/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set ts=8 sts=4 et sw=4 tw=99: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifndef jit_IonBuilder_h #define jit_IonBuilder_h // This file declares the data structures for building a MIRGraph from a // JSScript. #include "mozilla/LinkedList.h" #include "jit/BaselineInspector.h" #include "jit/BytecodeAnalysis.h" #include "jit/IonAnalysis.h" #include "jit/IonOptimizationLevels.h" #include "jit/MIR.h" #include "jit/MIRGenerator.h" #include "jit/MIRGraph.h" #include "jit/OptimizationTracking.h" namespace js { namespace jit { class CodeGenerator; class CallInfo; class BaselineFrameInspector; enum class InlinableNative : uint16_t; // Records information about a baseline frame for compilation that is stable // when later used off thread. BaselineFrameInspector* NewBaselineFrameInspector(TempAllocator* temp, BaselineFrame* frame, CompileInfo* info); class IonBuilder : public MIRGenerator, public mozilla::LinkedListElement { enum ControlStatus { ControlStatus_Error, ControlStatus_Abort, ControlStatus_Ended, // There is no continuation/join point. ControlStatus_Joined, // Created a join node. ControlStatus_Jumped, // Parsing another branch at the same level. ControlStatus_None // No control flow. }; struct DeferredEdge : public TempObject { MBasicBlock* block; DeferredEdge* next; DeferredEdge(MBasicBlock* block, DeferredEdge* next) : block(block), next(next) { } }; struct ControlFlowInfo { // Entry in the cfgStack. uint32_t cfgEntry; // Label that continues go to. jsbytecode* continuepc; ControlFlowInfo(uint32_t cfgEntry, jsbytecode* continuepc) : cfgEntry(cfgEntry), continuepc(continuepc) { } }; // To avoid recursion, the bytecode analyzer uses a stack where each entry // is a small state machine. As we encounter branches or jumps in the // bytecode, we push information about the edges on the stack so that the // CFG can be built in a tree-like fashion. struct CFGState { enum State { IF_TRUE, // if() { }, no else. IF_TRUE_EMPTY_ELSE, // if() { }, empty else IF_ELSE_TRUE, // if() { X } else { } IF_ELSE_FALSE, // if() { } else { X } DO_WHILE_LOOP_BODY, // do { x } while () DO_WHILE_LOOP_COND, // do { } while (x) WHILE_LOOP_COND, // while (x) { } WHILE_LOOP_BODY, // while () { x } FOR_LOOP_COND, // for (; x;) { } FOR_LOOP_BODY, // for (; ;) { x } FOR_LOOP_UPDATE, // for (; ; x) { } TABLE_SWITCH, // switch() { x } COND_SWITCH_CASE, // switch() { case X: ... } COND_SWITCH_BODY, // switch() { case ...: X } AND_OR, // && x, || x LABEL, // label: x TRY // try { x } catch(e) { } }; State state; // Current state of this control structure. jsbytecode* stopAt; // Bytecode at which to stop the processing loop. // For if structures, this contains branch information. union { struct { MBasicBlock* ifFalse; jsbytecode* falseEnd; MBasicBlock* ifTrue; // Set when the end of the true path is reached. MTest* test; } branch; struct { // Common entry point. MBasicBlock* entry; // Whether OSR is being performed for this loop. bool osr; // Position of where the loop body starts and ends. jsbytecode* bodyStart; jsbytecode* bodyEnd; // pc immediately after the loop exits. jsbytecode* exitpc; // pc for 'continue' jumps. jsbytecode* continuepc; // Common exit point. Created lazily, so it may be nullptr. MBasicBlock* successor; // Deferred break and continue targets. DeferredEdge* breaks; DeferredEdge* continues; // Initial state, in case loop processing is restarted. State initialState; jsbytecode* initialPc; jsbytecode* initialStopAt; jsbytecode* loopHead; // For-loops only. jsbytecode* condpc; jsbytecode* updatepc; jsbytecode* updateEnd; } loop; struct { // pc immediately after the switch. jsbytecode* exitpc; // Deferred break and continue targets. DeferredEdge* breaks; // MIR instruction MTableSwitch* ins; // The number of current successor that get mapped into a block. uint32_t currentBlock; } tableswitch; struct { // Vector of body blocks to process after the cases. FixedList* bodies; // When processing case statements, this counter points at the // last uninitialized body. When processing bodies, this // counter targets the next body to process. uint32_t currentIdx; // Remember the block index of the default case. jsbytecode* defaultTarget; uint32_t defaultIdx; // Block immediately after the switch. jsbytecode* exitpc; DeferredEdge* breaks; } condswitch; struct { DeferredEdge* breaks; } label; struct { MBasicBlock* successor; } try_; }; inline bool isLoop() const { switch (state) { case DO_WHILE_LOOP_COND: case DO_WHILE_LOOP_BODY: case WHILE_LOOP_COND: case WHILE_LOOP_BODY: case FOR_LOOP_COND: case FOR_LOOP_BODY: case FOR_LOOP_UPDATE: return true; default: return false; } } static CFGState If(jsbytecode* join, MTest* test); static CFGState IfElse(jsbytecode* trueEnd, jsbytecode* falseEnd, MTest* test); static CFGState AndOr(jsbytecode* join, MBasicBlock* lhs); static CFGState TableSwitch(jsbytecode* exitpc, MTableSwitch* ins); static CFGState CondSwitch(IonBuilder* builder, jsbytecode* exitpc, jsbytecode* defaultTarget); static CFGState Label(jsbytecode* exitpc); static CFGState Try(jsbytecode* exitpc, MBasicBlock* successor); }; static int CmpSuccessors(const void* a, const void* b); public: IonBuilder(JSContext* analysisContext, CompileCompartment* comp, const JitCompileOptions& options, TempAllocator* temp, MIRGraph* graph, CompilerConstraintList* constraints, BaselineInspector* inspector, CompileInfo* info, const OptimizationInfo* optimizationInfo, BaselineFrameInspector* baselineFrame, size_t inliningDepth = 0, uint32_t loopDepth = 0); // Callers of build() and buildInline() should always check whether the // call overrecursed, if false is returned. Overrecursion is not // signaled as OOM and will not in general be caught by OOM paths. MOZ_MUST_USE bool build(); MOZ_MUST_USE bool buildInline(IonBuilder* callerBuilder, MResumePoint* callerResumePoint, CallInfo& callInfo); private: MOZ_MUST_USE bool traverseBytecode(); ControlStatus snoopControlFlow(JSOp op); MOZ_MUST_USE bool processIterators(); MOZ_MUST_USE bool inspectOpcode(JSOp op); uint32_t readIndex(jsbytecode* pc); JSAtom* readAtom(jsbytecode* pc); bool abort(const char* message, ...) MOZ_FORMAT_PRINTF(2, 3); void trackActionableAbort(const char* message); void spew(const char* message); JSFunction* getSingleCallTarget(TemporaryTypeSet* calleeTypes); MOZ_MUST_USE bool getPolyCallTargets(TemporaryTypeSet* calleeTypes, bool constructing, ObjectVector& targets, uint32_t maxTargets); void popCfgStack(); DeferredEdge* filterDeadDeferredEdges(DeferredEdge* edge); MOZ_MUST_USE bool processDeferredContinues(CFGState& state); ControlStatus processControlEnd(); ControlStatus processCfgStack(); ControlStatus processCfgEntry(CFGState& state); ControlStatus processIfEnd(CFGState& state); ControlStatus processIfElseTrueEnd(CFGState& state); ControlStatus processIfElseFalseEnd(CFGState& state); ControlStatus