weex_core/Source/include/JavaScriptCore/heap/MarkedSpace.h - incubator-weex - Git at Google

 /*
  *  Copyright (C) 1999-2000 Harri Porten (porten@kde.org)
  *  Copyright (C) 2001 Peter Kelly (pmk@post.com)
  *  Copyright (C) 2003-2017 Apple Inc. All rights reserved.
  *
  *  This library is free software; you can redistribute it and/or
  *  modify it under the terms of the GNU Lesser General Public
  *  License as published by the Free Software Foundation; either
  *  version 2 of the License, or (at your option) any later version.
  *
  *  This library is distributed in the hope that it will be useful,
  *  but WITHOUT ANY WARRANTY; without even the implied warranty of
  *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  *  Lesser General Public License for more details.
  *
  *  You should have received a copy of the GNU Lesser General Public
  *  License along with this library; if not, write to the Free Software
  *  Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
  *
  */

 #pragma once

 #include "IterationStatus.h"
 #include "LargeAllocation.h"
 #include "MarkedAllocator.h"
 #include "MarkedBlock.h"
 #include "MarkedBlockSet.h"
 #include <array>
 #include <wtf/Bag.h>
 #include <wtf/HashSet.h>
 #include <wtf/Noncopyable.h>
 #include <wtf/RetainPtr.h>
 #include <wtf/SentinelLinkedList.h>
 #include <wtf/Vector.h>

 namespace JSC {

 class Heap;
 class HeapIterationScope;
 class LLIntOffsetsExtractor;
 class Subspace;
 class WeakSet;

 typedef uint32_t HeapVersion;

 class MarkedSpace {
     WTF_MAKE_NONCOPYABLE(MarkedSpace);
 public:
     // sizeStep is really a synonym for atomSize; it's no accident that they are the same.
     static const size_t sizeStep = MarkedBlock::atomSize;

     // Sizes up to this amount get a size class for each size step.
     static const size_t preciseCutoff = 80;

     // The amount of available payload in a block is the block's size minus the header. But the
     // header size might not be atom size aligned, so we round down the result accordingly.
     static const size_t blockPayload = (MarkedBlock::blockSize - sizeof(MarkedBlock)) & ~(MarkedBlock::atomSize - 1);

     // The largest cell we're willing to allocate in a MarkedBlock the "normal way" (i.e. using size
     // classes, rather than a large allocation) is half the size of the payload, rounded down. This
     // ensures that we only use the size class approach if it means being able to pack two things
     // into one block.
     static const size_t largeCutoff = (blockPayload / 2) & ~(sizeStep - 1);

     static const size_t numSizeClasses = largeCutoff / sizeStep;

     static const HeapVersion nullVersion = 0; // The version of freshly allocated blocks.
     static const HeapVersion initialVersion = 2; // The version that the heap starts out with. Set to make sure that nextVersion(nullVersion) != initialVersion.

     static HeapVersion nextVersion(HeapVersion version)
     {
         version++;
         if (version == nullVersion)
             version = initialVersion;
         return version;
     }

     static size_t sizeClassToIndex(size_t size)
     {
         ASSERT(size);
         return (size + sizeStep - 1) / sizeStep - 1;
     }

     static size_t indexToSizeClass(size_t index)
     {
         return (index + 1) * sizeStep;
     }

     MarkedSpace(Heap*);
     ~MarkedSpace();

     Heap* heap() const { return m_heap; }

     void lastChanceToFinalize(); // You must call stopAllocating before you call this.

     static size_t optimalSizeFor(size_t);

     void prepareForAllocation();

     void visitWeakSets(SlotVisitor&);
     void reapWeakSets();

     MarkedBlockSet& blocks() { return m_blocks; }

     void willStartIterating();
     bool isIterating() const { return m_isIterating; }
     void didFinishIterating();

     void stopAllocating();
     void resumeAllocating(); // If we just stopped allocation but we didn't do a collection, we need to resume allocation.

     void prepareForMarking();

     void prepareForConservativeScan();

     typedef HashSet<MarkedBlock*>::iterator BlockIterator;

     template<typename Functor> void forEachLiveCell(HeapIterationScope&, const Functor&);
     template<typename Functor> void forEachDeadCell(HeapIterationScope&, const Functor&);
     template<typename Functor> void forEachBlock(const Functor&);

     void shrink();
     void freeBlock(MarkedBlock::Handle*);
     void freeOrShrinkBlock(MarkedBlock::Handle*);

     void didAddBlock(MarkedBlock::Handle*);
     void didConsumeFreeList(MarkedBlock::Handle*);
     void didAllocateInBlock(MarkedBlock::Handle*);

     void beginMarking();
     void endMarking();
     void snapshotUnswept();
     void clearNewlyAllocated();
     void sweep();
     void sweepLargeAllocations();
     void assertNoUnswept();
     size_t objectCount();
     size_t size();
     size_t capacity();

     bool isPagedOut(double deadline);

