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diff --git a/doc/html/variant/design.html b/doc/html/variant/design.html new file mode 100755 index 0000000000..b9f2618047 --- /dev/null +++ b/doc/html/variant/design.html @@ -0,0 +1,349 @@ +<html> +<head> +<meta http-equiv="Content-Type" content="text/html; charset=US-ASCII"> +<title>Design Overview</title> +<link rel="stylesheet" href="../../../doc/src/boostbook.css" type="text/css"> +<meta name="generator" content="DocBook XSL Stylesheets V1.76.1"> +<link rel="home" href="../index.html" title="The Boost C++ Libraries BoostBook Documentation Subset"> +<link rel="up" href="../variant.html" title="Chapter 34. Boost.Variant"> +<link rel="prev" href="../boost/visitor_ptr.html" title="Function template visitor_ptr"> +<link rel="next" href="misc.html" title="Miscellaneous Notes"> +</head> +<body bgcolor="white" text="black" link="#0000FF" vlink="#840084" alink="#0000FF"> +<table cellpadding="2" width="100%"><tr> +<td valign="top"><img alt="Boost C++ Libraries" width="277" height="86" src="../../../boost.png"></td> +<td align="center"><a href="../../../index.html">Home</a></td> +<td align="center"><a href="../../../libs/libraries.htm">Libraries</a></td> +<td align="center"><a href="http://www.boost.org/users/people.html">People</a></td> +<td align="center"><a href="http://www.boost.org/users/faq.html">FAQ</a></td> +<td align="center"><a href="../../../more/index.htm">More</a></td> +</tr></table> +<hr> +<div class="spirit-nav"> +<a accesskey="p" href="../boost/visitor_ptr.html"><img src="../../../doc/src/images/prev.png" alt="Prev"></a><a accesskey="u" href="../variant.html"><img src="../../../doc/src/images/up.png" alt="Up"></a><a accesskey="h" href="../index.html"><img src="../../../doc/src/images/home.png" alt="Home"></a><a accesskey="n" href="misc.html"><img src="../../../doc/src/images/next.png" alt="Next"></a> +</div> +<div class="section"> +<div class="titlepage"><div><div><h2 class="title" style="clear: both"> +<a name="variant.design"></a>Design Overview</h2></div></div></div> +<div class="toc"><dl><dt><span class="section"><a href="design.html#variant.design.never-empty">"Never-Empty" Guarantee</a></span></dt></dl></div> +<div class="section"> +<div class="titlepage"><div><div><h3 class="title"> +<a name="variant.design.never-empty"></a>"Never-Empty" Guarantee</h3></div></div></div> +<div class="toc"><dl> +<dt><span class="section"><a href="design.html#variant.design.never-empty.guarantee">The Guarantee</a></span></dt> +<dt><span class="section"><a href="design.html#variant.design.never-empty.problem">The Implementation Problem</a></span></dt> +<dt><span class="section"><a href="design.html#variant.design.never-empty.memcpy-solution">The "Ideal" Solution: False Hopes</a></span></dt> +<dt><span class="section"><a href="design.html#variant.design.never-empty.double-storage-solution">An Initial Solution: Double Storage</a></span></dt> +<dt><span class="section"><a href="design.html#variant.design.never-empty.heap-backup-solution">Current Approach: Temporary Heap Backup</a></span></dt> +<dt><span class="section"><a href="design.html#variant.design.never-empty.optimizations">Enabling Optimizations</a></span></dt> +<dt><span class="section"><a href="design.html#variant.design.never-empty.roadmap">Future Direction: Policy-based Implementation</a></span></dt> +</dl></div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.guarantee"></a>The Guarantee</h4></div></div></div> +<p>All instances <code class="computeroutput">v</code> of type + <code class="computeroutput"><a class="link" href="../boost/variant.html" title="Class template variant">variant</a><T1,T2,...,TN></code> + guarantee that <code class="computeroutput">v</code> has constructed content of one of the + types <code class="computeroutput">T<span class="emphasis"><em>i</em></span></code>, even if an operation on + <code class="computeroutput">v</code> has previously failed.</p> +<p>This implies that <code class="computeroutput">variant</code> may be viewed precisely as + a union of <span class="emphasis"><em>exactly</em></span> its bounded types. This + "never-empty" property insulates the user from the + possibility of undefined <code class="computeroutput">variant</code> content and the + significant additional complexity-of-use attendant with such a + possibility.