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

 // Copyright 2006-2010 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_SPACES_INL_H_
 #define V8_SPACES_INL_H_

 #include "isolate.h"
 #include "spaces.h"
 #include "v8memory.h"

 namespace v8 {
 namespace internal {


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

 bool PageIterator::has_next() {
   return prev_page_ != stop_page_;
 }


 Page* PageIterator::next() {
   ASSERT(has_next());
   prev_page_ = (prev_page_ == NULL)
                ? space_->first_page_
                : prev_page_->next_page();
   return prev_page_;
 }


 // -----------------------------------------------------------------------------
 // Page

 Page* Page::next_page() {
   return heap_->isolate()->memory_allocator()->GetNextPage(this);
 }


 Address Page::AllocationTop() {
   PagedSpace* owner = heap_->isolate()->memory_allocator()->PageOwner(this);
   return owner->PageAllocationTop(this);
 }


 Address Page::AllocationWatermark() {
   PagedSpace* owner = heap_->isolate()->memory_allocator()->PageOwner(this);
   if (this == owner->AllocationTopPage()) {
     return owner->top();
   }
   return address() + AllocationWatermarkOffset();
 }


 uint32_t Page::AllocationWatermarkOffset() {
   return static_cast<uint32_t>((flags_ & kAllocationWatermarkOffsetMask) >>
                                kAllocationWatermarkOffsetShift);
 }


 void Page::SetAllocationWatermark(Address allocation_watermark) {
   if ((heap_->gc_state() == Heap::SCAVENGE) && IsWatermarkValid()) {
     // When iterating intergenerational references during scavenge
     // we might decide to promote an encountered young object.
     // We will allocate a space for such an object and put it
     // into the promotion queue to process it later.
     // If space for object was allocated somewhere beyond allocation
     // watermark this might cause garbage pointers to appear under allocation
     // watermark. To avoid visiting them during dirty regions iteration
     // which might be still in progress we store a valid allocation watermark
     // value and mark this page as having an invalid watermark.
     SetCachedAllocationWatermark(AllocationWatermark());
     InvalidateWatermark(true);
   }

   flags_ = (flags_ & kFlagsMask) |
            Offset(allocation_watermark) << kAllocationWatermarkOffsetShift;
   ASSERT(AllocationWatermarkOffset()
          == static_cast<uint32_t>(Offset(allocation_watermark)));
 }


 void Page::SetCachedAllocationWatermark(Address allocation_watermark) {
   mc_first_forwarded = allocation_watermark;
 }


 Address Page::CachedAllocationWatermark() {
   return mc_first_forwarded;
 }


 uint32_t Page::GetRegionMarks() {
   return dirty_regions_;
 }


 void Page::SetRegionMarks(uint32_t marks) {
   dirty_regions_ = marks;
 }


 int Page::GetRegionNumberForAddress(Address addr) {
   // Each page is divided into 256 byte regions. Each region has a corresponding
   // dirty mark bit in the page header. Region can contain intergenerational
   // references iff its dirty mark is set.
   // A normal 8K page contains exactly 32 regions so all region marks fit
   // into 32-bit integer field. To calculate a region number we just divide
   // offset inside page by region size.
   // A large page can contain more then 32 regions. But we want to avoid
   // additional write barrier code for distinguishing between large and normal
   // pages so we just ignore the fact that addr points into a large page and
   // calculate region number as if addr pointed into a normal 8K page. This way
   // we get a region number modulo 32 so for large pages several regions might
   // be mapped to a single dirty mark.
   ASSERT_PAGE_ALIGNED(this->address());
   STATIC_ASSERT((kPageAlignmentMask >> kRegionSizeLog2) < kBitsPerInt);

