// Licensed to the .NET Foundation under one or more agreements. // The .NET Foundation licenses this file to you under the MIT license. // See the LICENSE file in the project root for more information. /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Utils.h XX XX XX XX Has miscellaneous utility functions XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ #ifndef _UTILS_H_ #define _UTILS_H_ #include "iallocator.h" #include "hostallocator.h" #include "cycletimer.h" // Needed for unreached() #include "error.h" #ifdef _TARGET_64BIT_ #define BitScanForwardPtr BitScanForward64 #else #define BitScanForwardPtr BitScanForward #endif template unsigned ArrLen(T (&)[size]) { return size; } // return true if arg is a power of 2 template inline bool isPow2(T i) { return (i > 0 && ((i - 1) & i) == 0); } // Adapter for iterators to a type that is compatible with C++11 // range-based for loops. template class IteratorPair { TIterator m_begin; TIterator m_end; public: IteratorPair(TIterator begin, TIterator end) : m_begin(begin), m_end(end) { } inline TIterator begin() { return m_begin; } inline TIterator end() { return m_end; } }; template inline IteratorPair MakeIteratorPair(TIterator begin, TIterator end) { return IteratorPair(begin, end); } // Recursive template definition to calculate the base-2 logarithm // of a constant value. template struct ConstLog2 { enum { value = ConstLog2::value }; }; template struct ConstLog2<0, acc> { enum { value = acc }; }; template struct ConstLog2<1, acc> { enum { value = acc }; }; inline const char* dspBool(bool b) { return (b) ? "true" : "false"; } #ifdef FEATURE_CORECLR #ifdef _CRT_ABS_DEFINED // we don't have the full standard library inline int64_t abs(int64_t t) { return t > 0 ? t : -t; } #endif #endif // FEATURE_CORECLR template int signum(T val) { if (val < T(0)) { return -1; } else if (val > T(0)) { return 1; } else { return 0; } } #if defined(DEBUG) || defined(INLINE_DATA) // ConfigMethodRange describes a set of methods, specified via their // hash codes. This can be used for binary search and/or specifying an // explicit method set. // // Note method hash codes are not necessarily unique. For instance // many IL stubs may have the same hash. // // If range string is null or just whitespace, range includes all // methods. // // Parses values as decimal numbers. // // Examples: // // [string with just spaces] : all methods // 12345678 : a single method // 12345678-23456789 : a range of methods // 99998888 12345678-23456789 : a range of methods plus a single method class ConfigMethodRange { public: // Default capacity enum { DEFAULT_CAPACITY = 50 }; // Does the range include this method's hash? bool Contains(class ICorJitInfo* info, CORINFO_METHOD_HANDLE method); // Ensure the range string has been parsed. void EnsureInit(const wchar_t* rangeStr, unsigned capacity = DEFAULT_CAPACITY) { // Make sure that the memory was zero initialized assert(m_inited == 0 || m_inited == 1); if (!m_inited) { InitRanges(rangeStr, capacity); assert(m_inited == 1); } } // Error checks bool Error() const { return m_badChar != 0; } size_t BadCharIndex() const { return m_badChar - 1; } private: struct Range { unsigned m_low; unsigned m_high; }; void InitRanges(const wchar_t* rangeStr, unsigned capacity); unsigned m_entries; // number of entries in the range array unsigned m_lastRange; // count of low-high pairs unsigned m_inited; // 1 if range string has been parsed size_t m_badChar; // index + 1 of any bad character in range string Range* m_ranges; // ranges of functions to include }; #endif // defined(DEBUG) || defined(INLINE_DATA) class Compiler; /***************************************************************************** * Fixed bit vector class */ class FixedBitVect { private: UINT bitVectSize; UINT bitVect[]; // bitChunkSize() - Returns number of bits in a bitVect chunk static UINT bitChunkSize(); // bitNumToBit() - Returns a bit mask of the given bit number static UINT bitNumToBit(UINT bitNum); public: // bitVectInit() - Initializes a bit vector of a given size static FixedBitVect* bitVectInit(UINT size, Compiler* comp); // bitVectSet() - Sets the given bit void bitVectSet(UINT bitNum); // bitVectTest() - Tests the given bit bool bitVectTest(UINT bitNum); // bitVectOr() - Or in the