src/third_party/mozjs/js/src/jit/mips/BaselineIC-mips.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 "jsiter.h"

 #include "jit/BaselineCompiler.h"
 #include "jit/BaselineHelpers.h"
 #include "jit/BaselineIC.h"
 #include "jit/BaselineJIT.h"
 #include "jit/IonLinker.h"

 #include "jsboolinlines.h"

 using namespace js;
 using namespace js::jit;

 namespace js {
 namespace jit {

 // ICCompare_Int32

 bool
 ICCompare_Int32::Compiler::generateStubCode(MacroAssembler &masm)
 {
     // Guard that R0 is an integer and R1 is an integer.
     Label failure;
     Label conditionTrue;
     masm.branchTestInt32(Assembler::NotEqual, R0, &failure);
     masm.branchTestInt32(Assembler::NotEqual, R1, &failure);

     // Compare payload regs of R0 and R1.
     Assembler::Condition cond = JSOpToCondition(op, /* signed = */true);
     masm.ma_cmp_set(R0.payloadReg(), R0.payloadReg(), R1.payloadReg(), cond);

     masm.tagValue(JSVAL_TYPE_BOOLEAN, R0.payloadReg(), R0);
     EmitReturnFromIC(masm);

     // Failure case - jump to next stub
     masm.bind(&failure);
     EmitStubGuardFailure(masm);

     return true;
 }

 bool
 ICCompare_Double::Compiler::generateStubCode(MacroAssembler &masm)
 {
     Label failure, isNaN;
     masm.ensureDouble(R0, FloatReg0, &failure);
     masm.ensureDouble(R1, FloatReg1, &failure);

     Register dest = R0.scratchReg();

     Assembler::DoubleCondition doubleCond = JSOpToDoubleCondition(op);

     masm.ma_cmp_set_double(dest, FloatReg0, FloatReg1, doubleCond);

     masm.tagValue(JSVAL_TYPE_BOOLEAN, dest, R0);
     EmitReturnFromIC(masm);

     // Failure case - jump to next stub
     masm.bind(&failure);
     EmitStubGuardFailure(masm);
     return true;
 }

 // ICBinaryArith_Int32

 bool
 ICBinaryArith_Int32::Compiler::generateStubCode(MacroAssembler &masm)
 {
     // Guard that R0 is an integer and R1 is an integer.
     Label failure;
     masm.branchTestInt32(Assembler::NotEqual, R0, &failure);
     masm.branchTestInt32(Assembler::NotEqual, R1, &failure);

     // Add R0 and R1. Don't need to explicitly unbox, just use R2's payloadReg.
     Register scratchReg = R2.payloadReg();

     // DIV and MOD need an extra non-volatile ValueOperand to hold R0.
     GeneralRegisterSet savedRegs = availableGeneralRegs(2);
     savedRegs = GeneralRegisterSet::Intersect(GeneralRegisterSet::NonVolatile(), savedRegs);
     ValueOperand savedValue = savedRegs.takeAnyValue();

     Label goodMul, divTest1, divTest2;
     switch(op_) {
       case JSOP_ADD:
         // We know R0.typeReg() already contains the integer tag. No boxing
         // required.
         masm.ma_addTestOverflow(R0.payloadReg(), R0.payloadReg(), R1.payloadReg(), &failure);
         break;
       case JSOP_SUB:
         masm.ma_subTestOverflow(R0.payloadReg(), R0.payloadReg(), R1.payloadReg(), &failure);
         break;
       case JSOP_MUL: {
         masm.ma_mul_branch_overflow(scratchReg, R0.payloadReg(), R1.payloadReg(), &failure);

         masm.ma_b(scratchReg, Imm32(0), &goodMul, Assembler::NotEqual, ShortJump);

         // Result is -0 if operands have different signs.
         masm.as_xor(t8, R0.payloadReg(), R1.payloadReg());
         masm.ma_b(t8, Imm32(0), &failure, Assembler::LessThan, ShortJump);

         masm.bind(&goodMul);
         masm.move32(scratchReg, R0.payloadReg());
         break;
       }
       case JSOP_DIV:
       case JSOP_MOD: {
         // Check for INT_MIN / -1, it results in a double.
         masm.ma_b(R0.payloadReg(), Imm32(INT_MIN), &divTest1, Assembler::NotEqual, ShortJump);
         masm.ma_b(R1.payloadReg(), Imm32(-1), &failure, Assembler::Equal, ShortJump);
         masm.bind(&divTest1);

