base/trace_event/malloc_dump_provider.cc - chromium/src - Git at Google

 // 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 <stddef.h>

 #include <unordered_map>

 #include "base/allocator/allocator_extension.h"
 #include "base/allocator/allocator_shim.h"
 #include "base/allocator/features.h"
 #include "base/debug/profiler.h"
 #include "base/trace_event/heap_profiler_allocation_context.h"
 #include "base/trace_event/heap_profiler_allocation_context_tracker.h"
 #include "base/trace_event/heap_profiler_heap_dump_writer.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 <malloc/malloc.h>
 #else
 #include <malloc.h>
 #endif
 #if defined(OS_WIN)
 #include <windows.h>
 #endif

 namespace base {
 namespace trace_event {

 namespace {
 #if BUILDFLAG(USE_ALLOCATOR_SHIM)

 using allocator::AllocatorDispatch;

 void* HookAlloc(const AllocatorDispatch* self, size_t size, void* context) {
   const AllocatorDispatch* const next = self->next;
   void* ptr = next->alloc_function(next, size, context);
   if (ptr)
     MallocDumpProvider::GetInstance()->InsertAllocation(ptr, size);
   return ptr;
 }

 void* HookZeroInitAlloc(const AllocatorDispatch* self,
                         size_t n,
                         size_t size,
                         void* context) {
   const AllocatorDispatch* const next = self->next;
   void* ptr = next->alloc_zero_initialized_function(next, n, size, context);
   if (ptr)
     MallocDumpProvider::GetInstance()->InsertAllocation(ptr, n * size);
   return ptr;
 }

 void* HookAllocAligned(const AllocatorDispatch* self,
                        size_t alignment,
                        size_t size,
                        void* context) {
   const AllocatorDispatch* const next = self->next;
   void* ptr = next->alloc_aligned_function(next, alignment, size, context);
   if (ptr)
     MallocDumpProvider::GetInstance()->InsertAllocation(ptr, size);
   return ptr;
 }

 void* HookRealloc(const AllocatorDispatch* self,
                   void* address,
                   size_t size,
                   void* context) {
   const AllocatorDispatch* const next = self->next;
   void* ptr = next->realloc_function(next, address, size, context);
   MallocDumpProvider::GetInstance()->RemoveAllocation(address);
   if (size > 0)  // realloc(size == 0) means free().
     MallocDumpProvider::GetInstance()->InsertAllocation(ptr, size);
   return ptr;
 }

 void HookFree(const AllocatorDispatch* self, void* address, void* context) {
   if (address)
     MallocDumpProvider::GetInstance()->RemoveAllocation(address);
   const AllocatorDispatch* const next = self->next;
   next->free_function(next, address, context);
 }

 size_t HookGetSizeEstimate(const AllocatorDispatch* self,
                            void* address,
                            void* context) {
   const AllocatorDispatch* const next = self->next;
   return next->get_size_estimate_function(next, address, context);
 }

 unsigned HookBatchMalloc(const AllocatorDispatch* self,
                          size_t size,
                          void** results,
                          unsigned num_requested,
                          void* context) {
   const AllocatorDispatch* const next = self->next;
   unsigned count =
       next->batch_malloc_function(next, size, results, num_requested, context);
   for (unsigned i = 0; i < count; ++i) {
     MallocDumpProvider::GetInstance()->InsertAllocation(results[i], size);
   }
   return count;
 }

 void HookBatchFree(const AllocatorDispatch* self,
                    void** to_be_freed,
                    unsigned num_to_be_freed,
                    void* context) {
   const AllocatorDispatch* const next = self->next;
   for (unsigned i = 0; i < num_to_be_freed; ++i) {
     MallocDumpProvider::GetInstance()->RemoveAllocation(to_be_freed[i]);
   }
   next->batch_free_function(next, to_be_freed, num_to_be_freed, context);
 }

 void HookFreeDefiniteSize(const AllocatorDispatch* self,
                           void* ptr,
                           size_t size,
                           void* context) {
   if (ptr)
     MallocDumpProvider::GetInstance()->RemoveAllocation(ptr);
   const AllocatorDispatch* const next = self->next;
   next->free_definite_size_function(next, ptr, size, context);
 }

