src/v8/src/heap/marking.cc - cobalt - Git at Google

 // Copyright 2017 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.

 #include "src/heap/marking.h"

 namespace v8 {
 namespace internal {

 void Bitmap::Clear() {
   base::Atomic32* cell_base = reinterpret_cast<base::Atomic32*>(cells());
   for (int i = 0; i < CellsCount(); i++) {
     base::Relaxed_Store(cell_base + i, 0);
   }
   // This fence prevents re-ordering of publishing stores with the mark-bit
   // clearing stores.
   base::SeqCst_MemoryFence();
 }

 void Bitmap::SetRange(uint32_t start_index, uint32_t end_index) {
   unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);
   unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);
   if (start_cell_index != end_cell_index) {
     // Firstly, fill all bits from the start address to the end of the first
     // cell with 1s.
     SetBitsInCell<AccessMode::ATOMIC>(start_cell_index,
                                       ~(start_index_mask - 1));
     // Then fill all in between cells with 1s.
     base::Atomic32* cell_base = reinterpret_cast<base::Atomic32*>(cells());
     for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
       base::Relaxed_Store(cell_base + i, ~0u);
     }
     // Finally, fill all bits until the end address in the last cell with 1s.
     SetBitsInCell<AccessMode::ATOMIC>(end_cell_index, (end_index_mask - 1));
   } else {
     SetBitsInCell<AccessMode::ATOMIC>(start_cell_index,
                                       end_index_mask - start_index_mask);
   }
   // This fence prevents re-ordering of publishing stores with the mark-
   // bit setting stores.
   base::SeqCst_MemoryFence();
 }

 void Bitmap::ClearRange(uint32_t start_index, uint32_t end_index) {
   unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);

   unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);

   if (start_cell_index != end_cell_index) {
     // Firstly, fill all bits from the start address to the end of the first
     // cell with 0s.
     ClearBitsInCell<AccessMode::ATOMIC>(start_cell_index,
                                         ~(start_index_mask - 1));
     // Then fill all in between cells with 0s.
     base::Atomic32* cell_base = reinterpret_cast<base::Atomic32*>(cells());
     for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
       base::Relaxed_Store(cell_base + i, 0);
     }
     // Finally, set all bits until the end address in the last cell with 0s.
     ClearBitsInCell<AccessMode::ATOMIC>(end_cell_index, (end_index_mask - 1));
   } else {
     ClearBitsInCell<AccessMode::ATOMIC>(start_cell_index,
                                         (end_index_mask - start_index_mask));
   }
   // This fence prevents re-ordering of publishing stores with the mark-
   // bit clearing stores.
   base::SeqCst_MemoryFence();
 }

 bool Bitmap::AllBitsSetInRange(uint32_t start_index, uint32_t end_index) {
   unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);

   unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);

   MarkBit::CellType matching_mask;
   if (start_cell_index != end_cell_index) {
     matching_mask = ~(start_index_mask - 1);
     if ((cells()[start_cell_index] & matching_mask) != matching_mask) {
       return false;
     }
     for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
       if (cells()[i] != ~0u) return false;
     }
     matching_mask = (end_index_mask - 1);
     // Check against a mask of 0 to avoid dereferencing the cell after the
     // end of the bitmap.
     return (matching_mask == 0) ||
            ((cells()[end_cell_index] & matching_mask) == matching_mask);
   } else {
     matching_mask = end_index_mask - start_index_mask;
     // Check against a mask of 0 to avoid dereferencing the cell after the
     // end of the bitmap.
     return (matching_mask == 0) ||
            (cells()[end_cell_index] & matching_mask) == matching_mask;
   }
 }

 bool Bitmap::AllBitsClearInRange(uint32_t start_index, uint32_t end_index) {
   unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);

   unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
   MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);

