/* * Copyright (C) 2012 The Android Open Source Project * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "Config.h" #include "DebugData.h" #include "backtrace.h" #include "debug_disable.h" #include "debug_log.h" #include "malloc_debug.h" #include "UnwindBacktrace.h" // ------------------------------------------------------------------------ // Global Data // ------------------------------------------------------------------------ DebugData* g_debug; int* g_malloc_zygote_child; const MallocDispatch* g_dispatch; // ------------------------------------------------------------------------ // ------------------------------------------------------------------------ // Use C style prototypes for all exported functions. This makes it easy // to do dlsym lookups during libc initialization when malloc debug // is enabled. // ------------------------------------------------------------------------ __BEGIN_DECLS bool debug_initialize(const MallocDispatch* malloc_dispatch, int* malloc_zygote_child, const char* options); void debug_finalize(); void debug_dump_heap(const char* file_name); void debug_get_malloc_leak_info(uint8_t** info, size_t* overall_size, size_t* info_size, size_t* total_memory, size_t* backtrace_size); bool debug_write_malloc_leak_info(FILE* fp); ssize_t debug_malloc_backtrace(void* pointer, uintptr_t* frames, size_t frame_count); void debug_free_malloc_leak_info(uint8_t* info); size_t debug_malloc_usable_size(void* pointer); void* debug_malloc(size_t size); void debug_free(void* pointer); void* debug_aligned_alloc(size_t alignment, size_t size); void* debug_memalign(size_t alignment, size_t bytes); void* debug_realloc(void* pointer, size_t bytes); void* debug_calloc(size_t nmemb, size_t bytes); struct mallinfo debug_mallinfo(); int debug_mallopt(int param, int value); int debug_posix_memalign(void** memptr, size_t alignment, size_t size); int debug_iterate(uintptr_t base, size_t size, void (*callback)(uintptr_t base, size_t size, void* arg), void* arg); void debug_malloc_disable(); void debug_malloc_enable(); #if defined(HAVE_DEPRECATED_MALLOC_FUNCS) void* debug_pvalloc(size_t bytes); void* debug_valloc(size_t size); #endif __END_DECLS // ------------------------------------------------------------------------ static void InitAtfork() { static pthread_once_t atfork_init = PTHREAD_ONCE_INIT; pthread_once(&atfork_init, []() { pthread_atfork( []() { if (g_debug != nullptr) { g_debug->PrepareFork(); } }, []() { if (g_debug != nullptr) { g_debug->PostForkParent(); } }, []() { if (g_debug != nullptr) { g_debug->PostForkChild(); } }); }); } void BacktraceAndLog() { if (g_debug->config().options() & BACKTRACE_FULL) { std::vector frames; std::vector frames_info; if (!Unwind(&frames, &frames_info, 256)) { error_log(" Backtrace failed to get any frames."); } else { UnwindLog(frames_info); } } else { std::vector frames(256); size_t num_frames = backtrace_get(frames.data(), frames.size()); if (num_frames == 0) { error_log(" Backtrace failed to get any frames."); } else { backtrace_log(frames.data(), num_frames); } } } static void LogError(const void* pointer, const char* error_str) { error_log(LOG_DIVIDER); error_log("+++ ALLOCATION %p %s", pointer, error_str); // If we are tracking already freed pointers, check to see if this is // one so we can print extra information. if (g_debug->config().options() & FREE_TRACK) { PointerData::LogFreeBacktrace(pointer); } error_log("Backtrace at time of failure:"); BacktraceAndLog(); error_log(LOG_DIVIDER); } static bool VerifyPointer(const void* pointer, const char* function_name) { if (g_debug->HeaderEnabled()) { Header* header = g_debug->GetHeader(pointer); if (header->tag != DEBUG_TAG) { std::string error_str; if (header->tag == DEBUG_FREE_TAG) { error_str = std::string("USED AFTER FREE (") + function_name + ")"; } else { error_str = android::base::StringPrintf("HAS INVALID TAG %" PRIx32 " (%s)", header->tag, function_name); } LogError(pointer, error_str.c_str()); return false; } } if (g_debug->TrackPointers()) { if (!PointerData::Exists(pointer)) { std::string