src/third_party/mozjs/js/src/jit/shared/Lowering-x86-shared.cpp - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 #include "jit/MIR.h"
 #include "jit/Lowering.h"
 #include "jit/shared/Lowering-x86-shared.h"
 #include "jit/shared/Lowering-shared-inl.h"
 using namespace js;
 using namespace js::jit;

 LTableSwitch *
 LIRGeneratorX86Shared::newLTableSwitch(const LAllocation &in, const LDefinition &inputCopy,
                                        MTableSwitch *tableswitch)
 {
     return new LTableSwitch(in, inputCopy, temp(), tableswitch);
 }

 LTableSwitchV *
 LIRGeneratorX86Shared::newLTableSwitchV(MTableSwitch *tableswitch)
 {
     return new LTableSwitchV(temp(), tempFloat(), temp(), tableswitch);
 }

 bool
 LIRGeneratorX86Shared::visitInterruptCheck(MInterruptCheck *ins)
 {
     LInterruptCheck *lir = new LInterruptCheck();
     if (!add(lir, ins))
         return false;
     if (!assignSafepoint(lir, ins))
         return false;
     return true;
 }

 bool
 LIRGeneratorX86Shared::visitGuardShape(MGuardShape *ins)
 {
     JS_ASSERT(ins->obj()->type() == MIRType_Object);

     LGuardShape *guard = new LGuardShape(useRegister(ins->obj()));
     if (!assignSnapshot(guard, ins->bailoutKind()))
         return false;
     if (!add(guard, ins))
         return false;
     return redefine(ins, ins->obj());
 }

 bool
 LIRGeneratorX86Shared::visitGuardObjectType(MGuardObjectType *ins)
 {
     JS_ASSERT(ins->obj()->type() == MIRType_Object);

     LGuardObjectType *guard = new LGuardObjectType(useRegister(ins->obj()));
     if (!assignSnapshot(guard))
         return false;
     if (!add(guard, ins))
         return false;
     return redefine(ins, ins->obj());
 }

 bool
 LIRGeneratorX86Shared::visitPowHalf(MPowHalf *ins)
 {
     MDefinition *input = ins->input();
     JS_ASSERT(input->type() == MIRType_Double);
     LPowHalfD *lir = new LPowHalfD(useRegisterAtStart(input), temp());
     return defineReuseInput(lir, ins, 0);
 }

 bool
 LIRGeneratorX86Shared::lowerForShift(LInstructionHelper<1, 2, 0> *ins, MDefinition *mir,
                                      MDefinition *lhs, MDefinition *rhs)
 {
     ins->setOperand(0, useRegisterAtStart(lhs));

     // shift operator should be constant or in register ecx
     // x86 can't shift a non-ecx register
     if (rhs->isConstant())
         ins->setOperand(1, useOrConstant(rhs));
     else
         ins->setOperand(1, useFixed(rhs, ecx));

     return defineReuseInput(ins, mir, 0);
 }

 bool
 LIRGeneratorX86Shared::lowerForALU(LInstructionHelper<1, 1, 0> *ins, MDefinition *mir,
                                    MDefinition *input)
 {
     ins->setOperand(0, useRegisterAtStart(input));
     return defineReuseInput(ins, mir, 0);
 }

 bool
 LIRGeneratorX86Shared::lowerForALU(LInstructionHelper<1, 2, 0> *ins, MDefinition *mir,
                                    MDefinition *lhs, MDefinition *rhs)
 {
     ins->setOperand(0, useRegisterAtStart(lhs));
     ins->setOperand(1, useOrConstant(rhs));
     return defineReuseInput(ins, mir, 0);
 }

 bool
 LIRGeneratorX86Shared::lowerForFPU(LInstructionHelper<1, 2, 0> *ins, MDefinition *mir, MDefinition *lhs, MDefinition *rhs)
 {
     ins->setOperand(0, useRegisterAtStart(lhs));
     ins->setOperand(1, use(rhs));
     return defineReuseInput(ins, mir, 0);
 }

 bool
 LIRGeneratorX86Shared::lowerMulI(MMul *mul, MDefinition *lhs, MDefinition *rhs)
 {
     // Note: lhs is used twice, so that we can restore the original value for the
     // negative zero check.
     LMulI *lir = new LMulI(useRegisterAtStart(lhs), useOrConstant(rhs), use(lhs));
     if (mul->fallible() && !assignSnapshot(lir))
         return false;
     return defineReuseInput(lir, mul, 0);
 }

 bool
 LIRGeneratorX86Shared::lowerDivI(MDiv *div)
 {
     // Division instructions are slow. Division by constant denominators can be
     // rewritten to use other instructions.
     if (div->rhs()->isConstant()) {
         int32_t rhs = div->rhs()->toConstant()->value().toInt32();

