src/mark-compact.h - external/v8/3.6 - Git at Google

 // Copyright 2006-2008 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #ifndef V8_MARK_COMPACT_H_
 #define V8_MARK_COMPACT_H_

 #include "spaces.h"

 namespace v8 {
 namespace internal {

 // Callback function, returns whether an object is alive. The heap size
 // of the object is returned in size. It optionally updates the offset
 // to the first live object in the page (only used for old and map objects).
 typedef bool (*IsAliveFunction)(HeapObject* obj, int* size, int* offset);

 // Forward declarations.
 class CodeFlusher;
 class GCTracer;
 class MarkingVisitor;
 class RootMarkingVisitor;


 // ----------------------------------------------------------------------------
 // Marking stack for tracing live objects.

 class MarkingStack {
  public:
   MarkingStack() : low_(NULL), top_(NULL), high_(NULL), overflowed_(false) { }

   void Initialize(Address low, Address high) {
     top_ = low_ = reinterpret_cast<HeapObject**>(low);
     high_ = reinterpret_cast<HeapObject**>(high);
     overflowed_ = false;
   }

   bool is_full() const { return top_ >= high_; }

   bool is_empty() const { return top_ <= low_; }

   bool overflowed() const { return overflowed_; }

   void clear_overflowed() { overflowed_ = false; }

   // Push the (marked) object on the marking stack if there is room,
   // otherwise mark the object as overflowed and wait for a rescan of the
   // heap.
   void Push(HeapObject* object) {
     CHECK(object->IsHeapObject());
     if (is_full()) {
       object->SetOverflow();
       overflowed_ = true;
     } else {
       *(top_++) = object;
     }
   }

   HeapObject* Pop() {
     ASSERT(!is_empty());
     HeapObject* object = *(--top_);
     CHECK(object->IsHeapObject());
     return object;
   }

  private:
   HeapObject** low_;
   HeapObject** top_;
   HeapObject** high_;
   bool overflowed_;

   DISALLOW_COPY_AND_ASSIGN(MarkingStack);
 };


 // Defined in isolate.h.
 class ThreadLocalTop;


 // -------------------------------------------------------------------------
 // Mark-Compact collector

 class OverflowedObjectsScanner;

 class MarkCompactCollector {
  public:
   // Type of functions to compute forwarding addresses of objects in
   // compacted spaces.  Given an object and its size, return a (non-failure)
   // Object* that will be the object after forwarding.  There is a separate
   // allocation function for each (compactable) space based on the location
   // of the object before compaction.
   typedef MaybeObject* (*AllocationFunction)(Heap* heap,
                                              HeapObject* object,
                                              int object_size);

   // Type of functions to encode the forwarding address for an object.
   // Given the object, its size, and the new (non-failure) object it will be
   // forwarded to, encode the forwarding address.  For paged spaces, the
   // 'offset' input/output parameter contains the offset of the forwarded
   // object from the forwarding address of the previous live object in the
   // page as input, and is updated to contain the offset to be used for the
   // next live object in the same page.  For spaces using a different
   // encoding (ie, contiguous spaces), the offset parameter is ignored.
   typedef void (*EncodingFunction)(Heap* heap,
                                    HeapObject* old_object,
                                    int object_size,
                                    Object* new_object,
                                    int* offset);

   // Type of functions to process non-live objects.
   typedef void (*ProcessNonLiveFunction)(HeapObject* object, Isolate* isolate);

   // Pointer to member function, used in IterateLiveObjects.
   typedef int (MarkCompactCollector::*LiveObjectCallback)(HeapObject* obj);

   // Set the global force_compaction flag, it must be called before Prepare
   // to take effect.
   void SetForceCompaction(bool value) {
     force_compaction_ = value;
   }


   static void Initialize();

   // Prepares for GC by resetting relocation info in old and map spaces and
   // choosing spaces to compact.
   void Prepare(GCTracer* tracer);

   // Performs a global garbage collection.
   void CollectGarbage();

   // True if the last full GC performed heap compaction.
   bool HasCompacted() { return compacting_collection_; }

