/* -*- Mode: C; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* * PR assertion checker. */ #ifndef jsutil_h___ #define jsutil_h___ #include "mozilla/Attributes.h" #include "js/Utility.h" /* Forward declarations. */ struct JSContext; static JS_ALWAYS_INLINE void * js_memcpy(void *dst_, const void *src_, size_t len) { char *dst = (char *) dst_; const char *src = (const char *) src_; JS_ASSERT_IF(dst >= src, (size_t) (dst - src) >= len); JS_ASSERT_IF(src >= dst, (size_t) (src - dst) >= len); return memcpy(dst, src, len); } #ifdef __cplusplus namespace js { template struct AlignmentTestStruct { char c; T t; }; /* This macro determines the alignment requirements of a type. */ #define JS_ALIGNMENT_OF(t_) \ (sizeof(js::AlignmentTestStruct) - sizeof(t_)) template class AlignedPtrAndFlag { uintptr_t bits; public: AlignedPtrAndFlag(T *t, bool flag) { JS_ASSERT((uintptr_t(t) & 1) == 0); bits = uintptr_t(t) | uintptr_t(flag); } T *ptr() const { return (T *)(bits & ~uintptr_t(1)); } bool flag() const { return (bits & 1) != 0; } void setPtr(T *t) { JS_ASSERT((uintptr_t(t) & 1) == 0); bits = uintptr_t(t) | uintptr_t(flag()); } void setFlag() { bits |= 1; } void unsetFlag() { bits &= ~uintptr_t(1); } void set(T *t, bool flag) { JS_ASSERT((uintptr_t(t) & 1) == 0); bits = uintptr_t(t) | flag; } }; template static inline void Reverse(T *beg, T *end) { while (beg != end) { if (--end == beg) return; T tmp = *beg; *beg = *end; *end = tmp; ++beg; } } template static inline T * Find(T *beg, T *end, const T &v) { for (T *p = beg; p != end; ++p) { if (*p == v) return p; } return end; } template static inline typename Container::ElementType * Find(Container &c, const typename Container::ElementType &v) { return Find(c.begin(), c.end(), v); } template void ForEach(InputIterT begin, InputIterT end, CallableT f) { for (; begin != end; ++begin) f(*begin); } template static inline T Min(T t1, T t2) { return t1 < t2 ? t1 : t2; } template static inline T Max(T t1, T t2) { return t1 > t2 ? t1 : t2; } /* Allows a const variable to be initialized after its declaration. */ template static T& InitConst(const T &t) { return const_cast(t); } template JS_ALWAYS_INLINE T & ImplicitCast(U &u) { T &t = u; return t; } template class AutoScopedAssign { private: JS_DECL_USE_GUARD_OBJECT_NOTIFIER T *addr; T old; public: AutoScopedAssign(T *addr, const T &value JS_GUARD_OBJECT_NOTIFIER_PARAM) : addr(addr), old(*addr) { JS_GUARD_OBJECT_NOTIFIER_INIT; *addr = value; } ~AutoScopedAssign() { *addr = old; } }; template JS_ALWAYS_INLINE static void PodZero(T *t) { memset(t, 0, sizeof(T)); } template JS_ALWAYS_INLINE static void PodZero(T *t, size_t nelem) { /* * This function is often called with 'nelem' small; we use an * inline loop instead of calling 'memset' with a non-constant * length. The compiler should inline the memset call with constant * size, though. */ for (T *end = t + nelem; t != end; ++t) memset(t, 0, sizeof(T)); } /* * Arrays implicitly convert to pointers to their first element, which is * dangerous when combined with the above PodZero definitions. Adding an * overload for arrays is ambiguous, so we need another identifier. The * ambiguous overload is left to catch mistaken uses of PodZero; if you get a * compile error involving PodZero and array types, use PodArrayZero instead. */ template