Source/JavaScriptCore/jit/JITArithmetic32_64.cpp - WebKit - Git at Google

 /*
 * Copyright (C) 2008-2019 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. ``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
 * 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.
 */

 #include "config.h"

 #if ENABLE(JIT)
 #if USE(JSVALUE32_64)
 #include "JIT.h"

 #include "CodeBlock.h"
 #include "JITInlines.h"
 #include "JSArray.h"
 #include "JSFunction.h"
 #include "Interpreter.h"
 #include "JSCInlines.h"
 #include "ResultType.h"
 #include "SlowPathCall.h"


 namespace JSC {

 template <typename Op>
 void JIT::emit_compareAndJump(const Instruction* instruction, RelationalCondition condition)
 {
     JumpList notInt32Op1;
     JumpList notInt32Op2;

     auto bytecode = instruction->as<Op>();
     int op1 = bytecode.m_lhs.offset();
     int op2 = bytecode.m_rhs.offset();
     unsigned target = jumpTarget(instruction, bytecode.m_targetLabel);

     // Character less.
     if (isOperandConstantChar(op1)) {
         emitLoad(op2, regT1, regT0);
         addSlowCase(branchIfNotCell(regT1));
         JumpList failures;
         emitLoadCharacterString(regT0, regT0, failures);
         addSlowCase(failures);
         addJump(branch32(commute(condition), regT0, Imm32(asString(getConstantOperand(op1))->tryGetValue()[0])), target);
         return;
     }
     if (isOperandConstantChar(op2)) {
         emitLoad(op1, regT1, regT0);
         addSlowCase(branchIfNotCell(regT1));
         JumpList failures;
         emitLoadCharacterString(regT0, regT0, failures);
         addSlowCase(failures);
         addJump(branch32(condition, regT0, Imm32(asString(getConstantOperand(op2))->tryGetValue()[0])), target);
         return;
     }
     if (isOperandConstantInt(op1)) {
         emitLoad(op2, regT3, regT2);
         notInt32Op2.append(branchIfNotInt32(regT3));
         addJump(branch32(commute(condition), regT2, Imm32(getConstantOperand(op1).asInt32())), target);
     } else if (isOperandConstantInt(op2)) {
         emitLoad(op1, regT1, regT0);
         notInt32Op1.append(branchIfNotInt32(regT1));
         addJump(branch32(condition, regT0, Imm32(getConstantOperand(op2).asInt32())), target);
     } else {
         emitLoad2(op1, regT1, regT0, op2, regT3, regT2);
         notInt32Op1.append(branchIfNotInt32(regT1));
         notInt32Op2.append(branchIfNotInt32(regT3));
         addJump(branch32(condition, regT0, regT2), target);
     }

     if (!supportsFloatingPoint()) {
         addSlowCase(notInt32Op1);
         addSlowCase(notInt32Op2);
         return;
     }
     Jump end = jump();

     // Double less.
     emitBinaryDoubleOp<Op>(instruction, OperandTypes(), notInt32Op1, notInt32Op2, !isOperandConstantInt(op1), isOperandConstantInt(op1) || !isOperandConstantInt(op2));
     end.link(this);
 }

 template <typename Op>
 void JIT::emit_compareUnsignedAndJump(const Instruction* instruction, RelationalCondition condition)
 {
     auto bytecode = instruction->as<Op>();
     int op1 = bytecode.m_lhs.offset();
     int op2 = bytecode.m_rhs.offset();
     unsigned target = jumpTarget(instruction, bytecode.m_targetLabel);

     if (isOperandConstantInt(op1)) {
         emitLoad(op2, regT3, regT2);
         addJump(branch32(commute(condition), regT2, Imm32(getConstantOperand(op1).asInt32())), target);
     } else if (isOperandConstantInt(op2)) {
         emitLoad(op1, regT1, regT0);
         addJump(branch32(condition, regT0, Imm32(getConstantOperand(op2).asInt32())), target);
     } else {
         emitLoad2(op1, regT1, regT0, op2, regT3, regT2);
         addJump(branch32(condition, regT0, regT2), target);
     }
 }

