//=-- lsan_common.cc ------------------------------------------------------===// // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file is a part of LeakSanitizer. // Implementation of common leak checking functionality. // //===----------------------------------------------------------------------===// #include "lsan_common.h" #include "sanitizer_common/sanitizer_common.h" #include "sanitizer_common/sanitizer_flags.h" #include "sanitizer_common/sanitizer_placement_new.h" #include "sanitizer_common/sanitizer_stackdepot.h" #include "sanitizer_common/sanitizer_stacktrace.h" #include "sanitizer_common/sanitizer_stoptheworld.h" #include "sanitizer_common/sanitizer_suppressions.h" #include "sanitizer_common/sanitizer_report_decorator.h" #if CAN_SANITIZE_LEAKS namespace __lsan { // This mutex is used to prevent races between DoLeakCheck and IgnoreObject. BlockingMutex global_mutex(LINKER_INITIALIZED); THREADLOCAL int disable_counter; bool DisabledInThisThread() { return disable_counter > 0; } Flags lsan_flags; static void InitializeFlags() { Flags *f = flags(); // Default values. f->report_objects = false; f->resolution = 0; f->max_leaks = 0; f->exitcode = 23; f->suppressions=""; f->use_registers = true; f->use_globals = true; f->use_stacks = true; f->use_tls = true; f->use_unaligned = false; f->verbosity = 0; f->log_pointers = false; f->log_threads = false; const char *options = GetEnv("LSAN_OPTIONS"); if (options) { ParseFlag(options, &f->use_registers, "use_registers"); ParseFlag(options, &f->use_globals, "use_globals"); ParseFlag(options, &f->use_stacks, "use_stacks"); ParseFlag(options, &f->use_tls, "use_tls"); ParseFlag(options, &f->use_unaligned, "use_unaligned"); ParseFlag(options, &f->report_objects, "report_objects"); ParseFlag(options, &f->resolution, "resolution"); CHECK_GE(&f->resolution, 0); ParseFlag(options, &f->max_leaks, "max_leaks"); CHECK_GE(&f->max_leaks, 0); ParseFlag(options, &f->verbosity, "verbosity"); ParseFlag(options, &f->log_pointers, "log_pointers"); ParseFlag(options, &f->log_threads, "log_threads"); ParseFlag(options, &f->exitcode, "exitcode"); ParseFlag(options, &f->suppressions, "suppressions"); } } SuppressionContext *suppression_ctx; void InitializeSuppressions() { CHECK(!suppression_ctx); ALIGNED(64) static char placeholder_[sizeof(SuppressionContext)]; suppression_ctx = new(placeholder_) SuppressionContext; char *suppressions_from_file; uptr buffer_size; if (ReadFileToBuffer(flags()->suppressions, &suppressions_from_file, &buffer_size, 1 << 26 /* max_len */)) suppression_ctx->Parse(suppressions_from_file); if (flags()->suppressions[0] && !buffer_size) { Printf("LeakSanitizer: failed to read suppressions file '%s'\n", flags()->suppressions); Die(); } if (&__lsan_default_suppressions) suppression_ctx->Parse(__lsan_default_suppressions()); } void InitCommonLsan() { InitializeFlags(); if (common_flags()->detect_leaks) { // Initialization which can fail or print warnings should only be done if // LSan is actually enabled. InitializeSuppressions(); InitializePlatformSpecificModules(); } } class Decorator: private __sanitizer::AnsiColorDecorator { public: Decorator() : __sanitizer::AnsiColorDecorator(PrintsToTtyCached()) { } const char *Error() { return Red(); } const char *Leak() { return Blue(); } const char *End() { return Default(); } }; static inline bool CanBeAHeapPointer(uptr p) { // Since our heap is located in mmap-ed memory, we can assume a sensible lower // bound on heap addresses. const uptr kMinAddress = 4 * 4096; if (p < kMinAddress) return false; #ifdef __x86_64__ // Accept only canonical form user-space addresses. return ((p >> 47) == 0); #else return true; #endif } // Scans the memory range, looking for byte patterns that point into allocator // chunks. Marks those chunks with |tag| and adds them to |frontier|. // There are two usage modes for this function: finding reachable or ignored // chunks (|tag| = kReachable or kIgnored) and finding indirectly leaked chunks // (|tag| = kIndirectlyLeaked). In the second case, there's no flood fill, // so |frontier| = 0. void ScanRangeForPointers(uptr begin, uptr end, Frontier *frontier, const char *region_type, ChunkTag tag) { const uptr alignment = flags()->pointer_alignment(); if (flags()->log_pointers) Report("Scanning %s range %p-%p.