src/heap/incremental-marking.h - v8/v8 - 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.

 #ifndef V8_HEAP_INCREMENTAL_MARKING_H_
 #define V8_HEAP_INCREMENTAL_MARKING_H_

 #include "src/heap/heap.h"
 #include "src/heap/incremental-marking-job.h"
 #include "src/heap/mark-compact.h"
 #include "src/tasks/cancelable-task.h"

 namespace v8 {
 namespace internal {

 class HeapObject;
 class MarkBit;
 class Map;
 class Object;
 class PagedSpace;

 enum class StepOrigin { kV8, kTask };
 enum class StepResult {
   kNoImmediateWork,
   kMoreWorkRemaining,
   kWaitingForFinalization
 };

 class V8_EXPORT_PRIVATE IncrementalMarking final {
  public:
   enum State { STOPPED, SWEEPING, MARKING, COMPLETE };

   enum CompletionAction { GC_VIA_STACK_GUARD, NO_GC_VIA_STACK_GUARD };

   enum GCRequestType { NONE, COMPLETE_MARKING, FINALIZATION };

   using MarkingState = MarkCompactCollector::MarkingState;
   using AtomicMarkingState = MarkCompactCollector::AtomicMarkingState;
   using NonAtomicMarkingState = MarkCompactCollector::NonAtomicMarkingState;

   class PauseBlackAllocationScope {
    public:
     explicit PauseBlackAllocationScope(IncrementalMarking* marking)
         : marking_(marking), paused_(false) {
       if (marking_->black_allocation()) {
         paused_ = true;
         marking_->PauseBlackAllocation();
       }
     }

     ~PauseBlackAllocationScope() {
       if (paused_) {
         marking_->StartBlackAllocation();
       }
     }

    private:
     IncrementalMarking* marking_;
     bool paused_;
   };

   // It's hard to know how much work the incremental marker should do to make
   // progress in the face of the mutator creating new work for it.  We start
   // of at a moderate rate of work and gradually increase the speed of the
   // incremental marker until it completes.
   // Do some marking every time this much memory has been allocated or that many
   // heavy (color-checking) write barriers have been invoked.
   static const size_t kYoungGenerationAllocatedThreshold = 64 * KB;
   static const size_t kOldGenerationAllocatedThreshold = 256 * KB;
   static const size_t kMinStepSizeInBytes = 64 * KB;

   static constexpr double kStepSizeInMs = 1;
   static constexpr double kMaxStepSizeInMs = 5;

 #ifndef DEBUG
   static constexpr size_t kV8ActivationThreshold = 8 * MB;
   static constexpr size_t kGlobalActivationThreshold = 16 * MB;
 #else
   static constexpr size_t kV8ActivationThreshold = 0;
   static constexpr size_t kGlobalActivationThreshold = 0;
 #endif

 #ifdef V8_CONCURRENT_MARKING
   static const AccessMode kAtomicity = AccessMode::ATOMIC;
 #else
   static const AccessMode kAtomicity = AccessMode::NON_ATOMIC;
 #endif

   IncrementalMarking(Heap* heap, WeakObjects* weak_objects);

   MarkingState* marking_state() { return &marking_state_; }

   AtomicMarkingState* atomic_marking_state() { return &atomic_marking_state_; }

   NonAtomicMarkingState* non_atomic_marking_state() {
     return &non_atomic_marking_state_;
   }

   void NotifyLeftTrimming(HeapObject from, HeapObject to);

   V8_INLINE void TransferColor(HeapObject from, HeapObject to);

