/* * Copyright (C) 2011-2016 Apple Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "config.h" #include "DFGByteCodeParser.h" #if ENABLE(DFG_JIT) #include "ArrayConstructor.h" #include "BasicBlockLocation.h" #include "CallLinkStatus.h" #include "CodeBlock.h" #include "CodeBlockWithJITType.h" #include "DFGAbstractHeap.h" #include "DFGArrayMode.h" #include "DFGCapabilities.h" #include "DFGClobberize.h" #include "DFGClobbersExitState.h" #include "DFGGraph.h" #include "DFGJITCode.h" #include "GetByIdStatus.h" #include "Heap.h" #include "JSLexicalEnvironment.h" #include "JSCInlines.h" #include "JSModuleEnvironment.h" #include "PreciseJumpTargets.h" #include "PutByIdFlags.h" #include "PutByIdStatus.h" #include "RegExpPrototype.h" #include "StackAlignment.h" #include "StringConstructor.h" #include "StructureStubInfo.h" #include "Watchdog.h" #include #include #include #include namespace JSC { namespace DFG { static const bool verbose = false; class ConstantBufferKey { public: ConstantBufferKey() : m_codeBlock(0) , m_index(0) { } ConstantBufferKey(WTF::HashTableDeletedValueType) : m_codeBlock(0) , m_index(1) { } ConstantBufferKey(CodeBlock* codeBlock, unsigned index) : m_codeBlock(codeBlock) , m_index(index) { } bool operator==(const ConstantBufferKey& other) const { return m_codeBlock == other.m_codeBlock && m_index == other.m_index; } unsigned hash() const { return WTF::PtrHash::hash(m_codeBlock) ^ m_index; } bool isHashTableDeletedValue() const { return !m_codeBlock && m_index; } CodeBlock* codeBlock() const { return m_codeBlock; } unsigned index() const { return m_index; } private: CodeBlock* m_codeBlock; unsigned m_index; }; struct ConstantBufferKeyHash { static unsigned hash(const ConstantBufferKey& key) { return key.hash(); } static bool equal(const ConstantBufferKey& a, const ConstantBufferKey& b) { return a == b; } static const bool safeToCompareToEmptyOrDeleted = true; }; } } // namespace JSC::DFG namespace WTF { template struct DefaultHash; template<> struct DefaultHash { typedef JSC::DFG::ConstantBufferKeyHash Hash; }; template struct HashTraits; template<> struct HashTraits : SimpleClassHashTraits { }; } // namespace WTF namespace JSC { namespace DFG { // === ByteCodeParser === // // This class is used to compile the dataflow graph from a CodeBlock. class ByteCodeParser { public: ByteCodeParser(Graph& graph) : m_vm(&graph.m_vm) , m_codeBlock(graph.m_codeBlock) , m_profiledBlock(graph.m_profiledBlock) , m_graph(graph) , m_currentBlock(0) , m_currentIndex(0) , m_constantUndefined(graph.freeze(jsUndefined())) , m_constantNull(graph.freeze(jsNull())) , m_constantNaN(graph.freeze(jsNumber(PNaN))) , m_constantOne(graph.freeze(jsNumber(1))) , m_numArguments(m_codeBlock->numParameters()) , m_numLocals(m_codeBlock->m_numCalleeLocals) , m_parameterSlots(0) , m_numPassedVarArgs(0) , m_inlineStackTop(0) , m_currentInstruction(0) , m_hasDebuggerEnabled(graph.hasDebuggerEnabled()) { ASSERT(m_profiledBlock); } // Parse a full CodeBlock of bytecode. bool parse(); private: struct InlineStackEntry; // Just parse from m_currentIndex to the end of the current CodeBlock. void parseCodeBlock(); void ensureLocals(unsigned newNumLocals) { if (newNumLocals <= m_numLocals) return; m_numLocals = newNumLocals; for (size_t i = 0; i < m_graph.numBlocks(); ++i) m_graph.block(i)->ensureLocals(newNumLocals); } // Helper for min and max. template bool handleMinMax(int resultOperand, NodeType op, int registerOffset, int argumentCountIncludingThis, const ChecksFunctor& insertChecks); void refineStatically(CallLinkStatus&, Node* callTarget); // Handle calls. This resolves issues surrounding inlining and intrinsics. enum Terminality { Terminal, NonTerminal }; Terminality handleCall( int result, NodeType op, InlineCallFrame::Kind, unsigned instructionSize, Node* callTarget, int argCount, int registerOffset, CallLinkStatus, SpeculatedType prediction); Terminality handleCall( int result, NodeType op, CallMode, unsigned instructionSize, Node* callTarget, int argCount, int registerOffset, CallLinkStatus); Terminality handleCall(int result, NodeType op, CallMode, unsigned instructionSize, int callee, int argCount, int registerOffset); Terminality handleCall(Instruction* pc, NodeType op, CallMode); Terminality handleVarargsCall(Instruction* pc, NodeType op, CallMode); void emitFunctionChecks(CallVariant, Node* callTarget, VirtualRegister thisArgumnt); void emitArgumentPhantoms(int registerOffset, int argumentCountIncludingThis); Node* getArgumentCount(); unsigned inliningCost(CallVariant, int argumentCountIncludingThis, CallMode); // Return UINT_MAX if it's not an inlining candidate. By convention, intrinsics have a cost of 1. // Handle inlining. Return true if it succeeded, false if we need to plant a call. bool handleInlining(Node* callTargetNode, int resultOperand, const CallLinkStatus&, int registerOffset, VirtualRegister thisArgument, VirtualRegister argumentsArgument, unsigned argumentsOffset, int argumentCountIncludingThis, unsigned nextOffset, NodeType callOp, InlineCallFrame::Kind, SpeculatedType prediction); enum CallerLinkability { CallerDoesNormalLinking, CallerLinksManually }; template bool attemptToInlineCall(Node* callTargetNode, int resultOperand, CallVariant, int registerOffset, int argumentCountIncludingThis, unsigned nextOffset, InlineCallFrame::Kind, CallerLinkability, SpeculatedType prediction, unsigned& inliningBalance, const ChecksFunctor& insertChecks); template void inlineCall(Node* callTargetNode, int resultOperand, CallVariant, int registerOffset, int argumentCountIncludingThis, unsigned nextOffset, InlineCallFrame::Kind, CallerLinkability, const ChecksFunctor& insertChecks); void cancelLinkingForBlock(InlineStackEntry*, BasicBlock*); // Only works when the given block is the last one to have been added for that inline stack entry. // Handle intrinsic functions. Return true if it succeeded, false if we need to plant a call. template bool handleIntrinsicCall(Node* callee, int resultOperand, Intrinsic, int registerOffset, int argumentCountIncludingThis, SpeculatedType prediction, const ChecksFunctor& insertChecks); template bool handleIntrinsicGetter(int resultOperand, const GetByIdVariant& intrinsicVariant, Node* thisNode, const ChecksFunctor& insertChecks); template bool handleTypedArrayConstructor(int resultOperand, InternalFunction*, int registerOffset, int argumentCountIncludingThis, TypedArrayType, const ChecksFunctor& insertChecks); template bool handleConstantInternalFunction(Node* callTargetNode, int resultOperand, InternalFunction*, int registerOffset, int argumentCountIncludingThis, CodeSpecializationKind, const ChecksFunctor& insertChecks); Node* handlePutByOffset(Node* base, unsigned identifier, PropertyOffset, const InferredType::Descriptor&, Node* value); Node* handleGetByOffset(SpeculatedType, Node* base, unsigned identifierNumber, PropertyOffset, const InferredType::Descriptor&, NodeType = GetByOffset); // Create a presence ObjectPropertyCondition based on some known offset and structure set. Does not // check the validity of the condition, but it may return a null one if it encounters a contradiction. ObjectPropertyCondition presenceLike( JSObject* knownBase, UniquedStringImpl*, PropertyOffset, const StructureSet&); // Attempt to watch the presence of a property. It will watch that the property is present in the same // way as in all of the structures in the set. It may emit code instead of just setting a watchpoint. // Returns true if this all works out. bool checkPresenceLike(JSObject* knownBase, UniquedStringImpl*, PropertyOffset, const StructureSet&); void checkPresenceLike(Node* base, UniquedStringImpl*, PropertyOffset, const StructureSet&); // Works with both GetByIdVariant and the setter form of PutByIdVariant. template Node* load(SpeculatedType, Node* base, unsigned identifierNumber, const VariantType&); Node* store(Node* base, unsigned identifier, const PutByIdVariant&, Node* value); void handleTryGetById(int destinationOperand, Node* base, unsigned identifierNumber, const GetByIdStatus&); void handleGetById( int destinationOperand, SpeculatedType, Node* base, unsigned identifierNumber, GetByIdStatus, AccessType); void emitPutById( Node* base, unsigned identifierNumber, Node* value, const PutByIdStatus&, bool isDirect); void handlePutById( Node* base, unsigned identifierNumber, Node* value, const PutByIdStatus&, bool isDirect); // Either register a watchpoint or emit a check for this condition. Returns false if the // condition no longer holds, and therefore no reasonable check can be emitted. bool check(const ObjectPropertyCondition&); GetByOffsetMethod promoteToConstant(GetByOffsetMethod); // Either register a watchpoint or emit a check for this condition. It must be a Presence // condition. It will attempt to promote a Presence condition to an Equivalence condition. // Emits code for the loaded value that the condition guards, and returns a node containing // the loaded value. Returns null if the condition no longer holds. GetByOffsetMethod planLoad(const ObjectPropertyCondition&); Node* load(SpeculatedType, unsigned identifierNumber, const GetByOffsetMethod&, NodeType = GetByOffset); Node* load(SpeculatedType, const ObjectPropertyCondition&, NodeType = GetByOffset); // Calls check() for each condition in the set: that is, it either emits checks or registers // watchpoints (or a combination of the two) to make the conditions hold. If any of those // conditions are no longer checkable, returns false. bool check(const ObjectPropertyConditionSet&); // Calls check() for those conditions that aren't the slot base, and calls load() for the slot // base. Does a combination of watchpoint registration and check emission to guard the // conditions, and emits code to load the value from the slot base. Returns a node containing // the loaded value. Returns null if any of the conditions were no longer checkable. GetByOffsetMethod planLoad(const ObjectPropertyConditionSet&); Node* load(SpeculatedType, const ObjectPropertyConditionSet&, NodeType = GetByOffset); void prepareToParseBlock(); void clearCaches(); // Parse a single basic block of bytecode instructions. bool parseBlock(unsigned limit); // Link block successors. void linkBlock(BasicBlock*, Vector& possibleTargets); void linkBlocks(Vector& unlinkedBlocks, Vector& possibleTargets); VariableAccessData* newVariableAccessData(VirtualRegister operand) { ASSERT(!operand.isConstant()); m_graph.m_variableAccessData.append(VariableAccessData(operand)); return &m_graph.m_variableAccessData.last(); } // Get/Set the operands/result of a bytecode instruction. Node* getDirect(VirtualRegister operand) { ASSERT(!operand.isConstant()); // Is this an argument? if (operand.isArgument()) return getArgument(operand); // Must be a local. return getLocal(operand); } Node* get(VirtualRegister operand) { if (operand.isConstant()) { unsigned constantIndex = operand.toConstantIndex(); unsigned oldSize = m_constants.size(); if (constantIndex >= oldSize || !m_constants[constantIndex]) { const CodeBlock& codeBlock = *m_inlineStackTop->m_codeBlock; JSValue value = codeBlock.getConstant(operand.offset()); SourceCodeRepresentation sourceCodeRepresentation = codeBlock.constantSourceCodeRepresentation(operand.offset()); if (constantIndex >= oldSize) { m_constants.grow(constantIndex + 1); for (unsigned i = oldSize; i < m_constants.size(); ++i) m_constants[i] = nullptr; } Node* constantNode = nullptr; if (sourceCodeRepresentation == SourceCodeRepresentation::Double) constantNode = addToGraph(DoubleConstant, OpInfo(m_graph.freezeStrong(jsDoubleNumber(value.asNumber())))); else constantNode = addToGraph(JSConstant, OpInfo(m_graph.freezeStrong(value))); m_constants[constantIndex] = constantNode; } ASSERT(m_constants[constantIndex]); return m_constants[constantIndex]; } if (inlineCallFrame()) { if (!inlineCallFrame()->isClosureCall) { JSFunction* callee = inlineCallFrame()->calleeConstant(); if (operand.offset() == JSStack::Callee) return weakJSConstant(callee); } } else if (operand.offset() == JSStack::Callee) { // We have to do some constant-folding here because this enables CreateThis folding. Note // that we don't have such watchpoint-based folding for inlined uses of Callee, since in that // case if the function is a singleton then we already know it. if (FunctionExecutable* executable = jsDynamicCast(m_codeBlock->ownerExecutable())) { InferredValue* singleton = executable->singletonFunction(); if (JSValue value = singleton->inferredValue()) { m_graph.watchpoints().addLazily(singleton); JSFunction* function = jsCast(value); return weakJSConstant(function); } } return addToGraph(GetCallee); } return getDirect(m_inlineStackTop->remapOperand(operand)); } enum SetMode { // A normal set which follows a two-phase commit that spans code origins. During // the current code origin it issues a MovHint, and at the start of the next // code origin there will be a SetLocal. If the local needs flushing, the second // SetLocal will be preceded with a Flush. NormalSet, // A set where the SetLocal happens immediately and there is still a Flush. This // is relevant when assigning to a local in tricky situations for the delayed // SetLocal logic but where we know that we have not performed any side effects // within this code origin. This is a safe replacement for NormalSet anytime we // know that we have not yet performed side effects in this code origin. ImmediateSetWithFlush, // A set where the SetLocal happens immediately and we do not Flush it even if // this is a local that is marked as needing it. This is relevant when // initializing locals at the top of a function. ImmediateNakedSet }; Node* setDirect(VirtualRegister operand, Node* value, SetMode setMode = NormalSet) { addToGraph(MovHint, OpInfo(operand.offset()), value); // We can't exit anymore because our OSR exit state has changed. m_exitOK = false; DelayedSetLocal delayed(currentCodeOrigin(), operand, value); if (setMode == NormalSet) { m_setLocalQueue.append(delayed); return 0; } return delayed.execute(this, setMode); } void processSetLocalQueue() { for (unsigned i = 0; i < m_setLocalQueue.size(); ++i) m_setLocalQueue[i].execute(this); m_setLocalQueue.resize(0); } Node* set(VirtualRegister operand, Node* value, SetMode setMode = NormalSet) { return setDirect(m_inlineStackTop->remapOperand(operand), value, setMode); } Node* injectLazyOperandSpeculation(Node* node) { ASSERT(node->op() == GetLocal); ASSERT(node->origin.semantic.bytecodeIndex == m_currentIndex); ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); LazyOperandValueProfileKey key(m_currentIndex, node->local()); SpeculatedType prediction = m_inlineStackTop->m_lazyOperands.prediction(locker, key); node->variableAccessData()->predict(prediction); return node; } // Used in implementing get/set, above, where the operand is a local variable. Node* getLocal(VirtualRegister operand) { unsigned local = operand.toLocal(); Node* node = m_currentBlock->variablesAtTail.local(local); // This has two goals: 1) link together variable access datas, and 2) // try to avoid creating redundant GetLocals. (1) is required for // correctness - no other phase will ensure that block-local variable // access data unification is done correctly. (2) is purely opportunistic // and is meant as an compile-time optimization only. VariableAccessData* variable; if (node) { variable = node->variableAccessData(); switch (node->op()) { case GetLocal: return node; case SetLocal: return node->child1().node(); default: break; } } else variable = newVariableAccessData(operand); node = injectLazyOperandSpeculation(addToGraph(GetLocal, OpInfo(variable))); m_currentBlock->variablesAtTail.local(local) = node; return node; } Node* setLocal(const CodeOrigin& semanticOrigin, VirtualRegister operand, Node* value, SetMode setMode = NormalSet) { CodeOrigin oldSemanticOrigin = m_currentSemanticOrigin; m_currentSemanticOrigin = semanticOrigin; unsigned local = operand.toLocal(); if (setMode != ImmediateNakedSet) { ArgumentPosition* argumentPosition = findArgumentPositionForLocal(operand); if (argumentPosition) flushDirect(operand, argumentPosition); else if (m_hasDebuggerEnabled && operand == m_codeBlock->scopeRegister()) flush(operand); } VariableAccessData* variableAccessData = newVariableAccessData(operand); variableAccessData->mergeStructureCheckHoistingFailed( m_inlineStackTop->m_exitProfile.hasExitSite(semanticOrigin.bytecodeIndex, BadCache)); variableAccessData->mergeCheckArrayHoistingFailed( m_inlineStackTop->m_exitProfile.hasExitSite(semanticOrigin.bytecodeIndex, BadIndexingType)); Node* node = addToGraph(SetLocal, OpInfo(variableAccessData), value); m_currentBlock->variablesAtTail.local(local) = node; m_currentSemanticOrigin = oldSemanticOrigin; return node; } // Used in implementing get/set, above, where the operand is an argument. Node* getArgument(VirtualRegister operand) { unsigned argument = operand.toArgument(); ASSERT(argument < m_numArguments); Node* node = m_currentBlock->variablesAtTail.argument(argument); VariableAccessData* variable; if (node) { variable = node->variableAccessData(); switch (node->op()) { case GetLocal: return node; case SetLocal: return node->child1().node(); default: break; } } else variable = newVariableAccessData(operand); node = injectLazyOperandSpeculation(addToGraph(GetLocal, OpInfo(variable))); m_currentBlock->variablesAtTail.argument(argument) = node; return node; } Node* setArgument(const CodeOrigin& semanticOrigin, VirtualRegister operand, Node* value, SetMode setMode = NormalSet) { CodeOrigin oldSemanticOrigin = m_currentSemanticOrigin; m_currentSemanticOrigin = semanticOrigin; unsigned argument = operand.toArgument(); ASSERT(argument < m_numArguments); VariableAccessData* variableAccessData = newVariableAccessData(operand); // Always flush arguments, except for 'this'. If 'this' is created by us, // then make sure that it's never unboxed. if (argument) { if (setMode != ImmediateNakedSet) flushDirect(operand); } else if (m_codeBlock->specializationKind() == CodeForConstruct) variableAccessData->mergeShouldNeverUnbox(true); variableAccessData->mergeStructureCheckHoistingFailed( m_inlineStackTop->m_exitProfile.hasExitSite(semanticOrigin.bytecodeIndex, BadCache)); variableAccessData->mergeCheckArrayHoistingFailed( m_inlineStackTop->m_exitProfile.hasExitSite(semanticOrigin.bytecodeIndex, BadIndexingType)); Node* node = addToGraph(SetLocal, OpInfo(variableAccessData), value); m_currentBlock->variablesAtTail.argument(argument) = node; m_currentSemanticOrigin = oldSemanticOrigin; return node; } ArgumentPosition* findArgumentPositionForArgument(int argument) { InlineStackEntry* stack = m_inlineStackTop; while (stack->m_inlineCallFrame) stack = stack->m_caller; return stack->m_argumentPositions[argument]; } ArgumentPosition* findArgumentPositionForLocal(VirtualRegister operand) { for (InlineStackEntry* stack = m_inlineStackTop; ; stack = stack->m_caller) { InlineCallFrame* inlineCallFrame = stack->m_inlineCallFrame; if (!inlineCallFrame) break; if (operand.offset() < static_cast(inlineCallFrame->stackOffset + JSStack::CallFrameHeaderSize)) continue; if (operand.offset() == inlineCallFrame->stackOffset + CallFrame::thisArgumentOffset()) continue; if (operand.offset() >= static_cast(inlineCallFrame->stackOffset + CallFrame::thisArgumentOffset() + inlineCallFrame->arguments.size())) continue; int argument = VirtualRegister(operand.offset() - inlineCallFrame->stackOffset).toArgument(); return stack->m_argumentPositions[argument]; } return 0; } ArgumentPosition* findArgumentPosition(VirtualRegister operand) { if (operand.isArgument()) return findArgumentPositionForArgument(operand.toArgument()); return findArgumentPositionForLocal(operand); } void flush(VirtualRegister operand) { flushDirect(m_inlineStackTop->remapOperand(operand)); } void flushDirect(VirtualRegister operand) { flushDirect(operand, findArgumentPosition(operand)); } void flushDirect(VirtualRegister operand, ArgumentPosition* argumentPosition) { ASSERT(!operand.isConstant()); Node* node = m_currentBlock->variablesAtTail.operand(operand); VariableAccessData* variable; if (node) variable = node->variableAccessData(); else variable = newVariableAccessData(operand); node = addToGraph(Flush, OpInfo(variable)); m_currentBlock->variablesAtTail.operand(operand) = node; if (argumentPosition) argumentPosition->addVariable(variable); } void flush(InlineStackEntry* inlineStackEntry) { int numArguments; if (InlineCallFrame* inlineCallFrame = inlineStackEntry->m_inlineCallFrame) { ASSERT(!m_hasDebuggerEnabled); numArguments = inlineCallFrame->arguments.size(); if (inlineCallFrame->isClosureCall) flushDirect(inlineStackEntry->remapOperand(VirtualRegister(JSStack::Callee))); if (inlineCallFrame->isVarargs()) flushDirect(inlineStackEntry->remapOperand(VirtualRegister(JSStack::ArgumentCount))); } else numArguments = inlineStackEntry->m_codeBlock->numParameters(); for (unsigned argument = numArguments; argument-- > 1;) flushDirect(inlineStackEntry->remapOperand(virtualRegisterForArgument(argument))); if (m_hasDebuggerEnabled) flush(m_codeBlock->scopeRegister()); } void flushForTerminal() { for (InlineStackEntry* inlineStackEntry = m_inlineStackTop; inlineStackEntry; inlineStackEntry = inlineStackEntry->m_caller) flush(inlineStackEntry); } void flushForReturn() { flush(m_inlineStackTop); } void flushIfTerminal(SwitchData& data) { if (data.fallThrough.bytecodeIndex() > m_currentIndex) return; for (unsigned i = data.cases.size(); i--;) { if (data.cases[i].target.bytecodeIndex() > m_currentIndex) return; } flushForTerminal(); } // Assumes that the constant should be strongly marked. Node* jsConstant(JSValue constantValue) { return addToGraph(JSConstant, OpInfo(m_graph.freezeStrong(constantValue))); } Node* weakJSConstant(JSValue constantValue) { return addToGraph(JSConstant, OpInfo(m_graph.freeze(constantValue))); } // Helper functions to get/set the this value. Node* getThis() { return get(m_inlineStackTop->m_codeBlock->thisRegister()); } void setThis(Node* value) { set(m_inlineStackTop->m_codeBlock->thisRegister(), value); } InlineCallFrame* inlineCallFrame() { return m_inlineStackTop->m_inlineCallFrame; } bool allInlineFramesAreTailCalls() { return !inlineCallFrame() || !inlineCallFrame()->getCallerSkippingTailCalls(); } CodeOrigin currentCodeOrigin() { return CodeOrigin(m_currentIndex, inlineCallFrame()); } NodeOrigin currentNodeOrigin() { CodeOrigin semantic; CodeOrigin forExit; if (m_currentSemanticOrigin.isSet()) semantic = m_currentSemanticOrigin; else semantic = currentCodeOrigin(); forExit = currentCodeOrigin(); return NodeOrigin(semantic, forExit, m_exitOK); } BranchData* branchData(unsigned taken, unsigned notTaken) { // We assume that branches originating from bytecode always have a fall-through. We // use this assumption to avoid checking for the creation of terminal blocks. ASSERT((taken > m_currentIndex) || (notTaken > m_currentIndex)); BranchData* data = m_graph.m_branchData.add(); *data = BranchData::withBytecodeIndices(taken, notTaken); return data; } Node* addToGraph(Node* node) { if (Options::verboseDFGByteCodeParsing()) dataLog(" appended ", node, " ", Graph::opName(node->op()), "\n"); m_currentBlock->append(node); if (clobbersExitState(m_graph, node)) m_exitOK = false; return node; } Node* addToGraph(NodeType op, Node* child1 = 0, Node* child2 = 0, Node* child3 = 0) { Node* result = m_graph.addNode( SpecNone, op, currentNodeOrigin(), Edge(child1), Edge(child2), Edge(child3)); return addToGraph(result); } Node* addToGraph(NodeType op, Edge child1, Edge child2 = Edge(), Edge child3 = Edge()) { Node* result = m_graph.addNode( SpecNone, op, currentNodeOrigin(), child1, child2, child3); return addToGraph(result); } Node* addToGraph(NodeType op, OpInfo info, Node* child1 = 0, Node* child2 = 0, Node* child3 = 0) { Node* result = m_graph.addNode( SpecNone, op, currentNodeOrigin(), info, Edge(child1), Edge(child2), Edge(child3)); return addToGraph(result); } Node* addToGraph(NodeType op, OpInfo info, Edge child1, Edge child2 = Edge(), Edge child3 = Edge()) { Node* result = m_graph.addNode(SpecNone, op, currentNodeOrigin(), info, child1, child2, child3); return addToGraph(result); } Node* addToGraph(NodeType op, OpInfo info1, OpInfo info2, Node* child1 = 0, Node* child2 = 0, Node* child3 = 0) { Node* result = m_graph.addNode( SpecNone, op, currentNodeOrigin(), info1, info2, Edge(child1), Edge(child2), Edge(child3)); return addToGraph(result); } Node* addToGraph(NodeType op, OpInfo info1, OpInfo info2, Edge child1, Edge child2 = Edge(), Edge child3 = Edge()) { Node* result = m_graph.addNode( SpecNone, op, currentNodeOrigin(), info1, info2, child1, child2, child3); return addToGraph(result); } Node* addToGraph(Node::VarArgTag, NodeType op, OpInfo info1, OpInfo info2) { Node* result = m_graph.addNode( SpecNone, Node::VarArg, op, currentNodeOrigin(), info1, info2, m_graph.m_varArgChildren.size() - m_numPassedVarArgs, m_numPassedVarArgs); addToGraph(result); m_numPassedVarArgs = 0; return result; } void addVarArgChild(Node* child) { m_graph.m_varArgChildren.append(Edge(child)); m_numPassedVarArgs++; } Node* addCallWithoutSettingResult( NodeType op, OpInfo opInfo, Node* callee, int argCount, int registerOffset, OpInfo prediction) { addVarArgChild(callee); size_t frameSize = JSStack::CallFrameHeaderSize + argCount; size_t alignedFrameSize = WTF::roundUpToMultipleOf(stackAlignmentRegisters(), frameSize); size_t parameterSlots = alignedFrameSize - JSStack::CallerFrameAndPCSize; if (parameterSlots > m_parameterSlots) m_parameterSlots = parameterSlots; for (int i = 0; i < argCount; ++i) addVarArgChild(get(virtualRegisterForArgument(i, registerOffset))); return addToGraph(Node::VarArg, op, opInfo, prediction); } Node* addCall( int result, NodeType op, OpInfo opInfo, Node* callee, int argCount, int registerOffset, SpeculatedType prediction) { if (op == TailCall) { if (allInlineFramesAreTailCalls()) return addCallWithoutSettingResult(op, OpInfo(), callee, argCount, registerOffset, OpInfo()); op = TailCallInlinedCaller; } Node* call = addCallWithoutSettingResult( op, opInfo, callee, argCount, registerOffset, OpInfo(prediction)); VirtualRegister resultReg(result); if (resultReg.isValid()) set(resultReg, call); return call; } Node* cellConstantWithStructureCheck(JSCell* object, Structure* structure) { // FIXME: This should route to emitPropertyCheck, not the other way around. But currently, // this gets no profit from using emitPropertyCheck() since we'll non-adaptively watch the // object's structure as soon as we make it a weakJSCosntant. Node* objectNode = weakJSConstant(object); addToGraph(CheckStructure, OpInfo(m_graph.addStructureSet(structure)), objectNode); return objectNode; } SpeculatedType getPredictionWithoutOSRExit(unsigned bytecodeIndex) { SpeculatedType prediction; CodeBlock* profiledBlock = nullptr; { ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); prediction = m_inlineStackTop->m_profiledBlock->valueProfilePredictionForBytecodeOffset(locker, bytecodeIndex); if (prediction == SpecNone) { // If we have no information about the values this // node generates, we check if by any chance it is // a tail call opcode. In that case, we walk up the // inline frames to find a call higher in the call // chain and use its prediction. If we only have // inlined tail call frames, we use SpecFullTop // to avoid a spurious OSR exit. Instruction* instruction = m_inlineStackTop->m_profiledBlock->instructions().begin() + bytecodeIndex; OpcodeID opcodeID = m_vm->interpreter->getOpcodeID(instruction->u.opcode); switch (opcodeID) { case op_tail_call: case op_tail_call_varargs: { if (!inlineCallFrame()) { prediction = SpecFullTop; break; } CodeOrigin* codeOrigin = inlineCallFrame()->getCallerSkippingTailCalls(); if (!codeOrigin) { prediction = SpecFullTop; break; } InlineStackEntry* stack = m_inlineStackTop; while (stack->m_inlineCallFrame != codeOrigin->inlineCallFrame) stack = stack->m_caller; bytecodeIndex = codeOrigin->bytecodeIndex; profiledBlock = stack->m_profiledBlock; break; } default: break; } } } if (profiledBlock) { ConcurrentJITLocker locker(profiledBlock->m_lock); prediction = profiledBlock->valueProfilePredictionForBytecodeOffset(locker, bytecodeIndex); } return prediction; } SpeculatedType getPrediction(unsigned bytecodeIndex) { SpeculatedType prediction = getPredictionWithoutOSRExit(bytecodeIndex); if (prediction == SpecNone) { // We have no information about what values this node generates. Give up // on executing this code, since we're likely to do more damage than good. addToGraph(ForceOSRExit); } return prediction; } SpeculatedType getPredictionWithoutOSRExit() { return getPredictionWithoutOSRExit(m_currentIndex); } SpeculatedType getPrediction() { return getPrediction(m_currentIndex); } ArrayMode getArrayMode(ArrayProfile* profile, Array::Action action) { ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); profile->computeUpdatedPrediction(locker, m_inlineStackTop->m_profiledBlock); bool makeSafe = profile->outOfBounds(locker); return ArrayMode::fromObserved(locker, profile, action, makeSafe); } ArrayMode getArrayMode(ArrayProfile* profile) { return getArrayMode(profile, Array::Read); } Node* makeSafe(Node* node) { if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, Overflow)) node->mergeFlags(NodeMayOverflowInt32InDFG); if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, NegativeZero)) node->mergeFlags(NodeMayNegZeroInDFG); if (!isX86() && node->op() == ArithMod) return node; ResultProfile* resultProfile = m_inlineStackTop->m_profiledBlock->resultProfileForBytecodeOffset(m_currentIndex); if (resultProfile) { switch (node->op()) { case ArithAdd: case ArithSub: case ValueAdd: if (resultProfile->didObserveDouble()) node->mergeFlags(NodeMayHaveDoubleResult); if (resultProfile->didObserveNonNumber()) node->mergeFlags(NodeMayHaveNonNumberResult); break; case ArithMul: { if (resultProfile->didObserveInt52Overflow()) node->mergeFlags(NodeMayOverflowInt52); if (resultProfile->didObserveInt32Overflow() || m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, Overflow)) node->mergeFlags(NodeMayOverflowInt32InBaseline); if (resultProfile->didObserveNegZeroDouble() || m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, NegativeZero)) node->mergeFlags(NodeMayNegZeroInBaseline); if (resultProfile->didObserveDouble()) node->mergeFlags(NodeMayHaveDoubleResult); if (resultProfile->didObserveNonNumber()) node->mergeFlags(NodeMayHaveNonNumberResult); break; } default: break; } } if (m_inlineStackTop->m_profiledBlock->likelyToTakeSlowCase(m_currentIndex)) { switch (node->op()) { case UInt32ToNumber: case ArithAdd: case ArithSub: case ValueAdd: case ArithMod: // for ArithMod "MayOverflow" means we tried to divide by zero, or we saw double. node->mergeFlags(NodeMayOverflowInt32InBaseline); break; case ArithNegate: // Currently we can't tell the difference between a negation overflowing // (i.e. -(1 << 31)) or generating negative zero (i.e. -0). If it took slow // path then we assume that it did both of those things. node->mergeFlags(NodeMayOverflowInt32InBaseline); node->mergeFlags(NodeMayNegZeroInBaseline); break; default: break; } } return node; } Node* makeDivSafe(Node* node) { ASSERT(node->op() == ArithDiv); if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, Overflow)) node->mergeFlags(NodeMayOverflowInt32InDFG); if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, NegativeZero)) node->mergeFlags(NodeMayNegZeroInDFG); // The main slow case counter for op_div in the old JIT counts only when // the operands are not numbers. We don't care about that since we already // have speculations in place that take care of that separately. We only // care about when the outcome of the division is not an integer, which // is what the special fast case counter tells us. if (!m_inlineStackTop->m_profiledBlock->couldTakeSpecialFastCase(m_currentIndex)) return node; // FIXME: It might be possible to make this more granular. node->mergeFlags(NodeMayOverflowInt32InBaseline | NodeMayNegZeroInBaseline); return node; } void noticeArgumentsUse() { // All of the arguments in this function need to be formatted as JSValues because we will // load from them in a random-access fashion and we don't want to have to switch on // format. for (ArgumentPosition* argument : m_inlineStackTop->m_argumentPositions) argument->mergeShouldNeverUnbox(true); } bool needsDynamicLookup(ResolveType, OpcodeID); VM* m_vm; CodeBlock* m_codeBlock; CodeBlock* m_profiledBlock; Graph& m_graph; // The