static void PodZero(T (&)[N]); /* undefined */ template static void PodZero(T (&)[N], size_t); /* undefined */ template JS_ALWAYS_INLINE static void PodArrayZero(T (&t)[N]) { memset(t, 0, N * sizeof(T)); } template JS_ALWAYS_INLINE static void PodAssign(T *dst, const T *src) { js_memcpy((char *) dst, (const char *) src, sizeof(T)); } template JS_ALWAYS_INLINE static void PodCopy(T *dst, const T *src, size_t nelem) { /* Cannot find portable word-sized abs(). */ JS_ASSERT_IF(dst >= src, size_t(dst - src) >= nelem); JS_ASSERT_IF(src >= dst, size_t(src - dst) >= nelem); if (nelem < 128) { /* * Avoid using operator= in this loop, as it may have been * intentionally deleted by the POD type. */ for (const T *srcend = src + nelem; src != srcend; ++src, ++dst) PodAssign(dst, src); } else { memcpy(dst, src, nelem * sizeof(T)); } } template JS_ALWAYS_INLINE static bool PodEqual(T *one, T *two, size_t len) { if (len < 128) { T *p1end = one + len; for (T *p1 = one, *p2 = two; p1 != p1end; ++p1, ++p2) { if (*p1 != *p2) return false; } return true; } return !memcmp(one, two, len * sizeof(T)); } template JS_ALWAYS_INLINE static void Swap(T &t, T &u) { T tmp(Move(t)); t = Move(u); u = Move(tmp); } JS_ALWAYS_INLINE static size_t UnsignedPtrDiff(const void *bigger, const void *smaller) { return size_t(bigger) - size_t(smaller); } /* * Ordinarily, a function taking a JSContext* 'cx' parameter reports errors on * the context. In some cases, functions optionally report and indicate this by * taking a nullable 'maybecx' parameter. In some cases, though, a function * always needs a 'cx', but optionally reports. This option is presented by the * MaybeReportError. */ enum MaybeReportError { REPORT_ERROR = true, DONT_REPORT_ERROR = false }; /*****************************************************************************/ /* A bit array is an array of bits represented by an array of words (size_t). */ static inline unsigned NumWordsForBitArrayOfLength(size_t length) { return (length + (JS_BITS_PER_WORD - 1)) / JS_BITS_PER_WORD; } static inline unsigned BitArrayIndexToWordIndex(size_t length, size_t bitIndex) { unsigned wordIndex = bitIndex / JS_BITS_PER_WORD; JS_ASSERT(wordIndex < length); return wordIndex; } static inline size_t BitArrayIndexToWordMask(size_t i) { return size_t(1) << (i % JS_BITS_PER_WORD); } static inline bool IsBitArrayElementSet(size_t *array, size_t length, size_t i) { return array[BitArrayIndexToWordIndex(length, i)] & BitArrayIndexToWordMask(i); } static inline bool IsAnyBitArrayElementSet(size_t *array, size_t length) { unsigned numWords = NumWordsForBitArrayOfLength(length); for (unsigned i = 0; i < numWords; ++i) { if (array[i]) return true; } return false; } static inline void SetBitArrayElement(size_t *array, size_t length, size_t i) { array[BitArrayIndexToWordIndex(length, i)] |= BitArrayIndexToWordMask(i); } static inline void ClearBitArrayElement(size_t *array, size_t length, size_t i) { array[BitArrayIndexToWordIndex(length, i)] &= ~BitArrayIndexToWordMask(i); } static inline void ClearAllBitArrayElements(size_t *array, size_t length) { for (unsigned i = 0; i < length; ++i) array[i] = 0; } } /* namespace js */ #endif /* __cplusplus */ /* * JS_ROTATE_LEFT32 * * There is no rotate operation in the C Language so the construct (a << 4) | * (a >> 28) is used