mirror of
https://github.com/klzgrad/naiveproxy.git
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446 lines
15 KiB
C++
446 lines
15 KiB
C++
// Copyright 2018 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "base/sampling_heap_profiler/sampling_heap_profiler.h"
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#include <algorithm>
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#include <cmath>
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#include <utility>
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#include "base/allocator/allocator_shim.h"
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#include "base/allocator/buildflags.h"
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#include "base/allocator/partition_allocator/partition_alloc.h"
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#include "base/atomicops.h"
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#include "base/debug/stack_trace.h"
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#include "base/macros.h"
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#include "base/no_destructor.h"
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#include "base/partition_alloc_buildflags.h"
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#include "base/rand_util.h"
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#include "base/threading/thread_local_storage.h"
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#include "build/build_config.h"
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namespace base {
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using base::allocator::AllocatorDispatch;
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using base::subtle::Atomic32;
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using base::subtle::AtomicWord;
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namespace {
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// Control how many top frames to skip when recording call stack.
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// These frames correspond to the profiler own frames.
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const uint32_t kSkipBaseAllocatorFrames = 2;
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const size_t kDefaultSamplingIntervalBytes = 128 * 1024;
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// Controls if sample intervals should not be randomized. Used for testing.
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bool g_deterministic;
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// A positive value if profiling is running, otherwise it's zero.
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Atomic32 g_running;
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// Pointer to the current |SamplingHeapProfiler::SamplesMap|.
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AtomicWord g_current_samples_map;
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// Sampling interval parameter, the mean value for intervals between samples.
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AtomicWord g_sampling_interval = kDefaultSamplingIntervalBytes;
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void (*g_hooks_install_callback)();
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Atomic32 g_hooks_installed;
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void* AllocFn(const AllocatorDispatch* self, size_t size, void* context) {
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void* address = self->next->alloc_function(self->next, size, context);
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SamplingHeapProfiler::RecordAlloc(address, size, kSkipBaseAllocatorFrames);
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return address;
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}
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void* AllocZeroInitializedFn(const AllocatorDispatch* self,
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size_t n,
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size_t size,
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void* context) {
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void* address =
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self->next->alloc_zero_initialized_function(self->next, n, size, context);
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SamplingHeapProfiler::RecordAlloc(address, n * size,
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kSkipBaseAllocatorFrames);
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return address;
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}
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void* AllocAlignedFn(const AllocatorDispatch* self,
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size_t alignment,
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size_t size,
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void* context) {
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void* address =
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self->next->alloc_aligned_function(self->next, alignment, size, context);
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SamplingHeapProfiler::RecordAlloc(address, size, kSkipBaseAllocatorFrames);
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return address;
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}
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void* ReallocFn(const AllocatorDispatch* self,
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void* address,
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size_t size,
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void* context) {
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// Note: size == 0 actually performs free.
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SamplingHeapProfiler::RecordFree(address);
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address = self->next->realloc_function(self->next, address, size, context);
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SamplingHeapProfiler::RecordAlloc(address, size, kSkipBaseAllocatorFrames);
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return address;
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}
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void FreeFn(const AllocatorDispatch* self, void* address, void* context) {
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SamplingHeapProfiler::RecordFree(address);
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self->next->free_function(self->next, address, context);
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}
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size_t GetSizeEstimateFn(const AllocatorDispatch* self,
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void* address,
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void* context) {
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return self->next->get_size_estimate_function(self->next, address, context);
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}
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unsigned BatchMallocFn(const AllocatorDispatch* self,
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size_t size,
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void** results,
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unsigned num_requested,
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void* context) {
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unsigned num_allocated = self->next->batch_malloc_function(
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self->next, size, results, num_requested, context);
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for (unsigned i = 0; i < num_allocated; ++i) {
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SamplingHeapProfiler::RecordAlloc(results[i], size,
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kSkipBaseAllocatorFrames);
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}
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return num_allocated;
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}
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void BatchFreeFn(const AllocatorDispatch* self,
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void** to_be_freed,
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unsigned num_to_be_freed,
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void* context) {
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for (unsigned i = 0; i < num_to_be_freed; ++i)
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SamplingHeapProfiler::RecordFree(to_be_freed[i]);