processDoWhileBodyEnd(CFGState& state); ControlStatus processDoWhileCondEnd(CFGState& state); ControlStatus processWhileCondEnd(CFGState& state); ControlStatus processWhileBodyEnd(CFGState& state); ControlStatus processForCondEnd(CFGState& state); ControlStatus processForBodyEnd(CFGState& state); ControlStatus processForUpdateEnd(CFGState& state); ControlStatus processNextTableSwitchCase(CFGState& state); ControlStatus processCondSwitchCase(CFGState& state); ControlStatus processCondSwitchBody(CFGState& state); ControlStatus processSwitchBreak(JSOp op); ControlStatus processSwitchEnd(DeferredEdge* breaks, jsbytecode* exitpc); ControlStatus processAndOrEnd(CFGState& state); ControlStatus processLabelEnd(CFGState& state); ControlStatus processTryEnd(CFGState& state); ControlStatus processReturn(JSOp op); ControlStatus processThrow(); ControlStatus processContinue(JSOp op); ControlStatus processBreak(JSOp op, jssrcnote* sn); ControlStatus maybeLoop(JSOp op, jssrcnote* sn); MOZ_MUST_USE bool pushLoop(CFGState::State state, jsbytecode* stopAt, MBasicBlock* entry, bool osr, jsbytecode* loopHead, jsbytecode* initialPc, jsbytecode* bodyStart, jsbytecode* bodyEnd, jsbytecode* exitpc, jsbytecode* continuepc); MOZ_MUST_USE bool analyzeNewLoopTypes(MBasicBlock* entry, jsbytecode* start, jsbytecode* end); MBasicBlock* addBlock(MBasicBlock* block, uint32_t loopDepth); MBasicBlock* newBlock(MBasicBlock* predecessor, jsbytecode* pc); MBasicBlock* newBlock(MBasicBlock* predecessor, jsbytecode* pc, uint32_t loopDepth); MBasicBlock* newBlock(MBasicBlock* predecessor, jsbytecode* pc, MResumePoint* priorResumePoint); MBasicBlock* newBlockPopN(MBasicBlock* predecessor, jsbytecode* pc, uint32_t popped); MBasicBlock* newBlockAfter(MBasicBlock* at, MBasicBlock* predecessor, jsbytecode* pc); MBasicBlock* newOsrPreheader(MBasicBlock* header, jsbytecode* loopEntry, jsbytecode* beforeLoopEntry); MBasicBlock* newPendingLoopHeader(MBasicBlock* predecessor, jsbytecode* pc, bool osr, bool canOsr, unsigned stackPhiCount); MBasicBlock* newBlock(jsbytecode* pc) { return newBlock(nullptr, pc); } MBasicBlock* newBlockAfter(MBasicBlock* at, jsbytecode* pc) { return newBlockAfter(at, nullptr, pc); } // We want to make sure that our MTest instructions all check whether the // thing being tested might emulate undefined. So we funnel their creation // through this method, to make sure that happens. We don't want to just do // the check in MTest::New, because that can run on background compilation // threads, and we're not sure it's safe to touch that part of the typeset // from a background thread. MTest* newTest(MDefinition* ins, MBasicBlock* ifTrue, MBasicBlock* ifFalse); // Given a list of pending breaks, creates a new block and inserts a Goto // linking each break to the new block. MBasicBlock* createBreakCatchBlock(DeferredEdge* edge, jsbytecode* pc); // Finishes loops that do not actually loop, containing only breaks and // returns or a do while loop with a condition that is constant false. ControlStatus processBrokenLoop(CFGState& state); // Computes loop phis, places them in all successors of a loop, then // handles any pending breaks. ControlStatus finishLoop(CFGState& state, MBasicBlock* successor); // Incorporates a type/typeSet into an OSR value for a loop, after the loop // body has been processed. MOZ_MUST_USE bool addOsrValueTypeBarrier(uint32_t slot, MInstruction** def, MIRType type, TemporaryTypeSet* typeSet); MOZ_MUST_USE bool maybeAddOsrTypeBarriers(); // Restarts processing of a loop if the type information at its header was // incomplete. ControlStatus restartLoop(const CFGState& state); void assertValidLoopHeadOp(jsbytecode* pc); ControlStatus forLoop(JSOp op, jssrcnote* sn); ControlStatus whileOrForInLoop(jssrcnote* sn); ControlStatus doWhileLoop(JSOp op, jssrcnote* sn); ControlStatus tableSwitch(JSOp op, jssrcnote* sn); ControlStatus condSwitch(JSOp op, jssrcnote* sn); // Please see the Big Honkin' Comment about how resume points work in // IonBuilder.cpp, near the definition for this function. MOZ_MUST_USE bool resume(MInstruction* ins, jsbytecode* pc, MResumePoint::Mode mode); MOZ_MUST_USE bool resumeAt(MInstruction* ins, jsbytecode* pc); MOZ_MUST_USE bool resumeAfter(MInstruction* ins); MOZ_MUST_USE bool maybeInsertResume(); void insertRecompileCheck(); MOZ_MUST_USE bool initParameters(); void initLocals(); void rewriteParameter(uint32_t slotIdx, MDefinition* param, int32_t argIndex); MOZ_MUST_USE bool rewriteParameters(); MOZ_MUST_USE bool initEnvironmentChain(MDefinition* callee = nullptr); MOZ_MUST_USE bool initArgumentsObject(); void pushConstant(const Value& v); MConstant* constant(const Value& v); MConstant* constantInt(int32_t i); MInstruction* initializedLength(MDefinition* obj, MDefinition* elements); MInstruction* setInitializedLength(MDefinition* obj, size_t count); // Improve the type information at tests MOZ_MUST_USE bool improveTypesAtTest(MDefinition* ins, bool trueBranch, MTest* test); MOZ_MUST_USE bool improveTypesAtCompare(MCompare* ins, bool trueBranch, MTest* test); MOZ_MUST_USE bool improveTypesAtNullOrUndefinedCompare(MCompare* ins, bool trueBranch, MTest* test); MOZ_MUST_USE bool improveTypesAtTypeOfCompare(MCompare* ins, bool trueBranch, MTest* test); // Used to detect triangular structure at test. MOZ_MUST_USE bool detectAndOrStructure(MPhi* ins, bool* branchIsTrue); MOZ_MUST_USE bool replaceTypeSet(MDefinition* subject, TemporaryTypeSet* type, MTest* test); // Add a guard which ensure that the set of type which goes through this // generated code correspond to the observed types for the bytecode. MDefinition* addTypeBarrier(MDefinition* def, TemporaryTypeSet* observed, BarrierKind kind, MTypeBarrier** pbarrier = nullptr); MOZ_MUST_USE bool pushTypeBarrier(MDefinition* def, TemporaryTypeSet* observed, BarrierKind kind); // As pushTypeBarrier, but will compute the needBarrier boolean itself based // on observed and the JSFunction that we're planning to call. The // JSFunction must be a DOM method or getter. MOZ_MUST_USE bool pushDOMTypeBarrier(MInstruction* ins, TemporaryTypeSet* observed, JSFunction* func); // If definiteType is not known or def already has the right type, just // returns def. Otherwise, returns an MInstruction that has that definite // type, infallibly unboxing ins as needed. The new instruction will be // added to |current| in this case. MDefinition* ensureDefiniteType(MDefinition* def, MIRType definiteType); // Creates a MDefinition based on the given def improved with type as TypeSet. MDefinition* ensureDefiniteTypeSet(MDefinition* def, TemporaryTypeSet* types); void maybeMarkEmpty(MDefinition* ins); JSObject* getSingletonPrototype(JSFunction* target); MDefinition* createThisScripted(MDefinition* callee, MDefinition* newTarget); MDefinition* createThisScriptedSingleton(JSFunction* target, MDefinition* callee); MDefinition* createThisScriptedBaseline(MDefinition* callee); MDefinition* createThis(JSFunction* target, MDefinition* callee, MDefinition* newTarget); MInstruction* createNamedLambdaObject(MDefinition* callee, MDefinition* envObj); MInstruction* createCallObject(MDefinition* callee, MDefinition* envObj); MDefinition* walkEnvironmentChain(unsigned