/* -*- 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/BaselineIC.h" #include "jit/BaselineJIT.h" #include "jit/Linker.h" #include "jit/SharedICHelpers.h" #include "jsboolinlines.h" using namespace js; using namespace js::jit; namespace js { namespace jit { // 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 valueReg. Register scratchReg = R2.valueReg(); Label goodMul, divTest1, divTest2; switch(op_) { case JSOP_ADD: masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); masm.ma_addTestOverflow(scratchReg, ExtractTemp0, ExtractTemp1, &failure); masm.boxValue(JSVAL_TYPE_INT32, scratchReg, R0.valueReg()); break; case JSOP_SUB: masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); masm.ma_subTestOverflow(scratchReg, ExtractTemp0, ExtractTemp1, &failure); masm.boxValue(JSVAL_TYPE_INT32, scratchReg, R0.valueReg()); break; case JSOP_MUL: { masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); masm.ma_mul_branch_overflow(scratchReg, ExtractTemp0, ExtractTemp1, &failure); masm.ma_b(scratchReg, Imm32(0), &goodMul, Assembler::NotEqual, ShortJump); // Result is -0 if operands have different signs. masm.as_xor(t8, ExtractTemp0, ExtractTemp1); masm.ma_b(t8, Imm32(0), &failure, Assembler::LessThan, ShortJump); masm.bind(&goodMul); masm.boxValue(JSVAL_TYPE_INT32, scratchReg, R0.valueReg()); break; } case JSOP_DIV: case JSOP_MOD: { masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); // Check for INT_MIN / -1, it results in a double. masm.ma_b(ExtractTemp0, Imm32(INT_MIN), &divTest1, Assembler::NotEqual, ShortJump); masm.ma_b(ExtractTemp1, Imm32(-1), &failure, Assembler::Equal, ShortJump); masm.bind(&divTest1); // Check for division by zero masm.ma_b(ExtractTemp1, Imm32(0), &failure, Assembler::Equal, ShortJump); // Check for 0 / X with X < 0 (results in -0). masm.ma_b(ExtractTemp0, Imm32(0), &divTest2, Assembler::NotEqual, ShortJump); masm.ma_b(ExtractTemp1, Imm32(0), &failure, Assembler::LessThan, ShortJump); masm.bind(&divTest2); masm.as_div(ExtractTemp0, ExtractTemp1); 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(ExtractTemp0, Imm32(0), &failure, Assembler::LessThan, ShortJump); masm.bind(&done); masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0); } break; } case JSOP_BITOR: masm.as_or(R0.valueReg() , R0.valueReg(), R1.valueReg()); break; case JSOP_BITXOR: masm.as_xor(scratchReg, R0.valueReg(), R1.valueReg()); masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0); break; case JSOP_BITAND: masm.as_and(R0.valueReg() , R0.valueReg(), R1.valueReg()); break; case JSOP_LSH: masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); // MIPS will only use 5 lowest bits in R1 as shift offset. masm.ma_sll(scratchReg, ExtractTemp0, ExtractTemp1); masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0); break; case JSOP_RSH: masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); masm.ma_sra(scratchReg, ExtractTemp0, ExtractTemp1); masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0); break; case JSOP_URSH: masm.unboxInt32(R0, ExtractTemp0); masm.unboxInt32(R1, ExtractTemp1); masm.ma_srl(scratchReg, ExtractTemp0, ExtractTemp1); if (allowDouble_) { Label toUint; masm.ma_b(scratchReg, Imm32(0), &toUint, Assembler::LessThan, ShortJump); // Move result and box for return. masm.tagValue(JSVAL_TYPE_INT32, scratchReg, R0); 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.tagValue(JSVAL_TYPE_INT32, scratchReg, R0); } break; default: MOZ_CRASH("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.valueReg()); masm.tagValue(JSVAL_TYPE_INT32, R0.valueReg(), R0); break; case JSOP_NEG: masm.unboxInt32(R0, ExtractTemp0); // Guard against 0 and MIN_INT, both result in a double. masm.branchTest32(Assembler::Zero, ExtractTemp0, Imm32(INT32_MAX), &failure); masm.neg32(ExtractTemp0); masm.tagValue(JSVAL_TYPE_INT32, ExtractTemp0, R0); break; default: MOZ_CRASH("Unexpected op"); return false; } EmitReturnFromIC(masm); masm.bind(&failure); EmitStubGuardFailure(masm); return true; } } // namespace jit } // namespace js