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self->next->batch_free_function(self->next, to_be_freed, num_to_be_freed,
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context);
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}
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void FreeDefiniteSizeFn(const AllocatorDispatch* self,
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void* address,
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size_t size,
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void* context) {
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SamplingHeapProfiler::RecordFree(address);
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self->next->free_definite_size_function(self->next, address, size, context);
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}
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AllocatorDispatch g_allocator_dispatch = {&AllocFn,
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&AllocZeroInitializedFn,
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&AllocAlignedFn,
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&ReallocFn,
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&FreeFn,
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&GetSizeEstimateFn,
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&BatchMallocFn,
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&BatchFreeFn,
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&FreeDefiniteSizeFn,
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nullptr};
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#if BUILDFLAG(USE_PARTITION_ALLOC) && !defined(OS_NACL)
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void PartitionAllocHook(void* address, size_t size, const char*) {
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SamplingHeapProfiler::RecordAlloc(address, size);
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}
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void PartitionFreeHook(void* address) {
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SamplingHeapProfiler::RecordFree(address);
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}
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#endif // BUILDFLAG(USE_PARTITION_ALLOC) && !defined(OS_NACL)
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ThreadLocalStorage::Slot& AccumulatedBytesTLS() {
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static base::NoDestructor<base::ThreadLocalStorage::Slot>
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accumulated_bytes_tls;
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return *accumulated_bytes_tls;
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}
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} // namespace
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SamplingHeapProfiler::Sample::Sample(size_t size,
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size_t total,
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uint32_t ordinal)
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: size(size), total(total), ordinal(ordinal) {}
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SamplingHeapProfiler::Sample::Sample(const Sample&) = default;
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SamplingHeapProfiler::Sample::~Sample() = default;
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SamplingHeapProfiler* SamplingHeapProfiler::instance_;
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SamplingHeapProfiler::SamplingHeapProfiler() {
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instance_ = this;
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auto samples_map = std::make_unique<SamplesMap>(64);
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base::subtle::NoBarrier_Store(
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&g_current_samples_map, reinterpret_cast<AtomicWord>(samples_map.get()));
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sample_maps_.push(std::move(samples_map));
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}
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// static
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void SamplingHeapProfiler::InitTLSSlot() {
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// Preallocate the TLS slot early, so it can't cause reentracy issues
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// when sampling is started.
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ignore_result(AccumulatedBytesTLS().Get());
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}
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// static
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void SamplingHeapProfiler::InstallAllocatorHooksOnce() {
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static bool hook_installed = InstallAllocatorHooks();
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ignore_result(hook_installed);
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}
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// static
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bool SamplingHeapProfiler::InstallAllocatorHooks() {
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#if BUILDFLAG(USE_ALLOCATOR_SHIM)
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base::allocator::InsertAllocatorDispatch(&g_allocator_dispatch);
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#else
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ignore_result(g_allocator_dispatch);
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DLOG(WARNING)
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<< "base::allocator shims are not available for memory sampling.";
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#endif // BUILDFLAG(USE_ALLOCATOR_SHIM)
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#if BUILDFLAG(USE_PARTITION_ALLOC) && !defined(OS_NACL)
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base::PartitionAllocHooks::SetAllocationHook(&PartitionAllocHook);
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base::PartitionAllocHooks::SetFreeHook(&PartitionFreeHook);
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#endif // BUILDFLAG(USE_PARTITION_ALLOC) && !defined(OS_NACL)
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int32_t hooks_install_callback_has_been_set =
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base::subtle::Acquire_CompareAndSwap(&g_hooks_installed, 0, 1);
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if (hooks_install_callback_has_been_set)
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g_hooks_install_callback();
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return true;
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}
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// static
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void SamplingHeapProfiler::SetHooksInstallCallback(
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void (*hooks_install_callback)()) {
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CHECK(!g_hooks_install_callback && hooks_install_callback);
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g_hooks_install_callback = hooks_install_callback;
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int32_t profiler_has_already_been_initialized =
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base::subtle::Release_CompareAndSwap(&g_hooks_installed, 0, 1);
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if (profiler_has_already_been_initialized)
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g_hooks_install_callback();
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}
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uint32_t SamplingHeapProfiler::Start() {
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InstallAllocatorHooksOnce();
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base::subtle::Barrier_AtomicIncrement(&g_running, 1);
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return last_sample_ordinal_;
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}
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void SamplingHeapProfiler::Stop() {
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AtomicWord count = base::subtle::Barrier_AtomicIncrement(&g_running, -1);
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CHECK_GE(count, 0);
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}
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void SamplingHeapProfiler::SetSamplingInterval(size_t sampling_interval) {
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// TODO(alph): Reset the sample being collected if running.
