src/heap/spaces-inl.h - platform/external/v8 - Git at Google

 // Copyright 2011 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_SPACES_INL_H_
 #define V8_HEAP_SPACES_INL_H_

 #include "src/heap/incremental-marking.h"
 #include "src/heap/spaces.h"
 #include "src/isolate.h"
 #include "src/msan.h"
 #include "src/profiler/heap-profiler.h"
 #include "src/v8memory.h"

 namespace v8 {
 namespace internal {


 // -----------------------------------------------------------------------------
 // Bitmap

 void Bitmap::Clear(MemoryChunk* chunk) {
   Bitmap* bitmap = chunk->markbits();
   for (int i = 0; i < bitmap->CellsCount(); i++) bitmap->cells()[i] = 0;
   chunk->ResetLiveBytes();
 }


 // -----------------------------------------------------------------------------
 // PageIterator

 PageIterator::PageIterator(PagedSpace* space)
     : space_(space),
       prev_page_(&space->anchor_),
       next_page_(prev_page_->next_page()) {}


 bool PageIterator::has_next() { return next_page_ != &space_->anchor_; }


 Page* PageIterator::next() {
   DCHECK(has_next());
   prev_page_ = next_page_;
   next_page_ = next_page_->next_page();
   return prev_page_;
 }


 // -----------------------------------------------------------------------------
 // SemiSpaceIterator

 HeapObject* SemiSpaceIterator::Next() {
   while (current_ != limit_) {
     if (NewSpacePage::IsAtEnd(current_)) {
       NewSpacePage* page = NewSpacePage::FromLimit(current_);
       page = page->next_page();
       DCHECK(!page->is_anchor());
       current_ = page->area_start();
       if (current_ == limit_) return nullptr;
     }
     HeapObject* object = HeapObject::FromAddress(current_);
     current_ += object->Size();
     if (!object->IsFiller()) {
       return object;
     }
   }
   return nullptr;
 }


 HeapObject* SemiSpaceIterator::next_object() { return Next(); }


 // -----------------------------------------------------------------------------
 // NewSpacePageIterator

 NewSpacePageIterator::NewSpacePageIterator(NewSpace* space)
     : prev_page_(NewSpacePage::FromAddress(space->ToSpaceStart())->prev_page()),
       next_page_(NewSpacePage::FromAddress(space->ToSpaceStart())),
       last_page_(NewSpacePage::FromLimit(space->ToSpaceEnd())) {}

 NewSpacePageIterator::NewSpacePageIterator(SemiSpace* space)
     : prev_page_(space->anchor()),
       next_page_(prev_page_->next_page()),
       last_page_(prev_page_->prev_page()) {}

 NewSpacePageIterator::NewSpacePageIterator(Address start, Address limit)
     : prev_page_(NewSpacePage::FromAddress(start)->prev_page()),
       next_page_(NewSpacePage::FromAddress(start)),
       last_page_(NewSpacePage::FromLimit(limit)) {
   SemiSpace::AssertValidRange(start, limit);
 }


 bool NewSpacePageIterator::has_next() { return prev_page_ != last_page_; }


 NewSpacePage* NewSpacePageIterator::next() {
   DCHECK(has_next());
   prev_page_ = next_page_;
   next_page_ = next_page_->next_page();
   return prev_page_;
 }


 // -----------------------------------------------------------------------------
 // HeapObjectIterator

 HeapObject* HeapObjectIterator::Next() {
   do {
     HeapObject* next_obj = FromCurrentPage();
     if (next_obj != NULL) return next_obj;
   } while (AdvanceToNextPage());
   return NULL;
 }


 HeapObject* HeapObjectIterator::next_object() { return Next(); }


 HeapObject* HeapObjectIterator::FromCurrentPage() {
   while (cur_addr_ != cur_end_) {
     if (cur_addr_ == space_->top() && cur_addr_ != space_->limit()) {
       cur_addr_ = space_->limit();
       continue;
     }
     HeapObject* obj = HeapObject::FromAddress(cur_addr_);
     int obj_size = obj->Size();
     cur_addr_ += obj_size;
     DCHECK(cur_addr_ <= cur_end_);
     // TODO(hpayer): Remove the debugging code.
     if (cur_addr_ > cur_end_) {
       space_->heap()->isolate()->PushStackTraceAndDie(0xaaaaaaaa, obj, NULL,
                                                       obj_size);
     }

     if (!obj->IsFiller()) {
       if (obj->IsCode()) {
         DCHECK_EQ(space_, space_->heap()->code_space());
         DCHECK_CODEOBJECT_SIZE(obj_size, space_);
       } else {
         DCHECK_OBJECT_SIZE(obj_size);
       }
       return obj;
     }
   }
   return NULL;
 }


 // -----------------------------------------------------------------------------
 // MemoryAllocator