instead. Most compilers convert this to a rotate * instruction but some versions of MSVC don't without a little help. To get * MSVC to generate a rotate instruction, we have to use the _rotl intrinsic * and use a pragma to make _rotl inline. * * MSVC in VS2005 will do an inline rotate instruction on the above construct. */ #if defined(_MSC_VER) && (defined(_M_IX86) || defined(_M_AMD64) || \ defined(_M_X64)) #include #pragma intrinsic(_rotl) #define JS_ROTATE_LEFT32(a, bits) _rotl(a, bits) #else #define JS_ROTATE_LEFT32(a, bits) (((a) << (bits)) | ((a) >> (32 - (bits)))) #endif /* Static control-flow checks. */ #ifdef NS_STATIC_CHECKING /* Trigger a control flow check to make sure that code flows through label */ inline __attribute__ ((unused)) void MUST_FLOW_THROUGH(const char *label) {} /* Avoid unused goto-label warnings. */ # define MUST_FLOW_LABEL(label) goto label; label: #else # define MUST_FLOW_THROUGH(label) ((void) 0) # define MUST_FLOW_LABEL(label) #endif /* Crash diagnostics */ #ifdef DEBUG # define JS_CRASH_DIAGNOSTICS 1 #endif #ifdef JS_CRASH_DIAGNOSTICS # define JS_POISON(p, val, size) memset((p), (val), (size)) #else # define JS_POISON(p, val, size) ((void) 0) #endif /* Basic stats */ #ifdef DEBUG # define JS_BASIC_STATS 1 #endif #ifdef JS_BASIC_STATS # include typedef struct JSBasicStats { uint32_t num; uint32_t max; double sum; double sqsum; uint32_t logscale; /* logarithmic scale: 0 (linear), 2, 10 */ uint32_t hist[11]; } JSBasicStats; # define JS_INIT_STATIC_BASIC_STATS {0,0,0,0,0,{0,0,0,0,0,0,0,0,0,0,0}} # define JS_BASIC_STATS_INIT(bs) memset((bs), 0, sizeof(JSBasicStats)) # define JS_BASIC_STATS_ACCUM(bs,val) \ JS_BasicStatsAccum(bs, val) # define JS_MeanAndStdDevBS(bs,sigma) \ JS_MeanAndStdDev((bs)->num, (bs)->sum, (bs)->sqsum, sigma) extern void JS_BasicStatsAccum(JSBasicStats *bs, uint32_t val); extern double JS_MeanAndStdDev(uint32_t num, double sum, double sqsum, double *sigma); extern void JS_DumpBasicStats(JSBasicStats *bs, const char *title, FILE *fp); extern void JS_DumpHistogram(JSBasicStats *bs, FILE *fp); #else # define JS_BASIC_STATS_ACCUM(bs,val) #endif /* A jsbitmap_t is a long integer that can be used for bitmaps. */ typedef size_t jsbitmap; #define JS_TEST_BIT(_map,_bit) ((_map)[(_bit)>>JS_BITS_PER_WORD_LOG2] & \ ((jsbitmap)1<<((_bit)&(JS_BITS_PER_WORD-1)))) #define JS_SET_BIT(_map,_bit) ((_map)[(_bit)>>JS_BITS_PER_WORD_LOG2] |= \ ((jsbitmap)1<<((_bit)&(JS_BITS_PER_WORD-1)))) #define JS_CLEAR_BIT(_map,_bit) ((_map)[(_bit)>>JS_BITS_PER_WORD_LOG2] &= \ ~((jsbitmap)1<<((_bit)&(JS_BITS_PER_WORD-1)))) /* Wrapper for various macros to stop warnings coming from their expansions. */ #if defined(__clang__) # define JS_SILENCE_UNUSED_VALUE_IN_EXPR(expr) \ JS_BEGIN_MACRO \ _Pragma("clang diagnostic push") \ _Pragma("clang diagnostic ignored \"-Wunused-value\"") \ expr; \ _Pragma("clang diagnostic pop") \ JS_END_MACRO #elif (__GNUC__ >= 5) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6) # define JS_SILENCE_UNUSED_VALUE_IN_EXPR(expr) \ JS_BEGIN_MACRO \ _Pragma("GCC diagnostic push") \ _Pragma("GCC diagnostic ignored \"-Wunused-but-set-variable\"") \ expr; \ _Pragma("GCC diagnostic pop") \ JS_END_MACRO #else # define JS_SILENCE_UNUSED_VALUE_IN_EXPR(expr) \ JS_BEGIN_MACRO \ expr; \ JS_END_MACRO #endif #endif /* jsutil_h___ */