(-X)0( Option: Selecting an )(Error Reporting Format)](2.1.13)325.8 subh3
-[(This option can be used to select an error reporting format for any error messages that might be produced by)]308.8 norm1
-[(NASM.)]297.8 norm2
-[(Currently, two error reporting formats may be selected. They are the )2(-Xvc)0( option and the )2(-Xgnu)0( option. The)]280.8 norm1
-[(GNU format is the default and looks like this:)]269.8 norm2
-[2(filename.asm:65: error: specific error message)]252.8 code3
-[(where )2(filename.asm)0( is the name of the source file in which the error was detected, )2(65)0( is the source file)]235.8 norm1
-[(line number on which the error was detected, )2(error)0( is the severity of the error \(this could be )2(warning)0(\),)]224.8 norm0
-[(and )2(specific error message)0( is a more detailed text message which should help pinpoint the exact)]213.8 norm0
-[(problem.)]202.8 norm2
-[(The other format, specified by )2(-Xvc)0( is the style used by Microsoft Visual C++ and some other programs. It)]185.8 norm1
-[(looks like this:)]174.8 norm2
-[2(filename.asm\(65\) : error: specific error message)]157.8 code3
-[(where the only difference is that the line number is in parentheses instead of being delimited by colons.)]140.8 norm3
-[(See also the )2(Visual C++)0( output format, ){/section-7.5 xl}(section 7.5){el}(.)]123.8 norm3
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-[{/section-2.1.14 xa}(The )2(-Z)0( Option: Send Errors to a File)](2.1.14)678.8 subh3
-[(Under )2(MS-DOS)0( it can be difficult \(though there are ways\) to redirect the standard-error output of a program)]661.8 norm1
-[(to a file. Since NASM usually produces its warning and )(error messages on )2(stderr)0(, this can make it hard to)]650.8 norm0
-[(capture the errors if \(for example\) you want to load them into an editor.)]639.8 norm2
-[(NASM therefore provides the )2(-Z)0( option, taking a filename argument which causes errors to be sent to the)]622.8 norm1
-[(specified files rather than standard error. Therefore you can )(redirect the errors into a file by typing)]611.8 norm2
-[2(nasm -Z myfile.err -f obj myfile.asm)]594.8 code3
-[(In earlier versions of NASM, this option was called )2(-E)0(, but it was changed since )2(-E)0( is an option)]577.8 norm1
-[(conventionally used for preprocessing only, with disastrous results. See ){/section-2.1.20 xl}(section 2.1.20){el}(.)]566.8 norm2
-[{/section-2.1.15 xa}(The )2(-s)0( Option: Send Errors to )2(stdout)](2.1.15)547.6 subh3
-[(The )2(-s)0( option redirects )(error messages to )2(stdout)0( rather than )2(stderr)0(, so it can be redirected under)]530.6 norm1
-[2(MS-DOS)0(. To assemble the file )2(myfile.asm)0( and pipe its output to the )2(more)0( program, you can type:)]519.6 norm2
-[2(nasm -s -f obj myfile.asm | more)]502.6 code3
-[(See also the )2(-Z)0( option, ){/section-2.1.14 xl}(section 2.1.14){el}(.)]485.6 norm3
-[{/section-2.1.16 xa}(The )2(-i)0( Option: Include File Search Directories)](2.1.16)466.4 subh3
-[(When NASM sees the )2(%include)0( or )2(%pathsearch)0( directive in a source file \(see ){/section-4.6.1 xl}(section 4.6.1){el}(, ){/section-4.6.2 xl}(section){el}]449.4 norm1
-[{/section-4.6.2 xl}(4.6.2){el}( or ){/section-3.2.3 xl}(section 3.2.3){el}(\), it will search for the given file not only in the current directory, but also in any)]438.4 norm0
-[(directories specified on the command line by the use of the )2(-i)0( option. Therefore you can include files from a)]427.4 norm0
-[(macro library, for example, by typing)]416.4 norm2
-[2(nasm -ic:\\macrolib\\ -f obj myfile.asm)]399.4 code3
-[(\(As usual, a space between )2(-i)0( and the path name is allowed, and optional\).)]382.4 norm3
-[(NASM, in the interests of complete source-code portability, does not understand the file naming conventions)]365.4 norm1
-[(of the OS it is running on; the string you provide as an argument to the )2(-i)0( option will be prepended exactly as)]354.4 norm0
-[(written to the name of the include file. Therefore the trailing backslash in the above example is necessary.)]343.4 norm0
-[(Under Unix, a trailing forward slash is similarly necessary.)]332.4 norm2
-[(\(You can use this to your advantage, if you're really )(perverse, by noting that the option )2(-ifoo)0( will cause)]315.4 norm1
-[2(%include "bar.i")0( to search for the file )2(foobar.i)0(...\))]304.4 norm2
-[(If you want to define a )1(standard)0( )(include search path, similar to )2(/usr/include)0( on Unix systems, you)]287.4 norm1
-[(should place one or more )2(-i)0( directives in the )2(NASMENV)0( environment variable \(see ){/section-2.1.28 xl}(section 2.1.28){el}(\).)]276.4 norm2
-[(For Makefile compatibility with many C compilers, this option can also be specified as )2(-I)0(.)]259.4 norm3
-[{/section-2.1.17 xa}(The )2(-p)0( Option: )(Pre-Include a File)](2.1.17)240.2 subh3
-[(NASM allows you to specify files to be )1(pre-included)0( into your source file, by the use of the )2(-p)0( option. So)]223.2 norm1
-[(running)]212.2 norm2
-[2(nasm myfile.asm -p myinc.inc)]195.2 code3
-[(is equivalent to running )2(nasm myfile.asm)0( and placing the directive )2(%include "myinc.inc")0( at the)]178.2 norm1
-[(start of the file.)]167.2 norm2
-[(For consistency with the )2(-I)0(, )2(-D)0( and )2(-U)0( options, this option can also be specified as )2(-P)0(.)]150.2 norm3
-[{/section-2.1.18 xa}(The )2(-d)0( Option: )(Pre-Define a Macro)](2.1.18)131 subh3
-[(Just as the )2(-p)0( option gives an alternative to placing )2(%include)0( directives at the start of a source file, the )2(-d)]114 norm1
-[(option gives an alternative to placing a )2(%define)0( directive. You could code)]103 norm2
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-[2(nasm myfile.asm -dFOO=100)]681 code3
-[(as an alternative to placing the directive)]664 norm3
-[2(%define FOO 100)]647 code3
-[(at the start of the file. You can miss off the macro value, as well: the option )2(-dFOO)0( is equivalent to coding)]630 norm1
-[2(%define FOO)0(. This form of the directive may be useful for selecting )(assembly-time options which are then)]619 norm0
-[(tested using )2(%ifdef)0(, for example )2(-dDEBUG)0(.)]608 norm2
-[(For Makefile compatibility with many C compilers, this option can also be specified as )2(-D)0(.)]591 norm3
-[{/section-2.1.19 xa}(The )2(-u)0( Option: )(Undefine a Macro)](2.1.19)571.8 subh3
-[(The )2(-u)0( option undefines a macro that would otherwise have been pre-defined, either automatically or by a)]554.8 norm1
-[2(-p)0( or )2(-d)0( option specified earlier on the command lines.)]543.8 norm2
-[(For example, the following command line:)]526.8 norm3
-[2(nasm myfile.asm -dFOO=100 -uFOO)]509.8 code3
-[(would result in )2(FOO)0( )1(not)0( being a predefined macro in the program. This is useful to override options specified)]492.8 norm1
-[(at a different point in a Makefile.)]481.8 norm2
-[(For Makefile compatibility with many C compilers, this option can also be specified as )2(-U)0(.)]464.8 norm3
-[{/section-2.1.20 xa}(The )2(-E)0( Option: Preprocess Only)](2.1.20)445.6 subh3
-[(NASM allows the )(preprocessor to be run on its own, up to a point. Using the )2(-E)0( option \(which requires no)]428.6 norm1
-[(arguments\) will cause NASM to preprocess its input file, expand all the macro references, remove all the)]417.6 norm0
-[(comments and preprocessor directives, and print the resulting file on standard output \(or save it to a file, if the)]406.6 norm0
-[2(-o)0( option is also used\).)]395.6 norm2
-[(This option cannot be applied to programs which require the preprocessor to evaluate )(expressions which)]378.6 norm1
-[(depend on the values of symbols: so code such as)]367.6 norm2
-[2(%assign tablesize \($-tablestart\))]350.6 code3
-[(will cause an error in )(preprocess-only mode.)]333.6 norm3
-[(For compatiblity with older version of NASM, this option can also be written )2(-e)0(. )2(-E)0( in older versions of)]316.6 norm1
-[(NASM was the equivalent of the current )2(-Z)0( option, ){/section-2.1.14 xl}(section 2.1.14){el}(.)]305.6 norm2
-[{/section-2.1.21 xa}(The )2(-a)0( Option: Don't Preprocess At All)](2.1.21)286.4 subh3
-[(If NASM is being used as the back end to a compiler, it might be desirable to )(suppress preprocessing)]269.4 norm1
-[(completely and assume the compiler has already done it, to save time and increase compilation speeds. The)]258.4 norm0
-[2(-a)0( option, requiring no argument, instructs NASM to replace its powerful )(preprocessor with a )(stub)]247.4 norm0
-[(preprocessor which does nothing.)]236.4 norm2
-[{/section-2.1.22 xa}(The )2(-O)0( Option: Specifying )(Multipass Optimization)](2.1.22)217.2 subh3
-[(NASM defaults to not optimizing operands which can fit into a signed byte. This means that if you want the)]200.2 norm1
-[(shortest possible object code, you have to enable optimization.)]189.2 norm2
-[(Using the )2(-O)0( option, you can tell NASM to carry out different levels of optimization. The syntax is:)]172.2 norm3
-[2(-O0)0(: No optimization. All operands take their long forms, if a short form is not specified, except)]155.2 bull1
-[(conditional jumps. This is intended to match NASM 0.98 behavior.)]144.2 bull2
-[2(-O1)0(: Minimal optimization. As above, but immediate operands which will fit in a signed byte are)]127.2 bull1
-[(optimized, unless the long form is specified. Conditional jumps default to the long form unless otherwise)]116.2 bull0
-[(specified.)]105.2 bull2
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-[2(-Ox)0( \(where )2(x)0( is the actual letter )2(x)0(\): Multipass optimization. Minimize branch offsets and signed)]681 bull1
-[(immediate bytes, overriding size specification unless the )2(strict)0( keyword has been used \(see ){/section-3.7 xl}(section){el}]670 bull0
-[{/section-3.7 xl}(3.7){el}(\). For compatability with earlier releases, the letter )2(x)0( may also be any number greater than one. This)]659 bull0
-[(number has no effect on the actual number of passes.)]648 bull2
-[(The )2(-Ox)0( mode is recommended for most uses.)]631 norm3
-[(Note that this is a capital )2(O)0(, and is different from a small )2(o)0(, which is used to specify the output file name. See)]614 norm1
-[{/section-2.1.1 xl}(section 2.1.1){el}(.)]603 norm2
-[{/section-2.1.23 xa}(The )2(-t)0( Option: Enable TASM Compatibility Mode)](2.1.23)583.8 subh3
-[(NASM includes a limited form of compatibility with Borland's )2(TASM)0(. When NASM's )2(-t)0( option is used, the)]566.8 norm1
-[(following changes are made:)]555.8 norm2
-[(local labels may be prefixed with )2(@@)0( instead of )2(.)]538.8 bull3
-[(size override is supported within brackets. In TASM compatible mode, a size override inside square)]521.8 bull1
-[(brackets changes the size of the operand, and not the address type of the operand as it does in NASM)]510.8 bull0
-[(syntax. E.g. )2(mov eax,[DWORD val])0( is valid syntax in TASM compatibility mode. Note that you lose)]499.8 bull0
-[(the ability to override the default address type for the instruction.)]488.8 bull2
-[(unprefixed forms of some directives supported \()2(arg)0(, )2(elif)0(, )2(else)0(, )2(endif)0(, )2(if)0(, )2(ifdef)0(, )2(ifdifi)0(,)]471.8 bull1
-[2(ifndef)0(, )2(include)0(, )2(local)0(\))]460.8 bull2
-[{/section-2.1.24 xa}(The )2(-w)0( and )2(-W)0( Options: Enable or Disable Assembly )(Warnings)](2.1.24)441.6 subh3
-[(NASM can observe many conditions during the course of assembly which are worth mentioning to the user,)]424.6 norm1
-[(but not a sufficiently severe error to justify NASM refusing to generate an output file. These conditions are)]413.6 norm0
-[(reported like errors, but come up with the word `warning' before the message. Warnings do not prevent)]402.6 norm0
-[(NASM from generating an output file and returning a success status to the operating system.)]391.6 norm2
-[(Some conditions are even less severe than that: they are only sometimes worth mentioning to the user.)]374.6 norm1
-[(Therefore NASM supports the )2(-w)0( command-line option, which enables or disables certain classes of)]363.6 norm0
-[(assembly warning. Such warning classes are described by a name, for example )2(orphan-labels)0(; you can)]352.6 norm0
-[(enable warnings of this class by the command-line option )2(-w+orphan-labels)0( and disable it by)]341.6 norm0
-[2(-w-orphan-labels)0(.)]330.6 norm2
-[(The )(suppressible warning classes are:)]313.6 norm3
-[2(macro-params)0( covers warnings about )(multi-line macros being invoked with the wrong number of)]296.6 bull1
-[(parameters. This warning class is enabled by default; see ){/section-4.3.2 xl}(section 4.3.2){el}( for an example of why you might)]285.6 bull0
-[(want to disable it.)]274.6 bull2
-[2(macro-selfref)0( warns if a macro references itself. This warning class is disabled by default.)]257.6 bull3
-[2(macro-defaults)0( warns when a macro has more default parameters than optional parameters. This)]240.6 bull1
-[(warning class is enabled by default; see ){/section-4.3.5 xl}(section 4.3.5){el}( for why you might want to disable it.)]229.6 bull2
-[2(orphan-labels)0( covers warnings about source lines which contain no instruction but define a label)]212.6 bull1
-[(without a trailing colon. NASM warns about this somewhat obscure condition by default; see ){/section-3.1 xl}(section 3.1){el}]201.6 bull0
-[(for more information.)]190.6 bull2
-[2(number-overflow)0( covers warnings about numeric constants which don't fit in 64 bits. This warning)]173.6 bull1
-[(class is enabled by default.)]162.6 bull2
-[2(gnu-elf-extensions)0( warns if 8-bit or 16-bit relocations are used in )2(-f elf)0( format. The GNU)]145.6 bull1
-[(extensions allow this. This warning class is disabled by default.)]134.6 bull2
-[2(float-overflow)0( warns about floating point overflow. Enabled by default.)]117.6 bull3
-[2(float-denorm)0( warns about floating point denormals. Disabled by default.)]100.6 bull3
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-[2(float-underflow)0( warns about floating point underflow. Disabled by default.)]681 bull3
-[2(float-toolong)0( warns about too many digits in floating-point numbers. Enabled by default.)]664 bull3
-[2(user)0( controls )2(%warning)0( directives \(see ){/section-4.9 xl}(section 4.9){el}(\). Enabled by default.)]647 bull3
-[2(error)0( causes warnings to be treated as errors. Disabled by default.)]630 bull3
-[2(all)0( is an alias for )1(all)0( suppressible warning classes \(not including )2(error)0(\). Thus, )2(-w+all)0( enables all)]613 bull1
-[(available warnings.)]602 bull2
-[(In addition, you can set warning classes across sections. Warning classes may be enabled with)]585 norm1
-[2([warning +warning-name])0(, disabled with )2([warning -warning-name])0( or reset to their original)]574 norm0
-[(value with )2([warning *warning-name])0(. No "user form" \(without the brackets\) exists.)]563 norm2
-[(Since version 2.00, NASM has also supported the gcc-like syntax )2(-Wwarning)0( and )2(-Wno-warning)]546 norm1
-[(instead of )2(-w+warning)0( and )2(-w-warning)0(, respectively.)]535 norm2
-[{/section-2.1.25 xa}(The )2(-v)0( Option: Display )(Version Info)](2.1.25)515.8 subh3
-[(Typing )2(NASM -v)0( will display the version of NASM which you are using, and the date on which it was)]498.8 norm1
-[(compiled.)]487.8 norm2
-[(You will need the version number if you report a bug.)]470.8 norm3
-[{/section-2.1.26 xa}(The )2(-y)0( Option: Display Available Debug Info Formats)](2.1.26)451.6 subh3
-[(Typing )2(nasm -f <option> -y)0( will display a list of the available debug info formats for the given output)]434.6 norm1
-[(format. The default format is indicated by an asterisk. For example:)]423.6 norm2
-[2(nasm -f elf -y)]406.6 code3
-[2(valid debug formats for 'elf32' output format are )]389.6 code1
-[2( \('*' denotes default\): )]378.6 code0
-[2( * stabs ELF32 \(i386\) stabs debug format for Linux )]367.6 code0
-[2( dwarf elf32 \(i386\) dwarf debug format for Linux)]356.6 code2
-[{/section-2.1.27 xa}(The )2(--prefix)0( and )2(--postfix)0( Options.)](2.1.27)337.4 subh3
-[(The )2(--prefix)0( and )2(--postfix)0( options prepend or append \(respectively\) the given argument to all)]320.4 norm1
-[2(global)0( or )2(extern)0( variables. E.g. )2(--prefix _)0( will prepend the underscore to all global and external)]309.4 norm0
-[(variables, as C sometimes \(but not always\) likes it.)]298.4 norm2
-[{/section-2.1.28 xa}(The )2(NASMENV)0( )(Environment Variable)](2.1.28)279.2 subh3
-[(If you define an environment variable called )2(NASMENV)0(, the program will interpret it as a list of extra)]262.2 norm1
-[(command-line options, which are processed before the real command line. You can use this to define)]251.2 norm0
-[(standard search directories for include files, by putting )2(-i)0( options in the )2(NASMENV)0( variable.)]240.2 norm2
-[(The value of the variable is split up at white space, so that the value )2(-s -ic:\\nasmlib\\)0( will be treated as)]223.2 norm1
-[(two separate options. However, that means that the value )2(-dNAME="my name")0( won't do what you might)]212.2 norm0
-[(want, because it will be split at the space and the NASM command-line processing will get confused by the)]201.2 norm0
-[(two nonsensical words )2(-dNAME="my)0( and )2(name")0(.)]190.2 norm2
-[(To get round this, NASM provides a feature whereby, if you begin the )2(NASMENV)0( environment variable with)]173.2 norm1
-[(some character that isn't a minus sign, then NASM will treat this character as the )(separator character for)]162.2 norm0
-[(options. So setting the )2(NASMENV)0( variable to the value )2(!-s!-ic:\\nasmlib\\)0( is equivalent to setting it to)]151.2 norm0
-[2(-s -ic:\\nasmlib\\)0(, but )2(!-dNAME="my name")0( will work.)]140.2 norm2
-[(This environment variable was previously called )2(NASM)0(. This was changed with version 0.98.31.)]123.2 norm3
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-[{/section-2.2 xa}(Quick Start for )(MASM Users)](2.2)676.6 head3
-[(If you're used to writing programs with MASM, or with )(TASM in MASM-compatible \(non-Ideal\) mode, or)]659.6 norm1
-[(with )2(a86)0(, this section attempts to outline the major differences between MASM's syntax and NASM's. If)]648.6 norm0
-[(you're not already used to MASM, it's probably worth skipping this section.)]637.6 norm2
-[{/section-2.2.1 xa}(NASM Is )(Case-Sensitive)](2.2.1)618.4 subh3
-[(One simple difference is that NASM is case-sensitive. It makes a difference whether you call your label )2(foo)0(,)]601.4 norm1
-[2(Foo)0( or )2(FOO)0(. If you're assembling to )2(DOS)0( or )2(OS/2)0( )2(.OBJ)0( files, you can invoke the )2(UPPERCASE)0( directive)]590.4 norm0
-[(\(documented in ){/section-7.4 xl}(section 7.4){el}(\) to ensure that all symbols exported to other code modules are forced to be upper)]579.4 norm0
-[(case; but even then, )1(within)0( a single module, NASM will distinguish between labels differing only in case.)]568.4 norm2
-[{/section-2.2.2 xa}(NASM Requires )(Square Brackets For )(Memory References)](2.2.2)549.2 subh3
-[(NASM was designed with simplicity of syntax in mind. One of the )(design goals of NASM is that it should be)]532.2 norm1
-[(possible, as far as is practical, for the user to look at a single line of NASM code and tell what opcode is)]521.2 norm0
-[(generated by it. You can't do this in MASM: if you declare, for example,)]510.2 norm2
-[2(foo equ 1 )]493.2 code1
-[2(bar dw 2)]482.2 code2
-[(then the two lines of code)]465.2 norm3
-[2( mov ax,foo )]448.2 code1
-[2( mov ax,bar)]437.2 code2
-[(generate completely different opcodes, despite having identical-looking syntaxes.)]420.2 norm3
-[(NASM avoids this undesirable situation by having a much simpler syntax for memory references. The rule is)]403.2 norm1
-[(simply that any access to the )1(contents)0( of a memory location requires square brackets around the address, and)]392.2 norm0
-[(any access to the )1(address)0( of a variable doesn't. So an instruction of the form )2(mov ax,foo)0( will )1(always)0( refer)]381.2 norm0
-[(to a compile-time constant, whether it's an )2(EQU)0( or the address of a variable; and to access the )1(contents)0( of the)]370.2 norm0
-[(variable )2(bar)0(, you must code )2(mov ax,[bar])0(.)]359.2 norm2
-[(This also means that NASM has no need for MASM's )2(OFFSET)0( keyword, since the MASM code)]342.2 norm1
-[2(mov ax,offset bar)0( means exactly the same thing as NASM's )2(mov ax,bar)0(. If you're trying to get)]331.2 norm0
-[(large amounts of MASM code to assemble sensibly under NASM, you can always code)]320.2 norm0
-[2(%idefine offset)0( to make the preprocessor treat the )2(OFFSET)0( keyword as a no-op.)]309.2 norm2
-[(This issue is even more confusing in )2(a86)0(, where declaring a label with a trailing colon defines it to be a)]292.2 norm1
-[(`label' as opposed to a `variable' and causes )2(a86)0( to adopt NASM-style semantics; so in )2(a86)0(, )2(mov ax,var)]281.2 norm0
-[(has different behaviour depending on whether )2(var)0( was declared as )2(var: dw 0)0( \(a label\) or )2(var dw 0)0( \(a)]270.2 norm0
-[(word-size variable\). NASM is very simple by comparison: )1(everything)0( is a label.)]259.2 norm2
-[(NASM, in the interests of simplicity, also does not support the )(hybrid syntaxes supported by MASM and its)]242.2 norm1
-[(clones, such as )2(mov ax,table[bx])0(, where a memory reference is denoted by one portion outside square)]231.2 norm0
-[(brackets and another portion inside. The correct syntax for the above is )2(mov ax,[table+bx])0(. Likewise,)]220.2 norm0
-[2(mov ax,es:[di])0( is wrong and )2(mov ax,[es:di])0( is right.)]209.2 norm2
-[{/section-2.2.3 xa}(NASM Doesn't Store )(Variable Types)](2.2.3)190 subh3
-[(NASM, by design, chooses not to remember the types of variables you declare. Whereas MASM will)]173 norm1
-[(remember, on seeing )2(var dw 0)0(, that you declared )2(var)0( as a word-size variable, and will then be able to fill)]162 norm0
-[(in the )(ambiguity in the size of the instruction )2(mov var,2)0(, NASM will deliberately remember nothing about)]151 norm0
-[(the symbol )2(var)0( except where it begins, and so you must explicitly code )2(mov word [var],2)0(.)]140 norm2
-[(For this reason, NASM doesn't support the )2(LODS)0(, )2(MOVS)0(, )2(STOS)0(, )2(SCAS)0(, )2(CMPS)0(, )2(INS)0(, or )2(OUTS)0( instructions,)]123 norm1
-[(but only supports the forms such as )2(LODSB)0(, )2(MOVSW)0(, and )2(SCASD)0(, which explicitly specify the size of the)]112 norm0
-[(components of the strings being manipulated.)]101 norm2
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-[{/section-2.2.4 xa}(NASM Doesn't )2(ASSUME)](2.2.4)678.8 subh3
-[(As part of NASM's drive for simplicity, it also does not support the )2(ASSUME)0( directive. NASM will not keep)]661.8 norm1
-[(track of what values you choose to put in your segment registers, and will never )1(automatically)0( generate a)]650.8 norm0
-[(segment override prefix.)]639.8 norm2
-[{/section-2.2.5 xa}(NASM Doesn't Support )(Memory Models)](2.2.5)620.6 subh3
-[(NASM also does not have any directives to support different 16-bit memory models. The programmer has to)]603.6 norm1
-[(keep track of which functions are supposed to be called with a )(far call and which with a )(near call, and is)]592.6 norm0
-[(responsible for putting the correct form of )2(RET)0( instruction \()2(RETN)0( or )2(RETF)0(; NASM accepts )2(RET)0( itself as an)]581.6 norm0
-[(alternate form for )2(RETN)0(\); in addition, the programmer is responsible for coding CALL FAR instructions)]570.6 norm0
-[(where necessary when calling )1(external)0( functions, and must also keep track of which external variable)]559.6 norm0
-[(definitions are far and which are near.)]548.6 norm2
-[{/section-2.2.6 xa}(Floating-Point Differences)](2.2.6)529.4 subh3
-[(NASM uses different names to refer to floating-point registers from MASM: where MASM would call them)]512.4 norm1
-[2(ST\(0\))0(, )2(ST\(1\))0( and so on, and )2(a86)0( would call them simply )2(0)0(, )2(1)0( and so on, NASM chooses to call them)]501.4 norm0
-[2(st0)0(, )2(st1)0( etc.)]490.4 norm2
-[(As of version 0.96, NASM now treats the instructions with )(`nowait' forms in the same way as)]473.4 norm1
-[(MASM-compatible assemblers. The idiosyncratic treatment employed by 0.95 and earlier was based on a)]462.4 norm0
-[(misunderstanding by the authors.)]451.4 norm2
-[{/section-2.2.7 xa}(Other Differences)](2.2.7)432.2 subh3
-[(For historical reasons, NASM uses the keyword )2(TWORD)0( where MASM and compatible assemblers use)]415.2 norm1
-[2(TBYTE)0(.)]404.2 norm2
-[(NASM does not declare )(uninitialized storage in the same way as MASM: where a MASM programmer might)]387.2 norm1
-[(use )2(stack db 64 dup \(?\))0(, NASM requires )2(stack resb 64)0(, intended to be read as `reserve 64)]376.2 norm0
-[(bytes'. For a limited amount of compatibility, since NASM treats )2(?)0( as a valid character in symbol names, you)]365.2 norm0
-[(can code )2(? equ 0)0( and then writing )2(dw ?)0( will at least do something vaguely useful. )2(DUP)0( is still not a)]354.2 norm0
-[(supported syntax, however.)]343.2 norm2
-[(In addition to all of this, macros and directives work completely differently to MASM. See ){/chapter-4 xl}(chapter 4){el}( and)]326.2 norm1
-[{/chapter-6 xl}(chapter 6){el}( for further details.)]315.2 norm2
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-[{/chapter-3 xa}(Chapter 3: The NASM Language)]642.8 chap3
-[{/section-3.1 xa}(Layout of a NASM Source Line)](3.1)603.4 head3
-[(Like most assemblers, each NASM source line contains \(unless it is a macro, a preprocessor directive or an)]586.4 norm1
-[(assembler directive: see ){/chapter-4 xl}(chapter 4){el}( and ){/chapter-6 xl}(chapter 6){el}(\) some combination of the four fields)]575.4 norm2
-[2(label: instruction operands ; comment)]558.4 code3
-[(As usual, most of these fields are optional; the presence or absence of any combination of a label, an)]541.4 norm1
-[(instruction and a comment is allowed. Of course, the operand field is either required or forbidden by the)]530.4 norm0
-[(presence and nature of the instruction field.)]519.4 norm2
-[(NASM uses backslash \(\\\) as the line continuation character; if a line ends with backslash, the next line is)]502.4 norm1
-[(considered to be a part of the backslash-ended line.)]491.4 norm2
-[(NASM places no restrictions on white space within a line: labels may have white space before them, or)]474.4 norm1
-[(instructions may have no space before them, or anything. The )(colon after a label is also optional. \(Note that)]463.4 norm0
-[(this means that if you intend to code )2(lodsb)0( alone on a line, and type )2(lodab)0( by accident, then that's still a)]452.4 norm0
-[(valid source line which does nothing but define a label. Running NASM with the command-line option)]441.4 norm0
-[2(-w+orphan-labels)0( will cause it to warn you if you define a label alone on a line without a )(trailing colon.\))]430.4 norm2
-[(Valid characters in labels are letters, numbers, )2(_)0(, )2($)0(, )2(#)0(, )2(@)0(, )2(~)0(, )2(.)0(, and )2(?)0(. The only characters which may be used)]413.4 norm1
-[(as the )1(first)0( character of an identifier are letters, )2(.)0( \(with special meaning: see ){/section-3.9 xl}(section 3.9){el}(\), )2(_)0( and )2(?)0(. An)]402.4 norm0
-[(identifier may also be prefixed with a )2($)0( to indicate that it is intended to be read as an identifier and not a)]391.4 norm0
-[(reserved word; thus, if some other module you are linking with defines a symbol called )2(eax)0(, you can refer to)]380.4 norm0
-[2($eax)0( in NASM code to distinguish the symbol from the register. Maximum length of an identifier is 4095)]369.4 norm0
-[(characters.)]358.4 norm2
-[(The instruction field may contain any machine instruction: Pentium and P6 instructions, FPU instructions,)]341.4 norm1
-[(MMX instructions and even undocumented instructions are all supported. The instruction may be prefixed by)]330.4 norm0
-[2(LOCK)0(, )2(REP)0(, )2(REPE)0(/)2(REPZ)0( or )2(REPNE)0(/)2(REPNZ)0(, in the usual way. Explicit )(address-size and )(operand-size)]319.4 norm0
-[(prefixes )2(A16)0(, )2(A32)0(, )2(A64)0(, )2(O16)0( and )2(O32)0(, )2(O64)0( are provided \226 one example of their use is given in ){/chapter-10 xl}(chapter 10){el}(.)]308.4 norm0
-[(You can also use the name of a )(segment register as an instruction prefix: coding )2(es mov [bx],ax)0( is)]297.4 norm0
-[(equivalent to coding )2(mov [es:bx],ax)0(. We recommend the latter syntax, since it is consistent with other)]286.4 norm0
-[(syntactic features of the language, but for instructions such as )2(LODSB)0(, which has no operands and yet can)]275.4 norm0
-[(require a segment override, there is no clean syntactic way to proceed apart from )2(es lodsb)0(.)]264.4 norm2
-[(An instruction is not required to use a prefix: prefixes such as )2(CS)0(, )2(A32)0(, )2(LOCK)0( or )2(REPE)0( can appear on a line)]247.4 norm1
-[(by themselves, and NASM will just generate the prefix bytes.)]236.4 norm2
-[(In addition to actual machine instructions, NASM also supports a number of pseudo-instructions, described in)]219.4 norm1
-[{/section-3.2 xl}(section 3.2){el}(.)]208.4 norm2
-[(Instruction )(operands may take a number of forms: they can be registers, described simply by the register name)]191.4 norm1
-[(\(e.g. )2(ax)0(, )2(bp)0(, )2(ebx)0(, )2(cr0)0(: NASM does not use the )2(gas)0(\226style syntax in which register names must be prefixed)]180.4 norm0
-[(by a )2(%)0( sign\), or they can be )(effective addresses \(see ){/section-3.3 xl}(section 3.3){el}(\), constants \(){/section-3.4 xl}(section 3.4){el}(\) or expressions)]169.4 norm0
-[(\(){/section-3.5 xl}(section 3.5){el}(\).)]158.4 norm2
-[(For x87 )(floating-point instructions, NASM accepts a wide range of syntaxes: you can use two-operand forms)]141.4 norm1
-[(like MASM supports, or you can use NASM's native single-operand forms in most cases. For example, you)]130.4 norm0
-[(can code:)]119.4 norm2
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-[2( fadd st1 ; this sets st0 := st0 + st1 )]681 code1
-[2( fadd st0,st1 ; so does this )]670 code0
-[2()]659 code0
-[2( fadd st1,st0 ; this sets st1 := st1 + st0 )]648 code0
-[2( fadd to st1 ; so does this)]637 code2
-[(Almost any x87 floating-point instruction that references memory must use one of the prefixes )2(DWORD)0(,)]620 norm1
-[2(QWORD)0( or )2(TWORD)0( to indicate what size of )(memory operand it refers to.)]609 norm2
-[{/section-3.2 xa}(Pseudo-Instructions)](3.2)587.6 head3
-[(Pseudo-instructions are things which, though not real x86 machine instructions, are used in the instruction)]570.6 norm1
-[(field anyway because that's the most convenient place to put them. The current pseudo-instructions are )2(DB)0(,)]559.6 norm0
-[2(DW)0(, )2(DD)0(, )2(DQ)0(, )2(DT)0(, )2(DO)0( and )2(DY)0(; their )(uninitialized counterparts )2(RESB)0(, )2(RESW)0(, )2(RESD)0(, )2(RESQ)0(, )2(REST)0(, )2(RESO)0( and)]548.6 norm0
-[2(RESY)0(; the )2(INCBIN)0( command, the )2(EQU)0( command, and the )2(TIMES)0( prefix.)]537.6 norm2
-[{/section-3.2.1 xa}2(DB)0( and Friends: Declaring Initialized Data)](3.2.1)518.4 subh3
-[2(DB)0(, )2(DW)0(, )2(DD)0(, )2(DQ)0(, )2(DT)0(, )2(DO)0( and )2(DY)0( are used, much as in MASM, to declare initialized data in the output file.)]501.4 norm1
-[(They can be invoked in a wide range of ways: )]490.4 norm2
-[2( db 0x55 ; just the byte 0x55 )]473.4 code1
-[2( db 0x55,0x56,0x57 ; three bytes in succession )]462.4 code0
-[2( db 'a',0x55 ; character constants are OK )]451.4 code0
-[2( db 'hello',13,10,'$' ; so are string constants )]440.4 code0
-[2( dw 0x1234 ; 0x34 0x12 )]429.4 code0
-[2( dw 'a' ; 0x61 0x00 \(it's just a number\) )]418.4 code0
-[2( dw 'ab' ; 0x61 0x62 \(character constant\) )]407.4 code0
-[2( dw 'abc' ; 0x61 0x62 0x63 0x00 \(string\) )]396.4 code0
-[2( dd 0x12345678 ; 0x78 0x56 0x34 0x12 )]385.4 code0
-[2( dd 1.234567e20 ; floating-point constant )]374.4 code0
-[2( dq 0x123456789abcdef0 ; eight byte constant )]363.4 code0
-[2( dq 1.234567e20 ; double-precision float )]352.4 code0
-[2( dt 1.234567e20 ; extended-precision float)]341.4 code2
-[2(DT)0(, )2(DO)0( and )2(DY)0( do not accept )(numeric constants as operands.)]324.4 norm3
-[{/section-3.2.2 xa}2(RESB)0( and Friends: Declaring )(Uninitialized Data)](3.2.2)305.2 subh3
-[2(RESB)0(, )2(RESW)0(, )2(RESD)0(, )2(RESQ)0(, )2(REST)0(, )2(RESO)0( and )2(RESY)0( are designed to be used in the BSS section of a module:)]288.2 norm1
-[(they declare )1(uninitialized)0( storage space. Each takes a single operand, which is the number of bytes, words,)]277.2 norm0
-[(doublewords or whatever to reserve. As stated in ){/section-2.2.7 xl}(section 2.2.7){el}(, NASM does not support the MASM/TASM)]266.2 norm0
-[(syntax of reserving uninitialized space by writing )2(DW ?)0( or similar things: this is what it does instead. The)]255.2 norm0
-[(operand to a )2(RESB)0(\226type pseudo-instruction is a )1(critical expression)0(: see ){/section-3.8 xl}(section 3.8){el}(.)]244.2 norm2
-[(For example:)]227.2 norm3
-[2(buffer: resb 64 ; reserve 64 bytes )]210.2 code1
-[2(wordvar: resw 1 ; reserve a word )]199.2 code0
-[2(realarray resq 10 ; array of ten reals )]188.2 code0
-[2(ymmval: resy 1 ; one YMM register)]177.2 code2
-[{/section-3.2.3 xa}2(INCBIN)0(: Including External )(Binary Files)](3.2.3)158 subh3
-[2(INCBIN)0( is borrowed from the old Amiga assembler )(DevPac: it includes a binary file verbatim into the output)]141 norm1
-[(file. This can be handy for \(for example\) including )(graphics and )(sound data directly into a game executable)]130 norm0
-[(file. It can be called in one of these three ways:)]119 norm2
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-[2( incbin "file.dat" ; include the whole file )]681 code1
-[2( incbin "file.dat",1024 ; skip the first 1024 bytes )]670 code0
-[2( incbin "file.dat",1024,512 ; skip the first 1024, and )]659 code0
-[2( ; actually include at most 512)]648 code2
-[2(INCBIN)0( is both a directive and a standard macro; the standard macro version searches for the file in the)]631 norm1
-[(include file search path and adds the file to the dependency lists. This macro can be overridden if desired.)]620 norm2
-[{/section-3.2.4 xa}2(EQU)0(: Defining Constants)](3.2.4)600.8 subh3
-[2(EQU)0( defines a symbol to a given constant value: when )2(EQU)0( is used, the source line must contain a label. The)]583.8 norm1
-[(action of )2(EQU)0( is to define the given label name to the value of its \(only\) operand. This definition is absolute,)]572.8 norm0
-[(and cannot change later. So, for example,)]561.8 norm2
-[2(message db 'hello, world' )]544.8 code1
-[2(msglen equ $-message)]533.8 code2
-[(defines )2(msglen)0( to be the constant 12. )2(msglen)0( may not then be redefined later. This is not a )(preprocessor)]516.8 norm1
-[(definition either: the value of )2(msglen)0( is evaluated )1(once)0(, using the value of )2($)0( \(see ){/section-3.5 xl}(section 3.5){el}( for an)]505.8 norm0
-[(explanation of )2($)0(\) at the point of definition, rather than being evaluated wherever it is referenced and using the)]494.8 norm0
-[(value of )2($)0( at the point of reference.)]483.8 norm2
-[{/section-3.2.5 xa}2(TIMES)0(: )(Repeating Instructions or Data)](3.2.5)464.6 subh3
-[(The )2(TIMES)0( prefix causes the instruction to be assembled multiple times. This is partly present as NASM's)]447.6 norm1
-[(equivalent of the )2(DUP)0( syntax supported by )(MASM\226compatible assemblers, in that you can code)]436.6 norm2
-[2(zerobuf: times 64 db 0)]419.6 code3
-[(or similar things; but )2(TIMES)0( is more versatile than that. The argument to )2(TIMES)0( is not just a numeric)]402.6 norm1
-[(constant, but a numeric )1(expression)0(, so you can do things like)]391.6 norm2
-[2(buffer: db 'hello, world' )]374.6 code1
-[2( times 64-$+buffer db ' ')]363.6 code2
-[(which will store exactly enough spaces to make the total length of )2(buffer)0( up to 64. Finally, )2(TIMES)0( can be)]346.6 norm1
-[(applied to ordinary instructions, so you can code trivial )(unrolled loops in it:)]335.6 norm2
-[2( times 100 movsb)]318.6 code3
-[(Note that there is no effective difference between )2(times 100 resb 1)0( and )2(resb 100)0(, except that the)]301.6 norm1
-[(latter will be assembled about 100 times faster due to the internal structure of the assembler.)]290.6 norm2
-[(The operand to )2(TIMES)0( is a critical expression \(){/section-3.8 xl}(section 3.8){el}(\).)]273.6 norm3
-[(Note also that )2(TIMES)0( can't be applied to )(macros: the reason for this is that )2(TIMES)0( is processed after the)]256.6 norm1
-[(macro phase, which allows the argument to )2(TIMES)0( to contain expressions such as )2(64-$+buffer)0( as above.)]245.6 norm0
-[(To repeat more than one line of code, or a complex macro, use the preprocessor )2(%rep)0( directive.)]234.6 norm2
-[{/section-3.3 xa}(Effective Addresses)](3.3)213.2 head3
-[(An )(effective address is any operand to an instruction which )(references memory. Effective addresses, in)]196.2 norm1
-[(NASM, have a very simple syntax: they consist of an expression evaluating to the desired address, enclosed in)]185.2 norm0
-[(square brackets. For example:)]174.2 norm2
-[2(wordvar dw 123 )]157.2 code1
-[2( mov ax,[wordvar] )]146.2 code0
-[2( mov ax,[wordvar+1] )]135.2 code0
-[2( mov ax,[es:wordvar+bx])]124.2 code2
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-[(Anything not conforming to this simple system is not a valid memory reference in NASM, for example)]681 norm1
-[2(es:wordvar[bx])0(.)]670 norm2
-[(More complicated effective addresses, such as those involving more than one register, work in exactly the)]653 norm1
-[(same way:)]642 norm2
-[2( mov eax,[ebx*2+ecx+offset] )]625 code1
-[2( mov ax,[bp+di+8])]614 code2
-[(NASM is capable of doing )(algebra on these effective addresses, so that things which don't necessarily )1(look)]597 norm1
-[(legal are perfectly all right:)]586 norm2
-[2( mov eax,[ebx*5] ; assembles as [ebx*4+ebx] )]569 code1
-[2( mov eax,[label1*2-label2] ; ie [label1+\(label1-label2\)])]558 code2
-[(Some forms of effective address have more than one assembled form; in most such cases NASM will generate)]541 norm1
-[(the smallest form it can. For example, there are distinct assembled forms for the 32-bit effective addresses)]530 norm0
-[2([eax*2+0])0( and )2([eax+eax])0(, and NASM will generally generate the latter on the grounds that the former)]519 norm0
-[(requires four bytes to store a zero offset.)]508 norm2
-[(NASM has a hinting mechanism which will cause )2([eax+ebx])0( and )2([ebx+eax])0( to generate different)]491 norm1
-[(opcodes; this is occasionally useful because )2([esi+ebp])0( and )2([ebp+esi])0( have different default segment)]480 norm0
-[(registers.)]469 norm2
-[(However, you can force NASM to generate an effective address in a particular form by the use of the)]452 norm1
-[(keywords )2(BYTE)0(, )2(WORD)0(, )2(DWORD)0( and )2(NOSPLIT)0(. If you need )2([eax+3])0( to be assembled using a double-word)]441 norm0
-[(offset field instead of the one byte NASM will normally generate, you can code )2([dword eax+3])0(.)]430 norm0
-[(Similarly, you can force NASM to use a byte offset for a small value which it hasn't seen on the first pass \(see)]419 norm0
-[{/section-3.8 xl}(section 3.8){el}( for an example of such a code fragment\) by using )2([byte eax+offset])0(. As special cases,)]408 norm0
-[2([byte eax])0( will code )2([eax+0])0( with a byte offset of zero, and )2([dword eax])0( will code it with a)]397 norm0
-[(double-word offset of zero. The normal form, )2([eax])0(, will be coded with no offset field.)]386 norm2
-[(The form described in the previous paragraph is also useful if you are trying to access data in a 32-bit)]369 norm1
-[(segment from within 16 bit code. For more information on this see the section on mixed-size addressing)]358 norm0
-[(\(){/section-10.2 xl}(section 10.2){el}(\). In particular, if you need to access data with a known offset that is larger than will fit in a)]347 norm0
-[(16-bit value, if you don't specify that it is a dword offset, nasm will cause the high word of the offset to be)]336 norm0
-[(lost.)]325 norm2
-[(Similarly, NASM will split )2([eax*2])0( into )2([eax+eax])0( because that allows the offset field to be absent and)]308 norm1
-[(space to be saved; in fact, it will also split )2([eax*2+offset])0( into )2([eax+eax+offset])0(. You can combat)]297 norm0
-[(this behaviour by the use of the )2(NOSPLIT)0( keyword: )2([nosplit eax*2])0( will force )2([eax*2+0])0( to be)]286 norm0
-[(generated literally.)]275 norm2
-[(In 64-bit mode, NASM will by default generate absolute addresses. The )2(REL)0( keyword makes it produce)]258 norm1
-[2(RIP)0(\226relative addresses. Since this is frequently the normally desired behaviour, see the )2(DEFAULT)0( directive)]247 norm0
-[(\(){/section-6.2 xl}(section 6.2){el}(\). The keyword )2(ABS)0( overrides )2(REL)0(.)]236 norm2
-[{/section-3.4 xa}(Constants)](3.4)214.6 head3
-[(NASM understands four different types of constant: numeric, character, string and floating-point.)]197.6 norm3
-[{/section-3.4.1 xa}(Numeric Constants)](3.4.1)178.4 subh3
-[(A numeric constant is simply a number. NASM allows you to specify numbers in a variety of number bases,)]161.4 norm1
-[(in a variety of ways: you can suffix )2(H)0( or )2(X)0(, )2(Q)0( or )2(O)0(, and )2(B)0( for )(hexadecimal, )(octal and )(binary respectively, or)]150.4 norm0
-[(you can prefix )2(0x)0( for hexadecimal in the style of C, or you can prefix )2($)0( for hexadecimal in the style of)]139.4 norm0
-[(Borland Pascal. Note, though, that the )2($)0( prefix does double duty as a prefix on identifiers \(see ){/section-3.1 xl}(section 3.1){el}(\), so)]128.4 norm0
-[(a hex number prefixed with a )2($)0( sign must have a digit after the )2($)0( rather than a letter. In addition, current)]117.4 norm0
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-[(versions of NASM accept the prefix )2(0h)0( for hexadecimal, )2(0o)0( or )2(0q)0( for octal, and )2(0b)0( for binary. Please note)]681 norm0
-[(that unlike C, a )2(0)0( prefix by itself does )1(not)0( imply an octal constant!)]670 norm2
-[(Numeric constants can have underscores \()2(_)0(\) interspersed to break up long strings.)]653 norm3
-[(Some examples \(all producing exactly the same code\):)]636 norm3
-[2( mov ax,200 ; decimal )]619 code1
-[2( mov ax,0200 ; still decimal )]608 code0
-[2( mov ax,0200d ; explicitly decimal )]597 code0
-[2( mov ax,0d200 ; also decimal )]586 code0
-[2( mov ax,0c8h ; hex )]575 code0
-[2( mov ax,$0c8 ; hex again: the 0 is required )]564 code0
-[2( mov ax,0xc8 ; hex yet again )]553 code0
-[2( mov ax,0hc8 ; still hex )]542 code0
-[2( mov ax,310q ; octal )]531 code0
-[2( mov ax,310o ; octal again )]520 code0
-[2( mov ax,0o310 ; octal yet again )]509 code0
-[2( mov ax,0q310 ; hex yet again )]498 code0
-[2( mov ax,11001000b ; binary )]487 code0
-[2( mov ax,1100_1000b ; same binary constant )]476 code0
-[2( mov ax,0b1100_1000 ; same binary constant yet again)]465 code2
-[{/section-3.4.2 xa}(Character Strings)](3.4.2)445.8 subh3
-[(A character string consists of up to eight characters enclosed in either single quotes \()2('...')0(\), double quotes)]428.8 norm1
-[(\()2("...")0(\) or backquotes \()2(`...`)0(\). Single or double quotes are equivalent to NASM \(except of course that)]417.8 norm0
-[(surrounding the constant with single quotes allows double quotes to appear within it and vice versa\); the)]406.8 norm0
-[(contents of those are represented verbatim. Strings enclosed in backquotes support C-style )2(\\)0(\226escapes for)]395.8 norm0
-[(special characters.)]384.8 norm2
-[(The following )(escape sequences are recognized by backquoted strings:)]367.8 norm3
-[2( \\' single quote \('\) )]350.8 code1
-[2( \\" double quote \("\) )]339.8 code0
-[2( \\` backquote \(`\) )]328.8 code0
-[2( \\\\ backslash \(\\\) )]317.8 code0
-[2( \\? question mark \(?\) )]306.8 code0
-[2( \\a BEL \(ASCII 7\) )]295.8 code0
-[2( \\b BS \(ASCII 8\) )]284.8 code0
-[2( \\t TAB \(ASCII 9\) )]273.8 code0
-[2( \\n LF \(ASCII 10\) )]262.8 code0
-[2( \\v VT \(ASCII 11\) )]251.8 code0
-[2( \\f FF \(ASCII 12\) )]240.8 code0
-[2( \\r CR \(ASCII 13\) )]229.8 code0
-[2( \\e ESC \(ASCII 27\) )]218.8 code0
-[2( \\377 Up to 3 octal digits - literal byte )]207.8 code0
-[2( \\xFF Up to 2 hexadecimal digits - literal byte )]196.8 code0
-[2( \\u1234 4 hexadecimal digits - Unicode character )]185.8 code0
-[2( \\U12345678 8 hexadecimal digits - Unicode character)]174.8 code2
-[(All other escape sequences are reserved. Note that )2(\\0)0(, meaning a )2(NUL)0( character \(ASCII 0\), is a special case)]157.8 norm1
-[(of the octal escape sequence.)]146.8 norm2
-[(Unicode characters specified with )2(\\u)0( or )2(\\U)0( are converted to )(UTF-8. For example, the following lines are all)]129.8 norm1
-[(equivalent:)]118.8 norm2
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-[2( db `\\u263a` ; UTF-8 smiley face )]681 code1
-[2( db `\\xe2\\x98\\xba` ; UTF-8 smiley face )]670 code0
-[2( db 0E2h, 098h, 0BAh ; UTF-8 smiley face)]659 code2
-[{/section-3.4.3 xa}(Character Constants)](3.4.3)639.8 subh3
-[(A character constant consists of a string up to eight bytes long, used in an expression context. It is treated as if)]622.8 norm1
-[(it was an integer.)]611.8 norm2
-[(A character constant with more than one byte will be arranged with )(little-endian order in mind: if you code)]594.8 norm3
-[2( mov eax,'abcd')]577.8 code3
-[(then the constant generated is not )2(0x61626364)0(, but )2(0x64636261)0(, so that if you were then to store the)]560.8 norm1
-[(value into memory, it would read )2(abcd)0( rather than )2(dcba)0(. This is also the sense of character constants)]549.8 norm0
-[(understood by the Pentium's )2(CPUID)0( instruction.)]538.8 norm2
-[{/section-3.4.4 xa}(String Constants)](3.4.4)519.6 subh3
-[(String constants are character strings used in the context of some pseudo-instructions, namely the )2(DB)0( family)]502.6 norm1
-[(and )2(INCBIN)0( \(where it represents a filename.\) They are also used in certain preprocessor directives.)]491.6 norm2
-[(A string constant looks like a character constant, only longer. It is treated as a concatenation of)]474.6 norm1
-[(maximum-size character constants for the conditions. So the following are equivalent:)]463.6 norm2
-[2( db 'hello' ; string constant )]446.6 code1
-[2( db 'h','e','l','l','o' ; equivalent character constants)]435.6 code2
-[(And the following are also equivalent:)]418.6 norm3
-[2( dd 'ninechars' ; doubleword string constant )]401.6 code1
-[2( dd 'nine','char','s' ; becomes three doublewords )]390.6 code0
-[2( db 'ninechars',0,0,0 ; and really looks like this)]379.6 code2
-[(Note that when used in a string-supporting context, quoted strings are treated as a string constants even if)]362.6 norm1
-[(they are short enough to be a character constant, because otherwise )2(db 'ab')0( would have the same effect as)]351.6 norm0
-[2(db 'a')0(, which would be silly. Similarly, three-character or four-character constants are treated as strings)]340.6 norm0
-[(when they are operands to )2(DW)0(, and so forth.)]329.6 norm2
-[{/section-3.4.5 xa}(Unicode Strings)](3.4.5)310.4 subh3
-[(The special operators )2(__utf16__)0( and )2(__utf32__)0( allows definition of Unicode strings. They take a string)]293.4 norm1
-[(in UTF-8 format and converts it to \(littleendian\) UTF-16 or UTF-32, respectively.)]282.4 norm2
-[(For example:)]265.4 norm3
-[2(%define u\(x\) __utf16__\(x\) )]248.4 code1
-[2(%define w\(x\) __utf32__\(x\) )]237.4 code0
-[2()]226.4 code0
-[2( dw u\('C:\\WINDOWS'\), 0 ; Pathname in UTF-16 )]215.4 code0
-[2( dd w\(`A + B = \\u206a`\), 0 ; String in UTF-32)]204.4 code2
-[2(__utf16__)0( and )2(__utf32__)0( can be applied either to strings passed to the )2(DB)0( family instructions, or to)]187.4 norm1
-[(character constants in an expression context.)]176.4 norm2
-[{/section-3.4.6 xa}(Floating-Point Constants)](3.4.6)157.2 subh3
-[(Floating-point constants are acceptable only as arguments to )2(DB)0(, )2(DW)0(, )2(DD)0(, )2(DQ)0(, )2(DT)0(, and )2(DO)0(, or as arguments to)]140.2 norm1
-[(the special operators )2(__float8__)0(, )2(__float16__)0(, )2(__float32__)0(, )2(__float64__)0(, )2(__float80m__)0(,)]129.2 norm0
-[2(__float80e__)0(, )2(__float128l__)0(, and )2(__float128h__)0(.)]118.2 norm2
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-[(Floating-point constants are expressed in the traditional form: digits, then a period, then optionally more)]681 norm1
-[(digits, then optionally an )2(E)0( followed by an exponent. The period is mandatory, so that NASM can distinguish)]670 norm0
-[(between )2(dd 1)0(, which declares an integer constant, and )2(dd 1.0)0( which declares a floating-point constant.)]659 norm0
-[(NASM also support C99-style hexadecimal floating-point: )2(0x)0(, hexadecimal digits, period, optionally more)]648 norm0
-[(hexadeximal digits, then optionally a )2(P)0( followed by a )1(binary)0( \(not hexadecimal\) exponent in decimal notation.)]637 norm2
-[(Underscores to break up groups of digits are permitted in floating-point constants as well.)]620 norm3
-[(Some examples:)]603 norm3
-[2( db -0.2 ; "Quarter precision" )]586 code1
-[2( dw -0.5 ; IEEE 754r/SSE5 half precision )]575 code0
-[2( dd 1.2 ; an easy one )]564 code0
-[2( dd 1.222_222_222 ; underscores are permitted )]553 code0
-[2( dd 0x1p+2 ; 1.0x2^2 = 4.0 )]542 code0
-[2( dq 0x1p+32 ; 1.0x2^32 = 4 294 967 296.0 )]531 code0
-[2( dq 1.e10 ; 10 000 000 000.0 )]520 code0
-[2( dq 1.e+10 ; synonymous with 1.e10 )]509 code0
-[2( dq 1.e-10 ; 0.000 000 000 1 )]498 code0
-[2( dt 3.141592653589793238462 ; pi )]487 code0
-[2( do 1.e+4000 ; IEEE 754r quad precision)]476 code2
-[(The 8-bit "quarter-precision" floating-point format is sign:exponent:mantissa = 1:4:3 with an exponent bias)]459 norm1
-[(of 7. This appears to be the most frequently used 8-bit floating-point format, although it is not covered by)]448 norm0
-[(any formal standard. This is sometimes called a ")(minifloat.")]437 norm2
-[(The special operators are used to produce floating-point numbers in other contexts. They produce the binary)]420 norm1
-[(representation of a specific floating-point number as an integer, and can use anywhere integer constants are)]409 norm0
-[(used in an expression. )2(__float80m__)0( and )2(__float80e__)0( produce the 64-bit mantissa and 16-bit)]398 norm0
-[(exponent of an 80-bit floating-point number, and )2(__float128l__)0( and )2(__float128h__)0( produce the)]387 norm0
-[(lower and upper 64-bit halves of a 128-bit floating-point number, respectively.)]376 norm2
-[(For example:)]359 norm3
-[2( mov rax,__float64__\(3.141592653589793238462\))]342 code3
-[(... would assign the binary representation of pi as a 64-bit floating point number into )2(RAX)0(. This is exactly)]325 norm1
-[(equivalent to:)]314 norm2
-[2( mov rax,0x400921fb54442d18)]297 code3
-[(NASM cannot do compile-time arithmetic on floating-point constants. This is because NASM is designed to)]280 norm1
-[(be portable \226 although it always generates code to run on x86 processors, the assembler itself can run on any)]269 norm0
-[(system with an ANSI C compiler. Therefore, the assembler cannot guarantee the presence of a floating-point)]258 norm0
-[(unit capable of handling the )(Intel number formats, and so for NASM to be able to do floating arithmetic it)]247 norm0
-[(would have to include its own complete set of floating-point routines, which would significantly increase the)]236 norm0
-[(size of the assembler for very little benefit.)]225 norm2
-[(The special tokens )2(__Infinity__)0(, )2(__QNaN__)0( \(or )2(__NaN__)0(\) and )2(__SNaN__)0( can be used to generate)]208 norm1
-[(infinities, quiet )(NaNs, and signalling NaNs, respectively. These are normally used as macros:)]197 norm2
-[2(%define Inf __Infinity__ )]180 code1
-[2(%define NaN __QNaN__ )]169 code0
-[2()]158 code0
-[2( dq +1.5, -Inf, NaN ; Double-precision constants)]147 code2
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-[{/section-3.4.7 xa}(Packed BCD Constants)](3.4.7)678.8 subh3
-[(x87-style packed BCD constants can be used in the same contexts as 80-bit floating-point numbers. They)]661.8 norm1
-[(are suffixed with )2(p)0( or prefixed with )2(0p)0(, and can include up to 18 decimal digits.)]650.8 norm2
-[(As with other numeric constants, underscores can be used to separate digits.)]633.8 norm3
-[(For example:)]616.8 norm3
-[2( dt 12_345_678_901_245_678p )]599.8 code1
-[2( dt -12_345_678_901_245_678p )]588.8 code0
-[2( dt +0p33 )]577.8 code0
-[2( dt 33p)]566.8 code2
-[{/section-3.5 xa}(Expressions)](3.5)545.4 head3
-[(Expressions in NASM are similar in syntax to those in C. Expressions are evaluated as 64-bit integers which)]528.4 norm1
-[(are then adjusted to the appropriate size.)]517.4 norm2
-[(NASM supports two special tokens in expressions, allowing calculations to involve the current assembly)]500.4 norm1
-[(position: the )2($)0( and )2($$)0( tokens. )2($)0( evaluates to the assembly position at the beginning of the line containing the)]489.4 norm0
-[(expression; so you can code an )(infinite loop using )2(JMP $)0(. )2($$)0( evaluates to the beginning of the current)]478.4 norm0
-[(section; so you can tell how far into the section you are by using )2(\($-$$\))0(.)]467.4 norm2
-[(The arithmetic )(operators provided by NASM are listed here, in increasing order of )(precedence.)]450.4 norm3
-[{/section-3.5.1 xa}2(|)0(: )(Bitwise OR Operator)](3.5.1)431.2 subh3
-[(The )2(|)0( operator gives a bitwise OR, exactly as performed by the )2(OR)0( machine instruction. Bitwise OR is the)]414.2 norm1
-[(lowest-priority arithmetic operator supported by NASM.)]403.2 norm2
-[{/section-3.5.2 xa}2(^)0(: )(Bitwise XOR Operator)](3.5.2)384 subh3
-[2(^)0( provides the bitwise XOR operation.)]367 norm3
-[{/section-3.5.3 xa}2(&)0(: )(Bitwise AND Operator)](3.5.3)347.8 subh3
-[2(&)0( provides the bitwise AND operation.)]330.8 norm3
-[{/section-3.5.4 xa}2(<<)0( and )2(>>)0(: )(Bit Shift Operators)](3.5.4)311.6 subh3
-[2(<<)0( gives a bit-shift to the left, just as it does in C. So )2(5<<3)0( evaluates to 5 times 8, or 40. )2(>>)0( gives a bit-shift)]294.6 norm1
-[(to the right; in NASM, such a shift is )1(always)0( unsigned, so that the bits shifted in from the left-hand end are)]283.6 norm0
-[(filled with zero rather than a sign-extension of the previous highest bit.)]272.6 norm2
-[{/section-3.5.5 xa}2(+)0( and )2(-)0(: )(Addition and )(Subtraction Operators)](3.5.5)253.4 subh3
-[(The )2(+)0( and )2(-)0( operators do perfectly ordinary addition and subtraction.)]236.4 norm3
-[{/section-3.5.6 xa}2(*)0(, )2(/)0(, )2(//)0(, )2(%)0( and )2(%%)0(: )(Multiplication and )(Division)](3.5.6)217.2 subh3
-[2(*)0( is the multiplication operator. )2(/)0( and )2(//)0( are both division operators: )2(/)0( is )(unsigned division and )2(//)0( is )(signed)]200.2 norm1
-[(division. Similarly, )2(%)0( and )2(%%)0( provide )(unsigned and )(signed modulo operators respectively.)]189.2 norm2
-[(NASM, like ANSI C, provides no guarantees about the sensible operation of the signed modulo operator.)]172.2 norm3
-[(Since the )2(%)0( character is used extensively by the macro )(preprocessor, you should ensure that both the signed)]155.2 norm1
-[(and unsigned modulo operators are followed by white space wherever they appear.)]144.2 norm2
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-[{/section-3.5.7 xa}(Unary Operators: )2(+)0(, )2(-)0(, )2(~)0(, )2(!)0( and )2(SEG)](3.5.7)678.8 subh3
-[(The highest-priority operators in NASM's expression grammar are those which only apply to one argument.)]661.8 norm1
-[2(-)0( negates its operand, )2(+)0( does nothing \(it's provided for symmetry with )2(-)0(\), )2(~)0( computes the )(one's complement)]650.8 norm0
-[(of its operand, )2(!)0( is the )(logical negation operator, and )2(SEG)0( provides the )(segment address of its operand)]639.8 norm0
-[(\(explained in more detail in ){/section-3.6 xl}(section 3.6){el}(\).)]628.8 norm2
-[{/section-3.6 xa}2(SEG)0( and )2(WRT)](3.6)607.4 head3
-[(When writing large 16-bit programs, which must be split into multiple )(segments, it is often necessary to be)]590.4 norm1
-[(able to refer to the )(segment part of the address of a symbol. NASM supports the )2(SEG)0( operator to perform this)]579.4 norm0
-[(function.)]568.4 norm2
-[(The )2(SEG)0( operator returns the )1(preferred)0( segment base of a symbol, defined as the segment base relative to)]551.4 norm1
-[(which the offset of the symbol makes sense. So the code)]540.4 norm2
-[2( mov ax,seg symbol )]523.4 code1
-[2( mov es,ax )]512.4 code0
-[2( mov bx,symbol)]501.4 code2
-[(will load )2(ES:BX)0( with a valid pointer to the symbol )2(symbol)0(.)]484.4 norm3
-[(Things can be more complex than this: since 16-bit segments and )(groups may )(overlap, you might)]467.4 norm1
-[(occasionally want to refer to some symbol using a different segment base from the preferred one. NASM lets)]456.4 norm0
-[(you do this, by the use of the )2(WRT)0( \(With Reference To\) keyword. So you can do things like)]445.4 norm2
-[2( mov ax,weird_seg ; weird_seg is a segment base )]428.4 code1
-[2( mov es,ax )]417.4 code0
-[2( mov bx,symbol wrt weird_seg)]406.4 code2
-[(to load )2(ES:BX)0( with a different, but functionally equivalent, pointer to the symbol )2(symbol)0(.)]389.4 norm3
-[(NASM supports far \(inter-segment\) calls and jumps by means of the syntax )2(call segment:offset)0(,)]372.4 norm1
-[(where )2(segment)0( and )2(offset)0( both represent immediate values. So to call a far procedure, you could code)]361.4 norm0
-[(either of)]350.4 norm2
-[2( call \(seg procedure\):procedure )]333.4 code1
-[2( call weird_seg:\(procedure wrt weird_seg\))]322.4 code2
-[(\(The parentheses are included for clarity, to show the intended parsing of the above instructions. They are not)]305.4 norm1
-[(necessary in practice.\))]294.4 norm2
-[(NASM supports the syntax )2(call far procedure)0( as a synonym for the first of the above usages. )2(JMP)]277.4 norm1
-[(works identically to )2(CALL)0( in these examples.)]266.4 norm2
-[(To declare a )(far pointer to a data item in a data segment, you must code)]249.4 norm3
-[2( dw symbol, seg symbol)]232.4 code3
-[(NASM supports no convenient synonym for this, though you can always invent one using the macro)]215.4 norm1
-[(processor.)]204.4 norm2
-[{/section-3.7 xa}2(STRICT)0(: Inhibiting Optimization)](3.7)183 head3
-[(When assembling with the optimizer set to level 2 or higher \(see ){/section-2.1.22 xl}(section 2.1.22){el}(\), NASM will use size)]166 norm1
-[(specifiers \()2(BYTE)0(, )2(WORD)0(, )2(DWORD)0(, )2(QWORD)0(, )2(TWORD)0(, )2(OWORD)0( or )2(YWORD)0(\), but will give them the smallest)]155 norm0
-[(possible size. The keyword )2(STRICT)0( can be used to inhibit optimization and force a particular operand to be)]144 norm0
-[(emitted in the specified size. For example, with the optimizer on, and in )2(BITS 16)0( mode,)]133 norm2
-[2( push dword 33)]116 code3
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-[(is encoded in three bytes )2(66 6A 21)0(, whereas)]681 norm3
-[2( push strict dword 33)]664 code3
-[(is encoded in six bytes, with a full dword immediate operand )2(66 68 21 00 00 00)0(.)]647 norm3
-[(With the optimizer off, the same code \(six bytes\) is generated whether the )2(STRICT)0( keyword was used or not.)]630 norm3
-[{/section-3.8 xa}(Critical Expressions)](3.8)608.6 head3
-[(Although NASM has an optional multi-pass optimizer, there are some expressions which must be resolvable)]591.6 norm1
-[(on the first pass. These are called )1(Critical Expressions)0(.)]580.6 norm2
-[(The first pass is used to determine the size of all the assembled code and data, so that the second pass, when)]563.6 norm1
-[(generating all the code, knows all the symbol addresses the code refers to. So one thing NASM can't handle is)]552.6 norm0
-[(code whose size depends on the value of a symbol declared after the code in question. For example,)]541.6 norm2
-[2( times \(label-$\) db 0 )]524.6 code1
-[2(label: db 'Where am I?')]513.6 code2
-[(The argument to )2(TIMES)0( in this case could equally legally evaluate to anything at all; NASM will reject this)]496.6 norm1
-[(example because it cannot tell the size of the )2(TIMES)0( line when it first sees it. It will just as firmly reject the)]485.6 norm0
-[(slightly )(paradoxical code)]474.6 norm2
-[2( times \(label-$+1\) db 0 )]457.6 code1
-[2(label: db 'NOW where am I?')]446.6 code2
-[(in which )1(any)0( value for the )2(TIMES)0( argument is by definition wrong!)]429.6 norm3
-[(NASM rejects these examples by means of a concept called a )1(critical expression)0(, which is defined to be an)]412.6 norm1
-[(expression whose value is required to be computable in the first pass, and which must therefore depend only)]401.6 norm0
-[(on symbols defined before it. The argument to the )2(TIMES)0( prefix is a critical expression.)]390.6 norm2
-[{/section-3.9 xa}(Local Labels)](3.9)369.2 head3
-[(NASM gives special treatment to symbols beginning with a )(period. A label beginning with a single period is)]352.2 norm1
-[(treated as a )1(local)0( label, which means that it is associated with the previous non-local label. So, for example:)]341.2 norm2
-[2(label1 ; some code )]324.2 code1
-[2()]313.2 code0
-[2(.loop )]302.2 code0
-[2( ; some more code )]291.2 code0
-[2()]280.2 code0
-[2( jne .loop )]269.2 code0
-[2( ret )]258.2 code0
-[2()]247.2 code0
-[2(label2 ; some code )]236.2 code0
-[2()]225.2 code0
-[2(.loop )]214.2 code0
-[2( ; some more code )]203.2 code0
-[2()]192.2 code0
-[2( jne .loop )]181.2 code0
-[2( ret)]170.2 code2
-[(In the above code fragment, each )2(JNE)0( instruction jumps to the line immediately before it, because the two)]153.2 norm1
-[(definitions of )2(.loop)0( are kept separate by virtue of each being associated with the previous non-local label.)]142.2 norm2
-[(This form of local label handling is borrowed from the old Amiga assembler )(DevPac; however, NASM goes)]125.2 norm1
-[(one step further, in allowing access to local labels from other parts of the code. This is achieved by means of)]114.2 norm0
-[1(defining)0( a local label in terms of the previous non-local label: the first definition of )2(.loop)0( above is really)]103.2 norm0
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-[(defining a symbol called )2(label1.loop)0(, and the second defines a symbol called )2(label2.loop)0(. So, if you)]681 norm0
-[(really needed to, you could write)]670 norm2
-[2(label3 ; some more code )]653 code1
-[2( ; and some more )]642 code0
-[2()]631 code0
-[2( jmp label1.loop)]620 code2
-[(Sometimes it is useful \226 in a macro, for instance \226 to be able to define a label which can be referenced from)]603 norm1
-[(anywhere but which doesn't interfere with the normal local-label mechanism. Such a label can't be non-local)]592 norm0
-[(because it would interfere with subsequent definitions of, and references to, local labels; and it can't be local)]581 norm0
-[(because the macro that defined it wouldn't know the label's full name. NASM therefore introduces a third)]570 norm0
-[(type of label, which is probably only useful in macro definitions: if a label begins with the )(special prefix )2(..@)0(,)]559 norm0
-[(then it does nothing to the local label mechanism. So you could code)]548 norm2
-[2(label1: ; a non-local label )]531 code1
-[2(.local: ; this is really label1.local )]520 code0
-[2(..@foo: ; this is a special symbol )]509 code0
-[2(label2: ; another non-local label )]498 code0
-[2(.local: ; this is really label2.local )]487 code0
-[2()]476 code0
-[2( jmp ..@foo ; this will jump three lines up)]465 code2
-[(NASM has the capacity to define other special symbols beginning with a double period: for example,)]448 norm1
-[2(..start)0( is used to specify the entry point in the )2(obj)0( output format \(see ){/section-7.4.6 xl}(section 7.4.6){el}(\).)]437 norm2
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-[{/chapter-4 xa}(Chapter 4: The NASM )(Preprocessor)]642.8 chap3
-[(NASM contains a powerful )(macro processor, which supports conditional assembly, multi-level file inclusion,)]607.8 norm1
-[(two forms of macro \(single-line and multi-line\), and a `context stack' mechanism for extra macro power.)]596.8 norm0
-[(Preprocessor directives all begin with a )2(%)0( sign.)]585.8 norm2
-[(The preprocessor collapses all lines which end with a backslash \(\\\) character into a single line. Thus:)]568.8 norm3
-[2(%define THIS_VERY_LONG_MACRO_NAME_IS_DEFINED_TO \\ )]551.8 code1
-[2( THIS_VALUE)]540.8 code2
-[(will work like a single-line macro without the backslash-newline sequence.)]523.8 norm3
-[{/section-4.1 xa}(Single-Line Macros)](4.1)502.4 head3
-[{/section-4.1.1 xa}(The Normal Way: )2(%define)](4.1.1)483.2 subh3
-[(Single-line macros are defined using the )2(%define)0( preprocessor directive. The definitions work in a similar)]466.2 norm1
-[(way to C; so you can do things like)]455.2 norm2
-[2(%define ctrl 0x1F & )]438.2 code1
-[2(%define param\(a,b\) \(\(a\)+\(a\)*\(b\)\) )]427.2 code0
-[2()]416.2 code0
-[2( mov byte [param\(2,ebx\)], ctrl 'D')]405.2 code2
-[(which will expand to)]388.2 norm3
-[2( mov byte [\(2\)+\(2\)*\(ebx\)], 0x1F & 'D')]371.2 code3
-[(When the expansion of a single-line macro contains tokens which invoke another macro, the expansion is)]354.2 norm1
-[(performed at invocation time, not at definition time. Thus the code)]343.2 norm2
-[2(%define a\(x\) 1+b\(x\) )]326.2 code1
-[2(%define b\(x\) 2*x )]315.2 code0
-[2()]304.2 code0
-[2( mov ax,a\(8\))]293.2 code2
-[(will evaluate in the expected way to )2(mov ax,1+2*8)0(, even though the macro )2(b)0( wasn't defined at the time of)]276.2 norm1
-[(definition of )2(a)0(.)]265.2 norm2
-[(Macros defined with )2(%define)0( are )(case sensitive: after )2(%define foo bar)0(, only )2(foo)0( will expand to )2(bar)0(:)]248.2 norm1
-[2(Foo)0( or )2(FOO)0( will not. By using )2(%idefine)0( instead of )2(%define)0( \(the `i' stands for `insensitive'\) you can)]237.2 norm0
-[(define all the case variants of a macro at once, so that )2(%idefine foo bar)0( would cause )2(foo)0(, )2(Foo)0(, )2(FOO)0(,)]226.2 norm0
-[2(fOO)0( and so on all to expand to )2(bar)0(.)]215.2 norm2
-[(There is a mechanism which detects when a macro call has occurred as a result of a previous expansion of the)]198.2 norm1
-[(same macro, to guard against )(circular references and infinite loops. If this happens, the preprocessor will only)]187.2 norm0
-[(expand the first occurrence of the macro. Hence, if you code)]176.2 norm2
-[2(%define a\(x\) 1+a\(x\) )]159.2 code1
-[2()]148.2 code0
-[2( mov ax,a\(3\))]137.2 code2
-[(the macro )2(a\(3\))0( will expand once, becoming )2(1+a\(3\))0(, and will then expand no further. This behaviour can)]120.2 norm1
-[(be useful: see ){/section-9.1 xl}(section 9.1){el}( for an example of its use.)]109.2 norm2
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-[(You can )(overload single-line macros: if you write)]681 norm3
-[2(%define foo\(x\) 1+x )]664 code1
-[2(%define foo\(x,y\) 1+x*y)]653 code2
-[(the preprocessor will be able to handle both types of macro call, by counting the parameters you pass; so)]636 norm1
-[2(foo\(3\))0( will become )2(1+3)0( whereas )2(foo\(ebx,2\))0( will become )2(1+ebx*2)0(. However, if you define)]625 norm2
-[2(%define foo bar)]608 code3
-[(then no other definition of )2(foo)0( will be accepted: a macro with no parameters prohibits the definition of the)]591 norm1
-[(same name as a macro )1(with)0( parameters, and vice versa.)]580 norm2
-[(This doesn't prevent single-line macros being )1(redefined)0(: you can perfectly well define a macro with)]563 norm3
-[2(%define foo bar)]546 code3
-[(and then re-define it later in the same source file with)]529 norm3
-[2(%define foo baz)]512 code3
-[(Then everywhere the macro )2(foo)0( is invoked, it will be expanded according to the most recent definition. This)]495 norm1
-[(is particularly useful when defining single-line macros with )2(%assign)0( \(see ){/section-4.1.7 xl}(section 4.1.7){el}(\).)]484 norm2
-[(You can )(pre-define single-line macros using the `-d' option on the NASM command line: see ){/section-2.1.18 xl}(section 2.1.18){el}(.)]467 norm3
-[{/section-4.1.2 xa}(Resolving )2(%define)0(: )2(%xdefine)](4.1.2)447.8 subh3
-[(To have a reference to an embedded single-line macro resolved at the time that the embedding macro is)]430.8 norm1
-[1(defined)0(, as opposed to when the embedding macro is )1(expanded)0(, you need a different mechanism to the one)]419.8 norm0
-[(offered by )2(%define)0(. The solution is to use )2(%xdefine)0(, or it's )(case-insensitive counterpart )2(%ixdefine)0(.)]408.8 norm2
-[(Suppose you have the following code:)]391.8 norm3
-[2(%define isTrue 1 )]374.8 code1
-[2(%define isFalse isTrue )]363.8 code0
-[2(%define isTrue 0 )]352.8 code0
-[2()]341.8 code0
-[2(val1: db isFalse )]330.8 code0
-[2()]319.8 code0
-[2(%define isTrue 1 )]308.8 code0
-[2()]297.8 code0
-[2(val2: db isFalse)]286.8 code2
-[(In this case, )2(val1)0( is equal to 0, and )2(val2)0( is equal to 1. This is because, when a single-line macro is defined)]269.8 norm1
-[(using )2(%define)0(, it is expanded only when it is called. As )2(isFalse)0( expands to )2(isTrue)0(, the expansion will)]258.8 norm0
-[(be the current value of )2(isTrue)0(. The first time it is called that is 0, and the second time it is 1.)]247.8 norm2
-[(If you wanted )2(isFalse)0( to expand to the value assigned to the embedded macro )2(isTrue)0( at the time that)]230.8 norm1
-[2(isFalse)0( was defined, you need to change the above code to use )2(%xdefine)0(.)]219.8 norm2
-[2(%xdefine isTrue 1 )]202.8 code1
-[2(%xdefine isFalse isTrue )]191.8 code0
-[2(%xdefine isTrue 0 )]180.8 code0
-[2()]169.8 code0
-[2(val1: db isFalse )]158.8 code0
-[2()]147.8 code0
-[2(%xdefine isTrue 1 )]136.8 code0
-[2()]125.8 code0
-[2(val2: db isFalse)]114.8 code2
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-[(Now, each time that )2(isFalse)0( is called, it expands to 1, as that is what the embedded macro )2(isTrue)]681 norm1
-[(expanded to at the time that )2(isFalse)0( was defined.)]670 norm2
-[{/section-4.1.3 xa}(Macro Indirection: )2(%[...])](4.1.3)650.8 subh3
-[(The )2(%[...])0( construct can be used to expand macros in contexts where macro expansion would otherwise)]633.8 norm1
-[(not occur, including in the names other macros. For example, if you have a set of macros named )2(Foo16)0(,)]622.8 norm0
-[2(Foo32)0( and )2(Foo64)0(, you could write:)]611.8 norm2
-[2( mov ax,Foo%[__BITS__] ; The Foo value)]594.8 code3
-[(to use the builtin macro )2(__BITS__)0( \(see ){/section-4.11.5 xl}(section 4.11.5){el}(\) to automatically select between them. Similarly, the)]577.8 norm1
-[(two statements:)]566.8 norm2
-[2(%xdefine Bar Quux ; Expands due to %xdefine )]549.8 code1
-[2(%define Bar %[Quux] ; Expands due to %[...])]538.8 code2
-[(have, in fact, exactly the same effect.)]521.8 norm3
-[2(%[...])0( concatenates to adjacent tokens in the same way that multi-line macro parameters do, see ){/section-4.3.8 xl}(section){el}]504.8 norm1
-[{/section-4.3.8 xl}(4.3.8){el}( for details.)]493.8 norm2
-[{/section-4.1.4 xa}(Concatenating Single Line Macro Tokens: )2(%+)](4.1.4)474.6 subh3
-[(Individual tokens in single line macros can be concatenated, to produce longer tokens for later processing.)]457.6 norm1
-[(This can be useful if there are several similar macros that perform similar functions.)]446.6 norm2
-[(Please note that a space is required after )2(%+)0(, in order to disambiguate it from the syntax )2(%+1)0( used in multiline)]429.6 norm1
-[(macros.)]418.6 norm2
-[(As an example, consider the following:)]401.6 norm3
-[2(%define BDASTART 400h ; Start of BIOS data area)]384.6 code3
-[2(struc tBIOSDA ; its structure )]367.6 code1
-[2( .COM1addr RESW 1 )]356.6 code0
-[2( .COM2addr RESW 1 )]345.6 code0
-[2( ; ..and so on )]334.6 code0
-[2(endstruc)]323.6 code2
-[(Now, if we need to access the elements of tBIOSDA in different places, we can end up with:)]306.6 norm3
-[2( mov ax,BDASTART + tBIOSDA.COM1addr )]289.6 code1
-[2( mov bx,BDASTART + tBIOSDA.COM2addr)]278.6 code2
-[(This will become pretty ugly \(and tedious\) if used in many places, and can be reduced in size significantly by)]261.6 norm1
-[(using the following macro:)]250.6 norm2
-[2(; Macro to access BIOS variables by their names \(from tBDA\):)]233.6 code3
-[2(%define BDA\(x\) BDASTART + tBIOSDA. %+ x)]216.6 code3
-[(Now the above code can be written as:)]199.6 norm3
-[2( mov ax,BDA\(COM1addr\) )]182.6 code1
-[2( mov bx,BDA\(COM2addr\))]171.6 code2
-[(Using this feature, we can simplify references to a lot of macros \(and, in turn, reduce typing errors\).)]154.6 norm3
-[{/section-4.1.5 xa}(The Macro Name Itself: )2(%?)0( and )2(%??)](4.1.5)135.4 subh3
-[(The special symbols )2(%?)0( and )2(%??)0( can be used to reference the macro name itself inside a macro expansion,)]118.4 norm1
-[(this is supported for both single-and multi-line macros. )2(%?)0( refers to the macro name as )1(invoked)0(, whereas)]107.4 norm0
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-[2(%??)0( refers to the macro name as )1(declared)0(. The two are always the same for case-sensitive macros, but for)]681 norm0
-[(case-insensitive macros, they can differ.)]670 norm2
-[(For example:)]653 norm3
-[2(%idefine Foo mov %?,%?? )]636 code1
-[2()]625 code0
-[2( foo )]614 code0
-[2( FOO)]603 code2
-[(will expand to:)]586 norm3
-[2( mov foo,Foo )]569 code1
-[2( mov FOO,Foo)]558 code2
-[(The sequence:)]541 norm3
-[2(%idefine keyword $%?)]524 code3
-[(can be used to make a keyword "disappear", for example in case a new instruction has been used as a label in)]507 norm1
-[(older code. For example:)]496 norm2
-[2(%idefine pause $%? ; Hide the PAUSE instruction)]479 code3
-[{/section-4.1.6 xa}(Undefining Single-Line Macros: )2(%undef)](4.1.6)459.8 subh3
-[(Single-line macros can be removed with the )2(%undef)0( directive. For example, the following sequence:)]442.8 norm3
-[2(%define foo bar )]425.8 code1
-[2(%undef foo )]414.8 code0
-[2()]403.8 code0
-[2( mov eax, foo)]392.8 code2
-[(will expand to the instruction )2(mov eax, foo)0(, since after )2(%undef)0( the macro )2(foo)0( is no longer defined.)]375.8 norm3
-[(Macros that would otherwise be pre-defined can be undefined on the command-line using the `-u' option on)]358.8 norm1
-[(the NASM command line: see ){/section-2.1.19 xl}(section 2.1.19){el}(.)]347.8 norm2
-[{/section-4.1.7 xa}(Preprocessor Variables: )2(%assign)](4.1.7)328.6 subh3
-[(An alternative way to define single-line macros is by means of the )2(%assign)0( command \(and its)]311.6 norm1
-[(case-insensitive counterpart )2(%iassign)0(, which differs from )2(%assign)0( in exactly the same way that)]300.6 norm0
-[2(%idefine)0( differs from )2(%define)0(\).)]289.6 norm2
-[2(%assign)0( is used to define single-line macros which take no parameters and have a numeric value. This)]272.6 norm1
-[(value can be specified in the form of an expression, and it will be evaluated once, when the )2(%assign)]261.6 norm0
-[(directive is processed.)]250.6 norm2
-[(Like )2(%define)0(, macros defined using )2(%assign)0( can be re-defined later, so you can do things like)]233.6 norm3
-[2(%assign i i+1)]216.6 code3
-[(to increment the numeric value of a macro.)]199.6 norm3
-[2(%assign)0( is useful for controlling the termination of )2(%rep)0( preprocessor loops: see ){/section-4.5 xl}(section 4.5){el}( for an)]182.6 norm1
-[(example of this. Another use for )2(%assign)0( is given in ){/section-8.4 xl}(section 8.4){el}( and ){/section-9.1 xl}(section 9.1){el}(.)]171.6 norm2
-[(The expression passed to )2(%assign)0( is a )(critical expression \(see ){/section-3.8 xl}(section 3.8){el}(\), and must also evaluate to a pure)]154.6 norm1
-[(number \(rather than a relocatable reference such as a code or data address, or anything involving a register\).)]143.6 norm2
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-[{/section-4.1.8 xa}(Defining Strings: )2(%defstr)](4.1.8)678.8 subh3
-[2(%defstr)0(, and its case-insensitive counterpart )2(%idefstr)0(, define or redefine a single-line macro without)]661.8 norm1
-[(parameters but converts the entire right-hand side, after macro expansion, to a quoted string before definition.)]650.8 norm2
-[(For example:)]633.8 norm3
-[2(%defstr test TEST)]616.8 code3
-[(is equivalent to)]599.8 norm3
-[2(%define test 'TEST')]582.8 code3
-[(This can be used, for example, with the )2(%!)0( construct \(see ){/section-4.10.2 xl}(section 4.10.2){el}(\):)]565.8 norm3
-[2(%defstr PATH %!PATH ; The operating system PATH variable)]548.8 code3
-[{/section-4.1.9 xa}(Defining Tokens: )2(%deftok)](4.1.9)529.6 subh3
-[2(%deftok)0(, and its case-insensitive counterpart )2(%ideftok)0(, define or redefine a single-line macro without)]512.6 norm1
-[(parameters but converts the second parameter, after string conversion, to a sequence of tokens.)]501.6 norm2
-[(For example:)]484.6 norm3
-[2(%deftok test 'TEST')]467.6 code3
-[(is equivalent to)]450.6 norm3
-[2(%define test TEST)]433.6 code3
-[{/section-4.2 xa}(String Manipulation in Macros)](4.2)412.2 head3
-[(It's often useful to be able to handle strings in macros. NASM supports a few simple string handling macro)]395.2 norm1
-[(operators from which more complex operations can be constructed.)]384.2 norm2
-[(All the string operators define or redefine a value \(either a string or a numeric value\) to a single-line macro.)]367.2 norm1
-[(When producing a string value, it may change the style of quoting of the input string or strings, and possibly)]356.2 norm0
-[(use )2(\\)0(\226escapes inside )2(`)0(\226quoted strings.)]345.2 norm2
-[{/section-4.2.1 xa}(Concatenating Strings: )2(%strcat)](4.2.1)326 subh3
-[(The )2(%strcat)0( operator concatenates quoted strings and assign them to a single-line macro.)]309 norm3
-[(For example:)]292 norm3
-[2(%strcat alpha "Alpha: ", '12" screen')]275 code3
-[(... would assign the value )2('Alpha: 12" screen')0( to )2(alpha)0(. Similarly:)]258 norm3
-[2(%strcat beta '"foo"\\', "'bar'")]241 code3
-[(... would assign the value )2(`"foo"\\\\'bar'`)0( to )2(beta)0(.)]224 norm3
-[(The use of commas to separate strings is permitted but optional.)]207 norm3
-[{/section-4.2.2 xa}(String Length: )2(%strlen)](4.2.2)187.8 subh3
-[(The )2(%strlen)0( operator assigns the length of a string to a macro. For example:)]170.8 norm3
-[2(%strlen charcnt 'my string')]153.8 code3
-[(In this example, )2(charcnt)0( would receive the value 9, just as if an )2(%assign)0( had been used. In this example,)]136.8 norm1
-[2('my string')0( was a literal string but it could also have been a single-line macro that expands to a string, as)]125.8 norm0
-[(in the following example:)]114.8 norm2
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-[2(%define sometext 'my string' )]681 code1
-[2(%strlen charcnt sometext)]670 code2
-[(As in the first case, this would result in )2(charcnt)0( being assigned the value of 9.)]653 norm3
-[{/section-4.2.3 xa}(Extracting Substrings: )2(%substr)](4.2.3)633.8 subh3
-[(Individual letters or substrings in strings can be extracted using the )2(%substr)0( operator. An example of its use)]616.8 norm1
-[(is probably more useful than the description:)]605.8 norm2
-[2(%substr mychar 'xyzw' 1 ; equivalent to %define mychar 'x' )]588.8 code1
-[2(%substr mychar 'xyzw' 2 ; equivalent to %define mychar 'y' )]577.8 code0
-[2(%substr mychar 'xyzw' 3 ; equivalent to %define mychar 'z' )]566.8 code0
-[2(%substr mychar 'xyzw' 2,2 ; equivalent to %define mychar 'yz' )]555.8 code0
-[2(%substr mychar 'xyzw' 2,-1 ; equivalent to %define mychar 'yzw' )]544.8 code0
-[2(%substr mychar 'xyzw' 2,-2 ; equivalent to %define mychar 'yz')]533.8 code2
-[(As with )2(%strlen)0( \(see ){/section-4.2.2 xl}(section 4.2.2){el}(\), the first parameter is the single-line macro to be created and the)]516.8 norm1
-[(second is the string. The third parameter specifies the first character to be selected, and the optional fourth)]505.8 norm0
-[(parameter preceeded by comma\) is the length. Note that the first index is 1, not 0 and the last index is equal to)]494.8 norm0
-[(the value that )2(%strlen)0( would assign given the same string. Index values out of range result in an empty)]483.8 norm0
-[(string. A negative length means "until N-1 characters before the end of string", i.e. )2(-1)0( means until end of)]472.8 norm0
-[(string, )2(-2)0( until one character before, etc.)]461.8 norm2
-[{/section-4.3 xa}(Multi-Line Macros: )2(%macro)](4.3)440.4 head3
-[(Multi-line macros are much more like the type of macro seen in MASM and TASM: a multi-line macro)]423.4 norm1
-[(definition in NASM looks something like this.)]412.4 norm2
-[2(%macro prologue 1 )]395.4 code1
-[2()]384.4 code0
-[2( push ebp )]373.4 code0
-[2( mov ebp,esp )]362.4 code0
-[2( sub esp,%1 )]351.4 code0
-[2()]340.4 code0
-[2(%endmacro)]329.4 code2
-[(This defines a C-like function prologue as a macro: so you would invoke the macro with a call such as)]312.4 norm3
-[2(myfunc: prologue 12)]295.4 code3
-[(which would expand to the three lines of code)]278.4 norm3
-[2(myfunc: push ebp )]261.4 code1
-[2( mov ebp,esp )]250.4 code0
-[2( sub esp,12)]239.4 code2
-[(The number )2(1)0( after the macro name in the )2(%macro)0( line defines the number of parameters the macro)]222.4 norm1
-[2(prologue)0( expects to receive. The use of )2(%1)0( inside the macro definition refers to the first parameter to the)]211.4 norm0
-[(macro call. With a macro taking more than one parameter, subsequent parameters would be referred to as )2(%2)0(,)]200.4 norm0
-[2(%3)0( and so on.)]189.4 norm2
-[(Multi-line macros, like single-line macros, are )(case-sensitive, unless you define them using the alternative)]172.4 norm1
-[(directive )2(%imacro)0(.)]161.4 norm2
-[(If you need to pass a comma as )1(part)0( of a parameter to a multi-line macro, you can do that by enclosing the)]144.4 norm1
-[(entire parameter in )(braces. So you could code things like)]133.4 norm2
-[2(%macro silly 2 )]116.4 code1
-[2()]105.4 code0
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-[2( %2: db %1 )]681 code0
-[2()]670 code0
-[2(%endmacro )]659 code0
-[2()]648 code0
-[2( silly 'a', letter_a ; letter_a: db 'a' )]637 code0
-[2( silly 'ab', string_ab ; string_ab: db 'ab' )]626 code0
-[2( silly {13,10}, crlf ; crlf: db 13,10)]615 code2
-[{/section-4.3.1 xa}(Recursive Multi-Line Macros: )2(%rmacro)](4.3.1)595.8 subh3
-[(A multi-line macro cannot be referenced within itself, in order to prevent accidental infinite recursion.)]578.8 norm3
-[(Recursive multi-line macros allow for self-referencing, with the caveat that the user is aware of the)]561.8 norm1
-[(existence, use and purpose of recursive multi-line macros. There is also a generous, but sane, upper limit to)]550.8 norm0
-[(the number of recursions, in order to prevent run-away memory consumption in case of accidental infinite)]539.8 norm0
-[(recursion.)]528.8 norm2
-[(As with non-recursive multi-line macros, recursive multi-line macros are )(case-sensitive, unless you define)]511.8 norm1
-[(them using the alternative directive )2(%irmacro)0(.)]500.8 norm2
-[{/section-4.3.2 xa}(Overloading Multi-Line Macros)](4.3.2)481.6 subh3
-[(As with single-line macros, multi-line macros can be overloaded by defining the same macro name several)]464.6 norm1
-[(times with different numbers of parameters. This time, no exception is made for macros with no parameters at)]453.6 norm0
-[(all. So you could define)]442.6 norm2
-[2(%macro prologue 0 )]425.6 code1
-[2()]414.6 code0
-[2( push ebp )]403.6 code0
-[2( mov ebp,esp )]392.6 code0
-[2()]381.6 code0
-[2(%endmacro)]370.6 code2
-[(to define an alternative form of the function prologue which allocates no local stack space.)]353.6 norm3
-[(Sometimes, however, you might want to `overload' a machine instruction; for example, you might want to)]336.6 norm1
-[(define)]325.6 norm2
-[2(%macro push 2 )]308.6 code1
-[2()]297.6 code0
-[2( push %1 )]286.6 code0
-[2( push %2 )]275.6 code0
-[2()]264.6 code0
-[2(%endmacro)]253.6 code2
-[(so that you could code)]236.6 norm3
-[2( push ebx ; this line is not a macro call )]219.6 code1
-[2( push eax,ecx ; but this one is)]208.6 code2
-[(Ordinarily, NASM will give a warning for the first of the above two lines, since )2(push)0( is now defined to be a)]191.6 norm1
-[(macro, and is being invoked with a number of parameters for which no definition has been given. The correct)]180.6 norm0
-[(code will still be generated, but the assembler will give a warning. This warning can be disabled by the use of)]169.6 norm0
-[(the )2(-w-macro-params)0( command-line option \(see ){/section-2.1.24 xl}(section 2.1.24){el}(\).)]158.6 norm2
-[{/section-4.3.3 xa}(Macro-Local Labels)](4.3.3)139.4 subh3
-[(NASM allows you to define labels within a multi-line macro definition in such a way as to make them local)]122.4 norm1
-[(to the macro call: so calling the same macro multiple times will use a different label each time. You do this by)]111.4 norm0
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-[(prefixing )2(%%)0( to the label name. So you can invent an instruction which executes a )2(RET)0( if the )2(Z)0( flag is set by)]681 norm0
-[(doing this:)]670 norm2
-[2(%macro retz 0 )]653 code1
-[2()]642 code0
-[2( jnz %%skip )]631 code0
-[2( ret )]620 code0
-[2( %%skip: )]609 code0
-[2()]598 code0
-[2(%endmacro)]587 code2
-[(You can call this macro as many times as you want, and every time you call it NASM will make up a different)]570 norm1
-[(`real' name to substitute for the label )2(%%skip)0(. The names NASM invents are of the form )2(..@2345.skip)0(,)]559 norm0
-[(where the number 2345 changes with every macro call. The )2(..@)0( prefix prevents macro-local labels from)]548 norm0
-[(interfering with the local label mechanism, as described in ){/section-3.9 xl}(section 3.9){el}(. You should avoid defining your own)]537 norm0
-[(labels in this form \(the )2(..@)0( prefix, then a number, then another period\) in case they interfere with)]526 norm0
-[(macro-local labels.)]515 norm2
-[{/section-4.3.4 xa}(Greedy Macro Parameters)](4.3.4)495.8 subh3
-[(Occasionally it is useful to define a macro which lumps its entire command line into one parameter definition,)]478.8 norm1
-[(possibly after extracting one or two smaller parameters from the front. An example might be a macro to write)]467.8 norm0
-[(a text string to a file in MS-DOS, where you might want to be able to write)]456.8 norm2
-[2( writefile [filehandle],"hello, world",13,10)]439.8 code3
-[(NASM allows you to define the last parameter of a macro to be )1(greedy)0(, meaning that if you invoke the macro)]422.8 norm1
-[(with more parameters than it expects, all the spare parameters get lumped into the last defined one along with)]411.8 norm0
-[(the separating commas. So if you code:)]400.8 norm2
-[2(%macro writefile 2+ )]383.8 code1
-[2()]372.8 code0
-[2( jmp %%endstr )]361.8 code0
-[2( %%str: db %2 )]350.8 code0
-[2( %%endstr: )]339.8 code0
-[2( mov dx,%%str )]328.8 code0
-[2( mov cx,%%endstr-%%str )]317.8 code0
-[2( mov bx,%1 )]306.8 code0
-[2( mov ah,0x40 )]295.8 code0
-[2( int 0x21 )]284.8 code0
-[2()]273.8 code0
-[2(%endmacro)]262.8 code2
-[(then the example call to )2(writefile)0( above will work as expected: the text before the first comma,)]245.8 norm1
-[2([filehandle])0(, is used as the first macro parameter and expanded when )2(%1)0( is referred to, and all the)]234.8 norm0
-[(subsequent text is lumped into )2(%2)0( and placed after the )2(db)0(.)]223.8 norm2
-[(The greedy nature of the macro is indicated to NASM by the use of the )2(+)0( sign after the parameter count on the)]206.8 norm1
-[2(%macro)0( line.)]195.8 norm2
-[(If you define a greedy macro, you are effectively telling NASM how it should expand the macro given )1(any)]178.8 norm1
-[(number of parameters from the actual number specified up to infinity; in this case, for example, NASM now)]167.8 norm0
-[(knows what to do when it sees a call to )2(writefile)0( with 2, 3, 4 or more parameters. NASM will take this)]156.8 norm0
-[(into account when overloading macros, and will not allow you to define another form of )2(writefile)0( taking)]145.8 norm0
-[(4 parameters \(for example\).)]134.8 norm2
-[(Of course, the above macro could have been implemented as a non-greedy macro, in which case the call to it)]117.8 norm1
-[(would have had to look like)]106.8 norm2
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-[2( writefile [filehandle], {"hello, world",13,10})]681 code3
-[(NASM provides both mechanisms for putting )(commas in macro parameters, and you choose which one you)]664 norm1
-[(prefer for each macro definition.)]653 norm2
-[(See ){/section-6.3.1 xl}(section 6.3.1){el}( for a better way to write the above macro.)]636 norm3
-[{/section-4.3.5 xa}(Default Macro Parameters)](4.3.5)616.8 subh3
-[(NASM also allows you to define a multi-line macro with a )1(range)0( of allowable parameter counts. If you do)]599.8 norm1
-[(this, you can specify defaults for )(omitted parameters. So, for example:)]588.8 norm2
-[2(%macro die 0-1 "Painful program death has occurred." )]571.8 code1
-[2()]560.8 code0
-[2( writefile 2,%1 )]549.8 code0
-[2( mov ax,0x4c01 )]538.8 code0
-[2( int 0x21 )]527.8 code0
-[2()]516.8 code0
-[2(%endmacro)]505.8 code2
-[(This macro \(which makes use of the )2(writefile)0( macro defined in ){/section-4.3.4 xl}(section 4.3.4){el}(\) can be called with an)]488.8 norm1
-[(explicit error message, which it will display on the error output stream before exiting, or it can be called with)]477.8 norm0
-[(no parameters, in which case it will use the default error message supplied in the macro definition.)]466.8 norm2
-[(In general, you supply a minimum and maximum number of parameters for a macro of this type; the)]449.8 norm1
-[(minimum number of parameters are then required in the macro call, and then you provide defaults for the)]438.8 norm0
-[(optional ones. So if a macro definition began with the line)]427.8 norm2
-[2(%macro foobar 1-3 eax,[ebx+2])]410.8 code3
-[(then it could be called with between one and three parameters, and )2(%1)0( would always be taken from the macro)]393.8 norm1
-[(call. )2(%2)0(, if not specified by the macro call, would default to )2(eax)0(, and )2(%3)0( if not specified would default to)]382.8 norm0
-[2([ebx+2])0(.)]371.8 norm2
-[(You can provide extra information to a macro by providing too many default parameters:)]354.8 norm3
-[2(%macro quux 1 something)]337.8 code3
-[(This will trigger a warning by default; see ){/section-2.1.24 xl}(section 2.1.24){el}( for more information. When )2(quux)0( is invoked, it)]320.8 norm1
-[(receives not one but two parameters. )2(something)0( can be referred to as )2(%2)0(. The difference between passing)]309.8 norm0
-[2(something)0( this way and writing )2(something)0( in the macro body is that with this way )2(something)0( is)]298.8 norm0
-[(evaluated when the macro is defined, not when it is expanded.)]287.8 norm2
-[(You may omit parameter defaults from the macro definition, in which case the parameter default is taken to be)]270.8 norm1
-[(blank. This can be useful for macros which can take a variable number of parameters, since the )2(%0)0( token \(see)]259.8 norm0
-[{/section-4.3.6 xl}(section 4.3.6){el}(\) allows you to determine how many parameters were really passed to the macro call.)]248.8 norm2
-[(This defaulting mechanism can be combined with the greedy-parameter mechanism; so the )2(die)0( macro above)]231.8 norm1
-[(could be made more powerful, and more useful, by changing the first line of the definition to)]220.8 norm2
-[2(%macro die 0-1+ "Painful program death has occurred.",13,10)]203.8 code3
-[(The maximum parameter count can be infinite, denoted by )2(*)0(. In this case, of course, it is impossible to)]186.8 norm1
-[(provide a )1(full)0( set of default parameters. Examples of this usage are shown in ){/section-4.3.7 xl}(section 4.3.7){el}(.)]175.8 norm2
-[{/section-4.3.6 xa}2(%0)0(: )(Macro Parameter Counter)](4.3.6)156.6 subh3
-[(The parameter reference )2(%0)0( will return a numeric constant giving the number of parameters received, that is,)]139.6 norm1
-[(if )2(%0)0( is n then )2(%)0(n is the last parameter. )2(%0)0( is mostly useful for macros that can take a variable number of)]128.6 norm0
-[(parameters. It can be used as an argument to )2(%rep)0( \(see ){/section-4.5 xl}(section 4.5){el}(\) in order to iterate through all the)]117.6 norm0
-[(parameters of a macro. Examples are given in ){/section-4.3.7 xl}(section 4.3.7){el}(.)]106.6 norm2
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-[{/section-4.3.7 xa}2(%rotate)0(: )(Rotating Macro Parameters)](4.3.7)678.8 subh3
-[(Unix shell programmers will be familiar with the )2(shift)0( shell command, which allows the arguments passed)]661.8 norm1
-[(to a shell script \(referenced as )2($1)0(, )2($2)0( and so on\) to be moved left by one place, so that the argument)]650.8 norm0
-[(previously referenced as )2($2)0( becomes available as )2($1)0(, and the argument previously referenced as )2($1)0( is no)]639.8 norm0
-[(longer available at all.)]628.8 norm2
-[(NASM provides a similar mechanism, in the form of )2(%rotate)0(. As its name suggests, it differs from the)]611.8 norm1
-[(Unix )2(shift)0( in that no parameters are lost: parameters rotated off the left end of the argument list reappear on)]600.8 norm0
-[(the right, and vice versa.)]589.8 norm2
-[2(%rotate)0( is invoked with a single numeric argument \(which may be an expression\). The macro parameters)]572.8 norm1
-[(are rotated to the left by that many places. If the argument to )2(%rotate)0( is negative, the macro parameters are)]561.8 norm0
-[(rotated to the right.)]550.8 norm2
-[(So a pair of macros to save and restore a set of registers might work as follows:)]533.8 norm3
-[2(%macro multipush 1-* )]516.8 code1
-[2()]505.8 code0
-[2( %rep %0 )]494.8 code0
-[2( push %1 )]483.8 code0
-[2( %rotate 1 )]472.8 code0
-[2( %endrep )]461.8 code0
-[2()]450.8 code0
-[2(%endmacro)]439.8 code2
-[(This macro invokes the )2(PUSH)0( instruction on each of its arguments in turn, from left to right. It begins by)]422.8 norm1
-[(pushing its first argument, )2(%1)0(, then invokes )2(%rotate)0( to move all the arguments one place to the left, so that)]411.8 norm0
-[(the original second argument is now available as )2(%1)0(. Repeating this procedure as many times as there were)]400.8 norm0
-[(arguments \(achieved by supplying )2(%0)0( as the argument to )2(%rep)0(\) causes each argument in turn to be pushed.)]389.8 norm2
-[(Note also the use of )2(*)0( as the maximum parameter count, indicating that there is no upper limit on the number)]372.8 norm1
-[(of parameters you may supply to the )2(multipush)0( macro.)]361.8 norm2
-[(It would be convenient, when using this macro, to have a )2(POP)0( equivalent, which )1(didn't)0( require the arguments)]344.8 norm1
-[(to be given in reverse order. Ideally, you would write the )2(multipush)0( macro call, then cut-and-paste the)]333.8 norm0
-[(line to where the pop needed to be done, and change the name of the called macro to )2(multipop)0(, and the)]322.8 norm0
-[(macro would take care of popping the registers in the opposite order from the one in which they were pushed.)]311.8 norm2
-[(This can be done by the following definition:)]294.8 norm3
-[2(%macro multipop 1-* )]277.8 code1
-[2()]266.8 code0
-[2( %rep %0 )]255.8 code0
-[2( %rotate -1 )]244.8 code0
-[2( pop %1 )]233.8 code0
-[2( %endrep )]222.8 code0
-[2()]211.8 code0
-[2(%endmacro)]200.8 code2
-[(This macro begins by rotating its arguments one place to the )1(right)0(, so that the original )1(last)0( argument appears)]183.8 norm1
-[(as )2(%1)0(. This is then popped, and the arguments are rotated right again, so the second-to-last argument)]172.8 norm0
-[(becomes )2(%1)0(. Thus the arguments are iterated through in reverse order.)]161.8 norm2
-[{/section-4.3.8 xa}(Concatenating Macro Parameters)](4.3.8)142.6 subh3
-[(NASM can concatenate macro parameters and macro indirection constructs on to other text surrounding them.)]125.6 norm1
-[(This allows you to declare a family of symbols, for example, in a macro definition. If, for example, you)]114.6 norm0
-[(wanted to generate a table of key codes along with offsets into the table, you could code something like)]103.6 norm2
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-[2(%macro keytab_entry 2 )]681 code1
-[2()]670 code0
-[2( keypos%1 equ $-keytab )]659 code0
-[2( db %2 )]648 code0
-[2()]637 code0
-[2(%endmacro )]626 code0
-[2()]615 code0
-[2(keytab: )]604 code0
-[2( keytab_entry F1,128+1 )]593 code0
-[2( keytab_entry F2,128+2 )]582 code0
-[2( keytab_entry Return,13)]571 code2
-[(which would expand to)]554 norm3
-[2(keytab: )]537 code1
-[2(keyposF1 equ $-keytab )]526 code0
-[2( db 128+1 )]515 code0
-[2(keyposF2 equ $-keytab )]504 code0
-[2( db 128+2 )]493 code0
-[2(keyposReturn equ $-keytab )]482 code0
-[2( db 13)]471 code2
-[(You can just as easily concatenate text on to the other end of a macro parameter, by writing )2(%1foo)0(.)]454 norm3
-[(If you need to append a )1(digit)0( to a macro parameter, for example defining labels )2(foo1)0( and )2(foo2)0( when passed)]437 norm1
-[(the parameter )2(foo)0(, you can't code )2(%11)0( because that would be taken as the eleventh macro parameter.)]426 norm0
-[(Instead, you must code )2(%{1}1)0(, which will separate the first )2(1)0( \(giving the number of the macro parameter\))]415 norm0
-[(from the second \(literal text to be concatenated to the parameter\).)]404 norm2
-[(This concatenation can also be applied to other preprocessor in-line objects, such as macro-local labels)]387 norm1
-[(\(){/section-4.3.3 xl}(section 4.3.3){el}(\) and context-local labels \(){/section-4.7.2 xl}(section 4.7.2){el}(\). In all cases, ambiguities in syntax can be resolved by)]376 norm0
-[(enclosing everything after the )2(%)0( sign and before the literal text in braces: so )2(%{%foo}bar)0( concatenates the)]365 norm0
-[(text )2(bar)0( to the end of the real name of the macro-local label )2(%%foo)0(. \(This is unnecessary, since the form)]354 norm0
-[(NASM uses for the real names of macro-local labels means that the two usages )2(%{%foo}bar)0( and)]343 norm0
-[2(%%foobar)0( would both expand to the same thing anyway; nevertheless, the capability is there.\))]332 norm2
-[(The single-line macro indirection construct, )2(%[...])0( \(){/section-4.1.3 xl}(section 4.1.3){el}(\), behaves the same way as macro)]315 norm1
-[(parameters for the purpose of concatenation.)]304 norm2
-[(See also the )2(%+)0( operator, ){/section-4.1.4 xl}(section 4.1.4){el}(.)]287 norm3
-[{/section-4.3.9 xa}(Condition Codes as Macro Parameters)](4.3.9)267.8 subh3
-[(NASM can give special treatment to a macro parameter which contains a condition code. For a start, you can)]250.8 norm1
-[(refer to the macro parameter )2(%1)0( by means of the alternative syntax )2(%+1)0(, which informs NASM that this)]239.8 norm0
-[(macro parameter is supposed to contain a condition code, and will cause the preprocessor to report an error)]228.8 norm0
-[(message if the macro is called with a parameter which is )1(not)0( a valid condition code.)]217.8 norm2
-[(Far more usefully, though, you can refer to the macro parameter by means of )2(%-1)0(, which NASM will expand)]200.8 norm1
-[(as the )1(inverse)0( condition code. So the )2(retz)0( macro defined in ){/section-4.3.3 xl}(section 4.3.3){el}( can be replaced by a general)]189.8 norm0
-[(conditional-return macro like this:)]178.8 norm2
-[2(%macro retc 1 )]161.8 code1
-[2()]150.8 code0
-[2( j%-1 %%skip )]139.8 code0
-[2( ret )]128.8 code0
-[2( %%skip: )]117.8 code0
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-[2()]681 code0
-[2(%endmacro)]670 code2
-[(This macro can now be invoked using calls like )2(retc ne)0(, which will cause the conditional-jump instruction)]653 norm1
-[(in the macro expansion to come out as )2(JE)0(, or )2(retc po)0( which will make the jump a )2(JPE)0(.)]642 norm2
-[(The )2(%+1)0( macro-parameter reference is quite happy to interpret the arguments )2(CXZ)0( and )2(ECXZ)0( as valid)]625 norm1
-[(condition codes; however, )2(%-1)0( will report an error if passed either of these, because no inverse condition)]614 norm0
-[(code exists.)]603 norm2
-[{/section-4.3.10 xa}(Disabling Listing Expansion)](4.3.10)583.8 subh3
-[(When NASM is generating a listing file from your program, it will generally expand multi-line macros by)]566.8 norm1
-[(means of writing the macro call and then listing each line of the expansion. This allows you to see which)]555.8 norm0
-[(instructions in the macro expansion are generating what code; however, for some macros this clutters the)]544.8 norm0
-[(listing up unnecessarily.)]533.8 norm2
-[(NASM therefore provides the )2(.nolist)0( qualifier, which you can include in a macro definition to inhibit the)]516.8 norm1
-[(expansion of the macro in the listing file. The )2(.nolist)0( qualifier comes directly after the number of)]505.8 norm0
-[(parameters, like this:)]494.8 norm2
-[2(%macro foo 1.nolist)]477.8 code3
-[(Or like this:)]460.8 norm3
-[2(%macro bar 1-5+.nolist a,b,c,d,e,f,g,h)]443.8 code3
-[{/section-4.3.11 xa}(Undefining Multi-Line Macros: )2(%unmacro)](4.3.11)424.6 subh3
-[(Multi-line macros can be removed with the )2(%unmacro)0( directive. Unlike the )2(%undef)0( directive, however,)]407.6 norm1
-[2(%unmacro)0( takes an argument specification, and will only remove )(exact matches with that argument)]396.6 norm0
-[(specification.)]385.6 norm2
-[(For example:)]368.6 norm3
-[2(%macro foo 1-3 )]351.6 code1
-[2( ; Do something )]340.6 code0
-[2(%endmacro )]329.6 code0
-[2(%unmacro foo 1-3)]318.6 code2
-[(removes the previously defined macro )2(foo)0(, but)]301.6 norm3
-[2(%macro bar 1-3 )]284.6 code1
-[2( ; Do something )]273.6 code0
-[2(%endmacro )]262.6 code0
-[2(%unmacro bar 1)]251.6 code2
-[(does )1(not)0( remove the macro )2(bar)0(, since the argument specification does not match exactly.)]234.6 norm3
-[{/section-4.3.12 xa}(Exiting Multi-Line Macros: )2(%exitmacro)](4.3.12)215.4 subh3
-[(Multi-line macro expansions can be arbitrarily terminated with the )2(%exitmacro)0( directive.)]198.4 norm3
-[(For example:)]181.4 norm3
-[2(%macro foo 1-3 )]164.4 code1
-[2( ; Do something )]153.4 code0
-[2( %if<condition> )]142.4 code0
-[2( %exitmacro )]131.4 code0
-[2( %endif )]120.4 code0
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-[2( ; Do something )]681 code0
-[2(%endmacro)]670 code2
-[{/section-4.4 xa}(Conditional Assembly)](4.4)648.6 head3
-[(Similarly to the C preprocessor, NASM allows sections of a source file to be assembled only if certain)]631.6 norm1
-[(conditions are met. The general syntax of this feature looks like this:)]620.6 norm2
-[2(%if<condition> )]603.6 code1
-[2( ; some code which only appears if <condition> is met )]592.6 code0
-[2(%elif<condition2> )]581.6 code0
-[2( ; only appears if <condition> is not met but <condition2> is )]570.6 code0
-[2(%else )]559.6 code0
-[2( ; this appears if neither <condition> nor <condition2> was met )]548.6 code0
-[2(%endif)]537.6 code2
-[(The inverse forms )2(%ifn)0( and )2(%elifn)0( are also supported.)]520.6 norm3
-[(The )2(%else)0( clause is optional, as is the )2(%elif)0( clause. You can have more than one )2(%elif)0( clause as well.)]503.6 norm3
-[(There are a number of variants of the )2(%if)0( directive. Each has its corresponding )2(%elif)0(, )2(%ifn)0(, and )2(%elifn)]486.6 norm1
-[(directives; for example, the equivalents to the )2(%ifdef)0( directive are )2(%elifdef)0(, )2(%ifndef)0(, and)]475.6 norm0
-[2(%elifndef)0(.)]464.6 norm2
-[{/section-4.4.1 xa}2(%ifdef)0(: Testing Single-Line Macro Existence)](4.4.1)445.4 subh3
-[(Beginning a conditional-assembly block with the line )2(%ifdef MACRO)0( will assemble the subsequent code if,)]428.4 norm1
-[(and only if, a single-line macro called )2(MACRO)0( is defined. If not, then the )2(%elif)0( and )2(%else)0( blocks \(if any\))]417.4 norm0
-[(will be processed instead.)]406.4 norm2
-[(For example, when debugging a program, you might want to write code such as)]389.4 norm3
-[2( ; perform some function )]372.4 code1
-[2(%ifdef DEBUG )]361.4 code0
-[2( writefile 2,"Function performed successfully",13,10 )]350.4 code0
-[2(%endif )]339.4 code0
-[2( ; go and do something else)]328.4 code2
-[(Then you could use the command-line option )2(-dDEBUG)0( to create a version of the program which produced)]311.4 norm1
-[(debugging messages, and remove the option to generate the final release version of the program.)]300.4 norm2
-[(You can test for a macro )1(not)0( being defined by using )2(%ifndef)0( instead of )2(%ifdef)0(. You can also test for)]283.4 norm1
-[(macro definitions in )2(%elif)0( blocks by using )2(%elifdef)0( and )2(%elifndef)0(.)]272.4 norm2
-[{/section-4.4.2 xa}2(%ifmacro)0(: Testing Multi-Line Macro Existence)](4.4.2)253.2 subh3
-[(The )2(%ifmacro)0( directive operates in the same way as the )2(%ifdef)0( directive, except that it checks for the)]236.2 norm1
-[(existence of a multi-line macro.)]225.2 norm2
-[(For example, you may be working with a large project and not have control over the macros in a library. You)]208.2 norm1
-[(may want to create a macro with one name if it doesn't already exist, and another name if one with that name)]197.2 norm0
-[(does exist.)]186.2 norm2
-[(The )2(%ifmacro)0( is considered true if defining a macro with the given name and number of arguments would)]169.2 norm1
-[(cause a definitions conflict. For example:)]158.2 norm2
-[2(%ifmacro MyMacro 1-3 )]141.2 code1
-[2()]130.2 code0
-[2( %error "MyMacro 1-3" causes a conflict with an existing macro. )]119.2 code0
-[2()]108.2 code0
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-[2(%else )]681 code0
-[2()]670 code0
-[2( %macro MyMacro 1-3 )]659 code0
-[2()]648 code0
-[2( ; insert code to define the macro )]637 code0
-[2()]626 code0
-[2( %endmacro )]615 code0
-[2()]604 code0
-[2(%endif)]593 code2
-[(This will create the macro "MyMacro 1-3" if no macro already exists which would conflict with it, and emits)]576 norm1
-[(a warning if there would be a definition conflict.)]565 norm2
-[(You can test for the macro not existing by using the )2(%ifnmacro)0( instead of )2(%ifmacro)0(. Additional tests can)]548 norm1
-[(be performed in )2(%elif)0( blocks by using )2(%elifmacro)0( and )2(%elifnmacro)0(.)]537 norm2
-[{/section-4.4.3 xa}2(%ifctx)0(: Testing the Context Stack)](4.4.3)517.8 subh3
-[(The conditional-assembly construct )2(%ifctx)0( will cause the subsequent code to be assembled if and only if)]500.8 norm1
-[(the top context on the preprocessor's context stack has the same name as one of the arguments. As with)]489.8 norm0
-[2(%ifdef)0(, the inverse and )2(%elif)0( forms )2(%ifnctx)0(, )2(%elifctx)0( and )2(%elifnctx)0( are also supported.)]478.8 norm2
-[(For more details of the context stack, see ){/section-4.7 xl}(section 4.7){el}(. For a sample use of )2(%ifctx)0(, see ){/section-4.7.5 xl}(section 4.7.5){el}(.)]461.8 norm3
-[{/section-4.4.4 xa}2(%if)0(: Testing Arbitrary Numeric Expressions)](4.4.4)442.6 subh3
-[(The conditional-assembly construct )2(%if expr)0( will cause the subsequent code to be assembled if and only if)]425.6 norm1
-[(the value of the numeric expression )2(expr)0( is non-zero. An example of the use of this feature is in deciding)]414.6 norm0
-[(when to break out of a )2(%rep)0( preprocessor loop: see ){/section-4.5 xl}(section 4.5){el}( for a detailed example.)]403.6 norm2
-[(The expression given to )2(%if)0(, and its counterpart )2(%elif)0(, is a critical expression \(see ){/section-3.8 xl}(section 3.8){el}(\).)]386.6 norm3
-[2(%if)0( extends the normal NASM expression syntax, by providing a set of )(relational operators which are not)]369.6 norm1
-[(normally available in expressions. The operators )2(=)0(, )2(<)0(, )2(>)0(, )2(<=)0(, )2(>=)0( and )2(<>)0( test equality, less-than, greater-than,)]358.6 norm0
-[(less-or-equal, greater-or-equal and not-equal respectively. The C-like forms )2(==)0( and )2(!=)0( are supported as)]347.6 norm0
-[(alternative forms of )2(=)0( and )2(<>)0(. In addition, low-priority logical operators )2(&&)0(, )2(^^)0( and )2(||)0( are provided,)]336.6 norm0
-[(supplying )(logical AND, )(logical XOR and )(logical OR. These work like the C logical operators \(although C has)]325.6 norm0
-[(no logical XOR\), in that they always return either 0 or 1, and treat any non-zero input as 1 \(so that )2(^^)0(, for)]314.6 norm0
-[(example, returns 1 if exactly one of its inputs is zero, and 0 otherwise\). The relational operators also return 1)]303.6 norm0
-[(for true and 0 for false.)]292.6 norm2
-[(Like other )2(%if)0( constructs, )2(%if)0( has a counterpart )2(%elif)0(, and negative forms )2(%ifn)0( and )2(%elifn)0(.)]275.6 norm3
-[{/section-4.4.5 xa}2(%ifidn)0( and )2(%ifidni)0(: Testing Exact Text Identity)](4.4.5)256.4 subh3
-[(The construct )2(%ifidn text1,text2)0( will cause the subsequent code to be assembled if and only if)]239.4 norm1
-[2(text1)0( and )2(text2)0(, after expanding single-line macros, are identical pieces of text. Differences in white)]228.4 norm0
-[(space are not counted.)]217.4 norm2
-[2(%ifidni)0( is similar to )2(%ifidn)0(, but is )(case-insensitive.)]200.4 norm3
-[(For example, the following macro pushes a register or number on the stack, and allows you to treat )2(IP)0( as a)]183.4 norm1
-[(real register:)]172.4 norm2
-[2(%macro pushparam 1 )]155.4 code1
-[2()]144.4 code0
-[2( %ifidni %1,ip )]133.4 code0
-[2( call %%label )]122.4 code0
-[2( %%label: )]111.4 code0
-[2( %else )]100.4 code0
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-[2( push %1 )]681 code0
-[2( %endif )]670 code0
-[2()]659 code0
-[2(%endmacro)]648 code2
-[(Like other )2(%if)0( constructs, )2(%ifidn)0( has a counterpart )2(%elifidn)0(, and negative forms )2(%ifnidn)0( and)]631 norm1
-[2(%elifnidn)0(. Similarly, )2(%ifidni)0( has counterparts )2(%elifidni)0(, )2(%ifnidni)0( and )2(%elifnidni)0(.)]620 norm2
-[{/section-4.4.6 xa}2(%ifid)0(, )2(%ifnum)0(, )2(%ifstr)0(: Testing Token Types)](4.4.6)600.8 subh3
-[(Some macros will want to perform different tasks depending on whether they are passed a number, a string, or)]583.8 norm1
-[(an identifier. For example, a string output macro might want to be able to cope with being passed either a)]572.8 norm0
-[(string constant or a pointer to an existing string.)]561.8 norm2
-[(The conditional assembly construct )2(%ifid)0(, taking one parameter \(which may be blank\), assembles the)]544.8 norm1
-[(subsequent code if and only if the first token in the parameter exists and is an identifier. )2(%ifnum)0( works)]533.8 norm0
-[(similarly, but tests for the token being a numeric constant; )2(%ifstr)0( tests for it being a string.)]522.8 norm2
-[(For example, the )2(writefile)0( macro defined in ){/section-4.3.4 xl}(section 4.3.4){el}( can be extended to take advantage of )2(%ifstr)]505.8 norm1
-[(in the following fashion:)]494.8 norm2
-[2(%macro writefile 2-3+ )]477.8 code1
-[2()]466.8 code0
-[2( %ifstr %2 )]455.8 code0
-[2( jmp %%endstr )]444.8 code0
-[2( %if %0 = 3 )]433.8 code0
-[2( %%str: db %2,%3 )]422.8 code0
-[2( %else )]411.8 code0
-[2( %%str: db %2 )]400.8 code0
-[2( %endif )]389.8 code0
-[2( %%endstr: mov dx,%%str )]378.8 code0
-[2( mov cx,%%endstr-%%str )]367.8 code0
-[2( %else )]356.8 code0
-[2( mov dx,%2 )]345.8 code0
-[2( mov cx,%3 )]334.8 code0
-[2( %endif )]323.8 code0
-[2( mov bx,%1 )]312.8 code0
-[2( mov ah,0x40 )]301.8 code0
-[2( int 0x21 )]290.8 code0
-[2()]279.8 code0
-[2(%endmacro)]268.8 code2
-[(Then the )2(writefile)0( macro can cope with being called in either of the following two ways:)]251.8 norm3
-[2( writefile [file], strpointer, length )]234.8 code1
-[2( writefile [file], "hello", 13, 10)]223.8 code2
-[(In the first, )2(strpointer)0( is used as the address of an already-declared string, and )2(length)0( is used as its)]206.8 norm1
-[(length; in the second, a string is given to the macro, which therefore declares it itself and works out the)]195.8 norm0
-[(address and length for itself.)]184.8 norm2
-[(Note the use of )2(%if)0( inside the )2(%ifstr)0(: this is to detect whether the macro was passed two arguments \(so the)]167.8 norm1
-[(string would be a single string constant, and )2(db %2)0( would be adequate\) or more \(in which case, all but the)]156.8 norm0
-[(first two would be lumped together into )2(%3)0(, and )2(db %2,%3)0( would be required\).)]145.8 norm2
-[(The usual )2(%elif)0(..., )2(%ifn)0(..., and )2(%elifn)0(... versions exist for each of )2(%ifid)0(, )2(%ifnum)0( and )2(%ifstr)0(.)]128.8 norm3
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-[{/section-4.4.7 xa}2(%iftoken)0(: Test for a Single Token)](4.4.7)678.8 subh3
-[(Some macros will want to do different things depending on if it is passed a single token \(e.g. paste it to)]661.8 norm1
-[(something else using )2(%+)0(\) versus a multi-token sequence.)]650.8 norm2
-[(The conditional assembly construct )2(%iftoken)0( assembles the subsequent code if and only if the expanded)]633.8 norm1
-[(parameters consist of exactly one token, possibly surrounded by whitespace.)]622.8 norm2
-[(For example:)]605.8 norm3
-[2(%iftoken 1)]588.8 code3
-[(will assemble the subsequent code, but)]571.8 norm3
-[2(%iftoken -1)]554.8 code3
-[(will not, since )2(-1)0( contains two tokens: the unary minus operator )2(-)0(, and the number )2(1)0(.)]537.8 norm3
-[(The usual )2(%eliftoken)0(, )2(%ifntoken)0(, and )2(%elifntoken)0( variants are also provided.)]520.8 norm3
-[{/section-4.4.8 xa}2(%ifempty)0(: Test for Empty Expansion)](4.4.8)501.6 subh3
-[(The conditional assembly construct )2(%ifempty)0( assembles the subsequent code if and only if the expanded)]484.6 norm1
-[(parameters do not contain any tokens at all, whitespace excepted.)]473.6 norm2
-[(The usual )2(%elifempty)0(, )2(%ifnempty)0(, and )2(%elifnempty)0( variants are also provided.)]456.6 norm3
-[{/section-4.5 xa}(Preprocessor Loops)(: )2(%rep)](4.5)435.2 head3
-[(NASM's )2(TIMES)0( prefix, though useful, cannot be used to invoke a multi-line macro multiple times, because)]418.2 norm1
-[(it is processed by NASM after macros have already been expanded. Therefore NASM provides another form)]407.2 norm0
-[(of loop, this time at the preprocessor level: )2(%rep)0(.)]396.2 norm2
-[(The directives )2(%rep)0( and )2(%endrep)0( \()2(%rep)0( takes a numeric argument, which can be an expression; )2(%endrep)]379.2 norm1
-[(takes no arguments\) can be used to enclose a chunk of code, which is then replicated as many times as)]368.2 norm0
-[(specified by the preprocessor:)]357.2 norm2
-[2(%assign i 0 )]340.2 code1
-[2(%rep 64 )]329.2 code0
-[2( inc word [table+2*i] )]318.2 code0
-[2(%assign i i+1 )]307.2 code0
-[2(%endrep)]296.2 code2
-[(This will generate a sequence of 64 )2(INC)0( instructions, incrementing every word of memory from )2([table])0( to)]279.2 norm1
-[2([table+126])0(.)]268.2 norm2
-[(For more complex termination conditions, or to break out of a repeat loop part way along, you can use the)]251.2 norm1
-[2(%exitrep)0( directive to terminate the loop, like this:)]240.2 norm2
-[2(fibonacci: )]223.2 code1
-[2(%assign i 0 )]212.2 code0
-[2(%assign j 1 )]201.2 code0
-[2(%rep 100 )]190.2 code0
-[2(%if j > 65535 )]179.2 code0
-[2( %exitrep )]168.2 code0
-[2(%endif )]157.2 code0
-[2( dw j )]146.2 code0
-[2(%assign k j+i )]135.2 code0
-[2(%assign i j )]124.2 code0
-[2(%assign j k )]113.2 code0
-[2(%endrep )]102.2 code0
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-[2()]681 code0
-[2(fib_number equ \($-fibonacci\)/2)]670 code2
-[(This produces a list of all the Fibonacci numbers that will fit in 16 bits. Note that a maximum repeat count)]653 norm1
-[(must still be given to )2(%rep)0(. This is to prevent the possibility of NASM getting into an infinite loop in the)]642 norm0
-[(preprocessor, which \(on multitasking or multi-user systems\) would typically cause all the system memory to)]631 norm0
-[(be gradually used up and other applications to start crashing.)]620 norm2
-[{/section-4.6 xa}(Source Files and Dependencies)](4.6)598.6 head3
-[(These commands allow you to split your sources into multiple files.)]581.6 norm3
-[{/section-4.6.1 xa}2(%include)0(: )(Including Other Files)](4.6.1)562.4 subh3
-[(Using, once again, a very similar syntax to the C preprocessor, NASM's preprocessor lets you include other)]545.4 norm1
-[(source files into your code. This is done by the use of the )2(%include)0( directive:)]534.4 norm2
-[2(%include "macros.mac")]517.4 code3
-[(will include the contents of the file )2(macros.mac)0( into the source file containing the )2(%include)0( directive.)]500.4 norm3
-[(Include files are )(searched for in the current directory \(the directory you're in when you run NASM, as)]483.4 norm1
-[(opposed to the location of the NASM executable or the location of the source file\), plus any directories)]472.4 norm0
-[(specified on the NASM command line using the )2(-i)0( option.)]461.4 norm2
-[(The standard C idiom for preventing a file being included more than once is just as applicable in NASM: if)]444.4 norm1
-[(the file )2(macros.mac)0( has the form)]433.4 norm2
-[2(%ifndef MACROS_MAC )]416.4 code1
-[2( %define MACROS_MAC )]405.4 code0
-[2( ; now define some macros )]394.4 code0
-[2(%endif)]383.4 code2
-[(then including the file more than once will not cause errors, because the second time the file is included)]366.4 norm1
-[(nothing will happen because the macro )2(MACROS_MAC)0( will already be defined.)]355.4 norm2
-[(You can force a file to be included even if there is no )2(%include)0( directive that explicitly includes it, by using)]338.4 norm1
-[(the )2(-p)0( option on the NASM command line \(see ){/section-2.1.17 xl}(section 2.1.17){el}(\).)]327.4 norm2
-[{/section-4.6.2 xa}2(%pathsearch)0(: Search the Include Path)](4.6.2)308.2 subh3
-[(The )2(%pathsearch)0( directive takes a single-line macro name and a filename, and declare or redefines the)]291.2 norm1
-[(specified single-line macro to be the include-path-resolved version of the filename, if the file exists)]280.2 norm0
-[(\(otherwise, it is passed unchanged.\))]269.2 norm2
-[(For example,)]252.2 norm3
-[2(%pathsearch MyFoo "foo.bin")]235.2 code3
-[(... with )2(-Ibins/)0( in the include path may end up defining the macro )2(MyFoo)0( to be )2("bins/foo.bin")0(.)]218.2 norm3
-[{/section-4.6.3 xa}2(%depend)0(: Add Dependent Files)](4.6.3)199 subh3
-[(The )2(%depend)0( directive takes a filename and adds it to the list of files to be emitted as dependency generation)]182 norm1
-[(when the )2(-M)0( options and its relatives \(see ){/section-2.1.4 xl}(section 2.1.4){el}(\) are used. It produces no output.)]171 norm2
-[(This is generally used in conjunction with )2(%pathsearch)0(. For example, a simplified version of the standard)]154 norm1
-[(macro wrapper for the )2(INCBIN)0( directive looks like:)]143 norm2
-[2(%imacro incbin 1-2+ 0 )]126 code1
-[2(%pathsearch dep %1 )]115 code0
-[2(%depend dep )]104 code0
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-[2( incbin dep,%2 )]681 code0
-[2(%endmacro)]670 code2
-[(This first resolves the location of the file into the macro )2(dep)0(, then adds it to the dependency lists, and finally)]653 norm1
-[(issues the assembler-level )2(INCBIN)0( directive.)]642 norm2
-[{/section-4.6.4 xa}2(%use)0(: Include Standard Macro Package)](4.6.4)622.8 subh3
-[(The )2(%use)0( directive is similar to )2(%include)0(, but rather than including the contents of a file, it includes a)]605.8 norm1
-[(named standard macro package. The standard macro packages are part of NASM, and are described in ){/chapter-5 xl}(chapter){el}]594.8 norm0
-[{/chapter-5 xl}(5){el}(.)]583.8 norm2
-[(Unlike the )2(%include)0( directive, package names for the )2(%use)0( directive do not require quotes, but quotes are)]566.8 norm1
-[(permitted. In NASM 2.04 and 2.05 the unquoted form would be macro-expanded; this is no longer true. Thus,)]555.8 norm0
-[(the following lines are equivalent:)]544.8 norm2
-[2(%use altreg )]527.8 code1
-[2(%use 'altreg')]516.8 code2
-[(Standard macro packages are protected from multiple inclusion. When a standard macro package is used, a)]499.8 norm1
-[(testable single-line macro of the form )2(__USE_)1(package)2(__)0( is also defined, see ){/section-4.11.8 xl}(section 4.11.8){el}(.)]488.8 norm2
-[{/section-4.7 xa}(The )(Context Stack)](4.7)467.4 head3
-[(Having labels that are local to a macro definition is sometimes not quite powerful enough: sometimes you)]450.4 norm1
-[(want to be able to share labels between several macro calls. An example might be a )2(REPEAT)0( ... )2(UNTIL)0( loop,)]439.4 norm0
-[(in which the expansion of the )2(REPEAT)0( macro would need to be able to refer to a label which the )2(UNTIL)]428.4 norm0
-[(macro had defined. However, for such a macro you would also want to be able to nest these loops.)]417.4 norm2
-[(NASM provides this level of power by means of a )1(context stack)0(. The preprocessor maintains a stack of)]400.4 norm1
-[1(contexts)0(, each of which is characterized by a name. You add a new context to the stack using the )2(%push)]389.4 norm0
-[(directive, and remove one using )2(%pop)0(. You can define labels that are local to a particular context on the stack.)]378.4 norm2
-[{/section-4.7.1 xa}2(%push)0( and )2(%pop)0(: )(Creating and Removing Contexts)](4.7.1)359.2 subh3
-[(The )2(%push)0( directive is used to create a new context and place it on the top of the context stack. )2(%push)0( takes)]342.2 norm1
-[(an optional argument, which is the name of the context. For example:)]331.2 norm2
-[2(%push foobar)]314.2 code3
-[(This pushes a new context called )2(foobar)0( on the stack. You can have several contexts on the stack with the)]297.2 norm1
-[(same name: they can still be distinguished. If no name is given, the context is unnamed \(this is normally used)]286.2 norm0
-[(when both the )2(%push)0( and the )2(%pop)0( are inside a single macro definition.\))]275.2 norm2
-[(The directive )2(%pop)0(, taking one optional argument, removes the top context from the context stack and)]258.2 norm1
-[(destroys it, along with any labels associated with it. If an argument is given, it must match the name of the)]247.2 norm0
-[(current context, otherwise it will issue an error.)]236.2 norm2
-[{/section-4.7.2 xa}(Context-Local Labels)](4.7.2)217 subh3
-[(Just as the usage )2(%%foo)0( defines a label which is local to the particular macro call in which it is used, the)]200 norm1
-[(usage )2(%$foo)0( is used to define a label which is local to the context on the top of the context stack. So the)]189 norm0
-[2(REPEAT)0( and )2(UNTIL)0( example given above could be implemented by means of:)]178 norm2
-[2(%macro repeat 0 )]161 code1
-[2()]150 code0
-[2( %push repeat )]139 code0
-[2( %$begin: )]128 code0
-[2()]117 code0
-[2(%endmacro )]106 code0
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-[2()]681 code0
-[2(%macro until 1 )]670 code0
-[2()]659 code0
-[2( j%-1 %$begin )]648 code0
-[2( %pop )]637 code0
-[2()]626 code0
-[2(%endmacro)]615 code2
-[(and invoked by means of, for example,)]598 norm3
-[2( mov cx,string )]581 code1
-[2( repeat )]570 code0
-[2( add cx,3 )]559 code0
-[2( scasb )]548 code0
-[2( until e)]537 code2
-[(which would scan every fourth byte of a string in search of the byte in )2(AL)0(.)]520 norm3
-[(If you need to define, or access, labels local to the context )1(below)0( the top one on the stack, you can use)]503 norm1
-[2(%$$foo)0(, or )2(%$$$foo)0( for the context below that, and so on.)]492 norm2
-[{/section-4.7.3 xa}(Context-Local Single-Line Macros)](4.7.3)472.8 subh3
-[(NASM also allows you to define single-line macros which are local to a particular context, in just the same)]455.8 norm1
-[(way:)]444.8 norm2
-[2(%define %$localmac 3)]427.8 code3
-[(will define the single-line macro )2(%$localmac)0( to be local to the top context on the stack. Of course, after a)]410.8 norm1
-[(subsequent )2(%push)0(, it can then still be accessed by the name )2(%$$localmac)0(.)]399.8 norm2
-[{/section-4.7.4 xa}2(%repl)0(: )(Renaming a Context)](4.7.4)380.6 subh3
-[(If you need to change the name of the top context on the stack \(in order, for example, to have it respond)]363.6 norm1
-[(differently to )2(%ifctx)0(\), you can execute a )2(%pop)0( followed by a )2(%push)0(; but this will have the side effect of)]352.6 norm0
-[(destroying all context-local labels and macros associated with the context that was just popped.)]341.6 norm2
-[(NASM provides the directive )2(%repl)0(, which )1(replaces)0( a context with a different name, without touching the)]324.6 norm1
-[(associated macros and labels. So you could replace the destructive code)]313.6 norm2
-[2(%pop )]296.6 code1
-[2(%push newname)]285.6 code2
-[(with the non-destructive version )2(%repl newname)0(.)]268.6 norm3
-[{/section-4.7.5 xa}(Example Use of the )(Context Stack: )(Block IFs)](4.7.5)249.4 subh3
-[(This example makes use of almost all the context-stack features, including the conditional-assembly)]232.4 norm1
-[(construct )2(%ifctx)0(, to implement a block IF statement as a set of macros.)]221.4 norm2
-[2(%macro if 1 )]204.4 code1
-[2()]193.4 code0
-[2( %push if )]182.4 code0
-[2( j%-1 %$ifnot )]171.4 code0
-[2()]160.4 code0
-[2(%endmacro )]149.4 code0
-[2()]138.4 code0
-[2(%macro else 0 )]127.4 code0
-[2()]116.4 code0
-[2( %ifctx if )]105.4 code0
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-[2( %repl else )]681 code0
-[2( jmp %$ifend )]670 code0
-[2( %$ifnot: )]659 code0
-[2( %else )]648 code0