current block being generated. BasicBlock* m_currentBlock; // The bytecode index of the current instruction being generated. unsigned m_currentIndex; // The semantic origin of the current node if different from the current Index. CodeOrigin m_currentSemanticOrigin; // True if it's OK to OSR exit right now. bool m_exitOK { false }; FrozenValue* m_constantUndefined; FrozenValue* m_constantNull; FrozenValue* m_constantNaN; FrozenValue* m_constantOne; Vector m_constants; // The number of arguments passed to the function. unsigned m_numArguments; // The number of locals (vars + temporaries) used in the function. unsigned m_numLocals; // The number of slots (in units of sizeof(Register)) that we need to // preallocate for arguments to outgoing calls from this frame. This // number includes the CallFrame slots that we initialize for the callee // (but not the callee-initialized CallerFrame and ReturnPC slots). // This number is 0 if and only if this function is a leaf. unsigned m_parameterSlots; // The number of var args passed to the next var arg node. unsigned m_numPassedVarArgs; HashMap m_constantBufferCache; struct InlineStackEntry { ByteCodeParser* m_byteCodeParser; CodeBlock* m_codeBlock; CodeBlock* m_profiledBlock; InlineCallFrame* m_inlineCallFrame; ScriptExecutable* executable() { return m_codeBlock->ownerScriptExecutable(); } QueryableExitProfile m_exitProfile; // Remapping of identifier and constant numbers from the code block being // inlined (inline callee) to the code block that we're inlining into // (the machine code block, which is the transitive, though not necessarily // direct, caller). Vector m_identifierRemap; Vector m_constantBufferRemap; Vector m_switchRemap; // Blocks introduced by this code block, which need successor linking. // May include up to one basic block that includes the continuation after // the callsite in the caller. These must be appended in the order that they // are created, but their bytecodeBegin values need not be in order as they // are ignored. Vector m_unlinkedBlocks; // Potential block linking targets. Must be sorted by bytecodeBegin, and // cannot have two blocks that have the same bytecodeBegin. Vector m_blockLinkingTargets; // If the callsite's basic block was split into two, then this will be // the head of the callsite block. It needs its successors linked to the // m_unlinkedBlocks, but not the other way around: there's no way for // any blocks in m_unlinkedBlocks to jump back into this block. BasicBlock* m_callsiteBlockHead; // Does the callsite block head need linking? This is typically true // but will be false for the machine code block's inline stack entry // (since that one is not inlined) and for cases where an inline callee // did the linking for us. bool m_callsiteBlockHeadNeedsLinking; VirtualRegister m_returnValue; // Speculations about variable types collected from the profiled code block, // which are based on OSR exit profiles that past DFG compilatins of this // code block had gathered. LazyOperandValueProfileParser m_lazyOperands; CallLinkInfoMap m_callLinkInfos; StubInfoMap m_stubInfos; ByValInfoMap m_byValInfos; // Did we see any returns? We need to handle the (uncommon but necessary) // case where a procedure that does not return was inlined. bool m_didReturn; // Did we have any early returns? bool m_didEarlyReturn; // Pointers to the argument position trackers for this slice of code. Vector m_argumentPositions; InlineStackEntry* m_caller; InlineStackEntry( ByteCodeParser*, CodeBlock*, CodeBlock* profiledBlock, BasicBlock* callsiteBlockHead, JSFunction* callee, // Null if this is a closure call. VirtualRegister returnValueVR, VirtualRegister inlineCallFrameStart, int argumentCountIncludingThis, InlineCallFrame::Kind); ~InlineStackEntry() { m_byteCodeParser->m_inlineStackTop = m_caller; } VirtualRegister remapOperand(VirtualRegister operand) const { if (!m_inlineCallFrame) return operand; ASSERT(!operand.isConstant()); return VirtualRegister(operand.offset() + m_inlineCallFrame->stackOffset); } }; InlineStackEntry* m_inlineStackTop; struct DelayedSetLocal { CodeOrigin m_origin; VirtualRegister m_operand; Node* m_value; DelayedSetLocal() { } DelayedSetLocal(const CodeOrigin& origin, VirtualRegister operand, Node* value) : m_origin(origin) , m_operand(operand) , m_value(value) { } Node* execute(ByteCodeParser* parser, SetMode setMode = NormalSet) { if (m_operand.isArgument()) return parser->setArgument(m_origin, m_operand, m_value, setMode); return parser->setLocal(m_origin, m_operand, m_value, setMode); } }; Vector m_setLocalQueue; CodeBlock* m_dfgCodeBlock; CallLinkStatus::ContextMap m_callContextMap; StubInfoMap m_dfgStubInfos; Instruction* m_currentInstruction; bool m_hasDebuggerEnabled; }; #define NEXT_OPCODE(name) \ m_currentIndex += OPCODE_LENGTH(name); \ continue #define LAST_OPCODE(name) \ m_currentIndex += OPCODE_LENGTH(name); \ m_exitOK = false; \ return shouldContinueParsing ByteCodeParser::Terminality ByteCodeParser::handleCall(Instruction* pc, NodeType op, CallMode callMode) { ASSERT(OPCODE_LENGTH(op_call) == OPCODE_LENGTH(op_construct)); ASSERT(OPCODE_LENGTH(op_call) == OPCODE_LENGTH(op_tail_call)); return handleCall( pc[1].u.operand, op, callMode, OPCODE_LENGTH(op_call), pc[2].u.operand, pc[3].u.operand, -pc[4].u.operand); } ByteCodeParser::Terminality ByteCodeParser::handleCall( int result, NodeType op, CallMode callMode, unsigned instructionSize, int callee, int argumentCountIncludingThis, int registerOffset) { Node* callTarget = get(VirtualRegister(callee)); CallLinkStatus callLinkStatus = CallLinkStatus::computeFor( m_inlineStackTop->m_profiledBlock, currentCodeOrigin(), m_inlineStackTop->m_callLinkInfos, m_callContextMap); return handleCall( result, op, callMode, instructionSize, callTarget, argumentCountIncludingThis, registerOffset, callLinkStatus); } ByteCodeParser::Terminality ByteCodeParser::handleCall( int result, NodeType op, CallMode callMode, unsigned instructionSize, Node* callTarget, int argumentCountIncludingThis, int registerOffset, CallLinkStatus callLinkStatus) { return handleCall( result, op, InlineCallFrame::kindFor(callMode), instructionSize, callTarget, argumentCountIncludingThis, registerOffset, callLinkStatus, getPrediction()); } void ByteCodeParser::refineStatically(CallLinkStatus& callLinkStatus, Node* callTarget) { if (callTarget->isCellConstant()) { callLinkStatus.setProvenConstantCallee(CallVariant(callTarget->asCell())); return; } } ByteCodeParser::Terminality ByteCodeParser::handleCall( int result, NodeType op, InlineCallFrame::Kind kind, unsigned instructionSize, Node* callTarget, int argumentCountIncludingThis, int registerOffset, CallLinkStatus callLinkStatus, SpeculatedType prediction) { ASSERT(registerOffset <= 0); refineStatically(callLinkStatus, callTarget); if (Options::verboseDFGByteCodeParsing()) dataLog(" Handling call at ", currentCodeOrigin(), ": ", callLinkStatus, "\n"); if (!callLinkStatus.canOptimize()) { // Oddly, this conflates calls that haven't executed with calls that behaved sufficiently polymorphically // that we cannot optimize them. Node* callNode = addCall(result, op, OpInfo(), callTarget, argumentCountIncludingThis, registerOffset, prediction); if (callNode->op() == TailCall) return Terminal; ASSERT(callNode->op() != TailCallVarargs); return NonTerminal; } unsigned nextOffset = m_currentIndex + instructionSize; OpInfo callOpInfo; if (handleInlining(callTarget, result, callLinkStatus, registerOffset, virtualRegisterForArgument(0, registerOffset), VirtualRegister(), 0, argumentCountIncludingThis, nextOffset, op, kind, prediction)) { if (m_graph.compilation()) m_graph.compilation()->noticeInlinedCall(); return NonTerminal; } Node* callNode = addCall(result, op, callOpInfo, callTarget, argumentCountIncludingThis, registerOffset, prediction); if (callNode->op() == TailCall) return Terminal; ASSERT(callNode->op() != TailCallVarargs); return NonTerminal; } ByteCodeParser::Terminality ByteCodeParser::handleVarargsCall(Instruction* pc, NodeType op, CallMode callMode) { ASSERT(OPCODE_LENGTH(op_call_varargs) == OPCODE_LENGTH(op_construct_varargs)); ASSERT(OPCODE_LENGTH(op_call_varargs) == OPCODE_LENGTH(op_tail_call_varargs)); int result = pc[1].u.operand; int callee = pc[2].u.operand; int thisReg = pc[3].u.operand; int arguments = pc[4].u.operand; int firstFreeReg = pc[5].u.operand; int firstVarArgOffset = pc[6].u.operand; SpeculatedType prediction = getPrediction(); Node* callTarget = get(VirtualRegister(callee)); CallLinkStatus callLinkStatus = CallLinkStatus::computeFor( m_inlineStackTop->m_profiledBlock, currentCodeOrigin(), m_inlineStackTop->m_callLinkInfos, m_callContextMap); refineStatically(callLinkStatus, callTarget); if (Options::verboseDFGByteCodeParsing()) dataLog(" Varargs call link status at ", currentCodeOrigin(), ": ", callLinkStatus, "\n"); if (callLinkStatus.canOptimize() && handleInlining(callTarget, result, callLinkStatus, firstFreeReg, VirtualRegister(thisReg), VirtualRegister(arguments), firstVarArgOffset, 0, m_currentIndex + OPCODE_LENGTH(op_call_varargs), op, InlineCallFrame::varargsKindFor(callMode), prediction)) { if (m_graph.compilation()) m_graph.compilation()->noticeInlinedCall(); return NonTerminal; } CallVarargsData* data = m_graph.m_callVarargsData.add(); data->firstVarArgOffset = firstVarArgOffset; Node* thisChild = get(VirtualRegister(thisReg)); if (op == TailCallVarargs) { if (allInlineFramesAreTailCalls()) { addToGraph(op, OpInfo(data), OpInfo(), callTarget, get(VirtualRegister(arguments)), thisChild); return Terminal; } op = TailCallVarargsInlinedCaller; } Node* call = addToGraph(op, OpInfo(data), OpInfo(prediction), callTarget, get(VirtualRegister(arguments)), thisChild); VirtualRegister resultReg(result); if (resultReg.isValid()) set(resultReg, call); return NonTerminal; } void ByteCodeParser::emitFunctionChecks(CallVariant callee, Node* callTarget, VirtualRegister thisArgumentReg) { Node* thisArgument; if (thisArgumentReg.isValid()) thisArgument = get(thisArgumentReg); else thisArgument = 0; JSCell* calleeCell; Node* callTargetForCheck; if (callee.isClosureCall()) { calleeCell = callee.executable(); callTargetForCheck = addToGraph(GetExecutable, callTarget); } else { calleeCell = callee.nonExecutableCallee(); callTargetForCheck = callTarget; } ASSERT(calleeCell); addToGraph(CheckCell, OpInfo(m_graph.freeze(calleeCell)), callTargetForCheck, thisArgument); } Node* ByteCodeParser::getArgumentCount() { Node* argumentCount; if (m_inlineStackTop->m_inlineCallFrame) { if (m_inlineStackTop->m_inlineCallFrame->isVarargs()) argumentCount = get(VirtualRegister(JSStack::ArgumentCount)); else argumentCount = jsConstant(m_graph.freeze(jsNumber(m_inlineStackTop->m_inlineCallFrame->arguments.size()))->value()); } else argumentCount = addToGraph(GetArgumentCountIncludingThis, OpInfo(0), OpInfo(SpecInt32Only)); return argumentCount; } void ByteCodeParser::emitArgumentPhantoms(int registerOffset, int argumentCountIncludingThis) { for (int i = 0; i < argumentCountIncludingThis; ++i) addToGraph(Phantom, get(virtualRegisterForArgument(i, registerOffset))); } unsigned ByteCodeParser::inliningCost(CallVariant callee, int argumentCountIncludingThis, CallMode callMode) { CodeSpecializationKind kind = specializationKindFor(callMode); if (verbose) dataLog("Considering inlining ", callee, " into ", currentCodeOrigin(), "\n"); if (m_hasDebuggerEnabled) { if (verbose) dataLog(" Failing because the debugger is in use.\n"); return UINT_MAX; } FunctionExecutable* executable = callee.functionExecutable(); if (!executable) { if (verbose) dataLog(" Failing because there is no function executable.\n"); return UINT_MAX; } // Does the number of arguments we're passing match the arity of the target? We currently // inline only if the number of arguments passed is greater than or equal to the number // arguments expected. if (static_cast(executable->parameterCount()) + 1 > argumentCountIncludingThis) { if (verbose) dataLog(" Failing because of arity mismatch.\n"); return UINT_MAX; } // Do we have a code block, and does the code block's size match the heuristics/requirements for // being an inline candidate? We might not have a code block (1) if code was thrown away, // (2) if we simply hadn't actually made this call yet or (3) code is a builtin function and // specialization kind is construct. In the former 2 cases, we could still theoretically attempt // to inline it if we had a static proof of what was being called; this might happen for example // if you call a global function, where watchpointing gives us static information. Overall, // it's a rare case because we expect that any hot callees would have already been compiled. CodeBlock* codeBlock = executable->baselineCodeBlockFor(kind); if (!codeBlock) { if (verbose) dataLog(" Failing because no code block available.\n"); return UINT_MAX; } CapabilityLevel capabilityLevel = inlineFunctionForCapabilityLevel( codeBlock, kind, callee.isClosureCall()); if (verbose) { dataLog(" Call mode: ", callMode, "\n"); dataLog(" Is closure call: ", callee.isClosureCall(), "\n"); dataLog(" Capability level: ", capabilityLevel, "\n"); dataLog(" Might inline function: ", mightInlineFunctionFor(codeBlock, kind), "\n"); dataLog(" Might compile function: ", mightCompileFunctionFor(codeBlock, kind), "\n"); dataLog(" Is supported for inlining: ", isSupportedForInlining(codeBlock), "\n"); dataLog(" Is inlining candidate: ", codeBlock->ownerScriptExecutable()->isInliningCandidate(), "\n"); } if (!canInline(capabilityLevel)) { if (verbose) dataLog(" Failing because the function is not inlineable.\n"); return UINT_MAX; } // Check if the caller is already too large. We do this check here because that's just // where we happen to also have the callee's code block, and we want that for the // purpose of unsetting SABI. if (!isSmallEnoughToInlineCodeInto(m_codeBlock)) { codeBlock->m_shouldAlwaysBeInlined = false; if (verbose) dataLog(" Failing because the caller is too large.\n"); return UINT_MAX; } // FIXME: this should be better at predicting how much bloat we will introduce by inlining // this function. // https://bugs.webkit.org/show_bug.cgi?id=127627 // FIXME: We currently inline functions that have run in LLInt but not in Baseline. These // functions have very low fidelity profiling, and presumably they weren't very hot if they // haven't gotten to Baseline yet. Consider not inlining these functions. // https://bugs.webkit.org/show_bug.cgi?id=145503 // Have we exceeded inline stack depth, or are we trying to inline a recursive call to // too many levels? If either of these are detected, then don't inline. We adjust our // heuristics if we are dealing with a function that cannot otherwise be compiled. unsigned depth = 0; unsigned recursion = 0; for (InlineStackEntry* entry = m_inlineStackTop; entry; entry = entry->m_caller) { ++depth; if (depth >= Options::maximumInliningDepth()) { if (verbose) dataLog(" Failing because depth exceeded.\n"); return UINT_MAX; } if (entry->executable() == executable) { ++recursion; if (recursion >= Options::maximumInliningRecursion()) { if (verbose) dataLog(" Failing because recursion detected.\n"); return UINT_MAX; } } } if (verbose) dataLog(" Inlining should be possible.