   MarkBit::CellType matching_mask;
   if (start_cell_index != end_cell_index) {
     matching_mask = ~(start_index_mask - 1);
     if ((cells()[start_cell_index] & matching_mask)) return false;
     for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
       if (cells()[i]) return false;
     }
     matching_mask = (end_index_mask - 1);
     // Check against a mask of 0 to avoid dereferencing the cell after the
     // end of the bitmap.
     return (matching_mask == 0) || !(cells()[end_cell_index] & matching_mask);
   } else {
     matching_mask = end_index_mask - start_index_mask;
     // Check against a mask of 0 to avoid dereferencing the cell after the
     // end of the bitmap.
     return (matching_mask == 0) || !(cells()[end_cell_index] & matching_mask);
   }
 }

 namespace {

 void PrintWord(uint32_t word, uint32_t himask = 0) {
   for (uint32_t mask = 1; mask != 0; mask <<= 1) {
     if ((mask & himask) != 0) PrintF("[");
     PrintF((mask & word) ? "1" : "0");
     if ((mask & himask) != 0) PrintF("]");
   }
 }

 class CellPrinter {
  public:
   CellPrinter() : seq_start(0), seq_type(0), seq_length(0) {}

   void Print(uint32_t pos, uint32_t cell) {
     if (cell == seq_type) {
       seq_length++;
       return;
     }

     Flush();

     if (IsSeq(cell)) {
       seq_start = pos;
       seq_length = 0;
       seq_type = cell;
       return;
     }

     PrintF("%d: ", pos);
     PrintWord(cell);
     PrintF("\n");
   }

   void Flush() {
     if (seq_length > 0) {
       PrintF("%d: %dx%d\n", seq_start, seq_type == 0 ? 0 : 1,
              seq_length * Bitmap::kBitsPerCell);
       seq_length = 0;
     }
   }

   static bool IsSeq(uint32_t cell) { return cell == 0 || cell == 0xFFFFFFFF; }

  private:
   uint32_t seq_start;
   uint32_t seq_type;
   uint32_t seq_length;
 };

 }  // anonymous namespace

 void Bitmap::Print() {
   CellPrinter printer;
   for (int i = 0; i < CellsCount(); i++) {
     printer.Print(i, cells()[i]);
   }
   printer.Flush();
   PrintF("\n");
 }

 bool Bitmap::IsClean() {
   for (int i = 0; i < CellsCount(); i++) {
     if (cells()[i] != 0) {
       return false;
     }
   }
   return true;
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2017 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.

	#include "src/heap/marking.h"

	namespace v8 {
	namespace internal {

	void Bitmap::Clear() {
	base::Atomic32* cell_base = reinterpret_cast<base::Atomic32*>(cells());
	for (int i = 0; i < CellsCount(); i++) {
	base::Relaxed_Store(cell_base + i, 0);
	}
	// This fence prevents re-ordering of publishing stores with the mark-bit
	// clearing stores.
	base::SeqCst_MemoryFence();
	}

	void Bitmap::SetRange(uint32_t start_index, uint32_t end_index) {
	unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);
	unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);
	if (start_cell_index != end_cell_index) {
	// Firstly, fill all bits from the start address to the end of the first
	// cell with 1s.
	SetBitsInCell<AccessMode::ATOMIC>(start_cell_index,
	~(start_index_mask - 1));
	// Then fill all in between cells with 1s.
	base::Atomic32* cell_base = reinterpret_cast<base::Atomic32*>(cells());
	for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
	base::Relaxed_Store(cell_base + i, ~0u);
	}
	// Finally, fill all bits until the end address in the last cell with 1s.
	SetBitsInCell<AccessMode::ATOMIC>(end_cell_index, (end_index_mask - 1));
	} else {
	SetBitsInCell<AccessMode::ATOMIC>(start_cell_index,
	end_index_mask - start_index_mask);
	}
	// This fence prevents re-ordering of publishing stores with the mark-
	// bit setting stores.
	base::SeqCst_MemoryFence();
	}

	void Bitmap::ClearRange(uint32_t start_index, uint32_t end_index) {
	unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);

	unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);

	if (start_cell_index != end_cell_index) {
	// Firstly, fill all bits from the start address to the end of the first
	// cell with 0s.
	ClearBitsInCell<AccessMode::ATOMIC>(start_cell_index,
	~(start_index_mask - 1));
	// Then fill all in between cells with 0s.
	base::Atomic32* cell_base = reinterpret_cast<base::Atomic32*>(cells());
	for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
	base::Relaxed_Store(cell_base + i, 0);
	}
	// Finally, set all bits until the end address in the last cell with 0s.
	ClearBitsInCell<AccessMode::ATOMIC>(end_cell_index, (end_index_mask - 1));
	} else {
	ClearBitsInCell<AccessMode::ATOMIC>(start_cell_index,
	(end_index_mask - start_index_mask));
	}
	// This fence prevents re-ordering of publishing stores with the mark-
	// bit clearing stores.
	base::SeqCst_MemoryFence();
	}

	bool Bitmap::AllBitsSetInRange(uint32_t start_index, uint32_t end_index) {
	unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);

	unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);

