//===-- memprof_allocator.cpp --------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file is a part of MemProfiler, a memory profiler. // // Implementation of MemProf's memory allocator, which uses the allocator // from sanitizer_common. // //===----------------------------------------------------------------------===// #include "memprof_allocator.h" #include "memprof_mapping.h" #include "memprof_stack.h" #include "memprof_thread.h" #include "sanitizer_common/sanitizer_allocator_checks.h" #include "sanitizer_common/sanitizer_allocator_interface.h" #include "sanitizer_common/sanitizer_allocator_report.h" #include "sanitizer_common/sanitizer_errno.h" #include "sanitizer_common/sanitizer_file.h" #include "sanitizer_common/sanitizer_flags.h" #include "sanitizer_common/sanitizer_internal_defs.h" #include "sanitizer_common/sanitizer_list.h" #include "sanitizer_common/sanitizer_stackdepot.h" #include #include #include namespace __memprof { static int GetCpuId(void) { // _memprof_preinit is called via the preinit_array, which subsequently calls // malloc. Since this is before _dl_init calls VDSO_SETUP, sched_getcpu // will seg fault as the address of __vdso_getcpu will be null. if (!memprof_init_done) return -1; return sched_getcpu(); } // Compute the timestamp in ms. static int GetTimestamp(void) { // timespec_get will segfault if called from dl_init if (!memprof_timestamp_inited) { // By returning 0, this will be effectively treated as being // timestamped at memprof init time (when memprof_init_timestamp_s // is initialized). return 0; } timespec ts; timespec_get(&ts, TIME_UTC); return (ts.tv_sec - memprof_init_timestamp_s) * 1000 + ts.tv_nsec / 1000000; } static MemprofAllocator &get_allocator(); // The memory chunk allocated from the underlying allocator looks like this: // H H U U U U U U // H -- ChunkHeader (32 bytes) // U -- user memory. // If there is left padding before the ChunkHeader (due to use of memalign), // we store a magic value in the first uptr word of the memory block and // store the address of ChunkHeader in the next uptr. // M B L L L L L L L L L H H U U U U U U // | ^ // ---------------------| // M -- magic value kAllocBegMagic // B -- address of ChunkHeader pointing to the first 'H' constexpr uptr kMaxAllowedMallocBits = 40; // Should be no more than 32-bytes struct ChunkHeader { // 1-st 4 bytes. u32 alloc_context_id; // 2-nd 4 bytes u32 cpu_id; // 3-rd 4 bytes u32 timestamp_ms; // 4-th 4 bytes // Note only 1 bit is needed for this flag if we need space in the future for // more fields. u32 from_memalign; // 5-th and 6-th 4 bytes // The max size of an allocation is 2^40 (kMaxAllowedMallocSize), so this // could be shrunk to kMaxAllowedMallocBits if we need space in the future for // more fields. atomic_uint64_t user_requested_size; // 23 bits available // 7-th and 8-th 4 bytes u64 data_type_id; // TODO: hash of type name }; static const uptr kChunkHeaderSize = sizeof(ChunkHeader); COMPILER_CHECK(kChunkHeaderSize == 32); struct MemprofChunk : ChunkHeader { uptr Beg() { return reinterpret_cast(this) + kChunkHeaderSize; } uptr UsedSize() { return atomic_load(&user_requested_size, memory_order_relaxed); } void *AllocBeg() { if (from_memalign) return get_allocator().GetBlockBegin(reinterpret_cast(this)); return