         // Check for division by a positive power of two, which is an easy and
         // important case to optimize. Note that other optimizations are also
         // possible; division by negative powers of two can be optimized in a
         // similar manner as positive powers of two, and division by other
         // constants can be optimized by a reciprocal multiplication technique.
         int32_t shift;
         JS_FLOOR_LOG2(shift, rhs);
         if (rhs > 0 && 1 << shift == rhs) {
             LDivPowTwoI *lir = new LDivPowTwoI(useRegisterAtStart(div->lhs()), useRegister(div->lhs()), shift);
             if (div->fallible() && !assignSnapshot(lir))
                 return false;
             return defineReuseInput(lir, div, 0);
         }
     }

     LDivI *lir = new LDivI(useFixed(div->lhs(), eax), useRegister(div->rhs()), tempFixed(edx));
     if (div->fallible() && !assignSnapshot(lir))
         return false;
     return defineFixed(lir, div, LAllocation(AnyRegister(eax)));
 }

 bool
 LIRGeneratorX86Shared::lowerModI(MMod *mod)
 {
     if (mod->rhs()->isConstant()) {
         int32_t rhs = mod->rhs()->toConstant()->value().toInt32();
         int32_t shift;
         JS_FLOOR_LOG2(shift, rhs);
         if (rhs > 0 && 1 << shift == rhs) {
             LModPowTwoI *lir = new LModPowTwoI(useRegisterAtStart(mod->lhs()), shift);
             if (mod->fallible() && !assignSnapshot(lir))
                 return false;
             return defineReuseInput(lir, mod, 0);
         }
     }
     LModI *lir = new LModI(useRegister(mod->lhs()), useRegister(mod->rhs()), tempFixed(eax));
     if (mod->fallible() && !assignSnapshot(lir))
         return false;
     return defineFixed(lir, mod, LAllocation(AnyRegister(edx)));
 }

 bool
 LIRGeneratorX86Shared::visitAsmJSNeg(MAsmJSNeg *ins)
 {
     if (ins->type() == MIRType_Int32)
         return defineReuseInput(new LNegI(useRegisterAtStart(ins->input())), ins, 0);

     JS_ASSERT(ins->type() == MIRType_Double);
     return defineReuseInput(new LNegD(useRegisterAtStart(ins->input())), ins, 0);
 }

 bool
 LIRGeneratorX86Shared::visitAsmJSUDiv(MAsmJSUDiv *div)
 {
     LAsmJSDivOrMod *lir = new LAsmJSDivOrMod(useFixed(div->lhs(), eax),
                                              useRegister(div->rhs()),
                                              tempFixed(edx));
     return defineFixed(lir, div, LAllocation(AnyRegister(eax)));
 }

 bool
 LIRGeneratorX86Shared::visitAsmJSUMod(MAsmJSUMod *mod)
 {
     LAsmJSDivOrMod *lir = new LAsmJSDivOrMod(useFixed(mod->lhs(), eax),
                                              useRegister(mod->rhs()),
                                              LDefinition::BogusTemp());
     return defineFixed(lir, mod, LAllocation(AnyRegister(edx)));
 }

 bool
 LIRGeneratorX86Shared::lowerUrshD(MUrsh *mir)
 {
     MDefinition *lhs = mir->lhs();
     MDefinition *rhs = mir->rhs();

     JS_ASSERT(lhs->type() == MIRType_Int32);
     JS_ASSERT(rhs->type() == MIRType_Int32);
     JS_ASSERT(mir->type() == MIRType_Double);

 #ifdef JS_CPU_X64
     JS_ASSERT(ecx == rcx);
 #endif

     LUse lhsUse = useRegisterAtStart(lhs);
     LAllocation rhsAlloc = rhs->isConstant() ? useOrConstant(rhs) : useFixed(rhs, ecx);

     LUrshD *lir = new LUrshD(lhsUse, rhsAlloc, tempCopy(lhs, 0));
     return define(lir, mir);
 }

 bool
 LIRGeneratorX86Shared::lowerConstantDouble(double d, MInstruction *mir)
 {
     return define(new LDouble(d), mir);
 }

 bool
 LIRGeneratorX86Shared::visitConstant(MConstant *ins)
 {
     if (ins->type() == MIRType_Double)
         return lowerConstantDouble(ins->value().toDouble(), ins);

     // Emit non-double constants at their uses.
     if (ins->canEmitAtUses())
         return emitAtUses(ins);

     return LIRGeneratorShared::visitConstant(ins);
 }

 bool
 LIRGeneratorX86Shared::lowerTruncateDToInt32(MTruncateToInt32 *ins)
 {
     MDefinition *opd = ins->input();
     JS_ASSERT(opd->type() == MIRType_Double);

