//===-- tsan_interface_ann.cc ---------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file is a part of ThreadSanitizer (TSan), a race detector. // //===----------------------------------------------------------------------===// #include "sanitizer_common/sanitizer_libc.h" #include "sanitizer_common/sanitizer_internal_defs.h" #include "sanitizer_common/sanitizer_placement_new.h" #include "sanitizer_common/sanitizer_stacktrace.h" #include "sanitizer_common/sanitizer_vector.h" #include "tsan_interface_ann.h" #include "tsan_mutex.h" #include "tsan_report.h" #include "tsan_rtl.h" #include "tsan_mman.h" #include "tsan_flags.h" #include "tsan_platform.h" #define CALLERPC ((uptr)__builtin_return_address(0)) using namespace __tsan; // NOLINT namespace __tsan { class ScopedAnnotation { public: ScopedAnnotation(ThreadState *thr, const char *aname, uptr pc) : thr_(thr) { FuncEntry(thr_, pc); DPrintf("#%d: annotation %s()\n", thr_->tid, aname); } ~ScopedAnnotation() { FuncExit(thr_); CheckNoLocks(thr_); } private: ThreadState *const thr_; }; #define SCOPED_ANNOTATION_RET(typ, ret) \ if (!flags()->enable_annotations) \ return ret; \ ThreadState *thr = cur_thread(); \ const uptr caller_pc = (uptr)__builtin_return_address(0); \ StatInc(thr, StatAnnotation); \ StatInc(thr, Stat##typ); \ ScopedAnnotation sa(thr, __func__, caller_pc); \ const uptr pc = StackTrace::GetCurrentPc(); \ (void)pc; \ /**/ #define SCOPED_ANNOTATION(typ) SCOPED_ANNOTATION_RET(typ, ) static const int kMaxDescLen = 128; struct ExpectRace { ExpectRace *next; ExpectRace *prev; atomic_uintptr_t hitcount; atomic_uintptr_t addcount; uptr addr; uptr size; char *file; int line; char desc[kMaxDescLen]; }; struct DynamicAnnContext { Mutex mtx; ExpectRace expect; ExpectRace benign; DynamicAnnContext() : mtx(MutexTypeAnnotations, StatMtxAnnotations) { } }; static DynamicAnnContext *dyn_ann_ctx; static char dyn_ann_ctx_placeholder[sizeof(DynamicAnnContext)] ALIGNED(64); static void AddExpectRace(ExpectRace *list, char *f, int l, uptr addr, uptr size, char *desc) { ExpectRace *race = list->next; for (; race != list; race = race->next) { if (race->addr == addr && race->size == size) { atomic_store_relaxed(&race->addcount, atomic_load_relaxed(&race->addcount) + 1); return; } } race = (ExpectRace*)internal_alloc(MBlockExpectRace, sizeof(ExpectRace)); race->addr = addr; race->size = size; race->file = f; race->line = l; race->desc[0] = 0; atomic_store_relaxed(&race->hitcount, 0); atomic_store_relaxed(&race->addcount, 1); if (desc) { int i = 0; for (; i < kMaxDescLen - 1 && desc[i]; i++) race->desc[i] = desc[i]; race->desc[i] = 0; } race->prev = list; race->next = list->next; race->next->prev = race; list->next = race; } static ExpectRace *FindRace(ExpectRace *list, uptr addr, uptr size) { for (ExpectRace *race = list->next; race != list; race = race->next) { uptr maxbegin = max(race->addr, addr); uptr minend = min(race->addr + race->size, addr + size); if (maxbegin < minend) return race; } return 0; } static bool CheckContains(ExpectRace *list, uptr addr, uptr size) { ExpectRace *race = FindRace(list, addr, size); if (race == 0) return false; DPrintf("Hit expected/benign race: %s addr=%zx:%d %s:%d\n", race->desc, race->addr, (int)race->size, race->file, race->line); atomic_fetch_add(&race->hitcount, 1, memory_order_relaxed); return true; } static void InitList(ExpectRace *list) { list->next = list; list->prev = list; } void InitializeDynamicAnnotations() { dyn_ann_ctx = new(dyn_ann_ctx_placeholder) DynamicAnnContext; InitList(&dyn_ann_ctx->expect); InitList(&dyn_ann_ctx->benign); } bool IsExpectedReport(uptr addr, uptr size) { ReadLock lock(&dyn_ann_ctx->mtx); if (CheckContains(&dyn_ann_ctx->expect, addr, size)) return true; if (CheckContains(&dyn_ann_ctx->benign, addr, size)) return true; return false; } static void CollectMatchedBenignRaces(Vector *matched, int *unique_count, int *hit_count, atomic_uintptr_t ExpectRace::*counter) { ExpectRace *list = &dyn_ann_ctx->benign; for (ExpectRace *race = list->next; race != list; race = race->next) { (*unique_count)++; const uptr cnt = atomic_load_relaxed(&(race->*counter)); if (cnt == 0) continue; *hit_count += cnt; uptr i = 0; for (; i < matched->Size(); i++) { ExpectRace *race0 = &(*matched)[i]; if (race->line == race0->line && internal_strcmp(race->file, race0->file) == 0 && internal_strcmp(race->desc, race0->desc) == 0) { atomic_fetch_add(&(race0->*counter), cnt, memory_order_relaxed); break; } } if (i == matched->Size()) matched->PushBack(*race); } } void PrintMatchedBenignRaces() { Lock lock(&dyn_ann_ctx->mtx); int unique_count = 0; int hit_count = 0; int add_count = 0; Vector hit_matched; CollectMatchedBenignRaces(&hit_matched, &unique_count, &hit_count, &ExpectRace::hitcount); Vector add_matched; CollectMatchedBenignRaces(&add_matched, &unique_count, &add_count, &ExpectRace::addcount); if (hit_matched.Size()) { Printf("ThreadSanitizer: Matched %d \"benign\" races (pid=%d):\n", hit_count, (int)internal_getpid()); for (uptr i = 0; i < hit_matched.Size(); i++) { Printf("%d %s:%d %s\n", atomic_load_relaxed(&hit_matched[i].hitcount), hit_matched[i].file, hit_matched[i].line, hit_matched[i].desc); } } if (hit_matched.Size()) { Printf("ThreadSanitizer: Annotated %d \"benign\" races, %d unique" " (pid=%d):\n", add_count, unique_count, (int)internal_getpid()); for (uptr i = 0; i < add_matched.Size(); i++) { Printf("%d %s:%d %s\n", atomic_load_relaxed(&add_matched[i].addcount), add_matched[i].file, add_matched[i].line, add_matched[i].desc); } } } static void ReportMissedExpectedRace(ExpectRace *race) { Printf("==================\n"); Printf("WARNING: ThreadSanitizer: missed expected data race\n"); Printf(" %s addr=%zx %s:%d\n", race->desc, race->addr, race->file, race->line); Printf("==================\n"); } } // namespace __tsan using namespace __tsan; // NOLINT extern "C" { void INTERFACE_ATTRIBUTE AnnotateHappensBefore(char *f, int l, uptr addr) { SCOPED_ANNOTATION(AnnotateHappensBefore); Release(thr, pc, addr); } void INTERFACE_ATTRIBUTE AnnotateHappensAfter(char *f, int l, uptr addr) { SCOPED_ANNOTATION(AnnotateHappensAfter); Acquire(thr, pc, addr); } void