 template <typename Op>
 void JIT::emit_compareUnsigned(const Instruction* instruction, RelationalCondition condition)
 {
     auto bytecode = instruction->as<Op>();
     int dst = bytecode.m_dst.offset();
     int op1 = bytecode.m_lhs.offset();
     int op2 = bytecode.m_rhs.offset();

     if (isOperandConstantInt(op1)) {
         emitLoad(op2, regT3, regT2);
         compare32(commute(condition), regT2, Imm32(getConstantOperand(op1).asInt32()), regT0);
     } else if (isOperandConstantInt(op2)) {
         emitLoad(op1, regT1, regT0);
         compare32(condition, regT0, Imm32(getConstantOperand(op2).asInt32()), regT0);
     } else {
         emitLoad2(op1, regT1, regT0, op2, regT3, regT2);
         compare32(condition, regT0, regT2, regT0);
     }
     emitStoreBool(dst, regT0);
 }

 template <typename Op>
 void JIT::emit_compareAndJumpSlow(const Instruction *instruction, DoubleCondition, size_t (JIT_OPERATION *operation)(ExecState*, EncodedJSValue, EncodedJSValue), bool invert, Vector<SlowCaseEntry>::iterator& iter)
 {
     auto bytecode = instruction->as<Op>();
     int op1 = bytecode.m_lhs.offset();
     int op2 = bytecode.m_rhs.offset();
     unsigned target = jumpTarget(instruction, bytecode.m_targetLabel);

     linkAllSlowCases(iter);

     emitLoad(op1, regT1, regT0);
     emitLoad(op2, regT3, regT2);
     callOperation(operation, JSValueRegs(regT1, regT0), JSValueRegs(regT3, regT2));
     emitJumpSlowToHot(branchTest32(invert ? Zero : NonZero, returnValueGPR), target);
 }

 void JIT::emit_op_unsigned(const Instruction* currentInstruction)
 {
     auto bytecode = currentInstruction->as<OpUnsigned>();
     int result = bytecode.m_dst.offset();
     int op1 = bytecode.m_operand.offset();

     emitLoad(op1, regT1, regT0);

     addSlowCase(branchIfNotInt32(regT1));
     addSlowCase(branch32(LessThan, regT0, TrustedImm32(0)));
     emitStoreInt32(result, regT0, result == op1);
 }

 void JIT::emit_op_inc(const Instruction* currentInstruction)
 {
     auto bytecode = currentInstruction->as<OpInc>();
     int srcDst = bytecode.m_srcDst.offset();

     emitLoad(srcDst, regT1, regT0);

     addSlowCase(branchIfNotInt32(regT1));
     addSlowCase(branchAdd32(Overflow, TrustedImm32(1), regT0));
     emitStoreInt32(srcDst, regT0, true);
 }

 void JIT::emit_op_dec(const Instruction* currentInstruction)
 {
     auto bytecode = currentInstruction->as<OpDec>();
     int srcDst = bytecode.m_srcDst.offset();

     emitLoad(srcDst, regT1, regT0);

     addSlowCase(branchIfNotInt32(regT1));
     addSlowCase(branchSub32(Overflow, TrustedImm32(1), regT0));
     emitStoreInt32(srcDst, regT0, true);
 }

 template <typename Op>
 void JIT::emitBinaryDoubleOp(const Instruction *instruction, OperandTypes types, JumpList& notInt32Op1, JumpList& notInt32Op2, bool op1IsInRegisters, bool op2IsInRegisters)
 {
     JumpList end;

     auto bytecode = instruction->as<Op>();
     int opcodeID = Op::opcodeID;
     int target = jumpTarget(instruction, bytecode.m_targetLabel);
     int op1 = bytecode.m_lhs.offset();
     int op2 = bytecode.m_rhs.offset();

     if (!notInt32Op1.empty()) {
         // Double case 1: Op1 is not int32; Op2 is unknown.
         notInt32Op1.link(this);

         ASSERT(op1IsInRegisters);

         // Verify Op1 is double.
         if (!types.first().definitelyIsNumber())
             addSlowCase(branch32(Above, regT1, TrustedImm32(JSValue::LowestTag)));

         if (!op2IsInRegisters)
             emitLoad(op2, regT3, regT2);