error_str(std::string("UNKNOWN POINTER (") + function_name + ")"); LogError(pointer, error_str.c_str()); return false; } } return true; } static size_t InternalMallocUsableSize(void* pointer) { if (g_debug->HeaderEnabled()) { return g_debug->GetHeader(pointer)->usable_size; } else { return g_dispatch->malloc_usable_size(pointer); } } static void* InitHeader(Header* header, void* orig_pointer, size_t size) { header->tag = DEBUG_TAG; header->orig_pointer = orig_pointer; header->size = size; header->usable_size = g_dispatch->malloc_usable_size(orig_pointer); if (header->usable_size == 0) { g_dispatch->free(orig_pointer); return nullptr; } header->usable_size -= g_debug->pointer_offset() + reinterpret_cast(header) - reinterpret_cast(orig_pointer); if (g_debug->config().options() & FRONT_GUARD) { uint8_t* guard = g_debug->GetFrontGuard(header); memset(guard, g_debug->config().front_guard_value(), g_debug->config().front_guard_bytes()); } if (g_debug->config().options() & REAR_GUARD) { uint8_t* guard = g_debug->GetRearGuard(header); memset(guard, g_debug->config().rear_guard_value(), g_debug->config().rear_guard_bytes()); // If the rear guard is enabled, set the usable size to the exact size // of the allocation. header->usable_size = header->size; } return g_debug->GetPointer(header); } bool debug_initialize(const MallocDispatch* malloc_dispatch, int* malloc_zygote_child, const char* options) { if (malloc_zygote_child == nullptr || options == nullptr) { return false; } InitAtfork(); g_malloc_zygote_child = malloc_zygote_child; g_dispatch = malloc_dispatch; if (!DebugDisableInitialize()) { return false; } DebugData* debug = new DebugData(); if (!debug->Initialize(options)) { delete debug; DebugDisableFinalize(); return false; } g_debug = debug; // Always enable the backtrace code since we will use it in a number // of different error cases. backtrace_startup(); return true; } void debug_finalize() { if (g_debug == nullptr) { return; } if (g_debug->config().options() & FREE_TRACK) { PointerData::VerifyAllFreed(); } if (g_debug->config().options() & LEAK_TRACK) { PointerData::LogLeaks(); } if ((g_debug->config().options() & BACKTRACE) && g_debug->config().backtrace_dump_on_exit()) { ScopedDisableDebugCalls disable; debug_dump_heap(android::base::StringPrintf("%s.%d.exit.txt", g_debug->config().backtrace_dump_prefix().c_str(), getpid()) .c_str()); } DebugDisableSet(true); backtrace_shutdown(); delete g_debug; g_debug = nullptr; DebugDisableFinalize(); } void debug_get_malloc_leak_info(uint8_t** info, size_t* overall_size, size_t* info_size, size_t* total_memory, size_t* backtrace_size) { ScopedDisableDebugCalls disable; // Verify the arguments. if (info == nullptr || overall_size == nullptr || info_size == NULL || total_memory == nullptr || backtrace_size == nullptr) { error_log("get_malloc_leak_info: At least one invalid parameter."); return; } *info = nullptr; *overall_size = 0; *info_size = 0; *total_memory = 0; *backtrace_size = 0; if (!(g_debug->config().options() & BACKTRACE)) { error_log( "get_malloc_leak_info: Allocations not being tracked, to enable " "set the option 'backtrace'."); return; } PointerData::GetInfo(info, overall_size, info_size, total_memory, backtrace_size); } void debug_free_malloc_leak_info(uint8_t* info) { g_dispatch->free(info); } size_t debug_malloc_usable_size(void* pointer) { if (DebugCallsDisabled() || pointer == nullptr) { return g_dispatch->malloc_usable_size(pointer); } ScopedDisableDebugCalls disable; if (!VerifyPointer(pointer, "malloc_usable_size")) { return 0; } return InternalMallocUsableSize(pointer); } static void* InternalMalloc(size_t size) { if ((g_debug->config().options() & BACKTRACE) && g_debug->pointer->ShouldDumpAndReset()) { debug_dump_heap(android::base::StringPrintf( "%s.