   // True after the Prepare phase if the compaction is taking place.
   bool IsCompacting() {
 #ifdef DEBUG
     // For the purposes of asserts we don't want this to keep returning true
     // after the collection is completed.
     return state_ != IDLE && compacting_collection_;
 #else
     return compacting_collection_;
 #endif
   }

   // The count of the number of objects left marked at the end of the last
   // completed full GC (expected to be zero).
   int previous_marked_count() { return previous_marked_count_; }

   // During a full GC, there is a stack-allocated GCTracer that is used for
   // bookkeeping information.  Return a pointer to that tracer.
   GCTracer* tracer() { return tracer_; }

 #ifdef DEBUG
   // Checks whether performing mark-compact collection.
   bool in_use() { return state_ > PREPARE_GC; }
   bool are_map_pointers_encoded() { return state_ == UPDATE_POINTERS; }
 #endif

   // Determine type of object and emit deletion log event.
   static void ReportDeleteIfNeeded(HeapObject* obj, Isolate* isolate);

   // Returns size of a possibly marked object.
   static int SizeOfMarkedObject(HeapObject* obj);

   // Distinguishable invalid map encodings (for single word and multiple words)
   // that indicate free regions.
   static const uint32_t kSingleFreeEncoding = 0;
   static const uint32_t kMultiFreeEncoding = 1;

   inline Heap* heap() const { return heap_; }

   CodeFlusher* code_flusher() { return code_flusher_; }
   inline bool is_code_flushing_enabled() const { return code_flusher_ != NULL; }
   void EnableCodeFlushing(bool enable);

   inline Object* encountered_weak_maps() { return encountered_weak_maps_; }
   inline void set_encountered_weak_maps(Object* weak_map) {
     encountered_weak_maps_ = weak_map;
   }

  private:
   MarkCompactCollector();
   ~MarkCompactCollector();

 #ifdef DEBUG
   enum CollectorState {
     IDLE,
     PREPARE_GC,
     MARK_LIVE_OBJECTS,
     SWEEP_SPACES,
     ENCODE_FORWARDING_ADDRESSES,
     UPDATE_POINTERS,
     RELOCATE_OBJECTS
   };

   // The current stage of the collector.
   CollectorState state_;
 #endif

   // Global flag that forces a compaction.
   bool force_compaction_;

   // Global flag indicating whether spaces were compacted on the last GC.
   bool compacting_collection_;

   // Global flag indicating whether spaces will be compacted on the next GC.
   bool compact_on_next_gc_;

   // The number of objects left marked at the end of the last completed full
   // GC (expected to be zero).
   int previous_marked_count_;

   // A pointer to the current stack-allocated GC tracer object during a full
   // collection (NULL before and after).
   GCTracer* tracer_;

   // Finishes GC, performs heap verification if enabled.
   void Finish();

   // -----------------------------------------------------------------------
   // Phase 1: Marking live objects.
   //
   //  Before: The heap has been prepared for garbage collection by
   //          MarkCompactCollector::Prepare() and is otherwise in its
   //          normal state.
   //
   //   After: Live objects are marked and non-live objects are unmarked.


   friend class RootMarkingVisitor;
   friend class MarkingVisitor;
   friend class StaticMarkingVisitor;
   friend class CodeMarkingVisitor;
   friend class SharedFunctionInfoMarkingVisitor;

   // Mark non-optimize code for functions inlined into the given optimized
   // code. This will prevent it from being flushed.
   void MarkInlinedFunctionsCode(Code* code);

   // Mark code objects that are active on the stack to prevent them
   // from being flushed.
   void PrepareThreadForCodeFlushing(Isolate* isolate, ThreadLocalTop* top);

   void PrepareForCodeFlushing();

   // Marking operations for objects reachable from roots.
   void MarkLiveObjects();

   void MarkUnmarkedObject(HeapObject* obj);

   inline void MarkObject(HeapObject* obj) {
     if (!obj->IsMarked()) MarkUnmarkedObject(obj);
   }

   inline void SetMark(HeapObject* obj);

   // Creates back pointers for all map transitions, stores them in
   // the prototype field.  The original prototype pointers are restored
   // in ClearNonLiveTransitions().  All JSObject maps
   // connected by map transitions have the same prototype object, which
   // is why we can use this field temporarily for back pointers.
   void CreateBackPointers();

