/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * 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/Lowering.h" #include "mozilla/DebugOnly.h" #include "mozilla/EndianUtils.h" #include "mozilla/FloatingPoint.h" #include "mozilla/MathAlgorithms.h" #include #include "jit/ABIArgGenerator.h" #include "jit/IonOptimizationLevels.h" #include "jit/JitSpewer.h" #include "jit/LIR.h" #include "jit/MIR.h" #include "jit/MIRGraph.h" #include "jit/SharedICRegisters.h" #include "js/experimental/JitInfo.h" // JSJitInfo #include "util/Memory.h" #include "wasm/WasmCodegenTypes.h" #include "wasm/WasmInstanceData.h" #include "wasm/WasmJS.h" // for wasm::ReportSimdAnalysis #include "jit/shared/Lowering-shared-inl.h" #include "vm/BytecodeUtil-inl.h" using namespace js; using namespace jit; using JS::GenericNaN; using mozilla::DebugOnly; LBoxAllocation LIRGenerator::useBoxFixedAtStart(MDefinition* mir, ValueOperand op) { #if defined(JS_NUNBOX32) return useBoxFixed(mir, op.typeReg(), op.payloadReg(), true); #elif defined(JS_PUNBOX64) return useBoxFixed(mir, op.valueReg(), op.scratchReg(), true); #endif } LBoxAllocation LIRGenerator::useBoxAtStart(MDefinition* mir, LUse::Policy policy) { return useBox(mir, policy, /* useAtStart = */ true); } void LIRGenerator::visitParameter(MParameter* param) { ptrdiff_t offset; if (param->index() == MParameter::THIS_SLOT) { offset = THIS_FRAME_ARGSLOT; } else { offset = 1 + param->index(); } LParameter* ins = new (alloc()) LParameter; defineBox(ins, param, LDefinition::FIXED); offset *= sizeof(Value); #if defined(JS_NUNBOX32) # if MOZ_BIG_ENDIAN() ins->getDef(0)->setOutput(LArgument(offset)); ins->getDef(1)->setOutput(LArgument(offset + 4)); # else ins->getDef(0)->setOutput(LArgument(offset + 4)); ins->getDef(1)->setOutput(LArgument(offset)); # endif #elif defined(JS_PUNBOX64) ins->getDef(0)->setOutput(LArgument(offset)); #endif } void LIRGenerator::visitCallee(MCallee* ins) { define(new (alloc()) LCallee(), ins); } void LIRGenerator::visitIsConstructing(MIsConstructing* ins) { define(new (alloc()) LIsConstructing(), ins); } void LIRGenerator::visitGoto(MGoto* ins) { add(new (alloc()) LGoto(ins->target())); } void LIRGenerator::visitTableSwitch(MTableSwitch* tableswitch) { MDefinition* opd = tableswitch->getOperand(0); // There should be at least 1 successor. The default case! MOZ_ASSERT(tableswitch->numSuccessors() > 0); // If there are no cases, the default case is always taken. if (tableswitch->numSuccessors() == 1) { add(new (alloc()) LGoto(tableswitch->getDefault())); return; } // If we don't know the type. if (opd->type() == MIRType::Value) { LTableSwitchV* lir = newLTableSwitchV(tableswitch); add(lir); return; } // Case indices are numeric, so other types will always go to the default // case. if (opd->type() != MIRType::Int32 && opd->type() != MIRType::Double) { add(new (alloc()) LGoto(tableswitch->getDefault())); return; } // Return an LTableSwitch, capable of handling either an integer or // floating-point index. LAllocation index; LDefinition tempInt; if (opd->type() == MIRType::Int32) { index = useRegisterAtStart(opd); tempInt = tempCopy(opd, 0); } else { index = useRegister(opd); tempInt = temp(LDefinition::GENERAL); } add(newLTableSwitch(index, tempInt, tableswitch)); } void LIRGenerator::visitCheckOverRecursed(MCheckOverRecursed* ins) { LCheckOverRecursed* lir = new (alloc()) LCheckOverRecursed(); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewArray(MNewArray* ins) { LNewArray* lir = new (alloc()) LNewArray(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewArrayDynamicLength(MNewArrayDynamicLength* ins) { MDefinition* length = ins->length(); MOZ_ASSERT(length->type() == MIRType::Int32); LNewArrayDynamicLength* lir = new (alloc()) LNewArrayDynamicLength(useRegister(length), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewIterator(MNewIterator* ins) { LNewIterator* lir = new (alloc()) LNewIterator(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewTypedArray(MNewTypedArray* ins) { LNewTypedArray* lir = new (alloc()) LNewTypedArray(temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewTypedArrayDynamicLength( MNewTypedArrayDynamicLength* ins) { MDefinition* length = ins->length(); MOZ_ASSERT(length->type() == MIRType::Int32); LNewTypedArrayDynamicLength* lir = new (alloc()) LNewTypedArrayDynamicLength(useRegister(length), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewTypedArrayFromArray(MNewTypedArrayFromArray* ins) { MDefinition* array = ins->array(); MOZ_ASSERT(array->type() == MIRType::Object); auto* lir = new (alloc()) LNewTypedArrayFromArray(useRegisterAtStart(array)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewTypedArrayFromArrayBuffer( MNewTypedArrayFromArrayBuffer* ins) { MDefinition* arrayBuffer = ins->arrayBuffer(); MDefinition* byteOffset = ins->byteOffset(); MDefinition* length = ins->length(); MOZ_ASSERT(arrayBuffer->type() == MIRType::Object); MOZ_ASSERT(byteOffset->type() == MIRType::Value); MOZ_ASSERT(length->type() == MIRType::Value); auto* lir = new (alloc()) LNewTypedArrayFromArrayBuffer( useRegisterAtStart(arrayBuffer), useBoxAtStart(byteOffset), useBoxAtStart(length)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewObject(MNewObject* ins) { LNewObject* lir = new (alloc()) LNewObject(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewPlainObject(MNewPlainObject* ins) { LNewPlainObject* lir = new (alloc()) LNewPlainObject(temp(), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewArrayObject(MNewArrayObject* ins) { LNewArrayObject* lir = new (alloc()) LNewArrayObject(temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewNamedLambdaObject(MNewNamedLambdaObject* ins) { LNewNamedLambdaObject* lir = new (alloc()) LNewNamedLambdaObject(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewCallObject(MNewCallObject* ins) { LNewCallObject* lir = new (alloc()) LNewCallObject(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewStringObject(MNewStringObject* ins) { MOZ_ASSERT(ins->input()->type() == MIRType::String); LNewStringObject* lir = new (alloc()) LNewStringObject(useRegister(ins->input()), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitInitElemGetterSetter(MInitElemGetterSetter* ins) { LInitElemGetterSetter* lir = new (alloc()) LInitElemGetterSetter( useRegisterAtStart(ins->object()), useBoxAtStart(ins->id()), useRegisterAtStart(ins->value())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitMutateProto(MMutateProto* ins) { LMutateProto* lir = new (alloc()) LMutateProto( useRegisterAtStart(ins->object()), useBoxAtStart(ins->value())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitInitPropGetterSetter(MInitPropGetterSetter* ins) { LInitPropGetterSetter* lir = new (alloc()) LInitPropGetterSetter( useRegisterAtStart(ins->object()), useRegisterAtStart(ins->value())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCreateThis(MCreateThis* ins) { LCreateThis* lir = new (alloc()) LCreateThis(useRegisterOrConstantAtStart(ins->callee()), useRegisterOrConstantAtStart(ins->newTarget())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCreateArgumentsObject(MCreateArgumentsObject* ins) { LAllocation callObj = useRegisterAtStart(ins->getCallObject()); LCreateArgumentsObject* lir = new (alloc()) LCreateArgumentsObject(callObj, tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCreateInlinedArgumentsObject( MCreateInlinedArgumentsObject* ins) { LAllocation callObj = useRegisterAtStart(ins->getCallObject()); LAllocation callee = useRegisterAtStart(ins->getCallee()); uint32_t numActuals = ins->numActuals(); uint32_t numOperands = numActuals * BOX_PIECES + LCreateInlinedArgumentsObject::NumNonArgumentOperands; auto* lir = allocateVariadic( numOperands, tempFixed(CallTempReg0), tempFixed(CallTempReg1)); if (!lir) { abort(AbortReason::Alloc, "OOM: LIRGenerator::visitCreateInlinedArgumentsObject"); return; } lir->setOperand(LCreateInlinedArgumentsObject::CallObj, callObj); lir->setOperand(LCreateInlinedArgumentsObject::Callee, callee); for (uint32_t i = 0; i < numActuals; i++) { MDefinition* arg = ins->getArg(i); uint32_t index = LCreateInlinedArgumentsObject::ArgIndex(i); lir->setBoxOperand(index, useBoxOrTypedOrConstant(arg, /*useConstant = */ true, /*useAtStart = */ true)); } defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGetInlinedArgument(MGetInlinedArgument* ins) { #if defined(JS_PUNBOX64) // On 64-bit architectures, we don't support boxing a typed register // in-place without using a scratch register, so the result register // can't be the same as any of the inputs. Fortunately, those // architectures have registers to spare. const bool useAtStart = false; #else const bool useAtStart = true; #endif LAllocation index = useAtStart ? useRegisterAtStart(ins->index()) : useRegister(ins->index()); uint32_t numActuals = ins->numActuals(); uint32_t numOperands = numActuals * BOX_PIECES + LGetInlinedArgument::NumNonArgumentOperands; auto* lir = allocateVariadic(numOperands); if (!lir) { abort(AbortReason::Alloc, "OOM: LIRGenerator::visitGetInlinedArgument"); return; } lir->setOperand(LGetInlinedArgument::Index, index); for (uint32_t i = 0; i < numActuals; i++) { MDefinition* arg = ins->getArg(i); uint32_t index = LGetInlinedArgument::ArgIndex(i); lir->setBoxOperand( index, useBoxOrTypedOrConstant(arg, /*useConstant = */ true, useAtStart)); } defineBox(lir, ins); } void LIRGenerator::visitGetInlinedArgumentHole(MGetInlinedArgumentHole* ins) { #if defined(JS_CODEGEN_X64) || defined(JS_CODEGEN_MIPS64) // On some 64-bit architectures, we don't support boxing a typed // register in-place without using a scratch register, so the result // register can't be the same as any of the inputs. Fortunately, // those architectures have registers to spare. const bool useAtStart = false; #else const bool useAtStart = true; #endif LAllocation index = useAtStart ? useRegisterAtStart(ins->index()) : useRegister(ins->index()); uint32_t numActuals = ins->numActuals(); uint32_t numOperands = numActuals * BOX_PIECES + LGetInlinedArgumentHole::NumNonArgumentOperands; auto* lir = allocateVariadic(numOperands); if (!lir) { abort(AbortReason::Alloc, "OOM: LIRGenerator::visitGetInlinedArgumentHole"); return; } lir->setOperand(LGetInlinedArgumentHole::Index, index); for (uint32_t i = 0; i < numActuals; i++) { MDefinition* arg = ins->getArg(i); uint32_t index = LGetInlinedArgumentHole::ArgIndex(i); lir->setBoxOperand( index, useBoxOrTypedOrConstant(arg, /*useConstant = */ true, useAtStart)); } assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); } void LIRGenerator::visitGetArgumentsObjectArg(MGetArgumentsObjectArg* ins) { LAllocation argsObj = useRegister(ins->argsObject()); LGetArgumentsObjectArg* lir = new (alloc()) LGetArgumentsObjectArg(argsObj, temp()); defineBox(lir, ins); } void LIRGenerator::visitSetArgumentsObjectArg(MSetArgumentsObjectArg* ins) { LAllocation argsObj = useRegister(ins->argsObject()); LSetArgumentsObjectArg* lir = new (alloc()) LSetArgumentsObjectArg(argsObj, useBox(ins->value()), temp()); add(lir, ins); } void LIRGenerator::visitLoadArgumentsObjectArg(MLoadArgumentsObjectArg* ins) { MDefinition* argsObj = ins->argsObject(); MOZ_ASSERT(argsObj->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LLoadArgumentsObjectArg(useRegister(argsObj), useRegister(index), temp()); assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); } void LIRGenerator::visitLoadArgumentsObjectArgHole( MLoadArgumentsObjectArgHole* ins) { MDefinition* argsObj = ins->argsObject(); MOZ_ASSERT(argsObj->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LLoadArgumentsObjectArgHole( useRegister(argsObj), useRegister(index), temp()); assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); } void LIRGenerator::visitInArgumentsObjectArg(MInArgumentsObjectArg* ins) { MDefinition* argsObj = ins->argsObject(); MOZ_ASSERT(argsObj->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LInArgumentsObjectArg(useRegister(argsObj), useRegister(index), temp()); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitArgumentsObjectLength(MArgumentsObjectLength* ins) { MDefinition* argsObj = ins->argsObject(); MOZ_ASSERT(argsObj->type() == MIRType::Object); auto* lir = new (alloc()) LArgumentsObjectLength(useRegister(argsObj)); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitArrayFromArgumentsObject( MArrayFromArgumentsObject* ins) { MDefinition* argsObj = ins->argsObject(); MOZ_ASSERT(argsObj->type() == MIRType::Object); auto* lir = new (alloc()) LArrayFromArgumentsObject(useRegisterAtStart(argsObj)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGuardArgumentsObjectFlags( MGuardArgumentsObjectFlags* ins) { MDefinition* argsObj = ins->argsObject(); MOZ_ASSERT(argsObj->type() == MIRType::Object); auto* lir = new (alloc()) LGuardArgumentsObjectFlags(useRegister(argsObj), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, argsObj); } void LIRGenerator::visitReturnFromCtor(MReturnFromCtor* ins) { LReturnFromCtor* lir = new (alloc()) LReturnFromCtor(useBox(ins->value()), useRegister(ins->object())); define(lir, ins); } void LIRGenerator::visitBoxNonStrictThis(MBoxNonStrictThis* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); MOZ_ASSERT(ins->input()->type() == MIRType::Value); auto* lir = new (alloc()) LBoxNonStrictThis(useBox(ins->input())); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitImplicitThis(MImplicitThis* ins) { MDefinition* env = ins->envChain(); MOZ_ASSERT(env->type() == MIRType::Object); LImplicitThis* lir = new (alloc()) LImplicitThis(useRegisterAtStart(env)); defineReturn(lir, ins); assignSafepoint(lir, ins); } bool LIRGenerator::lowerCallArguments(MCall* call) { uint32_t argc = call->numStackArgs(); // Align the arguments of a call such that the callee would keep the same // alignment as the caller. uint32_t baseSlot = 0; if (JitStackValueAlignment > 1) { baseSlot = AlignBytes(argc, JitStackValueAlignment); } else { baseSlot = argc; } // Save the maximum number of argument, such that we can have one unique // frame size. if (baseSlot > maxargslots_) { maxargslots_ = baseSlot; } for (size_t i = 0; i < argc; i++) { MDefinition* arg = call->getArg(i); uint32_t argslot = baseSlot - i; // Values take a slow path. if (arg->type() == MIRType::Value) { LStackArgV* stack = new (alloc()) LStackArgV(useBox(arg), argslot); add(stack); } else { // Known types can move constant types and/or payloads. LStackArgT* stack = new (alloc()) LStackArgT(useRegisterOrConstant(arg), argslot, arg->type()); add(stack); } if (!alloc().ensureBallast()) { return false; } } return true; } void LIRGenerator::visitCall(MCall* call) { MOZ_ASSERT(call->getCallee()->type() == MIRType::Object); // In case of oom, skip the rest of the allocations. if (!lowerCallArguments(call)) { abort(AbortReason::Alloc, "OOM: LIRGenerator::visitCall"); return; } WrappedFunction* target = call->getSingleTarget(); LInstruction* lir; if (call->isCallDOMNative()) { // Call DOM functions. MOZ_ASSERT(target && target->isNativeWithoutJitEntry()); Register cxReg, objReg, privReg, argsReg; GetTempRegForIntArg(0, 0, &cxReg); GetTempRegForIntArg(1, 0, &objReg); GetTempRegForIntArg(2, 0, &privReg); mozilla::DebugOnly ok = GetTempRegForIntArg(3, 0, &argsReg); MOZ_ASSERT(ok, "How can we not have four temp registers?"); lir = new (alloc()) LCallDOMNative(tempFixed(cxReg), tempFixed(objReg), tempFixed(privReg), tempFixed(argsReg)); } else if (target) { // Call known functions. if (target->isNativeWithoutJitEntry()) { Register cxReg, numReg, vpReg, tmpReg; GetTempRegForIntArg(0, 0, &cxReg); GetTempRegForIntArg(1, 0, &numReg); GetTempRegForIntArg(2, 0, &vpReg); // Even though this is just a temp reg, use the same API to avoid // register collisions. mozilla::DebugOnly ok = GetTempRegForIntArg(3, 0, &tmpReg); MOZ_ASSERT(ok, "How can we not have four temp registers?"); lir = new (alloc()) LCallNative(tempFixed(cxReg), tempFixed(numReg), tempFixed(vpReg), tempFixed(tmpReg)); } else { lir = new (alloc()) LCallKnown(useRegisterAtStart(call->getCallee()), tempFixed(CallTempReg0)); } } else { // Call anything, using the most generic code. lir = new (alloc()) LCallGeneric(useRegisterAtStart(call->getCallee()), tempFixed(CallTempReg0), tempFixed(CallTempReg1)); } defineReturn(lir, call); assignSafepoint(lir, call); } void LIRGenerator::visitApplyArgs(MApplyArgs* apply) { MOZ_ASSERT(apply->getFunction()->type() == MIRType::Object); // Assert if the return value is already erased. static_assert(CallTempReg2 != JSReturnReg_Type); static_assert(CallTempReg2 != JSReturnReg_Data); LApplyArgsGeneric* lir = new (alloc()) LApplyArgsGeneric( useFixedAtStart(apply->getFunction(), CallTempReg3), useFixedAtStart(apply->getArgc(), CallTempReg0), useBoxFixedAtStart(apply->getThis(), CallTempReg4, CallTempReg5), tempFixed(CallTempReg1), // object register tempFixed(CallTempReg2)); // stack counter register // Bailout is needed in the case of too many values in the arguments array. assignSnapshot(lir, apply->bailoutKind()); defineReturn(lir, apply); assignSafepoint(lir, apply); } void LIRGenerator::visitApplyArgsObj(MApplyArgsObj* apply) { MOZ_ASSERT(apply->getFunction()->type() == MIRType::Object); // Assert if the return value is already erased. static_assert(CallTempReg2 != JSReturnReg_Type); static_assert(CallTempReg2 != JSReturnReg_Data); LApplyArgsObj* lir = new (alloc()) LApplyArgsObj( useFixedAtStart(apply->getFunction(), CallTempReg3), useFixedAtStart(apply->getArgsObj(), CallTempReg0), useBoxFixedAtStart(apply->getThis(), CallTempReg4, CallTempReg5), tempFixed(CallTempReg1), // object register tempFixed(CallTempReg2)); // stack counter register // Bailout is needed in the case of too many values in the arguments array. assignSnapshot(lir, apply->bailoutKind()); defineReturn(lir, apply); assignSafepoint(lir, apply); } void LIRGenerator::visitApplyArray(MApplyArray* apply) { MOZ_ASSERT(apply->getFunction()->type() == MIRType::Object); // Assert if the return value is already erased. static_assert(CallTempReg2 != JSReturnReg_Type); static_assert(CallTempReg2 != JSReturnReg_Data); LApplyArrayGeneric* lir = new (alloc()) LApplyArrayGeneric( useFixedAtStart(apply->getFunction(), CallTempReg3), useFixedAtStart(apply->getElements(), CallTempReg0), useBoxFixedAtStart(apply->getThis(), CallTempReg4, CallTempReg5), tempFixed(CallTempReg1), // object register tempFixed(CallTempReg2)); // stack counter register // Bailout is needed in the case of too many values in the array, or empty // space at the end of the array. assignSnapshot(lir, apply->bailoutKind()); defineReturn(lir, apply); assignSafepoint(lir, apply); } void LIRGenerator::visitConstructArgs(MConstructArgs* mir) { MOZ_ASSERT(mir->getFunction()->type() == MIRType::Object); MOZ_ASSERT(mir->getArgc()->type() == MIRType::Int32); MOZ_ASSERT(mir->getNewTarget()->type() == MIRType::Object); MOZ_ASSERT(mir->getThis()->type() == MIRType::Value); // Assert if the return value is already erased. static_assert(CallTempReg2 != JSReturnReg_Type); static_assert(CallTempReg2 != JSReturnReg_Data); auto* lir = new (alloc()) LConstructArgsGeneric( useFixedAtStart(mir->getFunction(), CallTempReg3), useFixedAtStart(mir->getArgc(), CallTempReg0), useFixedAtStart(mir->getNewTarget(), CallTempReg1), useBoxFixedAtStart(mir->getThis(), CallTempReg4, CallTempReg5), tempFixed(CallTempReg2)); // Bailout is needed in the case of too many values in the arguments array. assignSnapshot(lir, mir->bailoutKind()); defineReturn(lir, mir); assignSafepoint(lir, mir); } void LIRGenerator::visitConstructArray(MConstructArray* mir) { MOZ_ASSERT(mir->getFunction()->type() == MIRType::Object); MOZ_ASSERT(mir->getElements()->type() == MIRType::Elements); MOZ_ASSERT(mir->getNewTarget()->type() == MIRType::Object); MOZ_ASSERT(mir->getThis()->type() == MIRType::Value); // Assert if the return value is already erased. static_assert(CallTempReg2 != JSReturnReg_Type); static_assert(CallTempReg2 != JSReturnReg_Data); auto* lir = new (alloc()) LConstructArrayGeneric( useFixedAtStart(mir->getFunction(), CallTempReg3), useFixedAtStart(mir->getElements(), CallTempReg0), useFixedAtStart(mir->getNewTarget(), CallTempReg1), useBoxFixedAtStart(mir->getThis(), CallTempReg4, CallTempReg5), tempFixed(CallTempReg2)); // Bailout is needed in the case of too many values in the array, or empty // space at the end of the array. assignSnapshot(lir, mir->bailoutKind()); defineReturn(lir, mir); assignSafepoint(lir, mir); } void LIRGenerator::visitBail(MBail* bail) { LBail* lir = new (alloc()) LBail(); assignSnapshot(lir, bail->bailoutKind()); add(lir, bail); } void LIRGenerator::visitUnreachable(MUnreachable* unreachable) { LUnreachable* lir = new (alloc()) LUnreachable(); add(lir, unreachable); } void LIRGenerator::visitEncodeSnapshot(MEncodeSnapshot* mir) { LEncodeSnapshot* lir = new (alloc()) LEncodeSnapshot(); assignSnapshot(lir, mir->bailoutKind()); add(lir, mir); } void LIRGenerator::visitUnreachableResult(MUnreachableResult* mir) { if (mir->type() == MIRType::Value) { auto* lir = new (alloc()) LUnreachableResultV(); defineBox(lir, mir); } else { auto* lir = new (alloc()) LUnreachableResultT(); define(lir, mir); } } void LIRGenerator::visitAssertFloat32(MAssertFloat32* assertion) { MIRType type = assertion->input()->type(); DebugOnly checkIsFloat32 = assertion->mustBeFloat32(); if (type != MIRType::Value && !JitOptions.eagerIonCompilation()) { MOZ_ASSERT_IF(checkIsFloat32, type == MIRType::Float32); MOZ_ASSERT_IF(!checkIsFloat32, type != MIRType::Float32); } } void LIRGenerator::visitAssertRecoveredOnBailout( MAssertRecoveredOnBailout* assertion) { MOZ_CRASH("AssertRecoveredOnBailout nodes are always recovered on bailouts."); } [[nodiscard]] static JSOp ReorderComparison(JSOp op, MDefinition** lhsp, MDefinition** rhsp) { MDefinition* lhs = *lhsp; MDefinition* rhs = *rhsp; if (lhs->maybeConstantValue()) { *rhsp = lhs; *lhsp = rhs; return ReverseCompareOp(op); } return op; } void LIRGenerator::visitTest(MTest* test) { MDefinition* opd = test->getOperand(0); MBasicBlock* ifTrue = test->ifTrue(); MBasicBlock* ifFalse = test->ifFalse(); // String is converted to length of string in the type analysis phase (see // TestPolicy). MOZ_ASSERT(opd->type() != MIRType::String); // Testing a constant. if (MConstant* constant = opd->maybeConstantValue()) { bool b; if (constant->valueToBoolean(&b)) { add(new (alloc()) LGoto(b ? ifTrue : ifFalse)); return; } } if (opd->type() == MIRType::Value) { auto* lir = new (alloc()) LTestVAndBranch( ifTrue, ifFalse, useBox(opd), tempDouble(), tempToUnbox(), temp()); add(lir, test); return; } // Objects are truthy, except if it might emulate undefined. if (opd->type() == MIRType::Object) { add(new (alloc()) LTestOAndBranch(useRegister(opd), ifTrue, ifFalse, temp()), test); return; } // These must be explicitly sniffed out since they are constants and have // no payload. if (opd->type() == MIRType::Undefined || opd->type() == MIRType::Null) { add(new (alloc()) LGoto(ifFalse)); return; } // All symbols are truthy. if (opd->type() == MIRType::Symbol) { add(new (alloc()) LGoto(ifTrue)); return; } // Try to match the pattern // test=MTest( // comp=MCompare( // {EQ,NE} for {Int,UInt}{32,64}, // bitAnd={MBitAnd,MWasmBinaryBitwise(And{32,64})}(x, y), // MConstant(0) // ) // ) // and produce a single LBitAndAndBranch node. This requires both `comp` // and `bitAnd` to be marked emit-at-uses. Since we can't use // LBitAndAndBranch to represent a 64-bit AND on a 32-bit target, the 64-bit // case is restricted to 64-bit targets. if (opd->isCompare() && opd->isEmittedAtUses()) { #ifdef JS_64BIT constexpr bool targetIs64 = true; #else constexpr bool targetIs64 = false; #endif MCompare* comp = opd->toCompare(); Assembler::Condition compCond = JSOpToCondition(comp->compareType(), comp->jsop()); MDefinition* compL = comp->getOperand(0); MDefinition* compR = comp->getOperand(1); if ((comp->compareType() == MCompare::Compare_Int32 || comp->compareType() == MCompare::Compare_UInt32 || (targetIs64 && comp->compareType() == MCompare::Compare_Int64) || (targetIs64 && comp->compareType() == MCompare::Compare_UInt64)) && (compCond == Assembler::Equal || compCond == Assembler::NotEqual) && compR->isConstant() && (compR->toConstant()->isInt32(0) || (targetIs64 && compR->toConstant()->isInt64(0))) && (compL->isBitAnd() || (compL->isWasmBinaryBitwise() && compL->toWasmBinaryBitwise()->subOpcode() == MWasmBinaryBitwise::SubOpcode::And))) { // The