/* -*- 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/. */ /* JS bytecode generation. */ #ifndef frontend_BytecodeEmitter_h #define frontend_BytecodeEmitter_h #include "jscntxt.h" #include "jsopcode.h" #include "jsscript.h" #include "ds/InlineTable.h" #include "frontend/Parser.h" #include "frontend/SharedContext.h" #include "frontend/SourceNotes.h" #include "vm/Interpreter.h" namespace js { namespace frontend { class FullParseHandler; class ObjectBox; class ParseNode; template class Parser; class SharedContext; class TokenStream; class CGConstList { Vector list; public: explicit CGConstList(ExclusiveContext* cx) : list(cx) {} MOZ_MUST_USE bool append(const Value& v) { MOZ_ASSERT_IF(v.isString(), v.toString()->isAtom()); return list.append(v); } size_t length() const { return list.length(); } void finish(ConstArray* array); }; struct CGObjectList { uint32_t length; /* number of emitted so far objects */ ObjectBox* lastbox; /* last emitted object */ CGObjectList() : length(0), lastbox(nullptr) {} unsigned add(ObjectBox* objbox); unsigned indexOf(JSObject* obj); void finish(ObjectArray* array); ObjectBox* find(uint32_t index); }; struct MOZ_STACK_CLASS CGScopeList { Rooted> vector; explicit CGScopeList(ExclusiveContext* cx) : vector(cx, GCVector(cx)) { } bool append(Scope* scope) { return vector.append(scope); } uint32_t length() const { return vector.length(); } void finish(ScopeArray* array); }; struct CGTryNoteList { Vector list; explicit CGTryNoteList(ExclusiveContext* cx) : list(cx) {} MOZ_MUST_USE bool append(JSTryNoteKind kind, uint32_t stackDepth, size_t start, size_t end); size_t length() const { return list.length(); } void finish(TryNoteArray* array); }; struct CGScopeNote : public ScopeNote { // The end offset. Used to compute the length; may need adjusting first if // in the prologue. uint32_t end; // Is the start offset in the prologue? bool startInPrologue; // Is the end offset in the prologue? bool endInPrologue; }; struct CGScopeNoteList { Vector list; explicit CGScopeNoteList(ExclusiveContext* cx) : list(cx) {} MOZ_MUST_USE bool append(uint32_t scopeIndex, uint32_t offset, bool inPrologue, uint32_t parent); void recordEnd(uint32_t index, uint32_t offset, bool inPrologue); size_t length() const { return list.length(); } void finish(ScopeNoteArray* array, uint32_t prologueLength); }; struct CGYieldOffsetList { Vector list; explicit CGYieldOffsetList(ExclusiveContext* cx) : list(cx) {} MOZ_MUST_USE bool append(uint32_t offset) { return list.append(offset); } size_t length() const { return list.length(); } void finish(YieldOffsetArray& array, uint32_t prologueLength); }; // Use zero inline elements because these go on the stack and affect how many // nested functions are possible. typedef Vector BytecodeVector; typedef Vector SrcNotesVector; // Linked list of jump instructions that need to be patched. The linked list is // stored in the bytes of the incomplete bytecode that will be patched, so no // extra memory is needed, and patching the instructions destroys the list. // // Example: // // JumpList brList; // if (!emitJump(JSOP_IFEQ, &brList)) // return false; // ... // JumpTarget label; // if (!emitJumpTarget(&label)) // return false; // ... // if (!emitJump(JSOP_GOTO, &brList)) // return false; // ... // patchJumpsToTarget(brList, label); // // +-> -1 // | // | // ifeq .. <+ + +-+ ifeq .. // .. | | .. // label: | +-> label: // jumptarget | | jumptarget // .. | | .. // goto .. <+ + +-+ goto .. <+ // | | // | | // + + // brList