\n"); // It might be possible to inline. return codeBlock->instructionCount(); } template void ByteCodeParser::inlineCall(Node* callTargetNode, int resultOperand, CallVariant callee, int registerOffset, int argumentCountIncludingThis, unsigned nextOffset, InlineCallFrame::Kind kind, CallerLinkability callerLinkability, const ChecksFunctor& insertChecks) { CodeSpecializationKind specializationKind = InlineCallFrame::specializationKindFor(kind); ASSERT(inliningCost(callee, argumentCountIncludingThis, InlineCallFrame::callModeFor(kind)) != UINT_MAX); CodeBlock* codeBlock = callee.functionExecutable()->baselineCodeBlockFor(specializationKind); insertChecks(codeBlock); // FIXME: Don't flush constants! int inlineCallFrameStart = m_inlineStackTop->remapOperand(VirtualRegister(registerOffset)).offset() + JSStack::CallFrameHeaderSize; ensureLocals( VirtualRegister(inlineCallFrameStart).toLocal() + 1 + JSStack::CallFrameHeaderSize + codeBlock->m_numCalleeLocals); size_t argumentPositionStart = m_graph.m_argumentPositions.size(); VirtualRegister resultReg(resultOperand); if (resultReg.isValid()) resultReg = m_inlineStackTop->remapOperand(resultReg); VariableAccessData* calleeVariable = nullptr; if (callee.isClosureCall()) { Node* calleeSet = set( VirtualRegister(registerOffset + JSStack::Callee), callTargetNode, ImmediateNakedSet); calleeVariable = calleeSet->variableAccessData(); calleeVariable->mergeShouldNeverUnbox(true); } InlineStackEntry inlineStackEntry( this, codeBlock, codeBlock, m_graph.lastBlock(), callee.function(), resultReg, (VirtualRegister)inlineCallFrameStart, argumentCountIncludingThis, kind); // This is where the actual inlining really happens. unsigned oldIndex = m_currentIndex; m_currentIndex = 0; // At this point, it's again OK to OSR exit. m_exitOK = true; InlineVariableData inlineVariableData; inlineVariableData.inlineCallFrame = m_inlineStackTop->m_inlineCallFrame; inlineVariableData.argumentPositionStart = argumentPositionStart; inlineVariableData.calleeVariable = 0; RELEASE_ASSERT( m_inlineStackTop->m_inlineCallFrame->isClosureCall == callee.isClosureCall()); if (callee.isClosureCall()) { RELEASE_ASSERT(calleeVariable); inlineVariableData.calleeVariable = calleeVariable; } m_graph.m_inlineVariableData.append(inlineVariableData); parseCodeBlock(); clearCaches(); // Reset our state now that we're back to the outer code. m_currentIndex = oldIndex; m_exitOK = false; // If the inlined code created some new basic blocks, then we have linking to do. if (inlineStackEntry.m_callsiteBlockHead != m_graph.lastBlock()) { ASSERT(!inlineStackEntry.m_unlinkedBlocks.isEmpty()); if (inlineStackEntry.m_callsiteBlockHeadNeedsLinking) linkBlock(inlineStackEntry.m_callsiteBlockHead, inlineStackEntry.m_blockLinkingTargets); else ASSERT(inlineStackEntry.m_callsiteBlockHead->isLinked); if (callerLinkability == CallerDoesNormalLinking) cancelLinkingForBlock(inlineStackEntry.m_caller, inlineStackEntry.m_callsiteBlockHead); linkBlocks(inlineStackEntry.m_unlinkedBlocks, inlineStackEntry.m_blockLinkingTargets); } else ASSERT(inlineStackEntry.m_unlinkedBlocks.isEmpty()); BasicBlock* lastBlock = m_graph.lastBlock(); // If there was a return, but no early returns, then we're done. We allow parsing of // the caller to continue in whatever basic block we're in right now. if (!inlineStackEntry.m_didEarlyReturn && inlineStackEntry.m_didReturn) { if (Options::verboseDFGByteCodeParsing()) dataLog(" Allowing parsing to continue in last inlined block.\n"); ASSERT(lastBlock->isEmpty() || !lastBlock->terminal()); // If we created new blocks then the last block needs linking, but in the // caller. It doesn't need to be linked to, but it needs outgoing links. if (!inlineStackEntry.m_unlinkedBlocks.isEmpty()) { // For debugging purposes, set the bytecodeBegin. Note that this doesn't matter // for release builds because this block will never serve as a potential target // in the linker's binary search. if (Options::verboseDFGByteCodeParsing()) dataLog(" Repurposing last block from ", lastBlock->bytecodeBegin, " to ", m_currentIndex, "\n"); lastBlock->bytecodeBegin = m_currentIndex; if (callerLinkability == CallerDoesNormalLinking) { if (verbose) dataLog("Adding unlinked block ", RawPointer(m_graph.lastBlock()), " (one return)\n"); m_inlineStackTop->m_caller->m_unlinkedBlocks.append(UnlinkedBlock(m_graph.lastBlock())); } } m_currentBlock = m_graph.lastBlock(); return; } if (Options::verboseDFGByteCodeParsing()) dataLog(" Creating new block after inlining.\n"); // If we get to this point then all blocks must end in some sort of terminals. ASSERT(lastBlock->terminal()); // Need to create a new basic block for the continuation at the caller. RefPtr block = adoptRef(new BasicBlock(nextOffset, m_numArguments, m_numLocals, 1)); // Link the early returns to the basic block we're about to create. for (size_t i = 0; i < inlineStackEntry.m_unlinkedBlocks.size(); ++i) { if (!inlineStackEntry.m_unlinkedBlocks[i].m_needsEarlyReturnLinking) continue; BasicBlock* blockToLink = inlineStackEntry.m_unlinkedBlocks[i].m_block; ASSERT(!blockToLink->isLinked); Node* node = blockToLink->terminal(); ASSERT(node->op() == Jump); ASSERT(!node->targetBlock()); node->targetBlock() = block.get(); inlineStackEntry.m_unlinkedBlocks[i].m_needsEarlyReturnLinking = false; if (verbose) dataLog("Marking ", RawPointer(blockToLink), " as linked (jumps to return)\n"); blockToLink->didLink(); } m_currentBlock = block.get(); ASSERT(m_inlineStackTop->m_caller->m_blockLinkingTargets.isEmpty() || m_inlineStackTop->m_caller->m_blockLinkingTargets.last()->bytecodeBegin < nextOffset); if (verbose) dataLog("Adding unlinked block ", RawPointer(block.get()), " (many returns)\n"); if (callerLinkability == CallerDoesNormalLinking) { m_inlineStackTop->m_caller->m_unlinkedBlocks.append(UnlinkedBlock(block.get())); m_inlineStackTop->m_caller->m_blockLinkingTargets.append(block.get()); } m_graph.appendBlock(block); prepareToParseBlock(); } void ByteCodeParser::cancelLinkingForBlock(InlineStackEntry* inlineStackEntry, BasicBlock* block) { // It's possible that the callsite block head is not owned by the caller. if (!inlineStackEntry->m_unlinkedBlocks.isEmpty()) { // It's definitely owned by the caller, because the caller created new blocks. // Assert that this all adds up. ASSERT_UNUSED(block, inlineStackEntry->m_unlinkedBlocks.last().m_block == block); ASSERT(inlineStackEntry->m_unlinkedBlocks.last().m_needsNormalLinking); inlineStackEntry->m_unlinkedBlocks.last().m_needsNormalLinking = false; } else { // It's definitely not owned by the caller. Tell the caller that he does not // need to link his callsite block head, because we did it for him. ASSERT(inlineStackEntry->m_callsiteBlockHeadNeedsLinking); ASSERT_UNUSED(block, inlineStackEntry->m_callsiteBlockHead == block); inlineStackEntry->m_callsiteBlockHeadNeedsLinking = false; } } template bool ByteCodeParser::attemptToInlineCall(Node* callTargetNode, int resultOperand, CallVariant callee, int registerOffset, int argumentCountIncludingThis, unsigned nextOffset, InlineCallFrame::Kind kind, CallerLinkability callerLinkability, SpeculatedType prediction, unsigned& inliningBalance, const ChecksFunctor& insertChecks) { CodeSpecializationKind specializationKind = InlineCallFrame::specializationKindFor(kind); if (!inliningBalance) return false; if (verbose) dataLog(" Considering callee ", callee, "\n"); // Intrinsics and internal functions can only be inlined if we're not doing varargs. This is because // we currently don't have any way of getting profiling information for arguments to non-JS varargs // calls. The prediction propagator won't be of any help because LoadVarargs obscures the data flow, // and there are no callsite value profiles and native function won't have callee value profiles for // those arguments. Even worse, if the intrinsic decides to exit, it won't really have anywhere to // exit to: LoadVarargs is effectful and it's part of the op_call_varargs, so we can't exit without // calling LoadVarargs twice. if (!InlineCallFrame::isVarargs(kind)) { bool didInsertChecks = false; auto insertChecksWithAccounting = [&] () { insertChecks(nullptr); didInsertChecks = true; }; if (InternalFunction* function = callee.internalFunction()) { if (handleConstantInternalFunction(callTargetNode, resultOperand, function, registerOffset, argumentCountIncludingThis, specializationKind, insertChecksWithAccounting)) { RELEASE_ASSERT(didInsertChecks); addToGraph(Phantom, callTargetNode); emitArgumentPhantoms(registerOffset, argumentCountIncludingThis); inliningBalance--; return true; } RELEASE_ASSERT(!didInsertChecks); return false; } Intrinsic intrinsic = callee.intrinsicFor(specializationKind); if (intrinsic != NoIntrinsic) { if (handleIntrinsicCall(callTargetNode, resultOperand, intrinsic, registerOffset, argumentCountIncludingThis, prediction, insertChecksWithAccounting)) { RELEASE_ASSERT(didInsertChecks); addToGraph(Phantom, callTargetNode); emitArgumentPhantoms(registerOffset, argumentCountIncludingThis); inliningBalance--; return true; } RELEASE_ASSERT(!didInsertChecks); // We might still try to inline the Intrinsic because it might be a builtin JS function. } } unsigned myInliningCost = inliningCost(callee, argumentCountIncludingThis, InlineCallFrame::callModeFor(kind)); if (myInliningCost > inliningBalance) return false; Instruction* savedCurrentInstruction = m_currentInstruction; inlineCall(callTargetNode, resultOperand, callee, registerOffset, argumentCountIncludingThis, nextOffset, kind, callerLinkability, insertChecks); inliningBalance -= myInliningCost; m_currentInstruction = savedCurrentInstruction; return true; } bool ByteCodeParser::handleInlining( Node* callTargetNode, int resultOperand, const CallLinkStatus& callLinkStatus, int registerOffsetOrFirstFreeReg, VirtualRegister thisArgument, VirtualRegister argumentsArgument, unsigned argumentsOffset, int argumentCountIncludingThis, unsigned nextOffset, NodeType callOp, InlineCallFrame::Kind kind, SpeculatedType prediction) { if (verbose) { dataLog("Handling inlining...\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); } CodeSpecializationKind specializationKind = InlineCallFrame::specializationKindFor(kind); if (!callLinkStatus.size()) { if (verbose) dataLog("Bailing inlining.\n"); return false; } if (InlineCallFrame::isVarargs(kind) && callLinkStatus.maxNumArguments() > Options::maximumVarargsForInlining()) { if (verbose) dataLog("Bailing inlining because of varargs.\n"); return false; } unsigned inliningBalance = Options::maximumFunctionForCallInlineCandidateInstructionCount(); if (specializationKind == CodeForConstruct) inliningBalance = std::min(inliningBalance, Options::maximumFunctionForConstructInlineCandidateInstructionCount()); if (callLinkStatus.isClosureCall()) inliningBalance = std::min(inliningBalance, Options::maximumFunctionForClosureCallInlineCandidateInstructionCount()); // First check if we can avoid creating control flow. Our inliner does some CFG // simplification on the fly and this helps reduce compile times, but we can only leverage // this in cases where we don't need control flow diamonds to check the callee. if (!callLinkStatus.couldTakeSlowPath() && callLinkStatus.size() == 1) { int registerOffset; // Only used for varargs calls. unsigned mandatoryMinimum = 0; unsigned maxNumArguments = 0; if (InlineCallFrame::isVarargs(kind)) { if (FunctionExecutable* functionExecutable = callLinkStatus[0].functionExecutable()) mandatoryMinimum = functionExecutable->parameterCount(); else mandatoryMinimum = 0; // includes "this" maxNumArguments = std::max( callLinkStatus.maxNumArguments(), mandatoryMinimum + 1); // We sort of pretend that this *is* the number of arguments that were passed. argumentCountIncludingThis = maxNumArguments; registerOffset = registerOffsetOrFirstFreeReg + 1; registerOffset -= maxNumArguments; // includes "this" registerOffset -= JSStack::CallFrameHeaderSize; registerOffset = -WTF::roundUpToMultipleOf( stackAlignmentRegisters(), -registerOffset); } else registerOffset = registerOffsetOrFirstFreeReg; bool result = attemptToInlineCall( callTargetNode, resultOperand, callLinkStatus[0], registerOffset, argumentCountIncludingThis, nextOffset, kind, CallerDoesNormalLinking, prediction, inliningBalance, [&] (CodeBlock* codeBlock) { emitFunctionChecks(callLinkStatus[0], callTargetNode, thisArgument); // If we have a varargs call, we want to extract the arguments right now. if (InlineCallFrame::isVarargs(kind)) { int remappedRegisterOffset = m_inlineStackTop->remapOperand(VirtualRegister(registerOffset)).offset(); ensureLocals(VirtualRegister(remappedRegisterOffset).toLocal()); int argumentStart = registerOffset + JSStack::CallFrameHeaderSize; int remappedArgumentStart = m_inlineStackTop->remapOperand(VirtualRegister(argumentStart)).offset(); LoadVarargsData* data = m_graph.m_loadVarargsData.add(); data->start = VirtualRegister(remappedArgumentStart + 1); data->count = VirtualRegister(remappedRegisterOffset + JSStack::ArgumentCount); data->offset = argumentsOffset; data->limit = maxNumArguments; data->mandatoryMinimum = mandatoryMinimum; addToGraph(LoadVarargs, OpInfo(data), get(argumentsArgument)); // LoadVarargs may OSR exit. Hence, we need to keep alive callTargetNode, thisArgument // and argumentsArgument for the baseline JIT. However, we only need a Phantom for // callTargetNode because the other 2 are still in use and alive at this point. addToGraph(Phantom, callTargetNode); // In DFG IR before SSA, we cannot insert control flow between after the // LoadVarargs and the last SetArgument. This isn't a problem once we get to DFG // SSA. Fortunately, we also have other reasons for not inserting control flow // before SSA. VariableAccessData* countVariable = newVariableAccessData( VirtualRegister(remappedRegisterOffset + JSStack::ArgumentCount)); // This is pretty lame, but it will force the count to be flushed as an int. This doesn't // matter very much, since our use of a SetArgument and Flushes for this local slot is // mostly just a formality. countVariable->predict(SpecInt32Only); countVariable->mergeIsProfitableToUnbox(true); Node* setArgumentCount = addToGraph(SetArgument, OpInfo(countVariable)); m_currentBlock->variablesAtTail.setOperand(countVariable->local(), setArgumentCount); set(VirtualRegister(argumentStart), get(thisArgument), ImmediateNakedSet); for (unsigned argument = 1; argument < maxNumArguments; ++argument) { VariableAccessData* variable = newVariableAccessData( VirtualRegister(remappedArgumentStart + argument)); variable->mergeShouldNeverUnbox(true); // We currently have nowhere to put the type check on the LoadVarargs. LoadVarargs is effectful, so after it finishes, we cannot exit. // For a while it had been my intention to do things like this inside the // prediction injection phase. But in this case it's really best to do it here, // because it's here that we have access to the variable access datas for the // inlining we're about to do. // // Something else that's interesting here is that we'd really love to get // predictions from the arguments loaded at the callsite, rather than the // arguments received inside the callee. But that probably won't matter for most // calls. if (codeBlock && argument < static_cast(codeBlock->numParameters())) { ConcurrentJITLocker locker(codeBlock->m_lock); if (ValueProfile* profile = codeBlock->valueProfileForArgument(argument)) variable->predict(profile->computeUpdatedPrediction(locker)); } Node* setArgument = addToGraph(SetArgument, OpInfo(variable)); m_currentBlock->variablesAtTail.setOperand(variable->local(), setArgument); } } }); if (verbose) { dataLog("Done inlining (simple).\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); dataLog("Result: ", result, "\n"); } return result; } // We need to create some kind of switch over callee. For now we only do this if we believe that // we're in the top tier. We have two reasons for this: first, it provides us an opportunity to // do more detailed polyvariant/polymorphic profiling; and second, it reduces compile times in // the DFG. And by polyvariant profiling we mean polyvariant profiling of *this* call. Note that // we could improve that aspect of this by doing polymorphic inlining but having the profiling // also. if (!isFTL(m_graph.m_plan.mode) || !Options::usePolymorphicCallInlining() || InlineCallFrame::isVarargs(kind)) { if (verbose) { dataLog("Bailing inlining (hard).\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); } return false; } // If the claim is that this did not originate from a stub, then we don't want to emit a switch // statement. Whenever the non-stub profiling says that it could take slow path, it really means that // it has no idea. if (!Options::usePolymorphicCallInliningForNonStubStatus() && !callLinkStatus.isBasedOnStub()) { if (verbose) { dataLog("Bailing inlining (non-stub polymorphism).