 #ifdef ENABLE_HEAP_PROTECTION

 void MemoryAllocator::Protect(Address start, size_t size) {
   base::OS::Protect(start, size);
 }


 void MemoryAllocator::Unprotect(Address start, size_t size,
                                 Executability executable) {
   base::OS::Unprotect(start, size, executable);
 }


 void MemoryAllocator::ProtectChunkFromPage(Page* page) {
   int id = GetChunkId(page);
   base::OS::Protect(chunks_[id].address(), chunks_[id].size());
 }


 void MemoryAllocator::UnprotectChunkFromPage(Page* page) {
   int id = GetChunkId(page);
   base::OS::Unprotect(chunks_[id].address(), chunks_[id].size(),
                       chunks_[id].owner()->executable() == EXECUTABLE);
 }

 #endif

 // -----------------------------------------------------------------------------
 // SemiSpace

 bool SemiSpace::Contains(HeapObject* o) {
   return id_ == kToSpace
              ? MemoryChunk::FromAddress(o->address())->InToSpace()
              : MemoryChunk::FromAddress(o->address())->InFromSpace();
 }

 bool SemiSpace::Contains(Object* o) {
   return o->IsHeapObject() && Contains(HeapObject::cast(o));
 }

 bool SemiSpace::ContainsSlow(Address a) {
   NewSpacePageIterator it(this);
   while (it.has_next()) {
     if (it.next() == MemoryChunk::FromAddress(a)) return true;
   }
   return false;
 }

 // --------------------------------------------------------------------------
 // NewSpace

 bool NewSpace::Contains(HeapObject* o) {
   return MemoryChunk::FromAddress(o->address())->InNewSpace();
 }

 bool NewSpace::Contains(Object* o) {
   return o->IsHeapObject() && Contains(HeapObject::cast(o));
 }

 bool NewSpace::ContainsSlow(Address a) {
   return from_space_.ContainsSlow(a) || to_space_.ContainsSlow(a);
 }

 bool NewSpace::ToSpaceContainsSlow(Address a) {
   return to_space_.ContainsSlow(a);
 }

 bool NewSpace::FromSpaceContainsSlow(Address a) {
   return from_space_.ContainsSlow(a);
 }

 bool NewSpace::ToSpaceContains(Object* o) { return to_space_.Contains(o); }
 bool NewSpace::FromSpaceContains(Object* o) { return from_space_.Contains(o); }

 // --------------------------------------------------------------------------
 // AllocationResult

 AllocationSpace AllocationResult::RetrySpace() {
   DCHECK(IsRetry());
   return static_cast<AllocationSpace>(Smi::cast(object_)->value());
 }


 // --------------------------------------------------------------------------
 // PagedSpace

 Page* Page::Initialize(Heap* heap, MemoryChunk* chunk, Executability executable,
                        PagedSpace* owner) {
   Page* page = reinterpret_cast<Page*>(chunk);
   page->mutex_ = new base::Mutex();
   DCHECK(page->area_size() <= kAllocatableMemory);
   DCHECK(chunk->owner() == owner);
   owner->IncreaseCapacity(page->area_size());
   owner->Free(page->area_start(), page->area_size());

   heap->incremental_marking()->SetOldSpacePageFlags(chunk);

   return page;
 }

 void MemoryChunk::IncrementLiveBytesFromGC(HeapObject* object, int by) {
   MemoryChunk::FromAddress(object->address())->IncrementLiveBytes(by);
 }

 void MemoryChunk::ResetLiveBytes() {
   if (FLAG_trace_live_bytes) {
     PrintIsolate(heap()->isolate(), "live-bytes: reset page=%p %d->0\n", this,
                  live_byte_count_);
   }
   live_byte_count_ = 0;
 }

 void MemoryChunk::IncrementLiveBytes(int by) {
   if (FLAG_trace_live_bytes) {
     PrintIsolate(heap()->isolate(),
                  "live-bytes: update page=%p delta=%d %d->%d\n", this, by,
                  live_byte_count_, live_byte_count_ + by);
   }
   live_byte_count_ += by;
   DCHECK_GE(live_byte_count_, 0);
   DCHECK_LE(static_cast<size_t>(live_byte_count_), size_);
 }

 void MemoryChunk::IncrementLiveBytesFromMutator(HeapObject* object, int by) {
   MemoryChunk* chunk = MemoryChunk::FromAddress(object->address());
   if (!chunk->InNewSpace() && !static_cast<Page*>(chunk)->SweepingDone()) {
     static_cast<PagedSpace*>(chunk->owner())->Allocate(by);
   }
   chunk->IncrementLiveBytes(by);
 }

 bool PagedSpace::Contains(Address addr) {
   Page* p = Page::FromAddress(addr);
   if (!p->is_valid()) return false;
   return p->owner() == this;
 }

 bool PagedSpace::Contains(Object* o) {
   if (!o->IsHeapObject()) return false;
   Page* p = Page::FromAddress(HeapObject::cast(o)->address());
   if (!p->is_valid()) return false;
   return p->owner() == this;
 }

 MemoryChunk* MemoryChunk::FromAnyPointerAddress(Heap* heap, Address addr) {
   MemoryChunk* chunk = MemoryChunk::FromAddress(addr);
   uintptr_t offset = addr - chunk->address();
   if (offset < MemoryChunk::kHeaderSize || !chunk->HasPageHeader()) {
     chunk = heap->lo_space()->FindPage(addr);
   }
   return chunk;
 }