     LDefinition maybeTemp = Assembler::HasSSE3() ? LDefinition::BogusTemp() : tempFloat();
     return define(new LTruncateDToInt32(useRegister(opd), maybeTemp), ins);
 }
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	#include "jit/MIR.h"
	#include "jit/Lowering.h"
	#include "jit/shared/Lowering-x86-shared.h"
	#include "jit/shared/Lowering-shared-inl.h"
	using namespace js;
	using namespace js::jit;

	LTableSwitch *
	LIRGeneratorX86Shared::newLTableSwitch(const LAllocation &in, const LDefinition &inputCopy,
	MTableSwitch *tableswitch)
	{
	return new LTableSwitch(in, inputCopy, temp(), tableswitch);
	}

	LTableSwitchV *
	LIRGeneratorX86Shared::newLTableSwitchV(MTableSwitch *tableswitch)
	{
	return new LTableSwitchV(temp(), tempFloat(), temp(), tableswitch);
	}

	bool
	LIRGeneratorX86Shared::visitInterruptCheck(MInterruptCheck *ins)
	{
	LInterruptCheck *lir = new LInterruptCheck();
	if (!add(lir, ins))
	return false;
	if (!assignSafepoint(lir, ins))
	return false;
	return true;
	}

	bool
	LIRGeneratorX86Shared::visitGuardShape(MGuardShape *ins)
	{
	JS_ASSERT(ins->obj()->type() == MIRType_Object);

	LGuardShape *guard = new LGuardShape(useRegister(ins->obj()));
	if (!assignSnapshot(guard, ins->bailoutKind()))
	return false;
	if (!add(guard, ins))
	return false;
	return redefine(ins, ins->obj());
	}

	bool
	LIRGeneratorX86Shared::visitGuardObjectType(MGuardObjectType *ins)
	{
	JS_ASSERT(ins->obj()->type() == MIRType_Object);

	LGuardObjectType *guard = new LGuardObjectType(useRegister(ins->obj()));
	if (!assignSnapshot(guard))
	return false;
	if (!add(guard, ins))
	return false;
	return redefine(ins, ins->obj());
	}

	bool
	LIRGeneratorX86Shared::visitPowHalf(MPowHalf *ins)
	{
	MDefinition *input = ins->input();
	JS_ASSERT(input->type() == MIRType_Double);
	LPowHalfD *lir = new LPowHalfD(useRegisterAtStart(input), temp());
	return defineReuseInput(lir, ins, 0);
	}

	bool
	LIRGeneratorX86Shared::lowerForShift(LInstructionHelper<1, 2, 0> ins, MDefinition mir,
	MDefinition lhs, MDefinition rhs)
	{
	ins->setOperand(0, useRegisterAtStart(lhs));

	// shift operator should be constant or in register ecx
	// x86 can't shift a non-ecx register
	if (rhs->isConstant())
	ins->setOperand(1, useOrConstant(rhs));
	else
	ins->setOperand(1, useFixed(rhs, ecx));

	return defineReuseInput(ins, mir, 0);
	}

	bool
	LIRGeneratorX86Shared::lowerForALU(LInstructionHelper<1, 1, 0> ins, MDefinition mir,
	MDefinition *input)
	{
	ins->setOperand(0, useRegisterAtStart(input));
	return defineReuseInput(ins, mir, 0);
	}

	bool
	LIRGeneratorX86Shared::lowerForALU(LInstructionHelper<1, 2, 0> ins, MDefinition mir,
	MDefinition lhs, MDefinition rhs)
	{
	ins->setOperand(0, useRegisterAtStart(lhs));
	ins->setOperand(1, useOrConstant(rhs));
	return defineReuseInput(ins, mir, 0);
	}

	bool
	LIRGeneratorX86Shared::lowerForFPU(LInstructionHelper<1, 2, 0> ins, MDefinition mir, MDefinition lhs, MDefinition rhs)
	{
	ins->setOperand(0, useRegisterAtStart(lhs));
	ins->setOperand(1, use(rhs));
	return defineReuseInput(ins, mir, 0);
	}

	bool
	LIRGeneratorX86Shared::lowerMulI(MMul mul, MDefinition lhs, MDefinition *rhs)
	{
	// Note: lhs is used twice, so that we can restore the original value for the
	// negative zero check.
	LMulI *lir = new LMulI(useRegisterAtStart(lhs), useOrConstant(rhs), use(lhs));
	if (mul->fallible() && !assignSnapshot(lir))
	return false;
	return defineReuseInput(lir, mul, 0);
	}

	bool
	LIRGeneratorX86Shared::lowerDivI(MDiv *div)
	{
	// Division instructions are slow. Division by constant denominators can be
	// rewritten to use other instructions.
	if (div->rhs()->isConstant()) {
	int32_t rhs = div->rhs()->toConstant()->value().toInt32();

