/* * Copyright (C) 2008 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 #include #include #include #include #include #include "dlmalloc.h" #include "logd.h" #include "malloc_debug_common.h" // This file should be included into the build only when // MALLOC_LEAK_CHECK, or MALLOC_QEMU_INSTRUMENT, or both // macros are defined. #ifndef MALLOC_LEAK_CHECK #error MALLOC_LEAK_CHECK is not defined. #endif // !MALLOC_LEAK_CHECK // Global variables defined in malloc_debug_common.c extern int gMallocLeakZygoteChild; extern pthread_mutex_t gAllocationsMutex; extern HashTable gHashTable; extern const MallocDebug __libc_malloc_default_dispatch; extern const MallocDebug* __libc_malloc_dispatch; // ============================================================================= // log functions // ============================================================================= #define debug_log(format, ...) \ __libc_android_log_print(ANDROID_LOG_DEBUG, "malloc_leak_check", (format), ##__VA_ARGS__ ) #define error_log(format, ...) \ __libc_android_log_print(ANDROID_LOG_ERROR, "malloc_leak_check", (format), ##__VA_ARGS__ ) #define info_log(format, ...) \ __libc_android_log_print(ANDROID_LOG_INFO, "malloc_leak_check", (format), ##__VA_ARGS__ ) static int gTrapOnError = 1; #define MALLOC_ALIGNMENT 8 #define GUARD 0x48151642 #define DEBUG 0 // ============================================================================= // Structures // ============================================================================= typedef struct AllocationEntry AllocationEntry; struct AllocationEntry { HashEntry* entry; uint32_t guard; }; // ============================================================================= // Hash Table functions // ============================================================================= static uint32_t get_hash(intptr_t* backtrace, size_t numEntries) { if (backtrace == NULL) return 0; int hash = 0; size_t i; for (i = 0 ; i < numEntries ; i++) { hash = (hash * 33) + (backtrace[i] >> 2); } return hash; } static HashEntry* find_entry(HashTable* table, int slot, intptr_t* backtrace, size_t numEntries, size_t size) { HashEntry* entry = table->slots[slot]; while (entry != NULL) { //debug_log("backtrace: %p, entry: %p entry->backtrace: %p\n", // backtrace, entry, (entry != NULL) ? entry->backtrace : NULL); /* * See if the entry matches exactly. We compare the "size" field, * including the flag bits. */ if (entry->size == size && entry->numEntries == numEntries && !memcmp(backtrace, entry->backtrace, numEntries * sizeof(intptr_t))) { return entry; } entry = entry->next; } return NULL; } static HashEntry* record_backtrace(intptr_t* backtrace, size_t numEntries, size_t size) { size_t hash = get_hash(backtrace, numEntries); size_t slot = hash % HASHTABLE_SIZE; if (size & SIZE_FLAG_MASK) { debug_log("malloc_debug: allocation %zx exceeds bit width\n", size); abort(); } if (gMallocLeakZygoteChild) size |= SIZE_FLAG_ZYGOTE_CHILD; HashEntry* entry = find_entry(&gHashTable, slot, backtrace, numEntries, size); if (entry != NULL) { entry->allocations++; } else { // create a new entry entry = (HashEntry*)dlmalloc(sizeof(HashEntry) + numEntries*sizeof(intptr_t)); if (!entry) return NULL; entry->allocations = 1; entry->slot = slot; entry->prev = NULL; entry->next = gHashTable.slots[slot]; entry->numEntries = numEntries; entry->size = size; memcpy(entry->backtrace, backtrace, numEntries * sizeof(intptr_t)); gHashTable.slots[slot] = entry; if (entry->next != NULL) { entry->next->prev = entry; } // we just added an entry, increase the size of the hashtable gHashTable.count++; } return entry; } static int is_valid_entry(HashEntry* entry) { if (entry != NULL) { int i; for (i = 0 ; i < HASHTABLE_SIZE ; i++) { HashEntry* e1 = gHashTable.slots[i]; while (e1 != NULL) { if (e1 == entry) { return 1; } e1 = e1->next; } } } return 0; } static void remove_entry(HashEntry* entry) { HashEntry* prev = entry->prev; HashEntry* next = entry->next; if (prev != NULL) entry->prev->next = next; if (next != NULL) entry->next->prev = prev; if (prev == NULL) { // we are the head of the list. set the head to be next