   // We are using masking with kPageAlignmentMask instead of Page::Offset()
   // to get an offset to the beginning of 8K page containing addr not to the
   // beginning of actual page which can be bigger then 8K.
   intptr_t offset_inside_normal_page = OffsetFrom(addr) & kPageAlignmentMask;
   return static_cast<int>(offset_inside_normal_page >> kRegionSizeLog2);
 }


 uint32_t Page::GetRegionMaskForAddress(Address addr) {
   return 1 << GetRegionNumberForAddress(addr);
 }


 uint32_t Page::GetRegionMaskForSpan(Address start, int length_in_bytes) {
   uint32_t result = 0;
   if (length_in_bytes >= kPageSize) {
     result = kAllRegionsDirtyMarks;
   } else if (length_in_bytes > 0) {
     int start_region = GetRegionNumberForAddress(start);
     int end_region =
         GetRegionNumberForAddress(start + length_in_bytes - kPointerSize);
     uint32_t start_mask = (~0) << start_region;
     uint32_t end_mask = ~((~1) << end_region);
     result = start_mask & end_mask;
     // if end_region < start_region, the mask is ored.
     if (result == 0) result = start_mask | end_mask;
   }
 #ifdef DEBUG
   if (FLAG_enable_slow_asserts) {
     uint32_t expected = 0;
     for (Address a = start; a < start + length_in_bytes; a += kPointerSize) {
       expected |= GetRegionMaskForAddress(a);
     }
     ASSERT(expected == result);
   }
 #endif
   return result;
 }


 void Page::MarkRegionDirty(Address address) {
   SetRegionMarks(GetRegionMarks() | GetRegionMaskForAddress(address));
 }


 bool Page::IsRegionDirty(Address address) {
   return GetRegionMarks() & GetRegionMaskForAddress(address);
 }


 void Page::ClearRegionMarks(Address start, Address end, bool reaches_limit) {
   int rstart = GetRegionNumberForAddress(start);
   int rend = GetRegionNumberForAddress(end);

   if (reaches_limit) {
     end += 1;
   }

   if ((rend - rstart) == 0) {
     return;
   }

   uint32_t bitmask = 0;

   if ((OffsetFrom(start) & kRegionAlignmentMask) == 0
       || (start == ObjectAreaStart())) {
     // First region is fully covered
     bitmask = 1 << rstart;
   }

   while (++rstart < rend) {
     bitmask |= 1 << rstart;
   }

   if (bitmask) {
     SetRegionMarks(GetRegionMarks() & ~bitmask);
   }
 }


 void Page::FlipMeaningOfInvalidatedWatermarkFlag(Heap* heap) {
   heap->page_watermark_invalidated_mark_ ^= 1 << WATERMARK_INVALIDATED;
 }


 bool Page::IsWatermarkValid() {
   return (flags_ & (1 << WATERMARK_INVALIDATED)) !=
       heap_->page_watermark_invalidated_mark_;
 }


 void Page::InvalidateWatermark(bool value) {
   if (value) {
     flags_ = (flags_ & ~(1 << WATERMARK_INVALIDATED)) |
              heap_->page_watermark_invalidated_mark_;
   } else {
     flags_ =
         (flags_ & ~(1 << WATERMARK_INVALIDATED)) |
         (heap_->page_watermark_invalidated_mark_ ^
          (1 << WATERMARK_INVALIDATED));
   }

   ASSERT(IsWatermarkValid() == !value);
 }


 bool Page::GetPageFlag(PageFlag flag) {
   return (flags_ & static_cast<intptr_t>(1 << flag)) != 0;
 }


 void Page::SetPageFlag(PageFlag flag, bool value) {
   if (value) {
     flags_ |= static_cast<intptr_t>(1 << flag);
   } else {
     flags_ &= ~static_cast<intptr_t>(1 << flag);
   }
 }


 void Page::ClearPageFlags() {
   flags_ = 0;
 }


 void Page::ClearGCFields() {
   InvalidateWatermark(true);
   SetAllocationWatermark(ObjectAreaStart());
   if (heap_->gc_state() == Heap::SCAVENGE) {
     SetCachedAllocationWatermark(ObjectAreaStart());
   }
   SetRegionMarks(kAllRegionsCleanMarks);
 }


 bool Page::WasInUseBeforeMC() {
   return GetPageFlag(WAS_IN_USE_BEFORE_MC);
 }


 void Page::SetWasInUseBeforeMC(bool was_in_use) {
   SetPageFlag(WAS_IN_USE_BEFORE_MC, was_in_use);
 }


 bool Page::IsLargeObjectPage() {
   return !GetPageFlag(IS_NORMAL_PAGE);
 }


 void Page::SetIsLargeObjectPage(bool is_large_object_page) {
   SetPageFlag(IS_NORMAL_PAGE, !is_large_object_page);
 }

 bool Page::IsPageExecutable() {
   return GetPageFlag(IS_EXECUTABLE);
 }


 void Page::SetIsPageExecutable(bool is_page_executable) {
   SetPageFlag(IS_EXECUTABLE, is_page_executable);
 }


