weex_core/Source/include/JavaScriptCore/bytecode/BytecodeLivenessAnalysisInlines.h - incubator-weex - Git at Google

 /*
  * Copyright (C) 2013, 2015 Apple Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. 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.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS 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 APPLE INC. OR ITS 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.
  */

 #pragma once

 #include "BytecodeGraph.h"
 #include "BytecodeLivenessAnalysis.h"
 #include "CodeBlock.h"
 #include "Interpreter.h"
 #include "Operations.h"

 namespace JSC {

 inline bool operandIsAlwaysLive(int operand)
 {
     return !VirtualRegister(operand).isLocal();
 }

 inline bool operandThatIsNotAlwaysLiveIsLive(const FastBitVector& out, int operand)
 {
     unsigned local = VirtualRegister(operand).toLocal();
     if (local >= out.numBits())
         return false;
     return out[local];
 }

 inline bool operandIsLive(const FastBitVector& out, int operand)
 {
     return operandIsAlwaysLive(operand) || operandThatIsNotAlwaysLiveIsLive(out, operand);
 }

 inline bool isValidRegisterForLiveness(int operand)
 {
     VirtualRegister virtualReg(operand);
     if (virtualReg.isConstant())
         return false;
     return virtualReg.isLocal();
 }

 // Simplified interface to bytecode use/def, which determines defs first and then uses, and includes
 // exception handlers in the uses.
 template<typename DerivedAnalysis>
 template<typename Graph, typename UseFunctor, typename DefFunctor>
 inline void BytecodeLivenessPropagation<DerivedAnalysis>::stepOverInstruction(Graph& graph, unsigned bytecodeOffset, FastBitVector& out, const UseFunctor& use, const DefFunctor& def)
 {
     // This abstractly execute the instruction in reverse. Instructions logically first use operands and
     // then define operands. This logical ordering is necessary for operations that use and def the same
     // operand, like:
     //
     //     op_add loc1, loc1, loc2
     //
     // The use of loc1 happens before the def of loc1. That's a semantic requirement since the add
     // operation cannot travel forward in time to read the value that it will produce after reading that
     // value. Since we are executing in reverse, this means that we must do defs before uses (reverse of
     // uses before defs).
     //
     // Since this is a liveness analysis, this ordering ends up being particularly important: if we did
     // uses before defs, then the add operation above would appear to not have loc1 live, since we'd
     // first add it to the out set (the use), and then we'd remove it (the def).

     auto* codeBlock = graph.codeBlock();
     Interpreter* interpreter = codeBlock->vm()->interpreter;
     auto* instructionsBegin = graph.instructions().begin();
     auto* instruction = &instructionsBegin[bytecodeOffset];
     OpcodeID opcodeID = interpreter->getOpcodeID(*instruction);

     static_cast<DerivedAnalysis*>(this)->computeDefsForBytecodeOffset(
         codeBlock, opcodeID, instruction, out,
         [&] (typename Graph::CodeBlock*, typename Graph::Instruction*, OpcodeID, int operand) {
             if (isValidRegisterForLiveness(operand))
                 def(VirtualRegister(operand).toLocal());
         });

     static_cast<DerivedAnalysis*>(this)->computeUsesForBytecodeOffset(
         codeBlock, opcodeID, instruction, out,
         [&] (typename Graph::CodeBlock*, typename Graph::Instruction*, OpcodeID, int operand) {
             if (isValidRegisterForLiveness(operand))
                 use(VirtualRegister(operand).toLocal());
         });

     // If we have an exception handler, we want the live-in variables of the
     // exception handler block to be included in the live-in of this particular bytecode.
     if (auto* handler = codeBlock->handlerForBytecodeOffset(bytecodeOffset)) {
         BytecodeBasicBlock* handlerBlock = graph.findBasicBlockWithLeaderOffset(handler->target);
         ASSERT(handlerBlock);
         handlerBlock->in().forEachSetBit(use);
     }
 }

 template<typename DerivedAnalysis>
 template<typename Graph>
 inline void BytecodeLivenessPropagation<DerivedAnalysis>::stepOverInstruction(Graph& graph, unsigned bytecodeOffset, FastBitVector& out)
 {
     stepOverInstruction(
         graph, bytecodeOffset, out,
         [&] (unsigned bitIndex) {
             // This is the use functor, so we set the bit.
             out[bitIndex] = true;
         },
         [&] (unsigned bitIndex) {
             // This is the def functor, so we clear the bit.
             out[bitIndex] = false;
         });
 }

 template<typename DerivedAnalysis>
 template<typename Graph>
 inline bool BytecodeLivenessPropagation<DerivedAnalysis>::computeLocalLivenessForBytecodeOffset(Graph& graph, BytecodeBasicBlock* block, unsigned targetOffset, FastBitVector& result)
 {
     ASSERT(!block->isExitBlock());
     ASSERT(!block->isEntryBlock());