INTERFACE_ATTRIBUTE AnnotateCondVarSignal(char *f, int l, uptr cv) { SCOPED_ANNOTATION(AnnotateCondVarSignal); } void INTERFACE_ATTRIBUTE AnnotateCondVarSignalAll(char *f, int l, uptr cv) { SCOPED_ANNOTATION(AnnotateCondVarSignalAll); } void INTERFACE_ATTRIBUTE AnnotateMutexIsNotPHB(char *f, int l, uptr mu) { SCOPED_ANNOTATION(AnnotateMutexIsNotPHB); } void INTERFACE_ATTRIBUTE AnnotateCondVarWait(char *f, int l, uptr cv, uptr lock) { SCOPED_ANNOTATION(AnnotateCondVarWait); } void INTERFACE_ATTRIBUTE AnnotateRWLockCreate(char *f, int l, uptr m) { SCOPED_ANNOTATION(AnnotateRWLockCreate); MutexCreate(thr, pc, m, MutexFlagWriteReentrant); } void INTERFACE_ATTRIBUTE AnnotateRWLockCreateStatic(char *f, int l, uptr m) { SCOPED_ANNOTATION(AnnotateRWLockCreateStatic); MutexCreate(thr, pc, m, MutexFlagWriteReentrant | MutexFlagLinkerInit); } void INTERFACE_ATTRIBUTE AnnotateRWLockDestroy(char *f, int l, uptr m) { SCOPED_ANNOTATION(AnnotateRWLockDestroy); MutexDestroy(thr, pc, m); } void INTERFACE_ATTRIBUTE AnnotateRWLockAcquired(char *f, int l, uptr m, uptr is_w) { SCOPED_ANNOTATION(AnnotateRWLockAcquired); if (is_w) MutexPostLock(thr, pc, m, MutexFlagDoPreLockOnPostLock); else MutexPostReadLock(thr, pc, m, MutexFlagDoPreLockOnPostLock); } void INTERFACE_ATTRIBUTE AnnotateRWLockReleased(char *f, int l, uptr m, uptr is_w) { SCOPED_ANNOTATION(AnnotateRWLockReleased); if (is_w) MutexUnlock(thr, pc, m); else MutexReadUnlock(thr, pc, m); } void INTERFACE_ATTRIBUTE AnnotateTraceMemory(char *f, int l, uptr mem) { SCOPED_ANNOTATION(AnnotateTraceMemory); } void INTERFACE_ATTRIBUTE AnnotateFlushState(char *f, int l) { SCOPED_ANNOTATION(AnnotateFlushState); } void INTERFACE_ATTRIBUTE AnnotateNewMemory(char *f, int l, uptr mem, uptr size) { SCOPED_ANNOTATION(AnnotateNewMemory); } void INTERFACE_ATTRIBUTE AnnotateNoOp(char *f, int l, uptr mem) { SCOPED_ANNOTATION(AnnotateNoOp); } void INTERFACE_ATTRIBUTE AnnotateFlushExpectedRaces(char *f, int l) { SCOPED_ANNOTATION(AnnotateFlushExpectedRaces); Lock lock(&dyn_ann_ctx->mtx); while (dyn_ann_ctx->expect.next != &dyn_ann_ctx->expect) { ExpectRace *race = dyn_ann_ctx->expect.next; if (atomic_load_relaxed(&race->hitcount) == 0) { ctx->nmissed_expected++; ReportMissedExpectedRace(race); } race->prev->next = race->next; race->next->prev = race->prev; internal_free(race); } } void INTERFACE_ATTRIBUTE AnnotateEnableRaceDetection( char *f, int l, int enable) { SCOPED_ANNOTATION(AnnotateEnableRaceDetection); // FIXME: Reconsider this functionality later. It may be irrelevant. } void INTERFACE_ATTRIBUTE AnnotateMutexIsUsedAsCondVar( char *f, int l, uptr mu) { SCOPED_ANNOTATION(AnnotateMutexIsUsedAsCondVar); } void INTERFACE_ATTRIBUTE AnnotatePCQGet( char *f, int l, uptr pcq) { SCOPED_ANNOTATION(AnnotatePCQGet); } void INTERFACE_ATTRIBUTE AnnotatePCQPut( char *f, int l, uptr pcq) { SCOPED_ANNOTATION(AnnotatePCQPut); } void INTERFACE_ATTRIBUTE AnnotatePCQDestroy( char *f, int l, uptr pcq) { SCOPED_ANNOTATION(AnnotatePCQDestroy); } void INTERFACE_ATTRIBUTE AnnotatePCQCreate( char *f, int l, uptr