given bit vector void bitVectOr(FixedBitVect* bv); // bitVectAnd() - And with passed in bit vector void bitVectAnd(FixedBitVect& bv); // bitVectGetFirst() - Find the first bit on and return the bit num. // Return -1 if no bits found. UINT bitVectGetFirst(); // bitVectGetNext() - Find the next bit on given previous bit and return bit num. // Return -1 if no bits found. UINT bitVectGetNext(UINT bitNumPrev); // bitVectGetNextAndClear() - Find the first bit on, clear it and return it. // Return -1 if no bits found. UINT bitVectGetNextAndClear(); }; /****************************************************************************** * A specialized version of sprintf_s to simplify conversion to SecureCRT * * pWriteStart -> A pointer to the first byte to which data is written. * pBufStart -> the start of the buffer into which the data is written. If * composing a complex string with multiple calls to sprintf, this * should not change. * cbBufSize -> The size of the overall buffer (i.e. the size of the buffer * pointed to by pBufStart). For subsequent calls, this does not * change. * fmt -> The format string * ... -> Arguments. * * returns -> number of bytes successfully written, not including the null * terminator. Calls NO_WAY on error. */ int SimpleSprintf_s(__in_ecount(cbBufSize - (pWriteStart - pBufStart)) char* pWriteStart, __in_ecount(cbBufSize) char* pBufStart, size_t cbBufSize, __in_z const char* fmt, ...); #ifdef DEBUG void hexDump(FILE* dmpf, const char* name, BYTE* addr, size_t size); #endif // DEBUG /****************************************************************************** * ScopedSetVariable: A simple class to set and restore a variable within a scope. * For example, it can be used to set a 'bool' flag to 'true' at the beginning of a * function and automatically back to 'false' either at the end the function, or at * any other return location. The variable should not be changed during the scope: * the destructor asserts that the value at destruction time is the same one we set. * Usage: ScopedSetVariable _unused_name(&variable, true); */ template class ScopedSetVariable { public: ScopedSetVariable(T* pVariable, T value) : m_pVariable(pVariable) { m_oldValue = *m_pVariable; *m_pVariable = value; INDEBUG(m_value = value;) } ~ScopedSetVariable() { assert(*m_pVariable == m_value); // Assert that the value didn't change between ctor and dtor *m_pVariable = m_oldValue; } private: #ifdef DEBUG T m_value; // The value we set the variable to (used for assert). #endif // DEBUG T m_oldValue; // The old value, to restore the variable to. T* m_pVariable; // Address of the variable to change }; /****************************************************************************** * PhasedVar: A class to represent a variable that has phases, in particular, * a write phase where the variable is computed, and a read phase where the * variable is used. Once the variable has been read, it can no longer be changed. * Reading the variable essentially commits everyone to using that value forever, * and it is assumed that subsequent changes to the variable would invalidate * whatever assumptions were made by the previous readers, leading to bad generated code. * These assumptions are asserted in DEBUG builds. * The phase ordering is clean for AMD64, but not for x86/ARM. So don't do the phase * ordering asserts for those platforms. */ template class PhasedVar { public: PhasedVar() #ifdef DEBUG : m_initialized(false), m_writePhase(true) #endif // DEBUG { } PhasedVar(T value) : m_value(value) #ifdef DEBUG , m_initialized(true) , m_writePhase(true) #endif // DEBUG { } ~PhasedVar() { #ifdef DEBUG m_initialized = false; m_writePhase = true; #endif // DEBUG } // Read the value. Change to the read phase. // Marked 'const' because we don't change the encapsulated value, even though // we do change the write phase, which is only for debugging asserts. operator T() const { #ifdef DEBUG assert(m_initialized); (const_cast(this))->m_writePhase = false; #endif // DEBUG return m_value; } // Mark the value as read only; explicitly change the variable to the "read" phase. void MarkAsReadOnly() const { #ifdef DEBUG assert(m_initialized); (const_cast(this))->m_writePhase = false; #endif // DEBUG } // When dumping stuff we could try to read a