hops); MInstruction* addConvertElementsToDoubles(MDefinition* elements); MDefinition* addMaybeCopyElementsForWrite(MDefinition* object, bool checkNative); MInstruction* addBoundsCheck(MDefinition* index, MDefinition* length); MInstruction* addShapeGuard(MDefinition* obj, Shape* const shape, BailoutKind bailoutKind); MInstruction* addGroupGuard(MDefinition* obj, ObjectGroup* group, BailoutKind bailoutKind); MInstruction* addSharedTypedArrayGuard(MDefinition* obj); MInstruction* addGuardReceiverPolymorphic(MDefinition* obj, const BaselineInspector::ReceiverVector& receivers); MDefinition* convertShiftToMaskForStaticTypedArray(MDefinition* id, Scalar::Type viewType); bool invalidatedIdempotentCache(); bool hasStaticEnvironmentObject(EnvironmentCoordinate ec, JSObject** pcall); MOZ_MUST_USE bool loadSlot(MDefinition* obj, size_t slot, size_t nfixed, MIRType rvalType, BarrierKind barrier, TemporaryTypeSet* types); MOZ_MUST_USE bool loadSlot(MDefinition* obj, Shape* shape, MIRType rvalType, BarrierKind barrier, TemporaryTypeSet* types); MOZ_MUST_USE bool storeSlot(MDefinition* obj, size_t slot, size_t nfixed, MDefinition* value, bool needsBarrier, MIRType slotType = MIRType::None); MOZ_MUST_USE bool storeSlot(MDefinition* obj, Shape* shape, MDefinition* value, bool needsBarrier, MIRType slotType = MIRType::None); bool shouldAbortOnPreliminaryGroups(MDefinition *obj); MDefinition* tryInnerizeWindow(MDefinition* obj); MDefinition* maybeUnboxForPropertyAccess(MDefinition* def); // jsop_getprop() helpers. MOZ_MUST_USE bool checkIsDefinitelyOptimizedArguments(MDefinition* obj, bool* isOptimizedArgs); MOZ_MUST_USE bool getPropTryInferredConstant(bool* emitted, MDefinition* obj, PropertyName* name, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryArgumentsLength(bool* emitted, MDefinition* obj); MOZ_MUST_USE bool getPropTryArgumentsCallee(bool* emitted, MDefinition* obj, PropertyName* name); MOZ_MUST_USE bool getPropTryConstant(bool* emitted, MDefinition* obj, jsid id, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryNotDefined(bool* emitted, MDefinition* obj, jsid id, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryDefiniteSlot(bool* emitted, MDefinition* obj, PropertyName* name, BarrierKind barrier, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryModuleNamespace(bool* emitted, MDefinition* obj, PropertyName* name, BarrierKind barrier, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryCommonGetter(bool* emitted, MDefinition* obj, PropertyName* name, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryInlineAccess(bool* emitted, MDefinition* obj, PropertyName* name, BarrierKind barrier, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryTypedObject(bool* emitted, MDefinition* obj, PropertyName* name); MOZ_MUST_USE bool getPropTryScalarPropOfTypedObject(bool* emitted, MDefinition* typedObj, int32_t fieldOffset, TypedObjectPrediction fieldTypeReprs); MOZ_MUST_USE bool getPropTryReferencePropOfTypedObject(bool* emitted, MDefinition* typedObj, int32_t fieldOffset, TypedObjectPrediction fieldPrediction, PropertyName* name); MOZ_MUST_USE bool getPropTryComplexPropOfTypedObject(bool* emitted, MDefinition* typedObj, int32_t fieldOffset, TypedObjectPrediction fieldTypeReprs, size_t fieldIndex); MOZ_MUST_USE bool getPropTryInnerize(bool* emitted, MDefinition* obj, PropertyName* name, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTryCache(bool* emitted, MDefinition* obj, PropertyName* name, BarrierKind barrier, TemporaryTypeSet* types); MOZ_MUST_USE bool getPropTrySharedStub(bool* emitted, MDefinition* obj, TemporaryTypeSet* types); // jsop_setprop() helpers. MOZ_MUST_USE bool setPropTryCommonSetter(bool* emitted, MDefinition* obj, PropertyName* name, MDefinition* value); MOZ_MUST_USE bool setPropTryCommonDOMSetter(bool* emitted, MDefinition* obj, MDefinition* value, JSFunction* setter, TemporaryTypeSet* objTypes); MOZ_MUST_USE bool setPropTryDefiniteSlot(bool* emitted, MDefinition* obj, PropertyName* name, MDefinition* value, bool barrier, TemporaryTypeSet* objTypes); MOZ_MUST_USE bool setPropTryInlineAccess(bool* emitted, MDefinition* obj, PropertyName* name, MDefinition* value, bool barrier, TemporaryTypeSet* objTypes); MOZ_MUST_USE bool setPropTryTypedObject(bool* emitted, MDefinition* obj, PropertyName* name, MDefinition* value); MOZ_MUST_USE bool setPropTryReferencePropOfTypedObject(bool* emitted, MDefinition* obj, int32_t fieldOffset, MDefinition* value, TypedObjectPrediction fieldPrediction, PropertyName* name); MOZ_MUST_USE bool setPropTryScalarPropOfTypedObject(bool* emitted, MDefinition* obj, int32_t fieldOffset, MDefinition* value, TypedObjectPrediction fieldTypeReprs); MOZ_MUST_USE bool setPropTryCache(bool* emitted, MDefinition* obj, PropertyName* name, MDefinition* value, bool barrier, TemporaryTypeSet* objTypes); // jsop_binary_arith helpers. MBinaryArithInstruction* binaryArithInstruction(JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool binaryArithTryConcat(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool binaryArithTrySpecialized(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool binaryArithTrySpecializedOnBaselineInspector(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool arithTrySharedStub(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); // jsop_bitnot helpers. MOZ_MUST_USE bool bitnotTrySpecialized(bool* emitted, MDefinition* input); // jsop_pow helpers. MOZ_MUST_USE bool powTrySpecialized(bool* emitted, MDefinition* base, MDefinition* power, MIRType outputType); // jsop_compare helpers. MOZ_MUST_USE bool compareTrySpecialized(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool compareTryBitwise(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool compareTrySpecializedOnBaselineInspector(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool compareTrySharedStub(bool* emitted, JSOp op, MDefinition* left, MDefinition* right); // jsop_newarray helpers. MOZ_MUST_USE bool newArrayTrySharedStub(bool* emitted); MOZ_MUST_USE bool newArrayTryTemplateObject(bool* emitted, JSObject* templateObject, uint32_t length); MOZ_MUST_USE bool newArrayTryVM(bool* emitted, JSObject* templateObject, uint32_t length); // jsop_newobject helpers. MOZ_MUST_USE bool newObjectTrySharedStub(bool* emitted); MOZ_MUST_USE bool newObjectTryTemplateObject(bool* emitted, JSObject* templateObject); MOZ_MUST_USE bool newObjectTryVM(bool* emitted, JSObject* templateObject); // jsop_in helpers. MOZ_MUST_USE bool inTryDense(bool* emitted, MDefinition* obj, MDefinition* id); MOZ_MUST_USE bool inTryFold(bool* emitted, MDefinition* obj, MDefinition* id); // binary data lookup helpers. TypedObjectPrediction