     HeapVersion markingVersion() const { return m_markingVersion; }
     HeapVersion newlyAllocatedVersion() const { return m_newlyAllocatedVersion; }

     const Vector<LargeAllocation*>& largeAllocations() const { return m_largeAllocations; }
     unsigned largeAllocationsNurseryOffset() const { return m_largeAllocationsNurseryOffset; }
     unsigned largeAllocationsOffsetForThisCollection() const { return m_largeAllocationsOffsetForThisCollection; }

     // These are cached pointers and offsets for quickly searching the large allocations that are
     // relevant to this collection.
     LargeAllocation** largeAllocationsForThisCollectionBegin() const { return m_largeAllocationsForThisCollectionBegin; }
     LargeAllocation** largeAllocationsForThisCollectionEnd() const { return m_largeAllocationsForThisCollectionEnd; }
     unsigned largeAllocationsForThisCollectionSize() const { return m_largeAllocationsForThisCollectionSize; }

     MarkedAllocator* firstAllocator() const { return m_firstAllocator; }
     MarkedAllocator* allocatorForEmptyAllocation() const { return m_allocatorForEmptyAllocation; }

     MarkedBlock::Handle* findEmptyBlockToSteal();

     Lock& allocatorLock() { return m_allocatorLock; }
     MarkedAllocator* addMarkedAllocator(const AbstractLocker&, Subspace*, size_t cellSize);

     // When this is true it means that we have flipped but the mark bits haven't converged yet.
     bool isMarking() const { return m_isMarking; }

     void dumpBits(PrintStream& = WTF::dataFile());

     JS_EXPORT_PRIVATE static std::array<size_t, numSizeClasses> s_sizeClassForSizeStep;

 private:
     friend class LLIntOffsetsExtractor;
     friend class JIT;
     friend class WeakSet;
     friend class Subspace;

     void* allocateSlow(Subspace&, GCDeferralContext*, size_t);
     void* tryAllocateSlow(Subspace&, GCDeferralContext*, size_t);

     // Use this version when calling from within the GC where we know that the allocators
     // have already been stopped.
     template<typename Functor> void forEachLiveCell(const Functor&);

     static void initializeSizeClassForStepSize();

     void initializeSubspace(Subspace&);

     template<typename Functor> inline void forEachAllocator(const Functor&);

     void addActiveWeakSet(WeakSet*);

     Vector<Subspace*> m_subspaces;

     Vector<LargeAllocation*> m_largeAllocations;
     unsigned m_largeAllocationsNurseryOffset { 0 };
     unsigned m_largeAllocationsOffsetForThisCollection { 0 };
     unsigned m_largeAllocationsNurseryOffsetForSweep { 0 };
     LargeAllocation** m_largeAllocationsForThisCollectionBegin { nullptr };
     LargeAllocation** m_largeAllocationsForThisCollectionEnd { nullptr };
     unsigned m_largeAllocationsForThisCollectionSize { 0 };

     Heap* m_heap;
     HeapVersion m_markingVersion { initialVersion };
     HeapVersion m_newlyAllocatedVersion { initialVersion };
     size_t m_capacity;
     bool m_isIterating;
     bool m_isMarking { false };
     MarkedBlockSet m_blocks;

     SentinelLinkedList<WeakSet, BasicRawSentinelNode<WeakSet>> m_activeWeakSets;
     SentinelLinkedList<WeakSet, BasicRawSentinelNode<WeakSet>> m_newActiveWeakSets;

     Lock m_allocatorLock;
     Bag<MarkedAllocator> m_bagOfAllocators;
     MarkedAllocator* m_firstAllocator { nullptr };
     MarkedAllocator* m_lastAllocator { nullptr };
     MarkedAllocator* m_allocatorForEmptyAllocation { nullptr };

     friend class HeapVerifier;
 };

 template <typename Functor> inline void MarkedSpace::forEachBlock(const Functor& functor)
 {
     forEachAllocator(
         [&] (MarkedAllocator& allocator) -> IterationStatus {
             allocator.forEachBlock(functor);
             return IterationStatus::Continue;
         });
 }

 template <typename Functor>
 void MarkedSpace::forEachAllocator(const Functor& functor)
 {
     for (MarkedAllocator* allocator = m_firstAllocator; allocator; allocator = allocator->nextAllocator()) {
         if (functor(*allocator) == IterationStatus::Done)
             return;
     }
 }