\n", region_type, begin, end); uptr pp = begin; if (pp % alignment) pp = pp + alignment - pp % alignment; for (; pp + sizeof(void *) <= end; pp += alignment) { // NOLINT void *p = *reinterpret_cast(pp); if (!CanBeAHeapPointer(reinterpret_cast(p))) continue; uptr chunk = PointsIntoChunk(p); if (!chunk) continue; // Pointers to self don't count. This matters when tag == kIndirectlyLeaked. if (chunk == begin) continue; LsanMetadata m(chunk); // Reachable beats ignored beats leaked. if (m.tag() == kReachable) continue; if (m.tag() == kIgnored && tag != kReachable) continue; m.set_tag(tag); if (flags()->log_pointers) Report("%p: found %p pointing into chunk %p-%p of size %zu.\n", pp, p, chunk, chunk + m.requested_size(), m.requested_size()); if (frontier) frontier->push_back(chunk); } } void ForEachExtraStackRangeCb(uptr begin, uptr end, void* arg) { Frontier *frontier = reinterpret_cast(arg); ScanRangeForPointers(begin, end, frontier, "FAKE STACK", kReachable); } // Scans thread data (stacks and TLS) for heap pointers. static void ProcessThreads(SuspendedThreadsList const &suspended_threads, Frontier *frontier) { InternalScopedBuffer registers(SuspendedThreadsList::RegisterCount()); uptr registers_begin = reinterpret_cast(registers.data()); uptr registers_end = registers_begin + registers.size(); for (uptr i = 0; i < suspended_threads.thread_count(); i++) { uptr os_id = static_cast(suspended_threads.GetThreadID(i)); if (flags()->log_threads) Report("Processing thread %d.\n", os_id); uptr stack_begin, stack_end, tls_begin, tls_end, cache_begin, cache_end; bool thread_found = GetThreadRangesLocked(os_id, &stack_begin, &stack_end, &tls_begin, &tls_end, &cache_begin, &cache_end); if (!thread_found) { // If a thread can't be found in the thread registry, it's probably in the // process of destruction. Log this event and move on. if (flags()->log_threads) Report("Thread %d not found in registry.\n", os_id); continue; } uptr sp; bool have_registers = (suspended_threads.GetRegistersAndSP(i, registers.data(), &sp) == 0); if (!have_registers) { Report("Unable to get registers from thread %d.\n"); // If unable to get SP, consider the entire stack to be reachable. sp = stack_begin; } if (flags()->use_registers && have_registers) ScanRangeForPointers(registers_begin, registers_end, frontier, "REGISTERS", kReachable); if (flags()->use_stacks) { if (flags()->log_threads) Report("Stack at %p-%p, SP = %p.\n", stack_begin, stack_end, sp); if (sp < stack_begin || sp >= stack_end) { // SP is outside the recorded stack range (e.g. the thread is running a // signal handler on alternate stack). Again, consider the entire stack // range to be reachable. if (flags()->log_threads) Report("WARNING: stack pointer not in stack range.\n"); } else { // Shrink the stack range to ignore out-of-scope values. stack_begin = sp; } ScanRangeForPointers(stack_begin, stack_end, frontier, "STACK", kReachable); ForEachExtraStackRange(os_id, ForEachExtraStackRangeCb, frontier); } if (flags()->use_tls) { if (flags()->log_threads) Report("TLS at %p-%p.