src/v8/src/profiler/cpu-profiler.cc - cobalt - Git at Google

 // Copyright 2012 the V8 project 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 "src/profiler/cpu-profiler.h"

 #include "src/base/lazy-instance.h"
 #include "src/base/platform/mutex.h"
 #include "src/base/template-utils.h"
 #include "src/debug/debug.h"
 #include "src/deoptimizer.h"
 #include "src/frames-inl.h"
 #include "src/locked-queue-inl.h"
 #include "src/log-inl.h"
 #include "src/profiler/cpu-profiler-inl.h"
 #include "src/vm-state-inl.h"

 namespace v8 {
 namespace internal {

 static const int kProfilerStackSize = 64 * KB;

 class CpuSampler : public sampler::Sampler {
  public:
   CpuSampler(Isolate* isolate, ProfilerEventsProcessor* processor)
       : sampler::Sampler(reinterpret_cast<v8::Isolate*>(isolate)),
         processor_(processor) {}

   void SampleStack(const v8::RegisterState& regs) override {
     TickSample* sample = processor_->StartTickSample();
     if (sample == nullptr) return;
     Isolate* isolate = reinterpret_cast<Isolate*>(this->isolate());
     sample->Init(isolate, regs, TickSample::kIncludeCEntryFrame, true);
     if (is_counting_samples_ && !sample->timestamp.IsNull()) {
       if (sample->state == JS) ++js_sample_count_;
       if (sample->state == EXTERNAL) ++external_sample_count_;
     }
     processor_->FinishTickSample();
   }

  private:
   ProfilerEventsProcessor* processor_;
 };

 ProfilerEventsProcessor::ProfilerEventsProcessor(Isolate* isolate,
                                                  ProfileGenerator* generator,
                                                  base::TimeDelta period)
     : Thread(Thread::Options("v8:ProfEvntProc", kProfilerStackSize)),
       generator_(generator),
       sampler_(new CpuSampler(isolate, this)),
       running_(1),
       period_(period),
       last_code_event_id_(0),
       last_processed_code_event_id_(0) {
   sampler_->IncreaseProfilingDepth();
 }

 ProfilerEventsProcessor::~ProfilerEventsProcessor() {
   sampler_->DecreaseProfilingDepth();
 }

 void ProfilerEventsProcessor::Enqueue(const CodeEventsContainer& event) {
   event.generic.order = last_code_event_id_.Increment(1);
   events_buffer_.Enqueue(event);
 }


 void ProfilerEventsProcessor::AddDeoptStack(Isolate* isolate, Address from,
                                             int fp_to_sp_delta) {
   TickSampleEventRecord record(last_code_event_id_.Value());
   RegisterState regs;
   Address fp = isolate->c_entry_fp(isolate->thread_local_top());
   regs.sp = fp - fp_to_sp_delta;
   regs.fp = fp;
   regs.pc = from;
   record.sample.Init(isolate, regs, TickSample::kSkipCEntryFrame, false, false);
   ticks_from_vm_buffer_.Enqueue(record);
 }

 void ProfilerEventsProcessor::AddCurrentStack(Isolate* isolate,
                                               bool update_stats) {
   TickSampleEventRecord record(last_code_event_id_.Value());
   RegisterState regs;
   StackFrameIterator it(isolate);
   if (!it.done()) {
     StackFrame* frame = it.frame();
     regs.sp = frame->sp();
     regs.fp = frame->fp();
     regs.pc = frame->pc();
   }
   record.sample.Init(isolate, regs, TickSample::kSkipCEntryFrame, update_stats,
                      false);
   ticks_from_vm_buffer_.Enqueue(record);
 }


 void ProfilerEventsProcessor::StopSynchronously() {
   if (!base::Relaxed_AtomicExchange(&running_, 0)) return;
   Join();
 }


 bool ProfilerEventsProcessor::ProcessCodeEvent() {
   CodeEventsContainer record;
   if (events_buffer_.Dequeue(&record)) {
     switch (record.generic.type) {
 #define PROFILER_TYPE_CASE(type, clss)                          \
       case CodeEventRecord::type:                               \
         record.clss##_.UpdateCodeMap(generator_->code_map());   \
         break;