 Page* Page::FromAnyPointerAddress(Heap* heap, Address addr) {
   return static_cast<Page*>(MemoryChunk::FromAnyPointerAddress(heap, addr));
 }


 PointerChunkIterator::PointerChunkIterator(Heap* heap)
     : state_(kOldSpaceState),
       old_iterator_(heap->old_space()),
       map_iterator_(heap->map_space()),
       lo_iterator_(heap->lo_space()) {}


 MemoryChunk* PointerChunkIterator::next() {
   switch (state_) {
     case kOldSpaceState: {
       if (old_iterator_.has_next()) {
         return old_iterator_.next();
       }
       state_ = kMapState;
       // Fall through.
     }
     case kMapState: {
       if (map_iterator_.has_next()) {
         return map_iterator_.next();
       }
       state_ = kLargeObjectState;
       // Fall through.
     }
     case kLargeObjectState: {
       HeapObject* heap_object;
       do {
         heap_object = lo_iterator_.Next();
         if (heap_object == NULL) {
           state_ = kFinishedState;
           return NULL;
         }
         // Fixed arrays are the only pointer-containing objects in large
         // object space.
       } while (!heap_object->IsFixedArray());
       MemoryChunk* answer = MemoryChunk::FromAddress(heap_object->address());
       return answer;
     }
     case kFinishedState:
       return NULL;
     default:
       break;
   }
   UNREACHABLE();
   return NULL;
 }


 void Page::set_next_page(Page* page) {
   DCHECK(page->owner() == owner());
   set_next_chunk(page);
 }


 void Page::set_prev_page(Page* page) {
   DCHECK(page->owner() == owner());
   set_prev_chunk(page);
 }


 // Try linear allocation in the page of alloc_info's allocation top.  Does
 // not contain slow case logic (e.g. move to the next page or try free list
 // allocation) so it can be used by all the allocation functions and for all
 // the paged spaces.
 HeapObject* PagedSpace::AllocateLinearly(int size_in_bytes) {
   Address current_top = allocation_info_.top();
   Address new_top = current_top + size_in_bytes;
   if (new_top > allocation_info_.limit()) return NULL;

   allocation_info_.set_top(new_top);
   return HeapObject::FromAddress(current_top);
 }


 AllocationResult LocalAllocationBuffer::AllocateRawAligned(
     int size_in_bytes, AllocationAlignment alignment) {
   Address current_top = allocation_info_.top();
   int filler_size = Heap::GetFillToAlign(current_top, alignment);

   Address new_top = current_top + filler_size + size_in_bytes;
   if (new_top > allocation_info_.limit()) return AllocationResult::Retry();

   allocation_info_.set_top(new_top);
   if (filler_size > 0) {
     return heap_->PrecedeWithFiller(HeapObject::FromAddress(current_top),
                                     filler_size);
   }

   return AllocationResult(HeapObject::FromAddress(current_top));
 }


 HeapObject* PagedSpace::AllocateLinearlyAligned(int* size_in_bytes,
                                                 AllocationAlignment alignment) {
   Address current_top = allocation_info_.top();
   int filler_size = Heap::GetFillToAlign(current_top, alignment);

   Address new_top = current_top + filler_size + *size_in_bytes;
   if (new_top > allocation_info_.limit()) return NULL;

   allocation_info_.set_top(new_top);
   if (filler_size > 0) {
     *size_in_bytes += filler_size;
     return heap()->PrecedeWithFiller(HeapObject::FromAddress(current_top),
                                      filler_size);
   }

   return HeapObject::FromAddress(current_top);
 }


 // Raw allocation.
 AllocationResult PagedSpace::AllocateRawUnaligned(int size_in_bytes) {
   HeapObject* object = AllocateLinearly(size_in_bytes);

   if (object == NULL) {
     object = free_list_.Allocate(size_in_bytes);
     if (object == NULL) {
       object = SlowAllocateRaw(size_in_bytes);
     }
   }

   if (object != NULL) {
     if (identity() == CODE_SPACE) {
       SkipList::Update(object->address(), size_in_bytes);
     }
     MSAN_ALLOCATED_UNINITIALIZED_MEMORY(object->address(), size_in_bytes);
     return object;
   }

   return AllocationResult::Retry(identity());
 }


 AllocationResult PagedSpace::AllocateRawUnalignedSynchronized(
     int size_in_bytes) {
   base::LockGuard<base::Mutex> lock_guard(&space_mutex_);
   return AllocateRawUnaligned(size_in_bytes);
 }