-[2( %error "expected `if' before `else'" )]637 code0
-[2( %endif )]626 code0
-[2()]615 code0
-[2(%endmacro )]604 code0
-[2()]593 code0
-[2(%macro endif 0 )]582 code0
-[2()]571 code0
-[2( %ifctx if )]560 code0
-[2( %$ifnot: )]549 code0
-[2( %pop )]538 code0
-[2( %elifctx else )]527 code0
-[2( %$ifend: )]516 code0
-[2( %pop )]505 code0
-[2( %else )]494 code0
-[2( %error "expected `if' or `else' before `endif'" )]483 code0
-[2( %endif )]472 code0
-[2()]461 code0
-[2(%endmacro)]450 code2
-[(This code is more robust than the )2(REPEAT)0( and )2(UNTIL)0( macros given in ){/section-4.7.2 xl}(section 4.7.2){el}(, because it uses)]433 norm1
-[(conditional assembly to check that the macros are issued in the right order \(for example, not calling )2(endif)]422 norm0
-[(before )2(if)0(\) and issues a )2(%error)0( if they're not.)]411 norm2
-[(In addition, the )2(endif)0( macro has to be able to cope with the two distinct cases of either directly following an)]394 norm1
-[2(if)0(, or following an )2(else)0(. It achieves this, again, by using conditional assembly to do different things)]383 norm0
-[(depending on whether the context on top of the stack is )2(if)0( or )2(else)0(.)]372 norm2
-[(The )2(else)0( macro has to preserve the context on the stack, in order to have the )2(%$ifnot)0( referred to by the )2(if)]355 norm1
-[(macro be the same as the one defined by the )2(endif)0( macro, but has to change the context's name so that)]344 norm0
-[2(endif)0( will know there was an intervening )2(else)0(. It does this by the use of )2(%repl)0(.)]333 norm2
-[(A sample usage of these macros might look like:)]316 norm3
-[2( cmp ax,bx )]299 code1
-[2()]288 code0
-[2( if ae )]277 code0
-[2( cmp bx,cx )]266 code0
-[2()]255 code0
-[2( if ae )]244 code0
-[2( mov ax,cx )]233 code0
-[2( else )]222 code0
-[2( mov ax,bx )]211 code0
-[2( endif )]200 code0
-[2()]189 code0
-[2( else )]178 code0
-[2( cmp ax,cx )]167 code0
-[2()]156 code0
-[2( if ae )]145 code0
-[2( mov ax,cx )]134 code0
-[2( endif )]123 code0
-[2()]112 code0
-[2( endif)]101 code2
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-[(The block-)2(IF)0( macros handle nesting quite happily, by means of pushing another context, describing the inner)]681 norm1
-[2(if)0(, on top of the one describing the outer )2(if)0(; thus )2(else)0( and )2(endif)0( always refer to the last unmatched )2(if)]670 norm0
-[(or )2(else)0(.)]659 norm2
-[{/section-4.8 xa}(Stack Relative Preprocessor Directives)](4.8)637.6 head3
-[(The following preprocessor directives provide a way to use labels to refer to local variables allocated on the)]620.6 norm1
-[(stack.)]609.6 norm2
-[2(%arg)0( \(see ){/section-4.8.1 xl}(section 4.8.1){el}(\))]592.6 bull3
-[2(%stacksize)0( \(see ){/section-4.8.2 xl}(section 4.8.2){el}(\))]575.6 bull3
-[2(%local)0( \(see ){/section-4.8.3 xl}(section 4.8.3){el}(\))]558.6 bull3
-[{/section-4.8.1 xa}2(%arg)0( Directive)](4.8.1)539.4 subh3
-[(The )2(%arg)0( directive is used to simplify the handling of parameters passed on the stack. Stack based parameter)]522.4 norm1
-[(passing is used by many high level languages, including C, C++ and Pascal.)]511.4 norm2
-[(While NASM has macros which attempt to duplicate this functionality \(see ){/section-8.4.5 xl}(section 8.4.5){el}(\), the syntax is not)]494.4 norm1
-[(particularly convenient to use. and is not TASM compatible. Here is an example which shows the use of)]483.4 norm0
-[2(%arg)0( without any external macros:)]472.4 norm2
-[2(some_function: )]455.4 code1
-[2()]444.4 code0
-[2( %push mycontext ; save the current context )]433.4 code0
-[2( %stacksize large ; tell NASM to use bp )]422.4 code0
-[2( %arg i:word, j_ptr:word )]411.4 code0
-[2()]400.4 code0
-[2( mov ax,[i] )]389.4 code0
-[2( mov bx,[j_ptr] )]378.4 code0
-[2( add ax,[bx] )]367.4 code0
-[2( ret )]356.4 code0
-[2()]345.4 code0
-[2( %pop ; restore original context)]334.4 code2
-[(This is similar to the procedure defined in ){/section-8.4.5 xl}(section 8.4.5){el}( and adds the value in i to the value pointed to by j_ptr)]317.4 norm1
-[(and returns the sum in the ax register. See ){/section-4.7.1 xl}(section 4.7.1){el}( for an explanation of )2(push)0( and )2(pop)0( and the use of)]306.4 norm0
-[(context stacks.)]295.4 norm2
-[{/section-4.8.2 xa}2(%stacksize)0( Directive)](4.8.2)276.2 subh3
-[(The )2(%stacksize)0( directive is used in conjunction with the )2(%arg)0( \(see ){/section-4.8.1 xl}(section 4.8.1){el}(\) and the )2(%local)0( \(see)]259.2 norm1
-[{/section-4.8.3 xl}(section 4.8.3){el}(\) directives. It tells NASM the default size to use for subsequent )2(%arg)0( and )2(%local)0( directives.)]248.2 norm0
-[(The )2(%stacksize)0( directive takes one required argument which is one of )2(flat)0(, )2(flat64)0(, )2(large)0( or )2(small)0(.)]237.2 norm2
-[2(%stacksize flat)]220.2 code3
-[(This form causes NASM to use stack-based parameter addressing relative to )2(ebp)0( and it assumes that a near)]203.2 norm1
-[(form of call was used to get to this label \(i.e. that )2(eip)0( is on the stack\).)]192.2 norm2
-[2(%stacksize flat64)]175.2 code3
-[(This form causes NASM to use stack-based parameter addressing relative to )2(rbp)0( and it assumes that a near)]158.2 norm1
-[(form of call was used to get to this label \(i.e. that )2(rip)0( is on the stack\).)]147.2 norm2
-[2(%stacksize large)]130.2 code3
-[(This form uses )2(bp)0( to do stack-based parameter addressing and assumes that a far form of call was used to get)]113.2 norm1
-[(to this address \(i.e. that )2(ip)0( and )2(cs)0( are on the stack\).)]102.2 norm2
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-[2(%stacksize small)]681 code3
-[(This form also uses )2(bp)0( to address stack parameters, but it is different from )2(large)0( because it also assumes)]664 norm1
-[(that the old value of bp is pushed onto the stack \(i.e. it expects an )2(ENTER)0( instruction\). In other words, it)]653 norm0
-[(expects that )2(bp)0(, )2(ip)0( and )2(cs)0( are on the top of the stack, underneath any local space which may have been)]642 norm0
-[(allocated by )2(ENTER)0(. This form is probably most useful when used in combination with the )2(%local)0( directive)]631 norm0
-[(\(see ){/section-4.8.3 xl}(section 4.8.3){el}(\).)]620 norm2
-[{/section-4.8.3 xa}2(%local)0( Directive)](4.8.3)600.8 subh3
-[(The )2(%local)0( directive is used to simplify the use of local temporary stack variables allocated in a stack)]583.8 norm1
-[(frame. Automatic local variables in C are an example of this kind of variable. The )2(%local)0( directive is most)]572.8 norm0
-[(useful when used with the )2(%stacksize)0( \(see ){/section-4.8.2 xl}(section 4.8.2){el}( and is also compatible with the )2(%arg)0( directive)]561.8 norm0
-[(\(see ){/section-4.8.1 xl}(section 4.8.1){el}(\). It allows simplified reference to variables on the stack which have been allocated typically)]550.8 norm0
-[(by using the )2(ENTER)0( instruction. An example of its use is the following:)]539.8 norm2
-[2(silly_swap: )]522.8 code1
-[2()]511.8 code0
-[2( %push mycontext ; save the current context )]500.8 code0
-[2( %stacksize small ; tell NASM to use bp )]489.8 code0
-[2( %assign %$localsize 0 ; see text for explanation )]478.8 code0
-[2( %local old_ax:word, old_dx:word )]467.8 code0
-[2()]456.8 code0
-[2( enter %$localsize,0 ; see text for explanation )]445.8 code0
-[2( mov [old_ax],ax ; swap ax & bx )]434.8 code0
-[2( mov [old_dx],dx ; and swap dx & cx )]423.8 code0
-[2( mov ax,bx )]412.8 code0
-[2( mov dx,cx )]401.8 code0
-[2( mov bx,[old_ax] )]390.8 code0
-[2( mov cx,[old_dx] )]379.8 code0
-[2( leave ; restore old bp )]368.8 code0
-[2( ret ; )]357.8 code0
-[2()]346.8 code0
-[2( %pop ; restore original context)]335.8 code2
-[(The )2(%$localsize)0( variable is used internally by the )2(%local)0( directive and )1(must)0( be defined within the)]318.8 norm1
-[(current context before the )2(%local)0( directive may be used. Failure to do so will result in one expression)]307.8 norm0
-[(syntax error for each )2(%local)0( variable declared. It then may be used in the construction of an appropriately)]296.8 norm0
-[(sized ENTER instruction as shown in the example.)]285.8 norm2
-[{/section-4.9 xa}(Reporting )(User-Defined Errors: )2(%error)0(, )2(%warning)0(, )2(%fatal)](4.9)264.4 head3
-[(The preprocessor directive )2(%error)0( will cause NASM to report an error if it occurs in assembled code. So if)]247.4 norm1
-[(other users are going to try to assemble your source files, you can ensure that they define the right macros by)]236.4 norm0
-[(means of code like this:)]225.4 norm2
-[2(%ifdef F1 )]208.4 code1
-[2( ; do some setup )]197.4 code0
-[2(%elifdef F2 )]186.4 code0
-[2( ; do some different setup )]175.4 code0
-[2(%else )]164.4 code0
-[2( %error "Neither F1 nor F2 was defined." )]153.4 code0
-[2(%endif)]142.4 code2
-[(Then any user who fails to understand the way your code is supposed to be assembled will be quickly warned)]125.4 norm1
-[(of their mistake, rather than having to wait until the program crashes on being run and then not knowing what)]114.4 norm0
-[(went wrong.)]103.4 norm2
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-[(Similarly, )2(%warning)0( issues a warning, but allows assembly to continue:)]681 norm3
-[2(%ifdef F1 )]664 code1
-[2( ; do some setup )]653 code0
-[2(%elifdef F2 )]642 code0
-[2( ; do some different setup )]631 code0
-[2(%else )]620 code0
-[2( %warning "Neither F1 nor F2 was defined, assuming F1." )]609 code0
-[2( %define F1 )]598 code0
-[2(%endif)]587 code2
-[2(%error)0( and )2(%warning)0( are issued only on the final assembly pass. This makes them safe to use in)]570 norm1
-[(conjunction with tests that depend on symbol values.)]559 norm2
-[2(%fatal)0( terminates assembly immediately, regardless of pass. This is useful when there is no point in)]542 norm1
-[(continuing the assembly further, and doing so is likely just going to cause a spew of confusing error messages.)]531 norm2
-[(It is optional for the message string after )2(%error)0(, )2(%warning)0( or )2(%fatal)0( to be quoted. If it is )1(not)0(, then)]514 norm1
-[(single-line macros are expanded in it, which can be used to display more information to the user. For)]503 norm0
-[(example:)]492 norm2
-[2(%if foo > 64 )]475 code1
-[2( %assign foo_over foo-64 )]464 code0
-[2( %error foo is foo_over bytes too large )]453 code0
-[2(%endif)]442 code2
-[{/section-4.10 xa}(Other Preprocessor Directives)](4.10)420.6 head3
-[(NASM also has preprocessor directives which allow access to information from external sources. Currently)]403.6 norm1
-[(they include:)]392.6 norm2
-[2(%line)0( enables NASM to correctly handle the output of another preprocessor \(see ){/section-4.10.1 xl}(section 4.10.1){el}(\).)]375.6 bull3
-[2(%!)0( enables NASM to read in the value of an environment variable, which can then be used in your)]358.6 bull1
-[(program \(see ){/section-4.10.2 xl}(section 4.10.2){el}(\).)]347.6 bull2
-[{/section-4.10.1 xa}2(%line)0( Directive)](4.10.1)328.4 subh3
-[(The )2(%line)0( directive is used to notify NASM that the input line corresponds to a specific line number in)]311.4 norm1
-[(another file. Typically this other file would be an original source file, with the current NASM input being the)]300.4 norm0
-[(output of a pre-processor. The )2(%line)0( directive allows NASM to output messages which indicate the line)]289.4 norm0
-[(number of the original source file, instead of the file that is being read by NASM.)]278.4 norm2
-[(This preprocessor directive is not generally of use to programmers, by may be of interest to preprocessor)]261.4 norm1
-[(authors. The usage of the )2(%line)0( preprocessor directive is as follows:)]250.4 norm2
-[2(%line nnn[+mmm] [filename])]233.4 code3
-[(In this directive, )2(nnn)0( identifies the line of the original source file which this line corresponds to. )2(mmm)0( is an)]216.4 norm1
-[(optional parameter which specifies a line increment value; each line of the input file read in is considered to)]205.4 norm0
-[(correspond to )2(mmm)0( lines of the original source file. Finally, )2(filename)0( is an optional parameter which)]194.4 norm0
-[(specifies the file name of the original source file.)]183.4 norm2
-[(After reading a )2(%line)0( preprocessor directive, NASM will report all file name and line numbers relative to)]166.4 norm1
-[(the values specified therein.)]155.4 norm2
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-[{/section-4.10.2 xa}2(%!<env>)0(: Read an environment variable.)](4.10.2)678.8 subh3
-[(The )2(%!<env>)0( directive makes it possible to read the value of an environment variable at assembly time. This)]661.8 norm1
-[(could, for example, be used to store the contents of an environment variable into a string, which could be used)]650.8 norm0
-[(at some other point in your code.)]639.8 norm2
-[(For example, suppose that you have an environment variable )2(FOO)0(, and you want the contents of )2(FOO)0( to be)]622.8 norm1
-[(embedded in your program. You could do that as follows:)]611.8 norm2
-[2(%defstr FOO %!FOO)]594.8 code3
-[(See ){/section-4.1.8 xl}(section 4.1.8){el}( for notes on the )2(%defstr)0( directive.)]577.8 norm3
-[{/section-4.11 xa}(Standard Macros)](4.11)556.4 head3
-[(NASM defines a set of standard macros, which are already defined when it starts to process any source file. If)]539.4 norm1
-[(you really need a program to be assembled with no pre-defined macros, you can use the )2(%clear)0( directive to)]528.4 norm0
-[(empty the preprocessor of everything but context-local preprocessor variables and single-line macros.)]517.4 norm2
-[(Most )(user-level assembler directives \(see ){/chapter-6 xl}(chapter 6){el}(\) are implemented as macros which invoke primitive)]500.4 norm1
-[(directives; these are described in ){/chapter-6 xl}(chapter 6){el}(. The rest of the standard macro set is described here.)]489.4 norm2
-[{/section-4.11.1 xa}(NASM Version Macros)](4.11.1)470.2 subh3
-[(The single-line macros )2(__NASM_MAJOR__)0(, )2(__NASM_MINOR__)0(, )2(__NASM_SUBMINOR__)0( and)]453.2 norm1
-[2(___NASM_PATCHLEVEL__)0( expand to the major, minor, subminor and patch level parts of the )(version)]442.2 norm0
-[(number of NASM being used. So, under NASM 0.98.32p1 for example, )2(__NASM_MAJOR__)0( would be)]431.2 norm0
-[(defined to be 0, )2(__NASM_MINOR__)0( would be defined as 98, )2(__NASM_SUBMINOR__)0( would be defined to)]420.2 norm0
-[(32, and )2(___NASM_PATCHLEVEL__)0( would be defined as 1.)]409.2 norm2
-[(Additionally, the macro )2(__NASM_SNAPSHOT__)0( is defined for automatically generated snapshot releases)]392.2 norm1
-[1(only)0(.)]381.2 norm2
-[{/section-4.11.2 xa}2(__NASM_VERSION_ID__)0(: )(NASM Version ID)](4.11.2)362 subh3
-[(The single-line macro )2(__NASM_VERSION_ID__)0( expands to a dword integer representing the full version)]345 norm1
-[(number of the version of nasm being used. The value is the equivalent to )2(__NASM_MAJOR__)0(,)]334 norm0
-[2(__NASM_MINOR__)0(, )2(__NASM_SUBMINOR__)0( and )2(___NASM_PATCHLEVEL__)0( concatenated to produce a)]323 norm0
-[(single doubleword. Hence, for 0.98.32p1, the returned number would be equivalent to:)]312 norm2
-[2( dd 0x00622001)]295 code3
-[(or)]278 norm3
-[2( db 1,32,98,0)]261 code3
-[(Note that the above lines are generate exactly the same code, the second line is used just to give an indication)]244 norm1
-[(of the order that the separate values will be present in memory.)]233 norm2
-[{/section-4.11.3 xa}2(__NASM_VER__)0(: )(NASM Version string)](4.11.3)213.8 subh3
-[(The single-line macro )2(__NASM_VER__)0( expands to a string which defines the version number of nasm being)]196.8 norm1
-[(used. So, under NASM 0.98.32 for example,)]185.8 norm2
-[2( db __NASM_VER__)]168.8 code3
-[(would expand to)]151.8 norm3
-[2( db "0.98.32")]134.8 code3
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-[{/section-4.11.4 xa}2(__FILE__)0( and )2(__LINE__)0(: File Name and Line Number)](4.11.4)678.8 subh3
-[(Like the C preprocessor, NASM allows the user to find out the file name and line number containing the)]661.8 norm1
-[(current instruction. The macro )2(__FILE__)0( expands to a string constant giving the name of the current input)]650.8 norm0
-[(file \(which may change through the course of assembly if )2(%include)0( directives are used\), and )2(__LINE__)]639.8 norm0
-[(expands to a numeric constant giving the current line number in the input file.)]628.8 norm2
-[(These macros could be used, for example, to communicate debugging information to a macro, since invoking)]611.8 norm1
-[2(__LINE__)0( inside a macro definition \(either single-line or multi-line\) will return the line number of the)]600.8 norm0
-[(macro )1(call)0(, rather than )1(definition)0(. So to determine where in a piece of code a crash is occurring, for example,)]589.8 norm0
-[(one could write a routine )2(stillhere)0(, which is passed a line number in )2(EAX)0( and outputs something like)]578.8 norm0
-[(`line 155: still here'. You could then write a macro)]567.8 norm2
-[2(%macro notdeadyet 0 )]550.8 code1
-[2()]539.8 code0
-[2( push eax )]528.8 code0
-[2( mov eax,__LINE__ )]517.8 code0
-[2( call stillhere )]506.8 code0
-[2( pop eax )]495.8 code0
-[2()]484.8 code0
-[2(%endmacro)]473.8 code2
-[(and then pepper your code with calls to )2(notdeadyet)0( until you find the crash point.)]456.8 norm3
-[{/section-4.11.5 xa}2(__BITS__)0(: Current BITS Mode)](4.11.5)437.6 subh3
-[(The )2(__BITS__)0( standard macro is updated every time that the BITS mode is set using the )2(BITS XX)0( or)]420.6 norm1
-[2([BITS XX])0( directive, where XX is a valid mode number of 16, 32 or 64. )2(__BITS__)0( receives the specified)]409.6 norm0
-[(mode number and makes it globally available. This can be very useful for those who utilize mode-dependent)]398.6 norm0
-[(macros.)]387.6 norm2
-[{/section-4.11.6 xa}2(__OUTPUT_FORMAT__)0(: Current Output Format)](4.11.6)368.4 subh3
-[(The )2(__OUTPUT_FORMAT__)0( standard macro holds the current Output Format, as given by the )2(-f)0( option or)]351.4 norm1
-[(NASM's default. Type )2(nasm -hf)0( for a list.)]340.4 norm2
-[2(%ifidn __OUTPUT_FORMAT__, win32 )]323.4 code1
-[2( %define NEWLINE 13, 10 )]312.4 code0
-[2(%elifidn __OUTPUT_FORMAT__, elf32 )]301.4 code0
-[2( %define NEWLINE 10 )]290.4 code0
-[2(%endif)]279.4 code2
-[{/section-4.11.7 xa}(Assembly Date and Time Macros)](4.11.7)260.2 subh3
-[(NASM provides a variety of macros that represent the timestamp of the assembly session.)]243.2 norm3
-[(The )2(__DATE__)0( and )2(__TIME__)0( macros give the assembly date and time as strings, in ISO 8601 format)]226.2 bull1
-[(\()2("YYYY-MM-DD")0( and )2("HH:MM:SS")0(, respectively.\))]215.2 bull2
-[(The )2(__DATE_NUM__)0( and )2(__TIME_NUM__)0( macros give the assembly date and time in numeric form; in)]198.2 bull1
-[(the format )2(YYYYMMDD)0( and )2(HHMMSS)0( respectively.)]187.2 bull2
-[(The )2(__UTC_DATE__)0( and )2(__UTC_TIME__)0( macros give the assembly date and time in universal time)]170.2 bull1
-[(\(UTC\) as strings, in ISO 8601 format \()2("YYYY-MM-DD")0( and )2("HH:MM:SS")0(, respectively.\) If the host)]159.2 bull0
-[(platform doesn't provide UTC time, these macros are undefined.)]148.2 bull2
-[(The )2(__UTC_DATE_NUM__)0( and )2(__UTC_TIME_NUM__)0( macros give the assembly date and time)]131.2 bull1
-[(universal time \(UTC\) in numeric form; in the format )2(YYYYMMDD)0( and )2(HHMMSS)0( respectively. If the host)]120.2 bull0
-[(platform doesn't provide UTC time, these macros are undefined.)]109.2 bull2
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-[(The )2(__POSIX_TIME__)0( macro is defined as a number containing the number of seconds since the POSIX)]681 bull1
-[(epoch, 1 January 1970 00:00:00 UTC; excluding any leap seconds. This is computed using UTC time if)]670 bull0
-[(available on the host platform, otherwise it is computed using the local time as if it was UTC.)]659 bull2
-[(All instances of time and date macros in the same assembly session produce consistent output. For example,)]642 norm1
-[(in an assembly session started at 42 seconds after midnight on January 1, 2010 in Moscow \(timezone UTC+3\))]631 norm0
-[(these macros would have the following values, assuming, of course, a properly configured environment with a)]620 norm0
-[(correct clock:)]609 norm2
-[2( __DATE__ "2010-01-01" )]592 code1
-[2( __TIME__ "00:00:42" )]581 code0
-[2( __DATE_NUM__ 20100101 )]570 code0
-[2( __TIME_NUM__ 000042 )]559 code0
-[2( __UTC_DATE__ "2009-12-31" )]548 code0
-[2( __UTC_TIME__ "21:00:42" )]537 code0
-[2( __UTC_DATE_NUM__ 20091231 )]526 code0
-[2( __UTC_TIME_NUM__ 210042 )]515 code0
-[2( __POSIX_TIME__ 1262293242)]504 code2
-[{/section-4.11.8 xa}2(__USE_)1(package)2(__)0(: Package Include Test)](4.11.8)484.8 subh3
-[(When a standard macro package \(see ){/chapter-5 xl}(chapter 5){el}(\) is included with the )2(%use)0( directive \(see ){/section-4.6.4 xl}(section 4.6.4){el}(\), a)]467.8 norm1
-[(single-line macro of the form )2(__USE_)1(package)2(__)0( is automatically defined. This allows testing if a particular)]456.8 norm0
-[(package is invoked or not.)]445.8 norm2
-[(For example, if the )2(altreg)0( package is included \(see ){/section-5.1 xl}(section 5.1){el}(\), then the macro )2(__USE_ALTREG__)0( is)]428.8 norm1
-[(defined.)]417.8 norm2
-[{/section-4.11.9 xa}2(__PASS__)0(: Assembly Pass)](4.11.9)398.6 subh3
-[(The macro )2(__PASS__)0( is defined to be )2(1)0( on preparatory passes, and )2(2)0( on the final pass. In preprocess-only)]381.6 norm1
-[(mode, it is set to )2(3)0(, and when running only to generate dependencies \(due to the )2(-M)0( or )2(-MG)0( option, see)]370.6 norm0
-[{/section-2.1.4 xl}(section 2.1.4){el}(\) it is set to )2(0)0(.)]359.6 norm2
-[1(Avoid using this macro if at all possible. It is tremendously easy to generate very strange errors by misusing)]342.6 norm1
-[1(it, and the semantics may change in future versions of NASM.)]331.6 norm2
-[{/section-4.11.10 xa}2(STRUC)0( and )2(ENDSTRUC)0(: )(Declaring Structure Data Types)](4.11.10)312.4 subh3
-[(The core of NASM contains no intrinsic means of defining data structures; instead, the preprocessor is)]295.4 norm1
-[(sufficiently powerful that data structures can be implemented as a set of macros. The macros )2(STRUC)0( and)]284.4 norm0
-[2(ENDSTRUC)0( are used to define a structure data type.)]273.4 norm2
-[2(STRUC)0( takes one or two parameters. The first parameter is the name of the data type. The second, optional)]256.4 norm1
-[(parameter is the base offset of the structure. The name of the data type is defined as a symbol with the value)]245.4 norm0
-[(of the base offset, and the name of the data type with the suffix )2(_size)0( appended to it is defined as an )2(EQU)]234.4 norm0
-[(giving the size of the structure. Once )2(STRUC)0( has been issued, you are defining the structure, and should)]223.4 norm0
-[(define fields using the )2(RESB)0( family of pseudo-instructions, and then invoke )2(ENDSTRUC)0( to finish the)]212.4 norm0
-[(definition.)]201.4 norm2
-[(For example, to define a structure called )2(mytype)0( containing a longword, a word, a byte and a string of bytes,)]184.4 norm1
-[(you might code)]173.4 norm2
-[2(struc mytype )]156.4 code1
-[2()]145.4 code0
-[2( mt_long: resd 1 )]134.4 code0
-[2( mt_word: resw 1 )]123.4 code0
-[2( mt_byte: resb 1 )]112.4 code0
-[2( mt_str: resb 32 )]101.4 code0
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-[2()]681 code0
-[2(endstruc)]670 code2
-[(The above code defines six symbols: )2(mt_long)0( as 0 \(the offset from the beginning of a )2(mytype)0( structure to)]653 norm1
-[(the longword field\), )2(mt_word)0( as 4, )2(mt_byte)0( as 6, )2(mt_str)0( as 7, )2(mytype_size)0( as 39, and )2(mytype)0( itself)]642 norm0
-[(as zero.)]631 norm2
-[(The reason why the structure type name is defined at zero by default is a side effect of allowing structures to)]614 norm1
-[(work with the local label mechanism: if your structure members tend to have the same names in more than)]603 norm0
-[(one structure, you can define the above structure like this:)]592 norm2
-[2(struc mytype )]575 code1
-[2()]564 code0
-[2( .long: resd 1 )]553 code0
-[2( .word: resw 1 )]542 code0
-[2( .byte: resb 1 )]531 code0
-[2( .str: resb 32 )]520 code0
-[2()]509 code0
-[2(endstruc)]498 code2
-[(This defines the offsets to the structure fields as )2(mytype.long)0(, )2(mytype.word)0(, )2(mytype.byte)0( and)]481 norm1
-[2(mytype.str)0(.)]470 norm2
-[(NASM, since it has no )1(intrinsic)0( structure support, does not support any form of period notation to refer to the)]453 norm1
-[(elements of a structure once you have one \(except the above local-label notation\), so code such as)]442 norm0
-[2(mov ax,[mystruc.mt_word])0( is not valid. )2(mt_word)0( is a constant just like any other constant, so the)]431 norm0
-[(correct syntax is )2(mov ax,[mystruc+mt_word])0( or )2(mov ax,[mystruc+mytype.word])0(.)]420 norm2
-[(Sometimes you only have the address of the structure displaced by an offset. For example, consider this)]403 norm1
-[(standard stack frame setup:)]392 norm2
-[2(push ebp )]375 code1
-[2(mov ebp, esp )]364 code0
-[2(sub esp, 40)]353 code2
-[(In this case, you could access an element by subtracting the offset:)]336 norm3
-[2(mov [ebp - 40 + mytype.word], ax)]319 code3
-[(However, if you do not want to repeat this offset, you can use \22640 as a base offset:)]302 norm3
-[2(struc mytype, -40)]285 code3
-[(And access an element this way:)]268 norm3
-[2(mov [ebp + mytype.word], ax)]251 code3
-[{/section-4.11.11 xa}2(ISTRUC)0(, )2(AT)0( and )2(IEND)0(: Declaring )(Instances of Structures)](4.11.11)231.8 subh3
-[(Having defined a structure type, the next thing you typically want to do is to declare instances of that structure)]214.8 norm1
-[(in your data segment. NASM provides an easy way to do this in the )2(ISTRUC)0( mechanism. To declare a)]203.8 norm0
-[(structure of type )2(mytype)0( in a program, you code something like this:)]192.8 norm2
-[2(mystruc: )]175.8 code1
-[2( istruc mytype )]164.8 code0
-[2()]153.8 code0
-[2( at mt_long, dd 123456 )]142.8 code0
-[2( at mt_word, dw 1024 )]131.8 code0
-[2( at mt_byte, db 'x' )]120.8 code0
-[2( at mt_str, db 'hello, world', 13, 10, 0 )]109.8 code0
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-[2()]681 code0
-[2( iend)]670 code2
-[(The function of the )2(AT)0( macro is to make use of the )2(TIMES)0( prefix to advance the assembly position to the)]653 norm1
-[(correct point for the specified structure field, and then to declare the specified data. Therefore the structure)]642 norm0
-[(fields must be declared in the same order as they were specified in the structure definition.)]631 norm2
-[(If the data to go in a structure field requires more than one source line to specify, the remaining source lines)]614 norm1
-[(can easily come after the )2(AT)0( line. For example:)]603 norm2
-[2( at mt_str, db 123,134,145,156,167,178,189 )]586 code1
-[2( db 190,100,0)]575 code2
-[(Depending on personal taste, you can also omit the code part of the )2(AT)0( line completely, and start the structure)]558 norm1
-[(field on the next line:)]547 norm2
-[2( at mt_str )]530 code1
-[2( db 'hello, world' )]519 code0
-[2( db 13,10,0)]508 code2
-[{/section-4.11.12 xa}2(ALIGN)0( and )2(ALIGNB)0(: Data Alignment)](4.11.12)488.8 subh3
-[(The )2(ALIGN)0( and )2(ALIGNB)0( macros provides a convenient way to align code or data on a word, longword,)]471.8 norm1
-[(paragraph or other boundary. \(Some assemblers call this directive )2(EVEN)0(.\) The syntax of the )2(ALIGN)0( and)]460.8 norm0
-[2(ALIGNB)0( macros is)]449.8 norm2
-[2( align 4 ; align on 4-byte boundary )]432.8 code1
-[2( align 16 ; align on 16-byte boundary )]421.8 code0
-[2( align 8,db 0 ; pad with 0s rather than NOPs )]410.8 code0
-[2( align 4,resb 1 ; align to 4 in the BSS )]399.8 code0
-[2( alignb 4 ; equivalent to previous line)]388.8 code2
-[(Both macros require their first argument to be a power of two; they both compute the number of additional)]371.8 norm1
-[(bytes required to bring the length of the current section up to a multiple of that power of two, and then apply)]360.8 norm0
-[(the )2(TIMES)0( prefix to their second argument to perform the alignment.)]349.8 norm2
-[(If the second argument is not specified, the default for )2(ALIGN)0( is )2(NOP)0(, and the default for )2(ALIGNB)0( is)]332.8 norm1
-[2(RESB 1)0(. So if the second argument is specified, the two macros are equivalent. Normally, you can just use)]321.8 norm0
-[2(ALIGN)0( in code and data sections and )2(ALIGNB)0( in BSS sections, and never need the second argument except)]310.8 norm0
-[(for special purposes.)]299.8 norm2
-[2(ALIGN)0( and )2(ALIGNB)0(, being simple macros, perform no error checking: they cannot warn you if their first)]282.8 norm1
-[(argument fails to be a power of two, or if their second argument generates more than one byte of code. In each)]271.8 norm0
-[(of these cases they will silently do the wrong thing.)]260.8 norm2
-[2(ALIGNB)0( \(or )2(ALIGN)0( with a second argument of )2(RESB 1)0(\) can be used within structure definitions:)]243.8 norm3
-[2(struc mytype2 )]226.8 code1
-[2()]215.8 code0
-[2( mt_byte: )]204.8 code0
-[2( resb 1 )]193.8 code0
-[2( alignb 2 )]182.8 code0
-[2( mt_word: )]171.8 code0
-[2( resw 1 )]160.8 code0
-[2( alignb 4 )]149.8 code0
-[2( mt_long: )]138.8 code0
-[2( resd 1 )]127.8 code0
-[2( mt_str: )]116.8 code0
-[2( resb 32 )]105.8 code0
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-[2()]681 code0
-[2(endstruc)]670 code2
-[(This will ensure that the structure members are sensibly aligned relative to the base of the structure.)]653 norm3
-[(A final caveat: )2(ALIGN)0( and )2(ALIGNB)0( work relative to the beginning of the )1(section)0(, not the beginning of the)]636 norm1
-[(address space in the final executable. Aligning to a 16-byte boundary when the section you're in is only)]625 norm0
-[(guaranteed to be aligned to a 4-byte boundary, for example, is a waste of effort. Again, NASM does not)]614 norm0
-[(check that the section's alignment characteristics are sensible for the use of )2(ALIGN)0( or )2(ALIGNB)0(.)]603 norm2
-[(See also the )2(smartalign)0( standard macro package, ){/section-5.2 xl}(section 5.2){el}(.)]586 norm3
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-[{/chapter-5 xa}(Chapter 5: )(Standard Macro Packages)]642.8 chap3
-[(The )2(%use)0( directive \(see ){/section-4.6.4 xl}(section 4.6.4){el}(\) includes one of the standard macro packages included with the NASM)]607.8 norm1
-[(distribution and compiled into the NASM binary. It operates like the )2(%include)0( directive \(see ){/section-4.6.1 xl}(section 4.6.1){el}(\),)]596.8 norm0
-[(but the included contents is provided by NASM itself.)]585.8 norm2
-[(The names of standard macro packages are case insensitive, and can be quoted or not.)]568.8 norm3
-[{/section-5.1 xa}2(altreg)0(: )(Alternate Register Names)](5.1)547.4 head3
-[(The )2(altreg)0( standard macro package provides alternate register names. It provides numeric register names)]530.4 norm1
-[(for all registers \(not just )2(R8)0(\226)2(R15)0(\), the Intel-defined aliases )2(R8L)0(\226)2(R15L)0( for the low bytes of register \(as)]519.4 norm0
-[(opposed to the NASM/AMD standard names )2(R8B)0(\226)2(R15B)0(\), and the names )2(R0H)0(\226)2(R3H)0( \(by analogy with)]508.4 norm0
-[2(R0L)0(\226)2(R3L)0(\) for )2(AH)0(, )2(CH)0(, )2(DH)0(, and )2(BH)0(.)]497.4 norm2
-[(Example use:)]480.4 norm3
-[2(%use altreg )]463.4 code1
-[2()]452.4 code0
-[2(proc: )]441.4 code0
-[2( mov r0l,r3h ; mov al,bh )]430.4 code0
-[2( ret)]419.4 code2
-[(See also ){/section-11.1 xl}(section 11.1){el}(.)]402.4 norm3
-[{/section-5.2 xa}2(smartalign)0(: Smart )2(ALIGN)0( Macro)](5.2)381 head3
-[(The )2(smartalign)0( standard macro package provides for an )2(ALIGN)0( macro which is more powerful than the)]364 norm1
-[(default \(and backwards-compatible\) one \(see ){/section-4.11.12 xl}(section 4.11.12){el}(\). When the )2(smartalign)0( package is enabled,)]353 norm0
-[(when )2(ALIGN)0( is used without a second argument, NASM will generate a sequence of instructions more)]342 norm0
-[(efficient than a series of )2(NOP)0(. Furthermore, if the padding exceeds a specific threshold, then NASM will)]331 norm0
-[(generate a jump over the entire padding sequence.)]320 norm2
-[(The specific instructions generated can be controlled with the new )2(ALIGNMODE)0( macro. This macro takes two)]303 norm1
-[(parameters: one mode, and an optional jump threshold override. The modes are as follows:)]292 norm2
-[2(generic)0(: Works on all x86 CPUs and should have reasonable performance. The default jump threshold)]275 bull1
-[(is 8. This is the default.)]264 bull2
-[2(nop)0(: Pad out with )2(NOP)0( instructions. The only difference compared to the standard )2(ALIGN)0( macro is that)]247 bull1
-[(NASM can still jump over a large padding area. The default jump threshold is 16.)]236 bull2
-[2(k7)0(: Optimize for the AMD K7 \(Athlon/Althon XP\). These instructions should still work on all x86 CPUs.)]219 bull1
-[(The default jump threshold is 16.)]208 bull2
-[2(k8)0(: Optimize for the AMD K8 \(Opteron/Althon 64\). These instructions should still work on all x86 CPUs.)]191 bull1
-[(The default jump threshold is 16.)]180 bull2
-[2(p6)0(: Optimize for Intel CPUs. This uses the long )2(NOP)0( instructions first introduced in Pentium Pro. This is)]163 bull1
-[(incompatible with all CPUs of family 5 or lower, as well as some VIA CPUs and several virtualization)]152 bull0
-[(solutions. The default jump threshold is 16.)]141 bull2
-[(The macro )2(__ALIGNMODE__)0( is defined to contain the current alignment mode. A number of other macros)]124 norm1
-[(beginning with )2(__ALIGN_)0( are used internally by this macro package.)]113 norm2
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-[{/chapter-6 xa}(Chapter 6: )(Assembler Directives)]642.8 chap3
-[(NASM, though it attempts to avoid the bureaucracy of assemblers like MASM and TASM, is nevertheless)]607.8 norm1
-[(forced to support a )1(few)0( directives. These are described in this chapter.)]596.8 norm2
-[(NASM's directives come in two types: )1(user-level)0( directives and )1(primitive)0( directives. Typically, each)]579.8 norm1
-[(directive has a user-level form and a primitive form. In almost all cases, we recommend that users use the)]568.8 norm0
-[(user-level forms of the directives, which are implemented as macros which call the primitive forms.)]557.8 norm2
-[(Primitive directives are enclosed in square brackets; user-level directives are not.)]540.8 norm3
-[(In addition to the universal directives described in this chapter, each object file format can optionally supply)]523.8 norm1
-[(extra directives in order to control particular features of that file format. These )1(format-specific)0( directives are)]512.8 norm0
-[(documented along with the formats that implement them, in ){/chapter-7 xl}(chapter 7){el}(.)]501.8 norm2
-[{/section-6.1 xa}2(BITS)0(: Specifying Target )(Processor Mode)](6.1)480.4 head3
-[(The )2(BITS)0( directive specifies whether NASM should generate code )(designed to run on a processor operating)]463.4 norm1
-[(in 16-bit mode, 32-bit mode or 64-bit mode. The syntax is )2(BITS XX)0(, where XX is 16, 32 or 64.)]452.4 norm2
-[(In most cases, you should not need to use )2(BITS)0( explicitly. The )2(aout)0(, )2(coff)0(, )2(elf)0(, )2(macho)0(, )2(win32)0( and)]435.4 norm1
-[2(win64)0( object formats, which are designed for use in 32-bit or 64-bit operating systems, all cause NASM to)]424.4 norm0
-[(select 32-bit or 64-bit mode, respectively, by default. The )2(obj)0( object format allows you to specify each)]413.4 norm0
-[(segment you define as either )2(USE16)0( or )2(USE32)0(, and NASM will set its operating mode accordingly, so the)]402.4 norm0
-[(use of the )2(BITS)0( directive is once again unnecessary.)]391.4 norm2
-[(The most likely reason for using the )2(BITS)0( directive is to write 32-bit or 64-bit code in a flat binary file; this)]374.4 norm1
-[(is because the )2(bin)0( output format defaults to 16-bit mode in anticipation of it being used most frequently to)]363.4 norm0
-[(write DOS )2(.COM)0( programs, DOS )2(.SYS)0( device drivers and boot loader software.)]352.4 norm2
-[(You do )1(not)0( need to specify )2(BITS 32)0( merely in order to use 32-bit instructions in a 16-bit DOS program; if)]335.4 norm1
-[(you do, the assembler will generate incorrect code because it will be writing code targeted at a 32-bit)]324.4 norm0
-[(platform, to be run on a 16-bit one.)]313.4 norm2
-[(When NASM is in )2(BITS 16)0( mode, instructions which use 32-bit data are prefixed with an 0x66 byte, and)]296.4 norm1
-[(those referring to 32-bit addresses have an 0x67 prefix. In )2(BITS 32)0( mode, the reverse is true: 32-bit)]285.4 norm0
-[(instructions require no prefixes, whereas instructions using 16-bit data need an 0x66 and those working on)]274.4 norm0
-[(16-bit addresses need an 0x67.)]263.4 norm2
-[(When NASM is in )2(BITS 64)0( mode, most instructions operate the same as they do for )2(BITS 32)0( mode.)]246.4 norm1
-[(However, there are 8 more general and SSE registers, and 16-bit addressing is no longer supported.)]235.4 norm2
-[(The default address size is 64 bits; 32-bit addressing can be selected with the 0x67 prefix. The default)]218.4 norm1
-[(operand size is still 32 bits, however, and the 0x66 prefix selects 16-bit operand size. The )2(REX)0( prefix is used)]207.4 norm0
-[(both to select 64-bit operand size, and to access the new registers. NASM automatically inserts REX prefixes)]196.4 norm0
-[(when necessary.)]185.4 norm2
-[(When the )2(REX)0( prefix is used, the processor does not know how to address the AH, BH, CH or DH \(high 8-bit)]168.4 norm1
-[(legacy\) registers. Instead, it is possible to access the the low 8-bits of the SP, BP SI and DI registers as SPL,)]157.4 norm0
-[(BPL, SIL and DIL, respectively; but only when the REX prefix is used.)]146.4 norm2
-[(The )2(BITS)0( directive has an exactly equivalent primitive form, )2([BITS 16])0(, )2([BITS 32])0( and )2([BITS 64])0(.)]129.4 norm1
-[(The user-level form is a macro which has no function other than to call the primitive form.)]118.4 norm2
-[(Note that the space is neccessary, e.g. )2(BITS32)0( will )1(not)0( work!)]101.4 norm3
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-[{/section-6.1.1 xa}2(USE16)0( & )2(USE32)0(: Aliases for BITS)](6.1.1)678.8 subh3
-[(The `)2(USE16)0(' and `)2(USE32)0(' directives can be used in place of `)2(BITS 16)0(' and `)2(BITS 32)0(', for compatibility)]661.8 norm1
-[(with other assemblers.)]650.8 norm2
-[{/section-6.2 xa}2(DEFAULT)0(: Change the assembler defaults)](6.2)629.4 head3
-[(The )2(DEFAULT)0( directive changes the assembler defaults. Normally, NASM defaults to a mode where the)]612.4 norm1
-[(programmer is expected to explicitly specify most features directly. However, this is occationally obnoxious,)]601.4 norm0
-[(as the explicit form is pretty much the only one one wishes to use.)]590.4 norm2
-[(Currently, the only )2(DEFAULT)0( that is settable is whether or not registerless instructions in 64-bit mode are)]573.4 norm1
-[2(RIP)0(\226relative or not. By default, they are absolute unless overridden with the )2(REL)0( specifier \(see ){/section-3.3 xl}(section 3.3){el}(\).)]562.4 norm0
-[(However, if )2(DEFAULT REL)0( is specified, )2(REL)0( is default, unless overridden with the )2(ABS)0( specifier, )1(except)]551.4 norm0
-[1(when used with an FS or GS segment override)0(.)]540.4 norm2
-[(The special handling of )2(FS)0( and )2(GS)0( overrides are due to the fact that these registers are generally used as)]523.4 norm1
-[(thread pointers or other special functions in 64-bit mode, and generating )2(RIP)0(\226relative addresses would be)]512.4 norm0
-[(extremely confusing.)]501.4 norm2
-[2(DEFAULT REL)0( is disabled with )2(DEFAULT ABS)0(.)]484.4 norm3
-[{/section-6.3 xa}2(SECTION)0( or )2(SEGMENT)0(: Changing and )(Defining Sections)](6.3)463 head3
-[(The )2(SECTION)0( directive \()2(SEGMENT)0( is an exactly equivalent synonym\) changes which section of the output)]446 norm1
-[(file the code you write will be assembled into. In some object file formats, the number and names of sections)]435 norm0
-[(are fixed; in others, the user may make up as many as they wish. Hence )2(SECTION)0( may sometimes give an)]424 norm0
-[(error message, or may define a new section, if you try to switch to a section that does not \(yet\) exist.)]413 norm2
-[(The Unix object formats, and the )2(bin)0( object format \(but see ){/section-7.1.3 xl}(section 7.1.3){el}(, all support the )(standardized section)]396 norm1
-[(names )2(.text)0(, )2(.data)0( and )2(.bss)0( for the code, data and uninitialized-data sections. The )2(obj)0( format, by)]385 norm0
-[(contrast, does not recognize these section names as being special, and indeed will strip off the leading period)]374 norm0
-[(of any section name that has one.)]363 norm2
-[{/section-6.3.1 xa}(The )2(__SECT__)0( Macro)](6.3.1)343.8 subh3
-[(The )2(SECTION)0( directive is unusual in that its user-level form functions differently from its primitive form.)]326.8 norm1
-[(The primitive form, )2([SECTION xyz])0(, simply switches the current target section to the one given. The)]315.8 norm0
-[(user-level form, )2(SECTION xyz)0(, however, first defines the single-line macro )2(__SECT__)0( to be the primitive)]304.8 norm0
-[2([SECTION])0( directive which it is about to issue, and then issues it. So the user-level directive)]293.8 norm2
-[2( SECTION .text)]276.8 code3
-[(expands to the two lines)]259.8 norm3
-[2(%define __SECT__ [SECTION .text] )]242.8 code1
-[2( [SECTION .text])]231.8 code2
-[(Users may find it useful to make use of this in their own macros. For example, the )2(writefile)0( macro)]214.8 norm1
-[(defined in ){/section-4.3.4 xl}(section 4.3.4){el}( can be usefully rewritten in the following more sophisticated form:)]203.8 norm2
-[2(%macro writefile 2+ )]186.8 code1
-[2()]175.8 code0
-[2( [section .data] )]164.8 code0
-[2()]153.8 code0
-[2( %%str: db %2 )]142.8 code0
-[2( %%endstr: )]131.8 code0
-[2()]120.8 code0
-[2( __SECT__ )]109.8 code0
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-[2()]681 code0
-[2( mov dx,%%str )]670 code0
-[2( mov cx,%%endstr-%%str )]659 code0
-[2( mov bx,%1 )]648 code0
-[2( mov ah,0x40 )]637 code0
-[2( int 0x21 )]626 code0
-[2()]615 code0
-[2(%endmacro)]604 code2
-[(This form of the macro, once passed a string to output, first switches temporarily to the data section of the file,)]587 norm1
-[(using the primitive form of the )2(SECTION)0( directive so as not to modify )2(__SECT__)0(. It then declares its string)]576 norm0
-[(in the data section, and then invokes )2(__SECT__)0( to switch back to )1(whichever)0( section the user was previously)]565 norm0
-[(working in. It thus avoids the need, in the previous version of the macro, to include a )2(JMP)0( instruction to jump)]554 norm0
-[(over the data, and also does not fail if, in a complicated )2(OBJ)0( format module, the user could potentially be)]543 norm0
-[(assembling the code in any of several separate code sections.)]532 norm2
-[{/section-6.4 xa}2(ABSOLUTE)0(: Defining Absolute Labels)](6.4)510.6 head3
-[(The )2(ABSOLUTE)0( directive can be thought of as an alternative form of )2(SECTION)0(: it causes the subsequent)]493.6 norm1
-[(code to be directed at no physical section, but at the hypothetical section starting at the given absolute address.)]482.6 norm0
-[(The only instructions you can use in this mode are the )2(RESB)0( family.)]471.6 norm2
-[2(ABSOLUTE)0( is used as follows:)]454.6 norm3
-[2(absolute 0x1A )]437.6 code1
-[2()]426.6 code0
-[2( kbuf_chr resw 1 )]415.6 code0
-[2( kbuf_free resw 1 )]404.6 code0
-[2( kbuf resw 16)]393.6 code2
-[(This example describes a section of the PC BIOS data area, at segment address 0x40: the above code defines)]376.6 norm1
-[2(kbuf_chr)0( to be 0x1A, )2(kbuf_free)0( to be 0x1C, and )2(kbuf)0( to be 0x1E.)]365.6 norm2
-[(The user-level form of )2(ABSOLUTE)0(, like that of )2(SECTION)0(, redefines the )2(__SECT__)0( macro when it is)]348.6 norm1
-[(invoked.)]337.6 norm2
-[2(STRUC)0( and )2(ENDSTRUC)0( are defined as macros which use )2(ABSOLUTE)0( \(and also )2(__SECT__)0(\).)]320.6 norm3
-[2(ABSOLUTE)0( doesn't have to take an absolute constant as an argument: it can take an expression \(actually, a)]303.6 norm1
-[(critical expression: see ){/section-3.8 xl}(section 3.8){el}(\) and it can be a value in a segment. For example, a TSR can re-use its)]292.6 norm0
-[(setup code as run-time BSS like this:)]281.6 norm2
-[2( org 100h ; it's a .COM program )]264.6 code1
-[2()]253.6 code0
-[2( jmp setup ; setup code comes last )]242.6 code0
-[2()]231.6 code0
-[2( ; the resident part of the TSR goes here )]220.6 code0
-[2(setup: )]209.6 code0
-[2( ; now write the code that installs the TSR here )]198.6 code0
-[2()]187.6 code0
-[2(absolute setup )]176.6 code0
-[2()]165.6 code0
-[2(runtimevar1 resw 1 )]154.6 code0
-[2(runtimevar2 resd 20 )]143.6 code0
-[2()]132.6 code0
-[2(tsr_end:)]121.6 code2
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-[(This defines some variables `on top of' the setup code, so that after the setup has finished running, the space it)]681 norm1
-[(took up can be re-used as data storage for the running TSR. The symbol `tsr_end' can be used to calculate the)]670 norm0
-[(total size of the part of the TSR that needs to be made resident.)]659 norm2
-[{/section-6.5 xa}2(EXTERN)0(: )(Importing Symbols from Other Modules)](6.5)637.6 head3
-[2(EXTERN)0( is similar to the MASM directive )2(EXTRN)0( and the C keyword )2(extern)0(: it is used to declare a symbol)]620.6 norm1
-[(which is not defined anywhere in the module being assembled, but is assumed to be defined in some other)]609.6 norm0
-[(module and needs to be referred to by this one. Not every object-file format can support external variables:)]598.6 norm0
-[(the )2(bin)0( format cannot.)]587.6 norm2
-[(The )2(EXTERN)0( directive takes as many arguments as you like. Each argument is the name of a symbol:)]570.6 norm3
-[2(extern _printf )]553.6 code1
-[2(extern _sscanf,_fscanf)]542.6 code2
-[(Some object-file formats provide extra features to the )2(EXTERN)0( directive. In all cases, the extra features are)]525.6 norm1
-[(used by suffixing a colon to the symbol name followed by object-format specific text. For example, the )2(obj)]514.6 norm0
-[(format allows you to declare that the default segment base of an external should be the group )2(dgroup)0( by)]503.6 norm0
-[(means of the directive)]492.6 norm2
-[2(extern _variable:wrt dgroup)]475.6 code3
-[(The primitive form of )2(EXTERN)0( differs from the user-level form only in that it can take only one argument at)]458.6 norm1
-[(a time: the support for multiple arguments is implemented at the preprocessor level.)]447.6 norm2
-[(You can declare the same variable as )2(EXTERN)0( more than once: NASM will quietly ignore the second and)]430.6 norm1
-[(later redeclarations. You can't declare a variable as )2(EXTERN)0( as well as something else, though.)]419.6 norm2
-[{/section-6.6 xa}2(GLOBAL)0(: )(Exporting Symbols to Other Modules)](6.6)398.2 head3
-[2(GLOBAL)0( is the other end of )2(EXTERN)0(: if one module declares a symbol as )2(EXTERN)0( and refers to it, then in)]381.2 norm1
-[(order to prevent linker errors, some other module must actually )1(define)0( the symbol and declare it as )2(GLOBAL)0(.)]370.2 norm0
-[(Some assemblers use the name )2(PUBLIC)0( for this purpose.)]359.2 norm2
-[(The )2(GLOBAL)0( directive applying to a symbol must appear )1(before)0( the definition of the symbol.)]342.2 norm3
-[2(GLOBAL)0( uses the same syntax as )2(EXTERN)0(, except that it must refer to symbols which )1(are)0( defined in the same)]325.2 norm1
-[(module as the )2(GLOBAL)0( directive. For example:)]314.2 norm2
-[2(global _main )]297.2 code1
-[2(_main: )]286.2 code0
-[2( ; some code)]275.2 code2
-[2(GLOBAL)0(, like )2(EXTERN)0(, allows object formats to define private extensions by means of a colon. The )2(elf)]258.2 norm1
-[(object format, for example, lets you specify whether global data items are functions or data:)]247.2 norm2
-[2(global hashlookup:function, hashtable:data)]230.2 code3
-[(Like )2(EXTERN)0(, the primitive form of )2(GLOBAL)0( differs from the user-level form only in that it can take only)]213.2 norm1
-[(one argument at a time.)]202.2 norm2
-[{/section-6.7 xa}2(COMMON)0(: Defining Common Data Areas)](6.7)180.8 head3
-[(The )2(COMMON)0( directive is used to declare )1(common variables)0(. A common variable is much like a global)]163.8 norm1
-[(variable declared in the uninitialized data section, so that)]152.8 norm2
-[2(common intvar 4)]135.8 code3
-[(is similar in function to)]118.8 norm3
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-[2(global intvar )]681 code1
-[2(section .bss )]670 code0
-[2()]659 code0
-[2(intvar resd 1)]648 code2
-[(The difference is that if more than one module defines the same common variable, then at link time those)]631 norm1
-[(variables will be )1(merged)0(, and references to )2(intvar)0( in all modules will point at the same piece of memory.)]620 norm2
-[(Like )2(GLOBAL)0( and )2(EXTERN)0(, )2(COMMON)0( supports object-format specific extensions. For example, the )2(obj)]603 norm1
-[(format allows common variables to be NEAR or FAR, and the )2(elf)0( format allows you to specify the)]592 norm0
-[(alignment requirements of a common variable:)]581 norm2
-[2(common commvar 4:near ; works in OBJ )]564 code1
-[2(common intarray 100:4 ; works in ELF: 4 byte aligned)]553 code2
-[(Once again, like )2(EXTERN)0( and )2(GLOBAL)0(, the primitive form of )2(COMMON)0( differs from the user-level form only)]536 norm1
-[(in that it can take only one argument at a time.)]525 norm2
-[{/section-6.8 xa}2(CPU)0(: Defining CPU Dependencies)](6.8)503.6 head3
-[(The )2(CPU)0( directive restricts assembly to those instructions which are available on the specified CPU.)]486.6 norm3
-[(Options are:)]469.6 norm3
-[2(CPU 8086)0( Assemble only 8086 instruction set)]452.6 bull3
-[2(CPU 186)0( Assemble instructions up to the 80186 instruction set)]435.6 bull3
-[2(CPU 286)0( Assemble instructions up to the 286 instruction set)]418.6 bull3
-[2(CPU 386)0( Assemble instructions up to the 386 instruction set)]401.6 bull3
-[2(CPU 486)0( 486 instruction set)]384.6 bull3
-[2(CPU 586)0( Pentium instruction set)]367.6 bull3
-[2(CPU PENTIUM)0( Same as 586)]350.6 bull3
-[2(CPU 686)0( P6 instruction set)]333.6 bull3
-[2(CPU PPRO)0( Same as 686)]316.6 bull3
-[2(CPU P2)0( Same as 686)]299.6 bull3
-[2(CPU P3)0( Pentium III \(Katmai\) instruction sets)]282.6 bull3
-[2(CPU KATMAI)0( Same as P3)]265.6 bull3
-[2(CPU P4)0( Pentium 4 \(Willamette\) instruction set)]248.6 bull3
-[2(CPU WILLAMETTE)0( Same as P4)]231.6 bull3
-[2(CPU PRESCOTT)0( Prescott instruction set)]214.6 bull3
-[2(CPU X64)0( x86-64 \(x64/AMD64/Intel 64\) instruction set)]197.6 bull3
-[2(CPU IA64)0( IA64 CPU \(in x86 mode\) instruction set)]180.6 bull3
-[(All options are case insensitive. All instructions will be selected only if they apply to the selected CPU or)]163.6 norm1
-[(lower. By default, all instructions are available.)]152.6 norm2
-[{/section-6.9 xa}2(FLOAT)0(: Handling of )(floating-point constants)](6.9)131.2 head3
-[(By default, floating-point constants are rounded to nearest, and IEEE denormals are supported. The following)]114.2 norm1
-[(options can be set to alter this behaviour:)]103.2 norm2
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-[2(FLOAT DAZ)0( Flush denormals to zero)]681 bull3
-[2(FLOAT NODAZ)0( Do not flush denormals to zero \(default\))]664 bull3
-[2(FLOAT NEAR)0( Round to nearest \(default\))]647 bull3
-[2(FLOAT UP)0( Round up \(toward +Infinity\))]630 bull3
-[2(FLOAT DOWN)0( Round down \(toward \226Infinity\))]613 bull3
-[2(FLOAT ZERO)0( Round toward zero)]596 bull3
-[2(FLOAT DEFAULT)0( Restore default settings)]579 bull3
-[(The standard macros )2(__FLOAT_DAZ__)0(, )2(__FLOAT_ROUND__)0(, and )2(__FLOAT__)0( contain the current state,)]562 norm1
-[(as long as the programmer has avoided the use of the brackeded primitive form, \()2([FLOAT])0(\).)]551 norm2
-[2(__FLOAT__)0( contains the full set of floating-point settings; this value can be saved away and invoked later to)]534 norm1
-[(restore the setting.)]523 norm2
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-[{/chapter-7 xa}(Chapter 7: )(Output Formats)]642.8 chap3
-[(NASM is a portable assembler, designed to be able to compile on any ANSI C-supporting platform and)]607.8 norm1
-[(produce output to run on a variety of Intel x86 operating systems. For this reason, it has a large number of)]596.8 norm0
-[(available output formats, selected using the )2(-f)0( option on the NASM )(command line. Each of these formats,)]585.8 norm0
-[(along with its extensions to the base NASM syntax, is detailed in this chapter.)]574.8 norm2
-[(As stated in ){/section-2.1.1 xl}(section 2.1.1){el}(, NASM chooses a )(default name for your output file based on the input file name and)]557.8 norm1
-[(the chosen output format. This will be generated by removing the )(extension \()2(.asm)0(, )2(.s)0(, or whatever you like)]546.8 norm0
-[(to use\) from the input file name, and substituting an extension defined by the output format. The extensions)]535.8 norm0
-[(are given with each format below.)]524.8 norm2
-[{/section-7.1 xa}2(bin)0(: )(Flat-Form Binary)( Output)](7.1)503.4 head3
-[(The )2(bin)0( format does not produce object files: it generates nothing in the output file except the code you)]486.4 norm1
-[(wrote. Such `pure binary' files are used by )(MS-DOS: )2(.COM)0( executables and )2(.SYS)0( device drivers are pure)]475.4 norm0
-[(binary files. Pure binary output is also useful for )(operating system and )(boot loader development.)]464.4 norm2
-[(The )2(bin)0( format supports )(multiple section names. For details of how NASM handles sections in the )2(bin)]447.4 norm1
-[(format, see ){/section-7.1.3 xl}(section 7.1.3){el}(.)]436.4 norm2
-[(Using the )2(bin)0( format puts NASM by default into 16-bit mode \(see ){/section-6.1 xl}(section 6.1){el}(\). In order to use )2(bin)0( to write)]419.4 norm1
-[(32-bit or 64-bit code, such as an OS kernel, you need to explicitly issue the )2(BITS 32)0( or )2(BITS 64)0( directive.)]408.4 norm2
-[2(bin)0( has no default output file name extension: instead, it leaves your file name as it is once the original)]391.4 norm1
-[(extension has been removed. Thus, the default is for NASM to assemble )2(binprog.asm)0( into a binary file)]380.4 norm0
-[(called )2(binprog)0(.)]369.4 norm2
-[{/section-7.1.1 xa}2(ORG)0(: Binary File )(Program Origin)](7.1.1)350.2 subh3
-[(The )2(bin)0( format provides an additional directive to the list given in ){/chapter-6 xl}(chapter 6){el}(: )2(ORG)0(. The function of the )2(ORG)]333.2 norm1
-[(directive is to specify the origin address which NASM will assume the program begins at when it is loaded)]322.2 norm0
-[(into memory.)]311.2 norm2
-[(For example, the following code will generate the longword )2(0x00000104)0(:)]294.2 norm3
-[2( org 0x100 )]277.2 code1
-[2( dd label )]266.2 code0
-[2(label:)]255.2 code2
-[(Unlike the )2(ORG)0( directive provided by MASM-compatible assemblers, which allows you to jump around in)]238.2 norm1
-[(the object file and overwrite code you have already generated, NASM's )2(ORG)0( does exactly what the directive)]227.2 norm0
-[(says: )1(origin)0(. Its sole function is to specify one offset which is added to all internal address references within)]216.2 norm0
-[(the section; it does not permit any of the trickery that MASM's version does. See ){/section-12.1.3 xl}(section 12.1.3){el}( for further)]205.2 norm0
-[(comments.)]194.2 norm2
-[{/section-7.1.2 xa}2(bin)0( Extensions to the )2(SECTION)0( Directive)](7.1.2)175 subh3
-[(The )2(bin)0( output format extends the )2(SECTION)0( \(or )2(SEGMENT)0(\) directive to allow you to specify the alignment)]158 norm1
-[(requirements of segments. This is done by appending the )2(ALIGN)0( qualifier to the end of the section-definition)]147 norm0
-[(line. For example,)]136 norm2
-[2(section .data align=16)]119 code3
-[(switches to the section )2(.data)0( and also specifies that it must be aligned on a 16-byte boundary.)]102 norm3
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-[(The parameter to )2(ALIGN)0( specifies how many low bits of the section start address must be forced to zero. The)]681 norm1
-[(alignment value given may be any power of two.)]670 norm2
-[{/section-7.1.3 xa}(Multisection)( Support for the )2(bin)0( Format)](7.1.3)650.8 subh3
-[(The )2(bin)0( format allows the use of multiple sections, of arbitrary names, besides the "known" )2(.text)0(, )2(.data)0(,)]633.8 norm1
-[(and )2(.bss)0( names.)]622.8 norm2
-[(Sections may be designated )2(progbits)0( or )2(nobits)0(. Default is )2(progbits)0( \(except )2(.bss)0(, which defaults)]605.8 bull1
-[(to )2(nobits)0(, of course\).)]594.8 bull2
-[(Sections can be aligned at a specified boundary following the previous section with )2(align=)0(, or at an)]577.8 bull1
-[(arbitrary byte-granular position with )2(start=)0(.)]566.8 bull2
-[(Sections can be given a virtual start address, which will be used for the calculation of all memory)]549.8 bull1
-[(references within that section with )2(vstart=)0(.)]538.8 bull2
-[(Sections can be ordered using )2(follows=<section>)0( or )2(vfollows=<section>)0( as an alternative to)]521.8 bull1
-[(specifying an explicit start address.)]510.8 bull2
-[(Arguments to )2(org)0(, )2(start)0(, )2(vstart)0(, and )2(align=)0( are critical expressions. See ){/section-3.8 xl}(section 3.8){el}(. E.g.)]493.8 bull1
-[2(align=\(1 << ALIGN_SHIFT\))0( \226 )2(ALIGN_SHIFT)0( must be defined before it is used here.)]482.8 bull2
-[(Any code which comes before an explicit )2(SECTION)0( directive is directed by default into the )2(.text)]465.8 bull1
-[(section.)]454.8 bull2
-[(If an )2(ORG)0( statement is not given, )2(ORG 0)0( is used by default.)]437.8 bull3
-[(The )2(.bss)0( section will be placed after the last )2(progbits)0( section, unless )2(start=)0(, )2(vstart=)0(,)]420.8 bull1
-[2(follows=)0(, or )2(vfollows=)0( has been specified.)]409.8 bull2
-[(All sections are aligned on dword boundaries, unless a different alignment has been specified.)]392.8 bull3
-[(Sections may not overlap.)]375.8 bull3
-[(NASM creates the )2(section.<secname>.start)0( for each section, which may be used in your code.)]358.8 bull3
-[{/section-7.1.4 xa}(Map Files)](7.1.4)339.6 subh3
-[(Map files can be generated in )2(-f bin)0( format by means of the )2([map])0( option. Map types of )2(all)0( \(default\),)]322.6 norm1
-[2(brief)0(, )2(sections)0(, )2(segments)0(, or )2(symbols)0( may be specified. Output may be directed to )2(stdout)]311.6 norm0
-[(\(default\), )2(stderr)0(, or a specified file. E.g. )2([map symbols myfile.map])0(. No "user form" exists, the)]300.6 norm0
-[(square brackets must be used.)]289.6 norm2
-[{/section-7.2 xa}2(ith)0(: )(Intel Hex Output)](7.2)268.2 head3
-[(The )2(ith)0( file format produces Intel hex-format files. Just as the )2(bin)0( format, this is a flat memory image)]251.2 norm1
-[(format with no support for relocation or linking. It is usually used with ROM programmers and similar)]240.2 norm0
-[(utilities.)]229.2 norm2
-[(All extensions supported by the )2(bin)0( file format is also supported by the )2(ith)0( file format.)]212.2 norm3
-[2(ith)0( provides a default output file-name extension of )2(.ith)0(.)]195.2 norm3
-[{/section-7.3 xa}2(srec)0(: )(Motorola S-Records Output)](7.3)173.8 head3
-[(The )2(srec)0( file format produces Motorola S-records files. Just as the )2(bin)0( format, this is a flat memory image)]156.8 norm1
-[(format with no support for relocation or linking. It is usually used with ROM programmers and similar)]145.8 norm0
-[(utilities.)]134.8 norm2
-[(All extensions supported by the )2(bin)0( file format is also supported by the )2(srec)0( file format.)]117.8 norm3
-[2(srec)0( provides a default output file-name extension of )2(.srec)0(.)]100.8 norm3
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-[{/section-7.4 xa}2(obj)0(: )(Microsoft OMF)( Object Files)](7.4)676.6 head3
-[(The )2(obj)0( file format \(NASM calls it )2(obj)0( rather than )2(omf)0( for historical reasons\) is the one produced by)]659.6 norm1
-[(MASM and )(TASM, which is typically fed to 16-bit DOS linkers to produce )2(.EXE)0( files. It is also the format)]648.6 norm0
-[(used by )(OS/2.)]637.6 norm2
-[2(obj)0( provides a default output file-name extension of )2(.obj)0(.)]620.6 norm3
-[2(obj)0( is not exclusively a 16-bit format, though: NASM has full support for the 32-bit extensions to the)]603.6 norm1
-[(format. In particular, 32-bit )2(obj)0( format files are used by )(Borland's Win32 compilers, instead of using)]592.6 norm0
-[(Microsoft's newer )2(win32)0( object file format.)]581.6 norm2
-[(The )2(obj)0( format does not define any special segment names: you can call your segments anything you like.)]564.6 norm1
-[(Typical names for segments in )2(obj)0( format files are )2(CODE)0(, )2(DATA)0( and )2(BSS)0(.)]553.6 norm2
-[(If your source file contains code before specifying an explicit )2(SEGMENT)0( directive, then NASM will invent its)]536.6 norm1
-[(own segment called )2(__NASMDEFSEG)0( for you.)]525.6 norm2
-[(When you define a segment in an )2(obj)0( file, NASM defines the segment name as a symbol as well, so that you)]508.6 norm1
-[(can access the segment address of the segment. So, for example:)]497.6 norm2
-[2(segment data )]480.6 code1
-[2()]469.6 code0
-[2(dvar: dw 1234 )]458.6 code0
-[2()]447.6 code0
-[2(segment code )]436.6 code0
-[2()]425.6 code0
-[2(function: )]414.6 code0
-[2( mov ax,data ; get segment address of data )]403.6 code0
-[2( mov ds,ax ; and move it into DS )]392.6 code0
-[2( inc word [dvar] ; now this reference will work )]381.6 code0
-[2( ret)]370.6 code2
-[(The )2(obj)0( format also enables the use of the )2(SEG)0( and )2(WRT)0( operators, so that you can write code which does)]353.6 norm1
-[(things like)]342.6 norm2
-[2(extern foo )]325.6 code1
-[2()]314.6 code0
-[2( mov ax,seg foo ; get preferred segment of foo )]303.6 code0
-[2( mov ds,ax )]292.6 code0
-[2( mov ax,data ; a different segment )]281.6 code0
-[2( mov es,ax )]270.6 code0
-[2( mov ax,[ds:foo] ; this accesses `foo' )]259.6 code0
-[2( mov [es:foo wrt data],bx ; so does this)]248.6 code2
-[{/section-7.4.1 xa}2(obj)0( Extensions to the )2(SEGMENT)0( Directive)](7.4.1)229.4 subh3
-[(The )2(obj)0( output format extends the )2(SEGMENT)0( \(or )2(SECTION)0(\) directive to allow you to specify various)]212.4 norm1
-[(properties of the segment you are defining. This is done by appending extra qualifiers to the end of the)]201.4 norm0
-[(segment-definition line. For example,)]190.4 norm2
-[2(segment code private align=16)]173.4 code3
-[(defines the segment )2(code)0(, but also declares it to be a private segment, and requires that the portion of it)]156.4 norm1
-[(described in this code module must be aligned on a 16-byte boundary.)]145.4 norm2
-[(The available qualifiers are:)]128.4 norm3
-[2(PRIVATE)0(, )2(PUBLIC)0(, )2(COMMON)0( and )2(STACK)0( specify the combination characteristics of the segment.)]111.4 bull1
-[2(PRIVATE)0( segments do not get combined with any others by the linker; )2(PUBLIC)0( and )2(STACK)0( segments get)]100.4 bull0
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-[(concatenated together at link time; and )2(COMMON)0( segments all get overlaid on top of each other rather than)]681 bull0
-[(stuck end-to-end.)]670 bull2
-[2(ALIGN)0( is used, as shown above, to specify how many low bits of the segment start address must be forced)]653 bull1
-[(to zero. The alignment value given may be any power of two from 1 to 4096; in reality, the only values)]642 bull0
-[(supported are 1, 2, 4, 16, 256 and 4096, so if 8 is specified it will be rounded up to 16, and 32, 64 and 128)]631 bull0
-[(will all be rounded up to 256, and so on. Note that alignment to 4096-byte boundaries is a )(PharLap)]620 bull0
-[(extension to the format and may not be supported by all linkers.)]609 bull2
-[2(CLASS)0( can be used to specify the segment class; this feature indicates to the linker that segments of the)]592 bull1
-[(same class should be placed near each other in the output file. The class name can be any word, e.g.)]581 bull0
-[2(CLASS=CODE)0(.)]570 bull2
-[2(OVERLAY)0(, like )2(CLASS)0(, is specified with an arbitrary word as an argument, and provides overlay)]553 bull1
-[(information to an overlay-capable linker.)]542 bull2
-[(Segments can be declared as )2(USE16)0( or )2(USE32)0(, which has the effect of recording the choice in the object)]525 bull1
-[(file and also ensuring that NASM's default assembly mode when assembling in that segment is 16-bit or)]514 bull0
-[(32-bit respectively.)]503 bull2
-[(When writing )(OS/2 object files, you should declare 32-bit segments as )2(FLAT)0(, which causes the default)]486 bull1
-[(segment base for anything in the segment to be the special group )2(FLAT)0(, and also defines the group if it is)]475 bull0
-[(not already defined.)]464 bull2
-[(The )2(obj)0( file format also allows segments to be declared as having a pre-defined absolute segment)]447 bull1
-[(address, although no linkers are currently known to make sensible use of this feature; nevertheless, NASM)]436 bull0
-[(allows you to declare a segment such as )2(SEGMENT SCREEN ABSOLUTE=0xB800)0( if you need to. The)]425 bull0
-[2(ABSOLUTE)0( and )2(ALIGN)0( keywords are mutually exclusive.)]414 bull2
-[(NASM's default segment attributes are )2(PUBLIC)0(, )2(ALIGN=1)0(, no class, no overlay, and )2(USE16)0(.)]397 norm3
-[{/section-7.4.2 xa}2(GROUP)0(: Defining Groups of Segments)](7.4.2)377.8 subh3
-[(The )2(obj)0( format also allows segments to be grouped, so that a single segment register can be used to refer to)]360.8 norm1
-[(all the segments in a group. NASM therefore supplies the )2(GROUP)0( directive, whereby you can code)]349.8 norm2
-[2(segment data )]332.8 code1
-[2()]321.8 code0
-[2( ; some data )]310.8 code0
-[2()]299.8 code0
-[2(segment bss )]288.8 code0
-[2()]277.8 code0
-[2( ; some uninitialized data )]266.8 code0
-[2()]255.8 code0
-[2(group dgroup data bss)]244.8 code2
-[(which will define a group called )2(dgroup)0( to contain the segments )2(data)0( and )2(bss)0(. Like )2(SEGMENT)0(, )2(GROUP)]227.8 norm1
-[(causes the group name to be defined as a symbol, so that you can refer to a variable )2(var)0( in the )2(data)0( segment)]216.8 norm0
-[(as )2(var wrt data)0( or as )2(var wrt dgroup)0(, depending on which segment value is currently in your)]205.8 norm0
-[(segment register.)]194.8 norm2
-[(If you just refer to )2(var)0(, however, and )2(var)0( is declared in a segment which is part of a group, then NASM will)]177.8 norm1
-[(default to giving you the offset of )2(var)0( from the beginning of the )1(group)0(, not the )1(segment)0(. Therefore)]166.8 norm0
-[2(SEG var)0(, also, will return the group base rather than the segment base.)]155.8 norm2
-[(NASM will allow a segment to be part of more than one group, but will generate a warning if you do this.)]138.8 norm1
-[(Variables declared in a segment which is part of more than one group will default to being relative to the first)]127.8 norm0
-[(group that was defined to contain the segment.)]116.8 norm2
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-[(A group does not have to contain any segments; you can still make )2(WRT)0( references to a group which does not)]681 norm1
-[(contain the variable you are referring to. OS/2, for example, defines the special group )2(FLAT)0( with no segments)]670 norm0
-[(in it.)]659 norm2
-[{/section-7.4.3 xa}2(UPPERCASE)0(: Disabling Case Sensitivity in Output)](7.4.3)639.8 subh3
-[(Although NASM itself is )(case sensitive, some OMF linkers are not; therefore it can be useful for NASM to)]622.8 norm1
-[(output single-case object files. The )2(UPPERCASE)0( format-specific directive causes all segment, group and)]611.8 norm0
-[(symbol names that are written to the object file to be forced to upper case just before being written. Within a)]600.8 norm0
-[(source file, NASM is still case-sensitive; but the object file can be written entirely in upper case if desired.)]589.8 norm2
-[2(UPPERCASE)0( is used alone on a line; it requires no parameters.)]572.8 norm3
-[{/section-7.4.4 xa}2(IMPORT)0(: Importing DLL Symbols)](7.4.4)553.6 subh3
-[(The )2(IMPORT)0( format-specific directive defines a symbol to be imported from a DLL, for use if you are)]536.6 norm1
-[(writing a DLL's )(import library in NASM. You still need to declare the symbol as )2(EXTERN)0( as well as using)]525.6 norm0
-[(the )2(IMPORT)0( directive.)]514.6 norm2
-[(The )2(IMPORT)0( directive takes two required parameters, separated by white space, which are \(respectively\) the)]497.6 norm1
-[(name of the symbol you wish to import and the name of the library you wish to import it from. For example:)]486.6 norm2
-[2( import WSAStartup wsock32.dll)]469.6 code3
-[(A third optional parameter gives the name by which the symbol is known in the library you are importing it)]452.6 norm1
-[(from, in case this is not the same as the name you wish the symbol to be known by to your code once you)]441.6 norm0
-[(have imported it. For example:)]430.6 norm2
-[2( import asyncsel wsock32.dll WSAAsyncSelect)]413.6 code3
-[{/section-7.4.5 xa}2(EXPORT)0(: Exporting DLL Symbols)](7.4.5)394.4 subh3
-[(The )2(EXPORT)0( format-specific directive defines a global symbol to be exported as a DLL symbol, for use if)]377.4 norm1
-[(you are writing a DLL in NASM. You still need to declare the symbol as )2(GLOBAL)0( as well as using the)]366.4 norm0
-[2(EXPORT)0( directive.)]355.4 norm2
-[2(EXPORT)0( takes one required parameter, which is the name of the symbol you wish to export, as it was defined)]338.4 norm1
-[(in your source file. An optional second parameter \(separated by white space from the first\) gives the )1(external)]327.4 norm0
-[(name of the symbol: the name by which you wish the symbol to be known to programs using the DLL. If this)]316.4 norm0
-[(name is the same as the internal name, you may leave the second parameter off.)]305.4 norm2
-[(Further parameters can be given to define attributes of the exported symbol. These parameters, like the)]288.4 norm1
-[(second, are separated by white space. If further parameters are given, the external name must also be)]277.4 norm0
-[(specified, even if it is the same as the internal name. The available attributes are:)]266.4 norm2
-[2(resident)0( indicates that the exported name is to be kept resident by the system loader. This is an)]249.4 bull1
-[(optimisation for frequently used symbols imported by name.)]238.4 bull2
-[2(nodata)0( indicates that the exported symbol is a function which does not make use of any initialized data.)]221.4 bull3
-[2(parm=NNN)0(, where )2(NNN)0( is an integer, sets the number of parameter words for the case in which the symbol)]204.4 bull1
-[(is a call gate between 32-bit and 16-bit segments.)]193.4 bull2
-[(An attribute which is just a number indicates that the symbol should be exported with an identifying)]176.4 bull1
-[(number \(ordinal\), and gives the desired number.)]165.4 bull2
-[(For example:)]148.4 norm3
-[2( export myfunc )]131.4 code1
-[2( export myfunc TheRealMoreFormalLookingFunctionName )]120.4 code0
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-[2( export myfunc myfunc 1234 ; export by ordinal )]681 code0
-[2( export myfunc myfunc resident parm=23 nodata)]670 code2
-[{/section-7.4.6 xa}2(..start)0(: Defining the )(Program Entry Point)](7.4.6)650.8 subh3
-[2(OMF)0( linkers require exactly one of the object files being linked to define the program entry point, where)]633.8 norm1
-[(execution will begin when the program is run. If the object file that defines the entry point is assembled using)]622.8 norm0
-[(NASM, you specify the entry point by declaring the special symbol )2(..start)0( at the point where you wish)]611.8 norm0
-[(execution to begin.)]600.8 norm2
-[{/section-7.4.7 xa}2(obj)0( Extensions to the )2(EXTERN)0( Directive)](7.4.7)581.6 subh3
-[(If you declare an external symbol with the directive)]564.6 norm3
-[2( extern foo)]547.6 code3
-[(then references such as )2(mov ax,foo)0( will give you the offset of )2(foo)0( from its preferred segment base \(as)]530.6 norm1
-[(specified in whichever module )2(foo)0( is actually defined in\). So to access the contents of )2(foo)0( you will usually)]519.6 norm0
-[(need to do something like)]508.6 norm2
-[2( mov ax,seg foo ; get preferred segment base )]491.6 code1
-[2( mov es,ax ; move it into ES )]480.6 code0
-[2( mov ax,[es:foo] ; and use offset `foo' from it)]469.6 code2
-[(This is a little unwieldy, particularly if you know that an external is going to be accessible from a given)]452.6 norm1
-[(segment or group, say )2(dgroup)0(. So if )2(DS)0( already contained )2(dgroup)0(, you could simply code)]441.6 norm2
-[2( mov ax,[foo wrt dgroup])]424.6 code3
-[(However, having to type this every time you want to access )2(foo)0( can be a pain; so NASM allows you to)]407.6 norm1
-[(declare )2(foo)0( in the alternative form)]396.6 norm2
-[2( extern foo:wrt dgroup)]379.6 code3
-[(This form causes NASM to pretend that the preferred segment base of )2(foo)0( is in fact )2(dgroup)0(; so the)]362.6 norm1
-[(expression )2(seg foo)0( will now return )2(dgroup)0(, and the expression )2(foo)0( is equivalent to )2(foo wrt dgroup)0(.)]351.6 norm2
-[(This )(default-)2(WRT)0( mechanism can be used to make externals appear to be relative to any group or segment in)]334.6 norm1
-[(your program. It can also be applied to common variables: see ){/section-7.4.8 xl}(section 7.4.8){el}(.)]323.6 norm2
-[{/section-7.4.8 xa}2(obj)0( Extensions to the )2(COMMON)0( Directive)](7.4.8)304.4 subh3
-[(The )2(obj)0( format allows common variables to be either near)( or far)(; NASM allows you to specify which your)]287.4 norm1
-[(variables should be by the use of the syntax)]276.4 norm2
-[2(common nearvar 2:near ; `nearvar' is a near common )]259.4 code1
-[2(common farvar 10:far ; and `farvar' is far)]248.4 code2
-[(Far common variables may be greater in size than 64Kb, and so the OMF specification says that they are)]231.4 norm1
-[(declared as a number of )1(elements)0( of a given size. So a 10-byte far common variable could be declared as ten)]220.4 norm0
-[(one-byte elements, five two-byte elements, two five-byte elements or one ten-byte element.)]209.4 norm2
-[(Some )2(OMF)0( linkers require the )(element size, as well as the variable size, to match when resolving common)]192.4 norm1
-[(variables declared in more than one module. Therefore NASM must allow you to specify the element size on)]181.4 norm0
-[(your far common variables. This is done by the following syntax:)]170.4 norm2
-[2(common c_5by2 10:far 5 ; two five-byte elements )]153.4 code1
-[2(common c_2by5 10:far 2 ; five two-byte elements)]142.4 code2
-[(If no element size is specified, the default is 1. Also, the )2(FAR)0( keyword is not required when an element size is)]125.4 norm1
-[(specified, since only far commons may have element sizes at all. So the above declarations could equivalently)]114.4 norm0
-[(be)]103.4 norm2
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-[2(common c_5by2 10:5 ; two five-byte elements )]681 code1
-[2(common c_2by5 10:2 ; five two-byte elements)]670 code2
-[(In addition to these extensions, the )2(COMMON)0( directive in )2(obj)0( also supports default-)2(WRT)0( specification like)]653 norm1
-[2(EXTERN)0( does \(explained in ){/section-7.4.7 xl}(section 7.4.7){el}(\). So you can also declare things like)]642 norm2
-[2(common foo 10:wrt dgroup )]625 code1
-[2(common bar 16:far 2:wrt data )]614 code0
-[2(common baz 24:wrt data:6)]603 code2
-[{/section-7.5 xa}2(win32)0(: Microsoft Win32 Object Files)](7.5)581.6 head3
-[(The )2(win32)0( output format generates Microsoft Win32 object files, suitable for passing to Microsoft linkers)]564.6 norm1
-[(such as )(Visual C++. Note that Borland Win32 compilers do not use this format, but use )2(obj)0( instead \(see)]553.6 norm0
-[{/section-7.4 xl}(section 7.4){el}(\).)]542.6 norm2
-[2(win32)0( provides a default output file-name extension of )2(.obj)0(.)]525.6 norm3
-[(Note that although Microsoft say that Win32 object files follow the )2(COFF)0( \(Common Object File Format\))]508.6 norm1
-[(standard, the object files produced by Microsoft Win32 compilers are not compatible with COFF linkers such)]497.6 norm0
-[(as DJGPP's, and vice versa. This is due to a difference of opinion over the precise semantics of PC-relative)]486.6 norm0
-[(relocations. To produce COFF files suitable for DJGPP, use NASM's )2(coff)0( output format; conversely, the)]475.6 norm0
-[2(coff)0( format does not produce object files that Win32 linkers can generate correct output from.)]464.6 norm2
-[{/section-7.5.1 xa}2(win32)0( Extensions to the )2(SECTION)0( Directive)](7.5.1)445.4 subh3
-[(Like the )2(obj)0( format, )2(win32)0( allows you to specify additional information on the )2(SECTION)0( directive line, to)]428.4 norm1
-[(control the type and properties of sections you declare. Section types and properties are generated)]417.4 norm0
-[(automatically by NASM for the )(standard section names )2(.text)0(, )2(.data)0( and )2(.bss)0(, but may still be)]406.4 norm0
-[(overridden by these qualifiers.)]395.4 norm2
-[(The available qualifiers are:)]378.4 norm3
-[2(code)0(, or equivalently )2(text)0(, defines the section to be a code section. This marks the section as readable)]361.4 bull1
-[(and executable, but not writable, and also indicates to the linker that the type of the section is code.)]350.4 bull2
-[2(data)0( and )2(bss)0( define the section to be a data section, analogously to )2(code)0(. Data sections are marked as)]333.4 bull1
-[(readable and writable, but not executable. )2(data)0( declares an initialized data section, whereas )2(bss)0( declares)]322.4 bull0
-[(an uninitialized data section.)]311.4 bull2
-[2(rdata)0( declares an initialized data section that is readable but not writable. Microsoft compilers use this)]294.4 bull1
-[(section to place constants in it.)]283.4 bull2
-[2(info)0( defines the section to be an )(informational section, which is not included in the executable file by the)]266.4 bull1
-[(linker, but may \(for example\) pass information )1(to)0( the linker. For example, declaring an )2(info)0(\226type section)]255.4 bull0
-[(called )2(.drectve)0( causes the linker to interpret the contents of the section as command-line options.)]244.4 bull2
-[2(align=)0(, used with a trailing number as in )2(obj)0(, gives the )(alignment requirements of the section. The)]227.4 bull1
-[(maximum you may specify is 64: the Win32 object file format contains no means to request a greater)]216.4 bull0
-[(section alignment than this. If alignment is not explicitly specified, the defaults are 16-byte alignment for)]205.4 bull0
-[(code sections, 8-byte alignment for rdata sections and 4-byte alignment for data \(and BSS\) sections.)]194.4 bull0
-[(Informational sections get a default alignment of 1 byte \(no alignment\), though the value does not matter.)]183.4 bull2
-[(The defaults assumed by NASM if you do not specify the above qualifiers are:)]166.4 norm3
-[2(section .text code align=16 )]149.4 code1
-[2(section .data data align=4 )]138.4 code0
-[2(section .rdata rdata align=8 )]127.4 code0
-[2(section .bss bss align=4)]116.4 code2
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-[(Any other section name is treated by default like )2(.text)0(.)]681 norm3
-[{/section-7.5.2 xa}2(win32)0(: Safe Structured Exception Handling)](7.5.2)661.8 subh3
-[(Among other improvements in Windows XP SP2 and Windows Server 2003 Microsoft has introduced)]644.8 norm1
-[(concept of "safe structured exception handling." General idea is to collect handlers' entry points in designated)]633.8 norm0
-[(read-only table and have alleged entry point verified against this table prior exception control is passed to the)]622.8 norm0
-[(handler. In order for an executable module to be equipped with such "safe exception handler table," all object)]611.8 norm0
-[(modules on linker command line has to comply with certain criteria. If one single module among them does)]600.8 norm0
-[(not, then the table in question is omitted and above mentioned run-time checks will not be performed for)]589.8 norm0
-[(application in question. Table omission is by default silent and therefore can be easily overlooked. One can)]578.8 norm0
-[(instruct linker to refuse to produce binary without such table by passing )2(/safeseh)0( command line option.)]567.8 norm2
-[(Without regard to this run-time check merits it's natural to expect NASM to be capable of generating)]550.8 norm1
-[(modules suitable for )2(/safeseh)0( linking. From developer's viewpoint the problem is two-fold:)]539.8 norm2
-[(how to adapt modules not deploying exception handlers of their own;)]522.8 bull3
-[(how to adapt/develop modules utilizing custom exception handling;)]505.8 bull3
-[(Former can be easily achieved with any NASM version by adding following line to source code:)]488.8 norm3
-[2($@feat.00 equ 1)]471.8 code3
-[(As of version 2.03 NASM adds this absolute symbol automatically. If it's not already present to be precise.)]454.8 norm1
-[(I.e. if for whatever reason developer would choose to assign another value in source file, it would still be)]443.8 norm0
-[(perfectly possible.)]432.8 norm2
-[(Registering custom exception handler on the other hand requires certain "magic." As of version 2.03)]415.8 norm1
-[(additional directive is implemented, )2(safeseh)0(, which instructs the assembler to produce appropriately)]404.8 norm0
-[(formatted input data for above mentioned "safe exception handler table." Its typical use would be:)]393.8 norm2
-[2(section .text )]376.8 code1
-[2(extern _MessageBoxA@16 )]365.8 code0
-[2(%if __NASM_VERSION_ID__ >= 0x02030000 )]354.8 code0
-[2(safeseh handler ; register handler as "safe handler" )]343.8 code0
-[2(%endif )]332.8 code0
-[2(handler: )]321.8 code0
-[2( push DWORD 1 ; MB_OKCANCEL )]310.8 code0
-[2( push DWORD caption )]299.8 code0
-[2( push DWORD text )]288.8 code0
-[2( push DWORD 0 )]277.8 code0
-[2( call _MessageBoxA@16 )]266.8 code0
-[2( sub eax,1 ; incidentally suits as return value )]255.8 code0
-[2( ; for exception handler )]244.8 code0
-[2( ret )]233.8 code0
-[2(global _main )]222.8 code0
-[2(_main: )]211.8 code0
-[2( push DWORD handler )]200.8 code0
-[2( push DWORD [fs:0] )]189.8 code0
-[2( mov DWORD [fs:0],esp ; engage exception handler )]178.8 code0
-[2( xor eax,eax )]167.8 code0
-[2( mov eax,DWORD[eax] ; cause exception )]156.8 code0
-[2( pop DWORD [fs:0] ; disengage exception handler )]145.8 code0
-[2( add esp,4 )]134.8 code0
-[2( ret )]123.8 code0
-[2(text: db 'OK to rethrow, CANCEL to generate core dump',0 )]112.8 code0
-[2(caption:db 'SEGV',0 )]101.8 code0
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-[2()]681 code0
-[2(section .drectve info )]670 code0
-[2( db '/defaultlib:user32.lib /defaultlib:msvcrt.lib ')]659 code2
-[(As you might imagine, it's perfectly possible to produce .exe binary with "safe exception handler table" and)]642 norm1
-[(yet engage unregistered exception handler. Indeed, handler is engaged by simply manipulating )2([fs:0])]631 norm0
-[(location at run-time, something linker has no power over, run-time that is. It should be explicitly mentioned)]620 norm0
-[(that such failure to register handler's entry point with )2(safeseh)0( directive has undesired side effect at)]609 norm0
-[(run-time. If exception is raised and unregistered handler is to be executed, the application is abruptly)]598 norm0
-[(terminated without any notification whatsoever. One can argue that system could at least have logged some)]587 norm0
-[(kind "non-safe exception handler in x.exe at address n" message in event log, but no, literally no notification)]576 norm0
-[(is provided and user is left with no clue on what caused application failure.)]565 norm2
-[(Finally, all mentions of linker in this paragraph refer to Microsoft linker version 7.x and later. Presence of)]548 norm1
-[2(@feat.00)0( symbol and input data for "safe exception handler table" causes no backward incompatibilities)]537 norm0
-[(and "safeseh" modules generated by NASM 2.03 and later can still be linked by earlier versions or)]526 norm0
-[(non-Microsoft linkers.)]515 norm2
-[{/section-7.6 xa}2(win64)0(: Microsoft Win64 Object Files)](7.6)493.6 head3
-[(The )2(win64)0( output format generates Microsoft Win64 object files, which is nearly 100% identical to the)]476.6 norm1
-[2(win32)0( object format \(){/section-7.5 xl}(section 7.5){el}(\) with the exception that it is meant to target 64-bit code and the x86-64)]465.6 norm0
-[(platform altogether. This object file is used exactly the same as the )2(win32)0( object format \(){/section-7.5 xl}(section 7.5){el}(\), in)]454.6 norm0
-[(NASM, with regard to this exception.)]443.6 norm2
-[{/section-7.6.1 xa}2(win64)0(: Writing Position-Independent Code)](7.6.1)424.4 subh3
-[(While )2(REL)0( takes good care of RIP-relative addressing, there is one aspect that is easy to overlook for a)]407.4 norm1
-[(Win64 programmer: indirect references. Consider a switch dispatch table:)]396.4 norm2
-[2( jmp QWORD[dsptch+rax*8] )]379.4 code1
-[2( ... )]368.4 code0
-[2(dsptch: dq case0 )]357.4 code0
-[2( dq case1 )]346.4 code0
-[2( ...)]335.4 code2
-[(Even novice Win64 assembler programmer will soon realize that the code is not 64-bit savvy. Most notably)]318.4 norm1
-[(linker will refuse to link it with)]307.4 norm0
-[(")2('ADDR32' relocation to '.text' invalid without /LARGEADDRESSAWARE:NO)0(". So)]296.4 norm0
-[([s]he will have to split jmp instruction as following:)]285.4 norm2
-[2( lea rbx,[rel dsptch] )]268.4 code1
-[2( jmp QWORD[rbx+rax*8])]257.4 code2
-[(What happens behind the scene is that effective address in )2(lea)0( is encoded relative to instruction pointer, or in)]240.4 norm1
-[(perfectly position-independent manner. But this is only part of the problem! Trouble is that in .dll context)]229.4 norm0
-[2(caseN)0( relocations will make their way to the final module and might have to be adjusted at .dll load time. To)]218.4 norm0
-[(be specific when it can't be loaded at preferred address. And when this occurs, pages with such relocations)]207.4 norm0
-[(will be rendered private to current process, which kind of undermines the idea of sharing .dll. But no worry,)]196.4 norm0
-[(it's trivial to fix:)]185.4 norm2
-[2( lea rbx,[rel dsptch] )]168.4 code1
-[2( add rbx,QWORD[rbx+rax*8] )]157.4 code0
-[2( jmp rbx )]146.4 code0
-[2( ... )]135.4 code0
-[2(dsptch: dq case0-dsptch )]124.4 code0
-[2( dq case1-dsptch )]113.4 code0
-[2( ...)]102.4 code2
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-[(NASM version 2.03 and later provides another alternative, )2(wrt ..imagebase)0( operator, which returns)]681 norm1
-[(offset from base address of the current image, be it .exe or .dll module, therefore the name. For those)]670 norm0
-[(acquainted with PE-COFF format base address denotes start of )2(IMAGE_DOS_HEADER)0( structure. Here is)]659 norm0
-[(how to implement switch with these image-relative references:)]648 norm2
-[2( lea rbx,[rel dsptch] )]631 code1
-[2( mov eax,DWORD[rbx+rax*4] )]620 code0
-[2( sub rbx,dsptch wrt ..imagebase )]609 code0
-[2( add rbx,rax )]598 code0
-[2( jmp rbx )]587 code0
-[2( ... )]576 code0
-[2(dsptch: dd case0 wrt ..imagebase )]565 code0
-[2( dd case1 wrt ..imagebase)]554 code2
-[(One can argue that the operator is redundant. Indeed, snippet before last works just fine with any NASM)]537 norm1
-[(version and is not even Windows specific... The real reason for implementing )2(wrt ..imagebase)0( will)]526 norm0
-[(become apparent in next paragraph.)]515 norm2
-[(It should be noted that )2(wrt ..imagebase)0( is defined as 32-bit operand only:)]498 norm3
-[2( dd label wrt ..imagebase ; ok )]481 code1
-[2( dq label wrt ..imagebase ; bad )]470 code0
-[2( mov eax,label wrt ..imagebase ; ok )]459 code0
-[2( mov rax,label wrt ..imagebase ; bad)]448 code2
-[{/section-7.6.2 xa}2(win64)0(: Structured Exception Handling)](7.6.2)428.8 subh3
-[(Structured exception handing in Win64 is completely different matter from Win32. Upon exception program)]411.8 norm1
-[(counter value is noted, and linker-generated table comprising start and end addresses of all the functions [in)]400.8 norm0
-[(given executable module] is traversed and compared to the saved program counter. Thus so called)]389.8 norm0
-[2(UNWIND_INFO)0( structure is identified. If it's not found, then offending subroutine is assumed to be "leaf" and)]378.8 norm0
-[(just mentioned lookup procedure is attempted for its caller. In Win64 leaf function is such function that does)]367.8 norm0
-[(not call any other function )1(nor)0( modifies any Win64 non-volatile registers, including stack pointer. The latter)]356.8 norm0
-[(ensures that it's possible to identify leaf function's caller by simply pulling the value from the top of the stack.)]345.8 norm2
-[(While majority of subroutines written in assembler are not calling any other function, requirement for)]328.8 norm1
-[(non-volatile registers' immutability leaves developer with not more than 7 registers and no stack frame,)]317.8 norm0
-[(which is not necessarily what [s]he counted with. Customarily one would meet the requirement by saving)]306.8 norm0
-[(non-volatile registers on stack and restoring them upon return, so what can go wrong? If [and only if] an)]295.8 norm0
-[(exception is raised at run-time and no )2(UNWIND_INFO)0( structure is associated with such "leaf" function, the)]284.8 norm0
-[(stack unwind procedure will expect to find caller's return address on the top of stack immediately followed by)]273.8 norm0
-[(its frame. Given that developer pushed caller's non-volatile registers on stack, would the value on top point at)]262.8 norm0
-[(some code segment or even addressable space? Well, developer can attempt copying caller's return address to)]251.8 norm0
-[(the top of stack and this would actually work in some very specific circumstances. But unless developer can)]240.8 norm0
-[(guarantee that these circumstances are always met, it's more appropriate to assume worst case scenario, i.e.)]229.8 norm0
-[(stack unwind procedure going berserk. Relevant question is what happens then? Application is abruptly)]218.8 norm0
-[(terminated without any notification whatsoever. Just like in Win32 case, one can argue that system could at)]207.8 norm0
-[(least have logged "unwind procedure went berserk in x.exe at address n" in event log, but no, no trace of)]196.8 norm0
-[(failure is left.)]185.8 norm2
-[(Now, when we understand significance of the )2(UNWIND_INFO)0( structure, let's discuss what's in it and/or how)]168.8 norm1
-[(it's processed. First of all it is checked for presence of reference to custom language-specific exception)]157.8 norm0
-[(handler. If there is one, then it's invoked. Depending on the return value, execution flow is resumed)]146.8 norm0
-[(\(exception is said to be "handled"\), )1(or)0( rest of )2(UNWIND_INFO)0( structure is processed as following. Beside)]135.8 norm0
-[(optional reference to custom handler, it carries information about current callee's stack frame and where)]124.8 norm0
-[(non-volatile registers are saved. Information is detailed enough to be able to reconstruct contents of caller's)]113.8 norm0
-[(non-volatile registers upon call to current callee. And so caller's context is reconstructed, and then unwind)]102.8 norm0
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-[(procedure is repeated, i.e. another )2(UNWIND_INFO)0( structure is associated, this time, with caller's instruction)]681 norm0
-[(pointer, which is then checked for presence of reference to language-specific handler, etc. The procedure is)]670 norm0
-[(recursively repeated till exception is handled. As last resort system "handles" it by generating memory core)]659 norm0
-[(dump and terminating the application.)]648 norm2
-[(As for the moment of this writing NASM unfortunately does not facilitate generation of above mentioned)]631 norm1
-[(detailed information about stack frame layout. But as of version 2.03 it implements building blocks for)]620 norm0
-[(generating structures involved in stack unwinding. As simplest example, here is how to deploy custom)]609 norm0
-[(exception handler for leaf function:)]598 norm2
-[2(default rel )]581 code1
-[2(section .text )]570 code0
-[2(extern MessageBoxA )]559 code0
-[2(handler: )]548 code0
-[2( sub rsp,40 )]537 code0
-[2( mov rcx,0 )]526 code0
-[2( lea rdx,[text] )]515 code0
-[2( lea r8,[caption] )]504 code0
-[2( mov r9,1 ; MB_OKCANCEL )]493 code0
-[2( call MessageBoxA )]482 code0
-[2( sub eax,1 ; incidentally suits as return value )]471 code0
-[2( ; for exception handler )]460 code0
-[2( add rsp,40 )]449 code0
-[2( ret )]438 code0
-[2(global main )]427 code0
-[2(main: )]416 code0
-[2( xor rax,rax )]405 code0
-[2( mov rax,QWORD[rax] ; cause exception )]394 code0
-[2( ret )]383 code0
-[2(main_end: )]372 code0
-[2(text: db 'OK to rethrow, CANCEL to generate core dump',0 )]361 code0
-[2(caption:db 'SEGV',0 )]350 code0
-[2()]339 code0
-[2(section .pdata rdata align=4 )]328 code0
-[2( dd main wrt ..imagebase )]317 code0
-[2( dd main_end wrt ..imagebase )]306 code0
-[2( dd xmain wrt ..imagebase )]295 code0
-[2(section .xdata rdata align=8 )]284 code0
-[2(xmain: db 9,0,0,0 )]273 code0
-[2( dd handler wrt ..imagebase )]262 code0
-[2(section .drectve info )]251 code0
-[2( db '/defaultlib:user32.lib /defaultlib:msvcrt.lib ')]240 code2
-[(What you see in )2(.pdata)0( section is element of the "table comprising start and end addresses of function")]223 norm1
-[(along with reference to associated )2(UNWIND_INFO)0( structure. And what you see in )2(.xdata)0( section is)]212 norm0
-[2(UNWIND_INFO)0( structure describing function with no frame, but with designated exception handler.)]201 norm0
-[(References are )1(required)0( to be image-relative \(which is the real reason for implementing)]190 norm0
-[2(wrt ..imagebase)0( operator\). It should be noted that )2(rdata align=n)0(, as well as)]179 norm0
-[2(wrt ..imagebase)0(, are optional in these two segments' contexts, i.e. can be omitted. Latter means that )1(all)]168 norm0
-[(32-bit references, not only above listed required ones, placed into these two segments turn out)]157 norm0
-[(image-relative. Why is it important to understand? Developer is allowed to append handler-specific data to)]146 norm0
-[2(UNWIND_INFO)0( structure, and if [s]he adds a 32-bit reference, then [s]he will have to remember to adjust its)]135 norm0
-[(value to obtain the real pointer.)]124 norm2
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-[(As already mentioned, in Win64 terms leaf function is one that does not call any other function )1(nor)0( modifies)]681 norm1
-[(any non-volatile register, including stack pointer. But it's not uncommon that assembler programmer plans to)]670 norm0
-[(utilize every single register and sometimes even have variable stack frame. Is there anything one can do with)]659 norm0
-[(bare building blocks? I.e. besides manually composing fully-fledged )2(UNWIND_INFO)0( structure, which would)]648 norm0
-[(surely be considered error-prone? Yes, there is. Recall that exception handler is called first, before stack)]637 norm0
-[(layout is analyzed. As it turned out, it's perfectly possible to manipulate current callee's context in custom)]626 norm0
-[(handler in manner that permits further stack unwinding. General idea is that handler would not actually)]615 norm0
-[("handle" the exception, but instead restore callee's context, as it was at its entry point and thus mimic leaf)]604 norm0
-[(function. In other words, handler would simply undertake part of unwinding procedure. Consider following)]593 norm0
-[(example:)]582 norm2
-[2(function: )]565 code1
-[2( mov rax,rsp ; copy rsp to volatile register )]554 code0
-[2( push r15 ; save non-volatile registers )]543 code0
-[2( push rbx )]532 code0
-[2( push rbp )]521 code0
-[2( mov r11,rsp ; prepare variable stack frame )]510 code0
-[2( sub r11,rcx )]499 code0
-[2( and r11,-64 )]488 code0
-[2( mov QWORD[r11],rax ; check for exceptions )]477 code0
-[2( mov rsp,r11 ; allocate stack frame )]466 code0
-[2( mov QWORD[rsp],rax ; save original rsp value )]455 code0
-[2(magic_point: )]444 code0
-[2( ... )]433 code0
-[2( mov r11,QWORD[rsp] ; pull original rsp value )]422 code0
-[2( mov rbp,QWORD[r11-24] )]411 code0
-[2( mov rbx,QWORD[r11-16] )]400 code0
-[2( mov r15,QWORD[r11-8] )]389 code0
-[2( mov rsp,r11 ; destroy frame )]378 code0
-[2( ret)]367 code2
-[(The keyword is that up to )2(magic_point)0( original )2(rsp)0( value remains in chosen volatile register and no)]350 norm1
-[(non-volatile register, except for )2(rsp)0(, is modified. While past )2(magic_point)0( )2(rsp)0( remains constant till the)]339 norm0
-[(very end of the )2(function)0(. In this case custom language-specific exception handler would look like this:)]328 norm2
-[2(EXCEPTION_DISPOSITION handler \(EXCEPTION_RECORD *rec,ULONG64 frame, )]311 code1
-[2( CONTEXT *context,DISPATCHER_CONTEXT *disp\) )]300 code0
-[2({ ULONG64 *rsp; )]289 code0
-[2( if \(context->Rip<\(ULONG64\)magic_point\) )]278 code0
-[2( rsp = \(ULONG64 *\)context->Rax; )]267 code0
-[2( else )]256 code0
-[2( { rsp = \(\(ULONG64 **\)context->Rsp\)[0]; )]245 code0
-[2( context->Rbp = rsp[-3]; )]234 code0
-[2( context->Rbx = rsp[-2]; )]223 code0
-[2( context->R15 = rsp[-1]; )]212 code0
-[2( } )]201 code0
-[2( context->Rsp = \(ULONG64\)rsp; )]190 code0
-[2()]179 code0
-[2( memcpy \(disp->ContextRecord,context,sizeof\(CONTEXT\)\); )]168 code0
-[2( RtlVirtualUnwind\(UNW_FLAG_NHANDLER,disp->ImageBase, )]157 code0
-[2( dips->ControlPc,disp->FunctionEntry,disp->ContextRecord, )]146 code0
-[2( &disp->HandlerData,&disp->EstablisherFrame,NULL\); )]135 code0
-[2( return ExceptionContinueSearch; )]124 code0
-[2(})]113 code2
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-[(As custom handler mimics leaf function, corresponding )2(UNWIND_INFO)0( structure does not have to contain)]681 norm1
-[(any information about stack frame and its layout.)]670 norm2
-[{/section-7.7 xa}2(coff)0(: )(Common Object File Format)](7.7)648.6 head3
-[(The )2(coff)0( output type produces )2(COFF)0( object files suitable for linking with the )(DJGPP linker.)]631.6 norm3
-[2(coff)0( provides a default output file-name extension of )2(.o)0(.)]614.6 norm3
-[(The )2(coff)0( format supports the same extensions to the )2(SECTION)0( directive as )2(win32)0( does, except that the)]597.6 norm1
-[2(align)0( qualifier and the )2(info)0( section type are not supported.)]586.6 norm2
-[{/section-7.8 xa}2(macho32)0( and )2(macho64)0(: )(Mach Object File Format)](7.8)565.2 head3
-[(The )2(macho32)0( and )2(macho64)0( output formts produces )2(Mach-O)0( object files suitable for linking with the)]548.2 norm1
-[(MacOS X linker. )2(macho)0( is a synonym for )2(macho32)0(.)]537.2 norm2
-[2(macho)0( provides a default output file-name extension of )2(.o)0(.)]520.2 norm3
-[{/section-7.9 xa}2(elf32)0( and )2(elf64)0(: )(Executable and Linkable Format Object Files)](7.9)498.8 head3
-[(The )2(elf32)0( and )2(elf64)0( output formats generate )2(ELF32 and ELF64)0( \(Executable and Linkable Format\))]481.8 norm1
-[(object files, as used by Linux as well as )(Unix System V, including )(Solaris x86, )(UnixWare and )(SCO Unix.)]470.8 norm0
-[2(elf)0( provides a default output file-name extension of )2(.o)0(. )2(elf)0( is a synonym for )2(elf32)0(.)]459.8 norm2
-[{/section-7.9.1 xa}(ELF specific directive )2(osabi)](7.9.1)440.6 subh3
-[(The ELF header specifies the application binary interface for the target operating system \(OSABI\). This field)]423.6 norm1
-[(can be set by using the )2(osabi)0( directive with the numeric value \(0-255\) of the target system. If this directive)]412.6 norm0
-[(is not used, the default value will be "UNIX System V ABI" \(0\) which will work on most systems which)]401.6 norm0
-[(support ELF.)]390.6 norm2
-[{/section-7.9.2 xa}2(elf)0( Extensions to the )2(SECTION)0( Directive)](7.9.2)371.4 subh3
-[(Like the )2(obj)0( format, )2(elf)0( allows you to specify additional information on the )2(SECTION)0( directive line, to)]354.4 norm1
-[(control the type and properties of sections you declare. Section types and properties are generated)]343.4 norm0
-[(automatically by NASM for the )(standard section names, but may still be overridden by these qualifiers.)]332.4 norm2
-[(The available qualifiers are:)]315.4 norm3
-[2(alloc)0( defines the section to be one which is loaded into memory when the program is run. )2(noalloc)]298.4 bull1
-[(defines it to be one which is not, such as an informational or comment section.)]287.4 bull2
-[2(exec)0( defines the section to be one which should have execute permission when the program is run.)]270.4 bull1
-[2(noexec)0( defines it as one which should not.)]259.4 bull2
-[2(write)0( defines the section to be one which should be writable when the program is run. )2(nowrite)0( defines)]242.4 bull1
-[(it as one which should not.)]231.4 bull2
-[2(progbits)0( defines the section to be one with explicit contents stored in the object file: an ordinary code)]214.4 bull1
-[(or data section, for example, )2(nobits)0( defines the section to be one with no explicit contents given, such as)]203.4 bull0
-[(a BSS section.)]192.4 bull2
-[2(align=)0(, used with a trailing number as in )2(obj)0(, gives the )(alignment requirements of the section.)]175.4 bull3
-[2(tls)0( defines the section to be one which contains thread local variables.)]158.4 bull3
-[(The defaults assumed by NASM if you do not specify the above qualifiers are:)]141.4 norm3
-[( )( )( )( )( )( )( )( )( )]124.4 norm3
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-[2(section .text progbits alloc exec nowrite align=16 )]681 code1
-[2(section .rodata progbits alloc noexec nowrite align=4 )]670 code0
-[2(section .lrodata progbits alloc noexec nowrite align=4 )]659 code0
-[2(section .data progbits alloc noexec write align=4 )]648 code0
-[2(section .ldata progbits alloc noexec write align=4 )]637 code0
-[2(section .bss nobits alloc noexec write align=4 )]626 code0
-[2(section .lbss nobits alloc noexec write align=4 )]615 code0
-[2(section .tdata progbits alloc noexec write align=4 tls )]604 code0
-[2(section .tbss nobits alloc noexec write align=4 tls )]593 code0
-[2(section .comment progbits noalloc noexec nowrite align=1 )]582 code0
-[2(section other progbits alloc noexec nowrite align=1)]571 code2
-[(\(Any section name other than those in the above table is treated by default like )2(other)0( in the above table.)]554 norm1
-[(Please note that section names are case sensitive.\))]543 norm2
-[{/section-7.9.3 xa}(Position-Independent Code)(: )2(elf)0( Special Symbols and )2(WRT)](7.9.3)523.8 subh3
-[(The )2(ELF)0( specification contains enough features to allow position-independent code \(PIC\) to be written,)]506.8 norm1
-[(which makes )(ELF shared libraries very flexible. However, it also means NASM has to be able to generate a)]495.8 norm0
-[(variety of ELF specific relocation types in ELF object files, if it is to be an assembler which can write PIC.)]484.8 norm2
-[(Since )2(ELF)0( does not support segment-base references, the )2(WRT)0( operator is not used for its normal purpose;)]467.8 norm1
-[(therefore NASM's )2(elf)0( output format makes use of )2(WRT)0( for a different purpose, namely the PIC-specific)]456.8 norm0
-[(relocation types.)]445.8 norm2
-[2(elf)0( defines five special symbols which you can use as the right-hand side of the )2(WRT)0( operator to obtain PIC)]428.8 norm1
-[(relocation types. They are )2(..gotpc)0(, )2(..gotoff)0(, )2(..got)0(, )2(..plt)0( and )2(..sym)0(. Their functions are)]417.8 norm0
-[(summarized here:)]406.8 norm2
-[(Referring to the symbol marking the global offset table base using )2(wrt ..gotpc)0( will end up giving the)]389.8 bull1
-[(distance from the beginning of the current section to the global offset table.)]378.8 bull0
-[(\()2(_GLOBAL_OFFSET_TABLE_)0( is the standard symbol name used to refer to the )(GOT.\) So you would then)]367.8 bull0
-[(need to add )2($$)0( to the result to get the real address of the GOT.)]356.8 bull2
-[(Referring to a location in one of your own sections using )2(wrt ..gotoff)0( will give the distance from the)]339.8 bull1
-[(beginning of the GOT to the specified location, so that adding on the address of the GOT would give the)]328.8 bull0
-[(real address of the location you wanted.)]317.8 bull2
-[(Referring to an external or global symbol using )2(wrt ..got)0( causes the linker to build an entry )1(in)0( the)]300.8 bull1
-[(GOT containing the address of the symbol, and the reference gives the distance from the beginning of the)]289.8 bull0
-[(GOT to the entry; so you can add on the address of the GOT, load from the resulting address, and end up)]278.8 bull0
-[(with the address of the symbol.)]267.8 bull2
-[(Referring to a procedure name using )2(wrt ..plt)0( causes the linker to build a )(procedure linkage table)]250.8 bull1
-[(entry for the symbol, and the reference gives the address of the )(PLT entry. You can only use this in)]239.8 bull0
-[(contexts which would generate a PC-relative relocation normally \(i.e. as the destination for )2(CALL)0( or )2(JMP)0(\),)]228.8 bull0
-[(since ELF contains no relocation type to refer to PLT entries absolutely.)]217.8 bull2
-[(Referring to a symbol name using )2(wrt ..sym)0( causes NASM to write an ordinary relocation, but instead)]200.8 bull1
-[(of making the relocation relative to the start of the section and then adding on the offset to the symbol, it)]189.8 bull0
-[(will write a relocation record aimed directly at the symbol in question. The distinction is a necessary one)]178.8 bull0
-[(due to a peculiarity of the dynamic linker.)]167.8 bull2
-[(A fuller explanation of how to use these relocation types to write shared libraries entirely in NASM is given in)]150.8 norm1
-[{/section-9.2 xl}(section 9.2){el}(.)]139.8 norm2
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-[{/section-7.9.4 xa}(Thread Local Storage)(: )2(elf)0( Special Symbols and )2(WRT)](7.9.4)678.8 subh3
-[(In ELF32 mode, referring to an external or global symbol using )2(wrt ..tlsie)0( )( causes the linker to build)]661.8 bull1
-[(an entry )1(in)0( the GOT containing the offset of the symbol within the TLS block, so you can access the value)]650.8 bull0
-[(of the symbol with code such as:)]639.8 bull2
-[2( mov eax,[tid wrt ..tlsie] )]622.8 code1
-[2( mov [gs:eax],ebx)]611.8 code2
-[(In ELF64 mode, referring to an external or global symbol using )2(wrt ..gottpoff)0( )( causes the linker to)]594.8 bull1
-[(build an entry )1(in)0( the GOT containing the offset of the symbol within the TLS block, so you can access the)]583.8 bull0
-[(value of the symbol with code such as:)]572.8 bull2
-[2( mov rax,[rel tid wrt ..gottpoff] )]555.8 code1
-[2( mov rcx,[fs:rax])]544.8 code2
-[{/section-7.9.5 xa}2(elf)0( Extensions to the )2(GLOBAL)0( Directive)](7.9.5)525.6 subh3
-[2(ELF)0( object files can contain more information about a global symbol than just its address: they can contain)]508.6 norm1
-[(the )(size of the symbol and its )(type as well. These are not merely debugger conveniences, but are actually)]497.6 norm0
-[(necessary when the program being written is a )(shared library. NASM therefore supports some extensions to)]486.6 norm0
-[(the )2(GLOBAL)0( directive, allowing you to specify these features.)]475.6 norm2
-[(You can specify whether a global variable is a function or a data object by suffixing the name with a colon)]458.6 norm1
-[(and the word )2(function)0( or )2(data)0(. \()2(object)0( is a synonym for )2(data)0(.\) For example:)]447.6 norm2
-[2(global hashlookup:function, hashtable:data)]430.6 code3
-[(exports the global symbol )2(hashlookup)0( as a function and )2(hashtable)0( as a data object.)]413.6 norm3
-[(Optionally, you can control the ELF visibility of the symbol. Just add one of the visibility keywords:)]396.6 norm1
-[2(default)0(, )2(internal)0(, )2(hidden)0(, or )2(protected)0(. The default is )2(default)0( of course. For example, to make)]385.6 norm0
-[2(hashlookup)0( hidden:)]374.6 norm2
-[2(global hashlookup:function hidden)]357.6 code3
-[(You can also specify the size of the data associated with the symbol, as a numeric expression \(which may)]340.6 norm1
-[(involve labels, and even forward references\) after the type specifier. Like this:)]329.6 norm2
-[2(global hashtable:data \(hashtable.end - hashtable\) )]312.6 code1
-[2()]301.6 code0
-[2(hashtable: )]290.6 code0
-[2( db this,that,theother ; some data here )]279.6 code0
-[2(.end:)]268.6 code2
-[(This makes NASM automatically calculate the length of the table and place that information into the )2(ELF)]251.6 norm1
-[(symbol table.)]240.6 norm2
-[(Declaring the type and size of global symbols is necessary when writing shared library code. For more)]223.6 norm1
-[(information, see ){/section-9.2.4 xl}(section 9.2.4){el}(.)]212.6 norm2
-[{/section-7.9.6 xa}2(elf)0( Extensions to the )2(COMMON)0( Directive )](7.9.6)193.4 subh3
-[2(ELF)0( also allows you to specify alignment requirements )(on common variables. This is done by putting a)]176.4 norm1
-[(number \(which must be a power of two\) after the name and size of the common variable, separated \(as usual\))]165.4 norm0
-[(by a colon. For example, an array of doublewords would benefit from 4-byte alignment:)]154.4 norm2
-[2(common dwordarray 128:4)]137.4 code3
-[(This declares the total size of the array to be 128 bytes, and requires that it be aligned on a 4-byte boundary.)]120.4 norm3
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-[{/section-7.9.7 xa}(16-bit code and ELF )](7.9.7)678.8 subh3
-[(The )2(ELF32)0( specification doesn't provide relocations for 8- and 16-bit values, but the GNU )2(ld)0( linker adds)]661.8 norm1
-[(these as an extension. NASM can generate GNU-compatible relocations, to allow 16-bit code to be linked as)]650.8 norm0
-[(ELF using GNU )2(ld)0(. If NASM is used with the )2(-w+gnu-elf-extensions)0( option, a warning is issued)]639.8 norm0
-[(when one of these relocations is generated.)]628.8 norm2
-[{/section-7.9.8 xa}(Debug formats and ELF )](7.9.8)609.6 subh3
-[2(ELF32)0( and )2(ELF64)0( provide debug information in )2(STABS)0( and )2(DWARF)0( formats. Line number information is)]592.6 norm1
-[(generated for all executable sections, but please note that only the ".text" section is executable by default.)]581.6 norm2
-[{/section-7.10 xa}2(aout)0(: Linux )2(a.out)0( Object Files)](7.10)560.2 head3
-[(The )2(aout)0( format generates )2(a.out)0( object files, in the form used by early Linux systems \(current Linux)]543.2 norm1
-[(systems use ELF, see ){/section-7.9 xl}(section 7.9){el}(.\) These differ from other )2(a.out)0( object files in that the magic number in the)]532.2 norm0
-[(first four bytes of the file is different; also, some implementations of )2(a.out)0(, for example NetBSD's, support)]521.2 norm0
-[(position-independent code, which Linux's implementation does not.)]510.2 norm2
-[2(a.out)0( provides a default output file-name extension of )2(.o)0(.)]493.2 norm3
-[2(a.out)0( is a very simple object format. It supports no special directives, no special symbols, no use of )2(SEG)0( or)]476.2 norm1
-[2(WRT)0(, and no extensions to any standard directives. It supports only the three )(standard section names )2(.text)0(,)]465.2 norm0
-[2(.data)0( and )2(.bss)0(.)]454.2 norm2
-[{/section-7.11 xa}2(aoutb)0(: )(NetBSD/)(FreeBSD/)(OpenBSD )2(a.out)0( Object Files)](7.11)432.8 head3
-[(The )2(aoutb)0( format generates )2(a.out)0( object files, in the form used by the various free )2(BSD Unix)0( clones,)]415.8 norm1
-[2(NetBSD)0(, )2(FreeBSD)0( and )2(OpenBSD)0(. For simple object files, this object format is exactly the same as )2(aout)]404.8 norm0
-[(except for the magic number in the first four bytes of the file. However, the )2(aoutb)0( format supports)]393.8 norm0
-[(position-independent code in the same way as the )2(elf)0( format, so you can use it to write )2(BSD)0( )(shared libraries.)]382.8 norm2
-[2(aoutb)0( provides a default output file-name extension of )2(.o)0(.)]365.8 norm3
-[2(aoutb)0( supports no special directives, no special symbols, and only the three )(standard section names )2(.text)0(,)]348.8 norm1
-[2(.data)0( and )2(.bss)0(. However, it also supports the same use of )2(WRT)0( as )2(elf)0( does, to provide)]337.8 norm0
-[(position-independent code relocation types. See ){/section-7.9.3 xl}(section 7.9.3){el}( for full documentation of this feature.)]326.8 norm2
-[2(aoutb)0( also supports the same extensions to the )2(GLOBAL)0( directive as )2(elf)0( does: see ){/section-7.9.5 xl}(section 7.9.5){el}( for)]309.8 norm1
-[(documentation of this.)]298.8 norm2
-[{/section-7.12 xa}2(as86)0(: )(Minix/Linux)( )2(as86)0( Object Files)](7.12)277.4 head3
-[(The Minix/Linux 16-bit assembler )2(as86)0( has its own non-standard object file format. Although its)]260.4 norm1
-[(companion linker )2(ld86)0( produces something close to ordinary )2(a.out)0( binaries as output, the object file)]249.4 norm0
-[(format used to communicate between )2(as86)0( and )2(ld86)0( is not itself )2(a.out)0(.)]238.4 norm2
-[(NASM supports this format, just in case it is useful, as )2(as86)0(. )2(as86)0( provides a default output file-name)]221.4 norm1
-[(extension of )2(.o)0(.)]210.4 norm2
-[2(as86)0( is a very simple object format \(from the NASM user's point of view\). It supports no special directives,)]193.4 norm1
-[(no use of )2(SEG)0( or )2(WRT)0(, and no extensions to any standard directives. It supports only the three )(standard section)]182.4 norm0
-[(names )2(.text)0(, )2(.data)0( and )2(.bss)0(. The only special symbol supported is )2(..start)0(.)]171.4 norm2
-[{/section-7.13 xa}2(rdf)0(: )(Relocatable Dynamic Object File Format)](7.13)150 head3
-[(The )2(rdf)0( output format produces )2(RDOFF)0( object files. )2(RDOFF)0( \(Relocatable Dynamic Object File Format\) is a)]133 norm1
-[(home-grown object-file format, designed alongside NASM itself and reflecting in its file format the internal)]122 norm0
-[(structure of the assembler.)]111 norm2
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-[2(RDOFF)0( is not used by any well-known operating systems. Those writing their own systems, however, may)]681 norm1
-[(well wish to use )2(RDOFF)0( as their object format, on the grounds that it is designed primarily for simplicity and)]670 norm0
-[(contains very little file-header bureaucracy.)]659 norm2
-[(The Unix NASM archive, and the DOS archive which includes sources, both contain an )2(rdoff)0( subdirectory)]642 norm1
-[(holding a set of RDOFF utilities: an RDF linker, an )2(RDF)0( static-library manager, an RDF file dump utility,)]631 norm0
-[(and a program which will load and execute an RDF executable under Linux.)]620 norm2
-[2(rdf)0( supports only the )(standard section names )2(.text)0(, )2(.data)0( and )2(.bss)0(.)]603 norm3
-[{/section-7.13.1 xa}(Requiring a Library: The )2(LIBRARY)0( Directive)](7.13.1)583.8 subh3
-[2(RDOFF)0( contains a mechanism for an object file to demand a given library to be linked to the module, either at)]566.8 norm1
-[(load time or run time. This is done by the )2(LIBRARY)0( directive, which takes one argument which is the name)]555.8 norm0
-[(of the module:)]544.8 norm2
-[2( library mylib.rdl)]527.8 code3
-[{/section-7.13.2 xa}(Specifying a Module Name: The )2(MODULE)0( Directive)](7.13.2)508.6 subh3
-[(Special )2(RDOFF)0( header record is used to store the name of the module. It can be used, for example, by)]491.6 norm1
-[(run-time loader to perform dynamic linking. )2(MODULE)0( directive takes one argument which is the name of)]480.6 norm0
-[(current module:)]469.6 norm2
-[2( module mymodname)]452.6 code3
-[(Note that when you statically link modules and tell linker to strip the symbols from output file, all module)]435.6 norm1
-[(names will be stripped too. To avoid it, you should start module names with )2($)0(, like:)]424.6 norm2
-[2( module $kernel.core)]407.6 code3
-[{/section-7.13.3 xa}2(rdf)0( Extensions to the )2(GLOBAL)0( Directive)](7.13.3)388.4 subh3
-[2(RDOFF)0( global symbols can contain additional information needed by the static linker. You can mark a global)]371.4 norm1
-[(symbol as exported, thus telling the linker do not strip it from target executable or library file. Like in )2(ELF)0(,)]360.4 norm0
-[(you can also specify whether an exported symbol is a procedure \(function\) or data object.)]349.4 norm2
-[(Suffixing the name with a colon and the word )2(export)0( you make the symbol exported:)]332.4 norm3
-[2( global sys_open:export)]315.4 code3
-[(To specify that exported symbol is a procedure \(function\), you add the word )2(proc)0( or )2(function)0( after)]298.4 norm1
-[(declaration:)]287.4 norm2
-[2( global sys_open:export proc)]270.4 code3
-[(Similarly, to specify exported data object, add the word )2(data)0( or )2(object)0( to the directive:)]253.4 norm3
-[2( global kernel_ticks:export data)]236.4 code3
-[{/section-7.13.4 xa}2(rdf)0( Extensions to the )2(EXTERN)0( Directive)](7.13.4)217.2 subh3
-[(By default the )2(EXTERN)0( directive in )2(RDOFF)0( declares a "pure external" symbol \(i.e. the static linker will)]200.2 norm1
-[(complain if such a symbol is not resolved\). To declare an "imported" symbol, which must be resolved later)]189.2 norm0
-[(during a dynamic linking phase, )2(RDOFF)0( offers an additional )2(import)0( modifier. As in )2(GLOBAL)0(, you can also)]178.2 norm0
-[(specify whether an imported symbol is a procedure \(function\) or data object. For example:)]167.2 norm2
-[2( library $libc )]150.2 code1
-[2( extern _open:import )]139.2 code0
-[2( extern _printf:import proc )]128.2 code0
-[2( extern _errno:import data)]117.2 code2
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-[(Here the directive )2(LIBRARY)0( is also included, which gives the dynamic linker a hint as to where to find)]681 norm1
-[(requested symbols.)]670 norm2
-[{/section-7.14 xa}2(dbg)0(: Debugging Format)](7.14)648.6 head3
-[(The )2(dbg)0( output format is not built into NASM in the default configuration. If you are building your own)]631.6 norm1
-[(NASM executable from the sources, you can define )2(OF_DBG)0( in )2(output/outform.h)0( or on the compiler)]620.6 norm0
-[(command line, and obtain the )2(dbg)0( output format.)]609.6 norm2
-[(The )2(dbg)0( format does not output an object file as such; instead, it outputs a text file which contains a complete)]592.6 norm1
-[(list of all the transactions between the main body of NASM and the output-format back end module. It is)]581.6 norm0
-[(primarily intended to aid people who want to write their own output drivers, so that they can get a clearer idea)]570.6 norm0
-[(of the various requests the main program makes of the output driver, and in what order they happen.)]559.6 norm2
-[(For simple files, one can easily use the )2(dbg)0( format like this:)]542.6 norm3
-[2(nasm -f dbg filename.asm)]525.6 code3
-[(which will generate a diagnostic file called )2(filename.dbg)0(. However, this will not work well on files)]508.6 norm1
-[(which were designed for a different object format, because each object format defines its own macros \(usually)]497.6 norm0
-[(user-level forms of directives\), and those macros will not be defined in the )2(dbg)0( format. Therefore it can be)]486.6 norm0
-[(useful to run NASM twice, in order to do the preprocessing with the native object format selected:)]475.6 norm2
-[2(nasm -e -f rdf -o rdfprog.i rdfprog.asm )]458.6 code1
-[2(nasm -a -f dbg rdfprog.i)]447.6 code2
-[(This preprocesses )2(rdfprog.asm)0( into )2(rdfprog.i)0(, keeping the )2(rdf)0( object format selected in order to)]430.6 norm1
-[(make sure RDF special directives are converted into primitive form correctly. Then the preprocessed source is)]419.6 norm0
-[(fed through the )2(dbg)0( format to generate the final diagnostic output.)]408.6 norm2
-[(This workaround will still typically not work for programs intended for )2(obj)0( format, because the )2(obj)]391.6 norm1
-[2(SEGMENT)0( and )2(GROUP)0( directives have side effects of defining the segment and group names as symbols; )2(dbg)]380.6 norm0
-[(will not do this, so the program will not assemble. You will have to work around that by defining the symbols)]369.6 norm0
-[(yourself \(using )2(EXTERN)0(, for example\) if you really need to get a )2(dbg)0( trace of an )2(obj)0(\226specific source file.)]358.6 norm2
-[2(dbg)0( accepts any section name and any directives at all, and logs them all to its output file.)]341.6 norm3
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-[{/chapter-8 xa}(Chapter 8: Writing 16-bit Code \(DOS, Windows 3/3.1\))]642.8 chap3
-[(This chapter attempts to cover some of the common issues encountered when writing 16-bit code to run)]607.8 norm1
-[(under )2(MS-DOS)0( or )2(Windows 3.x)0(. It covers how to link programs to produce )2(.EXE)0( or )2(.COM)0( files, how to)]596.8 norm0
-[(write )2(.SYS)0( device drivers, and how to interface assembly language code with 16-bit C compilers and with)]585.8 norm0
-[(Borland Pascal.)]574.8 norm2
-[{/section-8.1 xa}(Producing )2(.EXE)0( Files)](8.1)553.4 head3
-[(Any large program written under DOS needs to be built as a )2(.EXE)0( file: only )2(.EXE)0( files have the necessary)]536.4 norm1
-[(internal structure required to span more than one 64K segment. )(Windows programs, also, have to be built as)]525.4 norm0
-[2(.EXE)0( files, since Windows does not support the )2(.COM)0( format.)]514.4 norm2
-[(In general, you generate )2(.EXE)0( files by using the )2(obj)0( output format to produce one or more )2(.OBJ)0( files, and)]497.4 norm1
-[(then linking them together using a linker. However, NASM also supports the direct generation of simple DOS)]486.4 norm0
-[2(.EXE)0( files using the )2(bin)0( output format \(by using )2(DB)0( and )2(DW)0( to construct the )2(.EXE)0( file header\), and a macro)]475.4 norm0
-[(package is supplied to do this. Thanks to Yann Guidon for contributing the code for this.)]464.4 norm2
-[(NASM may also support )2(.EXE)0( natively as another output format in future releases.)]447.4 norm3
-[{/section-8.1.1 xa}(Using the )2(obj)0( Format To Generate )2(.EXE)0( Files)](8.1.1)428.2 subh3
-[(This section describes the usual method of generating )2(.EXE)0( files by linking )2(.OBJ)0( files together.)]411.2 norm3
-[(Most 16-bit programming language packages come with a suitable linker; if you have none of these, there is a)]394.2 norm1
-[(free linker called )(VAL)(, available in )2(LZH)0( archive format from ){(ftp://x2ftp.oulu.fi/pub/msdos/programming/lang/)wl}2(x2ftp.oulu.fi){el}0(. An LZH archiver can be)]383.2 norm0
-[(found at ){(ftp://ftp.simtel.net/pub/simtelnet/msdos/arcers)wl}2(ftp.simtel.net){el}0(. There is another `free' linker \(though this one doesn't come with sources\))]372.2 norm0
-[(called )(FREELINK, available from ){(http://www.pcorner.com/tpc/old/3-101.html)wl}2(www.pcorner.com){el}0(. A third, )2(djlink)0(, written by DJ Delorie, is)]361.2 norm0
-[(available at ){(http://www.delorie.com/djgpp/16bit/djlink/)wl}2(www.delorie.com){el}0(. A fourth linker, )2(ALINK)0(, written by Anthony A.J. Williams, is available at)]350.2 norm0
-[{(http://alink.sourceforge.net)wl}2(alink.sourceforge.net){el}0(.)]339.2 norm2
-[(When linking several )2(.OBJ)0( files into a )2(.EXE)0( file, you should ensure that exactly one of them has a start point)]322.2 norm1
-[(defined \(using the )2(..start)0( special symbol defined by the )2(obj)0( format: see ){/section-7.4.6 xl}(section 7.4.6){el}(\). If no module)]311.2 norm0
-[(defines a start point, the linker will not know what value to give the entry-point field in the output file header;)]300.2 norm0
-[(if more than one defines a start point, the linker will not know )1(which)0( value to use.)]289.2 norm2
-[(An example of a NASM source file which can be assembled to a )2(.OBJ)0( file and linked on its own to a )2(.EXE)]272.2 norm1
-[(is given here. It demonstrates the basic principles of defining a stack, initialising the segment registers, and)]261.2 norm0
-[(declaring a start point. This file is also provided in the )2(test)0( subdirectory of the NASM archives, under the)]250.2 norm0
-[(name )2(objexe.asm)0(.)]239.2 norm2
-[2(segment code )]222.2 code1
-[2()]211.2 code0
-[2(..start: )]200.2 code0
-[2( mov ax,data )]189.2 code0
-[2( mov ds,ax )]178.2 code0
-[2( mov ax,stack )]167.2 code0
-[2( mov ss,ax )]156.2 code0
-[2( mov sp,stacktop)]145.2 code2
-[(This initial piece of code sets up )2(DS)0( to point to the data segment, and initializes )2(SS)0( and )2(SP)0( to point to the top)]128.2 norm1
-[(of the provided stack. Notice that interrupts are implicitly disabled for one instruction after a move into )2(SS)0(,)]117.2 norm0
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-[(precisely for this situation, so that there's no chance of an interrupt occurring between the loads of )2(SS)0( and )2(SP)]681 norm0
-[(and not having a stack to execute on.)]670 norm2
-[(Note also that the special symbol )2(..start)0( is defined at the beginning of this code, which means that will be)]653 norm1
-[(the entry point into the resulting executable file.)]642 norm2
-[2( mov dx,hello )]625 code1
-[2( mov ah,9 )]614 code0
-[2( int 0x21)]603 code2