   // Mark a Map and its DescriptorArray together, skipping transitions.
   void MarkMapContents(Map* map);
   void MarkDescriptorArray(DescriptorArray* descriptors);

   // Mark the heap roots and all objects reachable from them.
   void MarkRoots(RootMarkingVisitor* visitor);

   // Mark the symbol table specially.  References to symbols from the
   // symbol table are weak.
   void MarkSymbolTable();

   // Mark objects in object groups that have at least one object in the
   // group marked.
   void MarkObjectGroups();

   // Mark objects in implicit references groups if their parent object
   // is marked.
   void MarkImplicitRefGroups();

   // Mark all objects which are reachable due to host application
   // logic like object groups or implicit references' groups.
   void ProcessExternalMarking();

   // Mark objects reachable (transitively) from objects in the marking stack
   // or overflowed in the heap.
   void ProcessMarkingStack();

   // Mark objects reachable (transitively) from objects in the marking
   // stack.  This function empties the marking stack, but may leave
   // overflowed objects in the heap, in which case the marking stack's
   // overflow flag will be set.
   void EmptyMarkingStack();

   // Refill the marking stack with overflowed objects from the heap.  This
   // function either leaves the marking stack full or clears the overflow
   // flag on the marking stack.
   void RefillMarkingStack();

   // After reachable maps have been marked process per context object
   // literal map caches removing unmarked entries.
   void ProcessMapCaches();

   // Callback function for telling whether the object *p is an unmarked
   // heap object.
   static bool IsUnmarkedHeapObject(Object** p);

 #ifdef DEBUG
   void UpdateLiveObjectCount(HeapObject* obj);
 #endif

   // We sweep the large object space in the same way whether we are
   // compacting or not, because the large object space is never compacted.
   void SweepLargeObjectSpace();

   // Test whether a (possibly marked) object is a Map.
   static inline bool SafeIsMap(HeapObject* object);

   // Map transitions from a live map to a dead map must be killed.
   // We replace them with a null descriptor, with the same key.
   void ClearNonLiveTransitions();

   // Mark all values associated with reachable keys in weak maps encountered
   // so far.  This might push new object or even new weak maps onto the
   // marking stack.
   void ProcessWeakMaps();

   // After all reachable objects have been marked those weak map entries
   // with an unreachable key are removed from all encountered weak maps.
   // The linked list of all encountered weak maps is destroyed.
   void ClearWeakMaps();

   // -----------------------------------------------------------------------
   // Phase 2: Sweeping to clear mark bits and free non-live objects for
   // a non-compacting collection, or else computing and encoding
   // forwarding addresses for a compacting collection.
   //
   //  Before: Live objects are marked and non-live objects are unmarked.
   //
   //   After: (Non-compacting collection.)  Live objects are unmarked,
   //          non-live regions have been added to their space's free
   //          list.
   //
   //   After: (Compacting collection.)  The forwarding address of live
   //          objects in the paged spaces is encoded in their map word
   //          along with their (non-forwarded) map pointer.
   //
   //          The forwarding address of live objects in the new space is
   //          written to their map word's offset in the inactive
   //          semispace.
   //
   //          Bookkeeping data is written to the page header of
   //          eached paged-space page that contains live objects after
   //          compaction:
   //
   //          The allocation watermark field is used to track the
   //          relocation top address, the address of the first word
   //          after the end of the last live object in the page after
   //          compaction.
   //
   //          The Page::mc_page_index field contains the zero-based index of the
   //          page in its space.  This word is only used for map space pages, in
   //          order to encode the map addresses in 21 bits to free 11
   //          bits per map word for the forwarding address.
   //
   //          The Page::mc_first_forwarded field contains the (nonencoded)
   //          forwarding address of the first live object in the page.
   //
   //          In both the new space and the paged spaces, a linked list
   //          of live regions is constructructed (linked through
   //          pointers in the non-live region immediately following each
   //          live region) to speed further passes of the collector.