 // Raw allocation.
 AllocationResult PagedSpace::AllocateRawAligned(int size_in_bytes,
                                                 AllocationAlignment alignment) {
   DCHECK(identity() == OLD_SPACE);
   int allocation_size = size_in_bytes;
   HeapObject* object = AllocateLinearlyAligned(&allocation_size, alignment);

   if (object == NULL) {
     // We don't know exactly how much filler we need to align until space is
     // allocated, so assume the worst case.
     int filler_size = Heap::GetMaximumFillToAlign(alignment);
     allocation_size += filler_size;
     object = free_list_.Allocate(allocation_size);
     if (object == NULL) {
       object = SlowAllocateRaw(allocation_size);
     }
     if (object != NULL && filler_size != 0) {
       object = heap()->AlignWithFiller(object, size_in_bytes, allocation_size,
                                        alignment);
       // Filler objects are initialized, so mark only the aligned object memory
       // as uninitialized.
       allocation_size = size_in_bytes;
     }
   }

   if (object != NULL) {
     MSAN_ALLOCATED_UNINITIALIZED_MEMORY(object->address(), allocation_size);
     return object;
   }

   return AllocationResult::Retry(identity());
 }


 AllocationResult PagedSpace::AllocateRaw(int size_in_bytes,
                                          AllocationAlignment alignment) {
 #ifdef V8_HOST_ARCH_32_BIT
   AllocationResult result =
       alignment == kDoubleAligned
           ? AllocateRawAligned(size_in_bytes, kDoubleAligned)
           : AllocateRawUnaligned(size_in_bytes);
 #else
   AllocationResult result = AllocateRawUnaligned(size_in_bytes);
 #endif
   HeapObject* heap_obj = nullptr;
   if (!result.IsRetry() && result.To(&heap_obj)) {
     AllocationStep(heap_obj->address(), size_in_bytes);
   }
   return result;
 }


 // -----------------------------------------------------------------------------
 // NewSpace


 AllocationResult NewSpace::AllocateRawAligned(int size_in_bytes,
                                               AllocationAlignment alignment) {
   Address top = allocation_info_.top();
   int filler_size = Heap::GetFillToAlign(top, alignment);
   int aligned_size_in_bytes = size_in_bytes + filler_size;

   if (allocation_info_.limit() - top < aligned_size_in_bytes) {
     // See if we can create room.
     if (!EnsureAllocation(size_in_bytes, alignment)) {
       return AllocationResult::Retry();
     }

     top = allocation_info_.top();
     filler_size = Heap::GetFillToAlign(top, alignment);
     aligned_size_in_bytes = size_in_bytes + filler_size;
   }

   HeapObject* obj = HeapObject::FromAddress(top);
   allocation_info_.set_top(top + aligned_size_in_bytes);
   DCHECK_SEMISPACE_ALLOCATION_INFO(allocation_info_, to_space_);

   if (filler_size > 0) {
     obj = heap()->PrecedeWithFiller(obj, filler_size);
   }

   MSAN_ALLOCATED_UNINITIALIZED_MEMORY(obj->address(), size_in_bytes);

   return obj;
 }


 AllocationResult NewSpace::AllocateRawUnaligned(int size_in_bytes) {
   Address top = allocation_info_.top();
   if (allocation_info_.limit() < top + size_in_bytes) {
     // See if we can create room.
     if (!EnsureAllocation(size_in_bytes, kWordAligned)) {
       return AllocationResult::Retry();
     }

     top = allocation_info_.top();
   }

   HeapObject* obj = HeapObject::FromAddress(top);
   allocation_info_.set_top(top + size_in_bytes);
   DCHECK_SEMISPACE_ALLOCATION_INFO(allocation_info_, to_space_);

   MSAN_ALLOCATED_UNINITIALIZED_MEMORY(obj->address(), size_in_bytes);

   return obj;
 }


 AllocationResult NewSpace::AllocateRaw(int size_in_bytes,
                                        AllocationAlignment alignment) {
 #ifdef V8_HOST_ARCH_32_BIT
   return alignment == kDoubleAligned
              ? AllocateRawAligned(size_in_bytes, kDoubleAligned)
              : AllocateRawUnaligned(size_in_bytes);
 #else
   return AllocateRawUnaligned(size_in_bytes);
 #endif
 }


 MUST_USE_RESULT inline AllocationResult NewSpace::AllocateRawSynchronized(
     int size_in_bytes, AllocationAlignment alignment) {
   base::LockGuard<base::Mutex> guard(&mutex_);
   return AllocateRaw(size_in_bytes, alignment);
 }


 LargePage* LargePage::Initialize(Heap* heap, MemoryChunk* chunk) {
   heap->incremental_marking()->SetOldSpacePageFlags(chunk);
   return static_cast<LargePage*>(chunk);
 }


 intptr_t LargeObjectSpace::Available() {
   return ObjectSizeFor(heap()->isolate()->memory_allocator()->Available());
 }


 LocalAllocationBuffer LocalAllocationBuffer::InvalidBuffer() {
   return LocalAllocationBuffer(nullptr, AllocationInfo(nullptr, nullptr));
 }


 LocalAllocationBuffer LocalAllocationBuffer::FromResult(Heap* heap,
                                                         AllocationResult result,
                                                         intptr_t size) {
   if (result.IsRetry()) return InvalidBuffer();
   HeapObject* obj = nullptr;
   bool ok = result.To(&obj);
   USE(ok);
   DCHECK(ok);
   Address top = HeapObject::cast(obj)->address();
   return LocalAllocationBuffer(heap, AllocationInfo(top, top + size));
 }


 bool LocalAllocationBuffer::TryMerge(LocalAllocationBuffer* other) {
   if (allocation_info_.top() == other->allocation_info_.limit()) {
     allocation_info_.set_top(other->allocation_info_.top());
     other->allocation_info_.Reset(nullptr, nullptr);
     return true;
   }
   return false;
 }