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

 void MemoryAllocator::ChunkInfo::init(Address a, size_t s, PagedSpace* o) {
   address_ = a;
   size_ = s;
   owner_ = o;
   executable_ = (o == NULL) ? NOT_EXECUTABLE : o->executable();
   owner_identity_ = (o == NULL) ? FIRST_SPACE : o->identity();
 }


 bool MemoryAllocator::IsValidChunk(int chunk_id) {
   if (!IsValidChunkId(chunk_id)) return false;

   ChunkInfo& c = chunks_[chunk_id];
   return (c.address() != NULL) && (c.size() != 0) && (c.owner() != NULL);
 }


 bool MemoryAllocator::IsValidChunkId(int chunk_id) {
   return (0 <= chunk_id) && (chunk_id < max_nof_chunks_);
 }


 bool MemoryAllocator::IsPageInSpace(Page* p, PagedSpace* space) {
   ASSERT(p->is_valid());

   int chunk_id = GetChunkId(p);
   if (!IsValidChunkId(chunk_id)) return false;

   ChunkInfo& c = chunks_[chunk_id];
   return (c.address() <= p->address()) &&
          (p->address() < c.address() + c.size()) &&
          (space == c.owner());
 }


 Page* MemoryAllocator::GetNextPage(Page* p) {
   ASSERT(p->is_valid());
   intptr_t raw_addr = p->opaque_header & ~Page::kPageAlignmentMask;
   return Page::FromAddress(AddressFrom<Address>(raw_addr));
 }


 int MemoryAllocator::GetChunkId(Page* p) {
   ASSERT(p->is_valid());
   return static_cast<int>(p->opaque_header & Page::kPageAlignmentMask);
 }


 void MemoryAllocator::SetNextPage(Page* prev, Page* next) {
   ASSERT(prev->is_valid());
   int chunk_id = GetChunkId(prev);
   ASSERT_PAGE_ALIGNED(next->address());
   prev->opaque_header = OffsetFrom(next->address()) | chunk_id;
 }


 PagedSpace* MemoryAllocator::PageOwner(Page* page) {
   int chunk_id = GetChunkId(page);
   ASSERT(IsValidChunk(chunk_id));
   return chunks_[chunk_id].owner();
 }


 bool MemoryAllocator::InInitialChunk(Address address) {
   if (initial_chunk_ == NULL) return false;

   Address start = static_cast<Address>(initial_chunk_->address());
   return (start <= address) && (address < start + initial_chunk_->size());
 }


 #ifdef ENABLE_HEAP_PROTECTION

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


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


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


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

 #endif


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

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


 // Try linear allocation in the page of alloc_info's allocation top.  Does
 // not contain slow case logic (eg, 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(AllocationInfo* alloc_info,
                                          int size_in_bytes) {
   Address current_top = alloc_info->top;
   Address new_top = current_top + size_in_bytes;
   if (new_top > alloc_info->limit) return NULL;

   alloc_info->top = new_top;
   ASSERT(alloc_info->VerifyPagedAllocation());
   accounting_stats_.AllocateBytes(size_in_bytes);
   return HeapObject::FromAddress(current_top);
 }


 // Raw allocation.
 MaybeObject* PagedSpace::AllocateRaw(int size_in_bytes) {
   ASSERT(HasBeenSetup());
   ASSERT_OBJECT_SIZE(size_in_bytes);
   HeapObject* object = AllocateLinearly(&allocation_info_, size_in_bytes);
   if (object != NULL) return object;

   object = SlowAllocateRaw(size_in_bytes);
   if (object != NULL) return object;

   return Failure::RetryAfterGC(identity());
 }


 // Reallocating (and promoting) objects during a compacting collection.
 MaybeObject* PagedSpace::MCAllocateRaw(int size_in_bytes) {
   ASSERT(HasBeenSetup());
   ASSERT_OBJECT_SIZE(size_in_bytes);
   HeapObject* object = AllocateLinearly(&mc_forwarding_info_, size_in_bytes);
   if (object != NULL) return object;

   object = SlowMCAllocateRaw(size_in_bytes);
   if (object != NULL) return object;

   return Failure::RetryAfterGC(identity());
 }


 // -----------------------------------------------------------------------------
 // LargeObjectChunk