reinterpret_cast(this); } }; class LargeChunkHeader { static constexpr uptr kAllocBegMagic = FIRST_32_SECOND_64(0xCC6E96B9, 0xCC6E96B9CC6E96B9ULL); atomic_uintptr_t magic; MemprofChunk *chunk_header; public: MemprofChunk *Get() const { return atomic_load(&magic, memory_order_acquire) == kAllocBegMagic ? chunk_header : nullptr; } void Set(MemprofChunk *p) { if (p) { chunk_header = p; atomic_store(&magic, kAllocBegMagic, memory_order_release); return; } uptr old = kAllocBegMagic; if (!atomic_compare_exchange_strong(&magic, &old, 0, memory_order_release)) { CHECK_EQ(old, kAllocBegMagic); } } }; void FlushUnneededMemProfShadowMemory(uptr p, uptr size) { // Since memprof's mapping is compacting, the shadow chunk may be // not page-aligned, so we only flush the page-aligned portion. ReleaseMemoryPagesToOS(MemToShadow(p), MemToShadow(p + size)); } void MemprofMapUnmapCallback::OnMap(uptr p, uptr size) const { // Statistics. MemprofStats &thread_stats = GetCurrentThreadStats(); thread_stats.mmaps++; thread_stats.mmaped += size; } void MemprofMapUnmapCallback::OnUnmap(uptr p, uptr size) const { // We are about to unmap a chunk of user memory. // Mark the corresponding shadow memory as not needed. FlushUnneededMemProfShadowMemory(p, size); // Statistics. MemprofStats &thread_stats = GetCurrentThreadStats(); thread_stats.munmaps++; thread_stats.munmaped += size; } AllocatorCache *GetAllocatorCache(MemprofThreadLocalMallocStorage *ms) { CHECK(ms); return &ms->allocator_cache; } struct MemInfoBlock { u32 alloc_count; u64 total_access_count, min_access_count, max_access_count; u64 total_size; u32 min_size, max_size; u32 alloc_timestamp, dealloc_timestamp; u64 total_lifetime; u32 min_lifetime, max_lifetime; u32 alloc_cpu_id, dealloc_cpu_id; u32 num_migrated_cpu; // Only compared to prior deallocated object currently. u32 num_lifetime_overlaps; u32 num_same_alloc_cpu; u32 num_same_dealloc_cpu; u64 data_type_id; // TODO: hash of type name MemInfoBlock() : alloc_count(0) {} MemInfoBlock(u32 size, u64 access_count, u32 alloc_timestamp, u32 dealloc_timestamp, u32 alloc_cpu, u32 dealloc_cpu) : alloc_count(1), total_access_count(access_count), min_access_count(access_count), max_access_count(access_count), total_size(size), min_size(size), max_size(size), alloc_timestamp(alloc_timestamp), dealloc_timestamp(dealloc_timestamp), total_lifetime(dealloc_timestamp - alloc_timestamp), min_lifetime(total_lifetime), max_lifetime(total_lifetime), alloc_cpu_id(alloc_cpu), dealloc_cpu_id(dealloc_cpu), num_lifetime_overlaps(0), num_same_alloc_cpu(0), num_same_dealloc_cpu(0) { num_migrated_cpu = alloc_cpu_id != dealloc_cpu_id; } void Print(u64 id) { u64 p; if (flags()->print_terse) { p = total_size * 100 / alloc_count; Printf("MIB:%llu/%u/%d.%02d/%u/%u/", id, alloc_count, p / 100, p % 100, min_size, max_size); p = total_access_count * 100 / alloc_count; Printf("%d.%02d/%u/%u/", p / 100, p % 100, min_access_count, max_access_count); p = total_lifetime * 100 / alloc_count; Printf("%d.%02d/%u/%u/", p / 100, p % 100, min_lifetime, max_lifetime); Printf("%u/%u/%u/%u\n", num_migrated_cpu, num_lifetime_overlaps, num_same_alloc_cpu, num_same_dealloc_cpu); } else { p = total_size * 100 / alloc_count; Printf("Memory allocation stack id = %llu\n", id); Printf("\talloc_count %u, size (ave/min/max) %d.