 AllocatorDispatch g_allocator_hooks = {
     &HookAlloc,            /* alloc_function */
     &HookZeroInitAlloc,    /* alloc_zero_initialized_function */
     &HookAllocAligned,     /* alloc_aligned_function */
     &HookRealloc,          /* realloc_function */
     &HookFree,             /* free_function */
     &HookGetSizeEstimate,  /* get_size_estimate_function */
     &HookBatchMalloc,      /* batch_malloc_function */
     &HookBatchFree,        /* batch_free_function */
     &HookFreeDefiniteSize, /* free_definite_size_function */
     nullptr,               /* next */
 };
 #endif  // BUILDFLAG(USE_ALLOCATOR_SHIM)

 #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) {
 #if defined(SYZYASAN)
   if (base::debug::IsBinaryInstrumented())
     return;
 #endif

   // Iterate through whichever heap our CRT is using.
   HANDLE crt_heap = reinterpret_cast<HANDLE>(_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<MallocDumpProvider,
                    LeakySingletonTraits<MallocDumpProvider>>::get();
 }

 MallocDumpProvider::MallocDumpProvider()
     : tid_dumping_heap_(kInvalidThreadId) {}

 MallocDumpProvider::~MallocDumpProvider() {}

 // Called at trace dump point time. Creates a snapshot the memory counters for
 // the current process.
 bool MallocDumpProvider::OnMemoryDump(const MemoryDumpArgs& args,
                                       ProcessMemoryDump* pmd) {
   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)
   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);
   }

   // Heap profiler dumps.
   if (!allocation_register_.is_enabled())
     return true;

   // The dumps of the heap profiler should be created only when heap profiling
   // was enabled (--enable-heap-profiling) AND a DETAILED dump is requested.
   // However, when enabled, the overhead of the heap profiler should be always
   // reported to avoid oscillations of the malloc total in LIGHT dumps.

   tid_dumping_heap_ = PlatformThread::CurrentId();
   // At this point the Insert/RemoveAllocation hooks will ignore this thread.
   // Enclosing all the temporary data structures in a scope, so that the heap
   // profiler does not see unbalanced malloc/free calls from these containers.
   {
     TraceEventMemoryOverhead overhead;
     std::unordered_map<AllocationContext, AllocationMetrics> metrics_by_context;
     if (args.level_of_detail == MemoryDumpLevelOfDetail::DETAILED) {
       ShardedAllocationRegister::OutputMetrics shim_metrics =
           allocation_register_.UpdateAndReturnsMetrics(metrics_by_context);

       // Aggregate data for objects allocated through the shim.
       inner_dump->AddScalar("shim_allocated_objects_size",
                             MemoryAllocatorDump::kUnitsBytes,
                             shim_metrics.size);
       inner_dump->AddScalar("shim_allocator_object_count",
                             MemoryAllocatorDump::kUnitsObjects,
                             shim_metrics.count);
     }
     allocation_register_.EstimateTraceMemoryOverhead(&overhead);

     pmd->DumpHeapUsage(metrics_by_context, overhead, "malloc");
   }
   tid_dumping_heap_ = kInvalidThreadId;

   return true;
 }

 void MallocDumpProvider::OnHeapProfilingEnabled(bool enabled) {
 #if BUILDFLAG(USE_ALLOCATOR_SHIM)
   if (enabled) {
     allocation_register_.SetEnabled();
     allocator::InsertAllocatorDispatch(&g_allocator_hooks);
   } else {
     allocation_register_.SetDisabled();
   }
 #endif
 }

 void MallocDumpProvider::InsertAllocation(void* address, size_t size) {
   // CurrentId() can be a slow operation (crbug.com/497226). This apparently
   // redundant condition short circuits the CurrentID() calls when unnecessary.
   if (tid_dumping_heap_ != kInvalidThreadId &&
       tid_dumping_heap_ == PlatformThread::CurrentId())
     return;

   // AllocationContextTracker will return nullptr when called re-reentrantly.
   // This is the case of GetInstanceForCurrentThread() being called for the
   // first time, which causes a new() inside the tracker which re-enters the
   // heap profiler, in which case we just want to early out.
   auto* tracker = AllocationContextTracker::GetInstanceForCurrentThread();
   if (!tracker)
     return;

   AllocationContext context;
   if (!tracker->GetContextSnapshot(&context))
     return;

   if (!allocation_register_.is_enabled())
     return;

   allocation_register_.Insert(address, size, context);
 }

 void MallocDumpProvider::RemoveAllocation(void* address) {
   // No re-entrancy is expected here as none of the calls below should
   // cause a free()-s (|allocation_register_| does its own heap management).
   if (tid_dumping_heap_ != kInvalidThreadId &&
       tid_dumping_heap_ == PlatformThread::CurrentId())
     return;
   if (!allocation_register_.is_enabled())
     return;
   allocation_register_.Remove(address);
 }