   // Encodes forwarding addresses of objects in compactable parts of the
   // heap.
   void EncodeForwardingAddresses();

   // Encodes the forwarding addresses of objects in new space.
   void EncodeForwardingAddressesInNewSpace();

   // Function template to encode the forwarding addresses of objects in
   // paged spaces, parameterized by allocation and non-live processing
   // functions.
   template<AllocationFunction Alloc, ProcessNonLiveFunction ProcessNonLive>
   void EncodeForwardingAddressesInPagedSpace(PagedSpace* space);

   // Iterates live objects in a space, passes live objects
   // to a callback function which returns the heap size of the object.
   // Returns the number of live objects iterated.
   int IterateLiveObjects(NewSpace* space, LiveObjectCallback size_f);
   int IterateLiveObjects(PagedSpace* space, LiveObjectCallback size_f);

   // Iterates the live objects between a range of addresses, returning the
   // number of live objects.
   int IterateLiveObjectsInRange(Address start, Address end,
                                 LiveObjectCallback size_func);

   // If we are not compacting the heap, we simply sweep the spaces except
   // for the large object space, clearing mark bits and adding unmarked
   // regions to each space's free list.
   void SweepSpaces();

   // -----------------------------------------------------------------------
   // Phase 3: Updating pointers in live objects.
   //
   //  Before: Same as after phase 2 (compacting collection).
   //
   //   After: All pointers in live objects, including encoded map
   //          pointers, are updated to point to their target's new
   //          location.

   friend class UpdatingVisitor;  // helper for updating visited objects

   // Updates pointers in all spaces.
   void UpdatePointers();

   // Updates pointers in an object in new space.
   // Returns the heap size of the object.
   int UpdatePointersInNewObject(HeapObject* obj);

   // Updates pointers in an object in old spaces.
   // Returns the heap size of the object.
   int UpdatePointersInOldObject(HeapObject* obj);

   // Calculates the forwarding address of an object in an old space.
   static Address GetForwardingAddressInOldSpace(HeapObject* obj);

   // -----------------------------------------------------------------------
   // Phase 4: Relocating objects.
   //
   //  Before: Pointers to live objects are updated to point to their
   //          target's new location.
   //
   //   After: Objects have been moved to their new addresses.

   // Relocates objects in all spaces.
   void RelocateObjects();

   // Converts a code object's inline target to addresses, convention from
   // address to target happens in the marking phase.
   int ConvertCodeICTargetToAddress(HeapObject* obj);

   // Relocate a map object.
   int RelocateMapObject(HeapObject* obj);

   // Relocates an old object.
   int RelocateOldPointerObject(HeapObject* obj);
   int RelocateOldDataObject(HeapObject* obj);

   // Relocate a property cell object.
   int RelocateCellObject(HeapObject* obj);

   // Helper function.
   inline int RelocateOldNonCodeObject(HeapObject* obj,
                                       PagedSpace* space);

   // Relocates an object in the code space.
   int RelocateCodeObject(HeapObject* obj);

   // Copy a new object.
   int RelocateNewObject(HeapObject* obj);

 #ifdef DEBUG
   // -----------------------------------------------------------------------
   // Debugging variables, functions and classes
   // Counters used for debugging the marking phase of mark-compact or
   // mark-sweep collection.

   // Size of live objects in Heap::to_space_.
   int live_young_objects_size_;

   // Size of live objects in Heap::old_pointer_space_.
   int live_old_pointer_objects_size_;

   // Size of live objects in Heap::old_data_space_.
   int live_old_data_objects_size_;

   // Size of live objects in Heap::code_space_.
   int live_code_objects_size_;

   // Size of live objects in Heap::map_space_.
   int live_map_objects_size_;

   // Size of live objects in Heap::cell_space_.
   int live_cell_objects_size_;

   // Size of live objects in Heap::lo_space_.
   int live_lo_objects_size_;

   // Number of live bytes in this collection.
   int live_bytes_;

   friend class MarkObjectVisitor;
   static void VisitObject(HeapObject* obj);

   friend class UnmarkObjectVisitor;
   static void UnmarkObject(HeapObject* obj);
 #endif

   Heap* heap_;
   MarkingStack marking_stack_;
   CodeFlusher* code_flusher_;
   Object* encountered_weak_maps_;

   friend class Heap;
   friend class OverflowedObjectsScanner;
 };