         Jump doubleOp2 = branch32(Below, regT3, TrustedImm32(JSValue::LowestTag));

         if (!types.second().definitelyIsNumber())
             addSlowCase(branchIfNotInt32(regT3));

         convertInt32ToDouble(regT2, fpRegT0);
         Jump doTheMath = jump();

         // Load Op2 as double into double register.
         doubleOp2.link(this);
         emitLoadDouble(op2, fpRegT0);

         // Do the math.
         doTheMath.link(this);
         switch (opcodeID) {
             case op_jless:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleLessThan, fpRegT2, fpRegT0), target);
                 break;
             case op_jlesseq:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleLessThanOrEqual, fpRegT2, fpRegT0), target);
                 break;
             case op_jgreater:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleGreaterThan, fpRegT2, fpRegT0), target);
                 break;
             case op_jgreatereq:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleGreaterThanOrEqual, fpRegT2, fpRegT0), target);
                 break;
             case op_jnless:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleLessThanOrEqualOrUnordered, fpRegT0, fpRegT2), target);
                 break;
             case op_jnlesseq:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleLessThanOrUnordered, fpRegT0, fpRegT2), target);
                 break;
             case op_jngreater:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleGreaterThanOrEqualOrUnordered, fpRegT0, fpRegT2), target);
                 break;
             case op_jngreatereq:
                 emitLoadDouble(op1, fpRegT2);
                 addJump(branchDouble(DoubleGreaterThanOrUnordered, fpRegT0, fpRegT2), target);
                 break;
             default:
                 RELEASE_ASSERT_NOT_REACHED();
         }

         if (!notInt32Op2.empty())
             end.append(jump());
     }

     if (!notInt32Op2.empty()) {
         // Double case 2: Op1 is int32; Op2 is not int32.
         notInt32Op2.link(this);

         ASSERT(op2IsInRegisters);

         if (!op1IsInRegisters)
             emitLoadPayload(op1, regT0);

         convertInt32ToDouble(regT0, fpRegT0);

         // Verify op2 is double.
         if (!types.second().definitelyIsNumber())
             addSlowCase(branch32(Above, regT3, TrustedImm32(JSValue::LowestTag)));

         // Do the math.
         switch (opcodeID) {
             case op_jless:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleLessThan, fpRegT0, fpRegT1), target);
                 break;
             case op_jlesseq:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleLessThanOrEqual, fpRegT0, fpRegT1), target);
                 break;
             case op_jgreater:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleGreaterThan, fpRegT0, fpRegT1), target);
                 break;
             case op_jgreatereq:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleGreaterThanOrEqual, fpRegT0, fpRegT1), target);
                 break;
             case op_jnless:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleLessThanOrEqualOrUnordered, fpRegT1, fpRegT0), target);
                 break;
             case op_jnlesseq:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleLessThanOrUnordered, fpRegT1, fpRegT0), target);
                 break;
             case op_jngreater:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleGreaterThanOrEqualOrUnordered, fpRegT1, fpRegT0), target);
                 break;
             case op_jngreatereq:
                 emitLoadDouble(op2, fpRegT1);
                 addJump(branchDouble(DoubleGreaterThanOrUnordered, fpRegT1, fpRegT0), target);
                 break;
             default:
                 RELEASE_ASSERT_NOT_REACHED();
         }
     }

     end.link(this);
 }

 // Mod (%)

 /* ------------------------------ BEGIN: OP_MOD ------------------------------ */

 void JIT::emit_op_mod(const Instruction* currentInstruction)
 {
     JITSlowPathCall slowPathCall(this, currentInstruction, slow_path_mod);
     slowPathCall.call();
 }

 void JIT::emitSlow_op_mod(const Instruction*, Vector<SlowCaseEntry>::iterator&)
 {
     // We would have really useful assertions here if it wasn't for the compiler's
     // insistence on attribute noreturn.
     // RELEASE_ASSERT_NOT_REACHED();
 }