brList // // | ^ // +------- patchJumpsToTarget -------+ // // Offset of a jump target instruction, used for patching jump instructions. struct JumpTarget { ptrdiff_t offset; }; struct JumpList { // -1 is used to mark the end of jump lists. JumpList() : offset(-1) {} ptrdiff_t offset; // Add a jump instruction to the list. void push(jsbytecode* code, ptrdiff_t jumpOffset); // Patch all jump instructions in this list to jump to `target`. This // clobbers the list. void patchAll(jsbytecode* code, JumpTarget target); }; struct MOZ_STACK_CLASS BytecodeEmitter { class TDZCheckCache; class NestableControl; class EmitterScope; SharedContext* const sc; /* context shared between parsing and bytecode generation */ ExclusiveContext* const cx; BytecodeEmitter* const parent; /* enclosing function or global context */ Rooted script; /* the JSScript we're ultimately producing */ Rooted lazyScript; /* the lazy script if mode is LazyFunction, nullptr otherwise. */ struct EmitSection { BytecodeVector code; /* bytecode */ SrcNotesVector notes; /* source notes, see below */ ptrdiff_t lastNoteOffset; /* code offset for last source note */ uint32_t currentLine; /* line number for tree-based srcnote gen */ uint32_t lastColumn; /* zero-based column index on currentLine of last SRC_COLSPAN-annotated opcode */ JumpTarget lastTarget; // Last jump target emitted. EmitSection(ExclusiveContext* cx, uint32_t lineNum) : code(cx), notes(cx), lastNoteOffset(0), currentLine(lineNum), lastColumn(0), lastTarget{ -1 - ptrdiff_t(JSOP_JUMPTARGET_LENGTH) } {} }; EmitSection prologue, main, *current; Parser* const parser; PooledMapPtr atomIndices; /* literals indexed for mapping */ unsigned firstLine; /* first line, for JSScript::initFromEmitter */ uint32_t maxFixedSlots; /* maximum number of fixed frame slots so far */ uint32_t maxStackDepth; /* maximum number of expression stack slots so far */ int32_t stackDepth; /* current stack depth in script frame */ uint32_t arrayCompDepth; /* stack depth of array in comprehension */ unsigned emitLevel; /* emitTree recursion level */ uint32_t bodyScopeIndex; /* index into scopeList of the body scope */ EmitterScope* varEmitterScope; NestableControl* innermostNestableControl; EmitterScope* innermostEmitterScope; TDZCheckCache* innermostTDZCheckCache; CGConstList constList; /* constants to be included with the script */ CGObjectList objectList; /* list of emitted objects */ CGScopeList scopeList; /* list of emitted scopes */ CGTryNoteList tryNoteList; /* list of emitted try notes */ CGScopeNoteList scopeNoteList; /* list of emitted block scope notes */ /* * For each yield op, map the yield index (stored as bytecode operand) to * the offset of the next op. */ CGYieldOffsetList yieldOffsetList; uint16_t typesetCount; /* Number of JOF_TYPESET opcodes generated */ bool hasSingletons:1; /* script contains singleton initializer JSOP_OBJECT */ bool hasTryFinally:1; /* script contains finally block */ bool emittingRunOnceLambda:1; /* true while emitting a lambda which is only expected to run once. */ bool isRunOnceLambda(); enum EmitterMode { Normal, /* * Emit JSOP_GETINTRINSIC instead of JSOP_GETNAME and assert that * JSOP_GETNAME and JSOP_*GNAME don't ever get emitted. See the comment * for the field |selfHostingMode| in Parser.h for details. */ SelfHosting, /* * Check the static scope chain of the root function for resolving free * variable accesses in the script. */ LazyFunction }; const EmitterMode emitterMode; // The end location