</p> +</div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.problem"></a>The Implementation Problem</h4></div></div></div> +<p>While the + <a class="link" href="design.html#variant.design.never-empty.guarantee" title="The Guarantee">never-empty guarantee</a> + might at first seem "obvious," it is in fact not even + straightforward how to implement it in general (i.e., without + unreasonably restrictive additional requirements on + <a class="link" href="reference.html#variant.concepts.bounded-type" title="BoundedType">bounded types</a>).</p> +<p>The central difficulty emerges in the details of + <code class="computeroutput">variant</code> assignment. Given two instances <code class="computeroutput">v1</code> + and <code class="computeroutput">v2</code> of some concrete <code class="computeroutput">variant</code> type, there + are two distinct, fundamental cases we must consider for the assignment + <code class="computeroutput">v1 = v2</code>.</p> +<p>First consider the case that <code class="computeroutput">v1</code> and <code class="computeroutput">v2</code> + each contains a value of the same type. Call this type <code class="computeroutput">T</code>. + In this situation, assignment is perfectly straightforward: use + <code class="computeroutput">T::operator=</code>.</p> +<p>However, we must also consider the case that <code class="computeroutput">v1</code> and + <code class="computeroutput">v2</code> contain values <span class="emphasis"><em>of distinct types</em></span>. + Call these types <code class="computeroutput">T</code> and <code class="computeroutput">U</code>. At this point, + since <code class="computeroutput">variant</code> manages its content on the stack, the + left-hand side of the assignment (i.e., <code class="computeroutput">v1</code>) must destroy + its content so as to permit in-place copy-construction of the content + of the right-hand side (i.e., <code class="computeroutput">v2</code>). In the end, whereas + <code class="computeroutput">v1</code> began with content of type <code class="computeroutput">T</code>, it ends + with content of type <code class="computeroutput">U</code>, namely a copy of the content of + <code class="computeroutput">v2</code>.</p> +<p>The crux of the problem, then, is this: in the event that + copy-construction of the content of <code class="computeroutput">v2</code> fails, how can + <code class="computeroutput">v1</code> maintain its "never-empty" guarantee? + By the time copy-construction from <code class="computeroutput">v2</code> is attempted, + <code class="computeroutput">v1</code> has already destroyed its content!</p> +</div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.memcpy-solution"></a>The "Ideal" Solution: False Hopes</h4></div></div></div> +<p>Upon learning of this dilemma, clever individuals may propose the + following scheme hoping to solve the problem: + + </p> +<div class="orderedlist"><ol class="orderedlist" type="1"> +<li class="listitem">Provide some "backup" storage, appropriately + aligned, capable of holding values of the contained type of the + left-hand side.</li> +<li class="listitem">Copy the memory (e.g., using <code class="computeroutput">memcpy</code>) of the + storage of the left-hand side to the backup storage.</li> +<li class="listitem">Attempt a copy of the right-hand side content to the + (now-replicated) left-hand side storage.</li> +<li class="listitem">In the event of an exception from the copy, restore the + backup (i.e., copy the memory from the backup storage back into + the left-hand side storage).</li> +<li class="listitem">Otherwise, in the event of success, now copy the memory + of the left-hand side storage to another "temporary" + aligned storage.</li> +<li class="listitem">Now restore the backup (i.e., again copying the memory) + to the left-hand side storage; with the "old" content + now restored, invoke the destructor of the contained type on the + storage of the left-hand side.</li> +<li class="listitem">Finally, copy the memory of the temporary storage to the + (now-empty) storage of the left-hand side.</li> +</ol></div> +<p> + </p> +<p>While complicated, it appears such a scheme could provide the + desired safety in a relatively efficient manner. In fact, several + early iterations of the library implemented this very approach.