// Copyright 2015 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/trace_event/malloc_dump_provider.h" #include #include #include "base/allocator/allocator_extension.h" #include "base/allocator/buildflags.h" #include "base/debug/profiler.h" #include "base/trace_event/process_memory_dump.h" #include "base/trace_event/trace_event_argument.h" #include "build/build_config.h" #if defined(OS_MACOSX) #include #else #include #endif #if defined(OS_WIN) #include #endif namespace base { namespace trace_event { namespace { #if defined(OS_WIN) // A structure containing some information about a given heap. struct WinHeapInfo { size_t committed_size; size_t uncommitted_size; size_t allocated_size; size_t block_count; }; // NOTE: crbug.com/665516 // Unfortunately, there is no safe way to collect information from secondary // heaps due to limitations and racy nature of this piece of WinAPI. void WinHeapMemoryDumpImpl(WinHeapInfo* crt_heap_info) { // Iterate through whichever heap our CRT is using. HANDLE crt_heap = reinterpret_cast(_get_heap_handle()); ::HeapLock(crt_heap); PROCESS_HEAP_ENTRY heap_entry; heap_entry.lpData = nullptr; // Walk over all the entries in the main heap. while (::HeapWalk(crt_heap, &heap_entry) != FALSE) { if ((heap_entry.wFlags & PROCESS_HEAP_ENTRY_BUSY) != 0) { crt_heap_info->allocated_size += heap_entry.cbData; crt_heap_info->block_count++; } else if ((heap_entry.wFlags & PROCESS_HEAP_REGION) != 0) { crt_heap_info->committed_size += heap_entry.Region.dwCommittedSize; crt_heap_info->uncommitted_size += heap_entry.Region.dwUnCommittedSize; } } CHECK(::HeapUnlock(crt_heap) == TRUE); } #endif // defined(OS_WIN) } // namespace // static const char MallocDumpProvider::kAllocatedObjects[] = "malloc/allocated_objects"; // static MallocDumpProvider* MallocDumpProvider::GetInstance() { return Singleton>::get(); } MallocDumpProvider::MallocDumpProvider() = default; MallocDumpProvider::~MallocDumpProvider() = default; // Called at trace dump point time. Creates a snapshot the memory counters for // the current process. bool MallocDumpProvider::OnMemoryDump(const MemoryDumpArgs& args, ProcessMemoryDump* pmd) { { base::AutoLock auto_lock(emit_metrics_on_memory_dump_lock_); if (!emit_metrics_on_memory_dump_) return true; } size_t total_virtual_size = 0; size_t resident_size = 0; size_t allocated_objects_size = 0; size_t allocated_objects_count = 0; #if defined(USE_TCMALLOC) bool res = allocator::GetNumericProperty("generic.heap_size", &total_virtual_size); DCHECK(res); res = allocator::GetNumericProperty("generic.total_physical_bytes", &resident_size); DCHECK(res); res = allocator::GetNumericProperty("generic.current_allocated_bytes", &allocated_objects_size); DCHECK(res); #elif defined(OS_MACOSX) || defined(OS_IOS) malloc_statistics_t stats = {0}; malloc_zone_statistics(nullptr, &stats); total_virtual_size = stats.size_allocated; allocated_objects_size = stats.size_in_use; // Resident size is approximated pretty well by stats.max_size_in_use. // However, on macOS, freed blocks are both resident and reusable, which is // semantically equivalent to deallocated. The implementation of libmalloc // will also only hold a fixed number of freed regions before actually // starting to deallocate them, so stats.max_size_in_use is also not // representative of the peak size. As a result, stats.max_size_in_use is // typically somewhere between actually resident [non-reusable] pages, and // peak size. This is not very useful, so we just use stats.size_in_use for // resident_size, even though it's an underestimate and fails to account for // fragmentation. See // https://bugs.chromium.org/p/chromium/issues/detail?id=695263#c1. resident_size = stats.size_in_use; #elif defined(OS_WIN) // This is too expensive on Windows, crbug.com/780735. if (args.level_of_detail == MemoryDumpLevelOfDetail::DETAILED) { WinHeapInfo main_heap_info = {}; WinHeapMemoryDumpImpl(&main_heap_info); total_virtual_size = main_heap_info.committed_size + main_heap_info.uncommitted_size; // Resident size is approximated with committed heap size. Note that it is // possible to do this with better accuracy on windows by intersecting the // working set with the virtual memory ranges occuipied by the heap. It's // not clear that this is worth it, as it's fairly expensive to do. resident_size = main_heap_info.committed_size; allocated_objects_size = main_heap_info.allocated_size; allocated_objects_count = main_heap_info.block_count; } #elif defined(OS_FUCHSIA) // TODO(fuchsia): Port, see https://crbug.com/706592. #else struct mallinfo info = mallinfo(); DCHECK_GE(info.arena + info.hblkhd, info.uordblks); // In case of Android's jemalloc |arena| is 0 and the outer pages size is // reported by |hblkhd|. In case of dlmalloc the total is given by // |arena| + |hblkhd|. For more details see link: http://goo.gl/fMR8lF. total_virtual_size = info.arena + info.hblkhd; resident_size = info.uordblks; // Total allocated space is given by |uordblks|. allocated_objects_size = info.uordblks; #endif MemoryAllocatorDump* outer_dump = pmd->CreateAllocatorDump("malloc"); outer_dump->AddScalar("virtual_size", MemoryAllocatorDump::kUnitsBytes, total_virtual_size); outer_dump->AddScalar(MemoryAllocatorDump::kNameSize, MemoryAllocatorDump::kUnitsBytes, resident_size); MemoryAllocatorDump* inner_dump = pmd->CreateAllocatorDump(kAllocatedObjects); inner_dump->AddScalar(MemoryAllocatorDump::kNameSize, MemoryAllocatorDump::kUnitsBytes, allocated_objects_size); if (allocated_objects_count != 0) { inner_dump->AddScalar(MemoryAllocatorDump::kNameObjectCount, MemoryAllocatorDump::kUnitsObjects, allocated_objects_count); } if (resident_size > allocated_objects_size) { // Explicitly specify why is extra memory resident. In tcmalloc it accounts // for free lists and caches. In mac and ios it accounts for the // fragmentation and metadata. MemoryAllocatorDump* other_dump = pmd->CreateAllocatorDump("malloc/metadata_fragmentation_caches"); other_dump->AddScalar(MemoryAllocatorDump::kNameSize, MemoryAllocatorDump::kUnitsBytes, resident_size - allocated_objects_size); } return true; } void MallocDumpProvider::EnableMetrics() { base::AutoLock auto_lock(emit_metrics_on_memory_dump_lock_); emit_metrics_on_memory_dump_ = true; } void MallocDumpProvider::DisableMetrics() { base::AutoLock auto_lock(emit_metrics_on_memory_dump_lock_); emit_metrics_on_memory_dump_ = false; } } // namespace trace_event } // namespace base