%d.txt", g_debug->config().backtrace_dump_prefix().c_str(), getpid()) .c_str()); } if (size == 0) { size = 1; } size_t real_size = size + g_debug->extra_bytes(); if (real_size < size) { // Overflow. errno = ENOMEM; return nullptr; } if (size > PointerInfoType::MaxSize()) { errno = ENOMEM; return nullptr; } void* pointer; if (g_debug->HeaderEnabled()) { Header* header = reinterpret_cast(g_dispatch->memalign(MINIMUM_ALIGNMENT_BYTES, real_size)); if (header == nullptr) { return nullptr; } pointer = InitHeader(header, header, size); } else { pointer = g_dispatch->malloc(real_size); } if (pointer != nullptr) { if (g_debug->TrackPointers()) { PointerData::Add(pointer, size); } if (g_debug->config().options() & FILL_ON_ALLOC) { size_t bytes = InternalMallocUsableSize(pointer); size_t fill_bytes = g_debug->config().fill_on_alloc_bytes(); bytes = (bytes < fill_bytes) ? bytes : fill_bytes; memset(pointer, g_debug->config().fill_alloc_value(), bytes); } } return pointer; } void* debug_malloc(size_t size) { if (DebugCallsDisabled()) { return g_dispatch->malloc(size); } ScopedDisableDebugCalls disable; void* pointer = InternalMalloc(size); if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new MallocEntry(pointer, size)); } return pointer; } static void InternalFree(void* pointer) { if ((g_debug->config().options() & BACKTRACE) && g_debug->pointer->ShouldDumpAndReset()) { debug_dump_heap(android::base::StringPrintf( "%s.%d.txt", g_debug->config().backtrace_dump_prefix().c_str(), getpid()) .c_str()); } void* free_pointer = pointer; size_t bytes; Header* header; if (g_debug->HeaderEnabled()) { header = g_debug->GetHeader(pointer); free_pointer = header->orig_pointer; if (g_debug->config().options() & FRONT_GUARD) { if (!g_debug->front_guard->Valid(header)) { g_debug->front_guard->LogFailure(header); } } if (g_debug->config().options() & REAR_GUARD) { if (!g_debug->rear_guard->Valid(header)) { g_debug->rear_guard->LogFailure(header); } } header->tag = DEBUG_FREE_TAG; bytes = header->usable_size; } else { bytes = g_dispatch->malloc_usable_size(pointer); } if (g_debug->config().options() & FILL_ON_FREE) { size_t fill_bytes = g_debug->config().fill_on_free_bytes(); bytes = (bytes < fill_bytes) ? bytes : fill_bytes; memset(pointer, g_debug->config().fill_free_value(), bytes); } if (g_debug->TrackPointers()) { PointerData::Remove(pointer); } if (g_debug->config().options() & FREE_TRACK) { // Do not add the allocation until we are done modifying the pointer // itself. This avoids a race if a lot of threads are all doing // frees at the same time and we wind up trying to really free this // pointer from another thread, while still trying to free it in // this function. pointer = PointerData::AddFreed(pointer); if (pointer != nullptr) { if (g_debug->HeaderEnabled()) { pointer = g_debug->GetHeader(pointer)->orig_pointer; } g_dispatch->free(pointer); } } else { g_dispatch->free(free_pointer); } } void debug_free(void* pointer) { if (DebugCallsDisabled() || pointer == nullptr) { return g_dispatch->free(pointer); } ScopedDisableDebugCalls disable; if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new FreeEntry(pointer)); } if (!VerifyPointer(pointer, "free")) { return; } InternalFree(pointer); } void* debug_memalign(size_t alignment, size_t bytes) { if (DebugCallsDisabled()) { return g_dispatch->memalign(alignment, bytes); } ScopedDisableDebugCalls disable; if (bytes == 0) { bytes = 1; } if (bytes > PointerInfoType::MaxSize()) { errno = ENOMEM; return nullptr; } void* pointer; if (g_debug->HeaderEnabled()) { // Make the alignment a power of two. if (!powerof2(alignment)) { alignment = BIONIC_ROUND_UP_POWER_OF_2(alignment); } // Force the alignment to at least MINIMUM_ALIGNMENT_BYTES to guarantee // that the header is aligned properly. if (alignment < MINIMUM_ALIGNMENT_BYTES) { alignment = MINIMUM_ALIGNMENT_BYTES; } // We don't have any idea what the natural alignment of // the underlying native allocator is, so we always need to // over allocate. size_t real_size = alignment + bytes + g_debug->extra_bytes(); if (real_size < bytes) { // Overflow. errno = ENOMEM; return nullptr; } pointer = g_dispatch->malloc(real_size); if (pointer == nullptr) { return nullptr; } uintptr_t value = reinterpret_cast(pointer) + g_debug->pointer_offset(); // Now align