-[(The above is the main program: load )2(DS:DX)0( with a pointer to the greeting message \()2(hello)0( is implicitly)]586 norm1
-[(relative to the segment )2(data)0(, which was loaded into )2(DS)0( in the setup code, so the full pointer is valid\), and)]575 norm0
-[(call the DOS print-string function.)]564 norm2
-[2( mov ax,0x4c00 )]547 code1
-[2( int 0x21)]536 code2
-[(This terminates the program using another DOS system call.)]519 norm3
-[2(segment data )]502 code1
-[2()]491 code0
-[2(hello: db 'hello, world', 13, 10, '$')]480 code2
-[(The data segment contains the string we want to display.)]463 norm3
-[2(segment stack stack )]446 code1
-[2( resb 64 )]435 code0
-[2(stacktop:)]424 code2
-[(The above code declares a stack segment containing 64 bytes of uninitialized stack space, and points)]407 norm1
-[2(stacktop)0( at the top of it. The directive )2(segment stack stack)0( defines a segment )1(called)0( )2(stack)0(, and)]396 norm0
-[(also of )1(type)0( )2(STACK)0(. The latter is not necessary to the correct running of the program, but linkers are likely to)]385 norm0
-[(issue warnings or errors if your program has no segment of type )2(STACK)0(.)]374 norm2
-[(The above file, when assembled into a )2(.OBJ)0( file, will link on its own to a valid )2(.EXE)0( file, which when run)]357 norm1
-[(will print `hello, world' and then exit.)]346 norm2
-[{/section-8.1.2 xa}(Using the )2(bin)0( Format To Generate )2(.EXE)0( Files)](8.1.2)326.8 subh3
-[(The )2(.EXE)0( file format is simple enough that it's possible to build a )2(.EXE)0( file by writing a pure-binary)]309.8 norm1
-[(program and sticking a 32-byte header on the front. This header is simple enough that it can be generated)]298.8 norm0
-[(using )2(DB)0( and )2(DW)0( commands by NASM itself, so that you can use the )2(bin)0( output format to directly generate)]287.8 norm0
-[2(.EXE)0( files.)]276.8 norm2
-[(Included in the NASM archives, in the )2(misc)0( subdirectory, is a file )2(exebin.mac)0( of macros. It defines three)]259.8 norm1
-[(macros: )2(EXE_begin)0(, )2(EXE_stack)0( and )2(EXE_end)0(.)]248.8 norm2
-[(To produce a )2(.EXE)0( file using this method, you should start by using )2(%include)0( to load the )2(exebin.mac)]231.8 norm1
-[(macro package into your source file. You should then issue the )2(EXE_begin)0( macro call \(which takes no)]220.8 norm0
-[(arguments\) to generate the file header data. Then write code as normal for the )2(bin)0( format \226 you can use all)]209.8 norm0
-[(three standard sections )2(.text)0(, )2(.data)0( and )2(.bss)0(. At the end of the file you should call the )2(EXE_end)0( macro)]198.8 norm0
-[(\(again, no arguments\), which defines some symbols to mark section sizes, and these symbols are referred to in)]187.8 norm0
-[(the header code generated by )2(EXE_begin)0(.)]176.8 norm2
-[(In this model, the code you end up writing starts at )2(0x100)0(, just like a )2(.COM)0( file \226 in fact, if you strip off the)]159.8 norm1
-[(32-byte header from the resulting )2(.EXE)0( file, you will have a valid )2(.COM)0( program. All the segment bases are)]148.8 norm0
-[(the same, so you are limited to a 64K program, again just like a )2(.COM)0( file. Note that an )2(ORG)0( directive is)]137.8 norm0
-[(issued by the )2(EXE_begin)0( macro, so you should not explicitly issue one of your own.)]126.8 norm2
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-[(You can't directly refer to your segment base value, unfortunately, since this would require a relocation in the)]681 norm1
-[(header, and things would get a lot more complicated. So you should get your segment base by copying it out)]670 norm0
-[(of )2(CS)0( instead.)]659 norm2
-[(On entry to your )2(.EXE)0( file, )2(SS:SP)0( are already set up to point to the top of a 2Kb stack. You can adjust the)]642 norm1
-[(default stack size of 2Kb by calling the )2(EXE_stack)0( macro. For example, to change the stack size of your)]631 norm0
-[(program to 64 bytes, you would call )2(EXE_stack 64)0(.)]620 norm2
-[(A sample program which generates a )2(.EXE)0( file in this way is given in the )2(test)0( subdirectory of the NASM)]603 norm1
-[(archive, as )2(binexe.asm)0(.)]592 norm2
-[{/section-8.2 xa}(Producing )2(.COM)0( Files)](8.2)570.6 head3
-[(While large DOS programs must be written as )2(.EXE)0( files, small ones are often better written as )2(.COM)0( files.)]553.6 norm1
-[2(.COM)0( files are pure binary, and therefore most easily produced using the )2(bin)0( output format.)]542.6 norm2
-[{/section-8.2.1 xa}(Using the )2(bin)0( Format To Generate )2(.COM)0( Files)](8.2.1)523.4 subh3
-[2(.COM)0( files expect to be loaded at offset )2(100h)0( into their segment \(though the segment may change\).)]506.4 norm1
-[(Execution then begins at )2(100h)0(, i.e. right at the start of the program. So to write a )2(.COM)0( program, you would)]495.4 norm0
-[(create a source file looking like)]484.4 norm2
-[2( org 100h )]467.4 code1
-[2()]456.4 code0
-[2(section .text )]445.4 code0
-[2()]434.4 code0
-[2(start: )]423.4 code0
-[2( ; put your code here )]412.4 code0
-[2()]401.4 code0
-[2(section .data )]390.4 code0
-[2()]379.4 code0
-[2( ; put data items here )]368.4 code0
-[2()]357.4 code0
-[2(section .bss )]346.4 code0
-[2()]335.4 code0
-[2( ; put uninitialized data here)]324.4 code2
-[(The )2(bin)0( format puts the )2(.text)0( section first in the file, so you can declare data or BSS items before)]307.4 norm1
-[(beginning to write code if you want to and the code will still end up at the front of the file where it belongs.)]296.4 norm2
-[(The BSS \(uninitialized data\) section does not take up space in the )2(.COM)0( file itself: instead, addresses of BSS)]279.4 norm1
-[(items are resolved to point at space beyond the end of the file, on the grounds that this will be free memory)]268.4 norm0
-[(when the program is run. Therefore you should not rely on your BSS being initialized to all zeros when you)]257.4 norm0
-[(run.)]246.4 norm2
-[(To assemble the above program, you should use a command line like)]229.4 norm3
-[2(nasm myprog.asm -fbin -o myprog.com)]212.4 code3
-[(The )2(bin)0( format would produce a file called )2(myprog)0( if no explicit output file name were specified, so you)]195.4 norm1
-[(have to override it and give the desired file name.)]184.4 norm2
-[{/section-8.2.2 xa}(Using the )2(obj)0( Format To Generate )2(.COM)0( Files)](8.2.2)165.2 subh3
-[(If you are writing a )2(.COM)0( program as more than one module, you may wish to assemble several )2(.OBJ)0( files)]148.2 norm1
-[(and link them together into a )2(.COM)0( program. You can do this, provided you have a linker capable of)]137.2 norm0
-[(outputting )2(.COM)0( files directly \()(TLINK does this\), or alternatively a converter program such as )2(EXE2BIN)0( to)]126.2 norm0
-[(transform the )2(.EXE)0( file output from the linker into a )2(.COM)0( file.)]115.2 norm2
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-[(If you do this, you need to take care of several things:)]681 norm3
-[(The first object file containing code should start its code segment with a line like )2(RESB 100h)0(. This is to)]664 bull1
-[(ensure that the code begins at offset )2(100h)0( relative to the beginning of the code segment, so that the linker)]653 bull0
-[(or converter program does not have to adjust address references within the file when generating the )2(.COM)]642 bull0
-[(file. Other assemblers use an )2(ORG)0( directive for this purpose, but )2(ORG)0( in NASM is a format-specific)]631 bull0
-[(directive to the )2(bin)0( output format, and does not mean the same thing as it does in MASM-compatible)]620 bull0
-[(assemblers.)]609 bull2
-[(You don't need to define a stack segment.)]592 bull3
-[(All your segments should be in the same group, so that every time your code or data references a symbol)]575 bull1
-[(offset, all offsets are relative to the same segment base. This is because, when a )2(.COM)0( file is loaded, all the)]564 bull0
-[(segment registers contain the same value.)]553 bull2
-[{/section-8.3 xa}(Producing )2(.SYS)0( Files)](8.3)531.6 head3
-[(MS-DOS device drivers \226 )2(.SYS)0( files \226 are pure binary files, similar to )2(.COM)0( files, except that they start at)]514.6 norm1
-[(origin zero rather than )2(100h)0(. Therefore, if you are writing a device driver using the )2(bin)0( format, you do not)]503.6 norm0
-[(need the )2(ORG)0( directive, since the default origin for )2(bin)0( is zero. Similarly, if you are using )2(obj)0(, you do not)]492.6 norm0
-[(need the )2(RESB 100h)0( at the start of your code segment.)]481.6 norm2
-[2(.SYS)0( files start with a header structure, containing pointers to the various routines inside the driver which do)]464.6 norm1
-[(the work. This structure should be defined at the start of the code segment, even though it is not actually code.)]453.6 norm2
-[(For more information on the format of )2(.SYS)0( files, and the data which has to go in the header structure, a list)]436.6 norm1
-[(of books is given in the Frequently Asked Questions list for the newsgroup)]425.6 norm0
-[{(news:comp.os.msdos.programmer)wl}2(comp.os.msdos.programmer){el}0(.)]414.6 norm2
-[{/section-8.4 xa}(Interfacing to 16-bit C Programs)](8.4)393.2 head3
-[(This section covers the basics of writing assembly routines that call, or are called from, C programs. To do)]376.2 norm1
-[(this, you would typically write an assembly module as a )2(.OBJ)0( file, and link it with your C modules to)]365.2 norm0
-[(produce a )(mixed-language program.)]354.2 norm2
-[{/section-8.4.1 xa}(External Symbol Names)](8.4.1)335 subh3
-[(C compilers have the convention that the names of all global symbols \(functions or data\) they define are)]318 norm1
-[(formed by prefixing an underscore to the name as it appears in the C program. So, for example, the function a)]307 norm0
-[(C programmer thinks of as )2(printf)0( appears to an assembly language programmer as )2(_printf)0(. This means)]296 norm0
-[(that in your assembly programs, you can define symbols without a leading underscore, and not have to worry)]285 norm0
-[(about name clashes with C symbols.)]274 norm2
-[(If you find the underscores inconvenient, you can define macros to replace the )2(GLOBAL)0( and )2(EXTERN)]257 norm1
-[(directives as follows:)]246 norm2
-[2(%macro cglobal 1 )]229 code1
-[2()]218 code0
-[2( global _%1 )]207 code0
-[2( %define %1 _%1 )]196 code0
-[2()]185 code0
-[2(%endmacro )]174 code0
-[2()]163 code0
-[2(%macro cextern 1 )]152 code0
-[2()]141 code0
-[2( extern _%1 )]130 code0
-[2( %define %1 _%1 )]119 code0
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-[2()]681 code0
-[2(%endmacro)]670 code2
-[(\(These forms of the macros only take one argument at a time; a )2(%rep)0( construct could solve this.\))]653 norm3
-[(If you then declare an external like this:)]636 norm3
-[2(cextern printf)]619 code3
-[(then the macro will expand it as)]602 norm3
-[2(extern _printf )]585 code1
-[2(%define printf _printf)]574 code2
-[(Thereafter, you can reference )2(printf)0( as if it was a symbol, and the preprocessor will put the leading)]557 norm1
-[(underscore on where necessary.)]546 norm2
-[(The )2(cglobal)0( macro works similarly. You must use )2(cglobal)0( before defining the symbol in question, but)]529 norm1
-[(you would have had to do that anyway if you used )2(GLOBAL)0(.)]518 norm2
-[(Also see ){/section-2.1.27 xl}(section 2.1.27){el}(.)]501 norm3
-[{/section-8.4.2 xa}(Memory Models)](8.4.2)481.8 subh3
-[(NASM contains no mechanism to support the various C memory models directly; you have to keep track)]464.8 norm1
-[(yourself of which one you are writing for. This means you have to keep track of the following things:)]453.8 norm2
-[(In models using a single code segment \(tiny, small and compact\), functions are near. This means that)]436.8 bull1
-[(function pointers, when stored in data segments or pushed on the stack as function arguments, are 16 bits)]425.8 bull0
-[(long and contain only an offset field \(the )2(CS)0( register never changes its value, and always gives the segment)]414.8 bull0
-[(part of the full function address\), and that functions are called using ordinary near )2(CALL)0( instructions and)]403.8 bull0
-[(return using )2(RETN)0( \(which, in NASM, is synonymous with )2(RET)0( anyway\). This means both that you should)]392.8 bull0
-[(write your own routines to return with )2(RETN)0(, and that you should call external C routines with near )2(CALL)]381.8 bull0
-[(instructions.)]370.8 bull2
-[(In models using more than one code segment \(medium, large and huge\), functions are far. This means that)]353.8 bull1
-[(function pointers are 32 bits long \(consisting of a 16-bit offset followed by a 16-bit segment\), and that)]342.8 bull0
-[(functions are called using )2(CALL FAR)0( \(or )2(CALL seg:offset)0(\) and return using )2(RETF)0(. Again, you)]331.8 bull0
-[(should therefore write your own routines to return with )2(RETF)0( and use )2(CALL FAR)0( to call external routines.)]320.8 bull2
-[(In models using a single data segment \(tiny, small and medium\), data pointers are 16 bits long, containing)]303.8 bull1
-[(only an offset field \(the )2(DS)0( register doesn't change its value, and always gives the segment part of the full)]292.8 bull0
-[(data item address\).)]281.8 bull2
-[(In models using more than one data segment \(compact, large and huge\), data pointers are 32 bits long,)]264.8 bull1
-[(consisting of a 16-bit offset followed by a 16-bit segment. You should still be careful not to modify )2(DS)0( in)]253.8 bull0
-[(your routines without restoring it afterwards, but )2(ES)0( is free for you to use to access the contents of 32-bit)]242.8 bull0
-[(data pointers you are passed.)]231.8 bull2
-[(The huge memory model allows single data items to exceed 64K in size. In all other memory models, you)]214.8 bull1
-[(can access the whole of a data item just by doing arithmetic on the offset field of the pointer you are given,)]203.8 bull0
-[(whether a segment field is present or not; in huge model, you have to be more careful of your pointer)]192.8 bull0
-[(arithmetic.)]181.8 bull2
-[(In most memory models, there is a )1(default)0( data segment, whose segment address is kept in )2(DS)0( throughout)]164.8 bull1
-[(the program. This data segment is typically the same segment as the stack, kept in )2(SS)0(, so that functions')]153.8 bull0
-[(local variables \(which are stored on the stack\) and global data items can both be accessed easily without)]142.8 bull0
-[(changing )2(DS)0(. Particularly large data items are typically stored in other segments. However, some memory)]131.8 bull0
-[(models \(though not the standard ones, usually\) allow the assumption that )2(SS)0( and )2(DS)0( hold the same value to)]120.8 bull0
-[(be removed. Be careful about functions' local variables in this latter case.)]109.8 bull2
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-[(In models with a single code segment, the segment is called )2(_TEXT)0(, so your code segment must also go by)]681 norm1
-[(this name in order to be linked into the same place as the main code segment. In models with a single data)]670 norm0
-[(segment, or with a default data segment, it is called )2(_DATA)0(.)]659 norm2
-[{/section-8.4.3 xa}(Function Definitions and Function Calls)](8.4.3)639.8 subh3
-[(The )(C calling convention in 16-bit programs is as follows. In the following description, the words )1(caller)0( and)]622.8 norm1
-[1(callee)0( are used to denote the function doing the calling and the function which gets called.)]611.8 norm2
-[(The caller pushes the function's parameters on the stack, one after another, in reverse order \(right to left, so)]594.8 bull1
-[(that the first argument specified to the function is pushed last\).)]583.8 bull2
-[(The caller then executes a )2(CALL)0( instruction to pass control to the callee. This )2(CALL)0( is either near or far)]566.8 bull1
-[(depending on the memory model.)]555.8 bull2
-[(The callee receives control, and typically \(although this is not actually necessary, in functions which do not)]538.8 bull1
-[(need to access their parameters\) starts by saving the value of )2(SP)0( in )2(BP)0( so as to be able to use )2(BP)0( as a base)]527.8 bull0
-[(pointer to find its parameters on the stack. However, the caller was probably doing this too, so part of the)]516.8 bull0
-[(calling convention states that )2(BP)0( must be preserved by any C function. Hence the callee, if it is going to set)]505.8 bull0
-[(up )2(BP)0( as a )1(frame pointer)0(, must push the previous value first.)]494.8 bull2
-[(The callee may then access its parameters relative to )2(BP)0(. The word at )2([BP])0( holds the previous value of )2(BP)]477.8 bull1
-[(as it was pushed; the next word, at )2([BP+2])0(, holds the offset part of the return address, pushed implicitly)]466.8 bull0
-[(by )2(CALL)0(. In a small-model \(near\) function, the parameters start after that, at )2([BP+4])0(; in a large-model)]455.8 bull0
-[(\(far\) function, the segment part of the return address lives at )2([BP+4])0(, and the parameters begin at)]444.8 bull0
-[2([BP+6])0(. The leftmost parameter of the function, since it was pushed last, is accessible at this offset from)]433.8 bull0
-[2(BP)0(; the others follow, at successively greater offsets. Thus, in a function such as )2(printf)0( which takes a)]422.8 bull0
-[(variable number of parameters, the pushing of the parameters in reverse order means that the function)]411.8 bull0
-[(knows where to find its first parameter, which tells it the number and type of the remaining ones.)]400.8 bull2
-[(The callee may also wish to decrease )2(SP)0( further, so as to allocate space on the stack for local variables,)]383.8 bull1
-[(which will then be accessible at negative offsets from )2(BP)0(.)]372.8 bull2
-[(The callee, if it wishes to return a value to the caller, should leave the value in )2(AL)0(, )2(AX)0( or )2(DX:AX)]355.8 bull1
-[(depending on the size of the value. Floating-point results are sometimes \(depending on the compiler\))]344.8 bull0
-[(returned in )2(ST0)0(.)]333.8 bull2
-[(Once the callee has finished processing, it restores )2(SP)0( from )2(BP)0( if it had allocated local stack space, then)]316.8 bull1
-[(pops the previous value of )2(BP)0(, and returns via )2(RETN)0( or )2(RETF)0( depending on memory model.)]305.8 bull2
-[(When the caller regains control from the callee, the function parameters are still on the stack, so it typically)]288.8 bull1
-[(adds an immediate constant to )2(SP)0( to remove them \(instead of executing a number of slow )2(POP)]277.8 bull0
-[(instructions\). Thus, if a function is accidentally called with the wrong number of parameters due to a)]266.8 bull0
-[(prototype mismatch, the stack will still be returned to a sensible state since the caller, which )1(knows)0( how)]255.8 bull0
-[(many parameters it pushed, does the removing.)]244.8 bull2
-[(It is instructive to compare this calling convention with that for Pascal programs \(described in ){/section-8.5.1 xl}(section 8.5.1){el}(\).)]227.8 norm1
-[(Pascal has a simpler convention, since no functions have variable numbers of parameters. Therefore the callee)]216.8 norm0
-[(knows how many parameters it should have been passed, and is able to deallocate them from the stack itself)]205.8 norm0
-[(by passing an immediate argument to the )2(RET)0( or )2(RETF)0( instruction, so the caller does not have to do it. Also,)]194.8 norm0
-[(the parameters are pushed in left-to-right order, not right-to-left, which means that a compiler can give)]183.8 norm0
-[(better guarantees about sequence points without performance suffering.)]172.8 norm2
-[(Thus, you would define a function in C style in the following way. The following example is for small model:)]155.8 norm3
-[2(global _myfunc )]138.8 code1
-[2()]127.8 code0
-[2(_myfunc: )]116.8 code0
-[2( push bp )]105.8 code0
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-[2( mov bp,sp )]681 code0
-[2( sub sp,0x40 ; 64 bytes of local stack space )]670 code0
-[2( mov bx,[bp+4] ; first parameter to function )]659 code0
-[2()]648 code0
-[2( ; some more code )]637 code0
-[2()]626 code0
-[2( mov sp,bp ; undo "sub sp,0x40" above )]615 code0
-[2( pop bp )]604 code0
-[2( ret)]593 code2
-[(For a large-model function, you would replace )2(RET)0( by )2(RETF)0(, and look for the first parameter at )2([BP+6])]576 norm1
-[(instead of )2([BP+4])0(. Of course, if one of the parameters is a pointer, then the offsets of )1(subsequent)0( parameters)]565 norm0
-[(will change depending on the memory model as well: far pointers take up four bytes on the stack when passed)]554 norm0
-[(as a parameter, whereas near pointers take up two.)]543 norm2
-[(At the other end of the process, to call a C function from your assembly code, you would do something like)]526 norm1
-[(this:)]515 norm2
-[2(extern _printf )]498 code1
-[2()]487 code0
-[2( ; and then, further down... )]476 code0
-[2()]465 code0
-[2( push word [myint] ; one of my integer variables )]454 code0
-[2( push word mystring ; pointer into my data segment )]443 code0
-[2( call _printf )]432 code0
-[2( add sp,byte 4 ; `byte' saves space )]421 code0
-[2()]410 code0
-[2( ; then those data items... )]399 code0
-[2()]388 code0
-[2(segment _DATA )]377 code0
-[2()]366 code0
-[2(myint dw 1234 )]355 code0
-[2(mystring db 'This number -> %d <- should be 1234',10,0)]344 code2
-[(This piece of code is the small-model assembly equivalent of the C code)]327 norm3
-[2( int myint = 1234; )]310 code1
-[2( printf\("This number -> %d <- should be 1234\\n", myint\);)]299 code2
-[(In large model, the function-call code might look more like this. In this example, it is assumed that )2(DS)]282 norm1
-[(already holds the segment base of the segment )2(_DATA)0(. If not, you would have to initialize it first.)]271 norm2
-[2( push word [myint] )]254 code1
-[2( push word seg mystring ; Now push the segment, and... )]243 code0
-[2( push word mystring ; ... offset of "mystring" )]232 code0
-[2( call far _printf )]221 code0
-[2( add sp,byte 6)]210 code2
-[(The integer value still takes up one word on the stack, since large model does not affect the size of the )2(int)]193 norm1
-[(data type. The first argument \(pushed last\) to )2(printf)0(, however, is a data pointer, and therefore has to)]182 norm0
-[(contain a segment and offset part. The segment should be stored second in memory, and therefore must be)]171 norm0
-[(pushed first. \(Of course, )2(PUSH DS)0( would have been a shorter instruction than)]160 norm0
-[2(PUSH WORD SEG mystring)0(, if )2(DS)0( was set up as the above example assumed.\) Then the actual call)]149 norm0
-[(becomes a far call, since functions expect far calls in large model; and )2(SP)0( has to be increased by 6 rather than)]138 norm0
-[(4 afterwards to make up for the extra word of parameters.)]127 norm2
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-[{/section-8.4.4 xa}(Accessing Data Items)](8.4.4)678.8 subh3
-[(To get at the contents of C variables, or to declare variables which C can access, you need only declare the)]661.8 norm1
-[(names as )2(GLOBAL)0( or )2(EXTERN)0(. \(Again, the names require leading underscores, as stated in ){/section-8.4.1 xl}(section 8.4.1){el}(.\))]650.8 norm0
-[(Thus, a C variable declared as )2(int i)0( can be accessed from assembler as)]639.8 norm2
-[2(extern _i )]622.8 code1
-[2()]611.8 code0
-[2( mov ax,[_i])]600.8 code2
-[(And to declare your own integer variable which C programs can access as )2(extern int j)0(, you do this)]583.8 norm1
-[(\(making sure you are assembling in the )2(_DATA)0( segment, if necessary\):)]572.8 norm2
-[2(global _j )]555.8 code1
-[2()]544.8 code0
-[2(_j dw 0)]533.8 code2
-[(To access a C array, you need to know the size of the components of the array. For example, )2(int)0( variables)]516.8 norm1
-[(are two bytes long, so if a C program declares an array as )2(int a[10])0(, you can access )2(a[3])0( by coding)]505.8 norm0
-[2(mov ax,[_a+6])0(. \(The byte offset 6 is obtained by multiplying the desired array index, 3, by the size of the)]494.8 norm0
-[(array element, 2.\) The sizes of the C base types in 16-bit compilers are: 1 for )2(char)0(, 2 for )2(short)0( and )2(int)0(, 4)]483.8 norm0
-[(for )2(long)0( and )2(float)0(, and 8 for )2(double)0(.)]472.8 norm2
-[(To access a C )(data structure, you need to know the offset from the base of the structure to the field you are)]455.8 norm1
-[(interested in. You can either do this by converting the C structure definition into a NASM structure definition)]444.8 norm0
-[(\(using )2(STRUC)0(\), or by calculating the one offset and using just that.)]433.8 norm2
-[(To do either of these, you should read your C compiler's manual to find out how it organizes data structures.)]416.8 norm1
-[(NASM gives no special alignment to structure members in its own )2(STRUC)0( macro, so you have to specify)]405.8 norm0
-[(alignment yourself if the C compiler generates it. Typically, you might find that a structure like)]394.8 norm2
-[2(struct { )]377.8 code1
-[2( char c; )]366.8 code0
-[2( int i; )]355.8 code0
-[2(} foo;)]344.8 code2
-[(might be four bytes long rather than three, since the )2(int)0( field would be aligned to a two-byte boundary.)]327.8 norm1
-[(However, this sort of feature tends to be a configurable option in the C compiler, either using command-line)]316.8 norm0
-[(options or )2(#pragma)0( lines, so you have to find out how your own compiler does it.)]305.8 norm2
-[{/section-8.4.5 xa}2(c16.mac)0(: Helper Macros for the 16-bit C Interface)](8.4.5)286.6 subh3
-[(Included in the NASM archives, in the )2(misc)0( directory, is a file )2(c16.mac)0( of macros. It defines three macros:)]269.6 norm1
-[2(proc)0(, )2(arg)0( and )2(endproc)0(. These are intended to be used for C-style procedure definitions, and they)]258.6 norm0
-[(automate a lot of the work involved in keeping track of the calling convention.)]247.6 norm2
-[(\(An alternative, TASM compatible form of )2(arg)0( is also now built into NASM's preprocessor. See ){/section-4.8 xl}(section 4.8){el}]230.6 norm1
-[(for details.\))]219.6 norm2
-[(An example of an assembly function using the macro set is given here:)]202.6 norm3
-[2(proc _nearproc )]185.6 code1
-[2()]174.6 code0
-[2(%$i arg )]163.6 code0
-[2(%$j arg )]152.6 code0
-[2( mov ax,[bp + %$i] )]141.6 code0
-[2( mov bx,[bp + %$j] )]130.6 code0
-[2( add ax,[bx] )]119.6 code0
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-[2()]681 code0
-[2(endproc)]670 code2
-[(This defines )2(_nearproc)0( to be a procedure taking two arguments, the first \()2(i)0(\) an integer and the second \()2(j)0(\))]653 norm1
-[(a pointer to an integer. It returns )2(i + *j)0(.)]642 norm2
-[(Note that the )2(arg)0( macro has an )2(EQU)0( as the first line of its expansion, and since the label before the macro call)]625 norm1
-[(gets prepended to the first line of the expanded macro, the )2(EQU)0( works, defining )2(%$i)0( to be an offset from )2(BP)0(.)]614 norm0
-[(A context-local variable is used, local to the context pushed by the )2(proc)0( macro and popped by the)]603 norm0
-[2(endproc)0( macro, so that the same argument name can be used in later procedures. Of course, you don't )1(have)]592 norm0
-[(to do that.)]581 norm2
-[(The macro set produces code for near functions \(tiny, small and compact-model code\) by default. You can)]564 norm1
-[(have it generate far functions \(medium, large and huge-model code\) by means of coding)]553 norm0
-[2(%define FARCODE)0(. This changes the kind of return instruction generated by )2(endproc)0(, and also changes)]542 norm0
-[(the starting point for the argument offsets. The macro set contains no intrinsic dependency on whether data)]531 norm0
-[(pointers are far or not.)]520 norm2
-[2(arg)0( can take an optional parameter, giving the size of the argument. If no size is given, 2 is assumed, since it)]503 norm1
-[(is likely that many function parameters will be of type )2(int)0(.)]492 norm2
-[(The large-model equivalent of the above function would look like this:)]475 norm3
-[2(%define FARCODE )]458 code1
-[2()]447 code0
-[2(proc _farproc )]436 code0
-[2()]425 code0
-[2(%$i arg )]414 code0
-[2(%$j arg 4 )]403 code0
-[2( mov ax,[bp + %$i] )]392 code0
-[2( mov bx,[bp + %$j] )]381 code0
-[2( mov es,[bp + %$j + 2] )]370 code0
-[2( add ax,[bx] )]359 code0
-[2()]348 code0
-[2(endproc)]337 code2
-[(This makes use of the argument to the )2(arg)0( macro to define a parameter of size 4, because )2(j)0( is now a far)]320 norm1
-[(pointer. When we load from )2(j)0(, we must load a segment and an offset.)]309 norm2
-[{/section-8.5 xa}(Interfacing to )(Borland Pascal Programs)](8.5)287.6 head3
-[(Interfacing to Borland Pascal programs is similar in concept to interfacing to 16-bit C programs. The)]270.6 norm1
-[(differences are:)]259.6 norm2
-[(The leading underscore required for interfacing to C programs is not required for Pascal.)]242.6 bull3
-[(The memory model is always large: functions are far, data pointers are far, and no data item can be more)]225.6 bull1
-[(than 64K long. \(Actually, some functions are near, but only those functions that are local to a Pascal unit)]214.6 bull0
-[(and never called from outside it. All assembly functions that Pascal calls, and all Pascal functions that)]203.6 bull0
-[(assembly routines are able to call, are far.\) However, all static data declared in a Pascal program goes into)]192.6 bull0
-[(the default data segment, which is the one whose segment address will be in )2(DS)0( when control is passed to)]181.6 bull0
-[(your assembly code. The only things that do not live in the default data segment are local variables \(they)]170.6 bull0
-[(live in the stack segment\) and dynamically allocated variables. All data )1(pointers)0(, however, are far.)]159.6 bull2
-[(The function calling convention is different \226 described below.)]142.6 bull3
-[(Some data types, such as strings, are stored differently.)]125.6 bull3
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-[(There are restrictions on the segment names you are allowed to use \226 Borland Pascal will ignore code or)]681 bull1
-[(data declared in a segment it doesn't like the name of. The restrictions are described below.)]670 bull2
-[{/section-8.5.1 xa}(The Pascal Calling Convention)](8.5.1)650.8 subh3
-[(The 16-bit Pascal calling convention is as follows. In the following description, the words )1(caller)0( and )1(callee)]633.8 norm1
-[(are used to denote the function doing the calling and the function which gets called.)]622.8 norm2
-[(The caller pushes the function's parameters on the stack, one after another, in normal order \(left to right, so)]605.8 bull1
-[(that the first argument specified to the function is pushed first\).)]594.8 bull2
-[(The caller then executes a far )2(CALL)0( instruction to pass control to the callee.)]577.8 bull3
-[(The callee receives control, and typically \(although this is not actually necessary, in functions which do not)]560.8 bull1
-[(need to access their parameters\) starts by saving the value of )2(SP)0( in )2(BP)0( so as to be able to use )2(BP)0( as a base)]549.8 bull0
-[(pointer to find its parameters on the stack. However, the caller was probably doing this too, so part of the)]538.8 bull0
-[(calling convention states that )2(BP)0( must be preserved by any function. Hence the callee, if it is going to set)]527.8 bull0
-[(up )2(BP)0( as a )(frame pointer, must push the previous value first.)]516.8 bull2
-[(The callee may then access its parameters relative to )2(BP)0(. The word at )2([BP])0( holds the previous value of )2(BP)]499.8 bull1
-[(as it was pushed. The next word, at )2([BP+2])0(, holds the offset part of the return address, and the next one at)]488.8 bull0
-[2([BP+4])0( the segment part. The parameters begin at )2([BP+6])0(. The rightmost parameter of the function,)]477.8 bull0
-[(since it was pushed last, is accessible at this offset from )2(BP)0(; the others follow, at successively greater)]466.8 bull0
-[(offsets.)]455.8 bull2
-[(The callee may also wish to decrease )2(SP)0( further, so as to allocate space on the stack for local variables,)]438.8 bull1
-[(which will then be accessible at negative offsets from )2(BP)0(.)]427.8 bull2
-[(The callee, if it wishes to return a value to the caller, should leave the value in )2(AL)0(, )2(AX)0( or )2(DX:AX)]410.8 bull1
-[(depending on the size of the value. Floating-point results are returned in )2(ST0)0(. Results of type )2(Real)]399.8 bull0
-[(\(Borland's own custom floating-point data type, not handled directly by the FPU\) are returned in)]388.8 bull0
-[2(DX:BX:AX)0(. To return a result of type )2(String)0(, the caller pushes a pointer to a temporary string before)]377.8 bull0
-[(pushing the parameters, and the callee places the returned string value at that location. The pointer is not a)]366.8 bull0
-[(parameter, and should not be removed from the stack by the )2(RETF)0( instruction.)]355.8 bull2
-[(Once the callee has finished processing, it restores )2(SP)0( from )2(BP)0( if it had allocated local stack space, then)]338.8 bull1
-[(pops the previous value of )2(BP)0(, and returns via )2(RETF)0(. It uses the form of )2(RETF)0( with an immediate)]327.8 bull0
-[(parameter, giving the number of bytes taken up by the parameters on the stack. This causes the parameters)]316.8 bull0
-[(to be removed from the stack as a side effect of the return instruction.)]305.8 bull2
-[(When the caller regains control from the callee, the function parameters have already been removed from)]288.8 bull1
-[(the stack, so it needs to do nothing further.)]277.8 bull2
-[(Thus, you would define a function in Pascal style, taking two )2(Integer)0(\226type parameters, in the following)]260.8 norm1
-[(way:)]249.8 norm2
-[2(global myfunc )]232.8 code1
-[2()]221.8 code0
-[2(myfunc: push bp )]210.8 code0
-[2( mov bp,sp )]199.8 code0
-[2( sub sp,0x40 ; 64 bytes of local stack space )]188.8 code0
-[2( mov bx,[bp+8] ; first parameter to function )]177.8 code0
-[2( mov bx,[bp+6] ; second parameter to function )]166.8 code0
-[2()]155.8 code0
-[2( ; some more code )]144.8 code0
-[2()]133.8 code0
-[2( mov sp,bp ; undo "sub sp,0x40" above )]122.8 code0
-[2( pop bp )]111.8 code0
-[2( retf 4 ; total size of params is 4)]100.8 code2
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-[(At the other end of the process, to call a Pascal function from your assembly code, you would do something)]681 norm1
-[(like this:)]670 norm2
-[2(extern SomeFunc )]653 code1
-[2()]642 code0
-[2( ; and then, further down... )]631 code0
-[2()]620 code0
-[2( push word seg mystring ; Now push the segment, and... )]609 code0
-[2( push word mystring ; ... offset of "mystring" )]598 code0
-[2( push word [myint] ; one of my variables )]587 code0
-[2( call far SomeFunc)]576 code2
-[(This is equivalent to the Pascal code)]559 norm3
-[2(procedure SomeFunc\(String: PChar; Int: Integer\); )]542 code1
-[2( SomeFunc\(@mystring, myint\);)]531 code2
-[{/section-8.5.2 xa}(Borland Pascal )(Segment Name Restrictions)](8.5.2)511.8 subh3
-[(Since Borland Pascal's internal unit file format is completely different from )2(OBJ)0(, it only makes a very)]494.8 norm1
-[(sketchy job of actually reading and understanding the various information contained in a real )2(OBJ)0( file when it)]483.8 norm0
-[(links that in. Therefore an object file intended to be linked to a Pascal program must obey a number of)]472.8 norm0
-[(restrictions:)]461.8 norm2
-[(Procedures and functions must be in a segment whose name is either )2(CODE)0(, )2(CSEG)0(, or something ending in)]444.8 bull1
-[2(_TEXT)0(.)]433.8 bull2
-[(initialized data must be in a segment whose name is either )2(CONST)0( or something ending in )2(_DATA)0(.)]416.8 bull3
-[(Uninitialized data must be in a segment whose name is either )2(DATA)0(, )2(DSEG)0(, or something ending in )2(_BSS)0(.)]399.8 bull3
-[(Any other segments in the object file are completely ignored. )2(GROUP)0( directives and segment attributes are)]382.8 bull1
-[(also ignored.)]371.8 bull2
-[{/section-8.5.3 xa}(Using )2(c16.mac)0( With Pascal Programs)](8.5.3)352.6 subh3
-[(The )2(c16.mac)0( macro package, described in ){/section-8.4.5 xl}(section 8.4.5){el}(, can also be used to simplify writing functions to be)]335.6 norm1
-[(called from Pascal programs, if you code )2(%define PASCAL)0(. This definition ensures that functions are far)]324.6 norm0
-[(\(it implies )2(FARCODE)0(\), and also causes procedure return instructions to be generated with an operand.)]313.6 norm2
-[(Defining )2(PASCAL)0( does not change the code which calculates the argument offsets; you must declare your)]296.6 norm1
-[(function's arguments in reverse order. For example:)]285.6 norm2
-[2(%define PASCAL )]268.6 code1
-[2()]257.6 code0
-[2(proc _pascalproc )]246.6 code0
-[2()]235.6 code0
-[2(%$j arg 4 )]224.6 code0
-[2(%$i arg )]213.6 code0
-[2( mov ax,[bp + %$i] )]202.6 code0
-[2( mov bx,[bp + %$j] )]191.6 code0
-[2( mov es,[bp + %$j + 2] )]180.6 code0
-[2( add ax,[bx] )]169.6 code0
-[2()]158.6 code0
-[2(endproc)]147.6 code2
-[(This defines the same routine, conceptually, as the example in ){/section-8.4.5 xl}(section 8.4.5){el}(: it defines a function taking two)]130.6 norm1
-[(arguments, an integer and a pointer to an integer, which returns the sum of the integer and the contents of the)]119.6 norm0
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-[(pointer. The only difference between this code and the large-model C version is that )2(PASCAL)0( is defined)]681 norm0
-[(instead of )2(FARCODE)0(, and that the arguments are declared in reverse order.)]670 norm2
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-[{/chapter-9 xa}(Chapter 9: Writing 32-bit Code \(Unix, Win32, DJGPP\))]642.8 chap3
-[(This chapter attempts to cover some of the common issues involved when writing 32-bit code, to run under)]607.8 norm1
-[(Win32 or Unix, or to be linked with C code generated by a Unix-style C compiler such as )(DJGPP. It covers)]596.8 norm0
-[(how to write assembly code to interface with 32-bit C routines, and how to write position-independent code)]585.8 norm0
-[(for shared libraries.)]574.8 norm2
-[(Almost all 32-bit code, and in particular all code running under )2(Win32)0(, )2(DJGPP)0( or any of the PC Unix)]557.8 norm1
-[(variants, runs in )1(flat)0( memory model. This means that the segment registers and paging have already been set)]546.8 norm0
-[(up to give you the same 32-bit 4Gb address space no matter what segment you work relative to, and that you)]535.8 norm0
-[(should ignore all segment registers completely. When writing flat-model application code, you never need to)]524.8 norm0
-[(use a segment override or modify any segment register, and the code-section addresses you pass to )2(CALL)0( and)]513.8 norm0
-[2(JMP)0( live in the same address space as the data-section addresses you access your variables by and the)]502.8 norm0
-[(stack-section addresses you access local variables and procedure parameters by. Every address is 32 bits long)]491.8 norm0
-[(and contains only an offset part.)]480.8 norm2
-[{/section-9.1 xa}(Interfacing to 32-bit C Programs)](9.1)459.4 head3
-[(A lot of the discussion in ){/section-8.4 xl}(section 8.4){el}(, about interfacing to 16-bit C programs, still applies when working in 32)]442.4 norm1
-[(bits. The absence of memory models or segmentation worries simplifies things a lot.)]431.4 norm2
-[{/section-9.1.1 xa}(External Symbol Names)](9.1.1)412.2 subh3
-[(Most 32-bit C compilers share the convention used by 16-bit compilers, that the names of all global symbols)]395.2 norm1
-[(\(functions or data\) they define are formed by prefixing an underscore to the name as it appears in the C)]384.2 norm0
-[(program. However, not all of them do: the )2(ELF)0( specification states that C symbols do )1(not)0( have a leading)]373.2 norm0
-[(underscore on their assembly-language names.)]362.2 norm2
-[(The older Linux )2(a.out)0( C compiler, all )2(Win32)0( compilers, )2(DJGPP)0(, and )2(NetBSD)0( and )2(FreeBSD)0(, all use the)]345.2 norm1
-[(leading underscore; for these compilers, the macros )2(cextern)0( and )2(cglobal)0(, as given in ){/section-8.4.1 xl}(section 8.4.1){el}(, will)]334.2 norm0
-[(still work. For )2(ELF)0(, though, the leading underscore should not be used.)]323.2 norm2
-[(See also ){/section-2.1.27 xl}(section 2.1.27){el}(.)]306.2 norm3
-[{/section-9.1.2 xa}(Function Definitions and Function Calls)](9.1.2)287 subh3
-[(The )(C calling convention in 32-bit programs is as follows. In the following description, the words )1(caller)0( and)]270 norm1
-[1(callee)0( are used to denote the function doing the calling and the function which gets called.)]259 norm2
-[(The caller pushes the function's parameters on the stack, one after another, in reverse order \(right to left, so)]242 bull1
-[(that the first argument specified to the function is pushed last\).)]231 bull2
-[(The caller then executes a near )2(CALL)0( instruction to pass control to the callee.)]214 bull3
-[(The callee receives control, and typically \(although this is not actually necessary, in functions which do not)]197 bull1
-[(need to access their parameters\) starts by saving the value of )2(ESP)0( in )2(EBP)0( so as to be able to use )2(EBP)0( as a)]186 bull0
-[(base pointer to find its parameters on the stack. However, the caller was probably doing this too, so part of)]175 bull0
-[(the calling convention states that )2(EBP)0( must be preserved by any C function. Hence the callee, if it is going)]164 bull0
-[(to set up )2(EBP)0( as a )(frame pointer, must push the previous value first.)]153 bull2
-[(The callee may then access its parameters relative to )2(EBP)0(. The doubleword at )2([EBP])0( holds the previous)]136 bull1
-[(value of )2(EBP)0( as it was pushed; the next doubleword, at )2([EBP+4])0(, holds the return address, pushed)]125 bull0
-[(implicitly by )2(CALL)0(. The parameters start after that, at )2([EBP+8])0(. The leftmost parameter of the function,)]114 bull0
-[(since it was pushed last, is accessible at this offset from )2(EBP)0(; the others follow, at successively greater)]103 bull0
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-[(offsets. Thus, in a function such as )2(printf)0( which takes a variable number of parameters, the pushing of)]681 bull0
-[(the parameters in reverse order means that the function knows where to find its first parameter, which tells)]670 bull0
-[(it the number and type of the remaining ones.)]659 bull2
-[(The callee may also wish to decrease )2(ESP)0( further, so as to allocate space on the stack for local variables,)]642 bull1
-[(which will then be accessible at negative offsets from )2(EBP)0(.)]631 bull2
-[(The callee, if it wishes to return a value to the caller, should leave the value in )2(AL)0(, )2(AX)0( or )2(EAX)0( depending)]614 bull1
-[(on the size of the value. Floating-point results are typically returned in )2(ST0)0(.)]603 bull2
-[(Once the callee has finished processing, it restores )2(ESP)0( from )2(EBP)0( if it had allocated local stack space, then)]586 bull1
-[(pops the previous value of )2(EBP)0(, and returns via )2(RET)0( \(equivalently, )2(RETN)0(\).)]575 bull2
-[(When the caller regains control from the callee, the function parameters are still on the stack, so it typically)]558 bull1
-[(adds an immediate constant to )2(ESP)0( to remove them \(instead of executing a number of slow )2(POP)]547 bull0
-[(instructions\). Thus, if a function is accidentally called with the wrong number of parameters due to a)]536 bull0
-[(prototype mismatch, the stack will still be returned to a sensible state since the caller, which )1(knows)0( how)]525 bull0
-[(many parameters it pushed, does the removing.)]514 bull2
-[(There is an alternative calling convention used by Win32 programs for Windows API calls, and also for)]497 norm1
-[(functions called )1(by)0( the Windows API such as window procedures: they follow what Microsoft calls the)]486 norm0
-[2(__stdcall)0( convention. This is slightly closer to the Pascal convention, in that the callee clears the stack by)]475 norm0
-[(passing a parameter to the )2(RET)0( instruction. However, the parameters are still pushed in right-to-left order.)]464 norm2
-[(Thus, you would define a function in C style in the following way:)]447 norm3
-[2(global _myfunc )]430 code1
-[2()]419 code0
-[2(_myfunc: )]408 code0
-[2( push ebp )]397 code0
-[2( mov ebp,esp )]386 code0
-[2( sub esp,0x40 ; 64 bytes of local stack space )]375 code0
-[2( mov ebx,[ebp+8] ; first parameter to function )]364 code0
-[2()]353 code0
-[2( ; some more code )]342 code0
-[2()]331 code0
-[2( leave ; mov esp,ebp / pop ebp )]320 code0
-[2( ret)]309 code2
-[(At the other end of the process, to call a C function from your assembly code, you would do something like)]292 norm1
-[(this:)]281 norm2
-[2(extern _printf )]264 code1
-[2()]253 code0
-[2( ; and then, further down... )]242 code0
-[2()]231 code0
-[2( push dword [myint] ; one of my integer variables )]220 code0
-[2( push dword mystring ; pointer into my data segment )]209 code0
-[2( call _printf )]198 code0
-[2( add esp,byte 8 ; `byte' saves space )]187 code0
-[2()]176 code0
-[2( ; then those data items... )]165 code0
-[2()]154 code0
-[2(segment _DATA )]143 code0
-[2()]132 code0
-[2(myint dd 1234 )]121 code0
-[2(mystring db 'This number -> %d <- should be 1234',10,0)]110 code2
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-[(This piece of code is the assembly equivalent of the C code)]681 norm3
-[2( int myint = 1234; )]664 code1
-[2( printf\("This number -> %d <- should be 1234\\n", myint\);)]653 code2
-[{/section-9.1.3 xa}(Accessing Data Items)](9.1.3)633.8 subh3
-[(To get at the contents of C variables, or to declare variables which C can access, you need only declare the)]616.8 norm1
-[(names as )2(GLOBAL)0( or )2(EXTERN)0(. \(Again, the names require leading underscores, as stated in ){/section-9.1.1 xl}(section 9.1.1){el}(.\))]605.8 norm0
-[(Thus, a C variable declared as )2(int i)0( can be accessed from assembler as)]594.8 norm2
-[2( extern _i )]577.8 code1
-[2( mov eax,[_i])]566.8 code2
-[(And to declare your own integer variable which C programs can access as )2(extern int j)0(, you do this)]549.8 norm1
-[(\(making sure you are assembling in the )2(_DATA)0( segment, if necessary\):)]538.8 norm2
-[2( global _j )]521.8 code1
-[2(_j dd 0)]510.8 code2
-[(To access a C array, you need to know the size of the components of the array. For example, )2(int)0( variables)]493.8 norm1
-[(are four bytes long, so if a C program declares an array as )2(int a[10])0(, you can access )2(a[3])0( by coding)]482.8 norm0
-[2(mov ax,[_a+12])0(. \(The byte offset 12 is obtained by multiplying the desired array index, 3, by the size of)]471.8 norm0
-[(the array element, 4.\) The sizes of the C base types in 32-bit compilers are: 1 for )2(char)0(, 2 for )2(short)0(, 4 for)]460.8 norm0
-[2(int)0(, )2(long)0( and )2(float)0(, and 8 for )2(double)0(. Pointers, being 32-bit addresses, are also 4 bytes long.)]449.8 norm2
-[(To access a C )(data structure, you need to know the offset from the base of the structure to the field you are)]432.8 norm1
-[(interested in. You can either do this by converting the C structure definition into a NASM structure definition)]421.8 norm0
-[(\(using )2(STRUC)0(\), or by calculating the one offset and using just that.)]410.8 norm2
-[(To do either of these, you should read your C compiler's manual to find out how it organizes data structures.)]393.8 norm1
-[(NASM gives no special alignment to structure members in its own )2(STRUC)0( macro, so you have to specify)]382.8 norm0
-[(alignment yourself if the C compiler generates it. Typically, you might find that a structure like)]371.8 norm2
-[2(struct { )]354.8 code1
-[2( char c; )]343.8 code0
-[2( int i; )]332.8 code0
-[2(} foo;)]321.8 code2
-[(might be eight bytes long rather than five, since the )2(int)0( field would be aligned to a four-byte boundary.)]304.8 norm1
-[(However, this sort of feature is sometimes a configurable option in the C compiler, either using)]293.8 norm0
-[(command-line options or )2(#pragma)0( lines, so you have to find out how your own compiler does it.)]282.8 norm2
-[{/section-9.1.4 xa}2(c32.mac)0(: Helper Macros for the 32-bit C Interface)](9.1.4)263.6 subh3
-[(Included in the NASM archives, in the )2(misc)0( directory, is a file )2(c32.mac)0( of macros. It defines three macros:)]246.6 norm1
-[2(proc)0(, )2(arg)0( and )2(endproc)0(. These are intended to be used for C-style procedure definitions, and they)]235.6 norm0
-[(automate a lot of the work involved in keeping track of the calling convention.)]224.6 norm2
-[(An example of an assembly function using the macro set is given here:)]207.6 norm3
-[2(proc _proc32 )]190.6 code1
-[2()]179.6 code0
-[2(%$i arg )]168.6 code0
-[2(%$j arg )]157.6 code0
-[2( mov eax,[ebp + %$i] )]146.6 code0
-[2( mov ebx,[ebp + %$j] )]135.6 code0
-[2( add eax,[ebx] )]124.6 code0
-[2()]113.6 code0
-[2(endproc)]102.6 code2
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-[(This defines )2(_proc32)0( to be a procedure taking two arguments, the first \()2(i)0(\) an integer and the second \()2(j)0(\) a)]681 norm1
-[(pointer to an integer. It returns )2(i + *j)0(.)]670 norm2
-[(Note that the )2(arg)0( macro has an )2(EQU)0( as the first line of its expansion, and since the label before the macro call)]653 norm1
-[(gets prepended to the first line of the expanded macro, the )2(EQU)0( works, defining )2(%$i)0( to be an offset from )2(BP)0(.)]642 norm0
-[(A context-local variable is used, local to the context pushed by the )2(proc)0( macro and popped by the)]631 norm0
-[2(endproc)0( macro, so that the same argument name can be used in later procedures. Of course, you don't )1(have)]620 norm0
-[(to do that.)]609 norm2
-[2(arg)0( can take an optional parameter, giving the size of the argument. If no size is given, 4 is assumed, since it)]592 norm1
-[(is likely that many function parameters will be of type )2(int)0( or pointers.)]581 norm2
-[{/section-9.2 xa}(Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF )(Shared Libraries)](9.2)559.6 head3
-[2(ELF)0( replaced the older )2(a.out)0( object file format under Linux because it contains support for)]542.6 norm1
-[(position-independent code \()(PIC\), which makes writing shared libraries much easier. NASM supports the )2(ELF)]531.6 norm0
-[(position-independent code features, so you can write Linux )2(ELF)0( shared libraries in NASM.)]520.6 norm2
-[(NetBSD, and its close cousins )(FreeBSD and )(OpenBSD, take a different approach by hacking PIC support into)]503.6 norm1
-[(the )2(a.out)0( format. NASM supports this as the )2(aoutb)0( output format, so you can write )(BSD shared libraries)]492.6 norm0
-[(in NASM too.)]481.6 norm2
-[(The operating system loads a PIC shared library by memory-mapping the library file at an arbitrarily chosen)]464.6 norm1
-[(point in the address space of the running process. The contents of the library's code section must therefore not)]453.6 norm0
-[(depend on where it is loaded in memory.)]442.6 norm2
-[(Therefore, you cannot get at your variables by writing code like this:)]425.6 norm3
-[2( mov eax,[myvar] ; WRONG)]408.6 code3
-[(Instead, the linker provides an area of memory called the )1(global offset table)0(, or )(GOT; the GOT is situated at a)]391.6 norm1
-[(constant distance from your library's code, so if you can find out where your library is loaded \(which is)]380.6 norm0
-[(typically done using a )2(CALL)0( and )2(POP)0( combination\), you can obtain the address of the GOT, and you can then)]369.6 norm0
-[(load the addresses of your variables out of linker-generated entries in the GOT.)]358.6 norm2
-[(The )1(data)0( section of a PIC shared library does not have these restrictions: since the data section is writable, it)]341.6 norm1
-[(has to be copied into memory anyway rather than just paged in from the library file, so as long as it's being)]330.6 norm0
-[(copied it can be relocated too. So you can put ordinary types of relocation in the data section without too)]319.6 norm0
-[(much worry \(but see ){/section-9.2.4 xl}(section 9.2.4){el}( for a caveat\).)]308.6 norm2
-[{/section-9.2.1 xa}(Obtaining the Address of the GOT)](9.2.1)289.4 subh3
-[(Each code module in your shared library should define the GOT as an external symbol:)]272.4 norm3
-[2(extern _GLOBAL_OFFSET_TABLE_ ; in ELF )]255.4 code1
-[2(extern __GLOBAL_OFFSET_TABLE_ ; in BSD a.out)]244.4 code2
-[(At the beginning of any function in your shared library which plans to access your data or BSS sections, you)]227.4 norm1
-[(must first calculate the address of the GOT. This is typically done by writing the function in this form:)]216.4 norm2
-[2(func: push ebp )]199.4 code1
-[2( mov ebp,esp )]188.4 code0
-[2( push ebx )]177.4 code0
-[2( call .get_GOT )]166.4 code0
-[2(.get_GOT: )]155.4 code0
-[2( pop ebx )]144.4 code0
-[2( add ebx,_GLOBAL_OFFSET_TABLE_+$$-.get_GOT wrt ..gotpc )]133.4 code0
-[2()]122.4 code0
-[2( ; the function body comes here )]111.4 code0
-[2()]100.4 code0
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-[2( mov ebx,[ebp-4] )]681 code0
-[2( mov esp,ebp )]670 code0
-[2( pop ebp )]659 code0
-[2( ret)]648 code2
-[(\(For BSD, again, the symbol )2(_GLOBAL_OFFSET_TABLE)0( requires a second leading underscore.\))]631 norm3
-[(The first two lines of this function are simply the standard C prologue to set up a stack frame, and the last)]614 norm1
-[(three lines are standard C function epilogue. The third line, and the fourth to last line, save and restore the)]603 norm0
-[2(EBX)0( register, because PIC shared libraries use this register to store the address of the GOT.)]592 norm2
-[(The interesting bit is the )2(CALL)0( instruction and the following two lines. The )2(CALL)0( and )2(POP)0( combination)]575 norm1
-[(obtains the address of the label )2(.get_GOT)0(, without having to know in advance where the program was)]564 norm0
-[(loaded \(since the )2(CALL)0( instruction is encoded relative to the current position\). The )2(ADD)0( instruction makes use)]553 norm0
-[(of one of the special PIC relocation types: )(GOTPC relocation. With the )2(WRT ..gotpc)0( qualifier specified,)]542 norm0
-[(the symbol referenced \(here )2(_GLOBAL_OFFSET_TABLE_)0(, the special symbol assigned to the GOT\) is given)]531 norm0
-[(as an offset from the beginning of the section. \(Actually, )2(ELF)0( encodes it as the offset from the operand field)]520 norm0
-[(of the )2(ADD)0( instruction, but NASM simplifies this deliberately, so you do things the same way for both )2(ELF)]509 norm0
-[(and )2(BSD)0(.\) So the instruction then )1(adds)0( the beginning of the section, to get the real address of the GOT, and)]498 norm0
-[(subtracts the value of )2(.get_GOT)0( which it knows is in )2(EBX)0(. Therefore, by the time that instruction has)]487 norm0
-[(finished, )2(EBX)0( contains the address of the GOT.)]476 norm2
-[(If you didn't follow that, don't worry: it's never necessary to obtain the address of the GOT by any other)]459 norm1
-[(means, so you can put those three instructions into a macro and safely ignore them:)]448 norm2
-[2(%macro get_GOT 0 )]431 code1
-[2()]420 code0
-[2( call %%getgot )]409 code0
-[2( %%getgot: )]398 code0
-[2( pop ebx )]387 code0
-[2( add ebx,_GLOBAL_OFFSET_TABLE_+$$-%%getgot wrt ..gotpc )]376 code0
-[2()]365 code0
-[2(%endmacro)]354 code2
-[{/section-9.2.2 xa}(Finding Your Local Data Items)](9.2.2)334.8 subh3
-[(Having got the GOT, you can then use it to obtain the addresses of your data items. Most variables will reside)]317.8 norm1
-[(in the sections you have declared; they can be accessed using the )2(..gotoff)0( special )2(WRT)0( type. The way this)]306.8 norm0
-[(works is like this:)]295.8 norm2
-[2( lea eax,[ebx+myvar wrt ..gotoff])]278.8 code3
-[(The expression )2(myvar wrt ..gotoff)0( is calculated, when the shared library is linked, to be the offset to)]261.8 norm1
-[(the local variable )2(myvar)0( from the beginning of the GOT. Therefore, adding it to )2(EBX)0( as above will place the)]250.8 norm0
-[(real address of )2(myvar)0( in )2(EAX)0(.)]239.8 norm2
-[(If you declare variables as )2(GLOBAL)0( without specifying a size for them, they are shared between code modules)]222.8 norm1
-[(in the library, but do not get exported from the library to the program that loaded it. They will still be in your)]211.8 norm0
-[(ordinary data and BSS sections, so you can access them in the same way as local variables, using the above)]200.8 norm0
-[2(..gotoff)0( mechanism.)]189.8 norm2
-[(Note that due to a peculiarity of the way BSD )2(a.out)0( format handles this relocation type, there must be at)]172.8 norm1
-[(least one non-local symbol in the same section as the address you're trying to access.)]161.8 norm2
-[{/section-9.2.3 xa}(Finding External and Common Data Items)](9.2.3)142.6 subh3
-[(If your library needs to get at an external variable \(external to the )1(library)0(, not just to one of the modules)]125.6 norm1
-[(within it\), you must use the )2(..got)0( type to get at it. The )2(..got)0( type, instead of giving you the offset from)]114.6 norm0
-[(the GOT base to the variable, gives you the offset from the GOT base to a GOT )1(entry)0( containing the address)]103.6 norm0
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-[(of the variable. The linker will set up this GOT entry when it builds the library, and the dynamic linker will)]681 norm0
-[(place the correct address in it at load time. So to obtain the address of an external variable )2(extvar)0( in )2(EAX)0(,)]670 norm0
-[(you would code)]659 norm2
-[2( mov eax,[ebx+extvar wrt ..got])]642 code3
-[(This loads the address of )2(extvar)0( out of an entry in the GOT. The linker, when it builds the shared library,)]625 norm1
-[(collects together every relocation of type )2(..got)0(, and builds the GOT so as to ensure it has every necessary)]614 norm0
-[(entry present.)]603 norm2
-[(Common variables must also be accessed in this way.)]586 norm3
-[{/section-9.2.4 xa}(Exporting Symbols to the Library User)](9.2.4)566.8 subh3
-[(If you want to export symbols to the user of the library, you have to declare whether they are functions or)]549.8 norm1
-[(data, and if they are data, you have to give the size of the data item. This is because the dynamic linker has to)]538.8 norm0
-[(build )(procedure linkage table entries for any exported functions, and also moves exported data items away)]527.8 norm0
-[(from the library's data section in which they were declared.)]516.8 norm2
-[(So to export a function to users of the library, you must use)]499.8 norm3
-[2(global func:function ; declare it as a function )]482.8 code1
-[2()]471.8 code0
-[2(func: push ebp )]460.8 code0
-[2()]449.8 code0
-[2( ; etc.)]438.8 code2
-[(And to export a data item such as an array, you would have to code)]421.8 norm3
-[2(global array:data array.end-array ; give the size too )]404.8 code1
-[2()]393.8 code0
-[2(array: resd 128 )]382.8 code0
-[2(.end:)]371.8 code2
-[(Be careful: If you export a variable to the library user, by declaring it as )2(GLOBAL)0( and supplying a size, the)]354.8 norm1
-[(variable will end up living in the data section of the main program, rather than in your library's data section,)]343.8 norm0
-[(where you declared it. So you will have to access your own global variable with the )2(..got)0( mechanism rather)]332.8 norm0
-[(than )2(..gotoff)0(, as if it were external \(which, effectively, it has become\).)]321.8 norm2
-[(Equally, if you need to store the address of an exported global in one of your data sections, you can't do it by)]304.8 norm1
-[(means of the standard sort of code:)]293.8 norm2
-[2(dataptr: dd global_data_item ; WRONG)]276.8 code3
-[(NASM will interpret this code as an ordinary relocation, in which )2(global_data_item)0( is merely an offset)]259.8 norm1
-[(from the beginning of the )2(.data)0( section \(or whatever\); so this reference will end up pointing at your data)]248.8 norm0
-[(section instead of at the exported global which resides elsewhere.)]237.8 norm2
-[(Instead of the above code, then, you must write)]220.8 norm3
-[2(dataptr: dd global_data_item wrt ..sym)]203.8 code3
-[(which makes use of the special )2(WRT)0( type )2(..sym)0( to instruct NASM to search the symbol table for a particular)]186.8 norm1
-[(symbol at that address, rather than just relocating by section base.)]175.8 norm2
-[(Either method will work for functions: referring to one of your functions by means of)]158.8 norm3
-[2(funcptr: dd my_function)]141.8 code3
-[(will give the user the address of the code you wrote, whereas)]124.8 norm3
-[2(funcptr: dd my_function wrt .sym)]107.8 code3
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-[(will give the address of the procedure linkage table for the function, which is where the calling program will)]681 norm1
-[1(believe)0( the function lives. Either address is a valid way to call the function.)]670 norm2
-[{/section-9.2.5 xa}(Calling Procedures Outside the Library)](9.2.5)650.8 subh3
-[(Calling procedures outside your shared library has to be done by means of a )1(procedure linkage table)0(, or )(PLT.)]633.8 norm1
-[(The PLT is placed at a known offset from where the library is loaded, so the library code can make calls to the)]622.8 norm0
-[(PLT in a position-independent way. Within the PLT there is code to jump to offsets contained in the GOT, so)]611.8 norm0
-[(function calls to other shared libraries or to routines in the main program can be transparently passed off to)]600.8 norm0
-[(their real destinations.)]589.8 norm2
-[(To call an external routine, you must use another special PIC relocation type, )2(WRT ..plt)0(. This is much)]572.8 norm1
-[(easier than the GOT-based ones: you simply replace calls such as )2(CALL printf)0( with the PLT-relative)]561.8 norm0
-[(version )2(CALL printf WRT ..plt)0(.)]550.8 norm2
-[{/section-9.2.6 xa}(Generating the Library File)](9.2.6)531.6 subh3
-[(Having written some code modules and assembled them to )2(.o)0( files, you then generate your shared library)]514.6 norm1
-[(with a command such as)]503.6 norm2
-[2(ld -shared -o library.so module1.o module2.o # for ELF )]486.6 code1
-[2(ld -Bshareable -o library.so module1.o module2.o # for BSD)]475.6 code2
-[(For ELF, if your shared library is going to reside in system directories such as )2(/usr/lib)0( or )2(/lib)0(, it is)]458.6 norm1
-[(usually worth using the )2(-soname)0( flag to the linker, to store the final library file name, with a version)]447.6 norm0
-[(number, into the library:)]436.6 norm2
-[2(ld -shared -soname library.so.1 -o library.so.1.2 *.o)]419.6 code3
-[(You would then copy )2(library.so.1.2)0( into the library directory, and create )2(library.so.1)0( as a)]402.6 norm1
-[(symbolic link to it.)]391.6 norm2
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-[{/chapter-10 xa}(Chapter 10: Mixing 16 and 32 Bit Code)]642.8 chap3
-[(This chapter tries to cover some of the issues, largely related to unusual forms of addressing and jump)]607.8 norm1
-[(instructions, encountered when writing operating system code such as protected-mode initialisation routines,)]596.8 norm0
-[(which require code that operates in mixed segment sizes, such as code in a 16-bit segment trying to modify)]585.8 norm0
-[(data in a 32-bit one, or jumps between different-size segments.)]574.8 norm2
-[{/section-10.1 xa}(Mixed-Size Jumps)](10.1)553.4 head3
-[(The most common form of )(mixed-size instruction is the one used when writing a 32-bit OS: having done)]536.4 norm1
-[(your setup in 16-bit mode, such as loading the kernel, you then have to boot it by switching into protected)]525.4 norm0
-[(mode and jumping to the 32-bit kernel start address. In a fully 32-bit OS, this tends to be the )1(only)0( mixed-size)]514.4 norm0
-[(instruction you need, since everything before it can be done in pure 16-bit code, and everything after it can be)]503.4 norm0
-[(pure 32-bit.)]492.4 norm2
-[(This jump must specify a 48-bit far address, since the target segment is a 32-bit one. However, it must be)]475.4 norm1
-[(assembled in a 16-bit segment, so just coding, for example,)]464.4 norm2
-[2( jmp 0x1234:0x56789ABC ; wrong!)]447.4 code3
-[(will not work, since the offset part of the address will be truncated to )2(0x9ABC)0( and the jump will be an)]430.4 norm1
-[(ordinary 16-bit far one.)]419.4 norm2
-[(The Linux kernel setup code gets round the inability of )2(as86)0( to generate the required instruction by coding it)]402.4 norm1
-[(manually, using )2(DB)0( instructions. NASM can go one better than that, by actually generating the right)]391.4 norm0
-[(instruction itself. Here's how to do it right:)]380.4 norm2
-[2( jmp dword 0x1234:0x56789ABC ; right)]363.4 code3
-[(The )2(DWORD)0( prefix \(strictly speaking, it should come )1(after)0( the colon, since it is declaring the )1(offset)0( field to be a)]346.4 norm1
-[(doubleword; but NASM will accept either form, since both are unambiguous\) forces the offset part to be)]335.4 norm0
-[(treated as far, in the assumption that you are deliberately writing a jump from a 16-bit segment to a 32-bit)]324.4 norm0
-[(one.)]313.4 norm2
-[(You can do the reverse operation, jumping from a 32-bit segment to a 16-bit one, by means of the )2(WORD)]296.4 norm1
-[(prefix:)]285.4 norm2
-[2( jmp word 0x8765:0x4321 ; 32 to 16 bit)]268.4 code3
-[(If the )2(WORD)0( prefix is specified in 16-bit mode, or the )2(DWORD)0( prefix in 32-bit mode, they will be ignored,)]251.4 norm1
-[(since each is explicitly forcing NASM into a mode it was in anyway.)]240.4 norm2
-[{/section-10.2 xa}(Addressing Between Different-Size Segments)](10.2)219 head3
-[(If your OS is mixed 16 and 32-bit, or if you are writing a DOS extender, you are likely to have to deal with)]202 norm1
-[(some 16-bit segments and some 32-bit ones. At some point, you will probably end up writing code in a)]191 norm0
-[(16-bit segment which has to access data in a 32-bit segment, or vice versa.)]180 norm2
-[(If the data you are trying to access in a 32-bit segment lies within the first 64K of the segment, you may be)]163 norm1
-[(able to get away with using an ordinary 16-bit addressing operation for the purpose; but sooner or later, you)]152 norm0
-[(will want to do 32-bit addressing from 16-bit mode.)]141 norm2
-[(The easiest way to do this is to make sure you use a register for the address, since any effective address)]124 norm1
-[(containing a 32-bit register is forced to be a 32-bit address. So you can do)]113 norm2
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-[2( mov eax,offset_into_32_bit_segment_specified_by_fs )]681 code1
-[2( mov dword [fs:eax],0x11223344)]670 code2
-[(This is fine, but slightly cumbersome \(since it wastes an instruction and a register\) if you already know the)]653 norm1
-[(precise offset you are aiming at. The x86 architecture does allow 32-bit effective addresses to specify nothing)]642 norm0
-[(but a 4-byte offset, so why shouldn't NASM be able to generate the best instruction for the purpose?)]631 norm2
-[(It can. As in ){/section-10.1 xl}(section 10.1){el}(, you need only prefix the address with the )2(DWORD)0( keyword, and it will be forced to)]614 norm1
-[(be a 32-bit address:)]603 norm2
-[2( mov dword [fs:dword my_offset],0x11223344)]586 code3
-[(Also as in ){/section-10.1 xl}(section 10.1){el}(, NASM is not fussy about whether the )2(DWORD)0( prefix comes before or after the)]569 norm1
-[(segment override, so arguably a nicer-looking way to code the above instruction is)]558 norm2
-[2( mov dword [dword fs:my_offset],0x11223344)]541 code3
-[(Don't confuse the )2(DWORD)0( prefix )1(outside)0( the square brackets, which controls the size of the data stored at the)]524 norm1
-[(address, with the one )2(inside)0( the square brackets which controls the length of the address itself. The two can)]513 norm0
-[(quite easily be different:)]502 norm2
-[2( mov word [dword 0x12345678],0x9ABC)]485 code3
-[(This moves 16 bits of data to an address specified by a 32-bit offset.)]468 norm3
-[(You can also specify )2(WORD)0( or )2(DWORD)0( prefixes along with the )2(FAR)0( prefix to indirect far jumps or calls. For)]451 norm1
-[(example:)]440 norm2
-[2( call dword far [fs:word 0x4321])]423 code3
-[(This instruction contains an address specified by a 16-bit offset; it loads a 48-bit far pointer from that \(16-bit)]406 norm1
-[(segment and 32-bit offset\), and calls that address.)]395 norm2
-[{/section-10.3 xa}(Other Mixed-Size Instructions)](10.3)373.6 head3
-[(The other way you might want to access data might be using the string instructions \()2(LODSx)0(, )2(STOSx)0( and so)]356.6 norm1
-[(on\) or the )2(XLATB)0( instruction. These instructions, since they take no parameters, might seem to have no easy)]345.6 norm0
-[(way to make them perform 32-bit addressing when assembled in a 16-bit segment.)]334.6 norm2
-[(This is the purpose of NASM's )2(a16)0(, )2(a32)0( and )2(a64)0( prefixes. If you are coding )2(LODSB)0( in a 16-bit segment)]317.6 norm1
-[(but it is supposed to be accessing a string in a 32-bit segment, you should load the desired address into )2(ESI)]306.6 norm0
-[(and then code)]295.6 norm2
-[2( a32 lodsb)]278.6 code3
-[(The prefix forces the addressing size to 32 bits, meaning that )2(LODSB)0( loads from )2([DS:ESI])0( instead of)]261.6 norm1
-[2([DS:SI])0(. To access a string in a 16-bit segment when coding in a 32-bit one, the corresponding )2(a16)0( prefix)]250.6 norm0
-[(can be used.)]239.6 norm2
-[(The )2(a16)0(, )2(a32)0( and )2(a64)0( prefixes can be applied to any instruction in NASM's instruction table, but most of)]222.6 norm1
-[(them can generate all the useful forms without them. The prefixes are necessary only for instructions with)]211.6 norm0
-[(implicit addressing: )2(CMPSx)0(, )2(SCASx)0(, )2(LODSx)0(, )2(STOSx)0(, )2(MOVSx)0(, )2(INSx)0(, )2(OUTSx)0(, and )2(XLATB)0(. Also, the various)]200.6 norm0
-[(push and pop instructions \()2(PUSHA)0( and )2(POPF)0( as well as the more usual )2(PUSH)0( and )2(POP)0(\) can accept )2(a16)0(, )2(a32)]189.6 norm0
-[(or )2(a64)0( prefixes to force a particular one of )2(SP)0(, )2(ESP)0( or )2(RSP)0( to be used as a stack pointer, in case the stack)]178.6 norm0
-[(segment in use is a different size from the code segment.)]167.6 norm2
-[2(PUSH)0( and )2(POP)0(, when applied to segment registers in 32-bit mode, also have the slightly odd behaviour that)]150.6 norm1
-[(they push and pop 4 bytes at a time, of which the top two are ignored and the bottom two give the value of the)]139.6 norm0
-[(segment register being manipulated. To force the 16-bit behaviour of segment-register push and pop)]128.6 norm0
-[(instructions, you can use the operand-size prefix )2(o16)0(:)]117.6 norm2
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-[2( o16 push ss )]681 code1
-[2( o16 push ds)]670 code2
-[(This code saves a doubleword of stack space by fitting two segment registers into the space which would)]653 norm1
-[(normally be consumed by pushing one.)]642 norm2
-[(\(You can also use the )2(o32)0( prefix to force the 32-bit behaviour when in 16-bit mode, but this seems less)]625 norm1
-[(useful.\))]614 norm2
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-[{/chapter-11 xa}(Chapter 11: Writing 64-bit Code \(Unix, Win64\))]642.8 chap3
-[(This chapter attempts to cover some of the common issues involved when writing 64-bit code, to run under)]607.8 norm1
-[(Win64 or Unix. It covers how to write assembly code to interface with 64-bit C routines, and how to write)]596.8 norm0
-[(position-independent code for shared libraries.)]585.8 norm2
-[(All 64-bit code uses a flat memory model, since segmentation is not available in 64-bit mode. The one)]568.8 norm1
-[(exception is the )2(FS)0( and )2(GS)0( registers, which still add their bases.)]557.8 norm2
-[(Position independence in 64-bit mode is significantly simpler, since the processor supports )2(RIP)0(\226relative)]540.8 norm1
-[(addressing directly; see the )2(REL)0( keyword \(){/section-3.3 xl}(section 3.3){el}(\). On most 64-bit platforms, it is probably desirable to)]529.8 norm0
-[(make that the default, using the directive )2(DEFAULT REL)0( \(){/section-6.2 xl}(section 6.2){el}(\).)]518.8 norm2
-[(64-bit programming is relatively similar to 32-bit programming, but of course pointers are 64 bits long;)]501.8 norm1
-[(additionally, all existing platforms pass arguments in registers rather than on the stack. Furthermore, 64-bit)]490.8 norm0
-[(platforms use SSE2 by default for floating point. Please see the ABI documentation for your platform.)]479.8 norm2
-[(64-bit platforms differ in the sizes of the fundamental datatypes, not just from 32-bit platforms but from each)]462.8 norm1
-[(other. If a specific size data type is desired, it is probably best to use the types defined in the Standard C)]451.8 norm0
-[(header )2(<inttypes.h>)0(.)]440.8 norm2
-[(In 64-bit mode, the default instruction size is still 32 bits. When loading a value into a 32-bit register \(but not)]423.8 norm1
-[(an 8- or 16-bit register\), the upper 32 bits of the corresponding 64-bit register are set to zero.)]412.8 norm2
-[{/section-11.1 xa}(Register Names in 64-bit Mode)](11.1)391.4 head3
-[(NASM uses the following names for general-purpose registers in 64-bit mode, for 8-, 16-, 32- and 64-bit)]374.4 norm1
-[(references, respecitively:)]363.4 norm2
-[2( AL/AH, CL/CH, DL/DH, BL/BH, SPL, BPL, SIL, DIL, R8B-R15B )]346.4 code1
-[2( AX, CX, DX, BX, SP, BP, SI, DI, R8W-R15W )]335.4 code0
-[2( EAX, ECX, EDX, EBX, ESP, EBP, ESI, EDI, R8D-R15D )]324.4 code0
-[2( RAX, RCX, RDX, RBX, RSP, RBP, RSI, RDI, R8-R15)]313.4 code2
-[(This is consistent with the AMD documentation and most other assemblers. The Intel documentation,)]296.4 norm1
-[(however, uses the names )2(R8L-R15L)0( for 8-bit references to the higher registers. It is possible to use those)]285.4 norm0
-[(names by definiting them as macros; similarly, if one wants to use numeric names for the low 8 registers,)]274.4 norm0
-[(define them as macros. The standard macro package )2(altreg)0( \(see ){/section-5.1 xl}(section 5.1){el}(\) can be used for this purpose.)]263.4 norm2
-[{/section-11.2 xa}(Immediates and Displacements in 64-bit Mode)](11.2)242 head3
-[(In 64-bit mode, immediates and displacements are generally only 32 bits wide. NASM will therefore truncate)]225 norm1
-[(most displacements and immediates to 32 bits.)]214 norm2
-[(The only instruction which takes a full )(64-bit immediate is:)]197 norm3
-[2( MOV reg64,imm64)]180 code3
-[(NASM will produce this instruction whenever the programmer uses )2(MOV)0( with an immediate into a 64-bit)]163 norm1
-[(register. If this is not desirable, simply specify the equivalent 32-bit register, which will be automatically)]152 norm0
-[(zero-extended by the processor, or specify the immediate as )2(DWORD)0(:)]141 norm2
-[2( mov rax,foo ; 64-bit immediate )]124 code1
-[2( mov rax,qword foo ; \(identical\) )]113 code0
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-[2( mov eax,foo ; 32-bit immediate, zero-extended )]681 code0
-[2( mov rax,dword foo ; 32-bit immediate, sign-extended)]670 code2
-[(The length of these instructions are 10, 5 and 7 bytes, respectively.)]653 norm3
-[(The only instructions which take a full )(64-bit )1(displacement)0( is loading or storing, using )2(MOV)0(, )2(AL)0(, )2(AX)0(, )2(EAX)0( or)]636 norm1
-[2(RAX)0( \(but no other registers\) to an absolute 64-bit address. Since this is a relatively rarely used instruction)]625 norm0
-[(\(64-bit code generally uses relative addressing\), the programmer has to explicitly declare the displacement)]614 norm0
-[(size as )2(QWORD)0(:)]603 norm2
-[2( default abs )]586 code1
-[2()]575 code0
-[2( mov eax,[foo] ; 32-bit absolute disp, sign-extended )]564 code0
-[2( mov eax,[a32 foo] ; 32-bit absolute disp, zero-extended )]553 code0
-[2( mov eax,[qword foo] ; 64-bit absolute disp )]542 code0
-[2()]531 code0
-[2( default rel )]520 code0
-[2()]509 code0
-[2( mov eax,[foo] ; 32-bit relative disp )]498 code0
-[2( mov eax,[a32 foo] ; d:o, address truncated to 32 bits\(!\) )]487 code0
-[2( mov eax,[qword foo] ; error )]476 code0
-[2( mov eax,[abs qword foo] ; 64-bit absolute disp)]465 code2
-[(A sign-extended absolute displacement can access from \2262 GB to +2 GB; a zero-extended absolute)]448 norm1
-[(displacement can access from 0 to 4 GB.)]437 norm2
-[{/section-11.3 xa}(Interfacing to 64-bit C Programs \(Unix\))](11.3)415.6 head3
-[(On Unix, the 64-bit ABI is defined by the document:)]398.6 norm3
-[{(http://www.x86-64.org/documentation/abi.pdf)wl}2(http://www.x86-64.org/documentation/abi.pdf){el}]381.6 norm3
-[(Although written for AT&T-syntax assembly, the concepts apply equally well for NASM-style assembly.)]364.6 norm1
-[(What follows is a simplified summary.)]353.6 norm2
-[(The first six integer arguments \(from the left\) are passed in )2(RDI)0(, )2(RSI)0(, )2(RDX)0(, )2(RCX)0(, )2(R8)0(, and )2(R9)0(, in that order.)]336.6 norm1
-[(Additional integer arguments are passed on the stack. These registers, plus )2(RAX)0(, )2(R10)0( and )2(R11)0( are destroyed)]325.6 norm0
-[(by function calls, and thus are available for use by the function without saving.)]314.6 norm2
-[(Integer return values are passed in )2(RAX)0( and )2(RDX)0(, in that order.)]297.6 norm3
-[(Floating point is done using SSE registers, except for )2(long double)0(. Floating-point arguments are passed)]280.6 norm1
-[(in )2(XMM0)0( to )2(XMM7)0(; return is )2(XMM0)0( and )2(XMM1)0(. )2(long double)0( are passed on the stack, and returned in )2(ST0)]269.6 norm0
-[(and )2(ST1)0(.)]258.6 norm2
-[(All SSE and x87 registers are destroyed by function calls.)]241.6 norm3
-[(On 64-bit Unix, )2(long)0( is 64 bits.)]224.6 norm3
-[(Integer and SSE register arguments are counted separately, so for the case of)]207.6 norm3
-[2( void foo\(long a, double b, int c\))]190.6 code3
-[2(a)0( is passed in )2(RDI)0(, )2(b)0( in )2(XMM0)0(, and )2(c)0( in )2(ESI)0(.)]173.6 norm3
-[{/section-11.4 xa}(Interfacing to 64-bit C Programs \(Win64\))](11.4)152.2 head3
-[(The Win64 ABI is described at:)]135.2 norm3
-[{(http://msdn2.microsoft.com/en-gb/library/ms794533.aspx)wl}2(http://msdn2.microsoft.com/en-gb/library/ms794533.aspx){el}]118.2 norm3
-[(What follows is a simplified summary.)]101.2 norm3
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-[(The first four integer arguments are passed in )2(RCX)0(, )2(RDX)0(, )2(R8)0( and )2(R9)0(, in that order. Additional integer)]681 norm1
-[(arguments are passed on the stack. These registers, plus )2(RAX)0(, )2(R10)0( and )2(R11)0( are destroyed by function calls,)]670 norm0
-[(and thus are available for use by the function without saving.)]659 norm2
-[(Integer return values are passed in )2(RAX)0( only.)]642 norm3
-[(Floating point is done using SSE registers, except for )2(long double)0(. Floating-point arguments are passed)]625 norm1
-[(in )2(XMM0)0( to )2(XMM3)0(; return is )2(XMM0)0( only.)]614 norm2
-[(On Win64, )2(long)0( is 32 bits; )2(long long)0( or )2(_int64)0( is 64 bits.)]597 norm3
-[(Integer and SSE register arguments are counted together, so for the case of)]580 norm3
-[2( void foo\(long long a, double b, int c\))]563 code3
-[2(a)0( is passed in )2(RCX)0(, )2(b)0( in )2(XMM1)0(, and )2(c)0( in )2(R8D)0(.)]546 norm3
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-[{/chapter-12 xa}(Chapter 12: Troubleshooting)]642.8 chap3
-[(This chapter describes some of the common problems that users have been known to encounter with NASM,)]607.8 norm1
-[(and answers them. It also gives instructions for reporting bugs in NASM if you find a difficulty that isn't)]596.8 norm0
-[(listed here.)]585.8 norm2
-[{/section-12.1 xa}(Common Problems)](12.1)564.4 head3
-[{/section-12.1.1 xa}(NASM Generates )(Inefficient Code)](12.1.1)545.2 subh3
-[(We sometimes get `bug' reports about NASM generating inefficient, or even `wrong', code on instructions)]528.2 norm1
-[(such as )2(ADD ESP,8)0(. This is a deliberate design feature, connected to predictability of output: NASM, on)]517.2 norm0
-[(seeing )2(ADD ESP,8)0(, will generate the form of the instruction which leaves room for a 32-bit offset. You)]506.2 norm0
-[(need to code )2(ADD ESP,BYTE 8)0( if you want the space-efficient form of the instruction. This isn't a bug, it's)]495.2 norm0
-[(user error: if you prefer to have NASM produce the more efficient code automatically enable optimization)]484.2 norm0
-[(with the )2(-O)0( option \(see ){/section-2.1.22 xl}(section 2.1.22){el}(\).)]473.2 norm2
-[{/section-12.1.2 xa}(My Jumps are Out of Range)](12.1.2)454 subh3
-[(Similarly, people complain that when they issue )(conditional jumps \(which are )2(SHORT)0( by default\) that try to)]437 norm1
-[(jump too far, NASM reports `short jump out of range' instead of making the jumps longer.)]426 norm2
-[(This, again, is partly a predictability issue, but in fact has a more practical reason as well. NASM has no)]409 norm1
-[(means of being told what type of processor the code it is generating will be run on; so it cannot decide for)]398 norm0
-[(itself that it should generate )2(Jcc NEAR)0( type instructions, because it doesn't know that it's working for a 386)]387 norm0
-[(or above. Alternatively, it could replace the out-of-range short )2(JNE)0( instruction with a very short )2(JE)]376 norm0
-[(instruction that jumps over a )2(JMP NEAR)0(; this is a sensible solution for processors below a 386, but hardly)]365 norm0
-[(efficient on processors which have good branch prediction )1(and)0( could have used )2(JNE NEAR)0( instead. So, once)]354 norm0
-[(again, it's up to the user, not the assembler, to decide what instructions should be generated. See ){/section-2.1.22 xl}(section){el}]343 norm0
-[{/section-2.1.22 xl}(2.1.22){el}(.)]332 norm2
-[{/section-12.1.3 xa}2(ORG)0( Doesn't Work)](12.1.3)312.8 subh3
-[(People writing )(boot sector programs in the )2(bin)0( format often complain that )2(ORG)0( doesn't work the way they'd)]295.8 norm1
-[(like: in order to place the )2(0xAA55)0( signature word at the end of a 512-byte boot sector, people who are used)]284.8 norm0
-[(to MASM tend to code)]273.8 norm2
-[2( ORG 0 )]256.8 code1
-[2()]245.8 code0
-[2( ; some boot sector code )]234.8 code0
-[2()]223.8 code0
-[2( ORG 510 )]212.8 code0
-[2( DW 0xAA55)]201.8 code2
-[(This is not the intended use of the )2(ORG)0( directive in NASM, and will not work. The correct way to solve this)]184.8 norm1
-[(problem in NASM is to use the )2(TIMES)0( directive, like this:)]173.8 norm2
-[2( ORG 0 )]156.8 code1
-[2()]145.8 code0
-[2( ; some boot sector code )]134.8 code0
-[2()]123.8 code0
-[2( TIMES 510-\($-$$\) DB 0 )]112.8 code0
-[2( DW 0xAA55)]101.8 code2
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-[(The )2(TIMES)0( directive will insert exactly enough zero bytes into the output to move the assembly point up to)]681 norm1
-[(510. This method also has the advantage that if you accidentally fill your boot sector too full, NASM will)]670 norm0
-[(catch the problem at assembly time and report it, so you won't end up with a boot sector that you have to)]659 norm0
-[(disassemble to find out what's wrong with it.)]648 norm2
-[{/section-12.1.4 xa}2(TIMES)0( Doesn't Work)](12.1.4)628.8 subh3
-[(The other common problem with the above code is people who write the )2(TIMES)0( line as)]611.8 norm3
-[2( TIMES 510-$ DB 0)]594.8 code3
-[(by reasoning that )2($)0( should be a pure number, just like 510, so the difference between them is also a pure)]577.8 norm1
-[(number and can happily be fed to )2(TIMES)0(.)]566.8 norm2
-[(NASM is a )1(modular)0( assembler: the various component parts are designed to be easily separable for re-use, so)]549.8 norm1
-[(they don't exchange information unnecessarily. In consequence, the )2(bin)0( output format, even though it has)]538.8 norm0
-[(been told by the )2(ORG)0( directive that the )2(.text)0( section should start at 0, does not pass that information back to)]527.8 norm0
-[(the expression evaluator. So from the evaluator's point of view, )2($)0( isn't a pure number: it's an offset from a)]516.8 norm0
-[(section base. Therefore the difference between )2($)0( and 510 is also not a pure number, but involves a section)]505.8 norm0
-[(base. Values involving section bases cannot be passed as arguments to )2(TIMES)0(.)]494.8 norm2
-[(The solution, as in the previous section, is to code the )2(TIMES)0( line in the form)]477.8 norm3
-[2( TIMES 510-\($-$$\) DB 0)]460.8 code3
-[(in which )2($)0( and )2($$)0( are offsets from the same section base, and so their difference is a pure number. This will)]443.8 norm1
-[(solve the problem and generate sensible code.)]432.8 norm2
-[{/section-12.2 xa}(Bugs)](12.2)411.4 head3
-[(We have never yet released a version of NASM with any )1(known)0( bugs. That doesn't usually stop there being)]394.4 norm1
-[(plenty we didn't know about, though. Any that you find should be reported firstly via the )2(bugtracker)0( at)]383.4 norm0
-[{(https://sourceforge.net/projects/nasm/)wl}2(https://sourceforge.net/projects/nasm/){el}0( \(click on "Bugs"\), or if that fails then through one of)]372.4 norm0
-[(the contacts in ){/section-1.2 xl}(section 1.2){el}(.)]361.4 norm2
-[(Please read ){/section-2.2 xl}(section 2.2){el}( first, and don't report the bug if it's listed in there as a deliberate feature. \(If you think)]344.4 norm1
-[(the feature is badly thought out, feel free to send us reasons why you think it should be changed, but don't just)]333.4 norm0
-[(send us mail saying `This is a bug' if the documentation says we did it on purpose.\) Then read ){/section-12.1 xl}(section 12.1){el}(,)]322.4 norm0
-[(and don't bother reporting the bug if it's listed there.)]311.4 norm2
-[(If you do report a bug, )1(please)0( give us all of the following information:)]294.4 norm3
-[(What operating system you're running NASM under. DOS, Linux, NetBSD, Win16, Win32, VMS \(I'd be)]277.4 bull1
-[(impressed\), whatever.)]266.4 bull2
-[(If you're running NASM under DOS or Win32, tell us whether you've compiled your own executable from)]249.4 bull1
-[(the DOS source archive, or whether you were using the standard distribution binaries out of the archive. If)]238.4 bull0
-[(you were using a locally built executable, try to reproduce the problem using one of the standard binaries,)]227.4 bull0
-[(as this will make it easier for us to reproduce your problem prior to fixing it.)]216.4 bull2
-[(Which version of NASM you're using, and exactly how you invoked it. Give us the precise command line,)]199.4 bull1
-[(and the contents of the )2(NASMENV)0( environment variable if any.)]188.4 bull2
-[(Which versions of any supplementary programs you're using, and how you invoked them. If the problem)]171.4 bull1
-[(only becomes visible at link time, tell us what linker you're using, what version of it you've got, and the)]160.4 bull0
-[(exact linker command line. If the problem involves linking against object files generated by a compiler, tell)]149.4 bull0
-[(us what compiler, what version, and what command line or options you used. \(If you're compiling in an)]138.4 bull0
-[(IDE, please try to reproduce the problem with the command-line version of the compiler.\))]127.4 bull2
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-[(If at all possible, send us a NASM source file which exhibits the problem. If this causes copyright)]681 bull1
-[(problems \(e.g. you can only reproduce the bug in restricted-distribution code\) then bear in mind the)]670 bull0
-[(following two points: firstly, we guarantee that any source code sent to us for the purposes of debugging)]659 bull0
-[(NASM will be used )1(only)0( for the purposes of debugging NASM, and that we will delete all our copies of it)]648 bull0
-[(as soon as we have found and fixed the bug or bugs in question; and secondly, we would prefer )1(not)0( to be)]637 bull0
-[(mailed large chunks of code anyway. The smaller the file, the better. A three-line sample file that does)]626 bull0
-[(nothing useful )1(except)0( demonstrate the problem is much easier to work with than a fully fledged)]615 bull0
-[(ten-thousand-line program. \(Of course, some errors )1(do)0( only crop up in large files, so this may not be)]604 bull0
-[(possible.\))]593 bull2
-[(A description of what the problem actually )1(is)0(. `It doesn't work' is )1(not)0( a helpful description! Please describe)]576 bull1
-[(exactly what is happening that shouldn't be, or what isn't happening that should. Examples might be:)]565 bull0
-[(`NASM generates an error message saying Line 3 for an error that's actually on Line 5'; `NASM generates)]554 bull0
-[(an error message that I believe it shouldn't be generating at all'; `NASM fails to generate an error message)]543 bull0
-[(that I believe it )1(should)0( be generating'; `the object file produced from this source code crashes my linker';)]532 bull0
-[(`the ninth byte of the output file is 66 and I think it should be 77 instead'.)]521 bull2
-[(If you believe the output file from NASM to be faulty, send it to us. That allows us to determine whether)]504 bull1
-[(our own copy of NASM generates the same file, or whether the problem is related to portability issues)]493 bull0
-[(between our development platforms and yours. We can handle binary files mailed to us as MIME)]482 bull0
-[(attachments, uuencoded, and even BinHex. Alternatively, we may be able to provide an FTP site you can)]471 bull0
-[(upload the suspect files to; but mailing them is easier for us.)]460 bull2
-[(Any other information or data files that might be helpful. If, for example, the problem involves NASM)]443 bull1
-[(failing to generate an object file while TASM can generate an equivalent file without trouble, then send us)]432 bull0
-[1(both)0( object files, so we can see what TASM is doing differently from us.)]421 bull2
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-[{/appendix-A xa}(Appendix A: )(Ndisasm)]642.8 appn3
-[(The Netwide Disassembler, NDISASM)]601.8 norm3
-[{/section-A.1 xa}(Introduction)](A.1)580.4 head3
-[(The Netwide Disassembler is a small companion program to the Netwide Assembler, NASM. It seemed a)]563.4 norm1
-[(shame to have an x86 assembler, complete with a full instruction table, and not make as much use of it as)]552.4 norm0
-[(possible, so here's a disassembler which shares the instruction table \(and some other bits of code\) with NASM.)]541.4 norm2
-[(The Netwide Disassembler does nothing except to produce disassemblies of )1(binary)0( source files. NDISASM)]524.4 norm1
-[(does not have any understanding of object file formats, like )2(objdump)0(, and it will not understand )2(DOS .EXE)]513.4 norm0
-[(files like )2(debug)0( will. It just disassembles.)]502.4 norm2
-[{/section-A.2 xa}(Getting Started: Installation)](A.2)481 head3
-[(See ){/section-1.3 xl}(section 1.3){el}( for installation instructions. NDISASM, like NASM, has a )2(man page)0( which you may want)]464 norm1
-[(to put somewhere useful, if you are on a Unix system.)]453 norm2
-[{/section-A.3 xa}(Running NDISASM)](A.3)431.6 head3
-[(To disassemble a file, you will typically use a command of the form)]414.6 norm3
-[2( ndisasm -b {16|32|64} filename)]397.6 code3
-[(NDISASM can disassemble 16-, 32- or 64-bit code equally easily, provided of course that you remember to)]380.6 norm1
-[(specify which it is to work with. If no )2(-b)0( switch is present, NDISASM works in 16-bit mode by default. The)]369.6 norm0
-[2(-u)0( switch \(for USE32\) also invokes 32-bit mode.)]358.6 norm2
-[(Two more command line options are )2(-r)0( which reports the version number of NDISASM you are running, and)]341.6 norm1
-[2(-h)0( which gives a short summary of command line options.)]330.6 norm2
-[{/section-A.3.1 xa}(COM Files: Specifying an Origin)](A.3.1)311.4 subh3
-[(To disassemble a )2(DOS .COM)0( file correctly, a disassembler must assume that the first instruction in the file is)]294.4 norm1
-[(loaded at address )2(0x100)0(, rather than at zero. NDISASM, which assumes by default that any file you give it is)]283.4 norm0
-[(loaded at zero, will therefore need to be informed of this.)]272.4 norm2
-[(The )2(-o)0( option allows you to declare a different origin for the file you are disassembling. Its argument may be)]255.4 norm1
-[(expressed in any of the NASM numeric formats: decimal by default, if it begins with `)2($)0(' or `)2(0x)0(' or ends in)]244.4 norm0
-[(`)2(H)0(' it's )2(hex)0(, if it ends in `)2(Q)0(' it's )2(octal)0(, and if it ends in `)2(B)0(' it's )2(binary)0(.)]233.4 norm2
-[(Hence, to disassemble a )2(.COM)0( file:)]216.4 norm3
-[2( ndisasm -o100h filename.com)]199.4 code3
-[(will do the trick.)]182.4 norm3
-[{/section-A.3.2 xa}(Code Following Data: Synchronisation)](A.3.2)163.2 subh3
-[(Suppose you are disassembling a file which contains some data which isn't machine code, and )1(then)0( contains)]146.2 norm1
-[(some machine code. NDISASM will faithfully plough through the data section, producing machine)]135.2 norm0
-[(instructions wherever it can \(although most of them will look bizarre, and some may have unusual prefixes,)]124.2 norm0
-[(e.g. `)2(FS OR AX,0x240A)0('\), and generating `DB' instructions ever so often if it's totally stumped. Then it)]113.2 norm0
-[(will reach the code section.)]102.2 norm2
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-[(Supposing NDISASM has just finished generating a strange machine instruction from part of the data section,)]681 norm1
-[(and its file position is now one byte )1(before)0( the beginning of the code section. It's entirely possible that another)]670 norm0
-[(spurious instruction will get generated, starting with the final byte of the data section, and then the correct first)]659 norm0
-[(instruction in the code section will not be seen because the starting point skipped over it. This isn't really ideal.)]648 norm2
-[(To avoid this, you can specify a `)2(synchronisation)0(' point, or indeed as many synchronisation points as)]631 norm1
-[(you like \(although NDISASM can only handle 2147483647 sync points internally\). The definition of a sync)]620 norm0
-[(point is this: NDISASM guarantees to hit sync points exactly during disassembly. If it is thinking about)]609 norm0
-[(generating an instruction which would cause it to jump over a sync point, it will discard that instruction and)]598 norm0
-[(output a `)2(db)0(' instead. So it )1(will)0( start disassembly exactly from the sync point, and so you )1(will)0( see all the)]587 norm0
-[(instructions in your code section.)]576 norm2
-[(Sync points are specified using the )2(-s)0( option: they are measured in terms of the program origin, not the file)]559 norm1
-[(position. So if you want to synchronize after 32 bytes of a )2(.COM)0( file, you would have to do)]548 norm2
-[2( ndisasm -o100h -s120h file.com)]531 code3
-[(rather than)]514 norm3
-[2( ndisasm -o100h -s20h file.com)]497 code3
-[(As stated above, you can specify multiple sync markers if you need to, just by repeating the )2(-s)0( option.)]480 norm3
-[{/section-A.3.3 xa}(Mixed Code and Data: Automatic \(Intelligent\) Synchronisation )](A.3.3)460.8 subh3
-[(Suppose you are disassembling the boot sector of a )2(DOS)0( floppy \(maybe it has a virus, and you need to)]443.8 norm1
-[(understand the virus so that you know what kinds of damage it might have done you\). Typically, this will)]432.8 norm0
-[(contain a )2(JMP)0( instruction, then some data, then the rest of the code. So there is a very good chance of)]421.8 norm0
-[(NDISASM being )1(misaligned)0( when the data ends and the code begins. Hence a sync point is needed.)]410.8 norm2
-[(On the other hand, why should you have to specify the sync point manually? What you'd do in order to find)]393.8 norm1
-[(where the sync point would be, surely, would be to read the )2(JMP)0( instruction, and then to use its target address)]382.8 norm0
-[(as a sync point. So can NDISASM do that for you?)]371.8 norm2
-[(The answer, of course, is yes: using either of the synonymous switches )2(-a)0( \(for automatic sync\) or )2(-i)0( \(for)]354.8 norm1
-[(intelligent sync\) will enable )2(auto-sync)0( mode. Auto-sync mode automatically generates a sync point for)]343.8 norm0
-[(any forward-referring PC-relative jump or call instruction that NDISASM encounters. \(Since NDISASM is)]332.8 norm0
-[(one-pass, if it encounters a PC-relative jump whose target has already been processed, there isn't much it can)]321.8 norm0
-[(do about it...\))]310.8 norm2
-[(Only PC-relative jumps are processed, since an absolute jump is either through a register \(in which case)]293.8 norm1
-[(NDISASM doesn't know what the register contains\) or involves a segment address \(in which case the target)]282.8 norm0
-[(code isn't in the same segment that NDISASM is working in, and so the sync point can't be placed anywhere)]271.8 norm0
-[(useful\).)]260.8 norm2
-[(For some kinds of file, this mechanism will automatically put sync points in all the right places, and save you)]243.8 norm1
-[(from having to place any sync points manually. However, it should be stressed that auto-sync mode is )1(not)]232.8 norm0
-[(guaranteed to catch all the sync points, and you may still have to place some manually.)]221.8 norm2
-[(Auto-sync mode doesn't prevent you from declaring manual sync points: it just adds automatically generated)]204.8 norm1
-[(ones to the ones you provide. It's perfectly feasible to specify )2(-i)0( )1(and)0( some )2(-s)0( options.)]193.8 norm2
-[(Another caveat with auto-sync mode is that if, by some unpleasant fluke, something in your data section)]176.8 norm1
-[(should disassemble to a PC-relative call or jump instruction, NDISASM may obediently place a sync point in)]165.8 norm0
-[(a totally random place, for example in the middle of one of the instructions in your code section. So you may)]154.8 norm0
-[(end up with a wrong disassembly even if you use auto-sync. Again, there isn't much I can do about this. If)]143.8 norm0
-[(you have problems, you'll have to use manual sync points, or use the )2(-k)0( option \(documented below\) to)]132.8 norm0
-[(suppress disassembly of the data area.)]121.8 norm2
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-[{/section-A.3.4 xa}(Other Options)](A.3.4)678.8 subh3
-[(The )2(-e)0( option skips a header on the file, by ignoring the first N bytes. This means that the header is )1(not)]661.8 norm1
-[(counted towards the disassembly offset: if you give )2(-e10 -o10)0(, disassembly will start at byte 10 in the file,)]650.8 norm0
-[(and this will be given offset 10, not 20.)]639.8 norm2
-[(The )2(-k)0( option is provided with two comma-separated numeric arguments, the first of which is an assembly)]622.8 norm1
-[(offset and the second is a number of bytes to skip. This )1(will)0( count the skipped bytes towards the assembly)]611.8 norm0
-[(offset: its use is to suppress disassembly of a data section which wouldn't contain anything you wanted to see)]600.8 norm0
-[(anyway.)]589.8 norm2
-[{/section-A.4 xa}(Bugs and Improvements)](A.4)568.4 head3
-[(There are no known bugs. However, any you find, with patches if possible, should be sent to)]551.4 norm1
-[{(mailto:nasm-bugs@lists.sourceforge.net)wl}2(nasm-bugs@lists.sourceforge.net){el}0(, or to the developer's site at)]540.4 norm0
-[{(https://sourceforge.net/projects/nasm/)wl}2(https://sourceforge.net/projects/nasm/){el}0( and we'll try to fix them. Feel free to send)]529.4 norm0
-[(contributions and new features as well.)]518.4 norm2
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-[{/appendix-B xa}(Appendix B: )(Instruction List)]642.8 appn3
-[{/section-B.1 xa}(Introduction)](B.1)597.4 head3
-[(The following sections show the instructions which NASM currently supports. For each instruction, there is a)]580.4 norm1
-[(separate entry for each supported addressing mode. The third column shows the processor type in which the)]569.4 norm0
-[(instruction was introduced and, when appropriate, one or more usage flags.)]558.4 norm2
-[{/section-B.1.1 xa}(Special instructions...)](B.1.1)539.2 subh3
-[2(DB )]522.2 code1
-[2(DW )]511.2 code0
-[2(DD )]500.2 code0
-[2(DQ )]489.2 code0
-[2(DT )]478.2 code0
-[2(DO )]467.2 code0
-[2(DY )]456.2 code0
-[2(RESB imm 8086 )]445.2 code0
-[2(RESW )]434.2 code0
-[2(RESD )]423.2 code0
-[2(RESQ )]412.2 code0
-[2(REST )]401.2 code0
-[2(RESO )]390.2 code0
-[2(RESY )]379.2 code2
-[{/section-B.1.2 xa}(Conventional instructions)](B.1.2)360 subh3
-[2(AAA 8086,NOLONG )]343 code1
-[2(AAD 8086,NOLONG )]332 code0
-[2(AAD imm 8086,NOLONG )]321 code0
-[2(AAM 8086,NOLONG )]310 code0
-[2(AAM imm 8086,NOLONG )]299 code0
-[2(AAS 8086,NOLONG )]288 code0
-[2(ADC mem,reg8 8086 )]277 code0
-[2(ADC reg8,reg8 8086 )]266 code0
-[2(ADC mem,reg16 8086 )]255 code0
-[2(ADC reg16,reg16 8086 )]244 code0
-[2(ADC mem,reg32 386 )]233 code0
-[2(ADC reg32,reg32 386 )]222 code0
-[2(ADC mem,reg64 X64 )]211 code0
-[2(ADC reg64,reg64 X64 )]200 code0
-[2(ADC reg8,mem 8086 )]189 code0
-[2(ADC reg8,reg8 8086 )]178 code0
-[2(ADC reg16,mem 8086 )]167 code0
-[2(ADC reg16,reg16 8086 )]156 code0
-[2(ADC reg32,mem 386 )]145 code0
-[2(ADC reg32,reg32 386 )]134 code0
-[2(ADC reg64,mem X64 )]123 code0
-[2(ADC reg64,reg64 X64 )]112 code0
-[2(ADC rm16,imm8 8086 )]101 code0
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-[2(ADC rm32,imm8 386 )]681 code0
-[2(ADC rm64,imm8 X64 )]670 code0
-[2(ADC reg_al,imm 8086 )]659 code0
-[2(ADC reg_ax,sbyte16 8086 )]648 code0
-[2(ADC reg_ax,imm 8086 )]637 code0
-[2(ADC reg_eax,sbyte32 386 )]626 code0
-[2(ADC reg_eax,imm 386 )]615 code0
-[2(ADC reg_rax,sbyte64 X64 )]604 code0
-[2(ADC reg_rax,imm X64 )]593 code0
-[2(ADC rm8,imm 8086 )]582 code0
-[2(ADC rm16,imm 8086 )]571 code0
-[2(ADC rm32,imm 386 )]560 code0
-[2(ADC rm64,imm X64 )]549 code0
-[2(ADC mem,imm8 8086 )]538 code0
-[2(ADC mem,imm16 8086 )]527 code0
-[2(ADC mem,imm32 386 )]516 code0
-[2(ADD mem,reg8 8086 )]505 code0
-[2(ADD reg8,reg8 8086 )]494 code0
-[2(ADD mem,reg16 8086 )]483 code0
-[2(ADD reg16,reg16 8086 )]472 code0
-[2(ADD mem,reg32 386 )]461 code0
-[2(ADD reg32,reg32 386 )]450 code0
-[2(ADD mem,reg64 X64 )]439 code0
-[2(ADD reg64,reg64 X64 )]428 code0
-[2(ADD reg8,mem 8086 )]417 code0
-[2(ADD reg8,reg8 8086 )]406 code0
-[2(ADD reg16,mem 8086 )]395 code0
-[2(ADD reg16,reg16 8086 )]384 code0
-[2(ADD reg32,mem 386 )]373 code0
-[2(ADD reg32,reg32 386 )]362 code0
-[2(ADD reg64,mem X64 )]351 code0
-[2(ADD reg64,reg64 X64 )]340 code0
-[2(ADD rm16,imm8 8086 )]329 code0
-[2(ADD rm32,imm8 386 )]318 code0
-[2(ADD rm64,imm8 X64 )]307 code0
-[2(ADD reg_al,imm 8086 )]296 code0
-[2(ADD reg_ax,sbyte16 8086 )]285 code0
-[2(ADD reg_ax,imm 8086 )]274 code0
-[2(ADD reg_eax,sbyte32 386 )]263 code0
-[2(ADD reg_eax,imm 386 )]252 code0
-[2(ADD reg_rax,sbyte64 X64 )]241 code0
-[2(ADD reg_rax,imm X64 )]230 code0
-[2(ADD rm8,imm 8086 )]219 code0
-[2(ADD rm16,imm 8086 )]208 code0
-[2(ADD rm32,imm 386 )]197 code0
-[2(ADD rm64,imm X64 )]186 code0
-[2(ADD mem,imm8 8086 )]175 code0
-[2(ADD mem,imm16 8086 )]164 code0
-[2(ADD mem,imm32 386 )]153 code0
-[2(AND mem,reg8 8086 )]142 code0
-[2(AND reg8,reg8 8086 )]131 code0
-[2(AND mem,reg16 8086 )]120 code0
-[2(AND reg16,reg16 8086 )]109 code0
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-[2(AND mem,reg32 386 )]681 code0
-[2(AND reg32,reg32 386 )]670 code0
-[2(AND mem,reg64 X64 )]659 code0
-[2(AND reg64,reg64 X64 )]648 code0
-[2(AND reg8,mem 8086 )]637 code0
-[2(AND reg8,reg8 8086 )]626 code0
-[2(AND reg16,mem 8086 )]615 code0
-[2(AND reg16,reg16 8086 )]604 code0
-[2(AND reg32,mem 386 )]593 code0
-[2(AND reg32,reg32 386 )]582 code0
-[2(AND reg64,mem X64 )]571 code0
-[2(AND reg64,reg64 X64 )]560 code0
-[2(AND rm16,imm8 8086 )]549 code0
-[2(AND rm32,imm8 386 )]538 code0
-[2(AND rm64,imm8 X64 )]527 code0
-[2(AND reg_al,imm 8086 )]516 code0
-[2(AND reg_ax,sbyte16 8086 )]505 code0
-[2(AND reg_ax,imm 8086 )]494 code0
-[2(AND reg_eax,sbyte32 386 )]483 code0
-[2(AND reg_eax,imm 386 )]472 code0
-[2(AND reg_rax,sbyte64 X64 )]461 code0
-[2(AND reg_rax,imm X64 )]450 code0
-[2(AND rm8,imm 8086 )]439 code0
-[2(AND rm16,imm 8086 )]428 code0
-[2(AND rm32,imm 386 )]417 code0
-[2(AND rm64,imm X64 )]406 code0
-[2(AND mem,imm8 8086 )]395 code0
-[2(AND mem,imm16 8086 )]384 code0
-[2(AND mem,imm32 386 )]373 code0
-[2(ARPL mem,reg16 286,PROT,NOLONG )]362 code0
-[2(ARPL reg16,reg16 286,PROT,NOLONG )]351 code0
-[2(BB0_RESET PENT,CYRIX,ND )]340 code0
-[2(BB1_RESET PENT,CYRIX,ND )]329 code0
-[2(BOUND reg16,mem 186,NOLONG )]318 code0
-[2(BOUND reg32,mem 386,NOLONG )]307 code0
-[2(BSF reg16,mem 386 )]296 code0
-[2(BSF reg16,reg16 386 )]285 code0
-[2(BSF reg32,mem 386 )]274 code0
-[2(BSF reg32,reg32 386 )]263 code0
-[2(BSF reg64,mem X64 )]252 code0
-[2(BSF reg64,reg64 X64 )]241 code0
-[2(BSR reg16,mem 386 )]230 code0
-[2(BSR reg16,reg16 386 )]219 code0
-[2(BSR reg32,mem 386 )]208 code0
-[2(BSR reg32,reg32 386 )]197 code0
-[2(BSR reg64,mem X64 )]186 code0
-[2(BSR reg64,reg64 X64 )]175 code0
-[2(BSWAP reg32 486 )]164 code0
-[2(BSWAP reg64 X64 )]153 code0
-[2(BT mem,reg16 386 )]142 code0
-[2(BT reg16,reg16 386 )]131 code0
-[2(BT mem,reg32 386 )]120 code0
-[2(BT reg32,reg32 386 )]109 code0
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-[2(BT mem,reg64 X64 )]681 code0
-[2(BT reg64,reg64 X64 )]670 code0
-[2(BT rm16,imm 386 )]659 code0
-[2(BT rm32,imm 386 )]648 code0
-[2(BT rm64,imm X64 )]637 code0
-[2(BTC mem,reg16 386 )]626 code0
-[2(BTC reg16,reg16 386 )]615 code0
-[2(BTC mem,reg32 386 )]604 code0
-[2(BTC reg32,reg32 386 )]593 code0
-[2(BTC mem,reg64 X64 )]582 code0
-[2(BTC reg64,reg64 X64 )]571 code0
-[2(BTC rm16,imm 386 )]560 code0
-[2(BTC rm32,imm 386 )]549 code0
-[2(BTC rm64,imm X64 )]538 code0
-[2(BTR mem,reg16 386 )]527 code0
-[2(BTR reg16,reg16 386 )]516 code0
-[2(BTR mem,reg32 386 )]505 code0
-[2(BTR reg32,reg32 386 )]494 code0
-[2(BTR mem,reg64 X64 )]483 code0
-[2(BTR reg64,reg64 X64 )]472 code0
-[2(BTR rm16,imm 386 )]461 code0
-[2(BTR rm32,imm 386 )]450 code0
-[2(BTR rm64,imm X64 )]439 code0
-[2(BTS mem,reg16 386 )]428 code0
-[2(BTS reg16,reg16 386 )]417 code0
-[2(BTS mem,reg32 386 )]406 code0
-[2(BTS reg32,reg32 386 )]395 code0
-[2(BTS mem,reg64 X64 )]384 code0
-[2(BTS reg64,reg64 X64 )]373 code0
-[2(BTS rm16,imm 386 )]362 code0
-[2(BTS rm32,imm 386 )]351 code0
-[2(BTS rm64,imm X64 )]340 code0
-[2(CALL imm 8086 )]329 code0
-[2(CALL imm|near 8086 )]318 code0
-[2(CALL imm|far 8086,ND,NOLONG )]307 code0
-[2(CALL imm16 8086 )]296 code0
-[2(CALL imm16|near 8086 )]285 code0
-[2(CALL imm16|far 8086,ND,NOLONG )]274 code0
-[2(CALL imm32 386 )]263 code0
-[2(CALL imm32|near 386 )]252 code0
-[2(CALL imm32|far 386,ND,NOLONG )]241 code0
-[2(CALL imm:imm 8086,NOLONG )]230 code0
-[2(CALL imm16:imm 8086,NOLONG )]219 code0
-[2(CALL imm:imm16 8086,NOLONG )]208 code0
-[2(CALL imm32:imm 386,NOLONG )]197 code0
-[2(CALL imm:imm32 386,NOLONG )]186 code0
-[2(CALL mem|far 8086,NOLONG )]175 code0
-[2(CALL mem|far X64 )]164 code0
-[2(CALL mem16|far 8086 )]153 code0
-[2(CALL mem32|far 386 )]142 code0
-[2(CALL mem64|far X64 )]131 code0
-[2(CALL mem|near 8086 )]120 code0
-[2(CALL mem16|near 8086 )]109 code0
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-[2(CALL mem32|near 386,NOLONG )]681 code0
-[2(CALL mem64|near X64 )]670 code0
-[2(CALL reg16 8086 )]659 code0
-[2(CALL reg32 386,NOLONG )]648 code0
-[2(CALL reg64 X64 )]637 code0
-[2(CALL mem 8086 )]626 code0
-[2(CALL mem16 8086 )]615 code0
-[2(CALL mem32 386,NOLONG )]604 code0
-[2(CALL mem64 X64 )]593 code0
-[2(CBW 8086 )]582 code0
-[2(CDQ 386 )]571 code0
-[2(CDQE X64 )]560 code0
-[2(CLC 8086 )]549 code0
-[2(CLD 8086 )]538 code0
-[2(CLGI X64,AMD )]527 code0
-[2(CLI 8086 )]516 code0
-[2(CLTS 286,PRIV )]505 code0
-[2(CMC 8086 )]494 code0
-[2(CMP mem,reg8 8086 )]483 code0
-[2(CMP reg8,reg8 8086 )]472 code0
-[2(CMP mem,reg16 8086 )]461 code0
-[2(CMP reg16,reg16 8086 )]450 code0
-[2(CMP mem,reg32 386 )]439 code0
-[2(CMP reg32,reg32 386 )]428 code0
-[2(CMP mem,reg64 X64 )]417 code0
-[2(CMP reg64,reg64 X64 )]406 code0
-[2(CMP reg8,mem 8086 )]395 code0
-[2(CMP reg8,reg8 8086 )]384 code0
-[2(CMP reg16,mem 8086 )]373 code0
-[2(CMP reg16,reg16 8086 )]362 code0
-[2(CMP reg32,mem 386 )]351 code0
-[2(CMP reg32,reg32 386 )]340 code0
-[2(CMP reg64,mem X64 )]329 code0
-[2(CMP reg64,reg64 X64 )]318 code0
-[2(CMP rm16,imm8 8086 )]307 code0
-[2(CMP rm32,imm8 386 )]296 code0
-[2(CMP rm64,imm8 X64 )]285 code0
-[2(CMP reg_al,imm 8086 )]274 code0
-[2(CMP reg_ax,sbyte16 8086 )]263 code0
-[2(CMP reg_ax,imm 8086 )]252 code0
-[2(CMP reg_eax,sbyte32 386 )]241 code0
-[2(CMP reg_eax,imm 386 )]230 code0
-[2(CMP reg_rax,sbyte64 X64 )]219 code0
-[2(CMP reg_rax,imm X64 )]208 code0
-[2(CMP rm8,imm 8086 )]197 code0
-[2(CMP rm16,imm 8086 )]186 code0
-[2(CMP rm32,imm 386 )]175 code0
-[2(CMP rm64,imm X64 )]164 code0
-[2(CMP mem,imm8 8086 )]153 code0
-[2(CMP mem,imm16 8086 )]142 code0
-[2(CMP mem,imm32 386 )]131 code0
-[2(CMPSB 8086 )]120 code0
-[2(CMPSD 386 )]109 code0
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-[2(CMPSQ X64 )]681 code0
-[2(CMPSW 8086 )]670 code0
-[2(CMPXCHG mem,reg8 PENT )]659 code0
-[2(CMPXCHG reg8,reg8 PENT )]648 code0
-[2(CMPXCHG mem,reg16 PENT )]637 code0
-[2(CMPXCHG reg16,reg16 PENT )]626 code0
-[2(CMPXCHG mem,reg32 PENT )]615 code0
-[2(CMPXCHG reg32,reg32 PENT )]604 code0
-[2(CMPXCHG mem,reg64 X64 )]593 code0
-[2(CMPXCHG reg64,reg64 X64 )]582 code0
-[2(CMPXCHG486 mem,reg8 486,UNDOC,ND )]571 code0
-[2(CMPXCHG486 reg8,reg8 486,UNDOC,ND )]560 code0
-[2(CMPXCHG486 mem,reg16 486,UNDOC,ND )]549 code0
-[2(CMPXCHG486 reg16,reg16 486,UNDOC,ND )]538 code0
-[2(CMPXCHG486 mem,reg32 486,UNDOC,ND )]527 code0
-[2(CMPXCHG486 reg32,reg32 486,UNDOC,ND )]516 code0
-[2(CMPXCHG8B mem PENT )]505 code0
-[2(CMPXCHG16B mem X64 )]494 code0
-[2(CPUID PENT )]483 code0
-[2(CPU_READ PENT,CYRIX )]472 code0
-[2(CPU_WRITE PENT,CYRIX )]461 code0
-[2(CQO X64 )]450 code0
-[2(CWD 8086 )]439 code0
-[2(CWDE 386 )]428 code0
-[2(DAA 8086,NOLONG )]417 code0
-[2(DAS 8086,NOLONG )]406 code0
-[2(DEC reg16 8086,NOLONG )]395 code0
-[2(DEC reg32 386,NOLONG )]384 code0
-[2(DEC rm8 8086 )]373 code0
-[2(DEC rm16 8086 )]362 code0
-[2(DEC rm32 386 )]351 code0
-[2(DEC rm64 X64 )]340 code0
-[2(DIV rm8 8086 )]329 code0
-[2(DIV rm16 8086 )]318 code0
-[2(DIV rm32 386 )]307 code0
-[2(DIV rm64 X64 )]296 code0
-[2(DMINT P6,CYRIX )]285 code0
-[2(EMMS PENT,MMX )]274 code0
-[2(ENTER imm,imm 186 )]263 code0
-[2(EQU imm 8086 )]252 code0
-[2(EQU imm:imm 8086 )]241 code0
-[2(F2XM1 8086,FPU )]230 code0
-[2(FABS 8086,FPU )]219 code0
-[2(FADD mem32 8086,FPU )]208 code0
-[2(FADD mem64 8086,FPU )]197 code0
-[2(FADD fpureg|to 8086,FPU )]186 code0
-[2(FADD fpureg 8086,FPU )]175 code0
-[2(FADD fpureg,fpu0 8086,FPU )]164 code0
-[2(FADD fpu0,fpureg 8086,FPU )]153 code0
-[2(FADD 8086,FPU,ND )]142 code0
-[2(FADDP fpureg 8086,FPU )]131 code0
-[2(FADDP fpureg,fpu0 8086,FPU )]120 code0
-[2(FADDP 8086,FPU,ND )]109 code0
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-/128 pa
-[2(FBLD mem80 8086,FPU )]681 code0
-[2(FBLD mem 8086,FPU )]670 code0
-[2(FBSTP mem80 8086,FPU )]659 code0
-[2(FBSTP mem 8086,FPU )]648 code0
-[2(FCHS 8086,FPU )]637 code0
-[2(FCLEX 8086,FPU )]626 code0
-[2(FCMOVB fpureg P6,FPU )]615 code0
-[2(FCMOVB fpu0,fpureg P6,FPU )]604 code0
-[2(FCMOVB P6,FPU,ND )]593 code0
-[2(FCMOVBE fpureg P6,FPU )]582 code0
-[2(FCMOVBE fpu0,fpureg P6,FPU )]571 code0
-[2(FCMOVBE P6,FPU,ND )]560 code0
-[2(FCMOVE fpureg P6,FPU )]549 code0
-[2(FCMOVE fpu0,fpureg P6,FPU )]538 code0
-[2(FCMOVE P6,FPU,ND )]527 code0
-[2(FCMOVNB fpureg P6,FPU )]516 code0
-[2(FCMOVNB fpu0,fpureg P6,FPU )]505 code0
-[2(FCMOVNB P6,FPU,ND )]494 code0
-[2(FCMOVNBE fpureg P6,FPU )]483 code0
-[2(FCMOVNBE fpu0,fpureg P6,FPU )]472 code0
-[2(FCMOVNBE P6,FPU,ND )]461 code0
-[2(FCMOVNE fpureg P6,FPU )]450 code0
-[2(FCMOVNE fpu0,fpureg P6,FPU )]439 code0
-[2(FCMOVNE P6,FPU,ND )]428 code0
-[2(FCMOVNU fpureg P6,FPU )]417 code0
-[2(FCMOVNU fpu0,fpureg P6,FPU )]406 code0
-[2(FCMOVNU P6,FPU,ND )]395 code0
-[2(FCMOVU fpureg P6,FPU )]384 code0
-[2(FCMOVU fpu0,fpureg P6,FPU )]373 code0
-[2(FCMOVU P6,FPU,ND )]362 code0
-[2(FCOM mem32 8086,FPU )]351 code0
-[2(FCOM mem64 8086,FPU )]340 code0
-[2(FCOM fpureg 8086,FPU )]329 code0
-[2(FCOM fpu0,fpureg 8086,FPU )]318 code0
-[2(FCOM 8086,FPU,ND )]307 code0
-[2(FCOMI fpureg P6,FPU )]296 code0
-[2(FCOMI fpu0,fpureg P6,FPU )]285 code0
-[2(FCOMI P6,FPU,ND )]274 code0
-[2(FCOMIP fpureg P6,FPU )]263 code0
-[2(FCOMIP fpu0,fpureg P6,FPU )]252 code0
-[2(FCOMIP P6,FPU,ND )]241 code0
-[2(FCOMP mem32 8086,FPU )]230 code0
-[2(FCOMP mem64 8086,FPU )]219 code0
-[2(FCOMP fpureg 8086,FPU )]208 code0
-[2(FCOMP fpu0,fpureg 8086,FPU )]197 code0
-[2(FCOMP 8086,FPU,ND )]186 code0
-[2(FCOMPP 8086,FPU )]175 code0
-[2(FCOS 386,FPU )]164 code0
-[2(FDECSTP 8086,FPU )]153 code0
-[2(FDISI 8086,FPU )]142 code0
-[2(FDIV mem32 8086,FPU )]131 code0
-[2(FDIV mem64 8086,FPU )]120 code0
-[2(FDIV fpureg|to 8086,FPU )]109 code0
-(128)pageeven
-restore showpage
-%%Page: 129 129
-%%BeginPageSetup
-save
-%%EndPageSetup
-/129 pa
-[2(FDIV fpureg 8086,FPU )]681 code0
-[2(FDIV fpureg,fpu0 8086,FPU )]670 code0
-[2(FDIV fpu0,fpureg 8086,FPU )]659 code0
-[2(FDIV 8086,FPU,ND )]648 code0
-[2(FDIVP fpureg 8086,FPU )]637 code0
-[2(FDIVP fpureg,fpu0 8086,FPU )]626 code0
-[2(FDIVP 8086,FPU,ND )]615 code0
-[2(FDIVR mem32 8086,FPU )]604 code0
-[2(FDIVR mem64 8086,FPU )]593 code0
-[2(FDIVR fpureg|to 8086,FPU )]582 code0
-[2(FDIVR fpureg,fpu0 8086,FPU )]571 code0
-[2(FDIVR fpureg 8086,FPU )]560 code0
-[2(FDIVR fpu0,fpureg 8086,FPU )]549 code0
-[2(FDIVR 8086,FPU,ND )]538 code0
-[2(FDIVRP fpureg 8086,FPU )]527 code0
-[2(FDIVRP fpureg,fpu0 8086,FPU )]516 code0
-[2(FDIVRP 8086,FPU,ND )]505 code0
-[2(FEMMS PENT,3DNOW )]494 code0
-[2(FENI 8086,FPU )]483 code0
-[2(FFREE fpureg 8086,FPU )]472 code0
-[2(FFREE 8086,FPU )]461 code0
-[2(FFREEP fpureg 286,FPU,UNDOC )]450 code0
-[2(FFREEP 286,FPU,UNDOC )]439 code0
-[2(FIADD mem32 8086,FPU )]428 code0
-[2(FIADD mem16 8086,FPU )]417 code0
-[2(FICOM mem32 8086,FPU )]406 code0
-[2(FICOM mem16 8086,FPU )]395 code0
-[2(FICOMP mem32 8086,FPU )]384 code0
-[2(FICOMP mem16 8086,FPU )]373 code0
-[2(FIDIV mem32 8086,FPU )]362 code0
-[2(FIDIV mem16 8086,FPU )]351 code0
-[2(FIDIVR mem32 8086,FPU )]340 code0
-[2(FIDIVR mem16 8086,FPU )]329 code0
-[2(FILD mem32 8086,FPU )]318 code0
-[2(FILD mem16 8086,FPU )]307 code0
-[2(FILD mem64 8086,FPU )]296 code0
-[2(FIMUL mem32 8086,FPU )]285 code0
-[2(FIMUL mem16 8086,FPU )]274 code0
-[2(FINCSTP 8086,FPU )]263 code0
-[2(FINIT 8086,FPU )]252 code0
-[2(FIST mem32 8086,FPU )]241 code0
-[2(FIST mem16 8086,FPU )]230 code0
-[2(FISTP mem32 8086,FPU )]219 code0
-[2(FISTP mem16 8086,FPU )]208 code0
-[2(FISTP mem64 8086,FPU )]197 code0
-[2(FISTTP mem16 PRESCOTT,FPU )]186 code0
-[2(FISTTP mem32 PRESCOTT,FPU )]175 code0
-[2(FISTTP mem64 PRESCOTT,FPU )]164 code0
-[2(FISUB mem32 8086,FPU )]153 code0
-[2(FISUB mem16 8086,FPU )]142 code0
-[2(FISUBR mem32 8086,FPU )]131 code0
-[2(FISUBR mem16 8086,FPU )]120 code0
-[2(FLD mem32 8086,FPU )]109 code0
-(129)pageodd
-restore showpage
-%%Page: 130 130
-%%BeginPageSetup
-save
-%%EndPageSetup
-/130 pa
-[2(FLD mem64 8086,FPU )]681 code0
-[2(FLD mem80 8086,FPU )]670 code0
-[2(FLD fpureg 8086,FPU )]659 code0
-[2(FLD 8086,FPU,ND )]648 code0
-[2(FLD1 8086,FPU )]637 code0
-[2(FLDCW mem 8086,FPU,SW )]626 code0
-[2(FLDENV mem 8086,FPU )]615 code0
-[2(FLDL2E 8086,FPU )]604 code0
-[2(FLDL2T 8086,FPU )]593 code0
-[2(FLDLG2 8086,FPU )]582 code0
-[2(FLDLN2 8086,FPU )]571 code0
-[2(FLDPI 8086,FPU )]560 code0
-[2(FLDZ 8086,FPU )]549 code0
-[2(FMUL mem32 8086,FPU )]538 code0
-[2(FMUL mem64 8086,FPU )]527 code0
-[2(FMUL fpureg|to 8086,FPU )]516 code0
-[2(FMUL fpureg,fpu0 8086,FPU )]505 code0
-[2(FMUL fpureg 8086,FPU )]494 code0
-[2(FMUL fpu0,fpureg 8086,FPU )]483 code0
-[2(FMUL 8086,FPU,ND )]472 code0
-[2(FMULP fpureg 8086,FPU )]461 code0
-[2(FMULP fpureg,fpu0 8086,FPU )]450 code0
-[2(FMULP 8086,FPU,ND )]439 code0
-[2(FNCLEX 8086,FPU )]428 code0
-[2(FNDISI 8086,FPU )]417 code0
-[2(FNENI 8086,FPU )]406 code0
-[2(FNINIT 8086,FPU )]395 code0
-[2(FNOP 8086,FPU )]384 code0
-[2(FNSAVE mem 8086,FPU )]373 code0
-[2(FNSTCW mem 8086,FPU,SW )]362 code0
-[2(FNSTENV mem 8086,FPU )]351 code0
-[2(FNSTSW mem 8086,FPU,SW )]340 code0
-[2(FNSTSW reg_ax 286,FPU )]329 code0
-[2(FPATAN 8086,FPU )]318 code0
-[2(FPREM 8086,FPU )]307 code0
-[2(FPREM1 386,FPU )]296 code0
-[2(FPTAN 8086,FPU )]285 code0
-[2(FRNDINT 8086,FPU )]274 code0
-[2(FRSTOR mem 8086,FPU )]263 code0
-[2(FSAVE mem 8086,FPU )]252 code0
-[2(FSCALE 8086,FPU )]241 code0
-[2(FSETPM 286,FPU )]230 code0
-[2(FSIN 386,FPU )]219 code0
-[2(FSINCOS 386,FPU )]208 code0
-[2(FSQRT 8086,FPU )]197 code0
-[2(FST mem32 8086,FPU )]186 code0
-[2(FST mem64 8086,FPU )]175 code0
-[2(FST fpureg 8086,FPU )]164 code0
-[2(FST 8086,FPU,ND )]153 code0
-[2(FSTCW mem 8086,FPU,SW )]142 code0
-[2(FSTENV mem 8086,FPU )]131 code0
-[2(FSTP mem32 8086,FPU )]120 code0
-[2(FSTP mem64 8086,FPU )]109 code0
-(130)pageeven
-restore showpage
-%%Page: 131 131
-%%BeginPageSetup
-save
-%%EndPageSetup
-/131 pa
-[2(FSTP mem80 8086,FPU )]681 code0
-[2(FSTP fpureg 8086,FPU )]670 code0
-[2(FSTP 8086,FPU,ND )]659 code0
-[2(FSTSW mem 8086,FPU,SW )]648 code0
-[2(FSTSW reg_ax 286,FPU )]637 code0
-[2(FSUB mem32 8086,FPU )]626 code0
-[2(FSUB mem64 8086,FPU )]615 code0
-[2(FSUB fpureg|to 8086,FPU )]604 code0
-[2(FSUB fpureg,fpu0 8086,FPU )]593 code0
-[2(FSUB fpureg 8086,FPU )]582 code0
-[2(FSUB fpu0,fpureg 8086,FPU )]571 code0
-[2(FSUB 8086,FPU,ND )]560 code0
-[2(FSUBP fpureg 8086,FPU )]549 code0
-[2(FSUBP fpureg,fpu0 8086,FPU )]538 code0
-[2(FSUBP 8086,FPU,ND )]527 code0
-[2(FSUBR mem32 8086,FPU )]516 code0
-[2(FSUBR mem64 8086,FPU )]505 code0
-[2(FSUBR fpureg|to 8086,FPU )]494 code0
-[2(FSUBR fpureg,fpu0 8086,FPU )]483 code0
-[2(FSUBR fpureg 8086,FPU )]472 code0
-[2(FSUBR fpu0,fpureg 8086,FPU )]461 code0
-[2(FSUBR 8086,FPU,ND )]450 code0
-[2(FSUBRP fpureg 8086,FPU )]439 code0
-[2(FSUBRP fpureg,fpu0 8086,FPU )]428 code0
-[2(FSUBRP 8086,FPU,ND )]417 code0
-[2(FTST 8086,FPU )]406 code0
-[2(FUCOM fpureg 386,FPU )]395 code0
-[2(FUCOM fpu0,fpureg 386,FPU )]384 code0
-[2(FUCOM 386,FPU,ND )]373 code0
-[2(FUCOMI fpureg P6,FPU )]362 code0
-[2(FUCOMI fpu0,fpureg P6,FPU )]351 code0
-[2(FUCOMI P6,FPU,ND )]340 code0
-[2(FUCOMIP fpureg P6,FPU )]329 code0
-[2(FUCOMIP fpu0,fpureg P6,FPU )]318 code0
-[2(FUCOMIP P6,FPU,ND )]307 code0
-[2(FUCOMP fpureg 386,FPU )]296 code0
-[2(FUCOMP fpu0,fpureg 386,FPU )]285 code0
-[2(FUCOMP 386,FPU,ND )]274 code0
-[2(FUCOMPP 386,FPU )]263 code0
-[2(FXAM 8086,FPU )]252 code0
-[2(FXCH fpureg 8086,FPU )]241 code0
-[2(FXCH fpureg,fpu0 8086,FPU )]230 code0
-[2(FXCH fpu0,fpureg 8086,FPU )]219 code0
-[2(FXCH 8086,FPU,ND )]208 code0
-[2(FXTRACT 8086,FPU )]197 code0
-[2(FYL2X 8086,FPU )]186 code0
-[2(FYL2XP1 8086,FPU )]175 code0
-[2(HLT 8086,PRIV )]164 code0
-[2(IBTS mem,reg16 386,SW,UNDOC,ND )]153 code0
-[2(IBTS reg16,reg16 386,UNDOC,ND )]142 code0
-[2(IBTS mem,reg32 386,SD,UNDOC,ND )]131 code0
-[2(IBTS reg32,reg32 386,UNDOC,ND )]120 code0
-[2(ICEBP 386,ND )]109 code0
-(131)pageodd
-restore showpage
-%%Page: 132 132
-%%BeginPageSetup
-save
-%%EndPageSetup
-/132 pa
-[2(IDIV rm8 8086 )]681 code0
-[2(IDIV rm16 8086 )]670 code0
-[2(IDIV rm32 386 )]659 code0
-[2(IDIV rm64 X64 )]648 code0
-[2(IMUL rm8 8086 )]637 code0
-[2(IMUL rm16 8086 )]626 code0
-[2(IMUL rm32 386 )]615 code0
-[2(IMUL rm64 X64 )]604 code0
-[2(IMUL reg16,mem 386 )]593 code0
-[2(IMUL reg16,reg16 386 )]582 code0
-[2(IMUL reg32,mem 386 )]571 code0
-[2(IMUL reg32,reg32 386 )]560 code0
-[2(IMUL reg64,mem X64 )]549 code0
-[2(IMUL reg64,reg64 X64 )]538 code0
-[2(IMUL reg16,mem,imm8 186 )]527 code0
-[2(IMUL reg16,mem,sbyte16 186,ND )]516 code0
-[2(IMUL reg16,mem,imm16 186 )]505 code0
-[2(IMUL reg16,mem,imm 186,ND )]494 code0
-[2(IMUL reg16,reg16,imm8 186 )]483 code0
-[2(IMUL reg16,reg16,sbyte16 186,ND )]472 code0
-[2(IMUL reg16,reg16,imm16 186 )]461 code0
-[2(IMUL reg16,reg16,imm 186,ND )]450 code0
-[2(IMUL reg32,mem,imm8 386 )]439 code0
-[2(IMUL reg32,mem,sbyte32 386,ND )]428 code0
-[2(IMUL reg32,mem,imm32 386 )]417 code0
-[2(IMUL reg32,mem,imm 386,ND )]406 code0
-[2(IMUL reg32,reg32,imm8 386 )]395 code0
-[2(IMUL reg32,reg32,sbyte32 386,ND )]384 code0
-[2(IMUL reg32,reg32,imm32 386 )]373 code0
-[2(IMUL reg32,reg32,imm 386,ND )]362 code0
-[2(IMUL reg64,mem,imm8 X64 )]351 code0
-[2(IMUL reg64,mem,sbyte64 X64,ND )]340 code0
-[2(IMUL reg64,mem,imm32 X64 )]329 code0
-[2(IMUL reg64,mem,imm X64,ND )]318 code0
-[2(IMUL reg64,reg64,imm8 X64 )]307 code0
-[2(IMUL reg64,reg64,sbyte64 X64,ND )]296 code0
-[2(IMUL reg64,reg64,imm32 X64 )]285 code0
-[2(IMUL reg64,reg64,imm X64,ND )]274 code0
-[2(IMUL reg16,imm8 186 )]263 code0
-[2(IMUL reg16,sbyte16 186,ND )]252 code0
-[2(IMUL reg16,imm16 186 )]241 code0
-[2(IMUL reg16,imm 186,ND )]230 code0
-[2(IMUL reg32,imm8 386 )]219 code0
-[2(IMUL reg32,sbyte32 386,ND )]208 code0
-[2(IMUL reg32,imm32 386 )]197 code0
-[2(IMUL reg32,imm 386,ND )]186 code0
-[2(IMUL reg64,imm8 X64 )]175 code0
-[2(IMUL reg64,sbyte64 X64,ND )]164 code0
-[2(IMUL reg64,imm32 X64 )]153 code0
-[2(IMUL reg64,imm X64,ND )]142 code0
-[2(IN reg_al,imm 8086 )]131 code0
-[2(IN reg_ax,imm 8086 )]120 code0
-[2(IN reg_eax,imm 386 )]109 code0
-(132)pageeven
-restore showpage
-%%Page: 133 133
-%%BeginPageSetup
-save
-%%EndPageSetup
-/133 pa
-[2(IN reg_al,reg_dx 8086 )]681 code0
-[2(IN reg_ax,reg_dx 8086 )]670 code0
-[2(IN reg_eax,reg_dx 386 )]659 code0
-[2(INC reg16 8086,NOLONG )]648 code0
-[2(INC reg32 386,NOLONG )]637 code0
-[2(INC rm8 8086 )]626 code0
-[2(INC rm16 8086 )]615 code0
-[2(INC rm32 386 )]604 code0
-[2(INC rm64 X64 )]593 code0
-[2(INCBIN )]582 code0
-[2(INSB 186 )]571 code0
-[2(INSD 386 )]560 code0
-[2(INSW 186 )]549 code0
-[2(INT imm 8086 )]538 code0
-[2(INT01 386,ND )]527 code0
-[2(INT1 386 )]516 code0
-[2(INT03 8086,ND )]505 code0
-[2(INT3 8086 )]494 code0
-[2(INTO 8086,NOLONG )]483 code0
-[2(INVD 486,PRIV )]472 code0
-[2(INVLPG mem 486,PRIV )]461 code0
-[2(INVLPGA reg_ax,reg_ecx X86_64,AMD,NOLONG )]450 code0
-[2(INVLPGA reg_eax,reg_ecx X86_64,AMD )]439 code0
-[2(INVLPGA reg_rax,reg_ecx X64,AMD )]428 code0
-[2(INVLPGA X86_64,AMD )]417 code0
-[2(IRET 8086 )]406 code0
-[2(IRETD 386 )]395 code0
-[2(IRETQ X64 )]384 code0
-[2(IRETW 8086 )]373 code0
-[2(JCXZ imm 8086,NOLONG )]362 code0
-[2(JECXZ imm 386 )]351 code0
-[2(JRCXZ imm X64 )]340 code0
-[2(JMP imm|short 8086 )]329 code0
-[2(JMP imm 8086,ND )]318 code0
-[2(JMP imm 8086 )]307 code0
-[2(JMP imm|near 8086,ND )]296 code0
-[2(JMP imm|far 8086,ND,NOLONG )]285 code0
-[2(JMP imm16 8086 )]274 code0
-[2(JMP imm16|near 8086,ND )]263 code0
-[2(JMP imm16|far 8086,ND,NOLONG )]252 code0
-[2(JMP imm32 386 )]241 code0
-[2(JMP imm32|near 386,ND )]230 code0
-[2(JMP imm32|far 386,ND,NOLONG )]219 code0
-[2(JMP imm:imm 8086,NOLONG )]208 code0
-[2(JMP imm16:imm 8086,NOLONG )]197 code0
-[2(JMP imm:imm16 8086,NOLONG )]186 code0
-[2(JMP imm32:imm 386,NOLONG )]175 code0
-[2(JMP imm:imm32 386,NOLONG )]164 code0
-[2(JMP mem|far 8086,NOLONG )]153 code0
-[2(JMP mem|far X64 )]142 code0
-[2(JMP mem16|far 8086 )]131 code0
-[2(JMP mem32|far 386 )]120 code0
-[2(JMP mem64|far X64 )]109 code0
-(133)pageodd
-restore showpage
-%%Page: 134 134
-%%BeginPageSetup
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-%%EndPageSetup
-/134 pa
-[2(JMP mem|near 8086 )]681 code0
-[2(JMP mem16|near 8086 )]670 code0
-[2(JMP mem32|near 386,NOLONG )]659 code0
-[2(JMP mem64|near X64 )]648 code0
-[2(JMP reg16 8086 )]637 code0
-[2(JMP reg32 386,NOLONG )]626 code0
-[2(JMP reg64 X64 )]615 code0
-[2(JMP mem 8086 )]604 code0
-[2(JMP mem16 8086 )]593 code0
-[2(JMP mem32 386,NOLONG )]582 code0
-[2(JMP mem64 X64 )]571 code0
-[2(JMPE imm IA64 )]560 code0
-[2(JMPE imm16 IA64 )]549 code0
-[2(JMPE imm32 IA64 )]538 code0
-[2(JMPE rm16 IA64 )]527 code0
-[2(JMPE rm32 IA64 )]516 code0
-[2(LAHF 8086 )]505 code0
-[2(LAR reg16,mem 286,PROT,SW )]494 code0
-[2(LAR reg16,reg16 286,PROT )]483 code0
-[2(LAR reg16,reg32 386,PROT )]472 code0
-[2(LAR reg16,reg64 X64,PROT,ND )]461 code0
-[2(LAR reg32,mem 386,PROT,SW )]450 code0
-[2(LAR reg32,reg16 386,PROT )]439 code0
-[2(LAR reg32,reg32 386,PROT )]428 code0
-[2(LAR reg32,reg64 X64,PROT,ND )]417 code0
-[2(LAR reg64,mem X64,PROT,SW )]406 code0
-[2(LAR reg64,reg16 X64,PROT )]395 code0
-[2(LAR reg64,reg32 X64,PROT )]384 code0
-[2(LAR reg64,reg64 X64,PROT )]373 code0
-[2(LDS reg16,mem 8086,NOLONG )]362 code0
-[2(LDS reg32,mem 386,NOLONG )]351 code0
-[2(LEA reg16,mem 8086 )]340 code0
-[2(LEA reg32,mem 386 )]329 code0
-[2(LEA reg64,mem X64 )]318 code0
-[2(LEAVE 186 )]307 code0
-[2(LES reg16,mem 8086,NOLONG )]296 code0
-[2(LES reg32,mem 386,NOLONG )]285 code0
-[2(LFENCE X64,AMD )]274 code0
-[2(LFS reg16,mem 386 )]263 code0
-[2(LFS reg32,mem 386 )]252 code0
-[2(LGDT mem 286,PRIV )]241 code0
-[2(LGS reg16,mem 386 )]230 code0
-[2(LGS reg32,mem 386 )]219 code0
-[2(LIDT mem 286,PRIV )]208 code0
-[2(LLDT mem 286,PROT,PRIV )]197 code0
-[2(LLDT mem16 286,PROT,PRIV )]186 code0
-[2(LLDT reg16 286,PROT,PRIV )]175 code0
-[2(LMSW mem 286,PRIV )]164 code0
-[2(LMSW mem16 286,PRIV )]153 code0
-[2(LMSW reg16 286,PRIV )]142 code0
-[2(LOADALL 386,UNDOC )]131 code0
-[2(LOADALL286 286,UNDOC )]120 code0
-[2(LODSB 8086 )]109 code0
-(134)pageeven
-restore showpage
-%%Page: 135 135
-%%BeginPageSetup
-save
-%%EndPageSetup
-/135 pa
-[2(LODSD 386 )]681 code0
-[2(LODSQ X64 )]670 code0
-[2(LODSW 8086 )]659 code0
-[2(LOOP imm 8086 )]648 code0
-[2(LOOP imm,reg_cx 8086,NOLONG )]637 code0
-[2(LOOP imm,reg_ecx 386 )]626 code0
-[2(LOOP imm,reg_rcx X64 )]615 code0
-[2(LOOPE imm 8086 )]604 code0
-[2(LOOPE imm,reg_cx 8086,NOLONG )]593 code0
-[2(LOOPE imm,reg_ecx 386 )]582 code0
-[2(LOOPE imm,reg_rcx X64 )]571 code0
-[2(LOOPNE imm 8086 )]560 code0
-[2(LOOPNE imm,reg_cx 8086,NOLONG )]549 code0
-[2(LOOPNE imm,reg_ecx 386 )]538 code0
