// Copyright 2014 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. #ifndef V8_HEAP_GC_TRACER_H_ #define V8_HEAP_GC_TRACER_H_ #include "src/base/compiler-specific.h" #include "src/base/platform/platform.h" #include "src/base/ring-buffer.h" #include "src/common/globals.h" #include "src/heap/heap.h" #include "src/init/heap-symbols.h" #include "src/logging/counters.h" #include "testing/gtest/include/gtest/gtest_prod.h" // nogncheck namespace v8 { namespace internal { using BytesAndDuration = std::pair; inline BytesAndDuration MakeBytesAndDuration(uint64_t bytes, double duration) { return std::make_pair(bytes, duration); } enum ScavengeSpeedMode { kForAllObjects, kForSurvivedObjects }; #define TRACE_GC(tracer, scope_id) \ GCTracer::Scope::ScopeId gc_tracer_scope_id(scope_id); \ GCTracer::Scope gc_tracer_scope(tracer, gc_tracer_scope_id); \ TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.gc"), \ GCTracer::Scope::Name(gc_tracer_scope_id)) #define TRACE_BACKGROUND_GC(tracer, scope_id) \ WorkerThreadRuntimeCallStatsScope runtime_call_stats_scope( \ tracer->worker_thread_runtime_call_stats()); \ GCTracer::BackgroundScope background_scope(tracer, scope_id, \ runtime_call_stats_scope.Get()); \ TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.gc"), \ GCTracer::BackgroundScope::Name(scope_id)) // GCTracer collects and prints ONE line after each garbage collector // invocation IFF --trace_gc is used. class V8_EXPORT_PRIVATE GCTracer { public: struct IncrementalMarkingInfos { IncrementalMarkingInfos() : duration(0), longest_step(0), steps(0) {} void Update(double duration) { steps++; this->duration += duration; if (duration > longest_step) { longest_step = duration; } } void ResetCurrentCycle() { duration = 0; longest_step = 0; steps = 0; } double duration; double longest_step; int steps; }; class Scope { public: enum ScopeId { #define DEFINE_SCOPE(scope) scope, TRACER_SCOPES(DEFINE_SCOPE) TRACER_BACKGROUND_SCOPES(DEFINE_SCOPE) #undef DEFINE_SCOPE NUMBER_OF_SCOPES, FIRST_INCREMENTAL_SCOPE = MC_INCREMENTAL, LAST_INCREMENTAL_SCOPE = MC_INCREMENTAL_SWEEPING, FIRST_SCOPE = MC_INCREMENTAL, NUMBER_OF_INCREMENTAL_SCOPES = LAST_INCREMENTAL_SCOPE - FIRST_INCREMENTAL_SCOPE + 1, FIRST_GENERAL_BACKGROUND_SCOPE = BACKGROUND_ARRAY_BUFFER_FREE, LAST_GENERAL_BACKGROUND_SCOPE = BACKGROUND_UNMAPPER, FIRST_MC_BACKGROUND_SCOPE = MC_BACKGROUND_EVACUATE_COPY, LAST_MC_BACKGROUND_SCOPE = MC_BACKGROUND_SWEEPING, FIRST_TOP_MC_SCOPE = MC_CLEAR, LAST_TOP_MC_SCOPE = MC_SWEEP, FIRST_MINOR_GC_BACKGROUND_SCOPE = MINOR_MC_BACKGROUND_EVACUATE_COPY, LAST_MINOR_GC_BACKGROUND_SCOPE = SCAVENGER_BACKGROUND_SCAVENGE_PARALLEL, FIRST_BACKGROUND_SCOPE = FIRST_GENERAL_BACKGROUND_SCOPE }; Scope(GCTracer* tracer, ScopeId scope); ~Scope(); static const char* Name(ScopeId id); private: GCTracer* tracer_; ScopeId scope_; double start_time_; RuntimeCallTimer timer_; RuntimeCallStats* runtime_stats_ = nullptr; DISALLOW_COPY_AND_ASSIGN(Scope); }; class V8_EXPORT_PRIVATE BackgroundScope { public: enum ScopeId { #define DEFINE_SCOPE(scope) scope, TRACER_BACKGROUND_SCOPES(DEFINE_SCOPE) #undef DEFINE_SCOPE NUMBER_OF_SCOPES, FIRST_GENERAL_BACKGROUND_SCOPE = BACKGROUND_ARRAY_BUFFER_FREE, LAST_GENERAL_BACKGROUND_SCOPE = BACKGROUND_UNMAPPER, FIRST_MC_BACKGROUND_SCOPE = MC_BACKGROUND_EVACUATE_COPY, LAST_MC_BACKGROUND_SCOPE = MC_BACKGROUND_SWEEPING, FIRST_MINOR_GC_BACKGROUND_SCOPE = MINOR_MC_BACKGROUND_EVACUATE_COPY, LAST_MINOR_GC_BACKGROUND_SCOPE = SCAVENGER_BACKGROUND_SCAVENGE_PARALLEL }; BackgroundScope(GCTracer* tracer, ScopeId scope, RuntimeCallStats* runtime_stats); ~BackgroundScope(); static const char* Name(ScopeId id); private: GCTracer* tracer_; ScopeId scope_; double start_time_; RuntimeCallTimer timer_; RuntimeCallStats* runtime_stats_; DISALLOW_COPY_AND_ASSIGN(BackgroundScope); }; class Event { public: enum Type { SCAVENGER = 0, MARK_COMPACTOR = 1, INCREMENTAL_MARK_COMPACTOR = 2, MINOR_MARK_COMPACTOR = 3, START = 4 }; Event(Type type, GarbageCollectionReason gc_reason, const char* collector_reason); // Returns a string describing the event type. const char* TypeName(bool