\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); } return false; } unsigned oldOffset = m_currentIndex; bool allAreClosureCalls = true; bool allAreDirectCalls = true; for (unsigned i = callLinkStatus.size(); i--;) { if (callLinkStatus[i].isClosureCall()) allAreDirectCalls = false; else allAreClosureCalls = false; } Node* thingToSwitchOn; if (allAreDirectCalls) thingToSwitchOn = callTargetNode; else if (allAreClosureCalls) thingToSwitchOn = addToGraph(GetExecutable, callTargetNode); else { // FIXME: We should be able to handle this case, but it's tricky and we don't know of cases // where it would be beneficial. It might be best to handle these cases as if all calls were // closure calls. // https://bugs.webkit.org/show_bug.cgi?id=136020 if (verbose) { dataLog("Bailing inlining (mix).\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); } return false; } if (verbose) { dataLog("Doing hard inlining...\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); } int registerOffset = registerOffsetOrFirstFreeReg; // This makes me wish that we were in SSA all the time. We need to pick a variable into which to // store the callee so that it will be accessible to all of the blocks we're about to create. We // get away with doing an immediate-set here because we wouldn't have performed any side effects // yet. if (verbose) dataLog("Register offset: ", registerOffset); VirtualRegister calleeReg(registerOffset + JSStack::Callee); calleeReg = m_inlineStackTop->remapOperand(calleeReg); if (verbose) dataLog("Callee is going to be ", calleeReg, "\n"); setDirect(calleeReg, callTargetNode, ImmediateSetWithFlush); // It's OK to exit right now, even though we set some locals. That's because those locals are not // user-visible. m_exitOK = true; addToGraph(ExitOK); SwitchData& data = *m_graph.m_switchData.add(); data.kind = SwitchCell; addToGraph(Switch, OpInfo(&data), thingToSwitchOn); BasicBlock* originBlock = m_currentBlock; if (verbose) dataLog("Marking ", RawPointer(originBlock), " as linked (origin of poly inline)\n"); originBlock->didLink(); cancelLinkingForBlock(m_inlineStackTop, originBlock); // Each inlined callee will have a landing block that it returns at. They should all have jumps // to the continuation block, which we create last. Vector landingBlocks; // We may force this true if we give up on inlining any of the edges. bool couldTakeSlowPath = callLinkStatus.couldTakeSlowPath(); if (verbose) dataLog("About to loop over functions at ", currentCodeOrigin(), ".\n"); for (unsigned i = 0; i < callLinkStatus.size(); ++i) { m_currentIndex = oldOffset; RefPtr block = adoptRef(new BasicBlock(UINT_MAX, m_numArguments, m_numLocals, 1)); m_currentBlock = block.get(); m_graph.appendBlock(block); prepareToParseBlock(); Node* myCallTargetNode = getDirect(calleeReg); bool inliningResult = attemptToInlineCall( myCallTargetNode, resultOperand, callLinkStatus[i], registerOffset, argumentCountIncludingThis, nextOffset, kind, CallerLinksManually, prediction, inliningBalance, [&] (CodeBlock*) { }); if (!inliningResult) { // That failed so we let the block die. Nothing interesting should have been added to // the block. We also give up on inlining any of the (less frequent) callees. ASSERT(m_currentBlock == block.get()); ASSERT(m_graph.m_blocks.last() == block); m_graph.killBlockAndItsContents(block.get()); m_graph.m_blocks.removeLast(); // The fact that inlining failed means we need a slow path. couldTakeSlowPath = true; break; } JSCell* thingToCaseOn; if (allAreDirectCalls) thingToCaseOn = callLinkStatus[i].nonExecutableCallee(); else { ASSERT(allAreClosureCalls); thingToCaseOn = callLinkStatus[i].executable(); } data.cases.append(SwitchCase(m_graph.freeze(thingToCaseOn), block.get())); m_currentIndex = nextOffset; m_exitOK = true; processSetLocalQueue(); // This only comes into play for intrinsics, since normal inlined code will leave an empty queue. if (Node* terminal = m_currentBlock->terminal()) ASSERT_UNUSED(terminal, terminal->op() == TailCall || terminal->op() == TailCallVarargs); else { addToGraph(Jump); landingBlocks.append(m_currentBlock); } if (verbose) dataLog("Marking ", RawPointer(m_currentBlock), " as linked (tail of poly inlinee)\n"); m_currentBlock->didLink(); if (verbose) dataLog("Finished inlining ", callLinkStatus[i], " at ", currentCodeOrigin(), ".\n"); } RefPtr slowPathBlock = adoptRef( new BasicBlock(UINT_MAX, m_numArguments, m_numLocals, 1)); m_currentIndex = oldOffset; m_exitOK = true; data.fallThrough = BranchTarget(slowPathBlock.get()); m_graph.appendBlock(slowPathBlock); if (verbose) dataLog("Marking ", RawPointer(slowPathBlock.get()), " as linked (slow path block)\n"); slowPathBlock->didLink(); prepareToParseBlock(); m_currentBlock = slowPathBlock.get(); Node* myCallTargetNode = getDirect(calleeReg); if (couldTakeSlowPath) { addCall( resultOperand, callOp, OpInfo(), myCallTargetNode, argumentCountIncludingThis, registerOffset, prediction); } else { addToGraph(CheckBadCell); addToGraph(Phantom, myCallTargetNode); emitArgumentPhantoms(registerOffset, argumentCountIncludingThis); set(VirtualRegister(resultOperand), addToGraph(BottomValue)); } m_currentIndex = nextOffset; m_exitOK = true; // Origin changed, so it's fine to exit again. processSetLocalQueue(); if (Node* terminal = m_currentBlock->terminal()) ASSERT_UNUSED(terminal, terminal->op() == TailCall || terminal->op() == TailCallVarargs); else { addToGraph(Jump); landingBlocks.append(m_currentBlock); } RefPtr continuationBlock = adoptRef( new BasicBlock(UINT_MAX, m_numArguments, m_numLocals, 1)); m_graph.appendBlock(continuationBlock); if (verbose) dataLog("Adding unlinked block ", RawPointer(continuationBlock.get()), " (continuation)\n"); m_inlineStackTop->m_unlinkedBlocks.append(UnlinkedBlock(continuationBlock.get())); prepareToParseBlock(); m_currentBlock = continuationBlock.get(); for (unsigned i = landingBlocks.size(); i--;) landingBlocks[i]->terminal()->targetBlock() = continuationBlock.get(); m_currentIndex = oldOffset; m_exitOK = true; if (verbose) { dataLog("Done inlining (hard).\n"); dataLog("Stack: ", currentCodeOrigin(), "\n"); } return true; } template bool ByteCodeParser::handleMinMax(int resultOperand, NodeType op, int registerOffset, int argumentCountIncludingThis, const ChecksFunctor& insertChecks) { if (argumentCountIncludingThis == 1) { // Math.min() insertChecks(); set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantNaN))); return true; } if (argumentCountIncludingThis == 2) { // Math.min(x) insertChecks(); Node* result = get(VirtualRegister(virtualRegisterForArgument(1, registerOffset))); addToGraph(Phantom, Edge(result, NumberUse)); set(VirtualRegister(resultOperand), result); return true; } if (argumentCountIncludingThis == 3) { // Math.min(x, y) insertChecks(); set(VirtualRegister(resultOperand), addToGraph(op, get(virtualRegisterForArgument(1, registerOffset)), get(virtualRegisterForArgument(2, registerOffset)))); return true; } // Don't handle >=3 arguments for now. return false; } template bool ByteCodeParser::handleIntrinsicCall(Node* callee, int resultOperand, Intrinsic intrinsic, int registerOffset, int argumentCountIncludingThis, SpeculatedType prediction, const ChecksFunctor& insertChecks) { switch (intrinsic) { // Intrinsic Functions: case AbsIntrinsic: { if (argumentCountIncludingThis == 1) { // Math.abs() insertChecks(); set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantNaN))); return true; } if (!MacroAssembler::supportsFloatingPointAbs()) return false; insertChecks(); Node* node = addToGraph(ArithAbs, get(virtualRegisterForArgument(1, registerOffset))); if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, Overflow)) node->mergeFlags(NodeMayOverflowInt32InDFG); set(VirtualRegister(resultOperand), node); return true; } case MinIntrinsic: return handleMinMax(resultOperand, ArithMin, registerOffset, argumentCountIncludingThis, insertChecks); case MaxIntrinsic: return handleMinMax(resultOperand, ArithMax, registerOffset, argumentCountIncludingThis, insertChecks); case SqrtIntrinsic: case CosIntrinsic: case SinIntrinsic: case LogIntrinsic: { if (argumentCountIncludingThis == 1) { insertChecks(); set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantNaN))); return true; } switch (intrinsic) { case SqrtIntrinsic: insertChecks(); set(VirtualRegister(resultOperand), addToGraph(ArithSqrt, get(virtualRegisterForArgument(1, registerOffset)))); return true; case CosIntrinsic: insertChecks(); set(VirtualRegister(resultOperand), addToGraph(ArithCos, get(virtualRegisterForArgument(1, registerOffset)))); return true; case SinIntrinsic: insertChecks(); set(VirtualRegister(resultOperand), addToGraph(ArithSin, get(virtualRegisterForArgument(1, registerOffset)))); return true; case LogIntrinsic: insertChecks(); set(VirtualRegister(resultOperand), addToGraph(ArithLog, get(virtualRegisterForArgument(1, registerOffset)))); return true; default: RELEASE_ASSERT_NOT_REACHED(); return false; } } case PowIntrinsic: { if (argumentCountIncludingThis < 3) { // Math.pow() and Math.pow(x) return NaN. insertChecks(); set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantNaN))); return true; } insertChecks(); VirtualRegister xOperand = virtualRegisterForArgument(1, registerOffset); VirtualRegister yOperand = virtualRegisterForArgument(2, registerOffset); set(VirtualRegister(resultOperand), addToGraph(ArithPow, get(xOperand), get(yOperand))); return true; } case ArrayPushIntrinsic: { if (argumentCountIncludingThis != 2) return false; ArrayMode arrayMode = getArrayMode(m_currentInstruction[OPCODE_LENGTH(op_call) - 2].u.arrayProfile); if (!arrayMode.isJSArray()) return false; switch (arrayMode.type()) { case Array::Int32: case Array::Double: case Array::Contiguous: case Array::ArrayStorage: { insertChecks(); Node* arrayPush = addToGraph(ArrayPush, OpInfo(arrayMode.asWord()), OpInfo(prediction), get(virtualRegisterForArgument(0, registerOffset)), get(virtualRegisterForArgument(1, registerOffset))); set(VirtualRegister(resultOperand), arrayPush); return true; } default: return false; } } case ArrayPopIntrinsic: { if (argumentCountIncludingThis != 1) return false; ArrayMode arrayMode = getArrayMode(m_currentInstruction[OPCODE_LENGTH(op_call) - 2].u.arrayProfile); if (!arrayMode.isJSArray()) return false; switch (arrayMode.type()) { case Array::Int32: case Array::Double: case Array::Contiguous: case Array::ArrayStorage: { insertChecks(); Node* arrayPop = addToGraph(ArrayPop, OpInfo(arrayMode.asWord()), OpInfo(prediction), get(virtualRegisterForArgument(0, registerOffset))); set(VirtualRegister(resultOperand), arrayPop); return true; } default: return false; } } case CharCodeAtIntrinsic: { if (argumentCountIncludingThis != 2) return false; insertChecks(); VirtualRegister thisOperand = virtualRegisterForArgument(0, registerOffset); VirtualRegister indexOperand = virtualRegisterForArgument(1, registerOffset); Node* charCode = addToGraph(StringCharCodeAt, OpInfo(ArrayMode(Array::String).asWord()), get(thisOperand), get(indexOperand)); set(VirtualRegister(resultOperand), charCode); return true; } case CharAtIntrinsic: { if (argumentCountIncludingThis != 2) return false; insertChecks(); VirtualRegister thisOperand = virtualRegisterForArgument(0, registerOffset); VirtualRegister indexOperand = virtualRegisterForArgument(1, registerOffset); Node* charCode = addToGraph(StringCharAt, OpInfo(ArrayMode(Array::String).asWord()), get(thisOperand), get(indexOperand)); set(VirtualRegister(resultOperand), charCode); return true; } case Clz32Intrinsic: { insertChecks(); if (argumentCountIncludingThis == 1) set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_graph.freeze(jsNumber(32))))); else { Node* operand = get(virtualRegisterForArgument(1, registerOffset)); set(VirtualRegister(resultOperand), addToGraph(ArithClz32, operand)); } return true; } case FromCharCodeIntrinsic: { if (argumentCountIncludingThis != 2) return false; insertChecks(); VirtualRegister indexOperand = virtualRegisterForArgument(1, registerOffset); Node* charCode = addToGraph(StringFromCharCode, get(indexOperand)); set(VirtualRegister(resultOperand), charCode); return true; } case RegExpExecIntrinsic: { if (argumentCountIncludingThis != 2) return false; insertChecks(); Node* regExpExec = addToGraph(RegExpExec, OpInfo(0), OpInfo(prediction), addToGraph(GetGlobalObject, callee), get(virtualRegisterForArgument(0, registerOffset)), get(virtualRegisterForArgument(1, registerOffset))); set(VirtualRegister(resultOperand), regExpExec); return true; } case RegExpTestIntrinsic: case RegExpTestFastIntrinsic: { if (argumentCountIncludingThis != 2) return false; if (intrinsic == RegExpTestIntrinsic) { // Don't inline intrinsic if we exited due to one of the primordial RegExp checks failing. if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadCell)) return false; JSGlobalObject* globalObject = m_inlineStackTop->m_codeBlock->globalObject(); Structure* regExpStructure = globalObject->regExpStructure(); m_graph.registerStructure(regExpStructure); ASSERT(regExpStructure->storedPrototype().isObject()); ASSERT(regExpStructure->storedPrototype().asCell()->classInfo() == RegExpPrototype::info()); FrozenValue* regExpPrototypeObjectValue = m_graph.freeze(regExpStructure->storedPrototype()); Structure* regExpPrototypeStructure = regExpPrototypeObjectValue->structure(); auto isRegExpPropertySame = [&] (JSValue primordialProperty, UniquedStringImpl* propertyUID) { JSValue currentProperty; if (!m_graph.getRegExpPrototypeProperty(regExpStructure->storedPrototypeObject(), regExpPrototypeStructure, propertyUID, currentProperty)) return false; return currentProperty == primordialProperty; }; // Check that RegExp.exec is still the primordial RegExp.prototype.exec if (!isRegExpPropertySame(globalObject->regExpProtoExecFunction(), m_vm->propertyNames->exec.impl())) return false; // Check that regExpObject is actually a RegExp object. Node* regExpObject = get(virtualRegisterForArgument(0, registerOffset)); addToGraph(Check, Edge(regExpObject, RegExpObjectUse)); // Check that regExpObject's exec is actually the primodial RegExp.prototype.exec. UniquedStringImpl* execPropertyID = m_vm->propertyNames->exec.impl(); unsigned execIndex = m_graph.identifiers().ensure(execPropertyID); Node* actualProperty = addToGraph(TryGetById, OpInfo(execIndex), OpInfo(SpecFunction), Edge(regExpObject, CellUse)); FrozenValue* regExpPrototypeExec = m_graph.freeze(globalObject->regExpProtoExecFunction()); addToGraph(CheckCell, OpInfo(regExpPrototypeExec), Edge(actualProperty, CellUse)); } insertChecks(); Node* regExpObject = get(virtualRegisterForArgument(0, registerOffset)); Node* regExpExec = addToGraph(RegExpTest, OpInfo(0), OpInfo(prediction), addToGraph(GetGlobalObject, callee), regExpObject, get(virtualRegisterForArgument(1, registerOffset))); set(VirtualRegister(resultOperand), regExpExec); return true; } case IsRegExpObjectIntrinsic: { ASSERT(argumentCountIncludingThis == 2); insertChecks(); Node* isRegExpObject = addToGraph(IsRegExpObject, OpInfo(prediction), get(virtualRegisterForArgument(1, registerOffset))); set(VirtualRegister(resultOperand), isRegExpObject); return true; } case StringPrototypeReplaceIntrinsic: { if (argumentCountIncludingThis != 3) return false; // Don't inline intrinsic if we exited due to "search" not being a RegExp or String object. if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadType)) return false; // Don't inline intrinsic if we exited due to one of the primordial RegExp checks failing. if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadCell)) return false; JSGlobalObject* globalObject = m_inlineStackTop->m_codeBlock->globalObject(); Structure* regExpStructure = globalObject->regExpStructure(); m_graph.registerStructure(regExpStructure); ASSERT(regExpStructure->storedPrototype().isObject()); ASSERT(regExpStructure->storedPrototype().asCell()->classInfo() == RegExpPrototype::info()); FrozenValue* regExpPrototypeObjectValue = m_graph.freeze(regExpStructure->storedPrototype()); Structure* regExpPrototypeStructure = regExpPrototypeObjectValue->structure(); auto isRegExpPropertySame = [&] (JSValue primordialProperty, UniquedStringImpl* propertyUID) { JSValue currentProperty; if (!m_graph.getRegExpPrototypeProperty(regExpStructure->storedPrototypeObject(), regExpPrototypeStructure, propertyUID, currentProperty)) return false; return currentProperty == primordialProperty; }; // Check that searchRegExp.exec is still the primordial RegExp.prototype.exec if (!isRegExpPropertySame(globalObject->regExpProtoExecFunction(), m_vm->propertyNames->exec.impl())) return