   State state() const {
     DCHECK(state_ == STOPPED || FLAG_incremental_marking);
     return state_;
   }

   bool finalize_marking_completed() const {
     return finalize_marking_completed_;
   }

   void SetWeakClosureWasOverApproximatedForTesting(bool val) {
     finalize_marking_completed_ = val;
   }

   inline bool IsStopped() const { return state() == STOPPED; }

   inline bool IsSweeping() const { return state() == SWEEPING; }

   inline bool IsMarking() const { return state() >= MARKING; }

   inline bool IsMarkingIncomplete() const { return state() == MARKING; }

   inline bool IsComplete() const { return state() == COMPLETE; }

   inline bool IsReadyToOverApproximateWeakClosure() const {
     return request_type_ == FINALIZATION && !finalize_marking_completed_;
   }

   inline bool NeedsFinalization() {
     return IsMarking() &&
            (request_type_ == FINALIZATION || request_type_ == COMPLETE_MARKING);
   }

   GCRequestType request_type() const { return request_type_; }

   void reset_request_type() { request_type_ = NONE; }

   bool CanBeActivated();

   bool WasActivated();

   void Start(GarbageCollectionReason gc_reason);

   void FinalizeIncrementally();

   void UpdateMarkingWorklistAfterScavenge();
   void UpdateWeakReferencesAfterScavenge();
   void UpdateMarkedBytesAfterScavenge(size_t dead_bytes_in_new_space);

   void Hurry();

   void Finalize();

   void Stop();

   void FinalizeMarking(CompletionAction action);

   void MarkingComplete(CompletionAction action);

   void Epilogue();

   // Performs incremental marking steps and returns before the deadline_in_ms is
   // reached. It may return earlier if the marker is already ahead of the
   // marking schedule, which is indicated with StepResult::kDone.
   StepResult AdvanceWithDeadline(double deadline_in_ms,
                                  CompletionAction completion_action,
                                  StepOrigin step_origin);

   void FinalizeSweeping();

   StepResult Step(double max_step_size_in_ms, CompletionAction action,
                   StepOrigin step_origin);

   bool ShouldDoEmbedderStep();
   StepResult EmbedderStep(double expected_duration_ms, double* duration_ms);

   V8_INLINE void RestartIfNotMarking();

   // {raw_obj} and {slot_address} are raw Address values instead of a
   // HeapObject and a MaybeObjectSlot because this is called from
   // generated code via ExternalReference.
   static int RecordWriteFromCode(Address raw_obj, Address slot_address,
                                  Isolate* isolate);

   // Record a slot for compaction.  Returns false for objects that are
   // guaranteed to be rescanned or not guaranteed to survive.
   //
   // No slots in white objects should be recorded, as some slots are typed and
   // cannot be interpreted correctly if the underlying object does not survive
   // the incremental cycle (stays white).
   V8_INLINE bool BaseRecordWrite(HeapObject obj, HeapObject value);
   template <typename TSlot>
   V8_INLINE void RecordWrite(HeapObject obj, TSlot slot,
                              typename TSlot::TObject value);
   void RecordWriteSlow(HeapObject obj, HeapObjectSlot slot, HeapObject value);
   void RecordWriteIntoCode(Code host, RelocInfo* rinfo, HeapObject value);

   // Returns true if the function succeeds in transitioning the object
   // from white to grey.
   V8_INLINE bool WhiteToGreyAndPush(HeapObject obj);

   // This function is used to color the object black before it undergoes an
   // unsafe layout change. This is a part of synchronization protocol with
   // the concurrent marker.
   void MarkBlackAndVisitObjectDueToLayoutChange(HeapObject obj);

   bool IsCompacting() { return IsMarking() && is_compacting_; }

   void ProcessBlackAllocatedObject(HeapObject obj);

   Heap* heap() const { return heap_; }

   IncrementalMarkingJob* incremental_marking_job() {
     return &incremental_marking_job_;
   }

   bool black_allocation() { return black_allocation_; }

   void StartBlackAllocationForTesting() {
     if (!black_allocation_) {
       StartBlackAllocation();
     }
   }

   MarkingWorklists* marking_worklists() const {
     return collector_->marking_worklists();
   }

   void Deactivate();