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_HEAP_SPACES_INL_H_
	// Copyright 2011 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_SPACES_INL_H_
	#define V8_HEAP_SPACES_INL_H_

	#include "src/heap/incremental-marking.h"
	#include "src/heap/spaces.h"
	#include "src/isolate.h"
	#include "src/msan.h"
	#include "src/profiler/heap-profiler.h"
	#include "src/v8memory.h"

	namespace v8 {
	namespace internal {


	// -----------------------------------------------------------------------------
	// Bitmap

	void Bitmap::Clear(MemoryChunk* chunk) {
	Bitmap* bitmap = chunk->markbits();
	for (int i = 0; i < bitmap->CellsCount(); i++) bitmap->cells()[i] = 0;
	chunk->ResetLiveBytes();
	}


	// -----------------------------------------------------------------------------
	// PageIterator

	PageIterator::PageIterator(PagedSpace* space)
	: space_(space),
	prev_page_(&space->anchor_),
	next_page_(prev_page_->next_page()) {}


	bool PageIterator::has_next() { return next_page_ != &space_->anchor_; }


	Page* PageIterator::next() {
	DCHECK(has_next());
	prev_page_ = next_page_;
	next_page_ = next_page_->next_page();
	return prev_page_;
	}


	// -----------------------------------------------------------------------------
	// SemiSpaceIterator

	HeapObject* SemiSpaceIterator::Next() {
	while (current_ != limit_) {
	if (NewSpacePage::IsAtEnd(current_)) {
	NewSpacePage* page = NewSpacePage::FromLimit(current_);
	page = page->next_page();
	DCHECK(!page->is_anchor());
	current_ = page->area_start();
	if (current_ == limit_) return nullptr;
	}
	HeapObject* object = HeapObject::FromAddress(current_);
	current_ += object->Size();
	if (!object->IsFiller()) {
	return object;
	}
	}
	return nullptr;
	}


	HeapObject* SemiSpaceIterator::next_object() { return Next(); }


	// -----------------------------------------------------------------------------
	// NewSpacePageIterator

	NewSpacePageIterator::NewSpacePageIterator(NewSpace* space)
	: prev_page_(NewSpacePage::FromAddress(space->ToSpaceStart())->prev_page()),
	next_page_(NewSpacePage::FromAddress(space->ToSpaceStart())),
	last_page_(NewSpacePage::FromLimit(space->ToSpaceEnd())) {}

	NewSpacePageIterator::NewSpacePageIterator(SemiSpace* space)
	: prev_page_(space->anchor()),
	next_page_(prev_page_->next_page()),
	last_page_(prev_page_->prev_page()) {}

	NewSpacePageIterator::NewSpacePageIterator(Address start, Address limit)
	: prev_page_(NewSpacePage::FromAddress(start)->prev_page()),
	next_page_(NewSpacePage::FromAddress(start)),
	last_page_(NewSpacePage::FromLimit(limit)) {
	SemiSpace::AssertValidRange(start, limit);
	}


	bool NewSpacePageIterator::has_next() { return prev_page_ != last_page_; }


	NewSpacePage* NewSpacePageIterator::next() {
	DCHECK(has_next());
	prev_page_ = next_page_;
	next_page_ = next_page_->next_page();
	return prev_page_;
	}


	// -----------------------------------------------------------------------------
	// HeapObjectIterator

	HeapObject* HeapObjectIterator::Next() {
	do {
	HeapObject* next_obj = FromCurrentPage();
	if (next_obj != NULL) return next_obj;
	} while (AdvanceToNextPage());
	return NULL;
	}


	HeapObject* HeapObjectIterator::next_object() { return Next(); }


	HeapObject* HeapObjectIterator::FromCurrentPage() {
	while (cur_addr_ != cur_end_) {
	if (cur_addr_ == space_->top() && cur_addr_ != space_->limit()) {
	cur_addr_ = space_->limit();
	continue;
	}
	HeapObject* obj = HeapObject::FromAddress(cur_addr_);
	int obj_size = obj->Size();
	cur_addr_ += obj_size;
	DCHECK(cur_addr_ <= cur_end_);
	// TODO(hpayer): Remove the debugging code.
	if (cur_addr_ > cur_end_) {
	space_->heap()->isolate()->PushStackTraceAndDie(0xaaaaaaaa, obj, NULL,
	obj_size);
	}

	if (!obj->IsFiller()) {
	if (obj->IsCode()) {
	DCHECK_EQ(space_, space_->heap()->code_space());
	DCHECK_CODEOBJECT_SIZE(obj_size, space_);
	} else {
	DCHECK_OBJECT_SIZE(obj_size);
	}
	return obj;
	}
	}
	return NULL;
	}


	// -----------------------------------------------------------------------------
	// MemoryAllocator

	#ifdef ENABLE_HEAP_PROTECTION

	void MemoryAllocator::Protect(Address start, size_t size) {
	base::OS::Protect(start, size);
	}


	void MemoryAllocator::Unprotect(Address start, size_t size,
	Executability executable) {
	base::OS::Unprotect(start, size, executable);
	}


	void MemoryAllocator::ProtectChunkFromPage(Page* page) {
	int id = GetChunkId(page);
	base::OS::Protect(chunks_[id].address(), chunks_[id].size());
	}


	void MemoryAllocator::UnprotectChunkFromPage(Page* page) {
	int id = GetChunkId(page);
	base::OS::Unprotect(chunks_[id].address(), chunks_[id].size(),
	chunks_[id].owner()->executable() == EXECUTABLE);
	}