       CODE_EVENTS_TYPE_LIST(PROFILER_TYPE_CASE)

 #undef PROFILER_TYPE_CASE
       default: return true;  // Skip record.
     }
     last_processed_code_event_id_ = record.generic.order;
     return true;
   }
   return false;
 }

 ProfilerEventsProcessor::SampleProcessingResult
     ProfilerEventsProcessor::ProcessOneSample() {
   TickSampleEventRecord record1;
   if (ticks_from_vm_buffer_.Peek(&record1) &&
       (record1.order == last_processed_code_event_id_)) {
     TickSampleEventRecord record;
     ticks_from_vm_buffer_.Dequeue(&record);
     generator_->RecordTickSample(record.sample);
     return OneSampleProcessed;
   }

   const TickSampleEventRecord* record = ticks_buffer_.Peek();
   if (record == nullptr) {
     if (ticks_from_vm_buffer_.IsEmpty()) return NoSamplesInQueue;
     return FoundSampleForNextCodeEvent;
   }
   if (record->order != last_processed_code_event_id_) {
     return FoundSampleForNextCodeEvent;
   }
   generator_->RecordTickSample(record->sample);
   ticks_buffer_.Remove();
   return OneSampleProcessed;
 }


 void ProfilerEventsProcessor::Run() {
   while (!!base::Relaxed_Load(&running_)) {
     base::TimeTicks nextSampleTime =
         base::TimeTicks::HighResolutionNow() + period_;
     base::TimeTicks now;
     SampleProcessingResult result;
     // Keep processing existing events until we need to do next sample
     // or the ticks buffer is empty.
     do {
       result = ProcessOneSample();
       if (result == FoundSampleForNextCodeEvent) {
         // All ticks of the current last_processed_code_event_id_ are
         // processed, proceed to the next code event.
         ProcessCodeEvent();
       }
       now = base::TimeTicks::HighResolutionNow();
     } while (result != NoSamplesInQueue && now < nextSampleTime);

     if (nextSampleTime > now) {
 #if V8_OS_WIN
       // Do not use Sleep on Windows as it is very imprecise.
       // Could be up to 16ms jitter, which is unacceptable for the purpose.
       while (base::TimeTicks::HighResolutionNow() < nextSampleTime) {
       }
 #else
       base::OS::Sleep(nextSampleTime - now);
 #endif
     }

     // Schedule next sample. sampler_ is nullptr in tests.
     if (sampler_) sampler_->DoSample();
   }

   // Process remaining tick events.
   do {
     SampleProcessingResult result;
     do {
       result = ProcessOneSample();
     } while (result == OneSampleProcessed);
   } while (ProcessCodeEvent());
 }


 void* ProfilerEventsProcessor::operator new(size_t size) {
   return AlignedAlloc(size, V8_ALIGNOF(ProfilerEventsProcessor));
 }


 void ProfilerEventsProcessor::operator delete(void* ptr) {
   AlignedFree(ptr);
 }


 int CpuProfiler::GetProfilesCount() {
   // The count of profiles doesn't depend on a security token.
   return static_cast<int>(profiles_->profiles()->size());
 }


 CpuProfile* CpuProfiler::GetProfile(int index) {
   return profiles_->profiles()->at(index);
 }


 void CpuProfiler::DeleteAllProfiles() {
   if (is_profiling_) StopProcessor();
   ResetProfiles();
 }


 void CpuProfiler::DeleteProfile(CpuProfile* profile) {
   profiles_->RemoveProfile(profile);
   delete profile;
   if (profiles_->profiles()->empty() && !is_profiling_) {
     // If this was the last profile, clean up all accessory data as well.
     ResetProfiles();
   }
 }