     FastBitVector out = block->out();

     for (int i = block->offsets().size() - 1; i >= 0; i--) {
         unsigned bytecodeOffset = block->offsets()[i];
         if (targetOffset > bytecodeOffset)
             break;
         stepOverInstruction(graph, bytecodeOffset, out);
     }

     return result.setAndCheck(out);
 }

 template<typename DerivedAnalysis>
 template<typename Graph>
 inline bool BytecodeLivenessPropagation<DerivedAnalysis>::computeLocalLivenessForBlock(Graph& graph, BytecodeBasicBlock* block)
 {
     if (block->isExitBlock() || block->isEntryBlock())
         return false;
     return computeLocalLivenessForBytecodeOffset(graph, block, block->leaderOffset(), block->in());
 }

 template<typename DerivedAnalysis>
 template<typename Graph>
 inline FastBitVector BytecodeLivenessPropagation<DerivedAnalysis>::getLivenessInfoAtBytecodeOffset(Graph& graph, unsigned bytecodeOffset)
 {
     BytecodeBasicBlock* block = graph.findBasicBlockForBytecodeOffset(bytecodeOffset);
     ASSERT(block);
     ASSERT(!block->isEntryBlock());
     ASSERT(!block->isExitBlock());
     FastBitVector out;
     out.resize(block->out().numBits());
     computeLocalLivenessForBytecodeOffset(graph, block, bytecodeOffset, out);
     return out;
 }

 template<typename DerivedAnalysis>
 template<typename Graph>
 inline void BytecodeLivenessPropagation<DerivedAnalysis>::runLivenessFixpoint(Graph& graph)
 {
     auto* codeBlock = graph.codeBlock();
     unsigned numberOfVariables = codeBlock->numCalleeLocals();
     for (BytecodeBasicBlock* block : graph) {
         block->in().resize(numberOfVariables);
         block->out().resize(numberOfVariables);
         block->in().clearAll();
         block->out().clearAll();
     }

     bool changed;
     BytecodeBasicBlock* lastBlock = graph.last();
     lastBlock->in().clearAll();
     lastBlock->out().clearAll();
     FastBitVector newOut;
     newOut.resize(lastBlock->out().numBits());
     do {
         changed = false;
         for (std::unique_ptr<BytecodeBasicBlock>& block : graph.basicBlocksInReverseOrder()) {
             newOut.clearAll();
             for (BytecodeBasicBlock* successor : block->successors())
                 newOut |= successor->in();
             block->out() = newOut;
             changed |= computeLocalLivenessForBlock(graph, block.get());
         }
     } while (changed);
 }

 } // namespace JSC
	/*
	* Copyright (C) 2013, 2015 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. 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.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS 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 APPLE INC. OR ITS 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.
	*/

	#pragma once

	#include "BytecodeGraph.h"
	#include "BytecodeLivenessAnalysis.h"
	#include "CodeBlock.h"
	#include "Interpreter.h"
	#include "Operations.h"

	namespace JSC {

	inline bool operandIsAlwaysLive(int operand)
	{
	return !VirtualRegister(operand).isLocal();
	}

	inline bool operandThatIsNotAlwaysLiveIsLive(const FastBitVector& out, int operand)
	{
	unsigned local = VirtualRegister(operand).toLocal();
	if (local >= out.numBits())
	return false;
	return out[local];
	}

	inline bool operandIsLive(const FastBitVector& out, int operand)
	{
	return operandIsAlwaysLive(operand) \|\| operandThatIsNotAlwaysLiveIsLive(out, operand);
	}

	inline bool isValidRegisterForLiveness(int operand)
	{
	VirtualRegister virtualReg(operand);
	if (virtualReg.isConstant())
	return false;
	return virtualReg.isLocal();
	}

	// Simplified interface to bytecode use/def, which determines defs first and then uses, and includes
	// exception handlers in the uses.
	template<typename DerivedAnalysis>
	template<typename Graph, typename UseFunctor, typename DefFunctor>
	inline void BytecodeLivenessPropagation<DerivedAnalysis>::stepOverInstruction(Graph& graph, unsigned bytecodeOffset, FastBitVector& out, const UseFunctor& use, const DefFunctor& def)
	{
	// This abstractly execute the instruction in reverse. Instructions logically first use operands and
	// then define operands. This logical ordering is necessary for operations that use and def the same
	// operand, like:
	//
	// op_add loc1, loc1, loc2
	//
	// The use of loc1 happens before the def of loc1. That's a semantic requirement since the add
	// operation cannot travel forward in time to read the value that it will produce after reading that
	// value. Since we are executing in reverse, this means that we must do defs before uses (reverse of
	// uses before defs).
	//
	// Since this is a liveness analysis, this ordering ends up being particularly important: if we did
	// uses before defs, then the add operation above would appear to not have loc1 live, since we'd
	// first add it to the out set (the use), and then we'd remove it (the def).