</p> +<p>Unfortunately, as Dave Abraham's first noted, the scheme results + in undefined behavior: + + </p> +<div class="blockquote"><blockquote class="blockquote"> +<p>"That's a lot of code to read through, but if it's + doing what I think it's doing, it's undefined behavior.</p> +<p>"Is the trick to move the bits for an existing object + into a buffer so we can tentatively construct a new object in + that memory, and later move the old bits back temporarily to + destroy the old object?</p> +<p>"The standard does not give license to do that: only one + object may have a given address at a time. See 3.8, and + particularly paragraph 4."</p> +</blockquote></div> +<p> + </p> +<p>Additionally, as close examination quickly reveals, the scheme has + the potential to create irreconcilable race-conditions in concurrent + environments.</p> +<p>Ultimately, even if the above scheme could be made to work on + certain platforms with particular compilers, it is still necessary to + find a portable solution.</p> +</div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.double-storage-solution"></a>An Initial Solution: Double Storage</h4></div></div></div> +<p>Upon learning of the infeasibility of the above scheme, Anthony + Williams proposed in + <a class="link" href="refs.html#variant.refs.wil02">[Wil02]</a> a scheme that served + as the basis for a portable solution in some pre-release + implementations of <code class="computeroutput">variant</code>.</p> +<p>The essential idea to this scheme, which shall be referred to as + the "double storage" scheme, is to provide enough space + within a <code class="computeroutput">variant</code> to hold two separate values of any of + the bounded types.</p> +<p>With the secondary storage, a copy the right-hand side can be + attempted without first destroying the content of the left-hand side; + accordingly, the content of the left-hand side remains available in + the event of an exception.</p> +<p>Thus, with this scheme, the <code class="computeroutput">variant</code> implementation + needs only to keep track of which storage contains the content -- and + dispatch any visitation requests, queries, etc. accordingly.</p> +<p>The most obvious flaw to this approach is the space overhead + incurred. Though some optimizations could be applied in special cases + to eliminate the need for double storage -- for certain bounded types + or in some cases entirely (see + <a class="xref" href="design.html#variant.design.never-empty.optimizations" title="Enabling Optimizations">the section called “Enabling Optimizations”</a> for more + details) -- many users on the Boost mailing list strongly objected to + the use of double storage. In particular, it was noted that the + overhead of double storage would be at play at all times -- even if + assignment to <code class="computeroutput">variant</code> never occurred. For this reason + and others, a new approach was developed.</p> +</div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.heap-backup-solution"></a>Current Approach: Temporary Heap Backup</h4></div></div></div> +<p>Despite the many objections to the double storage solution, it was + realized that no replacement would be without drawbacks. Thus, a + compromise was desired.</p> +<p>To this end, Dave Abrahams suggested to include the following in + the behavior specification for <code class="computeroutput">variant</code> assignment: + "<code class="computeroutput">variant</code> assignment from one type to another may + incur dynamic allocation." That is, while <code class="computeroutput">variant</code> would + continue to store its content <span class="emphasis"><em>in situ</em></span> after + construction and after assignment involving identical contained types, + <code class="computeroutput">variant</code> would store its content on the heap after + assignment involving distinct contained types.</p> +<p>The algorithm for assignment would proceed as follows: + + </p> +<div class="orderedlist"><ol class="orderedlist" type="1"> +<li class="listitem">Copy-construct the content of the right-hand side to the + heap; call the pointer to this data <code class="computeroutput">p</code>.</li> +<li class="listitem">Destroy the content of the left-hand side.