%02d / %u / %u\n", alloc_count, p / 100, p % 100, min_size, max_size); p = total_access_count * 100 / alloc_count; Printf("\taccess_count (ave/min/max): %d.%02d / %u / %u\n", p / 100, p % 100, min_access_count, max_access_count); p = total_lifetime * 100 / alloc_count; Printf("\tlifetime (ave/min/max): %d.%02d / %u / %u\n", p / 100, p % 100, min_lifetime, max_lifetime); Printf("\tnum migrated: %u, num lifetime overlaps: %u, num same alloc " "cpu: %u, num same dealloc_cpu: %u\n", num_migrated_cpu, num_lifetime_overlaps, num_same_alloc_cpu, num_same_dealloc_cpu); } } static void printHeader() { CHECK(flags()->print_terse); Printf("MIB:StackID/AllocCount/AveSize/MinSize/MaxSize/AveAccessCount/" "MinAccessCount/MaxAccessCount/AveLifetime/MinLifetime/MaxLifetime/" "NumMigratedCpu/NumLifetimeOverlaps/NumSameAllocCpu/" "NumSameDeallocCpu\n"); } void Merge(MemInfoBlock &newMIB) { alloc_count += newMIB.alloc_count; total_access_count += newMIB.total_access_count; min_access_count = Min(min_access_count, newMIB.min_access_count); max_access_count = Max(max_access_count, newMIB.max_access_count); total_size += newMIB.total_size; min_size = Min(min_size, newMIB.min_size); max_size = Max(max_size, newMIB.max_size); total_lifetime += newMIB.total_lifetime; min_lifetime = Min(min_lifetime, newMIB.min_lifetime); max_lifetime = Max(max_lifetime, newMIB.max_lifetime); // We know newMIB was deallocated later, so just need to check if it was // allocated before last one deallocated. num_lifetime_overlaps += newMIB.alloc_timestamp < dealloc_timestamp; alloc_timestamp = newMIB.alloc_timestamp; dealloc_timestamp = newMIB.dealloc_timestamp; num_same_alloc_cpu += alloc_cpu_id == newMIB.alloc_cpu_id; num_same_dealloc_cpu += dealloc_cpu_id == newMIB.dealloc_cpu_id; alloc_cpu_id = newMIB.alloc_cpu_id; dealloc_cpu_id = newMIB.dealloc_cpu_id; } }; static u32 AccessCount = 0; static u32 MissCount = 0; struct SetEntry { SetEntry() : id(0), MIB() {} bool Empty() { return id == 0; } void Print() { CHECK(!Empty()); MIB.Print(id); } // The stack id u64 id; MemInfoBlock MIB; }; struct CacheSet { enum { kSetSize = 4 }; void PrintAll() { for (int i = 0; i < kSetSize; i++) { if (Entries[i].Empty()) continue; Entries[i].Print(); } } void insertOrMerge(u64 new_id, MemInfoBlock &newMIB) { AccessCount++; SetAccessCount++; for (int i = 0; i < kSetSize; i++) { auto id = Entries[i].id; // Check if this is a hit or an empty entry. Since we always move any // filled locations to the front of the array (see below), we don't need // to look after finding the first empty entry. if (id == new_id || !id) { if (id == 0) { Entries[i].id = new_id; Entries[i].MIB = newMIB; } else { Entries[i].MIB.Merge(newMIB); } // Assuming some id locality, we try to swap the matching entry // into the first set position. if (i != 0) { auto tmp = Entries[0]; Entries[0] = Entries[i]; Entries[i] = tmp; } return; } } // Miss MissCount++; SetMissCount++; // We try to find the entries with the lowest alloc count to be evicted: int min_idx = 0; u64 min_count = Entries[0].MIB.alloc_count; for (int i = 1; i < kSetSize; i++) { CHECK(!Entries[i].Empty()); if (Entries[i].MIB.alloc_count < min_count) { min_idx = i; min_count = Entries[i].MIB.alloc_count; } } // Print the evicted entry profile information if (!flags()->print_terse) Printf("Evicted:\n"); Entries[min_idx].Print(); // Similar to the hit case, put new MIB in first set position. if (min_idx != 0) Entries[min_idx] = Entries[0]; Entries[0].id = new_id; Entries[0].MIB = newMIB; } void PrintMissRate(int i) { u64 p = SetAccessCount ? SetMissCount * 10000ULL / SetAccessCount : 0; Printf("Set %d miss rate: %d / %d = %5d.