/* -*- 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/. */ #ifndef jit_arm_LIR_arm_h #define jit_arm_LIR_arm_h namespace js { namespace jit { class LBoxFloatingPoint : public LInstructionHelper<2, 1, 1> { MIRType type_; public: LIR_HEADER(BoxFloatingPoint); LBoxFloatingPoint(const LAllocation& in, const LDefinition& temp, MIRType type) : type_(type) { setOperand(0, in); setTemp(0, temp); } MIRType type() const { return type_; } const char* extraName() const { return StringFromMIRType(type_); } }; class LUnbox : public LInstructionHelper<1, 2, 0> { public: LIR_HEADER(Unbox); MUnbox* mir() const { return mir_->toUnbox(); } const LAllocation* payload() { return getOperand(0); } const LAllocation* type() { return getOperand(1); } const char* extraName() const { return StringFromMIRType(mir()->type()); } }; class LUnboxFloatingPoint : public LInstructionHelper<1, 2, 0> { MIRType type_; public: LIR_HEADER(UnboxFloatingPoint); static const size_t Input = 0; LUnboxFloatingPoint(const LBoxAllocation& input, MIRType type) : type_(type) { setBoxOperand(Input, input); } MUnbox* mir() const { return mir_->toUnbox(); } MIRType type() const { return type_; } const char* extraName() const { return StringFromMIRType(type_); } }; // Convert a 32-bit unsigned integer to a double. class LWasmUint32ToDouble : public LInstructionHelper<1, 1, 0> { public: LIR_HEADER(WasmUint32ToDouble) LWasmUint32ToDouble(const LAllocation& input) { setOperand(0, input); } }; // Convert a 32-bit unsigned integer to a float32. class LWasmUint32ToFloat32 : public LInstructionHelper<1, 1, 0> { public: LIR_HEADER(WasmUint32ToFloat32) LWasmUint32ToFloat32(const LAllocation& input) { setOperand(0, input); } }; class LDivI : public LBinaryMath<1> { public: LIR_HEADER(DivI); LDivI(const LAllocation& lhs, const LAllocation& rhs, const LDefinition& temp) { setOperand(0, lhs); setOperand(1, rhs); setTemp(0, temp); } MDiv* mir() const { return mir_->toDiv(); } }; class LDivOrModI64 : public LCallInstructionHelper { public: LIR_HEADER(DivOrModI64) static const size_t Lhs = 0; static const size_t Rhs = INT64_PIECES; LDivOrModI64(const LInt64Allocation& lhs, const LInt64Allocation& rhs) { setInt64Operand(Lhs, lhs); setInt64Operand(Rhs, rhs); } MBinaryArithInstruction* mir() const { MOZ_ASSERT(mir_->isDiv() || mir_->isMod()); return static_cast(mir_); } bool canBeDivideByZero() const { if (mir_->isMod()) return mir_->toMod()->canBeDivideByZero(); return mir_->toDiv()->canBeDivideByZero(); } bool canBeNegativeOverflow() const { if (mir_->isMod()) return mir_->toMod()->canBeNegativeDividend(); return mir_->toDiv()->canBeNegativeOverflow(); } wasm::TrapOffset trapOffset() const { MOZ_ASSERT(mir_->isDiv() || mir_->isMod()); if (mir_->isMod()) return mir_->toMod()->trapOffset(); return mir_->toDiv()->trapOffset(); } }; class LUDivOrModI64 : public LCallInstructionHelper { public: LIR_HEADER(UDivOrModI64) static const size_t Lhs = 0; static const size_t Rhs = INT64_PIECES; LUDivOrModI64(const LInt64Allocation& lhs, const LInt64Allocation& rhs) { setInt64Operand(Lhs, lhs); setInt64Operand(Rhs, rhs); } MBinaryArithInstruction* mir() const { MOZ_ASSERT(mir_->isDiv() || mir_->isMod()); return static_cast(mir_); } bool canBeDivideByZero() const { if (mir_->isMod()) return mir_->toMod()->canBeDivideByZero(); return mir_->toDiv()->canBeDivideByZero(); } bool canBeNegativeOverflow() const { if (mir_->isMod()) return mir_->toMod()->canBeNegativeDividend(); return mir_->toDiv()->canBeNegativeOverflow(); } wasm::TrapOffset trapOffset() const { MOZ_ASSERT(mir_->isDiv() || mir_->isMod()); if (mir_->isMod()) return mir_->toMod()->trapOffset(); return mir_->toDiv()->trapOffset(); } }; // LSoftDivI is a software divide for ARM cores that don't support a hardware // divide instruction. // // It is implemented as a proper C function so it trashes r0, r1, r2 and r3. // The call also trashes lr, and has the ability to trash ip. The function also // takes two arguments (dividend in r0, divisor in r1). The LInstruction gets // encoded such that the divisor and dividend are passed in their apropriate // registers and end their life at the start of the instruction by the use of // useFixedAtStart. The result is returned in r0 and the other three registers // that can be trashed are marked as temps. For the time being, the link // register is not marked as trashed because we never allocate to the link // register. The FP registers are not trashed. class LSoftDivI : public LBinaryMath<3> { public: LIR_HEADER(SoftDivI); LSoftDivI(const LAllocation& lhs, const LAllocation& rhs, const LDefinition& temp1, const LDefinition& temp2, const LDefinition& temp3) { setOperand(0, lhs); setOperand(1, rhs); setTemp(0, temp1); setTemp(1, temp2); setTemp(2, temp3); } MDiv* mir() const { return mir_->toDiv(); } }; class LDivPowTwoI : public LInstructionHelper<1, 1, 0> { const int32_t shift_; public: LIR_HEADER(DivPowTwoI) LDivPowTwoI(const LAllocation& lhs, int32_t shift) : shift_(shift) { setOperand(0, lhs); } const LAllocation* numerator() { return getOperand(0); } int32_t shift() { return shift_; } MDiv* mir() const { return mir_->toDiv(); } }; class LModI : public LBinaryMath<1> { public: LIR_HEADER(ModI); LModI(const LAllocation& lhs, const LAllocation& rhs, const LDefinition& callTemp) { setOperand(0, lhs); setOperand(1, rhs); setTemp(0, callTemp); } const LDefinition* callTemp() { return getTemp(0); } MMod* mir() const { return mir_->toMod(); } }; class LSoftModI : public LBinaryMath<4> { public: LIR_HEADER(SoftModI); LSoftModI(const LAllocation& lhs, const LAllocation& rhs, const LDefinition& temp1, const LDefinition& temp2, const LDefinition& temp3, const LDefinition& callTemp) { setOperand(0, lhs); setOperand(1, rhs); setTemp(0, temp1); setTemp(1, temp2); setTemp(2, temp3); setTemp(3, callTemp); } const LDefinition* callTemp() { return getTemp(3); } MMod* mir() const { return mir_->toMod(); } }; class LModPowTwoI : public LInstructionHelper<1, 1, 0> { const int32_t shift_; public: LIR_HEADER(ModPowTwoI); int32_t shift() { return shift_; } LModPowTwoI(const LAllocation& lhs, int32_t shift) : shift_(shift) { setOperand(0, lhs); } MMod* mir() const { return mir_->toMod(); } }; class LModMaskI : public LInstructionHelper<1, 1, 2> { const int32_t shift_; public: LIR_HEADER(ModMaskI); LModMaskI(const LAllocation& lhs, const LDefinition& temp1, const LDefinition& temp2, int32_t shift) : shift_(shift) { setOperand(0, lhs); setTemp(0, temp1); setTemp(1, temp2); } int32_t shift() const { return shift_; } MMod* mir() const { return mir_->toMod(); } }; // Takes a tableswitch with an integer to decide. class LTableSwitch : public LInstructionHelper<0, 1, 1> { public: LIR_HEADER(TableSwitch); LTableSwitch(const LAllocation& in, const LDefinition& inputCopy, MTableSwitch* ins) { setOperand(0, in); setTemp(0, inputCopy); setMir(ins); } MTableSwitch* mir() const { return mir_->toTableSwitch(); } const LAllocation* index() { return getOperand(0); } const LDefinition* tempInt() { return getTemp(0); } // This is added to share the same CodeGenerator prefixes. const