	#endif

	// -----------------------------------------------------------------------------
	// SemiSpace

	bool SemiSpace::Contains(HeapObject* o) {
	return id_ == kToSpace
	? MemoryChunk::FromAddress(o->address())->InToSpace()
	: MemoryChunk::FromAddress(o->address())->InFromSpace();
	}

	bool SemiSpace::Contains(Object* o) {
	return o->IsHeapObject() && Contains(HeapObject::cast(o));
	}

	bool SemiSpace::ContainsSlow(Address a) {
	NewSpacePageIterator it(this);
	while (it.has_next()) {
	if (it.next() == MemoryChunk::FromAddress(a)) return true;
	}
	return false;
	}

	// --------------------------------------------------------------------------
	// NewSpace

	bool NewSpace::Contains(HeapObject* o) {
	return MemoryChunk::FromAddress(o->address())->InNewSpace();
	}

	bool NewSpace::Contains(Object* o) {
	return o->IsHeapObject() && Contains(HeapObject::cast(o));
	}

	bool NewSpace::ContainsSlow(Address a) {
	return from_space_.ContainsSlow(a) \|\| to_space_.ContainsSlow(a);
	}

	bool NewSpace::ToSpaceContainsSlow(Address a) {
	return to_space_.ContainsSlow(a);
	}

	bool NewSpace::FromSpaceContainsSlow(Address a) {
	return from_space_.ContainsSlow(a);
	}

	bool NewSpace::ToSpaceContains(Object* o) { return to_space_.Contains(o); }
	bool NewSpace::FromSpaceContains(Object* o) { return from_space_.Contains(o); }

	// --------------------------------------------------------------------------
	// AllocationResult

	AllocationSpace AllocationResult::RetrySpace() {
	DCHECK(IsRetry());
	return static_cast<AllocationSpace>(Smi::cast(object_)->value());
	}


	// --------------------------------------------------------------------------
	// PagedSpace

	Page* Page::Initialize(Heap* heap, MemoryChunk* chunk, Executability executable,
	PagedSpace* owner) {
	Page* page = reinterpret_cast<Page*>(chunk);
	page->mutex_ = new base::Mutex();
	DCHECK(page->area_size() <= kAllocatableMemory);
	DCHECK(chunk->owner() == owner);
	owner->IncreaseCapacity(page->area_size());
	owner->Free(page->area_start(), page->area_size());

	heap->incremental_marking()->SetOldSpacePageFlags(chunk);

	return page;
	}

	void MemoryChunk::IncrementLiveBytesFromGC(HeapObject* object, int by) {
	MemoryChunk::FromAddress(object->address())->IncrementLiveBytes(by);
	}

	void MemoryChunk::ResetLiveBytes() {
	if (FLAG_trace_live_bytes) {
	PrintIsolate(heap()->isolate(), "live-bytes: reset page=%p %d->0\n", this,
	live_byte_count_);
	}
	live_byte_count_ = 0;
	}

	void MemoryChunk::IncrementLiveBytes(int by) {
	if (FLAG_trace_live_bytes) {
	PrintIsolate(heap()->isolate(),
	"live-bytes: update page=%p delta=%d %d->%d\n", this, by,
	live_byte_count_, live_byte_count_ + by);
	}
	live_byte_count_ += by;
	DCHECK_GE(live_byte_count_, 0);
	DCHECK_LE(static_cast<size_t>(live_byte_count_), size_);
	}

	void MemoryChunk::IncrementLiveBytesFromMutator(HeapObject* object, int by) {
	MemoryChunk* chunk = MemoryChunk::FromAddress(object->address());
	if (!chunk->InNewSpace() && !static_cast<Page*>(chunk)->SweepingDone()) {
	static_cast<PagedSpace*>(chunk->owner())->Allocate(by);
	}
	chunk->IncrementLiveBytes(by);
	}

	bool PagedSpace::Contains(Address addr) {
	Page* p = Page::FromAddress(addr);
	if (!p->is_valid()) return false;
	return p->owner() == this;
	}

	bool PagedSpace::Contains(Object* o) {
	if (!o->IsHeapObject()) return false;
	Page* p = Page::FromAddress(HeapObject::cast(o)->address());
	if (!p->is_valid()) return false;
	return p->owner() == this;
	}

	MemoryChunk* MemoryChunk::FromAnyPointerAddress(Heap* heap, Address addr) {
	MemoryChunk* chunk = MemoryChunk::FromAddress(addr);
	uintptr_t offset = addr - chunk->address();
	if (offset < MemoryChunk::kHeaderSize \|\| !chunk->HasPageHeader()) {
	chunk = heap->lo_space()->FindPage(addr);
	}
	return chunk;
	}

	Page* Page::FromAnyPointerAddress(Heap* heap, Address addr) {
	return static_cast<Page*>(MemoryChunk::FromAnyPointerAddress(heap, addr));
	}