   // Ensures that the given region is black allocated if it is in the old
   // generation.
   void EnsureBlackAllocated(Address allocated, size_t size);

   bool IsBelowActivationThresholds() const;

  private:
   class Observer : public AllocationObserver {
    public:
     Observer(IncrementalMarking* incremental_marking, intptr_t step_size)
         : AllocationObserver(step_size),
           incremental_marking_(incremental_marking) {}

     void Step(int bytes_allocated, Address, size_t) override;

    private:
     IncrementalMarking* incremental_marking_;
   };

   void StartMarking();

   void StartBlackAllocation();
   void PauseBlackAllocation();
   void FinishBlackAllocation();

   void MarkRoots();
   bool ShouldRetainMap(Map map, int age);
   // Retain dying maps for <FLAG_retain_maps_for_n_gc> garbage collections to
   // increase chances of reusing of map transition tree in future.
   void RetainMaps();

   void ActivateIncrementalWriteBarrier(PagedSpace* space);
   void ActivateIncrementalWriteBarrier(NewSpace* space);
   void ActivateIncrementalWriteBarrier();

   void DeactivateIncrementalWriteBarrierForSpace(PagedSpace* space);
   void DeactivateIncrementalWriteBarrierForSpace(NewSpace* space);
   void DeactivateIncrementalWriteBarrier();

   // Updates scheduled_bytes_to_mark_ to ensure marking progress based on
   // time.
   void ScheduleBytesToMarkBasedOnTime(double time_ms);
   // Updates scheduled_bytes_to_mark_ to ensure marking progress based on
   // allocations.
   void ScheduleBytesToMarkBasedOnAllocation();
   // Helper functions for ScheduleBytesToMarkBasedOnAllocation.
   size_t StepSizeToKeepUpWithAllocations();
   size_t StepSizeToMakeProgress();
   void AddScheduledBytesToMark(size_t bytes_to_mark);

   // Schedules more bytes to mark so that the marker is no longer ahead
   // of schedule.
   void FastForwardSchedule();
   void FastForwardScheduleIfCloseToFinalization();

   // Fetches marked byte counters from the concurrent marker.
   void FetchBytesMarkedConcurrently();

   // Returns the bytes to mark in the current step based on the scheduled
   // bytes and already marked bytes.
   size_t ComputeStepSizeInBytes(StepOrigin step_origin);

   void AdvanceOnAllocation();

   void SetState(State s) {
     state_ = s;
     heap_->SetIsMarkingFlag(s >= MARKING);
   }

   double CurrentTimeToMarkingTask() const;

   Heap* const heap_;
   MarkCompactCollector* const collector_;
   WeakObjects* weak_objects_;

   double start_time_ms_ = 0.0;
   double time_to_force_completion_ = 0.0;
   size_t initial_old_generation_size_ = 0;
   size_t old_generation_allocation_counter_ = 0;
   size_t bytes_marked_ = 0;
   size_t scheduled_bytes_to_mark_ = 0;
   double schedule_update_time_ms_ = 0.0;
   // A sample of concurrent_marking()->TotalMarkedBytes() at the last
   // incremental marking step. It is used for updating
   // bytes_marked_ahead_of_schedule_ with contribution of concurrent marking.
   size_t bytes_marked_concurrently_ = 0;

   // Must use SetState() above to update state_
   State state_;

   bool is_compacting_ = false;
   bool was_activated_ = false;
   bool black_allocation_ = false;
   bool finalize_marking_completed_ = false;
   IncrementalMarkingJob incremental_marking_job_;

   GCRequestType request_type_ = NONE;

   Observer new_generation_observer_;
   Observer old_generation_observer_;

   MarkingState marking_state_;
   AtomicMarkingState atomic_marking_state_;
   NonAtomicMarkingState non_atomic_marking_state_;

   DISALLOW_IMPLICIT_CONSTRUCTORS(IncrementalMarking);
 };
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_HEAP_INCREMENTAL_MARKING_H_
	// 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.