 } }  // namespace v8::internal

 #endif  // V8_MARK_COMPACT_H_
	// Copyright 2006-2008 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#ifndef V8_MARK_COMPACT_H_
	#define V8_MARK_COMPACT_H_

	#include "spaces.h"

	namespace v8 {
	namespace internal {

	// Callback function, returns whether an object is alive. The heap size
	// of the object is returned in size. It optionally updates the offset
	// to the first live object in the page (only used for old and map objects).
	typedef bool (IsAliveFunction)(HeapObject obj, int* size, int* offset);

	// Forward declarations.
	class CodeFlusher;
	class GCTracer;
	class MarkingVisitor;
	class RootMarkingVisitor;


	// ----------------------------------------------------------------------------
	// Marking stack for tracing live objects.

	class MarkingStack {
	public:
	MarkingStack() : low_(NULL), top_(NULL), high_(NULL), overflowed_(false) { }

	void Initialize(Address low, Address high) {
	top_ = low_ = reinterpret_cast<HeapObject**>(low);
	high_ = reinterpret_cast<HeapObject**>(high);
	overflowed_ = false;
	}

	bool is_full() const { return top_ >= high_; }

	bool is_empty() const { return top_ <= low_; }

	bool overflowed() const { return overflowed_; }

	void clear_overflowed() { overflowed_ = false; }

	// Push the (marked) object on the marking stack if there is room,
	// otherwise mark the object as overflowed and wait for a rescan of the
	// heap.
	void Push(HeapObject* object) {
	CHECK(object->IsHeapObject());
	if (is_full()) {
	object->SetOverflow();
	overflowed_ = true;
	} else {
	*(top_++) = object;
	}
	}

	HeapObject* Pop() {
	ASSERT(!is_empty());
	HeapObject* object = *(--top_);
	CHECK(object->IsHeapObject());
	return object;
	}

	private:
	HeapObject** low_;
	HeapObject** top_;
	HeapObject** high_;
	bool overflowed_;

	DISALLOW_COPY_AND_ASSIGN(MarkingStack);
	};


	// Defined in isolate.h.
	class ThreadLocalTop;


	// -------------------------------------------------------------------------
	// Mark-Compact collector

	class OverflowedObjectsScanner;

	class MarkCompactCollector {
	public:
	// Type of functions to compute forwarding addresses of objects in
	// compacted spaces. Given an object and its size, return a (non-failure)
	// Object* that will be the object after forwarding. There is a separate
	// allocation function for each (compactable) space based on the location
	// of the object before compaction.
	typedef MaybeObject* (AllocationFunction)(Heap heap,
	HeapObject* object,
	int object_size);

	// Type of functions to encode the forwarding address for an object.
	// Given the object, its size, and the new (non-failure) object it will be
	// forwarded to, encode the forwarding address. For paged spaces, the
	// 'offset' input/output parameter contains the offset of the forwarded
	// object from the forwarding address of the previous live object in the
	// page as input, and is updated to contain the offset to be used for the
	// next live object in the same page. For spaces using a different
	// encoding (ie, contiguous spaces), the offset parameter is ignored.
	typedef void (EncodingFunction)(Heap heap,
	HeapObject* old_object,
	int object_size,
	Object* new_object,
	int* offset);

	// Type of functions to process non-live objects.
	typedef void (ProcessNonLiveFunction)(HeapObject object, Isolate* isolate);

	// Pointer to member function, used in IterateLiveObjects.
	typedef int (MarkCompactCollector::LiveObjectCallback)(HeapObject obj);

	// Set the global force_compaction flag, it must be called before Prepare
	// to take effect.
	void SetForceCompaction(bool value) {
	force_compaction_ = value;
	}


	static void Initialize();

	// Prepares for GC by resetting relocation info in old and map spaces and
	// choosing spaces to compact.
	void Prepare(GCTracer* tracer);

	// Performs a global garbage collection.
	void CollectGarbage();

	// True if the last full GC performed heap compaction.
	bool HasCompacted() { return compacting_collection_; }