MCompare is OK; now check its first operand (the and-ish node). MDefinition* bitAnd = compL; MDefinition* bitAndL = bitAnd->getOperand(0); MDefinition* bitAndR = bitAnd->getOperand(1); MIRType bitAndLTy = bitAndL->type(); MIRType bitAndRTy = bitAndR->type(); if (bitAnd->isEmittedAtUses() && bitAndLTy == bitAndRTy && (bitAndLTy == MIRType::Int32 || (targetIs64 && bitAndLTy == MIRType::Int64))) { // Pattern match succeeded. ReorderCommutative(&bitAndL, &bitAndR, test); if (compCond == Assembler::Equal) { compCond = Assembler::Zero; } else if (compCond == Assembler::NotEqual) { compCond = Assembler::NonZero; } else { MOZ_ASSERT_UNREACHABLE("inequality operators cannot be folded"); } MOZ_ASSERT_IF(!targetIs64, bitAndLTy == MIRType::Int32); lowerForBitAndAndBranch( new (alloc()) LBitAndAndBranch( ifTrue, ifFalse, bitAndLTy == MIRType::Int64, compCond), test, bitAndL, bitAndR); return; } } } // Check if the operand for this test is a compare operation. If it is, we // want to emit an LCompare*AndBranch rather than an LTest*AndBranch, to fuse // the compare and jump instructions. if (opd->isCompare() && opd->isEmittedAtUses()) { MCompare* comp = opd->toCompare(); MDefinition* left = comp->lhs(); MDefinition* right = comp->rhs(); // Try to fold the comparison so that we don't have to handle all cases. bool result; if (comp->tryFold(&result)) { add(new (alloc()) LGoto(result ? ifTrue : ifFalse)); return; } // Emit LCompare*AndBranch. // Compare and branch null/undefined. // The second operand has known null/undefined type, // so just test the first operand. if (comp->compareType() == MCompare::Compare_Null || comp->compareType() == MCompare::Compare_Undefined) { if (left->type() == MIRType::Object) { auto* lir = new (alloc()) LIsNullOrLikeUndefinedAndBranchT( comp, useRegister(left), ifTrue, ifFalse, temp()); add(lir, test); return; } if (IsLooseEqualityOp(comp->jsop())) { auto* lir = new (alloc()) LIsNullOrLikeUndefinedAndBranchV( comp, ifTrue, ifFalse, useBox(left), temp(), tempToUnbox()); add(lir, test); return; } if (comp->compareType() == MCompare::Compare_Null) { auto* lir = new (alloc()) LIsNullAndBranch(comp, ifTrue, ifFalse, useBox(left)); add(lir, test); return; } auto* lir = new (alloc()) LIsUndefinedAndBranch(comp, ifTrue, ifFalse, useBox(left)); add(lir, test); return; } // Compare and branch Int32, Symbol, Object, or RefOrNull pointers. if (comp->isInt32Comparison() || comp->compareType() == MCompare::Compare_UInt32 || comp->compareType() == MCompare::Compare_UIntPtr || comp->compareType() == MCompare::Compare_Object || comp->compareType() == MCompare::Compare_Symbol || comp->compareType() == MCompare::Compare_RefOrNull) { JSOp op = ReorderComparison(comp->jsop(), &left, &right); LAllocation lhs = useRegister(left); LAllocation rhs; if (comp->isInt32Comparison() || comp->compareType() == MCompare::Compare_UInt32 || comp->compareType() == MCompare::Compare_UIntPtr) { rhs = useAnyOrInt32Constant(right); } else { rhs = useAny(right); } LCompareAndBranch* lir = new (alloc()) LCompareAndBranch(comp, op, lhs, rhs, ifTrue, ifFalse); add(lir, test); return; } // Compare and branch Int64. if (comp->compareType() == MCompare::Compare_Int64 || comp->compareType() == MCompare::Compare_UInt64) { JSOp op = ReorderComparison(comp->jsop(), &left, &right); lowerForCompareI64AndBranch(test, comp, op, left, right, ifTrue, ifFalse); return; } // Compare and branch doubles. if (comp->isDoubleComparison()) { LAllocation lhs = useRegister(left); LAllocation rhs = useRegister(right); LCompareDAndBranch* lir = new (alloc()) LCompareDAndBranch(comp, lhs, rhs, ifTrue, ifFalse); add(lir, test); return; } // Compare and branch floats. if (comp->isFloat32Comparison()) { LAllocation lhs = useRegister(left); LAllocation rhs = useRegister(right); LCompareFAndBranch* lir = new (alloc()) LCompareFAndBranch(comp, lhs, rhs, ifTrue, ifFalse); add(lir, test); return; } } // Check if the operand for this test is a bitand operation. If it is, we want // to emit an LBitAndAndBranch rather than an LTest*AndBranch. if (opd->isBitAnd() && opd->isEmittedAtUses()) { MDefinition* lhs = opd->getOperand(0); MDefinition* rhs = opd->getOperand(1); if (lhs->type() == MIRType::Int32 && rhs->type() == MIRType::Int32) { ReorderCommutative(&lhs, &rhs, test); lowerForBitAndAndBranch(new (alloc()) LBitAndAndBranch(ifTrue, ifFalse, /*is64=*/false), test, lhs, rhs); return; } } #if defined(ENABLE_WASM_SIMD) && \ (defined(JS_CODEGEN_X86) || defined(JS_CODEGEN_X64) || \ defined(JS_CODEGEN_ARM64)) // Check if the operand for this test is an any_true/all_true SIMD operation. // If it is, we want to emit an LWasmReduceAndBranchSimd128 node to avoid // generating an intermediate boolean result. if (opd->isWasmReduceSimd128() && opd->isEmittedAtUses()) { MWasmReduceSimd128* node = opd->toWasmReduceSimd128(); if (canFoldReduceSimd128AndBranch(node->simdOp())) { # ifdef DEBUG js::wasm::ReportSimdAnalysis("simd128-to-scalar-and-branch -> folded"); # endif auto* lir = new (alloc()) LWasmReduceAndBranchSimd128( useRegister(node->input()), node->simdOp(), ifTrue, ifFalse); add(lir, test); return; } } #endif if (opd->isIsObject() && opd->isEmittedAtUses()) { MDefinition* input = opd->toIsObject()->input(); MOZ_ASSERT(input->type() == MIRType::Value); LIsObjectAndBranch* lir = new (alloc()) LIsObjectAndBranch(ifTrue, ifFalse, useBoxAtStart(input)); add(lir, test); return; } if (opd->isWasmGcObjectIsSubtypeOf() && opd->isEmittedAtUses()) { MWasmGcObjectIsSubtypeOf* isSubTypeOf = opd->toWasmGcObjectIsSubtypeOf(); LAllocation object = useRegister(isSubTypeOf->object()); LAllocation superTypeDef = useRegister(isSubTypeOf->superTypeDef()); uint32_t subTypingDepth = isSubTypeOf->subTypingDepth(); LDefinition subTypeDepth = temp(); LDefinition scratch = subTypingDepth >= wasm::MinSuperTypeVectorLength ? temp() : LDefinition(); add(new (alloc()) LWasmGcObjectIsSubtypeOfAndBranch( ifTrue, ifFalse, object, superTypeDef, subTypingDepth, subTypeDepth, scratch), test); return; } if (opd->isIsNullOrUndefined() && opd->isEmittedAtUses()) { MIsNullOrUndefined* isNullOrUndefined = opd->toIsNullOrUndefined(); MDefinition* input = isNullOrUndefined->value(); MOZ_ASSERT(input->type() == MIRType::Value); auto* lir = new (alloc()) LIsNullOrUndefinedAndBranch( isNullOrUndefined, ifTrue, ifFalse, useBoxAtStart(input)); add(lir, test); return; } if (opd->isIsNoIter()) { MOZ_ASSERT(opd->isEmittedAtUses()); MDefinition* input = opd->toIsNoIter()->input(); MOZ_ASSERT(input->type() == MIRType::Value); LIsNoIterAndBranch* lir = new (alloc()) LIsNoIterAndBranch(ifTrue, ifFalse, useBox(input)); add(lir, test); return; } switch (opd->type()) { case MIRType::Double: add(new (alloc()) LTestDAndBranch(useRegister(opd), ifTrue, ifFalse)); break; case MIRType::Float32: add(new (alloc()) LTestFAndBranch(useRegister(opd), ifTrue, ifFalse)); break; case MIRType::Int32: case MIRType::Boolean: add(new (alloc()) LTestIAndBranch(useRegister(opd), ifTrue, ifFalse)); break; case MIRType::Int64: add(new (alloc()) LTestI64AndBranch(useInt64Register(opd), ifTrue, ifFalse)); break; case MIRType::BigInt: add(new (alloc()) LTestBIAndBranch(useRegister(opd), ifTrue, ifFalse)); break; default: MOZ_CRASH("Bad type"); } } static inline bool CanEmitCompareAtUses(MInstruction* ins) { if (!ins->canEmitAtUses()) { return false; } // If the result is never used, we can usefully defer emission to the use // point, since that will never happen. MUseIterator iter(ins->usesBegin()); if (iter == ins->usesEnd()) { return true; } // If the first use isn't of the expected form, the answer is No. MNode* node = iter->consumer(); if (!node->isDefinition()) { return false; } MDefinition* use = node->toDefinition(); if (!use->isTest() && !use->isWasmSelect()) { return false; } // Emission can be deferred to the first use point, but only if there are no // other use points. iter++; return iter == ins->usesEnd(); } static bool CanCompareCharactersInline(const JSLinearString* linear) { size_t length = linear->length(); // Limit the number of inline instructions used for character comparisons. Use // the same instruction limit for both encodings, i.e. two-byte uses half the // limit of Latin-1 strings. constexpr size_t Latin1StringCompareCutoff = 32; constexpr size_t TwoByteStringCompareCutoff = 16; return length > 0 && (linear->hasLatin1Chars() ? length <= Latin1StringCompareCutoff : length <= TwoByteStringCompareCutoff); } void LIRGenerator::visitCompare(MCompare* comp) { MDefinition* left = comp->lhs(); MDefinition* right = comp->rhs(); // Try to fold the comparison so that we don't have to handle all cases. bool result; if (comp->tryFold(&result)) { define(new (alloc()) LInteger(result), comp); return; } // Move below the emitAtUses call if we ever implement // LCompareSAndBranch. Doing this now wouldn't be wrong, but doesn't // make sense and avoids confusion. if (comp->compareType() == MCompare::Compare_String) { if (IsEqualityOp(comp->jsop())) { MConstant* constant = nullptr; if (left->isConstant()) { constant = left->toConstant(); } else if (right->isConstant()) { constant = right->toConstant(); } if (constant) { JSLinearString* linear = &constant->toString()->asLinear(); if (CanCompareCharactersInline(linear)) { MDefinition* input = left->isConstant() ? right : left; auto* lir = new (alloc()) LCompareSInline(useRegister(input), linear); define(lir, comp); assignSafepoint(lir, comp); return; } } } LCompareS* lir = new (alloc()) LCompareS(useRegister(left), useRegister(right)); define(lir, comp); assignSafepoint(lir, comp); return; } // Compare two BigInts. if (comp->compareType() == MCompare::Compare_BigInt) { auto* lir = new (alloc()) LCompareBigInt( useRegister(left), useRegister(right), temp(), temp(), temp()); define(lir, comp); return; } // Compare BigInt with Int32. if (comp->compareType() == MCompare::Compare_BigInt_Int32) { auto* lir = new (alloc()) LCompareBigIntInt32( useRegister(left), useRegister(right), temp(), temp()); define(lir, comp); return; } // Compare BigInt with Double. if (comp->compareType() == MCompare::Compare_BigInt_Double) { auto* lir = new (alloc()) LCompareBigIntDouble(useRegisterAtStart(left), useRegisterAtStart(right)); defineReturn(lir, comp); return; } // Compare BigInt with String. if (comp->compareType() == MCompare::Compare_BigInt_String) { auto* lir = new (alloc()) LCompareBigIntString(useRegisterAtStart(left), useRegisterAtStart(right)); defineReturn(lir, comp); assignSafepoint(lir, comp); return; } // Sniff out if the output of this compare is used only for a branching. // If it is, then we will emit an LCompare*AndBranch instruction in place // of this compare and any test that uses this compare. Thus, we can // ignore this Compare. if (CanEmitCompareAtUses(comp)) { emitAtUses(comp); return; } // Compare Null and Undefined. if (comp->compareType() == MCompare::Compare_Null || comp->compareType() == MCompare::Compare_Undefined) { if (left->type() == MIRType::Object) { define(new (alloc()) LIsNullOrLikeUndefinedT(useRegister(left)), comp); return; } if (IsLooseEqualityOp(comp->jsop())) { auto* lir = new (alloc()) LIsNullOrLikeUndefinedV(useBox(left), tempToUnbox()); define(lir, comp); return; } if (comp->compareType() == MCompare::Compare_Null) { auto* lir = new (alloc()) LIsNull(useBox(left)); define(lir, comp); return; } auto* lir = new (alloc()) LIsUndefined(useBox(left)); define(lir, comp); return; } // Compare Int32, Symbol, Object or Wasm pointers. if (comp->isInt32Comparison() || comp->compareType() == MCompare::Compare_UInt32 || comp->compareType() == MCompare::Compare_UIntPtr || comp->compareType() == MCompare::Compare_Object || comp->compareType() == MCompare::Compare_Symbol || comp->compareType() == MCompare::Compare_RefOrNull) { JSOp op = ReorderComparison(comp->jsop(), &left, &right); LAllocation lhs = useRegister(left); LAllocation rhs; if (comp->isInt32Comparison() || comp->compareType() == MCompare::Compare_UInt32 || comp->compareType() == MCompare::Compare_UIntPtr) { rhs = useAnyOrInt32Constant(right); } else { rhs = useAny(right); } define(new (alloc()) LCompare(op, lhs, rhs), comp); return; } // Compare Int64. if (comp->compareType() == MCompare::Compare_Int64 || comp->compareType() == MCompare::Compare_UInt64) { JSOp op = ReorderComparison(comp->jsop(), &left, &right); define(new (alloc()) LCompareI64(op, useInt64Register(left), useInt64OrConstant(right)), comp); return; } // Compare doubles. if (comp->isDoubleComparison()) { define(new (alloc()) LCompareD(useRegister(left), useRegister(right)), comp); return; } // Compare float32. if (comp->isFloat32Comparison()) { define(new (alloc()) LCompareF(useRegister(left), useRegister(right)), comp); return; } MOZ_CRASH("Unrecognized compare type."); } void LIRGenerator::visitSameValueDouble(MSameValueDouble* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == MIRType::Double); MOZ_ASSERT(rhs->type() == MIRType::Double); auto* lir = new (alloc()) LSameValueDouble(useRegister(lhs), useRegister(rhs), tempDouble()); define(lir, ins); } void LIRGenerator::visitSameValue(MSameValue* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == MIRType::Value); MOZ_ASSERT(rhs->type() == MIRType::Value); auto* lir = new (alloc()) LSameValue(useBox(lhs), useBox(rhs)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::lowerBitOp(JSOp op, MBinaryInstruction* ins) { MDefinition* lhs = ins->getOperand(0); MDefinition* rhs = ins->getOperand(1); MOZ_ASSERT(IsIntType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(lhs->type() == MIRType::Int32); MOZ_ASSERT(rhs->type() == MIRType::Int32); ReorderCommutative(&lhs, &rhs, ins); lowerForALU(new (alloc()) LBitOpI(op), ins, lhs, rhs); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(lhs->type() == MIRType::Int64); MOZ_ASSERT(rhs->type() == MIRType::Int64); ReorderCommutative(&lhs, &rhs, ins); lowerForALUInt64(new (alloc()) LBitOpI64(op), ins, lhs, rhs); return; } MOZ_CRASH("Unhandled integer specialization"); } void LIRGenerator::visitTypeOf(MTypeOf* ins) { MDefinition* opd = ins->input(); if (opd->type() == MIRType::Object) { auto* lir = new (alloc()) LTypeOfO(useRegister(opd)); define(lir, ins); return; } MOZ_ASSERT(opd->type() == MIRType::Value); LTypeOfV* lir = new (alloc()) LTypeOfV(useBox(opd), tempToUnbox()); define(lir, ins); } void LIRGenerator::visitTypeOfName(MTypeOfName* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Int32); auto* lir = new (alloc()) LTypeOfName(useRegister(input)); define(lir, ins); } void LIRGenerator::visitTypeOfIs(MTypeOfIs* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Object || input->type() == MIRType::Value); switch (ins->jstype()) { case JSTYPE_UNDEFINED: case JSTYPE_OBJECT: case JSTYPE_FUNCTION: { if (input->type() == MIRType::Object) { auto* lir = new (alloc()) LTypeOfIsNonPrimitiveO(useRegister(input)); define(lir, ins); } else { auto* lir = new (alloc()) LTypeOfIsNonPrimitiveV(useBox(input), tempToUnbox()); define(lir, ins); } return; } case JSTYPE_STRING: case JSTYPE_NUMBER: case JSTYPE_BOOLEAN: case JSTYPE_SYMBOL: case JSTYPE_BIGINT: { MOZ_ASSERT(input->type() == MIRType::Value); auto* lir = new (alloc()) LTypeOfIsPrimitive(useBoxAtStart(input)); define(lir, ins); return; } #ifdef ENABLE_RECORD_TUPLE case JSTYPE_RECORD: case JSTYPE_TUPLE: #endif case JSTYPE_LIMIT: break; } MOZ_CRASH("Unhandled JSType"); } void LIRGenerator::visitToAsyncIter(MToAsyncIter* ins) { LToAsyncIter* lir = new (alloc()) LToAsyncIter( useRegisterAtStart(ins->iterator()), useBoxAtStart(ins->nextMethod())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitToPropertyKeyCache(MToPropertyKeyCache* ins) { MDefinition* input = ins->getOperand(0); MOZ_ASSERT(ins->type() == MIRType::Value); auto* lir = new (alloc()) LToPropertyKeyCache(useBox(input)); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBitNot(MBitNot* ins) { MDefinition* input = ins->getOperand(0); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(input->type() == MIRType::Int32); lowerForALU(new (alloc()) LBitNotI(), ins, input); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(input->type() == MIRType::Int64); lowerForALUInt64(new (alloc()) LBitNotI64(), ins, input); return; } MOZ_CRASH("Unhandled integer specialization"); } static bool CanEmitBitAndAtUses(MInstruction* ins) { if (!ins->canEmitAtUses()) { return false; } MIRType tyL = ins->getOperand(0)->type(); MIRType tyR = ins->getOperand(1)->type(); if (tyL != tyR || (tyL != MIRType::Int32 && tyL != MIRType::Int64)) { return false; } MUseIterator iter(ins->usesBegin()); if (iter == ins->usesEnd()) { return false; } MNode* node = iter->consumer(); if (!node->isDefinition() || !node->toDefinition()->isInstruction()) { return false; } MInstruction* use = node->toDefinition()->toInstruction(); if (!use->isTest() && !(use->isCompare() && CanEmitCompareAtUses(use))) { return false; } iter++; return iter == ins->usesEnd(); } void LIRGenerator::visitBitAnd(MBitAnd* ins) { // Sniff out if the output of this bitand is used only for a branching. // If it is, then we will emit an LBitAndAndBranch instruction in place // of this bitand and any test that uses this bitand. Thus, we can // ignore this BitAnd. if (CanEmitBitAndAtUses(ins)) { emitAtUses(ins); } else { lowerBitOp(JSOp::BitAnd, ins); } } void LIRGenerator::visitBitOr(MBitOr* ins) { lowerBitOp(JSOp::BitOr, ins); } void LIRGenerator::visitBitXor(MBitXor* ins) { lowerBitOp(JSOp::BitXor, ins); } void LIRGenerator::visitWasmBinaryBitwise(MWasmBinaryBitwise* ins) { switch (ins->subOpcode()) { case MWasmBinaryBitwise::SubOpcode::And: if (CanEmitBitAndAtUses(ins)) { emitAtUses(ins); } else { lowerBitOp(JSOp::BitAnd, ins); } break; case MWasmBinaryBitwise::SubOpcode::Or: lowerBitOp(JSOp::BitOr, ins); break; case MWasmBinaryBitwise::SubOpcode::Xor: lowerBitOp(JSOp::BitXor, ins); break; default: MOZ_CRASH(); } } void LIRGenerator::lowerShiftOp(JSOp op, MShiftInstruction* ins) { MDefinition* lhs = ins->getOperand(0); MDefinition* rhs = ins->getOperand(1); if (op == JSOp::Ursh && ins->type() == MIRType::Double) { MOZ_ASSERT(lhs->type() == MIRType::Int32); MOZ_ASSERT(rhs->type() == MIRType::Int32); lowerUrshD(ins->toUrsh()); return; } MOZ_ASSERT(IsIntType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(lhs->type() == MIRType::Int32); MOZ_ASSERT(rhs->type() == MIRType::Int32); LShiftI* lir = new (alloc()) LShiftI(op); if (op == JSOp::Ursh) { if (ins->toUrsh()->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } } lowerForShift(lir, ins, lhs, rhs); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(lhs->type() == MIRType::Int64); MOZ_ASSERT(rhs->type() == MIRType::Int64); lowerForShiftInt64(new (alloc()) LShiftI64(op), ins, lhs, rhs); return; } MOZ_CRASH("Unhandled integer specialization"); } void LIRGenerator::visitLsh(MLsh* ins) { lowerShiftOp(JSOp::Lsh, ins); } void LIRGenerator::visitRsh(MRsh* ins) { lowerShiftOp(JSOp::Rsh, ins); } void LIRGenerator::visitUrsh(MUrsh* ins) { lowerShiftOp(JSOp::Ursh, ins); } void LIRGenerator::visitSignExtendInt32(MSignExtendInt32* ins) { LInstructionHelper<1, 1, 0>* lir; if (ins->mode() == MSignExtendInt32::Byte) { lir = new (alloc()) LSignExtendInt32(useByteOpRegisterAtStart(ins->input()), ins->mode()); } else { lir = new (alloc()) LSignExtendInt32(useRegisterAtStart(ins->input()), ins->mode()); } define(lir, ins); } void LIRGenerator::visitRotate(MRotate* ins) { MDefinition* input = ins->input(); MDefinition* count = ins->count(); if (ins->type() == MIRType::Int32) { auto* lir = new (alloc()) LRotate(); lowerForShift(lir, ins, input, count); } else if (ins->type() == MIRType::Int64) { auto* lir = new (alloc()) LRotateI64(); lowerForShiftInt64(lir, ins, input, count); } else { MOZ_CRASH("unexpected type in visitRotate"); } } void LIRGenerator::visitFloor(MFloor* ins) { MIRType type = ins->input()->type(); MOZ_ASSERT(IsFloatingPointType(type)); LInstructionHelper<1, 1, 0>* lir; if (type == MIRType::Double) { lir = new (alloc()) LFloor(useRegister(ins->input())); } else { lir = new (alloc()) LFloorF(useRegister(ins->input())); } assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitCeil(MCeil* ins) { MIRType type = ins->input()->type(); MOZ_ASSERT(IsFloatingPointType(type)); LInstructionHelper<1, 1, 0>* lir; if (type == MIRType::Double) { lir = new (alloc()) LCeil(useRegister(ins->input())); } else { lir = new (alloc()) LCeilF(useRegister(ins->input())); } assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitRound(MRound* ins) { MIRType type = ins->input()->type(); MOZ_ASSERT(IsFloatingPointType(type)); LInstructionHelper<1, 1, 1>* lir; if (type == MIRType::Double) { lir = new (alloc()) LRound(useRegister(ins->input()), tempDouble()); } else { lir = new (alloc()) LRoundF(useRegister(ins->input()), tempFloat32()); } assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitTrunc(MTrunc* ins) { MIRType type = ins->input()->type(); MOZ_ASSERT(IsFloatingPointType(type)); LInstructionHelper<1, 1, 0>* lir; if (type == MIRType::Double) { lir = new (alloc()) LTrunc(useRegister(ins->input())); } else { lir = new (alloc()) LTruncF(useRegister(ins->input())); } assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitNearbyInt(MNearbyInt* ins) { MIRType inputType = ins->input()->type(); MOZ_ASSERT(IsFloatingPointType(inputType)); MOZ_ASSERT(ins->type() == inputType); LInstructionHelper<1, 1, 0>* lir; if (inputType == MIRType::Double) { lir = new (alloc()) LNearbyInt(useRegisterAtStart(ins->input())); } else { lir = new (alloc()) LNearbyIntF(useRegisterAtStart(ins->input())); } define(lir, ins); } void LIRGenerator::visitMinMax(MMinMax* ins) { MDefinition* first = ins->getOperand(0); MDefinition* second = ins->getOperand(1); ReorderCommutative(&first, &second, ins); LMinMaxBase* lir; switch (ins->type()) { case MIRType::Int32: lir = new (alloc()) LMinMaxI(useRegisterAtStart(first), useRegisterOrConstant(second)); break; case MIRType::Float32: lir = new (alloc()) LMinMaxF(useRegisterAtStart(first), useRegister(second)); break; case MIRType::Double: lir = new (alloc()) LMinMaxD(useRegisterAtStart(first), useRegister(second)); break; default: MOZ_CRASH(); } // Input reuse is OK (for now) even on ARM64: floating min/max are fairly // expensive due to SNaN -> QNaN conversion, and int min/max is for asm.js. defineReuseInput(lir, ins, 0); } void LIRGenerator::visitMinMaxArray(MMinMaxArray* ins) { LInstructionHelper<1, 1, 3>* lir; if (ins->type() == MIRType::Int32) { lir = new (alloc()) LMinMaxArrayI(useRegisterAtStart(ins->array()), temp(), temp(), temp()); } else { MOZ_ASSERT(ins->type() == MIRType::Double); lir = new (alloc()) LMinMaxArrayD(useRegisterAtStart(ins->array()), tempDouble(), temp(), temp()); } assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } LInstructionHelper<1, 1, 0>* LIRGenerator::allocateAbs(MAbs* ins, LAllocation input) { MDefinition* num = ins->input(); MOZ_ASSERT(IsNumberType(num->type())); LInstructionHelper<1, 1, 0>* lir; switch (num->type()) { case MIRType::Int32: lir = new (alloc()) LAbsI(input); // needed to handle abs(INT32_MIN) if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } break; case MIRType::Float32: lir = new (alloc()) LAbsF(input); break; case MIRType::Double: lir = new (alloc()) LAbsD(input); break; default: MOZ_CRASH(); } return lir; } void LIRGenerator::visitClz(MClz* ins) { MDefinition* num = ins->num(); MOZ_ASSERT(IsIntType(ins->type())); if (ins->type() == MIRType::Int32) { LClzI* lir = new (alloc()) LClzI(useRegisterAtStart(num)); define(lir, ins); return; } auto* lir = new (alloc()) LClzI64(useInt64RegisterAtStart(num)); defineInt64(lir, ins); } void LIRGenerator::visitCtz(MCtz* ins) { MDefinition* num = ins->num(); MOZ_ASSERT(IsIntType(ins->type())); if (ins->type() == MIRType::Int32) { LCtzI* lir = new (alloc()) LCtzI(useRegisterAtStart(num)); define(lir, ins); return; } auto* lir = new (alloc()) LCtzI64(useInt64RegisterAtStart(num)); defineInt64(lir, ins); } void LIRGenerator::visitPopcnt(MPopcnt* ins) { MDefinition* num = ins->num(); MOZ_ASSERT(IsIntType(ins->type())); if (ins->type() == MIRType::Int32) { LPopcntI* lir = new (alloc()) LPopcntI(useRegisterAtStart(num), temp()); define(lir, ins); return; } auto* lir = new (alloc()) LPopcntI64(useInt64RegisterAtStart(num), temp()); defineInt64(lir, ins); } void LIRGenerator::visitSqrt(MSqrt* ins) { MDefinition* num = ins->input(); MOZ_ASSERT(IsFloatingPointType(num->type())); LInstructionHelper<1, 