 Address LargeObjectChunk::GetStartAddress() {
   // Round the chunk address up to the nearest page-aligned address
   // and return the heap object in that page.
   Page* page = Page::FromAddress(RoundUp(address(), Page::kPageSize));
   return page->ObjectAreaStart();
 }


 void LargeObjectChunk::Free(Executability executable) {
   Isolate* isolate =
       Page::FromAddress(RoundUp(address(), Page::kPageSize))->heap_->isolate();
   isolate->memory_allocator()->FreeRawMemory(address(), size(), executable);
 }

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

 MaybeObject* NewSpace::AllocateRawInternal(int size_in_bytes,
                                            AllocationInfo* alloc_info) {
   Address new_top = alloc_info->top + size_in_bytes;
   if (new_top > alloc_info->limit) return Failure::RetryAfterGC();

   Object* obj = HeapObject::FromAddress(alloc_info->top);
   alloc_info->top = new_top;
 #ifdef DEBUG
   SemiSpace* space =
       (alloc_info == &allocation_info_) ? &to_space_ : &from_space_;
   ASSERT(space->low() <= alloc_info->top
          && alloc_info->top <= space->high()
          && alloc_info->limit == space->high());
 #endif
   return obj;
 }


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


 template <typename StringType>
 void NewSpace::ShrinkStringAtAllocationBoundary(String* string, int length) {
   ASSERT(length <= string->length());
   ASSERT(string->IsSeqString());
   ASSERT(string->address() + StringType::SizeFor(string->length()) ==
          allocation_info_.top);
   allocation_info_.top =
       string->address() + StringType::SizeFor(length);
   string->set_length(length);
 }


 bool FreeListNode::IsFreeListNode(HeapObject* object) {
   return object->map() == HEAP->raw_unchecked_byte_array_map()
       || object->map() == HEAP->raw_unchecked_one_pointer_filler_map()
       || object->map() == HEAP->raw_unchecked_two_pointer_filler_map();
 }

 } }  // namespace v8::internal

 #endif  // V8_SPACES_INL_H_
	// Copyright 2006-2010 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_SPACES_INL_H_
	#define V8_SPACES_INL_H_

	#include "isolate.h"
	#include "spaces.h"
	#include "v8memory.h"

	namespace v8 {
	namespace internal {


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

	bool PageIterator::has_next() {
	return prev_page_ != stop_page_;
	}


	Page* PageIterator::next() {
	ASSERT(has_next());
	prev_page_ = (prev_page_ == NULL)
	? space_->first_page_
	: prev_page_->next_page();
	return prev_page_;
	}


	// -----------------------------------------------------------------------------
	// Page

	Page* Page::next_page() {
	return heap_->isolate()->memory_allocator()->GetNextPage(this);
	}


	Address Page::AllocationTop() {
	PagedSpace* owner = heap_->isolate()->memory_allocator()->PageOwner(this);
	return owner->PageAllocationTop(this);
	}


	Address Page::AllocationWatermark() {
	PagedSpace* owner = heap_->isolate()->memory_allocator()->PageOwner(this);
	if (this == owner->AllocationTopPage()) {
	return owner->top();
	}
	return address() + AllocationWatermarkOffset();
	}


	uint32_t Page::AllocationWatermarkOffset() {
	return static_cast<uint32_t>((flags_ & kAllocationWatermarkOffsetMask) >>
	kAllocationWatermarkOffsetShift);
	}


	void Page::SetAllocationWatermark(Address allocation_watermark) {
	if ((heap_->gc_state() == Heap::SCAVENGE) && IsWatermarkValid()) {
	// When iterating intergenerational references during scavenge
	// we might decide to promote an encountered young object.
	// We will allocate a space for such an object and put it
	// into the promotion queue to process it later.
	// If space for object was allocated somewhere beyond allocation
	// watermark this might cause garbage pointers to appear under allocation
	// watermark. To avoid visiting them during dirty regions iteration
	// which might be still in progress we store a valid allocation watermark
	// value and mark this page as having an invalid watermark.
	SetCachedAllocationWatermark(AllocationWatermark());
	InvalidateWatermark(true);
	}

	flags_ = (flags_ & kFlagsMask) \|
	Offset(allocation_watermark) << kAllocationWatermarkOffsetShift;
	ASSERT(AllocationWatermarkOffset()
	== static_cast<uint32_t>(Offset(allocation_watermark)));
	}


	void Page::SetCachedAllocationWatermark(Address allocation_watermark) {
	mc_first_forwarded = allocation_watermark;
	}