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base::subtle::Release_Store(&g_sampling_interval,
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static_cast<AtomicWord>(sampling_interval));
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}
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// static
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size_t SamplingHeapProfiler::GetNextSampleInterval(size_t interval) {
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if (UNLIKELY(g_deterministic))
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return interval;
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// We sample with a Poisson process, with constant average sampling
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// interval. This follows the exponential probability distribution with
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// parameter λ = 1/interval where |interval| is the average number of bytes
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// between samples.
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// Let u be a uniformly distributed random number between 0 and 1, then
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// next_sample = -ln(u) / λ
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double uniform = base::RandDouble();
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double value = -log(uniform) * interval;
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size_t min_value = sizeof(intptr_t);
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// We limit the upper bound of a sample interval to make sure we don't have
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// huge gaps in the sampling stream. Probability of the upper bound gets hit
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// is exp(-20) ~ 2e-9, so it should not skew the distibution.
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size_t max_value = interval * 20;
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if (UNLIKELY(value < min_value))
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return min_value;
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if (UNLIKELY(value > max_value))
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return max_value;
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return static_cast<size_t>(value);
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}
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// static
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void SamplingHeapProfiler::RecordAlloc(void* address,
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size_t size,
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uint32_t skip_frames) {
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if (UNLIKELY(!base::subtle::NoBarrier_Load(&g_running)))
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return;
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if (UNLIKELY(base::ThreadLocalStorage::HasBeenDestroyed()))
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return;
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// TODO(alph): On MacOS it may call the hook several times for a single
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// allocation. Handle the case.
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intptr_t accumulated_bytes =
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reinterpret_cast<intptr_t>(AccumulatedBytesTLS().Get());
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accumulated_bytes += size;
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if (LIKELY(accumulated_bytes < 0)) {
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AccumulatedBytesTLS().Set(reinterpret_cast<void*>(accumulated_bytes));
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return;
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}
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size_t mean_interval = base::subtle::NoBarrier_Load(&g_sampling_interval);
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size_t samples = accumulated_bytes / mean_interval;
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accumulated_bytes %= mean_interval;
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do {
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accumulated_bytes -= GetNextSampleInterval(mean_interval);
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++samples;
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} while (accumulated_bytes >= 0);
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AccumulatedBytesTLS().Set(reinterpret_cast<void*>(accumulated_bytes));
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instance_->DoRecordAlloc(samples * mean_interval, size, address, skip_frames);
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}
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void SamplingHeapProfiler::RecordStackTrace(Sample* sample,
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uint32_t skip_frames) {
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#if !defined(OS_NACL)
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// TODO(alph): Consider using debug::TraceStackFramePointers. It should be
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// somewhat faster than base::debug::StackTrace.