of a function body that is being emitted. uint32_t functionBodyEndPos; // Whether functionBodyEndPos was set. bool functionBodyEndPosSet; /* * Note that BytecodeEmitters are magic: they own the arena "top-of-stack" * space above their tempMark points. This means that you cannot alloc from * tempLifoAlloc and save the pointer beyond the next BytecodeEmitter * destruction. */ BytecodeEmitter(BytecodeEmitter* parent, Parser* parser, SharedContext* sc, HandleScript script, Handle lazyScript, uint32_t lineNum, EmitterMode emitterMode = Normal); // An alternate constructor that uses a TokenPos for the starting // line and that sets functionBodyEndPos as well. BytecodeEmitter(BytecodeEmitter* parent, Parser* parser, SharedContext* sc, HandleScript script, Handle lazyScript, TokenPos bodyPosition, EmitterMode emitterMode = Normal); MOZ_MUST_USE bool init(); template bool */> NestableControl* findInnermostNestableControl(Predicate predicate) const; template T* findInnermostNestableControl() const; template bool */> T* findInnermostNestableControl(Predicate predicate) const; NameLocation lookupName(JSAtom* name); // To implement Annex B and the formal parameter defaults scope semantics // requires accessing names that would otherwise be shadowed. This method // returns the access location of a name that is known to be bound in a // target scope. mozilla::Maybe locationOfNameBoundInScope(JSAtom* name, EmitterScope* target); // Get the location of a name known to be bound in the function scope, // starting at the source scope. mozilla::Maybe locationOfNameBoundInFunctionScope(JSAtom* name, EmitterScope* source); mozilla::Maybe locationOfNameBoundInFunctionScope(JSAtom* name) { return locationOfNameBoundInFunctionScope(name, innermostEmitterScope); } void setVarEmitterScope(EmitterScope* emitterScope) { MOZ_ASSERT(emitterScope); MOZ_ASSERT(!varEmitterScope); varEmitterScope = emitterScope; } Scope* bodyScope() const { return scopeList.vector[bodyScopeIndex]; } Scope* outermostScope() const { return scopeList.vector[0]; } Scope* innermostScope() const; MOZ_ALWAYS_INLINE MOZ_MUST_USE bool makeAtomIndex(JSAtom* atom, uint32_t* indexp) { MOZ_ASSERT(atomIndices); AtomIndexMap::AddPtr p = atomIndices->lookupForAdd(atom); if (p) { *indexp = p->value(); return true; } uint32_t index = atomIndices->count(); if (!atomIndices->add(p, atom, index)) return false; *indexp = index; return true; } bool isInLoop(); MOZ_MUST_USE bool checkSingletonContext(); // Check whether our function is in a run-once context (a toplevel // run-one script or a run-once lambda). MOZ_MUST_USE bool checkRunOnceContext(); bool needsImplicitThis(); MOZ_MUST_USE bool maybeSetDisplayURL(); MOZ_MUST_USE bool maybeSetSourceMap(); void tellDebuggerAboutCompiledScript(ExclusiveContext* cx); inline TokenStream* tokenStream(); BytecodeVector& code() const { return current->code; } jsbytecode* code(ptrdiff_t offset) const { return current->code.begin() + offset; } ptrdiff_t offset() const { return current->code.end() - current->code.begin(); } ptrdiff_t prologueOffset() const { return prologue.code.end() - prologue.code.begin(); } void switchToMain() { current = &main; } void switchToPrologue() { current = &prologue; } bool inPrologue() const { return current == &prologue; } SrcNotesVector& notes() const { return current->notes; } ptrdiff_t lastNoteOffset() const { return current->lastNoteOffset; } unsigned currentLine() const { return current->currentLine; } unsigned lastColumn() const { return current->lastColumn; } // Check if the last emitted opcode is a jump target. bool lastOpcodeIsJumpTarget() const { return offset() - current->lastTarget.offset == ptrdiff_t(JSOP_JUMPTARGET_LENGTH); } // JumpTarget should not be part of the emitted statement, as they can be // aliased by multiple statements. If we included the jump target as part of // the statement we might have issues where the enclosing statement might // not contain all the opcodes of the enclosed statements. ptrdiff_t lastNonJumpTargetOffset() const { return lastOpcodeIsJumpTarget() ? current->lastTarget.offset : offset(); } void setFunctionBodyEndPos(TokenPos pos) { functionBodyEndPos = pos.end; functionBodyEndPosSet = true; } bool reportError(ParseNode* pn, unsigned errorNumber, ...); bool reportStrictWarning(ParseNode* pn, unsigned errorNumber, ...); bool reportStrictModeError(ParseNode* pn, unsigned errorNumber, ...); // If pn contains a useful expression, return true with *answer set to true. // If pn contains a useless expression, return true with *answer set to // false. Return false on error. // // The caller should initialize *answer to false and invoke this function on // an expression statement or similar subtree to decide whether the tree // could produce code that has any side effects. For an expression // statement, we define useless code as code with no side effects, because // the main effect, the value left on the stack after the code executes, // will be discarded by a pop bytecode. MOZ_MUST_USE bool checkSideEffects(ParseNode* pn, bool* answer); #ifdef DEBUG MOZ_MUST_USE bool checkStrictOrSloppy(JSOp op); #endif // Append a new source note of the given type (and therefore size) to the // notes dynamic array, updating noteCount. Return the new note's index // within the array pointed at by current->notes as outparam. MOZ_MUST_USE bool newSrcNote(SrcNoteType type, unsigned* indexp = nullptr); MOZ_MUST_USE bool newSrcNote2(SrcNoteType type, ptrdiff_t offset, unsigned* indexp = nullptr); MOZ_MUST_USE bool newSrcNote3(SrcNoteType type, ptrdiff_t offset1, ptrdiff_t offset2, unsigned* indexp = nullptr); void copySrcNotes(jssrcnote* destination, uint32_t nsrcnotes); MOZ_MUST_USE bool setSrcNoteOffset(unsigned index, unsigned which, ptrdiff_t offset); // NB: this function can add at most one extra extended delta note. MOZ_MUST_USE bool addToSrcNoteDelta(jssrcnote* sn, ptrdiff_t delta); // Finish taking source notes in cx's notePool. If successful, the final // source note count is stored in the out outparam. MOZ_MUST_USE bool finishTakingSrcNotes(uint32_t* out); // Control whether emitTree emits a line number note. enum EmitLineNumberNote { EMIT_LINENOTE, SUPPRESS_LINENOTE }; // Emit code for the tree rooted at pn. MOZ_MUST_USE bool emitTree(ParseNode* pn, EmitLineNumberNote emitLineNote = EMIT_LINENOTE); // Emit code for the tree rooted at pn with its own TDZ cache. MOZ_MUST_USE bool emitTreeInBranch(ParseNode* pn); // Emit global, eval, or module code for tree rooted at body. Always // encompasses the entire source. MOZ_MUST_USE bool emitScript(ParseNode* body); // Emit function code for the tree rooted at body. MOZ_MUST_USE bool emitFunctionScript(ParseNode* body); // If op is JOF_TYPESET (see the type barriers comment in TypeInference.h), // reserve a type set to store its result. void checkTypeSet(JSOp op); void updateDepth(ptrdiff_t target); MOZ_MUST_USE bool updateLineNumberNotes(uint32_t offset); MOZ_MUST_USE bool updateSourceCoordNotes(uint32_t