the pointer. value += (-value % alignment); Header* header = g_debug->GetHeader(reinterpret_cast(value)); pointer = InitHeader(header, pointer, bytes); } else { size_t real_size = bytes + g_debug->extra_bytes(); if (real_size < bytes) { // Overflow. errno = ENOMEM; return nullptr; } pointer = g_dispatch->memalign(alignment, real_size); } if (pointer != nullptr) { if (g_debug->TrackPointers()) { PointerData::Add(pointer, bytes); } if (g_debug->config().options() & FILL_ON_ALLOC) { size_t bytes = InternalMallocUsableSize(pointer); size_t fill_bytes = g_debug->config().fill_on_alloc_bytes(); bytes = (bytes < fill_bytes) ? bytes : fill_bytes; memset(pointer, g_debug->config().fill_alloc_value(), bytes); } if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new MemalignEntry(pointer, bytes, alignment)); } } return pointer; } void* debug_realloc(void* pointer, size_t bytes) { if (DebugCallsDisabled()) { return g_dispatch->realloc(pointer, bytes); } ScopedDisableDebugCalls disable; if (pointer == nullptr) { pointer = InternalMalloc(bytes); if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new ReallocEntry(pointer, bytes, nullptr)); } return pointer; } if (!VerifyPointer(pointer, "realloc")) { return nullptr; } if (bytes == 0) { if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new ReallocEntry(nullptr, bytes, pointer)); } InternalFree(pointer); return nullptr; } size_t real_size = bytes; if (g_debug->config().options() & EXPAND_ALLOC) { real_size += g_debug->config().expand_alloc_bytes(); if (real_size < bytes) { // Overflow. errno = ENOMEM; return nullptr; } } if (bytes > PointerInfoType::MaxSize()) { errno = ENOMEM; return nullptr; } void* new_pointer; size_t prev_size; if (g_debug->HeaderEnabled()) { // Same size, do nothing. Header* header = g_debug->GetHeader(pointer); if (real_size == header->size) { if (g_debug->TrackPointers()) { // Remove and re-add so that the backtrace is updated. PointerData::Remove(pointer); PointerData::Add(pointer, real_size); } return pointer; } // Allocation is shrinking. if (real_size < header->usable_size) { header->size = real_size; if (g_debug->config().options() & REAR_GUARD) { // Don't bother allocating a smaller pointer in this case, simply // change the header usable_size and reset the rear guard. header->usable_size = header->size; memset(g_debug->GetRearGuard(header), g_debug->config().rear_guard_value(), g_debug->config().rear_guard_bytes()); } if (g_debug->TrackPointers()) { // Remove and re-add so that the backtrace is updated. PointerData::Remove(pointer); PointerData::Add(pointer, real_size); } return pointer; } // Allocate the new size. new_pointer = InternalMalloc(bytes); if (new_pointer == nullptr) { errno = ENOMEM; return nullptr; } prev_size = header->usable_size; memcpy(new_pointer, pointer, prev_size); InternalFree(pointer); } else { if (g_debug->TrackPointers()) { PointerData::Remove(pointer); } prev_size = g_dispatch->malloc_usable_size(pointer); new_pointer = g_dispatch->realloc(pointer, real_size); if (new_pointer == nullptr) { return nullptr; } if (g_debug->TrackPointers()) { PointerData::Add(new_pointer, real_size); } } if (g_debug->config().options() & FILL_ON_ALLOC) { size_t bytes = InternalMallocUsableSize(new_pointer); if (bytes > g_debug->config().fill_on_alloc_bytes()) { bytes = g_debug->config().fill_on_alloc_bytes(); } if (bytes > prev_size) { memset(reinterpret_cast(reinterpret_cast(new_pointer) + prev_size), g_debug->config().fill_alloc_value(), bytes - prev_size); } } if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new ReallocEntry(new_pointer, bytes, pointer)); } return new_pointer; } void* debug_calloc(size_t nmemb, size_t bytes) { if (DebugCallsDisabled()) { return g_dispatch->calloc(nmemb, bytes); } ScopedDisableDebugCalls disable; size_t size; if (__builtin_mul_overflow(nmemb, bytes, &size)) { // Overflow errno = ENOMEM; return nullptr; } if (size == 0) { size = 1; } size_t real_size; if (__builtin_add_overflow(size, g_debug->extra_bytes(), &real_size)) { // Overflow. errno = ENOMEM; return