\n", tls_begin, tls_end); if (cache_begin == cache_end) { ScanRangeForPointers(tls_begin, tls_end, frontier, "TLS", kReachable); } else { // Because LSan should not be loaded with dlopen(), we can assume // that allocator cache will be part of static TLS image. CHECK_LE(tls_begin, cache_begin); CHECK_GE(tls_end, cache_end); if (tls_begin < cache_begin) ScanRangeForPointers(tls_begin, cache_begin, frontier, "TLS", kReachable); if (tls_end > cache_end) ScanRangeForPointers(cache_end, tls_end, frontier, "TLS", kReachable); } } } } static void FloodFillTag(Frontier *frontier, ChunkTag tag) { while (frontier->size()) { uptr next_chunk = frontier->back(); frontier->pop_back(); LsanMetadata m(next_chunk); ScanRangeForPointers(next_chunk, next_chunk + m.requested_size(), frontier, "HEAP", tag); } } // ForEachChunk callback. If the chunk is marked as leaked, marks all chunks // which are reachable from it as indirectly leaked. static void MarkIndirectlyLeakedCb(uptr chunk, void *arg) { chunk = GetUserBegin(chunk); LsanMetadata m(chunk); if (m.allocated() && m.tag() != kReachable) { ScanRangeForPointers(chunk, chunk + m.requested_size(), /* frontier */ 0, "HEAP", kIndirectlyLeaked); } } // ForEachChunk callback. If chunk is marked as ignored, adds its address to // frontier. static void CollectIgnoredCb(uptr chunk, void *arg) { CHECK(arg); chunk = GetUserBegin(chunk); LsanMetadata m(chunk); if (m.allocated() && m.tag() == kIgnored) reinterpret_cast(arg)->push_back(chunk); } // Sets the appropriate tag on each chunk. static void ClassifyAllChunks(SuspendedThreadsList const &suspended_threads) { // Holds the flood fill frontier. Frontier frontier(GetPageSizeCached()); if (flags()->use_globals) ProcessGlobalRegions(&frontier); ProcessThreads(suspended_threads, &frontier); FloodFillTag(&frontier, kReachable); // The check here is relatively expensive, so we do this in a separate flood // fill. That way we can skip the check for chunks that are reachable // otherwise. if (flags()->log_pointers) Report("Processing platform-specific allocations.\n"); ProcessPlatformSpecificAllocations(&frontier); FloodFillTag(&frontier, kReachable); if (flags()->log_pointers) Report("Scanning ignored chunks.\n"); CHECK_EQ(0, frontier.size()); ForEachChunk(CollectIgnoredCb, &frontier); FloodFillTag(&frontier, kIgnored); // Iterate over leaked chunks and mark those that are reachable from other // leaked chunks. if (flags()->log_pointers) Report("Scanning leaked chunks.\n"); ForEachChunk(MarkIndirectlyLeakedCb, 0 /* arg */); } static void PrintStackTraceById(u32 stack_trace_id) { CHECK(stack_trace_id); uptr size = 0; const uptr *trace = StackDepotGet(stack_trace_id, &size); StackTrace::PrintStack(trace, size); } // ForEachChunk callback. Aggregates unreachable chunks into a LeakReport. static void CollectLeaksCb(uptr chunk, void *arg) { CHECK(arg); LeakReport *leak_report = reinterpret_cast(arg); chunk = GetUserBegin(chunk); LsanMetadata m(chunk); if (!m.allocated()) return; if (m.tag() == kDirectlyLeaked || m.tag() == kIndirectlyLeaked) { uptr resolution = flags()->resolution; if (resolution > 0) { uptr size = 0; const uptr *trace = StackDepotGet(m.stack_trace_id(), &size); size = Min(size, resolution); leak_report->Add(StackDepotPut(trace, size), m.requested_size(), m.tag()); } else { leak_report->Add(m.stack_trace_id(), m.requested_size(), m.tag()); } } } // ForEachChunkCallback. Prints addresses of unreachable chunks. static void PrintLeakedCb(uptr chunk, void *arg) { chunk = GetUserBegin(chunk); LsanMetadata m(chunk); if (!m.allocated()) return; if (m.tag() == kDirectlyLeaked || m.tag() == kIndirectlyLeaked) { Printf("%s leaked %zu byte object at %p.