	// Check for division by a positive power of two, which is an easy and
	// important case to optimize. Note that other optimizations are also
	// possible; division by negative powers of two can be optimized in a
	// similar manner as positive powers of two, and division by other
	// constants can be optimized by a reciprocal multiplication technique.
	int32_t shift;
	JS_FLOOR_LOG2(shift, rhs);
	if (rhs > 0 && 1 << shift == rhs) {
	LDivPowTwoI *lir = new LDivPowTwoI(useRegisterAtStart(div->lhs()), useRegister(div->lhs()), shift);
	if (div->fallible() && !assignSnapshot(lir))
	return false;
	return defineReuseInput(lir, div, 0);
	}
	}

	LDivI *lir = new LDivI(useFixed(div->lhs(), eax), useRegister(div->rhs()), tempFixed(edx));
	if (div->fallible() && !assignSnapshot(lir))
	return false;
	return defineFixed(lir, div, LAllocation(AnyRegister(eax)));
	}

	bool
	LIRGeneratorX86Shared::lowerModI(MMod *mod)
	{
	if (mod->rhs()->isConstant()) {
	int32_t rhs = mod->rhs()->toConstant()->value().toInt32();
	int32_t shift;
	JS_FLOOR_LOG2(shift, rhs);
	if (rhs > 0 && 1 << shift == rhs) {
	LModPowTwoI *lir = new LModPowTwoI(useRegisterAtStart(mod->lhs()), shift);
	if (mod->fallible() && !assignSnapshot(lir))
	return false;
	return defineReuseInput(lir, mod, 0);
	}
	}
	LModI *lir = new LModI(useRegister(mod->lhs()), useRegister(mod->rhs()), tempFixed(eax));
	if (mod->fallible() && !assignSnapshot(lir))
	return false;
	return defineFixed(lir, mod, LAllocation(AnyRegister(edx)));
	}

	bool
	LIRGeneratorX86Shared::visitAsmJSNeg(MAsmJSNeg *ins)
	{
	if (ins->type() == MIRType_Int32)
	return defineReuseInput(new LNegI(useRegisterAtStart(ins->input())), ins, 0);

	JS_ASSERT(ins->type() == MIRType_Double);
	return defineReuseInput(new LNegD(useRegisterAtStart(ins->input())), ins, 0);
	}

	bool
	LIRGeneratorX86Shared::visitAsmJSUDiv(MAsmJSUDiv *div)
	{
	LAsmJSDivOrMod *lir = new LAsmJSDivOrMod(useFixed(div->lhs(), eax),
	useRegister(div->rhs()),
	tempFixed(edx));
	return defineFixed(lir, div, LAllocation(AnyRegister(eax)));
	}

	bool
	LIRGeneratorX86Shared::visitAsmJSUMod(MAsmJSUMod *mod)
	{
	LAsmJSDivOrMod *lir = new LAsmJSDivOrMod(useFixed(mod->lhs(), eax),
	useRegister(mod->rhs()),
	LDefinition::BogusTemp());
	return defineFixed(lir, mod, LAllocation(AnyRegister(edx)));
	}

	bool
	LIRGeneratorX86Shared::lowerUrshD(MUrsh *mir)
	{
	MDefinition *lhs = mir->lhs();
	MDefinition *rhs = mir->rhs();

	JS_ASSERT(lhs->type() == MIRType_Int32);
	JS_ASSERT(rhs->type() == MIRType_Int32);
	JS_ASSERT(mir->type() == MIRType_Double);

	#ifdef JS_CPU_X64
	JS_ASSERT(ecx == rcx);
	#endif

	LUse lhsUse = useRegisterAtStart(lhs);
	LAllocation rhsAlloc = rhs->isConstant() ? useOrConstant(rhs) : useFixed(rhs, ecx);

	LUrshD *lir = new LUrshD(lhsUse, rhsAlloc, tempCopy(lhs, 0));
	return define(lir, mir);
	}

	bool
	LIRGeneratorX86Shared::lowerConstantDouble(double d, MInstruction *mir)
	{
	return define(new LDouble(d), mir);
	}

	bool
	LIRGeneratorX86Shared::visitConstant(MConstant *ins)
	{
	if (ins->type() == MIRType_Double)
	return lowerConstantDouble(ins->value().toDouble(), ins);

	// Emit non-double constants at their uses.
	if (ins->canEmitAtUses())
	return emitAtUses(ins);

	return LIRGeneratorShared::visitConstant(ins);
	}

	bool
	LIRGeneratorX86Shared::lowerTruncateDToInt32(MTruncateToInt32 *ins)
	{
	MDefinition *opd = ins->input();
	JS_ASSERT(opd->type() == MIRType_Double);

	LDefinition maybeTemp = Assembler::HasSSE3() ? LDefinition::BogusTemp() : tempFloat();
	return define(new LTruncateDToInt32(useRegister(opd), maybeTemp), ins);
	}