offset); JSOp strictifySetNameOp(JSOp op); MOZ_MUST_USE bool flushPops(int* npops); MOZ_MUST_USE bool emitCheck(ptrdiff_t delta, ptrdiff_t* offset); // Emit one bytecode. MOZ_MUST_USE bool emit1(JSOp op); // Emit two bytecodes, an opcode (op) with a byte of immediate operand // (op1). MOZ_MUST_USE bool emit2(JSOp op, uint8_t op1); // Emit three bytecodes, an opcode with two bytes of immediate operands. MOZ_MUST_USE bool emit3(JSOp op, jsbytecode op1, jsbytecode op2); // Helper to emit JSOP_DUPAT. The argument is the value's depth on the // JS stack, as measured from the top. MOZ_MUST_USE bool emitDupAt(unsigned slotFromTop); // Helper to emit JSOP_CHECKISOBJ. MOZ_MUST_USE bool emitCheckIsObj(CheckIsObjectKind kind); // Emit a bytecode followed by an uint16 immediate operand stored in // big-endian order. MOZ_MUST_USE bool emitUint16Operand(JSOp op, uint32_t operand); // Emit a bytecode followed by an uint32 immediate operand. MOZ_MUST_USE bool emitUint32Operand(JSOp op, uint32_t operand); // Emit (1 + extra) bytecodes, for N bytes of op and its immediate operand. MOZ_MUST_USE bool emitN(JSOp op, size_t extra, ptrdiff_t* offset = nullptr); MOZ_MUST_USE bool emitNumberOp(double dval); MOZ_MUST_USE bool emitThisLiteral(ParseNode* pn); MOZ_MUST_USE bool emitGetFunctionThis(ParseNode* pn); MOZ_MUST_USE bool emitGetThisForSuperBase(ParseNode* pn); MOZ_MUST_USE bool emitSetThis(ParseNode* pn); MOZ_MUST_USE bool emitCheckDerivedClassConstructorReturn(); // Handle jump opcodes and jump targets. MOZ_MUST_USE bool emitJumpTarget(JumpTarget* target); MOZ_MUST_USE bool emitJumpNoFallthrough(JSOp op, JumpList* jump); MOZ_MUST_USE bool emitJump(JSOp op, JumpList* jump); MOZ_MUST_USE bool emitBackwardJump(JSOp op, JumpTarget target, JumpList* jump, JumpTarget* fallthrough); void patchJumpsToTarget(JumpList jump, JumpTarget target); MOZ_MUST_USE bool emitJumpTargetAndPatch(JumpList jump); MOZ_MUST_USE bool emitCall(JSOp op, uint16_t argc, ParseNode* pn = nullptr); MOZ_MUST_USE bool emitCallIncDec(ParseNode* incDec); MOZ_MUST_USE bool emitLoopHead(ParseNode* nextpn, JumpTarget* top); MOZ_MUST_USE bool emitLoopEntry(ParseNode* nextpn, JumpList entryJump); MOZ_MUST_USE bool emitGoto(NestableControl* target, JumpList* jumplist, SrcNoteType noteType = SRC_NULL); MOZ_MUST_USE bool emitIndex32(JSOp op, uint32_t index); MOZ_MUST_USE bool emitIndexOp(JSOp op, uint32_t index); MOZ_MUST_USE bool emitAtomOp(JSAtom* atom, JSOp op); MOZ_MUST_USE bool emitAtomOp(ParseNode* pn, JSOp op); MOZ_MUST_USE bool emitArrayLiteral(ParseNode* pn); MOZ_MUST_USE bool emitArray(ParseNode* pn, uint32_t count, JSOp op); MOZ_MUST_USE bool emitArrayComp(ParseNode* pn); MOZ_MUST_USE bool emitInternedScopeOp(uint32_t index, JSOp op); MOZ_MUST_USE bool emitInternedObjectOp(uint32_t index, JSOp op); MOZ_MUST_USE bool emitObjectOp(ObjectBox* objbox, JSOp op); MOZ_MUST_USE bool emitObjectPairOp(ObjectBox* objbox1, ObjectBox* objbox2, JSOp op); MOZ_MUST_USE bool emitRegExp(uint32_t index); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitFunction(ParseNode* pn, bool needsProto = false); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitObject(ParseNode* pn); MOZ_MUST_USE bool emitHoistedFunctionsInList(ParseNode* pn); MOZ_MUST_USE bool emitPropertyList(ParseNode* pn, MutableHandlePlainObject objp, PropListType type); // To catch accidental misuse, emitUint16Operand/emit3 assert that they are // not used to unconditionally emit JSOP_GETLOCAL. Variable access should // instead