1, 0>* lir; if (num->type() == MIRType::Double) { lir = new (alloc()) LSqrtD(useRegisterAtStart(num)); } else { lir = new (alloc()) LSqrtF(useRegisterAtStart(num)); } define(lir, ins); } void LIRGenerator::visitAtan2(MAtan2* ins) { MDefinition* y = ins->y(); MOZ_ASSERT(y->type() == MIRType::Double); MDefinition* x = ins->x(); MOZ_ASSERT(x->type() == MIRType::Double); LAtan2D* lir = new (alloc()) LAtan2D(useRegisterAtStart(y), useRegisterAtStart(x)); defineReturn(lir, ins); } void LIRGenerator::visitHypot(MHypot* ins) { LHypot* lir = nullptr; uint32_t length = ins->numOperands(); for (uint32_t i = 0; i < length; ++i) { MOZ_ASSERT(ins->getOperand(i)->type() == MIRType::Double); } switch (length) { case 2: lir = new (alloc()) LHypot(useRegisterAtStart(ins->getOperand(0)), useRegisterAtStart(ins->getOperand(1))); break; case 3: lir = new (alloc()) LHypot(useRegisterAtStart(ins->getOperand(0)), useRegisterAtStart(ins->getOperand(1)), useRegisterAtStart(ins->getOperand(2))); break; case 4: lir = new (alloc()) LHypot(useRegisterAtStart(ins->getOperand(0)), useRegisterAtStart(ins->getOperand(1)), useRegisterAtStart(ins->getOperand(2)), useRegisterAtStart(ins->getOperand(3))); break; default: MOZ_CRASH("Unexpected number of arguments to LHypot."); } defineReturn(lir, ins); } void LIRGenerator::visitPow(MPow* ins) { MDefinition* input = ins->input(); MDefinition* power = ins->power(); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(input->type() == MIRType::Int32); MOZ_ASSERT(power->type() == MIRType::Int32); if (input->isConstant()) { // Restrict this optimization to |base <= 256| to avoid generating too // many consecutive shift instructions. int32_t base = input->toConstant()->toInt32(); if (2 <= base && base <= 256 && mozilla::IsPowerOfTwo(uint32_t(base))) { lowerPowOfTwoI(ins); return; } } auto* lir = new (alloc()) LPowII(useRegister(input), useRegister(power), temp(), temp()); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); return; } MOZ_ASSERT(ins->type() == MIRType::Double); MOZ_ASSERT(input->type() == MIRType::Double); MOZ_ASSERT(power->type() == MIRType::Int32 || power->type() == MIRType::Double); LInstruction* lir; if (power->type() == MIRType::Int32) { lir = new (alloc()) LPowI(useRegisterAtStart(input), useRegisterAtStart(power)); } else { lir = new (alloc()) LPowD(useRegisterAtStart(input), useRegisterAtStart(power)); } defineReturn(lir, ins); } void LIRGenerator::visitSign(MSign* ins) { if (ins->type() == ins->input()->type()) { LInstructionHelper<1, 1, 0>* lir; if (ins->type() == MIRType::Int32) { lir = new (alloc()) LSignI(useRegister(ins->input())); } else { MOZ_ASSERT(ins->type() == MIRType::Double); lir = new (alloc()) LSignD(useRegister(ins->input())); } define(lir, ins); } else { MOZ_ASSERT(ins->type() == MIRType::Int32); MOZ_ASSERT(ins->input()->type() == MIRType::Double); auto* lir = new (alloc()) LSignDI(useRegister(ins->input()), tempDouble()); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } } void LIRGenerator::visitMathFunction(MMathFunction* ins) { MOZ_ASSERT(IsFloatingPointType(ins->type())); MOZ_ASSERT(ins->type() == ins->input()->type()); LInstruction* lir; if (ins->type() == MIRType::Double) { lir = new (alloc()) LMathFunctionD(useRegisterAtStart(ins->input())); } else { lir = new (alloc()) LMathFunctionF(useRegisterAtStart(ins->input())); } defineReturn(lir, ins); } void LIRGenerator::visitRandom(MRandom* ins) { auto* lir = new (alloc()) LRandom(temp(), tempInt64(), tempInt64()); define(lir, ins); } // Try to mark an add or sub instruction as able to recover its input when // bailing out. template static void MaybeSetRecoversInput(S* mir, T* lir) { MOZ_ASSERT(lir->mirRaw() == mir); if (!mir->fallible() || !lir->snapshot()) { return; } if (lir->output()->policy() != LDefinition::MUST_REUSE_INPUT) { return; } // The original operands to an add or sub can't be recovered if they both // use the same register. if (lir->lhs()->isUse() && lir->rhs()->isUse() && lir->lhs()->toUse()->virtualRegister() == lir->rhs()->toUse()->virtualRegister()) { return; } // Add instructions that are on two different values can recover // the input they clobbered via MUST_REUSE_INPUT. Thus, a copy // of that input does not need to be kept alive in the snapshot // for the instruction. lir->setRecoversInput(); const LUse* input = lir->getOperand(lir->output()->getReusedInput())->toUse(); lir->snapshot()->rewriteRecoveredInput(*input); } void LIRGenerator::visitAdd(MAdd* ins) { MDefinition* lhs = ins->getOperand(0); MDefinition* rhs = ins->getOperand(1); MOZ_ASSERT(lhs->type() == rhs->type()); MOZ_ASSERT(IsNumberType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(lhs->type() == MIRType::Int32); ReorderCommutative(&lhs, &rhs, ins); LAddI* lir = new (alloc()) LAddI; if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } lowerForALU(lir, ins, lhs, rhs); MaybeSetRecoversInput(ins, lir); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(lhs->type() == MIRType::Int64); ReorderCommutative(&lhs, &rhs, ins); LAddI64* lir = new (alloc()) LAddI64; lowerForALUInt64(lir, ins, lhs, rhs); return; } if (ins->type() == MIRType::Double) { MOZ_ASSERT(lhs->type() == MIRType::Double); ReorderCommutative(&lhs, &rhs, ins); lowerForFPU(new (alloc()) LMathD(JSOp::Add), ins, lhs, rhs); return; } if (ins->type() == MIRType::Float32) { MOZ_ASSERT(lhs->type() == MIRType::Float32); ReorderCommutative(&lhs, &rhs, ins); lowerForFPU(new (alloc()) LMathF(JSOp::Add), ins, lhs, rhs); return; } MOZ_CRASH("Unhandled number specialization"); } void LIRGenerator::visitSub(MSub* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == rhs->type()); MOZ_ASSERT(IsNumberType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(lhs->type() == MIRType::Int32); LSubI* lir = new (alloc()) LSubI; if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } // If our LHS is a constant 0 and we don't have to worry about results that // can't be represented as an int32, we can optimize to an LNegI. if (!ins->fallible() && lhs->isConstant() && lhs->toConstant()->toInt32() == 0) { lowerNegI(ins, rhs); return; } lowerForALU(lir, ins, lhs, rhs); MaybeSetRecoversInput(ins, lir); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(lhs->type() == MIRType::Int64); // If our LHS is a constant 0, we can optimize to an LNegI64. if (lhs->isConstant() && lhs->toConstant()->toInt64() == 0) { lowerNegI64(ins, rhs); return; } LSubI64* lir = new (alloc()) LSubI64; lowerForALUInt64(lir, ins, lhs, rhs); return; } if (ins->type() == MIRType::Double) { MOZ_ASSERT(lhs->type() == MIRType::Double); lowerForFPU(new (alloc()) LMathD(JSOp::Sub), ins, lhs, rhs); return; } if (ins->type() == MIRType::Float32) { MOZ_ASSERT(lhs->type() == MIRType::Float32); lowerForFPU(new (alloc()) LMathF(JSOp::Sub), ins, lhs, rhs); return; } MOZ_CRASH("Unhandled number specialization"); } void LIRGenerator::visitMul(MMul* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == rhs->type()); MOZ_ASSERT(IsNumberType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(lhs->type() == MIRType::Int32); ReorderCommutative(&lhs, &rhs, ins); // If our RHS is a constant -1 and we don't have to worry about results that // can't be represented as an int32, we can optimize to an LNegI. if (!ins->fallible() && rhs->isConstant() && rhs->toConstant()->toInt32() == -1) { lowerNegI(ins, lhs); return; } lowerMulI(ins, lhs, rhs); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(lhs->type() == MIRType::Int64); ReorderCommutative(&lhs, &rhs, ins); // If our RHS is a constant -1, we can optimize to an LNegI64. if (rhs->isConstant() && rhs->toConstant()->toInt64() == -1) { lowerNegI64(ins, lhs); return; } LMulI64* lir = new (alloc()) LMulI64; lowerForMulInt64(lir, ins, lhs, rhs); return; } if (ins->type() == MIRType::Double) { MOZ_ASSERT(lhs->type() == MIRType::Double); ReorderCommutative(&lhs, &rhs, ins); // If our RHS is a constant -1.0, we can optimize to an LNegD. if (!ins->mustPreserveNaN() && rhs->isConstant() && rhs->toConstant()->toDouble() == -1.0) { defineReuseInput(new (alloc()) LNegD(useRegisterAtStart(lhs)), ins, 0); return; } lowerForFPU(new (alloc()) LMathD(JSOp::Mul), ins, lhs, rhs); return; } if (ins->type() == MIRType::Float32) { MOZ_ASSERT(lhs->type() == MIRType::Float32); ReorderCommutative(&lhs, &rhs, ins); // We apply the same optimizations as for doubles if (!ins->mustPreserveNaN() && rhs->isConstant() && rhs->toConstant()->toFloat32() == -1.0f) { defineReuseInput(new (alloc()) LNegF(useRegisterAtStart(lhs)), ins, 0); return; } lowerForFPU(new (alloc()) LMathF(JSOp::Mul), ins, lhs, rhs); return; } MOZ_CRASH("Unhandled number specialization"); } void LIRGenerator::visitDiv(MDiv* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == rhs->type()); MOZ_ASSERT(IsNumberType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(lhs->type() == MIRType::Int32); lowerDivI(ins); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(lhs->type() == MIRType::Int64); lowerDivI64(ins); return; } if (ins->type() == MIRType::Double) { MOZ_ASSERT(lhs->type() == MIRType::Double); lowerForFPU(new (alloc()) LMathD(JSOp::Div), ins, lhs, rhs); return; } if (ins->type() == MIRType::Float32) { MOZ_ASSERT(lhs->type() == MIRType::Float32); lowerForFPU(new (alloc()) LMathF(JSOp::Div), ins, lhs, rhs); return; } MOZ_CRASH("Unhandled number specialization"); } void LIRGenerator::visitWasmBuiltinDivI64(MWasmBuiltinDivI64* div) { lowerWasmBuiltinDivI64(div); } void LIRGenerator::visitWasmBuiltinModI64(MWasmBuiltinModI64* mod) { lowerWasmBuiltinModI64(mod); } void LIRGenerator::visitBuiltinInt64ToFloatingPoint( MBuiltinInt64ToFloatingPoint* ins) { lowerBuiltinInt64ToFloatingPoint(ins); } void LIRGenerator::visitWasmBuiltinTruncateToInt64( MWasmBuiltinTruncateToInt64* ins) { lowerWasmBuiltinTruncateToInt64(ins); } void LIRGenerator::visitWasmBuiltinModD(MWasmBuiltinModD* ins) { MOZ_ASSERT(gen->compilingWasm()); LWasmBuiltinModD* lir = new (alloc()) LWasmBuiltinModD( useRegisterAtStart(ins->lhs()), useRegisterAtStart(ins->rhs()), useFixedAtStart(ins->instance(), InstanceReg)); defineReturn(lir, ins); } void LIRGenerator::visitMod(MMod* ins) { MOZ_ASSERT(ins->lhs()->type() == ins->rhs()->type()); MOZ_ASSERT(IsNumberType(ins->type())); if (ins->type() == MIRType::Int32) { MOZ_ASSERT(ins->type() == MIRType::Int32); MOZ_ASSERT(ins->lhs()->type() == MIRType::Int32); lowerModI(ins); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(ins->type() == MIRType::Int64); MOZ_ASSERT(ins->lhs()->type() == MIRType::Int64); lowerModI64(ins); return; } if (ins->type() == MIRType::Double) { MOZ_ASSERT(ins->lhs()->type() == MIRType::Double); MOZ_ASSERT(ins->rhs()->type() == MIRType::Double); MOZ_ASSERT(!gen->compilingWasm()); if (Assembler::HasRoundInstruction(RoundingMode::TowardsZero)) { if (ins->rhs()->isConstant()) { double d = ins->rhs()->toConstant()->toDouble(); int32_t div; if (mozilla::NumberIsInt32(d, &div) && div > 0 && mozilla::IsPowerOfTwo(uint32_t(div))) { auto* lir = new (alloc()) LModPowTwoD(useRegister(ins->lhs()), div); define(lir, ins); return; } } } LModD* lir = new (alloc()) LModD(useRegisterAtStart(ins->lhs()), useRegisterAtStart(ins->rhs())); defineReturn(lir, ins); return; } MOZ_CRASH("Unhandled number specialization"); } void LIRGenerator::visitBigIntAdd(MBigIntAdd* ins) { auto* lir = new (alloc()) LBigIntAdd(useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntSub(MBigIntSub* ins) { auto* lir = new (alloc()) LBigIntSub(useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntMul(MBigIntMul* ins) { auto* lir = new (alloc()) LBigIntMul(useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntDiv(MBigIntDiv* ins) { lowerBigIntDiv(ins); } void LIRGenerator::visitBigIntMod(MBigIntMod* ins) { lowerBigIntMod(ins); } void LIRGenerator::visitBigIntPow(MBigIntPow* ins) { auto* lir = new (alloc()) LBigIntPow(useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntBitAnd(MBigIntBitAnd* ins) { auto* lir = new (alloc()) LBigIntBitAnd( useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntBitOr(MBigIntBitOr* ins) { auto* lir = new (alloc()) LBigIntBitOr( useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntBitXor(MBigIntBitXor* ins) { auto* lir = new (alloc()) LBigIntBitXor( useRegister(ins->lhs()), useRegister(ins->rhs()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntLsh(MBigIntLsh* ins) { lowerBigIntLsh(ins); } void LIRGenerator::visitBigIntRsh(MBigIntRsh* ins) { lowerBigIntRsh(ins); } void LIRGenerator::visitBigIntIncrement(MBigIntIncrement* ins) { auto* lir = new (alloc()) LBigIntIncrement(useRegister(ins->input()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntDecrement(MBigIntDecrement* ins) { auto* lir = new (alloc()) LBigIntDecrement(useRegister(ins->input()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntNegate(MBigIntNegate* ins) { auto* lir = new (alloc()) LBigIntNegate(useRegister(ins->input()), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntBitNot(MBigIntBitNot* ins) { auto* lir = new (alloc()) LBigIntBitNot(useRegister(ins->input()), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitInt32ToStringWithBase(MInt32ToStringWithBase* ins) { MOZ_ASSERT(ins->input()->type() == MIRType::Int32); MOZ_ASSERT(ins->base()->type() == MIRType::Int32); int32_t baseInt = ins->base()->isConstant() ? ins->base()->toConstant()->toInt32() : 0; LAllocation base; if (2 <= baseInt && baseInt <= 36) { base = useRegisterOrConstant(ins->base()); } else { base = useRegister(ins->base()); } auto* lir = new (alloc()) LInt32ToStringWithBase(useRegister(ins->input()), base, temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNumberParseInt(MNumberParseInt* ins) { MOZ_ASSERT(ins->string()->type() == MIRType::String); MOZ_ASSERT(ins->radix()->type() == MIRType::Int32); auto* lir = new (alloc()) LNumberParseInt(useRegisterAtStart(ins->string()), useRegisterAtStart(ins->radix()), tempFixed(CallTempReg0)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitDoubleParseInt(MDoubleParseInt* ins) { MOZ_ASSERT(ins->number()->type() == MIRType::Double); auto* lir = new (alloc()) LDoubleParseInt(useRegister(ins->number()), tempDouble()); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitConcat(MConcat* ins) { MDefinition* lhs = ins->getOperand(0); MDefinition* rhs = ins->getOperand(1); MOZ_ASSERT(lhs->type() == MIRType::String); MOZ_ASSERT(rhs->type() == MIRType::String); MOZ_ASSERT(ins->type() == MIRType::String); LConcat* lir = new (alloc()) LConcat( useFixedAtStart(lhs, CallTempReg0), useFixedAtStart(rhs, CallTempReg1), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2), tempFixed(CallTempReg3), tempFixed(CallTempReg4)); defineFixed(lir, ins, LAllocation(AnyRegister(CallTempReg5))); assignSafepoint(lir, ins); } void LIRGenerator::visitLinearizeForCharAccess(MLinearizeForCharAccess* ins) { MDefinition* str = ins->string(); MDefinition* idx = ins->index(); MOZ_ASSERT(str->type() == MIRType::String); MOZ_ASSERT(idx->type() == MIRType::Int32); auto* lir = new (alloc()) LLinearizeForCharAccess(useRegister(str), useRegister(idx)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCharCodeAt(MCharCodeAt* ins) { MDefinition* str = ins->string(); MDefinition* idx = ins->index(); MOZ_ASSERT(str->type() == MIRType::String); MOZ_ASSERT(idx->type() == MIRType::Int32); LCharCodeAt* lir = new (alloc()) LCharCodeAt(useRegister(str), useRegister(idx), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCharCodeAtMaybeOutOfBounds( MCharCodeAtMaybeOutOfBounds* ins) { MDefinition* str = ins->string(); MDefinition* idx = ins->index(); MOZ_ASSERT(str->type() == MIRType::String); MOZ_ASSERT(idx->type() == MIRType::Int32); auto* lir = new (alloc()) LCharCodeAtMaybeOutOfBounds( useRegister(str), useRegister(idx), temp(), temp()); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCharAtMaybeOutOfBounds(MCharAtMaybeOutOfBounds* ins) { MDefinition* str = ins->string(); MDefinition* idx = ins->index(); MOZ_ASSERT(str->type() == MIRType::String); MOZ_ASSERT(idx->type() == MIRType::Int32); auto* lir = new (alloc()) LCharAtMaybeOutOfBounds( useRegister(str), useRegister(idx), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitFromCharCode(MFromCharCode* ins) { MDefinition* code = ins->getOperand(0); MOZ_ASSERT(code->type() == MIRType::Int32); LFromCharCode* lir = new (alloc()) LFromCharCode(useRegister(code)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitFromCodePoint(MFromCodePoint* ins) { MDefinition* codePoint = ins->getOperand(0); MOZ_ASSERT(codePoint->type() == MIRType::Int32); LFromCodePoint* lir = new (alloc()) LFromCodePoint(useRegister(codePoint), temp(), temp()); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringIndexOf(MStringIndexOf* ins) { auto* string = ins->string(); MOZ_ASSERT(string->type() == MIRType::String); auto* searchStr = ins->searchString(); MOZ_ASSERT(searchStr->type() == MIRType::String); auto* lir = new (alloc()) LStringIndexOf(useRegisterAtStart(string), useRegisterAtStart(searchStr)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringStartsWith(MStringStartsWith* ins) { auto* string = ins->string(); MOZ_ASSERT(string->type() == MIRType::String); auto* searchStr = ins->searchString(); MOZ_ASSERT(searchStr->type() == MIRType::String); if (searchStr->isConstant()) { JSLinearString* linear = &searchStr->toConstant()->toString()->asLinear(); if (CanCompareCharactersInline(linear)) { auto* lir = new (alloc()) LStringStartsWithInline(useRegister(string), temp(), linear); define(lir, ins); assignSafepoint(lir, ins); return; } } auto* lir = new (alloc()) LStringStartsWith(useRegisterAtStart(string), useRegisterAtStart(searchStr)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringEndsWith(MStringEndsWith* ins) { auto* string = ins->string(); MOZ_ASSERT(string->type() == MIRType::String); auto* searchStr = ins->searchString(); MOZ_ASSERT(searchStr->type() == MIRType::String); if (searchStr->isConstant()) { JSLinearString* linear = &searchStr->toConstant()->toString()->asLinear(); if (CanCompareCharactersInline(linear)) { auto* lir = new (alloc()) LStringEndsWithInline(useRegister(string), temp(), linear); define(lir, ins); assignSafepoint(lir, ins); return; } } auto* lir = new (alloc()) LStringEndsWith(useRegisterAtStart(string), useRegisterAtStart(searchStr)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringConvertCase(MStringConvertCase* ins) { MOZ_ASSERT(ins->string()->type() == MIRType::String); if (ins->mode() == MStringConvertCase::LowerCase) { #ifdef JS_CODEGEN_X86 // Due to lack of registers on x86, we reuse the string register as // temporary. As a result we only need four temporary registers and take a // bogus temporary as the fifth argument. LDefinition temp4 = LDefinition::BogusTemp(); #else LDefinition temp4 = temp(); #endif auto* lir = new (alloc()) LStringToLowerCase(useRegister(ins->string()), temp(), temp(), temp(), temp4, tempByteOpRegister()); define(lir, ins); assignSafepoint(lir, ins); } else { auto* lir = new (alloc()) LStringToUpperCase(useRegisterAtStart(ins->string())); defineReturn(lir, ins); assignSafepoint(lir, ins); } } void LIRGenerator::visitStart(MStart* start) {} void LIRGenerator::visitNop(MNop* nop) {} void LIRGenerator::visitLimitedTruncate(MLimitedTruncate* nop) { redefine(nop, nop->input()); } void LIRGenerator::visitOsrEntry(MOsrEntry* entry) { LOsrEntry* lir = new (alloc()) LOsrEntry(temp()); defineFixed(lir, entry, LAllocation(AnyRegister(OsrFrameReg))); } void LIRGenerator::visitOsrValue(MOsrValue* value) { LOsrValue* lir = new (alloc()) LOsrValue(useRegister(value->entry())); defineBox(lir, value); } void LIRGenerator::visitOsrReturnValue(MOsrReturnValue* value) { LOsrReturnValue* lir = new (alloc()) LOsrReturnValue(useRegister(value->entry())); defineBox(lir, value); } void LIRGenerator::visitOsrEnvironmentChain(MOsrEnvironmentChain* object) { LOsrEnvironmentChain* lir = new (alloc()) LOsrEnvironmentChain(useRegister(object->entry())); define(lir, object); } void LIRGenerator::visitOsrArgumentsObject(MOsrArgumentsObject* object) { LOsrArgumentsObject* lir = new (alloc()) LOsrArgumentsObject(useRegister(object->entry())); define(lir, object); } void LIRGenerator::visitToDouble(MToDouble* convert) { MDefinition* opd = convert->input(); mozilla::DebugOnly conversion = convert->conversion(); switch (opd->type()) { case MIRType::Value: { LValueToDouble* lir = new (alloc()) LValueToDouble(useBox(opd)); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); break; } case MIRType::Null: MOZ_ASSERT(conversion == MToFPInstruction::NonStringPrimitives); lowerConstantDouble(0, convert); break; case MIRType::Undefined: MOZ_ASSERT(conversion == MToFPInstruction::NonStringPrimitives); lowerConstantDouble(GenericNaN(), convert); break; case MIRType::Boolean: MOZ_ASSERT(conversion == MToFPInstruction::NonStringPrimitives); [[fallthrough]]; case MIRType::Int32: { LInt32ToDouble* lir = new (alloc()) LInt32ToDouble(useRegisterAtStart(opd)); define(lir, convert); break; } case MIRType::Float32: { LFloat32ToDouble* lir = new (alloc()) LFloat32ToDouble(useRegisterAtStart(opd)); define(lir, convert); break; } case MIRType::Double: redefine(convert, opd); break; default: // Objects might be effectful. Symbols will throw. // Strings are complicated - we don't handle them yet. MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitToFloat32(MToFloat32* convert) { MDefinition* opd = convert->input(); mozilla::DebugOnly conversion = convert->conversion(); switch (opd->type()) { case MIRType::Value: { LValueToFloat32* lir = new (alloc()) LValueToFloat32(useBox(opd)); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); break; } case MIRType::Null: MOZ_ASSERT(conversion == MToFPInstruction::NonStringPrimitives); lowerConstantFloat32(0, convert); break; case MIRType::Undefined: MOZ_ASSERT(conversion == MToFPInstruction::NonStringPrimitives); lowerConstantFloat32(GenericNaN(), convert); break; case MIRType::Boolean: MOZ_ASSERT(conversion == MToFPInstruction::NonStringPrimitives); [[fallthrough]]; case MIRType::Int32: { LInt32ToFloat32* lir = new (alloc()) LInt32ToFloat32(useRegisterAtStart(opd)); define(lir, convert); break; } case MIRType::Double: { LDoubleToFloat32* lir = new (alloc()) LDoubleToFloat32(useRegisterAtStart(opd)); define(lir, convert); break; } case MIRType::Float32: redefine(convert, opd); break; default: // Objects might be effectful. Symbols will throw. // Strings are complicated - we don't handle them yet. MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitToNumberInt32(MToNumberInt32* convert) { MDefinition* opd = convert->input(); switch (opd->type()) { case MIRType::Value: { auto* lir = new (alloc()) LValueToInt32(useBox(opd), tempDouble(), temp(), LValueToInt32::NORMAL); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); if (lir->mode() == LValueToInt32::TRUNCATE || lir->mode() == LValueToInt32::TRUNCATE_NOWRAP) { assignSafepoint(lir, convert); } break; } case MIRType::Null: MOZ_ASSERT(convert->conversion() == IntConversionInputKind::Any); define(new (alloc()) LInteger(0), convert); break; case MIRType::Boolean: MOZ_ASSERT(convert->conversion() == IntConversionInputKind::Any || convert->conversion() == IntConversionInputKind::NumbersOrBoolsOnly); redefine(convert, opd); break; case MIRType::Int32: redefine(convert, opd); break; case MIRType::Float32: { LFloat32ToInt32* lir = new (alloc()) LFloat32ToInt32(useRegister(opd)); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); break; } case MIRType::Double: { LDoubleToInt32* lir = new (alloc()) LDoubleToInt32(useRegister(opd)); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); break; } case MIRType::String: case MIRType::Symbol: case MIRType::BigInt: case MIRType::Object: case MIRType::Undefined: // Objects might be effectful. Symbols and BigInts throw. Undefined // coerces to NaN, not int32. MOZ_CRASH("ToInt32 invalid input type"); default: MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitToIntegerInt32(MToIntegerInt32* convert) { MDefinition* opd = convert->input(); switch (opd->type()) { case MIRType::Value: { auto* lir = new (alloc()) LValueToInt32(useBox(opd), tempDouble(), temp(), LValueToInt32::TRUNCATE_NOWRAP); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); assignSafepoint(lir, convert); break; } case MIRType::Undefined: case MIRType::Null: define(new (alloc()) LInteger(0), convert); break; case MIRType::Boolean: case MIRType::Int32: redefine(convert, opd); break; case MIRType::Float32: { auto* lir = new (alloc()) LFloat32ToIntegerInt32(useRegister(opd)); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); break; } case MIRType::Double: { auto* lir = new (alloc()) LDoubleToIntegerInt32(useRegister(opd)); assignSnapshot(lir, convert->bailoutKind()); define(lir, convert); break; } case MIRType::String: case MIRType::Symbol: case MIRType::BigInt: case MIRType::Object: // Objects might be effectful. Symbols and BigInts throw. // Strings are complicated - we don't handle them yet. MOZ_CRASH("ToIntegerInt32 invalid input type"); default: MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitTruncateToInt32(MTruncateToInt32* truncate) { MDefinition* opd = truncate->input(); switch (opd->type()) { case MIRType::Value: { LValueToInt32* lir = new (alloc()) LValueToInt32( useBox(opd), tempDouble(), temp(), LValueToInt32::TRUNCATE); assignSnapshot(lir, truncate->bailoutKind()); define(lir, truncate); assignSafepoint(lir, truncate); break; } case MIRType::Null: case MIRType::Undefined: define(new (alloc()) LInteger(0), truncate); break; case MIRType::Int32: case MIRType::Boolean: redefine(truncate, opd); break; case MIRType::Double: // May call into JS::ToInt32() on the slow OOL path. gen->setNeedsStaticStackAlignment(); lowerTruncateDToInt32(truncate); break; case MIRType::Float32: // May call into JS::ToInt32() on the slow OOL path. gen->setNeedsStaticStackAlignment(); lowerTruncateFToInt32(truncate); break; default: // Objects might be effectful. Symbols throw. // Strings are complicated - we don't handle them yet. MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitInt32ToIntPtr(MInt32ToIntPtr* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Int32); MOZ_ASSERT(ins->type() == MIRType::IntPtr); #ifdef JS_64BIT // If the result is only used by instructions that expect a bounds-checked // index, we must have eliminated or hoisted a bounds check and we can assume // the index is non-negative. This lets us generate more efficient code. // In debug builds we verify this non-negative assumption at runtime. if (ins->canBeNegative()) { bool canBeNegative = false; for (MUseDefIterator iter(ins); iter; iter++) { if (!iter.def()->isSpectreMaskIndex() && !iter.def()->isLoadUnboxedScalar() && !iter.def()->isStoreUnboxedScalar() && !iter.def()->isLoadDataViewElement() && !iter.def()->isStoreDataViewElement()) { canBeNegative = true; break; } } if (!canBeNegative) { ins->setCanNotBeNegative(); } } if (ins->canBeNegative()) { auto* lir = new (alloc()) LInt32ToIntPtr(useAnyAtStart(input)); define(lir, ins); } else { # ifdef DEBUG auto* lir = new (alloc()) LInt32ToIntPtr(useRegisterAtStart(input)); defineReuseInput(lir, ins, 0); # else // In non-debug mode this is a no-op. redefine(ins, input); # endif } #else // On 32-bit platforms this is a no-op. redefine(ins, input); #endif } void LIRGenerator::visitNonNegativeIntPtrToInt32( MNonNegativeIntPtrToInt32* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::IntPtr); MOZ_ASSERT(ins->type() == MIRType::Int32); #ifdef JS_64BIT auto* lir = new (alloc()) LNonNegativeIntPtrToInt32(useRegisterAtStart(input)); assignSnapshot(lir, ins->bailoutKind()); defineReuseInput(lir, ins, 0); #else // On 32-bit platforms this is a no-op. redefine(ins, input); #endif } void LIRGenerator::visitWasmExtendU32Index(MWasmExtendU32Index* ins) { #ifdef JS_64BIT // Technically this produces an Int64 register and I guess we could clean that // up, but it's a 64-bit only operation, so it doesn't actually matter. MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Int32); MOZ_ASSERT(ins->type() == MIRType::Int64); // Input reuse is OK even on ARM64 because this node *must* reuse its input in // order not to generate any code at all, as is the intent. auto* lir = new (alloc()) LWasmExtendU32Index(useRegisterAtStart(input)); defineReuseInput(lir, ins, 0); #else MOZ_CRASH("64-bit only"); #endif } void LIRGenerator::visitWasmWrapU32Index(MWasmWrapU32Index* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Int64); MOZ_ASSERT(ins->type() == MIRType::Int32); // Tricky: On 64-bit, this just returns its input (except on MIPS64 there may // be a sign/zero extension). On 32-bit, it returns the low register of the // input, and should generate no code. // If this assertion does not hold then using "input" unadorned as an alias // for the low register will not work. #if defined(JS_NUNBOX32) static_assert(INT64LOW_INDEX == 0); #endif auto* lir = new (alloc()) LWasmWrapU32Index(useRegisterAtStart(input)); defineReuseInput(lir, ins, 0); } void LIRGenerator::visitIntPtrToDouble(MIntPtrToDouble* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::IntPtr); MOZ_ASSERT(ins->type() == MIRType::Double); auto* lir = new (alloc()) LIntPtrToDouble(useRegister(input)); define(lir, ins); } void LIRGenerator::visitAdjustDataViewLength(MAdjustDataViewLength* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::IntPtr); auto* lir = new (alloc()) LAdjustDataViewLength(useRegisterAtStart(input)); assignSnapshot(lir, ins->bailoutKind()); defineReuseInput(lir, ins, 0); } void LIRGenerator::visitToBigInt(MToBigInt* ins) { MDefinition* opd = ins->input(); switch (opd->type()) { case MIRType::Value: { auto* lir = new (alloc()) LValueToBigInt(useBox(opd)); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::BigInt: redefine(ins, opd); break; default: MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitToInt64(MToInt64* ins) { MDefinition* opd = ins->input(); switch (opd->type()) { case MIRType::Value: { auto* lir = new (alloc()) LValueToInt64(useBox(opd), temp()); assignSnapshot(lir, ins->bailoutKind()); defineInt64(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::Boolean: { auto* lir = new (alloc()) LBooleanToInt64(useRegisterAtStart(opd)); defineInt64(lir, ins); break; } case MIRType::String: { auto* lir = new (alloc()) LStringToInt64(useRegister(opd)); defineInt64(lir, ins); assignSafepoint(lir, ins); break; } // An Int64 may be passed here from a BigInt to Int64 conversion. case MIRType::Int64: { redefine(ins, opd); break; } default: // Undefined, Null, Number, and Symbol throw. // Objects may be effectful. // BigInt operands are eliminated by the type policy. MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitTruncateBigIntToInt64(MTruncateBigIntToInt64* ins) { MOZ_ASSERT(ins->input()->type() == MIRType::BigInt); auto* lir = new (alloc()) LTruncateBigIntToInt64(useRegister(ins->input())); defineInt64(lir, ins); } void LIRGenerator::visitInt64ToBigInt(MInt64ToBigInt* ins) { MOZ_ASSERT(ins->input()->type() == MIRType::Int64); auto* lir = new (alloc()) LInt64ToBigInt(useInt64Register(ins->input()), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitWasmTruncateToInt32(MWasmTruncateToInt32* ins) { MDefinition* input = ins->input(); switch (input->type()) { case MIRType::Double: case MIRType::Float32: { auto* lir = new (alloc()) LWasmTruncateToInt32(useRegisterAtStart(input)); define(lir, ins); break; } default: MOZ_CRASH("unexpected type in WasmTruncateToInt32"); } } void LIRGenerator::visitWasmBuiltinTruncateToInt32( MWasmBuiltinTruncateToInt32* truncate) { mozilla::DebugOnly opd = truncate->input(); MOZ_ASSERT(opd->type() == MIRType::Double || opd->type() == MIRType::Float32); // May call into JS::ToInt32() on the slow OOL path. gen->setNeedsStaticStackAlignment(); lowerWasmBuiltinTruncateToInt32(truncate); } void LIRGenerator::visitWasmBoxValue(MWasmBoxValue* ins) { LWasmBoxValue* lir = new (alloc()) LWasmBoxValue(useBox(ins->input())); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitWasmAnyRefFromJSObject(MWasmAnyRefFromJSObject* ins) { LWasmAnyRefFromJSObject* lir = new (alloc()) LWasmAnyRefFromJSObject(useRegisterAtStart(ins->input())); define(lir, ins); } void LIRGenerator::visitWrapInt64ToInt32(MWrapInt64ToInt32* ins) { define(new (alloc()) LWrapInt64ToInt32(useInt64AtStart(ins->input())), ins); } void LIRGenerator::visitToString(MToString* ins) { MDefinition* opd = ins->input(); switch (opd->type()) { case MIRType::Null: { const JSAtomState& names = gen->runtime->names(); LPointer* lir = new (alloc()) LPointer(names.null); define(lir, ins); break; } case MIRType::Undefined: { const JSAtomState& names = gen->runtime->names(); LPointer* lir = new (alloc()) LPointer(names.undefined); define(lir, ins); break; } case MIRType::Boolean: { LBooleanToString* lir = new (alloc()) LBooleanToString(useRegister(opd)); define(lir, ins); break; } case MIRType::Double: { LDoubleToString* lir = new (alloc()) LDoubleToString(useRegister(opd), temp()); define(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::Int32: { LIntToString* lir = new (alloc()) LIntToString(useRegister(opd)); define(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::String: redefine(ins, ins->input()); break; case MIRType::Value: { LValueToString* lir = new (alloc()) LValueToString(useBox(opd), tempToUnbox()); if (ins->needsSnapshot()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); assignSafepoint(lir, ins); break; } default: // Float32, symbols, bigint, and objects are not supported. MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitRegExp(MRegExp* ins) { LRegExp* lir = new (alloc()) LRegExp(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitRegExpMatcher(MRegExpMatcher* ins) { MOZ_ASSERT(ins->regexp()->type() == MIRType::Object); MOZ_ASSERT(ins->string()->type() == MIRType::String); MOZ_ASSERT(ins->lastIndex()->type() == MIRType::Int32); LRegExpMatcher* lir = new (alloc()) LRegExpMatcher( useFixedAtStart(ins->regexp(), RegExpMatcherRegExpReg), useFixedAtStart(ins->string(), RegExpMatcherStringReg), useFixedAtStart(ins->lastIndex(), RegExpMatcherLastIndexReg)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitRegExpSearcher(MRegExpSearcher* ins) { MOZ_ASSERT(ins->regexp()->type() == MIRType::Object); MOZ_ASSERT(ins->string()->type() == MIRType::String); MOZ_ASSERT(ins->lastIndex()->type() == MIRType::Int32); LRegExpSearcher* lir = new (alloc()) LRegExpSearcher( useFixedAtStart(ins->regexp(), RegExpTesterRegExpReg), useFixedAtStart(ins->string(), RegExpTesterStringReg), useFixedAtStart(ins->lastIndex(), RegExpTesterLastIndexReg)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitRegExpTester(MRegExpTester* ins) { MOZ_ASSERT(ins->regexp()->type() == MIRType::Object); MOZ_ASSERT(ins->string()->type() == MIRType::String); MOZ_ASSERT(ins->lastIndex()->type() == MIRType::Int32); LRegExpTester* lir = new (alloc()) LRegExpTester( useFixedAtStart(ins->regexp(), RegExpTesterRegExpReg), useFixedAtStart(ins->string(), RegExpTesterStringReg), useFixedAtStart(ins->lastIndex(), RegExpTesterLastIndexReg)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitRegExpPrototypeOptimizable( MRegExpPrototypeOptimizable* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); LRegExpPrototypeOptimizable* lir = new (alloc()) LRegExpPrototypeOptimizable(useRegister(ins->object()), temp()); define(lir, ins); } void LIRGenerator::visitRegExpInstanceOptimizable( MRegExpInstanceOptimizable* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->proto()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); LRegExpInstanceOptimizable* lir = new (alloc()) LRegExpInstanceOptimizable( useRegister(ins->object()), useRegister(ins->proto()), temp()); define(lir, ins); } void LIRGenerator::visitGetFirstDollarIndex(MGetFirstDollarIndex* ins) { MOZ_ASSERT(ins->str()->type() == MIRType::String); MOZ_ASSERT(ins->type() == MIRType::Int32); LGetFirstDollarIndex* lir = new (alloc()) LGetFirstDollarIndex(useRegister(ins->str()), temp(), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringReplace(MStringReplace* ins) { MOZ_ASSERT(ins->pattern()->type() == MIRType::String); MOZ_ASSERT(ins->string()->type() == MIRType::String); MOZ_ASSERT(ins->replacement()->type() == MIRType::String); LStringReplace* lir = new (alloc()) LStringReplace(useRegisterOrConstantAtStart(ins->string()), useRegisterAtStart(ins->pattern()), useRegisterOrConstantAtStart(ins->replacement())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBinaryCache(MBinaryCache* ins) { MDefinition* lhs = ins->getOperand(0); MDefinition* rhs = ins->getOperand(1); MOZ_ASSERT(ins->type() == MIRType::Value || ins->type() == MIRType::Boolean); LInstruction* lir; if (ins->type() == MIRType::Value) { LBinaryValueCache* valueLir = new (alloc()) LBinaryValueCache( useBox(lhs), useBox(rhs), tempFixed(FloatReg0), tempFixed(FloatReg1)); defineBox(valueLir, ins); lir = valueLir; } else { MOZ_ASSERT(ins->type() == MIRType::Boolean); LBinaryBoolCache* boolLir = new (alloc()) LBinaryBoolCache( useBox(lhs), useBox(rhs), tempFixed(FloatReg0), tempFixed(FloatReg1)); define(boolLir, ins); lir = boolLir; } assignSafepoint(lir, ins); } void LIRGenerator::visitUnaryCache(MUnaryCache* ins) { MDefinition* input = ins->getOperand(0); MOZ_ASSERT(ins->type() == MIRType::Value); LUnaryCache* lir = new (alloc()) LUnaryCache(useBox(input)); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitModuleMetadata(MModuleMetadata* ins) { LModuleMetadata* lir = new (alloc()) LModuleMetadata(); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitDynamicImport(MDynamicImport* ins) { LDynamicImport* lir = new (alloc()) LDynamicImport( useBoxAtStart(ins->specifier()), useBoxAtStart(ins->options())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitLambda(MLambda* ins) { MOZ_ASSERT(ins->environmentChain()->type() == MIRType::Object); auto* lir = new (alloc()) LLambda(useRegister(ins->environmentChain()), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitFunctionWithProto(MFunctionWithProto* ins) { MOZ_ASSERT(ins->environmentChain()->type() == MIRType::Object); MOZ_ASSERT(ins->prototype()->type() == MIRType::Object); auto* lir = new (alloc()) LFunctionWithProto(useRegisterAtStart(ins->environmentChain()), useRegisterAtStart(ins->prototype())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitSetFunName(MSetFunName* ins) { MOZ_ASSERT(ins->fun()->type() == MIRType::Object); MOZ_ASSERT(ins->name()->type() == MIRType::Value); LSetFunName* lir = new (alloc()) LSetFunName(useRegisterAtStart(ins->fun()), useBoxAtStart(ins->name())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewLexicalEnvironmentObject( MNewLexicalEnvironmentObject* ins) { auto* lir = new (alloc()) LNewLexicalEnvironmentObject(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewClassBodyEnvironmentObject( MNewClassBodyEnvironmentObject* ins) { auto* lir = new (alloc()) LNewClassBodyEnvironmentObject(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewVarEnvironmentObject(MNewVarEnvironmentObject* ins) { auto* lir = new (alloc()) LNewVarEnvironmentObject(temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitKeepAliveObject(MKeepAliveObject* ins) { MDefinition* obj = ins->object(); MOZ_ASSERT(obj->type() == MIRType::Object); add(new (alloc()) LKeepAliveObject(useKeepalive(obj)), ins); } void LIRGenerator::visitSlots(MSlots* ins) { define(new (alloc()) LSlots(useRegisterAtStart(ins->object())), ins); } void LIRGenerator::visitElements(MElements* ins) { define(new (alloc()) LElements(useRegisterAtStart(ins->object())), ins); } void LIRGenerator::visitLoadDynamicSlot(MLoadDynamicSlot* ins) { MOZ_ASSERT(ins->type() == MIRType::Value); defineBox(new (alloc()) LLoadDynamicSlotV(useRegisterAtStart(ins->slots())), ins); } void LIRGenerator::visitFunctionEnvironment(MFunctionEnvironment* ins) { define(new (alloc()) LFunctionEnvironment(useRegisterAtStart(ins->function())), ins); } void LIRGenerator::visitHomeObject(MHomeObject* ins) { define(new (alloc()) LHomeObject(useRegisterAtStart(ins->function())), ins); } void LIRGenerator::visitHomeObjectSuperBase(MHomeObjectSuperBase* ins) { MOZ_ASSERT(ins->homeObject()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Value); auto lir = new (alloc()) LHomeObjectSuperBase(useRegisterAtStart(ins->homeObject())); defineBox(lir, ins); } void LIRGenerator::visitInterruptCheck(MInterruptCheck* ins) { LInstruction* lir = new (alloc()) LInterruptCheck(); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitWasmInterruptCheck(MWasmInterruptCheck* ins) { auto* lir = new (alloc()) LWasmInterruptCheck(useRegisterAtStart(ins->instance())); add(lir, ins); assignWasmSafepoint(lir); } void LIRGenerator::visitWasmTrap(MWasmTrap* ins) { add(new (alloc()) LWasmTrap, ins); } void LIRGenerator::visitWasmReinterpret(MWasmReinterpret* ins) { if (ins->type() == MIRType::Int64) { defineInt64(new (alloc()) LWasmReinterpretToI64(useRegisterAtStart(ins->input())), ins); } else if (ins->input()->type() == MIRType::Int64) { define(new (alloc()) LWasmReinterpretFromI64(useInt64RegisterAtStart(ins->input())), ins); } else { define(new (alloc()) LWasmReinterpret(useRegisterAtStart(ins->input())), ins); } } void LIRGenerator::visitStoreDynamicSlot(MStoreDynamicSlot* ins) { LInstruction* lir; switch (ins->value()->type()) { case MIRType::Value: lir = new (alloc()) LStoreDynamicSlotV(useRegister(ins->slots()), useBox(ins->value())); add(lir, ins); break; case MIRType::Double: add(new (alloc()) LStoreDynamicSlotT(useRegister(ins->slots()), useRegister(ins->value())), ins); break; case MIRType::Float32: MOZ_CRASH("Float32 shouldn't be stored in a slot."); default: add(new (alloc()) LStoreDynamicSlotT(useRegister(ins->slots()), useRegisterOrConstant(ins->value())), ins); break; } } // Returns true iff |def| is a constant that's either not a GC thing or is not // allocated in the nursery. static bool IsNonNurseryConstant(MDefinition* def) { if (!def->isConstant()) { return false; } Value v = def->toConstant()->toJSValue(); return !v.isGCThing() || !IsInsideNursery(v.toGCThing()); } void LIRGenerator::visitPostWriteBarrier(MPostWriteBarrier* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); // LPostWriteBarrier assumes that if it has a constant object then that // object is tenured, and does not need to be tested for being in the // nursery. Ensure that assumption holds by lowering constant nursery // objects to a register. bool useConstantObject = IsNonNurseryConstant(ins->object()); switch (ins->value()->type()) { case MIRType::Object: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); LPostWriteBarrierO* lir = new (alloc()) LPostWriteBarrierO(useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->value()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::String: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); LPostWriteBarrierS* lir = new (alloc()) LPostWriteBarrierS(useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->value()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::BigInt: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); auto* lir = new (alloc()) LPostWriteBarrierBI(useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->value()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::Value: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); LPostWriteBarrierV* lir = new (alloc()) LPostWriteBarrierV(useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useBox(ins->value()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } default: // Currently, only objects and strings can be in the nursery. Other // instruction types cannot hold nursery pointers. break; } } void LIRGenerator::visitPostWriteElementBarrier(MPostWriteElementBarrier* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); // LPostWriteElementBarrier assumes that if it has a constant object then that // object is tenured, and does not need to be tested for being in the // nursery. Ensure that assumption holds by lowering constant nursery // objects to a register. bool useConstantObject = ins->object()->isConstant() && !IsInsideNursery(&ins->object()->toConstant()->toObject()); switch (ins->value()->type()) { case MIRType::Object: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); LPostWriteElementBarrierO* lir = new (alloc()) LPostWriteElementBarrierO( useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->value()), useRegister(ins->index()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::String: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); LPostWriteElementBarrierS* lir = new (alloc()) LPostWriteElementBarrierS( useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->value()), useRegister(ins->index()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::BigInt: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); auto* lir = new (alloc()) LPostWriteElementBarrierBI( useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->value()), useRegister(ins->index()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } case MIRType::Value: { LDefinition tmp = needTempForPostBarrier() ? temp() : LDefinition::BogusTemp(); LPostWriteElementBarrierV* lir = new (alloc()) LPostWriteElementBarrierV( useConstantObject ? useOrConstant(ins->object()) : useRegister(ins->object()), useRegister(ins->index()), useBox(ins->value()), tmp); add(lir, ins); assignSafepoint(lir, ins); break; } default: // Currently, only objects, strings, and bigints can be in the nursery. // Other instruction types cannot hold nursery pointers. break; } } void LIRGenerator::visitAssertCanElidePostWriteBarrier( MAssertCanElidePostWriteBarrier* ins) { auto* lir = new (alloc()) LAssertCanElidePostWriteBarrier( useRegister(ins->object()), useBox(ins->value()), temp()); add(lir, ins); } void LIRGenerator::visitArrayLength(MArrayLength* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); auto* lir = new (alloc()) LArrayLength(useRegisterAtStart(ins->elements())); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitSetArrayLength(MSetArrayLength* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); MOZ_ASSERT(ins->index()->isConstant()); add(new (alloc()) LSetArrayLength(useRegister(ins->elements()), useRegisterOrConstant(ins->index())), ins); } void LIRGenerator::visitFunctionLength(MFunctionLength* ins) { MOZ_ASSERT(ins->function()->type() == MIRType::Object); auto* lir = new (alloc()) LFunctionLength(useRegister(ins->function())); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitFunctionName(MFunctionName* ins) { MOZ_ASSERT(ins->function()->type() == MIRType::Object); auto* lir = new (alloc()) LFunctionName(useRegister(ins->function())); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); } void LIRGenerator::visitGetNextEntryForIterator(MGetNextEntryForIterator* ins) { MOZ_ASSERT(ins->iter()->type() == MIRType::Object); MOZ_ASSERT(ins->result()->type() == MIRType::Object); auto lir = new (alloc()) LGetNextEntryForIterator(useRegister(ins->iter()), useRegister(ins->result()), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitArrayBufferByteLength(MArrayBufferByteLength* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::IntPtr); auto* lir = new (alloc()) LArrayBufferByteLength(useRegisterAtStart(ins->object())); define(lir, ins); } void LIRGenerator::visitArrayBufferViewLength(MArrayBufferViewLength* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::IntPtr); auto* lir = new (alloc()) LArrayBufferViewLength(useRegisterAtStart(ins->object())); define(lir, ins); } void LIRGenerator::visitArrayBufferViewByteOffset( MArrayBufferViewByteOffset* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::IntPtr); auto* lir = new (alloc()) LArrayBufferViewByteOffset(useRegisterAtStart(ins->object())); define(lir, ins); } void LIRGenerator::visitArrayBufferViewElements(MArrayBufferViewElements* ins) { MOZ_ASSERT(ins->type() == MIRType::Elements); define(new (alloc()) LArrayBufferViewElements(useRegisterAtStart(ins->object())), ins); } void LIRGenerator::visitTypedArrayElementSize(MTypedArrayElementSize* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); define(new (alloc()) LTypedArrayElementSize(useRegisterAtStart(ins->object())), ins); } void LIRGenerator::visitGuardHasAttachedArrayBuffer( MGuardHasAttachedArrayBuffer* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardHasAttachedArrayBuffer(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardNumberToIntPtrIndex( MGuardNumberToIntPtrIndex* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Double); auto* lir = new (alloc()) LGuardNumberToIntPtrIndex(useRegister(input)); if (!ins->supportOOB()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); } void LIRGenerator::visitInitializedLength(MInitializedLength* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); define(new (alloc()) LInitializedLength(useRegisterAtStart(ins->elements())), ins); } void