typedObjectPrediction(MDefinition* typedObj); TypedObjectPrediction typedObjectPrediction(TemporaryTypeSet* types); MOZ_MUST_USE bool typedObjectHasField(MDefinition* typedObj, PropertyName* name, size_t* fieldOffset, TypedObjectPrediction* fieldTypeReprs, size_t* fieldIndex); MDefinition* loadTypedObjectType(MDefinition* value); void loadTypedObjectData(MDefinition* typedObj, MDefinition** owner, LinearSum* ownerOffset); void loadTypedObjectElements(MDefinition* typedObj, const LinearSum& byteOffset, uint32_t scale, MDefinition** ownerElements, MDefinition** ownerScaledOffset, int32_t* ownerByteAdjustment); MDefinition* typeObjectForElementFromArrayStructType(MDefinition* typedObj); MDefinition* typeObjectForFieldFromStructType(MDefinition* type, size_t fieldIndex); MOZ_MUST_USE bool storeReferenceTypedObjectValue(MDefinition* typedObj, const LinearSum& byteOffset, ReferenceTypeDescr::Type type, MDefinition* value, PropertyName* name); MOZ_MUST_USE bool storeScalarTypedObjectValue(MDefinition* typedObj, const LinearSum& byteOffset, ScalarTypeDescr::Type type, MDefinition* value); MOZ_MUST_USE bool checkTypedObjectIndexInBounds(uint32_t elemSize, MDefinition* obj, MDefinition* index, TypedObjectPrediction objTypeDescrs, LinearSum* indexAsByteOffset); MOZ_MUST_USE bool pushDerivedTypedObject(bool* emitted, MDefinition* obj, const LinearSum& byteOffset, TypedObjectPrediction derivedTypeDescrs, MDefinition* derivedTypeObj); MOZ_MUST_USE bool pushScalarLoadFromTypedObject(MDefinition* obj, const LinearSum& byteoffset, ScalarTypeDescr::Type type); MOZ_MUST_USE bool pushReferenceLoadFromTypedObject(MDefinition* typedObj, const LinearSum& byteOffset, ReferenceTypeDescr::Type type, PropertyName* name); JSObject* getStaticTypedArrayObject(MDefinition* obj, MDefinition* index); // jsop_setelem() helpers. MOZ_MUST_USE bool setElemTryTypedArray(bool* emitted, MDefinition* object, MDefinition* index, MDefinition* value); MOZ_MUST_USE bool setElemTryTypedObject(bool* emitted, MDefinition* obj, MDefinition* index, MDefinition* value); MOZ_MUST_USE bool setElemTryTypedStatic(bool* emitted, MDefinition* object, MDefinition* index, MDefinition* value); MOZ_MUST_USE bool setElemTryDense(bool* emitted, MDefinition* object, MDefinition* index, MDefinition* value, bool writeHole); MOZ_MUST_USE bool setElemTryArguments(bool* emitted, MDefinition* object, MDefinition* index, MDefinition* value); MOZ_MUST_USE bool setElemTryCache(bool* emitted, MDefinition* object, MDefinition* index, MDefinition* value); MOZ_MUST_USE bool setElemTryReferenceElemOfTypedObject(bool* emitted, MDefinition* obj, MDefinition* index, TypedObjectPrediction objPrediction, MDefinition* value, TypedObjectPrediction elemPrediction); MOZ_MUST_USE bool setElemTryScalarElemOfTypedObject(bool* emitted, MDefinition* obj, MDefinition* index, TypedObjectPrediction objTypeReprs, MDefinition* value, TypedObjectPrediction elemTypeReprs, uint32_t elemSize); MOZ_MUST_USE bool initializeArrayElement(MDefinition* obj, size_t index, MDefinition* value, bool addResumePointAndIncrementInitializedLength); // jsop_getelem() helpers. MOZ_MUST_USE bool getElemTryDense(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryGetProp(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryTypedStatic(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryTypedArray(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryTypedObject(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryString(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryArguments(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryArgumentsInlined(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryCache(bool* emitted, MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool getElemTryScalarElemOfTypedObject(bool* emitted, MDefinition* obj, MDefinition* index, TypedObjectPrediction objTypeReprs, TypedObjectPrediction elemTypeReprs, uint32_t elemSize); MOZ_MUST_USE bool getElemTryReferenceElemOfTypedObject(bool* emitted, MDefinition* obj, MDefinition* index, TypedObjectPrediction objPrediction, TypedObjectPrediction elemPrediction); MOZ_MUST_USE bool getElemTryComplexElemOfTypedObject(bool* emitted, MDefinition* obj, MDefinition* index, TypedObjectPrediction objTypeReprs, TypedObjectPrediction elemTypeReprs, uint32_t elemSize); TemporaryTypeSet* computeHeapType(const TemporaryTypeSet* objTypes, const jsid id); enum BoundsChecking { DoBoundsCheck, SkipBoundsCheck }; MInstruction* addArrayBufferByteLength(MDefinition* obj); // Add instructions to compute a typed array's length and data. Also // optionally convert |*index| into a bounds-checked definition, if // requested. // // If you only need the array's length, use addTypedArrayLength below. void addTypedArrayLengthAndData(MDefinition* obj, BoundsChecking checking, MDefinition** index, MInstruction** length, MInstruction** elements); // Add an instruction to compute a typed array's length to the current // block. If you also need the typed array's data, use the above method // instead. MInstruction* addTypedArrayLength(MDefinition* obj) { MInstruction* length; addTypedArrayLengthAndData(obj, SkipBoundsCheck, nullptr, &length, nullptr); return length; } MOZ_MUST_USE bool improveThisTypesForCall(); MDefinition* getCallee(); MDefinition* getAliasedVar(EnvironmentCoordinate ec); MDefinition* addLexicalCheck(MDefinition* input); MDefinition* convertToBoolean(MDefinition* input); MOZ_MUST_USE bool tryFoldInstanceOf(MDefinition* lhs, JSObject* protoObject); MOZ_MUST_USE bool hasOnProtoChain(TypeSet::ObjectKey* key, JSObject* protoObject, bool* hasOnProto); MOZ_MUST_USE bool jsop_add(MDefinition* left, MDefinition* right); MOZ_MUST_USE bool jsop_bitnot(); MOZ_MUST_USE bool jsop_bitop(JSOp op); MOZ_MUST_USE bool jsop_binary_arith(JSOp op); MOZ_MUST_USE bool jsop_binary_arith(JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool jsop_pow(); MOZ_MUST_USE bool jsop_pos(); MOZ_MUST_USE bool jsop_neg(); MOZ_MUST_USE bool jsop_tostring(); MOZ_MUST_USE bool jsop_setarg(uint32_t arg); MOZ_MUST_USE bool jsop_defvar(uint32_t index); MOZ_MUST_USE bool jsop_deflexical(uint32_t index); MOZ_MUST_USE bool jsop_deffun(uint32_t index); MOZ_MUST_USE bool jsop_notearg(); MOZ_MUST_USE bool jsop_throwsetconst(); MOZ_MUST_USE bool jsop_checklexical(); MOZ_MUST_USE bool jsop_checkaliasedlexical(EnvironmentCoordinate ec); MOZ_MUST_USE bool jsop_funcall(uint32_t argc); MOZ_MUST_USE bool jsop_funapply(uint32_t argc); MOZ_MUST_USE bool jsop_funapplyarguments(uint32_t argc); MOZ_MUST_USE bool jsop_funapplyarray(uint32_t argc); MOZ_MUST_USE bool jsop_call(uint32_t argc, bool constructing); MOZ_MUST_USE bool jsop_call(uint32_t argc, bool constructing, bool ignoresReturnValue); MOZ_MUST_USE bool jsop_eval(uint32_t argc); MOZ_MUST_USE bool jsop_ifeq(JSOp op); MOZ_MUST_USE bool jsop_try(); MOZ_MUST_USE bool jsop_label(); MOZ_MUST_USE bool jsop_condswitch(); MOZ_MUST_USE bool