\n", m.tag() == kDirectlyLeaked ? "Directly" : "Indirectly", m.requested_size(), chunk); } } static void PrintMatchedSuppressions() { InternalMmapVector matched(1); suppression_ctx->GetMatched(&matched); if (!matched.size()) return; const char *line = "-----------------------------------------------------"; Printf("%s\n", line); Printf("Suppressions used:\n"); Printf(" count bytes template\n"); for (uptr i = 0; i < matched.size(); i++) Printf("%7zu %10zu %s\n", static_cast(matched[i]->hit_count), matched[i]->weight, matched[i]->templ); Printf("%s\n\n", line); } static void PrintLeaked() { Printf("\n"); Printf("Reporting individual objects:\n"); ForEachChunk(PrintLeakedCb, 0 /* arg */); } struct DoLeakCheckParam { bool success; LeakReport leak_report; }; static void DoLeakCheckCallback(const SuspendedThreadsList &suspended_threads, void *arg) { DoLeakCheckParam *param = reinterpret_cast(arg); CHECK(param); CHECK(!param->success); CHECK(param->leak_report.IsEmpty()); ClassifyAllChunks(suspended_threads); ForEachChunk(CollectLeaksCb, ¶m->leak_report); if (!param->leak_report.IsEmpty() && flags()->report_objects) PrintLeaked(); param->success = true; } void DoLeakCheck() { EnsureMainThreadIDIsCorrect(); BlockingMutexLock l(&global_mutex); static bool already_done; if (already_done) return; already_done = true; if (&__lsan_is_turned_off && __lsan_is_turned_off()) return; DoLeakCheckParam param; param.success = false; LockThreadRegistry(); LockAllocator(); StopTheWorld(DoLeakCheckCallback, ¶m); UnlockAllocator(); UnlockThreadRegistry(); if (!param.success) { Report("LeakSanitizer has encountered a fatal error.\n"); Die(); } uptr have_unsuppressed = param.leak_report.ApplySuppressions(); if (have_unsuppressed) { Decorator d; Printf("\n" "=================================================================" "\n"); Printf("%s", d.Error()); Report("ERROR: LeakSanitizer: detected memory leaks\n"); Printf("%s", d.End()); param.leak_report.PrintLargest(flags()->max_leaks); } if (have_unsuppressed || (flags()->verbosity >= 1)) { PrintMatchedSuppressions(); param.leak_report.PrintSummary(); } if (have_unsuppressed && flags()->exitcode) internal__exit(flags()->exitcode); } static Suppression *GetSuppressionForAddr(uptr addr) { static const uptr kMaxAddrFrames = 16; InternalScopedBuffer addr_frames(kMaxAddrFrames); for (uptr i = 0; i < kMaxAddrFrames; i++) new (&addr_frames[i]) AddressInfo(); uptr addr_frames_num = Symbolizer::Get()->SymbolizeCode( addr, addr_frames.data(), kMaxAddrFrames); for (uptr i = 0; i < addr_frames_num; i++) { Suppression* s; if (suppression_ctx->Match(addr_frames[i].function, SuppressionLeak, &s) || suppression_ctx->Match(addr_frames[i].file, SuppressionLeak, &s) || suppression_ctx->Match(addr_frames[i].module, SuppressionLeak, &s)) return s; } return 0; } static Suppression *GetSuppressionForStack(u32 stack_trace_id) { uptr size = 0; const uptr *trace = StackDepotGet(stack_trace_id, &size); for (uptr i = 0; i < size; i++) { Suppression *s = GetSuppressionForAddr(StackTrace::GetPreviousInstructionPc(trace[i])); if (s) return s; } return 0; } ///// LeakReport implementation. ///// // A hard limit on the number of distinct leaks, to avoid quadratic complexity // in LeakReport::Add(). We don't expect to ever see this many leaks in // real-world applications. // FIXME: Get rid of this limit by changing the implementation of LeakReport to // use a hash table. const uptr kMaxLeaksConsidered = 5000; void LeakReport::Add(u32 stack_trace_id, uptr leaked_size, ChunkTag tag) { CHECK(tag == kDirectlyLeaked || tag == kIndirectlyLeaked); bool is_directly_leaked = (tag == kDirectlyLeaked); for (uptr i = 0; i < leaks_.size(); i++) if (leaks_[i].stack_trace_id == stack_trace_id && leaks_[i].is_directly_leaked == is_directly_leaked) { leaks_[i].hit_count++; leaks_[i].total_size += leaked_size; return; } if (leaks_.size() == kMaxLeaksConsidered) return; Leak leak = { /* hit_count */ 1, leaked_size, stack_trace_id, is_directly_leaked, /* is_suppressed */ false }; leaks_.push_back(leak); } static bool LeakComparator(const Leak &leak1, const Leak &leak2) { if (leak1.is_directly_leaked == leak2.is_directly_leaked) return leak1.total_size > leak2.total_size; else return leak1.is_directly_leaked; } void LeakReport::PrintLargest(uptr num_leaks_to_print) { CHECK(leaks_.size() <= kMaxLeaksConsidered); Printf("\n"); if (leaks_.size() == kMaxLeaksConsidered) Printf("Too many leaks! Only the first %zu leaks encountered will be " "reported.