be emitted using EmitVarOp. In special cases, when the caller // definitely knows that a given local slot is unaliased, this function may be // used as a non-asserting version of emitUint16Operand. MOZ_MUST_USE bool emitLocalOp(JSOp op, uint32_t slot); MOZ_MUST_USE bool emitArgOp(JSOp op, uint16_t slot); MOZ_MUST_USE bool emitEnvCoordOp(JSOp op, EnvironmentCoordinate ec); MOZ_MUST_USE bool emitGetNameAtLocation(JSAtom* name, const NameLocation& loc, bool callContext = false); MOZ_MUST_USE bool emitGetName(JSAtom* name, bool callContext = false) { return emitGetNameAtLocation(name, lookupName(name), callContext); } MOZ_MUST_USE bool emitGetName(ParseNode* pn, bool callContext = false); template MOZ_MUST_USE bool emitSetOrInitializeNameAtLocation(HandleAtom name, const NameLocation& loc, RHSEmitter emitRhs, bool initialize); template MOZ_MUST_USE bool emitSetOrInitializeName(HandleAtom name, RHSEmitter emitRhs, bool initialize) { return emitSetOrInitializeNameAtLocation(name, lookupName(name), emitRhs, initialize); } template MOZ_MUST_USE bool emitSetName(ParseNode* pn, RHSEmitter emitRhs) { RootedAtom name(cx, pn->name()); return emitSetName(name, emitRhs); } template MOZ_MUST_USE bool emitSetName(HandleAtom name, RHSEmitter emitRhs) { return emitSetOrInitializeName(name, emitRhs, false); } template MOZ_MUST_USE bool emitInitializeName(ParseNode* pn, RHSEmitter emitRhs) { RootedAtom name(cx, pn->name()); return emitInitializeName(name, emitRhs); } template MOZ_MUST_USE bool emitInitializeName(HandleAtom name, RHSEmitter emitRhs) { return emitSetOrInitializeName(name, emitRhs, true); } MOZ_MUST_USE bool emitTDZCheckIfNeeded(JSAtom* name, const NameLocation& loc); MOZ_MUST_USE bool emitNameIncDec(ParseNode* pn); MOZ_MUST_USE bool emitDeclarationList(ParseNode* decls); MOZ_MUST_USE bool emitSingleDeclaration(ParseNode* decls, ParseNode* decl, ParseNode* initializer); MOZ_MUST_USE bool emitNewInit(JSProtoKey key); MOZ_MUST_USE bool emitSingletonInitialiser(ParseNode* pn); MOZ_MUST_USE bool emitPrepareIteratorResult(); MOZ_MUST_USE bool emitFinishIteratorResult(bool done); MOZ_MUST_USE bool iteratorResultShape(unsigned* shape); MOZ_MUST_USE bool emitYield(ParseNode* pn); MOZ_MUST_USE bool emitYieldOp(JSOp op); MOZ_MUST_USE bool emitYieldStar(ParseNode* iter, ParseNode* gen); MOZ_MUST_USE bool emitPropLHS(ParseNode* pn); MOZ_MUST_USE bool emitPropOp(ParseNode* pn, JSOp op); MOZ_MUST_USE bool emitPropIncDec(ParseNode* pn); MOZ_MUST_USE bool emitAsyncWrapperLambda(unsigned index, bool isArrow); MOZ_MUST_USE bool emitAsyncWrapper(unsigned index, bool needsHomeObject, bool isArrow); MOZ_MUST_USE bool emitComputedPropertyName(ParseNode* computedPropName); // Emit bytecode to put operands for a JSOP_GETELEM/CALLELEM/SETELEM/DELELEM // opcode onto the stack in the right order. In the case of SETELEM, the // value to be assigned must already be pushed. enum class EmitElemOption { Get, Set, Call, IncDec, CompoundAssign, Ref }; MOZ_MUST_USE bool emitElemOperands(ParseNode* pn, EmitElemOption opts); MOZ_MUST_USE bool emitElemOpBase(JSOp op); MOZ_MUST_USE bool emitElemOp(ParseNode* pn, JSOp op); MOZ_MUST_USE bool emitElemIncDec(ParseNode* pn); MOZ_MUST_USE bool emitCatch(ParseNode* pn); MOZ_MUST_USE bool emitIf(ParseNode* pn); MOZ_MUST_USE bool emitWith(ParseNode* pn); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitLabeledStatement(const LabeledStatement* pn); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitLexicalScope(ParseNode* pn); MOZ_MUST_USE