LIRGenerator::visitSetInitializedLength(MSetInitializedLength* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); MOZ_ASSERT(ins->index()->isConstant()); add(new (alloc()) LSetInitializedLength(useRegister(ins->elements()), useRegisterOrConstant(ins->index())), ins); } void LIRGenerator::visitNot(MNot* ins) { MDefinition* op = ins->input(); // String is converted to length of string in the type analysis phase (see // TestPolicy). MOZ_ASSERT(op->type() != MIRType::String); // - boolean: x xor 1 // - int32: LCompare(x, 0) // - double: LCompare(x, 0) // - null or undefined: true // - symbol: false // - bigint: LNotBI(x) // - object: false if it never emulates undefined, else LNotO(x) switch (op->type()) { case MIRType::Boolean: { MConstant* cons = MConstant::New(alloc(), Int32Value(1)); ins->block()->insertBefore(ins, cons); lowerForALU(new (alloc()) LBitOpI(JSOp::BitXor), ins, op, cons); break; } case MIRType::Int32: define(new (alloc()) LNotI(useRegisterAtStart(op)), ins); break; case MIRType::Int64: define(new (alloc()) LNotI64(useInt64RegisterAtStart(op)), ins); break; case MIRType::Double: define(new (alloc()) LNotD(useRegister(op)), ins); break; case MIRType::Float32: define(new (alloc()) LNotF(useRegister(op)), ins); break; case MIRType::Undefined: case MIRType::Null: define(new (alloc()) LInteger(1), ins); break; case MIRType::Symbol: define(new (alloc()) LInteger(0), ins); break; case MIRType::BigInt: define(new (alloc()) LNotBI(useRegisterAtStart(op)), ins); break; case MIRType::Object: define(new (alloc()) LNotO(useRegister(op)), ins); break; case MIRType::Value: { auto* lir = new (alloc()) LNotV(useBox(op), tempDouble(), tempToUnbox()); define(lir, ins); break; } default: MOZ_CRASH("Unexpected MIRType."); } } void LIRGenerator::visitBoundsCheck(MBoundsCheck* ins) { MOZ_ASSERT(ins->type() == MIRType::Int32 || ins->type() == MIRType::IntPtr); MOZ_ASSERT(ins->index()->type() == ins->type()); MOZ_ASSERT(ins->length()->type() == ins->type()); if (!ins->fallible()) { return; } LInstruction* check; if (ins->minimum() || ins->maximum()) { check = new (alloc()) LBoundsCheckRange(useRegisterOrInt32Constant(ins->index()), useAny(ins->length()), temp()); } else { check = new (alloc()) LBoundsCheck(useRegisterOrInt32Constant(ins->index()), useAnyOrInt32Constant(ins->length())); } assignSnapshot(check, ins->bailoutKind()); add(check, ins); } void LIRGenerator::visitSpectreMaskIndex(MSpectreMaskIndex* ins) { MOZ_ASSERT(ins->type() == MIRType::Int32 || ins->type() == MIRType::IntPtr); MOZ_ASSERT(ins->index()->type() == ins->type()); MOZ_ASSERT(ins->length()->type() == ins->type()); auto* lir = new (alloc()) LSpectreMaskIndex(useRegister(ins->index()), useAny(ins->length())); define(lir, ins); } void LIRGenerator::visitBoundsCheckLower(MBoundsCheckLower* ins) { MOZ_ASSERT(ins->index()->type() == MIRType::Int32); if (!ins->fallible()) { return; } LInstruction* check = new (alloc()) LBoundsCheckLower(useRegister(ins->index())); assignSnapshot(check, ins->bailoutKind()); add(check, ins); } void LIRGenerator::visitInArray(MInArray* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); MOZ_ASSERT(ins->initLength()->type() == MIRType::Int32); MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); auto* lir = new (alloc()) LInArray(useRegister(ins->elements()), useRegisterOrConstant(ins->index()), useRegister(ins->initLength())); if (ins->needsNegativeIntCheck()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); } void LIRGenerator::visitGuardElementNotHole(MGuardElementNotHole* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); auto* guard = new (alloc()) LGuardElementNotHole(useRegisterAtStart(ins->elements()), useRegisterOrConstantAtStart(ins->index())); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); } void LIRGenerator::visitLoadElement(MLoadElement* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); MOZ_ASSERT(ins->type() == MIRType::Value); auto* lir = new (alloc()) LLoadElementV(useRegister(ins->elements()), useRegisterOrConstant(ins->index())); assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); } void LIRGenerator::visitLoadElementHole(MLoadElementHole* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); MOZ_ASSERT(ins->initLength()->type() == MIRType::Int32); MOZ_ASSERT(ins->type() == MIRType::Value); LLoadElementHole* lir = new (alloc()) LLoadElementHole(useRegister(ins->elements()), useRegister(ins->index()), useRegister(ins->initLength())); if (ins->needsNegativeIntCheck()) { assignSnapshot(lir, ins->bailoutKind()); } defineBox(lir, ins); } void LIRGenerator::visitStoreElement(MStoreElement* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); const LUse elements = useRegister(ins->elements()); const LAllocation index = useRegisterOrConstant(ins->index()); switch (ins->value()->type()) { case MIRType::Value: { LInstruction* lir = new (alloc()) LStoreElementV(elements, index, useBox(ins->value())); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } add(lir, ins); break; } default: { const LAllocation value = useRegisterOrNonDoubleConstant(ins->value()); LInstruction* lir = new (alloc()) LStoreElementT(elements, index, value); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } add(lir, ins); break; } } } void LIRGenerator::visitStoreHoleValueElement(MStoreHoleValueElement* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); auto* lir = new (alloc()) LStoreHoleValueElement(useRegister(ins->elements()), useRegister(ins->index())); add(lir, ins); } static bool BoundsCheckNeedsSpectreTemp() { // On x86, spectreBoundsCheck32 can emit better code if it has a scratch // register and index masking is enabled. #ifdef JS_CODEGEN_X86 return JitOptions.spectreIndexMasking; #else return false; #endif } void LIRGenerator::visitStoreElementHole(MStoreElementHole* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::Int32); const LUse object = useRegister(ins->object()); const LUse elements = useRegister(ins->elements()); const LAllocation index = useRegister(ins->index()); LInstruction* lir; switch (ins->value()->type()) { case MIRType::Value: lir = new (alloc()) LStoreElementHoleV(object, elements, index, useBox(ins->value()), temp()); break; default: { const LAllocation value = useRegisterOrNonDoubleConstant(ins->value()); lir = new (alloc()) LStoreElementHoleT(object, elements, index, value, temp()); break; } } assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitEffectiveAddress(MEffectiveAddress* ins) { define(new (alloc()) LEffectiveAddress(useRegister(ins->base()), useRegister(ins->index())), ins); } void LIRGenerator::visitArrayPopShift(MArrayPopShift* ins) { MOZ_ASSERT(ins->type() == MIRType::Value); auto* lir = new (alloc()) LArrayPopShift(useRegister(ins->object()), temp(), temp()); assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); if (ins->mode() == MArrayPopShift::Shift) { assignSafepoint(lir, ins); } } void LIRGenerator::visitArrayPush(MArrayPush* ins) { MOZ_ASSERT(ins->type() == MIRType::Int32); MOZ_ASSERT(ins->value()->type() == MIRType::Value); LUse object = useRegister(ins->object()); LDefinition spectreTemp = BoundsCheckNeedsSpectreTemp() ? temp() : LDefinition::BogusTemp(); auto* lir = new (alloc()) LArrayPush(object, useBox(ins->value()), temp(), spectreTemp); // We will bailout before pushing if the length would overflow INT32_MAX. assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitArraySlice(MArraySlice* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->begin()->type() == MIRType::Int32); MOZ_ASSERT(ins->end()->type() == MIRType::Int32); LArraySlice* lir = new (alloc()) LArraySlice( useRegisterAtStart(ins->object()), useRegisterAtStart(ins->begin()), useRegisterAtStart(ins->end()), tempFixed(CallTempReg0), tempFixed(CallTempReg1)); assignSnapshot(lir, ins->bailoutKind()); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitArgumentsSlice(MArgumentsSlice* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->begin()->type() == MIRType::Int32); MOZ_ASSERT(ins->end()->type() == MIRType::Int32); auto* lir = new (alloc()) LArgumentsSlice( useRegisterAtStart(ins->object()), useRegisterAtStart(ins->begin()), useRegisterAtStart(ins->end()), tempFixed(CallTempReg0), tempFixed(CallTempReg1)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitFrameArgumentsSlice(MFrameArgumentsSlice* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); MOZ_ASSERT(ins->begin()->type() == MIRType::Int32); MOZ_ASSERT(ins->count()->type() == MIRType::Int32); auto* lir = new (alloc()) LFrameArgumentsSlice( useRegister(ins->begin()), useRegister(ins->count()), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitInlineArgumentsSlice(MInlineArgumentsSlice* ins) { LAllocation begin = useRegisterOrConstant(ins->begin()); LAllocation count = useRegisterOrConstant(ins->count()); uint32_t numActuals = ins->numActuals(); uint32_t numOperands = numActuals * BOX_PIECES + LInlineArgumentsSlice::NumNonArgumentOperands; auto* lir = allocateVariadic(numOperands, temp()); if (!lir) { abort(AbortReason::Alloc, "OOM: LIRGenerator::visitInlineArgumentsSlice"); return; } lir->setOperand(LInlineArgumentsSlice::Begin, begin); lir->setOperand(LInlineArgumentsSlice::Count, count); for (uint32_t i = 0; i < numActuals; i++) { MDefinition* arg = ins->getArg(i); uint32_t index = LInlineArgumentsSlice::ArgIndex(i); lir->setBoxOperand(index, useBoxOrTypedOrConstant(arg, /*useConstant = */ true)); } define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNormalizeSliceTerm(MNormalizeSliceTerm* ins) { MOZ_ASSERT(ins->type() == MIRType::Int32); MOZ_ASSERT(ins->value()->type() == MIRType::Int32); MOZ_ASSERT(ins->length()->type() == MIRType::Int32); auto* lir = new (alloc()) LNormalizeSliceTerm(useRegister(ins->value()), useRegister(ins->length())); define(lir, ins); } void LIRGenerator::visitArrayJoin(MArrayJoin* ins) { MOZ_ASSERT(ins->type() == MIRType::String); MOZ_ASSERT(ins->array()->type() == MIRType::Object); MOZ_ASSERT(ins->sep()->type() == MIRType::String); auto* lir = new (alloc()) LArrayJoin(useRegisterAtStart(ins->array()), useRegisterAtStart(ins->sep()), tempFixed(CallTempReg0)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringSplit(MStringSplit* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); MOZ_ASSERT(ins->string()->type() == MIRType::String); MOZ_ASSERT(ins->separator()->type() == MIRType::String); LStringSplit* lir = new (alloc()) LStringSplit( useRegisterAtStart(ins->string()), useRegisterAtStart(ins->separator())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitLoadUnboxedScalar(MLoadUnboxedScalar* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::IntPtr); MOZ_ASSERT(IsNumericType(ins->type()) || ins->type() == MIRType::Boolean); if (Scalar::isBigIntType(ins->storageType()) && ins->requiresMemoryBarrier()) { lowerAtomicLoad64(ins); return; } const LUse elements = useRegister(ins->elements()); const LAllocation index = useRegisterOrIndexConstant( ins->index(), ins->storageType(), ins->offsetAdjustment()); // NOTE: the generated code must match the assembly code in gen_load in // GenerateAtomicOperations.py Synchronization sync = Synchronization::Load(); if (ins->requiresMemoryBarrier()) { LMemoryBarrier* fence = new (alloc()) LMemoryBarrier(sync.barrierBefore); add(fence, ins); } if (!Scalar::isBigIntType(ins->storageType())) { // We need a temp register for Uint32Array with known double result. LDefinition tempDef = LDefinition::BogusTemp(); if (ins->storageType() == Scalar::Uint32 && IsFloatingPointType(ins->type())) { tempDef = temp(); } auto* lir = new (alloc()) LLoadUnboxedScalar(elements, index, tempDef); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); } else { MOZ_ASSERT(ins->type() == MIRType::BigInt); auto* lir = new (alloc()) LLoadUnboxedBigInt(elements, index, temp(), tempInt64()); define(lir, ins); assignSafepoint(lir, ins); } if (ins->requiresMemoryBarrier()) { LMemoryBarrier* fence = new (alloc()) LMemoryBarrier(sync.barrierAfter); add(fence, ins); } } void LIRGenerator::visitLoadDataViewElement(MLoadDataViewElement* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::IntPtr); MOZ_ASSERT(IsNumericType(ins->type())); const LUse elements = useRegister(ins->elements()); const LUse index = useRegister(ins->index()); const LAllocation littleEndian = useRegisterOrConstant(ins->littleEndian()); // We need a temp register for: // - Uint32Array with known double result, // - Float32Array, // - and BigInt64Array and BigUint64Array. LDefinition tempDef = LDefinition::BogusTemp(); if ((ins->storageType() == Scalar::Uint32 && IsFloatingPointType(ins->type())) || ins->storageType() == Scalar::Float32) { tempDef = temp(); } if (Scalar::isBigIntType(ins->storageType())) { #ifdef JS_CODEGEN_X86 // There are not enough registers on x86. if (littleEndian.isConstant()) { tempDef = temp(); } #else tempDef = temp(); #endif } // We also need a separate 64-bit temp register for: // - Float64Array // - and BigInt64Array and BigUint64Array. LInt64Definition temp64Def = LInt64Definition::BogusTemp(); if (Scalar::byteSize(ins->storageType()) == 8) { temp64Def = tempInt64(); } auto* lir = new (alloc()) LLoadDataViewElement(elements, index, littleEndian, tempDef, temp64Def); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); if (Scalar::isBigIntType(ins->storageType())) { assignSafepoint(lir, ins); } } void LIRGenerator::visitClampToUint8(MClampToUint8* ins) { MDefinition* in = ins->input(); switch (in->type()) { case MIRType::Boolean: redefine(ins, in); break; case MIRType::Int32: defineReuseInput(new (alloc()) LClampIToUint8(useRegisterAtStart(in)), ins, 0); break; case MIRType::Double: // LClampDToUint8 clobbers its input register. Making it available as // a temp copy describes this behavior to the register allocator. define(new (alloc()) LClampDToUint8(useRegisterAtStart(in), tempCopy(in, 0)), ins); break; case MIRType::Value: { LClampVToUint8* lir = new (alloc()) LClampVToUint8(useBox(in), tempDouble()); assignSnapshot(lir, ins->bailoutKind()); define(lir, ins); assignSafepoint(lir, ins); break; } default: MOZ_CRASH("unexpected type"); } } void LIRGenerator::visitLoadTypedArrayElementHole( MLoadTypedArrayElementHole* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->index()->type() == MIRType::IntPtr); MOZ_ASSERT(ins->type() == MIRType::Value); const LUse object = useRegister(ins->object()); const LAllocation index = useRegister(ins->index()); if (!Scalar::isBigIntType(ins->arrayType())) { auto* lir = new (alloc()) LLoadTypedArrayElementHole(object, index, temp()); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } defineBox(lir, ins); } else { #ifdef JS_CODEGEN_X86 LDefinition tmp = LDefinition::BogusTemp(); #else LDefinition tmp = temp(); #endif auto* lir = new (alloc()) LLoadTypedArrayElementHoleBigInt(object, index, tmp, tempInt64()); defineBox(lir, ins); assignSafepoint(lir, ins); } } void LIRGenerator::visitStoreUnboxedScalar(MStoreUnboxedScalar* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::IntPtr); if (ins->isFloatWrite()) { MOZ_ASSERT_IF(ins->writeType() == Scalar::Float32, ins->value()->type() == MIRType::Float32); MOZ_ASSERT_IF(ins->writeType() == Scalar::Float64, ins->value()->type() == MIRType::Double); } else if (ins->isBigIntWrite()) { MOZ_ASSERT(ins->value()->type() == MIRType::BigInt); } else { MOZ_ASSERT(ins->value()->type() == MIRType::Int32); } if (ins->isBigIntWrite() && ins->requiresMemoryBarrier()) { lowerAtomicStore64(ins); return; } LUse elements = useRegister(ins->elements()); LAllocation index = useRegisterOrIndexConstant(ins->index(), ins->writeType()); LAllocation value; // For byte arrays, the value has to be in a byte register on x86. if (ins->isByteWrite()) { value = useByteOpRegisterOrNonDoubleConstant(ins->value()); } else if (ins->isBigIntWrite()) { value = useRegister(ins->value()); } else { value = useRegisterOrNonDoubleConstant(ins->value()); } // Optimization opportunity for atomics: on some platforms there // is a store instruction that incorporates the necessary // barriers, and we could use that instead of separate barrier and // store instructions. See bug #1077027. // // NOTE: the generated code must match the assembly code in gen_store in // GenerateAtomicOperations.py Synchronization sync = Synchronization::Store(); if (ins->requiresMemoryBarrier()) { LMemoryBarrier* fence = new (alloc()) LMemoryBarrier(sync.barrierBefore); add(fence, ins); } if (!ins->isBigIntWrite()) { add(new (alloc()) LStoreUnboxedScalar(elements, index, value), ins); } else { add(new (alloc()) LStoreUnboxedBigInt(elements, index, value, tempInt64()), ins); } if (ins->requiresMemoryBarrier()) { LMemoryBarrier* fence = new (alloc()) LMemoryBarrier(sync.barrierAfter); add(fence, ins); } } void LIRGenerator::visitStoreDataViewElement(MStoreDataViewElement* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::IntPtr); MOZ_ASSERT(ins->littleEndian()->type() == MIRType::Boolean); if (ins->isFloatWrite()) { MOZ_ASSERT_IF(ins->writeType() == Scalar::Float32, ins->value()->type() == MIRType::Float32); MOZ_ASSERT_IF(ins->writeType() == Scalar::Float64, ins->value()->type() == MIRType::Double); } else if (ins->isBigIntWrite()) { MOZ_ASSERT(ins->value()->type() == MIRType::BigInt); } else { MOZ_ASSERT(ins->value()->type() == MIRType::Int32); } LUse elements = useRegister(ins->elements()); LUse index = useRegister(ins->index()); LAllocation value; if (ins->isBigIntWrite()) { value = useRegister(ins->value()); } else { value = useRegisterOrNonDoubleConstant(ins->value()); } LAllocation littleEndian = useRegisterOrConstant(ins->littleEndian()); LDefinition tempDef = LDefinition::BogusTemp(); LInt64Definition temp64Def = LInt64Definition::BogusTemp(); if (Scalar::byteSize(ins->writeType()) < 8) { tempDef = temp(); } else { temp64Def = tempInt64(); } add(new (alloc()) LStoreDataViewElement(elements, index, value, littleEndian, tempDef, temp64Def), ins); } void LIRGenerator::visitStoreTypedArrayElementHole( MStoreTypedArrayElementHole* ins) { MOZ_ASSERT(ins->elements()->type() == MIRType::Elements); MOZ_ASSERT(ins->index()->type() == MIRType::IntPtr); MOZ_ASSERT(ins->length()->type() == MIRType::IntPtr); if (ins->isFloatWrite()) { MOZ_ASSERT_IF(ins->arrayType() == Scalar::Float32, ins->value()->type() == MIRType::Float32); MOZ_ASSERT_IF(ins->arrayType() == Scalar::Float64, ins->value()->type() == MIRType::Double); } else if (ins->isBigIntWrite()) { MOZ_ASSERT(ins->value()->type() == MIRType::BigInt); } else { MOZ_ASSERT(ins->value()->type() == MIRType::Int32); } LUse elements = useRegister(ins->elements()); LAllocation length = useAny(ins->length()); LAllocation index = useRegister(ins->index()); // For byte arrays, the value has to be in a byte register on x86. LAllocation value; if (ins->isByteWrite()) { value = useByteOpRegisterOrNonDoubleConstant(ins->value()); } else if (ins->isBigIntWrite()) { value = useRegister(ins->value()); } else { value = useRegisterOrNonDoubleConstant(ins->value()); } if (!ins->isBigIntWrite()) { LDefinition spectreTemp = BoundsCheckNeedsSpectreTemp() ? temp() : LDefinition::BogusTemp(); auto* lir = new (alloc()) LStoreTypedArrayElementHole( elements, length, index, value, spectreTemp); add(lir, ins); } else { auto* lir = new (alloc()) LStoreTypedArrayElementHoleBigInt( elements, length, index, value, tempInt64()); add(lir, ins); } } void LIRGenerator::visitLoadFixedSlot(MLoadFixedSlot* ins) { MDefinition* obj = ins->object(); MOZ_ASSERT(obj->type() == MIRType::Object); MIRType type = ins->type(); if (type == MIRType::Value) { LLoadFixedSlotV* lir = new (alloc()) LLoadFixedSlotV(useRegisterAtStart(obj)); defineBox(lir, ins); } else { LLoadFixedSlotT* lir = new (alloc()) LLoadFixedSlotT(useRegisterForTypedLoad(obj, type)); define(lir, ins); } } void LIRGenerator::visitLoadFixedSlotAndUnbox(MLoadFixedSlotAndUnbox* ins) { MDefinition* obj = ins->object(); MOZ_ASSERT(obj->type() == MIRType::Object); LLoadFixedSlotAndUnbox* lir = new (alloc()) LLoadFixedSlotAndUnbox(useRegisterAtStart(obj)); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); } void LIRGenerator::visitLoadDynamicSlotAndUnbox(MLoadDynamicSlotAndUnbox* ins) { MDefinition* slots = ins->slots(); MOZ_ASSERT(slots->type() == MIRType::Slots); auto* lir = new (alloc()) LLoadDynamicSlotAndUnbox(useRegisterAtStart(slots)); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); } void LIRGenerator::visitLoadElementAndUnbox(MLoadElementAndUnbox* ins) { MDefinition* elements = ins->elements(); MDefinition* index = ins->index(); MOZ_ASSERT(elements->type() == MIRType::Elements); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LLoadElementAndUnbox(useRegister(elements), useRegisterOrConstant(index)); if (ins->fallible()) { assignSnapshot(lir, ins->bailoutKind()); } define(lir, ins); } void LIRGenerator::visitAddAndStoreSlot(MAddAndStoreSlot* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); LDefinition maybeTemp = LDefinition::BogusTemp(); if (ins->kind() != MAddAndStoreSlot::Kind::FixedSlot) { maybeTemp = temp(); } auto* lir = new (alloc()) LAddAndStoreSlot(useRegister(ins->object()), useBox(ins->value()), maybeTemp); add(lir, ins); } void LIRGenerator::visitAllocateAndStoreSlot(MAllocateAndStoreSlot* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LAllocateAndStoreSlot( useRegisterAtStart(ins->object()), useBoxAtStart(ins->value()), tempFixed(CallTempReg0), tempFixed(CallTempReg1)); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); } void LIRGenerator::visitAddSlotAndCallAddPropHook( MAddSlotAndCallAddPropHook* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->value()->type() == MIRType::Value); auto* lir = new (alloc()) LAddSlotAndCallAddPropHook( useRegisterAtStart(ins->object()), useBoxAtStart(ins->value())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStoreFixedSlot(MStoreFixedSlot* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); if (ins->value()->type() == MIRType::Value) { LStoreFixedSlotV* lir = new (alloc()) LStoreFixedSlotV(useRegister(ins->object()), useBox(ins->value())); add(lir, ins); } else { LStoreFixedSlotT* lir = new (alloc()) LStoreFixedSlotT( useRegister(ins->object()), useRegisterOrConstant(ins->value())); add(lir, ins); } } void LIRGenerator::visitGetNameCache(MGetNameCache* ins) { MOZ_ASSERT(ins->envObj()->type() == MIRType::Object); // Emit an overrecursed check: this is necessary because the cache can // attach a scripted getter stub that calls this script recursively. gen->setNeedsOverrecursedCheck(); LGetNameCache* lir = new (alloc()) LGetNameCache(useRegister(ins->envObj()), temp()); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallGetIntrinsicValue(MCallGetIntrinsicValue* ins) { LCallGetIntrinsicValue* lir = new (alloc()) LCallGetIntrinsicValue(); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGetPropSuperCache(MGetPropSuperCache* ins) { MDefinition* obj = ins->object(); MDefinition* receiver = ins->receiver(); MDefinition* id = ins->idval(); gen->setNeedsOverrecursedCheck(); bool useConstId = id->type() == MIRType::String || id->type() == MIRType::Symbol; auto* lir = new (alloc()) LGetPropSuperCache(useRegister(obj), useBoxOrTyped(receiver), useBoxOrTypedOrConstant(id, useConstId)); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGetPropertyCache(MGetPropertyCache* ins) { MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Object || value->type() == MIRType::Value); MDefinition* id = ins->idval(); MOZ_ASSERT(id->type() == MIRType::String || id->type() == MIRType::Symbol || id->type() == MIRType::Int32 || id->type() == MIRType::Value); // Emit an overrecursed check: this is necessary because the cache can // attach a scripted getter stub that calls this script recursively. gen->setNeedsOverrecursedCheck(); // If this is a GetProp, the id is a constant string. Allow passing it as a // constant to reduce register allocation pressure. bool useConstId = id->type() == MIRType::String || id->type() == MIRType::Symbol; auto* lir = new (alloc()) LGetPropertyCache( useBoxOrTyped(value), useBoxOrTypedOrConstant(id, useConstId)); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBindNameCache(MBindNameCache* ins) { MOZ_ASSERT(ins->envChain()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Object); LBindNameCache* lir = new (alloc()) LBindNameCache(useRegister(ins->envChain()), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallBindVar(MCallBindVar* ins) { MOZ_ASSERT(ins->environmentChain()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Object); LCallBindVar* lir = new (alloc()) LCallBindVar(useRegister(ins->environmentChain())); define(lir, ins); } void LIRGenerator::visitGuardObjectIdentity(MGuardObjectIdentity* ins) { LGuardObjectIdentity* guard = new (alloc()) LGuardObjectIdentity( useRegister(ins->object()), useRegister(ins->expected())); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardSpecificFunction(MGuardSpecificFunction* ins) { auto* guard = new (alloc()) LGuardSpecificFunction( useRegister(ins->function()), useRegister(ins->expected())); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, ins->function()); } void LIRGenerator::visitGuardSpecificAtom(MGuardSpecificAtom* ins) { auto* guard = new (alloc()) LGuardSpecificAtom(useRegister(ins->str()), temp()); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, ins->str()); assignSafepoint(guard, ins); } void LIRGenerator::visitGuardSpecificSymbol(MGuardSpecificSymbol* ins) { auto* guard = new (alloc()) LGuardSpecificSymbol(useRegister(ins->symbol())); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, ins->symbol()); } void LIRGenerator::visitGuardSpecificInt32(MGuardSpecificInt32* ins) { auto* guard = new (alloc()) LGuardSpecificInt32(useRegister(ins->num())); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, ins->num()); } void LIRGenerator::visitGuardStringToIndex(MGuardStringToIndex* ins) { MOZ_ASSERT(ins->string()->type() == MIRType::String); auto* guard = new (alloc()) LGuardStringToIndex(useRegister(ins->string())); assignSnapshot(guard, ins->bailoutKind()); define(guard, ins); assignSafepoint(guard, ins); } void LIRGenerator::visitGuardStringToInt32(MGuardStringToInt32* ins) { MOZ_ASSERT(ins->string()->type() == MIRType::String); auto* guard = new (alloc()) LGuardStringToInt32(useRegister(ins->string()), temp()); assignSnapshot(guard, ins->bailoutKind()); define(guard, ins); assignSafepoint(guard, ins); } void LIRGenerator::visitGuardStringToDouble(MGuardStringToDouble* ins) { MOZ_ASSERT(ins->string()->type() == MIRType::String); auto* guard = new (alloc()) LGuardStringToDouble(useRegister(ins->string()), temp(), temp()); assignSnapshot(guard, ins->bailoutKind()); define(guard, ins); assignSafepoint(guard, ins); } void LIRGenerator::visitGuardNoDenseElements(MGuardNoDenseElements* ins) { auto* guard = new (alloc()) LGuardNoDenseElements(useRegister(ins->object()), temp()); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardShape(MGuardShape* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); if (JitOptions.spectreObjectMitigations) { auto* lir = new (alloc()) LGuardShape(useRegisterAtStart(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); defineReuseInput(lir, ins, 0); } else { auto* lir = new (alloc()) LGuardShape(useRegister(ins->object()), LDefinition::BogusTemp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } } void LIRGenerator::visitGuardMultipleShapes(MGuardMultipleShapes* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); if (JitOptions.spectreObjectMitigations) { auto* lir = new (alloc()) LGuardMultipleShapes( useRegisterAtStart(ins->object()), useRegister(ins->shapeList()), temp(), temp(), temp(), temp()); assignSnapshot(lir, ins->bailoutKind()); defineReuseInput(lir, ins, 0); } else { auto* lir = new (alloc()) LGuardMultipleShapes( useRegister(ins->object()), useRegister(ins->shapeList()), temp(), temp(), temp(), LDefinition::BogusTemp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } } void LIRGenerator::visitGuardProto(MGuardProto* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->expected()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardProto(useRegister(ins->object()), useRegister(ins->expected()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardNullProto(MGuardNullProto* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardNullProto(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardIsNativeObject(MGuardIsNativeObject* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardIsNativeObject(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardIsProxy(MGuardIsProxy* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardIsProxy(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardIsNotProxy(MGuardIsNotProxy* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardIsNotProxy(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardIsNotDOMProxy(MGuardIsNotDOMProxy* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardIsNotDOMProxy(useRegister(ins->proxy()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->proxy()); } void LIRGenerator::visitProxyGet(MProxyGet* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); auto* lir = new (alloc()) LProxyGet(useRegisterAtStart(ins->proxy()), tempFixed(CallTempReg0)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitProxyGetByValue(MProxyGetByValue* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); MOZ_ASSERT(ins->idVal()->type() == MIRType::Value); auto* lir = new (alloc()) LProxyGetByValue(useRegisterAtStart(ins->proxy()), useBoxAtStart(ins->idVal())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitProxyHasProp(MProxyHasProp* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); MOZ_ASSERT(ins->idVal()->type() == MIRType::Value); auto* lir = new (alloc()) LProxyHasProp(useRegisterAtStart(ins->proxy()), useBoxAtStart(ins->idVal())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitProxySet(MProxySet* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); MOZ_ASSERT(ins->rhs()->type() == MIRType::Value); auto* lir = new (alloc()) LProxySet(useRegisterAtStart(ins->proxy()), useBoxAtStart(ins->rhs()), tempFixed(CallTempReg0)); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitProxySetByValue(MProxySetByValue* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); MOZ_ASSERT(ins->idVal()->type() == MIRType::Value); MOZ_ASSERT(ins->rhs()->type() == MIRType::Value); auto* lir = new (alloc()) LProxySetByValue(useRegisterAtStart(ins->proxy()), useBoxAtStart(ins->idVal()), useBoxAtStart(ins->rhs())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallSetArrayLength(MCallSetArrayLength* ins) { MOZ_ASSERT(ins->obj()->type() == MIRType::Object); MOZ_ASSERT(ins->rhs()->type() == MIRType::Value); auto* lir = new (alloc()) LCallSetArrayLength(useRegisterAtStart(ins->obj()), useBoxAtStart(ins->rhs())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitMegamorphicLoadSlot(MMegamorphicLoadSlot* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LMegamorphicLoadSlot( useRegisterAtStart(ins->object()), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); assignSnapshot(lir, ins->bailoutKind()); defineReturn(lir, ins); } void LIRGenerator::visitMegamorphicLoadSlotByValue( MMegamorphicLoadSlotByValue* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->idVal()->type() == MIRType::Value); auto* lir = new (alloc()) LMegamorphicLoadSlotByValue( useRegisterAtStart(ins->object()), useBoxAtStart(ins->idVal()), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); assignSnapshot(lir, ins->bailoutKind()); defineReturn(lir, ins); } void LIRGenerator::visitMegamorphicStoreSlot(MMegamorphicStoreSlot* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->rhs()->type() == MIRType::Value); auto* lir = new (alloc()) LMegamorphicStoreSlot(useRegisterAtStart(ins->object()), useBoxAtStart(ins->rhs()), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); } void LIRGenerator::visitMegamorphicHasProp(MMegamorphicHasProp* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->idVal()->type() == MIRType::Value); auto* lir = new (alloc()) LMegamorphicHasProp(useRegisterAtStart(ins->object()), useBoxAtStart(ins->idVal()), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); assignSnapshot(lir, ins->bailoutKind()); defineReturn(lir, ins); } void LIRGenerator::visitGuardIsNotArrayBufferMaybeShared( MGuardIsNotArrayBufferMaybeShared* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardIsNotArrayBufferMaybeShared(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitGuardIsTypedArray(MGuardIsTypedArray* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardIsTypedArray(useRegister(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->object()); } void LIRGenerator::visitNurseryObject(MNurseryObject* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); auto* lir = new (alloc()) LNurseryObject(); define(lir, ins); } void LIRGenerator::visitGuardValue(MGuardValue* ins) { MOZ_ASSERT(ins->value()->type() == MIRType::Value); auto* lir = new (alloc()) LGuardValue(useBox(ins->value())); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->value()); } void LIRGenerator::visitGuardNullOrUndefined(MGuardNullOrUndefined* ins) { MOZ_ASSERT(ins->value()->type() == MIRType::Value); auto* lir = new (alloc()) LGuardNullOrUndefined(useBox(ins->value())); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->value()); } void LIRGenerator::visitGuardIsNotObject(MGuardIsNotObject* ins) { MOZ_ASSERT(ins->value()->type() == MIRType::Value); auto* lir = new (alloc()) LGuardIsNotObject(useBox(ins->value())); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->value()); } void LIRGenerator::visitGuardFunctionFlags(MGuardFunctionFlags* ins) { MOZ_ASSERT(ins->function()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardFunctionFlags(useRegister(ins->function())); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->function()); } void LIRGenerator::visitGuardFunctionIsNonBuiltinCtor( MGuardFunctionIsNonBuiltinCtor* ins) { MOZ_ASSERT(ins->function()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardFunctionIsNonBuiltinCtor(useRegister(ins->function()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->function()); } void LIRGenerator::visitGuardFunctionKind(MGuardFunctionKind* ins) { MOZ_ASSERT(ins->function()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardFunctionKind(useRegister(ins->function()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->function()); } void LIRGenerator::visitGuardFunctionScript(MGuardFunctionScript* ins) { MOZ_ASSERT(ins->function()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardFunctionScript(useRegister(ins->function())); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->function()); } void LIRGenerator::visitAssertRange(MAssertRange* ins) { MDefinition* input = ins->input(); LInstruction* lir = nullptr; switch (input->type()) { case MIRType::Boolean: case MIRType::Int32: case MIRType::IntPtr: lir = new (alloc()) LAssertRangeI(useRegisterAtStart(input)); break; case MIRType::Double: lir = new (alloc()) LAssertRangeD(useRegister(input), tempDouble()); break; case MIRType::Float32: lir = new (alloc()) LAssertRangeF(useRegister(input), tempDouble(), tempDouble()); break; case MIRType::Value: lir = new (alloc()) LAssertRangeV(useBox(input), tempToUnbox(), tempDouble(), tempDouble()); break; default: MOZ_CRASH("Unexpected Range for MIRType"); break; } lir->setMir(ins); add(lir); } void LIRGenerator::visitAssertClass(MAssertClass* ins) { auto* lir = new (alloc()) LAssertClass(useRegisterAtStart(ins->input()), temp()); add(lir, ins); } void LIRGenerator::visitAssertShape(MAssertShape* ins) { auto* lir = new (alloc()) LAssertShape(useRegisterAtStart(ins->input())); add(lir, ins); } void LIRGenerator::visitDeleteProperty(MDeleteProperty* ins) { LCallDeleteProperty* lir = new (alloc()) LCallDeleteProperty(useBoxAtStart(ins->value())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitDeleteElement(MDeleteElement* ins) { LCallDeleteElement* lir = new (alloc()) LCallDeleteElement( useBoxAtStart(ins->value()), useBoxAtStart(ins->index())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitObjectToIterator(MObjectToIterator* ins) { auto* lir = new (alloc()) LObjectToIterator(useRegister(ins->object()), temp(), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitValueToIterator(MValueToIterator* ins) { auto* lir = new (alloc()) LValueToIterator(useBoxAtStart(ins->value())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitSetPropertyCache(MSetPropertyCache* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MDefinition* id = ins->idval(); MOZ_ASSERT(id->type() == MIRType::String || id->type() == MIRType::Symbol || id->type() == MIRType::Int32 || id->type() == MIRType::Value); // If this is a SetProp, the id is a constant string. Allow passing it as a // constant to reduce register allocation pressure. bool useConstId = id->type() == MIRType::String || id->type() == MIRType::Symbol; bool useConstValue = IsNonNurseryConstant(ins->value()); // Emit an overrecursed check: this is necessary because the cache can // attach a scripted setter stub that calls this script recursively. gen->setNeedsOverrecursedCheck(); // We need a double temp register for TypedArray or TypedObject stubs. LDefinition tempD = tempFixed(FloatReg0); LInstruction* lir = new (alloc()) LSetPropertyCache( useRegister(ins->object()), useBoxOrTypedOrConstant(id, useConstId), useBoxOrTypedOrConstant(ins->value(), useConstValue), temp(), tempD); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitMegamorphicSetElement(MMegamorphicSetElement* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->index()->type() == MIRType::Value); MOZ_ASSERT(ins->value()->type() == MIRType::Value); auto* lir = new (alloc()) LMegamorphicSetElement( useRegisterAtStart(ins->object()), useBoxAtStart(ins->index()), useBoxAtStart(ins->value())); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGetIteratorCache(MGetIteratorCache* ins) { MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Object || value->type() == MIRType::Value); LGetIteratorCache* lir = new (alloc()) LGetIteratorCache(useBoxOrTyped(value), temp(), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitOptimizeSpreadCallCache(MOptimizeSpreadCallCache* ins) { MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Value); auto* lir = new (alloc()) LOptimizeSpreadCallCache(useBox(value), temp()); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitIteratorMore(MIteratorMore* ins) { LIteratorMore* lir = new (alloc()) LIteratorMore(useRegister(ins->iterator()), temp()); defineBox(lir, ins); } void LIRGenerator::visitIsNoIter(MIsNoIter* ins) { MOZ_ASSERT(ins->hasOneUse()); emitAtUses(ins); } void LIRGenerator::visitIteratorEnd(MIteratorEnd* ins) { LIteratorEnd* lir = new (alloc()) LIteratorEnd(useRegister(ins->iterator()), temp(), temp(), temp()); add(lir, ins); } void LIRGenerator::visitCloseIterCache(MCloseIterCache* ins) { LCloseIterCache* lir = new (alloc()) LCloseIterCache(useRegister(ins->iter()), temp()); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitStringLength(MStringLength* ins) { MOZ_ASSERT(ins->string()->type() == MIRType::String); define(new (alloc()) LStringLength(useRegisterAtStart(ins->string())), ins); } void LIRGenerator::visitArgumentsLength(MArgumentsLength* ins) { define(new (alloc()) LArgumentsLength(), ins); } void LIRGenerator::visitGetFrameArgument(MGetFrameArgument* ins) { LGetFrameArgument* lir = new (alloc()) LGetFrameArgument(useRegisterOrConstant(ins->index())); defineBox(lir, ins); } void LIRGenerator::visitGetFrameArgumentHole(MGetFrameArgumentHole* ins) { LDefinition spectreTemp = BoundsCheckNeedsSpectreTemp() ? temp() : LDefinition::BogusTemp(); auto* lir = new (alloc()) LGetFrameArgumentHole( useRegister(ins->index()), useRegister(ins->length()), spectreTemp); assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); } void LIRGenerator::visitNewTarget(MNewTarget* ins) { LNewTarget* lir = new (alloc()) LNewTarget(); defineBox(lir, ins); } void LIRGenerator::visitRest(MRest* ins) { MOZ_ASSERT(ins->numActuals()->type() == MIRType::Int32); LRest* lir = new (alloc()) LRest(useRegisterAtStart(ins->numActuals()), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitThrow(MThrow* ins) { MDefinition* value = ins->getOperand(0); MOZ_ASSERT(value->type() == MIRType::Value); LThrow* lir = new (alloc()) LThrow(useBoxAtStart(value)); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitInCache(MInCache* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == MIRType::String || lhs->type() == MIRType::Symbol || lhs->type() == MIRType::Int32 || lhs->type() == MIRType::Value); MOZ_ASSERT(rhs->type() == MIRType::Object); LInCache* lir = new (alloc()) LInCache(useBoxOrTyped(lhs), useRegister(rhs), temp()); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitHasOwnCache(MHasOwnCache* ins) { MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Object || value->type() == MIRType::Value); MDefinition* id = ins->idval(); MOZ_ASSERT(id->type() == MIRType::String || id->type() == MIRType::Symbol || id->type() == MIRType::Int32 || id->type() == MIRType::Value); // Emit an overrecursed check: this is necessary because the cache can // attach a scripted getter stub that calls this script recursively. gen->setNeedsOverrecursedCheck(); LHasOwnCache* lir = new (alloc()) LHasOwnCache(useBoxOrTyped(value), useBoxOrTyped(id)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCheckPrivateFieldCache(MCheckPrivateFieldCache* ins) { MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Object || value->type() == MIRType::Value); MDefinition* id = ins->idval(); MOZ_ASSERT(id->type() == MIRType::String || id->type() == MIRType::Symbol || id->type() == MIRType::Int32 || id->type() == MIRType::Value); LCheckPrivateFieldCache* lir = new (alloc()) LCheckPrivateFieldCache(useBoxOrTyped(value), useBoxOrTyped(id)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitNewPrivateName(MNewPrivateName* ins) { auto* lir = new (alloc()) LNewPrivateName(); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitInstanceOf(MInstanceOf* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == MIRType::Value || lhs->type() == MIRType::Object); MOZ_ASSERT(rhs->type() == MIRType::Object); if (lhs->type() == MIRType::Object) { auto* lir = new (alloc()) LInstanceOfO(useRegister(lhs), useRegister(rhs)); define(lir, ins); assignSafepoint(lir, ins); } else { auto* lir = new (alloc()) LInstanceOfV(useBox(lhs), useRegister(rhs)); define(lir, ins); assignSafepoint(lir, ins); } } void LIRGenerator::visitInstanceOfCache(MInstanceOfCache* ins) { MDefinition* lhs = ins->lhs(); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(lhs->type() == MIRType::Value); MOZ_ASSERT(rhs->type() == MIRType::Object); LInstanceOfCache* lir = new (alloc()) LInstanceOfCache(useBox(lhs), useRegister(rhs)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitIsArray(MIsArray* ins) { MOZ_ASSERT(ins->type() == MIRType::Boolean); if (ins->value()->type() == MIRType::Object) { LIsArrayO* lir = new (alloc()) LIsArrayO(useRegister(ins->value())); define(lir, ins); assignSafepoint(lir, ins); } else { MOZ_ASSERT(ins->value()->type() == MIRType::Value); LIsArrayV* lir = new (alloc()) LIsArrayV(useBox(ins->value()), temp()); define(lir, ins); assignSafepoint(lir, ins); } } void LIRGenerator::visitIsTypedArray(MIsTypedArray* ins) { MOZ_ASSERT(ins->value()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); auto* lir = new (alloc()) LIsTypedArray(useRegister(ins->value())); define(lir, ins); if (ins->isPossiblyWrapped()) { assignSafepoint(lir, ins); } } void LIRGenerator::visitIsCallable(MIsCallable* ins) { MOZ_ASSERT(ins->type() == MIRType::Boolean); if (ins->object()->type() == MIRType::Object) { define(new (alloc()) LIsCallableO(useRegister(ins->object())), ins); } else { MOZ_ASSERT(ins->object()->type() == MIRType::Value); define(new (alloc()) LIsCallableV(useBox(ins->object()), temp()), ins); } } void LIRGenerator::visitIsConstructor(MIsConstructor* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); define(new (alloc()) LIsConstructor(useRegister(ins->object())), ins); } void LIRGenerator::visitIsCrossRealmArrayConstructor( MIsCrossRealmArrayConstructor* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); define(new (alloc()) LIsCrossRealmArrayConstructor(useRegister(ins->object())), ins); } static bool CanEmitAtUseForSingleTest(MInstruction* ins) { if (!ins->canEmitAtUses()) { return false; } MUseIterator iter(ins->usesBegin()); if (iter == ins->usesEnd()) { return false; } MNode* node = iter->consumer(); if (!node->isDefinition()) { return false; } if (!node->toDefinition()->isTest()) { return false; } iter++; return iter == ins->usesEnd(); } void LIRGenerator::visitIsObject(MIsObject* ins) { if (CanEmitAtUseForSingleTest(ins)) { emitAtUses(ins); return; } MDefinition* opd = ins->input(); MOZ_ASSERT(opd->type() == MIRType::Value); LIsObject* lir = new (alloc()) LIsObject(useBoxAtStart(opd)); define(lir, ins); } void LIRGenerator::visitIsNullOrUndefined(MIsNullOrUndefined* ins) { if (CanEmitAtUseForSingleTest(ins)) { emitAtUses(ins); return; } MDefinition* opd = ins->input(); MOZ_ASSERT(opd->type() == MIRType::Value); LIsNullOrUndefined* lir = new (alloc()) LIsNullOrUndefined(useBoxAtStart(opd)); define(lir, ins); } void LIRGenerator::visitHasClass(MHasClass* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); define(new (alloc()) LHasClass(useRegister(ins->object())), ins); } void LIRGenerator::visitGuardToClass(MGuardToClass* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Object); LGuardToClass* lir = new (alloc()) LGuardToClass(useRegisterAtStart(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); defineReuseInput(lir, ins, 0); } void LIRGenerator::visitGuardToFunction(MGuardToFunction* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Object); LGuardToFunction* lir = new (alloc()) LGuardToFunction(useRegisterAtStart(ins->object()), temp()); assignSnapshot(lir, ins->bailoutKind()); defineReuseInput(lir, ins, 0); } void LIRGenerator::visitObjectClassToString(MObjectClassToString* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::String); auto* lir = new (alloc()) LObjectClassToString( useRegisterAtStart(ins->object()), tempFixed(CallTempReg0)); assignSnapshot(lir, ins->bailoutKind()); defineReturn(lir, ins); } void LIRGenerator::visitWasmAddOffset(MWasmAddOffset* ins) { MOZ_ASSERT(ins->offset()); if (ins->base()->type() == MIRType::Int32) { MOZ_ASSERT(ins->type() == MIRType::Int32); MOZ_ASSERT(ins->offset() <= UINT32_MAX); // Because memory32 define(new (alloc()) LWasmAddOffset(useRegisterAtStart(ins->base())), ins); } else { MOZ_ASSERT(ins->type() == MIRType::Int64); #ifdef JS_64BIT defineInt64(new (alloc()) LWasmAddOffset64(useInt64RegisterAtStart(ins->base())), ins); #else // Avoid situation where the input is (a,b) and the output is (b,a). defineInt64ReuseInput( new (alloc()) LWasmAddOffset64(useInt64RegisterAtStart(ins->base())), ins, 0); #endif } } void LIRGenerator::visitWasmLoadInstance(MWasmLoadInstance* ins) { if (ins->type() == MIRType::Int64) { #ifdef JS_PUNBOX64 LAllocation instance = useRegisterAtStart(ins->instance()); #else // Avoid reusing instance for a 64-bit output pair as the load clobbers the // first half of that pair before loading the second half. LAllocation instance = useRegister(ins->instance()); #endif auto* lir = new (alloc()) LWasmLoadInstance64(instance); defineInt64(lir, ins); } else { auto* lir = new (alloc()) LWasmLoadInstance(useRegisterAtStart(ins->instance())); define(lir, ins); } } void LIRGenerator::visitWasmStoreInstance(MWasmStoreInstance* ins) { MDefinition* value = ins->value(); if (value->type() == MIRType::Int64) { #ifdef JS_PUNBOX64 LAllocation instance = useRegisterAtStart(ins->instance()); LInt64Allocation valueAlloc = useInt64RegisterAtStart(value); #else LAllocation instance = useRegister(ins->instance()); LInt64Allocation valueAlloc = useInt64Register(value); #endif add(new (alloc()) LWasmStoreSlotI64(valueAlloc, instance, ins->offset(), mozilla::Nothing()), ins); } else { MOZ_ASSERT(value->type() != MIRType::RefOrNull); LAllocation instance = useRegisterAtStart(ins->instance()); LAllocation valueAlloc = useRegisterAtStart(value); add(new (alloc()) LWasmStoreSlot(valueAlloc, instance, ins->offset(), value->type(), MNarrowingOp::None, mozilla::Nothing()), ins); } } void LIRGenerator::visitWasmBoundsCheck(MWasmBoundsCheck* ins) { MOZ_ASSERT(!ins->isRedundant()); MDefinition* index = ins->index(); MDefinition* boundsCheckLimit = ins->boundsCheckLimit(); MOZ_ASSERT(boundsCheckLimit->type() == index->type()); if (index->type() == MIRType::Int64) { if (JitOptions.spectreIndexMasking) { auto* lir = new (alloc()) LWasmBoundsCheck64( useInt64RegisterAtStart(index), useInt64Register(boundsCheckLimit)); defineInt64ReuseInput(lir, ins, 0); } else { auto* lir = new (alloc()) LWasmBoundsCheck64(useInt64RegisterAtStart(index), useInt64RegisterAtStart(boundsCheckLimit)); add(lir, ins); } } else { MOZ_ASSERT(index->type() == MIRType::Int32); if (JitOptions.spectreIndexMasking) { auto* lir = new (alloc()) LWasmBoundsCheck(useRegisterAtStart(index), useRegister(boundsCheckLimit)); defineReuseInput(lir, ins, 0); } else { auto* lir = new (alloc()) LWasmBoundsCheck( useRegisterAtStart(index), useRegisterAtStart(boundsCheckLimit)); add(lir, ins); } } } void LIRGenerator::visitWasmAlignmentCheck(MWasmAlignmentCheck* ins) { MDefinition* index = ins->index(); if (index->type() == MIRType::Int64) { auto* lir = new (alloc()) LWasmAlignmentCheck64(useInt64RegisterAtStart(index)); add(lir, ins); } else { auto* lir = new (alloc()) LWasmAlignmentCheck(useRegisterAtStart(index)); add(lir, ins); } } void LIRGenerator::visitWasmLoadGlobalVar(MWasmLoadGlobalVar* ins) { size_t offs = wasm::Instance::offsetOfGlobalArea() + ins->globalDataOffset(); if (ins->type() == MIRType::Int64) { #ifdef JS_PUNBOX64 LAllocation instance = useRegisterAtStart(ins->instance()); #else // Avoid reusing instance for the output pair as the load clobbers the first // half of that pair before loading the second half. LAllocation instance = useRegister(ins->instance()); #endif defineInt64(new (alloc()) LWasmLoadSlotI64(instance, offs, mozilla::Nothing()), ins); } else { LAllocation instance = useRegisterAtStart(ins->instance()); define(new (alloc()) LWasmLoadSlot(instance, offs, ins->type(), MWideningOp::None, mozilla::Nothing()), ins); } } void LIRGenerator::visitWasmLoadGlobalCell(MWasmLoadGlobalCell* ins) { if (ins->type() == MIRType::Int64) { #ifdef JS_PUNBOX64 LAllocation cellPtr = useRegisterAtStart(ins->cellPtr()); #else // Avoid reusing cellPtr for the output pair as the load clobbers the first // half of that pair before loading the second half. LAllocation cellPtr = useRegister(ins->cellPtr()); #endif defineInt64(new (alloc()) LWasmLoadSlotI64(cellPtr, /*offset=*/0, mozilla::Nothing()), ins); } else { LAllocation cellPtr = useRegisterAtStart(ins->cellPtr()); define(new (alloc()) LWasmLoadSlot(cellPtr, /*offset=*/0, ins->type(), MWideningOp::None, mozilla::Nothing()), ins); } } void LIRGenerator::visitWasmLoadTableElement(MWasmLoadTableElement* ins) { LAllocation elements = useRegisterAtStart(ins->elements()); LAllocation index = useRegisterAtStart(ins->index()); define(new (alloc()) LWasmLoadTableElement(elements, index), ins); } void LIRGenerator::visitWasmStoreGlobalVar(MWasmStoreGlobalVar* ins) { MDefinition* value = ins->value(); size_t offs = wasm::Instance::offsetOfGlobalArea() + ins->globalDataOffset(); if (value->type() == MIRType::Int64) { #ifdef JS_PUNBOX64 LAllocation instance = useRegisterAtStart(ins->instance()); LInt64Allocation valueAlloc = useInt64RegisterAtStart(value); #else LAllocation instance = useRegister(ins->instance()); LInt64Allocation valueAlloc = useInt64Register(value); #endif add(new (alloc()) LWasmStoreSlotI64(valueAlloc, instance, offs, mozilla::Nothing()), ins); } else { MOZ_ASSERT(value->type() != MIRType::RefOrNull); LAllocation instance = useRegisterAtStart(ins->instance()); LAllocation valueAlloc = useRegisterAtStart(value); add(new (alloc()) LWasmStoreSlot(valueAlloc, instance, offs, value->type(), MNarrowingOp::None, mozilla::Nothing()), ins); } } void LIRGenerator::visitWasmStoreGlobalCell(MWasmStoreGlobalCell* ins) { MDefinition* value = ins->value(); size_t offs = 0; if (value->type() == MIRType::Int64) { #ifdef JS_PUNBOX64 LAllocation cellPtr = useRegisterAtStart(ins->cellPtr()); LInt64Allocation valueAlloc = useInt64RegisterAtStart(value); #else LAllocation cellPtr = useRegister(ins->cellPtr()); LInt64Allocation valueAlloc = useInt64Register(value); #endif add(new (alloc()) LWasmStoreSlotI64(valueAlloc, cellPtr, offs, mozilla::Nothing())); } else { MOZ_ASSERT(value->type() != MIRType::RefOrNull); LAllocation cellPtr = useRegisterAtStart(ins->cellPtr()); LAllocation valueAlloc = useRegisterAtStart(value); add(new (alloc()) LWasmStoreSlot(valueAlloc, cellPtr, offs, value->type(), MNarrowingOp::None, mozilla::Nothing())); } } void LIRGenerator::visitWasmStoreStackResult(MWasmStoreStackResult* ins) { MDefinition* stackResultArea = ins->stackResultArea(); MDefinition* value = ins->value(); size_t offs = ins->offset(); LInstruction* lir; if (value->type() == MIRType::Int64) { lir = new (alloc()) LWasmStoreSlotI64(useInt64Register(value), useRegister(stackResultArea), offs, mozilla::Nothing()); } else { MOZ_ASSERT(value->type() != MIRType::RefOrNull); lir = new (alloc()) LWasmStoreSlot(useRegister(value), useRegister(stackResultArea), offs, value->type(), MNarrowingOp::None, mozilla::Nothing()); } add(lir, ins); } void LIRGenerator::visitWasmDerivedPointer(MWasmDerivedPointer* ins) { LAllocation base = useRegisterAtStart(ins->base()); define(new (alloc()) LWasmDerivedPointer(base), ins); } void LIRGenerator::visitWasmDerivedIndexPointer(MWasmDerivedIndexPointer* ins) { LAllocation base = useRegisterAtStart(ins->base()); LAllocation index = useRegisterAtStart(ins->index()); define(new (alloc()) LWasmDerivedIndexPointer(base, index), ins); } void LIRGenerator::visitWasmStoreRef(MWasmStoreRef* ins) { LAllocation instance = useRegister(ins->instance()); LAllocation valueAddr = useFixed(ins->valueAddr(), PreBarrierReg); LAllocation value = useRegister(ins->value()); add(new (alloc()) LWasmStoreRef(instance, valueAddr, value, temp()), ins); } void LIRGenerator::visitWasmParameter(MWasmParameter* ins) { ABIArg abi = ins->abi(); if (ins->type() == MIRType::StackResults) { // Functions that return stack results receive an extra incoming parameter // with type MIRType::StackResults. This value is a pointer to fresh // memory. Here we treat it as if it were in fact MIRType::Pointer. auto* lir = new (alloc()) LWasmParameter; LDefinition def(LDefinition::TypeFrom(MIRType::Pointer), LDefinition::FIXED); def.setOutput(abi.argInRegister() ? LAllocation(abi.reg()) : LArgument(abi.offsetFromArgBase())); define(lir, ins, def); return; } if (abi.argInRegister()) { #if defined(JS_NUNBOX32) if (abi.isGeneralRegPair()) { defineInt64Fixed( new (alloc()) LWasmParameterI64, ins, LInt64Allocation(LAllocation(AnyRegister(abi.gpr64().high)), LAllocation(AnyRegister(abi.gpr64().low)))); return; } #endif defineFixed(new (alloc()) LWasmParameter, ins, LAllocation(abi.reg())); return; } if (ins->type() == MIRType::Int64) { MOZ_ASSERT(!abi.argInRegister()); defineInt64Fixed( new (alloc()) LWasmParameterI64, ins, #if defined(JS_NUNBOX32) LInt64Allocation(LArgument(abi.offsetFromArgBase() + INT64HIGH_OFFSET), LArgument(abi.offsetFromArgBase() + INT64LOW_OFFSET)) #else LInt64Allocation(LArgument(abi.offsetFromArgBase())) #endif ); } else { MOZ_ASSERT(IsNumberType(ins->type()) || ins->type() == MIRType::RefOrNull #ifdef ENABLE_WASM_SIMD || ins->type() == MIRType::Simd128 #endif ); defineFixed(new (alloc()) LWasmParameter, ins, LArgument(abi.offsetFromArgBase())); } } void LIRGenerator::visitWasmReturn(MWasmReturn* ins) { MDefinition* rval = ins->getOperand(0); MDefinition* instance = ins->getOperand(1); if (rval->type() == MIRType::Int64) { add(new (alloc()) LWasmReturnI64(useInt64Fixed(rval, ReturnReg64), useFixed(instance, InstanceReg))); return; } LAllocation returnReg; if (rval->type() == MIRType::Float32) { returnReg = useFixed(rval, ReturnFloat32Reg); } else if (rval->type() == MIRType::Double) { returnReg = useFixed(rval, ReturnDoubleReg); #ifdef ENABLE_WASM_SIMD } else if (rval->type() == MIRType::Simd128) { returnReg = useFixed(rval, ReturnSimd128Reg); #endif } else if (rval->type() == MIRType::Int32 || rval->type() == MIRType::RefOrNull) { returnReg = useFixed(rval, ReturnReg); } else { MOZ_CRASH("Unexpected wasm return type"); } LWasmReturn* lir = new (alloc()) LWasmReturn(useFixed(instance, InstanceReg), returnReg); add(lir); } void LIRGenerator::visitWasmReturnVoid(MWasmReturnVoid* ins) { MDefinition* instance = ins->getOperand(0); LWasmReturnVoid* lir = new (alloc()) LWasmReturnVoid(useFixed(instance, InstanceReg)); add(lir); } void LIRGenerator::visitWasmStackArg(MWasmStackArg* ins) { if (ins->arg()->type() == MIRType::Int64) { add(new (alloc()) LWasmStackArgI64(useInt64RegisterOrConstantAtStart(ins->arg())), ins); } else if (IsFloatingPointType(ins->arg()->type())) { MOZ_ASSERT(!ins->arg()->isEmittedAtUses()); add(new (alloc()) LWasmStackArg(useRegisterAtStart(ins->arg())), ins); } else { add(new (alloc()) LWasmStackArg(useRegisterOrConstantAtStart(ins->arg())), ins); } } void LIRGenerator::visitWasmRegisterResult(MWasmRegisterResult* ins) { auto* lir = new (alloc()) LWasmRegisterResult(); uint32_t vreg = getVirtualRegister(); MOZ_ASSERT(ins->type() != MIRType::Int64); auto type = LDefinition::TypeFrom(ins->type()); lir->setDef(0, LDefinition(vreg, type, LGeneralReg(ins->loc()))); ins->setVirtualRegister(vreg); add(lir, ins); } void LIRGenerator::visitWasmFloatRegisterResult(MWasmFloatRegisterResult* ins) { auto* lir = new (alloc()) LWasmRegisterResult(); uint32_t vreg = getVirtualRegister(); auto type = LDefinition::TypeFrom(ins->type()); lir->setDef(0, LDefinition(vreg, type, LFloatReg(ins->loc()))); ins->setVirtualRegister(vreg); add(lir, ins); } void LIRGenerator::visitWasmRegister64Result(MWasmRegister64Result* ins) { MOZ_ASSERT(ins->type() == MIRType::Int64); uint32_t vreg = getVirtualRegister(); #if defined(JS_NUNBOX32) auto* lir = new (alloc()) LWasmRegisterPairResult(); lir->setDef(INT64LOW_INDEX, LDefinition(vreg + INT64LOW_INDEX, LDefinition::GENERAL, LGeneralReg(ins->loc().low))); lir->setDef(INT64HIGH_INDEX, LDefinition(vreg + INT64HIGH_INDEX, LDefinition::GENERAL, LGeneralReg(ins->loc().high))); getVirtualRegister(); #elif defined(JS_PUNBOX64) auto* lir = new (alloc()) LWasmRegisterResult(); lir->setDef( 0, LDefinition(vreg, LDefinition::GENERAL, LGeneralReg(ins->loc().reg))); #else # error expected either JS_NUNBOX32 or JS_PUNBOX64 #endif ins->setVirtualRegister(vreg); add(lir, ins); } void LIRGenerator::visitWasmStackResultArea(MWasmStackResultArea* ins) { MOZ_ASSERT(ins->type() == MIRType::StackResults); auto* lir = new (alloc()) LWasmStackResultArea(temp()); uint32_t vreg = getVirtualRegister(); lir->setDef(0, LDefinition(vreg, LDefinition::STACKRESULTS, LDefinition::STACK)); ins->setVirtualRegister(vreg); add(lir, ins); } void LIRGenerator::visitWasmStackResult(MWasmStackResult* ins) { MWasmStackResultArea* area = ins->resultArea()->toWasmStackResultArea(); LDefinition::Policy pol = LDefinition::STACK; if (ins->type() == MIRType::Int64) { auto* lir = new (alloc()) LWasmStackResult64; lir->setOperand(0, use(area, LUse(LUse::STACK, /* usedAtStart = */ true))); uint32_t vreg = getVirtualRegister(); LDefinition::Type typ = LDefinition::GENERAL; #if defined(JS_NUNBOX32) getVirtualRegister(); lir->setDef(INT64LOW_INDEX, LDefinition(vreg + INT64LOW_INDEX, typ, pol)); lir->setDef(INT64HIGH_INDEX, LDefinition(vreg + INT64HIGH_INDEX, typ, pol)); #else lir->setDef(0, LDefinition(vreg, typ, pol)); #endif ins->setVirtualRegister(vreg); add(lir, ins); return; } auto* lir = new (alloc()) LWasmStackResult; lir->setOperand(0, use(area, LUse(LUse::STACK, /* usedAtStart = */ true))); uint32_t vreg = getVirtualRegister(); LDefinition::Type typ = LDefinition::TypeFrom(ins->type()); lir->setDef(0, LDefinition(vreg, typ, pol)); ins->setVirtualRegister(vreg); add(lir, ins); } template void LIRGenerator::visitWasmCall(MWasmCallT ins) { bool needsBoundsCheck = true; mozilla::Maybe tableSize; if (ins->callee().isTable()) { MDefinition* index = ins->getOperand(ins->numArgs()); if (ins->callee().which() == wasm::CalleeDesc::WasmTable) { uint32_t minLength = ins->callee().wasmTableMinLength(); mozilla::Maybe maxLength = ins->callee().wasmTableMaxLength(); if (index->isConstant() && uint32_t(index->toConstant()->toInt32()) < minLength) { needsBoundsCheck = false; } if (maxLength.isSome() && *maxLength == minLength) { tableSize = maxLength; } } } auto* lir = allocateVariadic(ins->numOperands(), needsBoundsCheck, tableSize); if (!lir) { abort(AbortReason::Alloc, "OOM: LIRGenerator::lowerWasmCall"); return; } for (unsigned i = 0; i < ins->numArgs(); i++) { lir->setOperand( i, useFixedAtStart(ins->getOperand(i), ins->registerForArg(i))); } if (ins->callee().isTable()) { MDefinition* index = ins->getOperand(ins->numArgs()); lir->setOperand(ins->numArgs(), useFixedAtStart(index, WasmTableCallIndexReg)); } if (ins->callee().isFuncRef()) { MDefinition* ref = ins->getOperand(ins->numArgs()); lir->setOperand(ins->numArgs(), useFixedAtStart(ref, WasmCallRefReg)); } add(lir, ins); assignWasmSafepoint(lir); // WasmCall with WasmTable has two call instructions, and they both need a // safepoint associated with them. Create a second safepoint here; the node // otherwise does nothing, and codegen for it only marks the safepoint at the // node. if (ins->callee().which() == wasm::CalleeDesc::WasmTable) { auto* adjunctSafepoint = new (alloc()) LWasmCallIndirectAdjunctSafepoint(); add(adjunctSafepoint); assignWasmSafepoint(adjunctSafepoint); lir->setAdjunctSafepoint(adjunctSafepoint); } } void LIRGenerator::visitWasmCallCatchable(MWasmCallCatchable* ins) { visitWasmCall(ins); } void LIRGenerator::visitWasmCallUncatchable(MWasmCallUncatchable* ins) { visitWasmCall(ins); } void LIRGenerator::visitWasmCallLandingPrePad(MWasmCallLandingPrePad* ins) { add(new (alloc()) LWasmCallLandingPrePad, ins); } void LIRGenerator::visitSetDOMProperty(MSetDOMProperty* ins) { MDefinition* val = ins->value(); Register cxReg, objReg, privReg, valueReg; GetTempRegForIntArg(0, 0, &cxReg); GetTempRegForIntArg(1, 0, &objReg); GetTempRegForIntArg(2, 0, &privReg); GetTempRegForIntArg(3, 0, &valueReg); // Keep using GetTempRegForIntArg, since we want to make sure we // don't clobber registers we're already using. Register tempReg1, tempReg2; GetTempRegForIntArg(4, 0, &tempReg1); mozilla::DebugOnly ok = GetTempRegForIntArg(5, 0, &tempReg2); MOZ_ASSERT(ok, "How can we not have six temp registers?"); LSetDOMProperty* lir = new (alloc()) LSetDOMProperty(tempFixed(cxReg), useFixedAtStart(ins->object(), objReg), useBoxFixedAtStart(val, tempReg1, tempReg2), tempFixed(privReg), tempFixed(valueReg)); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGetDOMProperty(MGetDOMProperty* ins) { Register cxReg, objReg, privReg, valueReg; GetTempRegForIntArg(0, 0, &cxReg); GetTempRegForIntArg(1, 0, &objReg); GetTempRegForIntArg(2, 0, &privReg); mozilla::DebugOnly ok = GetTempRegForIntArg(3, 0, &valueReg); MOZ_ASSERT(ok, "How can we not have four temp registers?"); LGetDOMProperty* lir = new (alloc()) LGetDOMProperty(tempFixed(cxReg), useFixedAtStart(ins->object(), objReg), tempFixed(privReg), tempFixed(valueReg)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGetDOMMember(MGetDOMMember* ins) { MOZ_ASSERT(ins->isDomMovable(), "Members had better be movable"); // We wish we could assert that ins->domAliasSet() == JSJitInfo::AliasNone, // but some MGetDOMMembers are for [Pure], not [Constant] properties, whose // value can in fact change as a result of DOM setters and method calls. MOZ_ASSERT(ins->domAliasSet() != JSJitInfo::AliasEverything, "Member gets had better not alias the world"); MDefinition* obj = ins->object(); MOZ_ASSERT(obj->type() == MIRType::Object); MIRType type = ins->type(); if (type == MIRType::Value) { LGetDOMMemberV* lir = new (alloc()) LGetDOMMemberV(useRegisterAtStart(obj)); defineBox(lir, ins); } else { LGetDOMMemberT* lir = new (alloc()) LGetDOMMemberT(useRegisterForTypedLoad(obj, type)); define(lir, ins); } } void LIRGenerator::visitLoadDOMExpandoValue(MLoadDOMExpandoValue* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); auto* lir = new (alloc()) LLoadDOMExpandoValue(useRegisterAtStart(ins->proxy())); defineBox(lir, ins); } void LIRGenerator::visitLoadDOMExpandoValueGuardGeneration( MLoadDOMExpandoValueGuardGeneration* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); auto* lir = new (alloc()) LLoadDOMExpandoValueGuardGeneration(useRegisterAtStart(ins->proxy())); assignSnapshot(lir, ins->bailoutKind()); defineBox(lir, ins); } void LIRGenerator::visitLoadDOMExpandoValueIgnoreGeneration( MLoadDOMExpandoValueIgnoreGeneration* ins) { MOZ_ASSERT(ins->proxy()->type() == MIRType::Object); auto* lir = new (alloc()) LLoadDOMExpandoValueIgnoreGeneration(useRegisterAtStart(ins->proxy())); defineBox(lir, ins); } void LIRGenerator::visitGuardDOMExpandoMissingOrGuardShape( MGuardDOMExpandoMissingOrGuardShape* ins) { MOZ_ASSERT(ins->expando()->type() == MIRType::Value); auto* lir = new (alloc()) LGuardDOMExpandoMissingOrGuardShape(useBox(ins->expando()), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->expando()); } void LIRGenerator::visitIncrementWarmUpCounter(MIncrementWarmUpCounter* ins) { LIncrementWarmUpCounter* lir = new (alloc()) LIncrementWarmUpCounter(temp()); add(lir, ins); } void LIRGenerator::visitLexicalCheck(MLexicalCheck* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Value); LLexicalCheck* lir = new (alloc()) LLexicalCheck(useBox(input)); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, input); } void LIRGenerator::visitThrowRuntimeLexicalError( MThrowRuntimeLexicalError* ins) { LThrowRuntimeLexicalError* lir = new (alloc()) LThrowRuntimeLexicalError(); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitThrowMsg(MThrowMsg* ins) { LThrowMsg* lir = new (alloc()) LThrowMsg(); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGlobalDeclInstantiation(MGlobalDeclInstantiation* ins) { LGlobalDeclInstantiation* lir = new (alloc()) LGlobalDeclInstantiation(); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitDebugger(MDebugger* ins) { auto* lir = new (alloc()) LDebugger(tempFixed(CallTempReg0)); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); } void LIRGenerator::visitAtomicIsLockFree(MAtomicIsLockFree* ins) { define(new (alloc()) LAtomicIsLockFree(useRegister(ins->input())), ins); } void LIRGenerator::visitCheckReturn(MCheckReturn* ins) { MDefinition* retVal = ins->returnValue(); MDefinition* thisVal = ins->thisValue(); MOZ_ASSERT(retVal->type() == MIRType::Value); MOZ_ASSERT(thisVal->type() == MIRType::Value); auto* lir = new (alloc()) LCheckReturn(useBoxAtStart(retVal), useBoxAtStart(thisVal)); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCheckIsObj(MCheckIsObj* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Value); LCheckIsObj* lir = new (alloc()) LCheckIsObj(useBox(input)); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCheckObjCoercible(MCheckObjCoercible* ins) { MDefinition* checkVal = ins->checkValue(); MOZ_ASSERT(checkVal->type() == MIRType::Value); auto* lir = new (alloc()) LCheckObjCoercible(useBoxAtStart(checkVal)); redefine(ins, checkVal); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCheckClassHeritage(MCheckClassHeritage* ins) { MDefinition* heritage = ins->heritage(); MOZ_ASSERT(heritage->type() == MIRType::Value); auto* lir = new (alloc()) LCheckClassHeritage(useBox(heritage), temp(), temp()); redefine(ins, heritage); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCheckThis(MCheckThis* ins) { MDefinition* thisValue = ins->thisValue(); MOZ_ASSERT(thisValue->type() == MIRType::Value); auto* lir = new (alloc()) LCheckThis(useBoxAtStart(thisValue)); redefine(ins, thisValue); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCheckThisReinit(MCheckThisReinit* ins) { MDefinition* thisValue = ins->thisValue(); MOZ_ASSERT(thisValue->type() == MIRType::Value); auto* lir = new (alloc()) LCheckThisReinit(useBoxAtStart(thisValue)); redefine(ins, thisValue); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGenerator(MGenerator* ins) { auto* lir = new (alloc()) LGenerator(useRegisterAtStart(ins->callee()), useRegisterAtStart(ins->environmentChain()), useRegisterAtStart(ins->argsObject())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitAsyncResolve(MAsyncResolve* ins) { auto* lir = new (alloc()) LAsyncResolve(useRegisterAtStart(ins->generator()), useBoxAtStart(ins->valueOrReason())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitAsyncAwait(MAsyncAwait* ins) { MOZ_ASSERT(ins->generator()->type() == MIRType::Object); auto* lir = new (alloc()) LAsyncAwait(useBoxAtStart(ins->value()), useRegisterAtStart(ins->generator())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCanSkipAwait(MCanSkipAwait* ins) { auto* lir = new (alloc()) LCanSkipAwait(useBoxAtStart(ins->value())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitMaybeExtractAwaitValue(MMaybeExtractAwaitValue* ins) { auto* lir = new (alloc()) LMaybeExtractAwaitValue( useBoxAtStart(ins->value()), useRegisterAtStart(ins->canSkip())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitDebugCheckSelfHosted(MDebugCheckSelfHosted* ins) { MDefinition* checkVal = ins->checkValue(); MOZ_ASSERT(checkVal->type() == MIRType::Value); LDebugCheckSelfHosted* lir = new (alloc()) LDebugCheckSelfHosted(useBoxAtStart(checkVal)); redefine(ins, checkVal); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitFinishBoundFunctionInit(MFinishBoundFunctionInit* ins) { auto lir = new (alloc()) LFinishBoundFunctionInit( useRegister(ins->bound()), useRegister(ins->target()), useRegister(ins->argCount()), temp(), temp()); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitIsPackedArray(MIsPackedArray* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Boolean); auto lir = new (alloc()) LIsPackedArray(useRegister(ins->object()), temp()); define(lir, ins); } void LIRGenerator::visitGuardArrayIsPacked(MGuardArrayIsPacked* ins) { MOZ_ASSERT(ins->array()->type() == MIRType::Object); auto* lir = new (alloc()) LGuardArrayIsPacked(useRegister(ins->array()), temp(), temp()); assignSnapshot(lir, ins->bailoutKind()); add(lir, ins); redefine(ins, ins->array()); } void LIRGenerator::visitGetPrototypeOf(MGetPrototypeOf* ins) { MOZ_ASSERT(ins->target()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Value); auto lir = new (alloc()) LGetPrototypeOf(useRegister(ins->target())); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitObjectWithProto(MObjectWithProto* ins) { MOZ_ASSERT(ins->prototype()->type() == MIRType::Value); MOZ_ASSERT(ins->type() == MIRType::Object); auto* lir = new (alloc()) LObjectWithProto(useBoxAtStart(ins->prototype())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitObjectStaticProto(MObjectStaticProto* ins) { MOZ_ASSERT(ins->object()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Object); auto* lir = new (alloc()) LObjectStaticProto(useRegisterAtStart(ins->object())); define(lir, ins); }; void LIRGenerator::visitBuiltinObject(MBuiltinObject* ins) { MOZ_ASSERT(ins->type() == MIRType::Object); auto* lir = new (alloc()) LBuiltinObject(); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitReturn(MReturn* ret) { return visitReturnImpl(ret->getOperand(0)); } void LIRGenerator::visitGeneratorReturn(MGeneratorReturn* ret) { return visitReturnImpl(ret->getOperand(0), true); } void LIRGenerator::visitSuperFunction(MSuperFunction* ins) { MOZ_ASSERT(ins->callee()->type() == MIRType::Object); MOZ_ASSERT(ins->type() == MIRType::Value); auto* lir = new (alloc()) LSuperFunction(useRegister(ins->callee()), temp()); defineBox(lir, ins); } void LIRGenerator::visitInitHomeObject(MInitHomeObject* ins) { MDefinition* function = ins->function(); MOZ_ASSERT(function->type() == MIRType::Object); MDefinition* homeObject = ins->homeObject(); MOZ_ASSERT(homeObject->type() == MIRType::Value); MOZ_ASSERT(ins->type() == MIRType::Object); auto* lir = new (alloc()) LInitHomeObject(useRegisterAtStart(function), useBoxAtStart(homeObject)); redefine(ins, function); add(lir, ins); } void LIRGenerator::visitIsTypedArrayConstructor(MIsTypedArrayConstructor* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); auto* lir = new (alloc()) LIsTypedArrayConstructor(useRegister(object)); define(lir, ins); } void LIRGenerator::visitLoadValueTag(MLoadValueTag* ins) { MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Value); define(new (alloc()) LLoadValueTag(useBoxAtStart(value)), ins); } void LIRGenerator::visitGuardTagNotEqual(MGuardTagNotEqual* ins) { MDefinition* lhs = ins->lhs(); MOZ_ASSERT(lhs->type() == MIRType::Int32); MDefinition* rhs = ins->rhs(); MOZ_ASSERT(rhs->type() == MIRType::Int32); auto* guard = new (alloc()) LGuardTagNotEqual(useRegister(lhs), useRegister(rhs)); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); } void LIRGenerator::visitLoadWrapperTarget(MLoadWrapperTarget* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); define(new (alloc()) LLoadWrapperTarget(useRegisterAtStart(object)), ins); } void LIRGenerator::visitGuardHasGetterSetter(MGuardHasGetterSetter* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); auto* guard = new (alloc()) LGuardHasGetterSetter(useRegisterAtStart(object), tempFixed(CallTempReg0), tempFixed(CallTempReg1), tempFixed(CallTempReg2)); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, object); } void LIRGenerator::visitGuardIsExtensible(MGuardIsExtensible* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); auto* guard = new (alloc()) LGuardIsExtensible(useRegister(object), temp()); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, object); } void LIRGenerator::visitGuardInt32IsNonNegative(MGuardInt32IsNonNegative* ins) { MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* guard = new (alloc()) LGuardInt32IsNonNegative(useRegister(index)); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, index); } void LIRGenerator::visitGuardInt32Range(MGuardInt32Range* ins) { MDefinition* input = ins->input(); MOZ_ASSERT(input->type() == MIRType::Int32); auto* guard = new (alloc()) LGuardInt32Range(useRegister(input)); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, input); } void LIRGenerator::visitGuardIndexIsNotDenseElement( MGuardIndexIsNotDenseElement* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); LDefinition spectreTemp = BoundsCheckNeedsSpectreTemp() ? temp() : LDefinition::BogusTemp(); auto* guard = new (alloc()) LGuardIndexIsNotDenseElement( useRegister(object), useRegister(index), temp(), spectreTemp); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, index); } void LIRGenerator::visitGuardIndexIsValidUpdateOrAdd( MGuardIndexIsValidUpdateOrAdd* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); LDefinition spectreTemp = BoundsCheckNeedsSpectreTemp() ? temp() : LDefinition::BogusTemp(); auto* guard = new (alloc()) LGuardIndexIsValidUpdateOrAdd( useRegister(object), useRegister(index), temp(), spectreTemp); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, index); } void LIRGenerator::visitCallAddOrUpdateSparseElement( MCallAddOrUpdateSparseElement* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); MDefinition* value = ins->value(); MOZ_ASSERT(value->type() == MIRType::Value); auto* lir = new (alloc()) LCallAddOrUpdateSparseElement( useRegisterAtStart(object), useRegisterAtStart(index), useBoxAtStart(value)); add(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallGetSparseElement(MCallGetSparseElement* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LCallGetSparseElement(useRegisterAtStart(object), useRegisterAtStart(index)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallNativeGetElement(MCallNativeGetElement* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LCallNativeGetElement(useRegisterAtStart(object), useRegisterAtStart(index)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallNativeGetElementSuper( MCallNativeGetElementSuper* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); MDefinition* receiver = ins->receiver(); auto* lir = new (alloc()) LCallNativeGetElementSuper( useRegisterAtStart(object), useRegisterAtStart(index), useBoxAtStart(receiver)); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitCallObjectHasSparseElement( MCallObjectHasSparseElement* ins) { MDefinition* object = ins->object(); MOZ_ASSERT(object->type() == MIRType::Object); MDefinition* index = ins->index(); MOZ_ASSERT(index->type() == MIRType::Int32); auto* lir = new (alloc()) LCallObjectHasSparseElement( useRegisterAtStart(object), useRegisterAtStart(index), tempFixed(CallTempReg0), tempFixed(CallTempReg1)); assignSnapshot(lir, ins->bailoutKind()); defineReturn(lir, ins); } void LIRGenerator::visitBigIntAsIntN(MBigIntAsIntN* ins) { MOZ_ASSERT(ins->bits()->type() == MIRType::Int32); MOZ_ASSERT(ins->input()->type() == MIRType::BigInt); if (ins->bits()->isConstant()) { int32_t bits = ins->bits()->toConstant()->toInt32(); if (bits == 64) { auto* lir = new (alloc()) LBigIntAsIntN64(useRegister(ins->input()), temp(), tempInt64()); define(lir, ins); assignSafepoint(lir, ins); return; } if (bits == 32) { auto* lir = new (alloc()) LBigIntAsIntN32(useRegister(ins->input()), temp(), tempInt64()); define(lir, ins); assignSafepoint(lir, ins); return; } } auto* lir = new (alloc()) LBigIntAsIntN(useRegisterAtStart(ins->bits()), useRegisterAtStart(ins->input())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitBigIntAsUintN(MBigIntAsUintN* ins) { MOZ_ASSERT(ins->bits()->type() == MIRType::Int32); MOZ_ASSERT(ins->input()->type() == MIRType::BigInt); if (ins->bits()->isConstant()) { int32_t bits = ins->bits()->toConstant()->toInt32(); if (bits == 64) { auto* lir = new (alloc()) LBigIntAsUintN64(useRegister(ins->input()), temp(), tempInt64()); define(lir, ins); assignSafepoint(lir, ins); return; } if (bits == 32) { auto* lir = new (alloc()) LBigIntAsUintN32(useRegister(ins->input()), temp(), tempInt64()); define(lir, ins); assignSafepoint(lir, ins); return; } } auto* lir = new (alloc()) LBigIntAsUintN(useRegisterAtStart(ins->bits()), useRegisterAtStart(ins->input())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitGuardNonGCThing(MGuardNonGCThing* ins) { MDefinition* input = ins->input(); auto* guard = new (alloc()) LGuardNonGCThing(useBox(input)); assignSnapshot(guard, ins->bailoutKind()); add(guard, ins); redefine(ins, input); } void LIRGenerator::visitToHashableNonGCThing(MToHashableNonGCThing* ins) { auto* lir = new (alloc()) LToHashableNonGCThing(useBox(ins->input()), tempDouble()); defineBox(lir, ins); } void LIRGenerator::visitToHashableString(MToHashableString* ins) { auto* lir = new (alloc()) LToHashableString(useRegister(ins->input())); define(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitToHashableValue(MToHashableValue* ins) { auto* lir = new (alloc()) LToHashableValue(useBox(ins->input()), tempDouble()); defineBox(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitHashNonGCThing(MHashNonGCThing* ins) { auto* lir = new (alloc()) LHashNonGCThing(useBox(ins->input()), temp()); define(lir, ins); } void LIRGenerator::visitHashString(MHashString* ins) { auto* lir = new (alloc()) LHashString(useRegister(ins->input()), temp()); define(lir, ins); } void LIRGenerator::visitHashSymbol(MHashSymbol* ins) { auto* lir = new (alloc()) LHashSymbol(useRegister(ins->input())); define(lir, ins); } void LIRGenerator::visitHashBigInt(MHashBigInt* ins) { auto* lir = new (alloc()) LHashBigInt(useRegister(ins->input()), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitHashObject(MHashObject* ins) { auto* lir = new (alloc()) LHashObject(useRegister(ins->set()), useBox(ins->input()), temp(), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitHashValue(MHashValue* ins) { auto* lir = new (alloc()) LHashValue(useRegister(ins->set()), useBox(ins->input()), temp(), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitSetObjectHasNonBigInt(MSetObjectHasNonBigInt* ins) { auto* lir = new (alloc()) LSetObjectHasNonBigInt(useRegister(ins->set()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp()); define(lir, ins); } void LIRGenerator::visitSetObjectHasBigInt(MSetObjectHasBigInt* ins) { auto* lir = new (alloc()) LSetObjectHasBigInt( useRegister(ins->set()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitSetObjectHasValue(MSetObjectHasValue* ins) { auto* lir = new (alloc()) LSetObjectHasValue( useRegister(ins->set()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitSetObjectHasValueVMCall(MSetObjectHasValueVMCall* ins) { auto* lir = new (alloc()) LSetObjectHasValueVMCall( useRegisterAtStart(ins->set()), useBoxAtStart(ins->value())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitSetObjectSize(MSetObjectSize* ins) { auto* lir = new (alloc()) LSetObjectSize(useRegisterAtStart(ins->set())); define(lir, ins); } void LIRGenerator::visitMapObjectHasNonBigInt(MMapObjectHasNonBigInt* ins) { auto* lir = new (alloc()) LMapObjectHasNonBigInt(useRegister(ins->map()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp()); define(lir, ins); } void LIRGenerator::visitMapObjectHasBigInt(MMapObjectHasBigInt* ins) { auto* lir = new (alloc()) LMapObjectHasBigInt( useRegister(ins->map()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitMapObjectHasValue(MMapObjectHasValue* ins) { auto* lir = new (alloc()) LMapObjectHasValue( useRegister(ins->map()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp(), temp(), temp()); define(lir, ins); } void LIRGenerator::visitMapObjectHasValueVMCall(MMapObjectHasValueVMCall* ins) { auto* lir = new (alloc()) LMapObjectHasValueVMCall( useRegisterAtStart(ins->map()), useBoxAtStart(ins->value())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitMapObjectGetNonBigInt(MMapObjectGetNonBigInt* ins) { auto* lir = new (alloc()) LMapObjectGetNonBigInt(useRegister(ins->map()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp()); defineBox(lir, ins); } void LIRGenerator::visitMapObjectGetBigInt(MMapObjectGetBigInt* ins) { auto* lir = new (alloc()) LMapObjectGetBigInt( useRegister(ins->map()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp(), temp(), temp()); defineBox(lir, ins); } void LIRGenerator::visitMapObjectGetValue(MMapObjectGetValue* ins) { auto* lir = new (alloc()) LMapObjectGetValue( useRegister(ins->map()), useBox(ins->value()), useRegister(ins->hash()), temp(), temp(), temp(), temp()); defineBox(lir, ins); } void LIRGenerator::visitMapObjectGetValueVMCall(MMapObjectGetValueVMCall* ins) { auto* lir = new (alloc()) LMapObjectGetValueVMCall( useRegisterAtStart(ins->map()), useBoxAtStart(ins->value())); defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitMapObjectSize(MMapObjectSize* ins) { auto* lir = new (alloc()) LMapObjectSize(useRegisterAtStart(ins->map())); define(lir, ins); } void LIRGenerator::visitConstant(MConstant* ins) { if (!IsFloatingPointType(ins->type()) && ins->canEmitAtUses()) { emitAtUses(ins); return; } switch (ins->type()) { case MIRType::Double: define(new (alloc()) LDouble(ins->toDouble()), ins); break; case MIRType::Float32: define(new (alloc()) LFloat32(ins->toFloat32()), ins); break; case MIRType::Boolean: define(new (alloc()) LInteger(ins->toBoolean()), ins); break; case MIRType::Int32: define(new (alloc()) LInteger(ins->toInt32()), ins); break; case MIRType::Int64: defineInt64(new (alloc()) LInteger64(ins->toInt64()), ins); break; case MIRType::IntPtr: #ifdef JS_64BIT defineInt64(new (alloc()) LInteger64(ins->toIntPtr()), ins); #else define(new (alloc()) LInteger(ins->toIntPtr()), ins); #endif break; case MIRType::String: define(new (alloc()) LPointer(ins->toString()), ins); break; case MIRType::Symbol: define(new (alloc()) LPointer(ins->toSymbol()), ins); break; case MIRType::BigInt: define(new (alloc()) LPointer(ins->toBigInt()), ins); break; case MIRType::Object: define(new (alloc()) LPointer(&ins->toObject()), ins); break; case MIRType::Shape: MOZ_ASSERT(ins->isEmittedAtUses()); break; default: // Constants of special types (undefined, null) should never flow into // here directly. Operations blindly consuming them require a Box. MOZ_CRASH("unexpected constant type"); } } void LIRGenerator::visitConstantProto(MConstantProto* ins) { JSObject* obj = &ins->protoObject()->toConstant()->toObject(); define(new (alloc()) LPointer(obj), ins); } void LIRGenerator::visitWasmNullConstant(MWasmNullConstant* ins) { define(new (alloc()) LWasmNullConstant(), ins); } void LIRGenerator::visitWasmFloatConstant(MWasmFloatConstant* ins) { switch (ins->type()) { case MIRType::Double: define(new (alloc()) LDouble(ins->toDouble()), ins); break; case MIRType::Float32: define(new (alloc()) LFloat32(ins->toFloat32()), ins); break; #ifdef ENABLE_WASM_SIMD case MIRType::Simd128: define(new (alloc()) LSimd128(ins->toSimd128()), ins); break; #endif default: MOZ_CRASH("unexpected constant type"); } } #ifdef JS_JITSPEW static void SpewResumePoint(MBasicBlock* block, MInstruction* ins, MResumePoint* resumePoint) { Fprinter& out = JitSpewPrinter(); out.printf("Current resume point %p details:\n", (void*)resumePoint); out.printf(" frame count: %u\n", resumePoint->frameCount()); if (ins) { out.printf(" taken after: "); ins->printName(out); } else { out.printf(" taken at block %u entry", block->id()); } out.printf("\n"); out.printf(" pc: %p (script: %p, offset: %d)\n", (void*)resumePoint->pc(), (void*)resumePoint->block()->info().script(), int(resumePoint->block()->info().script()->pcToOffset( resumePoint->pc()))); for (size_t i = 0, e = resumePoint->numOperands(); i < e; i++) { MDefinition* in = resumePoint->getOperand(i); out.printf(" slot%u: ", (unsigned)i); in->printName(out); out.printf("\n"); } } #endif void LIRGenerator::visitInstructionDispatch(MInstruction* ins) { #ifdef JS_CODEGEN_NONE // Don't compile the switch-statement below so that we don't have to define // the platform-specific visit* methods for the none-backend. MOZ_CRASH(); #else switch (ins->op()) { # define MIR_OP(op) \ case MDefinition::Opcode::op: \ visit##op(ins->to##op()); \ break; MIR_OPCODE_LIST(MIR_OP) # undef MIR_OP default: MOZ_CRASH("Invalid instruction"); } #endif } void LIRGeneratorShared::visitEmittedAtUses(MInstruction* ins) { static_cast(this)->visitInstructionDispatch(ins); } bool LIRGenerator::visitInstruction(MInstruction* ins) { MOZ_ASSERT(!errored()); if (ins->isRecoveredOnBailout()) { MOZ_ASSERT(!JitOptions.disableRecoverIns); return true; } if (!gen->ensureBallast()) { return false; } visitInstructionDispatch(ins); if (ins->resumePoint()) { updateResumeState(ins); } #ifdef DEBUG ins->setInWorklistUnchecked(); #endif // If no safepoint was created, there's no need for an OSI point. if (LOsiPoint* osiPoint = popOsiPoint()) { add(osiPoint); } return !errored(); } void LIRGenerator::definePhis() { size_t lirIndex = 0; MBasicBlock* block = current->mir(); for (MPhiIterator phi(block->phisBegin()); phi != block->phisEnd(); phi++) { if (phi->type() == MIRType::Value) { defineUntypedPhi(*phi, lirIndex); lirIndex += BOX_PIECES; } else if (phi->type() == MIRType::Int64) { defineInt64Phi(*phi, lirIndex); lirIndex += INT64_PIECES; } else { defineTypedPhi(*phi, lirIndex); lirIndex += 1; } } } void LIRGenerator::updateResumeState(MInstruction* ins) { lastResumePoint_ = ins->resumePoint(); #ifdef JS_JITSPEW if (JitSpewEnabled(JitSpew_IonSnapshots) && lastResumePoint_) { SpewResumePoint(nullptr, ins, lastResumePoint_); } #endif } void LIRGenerator::updateResumeState(MBasicBlock* block) { // Note: RangeAnalysis can flag blocks as unreachable, but they are only // removed iff GVN (including UCE) is enabled. MOZ_ASSERT_IF(!mir()->compilingWasm() && !block->unreachable(), block->entryResumePoint()); MOZ_ASSERT_IF(block->unreachable(), !mir()->optimizationInfo().gvnEnabled()); lastResumePoint_ = block->entryResumePoint(); #ifdef JS_JITSPEW if (JitSpewEnabled(JitSpew_IonSnapshots) && lastResumePoint_) { SpewResumePoint(block, nullptr, lastResumePoint_); } #endif } bool LIRGenerator::visitBlock(MBasicBlock* block) { current = block->lir(); updateResumeState(block); definePhis(); MOZ_ASSERT_IF(block->unreachable(), !mir()->optimizationInfo().gvnEnabled()); for (MInstructionIterator iter = block->begin(); *iter != block->lastIns(); iter++) { if (!visitInstruction(*iter)) { return false; } } if (block->successorWithPhis()) { // If we have a successor with phis, lower the phi input now that we // are approaching the join point. MBasicBlock* successor = block->successorWithPhis(); uint32_t position = block->positionInPhiSuccessor(); size_t lirIndex = 0; for (MPhiIterator phi(successor->phisBegin()); phi != successor->phisEnd(); phi++) { if (!gen->ensureBallast()) { return false; } MDefinition* opd = phi->getOperand(position); ensureDefined(opd); MOZ_ASSERT(opd->type() == phi->type()); if (phi->type() == MIRType::Value) { lowerUntypedPhiInput(*phi, position, successor->lir(), lirIndex); lirIndex += BOX_PIECES; } else if (phi->type() == MIRType::Int64) { lowerInt64PhiInput(*phi, position, successor->lir(), lirIndex); lirIndex += INT64_PIECES; } else { lowerTypedPhiInput(*phi, position, successor->lir(), lirIndex); lirIndex += 1; } } } // Now emit the last instruction, which is some form of branch. if (!visitInstruction(block->lastIns())) { return false; } return true; } void LIRGenerator::visitNaNToZero(MNaNToZero* ins) { MDefinition* input = ins->input(); if (ins->operandIsNeverNaN() && ins->operandIsNeverNegativeZero()) { redefine(ins, input); return; } LNaNToZero* lir = new (alloc()) LNaNToZero(useRegisterAtStart(input), tempDouble()); defineReuseInput(lir, ins, 0); } bool LIRGenerator::generate() { // Create all blocks and prep all phis beforehand. for (ReversePostorderIterator block(graph.rpoBegin()); block != graph.rpoEnd(); block++) { if (gen->shouldCancel("Lowering (preparation loop)")) { return false; } if (!lirGraph_.initBlock(*block)) { return false; } } for (ReversePostorderIterator block(graph.rpoBegin()); block != graph.rpoEnd(); block++) { if (gen->shouldCancel("Lowering (main loop)")) { return false; } if (!visitBlock(*block)) { return false; } } lirGraph_.setArgumentSlotCount(maxargslots_); return true; } void LIRGenerator::visitPhi(MPhi* phi) { // Phi nodes are not lowered because they are only meaningful for the register // allocator. MOZ_CRASH("Unexpected Phi node during Lowering."); } void LIRGenerator::visitBeta(MBeta* beta) { // Beta nodes are supposed to be removed before because they are // only used to carry the range information for Range analysis MOZ_CRASH("Unexpected Beta node during Lowering."); } void LIRGenerator::visitObjectState(MObjectState* objState) { // ObjectState nodes are always recovered on bailouts MOZ_CRASH("Unexpected ObjectState node during Lowering."); } void LIRGenerator::visitArrayState(MArrayState* objState) { // ArrayState nodes are always recovered on bailouts MOZ_CRASH("Unexpected ArrayState node during Lowering."); } void LIRGenerator::visitIonToWasmCall(MIonToWasmCall* ins) { // The instruction needs a temp register: // - that's not the FramePointer, since wasm is going to use it in the // function. // - that's not aliasing an input register. LDefinition scratch = tempFixed(ABINonArgReg0); // Note that since this is a LIR call instruction, regalloc will prevent // the use*AtStart below from reusing any of the temporaries. LInstruction* lir; if (ins->type() == MIRType::Value) { lir = allocateVariadic(ins->numOperands(), scratch); } else if (ins->type() == MIRType::Int64) { lir = allocateVariadic(ins->numOperands(), scratch); } else { lir = allocateVariadic(ins->numOperands(), scratch); } if (!lir) { abort(AbortReason::Alloc, "OOM: LIRGenerator::visitIonToWasmCall"); return; } ABIArgGenerator abi; for (unsigned i = 0; i < ins->numOperands(); i++) { MDefinition* argDef = ins->getOperand(i); ABIArg arg = abi.next(ToMIRType(argDef->type())); switch (arg.kind()) { case ABIArg::GPR: case ABIArg::FPU: lir->setOperand(i, useFixedAtStart(argDef, arg.reg())); break; case ABIArg::Stack: lir->setOperand(i, useAtStart(argDef)); break; #ifdef JS_CODEGEN_REGISTER_PAIR case ABIArg::GPR_PAIR: MOZ_CRASH( "no way to pass i64, and wasm uses hardfp for function calls"); #endif case ABIArg::Uninitialized: MOZ_CRASH("Uninitialized ABIArg kind"); } } defineReturn(lir, ins); assignSafepoint(lir, ins); } void LIRGenerator::visitWasmSelect(MWasmSelect* ins) { MDefinition* condExpr = ins->condExpr(); // Pick off specific cases that we can do with LWasmCompareAndSelect to avoid // generating a boolean that we then have to test again. if (condExpr->isCompare() && condExpr->isEmittedAtUses()) { MCompare* comp = condExpr->toCompare(); MCompare::CompareType compTy = comp->compareType(); if (canSpecializeWasmCompareAndSelect(compTy, ins->type())) { JSOp jsop = comp->jsop(); // We don't currently generate any other JSOPs for the comparison, and if // that changes, we want to know about it. Hence this assertion. MOZ_ASSERT(jsop == JSOp::Eq || jsop == JSOp::Ne || jsop == JSOp::Lt || jsop == JSOp::Gt || jsop == JSOp::Le || jsop == JSOp::Ge); MDefinition* lhs = comp->lhs(); MDefinition* rhs = comp->rhs(); jsop = ReorderComparison(jsop, &lhs, &rhs); lowerWasmCompareAndSelect(ins, lhs, rhs, compTy, jsop); return; } } // Fall through to code that generates a boolean and selects on that. if (ins->type() == MIRType::Int64) { lowerWasmSelectI64(ins); return; } lowerWasmSelectI(ins); } void LIRGenerator::visitWasmFence(MWasmFence* ins) { add(new (alloc()) LWasmFence, ins); } void LIRGenerator::visitWasmLoadField(MWasmLoadField* ins) { size_t offs = ins->offset(); LAllocation obj = useRegister(ins->obj()); MWideningOp wideningOp = ins->wideningOp(); if (ins->type() == MIRType::Int64) { MOZ_RELEASE_ASSERT(wideningOp == MWideningOp::None); defineInt64(new (alloc()) LWasmLoadSlotI64(obj, offs, ins->maybeTrap()), ins); } else { define(new (alloc()) LWasmLoadSlot(obj, offs, ins->type(), wideningOp, ins->maybeTrap()), ins); } } void LIRGenerator::visitWasmLoadFieldKA(MWasmLoadFieldKA* ins) { size_t offs = ins->offset(); LAllocation obj = useRegister(ins->obj()); MWideningOp wideningOp = ins->wideningOp(); if (ins->type() == MIRType::Int64) { MOZ_RELEASE_ASSERT(wideningOp == MWideningOp::None); defineInt64(new (alloc()) LWasmLoadSlotI64(obj, offs, ins->maybeTrap()), ins); } else { define(new (alloc()) LWasmLoadSlot(obj, offs, ins->type(), wideningOp, ins->maybeTrap()), ins); } add(new (alloc()) LKeepAliveObject(useKeepalive(ins->ka())), ins); } void LIRGenerator::visitWasmStoreFieldKA(MWasmStoreFieldKA* ins) { MDefinition* value = ins->value(); size_t offs = ins->offset(); MNarrowingOp narrowingOp = ins->narrowingOp(); LAllocation obj = useRegister(ins->obj()); LInstruction* lir; if (value->type() == MIRType::Int64) { MOZ_RELEASE_ASSERT(narrowingOp == MNarrowingOp::None); lir = new (alloc()) LWasmStoreSlotI64(useInt64Register(value), obj, offs, ins->maybeTrap()); } else { lir = new (alloc()) LWasmStoreSlot(useRegister(value), obj, offs, value->type(), narrowingOp, ins->maybeTrap()); } add(lir, ins); add(new (alloc()) LKeepAliveObject(useKeepalive(ins->ka())), ins); } void LIRGenerator::visitWasmStoreFieldRefKA(MWasmStoreFieldRefKA* ins) { LAllocation instance = useRegister(ins->instance()); LAllocation valueAddr = useFixed(ins->valueAddr(), PreBarrierReg); LAllocation value = useRegister(ins->value()); add(new (alloc()) LWasmStoreRef(instance, valueAddr, value, temp()), ins); add(new (alloc()) LKeepAliveObject(useKeepalive(ins->ka())), ins); } void LIRGenerator::visitWasmGcObjectIsSubtypeOf(MWasmGcObjectIsSubtypeOf* ins) { if (CanEmitAtUseForSingleTest(ins)) { emitAtUses(ins); return; } LAllocation object = useRegister(ins->object()); LAllocation superTypeDef = useRegister(ins->superTypeDef()); uint32_t subTypingDepth = ins->subTypingDepth(); LDefinition subTypeDepth = temp(); LDefinition scratch = subTypingDepth >= wasm::MinSuperTypeVectorLength ? temp() : LDefinition(); define(new (alloc()) LWasmGcObjectIsSubtypeOf(object, superTypeDef, subTypeDepth, scratch), ins); } #ifdef FUZZING_JS_FUZZILLI void LIRGenerator::visitFuzzilliHash(MFuzzilliHash* ins) { MDefinition* value = ins->getOperand(0); if (value->type() == MIRType::Undefined || value->type() == MIRType::Null) { define(new (alloc()) LFuzzilliHashT(LAllocation(), temp(), tempDouble()), ins); } else if (value->type() == MIRType::Int32 || value->type() == MIRType::Double || value->type() == MIRType::Float32 || value->type() == MIRType::Boolean || value->type() == MIRType::BigInt) { define(new (alloc()) LFuzzilliHashT(useRegister(value), temp(), tempDouble()), ins); } else if (value->type() == MIRType::Object) { LFuzzilliHashT* lir = new (alloc()) LFuzzilliHashT(useRegister(value), temp(), tempDouble()); define(lir, ins); assignSafepoint(lir, ins); } else if (value->type() == MIRType::Value) { LFuzzilliHashV* lir = new (alloc()) LFuzzilliHashV(useBox(value), temp(), tempDouble()); define(lir, ins); assignSafepoint(lir, ins); } else { define(new (alloc()) LInteger(0), ins); } } void LIRGenerator::visitFuzzilliHashStore(MFuzzilliHashStore* ins) { MDefinition* value = ins->getOperand(0); MOZ_ASSERT(value->type() == MIRType::Int32); add(new (alloc()) LFuzzilliHashStore(useRegister(value), temp(), temp()), ins); } #endif static_assert(!std::is_polymorphic_v, "LIRGenerator should not have any virtual methods"); #ifdef JS_CODEGEN_NONE void LIRGenerator::visitReturnImpl(MDefinition*, bool) { MOZ_CRASH(); } #endif