	auto* codeBlock = graph.codeBlock();
	Interpreter* interpreter = codeBlock->vm()->interpreter;
	auto* instructionsBegin = graph.instructions().begin();
	auto* instruction = &instructionsBegin[bytecodeOffset];
	OpcodeID opcodeID = interpreter->getOpcodeID(*instruction);

	static_cast<DerivedAnalysis*>(this)->computeDefsForBytecodeOffset(
	codeBlock, opcodeID, instruction, out,
	[&] (typename Graph::CodeBlock, typename Graph::Instruction, OpcodeID, int operand) {
	if (isValidRegisterForLiveness(operand))
	def(VirtualRegister(operand).toLocal());
	});

	static_cast<DerivedAnalysis*>(this)->computeUsesForBytecodeOffset(
	codeBlock, opcodeID, instruction, out,
	[&] (typename Graph::CodeBlock, typename Graph::Instruction, OpcodeID, int operand) {
	if (isValidRegisterForLiveness(operand))
	use(VirtualRegister(operand).toLocal());
	});

	// If we have an exception handler, we want the live-in variables of the
	// exception handler block to be included in the live-in of this particular bytecode.
	if (auto* handler = codeBlock->handlerForBytecodeOffset(bytecodeOffset)) {
	BytecodeBasicBlock* handlerBlock = graph.findBasicBlockWithLeaderOffset(handler->target);
	ASSERT(handlerBlock);
	handlerBlock->in().forEachSetBit(use);
	}
	}

	template<typename DerivedAnalysis>
	template<typename Graph>
	inline void BytecodeLivenessPropagation<DerivedAnalysis>::stepOverInstruction(Graph& graph, unsigned bytecodeOffset, FastBitVector& out)
	{
	stepOverInstruction(
	graph, bytecodeOffset, out,
	[&] (unsigned bitIndex) {
	// This is the use functor, so we set the bit.
	out[bitIndex] = true;
	},
	[&] (unsigned bitIndex) {
	// This is the def functor, so we clear the bit.
	out[bitIndex] = false;
	});
	}

	template<typename DerivedAnalysis>
	template<typename Graph>
	inline bool BytecodeLivenessPropagation<DerivedAnalysis>::computeLocalLivenessForBytecodeOffset(Graph& graph, BytecodeBasicBlock* block, unsigned targetOffset, FastBitVector& result)
	{
	ASSERT(!block->isExitBlock());
	ASSERT(!block->isEntryBlock());

	FastBitVector out = block->out();

	for (int i = block->offsets().size() - 1; i >= 0; i--) {
	unsigned bytecodeOffset = block->offsets()[i];
	if (targetOffset > bytecodeOffset)
	break;
	stepOverInstruction(graph, bytecodeOffset, out);
	}

	return result.setAndCheck(out);
	}

	template<typename DerivedAnalysis>
	template<typename Graph>
	inline bool BytecodeLivenessPropagation<DerivedAnalysis>::computeLocalLivenessForBlock(Graph& graph, BytecodeBasicBlock* block)
	{
	if (block->isExitBlock() \|\| block->isEntryBlock())
	return false;
	return computeLocalLivenessForBytecodeOffset(graph, block, block->leaderOffset(), block->in());
	}

	template<typename DerivedAnalysis>
	template<typename Graph>
	inline FastBitVector BytecodeLivenessPropagation<DerivedAnalysis>::getLivenessInfoAtBytecodeOffset(Graph& graph, unsigned bytecodeOffset)
	{
	BytecodeBasicBlock* block = graph.findBasicBlockForBytecodeOffset(bytecodeOffset);
	ASSERT(block);
	ASSERT(!block->isEntryBlock());
	ASSERT(!block->isExitBlock());
	FastBitVector out;
	out.resize(block->out().numBits());
	computeLocalLivenessForBytecodeOffset(graph, block, bytecodeOffset, out);
	return out;
	}

	template<typename DerivedAnalysis>
	template<typename Graph>
	inline void BytecodeLivenessPropagation<DerivedAnalysis>::runLivenessFixpoint(Graph& graph)
	{
	auto* codeBlock = graph.codeBlock();
	unsigned numberOfVariables = codeBlock->numCalleeLocals();
	for (BytecodeBasicBlock* block : graph) {
	block->in().resize(numberOfVariables);
	block->out().resize(numberOfVariables);
	block->in().clearAll();
	block->out().clearAll();
	}

	bool changed;
	BytecodeBasicBlock* lastBlock = graph.last();
	lastBlock->in().clearAll();
	lastBlock->out().clearAll();
	FastBitVector newOut;
	newOut.resize(lastBlock->out().numBits());
	do {
	changed = false;
	for (std::unique_ptr<BytecodeBasicBlock>& block : graph.basicBlocksInReverseOrder()) {
	newOut.clearAll();
	for (BytecodeBasicBlock* successor : block->successors())
	newOut \|= successor->in();
	block->out() = newOut;
	changed \|= computeLocalLivenessForBlock(graph, block.get());
	}
	} while (changed);
	}

	} // namespace JSC