 ALWAYS_INLINE size_t MarkedSpace::optimalSizeFor(size_t bytes)
 {
     ASSERT(bytes);
     if (bytes <= preciseCutoff)
         return WTF::roundUpToMultipleOf<sizeStep>(bytes);
     if (bytes <= largeCutoff)
         return s_sizeClassForSizeStep[sizeClassToIndex(bytes)];
     return bytes;
 }

 } // namespace JSC
	/*
	* Copyright (C) 1999-2000 Harri Porten (porten@kde.org)
	* Copyright (C) 2001 Peter Kelly (pmk@post.com)
	* Copyright (C) 2003-2017 Apple Inc. All rights reserved.
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
	*
	*/

	#pragma once

	#include "IterationStatus.h"
	#include "LargeAllocation.h"
	#include "MarkedAllocator.h"
	#include "MarkedBlock.h"
	#include "MarkedBlockSet.h"
	#include <array>
	#include <wtf/Bag.h>
	#include <wtf/HashSet.h>
	#include <wtf/Noncopyable.h>
	#include <wtf/RetainPtr.h>
	#include <wtf/SentinelLinkedList.h>
	#include <wtf/Vector.h>

	namespace JSC {

	class Heap;
	class HeapIterationScope;
	class LLIntOffsetsExtractor;
	class Subspace;
	class WeakSet;

	typedef uint32_t HeapVersion;

	class MarkedSpace {
	WTF_MAKE_NONCOPYABLE(MarkedSpace);
	public:
	// sizeStep is really a synonym for atomSize; it's no accident that they are the same.
	static const size_t sizeStep = MarkedBlock::atomSize;

	// Sizes up to this amount get a size class for each size step.
	static const size_t preciseCutoff = 80;

	// The amount of available payload in a block is the block's size minus the header. But the
	// header size might not be atom size aligned, so we round down the result accordingly.
	static const size_t blockPayload = (MarkedBlock::blockSize - sizeof(MarkedBlock)) & ~(MarkedBlock::atomSize - 1);

	// The largest cell we're willing to allocate in a MarkedBlock the "normal way" (i.e. using size
	// classes, rather than a large allocation) is half the size of the payload, rounded down. This
	// ensures that we only use the size class approach if it means being able to pack two things
	// into one block.
	static const size_t largeCutoff = (blockPayload / 2) & ~(sizeStep - 1);

	static const size_t numSizeClasses = largeCutoff / sizeStep;

	static const HeapVersion nullVersion = 0; // The version of freshly allocated blocks.
	static const HeapVersion initialVersion = 2; // The version that the heap starts out with. Set to make sure that nextVersion(nullVersion) != initialVersion.

	static HeapVersion nextVersion(HeapVersion version)
	{
	version++;
	if (version == nullVersion)
	version = initialVersion;
	return version;
	}

	static size_t sizeClassToIndex(size_t size)
	{
	ASSERT(size);
	return (size + sizeStep - 1) / sizeStep - 1;
	}

	static size_t indexToSizeClass(size_t index)
	{
	return (index + 1) * sizeStep;
	}

	MarkedSpace(Heap*);
	~MarkedSpace();

	Heap* heap() const { return m_heap; }

	void lastChanceToFinalize(); // You must call stopAllocating before you call this.

	static size_t optimalSizeFor(size_t);

	void prepareForAllocation();

	void visitWeakSets(SlotVisitor&);
	void reapWeakSets();

	MarkedBlockSet& blocks() { return m_blocks; }

	void willStartIterating();
	bool isIterating() const { return m_isIterating; }
	void didFinishIterating();

	void stopAllocating();
	void resumeAllocating(); // If we just stopped allocation but we didn't do a collection, we need to resume allocation.

	void prepareForMarking();

	void prepareForConservativeScan();

	typedef HashSet<MarkedBlock*>::iterator BlockIterator;

	template<typename Functor> void forEachLiveCell(HeapIterationScope&, const Functor&);
	template<typename Functor> void forEachDeadCell(HeapIterationScope&, const Functor&);
	template<typename Functor> void forEachBlock(const Functor&);

	void shrink();
	void freeBlock(MarkedBlock::Handle*);
	void freeOrShrinkBlock(MarkedBlock::Handle*);

	void didAddBlock(MarkedBlock::Handle*);
	void didConsumeFreeList(MarkedBlock::Handle*);
	void didAllocateInBlock(MarkedBlock::Handle*);

	void beginMarking();
	void endMarking();
	void snapshotUnswept();
	void clearNewlyAllocated();
	void sweep();
	void sweepLargeAllocations();
	void assertNoUnswept();
	size_t objectCount();
	size_t size();
	size_t capacity();

	bool isPagedOut(double deadline);