 }  // namespace trace_event
 }  // namespace base
	// 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 <stddef.h>

	#include <unordered_map>

	#include "base/allocator/allocator_extension.h"
	#include "base/allocator/allocator_shim.h"
	#include "base/allocator/features.h"
	#include "base/debug/profiler.h"
	#include "base/trace_event/heap_profiler_allocation_context.h"
	#include "base/trace_event/heap_profiler_allocation_context_tracker.h"
	#include "base/trace_event/heap_profiler_heap_dump_writer.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 <malloc/malloc.h>
	#else
	#include <malloc.h>
	#endif
	#if defined(OS_WIN)
	#include <windows.h>
	#endif

	namespace base {
	namespace trace_event {

	namespace {
	#if BUILDFLAG(USE_ALLOCATOR_SHIM)

	using allocator::AllocatorDispatch;

	void* HookAlloc(const AllocatorDispatch* self, size_t size, void* context) {
	const AllocatorDispatch* const next = self->next;
	void* ptr = next->alloc_function(next, size, context);
	if (ptr)
	MallocDumpProvider::GetInstance()->InsertAllocation(ptr, size);
	return ptr;
	}

	void* HookZeroInitAlloc(const AllocatorDispatch* self,
	size_t n,
	size_t size,
	void* context) {
	const AllocatorDispatch* const next = self->next;
	void* ptr = next->alloc_zero_initialized_function(next, n, size, context);
	if (ptr)
	MallocDumpProvider::GetInstance()->InsertAllocation(ptr, n * size);
	return ptr;
	}

	void* HookAllocAligned(const AllocatorDispatch* self,
	size_t alignment,
	size_t size,
	void* context) {
	const AllocatorDispatch* const next = self->next;
	void* ptr = next->alloc_aligned_function(next, alignment, size, context);
	if (ptr)
	MallocDumpProvider::GetInstance()->InsertAllocation(ptr, size);
	return ptr;
	}

	void* HookRealloc(const AllocatorDispatch* self,
	void* address,
	size_t size,
	void* context) {
	const AllocatorDispatch* const next = self->next;
	void* ptr = next->realloc_function(next, address, size, context);
	MallocDumpProvider::GetInstance()->RemoveAllocation(address);
	if (size > 0) // realloc(size == 0) means free().
	MallocDumpProvider::GetInstance()->InsertAllocation(ptr, size);
	return ptr;
	}

	void HookFree(const AllocatorDispatch* self, void* address, void* context) {
	if (address)
	MallocDumpProvider::GetInstance()->RemoveAllocation(address);
	const AllocatorDispatch* const next = self->next;
	next->free_function(next, address, context);
	}

	size_t HookGetSizeEstimate(const AllocatorDispatch* self,
	void* address,
	void* context) {
	const AllocatorDispatch* const next = self->next;
	return next->get_size_estimate_function(next, address, context);
	}

	unsigned HookBatchMalloc(const AllocatorDispatch* self,
	size_t size,
	void** results,
	unsigned num_requested,
	void* context) {
	const AllocatorDispatch* const next = self->next;
	unsigned count =
	next->batch_malloc_function(next, size, results, num_requested, context);
	for (unsigned i = 0; i < count; ++i) {
	MallocDumpProvider::GetInstance()->InsertAllocation(results[i], size);
	}
	return count;
	}

	void HookBatchFree(const AllocatorDispatch* self,
	void** to_be_freed,
	unsigned num_to_be_freed,
	void* context) {
	const AllocatorDispatch* const next = self->next;
	for (unsigned i = 0; i < num_to_be_freed; ++i) {
	MallocDumpProvider::GetInstance()->RemoveAllocation(to_be_freed[i]);
	}
	next->batch_free_function(next, to_be_freed, num_to_be_freed, context);
	}

	void HookFreeDefiniteSize(const AllocatorDispatch* self,
	void* ptr,
	size_t size,
	void* context) {
	if (ptr)
	MallocDumpProvider::GetInstance()->RemoveAllocation(ptr);
	const AllocatorDispatch* const next = self->next;
	next->free_definite_size_function(next, ptr, size, context);
	}

	AllocatorDispatch g_allocator_hooks = {
	&HookAlloc, /* alloc_function */
	&HookZeroInitAlloc, /* alloc_zero_initialized_function */
	&HookAllocAligned, /* alloc_aligned_function */
	&HookRealloc, /* realloc_function */
	&HookFree, /* free_function */
	&HookGetSizeEstimate, /* get_size_estimate_function */
	&HookBatchMalloc, /* batch_malloc_function */
	&HookBatchFree, /* batch_free_function */
	&HookFreeDefiniteSize, /* free_definite_size_function */
	nullptr, /* next */
	};
	#endif // BUILDFLAG(USE_ALLOCATOR_SHIM)