%02d%%\n", i, SetMissCount, SetAccessCount, p / 100, p % 100); } SetEntry Entries[kSetSize]; u32 SetAccessCount = 0; u32 SetMissCount = 0; }; struct MemInfoBlockCache { MemInfoBlockCache() { if (common_flags()->print_module_map) DumpProcessMap(); if (flags()->print_terse) MemInfoBlock::printHeader(); Sets = (CacheSet *)malloc(sizeof(CacheSet) * flags()->mem_info_cache_entries); Constructed = true; } ~MemInfoBlockCache() { free(Sets); } void insertOrMerge(u64 new_id, MemInfoBlock &newMIB) { u64 hv = new_id; // Use mod method where number of entries should be a prime close to power // of 2. hv %= flags()->mem_info_cache_entries; return Sets[hv].insertOrMerge(new_id, newMIB); } void PrintAll() { for (int i = 0; i < flags()->mem_info_cache_entries; i++) { Sets[i].PrintAll(); } } void PrintMissRate() { if (!flags()->print_mem_info_cache_miss_rate) return; u64 p = AccessCount ? MissCount * 10000ULL / AccessCount : 0; Printf("Overall miss rate: %d / %d = %5d.%02d%%\n", MissCount, AccessCount, p / 100, p % 100); if (flags()->print_mem_info_cache_miss_rate_details) for (int i = 0; i < flags()->mem_info_cache_entries; i++) Sets[i].PrintMissRate(i); } CacheSet *Sets; // Flag when the Sets have been allocated, in case a deallocation is called // very early before the static init of the Allocator and therefore this table // have completed. bool Constructed = false; }; // Accumulates the access count from the shadow for the given pointer and size. u64 GetShadowCount(uptr p, u32 size) { u64 *shadow = (u64 *)MEM_TO_SHADOW(p); u64 *shadow_end = (u64 *)MEM_TO_SHADOW(p + size); u64 count = 0; for (; shadow <= shadow_end; shadow++) count += *shadow; return count; } // Clears the shadow counters (when memory is allocated). void ClearShadow(uptr addr, uptr size) { CHECK(AddrIsAlignedByGranularity(addr)); CHECK(AddrIsInMem(addr)); CHECK(AddrIsAlignedByGranularity(addr + size)); CHECK(AddrIsInMem(addr + size - SHADOW_GRANULARITY)); CHECK(REAL(memset)); uptr shadow_beg = MEM_TO_SHADOW(addr); uptr shadow_end = MEM_TO_SHADOW(addr + size - SHADOW_GRANULARITY) + 1; if (shadow_end - shadow_beg < common_flags()->clear_shadow_mmap_threshold) { REAL(memset)((void *)shadow_beg, 0, shadow_end - shadow_beg); } else { uptr page_size = GetPageSizeCached(); uptr page_beg = RoundUpTo(shadow_beg, page_size); uptr page_end = RoundDownTo(shadow_end, page_size); if (page_beg >= page_end) { REAL(memset)((void *)shadow_beg, 0, shadow_end - shadow_beg); } else { if (page_beg != shadow_beg) { REAL(memset)((void *)shadow_beg, 0, page_beg - shadow_beg); } if (page_end != shadow_end) { REAL(memset)((void *)page_end, 0, shadow_end - page_end); } ReserveShadowMemoryRange(page_beg, page_end - 1, nullptr); } } } struct Allocator { static const uptr kMaxAllowedMallocSize = 1ULL << kMaxAllowedMallocBits; MemprofAllocator allocator; StaticSpinMutex fallback_mutex; AllocatorCache