</li> +<li class="listitem">Copy <code class="computeroutput">p</code> to the left-hand side + storage.</li> +</ol></div> +<p> + + Since all operations on pointers are nothrow, this scheme would allow + <code class="computeroutput">variant</code> to meet its never-empty guarantee. + </p> +<p>The most obvious concern with this approach is that while it + certainly eliminates the space overhead of double storage, it + introduces the overhead of dynamic-allocation to <code class="computeroutput">variant</code> + assignment -- not just in terms of the initial allocation but also + as a result of the continued storage of the content on the heap. While + the former problem is unavoidable, the latter problem may be avoided + with the following "temporary heap backup" technique: + + </p> +<div class="orderedlist"><ol class="orderedlist" type="1"> +<li class="listitem">Copy-construct the content of the + <span class="emphasis"><em>left</em></span>-hand side to the heap; call the pointer to + this data <code class="computeroutput">backup</code>.</li> +<li class="listitem">Destroy the content of the left-hand side.</li> +<li class="listitem">Copy-construct the content of the right-hand side in the + (now-empty) storage of the left-hand side.</li> +<li class="listitem">In the event of failure, copy <code class="computeroutput">backup</code> to the + left-hand side storage.</li> +<li class="listitem">In the event of success, deallocate the data pointed to + by <code class="computeroutput">backup</code>.</li> +</ol></div> +<p> + </p> +<p>With this technique: 1) only a single storage is used; + 2) allocation is on the heap in the long-term only if the assignment + fails; and 3) after any <span class="emphasis"><em>successful</em></span> assignment, + storage within the <code class="computeroutput">variant</code> is guaranteed. For the + purposes of the initial release of the library, these characteristics + were deemed a satisfactory compromise solution.</p> +<p>There remain notable shortcomings, however. In particular, there + may be some users for which heap allocation must be avoided at all + costs; for other users, any allocation may need to occur via a + user-supplied allocator. These issues will be addressed in the future + (see <a class="xref" href="design.html#variant.design.never-empty.roadmap" title="Future Direction: Policy-based Implementation">the section called “Future Direction: Policy-based Implementation”</a>). For now, + though, the library treats storage of its content as an implementation + detail. Nonetheless, as described in the next section, there + <span class="emphasis"><em>are</em></span> certain things the user can do to ensure the + greatest efficiency for <code class="computeroutput">variant</code> instances (see + <a class="xref" href="design.html#variant.design.never-empty.optimizations" title="Enabling Optimizations">the section called “Enabling Optimizations”</a> for + details).</p> +</div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.optimizations"></a>Enabling Optimizations</h4></div></div></div> +<p>As described in + <a class="xref" href="design.html#variant.design.never-empty.problem" title="The Implementation Problem">the section called “The Implementation Problem”</a>, the central + difficulty in implementing the never-empty guarantee is the + possibility of failed copy-construction during <code class="computeroutput">variant</code> + assignment. Yet types with nothrow copy constructors clearly never + face this possibility. Similarly, if one of the bounded types of the + <code class="computeroutput">variant</code> is nothrow default-constructible, then such a + type could be used as a safe "fallback" type in the event of + failed copy construction.</p> +<p>Accordingly, <code class="computeroutput">variant</code> is designed to enable the + following optimizations once the following criteria on its bounded + types are met: + + </p> +<div class="itemizedlist"><ul class="itemizedlist" type="disc"> +<li class="listitem">For each bounded type <code class="computeroutput">T</code> that is nothrow + copy-constructible (as indicated by + <code class="computeroutput">boost::has_nothrow_copy</code>), the + library guarantees <code class="computeroutput">variant</code> will use only single + storage and in-place construction for <code class="computeroutput">T</code>.