	Address Page::CachedAllocationWatermark() {
	return mc_first_forwarded;
	}


	uint32_t Page::GetRegionMarks() {
	return dirty_regions_;
	}


	void Page::SetRegionMarks(uint32_t marks) {
	dirty_regions_ = marks;
	}


	int Page::GetRegionNumberForAddress(Address addr) {
	// Each page is divided into 256 byte regions. Each region has a corresponding
	// dirty mark bit in the page header. Region can contain intergenerational
	// references iff its dirty mark is set.
	// A normal 8K page contains exactly 32 regions so all region marks fit
	// into 32-bit integer field. To calculate a region number we just divide
	// offset inside page by region size.
	// A large page can contain more then 32 regions. But we want to avoid
	// additional write barrier code for distinguishing between large and normal
	// pages so we just ignore the fact that addr points into a large page and
	// calculate region number as if addr pointed into a normal 8K page. This way
	// we get a region number modulo 32 so for large pages several regions might
	// be mapped to a single dirty mark.
	ASSERT_PAGE_ALIGNED(this->address());
	STATIC_ASSERT((kPageAlignmentMask >> kRegionSizeLog2) < kBitsPerInt);

	// We are using masking with kPageAlignmentMask instead of Page::Offset()
	// to get an offset to the beginning of 8K page containing addr not to the
	// beginning of actual page which can be bigger then 8K.
	intptr_t offset_inside_normal_page = OffsetFrom(addr) & kPageAlignmentMask;
	return static_cast<int>(offset_inside_normal_page >> kRegionSizeLog2);
	}


	uint32_t Page::GetRegionMaskForAddress(Address addr) {
	return 1 << GetRegionNumberForAddress(addr);
	}


	uint32_t Page::GetRegionMaskForSpan(Address start, int length_in_bytes) {
	uint32_t result = 0;
	if (length_in_bytes >= kPageSize) {
	result = kAllRegionsDirtyMarks;
	} else if (length_in_bytes > 0) {
	int start_region = GetRegionNumberForAddress(start);
	int end_region =
	GetRegionNumberForAddress(start + length_in_bytes - kPointerSize);
	uint32_t start_mask = (~0) << start_region;
	uint32_t end_mask = ~((~1) << end_region);
	result = start_mask & end_mask;
	// if end_region < start_region, the mask is ored.
	if (result == 0) result = start_mask \| end_mask;
	}
	#ifdef DEBUG
	if (FLAG_enable_slow_asserts) {
	uint32_t expected = 0;
	for (Address a = start; a < start + length_in_bytes; a += kPointerSize) {
	expected \|= GetRegionMaskForAddress(a);
	}
	ASSERT(expected == result);
	}
	#endif
	return result;
	}


	void Page::MarkRegionDirty(Address address) {
	SetRegionMarks(GetRegionMarks() \| GetRegionMaskForAddress(address));
	}


	bool Page::IsRegionDirty(Address address) {
	return GetRegionMarks() & GetRegionMaskForAddress(address);
	}


	void Page::ClearRegionMarks(Address start, Address end, bool reaches_limit) {
	int rstart = GetRegionNumberForAddress(start);
	int rend = GetRegionNumberForAddress(end);

	if (reaches_limit) {
	end += 1;
	}

	if ((rend - rstart) == 0) {
	return;
	}

	uint32_t bitmask = 0;

	if ((OffsetFrom(start) & kRegionAlignmentMask) == 0
	\|\| (start == ObjectAreaStart())) {
	// First region is fully covered
	bitmask = 1 << rstart;
	}

	while (++rstart < rend) {
	bitmask \|= 1 << rstart;
	}

	if (bitmask) {
	SetRegionMarks(GetRegionMarks() & ~bitmask);
	}
	}


	void Page::FlipMeaningOfInvalidatedWatermarkFlag(Heap* heap) {
	heap->page_watermark_invalidated_mark_ ^= 1 << WATERMARK_INVALIDATED;
	}


	bool Page::IsWatermarkValid() {
	return (flags_ & (1 << WATERMARK_INVALIDATED)) !=
	heap_->page_watermark_invalidated_mark_;
	}


	void Page::InvalidateWatermark(bool value) {
	if (value) {
	flags_ = (flags_ & ~(1 << WATERMARK_INVALIDATED)) \|
	heap_->page_watermark_invalidated_mark_;
	} else {
	flags_ =
	(flags_ & ~(1 << WATERMARK_INVALIDATED)) \|
	(heap_->page_watermark_invalidated_mark_ ^
	(1 << WATERMARK_INVALIDATED));
	}