short_name) const; // Type of event Type type; GarbageCollectionReason gc_reason; const char* collector_reason; // Timestamp set in the constructor. double start_time; // Timestamp set in the destructor. double end_time; // Memory reduction flag set. bool reduce_memory; // Size of objects in heap set in constructor. size_t start_object_size; // Size of objects in heap set in destructor. size_t end_object_size; // Size of memory allocated from OS set in constructor. size_t start_memory_size; // Size of memory allocated from OS set in destructor. size_t end_memory_size; // Total amount of space either wasted or contained in one of free lists // before the current GC. size_t start_holes_size; // Total amount of space either wasted or contained in one of free lists // after the current GC. size_t end_holes_size; // Size of young objects in constructor. size_t young_object_size; // Size of survived young objects in destructor. size_t survived_young_object_size; // Bytes marked incrementally for INCREMENTAL_MARK_COMPACTOR size_t incremental_marking_bytes; // Duration of incremental marking steps for INCREMENTAL_MARK_COMPACTOR. double incremental_marking_duration; // Amounts of time spent in different scopes during GC. double scopes[Scope::NUMBER_OF_SCOPES]; // Holds details for incremental marking scopes. IncrementalMarkingInfos incremental_marking_scopes[Scope::NUMBER_OF_INCREMENTAL_SCOPES]; }; static const int kThroughputTimeFrameMs = 5000; static constexpr double kConservativeSpeedInBytesPerMillisecond = 128 * KB; static double CombineSpeedsInBytesPerMillisecond(double default_speed, double optional_speed); static RuntimeCallCounterId RCSCounterFromScope(Scope::ScopeId id); static RuntimeCallCounterId RCSCounterFromBackgroundScope( BackgroundScope::ScopeId id); explicit GCTracer(Heap* heap); // Start collecting data. void Start(GarbageCollector collector, GarbageCollectionReason gc_reason, const char* collector_reason); // Stop collecting data and print results. void Stop(GarbageCollector collector); void NotifySweepingCompleted(); void NotifyYoungGenerationHandling( YoungGenerationHandling young_generation_handling); // Sample and accumulate bytes allocated since the last GC. void SampleAllocation(double current_ms, size_t new_space_counter_bytes, size_t old_generation_counter_bytes, size_t embedder_counter_bytes); // Log the accumulated new space allocation bytes. void AddAllocation(double current_ms); void AddContextDisposalTime(double time); void AddCompactionEvent(double duration, size_t live_bytes_compacted); void AddSurvivalRatio(double survival_ratio); // Log an incremental marking step. void AddIncrementalMarkingStep(double duration, size_t bytes); // Compute the average incremental marking speed in bytes/millisecond. // Returns a conservative value if no events have been recorded. double IncrementalMarkingSpeedInBytesPerMillisecond() const; // Compute the average embedder speed in bytes/millisecond. // Returns a conservative value if no events have been recorded. double EmbedderSpeedInBytesPerMillisecond() const; // Compute the average scavenge speed in bytes/millisecond. // Returns 0 if no events have been recorded. double ScavengeSpeedInBytesPerMillisecond( ScavengeSpeedMode mode = kForAllObjects) const; // Compute the average compaction speed in bytes/millisecond. // Returns 0 if not enough events have been recorded. double CompactionSpeedInBytesPerMillisecond() const; // Compute the average mark-sweep speed in bytes/millisecond. // Returns 0 if no events have been recorded. double MarkCompactSpeedInBytesPerMillisecond() const; // Compute the average incremental mark-sweep finalize speed in // bytes/millisecond. // Returns 0 if no events have been recorded. double FinalIncrementalMarkCompactSpeedInBytesPerMillisecond() const; // Compute the overall mark compact speed including incremental steps // and the final mark-compact step. double CombinedMarkCompactSpeedInBytesPerMillisecond(); // Allocation throughput in the new space in bytes/millisecond. // Returns 0 if no allocation events have been recorded. double