	PointerChunkIterator::PointerChunkIterator(Heap* heap)
	: state_(kOldSpaceState),
	old_iterator_(heap->old_space()),
	map_iterator_(heap->map_space()),
	lo_iterator_(heap->lo_space()) {}


	MemoryChunk* PointerChunkIterator::next() {
	switch (state_) {
	case kOldSpaceState: {
	if (old_iterator_.has_next()) {
	return old_iterator_.next();
	}
	state_ = kMapState;
	// Fall through.
	}
	case kMapState: {
	if (map_iterator_.has_next()) {
	return map_iterator_.next();
	}
	state_ = kLargeObjectState;
	// Fall through.
	}
	case kLargeObjectState: {
	HeapObject* heap_object;
	do {
	heap_object = lo_iterator_.Next();
	if (heap_object == NULL) {
	state_ = kFinishedState;
	return NULL;
	}
	// Fixed arrays are the only pointer-containing objects in large
	// object space.
	} while (!heap_object->IsFixedArray());
	MemoryChunk* answer = MemoryChunk::FromAddress(heap_object->address());
	return answer;
	}
	case kFinishedState:
	return NULL;
	default:
	break;
	}
	UNREACHABLE();
	return NULL;
	}


	void Page::set_next_page(Page* page) {
	DCHECK(page->owner() == owner());
	set_next_chunk(page);
	}


	void Page::set_prev_page(Page* page) {
	DCHECK(page->owner() == owner());
	set_prev_chunk(page);
	}


	// Try linear allocation in the page of alloc_info's allocation top. Does
	// not contain slow case logic (e.g. move to the next page or try free list
	// allocation) so it can be used by all the allocation functions and for all
	// the paged spaces.
	HeapObject* PagedSpace::AllocateLinearly(int size_in_bytes) {
	Address current_top = allocation_info_.top();
	Address new_top = current_top + size_in_bytes;
	if (new_top > allocation_info_.limit()) return NULL;

	allocation_info_.set_top(new_top);
	return HeapObject::FromAddress(current_top);
	}


	AllocationResult LocalAllocationBuffer::AllocateRawAligned(
	int size_in_bytes, AllocationAlignment alignment) {
	Address current_top = allocation_info_.top();
	int filler_size = Heap::GetFillToAlign(current_top, alignment);

	Address new_top = current_top + filler_size + size_in_bytes;
	if (new_top > allocation_info_.limit()) return AllocationResult::Retry();

	allocation_info_.set_top(new_top);
	if (filler_size > 0) {
	return heap_->PrecedeWithFiller(HeapObject::FromAddress(current_top),
	filler_size);
	}

	return AllocationResult(HeapObject::FromAddress(current_top));
	}


	HeapObject* PagedSpace::AllocateLinearlyAligned(int* size_in_bytes,
	AllocationAlignment alignment) {
	Address current_top = allocation_info_.top();
	int filler_size = Heap::GetFillToAlign(current_top, alignment);

	Address new_top = current_top + filler_size + *size_in_bytes;
	if (new_top > allocation_info_.limit()) return NULL;

	allocation_info_.set_top(new_top);
	if (filler_size > 0) {
	*size_in_bytes += filler_size;
	return heap()->PrecedeWithFiller(HeapObject::FromAddress(current_top),
	filler_size);
	}

	return HeapObject::FromAddress(current_top);
	}


	// Raw allocation.
	AllocationResult PagedSpace::AllocateRawUnaligned(int size_in_bytes) {
	HeapObject* object = AllocateLinearly(size_in_bytes);

	if (object == NULL) {
	object = free_list_.Allocate(size_in_bytes);
	if (object == NULL) {
	object = SlowAllocateRaw(size_in_bytes);
	}
	}

	if (object != NULL) {
	if (identity() == CODE_SPACE) {
	SkipList::Update(object->address(), size_in_bytes);
	}
	MSAN_ALLOCATED_UNINITIALIZED_MEMORY(object->address(), size_in_bytes);
	return object;
	}

	return AllocationResult::Retry(identity());
	}


	AllocationResult PagedSpace::AllocateRawUnalignedSynchronized(
	int size_in_bytes) {
	base::LockGuard<base::Mutex> lock_guard(&space_mutex_);
	return AllocateRawUnaligned(size_in_bytes);
	}


	// Raw allocation.
	AllocationResult PagedSpace::AllocateRawAligned(int size_in_bytes,
	AllocationAlignment alignment) {
	DCHECK(identity() == OLD_SPACE);
	int allocation_size = size_in_bytes;
	HeapObject* object = AllocateLinearlyAligned(&allocation_size, alignment);

	if (object == NULL) {
	// We don't know exactly how much filler we need to align until space is
	// allocated, so assume the worst case.
	int filler_size = Heap::GetMaximumFillToAlign(alignment);
	allocation_size += filler_size;
	object = free_list_.Allocate(allocation_size);
	if (object == NULL) {
	object = SlowAllocateRaw(allocation_size);
	}
	if (object != NULL && filler_size != 0) {
	object = heap()->AlignWithFiller(object, size_in_bytes, allocation_size,
	alignment);
	// Filler objects are initialized, so mark only the aligned object memory
	// as uninitialized.
	allocation_size = size_in_bytes;
	}
	}