\n", kMaxLeaksConsidered); uptr unsuppressed_count = 0; for (uptr i = 0; i < leaks_.size(); i++) if (!leaks_[i].is_suppressed) unsuppressed_count++; if (num_leaks_to_print > 0 && num_leaks_to_print < unsuppressed_count) Printf("The %zu largest leak(s):\n", num_leaks_to_print); InternalSort(&leaks_, leaks_.size(), LeakComparator); uptr leaks_printed = 0; Decorator d; for (uptr i = 0; i < leaks_.size(); i++) { if (leaks_[i].is_suppressed) continue; Printf("%s", d.Leak()); Printf("%s leak of %zu byte(s) in %zu object(s) allocated from:\n", leaks_[i].is_directly_leaked ? "Direct" : "Indirect", leaks_[i].total_size, leaks_[i].hit_count); Printf("%s", d.End()); PrintStackTraceById(leaks_[i].stack_trace_id); leaks_printed++; if (leaks_printed == num_leaks_to_print) break; } if (leaks_printed < unsuppressed_count) { uptr remaining = unsuppressed_count - leaks_printed; Printf("Omitting %zu more leak(s).\n", remaining); } } void LeakReport::PrintSummary() { CHECK(leaks_.size() <= kMaxLeaksConsidered); uptr bytes = 0, allocations = 0; for (uptr i = 0; i < leaks_.size(); i++) { if (leaks_[i].is_suppressed) continue; bytes += leaks_[i].total_size; allocations += leaks_[i].hit_count; } InternalScopedBuffer summary(kMaxSummaryLength); internal_snprintf(summary.data(), summary.size(), "%zu byte(s) leaked in %zu allocation(s).", bytes, allocations); ReportErrorSummary(summary.data()); } uptr LeakReport::ApplySuppressions() { uptr unsuppressed_count = 0; for (uptr i = 0; i < leaks_.size(); i++) { Suppression *s = GetSuppressionForStack(leaks_[i].stack_trace_id); if (s) { s->weight += leaks_[i].total_size; s->hit_count += leaks_[i].hit_count; leaks_[i].is_suppressed = true; } else { unsuppressed_count++; } } return unsuppressed_count; } } // namespace __lsan #endif // CAN_SANITIZE_LEAKS using namespace __lsan; // NOLINT extern "C" { SANITIZER_INTERFACE_ATTRIBUTE void __lsan_ignore_object(const void *p) { #if CAN_SANITIZE_LEAKS if (!common_flags()->detect_leaks) return; // Cannot use PointsIntoChunk or LsanMetadata here, since the allocator is not // locked. BlockingMutexLock l(&global_mutex); IgnoreObjectResult res = IgnoreObjectLocked(p); if (res == kIgnoreObjectInvalid && flags()->verbosity >= 2) Report("__lsan_ignore_object(): no heap object found at %p", p); if (res == kIgnoreObjectAlreadyIgnored && flags()->verbosity >= 2) Report("__lsan_ignore_object(): " "heap object at %p is already being ignored\n", p); if (res == kIgnoreObjectSuccess && flags()->verbosity >= 3) Report("__lsan_ignore_object(): ignoring heap object at %p\n", p); #endif // CAN_SANITIZE_LEAKS } SANITIZER_INTERFACE_ATTRIBUTE void __lsan_disable() { #if CAN_SANITIZE_LEAKS __lsan::disable_counter++; #endif } SANITIZER_INTERFACE_ATTRIBUTE void __lsan_enable() { #if CAN_SANITIZE_LEAKS if (!__lsan::disable_counter && common_flags()->detect_leaks) { Report("Unmatched call to __lsan_enable().\n"); Die(); } __lsan::disable_counter--; #endif } SANITIZER_INTERFACE_ATTRIBUTE void __lsan_do_leak_check() { #if CAN_SANITIZE_LEAKS if (common_flags()->detect_leaks) __lsan::DoLeakCheck(); #endif // CAN_SANITIZE_LEAKS } #if !SANITIZER_SUPPORTS_WEAK_HOOKS SANITIZER_INTERFACE_ATTRIBUTE SANITIZER_WEAK_ATTRIBUTE int __lsan_is_turned_off() { return 0; } #endif } // extern "C"