bool emitLexicalScopeBody(ParseNode* body, EmitLineNumberNote emitLineNote = EMIT_LINENOTE); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitSwitch(ParseNode* pn); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitTry(ParseNode* pn); enum DestructuringFlavor { // Destructuring into a declaration. DestructuringDeclaration, // Destructuring into a formal parameter, when the formal parameters // contain an expression that might be evaluated, and thus require // this destructuring to assign not into the innermost scope that // contains the function body's vars, but into its enclosing scope for // parameter expressions. DestructuringFormalParameterInVarScope, // Destructuring as part of an AssignmentExpression. DestructuringAssignment }; // emitDestructuringLHSRef emits the lhs expression's reference. // If the lhs expression is object property |OBJ.prop|, it emits |OBJ|. // If it's object element |OBJ[ELEM]|, it emits |OBJ| and |ELEM|. // If there's nothing to evaluate for the reference, it emits nothing. // |emitted| parameter receives the number of values pushed onto the stack. MOZ_MUST_USE bool emitDestructuringLHSRef(ParseNode* target, size_t* emitted); // emitSetOrInitializeDestructuring assumes the lhs expression's reference // and the to-be-destructured value has been pushed on the stack. It emits // code to destructure a single lhs expression (either a name or a compound // []/{} expression). MOZ_MUST_USE bool emitSetOrInitializeDestructuring(ParseNode* target, DestructuringFlavor flav); // emitDestructuringOps assumes the to-be-destructured value has been // pushed on the stack and emits code to destructure each part of a [] or // {} lhs expression. MOZ_MUST_USE bool emitDestructuringOps(ParseNode* pattern, DestructuringFlavor flav); MOZ_MUST_USE bool emitDestructuringOpsArray(ParseNode* pattern, DestructuringFlavor flav); MOZ_MUST_USE bool emitDestructuringOpsObject(ParseNode* pattern, DestructuringFlavor flav); typedef bool (*DestructuringDeclEmitter)(BytecodeEmitter* bce, ParseNode* pn); template MOZ_MUST_USE bool emitDestructuringDeclsWithEmitter(ParseNode* pattern, NameEmitter emitName); // Throw a TypeError if the value atop the stack isn't convertible to an // object, with no overall effect on the stack. MOZ_MUST_USE bool emitRequireObjectCoercible(); // emitIterator expects the iterable to already be on the stack. // It will replace that stack value with the corresponding iterator MOZ_MUST_USE bool emitIterator(); // Pops iterator from the top of the stack. Pushes the result of |.next()| // onto the stack. MOZ_MUST_USE bool emitIteratorNext(ParseNode* pn, bool allowSelfHosted = false); // Check if the value on top of the stack is "undefined". If so, replace // that value on the stack with the value defined by |defaultExpr|. // |pattern| is a lhs node of the default expression. If it's an // identifier and |defaultExpr| is an anonymous function, |SetFunctionName| // is called at compile time. MOZ_MUST_USE bool emitDefault(ParseNode* defaultExpr, ParseNode* pattern); MOZ_MUST_USE bool setOrEmitSetFunName(ParseNode* maybeFun, HandleAtom name, FunctionPrefixKind prefixKind); MOZ_MUST_USE bool emitInitializer(ParseNode* initializer, ParseNode* pattern); MOZ_MUST_USE bool emitInitializerInBranch(ParseNode* initializer, ParseNode* pattern); MOZ_MUST_USE bool emitCallSiteObject(ParseNode* pn); MOZ_MUST_USE bool emitTemplateString(ParseNode* pn); MOZ_MUST_USE bool emitAssignment(ParseNode* lhs, JSOp