	if (object != NULL) {
	MSAN_ALLOCATED_UNINITIALIZED_MEMORY(object->address(), allocation_size);
	return object;
	}

	return AllocationResult::Retry(identity());
	}


	AllocationResult PagedSpace::AllocateRaw(int size_in_bytes,
	AllocationAlignment alignment) {
	#ifdef V8_HOST_ARCH_32_BIT
	AllocationResult result =
	alignment == kDoubleAligned
	? AllocateRawAligned(size_in_bytes, kDoubleAligned)
	: AllocateRawUnaligned(size_in_bytes);
	#else
	AllocationResult result = AllocateRawUnaligned(size_in_bytes);
	#endif
	HeapObject* heap_obj = nullptr;
	if (!result.IsRetry() && result.To(&heap_obj)) {
	AllocationStep(heap_obj->address(), size_in_bytes);
	}
	return result;
	}


	// -----------------------------------------------------------------------------
	// NewSpace


	AllocationResult NewSpace::AllocateRawAligned(int size_in_bytes,
	AllocationAlignment alignment) {
	Address top = allocation_info_.top();
	int filler_size = Heap::GetFillToAlign(top, alignment);
	int aligned_size_in_bytes = size_in_bytes + filler_size;

	if (allocation_info_.limit() - top < aligned_size_in_bytes) {
	// See if we can create room.
	if (!EnsureAllocation(size_in_bytes, alignment)) {
	return AllocationResult::Retry();
	}

	top = allocation_info_.top();
	filler_size = Heap::GetFillToAlign(top, alignment);
	aligned_size_in_bytes = size_in_bytes + filler_size;
	}

	HeapObject* obj = HeapObject::FromAddress(top);
	allocation_info_.set_top(top + aligned_size_in_bytes);
	DCHECK_SEMISPACE_ALLOCATION_INFO(allocation_info_, to_space_);

	if (filler_size > 0) {
	obj = heap()->PrecedeWithFiller(obj, filler_size);
	}

	MSAN_ALLOCATED_UNINITIALIZED_MEMORY(obj->address(), size_in_bytes);

	return obj;
	}


	AllocationResult NewSpace::AllocateRawUnaligned(int size_in_bytes) {
	Address top = allocation_info_.top();
	if (allocation_info_.limit() < top + size_in_bytes) {
	// See if we can create room.
	if (!EnsureAllocation(size_in_bytes, kWordAligned)) {
	return AllocationResult::Retry();
	}

	top = allocation_info_.top();
	}

	HeapObject* obj = HeapObject::FromAddress(top);
	allocation_info_.set_top(top + size_in_bytes);
	DCHECK_SEMISPACE_ALLOCATION_INFO(allocation_info_, to_space_);

	MSAN_ALLOCATED_UNINITIALIZED_MEMORY(obj->address(), size_in_bytes);

	return obj;
	}


	AllocationResult NewSpace::AllocateRaw(int size_in_bytes,
	AllocationAlignment alignment) {
	#ifdef V8_HOST_ARCH_32_BIT
	return alignment == kDoubleAligned
	? AllocateRawAligned(size_in_bytes, kDoubleAligned)
	: AllocateRawUnaligned(size_in_bytes);
	#else
	return AllocateRawUnaligned(size_in_bytes);
	#endif
	}


	MUST_USE_RESULT inline AllocationResult NewSpace::AllocateRawSynchronized(
	int size_in_bytes, AllocationAlignment alignment) {
	base::LockGuard<base::Mutex> guard(&mutex_);
	return AllocateRaw(size_in_bytes, alignment);
	}


	LargePage* LargePage::Initialize(Heap* heap, MemoryChunk* chunk) {
	heap->incremental_marking()->SetOldSpacePageFlags(chunk);
	return static_cast<LargePage*>(chunk);
	}


	intptr_t LargeObjectSpace::Available() {
	return ObjectSizeFor(heap()->isolate()->memory_allocator()->Available());
	}


	LocalAllocationBuffer LocalAllocationBuffer::InvalidBuffer() {
	return LocalAllocationBuffer(nullptr, AllocationInfo(nullptr, nullptr));
	}


	LocalAllocationBuffer LocalAllocationBuffer::FromResult(Heap* heap,
	AllocationResult result,
	intptr_t size) {
	if (result.IsRetry()) return InvalidBuffer();
	HeapObject* obj = nullptr;
	bool ok = result.To(&obj);
	USE(ok);
	DCHECK(ok);
	Address top = HeapObject::cast(obj)->address();
	return LocalAllocationBuffer(heap, AllocationInfo(top, top + size));
	}


	bool LocalAllocationBuffer::TryMerge(LocalAllocationBuffer* other) {
	if (allocation_info_.top() == other->allocation_info_.limit()) {
	allocation_info_.set_top(other->allocation_info_.top());
	other->allocation_info_.Reset(nullptr, nullptr);
	return true;
	}
	return false;
	}

	} // namespace internal
	} // namespace v8

	#endif // V8_HEAP_SPACES_INL_H_