// 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 #include #include "src/base/lazy-instance.h" #include "src/base/template-utils.h" #include "src/debug/debug.h" #include "src/execution/frames-inl.h" #include "src/execution/vm-state-inl.h" #include "src/logging/counters.h" #include "src/logging/log.h" #include "src/profiler/cpu-profiler-inl.h" #include "src/utils/locked-queue-inl.h" #include "src/wasm/wasm-engine.h" namespace v8 { namespace internal { static const int kProfilerStackSize = 64 * KB; class CpuSampler : public sampler::Sampler { public: CpuSampler(Isolate* isolate, SamplingEventsProcessor* processor) : sampler::Sampler(reinterpret_cast(isolate)), processor_(processor) {} void SampleStack(const v8::RegisterState& regs) override { TickSample* sample = processor_->StartTickSample(); if (sample == nullptr) return; Isolate* isolate = reinterpret_cast(this->isolate()); sample->Init(isolate, regs, TickSample::kIncludeCEntryFrame, /* update_stats */ true, /* use_simulator_reg_state */ true, processor_->period()); if (is_counting_samples_ && !sample->timestamp.IsNull()) { if (sample->state == JS) ++js_sample_count_; if (sample->state == EXTERNAL) ++external_sample_count_; } processor_->FinishTickSample(); } private: SamplingEventsProcessor* processor_; }; ProfilingScope::ProfilingScope(Isolate* isolate, ProfilerListener* listener) : isolate_(isolate), listener_(listener) { size_t profiler_count = isolate_->num_cpu_profilers(); profiler_count++; isolate_->set_num_cpu_profilers(profiler_count); isolate_->set_is_profiling(true); isolate_->wasm_engine()->EnableCodeLogging(isolate_); Logger* logger = isolate_->logger(); logger->AddCodeEventListener(listener_); // Populate the ProfilerCodeObserver with the initial functions and // callbacks on the heap. DCHECK(isolate_->heap()->HasBeenSetUp()); if (!FLAG_prof_browser_mode) { logger->LogCodeObjects(); } logger->LogCompiledFunctions(); logger->LogAccessorCallbacks(); } ProfilingScope::~ProfilingScope() { isolate_->logger()->RemoveCodeEventListener(listener_); size_t profiler_count = isolate_->num_cpu_profilers(); DCHECK_GT(profiler_count, 0); profiler_count--; isolate_->set_num_cpu_profilers(profiler_count); if (profiler_count == 0) isolate_->set_is_profiling(false); } ProfilerEventsProcessor::ProfilerEventsProcessor( Isolate* isolate, ProfileGenerator* generator, ProfilerCodeObserver* code_observer) : Thread(Thread::Options("v8:ProfEvntProc", kProfilerStackSize)), generator_(generator), code_observer_(code_observer), running_(1), last_code_event_id_(0), last_processed_code_event_id_(0), isolate_(isolate) { DCHECK(!code_observer_->processor()); code_observer_->set_processor(this); } SamplingEventsProcessor::SamplingEventsProcessor( Isolate* isolate, ProfileGenerator* generator, ProfilerCodeObserver* code_observer, base::TimeDelta period, bool use_precise_sampling) : ProfilerEventsProcessor(isolate, generator, code_observer), sampler_(new CpuSampler(isolate, this)), period_(period), use_precise_sampling_(use_precise_sampling) { sampler_->Start(); } SamplingEventsProcessor::~SamplingEventsProcessor() { sampler_->Stop(); } ProfilerEventsProcessor::~ProfilerEventsProcessor() { DCHECK_EQ(code_observer_->processor(), this); code_observer_->clear_processor(); } void ProfilerEventsProcessor::Enqueue(const CodeEventsContainer& event) { event.generic.order = ++last_code_event_id_; events_buffer_.Enqueue(event); } void ProfilerEventsProcessor::AddDeoptStack(Address from, int fp_to_sp_delta) { TickSampleEventRecord