-[2(LOOPNE imm,reg_rcx X64 )]527 code0
-[2(LOOPNZ imm 8086 )]516 code0
-[2(LOOPNZ imm,reg_cx 8086,NOLONG )]505 code0
-[2(LOOPNZ imm,reg_ecx 386 )]494 code0
-[2(LOOPNZ imm,reg_rcx X64 )]483 code0
-[2(LOOPZ imm 8086 )]472 code0
-[2(LOOPZ imm,reg_cx 8086,NOLONG )]461 code0
-[2(LOOPZ imm,reg_ecx 386 )]450 code0
-[2(LOOPZ imm,reg_rcx X64 )]439 code0
-[2(LSL reg16,mem 286,PROT,SW )]428 code0
-[2(LSL reg16,reg16 286,PROT )]417 code0
-[2(LSL reg16,reg32 386,PROT )]406 code0
-[2(LSL reg16,reg64 X64,PROT,ND )]395 code0
-[2(LSL reg32,mem 386,PROT,SW )]384 code0
-[2(LSL reg32,reg16 386,PROT )]373 code0
-[2(LSL reg32,reg32 386,PROT )]362 code0
-[2(LSL reg32,reg64 X64,PROT,ND )]351 code0
-[2(LSL reg64,mem X64,PROT,SW )]340 code0
-[2(LSL reg64,reg16 X64,PROT )]329 code0
-[2(LSL reg64,reg32 X64,PROT )]318 code0
-[2(LSL reg64,reg64 X64,PROT )]307 code0
-[2(LSS reg16,mem 386 )]296 code0
-[2(LSS reg32,mem 386 )]285 code0
-[2(LTR mem 286,PROT,PRIV )]274 code0
-[2(LTR mem16 286,PROT,PRIV )]263 code0
-[2(LTR reg16 286,PROT,PRIV )]252 code0
-[2(MFENCE X64,AMD )]241 code0
-[2(MONITOR PRESCOTT )]230 code0
-[2(MONITOR reg_eax,reg_ecx,reg_edx PRESCOTT,ND )]219 code0
-[2(MONITOR reg_rax,reg_ecx,reg_edx X64,ND )]208 code0
-[2(MOV mem,reg_sreg 8086 )]197 code0
-[2(MOV reg16,reg_sreg 8086 )]186 code0
-[2(MOV reg32,reg_sreg 386 )]175 code0
-[2(MOV reg_sreg,mem 8086 )]164 code0
-[2(MOV reg_sreg,reg16 8086 )]153 code0
-[2(MOV reg_sreg,reg32 386 )]142 code0
-[2(MOV reg_al,mem_offs 8086 )]131 code0
-[2(MOV reg_ax,mem_offs 8086 )]120 code0
-[2(MOV reg_eax,mem_offs 386 )]109 code0
-(135)pageodd
-restore showpage
-%%Page: 136 136
-%%BeginPageSetup
-save
-%%EndPageSetup
-/136 pa
-[2(MOV reg_rax,mem_offs X64 )]681 code0
-[2(MOV mem_offs,reg_al 8086 )]670 code0
-[2(MOV mem_offs,reg_ax 8086 )]659 code0
-[2(MOV mem_offs,reg_eax 386 )]648 code0
-[2(MOV mem_offs,reg_rax X64 )]637 code0
-[2(MOV reg32,reg_creg 386,PRIV,NOLONG )]626 code0
-[2(MOV reg64,reg_creg X64,PRIV )]615 code0
-[2(MOV reg_creg,reg32 386,PRIV,NOLONG )]604 code0
-[2(MOV reg_creg,reg64 X64,PRIV )]593 code0
-[2(MOV reg32,reg_dreg 386,PRIV,NOLONG )]582 code0
-[2(MOV reg64,reg_dreg X64,PRIV )]571 code0
-[2(MOV reg_dreg,reg32 386,PRIV,NOLONG )]560 code0
-[2(MOV reg_dreg,reg64 X64,PRIV )]549 code0
-[2(MOV reg32,reg_treg 386,NOLONG,ND )]538 code0
-[2(MOV reg_treg,reg32 386,NOLONG,ND )]527 code0
-[2(MOV mem,reg8 8086 )]516 code0
-[2(MOV reg8,reg8 8086 )]505 code0
-[2(MOV mem,reg16 8086 )]494 code0
-[2(MOV reg16,reg16 8086 )]483 code0
-[2(MOV mem,reg32 386 )]472 code0
-[2(MOV reg32,reg32 386 )]461 code0
-[2(MOV mem,reg64 X64 )]450 code0
-[2(MOV reg64,reg64 X64 )]439 code0
-[2(MOV reg8,mem 8086 )]428 code0
-[2(MOV reg8,reg8 8086 )]417 code0
-[2(MOV reg16,mem 8086 )]406 code0
-[2(MOV reg16,reg16 8086 )]395 code0
-[2(MOV reg32,mem 386 )]384 code0
-[2(MOV reg32,reg32 386 )]373 code0
-[2(MOV reg64,mem X64 )]362 code0
-[2(MOV reg64,reg64 X64 )]351 code0
-[2(MOV reg8,imm 8086 )]340 code0
-[2(MOV reg16,imm 8086 )]329 code0
-[2(MOV reg32,imm 386 )]318 code0
-[2(MOV reg64,imm X64 )]307 code0
-[2(MOV reg64,imm32 X64 )]296 code0
-[2(MOV rm8,imm 8086 )]285 code0
-[2(MOV rm16,imm 8086 )]274 code0
-[2(MOV rm32,imm 386 )]263 code0
-[2(MOV rm64,imm X64 )]252 code0
-[2(MOV mem,imm8 8086 )]241 code0
-[2(MOV mem,imm16 8086 )]230 code0
-[2(MOV mem,imm32 386 )]219 code0
-[2(MOVD mmxreg,mem PENT,MMX,SD )]208 code0
-[2(MOVD mmxreg,reg32 PENT,MMX )]197 code0
-[2(MOVD mem,mmxreg PENT,MMX,SD )]186 code0
-[2(MOVD reg32,mmxreg PENT,MMX )]175 code0
-[2(MOVD xmmreg,mem X64,SD )]164 code0
-[2(MOVD xmmreg,reg32 X64 )]153 code0
-[2(MOVD mem,xmmreg X64,SD )]142 code0
-[2(MOVD reg32,xmmreg X64,SSE )]131 code0
-[2(MOVQ mmxreg,mmxrm PENT,MMX )]120 code0
-[2(MOVQ mmxrm,mmxreg PENT,MMX )]109 code0
-(136)pageeven
-restore showpage
-%%Page: 137 137
-%%BeginPageSetup
-save
-%%EndPageSetup
-/137 pa
-[2(MOVQ mmxreg,rm64 X64,MMX )]681 code0
-[2(MOVQ rm64,mmxreg X64,MMX )]670 code0
-[2(MOVSB 8086 )]659 code0
-[2(MOVSD 386 )]648 code0
-[2(MOVSQ X64 )]637 code0
-[2(MOVSW 8086 )]626 code0
-[2(MOVSX reg16,mem 386 )]615 code0
-[2(MOVSX reg16,reg8 386 )]604 code0
-[2(MOVSX reg32,rm8 386 )]593 code0
-[2(MOVSX reg32,rm16 386 )]582 code0
-[2(MOVSX reg64,rm8 X64 )]571 code0
-[2(MOVSX reg64,rm16 X64 )]560 code0
-[2(MOVSXD reg64,rm32 X64 )]549 code0
-[2(MOVSX reg64,rm32 X64,ND )]538 code0
-[2(MOVZX reg16,mem 386 )]527 code0
-[2(MOVZX reg16,reg8 386 )]516 code0
-[2(MOVZX reg32,rm8 386 )]505 code0
-[2(MOVZX reg32,rm16 386 )]494 code0
-[2(MOVZX reg64,rm8 X64 )]483 code0
-[2(MOVZX reg64,rm16 X64 )]472 code0
-[2(MUL rm8 8086 )]461 code0
-[2(MUL rm16 8086 )]450 code0
-[2(MUL rm32 386 )]439 code0
-[2(MUL rm64 X64 )]428 code0
-[2(MWAIT PRESCOTT )]417 code0
-[2(MWAIT reg_eax,reg_ecx PRESCOTT,ND )]406 code0
-[2(NEG rm8 8086 )]395 code0
-[2(NEG rm16 8086 )]384 code0
-[2(NEG rm32 386 )]373 code0
-[2(NEG rm64 X64 )]362 code0
-[2(NOP 8086 )]351 code0
-[2(NOP rm16 P6 )]340 code0
-[2(NOP rm32 P6 )]329 code0
-[2(NOP rm64 X64 )]318 code0
-[2(NOT rm8 8086 )]307 code0
-[2(NOT rm16 8086 )]296 code0
-[2(NOT rm32 386 )]285 code0
-[2(NOT rm64 X64 )]274 code0
-[2(OR mem,reg8 8086 )]263 code0
-[2(OR reg8,reg8 8086 )]252 code0
-[2(OR mem,reg16 8086 )]241 code0
-[2(OR reg16,reg16 8086 )]230 code0
-[2(OR mem,reg32 386 )]219 code0
-[2(OR reg32,reg32 386 )]208 code0
-[2(OR mem,reg64 X64 )]197 code0
-[2(OR reg64,reg64 X64 )]186 code0
-[2(OR reg8,mem 8086 )]175 code0
-[2(OR reg8,reg8 8086 )]164 code0
-[2(OR reg16,mem 8086 )]153 code0
-[2(OR reg16,reg16 8086 )]142 code0
-[2(OR reg32,mem 386 )]131 code0
-[2(OR reg32,reg32 386 )]120 code0
-[2(OR reg64,mem X64 )]109 code0
-(137)pageodd
-restore showpage
-%%Page: 138 138
-%%BeginPageSetup
-save
-%%EndPageSetup
-/138 pa
-[2(OR reg64,reg64 X64 )]681 code0
-[2(OR rm16,imm8 8086 )]670 code0
-[2(OR rm32,imm8 386 )]659 code0
-[2(OR rm64,imm8 X64 )]648 code0
-[2(OR reg_al,imm 8086 )]637 code0
-[2(OR reg_ax,sbyte16 8086 )]626 code0
-[2(OR reg_ax,imm 8086 )]615 code0
-[2(OR reg_eax,sbyte32 386 )]604 code0
-[2(OR reg_eax,imm 386 )]593 code0
-[2(OR reg_rax,sbyte64 X64 )]582 code0
-[2(OR reg_rax,imm X64 )]571 code0
-[2(OR rm8,imm 8086 )]560 code0
-[2(OR rm16,imm 8086 )]549 code0
-[2(OR rm32,imm 386 )]538 code0
-[2(OR rm64,imm X64 )]527 code0
-[2(OR mem,imm8 8086 )]516 code0
-[2(OR mem,imm16 8086 )]505 code0
-[2(OR mem,imm32 386 )]494 code0
-[2(OUT imm,reg_al 8086 )]483 code0
-[2(OUT imm,reg_ax 8086 )]472 code0
-[2(OUT imm,reg_eax 386 )]461 code0
-[2(OUT reg_dx,reg_al 8086 )]450 code0
-[2(OUT reg_dx,reg_ax 8086 )]439 code0
-[2(OUT reg_dx,reg_eax 386 )]428 code0
-[2(OUTSB 186 )]417 code0
-[2(OUTSD 386 )]406 code0
-[2(OUTSW 186 )]395 code0
-[2(PACKSSDW mmxreg,mmxrm PENT,MMX )]384 code0
-[2(PACKSSWB mmxreg,mmxrm PENT,MMX )]373 code0
-[2(PACKUSWB mmxreg,mmxrm PENT,MMX )]362 code0
-[2(PADDB mmxreg,mmxrm PENT,MMX )]351 code0
-[2(PADDD mmxreg,mmxrm PENT,MMX )]340 code0
-[2(PADDSB mmxreg,mmxrm PENT,MMX )]329 code0
-[2(PADDSIW mmxreg,mmxrm PENT,MMX,CYRIX )]318 code0
-[2(PADDSW mmxreg,mmxrm PENT,MMX )]307 code0
-[2(PADDUSB mmxreg,mmxrm PENT,MMX )]296 code0
-[2(PADDUSW mmxreg,mmxrm PENT,MMX )]285 code0
-[2(PADDW mmxreg,mmxrm PENT,MMX )]274 code0
-[2(PAND mmxreg,mmxrm PENT,MMX )]263 code0
-[2(PANDN mmxreg,mmxrm PENT,MMX )]252 code0
-[2(PAUSE 8086 )]241 code0
-[2(PAVEB mmxreg,mmxrm PENT,MMX,CYRIX )]230 code0
-[2(PAVGUSB mmxreg,mmxrm PENT,3DNOW )]219 code0
-[2(PCMPEQB mmxreg,mmxrm PENT,MMX )]208 code0
-[2(PCMPEQD mmxreg,mmxrm PENT,MMX )]197 code0
-[2(PCMPEQW mmxreg,mmxrm PENT,MMX )]186 code0
-[2(PCMPGTB mmxreg,mmxrm PENT,MMX )]175 code0
-[2(PCMPGTD mmxreg,mmxrm PENT,MMX )]164 code0
-[2(PCMPGTW mmxreg,mmxrm PENT,MMX )]153 code0
-[2(PDISTIB mmxreg,mem PENT,MMX,CYRIX )]142 code0
-[2(PF2ID mmxreg,mmxrm PENT,3DNOW )]131 code0
-[2(PFACC mmxreg,mmxrm PENT,3DNOW )]120 code0
-[2(PFADD mmxreg,mmxrm PENT,3DNOW )]109 code0
-(138)pageeven
-restore showpage
-%%Page: 139 139
-%%BeginPageSetup
-save
-%%EndPageSetup
-/139 pa
-[2(PFCMPEQ mmxreg,mmxrm PENT,3DNOW )]681 code0
-[2(PFCMPGE mmxreg,mmxrm PENT,3DNOW )]670 code0
-[2(PFCMPGT mmxreg,mmxrm PENT,3DNOW )]659 code0
-[2(PFMAX mmxreg,mmxrm PENT,3DNOW )]648 code0
-[2(PFMIN mmxreg,mmxrm PENT,3DNOW )]637 code0
-[2(PFMUL mmxreg,mmxrm PENT,3DNOW )]626 code0
-[2(PFRCP mmxreg,mmxrm PENT,3DNOW )]615 code0
-[2(PFRCPIT1 mmxreg,mmxrm PENT,3DNOW )]604 code0
-[2(PFRCPIT2 mmxreg,mmxrm PENT,3DNOW )]593 code0
-[2(PFRSQIT1 mmxreg,mmxrm PENT,3DNOW )]582 code0
-[2(PFRSQRT mmxreg,mmxrm PENT,3DNOW )]571 code0
-[2(PFSUB mmxreg,mmxrm PENT,3DNOW )]560 code0
-[2(PFSUBR mmxreg,mmxrm PENT,3DNOW )]549 code0
-[2(PI2FD mmxreg,mmxrm PENT,3DNOW )]538 code0
-[2(PMACHRIW mmxreg,mem PENT,MMX,CYRIX )]527 code0
-[2(PMADDWD mmxreg,mmxrm PENT,MMX )]516 code0
-[2(PMAGW mmxreg,mmxrm PENT,MMX,CYRIX )]505 code0
-[2(PMULHRIW mmxreg,mmxrm PENT,MMX,CYRIX )]494 code0
-[2(PMULHRWA mmxreg,mmxrm PENT,3DNOW )]483 code0
-[2(PMULHRWC mmxreg,mmxrm PENT,MMX,CYRIX )]472 code0
-[2(PMULHW mmxreg,mmxrm PENT,MMX )]461 code0
-[2(PMULLW mmxreg,mmxrm PENT,MMX )]450 code0
-[2(PMVGEZB mmxreg,mem PENT,MMX,CYRIX )]439 code0
-[2(PMVLZB mmxreg,mem PENT,MMX,CYRIX )]428 code0
-[2(PMVNZB mmxreg,mem PENT,MMX,CYRIX )]417 code0
-[2(PMVZB mmxreg,mem PENT,MMX,CYRIX )]406 code0
-[2(POP reg16 8086 )]395 code0
-[2(POP reg32 386,NOLONG )]384 code0
-[2(POP reg64 X64 )]373 code0
-[2(POP rm16 8086 )]362 code0
-[2(POP rm32 386,NOLONG )]351 code0
-[2(POP rm64 X64 )]340 code0
-[2(POP reg_cs 8086,UNDOC,ND )]329 code0
-[2(POP reg_dess 8086,NOLONG )]318 code0
-[2(POP reg_fsgs 386 )]307 code0
-[2(POPA 186,NOLONG )]296 code0
-[2(POPAD 386,NOLONG )]285 code0
-[2(POPAW 186,NOLONG )]274 code0
-[2(POPF 8086 )]263 code0
-[2(POPFD 386,NOLONG )]252 code0
-[2(POPFQ X64 )]241 code0
-[2(POPFW 8086 )]230 code0
-[2(POR mmxreg,mmxrm PENT,MMX )]219 code0
-[2(PREFETCH mem PENT,3DNOW )]208 code0
-[2(PREFETCHW mem PENT,3DNOW )]197 code0
-[2(PSLLD mmxreg,mmxrm PENT,MMX )]186 code0
-[2(PSLLD mmxreg,imm PENT,MMX )]175 code0
-[2(PSLLQ mmxreg,mmxrm PENT,MMX )]164 code0
-[2(PSLLQ mmxreg,imm PENT,MMX )]153 code0
-[2(PSLLW mmxreg,mmxrm PENT,MMX )]142 code0
-[2(PSLLW mmxreg,imm PENT,MMX )]131 code0
-[2(PSRAD mmxreg,mmxrm PENT,MMX )]120 code0
-[2(PSRAD mmxreg,imm PENT,MMX )]109 code0
-(139)pageodd
-restore showpage
-%%Page: 140 140
-%%BeginPageSetup
-save
-%%EndPageSetup
-/140 pa
-[2(PSRAW mmxreg,mmxrm PENT,MMX )]681 code0
-[2(PSRAW mmxreg,imm PENT,MMX )]670 code0
-[2(PSRLD mmxreg,mmxrm PENT,MMX )]659 code0
-[2(PSRLD mmxreg,imm PENT,MMX )]648 code0
-[2(PSRLQ mmxreg,mmxrm PENT,MMX )]637 code0
-[2(PSRLQ mmxreg,imm PENT,MMX )]626 code0
-[2(PSRLW mmxreg,mmxrm PENT,MMX )]615 code0
-[2(PSRLW mmxreg,imm PENT,MMX )]604 code0
-[2(PSUBB mmxreg,mmxrm PENT,MMX )]593 code0
-[2(PSUBD mmxreg,mmxrm PENT,MMX )]582 code0
-[2(PSUBSB mmxreg,mmxrm PENT,MMX )]571 code0
-[2(PSUBSIW mmxreg,mmxrm PENT,MMX,CYRIX )]560 code0
-[2(PSUBSW mmxreg,mmxrm PENT,MMX )]549 code0
-[2(PSUBUSB mmxreg,mmxrm PENT,MMX )]538 code0
-[2(PSUBUSW mmxreg,mmxrm PENT,MMX )]527 code0
-[2(PSUBW mmxreg,mmxrm PENT,MMX )]516 code0
-[2(PUNPCKHBW mmxreg,mmxrm PENT,MMX )]505 code0
-[2(PUNPCKHDQ mmxreg,mmxrm PENT,MMX )]494 code0
-[2(PUNPCKHWD mmxreg,mmxrm PENT,MMX )]483 code0
-[2(PUNPCKLBW mmxreg,mmxrm PENT,MMX )]472 code0
-[2(PUNPCKLDQ mmxreg,mmxrm PENT,MMX )]461 code0
-[2(PUNPCKLWD mmxreg,mmxrm PENT,MMX )]450 code0
-[2(PUSH reg16 8086 )]439 code0
-[2(PUSH reg32 386,NOLONG )]428 code0
-[2(PUSH reg64 X64 )]417 code0
-[2(PUSH rm16 8086 )]406 code0
-[2(PUSH rm32 386,NOLONG )]395 code0
-[2(PUSH rm64 X64 )]384 code0
-[2(PUSH reg_cs 8086,NOLONG )]373 code0
-[2(PUSH reg_dess 8086,NOLONG )]362 code0
-[2(PUSH reg_fsgs 386 )]351 code0
-[2(PUSH imm8 186 )]340 code0
-[2(PUSH imm16 186,AR0,SZ )]329 code0
-[2(PUSH imm32 386,NOLONG,AR0,SZ )]318 code0
-[2(PUSH imm32 386,NOLONG,SD )]307 code0
-[2(PUSH imm64 X64,AR0,SZ )]296 code0
-[2(PUSHA 186,NOLONG )]285 code0
-[2(PUSHAD 386,NOLONG )]274 code0
-[2(PUSHAW 186,NOLONG )]263 code0
-[2(PUSHF 8086 )]252 code0
-[2(PUSHFD 386,NOLONG )]241 code0
-[2(PUSHFQ X64 )]230 code0
-[2(PUSHFW 8086 )]219 code0
-[2(PXOR mmxreg,mmxrm PENT,MMX )]208 code0
-[2(RCL rm8,unity 8086 )]197 code0
-[2(RCL rm8,reg_cl 8086 )]186 code0
-[2(RCL rm8,imm 186 )]175 code0
-[2(RCL rm16,unity 8086 )]164 code0
-[2(RCL rm16,reg_cl 8086 )]153 code0
-[2(RCL rm16,imm 186 )]142 code0
-[2(RCL rm32,unity 386 )]131 code0
-[2(RCL rm32,reg_cl 386 )]120 code0
-[2(RCL rm32,imm 386 )]109 code0
-(140)pageeven
-restore showpage
-%%Page: 141 141
-%%BeginPageSetup
-save
-%%EndPageSetup
-/141 pa
-[2(RCL rm64,unity X64 )]681 code0
-[2(RCL rm64,reg_cl X64 )]670 code0
-[2(RCL rm64,imm X64 )]659 code0
-[2(RCR rm8,unity 8086 )]648 code0
-[2(RCR rm8,reg_cl 8086 )]637 code0
-[2(RCR rm8,imm 186 )]626 code0
-[2(RCR rm16,unity 8086 )]615 code0
-[2(RCR rm16,reg_cl 8086 )]604 code0
-[2(RCR rm16,imm 186 )]593 code0
-[2(RCR rm32,unity 386 )]582 code0
-[2(RCR rm32,reg_cl 386 )]571 code0
-[2(RCR rm32,imm 386 )]560 code0
-[2(RCR rm64,unity X64 )]549 code0
-[2(RCR rm64,reg_cl X64 )]538 code0
-[2(RCR rm64,imm X64 )]527 code0
-[2(RDSHR rm32 P6,CYRIXM )]516 code0
-[2(RDMSR PENT,PRIV )]505 code0
-[2(RDPMC P6 )]494 code0
-[2(RDTSC PENT )]483 code0
-[2(RDTSCP X86_64 )]472 code0
-[2(RET 8086 )]461 code0
-[2(RET imm 8086,SW )]450 code0
-[2(RETF 8086 )]439 code0
-[2(RETF imm 8086,SW )]428 code0
-[2(RETN 8086 )]417 code0
-[2(RETN imm 8086,SW )]406 code0
-[2(ROL rm8,unity 8086 )]395 code0
-[2(ROL rm8,reg_cl 8086 )]384 code0
-[2(ROL rm8,imm 186 )]373 code0
-[2(ROL rm16,unity 8086 )]362 code0
-[2(ROL rm16,reg_cl 8086 )]351 code0
-[2(ROL rm16,imm 186 )]340 code0
-[2(ROL rm32,unity 386 )]329 code0
-[2(ROL rm32,reg_cl 386 )]318 code0
-[2(ROL rm32,imm 386 )]307 code0
-[2(ROL rm64,unity X64 )]296 code0
-[2(ROL rm64,reg_cl X64 )]285 code0
-[2(ROL rm64,imm X64 )]274 code0
-[2(ROR rm8,unity 8086 )]263 code0
-[2(ROR rm8,reg_cl 8086 )]252 code0
-[2(ROR rm8,imm 186 )]241 code0
-[2(ROR rm16,unity 8086 )]230 code0
-[2(ROR rm16,reg_cl 8086 )]219 code0
-[2(ROR rm16,imm 186 )]208 code0
-[2(ROR rm32,unity 386 )]197 code0
-[2(ROR rm32,reg_cl 386 )]186 code0
-[2(ROR rm32,imm 386 )]175 code0
-[2(ROR rm64,unity X64 )]164 code0
-[2(ROR rm64,reg_cl X64 )]153 code0
-[2(ROR rm64,imm X64 )]142 code0
-[2(RDM P6,CYRIX,ND )]131 code0
-[2(RSDC reg_sreg,mem80 486,CYRIXM )]120 code0
-[2(RSLDT mem80 486,CYRIXM )]109 code0
-(141)pageodd
-restore showpage
-%%Page: 142 142
-%%BeginPageSetup
-save
-%%EndPageSetup
-/142 pa
-[2(RSM PENTM )]681 code0
-[2(RSTS mem80 486,CYRIXM )]670 code0
-[2(SAHF 8086 )]659 code0
-[2(SAL rm8,unity 8086,ND )]648 code0
-[2(SAL rm8,reg_cl 8086,ND )]637 code0
-[2(SAL rm8,imm 186,ND )]626 code0
-[2(SAL rm16,unity 8086,ND )]615 code0
-[2(SAL rm16,reg_cl 8086,ND )]604 code0
-[2(SAL rm16,imm 186,ND )]593 code0
-[2(SAL rm32,unity 386,ND )]582 code0
-[2(SAL rm32,reg_cl 386,ND )]571 code0
-[2(SAL rm32,imm 386,ND )]560 code0
-[2(SAL rm64,unity X64,ND )]549 code0
-[2(SAL rm64,reg_cl X64,ND )]538 code0
-[2(SAL rm64,imm X64,ND )]527 code0
-[2(SALC 8086,UNDOC )]516 code0
-[2(SAR rm8,unity 8086 )]505 code0
-[2(SAR rm8,reg_cl 8086 )]494 code0
-[2(SAR rm8,imm 186 )]483 code0
-[2(SAR rm16,unity 8086 )]472 code0
-[2(SAR rm16,reg_cl 8086 )]461 code0
-[2(SAR rm16,imm 186 )]450 code0
-[2(SAR rm32,unity 386 )]439 code0
-[2(SAR rm32,reg_cl 386 )]428 code0
-[2(SAR rm32,imm 386 )]417 code0
-[2(SAR rm64,unity X64 )]406 code0
-[2(SAR rm64,reg_cl X64 )]395 code0
-[2(SAR rm64,imm X64 )]384 code0
-[2(SBB mem,reg8 8086 )]373 code0
-[2(SBB reg8,reg8 8086 )]362 code0
-[2(SBB mem,reg16 8086 )]351 code0
-[2(SBB reg16,reg16 8086 )]340 code0
-[2(SBB mem,reg32 386 )]329 code0
-[2(SBB reg32,reg32 386 )]318 code0
-[2(SBB mem,reg64 X64 )]307 code0
-[2(SBB reg64,reg64 X64 )]296 code0
-[2(SBB reg8,mem 8086 )]285 code0
-[2(SBB reg8,reg8 8086 )]274 code0
-[2(SBB reg16,mem 8086 )]263 code0
-[2(SBB reg16,reg16 8086 )]252 code0
-[2(SBB reg32,mem 386 )]241 code0
-[2(SBB reg32,reg32 386 )]230 code0
-[2(SBB reg64,mem X64 )]219 code0
-[2(SBB reg64,reg64 X64 )]208 code0
-[2(SBB rm16,imm8 8086 )]197 code0
-[2(SBB rm32,imm8 386 )]186 code0
-[2(SBB rm64,imm8 X64 )]175 code0
-[2(SBB reg_al,imm 8086 )]164 code0
-[2(SBB reg_ax,sbyte16 8086 )]153 code0
-[2(SBB reg_ax,imm 8086 )]142 code0
-[2(SBB reg_eax,sbyte32 386 )]131 code0
-[2(SBB reg_eax,imm 386 )]120 code0
-[2(SBB reg_rax,sbyte64 X64 )]109 code0
-(142)pageeven
-restore showpage
-%%Page: 143 143
-%%BeginPageSetup
-save
-%%EndPageSetup
-/143 pa
-[2(SBB reg_rax,imm X64 )]681 code0
-[2(SBB rm8,imm 8086 )]670 code0
-[2(SBB rm16,imm 8086 )]659 code0
-[2(SBB rm32,imm 386 )]648 code0
-[2(SBB rm64,imm X64 )]637 code0
-[2(SBB mem,imm8 8086 )]626 code0
-[2(SBB mem,imm16 8086 )]615 code0
-[2(SBB mem,imm32 386 )]604 code0
-[2(SCASB 8086 )]593 code0
-[2(SCASD 386 )]582 code0
-[2(SCASQ X64 )]571 code0
-[2(SCASW 8086 )]560 code0
-[2(SFENCE X64,AMD )]549 code0
-[2(SGDT mem 286 )]538 code0
-[2(SHL rm8,unity 8086 )]527 code0
-[2(SHL rm8,reg_cl 8086 )]516 code0
-[2(SHL rm8,imm 186 )]505 code0
-[2(SHL rm16,unity 8086 )]494 code0
-[2(SHL rm16,reg_cl 8086 )]483 code0
-[2(SHL rm16,imm 186 )]472 code0
-[2(SHL rm32,unity 386 )]461 code0
-[2(SHL rm32,reg_cl 386 )]450 code0
-[2(SHL rm32,imm 386 )]439 code0
-[2(SHL rm64,unity X64 )]428 code0
-[2(SHL rm64,reg_cl X64 )]417 code0
-[2(SHL rm64,imm X64 )]406 code0
-[2(SHLD mem,reg16,imm 3862 )]395 code0
-[2(SHLD reg16,reg16,imm 3862 )]384 code0
-[2(SHLD mem,reg32,imm 3862 )]373 code0
-[2(SHLD reg32,reg32,imm 3862 )]362 code0
-[2(SHLD mem,reg64,imm X642 )]351 code0
-[2(SHLD reg64,reg64,imm X642 )]340 code0
-[2(SHLD mem,reg16,reg_cl 386 )]329 code0
-[2(SHLD reg16,reg16,reg_cl 386 )]318 code0
-[2(SHLD mem,reg32,reg_cl 386 )]307 code0
-[2(SHLD reg32,reg32,reg_cl 386 )]296 code0
-[2(SHLD mem,reg64,reg_cl X64 )]285 code0
-[2(SHLD reg64,reg64,reg_cl X64 )]274 code0
-[2(SHR rm8,unity 8086 )]263 code0
-[2(SHR rm8,reg_cl 8086 )]252 code0
-[2(SHR rm8,imm 186 )]241 code0
-[2(SHR rm16,unity 8086 )]230 code0
-[2(SHR rm16,reg_cl 8086 )]219 code0
-[2(SHR rm16,imm 186 )]208 code0
-[2(SHR rm32,unity 386 )]197 code0
-[2(SHR rm32,reg_cl 386 )]186 code0
-[2(SHR rm32,imm 386 )]175 code0
-[2(SHR rm64,unity X64 )]164 code0
-[2(SHR rm64,reg_cl X64 )]153 code0
-[2(SHR rm64,imm X64 )]142 code0
-[2(SHRD mem,reg16,imm 3862 )]131 code0
-[2(SHRD reg16,reg16,imm 3862 )]120 code0
-[2(SHRD mem,reg32,imm 3862 )]109 code0
-(143)pageodd
-restore showpage
-%%Page: 144 144
-%%BeginPageSetup
-save
-%%EndPageSetup
-/144 pa
-[2(SHRD reg32,reg32,imm 3862 )]681 code0
-[2(SHRD mem,reg64,imm X642 )]670 code0
-[2(SHRD reg64,reg64,imm X642 )]659 code0
-[2(SHRD mem,reg16,reg_cl 386 )]648 code0
-[2(SHRD reg16,reg16,reg_cl 386 )]637 code0
-[2(SHRD mem,reg32,reg_cl 386 )]626 code0
-[2(SHRD reg32,reg32,reg_cl 386 )]615 code0
-[2(SHRD mem,reg64,reg_cl X64 )]604 code0
-[2(SHRD reg64,reg64,reg_cl X64 )]593 code0
-[2(SIDT mem 286 )]582 code0
-[2(SLDT mem 286 )]571 code0
-[2(SLDT mem16 286 )]560 code0
-[2(SLDT reg16 286 )]549 code0
-[2(SLDT reg32 386 )]538 code0
-[2(SLDT reg64 X64,ND )]527 code0
-[2(SLDT reg64 X64 )]516 code0
-[2(SKINIT X64 )]505 code0
-[2(SMI 386,UNDOC )]494 code0
-[2(SMINT P6,CYRIX,ND )]483 code0
-[2(SMINTOLD 486,CYRIX,ND )]472 code0
-[2(SMSW mem 286 )]461 code0
-[2(SMSW mem16 286 )]450 code0
-[2(SMSW reg16 286 )]439 code0
-[2(SMSW reg32 386 )]428 code0
-[2(STC 8086 )]417 code0
-[2(STD 8086 )]406 code0
-[2(STGI X64 )]395 code0
-[2(STI 8086 )]384 code0
-[2(STOSB 8086 )]373 code0
-[2(STOSD 386 )]362 code0
-[2(STOSQ X64 )]351 code0
-[2(STOSW 8086 )]340 code0
-[2(STR mem 286,PROT )]329 code0
-[2(STR mem16 286,PROT )]318 code0
-[2(STR reg16 286,PROT )]307 code0
-[2(STR reg32 386,PROT )]296 code0
-[2(STR reg64 X64 )]285 code0
-[2(SUB mem,reg8 8086 )]274 code0
-[2(SUB reg8,reg8 8086 )]263 code0
-[2(SUB mem,reg16 8086 )]252 code0
-[2(SUB reg16,reg16 8086 )]241 code0
-[2(SUB mem,reg32 386 )]230 code0
-[2(SUB reg32,reg32 386 )]219 code0
-[2(SUB mem,reg64 X64 )]208 code0
-[2(SUB reg64,reg64 X64 )]197 code0
-[2(SUB reg8,mem 8086 )]186 code0
-[2(SUB reg8,reg8 8086 )]175 code0
-[2(SUB reg16,mem 8086 )]164 code0
-[2(SUB reg16,reg16 8086 )]153 code0
-[2(SUB reg32,mem 386 )]142 code0
-[2(SUB reg32,reg32 386 )]131 code0
-[2(SUB reg64,mem X64 )]120 code0
-[2(SUB reg64,reg64 X64 )]109 code0
-(144)pageeven
-restore showpage
-%%Page: 145 145
-%%BeginPageSetup
-save
-%%EndPageSetup
-/145 pa
-[2(SUB rm16,imm8 8086 )]681 code0
-[2(SUB rm32,imm8 386 )]670 code0
-[2(SUB rm64,imm8 X64 )]659 code0
-[2(SUB reg_al,imm 8086 )]648 code0
-[2(SUB reg_ax,sbyte16 8086 )]637 code0
-[2(SUB reg_ax,imm 8086 )]626 code0
-[2(SUB reg_eax,sbyte32 386 )]615 code0
-[2(SUB reg_eax,imm 386 )]604 code0
-[2(SUB reg_rax,sbyte64 X64 )]593 code0
-[2(SUB reg_rax,imm X64 )]582 code0
-[2(SUB rm8,imm 8086 )]571 code0
-[2(SUB rm16,imm 8086 )]560 code0
-[2(SUB rm32,imm 386 )]549 code0
-[2(SUB rm64,imm X64 )]538 code0
-[2(SUB mem,imm8 8086 )]527 code0
-[2(SUB mem,imm16 8086 )]516 code0
-[2(SUB mem,imm32 386 )]505 code0
-[2(SVDC mem80,reg_sreg 486,CYRIXM )]494 code0
-[2(SVLDT mem80 486,CYRIXM,ND )]483 code0
-[2(SVTS mem80 486,CYRIXM )]472 code0
-[2(SWAPGS X64 )]461 code0
-[2(SYSCALL P6,AMD )]450 code0
-[2(SYSENTER P6 )]439 code0
-[2(SYSEXIT P6,PRIV )]428 code0
-[2(SYSRET P6,PRIV,AMD )]417 code0
-[2(TEST mem,reg8 8086 )]406 code0
-[2(TEST reg8,reg8 8086 )]395 code0
-[2(TEST mem,reg16 8086 )]384 code0
-[2(TEST reg16,reg16 8086 )]373 code0
-[2(TEST mem,reg32 386 )]362 code0
-[2(TEST reg32,reg32 386 )]351 code0
-[2(TEST mem,reg64 X64 )]340 code0
-[2(TEST reg64,reg64 X64 )]329 code0
-[2(TEST reg8,mem 8086 )]318 code0
-[2(TEST reg16,mem 8086 )]307 code0
-[2(TEST reg32,mem 386 )]296 code0
-[2(TEST reg64,mem X64 )]285 code0
-[2(TEST reg_al,imm 8086 )]274 code0
-[2(TEST reg_ax,imm 8086 )]263 code0
-[2(TEST reg_eax,imm 386 )]252 code0
-[2(TEST reg_rax,imm X64 )]241 code0
-[2(TEST rm8,imm 8086 )]230 code0
-[2(TEST rm16,imm 8086 )]219 code0
-[2(TEST rm32,imm 386 )]208 code0
-[2(TEST rm64,imm X64 )]197 code0
-[2(TEST mem,imm8 8086 )]186 code0
-[2(TEST mem,imm16 8086 )]175 code0
-[2(TEST mem,imm32 386 )]164 code0
-[2(UD0 186,UNDOC )]153 code0
-[2(UD1 186,UNDOC )]142 code0
-[2(UD2B 186,UNDOC,ND )]131 code0
-[2(UD2 186 )]120 code0
-[2(UD2A 186,ND )]109 code0
-(145)pageodd
-restore showpage
-%%Page: 146 146
-%%BeginPageSetup
-save
-%%EndPageSetup
-/146 pa
-[2(UMOV mem,reg8 386,UNDOC,ND )]681 code0
-[2(UMOV reg8,reg8 386,UNDOC,ND )]670 code0
-[2(UMOV mem,reg16 386,UNDOC,ND )]659 code0
-[2(UMOV reg16,reg16 386,UNDOC,ND )]648 code0
-[2(UMOV mem,reg32 386,UNDOC,ND )]637 code0
-[2(UMOV reg32,reg32 386,UNDOC,ND )]626 code0
-[2(UMOV reg8,mem 386,UNDOC,ND )]615 code0
-[2(UMOV reg8,reg8 386,UNDOC,ND )]604 code0
-[2(UMOV reg16,mem 386,UNDOC,ND )]593 code0
-[2(UMOV reg16,reg16 386,UNDOC,ND )]582 code0
-[2(UMOV reg32,mem 386,UNDOC,ND )]571 code0
-[2(UMOV reg32,reg32 386,UNDOC,ND )]560 code0
-[2(VERR mem 286,PROT )]549 code0
-[2(VERR mem16 286,PROT )]538 code0
-[2(VERR reg16 286,PROT )]527 code0
-[2(VERW mem 286,PROT )]516 code0
-[2(VERW mem16 286,PROT )]505 code0
-[2(VERW reg16 286,PROT )]494 code0
-[2(FWAIT 8086 )]483 code0
-[2(WBINVD 486,PRIV )]472 code0
-[2(WRSHR rm32 P6,CYRIXM )]461 code0
-[2(WRMSR PENT,PRIV )]450 code0
-[2(XADD mem,reg8 486 )]439 code0
-[2(XADD reg8,reg8 486 )]428 code0
-[2(XADD mem,reg16 486 )]417 code0
-[2(XADD reg16,reg16 486 )]406 code0
-[2(XADD mem,reg32 486 )]395 code0
-[2(XADD reg32,reg32 486 )]384 code0
-[2(XADD mem,reg64 X64 )]373 code0
-[2(XADD reg64,reg64 X64 )]362 code0
-[2(XBTS reg16,mem 386,SW,UNDOC,ND )]351 code0
-[2(XBTS reg16,reg16 386,UNDOC,ND )]340 code0
-[2(XBTS reg32,mem 386,SD,UNDOC,ND )]329 code0
-[2(XBTS reg32,reg32 386,UNDOC,ND )]318 code0
-[2(XCHG reg_ax,reg16 8086 )]307 code0
-[2(XCHG reg_eax,reg32na 386 )]296 code0
-[2(XCHG reg_rax,reg64 X64 )]285 code0
-[2(XCHG reg16,reg_ax 8086 )]274 code0
-[2(XCHG reg32na,reg_eax 386 )]263 code0
-[2(XCHG reg64,reg_rax X64 )]252 code0
-[2(XCHG reg_eax,reg_eax 386,NOLONG )]241 code0
-[2(XCHG reg8,mem 8086 )]230 code0
-[2(XCHG reg8,reg8 8086 )]219 code0
-[2(XCHG reg16,mem 8086 )]208 code0
-[2(XCHG reg16,reg16 8086 )]197 code0
-[2(XCHG reg32,mem 386 )]186 code0
-[2(XCHG reg32,reg32 386 )]175 code0
-[2(XCHG reg64,mem X64 )]164 code0
-[2(XCHG reg64,reg64 X64 )]153 code0
-[2(XCHG mem,reg8 8086 )]142 code0
-[2(XCHG reg8,reg8 8086 )]131 code0
-[2(XCHG mem,reg16 8086 )]120 code0
-[2(XCHG reg16,reg16 8086 )]109 code0
-(146)pageeven
-restore showpage
-%%Page: 147 147
-%%BeginPageSetup
-save
-%%EndPageSetup
-/147 pa
-[2(XCHG mem,reg32 386 )]681 code0
-[2(XCHG reg32,reg32 386 )]670 code0
-[2(XCHG mem,reg64 X64 )]659 code0
-[2(XCHG reg64,reg64 X64 )]648 code0
-[2(XLATB 8086 )]637 code0
-[2(XLAT 8086 )]626 code0
-[2(XOR mem,reg8 8086 )]615 code0
-[2(XOR reg8,reg8 8086 )]604 code0
-[2(XOR mem,reg16 8086 )]593 code0
-[2(XOR reg16,reg16 8086 )]582 code0
-[2(XOR mem,reg32 386 )]571 code0
-[2(XOR reg32,reg32 386 )]560 code0
-[2(XOR mem,reg64 X64 )]549 code0
-[2(XOR reg64,reg64 X64 )]538 code0
-[2(XOR reg8,mem 8086 )]527 code0
-[2(XOR reg8,reg8 8086 )]516 code0
-[2(XOR reg16,mem 8086 )]505 code0
-[2(XOR reg16,reg16 8086 )]494 code0
-[2(XOR reg32,mem 386 )]483 code0
-[2(XOR reg32,reg32 386 )]472 code0
-[2(XOR reg64,mem X64 )]461 code0
-[2(XOR reg64,reg64 X64 )]450 code0
-[2(XOR rm16,imm8 8086 )]439 code0
-[2(XOR rm32,imm8 386 )]428 code0
-[2(XOR rm64,imm8 X64 )]417 code0
-[2(XOR reg_al,imm 8086 )]406 code0
-[2(XOR reg_ax,sbyte16 8086 )]395 code0
-[2(XOR reg_ax,imm 8086 )]384 code0
-[2(XOR reg_eax,sbyte32 386 )]373 code0
-[2(XOR reg_eax,imm 386 )]362 code0
-[2(XOR reg_rax,sbyte64 X64 )]351 code0
-[2(XOR reg_rax,imm X64 )]340 code0
-[2(XOR rm8,imm 8086 )]329 code0
-[2(XOR rm16,imm 8086 )]318 code0
-[2(XOR rm32,imm 386 )]307 code0
-[2(XOR rm64,imm X64 )]296 code0
-[2(XOR mem,imm8 8086 )]285 code0
-[2(XOR mem,imm16 8086 )]274 code0
-[2(XOR mem,imm32 386 )]263 code0
-[2(CMOVcc reg16,mem P6 )]252 code0
-[2(CMOVcc reg16,reg16 P6 )]241 code0
-[2(CMOVcc reg32,mem P6 )]230 code0
-[2(CMOVcc reg32,reg32 P6 )]219 code0
-[2(CMOVcc reg64,mem X64 )]208 code0
-[2(CMOVcc reg64,reg64 X64 )]197 code0
-[2(Jcc imm|near 386 )]186 code0
-[2(Jcc imm16|near 386 )]175 code0
-[2(Jcc imm32|near 386 )]164 code0
-[2(Jcc imm|short 8086,ND )]153 code0
-[2(Jcc imm 8086,ND )]142 code0
-[2(Jcc imm 386,ND )]131 code0
-[2(Jcc imm 8086,ND )]120 code0
-[2(Jcc imm 8086 )]109 code0
-(147)pageodd
-restore showpage
-%%Page: 148 148
-%%BeginPageSetup
-save
-%%EndPageSetup
-/148 pa
-[2(SETcc mem 386 )]681 code0
-[2(SETcc reg8 386)]670 code2
-[{/section-B.1.3 xa}(Katmai Streaming SIMD instructions \(SSE \226\226 a.k.a. KNI, XMM, MMX2\))](B.1.3)650.8 subh3
-[2(ADDPS xmmreg,xmmrm KATMAI,SSE )]633.8 code1
-[2(ADDSS xmmreg,xmmrm KATMAI,SSE,SD )]622.8 code0
-[2(ANDNPS xmmreg,xmmrm KATMAI,SSE )]611.8 code0
-[2(ANDPS xmmreg,xmmrm KATMAI,SSE )]600.8 code0
-[2(CMPEQPS xmmreg,xmmrm KATMAI,SSE )]589.8 code0
-[2(CMPEQSS xmmreg,xmmrm KATMAI,SSE )]578.8 code0
-[2(CMPLEPS xmmreg,xmmrm KATMAI,SSE )]567.8 code0
-[2(CMPLESS xmmreg,xmmrm KATMAI,SSE )]556.8 code0
-[2(CMPLTPS xmmreg,xmmrm KATMAI,SSE )]545.8 code0
-[2(CMPLTSS xmmreg,xmmrm KATMAI,SSE )]534.8 code0
-[2(CMPNEQPS xmmreg,xmmrm KATMAI,SSE )]523.8 code0
-[2(CMPNEQSS xmmreg,xmmrm KATMAI,SSE )]512.8 code0
-[2(CMPNLEPS xmmreg,xmmrm KATMAI,SSE )]501.8 code0
-[2(CMPNLESS xmmreg,xmmrm KATMAI,SSE )]490.8 code0
-[2(CMPNLTPS xmmreg,xmmrm KATMAI,SSE )]479.8 code0
-[2(CMPNLTSS xmmreg,xmmrm KATMAI,SSE )]468.8 code0
-[2(CMPORDPS xmmreg,xmmrm KATMAI,SSE )]457.8 code0
-[2(CMPORDSS xmmreg,xmmrm KATMAI,SSE )]446.8 code0
-[2(CMPUNORDPS xmmreg,xmmrm KATMAI,SSE )]435.8 code0
-[2(CMPUNORDSS xmmreg,xmmrm KATMAI,SSE )]424.8 code0
-[2(CMPPS xmmreg,mem,imm KATMAI,SSE )]413.8 code0
-[2(CMPPS xmmreg,xmmreg,imm KATMAI,SSE )]402.8 code0
-[2(CMPSS xmmreg,mem,imm KATMAI,SSE )]391.8 code0
-[2(CMPSS xmmreg,xmmreg,imm KATMAI,SSE )]380.8 code0
-[2(COMISS xmmreg,xmmrm KATMAI,SSE )]369.8 code0
-[2(CVTPI2PS xmmreg,mmxrm KATMAI,SSE,MMX )]358.8 code0
-[2(CVTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX )]347.8 code0
-[2(CVTSI2SS xmmreg,mem KATMAI,SSE,SD,AR1,ND )]336.8 code0
-[2(CVTSI2SS xmmreg,rm32 KATMAI,SSE,SD,AR1 )]325.8 code0
-[2(CVTSI2SS xmmreg,rm64 X64,SSE,AR1 )]314.8 code0
-[2(CVTSS2SI reg32,xmmreg KATMAI,SSE,SD,AR1 )]303.8 code0
-[2(CVTSS2SI reg32,mem KATMAI,SSE,SD,AR1 )]292.8 code0
-[2(CVTSS2SI reg64,xmmreg X64,SSE,SD,AR1 )]281.8 code0
-[2(CVTSS2SI reg64,mem X64,SSE,SD,AR1 )]270.8 code0
-[2(CVTTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX )]259.8 code0
-[2(CVTTSS2SI reg32,xmmrm KATMAI,SSE,SD,AR1 )]248.8 code0
-[2(CVTTSS2SI reg64,xmmrm X64,SSE,SD,AR1 )]237.8 code0
-[2(DIVPS xmmreg,xmmrm KATMAI,SSE )]226.8 code0
-[2(DIVSS xmmreg,xmmrm KATMAI,SSE )]215.8 code0
-[2(LDMXCSR mem KATMAI,SSE,SD )]204.8 code0
-[2(MAXPS xmmreg,xmmrm KATMAI,SSE )]193.8 code0
-[2(MAXSS xmmreg,xmmrm KATMAI,SSE )]182.8 code0
-[2(MINPS xmmreg,xmmrm KATMAI,SSE )]171.8 code0
-[2(MINSS xmmreg,xmmrm KATMAI,SSE )]160.8 code0
-[2(MOVAPS xmmreg,mem KATMAI,SSE )]149.8 code0
-[2(MOVAPS mem,xmmreg KATMAI,SSE )]138.8 code0
-[2(MOVAPS xmmreg,xmmreg KATMAI,SSE )]127.8 code0
-[2(MOVAPS xmmreg,xmmreg KATMAI,SSE )]116.8 code0
-[2(MOVHPS xmmreg,mem KATMAI,SSE )]105.8 code0
-(148)pageeven
-restore showpage
-%%Page: 149 149
-%%BeginPageSetup
-save
-%%EndPageSetup
-/149 pa
-[2(MOVHPS mem,xmmreg KATMAI,SSE )]681 code0
-[2(MOVLHPS xmmreg,xmmreg KATMAI,SSE )]670 code0
-[2(MOVLPS xmmreg,mem KATMAI,SSE )]659 code0
-[2(MOVLPS mem,xmmreg KATMAI,SSE )]648 code0
-[2(MOVHLPS xmmreg,xmmreg KATMAI,SSE )]637 code0
-[2(MOVMSKPS reg32,xmmreg KATMAI,SSE )]626 code0
-[2(MOVMSKPS reg64,xmmreg X64,SSE )]615 code0
-[2(MOVNTPS mem,xmmreg KATMAI,SSE )]604 code0
-[2(MOVSS xmmreg,mem KATMAI,SSE )]593 code0
-[2(MOVSS mem,xmmreg KATMAI,SSE )]582 code0
-[2(MOVSS xmmreg,xmmreg KATMAI,SSE )]571 code0
-[2(MOVSS xmmreg,xmmreg KATMAI,SSE )]560 code0
-[2(MOVUPS xmmreg,mem KATMAI,SSE )]549 code0
-[2(MOVUPS mem,xmmreg KATMAI,SSE )]538 code0
-[2(MOVUPS xmmreg,xmmreg KATMAI,SSE )]527 code0
-[2(MOVUPS xmmreg,xmmreg KATMAI,SSE )]516 code0
-[2(MULPS xmmreg,xmmrm KATMAI,SSE )]505 code0
-[2(MULSS xmmreg,xmmrm KATMAI,SSE )]494 code0
-[2(ORPS xmmreg,xmmrm KATMAI,SSE )]483 code0
-[2(RCPPS xmmreg,xmmrm KATMAI,SSE )]472 code0
-[2(RCPSS xmmreg,xmmrm KATMAI,SSE )]461 code0
-[2(RSQRTPS xmmreg,xmmrm KATMAI,SSE )]450 code0
-[2(RSQRTSS xmmreg,xmmrm KATMAI,SSE )]439 code0
-[2(SHUFPS xmmreg,mem,imm KATMAI,SSE )]428 code0
-[2(SHUFPS xmmreg,xmmreg,imm KATMAI,SSE )]417 code0
-[2(SQRTPS xmmreg,xmmrm KATMAI,SSE )]406 code0
-[2(SQRTSS xmmreg,xmmrm KATMAI,SSE )]395 code0
-[2(STMXCSR mem KATMAI,SSE,SD )]384 code0
-[2(SUBPS xmmreg,xmmrm KATMAI,SSE )]373 code0
-[2(SUBSS xmmreg,xmmrm KATMAI,SSE )]362 code0
-[2(UCOMISS xmmreg,xmmrm KATMAI,SSE )]351 code0
-[2(UNPCKHPS xmmreg,xmmrm KATMAI,SSE )]340 code0
-[2(UNPCKLPS xmmreg,xmmrm KATMAI,SSE )]329 code0
-[2(XORPS xmmreg,xmmrm KATMAI,SSE)]318 code2
-[{/section-B.1.4 xa}(Introduced in Deschutes but necessary for SSE support)](B.1.4)298.8 subh3
-[2(FXRSTOR mem P6,SSE,FPU )]281.8 code1
-[2(FXSAVE mem P6,SSE,FPU)]270.8 code2
-[{/section-B.1.5 xa}(XSAVE group \(AVX and extended state\))](B.1.5)251.6 subh3
-[2(XGETBV NEHALEM )]234.6 code1
-[2(XSETBV NEHALEM,PRIV )]223.6 code0
-[2(XSAVE mem NEHALEM )]212.6 code0
-[2(XRSTOR mem NEHALEM)]201.6 code2
-[{/section-B.1.6 xa}(Generic memory operations)](B.1.6)182.4 subh3
-[2(PREFETCHNTA mem KATMAI )]165.4 code1
-[2(PREFETCHT0 mem KATMAI )]154.4 code0
-[2(PREFETCHT1 mem KATMAI )]143.4 code0
-[2(PREFETCHT2 mem KATMAI )]132.4 code0
-[2(SFENCE KATMAI)]121.4 code2
-(149)pageodd
-restore showpage
-%%Page: 150 150
-%%BeginPageSetup
-save
-%%EndPageSetup
-/150 pa
-[{/section-B.1.7 xa}(New MMX instructions introduced in Katmai)](B.1.7)678.8 subh3
-[2(MASKMOVQ mmxreg,mmxreg KATMAI,MMX )]661.8 code1
-[2(MOVNTQ mem,mmxreg KATMAI,MMX )]650.8 code0
-[2(PAVGB mmxreg,mmxrm KATMAI,MMX )]639.8 code0
-[2(PAVGW mmxreg,mmxrm KATMAI,MMX )]628.8 code0
-[2(PEXTRW reg32,mmxreg,imm KATMAI,MMX )]617.8 code0
-[2(PINSRW mmxreg,mem,imm KATMAI,MMX )]606.8 code0
-[2(PINSRW mmxreg,rm16,imm KATMAI,MMX )]595.8 code0
-[2(PINSRW mmxreg,reg32,imm KATMAI,MMX )]584.8 code0
-[2(PMAXSW mmxreg,mmxrm KATMAI,MMX )]573.8 code0
-[2(PMAXUB mmxreg,mmxrm KATMAI,MMX )]562.8 code0
-[2(PMINSW mmxreg,mmxrm KATMAI,MMX )]551.8 code0
-[2(PMINUB mmxreg,mmxrm KATMAI,MMX )]540.8 code0
-[2(PMOVMSKB reg32,mmxreg KATMAI,MMX )]529.8 code0
-[2(PMULHUW mmxreg,mmxrm KATMAI,MMX )]518.8 code0
-[2(PSADBW mmxreg,mmxrm KATMAI,MMX )]507.8 code0
-[2(PSHUFW mmxreg,mmxrm,imm KATMAI,MMX2)]496.8 code2
-[{/section-B.1.8 xa}(AMD Enhanced 3DNow! \(Athlon\) instructions)](B.1.8)477.6 subh3
-[2(PF2IW mmxreg,mmxrm PENT,3DNOW )]460.6 code1
-[2(PFNACC mmxreg,mmxrm PENT,3DNOW )]449.6 code0
-[2(PFPNACC mmxreg,mmxrm PENT,3DNOW )]438.6 code0
-[2(PI2FW mmxreg,mmxrm PENT,3DNOW )]427.6 code0
-[2(PSWAPD mmxreg,mmxrm PENT,3DNOW)]416.6 code2
-[{/section-B.1.9 xa}(Willamette SSE2 Cacheability Instructions)](B.1.9)397.4 subh3
-[2(MASKMOVDQU xmmreg,xmmreg WILLAMETTE,SSE2 )]380.4 code1
-[2(CLFLUSH mem WILLAMETTE,SSE2 )]369.4 code0
-[2(MOVNTDQ mem,xmmreg WILLAMETTE,SSE2,SO )]358.4 code0
-[2(MOVNTI mem,reg32 WILLAMETTE,SD )]347.4 code0
-[2(MOVNTI mem,reg64 X64 )]336.4 code0
-[2(MOVNTPD mem,xmmreg WILLAMETTE,SSE2,SO )]325.4 code0
-[2(LFENCE WILLAMETTE,SSE2 )]314.4 code0
-[2(MFENCE WILLAMETTE,SSE2)]303.4 code2
-[{/section-B.1.10 xa}(Willamette MMX instructions \(SSE2 SIMD Integer Instructions\))](B.1.10)284.2 subh3
-[2(MOVD mem,xmmreg WILLAMETTE,SSE2,SD )]267.2 code1
-[2(MOVD xmmreg,mem WILLAMETTE,SSE2,SD )]256.2 code0
-[2(MOVD xmmreg,rm32 WILLAMETTE,SSE2 )]245.2 code0
-[2(MOVD rm32,xmmreg WILLAMETTE,SSE2 )]234.2 code0
-[2(MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2 )]223.2 code0
-[2(MOVDQA mem,xmmreg WILLAMETTE,SSE2,SO )]212.2 code0
-[2(MOVDQA xmmreg,mem WILLAMETTE,SSE2,SO )]201.2 code0
-[2(MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2 )]190.2 code0
-[2(MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2 )]179.2 code0
-[2(MOVDQU mem,xmmreg WILLAMETTE,SSE2,SO )]168.2 code0
-[2(MOVDQU xmmreg,mem WILLAMETTE,SSE2,SO )]157.2 code0
-[2(MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2 )]146.2 code0
-[2(MOVDQ2Q mmxreg,xmmreg WILLAMETTE,SSE2 )]135.2 code0
-[2(MOVQ xmmreg,xmmreg WILLAMETTE,SSE2 )]124.2 code0
-[2(MOVQ xmmreg,xmmreg WILLAMETTE,SSE2 )]113.2 code0
-[2(MOVQ mem,xmmreg WILLAMETTE,SSE2 )]102.2 code0
-(150)pageeven
-restore showpage
-%%Page: 151 151
-%%BeginPageSetup
-save
-%%EndPageSetup
-/151 pa
-[2(MOVQ xmmreg,mem WILLAMETTE,SSE2 )]681 code0
-[2(MOVQ xmmreg,rm64 X64,SSE2 )]670 code0
-[2(MOVQ rm64,xmmreg X64,SSE2 )]659 code0
-[2(MOVQ2DQ xmmreg,mmxreg WILLAMETTE,SSE2 )]648 code0
-[2(PACKSSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]637 code0
-[2(PACKSSDW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]626 code0
-[2(PACKUSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]615 code0
-[2(PADDB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]604 code0
-[2(PADDW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]593 code0
-[2(PADDD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]582 code0
-[2(PADDQ mmxreg,mmxrm WILLAMETTE,MMX )]571 code0
-[2(PADDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]560 code0
-[2(PADDSB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]549 code0
-[2(PADDSW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]538 code0
-[2(PADDUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]527 code0
-[2(PADDUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]516 code0
-[2(PAND xmmreg,xmmrm WILLAMETTE,SSE2,SO )]505 code0
-[2(PANDN xmmreg,xmmrm WILLAMETTE,SSE2,SO )]494 code0
-[2(PAVGB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]483 code0
-[2(PAVGW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]472 code0
-[2(PCMPEQB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]461 code0
-[2(PCMPEQW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]450 code0
-[2(PCMPEQD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]439 code0
-[2(PCMPGTB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]428 code0
-[2(PCMPGTW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]417 code0
-[2(PCMPGTD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]406 code0
-[2(PEXTRW reg32,xmmreg,imm WILLAMETTE,SSE2 )]395 code0
-[2(PINSRW xmmreg,reg16,imm WILLAMETTE,SSE2 )]384 code0
-[2(PINSRW xmmreg,reg32,imm WILLAMETTE,SSE2,ND )]373 code0
-[2(PINSRW xmmreg,mem,imm WILLAMETTE,SSE2 )]362 code0
-[2(PINSRW xmmreg,mem16,imm WILLAMETTE,SSE2 )]351 code0
-[2(PMADDWD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]340 code0
-[2(PMAXSW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]329 code0
-[2(PMAXUB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]318 code0
-[2(PMINSW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]307 code0
-[2(PMINUB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]296 code0
-[2(PMOVMSKB reg32,xmmreg WILLAMETTE,SSE2 )]285 code0
-[2(PMULHUW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]274 code0
-[2(PMULHW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]263 code0
-[2(PMULLW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]252 code0
-[2(PMULUDQ mmxreg,mmxrm WILLAMETTE,SSE2,SO )]241 code0
-[2(PMULUDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]230 code0
-[2(POR xmmreg,xmmrm WILLAMETTE,SSE2,SO )]219 code0
-[2(PSADBW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]208 code0
-[2(PSHUFD xmmreg,xmmreg,imm WILLAMETTE,SSE2 )]197 code0
-[2(PSHUFD xmmreg,mem,imm WILLAMETTE,SSE22 )]186 code0
-[2(PSHUFHW xmmreg,xmmreg,imm WILLAMETTE,SSE2 )]175 code0
-[2(PSHUFHW xmmreg,mem,imm WILLAMETTE,SSE22 )]164 code0
-[2(PSHUFLW xmmreg,xmmreg,imm WILLAMETTE,SSE2 )]153 code0
-[2(PSHUFLW xmmreg,mem,imm WILLAMETTE,SSE22 )]142 code0
-[2(PSLLDQ xmmreg,imm WILLAMETTE,SSE2,AR1 )]131 code0
-[2(PSLLW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]120 code0
-[2(PSLLW xmmreg,imm WILLAMETTE,SSE2,AR1 )]109 code0
-(151)pageodd
-restore showpage
-%%Page: 152 152
-%%BeginPageSetup
-save
-%%EndPageSetup
-/152 pa
-[2(PSLLD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]681 code0
-[2(PSLLD xmmreg,imm WILLAMETTE,SSE2,AR1 )]670 code0
-[2(PSLLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]659 code0
-[2(PSLLQ xmmreg,imm WILLAMETTE,SSE2,AR1 )]648 code0
-[2(PSRAW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]637 code0
-[2(PSRAW xmmreg,imm WILLAMETTE,SSE2,AR1 )]626 code0
-[2(PSRAD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]615 code0
-[2(PSRAD xmmreg,imm WILLAMETTE,SSE2,AR1 )]604 code0
-[2(PSRLDQ xmmreg,imm WILLAMETTE,SSE2,AR1 )]593 code0
-[2(PSRLW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]582 code0
-[2(PSRLW xmmreg,imm WILLAMETTE,SSE2,AR1 )]571 code0
-[2(PSRLD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]560 code0
-[2(PSRLD xmmreg,imm WILLAMETTE,SSE2,AR1 )]549 code0
-[2(PSRLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]538 code0
-[2(PSRLQ xmmreg,imm WILLAMETTE,SSE2,AR1 )]527 code0
-[2(PSUBB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]516 code0
-[2(PSUBW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]505 code0
-[2(PSUBD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]494 code0
-[2(PSUBQ mmxreg,mmxrm WILLAMETTE,SSE2,SO )]483 code0
-[2(PSUBQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]472 code0
-[2(PSUBSB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]461 code0
-[2(PSUBSW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]450 code0
-[2(PSUBUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO )]439 code0
-[2(PSUBUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]428 code0
-[2(PUNPCKHBW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]417 code0
-[2(PUNPCKHWD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]406 code0
-[2(PUNPCKHDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]395 code0
-[2(PUNPCKHQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]384 code0
-[2(PUNPCKLBW xmmreg,xmmrm WILLAMETTE,SSE2,SO )]373 code0
-[2(PUNPCKLWD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]362 code0
-[2(PUNPCKLDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]351 code0
-[2(PUNPCKLQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]340 code0
-[2(PXOR xmmreg,xmmrm WILLAMETTE,SSE2,SO)]329 code2
-[{/section-B.1.11 xa}(Willamette Streaming SIMD instructions \(SSE2\))](B.1.11)309.8 subh3
-[2(ADDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]292.8 code1
-[2(ADDSD xmmreg,xmmrm WILLAMETTE,SSE2 )]281.8 code0
-[2(ANDNPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]270.8 code0
-[2(ANDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]259.8 code0
-[2(CMPEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]248.8 code0
-[2(CMPEQSD xmmreg,xmmrm WILLAMETTE,SSE2 )]237.8 code0
-[2(CMPLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]226.8 code0
-[2(CMPLESD xmmreg,xmmrm WILLAMETTE,SSE2 )]215.8 code0
-[2(CMPLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]204.8 code0
-[2(CMPLTSD xmmreg,xmmrm WILLAMETTE,SSE2 )]193.8 code0
-[2(CMPNEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]182.8 code0
-[2(CMPNEQSD xmmreg,xmmrm WILLAMETTE,SSE2 )]171.8 code0
-[2(CMPNLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]160.8 code0
-[2(CMPNLESD xmmreg,xmmrm WILLAMETTE,SSE2 )]149.8 code0
-[2(CMPNLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]138.8 code0
-[2(CMPNLTSD xmmreg,xmmrm WILLAMETTE,SSE2 )]127.8 code0
-[2(CMPORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]116.8 code0
-[2(CMPORDSD xmmreg,xmmrm WILLAMETTE,SSE2 )]105.8 code0
-(152)pageeven
-restore showpage
-%%Page: 153 153
-%%BeginPageSetup
-save
-%%EndPageSetup
-/153 pa
-[2(CMPUNORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]681 code0
-[2(CMPUNORDSD xmmreg,xmmrm WILLAMETTE,SSE2 )]670 code0
-[2(CMPPD xmmreg,xmmrm,imm WILLAMETTE,SSE22 )]659 code0
-[2(CMPSD xmmreg,xmmrm,imm WILLAMETTE,SSE2 )]648 code0
-[2(COMISD xmmreg,xmmrm WILLAMETTE,SSE2 )]637 code0
-[2(CVTDQ2PD xmmreg,xmmrm WILLAMETTE,SSE2 )]626 code0
-[2(CVTDQ2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO )]615 code0
-[2(CVTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]604 code0
-[2(CVTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO )]593 code0
-[2(CVTPD2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO )]582 code0
-[2(CVTPI2PD xmmreg,mmxrm WILLAMETTE,SSE2 )]571 code0
-[2(CVTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]560 code0
-[2(CVTPS2PD xmmreg,xmmrm WILLAMETTE,SSE2 )]549 code0
-[2(CVTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1 )]538 code0
-[2(CVTSD2SI reg32,mem WILLAMETTE,SSE2,AR1 )]527 code0
-[2(CVTSD2SI reg64,xmmreg X64,SSE2,AR1 )]516 code0
-[2(CVTSD2SI reg64,mem X64,SSE2,AR1 )]505 code0
-[2(CVTSD2SS xmmreg,xmmrm WILLAMETTE,SSE2 )]494 code0
-[2(CVTSI2SD xmmreg,mem WILLAMETTE,SSE2,SD,AR1,ND )]483 code0
-[2(CVTSI2SD xmmreg,rm32 WILLAMETTE,SSE2,SD,AR1 )]472 code0
-[2(CVTSI2SD xmmreg,rm64 X64,SSE2,AR1 )]461 code0
-[2(CVTSS2SD xmmreg,xmmrm WILLAMETTE,SSE2,SD )]450 code0
-[2(CVTTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO )]439 code0
-[2(CVTTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]428 code0
-[2(CVTTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO )]417 code0
-[2(CVTTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1 )]406 code0
-[2(CVTTSD2SI reg32,mem WILLAMETTE,SSE2,AR1 )]395 code0
-[2(CVTTSD2SI reg64,xmmreg X64,SSE2,AR1 )]384 code0
-[2(CVTTSD2SI reg64,mem X64,SSE2,AR1 )]373 code0
-[2(DIVPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]362 code0
-[2(DIVSD xmmreg,xmmrm WILLAMETTE,SSE2 )]351 code0
-[2(MAXPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]340 code0
-[2(MAXSD xmmreg,xmmrm WILLAMETTE,SSE2 )]329 code0
-[2(MINPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]318 code0
-[2(MINSD xmmreg,xmmrm WILLAMETTE,SSE2 )]307 code0
-[2(MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2 )]296 code0
-[2(MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2 )]285 code0
-[2(MOVAPD mem,xmmreg WILLAMETTE,SSE2,SO )]274 code0
-[2(MOVAPD xmmreg,mem WILLAMETTE,SSE2,SO )]263 code0
-[2(MOVHPD mem,xmmreg WILLAMETTE,SSE2 )]252 code0
-[2(MOVHPD xmmreg,mem WILLAMETTE,SSE2 )]241 code0
-[2(MOVLPD mem,xmmreg WILLAMETTE,SSE2 )]230 code0
-[2(MOVLPD xmmreg,mem WILLAMETTE,SSE2 )]219 code0
-[2(MOVMSKPD reg32,xmmreg WILLAMETTE,SSE2 )]208 code0
-[2(MOVMSKPD reg64,xmmreg X64,SSE2 )]197 code0
-[2(MOVSD xmmreg,xmmreg WILLAMETTE,SSE2 )]186 code0
-[2(MOVSD xmmreg,xmmreg WILLAMETTE,SSE2 )]175 code0
-[2(MOVSD mem,xmmreg WILLAMETTE,SSE2 )]164 code0
-[2(MOVSD xmmreg,mem WILLAMETTE,SSE2 )]153 code0
-[2(MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2 )]142 code0
-[2(MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2 )]131 code0
-[2(MOVUPD mem,xmmreg WILLAMETTE,SSE2,SO )]120 code0
-[2(MOVUPD xmmreg,mem WILLAMETTE,SSE2,SO )]109 code0
-(153)pageodd
-restore showpage
-%%Page: 154 154
-%%BeginPageSetup
-save
-%%EndPageSetup
-/154 pa
-[2(MULPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]681 code0
-[2(MULSD xmmreg,xmmrm WILLAMETTE,SSE2 )]670 code0
-[2(ORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]659 code0
-[2(SHUFPD xmmreg,xmmreg,imm WILLAMETTE,SSE2 )]648 code0
-[2(SHUFPD xmmreg,mem,imm WILLAMETTE,SSE2 )]637 code0
-[2(SQRTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]626 code0
-[2(SQRTSD xmmreg,xmmrm WILLAMETTE,SSE2 )]615 code0
-[2(SUBPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]604 code0
-[2(SUBSD xmmreg,xmmrm WILLAMETTE,SSE2 )]593 code0
-[2(UCOMISD xmmreg,xmmrm WILLAMETTE,SSE2 )]582 code0
-[2(UNPCKHPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]571 code0
-[2(UNPCKLPD xmmreg,xmmrm WILLAMETTE,SSE2,SO )]560 code0
-[2(XORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO)]549 code2
-[{/section-B.1.12 xa}(Prescott New Instructions \(SSE3\))](B.1.12)529.8 subh3
-[2(ADDSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO )]512.8 code1
-[2(ADDSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO )]501.8 code0
-[2(HADDPD xmmreg,xmmrm PRESCOTT,SSE3,SO )]490.8 code0
-[2(HADDPS xmmreg,xmmrm PRESCOTT,SSE3,SO )]479.8 code0
-[2(HSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO )]468.8 code0
-[2(HSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO )]457.8 code0
-[2(LDDQU xmmreg,mem PRESCOTT,SSE3,SO )]446.8 code0
-[2(MOVDDUP xmmreg,xmmrm PRESCOTT,SSE3 )]435.8 code0
-[2(MOVSHDUP xmmreg,xmmrm PRESCOTT,SSE3 )]424.8 code0
-[2(MOVSLDUP xmmreg,xmmrm PRESCOTT,SSE3)]413.8 code2
-[{/section-B.1.13 xa}(VMX Instructions)](B.1.13)394.6 subh3
-[2(VMCALL VMX )]377.6 code1
-[2(VMCLEAR mem VMX )]366.6 code0
-[2(VMLAUNCH VMX )]355.6 code0
-[2(VMLOAD X64,VMX )]344.6 code0
-[2(VMMCALL X64,VMX )]333.6 code0
-[2(VMPTRLD mem VMX )]322.6 code0
-[2(VMPTRST mem VMX )]311.6 code0
-[2(VMREAD rm32,reg32 VMX,NOLONG,SD )]300.6 code0
-[2(VMREAD rm64,reg64 X64,VMX )]289.6 code0
-[2(VMRESUME VMX )]278.6 code0
-[2(VMRUN X64,VMX )]267.6 code0
-[2(VMSAVE X64,VMX )]256.6 code0
-[2(VMWRITE reg32,rm32 VMX,NOLONG,SD )]245.6 code0
-[2(VMWRITE reg64,rm64 X64,VMX )]234.6 code0
-[2(VMXOFF VMX )]223.6 code0
-[2(VMXON mem VMX)]212.6 code2
-[{/section-B.1.14 xa}(Extended Page Tables VMX instructions)](B.1.14)193.4 subh3
-[2(INVEPT reg32,mem VMX,SO,NOLONG )]176.4 code1
-[2(INVEPT reg64,mem VMX,SO,LONG )]165.4 code0
-[2(INVVPID reg32,mem VMX,SO,NOLONG )]154.4 code0
-[2(INVVPID reg64,mem VMX,SO,LONG)]143.4 code2
-(154)pageeven
-restore showpage
-%%Page: 155 155
-%%BeginPageSetup
-save
-%%EndPageSetup
-/155 pa
-[{/section-B.1.15 xa}(Tejas New Instructions \(SSSE3\))](B.1.15)678.8 subh3
-[2(PABSB mmxreg,mmxrm SSSE3,MMX )]661.8 code1
-[2(PABSB xmmreg,xmmrm SSSE3 )]650.8 code0
-[2(PABSW mmxreg,mmxrm SSSE3,MMX )]639.8 code0
-[2(PABSW xmmreg,xmmrm SSSE3 )]628.8 code0
-[2(PABSD mmxreg,mmxrm SSSE3,MMX )]617.8 code0
-[2(PABSD xmmreg,xmmrm SSSE3 )]606.8 code0
-[2(PALIGNR mmxreg,mmxrm,imm SSSE3,MMX )]595.8 code0
-[2(PALIGNR xmmreg,xmmrm,imm SSSE3 )]584.8 code0
-[2(PHADDW mmxreg,mmxrm SSSE3,MMX )]573.8 code0
-[2(PHADDW xmmreg,xmmrm SSSE3 )]562.8 code0
-[2(PHADDD mmxreg,mmxrm SSSE3,MMX )]551.8 code0
-[2(PHADDD xmmreg,xmmrm SSSE3 )]540.8 code0
-[2(PHADDSW mmxreg,mmxrm SSSE3,MMX )]529.8 code0
-[2(PHADDSW xmmreg,xmmrm SSSE3 )]518.8 code0
-[2(PHSUBW mmxreg,mmxrm SSSE3,MMX )]507.8 code0
-[2(PHSUBW xmmreg,xmmrm SSSE3 )]496.8 code0
-[2(PHSUBD mmxreg,mmxrm SSSE3,MMX )]485.8 code0
-[2(PHSUBD xmmreg,xmmrm SSSE3 )]474.8 code0
-[2(PHSUBSW mmxreg,mmxrm SSSE3,MMX )]463.8 code0
-[2(PHSUBSW xmmreg,xmmrm SSSE3 )]452.8 code0
-[2(PMADDUBSW mmxreg,mmxrm SSSE3,MMX )]441.8 code0
-[2(PMADDUBSW xmmreg,xmmrm SSSE3 )]430.8 code0
-[2(PMULHRSW mmxreg,mmxrm SSSE3,MMX )]419.8 code0
-[2(PMULHRSW xmmreg,xmmrm SSSE3 )]408.8 code0
-[2(PSHUFB mmxreg,mmxrm SSSE3,MMX )]397.8 code0
-[2(PSHUFB xmmreg,xmmrm SSSE3 )]386.8 code0
-[2(PSIGNB mmxreg,mmxrm SSSE3,MMX )]375.8 code0
-[2(PSIGNB xmmreg,xmmrm SSSE3 )]364.8 code0
-[2(PSIGNW mmxreg,mmxrm SSSE3,MMX )]353.8 code0
-[2(PSIGNW xmmreg,xmmrm SSSE3 )]342.8 code0
-[2(PSIGND mmxreg,mmxrm SSSE3,MMX )]331.8 code0
-[2(PSIGND xmmreg,xmmrm SSSE3)]320.8 code2
-[{/section-B.1.16 xa}(AMD SSE4A)](B.1.16)301.6 subh3
-[2(EXTRQ xmmreg,imm,imm SSE4A,AMD )]284.6 code1
-[2(EXTRQ xmmreg,xmmreg SSE4A,AMD )]273.6 code0
-[2(INSERTQ xmmreg,xmmreg,imm,imm SSE4A,AMD )]262.6 code0
-[2(INSERTQ xmmreg,xmmreg SSE4A,AMD )]251.6 code0
-[2(MOVNTSD mem,xmmreg SSE4A,AMD )]240.6 code0
-[2(MOVNTSS mem,xmmreg SSE4A,AMD,SD)]229.6 code2
-[{/section-B.1.17 xa}(New instructions in Barcelona)](B.1.17)210.4 subh3
-[2(LZCNT reg16,rm16 P6,AMD )]193.4 code1
-[2(LZCNT reg32,rm32 P6,AMD )]182.4 code0
-[2(LZCNT reg64,rm64 X64,AMD)]171.4 code2
-[{/section-B.1.18 xa}(Penryn New Instructions \(SSE4.1\))](B.1.18)152.2 subh3
-[2(BLENDPD xmmreg,xmmrm,imm SSE41 )]135.2 code1
-[2(BLENDPS xmmreg,xmmrm,imm SSE41 )]124.2 code0
-[2(BLENDVPD xmmreg,xmmrm,xmm0 SSE41 )]113.2 code0
-[2(BLENDVPS xmmreg,xmmrm,xmm0 SSE41 )]102.2 code0
-(155)pageodd
-restore showpage
-%%Page: 156 156
-%%BeginPageSetup
-save
-%%EndPageSetup
-/156 pa
-[2(DPPD xmmreg,xmmrm,imm SSE41 )]681 code0
-[2(DPPS xmmreg,xmmrm,imm SSE41 )]670 code0
-[2(EXTRACTPS rm32,xmmreg,imm SSE41 )]659 code0
-[2(EXTRACTPS reg64,xmmreg,imm SSE41,X64 )]648 code0
-[2(INSERTPS xmmreg,xmmrm,imm SSE41,SD )]637 code0
-[2(MOVNTDQA xmmreg,mem SSE41 )]626 code0
-[2(MPSADBW xmmreg,xmmrm,imm SSE41 )]615 code0
-[2(PACKUSDW xmmreg,xmmrm SSE41 )]604 code0
-[2(PBLENDVB xmmreg,xmmrm,xmm0 SSE41 )]593 code0
-[2(PBLENDW xmmreg,xmmrm,imm SSE41 )]582 code0
-[2(PCMPEQQ xmmreg,xmmrm SSE41 )]571 code0
-[2(PEXTRB reg32,xmmreg,imm SSE41 )]560 code0
-[2(PEXTRB mem8,xmmreg,imm SSE41 )]549 code0
-[2(PEXTRB reg64,xmmreg,imm SSE41,X64 )]538 code0
-[2(PEXTRD rm32,xmmreg,imm SSE41 )]527 code0
-[2(PEXTRQ rm64,xmmreg,imm SSE41,X64 )]516 code0
-[2(PEXTRW reg32,xmmreg,imm SSE41 )]505 code0
-[2(PEXTRW mem16,xmmreg,imm SSE41 )]494 code0
-[2(PEXTRW reg64,xmmreg,imm SSE41,X64 )]483 code0
-[2(PHMINPOSUW xmmreg,xmmrm SSE41 )]472 code0
-[2(PINSRB xmmreg,mem,imm SSE41 )]461 code0
-[2(PINSRB xmmreg,rm8,imm SSE41 )]450 code0
-[2(PINSRB xmmreg,reg32,imm SSE41 )]439 code0
-[2(PINSRD xmmreg,mem,imm SSE41 )]428 code0
-[2(PINSRD xmmreg,rm32,imm SSE41 )]417 code0
-[2(PINSRQ xmmreg,mem,imm SSE41,X64 )]406 code0
-[2(PINSRQ xmmreg,rm64,imm SSE41,X64 )]395 code0
-[2(PMAXSB xmmreg,xmmrm SSE41 )]384 code0
-[2(PMAXSD xmmreg,xmmrm SSE41 )]373 code0
-[2(PMAXUD xmmreg,xmmrm SSE41 )]362 code0
-[2(PMAXUW xmmreg,xmmrm SSE41 )]351 code0
-[2(PMINSB xmmreg,xmmrm SSE41 )]340 code0
-[2(PMINSD xmmreg,xmmrm SSE41 )]329 code0
-[2(PMINUD xmmreg,xmmrm SSE41 )]318 code0
-[2(PMINUW xmmreg,xmmrm SSE41 )]307 code0
-[2(PMOVSXBW xmmreg,xmmrm SSE41 )]296 code0
-[2(PMOVSXBD xmmreg,xmmrm SSE41,SD )]285 code0
-[2(PMOVSXBQ xmmreg,xmmrm SSE41,SW )]274 code0
-[2(PMOVSXWD xmmreg,xmmrm SSE41 )]263 code0
-[2(PMOVSXWQ xmmreg,xmmrm SSE41,SD )]252 code0
-[2(PMOVSXDQ xmmreg,xmmrm SSE41 )]241 code0
-[2(PMOVZXBW xmmreg,xmmrm SSE41 )]230 code0
-[2(PMOVZXBD xmmreg,xmmrm SSE41,SD )]219 code0
-[2(PMOVZXBQ xmmreg,xmmrm SSE41,SW )]208 code0
-[2(PMOVZXWD xmmreg,xmmrm SSE41 )]197 code0
-[2(PMOVZXWQ xmmreg,xmmrm SSE41,SD )]186 code0
-[2(PMOVZXDQ xmmreg,xmmrm SSE41 )]175 code0
-[2(PMULDQ xmmreg,xmmrm SSE41 )]164 code0
-[2(PMULLD xmmreg,xmmrm SSE41 )]153 code0
-[2(PTEST xmmreg,xmmrm SSE41 )]142 code0
-[2(ROUNDPD xmmreg,xmmrm,imm SSE41 )]131 code0
-[2(ROUNDPS xmmreg,xmmrm,imm SSE41 )]120 code0
-(156)pageeven
-restore showpage
-%%Page: 157 157
-%%BeginPageSetup
-save
-%%EndPageSetup
-/157 pa
-[2(ROUNDSD xmmreg,xmmrm,imm SSE41 )]681 code0
-[2(ROUNDSS xmmreg,xmmrm,imm SSE41)]670 code2
-[{/section-B.1.19 xa}(Nehalem New Instructions \(SSE4.2\))](B.1.19)650.8 subh3
-[2(CRC32 reg32,rm8 SSE42 )]633.8 code1
-[2(CRC32 reg32,rm16 SSE42 )]622.8 code0
-[2(CRC32 reg32,rm32 SSE42 )]611.8 code0
-[2(CRC32 reg64,rm8 SSE42,X64 )]600.8 code0
-[2(CRC32 reg64,rm64 SSE42,X64 )]589.8 code0
-[2(PCMPESTRI xmmreg,xmmrm,imm SSE42 )]578.8 code0
-[2(PCMPESTRM xmmreg,xmmrm,imm SSE42 )]567.8 code0
-[2(PCMPISTRI xmmreg,xmmrm,imm SSE42 )]556.8 code0
-[2(PCMPISTRM xmmreg,xmmrm,imm SSE42 )]545.8 code0
-[2(PCMPGTQ xmmreg,xmmrm SSE42 )]534.8 code0
-[2(POPCNT reg16,rm16 NEHALEM,SW )]523.8 code0
-[2(POPCNT reg32,rm32 NEHALEM,SD )]512.8 code0
-[2(POPCNT reg64,rm64 NEHALEM,X64)]501.8 code2
-[{/section-B.1.20 xa}(Intel SMX)](B.1.20)482.6 subh3
-[2(GETSEC KATMAI)]465.6 code3
-[{/section-B.1.21 xa}(Geode \(Cyrix\) 3DNow! additions)](B.1.21)446.4 subh3
-[2(PFRCPV mmxreg,mmxrm PENT,3DNOW,CYRIX )]429.4 code1
-[2(PFRSQRTV mmxreg,mmxrm PENT,3DNOW,CYRIX)]418.4 code2
-[{/section-B.1.22 xa}(Intel new instructions in ???)](B.1.22)399.2 subh3
-[2(MOVBE reg16,mem16 NEHALEM )]382.2 code1
-[2(MOVBE reg32,mem32 NEHALEM )]371.2 code0
-[2(MOVBE reg64,mem64 NEHALEM )]360.2 code0
-[2(MOVBE mem16,reg16 NEHALEM )]349.2 code0
-[2(MOVBE mem32,reg32 NEHALEM )]338.2 code0
-[2(MOVBE mem64,reg64 NEHALEM)]327.2 code2
-[{/section-B.1.23 xa}(Intel AES instructions)](B.1.23)308 subh3
-[2(AESENC xmmreg,xmmrm128 SSE,WESTMERE )]291 code1
-[2(AESENCLAST xmmreg,xmmrm128 SSE,WESTMERE )]280 code0
-[2(AESDEC xmmreg,xmmrm128 SSE,WESTMERE )]269 code0
-[2(AESDECLAST xmmreg,xmmrm128 SSE,WESTMERE )]258 code0
-[2(AESIMC xmmreg,xmmrm128 SSE,WESTMERE )]247 code0
-[2(AESKEYGENASSIST xmmreg,xmmrm128,imm8 SSE,WESTMERE)]236 code2
-[{/section-B.1.24 xa}(Intel AVX AES instructions)](B.1.24)216.8 subh3
-[2(VAESENC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]199.8 code1
-[2(VAESENCLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]188.8 code0
-[2(VAESDEC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]177.8 code0
-[2(VAESDECLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]166.8 code0
-[2(VAESIMC xmmreg,xmmrm128 AVX,SANDYBRIDGE )]155.8 code0
-[2(VAESKEYGENASSIST xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE)]144.8 code2
-(157)pageodd
-restore showpage
-%%Page: 158 158
-%%BeginPageSetup
-save
-%%EndPageSetup
-/158 pa
-[{/section-B.1.25 xa}(Intel AVX instructions)](B.1.25)678.8 subh3
-[2(VADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]661.8 code1
-[2(VADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]650.8 code0
-[2(VADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]639.8 code0
-[2(VADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]628.8 code0
-[2(VADDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]617.8 code0
-[2(VADDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]606.8 code0
-[2(VADDSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]595.8 code0
-[2(VADDSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]584.8 code0
-[2(VADDSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]573.8 code0
-[2(VADDSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]562.8 code0
-[2(VANDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]551.8 code0
-[2(VANDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]540.8 code0
-[2(VANDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]529.8 code0
-[2(VANDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]518.8 code0
-[2(VANDNPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]507.8 code0
-[2(VANDNPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]496.8 code0
-[2(VANDNPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]485.8 code0
-[2(VANDNPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]474.8 code0
-[2(VBLENDPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]463.8 code0
-[2(VBLENDPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]452.8 code0
-[2(VBLENDPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]441.8 code0
-[2(VBLENDPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]430.8 code0
-[2(VBLENDVPD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]419.8 code0
-[2(VBLENDVPD xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE )]408.8 code0
-[2(VBLENDVPD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]397.8 code0
-[2(VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE )]386.8 code0
-[2(VBLENDVPS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]375.8 code0
-[2(VBLENDVPS xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE )]364.8 code0
-[2(VBLENDVPS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]353.8 code0
-[2(VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE )]342.8 code0
-[2(VBROADCASTSS xmmreg,mem32 AVX,SANDYBRIDGE )]331.8 code0
-[2(VBROADCASTSS ymmreg,mem32 AVX,SANDYBRIDGE )]320.8 code0
-[2(VBROADCASTSD ymmreg,mem64 AVX,SANDYBRIDGE )]309.8 code0
-[2(VBROADCASTF128 ymmreg,mem128 AVX,SANDYBRIDGE )]298.8 code0
-[2(VCMPEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]287.8 code0
-[2(VCMPEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]276.8 code0
-[2(VCMPLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]265.8 code0
-[2(VCMPLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]254.8 code0
-[2(VCMPLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]243.8 code0
-[2(VCMPLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]232.8 code0
-[2(VCMPUNORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]221.8 code0
-[2(VCMPUNORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]210.8 code0
-[2(VCMPNEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]199.8 code0
-[2(VCMPNEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]188.8 code0
-[2(VCMPNLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]177.8 code0
-[2(VCMPNLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]166.8 code0
-[2(VCMPNLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]155.8 code0
-[2(VCMPNLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]144.8 code0
-[2(VCMPORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]133.8 code0
-[2(VCMPORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]122.8 code0
-[2(VCMPEQ_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]111.8 code0
-[2(VCMPEQ_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]100.8 code0
-(158)pageeven
-restore showpage
-%%Page: 159 159
-%%BeginPageSetup
-save
-%%EndPageSetup
-/159 pa
-[2(VCMPNGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]681 code0
-[2(VCMPNGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]670 code0
-[2(VCMPNGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]659 code0
-[2(VCMPNGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]648 code0
-[2(VCMPFALSEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]637 code0
-[2(VCMPFALSEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]626 code0
-[2(VCMPNEQ_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]615 code0
-[2(VCMPNEQ_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]604 code0
-[2(VCMPGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]593 code0
-[2(VCMPGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]582 code0
-[2(VCMPGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]571 code0
-[2(VCMPGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]560 code0
-[2(VCMPTRUEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]549 code0
-[2(VCMPTRUEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]538 code0
-[2(VCMPEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]527 code0
-[2(VCMPEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]516 code0
-[2(VCMPLT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]505 code0
-[2(VCMPLT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]494 code0
-[2(VCMPLE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]483 code0
-[2(VCMPLE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]472 code0
-[2(VCMPUNORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]461 code0
-[2(VCMPUNORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]450 code0
-[2(VCMPNEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]439 code0
-[2(VCMPNEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]428 code0
-[2(VCMPNLT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]417 code0
-[2(VCMPNLT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]406 code0
-[2(VCMPNLE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]395 code0
-[2(VCMPNLE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]384 code0
-[2(VCMPORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]373 code0
-[2(VCMPORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]362 code0
-[2(VCMPEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]351 code0
-[2(VCMPEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]340 code0
-[2(VCMPNGE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]329 code0
-[2(VCMPNGE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]318 code0
-[2(VCMPNGT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]307 code0
-[2(VCMPNGT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]296 code0
-[2(VCMPFALSE_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]285 code0
-[2(VCMPFALSE_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]274 code0
-[2(VCMPNEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]263 code0
-[2(VCMPNEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]252 code0
-[2(VCMPGE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]241 code0
-[2(VCMPGE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]230 code0
-[2(VCMPGT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]219 code0
-[2(VCMPGT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]208 code0
-[2(VCMPTRUE_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]197 code0
-[2(VCMPTRUE_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]186 code0
-[2(VCMPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]175 code0
-[2(VCMPPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]164 code0
-[2(VCMPEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]153 code0
-[2(VCMPEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]142 code0
-[2(VCMPLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]131 code0
-[2(VCMPLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]120 code0
-[2(VCMPLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]109 code0
-(159)pageodd
-restore showpage
-%%Page: 160 160
-%%BeginPageSetup
-save
-%%EndPageSetup
-/160 pa
-[2(VCMPLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]681 code0
-[2(VCMPUNORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]670 code0
-[2(VCMPUNORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]659 code0
-[2(VCMPNEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]648 code0
-[2(VCMPNEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]637 code0
-[2(VCMPNLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]626 code0
-[2(VCMPNLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]615 code0
-[2(VCMPNLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]604 code0
-[2(VCMPNLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]593 code0
-[2(VCMPORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]582 code0
-[2(VCMPORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]571 code0
-[2(VCMPEQ_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]560 code0
-[2(VCMPEQ_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]549 code0
-[2(VCMPNGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]538 code0
-[2(VCMPNGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]527 code0
-[2(VCMPNGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]516 code0
-[2(VCMPNGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]505 code0
-[2(VCMPFALSEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]494 code0
-[2(VCMPFALSEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]483 code0
-[2(VCMPNEQ_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]472 code0
-[2(VCMPNEQ_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]461 code0
-[2(VCMPGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]450 code0
-[2(VCMPGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]439 code0
-[2(VCMPGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]428 code0
-[2(VCMPGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]417 code0
-[2(VCMPTRUEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]406 code0
-[2(VCMPTRUEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]395 code0
-[2(VCMPEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]384 code0
-[2(VCMPEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]373 code0
-[2(VCMPLT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]362 code0
-[2(VCMPLT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]351 code0
-[2(VCMPLE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]340 code0
-[2(VCMPLE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]329 code0
-[2(VCMPUNORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]318 code0
-[2(VCMPUNORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]307 code0
-[2(VCMPNEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]296 code0
-[2(VCMPNEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]285 code0
-[2(VCMPNLT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]274 code0
-[2(VCMPNLT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]263 code0
-[2(VCMPNLE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]252 code0
-[2(VCMPNLE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]241 code0
-[2(VCMPORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]230 code0
-[2(VCMPORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]219 code0
-[2(VCMPEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]208 code0
-[2(VCMPEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]197 code0
-[2(VCMPNGE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]186 code0
-[2(VCMPNGE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]175 code0
-[2(VCMPNGT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]164 code0
-[2(VCMPNGT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]153 code0
-[2(VCMPFALSE_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]142 code0
-[2(VCMPFALSE_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]131 code0
-[2(VCMPNEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]120 code0
-[2(VCMPNEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]109 code0
-(160)pageeven
-restore showpage
-%%Page: 161 161
-%%BeginPageSetup
-save
-%%EndPageSetup
-/161 pa
-[2(VCMPGE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]681 code0
-[2(VCMPGE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]670 code0
-[2(VCMPGT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]659 code0
-[2(VCMPGT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]648 code0
-[2(VCMPTRUE_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]637 code0
-[2(VCMPTRUE_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]626 code0
-[2(VCMPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]615 code0
-[2(VCMPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]604 code0
-[2(VCMPEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]593 code0
-[2(VCMPLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]582 code0
-[2(VCMPLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]571 code0
-[2(VCMPUNORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]560 code0
-[2(VCMPNEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]549 code0
-[2(VCMPNLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]538 code0
-[2(VCMPNLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]527 code0
-[2(VCMPORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]516 code0
-[2(VCMPEQ_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]505 code0
-[2(VCMPNGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]494 code0
-[2(VCMPNGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]483 code0
-[2(VCMPFALSESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]472 code0
-[2(VCMPNEQ_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]461 code0
-[2(VCMPGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]450 code0
-[2(VCMPGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]439 code0
-[2(VCMPTRUESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]428 code0
-[2(VCMPEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]417 code0
-[2(VCMPLT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]406 code0
-[2(VCMPLE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]395 code0
-[2(VCMPUNORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]384 code0
-[2(VCMPNEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]373 code0
-[2(VCMPNLT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]362 code0
-[2(VCMPNLE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]351 code0
-[2(VCMPORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]340 code0
-[2(VCMPEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]329 code0
-[2(VCMPNGE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]318 code0
-[2(VCMPNGT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]307 code0
-[2(VCMPFALSE_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]296 code0
-[2(VCMPNEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]285 code0
-[2(VCMPGE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]274 code0
-[2(VCMPGT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]263 code0
-[2(VCMPTRUE_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]252 code0
-[2(VCMPSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE )]241 code0
-[2(VCMPEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]230 code0
-[2(VCMPLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]219 code0
-[2(VCMPLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]208 code0
-[2(VCMPUNORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]197 code0
-[2(VCMPNEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]186 code0
-[2(VCMPNLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]175 code0
-[2(VCMPNLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]164 code0
-[2(VCMPORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]153 code0
-[2(VCMPEQ_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]142 code0
-[2(VCMPNGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]131 code0
-[2(VCMPNGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]120 code0
-[2(VCMPFALSESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]109 code0
-(161)pageodd
-restore showpage
-%%Page: 162 162
-%%BeginPageSetup
-save
-%%EndPageSetup
-/162 pa
-[2(VCMPNEQ_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]681 code0
-[2(VCMPGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]670 code0
-[2(VCMPGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]659 code0
-[2(VCMPTRUESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]648 code0
-[2(VCMPEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]637 code0
-[2(VCMPLT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]626 code0
-[2(VCMPLE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]615 code0
-[2(VCMPUNORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]604 code0
-[2(VCMPNEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]593 code0
-[2(VCMPNLT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]582 code0
-[2(VCMPNLE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]571 code0
-[2(VCMPORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]560 code0
-[2(VCMPEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]549 code0
-[2(VCMPNGE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]538 code0
-[2(VCMPNGT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]527 code0
-[2(VCMPFALSE_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]516 code0
-[2(VCMPNEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]505 code0
-[2(VCMPGE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]494 code0
-[2(VCMPGT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]483 code0
-[2(VCMPTRUE_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]472 code0
-[2(VCMPSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE )]461 code0
-[2(VCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE )]450 code0
-[2(VCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE )]439 code0
-[2(VCVTDQ2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE )]428 code0
-[2(VCVTDQ2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE )]417 code0
-[2(VCVTDQ2PS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]406 code0
-[2(VCVTDQ2PS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]395 code0
-[2(VCVTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE )]384 code0
-[2(VCVTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO )]373 code0
-[2(VCVTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE )]362 code0
-[2(VCVTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY )]351 code0
-[2(VCVTPD2PS xmmreg,xmmreg AVX,SANDYBRIDGE )]340 code0
-[2(VCVTPD2PS xmmreg,mem128 AVX,SANDYBRIDGE,SO )]329 code0
-[2(VCVTPD2PS xmmreg,ymmreg AVX,SANDYBRIDGE )]318 code0
-[2(VCVTPD2PS xmmreg,mem256 AVX,SANDYBRIDGE,SY )]307 code0
-[2(VCVTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE )]296 code0
-[2(VCVTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE )]285 code0
-[2(VCVTPS2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE )]274 code0
-[2(VCVTPS2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE )]263 code0
-[2(VCVTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE )]252 code0
-[2(VCVTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG )]241 code0
-[2(VCVTSD2SS xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]230 code0
-[2(VCVTSI2SD xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD )]219 code0
-[2(VCVTSI2SD xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD )]208 code0
-[2(VCVTSI2SD xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG )]197 code0
-[2(VCVTSI2SS xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD )]186 code0
-[2(VCVTSI2SS xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD )]175 code0
-[2(VCVTSI2SS xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG )]164 code0
-[2(VCVTSS2SD xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]153 code0
-[2(VCVTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE )]142 code0
-[2(VCVTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG )]131 code0
-[2(VCVTTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE )]120 code0
-[2(VCVTTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO )]109 code0
-(162)pageeven
-restore showpage
-%%Page: 163 163
-%%BeginPageSetup
-save
-%%EndPageSetup
-/163 pa
-[2(VCVTTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE )]681 code0
-[2(VCVTTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY )]670 code0
-[2(VCVTTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE )]659 code0
-[2(VCVTTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE )]648 code0
-[2(VCVTTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE )]637 code0
-[2(VCVTTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG )]626 code0
-[2(VCVTTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE )]615 code0
-[2(VCVTTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG )]604 code0
-[2(VDIVPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]593 code0
-[2(VDIVPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]582 code0
-[2(VDIVPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]571 code0
-[2(VDIVPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]560 code0
-[2(VDIVSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]549 code0
-[2(VDIVSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]538 code0
-[2(VDPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]527 code0
-[2(VDPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]516 code0
-[2(VDPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]505 code0
-[2(VEXTRACTF128 xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE )]494 code0
-[2(VEXTRACTPS rm32,xmmreg,imm8 AVX,SANDYBRIDGE )]483 code0
-[2(VHADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]472 code0
-[2(VHADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]461 code0
-[2(VHADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]450 code0
-[2(VHADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]439 code0
-[2(VHSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]428 code0
-[2(VHSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]417 code0
-[2(VHSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]406 code0
-[2(VHSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]395 code0
-[2(VINSERTF128 ymmreg,ymmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]384 code0
-[2(VINSERTPS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE )]373 code0
-[2(VLDDQU xmmreg,mem128 AVX,SANDYBRIDGE )]362 code0
-[2(VLDQQU ymmreg,mem256 AVX,SANDYBRIDGE )]351 code0
-[2(VLDDQU ymmreg,mem256 AVX,SANDYBRIDGE )]340 code0
-[2(VLDMXCSR mem32 AVX,SANDYBRIDGE )]329 code0
-[2(VMASKMOVDQU xmmreg,xmmreg AVX,SANDYBRIDGE )]318 code0
-[2(VMASKMOVPS xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE )]307 code0
-[2(VMASKMOVPS ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE )]296 code0
-[2(VMASKMOVPS mem128,xmmreg,xmmreg AVX,SANDYBRIDGE,SO )]285 code0
-[2(VMASKMOVPS mem256,xmmreg,xmmreg AVX,SANDYBRIDGE,SY )]274 code0
-[2(VMASKMOVPD xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE )]263 code0
-[2(VMASKMOVPD ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE )]252 code0
-[2(VMASKMOVPD mem128,xmmreg,xmmreg AVX,SANDYBRIDGE )]241 code0
-[2(VMASKMOVPD mem256,ymmreg,ymmreg AVX,SANDYBRIDGE )]230 code0
-[2(VMAXPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]219 code0
-[2(VMAXPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]208 code0
-[2(VMAXPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]197 code0
-[2(VMAXPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]186 code0
-[2(VMAXSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]175 code0
-[2(VMAXSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]164 code0
-[2(VMINPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]153 code0
-[2(VMINPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]142 code0
-[2(VMINPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]131 code0
-[2(VMINPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]120 code0
-[2(VMINSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]109 code0
-(163)pageodd
-restore showpage
-%%Page: 164 164
-%%BeginPageSetup
-save
-%%EndPageSetup
-/164 pa
-[2(VMINSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]681 code0
-[2(VMOVAPD xmmreg,xmmrm128 AVX,SANDYBRIDGE )]670 code0
-[2(VMOVAPD xmmrm128,xmmreg AVX,SANDYBRIDGE )]659 code0
-[2(VMOVAPD ymmreg,ymmrm256 AVX,SANDYBRIDGE )]648 code0
-[2(VMOVAPD ymmrm256,ymmreg AVX,SANDYBRIDGE )]637 code0
-[2(VMOVAPS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]626 code0
-[2(VMOVAPS xmmrm128,xmmreg AVX,SANDYBRIDGE )]615 code0
-[2(VMOVAPS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]604 code0
-[2(VMOVAPS ymmrm256,ymmreg AVX,SANDYBRIDGE )]593 code0
-[2(VMOVQ xmmreg,xmmrm64 AVX,SANDYBRIDGE )]582 code0
-[2(VMOVQ xmmrm64,xmmreg AVX,SANDYBRIDGE )]571 code0
-[2(VMOVQ xmmreg,rm64 AVX,SANDYBRIDGE,LONG )]560 code0
-[2(VMOVQ rm64,xmmreg AVX,SANDYBRIDGE,LONG )]549 code0
-[2(VMOVD xmmreg,rm32 AVX,SANDYBRIDGE )]538 code0
-[2(VMOVD rm32,xmmreg AVX,SANDYBRIDGE )]527 code0
-[2(VMOVDDUP xmmreg,xmmrm64 AVX,SANDYBRIDGE )]516 code0
-[2(VMOVDDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE )]505 code0
-[2(VMOVDQA xmmreg,xmmrm128 AVX,SANDYBRIDGE )]494 code0
-[2(VMOVDQA xmmrm128,xmmreg AVX,SANDYBRIDGE )]483 code0
-[2(VMOVQQA ymmreg,ymmrm256 AVX,SANDYBRIDGE )]472 code0
-[2(VMOVQQA ymmrm256,ymmreg AVX,SANDYBRIDGE )]461 code0
-[2(VMOVDQA ymmreg,ymmrm AVX,SANDYBRIDGE )]450 code0
-[2(VMOVDQA ymmrm256,ymmreg AVX,SANDYBRIDGE )]439 code0
-[2(VMOVDQU xmmreg,xmmrm128 AVX,SANDYBRIDGE )]428 code0
-[2(VMOVDQU xmmrm128,xmmreg AVX,SANDYBRIDGE )]417 code0
-[2(VMOVQQU ymmreg,ymmrm256 AVX,SANDYBRIDGE )]406 code0
-[2(VMOVQQU ymmrm256,ymmreg AVX,SANDYBRIDGE )]395 code0
-[2(VMOVDQU ymmreg,ymmrm256 AVX,SANDYBRIDGE )]384 code0
-[2(VMOVDQU ymmrm256,ymmreg AVX,SANDYBRIDGE )]373 code0
-[2(VMOVHLPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE )]362 code0
-[2(VMOVHPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE )]351 code0
-[2(VMOVHPD mem64,xmmreg AVX,SANDYBRIDGE )]340 code0
-[2(VMOVHPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE )]329 code0
-[2(VMOVHPS mem64,xmmreg AVX,SANDYBRIDGE )]318 code0
-[2(VMOVLHPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE )]307 code0
-[2(VMOVLPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE )]296 code0
-[2(VMOVLPD mem64,xmmreg AVX,SANDYBRIDGE )]285 code0
-[2(VMOVLPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE )]274 code0
-[2(VMOVLPS mem64,xmmreg AVX,SANDYBRIDGE )]263 code0
-[2(VMOVMSKPD reg64,xmmreg AVX,SANDYBRIDGE,LONG )]252 code0
-[2(VMOVMSKPD reg32,xmmreg AVX,SANDYBRIDGE )]241 code0
-[2(VMOVMSKPD reg64,ymmreg AVX,SANDYBRIDGE,LONG )]230 code0
-[2(VMOVMSKPD reg32,ymmreg AVX,SANDYBRIDGE )]219 code0
-[2(VMOVMSKPS reg64,xmmreg AVX,SANDYBRIDGE,LONG )]208 code0
-[2(VMOVMSKPS reg32,xmmreg AVX,SANDYBRIDGE )]197 code0
-[2(VMOVMSKPS reg64,ymmreg AVX,SANDYBRIDGE,LONG )]186 code0
-[2(VMOVMSKPS reg32,ymmreg AVX,SANDYBRIDGE )]175 code0
-[2(VMOVNTDQ mem128,xmmreg AVX,SANDYBRIDGE )]164 code0
-[2(VMOVNTQQ mem256,ymmreg AVX,SANDYBRIDGE )]153 code0
-[2(VMOVNTDQ mem256,ymmreg AVX,SANDYBRIDGE )]142 code0
-[2(VMOVNTDQA xmmreg,mem128 AVX,SANDYBRIDGE )]131 code0
-[2(VMOVNTPD mem128,xmmreg AVX,SANDYBRIDGE )]120 code0
-[2(VMOVNTPD mem256,ymmreg AVX,SANDYBRIDGE )]109 code0
-(164)pageeven
-restore showpage
-%%Page: 165 165
-%%BeginPageSetup
-save
-%%EndPageSetup
-/165 pa
-[2(VMOVNTPS mem128,xmmreg AVX,SANDYBRIDGE )]681 code0
-[2(VMOVNTPS mem128,ymmreg AVX,SANDYBRIDGE )]670 code0
-[2(VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE )]659 code0
-[2(VMOVSD xmmreg,mem64 AVX,SANDYBRIDGE )]648 code0
-[2(VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE )]637 code0
-[2(VMOVSD mem64,xmmreg AVX,SANDYBRIDGE )]626 code0
-[2(VMOVSHDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE )]615 code0
-[2(VMOVSHDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE )]604 code0
-[2(VMOVSLDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE )]593 code0
-[2(VMOVSLDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE )]582 code0
-[2(VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE )]571 code0
-[2(VMOVSS xmmreg,mem64 AVX,SANDYBRIDGE )]560 code0
-[2(VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE )]549 code0
-[2(VMOVSS mem64,xmmreg AVX,SANDYBRIDGE )]538 code0
-[2(VMOVUPD xmmreg,xmmrm128 AVX,SANDYBRIDGE )]527 code0
-[2(VMOVUPD xmmrm128,xmmreg AVX,SANDYBRIDGE )]516 code0
-[2(VMOVUPD ymmreg,ymmrm256 AVX,SANDYBRIDGE )]505 code0
-[2(VMOVUPD ymmrm256,ymmreg AVX,SANDYBRIDGE )]494 code0
-[2(VMOVUPS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]483 code0
-[2(VMOVUPS xmmrm128,xmmreg AVX,SANDYBRIDGE )]472 code0
-[2(VMOVUPS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]461 code0
-[2(VMOVUPS ymmrm256,ymmreg AVX,SANDYBRIDGE )]450 code0
-[2(VMPSADBW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]439 code0
-[2(VMULPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]428 code0
-[2(VMULPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]417 code0
-[2(VMULPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]406 code0
-[2(VMULPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]395 code0
-[2(VMULSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]384 code0
-[2(VMULSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]373 code0
-[2(VORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]362 code0
-[2(VORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]351 code0
-[2(VORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]340 code0
-[2(VORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]329 code0
-[2(VPABSB xmmreg,xmmrm128 AVX,SANDYBRIDGE )]318 code0
-[2(VPABSW xmmreg,xmmrm128 AVX,SANDYBRIDGE )]307 code0
-[2(VPABSD xmmreg,xmmrm128 AVX,SANDYBRIDGE )]296 code0
-[2(VPACKSSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]285 code0
-[2(VPACKSSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]274 code0
-[2(VPACKUSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]263 code0
-[2(VPACKUSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]252 code0
-[2(VPADDB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]241 code0
-[2(VPADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]230 code0
-[2(VPADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]219 code0
-[2(VPADDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]208 code0
-[2(VPADDSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]197 code0
-[2(VPADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]186 code0
-[2(VPADDUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]175 code0
-[2(VPADDUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]164 code0
-[2(VPALIGNR xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]153 code0
-[2(VPAND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]142 code0
-[2(VPANDN xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]131 code0
-[2(VPAVGB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]120 code0
-[2(VPAVGW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]109 code0
-(165)pageodd
-restore showpage
-%%Page: 166 166
-%%BeginPageSetup
-save
-%%EndPageSetup
-/166 pa
-[2(VPBLENDVB xmmreg,xmmreg*,xmmrm128,xmmreg AVX,SANDYBRIDGE )]681 code0
-[2(VPBLENDW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]670 code0
-[2(VPCMPESTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]659 code0
-[2(VPCMPESTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]648 code0
-[2(VPCMPISTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]637 code0
-[2(VPCMPISTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]626 code0
-[2(VPCMPEQB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]615 code0
-[2(VPCMPEQW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]604 code0
-[2(VPCMPEQD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]593 code0
-[2(VPCMPEQQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]582 code0
-[2(VPCMPGTB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]571 code0
-[2(VPCMPGTW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]560 code0
-[2(VPCMPGTD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]549 code0
-[2(VPCMPGTQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]538 code0
-[2(VPERMILPD xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]527 code0
-[2(VPERMILPD ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]516 code0
-[2(VPERMILPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]505 code0
-[2(VPERMILPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]494 code0
-[2(VPERMILTD2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]483 code0
-[2(VPERMILTD2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]472 code0
-[2(VPERMILTD2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]461 code0
-[2(VPERMILTD2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]450 code0
-[2(VPERMILMO2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]439 code0
-[2(VPERMILMO2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]428 code0
-[2(VPERMILMO2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]417 code0
-[2(VPERMILMO2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]406 code0
-[2(VPERMILMZ2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]395 code0
-[2(VPERMILMZ2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]384 code0
-[2(VPERMILMZ2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]373 code0
-[2(VPERMILMZ2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]362 code0
-[2(VPERMIL2PD xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE )]351 code0
-[2(VPERMIL2PD xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]340 code0
-[2(VPERMIL2PD ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE )]329 code0
-[2(VPERMIL2PD ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]318 code0
-[2(VPERMILPS xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]307 code0
-[2(VPERMILPS ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]296 code0
-[2(VPERMILPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]285 code0
-[2(VPERMILPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]274 code0
-[2(VPERMILTD2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]263 code0
-[2(VPERMILTD2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]252 code0
-[2(VPERMILTD2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]241 code0
-[2(VPERMILTD2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]230 code0
-[2(VPERMILMO2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]219 code0
-[2(VPERMILMO2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]208 code0
-[2(VPERMILMO2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]197 code0
-[2(VPERMILMO2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]186 code0
-[2(VPERMILMZ2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE )]175 code0
-[2(VPERMILMZ2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE )]164 code0
-[2(VPERMILMZ2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE )]153 code0
-[2(VPERMILMZ2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE )]142 code0
-[2(VPERMIL2PS xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE )]131 code0
-[2(VPERMIL2PS xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]120 code0
-[2(VPERMIL2PS ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE )]109 code0
-(166)pageeven
-restore showpage
-%%Page: 167 167
-%%BeginPageSetup
-save
-%%EndPageSetup
-/167 pa
-[2(VPERMIL2PS ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]681 code0
-[2(VPERM2F128 ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]670 code0
-[2(VPEXTRB reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG )]659 code0
-[2(VPEXTRB reg32,xmmreg,imm8 AVX,SANDYBRIDGE )]648 code0
-[2(VPEXTRB mem8,xmmreg,imm8 AVX,SANDYBRIDGE )]637 code0
-[2(VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG )]626 code0
-[2(VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE )]615 code0
-[2(VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE )]604 code0
-[2(VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG )]593 code0
-[2(VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE )]582 code0
-[2(VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE )]571 code0
-[2(VPEXTRD reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG )]560 code0
-[2(VPEXTRD rm32,xmmreg,imm8 AVX,SANDYBRIDGE )]549 code0
-[2(VPEXTRQ rm64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG )]538 code0
-[2(VPHADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]527 code0
-[2(VPHADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]516 code0
-[2(VPHADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]505 code0
-[2(VPHMINPOSUW xmmreg,xmmrm128 AVX,SANDYBRIDGE )]494 code0
-[2(VPHSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]483 code0
-[2(VPHSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]472 code0
-[2(VPHSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]461 code0
-[2(VPINSRB xmmreg,xmmreg*,mem8,imm8 AVX,SANDYBRIDGE )]450 code0
-[2(VPINSRB xmmreg,xmmreg*,rm8,imm8 AVX,SANDYBRIDGE )]439 code0
-[2(VPINSRB xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE )]428 code0
-[2(VPINSRW xmmreg,xmmreg*,mem16,imm8 AVX,SANDYBRIDGE )]417 code0
-[2(VPINSRW xmmreg,xmmreg*,rm16,imm8 AVX,SANDYBRIDGE )]406 code0
-[2(VPINSRW xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE )]395 code0
-[2(VPINSRD xmmreg,xmmreg*,mem32,imm8 AVX,SANDYBRIDGE )]384 code0
-[2(VPINSRD xmmreg,xmmreg*,rm32,imm8 AVX,SANDYBRIDGE )]373 code0
-[2(VPINSRQ xmmreg,xmmreg*,mem64,imm8 AVX,SANDYBRIDGE,LONG )]362 code0
-[2(VPINSRQ xmmreg,xmmreg*,rm64,imm8 AVX,SANDYBRIDGE,LONG )]351 code0
-[2(VPMADDWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]340 code0
-[2(VPMADDUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]329 code0
-[2(VPMAXSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]318 code0
-[2(VPMAXSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]307 code0
-[2(VPMAXSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]296 code0
-[2(VPMAXUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]285 code0
-[2(VPMAXUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]274 code0
-[2(VPMAXUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]263 code0
-[2(VPMINSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]252 code0
-[2(VPMINSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]241 code0
-[2(VPMINSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]230 code0
-[2(VPMINUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]219 code0
-[2(VPMINUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]208 code0
-[2(VPMINUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]197 code0
-[2(VPMOVMSKB reg64,xmmreg AVX,SANDYBRIDGE,LONG )]186 code0
-[2(VPMOVMSKB reg32,xmmreg AVX,SANDYBRIDGE )]175 code0
-[2(VPMOVSXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE )]164 code0
-[2(VPMOVSXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE )]153 code0
-[2(VPMOVSXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE )]142 code0
-[2(VPMOVSXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE )]131 code0
-[2(VPMOVSXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE )]120 code0
-[2(VPMOVSXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE )]109 code0
-(167)pageodd
-restore showpage
-%%Page: 168 168
-%%BeginPageSetup
-save
-%%EndPageSetup
-/168 pa
-[2(VPMOVZXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE )]681 code0
-[2(VPMOVZXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE )]670 code0
-[2(VPMOVZXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE )]659 code0
-[2(VPMOVZXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE )]648 code0
-[2(VPMOVZXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE )]637 code0
-[2(VPMOVZXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE )]626 code0
-[2(VPMULHUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]615 code0
-[2(VPMULHRSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]604 code0
-[2(VPMULHW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]593 code0
-[2(VPMULLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]582 code0
-[2(VPMULLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]571 code0
-[2(VPMULUDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]560 code0
-[2(VPMULDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]549 code0
-[2(VPOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]538 code0
-[2(VPSADBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]527 code0
-[2(VPSHUFB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]516 code0
-[2(VPSHUFD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]505 code0
-[2(VPSHUFHW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]494 code0
-[2(VPSHUFLW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]483 code0
-[2(VPSIGNB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]472 code0
-[2(VPSIGNW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]461 code0
-[2(VPSIGND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]450 code0
-[2(VPSLLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]439 code0
-[2(VPSRLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]428 code0
-[2(VPSLLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]417 code0
-[2(VPSLLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]406 code0
-[2(VPSLLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]395 code0
-[2(VPSLLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]384 code0
-[2(VPSLLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]373 code0
-[2(VPSLLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]362 code0
-[2(VPSRAW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]351 code0
-[2(VPSRAW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]340 code0
-[2(VPSRAD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]329 code0
-[2(VPSRAD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]318 code0
-[2(VPSRLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]307 code0
-[2(VPSRLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]296 code0
-[2(VPSRLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]285 code0
-[2(VPSRLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]274 code0
-[2(VPSRLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]263 code0
-[2(VPSRLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE )]252 code0
-[2(VPTEST xmmreg,xmmrm128 AVX,SANDYBRIDGE )]241 code0
-[2(VPTEST ymmreg,ymmrm256 AVX,SANDYBRIDGE )]230 code0
-[2(VPSUBB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]219 code0
-[2(VPSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]208 code0
-[2(VPSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]197 code0
-[2(VPSUBQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]186 code0
-[2(VPSUBSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]175 code0
-[2(VPSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]164 code0
-[2(VPSUBUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]153 code0
-[2(VPSUBUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]142 code0
-[2(VPUNPCKHBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]131 code0
-[2(VPUNPCKHWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]120 code0
-[2(VPUNPCKHDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]109 code0
-(168)pageeven
-restore showpage
-%%Page: 169 169
-%%BeginPageSetup
-save
-%%EndPageSetup
-/169 pa
-[2(VPUNPCKHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]681 code0
-[2(VPUNPCKLBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]670 code0
-[2(VPUNPCKLWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]659 code0
-[2(VPUNPCKLDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]648 code0
-[2(VPUNPCKLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]637 code0
-[2(VPXOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]626 code0
-[2(VRCPPS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]615 code0
-[2(VRCPPS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]604 code0
-[2(VRCPSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]593 code0
-[2(VRSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]582 code0
-[2(VRSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]571 code0
-[2(VRSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]560 code0
-[2(VROUNDPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]549 code0
-[2(VROUNDPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]538 code0
-[2(VROUNDPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE )]527 code0
-[2(VROUNDPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE )]516 code0
-[2(VROUNDSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE )]505 code0
-[2(VROUNDSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE )]494 code0
-[2(VSHUFPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]483 code0
-[2(VSHUFPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]472 code0
-[2(VSHUFPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE )]461 code0
-[2(VSHUFPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE )]450 code0
-[2(VSQRTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE )]439 code0
-[2(VSQRTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE )]428 code0
-[2(VSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]417 code0
-[2(VSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]406 code0
-[2(VSQRTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]395 code0
-[2(VSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]384 code0
-[2(VSTMXCSR mem32 AVX,SANDYBRIDGE )]373 code0
-[2(VSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]362 code0
-[2(VSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]351 code0
-[2(VSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]340 code0
-[2(VSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]329 code0
-[2(VSUBSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE )]318 code0
-[2(VSUBSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE )]307 code0
-[2(VTESTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE )]296 code0
-[2(VTESTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE )]285 code0
-[2(VTESTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE )]274 code0
-[2(VTESTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE )]263 code0
-[2(VUCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE )]252 code0
-[2(VUCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE )]241 code0
-[2(VUNPCKHPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]230 code0
-[2(VUNPCKHPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]219 code0
-[2(VUNPCKHPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]208 code0
-[2(VUNPCKHPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]197 code0
-[2(VUNPCKLPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]186 code0
-[2(VUNPCKLPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]175 code0
-[2(VUNPCKLPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]164 code0
-[2(VUNPCKLPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]153 code0
-[2(VXORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]142 code0
-[2(VXORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]131 code0
-[2(VXORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]120 code0
-[2(VXORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE )]109 code0
-(169)pageodd
-restore showpage
-%%Page: 170 170
-%%BeginPageSetup
-save
-%%EndPageSetup
-/170 pa
-[2(VZEROALL AVX,SANDYBRIDGE )]681 code0
-[2(VZEROUPPER AVX,SANDYBRIDGE)]670 code2
-[{/section-B.1.26 xa}(Intel Carry-Less Multiplication instructions \(CLMUL\))](B.1.26)650.8 subh3
-[2(PCLMULLQLQDQ xmmreg,xmmrm128 SSE,WESTMERE )]633.8 code1
-[2(PCLMULHQLQDQ xmmreg,xmmrm128 SSE,WESTMERE )]622.8 code0
-[2(PCLMULLQHQDQ xmmreg,xmmrm128 SSE,WESTMERE )]611.8 code0
-[2(PCLMULHQHQDQ xmmreg,xmmrm128 SSE,WESTMERE )]600.8 code0
-[2(PCLMULQDQ xmmreg,xmmrm128,imm8 SSE,WESTMERE)]589.8 code2
-[{/section-B.1.27 xa}(Intel AVX Carry-Less Multiplication instructions \(CLMUL\))](B.1.27)570.6 subh3
-[2(VPCLMULLQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]553.6 code1
-[2(VPCLMULHQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]542.6 code0
-[2(VPCLMULLQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]531.6 code0
-[2(VPCLMULHQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE )]520.6 code0
-[2(VPCLMULQDQ xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE)]509.6 code2
-[{/section-B.1.28 xa}(Intel Fused Multiply-Add instructions \(FMA\))](B.1.28)490.4 subh3
-[2(VFMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]473.4 code1
-[2(VFMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]462.4 code0
-[2(VFMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]451.4 code0
-[2(VFMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]440.4 code0
-[2(VFMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]429.4 code0
-[2(VFMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]418.4 code0
-[2(VFMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]407.4 code0
-[2(VFMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]396.4 code0
-[2(VFMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]385.4 code0
-[2(VFMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]374.4 code0
-[2(VFMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]363.4 code0
-[2(VFMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]352.4 code0
-[2(VFMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]341.4 code0
-[2(VFMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]330.4 code0
-[2(VFMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]319.4 code0
-[2(VFMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]308.4 code0
-[2(VFMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]297.4 code0
-[2(VFMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]286.4 code0
-[2(VFMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]275.4 code0
-[2(VFMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]264.4 code0
-[2(VFMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]253.4 code0
-[2(VFMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]242.4 code0
-[2(VFMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]231.4 code0
-[2(VFMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]220.4 code0
-[2(VFMADDSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]209.4 code0
-[2(VFMADDSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]198.4 code0
-[2(VFMADDSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]187.4 code0
-[2(VFMADDSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]176.4 code0
-[2(VFMADDSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]165.4 code0
-[2(VFMADDSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]154.4 code0
-[2(VFMADDSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]143.4 code0
-[2(VFMADDSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]132.4 code0
-[2(VFMADDSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]121.4 code0
-[2(VFMADDSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]110.4 code0
-(170)pageeven
-restore showpage
-%%Page: 171 171
-%%BeginPageSetup
-save
-%%EndPageSetup
-/171 pa
-[2(VFMADDSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]681 code0
-[2(VFMADDSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]670 code0
-[2(VFMADDSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]659 code0
-[2(VFMADDSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]648 code0
-[2(VFMADDSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]637 code0
-[2(VFMADDSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]626 code0
-[2(VFMADDSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]615 code0
-[2(VFMADDSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]604 code0
-[2(VFMADDSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]593 code0
-[2(VFMADDSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]582 code0
-[2(VFMADDSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]571 code0
-[2(VFMADDSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]560 code0
-[2(VFMADDSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]549 code0
-[2(VFMADDSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]538 code0
-[2(VFMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]527 code0
-[2(VFMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]516 code0
-[2(VFMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]505 code0
-[2(VFMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]494 code0
-[2(VFMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]483 code0
-[2(VFMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]472 code0
-[2(VFMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]461 code0
-[2(VFMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]450 code0
-[2(VFMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]439 code0
-[2(VFMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]428 code0
-[2(VFMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]417 code0
-[2(VFMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]406 code0
-[2(VFMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]395 code0
-[2(VFMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]384 code0
-[2(VFMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]373 code0
-[2(VFMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]362 code0
-[2(VFMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]351 code0
-[2(VFMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]340 code0
-[2(VFMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]329 code0
-[2(VFMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]318 code0
-[2(VFMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]307 code0
-[2(VFMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]296 code0
-[2(VFMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]285 code0
-[2(VFMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]274 code0
-[2(VFMSUBADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]263 code0
-[2(VFMSUBADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]252 code0
-[2(VFMSUBADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]241 code0
-[2(VFMSUBADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]230 code0
-[2(VFMSUBADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]219 code0
-[2(VFMSUBADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]208 code0
-[2(VFMSUBADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]197 code0
-[2(VFMSUBADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]186 code0
-[2(VFMSUBADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]175 code0
-[2(VFMSUBADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]164 code0
-[2(VFMSUBADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]153 code0
-[2(VFMSUBADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]142 code0
-[2(VFMSUBADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]131 code0
-[2(VFMSUBADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]120 code0
-[2(VFMSUBADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]109 code0
-(171)pageodd
-restore showpage
-%%Page: 172 172
-%%BeginPageSetup
-save
-%%EndPageSetup
-/172 pa
-[2(VFMSUBADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]681 code0
-[2(VFMSUBADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]670 code0
-[2(VFMSUBADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]659 code0
-[2(VFMSUBADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]648 code0
-[2(VFMSUBADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]637 code0
-[2(VFMSUBADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]626 code0
-[2(VFMSUBADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]615 code0
-[2(VFMSUBADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]604 code0
-[2(VFMSUBADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]593 code0
-[2(VFNMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]582 code0
-[2(VFNMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]571 code0
-[2(VFNMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]560 code0
-[2(VFNMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]549 code0
-[2(VFNMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]538 code0
-[2(VFNMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]527 code0
-[2(VFNMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]516 code0
-[2(VFNMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]505 code0
-[2(VFNMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]494 code0
-[2(VFNMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]483 code0
-[2(VFNMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]472 code0
-[2(VFNMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]461 code0
-[2(VFNMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]450 code0
-[2(VFNMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]439 code0
-[2(VFNMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]428 code0
-[2(VFNMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]417 code0
-[2(VFNMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]406 code0
-[2(VFNMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]395 code0
-[2(VFNMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]384 code0
-[2(VFNMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]373 code0
-[2(VFNMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]362 code0
-[2(VFNMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]351 code0
-[2(VFNMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]340 code0
-[2(VFNMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]329 code0
-[2(VFNMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]318 code0
-[2(VFNMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]307 code0
-[2(VFNMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]296 code0
-[2(VFNMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]285 code0
-[2(VFNMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]274 code0
-[2(VFNMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]263 code0
-[2(VFNMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]252 code0
-[2(VFNMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]241 code0
-[2(VFNMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]230 code0
-[2(VFNMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]219 code0
-[2(VFNMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]208 code0
-[2(VFNMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]197 code0
-[2(VFNMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]186 code0
-[2(VFNMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]175 code0
-[2(VFNMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]164 code0
-[2(VFNMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]153 code0
-[2(VFNMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]142 code0
-[2(VFNMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]131 code0
-[2(VFNMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]120 code0
-[2(VFNMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]109 code0
-(172)pageeven
-restore showpage
-%%Page: 173 173
-%%BeginPageSetup
-save
-%%EndPageSetup
-/173 pa
-[2(VFNMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]681 code0
-[2(VFNMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]670 code0
-[2(VFNMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE )]659 code0
-[2(VFNMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE )]648 code0
-[2(VFMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]637 code0
-[2(VFMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]626 code0
-[2(VFMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]615 code0
-[2(VFMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]604 code0
-[2(VFMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]593 code0
-[2(VFMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]582 code0
-[2(VFMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]571 code0
-[2(VFMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]560 code0
-[2(VFMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]549 code0
-[2(VFMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]538 code0
-[2(VFMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]527 code0
-[2(VFMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]516 code0
-[2(VFMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]505 code0
-[2(VFMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]494 code0
-[2(VFMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]483 code0
-[2(VFMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]472 code0
-[2(VFMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]461 code0
-[2(VFMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]450 code0
-[2(VFMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]439 code0
-[2(VFMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]428 code0
-[2(VFMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]417 code0
-[2(VFMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]406 code0
-[2(VFMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]395 code0
-[2(VFMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]384 code0
-[2(VFNMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]373 code0
-[2(VFNMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]362 code0
-[2(VFNMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]351 code0
-[2(VFNMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]340 code0
-[2(VFNMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]329 code0
-[2(VFNMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]318 code0
-[2(VFNMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]307 code0
-[2(VFNMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]296 code0
-[2(VFNMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]285 code0
-[2(VFNMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]274 code0
-[2(VFNMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]263 code0
-[2(VFNMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]252 code0
-[2(VFNMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]241 code0
-[2(VFNMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]230 code0
-[2(VFNMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]219 code0
-[2(VFNMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]208 code0
-[2(VFNMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]197 code0
-[2(VFNMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]186 code0
-[2(VFNMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]175 code0
-[2(VFNMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]164 code0
-[2(VFNMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]153 code0
-[2(VFNMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE )]142 code0
-[2(VFNMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE )]131 code0
-[2(VFNMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE)]120 code2
-(173)pageodd
-restore showpage
-%%Page: 174 174
-%%BeginPageSetup
-save
-%%EndPageSetup
-/174 pa
-[{/section-B.1.29 xa}(VIA \(Centaur\) security instructions)](B.1.29)678.8 subh3
-[2(XSTORE PENT,CYRIX )]661.8 code1
-[2(XCRYPTECB PENT,CYRIX )]650.8 code0
-[2(XCRYPTCBC PENT,CYRIX )]639.8 code0
-[2(XCRYPTCTR PENT,CYRIX )]628.8 code0
-[2(XCRYPTCFB PENT,CYRIX )]617.8 code0
-[2(XCRYPTOFB PENT,CYRIX )]606.8 code0
-[2(MONTMUL PENT,CYRIX )]595.8 code0
-[2(XSHA1 PENT,CYRIX )]584.8 code0
-[2(XSHA256 PENT,CYRIX)]573.8 code2
-[{/section-B.1.30 xa}(AMD Lightweight Profiling \(LWP\) instructions)](B.1.30)554.6 subh3
-[2(LLWPCB reg16 AMD )]537.6 code1
-[2(LLWPCB reg32 AMD,386 )]526.6 code0
-[2(LLWPCB reg64 AMD,X64 )]515.6 code0
-[2(SLWPCB reg16 AMD )]504.6 code0
-[2(SLWPCB reg32 AMD,386 )]493.6 code0
-[2(SLWPCB reg64 AMD,X64 )]482.6 code0
-[2(LWPVAL reg16,rm32,imm16 AMD,386 )]471.6 code0
-[2(LWPVAL reg32,rm32,imm32 AMD,386 )]460.6 code0
-[2(LWPVAL reg64,rm32,imm32 AMD,X64 )]449.6 code0
-[2(LWPINS reg16,rm32,imm16 AMD,386 )]438.6 code0
-[2(LWPINS reg32,rm32,imm32 AMD,386 )]427.6 code0
-[2(LWPINS reg64,rm32,imm32 AMD,X64)]416.6 code2
-[{/section-B.1.31 xa}(AMD XOP, FMA4 and CVT16 instructions \(SSE5\))](B.1.31)397.4 subh3
-[2(VCVTPH2PS xmmreg,xmmrm64*,imm8 AMD,SSE5 )]380.4 code1
-[2(VCVTPH2PS ymmreg,xmmrm128,imm8 AMD,SSE5 )]369.4 code0
-[2(VCVTPH2PS ymmreg,ymmrm128*,imm8 AMD,SSE5 )]358.4 code0
-[2(VCVTPS2PH xmmrm64,xmmreg*,imm8 AMD,SSE5 )]347.4 code0
-[2(VCVTPS2PH xmmrm128,ymmreg,imm8 AMD,SSE5 )]336.4 code0
-[2(VCVTPS2PH ymmrm128,ymmreg*,imm8 AMD,SSE5 )]325.4 code0
-[2(VFMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]314.4 code0
-[2(VFMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]303.4 code0
-[2(VFMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]292.4 code0
-[2(VFMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]281.4 code0
-[2(VFMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]270.4 code0
-[2(VFMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]259.4 code0
-[2(VFMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]248.4 code0
-[2(VFMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]237.4 code0
-[2(VFMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5 )]226.4 code0
-[2(VFMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5 )]215.4 code0
-[2(VFMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5 )]204.4 code0
-[2(VFMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5 )]193.4 code0
-[2(VFMADDSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]182.4 code0
-[2(VFMADDSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]171.4 code0
-[2(VFMADDSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]160.4 code0
-[2(VFMADDSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]149.4 code0
-[2(VFMADDSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]138.4 code0
-[2(VFMADDSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]127.4 code0
-[2(VFMADDSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]116.4 code0
-[2(VFMADDSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]105.4 code0
-(174)pageeven
-restore showpage
-%%Page: 175 175
-%%BeginPageSetup
-save
-%%EndPageSetup
-/175 pa
-[2(VFMSUBADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]681 code0
-[2(VFMSUBADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]670 code0
-[2(VFMSUBADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]659 code0
-[2(VFMSUBADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]648 code0
-[2(VFMSUBADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]637 code0
-[2(VFMSUBADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]626 code0
-[2(VFMSUBADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]615 code0
-[2(VFMSUBADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]604 code0
-[2(VFMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]593 code0
-[2(VFMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]582 code0
-[2(VFMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]571 code0
-[2(VFMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]560 code0
-[2(VFMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]549 code0
-[2(VFMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]538 code0
-[2(VFMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]527 code0
-[2(VFMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]516 code0
-[2(VFMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5 )]505 code0
-[2(VFMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5 )]494 code0
-[2(VFMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5 )]483 code0
-[2(VFMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5 )]472 code0
-[2(VFNMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]461 code0
-[2(VFNMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]450 code0
-[2(VFNMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]439 code0
-[2(VFNMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]428 code0
-[2(VFNMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]417 code0
-[2(VFNMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]406 code0
-[2(VFNMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]395 code0
-[2(VFNMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]384 code0
-[2(VFNMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5 )]373 code0
-[2(VFNMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5 )]362 code0
-[2(VFNMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5 )]351 code0
-[2(VFNMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5 )]340 code0
-[2(VFNMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]329 code0
-[2(VFNMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]318 code0
-[2(VFNMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]307 code0
-[2(VFNMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]296 code0
-[2(VFNMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]285 code0
-[2(VFNMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]274 code0
-[2(VFNMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]263 code0
-[2(VFNMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]252 code0
-[2(VFNMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5 )]241 code0
-[2(VFNMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5 )]230 code0
-[2(VFNMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5 )]219 code0
-[2(VFNMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5 )]208 code0
-[2(VFRCZPD xmmreg,xmmrm128* AMD,SSE5 )]197 code0
-[2(VFRCZPD ymmreg,ymmrm256* AMD,SSE5 )]186 code0
-[2(VFRCZPS xmmreg,xmmrm128* AMD,SSE5 )]175 code0
-[2(VFRCZPS ymmreg,ymmrm256* AMD,SSE5 )]164 code0
-[2(VFRCZSD xmmreg,xmmrm64* AMD,SSE5 )]153 code0
-[2(VFRCZSS xmmreg,xmmrm32* AMD,SSE5 )]142 code0
-[2(VPCMOV xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]131 code0
-[2(VPCMOV ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5 )]120 code0
-[2(VPCMOV xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]109 code0
-(175)pageodd
-restore showpage
-%%Page: 176 176
-%%BeginPageSetup
-save
-%%EndPageSetup
-/176 pa
-[2(VPCMOV ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5 )]681 code0
-[2(VPCOMB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]670 code0
-[2(VPCOMD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]659 code0
-[2(VPCOMQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]648 code0
-[2(VPCOMUB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]637 code0
-[2(VPCOMUD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]626 code0
-[2(VPCOMUQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]615 code0
-[2(VPCOMUW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]604 code0
-[2(VPCOMW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5 )]593 code0
-[2(VPHADDBD xmmreg,xmmrm128* AMD,SSE5 )]582 code0
-[2(VPHADDBQ xmmreg,xmmrm128* AMD,SSE5 )]571 code0
-[2(VPHADDBW xmmreg,xmmrm128* AMD,SSE5 )]560 code0
-[2(VPHADDDQ xmmreg,xmmrm128* AMD,SSE5 )]549 code0
-[2(VPHADDUBD xmmreg,xmmrm128* AMD,SSE5 )]538 code0
-[2(VPHADDUBQ xmmreg,xmmrm128* AMD,SSE5 )]527 code0
-[2(VPHADDUBW xmmreg,xmmrm128* AMD,SSE5 )]516 code0
-[2(VPHADDUDQ xmmreg,xmmrm128* AMD,SSE5 )]505 code0
-[2(VPHADDUWD xmmreg,xmmrm128* AMD,SSE5 )]494 code0
-[2(VPHADDUWQ xmmreg,xmmrm128* AMD,SSE5 )]483 code0
-[2(VPHADDWD xmmreg,xmmrm128* AMD,SSE5 )]472 code0
-[2(VPHADDWQ xmmreg,xmmrm128* AMD,SSE5 )]461 code0
-[2(VPHSUBBW xmmreg,xmmrm128* AMD,SSE5 )]450 code0
-[2(VPHSUBDQ xmmreg,xmmrm128* AMD,SSE5 )]439 code0
-[2(VPHSUBWD xmmreg,xmmrm128* AMD,SSE5 )]428 code0
-[2(VPMACSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]417 code0