fallback_allocator_cache; uptr max_user_defined_malloc_size; atomic_uint8_t rss_limit_exceeded; MemInfoBlockCache MemInfoBlockTable; bool destructing; // ------------------- Initialization ------------------------ explicit Allocator(LinkerInitialized) : destructing(false) {} ~Allocator() { FinishAndPrint(); } void FinishAndPrint() { if (!flags()->print_terse) Printf("Live on exit:\n"); allocator.ForceLock(); allocator.ForEachChunk( [](uptr chunk, void *alloc) { u64 user_requested_size; MemprofChunk *m = ((Allocator *)alloc) ->GetMemprofChunk((void *)chunk, user_requested_size); if (!m) return; uptr user_beg = ((uptr)m) + kChunkHeaderSize; u64 c = GetShadowCount(user_beg, user_requested_size); long curtime = GetTimestamp(); MemInfoBlock newMIB(user_requested_size, c, m->timestamp_ms, curtime, m->cpu_id, GetCpuId()); ((Allocator *)alloc) ->MemInfoBlockTable.insertOrMerge(m->alloc_context_id, newMIB); }, this); allocator.ForceUnlock(); destructing = true; MemInfoBlockTable.PrintMissRate(); MemInfoBlockTable.PrintAll(); StackDepotPrintAll(); } void InitLinkerInitialized() { SetAllocatorMayReturnNull(common_flags()->allocator_may_return_null); allocator.InitLinkerInitialized( common_flags()->allocator_release_to_os_interval_ms); max_user_defined_malloc_size = common_flags()->max_allocation_size_mb ? common_flags()->max_allocation_size_mb << 20 : kMaxAllowedMallocSize; } bool RssLimitExceeded() { return atomic_load(&rss_limit_exceeded, memory_order_relaxed); } void SetRssLimitExceeded(bool limit_exceeded) { atomic_store(&rss_limit_exceeded, limit_exceeded, memory_order_relaxed); } // -------------------- Allocation/Deallocation routines --------------- void *Allocate(uptr size, uptr alignment, BufferedStackTrace *stack, AllocType alloc_type) { if (UNLIKELY(!memprof_inited)) MemprofInitFromRtl(); if (RssLimitExceeded()) { if (AllocatorMayReturnNull()) return nullptr; ReportRssLimitExceeded(stack); } CHECK(stack); const uptr min_alignment = MEMPROF_ALIGNMENT; if (alignment < min_alignment) alignment = min_alignment; if (size == 0) { // We'd be happy to avoid allocating memory for zero-size requests, but // some programs/tests depend on this behavior and assume that malloc // would not return NULL even for zero-size allocations. Moreover, it // looks like operator new should never return NULL, and results of // consecutive "new" calls must be different even if the allocated size // is zero. size = 1; } CHECK(IsPowerOfTwo(alignment)); uptr rounded_size = RoundUpTo(size, alignment); uptr needed_size = rounded_size + kChunkHeaderSize; if (alignment > min_alignment) needed_size += alignment; CHECK(IsAligned(needed_size, min_alignment)); if (size > kMaxAllowedMallocSize || needed_size > kMaxAllowedMallocSize || size > max_user_defined_malloc_size) { if (AllocatorMayReturnNull()) { Report("WARNING: MemProfiler failed to allocate 0x%zx bytes\n", (void *)size); return nullptr; } uptr malloc_limit = Min(kMaxAllowedMallocSize, max_user_defined_malloc_size); ReportAllocationSizeTooBig(size, malloc_limit, stack); } MemprofThread *t = GetCurrentThread(); void *allocated; if (t) { AllocatorCache *cache = GetAllocatorCache(&t->malloc_storage()); allocated = allocator.Allocate(cache, needed_size, 8); } else { SpinMutexLock l(&fallback_mutex); AllocatorCache *cache = &fallback_allocator_cache; allocated = allocator.Allocate(cache, needed_size, 8); } if (UNLIKELY(!allocated)) { SetAllocatorOutOfMemory(); if (AllocatorMayReturnNull()) return nullptr; ReportOutOfMemory(size, stack); } uptr alloc_beg = reinterpret_cast(allocated); uptr alloc_end = alloc_beg + needed_size; uptr beg_plus_header = alloc_beg + kChunkHeaderSize; uptr user_beg = beg_plus_header; if (!IsAligned(user_beg, alignment)) user_beg = RoundUpTo(user_beg, alignment); uptr user_end = user_beg + size; CHECK_LE(user_end, alloc_end); uptr chunk_beg = user_beg - kChunkHeaderSize; MemprofChunk *m = reinterpret_cast(chunk_beg); m->from_memalign = alloc_beg != chunk_beg; CHECK(size); m->cpu_id = GetCpuId(); m->timestamp_ms = GetTimestamp(); m->alloc_context_id = StackDepotPut(*stack); uptr size_rounded_down_to_granularity = RoundDownTo(size, SHADOW_GRANULARITY); if (size_rounded_down_to_granularity) ClearShadow(user_beg, size_rounded_down_to_granularity); MemprofStats &thread_stats = GetCurrentThreadStats(); thread_stats.mallocs++; thread_stats.malloced += size; thread_stats.malloced_overhead += needed_size - size; if (needed_size > SizeClassMap::kMaxSize) thread_stats.malloc_large++; else thread_stats.malloced_by_size[SizeClassMap::ClassID(needed_size)]++; void *res = reinterpret_cast(user_beg); atomic_store(&m->user_requested_size, size, memory_order_release); if (alloc_beg != chunk_beg) { CHECK_LE(alloc_beg + sizeof(LargeChunkHeader), chunk_beg); reinterpret_cast(alloc_beg)->Set(m); } MEMPROF_MALLOC_HOOK(res, size); return res; } void Deallocate(void *ptr, uptr delete_size, uptr delete_alignment, BufferedStackTrace *stack, AllocType alloc_type) { uptr p = reinterpret_cast(ptr); if (p == 0) return; MEMPROF_FREE_HOOK(ptr); uptr chunk_beg = p - kChunkHeaderSize; MemprofChunk *m = reinterpret_cast(chunk_beg); u64 user_requested_size = atomic_exchange(&m->user_requested_size, 0, memory_order_acquire); if (memprof_inited && memprof_init_done && !destructing && MemInfoBlockTable.Constructed) { u64 c = GetShadowCount(p, user_requested_size); long curtime = GetTimestamp(); MemInfoBlock newMIB(user_requested_size, c, m->timestamp_ms, curtime, m->cpu_id, GetCpuId()); { SpinMutexLock l(&fallback_mutex); MemInfoBlockTable.insertOrMerge(m->alloc_context_id, newMIB); } } MemprofStats &thread_stats = GetCurrentThreadStats(); thread_stats.frees++; thread_stats.freed += user_requested_size; void *alloc_beg = m->AllocBeg(); if (alloc_beg != m) { // Clear the magic value, as allocator internals may overwrite the // contents of deallocated chunk, confusing GetMemprofChunk lookup. reinterpret_cast(alloc_beg)->Set(nullptr); } MemprofThread *t = GetCurrentThread(); if (t) { AllocatorCache *cache = GetAllocatorCache(&t->malloc_storage()); allocator.Deallocate(cache, alloc_beg); } else { SpinMutexLock l(&fallback_mutex); AllocatorCache *cache = &fallback_allocator_cache; allocator.Deallocate(cache, alloc_beg); } } void *Reallocate(void *old_ptr, uptr new_size, BufferedStackTrace *stack) { CHECK(old_ptr && new_size); uptr p = reinterpret_cast(old_ptr); uptr chunk_beg = p - kChunkHeaderSize; MemprofChunk *m = reinterpret_cast(chunk_beg); MemprofStats &thread_stats = GetCurrentThreadStats(); thread_stats.reallocs++; thread_stats.realloced += new_size; void *new_ptr = Allocate(new_size, 8, stack, FROM_MALLOC); if (new_ptr) { CHECK_NE(REAL(memcpy), nullptr); uptr memcpy_size = Min(new_size, m->UsedSize()); REAL(memcpy)(new_ptr, old_ptr, memcpy_size); Deallocate(old_ptr, 0, 0, stack, FROM_MALLOC); } return new_ptr; } void *Calloc(uptr nmemb, uptr size, BufferedStackTrace *stack) { if (UNLIKELY(CheckForCallocOverflow(size, nmemb))) { if (AllocatorMayReturnNull()) return nullptr; ReportCallocOverflow(nmemb, size, stack); } void *ptr = Allocate(nmemb * size, 8, stack, FROM_MALLOC); // If the memory comes from the secondary allocator no need to clear it // as it comes directly from mmap. if (ptr && allocator.FromPrimary(ptr)) REAL(memset)(ptr, 0, nmemb * size); return ptr; } void CommitBack(MemprofThreadLocalMallocStorage *ms, BufferedStackTrace *stack) { AllocatorCache *ac = GetAllocatorCache(ms); allocator.SwallowCache(ac); } // -------------------------- Chunk lookup ---------------------- // Assumes alloc_beg == allocator.GetBlockBegin(alloc_beg). MemprofChunk *GetMemprofChunk(void *alloc_beg, u64 &user_requested_size) { if (!alloc_beg) return nullptr; MemprofChunk *p = reinterpret_cast(alloc_beg)->Get(); if (!p) { if (!allocator.FromPrimary(alloc_beg)) return nullptr; p = reinterpret_cast(alloc_beg); } // The size is reset to 0 on deallocation (and a min of 1 on // allocation). user_requested_size = atomic_load(&p->user_requested_size, memory_order_acquire); if (user_requested_size) return p; return nullptr; } MemprofChunk *GetMemprofChunkByAddr(uptr p, u64 &user_requested_size) { void *alloc_beg = allocator.GetBlockBegin(reinterpret_cast(p)); return GetMemprofChunk(alloc_beg, user_requested_size); } uptr AllocationSize(uptr p) { u64 user_requested_size; MemprofChunk *m = GetMemprofChunkByAddr(p, user_requested_size); if (!m) return 0; if (m->Beg() != p) return 0; return user_requested_size; } void Purge(BufferedStackTrace *stack) { allocator.ForceReleaseToOS(); } void PrintStats() { allocator.PrintStats(); } void ForceLock() { allocator.ForceLock(); fallback_mutex.Lock(); } void ForceUnlock() { fallback_mutex.Unlock(); allocator.ForceUnlock(); } }; static Allocator instance(LINKER_INITIALIZED); static MemprofAllocator &get_allocator() { return instance.allocator; } void InitializeAllocator() { instance.InitLinkerInitialized(); } void MemprofThreadLocalMallocStorage::CommitBack() { GET_STACK_TRACE_MALLOC; instance.CommitBack(this, &stack); } void PrintInternalAllocatorStats() { instance.PrintStats(); } void memprof_free(void *ptr, BufferedStackTrace *stack, AllocType alloc_type) { instance.Deallocate(ptr, 0, 0, stack, alloc_type); } void memprof_delete(void *ptr, uptr size, uptr alignment, BufferedStackTrace *stack, AllocType alloc_type) { instance.Deallocate(ptr, size, alignment, stack, alloc_type); } void *memprof_malloc(uptr size, BufferedStackTrace *stack) { return SetErrnoOnNull(instance.Allocate(size, 8, stack, FROM_MALLOC)); } void *memprof_calloc(uptr nmemb, uptr size, BufferedStackTrace *stack) { return SetErrnoOnNull(instance.Calloc(nmemb, size, stack)); } void *memprof_reallocarray(void *p, uptr nmemb, uptr size, BufferedStackTrace *stack) { if (UNLIKELY(CheckForCallocOverflow(size, nmemb))) { errno = errno_ENOMEM; if (AllocatorMayReturnNull()) return