         // Check for division by zero
         masm.ma_b(R1.payloadReg(), Imm32(0), &failure, Assembler::Equal, ShortJump);

         // Check for 0 / X with X < 0 (results in -0).
         masm.ma_b(R0.payloadReg(), Imm32(0), &divTest2, Assembler::NotEqual, ShortJump);
         masm.ma_b(R1.payloadReg(), Imm32(0), &failure, Assembler::LessThan, ShortJump);
         masm.bind(&divTest2);

         masm.as_div(R0.payloadReg(), R1.payloadReg());

         if (op_ == JSOP_DIV) {
             // Result is a double if the remainder != 0.
             masm.as_mfhi(scratchReg);
             masm.ma_b(scratchReg, Imm32(0), &failure, Assembler::NotEqual, ShortJump);
             masm.as_mflo(scratchReg);
             masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0);
         } else {
             Label done;
             // If X % Y == 0 and X < 0, the result is -0.
             masm.as_mfhi(scratchReg);
             masm.ma_b(scratchReg, Imm32(0), &done, Assembler::NotEqual, ShortJump);
             masm.ma_b(R0.payloadReg(), Imm32(0), &failure, Assembler::LessThan, ShortJump);
             masm.bind(&done);
             masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0);
         }
         break;
       }
       case JSOP_BITOR:
         masm.ma_or(R0.payloadReg() , R0.payloadReg(), R1.payloadReg());
         break;
       case JSOP_BITXOR:
         masm.ma_xor(R0.payloadReg() , R0.payloadReg(), R1.payloadReg());
         break;
       case JSOP_BITAND:
         masm.ma_and(R0.payloadReg() , R0.payloadReg(), R1.payloadReg());
         break;
       case JSOP_LSH:
         // MIPS will only use 5 lowest bits in R1 as shift offset.
         masm.ma_sll(R0.payloadReg(), R0.payloadReg(), R1.payloadReg());
         break;
       case JSOP_RSH:
         masm.ma_sra(R0.payloadReg(), R0.payloadReg(), R1.payloadReg());
         break;
       case JSOP_URSH:
         masm.ma_srl(scratchReg, R0.payloadReg(), R1.payloadReg());
         if (allowDouble_) {
             Label toUint;
             masm.ma_b(scratchReg, Imm32(0), &toUint, Assembler::LessThan, ShortJump);

             // Move result and box for return.
             masm.move32(scratchReg, R0.payloadReg());
             EmitReturnFromIC(masm);

             masm.bind(&toUint);
             masm.convertUInt32ToDouble(scratchReg, FloatReg1);
             masm.boxDouble(FloatReg1, R0);
         } else {
             masm.ma_b(scratchReg, Imm32(0), &failure, Assembler::LessThan, ShortJump);
             // Move result for return.
             masm.move32(scratchReg, R0.payloadReg());
         }
         break;
       default:
         JS_NOT_REACHED("Unhandled op for BinaryArith_Int32.");
     }

     EmitReturnFromIC(masm);

     // Failure case - jump to next stub
     masm.bind(&failure);
     EmitStubGuardFailure(masm);

     return true;
 }

 bool
 ICUnaryArith_Int32::Compiler::generateStubCode(MacroAssembler &masm)
 {
     Label failure;
     masm.branchTestInt32(Assembler::NotEqual, R0, &failure);

     switch (op) {
       case JSOP_BITNOT:
         masm.not32(R0.payloadReg());
         break;
       case JSOP_NEG:
         // Guard against 0 and MIN_INT, both result in a double.
         masm.branchTest32(Assembler::Zero, R0.payloadReg(), Imm32(INT32_MAX), &failure);

         masm.neg32(R0.payloadReg());
         break;
       default:
         JS_NOT_REACHED("Unexpected op");
         return false;
     }

     EmitReturnFromIC(masm);

     masm.bind(&failure);
     EmitStubGuardFailure(masm);
     return true;
 }


 } // namespace jit
 } // namespace js
	/* -- 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 "jsiter.h"