-[2(VPMACSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]406 code0
-[2(VPMACSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]395 code0
-[2(VPMACSSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]384 code0
-[2(VPMACSSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]373 code0
-[2(VPMACSSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]362 code0
-[2(VPMACSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]351 code0
-[2(VPMACSSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]340 code0
-[2(VPMACSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]329 code0
-[2(VPMACSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]318 code0
-[2(VPMADCSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]307 code0
-[2(VPMADCSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]296 code0
-[2(VPPERM xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5 )]285 code0
-[2(VPPERM xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5 )]274 code0
-[2(VPROTB xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]263 code0
-[2(VPROTB xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]252 code0
-[2(VPROTB xmmreg,xmmrm128*,imm8 AMD,SSE5 )]241 code0
-[2(VPROTD xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]230 code0
-[2(VPROTD xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]219 code0
-[2(VPROTD xmmreg,xmmrm128*,imm8 AMD,SSE5 )]208 code0
-[2(VPROTQ xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]197 code0
-[2(VPROTQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]186 code0
-[2(VPROTQ xmmreg,xmmrm128*,imm8 AMD,SSE5 )]175 code0
-[2(VPROTW xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]164 code0
-[2(VPROTW xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]153 code0
-[2(VPROTW xmmreg,xmmrm128*,imm8 AMD,SSE5 )]142 code0
-[2(VPSHAB xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]131 code0
-[2(VPSHAB xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]120 code0
-[2(VPSHAD xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]109 code0
-(176)pageeven
-restore showpage
-%%Page: 177 177
-%%BeginPageSetup
-save
-%%EndPageSetup
-/177 pa
-[2(VPSHAD xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]681 code0
-[2(VPSHAQ xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]670 code0
-[2(VPSHAQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]659 code0
-[2(VPSHAW xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]648 code0
-[2(VPSHAW xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]637 code0
-[2(VPSHLB xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]626 code0
-[2(VPSHLB xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]615 code0
-[2(VPSHLD xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]604 code0
-[2(VPSHLD xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]593 code0
-[2(VPSHLQ xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]582 code0
-[2(VPSHLQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5 )]571 code0
-[2(VPSHLW xmmreg,xmmrm128*,xmmreg AMD,SSE5 )]560 code0
-[2(VPSHLW xmmreg,xmmreg*,xmmrm128 AMD,SSE5)]549 code2
-[{/section-B.1.32 xa}(Systematic names for the hinting nop instructions)](B.1.32)529.8 subh3
-[2(HINT_NOP0 rm16 P6,UNDOC )]512.8 code1
-[2(HINT_NOP0 rm32 P6,UNDOC )]501.8 code0
-[2(HINT_NOP0 rm64 X64,UNDOC )]490.8 code0
-[2(HINT_NOP1 rm16 P6,UNDOC )]479.8 code0
-[2(HINT_NOP1 rm32 P6,UNDOC )]468.8 code0
-[2(HINT_NOP1 rm64 X64,UNDOC )]457.8 code0
-[2(HINT_NOP2 rm16 P6,UNDOC )]446.8 code0
-[2(HINT_NOP2 rm32 P6,UNDOC )]435.8 code0
-[2(HINT_NOP2 rm64 X64,UNDOC )]424.8 code0
-[2(HINT_NOP3 rm16 P6,UNDOC )]413.8 code0
-[2(HINT_NOP3 rm32 P6,UNDOC )]402.8 code0
-[2(HINT_NOP3 rm64 X64,UNDOC )]391.8 code0
-[2(HINT_NOP4 rm16 P6,UNDOC )]380.8 code0
-[2(HINT_NOP4 rm32 P6,UNDOC )]369.8 code0
-[2(HINT_NOP4 rm64 X64,UNDOC )]358.8 code0
-[2(HINT_NOP5 rm16 P6,UNDOC )]347.8 code0
-[2(HINT_NOP5 rm32 P6,UNDOC )]336.8 code0
-[2(HINT_NOP5 rm64 X64,UNDOC )]325.8 code0
-[2(HINT_NOP6 rm16 P6,UNDOC )]314.8 code0
-[2(HINT_NOP6 rm32 P6,UNDOC )]303.8 code0
-[2(HINT_NOP6 rm64 X64,UNDOC )]292.8 code0
-[2(HINT_NOP7 rm16 P6,UNDOC )]281.8 code0
-[2(HINT_NOP7 rm32 P6,UNDOC )]270.8 code0
-[2(HINT_NOP7 rm64 X64,UNDOC )]259.8 code0
-[2(HINT_NOP8 rm16 P6,UNDOC )]248.8 code0
-[2(HINT_NOP8 rm32 P6,UNDOC )]237.8 code0
-[2(HINT_NOP8 rm64 X64,UNDOC )]226.8 code0
-[2(HINT_NOP9 rm16 P6,UNDOC )]215.8 code0
-[2(HINT_NOP9 rm32 P6,UNDOC )]204.8 code0
-[2(HINT_NOP9 rm64 X64,UNDOC )]193.8 code0
-[2(HINT_NOP10 rm16 P6,UNDOC )]182.8 code0
-[2(HINT_NOP10 rm32 P6,UNDOC )]171.8 code0
-[2(HINT_NOP10 rm64 X64,UNDOC )]160.8 code0
-[2(HINT_NOP11 rm16 P6,UNDOC )]149.8 code0
-[2(HINT_NOP11 rm32 P6,UNDOC )]138.8 code0
-[2(HINT_NOP11 rm64 X64,UNDOC )]127.8 code0
-[2(HINT_NOP12 rm16 P6,UNDOC )]116.8 code0
-[2(HINT_NOP12 rm32 P6,UNDOC )]105.8 code0
-(177)pageodd
-restore showpage
-%%Page: 178 178
-%%BeginPageSetup
-save
-%%EndPageSetup
-/178 pa
-[2(HINT_NOP12 rm64 X64,UNDOC )]681 code0
-[2(HINT_NOP13 rm16 P6,UNDOC )]670 code0
-[2(HINT_NOP13 rm32 P6,UNDOC )]659 code0
-[2(HINT_NOP13 rm64 X64,UNDOC )]648 code0
-[2(HINT_NOP14 rm16 P6,UNDOC )]637 code0
-[2(HINT_NOP14 rm32 P6,UNDOC )]626 code0
-[2(HINT_NOP14 rm64 X64,UNDOC )]615 code0
-[2(HINT_NOP15 rm16 P6,UNDOC )]604 code0
-[2(HINT_NOP15 rm32 P6,UNDOC )]593 code0
-[2(HINT_NOP15 rm64 X64,UNDOC )]582 code0
-[2(HINT_NOP16 rm16 P6,UNDOC )]571 code0
-[2(HINT_NOP16 rm32 P6,UNDOC )]560 code0
-[2(HINT_NOP16 rm64 X64,UNDOC )]549 code0
-[2(HINT_NOP17 rm16 P6,UNDOC )]538 code0
-[2(HINT_NOP17 rm32 P6,UNDOC )]527 code0
-[2(HINT_NOP17 rm64 X64,UNDOC )]516 code0
-[2(HINT_NOP18 rm16 P6,UNDOC )]505 code0
-[2(HINT_NOP18 rm32 P6,UNDOC )]494 code0
-[2(HINT_NOP18 rm64 X64,UNDOC )]483 code0
-[2(HINT_NOP19 rm16 P6,UNDOC )]472 code0
-[2(HINT_NOP19 rm32 P6,UNDOC )]461 code0
-[2(HINT_NOP19 rm64 X64,UNDOC )]450 code0
-[2(HINT_NOP20 rm16 P6,UNDOC )]439 code0
-[2(HINT_NOP20 rm32 P6,UNDOC )]428 code0
-[2(HINT_NOP20 rm64 X64,UNDOC )]417 code0
-[2(HINT_NOP21 rm16 P6,UNDOC )]406 code0
-[2(HINT_NOP21 rm32 P6,UNDOC )]395 code0
-[2(HINT_NOP21 rm64 X64,UNDOC )]384 code0
-[2(HINT_NOP22 rm16 P6,UNDOC )]373 code0
-[2(HINT_NOP22 rm32 P6,UNDOC )]362 code0
-[2(HINT_NOP22 rm64 X64,UNDOC )]351 code0
-[2(HINT_NOP23 rm16 P6,UNDOC )]340 code0
-[2(HINT_NOP23 rm32 P6,UNDOC )]329 code0
-[2(HINT_NOP23 rm64 X64,UNDOC )]318 code0
-[2(HINT_NOP24 rm16 P6,UNDOC )]307 code0
-[2(HINT_NOP24 rm32 P6,UNDOC )]296 code0
-[2(HINT_NOP24 rm64 X64,UNDOC )]285 code0
-[2(HINT_NOP25 rm16 P6,UNDOC )]274 code0
-[2(HINT_NOP25 rm32 P6,UNDOC )]263 code0
-[2(HINT_NOP25 rm64 X64,UNDOC )]252 code0
-[2(HINT_NOP26 rm16 P6,UNDOC )]241 code0
-[2(HINT_NOP26 rm32 P6,UNDOC )]230 code0
-[2(HINT_NOP26 rm64 X64,UNDOC )]219 code0
-[2(HINT_NOP27 rm16 P6,UNDOC )]208 code0
-[2(HINT_NOP27 rm32 P6,UNDOC )]197 code0
-[2(HINT_NOP27 rm64 X64,UNDOC )]186 code0
-[2(HINT_NOP28 rm16 P6,UNDOC )]175 code0
-[2(HINT_NOP28 rm32 P6,UNDOC )]164 code0
-[2(HINT_NOP28 rm64 X64,UNDOC )]153 code0
-[2(HINT_NOP29 rm16 P6,UNDOC )]142 code0
-[2(HINT_NOP29 rm32 P6,UNDOC )]131 code0
-[2(HINT_NOP29 rm64 X64,UNDOC )]120 code0
-[2(HINT_NOP30 rm16 P6,UNDOC )]109 code0
-(178)pageeven
-restore showpage
-%%Page: 179 179
-%%BeginPageSetup
-save
-%%EndPageSetup
-/179 pa
-[2(HINT_NOP30 rm32 P6,UNDOC )]681 code0
-[2(HINT_NOP30 rm64 X64,UNDOC )]670 code0
-[2(HINT_NOP31 rm16 P6,UNDOC )]659 code0
-[2(HINT_NOP31 rm32 P6,UNDOC )]648 code0
-[2(HINT_NOP31 rm64 X64,UNDOC )]637 code0
-[2(HINT_NOP32 rm16 P6,UNDOC )]626 code0
-[2(HINT_NOP32 rm32 P6,UNDOC )]615 code0
-[2(HINT_NOP32 rm64 X64,UNDOC )]604 code0
-[2(HINT_NOP33 rm16 P6,UNDOC )]593 code0
-[2(HINT_NOP33 rm32 P6,UNDOC )]582 code0
-[2(HINT_NOP33 rm64 X64,UNDOC )]571 code0
-[2(HINT_NOP34 rm16 P6,UNDOC )]560 code0
-[2(HINT_NOP34 rm32 P6,UNDOC )]549 code0
-[2(HINT_NOP34 rm64 X64,UNDOC )]538 code0
-[2(HINT_NOP35 rm16 P6,UNDOC )]527 code0
-[2(HINT_NOP35 rm32 P6,UNDOC )]516 code0
-[2(HINT_NOP35 rm64 X64,UNDOC )]505 code0
-[2(HINT_NOP36 rm16 P6,UNDOC )]494 code0
-[2(HINT_NOP36 rm32 P6,UNDOC )]483 code0
-[2(HINT_NOP36 rm64 X64,UNDOC )]472 code0
-[2(HINT_NOP37 rm16 P6,UNDOC )]461 code0
-[2(HINT_NOP37 rm32 P6,UNDOC )]450 code0
-[2(HINT_NOP37 rm64 X64,UNDOC )]439 code0
-[2(HINT_NOP38 rm16 P6,UNDOC )]428 code0
-[2(HINT_NOP38 rm32 P6,UNDOC )]417 code0
-[2(HINT_NOP38 rm64 X64,UNDOC )]406 code0
-[2(HINT_NOP39 rm16 P6,UNDOC )]395 code0
-[2(HINT_NOP39 rm32 P6,UNDOC )]384 code0
-[2(HINT_NOP39 rm64 X64,UNDOC )]373 code0
-[2(HINT_NOP40 rm16 P6,UNDOC )]362 code0
-[2(HINT_NOP40 rm32 P6,UNDOC )]351 code0
-[2(HINT_NOP40 rm64 X64,UNDOC )]340 code0
-[2(HINT_NOP41 rm16 P6,UNDOC )]329 code0
-[2(HINT_NOP41 rm32 P6,UNDOC )]318 code0
-[2(HINT_NOP41 rm64 X64,UNDOC )]307 code0
-[2(HINT_NOP42 rm16 P6,UNDOC )]296 code0
-[2(HINT_NOP42 rm32 P6,UNDOC )]285 code0
-[2(HINT_NOP42 rm64 X64,UNDOC )]274 code0
-[2(HINT_NOP43 rm16 P6,UNDOC )]263 code0
-[2(HINT_NOP43 rm32 P6,UNDOC )]252 code0
-[2(HINT_NOP43 rm64 X64,UNDOC )]241 code0
-[2(HINT_NOP44 rm16 P6,UNDOC )]230 code0
-[2(HINT_NOP44 rm32 P6,UNDOC )]219 code0
-[2(HINT_NOP44 rm64 X64,UNDOC )]208 code0
-[2(HINT_NOP45 rm16 P6,UNDOC )]197 code0
-[2(HINT_NOP45 rm32 P6,UNDOC )]186 code0
-[2(HINT_NOP45 rm64 X64,UNDOC )]175 code0
-[2(HINT_NOP46 rm16 P6,UNDOC )]164 code0
-[2(HINT_NOP46 rm32 P6,UNDOC )]153 code0
-[2(HINT_NOP46 rm64 X64,UNDOC )]142 code0
-[2(HINT_NOP47 rm16 P6,UNDOC )]131 code0
-[2(HINT_NOP47 rm32 P6,UNDOC )]120 code0
-[2(HINT_NOP47 rm64 X64,UNDOC )]109 code0
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-[2(HINT_NOP48 rm16 P6,UNDOC )]681 code0
-[2(HINT_NOP48 rm32 P6,UNDOC )]670 code0
-[2(HINT_NOP48 rm64 X64,UNDOC )]659 code0
-[2(HINT_NOP49 rm16 P6,UNDOC )]648 code0
-[2(HINT_NOP49 rm32 P6,UNDOC )]637 code0
-[2(HINT_NOP49 rm64 X64,UNDOC )]626 code0
-[2(HINT_NOP50 rm16 P6,UNDOC )]615 code0
-[2(HINT_NOP50 rm32 P6,UNDOC )]604 code0
-[2(HINT_NOP50 rm64 X64,UNDOC )]593 code0
-[2(HINT_NOP51 rm16 P6,UNDOC )]582 code0
-[2(HINT_NOP51 rm32 P6,UNDOC )]571 code0
-[2(HINT_NOP51 rm64 X64,UNDOC )]560 code0
-[2(HINT_NOP52 rm16 P6,UNDOC )]549 code0
-[2(HINT_NOP52 rm32 P6,UNDOC )]538 code0
-[2(HINT_NOP52 rm64 X64,UNDOC )]527 code0
-[2(HINT_NOP53 rm16 P6,UNDOC )]516 code0
-[2(HINT_NOP53 rm32 P6,UNDOC )]505 code0
-[2(HINT_NOP53 rm64 X64,UNDOC )]494 code0
-[2(HINT_NOP54 rm16 P6,UNDOC )]483 code0
-[2(HINT_NOP54 rm32 P6,UNDOC )]472 code0
-[2(HINT_NOP54 rm64 X64,UNDOC )]461 code0
-[2(HINT_NOP55 rm16 P6,UNDOC )]450 code0
-[2(HINT_NOP55 rm32 P6,UNDOC )]439 code0
-[2(HINT_NOP55 rm64 X64,UNDOC )]428 code0
-[2(HINT_NOP56 rm16 P6,UNDOC )]417 code0
-[2(HINT_NOP56 rm32 P6,UNDOC )]406 code0
-[2(HINT_NOP56 rm64 X64,UNDOC )]395 code0
-[2(HINT_NOP57 rm16 P6,UNDOC )]384 code0
-[2(HINT_NOP57 rm32 P6,UNDOC )]373 code0
-[2(HINT_NOP57 rm64 X64,UNDOC )]362 code0
-[2(HINT_NOP58 rm16 P6,UNDOC )]351 code0
-[2(HINT_NOP58 rm32 P6,UNDOC )]340 code0
-[2(HINT_NOP58 rm64 X64,UNDOC )]329 code0
-[2(HINT_NOP59 rm16 P6,UNDOC )]318 code0
-[2(HINT_NOP59 rm32 P6,UNDOC )]307 code0
-[2(HINT_NOP59 rm64 X64,UNDOC )]296 code0
-[2(HINT_NOP60 rm16 P6,UNDOC )]285 code0
-[2(HINT_NOP60 rm32 P6,UNDOC )]274 code0
-[2(HINT_NOP60 rm64 X64,UNDOC )]263 code0
-[2(HINT_NOP61 rm16 P6,UNDOC )]252 code0
-[2(HINT_NOP61 rm32 P6,UNDOC )]241 code0
-[2(HINT_NOP61 rm64 X64,UNDOC )]230 code0
-[2(HINT_NOP62 rm16 P6,UNDOC )]219 code0
-[2(HINT_NOP62 rm32 P6,UNDOC )]208 code0
-[2(HINT_NOP62 rm64 X64,UNDOC )]197 code0
-[2(HINT_NOP63 rm16 P6,UNDOC )]186 code0
-[2(HINT_NOP63 rm32 P6,UNDOC )]175 code0
-[2(HINT_NOP63 rm64 X64,UNDOC)]164 code2
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-[{/appendix-C xa}(Appendix C: )(NASM Version History)]642.8 appn3
-[{/section-C.1 xa}(NASM 2 Series)](C.1)597.4 head3
-[(The NASM 2 series support x86-64, and is the production version of NASM since 2007.)]580.4 norm3
-[{/section-C.1.1 xa}(Version 2.08)](C.1.1)561.2 subh3
-[(A number of enhancements/fixes in macros area.)]544.2 bull3
-[(Support for arbitrarily terminating macro expansions )2(%exitmacro)0(. See ){/section-4.3.12 xl}(section 4.3.12){el}(.)]527.2 bull3
-[(Support for recursive macro expansion )2(%rmacro/irmacro)0(. See ){/section-4.3.1 xl}(section 4.3.1){el}(.)]510.2 bull3
-[(Support for converting strings to tokens. See ){/section-4.1.9 xl}(section 4.1.9){el}(.)]493.2 bull3
-[(Fuzzy operand size logic introduced.)]476.2 bull3
-[(Fix COFF stack overrun on too long export identifiers.)]459.2 bull3
-[(Fix Macho-O alignment bug.)]442.2 bull3
-[(Fix crashes with \226fwin32 on file with many exports.)]425.2 bull3
-[(Fix stack overrun for too long [DEBUG id].)]408.2 bull3
-[(Fix incorrect sbyte usage in IMUL \(hit only if optimization flag passed\).)]391.2 bull3
-[(Append ending token for )2(.stabs)0( records in the ELF output format.)]374.2 bull3
-[(New NSIS script which uses ModernUI and MultiUser approach.)]357.2 bull3
-[(Visual Studio 2008 NASM integration \(rules file\).)]340.2 bull3
-[(Warn a user if a constant is too long \(and as result will be stripped\).)]323.2 bull3
-[(The obsoleted pre-XOP AMD SSE5 instruction set which was never actualized was removed.)]306.2 bull3
-[(Fix stack overrun on too long error file name passed from the command line.)]289.2 bull3
-[(Bind symbols to the .text section by default \(ie in case if SECTION directive was omitted\) in the ELF)]272.2 bull1
-[(output format.)]261.2 bull2
-[(Fix sync points array index wrapping.)]244.2 bull3
-[(A few fixes for FMA4 and XOP instruction templates.)]227.2 bull3
-[(Add AMD Lightweight Profiling \(LWP\) instructions.)]210.2 bull3
-[{/section-C.1.2 xa}(Version 2.07)](C.1.2)191 subh3
-[(NASM is now under the 2-clause BSD license. See ){/section-1.1.2 xl}(section 1.1.2){el}(.)]174 bull3
-[(Fix the section type for the )2(.strtab)0( section in the )2(elf64)0( output format.)]157 bull3
-[(Fix the handling of )2(COMMON)0( directives in the )2(obj)0( output format.)]140 bull3
-[(New )2(ith)0( and )2(srec)0( output formats; these are variants of the )2(bin)0( output format which output Intel hex)]123 bull1
-[(and Motorola S-records, respectively. See ){/section-7.2 xl}(section 7.2){el}( and ){/section-7.3 xl}(section 7.3){el}(.)]112 bull2
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-[2(rdf2ihx)0( replaced with an enhanced )2(rdf2bin)0(, which can output binary, COM, Intel hex or Motorola)]681 bull1
-[(S-records.)]670 bull2
-[(The Windows installer now puts the NASM directory first in the )2(PATH)0( of the "NASM Shell".)]653 bull3
-[(Revert the early expansion behavior of )2(%+)0( to pre-2.06 behavior: )2(%+)0( is only expanded late.)]636 bull3
-[(Yet another Mach-O alignment fix.)]619 bull3
-[(Don't delete the list file on errors. Also, include error and warning information in the list file.)]602 bull3
-[(Support for 64-bit Mach-O output, see ){/section-7.8 xl}(section 7.8){el}(.)]585 bull3
-[(Fix assert failure on certain operations that involve strings with high-bit bytes.)]568 bull3
-[{/section-C.1.3 xa}(Version 2.06)](C.1.3)548.8 subh3
-[(This release is dedicated to the memory of Charles A. Crayne, long time NASM developer as well as)]531.8 bull1
-[(moderator of )2(comp.lang.asm.x86)0( and author of the book )1(Serious Assembler)0(. We miss you, Chuck.)]520.8 bull2
-[(Support for indirect macro expansion \()2(%[...])0(\). See ){/section-4.1.3 xl}(section 4.1.3){el}(.)]503.8 bull3
-[2(%pop)0( can now take an argument, see ){/section-4.7.1 xl}(section 4.7.1){el}(.)]486.8 bull3
-[(The argument to )2(%use)0( is no longer macro-expanded. Use )2(%[...])0( if macro expansion is desired.)]469.8 bull3
-[(Support for thread-local storage in ELF32 and ELF64. See ){/section-7.9.4 xl}(section 7.9.4){el}(.)]452.8 bull3
-[(Fix crash on )2(%ifmacro)0( without an argument.)]435.8 bull3
-[(Correct the arguments to the )2(POPCNT)0( instruction.)]418.8 bull3
-[(Fix section alignment in the Mach-O format.)]401.8 bull3
-[(Update AVX support to version 5 of the Intel specification.)]384.8 bull3
-[(Fix the handling of accesses to context-local macros from higher levels in the context stack.)]367.8 bull3
-[(Treat )2(WAIT)0( as a prefix rather than as an instruction, thereby allowing constructs like )2(O16 FSAVE)0( to work)]350.8 bull1
-[(correctly.)]339.8 bull2
-[(Support for structures with a non-zero base offset. See ){/section-4.11.10 xl}(section 4.11.10){el}(.)]322.8 bull3
-[(Correctly handle preprocessor token concatenation \(see ){/section-4.3.8 xl}(section 4.3.8){el}(\) involving floating-point numbers.)]305.8 bull3
-[(The )2(PINSR)0( series of instructions have been corrected and rationalized.)]288.8 bull3
-[(Removed AMD SSE5, replaced with the new XOP/FMA4/CVT16 \(rev 3.03\) spec.)]271.8 bull3
-[(The ELF backends no longer automatically generate a )2(.comment)0( section.)]254.8 bull3
-[(Add additional "well-known" ELF sections with default attributes. See ){/section-7.9.2 xl}(section 7.9.2){el}(.)]237.8 bull3
-[{/section-C.1.4 xa}(Version 2.05.01)](C.1.4)218.6 subh3
-[(Fix the )2(-w)0(/)2(-W)0( option parsing, which was broken in NASM 2.05.)]201.6 bull3
-[{/section-C.1.5 xa}(Version 2.05)](C.1.5)182.4 subh3
-[(Fix redundant REX.W prefix on )2(JMP reg64)0(.)]165.4 bull3
-[(Make the behaviour of )2(-O0)0( match NASM 0.98 legacy behavior. See ){/section-2.1.22 xl}(section 2.1.22){el}(.)]148.4 bull3
-[2(-w-user)0( can be used to suppress the output of )2(%warning)0( directives. See ){/section-2.1.24 xl}(section 2.1.24){el}(.)]131.4 bull3
-[(Fix bug where )2(ALIGN)0( would issue a full alignment datum instead of zero bytes.)]114.4 bull3
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-[(Fix offsets in list files.)]681 bull3
-[(Fix )2(%include)0( inside multi-line macros or loops.)]664 bull3
-[(Fix error where NASM would generate a spurious warning on valid optimizations of immediate values.)]647 bull3
-[(Fix arguments to a number of the )2(CVT)0( SSE instructions.)]630 bull3
-[(Fix RIP-relative offsets when the instruction carries an immediate.)]613 bull3
-[(Massive overhaul of the ELF64 backend for spec compliance.)]596 bull3
-[(Fix the Geode )2(PFRCPV)0( and )2(PFRSQRTV)0( instruction.)]579 bull3
-[(Fix the SSE 4.2 )2(CRC32)0( instruction.)]562 bull3
-[{/section-C.1.6 xa}(Version 2.04)](C.1.6)542.8 subh3
-[(Sanitize macro handing in the )2(%error)0( directive.)]525.8 bull3
-[(New )2(%warning)0( directive to issue user-controlled warnings.)]508.8 bull3
-[2(%error)0( directives are now deferred to the final assembly phase.)]491.8 bull3
-[(New )2(%fatal)0( directive to immediately terminate assembly.)]474.8 bull3
-[(New )2(%strcat)0( directive to join quoted strings together.)]457.8 bull3
-[(New )2(%use)0( macro directive to support standard macro directives. See ){/section-4.6.4 xl}(section 4.6.4){el}(.)]440.8 bull3
-[(Excess default parameters to )2(%macro)0( now issues a warning by default. See ){/section-4.3 xl}(section 4.3){el}(.)]423.8 bull3
-[(Fix )2(%ifn)0( and )2(%elifn)0(.)]406.8 bull3
-[(Fix nested )2(%else)0( clauses.)]389.8 bull3
-[(Correct the handling of nested )2(%rep)0(s.)]372.8 bull3
-[(New )2(%unmacro)0( directive to undeclare a multi-line macro. See ){/section-4.3.11 xl}(section 4.3.11){el}(.)]355.8 bull3
-[(Builtin macro )2(__PASS__)0( which expands to the current assembly pass. See ){/section-4.11.9 xl}(section 4.11.9){el}(.)]338.8 bull3
-[2(__utf16__)0( and )2(__utf32__)0( operators to generate UTF-16 and UTF-32 strings. See ){/section-3.4.5 xl}(section 3.4.5){el}(.)]321.8 bull3
-[(Fix bug in case-insensitive matching when compiled on platforms that don't use the )2(configure)0( script.)]304.8 bull1
-[(Of the official release binaries, that only affected the OS/2 binary.)]293.8 bull2
-[(Support for x87 packed BCD constants. See ){/section-3.4.7 xl}(section 3.4.7){el}(.)]276.8 bull3
-[(Correct the )2(LTR)0( and )2(SLDT)0( instructions in 64-bit mode.)]259.8 bull3
-[(Fix unnecessary REX.W prefix on indirect jumps in 64-bit mode.)]242.8 bull3
-[(Add AVX versions of the AES instructions \()2(VAES)0(...\).)]225.8 bull3
-[(Fix the 256-bit FMA instructions.)]208.8 bull3
-[(Add 256-bit AVX stores per the latest AVX spec.)]191.8 bull3
-[(VIA XCRYPT instructions can now be written either with or without )2(REP)0(, apparently different versions of)]174.8 bull1
-[(the VIA spec wrote them differently.)]163.8 bull2
-[(Add missing 64-bit )2(MOVNTI)0( instruction.)]146.8 bull3
-[(Fix the operand size of )2(VMREAD)0( and )2(VMWRITE)0(.)]129.8 bull3
-[(Numerous bug fixes, especially to the AES, AVX and VTX instructions.)]112.8 bull3
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-[(The optimizer now always runs until it converges. It also runs even when disabled, but doesn't optimize.)]681 bull1
-[(This allows most forward references to be resolved properly.)]670 bull2
-[2(%push)0( no longer needs a context identifier; omitting the context identifier results in an anonymous context.)]653 bull3
-[{/section-C.1.7 xa}(Version 2.03.01)](C.1.7)633.8 subh3
-[(Fix buffer overflow in the listing module.)]616.8 bull3
-[(Fix the handling of hexadecimal escape codes in `...` strings.)]599.8 bull3
-[(The Postscript/PDF documentation has been reformatted.)]582.8 bull3
-[(The )2(-F)0( option now implies )2(-g)0(.)]565.8 bull3
-[{/section-C.1.8 xa}(Version 2.03)](C.1.8)546.6 subh3
-[(Add support for Intel AVX, CLMUL and FMA instructions, including YMM registers.)]529.6 bull3
-[2(dy)0(, )2(resy)0( and )2(yword)0( for 32-byte operands.)]512.6 bull3
-[(Fix some SSE5 instructions.)]495.6 bull3
-[(Intel )2(INVEPT)0(, )2(INVVPID)0( and )2(MOVBE)0( instructions.)]478.6 bull3
-[(Fix checking for critical expressions when the optimizer is enabled.)]461.6 bull3
-[(Support the DWARF debugging format for ELF targets.)]444.6 bull3
-[(Fix optimizations of signed bytes.)]427.6 bull3
-[(Fix operation on bigendian machines.)]410.6 bull3
-[(Fix buffer overflow in the preprocessor.)]393.6 bull3
-[2(SAFESEH)0( support for Win32, )2(IMAGEREL)0( for Win64 \(SEH\).)]376.6 bull3
-[2(%?)0( and )2(%??)0( to refer to the name of a macro itself. In particular, )2(%idefine keyword $%?)0( can be used)]359.6 bull1
-[(to make a keyword "disappear".)]348.6 bull2
-[(New options for dependency generation: )2(-MD)0(, )2(-MF)0(, )2(-MP)0(, )2(-MT)0(, )2(-MQ)0(.)]331.6 bull3
-[(New preprocessor directives )2(%pathsearch)0( and )2(%depend)0(; INCBIN reimplemented as a macro.)]314.6 bull3
-[2(%include)0( now resolves macros in a sane manner.)]297.6 bull3
-[2(%substr)0( can now be used to get other than one-character substrings.)]280.6 bull3
-[(New type of character/string constants, using backquotes \()2(`...`)0(\), which support C-style escape)]263.6 bull1
-[(sequences.)]252.6 bull2
-[2(%defstr)0( and )2(%idefstr)0( to stringize macro definitions before creation.)]235.6 bull3
-[(Fix forward references used in )2(EQU)0( statements.)]218.6 bull3
-[{/section-C.1.9 xa}(Version 2.02)](C.1.9)199.4 subh3
-[(Additional fixes for MMX operands with explicit )2(qword)0(, as well as \(hopefully\) SSE operands with)]182.4 bull1
-[2(oword)0(.)]171.4 bull2
-[(Fix handling of truncated strings with )2(DO)0(.)]154.4 bull3
-[(Fix segfaults due to memory overwrites when floating-point constants were used.)]137.4 bull3
-[(Fix segfaults due to missing include files.)]120.4 bull3
-[(Fix OpenWatcom Makefiles for DOS and OS/2.)]103.4 bull3
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-[(Add autogenerated instruction list back into the documentation.)]681 bull3
-[(ELF: Fix segfault when generating stabs, and no symbols have been defined.)]664 bull3
-[(ELF: Experimental support for DWARF debugging information.)]647 bull3
-[(New compile date and time standard macros.)]630 bull3
-[2(%ifnum)0( now returns true for negative numbers.)]613 bull3
-[(New )2(%iftoken)0( test for a single token.)]596 bull3
-[(New )2(%ifempty)0( test for empty expansion.)]579 bull3
-[(Add support for the )2(XSAVE)0( instruction group.)]562 bull3
-[(Makefile for Netware/gcc.)]545 bull3
-[(Fix issue with some warnings getting emitted way too many times.)]528 bull3
-[(Autogenerated instruction list added to the documentation.)]511 bull3
-[{/section-C.1.10 xa}(Version 2.01)](C.1.10)491.8 subh3
-[(Fix the handling of MMX registers with explicit )2(qword)0( tags on memory \(broken in 2.00 due to 64-bit)]474.8 bull1
-[(changes.\))]463.8 bull2
-[(Fix the PREFETCH instructions.)]446.8 bull3
-[(Fix the documentation.)]429.8 bull3
-[(Fix debugging info when using )2(-f elf)0( \(backwards compatibility alias for )2(-f elf32)0(\).)]412.8 bull3
-[(Man pages for rdoff tools \(from the Debian project.\))]395.8 bull3
-[(ELF: handle large numbers of sections.)]378.8 bull3
-[(Fix corrupt output when the optimizer runs out of passes.)]361.8 bull3
-[{/section-C.1.11 xa}(Version 2.00)](C.1.11)342.6 subh3
-[(Added c99 data-type compliance.)]325.6 bull3
-[(Added general x86-64 support.)]308.6 bull3
-[(Added win64 \(x86-64 COFF\) output format.)]291.6 bull3
-[(Added )2(__BITS__)0( standard macro.)]274.6 bull3
-[(Renamed the )2(elf)0( output format to )2(elf32)0( for clarity.)]257.6 bull3
-[(Added )2(elf64)0( and )2(macho)0( \(MacOS X\) output formats.)]240.6 bull3
-[(Added Numeric constants in )2(dq)0( directive.)]223.6 bull3
-[(Added )2(oword)0(, )2(do)0( and )2(reso)0( pseudo operands.)]206.6 bull3
-[(Allow underscores in numbers.)]189.6 bull3
-[(Added 8-, 16- and 128-bit floating-point formats.)]172.6 bull3
-[(Added binary, octal and hexadecimal floating-point.)]155.6 bull3
-[(Correct the generation of floating-point constants.)]138.6 bull3
-[(Added floating-point option control.)]121.6 bull3
-[(Added Infinity and NaN floating point support.)]104.6 bull3
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-[(Added ELF Symbol Visibility support.)]681 bull3
-[(Added setting OSABI value in ELF header directive.)]664 bull3
-[(Added Generate Makefile Dependencies option.)]647 bull3
-[(Added Unlimited Optimization Passes option.)]630 bull3
-[(Added )2(%IFN)0( and )2(%ELIFN)0( support.)]613 bull3
-[(Added Logical Negation Operator.)]596 bull3
-[(Enhanced Stack Relative Preprocessor Directives.)]579 bull3
-[(Enhanced ELF Debug Formats.)]562 bull3
-[(Enhanced Send Errors to a File option.)]545 bull3
-[(Added SSSE3, SSE4.1, SSE4.2, SSE5 support.)]528 bull3
-[(Added a large number of additional instructions.)]511 bull3
-[(Significant performance improvements.)]494 bull3
-[2(-w+warning)0( and )2(-w-warning)0( can now be written as \226Wwarning and \226Wno-warning, respectively.)]477 bull1
-[(See ){/section-2.1.24 xl}(section 2.1.24){el}(.)]466 bull2
-[(Add )2(-w+error)0( to treat warnings as errors. See ){/section-2.1.24 xl}(section 2.1.24){el}(.)]449 bull3
-[(Add )2(-w+all)0( and )2(-w-all)0( to enable or disable all suppressible warnings. See ){/section-2.1.24 xl}(section 2.1.24){el}(.)]432 bull3
-[{/section-C.2 xa}(NASM 0.98 Series)](C.2)410.6 head3
-[(The 0.98 series was the production versions of NASM from 1999 to 2007.)]393.6 norm3
-[{/section-C.2.1 xa}(Version 0.98.39)](C.2.1)374.4 subh3
-[(fix buffer overflow)]357.4 bull3
-[(fix outas86's )2(.bss)0( handling)]340.4 bull3
-[("make spotless" no longer deletes config.h.in.)]323.4 bull3
-[2(%\(el\)if\(n\)idn)0( insensitivity to string quotes difference \(#809300\).)]306.4 bull3
-[(\(nasm.c\))2(__OUTPUT_FORMAT__)0( changed to string value instead of symbol.)]289.4 bull3
-[{/section-C.2.2 xa}(Version 0.98.38)](C.2.2)270.2 subh3
-[(Add Makefile for 16-bit DOS binaries under OpenWatcom, and modify )2(mkdep.pl)0( to be able to generate)]253.2 bull1
-[(completely pathless dependencies, as required by OpenWatcom wmake \(it supports path searches, but not)]242.2 bull0
-[(explicit paths.\))]231.2 bull2
-[(Fix the )2(STR)0( instruction.)]214.2 bull3
-[(Fix the ELF output format, which was broken under certain circumstances due to the addition of stabs)]197.2 bull1
-[(support.)]186.2 bull2
-[(Quick-fix Borland format debug-info for )2(-f obj)]169.2 bull3
-[(Fix for )2(%rep)0( with no arguments \(#560568\))]152.2 bull3
-[(Fix concatenation of preprocessor function call \(#794686\))]135.2 bull3
-[(Fix long label causes coredump \(#677841\))]118.2 bull3
-[(Use autoheader as well as autoconf to keep configure from generating ridiculously long command lines.)]101.2 bull3
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-[(Make sure that all of the formats which support debugging output actually will suppress debugging output)]681 bull1
-[(when )2(-g)0( not specified.)]670 bull2
-[{/section-C.2.3 xa}(Version 0.98.37)](C.2.3)650.8 subh3
-[(Paths given in )2(-I)0( switch searched for )2(incbin)0(\226ed as well as )2(%include)0(\226ed files.)]633.8 bull3
-[(Added stabs debugging for the ELF output format, patch from Martin Wawro.)]616.8 bull3
-[(Fix )2(output/outbin.c)0( to allow origin > 80000000h.)]599.8 bull3
-[(Make )2(-U)0( switch work.)]582.8 bull3
-[(Fix the use of relative offsets with explicit prefixes, e.g. )2(a32 loop foo)0(.)]565.8 bull3
-[(Remove )2(backslash\(\))0(.)]548.8 bull3
-[(Fix the )2(SMSW)0( and )2(SLDT)0( instructions.)]531.8 bull3
-[2(-O2)0( and )2(-O3)0( are no longer aliases for )2(-O10)0( and )2(-O15)0(. If you mean the latter, please say so! :\))]514.8 bull3
-[{/section-C.2.4 xa}(Version 0.98.36)](C.2.4)495.6 subh3
-[(Update rdoff \226 librarian/archiver \226 common rec \226 docs!)]478.6 bull3
-[(Fix signed/unsigned problems.)]461.6 bull3
-[(Fix )2(JMP FAR label)0( and )2(CALL FAR label)0(.)]444.6 bull3
-[(Add new multisection support \226 map files \226 fix align bug)]427.6 bull3
-[(Fix sysexit, movhps/movlps reg,reg bugs in insns.dat)]410.6 bull3
-[2(Q)0( or )2(O)0( suffixes indicate octal)]393.6 bull3
-[(Support Prescott new instructions \(PNI\).)]376.6 bull3
-[(Cyrix )2(XSTORE)0( instruction.)]359.6 bull3
-[{/section-C.2.5 xa}(Version 0.98.35)](C.2.5)340.4 subh3
-[(Fix build failure on 16-bit DOS \(Makefile.bc3 workaround for compiler bug.\))]323.4 bull3
-[(Fix dependencies and compiler warnings.)]306.4 bull3
-[(Add "const" in a number of places.)]289.4 bull3
-[(Add \226X option to specify error reporting format \(use \226Xvc to integrate with Microsoft Visual Studio.\))]272.4 bull3
-[(Minor changes for code legibility.)]255.4 bull3
-[(Drop use of tmpnam\(\) in rdoff \(security fix.\))]238.4 bull3
-[{/section-C.2.6 xa}(Version 0.98.34)](C.2.6)219.2 subh3
-[(Correct additional address-size vs. operand-size confusions.)]202.2 bull3
-[(Generate dependencies for all Makefiles automatically.)]185.2 bull3
-[(Add support for unimplemented \(but theoretically available\) registers such as tr0 and cr5. Segment)]168.2 bull1
-[(registers 6 and 7 are called segr6 and segr7 for the operations which they can be represented.)]157.2 bull2
-[(Correct some disassembler bugs related to redundant address-size prefixes. Some work still remains in this)]140.2 bull1
-[(area.)]129.2 bull2
-[(Correctly generate an error for things like "SEG eax".)]112.2 bull3
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-[(Add the JMPE instruction, enabled by "CPU IA64".)]681 bull3
-[(Correct compilation on newer gcc/glibc platforms.)]664 bull3
-[(Issue an error on things like "jmp far eax".)]647 bull3
-[{/section-C.2.7 xa}(Version 0.98.33)](C.2.7)627.8 subh3
-[(New __NASM_PATCHLEVEL__ and __NASM_VERSION_ID__ standard macros to round out the)]610.8 bull1
-[(version-query macros. version.pl now understands X.YYplWW or X.YY.ZZplWW as a version number,)]599.8 bull0
-[(equivalent to X.YY.ZZ.WW \(or X.YY.0.WW, as appropriate\).)]588.8 bull2
-[(New keyword "strict" to disable the optimization of specific operands.)]571.8 bull3
-[(Fix the handing of size overrides with JMP instructions \(instructions such as "jmp dword foo".\))]554.8 bull3
-[(Fix the handling of "ABSOLUTE label", where "label" points into a relocatable segment.)]537.8 bull3
-[(Fix OBJ output format with lots of externs.)]520.8 bull3
-[(More documentation updates.)]503.8 bull3
-[(Add \226Ov option to get verbose information about optimizations.)]486.8 bull3
-[(Undo a braindead change which broke )2(%elif)0( directives.)]469.8 bull3
-[(Makefile updates.)]452.8 bull3
-[{/section-C.2.8 xa}(Version 0.98.32)](C.2.8)433.6 subh3
-[(Fix NASM crashing when )2(%macro)0( directives were left unterminated.)]416.6 bull3
-[(Lots of documentation updates.)]399.6 bull3
-[(Complete rewrite of the PostScript/PDF documentation generator.)]382.6 bull3
-[(The MS Visual C++ Makefile was updated and corrected.)]365.6 bull3
-[(Recognize .rodata as a standard section name in ELF.)]348.6 bull3
-[(Fix some obsolete Perl4-isms in Perl scripts.)]331.6 bull3
-[(Fix configure.in to work with autoconf 2.5x.)]314.6 bull3
-[(Fix a couple of "make cleaner" misses.)]297.6 bull3
-[(Make the normal "./configure && make" work with Cygwin.)]280.6 bull3
-[{/section-C.2.9 xa}(Version 0.98.31)](C.2.9)261.4 subh3
-[(Correctly build in a separate object directory again.)]244.4 bull3
-[(Derive all references to the version number from the version file.)]227.4 bull3
-[(New standard macros __NASM_SUBMINOR__ and __NASM_VER__ macros.)]210.4 bull3
-[(Lots of Makefile updates and bug fixes.)]193.4 bull3
-[(New )2(%ifmacro)0( directive to test for multiline macros.)]176.4 bull3
-[(Documentation updates.)]159.4 bull3
-[(Fixes for 16-bit OBJ format output.)]142.4 bull3
-[(Changed the NASM environment variable to NASMENV.)]125.4 bull3
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-[{/section-C.2.10 xa}(Version 0.98.30)](C.2.10)678.8 subh3
-[(Changed doc files a lot: completely removed old READMExx and Wishlist files, incorporating all)]661.8 bull1
-[(information in CHANGES and TODO.)]650.8 bull2
-[(I waited a long time to rename zoutieee.c to \(original\) outieee.c)]633.8 bull3
-[(moved all output modules to output/ subdirectory.)]616.8 bull3
-[(Added 'make strip' target to strip debug info from nasm & ndisasm.)]599.8 bull3
-[(Added INSTALL file with installation instructions.)]582.8 bull3
-[(Added \226v option description to nasm man.)]565.8 bull3
-[(Added dist makefile target to produce source distributions.)]548.8 bull3
-[(16-bit support for ELF output format \(GNU extension, but useful.\))]531.8 bull3
-[{/section-C.2.11 xa}(Version 0.98.28)](C.2.11)512.6 subh3
-[(Fastcooked this for Debian's Woody release: Frank applied the INCBIN bug patch to 0.98.25alt and called)]495.6 bull1
-[(it 0.98.28 to not confuse poor little apt-get.)]484.6 bull2
-[{/section-C.2.12 xa}(Version 0.98.26)](C.2.12)465.4 subh3
-[(Reorganised files even better from 0.98.25alt)]448.4 bull3
-[{/section-C.2.13 xa}(Version 0.98.25alt)](C.2.13)429.2 subh3
-[(Prettified the source tree. Moved files to more reasonable places.)]412.2 bull3
-[(Added findleak.pl script to misc/ directory.)]395.2 bull3
-[(Attempted to fix doc.)]378.2 bull3
-[{/section-C.2.14 xa}(Version 0.98.25)](C.2.14)359 subh3
-[(Line continuation character )2(\\)0(.)]342 bull3
-[(Docs inadvertantly reverted \226 "dos packaging".)]325 bull3
-[{/section-C.2.15 xa}(Version 0.98.24p1)](C.2.15)305.8 subh3
-[(FIXME: Someone, document this please.)]288.8 bull3
-[{/section-C.2.16 xa}(Version 0.98.24)](C.2.16)269.6 subh3
-[(Documentation \226 Ndisasm doc added to Nasm.doc.)]252.6 bull3
-[{/section-C.2.17 xa}(Version 0.98.23)](C.2.17)233.4 subh3
-[(Attempted to remove rdoff version1)]216.4 bull3
-[(Lino Mastrodomenico's patches to preproc.c \(%$$ bug?\).)]199.4 bull3
-[{/section-C.2.18 xa}(Version 0.98.22)](C.2.18)180.2 subh3
-[(Update rdoff2 \226 attempt to remove v1.)]163.2 bull3
-[{/section-C.2.19 xa}(Version 0.98.21)](C.2.19)144 subh3
-[(Optimization fixes.)]127 bull3
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-[{/section-C.2.20 xa}(Version 0.98.20)](C.2.20)678.8 subh3
-[(Optimization fixes.)]661.8 bull3
-[{/section-C.2.21 xa}(Version 0.98.19)](C.2.21)642.6 subh3
-[(H. J. Lu's patch back out.)]625.6 bull3
-[{/section-C.2.22 xa}(Version 0.98.18)](C.2.22)606.4 subh3
-[(Added ".rdata" to "-f win32".)]589.4 bull3
-[{/section-C.2.23 xa}(Version 0.98.17)](C.2.23)570.2 subh3
-[(H. J. Lu's "bogus elf" patch. \(Red Hat problem?\))]553.2 bull3
-[{/section-C.2.24 xa}(Version 0.98.16)](C.2.24)534 subh3
-[(Fix whitespace before "[section ..." bug.)]517 bull3
-[{/section-C.2.25 xa}(Version 0.98.15)](C.2.25)497.8 subh3
-[(Rdoff changes \(?\).)]480.8 bull3
-[(Fix fixes to memory leaks.)]463.8 bull3
-[{/section-C.2.26 xa}(Version 0.98.14)](C.2.26)444.6 subh3
-[(Fix memory leaks.)]427.6 bull3
-[{/section-C.2.27 xa}(Version 0.98.13)](C.2.27)408.4 subh3
-[(There was no 0.98.13)]391.4 bull3
-[{/section-C.2.28 xa}(Version 0.98.12)](C.2.28)372.2 subh3
-[(Update optimization \(new function of "-O1"\))]355.2 bull3
-[(Changes to test/bintest.asm \(?\).)]338.2 bull3
-[{/section-C.2.29 xa}(Version 0.98.11)](C.2.29)319 subh3
-[(Optimization changes.)]302 bull3
-[(Ndisasm fixed.)]285 bull3
-[{/section-C.2.30 xa}(Version 0.98.10)](C.2.30)265.8 subh3
-[(There was no 0.98.10)]248.8 bull3
-[{/section-C.2.31 xa}(Version 0.98.09)](C.2.31)229.6 subh3
-[(Add multiple sections support to "-f bin".)]212.6 bull3
-[(Changed GLOBAL_TEMP_BASE in outelf.c from 6 to 15.)]195.6 bull3
-[(Add "-v" as an alias to the "-r" switch.)]178.6 bull3
-[(Remove "#ifdef" from Tasm compatibility options.)]161.6 bull3
-[(Remove redundant size-overrides on "mov ds, ex", etc.)]144.6 bull3
-[(Fixes to SSE2, other insns.dat \(?\).)]127.6 bull3
-[(Enable uppercase "I" and "P" switches.)]110.6 bull3
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-[(Case insinsitive "seg" and "wrt".)]681 bull3
-[(Update install.sh \(?\).)]664 bull3
-[(Allocate tokens in blocks.)]647 bull3
-[(Improve "invalid effective address" messages.)]630 bull3
-[{/section-C.2.32 xa}(Version 0.98.08)](C.2.32)610.8 subh3
-[(Add ")2(%strlen)0(" and ")2(%substr)0(" macro operators)]593.8 bull3
-[(Fixed broken c16.mac.)]576.8 bull3
-[(Unterminated string error reported.)]559.8 bull3
-[(Fixed bugs as per 0.98bf)]542.8 bull3
-[{/section-C.2.33 xa}(Version 0.98.09b with John Coffman patches released 28-Oct-2001)](C.2.33)523.6 subh3
-[(Changes from 0.98.07 release to 98.09b as of 28-Oct-2001)]506.6 norm3
-[(More closely compatible with 0.98 when \226O0 is implied or specified. Not strictly identical, since backward)]489.6 bull1
-[(branches in range of short offsets are recognized, and signed byte values with no explicit size specification)]478.6 bull0
-[(will be assembled as a single byte.)]467.6 bull2
-[(More forgiving with the PUSH instruction. 0.98 requires a size to be specified always. 0.98.09b will imply)]450.6 bull1
-[(the size from the current BITS setting \(16 or 32\).)]439.6 bull2
-[(Changed definition of the optimization flag:)]422.6 bull3
-[(\226O0 strict two-pass assembly, JMP and Jcc are handled more like 0.98, except that back- ward JMPs are)]405.6 norm1
-[(short, if possible.)]394.6 norm2
-[(\226O1 strict two-pass assembly, but forward branches are assembled with code guaranteed to reach; may)]377.6 norm1
-[(produce larger code than \226O0, but will produce successful assembly more often if branch offset sizes are not)]366.6 norm0
-[(specified.)]355.6 norm2
-[(\226O2 multi-pass optimization, minimize branch offsets; also will minimize signed immed- iate bytes,)]338.6 norm1
-[(overriding size specification.)]327.6 norm2
-[(\226O3 like \226O2, but more passes taken, if needed)]310.6 norm3
-[{/section-C.2.34 xa}(Version 0.98.07 released 01/28/01)](C.2.34)291.4 subh3
-[(Added Stepane Denis' SSE2 instructions to a *working* version of the code \226 some earlier versions were)]274.4 bull1
-[(based on broken code \226 sorry 'bout that. version "0.98.07")]263.4 bull2
-[(01/28/01)]246.4 norm3
-[(Cosmetic modifications to nasm.c, nasm.h, AUTHORS, MODIFIED)]229.4 bull3
-[{/section-C.2.35 xa}(Version 0.98.06f released 01/18/01)](C.2.35)210.2 subh3
-[(\226 Add "metalbrain"s jecxz bug fix in insns.dat \226 alter nasmdoc.src to match \226 version "0.98.06f")]193.2 bull3
-[{/section-C.2.36 xa}(Version 0.98.06e released 01/09/01)](C.2.36)174 subh3
-[(Removed the "outforms.h" file \226 it appears to be someone's old backup of "outform.h". version "0.98.06e")]157 bull3
-[(01/09/01)]140 norm3
-[(fbk \226 finally added the fix for the "multiple %includes bug", known since 7/27/99 \226 reported originally \(?\))]123 bull1
-[(and sent to us by Austin Lunnen \226 he reports that John Fine had a fix within the day. Here it is...)]112 bull2
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-[(Nelson Rush resigns from the group. Big thanks to Nelson for his leadership and enthusiasm in getting)]681 bull1
-[(these changes incorporated into Nasm!)]670 bull2
-[(fbk \226 [list +], [list \226] directives \226 ineptly implemented, should be re-written or removed, perhaps.)]653 bull3
-[(Brian Raiter / fbk \226 "elfso bug" fix \226 applied to aoutb format as well \226 testing might be desirable...)]636 bull3
-[(08/07/00)]619 norm3
-[(James Seter \226 \226postfix, \226prefix command line switches.)]602 bull3
-[(Yuri Zaporogets \226 rdoff utility changes.)]585 bull3
-[{/section-C.2.37 xa}(Version 0.98p1)](C.2.37)565.8 subh3
-[(GAS-like palign \(Panos Minos\))]548.8 bull3
-[(FIXME: Someone, fill this in with details)]531.8 bull3
-[{/section-C.2.38 xa}(Version 0.98bf \(bug-fixed\))](C.2.38)512.6 subh3
-[(Fixed \226 elf and aoutb bug \226 shared libraries \226 multiple "%include" bug in "-f obj" \226 jcxz, jecxz bug \226)]495.6 bull1
-[(unrecognized option bug in ndisasm)]484.6 bull2
-[{/section-C.2.39 xa}(Version 0.98.03 with John Coffman's changes released 27-Jul-2000)](C.2.39)465.4 subh3
-[(Added signed byte optimizations for the 0x81/0x83 class of instructions: ADC, ADD, AND, CMP, OR,)]448.4 bull1
-[(SBB, SUB, XOR: when used as 'ADD reg16,imm' or 'ADD reg32,imm.' Also optimization of signed byte)]437.4 bull0
-[(form of 'PUSH imm' and 'IMUL reg,imm'/'IMUL reg,reg,imm.' No size specification is needed.)]426.4 bull2
-[(Added multi-pass JMP and Jcc offset optimization. Offsets on forward references will preferentially use)]409.4 bull1
-[(the short form, without the need to code a specific size \(short or near\) for the branch. Added instructions)]398.4 bull0
-[(for 'Jcc label' to use the form 'Jnotcc $+3/JMP label', in cases where a short offset is out of bounds. If)]387.4 bull0
-[(compiling for a 386 or higher CPU, then the 386 form of Jcc will be used instead.)]376.4 bull2
-[(This feature is controlled by a new command-line switch: "O", \(upper case letter O\). "-O0" reverts the)]359.4 norm1
-[(assembler to no extra optimization passes, "-O1" allows up to 5 extra passes, and "-O2"\(default\), allows up)]348.4 norm0
-[(to 10 extra optimization passes.)]337.4 norm2
-[(Added a new directive: 'cpu XXX', where XXX is any of: 8086, 186, 286, 386, 486, 586, pentium, 686,)]320.4 bull1
-[(PPro, P2, P3 or Katmai. All are case insensitive. All instructions will be selected only if they apply to the)]309.4 bull0
-[(selected cpu or lower. Corrected a couple of bugs in cpu-dependence in 'insns.dat'.)]298.4 bull2
-[(Added to 'standard.mac', the "use16" and "use32" forms of the "bits 16/32" directive. This is nothing new,)]281.4 bull1
-[(just conforms to a lot of other assemblers. \(minor\))]270.4 bull2
-[(Changed label allocation from 320/32 \(10000 labels @ 200K+\) to 32/37 \(1000 labels\); makes running)]253.4 bull1
-[(under DOS much easier. Since additional label space is allocated dynamically, this should have no effect)]242.4 bull0
-[(on large programs with lots of labels. The 37 is a prime, believed to be better for hashing. \(minor\))]231.4 bull2
-[{/section-C.2.40 xa}(Version 0.98.03)](C.2.40)212.2 subh3
-[("Integrated patchfile 0.98-0.98.01. I call this version 0.98.03 for historical reasons: 0.98.02 was trashed.")]195.2 norm1
-[(\226\226John Coffman <johninsd@san.rr.com>, 27-Jul-2000)]184.2 norm2
-[(Kendall Bennett's SciTech MGL changes)]167.2 bull3
-[(Note that you must define "TASM_COMPAT" at compile-time to get the Tasm Ideal Mode compatibility.)]150.2 bull3
-[(All changes can be compiled in and out using the TASM_COMPAT macros, and when compiled without)]133.2 bull1
-[(TASM_COMPAT defined we get the exact same binary as the unmodified 0.98 sources.)]122.2 bull2
-[(standard.mac, macros.c: Added macros to ignore TASM directives before first include)]105.2 bull3
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-[(nasm.h: Added extern declaration for tasm_compatible_mode)]681 bull3
-[(nasm.c: Added global variable tasm_compatible_mode)]664 bull3
-[(Added command line switch for TASM compatible mode \(-t\))]647 bull3
-[(Changed version command line to reflect when compiled with TASM additions)]630 bull3
-[(Added response file processing to allow all arguments on a single line \(response file is @resp rather than)]613 bull1
-[(\226@resp for NASM format\).)]602 bull2
-[(labels.c: Changes islocal\(\) macro to support TASM style @@local labels.)]585 bull3
-[(Added islocalchar\(\) macro to support TASM style @@local labels.)]568 bull3
-[(parser.c: Added support for TASM style memory references \(ie: mov [DWORD eax],10 rather than the)]551 bull1
-[(NASM style mov DWORD [eax],10\).)]540 bull2
-[(preproc.c: Added new directives, )2(%arg)0(, )2(%local)0(, )2(%stacksize)0( to directives table)]523 bull3
-[(Added support for TASM style directives without a leading % symbol.)]506 bull3
-[(Integrated a block of changes from Andrew Zabolotny <bit@eltech.ru>:)]489 bull3
-[(A new keyword )2(%xdefine)0( and its case-insensitive counterpart )2(%ixdefine)0(. They work almost the)]472 bull1
-[(same way as )2(%define)0( and )2(%idefine)0( but expand the definition immediately, not on the invocation.)]461 bull0
-[(Something like a cross between )2(%define)0( and )2(%assign)0(. The "x" suffix stands for "eXpand", so)]450 bull0
-[("xdefine" can be deciphered as "expand-and-define". Thus you can do things like this:)]439 bull2
-[2( %assign ofs 0 )]422 code1
-[2()]411 code0
-[2( %macro arg 1 )]400 code0
-[2( %xdefine %1 dword [esp+ofs] )]389 code0
-[2( %assign ofs ofs+4 )]378 code0
-[2( %endmacro)]367 code2
-[(Changed the place where the expansion of %$name macros are expanded. Now they are converted into)]350 bull1
-[(..@ctxnum.name form when detokenizing, so there are no quirks as before when using %$name arguments)]339 bull0
-[(to macros, in macros etc. For example:)]328 bull2
-[2( %macro abc 1 )]311 code1
-[2( %define %1 hello )]300 code0
-[2( %endm )]289 code0
-[2()]278 code0
-[2( abc %$here )]267 code0
-[2( %$here)]256 code2
-[(Now last line will be expanded into "hello" as expected. This also allows for lots of goodies, a good example)]239 norm1
-[(are extended "proc" macros included in this archive.)]228 norm2
-[(Added a check for "cstk" in smacro_defined\(\) before calling get_ctx\(\) \226 this allows for things like:)]211 bull3
-[2( %ifdef %$abc )]194 code1
-[2( %endif)]183 code2
-[(to work without warnings even in no context.)]166 norm3
-[(Added a check for "cstk" in %if*ctx and %elif*ctx directives \226 this allows to use )2(%ifctx)0( without)]149 bull1
-[(excessive warnings. If there is no active context, )2(%ifctx)0( goes through "false" branch.)]138 bull2
-[(Removed "user error: " prefix with )2(%error)0( directive: it just clobbers the output and has absolutely no)]121 bull1
-[(functionality. Besides, this allows to write macros that does not differ from built-in functions in any way.)]110 bull2
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-[(Added expansion of string that is output by )2(%error)0( directive. Now you can do things like:)]681 bull3
-[2( %define hello\(x\) Hello, x! )]664 code1
-[2()]653 code0
-[2( %define %$name andy )]642 code0
-[2( %error "hello\(%$name\)")]631 code2
-[(Same happened with )2(%include)0( directive.)]614 norm3
-[(Now all directives that expect an identifier will try to expand and concatenate everything without)]597 bull1
-[(whitespaces in between before usage. For example, with "unfixed" nasm the commands)]586 bull2
-[2( %define %$abc hello )]569 code1
-[2( %define __%$abc goodbye )]558 code0
-[2( __%$abc)]547 code2
-[(would produce "incorrect" output: last line will expand to)]530 norm3
-[2( hello goodbyehello)]513 code3
-[(Not quite what you expected, eh? :-\) The answer is that preprocessor treats the )2(%define)0( construct as if it)]496 norm1
-[(would be)]485 norm2
-[2( %define __ %$abc goodbye)]468 code3
-[(\(note the white space between __ and %$abc\). After my "fix" it will "correctly" expand into)]451 norm3
-[2( goodbye)]434 code3
-[(as expected. Note that I use quotes around words "correct", "incorrect" etc because this is rather a feature not)]417 norm1
-[(a bug; however current behaviour is more logical \(and allows more advanced macro usage :-\).)]406 norm2
-[(Same change was applied to: )2(%push)0(,)2(%macro)0(,)2(%imacro)0(,)2(%define)0(,)2(%idefine)0(,)2(%xdefine)0(,)2(%ixdefine)0(,)]389 norm1
-[2(%assign)0(,)2(%iassign)0(,)2(%undef)]378 norm2
-[(A new directive [WARNING {+|-}warning-id] have been added. It works only if the assembly phase is)]361 bull1
-[(enabled \(i.e. it doesn't work with nasm \226e\).)]350 bull2
-[(A new warning type: macro-selfref. By default this warning is disabled; when enabled NASM warns when)]333 bull1
-[(a macro self-references itself; for example the following source:)]322 bull2
-[2( [WARNING macro-selfref] )]305 code1
-[2()]294 code0
-[2( %macro push 1-* )]283 code0
-[2( %rep %0 )]272 code0
-[2( push %1 )]261 code0
-[2( %rotate 1 )]250 code0
-[2( %endrep )]239 code0
-[2( %endmacro )]228 code0
-[2()]217 code0
-[2( push eax,ebx,ecx)]206 code2
-[(will produce a warning, but if we remove the first line we won't see it anymore \(which is The Right Thing To)]189 norm1
-[(Do {tm} IMHO since C preprocessor eats such constructs without warnings at all\).)]178 norm2
-[(Added a "error" routine to preprocessor which always will set ERR_PASS1 bit in severity_code. This)]161 bull1
-[(removes annoying repeated errors on first and second passes from preprocessor.)]150 bull2
-[(Added the %+ operator in single-line macros for concatenating two identifiers. Usage example:)]133 bull3
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-[2( %define _myfunc _otherfunc )]681 code1
-[2( %define cextern\(x\) _ %+ x )]670 code0
-[2( cextern \(myfunc\))]659 code2
-[(After first expansion, third line will become "_myfunc". After this expansion is performed again so it)]642 norm1
-[(becomes "_otherunc".)]631 norm2
-[(Now if preprocessor is in a non-emitting state, no warning or error will be emitted. Example:)]614 bull3
-[2( %if 1 )]597 code1
-[2( mov eax,ebx )]586 code0
-[2( %else )]575 code0
-[2( put anything you want between these two brackets, )]564 code0
-[2( even macro-parameter references %1 or local )]553 code0
-[2( labels %$zz or macro-local labels %%zz - no )]542 code0
-[2( warning will be emitted. )]531 code0
-[2( %endif)]520 code2
-[(Context-local variables on expansion as a last resort are looked up in outer contexts. For example, the)]503 bull1
-[(following piece:)]492 bull2
-[2( %push outer )]475 code1
-[2( %define %$a [esp] )]464 code0
-[2()]453 code0
-[2( %push inner )]442 code0
-[2( %$a )]431 code0
-[2( %pop )]420 code0
-[2( %pop)]409 code2
-[(will expand correctly the fourth line to [esp]; if we'll define another %$a inside the "inner" context, it will)]392 norm1
-[(take precedence over outer definition. However, this modification has been applied only to expand_smacro)]381 norm0
-[(and not to smacro_define: as a consequence expansion looks in outer contexts, but )2(%ifdef)0( won't look in)]370 norm0
-[(outer contexts.)]359 norm2
-[(This behaviour is needed because we don't want nested contexts to act on already defined local macros.)]342 norm1
-[(Example:)]331 norm2
-[2( %define %$arg1 [esp+4] )]314 code1
-[2( test eax,eax )]303 code0
-[2( if nz )]292 code0
-[2( mov eax,%$arg1 )]281 code0
-[2( endif)]270 code2
-[(In this example the "if" mmacro enters into the "if" context, so %$arg1 is not valid anymore inside "if". Of)]253 norm1
-[(course it could be worked around by using explicitely %$$arg1 but this is ugly IMHO.)]242 norm2
-[(Fixed memory leak in )2(%undef)0(. The origline wasn't freed before exiting on success.)]225 bull3
-[(Fixed trap in preprocessor when line expanded to empty set of tokens. This happens, for example, in the)]208 bull1
-[(following case:)]197 bull2
-[2( #define SOMETHING )]180 code1
-[2( SOMETHING)]169 code2
-[{/section-C.2.41 xa}(Version 0.98)](C.2.41)149.8 subh3
-[(All changes since NASM 0.98p3 have been produced by H. Peter Anvin <hpa@zytor.com>.)]132.8 norm3
-[(The documentation comment delimiter is)]115.8 bull3
-(195)pageodd
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-[(Allow EQU definitions to refer to external labels; reported by Pedro Gimeno.)]681 bull3
-[(Re-enable support for RDOFF v1; reported by Pedro Gimeno.)]664 bull3
-[(Updated License file per OK from Simon and Julian.)]647 bull3
-[{/section-C.2.42 xa}(Version 0.98p9)](C.2.42)627.8 subh3
-[(Update documentation \(although the instruction set reference will have to wait; I don't want to hold up the)]610.8 bull1
-[(0.98 release for it.\))]599.8 bull2
-[(Verified that the NASM implementation of the PEXTRW and PMOVMSKB instructions is correct. The)]582.8 bull1
-[(encoding differs from what the Intel manuals document, but the Pentium III behaviour matches NASM, not)]571.8 bull0
-[(the Intel manuals.)]560.8 bull2
-[(Fix handling of implicit sizes in PSHUFW and PINSRW, reported by Stefan Hoffmeister.)]543.8 bull3
-[(Resurrect the \226s option, which was removed when changing the diagnostic output to stdout.)]526.8 bull3
-[{/section-C.2.43 xa}(Version 0.98p8)](C.2.43)507.6 subh3
-[(Fix for "DB" when NASM is running on a bigendian machine.)]490.6 bull3
-[(Invoke insns.pl once for each output script, making Makefile.in legal for "make \226j".)]473.6 bull3
-[(Improve the Unix configure-based makefiles to make package creation easier.)]456.6 bull3
-[(Included an RPM .spec file for building RPM \(RedHat Package Manager\) packages on Linux or Unix)]439.6 bull1
-[(systems.)]428.6 bull2
-[(Fix Makefile dependency problems.)]411.6 bull3
-[(Change src/rdsrc.pl to include sectioning information in info output; required for install-info to work.)]394.6 bull3
-[(Updated the RDOFF distribution to version 2 from Jules; minor massaging to make it compile in my)]377.6 bull1
-[(environment.)]366.6 bull2
-[(Split doc files that can be built by anyone with a Perl interpreter off into a separate archive.)]349.6 bull3
-[("Dress rehearsal" release!)]332.6 bull3
-[{/section-C.2.44 xa}(Version 0.98p7)](C.2.44)313.4 subh3
-[(Fixed opcodes with a third byte-sized immediate argument to not complain if given "byte" on the)]296.4 bull1
-[(immediate.)]285.4 bull2
-[(Allow )2(%undef)0( to remove single-line macros with arguments. This matches the behaviour of #undef in the)]268.4 bull1
-[(C preprocessor.)]257.4 bull2
-[(Allow \226d, \226u, \226i and \226p to be specified as \226D, \226U, \226I and \226P for compatibility with most C compilers and)]240.4 bull1
-[(preprocessors. This allows Makefile options to be shared between cc and nasm, for example.)]229.4 bull2
-[(Minor cleanups.)]212.4 bull3
-[(Went through the list of Katmai instructions and hopefully fixed the \(rather few\) mistakes in it.)]195.4 bull3
-[(\(Hopefully\) fixed a number of disassembler bugs related to ambiguous instructions \(disambiguated by \226p\))]178.4 bull1
-[(and SSE instructions with REP.)]167.4 bull2
-[(Fix for bug reported by Mark Junger: "call dword 0x12345678" should work and may add an OSP)]150.4 bull1
-[(\(affected CALL, JMP, Jcc\).)]139.4 bull2
-[(Fix for environments when "stderr" isn't a compile-time constant.)]122.4 bull3
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-[{/section-C.2.45 xa}(Version 0.98p6)](C.2.45)678.8 subh3
-[(Took officially over coordination of the 0.98 release; so drop the p3.x notation. Skipped p4 and p5 to avoid)]661.8 bull1
-[(confusion with John Fine's J4 and J5 releases.)]650.8 bull2
-[(Update the documentation; however, it still doesn't include documentation for the various new)]633.8 bull1
-[(instructions. I somehow wonder if it makes sense to have an instruction set reference in the assembler)]622.8 bull0
-[(manual when Intel et al have PDF versions of their manuals online.)]611.8 bull2
-[(Recognize "idt" or "centaur" for the \226p option to ndisasm.)]594.8 bull3
-[(Changed error messages back to stderr where they belong, but add an \226E option to redirect them elsewhere)]577.8 bull1
-[(\(the DOS shell cannot redirect stderr.\))]566.8 bull2
-[(\226M option to generate Makefile dependencies \(based on code from Alex Verstak.\))]549.8 bull3
-[2(%undef)0( preprocessor directive, and \226u option, that undefines a single-line macro.)]532.8 bull3
-[(OS/2 Makefile \(Mkfiles/Makefile.os2\) for Borland under OS/2; from Chuck Crayne.)]515.8 bull3
-[(Various minor bugfixes \(reported by\): \226 Dangling )2(%s)0( in preproc.c \(Martin Junker\))]498.8 bull3
-[(THERE ARE KNOWN BUGS IN SSE AND THE OTHER KATMAI INSTRUCTIONS. I am on a trip)]481.8 bull1
-[(and didn't bring the Katmai instruction reference, so I can't work on them right now.)]470.8 bull2
-[(Updated the License file per agreement with Simon and Jules to include a GPL distribution clause.)]453.8 bull3
-[{/section-C.2.46 xa}(Version 0.98p3.7)](C.2.46)434.6 subh3
-[(\(Hopefully\) fixed the canned Makefiles to include the outrdf2 and zoutieee modules.)]417.6 bull3
-[(Renamed changes.asm to changed.asm.)]400.6 bull3
-[{/section-C.2.47 xa}(Version 0.98p3.6)](C.2.47)381.4 subh3
-[(Fixed a bunch of instructions that were added in 0.98p3.5 which had memory operands, and the)]364.4 bull1
-[(address-size prefix was missing from the instruction pattern.)]353.4 bull2
-[{/section-C.2.48 xa}(Version 0.98p3.5)](C.2.48)334.2 subh3
-[(Merged in changes from John S. Fine's 0.98-J5 release. John's based 0.98-J5 on my 0.98p3.3 release; this)]317.2 bull1
-[(merges the changes.)]306.2 bull2
-[(Expanded the instructions flag field to a long so we can fit more flags; mark SSE \(KNI\) and AMD or)]289.2 bull1
-[(Katmai-specific instructions as such.)]278.2 bull2
-[(Fix the "PRIV" flag on a bunch of instructions, and create new "PROT" flag for protected-mode-only)]261.2 bull1
-[(instructions \(orthogonal to if the instruction is privileged!\) and new "SMM" flag for SMM-only)]250.2 bull0
-[(instructions.)]239.2 bull2
-[(Added AMD-only SYSCALL and SYSRET instructions.)]222.2 bull3
-[(Make SSE actually work, and add new Katmai MMX instructions.)]205.2 bull3
-[(Added a \226p \(preferred vendor\) option to ndisasm so that it can distinguish e.g. Cyrix opcodes also used in)]188.2 bull1
-[(SSE. For example:)]177.2 bull2
-[2( ndisasm -p cyrix aliased.bin )]160.2 code1
-[2( 00000000 670F514310 paddsiw mm0,[ebx+0x10] )]149.2 code0
-[2( 00000005 670F514320 paddsiw mm0,[ebx+0x20] )]138.2 code0
-[2( ndisasm -p intel aliased.bin )]127.2 code0
-[2( 00000000 670F514310 sqrtps xmm0,[ebx+0x10] )]116.2 code0
-[2( 00000005 670F514320 sqrtps xmm0,[ebx+0x20])]105.2 code2
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-[(Added a bunch of Cyrix-specific instructions.)]681 bull3
-[{/section-C.2.49 xa}(Version 0.98p3.4)](C.2.49)661.8 subh3
-[(Made at least an attempt to modify all the additional Makefiles \(in the Mkfiles directory\). I can't test it, but)]644.8 bull1
-[(this was the best I could do.)]633.8 bull2
-[(DOS DJGPP+"Opus Make" Makefile from John S. Fine.)]616.8 bull3
-[(changes.asm changes from John S. Fine.)]599.8 bull3
-[{/section-C.2.50 xa}(Version 0.98p3.3)](C.2.50)580.6 subh3
-[(Patch from Conan Brink to allow nesting of )2(%rep)0( directives.)]563.6 bull3
-[(If we're going to allow INT01 as an alias for INT1/ICEBP \(one of Jules 0.98p3 changes\), then we should)]546.6 bull1
-[(allow INT03 as an alias for INT3 as well.)]535.6 bull2
-[(Updated changes.asm to include the latest changes.)]518.6 bull3
-[(Tried to clean up the <CR>s that had snuck in from a DOS/Windows environment into my Unix)]501.6 bull1
-[(environment, and try to make sure than DOS/Windows users get them back.)]490.6 bull2
-[(We would silently generate broken tools if insns.dat wasn't sorted properly. Change insns.pl so that the)]473.6 bull1
-[(order doesn't matter.)]462.6 bull2
-[(Fix bug in insns.pl \(introduced by me\) which would cause conditional instructions to have an extra "cc" in)]445.6 bull1
-[(disassembly, e.g. "jnz" disassembled as "jccnz".)]434.6 bull2
-[{/section-C.2.51 xa}(Version 0.98p3.2)](C.2.51)415.4 subh3
-[(Merged in John S. Fine's changes from his 0.98-J4 prerelease; see http://www.csoft.net/cz/johnfine/)]398.4 bull3
-[(Changed previous "spotless" Makefile target \(appropriate for distribution\) to "distclean", and added)]381.4 bull1
-[("cleaner" target which is same as "clean" except deletes files generated by Perl scripts; "spotless" is union.)]370.4 bull2
-[(Removed BASIC programs from distribution. Get a Perl interpreter instead \(see below.\))]353.4 bull3
-[(Calling this "pre-release 3.2" rather than "p3-hpa2" because of John's contributions.)]336.4 bull3
-[(Actually link in the IEEE output format \(zoutieee.c\); fix a bunch of compiler warnings in that file. Note I)]319.4 bull1
-[(don't know what IEEE output is supposed to look like, so these changes were made "blind".)]308.4 bull2
-[{/section-C.2.52 xa}(Version 0.98p3-hpa)](C.2.52)289.2 subh3
-[(Merged nasm098p3.zip with nasm-0.97.tar.gz to create a fully buildable version for Unix systems)]272.2 bull1
-[(\(Makefile.in updates, etc.\))]261.2 bull2
-[(Changed insns.pl to create the instruction tables in nasm.h and names.c, so that a new instruction can be)]244.2 bull1
-[(added by adding it *only* to insns.dat.)]233.2 bull2
-[(Added the following new instructions: SYSENTER, SYSEXIT, FXSAVE, FXRSTOR, UD1, UD2 \(the)]216.2 bull1
-[(latter two are two opcodes that Intel guarantee will never be used; one of them is documented as UD2 in)]205.2 bull0
-[(Intel documentation, the other one just as "Undefined Opcode" \226\226 calling it UD1 seemed to make sense.\))]194.2 bull2
-[(MAX_SYMBOL was defined to be 9, but LOADALL286 and LOADALL386 are 10 characters long. Now)]177.2 bull1
-[(MAX_SYMBOL is derived from insns.dat.)]166.2 bull2
-[(A note on the BASIC programs included: forget them. insns.bas is already out of date. Get yourself a Perl)]149.2 bull1
-[(interpreter for your platform of choice at ){(http://www.cpan.org/ports/index.html)wl}(http://www.cpan.org/ports/index.html){el}(.)]138.2 bull2
-[{/section-C.2.53 xa}(Version 0.98 pre-release 3)](C.2.53)119 subh3
-[(added response file support, improved command line handling, new layout help screen)]102 bull3
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-[(fixed limit checking bug, 'OUT byte nn, reg' bug, and a couple of rdoff related bugs, updated Wishlist;)]681 bull1
-[(0.98 Prerelease 3.)]670 bull2
-[{/section-C.2.54 xa}(Version 0.98 pre-release 2)](C.2.54)650.8 subh3
-[(fixed bug in outcoff.c to do with truncating section names longer than 8 characters, referencing beyond end)]633.8 bull1
-[(of string; 0.98 pre-release 2)]622.8 bull2
-[{/section-C.2.55 xa}(Version 0.98 pre-release 1)](C.2.55)603.6 subh3
-[(Fixed a bug whereby STRUC didn't work at all in RDF.)]586.6 bull3
-[(Fixed a problem with group specification in PUBDEFs in OBJ.)]569.6 bull3
-[(Improved ease of adding new output formats. Contribution due to Fox Cutter.)]552.6 bull3
-[(Fixed a bug in relocations in the `bin' format: was showing up when a relocatable reference crossed an)]535.6 bull1
-[(8192-byte boundary in any output section.)]524.6 bull2
-[(Fixed a bug in local labels: local-label lookups were inconsistent between passes one and two if an EQU)]507.6 bull1
-[(occurred between the definition of a global label and the subsequent use of a local label local to that global.)]496.6 bull2
-[(Fixed a seg-fault in the preprocessor \(again\) which happened when you use a blank line as the first line of)]479.6 bull1
-[(a multi-line macro definition and then defined a label on the same line as a call to that macro.)]468.6 bull2
-[(Fixed a stale-pointer bug in the handling of the NASM environment variable. Thanks to Thomas)]451.6 bull1
-[(McWilliams.)]440.6 bull2
-[(ELF had a hard limit on the number of sections which caused segfaults when transgressed. Fixed.)]423.6 bull3
-[(Added ability for ndisasm to read from stdin by using `-' as the filename.)]406.6 bull3
-[(ndisasm wasn't outputting the TO keyword. Fixed.)]389.6 bull3
-[(Fixed error cascade on bogus expression in )2(%if)0( \226 an error in evaluation was causing the entire )2(%if)0( to be)]372.6 bull1
-[(discarded, thus creating trouble later when the )2(%else)0( or )2(%endif)0( was encountered.)]361.6 bull2
-[(Forward reference tracking was instruction-granular not operand- granular, which was causing)]344.6 bull1
-[(286-specific code to be generated needlessly on code of the form `shr word [forwardref],1'. Thanks to Jim)]333.6 bull0
-[(Hague for sending a patch.)]322.6 bull2
-[(All messages now appear on stdout, as sending them to stderr serves no useful purpose other than to make)]305.6 bull1
-[(redirection difficult.)]294.6 bull2
-[(Fixed the problem with EQUs pointing to an external symbol \226 this now generates an error message.)]277.6 bull3
-[(Allowed multiple size prefixes to an operand, of which only the first is taken into account.)]260.6 bull3
-[(Incorporated John Fine's changes, including fixes of a large number of preprocessor bugs, some small)]243.6 bull1
-[(problems in OBJ, and a reworking of label handling to define labels before their line is assembled, rather)]232.6 bull0
-[(than after.)]221.6 bull2
-[(Reformatted a lot of the source code to be more readable. Included 'coding.txt' as a guideline for how to)]204.6 bull1
-[(format code for contributors.)]193.6 bull2
-[(Stopped nested )2(%reps)0( causing a panic \226 they now cause a slightly more friendly error message instead.)]176.6 bull3
-[(Fixed floating point constant problems \(patch by Pedro Gimeno\))]159.6 bull3
-[(Fixed the return value of insn_size\(\) not being checked for \2261, indicating an error.)]142.6 bull3
-[(Incorporated 3Dnow! instructions.)]125.6 bull3
-[(Fixed the 'mov eax, eax + ebx' bug.)]108.6 bull3
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-[(Fixed the GLOBAL EQU bug in ELF. Released developers release 3.)]681 bull3
-[(Incorporated John Fine's command line parsing changes)]664 bull3
-[(Incorporated David Lindauer's OMF debug support)]647 bull3
-[(Made changes for LCC 4.0 support \()2(__NASM_CDecl__)0(, removed register size specification warning)]630 bull1
-[(when sizes agree\).)]619 bull2
-[{/section-C.3 xa}(NASM 0.9 Series)](C.3)597.6 head3
-[(Revisions before 0.98.)]580.6 norm3
-[{/section-C.3.1 xa}(Version 0.97 released December 1997)](C.3.1)561.4 subh3
-[(This was entirely a bug-fix release to 0.96, which seems to have got cursed. Silly me.)]544.4 bull3
-[(Fixed stupid mistake in OBJ which caused `MOV EAX,<constant>' to fail. Caused by an error in the)]527.4 bull1
-[(`MOV EAX,<segment>' support.)]516.4 bull2
-[(ndisasm hung at EOF when compiled with lcc on Linux because lcc on Linux somehow breaks feof\(\).)]499.4 bull1
-[(ndisasm now does not rely on feof\(\).)]488.4 bull2
-[(A heading in the documentation was missing due to a markup error in the indexing. Fixed.)]471.4 bull3
-[(Fixed failure to update all pointers on realloc\(\) within extended- operand code in parser.c. Was causing)]454.4 bull1
-[(wrong behaviour and seg faults on lines such as `dd 0.0,0.0,0.0,0.0,...')]443.4 bull2
-[(Fixed a subtle preprocessor bug whereby invoking one multi-line macro on the first line of the expansion)]426.4 bull1
-[(of another, when the second had been invoked with a label defined before it, didn't expand the inner macro.)]415.4 bull2
-[(Added internal.doc back in to the distribution archives \226 it was missing in 0.96 *blush*)]398.4 bull3
-[(Fixed bug causing 0.96 to be unable to assemble its own test files, specifically objtest.asm. *blush again*)]381.4 bull3
-[(Fixed seg-faults and bogus error messages caused by mismatching )2(%rep)0( and )2(%endrep)0( within multi-line)]364.4 bull1
-[(macro definitions.)]353.4 bull2
-[(Fixed a problem with buffer overrun in OBJ, which was causing corruption at ends of long PUBDEF)]336.4 bull1
-[(records.)]325.4 bull2
-[(Separated DOS archives into main-program and documentation to reduce download size.)]308.4 bull3
-[{/section-C.3.2 xa}(Version 0.96 released November 1997)](C.3.2)289.2 subh3
-[(Fixed a bug whereby, if `nasm sourcefile' would cause a filename collision warning and put output into)]272.2 bull1
-[(`nasm.out', then `nasm sourcefile \226o outputfile' still gave the warning even though the `-o' was honoured.)]261.2 bull0
-[(Fixed name pollution under Digital UNIX: one of its header files defined R_SP, which broke the enum in)]250.2 bull0
-[(nasm.h.)]239.2 bull2
-[(Fixed minor instruction table problems: FUCOM and FUCOMP didn't have two-operand forms;)]222.2 bull1
-[(NDISASM didn't recognise the longer register forms of PUSH and POP \(eg FF F3 for PUSH BX\); TEST)]211.2 bull0
-[(mem,imm32 was flagged as undocumented; the 32-bit forms of CMOV had 16-bit operand size prefixes;)]200.2 bull0
-[(`AAD imm' and `AAM imm' are no longer flagged as undocumented because the Intel Architecture)]189.2 bull0
-[(reference documents them.)]178.2 bull2
-[(Fixed a problem with the local-label mechanism, whereby strange types of symbol \(EQUs, auto-defined)]161.2 bull1
-[(OBJ segment base symbols\) interfered with the `previous global label' value and screwed up local labels.)]150.2 bull2
-[(Fixed a bug whereby the stub preprocessor didn't communicate with the listing file generator, so that the)]133.2 bull1
-[(\226a and \226l options in conjunction would produce a useless listing file.)]122.2 bull2
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-[(Merged `os2' object file format back into `obj', after discovering that `obj' _also_ shouldn't have a link)]681 bull1
-[(pass separator in a module containing a non-trivial MODEND. Flat segments are now declared using the)]670 bull0
-[(FLAT attribute. `os2' is no longer a valid object format name: use `obj'.)]659 bull2
-[(Removed the fixed-size temporary storage in the evaluator. Very very long expressions \(like `mov)]642 bull1
-[(ax,1+1+1+1+...' for two hundred 1s or so\) should now no longer crash NASM.)]631 bull2
-[(Fixed a bug involving segfaults on disassembly of MMX instructions, by changing the meaning of one of)]614 bull1
-[(the operand-type flags in nasm.h. This may cause other apparently unrelated MMX problems; it needs to)]603 bull0
-[(be tested thoroughly.)]592 bull2
-[(Fixed some buffer overrun problems with large OBJ output files. Thanks to DJ Delorie for the bug report)]575 bull1
-[(and fix.)]564 bull2
-[(Made preprocess-only mode actually listen to the )2(%line)0( markers as it prints them, so that it can report)]547 bull1
-[(errors more sanely.)]536 bull2
-[(Re-designed the evaluator to keep more sensible track of expressions involving forward references: can)]519 bull1
-[(now cope with previously-nightmare situations such as:)]508 bull2
-[2( mov ax,foo | bar )]491 code1
-[2( foo equ 1 )]480 code0
-[2( bar equ 2)]469 code2
-[(Added the ALIGN and ALIGNB standard macros.)]452 bull3
-[(Added PIC support in ELF: use of WRT to obtain the four extra relocation types needed.)]435 bull3
-[(Added the ability for output file formats to define their own extensions to the GLOBAL, COMMON and)]418 bull1
-[(EXTERN directives.)]407 bull2
-[(Implemented common-variable alignment, and global-symbol type and size declarations, in ELF.)]390 bull3
-[(Implemented NEAR and FAR keywords for common variables, plus far-common element size)]373 bull1
-[(specification, in OBJ.)]362 bull2
-[(Added a feature whereby EXTERNs and COMMONs in OBJ can be given a default WRT specification)]345 bull1
-[(\(either a segment or a group\).)]334 bull2
-[(Transformed the Unix NASM archive into an auto-configuring package.)]317 bull3
-[(Added a sanity-check for people applying SEG to things which are already segment bases: this previously)]300 bull1
-[(went unnoticed by the SEG processing and caused OBJ-driver panics later.)]289 bull2
-[(Added the ability, in OBJ format, to deal with `MOV EAX,<segment>' type references: OBJ doesn't)]272 bull1
-[(directly support dword-size segment base fixups, but as long as the low two bytes of the constant term are)]261 bull0
-[(zero, a word-size fixup can be generated instead and it will work.)]250 bull2
-[(Added the ability to specify sections' alignment requirements in Win32 object files and pure binary files.)]233 bull3
-[(Added preprocess-time expression evaluation: the )2(%assign)0( \(and )2(%iassign)0(\) directive and the bare )2(%if)]216 bull1
-[(\(and )2(%elif)0(\) conditional. Added relational operators to the evaluator, for use only in )2(%if)0( constructs: the)]205 bull0
-[(standard relationals = < > <= >= <> \(and C-like synonyms == and !=\) plus low-precedence logical)]194 bull0
-[(operators &&, ^^ and ||.)]183 bull2
-[(Added a preprocessor repeat construct: )2(%rep)0( / )2(%exitrep)0( / )2(%endrep)0(.)]166 bull3
-[(Added the __FILE__ and __LINE__ standard macros.)]149 bull3
-[(Added a sanity check for number constants being greater than 0xFFFFFFFF. The warning can be disabled.)]132 bull3
-[(Added the %0 token whereby a variadic multi-line macro can tell how many parameters it's been given in)]115 bull1
-[(a specific invocation.)]104 bull2
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-[(Added )2(%rotate)0(, allowing multi-line macro parameters to be cycled.)]681 bull3
-[(Added the `*' option for the maximum parameter count on multi-line macros, allowing them to take)]664 bull1
-[(arbitrarily many parameters.)]653 bull2
-[(Added the ability for the user-level forms of EXTERN, GLOBAL and COMMON to take more than one)]636 bull1
-[(argument.)]625 bull2
-[(Added the IMPORT and EXPORT directives in OBJ format, to deal with Windows DLLs.)]608 bull3
-[(Added some more preprocessor )2(%if)0( constructs: )2(%ifidn)0( / )2(%ifidni)0( \(exact textual identity\), and )2(%ifid)]591 bull1
-[(/ )2(%ifnum)0( / )2(%ifstr)0( \(token type testing\).)]580 bull2
-[(Added the ability to distinguish SHL AX,1 \(the 8086 version\) from SHL AX,BYTE 1 \(the)]563 bull1
-[(286-and-upwards version whose constant happens to be 1\).)]552 bull2
-[(Added NetBSD/FreeBSD/OpenBSD's variant of a.out format, complete with PIC shared library features.)]535 bull3
-[(Changed NASM's idiosyncratic handling of FCLEX, FDISI, FENI, FINIT, FSAVE, FSTCW, FSTENV,)]518 bull1
-[(and FSTSW to bring it into line with the otherwise accepted standard. The previous behaviour, though it)]507 bull0
-[(was a deliberate feature, was a deliberate feature based on a misunderstanding. Apologies for the)]496 bull0
-[(inconvenience.)]485 bull2
-[(Improved the flexibility of ABSOLUTE: you can now give it an expression rather than being restricted to a)]468 bull1
-[(constant, and it can take relocatable arguments as well.)]457 bull2
-[(Added the ability for a variable to be declared as EXTERN multiple times, and the subsequent definitions)]440 bull1
-[(are just ignored.)]429 bull2
-[(We now allow instruction prefixes \(CS, DS, LOCK, REPZ etc\) to be alone on a line \(without a following)]412 bull1
-[(instruction\).)]401 bull2
-[(Improved sanity checks on whether the arguments to EXTERN, GLOBAL and COMMON are valid)]384 bull1
-[(identifiers.)]373 bull2
-[(Added misc/exebin.mac to allow direct generation of .EXE files by hacking up an EXE header using DB)]356 bull1
-[(and DW; also added test/binexe.asm to demonstrate the use of this. Thanks to Yann Guidon for)]345 bull0
-[(contributing the EXE header code.)]334 bull2
-[(ndisasm forgot to check whether the input file had been successfully opened. Now it does. Doh!)]317 bull3
-[(Added the Cyrix extensions to the MMX instruction set.)]300 bull3
-[(Added a hinting mechanism to allow [EAX+EBX] and [EBX+EAX] to be assembled differently. This is)]283 bull1
-[(important since [ESI+EBP] and [EBP+ESI] have different default base segment registers.)]272 bull2
-[(Added support for the PharLap OMF extension for 4096-byte segment alignment.)]255 bull3
-[{/section-C.3.3 xa}(Version 0.95 released July 1997)](C.3.3)235.8 subh3
-[(Fixed yet another ELF bug. This one manifested if the user relied on the default segment, and attempted to)]218.8 bull1
-[(define global symbols without first explicitly declaring the target segment.)]207.8 bull2
-[(Added makefiles \(for NASM and the RDF tools\) to build Win32 console apps under Symantec C++.)]190.8 bull1
-[(Donated by Mark Junker.)]179.8 bull2
-[(Added `macros.bas' and `insns.bas', QBasic versions of the Perl scripts that convert `standard.mac' to)]162.8 bull1
-[(`macros.c' and convert `insns.dat' to `insnsa.c' and `insnsd.c'. Also thanks to Mark Junker.)]151.8 bull2
-[(Changed the diassembled forms of the conditional instructions so that JB is now emitted as JC, and other)]134.8 bull1
-[(similar changes. Suggested list by Ulrich Doewich.)]123.8 bull2
-[(Added `@' to the list of valid characters to begin an identifier with.)]106.8 bull3
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-[(Documentary changes, notably the addition of the `Common Problems' section in nasm.doc.)]681 bull3
-[(Fixed a bug relating to 32-bit PC-relative fixups in OBJ.)]664 bull3
-[(Fixed a bug in perm_copy\(\) in labels.c which was causing exceptions in cleanup_labels\(\) on some systems.)]647 bull3
-[(Positivity sanity check in TIMES argument changed from a warning to an error following a further)]630 bull1
-[(complaint.)]619 bull2
-[(Changed the acceptable limits on byte and word operands to allow things like `~10111001b' to work.)]602 bull3
-[(Fixed a major problem in the preprocessor which caused seg-faults if macro definitions contained blank)]585 bull1
-[(lines or comment-only lines.)]574 bull2
-[(Fixed inadequate error checking on the commas separating the arguments to `db', `dw' etc.)]557 bull3
-[(Fixed a crippling bug in the handling of macros with operand counts defined with a `+' modifier.)]540 bull3
-[(Fixed a bug whereby object file formats which stored the input file name in the output file \(such as OBJ)]523 bull1
-[(and COFF\) weren't doing so correctly when the output file name was specified on the command line.)]512 bull2
-[(Removed [INC] and [INCLUDE] support for good, since they were obsolete anyway.)]495 bull3
-[(Fixed a bug in OBJ which caused all fixups to be output in 16-bit \(old-format\) FIXUPP records, rather)]478 bull1
-[(than putting the 32-bit ones in FIXUPP32 \(new-format\) records.)]467 bull2
-[(Added, tentatively, OS/2 object file support \(as a minor variant on OBJ\).)]450 bull3
-[(Updates to Fox Cutter's Borland C makefile, Makefile.bc2.)]433 bull3
-[(Removed a spurious second fclose\(\) on the output file.)]416 bull3
-[(Added the `-s' command line option to redirect all messages which would go to stderr \(errors, help text\) to)]399 bull1
-[(stdout instead.)]388 bull2
-[(Added the `-w' command line option to selectively suppress some classes of assembly warning messages.)]371 bull3
-[(Added the `-p' pre-include and `-d' pre-define command-line options.)]354 bull3
-[(Added an include file search path: the `-i' command line option.)]337 bull3
-[(Fixed a silly little preprocessor bug whereby starting a line with a `%!' environment-variable reference)]320 bull1
-[(caused an `unknown directive' error.)]309 bull2
-[(Added the long-awaited listing file support: the `-l' command line option.)]292 bull3
-[(Fixed a problem with OBJ format whereby, in the absence of any explicit segment definition, non-global)]275 bull1
-[(symbols declared in the implicit default segment generated spurious EXTDEF records in the output.)]264 bull2
-[(Added the NASM environment variable.)]247 bull3
-[(From this version forward, Win32 console-mode binaries will be included in the DOS distribution in)]230 bull1
-[(addition to the 16-bit binaries. Added Makefile.vc for this purpose.)]219 bull2
-[(Added `return 0;' to test/objlink.c to prevent compiler warnings.)]202 bull3
-[(Added the __NASM_MAJOR__ and __NASM_MINOR__ standard defines.)]185 bull3
-[(Added an alternative memory-reference syntax in which prefixing an operand with `&' is equivalent to)]168 bull1
-[(enclosing it in square brackets, at the request of Fox Cutter.)]157 bull2
-[(Errors in pass two now cause the program to return a non-zero error code, which they didn't before.)]140 bull3
-[(Fixed the single-line macro cycle detection, which didn't work at all on macros with no parameters)]123 bull1
-[(\(caused an infinite loop\). Also changed the behaviour of single-line macro cycle detection to work like)]112 bull0
-[(cpp, so that macros like `extrn' as given in the documentation can be implemented.)]101 bull2
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-[(Fixed the implementation of WRT, which was too restrictive in that you couldn't do `mov ax,[di+abc wrt)]681 bull1
-[(dgroup]' because \(di+abc\) wasn't a relocatable reference.)]670 bull2
-[{/section-C.3.4 xa}(Version 0.94 released April 1997)](C.3.4)650.8 subh3
-[(Major item: added the macro processor.)]633.8 bull3
-[(Added undocumented instructions SMI, IBTS, XBTS and LOADALL286. Also reorganised CMPXCHG)]616.8 bull1
-[(instruction into early-486 and Pentium forms. Thanks to Thobias Jones for the information.)]605.8 bull2
-[(Fixed two more stupid bugs in ELF, which were causing `ld' to continue to seg-fault in a lot of non-trivial)]588.8 bull1
-[(cases.)]577.8 bull2
-[(Fixed a seg-fault in the label manager.)]560.8 bull3
-[(Stopped FBLD and FBSTP from _requiring_ the TWORD keyword, which is the only option for BCD)]543.8 bull1
-[(loads/stores in any case.)]532.8 bull2
-[(Ensured FLDCW, FSTCW and FSTSW can cope with the WORD keyword, if anyone bothers to provide)]515.8 bull1
-[(it. Previously they complained unless no keyword at all was present.)]504.8 bull2
-[(Some forms of FDIV/FDIVR and FSUB/FSUBR were still inverted: a vestige of a bug that I thought had)]487.8 bull1
-[(been fixed in 0.92. This was fixed, hopefully for good this time...)]476.8 bull2
-[(Another minor phase error \(insofar as a phase error can _ever_ be minor\) fixed, this one occurring in code)]459.8 bull1
-[(of the form)]448.8 bull2
-[2( rol ax,forward_reference )]431.8 code1
-[2( forward_reference equ 1)]420.8 code2
-[(The number supplied to TIMES is now sanity-checked for positivity, and also may be greater than 64K)]403.8 bull1
-[(\(which previously didn't work on 16-bit systems\).)]392.8 bull2
-[(Added Watcom C makefiles, and misc/pmw.bat, donated by Dominik Behr.)]375.8 bull3
-[(Added the INCBIN pseudo-opcode.)]358.8 bull3
-[(Due to the advent of the preprocessor, the [INCLUDE] and [INC] directives have become obsolete. They)]341.8 bull1
-[(are still supported in this version, with a warning, but won't be in the next.)]330.8 bull2
-[(Fixed a bug in OBJ format, which caused incorrect object records to be output when absolute labels were)]313.8 bull1
-[(made global.)]302.8 bull2
-[(Updates to RDOFF subdirectory, and changes to outrdf.c.)]285.8 bull3
-[{/section-C.3.5 xa}(Version 0.93 released January 1997)](C.3.5)266.6 subh3
-[(This release went out in a great hurry after semi-crippling bugs were found in 0.92.)]249.6 norm3
-[(Really )1(did)0( fix the stack overflows this time. *blush*)]232.6 bull3
-[(Had problems with EA instruction sizes changing between passes, when an offset contained a forward)]215.6 bull1
-[(reference and so 4 bytes were allocated for the offset in pass one; by pass two the symbol had been defined)]204.6 bull0
-[(and happened to be a small absolute value, so only 1 byte got allocated, causing instruction size mismatch)]193.6 bull0
-[(between passes and hence incorrect address calculations. Fixed.)]182.6 bull2
-[(Stupid bug in the revised ELF section generation fixed \(associated string-table section for .symtab was)]165.6 bull1
-[(hard-coded as 7, even when this didn't fit with the real section table\). Was causing `ld' to seg-fault under)]154.6 bull0
-[(Linux.)]143.6 bull2
-[(Included a new Borland C makefile, Makefile.bc2, donated by Fox Cutter <lmb@comtch.iea.com>.)]126.6 bull3
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-[{/section-C.3.6 xa}(Version 0.92 released January 1997)](C.3.6)678.8 subh3
-[(The FDIVP/FDIVRP and FSUBP/FSUBRP pairs had been inverted: this was fixed. This also affected the)]661.8 bull1
-[(LCC driver.)]650.8 bull2
-[(Fixed a bug regarding 32-bit effective addresses of the form )2([other_register+ESP])0(.)]633.8 bull3
-[(Documentary changes, notably documentation of the fact that Borland Win32 compilers use `obj' rather)]616.8 bull1
-[(than `win32' object format.)]605.8 bull2
-[(Fixed the COMENT record in OBJ files, which was formatted incorrectly.)]588.8 bull3
-[(Fixed a bug causing segfaults in large RDF files.)]571.8 bull3
-[(OBJ format now strips initial periods from segment and group definitions, in order to avoid complications)]554.8 bull1
-[(with the local label syntax.)]543.8 bull2
-[(Fixed a bug in disassembling far calls and jumps in NDISASM.)]526.8 bull3
-[(Added support for user-defined sections in COFF and ELF files.)]509.8 bull3
-[(Compiled the DOS binaries with a sensible amount of stack, to prevent stack overflows on any arithmetic)]492.8 bull1
-[(expression containing parentheses.)]481.8 bull2
-[(Fixed a bug in handling of files that do not terminate in a newline.)]464.8 bull3
-[{/section-C.3.7 xa}(Version 0.91 released November 1996)](C.3.7)445.6 subh3
-[(Loads of bug fixes.)]428.6 bull3
-[(Support for RDF added.)]411.6 bull3
-[(Support for DBG debugging format added.)]394.6 bull3
-[(Support for 32-bit extensions to Microsoft OBJ format added.)]377.6 bull3
-[(Revised for Borland C: some variable names changed, makefile added.)]360.6 bull3
-[(LCC support revised to actually work.)]343.6 bull3
-[(JMP/CALL NEAR/FAR notation added.)]326.6 bull3
-[(`a16', `o16', `a32' and `o32' prefixes added.)]309.6 bull3
-[(Range checking on short jumps implemented.)]292.6 bull3
-[(MMX instruction support added.)]275.6 bull3
-[(Negative floating point constant support added.)]258.6 bull3
-[(Memory handling improved to bypass 64K barrier under DOS.)]241.6 bull3
-[2($)0( prefix to force treatment of reserved words as identifiers added.)]224.6 bull3
-[(Default-size mechanism for object formats added.)]207.6 bull3
-[(Compile-time configurability added.)]190.6 bull3
-[2(#)0(, )2(@)0(, )2(~)0( and c{?} are now valid characters in labels.)]173.6 bull3
-[2(-e)0( and )2(-k)0( options in NDISASM added.)]156.6 bull3
-[{/section-C.3.8 xa}(Version 0.90 released October 1996)](C.3.8)137.4 subh3
-[(First release version. First support for object file output. Other changes from previous version \(0.3x\) too)]120.4 norm1
-[(numerous to document.)]109.4 norm2
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-[{/index xa}(Index)]642.8 chap3
-[2(!)0( operator, unary)][{/34 pl}(34){el}]607.8 0 idx03
-[2(!=)0( operator)][{/50 pl}(50){el}]596.8 0 idx03
-[2($$)0( token)][{/33 pl}(33,){el}( ){/86 pl}(86){el}]585.8 0 idx03
-[2($)][]574.8 0 idx03
-[(Here token)][{/33 pl}(33){el}]563.8 0 idx13
-[(prefix)][{/26 pl}(26,){el}( ){/29 pl}(29,){el}( ){/89 pl}(89){el}]552.8 0 idx13
-[2(%)0( operator)][{/33 pl}(33){el}]541.8 0 idx03
-[2(%!)][{/60 pl}(60){el}]530.8 0 idx03
-[2(%$)0( and )2(%$$)0( prefixes)][{/54 pl}(54,){el}( ){/55 pl}(55){el}]519.8 0 idx03
-[2(%%)0( operator)][{/33 pl}(33,){el}( ){/44 pl}(44){el}]508.8 0 idx03
-[2(%+)][{/39 pl}(39){el}]497.8 0 idx03
-[2(%?)][{/39 pl}(39){el}]486.8 0 idx03
-[2(%??)][{/39 pl}(39){el}]475.8 0 idx03
-[2(%[)][{/39 pl}(39){el}]464.8 0 idx03
-[2(&)0( operator)][{/33 pl}(33){el}]453.8 0 idx03
-[2(&&)0( operator)][{/50 pl}(50){el}]442.8 0 idx03
-[2(*)0( operator)][{/33 pl}(33){el}]431.8 0 idx03
-[2(+)0( modifier)][{/44 pl}(44){el}]420.8 0 idx03
-[2(+)0( operator)][]409.8 0 idx03
-[(binary)][{/33 pl}(33){el}]398.8 0 idx13
-[(unary)][{/34 pl}(34){el}]387.8 0 idx13
-[2(-)0( operator)][]376.8 0 idx03
-[(binary)][{/33 pl}(33){el}]365.8 0 idx13
-[(unary)][{/34 pl}(34){el}]354.8 0 idx13
-[2(..@)0( symbol prefix)][{/36 pl}(36,){el}( ){/44 pl}(44){el}]343.8 0 idx03
-[2(/)0( operator)][{/33 pl}(33){el}]332.8 0 idx03
-[2(//)0( operator)][{/33 pl}(33){el}]321.8 0 idx03
-[2(<)0( operator)][{/50 pl}(50){el}]310.8 0 idx03
-[2(<<)0( operator)][{/33 pl}(33){el}]299.8 0 idx03
-[2(<=)0( operator)][{/50 pl}(50){el}]288.8 0 idx03
-[2(<>)0( operator)][{/50 pl}(50){el}]277.8 0 idx03
-[2(=)0( operator)][{/50 pl}(50){el}]266.8 0 idx03
-[2(==)0( operator)][{/50 pl}(50){el}]255.8 0 idx03
-[2(>)0( operator)][{/50 pl}(50){el}]244.8 0 idx03
-[2(>=)0( operator)][{/50 pl}(50){el}]233.8 0 idx03
-[2(>>)0( operator)][{/33 pl}(33){el}]222.8 0 idx03
-[2(?)0( MASM syntax)][{/27 pl}(27){el}]211.8 0 idx03
-[2(^)0( operator)][{/33 pl}(33){el}]200.8 0 idx03
-[2(^^)0( operator)][{/50 pl}(50){el}]189.8 0 idx03
-[2(|)0( operator)][{/33 pl}(33){el}]178.8 0 idx03
-[2(||)0( operator)][{/50 pl}(50){el}]167.8 0 idx03
-[2(~)0( operator)][{/34 pl}(34){el}]156.8 0 idx03
-[2(%0)0( parameter count)][{/45 pl}(45){el}]145.8 0 idx03
-[2(%+1)0( and )2(%-1)0( syntax)][{/47 pl}(47){el}]134.8 0 idx03
-[(16-bit mode, versus 32-bit mode)][{/67 pl}(67){el}]123.8 0 idx03
-[(64-bit displacement)][{/114 pl}(114){el}]112.8 0 idx03
-[(64-bit immediate)][{/113 pl}(113){el}]101.8 0 idx03
-[2(-a)0( option)][{/21 pl}(21,){el}( ){/120 pl}(120){el}]607.8 1 idx03
-[2(A16)][{/26 pl}(26){el}]596.8 1 idx03
-[2(a16)][{/111 pl}(111){el}]585.8 1 idx03
-[2(A32)][{/26 pl}(26){el}]574.8 1 idx03
-[2(a32)][{/111 pl}(111){el}]563.8 1 idx03
-[2(A64)][{/26 pl}(26){el}]552.8 1 idx03
-[2(a64)][{/111 pl}(111){el}]541.8 1 idx03
-[2(a86)][{/14 pl}(14,){el}( ){/24 pl}(24,){el}( ){/25 pl}(25){el}]530.8 1 idx03
-[2(ABS)][{/29 pl}(29){el}]519.8 1 idx03
-[2(ABSOLUTE)][{/69 pl}(69,){el}( ){/76 pl}(76){el}]508.8 1 idx03
-[(addition)][{/33 pl}(33){el}]497.8 1 idx03
-[(addressing, mixed-size)][{/110 pl}(110){el}]486.8 1 idx03
-[(address-size prefixes)][{/26 pl}(26){el}]475.8 1 idx03
-[(algebra)][{/29 pl}(29){el}]464.8 1 idx03
-[2(ALIGN)][{/64 pl}(64,){el}( ){/66 pl}(66,){el}( ){/73 pl}(73,){el}( ){/76 pl}(76){el}]453.8 1 idx03
-[(smart)][{/66 pl}(66){el}]442.8 1 idx13
-[2(ALIGNB)][{/64 pl}(64){el}]431.8 1 idx03
-[(alignment)][]420.8 1 idx03
-[(in )2(bin)0( sections)][{/74 pl}(74){el}]409.8 1 idx13
-[(in )2(elf)0( sections)][{/85 pl}(85){el}]398.8 1 idx13
-[(in )2(obj)0( sections)][{/76 pl}(76){el}]387.8 1 idx13
-[(in )2(win32)0( sections)][{/79 pl}(79){el}]376.8 1 idx13
-[(of )2(elf)0( common variables)][{/87 pl}(87){el}]365.8 1 idx13
-[2(ALIGNMODE)][{/66 pl}(66){el}]354.8 1 idx03
-[2(__ALIGNMODE__)][{/66 pl}(66){el}]343.8 1 idx03
-[2(ALINK)][{/91 pl}(91){el}]332.8 1 idx03
-[2(alink.sourceforge.net)][{/91 pl}(91){el}]321.8 1 idx03
-[2(all)][{/23 pl}(23){el}]310.8 1 idx03
-[2(alloc)][{/85 pl}(85){el}]299.8 1 idx03
-[(alternate register names)][{/66 pl}(66){el}]288.8 1 idx03
-[2(alt.lang.asm)][{/14 pl}(14){el}]277.8 1 idx03
-[2(altreg)][{/66 pl}(66){el}]266.8 1 idx03
-[(ambiguity)][{/24 pl}(24){el}]255.8 1 idx03
-[2(a.out)][]244.8 1 idx03
-[(BSD version)][{/88 pl}(88){el}]233.8 1 idx13
-[(Linux version)][{/88 pl}(88){el}]222.8 1 idx13
-[2(aout)][{/88 pl}(88){el}]211.8 1 idx03
-[2(aoutb)][{/88 pl}(88,){el}( ){/106 pl}(106){el}]200.8 1 idx03
-[2(%arg)][{/57 pl}(57){el}]189.8 1 idx03
-[2(arg)][{/98 pl}(98,){el}( ){/105 pl}(105){el}]178.8 1 idx03
-[2(as86)][{/14 pl}(14,){el}( ){/88 pl}(88){el}]167.8 1 idx03
-[(assembler directives)][{/67 pl}(67){el}]156.8 1 idx03
-[(assembly-time options)][{/21 pl}(21){el}]145.8 1 idx03
-[2(%assign)][{/40 pl}(40){el}]134.8 1 idx03
-[2(ASSUME)][{/25 pl}(25){el}]123.8 1 idx03
-[2(AT)][{/63 pl}(63){el}]112.8 1 idx03
-[(Autoconf)][{/16 pl}(16){el}]101.8 1 idx03
-(206)pageeven
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-%%Page: 207 207
-%%BeginPageSetup
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-%%EndPageSetup
-/207 pa
-[2(autoexec.bat)][{/15 pl}(15){el}]681 0 idx03
-[2(auto-sync)][{/120 pl}(120){el}]670 0 idx03
-[2(-b)][{/119 pl}(119){el}]659 0 idx03
-[(bin)][{/18 pl}(18,){el}( ){/73 pl}(73){el}]648 0 idx03
-[(multisection)][{/74 pl}(74){el}]637 0 idx13
-[(binary)][{/29 pl}(29){el}]626 0 idx03
-[(binary files)][{/27 pl}(27){el}]615 0 idx03
-[(bit shift)][{/33 pl}(33){el}]604 0 idx03
-[2(BITS)][{/67 pl}(67,){el}( ){/73 pl}(73){el}]593 0 idx03
-[2(__BITS__)][{/61 pl}(61){el}]582 0 idx03
-[(bitwise AND)][{/33 pl}(33){el}]571 0 idx03
-[(bitwise OR)][{/33 pl}(33){el}]560 0 idx03
-[(bitwise XOR)][{/33 pl}(33){el}]549 0 idx03
-[(block IFs)][{/55 pl}(55){el}]538 0 idx03
-[(boot loader)][{/73 pl}(73){el}]527 0 idx03
-[(boot sector)][{/116 pl}(116){el}]516 0 idx03
-[(Borland)][]505 0 idx03
-[(Pascal)][{/99 pl}(99){el}]494 0 idx13
-[(Win32 compilers)][{/75 pl}(75){el}]483 0 idx13
-[(braces)][]472 0 idx03
-[(after )2(%)0( sign)][{/47 pl}(47){el}]461 0 idx13
-[(around macro parameters)][{/42 pl}(42){el}]450 0 idx13
-[(BSD)][{/106 pl}(106){el}]439 0 idx03
-[2(.bss)][{/85 pl}(85,){el}( ){/88 pl}(88,){el}( ){/89 pl}(89){el}]428 0 idx03
-[(bugs)][{/117 pl}(117){el}]417 0 idx03
-[2(bugtracker)][{/117 pl}(117){el}]406 0 idx03
-[2(BYTE)][{/116 pl}(116){el}]395 0 idx03
-[(C calling convention)][{/96 pl}(96,){el}( ){/103 pl}(103){el}]384 0 idx03
-[(C symbol names)][{/94 pl}(94){el}]373 0 idx03
-[2(c16.mac)][{/98 pl}(98,){el}( ){/101 pl}(101){el}]362 0 idx03
-[2(c32.mac)][{/105 pl}(105){el}]351 0 idx03
-[2(CALL FAR)][{/34 pl}(34){el}]340 0 idx03
-[(case sensitivity)][{/24 pl}(24,){el}( ){/37 pl}(37,){el}( ){/38 pl}(38,){el}( ){/40 pl}(40,){el}( ){/42 pl}(42,){el}( ){/43 pl}(43,){el}( ){/50 pl}(50,){el}( ){/77 pl}(77){el}]329 0 idx03
-[(changing sections)][{/68 pl}(68){el}]318 0 idx03
-[(character constant)][{/27 pl}(27,){el}( ){/31 pl}(31){el}]307 0 idx03
-[(character strings)][{/30 pl}(30){el}]296 0 idx03
-[(circular references)][{/37 pl}(37){el}]285 0 idx03
-[2(CLASS)][{/76 pl}(76){el}]274 0 idx03
-[2(%clear)][{/60 pl}(60){el}]263 0 idx03
-[2(coff)][{/85 pl}(85){el}]252 0 idx03
-[(colon)][{/26 pl}(26){el}]241 0 idx03
-[2(.COM)][{/73 pl}(73,){el}( ){/93 pl}(93){el}]230 0 idx03
-[(command-line)][{/17 pl}(17,){el}( ){/73 pl}(73){el}]219 0 idx03
-[(commas in macro parameters)][{/45 pl}(45){el}]208 0 idx03
-[2(.comment)][{/85 pl}(85){el}]197 0 idx03
-[2(COMMON)][{/70 pl}(70,){el}( ){/75 pl}(75){el}]186 0 idx03
-[2(elf)0( extensions to)][{/87 pl}(87){el}]175 0 idx13
-[2(obj)0( extensions to)][{/78 pl}(78){el}]164 0 idx13
-[(Common Object File Format)][{/85 pl}(85){el}]153 0 idx03
-[(common variables)][{/70 pl}(70){el}]142 0 idx03
-[(alignment in )2(elf)][{/87 pl}(87){el}]131 0 idx13
-[(element size)][{/78 pl}(78){el}]120 0 idx13
-[2(comp.lang.asm.x86)][{/14 pl}(14,){el}( ){/15 pl}(15){el}]109 0 idx03
-[2(comp.os.msdos.programmer)][{/94 pl}(94){el}]681 1 idx03
-[(concatenating macro parameters)][{/46 pl}(46){el}]670 1 idx03
-[(concatenating strings)][{/41 pl}(41){el}]659 1 idx03
-[(condition codes as macro parameters)][{/47 pl}(47){el}]648 1 idx03
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-[2(NASMENV)][{/23 pl}(23){el}]494 1 idx03
-[2(nasm.exe)][{/15 pl}(15){el}]483 1 idx03
-[2(nasm -hf)][{/18 pl}(18){el}]472 1 idx03
-[2(__NASM_MAJOR__)][{/60 pl}(60){el}]461 1 idx03
-[2(__NASM_MINOR__)][{/60 pl}(60){el}]450 1 idx03
-[2(nasm.out)][{/18 pl}(18){el}]439 1 idx03
-[2(___NASM_PATCHLEVEL__)][{/60 pl}(60){el}]428 1 idx03
-[2(__NASM_SNAPSHOT__)][{/60 pl}(60){el}]417 1 idx03
-[2(__NASM_SUBMINOR__)][{/60 pl}(60){el}]406 1 idx03
-[2(__NASM_VER__)][{/60 pl}(60){el}]395 1 idx03
-[2(__NASM_VERSION_ID__)][{/60 pl}(60){el}]384 1 idx03
-[2(nasm-XXX-dos.zip)][{/15 pl}(15){el}]373 1 idx03
-[2(nasm-XXX.tar.gz)][{/16 pl}(16){el}]362 1 idx03
-[2(nasm-XXX-win32.zip)][{/15 pl}(15){el}]351 1 idx03
-[2(nasm-XXX.zip)][{/15 pl}(15){el}]340 1 idx03
-[(ndisasm)][{/119 pl}(119){el}]329 1 idx03
-[2(ndisasm.1)][{/16 pl}(16){el}]318 1 idx03
-[2(ndisasm.exe)][{/15 pl}(15){el}]307 1 idx03
-[(near call)][{/25 pl}(25){el}]296 1 idx03
-[(near common variables)][{/78 pl}(78){el}]285 1 idx03
-[(NetBSD)][{/88 pl}(88,){el}( ){/106 pl}(106){el}]274 1 idx03
-[(new releases)][{/15 pl}(15){el}]263 1 idx03
-[2(noalloc)][{/85 pl}(85){el}]252 1 idx03
-[2(nobits)][{/74 pl}(74,){el}( ){/85 pl}(85){el}]241 1 idx03
-[2(noexec)][{/85 pl}(85){el}]230 1 idx03
-[2(.nolist)][{/48 pl}(48){el}]219 1 idx03
-[(`nowait')][{/25 pl}(25){el}]208 1 idx03
-[2(nowrite)][{/85 pl}(85){el}]197 1 idx03
-[2(number-overflow)][{/22 pl}(22){el}]186 1 idx03
-[(numeric constants)][{/27 pl}(27,){el}( ){/29 pl}(29){el}]175 1 idx03
-[2(-O)0( option)][{/21 pl}(21){el}]164 1 idx03
-[2(-o)0( option)][{/17 pl}(17,){el}( ){/119 pl}(119){el}]153 1 idx03
-[2(O16)][{/26 pl}(26){el}]142 1 idx03
-[2(o16)][{/111 pl}(111){el}]131 1 idx03
-[2(O32)][{/26 pl}(26){el}]120 1 idx03
-[2(o32)][{/112 pl}(112){el}]109 1 idx03
-(210)pageeven
-restore showpage
-%%Page: 211 211
-%%BeginPageSetup
-save
-%%EndPageSetup
-/211 pa
-[2(O64)][{/26 pl}(26){el}]681 0 idx03
-[2(.OBJ)][{/91 pl}(91){el}]670 0 idx03
-[2(obj)][{/75 pl}(75){el}]659 0 idx03
-[2(object)][{/87 pl}(87,){el}( ){/89 pl}(89){el}]648 0 idx03
-[(octal)][{/29 pl}(29){el}]637 0 idx03
-[2(OF_DBG)][{/90 pl}(90){el}]626 0 idx03
-[2(OF_DEFAULT)][{/18 pl}(18){el}]615 0 idx03
-[2(OFFSET)][{/24 pl}(24){el}]604 0 idx03
-[(OMF)][{/75 pl}(75){el}]593 0 idx03
-[(omitted parameters)][{/45 pl}(45){el}]582 0 idx03
-[(one's complement)][{/34 pl}(34){el}]571 0 idx03
-[(OpenBSD)][{/88 pl}(88,){el}( ){/106 pl}(106){el}]560 0 idx03
-[(operands)][{/26 pl}(26){el}]549 0 idx03
-[(operand-size prefixes)][{/26 pl}(26){el}]538 0 idx03
-[(operating system)][{/73 pl}(73){el}]527 0 idx03
-[(writing)][{/110 pl}(110){el}]516 0 idx13
-[(operators)][{/33 pl}(33){el}]505 0 idx03
-[2(ORG)][{/73 pl}(73,){el}( ){/93 pl}(93,){el}( ){/94 pl}(94,){el}( ){/116 pl}(116){el}]494 0 idx03
-[2(orphan-labels)][{/22 pl}(22,){el}( ){/26 pl}(26){el}]483 0 idx03
-[(OS/2)][{/75 pl}(75,){el}( ){/76 pl}(76){el}]472 0 idx03
-[2(osabi)][{/85 pl}(85){el}]461 0 idx03
-[(other preprocessor directives)][{/59 pl}(59){el}]450 0 idx03
-[(out of range, jumps)][{/116 pl}(116){el}]439 0 idx03
-[(output file format)][{/18 pl}(18){el}]428 0 idx03
-[(output formats)][{/73 pl}(73){el}]417 0 idx03
-[2(__OUTPUT_FORMAT__)][{/61 pl}(61){el}]406 0 idx03
-[(overlapping segments)][{/34 pl}(34){el}]395 0 idx03
-[2(OVERLAY)][{/76 pl}(76){el}]384 0 idx03
-[(overloading)][]373 0 idx03
-[(multi-line macros)][{/43 pl}(43){el}]362 0 idx13
-[(single-line macros)][{/38 pl}(38){el}]351 0 idx13
-[2(-P)0( option)][{/20 pl}(20){el}]340 0 idx03
-[2(-p)0( option)][{/20 pl}(20,){el}( ){/53 pl}(53){el}]329 0 idx03
-[(paradox)][{/35 pl}(35){el}]318 0 idx03
-[2(PASCAL)][{/101 pl}(101){el}]307 0 idx03
-[(Pascal calling convention)][{/100 pl}(100){el}]296 0 idx03
-[2(__PASS__)][{/62 pl}(62){el}]285 0 idx03
-[(passes, assembly)][]274 0 idx03
-[2(PATH)][{/15 pl}(15){el}]263 0 idx03
-[2(%pathsearch)][{/20 pl}(20,){el}( ){/53 pl}(53){el}]252 0 idx03
-[(period)][{/35 pl}(35){el}]241 0 idx03
-[(Perl)][{/15 pl}(15){el}]230 0 idx03
-[(perverse)][{/20 pl}(20){el}]219 0 idx03
-[(PharLap)][{/76 pl}(76){el}]208 0 idx03
-[(PIC)][{/86 pl}(86,){el}( ){/88 pl}(88,){el}( ){/106 pl}(106){el}]197 0 idx03
-[2(..plt)][{/86 pl}(86){el}]186 0 idx03
-[2(PLT)0( relocations)][{/86 pl}(86,){el}( ){/108 pl}(108,){el}( ){/109 pl}(109){el}]175 0 idx03
-[(plt relocations)][{/109 pl}(109){el}]164 0 idx03
-[2(%pop)][{/54 pl}(54){el}]153 0 idx03
-[(position-independent code)][{/86 pl}(86,){el}( ){/88 pl}(88,){el}( ){/106 pl}(106){el}]142 0 idx03
-[2(--postfix)][{/23 pl}(23){el}]131 0 idx03
-[(precedence)][{/33 pl}(33){el}]120 0 idx03
-[(pre-defining macros)][{/20 pl}(20,){el}( ){/38 pl}(38){el}]109 0 idx03
-[(preferred)][{/34 pl}(34){el}]681 1 idx03
-[2(--prefix)][{/23 pl}(23){el}]670 1 idx03
-[(pre-including files)][{/20 pl}(20){el}]659 1 idx03
-[(preprocess-only mode)][{/21 pl}(21){el}]648 1 idx03
-[(preprocessor)][{/21 pl}(21,){el}( ){/28 pl}(28,){el}( ){/33 pl}(33,){el}( ){/37 pl}(37){el}]637 1 idx03
-[(preprocessor expressions)][{/21 pl}(21){el}]626 1 idx03
-[(preprocessor loops)][{/52 pl}(52){el}]615 1 idx03
-[(preprocessor variables)][{/40 pl}(40){el}]604 1 idx03
-[(primitive directives)][{/67 pl}(67){el}]593 1 idx03
-[2(PRIVATE)][{/75 pl}(75){el}]582 1 idx03
-[2(proc)][{/89 pl}(89,){el}( ){/98 pl}(98,){el}( ){/105 pl}(105){el}]571 1 idx03
-[(procedure linkage table)][{/86 pl}(86,){el}( ){/108 pl}(108,){el}( ){/109 pl}(109){el}]560 1 idx03
-[(processor mode)][{/67 pl}(67){el}]549 1 idx03
-[2(progbits)][{/74 pl}(74,){el}( ){/85 pl}(85){el}]538 1 idx03
-[(program entry point)][{/78 pl}(78,){el}( ){/91 pl}(91){el}]527 1 idx03
-[(program origin)][{/73 pl}(73){el}]516 1 idx03
-[2(protected)][{/87 pl}(87){el}]505 1 idx03
-[(pseudo-instructions)][{/27 pl}(27){el}]494 1 idx03
-[2(PUBLIC)][{/70 pl}(70,){el}( ){/75 pl}(75){el}]483 1 idx03
-[(pure binary)][{/73 pl}(73){el}]472 1 idx03
-[2(%push)][{/54 pl}(54){el}]461 1 idx03
-[2(__QNaN__)][{/32 pl}(32){el}]450 1 idx03
-[(quick start)][{/24 pl}(24){el}]439 1 idx03
-[2(QWORD)][{/27 pl}(27){el}]428 1 idx03
-[2(-r)][{/119 pl}(119){el}]417 1 idx03
-[2(rdf)][{/88 pl}(88){el}]406 1 idx03
-[2(rdoff)0( subdirectory)][{/16 pl}(16,){el}( ){/88 pl}(88,){el}( ){/89 pl}(89){el}]395 1 idx03
-[(recursive multi-line macros)][{/43 pl}(43){el}]384 1 idx03
-[(redirecting errors)][{/20 pl}(20){el}]373 1 idx03
-[2(REL)][{/29 pl}(29,){el}( ){/68 pl}(68){el}]362 1 idx03
-[(relational operators)][{/50 pl}(50){el}]351 1 idx03
-[(release candidates)][{/15 pl}(15){el}]340 1 idx03
-[(Relocatable Dynamic Object File Format)][{/88 pl}(88){el}]329 1 idx03
-[(relocations, PIC-specific)][{/86 pl}(86){el}]318 1 idx03
-[(removing contexts)][{/54 pl}(54){el}]307 1 idx03
-[(renaming contexts)][{/55 pl}(55){el}]296 1 idx03
-[2(%rep)][{/28 pl}(28,){el}( ){/52 pl}(52){el}]285 1 idx03
-[(repeating)][{/28 pl}(28,){el}( ){/52 pl}(52){el}]274 1 idx03
-[2(%repl)][{/55 pl}(55){el}]263 1 idx03
-[(reporting bugs)][{/117 pl}(117){el}]252 1 idx03
-[2(RESB)][{/25 pl}(25,){el}( ){/27 pl}(27){el}]241 1 idx03
-[2(RESD)][{/27 pl}(27){el}]230 1 idx03
-[2(RESO)][{/27 pl}(27){el}]219 1 idx03
-[2(RESQ)][{/27 pl}(27){el}]208 1 idx03
-[2(REST)][{/27 pl}(27){el}]197 1 idx03
-[2(RESW)][{/27 pl}(27){el}]186 1 idx03
-[2(RESY)][{/27 pl}(27){el}]175 1 idx03
-[2(%rmacro)][{/43 pl}(43){el}]164 1 idx03
-[2(.rodata)][{/85 pl}(85){el}]153 1 idx03
-[2(%rotate)][{/46 pl}(46){el}]142 1 idx03
-[(rotating macro parameters)][{/46 pl}(46){el}]131 1 idx03
-[2(-s)0( option)][{/20 pl}(20,){el}( ){/120 pl}(120){el}]120 1 idx03
-[(searching for include files)][{/53 pl}(53){el}]109 1 idx03
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-/212 pa
-[2(__SECT__)][{/68 pl}(68,){el}( ){/69 pl}(69){el}]681 0 idx03
-[2(SECTION)][{/68 pl}(68){el}]670 0 idx03
-[2(elf)0( extensions to)][{/85 pl}(85){el}]659 0 idx13
-[2(win32)0( extensions to)][{/79 pl}(79){el}]648 0 idx13
-[(section alignment)][]637 0 idx03
-[(in )2(bin)][{/74 pl}(74){el}]626 0 idx13
-[(in )2(elf)][{/85 pl}(85){el}]615 0 idx13
-[(in )2(obj)][{/76 pl}(76){el}]604 0 idx13
-[(in )2(win32)][{/79 pl}(79){el}]593 0 idx13
-[(section, bin extensions to)][{/73 pl}(73){el}]582 0 idx03
-[2(SEG)][{/34 pl}(34,){el}( ){/75 pl}(75){el}]571 0 idx03
-[2(SEGMENT)][{/68 pl}(68){el}]560 0 idx03
-[2(elf)0( extensions to)][{/75 pl}(75){el}]549 0 idx13
-[(segment address)][{/34 pl}(34){el}]538 0 idx03
-[(segment alignment)][]527 0 idx03
-[(in )2(bin)][{/74 pl}(74){el}]516 0 idx13
-[(in )2(obj)][{/76 pl}(76){el}]505 0 idx13
-[(segment names, Borland Pascal)][{/101 pl}(101){el}]494 0 idx03
-[(segment override)][{/25 pl}(25,){el}( ){/26 pl}(26){el}]483 0 idx03
-[(segments)][{/34 pl}(34){el}]472 0 idx03
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-[(separator character)][{/23 pl}(23){el}]450 0 idx03
-[(shared libraries)][{/88 pl}(88,){el}( ){/106 pl}(106){el}]439 0 idx03
-[(shared library)][{/87 pl}(87){el}]428 0 idx03
-[2(shift)0( command)][{/46 pl}(46){el}]417 0 idx03
-[(SIB byte)][]406 0 idx03
-[(signed division)][{/33 pl}(33){el}]395 0 idx03
-[(signed modulo)][{/33 pl}(33){el}]384 0 idx03
-[(single-line macros)][{/37 pl}(37){el}]373 0 idx03
-[(size, of symbols)][{/87 pl}(87){el}]362 0 idx03
-[2(smartalign)][{/66 pl}(66){el}]351 0 idx03
-[2(__SNaN__)][{/32 pl}(32){el}]340 0 idx03
-[(snapshots, daily development)][{/15 pl}(15){el}]329 0 idx03
-[(Solaris x86)][{/85 pl}(85){el}]318 0 idx03
-[2(-soname)][{/109 pl}(109){el}]307 0 idx03
-[(sound)][{/27 pl}(27){el}]296 0 idx03
-[(source code)][{/15 pl}(15){el}]285 0 idx03
-[(source-listing file)][{/18 pl}(18){el}]274 0 idx03
-[(square brackets)][{/24 pl}(24,){el}( ){/28 pl}(28){el}]263 0 idx03
-[2(srec)][{/74 pl}(74){el}]252 0 idx03
-[2(STACK)][{/75 pl}(75){el}]241 0 idx03
-[(stack relative preprocessor directives)][{/57 pl}(57){el}]230 0 idx03
-[2(%stacksize)][{/57 pl}(57){el}]219 0 idx03
-[(standard macro packages)][{/66 pl}(66){el}]208 0 idx03
-[(standard macros)][{/60 pl}(60){el}]197 0 idx03
-[(standardized section names)][{/68 pl}(68,){el}( ){/79 pl}(79,){el}( ){/85 pl}(85,){el}( ){/88 pl}(88,){el}( ){/89 pl}(89){el}]186 0 idx03
-[2(..start)][{/78 pl}(78,){el}( ){/91 pl}(91){el}]175 0 idx03
-[2(start=)][{/74 pl}(74){el}]164 0 idx03
-[2(stderr)][{/20 pl}(20){el}]153 0 idx03
-[2(stdout)][{/20 pl}(20){el}]142 0 idx03
-[2(%strcat)][{/41 pl}(41){el}]131 0 idx03
-[2(STRICT)][{/34 pl}(34){el}]120 0 idx03
-[(string constant)][{/27 pl}(27){el}]109 0 idx03
-[(string constants)][{/31 pl}(31){el}]681 1 idx03
-[(string length)][{/41 pl}(41){el}]670 1 idx03
-[(string manipulation in macros)][{/41 pl}(41){el}]659 1 idx03
-[(strings)][{/30 pl}(30){el}]648 1 idx03
-[2(%strlen)][{/41 pl}(41){el}]637 1 idx03
-[2(STRUC)][{/62 pl}(62,){el}( ){/69 pl}(69,){el}( ){/98 pl}(98,){el}( ){/105 pl}(105){el}]626 1 idx03
-[(stub preprocessor)][{/21 pl}(21){el}]615 1 idx03
-[2(%substr)][{/42 pl}(42){el}]604 1 idx03
-[(subtraction)][{/33 pl}(33){el}]593 1 idx03
-[(suppressible warning)][{/22 pl}(22){el}]582 1 idx03
-[(suppressing preprocessing)][{/21 pl}(21){el}]571 1 idx03
-[(switching between sections)][{/68 pl}(68){el}]560 1 idx03
-[2(..sym)][{/86 pl}(86){el}]549 1 idx03
-[(symbol sizes, specifying)][{/87 pl}(87){el}]538 1 idx03
-[(symbol types, specifying)][{/87 pl}(87){el}]527 1 idx03
-[(symbols)][]516 1 idx03
-[(exporting from DLLs)][{/77 pl}(77){el}]505 1 idx13
-[(importing from DLLs)][{/77 pl}(77){el}]494 1 idx13
-[2(synchronisation)][{/120 pl}(120){el}]483 1 idx03
-[2(.SYS)][{/73 pl}(73,){el}( ){/94 pl}(94){el}]472 1 idx03
-[2(-t)][{/22 pl}(22){el}]461 1 idx03
-[2(TASM)][{/14 pl}(14,){el}( ){/22 pl}(22){el}]450 1 idx03
-[(tasm)][{/24 pl}(24,){el}( ){/75 pl}(75){el}]439 1 idx03
-[2(.tbss)][{/85 pl}(85){el}]428 1 idx03
-[2(TBYTE)][{/25 pl}(25){el}]417 1 idx03
-[2(.tdata)][{/85 pl}(85){el}]406 1 idx03
-[2(test)0( subdirectory)][{/91 pl}(91){el}]395 1 idx03
-[(testing)][]384 1 idx03
-[(arbitrary numeric expressions)][{/50 pl}(50){el}]373 1 idx13
-[(context stack)][{/50 pl}(50){el}]362 1 idx13
-[(exact text identity)][{/50 pl}(50){el}]351 1 idx13
-[(multi-line macro existence)][{/49 pl}(49){el}]340 1 idx13
-[(single-line macro existence)][{/49 pl}(49){el}]329 1 idx13
-[(token types)][{/51 pl}(51){el}]318 1 idx13
-[2(.text)][{/85 pl}(85,){el}( ){/88 pl}(88,){el}( ){/89 pl}(89){el}]307 1 idx03
-[2(_TEXT)][{/96 pl}(96){el}]296 1 idx03
-[(thread local storage)][{/87 pl}(87){el}]285 1 idx03
-[2(__TIME__)][{/61 pl}(61){el}]274 1 idx03
-[2(__TIME_NUM__)][{/61 pl}(61){el}]263 1 idx03
-[2(TIMES)][{/27 pl}(27,){el}( ){/28 pl}(28,){el}( ){/35 pl}(35,){el}( ){/116 pl}(116,){el}( ){/117 pl}(117){el}]252 1 idx03
-[2(TLINK)][{/93 pl}(93){el}]241 1 idx03
-[2(tls)][{/85 pl}(85,){el}( ){/87 pl}(87){el}]230 1 idx03
-[2(..tlsie)][{/87 pl}(87){el}]219 1 idx03
-[(trailing colon)][{/26 pl}(26){el}]208 1 idx03
-[2(TWORD)][{/25 pl}(25,){el}( ){/27 pl}(27){el}]197 1 idx03
-[(type, of symbols)][{/87 pl}(87){el}]186 1 idx03
-[2(-U)0( option)][{/21 pl}(21){el}]175 1 idx03
-[2(-u)0( option)][{/21 pl}(21,){el}( ){/119 pl}(119){el}]164 1 idx03
-[(unary operators)][{/34 pl}(34){el}]153 1 idx03
-[2(%undef)][{/21 pl}(21,){el}( ){/40 pl}(40){el}]142 1 idx03
-[(undefining macros)][{/21 pl}(21){el}]131 1 idx03
-[(underscore, in C symbols)][{/94 pl}(94){el}]120 1 idx03
-[(Unicode)][{/30 pl}(30,){el}( ){/31 pl}(31){el}]109 1 idx03
-(212)pageeven
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-%%EndPageSetup
-/213 pa
-[(uninitialized)][{/27 pl}(27){el}]681 0 idx03
-[(uninitialized storage)][{/25 pl}(25){el}]670 0 idx03
-[(Unix)][{/16 pl}(16){el}]659 0 idx03
-[(SCO)][{/85 pl}(85){el}]648 0 idx13
-[(source archive)][{/16 pl}(16){el}]637 0 idx13
-[(System V)][{/85 pl}(85){el}]626 0 idx13
-[(UnixWare)][{/85 pl}(85){el}]615 0 idx03
-[2(%unmacro)][{/48 pl}(48){el}]604 0 idx03
-[(unrolled loops)][{/28 pl}(28){el}]593 0 idx03
-[(unsigned division)][{/33 pl}(33){el}]582 0 idx03
-[(unsigned modulo)][{/33 pl}(33){el}]571 0 idx03
-[2(UPPERCASE)][{/24 pl}(24,){el}( ){/77 pl}(77){el}]560 0 idx03
-[2(%use)][{/54 pl}(54,){el}( ){/66 pl}(66){el}]549 0 idx03
-[2(__USE_*__)][{/62 pl}(62){el}]538 0 idx03
-[2(USE16)][{/68 pl}(68,){el}( ){/76 pl}(76){el}]527 0 idx03
-[2(USE32)][{/68 pl}(68,){el}( ){/76 pl}(76){el}]516 0 idx03
-[2(user)][{/23 pl}(23){el}]505 0 idx03
-[(user-defined errors)][{/58 pl}(58){el}]494 0 idx03
-[(user-level assembler directives)][{/60 pl}(60){el}]483 0 idx03
-[(user-level directives)][{/67 pl}(67){el}]472 0 idx03
-[2(__UTC_DATE__)][{/61 pl}(61){el}]461 0 idx03
-[2(__UTC_DATE_NUM__)][{/61 pl}(61){el}]450 0 idx03
-[2(__UTC_TIME__)][{/61 pl}(61){el}]439 0 idx03
-[2(__UTC_TIME_NUM__)][{/61 pl}(61){el}]428 0 idx03
-[(UTF-16)][{/31 pl}(31){el}]417 0 idx03
-[(UTF-32)][{/31 pl}(31){el}]406 0 idx03
-[(UTF-8)][{/30 pl}(30){el}]395 0 idx03
-[2(__utf16__)][{/31 pl}(31){el}]384 0 idx03
-[2(__utf32__)][{/31 pl}(31){el}]373 0 idx03
-[2(-v)0( option)][{/23 pl}(23){el}]362 0 idx03
-[(VAL)][{/91 pl}(91){el}]351 0 idx03
-[(valid characters)][{/26 pl}(26){el}]340 0 idx03
-[(variable types)][{/24 pl}(24){el}]329 0 idx03
-[(version)][{/23 pl}(23){el}]318 0 idx03
-[(version number of NASM)][{/60 pl}(60){el}]307 0 idx03
-[2(vfollows=)][{/74 pl}(74){el}]296 0 idx03
-[(Visual C++)][{/79 pl}(79){el}]285 0 idx03
-[2(vstart=)][{/74 pl}(74){el}]274 0 idx03
-[2(-W)0( option)][{/22 pl}(22){el}]263 0 idx03
-[2(-w)0( option)][{/22 pl}(22){el}]252 0 idx03
-[2(%warning)][{/58 pl}(58){el}]241 0 idx03
-[(warnings)][{/22 pl}(22){el}]230 0 idx03
-[2([warning *warning-name])][{/23 pl}(23){el}]219 0 idx03
-[2([warning +warning-name])][{/23 pl}(23){el}]208 0 idx03
-[2([warning -warning-name])][{/23 pl}(23){el}]197 0 idx03
-[(website)][{/15 pl}(15){el}]186 0 idx03
-[2(win64)][{/81 pl}(81,){el}( ){/113 pl}(113){el}]175 0 idx03
-[(Win64)][{/75 pl}(75,){el}( ){/79 pl}(79,){el}( ){/103 pl}(103){el}]164 0 idx03
-[(Windows)][{/91 pl}(91){el}]153 0 idx03
-[(Windows 95)][]142 0 idx03
-[(Windows NT)][]131 0 idx03
-[2(write)][{/85 pl}(85){el}]120 0 idx03
-[(writing operating systems)][{/110 pl}(110){el}]109 0 idx03
-[2(WRT)][{/34 pl}(34,){el}( ){/75 pl}(75,){el}( ){/86 pl}(86,){el}( ){/87 pl}(87,){el}( ){/88 pl}(88){el}]681 1 idx03
-[2(WRT ..got)][{/107 pl}(107){el}]670 1 idx03
-[2(WRT ..gotoff)][{/107 pl}(107){el}]659 1 idx03
-[2(WRT ..gotpc)][{/107 pl}(107){el}]648 1 idx03
-[2(WRT ..plt)][{/109 pl}(109){el}]637 1 idx03
-[2(WRT ..sym)][{/108 pl}(108){el}]626 1 idx03
-[(WWW page)][]615 1 idx03
-[2(www.cpan.org)][{/15 pl}(15){el}]604 1 idx03
-[2(www.delorie.com)][{/91 pl}(91){el}]593 1 idx03
-[2(www.pcorner.com)][{/91 pl}(91){el}]582 1 idx03
-[2(-X)0( option)][{/19 pl}(19){el}]571 1 idx03
-[2(x2ftp.oulu.fi)][{/91 pl}(91){el}]560 1 idx03
-[2(%xdefine)][{/38 pl}(38){el}]549 1 idx03
-[2(-y)0( option)][{/23 pl}(23){el}]538 1 idx03
-[2(-Z)0( option)][{/20 pl}(20){el}]527 1 idx03
-(213)pageodd
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-%%EOF
diff --git a/doc/nasmdoc.txt b/doc/nasmdoc.txt
deleted file mode 100644
index 5a7286b..0000000
--- a/doc/nasmdoc.txt
+++ /dev/null
@@ -1,12394 +0,0 @@
- The Netwide Assembler: NASM
- ===========================
-
-Chapter 1: Introduction
------------------------
-
- 1.1 What Is NASM?
-
- The Netwide Assembler, NASM, is an 80x86 and x86-64 assembler
- designed for portability and modularity. It supports a range of
- object file formats, including Linux and `*BSD' `a.out', `ELF',
- `COFF', `Mach-O', Microsoft 16-bit `OBJ', `Win32' and `Win64'. It
- will also output plain binary files. Its syntax is designed to be
- simple and easy to understand, similar to Intel's but less complex.
- It supports all currently known x86 architectural extensions, and
- has strong support for macros.
-
- 1.1.1 Why Yet Another Assembler?
-
- The Netwide Assembler grew out of an idea on `comp.lang.asm.x86' (or
- possibly `alt.lang.asm' - I forget which), which was essentially
- that there didn't seem to be a good _free_ x86-series assembler
- around, and that maybe someone ought to write one.
-
- (*) `a86' is good, but not free, and in particular you don't get any
- 32-bit capability until you pay. It's DOS only, too.
-
- (*) `gas' is free, and ports over to DOS and Unix, but it's not very
- good, since it's designed to be a back end to `gcc', which
- always feeds it correct code. So its error checking is minimal.
- Also, its syntax is horrible, from the point of view of anyone
- trying to actually _write_ anything in it. Plus you can't write
- 16-bit code in it (properly.)
-
- (*) `as86' is specific to Minix and Linux, and (my version at least)
- doesn't seem to have much (or any) documentation.
-
- (*) `MASM' isn't very good, and it's (was) expensive, and it runs
- only under DOS.
-
- (*) `TASM' is better, but still strives for MASM compatibility,
- which means millions of directives and tons of red tape. And its
- syntax is essentially MASM's, with the contradictions and quirks
- that entails (although it sorts out some of those by means of
- Ideal mode.) It's expensive too. And it's DOS-only.
-
- So here, for your coding pleasure, is NASM. At present it's still in
- prototype stage - we don't promise that it can outperform any of
- these assemblers. But please, _please_ send us bug reports, fixes,
- helpful information, and anything else you can get your hands on
- (and thanks to the many people who've done this already! You all
- know who you are), and we'll improve it out of all recognition.
- Again.
-
- 1.1.2 License Conditions
-
- Please see the file `LICENSE', supplied as part of any NASM
- distribution archive, for the license conditions under which you may
- use NASM. NASM is now under the so-called 2-clause BSD license, also
- known as the simplified BSD license.
-
- Copyright 1996-2009 the NASM Authors - All rights reserved.
-
- Redistribution and use in source and binary forms, with or without
- modification, are permitted provided that the following conditions
- are met:
-
- (*) Redistributions of source code must retain the above copyright
- notice, this list of conditions and the following disclaimer.
-
- (*) Redistributions in binary form must reproduce the above
- copyright notice, this list of conditions and the following
- disclaimer in the documentation and/or other materials provided
- with the distribution.
-
- THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
- "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
- LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
- FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
- COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
- INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
- BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
- LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
- CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
- LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
- ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
- POSSIBILITY OF SUCH DAMAGE.
-
- 1.2 Contact Information
-
- The current version of NASM (since about 0.98.08) is maintained by a
- team of developers, accessible through the `nasm-devel' mailing list
- (see below for the link). If you want to report a bug, please read
- section 12.2 first.
-
- NASM has a website at `http://www.nasm.us/'. If it's not there,
- google for us!
-
- New releases, release candidates, and daily development snapshots of
- NASM are available from the official web site.
-
- Announcements are posted to `comp.lang.asm.x86', and to the web site
- `http://www.freshmeat.net/'.
-
- If you want information about the current development status, please
- subscribe to the `nasm-devel' email list; see link from the website.
-
- 1.3 Installation
-
- 1.3.1 Installing NASM under MS-DOS or Windows
-
- Once you've obtained the appropriate archive for NASM,
- `nasm-XXX-dos.zip' or `nasm-XXX-win32.zip' (where `XXX' denotes the
- version number of NASM contained in the archive), unpack it into its
- own directory (for example `c:\nasm').
-
- The archive will contain a set of executable files: the NASM
- executable file `nasm.exe', the NDISASM executable file
- `ndisasm.exe', and possibly additional utilities to handle the RDOFF
- file format.
-
- The only file NASM needs to run is its own executable, so copy
- `nasm.exe' to a directory on your PATH, or alternatively edit
- `autoexec.bat' to add the `nasm' directory to your `PATH' (to do
- that under Windows XP, go to Start > Control Panel > System >
- Advanced > Environment Variables; these instructions may work under
- other versions of Windows as well.)
-
- That's it - NASM is installed. You don't need the nasm directory to
- be present to run NASM (unless you've added it to your `PATH'), so
- you can delete it if you need to save space; however, you may want
- to keep the documentation or test programs.
-
- If you've downloaded the DOS source archive, `nasm-XXX.zip', the
- `nasm' directory will also contain the full NASM source code, and a
- selection of Makefiles you can (hopefully) use to rebuild your copy
- of NASM from scratch. See the file `INSTALL' in the source archive.
-
- Note that a number of files are generated from other files by Perl
- scripts. Although the NASM source distribution includes these
- generated files, you will need to rebuild them (and hence, will need
- a Perl interpreter) if you change insns.dat, standard.mac or the
- documentation. It is possible future source distributions may not
- include these files at all. Ports of Perl for a variety of
- platforms, including DOS and Windows, are available from
- www.cpan.org.
-
- 1.3.2 Installing NASM under Unix
-
- Once you've obtained the Unix source archive for NASM,
- `nasm-XXX.tar.gz' (where `XXX' denotes the version number of NASM
- contained in the archive), unpack it into a directory such as
- `/usr/local/src'. The archive, when unpacked, will create its own
- subdirectory `nasm-XXX'.
-
- NASM is an auto-configuring package: once you've unpacked it, `cd'
- to the directory it's been unpacked into and type `./configure'.
- This shell script will find the best C compiler to use for building
- NASM and set up Makefiles accordingly.
-
- Once NASM has auto-configured, you can type `make' to build the
- `nasm' and `ndisasm' binaries, and then `make install' to install
- them in `/usr/local/bin' and install the man pages `nasm.1' and
- `ndisasm.1' in `/usr/local/man/man1'. Alternatively, you can give
- options such as `--prefix' to the configure script (see the file
- `INSTALL' for more details), or install the programs yourself.
-
- NASM also comes with a set of utilities for handling the `RDOFF'
- custom object-file format, which are in the `rdoff' subdirectory of
- the NASM archive. You can build these with `make rdf' and install
- them with `make rdf_install', if you want them.
-
-Chapter 2: Running NASM
------------------------
-
- 2.1 NASM Command-Line Syntax
-
- To assemble a file, you issue a command of the form
-
- nasm -f <format> <filename> [-o <output>]
-
- For example,
-
- nasm -f elf myfile.asm
-
- will assemble `myfile.asm' into an `ELF' object file `myfile.o'. And
-
- nasm -f bin myfile.asm -o myfile.com
-
- will assemble `myfile.asm' into a raw binary file `myfile.com'.
-
- To produce a listing file, with the hex codes output from NASM
- displayed on the left of the original sources, use the `-l' option
- to give a listing file name, for example:
-
- nasm -f coff myfile.asm -l myfile.lst
-
- To get further usage instructions from NASM, try typing
-
- nasm -h
-
- As `-hf', this will also list the available output file formats, and
- what they are.
-
- If you use Linux but aren't sure whether your system is `a.out' or
- `ELF', type
-
- file nasm
-
- (in the directory in which you put the NASM binary when you
- installed it). If it says something like
-
- nasm: ELF 32-bit LSB executable i386 (386 and up) Version 1
-
- then your system is `ELF', and you should use the option `-f elf'
- when you want NASM to produce Linux object files. If it says
-
- nasm: Linux/i386 demand-paged executable (QMAGIC)
-
- or something similar, your system is `a.out', and you should use
- `-f aout' instead (Linux `a.out' systems have long been obsolete,
- and are rare these days.)
-
- Like Unix compilers and assemblers, NASM is silent unless it goes
- wrong: you won't see any output at all, unless it gives error
- messages.
-
- 2.1.1 The `-o' Option: Specifying the Output File Name
-
- NASM will normally choose the name of your output file for you;
- precisely how it does this is dependent on the object file format.
- For Microsoft object file formats (`obj', `win32' and `win64'), it
- will remove the `.asm' extension (or whatever extension you like to
- use - NASM doesn't care) from your source file name and substitute
- `.obj'. For Unix object file formats (`aout', `as86', `coff',
- `elf32', `elf64', `ieee', `macho32' and `macho64') it will
- substitute `.o'. For `dbg', `rdf', `ith' and `srec', it will use
- `.dbg', `.rdf', `.ith' and `.srec', respectively, and for the `bin'
- format it will simply remove the extension, so that `myfile.asm'
- produces the output file `myfile'.
-
- If the output file already exists, NASM will overwrite it, unless it
- has the same name as the input file, in which case it will give a
- warning and use `nasm.out' as the output file name instead.
-
- For situations in which this behaviour is unacceptable, NASM
- provides the `-o' command-line option, which allows you to specify
- your desired output file name. You invoke `-o' by following it with
- the name you wish for the output file, either with or without an
- intervening space. For example:
-
- nasm -f bin program.asm -o program.com
- nasm -f bin driver.asm -odriver.sys
-
- Note that this is a small o, and is different from a capital O ,
- which is used to specify the number of optimisation passes required.
- See section 2.1.22.
-
- 2.1.2 The `-f' Option: Specifying the Output File Format
-
- If you do not supply the `-f' option to NASM, it will choose an
- output file format for you itself. In the distribution versions of
- NASM, the default is always `bin'; if you've compiled your own copy
- of NASM, you can redefine `OF_DEFAULT' at compile time and choose
- what you want the default to be.
-
- Like `-o', the intervening space between `-f' and the output file
- format is optional; so `-f elf' and `-felf' are both valid.
-
- A complete list of the available output file formats can be given by
- issuing the command `nasm -hf'.
-
- 2.1.3 The `-l' Option: Generating a Listing File
-
- If you supply the `-l' option to NASM, followed (with the usual
- optional space) by a file name, NASM will generate a source-listing
- file for you, in which addresses and generated code are listed on
- the left, and the actual source code, with expansions of multi-line
- macros (except those which specifically request no expansion in
- source listings: see section 4.3.10) on the right. For example:
-
- nasm -f elf myfile.asm -l myfile.lst
-
- If a list file is selected, you may turn off listing for a section
- of your source with `[list -]', and turn it back on with `[list +]',
- (the default, obviously). There is no "user form" (without the
- brackets). This can be used to list only sections of interest,
- avoiding excessively long listings.
-
- 2.1.4 The `-M' Option: Generate Makefile Dependencies
-
- This option can be used to generate makefile dependencies on stdout.
- This can be redirected to a file for further processing. For
- example:
-
- nasm -M myfile.asm > myfile.dep
-
- 2.1.5 The `-MG' Option: Generate Makefile Dependencies
-
- This option can be used to generate makefile dependencies on stdout.
- This differs from the `-M' option in that if a nonexisting file is
- encountered, it is assumed to be a generated file and is added to
- the dependency list without a prefix.
-
- 2.1.6 The `-MF' Option: Set Makefile Dependency File
-
- This option can be used with the `-M' or `-MG' options to send the
- output to a file, rather than to stdout. For example:
-
- nasm -M -MF myfile.dep myfile.asm
-
- 2.1.7 The `-MD' Option: Assemble and Generate Dependencies
-
- The `-MD' option acts as the combination of the `-M' and `-MF'
- options (i.e. a filename has to be specified.) However, unlike the
- `-M' or `-MG' options, `-MD' does _not_ inhibit the normal operation
- of the assembler. Use this to automatically generate updated
- dependencies with every assembly session. For example:
-
- nasm -f elf -o myfile.o -MD myfile.dep myfile.asm
-
- 2.1.8 The `-MT' Option: Dependency Target Name
-
- The `-MT' option can be used to override the default name of the
- dependency target. This is normally the same as the output filename,
- specified by the `-o' option.
-
- 2.1.9 The `-MQ' Option: Dependency Target Name (Quoted)
-
- The `-MQ' option acts as the `-MT' option, except it tries to quote
- characters that have special meaning in Makefile syntax. This is not
- foolproof, as not all characters with special meaning are quotable
- in Make.