	// True after the Prepare phase if the compaction is taking place.
	bool IsCompacting() {
	#ifdef DEBUG
	// For the purposes of asserts we don't want this to keep returning true
	// after the collection is completed.
	return state_ != IDLE && compacting_collection_;
	#else
	return compacting_collection_;
	#endif
	}

	// The count of the number of objects left marked at the end of the last
	// completed full GC (expected to be zero).
	int previous_marked_count() { return previous_marked_count_; }

	// During a full GC, there is a stack-allocated GCTracer that is used for
	// bookkeeping information. Return a pointer to that tracer.
	GCTracer* tracer() { return tracer_; }

	#ifdef DEBUG
	// Checks whether performing mark-compact collection.
	bool in_use() { return state_ > PREPARE_GC; }
	bool are_map_pointers_encoded() { return state_ == UPDATE_POINTERS; }
	#endif

	// Determine type of object and emit deletion log event.
	static void ReportDeleteIfNeeded(HeapObject* obj, Isolate* isolate);

	// Returns size of a possibly marked object.
	static int SizeOfMarkedObject(HeapObject* obj);

	// Distinguishable invalid map encodings (for single word and multiple words)
	// that indicate free regions.
	static const uint32_t kSingleFreeEncoding = 0;
	static const uint32_t kMultiFreeEncoding = 1;

	inline Heap* heap() const { return heap_; }

	CodeFlusher* code_flusher() { return code_flusher_; }
	inline bool is_code_flushing_enabled() const { return code_flusher_ != NULL; }
	void EnableCodeFlushing(bool enable);

	inline Object* encountered_weak_maps() { return encountered_weak_maps_; }
	inline void set_encountered_weak_maps(Object* weak_map) {
	encountered_weak_maps_ = weak_map;
	}

	private:
	MarkCompactCollector();
	~MarkCompactCollector();

	#ifdef DEBUG
	enum CollectorState {
	IDLE,
	PREPARE_GC,
	MARK_LIVE_OBJECTS,
	SWEEP_SPACES,
	ENCODE_FORWARDING_ADDRESSES,
	UPDATE_POINTERS,
	RELOCATE_OBJECTS
	};

	// The current stage of the collector.
	CollectorState state_;
	#endif

	// Global flag that forces a compaction.
	bool force_compaction_;

	// Global flag indicating whether spaces were compacted on the last GC.
	bool compacting_collection_;

	// Global flag indicating whether spaces will be compacted on the next GC.
	bool compact_on_next_gc_;

	// The number of objects left marked at the end of the last completed full
	// GC (expected to be zero).
	int previous_marked_count_;

	// A pointer to the current stack-allocated GC tracer object during a full
	// collection (NULL before and after).
	GCTracer* tracer_;

	// Finishes GC, performs heap verification if enabled.
	void Finish();

	// -----------------------------------------------------------------------
	// Phase 1: Marking live objects.
	//
	// Before: The heap has been prepared for garbage collection by
	// MarkCompactCollector::Prepare() and is otherwise in its
	// normal state.
	//
	// After: Live objects are marked and non-live objects are unmarked.


	friend class RootMarkingVisitor;
	friend class MarkingVisitor;
	friend class StaticMarkingVisitor;
	friend class CodeMarkingVisitor;
	friend class SharedFunctionInfoMarkingVisitor;

	// Mark non-optimize code for functions inlined into the given optimized
	// code. This will prevent it from being flushed.
	void MarkInlinedFunctionsCode(Code* code);

	// Mark code objects that are active on the stack to prevent them
	// from being flushed.
	void PrepareThreadForCodeFlushing(Isolate* isolate, ThreadLocalTop* top);

	void PrepareForCodeFlushing();

	// Marking operations for objects reachable from roots.
	void MarkLiveObjects();

	void MarkUnmarkedObject(HeapObject* obj);

	inline void MarkObject(HeapObject* obj) {
	if (!obj->IsMarked()) MarkUnmarkedObject(obj);
	}

	inline void SetMark(HeapObject* obj);

	// Creates back pointers for all map transitions, stores them in
	// the prototype field. The original prototype pointers are restored
	// in ClearNonLiveTransitions(). All JSObject maps
	// connected by map transitions have the same prototype object, which
	// is why we can use this field temporarily for back pointers.
	void CreateBackPointers();