	#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) {
	#if defined(SYZYASAN)
	if (base::debug::IsBinaryInstrumented())
	return;
	#endif

	// Iterate through whichever heap our CRT is using.
	HANDLE crt_heap = reinterpret_cast<HANDLE>(_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<MallocDumpProvider,
	LeakySingletonTraits<MallocDumpProvider>>::get();
	}

	MallocDumpProvider::MallocDumpProvider()
	: tid_dumping_heap_(kInvalidThreadId) {}

	MallocDumpProvider::~MallocDumpProvider() {}

	// Called at trace dump point time. Creates a snapshot the memory counters for
	// the current process.
	bool MallocDumpProvider::OnMemoryDump(const MemoryDumpArgs& args,
	ProcessMemoryDump* pmd) {
	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)
	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);
	}

	// Heap profiler dumps.
	if (!allocation_register_.is_enabled())
	return true;

	// The dumps of the heap profiler should be created only when heap profiling
	// was enabled (--enable-heap-profiling) AND a DETAILED dump is requested.
	// However, when enabled, the overhead of the heap profiler should be always
	// reported to avoid oscillations of the malloc total in LIGHT dumps.

	tid_dumping_heap_ = PlatformThread::CurrentId();
	// At this point the Insert/RemoveAllocation hooks will ignore this thread.
	// Enclosing all the temporary data structures in a scope, so that the heap
	// profiler does not see unbalanced malloc/free calls from these containers.
	{
	TraceEventMemoryOverhead overhead;
	std::unordered_map<AllocationContext, AllocationMetrics> metrics_by_context;
	if (args.level_of_detail == MemoryDumpLevelOfDetail::DETAILED) {
	ShardedAllocationRegister::OutputMetrics shim_metrics =
	allocation_register_.UpdateAndReturnsMetrics(metrics_by_context);

	// Aggregate data for objects allocated through the shim.
	inner_dump->AddScalar("shim_allocated_objects_size",
	MemoryAllocatorDump::kUnitsBytes,
	shim_metrics.size);
	inner_dump->AddScalar("shim_allocator_object_count",
	MemoryAllocatorDump::kUnitsObjects,
	shim_metrics.count);
	}
	allocation_register_.EstimateTraceMemoryOverhead(&overhead);

	pmd->DumpHeapUsage(metrics_by_context, overhead, "malloc");
	}
	tid_dumping_heap_ = kInvalidThreadId;

	return true;
	}

	void MallocDumpProvider::OnHeapProfilingEnabled(bool enabled) {
	#if BUILDFLAG(USE_ALLOCATOR_SHIM)
	if (enabled) {
	allocation_register_.SetEnabled();
	allocator::InsertAllocatorDispatch(&g_allocator_hooks);
	} else {
	allocation_register_.SetDisabled();
	}
	#endif
	}

	void MallocDumpProvider::InsertAllocation(void* address, size_t size) {
	// CurrentId() can be a slow operation (crbug.com/497226). This apparently
	// redundant condition short circuits the CurrentID() calls when unnecessary.
	if (tid_dumping_heap_ != kInvalidThreadId &&
	tid_dumping_heap_ == PlatformThread::CurrentId())
	return;

	// AllocationContextTracker will return nullptr when called re-reentrantly.
	// This is the case of GetInstanceForCurrentThread() being called for the
	// first time, which causes a new() inside the tracker which re-enters the
	// heap profiler, in which case we just want to early out.
	auto* tracker = AllocationContextTracker::GetInstanceForCurrentThread();
	if (!tracker)
	return;

	AllocationContext context;
	if (!tracker->GetContextSnapshot(&context))
	return;

	if (!allocation_register_.is_enabled())
	return;

	allocation_register_.Insert(address, size, context);
	}

	void MallocDumpProvider::RemoveAllocation(void* address) {
	// No re-entrancy is expected here as none of the calls below should
	// cause a free()-s (\|allocation_register_\| does its own heap management).
	if (tid_dumping_heap_ != kInvalidThreadId &&
	tid_dumping_heap_ == PlatformThread::CurrentId())
	return;
	if (!allocation_register_.is_enabled())
	return;
	allocation_register_.Remove(address);
	}

	} // namespace trace_event
	} // namespace base