	#ifndef V8_HEAP_INCREMENTAL_MARKING_H_
	#define V8_HEAP_INCREMENTAL_MARKING_H_

	#include "src/heap/heap.h"
	#include "src/heap/incremental-marking-job.h"
	#include "src/heap/mark-compact.h"
	#include "src/tasks/cancelable-task.h"

	namespace v8 {
	namespace internal {

	class HeapObject;
	class MarkBit;
	class Map;
	class Object;
	class PagedSpace;

	enum class StepOrigin { kV8, kTask };
	enum class StepResult {
	kNoImmediateWork,
	kMoreWorkRemaining,
	kWaitingForFinalization
	};

	class V8_EXPORT_PRIVATE IncrementalMarking final {
	public:
	enum State { STOPPED, SWEEPING, MARKING, COMPLETE };

	enum CompletionAction { GC_VIA_STACK_GUARD, NO_GC_VIA_STACK_GUARD };

	enum GCRequestType { NONE, COMPLETE_MARKING, FINALIZATION };

	using MarkingState = MarkCompactCollector::MarkingState;
	using AtomicMarkingState = MarkCompactCollector::AtomicMarkingState;
	using NonAtomicMarkingState = MarkCompactCollector::NonAtomicMarkingState;

	class PauseBlackAllocationScope {
	public:
	explicit PauseBlackAllocationScope(IncrementalMarking* marking)
	: marking_(marking), paused_(false) {
	if (marking_->black_allocation()) {
	paused_ = true;
	marking_->PauseBlackAllocation();
	}
	}

	~PauseBlackAllocationScope() {
	if (paused_) {
	marking_->StartBlackAllocation();
	}
	}

	private:
	IncrementalMarking* marking_;
	bool paused_;
	};

	// It's hard to know how much work the incremental marker should do to make
	// progress in the face of the mutator creating new work for it. We start
	// of at a moderate rate of work and gradually increase the speed of the
	// incremental marker until it completes.
	// Do some marking every time this much memory has been allocated or that many
	// heavy (color-checking) write barriers have been invoked.
	static const size_t kYoungGenerationAllocatedThreshold = 64 * KB;
	static const size_t kOldGenerationAllocatedThreshold = 256 * KB;
	static const size_t kMinStepSizeInBytes = 64 * KB;

	static constexpr double kStepSizeInMs = 1;
	static constexpr double kMaxStepSizeInMs = 5;

	#ifndef DEBUG
	static constexpr size_t kV8ActivationThreshold = 8 * MB;
	static constexpr size_t kGlobalActivationThreshold = 16 * MB;
	#else
	static constexpr size_t kV8ActivationThreshold = 0;
	static constexpr size_t kGlobalActivationThreshold = 0;
	#endif

	#ifdef V8_CONCURRENT_MARKING
	static const AccessMode kAtomicity = AccessMode::ATOMIC;
	#else
	static const AccessMode kAtomicity = AccessMode::NON_ATOMIC;
	#endif

	IncrementalMarking(Heap* heap, WeakObjects* weak_objects);

	MarkingState* marking_state() { return &marking_state_; }

	AtomicMarkingState* atomic_marking_state() { return &atomic_marking_state_; }

	NonAtomicMarkingState* non_atomic_marking_state() {
	return &non_atomic_marking_state_;
	}

	void NotifyLeftTrimming(HeapObject from, HeapObject to);

	V8_INLINE void TransferColor(HeapObject from, HeapObject to);