gHashTable.slots[entry->slot] = entry->next; } // we just removed and entry, decrease the size of the hashtable gHashTable.count--; } // ============================================================================= // stack trace functions // ============================================================================= typedef struct { size_t count; intptr_t* addrs; } stack_crawl_state_t; /* depends how the system includes define this */ #ifdef HAVE_UNWIND_CONTEXT_STRUCT typedef struct _Unwind_Context __unwind_context; #else typedef _Unwind_Context __unwind_context; #endif static _Unwind_Reason_Code trace_function(__unwind_context *context, void *arg) { stack_crawl_state_t* state = (stack_crawl_state_t*)arg; if (state->count) { intptr_t ip = (intptr_t)_Unwind_GetIP(context); if (ip) { state->addrs[0] = ip; state->addrs++; state->count--; return _URC_NO_REASON; } } /* * If we run out of space to record the address or 0 has been seen, stop * unwinding the stack. */ return _URC_END_OF_STACK; } static inline int get_backtrace(intptr_t* addrs, size_t max_entries) { stack_crawl_state_t state; state.count = max_entries; state.addrs = (intptr_t*)addrs; _Unwind_Backtrace(trace_function, (void*)&state); return max_entries - state.count; } // ============================================================================= // malloc check functions // ============================================================================= #define CHK_FILL_FREE 0xef #define CHK_SENTINEL_VALUE 0xeb #define CHK_SENTINEL_HEAD_SIZE 16 #define CHK_SENTINEL_TAIL_SIZE 16 #define CHK_OVERHEAD_SIZE ( CHK_SENTINEL_HEAD_SIZE + \ CHK_SENTINEL_TAIL_SIZE + \ sizeof(size_t) ) static void dump_stack_trace() { intptr_t addrs[20]; int c = get_backtrace(addrs, 20); char buf[16]; char tmp[16*20]; int i; tmp[0] = 0; // Need to initialize tmp[0] for the first strcat for (i=0 ; i=0 ; i--) { if (buf[i] != CHK_SENTINEL_VALUE) { assert_log_message( "*** %s CHECK: buffer %p, size=%lu, " "corrupted %d bytes after allocation", func, buffer, bytes, i+1); return -1; } } *allocated = bytes; return 0; } void* chk_malloc(size_t bytes) { char* buffer = (char*)dlmalloc(bytes + CHK_OVERHEAD_SIZE); if (buffer) { memset(buffer, CHK_SENTINEL_VALUE, bytes + CHK_OVERHEAD_SIZE); size_t offset = dlmalloc_usable_size(buffer) - sizeof(size_t); *(size_t *)(buffer + offset) = bytes; buffer += CHK_SENTINEL_HEAD_SIZE; } return buffer; } void chk_free(void* mem) { assert_valid_malloc_pointer(mem); if (mem) { size_t size; char* buffer; if (chk_mem_check(mem, &size, "FREE") == 0) { buffer = (char*)mem - CHK_SENTINEL_HEAD_SIZE; memset(buffer, CHK_FILL_FREE, size + CHK_OVERHEAD_SIZE); dlfree(buffer); } } } void* chk_calloc(size_t n_elements, size_t elem_size) { size_t size; void* ptr; /* Fail on overflow - just to be safe even though this code runs only * within the debugging C library, not the production one */ if (n_elements && MAX_SIZE_T / n_elements < elem_size) { return NULL; } size = n_elements * elem_size; ptr = chk_malloc(size); if (ptr != NULL) { memset(ptr, 0, size); } return ptr; } void* chk_realloc(void* mem, size_t bytes) { char* buffer; int ret; size_t old_bytes = 0; assert_valid_malloc_pointer(mem); if (mem != NULL && chk_mem_check(mem, &old_bytes, "REALLOC") < 0) return NULL; char* new_buffer = chk_malloc(bytes); if (mem == NULL) { return new_buffer; } if (new_buffer) { if (bytes > old_bytes) bytes = old_bytes; memcpy(new_buffer, mem, bytes); chk_free(mem); } return new_buffer; } void* chk_memalign(size_t alignment, size_t bytes) { // XXX: it's better to use malloc, than being wrong return chk_malloc(bytes); } // ============================================================================= // malloc fill functions // ============================================================================= void* fill_malloc(size_t bytes) { void* buffer = dlmalloc(bytes); if (buffer) { memset(buffer, CHK_SENTINEL_VALUE, bytes); } return buffer; } void fill_free(void* mem) { size_t bytes = dlmalloc_usable_size(mem); memset(mem, CHK_FILL_FREE, bytes); dlfree(mem); } void* fill_realloc(void* mem, size_t bytes) { void* buffer = fill_malloc(bytes); if (mem == NULL) { return buffer; } if (buffer) { size_t old_size = dlmalloc_usable_size(mem); size_t size = (bytes < old_size)?