	ASSERT(IsWatermarkValid() == !value);
	}


	bool Page::GetPageFlag(PageFlag flag) {
	return (flags_ & static_cast<intptr_t>(1 << flag)) != 0;
	}


	void Page::SetPageFlag(PageFlag flag, bool value) {
	if (value) {
	flags_ \|= static_cast<intptr_t>(1 << flag);
	} else {
	flags_ &= ~static_cast<intptr_t>(1 << flag);
	}
	}


	void Page::ClearPageFlags() {
	flags_ = 0;
	}


	void Page::ClearGCFields() {
	InvalidateWatermark(true);
	SetAllocationWatermark(ObjectAreaStart());
	if (heap_->gc_state() == Heap::SCAVENGE) {
	SetCachedAllocationWatermark(ObjectAreaStart());
	}
	SetRegionMarks(kAllRegionsCleanMarks);
	}


	bool Page::WasInUseBeforeMC() {
	return GetPageFlag(WAS_IN_USE_BEFORE_MC);
	}


	void Page::SetWasInUseBeforeMC(bool was_in_use) {
	SetPageFlag(WAS_IN_USE_BEFORE_MC, was_in_use);
	}


	bool Page::IsLargeObjectPage() {
	return !GetPageFlag(IS_NORMAL_PAGE);
	}


	void Page::SetIsLargeObjectPage(bool is_large_object_page) {
	SetPageFlag(IS_NORMAL_PAGE, !is_large_object_page);
	}

	bool Page::IsPageExecutable() {
	return GetPageFlag(IS_EXECUTABLE);
	}


	void Page::SetIsPageExecutable(bool is_page_executable) {
	SetPageFlag(IS_EXECUTABLE, is_page_executable);
	}


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

	void MemoryAllocator::ChunkInfo::init(Address a, size_t s, PagedSpace* o) {
	address_ = a;
	size_ = s;
	owner_ = o;
	executable_ = (o == NULL) ? NOT_EXECUTABLE : o->executable();
	owner_identity_ = (o == NULL) ? FIRST_SPACE : o->identity();
	}


	bool MemoryAllocator::IsValidChunk(int chunk_id) {
	if (!IsValidChunkId(chunk_id)) return false;

	ChunkInfo& c = chunks_[chunk_id];
	return (c.address() != NULL) && (c.size() != 0) && (c.owner() != NULL);
	}


	bool MemoryAllocator::IsValidChunkId(int chunk_id) {
	return (0 <= chunk_id) && (chunk_id < max_nof_chunks_);
	}


	bool MemoryAllocator::IsPageInSpace(Page* p, PagedSpace* space) {
	ASSERT(p->is_valid());

	int chunk_id = GetChunkId(p);
	if (!IsValidChunkId(chunk_id)) return false;

	ChunkInfo& c = chunks_[chunk_id];
	return (c.address() <= p->address()) &&
	(p->address() < c.address() + c.size()) &&
	(space == c.owner());
	}


	Page* MemoryAllocator::GetNextPage(Page* p) {
	ASSERT(p->is_valid());
	intptr_t raw_addr = p->opaque_header & ~Page::kPageAlignmentMask;
	return Page::FromAddress(AddressFrom<Address>(raw_addr));
	}


	int MemoryAllocator::GetChunkId(Page* p) {
	ASSERT(p->is_valid());
	return static_cast<int>(p->opaque_header & Page::kPageAlignmentMask);
	}


	void MemoryAllocator::SetNextPage(Page* prev, Page* next) {
	ASSERT(prev->is_valid());
	int chunk_id = GetChunkId(prev);
	ASSERT_PAGE_ALIGNED(next->address());
	prev->opaque_header = OffsetFrom(next->address()) \| chunk_id;
	}