 void CpuProfiler::CodeEventHandler(const CodeEventsContainer& evt_rec) {
   switch (evt_rec.generic.type) {
     case CodeEventRecord::CODE_CREATION:
     case CodeEventRecord::CODE_MOVE:
     case CodeEventRecord::CODE_DISABLE_OPT:
       processor_->Enqueue(evt_rec);
       break;
     case CodeEventRecord::CODE_DEOPT: {
       const CodeDeoptEventRecord* rec = &evt_rec.CodeDeoptEventRecord_;
       Address pc = reinterpret_cast<Address>(rec->pc);
       int fp_to_sp_delta = rec->fp_to_sp_delta;
       processor_->Enqueue(evt_rec);
       processor_->AddDeoptStack(isolate_, pc, fp_to_sp_delta);
       break;
     }
     default:
       UNREACHABLE();
   }
 }

 namespace {

 class CpuProfilersManager {
  public:
   void AddProfiler(Isolate* isolate, CpuProfiler* profiler) {
     base::LockGuard<base::Mutex> lock(&mutex_);
     auto result = profilers_.insert(
         std::pair<Isolate*, std::unique_ptr<std::set<CpuProfiler*>>>(
             isolate, base::make_unique<std::set<CpuProfiler*>>()));
     result.first->second->insert(profiler);
   }

   void RemoveProfiler(Isolate* isolate, CpuProfiler* profiler) {
     base::LockGuard<base::Mutex> lock(&mutex_);
     auto it = profilers_.find(isolate);
     DCHECK(it != profilers_.end());
     it->second->erase(profiler);
     if (it->second->empty()) {
       profilers_.erase(it);
     }
   }

   void CallCollectSample(Isolate* isolate) {
     base::LockGuard<base::Mutex> lock(&mutex_);
     auto profilers = profilers_.find(isolate);
     if (profilers == profilers_.end()) return;
     for (auto it : *profilers->second) {
       it->CollectSample();
     }
   }

  private:
   std::map<Isolate*, std::unique_ptr<std::set<CpuProfiler*>>> profilers_;
   base::Mutex mutex_;
 };

 base::LazyInstance<CpuProfilersManager>::type g_profilers_manager =
     LAZY_INSTANCE_INITIALIZER;

 }  // namespace

 CpuProfiler::CpuProfiler(Isolate* isolate)
     : CpuProfiler(isolate, new CpuProfilesCollection(isolate), nullptr,
                   nullptr) {}

 CpuProfiler::CpuProfiler(Isolate* isolate, CpuProfilesCollection* test_profiles,
                          ProfileGenerator* test_generator,
                          ProfilerEventsProcessor* test_processor)
     : isolate_(isolate),
       sampling_interval_(base::TimeDelta::FromMicroseconds(
           FLAG_cpu_profiler_sampling_interval)),
       profiles_(test_profiles),
       generator_(test_generator),
       processor_(test_processor),
       is_profiling_(false) {
   profiles_->set_cpu_profiler(this);
   g_profilers_manager.Pointer()->AddProfiler(isolate, this);
 }

 CpuProfiler::~CpuProfiler() {
   DCHECK(!is_profiling_);
   g_profilers_manager.Pointer()->RemoveProfiler(isolate_, this);
 }

 void CpuProfiler::set_sampling_interval(base::TimeDelta value) {
   DCHECK(!is_profiling_);
   sampling_interval_ = value;
 }

 void CpuProfiler::ResetProfiles() {
   profiles_.reset(new CpuProfilesCollection(isolate_));
   profiles_->set_cpu_profiler(this);
 }

 void CpuProfiler::CreateEntriesForRuntimeCallStats() {
   static_entries_.clear();
   RuntimeCallStats* rcs = isolate_->counters()->runtime_call_stats();
   CodeMap* code_map = generator_->code_map();
   for (int i = 0; i < RuntimeCallStats::kNumberOfCounters; ++i) {
     RuntimeCallCounter* counter = rcs->GetCounter(i);
     DCHECK(counter->name());
     std::unique_ptr<CodeEntry> entry(
         new CodeEntry(CodeEventListener::FUNCTION_TAG, counter->name(),
                       CodeEntry::kEmptyNamePrefix, "native V8Runtime"));
     code_map->AddCode(reinterpret_cast<Address>(counter), entry.get(), 1);
     static_entries_.push_back(std::move(entry));
   }
 }