LDefinition* tempPointer() { return nullptr; } }; // Takes a tableswitch with an integer to decide. class LTableSwitchV : public LInstructionHelper<0, BOX_PIECES, 2> { public: LIR_HEADER(TableSwitchV); LTableSwitchV(const LBoxAllocation& input, const LDefinition& inputCopy, const LDefinition& floatCopy, MTableSwitch* ins) { setBoxOperand(InputValue, input); setTemp(0, inputCopy); setTemp(1, floatCopy); setMir(ins); } MTableSwitch* mir() const { return mir_->toTableSwitch(); } static const size_t InputValue = 0; const LDefinition* tempInt() { return getTemp(0); } const LDefinition* tempFloat() { return getTemp(1); } const LDefinition* tempPointer() { return nullptr; } }; class LGuardShape : public LInstructionHelper<0, 1, 1> { public: LIR_HEADER(GuardShape); LGuardShape(const LAllocation& in, const LDefinition& temp) { setOperand(0, in); setTemp(0, temp); } const MGuardShape* mir() const { return mir_->toGuardShape(); } const LDefinition* tempInt() { return getTemp(0); } }; class LGuardObjectGroup : public LInstructionHelper<0, 1, 1> { public: LIR_HEADER(GuardObjectGroup); LGuardObjectGroup(const LAllocation& in, const LDefinition& temp) { setOperand(0, in); setTemp(0, temp); } const MGuardObjectGroup* mir() const { return mir_->toGuardObjectGroup(); } const LDefinition* tempInt() { return getTemp(0); } }; class LMulI : public LBinaryMath<0> { public: LIR_HEADER(MulI); MMul* mir() { return mir_->toMul(); } }; class LUDiv : public LBinaryMath<0> { public: LIR_HEADER(UDiv); MDiv* mir() { return mir_->toDiv(); } }; class LUMod : public LBinaryMath<0> { public: LIR_HEADER(UMod); MMod* mir() { return mir_->toMod(); } }; class LSoftUDivOrMod : public LBinaryMath<3> { public: LIR_HEADER(SoftUDivOrMod); LSoftUDivOrMod(const LAllocation& lhs, const LAllocation& rhs, const LDefinition& temp1, const LDefinition& temp2, const LDefinition& temp3) { setOperand(0, lhs); setOperand(1, rhs); setTemp(0, temp1); setTemp(1, temp2); setTemp(2, temp3); } MInstruction* mir() { return mir_->toInstruction(); } }; class LAsmJSCompareExchangeCallout : public LCallInstructionHelper<1, 4, 2> { public: LIR_HEADER(AsmJSCompareExchangeCallout) LAsmJSCompareExchangeCallout(const LAllocation& ptr, const LAllocation& oldval, const LAllocation& newval, const LAllocation& tls, const LDefinition& temp1, const LDefinition& temp2) { setOperand(0, ptr); setOperand(1, oldval); setOperand(2, newval); setOperand(3, tls); setTemp(0, temp1); setTemp(1, temp2); } const LAllocation* ptr() { return getOperand(0); } const LAllocation* oldval() { return getOperand(1); } const LAllocation* newval() { return getOperand(2); } const LAllocation* tls() { return getOperand(3); } const MAsmJSCompareExchangeHeap* mir() const { return mir_->toAsmJSCompareExchangeHeap(); } }; class LAsmJSAtomicExchangeCallout : public LCallInstructionHelper<1, 3, 2> { public: LIR_HEADER(AsmJSAtomicExchangeCallout) LAsmJSAtomicExchangeCallout(const LAllocation& ptr, const LAllocation& value, const LAllocation& tls, const LDefinition& temp1, const LDefinition& temp2) { setOperand(0, ptr); setOperand(1, value); setOperand(2, tls); setTemp(0, temp1); setTemp(1, temp2); } const LAllocation* ptr() { return getOperand(0); } const LAllocation* value() { return getOperand(1); } const LAllocation* tls() { return getOperand(2); } const MAsmJSAtomicExchangeHeap* mir() const { return mir_->toAsmJSAtomicExchangeHeap(); } }; class LAsmJSAtomicBinopCallout : public LCallInstructionHelper<1, 3, 2> { public: LIR_HEADER(AsmJSAtomicBinopCallout) LAsmJSAtomicBinopCallout(const