 /* ------------------------------ END: OP_MOD ------------------------------ */

 } // namespace JSC

 #endif // USE(JSVALUE32_64)
 #endif // ENABLE(JIT)
	/*
	* Copyright (C) 2008-2019 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. ``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
	* 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.
	*/

	#include "config.h"

	#if ENABLE(JIT)
	#if USE(JSVALUE32_64)
	#include "JIT.h"

	#include "CodeBlock.h"
	#include "JITInlines.h"
	#include "JSArray.h"
	#include "JSFunction.h"
	#include "Interpreter.h"
	#include "JSCInlines.h"
	#include "ResultType.h"
	#include "SlowPathCall.h"


	namespace JSC {

	template <typename Op>
	void JIT::emit_compareAndJump(const Instruction* instruction, RelationalCondition condition)
	{
	JumpList notInt32Op1;
	JumpList notInt32Op2;

	auto bytecode = instruction->as<Op>();
	int op1 = bytecode.m_lhs.offset();
	int op2 = bytecode.m_rhs.offset();
	unsigned target = jumpTarget(instruction, bytecode.m_targetLabel);

	// Character less.
	if (isOperandConstantChar(op1)) {
	emitLoad(op2, regT1, regT0);
	addSlowCase(branchIfNotCell(regT1));
	JumpList failures;
	emitLoadCharacterString(regT0, regT0, failures);
	addSlowCase(failures);
	addJump(branch32(commute(condition), regT0, Imm32(asString(getConstantOperand(op1))->tryGetValue()[0])), target);
	return;
	}
	if (isOperandConstantChar(op2)) {
	emitLoad(op1, regT1, regT0);
	addSlowCase(branchIfNotCell(regT1));
	JumpList failures;
	emitLoadCharacterString(regT0, regT0, failures);
	addSlowCase(failures);
	addJump(branch32(condition, regT0, Imm32(asString(getConstantOperand(op2))->tryGetValue()[0])), target);
	return;
	}
	if (isOperandConstantInt(op1)) {
	emitLoad(op2, regT3, regT2);
	notInt32Op2.append(branchIfNotInt32(regT3));
	addJump(branch32(commute(condition), regT2, Imm32(getConstantOperand(op1).asInt32())), target);
	} else if (isOperandConstantInt(op2)) {
	emitLoad(op1, regT1, regT0);
	notInt32Op1.append(branchIfNotInt32(regT1));
	addJump(branch32(condition, regT0, Imm32(getConstantOperand(op2).asInt32())), target);
	} else {
	emitLoad2(op1, regT1, regT0, op2, regT3, regT2);
	notInt32Op1.append(branchIfNotInt32(regT1));
	notInt32Op2.append(branchIfNotInt32(regT3));
	addJump(branch32(condition, regT0, regT2), target);
	}

	if (!supportsFloatingPoint()) {
	addSlowCase(notInt32Op1);
	addSlowCase(notInt32Op2);
	return;
	}
	Jump end = jump();

	// Double less.
	emitBinaryDoubleOp<Op>(instruction, OperandTypes(), notInt32Op1, notInt32Op2, !isOperandConstantInt(op1), isOperandConstantInt(op1) \|\| !isOperandConstantInt(op2));
	end.link(this);
	}

	template <typename Op>
	void JIT::emit_compareUnsignedAndJump(const Instruction* instruction, RelationalCondition condition)
	{
	auto bytecode = instruction->as<Op>();
	int op1 = bytecode.m_lhs.offset();
	int op2 = bytecode.m_rhs.offset();
	unsigned target = jumpTarget(instruction, bytecode.m_targetLabel);

	if (isOperandConstantInt(op1)) {
	emitLoad(op2, regT3, regT2);
	addJump(branch32(commute(condition), regT2, Imm32(getConstantOperand(op1).asInt32())), target);
	} else if (isOperandConstantInt(op2)) {
	emitLoad(op1, regT1, regT0);
	addJump(branch32(condition, regT0, Imm32(getConstantOperand(op2).asInt32())), target);
	} else {
	emitLoad2(op1, regT1, regT0, op2, regT3, regT2);
	addJump(branch32(condition, regT0, regT2), target);
	}
	}