jsop_andor(JSOp op); MOZ_MUST_USE bool jsop_dup2(); MOZ_MUST_USE bool jsop_loophead(jsbytecode* pc); MOZ_MUST_USE bool jsop_compare(JSOp op); MOZ_MUST_USE bool jsop_compare(JSOp op, MDefinition* left, MDefinition* right); MOZ_MUST_USE bool getStaticName(JSObject* staticObject, PropertyName* name, bool* psucceeded, MDefinition* lexicalCheck = nullptr); MOZ_MUST_USE bool loadStaticSlot(JSObject* staticObject, BarrierKind barrier, TemporaryTypeSet* types, uint32_t slot); MOZ_MUST_USE bool setStaticName(JSObject* staticObject, PropertyName* name); MOZ_MUST_USE bool jsop_getgname(PropertyName* name); MOZ_MUST_USE bool jsop_getname(PropertyName* name); MOZ_MUST_USE bool jsop_intrinsic(PropertyName* name); MOZ_MUST_USE bool jsop_getimport(PropertyName* name); MOZ_MUST_USE bool jsop_bindname(PropertyName* name); MOZ_MUST_USE bool jsop_bindvar(); MOZ_MUST_USE bool jsop_getelem(); MOZ_MUST_USE bool jsop_getelem_dense(MDefinition* obj, MDefinition* index); MOZ_MUST_USE bool jsop_getelem_typed(MDefinition* obj, MDefinition* index, ScalarTypeDescr::Type arrayType); MOZ_MUST_USE bool jsop_setelem(); MOZ_MUST_USE bool jsop_setelem_dense(TemporaryTypeSet::DoubleConversion conversion, MDefinition* object, MDefinition* index, MDefinition* value, bool writeHole, bool* emitted); MOZ_MUST_USE bool jsop_setelem_typed(ScalarTypeDescr::Type arrayType, MDefinition* object, MDefinition* index, MDefinition* value); MOZ_MUST_USE bool jsop_length(); MOZ_MUST_USE bool jsop_length_fastPath(); MOZ_MUST_USE bool jsop_arguments(); MOZ_MUST_USE bool jsop_arguments_getelem(); MOZ_MUST_USE bool jsop_runonce(); MOZ_MUST_USE bool jsop_rest(); MOZ_MUST_USE bool jsop_not(); MOZ_MUST_USE bool jsop_getprop(PropertyName* name); MOZ_MUST_USE bool jsop_setprop(PropertyName* name); MOZ_MUST_USE bool jsop_delprop(PropertyName* name); MOZ_MUST_USE bool jsop_delelem(); MOZ_MUST_USE bool jsop_newarray(uint32_t length); MOZ_MUST_USE bool jsop_newarray(JSObject* templateObject, uint32_t length); MOZ_MUST_USE bool jsop_newarray_copyonwrite(); MOZ_MUST_USE bool jsop_newobject(); MOZ_MUST_USE bool jsop_initelem(); MOZ_MUST_USE bool jsop_initelem_array(); MOZ_MUST_USE bool jsop_initelem_getter_setter(); MOZ_MUST_USE bool jsop_mutateproto(); MOZ_MUST_USE bool jsop_initprop(PropertyName* name); MOZ_MUST_USE bool jsop_initprop_getter_setter(PropertyName* name); MOZ_MUST_USE bool jsop_regexp(RegExpObject* reobj); MOZ_MUST_USE bool jsop_object(JSObject* obj); MOZ_MUST_USE bool jsop_lambda(JSFunction* fun); MOZ_MUST_USE bool jsop_lambda_arrow(JSFunction* fun); MOZ_MUST_USE bool jsop_setfunname(uint8_t prefixKind); MOZ_MUST_USE bool jsop_functionthis(); MOZ_MUST_USE bool jsop_globalthis(); MOZ_MUST_USE bool jsop_typeof(); MOZ_MUST_USE bool jsop_toasync(); MOZ_MUST_USE bool jsop_toid(); MOZ_MUST_USE bool jsop_iter(uint8_t flags); MOZ_MUST_USE bool jsop_itermore(); MOZ_MUST_USE bool jsop_isnoiter(); MOZ_MUST_USE bool jsop_iterend(); MOZ_MUST_USE bool jsop_in(); MOZ_MUST_USE bool jsop_instanceof(); MOZ_MUST_USE bool jsop_getaliasedvar(EnvironmentCoordinate ec); MOZ_MUST_USE bool jsop_setaliasedvar(EnvironmentCoordinate ec); MOZ_MUST_USE bool jsop_debugger(); MOZ_MUST_USE bool jsop_newtarget(); MOZ_MUST_USE bool jsop_checkisobj(uint8_t kind); MOZ_MUST_USE bool jsop_checkiscallable(uint8_t kind); MOZ_MUST_USE bool jsop_checkobjcoercible(); MOZ_MUST_USE bool jsop_pushcallobj(); /* Inlining. */ enum InliningStatus { InliningStatus_Error, InliningStatus_NotInlined, InliningStatus_WarmUpCountTooLow, InliningStatus_Inlined }; enum InliningDecision { InliningDecision_Error, InliningDecision_Inline, InliningDecision_DontInline, InliningDecision_WarmUpCountTooLow }; static InliningDecision DontInline(JSScript* targetScript, const char* reason); // Helper function for canInlineTarget bool hasCommonInliningPath(const JSScript* scriptToInline); // Oracles. InliningDecision canInlineTarget(JSFunction* target, CallInfo& callInfo); InliningDecision makeInliningDecision(JSObject* target, CallInfo& callInfo); MOZ_MUST_USE bool selectInliningTargets(const ObjectVector& targets, CallInfo& callInfo, BoolVector& choiceSet, uint32_t* numInlineable); // Native inlining helpers. // The typeset for the return value of our function. These are // the types it's been observed returning in the past. TemporaryTypeSet* getInlineReturnTypeSet(); // The known MIR type of getInlineReturnTypeSet. MIRType getInlineReturnType(); // Array natives. InliningStatus inlineArray(CallInfo& callInfo); InliningStatus inlineArrayIsArray(CallInfo& callInfo); InliningStatus inlineArrayPopShift(CallInfo& callInfo, MArrayPopShift::Mode mode); InliningStatus inlineArrayPush(CallInfo& callInfo); InliningStatus inlineArraySlice(CallInfo& callInfo); InliningStatus inlineArrayJoin(CallInfo& callInfo); // Math natives. InliningStatus inlineMathAbs(CallInfo& callInfo); InliningStatus inlineMathFloor(CallInfo& callInfo); InliningStatus inlineMathCeil(CallInfo& callInfo); InliningStatus inlineMathClz32(CallInfo& callInfo); InliningStatus inlineMathRound(CallInfo& callInfo); InliningStatus inlineMathSqrt(CallInfo& callInfo); InliningStatus inlineMathAtan2(CallInfo& callInfo); InliningStatus inlineMathHypot(CallInfo& callInfo); InliningStatus inlineMathMinMax(CallInfo& callInfo, bool max); InliningStatus inlineMathPow(CallInfo& callInfo); InliningStatus inlineMathRandom(CallInfo& callInfo); InliningStatus inlineMathImul(CallInfo& callInfo); InliningStatus inlineMathFRound(CallInfo& callInfo); InliningStatus inlineMathFunction(CallInfo& callInfo, MMathFunction::Function function); // String natives. InliningStatus inlineStringObject(CallInfo& callInfo); InliningStatus inlineStrCharCodeAt(CallInfo& callInfo); InliningStatus inlineConstantCharCodeAt(CallInfo& callInfo); InliningStatus inlineStrFromCharCode(CallInfo& callInfo); InliningStatus inlineStrFromCodePoint(CallInfo& callInfo); InliningStatus inlineStrCharAt(CallInfo& callInfo); // String intrinsics. InliningStatus inlineStringReplaceString(CallInfo& callInfo); InliningStatus inlineConstantStringSplitString(CallInfo& callInfo); InliningStatus inlineStringSplitString(CallInfo& callInfo); // RegExp intrinsics. InliningStatus inlineRegExpMatcher(CallInfo& callInfo); InliningStatus inlineRegExpSearcher(CallInfo& callInfo); InliningStatus inlineRegExpTester(CallInfo& callInfo); InliningStatus inlineIsRegExpObject(CallInfo& callInfo); InliningStatus inlineRegExpPrototypeOptimizable(CallInfo& callInfo); InliningStatus inlineRegExpInstanceOptimizable(CallInfo& callInfo); InliningStatus inlineGetFirstDollarIndex(CallInfo& callInfo); // Object natives and intrinsics. InliningStatus inlineObjectCreate(CallInfo& callInfo); InliningStatus inlineDefineDataProperty(CallInfo& callInfo); // Atomics natives. InliningStatus inlineAtomicsCompareExchange(CallInfo& callInfo); InliningStatus inlineAtomicsExchange(CallInfo& callInfo); InliningStatus inlineAtomicsLoad(CallInfo& callInfo); InliningStatus