nullptr; } if (real_size > PointerInfoType::MaxSize()) { errno = ENOMEM; return nullptr; } void* pointer; if (g_debug->HeaderEnabled()) { // Need to guarantee the alignment of the header. Header* header = reinterpret_cast(g_dispatch->memalign(MINIMUM_ALIGNMENT_BYTES, real_size)); if (header == nullptr) { return nullptr; } memset(header, 0, g_dispatch->malloc_usable_size(header)); pointer = InitHeader(header, header, size); } else { pointer = g_dispatch->calloc(1, real_size); } if (g_debug->config().options() & RECORD_ALLOCS) { g_debug->record->AddEntry(new CallocEntry(pointer, bytes, nmemb)); } if (pointer != nullptr && g_debug->TrackPointers()) { PointerData::Add(pointer, size); } return pointer; } struct mallinfo debug_mallinfo() { return g_dispatch->mallinfo(); } int debug_mallopt(int param, int value) { return g_dispatch->mallopt(param, value); } void* debug_aligned_alloc(size_t alignment, size_t size) { if (DebugCallsDisabled()) { return g_dispatch->aligned_alloc(alignment, size); } if (!powerof2(alignment)) { errno = EINVAL; return nullptr; } return debug_memalign(alignment, size); } int debug_posix_memalign(void** memptr, size_t alignment, size_t size) { if (DebugCallsDisabled()) { return g_dispatch->posix_memalign(memptr, alignment, size); } if (!powerof2(alignment)) { return EINVAL; } int saved_errno = errno; *memptr = debug_memalign(alignment, size); errno = saved_errno; return (*memptr != nullptr) ? 0 : ENOMEM; } int debug_iterate(uintptr_t base, size_t size, void (*callback)(uintptr_t, size_t, void*), void* arg) { if (g_debug->TrackPointers()) { // Since malloc is disabled, don't bother acquiring any locks. for (auto it = PointerData::begin(); it != PointerData::end(); ++it) { callback(it->first, InternalMallocUsableSize(reinterpret_cast(it->first)), arg); } return 0; } // An option that adds a header will add pointer tracking, so no need to // check if headers are enabled. return g_dispatch->iterate(base, size, callback, arg); } void debug_malloc_disable() { g_dispatch->malloc_disable(); if (g_debug->pointer) { g_debug->pointer->PrepareFork(); } } void debug_malloc_enable() { if (g_debug->pointer) { g_debug->pointer->PostForkParent(); } g_dispatch->malloc_enable(); } ssize_t debug_malloc_backtrace(void* pointer, uintptr_t* frames, size_t max_frames) { if (DebugCallsDisabled() || pointer == nullptr) { return 0; } ScopedDisableDebugCalls disable; if (!(g_debug->config().options() & BACKTRACE)) { return 0; } return PointerData::GetFrames(pointer, frames, max_frames); } #if defined(HAVE_DEPRECATED_MALLOC_FUNCS) void* debug_pvalloc(size_t bytes) { if (DebugCallsDisabled()) { return g_dispatch->pvalloc(bytes); } size_t pagesize = getpagesize(); size_t size = __BIONIC_ALIGN(bytes, pagesize); if (size < bytes) { // Overflow errno = ENOMEM; return nullptr; } return debug_memalign(pagesize, size); } void* debug_valloc(size_t size) { if (DebugCallsDisabled()) { return g_dispatch->valloc(size); } return debug_memalign(getpagesize(), size); } #endif static std::mutex g_dump_lock; static void write_dump(FILE* fp) { fprintf(fp, "Android Native Heap Dump v1.2\n\n"); std::string fingerprint = android::base::GetProperty("ro.build.fingerprint", "unknown"); fprintf(fp, "Build fingerprint: '%s'\n\n", fingerprint.c_str()); PointerData::DumpLiveToFile(fp); fprintf(fp, "MAPS\n"); std::string content; if (!android::base::ReadFileToString("/proc/self/maps", &content)) { fprintf(fp, "Could not open /proc/self/maps\n"); } else { fprintf(fp, "%s", content.c_str()); } fprintf(fp, "END\n"); } bool debug_write_malloc_leak_info(FILE* fp) { ScopedDisableDebugCalls disable; std::lock_guard guard(g_dump_lock); if (!(g_debug->config().options() & BACKTRACE)) { return false; } write_dump(fp); return true; } void debug_dump_heap(const char* file_name) { ScopedDisableDebugCalls disable; std::lock_guard guard(g_dump_lock); FILE* fp = fopen(file_name, "w+e"); if (fp == nullptr) { error_log("Unable to create file: %s", file_name); return; } error_log("Dumping to file: %s\n", file_name); write_dump(fp); fclose(fp); }