NewSpaceAllocationThroughputInBytesPerMillisecond( double time_ms = 0) const; // Allocation throughput in the old generation in bytes/millisecond in the // last time_ms milliseconds. // Returns 0 if no allocation events have been recorded. double OldGenerationAllocationThroughputInBytesPerMillisecond( double time_ms = 0) const; // Allocation throughput in the embedder in bytes/millisecond in the // last time_ms milliseconds. Reported through v8::EmbedderHeapTracer. // Returns 0 if no allocation events have been recorded. double EmbedderAllocationThroughputInBytesPerMillisecond( double time_ms = 0) const; // Allocation throughput in heap in bytes/millisecond in the last time_ms // milliseconds. // Returns 0 if no allocation events have been recorded. double AllocationThroughputInBytesPerMillisecond(double time_ms) const; // Allocation throughput in heap in bytes/milliseconds in the last // kThroughputTimeFrameMs seconds. // Returns 0 if no allocation events have been recorded. double CurrentAllocationThroughputInBytesPerMillisecond() const; // Allocation throughput in old generation in bytes/milliseconds in the last // kThroughputTimeFrameMs seconds. // Returns 0 if no allocation events have been recorded. double CurrentOldGenerationAllocationThroughputInBytesPerMillisecond() const; // Allocation throughput in the embedder in bytes/milliseconds in the last // kThroughputTimeFrameMs seconds. Reported through v8::EmbedderHeapTracer. // Returns 0 if no allocation events have been recorded. double CurrentEmbedderAllocationThroughputInBytesPerMillisecond() const; // Computes the context disposal rate in milliseconds. It takes the time // frame of the first recorded context disposal to the current time and // divides it by the number of recorded events. // Returns 0 if no events have been recorded. double ContextDisposalRateInMilliseconds() const; // Computes the average survival ratio based on the last recorded survival // events. // Returns 0 if no events have been recorded. double AverageSurvivalRatio() const; // Returns true if at least one survival event was recorded. bool SurvivalEventsRecorded() const; // Discard all recorded survival events. void ResetSurvivalEvents(); void NotifyIncrementalMarkingStart(); // Returns average mutator utilization with respect to mark-compact // garbage collections. This ignores scavenger. double AverageMarkCompactMutatorUtilization() const; double CurrentMarkCompactMutatorUtilization() const; V8_INLINE void AddScopeSample(Scope::ScopeId scope, double duration) { DCHECK(scope < Scope::NUMBER_OF_SCOPES); if (scope >= Scope::FIRST_INCREMENTAL_SCOPE && scope <= Scope::LAST_INCREMENTAL_SCOPE) { incremental_marking_scopes_[scope - Scope::FIRST_INCREMENTAL_SCOPE] .Update(duration); } else { current_.scopes[scope] += duration; } } void AddBackgroundScopeSample(BackgroundScope::ScopeId scope, double duration); void RecordGCPhasesHistograms(TimedHistogram* gc_timer); void RecordEmbedderSpeed(size_t bytes, double duration); WorkerThreadRuntimeCallStats* worker_thread_runtime_call_stats(); private: FRIEND_TEST(GCTracer, AverageSpeed); FRIEND_TEST(GCTracerTest, AllocationThroughput); FRIEND_TEST(GCTracerTest, BackgroundScavengerScope); FRIEND_TEST(GCTracerTest, BackgroundMinorMCScope); FRIEND_TEST(GCTracerTest, BackgroundMajorMCScope); FRIEND_TEST(GCTracerTest, EmbedderAllocationThroughput); FRIEND_TEST(GCTracerTest, MultithreadedBackgroundScope); FRIEND_TEST(GCTracerTest, NewSpaceAllocationThroughput); FRIEND_TEST(GCTracerTest, PerGenerationAllocationThroughput); FRIEND_TEST(GCTracerTest, PerGenerationAllocationThroughputWithProvidedTime); FRIEND_TEST(GCTracerTest, RegularScope); FRIEND_TEST(GCTracerTest, IncrementalMarkingDetails); FRIEND_TEST(GCTracerTest, IncrementalScope); FRIEND_TEST(GCTracerTest, IncrementalMarkingSpeed); FRIEND_TEST(GCTracerTest, MutatorUtilization); FRIEND_TEST(GCTracerTest, RecordGCSumHistograms); FRIEND_TEST(GCTracerTest, RecordMarkCompactHistograms); FRIEND_TEST(GCTracerTest, RecordScavengerHistograms); struct BackgroundCounter { double total_duration_ms; }; // Returns the