	HeapVersion markingVersion() const { return m_markingVersion; }
	HeapVersion newlyAllocatedVersion() const { return m_newlyAllocatedVersion; }

	const Vector<LargeAllocation*>& largeAllocations() const { return m_largeAllocations; }
	unsigned largeAllocationsNurseryOffset() const { return m_largeAllocationsNurseryOffset; }
	unsigned largeAllocationsOffsetForThisCollection() const { return m_largeAllocationsOffsetForThisCollection; }

	// These are cached pointers and offsets for quickly searching the large allocations that are
	// relevant to this collection.
	LargeAllocation** largeAllocationsForThisCollectionBegin() const { return m_largeAllocationsForThisCollectionBegin; }
	LargeAllocation** largeAllocationsForThisCollectionEnd() const { return m_largeAllocationsForThisCollectionEnd; }
	unsigned largeAllocationsForThisCollectionSize() const { return m_largeAllocationsForThisCollectionSize; }

	MarkedAllocator* firstAllocator() const { return m_firstAllocator; }
	MarkedAllocator* allocatorForEmptyAllocation() const { return m_allocatorForEmptyAllocation; }

	MarkedBlock::Handle* findEmptyBlockToSteal();

	Lock& allocatorLock() { return m_allocatorLock; }
	MarkedAllocator* addMarkedAllocator(const AbstractLocker&, Subspace*, size_t cellSize);

	// When this is true it means that we have flipped but the mark bits haven't converged yet.
	bool isMarking() const { return m_isMarking; }

	void dumpBits(PrintStream& = WTF::dataFile());

	JS_EXPORT_PRIVATE static std::array<size_t, numSizeClasses> s_sizeClassForSizeStep;

	private:
	friend class LLIntOffsetsExtractor;
	friend class JIT;
	friend class WeakSet;
	friend class Subspace;

	void* allocateSlow(Subspace&, GCDeferralContext*, size_t);
	void* tryAllocateSlow(Subspace&, GCDeferralContext*, size_t);

	// Use this version when calling from within the GC where we know that the allocators
	// have already been stopped.
	template<typename Functor> void forEachLiveCell(const Functor&);

	static void initializeSizeClassForStepSize();

	void initializeSubspace(Subspace&);

	template<typename Functor> inline void forEachAllocator(const Functor&);

	void addActiveWeakSet(WeakSet*);

	Vector<Subspace*> m_subspaces;

	Vector<LargeAllocation*> m_largeAllocations;
	unsigned m_largeAllocationsNurseryOffset { 0 };
	unsigned m_largeAllocationsOffsetForThisCollection { 0 };
	unsigned m_largeAllocationsNurseryOffsetForSweep { 0 };
	LargeAllocation** m_largeAllocationsForThisCollectionBegin { nullptr };
	LargeAllocation** m_largeAllocationsForThisCollectionEnd { nullptr };
	unsigned m_largeAllocationsForThisCollectionSize { 0 };

	Heap* m_heap;
	HeapVersion m_markingVersion { initialVersion };
	HeapVersion m_newlyAllocatedVersion { initialVersion };
	size_t m_capacity;
	bool m_isIterating;
	bool m_isMarking { false };
	MarkedBlockSet m_blocks;

	SentinelLinkedList<WeakSet, BasicRawSentinelNode<WeakSet>> m_activeWeakSets;
	SentinelLinkedList<WeakSet, BasicRawSentinelNode<WeakSet>> m_newActiveWeakSets;

	Lock m_allocatorLock;
	Bag<MarkedAllocator> m_bagOfAllocators;
	MarkedAllocator* m_firstAllocator { nullptr };
	MarkedAllocator* m_lastAllocator { nullptr };
	MarkedAllocator* m_allocatorForEmptyAllocation { nullptr };

	friend class HeapVerifier;
	};

	template <typename Functor> inline void MarkedSpace::forEachBlock(const Functor& functor)
	{
	forEachAllocator(
	[&] (MarkedAllocator& allocator) -> IterationStatus {
	allocator.forEachBlock(functor);
	return IterationStatus::Continue;
	});
	}

	template <typename Functor>
	void MarkedSpace::forEachAllocator(const Functor& functor)
	{
	for (MarkedAllocator* allocator = m_firstAllocator; allocator; allocator = allocator->nextAllocator()) {
	if (functor(*allocator) == IterationStatus::Done)
	return;
	}
	}

	ALWAYS_INLINE size_t MarkedSpace::optimalSizeFor(size_t bytes)
	{
	ASSERT(bytes);
	if (bytes <= preciseCutoff)
	return WTF::roundUpToMultipleOf<sizeStep>(bytes);
	if (bytes <= largeCutoff)
	return s_sizeClassForSizeStep[sizeClassToIndex(bytes)];
	return bytes;
	}

	} // namespace JSC