PhasedVariable // This method tells us whether we should read the PhasedVariable bool HasFinalValue() const { #ifdef DEBUG return (const_cast(this))->m_writePhase == false; #else return true; #endif // DEBUG } // Functions/operators to write the value. Must be in the write phase. PhasedVar& operator=(const T& value) { #ifdef DEBUG assert(m_writePhase); m_initialized = true; #endif // DEBUG m_value = value; return *this; } PhasedVar& operator&=(const T& value) { #ifdef DEBUG assert(m_writePhase); m_initialized = true; #endif // DEBUG m_value &= value; return *this; } // Note: if you need more = functions, you can define them here, like operator&= // Assign a value, but don't assert if we're not in the write phase, and // don't change the phase (if we're actually in the read phase, we'll stay // in the read phase). This is a dangerous function, and overrides the main // benefit of this class. Use it wisely! void OverrideAssign(const T& value) { #ifdef DEBUG m_initialized = true; #endif // DEBUG m_value = value; } // We've decided that this variable can go back to write phase, even if it has been // written. This can be used, for example, for variables set and read during frame // layout calculation, as long as it is before final layout, such that anything // being calculated is just an estimate anyway. Obviously, it must be used carefully, // since it overrides the main benefit of this class. void ResetWritePhase() { #ifdef DEBUG m_writePhase = true; #endif // DEBUG } private: // Don't allow a copy constructor. (This could be allowed, but only add it once it is actually needed.) PhasedVar(const PhasedVar& o) { unreached(); } T m_value; #ifdef DEBUG bool m_initialized; // true once the variable has been initialized, that is, written once. bool m_writePhase; // true if we are in the (initial) "write" phase. Once the value is read, this changes to false, // and can't be changed back. #endif // DEBUG }; class HelperCallProperties { private: bool m_isPure[CORINFO_HELP_COUNT]; bool m_noThrow[CORINFO_HELP_COUNT]; bool m_nonNullReturn[CORINFO_HELP_COUNT]; bool m_isAllocator[CORINFO_HELP_COUNT]; bool m_mutatesHeap[CORINFO_HELP_COUNT]; bool m_mayRunCctor[CORINFO_HELP_COUNT]; bool m_mayFinalize[CORINFO_HELP_COUNT]; void init(); public: HelperCallProperties() { init(); } bool IsPure(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_isPure[helperId]; } bool NoThrow(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_noThrow[helperId]; } bool NonNullReturn(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_nonNullReturn[helperId]; } bool IsAllocator(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_isAllocator[helperId]; } bool MutatesHeap(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_mutatesHeap[helperId]; } bool MayRunCctor(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_mayRunCctor[helperId]; } bool MayFinalize(CorInfoHelpFunc helperId) { assert(helperId > CORINFO_HELP_UNDEF); assert(helperId < CORINFO_HELP_COUNT); return m_mayFinalize[helperId]; } }; //***************************************************************************** // AssemblyNamesList2: Parses and stores a list of Assembly names, and provides // a function for determining whether a given assembly name is part of the list. // // This is a clone of the AssemblyNamesList class that exists in the VM's utilcode, // modified to use the JIT's memory allocator and throw on out of memory behavior. // It is named AssemblyNamesList2 to avoid a name conflict with the VM version. // It might be preferable to adapt the VM's code to be more flexible (for example, // by using an IAllocator), but the string handling code there is heavily macroized, // and for the small usage we have of this class, investing in genericizing the VM // implementation didn't seem worth it. //***************************************************************************** class AssemblyNamesList2 { struct AssemblyName { char* m_assemblyName; AssemblyName* m_next; }; AssemblyName* m_pNames; // List of names HostAllocator m_alloc; // HostAllocator to use in this class public: // Take a Unicode string list of assembly names, parse it, and store it. AssemblyNamesList2(const wchar_t* list, HostAllocator alloc); ~AssemblyNamesList2(); // Return 'true' if 'assemblyName' (in UTF-8 