	State state() const {
	DCHECK(state_ == STOPPED \|\| FLAG_incremental_marking);
	return state_;
	}

	bool finalize_marking_completed() const {
	return finalize_marking_completed_;
	}

	void SetWeakClosureWasOverApproximatedForTesting(bool val) {
	finalize_marking_completed_ = val;
	}

	inline bool IsStopped() const { return state() == STOPPED; }

	inline bool IsSweeping() const { return state() == SWEEPING; }

	inline bool IsMarking() const { return state() >= MARKING; }

	inline bool IsMarkingIncomplete() const { return state() == MARKING; }

	inline bool IsComplete() const { return state() == COMPLETE; }

	inline bool IsReadyToOverApproximateWeakClosure() const {
	return request_type_ == FINALIZATION && !finalize_marking_completed_;
	}

	inline bool NeedsFinalization() {
	return IsMarking() &&
	(request_type_ == FINALIZATION \|\| request_type_ == COMPLETE_MARKING);
	}

	GCRequestType request_type() const { return request_type_; }

	void reset_request_type() { request_type_ = NONE; }

	bool CanBeActivated();

	bool WasActivated();

	void Start(GarbageCollectionReason gc_reason);

	void FinalizeIncrementally();

	void UpdateMarkingWorklistAfterScavenge();
	void UpdateWeakReferencesAfterScavenge();
	void UpdateMarkedBytesAfterScavenge(size_t dead_bytes_in_new_space);

	void Hurry();

	void Finalize();

	void Stop();

	void FinalizeMarking(CompletionAction action);

	void MarkingComplete(CompletionAction action);

	void Epilogue();

	// Performs incremental marking steps and returns before the deadline_in_ms is
	// reached. It may return earlier if the marker is already ahead of the
	// marking schedule, which is indicated with StepResult::kDone.
	StepResult AdvanceWithDeadline(double deadline_in_ms,
	CompletionAction completion_action,
	StepOrigin step_origin);

	void FinalizeSweeping();

	StepResult Step(double max_step_size_in_ms, CompletionAction action,
	StepOrigin step_origin);

	bool ShouldDoEmbedderStep();
	StepResult EmbedderStep(double expected_duration_ms, double* duration_ms);

	V8_INLINE void RestartIfNotMarking();

	// {raw_obj} and {slot_address} are raw Address values instead of a
	// HeapObject and a MaybeObjectSlot because this is called from
	// generated code via ExternalReference.
	static int RecordWriteFromCode(Address raw_obj, Address slot_address,
	Isolate* isolate);

	// Record a slot for compaction. Returns false for objects that are
	// guaranteed to be rescanned or not guaranteed to survive.
	//
	// No slots in white objects should be recorded, as some slots are typed and
	// cannot be interpreted correctly if the underlying object does not survive
	// the incremental cycle (stays white).
	V8_INLINE bool BaseRecordWrite(HeapObject obj, HeapObject value);
	template <typename TSlot>
	V8_INLINE void RecordWrite(HeapObject obj, TSlot slot,
	typename TSlot::TObject value);
	void RecordWriteSlow(HeapObject obj, HeapObjectSlot slot, HeapObject value);
	void RecordWriteIntoCode(Code host, RelocInfo* rinfo, HeapObject value);

	// Returns true if the function succeeds in transitioning the object
	// from white to grey.
	V8_INLINE bool WhiteToGreyAndPush(HeapObject obj);

	// This function is used to color the object black before it undergoes an
	// unsafe layout change. This is a part of synchronization protocol with
	// the concurrent marker.
	void MarkBlackAndVisitObjectDueToLayoutChange(HeapObject obj);

	bool IsCompacting() { return IsMarking() && is_compacting_; }

	void ProcessBlackAllocatedObject(HeapObject obj);

	Heap* heap() const { return heap_; }

	IncrementalMarkingJob* incremental_marking_job() {
	return &incremental_marking_job_;
	}

	bool black_allocation() { return black_allocation_; }

	void StartBlackAllocationForTesting() {
	if (!black_allocation_) {
	StartBlackAllocation();
	}
	}

	MarkingWorklists* marking_worklists() const {
	return collector_->marking_worklists();
	}

	void Deactivate();