inlineAtomicsStore(CallInfo& callInfo); InliningStatus inlineAtomicsBinop(CallInfo& callInfo, InlinableNative target); InliningStatus inlineAtomicsIsLockFree(CallInfo& callInfo); // Slot intrinsics. InliningStatus inlineUnsafeSetReservedSlot(CallInfo& callInfo); InliningStatus inlineUnsafeGetReservedSlot(CallInfo& callInfo, MIRType knownValueType); // Map and Set intrinsics. InliningStatus inlineGetNextEntryForIterator(CallInfo& callInfo, MGetNextEntryForIterator::Mode mode); // ArrayBuffer intrinsics. InliningStatus inlineArrayBufferByteLength(CallInfo& callInfo); InliningStatus inlinePossiblyWrappedArrayBufferByteLength(CallInfo& callInfo); // TypedArray intrinsics. enum WrappingBehavior { AllowWrappedTypedArrays, RejectWrappedTypedArrays }; InliningStatus inlineTypedArray(CallInfo& callInfo, Native native); InliningStatus inlineIsTypedArrayHelper(CallInfo& callInfo, WrappingBehavior wrappingBehavior); InliningStatus inlineIsTypedArray(CallInfo& callInfo); InliningStatus inlineIsPossiblyWrappedTypedArray(CallInfo& callInfo); InliningStatus inlineTypedArrayLength(CallInfo& callInfo); InliningStatus inlinePossiblyWrappedTypedArrayLength(CallInfo& callInfo); InliningStatus inlineSetDisjointTypedElements(CallInfo& callInfo); // TypedObject intrinsics and natives. InliningStatus inlineObjectIsTypeDescr(CallInfo& callInfo); InliningStatus inlineSetTypedObjectOffset(CallInfo& callInfo); InliningStatus inlineConstructTypedObject(CallInfo& callInfo, TypeDescr* target); // SIMD intrinsics and natives. InliningStatus inlineConstructSimdObject(CallInfo& callInfo, SimdTypeDescr* target); // SIMD helpers. bool canInlineSimd(CallInfo& callInfo, JSNative native, unsigned numArgs, InlineTypedObject** templateObj); MDefinition* unboxSimd(MDefinition* ins, SimdType type); IonBuilder::InliningStatus boxSimd(CallInfo& callInfo, MDefinition* ins, InlineTypedObject* templateObj); MDefinition* convertToBooleanSimdLane(MDefinition* scalar); InliningStatus inlineSimd(CallInfo& callInfo, JSFunction* target, SimdType type); InliningStatus inlineSimdBinaryArith(CallInfo& callInfo, JSNative native, MSimdBinaryArith::Operation op, SimdType type); InliningStatus inlineSimdBinaryBitwise(CallInfo& callInfo, JSNative native, MSimdBinaryBitwise::Operation op, SimdType type); InliningStatus inlineSimdBinarySaturating(CallInfo& callInfo, JSNative native, MSimdBinarySaturating::Operation op, SimdType type); InliningStatus inlineSimdShift(CallInfo& callInfo, JSNative native, MSimdShift::Operation op, SimdType type); InliningStatus inlineSimdComp(CallInfo& callInfo, JSNative native, MSimdBinaryComp::Operation op, SimdType type); InliningStatus inlineSimdUnary(CallInfo& callInfo, JSNative native, MSimdUnaryArith::Operation op, SimdType type); InliningStatus inlineSimdExtractLane(CallInfo& callInfo, JSNative native, SimdType type); InliningStatus inlineSimdReplaceLane(CallInfo& callInfo, JSNative native, SimdType type); InliningStatus inlineSimdSplat(CallInfo& callInfo, JSNative native, SimdType type); InliningStatus inlineSimdShuffle(CallInfo& callInfo, JSNative native, SimdType type, unsigned numVectors); InliningStatus inlineSimdCheck(CallInfo& callInfo, JSNative native, SimdType type); InliningStatus inlineSimdConvert(CallInfo& callInfo, JSNative native, bool isCast, SimdType from, SimdType to); InliningStatus inlineSimdSelect(CallInfo& callInfo, JSNative native, SimdType type); MOZ_MUST_USE bool prepareForSimdLoadStore(CallInfo& callInfo, Scalar::Type simdType, MInstruction** elements, MDefinition** index, Scalar::Type* arrayType); InliningStatus inlineSimdLoad(CallInfo& callInfo, JSNative native, SimdType type, unsigned numElems); InliningStatus inlineSimdStore(CallInfo& callInfo, JSNative native, SimdType type, unsigned numElems); InliningStatus inlineSimdAnyAllTrue(CallInfo& callInfo, bool IsAllTrue, JSNative native, SimdType type); // Utility intrinsics. InliningStatus inlineIsCallable(CallInfo& callInfo); InliningStatus inlineIsConstructor(CallInfo& callInfo); InliningStatus inlineIsObject(CallInfo& callInfo); InliningStatus inlineToObject(CallInfo& callInfo); InliningStatus inlineIsWrappedArrayConstructor(CallInfo& callInfo); InliningStatus inlineToInteger(CallInfo& callInfo); InliningStatus inlineToString(CallInfo& callInfo); InliningStatus inlineDump(CallInfo& callInfo); InliningStatus inlineHasClass(CallInfo& callInfo, const Class* clasp, const Class* clasp2 = nullptr, const Class* clasp3 = nullptr, const Class* clasp4 = nullptr); InliningStatus inlineGuardToClass(CallInfo& callInfo, const Class* clasp); InliningStatus inlineIsConstructing(CallInfo& callInfo); InliningStatus inlineSubstringKernel(CallInfo& callInfo); InliningStatus inlineObjectHasPrototype(CallInfo& callInfo); // Testing functions. InliningStatus inlineBailout(CallInfo& callInfo); InliningStatus inlineAssertFloat32(CallInfo& callInfo); InliningStatus inlineAssertRecoveredOnBailout(CallInfo& callInfo); // Bind function. InliningStatus inlineBoundFunction(CallInfo& callInfo, JSFunction* target); // Main inlining functions InliningStatus inlineNativeCall(CallInfo& callInfo, JSFunction* target); InliningStatus inlineNativeGetter(CallInfo& callInfo, JSFunction* target); InliningStatus inlineNonFunctionCall(CallInfo& callInfo, JSObject* target); InliningStatus inlineScriptedCall(CallInfo& callInfo, JSFunction* target); InliningStatus inlineSingleCall(CallInfo& callInfo, JSObject* target); // Call functions InliningStatus inlineCallsite(const ObjectVector& targets, CallInfo& callInfo); MOZ_MUST_USE bool inlineCalls(CallInfo& callInfo, const ObjectVector& targets, BoolVector& choiceSet, MGetPropertyCache* maybeCache); // Inlining helpers. MOZ_MUST_USE bool inlineGenericFallback(JSFunction* target, CallInfo& callInfo, MBasicBlock* dispatchBlock); MOZ_MUST_USE bool inlineObjectGroupFallback(CallInfo& callInfo, MBasicBlock* dispatchBlock, MObjectGroupDispatch* dispatch, MGetPropertyCache* cache, MBasicBlock** fallbackTarget); enum AtomicCheckResult { DontCheckAtomicResult, DoCheckAtomicResult }; MOZ_MUST_USE bool atomicsMeetsPreconditions(CallInfo& callInfo, Scalar::Type* arrayElementType, bool* requiresDynamicCheck, AtomicCheckResult checkResult=DoCheckAtomicResult); void atomicsCheckBounds(CallInfo& callInfo, MInstruction** elements, MDefinition** index); MOZ_MUST_USE bool testNeedsArgumentCheck(JSFunction* target, CallInfo& callInfo); MCall* makeCallHelper(JSFunction* target, CallInfo& callInfo); MOZ_MUST_USE bool makeCall(JSFunction* target, CallInfo& callInfo); MDefinition* patchInlinedReturn(CallInfo& callInfo, MBasicBlock* exit, MBasicBlock* bottom); MDefinition* patchInlinedReturns(CallInfo& callInfo, MIRGraphReturns& returns, MBasicBlock* bottom); MDefinition* specializeInlinedReturn(MDefinition* rdef, MBasicBlock* exit); MOZ_MUST_USE bool objectsHaveCommonPrototype(TemporaryTypeSet* types, PropertyName* name, bool isGetter, JSObject* foundProto, bool* guardGlobal); void