nullptr; ReportReallocArrayOverflow(nmemb, size, stack); } return memprof_realloc(p, nmemb * size, stack); } void *memprof_realloc(void *p, uptr size, BufferedStackTrace *stack) { if (!p) return SetErrnoOnNull(instance.Allocate(size, 8, stack, FROM_MALLOC)); if (size == 0) { if (flags()->allocator_frees_and_returns_null_on_realloc_zero) { instance.Deallocate(p, 0, 0, stack, FROM_MALLOC); return nullptr; } // Allocate a size of 1 if we shouldn't free() on Realloc to 0 size = 1; } return SetErrnoOnNull(instance.Reallocate(p, size, stack)); } void *memprof_valloc(uptr size, BufferedStackTrace *stack) { return SetErrnoOnNull( instance.Allocate(size, GetPageSizeCached(), stack, FROM_MALLOC)); } void *memprof_pvalloc(uptr size, BufferedStackTrace *stack) { uptr PageSize = GetPageSizeCached(); if (UNLIKELY(CheckForPvallocOverflow(size, PageSize))) { errno = errno_ENOMEM; if (AllocatorMayReturnNull()) return nullptr; ReportPvallocOverflow(size, stack); } // pvalloc(0) should allocate one page. size = size ? RoundUpTo(size, PageSize) : PageSize; return SetErrnoOnNull(instance.Allocate(size, PageSize, stack, FROM_MALLOC)); } void *memprof_memalign(uptr alignment, uptr size, BufferedStackTrace *stack, AllocType alloc_type) { if (UNLIKELY(!IsPowerOfTwo(alignment))) { errno = errno_EINVAL; if (AllocatorMayReturnNull()) return nullptr; ReportInvalidAllocationAlignment(alignment, stack); } return SetErrnoOnNull(instance.Allocate(size, alignment, stack, alloc_type)); } void *memprof_aligned_alloc(uptr alignment, uptr size, BufferedStackTrace *stack) { if (UNLIKELY(!CheckAlignedAllocAlignmentAndSize(alignment, size))) { errno = errno_EINVAL; if (AllocatorMayReturnNull()) return nullptr; ReportInvalidAlignedAllocAlignment(size, alignment, stack); } return SetErrnoOnNull(instance.Allocate(size, alignment, stack, FROM_MALLOC)); } int memprof_posix_memalign(void **memptr, uptr alignment, uptr size, BufferedStackTrace *stack) { if (UNLIKELY(!CheckPosixMemalignAlignment(alignment))) { if (AllocatorMayReturnNull()) return errno_EINVAL; ReportInvalidPosixMemalignAlignment(alignment, stack); } void *ptr = instance.Allocate(size, alignment, stack, FROM_MALLOC); if (UNLIKELY(!ptr)) // OOM error is already taken care of by Allocate. return errno_ENOMEM; CHECK(IsAligned((uptr)ptr, alignment)); *memptr = ptr; return 0; } uptr memprof_malloc_usable_size(const void *ptr, uptr pc, uptr bp) { if (!ptr) return 0; uptr usable_size = instance.AllocationSize(reinterpret_cast(ptr)); return usable_size; } void MemprofSoftRssLimitExceededCallback(bool limit_exceeded) { instance.SetRssLimitExceeded(limit_exceeded); } } // namespace __memprof // ---------------------- Interface ---------------- {{{1 using namespace __memprof; #if !SANITIZER_SUPPORTS_WEAK_HOOKS // Provide default (no-op) implementation of malloc hooks. SANITIZER_INTERFACE_WEAK_DEF(void, __sanitizer_malloc_hook, void *ptr, uptr size) { (void)ptr; (void)size; } SANITIZER_INTERFACE_WEAK_DEF(void, __sanitizer_free_hook, void *ptr) { (void)ptr; } #endif uptr __sanitizer_get_estimated_allocated_size(uptr size) { return size; } int __sanitizer_get_ownership(const void *p) { return memprof_malloc_usable_size(p, 0, 0) != 0; } uptr __sanitizer_get_allocated_size(const void *p) { return memprof_malloc_usable_size(p, 0, 0); }