record(last_code_event_id_); RegisterState regs; Address fp = isolate_->c_entry_fp(isolate_->thread_local_top()); regs.sp = reinterpret_cast(fp - fp_to_sp_delta); regs.fp = reinterpret_cast(fp); regs.pc = reinterpret_cast(from); record.sample.Init(isolate_, regs, TickSample::kSkipCEntryFrame, false, false); ticks_from_vm_buffer_.Enqueue(record); } void ProfilerEventsProcessor::AddCurrentStack(bool update_stats) { TickSampleEventRecord record(last_code_event_id_); RegisterState regs; StackFrameIterator it(isolate_); if (!it.done()) { StackFrame* frame = it.frame(); regs.sp = reinterpret_cast(frame->sp()); regs.fp = reinterpret_cast(frame->fp()); regs.pc = reinterpret_cast(frame->pc()); } record.sample.Init(isolate_, regs, TickSample::kSkipCEntryFrame, update_stats, false); ticks_from_vm_buffer_.Enqueue(record); } void ProfilerEventsProcessor::AddSample(TickSample sample) { TickSampleEventRecord record(last_code_event_id_); record.sample = sample; ticks_from_vm_buffer_.Enqueue(record); } void ProfilerEventsProcessor::StopSynchronously() { if (!base::Relaxed_AtomicExchange(&running_, 0)) return; { base::MutexGuard guard(&running_mutex_); running_cond_.NotifyOne(); } Join(); } bool ProfilerEventsProcessor::ProcessCodeEvent() { CodeEventsContainer record; if (events_buffer_.Dequeue(&record)) { if (record.generic.type == CodeEventRecord::NATIVE_CONTEXT_MOVE) { NativeContextMoveEventRecord& nc_record = record.NativeContextMoveEventRecord_; generator_->UpdateNativeContextAddress(nc_record.from_address, nc_record.to_address); } else { code_observer_->CodeEventHandlerInternal(record); } last_processed_code_event_id_ = record.generic.order; return true; } return false; } void ProfilerEventsProcessor::CodeEventHandler( const CodeEventsContainer& evt_rec) { switch (evt_rec.generic.type) { case CodeEventRecord::CODE_CREATION: case CodeEventRecord::CODE_MOVE: case CodeEventRecord::CODE_DISABLE_OPT: case CodeEventRecord::NATIVE_CONTEXT_MOVE: Enqueue(evt_rec); break; case CodeEventRecord::CODE_DEOPT: { const CodeDeoptEventRecord* rec = &evt_rec.CodeDeoptEventRecord_; Address pc = rec->pc; int fp_to_sp_delta = rec->fp_to_sp_delta; Enqueue(evt_rec); AddDeoptStack(pc, fp_to_sp_delta); break; } case CodeEventRecord::NONE: case CodeEventRecord::REPORT_BUILTIN: UNREACHABLE(); } } ProfilerEventsProcessor::SampleProcessingResult SamplingEventsProcessor::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 SamplingEventsProcessor::Run() { base::MutexGuard guard(&running_mutex_); 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 if (use_precise_sampling_ && nextSampleTime - now < base::TimeDelta::FromMilliseconds(100)) { // Do not use Sleep on Windows as it is very imprecise, with up to 16ms // jitter, which is unacceptable for short profile intervals. while (base::TimeTicks::HighResolutionNow() < nextSampleTime) { } } else // NOLINT #else USE(use_precise_sampling_); #endif // V8_OS_WIN { // Allow another thread to interrupt the delay between samples in the // event of profiler shutdown. while (now < nextSampleTime && running_cond_.WaitFor(&running_mutex_, nextSampleTime - now)) { // If true was returned, we got interrupted before the timeout // elapsed. If this was not due to a change in running state, a // spurious wakeup occurred (thus we should continue to wait). if (!base::Relaxed_Load(&running_)) { break; } now = base::TimeTicks::HighResolutionNow(); } } } // Schedule next sample. sampler_->DoSample(); } // Process remaining tick events. do { SampleProcessingResult result; do { result = ProcessOneSample(); } while (result == OneSampleProcessed); } while (ProcessCodeEvent()); } void SamplingEventsProcessor::SetSamplingInterval(base::TimeDelta period) { if (period_ == period) return; StopSynchronously(); period_ = period; base::Relaxed_Store(&running_, 1); StartSynchronously(); } void* SamplingEventsProcessor::operator new(size_t size) { return AlignedAlloc(size, alignof(SamplingEventsProcessor)); } void SamplingEventsProcessor::operator delete(void* ptr) { AlignedFree(ptr); } ProfilerCodeObserver::ProfilerCodeObserver(Isolate* isolate) : isolate_(isolate), processor_(nullptr) { CreateEntriesForRuntimeCallStats(); LogBuiltins(); } void ProfilerCodeObserver::CodeEventHandler( const CodeEventsContainer& evt_rec) { if (processor_) { processor_->CodeEventHandler(evt_rec); return; } CodeEventHandlerInternal(evt_rec); } void ProfilerCodeObserver::CodeEventHandlerInternal( const CodeEventsContainer& evt_rec) { CodeEventsContainer record = evt_rec; switch (evt_rec.generic.type) { #define PROFILER_TYPE_CASE(type, clss) \ case CodeEventRecord::type: \ record.clss##_.UpdateCodeMap(&code_map_); \ break; CODE_EVENTS_TYPE_LIST(PROFILER_TYPE_CASE) #undef PROFILER_TYPE_CASE default: break; } } void ProfilerCodeObserver::CreateEntriesForRuntimeCallStats() { RuntimeCallStats* rcs = isolate_->counters()->runtime_call_stats(); for (int i = 0; i < RuntimeCallStats::kNumberOfCounters; ++i) { RuntimeCallCounter* counter = rcs->GetCounter(i); DCHECK(counter->name()); auto entry = new CodeEntry(CodeEventListener::FUNCTION_TAG, counter->name(), "native V8Runtime"); code_map_.AddCode(reinterpret_cast
(counter), entry, 1); } } void ProfilerCodeObserver::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(i); rec->instruction_start = builtins->builtin(id).InstructionStart(); rec->builtin_id = id; CodeEventHandlerInternal(evt_rec); } } int CpuProfiler::GetProfilesCount() { // The count of profiles doesn't depend on a security token. return static_cast(profiles_->profiles()->size()); } CpuProfile* CpuProfiler::GetProfile(int index) { return profiles_->profiles()->at(index).get(); } void CpuProfiler::DeleteAllProfiles() { if (is_profiling_) StopProcessor(); ResetProfiles(); } void CpuProfiler::DeleteProfile(CpuProfile* profile) { profiles_->RemoveProfile(profile); if (profiles_->profiles()->empty() && !is_profiling_) { // If this was the last profile, clean up all accessory data as well. ResetProfiles(); } } namespace { class CpuProfilersManager { public: void AddProfiler(Isolate* isolate, CpuProfiler* profiler) { base::MutexGuard lock(&mutex_); profilers_.emplace(isolate, profiler); } void RemoveProfiler(Isolate* isolate, CpuProfiler* profiler) { base::MutexGuard lock(&mutex_); auto range = profilers_.equal_range(isolate); for (auto it = range.first; it != range.second; ++it) { if (it->second != profiler) continue; profilers_.erase(it); return; } UNREACHABLE(); } void CallCollectSample(Isolate* isolate) { base::MutexGuard lock(&mutex_); auto range = profilers_.equal_range(isolate); for (auto it = range.first; it != range.second; ++it) { it->second->CollectSample(); } } private: std::unordered_multimap profilers_; base::Mutex mutex_; }; DEFINE_LAZY_LEAKY_OBJECT_GETTER(CpuProfilersManager, GetProfilersManager) } // namespace CpuProfiler::CpuProfiler(Isolate* isolate, CpuProfilingNamingMode naming_mode, CpuProfilingLoggingMode logging_mode) : CpuProfiler(isolate, naming_mode, logging_mode, new CpuProfilesCollection(isolate), nullptr, nullptr) {} CpuProfiler::CpuProfiler(Isolate* isolate, CpuProfilingNamingMode