average speed of the events in the buffer. // If the buffer is empty, the result is 0. // Otherwise, the result is between 1 byte/ms and 1 GB/ms. static double AverageSpeed(const base::RingBuffer& buffer); static double AverageSpeed(const base::RingBuffer& buffer, const BytesAndDuration& initial, double time_ms); void ResetForTesting(); void ResetIncrementalMarkingCounters(); void RecordIncrementalMarkingSpeed(size_t bytes, double duration); void RecordMutatorUtilization(double mark_compactor_end_time, double mark_compactor_duration); // Overall time spent in mark compact within a given GC cycle. Exact // accounting of events within a GC is not necessary which is why the // recording takes place at the end of the atomic pause. void RecordGCSumCounters(double atomic_pause_duration); // Print one detailed trace line in name=value format. // TODO(ernstm): Move to Heap. void PrintNVP() const; // Print one trace line. // TODO(ernstm): Move to Heap. void Print() const; // Prints a line and also adds it to the heap's ring buffer so that // it can be included in later crash dumps. void PRINTF_FORMAT(2, 3) Output(const char* format, ...) const; double TotalExternalTime() const { return current_.scopes[Scope::HEAP_EXTERNAL_WEAK_GLOBAL_HANDLES] + current_.scopes[Scope::HEAP_EXTERNAL_EPILOGUE] + current_.scopes[Scope::HEAP_EXTERNAL_PROLOGUE] + current_.scopes[Scope::MC_INCREMENTAL_EXTERNAL_EPILOGUE] + current_.scopes[Scope::MC_INCREMENTAL_EXTERNAL_PROLOGUE]; } void FetchBackgroundCounters(int first_global_scope, int last_global_scope, int first_background_scope, int last_background_scope); void FetchBackgroundMinorGCCounters(); void FetchBackgroundMarkCompactCounters(); void FetchBackgroundGeneralCounters(); // Pointer to the heap that owns this tracer. Heap* heap_; // Current tracer event. Populated during Start/Stop cycle. Valid after Stop() // has returned. Event current_; // Previous tracer event. Event previous_; // Size of incremental marking steps (in bytes) accumulated since the end of // the last mark compact GC. size_t incremental_marking_bytes_; // Duration of incremental marking steps since the end of the last mark- // compact event. double incremental_marking_duration_; double incremental_marking_start_time_; double recorded_incremental_marking_speed_; double recorded_embedder_speed_ = 0.0; // Incremental scopes carry more information than just the duration. The infos // here are merged back upon starting/stopping the GC tracer. IncrementalMarkingInfos incremental_marking_scopes_[Scope::NUMBER_OF_INCREMENTAL_SCOPES]; // Timestamp and allocation counter at the last sampled allocation event. double allocation_time_ms_; size_t new_space_allocation_counter_bytes_; size_t old_generation_allocation_counter_bytes_; size_t embedder_allocation_counter_bytes_; // Accumulated duration and allocated bytes since the last GC. double allocation_duration_since_gc_; size_t new_space_allocation_in_bytes_since_gc_; size_t old_generation_allocation_in_bytes_since_gc_; size_t embedder_allocation_in_bytes_since_gc_; double combined_mark_compact_speed_cache_; // Counts how many tracers were started without stopping. int start_counter_; // Used for computing average mutator utilization. double average_mutator_duration_; double average_mark_compact_duration_; double current_mark_compact_mutator_utilization_; double previous_mark_compact_end_time_; base::RingBuffer recorded_minor_gcs_total_; base::RingBuffer recorded_minor_gcs_survived_; base::RingBuffer recorded_compactions_; base::RingBuffer recorded_incremental_mark_compacts_; base::RingBuffer recorded_mark_compacts_; base::RingBuffer recorded_new_generation_allocations_; base::RingBuffer recorded_old_generation_allocations_; base::RingBuffer recorded_embedder_generation_allocations_; base::RingBuffer recorded_context_disposal_times_; base::RingBuffer recorded_survival_ratios_; base::Mutex background_counter_mutex_; BackgroundCounter background_counter_[BackgroundScope::NUMBER_OF_SCOPES]; DISALLOW_COPY_AND_ASSIGN(GCTracer); }; } // namespace internal } // namespace v8 #endif // V8_HEAP_GC_TRACER_H_