	#include "jit/BaselineCompiler.h"
	#include "jit/BaselineHelpers.h"
	#include "jit/BaselineIC.h"
	#include "jit/BaselineJIT.h"
	#include "jit/IonLinker.h"

	#include "jsboolinlines.h"

	using namespace js;
	using namespace js::jit;

	namespace js {
	namespace jit {

	// ICCompare_Int32

	bool
	ICCompare_Int32::Compiler::generateStubCode(MacroAssembler &masm)
	{
	// Guard that R0 is an integer and R1 is an integer.
	Label failure;
	Label conditionTrue;
	masm.branchTestInt32(Assembler::NotEqual, R0, &failure);
	masm.branchTestInt32(Assembler::NotEqual, R1, &failure);

	// Compare payload regs of R0 and R1.
	Assembler::Condition cond = JSOpToCondition(op, /* signed = */true);
	masm.ma_cmp_set(R0.payloadReg(), R0.payloadReg(), R1.payloadReg(), cond);

	masm.tagValue(JSVAL_TYPE_BOOLEAN, R0.payloadReg(), R0);
	EmitReturnFromIC(masm);

	// Failure case - jump to next stub
	masm.bind(&failure);
	EmitStubGuardFailure(masm);

	return true;
	}

	bool
	ICCompare_Double::Compiler::generateStubCode(MacroAssembler &masm)
	{
	Label failure, isNaN;
	masm.ensureDouble(R0, FloatReg0, &failure);
	masm.ensureDouble(R1, FloatReg1, &failure);

	Register dest = R0.scratchReg();

	Assembler::DoubleCondition doubleCond = JSOpToDoubleCondition(op);

	masm.ma_cmp_set_double(dest, FloatReg0, FloatReg1, doubleCond);

	masm.tagValue(JSVAL_TYPE_BOOLEAN, dest, R0);
	EmitReturnFromIC(masm);

	// Failure case - jump to next stub
	masm.bind(&failure);
	EmitStubGuardFailure(masm);
	return true;
	}

	// ICBinaryArith_Int32

	bool
	ICBinaryArith_Int32::Compiler::generateStubCode(MacroAssembler &masm)
	{
	// Guard that R0 is an integer and R1 is an integer.
	Label failure;
	masm.branchTestInt32(Assembler::NotEqual, R0, &failure);
	masm.branchTestInt32(Assembler::NotEqual, R1, &failure);

	// Add R0 and R1. Don't need to explicitly unbox, just use R2's payloadReg.
	Register scratchReg = R2.payloadReg();

	// DIV and MOD need an extra non-volatile ValueOperand to hold R0.
	GeneralRegisterSet savedRegs = availableGeneralRegs(2);
	savedRegs = GeneralRegisterSet::Intersect(GeneralRegisterSet::NonVolatile(), savedRegs);
	ValueOperand savedValue = savedRegs.takeAnyValue();

	Label goodMul, divTest1, divTest2;
	switch(op_) {
	case JSOP_ADD:
	// We know R0.typeReg() already contains the integer tag. No boxing
	// required.
	masm.ma_addTestOverflow(R0.payloadReg(), R0.payloadReg(), R1.payloadReg(), &failure);
	break;
	case JSOP_SUB:
	masm.ma_subTestOverflow(R0.payloadReg(), R0.payloadReg(), R1.payloadReg(), &failure);
	break;
	case JSOP_MUL: {
	masm.ma_mul_branch_overflow(scratchReg, R0.payloadReg(), R1.payloadReg(), &failure);

	masm.ma_b(scratchReg, Imm32(0), &goodMul, Assembler::NotEqual, ShortJump);

	// Result is -0 if operands have different signs.
	masm.as_xor(t8, R0.payloadReg(), R1.payloadReg());
	masm.ma_b(t8, Imm32(0), &failure, Assembler::LessThan, ShortJump);

	masm.bind(&goodMul);
	masm.move32(scratchReg, R0.payloadReg());
	break;
	}
	case JSOP_DIV:
	case JSOP_MOD: {
	// Check for INT_MIN / -1, it results in a double.
	masm.ma_b(R0.payloadReg(), Imm32(INT_MIN), &divTest1, Assembler::NotEqual, ShortJump);
	masm.ma_b(R1.payloadReg(), Imm32(-1), &failure, Assembler::Equal, ShortJump);
	masm.bind(&divTest1);