op, ParseNode* rhs); MOZ_MUST_USE bool emitReturn(ParseNode* pn); MOZ_MUST_USE bool emitStatement(ParseNode* pn); MOZ_MUST_USE bool emitStatementList(ParseNode* pn); MOZ_MUST_USE bool emitDeleteName(ParseNode* pn); MOZ_MUST_USE bool emitDeleteProperty(ParseNode* pn); MOZ_MUST_USE bool emitDeleteElement(ParseNode* pn); MOZ_MUST_USE bool emitDeleteExpression(ParseNode* pn); // |op| must be JSOP_TYPEOF or JSOP_TYPEOFEXPR. MOZ_MUST_USE bool emitTypeof(ParseNode* node, JSOp op); MOZ_MUST_USE bool emitUnary(ParseNode* pn); MOZ_MUST_USE bool emitRightAssociative(ParseNode* pn); MOZ_MUST_USE bool emitLeftAssociative(ParseNode* pn); MOZ_MUST_USE bool emitLogical(ParseNode* pn); MOZ_MUST_USE bool emitSequenceExpr(ParseNode* pn); MOZ_NEVER_INLINE MOZ_MUST_USE bool emitIncOrDec(ParseNode* pn); MOZ_MUST_USE bool emitConditionalExpression(ConditionalExpression& conditional); MOZ_MUST_USE bool isRestParameter(ParseNode* pn, bool* result); MOZ_MUST_USE bool emitOptimizeSpread(ParseNode* arg0, JumpList* jmp, bool* emitted); MOZ_MUST_USE bool emitCallOrNew(ParseNode* pn); MOZ_MUST_USE bool emitSelfHostedCallFunction(ParseNode* pn); MOZ_MUST_USE bool emitSelfHostedResumeGenerator(ParseNode* pn); MOZ_MUST_USE bool emitSelfHostedForceInterpreter(ParseNode* pn); MOZ_MUST_USE bool emitSelfHostedAllowContentSpread(ParseNode* pn); MOZ_MUST_USE bool emitComprehensionFor(ParseNode* compFor); MOZ_MUST_USE bool emitComprehensionForIn(ParseNode* pn); MOZ_MUST_USE bool emitComprehensionForInOrOfVariables(ParseNode* pn, bool* lexicalScope); MOZ_MUST_USE bool emitComprehensionForOf(ParseNode* pn); MOZ_MUST_USE bool emitDo(ParseNode* pn); MOZ_MUST_USE bool emitWhile(ParseNode* pn); MOZ_MUST_USE bool emitFor(ParseNode* pn, EmitterScope* headLexicalEmitterScope = nullptr); MOZ_MUST_USE bool emitCStyleFor(ParseNode* pn, EmitterScope* headLexicalEmitterScope); MOZ_MUST_USE bool emitForIn(ParseNode* pn, EmitterScope* headLexicalEmitterScope); MOZ_MUST_USE bool emitForOf(ParseNode* pn, EmitterScope* headLexicalEmitterScope); MOZ_MUST_USE bool emitInitializeForInOrOfTarget(ParseNode* forHead); MOZ_MUST_USE bool emitBreak(PropertyName* label); MOZ_MUST_USE bool emitContinue(PropertyName* label); MOZ_MUST_USE bool emitFunctionFormalParametersAndBody(ParseNode* pn); MOZ_MUST_USE bool emitFunctionFormalParameters(ParseNode* pn); MOZ_MUST_USE bool emitInitializeFunctionSpecialNames(); MOZ_MUST_USE bool emitFunctionBody(ParseNode* pn); MOZ_MUST_USE bool emitLexicalInitialization(ParseNode* pn); // Emit bytecode for the spread operator. // // emitSpread expects the current index (I) of the array, the array itself // and the iterator to be on the stack in that order (iterator on the bottom). // It will pop the iterator and I, then iterate over the iterator by calling // |.next()| and put the results into the I-th element of array with // incrementing I, then push the result I (it will be original I + // iteration count). The stack after iteration will look like |ARRAY INDEX|. MOZ_MUST_USE bool emitSpread(bool allowSelfHosted = false); MOZ_MUST_USE bool emitClass(ParseNode* pn); MOZ_MUST_USE bool emitSuperPropLHS(ParseNode* superBase, bool isCall = false); MOZ_MUST_USE bool emitSuperPropOp(ParseNode* pn, JSOp op, bool isCall = false); MOZ_MUST_USE bool emitSuperElemOperands(ParseNode* pn, EmitElemOption opts = EmitElemOption::Get); MOZ_MUST_USE bool emitSuperElemOp(ParseNode* pn, JSOp op, bool isCall = false); }; } /* namespace frontend */ } /* namespace js */ #endif /* frontend_BytecodeEmitter_h */