freezePropertiesForCommonPrototype(TemporaryTypeSet* types, PropertyName* name, JSObject* foundProto, bool allowEmptyTypesForGlobal = false); /* * Callers must pass a non-null globalGuard if they pass a non-null globalShape. */ MOZ_MUST_USE bool testCommonGetterSetter(TemporaryTypeSet* types, PropertyName* name, bool isGetter, JSObject* foundProto, Shape* lastProperty, JSFunction* getterOrSetter, MDefinition** guard, Shape* globalShape = nullptr, MDefinition** globalGuard = nullptr); MOZ_MUST_USE bool testShouldDOMCall(TypeSet* inTypes, JSFunction* func, JSJitInfo::OpType opType); MDefinition* addShapeGuardsForGetterSetter(MDefinition* obj, JSObject* holder, Shape* holderShape, const BaselineInspector::ReceiverVector& receivers, bool isOwnProperty); MOZ_MUST_USE bool annotateGetPropertyCache(MDefinition* obj, PropertyName* name, MGetPropertyCache* getPropCache, TemporaryTypeSet* objTypes, TemporaryTypeSet* pushedTypes); MGetPropertyCache* getInlineableGetPropertyCache(CallInfo& callInfo); JSObject* testGlobalLexicalBinding(PropertyName* name); JSObject* testSingletonProperty(JSObject* obj, jsid id); JSObject* testSingletonPropertyTypes(MDefinition* obj, jsid id); ResultWithOOM testNotDefinedProperty(MDefinition* obj, jsid id); uint32_t getDefiniteSlot(TemporaryTypeSet* types, PropertyName* name, uint32_t* pnfixed); MOZ_MUST_USE bool checkPreliminaryGroups(MDefinition *obj); MOZ_MUST_USE bool freezePropTypeSets(TemporaryTypeSet* types, JSObject* foundProto, PropertyName* name); bool canInlinePropertyOpShapes(const BaselineInspector::ReceiverVector& receivers); TemporaryTypeSet* bytecodeTypes(jsbytecode* pc); // Use one of the below methods for updating the current block, rather than // updating |current| directly. setCurrent() should only be used in cases // where the block cannot have phis whose type needs to be computed. MOZ_MUST_USE bool setCurrentAndSpecializePhis(MBasicBlock* block) { if (block) { if (!block->specializePhis(alloc())) return false; } setCurrent(block); return true; } void setCurrent(MBasicBlock* block) { current = block; } // A builder is inextricably tied to a particular script. JSScript* script_; // script->hasIonScript() at the start of the compilation. Used to avoid // calling hasIonScript() from background compilation threads. bool scriptHasIonScript_; // If off thread compilation is successful, the final code generator is // attached here. Code has been generated, but not linked (there is not yet // an IonScript). This is heap allocated, and must be explicitly destroyed, // performed by FinishOffThreadBuilder(). CodeGenerator* backgroundCodegen_; // Some aborts are actionable (e.g., using an unsupported bytecode). When // optimization tracking is enabled, the location and message of the abort // are recorded here so they may be propagated to the script's // corresponding JitcodeGlobalEntry::BaselineEntry. JSScript* actionableAbortScript_; jsbytecode* actionableAbortPc_; const char* actionableAbortMessage_; MRootList* rootList_; public: void setRootList(MRootList& rootList) { MOZ_ASSERT(!rootList_); rootList_ = &rootList; } void clearForBackEnd(); JSObject* checkNurseryObject(JSObject* obj); JSScript* script() const { return script_; } bool scriptHasIonScript() const { return scriptHasIonScript_; } CodeGenerator* backgroundCodegen() const { return backgroundCodegen_; } void setBackgroundCodegen(CodeGenerator* codegen) { backgroundCodegen_ = codegen; } CompilerConstraintList* constraints() { return constraints_; } bool isInlineBuilder() const { return callerBuilder_ != nullptr; } const JSAtomState& names() { return compartment->runtime()->names(); } bool hadActionableAbort() const { MOZ_ASSERT(!actionableAbortScript_ || (actionableAbortPc_ && actionableAbortMessage_)); return actionableAbortScript_ != nullptr; } TraceLoggerThread *traceLogger() { // Currently ionbuilder only runs on the main thread. return TraceLoggerForMainThread(compartment->runtime()->mainThread()->runtimeFromMainThread()); } void actionableAbortLocationAndMessage(JSScript** abortScript, jsbytecode** abortPc, const char** abortMessage) { MOZ_ASSERT(hadActionableAbort()); *abortScript = actionableAbortScript_; *abortPc = actionableAbortPc_; *abortMessage = actionableAbortMessage_; } void trace(JSTracer* trc); private: MOZ_MUST_USE bool init(); JSContext* analysisContext; BaselineFrameInspector* baselineFrame_; // Constraints for recording dependencies on type information. CompilerConstraintList* constraints_; // Basic analysis information about the script. BytecodeAnalysis analysis_; BytecodeAnalysis& analysis() { return analysis_; } TemporaryTypeSet* thisTypes; TemporaryTypeSet* argTypes; TemporaryTypeSet* typeArray; uint32_t typeArrayHint; uint32_t* bytecodeTypeMap; GSNCache gsn; EnvironmentCoordinateNameCache envCoordinateNameCache; jsbytecode* pc; MBasicBlock* current; uint32_t loopDepth_; Vector trackedOptimizationSites_; BytecodeSite* bytecodeSite(jsbytecode* pc) { MOZ_ASSERT(info().inlineScriptTree()->script()->containsPC(pc)); // See comment in maybeTrackedOptimizationSite. if (isOptimizationTrackingEnabled()) { if (BytecodeSite* site = maybeTrackedOptimizationSite(pc)) return site; } return new(alloc()) BytecodeSite(info().inlineScriptTree(), pc); } BytecodeSite* maybeTrackedOptimizationSite(jsbytecode* pc); MDefinition* lexicalCheck_; void setLexicalCheck(MDefinition* lexical) { MOZ_ASSERT(!lexicalCheck_); lexicalCheck_ = lexical; } MDefinition* takeLexicalCheck() { MDefinition* lexical = lexicalCheck_; lexicalCheck_ = nullptr; return lexical; } /* Information used for inline-call builders. */ MResumePoint* callerResumePoint_; jsbytecode* callerPC() { return callerResumePoint_ ? callerResumePoint_->pc() : nullptr; } IonBuilder* callerBuilder_; IonBuilder* outermostBuilder(); struct LoopHeader { jsbytecode* pc; MBasicBlock* header; LoopHeader(jsbytecode* pc, MBasicBlock* header) : pc(pc), header(header) {} }; Vector cfgStack_; Vector loops_; Vector switches_; Vector labels_; Vector iterators_; Vector loopHeaders_; BaselineInspector* inspector; size_t inliningDepth_; // Total bytecode length of all inlined scripts. Only tracked for the // outermost builder. size_t inlinedBytecodeLength_; // Cutoff to disable compilation if excessive time is spent reanalyzing // loop bodies to compute a fixpoint of the types for loop variables. static const size_t MAX_LOOP_RESTARTS = 40; size_t numLoopRestarts_; // True if script->failedBoundsCheck is set for the current script or // an outer script. bool failedBoundsCheck_; // True if script->failedShapeGuard is set for the current script or // an outer script. bool failedShapeGuard_; // True if script->failedLexicalCheck_ is set for the current script or // an outer script. bool failedLexicalCheck_; // Has an iterator other than 'for in'. bool nonStringIteration_; // If this script can use a lazy arguments object, it will be pre-created // here. MInstruction* lazyArguments_; // If this is an inline builder, the call info for the builder. const CallInfo* inlineCallInfo_; // When compiling a call with multiple targets, we are first creating a // MGetPropertyCache. This MGetPropertyCache is following the bytecode, and // is used to recover the JSFunction. In some cases, the Type of the object // which own the property is enough for dispatching to the right function. // In such cases we do not have read the property, except when the type // object is unknown. // // As an optimization, we can dispatch a call based on the object group, // without doing the MGetPropertyCache. This is what is achieved by // |IonBuilder::inlineCalls|. As we might not know all the functions, we // are adding a fallback path, where this MGetPropertyCache would be moved // into. // // In order to build the fallback path, we have to capture a resume point // ahead, for the potential fallback path. This resume point is captured // while building MGetPropertyCache. It is capturing the state of Baseline // before the execution of the MGetPropertyCache, such as we can safely do // it in the fallback path. // // This field is used to discard the resume point if it is not used for // building a fallback path. // Discard the prior resume point while setting a new MGetPropertyCache. void replaceMaybeFallbackFunctionGetter(MGetPropertyCache* cache); // Discard the MGetPropertyCache if it is handled by WrapMGetPropertyCache. void keepFallbackFunctionGetter(MGetPropertyCache* cache) { if (cache == maybeFallbackFunctionGetter_) maybeFallbackFunctionGetter_ = nullptr; } MGetPropertyCache* maybeFallbackFunctionGetter_; // Used in tracking outcomes of optimization strategies for devtools. void startTrackingOptimizations(); // The track* methods below are called often. Do not combine them with the // unchecked variants, despite the unchecked variants having no other // callers. void trackTypeInfo(JS::TrackedTypeSite site, MIRType mirType, TemporaryTypeSet* typeSet) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackTypeInfoUnchecked(site, mirType, typeSet); } void trackTypeInfo(JS::TrackedTypeSite site, JSObject* obj) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackTypeInfoUnchecked(site, obj); } void trackTypeInfo(CallInfo& callInfo) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackTypeInfoUnchecked(callInfo); } void trackOptimizationAttempt(JS::TrackedStrategy strategy) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackOptimizationAttemptUnchecked(strategy); } void amendOptimizationAttempt(uint32_t index) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) amendOptimizationAttemptUnchecked(index); } void trackOptimizationOutcome(JS::TrackedOutcome outcome) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackOptimizationOutcomeUnchecked(outcome); } void trackOptimizationSuccess() { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackOptimizationSuccessUnchecked(); } void trackInlineSuccess(InliningStatus status = InliningStatus_Inlined) { if (MOZ_UNLIKELY(current->trackedSite()->hasOptimizations())) trackInlineSuccessUnchecked(status); } bool forceInlineCaches() { return MOZ_UNLIKELY(JitOptions.forceInlineCaches); } // Out-of-line variants that don't check if optimization tracking is // enabled. void trackTypeInfoUnchecked(JS::TrackedTypeSite site, MIRType mirType, TemporaryTypeSet* typeSet); void trackTypeInfoUnchecked(JS::TrackedTypeSite site, JSObject* obj); void trackTypeInfoUnchecked(CallInfo& callInfo); void trackOptimizationAttemptUnchecked(JS::TrackedStrategy strategy); void amendOptimizationAttemptUnchecked(uint32_t index); void trackOptimizationOutcomeUnchecked(JS::TrackedOutcome outcome); void trackOptimizationSuccessUnchecked(); void trackInlineSuccessUnchecked(InliningStatus status); }; class CallInfo { MDefinition* fun_; MDefinition* thisArg_; MDefinition* newTargetArg_; MDefinitionVector args_; bool constructing_:1; // True if the caller does not use the return value. bool ignoresReturnValue_:1; bool setter_:1; public: CallInfo(TempAllocator& alloc, bool constructing, bool ignoresReturnValue) : fun_(nullptr), thisArg_(nullptr), newTargetArg_(nullptr), args_(alloc), constructing_(constructing), ignoresReturnValue_(ignoresReturnValue), setter_(false) { } MOZ_MUST_USE bool init(CallInfo& callInfo) { MOZ_ASSERT(constructing_ == callInfo.constructing()); fun_ = callInfo.fun(); thisArg_ = callInfo.thisArg(); ignoresReturnValue_ = callInfo.ignoresReturnValue(); if (constructing()) newTargetArg_ = callInfo.getNewTarget(); if (!args_.appendAll(callInfo.argv())) return false; return true; } MOZ_MUST_USE bool init(MBasicBlock* current, uint32_t argc) { MOZ_ASSERT(args_.empty()); // Get the arguments in the right order if (!args_.reserve(argc)) return false; if (constructing()) setNewTarget(current->pop()); for (int32_t i = argc; i > 0; i--) args_.infallibleAppend(current->peek(-i)); current->popn(argc); // Get |this| and |fun| setThis(current->pop()); setFun(current->pop()); return true; } void popFormals(MBasicBlock* current) { current->popn(numFormals()); } void pushFormals(MBasicBlock* current) { current->push(fun()); current->push(thisArg()); for (uint32_t i = 0; i < argc(); i++) current->push(getArg(i)); if (constructing()) current->push(getNewTarget()); } uint32_t argc() const { return args_.length(); } uint32_t numFormals() const { return argc() + 2 + constructing(); } MOZ_MUST_USE bool setArgs(const MDefinitionVector& args) { MOZ_ASSERT(args_.empty()); return args_.appendAll(args); } MDefinitionVector& argv() { return args_; } const MDefinitionVector& argv() const { return args_; } MDefinition* getArg(uint32_t i) const { MOZ_ASSERT(i < argc()); return args_[i]; } MDefinition* getArgWithDefault(uint32_t i, MDefinition* defaultValue) const { if (i < argc()) return args_[i]; return defaultValue; } void setArg(uint32_t i, MDefinition* def) { MOZ_ASSERT(i < argc()); args_[i] = def; } MDefinition* thisArg() const { MOZ_ASSERT(thisArg_); return thisArg_; } void setThis(MDefinition* thisArg) { thisArg_ = thisArg; } bool constructing() const { return constructing_; } bool ignoresReturnValue() const { return ignoresReturnValue_; } void setNewTarget(MDefinition* newTarget) { MOZ_ASSERT(constructing()); newTargetArg_ = newTarget; } MDefinition* getNewTarget() const { MOZ_ASSERT(newTargetArg_); return newTargetArg_; } bool isSetter() const { return setter_; } void markAsSetter() { setter_ = true; } MDefinition* fun() const { MOZ_ASSERT(fun_); return fun_; } void setFun(MDefinition* fun) { fun_ = fun; } void setImplicitlyUsedUnchecked() { fun_->setImplicitlyUsedUnchecked(); thisArg_->setImplicitlyUsedUnchecked(); if (newTargetArg_) newTargetArg_->setImplicitlyUsedUnchecked(); for (uint32_t i = 0; i < argc(); i++) getArg(i)->setImplicitlyUsedUnchecked(); } }; bool NeedsPostBarrier(MDefinition* value); } // namespace jit } // namespace js #endif /* jit_IonBuilder_h */