 // static
 void CpuProfiler::CollectSample(Isolate* isolate) {
   g_profilers_manager.Pointer()->CallCollectSample(isolate);
 }

 void CpuProfiler::CollectSample() {
   if (processor_) {
     processor_->AddCurrentStack(isolate_);
   }
 }

 void CpuProfiler::StartProfiling(const char* title, bool record_samples) {
   if (profiles_->StartProfiling(title, record_samples)) {
     TRACE_EVENT0("v8", "CpuProfiler::StartProfiling");
     StartProcessorIfNotStarted();
   }
 }


 void CpuProfiler::StartProfiling(String* title, bool record_samples) {
   StartProfiling(profiles_->GetName(title), record_samples);
   isolate_->debug()->feature_tracker()->Track(DebugFeatureTracker::kProfiler);
 }


 void CpuProfiler::StartProcessorIfNotStarted() {
   if (processor_) {
     processor_->AddCurrentStack(isolate_);
     return;
   }
   Logger* logger = isolate_->logger();
   // Disable logging when using the new implementation.
   saved_is_logging_ = logger->is_logging_;
   logger->is_logging_ = false;
   generator_.reset(new ProfileGenerator(profiles_.get()));
   processor_.reset(new ProfilerEventsProcessor(isolate_, generator_.get(),
                                                sampling_interval_));
   CreateEntriesForRuntimeCallStats();
   logger->SetUpProfilerListener();
   ProfilerListener* profiler_listener = logger->profiler_listener();
   profiler_listener->AddObserver(this);
   is_profiling_ = true;
   isolate_->set_is_profiling(true);
   // Enumerate stuff we already have in the heap.
   DCHECK(isolate_->heap()->HasBeenSetUp());
   if (!FLAG_prof_browser_mode) {
     logger->LogCodeObjects();
   }
   logger->LogCompiledFunctions();
   logger->LogAccessorCallbacks();
   LogBuiltins();
   // Enable stack sampling.
   processor_->AddCurrentStack(isolate_);
   processor_->StartSynchronously();
 }

 CpuProfile* CpuProfiler::StopProfiling(const char* title) {
   if (!is_profiling_) return nullptr;
   StopProcessorIfLastProfile(title);
   return profiles_->StopProfiling(title);
 }

 CpuProfile* CpuProfiler::StopProfiling(String* title) {
   return StopProfiling(profiles_->GetName(title));
 }

 void CpuProfiler::StopProcessorIfLastProfile(const char* title) {
   if (!profiles_->IsLastProfile(title)) return;
   StopProcessor();
 }

 void CpuProfiler::StopProcessor() {
   Logger* logger = isolate_->logger();
   is_profiling_ = false;
   isolate_->set_is_profiling(false);
   ProfilerListener* profiler_listener = logger->profiler_listener();
   profiler_listener->RemoveObserver(this);
   processor_->StopSynchronously();
   logger->TearDownProfilerListener();
   processor_.reset();
   generator_.reset();
   logger->is_logging_ = saved_is_logging_;
 }


 void CpuProfiler::LogBuiltins() {
   Builtins* builtins = isolate_->builtins();
   DCHECK(builtins->is_initialized());
   for (int i = 0; i < Builtins::builtin_count; i++) {
     CodeEventsContainer evt_rec(CodeEventRecord::REPORT_BUILTIN);
     ReportBuiltinEventRecord* rec = &evt_rec.ReportBuiltinEventRecord_;
     Builtins::Name id = static_cast<Builtins::Name>(i);
     rec->start = builtins->builtin(id)->address();
     rec->builtin_id = id;
     processor_->Enqueue(evt_rec);
   }
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2012 the V8 project 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 "src/profiler/cpu-profiler.h"