(bytes):(old_size); memcpy(buffer, mem, size); fill_free(mem); } return buffer; } void* fill_memalign(size_t alignment, size_t bytes) { void* buffer = dlmemalign(alignment, bytes); if (buffer) { memset(buffer, CHK_SENTINEL_VALUE, bytes); } return buffer; } // ============================================================================= // malloc leak functions // ============================================================================= #define MEMALIGN_GUARD ((void*)0xA1A41520) void* leak_malloc(size_t bytes) { // allocate enough space infront of the allocation to store the pointer for // the alloc structure. This will making free'ing the structer really fast! // 1. allocate enough memory and include our header // 2. set the base pointer to be right after our header void* base = dlmalloc(bytes + sizeof(AllocationEntry)); if (base != NULL) { pthread_mutex_lock(&gAllocationsMutex); intptr_t backtrace[BACKTRACE_SIZE]; size_t numEntries = get_backtrace(backtrace, BACKTRACE_SIZE); AllocationEntry* header = (AllocationEntry*)base; header->entry = record_backtrace(backtrace, numEntries, bytes); header->guard = GUARD; // now increment base to point to after our header. // this should just work since our header is 8 bytes. base = (AllocationEntry*)base + 1; pthread_mutex_unlock(&gAllocationsMutex); } return base; } void leak_free(void* mem) { if (mem != NULL) { pthread_mutex_lock(&gAllocationsMutex); // check the guard to make sure it is valid AllocationEntry* header = (AllocationEntry*)mem - 1; if (header->guard != GUARD) { // could be a memaligned block if (((void**)mem)[-1] == MEMALIGN_GUARD) { mem = ((void**)mem)[-2]; header = (AllocationEntry*)mem - 1; } } if (header->guard == GUARD || is_valid_entry(header->entry)) { // decrement the allocations HashEntry* entry = header->entry; entry->allocations--; if (entry->allocations <= 0) { remove_entry(entry); dlfree(entry); } // now free the memory! dlfree(header); } else { debug_log("WARNING bad header guard: '0x%x'! and invalid entry: %p\n", header->guard, header->entry); } pthread_mutex_unlock(&gAllocationsMutex); } } void* leak_calloc(size_t n_elements, size_t elem_size) { size_t size; void* ptr; /* Fail on overflow - just to be safe even though this code runs only * within the debugging C library, not the production one */ if (n_elements && MAX_SIZE_T / n_elements < elem_size) { return NULL; } size = n_elements * elem_size; ptr = leak_malloc(size); if (ptr != NULL) { memset(ptr, 0, size); } return ptr; } void* leak_realloc(void* oldMem, size_t bytes) { if (oldMem == NULL) { return leak_malloc(bytes); } void* newMem = NULL; AllocationEntry* header = (AllocationEntry*)oldMem - 1; if (header && header->guard == GUARD) { size_t oldSize = header->entry->size & ~SIZE_FLAG_MASK; newMem = leak_malloc(bytes); if (newMem != NULL) { size_t copySize = (oldSize <= bytes) ? oldSize : bytes; memcpy(newMem, oldMem, copySize); leak_free(oldMem); } } else { newMem = dlrealloc(oldMem, bytes); } return newMem; } void* leak_memalign(size_t alignment, size_t bytes) { // we can just use malloc if (alignment <= MALLOC_ALIGNMENT) return leak_malloc(bytes); // need to make sure it's a power of two if (alignment & (alignment-1)) alignment = 1L << (31 - __builtin_clz(alignment)); // here, aligment is at least MALLOC_ALIGNMENT<<1 bytes // we will align by at least MALLOC_ALIGNMENT bytes // and at most alignment-MALLOC_ALIGNMENT bytes size_t size = (alignment-MALLOC_ALIGNMENT) + bytes; void* base = leak_malloc(size); if (base != NULL) { intptr_t ptr = (intptr_t)base; if ((ptr % alignment) == 0) return base; // align the pointer ptr += ((-ptr) % alignment); // there is always enough space for the base pointer and the guard ((void**)ptr)[-1] = MEMALIGN_GUARD; ((void**)ptr)[-2] = base; return (void*)ptr; } return base; } /* Initializes malloc debugging framework. * See comments on MallocDebugInit in malloc_debug_common.h */ int malloc_debug_initialize(void) { // We don't really have anything that requires initialization here. return 0; }