	// Mark a Map and its DescriptorArray together, skipping transitions.
	void MarkMapContents(Map* map);
	void MarkDescriptorArray(DescriptorArray* descriptors);

	// Mark the heap roots and all objects reachable from them.
	void MarkRoots(RootMarkingVisitor* visitor);

	// Mark the symbol table specially. References to symbols from the
	// symbol table are weak.
	void MarkSymbolTable();

	// Mark objects in object groups that have at least one object in the
	// group marked.
	void MarkObjectGroups();

	// Mark objects in implicit references groups if their parent object
	// is marked.
	void MarkImplicitRefGroups();

	// Mark all objects which are reachable due to host application
	// logic like object groups or implicit references' groups.
	void ProcessExternalMarking();

	// Mark objects reachable (transitively) from objects in the marking stack
	// or overflowed in the heap.
	void ProcessMarkingStack();

	// Mark objects reachable (transitively) from objects in the marking
	// stack. This function empties the marking stack, but may leave
	// overflowed objects in the heap, in which case the marking stack's
	// overflow flag will be set.
	void EmptyMarkingStack();

	// Refill the marking stack with overflowed objects from the heap. This
	// function either leaves the marking stack full or clears the overflow
	// flag on the marking stack.
	void RefillMarkingStack();

	// After reachable maps have been marked process per context object
	// literal map caches removing unmarked entries.
	void ProcessMapCaches();

	// Callback function for telling whether the object *p is an unmarked
	// heap object.
	static bool IsUnmarkedHeapObject(Object** p);

	#ifdef DEBUG
	void UpdateLiveObjectCount(HeapObject* obj);
	#endif

	// We sweep the large object space in the same way whether we are
	// compacting or not, because the large object space is never compacted.
	void SweepLargeObjectSpace();

	// Test whether a (possibly marked) object is a Map.
	static inline bool SafeIsMap(HeapObject* object);

	// Map transitions from a live map to a dead map must be killed.
	// We replace them with a null descriptor, with the same key.
	void ClearNonLiveTransitions();

	// Mark all values associated with reachable keys in weak maps encountered
	// so far. This might push new object or even new weak maps onto the
	// marking stack.
	void ProcessWeakMaps();

	// After all reachable objects have been marked those weak map entries
	// with an unreachable key are removed from all encountered weak maps.
	// The linked list of all encountered weak maps is destroyed.
	void ClearWeakMaps();

	// -----------------------------------------------------------------------
	// Phase 2: Sweeping to clear mark bits and free non-live objects for
	// a non-compacting collection, or else computing and encoding
	// forwarding addresses for a compacting collection.
	//
	// Before: Live objects are marked and non-live objects are unmarked.
	//
	// After: (Non-compacting collection.) Live objects are unmarked,
	// non-live regions have been added to their space's free
	// list.
	//
	// After: (Compacting collection.) The forwarding address of live
	// objects in the paged spaces is encoded in their map word
	// along with their (non-forwarded) map pointer.
	//
	// The forwarding address of live objects in the new space is
	// written to their map word's offset in the inactive
	// semispace.
	//
	// Bookkeeping data is written to the page header of
	// eached paged-space page that contains live objects after
	// compaction:
	//
	// The allocation watermark field is used to track the
	// relocation top address, the address of the first word
	// after the end of the last live object in the page after
	// compaction.
	//
	// The Page::mc_page_index field contains the zero-based index of the
	// page in its space. This word is only used for map space pages, in
	// order to encode the map addresses in 21 bits to free 11
	// bits per map word for the forwarding address.
	//
	// The Page::mc_first_forwarded field contains the (nonencoded)
	// forwarding address of the first live object in the page.
	//
	// In both the new space and the paged spaces, a linked list
	// of live regions is constructructed (linked through
	// pointers in the non-live region immediately following each
	// live region) to speed further passes of the collector.