	#include "src/base/lazy-instance.h"
	#include "src/base/platform/mutex.h"
	#include "src/base/template-utils.h"
	#include "src/debug/debug.h"
	#include "src/deoptimizer.h"
	#include "src/frames-inl.h"
	#include "src/locked-queue-inl.h"
	#include "src/log-inl.h"
	#include "src/profiler/cpu-profiler-inl.h"
	#include "src/vm-state-inl.h"

	namespace v8 {
	namespace internal {

	static const int kProfilerStackSize = 64 * KB;

	class CpuSampler : public sampler::Sampler {
	public:
	CpuSampler(Isolate* isolate, ProfilerEventsProcessor* processor)
	: sampler::Sampler(reinterpret_cast<v8::Isolate*>(isolate)),
	processor_(processor) {}

	void SampleStack(const v8::RegisterState& regs) override {
	TickSample* sample = processor_->StartTickSample();
	if (sample == nullptr) return;
	Isolate* isolate = reinterpret_cast<Isolate*>(this->isolate());
	sample->Init(isolate, regs, TickSample::kIncludeCEntryFrame, true);
	if (is_counting_samples_ && !sample->timestamp.IsNull()) {
	if (sample->state == JS) ++js_sample_count_;
	if (sample->state == EXTERNAL) ++external_sample_count_;
	}
	processor_->FinishTickSample();
	}

	private:
	ProfilerEventsProcessor* processor_;
	};

	ProfilerEventsProcessor::ProfilerEventsProcessor(Isolate* isolate,
	ProfileGenerator* generator,
	base::TimeDelta period)
	: Thread(Thread::Options("v8:ProfEvntProc", kProfilerStackSize)),
	generator_(generator),
	sampler_(new CpuSampler(isolate, this)),
	running_(1),
	period_(period),
	last_code_event_id_(0),
	last_processed_code_event_id_(0) {
	sampler_->IncreaseProfilingDepth();
	}

	ProfilerEventsProcessor::~ProfilerEventsProcessor() {
	sampler_->DecreaseProfilingDepth();
	}

	void ProfilerEventsProcessor::Enqueue(const CodeEventsContainer& event) {
	event.generic.order = last_code_event_id_.Increment(1);
	events_buffer_.Enqueue(event);
	}


	void ProfilerEventsProcessor::AddDeoptStack(Isolate* isolate, Address from,
	int fp_to_sp_delta) {
	TickSampleEventRecord record(last_code_event_id_.Value());
	RegisterState regs;
	Address fp = isolate->c_entry_fp(isolate->thread_local_top());
	regs.sp = fp - fp_to_sp_delta;
	regs.fp = fp;
	regs.pc = from;
	record.sample.Init(isolate, regs, TickSample::kSkipCEntryFrame, false, false);
	ticks_from_vm_buffer_.Enqueue(record);
	}

	void ProfilerEventsProcessor::AddCurrentStack(Isolate* isolate,
	bool update_stats) {
	TickSampleEventRecord record(last_code_event_id_.Value());
	RegisterState regs;
	StackFrameIterator it(isolate);
	if (!it.done()) {
	StackFrame* frame = it.frame();
	regs.sp = frame->sp();
	regs.fp = frame->fp();
	regs.pc = frame->pc();
	}
	record.sample.Init(isolate, regs, TickSample::kSkipCEntryFrame, update_stats,
	false);
	ticks_from_vm_buffer_.Enqueue(record);
	}


	void ProfilerEventsProcessor::StopSynchronously() {
	if (!base::Relaxed_AtomicExchange(&running_, 0)) return;
	Join();
	}


	bool ProfilerEventsProcessor::ProcessCodeEvent() {
	CodeEventsContainer record;
	if (events_buffer_.Dequeue(&record)) {
	switch (record.generic.type) {
	#define PROFILER_TYPE_CASE(type, clss) \
	case CodeEventRecord::type: \
	record.clss##_.UpdateCodeMap(generator_->code_map()); \
	break;