	MarkBit::CellType matching_mask;
	if (start_cell_index != end_cell_index) {
	matching_mask = ~(start_index_mask - 1);
	if ((cells()[start_cell_index] & matching_mask) != matching_mask) {
	return false;
	}
	for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
	if (cells()[i] != ~0u) return false;
	}
	matching_mask = (end_index_mask - 1);
	// Check against a mask of 0 to avoid dereferencing the cell after the
	// end of the bitmap.
	return (matching_mask == 0) \|\|
	((cells()[end_cell_index] & matching_mask) == matching_mask);
	} else {
	matching_mask = end_index_mask - start_index_mask;
	// Check against a mask of 0 to avoid dereferencing the cell after the
	// end of the bitmap.
	return (matching_mask == 0) \|\|
	(cells()[end_cell_index] & matching_mask) == matching_mask;
	}
	}

	bool Bitmap::AllBitsClearInRange(uint32_t start_index, uint32_t end_index) {
	unsigned int start_cell_index = start_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType start_index_mask = 1u << Bitmap::IndexInCell(start_index);

	unsigned int end_cell_index = end_index >> Bitmap::kBitsPerCellLog2;
	MarkBit::CellType end_index_mask = 1u << Bitmap::IndexInCell(end_index);

	MarkBit::CellType matching_mask;
	if (start_cell_index != end_cell_index) {
	matching_mask = ~(start_index_mask - 1);
	if ((cells()[start_cell_index] & matching_mask)) return false;
	for (unsigned int i = start_cell_index + 1; i < end_cell_index; i++) {
	if (cells()[i]) return false;
	}
	matching_mask = (end_index_mask - 1);
	// Check against a mask of 0 to avoid dereferencing the cell after the
	// end of the bitmap.
	return (matching_mask == 0) \|\| !(cells()[end_cell_index] & matching_mask);
	} else {
	matching_mask = end_index_mask - start_index_mask;
	// Check against a mask of 0 to avoid dereferencing the cell after the
	// end of the bitmap.
	return (matching_mask == 0) \|\| !(cells()[end_cell_index] & matching_mask);
	}
	}

	namespace {

	void PrintWord(uint32_t word, uint32_t himask = 0) {
	for (uint32_t mask = 1; mask != 0; mask <<= 1) {
	if ((mask & himask) != 0) PrintF("[");
	PrintF((mask & word) ? "1" : "0");
	if ((mask & himask) != 0) PrintF("]");
	}
	}

	class CellPrinter {
	public:
	CellPrinter() : seq_start(0), seq_type(0), seq_length(0) {}

	void Print(uint32_t pos, uint32_t cell) {
	if (cell == seq_type) {
	seq_length++;
	return;
	}

	Flush();

	if (IsSeq(cell)) {
	seq_start = pos;
	seq_length = 0;
	seq_type = cell;
	return;
	}

	PrintF("%d: ", pos);
	PrintWord(cell);
	PrintF("\n");
	}

	void Flush() {
	if (seq_length > 0) {
	PrintF("%d: %dx%d\n", seq_start, seq_type == 0 ? 0 : 1,
	seq_length * Bitmap::kBitsPerCell);
	seq_length = 0;
	}
	}

	static bool IsSeq(uint32_t cell) { return cell == 0 \|\| cell == 0xFFFFFFFF; }

	private:
	uint32_t seq_start;
	uint32_t seq_type;
	uint32_t seq_length;
	};

	} // anonymous namespace

	void Bitmap::Print() {
	CellPrinter printer;
	for (int i = 0; i < CellsCount(); i++) {
	printer.Print(i, cells()[i]);
	}
	printer.Flush();
	PrintF("\n");
	}

	bool Bitmap::IsClean() {
	for (int i = 0; i < CellsCount(); i++) {
	if (cells()[i] != 0) {
	return false;
	}
	}
	return true;
	}

	} // namespace internal
	} // namespace v8