-
-2.1.10 The `-MP' Option: Emit phony targets
-
- When used with any of the dependency generation options, the `-MP'
- option causes NASM to emit a phony target without dependencies for
- each header file. This prevents Make from complaining if a header
- file has been removed.
-
-2.1.11 The `-F' Option: Selecting a Debug Information Format
-
- This option is used to select the format of the debug information
- emitted into the output file, to be used by a debugger (or _will_
- be). Prior to version 2.03.01, the use of this switch did _not_
- enable output of the selected debug info format. Use `-g', see
- section 2.1.12, to enable output. Versions 2.03.01 and later
- automatically enable `-g' if `-F' is specified.
-
- A complete list of the available debug file formats for an output
- format can be seen by issuing the command `nasm -f <format> -y'. Not
- all output formats currently support debugging output. See section
- 2.1.26.
-
- This should not be confused with the `-f dbg' output format option
- which is not built into NASM by default. For information on how to
- enable it when building from the sources, see section 7.14.
-
-2.1.12 The `-g' Option: Enabling Debug Information.
-
- This option can be used to generate debugging information in the
- specified format. See section 2.1.11. Using `-g' without `-F'
- results in emitting debug info in the default format, if any, for
- the selected output format. If no debug information is currently
- implemented in the selected output format, `-g' is _silently
- ignored_.
-
-2.1.13 The `-X' Option: Selecting an Error Reporting Format
-
- This option can be used to select an error reporting format for any
- error messages that might be produced by NASM.
-
- Currently, two error reporting formats may be selected. They are the
- `-Xvc' option and the `-Xgnu' option. The GNU format is the default
- and looks like this:
-
- filename.asm:65: error: specific error message
-
- where `filename.asm' is the name of the source file in which the
- error was detected, `65' is the source file line number on which the
- error was detected, `error' is the severity of the error (this could
- be `warning'), and `specific error message' is a more detailed text
- message which should help pinpoint the exact problem.
-
- The other format, specified by `-Xvc' is the style used by Microsoft
- Visual C++ and some other programs. It looks like this:
-
- filename.asm(65) : error: specific error message
-
- where the only difference is that the line number is in parentheses
- instead of being delimited by colons.
-
- See also the `Visual C++' output format, section 7.5.
-
-2.1.14 The `-Z' Option: Send Errors to a File
-
- Under `MS-DOS' it can be difficult (though there are ways) to
- redirect the standard-error output of a program to a file. Since
- NASM usually produces its warning and error messages on `stderr',
- this can make it hard to capture the errors if (for example) you
- want to load them into an editor.
-
- NASM therefore provides the `-Z' option, taking a filename argument
- which causes errors to be sent to the specified files rather than
- standard error. Therefore you can redirect the errors into a file by
- typing
-
- nasm -Z myfile.err -f obj myfile.asm
-
- In earlier versions of NASM, this option was called `-E', but it was
- changed since `-E' is an option conventionally used for
- preprocessing only, with disastrous results. See section 2.1.20.
-
-2.1.15 The `-s' Option: Send Errors to `stdout'
-
- The `-s' option redirects error messages to `stdout' rather than
- `stderr', so it can be redirected under `MS-DOS'. To assemble the
- file `myfile.asm' and pipe its output to the `more' program, you can
- type:
-
- nasm -s -f obj myfile.asm | more
-
- See also the `-Z' option, section 2.1.14.
-
-2.1.16 The `-i' Option: Include File Search Directories
-
- When NASM sees the `%include' or `%pathsearch' directive in a source
- file (see section 4.6.1, section 4.6.2 or section 3.2.3), it will
- search for the given file not only in the current directory, but
- also in any directories specified on the command line by the use of
- the `-i' option. Therefore you can include files from a macro
- library, for example, by typing
-
- nasm -ic:\macrolib\ -f obj myfile.asm
-
- (As usual, a space between `-i' and the path name is allowed, and
- optional).
-
- NASM, in the interests of complete source-code portability, does not
- understand the file naming conventions of the OS it is running on;
- the string you provide as an argument to the `-i' option will be
- prepended exactly as written to the name of the include file.
- Therefore the trailing backslash in the above example is necessary.
- Under Unix, a trailing forward slash is similarly necessary.
-
- (You can use this to your advantage, if you're really perverse, by
- noting that the option `-ifoo' will cause `%include "bar.i"' to
- search for the file `foobar.i'...)
-
- If you want to define a _standard_ include search path, similar to
- `/usr/include' on Unix systems, you should place one or more `-i'
- directives in the `NASMENV' environment variable (see section
- 2.1.28).
-
- For Makefile compatibility with many C compilers, this option can
- also be specified as `-I'.
-
-2.1.17 The `-p' Option: Pre-Include a File
-
- NASM allows you to specify files to be _pre-included_ into your
- source file, by the use of the `-p' option. So running
-
- nasm myfile.asm -p myinc.inc
-
- is equivalent to running `nasm myfile.asm' and placing the directive
- `%include "myinc.inc"' at the start of the file.
-
- For consistency with the `-I', `-D' and `-U' options, this option
- can also be specified as `-P'.
-
-2.1.18 The `-d' Option: Pre-Define a Macro
-
- Just as the `-p' option gives an alternative to placing `%include'
- directives at the start of a source file, the `-d' option gives an
- alternative to placing a `%define' directive. You could code
-
- nasm myfile.asm -dFOO=100
-
- as an alternative to placing the directive
-
- %define FOO 100
-
- at the start of the file. You can miss off the macro value, as well:
- the option `-dFOO' is equivalent to coding `%define FOO'. This form
- of the directive may be useful for selecting assembly-time options
- which are then tested using `%ifdef', for example `-dDEBUG'.
-
- For Makefile compatibility with many C compilers, this option can
- also be specified as `-D'.
-
-2.1.19 The `-u' Option: Undefine a Macro
-
- The `-u' option undefines a macro that would otherwise have been
- pre-defined, either automatically or by a `-p' or `-d' option
- specified earlier on the command lines.
-
- For example, the following command line:
-
- nasm myfile.asm -dFOO=100 -uFOO
-
- would result in `FOO' _not_ being a predefined macro in the program.
- This is useful to override options specified at a different point in
- a Makefile.
-
- For Makefile compatibility with many C compilers, this option can
- also be specified as `-U'.
-
-2.1.20 The `-E' Option: Preprocess Only
-
- NASM allows the preprocessor to be run on its own, up to a point.
- Using the `-E' option (which requires no arguments) will cause NASM
- to preprocess its input file, expand all the macro references,
- remove all the comments and preprocessor directives, and print the
- resulting file on standard output (or save it to a file, if the `-o'
- option is also used).
-
- This option cannot be applied to programs which require the
- preprocessor to evaluate expressions which depend on the values of
- symbols: so code such as
-
- %assign tablesize ($-tablestart)
-
- will cause an error in preprocess-only mode.
-
- For compatiblity with older version of NASM, this option can also be
- written `-e'. `-E' in older versions of NASM was the equivalent of
- the current `-Z' option, section 2.1.14.
-
-2.1.21 The `-a' Option: Don't Preprocess At All
-
- If NASM is being used as the back end to a compiler, it might be
- desirable to suppress preprocessing completely and assume the
- compiler has already done it, to save time and increase compilation
- speeds. The `-a' option, requiring no argument, instructs NASM to
- replace its powerful preprocessor with a stub preprocessor which
- does nothing.
-
-2.1.22 The `-O' Option: Specifying Multipass Optimization
-
- NASM defaults to not optimizing operands which can fit into a signed
- byte. This means that if you want the shortest possible object code,
- you have to enable optimization.
-
- Using the `-O' option, you can tell NASM to carry out different
- levels of optimization. The syntax is:
-
- (*) `-O0': No optimization. All operands take their long forms, if a
- short form is not specified, except conditional jumps. This is
- intended to match NASM 0.98 behavior.
-
- (*) `-O1': Minimal optimization. As above, but immediate operands
- which will fit in a signed byte are optimized, unless the long
- form is specified. Conditional jumps default to the long form
- unless otherwise specified.
-
- (*) `-Ox' (where `x' is the actual letter `x'): Multipass
- optimization. Minimize branch offsets and signed immediate
- bytes, overriding size specification unless the `strict' keyword
- has been used (see section 3.7). For compatability with earlier
- releases, the letter `x' may also be any number greater than
- one. This number has no effect on the actual number of passes.
-
- The `-Ox' mode is recommended for most uses.
-
- Note that this is a capital `O', and is different from a small `o',
- which is used to specify the output file name. See section 2.1.1.
-
-2.1.23 The `-t' Option: Enable TASM Compatibility Mode
-
- NASM includes a limited form of compatibility with Borland's `TASM'.
- When NASM's `-t' option is used, the following changes are made:
-
- (*) local labels may be prefixed with `@@' instead of `.'
-
- (*) size override is supported within brackets. In TASM compatible
- mode, a size override inside square brackets changes the size of
- the operand, and not the address type of the operand as it does
- in NASM syntax. E.g. `mov eax,[DWORD val]' is valid syntax in
- TASM compatibility mode. Note that you lose the ability to
- override the default address type for the instruction.
-
- (*) unprefixed forms of some directives supported (`arg', `elif',
- `else', `endif', `if', `ifdef', `ifdifi', `ifndef', `include',
- `local')
-
-2.1.24 The `-w' and `-W' Options: Enable or Disable Assembly Warnings
-
- NASM can observe many conditions during the course of assembly which
- are worth mentioning to the user, but not a sufficiently severe
- error to justify NASM refusing to generate an output file. These
- conditions are reported like errors, but come up with the word
- `warning' before the message. Warnings do not prevent NASM from
- generating an output file and returning a success status to the
- operating system.
-
- Some conditions are even less severe than that: they are only
- sometimes worth mentioning to the user. Therefore NASM supports the
- `-w' command-line option, which enables or disables certain classes
- of assembly warning. Such warning classes are described by a name,
- for example `orphan-labels'; you can enable warnings of this class
- by the command-line option `-w+orphan-labels' and disable it by
- `-w-orphan-labels'.
-
- The suppressible warning classes are:
-
- (*) `macro-params' covers warnings about multi-line macros being
- invoked with the wrong number of parameters. This warning class
- is enabled by default; see section 4.3.2 for an example of why
- you might want to disable it.
-
- (*) `macro-selfref' warns if a macro references itself. This warning
- class is disabled by default.
-
- (*) `macro-defaults' warns when a macro has more default parameters
- than optional parameters. This warning class is enabled by
- default; see section 4.3.5 for why you might want to disable it.
-
- (*) `orphan-labels' covers warnings about source lines which contain
- no instruction but define a label without a trailing colon. NASM
- warns about this somewhat obscure condition by default; see
- section 3.1 for more information.
-
- (*) `number-overflow' covers warnings about numeric constants which
- don't fit in 64 bits. This warning class is enabled by default.
-
- (*) `gnu-elf-extensions' warns if 8-bit or 16-bit relocations are
- used in `-f elf' format. The GNU extensions allow this. This
- warning class is disabled by default.
-
- (*) `float-overflow' warns about floating point overflow. Enabled by
- default.
-
- (*) `float-denorm' warns about floating point denormals. Disabled by
- default.
-
- (*) `float-underflow' warns about floating point underflow. Disabled
- by default.
-
- (*) `float-toolong' warns about too many digits in floating-point
- numbers. Enabled by default.
-
- (*) `user' controls `%warning' directives (see section 4.9). Enabled
- by default.
-
- (*) `error' causes warnings to be treated as errors. Disabled by
- default.
-
- (*) `all' is an alias for _all_ suppressible warning classes (not
- including `error'). Thus, `-w+all' enables all available
- warnings.
-
- In addition, you can set warning classes across sections. Warning
- classes may be enabled with `[warning +warning-name]', disabled with
- `[warning -warning-name]' or reset to their original value with
- `[warning *warning-name]'. No "user form" (without the brackets)
- exists.
-
- Since version 2.00, NASM has also supported the gcc-like syntax
- `-Wwarning' and `-Wno-warning' instead of `-w+warning' and
- `-w-warning', respectively.
-
-2.1.25 The `-v' Option: Display Version Info
-
- Typing `NASM -v' will display the version of NASM which you are
- using, and the date on which it was compiled.
-
- You will need the version number if you report a bug.
-
-2.1.26 The `-y' Option: Display Available Debug Info Formats
-
- Typing `nasm -f <option> -y' will display a list of the available
- debug info formats for the given output format. The default format
- is indicated by an asterisk. For example:
-
- nasm -f elf -y
-
- valid debug formats for 'elf32' output format are
- ('*' denotes default):
- * stabs ELF32 (i386) stabs debug format for Linux
- dwarf elf32 (i386) dwarf debug format for Linux
-
-2.1.27 The `--prefix' and `--postfix' Options.
-
- The `--prefix' and `--postfix' options prepend or append
- (respectively) the given argument to all `global' or `extern'
- variables. E.g. `--prefix _' will prepend the underscore to all
- global and external variables, as C sometimes (but not always) likes
- it.
-
-2.1.28 The `NASMENV' Environment Variable
-
- If you define an environment variable called `NASMENV', the program
- will interpret it as a list of extra command-line options, which are
- processed before the real command line. You can use this to define
- standard search directories for include files, by putting `-i'
- options in the `NASMENV' variable.
-
- The value of the variable is split up at white space, so that the
- value `-s -ic:\nasmlib\' will be treated as two separate options.
- However, that means that the value `-dNAME="my name"' won't do what
- you might want, because it will be split at the space and the NASM
- command-line processing will get confused by the two nonsensical
- words `-dNAME="my' and `name"'.
-
- To get round this, NASM provides a feature whereby, if you begin the
- `NASMENV' environment variable with some character that isn't a
- minus sign, then NASM will treat this character as the separator
- character for options. So setting the `NASMENV' variable to the
- value `!-s!-ic:\nasmlib\' is equivalent to setting it to
- `-s -ic:\nasmlib\', but `!-dNAME="my name"' will work.
-
- This environment variable was previously called `NASM'. This was
- changed with version 0.98.31.
-
- 2.2 Quick Start for MASM Users
-
- If you're used to writing programs with MASM, or with TASM in MASM-
- compatible (non-Ideal) mode, or with `a86', this section attempts to
- outline the major differences between MASM's syntax and NASM's. If
- you're not already used to MASM, it's probably worth skipping this
- section.
-
- 2.2.1 NASM Is Case-Sensitive
-
- One simple difference is that NASM is case-sensitive. It makes a
- difference whether you call your label `foo', `Foo' or `FOO'. If
- you're assembling to `DOS' or `OS/2' `.OBJ' files, you can invoke
- the `UPPERCASE' directive (documented in section 7.4) to ensure that
- all symbols exported to other code modules are forced to be upper
- case; but even then, _within_ a single module, NASM will distinguish
- between labels differing only in case.
-
- 2.2.2 NASM Requires Square Brackets For Memory References
-
- NASM was designed with simplicity of syntax in mind. One of the
- design goals of NASM is that it should be possible, as far as is
- practical, for the user to look at a single line of NASM code and
- tell what opcode is generated by it. You can't do this in MASM: if
- you declare, for example,
-
- foo equ 1
- bar dw 2
-
- then the two lines of code
-
- mov ax,foo
- mov ax,bar
-
- generate completely different opcodes, despite having identical-
- looking syntaxes.
-
- NASM avoids this undesirable situation by having a much simpler
- syntax for memory references. The rule is simply that any access to
- the _contents_ of a memory location requires square brackets around
- the address, and any access to the _address_ of a variable doesn't.
- So an instruction of the form `mov ax,foo' will _always_ refer to a
- compile-time constant, whether it's an `EQU' or the address of a
- variable; and to access the _contents_ of the variable `bar', you
- must code `mov ax,[bar]'.
-
- This also means that NASM has no need for MASM's `OFFSET' keyword,
- since the MASM code `mov ax,offset bar' means exactly the same thing
- as NASM's `mov ax,bar'. If you're trying to get large amounts of
- MASM code to assemble sensibly under NASM, you can always code
- `%idefine offset' to make the preprocessor treat the `OFFSET'
- keyword as a no-op.
-
- This issue is even more confusing in `a86', where declaring a label
- with a trailing colon defines it to be a `label' as opposed to a
- `variable' and causes `a86' to adopt NASM-style semantics; so in
- `a86', `mov ax,var' has different behaviour depending on whether
- `var' was declared as `var: dw 0' (a label) or `var dw 0' (a word-
- size variable). NASM is very simple by comparison: _everything_ is a
- label.
-
- NASM, in the interests of simplicity, also does not support the
- hybrid syntaxes supported by MASM and its clones, such as
- `mov ax,table[bx]', where a memory reference is denoted by one
- portion outside square brackets and another portion inside. The
- correct syntax for the above is `mov ax,[table+bx]'. Likewise,
- `mov ax,es:[di]' is wrong and `mov ax,[es:di]' is right.
-
- 2.2.3 NASM Doesn't Store Variable Types
-
- NASM, by design, chooses not to remember the types of variables you
- declare. Whereas MASM will remember, on seeing `var dw 0', that you
- declared `var' as a word-size variable, and will then be able to
- fill in the ambiguity in the size of the instruction `mov var,2',
- NASM will deliberately remember nothing about the symbol `var'
- except where it begins, and so you must explicitly code
- `mov word [var],2'.
-
- For this reason, NASM doesn't support the `LODS', `MOVS', `STOS',
- `SCAS', `CMPS', `INS', or `OUTS' instructions, but only supports the
- forms such as `LODSB', `MOVSW', and `SCASD', which explicitly
- specify the size of the components of the strings being manipulated.
-
- 2.2.4 NASM Doesn't `ASSUME'
-
- As part of NASM's drive for simplicity, it also does not support the
- `ASSUME' directive. NASM will not keep track of what values you
- choose to put in your segment registers, and will never
- _automatically_ generate a segment override prefix.
-
- 2.2.5 NASM Doesn't Support Memory Models
-
- NASM also does not have any directives to support different 16-bit
- memory models. The programmer has to keep track of which functions
- are supposed to be called with a far call and which with a near
- call, and is responsible for putting the correct form of `RET'
- instruction (`RETN' or `RETF'; NASM accepts `RET' itself as an
- alternate form for `RETN'); in addition, the programmer is
- responsible for coding CALL FAR instructions where necessary when
- calling _external_ functions, and must also keep track of which
- external variable definitions are far and which are near.
-
- 2.2.6 Floating-Point Differences
-
- NASM uses different names to refer to floating-point registers from
- MASM: where MASM would call them `ST(0)', `ST(1)' and so on, and
- `a86' would call them simply `0', `1' and so on, NASM chooses to
- call them `st0', `st1' etc.
-
- As of version 0.96, NASM now treats the instructions with `nowait'
- forms in the same way as MASM-compatible assemblers. The
- idiosyncratic treatment employed by 0.95 and earlier was based on a
- misunderstanding by the authors.
-
- 2.2.7 Other Differences
-
- For historical reasons, NASM uses the keyword `TWORD' where MASM and
- compatible assemblers use `TBYTE'.
-
- NASM does not declare uninitialized storage in the same way as MASM:
- where a MASM programmer might use `stack db 64 dup (?)', NASM
- requires `stack resb 64', intended to be read as `reserve 64 bytes'.
- For a limited amount of compatibility, since NASM treats `?' as a
- valid character in symbol names, you can code `? equ 0' and then
- writing `dw ?' will at least do something vaguely useful. `DUP' is
- still not a supported syntax, however.
-
- In addition to all of this, macros and directives work completely
- differently to MASM. See chapter 4 and chapter 6 for further
- details.
-
-Chapter 3: The NASM Language
-----------------------------
-
- 3.1 Layout of a NASM Source Line
-
- Like most assemblers, each NASM source line contains (unless it is a
- macro, a preprocessor directive or an assembler directive: see
- chapter 4 and chapter 6) some combination of the four fields
-
- label: instruction operands ; comment
-
- As usual, most of these fields are optional; the presence or absence
- of any combination of a label, an instruction and a comment is
- allowed. Of course, the operand field is either required or
- forbidden by the presence and nature of the instruction field.
-
- NASM uses backslash (\) as the line continuation character; if a
- line ends with backslash, the next line is considered to be a part
- of the backslash-ended line.
-
- NASM places no restrictions on white space within a line: labels may
- have white space before them, or instructions may have no space
- before them, or anything. The colon after a label is also optional.
- (Note that this means that if you intend to code `lodsb' alone on a
- line, and type `lodab' by accident, then that's still a valid source
- line which does nothing but define a label. Running NASM with the
- command-line option `-w+orphan-labels' will cause it to warn you if
- you define a label alone on a line without a trailing colon.)
-
- Valid characters in labels are letters, numbers, `_', `$', `#', `@',
- `~', `.', and `?'. The only characters which may be used as the
- _first_ character of an identifier are letters, `.' (with special
- meaning: see section 3.9), `_' and `?'. An identifier may also be
- prefixed with a `$' to indicate that it is intended to be read as an
- identifier and not a reserved word; thus, if some other module you
- are linking with defines a symbol called `eax', you can refer to
- `$eax' in NASM code to distinguish the symbol from the register.
- Maximum length of an identifier is 4095 characters.
-
- The instruction field may contain any machine instruction: Pentium
- and P6 instructions, FPU instructions, MMX instructions and even
- undocumented instructions are all supported. The instruction may be
- prefixed by `LOCK', `REP', `REPE'/`REPZ' or `REPNE'/`REPNZ', in the
- usual way. Explicit address-size and operand-size prefixes `A16',
- `A32', `A64', `O16' and `O32', `O64' are provided - one example of
- their use is given in chapter 10. You can also use the name of a
- segment register as an instruction prefix: coding `es mov [bx],ax'
- is equivalent to coding `mov [es:bx],ax'. We recommend the latter
- syntax, since it is consistent with other syntactic features of the
- language, but for instructions such as `LODSB', which has no
- operands and yet can require a segment override, there is no clean
- syntactic way to proceed apart from `es lodsb'.
-
- An instruction is not required to use a prefix: prefixes such as
- `CS', `A32', `LOCK' or `REPE' can appear on a line by themselves,
- and NASM will just generate the prefix bytes.
-
- In addition to actual machine instructions, NASM also supports a
- number of pseudo-instructions, described in section 3.2.
-
- Instruction operands may take a number of forms: they can be
- registers, described simply by the register name (e.g. `ax', `bp',
- `ebx', `cr0': NASM does not use the `gas'-style syntax in which
- register names must be prefixed by a `%' sign), or they can be
- effective addresses (see section 3.3), constants (section 3.4) or
- expressions (section 3.5).
-
- For x87 floating-point instructions, NASM accepts a wide range of
- syntaxes: you can use two-operand forms like MASM supports, or you
- can use NASM's native single-operand forms in most cases. For
- example, you can code:
-
- fadd st1 ; this sets st0 := st0 + st1
- fadd st0,st1 ; so does this
-
- fadd st1,st0 ; this sets st1 := st1 + st0
- fadd to st1 ; so does this
-
- Almost any x87 floating-point instruction that references memory
- must use one of the prefixes `DWORD', `QWORD' or `TWORD' to indicate
- what size of memory operand it refers to.
-
- 3.2 Pseudo-Instructions
-
- Pseudo-instructions are things which, though not real x86 machine
- instructions, are used in the instruction field anyway because
- that's the most convenient place to put them. The current pseudo-
- instructions are `DB', `DW', `DD', `DQ', `DT', `DO' and `DY'; their
- uninitialized counterparts `RESB', `RESW', `RESD', `RESQ', `REST',
- `RESO' and `RESY'; the `INCBIN' command, the `EQU' command, and the
- `TIMES' prefix.
-
- 3.2.1 `DB' and Friends: Declaring Initialized Data
-
- `DB', `DW', `DD', `DQ', `DT', `DO' and `DY' are used, much as in
- MASM, to declare initialized data in the output file. They can be
- invoked in a wide range of ways:
-
- db 0x55 ; just the byte 0x55
- db 0x55,0x56,0x57 ; three bytes in succession
- db 'a',0x55 ; character constants are OK
- db 'hello',13,10,'$' ; so are string constants
- dw 0x1234 ; 0x34 0x12
- dw 'a' ; 0x61 0x00 (it's just a number)
- dw 'ab' ; 0x61 0x62 (character constant)
- dw 'abc' ; 0x61 0x62 0x63 0x00 (string)
- dd 0x12345678 ; 0x78 0x56 0x34 0x12
- dd 1.234567e20 ; floating-point constant
- dq 0x123456789abcdef0 ; eight byte constant
- dq 1.234567e20 ; double-precision float
- dt 1.234567e20 ; extended-precision float
-
- `DT', `DO' and `DY' do not accept numeric constants as operands.
-
- 3.2.2 `RESB' and Friends: Declaring Uninitialized Data
-
- `RESB', `RESW', `RESD', `RESQ', `REST', `RESO' and `RESY' are
- designed to be used in the BSS section of a module: they declare
- _uninitialized_ storage space. Each takes a single operand, which is
- the number of bytes, words, doublewords or whatever to reserve. As
- stated in section 2.2.7, NASM does not support the MASM/TASM syntax
- of reserving uninitialized space by writing `DW ?' or similar
- things: this is what it does instead. The operand to a `RESB'-type
- pseudo-instruction is a _critical expression_: see section 3.8.
-
- For example:
-
- buffer: resb 64 ; reserve 64 bytes
- wordvar: resw 1 ; reserve a word
- realarray resq 10 ; array of ten reals
- ymmval: resy 1 ; one YMM register
-
- 3.2.3 `INCBIN': Including External Binary Files
-
- `INCBIN' is borrowed from the old Amiga assembler DevPac: it
- includes a binary file verbatim into the output file. This can be
- handy for (for example) including graphics and sound data directly
- into a game executable file. It can be called in one of these three
- ways:
-
- incbin "file.dat" ; include the whole file
- incbin "file.dat",1024 ; skip the first 1024 bytes
- incbin "file.dat",1024,512 ; skip the first 1024, and
- ; actually include at most 512
-
- `INCBIN' is both a directive and a standard macro; the standard
- macro version searches for the file in the include file search path
- and adds the file to the dependency lists. This macro can be
- overridden if desired.
-
- 3.2.4 `EQU': Defining Constants
-
- `EQU' defines a symbol to a given constant value: when `EQU' is
- used, the source line must contain a label. The action of `EQU' is
- to define the given label name to the value of its (only) operand.
- This definition is absolute, and cannot change later. So, for
- example,
-
- message db 'hello, world'
- msglen equ $-message
-
- defines `msglen' to be the constant 12. `msglen' may not then be
- redefined later. This is not a preprocessor definition either: the
- value of `msglen' is evaluated _once_, using the value of `$' (see
- section 3.5 for an explanation of `$') at the point of definition,
- rather than being evaluated wherever it is referenced and using the
- value of `$' at the point of reference.
-
- 3.2.5 `TIMES': Repeating Instructions or Data
-
- The `TIMES' prefix causes the instruction to be assembled multiple
- times. This is partly present as NASM's equivalent of the `DUP'
- syntax supported by MASM-compatible assemblers, in that you can code
-
- zerobuf: times 64 db 0
-
- or similar things; but `TIMES' is more versatile than that. The
- argument to `TIMES' is not just a numeric constant, but a numeric
- _expression_, so you can do things like
-
- buffer: db 'hello, world'
- times 64-$+buffer db ' '
-
- which will store exactly enough spaces to make the total length of
- `buffer' up to 64. Finally, `TIMES' can be applied to ordinary
- instructions, so you can code trivial unrolled loops in it:
-
- times 100 movsb
-
- Note that there is no effective difference between
- `times 100 resb 1' and `resb 100', except that the latter will be
- assembled about 100 times faster due to the internal structure of
- the assembler.
-
- The operand to `TIMES' is a critical expression (section 3.8).
-
- Note also that `TIMES' can't be applied to macros: the reason for
- this is that `TIMES' is processed after the macro phase, which
- allows the argument to `TIMES' to contain expressions such as
- `64-$+buffer' as above. To repeat more than one line of code, or a
- complex macro, use the preprocessor `%rep' directive.
-
- 3.3 Effective Addresses
-
- An effective address is any operand to an instruction which
- references memory. Effective addresses, in NASM, have a very simple
- syntax: they consist of an expression evaluating to the desired
- address, enclosed in square brackets. For example:
-
- wordvar dw 123
- mov ax,[wordvar]
- mov ax,[wordvar+1]
- mov ax,[es:wordvar+bx]
-
- Anything not conforming to this simple system is not a valid memory
- reference in NASM, for example `es:wordvar[bx]'.
-
- More complicated effective addresses, such as those involving more
- than one register, work in exactly the same way:
-
- mov eax,[ebx*2+ecx+offset]
- mov ax,[bp+di+8]
-
- NASM is capable of doing algebra on these effective addresses, so
- that things which don't necessarily _look_ legal are perfectly all
- right:
-
- mov eax,[ebx*5] ; assembles as [ebx*4+ebx]
- mov eax,[label1*2-label2] ; ie [label1+(label1-label2)]
-
- Some forms of effective address have more than one assembled form;
- in most such cases NASM will generate the smallest form it can. For
- example, there are distinct assembled forms for the 32-bit effective
- addresses `[eax*2+0]' and `[eax+eax]', and NASM will generally
- generate the latter on the grounds that the former requires four
- bytes to store a zero offset.
-
- NASM has a hinting mechanism which will cause `[eax+ebx]' and
- `[ebx+eax]' to generate different opcodes; this is occasionally
- useful because `[esi+ebp]' and `[ebp+esi]' have different default
- segment registers.
-
- However, you can force NASM to generate an effective address in a
- particular form by the use of the keywords `BYTE', `WORD', `DWORD'
- and `NOSPLIT'. If you need `[eax+3]' to be assembled using a double-
- word offset field instead of the one byte NASM will normally
- generate, you can code `[dword eax+3]'. Similarly, you can force
- NASM to use a byte offset for a small value which it hasn't seen on
- the first pass (see section 3.8 for an example of such a code
- fragment) by using `[byte eax+offset]'. As special cases,
- `[byte eax]' will code `[eax+0]' with a byte offset of zero, and
- `[dword eax]' will code it with a double-word offset of zero. The
- normal form, `[eax]', will be coded with no offset field.
-
- The form described in the previous paragraph is also useful if you
- are trying to access data in a 32-bit segment from within 16 bit
- code. For more information on this see the section on mixed-size
- addressing (section 10.2). In particular, if you need to access data
- with a known offset that is larger than will fit in a 16-bit value,
- if you don't specify that it is a dword offset, nasm will cause the
- high word of the offset to be lost.
-
- Similarly, NASM will split `[eax*2]' into `[eax+eax]' because that
- allows the offset field to be absent and space to be saved; in fact,
- it will also split `[eax*2+offset]' into `[eax+eax+offset]'. You can
- combat this behaviour by the use of the `NOSPLIT' keyword:
- `[nosplit eax*2]' will force `[eax*2+0]' to be generated literally.
-
- In 64-bit mode, NASM will by default generate absolute addresses.
- The `REL' keyword makes it produce `RIP'-relative addresses. Since
- this is frequently the normally desired behaviour, see the `DEFAULT'
- directive (section 6.2). The keyword `ABS' overrides `REL'.
-
- 3.4 Constants
-
- NASM understands four different types of constant: numeric,
- character, string and floating-point.
-
- 3.4.1 Numeric Constants
-
- A numeric constant is simply a number. NASM allows you to specify
- numbers in a variety of number bases, in a variety of ways: you can
- suffix `H' or `X', `Q' or `O', and `B' for hexadecimal, octal and
- binary respectively, or you can prefix `0x' for hexadecimal in the
- style of C, or you can prefix `$' for hexadecimal in the style of
- Borland Pascal. Note, though, that the `$' prefix does double duty
- as a prefix on identifiers (see section 3.1), so a hex number
- prefixed with a `$' sign must have a digit after the `$' rather than
- a letter. In addition, current versions of NASM accept the prefix
- `0h' for hexadecimal, `0o' or `0q' for octal, and `0b' for binary.
- Please note that unlike C, a `0' prefix by itself does _not_ imply
- an octal constant!
-
- Numeric constants can have underscores (`_') interspersed to break
- up long strings.
-
- Some examples (all producing exactly the same code):
-
- mov ax,200 ; decimal
- mov ax,0200 ; still decimal
- mov ax,0200d ; explicitly decimal
- mov ax,0d200 ; also decimal
- mov ax,0c8h ; hex
- mov ax,$0c8 ; hex again: the 0 is required
- mov ax,0xc8 ; hex yet again
- mov ax,0hc8 ; still hex
- mov ax,310q ; octal
- mov ax,310o ; octal again
- mov ax,0o310 ; octal yet again
- mov ax,0q310 ; hex yet again
- mov ax,11001000b ; binary
- mov ax,1100_1000b ; same binary constant
- mov ax,0b1100_1000 ; same binary constant yet again
-
- 3.4.2 Character Strings
-
- A character string consists of up to eight characters enclosed in
- either single quotes (`'...''), double quotes (`"..."') or
- backquotes (``...`'). Single or double quotes are equivalent to NASM
- (except of course that surrounding the constant with single quotes
- allows double quotes to appear within it and vice versa); the
- contents of those are represented verbatim. Strings enclosed in
- backquotes support C-style `\'-escapes for special characters.
-
- The following escape sequences are recognized by backquoted strings:
-
- \' single quote (')
- \" double quote (")
- \` backquote (`)
- \\ backslash (\)
- \? question mark (?)
- \a BEL (ASCII 7)
- \b BS (ASCII 8)
- \t TAB (ASCII 9)
- \n LF (ASCII 10)
- \v VT (ASCII 11)
- \f FF (ASCII 12)
- \r CR (ASCII 13)
- \e ESC (ASCII 27)
- \377 Up to 3 octal digits - literal byte
- \xFF Up to 2 hexadecimal digits - literal byte
- \u1234 4 hexadecimal digits - Unicode character
- \U12345678 8 hexadecimal digits - Unicode character
-
- All other escape sequences are reserved. Note that `\0', meaning a
- `NUL' character (ASCII 0), is a special case of the octal escape
- sequence.
-
- Unicode characters specified with `\u' or `\U' are converted to
- UTF-8. For example, the following lines are all equivalent:
-
- db `\u263a` ; UTF-8 smiley face
- db `\xe2\x98\xba` ; UTF-8 smiley face
- db 0E2h, 098h, 0BAh ; UTF-8 smiley face
-
- 3.4.3 Character Constants
-
- A character constant consists of a string up to eight bytes long,
- used in an expression context. It is treated as if it was an
- integer.
-
- A character constant with more than one byte will be arranged with
- little-endian order in mind: if you code
-
- mov eax,'abcd'
-
- then the constant generated is not `0x61626364', but `0x64636261',
- so that if you were then to store the value into memory, it would
- read `abcd' rather than `dcba'. This is also the sense of character
- constants understood by the Pentium's `CPUID' instruction.
-
- 3.4.4 String Constants
-
- String constants are character strings used in the context of some
- pseudo-instructions, namely the `DB' family and `INCBIN' (where it
- represents a filename.) They are also used in certain preprocessor
- directives.
-
- A string constant looks like a character constant, only longer. It
- is treated as a concatenation of maximum-size character constants
- for the conditions. So the following are equivalent:
-
- db 'hello' ; string constant
- db 'h','e','l','l','o' ; equivalent character constants
-
- And the following are also equivalent:
-
- dd 'ninechars' ; doubleword string constant
- dd 'nine','char','s' ; becomes three doublewords
- db 'ninechars',0,0,0 ; and really looks like this
-
- Note that when used in a string-supporting context, quoted strings
- are treated as a string constants even if they are short enough to
- be a character constant, because otherwise `db 'ab'' would have the
- same effect as `db 'a'', which would be silly. Similarly, three-
- character or four-character constants are treated as strings when
- they are operands to `DW', and so forth.
-
- 3.4.5 Unicode Strings
-
- The special operators `__utf16__' and `__utf32__' allows definition
- of Unicode strings. They take a string in UTF-8 format and converts
- it to (littleendian) UTF-16 or UTF-32, respectively.
-
- For example:
-
- %define u(x) __utf16__(x)
- %define w(x) __utf32__(x)
-
- dw u('C:\WINDOWS'), 0 ; Pathname in UTF-16
- dd w(`A + B = \u206a`), 0 ; String in UTF-32
-
- `__utf16__' and `__utf32__' can be applied either to strings passed
- to the `DB' family instructions, or to character constants in an
- expression context.
-
- 3.4.6 Floating-Point Constants
-
- Floating-point constants are acceptable only as arguments to `DB',
- `DW', `DD', `DQ', `DT', and `DO', or as arguments to the special
- operators `__float8__', `__float16__', `__float32__', `__float64__',
- `__float80m__', `__float80e__', `__float128l__', and
- `__float128h__'.
-
- Floating-point constants are expressed in the traditional form:
- digits, then a period, then optionally more digits, then optionally
- an `E' followed by an exponent. The period is mandatory, so that
- NASM can distinguish between `dd 1', which declares an integer
- constant, and `dd 1.0' which declares a floating-point constant.
- NASM also support C99-style hexadecimal floating-point: `0x',
- hexadecimal digits, period, optionally more hexadeximal digits, then
- optionally a `P' followed by a _binary_ (not hexadecimal) exponent
- in decimal notation.
-
- Underscores to break up groups of digits are permitted in floating-
- point constants as well.
-
- Some examples:
-
- db -0.2 ; "Quarter precision"
- dw -0.5 ; IEEE 754r/SSE5 half precision
- dd 1.2 ; an easy one
- dd 1.222_222_222 ; underscores are permitted
- dd 0x1p+2 ; 1.0x2^2 = 4.0
- dq 0x1p+32 ; 1.0x2^32 = 4 294 967 296.0
- dq 1.e10 ; 10 000 000 000.0
- dq 1.e+10 ; synonymous with 1.e10
- dq 1.e-10 ; 0.000 000 000 1
- dt 3.141592653589793238462 ; pi
- do 1.e+4000 ; IEEE 754r quad precision
-
- The 8-bit "quarter-precision" floating-point format is
- sign:exponent:mantissa = 1:4:3 with an exponent bias of 7. This
- appears to be the most frequently used 8-bit floating-point format,
- although it is not covered by any formal standard. This is sometimes
- called a "minifloat."
-
- The special operators are used to produce floating-point numbers in
- other contexts. They produce the binary representation of a specific
- floating-point number as an integer, and can use anywhere integer
- constants are used in an expression. `__float80m__' and
- `__float80e__' produce the 64-bit mantissa and 16-bit exponent of an
- 80-bit floating-point number, and `__float128l__' and
- `__float128h__' produce the lower and upper 64-bit halves of a 128-
- bit floating-point number, respectively.
-
- For example:
-
- mov rax,__float64__(3.141592653589793238462)
-
- ... would assign the binary representation of pi as a 64-bit
- floating point number into `RAX'. This is exactly equivalent to:
-
- mov rax,0x400921fb54442d18
-
- NASM cannot do compile-time arithmetic on floating-point constants.
- This is because NASM is designed to be portable - although it always
- generates code to run on x86 processors, the assembler itself can
- run on any system with an ANSI C compiler. Therefore, the assembler
- cannot guarantee the presence of a floating-point unit capable of
- handling the Intel number formats, and so for NASM to be able to do
- floating arithmetic it would have to include its own complete set of
- floating-point routines, which would significantly increase the size
- of the assembler for very little benefit.
-
- The special tokens `__Infinity__', `__QNaN__' (or `__NaN__') and
- `__SNaN__' can be used to generate infinities, quiet NaNs, and
- signalling NaNs, respectively. These are normally used as macros:
-
- %define Inf __Infinity__
- %define NaN __QNaN__
-
- dq +1.5, -Inf, NaN ; Double-precision constants
-
- 3.4.7 Packed BCD Constants
-
- x87-style packed BCD constants can be used in the same contexts as
- 80-bit floating-point numbers. They are suffixed with `p' or
- prefixed with `0p', and can include up to 18 decimal digits.
-
- As with other numeric constants, underscores can be used to separate
- digits.
-
- For example:
-
- dt 12_345_678_901_245_678p
- dt -12_345_678_901_245_678p
- dt +0p33
- dt 33p
-
- 3.5 Expressions
-
- Expressions in NASM are similar in syntax to those in C. Expressions
- are evaluated as 64-bit integers which are then adjusted to the
- appropriate size.
-
- NASM supports two special tokens in expressions, allowing
- calculations to involve the current assembly position: the `$' and
- `$$' tokens. `$' evaluates to the assembly position at the beginning
- of the line containing the expression; so you can code an infinite
- loop using `JMP $'. `$$' evaluates to the beginning of the current
- section; so you can tell how far into the section you are by using
- `($-$$)'.
-
- The arithmetic operators provided by NASM are listed here, in
- increasing order of precedence.
-
- 3.5.1 `|': Bitwise OR Operator
-
- The `|' operator gives a bitwise OR, exactly as performed by the
- `OR' machine instruction. Bitwise OR is the lowest-priority
- arithmetic operator supported by NASM.
-
- 3.5.2 `^': Bitwise XOR Operator
-
- `^' provides the bitwise XOR operation.
-
- 3.5.3 `&': Bitwise AND Operator
-
- `&' provides the bitwise AND operation.
-
- 3.5.4 `<<' and `>>': Bit Shift Operators
-
- `<<' gives a bit-shift to the left, just as it does in C. So `5<<3'
- evaluates to 5 times 8, or 40. `>>' gives a bit-shift to the right;
- in NASM, such a shift is _always_ unsigned, so that the bits shifted
- in from the left-hand end are filled with zero rather than a sign-
- extension of the previous highest bit.
-
- 3.5.5 `+' and `-': Addition and Subtraction Operators
-
- The `+' and `-' operators do perfectly ordinary addition and
- subtraction.
-
- 3.5.6 `*', `/', `//', `%' and `%%': Multiplication and Division
-
- `*' is the multiplication operator. `/' and `//' are both division
- operators: `/' is unsigned division and `//' is signed division.
- Similarly, `%' and `%%' provide unsigned and signed modulo operators
- respectively.
-
- NASM, like ANSI C, provides no guarantees about the sensible
- operation of the signed modulo operator.
-
- Since the `%' character is used extensively by the macro
- preprocessor, you should ensure that both the signed and unsigned
- modulo operators are followed by white space wherever they appear.
-
- 3.5.7 Unary Operators: `+', `-', `~', `!' and `SEG'
-
- The highest-priority operators in NASM's expression grammar are
- those which only apply to one argument. `-' negates its operand, `+'
- does nothing (it's provided for symmetry with `-'), `~' computes the
- one's complement of its operand, `!' is the logical negation
- operator, and `SEG' provides the segment address of its operand
- (explained in more detail in section 3.6).
-
- 3.6 `SEG' and `WRT'
-
- When writing large 16-bit programs, which must be split into
- multiple segments, it is often necessary to be able to refer to the
- segment part of the address of a symbol. NASM supports the `SEG'
- operator to perform this function.
-
- The `SEG' operator returns the _preferred_ segment base of a symbol,
- defined as the segment base relative to which the offset of the
- symbol makes sense. So the code
-
- mov ax,seg symbol
- mov es,ax
- mov bx,symbol
-
- will load `ES:BX' with a valid pointer to the symbol `symbol'.
-
- Things can be more complex than this: since 16-bit segments and
- groups may overlap, you might occasionally want to refer to some
- symbol using a different segment base from the preferred one. NASM
- lets you do this, by the use of the `WRT' (With Reference To)
- keyword. So you can do things like
-
- mov ax,weird_seg ; weird_seg is a segment base
- mov es,ax
- mov bx,symbol wrt weird_seg
-
- to load `ES:BX' with a different, but functionally equivalent,
- pointer to the symbol `symbol'.
-
- NASM supports far (inter-segment) calls and jumps by means of the
- syntax `call segment:offset', where `segment' and `offset' both
- represent immediate values. So to call a far procedure, you could
- code either of
-
- call (seg procedure):procedure
- call weird_seg:(procedure wrt weird_seg)
-
- (The parentheses are included for clarity, to show the intended
- parsing of the above instructions. They are not necessary in
- practice.)
-
- NASM supports the syntax `call far procedure' as a synonym for the
- first of the above usages. `JMP' works identically to `CALL' in
- these examples.
-
- To declare a far pointer to a data item in a data segment, you must
- code
-
- dw symbol, seg symbol
-
- NASM supports no convenient synonym for this, though you can always
- invent one using the macro processor.
-
- 3.7 `STRICT': Inhibiting Optimization
-
- When assembling with the optimizer set to level 2 or higher (see
- section 2.1.22), NASM will use size specifiers (`BYTE', `WORD',
- `DWORD', `QWORD', `TWORD', `OWORD' or `YWORD'), but will give them
- the smallest possible size. The keyword `STRICT' can be used to
- inhibit optimization and force a particular operand to be emitted in
- the specified size. For example, with the optimizer on, and in
- `BITS 16' mode,
-
- push dword 33
-
- is encoded in three bytes `66 6A 21', whereas
-
- push strict dword 33
-
- is encoded in six bytes, with a full dword immediate operand
- `66 68 21 00 00 00'.
-
- With the optimizer off, the same code (six bytes) is generated
- whether the `STRICT' keyword was used or not.
-
- 3.8 Critical Expressions
-
- Although NASM has an optional multi-pass optimizer, there are some
- expressions which must be resolvable on the first pass. These are
- called _Critical Expressions_.
-
- The first pass is used to determine the size of all the assembled
- code and data, so that the second pass, when generating all the
- code, knows all the symbol addresses the code refers to. So one
- thing NASM can't handle is code whose size depends on the value of a
- symbol declared after the code in question. For example,
-
- times (label-$) db 0
- label: db 'Where am I?'
-
- The argument to `TIMES' in this case could equally legally evaluate
- to anything at all; NASM will reject this example because it cannot
- tell the size of the `TIMES' line when it first sees it. It will
- just as firmly reject the slightly paradoxical code
-
- times (label-$+1) db 0
- label: db 'NOW where am I?'
-
- in which _any_ value for the `TIMES' argument is by definition
- wrong!
-
- NASM rejects these examples by means of a concept called a _critical
- expression_, which is defined to be an expression whose value is
- required to be computable in the first pass, and which must
- therefore depend only on symbols defined before it. The argument to
- the `TIMES' prefix is a critical expression.
-
- 3.9 Local Labels
-
- NASM gives special treatment to symbols beginning with a period. A
- label beginning with a single period is treated as a _local_ label,
- which means that it is associated with the previous non-local label.
- So, for example:
-
- label1 ; some code
-
- .loop
- ; some more code
-
- jne .loop
- ret
-
- label2 ; some code
-
- .loop
- ; some more code
-
- jne .loop
- ret
-
- In the above code fragment, each `JNE' instruction jumps to the line
- immediately before it, because the two definitions of `.loop' are
- kept separate by virtue of each being associated with the previous
- non-local label.
-
- This form of local label handling is borrowed from the old Amiga
- assembler DevPac; however, NASM goes one step further, in allowing
- access to local labels from other parts of the code. This is
- achieved by means of _defining_ a local label in terms of the
- previous non-local label: the first definition of `.loop' above is
- really defining a symbol called `label1.loop', and the second
- defines a symbol called `label2.loop'. So, if you really needed to,
- you could write
-
- label3 ; some more code
- ; and some more
-
- jmp label1.loop
-
- Sometimes it is useful - in a macro, for instance - to be able to
- define a label which can be referenced from anywhere but which
- doesn't interfere with the normal local-label mechanism. Such a
- label can't be non-local because it would interfere with subsequent
- definitions of, and references to, local labels; and it can't be
- local because the macro that defined it wouldn't know the label's
- full name. NASM therefore introduces a third type of label, which is
- probably only useful in macro definitions: if a label begins with
- the special prefix `..@', then it does nothing to the local label
- mechanism. So you could code
-
- label1: ; a non-local label
- .local: ; this is really label1.local
- ..@foo: ; this is a special symbol
- label2: ; another non-local label
- .local: ; this is really label2.local
-
- jmp ..@foo ; this will jump three lines up
-
- NASM has the capacity to define other special symbols beginning with
- a double period: for example, `..start' is used to specify the entry
- point in the `obj' output format (see section 7.4.6).
-
-Chapter 4: The NASM Preprocessor
---------------------------------
-
- NASM contains a powerful macro processor, which supports conditional
- assembly, multi-level file inclusion, two forms of macro (single-
- line and multi-line), and a `context stack' mechanism for extra
- macro power. Preprocessor directives all begin with a `%' sign.
-
- The preprocessor collapses all lines which end with a backslash (\)
- character into a single line. Thus:
-
- %define THIS_VERY_LONG_MACRO_NAME_IS_DEFINED_TO \
- THIS_VALUE
-
- will work like a single-line macro without the backslash-newline
- sequence.
-
- 4.1 Single-Line Macros
-
- 4.1.1 The Normal Way: `%define'
-
- Single-line macros are defined using the `%define' preprocessor
- directive. The definitions work in a similar way to C; so you can do
- things like
-
- %define ctrl 0x1F &
- %define param(a,b) ((a)+(a)*(b))
-
- mov byte [param(2,ebx)], ctrl 'D'
-
- which will expand to
-
- mov byte [(2)+(2)*(ebx)], 0x1F & 'D'
-
- When the expansion of a single-line macro contains tokens which
- invoke another macro, the expansion is performed at invocation time,
- not at definition time. Thus the code
-
- %define a(x) 1+b(x)
- %define b(x) 2*x
-
- mov ax,a(8)
-
- will evaluate in the expected way to `mov ax,1+2*8', even though the
- macro `b' wasn't defined at the time of definition of `a'.
-
- Macros defined with `%define' are case sensitive: after
- `%define foo bar', only `foo' will expand to `bar': `Foo' or `FOO'
- will not. By using `%idefine' instead of `%define' (the `i' stands
- for `insensitive') you can define all the case variants of a macro
- at once, so that `%idefine foo bar' would cause `foo', `Foo', `FOO',
- `fOO' and so on all to expand to `bar'.
-
- There is a mechanism which detects when a macro call has occurred as
- a result of a previous expansion of the same macro, to guard against
- circular references and infinite loops. If this happens, the
- preprocessor will only expand the first occurrence of the macro.
- Hence, if you code
-
- %define a(x) 1+a(x)
-
- mov ax,a(3)
-
- the macro `a(3)' will expand once, becoming `1+a(3)', and will then
- expand no further. This behaviour can be useful: see section 9.1 for
- an example of its use.
-
- You can overload single-line macros: if you write
-
- %define foo(x) 1+x
- %define foo(x,y) 1+x*y
-
- the preprocessor will be able to handle both types of macro call, by
- counting the parameters you pass; so `foo(3)' will become `1+3'
- whereas `foo(ebx,2)' will become `1+ebx*2'. However, if you define
-
- %define foo bar
-
- then no other definition of `foo' will be accepted: a macro with no
- parameters prohibits the definition of the same name as a macro
- _with_ parameters, and vice versa.
-
- This doesn't prevent single-line macros being _redefined_: you can
- perfectly well define a macro with
-
- %define foo bar
-
- and then re-define it later in the same source file with
-
- %define foo baz
-
- Then everywhere the macro `foo' is invoked, it will be expanded
- according to the most recent definition. This is particularly useful
- when defining single-line macros with `%assign' (see section 4.1.7).
-
- You can pre-define single-line macros using the `-d' option on the
- NASM command line: see section 2.1.18.
-
- 4.1.2 Resolving `%define': `%xdefine'
-
- To have a reference to an embedded single-line macro resolved at the
- time that the embedding macro is _defined_, as opposed to when the
- embedding macro is _expanded_, you need a different mechanism to the
- one offered by `%define'. The solution is to use `%xdefine', or it's
- case-insensitive counterpart `%ixdefine'.
-
- Suppose you have the following code:
-
- %define isTrue 1
- %define isFalse isTrue
- %define isTrue 0
-
- val1: db isFalse
-
- %define isTrue 1
-
- val2: db isFalse
-
- In this case, `val1' is equal to 0, and `val2' is equal to 1. This
- is because, when a single-line macro is defined using `%define', it
- is expanded only when it is called. As `isFalse' expands to
- `isTrue', the expansion will be the current value of `isTrue'. The
- first time it is called that is 0, and the second time it is 1.
-
- If you wanted `isFalse' to expand to the value assigned to the
- embedded macro `isTrue' at the time that `isFalse' was defined, you
- need to change the above code to use `%xdefine'.
-
- %xdefine isTrue 1
- %xdefine isFalse isTrue
- %xdefine isTrue 0
-
- val1: db isFalse
-
- %xdefine isTrue 1
-
- val2: db isFalse
-
- Now, each time that `isFalse' is called, it expands to 1, as that is
- what the embedded macro `isTrue' expanded to at the time that
- `isFalse' was defined.
-
- 4.1.3 Macro Indirection: `%[...]'
-
- The `%[...]' construct can be used to expand macros in contexts
- where macro expansion would otherwise not occur, including in the
- names other macros. For example, if you have a set of macros named
- `Foo16', `Foo32' and `Foo64', you could write:
-
- mov ax,Foo%[__BITS__] ; The Foo value
-
- to use the builtin macro `__BITS__' (see section 4.11.5) to
- automatically select between them. Similarly, the two statements:
-
- %xdefine Bar Quux ; Expands due to %xdefine
- %define Bar %[Quux] ; Expands due to %[...]
-
- have, in fact, exactly the same effect.
-
- `%[...]' concatenates to adjacent tokens in the same way that multi-
- line macro parameters do, see section 4.3.8 for details.
-
- 4.1.4 Concatenating Single Line Macro Tokens: `%+'
-
- Individual tokens in single line macros can be concatenated, to
- produce longer tokens for later processing. This can be useful if
- there are several similar macros that perform similar functions.
-
- Please note that a space is required after `%+', in order to
- disambiguate it from the syntax `%+1' used in multiline macros.
-
- As an example, consider the following:
-
- %define BDASTART 400h ; Start of BIOS data area
-
- struc tBIOSDA ; its structure
- .COM1addr RESW 1
- .COM2addr RESW 1
- ; ..and so on
- endstruc
-
- Now, if we need to access the elements of tBIOSDA in different
- places, we can end up with:
-
- mov ax,BDASTART + tBIOSDA.COM1addr
- mov bx,BDASTART + tBIOSDA.COM2addr
-
- This will become pretty ugly (and tedious) if used in many places,
- and can be reduced in size significantly by using the following
- macro:
-
- ; Macro to access BIOS variables by their names (from tBDA):
-
- %define BDA(x) BDASTART + tBIOSDA. %+ x
-
- Now the above code can be written as:
-
- mov ax,BDA(COM1addr)
- mov bx,BDA(COM2addr)
-
- Using this feature, we can simplify references to a lot of macros
- (and, in turn, reduce typing errors).
-
- 4.1.5 The Macro Name Itself: `%?' and `%??'
-
- The special symbols `%?' and `%??' can be used to reference the
- macro name itself inside a macro expansion, this is supported for
- both single-and multi-line macros. `%?' refers to the macro name as
- _invoked_, whereas `%??' refers to the macro name as _declared_. The
- two are always the same for case-sensitive macros, but for case-
- insensitive macros, they can differ.
-
- For example:
-
- %idefine Foo mov %?,%??
-
- foo
- FOO
-
- will expand to:
-
- mov foo,Foo
- mov FOO,Foo
-
- The sequence:
-
- %idefine keyword $%?
-
- can be used to make a keyword "disappear", for example in case a new
- instruction has been used as a label in older code. For example:
-
- %idefine pause $%? ; Hide the PAUSE instruction
-
- 4.1.6 Undefining Single-Line Macros: `%undef'
-
- Single-line macros can be removed with the `%undef' directive. For
- example, the following sequence:
-
- %define foo bar
- %undef foo
-
- mov eax, foo
-
- will expand to the instruction `mov eax, foo', since after `%undef'
- the macro `foo' is no longer defined.
-
- Macros that would otherwise be pre-defined can be undefined on the
- command-line using the `-u' option on the NASM command line: see
- section 2.1.19.
-
- 4.1.7 Preprocessor Variables: `%assign'
-
- An alternative way to define single-line macros is by means of the
- `%assign' command (and its case-insensitive counterpart `%iassign',
- which differs from `%assign' in exactly the same way that `%idefine'
- differs from `%define').
-
- `%assign' is used to define single-line macros which take no
- parameters and have a numeric value. This value can be specified in
- the form of an expression, and it will be evaluated once, when the
- `%assign' directive is processed.
-
- Like `%define', macros defined using `%assign' can be re-defined
- later, so you can do things like
-
- %assign i i+1
-
- to increment the numeric value of a macro.
-
- `%assign' is useful for controlling the termination of `%rep'
- preprocessor loops: see section 4.5 for an example of this. Another
- use for `%assign' is given in section 8.4 and section 9.1.
-
- The expression passed to `%assign' is a critical expression (see
- section 3.8), and must also evaluate to a pure number (rather than a
- relocatable reference such as a code or data address, or anything
- involving a register).
-
- 4.1.8 Defining Strings: `%defstr'
-
- `%defstr', and its case-insensitive counterpart `%idefstr', define
- or redefine a single-line macro without parameters but converts the
- entire right-hand side, after macro expansion, to a quoted string
- before definition.
-
- For example:
-
- %defstr test TEST
-
- is equivalent to
-
- %define test 'TEST'
-
- This can be used, for example, with the `%!' construct (see section
- 4.10.2):
-
- %defstr PATH %!PATH ; The operating system PATH variable
-
- 4.1.9 Defining Tokens: `%deftok'
-
- `%deftok', and its case-insensitive counterpart `%ideftok', define
- or redefine a single-line macro without parameters but converts the
- second parameter, after string conversion, to a sequence of tokens.
-
- For example:
-
- %deftok test 'TEST'
-
- is equivalent to
-
- %define test TEST
-
- 4.2 String Manipulation in Macros
-
- It's often useful to be able to handle strings in macros. NASM
- supports a few simple string handling macro operators from which
- more complex operations can be constructed.
-
- All the string operators define or redefine a value (either a string
- or a numeric value) to a single-line macro. When producing a string
- value, it may change the style of quoting of the input string or
- strings, and possibly use `\'-escapes inside ``'-quoted strings.
-
- 4.2.1 Concatenating Strings: `%strcat'
-
- The `%strcat' operator concatenates quoted strings and assign them
- to a single-line macro.
-
- For example:
-
- %strcat alpha "Alpha: ", '12" screen'
-
- ... would assign the value `'Alpha: 12" screen'' to `alpha'.
- Similarly:
-
- %strcat beta '"foo"\', "'bar'"
-
- ... would assign the value ``"foo"\\'bar'`' to `beta'.
-
- The use of commas to separate strings is permitted but optional.
-
- 4.2.2 String Length: `%strlen'
-
- The `%strlen' operator assigns the length of a string to a macro.
- For example:
-
- %strlen charcnt 'my string'
-
- In this example, `charcnt' would receive the value 9, just as if an
- `%assign' had been used. In this example, `'my string'' was a
- literal string but it could also have been a single-line macro that
- expands to a string, as in the following example:
-
- %define sometext 'my string'
- %strlen charcnt sometext
-
- As in the first case, this would result in `charcnt' being assigned
- the value of 9.
-
- 4.2.3 Extracting Substrings: `%substr'
-
- Individual letters or substrings in strings can be extracted using
- the `%substr' operator. An example of its use is probably more
- useful than the description:
-
- %substr mychar 'xyzw' 1 ; equivalent to %define mychar 'x'
- %substr mychar 'xyzw' 2 ; equivalent to %define mychar 'y'
- %substr mychar 'xyzw' 3 ; equivalent to %define mychar 'z'
- %substr mychar 'xyzw' 2,2 ; equivalent to %define mychar 'yz'
- %substr mychar 'xyzw' 2,-1 ; equivalent to %define mychar 'yzw'
- %substr mychar 'xyzw' 2,-2 ; equivalent to %define mychar 'yz'
-
- As with `%strlen' (see section 4.2.2), the first parameter is the
- single-line macro to be created and the second is the string. The
- third parameter specifies the first character to be selected, and
- the optional fourth parameter preceeded by comma) is the length.
- Note that the first index is 1, not 0 and the last index is equal to
- the value that `%strlen' would assign given the same string. Index
- values out of range result in an empty string. A negative length
- means "until N-1 characters before the end of string", i.e. `-1'
- means until end of string, `-2' until one character before, etc.
-
- 4.3 Multi-Line Macros: `%macro'
-
- Multi-line macros are much more like the type of macro seen in MASM
- and TASM: a multi-line macro definition in NASM looks something like
- this.
-
- %macro prologue 1
-
- push ebp
- mov ebp,esp
- sub esp,%1
-
- %endmacro
-
- This defines a C-like function prologue as a macro: so you would
- invoke the macro with a call such as
-
- myfunc: prologue 12
-
- which would expand to the three lines of code
-
- myfunc: push ebp
- mov ebp,esp
- sub esp,12
-
- The number `1' after the macro name in the `%macro' line defines the
- number of parameters the macro `prologue' expects to receive. The
- use of `%1' inside the macro definition refers to the first
- parameter to the macro call. With a macro taking more than one
- parameter, subsequent parameters would be referred to as `%2', `%3'
- and so on.
-
- Multi-line macros, like single-line macros, are case-sensitive,
- unless you define them using the alternative directive `%imacro'.
-
- If you need to pass a comma as _part_ of a parameter to a multi-line
- macro, you can do that by enclosing the entire parameter in braces.
- So you could code things like
-
- %macro silly 2
-
- %2: db %1
-
- %endmacro
-
- silly 'a', letter_a ; letter_a: db 'a'
- silly 'ab', string_ab ; string_ab: db 'ab'
- silly {13,10}, crlf ; crlf: db 13,10
-
- 4.3.1 Recursive Multi-Line Macros: `%rmacro'
-
- A multi-line macro cannot be referenced within itself, in order to
- prevent accidental infinite recursion.
-
- Recursive multi-line macros allow for self-referencing, with the
- caveat that the user is aware of the existence, use and purpose of
- recursive multi-line macros. There is also a generous, but sane,
- upper limit to the number of recursions, in order to prevent run-
- away memory consumption in case of accidental infinite recursion.
-
- As with non-recursive multi-line macros, recursive multi-line macros
- are case-sensitive, unless you define them using the alternative
- directive `%irmacro'.
-
- 4.3.2 Overloading Multi-Line Macros
-
- As with single-line macros, multi-line macros can be overloaded by
- defining the same macro name several times with different numbers of
- parameters. This time, no exception is made for macros with no
- parameters at all. So you could define
-
- %macro prologue 0
-
- push ebp
- mov ebp,esp
-
- %endmacro
-
- to define an alternative form of the function prologue which
- allocates no local stack space.
-
- Sometimes, however, you might want to `overload' a machine
- instruction; for example, you might want to define
-
- %macro push 2
-
- push %1
- push %2
-
- %endmacro
-
- so that you could code
-
- push ebx ; this line is not a macro call
- push eax,ecx ; but this one is
-
- Ordinarily, NASM will give a warning for the first of the above two
- lines, since `push' is now defined to be a macro, and is being
- invoked with a number of parameters for which no definition has been
- given. The correct code will still be generated, but the assembler
- will give a warning. This warning can be disabled by the use of the
- `-w-macro-params' command-line option (see section 2.1.24).
-
- 4.3.3 Macro-Local Labels
-
- NASM allows you to define labels within a multi-line macro
- definition in such a way as to make them local to the macro call: so
- calling the same macro multiple times will use a different label
- each time. You do this by prefixing `%%' to the label name. So you
- can invent an instruction which executes a `RET' if the `Z' flag is
- set by doing this:
-
- %macro retz 0
-
- jnz %%skip
- ret
- %%skip:
-
- %endmacro
-
- You can call this macro as many times as you want, and every time
- you call it NASM will make up a different `real' name to substitute
- for the label `%%skip'. The names NASM invents are of the form
- `..@2345.skip', where the number 2345 changes with every macro call.
- The `..@' prefix prevents macro-local labels from interfering with
- the local label mechanism, as described in section 3.9. You should
- avoid defining your own labels in this form (the `..@' prefix, then
- a number, then another period) in case they interfere with macro-
- local labels.
-
- 4.3.4 Greedy Macro Parameters
-
- Occasionally it is useful to define a macro which lumps its entire
- command line into one parameter definition, possibly after
- extracting one or two smaller parameters from the front. An example
- might be a macro to write a text string to a file in MS-DOS, where
- you might want to be able to write
-
- writefile [filehandle],"hello, world",13,10
-
- NASM allows you to define the last parameter of a macro to be
- _greedy_, meaning that if you invoke the macro with more parameters
- than it expects, all the spare parameters get lumped into the last
- defined one along with the separating commas. So if you code:
-
- %macro writefile 2+
-
- jmp %%endstr
- %%str: db %2
- %%endstr:
- mov dx,%%str
- mov cx,%%endstr-%%str
- mov bx,%1
- mov ah,0x40
- int 0x21
-
- %endmacro
-
- then the example call to `writefile' above will work as expected:
- the text before the first comma, `[filehandle]', is used as the
- first macro parameter and expanded when `%1' is referred to, and all
- the subsequent text is lumped into `%2' and placed after the `db'.
-
- The greedy nature of the macro is indicated to NASM by the use of
- the `+' sign after the parameter count on the `%macro' line.
-
- If you define a greedy macro, you are effectively telling NASM how
- it should expand the macro given _any_ number of parameters from the
- actual number specified up to infinity; in this case, for example,
- NASM now knows what to do when it sees a call to `writefile' with 2,
- 3, 4 or more parameters. NASM will take this into account when
- overloading macros, and will not allow you to define another form of
- `writefile' taking 4 parameters (for example).
-
- Of course, the above macro could have been implemented as a non-
- greedy macro, in which case the call to it would have had to look
- like
-
- writefile [filehandle], {"hello, world",13,10}
-
- NASM provides both mechanisms for putting commas in macro
- parameters, and you choose which one you prefer for each macro
- definition.
-
- See section 6.3.1 for a better way to write the above macro.
-
- 4.3.5 Default Macro Parameters
-
- NASM also allows you to define a multi-line macro with a _range_ of
- allowable parameter counts. If you do this, you can specify defaults
- for omitted parameters. So, for example:
-
- %macro die 0-1 "Painful program death has occurred."
-
- writefile 2,%1
- mov ax,0x4c01
- int 0x21
-
- %endmacro
-
- This macro (which makes use of the `writefile' macro defined in
- section 4.3.4) can be called with an explicit error message, which
- it will display on the error output stream before exiting, or it can
- be called with no parameters, in which case it will use the default
- error message supplied in the macro definition.
-
- In general, you supply a minimum and maximum number of parameters
- for a macro of this type; the minimum number of parameters are then
- required in the macro call, and then you provide defaults for the
- optional ones. So if a macro definition began with the line
-
- %macro foobar 1-3 eax,[ebx+2]
-
- then it could be called with between one and three parameters, and
- `%1' would always be taken from the macro call. `%2', if not
- specified by the macro call, would default to `eax', and `%3' if not
- specified would default to `[ebx+2]'.
-
- You can provide extra information to a macro by providing too many
- default parameters:
-
- %macro quux 1 something
-
- This will trigger a warning by default; see section 2.1.24 for more
- information. When `quux' is invoked, it receives not one but two
- parameters. `something' can be referred to as `%2'. The difference
- between passing `something' this way and writing `something' in the
- macro body is that with this way `something' is evaluated when the
- macro is defined, not when it is expanded.
-
- You may omit parameter defaults from the macro definition, in which
- case the parameter default is taken to be blank. This can be useful
- for macros which can take a variable number of parameters, since the
- `%0' token (see section 4.3.6) allows you to determine how many
- parameters were really passed to the macro call.
-
- This defaulting mechanism can be combined with the greedy-parameter
- mechanism; so the `die' macro above could be made more powerful, and
- more useful, by changing the first line of the definition to
-
- %macro die 0-1+ "Painful program death has occurred.",13,10
-
- The maximum parameter count can be infinite, denoted by `*'. In this
- case, of course, it is impossible to provide a _full_ set of default
- parameters. Examples of this usage are shown in section 4.3.7.
-
- 4.3.6 `%0': Macro Parameter Counter
-
- The parameter reference `%0' will return a numeric constant giving
- the number of parameters received, that is, if `%0' is n then `%'n
- is the last parameter. `%0' is mostly useful for macros that can
- take a variable number of parameters. It can be used as an argument
- to `%rep' (see section 4.5) in order to iterate through all the
- parameters of a macro. Examples are given in section 4.3.7.
-
- 4.3.7 `%rotate': Rotating Macro Parameters
-
- Unix shell programmers will be familiar with the `shift' shell
- command, which allows the arguments passed to a shell script
- (referenced as `$1', `$2' and so on) to be moved left by one place,
- so that the argument previously referenced as `$2' becomes available
- as `$1', and the argument previously referenced as `$1' is no longer
- available at all.
-
- NASM provides a similar mechanism, in the form of `%rotate'. As its
- name suggests, it differs from the Unix `shift' in that no
- parameters are lost: parameters rotated off the left end of the
- argument list reappear on the right, and vice versa.
-
- `%rotate' is invoked with a single numeric argument (which may be an
- expression). The macro parameters are rotated to the left by that
- many places. If the argument to `%rotate' is negative, the macro
- parameters are rotated to the right.
-
- So a pair of macros to save and restore a set of registers might
- work as follows:
-
- %macro multipush 1-*
-
- %rep %0
- push %1
- %rotate 1
- %endrep
-
- %endmacro
-
- This macro invokes the `PUSH' instruction on each of its arguments
- in turn, from left to right. It begins by pushing its first
- argument, `%1', then invokes `%rotate' to move all the arguments one
- place to the left, so that the original second argument is now
- available as `%1'. Repeating this procedure as many times as there
- were arguments (achieved by supplying `%0' as the argument to
- `%rep') causes each argument in turn to be pushed.
-
- Note also the use of `*' as the maximum parameter count, indicating
- that there is no upper limit on the number of parameters you may
- supply to the `multipush' macro.
-
- It would be convenient, when using this macro, to have a `POP'
- equivalent, which _didn't_ require the arguments to be given in
- reverse order. Ideally, you would write the `multipush' macro call,
- then cut-and-paste the line to where the pop needed to be done, and
- change the name of the called macro to `multipop', and the macro
- would take care of popping the registers in the opposite order from
- the one in which they were pushed.
-
- This can be done by the following definition:
-
- %macro multipop 1-*
-
- %rep %0
- %rotate -1
- pop %1
- %endrep
-
- %endmacro
-
- This macro begins by rotating its arguments one place to the
- _right_, so that the original _last_ argument appears as `%1'. This
- is then popped, and the arguments are rotated right again, so the
- second-to-last argument becomes `%1'. Thus the arguments are
- iterated through in reverse order.
-
- 4.3.8 Concatenating Macro Parameters
-
- NASM can concatenate macro parameters and macro indirection
- constructs on to other text surrounding them. This allows you to
- declare a family of symbols, for example, in a macro definition. If,
- for example, you wanted to generate a table of key codes along with
- offsets into the table, you could code something like
-
- %macro keytab_entry 2
-
- keypos%1 equ $-keytab
- db %2
-
- %endmacro
-
- keytab:
- keytab_entry F1,128+1
- keytab_entry F2,128+2
- keytab_entry Return,13
-
- which would expand to
-
- keytab:
- keyposF1 equ $-keytab
- db 128+1
- keyposF2 equ $-keytab
- db 128+2
- keyposReturn equ $-keytab
- db 13
-
- You can just as easily concatenate text on to the other end of a
- macro parameter, by writing `%1foo'.
-
- If you need to append a _digit_ to a macro parameter, for example
- defining labels `foo1' and `foo2' when passed the parameter `foo',
- you can't code `%11' because that would be taken as the eleventh
- macro parameter. Instead, you must code `%{1}1', which will separate
- the first `1' (giving the number of the macro parameter) from the
- second (literal text to be concatenated to the parameter).
-
- This concatenation can also be applied to other preprocessor in-line
- objects, such as macro-local labels (section 4.3.3) and context-
- local labels (section 4.7.2). In all cases, ambiguities in syntax
- can be resolved by enclosing everything after the `%' sign and
- before the literal text in braces: so `%{%foo}bar' concatenates the
- text `bar' to the end of the real name of the macro-local label
- `%%foo'. (This is unnecessary, since the form NASM uses for the real
- names of macro-local labels means that the two usages `%{%foo}bar'
- and `%%foobar' would both expand to the same thing anyway;
- nevertheless, the capability is there.)
-
- The single-line macro indirection construct, `%[...]' (section
- 4.1.3), behaves the same way as macro parameters for the purpose of
- concatenation.
-
- See also the `%+' operator, section 4.1.4.
-
- 4.3.9 Condition Codes as Macro Parameters
-
- NASM can give special treatment to a macro parameter which contains
- a condition code. For a start, you can refer to the macro parameter
- `%1' by means of the alternative syntax `%+1', which informs NASM
- that this macro parameter is supposed to contain a condition code,
- and will cause the preprocessor to report an error message if the
- macro is called with a parameter which is _not_ a valid condition
- code.
-
- Far more usefully, though, you can refer to the macro parameter by
- means of `%-1', which NASM will expand as the _inverse_ condition
- code. So the `retz' macro defined in section 4.3.3 can be replaced
- by a general conditional-return macro like this:
-
- %macro retc 1
-
- j%-1 %%skip
- ret
- %%skip:
-
- %endmacro
-
- This macro can now be invoked using calls like `retc ne', which will
- cause the conditional-jump instruction in the macro expansion to
- come out as `JE', or `retc po' which will make the jump a `JPE'.
-
- The `%+1' macro-parameter reference is quite happy to interpret the
- arguments `CXZ' and `ECXZ' as valid condition codes; however, `%-1'
- will report an error if passed either of these, because no inverse
- condition code exists.
-
-4.3.10 Disabling Listing Expansion
-
- When NASM is generating a listing file from your program, it will
- generally expand multi-line macros by means of writing the macro
- call and then listing each line of the expansion. This allows you to
- see which instructions in the macro expansion are generating what
- code; however, for some macros this clutters the listing up
- unnecessarily.
-
- NASM therefore provides the `.nolist' qualifier, which you can
- include in a macro definition to inhibit the expansion of the macro
- in the listing file. The `.nolist' qualifier comes directly after
- the number of parameters, like this:
-
- %macro foo 1.nolist
-
- Or like this:
-
- %macro bar 1-5+.nolist a,b,c,d,e,f,g,h
-
-4.3.11 Undefining Multi-Line Macros: `%unmacro'
-
- Multi-line macros can be removed with the `%unmacro' directive.
- Unlike the `%undef' directive, however, `%unmacro' takes an argument
- specification, and will only remove exact matches with that argument
- specification.
-
- For example:
-
- %macro foo 1-3
- ; Do something
- %endmacro
- %unmacro foo 1-3
-
- removes the previously defined macro `foo', but
-
- %macro bar 1-3
- ; Do something
- %endmacro
- %unmacro bar 1
-
- does _not_ remove the macro `bar', since the argument specification
- does not match exactly.
-
-4.3.12 Exiting Multi-Line Macros: `%exitmacro'
-
- Multi-line macro expansions can be arbitrarily terminated with the
- `%exitmacro' directive.
-
- For example:
-
- %macro foo 1-3
- ; Do something
- %if<condition>
- %exitmacro
- %endif
- ; Do something
- %endmacro
-
- 4.4 Conditional Assembly
-
- Similarly to the C preprocessor, NASM allows sections of a source
- file to be assembled only if certain conditions are met. The general
- syntax of this feature looks like this:
-
- %if<condition>
- ; some code which only appears if <condition> is met
- %elif<condition2>
- ; only appears if <condition> is not met but <condition2> is
- %else
- ; this appears if neither <condition> nor <condition2> was met
- %endif
-
- The inverse forms `%ifn' and `%elifn' are also supported.
-
- The `%else' clause is optional, as is the `%elif' clause. You can
- have more than one `%elif' clause as well.
-
- There are a number of variants of the `%if' directive. Each has its
- corresponding `%elif', `%ifn', and `%elifn' directives; for example,
- the equivalents to the `%ifdef' directive are `%elifdef', `%ifndef',
- and `%elifndef'.
-
- 4.4.1 `%ifdef': Testing Single-Line Macro Existence
-
- Beginning a conditional-assembly block with the line `%ifdef MACRO'
- will assemble the subsequent code if, and only if, a single-line
- macro called `MACRO' is defined. If not, then the `%elif' and
- `%else' blocks (if any) will be processed instead.
-
- For example, when debugging a program, you might want to write code
- such as
-
- ; perform some function
- %ifdef DEBUG
- writefile 2,"Function performed successfully",13,10
- %endif
- ; go and do something else
-
- Then you could use the command-line option `-dDEBUG' to create a
- version of the program which produced debugging messages, and remove
- the option to generate the final release version of the program.
-
- You can test for a macro _not_ being defined by using `%ifndef'
- instead of `%ifdef'. You can also test for macro definitions in
- `%elif' blocks by using `%elifdef' and `%elifndef'.
-
- 4.4.2 `%ifmacro': Testing Multi-Line Macro Existence
-
- The `%ifmacro' directive operates in the same way as the `%ifdef'
- directive, except that it checks for the existence of a multi-line
- macro.
-
- For example, you may be working with a large project and not have
- control over the macros in a library. You may want to create a macro
- with one name if it doesn't already exist, and another name if one
- with that name does exist.
-
- The `%ifmacro' is considered true if defining a macro with the given
- name and number of arguments would cause a definitions conflict. For
- example:
-
- %ifmacro MyMacro 1-3
-
- %error "MyMacro 1-3" causes a conflict with an existing macro.
-
- %else
-
- %macro MyMacro 1-3
-
- ; insert code to define the macro
-
- %endmacro
-
- %endif
-
- This will create the macro "MyMacro 1-3" if no macro already exists
- which would conflict with it, and emits a warning if there would be
- a definition conflict.
-
- You can test for the macro not existing by using the `%ifnmacro'
- instead of `%ifmacro'. Additional tests can be performed in `%elif'
- blocks by using `%elifmacro' and `%elifnmacro'.
-
- 4.4.3 `%ifctx': Testing the Context Stack
-
- The conditional-assembly construct `%ifctx' will cause the
- subsequent code to be assembled if and only if the top context on
- the preprocessor's context stack has the same name as one of the
- arguments. As with `%ifdef', the inverse and `%elif' forms
- `%ifnctx', `%elifctx' and `%elifnctx' are also supported.
-
- For more details of the context stack, see section 4.7. For a sample
- use of `%ifctx', see section 4.7.5.
-
- 4.4.4 `%if': Testing Arbitrary Numeric Expressions
-
- The conditional-assembly construct `%if expr' will cause the
- subsequent code to be assembled if and only if the value of the
- numeric expression `expr' is non-zero. An example of the use of this
- feature is in deciding when to break out of a `%rep' preprocessor
- loop: see section 4.5 for a detailed example.
-
- The expression given to `%if', and its counterpart `%elif', is a
- critical expression (see section 3.8).
-
- `%if' extends the normal NASM expression syntax, by providing a set
- of relational operators which are not normally available in
- expressions. The operators `=', `<', `>', `<=', `>=' and `<>' test
- equality, less-than, greater-than, less-or-equal, greater-or-equal
- and not-equal respectively. The C-like forms `==' and `!=' are
- supported as alternative forms of `=' and `<>'. In addition, low-
- priority logical operators `&&', `^^' and `||' are provided,
- supplying logical AND, logical XOR and logical OR. These work like
- the C logical operators (although C has no logical XOR), in that
- they always return either 0 or 1, and treat any non-zero input as 1
- (so that `^^', for example, returns 1 if exactly one of its inputs
- is zero, and 0 otherwise). The relational operators also return 1
- for true and 0 for false.
-
- Like other `%if' constructs, `%if' has a counterpart `%elif', and
- negative forms `%ifn' and `%elifn'.
-
- 4.4.5 `%ifidn' and `%ifidni': Testing Exact Text Identity
-
- The construct `%ifidn text1,text2' will cause the subsequent code to
- be assembled if and only if `text1' and `text2', after expanding
- single-line macros, are identical pieces of text. Differences in
- white space are not counted.
-
- `%ifidni' is similar to `%ifidn', but is case-insensitive.
-
- For example, the following macro pushes a register or number on the
- stack, and allows you to treat `IP' as a real register:
-
- %macro pushparam 1
-
- %ifidni %1,ip
- call %%label
- %%label:
- %else
- push %1
- %endif
-
- %endmacro
-
- Like other `%if' constructs, `%ifidn' has a counterpart `%elifidn',
- and negative forms `%ifnidn' and `%elifnidn'. Similarly, `%ifidni'
- has counterparts `%elifidni', `%ifnidni' and `%elifnidni'.
-
- 4.4.6 `%ifid', `%ifnum', `%ifstr': Testing Token Types
-
- Some macros will want to perform different tasks depending on
- whether they are passed a number, a string, or an identifier. For
- example, a string output macro might want to be able to cope with
- being passed either a string constant or a pointer to an existing
- string.
-
- The conditional assembly construct `%ifid', taking one parameter
- (which may be blank), assembles the subsequent code if and only if
- the first token in the parameter exists and is an identifier.
- `%ifnum' works similarly, but tests for the token being a numeric
- constant; `%ifstr' tests for it being a string.
-
- For example, the `writefile' macro defined in section 4.3.4 can be
- extended to take advantage of `%ifstr' in the following fashion:
-
- %macro writefile 2-3+
-
- %ifstr %2
- jmp %%endstr
- %if %0 = 3
- %%str: db %2,%3
- %else
- %%str: db %2
- %endif
- %%endstr: mov dx,%%str
- mov cx,%%endstr-%%str
- %else
- mov dx,%2
- mov cx,%3
- %endif
- mov bx,%1
- mov ah,0x40
- int 0x21
-
- %endmacro
-
- Then the `writefile' macro can cope with being called in either of
- the following two ways:
-
- writefile [file], strpointer, length
- writefile [file], "hello", 13, 10
-
- In the first, `strpointer' is used as the address of an already-
- declared string, and `length' is used as its length; in the second,
- a string is given to the macro, which therefore declares it itself
- and works out the address and length for itself.
-
- Note the use of `%if' inside the `%ifstr': this is to detect whether
- the macro was passed two arguments (so the string would be a single
- string constant, and `db %2' would be adequate) or more (in which
- case, all but the first two would be lumped together into `%3', and
- `db %2,%3' would be required).
-
- The usual `%elif'..., `%ifn'..., and `%elifn'... versions exist for
- each of `%ifid', `%ifnum' and `%ifstr'.
-
- 4.4.7 `%iftoken': Test for a Single Token
-
- Some macros will want to do different things depending on if it is
- passed a single token (e.g. paste it to something else using `%+')
- versus a multi-token sequence.
-
- The conditional assembly construct `%iftoken' assembles the
- subsequent code if and only if the expanded parameters consist of
- exactly one token, possibly surrounded by whitespace.
-
- For example:
-
- %iftoken 1
-
- will assemble the subsequent code, but
-
- %iftoken -1
-
- will not, since `-1' contains two tokens: the unary minus operator
- `-', and the number `1'.
-
- The usual `%eliftoken', `%ifntoken', and `%elifntoken' variants are
- also provided.
-
- 4.4.8 `%ifempty': Test for Empty Expansion
-
- The conditional assembly construct `%ifempty' assembles the
- subsequent code if and only if the expanded parameters do not
- contain any tokens at all, whitespace excepted.
-
- The usual `%elifempty', `%ifnempty', and `%elifnempty' variants are
- also provided.
-
- 4.5 Preprocessor Loops: `%rep'
-
- NASM's `TIMES' prefix, though useful, cannot be used to invoke a
- multi-line macro multiple times, because it is processed by NASM
- after macros have already been expanded. Therefore NASM provides
- another form of loop, this time at the preprocessor level: `%rep'.
-
- The directives `%rep' and `%endrep' (`%rep' takes a numeric
- argument, which can be an expression; `%endrep' takes no arguments)
- can be used to enclose a chunk of code, which is then replicated as
- many times as specified by the preprocessor:
-
- %assign i 0
- %rep 64
- inc word [table+2*i]
- %assign i i+1
- %endrep
-
- This will generate a sequence of 64 `INC' instructions, incrementing
- every word of memory from `[table]' to `[table+126]'.
-
- For more complex termination conditions, or to break out of a repeat
- loop part way along, you can use the `%exitrep' directive to
- terminate the loop, like this:
-
- fibonacci:
- %assign i 0
- %assign j 1
- %rep 100
- %if j > 65535
- %exitrep
- %endif
- dw j
- %assign k j+i
- %assign i j
- %assign j k
- %endrep
-
- fib_number equ ($-fibonacci)/2
-
- This produces a list of all the Fibonacci numbers that will fit in
- 16 bits. Note that a maximum repeat count must still be given to
- `%rep'. This is to prevent the possibility of NASM getting into an
- infinite loop in the preprocessor, which (on multitasking or multi-
- user systems) would typically cause all the system memory to be
- gradually used up and other applications to start crashing.
-
- 4.6 Source Files and Dependencies
-
- These commands allow you to split your sources into multiple files.
-
- 4.6.1 `%include': Including Other Files
-
- Using, once again, a very similar syntax to the C preprocessor,
- NASM's preprocessor lets you include other source files into your
- code. This is done by the use of the `%include' directive:
-
- %include "macros.mac"
-
- will include the contents of the file `macros.mac' into the source
- file containing the `%include' directive.
-
- Include files are searched for in the current directory (the
- directory you're in when you run NASM, as opposed to the location of
- the NASM executable or the location of the source file), plus any
- directories specified on the NASM command line using the `-i'
- option.
-
- The standard C idiom for preventing a file being included more than
- once is just as applicable in NASM: if the file `macros.mac' has the
- form
-
- %ifndef MACROS_MAC
- %define MACROS_MAC
- ; now define some macros
- %endif
-
- then including the file more than once will not cause errors,
- because the second time the file is included nothing will happen
- because the macro `MACROS_MAC' will already be defined.
-
- You can force a file to be included even if there is no `%include'
- directive that explicitly includes it, by using the `-p' option on
- the NASM command line (see section 2.1.17).
-
- 4.6.2 `%pathsearch': Search the Include Path
-
- The `%pathsearch' directive takes a single-line macro name and a
- filename, and declare or redefines the specified single-line macro
- to be the include-path-resolved version of the filename, if the file
- exists (otherwise, it is passed unchanged.)
-
- For example,
-
- %pathsearch MyFoo "foo.bin"
-
- ... with `-Ibins/' in the include path may end up defining the macro
- `MyFoo' to be `"bins/foo.bin"'.
-
- 4.6.3 `%depend': Add Dependent Files
-
- The `%depend' directive takes a filename and adds it to the list of
- files to be emitted as dependency generation when the `-M' options
- and its relatives (see section 2.1.4) are used. It produces no
- output.
-
- This is generally used in conjunction with `%pathsearch'. For
- example, a simplified version of the standard macro wrapper for the
- `INCBIN' directive looks like:
-
- %imacro incbin 1-2+ 0
- %pathsearch dep %1
- %depend dep
- incbin dep,%2
- %endmacro
-
- This first resolves the location of the file into the macro `dep',
- then adds it to the dependency lists, and finally issues the
- assembler-level `INCBIN' directive.
-
- 4.6.4 `%use': Include Standard Macro Package
-
- The `%use' directive is similar to `%include', but rather than
- including the contents of a file, it includes a named standard macro
- package. The standard macro packages are part of NASM, and are
- described in chapter 5.
-
- Unlike the `%include' directive, package names for the `%use'
- directive do not require quotes, but quotes are permitted. In NASM
- 2.04 and 2.05 the unquoted form would be macro-expanded; this is no
- longer true. Thus, the following lines are equivalent:
-
- %use altreg
- %use 'altreg'
-
- Standard macro packages are protected from multiple inclusion. When
- a standard macro package is used, a testable single-line macro of
- the form `__USE_'_package_`__' is also defined, see section 4.11.8.
-
- 4.7 The Context Stack
-
- Having labels that are local to a macro definition is sometimes not
- quite powerful enough: sometimes you want to be able to share labels
- between several macro calls. An example might be a `REPEAT' ...
- `UNTIL' loop, in which the expansion of the `REPEAT' macro would
- need to be able to refer to a label which the `UNTIL' macro had
- defined. However, for such a macro you would also want to be able to
- nest these loops.
-
- NASM provides this level of power by means of a _context stack_. The
- preprocessor maintains a stack of _contexts_, each of which is
- characterized by a name. You add a new context to the stack using
- the `%push' directive, and remove one using `%pop'. You can define
- labels that are local to a particular context on the stack.
-
- 4.7.1 `%push' and `%pop': Creating and Removing Contexts
-
- The `%push' directive is used to create a new context and place it
- on the top of the context stack. `%push' takes an optional argument,
- which is the name of the context. For example:
-
- %push foobar
-
- This pushes a new context called `foobar' on the stack. You can have
- several contexts on the stack with the same name: they can still be
- distinguished. If no name is given, the context is unnamed (this is
- normally used when both the `%push' and the `%pop' are inside a
- single macro definition.)
-
- The directive `%pop', taking one optional argument, removes the top
- context from the context stack and destroys it, along with any
- labels associated with it. If an argument is given, it must match
- the name of the current context, otherwise it will issue an error.
-
- 4.7.2 Context-Local Labels
-
- Just as the usage `%%foo' defines a label which is local to the
- particular macro call in which it is used, the usage `%$foo' is used
- to define a label which is local to the context on the top of the
- context stack. So the `REPEAT' and `UNTIL' example given above could
- be implemented by means of:
-
- %macro repeat 0
-
- %push repeat
- %$begin:
-
- %endmacro
-
- %macro until 1
-
- j%-1 %$begin
- %pop
-
- %endmacro
-
- and invoked by means of, for example,
-
- mov cx,string
- repeat
- add cx,3
- scasb
- until e
-
- which would scan every fourth byte of a string in search of the byte
- in `AL'.
-
- If you need to define, or access, labels local to the context
- _below_ the top one on the stack, you can use `%$$foo', or `%$$$foo'
- for the context below that, and so on.
-
- 4.7.3 Context-Local Single-Line Macros
-
- NASM also allows you to define single-line macros which are local to
- a particular context, in just the same way:
-
- %define %$localmac 3
-
- will define the single-line macro `%$localmac' to be local to the
- top context on the stack. Of course, after a subsequent `%push', it
- can then still be accessed by the name `%$$localmac'.
-
- 4.7.4 `%repl': Renaming a Context
-
- If you need to change the name of the top context on the stack (in
- order, for example, to have it respond differently to `%ifctx'), you
- can execute a `%pop' followed by a `%push'; but this will have the
- side effect of destroying all context-local labels and macros
- associated with the context that was just popped.
-
- NASM provides the directive `%repl', which _replaces_ a context with
- a different name, without touching the associated macros and labels.
- So you could replace the destructive code
-
- %pop
- %push newname
-
- with the non-destructive version `%repl newname'.
-
- 4.7.5 Example Use of the Context Stack: Block IFs
-
- This example makes use of almost all the context-stack features,
- including the conditional-assembly construct `%ifctx', to implement
- a block IF statement as a set of macros.
-
- %macro if 1
-
- %push if
- j%-1 %$ifnot
-
- %endmacro
-
- %macro else 0
-
- %ifctx if
- %repl else
- jmp %$ifend
- %$ifnot:
- %else
- %error "expected `if' before `else'"
- %endif
-
- %endmacro
-
- %macro endif 0
-
- %ifctx if
- %$ifnot:
- %pop
- %elifctx else
- %$ifend:
- %pop
- %else
- %error "expected `if' or `else' before `endif'"
- %endif
-
- %endmacro
-
- This code is more robust than the `REPEAT' and `UNTIL' macros given
- in section 4.7.2, because it uses conditional assembly to check that
- the macros are issued in the right order (for example, not calling
- `endif' before `if') and issues a `%error' if they're not.
-
- In addition, the `endif' macro has to be able to cope with the two
- distinct cases of either directly following an `if', or following an
- `else'. It achieves this, again, by using conditional assembly to do
- different things depending on whether the context on top of the
- stack is `if' or `else'.
-
- The `else' macro has to preserve the context on the stack, in order
- to have the `%$ifnot' referred to by the `if' macro be the same as
- the one defined by the `endif' macro, but has to change the
- context's name so that `endif' will know there was an intervening
- `else'. It does this by the use of `%repl'.
-
- A sample usage of these macros might look like:
-
- cmp ax,bx
-
- if ae
- cmp bx,cx
-
- if ae
- mov ax,cx
- else
- mov ax,bx
- endif
-
- else
- cmp ax,cx
-
- if ae
- mov ax,cx
- endif
-
- endif
-
- The block-`IF' macros handle nesting quite happily, by means of
- pushing another context, describing the inner `if', on top of the
- one describing the outer `if'; thus `else' and `endif' always refer
- to the last unmatched `if' or `else'.
-
- 4.8 Stack Relative Preprocessor Directives
-
- The following preprocessor directives provide a way to use labels to
- refer to local variables allocated on the stack.
-
- (*) `%arg' (see section 4.8.1)
-
- (*) `%stacksize' (see section 4.8.2)
-
- (*) `%local' (see section 4.8.3)
-
- 4.8.1 `%arg' Directive
-
- The `%arg' directive is used to simplify the handling of parameters
- passed on the stack. Stack based parameter passing is used by many
- high level languages, including C, C++ and Pascal.
-
- While NASM has macros which attempt to duplicate this functionality
- (see section 8.4.5), the syntax is not particularly convenient to
- use. and is not TASM compatible. Here is an example which shows the
- use of `%arg' without any external macros:
-
- some_function:
-
- %push mycontext ; save the current context
- %stacksize large ; tell NASM to use bp
- %arg i:word, j_ptr:word
-
- mov ax,[i]
- mov bx,[j_ptr]
- add ax,[bx]
- ret
-
- %pop ; restore original context
-
- This is similar to the procedure defined in section 8.4.5 and adds
- the value in i to the value pointed to by j_ptr and returns the sum
- in the ax register. See section 4.7.1 for an explanation of `push'
- and `pop' and the use of context stacks.
-
- 4.8.2 `%stacksize' Directive
-
- The `%stacksize' directive is used in conjunction with the `%arg'
- (see section 4.8.1) and the `%local' (see section 4.8.3) directives.
- It tells NASM the default size to use for subsequent `%arg' and
- `%local' directives. The `%stacksize' directive takes one required
- argument which is one of `flat', `flat64', `large' or `small'.
-
- %stacksize flat
-
- This form causes NASM to use stack-based parameter addressing
- relative to `ebp' and it assumes that a near form of call was used
- to get to this label (i.e. that `eip' is on the stack).
-
- %stacksize flat64
-
- This form causes NASM to use stack-based parameter addressing
- relative to `rbp' and it assumes that a near form of call was used
- to get to this label (i.e. that `rip' is on the stack).
-
- %stacksize large
-
- This form uses `bp' to do stack-based parameter addressing and
- assumes that a far form of call was used to get to this address
- (i.e. that `ip' and `cs' are on the stack).
-
- %stacksize small
-
- This form also uses `bp' to address stack parameters, but it is
- different from `large' because it also assumes that the old value of
- bp is pushed onto the stack (i.e. it expects an `ENTER'
- instruction). In other words, it expects that `bp', `ip' and `cs'
- are on the top of the stack, underneath any local space which may
- have been allocated by `ENTER'. This form is probably most useful
- when used in combination with the `%local' directive (see section
- 4.8.3).
-
- 4.8.3 `%local' Directive
-
- The `%local' directive is used to simplify the use of local
- temporary stack variables allocated in a stack frame. Automatic
- local variables in C are an example of this kind of variable. The
- `%local' directive is most useful when used with the `%stacksize'
- (see section 4.8.2 and is also compatible with the `%arg' directive
- (see section 4.8.1). It allows simplified reference to variables on
- the stack which have been allocated typically by using the `ENTER'
- instruction. An example of its use is the following:
-
- silly_swap:
-
- %push mycontext ; save the current context
- %stacksize small ; tell NASM to use bp
- %assign %$localsize 0 ; see text for explanation
- %local old_ax:word, old_dx:word
-
- enter %$localsize,0 ; see text for explanation
- mov [old_ax],ax ; swap ax & bx
- mov [old_dx],dx ; and swap dx & cx
- mov ax,bx
- mov dx,cx
- mov bx,[old_ax]
- mov cx,[old_dx]
- leave ; restore old bp
- ret ;
-
- %pop ; restore original context
-
- The `%$localsize' variable is used internally by the `%local'
- directive and _must_ be defined within the current context before
- the `%local' directive may be used. Failure to do so will result in
- one expression syntax error for each `%local' variable declared. It
- then may be used in the construction of an appropriately sized ENTER
- instruction as shown in the example.
-
- 4.9 Reporting User-Defined Errors: `%error', `%warning', `%fatal'
-
- The preprocessor directive `%error' will cause NASM to report an
- error if it occurs in assembled code. So if other users are going to
- try to assemble your source files, you can ensure that they define
- the right macros by means of code like this:
-
- %ifdef F1
- ; do some setup
- %elifdef F2
- ; do some different setup
- %else
- %error "Neither F1 nor F2 was defined."
- %endif
-
- Then any user who fails to understand the way your code is supposed
- to be assembled will be quickly warned of their mistake, rather than
- having to wait until the program crashes on being run and then not
- knowing what went wrong.
-
- Similarly, `%warning' issues a warning, but allows assembly to
- continue:
-
- %ifdef F1
- ; do some setup
- %elifdef F2
- ; do some different setup
- %else
- %warning "Neither F1 nor F2 was defined, assuming F1."
- %define F1
- %endif
-
- `%error' and `%warning' are issued only on the final assembly pass.
- This makes them safe to use in conjunction with tests that depend on
- symbol values.
-
- `%fatal' terminates assembly immediately, regardless of pass. This
- is useful when there is no point in continuing the assembly further,
- and doing so is likely just going to cause a spew of confusing error
- messages.
-
- It is optional for the message string after `%error', `%warning' or
- `%fatal' to be quoted. If it is _not_, then single-line macros are
- expanded in it, which can be used to display more information to the
- user. For example:
-
- %if foo > 64
- %assign foo_over foo-64
- %error foo is foo_over bytes too large
- %endif
-
- 4.10 Other Preprocessor Directives
-
- NASM also has preprocessor directives which allow access to
- information from external sources. Currently they include:
-
- (*) `%line' enables NASM to correctly handle the output of another
- preprocessor (see section 4.10.1).
-
- (*) `%!' enables NASM to read in the value of an environment
- variable, which can then be used in your program (see section
- 4.10.2).
-
-4.10.1 `%line' Directive
-
- The `%line' directive is used to notify NASM that the input line
- corresponds to a specific line number in another file. Typically
- this other file would be an original source file, with the current
- NASM input being the output of a pre-processor. The `%line'
- directive allows NASM to output messages which indicate the line
- number of the original source file, instead of the file that is
- being read by NASM.
-
- This preprocessor directive is not generally of use to programmers,
- by may be of interest to preprocessor authors. The usage of the
- `%line' preprocessor directive is as follows:
-
- %line nnn[+mmm] [filename]
-
- In this directive, `nnn' identifies the line of the original source
- file which this line corresponds to. `mmm' is an optional parameter
- which specifies a line increment value; each line of the input file
- read in is considered to correspond to `mmm' lines of the original
- source file. Finally, `filename' is an optional parameter which
- specifies the file name of the original source file.
-
- After reading a `%line' preprocessor directive, NASM will report all
- file name and line numbers relative to the values specified therein.
-
-4.10.2 `%!'`<env>': Read an environment variable.
-
- The `%!<env>' directive makes it possible to read the value of an
- environment variable at assembly time. This could, for example, be
- used to store the contents of an environment variable into a string,
- which could be used at some other point in your code.
-
- For example, suppose that you have an environment variable `FOO',
- and you want the contents of `FOO' to be embedded in your program.
- You could do that as follows:
-
- %defstr FOO %!FOO
-
- See section 4.1.8 for notes on the `%defstr' directive.
-
- 4.11 Standard Macros
-
- NASM defines a set of standard macros, which are already defined
- when it starts to process any source file. If you really need a
- program to be assembled with no pre-defined macros, you can use the
- `%clear' directive to empty the preprocessor of everything but
- context-local preprocessor variables and single-line macros.
-
- Most user-level assembler directives (see chapter 6) are implemented
- as macros which invoke primitive directives; these are described in
- chapter 6. The rest of the standard macro set is described here.
-
-4.11.1 NASM Version Macros
-
- The single-line macros `__NASM_MAJOR__', `__NASM_MINOR__',
- `__NASM_SUBMINOR__' and `___NASM_PATCHLEVEL__' expand to the major,
- minor, subminor and patch level parts of the version number of NASM
- being used. So, under NASM 0.98.32p1 for example, `__NASM_MAJOR__'
- would be defined to be 0, `__NASM_MINOR__' would be defined as 98,
- `__NASM_SUBMINOR__' would be defined to 32, and
- `___NASM_PATCHLEVEL__' would be defined as 1.
-
- Additionally, the macro `__NASM_SNAPSHOT__' is defined for
- automatically generated snapshot releases _only_.
-
-4.11.2 `__NASM_VERSION_ID__': NASM Version ID
-
- The single-line macro `__NASM_VERSION_ID__' expands to a dword
- integer representing the full version number of the version of nasm
- being used. The value is the equivalent to `__NASM_MAJOR__',
- `__NASM_MINOR__', `__NASM_SUBMINOR__' and `___NASM_PATCHLEVEL__'
- concatenated to produce a single doubleword. Hence, for 0.98.32p1,
- the returned number would be equivalent to:
-
- dd 0x00622001
-
- or
-
- db 1,32,98,0
-
- Note that the above lines are generate exactly the same code, the
- second line is used just to give an indication of the order that the
- separate values will be present in memory.
-
-4.11.3 `__NASM_VER__': NASM Version string
-
- The single-line macro `__NASM_VER__' expands to a string which
- defines the version number of nasm being used. So, under NASM
- 0.98.32 for example,
-
- db __NASM_VER__
-
- would expand to
-
- db "0.98.32"
-
-4.11.4 `__FILE__' and `__LINE__': File Name and Line Number
-
- Like the C preprocessor, NASM allows the user to find out the file
- name and line number containing the current instruction. The macro
- `__FILE__' expands to a string constant giving the name of the
- current input file (which may change through the course of assembly
- if `%include' directives are used), and `__LINE__' expands to a
- numeric constant giving the current line number in the input file.
-
- These macros could be used, for example, to communicate debugging
- information to a macro, since invoking `__LINE__' inside a macro
- definition (either single-line or multi-line) will return the line
- number of the macro _call_, rather than _definition_. So to
- determine where in a piece of code a crash is occurring, for
- example, one could write a routine `stillhere', which is passed a
- line number in `EAX' and outputs something like `line 155: still
- here'. You could then write a macro
-
- %macro notdeadyet 0
-
- push eax
- mov eax,__LINE__
- call stillhere
- pop eax
-
- %endmacro
-
- and then pepper your code with calls to `notdeadyet' until you find
- the crash point.
-
-4.11.5 `__BITS__': Current BITS Mode
-
- The `__BITS__' standard macro is updated every time that the BITS
- mode is set using the `BITS XX' or `[BITS XX]' directive, where XX
- is a valid mode number of 16, 32 or 64. `__BITS__' receives the
- specified mode number and makes it globally available. This can be
- very useful for those who utilize mode-dependent macros.
-
-4.11.6 `__OUTPUT_FORMAT__': Current Output Format
-
- The `__OUTPUT_FORMAT__' standard macro holds the current Output
- Format, as given by the `-f' option or NASM's default. Type
- `nasm -hf' for a list.
-
- %ifidn __OUTPUT_FORMAT__, win32
- %define NEWLINE 13, 10
- %elifidn __OUTPUT_FORMAT__, elf32
- %define NEWLINE 10
- %endif
-
-4.11.7 Assembly Date and Time Macros
-
- NASM provides a variety of macros that represent the timestamp of
- the assembly session.
-
- (*) The `__DATE__' and `__TIME__' macros give the assembly date and
- time as strings, in ISO 8601 format (`"YYYY-MM-DD"' and
- `"HH:MM:SS"', respectively.)
-
- (*) The `__DATE_NUM__' and `__TIME_NUM__' macros give the assembly
- date and time in numeric form; in the format `YYYYMMDD' and
- `HHMMSS' respectively.
-
- (*) The `__UTC_DATE__' and `__UTC_TIME__' macros give the assembly
- date and time in universal time (UTC) as strings, in ISO 8601
- format (`"YYYY-MM-DD"' and `"HH:MM:SS"', respectively.) If the
- host platform doesn't provide UTC time, these macros are
- undefined.
-
- (*) The `__UTC_DATE_NUM__' and `__UTC_TIME_NUM__' macros give the
- assembly date and time universal time (UTC) in numeric form; in
- the format `YYYYMMDD' and `HHMMSS' respectively. If the host
- platform doesn't provide UTC time, these macros are undefined.
-
- (*) The `__POSIX_TIME__' macro is defined as a number containing the
- number of seconds since the POSIX epoch, 1 January 1970 00:00:00
- UTC; excluding any leap seconds. This is computed using UTC time
- if available on the host platform, otherwise it is computed
- using the local time as if it was UTC.
-
- All instances of time and date macros in the same assembly session
- produce consistent output. For example, in an assembly session
- started at 42 seconds after midnight on January 1, 2010 in Moscow
- (timezone UTC+3) these macros would have the following values,
- assuming, of course, a properly configured environment with a
- correct clock:
-
- __DATE__ "2010-01-01"
- __TIME__ "00:00:42"
- __DATE_NUM__ 20100101
- __TIME_NUM__ 000042
- __UTC_DATE__ "2009-12-31"
- __UTC_TIME__ "21:00:42"
- __UTC_DATE_NUM__ 20091231
- __UTC_TIME_NUM__ 210042
- __POSIX_TIME__ 1262293242
-
-4.11.8 `__USE_'_package_`__': Package Include Test
-
- When a standard macro package (see chapter 5) is included with the
- `%use' directive (see section 4.6.4), a single-line macro of the
- form `__USE_'_package_`__' is automatically defined. This allows
- testing if a particular package is invoked or not.
-
- For example, if the `altreg' package is included (see section 5.1),
- then the macro `__USE_ALTREG__' is defined.
-
-4.11.9 `__PASS__': Assembly Pass
-
- The macro `__PASS__' is defined to be `1' on preparatory passes, and
- `2' on the final pass. In preprocess-only mode, it is set to `3',
- and when running only to generate dependencies (due to the `-M' or
- `-MG' option, see section 2.1.4) it is set to `0'.
-
- _Avoid using this macro if at all possible. It is tremendously easy
- to generate very strange errors by misusing it, and the semantics
- may change in future versions of NASM._
-
-4.11.10 `STRUC' and `ENDSTRUC': Declaring Structure Data Types
-
- The core of NASM contains no intrinsic means of defining data
- structures; instead, the preprocessor is sufficiently powerful that
- data structures can be implemented as a set of macros. The macros
- `STRUC' and `ENDSTRUC' are used to define a structure data type.
-
- `STRUC' takes one or two parameters. The first parameter is the name
- of the data type. The second, optional parameter is the base offset
- of the structure. The name of the data type is defined as a symbol
- with the value of the base offset, and the name of the data type
- with the suffix `_size' appended to it is defined as an `EQU' giving
- the size of the structure. Once `STRUC' has been issued, you are
- defining the structure, and should define fields using the `RESB'
- family of pseudo-instructions, and then invoke `ENDSTRUC' to finish
- the definition.
-
- For example, to define a structure called `mytype' containing a
- longword, a word, a byte and a string of bytes, you might code
-
- struc mytype
-
- mt_long: resd 1
- mt_word: resw 1
- mt_byte: resb 1
- mt_str: resb 32
-
- endstruc
-
- The above code defines six symbols: `mt_long' as 0 (the offset from
- the beginning of a `mytype' structure to the longword field),
- `mt_word' as 4, `mt_byte' as 6, `mt_str' as 7, `mytype_size' as 39,
- and `mytype' itself as zero.
-
- The reason why the structure type name is defined at zero by default
- is a side effect of allowing structures to work with the local label
- mechanism: if your structure members tend to have the same names in
- more than one structure, you can define the above structure like
- this:
-
- struc mytype
-
- .long: resd 1
- .word: resw 1
- .byte: resb 1
- .str: resb 32
-
- endstruc
-
- This defines the offsets to the structure fields as `mytype.long',
- `mytype.word', `mytype.byte' and `mytype.str'.
-
- NASM, since it has no _intrinsic_ structure support, does not
- support any form of period notation to refer to the elements of a
- structure once you have one (except the above local-label notation),
- so code such as `mov ax,[mystruc.mt_word]' is not valid. `mt_word'
- is a constant just like any other constant, so the correct syntax is
- `mov ax,[mystruc+mt_word]' or `mov ax,[mystruc+mytype.word]'.
-
- Sometimes you only have the address of the structure displaced by an
- offset. For example, consider this standard stack frame setup:
-
- push ebp
- mov ebp, esp
- sub esp, 40
-
- In this case, you could access an element by subtracting the offset:
-
- mov [ebp - 40 + mytype.word], ax
-
- However, if you do not want to repeat this offset, you can use -40
- as a base offset:
-
- struc mytype, -40
-
- And access an element this way:
-
- mov [ebp + mytype.word], ax
-
-4.11.11 `ISTRUC', `AT' and `IEND': Declaring Instances of Structures
-
- Having defined a structure type, the next thing you typically want
- to do is to declare instances of that structure in your data
- segment. NASM provides an easy way to do this in the `ISTRUC'
- mechanism. To declare a structure of type `mytype' in a program, you
- code something like this:
-
- mystruc:
- istruc mytype
-
- at mt_long, dd 123456
- at mt_word, dw 1024
- at mt_byte, db 'x'
- at mt_str, db 'hello, world', 13, 10, 0
-
- iend
-
- The function of the `AT' macro is to make use of the `TIMES' prefix
- to advance the assembly position to the correct point for the
- specified structure field, and then to declare the specified data.
- Therefore the structure fields must be declared in the same order as
- they were specified in the structure definition.
-
- If the data to go in a structure field requires more than one source
- line to specify, the remaining source lines can easily come after
- the `AT' line. For example:
-
- at mt_str, db 123,134,145,156,167,178,189
- db 190,100,0
-
- Depending on personal taste, you can also omit the code part of the
- `AT' line completely, and start the structure field on the next
- line:
-
- at mt_str
- db 'hello, world'
- db 13,10,0
-
-4.11.12 `ALIGN' and `ALIGNB': Data Alignment
-
- The `ALIGN' and `ALIGNB' macros provides a convenient way to align
- code or data on a word, longword, paragraph or other boundary. (Some
- assemblers call this directive `EVEN'.) The syntax of the `ALIGN'
- and `ALIGNB' macros is
-
- align 4 ; align on 4-byte boundary
- align 16 ; align on 16-byte boundary
- align 8,db 0 ; pad with 0s rather than NOPs
- align 4,resb 1 ; align to 4 in the BSS
- alignb 4 ; equivalent to previous line
-
- Both macros require their first argument to be a power of two; they
- both compute the number of additional bytes required to bring the
- length of the current section up to a multiple of that power of two,
- and then apply the `TIMES' prefix to their second argument to
- perform the alignment.
-
- If the second argument is not specified, the default for `ALIGN' is
- `NOP', and the default for `ALIGNB' is `RESB 1'. So if the second
- argument is specified, the two macros are equivalent. Normally, you
- can just use `ALIGN' in code and data sections and `ALIGNB' in BSS
- sections, and never need the second argument except for special
- purposes.
-
- `ALIGN' and `ALIGNB', being simple macros, perform no error
- checking: they cannot warn you if their first argument fails to be a
- power of two, or if their second argument generates more than one
- byte of code. In each of these cases they will silently do the wrong
- thing.
-
- `ALIGNB' (or `ALIGN' with a second argument of `RESB 1') can be used
- within structure definitions:
-
- struc mytype2
-
- mt_byte:
- resb 1
- alignb 2
- mt_word:
- resw 1
- alignb 4
- mt_long:
- resd 1
- mt_str:
- resb 32
-
- endstruc
-
- This will ensure that the structure members are sensibly aligned
- relative to the base of the structure.
-
- A final caveat: `ALIGN' and `ALIGNB' work relative to the beginning
- of the _section_, not the beginning of the address space in the
- final executable. Aligning to a 16-byte boundary when the section
- you're in is only guaranteed to be aligned to a 4-byte boundary, for
- example, is a waste of effort. Again, NASM does not check that the
- section's alignment characteristics are sensible for the use of
- `ALIGN' or `ALIGNB'.
-
- See also the `smartalign' standard macro package, section 5.2.
-
-Chapter 5: Standard Macro Packages
-----------------------------------
-
- The `%use' directive (see section 4.6.4) includes one of the
- standard macro packages included with the NASM distribution and
- compiled into the NASM binary. It operates like the `%include'
- directive (see section 4.6.1), but the included contents is provided
- by NASM itself.
-
- The names of standard macro packages are case insensitive, and can
- be quoted or not.
-
- 5.1 `altreg': Alternate Register Names
-
- The `altreg' standard macro package provides alternate register
- names. It provides numeric register names for all registers (not
- just `R8'-`R15'), the Intel-defined aliases `R8L'-`R15L' for the low
- bytes of register (as opposed to the NASM/AMD standard names `R8B'-
- `R15B'), and the names `R0H'-`R3H' (by analogy with `R0L'-`R3L') for
- `AH', `CH', `DH', and `BH'.
-
- Example use:
-
- %use altreg
-
- proc:
- mov r0l,r3h ; mov al,bh
- ret
-
- See also section 11.1.
-
- 5.2 `smartalign': Smart `ALIGN' Macro
-
- The `smartalign' standard macro package provides for an `ALIGN'
- macro which is more powerful than the default (and backwards-
- compatible) one (see section 4.11.12). When the `smartalign' package
- is enabled, when `ALIGN' is used without a second argument, NASM
- will generate a sequence of instructions more efficient than a
- series of `NOP'. Furthermore, if the padding exceeds a specific
- threshold, then NASM will generate a jump over the entire padding
- sequence.
-
- The specific instructions generated can be controlled with the new
- `ALIGNMODE' macro. This macro takes two parameters: one mode, and an
- optional jump threshold override. The modes are as follows:
-
- (*) `generic': Works on all x86 CPUs and should have reasonable
- performance. The default jump threshold is 8. This is the
- default.
-
- (*) `nop': Pad out with `NOP' instructions. The only difference
- compared to the standard `ALIGN' macro is that NASM can still
- jump over a large padding area. The default jump threshold is
- 16.
-
- (*) `k7': Optimize for the AMD K7 (Athlon/Althon XP). These
- instructions should still work on all x86 CPUs. The default jump
- threshold is 16.
-
- (*) `k8': Optimize for the AMD K8 (Opteron/Althon 64). These
- instructions should still work on all x86 CPUs. The default jump
- threshold is 16.
-
- (*) `p6': Optimize for Intel CPUs. This uses the long `NOP'
- instructions first introduced in Pentium Pro. This is
- incompatible with all CPUs of family 5 or lower, as well as some
- VIA CPUs and several virtualization solutions. The default jump
- threshold is 16.
-
- The macro `__ALIGNMODE__' is defined to contain the current
- alignment mode. A number of other macros beginning with `__ALIGN_'
- are used internally by this macro package.
-
-Chapter 6: Assembler Directives
--------------------------------
-
- NASM, though it attempts to avoid the bureaucracy of assemblers like
- MASM and TASM, is nevertheless forced to support a _few_ directives.
- These are described in this chapter.
-
- NASM's directives come in two types: _user-level_ directives and
- _primitive_ directives. Typically, each directive has a user-level
- form and a primitive form. In almost all cases, we recommend that
- users use the user-level forms of the directives, which are
- implemented as macros which call the primitive forms.
-
- Primitive directives are enclosed in square brackets; user-level
- directives are not.
-
- In addition to the universal directives described in this chapter,
- each object file format can optionally supply extra directives in
- order to control particular features of that file format. These
- _format-specific_ directives are documented along with the formats
- that implement them, in chapter 7.
-
- 6.1 `BITS': Specifying Target Processor Mode
-
- The `BITS' directive specifies whether NASM should generate code
- designed to run on a processor operating in 16-bit mode, 32-bit mode
- or 64-bit mode. The syntax is `BITS XX', where XX is 16, 32 or 64.
-
- In most cases, you should not need to use `BITS' explicitly. The
- `aout', `coff', `elf', `macho', `win32' and `win64' object formats,
- which are designed for use in 32-bit or 64-bit operating systems,
- all cause NASM to select 32-bit or 64-bit mode, respectively, by
- default. The `obj' object format allows you to specify each segment
- you define as either `USE16' or `USE32', and NASM will set its
- operating mode accordingly, so the use of the `BITS' directive is
- once again unnecessary.
-
- The most likely reason for using the `BITS' directive is to write
- 32-bit or 64-bit code in a flat binary file; this is because the
- `bin' output format defaults to 16-bit mode in anticipation of it
- being used most frequently to write DOS `.COM' programs, DOS `.SYS'
- device drivers and boot loader software.
-
- You do _not_ need to specify `BITS 32' merely in order to use 32-bit
- instructions in a 16-bit DOS program; if you do, the assembler will
- generate incorrect code because it will be writing code targeted at
- a 32-bit platform, to be run on a 16-bit one.
-
- When NASM is in `BITS 16' mode, instructions which use 32-bit data
- are prefixed with an 0x66 byte, and those referring to 32-bit
- addresses have an 0x67 prefix. In `BITS 32' mode, the reverse is
- true: 32-bit instructions require no prefixes, whereas instructions
- using 16-bit data need an 0x66 and those working on 16-bit addresses
- need an 0x67.
-
- When NASM is in `BITS 64' mode, most instructions operate the same
- as they do for `BITS 32' mode. However, there are 8 more general and
- SSE registers, and 16-bit addressing is no longer supported.
-
- The default address size is 64 bits; 32-bit addressing can be
- selected with the 0x67 prefix. The default operand size is still 32
- bits, however, and the 0x66 prefix selects 16-bit operand size. The
- `REX' prefix is used both to select 64-bit operand size, and to
- access the new registers. NASM automatically inserts REX prefixes
- when necessary.
-
- When the `REX' prefix is used, the processor does not know how to
- address the AH, BH, CH or DH (high 8-bit legacy) registers. Instead,
- it is possible to access the the low 8-bits of the SP, BP SI and DI
- registers as SPL, BPL, SIL and DIL, respectively; but only when the
- REX prefix is used.
-
- The `BITS' directive has an exactly equivalent primitive form,
- `[BITS 16]', `[BITS 32]' and `[BITS 64]'. The user-level form is a
- macro which has no function other than to call the primitive form.
-
- Note that the space is neccessary, e.g. `BITS32' will _not_ work!
-
- 6.1.1 `USE16' & `USE32': Aliases for BITS
-
- The ``USE16'' and ``USE32'' directives can be used in place of
- ``BITS 16'' and ``BITS 32'', for compatibility with other
- assemblers.
-
- 6.2 `DEFAULT': Change the assembler defaults
-
- The `DEFAULT' directive changes the assembler defaults. Normally,
- NASM defaults to a mode where the programmer is expected to
- explicitly specify most features directly. However, this is
- occationally obnoxious, as the explicit form is pretty much the only
- one one wishes to use.
-
- Currently, the only `DEFAULT' that is settable is whether or not
- registerless instructions in 64-bit mode are `RIP'-relative or not.
- By default, they are absolute unless overridden with the `REL'
- specifier (see section 3.3). However, if `DEFAULT REL' is specified,
- `REL' is default, unless overridden with the `ABS' specifier,
- _except when used with an FS or GS segment override_.
-
- The special handling of `FS' and `GS' overrides are due to the fact
- that these registers are generally used as thread pointers or other
- special functions in 64-bit mode, and generating `RIP'-relative
- addresses would be extremely confusing.
-
- `DEFAULT REL' is disabled with `DEFAULT ABS'.
-
- 6.3 `SECTION' or `SEGMENT': Changing and Defining Sections
-
- The `SECTION' directive (`SEGMENT' is an exactly equivalent synonym)
- changes which section of the output file the code you write will be
- assembled into. In some object file formats, the number and names of
- sections are fixed; in others, the user may make up as many as they
- wish. Hence `SECTION' may sometimes give an error message, or may
- define a new section, if you try to switch to a section that does
- not (yet) exist.
-
- The Unix object formats, and the `bin' object format (but see
- section 7.1.3, all support the standardized section names `.text',
- `.data' and `.bss' for the code, data and uninitialized-data
- sections. The `obj' format, by contrast, does not recognize these
- section names as being special, and indeed will strip off the
- leading period of any section name that has one.
-
- 6.3.1 The `__SECT__' Macro
-
- The `SECTION' directive is unusual in that its user-level form
- functions differently from its primitive form. The primitive form,
- `[SECTION xyz]', simply switches the current target section to the
- one given. The user-level form, `SECTION xyz', however, first
- defines the single-line macro `__SECT__' to be the primitive
- `[SECTION]' directive which it is about to issue, and then issues
- it. So the user-level directive
-
- SECTION .text
-
- expands to the two lines
-
- %define __SECT__ [SECTION .text]
- [SECTION .text]
-
- Users may find it useful to make use of this in their own macros.
- For example, the `writefile' macro defined in section 4.3.4 can be
- usefully rewritten in the following more sophisticated form:
-
- %macro writefile 2+
-
- [section .data]
-
- %%str: db %2
- %%endstr:
-
- __SECT__
-
- mov dx,%%str
- mov cx,%%endstr-%%str
- mov bx,%1
- mov ah,0x40
- int 0x21
-
- %endmacro
-
- This form of the macro, once passed a string to output, first
- switches temporarily to the data section of the file, using the
- primitive form of the `SECTION' directive so as not to modify
- `__SECT__'. It then declares its string in the data section, and
- then invokes `__SECT__' to switch back to _whichever_ section the
- user was previously working in. It thus avoids the need, in the
- previous version of the macro, to include a `JMP' instruction to
- jump over the data, and also does not fail if, in a complicated
- `OBJ' format module, the user could potentially be assembling the
- code in any of several separate code sections.
-
- 6.4 `ABSOLUTE': Defining Absolute Labels
-
- The `ABSOLUTE' directive can be thought of as an alternative form of
- `SECTION': it causes the subsequent code to be directed at no
- physical section, but at the hypothetical section starting at the
- given absolute address. The only instructions you can use in this
- mode are the `RESB' family.
-
- `ABSOLUTE' is used as follows:
-
- absolute 0x1A
-
- kbuf_chr resw 1
- kbuf_free resw 1
- kbuf resw 16
-
- This example describes a section of the PC BIOS data area, at
- segment address 0x40: the above code defines `kbuf_chr' to be 0x1A,
- `kbuf_free' to be 0x1C, and `kbuf' to be 0x1E.
-
- The user-level form of `ABSOLUTE', like that of `SECTION', redefines
- the `__SECT__' macro when it is invoked.
-
- `STRUC' and `ENDSTRUC' are defined as macros which use `ABSOLUTE'
- (and also `__SECT__').
-
- `ABSOLUTE' doesn't have to take an absolute constant as an argument:
- it can take an expression (actually, a critical expression: see
- section 3.8) and it can be a value in a segment. For example, a TSR
- can re-use its setup code as run-time BSS like this:
-
- org 100h ; it's a .COM program
-
- jmp setup ; setup code comes last
-
- ; the resident part of the TSR goes here
- setup:
- ; now write the code that installs the TSR here
-
- absolute setup
-
- runtimevar1 resw 1
- runtimevar2 resd 20
-
- tsr_end:
-
- This defines some variables `on top of' the setup code, so that
- after the setup has finished running, the space it took up can be
- re-used as data storage for the running TSR. The symbol `tsr_end'
- can be used to calculate the total size of the part of the TSR that
- needs to be made resident.
-
- 6.5 `EXTERN': Importing Symbols from Other Modules
-
- `EXTERN' is similar to the MASM directive `EXTRN' and the C keyword
- `extern': it is used to declare a symbol which is not defined
- anywhere in the module being assembled, but is assumed to be defined
- in some other module and needs to be referred to by this one. Not
- every object-file format can support external variables: the `bin'
- format cannot.
-
- The `EXTERN' directive takes as many arguments as you like. Each
- argument is the name of a symbol:
-
- extern _printf
- extern _sscanf,_fscanf
-
- Some object-file formats provide extra features to the `EXTERN'
- directive. In all cases, the extra features are used by suffixing a
- colon to the symbol name followed by object-format specific text.
- For example, the `obj' format allows you to declare that the default
- segment base of an external should be the group `dgroup' by means of
- the directive
-
- extern _variable:wrt dgroup
-
- The primitive form of `EXTERN' differs from the user-level form only
- in that it can take only one argument at a time: the support for
- multiple arguments is implemented at the preprocessor level.
-
- You can declare the same variable as `EXTERN' more than once: NASM
- will quietly ignore the second and later redeclarations. You can't
- declare a variable as `EXTERN' as well as something else, though.
-
- 6.6 `GLOBAL': Exporting Symbols to Other Modules
-
- `GLOBAL' is the other end of `EXTERN': if one module declares a
- symbol as `EXTERN' and refers to it, then in order to prevent linker
- errors, some other module must actually _define_ the symbol and
- declare it as `GLOBAL'. Some assemblers use the name `PUBLIC' for
- this purpose.
-
- The `GLOBAL' directive applying to a symbol must appear _before_ the
- definition of the symbol.
-
- `GLOBAL' uses the same syntax as `EXTERN', except that it must refer
- to symbols which _are_ defined in the same module as the `GLOBAL'
- directive. For example:
-
- global _main
- _main:
- ; some code
-
- `GLOBAL', like `EXTERN', allows object formats to define private
- extensions by means of a colon. The `elf' object format, for
- example, lets you specify whether global data items are functions or
- data:
-
- global hashlookup:function, hashtable:data
-
- Like `EXTERN', the primitive form of `GLOBAL' differs from the user-
- level form only in that it can take only one argument at a time.
-
- 6.7 `COMMON': Defining Common Data Areas
-
- The `COMMON' directive is used to declare _common variables_. A
- common variable is much like a global variable declared in the
- uninitialized data section, so that
-
- common intvar 4
-
- is similar in function to
-
- global intvar
- section .bss
-
- intvar resd 1
-
- The difference is that if more than one module defines the same
- common variable, then at link time those variables will be _merged_,
- and references to `intvar' in all modules will point at the same
- piece of memory.
-
- Like `GLOBAL' and `EXTERN', `COMMON' supports object-format specific
- extensions. For example, the `obj' format allows common variables to
- be NEAR or FAR, and the `elf' format allows you to specify the
- alignment requirements of a common variable:
-
- common commvar 4:near ; works in OBJ
- common intarray 100:4 ; works in ELF: 4 byte aligned
-
- Once again, like `EXTERN' and `GLOBAL', the primitive form of
- `COMMON' differs from the user-level form only in that it can take
- only one argument at a time.
-
- 6.8 `CPU': Defining CPU Dependencies
-
- The `CPU' directive restricts assembly to those instructions which
- are available on the specified CPU.
-
- Options are:
-
- (*) `CPU 8086' Assemble only 8086 instruction set
-
- (*) `CPU 186' Assemble instructions up to the 80186 instruction set
-
- (*) `CPU 286' Assemble instructions up to the 286 instruction set
-
- (*) `CPU 386' Assemble instructions up to the 386 instruction set
-
- (*) `CPU 486' 486 instruction set
-
- (*) `CPU 586' Pentium instruction set
-
- (*) `CPU PENTIUM' Same as 586
-
- (*) `CPU 686' P6 instruction set
-
- (*) `CPU PPRO' Same as 686
-
- (*) `CPU P2' Same as 686
-
- (*) `CPU P3' Pentium III (Katmai) instruction sets
-
- (*) `CPU KATMAI' Same as P3
-
- (*) `CPU P4' Pentium 4 (Willamette) instruction set
-
- (*) `CPU WILLAMETTE' Same as P4
-
- (*) `CPU PRESCOTT' Prescott instruction set
-
- (*) `CPU X64' x86-64 (x64/AMD64/Intel 64) instruction set
-
- (*) `CPU IA64' IA64 CPU (in x86 mode) instruction set
-
- All options are case insensitive. All instructions will be selected
- only if they apply to the selected CPU or lower. By default, all
- instructions are available.
-
- 6.9 `FLOAT': Handling of floating-point constants
-
- By default, floating-point constants are rounded to nearest, and
- IEEE denormals are supported. The following options can be set to
- alter this behaviour:
-
- (*) `FLOAT DAZ' Flush denormals to zero
-
- (*) `FLOAT NODAZ' Do not flush denormals to zero (default)
-
- (*) `FLOAT NEAR' Round to nearest (default)
-
- (*) `FLOAT UP' Round up (toward +Infinity)
-
- (*) `FLOAT DOWN' Round down (toward -Infinity)
-
- (*) `FLOAT ZERO' Round toward zero
-
- (*) `FLOAT DEFAULT' Restore default settings
-
- The standard macros `__FLOAT_DAZ__', `__FLOAT_ROUND__', and
- `__FLOAT__' contain the current state, as long as the programmer has
- avoided the use of the brackeded primitive form, (`[FLOAT]').
-
- `__FLOAT__' contains the full set of floating-point settings; this
- value can be saved away and invoked later to restore the setting.
-
-Chapter 7: Output Formats
--------------------------
-
- NASM is a portable assembler, designed to be able to compile on any
- ANSI C-supporting platform and produce output to run on a variety of
- Intel x86 operating systems. For this reason, it has a large number
- of available output formats, selected using the `-f' option on the
- NASM command line. Each of these formats, along with its extensions
- to the base NASM syntax, is detailed in this chapter.
-
- As stated in section 2.1.1, NASM chooses a default name for your
- output file based on the input file name and the chosen output
- format. This will be generated by removing the extension (`.asm',
- `.s', or whatever you like to use) from the input file name, and
- substituting an extension defined by the output format. The
- extensions are given with each format below.
-
- 7.1 `bin': Flat-Form Binary Output
-
- The `bin' format does not produce object files: it generates nothing
- in the output file except the code you wrote. Such `pure binary'
- files are used by MS-DOS: `.COM' executables and `.SYS' device
- drivers are pure binary files. Pure binary output is also useful for
- operating system and boot loader development.
-
- The `bin' format supports multiple section names. For details of how
- NASM handles sections in the `bin' format, see section 7.1.3.
-
- Using the `bin' format puts NASM by default into 16-bit mode (see
- section 6.1). In order to use `bin' to write 32-bit or 64-bit code,
- such as an OS kernel, you need to explicitly issue the `BITS 32' or
- `BITS 64' directive.
-
- `bin' has no default output file name extension: instead, it leaves
- your file name as it is once the original extension has been
- removed. Thus, the default is for NASM to assemble `binprog.asm'
- into a binary file called `binprog'.
-
- 7.1.1 `ORG': Binary File Program Origin
-
- The `bin' format provides an additional directive to the list given
- in chapter 6: `ORG'. The function of the `ORG' directive is to
- specify the origin address which NASM will assume the program begins
- at when it is loaded into memory.
-
- For example, the following code will generate the longword
- `0x00000104':
-
- org 0x100
- dd label
- label:
-
- Unlike the `ORG' directive provided by MASM-compatible assemblers,
- which allows you to jump around in the object file and overwrite
- code you have already generated, NASM's `ORG' does exactly what the
- directive says: _origin_. Its sole function is to specify one offset
- which is added to all internal address references within the
- section; it does not permit any of the trickery that MASM's version
- does. See section 12.1.3 for further comments.
-
- 7.1.2 `bin' Extensions to the `SECTION' Directive
-
- The `bin' output format extends the `SECTION' (or `SEGMENT')
- directive to allow you to specify the alignment requirements of
- segments. This is done by appending the `ALIGN' qualifier to the end
- of the section-definition line. For example,
-
- section .data align=16
-
- switches to the section `.data' and also specifies that it must be
- aligned on a 16-byte boundary.
-
- The parameter to `ALIGN' specifies how many low bits of the section
- start address must be forced to zero. The alignment value given may
- be any power of two.
-
- 7.1.3 Multisection Support for the `bin' Format
-
- The `bin' format allows the use of multiple sections, of arbitrary
- names, besides the "known" `.text', `.data', and `.bss' names.
-
- (*) Sections may be designated `progbits' or `nobits'. Default is
- `progbits' (except `.bss', which defaults to `nobits', of
- course).
-
- (*) Sections can be aligned at a specified boundary following the
- previous section with `align=', or at an arbitrary byte-granular
- position with `start='.
-
- (*) Sections can be given a virtual start address, which will be
- used for the calculation of all memory references within that
- section with `vstart='.
-
- (*) Sections can be ordered using `follows='`<section>' or
- `vfollows='`<section>' as an alternative to specifying an
- explicit start address.
-
- (*) Arguments to `org', `start', `vstart', and `align=' are critical
- expressions. See section 3.8. E.g. `align=(1 << ALIGN_SHIFT)' -
- `ALIGN_SHIFT' must be defined before it is used here.
-
- (*) Any code which comes before an explicit `SECTION' directive is
- directed by default into the `.text' section.
-
- (*) If an `ORG' statement is not given, `ORG 0' is used by default.
-
- (*) The `.bss' section will be placed after the last `progbits'
- section, unless `start=', `vstart=', `follows=', or `vfollows='
- has been specified.
-
- (*) All sections are aligned on dword boundaries, unless a different
- alignment has been specified.
-
- (*) Sections may not overlap.
-
- (*) NASM creates the `section.<secname>.start' for each section,
- which may be used in your code.
-
- 7.1.4 Map Files
-
- Map files can be generated in `-f bin' format by means of the
- `[map]' option. Map types of `all' (default), `brief', `sections',
- `segments', or `symbols' may be specified. Output may be directed to
- `stdout' (default), `stderr', or a specified file. E.g.
- `[map symbols myfile.map]'. No "user form" exists, the square
- brackets must be used.
-
- 7.2 `ith': Intel Hex Output
-
- The `ith' file format produces Intel hex-format files. Just as the
- `bin' format, this is a flat memory image format with no support for
- relocation or linking. It is usually used with ROM programmers and
- similar utilities.
-
- All extensions supported by the `bin' file format is also supported
- by the `ith' file format.
-
- `ith' provides a default output file-name extension of `.ith'.
-
- 7.3 `srec': Motorola S-Records Output
-
- The `srec' file format produces Motorola S-records files. Just as
- the `bin' format, this is a flat memory image format with no support
- for relocation or linking. It is usually used with ROM programmers
- and similar utilities.
-
- All extensions supported by the `bin' file format is also supported
- by the `srec' file format.
-
- `srec' provides a default output file-name extension of `.srec'.
-
- 7.4 `obj': Microsoft OMF Object Files
-
- The `obj' file format (NASM calls it `obj' rather than `omf' for
- historical reasons) is the one produced by MASM and TASM, which is
- typically fed to 16-bit DOS linkers to produce `.EXE' files. It is
- also the format used by OS/2.
-
- `obj' provides a default output file-name extension of `.obj'.
-
- `obj' is not exclusively a 16-bit format, though: NASM has full
- support for the 32-bit extensions to the format. In particular, 32-
- bit `obj' format files are used by Borland's Win32 compilers,
- instead of using Microsoft's newer `win32' object file format.
-
- The `obj' format does not define any special segment names: you can
- call your segments anything you like. Typical names for segments in
- `obj' format files are `CODE', `DATA' and `BSS'.
-
- If your source file contains code before specifying an explicit
- `SEGMENT' directive, then NASM will invent its own segment called
- `__NASMDEFSEG' for you.
-
- When you define a segment in an `obj' file, NASM defines the segment
- name as a symbol as well, so that you can access the segment address
- of the segment. So, for example:
-
- segment data
-
- dvar: dw 1234
-
- segment code
-
- function:
- mov ax,data ; get segment address of data
- mov ds,ax ; and move it into DS
- inc word [dvar] ; now this reference will work
- ret
-
- The `obj' format also enables the use of the `SEG' and `WRT'
- operators, so that you can write code which does things like
-
- extern foo
-
- mov ax,seg foo ; get preferred segment of foo
- mov ds,ax
- mov ax,data ; a different segment
- mov es,ax
- mov ax,[ds:foo] ; this accesses `foo'
- mov [es:foo wrt data],bx ; so does this
-
- 7.4.1 `obj' Extensions to the `SEGMENT' Directive
-
- The `obj' output format extends the `SEGMENT' (or `SECTION')
- directive to allow you to specify various properties of the segment
- you are defining. This is done by appending extra qualifiers to the
- end of the segment-definition line. For example,
-
- segment code private align=16
-
- defines the segment `code', but also declares it to be a private
- segment, and requires that the portion of it described in this code
- module must be aligned on a 16-byte boundary.
-
- The available qualifiers are:
-
- (*) `PRIVATE', `PUBLIC', `COMMON' and `STACK' specify the
- combination characteristics of the segment. `PRIVATE' segments
- do not get combined with any others by the linker; `PUBLIC' and
- `STACK' segments get concatenated together at link time; and
- `COMMON' segments all get overlaid on top of each other rather
- than stuck end-to-end.
-
- (*) `ALIGN' is used, as shown above, to specify how many low bits of
- the segment start address must be forced to zero. The alignment
- value given may be any power of two from 1 to 4096; in reality,
- the only values supported are 1, 2, 4, 16, 256 and 4096, so if 8
- is specified it will be rounded up to 16, and 32, 64 and 128
- will all be rounded up to 256, and so on. Note that alignment to
- 4096-byte boundaries is a PharLap extension to the format and
- may not be supported by all linkers.
-
- (*) `CLASS' can be used to specify the segment class; this feature
- indicates to the linker that segments of the same class should
- be placed near each other in the output file. The class name can
- be any word, e.g. `CLASS=CODE'.
-
- (*) `OVERLAY', like `CLASS', is specified with an arbitrary word as
- an argument, and provides overlay information to an overlay-
- capable linker.
-
- (*) Segments can be declared as `USE16' or `USE32', which has the
- effect of recording the choice in the object file and also
- ensuring that NASM's default assembly mode when assembling in
- that segment is 16-bit or 32-bit respectively.
-
- (*) When writing OS/2 object files, you should declare 32-bit
- segments as `FLAT', which causes the default segment base for
- anything in the segment to be the special group `FLAT', and also
- defines the group if it is not already defined.
-
- (*) The `obj' file format also allows segments to be declared as
- having a pre-defined absolute segment address, although no
- linkers are currently known to make sensible use of this
- feature; nevertheless, NASM allows you to declare a segment such
- as `SEGMENT SCREEN ABSOLUTE=0xB800' if you need to. The
- `ABSOLUTE' and `ALIGN' keywords are mutually exclusive.
-
- NASM's default segment attributes are `PUBLIC', `ALIGN=1', no class,
- no overlay, and `USE16'.
-
- 7.4.2 `GROUP': Defining Groups of Segments
-
- The `obj' format also allows segments to be grouped, so that a
- single segment register can be used to refer to all the segments in
- a group. NASM therefore supplies the `GROUP' directive, whereby you
- can code
-
- segment data
-
- ; some data
-
- segment bss
-
- ; some uninitialized data
-
- group dgroup data bss
-
- which will define a group called `dgroup' to contain the segments
- `data' and `bss'. Like `SEGMENT', `GROUP' causes the group name to
- be defined as a symbol, so that you can refer to a variable `var' in
- the `data' segment as `var wrt data' or as `var wrt dgroup',
- depending on which segment value is currently in your segment
- register.
-
- If you just refer to `var', however, and `var' is declared in a
- segment which is part of a group, then NASM will default to giving
- you the offset of `var' from the beginning of the _group_, not the
- _segment_. Therefore `SEG var', also, will return the group base
- rather than the segment base.
-
- NASM will allow a segment to be part of more than one group, but
- will generate a warning if you do this. Variables declared in a
- segment which is part of more than one group will default to being
- relative to the first group that was defined to contain the segment.
-
- A group does not have to contain any segments; you can still make
- `WRT' references to a group which does not contain the variable you
- are referring to. OS/2, for example, defines the special group
- `FLAT' with no segments in it.
-
- 7.4.3 `UPPERCASE': Disabling Case Sensitivity in Output
-
- Although NASM itself is case sensitive, some OMF linkers are not;
- therefore it can be useful for NASM to output single-case object
- files. The `UPPERCASE' format-specific directive causes all segment,
- group and symbol names that are written to the object file to be
- forced to upper case just before being written. Within a source
- file, NASM is still case-sensitive; but the object file can be
- written entirely in upper case if desired.
-
- `UPPERCASE' is used alone on a line; it requires no parameters.
-
- 7.4.4 `IMPORT': Importing DLL Symbols
-
- The `IMPORT' format-specific directive defines a symbol to be
- imported from a DLL, for use if you are writing a DLL's import
- library in NASM. You still need to declare the symbol as `EXTERN' as
- well as using the `IMPORT' directive.
-
- The `IMPORT' directive takes two required parameters, separated by
- white space, which are (respectively) the name of the symbol you
- wish to import and the name of the library you wish to import it
- from. For example:
-
- import WSAStartup wsock32.dll
-
- A third optional parameter gives the name by which the symbol is
- known in the library you are importing it from, in case this is not
- the same as the name you wish the symbol to be known by to your code
- once you have imported it. For example:
-
- import asyncsel wsock32.dll WSAAsyncSelect
-
- 7.4.5 `EXPORT': Exporting DLL Symbols
-
- The `EXPORT' format-specific directive defines a global symbol to be
- exported as a DLL symbol, for use if you are writing a DLL in NASM.
- You still need to declare the symbol as `GLOBAL' as well as using
- the `EXPORT' directive.
-
- `EXPORT' takes one required parameter, which is the name of the
- symbol you wish to export, as it was defined in your source file. An
- optional second parameter (separated by white space from the first)
- gives the _external_ name of the symbol: the name by which you wish
- the symbol to be known to programs using the DLL. If this name is
- the same as the internal name, you may leave the second parameter
- off.
-
- Further parameters can be given to define attributes of the exported
- symbol. These parameters, like the second, are separated by white
- space. If further parameters are given, the external name must also
- be specified, even if it is the same as the internal name. The
- available attributes are:
-
- (*) `resident' indicates that the exported name is to be kept
- resident by the system loader. This is an optimisation for
- frequently used symbols imported by name.
-
- (*) `nodata' indicates that the exported symbol is a function which
- does not make use of any initialized data.
-
- (*) `parm=NNN', where `NNN' is an integer, sets the number of
- parameter words for the case in which the symbol is a call gate
- between 32-bit and 16-bit segments.
-
- (*) An attribute which is just a number indicates that the symbol
- should be exported with an identifying number (ordinal), and
- gives the desired number.
-
- For example:
-
- export myfunc
- export myfunc TheRealMoreFormalLookingFunctionName
- export myfunc myfunc 1234 ; export by ordinal
- export myfunc myfunc resident parm=23 nodata
-
- 7.4.6 `..start': Defining the Program Entry Point
-
- `OMF' linkers require exactly one of the object files being linked
- to define the program entry point, where execution will begin when
- the program is run. If the object file that defines the entry point
- is assembled using NASM, you specify the entry point by declaring
- the special symbol `..start' at the point where you wish execution
- to begin.