	CODE_EVENTS_TYPE_LIST(PROFILER_TYPE_CASE)

	#undef PROFILER_TYPE_CASE
	default: return true; // Skip record.
	}
	last_processed_code_event_id_ = record.generic.order;
	return true;
	}
	return false;
	}

	ProfilerEventsProcessor::SampleProcessingResult
	ProfilerEventsProcessor::ProcessOneSample() {
	TickSampleEventRecord record1;
	if (ticks_from_vm_buffer_.Peek(&record1) &&
	(record1.order == last_processed_code_event_id_)) {
	TickSampleEventRecord record;
	ticks_from_vm_buffer_.Dequeue(&record);
	generator_->RecordTickSample(record.sample);
	return OneSampleProcessed;
	}

	const TickSampleEventRecord* record = ticks_buffer_.Peek();
	if (record == nullptr) {
	if (ticks_from_vm_buffer_.IsEmpty()) return NoSamplesInQueue;
	return FoundSampleForNextCodeEvent;
	}
	if (record->order != last_processed_code_event_id_) {
	return FoundSampleForNextCodeEvent;
	}
	generator_->RecordTickSample(record->sample);
	ticks_buffer_.Remove();
	return OneSampleProcessed;
	}


	void ProfilerEventsProcessor::Run() {
	while (!!base::Relaxed_Load(&running_)) {
	base::TimeTicks nextSampleTime =
	base::TimeTicks::HighResolutionNow() + period_;
	base::TimeTicks now;
	SampleProcessingResult result;
	// Keep processing existing events until we need to do next sample
	// or the ticks buffer is empty.
	do {
	result = ProcessOneSample();
	if (result == FoundSampleForNextCodeEvent) {
	// All ticks of the current last_processed_code_event_id_ are
	// processed, proceed to the next code event.
	ProcessCodeEvent();
	}
	now = base::TimeTicks::HighResolutionNow();
	} while (result != NoSamplesInQueue && now < nextSampleTime);

	if (nextSampleTime > now) {
	#if V8_OS_WIN
	// Do not use Sleep on Windows as it is very imprecise.
	// Could be up to 16ms jitter, which is unacceptable for the purpose.
	while (base::TimeTicks::HighResolutionNow() < nextSampleTime) {
	}
	#else
	base::OS::Sleep(nextSampleTime - now);
	#endif
	}

	// Schedule next sample. sampler_ is nullptr in tests.
	if (sampler_) sampler_->DoSample();
	}

	// Process remaining tick events.
	do {
	SampleProcessingResult result;
	do {
	result = ProcessOneSample();
	} while (result == OneSampleProcessed);
	} while (ProcessCodeEvent());
	}


	void* ProfilerEventsProcessor::operator new(size_t size) {
	return AlignedAlloc(size, V8_ALIGNOF(ProfilerEventsProcessor));
	}


	void ProfilerEventsProcessor::operator delete(void* ptr) {
	AlignedFree(ptr);
	}


	int CpuProfiler::GetProfilesCount() {
	// The count of profiles doesn't depend on a security token.
	return static_cast<int>(profiles_->profiles()->size());
	}


	CpuProfile* CpuProfiler::GetProfile(int index) {
	return profiles_->profiles()->at(index);
	}


	void CpuProfiler::DeleteAllProfiles() {
	if (is_profiling_) StopProcessor();
	ResetProfiles();
	}


	void CpuProfiler::DeleteProfile(CpuProfile* profile) {
	profiles_->RemoveProfile(profile);
	delete profile;
	if (profiles_->profiles()->empty() && !is_profiling_) {
	// If this was the last profile, clean up all accessory data as well.
	ResetProfiles();
	}
	}