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base::debug::StackTrace trace;
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size_t count;
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void* const* addresses = const_cast<void* const*>(trace.Addresses(&count));
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const uint32_t kSkipProfilerOwnFrames = 2;
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skip_frames += kSkipProfilerOwnFrames;
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sample->stack.insert(
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sample->stack.end(), &addresses[skip_frames],
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&addresses[std::max(count, static_cast<size_t>(skip_frames))]);
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#endif
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}
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void SamplingHeapProfiler::DoRecordAlloc(size_t total_allocated,
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size_t size,
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void* address,
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uint32_t skip_frames) {
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if (entered_.Get())
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return;
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entered_.Set(true);
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{
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base::AutoLock lock(mutex_);
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Sample sample(size, total_allocated, ++last_sample_ordinal_);
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RecordStackTrace(&sample, skip_frames);
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for (auto* observer : observers_)
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observer->SampleAdded(sample.ordinal, size, total_allocated);
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EnsureNoRehashingMap().emplace(address, std::move(sample));
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}
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entered_.Set(false);
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}
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// static
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void SamplingHeapProfiler::RecordFree(void* address) {
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const SamplesMap& samples = SamplingHeapProfiler::samples();
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if (UNLIKELY(samples.find(address) != samples.end()))
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instance_->DoRecordFree(address);
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}
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void SamplingHeapProfiler::DoRecordFree(void* address) {
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if (UNLIKELY(base::ThreadLocalStorage::HasBeenDestroyed()))
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return;
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if (entered_.Get())
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return;
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entered_.Set(true);
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{
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base::AutoLock lock(mutex_);
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SamplesMap& samples = this->samples();
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auto it = samples.find(address);
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CHECK(it != samples.end());
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for (auto* observer : observers_)
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observer->SampleRemoved(it->second.ordinal);
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samples.erase(it);
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}
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entered_.Set(false);
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}
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SamplingHeapProfiler::SamplesMap& SamplingHeapProfiler::EnsureNoRehashingMap() {
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// The function makes sure we never rehash the current map in place.
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// Instead if it comes close to the rehashing boundary, we allocate a twice
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// larger map, copy the samples into it, and atomically switch new readers
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// to use the new map.
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// We still have to keep all the old maps alive to resolve the theoretical
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// race with readers in |RecordFree| that have already obtained the map,
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// but haven't yet managed to access it.
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SamplesMap& samples = this->samples();
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size_t max_items_before_rehash =
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static_cast<size_t>(samples.bucket_count() * samples.max_load_factor());
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// Conservatively use 2 instead of 1 to workaround potential rounding errors.
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bool may_rehash_on_insert = samples.size() + 2 >= max_items_before_rehash;
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if (!may_rehash_on_insert)
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return samples;
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auto new_map = std::make_unique<SamplesMap>(samples.begin(), samples.end(),
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samples.bucket_count() * 2);
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base::subtle::Release_Store(&g_current_samples_map,
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reinterpret_cast<AtomicWord>(new_map.get()));
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sample_maps_.push(std::move(new_map));
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return this->samples();
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}
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// static
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SamplingHeapProfiler::SamplesMap& SamplingHeapProfiler::samples() {
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return *reinterpret_cast<SamplesMap*>(
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base::subtle::NoBarrier_Load(&g_current_samples_map));
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}
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// static
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SamplingHeapProfiler* SamplingHeapProfiler::GetInstance() {
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static base::NoDestructor<SamplingHeapProfiler> instance;
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return instance.get();
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}
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// static
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void SamplingHeapProfiler::SuppressRandomnessForTest(bool suppress) {
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g_deterministic = suppress;
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}
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void SamplingHeapProfiler::AddSamplesObserver(SamplesObserver* observer) {
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CHECK(!entered_.Get());
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entered_.Set(true);
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{
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base::AutoLock lock(mutex_);
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observers_.push_back(observer);
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}
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entered_.Set(false);
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}
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void SamplingHeapProfiler::RemoveSamplesObserver(SamplesObserver* observer) {
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CHECK(!entered_.Get());
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entered_.Set(true);
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{
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base::AutoLock lock(mutex_);
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auto it = std::find(observers_.begin(), observers_.end(), observer);
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CHECK(it != observers_.end());
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observers_.erase(it);
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}
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entered_.Set(false);
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}
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std::vector<SamplingHeapProfiler::Sample> SamplingHeapProfiler::GetSamples(
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uint32_t profile_id) {
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CHECK(!entered_.Get());
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entered_.Set(true);
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std::vector<Sample> samples;
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{
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base::AutoLock lock(mutex_);
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for (auto& it : this->samples()) {
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Sample& sample = it.second;
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if (sample.ordinal > profile_id)
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samples.push_back(sample);
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}
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}
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entered_.Set(false);
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return samples;
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}
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} // namespace base
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