	template <typename Op>
	void JIT::emit_compareUnsigned(const Instruction* instruction, RelationalCondition condition)
	{
	auto bytecode = instruction->as<Op>();
	int dst = bytecode.m_dst.offset();
	int op1 = bytecode.m_lhs.offset();
	int op2 = bytecode.m_rhs.offset();

	if (isOperandConstantInt(op1)) {
	emitLoad(op2, regT3, regT2);
	compare32(commute(condition), regT2, Imm32(getConstantOperand(op1).asInt32()), regT0);
	} else if (isOperandConstantInt(op2)) {
	emitLoad(op1, regT1, regT0);
	compare32(condition, regT0, Imm32(getConstantOperand(op2).asInt32()), regT0);
	} else {
	emitLoad2(op1, regT1, regT0, op2, regT3, regT2);
	compare32(condition, regT0, regT2, regT0);
	}
	emitStoreBool(dst, regT0);
	}

	template <typename Op>
	void JIT::emit_compareAndJumpSlow(const Instruction instruction, DoubleCondition, size_t (JIT_OPERATION operation)(ExecState*, EncodedJSValue, EncodedJSValue), bool invert, Vector<SlowCaseEntry>::iterator& iter)
	{
	auto bytecode = instruction->as<Op>();
	int op1 = bytecode.m_lhs.offset();
	int op2 = bytecode.m_rhs.offset();
	unsigned target = jumpTarget(instruction, bytecode.m_targetLabel);

	linkAllSlowCases(iter);

	emitLoad(op1, regT1, regT0);
	emitLoad(op2, regT3, regT2);
	callOperation(operation, JSValueRegs(regT1, regT0), JSValueRegs(regT3, regT2));
	emitJumpSlowToHot(branchTest32(invert ? Zero : NonZero, returnValueGPR), target);
	}

	void JIT::emit_op_unsigned(const Instruction* currentInstruction)
	{
	auto bytecode = currentInstruction->as<OpUnsigned>();
	int result = bytecode.m_dst.offset();
	int op1 = bytecode.m_operand.offset();

	emitLoad(op1, regT1, regT0);

	addSlowCase(branchIfNotInt32(regT1));
	addSlowCase(branch32(LessThan, regT0, TrustedImm32(0)));
	emitStoreInt32(result, regT0, result == op1);
	}

	void JIT::emit_op_inc(const Instruction* currentInstruction)
	{
	auto bytecode = currentInstruction->as<OpInc>();
	int srcDst = bytecode.m_srcDst.offset();

	emitLoad(srcDst, regT1, regT0);

	addSlowCase(branchIfNotInt32(regT1));
	addSlowCase(branchAdd32(Overflow, TrustedImm32(1), regT0));
	emitStoreInt32(srcDst, regT0, true);
	}

	void JIT::emit_op_dec(const Instruction* currentInstruction)
	{
	auto bytecode = currentInstruction->as<OpDec>();
	int srcDst = bytecode.m_srcDst.offset();

	emitLoad(srcDst, regT1, regT0);

	addSlowCase(branchIfNotInt32(regT1));
	addSlowCase(branchSub32(Overflow, TrustedImm32(1), regT0));
	emitStoreInt32(srcDst, regT0, true);
	}

	template <typename Op>
	void JIT::emitBinaryDoubleOp(const Instruction *instruction, OperandTypes types, JumpList& notInt32Op1, JumpList& notInt32Op2, bool op1IsInRegisters, bool op2IsInRegisters)
	{
	JumpList end;

	auto bytecode = instruction->as<Op>();
	int opcodeID = Op::opcodeID;
	int target = jumpTarget(instruction, bytecode.m_targetLabel);
	int op1 = bytecode.m_lhs.offset();
	int op2 = bytecode.m_rhs.offset();

	if (!notInt32Op1.empty()) {
	// Double case 1: Op1 is not int32; Op2 is unknown.
	notInt32Op1.link(this);

	ASSERT(op1IsInRegisters);

	// Verify Op1 is double.
	if (!types.first().definitelyIsNumber())
	addSlowCase(branch32(Above, regT1, TrustedImm32(JSValue::LowestTag)));

	if (!op2IsInRegisters)
	emitLoad(op2, regT3, regT2);