naming_mode, CpuProfilingLoggingMode logging_mode, CpuProfilesCollection* test_profiles, ProfileGenerator* test_generator, ProfilerEventsProcessor* test_processor) : isolate_(isolate), naming_mode_(naming_mode), logging_mode_(logging_mode), base_sampling_interval_(base::TimeDelta::FromMicroseconds( FLAG_cpu_profiler_sampling_interval)), profiles_(test_profiles), generator_(test_generator), processor_(test_processor), code_observer_(isolate), is_profiling_(false) { profiles_->set_cpu_profiler(this); GetProfilersManager()->AddProfiler(isolate, this); if (logging_mode == kEagerLogging) EnableLogging(); } CpuProfiler::~CpuProfiler() { DCHECK(!is_profiling_); GetProfilersManager()->RemoveProfiler(isolate_, this); DisableLogging(); } void CpuProfiler::set_sampling_interval(base::TimeDelta value) { DCHECK(!is_profiling_); base_sampling_interval_ = value; } void CpuProfiler::set_use_precise_sampling(bool value) { DCHECK(!is_profiling_); use_precise_sampling_ = value; } void CpuProfiler::ResetProfiles() { profiles_.reset(new CpuProfilesCollection(isolate_)); profiles_->set_cpu_profiler(this); generator_.reset(); if (!profiling_scope_) profiler_listener_.reset(); } void CpuProfiler::EnableLogging() { if (profiling_scope_) return; if (!profiler_listener_) { profiler_listener_.reset( new ProfilerListener(isolate_, &code_observer_, naming_mode_)); } profiling_scope_.reset( new ProfilingScope(isolate_, profiler_listener_.get())); } void CpuProfiler::DisableLogging() { if (!profiling_scope_) return; DCHECK(profiler_listener_); profiling_scope_.reset(); } base::TimeDelta CpuProfiler::ComputeSamplingInterval() const { return profiles_->GetCommonSamplingInterval(); } void CpuProfiler::AdjustSamplingInterval() { if (!processor_) return; base::TimeDelta base_interval = ComputeSamplingInterval(); processor_->SetSamplingInterval(base_interval); } // static void CpuProfiler::CollectSample(Isolate* isolate) { GetProfilersManager()->CallCollectSample(isolate); } void CpuProfiler::CollectSample() { if (processor_) { processor_->AddCurrentStack(); } } void CpuProfiler::StartProfiling(const char* title, CpuProfilingOptions options) { if (profiles_->StartProfiling(title, options)) { TRACE_EVENT0("v8", "CpuProfiler::StartProfiling"); AdjustSamplingInterval(); StartProcessorIfNotStarted(); } } void CpuProfiler::StartProfiling(String title, CpuProfilingOptions options) { StartProfiling(profiles_->GetName(title), options); } void CpuProfiler::StartProcessorIfNotStarted() { if (processor_) { processor_->AddCurrentStack(); return; } if (!profiling_scope_) { DCHECK_EQ(logging_mode_, kLazyLogging); EnableLogging(); } if (!generator_) { generator_.reset( new ProfileGenerator(profiles_.get(), code_observer_.code_map())); } base::TimeDelta sampling_interval = ComputeSamplingInterval(); processor_.reset( new SamplingEventsProcessor(isolate_, generator_.get(), &code_observer_, sampling_interval, use_precise_sampling_)); is_profiling_ = true; // Enable stack sampling. processor_->AddCurrentStack(); processor_->StartSynchronously(); } CpuProfile* CpuProfiler::StopProfiling(const char* title) { if (!is_profiling_) return nullptr; StopProcessorIfLastProfile(title); CpuProfile* result = profiles_->StopProfiling(title); AdjustSamplingInterval(); return result; } 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() { is_profiling_ = false; processor_->StopSynchronously(); processor_.reset(); DCHECK(profiling_scope_); if (logging_mode_ == kLazyLogging) { DisableLogging(); } } } // namespace internal } // namespace v8