pcq) { SCOPED_ANNOTATION(AnnotatePCQCreate); } void INTERFACE_ATTRIBUTE AnnotateExpectRace( char *f, int l, uptr mem, char *desc) { SCOPED_ANNOTATION(AnnotateExpectRace); Lock lock(&dyn_ann_ctx->mtx); AddExpectRace(&dyn_ann_ctx->expect, f, l, mem, 1, desc); DPrintf("Add expected race: %s addr=%zx %s:%d\n", desc, mem, f, l); } static void BenignRaceImpl( char *f, int l, uptr mem, uptr size, char *desc) { Lock lock(&dyn_ann_ctx->mtx); AddExpectRace(&dyn_ann_ctx->benign, f, l, mem, size, desc); DPrintf("Add benign race: %s addr=%zx %s:%d\n", desc, mem, f, l); } // FIXME: Turn it off later. WTF is benign race?1?? Go talk to Hans Boehm. void INTERFACE_ATTRIBUTE AnnotateBenignRaceSized( char *f, int l, uptr mem, uptr size, char *desc) { SCOPED_ANNOTATION(AnnotateBenignRaceSized); BenignRaceImpl(f, l, mem, size, desc); } void INTERFACE_ATTRIBUTE AnnotateBenignRace( char *f, int l, uptr mem, char *desc) { SCOPED_ANNOTATION(AnnotateBenignRace); BenignRaceImpl(f, l, mem, 1, desc); } void INTERFACE_ATTRIBUTE AnnotateIgnoreReadsBegin(char *f, int l) { SCOPED_ANNOTATION(AnnotateIgnoreReadsBegin); ThreadIgnoreBegin(thr, pc); } void INTERFACE_ATTRIBUTE AnnotateIgnoreReadsEnd(char *f, int l) { SCOPED_ANNOTATION(AnnotateIgnoreReadsEnd); ThreadIgnoreEnd(thr, pc); } void INTERFACE_ATTRIBUTE AnnotateIgnoreWritesBegin(char *f, int l) { SCOPED_ANNOTATION(AnnotateIgnoreWritesBegin); ThreadIgnoreBegin(thr, pc); } void INTERFACE_ATTRIBUTE AnnotateIgnoreWritesEnd(char *f, int l) { SCOPED_ANNOTATION(AnnotateIgnoreWritesEnd); ThreadIgnoreEnd(thr, pc); } void INTERFACE_ATTRIBUTE AnnotateIgnoreSyncBegin(char *f, int l) { SCOPED_ANNOTATION(AnnotateIgnoreSyncBegin); ThreadIgnoreSyncBegin(thr, pc); } void INTERFACE_ATTRIBUTE AnnotateIgnoreSyncEnd(char *f, int l) { SCOPED_ANNOTATION(AnnotateIgnoreSyncEnd); ThreadIgnoreSyncEnd(thr, pc); } void INTERFACE_ATTRIBUTE AnnotatePublishMemoryRange( char *f, int l, uptr addr, uptr size) { SCOPED_ANNOTATION(AnnotatePublishMemoryRange); } void INTERFACE_ATTRIBUTE AnnotateUnpublishMemoryRange( char *f, int l, uptr addr, uptr size) { SCOPED_ANNOTATION(AnnotateUnpublishMemoryRange); } void INTERFACE_ATTRIBUTE AnnotateThreadName( char *f, int l, char *name) { SCOPED_ANNOTATION(AnnotateThreadName); ThreadSetName(thr, name); } // We deliberately omit the implementation of WTFAnnotateHappensBefore() and // WTFAnnotateHappensAfter(). Those are being used by Webkit to annotate // atomic operations, which should be handled by ThreadSanitizer correctly. void INTERFACE_ATTRIBUTE WTFAnnotateHappensBefore(char *f, int l, uptr addr) { SCOPED_ANNOTATION(AnnotateHappensBefore); } void INTERFACE_ATTRIBUTE WTFAnnotateHappensAfter(char *f, int l, uptr addr) { SCOPED_ANNOTATION(AnnotateHappensAfter); } void INTERFACE_ATTRIBUTE WTFAnnotateBenignRaceSized( char *f, int l, uptr mem, uptr sz, char *desc) { SCOPED_ANNOTATION(AnnotateBenignRaceSized); BenignRaceImpl(f, l, mem, sz, desc); } int INTERFACE_ATTRIBUTE RunningOnValgrind() { return flags()->running_on_valgrind; } double __attribute__((weak)) INTERFACE_ATTRIBUTE ValgrindSlowdown(void) { return 