	PagedSpace* MemoryAllocator::PageOwner(Page* page) {
	int chunk_id = GetChunkId(page);
	ASSERT(IsValidChunk(chunk_id));
	return chunks_[chunk_id].owner();
	}


	bool MemoryAllocator::InInitialChunk(Address address) {
	if (initial_chunk_ == NULL) return false;

	Address start = static_cast<Address>(initial_chunk_->address());
	return (start <= address) && (address < start + initial_chunk_->size());
	}


	#ifdef ENABLE_HEAP_PROTECTION

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


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


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


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

	#endif


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

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


	// Try linear allocation in the page of alloc_info's allocation top. Does
	// not contain slow case logic (eg, 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(AllocationInfo* alloc_info,
	int size_in_bytes) {
	Address current_top = alloc_info->top;
	Address new_top = current_top + size_in_bytes;
	if (new_top > alloc_info->limit) return NULL;

	alloc_info->top = new_top;
	ASSERT(alloc_info->VerifyPagedAllocation());
	accounting_stats_.AllocateBytes(size_in_bytes);
	return HeapObject::FromAddress(current_top);
	}


	// Raw allocation.
	MaybeObject* PagedSpace::AllocateRaw(int size_in_bytes) {
	ASSERT(HasBeenSetup());
	ASSERT_OBJECT_SIZE(size_in_bytes);
	HeapObject* object = AllocateLinearly(&allocation_info_, size_in_bytes);
	if (object != NULL) return object;

	object = SlowAllocateRaw(size_in_bytes);
	if (object != NULL) return object;

	return Failure::RetryAfterGC(identity());
	}


	// Reallocating (and promoting) objects during a compacting collection.
	MaybeObject* PagedSpace::MCAllocateRaw(int size_in_bytes) {
	ASSERT(HasBeenSetup());
	ASSERT_OBJECT_SIZE(size_in_bytes);
	HeapObject* object = AllocateLinearly(&mc_forwarding_info_, size_in_bytes);
	if (object != NULL) return object;

	object = SlowMCAllocateRaw(size_in_bytes);
	if (object != NULL) return object;

	return Failure::RetryAfterGC(identity());
	}


	// -----------------------------------------------------------------------------
	// LargeObjectChunk

	Address LargeObjectChunk::GetStartAddress() {
	// Round the chunk address up to the nearest page-aligned address
	// and return the heap object in that page.
	Page* page = Page::FromAddress(RoundUp(address(), Page::kPageSize));
	return page->ObjectAreaStart();
	}


	void LargeObjectChunk::Free(Executability executable) {
	Isolate* isolate =
	Page::FromAddress(RoundUp(address(), Page::kPageSize))->heap_->isolate();
	isolate->memory_allocator()->FreeRawMemory(address(), size(), executable);
	}

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

	MaybeObject* NewSpace::AllocateRawInternal(int size_in_bytes,
	AllocationInfo* alloc_info) {
	Address new_top = alloc_info->top + size_in_bytes;
	if (new_top > alloc_info->limit) return Failure::RetryAfterGC();

	Object* obj = HeapObject::FromAddress(alloc_info->top);
	alloc_info->top = new_top;
	#ifdef DEBUG
	SemiSpace* space =
	(alloc_info == &allocation_info_) ? &to_space_ : &from_space_;
	ASSERT(space->low() <= alloc_info->top
	&& alloc_info->top <= space->high()
	&& alloc_info->limit == space->high());
	#endif
	return obj;
	}


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


	template <typename StringType>
	void NewSpace::ShrinkStringAtAllocationBoundary(String* string, int length) {
	ASSERT(length <= string->length());
	ASSERT(string->IsSeqString());
	ASSERT(string->address() + StringType::SizeFor(string->length()) ==
	allocation_info_.top);
	allocation_info_.top =
	string->address() + StringType::SizeFor(length);
	string->set_length(length);
	}


	bool FreeListNode::IsFreeListNode(HeapObject* object) {
	return object->map() == HEAP->raw_unchecked_byte_array_map()
	\|\| object->map() == HEAP->raw_unchecked_one_pointer_filler_map()
	\|\| object->map() == HEAP->raw_unchecked_two_pointer_filler_map();
	}

	} } // namespace v8::internal

	#endif // V8_SPACES_INL_H_