	Jump doubleOp2 = branch32(Below, regT3, TrustedImm32(JSValue::LowestTag));

	if (!types.second().definitelyIsNumber())
	addSlowCase(branchIfNotInt32(regT3));

	convertInt32ToDouble(regT2, fpRegT0);
	Jump doTheMath = jump();

	// Load Op2 as double into double register.
	doubleOp2.link(this);
	emitLoadDouble(op2, fpRegT0);

	// Do the math.
	doTheMath.link(this);
	switch (opcodeID) {
	case op_jless:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleLessThan, fpRegT2, fpRegT0), target);
	break;
	case op_jlesseq:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleLessThanOrEqual, fpRegT2, fpRegT0), target);
	break;
	case op_jgreater:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleGreaterThan, fpRegT2, fpRegT0), target);
	break;
	case op_jgreatereq:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleGreaterThanOrEqual, fpRegT2, fpRegT0), target);
	break;
	case op_jnless:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleLessThanOrEqualOrUnordered, fpRegT0, fpRegT2), target);
	break;
	case op_jnlesseq:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleLessThanOrUnordered, fpRegT0, fpRegT2), target);
	break;
	case op_jngreater:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleGreaterThanOrEqualOrUnordered, fpRegT0, fpRegT2), target);
	break;
	case op_jngreatereq:
	emitLoadDouble(op1, fpRegT2);
	addJump(branchDouble(DoubleGreaterThanOrUnordered, fpRegT0, fpRegT2), target);
	break;
	default:
	RELEASE_ASSERT_NOT_REACHED();
	}

	if (!notInt32Op2.empty())
	end.append(jump());
	}

	if (!notInt32Op2.empty()) {
	// Double case 2: Op1 is int32; Op2 is not int32.
	notInt32Op2.link(this);

	ASSERT(op2IsInRegisters);

	if (!op1IsInRegisters)
	emitLoadPayload(op1, regT0);

	convertInt32ToDouble(regT0, fpRegT0);

	// Verify op2 is double.
	if (!types.second().definitelyIsNumber())
	addSlowCase(branch32(Above, regT3, TrustedImm32(JSValue::LowestTag)));

	// Do the math.
	switch (opcodeID) {
	case op_jless:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleLessThan, fpRegT0, fpRegT1), target);
	break;
	case op_jlesseq:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleLessThanOrEqual, fpRegT0, fpRegT1), target);
	break;
	case op_jgreater:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleGreaterThan, fpRegT0, fpRegT1), target);
	break;
	case op_jgreatereq:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleGreaterThanOrEqual, fpRegT0, fpRegT1), target);
	break;
	case op_jnless:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleLessThanOrEqualOrUnordered, fpRegT1, fpRegT0), target);
	break;
	case op_jnlesseq:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleLessThanOrUnordered, fpRegT1, fpRegT0), target);
	break;
	case op_jngreater:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleGreaterThanOrEqualOrUnordered, fpRegT1, fpRegT0), target);
	break;
	case op_jngreatereq:
	emitLoadDouble(op2, fpRegT1);
	addJump(branchDouble(DoubleGreaterThanOrUnordered, fpRegT1, fpRegT0), target);
	break;
	default:
	RELEASE_ASSERT_NOT_REACHED();
	}
	}

	end.link(this);
	}

	// Mod (%)

	/* ------------------------------ BEGIN: OP_MOD ------------------------------ */

	void JIT::emit_op_mod(const Instruction* currentInstruction)
	{
	JITSlowPathCall slowPathCall(this, currentInstruction, slow_path_mod);
	slowPathCall.call();
	}

	void JIT::emitSlow_op_mod(const Instruction*, Vector<SlowCaseEntry>::iterator&)
	{
	// We would have really useful assertions here if it wasn't for the compiler's
	// insistence on attribute noreturn.
	// RELEASE_ASSERT_NOT_REACHED();
	}

	/* ------------------------------ END: OP_MOD ------------------------------ */

	} // namespace JSC

	#endif // USE(JSVALUE32_64)
	#endif // ENABLE(JIT)