LAllocation& ptr, const LAllocation& value, const LAllocation& tls, const LDefinition& temp1, const LDefinition& temp2) { setOperand(0, ptr); setOperand(1, value); setOperand(2, tls); setTemp(0, temp1); setTemp(1, temp2); } const LAllocation* ptr() { return getOperand(0); } const LAllocation* value() { return getOperand(1); } const LAllocation* tls() { return getOperand(2); } const MAsmJSAtomicBinopHeap* mir() const { return mir_->toAsmJSAtomicBinopHeap(); } }; class LWasmTruncateToInt64 : public LCallInstructionHelper { public: LIR_HEADER(WasmTruncateToInt64); LWasmTruncateToInt64(const LAllocation& in) { setOperand(0, in); } MWasmTruncateToInt64* mir() const { return mir_->toWasmTruncateToInt64(); } }; class LInt64ToFloatingPointCall: public LCallInstructionHelper<1, INT64_PIECES, 0> { public: LIR_HEADER(Int64ToFloatingPointCall); MInt64ToFloatingPoint* mir() const { return mir_->toInt64ToFloatingPoint(); } }; namespace details { // Base class for the int64 and non-int64 variants. template class LWasmUnalignedLoadBase : public details::LWasmLoadBase { public: typedef LWasmLoadBase Base; explicit LWasmUnalignedLoadBase(const LAllocation& ptr, const LDefinition& ptrCopy, const LDefinition& temp1, const LDefinition& temp2, const LDefinition& temp3) : Base(ptr) { Base::setTemp(0, ptrCopy); Base::setTemp(1, temp1); Base::setTemp(2, temp2); Base::setTemp(3, temp3); } const LDefinition* ptrCopy() { return Base::getTemp(0); } }; } // namespace details class LWasmUnalignedLoad : public details::LWasmUnalignedLoadBase<1> { public: explicit LWasmUnalignedLoad(const LAllocation& ptr, const LDefinition& ptrCopy, const LDefinition& temp1, const LDefinition& temp2, const LDefinition& temp3) : LWasmUnalignedLoadBase(ptr, ptrCopy, temp1, temp2, temp3) {} LIR_HEADER(WasmUnalignedLoad); }; class LWasmUnalignedLoadI64 : public details::LWasmUnalignedLoadBase { public: explicit LWasmUnalignedLoadI64(const LAllocation& ptr, const LDefinition& ptrCopy, const LDefinition& temp1, const LDefinition& temp2, const LDefinition& temp3) : LWasmUnalignedLoadBase(ptr, ptrCopy, temp1, temp2, temp3) {} LIR_HEADER(WasmUnalignedLoadI64); }; namespace details { // Base class for the int64 and non-int64 variants. template class LWasmUnalignedStoreBase : public LInstructionHelper<0, NumOps, 2> { public: typedef LInstructionHelper<0, NumOps, 2> Base; static const uint32_t ValueIndex = 1; LWasmUnalignedStoreBase(const LAllocation& ptr, const LDefinition& ptrCopy, const LDefinition& valueHelper) { Base::setOperand(0, ptr); Base::setTemp(0, ptrCopy); Base::setTemp(1, valueHelper); } MWasmStore* mir() const { return Base::mir_->toWasmStore(); } const LDefinition* ptrCopy() { return Base::getTemp(0); } const LDefinition* valueHelper() { return Base::getTemp(1); } }; } // namespace details class LWasmUnalignedStore : public details::LWasmUnalignedStoreBase<2> { public: LIR_HEADER(WasmUnalignedStore); LWasmUnalignedStore(const LAllocation& ptr, const LAllocation& value, const LDefinition& ptrCopy, const LDefinition& valueHelper) : LWasmUnalignedStoreBase(ptr, ptrCopy, valueHelper) { setOperand(1, value); } }; class LWasmUnalignedStoreI64 : public details::LWasmUnalignedStoreBase<1 + INT64_PIECES> { public: LIR_HEADER(WasmUnalignedStoreI64); LWasmUnalignedStoreI64(const LAllocation& ptr, const LInt64Allocation& value, const LDefinition& ptrCopy, const LDefinition& valueHelper) : LWasmUnalignedStoreBase(ptr, ptrCopy, valueHelper) { setInt64Operand(1, value); } }; } // namespace jit } // namespace js #endif /* jit_arm_LIR_arm_h */