	void CpuProfiler::CodeEventHandler(const CodeEventsContainer& evt_rec) {
	switch (evt_rec.generic.type) {
	case CodeEventRecord::CODE_CREATION:
	case CodeEventRecord::CODE_MOVE:
	case CodeEventRecord::CODE_DISABLE_OPT:
	processor_->Enqueue(evt_rec);
	break;
	case CodeEventRecord::CODE_DEOPT: {
	const CodeDeoptEventRecord* rec = &evt_rec.CodeDeoptEventRecord_;
	Address pc = reinterpret_cast<Address>(rec->pc);
	int fp_to_sp_delta = rec->fp_to_sp_delta;
	processor_->Enqueue(evt_rec);
	processor_->AddDeoptStack(isolate_, pc, fp_to_sp_delta);
	break;
	}
	default:
	UNREACHABLE();
	}
	}

	namespace {

	class CpuProfilersManager {
	public:
	void AddProfiler(Isolate* isolate, CpuProfiler* profiler) {
	base::LockGuard<base::Mutex> lock(&mutex_);
	auto result = profilers_.insert(
	std::pair<Isolate, std::unique_ptr<std::set<CpuProfiler>>>(
	isolate, base::make_unique<std::set<CpuProfiler*>>()));
	result.first->second->insert(profiler);
	}

	void RemoveProfiler(Isolate* isolate, CpuProfiler* profiler) {
	base::LockGuard<base::Mutex> lock(&mutex_);
	auto it = profilers_.find(isolate);
	DCHECK(it != profilers_.end());
	it->second->erase(profiler);
	if (it->second->empty()) {
	profilers_.erase(it);
	}
	}

	void CallCollectSample(Isolate* isolate) {
	base::LockGuard<base::Mutex> lock(&mutex_);
	auto profilers = profilers_.find(isolate);
	if (profilers == profilers_.end()) return;
	for (auto it : *profilers->second) {
	it->CollectSample();
	}
	}

	private:
	std::map<Isolate, std::unique_ptr<std::set<CpuProfiler>>> profilers_;
	base::Mutex mutex_;
	};

	base::LazyInstance<CpuProfilersManager>::type g_profilers_manager =
	LAZY_INSTANCE_INITIALIZER;

	} // namespace

	CpuProfiler::CpuProfiler(Isolate* isolate)
	: CpuProfiler(isolate, new CpuProfilesCollection(isolate), nullptr,
	nullptr) {}

	CpuProfiler::CpuProfiler(Isolate* isolate, CpuProfilesCollection* test_profiles,
	ProfileGenerator* test_generator,
	ProfilerEventsProcessor* test_processor)
	: isolate_(isolate),
	sampling_interval_(base::TimeDelta::FromMicroseconds(
	FLAG_cpu_profiler_sampling_interval)),
	profiles_(test_profiles),
	generator_(test_generator),
	processor_(test_processor),
	is_profiling_(false) {
	profiles_->set_cpu_profiler(this);
	g_profilers_manager.Pointer()->AddProfiler(isolate, this);
	}

	CpuProfiler::~CpuProfiler() {
	DCHECK(!is_profiling_);
	g_profilers_manager.Pointer()->RemoveProfiler(isolate_, this);
	}

	void CpuProfiler::set_sampling_interval(base::TimeDelta value) {
	DCHECK(!is_profiling_);
	sampling_interval_ = value;
	}

	void CpuProfiler::ResetProfiles() {
	profiles_.reset(new CpuProfilesCollection(isolate_));
	profiles_->set_cpu_profiler(this);
	}

	void CpuProfiler::CreateEntriesForRuntimeCallStats() {
	static_entries_.clear();
	RuntimeCallStats* rcs = isolate_->counters()->runtime_call_stats();
	CodeMap* code_map = generator_->code_map();
	for (int i = 0; i < RuntimeCallStats::kNumberOfCounters; ++i) {
	RuntimeCallCounter* counter = rcs->GetCounter(i);
	DCHECK(counter->name());
	std::unique_ptr<CodeEntry> entry(
	new CodeEntry(CodeEventListener::FUNCTION_TAG, counter->name(),
	CodeEntry::kEmptyNamePrefix, "native V8Runtime"));
	code_map->AddCode(reinterpret_cast<Address>(counter), entry.get(), 1);
	static_entries_.push_back(std::move(entry));
	}
	}