10.0; } const char INTERFACE_ATTRIBUTE* ThreadSanitizerQuery(const char *query) { if (internal_strcmp(query, "pure_happens_before") == 0) return "1"; else return "0"; } void INTERFACE_ATTRIBUTE AnnotateMemoryIsInitialized(char *f, int l, uptr mem, uptr sz) {} void INTERFACE_ATTRIBUTE AnnotateMemoryIsUninitialized(char *f, int l, uptr mem, uptr sz) {} // Note: the parameter is called flagz, because flags is already taken // by the global function that returns flags. INTERFACE_ATTRIBUTE void __tsan_mutex_create(void *m, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_create); MutexCreate(thr, pc, (uptr)m, flagz & MutexCreationFlagMask); } INTERFACE_ATTRIBUTE void __tsan_mutex_destroy(void *m, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_destroy); MutexDestroy(thr, pc, (uptr)m, flagz); } INTERFACE_ATTRIBUTE void __tsan_mutex_pre_lock(void *m, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_pre_lock); if (!(flagz & MutexFlagTryLock)) { if (flagz & MutexFlagReadLock) MutexPreReadLock(thr, pc, (uptr)m); else MutexPreLock(thr, pc, (uptr)m); } ThreadIgnoreBegin(thr, pc, /*save_stack=*/false); ThreadIgnoreSyncBegin(thr, pc, /*save_stack=*/false); } INTERFACE_ATTRIBUTE void __tsan_mutex_post_lock(void *m, unsigned flagz, int rec) { SCOPED_ANNOTATION(__tsan_mutex_post_lock); ThreadIgnoreSyncEnd(thr, pc); ThreadIgnoreEnd(thr, pc); if (!(flagz & MutexFlagTryLockFailed)) { if (flagz & MutexFlagReadLock) MutexPostReadLock(thr, pc, (uptr)m, flagz); else MutexPostLock(thr, pc, (uptr)m, flagz, rec); } } INTERFACE_ATTRIBUTE int __tsan_mutex_pre_unlock(void *m, unsigned flagz) { SCOPED_ANNOTATION_RET(__tsan_mutex_pre_unlock, 0); int ret = 0; if (flagz & MutexFlagReadLock) { CHECK(!(flagz & MutexFlagRecursiveUnlock)); MutexReadUnlock(thr, pc, (uptr)m); } else { ret = MutexUnlock(thr, pc, (uptr)m, flagz); } ThreadIgnoreBegin(thr, pc, /*save_stack=*/false); ThreadIgnoreSyncBegin(thr, pc, /*save_stack=*/false); return ret; } INTERFACE_ATTRIBUTE void __tsan_mutex_post_unlock(void *m, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_post_unlock); ThreadIgnoreSyncEnd(thr, pc); ThreadIgnoreEnd(thr, pc); } INTERFACE_ATTRIBUTE void __tsan_mutex_pre_signal(void *addr, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_pre_signal); ThreadIgnoreBegin(thr, pc, /*save_stack=*/false); ThreadIgnoreSyncBegin(thr, pc, /*save_stack=*/false); } INTERFACE_ATTRIBUTE void __tsan_mutex_post_signal(void *addr, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_post_signal); ThreadIgnoreSyncEnd(thr, pc); ThreadIgnoreEnd(thr, pc); } INTERFACE_ATTRIBUTE void __tsan_mutex_pre_divert(void *addr, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_pre_divert); // Exit from ignore region started in __tsan_mutex_pre_lock/unlock/signal. ThreadIgnoreSyncEnd(thr, pc); ThreadIgnoreEnd(thr, pc); } INTERFACE_ATTRIBUTE void __tsan_mutex_post_divert(void *addr, unsigned flagz) { SCOPED_ANNOTATION(__tsan_mutex_post_divert); ThreadIgnoreBegin(thr, pc, /*save_stack=*/false); ThreadIgnoreSyncBegin(thr, pc, /*save_stack=*/false); } } // extern "C"