	// Check for division by zero
	masm.ma_b(R1.payloadReg(), Imm32(0), &failure, Assembler::Equal, ShortJump);

	// Check for 0 / X with X < 0 (results in -0).
	masm.ma_b(R0.payloadReg(), Imm32(0), &divTest2, Assembler::NotEqual, ShortJump);
	masm.ma_b(R1.payloadReg(), Imm32(0), &failure, Assembler::LessThan, ShortJump);
	masm.bind(&divTest2);

	masm.as_div(R0.payloadReg(), R1.payloadReg());

	if (op_ == JSOP_DIV) {
	// Result is a double if the remainder != 0.
	masm.as_mfhi(scratchReg);
	masm.ma_b(scratchReg, Imm32(0), &failure, Assembler::NotEqual, ShortJump);
	masm.as_mflo(scratchReg);
	masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0);
	} else {
	Label done;
	// If X % Y == 0 and X < 0, the result is -0.
	masm.as_mfhi(scratchReg);
	masm.ma_b(scratchReg, Imm32(0), &done, Assembler::NotEqual, ShortJump);
	masm.ma_b(R0.payloadReg(), Imm32(0), &failure, Assembler::LessThan, ShortJump);
	masm.bind(&done);
	masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0);
	}
	break;
	}
	case JSOP_BITOR:
	masm.ma_or(R0.payloadReg() , R0.payloadReg(), R1.payloadReg());
	break;
	case JSOP_BITXOR:
	masm.ma_xor(R0.payloadReg() , R0.payloadReg(), R1.payloadReg());
	break;
	case JSOP_BITAND:
	masm.ma_and(R0.payloadReg() , R0.payloadReg(), R1.payloadReg());
	break;
	case JSOP_LSH:
	// MIPS will only use 5 lowest bits in R1 as shift offset.
	masm.ma_sll(R0.payloadReg(), R0.payloadReg(), R1.payloadReg());
	break;
	case JSOP_RSH:
	masm.ma_sra(R0.payloadReg(), R0.payloadReg(), R1.payloadReg());
	break;
	case JSOP_URSH:
	masm.ma_srl(scratchReg, R0.payloadReg(), R1.payloadReg());
	if (allowDouble_) {
	Label toUint;
	masm.ma_b(scratchReg, Imm32(0), &toUint, Assembler::LessThan, ShortJump);

	// Move result and box for return.
	masm.move32(scratchReg, R0.payloadReg());
	EmitReturnFromIC(masm);

	masm.bind(&toUint);
	masm.convertUInt32ToDouble(scratchReg, FloatReg1);
	masm.boxDouble(FloatReg1, R0);
	} else {
	masm.ma_b(scratchReg, Imm32(0), &failure, Assembler::LessThan, ShortJump);
	// Move result for return.
	masm.move32(scratchReg, R0.payloadReg());
	}
	break;
	default:
	JS_NOT_REACHED("Unhandled op for BinaryArith_Int32.");
	}

	EmitReturnFromIC(masm);

	// Failure case - jump to next stub
	masm.bind(&failure);
	EmitStubGuardFailure(masm);

	return true;
	}

	bool
	ICUnaryArith_Int32::Compiler::generateStubCode(MacroAssembler &masm)
	{
	Label failure;
	masm.branchTestInt32(Assembler::NotEqual, R0, &failure);

	switch (op) {
	case JSOP_BITNOT:
	masm.not32(R0.payloadReg());
	break;
	case JSOP_NEG:
	// Guard against 0 and MIN_INT, both result in a double.
	masm.branchTest32(Assembler::Zero, R0.payloadReg(), Imm32(INT32_MAX), &failure);

	masm.neg32(R0.payloadReg());
	break;
	default:
	JS_NOT_REACHED("Unexpected op");
	return false;
	}

	EmitReturnFromIC(masm);

	masm.bind(&failure);
	EmitStubGuardFailure(masm);
	return true;
	}


	} // namespace jit
	} // namespace js