-
- 7.4.7 `obj' Extensions to the `EXTERN' Directive
-
- If you declare an external symbol with the directive
-
- extern foo
-
- then references such as `mov ax,foo' will give you the offset of
- `foo' from its preferred segment base (as specified in whichever
- module `foo' is actually defined in). So to access the contents of
- `foo' you will usually need to do something like
-
- mov ax,seg foo ; get preferred segment base
- mov es,ax ; move it into ES
- mov ax,[es:foo] ; and use offset `foo' from it
-
- This is a little unwieldy, particularly if you know that an external
- is going to be accessible from a given segment or group, say
- `dgroup'. So if `DS' already contained `dgroup', you could simply
- code
-
- mov ax,[foo wrt dgroup]
-
- However, having to type this every time you want to access `foo' can
- be a pain; so NASM allows you to declare `foo' in the alternative
- form
-
- extern foo:wrt dgroup
-
- This form causes NASM to pretend that the preferred segment base of
- `foo' is in fact `dgroup'; so the expression `seg foo' will now
- return `dgroup', and the expression `foo' is equivalent to
- `foo wrt dgroup'.
-
- This default-`WRT' mechanism can be used to make externals appear to
- be relative to any group or segment in your program. It can also be
- applied to common variables: see section 7.4.8.
-
- 7.4.8 `obj' Extensions to the `COMMON' Directive
-
- The `obj' format allows common variables to be either near or far;
- NASM allows you to specify which your variables should be by the use
- of the syntax
-
- common nearvar 2:near ; `nearvar' is a near common
- common farvar 10:far ; and `farvar' is far
-
- Far common variables may be greater in size than 64Kb, and so the
- OMF specification says that they are declared as a number of
- _elements_ of a given size. So a 10-byte far common variable could
- be declared as ten one-byte elements, five two-byte elements, two
- five-byte elements or one ten-byte element.
-
- Some `OMF' linkers require the element size, as well as the variable
- size, to match when resolving common variables declared in more than
- one module. Therefore NASM must allow you to specify the element
- size on your far common variables. This is done by the following
- syntax:
-
- common c_5by2 10:far 5 ; two five-byte elements
- common c_2by5 10:far 2 ; five two-byte elements
-
- If no element size is specified, the default is 1. Also, the `FAR'
- keyword is not required when an element size is specified, since
- only far commons may have element sizes at all. So the above
- declarations could equivalently be
-
- common c_5by2 10:5 ; two five-byte elements
- common c_2by5 10:2 ; five two-byte elements
-
- In addition to these extensions, the `COMMON' directive in `obj'
- also supports default-`WRT' specification like `EXTERN' does
- (explained in section 7.4.7). So you can also declare things like
-
- common foo 10:wrt dgroup
- common bar 16:far 2:wrt data
- common baz 24:wrt data:6
-
- 7.5 `win32': Microsoft Win32 Object Files
-
- The `win32' output format generates Microsoft Win32 object files,
- suitable for passing to Microsoft linkers such as Visual C++. Note
- that Borland Win32 compilers do not use this format, but use `obj'
- instead (see section 7.4).
-
- `win32' provides a default output file-name extension of `.obj'.
-
- Note that although Microsoft say that Win32 object files follow the
- `COFF' (Common Object File Format) standard, the object files
- produced by Microsoft Win32 compilers are not compatible with COFF
- linkers such as DJGPP's, and vice versa. This is due to a difference
- of opinion over the precise semantics of PC-relative relocations. To
- produce COFF files suitable for DJGPP, use NASM's `coff' output
- format; conversely, the `coff' format does not produce object files
- that Win32 linkers can generate correct output from.
-
- 7.5.1 `win32' Extensions to the `SECTION' Directive
-
- Like the `obj' format, `win32' allows you to specify additional
- information on the `SECTION' directive line, to control the type and
- properties of sections you declare. Section types and properties are
- generated automatically by NASM for the standard section names
- `.text', `.data' and `.bss', but may still be overridden by these
- qualifiers.
-
- The available qualifiers are:
-
- (*) `code', or equivalently `text', defines the section to be a code
- section. This marks the section as readable and executable, but
- not writable, and also indicates to the linker that the type of
- the section is code.
-
- (*) `data' and `bss' define the section to be a data section,
- analogously to `code'. Data sections are marked as readable and
- writable, but not executable. `data' declares an initialized
- data section, whereas `bss' declares an uninitialized data
- section.
-
- (*) `rdata' declares an initialized data section that is readable
- but not writable. Microsoft compilers use this section to place
- constants in it.
-
- (*) `info' defines the section to be an informational section, which
- is not included in the executable file by the linker, but may
- (for example) pass information _to_ the linker. For example,
- declaring an `info'-type section called `.drectve' causes the
- linker to interpret the contents of the section as command-line
- options.
-
- (*) `align=', used with a trailing number as in `obj', gives the
- alignment requirements of the section. The maximum you may
- specify is 64: the Win32 object file format contains no means to
- request a greater section alignment than this. If alignment is
- not explicitly specified, the defaults are 16-byte alignment for
- code sections, 8-byte alignment for rdata sections and 4-byte
- alignment for data (and BSS) sections. Informational sections
- get a default alignment of 1 byte (no alignment), though the
- value does not matter.
-
- The defaults assumed by NASM if you do not specify the above
- qualifiers are:
-
- section .text code align=16
- section .data data align=4
- section .rdata rdata align=8
- section .bss bss align=4
-
- Any other section name is treated by default like `.text'.
-
- 7.5.2 `win32': Safe Structured Exception Handling
-
- Among other improvements in Windows XP SP2 and Windows Server 2003
- Microsoft has introduced concept of "safe structured exception
- handling." General idea is to collect handlers' entry points in
- designated read-only table and have alleged entry point verified
- against this table prior exception control is passed to the handler.
- In order for an executable module to be equipped with such "safe
- exception handler table," all object modules on linker command line
- has to comply with certain criteria. If one single module among them
- does not, then the table in question is omitted and above mentioned
- run-time checks will not be performed for application in question.
- Table omission is by default silent and therefore can be easily
- overlooked. One can instruct linker to refuse to produce binary
- without such table by passing `/safeseh' command line option.
-
- Without regard to this run-time check merits it's natural to expect
- NASM to be capable of generating modules suitable for `/safeseh'
- linking. From developer's viewpoint the problem is two-fold:
-
- (*) how to adapt modules not deploying exception handlers of their
- own;
-
- (*) how to adapt/develop modules utilizing custom exception
- handling;
-
- Former can be easily achieved with any NASM version by adding
- following line to source code:
-
- $@feat.00 equ 1
-
- As of version 2.03 NASM adds this absolute symbol automatically. If
- it's not already present to be precise. I.e. if for whatever reason
- developer would choose to assign another value in source file, it
- would still be perfectly possible.
-
- Registering custom exception handler on the other hand requires
- certain "magic." As of version 2.03 additional directive is
- implemented, `safeseh', which instructs the assembler to produce
- appropriately formatted input data for above mentioned "safe
- exception handler table." Its typical use would be:
-
- section .text
- extern _MessageBoxA@16
- %if __NASM_VERSION_ID__ >= 0x02030000
- safeseh handler ; register handler as "safe handler"
- %endif
- handler:
- push DWORD 1 ; MB_OKCANCEL
- push DWORD caption
- push DWORD text
- push DWORD 0
- call _MessageBoxA@16
- sub eax,1 ; incidentally suits as return value
- ; for exception handler
- ret
- global _main
- _main:
- push DWORD handler
- push DWORD [fs:0]
- mov DWORD [fs:0],esp ; engage exception handler
- xor eax,eax
- mov eax,DWORD[eax] ; cause exception
- pop DWORD [fs:0] ; disengage exception handler
- add esp,4
- ret
- text: db 'OK to rethrow, CANCEL to generate core dump',0
- caption:db 'SEGV',0
-
- section .drectve info
- db '/defaultlib:user32.lib /defaultlib:msvcrt.lib '
-
- As you might imagine, it's perfectly possible to produce .exe binary
- with "safe exception handler table" and yet engage unregistered
- exception handler. Indeed, handler is engaged by simply manipulating
- `[fs:0]' location at run-time, something linker has no power over,
- run-time that is. It should be explicitly mentioned that such
- failure to register handler's entry point with `safeseh' directive
- has undesired side effect at run-time. If exception is raised and
- unregistered handler is to be executed, the application is abruptly
- terminated without any notification whatsoever. One can argue that
- system could at least have logged some kind "non-safe exception
- handler in x.exe at address n" message in event log, but no,
- literally no notification is provided and user is left with no clue
- on what caused application failure.
-
- Finally, all mentions of linker in this paragraph refer to Microsoft
- linker version 7.x and later. Presence of `@feat.00' symbol and
- input data for "safe exception handler table" causes no backward
- incompatibilities and "safeseh" modules generated by NASM 2.03 and
- later can still be linked by earlier versions or non-Microsoft
- linkers.
-
- 7.6 `win64': Microsoft Win64 Object Files
-
- The `win64' output format generates Microsoft Win64 object files,
- which is nearly 100% identical to the `win32' object format (section
- 7.5) with the exception that it is meant to target 64-bit code and
- the x86-64 platform altogether. This object file is used exactly the
- same as the `win32' object format (section 7.5), in NASM, with
- regard to this exception.
-
- 7.6.1 `win64': Writing Position-Independent Code
-
- While `REL' takes good care of RIP-relative addressing, there is one
- aspect that is easy to overlook for a Win64 programmer: indirect
- references. Consider a switch dispatch table:
-
- jmp QWORD[dsptch+rax*8]
- ...
- dsptch: dq case0
- dq case1
- ...
-
- Even novice Win64 assembler programmer will soon realize that the
- code is not 64-bit savvy. Most notably linker will refuse to link it
- with
- "`'ADDR32' relocation to '.text' invalid without /LARGEADDRESSAWARE:NO'".
- So [s]he will have to split jmp instruction as following:
-
- lea rbx,[rel dsptch]
- jmp QWORD[rbx+rax*8]
-
- What happens behind the scene is that effective address in `lea' is
- encoded relative to instruction pointer, or in perfectly position-
- independent manner. But this is only part of the problem! Trouble is
- that in .dll context `caseN' relocations will make their way to the
- final module and might have to be adjusted at .dll load time. To be
- specific when it can't be loaded at preferred address. And when this
- occurs, pages with such relocations will be rendered private to
- current process, which kind of undermines the idea of sharing .dll.
- But no worry, it's trivial to fix:
-
- lea rbx,[rel dsptch]
- add rbx,QWORD[rbx+rax*8]
- jmp rbx
- ...
- dsptch: dq case0-dsptch
- dq case1-dsptch
- ...
-
- NASM version 2.03 and later provides another alternative,
- `wrt ..imagebase' operator, which returns offset from base address
- of the current image, be it .exe or .dll module, therefore the name.
- For those acquainted with PE-COFF format base address denotes start
- of `IMAGE_DOS_HEADER' structure. Here is how to implement switch
- with these image-relative references:
-
- lea rbx,[rel dsptch]
- mov eax,DWORD[rbx+rax*4]
- sub rbx,dsptch wrt ..imagebase
- add rbx,rax
- jmp rbx
- ...
- dsptch: dd case0 wrt ..imagebase
- dd case1 wrt ..imagebase
-
- One can argue that the operator is redundant. Indeed, snippet before
- last works just fine with any NASM version and is not even Windows
- specific... The real reason for implementing `wrt ..imagebase' will
- become apparent in next paragraph.
-
- It should be noted that `wrt ..imagebase' is defined as 32-bit
- operand only:
-
- dd label wrt ..imagebase ; ok
- dq label wrt ..imagebase ; bad
- mov eax,label wrt ..imagebase ; ok
- mov rax,label wrt ..imagebase ; bad
-
- 7.6.2 `win64': Structured Exception Handling
-
- Structured exception handing in Win64 is completely different matter
- from Win32. Upon exception program counter value is noted, and
- linker-generated table comprising start and end addresses of all the
- functions [in given executable module] is traversed and compared to
- the saved program counter. Thus so called `UNWIND_INFO' structure is
- identified. If it's not found, then offending subroutine is assumed
- to be "leaf" and just mentioned lookup procedure is attempted for
- its caller. In Win64 leaf function is such function that does not
- call any other function _nor_ modifies any Win64 non-volatile
- registers, including stack pointer. The latter ensures that it's
- possible to identify leaf function's caller by simply pulling the
- value from the top of the stack.
-
- While majority of subroutines written in assembler are not calling
- any other function, requirement for non-volatile registers'
- immutability leaves developer with not more than 7 registers and no
- stack frame, which is not necessarily what [s]he counted with.
- Customarily one would meet the requirement by saving non-volatile
- registers on stack and restoring them upon return, so what can go
- wrong? If [and only if] an exception is raised at run-time and no
- `UNWIND_INFO' structure is associated with such "leaf" function, the
- stack unwind procedure will expect to find caller's return address
- on the top of stack immediately followed by its frame. Given that
- developer pushed caller's non-volatile registers on stack, would the
- value on top point at some code segment or even addressable space?
- Well, developer can attempt copying caller's return address to the
- top of stack and this would actually work in some very specific
- circumstances. But unless developer can guarantee that these
- circumstances are always met, it's more appropriate to assume worst
- case scenario, i.e. stack unwind procedure going berserk. Relevant
- question is what happens then? Application is abruptly terminated
- without any notification whatsoever. Just like in Win32 case, one
- can argue that system could at least have logged "unwind procedure
- went berserk in x.exe at address n" in event log, but no, no trace
- of failure is left.
-
- Now, when we understand significance of the `UNWIND_INFO' structure,
- let's discuss what's in it and/or how it's processed. First of all
- it is checked for presence of reference to custom language-specific
- exception handler. If there is one, then it's invoked. Depending on
- the return value, execution flow is resumed (exception is said to be
- "handled"), _or_ rest of `UNWIND_INFO' structure is processed as
- following. Beside optional reference to custom handler, it carries
- information about current callee's stack frame and where non-
- volatile registers are saved. Information is detailed enough to be
- able to reconstruct contents of caller's non-volatile registers upon
- call to current callee. And so caller's context is reconstructed,
- and then unwind procedure is repeated, i.e. another `UNWIND_INFO'
- structure is associated, this time, with caller's instruction
- pointer, which is then checked for presence of reference to
- language-specific handler, etc. The procedure is recursively
- repeated till exception is handled. As last resort system "handles"
- it by generating memory core dump and terminating the application.
-
- As for the moment of this writing NASM unfortunately does not
- facilitate generation of above mentioned detailed information about
- stack frame layout. But as of version 2.03 it implements building
- blocks for generating structures involved in stack unwinding. As
- simplest example, here is how to deploy custom exception handler for
- leaf function:
-
- default rel
- section .text
- extern MessageBoxA
- handler:
- sub rsp,40
- mov rcx,0
- lea rdx,[text]
- lea r8,[caption]
- mov r9,1 ; MB_OKCANCEL
- call MessageBoxA
- sub eax,1 ; incidentally suits as return value
- ; for exception handler
- add rsp,40
- ret
- global main
- main:
- xor rax,rax
- mov rax,QWORD[rax] ; cause exception
- ret
- main_end:
- text: db 'OK to rethrow, CANCEL to generate core dump',0
- caption:db 'SEGV',0
-
- section .pdata rdata align=4
- dd main wrt ..imagebase
- dd main_end wrt ..imagebase
- dd xmain wrt ..imagebase
- section .xdata rdata align=8
- xmain: db 9,0,0,0
- dd handler wrt ..imagebase
- section .drectve info
- db '/defaultlib:user32.lib /defaultlib:msvcrt.lib '
-
- What you see in `.pdata' section is element of the "table comprising
- start and end addresses of function" along with reference to
- associated `UNWIND_INFO' structure. And what you see in `.xdata'
- section is `UNWIND_INFO' structure describing function with no
- frame, but with designated exception handler. References are
- _required_ to be image-relative (which is the real reason for
- implementing `wrt ..imagebase' operator). It should be noted that
- `rdata align=n', as well as `wrt ..imagebase', are optional in these
- two segments' contexts, i.e. can be omitted. Latter means that _all_
- 32-bit references, not only above listed required ones, placed into
- these two segments turn out image-relative. Why is it important to
- understand? Developer is allowed to append handler-specific data to
- `UNWIND_INFO' structure, and if [s]he adds a 32-bit reference, then
- [s]he will have to remember to adjust its value to obtain the real
- pointer.
-
- As already mentioned, in Win64 terms leaf function is one that does
- not call any other function _nor_ modifies any non-volatile
- register, including stack pointer. But it's not uncommon that
- assembler programmer plans to utilize every single register and
- sometimes even have variable stack frame. Is there anything one can
- do with bare building blocks? I.e. besides manually composing fully-
- fledged `UNWIND_INFO' structure, which would surely be considered
- error-prone? Yes, there is. Recall that exception handler is called
- first, before stack layout is analyzed. As it turned out, it's
- perfectly possible to manipulate current callee's context in custom
- handler in manner that permits further stack unwinding. General idea
- is that handler would not actually "handle" the exception, but
- instead restore callee's context, as it was at its entry point and
- thus mimic leaf function. In other words, handler would simply
- undertake part of unwinding procedure. Consider following example:
-
- function:
- mov rax,rsp ; copy rsp to volatile register
- push r15 ; save non-volatile registers
- push rbx
- push rbp
- mov r11,rsp ; prepare variable stack frame
- sub r11,rcx
- and r11,-64
- mov QWORD[r11],rax ; check for exceptions
- mov rsp,r11 ; allocate stack frame
- mov QWORD[rsp],rax ; save original rsp value
- magic_point:
- ...
- mov r11,QWORD[rsp] ; pull original rsp value
- mov rbp,QWORD[r11-24]
- mov rbx,QWORD[r11-16]
- mov r15,QWORD[r11-8]
- mov rsp,r11 ; destroy frame
- ret
-
- The keyword is that up to `magic_point' original `rsp' value remains
- in chosen volatile register and no non-volatile register, except for
- `rsp', is modified. While past `magic_point' `rsp' remains constant
- till the very end of the `function'. In this case custom language-
- specific exception handler would look like this:
-
- EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame,
- CONTEXT *context,DISPATCHER_CONTEXT *disp)
- { ULONG64 *rsp;
- if (context->Rip<(ULONG64)magic_point)
- rsp = (ULONG64 *)context->Rax;
- else
- { rsp = ((ULONG64 **)context->Rsp)[0];
- context->Rbp = rsp[-3];
- context->Rbx = rsp[-2];
- context->R15 = rsp[-1];
- }
- context->Rsp = (ULONG64)rsp;
-
- memcpy (disp->ContextRecord,context,sizeof(CONTEXT));
- RtlVirtualUnwind(UNW_FLAG_NHANDLER,disp->ImageBase,
- dips->ControlPc,disp->FunctionEntry,disp->ContextRecord,
- &disp->HandlerData,&disp->EstablisherFrame,NULL);
- return ExceptionContinueSearch;
- }
-
- As custom handler mimics leaf function, corresponding `UNWIND_INFO'
- structure does not have to contain any information about stack frame
- and its layout.
-
- 7.7 `coff': Common Object File Format
-
- The `coff' output type produces `COFF' object files suitable for
- linking with the DJGPP linker.
-
- `coff' provides a default output file-name extension of `.o'.
-
- The `coff' format supports the same extensions to the `SECTION'
- directive as `win32' does, except that the `align' qualifier and the
- `info' section type are not supported.
-
- 7.8 `macho32' and `macho64': Mach Object File Format
-
- The `macho32' and `macho64' output formts produces `Mach-O' object
- files suitable for linking with the MacOS X linker. `macho' is a
- synonym for `macho32'.
-
- `macho' provides a default output file-name extension of `.o'.
-
- 7.9 `elf32' and `elf64': Executable and Linkable Format Object Files
-
- The `elf32' and `elf64' output formats generate `ELF32 and ELF64'
- (Executable and Linkable Format) object files, as used by Linux as
- well as Unix System V, including Solaris x86, UnixWare and SCO Unix.
- `elf' provides a default output file-name extension of `.o'. `elf'
- is a synonym for `elf32'.
-
- 7.9.1 ELF specific directive `osabi'
-
- The ELF header specifies the application binary interface for the
- target operating system (OSABI). This field can be set by using the
- `osabi' directive with the numeric value (0-255) of the target
- system. If this directive is not used, the default value will be
- "UNIX System V ABI" (0) which will work on most systems which
- support ELF.
-
- 7.9.2 `elf' Extensions to the `SECTION' Directive
-
- Like the `obj' format, `elf' allows you to specify additional
- information on the `SECTION' directive line, to control the type and
- properties of sections you declare. Section types and properties are
- generated automatically by NASM for the standard section names, but
- may still be overridden by these qualifiers.
-
- The available qualifiers are:
-
- (*) `alloc' defines the section to be one which is loaded into
- memory when the program is run. `noalloc' defines it to be one
- which is not, such as an informational or comment section.
-
- (*) `exec' defines the section to be one which should have execute
- permission when the program is run. `noexec' defines it as one
- which should not.
-
- (*) `write' defines the section to be one which should be writable
- when the program is run. `nowrite' defines it as one which
- should not.
-
- (*) `progbits' defines the section to be one with explicit contents
- stored in the object file: an ordinary code or data section, for
- example, `nobits' defines the section to be one with no explicit
- contents given, such as a BSS section.
-
- (*) `align=', used with a trailing number as in `obj', gives the
- alignment requirements of the section.
-
- (*) `tls' defines the section to be one which contains thread local
- variables.
-
- The defaults assumed by NASM if you do not specify the above
- qualifiers are:
-
-
- section .text progbits alloc exec nowrite align=16
- section .rodata progbits alloc noexec nowrite align=4
- section .lrodata progbits alloc noexec nowrite align=4
- section .data progbits alloc noexec write align=4
- section .ldata progbits alloc noexec write align=4
- section .bss nobits alloc noexec write align=4
- section .lbss nobits alloc noexec write align=4
- section .tdata progbits alloc noexec write align=4 tls
- section .tbss nobits alloc noexec write align=4 tls
- section .comment progbits noalloc noexec nowrite align=1
- section other progbits alloc noexec nowrite align=1
-
- (Any section name other than those in the above table is treated by
- default like `other' in the above table. Please note that section
- names are case sensitive.)
-
- 7.9.3 Position-Independent Code: `elf' Special Symbols and `WRT'
-
- The `ELF' specification contains enough features to allow position-
- independent code (PIC) to be written, which makes ELF shared
- libraries very flexible. However, it also means NASM has to be able
- to generate a variety of ELF specific relocation types in ELF object
- files, if it is to be an assembler which can write PIC.
-
- Since `ELF' does not support segment-base references, the `WRT'
- operator is not used for its normal purpose; therefore NASM's `elf'
- output format makes use of `WRT' for a different purpose, namely the
- PIC-specific relocation types.
-
- `elf' defines five special symbols which you can use as the right-
- hand side of the `WRT' operator to obtain PIC relocation types. They
- are `..gotpc', `..gotoff', `..got', `..plt' and `..sym'. Their
- functions are summarized here:
-
- (*) Referring to the symbol marking the global offset table base
- using `wrt ..gotpc' will end up giving the distance from the
- beginning of the current section to the global offset table.
- (`_GLOBAL_OFFSET_TABLE_' is the standard symbol name used to
- refer to the GOT.) So you would then need to add `$$' to the
- result to get the real address of the GOT.
-
- (*) Referring to a location in one of your own sections using
- `wrt ..gotoff' will give the distance from the beginning of the
- GOT to the specified location, so that adding on the address of
- the GOT would give the real address of the location you wanted.
-
- (*) Referring to an external or global symbol using `wrt ..got'
- causes the linker to build an entry _in_ the GOT containing the
- address of the symbol, and the reference gives the distance from
- the beginning of the GOT to the entry; so you can add on the
- address of the GOT, load from the resulting address, and end up
- with the address of the symbol.
-
- (*) Referring to a procedure name using `wrt ..plt' causes the
- linker to build a procedure linkage table entry for the symbol,
- and the reference gives the address of the PLT entry. You can
- only use this in contexts which would generate a PC-relative
- relocation normally (i.e. as the destination for `CALL' or
- `JMP'), since ELF contains no relocation type to refer to PLT
- entries absolutely.
-
- (*) Referring to a symbol name using `wrt ..sym' causes NASM to
- write an ordinary relocation, but instead of making the
- relocation relative to the start of the section and then adding
- on the offset to the symbol, it will write a relocation record
- aimed directly at the symbol in question. The distinction is a
- necessary one due to a peculiarity of the dynamic linker.
-
- A fuller explanation of how to use these relocation types to write
- shared libraries entirely in NASM is given in section 9.2.
-
- 7.9.4 Thread Local Storage: `elf' Special Symbols and `WRT'
-
- (*) In ELF32 mode, referring to an external or global symbol using
- `wrt ..tlsie' causes the linker to build an entry _in_ the GOT
- containing the offset of the symbol within the TLS block, so you
- can access the value of the symbol with code such as:
-
- mov eax,[tid wrt ..tlsie]
- mov [gs:eax],ebx
-
- (*) In ELF64 mode, referring to an external or global symbol using
- `wrt ..gottpoff' causes the linker to build an entry _in_ the
- GOT containing the offset of the symbol within the TLS block, so
- you can access the value of the symbol with code such as:
-
- mov rax,[rel tid wrt ..gottpoff]
- mov rcx,[fs:rax]
-
- 7.9.5 `elf' Extensions to the `GLOBAL' Directive
-
- `ELF' object files can contain more information about a global
- symbol than just its address: they can contain the size of the
- symbol and its type as well. These are not merely debugger
- conveniences, but are actually necessary when the program being
- written is a shared library. NASM therefore supports some extensions
- to the `GLOBAL' directive, allowing you to specify these features.
-
- You can specify whether a global variable is a function or a data
- object by suffixing the name with a colon and the word `function' or
- `data'. (`object' is a synonym for `data'.) For example:
-
- global hashlookup:function, hashtable:data
-
- exports the global symbol `hashlookup' as a function and `hashtable'
- as a data object.
-
- Optionally, you can control the ELF visibility of the symbol. Just
- add one of the visibility keywords: `default', `internal', `hidden',
- or `protected'. The default is `default' of course. For example, to
- make `hashlookup' hidden:
-
- global hashlookup:function hidden
-
- You can also specify the size of the data associated with the
- symbol, as a numeric expression (which may involve labels, and even
- forward references) after the type specifier. Like this:
-
- global hashtable:data (hashtable.end - hashtable)
-
- hashtable:
- db this,that,theother ; some data here
- .end:
-
- This makes NASM automatically calculate the length of the table and
- place that information into the `ELF' symbol table.
-
- Declaring the type and size of global symbols is necessary when
- writing shared library code. For more information, see section
- 9.2.4.
-
- 7.9.6 `elf' Extensions to the `COMMON' Directive
-
- `ELF' also allows you to specify alignment requirements on common
- variables. This is done by putting a number (which must be a power
- of two) after the name and size of the common variable, separated
- (as usual) by a colon. For example, an array of doublewords would
- benefit from 4-byte alignment:
-
- common dwordarray 128:4
-
- This declares the total size of the array to be 128 bytes, and
- requires that it be aligned on a 4-byte boundary.
-
- 7.9.7 16-bit code and ELF
-
- The `ELF32' specification doesn't provide relocations for 8- and 16-
- bit values, but the GNU `ld' linker adds these as an extension. NASM
- can generate GNU-compatible relocations, to allow 16-bit code to be
- linked as ELF using GNU `ld'. If NASM is used with the
- `-w+gnu-elf-extensions' option, a warning is issued when one of
- these relocations is generated.
-
- 7.9.8 Debug formats and ELF
-
- `ELF32' and `ELF64' provide debug information in `STABS' and `DWARF'
- formats. Line number information is generated for all executable
- sections, but please note that only the ".text" section is
- executable by default.
-
- 7.10 `aout': Linux `a.out' Object Files
-
- The `aout' format generates `a.out' object files, in the form used
- by early Linux systems (current Linux systems use ELF, see section
- 7.9.) These differ from other `a.out' object files in that the magic
- number in the first four bytes of the file is different; also, some
- implementations of `a.out', for example NetBSD's, support position-
- independent code, which Linux's implementation does not.
-
- `a.out' provides a default output file-name extension of `.o'.
-
- `a.out' is a very simple object format. It supports no special
- directives, no special symbols, no use of `SEG' or `WRT', and no
- extensions to any standard directives. It supports only the three
- standard section names `.text', `.data' and `.bss'.
-
- 7.11 `aoutb': NetBSD/FreeBSD/OpenBSD `a.out' Object Files
-
- The `aoutb' format generates `a.out' object files, in the form used
- by the various free `BSD Unix' clones, `NetBSD', `FreeBSD' and
- `OpenBSD'. For simple object files, this object format is exactly
- the same as `aout' except for the magic number in the first four
- bytes of the file. However, the `aoutb' format supports
- position-independent code in the same way as the `elf' format, so
- you can use it to write `BSD' shared libraries.
-
- `aoutb' provides a default output file-name extension of `.o'.
-
- `aoutb' supports no special directives, no special symbols, and only
- the three standard section names `.text', `.data' and `.bss'.
- However, it also supports the same use of `WRT' as `elf' does, to
- provide position-independent code relocation types. See section
- 7.9.3 for full documentation of this feature.
-
- `aoutb' also supports the same extensions to the `GLOBAL' directive
- as `elf' does: see section 7.9.5 for documentation of this.
-
- 7.12 `as86': Minix/Linux `as86' Object Files
-
- The Minix/Linux 16-bit assembler `as86' has its own non-standard
- object file format. Although its companion linker `ld86' produces
- something close to ordinary `a.out' binaries as output, the object
- file format used to communicate between `as86' and `ld86' is not
- itself `a.out'.
-
- NASM supports this format, just in case it is useful, as `as86'.
- `as86' provides a default output file-name extension of `.o'.
-
- `as86' is a very simple object format (from the NASM user's point of
- view). It supports no special directives, no use of `SEG' or `WRT',
- and no extensions to any standard directives. It supports only the
- three standard section names `.text', `.data' and `.bss'. The only
- special symbol supported is `..start'.
-
- 7.13 `rdf': Relocatable Dynamic Object File Format
-
- The `rdf' output format produces `RDOFF' object files. `RDOFF'
- (Relocatable Dynamic Object File Format) is a home-grown object-file
- format, designed alongside NASM itself and reflecting in its file
- format the internal structure of the assembler.
-
- `RDOFF' is not used by any well-known operating systems. Those
- writing their own systems, however, may well wish to use `RDOFF' as
- their object format, on the grounds that it is designed primarily
- for simplicity and contains very little file-header bureaucracy.
-
- The Unix NASM archive, and the DOS archive which includes sources,
- both contain an `rdoff' subdirectory holding a set of RDOFF
- utilities: an RDF linker, an `RDF' static-library manager, an RDF
- file dump utility, and a program which will load and execute an RDF
- executable under Linux.
-
- `rdf' supports only the standard section names `.text', `.data' and
- `.bss'.
-
-7.13.1 Requiring a Library: The `LIBRARY' Directive
-
- `RDOFF' contains a mechanism for an object file to demand a given
- library to be linked to the module, either at load time or run time.
- This is done by the `LIBRARY' directive, which takes one argument
- which is the name of the module:
-
- library mylib.rdl
-
-7.13.2 Specifying a Module Name: The `MODULE' Directive
-
- Special `RDOFF' header record is used to store the name of the
- module. It can be used, for example, by run-time loader to perform
- dynamic linking. `MODULE' directive takes one argument which is the
- name of current module:
-
- module mymodname
-
- Note that when you statically link modules and tell linker to strip
- the symbols from output file, all module names will be stripped too.
- To avoid it, you should start module names with `$', like:
-
- module $kernel.core
-
-7.13.3 `rdf' Extensions to the `GLOBAL' Directive
-
- `RDOFF' global symbols can contain additional information needed by
- the static linker. You can mark a global symbol as exported, thus
- telling the linker do not strip it from target executable or library
- file. Like in `ELF', you can also specify whether an exported symbol
- is a procedure (function) or data object.
-
- Suffixing the name with a colon and the word `export' you make the
- symbol exported:
-
- global sys_open:export
-
- To specify that exported symbol is a procedure (function), you add
- the word `proc' or `function' after declaration:
-
- global sys_open:export proc
-
- Similarly, to specify exported data object, add the word `data' or
- `object' to the directive:
-
- global kernel_ticks:export data
-
-7.13.4 `rdf' Extensions to the `EXTERN' Directive
-
- By default the `EXTERN' directive in `RDOFF' declares a "pure
- external" symbol (i.e. the static linker will complain if such a
- symbol is not resolved). To declare an "imported" symbol, which must
- be resolved later during a dynamic linking phase, `RDOFF' offers an
- additional `import' modifier. As in `GLOBAL', you can also specify
- whether an imported symbol is a procedure (function) or data object.
- For example:
-
- library $libc
- extern _open:import
- extern _printf:import proc
- extern _errno:import data
-
- Here the directive `LIBRARY' is also included, which gives the
- dynamic linker a hint as to where to find requested symbols.
-
- 7.14 `dbg': Debugging Format
-
- The `dbg' output format is not built into NASM in the default
- configuration. If you are building your own NASM executable from the
- sources, you can define `OF_DBG' in `output/outform.h' or on the
- compiler command line, and obtain the `dbg' output format.
-
- The `dbg' format does not output an object file as such; instead, it
- outputs a text file which contains a complete list of all the
- transactions between the main body of NASM and the output-format
- back end module. It is primarily intended to aid people who want to
- write their own output drivers, so that they can get a clearer idea
- of the various requests the main program makes of the output driver,
- and in what order they happen.
-
- For simple files, one can easily use the `dbg' format like this:
-
- nasm -f dbg filename.asm
-
- which will generate a diagnostic file called `filename.dbg'.
- However, this will not work well on files which were designed for a
- different object format, because each object format defines its own
- macros (usually user-level forms of directives), and those macros
- will not be defined in the `dbg' format. Therefore it can be useful
- to run NASM twice, in order to do the preprocessing with the native
- object format selected:
-
- nasm -e -f rdf -o rdfprog.i rdfprog.asm
- nasm -a -f dbg rdfprog.i
-
- This preprocesses `rdfprog.asm' into `rdfprog.i', keeping the `rdf'
- object format selected in order to make sure RDF special directives
- are converted into primitive form correctly. Then the preprocessed
- source is fed through the `dbg' format to generate the final
- diagnostic output.
-
- This workaround will still typically not work for programs intended
- for `obj' format, because the `obj' `SEGMENT' and `GROUP' directives
- have side effects of defining the segment and group names as
- symbols; `dbg' will not do this, so the program will not assemble.
- You will have to work around that by defining the symbols yourself
- (using `EXTERN', for example) if you really need to get a `dbg'
- trace of an `obj'-specific source file.
-
- `dbg' accepts any section name and any directives at all, and logs
- them all to its output file.
-
-Chapter 8: Writing 16-bit Code (DOS, Windows 3/3.1)
----------------------------------------------------
-
- This chapter attempts to cover some of the common issues encountered
- when writing 16-bit code to run under `MS-DOS' or `Windows 3.x'. It
- covers how to link programs to produce `.EXE' or `.COM' files, how
- to write `.SYS' device drivers, and how to interface assembly
- language code with 16-bit C compilers and with Borland Pascal.
-
- 8.1 Producing `.EXE' Files
-
- Any large program written under DOS needs to be built as a `.EXE'
- file: only `.EXE' files have the necessary internal structure
- required to span more than one 64K segment. Windows programs, also,
- have to be built as `.EXE' files, since Windows does not support the
- `.COM' format.
-
- In general, you generate `.EXE' files by using the `obj' output
- format to produce one or more `.OBJ' files, and then linking them
- together using a linker. However, NASM also supports the direct
- generation of simple DOS `.EXE' files using the `bin' output format
- (by using `DB' and `DW' to construct the `.EXE' file header), and a
- macro package is supplied to do this. Thanks to Yann Guidon for
- contributing the code for this.
-
- NASM may also support `.EXE' natively as another output format in
- future releases.
-
- 8.1.1 Using the `obj' Format To Generate `.EXE' Files
-
- This section describes the usual method of generating `.EXE' files
- by linking `.OBJ' files together.
-
- Most 16-bit programming language packages come with a suitable
- linker; if you have none of these, there is a free linker called
- VAL, available in `LZH' archive format from `x2ftp.oulu.fi'. An LZH
- archiver can be found at `ftp.simtel.net'. There is another `free'
- linker (though this one doesn't come with sources) called FREELINK,
- available from `www.pcorner.com'. A third, `djlink', written by DJ
- Delorie, is available at `www.delorie.com'. A fourth linker,
- `ALINK', written by Anthony A.J. Williams, is available at
- `alink.sourceforge.net'.
-
- When linking several `.OBJ' files into a `.EXE' file, you should
- ensure that exactly one of them has a start point defined (using the
- `..start' special symbol defined by the `obj' format: see section
- 7.4.6). If no module defines a start point, the linker will not know
- what value to give the entry-point field in the output file header;
- if more than one defines a start point, the linker will not know
- _which_ value to use.
-
- An example of a NASM source file which can be assembled to a `.OBJ'
- file and linked on its own to a `.EXE' is given here. It
- demonstrates the basic principles of defining a stack, initialising
- the segment registers, and declaring a start point. This file is
- also provided in the `test' subdirectory of the NASM archives, under
- the name `objexe.asm'.
-
- segment code
-
- ..start:
- mov ax,data
- mov ds,ax
- mov ax,stack
- mov ss,ax
- mov sp,stacktop
-
- This initial piece of code sets up `DS' to point to the data
- segment, and initializes `SS' and `SP' to point to the top of the
- provided stack. Notice that interrupts are implicitly disabled for
- one instruction after a move into `SS', precisely for this
- situation, so that there's no chance of an interrupt occurring
- between the loads of `SS' and `SP' and not having a stack to execute
- on.
-
- Note also that the special symbol `..start' is defined at the
- beginning of this code, which means that will be the entry point
- into the resulting executable file.
-
- mov dx,hello
- mov ah,9
- int 0x21
-
- The above is the main program: load `DS:DX' with a pointer to the
- greeting message (`hello' is implicitly relative to the segment
- `data', which was loaded into `DS' in the setup code, so the full
- pointer is valid), and call the DOS print-string function.
-
- mov ax,0x4c00
- int 0x21
-
- This terminates the program using another DOS system call.
-
- segment data
-
- hello: db 'hello, world', 13, 10, '$'
-
- The data segment contains the string we want to display.
-
- segment stack stack
- resb 64
- stacktop:
-
- The above code declares a stack segment containing 64 bytes of
- uninitialized stack space, and points `stacktop' at the top of it.
- The directive `segment stack stack' defines a segment _called_
- `stack', and also of _type_ `STACK'. The latter is not necessary to
- the correct running of the program, but linkers are likely to issue
- warnings or errors if your program has no segment of type `STACK'.
-
- The above file, when assembled into a `.OBJ' file, will link on its
- own to a valid `.EXE' file, which when run will print `hello, world'
- and then exit.
-
- 8.1.2 Using the `bin' Format To Generate `.EXE' Files
-
- The `.EXE' file format is simple enough that it's possible to build
- a `.EXE' file by writing a pure-binary program and sticking a 32-
- byte header on the front. This header is simple enough that it can
- be generated using `DB' and `DW' commands by NASM itself, so that
- you can use the `bin' output format to directly generate `.EXE'
- files.
-
- Included in the NASM archives, in the `misc' subdirectory, is a file
- `exebin.mac' of macros. It defines three macros: `EXE_begin',
- `EXE_stack' and `EXE_end'.
-
- To produce a `.EXE' file using this method, you should start by
- using `%include' to load the `exebin.mac' macro package into your
- source file. You should then issue the `EXE_begin' macro call (which
- takes no arguments) to generate the file header data. Then write
- code as normal for the `bin' format - you can use all three standard
- sections `.text', `.data' and `.bss'. At the end of the file you
- should call the `EXE_end' macro (again, no arguments), which defines
- some symbols to mark section sizes, and these symbols are referred
- to in the header code generated by `EXE_begin'.
-
- In this model, the code you end up writing starts at `0x100', just
- like a `.COM' file - in fact, if you strip off the 32-byte header
- from the resulting `.EXE' file, you will have a valid `.COM'
- program. All the segment bases are the same, so you are limited to a
- 64K program, again just like a `.COM' file. Note that an `ORG'
- directive is issued by the `EXE_begin' macro, so you should not
- explicitly issue one of your own.
-
- You can't directly refer to your segment base value, unfortunately,
- since this would require a relocation in the header, and things
- would get a lot more complicated. So you should get your segment
- base by copying it out of `CS' instead.
-
- On entry to your `.EXE' file, `SS:SP' are already set up to point to
- the top of a 2Kb stack. You can adjust the default stack size of 2Kb
- by calling the `EXE_stack' macro. For example, to change the stack
- size of your program to 64 bytes, you would call `EXE_stack 64'.
-
- A sample program which generates a `.EXE' file in this way is given
- in the `test' subdirectory of the NASM archive, as `binexe.asm'.
-
- 8.2 Producing `.COM' Files
-
- While large DOS programs must be written as `.EXE' files, small ones
- are often better written as `.COM' files. `.COM' files are pure
- binary, and therefore most easily produced using the `bin' output
- format.
-
- 8.2.1 Using the `bin' Format To Generate `.COM' Files
-
- `.COM' files expect to be loaded at offset `100h' into their segment
- (though the segment may change). Execution then begins at `100h',
- i.e. right at the start of the program. So to write a `.COM'
- program, you would create a source file looking like
-
- org 100h
-
- section .text
-
- start:
- ; put your code here
-
- section .data
-
- ; put data items here
-
- section .bss
-
- ; put uninitialized data here
-
- The `bin' format puts the `.text' section first in the file, so you
- can declare data or BSS items before beginning to write code if you
- want to and the code will still end up at the front of the file
- where it belongs.
-
- The BSS (uninitialized data) section does not take up space in the
- `.COM' file itself: instead, addresses of BSS items are resolved to
- point at space beyond the end of the file, on the grounds that this
- will be free memory when the program is run. Therefore you should
- not rely on your BSS being initialized to all zeros when you run.
-
- To assemble the above program, you should use a command line like
-
- nasm myprog.asm -fbin -o myprog.com
-
- The `bin' format would produce a file called `myprog' if no explicit
- output file name were specified, so you have to override it and give
- the desired file name.
-
- 8.2.2 Using the `obj' Format To Generate `.COM' Files
-
- If you are writing a `.COM' program as more than one module, you may
- wish to assemble several `.OBJ' files and link them together into a
- `.COM' program. You can do this, provided you have a linker capable
- of outputting `.COM' files directly (TLINK does this), or
- alternatively a converter program such as `EXE2BIN' to transform the
- `.EXE' file output from the linker into a `.COM' file.
-
- If you do this, you need to take care of several things:
-
- (*) The first object file containing code should start its code
- segment with a line like `RESB 100h'. This is to ensure that the
- code begins at offset `100h' relative to the beginning of the
- code segment, so that the linker or converter program does not
- have to adjust address references within the file when
- generating the `.COM' file. Other assemblers use an `ORG'
- directive for this purpose, but `ORG' in NASM is a format-
- specific directive to the `bin' output format, and does not mean
- the same thing as it does in MASM-compatible assemblers.
-
- (*) You don't need to define a stack segment.
-
- (*) All your segments should be in the same group, so that every
- time your code or data references a symbol offset, all offsets
- are relative to the same segment base. This is because, when a
- `.COM' file is loaded, all the segment registers contain the
- same value.
-
- 8.3 Producing `.SYS' Files
-
- MS-DOS device drivers - `.SYS' files - are pure binary files,
- similar to `.COM' files, except that they start at origin zero
- rather than `100h'. Therefore, if you are writing a device driver
- using the `bin' format, you do not need the `ORG' directive, since
- the default origin for `bin' is zero. Similarly, if you are using
- `obj', you do not need the `RESB 100h' at the start of your code
- segment.
-
- `.SYS' files start with a header structure, containing pointers to
- the various routines inside the driver which do the work. This
- structure should be defined at the start of the code segment, even
- though it is not actually code.
-
- For more information on the format of `.SYS' files, and the data
- which has to go in the header structure, a list of books is given in
- the Frequently Asked Questions list for the newsgroup
- `comp.os.msdos.programmer'.
-
- 8.4 Interfacing to 16-bit C Programs
-
- This section covers the basics of writing assembly routines that
- call, or are called from, C programs. To do this, you would
- typically write an assembly module as a `.OBJ' file, and link it
- with your C modules to produce a mixed-language program.
-
- 8.4.1 External Symbol Names
-
- C compilers have the convention that the names of all global symbols
- (functions or data) they define are formed by prefixing an
- underscore to the name as it appears in the C program. So, for
- example, the function a C programmer thinks of as `printf' appears
- to an assembly language programmer as `_printf'. This means that in
- your assembly programs, you can define symbols without a leading
- underscore, and not have to worry about name clashes with C symbols.
-
- If you find the underscores inconvenient, you can define macros to
- replace the `GLOBAL' and `EXTERN' directives as follows:
-
- %macro cglobal 1
-
- global _%1
- %define %1 _%1
-
- %endmacro
-
- %macro cextern 1
-
- extern _%1
- %define %1 _%1
-
- %endmacro
-
- (These forms of the macros only take one argument at a time; a
- `%rep' construct could solve this.)
-
- If you then declare an external like this:
-
- cextern printf
-
- then the macro will expand it as
-
- extern _printf
- %define printf _printf
-
- Thereafter, you can reference `printf' as if it was a symbol, and
- the preprocessor will put the leading underscore on where necessary.
-
- The `cglobal' macro works similarly. You must use `cglobal' before
- defining the symbol in question, but you would have had to do that
- anyway if you used `GLOBAL'.
-
- Also see section 2.1.27.
-
- 8.4.2 Memory Models
-
- NASM contains no mechanism to support the various C memory models
- directly; you have to keep track yourself of which one you are
- writing for. This means you have to keep track of the following
- things:
-
- (*) In models using a single code segment (tiny, small and compact),
- functions are near. This means that function pointers, when
- stored in data segments or pushed on the stack as function
- arguments, are 16 bits long and contain only an offset field
- (the `CS' register never changes its value, and always gives the
- segment part of the full function address), and that functions
- are called using ordinary near `CALL' instructions and return
- using `RETN' (which, in NASM, is synonymous with `RET' anyway).
- This means both that you should write your own routines to
- return with `RETN', and that you should call external C routines
- with near `CALL' instructions.
-
- (*) In models using more than one code segment (medium, large and
- huge), functions are far. This means that function pointers are
- 32 bits long (consisting of a 16-bit offset followed by a 16-bit
- segment), and that functions are called using `CALL FAR' (or
- `CALL seg:offset') and return using `RETF'. Again, you should
- therefore write your own routines to return with `RETF' and use
- `CALL FAR' to call external routines.
-
- (*) In models using a single data segment (tiny, small and medium),
- data pointers are 16 bits long, containing only an offset field
- (the `DS' register doesn't change its value, and always gives
- the segment part of the full data item address).
-
- (*) In models using more than one data segment (compact, large and
- huge), data pointers are 32 bits long, consisting of a 16-bit
- offset followed by a 16-bit segment. You should still be careful
- not to modify `DS' in your routines without restoring it
- afterwards, but `ES' is free for you to use to access the
- contents of 32-bit data pointers you are passed.
-
- (*) The huge memory model allows single data items to exceed 64K in
- size. In all other memory models, you can access the whole of a
- data item just by doing arithmetic on the offset field of the
- pointer you are given, whether a segment field is present or
- not; in huge model, you have to be more careful of your pointer
- arithmetic.
-
- (*) In most memory models, there is a _default_ data segment, whose
- segment address is kept in `DS' throughout the program. This
- data segment is typically the same segment as the stack, kept in
- `SS', so that functions' local variables (which are stored on
- the stack) and global data items can both be accessed easily
- without changing `DS'. Particularly large data items are
- typically stored in other segments. However, some memory models
- (though not the standard ones, usually) allow the assumption
- that `SS' and `DS' hold the same value to be removed. Be careful
- about functions' local variables in this latter case.
-
- In models with a single code segment, the segment is called `_TEXT',
- so your code segment must also go by this name in order to be linked
- into the same place as the main code segment. In models with a
- single data segment, or with a default data segment, it is called
- `_DATA'.
-
- 8.4.3 Function Definitions and Function Calls
-
- The C calling convention in 16-bit programs is as follows. In the
- following description, the words _caller_ and _callee_ are used to
- denote the function doing the calling and the function which gets
- called.
-
- (*) The caller pushes the function's parameters on the stack, one
- after another, in reverse order (right to left, so that the
- first argument specified to the function is pushed last).
-
- (*) The caller then executes a `CALL' instruction to pass control to
- the callee. This `CALL' is either near or far depending on the
- memory model.
-
- (*) The callee receives control, and typically (although this is not
- actually necessary, in functions which do not need to access
- their parameters) starts by saving the value of `SP' in `BP' so
- as to be able to use `BP' as a base pointer to find its
- parameters on the stack. However, the caller was probably doing
- this too, so part of the calling convention states that `BP'
- must be preserved by any C function. Hence the callee, if it is
- going to set up `BP' as a _frame pointer_, must push the
- previous value first.
-
- (*) The callee may then access its parameters relative to `BP'. The
- word at `[BP]' holds the previous value of `BP' as it was
- pushed; the next word, at `[BP+2]', holds the offset part of the
- return address, pushed implicitly by `CALL'. In a small-model
- (near) function, the parameters start after that, at `[BP+4]';
- in a large-model (far) function, the segment part of the return
- address lives at `[BP+4]', and the parameters begin at `[BP+6]'.
- The leftmost parameter of the function, since it was pushed
- last, is accessible at this offset from `BP'; the others follow,
- at successively greater offsets. Thus, in a function such as
- `printf' which takes a variable number of parameters, the
- pushing of the parameters in reverse order means that the
- function knows where to find its first parameter, which tells it
- the number and type of the remaining ones.
-
- (*) The callee may also wish to decrease `SP' further, so as to
- allocate space on the stack for local variables, which will then
- be accessible at negative offsets from `BP'.
-
- (*) The callee, if it wishes to return a value to the caller, should
- leave the value in `AL', `AX' or `DX:AX' depending on the size
- of the value. Floating-point results are sometimes (depending on
- the compiler) returned in `ST0'.
-
- (*) Once the callee has finished processing, it restores `SP' from
- `BP' if it had allocated local stack space, then pops the
- previous value of `BP', and returns via `RETN' or `RETF'
- depending on memory model.
-
- (*) When the caller regains control from the callee, the function
- parameters are still on the stack, so it typically adds an
- immediate constant to `SP' to remove them (instead of executing
- a number of slow `POP' instructions). Thus, if a function is
- accidentally called with the wrong number of parameters due to a
- prototype mismatch, the stack will still be returned to a
- sensible state since the caller, which _knows_ how many
- parameters it pushed, does the removing.
-
- It is instructive to compare this calling convention with that for
- Pascal programs (described in section 8.5.1). Pascal has a simpler
- convention, since no functions have variable numbers of parameters.
- Therefore the callee knows how many parameters it should have been
- passed, and is able to deallocate them from the stack itself by
- passing an immediate argument to the `RET' or `RETF' instruction, so
- the caller does not have to do it. Also, the parameters are pushed
- in left-to-right order, not right-to-left, which means that a
- compiler can give better guarantees about sequence points without
- performance suffering.
-
- Thus, you would define a function in C style in the following way.
- The following example is for small model:
-
- global _myfunc
-
- _myfunc:
- push bp
- mov bp,sp
- sub sp,0x40 ; 64 bytes of local stack space
- mov bx,[bp+4] ; first parameter to function
-
- ; some more code
-
- mov sp,bp ; undo "sub sp,0x40" above
- pop bp
- ret
-
- For a large-model function, you would replace `RET' by `RETF', and
- look for the first parameter at `[BP+6]' instead of `[BP+4]'. Of
- course, if one of the parameters is a pointer, then the offsets of
- _subsequent_ parameters will change depending on the memory model as
- well: far pointers take up four bytes on the stack when passed as a
- parameter, whereas near pointers take up two.
-
- At the other end of the process, to call a C function from your
- assembly code, you would do something like this:
-
- extern _printf
-
- ; and then, further down...
-
- push word [myint] ; one of my integer variables
- push word mystring ; pointer into my data segment
- call _printf
- add sp,byte 4 ; `byte' saves space
-
- ; then those data items...
-
- segment _DATA
-
- myint dw 1234
- mystring db 'This number -> %d <- should be 1234',10,0
-
- This piece of code is the small-model assembly equivalent of the C
- code
-
- int myint = 1234;
- printf("This number -> %d <- should be 1234\n", myint);
-
- In large model, the function-call code might look more like this. In
- this example, it is assumed that `DS' already holds the segment base
- of the segment `_DATA'. If not, you would have to initialize it
- first.
-
- push word [myint]
- push word seg mystring ; Now push the segment, and...
- push word mystring ; ... offset of "mystring"
- call far _printf
- add sp,byte 6
-
- The integer value still takes up one word on the stack, since large
- model does not affect the size of the `int' data type. The first
- argument (pushed last) to `printf', however, is a data pointer, and
- therefore has to contain a segment and offset part. The segment
- should be stored second in memory, and therefore must be pushed
- first. (Of course, `PUSH DS' would have been a shorter instruction
- than `PUSH WORD SEG mystring', if `DS' was set up as the above
- example assumed.) Then the actual call becomes a far call, since
- functions expect far calls in large model; and `SP' has to be
- increased by 6 rather than 4 afterwards to make up for the extra
- word of parameters.
-
- 8.4.4 Accessing Data Items
-
- To get at the contents of C variables, or to declare variables which
- C can access, you need only declare the names as `GLOBAL' or
- `EXTERN'. (Again, the names require leading underscores, as stated
- in section 8.4.1.) Thus, a C variable declared as `int i' can be
- accessed from assembler as
-
- extern _i
-
- mov ax,[_i]
-
- And to declare your own integer variable which C programs can access
- as `extern int j', you do this (making sure you are assembling in
- the `_DATA' segment, if necessary):
-
- global _j
-
- _j dw 0
-
- To access a C array, you need to know the size of the components of
- the array. For example, `int' variables are two bytes long, so if a
- C program declares an array as `int a[10]', you can access `a[3]' by
- coding `mov ax,[_a+6]'. (The byte offset 6 is obtained by
- multiplying the desired array index, 3, by the size of the array
- element, 2.) The sizes of the C base types in 16-bit compilers are:
- 1 for `char', 2 for `short' and `int', 4 for `long' and `float', and
- 8 for `double'.
-
- To access a C data structure, you need to know the offset from the
- base of the structure to the field you are interested in. You can
- either do this by converting the C structure definition into a NASM
- structure definition (using `STRUC'), or by calculating the one
- offset and using just that.
-
- To do either of these, you should read your C compiler's manual to
- find out how it organizes data structures. NASM gives no special
- alignment to structure members in its own `STRUC' macro, so you have
- to specify alignment yourself if the C compiler generates it.
- Typically, you might find that a structure like
-
- struct {
- char c;
- int i;
- } foo;
-
- might be four bytes long rather than three, since the `int' field
- would be aligned to a two-byte boundary. However, this sort of
- feature tends to be a configurable option in the C compiler, either
- using command-line options or `#pragma' lines, so you have to find
- out how your own compiler does it.
-
- 8.4.5 `c16.mac': Helper Macros for the 16-bit C Interface
-
- Included in the NASM archives, in the `misc' directory, is a file
- `c16.mac' of macros. It defines three macros: `proc', `arg' and
- `endproc'. These are intended to be used for C-style procedure
- definitions, and they automate a lot of the work involved in keeping
- track of the calling convention.
-
- (An alternative, TASM compatible form of `arg' is also now built
- into NASM's preprocessor. See section 4.8 for details.)
-
- An example of an assembly function using the macro set is given
- here:
-
- proc _nearproc
-
- %$i arg
- %$j arg
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- add ax,[bx]
-
- endproc
-
- This defines `_nearproc' to be a procedure taking two arguments, the
- first (`i') an integer and the second (`j') a pointer to an integer.
- It returns `i + *j'.
-
- Note that the `arg' macro has an `EQU' as the first line of its
- expansion, and since the label before the macro call gets prepended
- to the first line of the expanded macro, the `EQU' works, defining
- `%$i' to be an offset from `BP'. A context-local variable is used,
- local to the context pushed by the `proc' macro and popped by the
- `endproc' macro, so that the same argument name can be used in later
- procedures. Of course, you don't _have_ to do that.
-
- The macro set produces code for near functions (tiny, small and
- compact-model code) by default. You can have it generate far
- functions (medium, large and huge-model code) by means of coding
- `%define FARCODE'. This changes the kind of return instruction
- generated by `endproc', and also changes the starting point for the
- argument offsets. The macro set contains no intrinsic dependency on
- whether data pointers are far or not.
-
- `arg' can take an optional parameter, giving the size of the
- argument. If no size is given, 2 is assumed, since it is likely that
- many function parameters will be of type `int'.
-
- The large-model equivalent of the above function would look like
- this:
-
- %define FARCODE
-
- proc _farproc
-
- %$i arg
- %$j arg 4
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- mov es,[bp + %$j + 2]
- add ax,[bx]
-
- endproc
-
- This makes use of the argument to the `arg' macro to define a
- parameter of size 4, because `j' is now a far pointer. When we load
- from `j', we must load a segment and an offset.
-
- 8.5 Interfacing to Borland Pascal Programs
-
- Interfacing to Borland Pascal programs is similar in concept to
- interfacing to 16-bit C programs. The differences are:
-
- (*) The leading underscore required for interfacing to C programs is
- not required for Pascal.
-
- (*) The memory model is always large: functions are far, data
- pointers are far, and no data item can be more than 64K long.
- (Actually, some functions are near, but only those functions
- that are local to a Pascal unit and never called from outside
- it. All assembly functions that Pascal calls, and all Pascal
- functions that assembly routines are able to call, are far.)
- However, all static data declared in a Pascal program goes into
- the default data segment, which is the one whose segment address
- will be in `DS' when control is passed to your assembly code.
- The only things that do not live in the default data segment are
- local variables (they live in the stack segment) and dynamically
- allocated variables. All data _pointers_, however, are far.
-
- (*) The function calling convention is different - described below.
-
- (*) Some data types, such as strings, are stored differently.
-
- (*) There are restrictions on the segment names you are allowed to
- use - Borland Pascal will ignore code or data declared in a
- segment it doesn't like the name of. The restrictions are
- described below.
-
- 8.5.1 The Pascal Calling Convention
-
- The 16-bit Pascal calling convention is as follows. In the following
- description, the words _caller_ and _callee_ are used to denote the
- function doing the calling and the function which gets called.
-
- (*) The caller pushes the function's parameters on the stack, one
- after another, in normal order (left to right, so that the first
- argument specified to the function is pushed first).
-
- (*) The caller then executes a far `CALL' instruction to pass
- control to the callee.
-
- (*) The callee receives control, and typically (although this is not
- actually necessary, in functions which do not need to access
- their parameters) starts by saving the value of `SP' in `BP' so
- as to be able to use `BP' as a base pointer to find its
- parameters on the stack. However, the caller was probably doing
- this too, so part of the calling convention states that `BP'
- must be preserved by any function. Hence the callee, if it is
- going to set up `BP' as a frame pointer, must push the previous
- value first.
-
- (*) The callee may then access its parameters relative to `BP'. The
- word at `[BP]' holds the previous value of `BP' as it was
- pushed. The next word, at `[BP+2]', holds the offset part of the
- return address, and the next one at `[BP+4]' the segment part.
- The parameters begin at `[BP+6]'. The rightmost parameter of the
- function, since it was pushed last, is accessible at this offset
- from `BP'; the others follow, at successively greater offsets.
-
- (*) The callee may also wish to decrease `SP' further, so as to
- allocate space on the stack for local variables, which will then
- be accessible at negative offsets from `BP'.
-
- (*) The callee, if it wishes to return a value to the caller, should
- leave the value in `AL', `AX' or `DX:AX' depending on the size
- of the value. Floating-point results are returned in `ST0'.
- Results of type `Real' (Borland's own custom floating-point data
- type, not handled directly by the FPU) are returned in
- `DX:BX:AX'. To return a result of type `String', the caller
- pushes a pointer to a temporary string before pushing the
- parameters, and the callee places the returned string value at
- that location. The pointer is not a parameter, and should not be
- removed from the stack by the `RETF' instruction.
-
- (*) Once the callee has finished processing, it restores `SP' from
- `BP' if it had allocated local stack space, then pops the
- previous value of `BP', and returns via `RETF'. It uses the form
- of `RETF' with an immediate parameter, giving the number of
- bytes taken up by the parameters on the stack. This causes the
- parameters to be removed from the stack as a side effect of the
- return instruction.
-
- (*) When the caller regains control from the callee, the function
- parameters have already been removed from the stack, so it needs
- to do nothing further.
-
- Thus, you would define a function in Pascal style, taking two
- `Integer'-type parameters, in the following way:
-
- global myfunc
-
- myfunc: push bp
- mov bp,sp
- sub sp,0x40 ; 64 bytes of local stack space
- mov bx,[bp+8] ; first parameter to function
- mov bx,[bp+6] ; second parameter to function
-
- ; some more code
-
- mov sp,bp ; undo "sub sp,0x40" above
- pop bp
- retf 4 ; total size of params is 4
-
- At the other end of the process, to call a Pascal function from your
- assembly code, you would do something like this:
-
- extern SomeFunc
-
- ; and then, further down...
-
- push word seg mystring ; Now push the segment, and...
- push word mystring ; ... offset of "mystring"
- push word [myint] ; one of my variables
- call far SomeFunc
-
- This is equivalent to the Pascal code
-
- procedure SomeFunc(String: PChar; Int: Integer);
- SomeFunc(@mystring, myint);
-
- 8.5.2 Borland Pascal Segment Name Restrictions
-
- Since Borland Pascal's internal unit file format is completely
- different from `OBJ', it only makes a very sketchy job of actually
- reading and understanding the various information contained in a
- real `OBJ' file when it links that in. Therefore an object file
- intended to be linked to a Pascal program must obey a number of
- restrictions:
-
- (*) Procedures and functions must be in a segment whose name is
- either `CODE', `CSEG', or something ending in `_TEXT'.
-
- (*) initialized data must be in a segment whose name is either
- `CONST' or something ending in `_DATA'.
-
- (*) Uninitialized data must be in a segment whose name is either
- `DATA', `DSEG', or something ending in `_BSS'.
-
- (*) Any other segments in the object file are completely ignored.
- `GROUP' directives and segment attributes are also ignored.
-
- 8.5.3 Using `c16.mac' With Pascal Programs
-
- The `c16.mac' macro package, described in section 8.4.5, can also be
- used to simplify writing functions to be called from Pascal
- programs, if you code `%define PASCAL'. This definition ensures that
- functions are far (it implies `FARCODE'), and also causes procedure
- return instructions to be generated with an operand.
-
- Defining `PASCAL' does not change the code which calculates the
- argument offsets; you must declare your function's arguments in
- reverse order. For example:
-
- %define PASCAL
-
- proc _pascalproc
-
- %$j arg 4
- %$i arg
- mov ax,[bp + %$i]
- mov bx,[bp + %$j]
- mov es,[bp + %$j + 2]
- add ax,[bx]
-
- endproc
-
- This defines the same routine, conceptually, as the example in
- section 8.4.5: it defines a function taking two arguments, an
- integer and a pointer to an integer, which returns the sum of the
- integer and the contents of the pointer. The only difference between
- this code and the large-model C version is that `PASCAL' is defined
- instead of `FARCODE', and that the arguments are declared in reverse
- order.
-
-Chapter 9: Writing 32-bit Code (Unix, Win32, DJGPP)
----------------------------------------------------
-
- This chapter attempts to cover some of the common issues involved
- when writing 32-bit code, to run under Win32 or Unix, or to be
- linked with C code generated by a Unix-style C compiler such as
- DJGPP. It covers how to write assembly code to interface with 32-bit
- C routines, and how to write position-independent code for shared
- libraries.
-
- Almost all 32-bit code, and in particular all code running under
- `Win32', `DJGPP' or any of the PC Unix variants, runs in _flat_
- memory model. This means that the segment registers and paging have
- already been set up to give you the same 32-bit 4Gb address space no
- matter what segment you work relative to, and that you should ignore
- all segment registers completely. When writing flat-model
- application code, you never need to use a segment override or modify
- any segment register, and the code-section addresses you pass to
- `CALL' and `JMP' live in the same address space as the data-section
- addresses you access your variables by and the stack-section
- addresses you access local variables and procedure parameters by.
- Every address is 32 bits long and contains only an offset part.
-
- 9.1 Interfacing to 32-bit C Programs
-
- A lot of the discussion in section 8.4, about interfacing to 16-bit
- C programs, still applies when working in 32 bits. The absence of
- memory models or segmentation worries simplifies things a lot.
-
- 9.1.1 External Symbol Names
-
- Most 32-bit C compilers share the convention used by 16-bit
- compilers, that the names of all global symbols (functions or data)
- they define are formed by prefixing an underscore to the name as it
- appears in the C program. However, not all of them do: the `ELF'
- specification states that C symbols do _not_ have a leading
- underscore on their assembly-language names.
-
- The older Linux `a.out' C compiler, all `Win32' compilers, `DJGPP',
- and `NetBSD' and `FreeBSD', all use the leading underscore; for
- these compilers, the macros `cextern' and `cglobal', as given in
- section 8.4.1, will still work. For `ELF', though, the leading
- underscore should not be used.
-
- See also section 2.1.27.
-
- 9.1.2 Function Definitions and Function Calls
-
- The C calling convention in 32-bit programs is as follows. In the
- following description, the words _caller_ and _callee_ are used to
- denote the function doing the calling and the function which gets
- called.
-
- (*) The caller pushes the function's parameters on the stack, one
- after another, in reverse order (right to left, so that the
- first argument specified to the function is pushed last).
-
- (*) The caller then executes a near `CALL' instruction to pass
- control to the callee.
-
- (*) The callee receives control, and typically (although this is not
- actually necessary, in functions which do not need to access
- their parameters) starts by saving the value of `ESP' in `EBP'
- so as to be able to use `EBP' as a base pointer to find its
- parameters on the stack. However, the caller was probably doing
- this too, so part of the calling convention states that `EBP'
- must be preserved by any C function. Hence the callee, if it is
- going to set up `EBP' as a frame pointer, must push the previous
- value first.
-
- (*) The callee may then access its parameters relative to `EBP'. The
- doubleword at `[EBP]' holds the previous value of `EBP' as it
- was pushed; the next doubleword, at `[EBP+4]', holds the return
- address, pushed implicitly by `CALL'. The parameters start after
- that, at `[EBP+8]'. The leftmost parameter of the function,
- since it was pushed last, is accessible at this offset from
- `EBP'; the others follow, at successively greater offsets. Thus,
- in a function such as `printf' which takes a variable number of
- parameters, the pushing of the parameters in reverse order means
- that the function knows where to find its first parameter, which
- tells it the number and type of the remaining ones.
-
- (*) The callee may also wish to decrease `ESP' further, so as to
- allocate space on the stack for local variables, which will then
- be accessible at negative offsets from `EBP'.
-
- (*) The callee, if it wishes to return a value to the caller, should
- leave the value in `AL', `AX' or `EAX' depending on the size of
- the value. Floating-point results are typically returned in
- `ST0'.
-
- (*) Once the callee has finished processing, it restores `ESP' from
- `EBP' if it had allocated local stack space, then pops the
- previous value of `EBP', and returns via `RET' (equivalently,
- `RETN').
-
- (*) When the caller regains control from the callee, the function
- parameters are still on the stack, so it typically adds an
- immediate constant to `ESP' to remove them (instead of executing
- a number of slow `POP' instructions). Thus, if a function is
- accidentally called with the wrong number of parameters due to a
- prototype mismatch, the stack will still be returned to a
- sensible state since the caller, which _knows_ how many
- parameters it pushed, does the removing.
-
- There is an alternative calling convention used by Win32 programs
- for Windows API calls, and also for functions called _by_ the
- Windows API such as window procedures: they follow what Microsoft
- calls the `__stdcall' convention. This is slightly closer to the
- Pascal convention, in that the callee clears the stack by passing a
- parameter to the `RET' instruction. However, the parameters are
- still pushed in right-to-left order.
-
- Thus, you would define a function in C style in the following way:
-
- global _myfunc
-
- _myfunc:
- push ebp
- mov ebp,esp
- sub esp,0x40 ; 64 bytes of local stack space
- mov ebx,[ebp+8] ; first parameter to function
-
- ; some more code
-
- leave ; mov esp,ebp / pop ebp
- ret
-
- At the other end of the process, to call a C function from your
- assembly code, you would do something like this:
-
- extern _printf
-
- ; and then, further down...
-
- push dword [myint] ; one of my integer variables
- push dword mystring ; pointer into my data segment
- call _printf
- add esp,byte 8 ; `byte' saves space
-
- ; then those data items...
-
- segment _DATA
-
- myint dd 1234
- mystring db 'This number -> %d <- should be 1234',10,0
-
- This piece of code is the assembly equivalent of the C code
-
- int myint = 1234;
- printf("This number -> %d <- should be 1234\n", myint);
-
- 9.1.3 Accessing Data Items
-
- To get at the contents of C variables, or to declare variables which
- C can access, you need only declare the names as `GLOBAL' or
- `EXTERN'. (Again, the names require leading underscores, as stated
- in section 9.1.1.) Thus, a C variable declared as `int i' can be
- accessed from assembler as
-
- extern _i
- mov eax,[_i]
-
- And to declare your own integer variable which C programs can access
- as `extern int j', you do this (making sure you are assembling in
- the `_DATA' segment, if necessary):
-
- global _j
- _j dd 0
-
- To access a C array, you need to know the size of the components of
- the array. For example, `int' variables are four bytes long, so if a
- C program declares an array as `int a[10]', you can access `a[3]' by
- coding `mov ax,[_a+12]'. (The byte offset 12 is obtained by
- multiplying the desired array index, 3, by the size of the array
- element, 4.) The sizes of the C base types in 32-bit compilers are:
- 1 for `char', 2 for `short', 4 for `int', `long' and `float', and 8
- for `double'. Pointers, being 32-bit addresses, are also 4 bytes
- long.
-
- To access a C data structure, you need to know the offset from the
- base of the structure to the field you are interested in. You can
- either do this by converting the C structure definition into a NASM
- structure definition (using `STRUC'), or by calculating the one
- offset and using just that.
-
- To do either of these, you should read your C compiler's manual to
- find out how it organizes data structures. NASM gives no special
- alignment to structure members in its own `STRUC' macro, so you have
- to specify alignment yourself if the C compiler generates it.
- Typically, you might find that a structure like
-
- struct {
- char c;
- int i;
- } foo;
-
- might be eight bytes long rather than five, since the `int' field
- would be aligned to a four-byte boundary. However, this sort of
- feature is sometimes a configurable option in the C compiler, either
- using command-line options or `#pragma' lines, so you have to find
- out how your own compiler does it.
-
- 9.1.4 `c32.mac': Helper Macros for the 32-bit C Interface
-
- Included in the NASM archives, in the `misc' directory, is a file
- `c32.mac' of macros. It defines three macros: `proc', `arg' and
- `endproc'. These are intended to be used for C-style procedure
- definitions, and they automate a lot of the work involved in keeping
- track of the calling convention.
-
- An example of an assembly function using the macro set is given
- here:
-
- proc _proc32
-
- %$i arg
- %$j arg
- mov eax,[ebp + %$i]
- mov ebx,[ebp + %$j]
- add eax,[ebx]
-
- endproc
-
- This defines `_proc32' to be a procedure taking two arguments, the
- first (`i') an integer and the second (`j') a pointer to an integer.
- It returns `i + *j'.
-
- Note that the `arg' macro has an `EQU' as the first line of its
- expansion, and since the label before the macro call gets prepended
- to the first line of the expanded macro, the `EQU' works, defining
- `%$i' to be an offset from `BP'. A context-local variable is used,
- local to the context pushed by the `proc' macro and popped by the
- `endproc' macro, so that the same argument name can be used in later
- procedures. Of course, you don't _have_ to do that.
-
- `arg' can take an optional parameter, giving the size of the
- argument. If no size is given, 4 is assumed, since it is likely that
- many function parameters will be of type `int' or pointers.
-
- 9.2 Writing NetBSD/FreeBSD/OpenBSD and Linux/ELF Shared Libraries
-
- `ELF' replaced the older `a.out' object file format under Linux
- because it contains support for position-independent code (PIC),
- which makes writing shared libraries much easier. NASM supports the
- `ELF' position-independent code features, so you can write Linux
- `ELF' shared libraries in NASM.
-
- NetBSD, and its close cousins FreeBSD and OpenBSD, take a different
- approach by hacking PIC support into the `a.out' format. NASM
- supports this as the `aoutb' output format, so you can write BSD
- shared libraries in NASM too.
-
- The operating system loads a PIC shared library by memory-mapping
- the library file at an arbitrarily chosen point in the address space
- of the running process. The contents of the library's code section
- must therefore not depend on where it is loaded in memory.
-
- Therefore, you cannot get at your variables by writing code like
- this:
-
- mov eax,[myvar] ; WRONG
-
- Instead, the linker provides an area of memory called the _global
- offset table_, or GOT; the GOT is situated at a constant distance
- from your library's code, so if you can find out where your library
- is loaded (which is typically done using a `CALL' and `POP'
- combination), you can obtain the address of the GOT, and you can
- then load the addresses of your variables out of linker-generated
- entries in the GOT.
-
- The _data_ section of a PIC shared library does not have these
- restrictions: since the data section is writable, it has to be
- copied into memory anyway rather than just paged in from the library
- file, so as long as it's being copied it can be relocated too. So
- you can put ordinary types of relocation in the data section without
- too much worry (but see section 9.2.4 for a caveat).
-
- 9.2.1 Obtaining the Address of the GOT
-
- Each code module in your shared library should define the GOT as an
- external symbol:
-
- extern _GLOBAL_OFFSET_TABLE_ ; in ELF
- extern __GLOBAL_OFFSET_TABLE_ ; in BSD a.out
-
- At the beginning of any function in your shared library which plans
- to access your data or BSS sections, you must first calculate the
- address of the GOT. This is typically done by writing the function
- in this form:
-
- func: push ebp
- mov ebp,esp
- push ebx
- call .get_GOT
- .get_GOT:
- pop ebx
- add ebx,_GLOBAL_OFFSET_TABLE_+$$-.get_GOT wrt ..gotpc
-
- ; the function body comes here
-
- mov ebx,[ebp-4]
- mov esp,ebp
- pop ebp
- ret
-
- (For BSD, again, the symbol `_GLOBAL_OFFSET_TABLE' requires a second
- leading underscore.)
-
- The first two lines of this function are simply the standard C
- prologue to set up a stack frame, and the last three lines are
- standard C function epilogue. The third line, and the fourth to last
- line, save and restore the `EBX' register, because PIC shared
- libraries use this register to store the address of the GOT.
-
- The interesting bit is the `CALL' instruction and the following two
- lines. The `CALL' and `POP' combination obtains the address of the
- label `.get_GOT', without having to know in advance where the
- program was loaded (since the `CALL' instruction is encoded relative
- to the current position). The `ADD' instruction makes use of one of
- the special PIC relocation types: GOTPC relocation. With the
- `WRT ..gotpc' qualifier specified, the symbol referenced (here
- `_GLOBAL_OFFSET_TABLE_', the special symbol assigned to the GOT) is
- given as an offset from the beginning of the section. (Actually,
- `ELF' encodes it as the offset from the operand field of the `ADD'
- instruction, but NASM simplifies this deliberately, so you do things
- the same way for both `ELF' and `BSD'.) So the instruction then
- _adds_ the beginning of the section, to get the real address of the
- GOT, and subtracts the value of `.get_GOT' which it knows is in
- `EBX'. Therefore, by the time that instruction has finished, `EBX'
- contains the address of the GOT.
-
- If you didn't follow that, don't worry: it's never necessary to
- obtain the address of the GOT by any other means, so you can put
- those three instructions into a macro and safely ignore them:
-
- %macro get_GOT 0
-
- call %%getgot
- %%getgot:
- pop ebx
- add ebx,_GLOBAL_OFFSET_TABLE_+$$-%%getgot wrt ..gotpc
-
- %endmacro
-
- 9.2.2 Finding Your Local Data Items
-
- Having got the GOT, you can then use it to obtain the addresses of
- your data items. Most variables will reside in the sections you have
- declared; they can be accessed using the `..gotoff' special `WRT'
- type. The way this works is like this:
-
- lea eax,[ebx+myvar wrt ..gotoff]
-
- The expression `myvar wrt ..gotoff' is calculated, when the shared
- library is linked, to be the offset to the local variable `myvar'
- from the beginning of the GOT. Therefore, adding it to `EBX' as
- above will place the real address of `myvar' in `EAX'.
-
- If you declare variables as `GLOBAL' without specifying a size for
- them, they are shared between code modules in the library, but do
- not get exported from the library to the program that loaded it.
- They will still be in your ordinary data and BSS sections, so you
- can access them in the same way as local variables, using the above
- `..gotoff' mechanism.
-
- Note that due to a peculiarity of the way BSD `a.out' format handles
- this relocation type, there must be at least one non-local symbol in
- the same section as the address you're trying to access.
-
- 9.2.3 Finding External and Common Data Items
-
- If your library needs to get at an external variable (external to
- the _library_, not just to one of the modules within it), you must
- use the `..got' type to get at it. The `..got' type, instead of
- giving you the offset from the GOT base to the variable, gives you
- the offset from the GOT base to a GOT _entry_ containing the address
- of the variable. The linker will set up this GOT entry when it
- builds the library, and the dynamic linker will place the correct
- address in it at load time. So to obtain the address of an external
- variable `extvar' in `EAX', you would code
-
- mov eax,[ebx+extvar wrt ..got]
-
- This loads the address of `extvar' out of an entry in the GOT. The
- linker, when it builds the shared library, collects together every
- relocation of type `..got', and builds the GOT so as to ensure it
- has every necessary entry present.
-
- Common variables must also be accessed in this way.
-
- 9.2.4 Exporting Symbols to the Library User
-
- If you want to export symbols to the user of the library, you have
- to declare whether they are functions or data, and if they are data,
- you have to give the size of the data item. This is because the
- dynamic linker has to build procedure linkage table entries for any
- exported functions, and also moves exported data items away from the
- library's data section in which they were declared.
-
- So to export a function to users of the library, you must use
-
- global func:function ; declare it as a function
-
- func: push ebp
-
- ; etc.
-
- And to export a data item such as an array, you would have to code
-
- global array:data array.end-array ; give the size too
-
- array: resd 128
- .end:
-
- Be careful: If you export a variable to the library user, by
- declaring it as `GLOBAL' and supplying a size, the variable will end
- up living in the data section of the main program, rather than in
- your library's data section, where you declared it. So you will have
- to access your own global variable with the `..got' mechanism rather
- than `..gotoff', as if it were external (which, effectively, it has
- become).
-
- Equally, if you need to store the address of an exported global in
- one of your data sections, you can't do it by means of the standard
- sort of code:
-
- dataptr: dd global_data_item ; WRONG
-
- NASM will interpret this code as an ordinary relocation, in which
- `global_data_item' is merely an offset from the beginning of the
- `.data' section (or whatever); so this reference will end up
- pointing at your data section instead of at the exported global
- which resides elsewhere.
-
- Instead of the above code, then, you must write
-
- dataptr: dd global_data_item wrt ..sym
-
- which makes use of the special `WRT' type `..sym' to instruct NASM
- to search the symbol table for a particular symbol at that address,
- rather than just relocating by section base.
-
- Either method will work for functions: referring to one of your
- functions by means of
-
- funcptr: dd my_function
-
- will give the user the address of the code you wrote, whereas
-
- funcptr: dd my_function wrt .sym
-
- will give the address of the procedure linkage table for the
- function, which is where the calling program will _believe_ the
- function lives. Either address is a valid way to call the function.
-
- 9.2.5 Calling Procedures Outside the Library
-
- Calling procedures outside your shared library has to be done by
- means of a _procedure linkage table_, or PLT. The PLT is placed at a
- known offset from where the library is loaded, so the library code
- can make calls to the PLT in a position-independent way. Within the
- PLT there is code to jump to offsets contained in the GOT, so
- function calls to other shared libraries or to routines in the main
- program can be transparently passed off to their real destinations.
-
- To call an external routine, you must use another special PIC
- relocation type, `WRT ..plt'. This is much easier than the GOT-based
- ones: you simply replace calls such as `CALL printf' with the PLT-
- relative version `CALL printf WRT ..plt'.
-
- 9.2.6 Generating the Library File
-
- Having written some code modules and assembled them to `.o' files,
- you then generate your shared library with a command such as
-
- ld -shared -o library.so module1.o module2.o # for ELF
- ld -Bshareable -o library.so module1.o module2.o # for BSD
-
- For ELF, if your shared library is going to reside in system
- directories such as `/usr/lib' or `/lib', it is usually worth using
- the `-soname' flag to the linker, to store the final library file
- name, with a version number, into the library:
-
- ld -shared -soname library.so.1 -o library.so.1.2 *.o
-
- You would then copy `library.so.1.2' into the library directory, and
- create `library.so.1' as a symbolic link to it.
-
-Chapter 10: Mixing 16 and 32 Bit Code
--------------------------------------
-
- This chapter tries to cover some of the issues, largely related to
- unusual forms of addressing and jump instructions, encountered when
- writing operating system code such as protected-mode initialisation
- routines, which require code that operates in mixed segment sizes,
- such as code in a 16-bit segment trying to modify data in a 32-bit
- one, or jumps between different-size segments.
-
- 10.1 Mixed-Size Jumps
-
- The most common form of mixed-size instruction is the one used when
- writing a 32-bit OS: having done your setup in 16-bit mode, such as
- loading the kernel, you then have to boot it by switching into
- protected mode and jumping to the 32-bit kernel start address. In a
- fully 32-bit OS, this tends to be the _only_ mixed-size instruction
- you need, since everything before it can be done in pure 16-bit
- code, and everything after it can be pure 32-bit.
-
- This jump must specify a 48-bit far address, since the target
- segment is a 32-bit one. However, it must be assembled in a 16-bit
- segment, so just coding, for example,
-
- jmp 0x1234:0x56789ABC ; wrong!
-
- will not work, since the offset part of the address will be
- truncated to `0x9ABC' and the jump will be an ordinary 16-bit far
- one.
-
- The Linux kernel setup code gets round the inability of `as86' to
- generate the required instruction by coding it manually, using `DB'
- instructions. NASM can go one better than that, by actually
- generating the right instruction itself. Here's how to do it right:
-
- jmp dword 0x1234:0x56789ABC ; right
-
- The `DWORD' prefix (strictly speaking, it should come _after_ the
- colon, since it is declaring the _offset_ field to be a doubleword;
- but NASM will accept either form, since both are unambiguous) forces
- the offset part to be treated as far, in the assumption that you are
- deliberately writing a jump from a 16-bit segment to a 32-bit one.
-
- You can do the reverse operation, jumping from a 32-bit segment to a
- 16-bit one, by means of the `WORD' prefix:
-
- jmp word 0x8765:0x4321 ; 32 to 16 bit
-
- If the `WORD' prefix is specified in 16-bit mode, or the `DWORD'
- prefix in 32-bit mode, they will be ignored, since each is
- explicitly forcing NASM into a mode it was in anyway.
-
- 10.2 Addressing Between Different-Size Segments
-
- If your OS is mixed 16 and 32-bit, or if you are writing a DOS
- extender, you are likely to have to deal with some 16-bit segments
- and some 32-bit ones. At some point, you will probably end up
- writing code in a 16-bit segment which has to access data in a 32-
- bit segment, or vice versa.
-
- If the data you are trying to access in a 32-bit segment lies within
- the first 64K of the segment, you may be able to get away with using
- an ordinary 16-bit addressing operation for the purpose; but sooner
- or later, you will want to do 32-bit addressing from 16-bit mode.
-
- The easiest way to do this is to make sure you use a register for
- the address, since any effective address containing a 32-bit
- register is forced to be a 32-bit address. So you can do
-
- mov eax,offset_into_32_bit_segment_specified_by_fs
- mov dword [fs:eax],0x11223344
-
- This is fine, but slightly cumbersome (since it wastes an
- instruction and a register) if you already know the precise offset
- you are aiming at. The x86 architecture does allow 32-bit effective
- addresses to specify nothing but a 4-byte offset, so why shouldn't
- NASM be able to generate the best instruction for the purpose?
-
- It can. As in section 10.1, you need only prefix the address with
- the `DWORD' keyword, and it will be forced to be a 32-bit address:
-
- mov dword [fs:dword my_offset],0x11223344
-
- Also as in section 10.1, NASM is not fussy about whether the `DWORD'
- prefix comes before or after the segment override, so arguably a
- nicer-looking way to code the above instruction is
-
- mov dword [dword fs:my_offset],0x11223344
-
- Don't confuse the `DWORD' prefix _outside_ the square brackets,
- which controls the size of the data stored at the address, with the
- one `inside' the square brackets which controls the length of the
- address itself. The two can quite easily be different:
-
- mov word [dword 0x12345678],0x9ABC
-
- This moves 16 bits of data to an address specified by a 32-bit
- offset.
-
- You can also specify `WORD' or `DWORD' prefixes along with the `FAR'
- prefix to indirect far jumps or calls. For example:
-
- call dword far [fs:word 0x4321]
-
- This instruction contains an address specified by a 16-bit offset;
- it loads a 48-bit far pointer from that (16-bit segment and 32-bit
- offset), and calls that address.
-
- 10.3 Other Mixed-Size Instructions
-
- The other way you might want to access data might be using the
- string instructions (`LODSx', `STOSx' and so on) or the `XLATB'
- instruction. These instructions, since they take no parameters,
- might seem to have no easy way to make them perform 32-bit
- addressing when assembled in a 16-bit segment.
-
- This is the purpose of NASM's `a16', `a32' and `a64' prefixes. If
- you are coding `LODSB' in a 16-bit segment but it is supposed to be
- accessing a string in a 32-bit segment, you should load the desired
- address into `ESI' and then code
-
- a32 lodsb
-
- The prefix forces the addressing size to 32 bits, meaning that
- `LODSB' loads from `[DS:ESI]' instead of `[DS:SI]'. To access a
- string in a 16-bit segment when coding in a 32-bit one, the
- corresponding `a16' prefix can be used.
-
- The `a16', `a32' and `a64' prefixes can be applied to any
- instruction in NASM's instruction table, but most of them can
- generate all the useful forms without them. The prefixes are
- necessary only for instructions with implicit addressing: `CMPSx',
- `SCASx', `LODSx', `STOSx', `MOVSx', `INSx', `OUTSx', and `XLATB'.
- Also, the various push and pop instructions (`PUSHA' and `POPF' as
- well as the more usual `PUSH' and `POP') can accept `a16', `a32' or
- `a64' prefixes to force a particular one of `SP', `ESP' or `RSP' to
- be used as a stack pointer, in case the stack segment in use is a
- different size from the code segment.
-
- `PUSH' and `POP', when applied to segment registers in 32-bit mode,
- also have the slightly odd behaviour that they push and pop 4 bytes
- at a time, of which the top two are ignored and the bottom two give
- the value of the segment register being manipulated. To force the
- 16-bit behaviour of segment-register push and pop instructions, you
- can use the operand-size prefix `o16':
-
- o16 push ss
- o16 push ds
-
- This code saves a doubleword of stack space by fitting two segment
- registers into the space which would normally be consumed by pushing
- one.
-
- (You can also use the `o32' prefix to force the 32-bit behaviour
- when in 16-bit mode, but this seems less useful.)
-
-Chapter 11: Writing 64-bit Code (Unix, Win64)
----------------------------------------------
-
- This chapter attempts to cover some of the common issues involved
- when writing 64-bit code, to run under Win64 or Unix. It covers how
- to write assembly code to interface with 64-bit C routines, and how
- to write position-independent code for shared libraries.
-
- All 64-bit code uses a flat memory model, since segmentation is not
- available in 64-bit mode. The one exception is the `FS' and `GS'
- registers, which still add their bases.
-
- Position independence in 64-bit mode is significantly simpler, since
- the processor supports `RIP'-relative addressing directly; see the
- `REL' keyword (section 3.3). On most 64-bit platforms, it is
- probably desirable to make that the default, using the directive
- `DEFAULT REL' (section 6.2).
-
- 64-bit programming is relatively similar to 32-bit programming, but
- of course pointers are 64 bits long; additionally, all existing
- platforms pass arguments in registers rather than on the stack.
- Furthermore, 64-bit platforms use SSE2 by default for floating
- point. Please see the ABI documentation for your platform.
-
- 64-bit platforms differ in the sizes of the fundamental datatypes,
- not just from 32-bit platforms but from each other. If a specific
- size data type is desired, it is probably best to use the types
- defined in the Standard C header `<inttypes.h>'.
-
- In 64-bit mode, the default instruction size is still 32 bits. When
- loading a value into a 32-bit register (but not an 8- or 16-bit
- register), the upper 32 bits of the corresponding 64-bit register
- are set to zero.
-
- 11.1 Register Names in 64-bit Mode
-
- NASM uses the following names for general-purpose registers in 64-
- bit mode, for 8-, 16-, 32- and 64-bit references, respecitively:
-
- AL/AH, CL/CH, DL/DH, BL/BH, SPL, BPL, SIL, DIL, R8B-R15B
- AX, CX, DX, BX, SP, BP, SI, DI, R8W-R15W
- EAX, ECX, EDX, EBX, ESP, EBP, ESI, EDI, R8D-R15D
- RAX, RCX, RDX, RBX, RSP, RBP, RSI, RDI, R8-R15
-
- This is consistent with the AMD documentation and most other
- assemblers. The Intel documentation, however, uses the names
- `R8L-R15L' for 8-bit references to the higher registers. It is
- possible to use those names by definiting them as macros; similarly,
- if one wants to use numeric names for the low 8 registers, define
- them as macros. The standard macro package `altreg' (see section
- 5.1) can be used for this purpose.
-
- 11.2 Immediates and Displacements in 64-bit Mode
-
- In 64-bit mode, immediates and displacements are generally only 32
- bits wide. NASM will therefore truncate most displacements and
- immediates to 32 bits.
-
- The only instruction which takes a full 64-bit immediate is:
-
- MOV reg64,imm64
-
- NASM will produce this instruction whenever the programmer uses
- `MOV' with an immediate into a 64-bit register. If this is not
- desirable, simply specify the equivalent 32-bit register, which will
- be automatically zero-extended by the processor, or specify the
- immediate as `DWORD':
-
- mov rax,foo ; 64-bit immediate
- mov rax,qword foo ; (identical)
- mov eax,foo ; 32-bit immediate, zero-extended
- mov rax,dword foo ; 32-bit immediate, sign-extended
-
- The length of these instructions are 10, 5 and 7 bytes,
- respectively.
-
- The only instructions which take a full 64-bit _displacement_ is
- loading or storing, using `MOV', `AL', `AX', `EAX' or `RAX' (but no
- other registers) to an absolute 64-bit address. Since this is a
- relatively rarely used instruction (64-bit code generally uses
- relative addressing), the programmer has to explicitly declare the
- displacement size as `QWORD':
-
- default abs
-
- mov eax,[foo] ; 32-bit absolute disp, sign-extended
- mov eax,[a32 foo] ; 32-bit absolute disp, zero-extended
- mov eax,[qword foo] ; 64-bit absolute disp
-
- default rel
-
- mov eax,[foo] ; 32-bit relative disp
- mov eax,[a32 foo] ; d:o, address truncated to 32 bits(!)
- mov eax,[qword foo] ; error
- mov eax,[abs qword foo] ; 64-bit absolute disp
-
- A sign-extended absolute displacement can access from -2 GB to +2
- GB; a zero-extended absolute displacement can access from 0 to 4 GB.
-
- 11.3 Interfacing to 64-bit C Programs (Unix)
-
- On Unix, the 64-bit ABI is defined by the document:
-
- `http://www.x86-64.org/documentation/abi.pdf'
-
- Although written for AT&T-syntax assembly, the concepts apply
- equally well for NASM-style assembly. What follows is a simplified
- summary.
-
- The first six integer arguments (from the left) are passed in `RDI',
- `RSI', `RDX', `RCX', `R8', and `R9', in that order. Additional
- integer arguments are passed on the stack. These registers, plus
- `RAX', `R10' and `R11' are destroyed by function calls, and thus are
- available for use by the function without saving.
-
- Integer return values are passed in `RAX' and `RDX', in that order.
-
- Floating point is done using SSE registers, except for
- `long double'. Floating-point arguments are passed in `XMM0' to
- `XMM7'; return is `XMM0' and `XMM1'. `long double' are passed on the
- stack, and returned in `ST0' and `ST1'.
-
- All SSE and x87 registers are destroyed by function calls.
-
- On 64-bit Unix, `long' is 64 bits.
-
- Integer and SSE register arguments are counted separately, so for
- the case of
-
- void foo(long a, double b, int c)
-
- `a' is passed in `RDI', `b' in `XMM0', and `c' in `ESI'.
-
- 11.4 Interfacing to 64-bit C Programs (Win64)
-
- The Win64 ABI is described at:
-
- `http://msdn2.microsoft.com/en-gb/library/ms794533.aspx'
-
- What follows is a simplified summary.
-
- The first four integer arguments are passed in `RCX', `RDX', `R8'
- and `R9', in that order. Additional integer arguments are passed on
- the stack. These registers, plus `RAX', `R10' and `R11' are
- destroyed by function calls, and thus are available for use by the
- function without saving.
-
- Integer return values are passed in `RAX' only.
-
- Floating point is done using SSE registers, except for
- `long double'. Floating-point arguments are passed in `XMM0' to
- `XMM3'; return is `XMM0' only.
-
- On Win64, `long' is 32 bits; `long long' or `_int64' is 64 bits.
-
- Integer and SSE register arguments are counted together, so for the
- case of
-
- void foo(long long a, double b, int c)
-
- `a' is passed in `RCX', `b' in `XMM1', and `c' in `R8D'.
-
-Chapter 12: Troubleshooting
----------------------------
-
- This chapter describes some of the common problems that users have
- been known to encounter with NASM, and answers them. It also gives
- instructions for reporting bugs in NASM if you find a difficulty
- that isn't listed here.
-
- 12.1 Common Problems
-
-12.1.1 NASM Generates Inefficient Code
-
- We sometimes get `bug' reports about NASM generating inefficient, or
- even `wrong', code on instructions such as `ADD ESP,8'. This is a
- deliberate design feature, connected to predictability of output:
- NASM, on seeing `ADD ESP,8', will generate the form of the
- instruction which leaves room for a 32-bit offset. You need to code
- `ADD ESP,BYTE 8' if you want the space-efficient form of the
- instruction. This isn't a bug, it's user error: if you prefer to
- have NASM produce the more efficient code automatically enable
- optimization with the `-O' option (see section 2.1.22).
-
-12.1.2 My Jumps are Out of Range
-
- Similarly, people complain that when they issue conditional jumps
- (which are `SHORT' by default) that try to jump too far, NASM
- reports `short jump out of range' instead of making the jumps
- longer.
-
- This, again, is partly a predictability issue, but in fact has a
- more practical reason as well. NASM has no means of being told what
- type of processor the code it is generating will be run on; so it
- cannot decide for itself that it should generate `Jcc NEAR' type
- instructions, because it doesn't know that it's working for a 386 or
- above. Alternatively, it could replace the out-of-range short `JNE'
- instruction with a very short `JE' instruction that jumps over a
- `JMP NEAR'; this is a sensible solution for processors below a 386,
- but hardly efficient on processors which have good branch prediction
- _and_ could have used `JNE NEAR' instead. So, once again, it's up to
- the user, not the assembler, to decide what instructions should be
- generated. See section 2.1.22.
-
-12.1.3 `ORG' Doesn't Work
-
- People writing boot sector programs in the `bin' format often
- complain that `ORG' doesn't work the way they'd like: in order to
- place the `0xAA55' signature word at the end of a 512-byte boot
- sector, people who are used to MASM tend to code
-
- ORG 0
-
- ; some boot sector code
-
- ORG 510
- DW 0xAA55
-
- This is not the intended use of the `ORG' directive in NASM, and
- will not work. The correct way to solve this problem in NASM is to
- use the `TIMES' directive, like this:
-
- ORG 0
-
- ; some boot sector code
-
- TIMES 510-($-$$) DB 0
- DW 0xAA55
-
- The `TIMES' directive will insert exactly enough zero bytes into the
- output to move the assembly point up to 510. This method also has
- the advantage that if you accidentally fill your boot sector too
- full, NASM will catch the problem at assembly time and report it, so
- you won't end up with a boot sector that you have to disassemble to
- find out what's wrong with it.
-
-12.1.4 `TIMES' Doesn't Work
-
- The other common problem with the above code is people who write the
- `TIMES' line as
-
- TIMES 510-$ DB 0
-
- by reasoning that `$' should be a pure number, just like 510, so the
- difference between them is also a pure number and can happily be fed
- to `TIMES'.
-
- NASM is a _modular_ assembler: the various component parts are
- designed to be easily separable for re-use, so they don't exchange
- information unnecessarily. In consequence, the `bin' output format,
- even though it has been told by the `ORG' directive that the `.text'
- section should start at 0, does not pass that information back to
- the expression evaluator. So from the evaluator's point of view, `$'
- isn't a pure number: it's an offset from a section base. Therefore
- the difference between `$' and 510 is also not a pure number, but
- involves a section base. Values involving section bases cannot be
- passed as arguments to `TIMES'.
-
- The solution, as in the previous section, is to code the `TIMES'
- line in the form
-
- TIMES 510-($-$$) DB 0
-
- in which `$' and `$$' are offsets from the same section base, and so
- their difference is a pure number. This will solve the problem and
- generate sensible code.
-
- 12.2 Bugs
-
- We have never yet released a version of NASM with any _known_ bugs.
- That doesn't usually stop there being plenty we didn't know about,
- though. Any that you find should be reported firstly via the
- `bugtracker' at `https://sourceforge.net/projects/nasm/' (click on
- "Bugs"), or if that fails then through one of the contacts in
- section 1.2.
-
- Please read section 2.2 first, and don't report the bug if it's
- listed in there as a deliberate feature. (If you think the feature
- is badly thought out, feel free to send us reasons why you think it
- should be changed, but don't just send us mail saying `This is a
- bug' if the documentation says we did it on purpose.) Then read
- section 12.1, and don't bother reporting the bug if it's listed
- there.
-
- If you do report a bug, _please_ give us all of the following
- information:
-
- (*) What operating system you're running NASM under. DOS, Linux,
- NetBSD, Win16, Win32, VMS (I'd be impressed), whatever.
-
- (*) If you're running NASM under DOS or Win32, tell us whether
- you've compiled your own executable from the DOS source archive,
- or whether you were using the standard distribution binaries out
- of the archive. If you were using a locally built executable,
- try to reproduce the problem using one of the standard binaries,
- as this will make it easier for us to reproduce your problem
- prior to fixing it.
-
- (*) Which version of NASM you're using, and exactly how you invoked
- it. Give us the precise command line, and the contents of the
- `NASMENV' environment variable if any.
-
- (*) Which versions of any supplementary programs you're using, and
- how you invoked them. If the problem only becomes visible at
- link time, tell us what linker you're using, what version of it
- you've got, and the exact linker command line. If the problem
- involves linking against object files generated by a compiler,
- tell us what compiler, what version, and what command line or
- options you used. (If you're compiling in an IDE, please try to
- reproduce the problem with the command-line version of the
- compiler.)
-
- (*) If at all possible, send us a NASM source file which exhibits
- the problem. If this causes copyright problems (e.g. you can
- only reproduce the bug in restricted-distribution code) then
- bear in mind the following two points: firstly, we guarantee
- that any source code sent to us for the purposes of debugging
- NASM will be used _only_ for the purposes of debugging NASM, and
- that we will delete all our copies of it as soon as we have
- found and fixed the bug or bugs in question; and secondly, we
- would prefer _not_ to be mailed large chunks of code anyway. The
- smaller the file, the better. A three-line sample file that does
- nothing useful _except_ demonstrate the problem is much easier
- to work with than a fully fledged ten-thousand-line program. (Of
- course, some errors _do_ only crop up in large files, so this
- may not be possible.)
-
- (*) A description of what the problem actually _is_. `It doesn't
- work' is _not_ a helpful description! Please describe exactly
- what is happening that shouldn't be, or what isn't happening
- that should. Examples might be: `NASM generates an error message
- saying Line 3 for an error that's actually on Line 5'; `NASM
- generates an error message that I believe it shouldn't be
- generating at all'; `NASM fails to generate an error message
- that I believe it _should_ be generating'; `the object file
- produced from this source code crashes my linker'; `the ninth
- byte of the output file is 66 and I think it should be 77
- instead'.
-
- (*) If you believe the output file from NASM to be faulty, send it
- to us. That allows us to determine whether our own copy of NASM
- generates the same file, or whether the problem is related to
- portability issues between our development platforms and yours.
- We can handle binary files mailed to us as MIME attachments,
- uuencoded, and even BinHex. Alternatively, we may be able to
- provide an FTP site you can upload the suspect files to; but
- mailing them is easier for us.
-
- (*) Any other information or data files that might be helpful. If,
- for example, the problem involves NASM failing to generate an
- object file while TASM can generate an equivalent file without
- trouble, then send us _both_ object files, so we can see what
- TASM is doing differently from us.
-
-Appendix A: Ndisasm
--------------------
-
- The Netwide Disassembler, NDISASM
-
- A.1 Introduction
-
- The Netwide Disassembler is a small companion program to the Netwide
- Assembler, NASM. It seemed a shame to have an x86 assembler,
- complete with a full instruction table, and not make as much use of
- it as possible, so here's a disassembler which shares the
- instruction table (and some other bits of code) with NASM.
-
- The Netwide Disassembler does nothing except to produce
- disassemblies of _binary_ source files. NDISASM does not have any
- understanding of object file formats, like `objdump', and it will
- not understand `DOS .EXE' files like `debug' will. It just
- disassembles.
-
- A.2 Getting Started: Installation
-
- See section 1.3 for installation instructions. NDISASM, like NASM,
- has a `man page' which you may want to put somewhere useful, if you
- are on a Unix system.
-
- A.3 Running NDISASM
-
- To disassemble a file, you will typically use a command of the form
-
- ndisasm -b {16|32|64} filename
-
- NDISASM can disassemble 16-, 32- or 64-bit code equally easily,
- provided of course that you remember to specify which it is to work
- with. If no `-b' switch is present, NDISASM works in 16-bit mode by
- default. The `-u' switch (for USE32) also invokes 32-bit mode.
-
- Two more command line options are `-r' which reports the version
- number of NDISASM you are running, and `-h' which gives a short
- summary of command line options.
-
- A.3.1 COM Files: Specifying an Origin
-
- To disassemble a `DOS .COM' file correctly, a disassembler must
- assume that the first instruction in the file is loaded at address
- `0x100', rather than at zero. NDISASM, which assumes by default that
- any file you give it is loaded at zero, will therefore need to be
- informed of this.
-
- The `-o' option allows you to declare a different origin for the
- file you are disassembling. Its argument may be expressed in any of
- the NASM numeric formats: decimal by default, if it begins with
- ``$'' or ``0x'' or ends in ``H'' it's `hex', if it ends in ``Q''
- it's `octal', and if it ends in ``B'' it's `binary'.
-
- Hence, to disassemble a `.COM' file:
-
- ndisasm -o100h filename.com
-
- will do the trick.
-
- A.3.2 Code Following Data: Synchronisation
-
- Suppose you are disassembling a file which contains some data which
- isn't machine code, and _then_ contains some machine code. NDISASM
- will faithfully plough through the data section, producing machine
- instructions wherever it can (although most of them will look
- bizarre, and some may have unusual prefixes, e.g.
- ``FS OR AX,0x240A''), and generating `DB' instructions ever so often
- if it's totally stumped. Then it will reach the code section.
-
- Supposing NDISASM has just finished generating a strange machine
- instruction from part of the data section, and its file position is
- now one byte _before_ the beginning of the code section. It's
- entirely possible that another spurious instruction will get
- generated, starting with the final byte of the data section, and
- then the correct first instruction in the code section will not be
- seen because the starting point skipped over it. This isn't really
- ideal.
-
- To avoid this, you can specify a ``synchronisation'' point, or
- indeed as many synchronisation points as you like (although NDISASM
- can only handle 2147483647 sync points internally). The definition
- of a sync point is this: NDISASM guarantees to hit sync points
- exactly during disassembly. If it is thinking about generating an
- instruction which would cause it to jump over a sync point, it will
- discard that instruction and output a ``db'' instead. So it _will_
- start disassembly exactly from the sync point, and so you _will_ see
- all the instructions in your code section.
-
- Sync points are specified using the `-s' option: they are measured
- in terms of the program origin, not the file position. So if you
- want to synchronize after 32 bytes of a `.COM' file, you would have
- to do
-
- ndisasm -o100h -s120h file.com
-
- rather than
-
- ndisasm -o100h -s20h file.com
-
- As stated above, you can specify multiple sync markers if you need
- to, just by repeating the `-s' option.
-
- A.3.3 Mixed Code and Data: Automatic (Intelligent) Synchronisation
-
- Suppose you are disassembling the boot sector of a `DOS' floppy
- (maybe it has a virus, and you need to understand the virus so that
- you know what kinds of damage it might have done you). Typically,
- this will contain a `JMP' instruction, then some data, then the rest
- of the code. So there is a very good chance of NDISASM being
- _misaligned_ when the data ends and the code begins. Hence a sync
- point is needed.
-
- On the other hand, why should you have to specify the sync point
- manually? What you'd do in order to find where the sync point would
- be, surely, would be to read the `JMP' instruction, and then to use
- its target address as a sync point. So can NDISASM do that for you?
-
- The answer, of course, is yes: using either of the synonymous
- switches `-a' (for automatic sync) or `-i' (for intelligent sync)
- will enable `auto-sync' mode. Auto-sync mode automatically generates
- a sync point for any forward-referring PC-relative jump or call
- instruction that NDISASM encounters. (Since NDISASM is one-pass, if
- it encounters a PC-relative jump whose target has already been
- processed, there isn't much it can do about it...)
-
- Only PC-relative jumps are processed, since an absolute jump is
- either through a register (in which case NDISASM doesn't know what
- the register contains) or involves a segment address (in which case
- the target code isn't in the same segment that NDISASM is working
- in, and so the sync point can't be placed anywhere useful).
-
- For some kinds of file, this mechanism will automatically put sync
- points in all the right places, and save you from having to place
- any sync points manually. However, it should be stressed that auto-
- sync mode is _not_ guaranteed to catch all the sync points, and you
- may still have to place some manually.
-
- Auto-sync mode doesn't prevent you from declaring manual sync
- points: it just adds automatically generated ones to the ones you
- provide. It's perfectly feasible to specify `-i' _and_ some `-s'
- options.
-
- Another caveat with auto-sync mode is that if, by some unpleasant
- fluke, something in your data section should disassemble to a PC-
- relative call or jump instruction, NDISASM may obediently place a
- sync point in a totally random place, for example in the middle of
- one of the instructions in your code section. So you may end up with
- a wrong disassembly even if you use auto-sync. Again, there isn't
- much I can do about this. If you have problems, you'll have to use
- manual sync points, or use the `-k' option (documented below) to
- suppress disassembly of the data area.
-
- A.3.4 Other Options
-
- The `-e' option skips a header on the file, by ignoring the first N
- bytes. This means that the header is _not_ counted towards the
- disassembly offset: if you give `-e10 -o10', disassembly will start
- at byte 10 in the file, and this will be given offset 10, not 20.
-
- The `-k' option is provided with two comma-separated numeric
- arguments, the first of which is an assembly offset and the second
- is a number of bytes to skip. This _will_ count the skipped bytes
- towards the assembly offset: its use is to suppress disassembly of a
- data section which wouldn't contain anything you wanted to see
- anyway.
-
- A.4 Bugs and Improvements
-
- There are no known bugs. However, any you find, with patches if
- possible, should be sent to `nasm-bugs@lists.sourceforge.net', or to
- the developer's site at `https://sourceforge.net/projects/nasm/' and
- we'll try to fix them. Feel free to send contributions and new
- features as well.
-
-Appendix B: Instruction List
-----------------------------
-
- B.1 Introduction
-
- The following sections show the instructions which NASM currently
- supports. For each instruction, there is a separate entry for each
- supported addressing mode. The third column shows the processor type
- in which the instruction was introduced and, when appropriate, one
- or more usage flags.
-
- B.1.1 Special instructions...