	// Ensures that the given region is black allocated if it is in the old
	// generation.
	void EnsureBlackAllocated(Address allocated, size_t size);

	bool IsBelowActivationThresholds() const;

	private:
	class Observer : public AllocationObserver {
	public:
	Observer(IncrementalMarking* incremental_marking, intptr_t step_size)
	: AllocationObserver(step_size),
	incremental_marking_(incremental_marking) {}

	void Step(int bytes_allocated, Address, size_t) override;

	private:
	IncrementalMarking* incremental_marking_;
	};

	void StartMarking();

	void StartBlackAllocation();
	void PauseBlackAllocation();
	void FinishBlackAllocation();

	void MarkRoots();
	bool ShouldRetainMap(Map map, int age);
	// Retain dying maps for <FLAG_retain_maps_for_n_gc> garbage collections to
	// increase chances of reusing of map transition tree in future.
	void RetainMaps();

	void ActivateIncrementalWriteBarrier(PagedSpace* space);
	void ActivateIncrementalWriteBarrier(NewSpace* space);
	void ActivateIncrementalWriteBarrier();

	void DeactivateIncrementalWriteBarrierForSpace(PagedSpace* space);
	void DeactivateIncrementalWriteBarrierForSpace(NewSpace* space);
	void DeactivateIncrementalWriteBarrier();

	// Updates scheduled_bytes_to_mark_ to ensure marking progress based on
	// time.
	void ScheduleBytesToMarkBasedOnTime(double time_ms);
	// Updates scheduled_bytes_to_mark_ to ensure marking progress based on
	// allocations.
	void ScheduleBytesToMarkBasedOnAllocation();
	// Helper functions for ScheduleBytesToMarkBasedOnAllocation.
	size_t StepSizeToKeepUpWithAllocations();
	size_t StepSizeToMakeProgress();
	void AddScheduledBytesToMark(size_t bytes_to_mark);

	// Schedules more bytes to mark so that the marker is no longer ahead
	// of schedule.
	void FastForwardSchedule();
	void FastForwardScheduleIfCloseToFinalization();

	// Fetches marked byte counters from the concurrent marker.
	void FetchBytesMarkedConcurrently();

	// Returns the bytes to mark in the current step based on the scheduled
	// bytes and already marked bytes.
	size_t ComputeStepSizeInBytes(StepOrigin step_origin);

	void AdvanceOnAllocation();

	void SetState(State s) {
	state_ = s;
	heap_->SetIsMarkingFlag(s >= MARKING);
	}

	double CurrentTimeToMarkingTask() const;

	Heap* const heap_;
	MarkCompactCollector* const collector_;
	WeakObjects* weak_objects_;

	double start_time_ms_ = 0.0;
	double time_to_force_completion_ = 0.0;
	size_t initial_old_generation_size_ = 0;
	size_t old_generation_allocation_counter_ = 0;
	size_t bytes_marked_ = 0;
	size_t scheduled_bytes_to_mark_ = 0;
	double schedule_update_time_ms_ = 0.0;
	// A sample of concurrent_marking()->TotalMarkedBytes() at the last
	// incremental marking step. It is used for updating
	// bytes_marked_ahead_of_schedule_ with contribution of concurrent marking.
	size_t bytes_marked_concurrently_ = 0;

	// Must use SetState() above to update state_
	State state_;

	bool is_compacting_ = false;
	bool was_activated_ = false;
	bool black_allocation_ = false;
	bool finalize_marking_completed_ = false;
	IncrementalMarkingJob incremental_marking_job_;

	GCRequestType request_type_ = NONE;

	Observer new_generation_observer_;
	Observer old_generation_observer_;

	MarkingState marking_state_;
	AtomicMarkingState atomic_marking_state_;
	NonAtomicMarkingState non_atomic_marking_state_;

	DISALLOW_IMPLICIT_CONSTRUCTORS(IncrementalMarking);
	};
	} // namespace internal
	} // namespace v8

	#endif // V8_HEAP_INCREMENTAL_MARKING_H_