</li> +<li class="listitem">If <span class="emphasis"><em>any</em></span> bounded type is nothrow + default-constructible (as indicated by + <code class="computeroutput">boost::has_nothrow_constructor</code>), + the library guarantees <code class="computeroutput">variant</code> will use only single + storage and in-place construction for <span class="emphasis"><em>every</em></span> + bounded type in the <code class="computeroutput">variant</code>. Note, however, that in + the event of assignment failure, an unspecified nothrow + default-constructible bounded type will be default-constructed in + the left-hand side operand so as to preserve the never-empty + guarantee.</li> +</ul></div> +<p> + + </p> +<p><span class="bold"><strong>Caveat</strong></span>: On most platforms, the + <a href="../../../libs/type_traits/index.html" target="_top">Type Traits</a> templates + <code class="computeroutput">has_nothrow_copy</code> and <code class="computeroutput">has_nothrow_constructor</code> + by default return <code class="computeroutput">false</code> for all <code class="computeroutput">class</code> and + <code class="computeroutput">struct</code> types. It is necessary therefore to provide + specializations of these templates as appropriate for user-defined + types, as demonstrated in the following: + +</p> +<pre class="programlisting">// ...in your code (at file scope)... + +namespace boost { + + template <> + struct <code class="computeroutput">has_nothrow_copy</code>< myUDT > + : <code class="computeroutput">mpl::true_</code> + { + }; + +} +</pre> +<p> + + </p> +<p><span class="bold"><strong>Implementation Note</strong></span>: So as to make + the behavior of <code class="computeroutput">variant</code> more predictable in the aftermath + of an exception, the current implementation prefers to default-construct + <code class="computeroutput">boost::blank</code> if specified as a + bounded type instead of other nothrow default-constructible bounded + types. (If this is deemed to be a useful feature, it will become part + of the specification for <code class="computeroutput">variant</code>; otherwise, it may be + obsoleted. Please provide feedback to the Boost mailing list.)</p> +</div> +<div class="section"> +<div class="titlepage"><div><div><h4 class="title"> +<a name="variant.design.never-empty.roadmap"></a>Future Direction: Policy-based Implementation</h4></div></div></div> +<p>As the previous sections have demonstrated, much effort has been + expended in an attempt to provide a balance between performance, data + size, and heap usage. Further, significant optimizations may be + enabled in <code class="computeroutput">variant</code> on the basis of certain traits of its + bounded types.</p> +<p>However, there will be some users for whom the chosen compromise + is unsatisfactory (e.g.: heap allocation must be avoided at all costs; + if heap allocation is used, custom allocators must be used; etc.). For + this reason, a future version of the library will support a + policy-based implementation of <code class="computeroutput">variant</code>. While this will + not eliminate the problems described in the previous sections, it will + allow the decisions regarding tradeoffs to be decided by the user + rather than the library designers.</p> +</div> +</div> +</div> +<table xmlns:rev="http://www.cs.rpi.edu/~gregod/boost/tools/doc/revision" width="100%"><tr> +<td align="left"></td> +<td align="right"><div class="copyright-footer">Copyright © 2002, 2003 Eric Friedman, Itay Maman<p>Distributed under the Boost Software License, Version 1.0. + (See accompanying file <code class="filename">LICENSE_1_0.txt</code> or copy at + <a href="http://www.boost.org/LICENSE_1_0.txt" target="_top">http://www.boost.org/LICENSE_1_0.txt</a>) + </p> +</div></td> +</tr></table> +<hr> +<div class="spirit-nav"> +<a accesskey="p" href="../boost/visitor_ptr.html"><img src="../../../doc/src/images/prev.png" alt="Prev"></a><a accesskey="u" href="../variant.html"><img src="../../../doc/src/images/up.png" alt="Up"></a><a accesskey="h" href="../index.html"><img src="../../../doc/src/images/home.png" alt="Home"></a><a accesskey="n" href="misc.html"><img src="../../../doc/src/images/next.png" alt="Next"></a> +</div> +</body> +</html> |