-
- DB
- DW
- DD
- DQ
- DT
- DO
- DY
- RESB imm 8086
- RESW
- RESD
- RESQ
- REST
- RESO
- RESY
-
- B.1.2 Conventional instructions
-
- AAA 8086,NOLONG
- AAD 8086,NOLONG
- AAD imm 8086,NOLONG
- AAM 8086,NOLONG
- AAM imm 8086,NOLONG
- AAS 8086,NOLONG
- ADC mem,reg8 8086
- ADC reg8,reg8 8086
- ADC mem,reg16 8086
- ADC reg16,reg16 8086
- ADC mem,reg32 386
- ADC reg32,reg32 386
- ADC mem,reg64 X64
- ADC reg64,reg64 X64
- ADC reg8,mem 8086
- ADC reg8,reg8 8086
- ADC reg16,mem 8086
- ADC reg16,reg16 8086
- ADC reg32,mem 386
- ADC reg32,reg32 386
- ADC reg64,mem X64
- ADC reg64,reg64 X64
- ADC rm16,imm8 8086
- ADC rm32,imm8 386
- ADC rm64,imm8 X64
- ADC reg_al,imm 8086
- ADC reg_ax,sbyte16 8086
- ADC reg_ax,imm 8086
- ADC reg_eax,sbyte32 386
- ADC reg_eax,imm 386
- ADC reg_rax,sbyte64 X64
- ADC reg_rax,imm X64
- ADC rm8,imm 8086
- ADC rm16,imm 8086
- ADC rm32,imm 386
- ADC rm64,imm X64
- ADC mem,imm8 8086
- ADC mem,imm16 8086
- ADC mem,imm32 386
- ADD mem,reg8 8086
- ADD reg8,reg8 8086
- ADD mem,reg16 8086
- ADD reg16,reg16 8086
- ADD mem,reg32 386
- ADD reg32,reg32 386
- ADD mem,reg64 X64
- ADD reg64,reg64 X64
- ADD reg8,mem 8086
- ADD reg8,reg8 8086
- ADD reg16,mem 8086
- ADD reg16,reg16 8086
- ADD reg32,mem 386
- ADD reg32,reg32 386
- ADD reg64,mem X64
- ADD reg64,reg64 X64
- ADD rm16,imm8 8086
- ADD rm32,imm8 386
- ADD rm64,imm8 X64
- ADD reg_al,imm 8086
- ADD reg_ax,sbyte16 8086
- ADD reg_ax,imm 8086
- ADD reg_eax,sbyte32 386
- ADD reg_eax,imm 386
- ADD reg_rax,sbyte64 X64
- ADD reg_rax,imm X64
- ADD rm8,imm 8086
- ADD rm16,imm 8086
- ADD rm32,imm 386
- ADD rm64,imm X64
- ADD mem,imm8 8086
- ADD mem,imm16 8086
- ADD mem,imm32 386
- AND mem,reg8 8086
- AND reg8,reg8 8086
- AND mem,reg16 8086
- AND reg16,reg16 8086
- AND mem,reg32 386
- AND reg32,reg32 386
- AND mem,reg64 X64
- AND reg64,reg64 X64
- AND reg8,mem 8086
- AND reg8,reg8 8086
- AND reg16,mem 8086
- AND reg16,reg16 8086
- AND reg32,mem 386
- AND reg32,reg32 386
- AND reg64,mem X64
- AND reg64,reg64 X64
- AND rm16,imm8 8086
- AND rm32,imm8 386
- AND rm64,imm8 X64
- AND reg_al,imm 8086
- AND reg_ax,sbyte16 8086
- AND reg_ax,imm 8086
- AND reg_eax,sbyte32 386
- AND reg_eax,imm 386
- AND reg_rax,sbyte64 X64
- AND reg_rax,imm X64
- AND rm8,imm 8086
- AND rm16,imm 8086
- AND rm32,imm 386
- AND rm64,imm X64
- AND mem,imm8 8086
- AND mem,imm16 8086
- AND mem,imm32 386
- ARPL mem,reg16 286,PROT,NOLONG
- ARPL reg16,reg16 286,PROT,NOLONG
- BB0_RESET PENT,CYRIX,ND
- BB1_RESET PENT,CYRIX,ND
- BOUND reg16,mem 186,NOLONG
- BOUND reg32,mem 386,NOLONG
- BSF reg16,mem 386
- BSF reg16,reg16 386
- BSF reg32,mem 386
- BSF reg32,reg32 386
- BSF reg64,mem X64
- BSF reg64,reg64 X64
- BSR reg16,mem 386
- BSR reg16,reg16 386
- BSR reg32,mem 386
- BSR reg32,reg32 386
- BSR reg64,mem X64
- BSR reg64,reg64 X64
- BSWAP reg32 486
- BSWAP reg64 X64
- BT mem,reg16 386
- BT reg16,reg16 386
- BT mem,reg32 386
- BT reg32,reg32 386
- BT mem,reg64 X64
- BT reg64,reg64 X64
- BT rm16,imm 386
- BT rm32,imm 386
- BT rm64,imm X64
- BTC mem,reg16 386
- BTC reg16,reg16 386
- BTC mem,reg32 386
- BTC reg32,reg32 386
- BTC mem,reg64 X64
- BTC reg64,reg64 X64
- BTC rm16,imm 386
- BTC rm32,imm 386
- BTC rm64,imm X64
- BTR mem,reg16 386
- BTR reg16,reg16 386
- BTR mem,reg32 386
- BTR reg32,reg32 386
- BTR mem,reg64 X64
- BTR reg64,reg64 X64
- BTR rm16,imm 386
- BTR rm32,imm 386
- BTR rm64,imm X64
- BTS mem,reg16 386
- BTS reg16,reg16 386
- BTS mem,reg32 386
- BTS reg32,reg32 386
- BTS mem,reg64 X64
- BTS reg64,reg64 X64
- BTS rm16,imm 386
- BTS rm32,imm 386
- BTS rm64,imm X64
- CALL imm 8086
- CALL imm|near 8086
- CALL imm|far 8086,ND,NOLONG
- CALL imm16 8086
- CALL imm16|near 8086
- CALL imm16|far 8086,ND,NOLONG
- CALL imm32 386
- CALL imm32|near 386
- CALL imm32|far 386,ND,NOLONG
- CALL imm:imm 8086,NOLONG
- CALL imm16:imm 8086,NOLONG
- CALL imm:imm16 8086,NOLONG
- CALL imm32:imm 386,NOLONG
- CALL imm:imm32 386,NOLONG
- CALL mem|far 8086,NOLONG
- CALL mem|far X64
- CALL mem16|far 8086
- CALL mem32|far 386
- CALL mem64|far X64
- CALL mem|near 8086
- CALL mem16|near 8086
- CALL mem32|near 386,NOLONG
- CALL mem64|near X64
- CALL reg16 8086
- CALL reg32 386,NOLONG
- CALL reg64 X64
- CALL mem 8086
- CALL mem16 8086
- CALL mem32 386,NOLONG
- CALL mem64 X64
- CBW 8086
- CDQ 386
- CDQE X64
- CLC 8086
- CLD 8086
- CLGI X64,AMD
- CLI 8086
- CLTS 286,PRIV
- CMC 8086
- CMP mem,reg8 8086
- CMP reg8,reg8 8086
- CMP mem,reg16 8086
- CMP reg16,reg16 8086
- CMP mem,reg32 386
- CMP reg32,reg32 386
- CMP mem,reg64 X64
- CMP reg64,reg64 X64
- CMP reg8,mem 8086
- CMP reg8,reg8 8086
- CMP reg16,mem 8086
- CMP reg16,reg16 8086
- CMP reg32,mem 386
- CMP reg32,reg32 386
- CMP reg64,mem X64
- CMP reg64,reg64 X64
- CMP rm16,imm8 8086
- CMP rm32,imm8 386
- CMP rm64,imm8 X64
- CMP reg_al,imm 8086
- CMP reg_ax,sbyte16 8086
- CMP reg_ax,imm 8086
- CMP reg_eax,sbyte32 386
- CMP reg_eax,imm 386
- CMP reg_rax,sbyte64 X64
- CMP reg_rax,imm X64
- CMP rm8,imm 8086
- CMP rm16,imm 8086
- CMP rm32,imm 386
- CMP rm64,imm X64
- CMP mem,imm8 8086
- CMP mem,imm16 8086
- CMP mem,imm32 386
- CMPSB 8086
- CMPSD 386
- CMPSQ X64
- CMPSW 8086
- CMPXCHG mem,reg8 PENT
- CMPXCHG reg8,reg8 PENT
- CMPXCHG mem,reg16 PENT
- CMPXCHG reg16,reg16 PENT
- CMPXCHG mem,reg32 PENT
- CMPXCHG reg32,reg32 PENT
- CMPXCHG mem,reg64 X64
- CMPXCHG reg64,reg64 X64
- CMPXCHG486 mem,reg8 486,UNDOC,ND
- CMPXCHG486 reg8,reg8 486,UNDOC,ND
- CMPXCHG486 mem,reg16 486,UNDOC,ND
- CMPXCHG486 reg16,reg16 486,UNDOC,ND
- CMPXCHG486 mem,reg32 486,UNDOC,ND
- CMPXCHG486 reg32,reg32 486,UNDOC,ND
- CMPXCHG8B mem PENT
- CMPXCHG16B mem X64
- CPUID PENT
- CPU_READ PENT,CYRIX
- CPU_WRITE PENT,CYRIX
- CQO X64
- CWD 8086
- CWDE 386
- DAA 8086,NOLONG
- DAS 8086,NOLONG
- DEC reg16 8086,NOLONG
- DEC reg32 386,NOLONG
- DEC rm8 8086
- DEC rm16 8086
- DEC rm32 386
- DEC rm64 X64
- DIV rm8 8086
- DIV rm16 8086
- DIV rm32 386
- DIV rm64 X64
- DMINT P6,CYRIX
- EMMS PENT,MMX
- ENTER imm,imm 186
- EQU imm 8086
- EQU imm:imm 8086
- F2XM1 8086,FPU
- FABS 8086,FPU
- FADD mem32 8086,FPU
- FADD mem64 8086,FPU
- FADD fpureg|to 8086,FPU
- FADD fpureg 8086,FPU
- FADD fpureg,fpu0 8086,FPU
- FADD fpu0,fpureg 8086,FPU
- FADD 8086,FPU,ND
- FADDP fpureg 8086,FPU
- FADDP fpureg,fpu0 8086,FPU
- FADDP 8086,FPU,ND
- FBLD mem80 8086,FPU
- FBLD mem 8086,FPU
- FBSTP mem80 8086,FPU
- FBSTP mem 8086,FPU
- FCHS 8086,FPU
- FCLEX 8086,FPU
- FCMOVB fpureg P6,FPU
- FCMOVB fpu0,fpureg P6,FPU
- FCMOVB P6,FPU,ND
- FCMOVBE fpureg P6,FPU
- FCMOVBE fpu0,fpureg P6,FPU
- FCMOVBE P6,FPU,ND
- FCMOVE fpureg P6,FPU
- FCMOVE fpu0,fpureg P6,FPU
- FCMOVE P6,FPU,ND
- FCMOVNB fpureg P6,FPU
- FCMOVNB fpu0,fpureg P6,FPU
- FCMOVNB P6,FPU,ND
- FCMOVNBE fpureg P6,FPU
- FCMOVNBE fpu0,fpureg P6,FPU
- FCMOVNBE P6,FPU,ND
- FCMOVNE fpureg P6,FPU
- FCMOVNE fpu0,fpureg P6,FPU
- FCMOVNE P6,FPU,ND
- FCMOVNU fpureg P6,FPU
- FCMOVNU fpu0,fpureg P6,FPU
- FCMOVNU P6,FPU,ND
- FCMOVU fpureg P6,FPU
- FCMOVU fpu0,fpureg P6,FPU
- FCMOVU P6,FPU,ND
- FCOM mem32 8086,FPU
- FCOM mem64 8086,FPU
- FCOM fpureg 8086,FPU
- FCOM fpu0,fpureg 8086,FPU
- FCOM 8086,FPU,ND
- FCOMI fpureg P6,FPU
- FCOMI fpu0,fpureg P6,FPU
- FCOMI P6,FPU,ND
- FCOMIP fpureg P6,FPU
- FCOMIP fpu0,fpureg P6,FPU
- FCOMIP P6,FPU,ND
- FCOMP mem32 8086,FPU
- FCOMP mem64 8086,FPU
- FCOMP fpureg 8086,FPU
- FCOMP fpu0,fpureg 8086,FPU
- FCOMP 8086,FPU,ND
- FCOMPP 8086,FPU
- FCOS 386,FPU
- FDECSTP 8086,FPU
- FDISI 8086,FPU
- FDIV mem32 8086,FPU
- FDIV mem64 8086,FPU
- FDIV fpureg|to 8086,FPU
- FDIV fpureg 8086,FPU
- FDIV fpureg,fpu0 8086,FPU
- FDIV fpu0,fpureg 8086,FPU
- FDIV 8086,FPU,ND
- FDIVP fpureg 8086,FPU
- FDIVP fpureg,fpu0 8086,FPU
- FDIVP 8086,FPU,ND
- FDIVR mem32 8086,FPU
- FDIVR mem64 8086,FPU
- FDIVR fpureg|to 8086,FPU
- FDIVR fpureg,fpu0 8086,FPU
- FDIVR fpureg 8086,FPU
- FDIVR fpu0,fpureg 8086,FPU
- FDIVR 8086,FPU,ND
- FDIVRP fpureg 8086,FPU
- FDIVRP fpureg,fpu0 8086,FPU
- FDIVRP 8086,FPU,ND
- FEMMS PENT,3DNOW
- FENI 8086,FPU
- FFREE fpureg 8086,FPU
- FFREE 8086,FPU
- FFREEP fpureg 286,FPU,UNDOC
- FFREEP 286,FPU,UNDOC
- FIADD mem32 8086,FPU
- FIADD mem16 8086,FPU
- FICOM mem32 8086,FPU
- FICOM mem16 8086,FPU
- FICOMP mem32 8086,FPU
- FICOMP mem16 8086,FPU
- FIDIV mem32 8086,FPU
- FIDIV mem16 8086,FPU
- FIDIVR mem32 8086,FPU
- FIDIVR mem16 8086,FPU
- FILD mem32 8086,FPU
- FILD mem16 8086,FPU
- FILD mem64 8086,FPU
- FIMUL mem32 8086,FPU
- FIMUL mem16 8086,FPU
- FINCSTP 8086,FPU
- FINIT 8086,FPU
- FIST mem32 8086,FPU
- FIST mem16 8086,FPU
- FISTP mem32 8086,FPU
- FISTP mem16 8086,FPU
- FISTP mem64 8086,FPU
- FISTTP mem16 PRESCOTT,FPU
- FISTTP mem32 PRESCOTT,FPU
- FISTTP mem64 PRESCOTT,FPU
- FISUB mem32 8086,FPU
- FISUB mem16 8086,FPU
- FISUBR mem32 8086,FPU
- FISUBR mem16 8086,FPU
- FLD mem32 8086,FPU
- FLD mem64 8086,FPU
- FLD mem80 8086,FPU
- FLD fpureg 8086,FPU
- FLD 8086,FPU,ND
- FLD1 8086,FPU
- FLDCW mem 8086,FPU,SW
- FLDENV mem 8086,FPU
- FLDL2E 8086,FPU
- FLDL2T 8086,FPU
- FLDLG2 8086,FPU
- FLDLN2 8086,FPU
- FLDPI 8086,FPU
- FLDZ 8086,FPU
- FMUL mem32 8086,FPU
- FMUL mem64 8086,FPU
- FMUL fpureg|to 8086,FPU
- FMUL fpureg,fpu0 8086,FPU
- FMUL fpureg 8086,FPU
- FMUL fpu0,fpureg 8086,FPU
- FMUL 8086,FPU,ND
- FMULP fpureg 8086,FPU
- FMULP fpureg,fpu0 8086,FPU
- FMULP 8086,FPU,ND
- FNCLEX 8086,FPU
- FNDISI 8086,FPU
- FNENI 8086,FPU
- FNINIT 8086,FPU
- FNOP 8086,FPU
- FNSAVE mem 8086,FPU
- FNSTCW mem 8086,FPU,SW
- FNSTENV mem 8086,FPU
- FNSTSW mem 8086,FPU,SW
- FNSTSW reg_ax 286,FPU
- FPATAN 8086,FPU
- FPREM 8086,FPU
- FPREM1 386,FPU
- FPTAN 8086,FPU
- FRNDINT 8086,FPU
- FRSTOR mem 8086,FPU
- FSAVE mem 8086,FPU
- FSCALE 8086,FPU
- FSETPM 286,FPU
- FSIN 386,FPU
- FSINCOS 386,FPU
- FSQRT 8086,FPU
- FST mem32 8086,FPU
- FST mem64 8086,FPU
- FST fpureg 8086,FPU
- FST 8086,FPU,ND
- FSTCW mem 8086,FPU,SW
- FSTENV mem 8086,FPU
- FSTP mem32 8086,FPU
- FSTP mem64 8086,FPU
- FSTP mem80 8086,FPU
- FSTP fpureg 8086,FPU
- FSTP 8086,FPU,ND
- FSTSW mem 8086,FPU,SW
- FSTSW reg_ax 286,FPU
- FSUB mem32 8086,FPU
- FSUB mem64 8086,FPU
- FSUB fpureg|to 8086,FPU
- FSUB fpureg,fpu0 8086,FPU
- FSUB fpureg 8086,FPU
- FSUB fpu0,fpureg 8086,FPU
- FSUB 8086,FPU,ND
- FSUBP fpureg 8086,FPU
- FSUBP fpureg,fpu0 8086,FPU
- FSUBP 8086,FPU,ND
- FSUBR mem32 8086,FPU
- FSUBR mem64 8086,FPU
- FSUBR fpureg|to 8086,FPU
- FSUBR fpureg,fpu0 8086,FPU
- FSUBR fpureg 8086,FPU
- FSUBR fpu0,fpureg 8086,FPU
- FSUBR 8086,FPU,ND
- FSUBRP fpureg 8086,FPU
- FSUBRP fpureg,fpu0 8086,FPU
- FSUBRP 8086,FPU,ND
- FTST 8086,FPU
- FUCOM fpureg 386,FPU
- FUCOM fpu0,fpureg 386,FPU
- FUCOM 386,FPU,ND
- FUCOMI fpureg P6,FPU
- FUCOMI fpu0,fpureg P6,FPU
- FUCOMI P6,FPU,ND
- FUCOMIP fpureg P6,FPU
- FUCOMIP fpu0,fpureg P6,FPU
- FUCOMIP P6,FPU,ND
- FUCOMP fpureg 386,FPU
- FUCOMP fpu0,fpureg 386,FPU
- FUCOMP 386,FPU,ND
- FUCOMPP 386,FPU
- FXAM 8086,FPU
- FXCH fpureg 8086,FPU
- FXCH fpureg,fpu0 8086,FPU
- FXCH fpu0,fpureg 8086,FPU
- FXCH 8086,FPU,ND
- FXTRACT 8086,FPU
- FYL2X 8086,FPU
- FYL2XP1 8086,FPU
- HLT 8086,PRIV
- IBTS mem,reg16 386,SW,UNDOC,ND
- IBTS reg16,reg16 386,UNDOC,ND
- IBTS mem,reg32 386,SD,UNDOC,ND
- IBTS reg32,reg32 386,UNDOC,ND
- ICEBP 386,ND
- IDIV rm8 8086
- IDIV rm16 8086
- IDIV rm32 386
- IDIV rm64 X64
- IMUL rm8 8086
- IMUL rm16 8086
- IMUL rm32 386
- IMUL rm64 X64
- IMUL reg16,mem 386
- IMUL reg16,reg16 386
- IMUL reg32,mem 386
- IMUL reg32,reg32 386
- IMUL reg64,mem X64
- IMUL reg64,reg64 X64
- IMUL reg16,mem,imm8 186
- IMUL reg16,mem,sbyte16 186,ND
- IMUL reg16,mem,imm16 186
- IMUL reg16,mem,imm 186,ND
- IMUL reg16,reg16,imm8 186
- IMUL reg16,reg16,sbyte16 186,ND
- IMUL reg16,reg16,imm16 186
- IMUL reg16,reg16,imm 186,ND
- IMUL reg32,mem,imm8 386
- IMUL reg32,mem,sbyte32 386,ND
- IMUL reg32,mem,imm32 386
- IMUL reg32,mem,imm 386,ND
- IMUL reg32,reg32,imm8 386
- IMUL reg32,reg32,sbyte32 386,ND
- IMUL reg32,reg32,imm32 386
- IMUL reg32,reg32,imm 386,ND
- IMUL reg64,mem,imm8 X64
- IMUL reg64,mem,sbyte64 X64,ND
- IMUL reg64,mem,imm32 X64
- IMUL reg64,mem,imm X64,ND
- IMUL reg64,reg64,imm8 X64
- IMUL reg64,reg64,sbyte64 X64,ND
- IMUL reg64,reg64,imm32 X64
- IMUL reg64,reg64,imm X64,ND
- IMUL reg16,imm8 186
- IMUL reg16,sbyte16 186,ND
- IMUL reg16,imm16 186
- IMUL reg16,imm 186,ND
- IMUL reg32,imm8 386
- IMUL reg32,sbyte32 386,ND
- IMUL reg32,imm32 386
- IMUL reg32,imm 386,ND
- IMUL reg64,imm8 X64
- IMUL reg64,sbyte64 X64,ND
- IMUL reg64,imm32 X64
- IMUL reg64,imm X64,ND
- IN reg_al,imm 8086
- IN reg_ax,imm 8086
- IN reg_eax,imm 386
- IN reg_al,reg_dx 8086
- IN reg_ax,reg_dx 8086
- IN reg_eax,reg_dx 386
- INC reg16 8086,NOLONG
- INC reg32 386,NOLONG
- INC rm8 8086
- INC rm16 8086
- INC rm32 386
- INC rm64 X64
- INCBIN
- INSB 186
- INSD 386
- INSW 186
- INT imm 8086
- INT01 386,ND
- INT1 386
- INT03 8086,ND
- INT3 8086
- INTO 8086,NOLONG
- INVD 486,PRIV
- INVLPG mem 486,PRIV
- INVLPGA reg_ax,reg_ecx X86_64,AMD,NOLONG
- INVLPGA reg_eax,reg_ecx X86_64,AMD
- INVLPGA reg_rax,reg_ecx X64,AMD
- INVLPGA X86_64,AMD
- IRET 8086
- IRETD 386
- IRETQ X64
- IRETW 8086
- JCXZ imm 8086,NOLONG
- JECXZ imm 386
- JRCXZ imm X64
- JMP imm|short 8086
- JMP imm 8086,ND
- JMP imm 8086
- JMP imm|near 8086,ND
- JMP imm|far 8086,ND,NOLONG
- JMP imm16 8086
- JMP imm16|near 8086,ND
- JMP imm16|far 8086,ND,NOLONG
- JMP imm32 386
- JMP imm32|near 386,ND
- JMP imm32|far 386,ND,NOLONG
- JMP imm:imm 8086,NOLONG
- JMP imm16:imm 8086,NOLONG
- JMP imm:imm16 8086,NOLONG
- JMP imm32:imm 386,NOLONG
- JMP imm:imm32 386,NOLONG
- JMP mem|far 8086,NOLONG
- JMP mem|far X64
- JMP mem16|far 8086
- JMP mem32|far 386
- JMP mem64|far X64
- JMP mem|near 8086
- JMP mem16|near 8086
- JMP mem32|near 386,NOLONG
- JMP mem64|near X64
- JMP reg16 8086
- JMP reg32 386,NOLONG
- JMP reg64 X64
- JMP mem 8086
- JMP mem16 8086
- JMP mem32 386,NOLONG
- JMP mem64 X64
- JMPE imm IA64
- JMPE imm16 IA64
- JMPE imm32 IA64
- JMPE rm16 IA64
- JMPE rm32 IA64
- LAHF 8086
- LAR reg16,mem 286,PROT,SW
- LAR reg16,reg16 286,PROT
- LAR reg16,reg32 386,PROT
- LAR reg16,reg64 X64,PROT,ND
- LAR reg32,mem 386,PROT,SW
- LAR reg32,reg16 386,PROT
- LAR reg32,reg32 386,PROT
- LAR reg32,reg64 X64,PROT,ND
- LAR reg64,mem X64,PROT,SW
- LAR reg64,reg16 X64,PROT
- LAR reg64,reg32 X64,PROT
- LAR reg64,reg64 X64,PROT
- LDS reg16,mem 8086,NOLONG
- LDS reg32,mem 386,NOLONG
- LEA reg16,mem 8086
- LEA reg32,mem 386
- LEA reg64,mem X64
- LEAVE 186
- LES reg16,mem 8086,NOLONG
- LES reg32,mem 386,NOLONG
- LFENCE X64,AMD
- LFS reg16,mem 386
- LFS reg32,mem 386
- LGDT mem 286,PRIV
- LGS reg16,mem 386
- LGS reg32,mem 386
- LIDT mem 286,PRIV
- LLDT mem 286,PROT,PRIV
- LLDT mem16 286,PROT,PRIV
- LLDT reg16 286,PROT,PRIV
- LMSW mem 286,PRIV
- LMSW mem16 286,PRIV
- LMSW reg16 286,PRIV
- LOADALL 386,UNDOC
- LOADALL286 286,UNDOC
- LODSB 8086
- LODSD 386
- LODSQ X64
- LODSW 8086
- LOOP imm 8086
- LOOP imm,reg_cx 8086,NOLONG
- LOOP imm,reg_ecx 386
- LOOP imm,reg_rcx X64
- LOOPE imm 8086
- LOOPE imm,reg_cx 8086,NOLONG
- LOOPE imm,reg_ecx 386
- LOOPE imm,reg_rcx X64
- LOOPNE imm 8086
- LOOPNE imm,reg_cx 8086,NOLONG
- LOOPNE imm,reg_ecx 386
- LOOPNE imm,reg_rcx X64
- LOOPNZ imm 8086
- LOOPNZ imm,reg_cx 8086,NOLONG
- LOOPNZ imm,reg_ecx 386
- LOOPNZ imm,reg_rcx X64
- LOOPZ imm 8086
- LOOPZ imm,reg_cx 8086,NOLONG
- LOOPZ imm,reg_ecx 386
- LOOPZ imm,reg_rcx X64
- LSL reg16,mem 286,PROT,SW
- LSL reg16,reg16 286,PROT
- LSL reg16,reg32 386,PROT
- LSL reg16,reg64 X64,PROT,ND
- LSL reg32,mem 386,PROT,SW
- LSL reg32,reg16 386,PROT
- LSL reg32,reg32 386,PROT
- LSL reg32,reg64 X64,PROT,ND
- LSL reg64,mem X64,PROT,SW
- LSL reg64,reg16 X64,PROT
- LSL reg64,reg32 X64,PROT
- LSL reg64,reg64 X64,PROT
- LSS reg16,mem 386
- LSS reg32,mem 386
- LTR mem 286,PROT,PRIV
- LTR mem16 286,PROT,PRIV
- LTR reg16 286,PROT,PRIV
- MFENCE X64,AMD
- MONITOR PRESCOTT
- MONITOR reg_eax,reg_ecx,reg_edx PRESCOTT,ND
- MONITOR reg_rax,reg_ecx,reg_edx X64,ND
- MOV mem,reg_sreg 8086
- MOV reg16,reg_sreg 8086
- MOV reg32,reg_sreg 386
- MOV reg_sreg,mem 8086
- MOV reg_sreg,reg16 8086
- MOV reg_sreg,reg32 386
- MOV reg_al,mem_offs 8086
- MOV reg_ax,mem_offs 8086
- MOV reg_eax,mem_offs 386
- MOV reg_rax,mem_offs X64
- MOV mem_offs,reg_al 8086
- MOV mem_offs,reg_ax 8086
- MOV mem_offs,reg_eax 386
- MOV mem_offs,reg_rax X64
- MOV reg32,reg_creg 386,PRIV,NOLONG
- MOV reg64,reg_creg X64,PRIV
- MOV reg_creg,reg32 386,PRIV,NOLONG
- MOV reg_creg,reg64 X64,PRIV
- MOV reg32,reg_dreg 386,PRIV,NOLONG
- MOV reg64,reg_dreg X64,PRIV
- MOV reg_dreg,reg32 386,PRIV,NOLONG
- MOV reg_dreg,reg64 X64,PRIV
- MOV reg32,reg_treg 386,NOLONG,ND
- MOV reg_treg,reg32 386,NOLONG,ND
- MOV mem,reg8 8086
- MOV reg8,reg8 8086
- MOV mem,reg16 8086
- MOV reg16,reg16 8086
- MOV mem,reg32 386
- MOV reg32,reg32 386
- MOV mem,reg64 X64
- MOV reg64,reg64 X64
- MOV reg8,mem 8086
- MOV reg8,reg8 8086
- MOV reg16,mem 8086
- MOV reg16,reg16 8086
- MOV reg32,mem 386
- MOV reg32,reg32 386
- MOV reg64,mem X64
- MOV reg64,reg64 X64
- MOV reg8,imm 8086
- MOV reg16,imm 8086
- MOV reg32,imm 386
- MOV reg64,imm X64
- MOV reg64,imm32 X64
- MOV rm8,imm 8086
- MOV rm16,imm 8086
- MOV rm32,imm 386
- MOV rm64,imm X64
- MOV mem,imm8 8086
- MOV mem,imm16 8086
- MOV mem,imm32 386
- MOVD mmxreg,mem PENT,MMX,SD
- MOVD mmxreg,reg32 PENT,MMX
- MOVD mem,mmxreg PENT,MMX,SD
- MOVD reg32,mmxreg PENT,MMX
- MOVD xmmreg,mem X64,SD
- MOVD xmmreg,reg32 X64
- MOVD mem,xmmreg X64,SD
- MOVD reg32,xmmreg X64,SSE
- MOVQ mmxreg,mmxrm PENT,MMX
- MOVQ mmxrm,mmxreg PENT,MMX
- MOVQ mmxreg,rm64 X64,MMX
- MOVQ rm64,mmxreg X64,MMX
- MOVSB 8086
- MOVSD 386
- MOVSQ X64
- MOVSW 8086
- MOVSX reg16,mem 386
- MOVSX reg16,reg8 386
- MOVSX reg32,rm8 386
- MOVSX reg32,rm16 386
- MOVSX reg64,rm8 X64
- MOVSX reg64,rm16 X64
- MOVSXD reg64,rm32 X64
- MOVSX reg64,rm32 X64,ND
- MOVZX reg16,mem 386
- MOVZX reg16,reg8 386
- MOVZX reg32,rm8 386
- MOVZX reg32,rm16 386
- MOVZX reg64,rm8 X64
- MOVZX reg64,rm16 X64
- MUL rm8 8086
- MUL rm16 8086
- MUL rm32 386
- MUL rm64 X64
- MWAIT PRESCOTT
- MWAIT reg_eax,reg_ecx PRESCOTT,ND
- NEG rm8 8086
- NEG rm16 8086
- NEG rm32 386
- NEG rm64 X64
- NOP 8086
- NOP rm16 P6
- NOP rm32 P6
- NOP rm64 X64
- NOT rm8 8086
- NOT rm16 8086
- NOT rm32 386
- NOT rm64 X64
- OR mem,reg8 8086
- OR reg8,reg8 8086
- OR mem,reg16 8086
- OR reg16,reg16 8086
- OR mem,reg32 386
- OR reg32,reg32 386
- OR mem,reg64 X64
- OR reg64,reg64 X64
- OR reg8,mem 8086
- OR reg8,reg8 8086
- OR reg16,mem 8086
- OR reg16,reg16 8086
- OR reg32,mem 386
- OR reg32,reg32 386
- OR reg64,mem X64
- OR reg64,reg64 X64
- OR rm16,imm8 8086
- OR rm32,imm8 386
- OR rm64,imm8 X64
- OR reg_al,imm 8086
- OR reg_ax,sbyte16 8086
- OR reg_ax,imm 8086
- OR reg_eax,sbyte32 386
- OR reg_eax,imm 386
- OR reg_rax,sbyte64 X64
- OR reg_rax,imm X64
- OR rm8,imm 8086
- OR rm16,imm 8086
- OR rm32,imm 386
- OR rm64,imm X64
- OR mem,imm8 8086
- OR mem,imm16 8086
- OR mem,imm32 386
- OUT imm,reg_al 8086
- OUT imm,reg_ax 8086
- OUT imm,reg_eax 386
- OUT reg_dx,reg_al 8086
- OUT reg_dx,reg_ax 8086
- OUT reg_dx,reg_eax 386
- OUTSB 186
- OUTSD 386
- OUTSW 186
- PACKSSDW mmxreg,mmxrm PENT,MMX
- PACKSSWB mmxreg,mmxrm PENT,MMX
- PACKUSWB mmxreg,mmxrm PENT,MMX
- PADDB mmxreg,mmxrm PENT,MMX
- PADDD mmxreg,mmxrm PENT,MMX
- PADDSB mmxreg,mmxrm PENT,MMX
- PADDSIW mmxreg,mmxrm PENT,MMX,CYRIX
- PADDSW mmxreg,mmxrm PENT,MMX
- PADDUSB mmxreg,mmxrm PENT,MMX
- PADDUSW mmxreg,mmxrm PENT,MMX
- PADDW mmxreg,mmxrm PENT,MMX
- PAND mmxreg,mmxrm PENT,MMX
- PANDN mmxreg,mmxrm PENT,MMX
- PAUSE 8086
- PAVEB mmxreg,mmxrm PENT,MMX,CYRIX
- PAVGUSB mmxreg,mmxrm PENT,3DNOW
- PCMPEQB mmxreg,mmxrm PENT,MMX
- PCMPEQD mmxreg,mmxrm PENT,MMX
- PCMPEQW mmxreg,mmxrm PENT,MMX
- PCMPGTB mmxreg,mmxrm PENT,MMX
- PCMPGTD mmxreg,mmxrm PENT,MMX
- PCMPGTW mmxreg,mmxrm PENT,MMX
- PDISTIB mmxreg,mem PENT,MMX,CYRIX
- PF2ID mmxreg,mmxrm PENT,3DNOW
- PFACC mmxreg,mmxrm PENT,3DNOW
- PFADD mmxreg,mmxrm PENT,3DNOW
- PFCMPEQ mmxreg,mmxrm PENT,3DNOW
- PFCMPGE mmxreg,mmxrm PENT,3DNOW
- PFCMPGT mmxreg,mmxrm PENT,3DNOW
- PFMAX mmxreg,mmxrm PENT,3DNOW
- PFMIN mmxreg,mmxrm PENT,3DNOW
- PFMUL mmxreg,mmxrm PENT,3DNOW
- PFRCP mmxreg,mmxrm PENT,3DNOW
- PFRCPIT1 mmxreg,mmxrm PENT,3DNOW
- PFRCPIT2 mmxreg,mmxrm PENT,3DNOW
- PFRSQIT1 mmxreg,mmxrm PENT,3DNOW
- PFRSQRT mmxreg,mmxrm PENT,3DNOW
- PFSUB mmxreg,mmxrm PENT,3DNOW
- PFSUBR mmxreg,mmxrm PENT,3DNOW
- PI2FD mmxreg,mmxrm PENT,3DNOW
- PMACHRIW mmxreg,mem PENT,MMX,CYRIX
- PMADDWD mmxreg,mmxrm PENT,MMX
- PMAGW mmxreg,mmxrm PENT,MMX,CYRIX
- PMULHRIW mmxreg,mmxrm PENT,MMX,CYRIX
- PMULHRWA mmxreg,mmxrm PENT,3DNOW
- PMULHRWC mmxreg,mmxrm PENT,MMX,CYRIX
- PMULHW mmxreg,mmxrm PENT,MMX
- PMULLW mmxreg,mmxrm PENT,MMX
- PMVGEZB mmxreg,mem PENT,MMX,CYRIX
- PMVLZB mmxreg,mem PENT,MMX,CYRIX
- PMVNZB mmxreg,mem PENT,MMX,CYRIX
- PMVZB mmxreg,mem PENT,MMX,CYRIX
- POP reg16 8086
- POP reg32 386,NOLONG
- POP reg64 X64
- POP rm16 8086
- POP rm32 386,NOLONG
- POP rm64 X64
- POP reg_cs 8086,UNDOC,ND
- POP reg_dess 8086,NOLONG
- POP reg_fsgs 386
- POPA 186,NOLONG
- POPAD 386,NOLONG
- POPAW 186,NOLONG
- POPF 8086
- POPFD 386,NOLONG
- POPFQ X64
- POPFW 8086
- POR mmxreg,mmxrm PENT,MMX
- PREFETCH mem PENT,3DNOW
- PREFETCHW mem PENT,3DNOW
- PSLLD mmxreg,mmxrm PENT,MMX
- PSLLD mmxreg,imm PENT,MMX
- PSLLQ mmxreg,mmxrm PENT,MMX
- PSLLQ mmxreg,imm PENT,MMX
- PSLLW mmxreg,mmxrm PENT,MMX
- PSLLW mmxreg,imm PENT,MMX
- PSRAD mmxreg,mmxrm PENT,MMX
- PSRAD mmxreg,imm PENT,MMX
- PSRAW mmxreg,mmxrm PENT,MMX
- PSRAW mmxreg,imm PENT,MMX
- PSRLD mmxreg,mmxrm PENT,MMX
- PSRLD mmxreg,imm PENT,MMX
- PSRLQ mmxreg,mmxrm PENT,MMX
- PSRLQ mmxreg,imm PENT,MMX
- PSRLW mmxreg,mmxrm PENT,MMX
- PSRLW mmxreg,imm PENT,MMX
- PSUBB mmxreg,mmxrm PENT,MMX
- PSUBD mmxreg,mmxrm PENT,MMX
- PSUBSB mmxreg,mmxrm PENT,MMX
- PSUBSIW mmxreg,mmxrm PENT,MMX,CYRIX
- PSUBSW mmxreg,mmxrm PENT,MMX
- PSUBUSB mmxreg,mmxrm PENT,MMX
- PSUBUSW mmxreg,mmxrm PENT,MMX
- PSUBW mmxreg,mmxrm PENT,MMX
- PUNPCKHBW mmxreg,mmxrm PENT,MMX
- PUNPCKHDQ mmxreg,mmxrm PENT,MMX
- PUNPCKHWD mmxreg,mmxrm PENT,MMX
- PUNPCKLBW mmxreg,mmxrm PENT,MMX
- PUNPCKLDQ mmxreg,mmxrm PENT,MMX
- PUNPCKLWD mmxreg,mmxrm PENT,MMX
- PUSH reg16 8086
- PUSH reg32 386,NOLONG
- PUSH reg64 X64
- PUSH rm16 8086
- PUSH rm32 386,NOLONG
- PUSH rm64 X64
- PUSH reg_cs 8086,NOLONG
- PUSH reg_dess 8086,NOLONG
- PUSH reg_fsgs 386
- PUSH imm8 186
- PUSH imm16 186,AR0,SZ
- PUSH imm32 386,NOLONG,AR0,SZ
- PUSH imm32 386,NOLONG,SD
- PUSH imm64 X64,AR0,SZ
- PUSHA 186,NOLONG
- PUSHAD 386,NOLONG
- PUSHAW 186,NOLONG
- PUSHF 8086
- PUSHFD 386,NOLONG
- PUSHFQ X64
- PUSHFW 8086
- PXOR mmxreg,mmxrm PENT,MMX
- RCL rm8,unity 8086
- RCL rm8,reg_cl 8086
- RCL rm8,imm 186
- RCL rm16,unity 8086
- RCL rm16,reg_cl 8086
- RCL rm16,imm 186
- RCL rm32,unity 386
- RCL rm32,reg_cl 386
- RCL rm32,imm 386
- RCL rm64,unity X64
- RCL rm64,reg_cl X64
- RCL rm64,imm X64
- RCR rm8,unity 8086
- RCR rm8,reg_cl 8086
- RCR rm8,imm 186
- RCR rm16,unity 8086
- RCR rm16,reg_cl 8086
- RCR rm16,imm 186
- RCR rm32,unity 386
- RCR rm32,reg_cl 386
- RCR rm32,imm 386
- RCR rm64,unity X64
- RCR rm64,reg_cl X64
- RCR rm64,imm X64
- RDSHR rm32 P6,CYRIXM
- RDMSR PENT,PRIV
- RDPMC P6
- RDTSC PENT
- RDTSCP X86_64
- RET 8086
- RET imm 8086,SW
- RETF 8086
- RETF imm 8086,SW
- RETN 8086
- RETN imm 8086,SW
- ROL rm8,unity 8086
- ROL rm8,reg_cl 8086
- ROL rm8,imm 186
- ROL rm16,unity 8086
- ROL rm16,reg_cl 8086
- ROL rm16,imm 186
- ROL rm32,unity 386
- ROL rm32,reg_cl 386
- ROL rm32,imm 386
- ROL rm64,unity X64
- ROL rm64,reg_cl X64
- ROL rm64,imm X64
- ROR rm8,unity 8086
- ROR rm8,reg_cl 8086
- ROR rm8,imm 186
- ROR rm16,unity 8086
- ROR rm16,reg_cl 8086
- ROR rm16,imm 186
- ROR rm32,unity 386
- ROR rm32,reg_cl 386
- ROR rm32,imm 386
- ROR rm64,unity X64
- ROR rm64,reg_cl X64
- ROR rm64,imm X64
- RDM P6,CYRIX,ND
- RSDC reg_sreg,mem80 486,CYRIXM
- RSLDT mem80 486,CYRIXM
- RSM PENTM
- RSTS mem80 486,CYRIXM
- SAHF 8086
- SAL rm8,unity 8086,ND
- SAL rm8,reg_cl 8086,ND
- SAL rm8,imm 186,ND
- SAL rm16,unity 8086,ND
- SAL rm16,reg_cl 8086,ND
- SAL rm16,imm 186,ND
- SAL rm32,unity 386,ND
- SAL rm32,reg_cl 386,ND
- SAL rm32,imm 386,ND
- SAL rm64,unity X64,ND
- SAL rm64,reg_cl X64,ND
- SAL rm64,imm X64,ND
- SALC 8086,UNDOC
- SAR rm8,unity 8086
- SAR rm8,reg_cl 8086
- SAR rm8,imm 186
- SAR rm16,unity 8086
- SAR rm16,reg_cl 8086
- SAR rm16,imm 186
- SAR rm32,unity 386
- SAR rm32,reg_cl 386
- SAR rm32,imm 386
- SAR rm64,unity X64
- SAR rm64,reg_cl X64
- SAR rm64,imm X64
- SBB mem,reg8 8086
- SBB reg8,reg8 8086
- SBB mem,reg16 8086
- SBB reg16,reg16 8086
- SBB mem,reg32 386
- SBB reg32,reg32 386
- SBB mem,reg64 X64
- SBB reg64,reg64 X64
- SBB reg8,mem 8086
- SBB reg8,reg8 8086
- SBB reg16,mem 8086
- SBB reg16,reg16 8086
- SBB reg32,mem 386
- SBB reg32,reg32 386
- SBB reg64,mem X64
- SBB reg64,reg64 X64
- SBB rm16,imm8 8086
- SBB rm32,imm8 386
- SBB rm64,imm8 X64
- SBB reg_al,imm 8086
- SBB reg_ax,sbyte16 8086
- SBB reg_ax,imm 8086
- SBB reg_eax,sbyte32 386
- SBB reg_eax,imm 386
- SBB reg_rax,sbyte64 X64
- SBB reg_rax,imm X64
- SBB rm8,imm 8086
- SBB rm16,imm 8086
- SBB rm32,imm 386
- SBB rm64,imm X64
- SBB mem,imm8 8086
- SBB mem,imm16 8086
- SBB mem,imm32 386
- SCASB 8086
- SCASD 386
- SCASQ X64
- SCASW 8086
- SFENCE X64,AMD
- SGDT mem 286
- SHL rm8,unity 8086
- SHL rm8,reg_cl 8086
- SHL rm8,imm 186
- SHL rm16,unity 8086
- SHL rm16,reg_cl 8086
- SHL rm16,imm 186
- SHL rm32,unity 386
- SHL rm32,reg_cl 386
- SHL rm32,imm 386
- SHL rm64,unity X64
- SHL rm64,reg_cl X64
- SHL rm64,imm X64
- SHLD mem,reg16,imm 3862
- SHLD reg16,reg16,imm 3862
- SHLD mem,reg32,imm 3862
- SHLD reg32,reg32,imm 3862
- SHLD mem,reg64,imm X642
- SHLD reg64,reg64,imm X642
- SHLD mem,reg16,reg_cl 386
- SHLD reg16,reg16,reg_cl 386
- SHLD mem,reg32,reg_cl 386
- SHLD reg32,reg32,reg_cl 386
- SHLD mem,reg64,reg_cl X64
- SHLD reg64,reg64,reg_cl X64
- SHR rm8,unity 8086
- SHR rm8,reg_cl 8086
- SHR rm8,imm 186
- SHR rm16,unity 8086
- SHR rm16,reg_cl 8086
- SHR rm16,imm 186
- SHR rm32,unity 386
- SHR rm32,reg_cl 386
- SHR rm32,imm 386
- SHR rm64,unity X64
- SHR rm64,reg_cl X64
- SHR rm64,imm X64
- SHRD mem,reg16,imm 3862
- SHRD reg16,reg16,imm 3862
- SHRD mem,reg32,imm 3862
- SHRD reg32,reg32,imm 3862
- SHRD mem,reg64,imm X642
- SHRD reg64,reg64,imm X642
- SHRD mem,reg16,reg_cl 386
- SHRD reg16,reg16,reg_cl 386
- SHRD mem,reg32,reg_cl 386
- SHRD reg32,reg32,reg_cl 386
- SHRD mem,reg64,reg_cl X64
- SHRD reg64,reg64,reg_cl X64
- SIDT mem 286
- SLDT mem 286
- SLDT mem16 286
- SLDT reg16 286
- SLDT reg32 386
- SLDT reg64 X64,ND
- SLDT reg64 X64
- SKINIT X64
- SMI 386,UNDOC
- SMINT P6,CYRIX,ND
- SMINTOLD 486,CYRIX,ND
- SMSW mem 286
- SMSW mem16 286
- SMSW reg16 286
- SMSW reg32 386
- STC 8086
- STD 8086
- STGI X64
- STI 8086
- STOSB 8086
- STOSD 386
- STOSQ X64
- STOSW 8086
- STR mem 286,PROT
- STR mem16 286,PROT
- STR reg16 286,PROT
- STR reg32 386,PROT
- STR reg64 X64
- SUB mem,reg8 8086
- SUB reg8,reg8 8086
- SUB mem,reg16 8086
- SUB reg16,reg16 8086
- SUB mem,reg32 386
- SUB reg32,reg32 386
- SUB mem,reg64 X64
- SUB reg64,reg64 X64
- SUB reg8,mem 8086
- SUB reg8,reg8 8086
- SUB reg16,mem 8086
- SUB reg16,reg16 8086
- SUB reg32,mem 386
- SUB reg32,reg32 386
- SUB reg64,mem X64
- SUB reg64,reg64 X64
- SUB rm16,imm8 8086
- SUB rm32,imm8 386
- SUB rm64,imm8 X64
- SUB reg_al,imm 8086
- SUB reg_ax,sbyte16 8086
- SUB reg_ax,imm 8086
- SUB reg_eax,sbyte32 386
- SUB reg_eax,imm 386
- SUB reg_rax,sbyte64 X64
- SUB reg_rax,imm X64
- SUB rm8,imm 8086
- SUB rm16,imm 8086
- SUB rm32,imm 386
- SUB rm64,imm X64
- SUB mem,imm8 8086
- SUB mem,imm16 8086
- SUB mem,imm32 386
- SVDC mem80,reg_sreg 486,CYRIXM
- SVLDT mem80 486,CYRIXM,ND
- SVTS mem80 486,CYRIXM
- SWAPGS X64
- SYSCALL P6,AMD
- SYSENTER P6
- SYSEXIT P6,PRIV
- SYSRET P6,PRIV,AMD
- TEST mem,reg8 8086
- TEST reg8,reg8 8086
- TEST mem,reg16 8086
- TEST reg16,reg16 8086
- TEST mem,reg32 386
- TEST reg32,reg32 386
- TEST mem,reg64 X64
- TEST reg64,reg64 X64
- TEST reg8,mem 8086
- TEST reg16,mem 8086
- TEST reg32,mem 386
- TEST reg64,mem X64
- TEST reg_al,imm 8086
- TEST reg_ax,imm 8086
- TEST reg_eax,imm 386
- TEST reg_rax,imm X64
- TEST rm8,imm 8086
- TEST rm16,imm 8086
- TEST rm32,imm 386
- TEST rm64,imm X64
- TEST mem,imm8 8086
- TEST mem,imm16 8086
- TEST mem,imm32 386
- UD0 186,UNDOC
- UD1 186,UNDOC
- UD2B 186,UNDOC,ND
- UD2 186
- UD2A 186,ND
- UMOV mem,reg8 386,UNDOC,ND
- UMOV reg8,reg8 386,UNDOC,ND
- UMOV mem,reg16 386,UNDOC,ND
- UMOV reg16,reg16 386,UNDOC,ND
- UMOV mem,reg32 386,UNDOC,ND
- UMOV reg32,reg32 386,UNDOC,ND
- UMOV reg8,mem 386,UNDOC,ND
- UMOV reg8,reg8 386,UNDOC,ND
- UMOV reg16,mem 386,UNDOC,ND
- UMOV reg16,reg16 386,UNDOC,ND
- UMOV reg32,mem 386,UNDOC,ND
- UMOV reg32,reg32 386,UNDOC,ND
- VERR mem 286,PROT
- VERR mem16 286,PROT
- VERR reg16 286,PROT
- VERW mem 286,PROT
- VERW mem16 286,PROT
- VERW reg16 286,PROT
- FWAIT 8086
- WBINVD 486,PRIV
- WRSHR rm32 P6,CYRIXM
- WRMSR PENT,PRIV
- XADD mem,reg8 486
- XADD reg8,reg8 486
- XADD mem,reg16 486
- XADD reg16,reg16 486
- XADD mem,reg32 486
- XADD reg32,reg32 486
- XADD mem,reg64 X64
- XADD reg64,reg64 X64
- XBTS reg16,mem 386,SW,UNDOC,ND
- XBTS reg16,reg16 386,UNDOC,ND
- XBTS reg32,mem 386,SD,UNDOC,ND
- XBTS reg32,reg32 386,UNDOC,ND
- XCHG reg_ax,reg16 8086
- XCHG reg_eax,reg32na 386
- XCHG reg_rax,reg64 X64
- XCHG reg16,reg_ax 8086
- XCHG reg32na,reg_eax 386
- XCHG reg64,reg_rax X64
- XCHG reg_eax,reg_eax 386,NOLONG
- XCHG reg8,mem 8086
- XCHG reg8,reg8 8086
- XCHG reg16,mem 8086
- XCHG reg16,reg16 8086
- XCHG reg32,mem 386
- XCHG reg32,reg32 386
- XCHG reg64,mem X64
- XCHG reg64,reg64 X64
- XCHG mem,reg8 8086
- XCHG reg8,reg8 8086
- XCHG mem,reg16 8086
- XCHG reg16,reg16 8086
- XCHG mem,reg32 386
- XCHG reg32,reg32 386
- XCHG mem,reg64 X64
- XCHG reg64,reg64 X64
- XLATB 8086
- XLAT 8086
- XOR mem,reg8 8086
- XOR reg8,reg8 8086
- XOR mem,reg16 8086
- XOR reg16,reg16 8086
- XOR mem,reg32 386
- XOR reg32,reg32 386
- XOR mem,reg64 X64
- XOR reg64,reg64 X64
- XOR reg8,mem 8086
- XOR reg8,reg8 8086
- XOR reg16,mem 8086
- XOR reg16,reg16 8086
- XOR reg32,mem 386
- XOR reg32,reg32 386
- XOR reg64,mem X64
- XOR reg64,reg64 X64
- XOR rm16,imm8 8086
- XOR rm32,imm8 386
- XOR rm64,imm8 X64
- XOR reg_al,imm 8086
- XOR reg_ax,sbyte16 8086
- XOR reg_ax,imm 8086
- XOR reg_eax,sbyte32 386
- XOR reg_eax,imm 386
- XOR reg_rax,sbyte64 X64
- XOR reg_rax,imm X64
- XOR rm8,imm 8086
- XOR rm16,imm 8086
- XOR rm32,imm 386
- XOR rm64,imm X64
- XOR mem,imm8 8086
- XOR mem,imm16 8086
- XOR mem,imm32 386
- CMOVcc reg16,mem P6
- CMOVcc reg16,reg16 P6
- CMOVcc reg32,mem P6
- CMOVcc reg32,reg32 P6
- CMOVcc reg64,mem X64
- CMOVcc reg64,reg64 X64
- Jcc imm|near 386
- Jcc imm16|near 386
- Jcc imm32|near 386
- Jcc imm|short 8086,ND
- Jcc imm 8086,ND
- Jcc imm 386,ND
- Jcc imm 8086,ND
- Jcc imm 8086
- SETcc mem 386
- SETcc reg8 386
-
- B.1.3 Katmai Streaming SIMD instructions (SSE -- a.k.a. KNI, XMM, MMX2)
-
- ADDPS xmmreg,xmmrm KATMAI,SSE
- ADDSS xmmreg,xmmrm KATMAI,SSE,SD
- ANDNPS xmmreg,xmmrm KATMAI,SSE
- ANDPS xmmreg,xmmrm KATMAI,SSE
- CMPEQPS xmmreg,xmmrm KATMAI,SSE
- CMPEQSS xmmreg,xmmrm KATMAI,SSE
- CMPLEPS xmmreg,xmmrm KATMAI,SSE
- CMPLESS xmmreg,xmmrm KATMAI,SSE
- CMPLTPS xmmreg,xmmrm KATMAI,SSE
- CMPLTSS xmmreg,xmmrm KATMAI,SSE
- CMPNEQPS xmmreg,xmmrm KATMAI,SSE
- CMPNEQSS xmmreg,xmmrm KATMAI,SSE
- CMPNLEPS xmmreg,xmmrm KATMAI,SSE
- CMPNLESS xmmreg,xmmrm KATMAI,SSE
- CMPNLTPS xmmreg,xmmrm KATMAI,SSE
- CMPNLTSS xmmreg,xmmrm KATMAI,SSE
- CMPORDPS xmmreg,xmmrm KATMAI,SSE
- CMPORDSS xmmreg,xmmrm KATMAI,SSE
- CMPUNORDPS xmmreg,xmmrm KATMAI,SSE
- CMPUNORDSS xmmreg,xmmrm KATMAI,SSE
- CMPPS xmmreg,mem,imm KATMAI,SSE
- CMPPS xmmreg,xmmreg,imm KATMAI,SSE
- CMPSS xmmreg,mem,imm KATMAI,SSE
- CMPSS xmmreg,xmmreg,imm KATMAI,SSE
- COMISS xmmreg,xmmrm KATMAI,SSE
- CVTPI2PS xmmreg,mmxrm KATMAI,SSE,MMX
- CVTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
- CVTSI2SS xmmreg,mem KATMAI,SSE,SD,AR1,ND
- CVTSI2SS xmmreg,rm32 KATMAI,SSE,SD,AR1
- CVTSI2SS xmmreg,rm64 X64,SSE,AR1
- CVTSS2SI reg32,xmmreg KATMAI,SSE,SD,AR1
- CVTSS2SI reg32,mem KATMAI,SSE,SD,AR1
- CVTSS2SI reg64,xmmreg X64,SSE,SD,AR1
- CVTSS2SI reg64,mem X64,SSE,SD,AR1
- CVTTPS2PI mmxreg,xmmrm KATMAI,SSE,MMX
- CVTTSS2SI reg32,xmmrm KATMAI,SSE,SD,AR1
- CVTTSS2SI reg64,xmmrm X64,SSE,SD,AR1
- DIVPS xmmreg,xmmrm KATMAI,SSE
- DIVSS xmmreg,xmmrm KATMAI,SSE
- LDMXCSR mem KATMAI,SSE,SD
- MAXPS xmmreg,xmmrm KATMAI,SSE
- MAXSS xmmreg,xmmrm KATMAI,SSE
- MINPS xmmreg,xmmrm KATMAI,SSE
- MINSS xmmreg,xmmrm KATMAI,SSE
- MOVAPS xmmreg,mem KATMAI,SSE
- MOVAPS mem,xmmreg KATMAI,SSE
- MOVAPS xmmreg,xmmreg KATMAI,SSE
- MOVAPS xmmreg,xmmreg KATMAI,SSE
- MOVHPS xmmreg,mem KATMAI,SSE
- MOVHPS mem,xmmreg KATMAI,SSE
- MOVLHPS xmmreg,xmmreg KATMAI,SSE
- MOVLPS xmmreg,mem KATMAI,SSE
- MOVLPS mem,xmmreg KATMAI,SSE
- MOVHLPS xmmreg,xmmreg KATMAI,SSE
- MOVMSKPS reg32,xmmreg KATMAI,SSE
- MOVMSKPS reg64,xmmreg X64,SSE
- MOVNTPS mem,xmmreg KATMAI,SSE
- MOVSS xmmreg,mem KATMAI,SSE
- MOVSS mem,xmmreg KATMAI,SSE
- MOVSS xmmreg,xmmreg KATMAI,SSE
- MOVSS xmmreg,xmmreg KATMAI,SSE
- MOVUPS xmmreg,mem KATMAI,SSE
- MOVUPS mem,xmmreg KATMAI,SSE
- MOVUPS xmmreg,xmmreg KATMAI,SSE
- MOVUPS xmmreg,xmmreg KATMAI,SSE
- MULPS xmmreg,xmmrm KATMAI,SSE
- MULSS xmmreg,xmmrm KATMAI,SSE
- ORPS xmmreg,xmmrm KATMAI,SSE
- RCPPS xmmreg,xmmrm KATMAI,SSE
- RCPSS xmmreg,xmmrm KATMAI,SSE
- RSQRTPS xmmreg,xmmrm KATMAI,SSE
- RSQRTSS xmmreg,xmmrm KATMAI,SSE
- SHUFPS xmmreg,mem,imm KATMAI,SSE
- SHUFPS xmmreg,xmmreg,imm KATMAI,SSE
- SQRTPS xmmreg,xmmrm KATMAI,SSE
- SQRTSS xmmreg,xmmrm KATMAI,SSE
- STMXCSR mem KATMAI,SSE,SD
- SUBPS xmmreg,xmmrm KATMAI,SSE
- SUBSS xmmreg,xmmrm KATMAI,SSE
- UCOMISS xmmreg,xmmrm KATMAI,SSE
- UNPCKHPS xmmreg,xmmrm KATMAI,SSE
- UNPCKLPS xmmreg,xmmrm KATMAI,SSE
- XORPS xmmreg,xmmrm KATMAI,SSE
-
- B.1.4 Introduced in Deschutes but necessary for SSE support
-
- FXRSTOR mem P6,SSE,FPU
- FXSAVE mem P6,SSE,FPU
-
- B.1.5 XSAVE group (AVX and extended state)
-
- XGETBV NEHALEM
- XSETBV NEHALEM,PRIV
- XSAVE mem NEHALEM
- XRSTOR mem NEHALEM
-
- B.1.6 Generic memory operations
-
- PREFETCHNTA mem KATMAI
- PREFETCHT0 mem KATMAI
- PREFETCHT1 mem KATMAI
- PREFETCHT2 mem KATMAI
- SFENCE KATMAI
-
- B.1.7 New MMX instructions introduced in Katmai
-
- MASKMOVQ mmxreg,mmxreg KATMAI,MMX
- MOVNTQ mem,mmxreg KATMAI,MMX
- PAVGB mmxreg,mmxrm KATMAI,MMX
- PAVGW mmxreg,mmxrm KATMAI,MMX
- PEXTRW reg32,mmxreg,imm KATMAI,MMX
- PINSRW mmxreg,mem,imm KATMAI,MMX
- PINSRW mmxreg,rm16,imm KATMAI,MMX
- PINSRW mmxreg,reg32,imm KATMAI,MMX
- PMAXSW mmxreg,mmxrm KATMAI,MMX
- PMAXUB mmxreg,mmxrm KATMAI,MMX
- PMINSW mmxreg,mmxrm KATMAI,MMX
- PMINUB mmxreg,mmxrm KATMAI,MMX
- PMOVMSKB reg32,mmxreg KATMAI,MMX
- PMULHUW mmxreg,mmxrm KATMAI,MMX
- PSADBW mmxreg,mmxrm KATMAI,MMX
- PSHUFW mmxreg,mmxrm,imm KATMAI,MMX2
-
- B.1.8 AMD Enhanced 3DNow! (Athlon) instructions
-
- PF2IW mmxreg,mmxrm PENT,3DNOW
- PFNACC mmxreg,mmxrm PENT,3DNOW
- PFPNACC mmxreg,mmxrm PENT,3DNOW
- PI2FW mmxreg,mmxrm PENT,3DNOW
- PSWAPD mmxreg,mmxrm PENT,3DNOW
-
- B.1.9 Willamette SSE2 Cacheability Instructions
-
- MASKMOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
- CLFLUSH mem WILLAMETTE,SSE2
- MOVNTDQ mem,xmmreg WILLAMETTE,SSE2,SO
- MOVNTI mem,reg32 WILLAMETTE,SD
- MOVNTI mem,reg64 X64
- MOVNTPD mem,xmmreg WILLAMETTE,SSE2,SO
- LFENCE WILLAMETTE,SSE2
- MFENCE WILLAMETTE,SSE2
-
-B.1.10 Willamette MMX instructions (SSE2 SIMD Integer Instructions)
-
- MOVD mem,xmmreg WILLAMETTE,SSE2,SD
- MOVD xmmreg,mem WILLAMETTE,SSE2,SD
- MOVD xmmreg,rm32 WILLAMETTE,SSE2
- MOVD rm32,xmmreg WILLAMETTE,SSE2
- MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQA mem,xmmreg WILLAMETTE,SSE2,SO
- MOVDQA xmmreg,mem WILLAMETTE,SSE2,SO
- MOVDQA xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQU mem,xmmreg WILLAMETTE,SSE2,SO
- MOVDQU xmmreg,mem WILLAMETTE,SSE2,SO
- MOVDQU xmmreg,xmmreg WILLAMETTE,SSE2
- MOVDQ2Q mmxreg,xmmreg WILLAMETTE,SSE2
- MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
- MOVQ xmmreg,xmmreg WILLAMETTE,SSE2
- MOVQ mem,xmmreg WILLAMETTE,SSE2
- MOVQ xmmreg,mem WILLAMETTE,SSE2
- MOVQ xmmreg,rm64 X64,SSE2
- MOVQ rm64,xmmreg X64,SSE2
- MOVQ2DQ xmmreg,mmxreg WILLAMETTE,SSE2
- PACKSSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PACKSSDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PACKUSWB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDQ mmxreg,mmxrm WILLAMETTE,MMX
- PADDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PADDUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PAND xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PANDN xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PAVGB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PAVGW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPEQB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPEQW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPEQD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPGTB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPGTW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PCMPGTD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PEXTRW reg32,xmmreg,imm WILLAMETTE,SSE2
- PINSRW xmmreg,reg16,imm WILLAMETTE,SSE2
- PINSRW xmmreg,reg32,imm WILLAMETTE,SSE2,ND
- PINSRW xmmreg,mem,imm WILLAMETTE,SSE2
- PINSRW xmmreg,mem16,imm WILLAMETTE,SSE2
- PMADDWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMAXSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMAXUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMINSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMINUB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMOVMSKB reg32,xmmreg WILLAMETTE,SSE2
- PMULHUW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMULHW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMULLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PMULUDQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
- PMULUDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- POR xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSADBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSHUFD xmmreg,xmmreg,imm WILLAMETTE,SSE2
- PSHUFD xmmreg,mem,imm WILLAMETTE,SSE22
- PSHUFHW xmmreg,xmmreg,imm WILLAMETTE,SSE2
- PSHUFHW xmmreg,mem,imm WILLAMETTE,SSE22
- PSHUFLW xmmreg,xmmreg,imm WILLAMETTE,SSE2
- PSHUFLW xmmreg,mem,imm WILLAMETTE,SSE22
- PSLLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSLLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSLLW xmmreg,imm WILLAMETTE,SSE2,AR1
- PSLLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSLLD xmmreg,imm WILLAMETTE,SSE2,AR1
- PSLLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSLLQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRAW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRAW xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRAD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRAD xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLDQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRLW xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRLD xmmreg,imm WILLAMETTE,SSE2,AR1
- PSRLQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSRLQ xmmreg,imm WILLAMETTE,SSE2,AR1
- PSUBB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBQ mmxreg,mmxrm WILLAMETTE,SSE2,SO
- PSUBQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBUSB xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PSUBUSW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKHQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLBW xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLWD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PUNPCKLQDQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- PXOR xmmreg,xmmrm WILLAMETTE,SSE2,SO
-
-B.1.11 Willamette Streaming SIMD instructions (SSE2)
-
- ADDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- ADDSD xmmreg,xmmrm WILLAMETTE,SSE2
- ANDNPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- ANDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPEQSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPLESD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPLTSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPNEQPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPNEQSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPNLEPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPNLESD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPNLTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPNLTSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPORDSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPUNORDPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CMPUNORDSD xmmreg,xmmrm WILLAMETTE,SSE2
- CMPPD xmmreg,xmmrm,imm WILLAMETTE,SSE22
- CMPSD xmmreg,xmmrm,imm WILLAMETTE,SSE2
- COMISD xmmreg,xmmrm WILLAMETTE,SSE2
- CVTDQ2PD xmmreg,xmmrm WILLAMETTE,SSE2
- CVTDQ2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPD2PS xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPI2PD xmmreg,mmxrm WILLAMETTE,SSE2
- CVTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTPS2PD xmmreg,xmmrm WILLAMETTE,SSE2
- CVTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
- CVTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
- CVTSD2SI reg64,xmmreg X64,SSE2,AR1
- CVTSD2SI reg64,mem X64,SSE2,AR1
- CVTSD2SS xmmreg,xmmrm WILLAMETTE,SSE2
- CVTSI2SD xmmreg,mem WILLAMETTE,SSE2,SD,AR1,ND
- CVTSI2SD xmmreg,rm32 WILLAMETTE,SSE2,SD,AR1
- CVTSI2SD xmmreg,rm64 X64,SSE2,AR1
- CVTSS2SD xmmreg,xmmrm WILLAMETTE,SSE2,SD
- CVTTPD2PI mmxreg,xmmrm WILLAMETTE,SSE2,SO
- CVTTPD2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTTPS2DQ xmmreg,xmmrm WILLAMETTE,SSE2,SO
- CVTTSD2SI reg32,xmmreg WILLAMETTE,SSE2,AR1
- CVTTSD2SI reg32,mem WILLAMETTE,SSE2,AR1
- CVTTSD2SI reg64,xmmreg X64,SSE2,AR1
- CVTTSD2SI reg64,mem X64,SSE2,AR1
- DIVPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- DIVSD xmmreg,xmmrm WILLAMETTE,SSE2
- MAXPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- MAXSD xmmreg,xmmrm WILLAMETTE,SSE2
- MINPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- MINSD xmmreg,xmmrm WILLAMETTE,SSE2
- MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVAPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVAPD mem,xmmreg WILLAMETTE,SSE2,SO
- MOVAPD xmmreg,mem WILLAMETTE,SSE2,SO
- MOVHPD mem,xmmreg WILLAMETTE,SSE2
- MOVHPD xmmreg,mem WILLAMETTE,SSE2
- MOVLPD mem,xmmreg WILLAMETTE,SSE2
- MOVLPD xmmreg,mem WILLAMETTE,SSE2
- MOVMSKPD reg32,xmmreg WILLAMETTE,SSE2
- MOVMSKPD reg64,xmmreg X64,SSE2
- MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVSD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVSD mem,xmmreg WILLAMETTE,SSE2
- MOVSD xmmreg,mem WILLAMETTE,SSE2
- MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVUPD xmmreg,xmmreg WILLAMETTE,SSE2
- MOVUPD mem,xmmreg WILLAMETTE,SSE2,SO
- MOVUPD xmmreg,mem WILLAMETTE,SSE2,SO
- MULPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- MULSD xmmreg,xmmrm WILLAMETTE,SSE2
- ORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- SHUFPD xmmreg,xmmreg,imm WILLAMETTE,SSE2
- SHUFPD xmmreg,mem,imm WILLAMETTE,SSE2
- SQRTPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- SQRTSD xmmreg,xmmrm WILLAMETTE,SSE2
- SUBPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- SUBSD xmmreg,xmmrm WILLAMETTE,SSE2
- UCOMISD xmmreg,xmmrm WILLAMETTE,SSE2
- UNPCKHPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- UNPCKLPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
- XORPD xmmreg,xmmrm WILLAMETTE,SSE2,SO
-
-B.1.12 Prescott New Instructions (SSE3)
-
- ADDSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
- ADDSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
- HADDPD xmmreg,xmmrm PRESCOTT,SSE3,SO
- HADDPS xmmreg,xmmrm PRESCOTT,SSE3,SO
- HSUBPD xmmreg,xmmrm PRESCOTT,SSE3,SO
- HSUBPS xmmreg,xmmrm PRESCOTT,SSE3,SO
- LDDQU xmmreg,mem PRESCOTT,SSE3,SO
- MOVDDUP xmmreg,xmmrm PRESCOTT,SSE3
- MOVSHDUP xmmreg,xmmrm PRESCOTT,SSE3
- MOVSLDUP xmmreg,xmmrm PRESCOTT,SSE3
-
-B.1.13 VMX Instructions
-
- VMCALL VMX
- VMCLEAR mem VMX
- VMLAUNCH VMX
- VMLOAD X64,VMX
- VMMCALL X64,VMX
- VMPTRLD mem VMX
- VMPTRST mem VMX
- VMREAD rm32,reg32 VMX,NOLONG,SD
- VMREAD rm64,reg64 X64,VMX
- VMRESUME VMX
- VMRUN X64,VMX
- VMSAVE X64,VMX
- VMWRITE reg32,rm32 VMX,NOLONG,SD
- VMWRITE reg64,rm64 X64,VMX
- VMXOFF VMX
- VMXON mem VMX
-
-B.1.14 Extended Page Tables VMX instructions
-
- INVEPT reg32,mem VMX,SO,NOLONG
- INVEPT reg64,mem VMX,SO,LONG
- INVVPID reg32,mem VMX,SO,NOLONG
- INVVPID reg64,mem VMX,SO,LONG
-
-B.1.15 Tejas New Instructions (SSSE3)
-
- PABSB mmxreg,mmxrm SSSE3,MMX
- PABSB xmmreg,xmmrm SSSE3
- PABSW mmxreg,mmxrm SSSE3,MMX
- PABSW xmmreg,xmmrm SSSE3
- PABSD mmxreg,mmxrm SSSE3,MMX
- PABSD xmmreg,xmmrm SSSE3
- PALIGNR mmxreg,mmxrm,imm SSSE3,MMX
- PALIGNR xmmreg,xmmrm,imm SSSE3
- PHADDW mmxreg,mmxrm SSSE3,MMX
- PHADDW xmmreg,xmmrm SSSE3
- PHADDD mmxreg,mmxrm SSSE3,MMX
- PHADDD xmmreg,xmmrm SSSE3
- PHADDSW mmxreg,mmxrm SSSE3,MMX
- PHADDSW xmmreg,xmmrm SSSE3
- PHSUBW mmxreg,mmxrm SSSE3,MMX
- PHSUBW xmmreg,xmmrm SSSE3
- PHSUBD mmxreg,mmxrm SSSE3,MMX
- PHSUBD xmmreg,xmmrm SSSE3
- PHSUBSW mmxreg,mmxrm SSSE3,MMX
- PHSUBSW xmmreg,xmmrm SSSE3
- PMADDUBSW mmxreg,mmxrm SSSE3,MMX
- PMADDUBSW xmmreg,xmmrm SSSE3
- PMULHRSW mmxreg,mmxrm SSSE3,MMX
- PMULHRSW xmmreg,xmmrm SSSE3
- PSHUFB mmxreg,mmxrm SSSE3,MMX
- PSHUFB xmmreg,xmmrm SSSE3
- PSIGNB mmxreg,mmxrm SSSE3,MMX
- PSIGNB xmmreg,xmmrm SSSE3
- PSIGNW mmxreg,mmxrm SSSE3,MMX
- PSIGNW xmmreg,xmmrm SSSE3
- PSIGND mmxreg,mmxrm SSSE3,MMX
- PSIGND xmmreg,xmmrm SSSE3
-
-B.1.16 AMD SSE4A
-
- EXTRQ xmmreg,imm,imm SSE4A,AMD
- EXTRQ xmmreg,xmmreg SSE4A,AMD
- INSERTQ xmmreg,xmmreg,imm,imm SSE4A,AMD
- INSERTQ xmmreg,xmmreg SSE4A,AMD
- MOVNTSD mem,xmmreg SSE4A,AMD
- MOVNTSS mem,xmmreg SSE4A,AMD,SD
-
-B.1.17 New instructions in Barcelona
-
- LZCNT reg16,rm16 P6,AMD
- LZCNT reg32,rm32 P6,AMD
- LZCNT reg64,rm64 X64,AMD
-
-B.1.18 Penryn New Instructions (SSE4.1)
-
- BLENDPD xmmreg,xmmrm,imm SSE41
- BLENDPS xmmreg,xmmrm,imm SSE41
- BLENDVPD xmmreg,xmmrm,xmm0 SSE41
- BLENDVPS xmmreg,xmmrm,xmm0 SSE41
- DPPD xmmreg,xmmrm,imm SSE41
- DPPS xmmreg,xmmrm,imm SSE41
- EXTRACTPS rm32,xmmreg,imm SSE41
- EXTRACTPS reg64,xmmreg,imm SSE41,X64
- INSERTPS xmmreg,xmmrm,imm SSE41,SD
- MOVNTDQA xmmreg,mem SSE41
- MPSADBW xmmreg,xmmrm,imm SSE41
- PACKUSDW xmmreg,xmmrm SSE41
- PBLENDVB xmmreg,xmmrm,xmm0 SSE41
- PBLENDW xmmreg,xmmrm,imm SSE41
- PCMPEQQ xmmreg,xmmrm SSE41
- PEXTRB reg32,xmmreg,imm SSE41
- PEXTRB mem8,xmmreg,imm SSE41
- PEXTRB reg64,xmmreg,imm SSE41,X64
- PEXTRD rm32,xmmreg,imm SSE41
- PEXTRQ rm64,xmmreg,imm SSE41,X64
- PEXTRW reg32,xmmreg,imm SSE41
- PEXTRW mem16,xmmreg,imm SSE41
- PEXTRW reg64,xmmreg,imm SSE41,X64
- PHMINPOSUW xmmreg,xmmrm SSE41
- PINSRB xmmreg,mem,imm SSE41
- PINSRB xmmreg,rm8,imm SSE41
- PINSRB xmmreg,reg32,imm SSE41
- PINSRD xmmreg,mem,imm SSE41
- PINSRD xmmreg,rm32,imm SSE41
- PINSRQ xmmreg,mem,imm SSE41,X64
- PINSRQ xmmreg,rm64,imm SSE41,X64
- PMAXSB xmmreg,xmmrm SSE41
- PMAXSD xmmreg,xmmrm SSE41
- PMAXUD xmmreg,xmmrm SSE41
- PMAXUW xmmreg,xmmrm SSE41
- PMINSB xmmreg,xmmrm SSE41
- PMINSD xmmreg,xmmrm SSE41
- PMINUD xmmreg,xmmrm SSE41
- PMINUW xmmreg,xmmrm SSE41
- PMOVSXBW xmmreg,xmmrm SSE41
- PMOVSXBD xmmreg,xmmrm SSE41,SD
- PMOVSXBQ xmmreg,xmmrm SSE41,SW
- PMOVSXWD xmmreg,xmmrm SSE41
- PMOVSXWQ xmmreg,xmmrm SSE41,SD
- PMOVSXDQ xmmreg,xmmrm SSE41
- PMOVZXBW xmmreg,xmmrm SSE41
- PMOVZXBD xmmreg,xmmrm SSE41,SD
- PMOVZXBQ xmmreg,xmmrm SSE41,SW
- PMOVZXWD xmmreg,xmmrm SSE41
- PMOVZXWQ xmmreg,xmmrm SSE41,SD
- PMOVZXDQ xmmreg,xmmrm SSE41
- PMULDQ xmmreg,xmmrm SSE41
- PMULLD xmmreg,xmmrm SSE41
- PTEST xmmreg,xmmrm SSE41
- ROUNDPD xmmreg,xmmrm,imm SSE41
- ROUNDPS xmmreg,xmmrm,imm SSE41
- ROUNDSD xmmreg,xmmrm,imm SSE41
- ROUNDSS xmmreg,xmmrm,imm SSE41
-
-B.1.19 Nehalem New Instructions (SSE4.2)
-
- CRC32 reg32,rm8 SSE42
- CRC32 reg32,rm16 SSE42
- CRC32 reg32,rm32 SSE42
- CRC32 reg64,rm8 SSE42,X64
- CRC32 reg64,rm64 SSE42,X64
- PCMPESTRI xmmreg,xmmrm,imm SSE42
- PCMPESTRM xmmreg,xmmrm,imm SSE42
- PCMPISTRI xmmreg,xmmrm,imm SSE42
- PCMPISTRM xmmreg,xmmrm,imm SSE42
- PCMPGTQ xmmreg,xmmrm SSE42
- POPCNT reg16,rm16 NEHALEM,SW
- POPCNT reg32,rm32 NEHALEM,SD
- POPCNT reg64,rm64 NEHALEM,X64
-
-B.1.20 Intel SMX
-
- GETSEC KATMAI
-
-B.1.21 Geode (Cyrix) 3DNow! additions
-
- PFRCPV mmxreg,mmxrm PENT,3DNOW,CYRIX
- PFRSQRTV mmxreg,mmxrm PENT,3DNOW,CYRIX
-
-B.1.22 Intel new instructions in ???
-
- MOVBE reg16,mem16 NEHALEM
- MOVBE reg32,mem32 NEHALEM
- MOVBE reg64,mem64 NEHALEM
- MOVBE mem16,reg16 NEHALEM
- MOVBE mem32,reg32 NEHALEM
- MOVBE mem64,reg64 NEHALEM
-
-B.1.23 Intel AES instructions
-
- AESENC xmmreg,xmmrm128 SSE,WESTMERE
- AESENCLAST xmmreg,xmmrm128 SSE,WESTMERE
- AESDEC xmmreg,xmmrm128 SSE,WESTMERE
- AESDECLAST xmmreg,xmmrm128 SSE,WESTMERE
- AESIMC xmmreg,xmmrm128 SSE,WESTMERE
- AESKEYGENASSIST xmmreg,xmmrm128,imm8 SSE,WESTMERE
-
-B.1.24 Intel AVX AES instructions
-
- VAESENC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESENCLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESDEC xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESDECLAST xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VAESIMC xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VAESKEYGENASSIST xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
-
-B.1.25 Intel AVX instructions
-
- VADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VADDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VADDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VADDSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VADDSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VADDSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDNPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDNPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VANDNPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VANDNPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VBLENDPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VBLENDPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VBLENDPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VBLENDPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VBLENDVPD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VBLENDVPD xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
- VBLENDVPD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
- VBLENDVPS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VBLENDVPS xmmreg,xmmrm128,xmm0 AVX,SANDYBRIDGE
- VBLENDVPS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VBLENDVPD ymmreg,ymmrm256,ymm0 AVX,SANDYBRIDGE
- VBROADCASTSS xmmreg,mem32 AVX,SANDYBRIDGE
- VBROADCASTSS ymmreg,mem32 AVX,SANDYBRIDGE
- VBROADCASTSD ymmreg,mem64 AVX,SANDYBRIDGE
- VBROADCASTF128 ymmreg,mem128 AVX,SANDYBRIDGE
- VCMPEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGTPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGTPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUEPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUEPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORD_SPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORD_SPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGE_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGE_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGT_UQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGT_UQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSE_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSE_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OSPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OSPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGE_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGE_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGT_OQPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGT_OQPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUE_USPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUE_USPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VCMPPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VCMPEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGTPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGTPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUEPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUEPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPLE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPLE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPUNORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPUNORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNLE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNLE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPORD_SPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPORD_SPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPEQ_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPEQ_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGE_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGE_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNGT_UQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNGT_UQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPFALSE_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPFALSE_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPNEQ_OSPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPNEQ_OSPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGE_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGE_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPGT_OQPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPGT_OQPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPTRUE_USPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VCMPTRUE_USPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VCMPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VCMPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VCMPEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPUNORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPORDSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPEQ_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPFALSESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQ_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPTRUESD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPLE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPUNORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNLE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPORD_SSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPEQ_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGE_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNGT_UQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPFALSE_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPNEQ_OSSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGE_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPGT_OQSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPTRUE_USSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCMPSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
- VCMPEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPUNORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPORDSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPEQ_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPFALSESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQ_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPTRUESS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPLE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPUNORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNLE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPORD_SSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPEQ_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGE_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNGT_UQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPFALSE_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPNEQ_OSSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGE_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPGT_OQSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPTRUE_USSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCMPSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
- VCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VCVTDQ2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VCVTDQ2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTDQ2PS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTDQ2PS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VCVTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
- VCVTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
- VCVTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
- VCVTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
- VCVTPD2PS xmmreg,xmmreg AVX,SANDYBRIDGE
- VCVTPD2PS xmmreg,mem128 AVX,SANDYBRIDGE,SO
- VCVTPD2PS xmmreg,ymmreg AVX,SANDYBRIDGE
- VCVTPD2PS xmmreg,mem256 AVX,SANDYBRIDGE,SY
- VCVTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VCVTPS2PD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VCVTPS2PD ymmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
- VCVTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
- VCVTSD2SS xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VCVTSI2SD xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
- VCVTSI2SD xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
- VCVTSI2SD xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
- VCVTSI2SS xmmreg,xmmreg*,rm32 AVX,SANDYBRIDGE,SD
- VCVTSI2SS xmmreg,xmmreg*,mem32 AVX,SANDYBRIDGE,ND,SD
- VCVTSI2SS xmmreg,xmmreg*,rm64 AVX,SANDYBRIDGE,LONG
- VCVTSS2SD xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VCVTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
- VCVTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
- VCVTTPD2DQ xmmreg,xmmreg AVX,SANDYBRIDGE
- VCVTTPD2DQ xmmreg,mem128 AVX,SANDYBRIDGE,SO
- VCVTTPD2DQ xmmreg,ymmreg AVX,SANDYBRIDGE
- VCVTTPD2DQ xmmreg,mem256 AVX,SANDYBRIDGE,SY
- VCVTTPS2DQ xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VCVTTPS2DQ ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VCVTTSD2SI reg32,xmmrm64 AVX,SANDYBRIDGE
- VCVTTSD2SI reg64,xmmrm64 AVX,SANDYBRIDGE,LONG
- VCVTTSS2SI reg32,xmmrm32 AVX,SANDYBRIDGE
- VCVTTSS2SI reg64,xmmrm32 AVX,SANDYBRIDGE,LONG
- VDIVPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VDIVPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VDIVPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VDIVPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VDIVSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VDIVSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VDPPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VDPPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VDPPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VEXTRACTF128 xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
- VEXTRACTPS rm32,xmmreg,imm8 AVX,SANDYBRIDGE
- VHADDPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHADDPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VHADDPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHADDPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VHSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VHSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VHSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VINSERTF128 ymmreg,ymmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VINSERTPS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
- VLDDQU xmmreg,mem128 AVX,SANDYBRIDGE
- VLDQQU ymmreg,mem256 AVX,SANDYBRIDGE
- VLDDQU ymmreg,mem256 AVX,SANDYBRIDGE
- VLDMXCSR mem32 AVX,SANDYBRIDGE
- VMASKMOVDQU xmmreg,xmmreg AVX,SANDYBRIDGE
- VMASKMOVPS xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
- VMASKMOVPS ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
- VMASKMOVPS mem128,xmmreg,xmmreg AVX,SANDYBRIDGE,SO
- VMASKMOVPS mem256,xmmreg,xmmreg AVX,SANDYBRIDGE,SY
- VMASKMOVPD xmmreg,xmmreg,mem128 AVX,SANDYBRIDGE
- VMASKMOVPD ymmreg,ymmreg,mem256 AVX,SANDYBRIDGE
- VMASKMOVPD mem128,xmmreg,xmmreg AVX,SANDYBRIDGE
- VMASKMOVPD mem256,ymmreg,ymmreg AVX,SANDYBRIDGE
- VMAXPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMAXPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMAXPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMAXPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMAXSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VMAXSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VMINPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMINPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMINPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMINPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMINSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VMINSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VMOVAPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVAPD xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVAPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVAPD ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVAPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVAPS xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVAPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVAPS ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VMOVQ xmmrm64,xmmreg AVX,SANDYBRIDGE
- VMOVQ xmmreg,rm64 AVX,SANDYBRIDGE,LONG
- VMOVQ rm64,xmmreg AVX,SANDYBRIDGE,LONG
- VMOVD xmmreg,rm32 AVX,SANDYBRIDGE
- VMOVD rm32,xmmreg AVX,SANDYBRIDGE
- VMOVDDUP xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VMOVDDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVDQA xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVDQA xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVQQA ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVQQA ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVDQA ymmreg,ymmrm AVX,SANDYBRIDGE
- VMOVDQA ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVDQU xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVDQU xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVQQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVQQU ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVDQU ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVDQU ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVHLPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVHPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVHPD mem64,xmmreg AVX,SANDYBRIDGE
- VMOVHPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVHPS mem64,xmmreg AVX,SANDYBRIDGE
- VMOVLHPS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVLPD xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVLPD mem64,xmmreg AVX,SANDYBRIDGE
- VMOVLPS xmmreg,xmmreg*,mem64 AVX,SANDYBRIDGE
- VMOVLPS mem64,xmmreg AVX,SANDYBRIDGE
- VMOVMSKPD reg64,xmmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPD reg32,xmmreg AVX,SANDYBRIDGE
- VMOVMSKPD reg64,ymmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPD reg32,ymmreg AVX,SANDYBRIDGE
- VMOVMSKPS reg64,xmmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPS reg32,xmmreg AVX,SANDYBRIDGE
- VMOVMSKPS reg64,ymmreg AVX,SANDYBRIDGE,LONG
- VMOVMSKPS reg32,ymmreg AVX,SANDYBRIDGE
- VMOVNTDQ mem128,xmmreg AVX,SANDYBRIDGE
- VMOVNTQQ mem256,ymmreg AVX,SANDYBRIDGE
- VMOVNTDQ mem256,ymmreg AVX,SANDYBRIDGE
- VMOVNTDQA xmmreg,mem128 AVX,SANDYBRIDGE
- VMOVNTPD mem128,xmmreg AVX,SANDYBRIDGE
- VMOVNTPD mem256,ymmreg AVX,SANDYBRIDGE
- VMOVNTPS mem128,xmmreg AVX,SANDYBRIDGE
- VMOVNTPS mem128,ymmreg AVX,SANDYBRIDGE
- VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSD xmmreg,mem64 AVX,SANDYBRIDGE
- VMOVSD xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSD mem64,xmmreg AVX,SANDYBRIDGE
- VMOVSHDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVSHDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVSLDUP xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVSLDUP ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSS xmmreg,mem64 AVX,SANDYBRIDGE
- VMOVSS xmmreg,xmmreg*,xmmreg AVX,SANDYBRIDGE
- VMOVSS mem64,xmmreg AVX,SANDYBRIDGE
- VMOVUPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVUPD xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVUPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVUPD ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMOVUPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VMOVUPS xmmrm128,xmmreg AVX,SANDYBRIDGE
- VMOVUPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VMOVUPS ymmrm256,ymmreg AVX,SANDYBRIDGE
- VMPSADBW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VMULPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMULPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMULPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VMULPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VMULSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VMULSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VPABSB xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPABSW xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPABSD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPACKSSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPACKSSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPACKUSWB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPACKUSDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPADDUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPALIGNR xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPAND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPANDN xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPAVGB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPAVGW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPBLENDVB xmmreg,xmmreg*,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPBLENDW xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPESTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPESTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPISTRI xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPISTRM xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPCMPEQB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPEQW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPEQD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPEQQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCMPGTQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPERMILPD xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILPD ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMILPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERMILTD2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILTD2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILTD2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILTD2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMO2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMO2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMO2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMO2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMZ2PD xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMZ2PD xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMZ2PD ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMZ2PD ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMIL2PD xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PD xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMIL2PD ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PD ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERMILPS xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILPS ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMILPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERMILTD2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILTD2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILTD2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILTD2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMO2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMO2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMO2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMO2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMILMZ2PS xmmreg,xmmreg,xmmrm128,xmmreg AVX,SANDYBRIDGE
- VPERMILMZ2PS xmmreg,xmmreg,xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPERMILMZ2PS ymmreg,ymmreg,ymmrm256,ymmreg AVX,SANDYBRIDGE
- VPERMILMZ2PS ymmreg,ymmreg,ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPERMIL2PS xmmreg,xmmreg,xmmrm128,xmmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PS xmmreg,xmmreg,xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPERMIL2PS ymmreg,ymmreg,ymmrm256,ymmreg,imm8 AVX,SANDYBRIDGE
- VPERMIL2PS ymmreg,ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPERM2F128 ymmreg,ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VPEXTRB reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRB reg32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRB mem8,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRW reg32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRW mem16,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRD reg64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPEXTRD rm32,xmmreg,imm8 AVX,SANDYBRIDGE
- VPEXTRQ rm64,xmmreg,imm8 AVX,SANDYBRIDGE,LONG
- VPHADDW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHADDD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHADDSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHMINPOSUW xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPHSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPHSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPINSRB xmmreg,xmmreg*,mem8,imm8 AVX,SANDYBRIDGE
- VPINSRB xmmreg,xmmreg*,rm8,imm8 AVX,SANDYBRIDGE
- VPINSRB xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
- VPINSRW xmmreg,xmmreg*,mem16,imm8 AVX,SANDYBRIDGE
- VPINSRW xmmreg,xmmreg*,rm16,imm8 AVX,SANDYBRIDGE
- VPINSRW xmmreg,xmmreg*,reg32,imm8 AVX,SANDYBRIDGE
- VPINSRD xmmreg,xmmreg*,mem32,imm8 AVX,SANDYBRIDGE
- VPINSRD xmmreg,xmmreg*,rm32,imm8 AVX,SANDYBRIDGE
- VPINSRQ xmmreg,xmmreg*,mem64,imm8 AVX,SANDYBRIDGE,LONG
- VPINSRQ xmmreg,xmmreg*,rm64,imm8 AVX,SANDYBRIDGE,LONG
- VPMADDWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMADDUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMAXUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINSD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINUB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMINUD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMOVMSKB reg64,xmmreg AVX,SANDYBRIDGE,LONG
- VPMOVMSKB reg32,xmmreg AVX,SANDYBRIDGE
- VPMOVSXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVSXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVSXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
- VPMOVSXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVSXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVSXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVZXBW xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVZXBD xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVZXBQ xmmreg,xmmrm16 AVX,SANDYBRIDGE
- VPMOVZXWD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMOVZXWQ xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VPMOVZXDQ xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VPMULHUW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULHRSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULHW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULUDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPMULDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSADBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSHUFB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSHUFD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPSHUFHW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPSHUFLW xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VPSIGNB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSIGNW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSIGND xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLDQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSLLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSLLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSLLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSLLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRAW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRAW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRAD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRAD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRLW xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRLD xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPSRLQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSRLQ xmmreg,xmmreg*,imm8 AVX,SANDYBRIDGE
- VPTEST xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VPTEST ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VPSUBB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBUSB xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPSUBUSW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLBW xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLWD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPUNPCKLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPXOR xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VRCPPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VRCPPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VRCPSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VRSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VRSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VRSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VROUNDPD xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VROUNDPD ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VROUNDPS xmmreg,xmmrm128,imm8 AVX,SANDYBRIDGE
- VROUNDPS ymmreg,ymmrm256,imm8 AVX,SANDYBRIDGE
- VROUNDSD xmmreg,xmmreg*,xmmrm64,imm8 AVX,SANDYBRIDGE
- VROUNDSS xmmreg,xmmreg*,xmmrm32,imm8 AVX,SANDYBRIDGE
- VSHUFPD xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VSHUFPD ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VSHUFPS xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
- VSHUFPS ymmreg,ymmreg*,ymmrm256,imm8 AVX,SANDYBRIDGE
- VSQRTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VSQRTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VSQRTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VSQRTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VSQRTSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VSQRTSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VSTMXCSR mem32 AVX,SANDYBRIDGE
- VSUBPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VSUBPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VSUBPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VSUBPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VSUBSD xmmreg,xmmreg*,xmmrm64 AVX,SANDYBRIDGE
- VSUBSS xmmreg,xmmreg*,xmmrm32 AVX,SANDYBRIDGE
- VTESTPS xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VTESTPS ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VTESTPD xmmreg,xmmrm128 AVX,SANDYBRIDGE
- VTESTPD ymmreg,ymmrm256 AVX,SANDYBRIDGE
- VUCOMISD xmmreg,xmmrm64 AVX,SANDYBRIDGE
- VUCOMISS xmmreg,xmmrm32 AVX,SANDYBRIDGE
- VUNPCKHPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKHPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VUNPCKHPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKHPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VUNPCKLPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKLPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VUNPCKLPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VUNPCKLPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VXORPD xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VXORPD ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VXORPS xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VXORPS ymmreg,ymmreg*,ymmrm256 AVX,SANDYBRIDGE
- VZEROALL AVX,SANDYBRIDGE
- VZEROUPPER AVX,SANDYBRIDGE
-
-B.1.26 Intel Carry-Less Multiplication instructions (CLMUL)
-
- PCLMULLQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULHQLQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULLQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULHQHQDQ xmmreg,xmmrm128 SSE,WESTMERE
- PCLMULQDQ xmmreg,xmmrm128,imm8 SSE,WESTMERE
-
-B.1.27 Intel AVX Carry-Less Multiplication instructions (CLMUL)
-
- VPCLMULLQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULHQLQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULLQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULHQHQDQ xmmreg,xmmreg*,xmmrm128 AVX,SANDYBRIDGE
- VPCLMULQDQ xmmreg,xmmreg*,xmmrm128,imm8 AVX,SANDYBRIDGE
-
-B.1.28 Intel Fused Multiply-Add instructions (FMA)
-
- VFMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADDSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMADDSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMSUBADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFMSUBADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMADD321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMADD321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB132PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB132PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB132PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB132PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB312PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB312PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB312PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB312PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB213PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB213PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB213PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB213PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB123PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB123PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB123PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB123PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB231PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB231PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB231PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB231PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB321PS xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB321PS ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFNMSUB321PD xmmreg,xmmreg,xmmrm128 FMA,FUTURE
- VFNMSUB321PD ymmreg,ymmreg,ymmrm256 FMA,FUTURE
- VFMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMADD321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMADD321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB132SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB132SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB312SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB312SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB213SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB213SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB123SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB123SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB231SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB231SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
- VFNMSUB321SS xmmreg,xmmreg,xmmrm32 FMA,FUTURE
- VFNMSUB321SD xmmreg,xmmreg,xmmrm64 FMA,FUTURE
-
-B.1.29 VIA (Centaur) security instructions
-
- XSTORE PENT,CYRIX
- XCRYPTECB PENT,CYRIX
- XCRYPTCBC PENT,CYRIX
- XCRYPTCTR PENT,CYRIX
- XCRYPTCFB PENT,CYRIX
- XCRYPTOFB PENT,CYRIX
- MONTMUL PENT,CYRIX
- XSHA1 PENT,CYRIX
- XSHA256 PENT,CYRIX
-
-B.1.30 AMD Lightweight Profiling (LWP) instructions
-
- LLWPCB reg16 AMD
- LLWPCB reg32 AMD,386
- LLWPCB reg64 AMD,X64
- SLWPCB reg16 AMD
- SLWPCB reg32 AMD,386
- SLWPCB reg64 AMD,X64
- LWPVAL reg16,rm32,imm16 AMD,386
- LWPVAL reg32,rm32,imm32 AMD,386
- LWPVAL reg64,rm32,imm32 AMD,X64
- LWPINS reg16,rm32,imm16 AMD,386
- LWPINS reg32,rm32,imm32 AMD,386
- LWPINS reg64,rm32,imm32 AMD,X64
-
-B.1.31 AMD XOP, FMA4 and CVT16 instructions (SSE5)
-
- VCVTPH2PS xmmreg,xmmrm64*,imm8 AMD,SSE5
- VCVTPH2PS ymmreg,xmmrm128,imm8 AMD,SSE5
- VCVTPH2PS ymmreg,ymmrm128*,imm8 AMD,SSE5
- VCVTPS2PH xmmrm64,xmmreg*,imm8 AMD,SSE5
- VCVTPS2PH xmmrm128,ymmreg,imm8 AMD,SSE5
- VCVTPS2PH ymmrm128,ymmreg*,imm8 AMD,SSE5
- VFMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFMADDSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMADDSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMADDSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMADDSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMADDSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFNMADDPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMADDPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMADDPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMADDPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMADDPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMADDPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMADDPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMADDPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMADDSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFNMADDSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFNMADDSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFNMADDSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFNMSUBPD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMSUBPD ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMSUBPD xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMSUBPD ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMSUBPS xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VFNMSUBPS ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VFNMSUBPS xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VFNMSUBPS ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VFNMSUBSD xmmreg,xmmreg*,xmmrm64,xmmreg AMD,SSE5
- VFNMSUBSD xmmreg,xmmreg*,xmmreg,xmmrm64 AMD,SSE5
- VFNMSUBSS xmmreg,xmmreg*,xmmrm32,xmmreg AMD,SSE5
- VFNMSUBSS xmmreg,xmmreg*,xmmreg,xmmrm32 AMD,SSE5
- VFRCZPD xmmreg,xmmrm128* AMD,SSE5
- VFRCZPD ymmreg,ymmrm256* AMD,SSE5
- VFRCZPS xmmreg,xmmrm128* AMD,SSE5
- VFRCZPS ymmreg,ymmrm256* AMD,SSE5
- VFRCZSD xmmreg,xmmrm64* AMD,SSE5
- VFRCZSS xmmreg,xmmrm32* AMD,SSE5
- VPCMOV xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPCMOV ymmreg,ymmreg*,ymmrm256,ymmreg AMD,SSE5
- VPCMOV xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VPCMOV ymmreg,ymmreg*,ymmreg,ymmrm256 AMD,SSE5
- VPCOMB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUB xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUD xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUQ xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMUW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPCOMW xmmreg,xmmreg*,xmmrm128,imm8 AMD,SSE5
- VPHADDBD xmmreg,xmmrm128* AMD,SSE5
- VPHADDBQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDBW xmmreg,xmmrm128* AMD,SSE5
- VPHADDDQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDUBD xmmreg,xmmrm128* AMD,SSE5
- VPHADDUBQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDUBW xmmreg,xmmrm128* AMD,SSE5
- VPHADDUDQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDUWD xmmreg,xmmrm128* AMD,SSE5
- VPHADDUWQ xmmreg,xmmrm128* AMD,SSE5
- VPHADDWD xmmreg,xmmrm128* AMD,SSE5
- VPHADDWQ xmmreg,xmmrm128* AMD,SSE5
- VPHSUBBW xmmreg,xmmrm128* AMD,SSE5
- VPHSUBDQ xmmreg,xmmrm128* AMD,SSE5
- VPHSUBWD xmmreg,xmmrm128* AMD,SSE5
- VPMACSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSDD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSDQH xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSDQL xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMACSWW xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMADCSSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPMADCSWD xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPPERM xmmreg,xmmreg*,xmmreg,xmmrm128 AMD,SSE5
- VPPERM xmmreg,xmmreg*,xmmrm128,xmmreg AMD,SSE5
- VPROTB xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTB xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPROTD xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTD xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPROTQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTQ xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPROTW xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPROTW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPROTW xmmreg,xmmrm128*,imm8 AMD,SSE5
- VPSHAB xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHAD xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHAQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHAW xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHAW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLB xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLB xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLD xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLD xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLQ xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLQ xmmreg,xmmreg*,xmmrm128 AMD,SSE5
- VPSHLW xmmreg,xmmrm128*,xmmreg AMD,SSE5
- VPSHLW xmmreg,xmmreg*,xmmrm128 AMD,SSE5
-
-B.1.32 Systematic names for the hinting nop instructions
-
- HINT_NOP0 rm16 P6,UNDOC
- HINT_NOP0 rm32 P6,UNDOC
- HINT_NOP0 rm64 X64,UNDOC
- HINT_NOP1 rm16 P6,UNDOC
- HINT_NOP1 rm32 P6,UNDOC
- HINT_NOP1 rm64 X64,UNDOC
- HINT_NOP2 rm16 P6,UNDOC
- HINT_NOP2 rm32 P6,UNDOC
- HINT_NOP2 rm64 X64,UNDOC
- HINT_NOP3 rm16 P6,UNDOC
- HINT_NOP3 rm32 P6,UNDOC
- HINT_NOP3 rm64 X64,UNDOC
- HINT_NOP4 rm16 P6,UNDOC
- HINT_NOP4 rm32 P6,UNDOC
- HINT_NOP4 rm64 X64,UNDOC
- HINT_NOP5 rm16 P6,UNDOC
- HINT_NOP5 rm32 P6,UNDOC
- HINT_NOP5 rm64 X64,UNDOC
- HINT_NOP6 rm16 P6,UNDOC
- HINT_NOP6 rm32 P6,UNDOC
- HINT_NOP6 rm64 X64,UNDOC
- HINT_NOP7 rm16 P6,UNDOC
- HINT_NOP7 rm32 P6,UNDOC
- HINT_NOP7 rm64 X64,UNDOC
- HINT_NOP8 rm16 P6,UNDOC
- HINT_NOP8 rm32 P6,UNDOC
- HINT_NOP8 rm64 X64,UNDOC
- HINT_NOP9 rm16 P6,UNDOC
- HINT_NOP9 rm32 P6,UNDOC
- HINT_NOP9 rm64 X64,UNDOC
- HINT_NOP10 rm16 P6,UNDOC
- HINT_NOP10 rm32 P6,UNDOC
- HINT_NOP10 rm64 X64,UNDOC
- HINT_NOP11 rm16 P6,UNDOC
- HINT_NOP11 rm32 P6,UNDOC
- HINT_NOP11 rm64 X64,UNDOC
- HINT_NOP12 rm16 P6,UNDOC
- HINT_NOP12 rm32 P6,UNDOC
- HINT_NOP12 rm64 X64,UNDOC
- HINT_NOP13 rm16 P6,UNDOC
- HINT_NOP13 rm32 P6,UNDOC
- HINT_NOP13 rm64 X64,UNDOC
- HINT_NOP14 rm16 P6,UNDOC
- HINT_NOP14 rm32 P6,UNDOC
- HINT_NOP14 rm64 X64,UNDOC
- HINT_NOP15 rm16 P6,UNDOC
- HINT_NOP15 rm32 P6,UNDOC
- HINT_NOP15 rm64 X64,UNDOC
- HINT_NOP16 rm16 P6,UNDOC
- HINT_NOP16 rm32 P6,UNDOC
- HINT_NOP16 rm64 X64,UNDOC
- HINT_NOP17 rm16 P6,UNDOC
- HINT_NOP17 rm32 P6,UNDOC
- HINT_NOP17 rm64 X64,UNDOC
- HINT_NOP18 rm16 P6,UNDOC
- HINT_NOP18 rm32 P6,UNDOC
- HINT_NOP18 rm64 X64,UNDOC
- HINT_NOP19 rm16 P6,UNDOC
- HINT_NOP19 rm32 P6,UNDOC
- HINT_NOP19 rm64 X64,UNDOC
- HINT_NOP20 rm16 P6,UNDOC
- HINT_NOP20 rm32 P6,UNDOC
- HINT_NOP20 rm64 X64,UNDOC
- HINT_NOP21 rm16 P6,UNDOC
- HINT_NOP21 rm32 P6,UNDOC
- HINT_NOP21 rm64 X64,UNDOC
- HINT_NOP22 rm16 P6,UNDOC
- HINT_NOP22 rm32 P6,UNDOC
- HINT_NOP22 rm64 X64,UNDOC
- HINT_NOP23 rm16 P6,UNDOC
- HINT_NOP23 rm32 P6,UNDOC
- HINT_NOP23 rm64 X64,UNDOC
- HINT_NOP24 rm16 P6,UNDOC
- HINT_NOP24 rm32 P6,UNDOC
- HINT_NOP24 rm64 X64,UNDOC
- HINT_NOP25 rm16 P6,UNDOC
- HINT_NOP25 rm32 P6,UNDOC
- HINT_NOP25 rm64 X64,UNDOC
- HINT_NOP26 rm16 P6,UNDOC
- HINT_NOP26 rm32 P6,UNDOC
- HINT_NOP26 rm64 X64,UNDOC
- HINT_NOP27 rm16 P6,UNDOC
- HINT_NOP27 rm32 P6,UNDOC
- HINT_NOP27 rm64 X64,UNDOC
- HINT_NOP28 rm16 P6,UNDOC
- HINT_NOP28 rm32 P6,UNDOC
- HINT_NOP28 rm64 X64,UNDOC
- HINT_NOP29 rm16 P6,UNDOC
- HINT_NOP29 rm32 P6,UNDOC
- HINT_NOP29 rm64 X64,UNDOC
- HINT_NOP30 rm16 P6,UNDOC
- HINT_NOP30 rm32 P6,UNDOC
- HINT_NOP30 rm64 X64,UNDOC
- HINT_NOP31 rm16 P6,UNDOC
- HINT_NOP31 rm32 P6,UNDOC
- HINT_NOP31 rm64 X64,UNDOC
- HINT_NOP32 rm16 P6,UNDOC
- HINT_NOP32 rm32 P6,UNDOC
- HINT_NOP32 rm64 X64,UNDOC
- HINT_NOP33 rm16 P6,UNDOC
- HINT_NOP33 rm32 P6,UNDOC
- HINT_NOP33 rm64 X64,UNDOC
- HINT_NOP34 rm16 P6,UNDOC
- HINT_NOP34 rm32 P6,UNDOC
- HINT_NOP34 rm64 X64,UNDOC
- HINT_NOP35 rm16 P6,UNDOC
- HINT_NOP35 rm32 P6,UNDOC
- HINT_NOP35 rm64 X64,UNDOC
- HINT_NOP36 rm16 P6,UNDOC
- HINT_NOP36 rm32 P6,UNDOC
- HINT_NOP36 rm64 X64,UNDOC
- HINT_NOP37 rm16 P6,UNDOC
- HINT_NOP37 rm32 P6,UNDOC
- HINT_NOP37 rm64 X64,UNDOC
- HINT_NOP38 rm16 P6,UNDOC
- HINT_NOP38 rm32 P6,UNDOC
- HINT_NOP38 rm64 X64,UNDOC
- HINT_NOP39 rm16 P6,UNDOC
- HINT_NOP39 rm32 P6,UNDOC
- HINT_NOP39 rm64 X64,UNDOC
- HINT_NOP40 rm16 P6,UNDOC
- HINT_NOP40 rm32 P6,UNDOC
- HINT_NOP40 rm64 X64,UNDOC
- HINT_NOP41 rm16 P6,UNDOC
- HINT_NOP41 rm32 P6,UNDOC
- HINT_NOP41 rm64 X64,UNDOC
- HINT_NOP42 rm16 P6,UNDOC
- HINT_NOP42 rm32 P6,UNDOC
- HINT_NOP42 rm64 X64,UNDOC
- HINT_NOP43 rm16 P6,UNDOC
- HINT_NOP43 rm32 P6,UNDOC
- HINT_NOP43 rm64 X64,UNDOC
- HINT_NOP44 rm16 P6,UNDOC
- HINT_NOP44 rm32 P6,UNDOC
- HINT_NOP44 rm64 X64,UNDOC
- HINT_NOP45 rm16 P6,UNDOC
- HINT_NOP45 rm32 P6,UNDOC
- HINT_NOP45 rm64 X64,UNDOC
- HINT_NOP46 rm16 P6,UNDOC
- HINT_NOP46 rm32 P6,UNDOC
- HINT_NOP46 rm64 X64,UNDOC
- HINT_NOP47 rm16 P6,UNDOC
- HINT_NOP47 rm32 P6,UNDOC
- HINT_NOP47 rm64 X64,UNDOC
- HINT_NOP48 rm16 P6,UNDOC
- HINT_NOP48 rm32 P6,UNDOC
- HINT_NOP48 rm64 X64,UNDOC
- HINT_NOP49 rm16 P6,UNDOC
- HINT_NOP49 rm32 P6,UNDOC
- HINT_NOP49 rm64 X64,UNDOC
- HINT_NOP50 rm16 P6,UNDOC
- HINT_NOP50 rm32 P6,UNDOC
- HINT_NOP50 rm64 X64,UNDOC
- HINT_NOP51 rm16 P6,UNDOC
- HINT_NOP51 rm32 P6,UNDOC
- HINT_NOP51 rm64 X64,UNDOC
- HINT_NOP52 rm16 P6,UNDOC
- HINT_NOP52 rm32 P6,UNDOC
- HINT_NOP52 rm64 X64,UNDOC
- HINT_NOP53 rm16 P6,UNDOC
- HINT_NOP53 rm32 P6,UNDOC
- HINT_NOP53 rm64 X64,UNDOC
- HINT_NOP54 rm16 P6,UNDOC
- HINT_NOP54 rm32 P6,UNDOC
- HINT_NOP54 rm64 X64,UNDOC
- HINT_NOP55 rm16 P6,UNDOC
- HINT_NOP55 rm32 P6,UNDOC
- HINT_NOP55 rm64 X64,UNDOC
- HINT_NOP56 rm16 P6,UNDOC
- HINT_NOP56 rm32 P6,UNDOC
- HINT_NOP56 rm64 X64,UNDOC
- HINT_NOP57 rm16 P6,UNDOC
- HINT_NOP57 rm32 P6,UNDOC
- HINT_NOP57 rm64 X64,UNDOC
- HINT_NOP58 rm16 P6,UNDOC
- HINT_NOP58 rm32 P6,UNDOC
- HINT_NOP58 rm64 X64,UNDOC
- HINT_NOP59 rm16 P6,UNDOC
- HINT_NOP59 rm32 P6,UNDOC
- HINT_NOP59 rm64 X64,UNDOC
- HINT_NOP60 rm16 P6,UNDOC
- HINT_NOP60 rm32 P6,UNDOC
- HINT_NOP60 rm64 X64,UNDOC
- HINT_NOP61 rm16 P6,UNDOC
- HINT_NOP61 rm32 P6,UNDOC
- HINT_NOP61 rm64 X64,UNDOC
- HINT_NOP62 rm16 P6,UNDOC
- HINT_NOP62 rm32 P6,UNDOC
- HINT_NOP62 rm64 X64,UNDOC
- HINT_NOP63 rm16 P6,UNDOC
- HINT_NOP63 rm32 P6,UNDOC
- HINT_NOP63 rm64 X64,UNDOC
-
-Appendix C: NASM Version History
---------------------------------
-
- C.1 NASM 2 Series
-
- The NASM 2 series support x86-64, and is the production version of
- NASM since 2007.
-
- C.1.1 Version 2.08
-
- (*) A number of enhancements/fixes in macros area.
-
- (*) Support for arbitrarily terminating macro expansions
- `%exitmacro'. See section 4.3.12.
-
- (*) Support for recursive macro expansion `%rmacro/irmacro'. See
- section 4.3.1.
-
- (*) Support for converting strings to tokens. See section 4.1.9.
-
- (*) Fuzzy operand size logic introduced.
-
- (*) Fix COFF stack overrun on too long export identifiers.
-
- (*) Fix Macho-O alignment bug.
-
- (*) Fix crashes with -fwin32 on file with many exports.
-
- (*) Fix stack overrun for too long [DEBUG id].
-
- (*) Fix incorrect sbyte usage in IMUL (hit only if optimization flag
- passed).
-
- (*) Append ending token for `.stabs' records in the ELF output
- format.
-
- (*) New NSIS script which uses ModernUI and MultiUser approach.
-
- (*) Visual Studio 2008 NASM integration (rules file).
-
- (*) Warn a user if a constant is too long (and as result will be
- stripped).
-
- (*) The obsoleted pre-XOP AMD SSE5 instruction set which was never
- actualized was removed.
-
- (*) Fix stack overrun on too long error file name passed from the
- command line.
-
- (*) Bind symbols to the .text section by default (ie in case if
- SECTION directive was omitted) in the ELF output format.
-
- (*) Fix sync points array index wrapping.
-
- (*) A few fixes for FMA4 and XOP instruction templates.
-
- (*) Add AMD Lightweight Profiling (LWP) instructions.
-
- C.1.2 Version 2.07
-
- (*) NASM is now under the 2-clause BSD license. See section 1.1.2.
-
- (*) Fix the section type for the `.strtab' section in the `elf64'
- output format.
-
- (*) Fix the handling of `COMMON' directives in the `obj' output
- format.
-
- (*) New `ith' and `srec' output formats; these are variants of the
- `bin' output format which output Intel hex and Motorola S-
- records, respectively. See section 7.2 and section 7.3.
-
- (*) `rdf2ihx' replaced with an enhanced `rdf2bin', which can output
- binary, COM, Intel hex or Motorola S-records.
-
- (*) The Windows installer now puts the NASM directory first in the
- `PATH' of the "NASM Shell".
-
- (*) Revert the early expansion behavior of `%+' to pre-2.06
- behavior: `%+' is only expanded late.
-
- (*) Yet another Mach-O alignment fix.
-
- (*) Don't delete the list file on errors. Also, include error and
- warning information in the list file.
-
- (*) Support for 64-bit Mach-O output, see section 7.8.
-
- (*) Fix assert failure on certain operations that involve strings
- with high-bit bytes.
-
- C.1.3 Version 2.06
-
- (*) This release is dedicated to the memory of Charles A. Crayne,
- long time NASM developer as well as moderator of
- `comp.lang.asm.x86' and author of the book _Serious Assembler_.
- We miss you, Chuck.
-
- (*) Support for indirect macro expansion (`%[...]'). See section
- 4.1.3.
-
- (*) `%pop' can now take an argument, see section 4.7.1.
-
- (*) The argument to `%use' is no longer macro-expanded. Use `%[...]'
- if macro expansion is desired.
-
- (*) Support for thread-local storage in ELF32 and ELF64. See section
- 7.9.4.
-
- (*) Fix crash on `%ifmacro' without an argument.
-
- (*) Correct the arguments to the `POPCNT' instruction.
-
- (*) Fix section alignment in the Mach-O format.
-
- (*) Update AVX support to version 5 of the Intel specification.
-
- (*) Fix the handling of accesses to context-local macros from higher
- levels in the context stack.
-
- (*) Treat `WAIT' as a prefix rather than as an instruction, thereby
- allowing constructs like `O16 FSAVE' to work correctly.
-
- (*) Support for structures with a non-zero base offset. See section
- 4.11.10.
-
- (*) Correctly handle preprocessor token concatenation (see section
- 4.3.8) involving floating-point numbers.
-
- (*) The `PINSR' series of instructions have been corrected and
- rationalized.
-
- (*) Removed AMD SSE5, replaced with the new XOP/FMA4/CVT16 (rev
- 3.03) spec.
-
- (*) The ELF backends no longer automatically generate a `.comment'
- section.
-
- (*) Add additional "well-known" ELF sections with default
- attributes. See section 7.9.2.
-
- C.1.4 Version 2.05.01
-
- (*) Fix the `-w'/`-W' option parsing, which was broken in NASM 2.05.
-
- C.1.5 Version 2.05
-
- (*) Fix redundant REX.W prefix on `JMP reg64'.
-
- (*) Make the behaviour of `-O0' match NASM 0.98 legacy behavior. See
- section 2.1.22.
-
- (*) `-w-user' can be used to suppress the output of `%warning'
- directives. See section 2.1.24.
-
- (*) Fix bug where `ALIGN' would issue a full alignment datum instead
- of zero bytes.
-
- (*) Fix offsets in list files.
-
- (*) Fix `%include' inside multi-line macros or loops.
-
- (*) Fix error where NASM would generate a spurious warning on valid
- optimizations of immediate values.
-
- (*) Fix arguments to a number of the `CVT' SSE instructions.
-
- (*) Fix RIP-relative offsets when the instruction carries an
- immediate.
-
- (*) Massive overhaul of the ELF64 backend for spec compliance.
-
- (*) Fix the Geode `PFRCPV' and `PFRSQRTV' instruction.
-
- (*) Fix the SSE 4.2 `CRC32' instruction.
-
- C.1.6 Version 2.04
-
- (*) Sanitize macro handing in the `%error' directive.
-
- (*) New `%warning' directive to issue user-controlled warnings.
-
- (*) `%error' directives are now deferred to the final assembly
- phase.
-
- (*) New `%fatal' directive to immediately terminate assembly.
-
- (*) New `%strcat' directive to join quoted strings together.
-
- (*) New `%use' macro directive to support standard macro directives.
- See section 4.6.4.
-
- (*) Excess default parameters to `%macro' now issues a warning by
- default. See section 4.3.
-
- (*) Fix `%ifn' and `%elifn'.
-
- (*) Fix nested `%else' clauses.
-
- (*) Correct the handling of nested `%rep's.
-
- (*) New `%unmacro' directive to undeclare a multi-line macro. See
- section 4.3.11.
-
- (*) Builtin macro `__PASS__' which expands to the current assembly
- pass. See section 4.11.9.
-
- (*) `__utf16__' and `__utf32__' operators to generate UTF-16 and
- UTF-32 strings. See section 3.4.5.
-
- (*) Fix bug in case-insensitive matching when compiled on platforms
- that don't use the `configure' script. Of the official release
- binaries, that only affected the OS/2 binary.
-
- (*) Support for x87 packed BCD constants. See section 3.4.7.
-
- (*) Correct the `LTR' and `SLDT' instructions in 64-bit mode.
-
- (*) Fix unnecessary REX.W prefix on indirect jumps in 64-bit mode.
-
- (*) Add AVX versions of the AES instructions (`VAES'...).
-
- (*) Fix the 256-bit FMA instructions.
-
- (*) Add 256-bit AVX stores per the latest AVX spec.
-
- (*) VIA XCRYPT instructions can now be written either with or
- without `REP', apparently different versions of the VIA spec
- wrote them differently.
-
- (*) Add missing 64-bit `MOVNTI' instruction.
-
- (*) Fix the operand size of `VMREAD' and `VMWRITE'.
-
- (*) Numerous bug fixes, especially to the AES, AVX and VTX
- instructions.
-
- (*) The optimizer now always runs until it converges. It also runs
- even when disabled, but doesn't optimize. This allows most
- forward references to be resolved properly.
-
- (*) `%push' no longer needs a context identifier; omitting the
- context identifier results in an anonymous context.
-
- C.1.7 Version 2.03.01
-
- (*) Fix buffer overflow in the listing module.
-
- (*) Fix the handling of hexadecimal escape codes in `...` strings.
-
- (*) The Postscript/PDF documentation has been reformatted.
-
- (*) The `-F' option now implies `-g'.
-
- C.1.8 Version 2.03
-
- (*) Add support for Intel AVX, CLMUL and FMA instructions, including
- YMM registers.
-
- (*) `dy', `resy' and `yword' for 32-byte operands.
-
- (*) Fix some SSE5 instructions.
-
- (*) Intel `INVEPT', `INVVPID' and `MOVBE' instructions.
-
- (*) Fix checking for critical expressions when the optimizer is
- enabled.
-
- (*) Support the DWARF debugging format for ELF targets.
-
- (*) Fix optimizations of signed bytes.
-
- (*) Fix operation on bigendian machines.
-
- (*) Fix buffer overflow in the preprocessor.
-
- (*) `SAFESEH' support for Win32, `IMAGEREL' for Win64 (SEH).
-
- (*) `%?' and `%??' to refer to the name of a macro itself. In
- particular, `%idefine keyword $%?' can be used to make a keyword
- "disappear".
-
- (*) New options for dependency generation: `-MD', `-MF', `-MP',
- `-MT', `-MQ'.
-
- (*) New preprocessor directives `%pathsearch' and `%depend'; INCBIN
- reimplemented as a macro.
-
- (*) `%include' now resolves macros in a sane manner.
-
- (*) `%substr' can now be used to get other than one-character
- substrings.
-
- (*) New type of character/string constants, using backquotes
- (``...`'), which support C-style escape sequences.
-
- (*) `%defstr' and `%idefstr' to stringize macro definitions before
- creation.
-
- (*) Fix forward references used in `EQU' statements.
-
- C.1.9 Version 2.02
-
- (*) Additional fixes for MMX operands with explicit `qword', as well
- as (hopefully) SSE operands with `oword'.
-
- (*) Fix handling of truncated strings with `DO'.
-
- (*) Fix segfaults due to memory overwrites when floating-point
- constants were used.
-
- (*) Fix segfaults due to missing include files.
-
- (*) Fix OpenWatcom Makefiles for DOS and OS/2.
-
- (*) Add autogenerated instruction list back into the documentation.
-
- (*) ELF: Fix segfault when generating stabs, and no symbols have
- been defined.
-
- (*) ELF: Experimental support for DWARF debugging information.
-
- (*) New compile date and time standard macros.
-
- (*) `%ifnum' now returns true for negative numbers.
-
- (*) New `%iftoken' test for a single token.
-
- (*) New `%ifempty' test for empty expansion.
-
- (*) Add support for the `XSAVE' instruction group.
-
- (*) Makefile for Netware/gcc.
-
- (*) Fix issue with some warnings getting emitted way too many times.
-
- (*) Autogenerated instruction list added to the documentation.
-
-C.1.10 Version 2.01
-
- (*) Fix the handling of MMX registers with explicit `qword' tags on
- memory (broken in 2.00 due to 64-bit changes.)
-
- (*) Fix the PREFETCH instructions.
-
- (*) Fix the documentation.
-
- (*) Fix debugging info when using `-f elf' (backwards compatibility
- alias for `-f elf32').
-
- (*) Man pages for rdoff tools (from the Debian project.)
-
- (*) ELF: handle large numbers of sections.
-
- (*) Fix corrupt output when the optimizer runs out of passes.
-
-C.1.11 Version 2.00
-
- (*) Added c99 data-type compliance.
-
- (*) Added general x86-64 support.
-
- (*) Added win64 (x86-64 COFF) output format.
-
- (*) Added `__BITS__' standard macro.
-
- (*) Renamed the `elf' output format to `elf32' for clarity.
-
- (*) Added `elf64' and `macho' (MacOS X) output formats.
-
- (*) Added Numeric constants in `dq' directive.
-
- (*) Added `oword', `do' and `reso' pseudo operands.
-
- (*) Allow underscores in numbers.
-
- (*) Added 8-, 16- and 128-bit floating-point formats.
-
- (*) Added binary, octal and hexadecimal floating-point.
-
- (*) Correct the generation of floating-point constants.
-
- (*) Added floating-point option control.
-
- (*) Added Infinity and NaN floating point support.
-
- (*) Added ELF Symbol Visibility support.
-
- (*) Added setting OSABI value in ELF header directive.
-
- (*) Added Generate Makefile Dependencies option.
-
- (*) Added Unlimited Optimization Passes option.
-
- (*) Added `%IFN' and `%ELIFN' support.
-
- (*) Added Logical Negation Operator.
-
- (*) Enhanced Stack Relative Preprocessor Directives.
-
- (*) Enhanced ELF Debug Formats.
-
- (*) Enhanced Send Errors to a File option.
-
- (*) Added SSSE3, SSE4.1, SSE4.2, SSE5 support.
-
- (*) Added a large number of additional instructions.
-
- (*) Significant performance improvements.
-
- (*) `-w+warning' and `-w-warning' can now be written as -Wwarning
- and -Wno-warning, respectively. See section 2.1.24.
-
- (*) Add `-w+error' to treat warnings as errors. See section 2.1.24.
-
- (*) Add `-w+all' and `-w-all' to enable or disable all suppressible
- warnings. See section 2.1.24.
-
- C.2 NASM 0.98 Series
-
- The 0.98 series was the production versions of NASM from 1999 to
- 2007.
-
- C.2.1 Version 0.98.39
-
- (*) fix buffer overflow
-
- (*) fix outas86's `.bss' handling
-
- (*) "make spotless" no longer deletes config.h.in.
-
- (*) `%(el)if(n)idn' insensitivity to string quotes difference
- (#809300).
-
- (*) (nasm.c)`__OUTPUT_FORMAT__' changed to string value instead of
- symbol.
-
- C.2.2 Version 0.98.38
-
- (*) Add Makefile for 16-bit DOS binaries under OpenWatcom, and
- modify `mkdep.pl' to be able to generate completely pathless
- dependencies, as required by OpenWatcom wmake (it supports path
- searches, but not explicit paths.)
-
- (*) Fix the `STR' instruction.
-
- (*) Fix the ELF output format, which was broken under certain
- circumstances due to the addition of stabs support.
-
- (*) Quick-fix Borland format debug-info for `-f obj'
-
- (*) Fix for `%rep' with no arguments (#560568)
-
- (*) Fix concatenation of preprocessor function call (#794686)
-
- (*) Fix long label causes coredump (#677841)
-
- (*) Use autoheader as well as autoconf to keep configure from
- generating ridiculously long command lines.
-
- (*) Make sure that all of the formats which support debugging output
- actually will suppress debugging output when `-g' not specified.
-
- C.2.3 Version 0.98.37
-
- (*) Paths given in `-I' switch searched for `incbin'-ed as well as
- `%include'-ed files.
-
- (*) Added stabs debugging for the ELF output format, patch from
- Martin Wawro.
-
- (*) Fix `output/outbin.c' to allow origin > 80000000h.
-
- (*) Make `-U' switch work.
-
- (*) Fix the use of relative offsets with explicit prefixes, e.g.
- `a32 loop foo'.
-
- (*) Remove `backslash()'.
-
- (*) Fix the `SMSW' and `SLDT' instructions.
-
- (*) `-O2' and `-O3' are no longer aliases for `-O10' and `-O15'. If
- you mean the latter, please say so! :)
-
- C.2.4 Version 0.98.36
-
- (*) Update rdoff - librarian/archiver - common rec - docs!
-
- (*) Fix signed/unsigned problems.
-
- (*) Fix `JMP FAR label' and `CALL FAR label'.
-
- (*) Add new multisection support - map files - fix align bug
-
- (*) Fix sysexit, movhps/movlps reg,reg bugs in insns.dat
-
- (*) `Q' or `O' suffixes indicate octal
-
- (*) Support Prescott new instructions (PNI).
-
- (*) Cyrix `XSTORE' instruction.
-
- C.2.5 Version 0.98.35
-
- (*) Fix build failure on 16-bit DOS (Makefile.bc3 workaround for
- compiler bug.)
-
- (*) Fix dependencies and compiler warnings.
-
- (*) Add "const" in a number of places.
-
- (*) Add -X option to specify error reporting format (use -Xvc to
- integrate with Microsoft Visual Studio.)
-
- (*) Minor changes for code legibility.
-
- (*) Drop use of tmpnam() in rdoff (security fix.)
-
- C.2.6 Version 0.98.34
-
- (*) Correct additional address-size vs. operand-size confusions.
-
- (*) Generate dependencies for all Makefiles automatically.
-
- (*) Add support for unimplemented (but theoretically available)
- registers such as tr0 and cr5. Segment registers 6 and 7 are
- called segr6 and segr7 for the operations which they can be
- represented.
-
- (*) Correct some disassembler bugs related to redundant address-size
- prefixes. Some work still remains in this area.
-
- (*) Correctly generate an error for things like "SEG eax".
-
- (*) Add the JMPE instruction, enabled by "CPU IA64".
-
- (*) Correct compilation on newer gcc/glibc platforms.
-
- (*) Issue an error on things like "jmp far eax".
-
- C.2.7 Version 0.98.33
-
- (*) New __NASM_PATCHLEVEL__ and __NASM_VERSION_ID__ standard macros
- to round out the version-query macros. version.pl now
- understands X.YYplWW or X.YY.ZZplWW as a version number,
- equivalent to X.YY.ZZ.WW (or X.YY.0.WW, as appropriate).
-
- (*) New keyword "strict" to disable the optimization of specific
- operands.
-
- (*) Fix the handing of size overrides with JMP instructions
- (instructions such as "jmp dword foo".)
-
- (*) Fix the handling of "ABSOLUTE label", where "label" points into
- a relocatable segment.
-
- (*) Fix OBJ output format with lots of externs.
-
- (*) More documentation updates.
-
- (*) Add -Ov option to get verbose information about optimizations.
-
- (*) Undo a braindead change which broke `%elif' directives.
-
- (*) Makefile updates.
-
- C.2.8 Version 0.98.32
-
- (*) Fix NASM crashing when `%macro' directives were left
- unterminated.
-
- (*) Lots of documentation updates.
-
- (*) Complete rewrite of the PostScript/PDF documentation generator.
-
- (*) The MS Visual C++ Makefile was updated and corrected.
-
- (*) Recognize .rodata as a standard section name in ELF.
-
- (*) Fix some obsolete Perl4-isms in Perl scripts.
-
- (*) Fix configure.in to work with autoconf 2.5x.
-
- (*) Fix a couple of "make cleaner" misses.
-
- (*) Make the normal "./configure && make" work with Cygwin.
-
- C.2.9 Version 0.98.31
-
- (*) Correctly build in a separate object directory again.
-
- (*) Derive all references to the version number from the version
- file.
-
- (*) New standard macros __NASM_SUBMINOR__ and __NASM_VER__ macros.
-
- (*) Lots of Makefile updates and bug fixes.
-
- (*) New `%ifmacro' directive to test for multiline macros.
-
- (*) Documentation updates.
-
- (*) Fixes for 16-bit OBJ format output.
-
- (*) Changed the NASM environment variable to NASMENV.
-
-C.2.10 Version 0.98.30
-
- (*) Changed doc files a lot: completely removed old READMExx and
- Wishlist files, incorporating all information in CHANGES and
- TODO.
-
- (*) I waited a long time to rename zoutieee.c to (original)
- outieee.c
-
- (*) moved all output modules to output/ subdirectory.
-
- (*) Added 'make strip' target to strip debug info from nasm &
- ndisasm.
-
- (*) Added INSTALL file with installation instructions.
-
- (*) Added -v option description to nasm man.
-
- (*) Added dist makefile target to produce source distributions.
-
- (*) 16-bit support for ELF output format (GNU extension, but
- useful.)
-
-C.2.11 Version 0.98.28
-
- (*) Fastcooked this for Debian's Woody release: Frank applied the
- INCBIN bug patch to 0.98.25alt and called it 0.98.28 to not
- confuse poor little apt-get.
-
-C.2.12 Version 0.98.26
-
- (*) Reorganised files even better from 0.98.25alt
-
-C.2.13 Version 0.98.25alt
-
- (*) Prettified the source tree. Moved files to more reasonable
- places.
-
- (*) Added findleak.pl script to misc/ directory.
-
- (*) Attempted to fix doc.
-
-C.2.14 Version 0.98.25
-
- (*) Line continuation character `\'.
-
- (*) Docs inadvertantly reverted - "dos packaging".
-
-C.2.15 Version 0.98.24p1
-
- (*) FIXME: Someone, document this please.
-
-C.2.16 Version 0.98.24
-
- (*) Documentation - Ndisasm doc added to Nasm.doc.
-
-C.2.17 Version 0.98.23
-
- (*) Attempted to remove rdoff version1
-
- (*) Lino Mastrodomenico's patches to preproc.c (%$$ bug?).
-
-C.2.18 Version 0.98.22
-
- (*) Update rdoff2 - attempt to remove v1.
-
-C.2.19 Version 0.98.21
-
- (*) Optimization fixes.
-
-C.2.20 Version 0.98.20
-
- (*) Optimization fixes.
-
-C.2.21 Version 0.98.19
-
- (*) H. J. Lu's patch back out.
-
-C.2.22 Version 0.98.18
-
- (*) Added ".rdata" to "-f win32".
-
-C.2.23 Version 0.98.17
-
- (*) H. J. Lu's "bogus elf" patch. (Red Hat problem?)
-
-C.2.24 Version 0.98.16
-
- (*) Fix whitespace before "[section ..." bug.
-
-C.2.25 Version 0.98.15
-
- (*) Rdoff changes (?).
-
- (*) Fix fixes to memory leaks.
-
-C.2.26 Version 0.98.14
-
- (*) Fix memory leaks.
-
-C.2.27 Version 0.98.13
-
- (*) There was no 0.98.13
-
-C.2.28 Version 0.98.12
-
- (*) Update optimization (new function of "-O1")
-
- (*) Changes to test/bintest.asm (?).
-
-C.2.29 Version 0.98.11
-
- (*) Optimization changes.
-
- (*) Ndisasm fixed.
-
-C.2.30 Version 0.98.10
-
- (*) There was no 0.98.10
-
-C.2.31 Version 0.98.09
-
- (*) Add multiple sections support to "-f bin".
-
- (*) Changed GLOBAL_TEMP_BASE in outelf.c from 6 to 15.
-
- (*) Add "-v" as an alias to the "-r" switch.
-
- (*) Remove "#ifdef" from Tasm compatibility options.
-
- (*) Remove redundant size-overrides on "mov ds, ex", etc.
-
- (*) Fixes to SSE2, other insns.dat (?).
-
- (*) Enable uppercase "I" and "P" switches.
-
- (*) Case insinsitive "seg" and "wrt".
-
- (*) Update install.sh (?).
-
- (*) Allocate tokens in blocks.
-
- (*) Improve "invalid effective address" messages.
-
-C.2.32 Version 0.98.08
-
- (*) Add "`%strlen'" and "`%substr'" macro operators
-
- (*) Fixed broken c16.mac.
-
- (*) Unterminated string error reported.
-
- (*) Fixed bugs as per 0.98bf
-
-C.2.33 Version 0.98.09b with John Coffman patches released 28-Oct-2001
-
- Changes from 0.98.07 release to 98.09b as of 28-Oct-2001
-
- (*) More closely compatible with 0.98 when -O0 is implied or
- specified. Not strictly identical, since backward branches in
- range of short offsets are recognized, and signed byte values
- with no explicit size specification will be assembled as a
- single byte.
-
- (*) More forgiving with the PUSH instruction. 0.98 requires a size
- to be specified always. 0.98.09b will imply the size from the
- current BITS setting (16 or 32).
-
- (*) Changed definition of the optimization flag:
-
- -O0 strict two-pass assembly, JMP and Jcc are handled more like
- 0.98, except that back- ward JMPs are short, if possible.
-
- -O1 strict two-pass assembly, but forward branches are assembled
- with code guaranteed to reach; may produce larger code than -O0, but
- will produce successful assembly more often if branch offset sizes
- are not specified.
-
- -O2 multi-pass optimization, minimize branch offsets; also will
- minimize signed immed- iate bytes, overriding size specification.
-
- -O3 like -O2, but more passes taken, if needed
-
-C.2.34 Version 0.98.07 released 01/28/01
-
- (*) Added Stepane Denis' SSE2 instructions to a *working* version of
- the code - some earlier versions were based on broken code -
- sorry 'bout that. version "0.98.07"
-
- 01/28/01
-
- (*) Cosmetic modifications to nasm.c, nasm.h, AUTHORS, MODIFIED
-
-C.2.35 Version 0.98.06f released 01/18/01
-
- (*) - Add "metalbrain"s jecxz bug fix in insns.dat - alter
- nasmdoc.src to match - version "0.98.06f"
-
-C.2.36 Version 0.98.06e released 01/09/01
-
- (*) Removed the "outforms.h" file - it appears to be someone's old
- backup of "outform.h". version "0.98.06e"
-
- 01/09/01
-
- (*) fbk - finally added the fix for the "multiple %includes bug",
- known since 7/27/99 - reported originally (?) and sent to us by
- Austin Lunnen - he reports that John Fine had a fix within the
- day. Here it is...
-
- (*) Nelson Rush resigns from the group. Big thanks to Nelson for his
- leadership and enthusiasm in getting these changes incorporated
- into Nasm!
-
- (*) fbk - [list +], [list -] directives - ineptly implemented,
- should be re-written or removed, perhaps.
-
- (*) Brian Raiter / fbk - "elfso bug" fix - applied to aoutb format
- as well - testing might be desirable...
-
- 08/07/00
-
- (*) James Seter - -postfix, -prefix command line switches.
-
- (*) Yuri Zaporogets - rdoff utility changes.
-
-C.2.37 Version 0.98p1
-
- (*) GAS-like palign (Panos Minos)
-
- (*) FIXME: Someone, fill this in with details
-
-C.2.38 Version 0.98bf (bug-fixed)
-
- (*) Fixed - elf and aoutb bug - shared libraries - multiple
- "%include" bug in "-f obj" - jcxz, jecxz bug - unrecognized
- option bug in ndisasm
-
-C.2.39 Version 0.98.03 with John Coffman's changes released 27-Jul-2000
-
- (*) Added signed byte optimizations for the 0x81/0x83 class of
- instructions: ADC, ADD, AND, CMP, OR, SBB, SUB, XOR: when used
- as 'ADD reg16,imm' or 'ADD reg32,imm.' Also optimization of
- signed byte form of 'PUSH imm' and 'IMUL reg,imm'/'IMUL
- reg,reg,imm.' No size specification is needed.
-
- (*) Added multi-pass JMP and Jcc offset optimization. Offsets on
- forward references will preferentially use the short form,
- without the need to code a specific size (short or near) for the
- branch. Added instructions for 'Jcc label' to use the form
- 'Jnotcc $+3/JMP label', in cases where a short offset is out of
- bounds. If compiling for a 386 or higher CPU, then the 386 form
- of Jcc will be used instead.
-
- This feature is controlled by a new command-line switch: "O", (upper
- case letter O). "-O0" reverts the assembler to no extra optimization
- passes, "-O1" allows up to 5 extra passes, and "-O2"(default),
- allows up to 10 extra optimization passes.
-
- (*) Added a new directive: 'cpu XXX', where XXX is any of: 8086,
- 186, 286, 386, 486, 586, pentium, 686, PPro, P2, P3 or Katmai.
- All are case insensitive. All instructions will be selected only
- if they apply to the selected cpu or lower. Corrected a couple
- of bugs in cpu-dependence in 'insns.dat'.
-
- (*) Added to 'standard.mac', the "use16" and "use32" forms of the
- "bits 16/32" directive. This is nothing new, just conforms to a
- lot of other assemblers. (minor)
-
- (*) Changed label allocation from 320/32 (10000 labels @ 200K+) to
- 32/37 (1000 labels); makes running under DOS much easier. Since
- additional label space is allocated dynamically, this should
- have no effect on large programs with lots of labels. The 37 is
- a prime, believed to be better for hashing. (minor)
-
-C.2.40 Version 0.98.03
-
- "Integrated patchfile 0.98-0.98.01. I call this version 0.98.03 for
- historical reasons: 0.98.02 was trashed." --John Coffman
- <johninsd@san.rr.com>, 27-Jul-2000
-
- (*) Kendall Bennett's SciTech MGL changes
-
- (*) Note that you must define "TASM_COMPAT" at compile-time to get
- the Tasm Ideal Mode compatibility.
-
- (*) All changes can be compiled in and out using the TASM_COMPAT
- macros, and when compiled without TASM_COMPAT defined we get the
- exact same binary as the unmodified 0.98 sources.
-
- (*) standard.mac, macros.c: Added macros to ignore TASM directives
- before first include
-
- (*) nasm.h: Added extern declaration for tasm_compatible_mode
-
- (*) nasm.c: Added global variable tasm_compatible_mode
-
- (*) Added command line switch for TASM compatible mode (-t)
-
- (*) Changed version command line to reflect when compiled with TASM
- additions
-
- (*) Added response file processing to allow all arguments on a
- single line (response file is @resp rather than -@resp for NASM
- format).
-
- (*) labels.c: Changes islocal() macro to support TASM style @@local
- labels.
-
- (*) Added islocalchar() macro to support TASM style @@local labels.
-
- (*) parser.c: Added support for TASM style memory references (ie:
- mov [DWORD eax],10 rather than the NASM style mov DWORD
- [eax],10).
-
- (*) preproc.c: Added new directives, `%arg', `%local', `%stacksize'
- to directives table
-
- (*) Added support for TASM style directives without a leading %
- symbol.
-
- (*) Integrated a block of changes from Andrew Zabolotny
- <bit@eltech.ru>:
-
- (*) A new keyword `%xdefine' and its case-insensitive counterpart
- `%ixdefine'. They work almost the same way as `%define' and
- `%idefine' but expand the definition immediately, not on the
- invocation. Something like a cross between `%define' and
- `%assign'. The "x" suffix stands for "eXpand", so "xdefine" can
- be deciphered as "expand-and-define". Thus you can do things
- like this:
-
- %assign ofs 0
-
- %macro arg 1
- %xdefine %1 dword [esp+ofs]
- %assign ofs ofs+4
- %endmacro
-
- (*) Changed the place where the expansion of %$name macros are
- expanded. Now they are converted into ..@ctxnum.name form when
- detokenizing, so there are no quirks as before when using %$name
- arguments to macros, in macros etc. For example:
-
- %macro abc 1
- %define %1 hello
- %endm
-
- abc %$here
- %$here
-
- Now last line will be expanded into "hello" as expected. This also
- allows for lots of goodies, a good example are extended "proc"
- macros included in this archive.
-
- (*) Added a check for "cstk" in smacro_defined() before calling
- get_ctx() - this allows for things like:
-
- %ifdef %$abc
- %endif
-
- to work without warnings even in no context.
-
- (*) Added a check for "cstk" in %if*ctx and %elif*ctx directives -
- this allows to use `%ifctx' without excessive warnings. If there
- is no active context, `%ifctx' goes through "false" branch.
-
- (*) Removed "user error: " prefix with `%error' directive: it just
- clobbers the output and has absolutely no functionality.
- Besides, this allows to write macros that does not differ from
- built-in functions in any way.
-
- (*) Added expansion of string that is output by `%error' directive.
- Now you can do things like:
-
- %define hello(x) Hello, x!
-
- %define %$name andy
- %error "hello(%$name)"
-
- Same happened with `%include' directive.
-
- (*) Now all directives that expect an identifier will try to expand
- and concatenate everything without whitespaces in between before
- usage. For example, with "unfixed" nasm the commands
-
- %define %$abc hello
- %define __%$abc goodbye
- __%$abc
-
- would produce "incorrect" output: last line will expand to
-
- hello goodbyehello
-
- Not quite what you expected, eh? :-) The answer is that preprocessor
- treats the `%define' construct as if it would be
-
- %define __ %$abc goodbye
-
- (note the white space between __ and %$abc). After my "fix" it will
- "correctly" expand into
-
- goodbye
-
- as expected. Note that I use quotes around words "correct",
- "incorrect" etc because this is rather a feature not a bug; however
- current behaviour is more logical (and allows more advanced macro
- usage :-).
-
- Same change was applied to:
- `%push',`%macro',`%imacro',`%define',`%idefine',`%xdefine',`%ixdefine',
- `%assign',`%iassign',`%undef'
-
- (*) A new directive [WARNING {+|-}warning-id] have been added. It
- works only if the assembly phase is enabled (i.e. it doesn't
- work with nasm -e).
-
- (*) A new warning type: macro-selfref. By default this warning is
- disabled; when enabled NASM warns when a macro self-references
- itself; for example the following source:
-
- [WARNING macro-selfref]
-
- %macro push 1-*
- %rep %0
- push %1
- %rotate 1
- %endrep
- %endmacro
-
- push eax,ebx,ecx
-
- will produce a warning, but if we remove the first line we won't see
- it anymore (which is The Right Thing To Do {tm} IMHO since C
- preprocessor eats such constructs without warnings at all).
-
- (*) Added a "error" routine to preprocessor which always will set
- ERR_PASS1 bit in severity_code. This removes annoying repeated
- errors on first and second passes from preprocessor.
-
- (*) Added the %+ operator in single-line macros for concatenating
- two identifiers. Usage example:
-
- %define _myfunc _otherfunc
- %define cextern(x) _ %+ x
- cextern (myfunc)
-
- After first expansion, third line will become "_myfunc". After this
- expansion is performed again so it becomes "_otherunc".
-
- (*) Now if preprocessor is in a non-emitting state, no warning or
- error will be emitted. Example:
-
- %if 1
- mov eax,ebx
- %else
- put anything you want between these two brackets,
- even macro-parameter references %1 or local
- labels %$zz or macro-local labels %%zz - no
- warning will be emitted.
- %endif
-
- (*) Context-local variables on expansion as a last resort are looked
- up in outer contexts. For example, the following piece:
-
- %push outer
- %define %$a [esp]
-
- %push inner
- %$a
- %pop
- %pop
-
- will expand correctly the fourth line to [esp]; if we'll define
- another %$a inside the "inner" context, it will take precedence over
- outer definition. However, this modification has been applied only
- to expand_smacro and not to smacro_define: as a consequence
- expansion looks in outer contexts, but `%ifdef' won't look in outer
- contexts.
-
- This behaviour is needed because we don't want nested contexts to
- act on already defined local macros. Example:
-
- %define %$arg1 [esp+4]
- test eax,eax
- if nz
- mov eax,%$arg1
- endif
-
- In this example the "if" mmacro enters into the "if" context, so
- %$arg1 is not valid anymore inside "if". Of course it could be
- worked around by using explicitely %$$arg1 but this is ugly IMHO.
-
- (*) Fixed memory leak in `%undef'. The origline wasn't freed before
- exiting on success.
-
- (*) Fixed trap in preprocessor when line expanded to empty set of
- tokens. This happens, for example, in the following case:
-
- #define SOMETHING
- SOMETHING
-
-C.2.41 Version 0.98
-
- All changes since NASM 0.98p3 have been produced by H. Peter Anvin
- <hpa@zytor.com>.
-
- (*) The documentation comment delimiter is
-
- (*) Allow EQU definitions to refer to external labels; reported by
- Pedro Gimeno.
-
- (*) Re-enable support for RDOFF v1; reported by Pedro Gimeno.
-
- (*) Updated License file per OK from Simon and Julian.
-
-C.2.42 Version 0.98p9
-
- (*) Update documentation (although the instruction set reference
- will have to wait; I don't want to hold up the 0.98 release for
- it.)
-
- (*) Verified that the NASM implementation of the PEXTRW and PMOVMSKB
- instructions is correct. The encoding differs from what the
- Intel manuals document, but the Pentium III behaviour matches
- NASM, not the Intel manuals.
-
- (*) Fix handling of implicit sizes in PSHUFW and PINSRW, reported by
- Stefan Hoffmeister.
-
- (*) Resurrect the -s option, which was removed when changing the
- diagnostic output to stdout.
-
-C.2.43 Version 0.98p8
-
- (*) Fix for "DB" when NASM is running on a bigendian machine.
-
- (*) Invoke insns.pl once for each output script, making Makefile.in
- legal for "make -j".
-
- (*) Improve the Unix configure-based makefiles to make package
- creation easier.
-
- (*) Included an RPM .spec file for building RPM (RedHat Package
- Manager) packages on Linux or Unix systems.
-
- (*) Fix Makefile dependency problems.
-
- (*) Change src/rdsrc.pl to include sectioning information in info
- output; required for install-info to work.
-
- (*) Updated the RDOFF distribution to version 2 from Jules; minor
- massaging to make it compile in my environment.
-
- (*) Split doc files that can be built by anyone with a Perl
- interpreter off into a separate archive.
-
- (*) "Dress rehearsal" release!
-
-C.2.44 Version 0.98p7
-
- (*) Fixed opcodes with a third byte-sized immediate argument to not
- complain if given "byte" on the immediate.
-
- (*) Allow `%undef' to remove single-line macros with arguments. This
- matches the behaviour of #undef in the C preprocessor.
-
- (*) Allow -d, -u, -i and -p to be specified as -D, -U, -I and -P for
- compatibility with most C compilers and preprocessors. This
- allows Makefile options to be shared between cc and nasm, for
- example.
-
- (*) Minor cleanups.
-
- (*) Went through the list of Katmai instructions and hopefully fixed
- the (rather few) mistakes in it.
-
- (*) (Hopefully) fixed a number of disassembler bugs related to
- ambiguous instructions (disambiguated by -p) and SSE
- instructions with REP.
-
- (*) Fix for bug reported by Mark Junger: "call dword 0x12345678"
- should work and may add an OSP (affected CALL, JMP, Jcc).
-
- (*) Fix for environments when "stderr" isn't a compile-time
- constant.
-
-C.2.45 Version 0.98p6
-
- (*) Took officially over coordination of the 0.98 release; so drop
- the p3.x notation. Skipped p4 and p5 to avoid confusion with
- John Fine's J4 and J5 releases.
-
- (*) Update the documentation; however, it still doesn't include
- documentation for the various new instructions. I somehow wonder
- if it makes sense to have an instruction set reference in the
- assembler manual when Intel et al have PDF versions of their
- manuals online.
-
- (*) Recognize "idt" or "centaur" for the -p option to ndisasm.
-
- (*) Changed error messages back to stderr where they belong, but add
- an -E option to redirect them elsewhere (the DOS shell cannot
- redirect stderr.)
-
- (*) -M option to generate Makefile dependencies (based on code from
- Alex Verstak.)
-
- (*) `%undef' preprocessor directive, and -u option, that undefines a
- single-line macro.
-
- (*) OS/2 Makefile (Mkfiles/Makefile.os2) for Borland under OS/2;
- from Chuck Crayne.
-
- (*) Various minor bugfixes (reported by): - Dangling `%s' in
- preproc.c (Martin Junker)
-
- (*) THERE ARE KNOWN BUGS IN SSE AND THE OTHER KATMAI INSTRUCTIONS. I
- am on a trip and didn't bring the Katmai instruction reference,
- so I can't work on them right now.
-
- (*) Updated the License file per agreement with Simon and Jules to
- include a GPL distribution clause.
-
-C.2.46 Version 0.98p3.7
-
- (*) (Hopefully) fixed the canned Makefiles to include the outrdf2
- and zoutieee modules.
-
- (*) Renamed changes.asm to changed.asm.
-
-C.2.47 Version 0.98p3.6
-
- (*) Fixed a bunch of instructions that were added in 0.98p3.5 which
- had memory operands, and the address-size prefix was missing
- from the instruction pattern.
-
-C.2.48 Version 0.98p3.5
-
- (*) Merged in changes from John S. Fine's 0.98-J5 release. John's
- based 0.98-J5 on my 0.98p3.3 release; this merges the changes.
-
- (*) Expanded the instructions flag field to a long so we can fit
- more flags; mark SSE (KNI) and AMD or Katmai-specific
- instructions as such.
-
- (*) Fix the "PRIV" flag on a bunch of instructions, and create new
- "PROT" flag for protected-mode-only instructions (orthogonal to
- if the instruction is privileged!) and new "SMM" flag for SMM-
- only instructions.
-
- (*) Added AMD-only SYSCALL and SYSRET instructions.
-
- (*) Make SSE actually work, and add new Katmai MMX instructions.
-
- (*) Added a -p (preferred vendor) option to ndisasm so that it can
- distinguish e.g. Cyrix opcodes also used in SSE. For example:
-
- ndisasm -p cyrix aliased.bin
- 00000000 670F514310 paddsiw mm0,[ebx+0x10]
- 00000005 670F514320 paddsiw mm0,[ebx+0x20]
- ndisasm -p intel aliased.bin
- 00000000 670F514310 sqrtps xmm0,[ebx+0x10]
- 00000005 670F514320 sqrtps xmm0,[ebx+0x20]
-
- (*) Added a bunch of Cyrix-specific instructions.
-
-C.2.49 Version 0.98p3.4
-
- (*) Made at least an attempt to modify all the additional Makefiles
- (in the Mkfiles directory). I can't test it, but this was the
- best I could do.
-
- (*) DOS DJGPP+"Opus Make" Makefile from John S. Fine.
-
- (*) changes.asm changes from John S. Fine.
-
-C.2.50 Version 0.98p3.3
-
- (*) Patch from Conan Brink to allow nesting of `%rep' directives.
-
- (*) If we're going to allow INT01 as an alias for INT1/ICEBP (one of
- Jules 0.98p3 changes), then we should allow INT03 as an alias
- for INT3 as well.
-
- (*) Updated changes.asm to include the latest changes.
-
- (*) Tried to clean up the <CR>s that had snuck in from a DOS/Windows
- environment into my Unix environment, and try to make sure than
- DOS/Windows users get them back.
-
- (*) We would silently generate broken tools if insns.dat wasn't
- sorted properly. Change insns.pl so that the order doesn't
- matter.
-
- (*) Fix bug in insns.pl (introduced by me) which would cause
- conditional instructions to have an extra "cc" in disassembly,
- e.g. "jnz" disassembled as "jccnz".
-
-C.2.51 Version 0.98p3.2
-
- (*) Merged in John S. Fine's changes from his 0.98-J4 prerelease;
- see http://www.csoft.net/cz/johnfine/
-
- (*) Changed previous "spotless" Makefile target (appropriate for
- distribution) to "distclean", and added "cleaner" target which
- is same as "clean" except deletes files generated by Perl
- scripts; "spotless" is union.
-
- (*) Removed BASIC programs from distribution. Get a Perl interpreter
- instead (see below.)
-
- (*) Calling this "pre-release 3.2" rather than "p3-hpa2" because of
- John's contributions.
-
- (*) Actually link in the IEEE output format (zoutieee.c); fix a
- bunch of compiler warnings in that file. Note I don't know what
- IEEE output is supposed to look like, so these changes were made
- "blind".
-
-C.2.52 Version 0.98p3-hpa
-
- (*) Merged nasm098p3.zip with nasm-0.97.tar.gz to create a fully
- buildable version for Unix systems (Makefile.in updates, etc.)
-
- (*) Changed insns.pl to create the instruction tables in nasm.h and
- names.c, so that a new instruction can be added by adding it
- *only* to insns.dat.
-
- (*) Added the following new instructions: SYSENTER, SYSEXIT, FXSAVE,
- FXRSTOR, UD1, UD2 (the latter two are two opcodes that Intel
- guarantee will never be used; one of them is documented as UD2
- in Intel documentation, the other one just as "Undefined Opcode"
- -- calling it UD1 seemed to make sense.)
-
- (*) MAX_SYMBOL was defined to be 9, but LOADALL286 and LOADALL386
- are 10 characters long. Now MAX_SYMBOL is derived from
- insns.dat.
-
- (*) A note on the BASIC programs included: forget them. insns.bas is
- already out of date. Get yourself a Perl interpreter for your
- platform of choice at http://www.cpan.org/ports/index.html.
-
-C.2.53 Version 0.98 pre-release 3
-
- (*) added response file support, improved command line handling, new
- layout help screen
-
- (*) fixed limit checking bug, 'OUT byte nn, reg' bug, and a couple
- of rdoff related bugs, updated Wishlist; 0.98 Prerelease 3.
-
-C.2.54 Version 0.98 pre-release 2
-
- (*) fixed bug in outcoff.c to do with truncating section names
- longer than 8 characters, referencing beyond end of string; 0.98
- pre-release 2
-
-C.2.55 Version 0.98 pre-release 1
-
- (*) Fixed a bug whereby STRUC didn't work at all in RDF.
-
- (*) Fixed a problem with group specification in PUBDEFs in OBJ.
-
- (*) Improved ease of adding new output formats. Contribution due to
- Fox Cutter.
-
- (*) Fixed a bug in relocations in the `bin' format: was showing up
- when a relocatable reference crossed an 8192-byte boundary in
- any output section.
-
- (*) Fixed a bug in local labels: local-label lookups were
- inconsistent between passes one and two if an EQU occurred
- between the definition of a global label and the subsequent use
- of a local label local to that global.
-
- (*) Fixed a seg-fault in the preprocessor (again) which happened
- when you use a blank line as the first line of a multi-line
- macro definition and then defined a label on the same line as a
- call to that macro.
-
- (*) Fixed a stale-pointer bug in the handling of the NASM
- environment variable. Thanks to Thomas McWilliams.
-
- (*) ELF had a hard limit on the number of sections which caused
- segfaults when transgressed. Fixed.
-
- (*) Added ability for ndisasm to read from stdin by using `-' as the
- filename.
-
- (*) ndisasm wasn't outputting the TO keyword. Fixed.
-
- (*) Fixed error cascade on bogus expression in `%if' - an error in
- evaluation was causing the entire `%if' to be discarded, thus
- creating trouble later when the `%else' or `%endif' was
- encountered.
-
- (*) Forward reference tracking was instruction-granular not operand-
- granular, which was causing 286-specific code to be generated
- needlessly on code of the form `shr word [forwardref],1'. Thanks
- to Jim Hague for sending a patch.
-
- (*) All messages now appear on stdout, as sending them to stderr
- serves no useful purpose other than to make redirection
- difficult.
-
- (*) Fixed the problem with EQUs pointing to an external symbol -
- this now generates an error message.
-
- (*) Allowed multiple size prefixes to an operand, of which only the
- first is taken into account.
-
- (*) Incorporated John Fine's changes, including fixes of a large
- number of preprocessor bugs, some small problems in OBJ, and a
- reworking of label handling to define labels before their line
- is assembled, rather than after.
-
- (*) Reformatted a lot of the source code to be more readable.
- Included 'coding.txt' as a guideline for how to format code for
- contributors.
-
- (*) Stopped nested `%reps' causing a panic - they now cause a
- slightly more friendly error message instead.
-
- (*) Fixed floating point constant problems (patch by Pedro Gimeno)
-
- (*) Fixed the return value of insn_size() not being checked for -1,
- indicating an error.
-
- (*) Incorporated 3Dnow! instructions.
-
- (*) Fixed the 'mov eax, eax + ebx' bug.
-
- (*) Fixed the GLOBAL EQU bug in ELF. Released developers release 3.
-
- (*) Incorporated John Fine's command line parsing changes
-
- (*) Incorporated David Lindauer's OMF debug support
-
- (*) Made changes for LCC 4.0 support (`__NASM_CDecl__', removed
- register size specification warning when sizes agree).
-
- C.3 NASM 0.9 Series
-
- Revisions before 0.98.
-
- C.3.1 Version 0.97 released December 1997
-
- (*) This was entirely a bug-fix release to 0.96, which seems to have
- got cursed. Silly me.
-
- (*) Fixed stupid mistake in OBJ which caused `MOV EAX,<constant>' to
- fail. Caused by an error in the `MOV EAX,<segment>' support.
-
- (*) ndisasm hung at EOF when compiled with lcc on Linux because lcc
- on Linux somehow breaks feof(). ndisasm now does not rely on
- feof().
-
- (*) A heading in the documentation was missing due to a markup error
- in the indexing. Fixed.
-
- (*) Fixed failure to update all pointers on realloc() within
- extended- operand code in parser.c. Was causing wrong behaviour
- and seg faults on lines such as `dd 0.0,0.0,0.0,0.0,...'
-
- (*) Fixed a subtle preprocessor bug whereby invoking one multi-line
- macro on the first line of the expansion of another, when the
- second had been invoked with a label defined before it, didn't
- expand the inner macro.
-
- (*) Added internal.doc back in to the distribution archives - it was
- missing in 0.96 *blush*
-
- (*) Fixed bug causing 0.96 to be unable to assemble its own test
- files, specifically objtest.asm. *blush again*
-
- (*) Fixed seg-faults and bogus error messages caused by mismatching
- `%rep' and `%endrep' within multi-line macro definitions.
-
- (*) Fixed a problem with buffer overrun in OBJ, which was causing
- corruption at ends of long PUBDEF records.
-
- (*) Separated DOS archives into main-program and documentation to
- reduce download size.
-
- C.3.2 Version 0.96 released November 1997
-
- (*) Fixed a bug whereby, if `nasm sourcefile' would cause a filename
- collision warning and put output into `nasm.out', then `nasm
- sourcefile -o outputfile' still gave the warning even though the
- `-o' was honoured. Fixed name pollution under Digital UNIX: one
- of its header files defined R_SP, which broke the enum in
- nasm.h.
-
- (*) Fixed minor instruction table problems: FUCOM and FUCOMP didn't
- have two-operand forms; NDISASM didn't recognise the longer
- register forms of PUSH and POP (eg FF F3 for PUSH BX); TEST
- mem,imm32 was flagged as undocumented; the 32-bit forms of CMOV
- had 16-bit operand size prefixes; `AAD imm' and `AAM imm' are no
- longer flagged as undocumented because the Intel Architecture
- reference documents them.
-
- (*) Fixed a problem with the local-label mechanism, whereby strange
- types of symbol (EQUs, auto-defined OBJ segment base symbols)
- interfered with the `previous global label' value and screwed up
- local labels.
-
- (*) Fixed a bug whereby the stub preprocessor didn't communicate
- with the listing file generator, so that the -a and -l options
- in conjunction would produce a useless listing file.
-
- (*) Merged `os2' object file format back into `obj', after
- discovering that `obj' _also_ shouldn't have a link pass
- separator in a module containing a non-trivial MODEND. Flat
- segments are now declared using the FLAT attribute. `os2' is no
- longer a valid object format name: use `obj'.
-
- (*) Removed the fixed-size temporary storage in the evaluator. Very
- very long expressions (like `mov ax,1+1+1+1+...' for two hundred
- 1s or so) should now no longer crash NASM.
-
- (*) Fixed a bug involving segfaults on disassembly of MMX
- instructions, by changing the meaning of one of the operand-type
- flags in nasm.h. This may cause other apparently unrelated MMX
- problems; it needs to be tested thoroughly.
-
- (*) Fixed some buffer overrun problems with large OBJ output files.
- Thanks to DJ Delorie for the bug report and fix.
-
- (*) Made preprocess-only mode actually listen to the `%line' markers
- as it prints them, so that it can report errors more sanely.
-
- (*) Re-designed the evaluator to keep more sensible track of
- expressions involving forward references: can now cope with
- previously-nightmare situations such as:
-
- mov ax,foo | bar
- foo equ 1
- bar equ 2
-
- (*) Added the ALIGN and ALIGNB standard macros.
-
- (*) Added PIC support in ELF: use of WRT to obtain the four extra
- relocation types needed.
-
- (*) Added the ability for output file formats to define their own
- extensions to the GLOBAL, COMMON and EXTERN directives.
-
- (*) Implemented common-variable alignment, and global-symbol type
- and size declarations, in ELF.
-
- (*) Implemented NEAR and FAR keywords for common variables, plus
- far-common element size specification, in OBJ.
-
- (*) Added a feature whereby EXTERNs and COMMONs in OBJ can be given
- a default WRT specification (either a segment or a group).
-
- (*) Transformed the Unix NASM archive into an auto-configuring
- package.
-
- (*) Added a sanity-check for people applying SEG to things which are
- already segment bases: this previously went unnoticed by the SEG
- processing and caused OBJ-driver panics later.
-
- (*) Added the ability, in OBJ format, to deal with `MOV
- EAX,<segment>' type references: OBJ doesn't directly support
- dword-size segment base fixups, but as long as the low two bytes
- of the constant term are zero, a word-size fixup can be
- generated instead and it will work.
-
- (*) Added the ability to specify sections' alignment requirements in
- Win32 object files and pure binary files.
-
- (*) Added preprocess-time expression evaluation: the `%assign' (and
- `%iassign') directive and the bare `%if' (and `%elif')
- conditional. Added relational operators to the evaluator, for
- use only in `%if' constructs: the standard relationals = < > <=
- >= <> (and C-like synonyms == and !=) plus low-precedence
- logical operators &&, ^^ and ||.
-
- (*) Added a preprocessor repeat construct: `%rep' / `%exitrep' /
- `%endrep'.
-
- (*) Added the __FILE__ and __LINE__ standard macros.
-
- (*) Added a sanity check for number constants being greater than
- 0xFFFFFFFF. The warning can be disabled.
-
- (*) Added the %0 token whereby a variadic multi-line macro can tell
- how many parameters it's been given in a specific invocation.
-
- (*) Added `%rotate', allowing multi-line macro parameters to be
- cycled.
-
- (*) Added the `*' option for the maximum parameter count on multi-
- line macros, allowing them to take arbitrarily many parameters.
-
- (*) Added the ability for the user-level forms of EXTERN, GLOBAL and
- COMMON to take more than one argument.
-
- (*) Added the IMPORT and EXPORT directives in OBJ format, to deal
- with Windows DLLs.
-
- (*) Added some more preprocessor `%if' constructs: `%ifidn' /
- `%ifidni' (exact textual identity), and `%ifid' / `%ifnum' /
- `%ifstr' (token type testing).
-
- (*) Added the ability to distinguish SHL AX,1 (the 8086 version)
- from SHL AX,BYTE 1 (the 286-and-upwards version whose constant
- happens to be 1).
-
- (*) Added NetBSD/FreeBSD/OpenBSD's variant of a.out format, complete
- with PIC shared library features.
-
- (*) Changed NASM's idiosyncratic handling of FCLEX, FDISI, FENI,
- FINIT, FSAVE, FSTCW, FSTENV, and FSTSW to bring it into line
- with the otherwise accepted standard. The previous behaviour,
- though it was a deliberate feature, was a deliberate feature
- based on a misunderstanding. Apologies for the inconvenience.
-
- (*) Improved the flexibility of ABSOLUTE: you can now give it an
- expression rather than being restricted to a constant, and it
- can take relocatable arguments as well.
-
- (*) Added the ability for a variable to be declared as EXTERN
- multiple times, and the subsequent definitions are just ignored.
-
- (*) We now allow instruction prefixes (CS, DS, LOCK, REPZ etc) to be
- alone on a line (without a following instruction).
-
- (*) Improved sanity checks on whether the arguments to EXTERN,
- GLOBAL and COMMON are valid identifiers.
-
- (*) Added misc/exebin.mac to allow direct generation of .EXE files
- by hacking up an EXE header using DB and DW; also added
- test/binexe.asm to demonstrate the use of this. Thanks to Yann
- Guidon for contributing the EXE header code.
-
- (*) ndisasm forgot to check whether the input file had been
- successfully opened. Now it does. Doh!
-
- (*) Added the Cyrix extensions to the MMX instruction set.
-
- (*) Added a hinting mechanism to allow [EAX+EBX] and [EBX+EAX] to be
- assembled differently. This is important since [ESI+EBP] and
- [EBP+ESI] have different default base segment registers.
-
- (*) Added support for the PharLap OMF extension for 4096-byte
- segment alignment.
-
- C.3.3 Version 0.95 released July 1997
-
- (*) Fixed yet another ELF bug. This one manifested if the user
- relied on the default segment, and attempted to define global
- symbols without first explicitly declaring the target segment.
-
- (*) Added makefiles (for NASM and the RDF tools) to build Win32
- console apps under Symantec C++. Donated by Mark Junker.
-
- (*) Added `macros.bas' and `insns.bas', QBasic versions of the Perl
- scripts that convert `standard.mac' to `macros.c' and convert
- `insns.dat' to `insnsa.c' and `insnsd.c'. Also thanks to Mark
- Junker.
-
- (*) Changed the diassembled forms of the conditional instructions so
- that JB is now emitted as JC, and other similar changes.
- Suggested list by Ulrich Doewich.
-
- (*) Added `@' to the list of valid characters to begin an identifier
- with.
-
- (*) Documentary changes, notably the addition of the `Common
- Problems' section in nasm.doc.
-
- (*) Fixed a bug relating to 32-bit PC-relative fixups in OBJ.
-
- (*) Fixed a bug in perm_copy() in labels.c which was causing
- exceptions in cleanup_labels() on some systems.
-
- (*) Positivity sanity check in TIMES argument changed from a warning
- to an error following a further complaint.
-
- (*) Changed the acceptable limits on byte and word operands to allow
- things like `~10111001b' to work.
-
- (*) Fixed a major problem in the preprocessor which caused seg-
- faults if macro definitions contained blank lines or comment-
- only lines.
-
- (*) Fixed inadequate error checking on the commas separating the
- arguments to `db', `dw' etc.
-
- (*) Fixed a crippling bug in the handling of macros with operand
- counts defined with a `+' modifier.
-
- (*) Fixed a bug whereby object file formats which stored the input
- file name in the output file (such as OBJ and COFF) weren't
- doing so correctly when the output file name was specified on
- the command line.
-
- (*) Removed [INC] and [INCLUDE] support for good, since they were
- obsolete anyway.
-
- (*) Fixed a bug in OBJ which caused all fixups to be output in 16-
- bit (old-format) FIXUPP records, rather than putting the 32-bit
- ones in FIXUPP32 (new-format) records.
-
- (*) Added, tentatively, OS/2 object file support (as a minor variant
- on OBJ).
-
- (*) Updates to Fox Cutter's Borland C makefile, Makefile.bc2.
-
- (*) Removed a spurious second fclose() on the output file.
-
- (*) Added the `-s' command line option to redirect all messages
- which would go to stderr (errors, help text) to stdout instead.
-
- (*) Added the `-w' command line option to selectively suppress some
- classes of assembly warning messages.
-
- (*) Added the `-p' pre-include and `-d' pre-define command-line
- options.
-
- (*) Added an include file search path: the `-i' command line option.
-
- (*) Fixed a silly little preprocessor bug whereby starting a line
- with a `%!' environment-variable reference caused an `unknown
- directive' error.
-
- (*) Added the long-awaited listing file support: the `-l' command
- line option.
-
- (*) Fixed a problem with OBJ format whereby, in the absence of any
- explicit segment definition, non-global symbols declared in the
- implicit default segment generated spurious EXTDEF records in
- the output.
-
- (*) Added the NASM environment variable.
-
- (*) From this version forward, Win32 console-mode binaries will be
- included in the DOS distribution in addition to the 16-bit
- binaries. Added Makefile.vc for this purpose.
-
- (*) Added `return 0;' to test/objlink.c to prevent compiler
- warnings.
-
- (*) Added the __NASM_MAJOR__ and __NASM_MINOR__ standard defines.
-
- (*) Added an alternative memory-reference syntax in which prefixing
- an operand with `&' is equivalent to enclosing it in square
- brackets, at the request of Fox Cutter.
-
- (*) Errors in pass two now cause the program to return a non-zero
- error code, which they didn't before.
-
- (*) Fixed the single-line macro cycle detection, which didn't work
- at all on macros with no parameters (caused an infinite loop).
- Also changed the behaviour of single-line macro cycle detection
- to work like cpp, so that macros like `extrn' as given in the
- documentation can be implemented.
-
- (*) Fixed the implementation of WRT, which was too restrictive in
- that you couldn't do `mov ax,[di+abc wrt dgroup]' because
- (di+abc) wasn't a relocatable reference.
-
- C.3.4 Version 0.94 released April 1997
-
- (*) Major item: added the macro processor.
-
- (*) Added undocumented instructions SMI, IBTS, XBTS and LOADALL286.
- Also reorganised CMPXCHG instruction into early-486 and Pentium
- forms. Thanks to Thobias Jones for the information.
-
- (*) Fixed two more stupid bugs in ELF, which were causing `ld' to
- continue to seg-fault in a lot of non-trivial cases.
-
- (*) Fixed a seg-fault in the label manager.
-
- (*) Stopped FBLD and FBSTP from _requiring_ the TWORD keyword, which
- is the only option for BCD loads/stores in any case.
-
- (*) Ensured FLDCW, FSTCW and FSTSW can cope with the WORD keyword,
- if anyone bothers to provide it. Previously they complained
- unless no keyword at all was present.
-
- (*) Some forms of FDIV/FDIVR and FSUB/FSUBR were still inverted: a
- vestige of a bug that I thought had been fixed in 0.92. This was
- fixed, hopefully for good this time...
-
- (*) Another minor phase error (insofar as a phase error can _ever_
- be minor) fixed, this one occurring in code of the form
-
- rol ax,forward_reference
- forward_reference equ 1
-
- (*) The number supplied to TIMES is now sanity-checked for
- positivity, and also may be greater than 64K (which previously
- didn't work on 16-bit systems).
-
- (*) Added Watcom C makefiles, and misc/pmw.bat, donated by Dominik
- Behr.
-
- (*) Added the INCBIN pseudo-opcode.
-
- (*) Due to the advent of the preprocessor, the [INCLUDE] and [INC]
- directives have become obsolete. They are still supported in
- this version, with a warning, but won't be in the next.
-
- (*) Fixed a bug in OBJ format, which caused incorrect object records
- to be output when absolute labels were made global.
-
- (*) Updates to RDOFF subdirectory, and changes to outrdf.c.
-
- C.3.5 Version 0.93 released January 1997
-
- This release went out in a great hurry after semi-crippling bugs
- were found in 0.92.
-
- (*) Really _did_ fix the stack overflows this time. *blush*
-
- (*) Had problems with EA instruction sizes changing between passes,
- when an offset contained a forward reference and so 4 bytes were
- allocated for the offset in pass one; by pass two the symbol had
- been defined and happened to be a small absolute value, so only
- 1 byte got allocated, causing instruction size mismatch between
- passes and hence incorrect address calculations. Fixed.
-
- (*) Stupid bug in the revised ELF section generation fixed
- (associated string-table section for .symtab was hard-coded as
- 7, even when this didn't fit with the real section table). Was
- causing `ld' to seg-fault under Linux.
-
- (*) Included a new Borland C makefile, Makefile.bc2, donated by Fox
- Cutter <lmb@comtch.iea.com>.
-
- C.3.6 Version 0.92 released January 1997
-
- (*) The FDIVP/FDIVRP and FSUBP/FSUBRP pairs had been inverted: this
- was fixed. This also affected the LCC driver.
-
- (*) Fixed a bug regarding 32-bit effective addresses of the form
- `[other_register+ESP]'.
-
- (*) Documentary changes, notably documentation of the fact that
- Borland Win32 compilers use `obj' rather than `win32' object
- format.
-
- (*) Fixed the COMENT record in OBJ files, which was formatted
- incorrectly.
-
- (*) Fixed a bug causing segfaults in large RDF files.
-
- (*) OBJ format now strips initial periods from segment and group
- definitions, in order to avoid complications with the local
- label syntax.
-
- (*) Fixed a bug in disassembling far calls and jumps in NDISASM.
-
- (*) Added support for user-defined sections in COFF and ELF files.
-
- (*) Compiled the DOS binaries with a sensible amount of stack, to
- prevent stack overflows on any arithmetic expression containing
- parentheses.
-
- (*) Fixed a bug in handling of files that do not terminate in a
- newline.
-
- C.3.7 Version 0.91 released November 1996
-
- (*) Loads of bug fixes.
-
- (*) Support for RDF added.
-
- (*) Support for DBG debugging format added.
-
- (*) Support for 32-bit extensions to Microsoft OBJ format added.
-
- (*) Revised for Borland C: some variable names changed, makefile
- added.
-
- (*) LCC support revised to actually work.
-
- (*) JMP/CALL NEAR/FAR notation added.
-
- (*) `a16', `o16', `a32' and `o32' prefixes added.
-
- (*) Range checking on short jumps implemented.
-
- (*) MMX instruction support added.
-
- (*) Negative floating point constant support added.
-
- (*) Memory handling improved to bypass 64K barrier under DOS.
-
- (*) `$' prefix to force treatment of reserved words as identifiers
- added.
-
- (*) Default-size mechanism for object formats added.
-
- (*) Compile-time configurability added.
-
- (*) `#', `@', `~' and c{?} are now valid characters in labels.
-
- (*) `-e' and `-k' options in NDISASM added.
-
- C.3.8 Version 0.90 released October 1996
-
- First release version. First support for object file output. Other
- changes from previous version (0.3x) too numerous to document.
diff --git a/packaging/nasm.manifest b/packaging/nasm.manifest
deleted file mode 100644
index 017d22d..0000000
--- a/packaging/nasm.manifest
+++ /dev/null
@@ -1,5 +0,0 @@
-<manifest>
- <request>
- <domain name="_"/>
- </request>
-</manifest>
diff --git a/packaging/nasm.spec b/packaging/nasm.spec
index dcfda70..17fa4d7 100644
--- a/packaging/nasm.spec
+++ b/packaging/nasm.spec
@@ -2,16 +2,13 @@
Summary: A portable x86 assembler which uses Intel-like syntax
Name: nasm
Version: 2.08rc7
-Release: 2.16
+Release: 2.1
License: simplified BSD license
Group: Development/Languages
URL: http://nasm.sourceforge.net/
Source0: nasm-%{version}.tar.bz2
Source1: nasm-%{version}-xdoc.tar.bz2
Source2: nasm.sh
-Source1001: packaging/nasm.manifest
-# >> gbp-patch-tags # auto-added by gbp
-# << gbp-patch-tags # auto-added by gbp
BuildRequires: perl
%package rdoff
@@ -30,14 +27,11 @@ include linker, library manager, loader, and information dump.
%prep
%setup -q
-# >> gbp-apply-patches # auto-added by gbp
-# << gbp-apply-patches # auto-added by gbp
tar xjf %{SOURCE1} --strip-components 1
%build
-cp %{SOURCE1001} .
%configure
-make all
+make all %{?_smp_mflags}
%install
rm -rf $RPM_BUILD_ROOT
@@ -51,14 +45,12 @@ cp %{SOURCE2} $RPM_BUILD_ROOT/etc/profile.d/
%remove_docs
%files
-%manifest nasm.manifest
%{_bindir}/nasm
%{_bindir}/ndisasm
/etc/profile.d/nasm.sh
%files rdoff
-%manifest nasm.manifest
%defattr(-,root,root)
%{_bindir}/ldrdf
%{_bindir}/rdf2bin