	// static
	void CpuProfiler::CollectSample(Isolate* isolate) {
	g_profilers_manager.Pointer()->CallCollectSample(isolate);
	}

	void CpuProfiler::CollectSample() {
	if (processor_) {
	processor_->AddCurrentStack(isolate_);
	}
	}

	void CpuProfiler::StartProfiling(const char* title, bool record_samples) {
	if (profiles_->StartProfiling(title, record_samples)) {
	TRACE_EVENT0("v8", "CpuProfiler::StartProfiling");
	StartProcessorIfNotStarted();
	}
	}


	void CpuProfiler::StartProfiling(String* title, bool record_samples) {
	StartProfiling(profiles_->GetName(title), record_samples);
	isolate_->debug()->feature_tracker()->Track(DebugFeatureTracker::kProfiler);
	}


	void CpuProfiler::StartProcessorIfNotStarted() {
	if (processor_) {
	processor_->AddCurrentStack(isolate_);
	return;
	}
	Logger* logger = isolate_->logger();
	// Disable logging when using the new implementation.
	saved_is_logging_ = logger->is_logging_;
	logger->is_logging_ = false;
	generator_.reset(new ProfileGenerator(profiles_.get()));
	processor_.reset(new ProfilerEventsProcessor(isolate_, generator_.get(),
	sampling_interval_));
	CreateEntriesForRuntimeCallStats();
	logger->SetUpProfilerListener();
	ProfilerListener* profiler_listener = logger->profiler_listener();
	profiler_listener->AddObserver(this);
	is_profiling_ = true;
	isolate_->set_is_profiling(true);
	// Enumerate stuff we already have in the heap.
	DCHECK(isolate_->heap()->HasBeenSetUp());
	if (!FLAG_prof_browser_mode) {
	logger->LogCodeObjects();
	}
	logger->LogCompiledFunctions();
	logger->LogAccessorCallbacks();
	LogBuiltins();
	// Enable stack sampling.
	processor_->AddCurrentStack(isolate_);
	processor_->StartSynchronously();
	}

	CpuProfile* CpuProfiler::StopProfiling(const char* title) {
	if (!is_profiling_) return nullptr;
	StopProcessorIfLastProfile(title);
	return profiles_->StopProfiling(title);
	}

	CpuProfile* CpuProfiler::StopProfiling(String* title) {
	return StopProfiling(profiles_->GetName(title));
	}

	void CpuProfiler::StopProcessorIfLastProfile(const char* title) {
	if (!profiles_->IsLastProfile(title)) return;
	StopProcessor();
	}

	void CpuProfiler::StopProcessor() {
	Logger* logger = isolate_->logger();
	is_profiling_ = false;
	isolate_->set_is_profiling(false);
	ProfilerListener* profiler_listener = logger->profiler_listener();
	profiler_listener->RemoveObserver(this);
	processor_->StopSynchronously();
	logger->TearDownProfilerListener();
	processor_.reset();
	generator_.reset();
	logger->is_logging_ = saved_is_logging_;
	}


	void CpuProfiler::LogBuiltins() {
	Builtins* builtins = isolate_->builtins();
	DCHECK(builtins->is_initialized());
	for (int i = 0; i < Builtins::builtin_count; i++) {
	CodeEventsContainer evt_rec(CodeEventRecord::REPORT_BUILTIN);
	ReportBuiltinEventRecord* rec = &evt_rec.ReportBuiltinEventRecord_;
	Builtins::Name id = static_cast<Builtins::Name>(i);
	rec->start = builtins->builtin(id)->address();
	rec->builtin_id = id;
	processor_->Enqueue(evt_rec);
	}
	}

	} // namespace internal
	} // namespace v8