	// Encodes forwarding addresses of objects in compactable parts of the
	// heap.
	void EncodeForwardingAddresses();

	// Encodes the forwarding addresses of objects in new space.
	void EncodeForwardingAddressesInNewSpace();

	// Function template to encode the forwarding addresses of objects in
	// paged spaces, parameterized by allocation and non-live processing
	// functions.
	template<AllocationFunction Alloc, ProcessNonLiveFunction ProcessNonLive>
	void EncodeForwardingAddressesInPagedSpace(PagedSpace* space);

	// Iterates live objects in a space, passes live objects
	// to a callback function which returns the heap size of the object.
	// Returns the number of live objects iterated.
	int IterateLiveObjects(NewSpace* space, LiveObjectCallback size_f);
	int IterateLiveObjects(PagedSpace* space, LiveObjectCallback size_f);

	// Iterates the live objects between a range of addresses, returning the
	// number of live objects.
	int IterateLiveObjectsInRange(Address start, Address end,
	LiveObjectCallback size_func);

	// If we are not compacting the heap, we simply sweep the spaces except
	// for the large object space, clearing mark bits and adding unmarked
	// regions to each space's free list.
	void SweepSpaces();

	// -----------------------------------------------------------------------
	// Phase 3: Updating pointers in live objects.
	//
	// Before: Same as after phase 2 (compacting collection).
	//
	// After: All pointers in live objects, including encoded map
	// pointers, are updated to point to their target's new
	// location.

	friend class UpdatingVisitor; // helper for updating visited objects

	// Updates pointers in all spaces.
	void UpdatePointers();

	// Updates pointers in an object in new space.
	// Returns the heap size of the object.
	int UpdatePointersInNewObject(HeapObject* obj);

	// Updates pointers in an object in old spaces.
	// Returns the heap size of the object.
	int UpdatePointersInOldObject(HeapObject* obj);

	// Calculates the forwarding address of an object in an old space.
	static Address GetForwardingAddressInOldSpace(HeapObject* obj);

	// -----------------------------------------------------------------------
	// Phase 4: Relocating objects.
	//
	// Before: Pointers to live objects are updated to point to their
	// target's new location.
	//
	// After: Objects have been moved to their new addresses.

	// Relocates objects in all spaces.
	void RelocateObjects();

	// Converts a code object's inline target to addresses, convention from
	// address to target happens in the marking phase.
	int ConvertCodeICTargetToAddress(HeapObject* obj);

	// Relocate a map object.
	int RelocateMapObject(HeapObject* obj);

	// Relocates an old object.
	int RelocateOldPointerObject(HeapObject* obj);
	int RelocateOldDataObject(HeapObject* obj);

	// Relocate a property cell object.
	int RelocateCellObject(HeapObject* obj);

	// Helper function.
	inline int RelocateOldNonCodeObject(HeapObject* obj,
	PagedSpace* space);

	// Relocates an object in the code space.
	int RelocateCodeObject(HeapObject* obj);

	// Copy a new object.
	int RelocateNewObject(HeapObject* obj);

	#ifdef DEBUG
	// -----------------------------------------------------------------------
	// Debugging variables, functions and classes
	// Counters used for debugging the marking phase of mark-compact or
	// mark-sweep collection.

	// Size of live objects in Heap::to_space_.
	int live_young_objects_size_;

	// Size of live objects in Heap::old_pointer_space_.
	int live_old_pointer_objects_size_;

	// Size of live objects in Heap::old_data_space_.
	int live_old_data_objects_size_;

	// Size of live objects in Heap::code_space_.
	int live_code_objects_size_;

	// Size of live objects in Heap::map_space_.
	int live_map_objects_size_;

	// Size of live objects in Heap::cell_space_.
	int live_cell_objects_size_;

	// Size of live objects in Heap::lo_space_.
	int live_lo_objects_size_;

	// Number of live bytes in this collection.
	int live_bytes_;

	friend class MarkObjectVisitor;
	static void VisitObject(HeapObject* obj);

	friend class UnmarkObjectVisitor;
	static void UnmarkObject(HeapObject* obj);
	#endif

	Heap* heap_;
	MarkingStack marking_stack_;
	CodeFlusher* code_flusher_;
	Object* encountered_weak_maps_;

	friend class Heap;
	friend class OverflowedObjectsScanner;
	};


	} } // namespace v8::internal

	#endif // V8_MARK_COMPACT_H_