format) is in the stored list of assembly names. bool IsInList(const char* assemblyName); // Return 'true' if the assembly name list is empty. bool IsEmpty() { return m_pNames == nullptr; } }; #ifdef FEATURE_JIT_METHOD_PERF // When Start() is called time is noted and when ElapsedTime // is called we know how much time was spent in msecs. // class CycleCount { private: double cps; // cycles per second unsigned __int64 beginCycles; // cycles at stop watch construction public: CycleCount(); // Kick off the counter, and if re-entrant will use the latest cycles as starting point. // If the method returns false, any other query yield unpredictable results. bool Start(); // Return time elapsed in msecs, if Start returned true. double ElapsedTime(); private: // Return true if successful. bool GetCycles(unsigned __int64* time); }; // Uses win API QueryPerformanceCounter/QueryPerformanceFrequency. class PerfCounter { LARGE_INTEGER beg; double freq; public: // If the method returns false, any other query yield unpredictable results. bool Start(); // Return time elapsed from start in millis, if Start returned true. double ElapsedTime(); }; #endif // FEATURE_JIT_METHOD_PERF #ifdef DEBUG /***************************************************************************** * Return the number of digits in a number of the given base (default base 10). * Used when outputting strings. */ unsigned CountDigits(unsigned num, unsigned base = 10); #endif // DEBUG /***************************************************************************** * Floating point utility class */ class FloatingPointUtils { public: static double convertUInt64ToDouble(unsigned __int64 u64); static float convertUInt64ToFloat(unsigned __int64 u64); static unsigned __int64 convertDoubleToUInt64(double d); static double round(double x); static float round(float x); }; // The CLR requires that critical section locks be initialized via its ClrCreateCriticalSection API...but // that can't be called until the CLR is initialized. If we have static data that we'd like to protect by a // lock, and we have a statically allocated lock to protect that data, there's an issue in how to initialize // that lock. We could insert an initialize call in the startup path, but one might prefer to keep the code // more local. For such situations, CritSecObject solves the initialization problem, via a level of // indirection. A pointer to the lock is initially null, and when we query for the lock pointer via "Val()". // If the lock has not yet been allocated, this allocates one (here a leaf lock), and uses a // CompareAndExchange-based lazy-initialization to update the field. If this fails, the allocated lock is // destroyed. This will work as long as the first locking attempt occurs after enough CLR initialization has // happened to make ClrCreateCriticalSection calls legal. class CritSecObject { public: CritSecObject() { m_pCs = nullptr; } CRITSEC_COOKIE Val() { if (m_pCs == nullptr) { // CompareExchange-based lazy init. CRITSEC_COOKIE newCs = ClrCreateCriticalSection(CrstLeafLock, CRST_DEFAULT); CRITSEC_COOKIE observed = InterlockedCompareExchangeT(&m_pCs, newCs, NULL); if (observed != nullptr) { ClrDeleteCriticalSection(newCs); } } return m_pCs; } private: // CRITSEC_COOKIE is an opaque pointer type. CRITSEC_COOKIE m_pCs; // No copying or assignment allowed. CritSecObject(const CritSecObject&) = delete; CritSecObject& operator=(const CritSecObject&) = delete; }; // Stack-based holder for a critial section lock. // Ensures lock is released. class CritSecHolder { public: CritSecHolder(CritSecObject& critSec) : m_CritSec(critSec) { ClrEnterCriticalSection(m_CritSec.Val()); } ~CritSecHolder() { ClrLeaveCriticalSection(m_CritSec.Val()); } private: CritSecObject& m_CritSec; // No copying or assignment allowed. CritSecHolder(const CritSecHolder&) = delete; CritSecHolder& operator=(const CritSecHolder&) = delete; }; namespace MagicDivide { uint32_t GetUnsigned32Magic(uint32_t d, bool* add /*out*/, int* shift /*out*/); #ifdef _TARGET_64BIT_ uint64_t GetUnsigned64Magic(uint64_t d, bool* add /*out*/, int* shift /*out*/); #endif int32_t GetSigned32Magic(int32_t d, int* shift /*out*/); #ifdef _TARGET_64BIT_ int64_t GetSigned64Magic(int64_t d, int* shift /*out*/); #endif } #endif // _UTILS_H_