false; // Check that searchRegExp.global is still the primordial RegExp.prototype.global if (!isRegExpPropertySame(globalObject->regExpProtoGlobalGetter(), m_vm->propertyNames->global.impl())) return false; // Check that searchRegExp.unicode is still the primordial RegExp.prototype.unicode if (!isRegExpPropertySame(globalObject->regExpProtoUnicodeGetter(), m_vm->propertyNames->unicode.impl())) return false; // Check that searchRegExp[Symbol.match] is still the primordial RegExp.prototype[Symbol.replace] if (!isRegExpPropertySame(globalObject->regExpProtoSymbolReplaceFunction(), m_vm->propertyNames->replaceSymbol.impl())) return false; insertChecks(); Node* result = addToGraph(StringReplace, OpInfo(0), OpInfo(prediction), get(virtualRegisterForArgument(0, registerOffset)), get(virtualRegisterForArgument(1, registerOffset)), get(virtualRegisterForArgument(2, registerOffset))); set(VirtualRegister(resultOperand), result); return true; } case StringPrototypeReplaceRegExpIntrinsic: { if (argumentCountIncludingThis != 3) return false; insertChecks(); Node* result = addToGraph(StringReplaceRegExp, OpInfo(0), OpInfo(prediction), get(virtualRegisterForArgument(0, registerOffset)), get(virtualRegisterForArgument(1, registerOffset)), get(virtualRegisterForArgument(2, registerOffset))); set(VirtualRegister(resultOperand), result); return true; } case RoundIntrinsic: case FloorIntrinsic: case CeilIntrinsic: case TruncIntrinsic: { if (argumentCountIncludingThis == 1) { insertChecks(); set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantNaN))); return true; } if (argumentCountIncludingThis == 2) { insertChecks(); Node* operand = get(virtualRegisterForArgument(1, registerOffset)); NodeType op; if (intrinsic == RoundIntrinsic) op = ArithRound; else if (intrinsic == FloorIntrinsic) op = ArithFloor; else if (intrinsic == CeilIntrinsic) op = ArithCeil; else { ASSERT(intrinsic == TruncIntrinsic); op = ArithTrunc; } Node* roundNode = addToGraph(op, OpInfo(0), OpInfo(prediction), operand); set(VirtualRegister(resultOperand), roundNode); return true; } return false; } case IMulIntrinsic: { if (argumentCountIncludingThis != 3) return false; insertChecks(); VirtualRegister leftOperand = virtualRegisterForArgument(1, registerOffset); VirtualRegister rightOperand = virtualRegisterForArgument(2, registerOffset); Node* left = get(leftOperand); Node* right = get(rightOperand); set(VirtualRegister(resultOperand), addToGraph(ArithIMul, left, right)); return true; } case RandomIntrinsic: { if (argumentCountIncludingThis != 1) return false; insertChecks(); set(VirtualRegister(resultOperand), addToGraph(ArithRandom)); return true; } case FRoundIntrinsic: { if (argumentCountIncludingThis != 2) return false; insertChecks(); VirtualRegister operand = virtualRegisterForArgument(1, registerOffset); set(VirtualRegister(resultOperand), addToGraph(ArithFRound, get(operand))); return true; } case DFGTrueIntrinsic: { insertChecks(); set(VirtualRegister(resultOperand), jsConstant(jsBoolean(true))); return true; } case OSRExitIntrinsic: { insertChecks(); addToGraph(ForceOSRExit); set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantUndefined))); return true; } case IsFinalTierIntrinsic: { insertChecks(); set(VirtualRegister(resultOperand), jsConstant(jsBoolean(Options::useFTLJIT() ? isFTL(m_graph.m_plan.mode) : true))); return true; } case SetInt32HeapPredictionIntrinsic: { insertChecks(); for (int i = 1; i < argumentCountIncludingThis; ++i) { Node* node = get(virtualRegisterForArgument(i, registerOffset)); if (node->hasHeapPrediction()) node->setHeapPrediction(SpecInt32Only); } set(VirtualRegister(resultOperand), addToGraph(JSConstant, OpInfo(m_constantUndefined))); return true; } case CheckInt32Intrinsic: { insertChecks(); for (int i = 1; i < argumentCountIncludingThis; ++i) { Node* node = get(virtualRegisterForArgument(i, registerOffset)); addToGraph(Phantom, Edge(node, Int32Use)); } set(VirtualRegister(resultOperand), jsConstant(jsBoolean(true))); return true; } case FiatInt52Intrinsic: { if (argumentCountIncludingThis != 2) return false; insertChecks(); VirtualRegister operand = virtualRegisterForArgument(1, registerOffset); if (enableInt52()) set(VirtualRegister(resultOperand), addToGraph(FiatInt52, get(operand))); else set(VirtualRegister(resultOperand), get(operand)); return true; } default: return false; } } template bool ByteCodeParser::handleIntrinsicGetter(int resultOperand, const GetByIdVariant& variant, Node* thisNode, const ChecksFunctor& insertChecks) { switch (variant.intrinsic()) { case TypedArrayByteLengthIntrinsic: { insertChecks(); TypedArrayType type = (*variant.structureSet().begin())->classInfo()->typedArrayStorageType; Array::Type arrayType = toArrayType(type); size_t logSize = logElementSize(type); variant.structureSet().forEach([&] (Structure* structure) { TypedArrayType curType = structure->classInfo()->typedArrayStorageType; ASSERT(logSize == logElementSize(curType)); arrayType = refineTypedArrayType(arrayType, curType); ASSERT(arrayType != Array::Generic); }); Node* lengthNode = addToGraph(GetArrayLength, OpInfo(ArrayMode(arrayType).asWord()), thisNode); if (!logSize) { set(VirtualRegister(resultOperand), lengthNode); return true; } // We can use a BitLShift here because typed arrays will never have a byteLength // that overflows int32. Node* shiftNode = jsConstant(jsNumber(logSize)); set(VirtualRegister(resultOperand), addToGraph(BitLShift, lengthNode, shiftNode)); return true; } case TypedArrayLengthIntrinsic: { insertChecks(); TypedArrayType type = (*variant.structureSet().begin())->classInfo()->typedArrayStorageType; Array::Type arrayType = toArrayType(type); variant.structureSet().forEach([&] (Structure* structure) { TypedArrayType curType = structure->classInfo()->typedArrayStorageType; arrayType = refineTypedArrayType(arrayType, curType); ASSERT(arrayType != Array::Generic); }); set(VirtualRegister(resultOperand), addToGraph(GetArrayLength, OpInfo(ArrayMode(arrayType).asWord()), thisNode)); return true; } case TypedArrayByteOffsetIntrinsic: { insertChecks(); TypedArrayType type = (*variant.structureSet().begin())->classInfo()->typedArrayStorageType; Array::Type arrayType = toArrayType(type); variant.structureSet().forEach([&] (Structure* structure) { TypedArrayType curType = structure->classInfo()->typedArrayStorageType; arrayType = refineTypedArrayType(arrayType, curType); ASSERT(arrayType != Array::Generic); }); set(VirtualRegister(resultOperand), addToGraph(GetTypedArrayByteOffset, OpInfo(ArrayMode(arrayType).asWord()), thisNode)); return true; } default: return false; } RELEASE_ASSERT_NOT_REACHED(); } template bool ByteCodeParser::handleTypedArrayConstructor( int resultOperand, InternalFunction* function, int registerOffset, int argumentCountIncludingThis, TypedArrayType type, const ChecksFunctor& insertChecks) { if (!isTypedView(type)) return false; if (function->classInfo() != constructorClassInfoForType(type)) return false; if (function->globalObject() != m_inlineStackTop->m_codeBlock->globalObject()) return false; // We only have an intrinsic for the case where you say: // // new FooArray(blah); // // Of course, 'blah' could be any of the following: // // - Integer, indicating that you want to allocate an array of that length. // This is the thing we're hoping for, and what we can actually do meaningful // optimizations for. // // - Array buffer, indicating that you want to create a view onto that _entire_ // buffer. // // - Non-buffer object, indicating that you want to create a copy of that // object by pretending that it quacks like an array. // // - Anything else, indicating that you want to have an exception thrown at // you. // // The intrinsic, NewTypedArray, will behave as if it could do any of these // things up until we do Fixup. Thereafter, if child1 (i.e. 'blah') is // predicted Int32, then we lock it in as a normal typed array allocation. // Otherwise, NewTypedArray turns into a totally opaque function call that // may clobber the world - by virtue of it accessing properties on what could // be an object. // // Note that although the generic form of NewTypedArray sounds sort of awful, // it is actually quite likely to be more efficient than a fully generic // Construct. So, we might want to think about making NewTypedArray variadic, // or else making Construct not super slow. if (argumentCountIncludingThis != 2) return false; if (!function->globalObject()->typedArrayStructureConcurrently(type)) return false; insertChecks(); set(VirtualRegister(resultOperand), addToGraph(NewTypedArray, OpInfo(type), get(virtualRegisterForArgument(1, registerOffset)))); return true; } template bool ByteCodeParser::handleConstantInternalFunction( Node* callTargetNode, int resultOperand, InternalFunction* function, int registerOffset, int argumentCountIncludingThis, CodeSpecializationKind kind, const ChecksFunctor& insertChecks) { if (verbose) dataLog(" Handling constant internal function ", JSValue(function), "\n"); if (kind == CodeForConstruct) { Node* newTargetNode = get(virtualRegisterForArgument(0, registerOffset)); // We cannot handle the case where new.target != callee (i.e. a construct from a super call) because we // don't know what the prototype of the constructed object will be. // FIXME: If we have inlined super calls up to the call site, however, we should be able to figure out the structure. https://bugs.webkit.org/show_bug.cgi?id=152700 if (newTargetNode != callTargetNode) return false; } if (function->classInfo() == ArrayConstructor::info()) { if (function->globalObject() != m_inlineStackTop->m_codeBlock->globalObject()) return false; insertChecks(); if (argumentCountIncludingThis == 2) { set(VirtualRegister(resultOperand), addToGraph(NewArrayWithSize, OpInfo(ArrayWithUndecided), get(virtualRegisterForArgument(1, registerOffset)))); return true; } for (int i = 1; i < argumentCountIncludingThis; ++i) addVarArgChild(get(virtualRegisterForArgument(i, registerOffset))); set(VirtualRegister(resultOperand), addToGraph(Node::VarArg, NewArray, OpInfo(ArrayWithUndecided), OpInfo(0))); return true; } if (function->classInfo() == StringConstructor::info()) { insertChecks(); Node* result; if (argumentCountIncludingThis <= 1) result = jsConstant(m_vm->smallStrings.emptyString()); else result = addToGraph(CallStringConstructor, get(virtualRegisterForArgument(1, registerOffset))); if (kind == CodeForConstruct) result = addToGraph(NewStringObject, OpInfo(function->globalObject()->stringObjectStructure()), result); set(VirtualRegister(resultOperand), result); return true; } for (unsigned typeIndex = 0; typeIndex < NUMBER_OF_TYPED_ARRAY_TYPES; ++typeIndex) { bool result = handleTypedArrayConstructor( resultOperand, function, registerOffset, argumentCountIncludingThis, indexToTypedArrayType(typeIndex), insertChecks); if (result) return true; } return false; } Node* ByteCodeParser::handleGetByOffset( SpeculatedType prediction, Node* base, unsigned identifierNumber, PropertyOffset offset, const InferredType::Descriptor& inferredType, NodeType op) { Node* propertyStorage; if (isInlineOffset(offset)) propertyStorage = base; else propertyStorage = addToGraph(GetButterfly, base); StorageAccessData* data = m_graph.m_storageAccessData.add(); data->offset = offset; data->identifierNumber = identifierNumber; data->inferredType = inferredType; m_graph.registerInferredType(inferredType); Node* getByOffset = addToGraph(op, OpInfo(data), OpInfo(prediction), propertyStorage, base); return getByOffset; } Node* ByteCodeParser::handlePutByOffset( Node* base, unsigned identifier, PropertyOffset offset, const InferredType::Descriptor& inferredType, Node* value) { Node* propertyStorage; if (isInlineOffset(offset)) propertyStorage = base; else propertyStorage = addToGraph(GetButterfly, base); StorageAccessData* data = m_graph.m_storageAccessData.add(); data->offset = offset; data->identifierNumber = identifier; data->inferredType = inferredType; m_graph.registerInferredType(inferredType); Node* result = addToGraph(PutByOffset, OpInfo(data), propertyStorage, base, value); return result; } bool ByteCodeParser::check(const ObjectPropertyCondition& condition) { if (!condition) return false; if (m_graph.watchCondition(condition)) return true; Structure* structure = condition.object()->structure(); if (!condition.structureEnsuresValidity(structure)) return false; addToGraph( CheckStructure, OpInfo(m_graph.addStructureSet(structure)), weakJSConstant(condition.object())); return true; } GetByOffsetMethod ByteCodeParser::promoteToConstant(GetByOffsetMethod method) { if (method.kind() == GetByOffsetMethod::LoadFromPrototype && method.prototype()->structure()->dfgShouldWatch()) { if (JSValue constant = m_graph.tryGetConstantProperty(method.prototype()->value(), method.prototype()->structure(), method.offset())) return GetByOffsetMethod::constant(m_graph.freeze(constant)); } return method; } bool ByteCodeParser::needsDynamicLookup(ResolveType type, OpcodeID opcode) { ASSERT(opcode == op_resolve_scope || opcode == op_get_from_scope || opcode == op_put_to_scope); JSGlobalObject* globalObject = m_inlineStackTop->m_codeBlock->globalObject(); if (needsVarInjectionChecks(type) && globalObject->varInjectionWatchpoint()->hasBeenInvalidated()) return true; switch (type) { case GlobalProperty: case GlobalVar: case GlobalLexicalVar: case ClosureVar: case LocalClosureVar: case ModuleVar: return false; case UnresolvedProperty: case UnresolvedPropertyWithVarInjectionChecks: { // The heuristic for UnresolvedProperty scope accesses is we will ForceOSRExit if we // haven't exited from from this access before to let the baseline JIT try to better // cache the access. If we've already exited from this operation, it's unlikely that // the baseline will come up with a better ResolveType and instead we will compile // this as a dynamic scope access. // We only track our heuristic through resolve_scope since resolve_scope will // dominate unresolved gets/puts on that scope. if (opcode != op_resolve_scope) return true; if (m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, InadequateCoverage)) { // We've already exited so give up on getting better ResolveType information. return true; } // We have not exited yet, so let's have the baseline get better ResolveType information for us. // This type of code is often seen when we tier up in a loop but haven't executed the part // of a function that comes after the loop. return false; } case Dynamic: return true; case GlobalPropertyWithVarInjectionChecks: case GlobalVarWithVarInjectionChecks: case GlobalLexicalVarWithVarInjectionChecks: case ClosureVarWithVarInjectionChecks: return false; } ASSERT_NOT_REACHED(); return false; } GetByOffsetMethod ByteCodeParser::planLoad(const ObjectPropertyCondition& condition) { if (verbose) dataLog("Planning a load: ", condition, "\n"); // We might promote this to Equivalence, and a later DFG pass might also do such promotion // even if we fail, but for simplicity this cannot be asked to load an equivalence condition. // None of the clients of this method will request a load of an Equivalence condition anyway, // and supporting it would complicate the heuristics below. RELEASE_ASSERT(condition.kind() == PropertyCondition::Presence); // Here's the ranking of how to handle this, from most preferred to least preferred: // // 1) Watchpoint on an equivalence condition and return a constant node for the loaded value. // No other code is emitted, and the structure of the base object is never registered. // Hence this results in zero code and we won't jettison this compilation if the object // transitions, even if the structure is watchable right now. // // 2) Need to emit a load, and the current structure of the base is going to be watched by the // DFG anyway (i.e. dfgShouldWatch). Watch the structure and emit the load. Don't watch the // condition, since the act of turning the base into a constant in IR will cause the DFG to // watch the structure anyway and doing so would subsume watching the condition. // // 3) Need to emit a load, and the current structure of the base is watchable but not by the // DFG (i.e. transitionWatchpointSetIsStillValid() and !dfgShouldWatchIfPossible()). Watch // the condition, and emit a load. // // 4) Need to emit a load, and the current structure of the base is not watchable. Emit a // structure check, and emit a load. // // 5) The condition does not hold. Give up and return null. // First, try to promote Presence to Equivalence. We do this before doing anything else // because it's the most profitable. Also, there are cases where the presence is watchable but // we don't want to watch it unless it became an equivalence (see the relationship between // (1), (2), and (3) above). ObjectPropertyCondition equivalenceCondition = condition.attemptToMakeEquivalenceWithoutBarrier(); if (m_graph.watchCondition(equivalenceCondition)) return GetByOffsetMethod::constant(m_graph.freeze(equivalenceCondition.requiredValue())); // At this point, we'll have to materialize the condition's base as a constant in DFG IR. Once // we do this, the frozen value will have its own idea of what the structure is. Use that from // now on just because it's less confusing. FrozenValue* base = m_graph.freeze(condition.object()); Structure* structure = base->structure(); // Check if the structure that we've registered makes the condition hold. If not, just give // up. This is case (5) above. if (!condition.structureEnsuresValidity(structure)) return GetByOffsetMethod(); // If the structure is watched by the DFG already, then just use this fact to emit the load. // This is case (2) above. if (structure->dfgShouldWatch()) return promoteToConstant(GetByOffsetMethod::loadFromPrototype(base, condition.offset())); // If we can watch the condition right now, then we can emit the load after watching it. This // is case (3) above. if (m_graph.watchCondition(condition)) return promoteToConstant(GetByOffsetMethod::loadFromPrototype(base, condition.offset())); // We can't watch anything but we know that the current structure satisfies the condition. So, // check for that structure and then emit the load. addToGraph( CheckStructure, OpInfo(m_graph.addStructureSet(structure)), addToGraph(JSConstant, OpInfo(base))); return promoteToConstant(GetByOffsetMethod::loadFromPrototype(base, condition.offset())); } Node* ByteCodeParser::load( SpeculatedType prediction, unsigned identifierNumber, const GetByOffsetMethod& method, NodeType op) { switch (method.kind()) { case GetByOffsetMethod::Invalid: return nullptr; case GetByOffsetMethod::Constant: return addToGraph(JSConstant, OpInfo(method.constant())); case GetByOffsetMethod::LoadFromPrototype: { Node* baseNode = addToGraph(JSConstant, OpInfo(method.prototype())); return handleGetByOffset( prediction, baseNode, identifierNumber, method.offset(), InferredType::Top, op); } case GetByOffsetMethod::Load: // Will never see this from planLoad(). RELEASE_ASSERT_NOT_REACHED(); return nullptr; } RELEASE_ASSERT_NOT_REACHED(); return nullptr; } Node* ByteCodeParser::load( SpeculatedType prediction, const ObjectPropertyCondition& condition, NodeType op) { GetByOffsetMethod method = planLoad(condition); return load(prediction, m_graph.identifiers().ensure(condition.uid()), method, op); } bool ByteCodeParser::check(const ObjectPropertyConditionSet& conditionSet) { for (const ObjectPropertyCondition condition : conditionSet) { if (!check(condition)) return false; } return true; } GetByOffsetMethod ByteCodeParser::planLoad(const ObjectPropertyConditionSet& conditionSet) { if (verbose) dataLog("conditionSet = ", conditionSet, "\n"); GetByOffsetMethod result; for (const ObjectPropertyCondition condition : conditionSet) { switch (condition.kind()) { case PropertyCondition::Presence: RELEASE_ASSERT(!result); // Should only see exactly one of these. result = planLoad(condition); if (!result) return GetByOffsetMethod(); break; default: if (!check(condition)) return GetByOffsetMethod(); break; } } RELEASE_ASSERT(!!result); return result; } Node* ByteCodeParser::load( SpeculatedType prediction, const ObjectPropertyConditionSet& conditionSet, NodeType op) { GetByOffsetMethod method = planLoad(conditionSet); return load( prediction, m_graph.identifiers().ensure(conditionSet.slotBaseCondition().uid()), method, op); } ObjectPropertyCondition ByteCodeParser::presenceLike( JSObject* knownBase, UniquedStringImpl* uid, PropertyOffset offset, const StructureSet& set) { if (set.isEmpty()) return ObjectPropertyCondition(); unsigned attributes; PropertyOffset firstOffset = set[0]->getConcurrently(uid, attributes); if (firstOffset != offset) return ObjectPropertyCondition(); for (unsigned i = 1; i < set.size(); ++i) { unsigned otherAttributes; PropertyOffset otherOffset = set[i]->getConcurrently(uid, otherAttributes); if (otherOffset != offset || otherAttributes != attributes) return ObjectPropertyCondition(); } return ObjectPropertyCondition::presenceWithoutBarrier(knownBase, uid, offset, attributes); } bool ByteCodeParser::checkPresenceLike( JSObject* knownBase, UniquedStringImpl* uid, PropertyOffset offset, const StructureSet& set) { return check(presenceLike(knownBase, uid, offset, set)); } void ByteCodeParser::checkPresenceLike( Node* base, UniquedStringImpl* uid, PropertyOffset offset, const StructureSet& set) { if (JSObject* knownBase = base->dynamicCastConstant()) { if (checkPresenceLike(knownBase, uid, offset, set)) return; } addToGraph(CheckStructure, OpInfo(m_graph.addStructureSet(set)), base); } template Node* ByteCodeParser::load( SpeculatedType prediction, Node* base, unsigned identifierNumber, const VariantType& variant) { // Make sure backwards propagation knows that we've used base. addToGraph(Phantom, base); bool needStructureCheck = true; UniquedStringImpl* uid = m_graph.identifiers()[identifierNumber]; if (JSObject* knownBase = base->dynamicCastConstant()) { // Try to optimize away the structure check. Note that it's not worth doing anything about this // if the base's structure is watched. Structure* structure = base->constant()->structure(); if (!structure->dfgShouldWatch()) { if (!variant.conditionSet().isEmpty()) { // This means that we're loading from a prototype. We expect the base not to have the // property. We can only use ObjectPropertyCondition if all of the structures in the // variant.structureSet() agree on the prototype (it would be hilariously rare if they // didn't). Note that we are relying on structureSet() having at least one element. That // will always be true here because of how GetByIdStatus/PutByIdStatus work. JSObject* prototype = variant.structureSet()[0]->storedPrototypeObject(); bool allAgree = true; for (unsigned i = 1; i < variant.structureSet().size(); ++i) { if (variant.structureSet()[i]->storedPrototypeObject() != prototype) { allAgree = false; break; } } if (allAgree) { ObjectPropertyCondition condition = ObjectPropertyCondition::absenceWithoutBarrier( knownBase, uid, prototype); if (check(condition)) needStructureCheck = false; } } else { // This means we're loading directly from base. We can avoid all of the code that follows // if we can prove that the property is a constant. Otherwise, we try to prove that the // property is watchably present, in which case we get rid of the structure check. ObjectPropertyCondition presenceCondition = presenceLike(knownBase, uid, variant.offset(), variant.structureSet()); if (presenceCondition) { ObjectPropertyCondition equivalenceCondition = presenceCondition.attemptToMakeEquivalenceWithoutBarrier(); if (m_graph.watchCondition(equivalenceCondition)) return weakJSConstant(equivalenceCondition.requiredValue()); if (check(presenceCondition)) needStructureCheck = false; } } } } if (needStructureCheck) addToGraph(CheckStructure, OpInfo(m_graph.addStructureSet(variant.structureSet())), base); SpeculatedType loadPrediction; NodeType loadOp; if (variant.callLinkStatus() || variant.intrinsic() != NoIntrinsic) { loadPrediction = SpecCellOther; loadOp = GetGetterSetterByOffset; } else { loadPrediction = prediction; loadOp = GetByOffset; } Node* loadedValue; if (!variant.conditionSet().isEmpty()) loadedValue = load(loadPrediction, variant.conditionSet(), loadOp); else { if (needStructureCheck && base->hasConstant()) { // We did emit a structure check. That means that we have an opportunity to do constant folding // here, since we didn't do it above. JSValue constant = m_graph.tryGetConstantProperty( base->asJSValue(), variant.structureSet(), variant.offset()); if (constant) return weakJSConstant(constant); } InferredType::Descriptor inferredType; if (needStructureCheck) { for (Structure* structure : variant.structureSet()) { InferredType::Descriptor thisType = m_graph.inferredTypeForProperty(structure, uid); inferredType.merge(thisType); } } else inferredType = InferredType::Top; loadedValue = handleGetByOffset( loadPrediction, base, identifierNumber, variant.offset(), inferredType, loadOp); } return loadedValue; } Node* ByteCodeParser::store(Node* base, unsigned identifier, const PutByIdVariant& variant, Node* value) { RELEASE_ASSERT(variant.kind() == PutByIdVariant::Replace); checkPresenceLike(base, m_graph.identifiers()[identifier], variant.offset(), variant.structure()); return handlePutByOffset(base, identifier, variant.offset(), variant.requiredType(), value); } void ByteCodeParser::handleGetById( int destinationOperand, SpeculatedType prediction, Node* base, unsigned identifierNumber, GetByIdStatus getByIdStatus, AccessType type) { // Attempt to reduce the set of things in the GetByIdStatus. if (base->op() == NewObject) { bool ok = true; for (unsigned i = m_currentBlock->size(); i--;) { Node* node = m_currentBlock->at(i); if (node == base) break; if (writesOverlap(m_graph, node, JSCell_structureID)) { ok = false; break; } } if (ok) getByIdStatus.filter(base->structure()); } NodeType getById; if (type == AccessType::Get) getById = getByIdStatus.makesCalls() ? GetByIdFlush : GetById; else getById = TryGetById; ASSERT(type == AccessType::Get || !getByIdStatus.makesCalls()); if (!getByIdStatus.isSimple() || !getByIdStatus.numVariants() || !Options::useAccessInlining()) { set(VirtualRegister(destinationOperand), addToGraph(getById, OpInfo(identifierNumber), OpInfo(prediction), base)); return; } if (getByIdStatus.numVariants() > 1) { if (getByIdStatus.makesCalls() || !isFTL(m_graph.m_plan.mode) || !Options::usePolymorphicAccessInlining()) { set(VirtualRegister(destinationOperand), addToGraph(getById, OpInfo(identifierNumber), OpInfo(prediction), base)); return; } Vector cases; // 1) Emit prototype structure checks for all chains. This could sort of maybe not be // optimal, if there is some rarely executed case in the chain that requires a lot // of checks and those checks are not watchpointable. for (const GetByIdVariant& variant : getByIdStatus.variants()) { if (variant.intrinsic() != NoIntrinsic) { set(VirtualRegister(destinationOperand), addToGraph(getById, OpInfo(identifierNumber), OpInfo(prediction), base)); return; } if (variant.conditionSet().isEmpty()) { cases.append( MultiGetByOffsetCase( variant.structureSet(), GetByOffsetMethod::load(variant.offset()))); continue; } GetByOffsetMethod method = planLoad(variant.conditionSet()); if (!method) { set(VirtualRegister(destinationOperand), addToGraph(getById, OpInfo(identifierNumber), OpInfo(prediction), base)); return; } cases.append(MultiGetByOffsetCase(variant.structureSet(), method)); } if (m_graph.compilation()) m_graph.compilation()->noticeInlinedGetById(); // 2) Emit a MultiGetByOffset MultiGetByOffsetData* data = m_graph.m_multiGetByOffsetData.add(); data->cases = cases; data->identifierNumber = identifierNumber; set(VirtualRegister(destinationOperand), addToGraph(MultiGetByOffset, OpInfo(data), OpInfo(prediction), base)); return; } ASSERT(getByIdStatus.numVariants() == 1); GetByIdVariant variant = getByIdStatus[0]; Node* loadedValue = load(prediction, base, identifierNumber, variant); if (!loadedValue) { set(VirtualRegister(destinationOperand), addToGraph(getById, OpInfo(identifierNumber), OpInfo(prediction), base)); return; } if (m_graph.compilation()) m_graph.compilation()->noticeInlinedGetById(); ASSERT(type == AccessType::Get || !variant.callLinkStatus()); if (!variant.callLinkStatus() && variant.intrinsic() == NoIntrinsic) { set(VirtualRegister(destinationOperand), loadedValue); return; } Node* getter = addToGraph(GetGetter, loadedValue); if (handleIntrinsicGetter(destinationOperand, variant, base, [&] () { addToGraph(CheckCell, OpInfo(m_graph.freeze(variant.intrinsicFunction())), getter, base); })) { addToGraph(Phantom, getter); return; } ASSERT(variant.intrinsic() == NoIntrinsic); // Make a call. We don't try to get fancy with using the smallest operand number because // the stack layout phase should compress the stack anyway. unsigned numberOfParameters = 0; numberOfParameters++; // The 'this' argument. numberOfParameters++; // True return PC. // Start with a register offset that corresponds to the last in-use register. int registerOffset = virtualRegisterForLocal( m_inlineStackTop->m_profiledBlock->m_numCalleeLocals - 1).offset(); registerOffset -= numberOfParameters; registerOffset -= JSStack::CallFrameHeaderSize; // Get the alignment right. registerOffset = -WTF::roundUpToMultipleOf( stackAlignmentRegisters(), -registerOffset); ensureLocals( m_inlineStackTop->remapOperand( VirtualRegister(registerOffset)).toLocal()); // Issue SetLocals. This has two effects: // 1) That's how handleCall() sees the arguments. // 2) If we inline then this ensures that the arguments are flushed so that if you use // the dreaded arguments object on the getter, the right things happen. Well, sort of - // since we only really care about 'this' in this case. But we're not going to take that // shortcut. int nextRegister = registerOffset + JSStack::CallFrameHeaderSize; set(VirtualRegister(nextRegister++), base, ImmediateNakedSet); // We've set some locals, but they are not user-visible. It's still OK to exit from here. m_exitOK = true; addToGraph(ExitOK); handleCall( destinationOperand, Call, InlineCallFrame::GetterCall, OPCODE_LENGTH(op_get_by_id), getter, numberOfParameters - 1, registerOffset, *variant.callLinkStatus(), prediction); } void ByteCodeParser::emitPutById( Node* base, unsigned identifierNumber, Node* value, const PutByIdStatus& putByIdStatus, bool isDirect) { if (isDirect) addToGraph(PutByIdDirect, OpInfo(identifierNumber), base, value); else addToGraph(putByIdStatus.makesCalls() ? PutByIdFlush : PutById, OpInfo(identifierNumber), base, value); } void ByteCodeParser::handlePutById( Node* base, unsigned identifierNumber, Node* value, const PutByIdStatus& putByIdStatus, bool isDirect) { if (!putByIdStatus.isSimple() || !putByIdStatus.numVariants() || !Options::useAccessInlining()) { if (!putByIdStatus.isSet()) addToGraph(ForceOSRExit); emitPutById(base, identifierNumber, value, putByIdStatus, isDirect); return; } if (putByIdStatus.numVariants() > 1) { if (!isFTL(m_graph.m_plan.mode) || putByIdStatus.makesCalls() || !Options::usePolymorphicAccessInlining()) { emitPutById(base, identifierNumber, value, putByIdStatus, isDirect); return; } if (!isDirect) { for (unsigned variantIndex = putByIdStatus.numVariants(); variantIndex--;) { if (putByIdStatus[variantIndex].kind() != PutByIdVariant::Transition) continue; if (!check(putByIdStatus[variantIndex].conditionSet())) { emitPutById(base, identifierNumber, value, putByIdStatus, isDirect); return; } } } if (m_graph.compilation()) m_graph.compilation()->noticeInlinedPutById(); for (const PutByIdVariant& variant : putByIdStatus.variants()) m_graph.registerInferredType(variant.requiredType()); MultiPutByOffsetData* data = m_graph.m_multiPutByOffsetData.add(); data->variants = putByIdStatus.variants(); data->identifierNumber = identifierNumber; addToGraph(MultiPutByOffset, OpInfo(data), base, value); return; } ASSERT(putByIdStatus.numVariants() == 1); const PutByIdVariant& variant = putByIdStatus[0]; switch (variant.kind()) { case PutByIdVariant::Replace: { store(base, identifierNumber, variant, value); if (m_graph.compilation()) m_graph.compilation()->noticeInlinedPutById(); return; } case PutByIdVariant::Transition: { addToGraph(CheckStructure, OpInfo(m_graph.addStructureSet(variant.oldStructure())), base); if (!check(variant.conditionSet())) { emitPutById(base, identifierNumber, value, putByIdStatus, isDirect); return; } ASSERT(variant.oldStructureForTransition()->transitionWatchpointSetHasBeenInvalidated()); Node* propertyStorage; Transition* transition = m_graph.m_transitions.add( variant.oldStructureForTransition(), variant.newStructure()); if (variant.reallocatesStorage()) { // If we're growing the property storage then it must be because we're // storing into the out-of-line storage. ASSERT(!isInlineOffset(variant.offset())); if (!variant.oldStructureForTransition()->outOfLineCapacity()) { propertyStorage = addToGraph( AllocatePropertyStorage, OpInfo(transition), base); } else { propertyStorage = addToGraph( ReallocatePropertyStorage, OpInfo(transition), base, addToGraph(GetButterfly, base)); } } else { if (isInlineOffset(variant.offset())) propertyStorage = base; else propertyStorage = addToGraph(GetButterfly, base); } StorageAccessData* data = m_graph.m_storageAccessData.add(); data->offset = variant.offset(); data->identifierNumber = identifierNumber; data->inferredType = variant.requiredType(); m_graph.registerInferredType(data->inferredType); addToGraph( PutByOffset, OpInfo(data), propertyStorage, base, value); // FIXME: PutStructure goes last until we fix either // https://bugs.webkit.org/show_bug.cgi?id=142921 or // https://bugs.webkit.org/show_bug.cgi?id=142924. addToGraph(PutStructure, OpInfo(transition), base); if (m_graph.compilation()) m_graph.compilation()->noticeInlinedPutById(); return; } case PutByIdVariant::Setter: { Node* loadedValue = load(SpecCellOther, base, identifierNumber, variant); if (!loadedValue) { emitPutById(base, identifierNumber, value, putByIdStatus, isDirect); return; } Node* setter = addToGraph(GetSetter, loadedValue); // Make a call. We don't try to get fancy with using the smallest operand number because // the stack layout phase should compress the stack anyway. unsigned numberOfParameters = 0; numberOfParameters++; // The 'this' argument. numberOfParameters++; // The new value. numberOfParameters++; // True return PC. // Start with a register offset that corresponds to the last in-use register. int registerOffset = virtualRegisterForLocal( m_inlineStackTop->m_profiledBlock->m_numCalleeLocals - 1).offset(); registerOffset -= numberOfParameters; registerOffset -= JSStack::CallFrameHeaderSize; // Get the alignment right. registerOffset = -WTF::roundUpToMultipleOf( stackAlignmentRegisters(), -registerOffset); ensureLocals( m_inlineStackTop->remapOperand( VirtualRegister(registerOffset)).toLocal()); int nextRegister = registerOffset + JSStack::CallFrameHeaderSize; set(VirtualRegister(nextRegister++), base, ImmediateNakedSet); set(VirtualRegister(nextRegister++), value, ImmediateNakedSet); // We've set some locals, but they are not user-visible. It's still OK to exit from here. m_exitOK = true; addToGraph(ExitOK); handleCall( VirtualRegister().offset(), Call, InlineCallFrame::SetterCall, OPCODE_LENGTH(op_put_by_id), setter, numberOfParameters - 1, registerOffset, *variant.callLinkStatus(), SpecOther); return; } default: { emitPutById(base, identifierNumber, value, putByIdStatus, isDirect); return; } } } void ByteCodeParser::prepareToParseBlock() { clearCaches(); ASSERT(m_setLocalQueue.isEmpty()); } void ByteCodeParser::clearCaches() { m_constants.resize(0); } bool ByteCodeParser::parseBlock(unsigned limit) { bool shouldContinueParsing = true; Interpreter* interpreter = m_vm->interpreter; Instruction* instructionsBegin = m_inlineStackTop->m_codeBlock->instructions().begin(); unsigned blockBegin = m_currentIndex; // If we are the first basic block, introduce markers for arguments. This allows // us to track if a use of an argument may use the actual argument passed, as // opposed to using a value we set explicitly. if (m_currentBlock == m_graph.block(0) && !inlineCallFrame()) { m_graph.m_arguments.resize(m_numArguments); // We will emit SetArgument nodes. They don't exit, but we're at the top of an op_enter so // exitOK = true. m_exitOK = true; for (unsigned argument = 0; argument < m_numArguments; ++argument) { VariableAccessData* variable = newVariableAccessData( virtualRegisterForArgument(argument)); variable->mergeStructureCheckHoistingFailed( m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadCache)); variable->mergeCheckArrayHoistingFailed( m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadIndexingType)); Node* setArgument = addToGraph(SetArgument, OpInfo(variable)); m_graph.m_arguments[argument] = setArgument; m_currentBlock->variablesAtTail.setArgumentFirstTime(argument, setArgument); } } while (true) { // We're staring a new bytecode instruction. Hence, we once again have a place that we can exit // to. m_exitOK = true; processSetLocalQueue(); // Don't extend over jump destinations. if (m_currentIndex == limit) { // Ordinarily we want to plant a jump. But refuse to do this if the block is // empty. This is a special case for inlining, which might otherwise create // some empty blocks in some cases. When parseBlock() returns with an empty // block, it will get repurposed instead of creating a new one. Note that this // logic relies on every bytecode resulting in one or more nodes, which would // be true anyway except for op_loop_hint, which emits a Phantom to force this // to be true. // We also don't insert a jump if the block already has a terminal, // which could happen after a tail call. ASSERT(m_currentBlock->isEmpty() || !m_currentBlock->terminal()); if (!m_currentBlock->isEmpty()) addToGraph(Jump, OpInfo(m_currentIndex)); return shouldContinueParsing; } // Switch on the current bytecode opcode. Instruction* currentInstruction = instructionsBegin + m_currentIndex; m_currentInstruction = currentInstruction; // Some methods want to use this, and we'd rather not thread it through calls. OpcodeID opcodeID = interpreter->getOpcodeID(currentInstruction->u.opcode); if (Options::verboseDFGByteCodeParsing()) dataLog(" parsing ", currentCodeOrigin(), ": ", opcodeID, "\n"); if (m_graph.compilation()) { addToGraph(CountExecution, OpInfo(m_graph.compilation()->executionCounterFor( Profiler::OriginStack(*m_vm->m_perBytecodeProfiler, m_codeBlock, currentCodeOrigin())))); } switch (opcodeID) { // === Function entry opcodes === case op_enter: { Node* undefined = addToGraph(JSConstant, OpInfo(m_constantUndefined)); // Initialize all locals to undefined. for (int i = 0; i < m_inlineStackTop->m_codeBlock->m_numVars; ++i) set(virtualRegisterForLocal(i), undefined, ImmediateNakedSet); NEXT_OPCODE(op_enter); } case op_to_this: { Node* op1 = getThis(); if (op1->op() != ToThis) { Structure* cachedStructure = currentInstruction[2].u.structure.get(); if (currentInstruction[2].u.toThisStatus != ToThisOK || !cachedStructure || cachedStructure->classInfo()->methodTable.toThis != JSObject::info()->methodTable.toThis || m_inlineStackTop->m_profiledBlock->couldTakeSlowCase(m_currentIndex) || m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadCache) || (op1->op() == GetLocal && op1->variableAccessData()->structureCheckHoistingFailed())) { setThis(addToGraph(ToThis, op1)); } else { addToGraph( CheckStructure, OpInfo(m_graph.addStructureSet(cachedStructure)), op1); } } NEXT_OPCODE(op_to_this); } case op_create_this: { int calleeOperand = currentInstruction[2].u.operand; Node* callee = get(VirtualRegister(calleeOperand)); JSFunction* function = callee->dynamicCastConstant(); if (!function) { JSCell* cachedFunction = currentInstruction[4].u.jsCell.unvalidatedGet(); if (cachedFunction && cachedFunction != JSCell::seenMultipleCalleeObjects() && !m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadCell)) { ASSERT(cachedFunction->inherits(JSFunction::info())); FrozenValue* frozen = m_graph.freeze(cachedFunction); addToGraph(CheckCell, OpInfo(frozen), callee); function = static_cast(cachedFunction); } } bool alreadyEmitted = false; if (function) { if (FunctionRareData* rareData = function->rareData()) { if (Structure* structure = rareData->objectAllocationStructure()) { m_graph.freeze(rareData); m_graph.watchpoints().addLazily(rareData->allocationProfileWatchpointSet()); // The callee is still live up to this point. addToGraph(Phantom, callee); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(NewObject, OpInfo(structure))); alreadyEmitted = true; } } } if (!alreadyEmitted) { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CreateThis, OpInfo(currentInstruction[3].u.operand), callee)); } NEXT_OPCODE(op_create_this); } case op_new_object: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(NewObject, OpInfo(currentInstruction[3].u.objectAllocationProfile->structure()))); NEXT_OPCODE(op_new_object); } case op_new_array: { int startOperand = currentInstruction[2].u.operand; int numOperands = currentInstruction[3].u.operand; ArrayAllocationProfile* profile = currentInstruction[4].u.arrayAllocationProfile; for (int operandIdx = startOperand; operandIdx > startOperand - numOperands; --operandIdx) addVarArgChild(get(VirtualRegister(operandIdx))); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(Node::VarArg, NewArray, OpInfo(profile->selectIndexingType()), OpInfo(0))); NEXT_OPCODE(op_new_array); } case op_new_array_with_size: { int lengthOperand = currentInstruction[2].u.operand; ArrayAllocationProfile* profile = currentInstruction[3].u.arrayAllocationProfile; set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(NewArrayWithSize, OpInfo(profile->selectIndexingType()), get(VirtualRegister(lengthOperand)))); NEXT_OPCODE(op_new_array_with_size); } case op_new_array_buffer: { int startConstant = currentInstruction[2].u.operand; int numConstants = currentInstruction[3].u.operand; ArrayAllocationProfile* profile = currentInstruction[4].u.arrayAllocationProfile; NewArrayBufferData data; data.startConstant = m_inlineStackTop->m_constantBufferRemap[startConstant]; data.numConstants = numConstants; data.indexingType = profile->selectIndexingType(); // If this statement has never executed, we'll have the wrong indexing type in the profile. for (int i = 0; i < numConstants; ++i) { data.indexingType = leastUpperBoundOfIndexingTypeAndValue( data.indexingType, m_codeBlock->constantBuffer(data.startConstant)[i]); } m_graph.m_newArrayBufferData.append(data); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(NewArrayBuffer, OpInfo(&m_graph.m_newArrayBufferData.last()))); NEXT_OPCODE(op_new_array_buffer); } case op_new_regexp: { // FIXME: We really should be able to inline code that uses NewRegexp. That means // using something other than the index into the CodeBlock here. // https://bugs.webkit.org/show_bug.cgi?id=154808 set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(NewRegexp, OpInfo(currentInstruction[2].u.operand))); NEXT_OPCODE(op_new_regexp); } case op_get_rest_length: { InlineCallFrame* inlineCallFrame = this->inlineCallFrame(); Node* length; if (inlineCallFrame && !inlineCallFrame->isVarargs()) { unsigned argumentsLength = inlineCallFrame->arguments.size() - 1; unsigned numParamsToSkip = currentInstruction[2].u.unsignedValue; JSValue restLength; if (argumentsLength <= numParamsToSkip) restLength = jsNumber(0); else restLength = jsNumber(argumentsLength - numParamsToSkip); length = jsConstant(restLength); } else length = addToGraph(GetRestLength, OpInfo(currentInstruction[2].u.unsignedValue)); set(VirtualRegister(currentInstruction[1].u.operand), length); NEXT_OPCODE(op_get_rest_length); } case op_copy_rest: { noticeArgumentsUse(); Node* array = get(VirtualRegister(currentInstruction[1].u.operand)); Node* arrayLength = get(VirtualRegister(currentInstruction[2].u.operand)); addToGraph(CopyRest, OpInfo(currentInstruction[3].u.unsignedValue), array, arrayLength); NEXT_OPCODE(op_copy_rest); } // === Bitwise operations === case op_bitand: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(BitAnd, op1, op2)); NEXT_OPCODE(op_bitand); } case op_bitor: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(BitOr, op1, op2)); NEXT_OPCODE(op_bitor); } case op_bitxor: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(BitXor, op1, op2)); NEXT_OPCODE(op_bitxor); } case op_rshift: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(BitRShift, op1, op2)); NEXT_OPCODE(op_rshift); } case op_lshift: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(BitLShift, op1, op2)); NEXT_OPCODE(op_lshift); } case op_urshift: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(BitURShift, op1, op2)); NEXT_OPCODE(op_urshift); } case op_unsigned: { set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(UInt32ToNumber, get(VirtualRegister(currentInstruction[2].u.operand))))); NEXT_OPCODE(op_unsigned); } // === Increment/Decrement opcodes === case op_inc: { int srcDst = currentInstruction[1].u.operand; VirtualRegister srcDstVirtualRegister = VirtualRegister(srcDst); Node* op = get(srcDstVirtualRegister); set(srcDstVirtualRegister, makeSafe(addToGraph(ArithAdd, op, addToGraph(JSConstant, OpInfo(m_constantOne))))); NEXT_OPCODE(op_inc); } case op_dec: { int srcDst = currentInstruction[1].u.operand; VirtualRegister srcDstVirtualRegister = VirtualRegister(srcDst); Node* op = get(srcDstVirtualRegister); set(srcDstVirtualRegister, makeSafe(addToGraph(ArithSub, op, addToGraph(JSConstant, OpInfo(m_constantOne))))); NEXT_OPCODE(op_dec); } // === Arithmetic operations === case op_add: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); if (op1->hasNumberResult() && op2->hasNumberResult()) set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(ArithAdd, op1, op2))); else set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(ValueAdd, op1, op2))); NEXT_OPCODE(op_add); } case op_sub: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(ArithSub, op1, op2))); NEXT_OPCODE(op_sub); } case op_negate: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(ArithNegate, op1))); NEXT_OPCODE(op_negate); } case op_mul: { // Multiply requires that the inputs are not truncated, unfortunately. Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(ArithMul, op1, op2))); NEXT_OPCODE(op_mul); } case op_mod: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), makeSafe(addToGraph(ArithMod, op1, op2))); NEXT_OPCODE(op_mod); } case op_div: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), makeDivSafe(addToGraph(ArithDiv, op1, op2))); NEXT_OPCODE(op_div); } // === Misc operations === case op_debug: { // This is a nop in the DFG/FTL because when we set a breakpoint in the debugger, // we will jettison all optimized CodeBlocks that contains the breakpoint. addToGraph(Check); // We add a nop here so that basic block linking doesn't break. NEXT_OPCODE(op_debug); } case op_mov: { Node* op = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), op); NEXT_OPCODE(op_mov); } case op_check_tdz: { addToGraph(CheckNotEmpty, get(VirtualRegister(currentInstruction[1].u.operand))); NEXT_OPCODE(op_check_tdz); } case op_overrides_has_instance: { JSFunction* defaultHasInstanceSymbolFunction = m_inlineStackTop->m_codeBlock->globalObjectFor(currentCodeOrigin())->functionProtoHasInstanceSymbolFunction(); Node* constructor = get(VirtualRegister(currentInstruction[2].u.operand)); Node* hasInstanceValue = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(OverridesHasInstance, OpInfo(m_graph.freeze(defaultHasInstanceSymbolFunction)), constructor, hasInstanceValue)); NEXT_OPCODE(op_overrides_has_instance); } case op_instanceof: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); Node* prototype = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(InstanceOf, value, prototype)); NEXT_OPCODE(op_instanceof); } case op_instanceof_custom: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); Node* constructor = get(VirtualRegister(currentInstruction[3].u.operand)); Node* hasInstanceValue = get(VirtualRegister(currentInstruction[4].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(InstanceOfCustom, value, constructor, hasInstanceValue)); NEXT_OPCODE(op_instanceof_custom); } case op_is_empty: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsEmpty, value)); NEXT_OPCODE(op_is_empty); } case op_is_undefined: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsUndefined, value)); NEXT_OPCODE(op_is_undefined); } case op_is_boolean: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsBoolean, value)); NEXT_OPCODE(op_is_boolean); } case op_is_number: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsNumber, value)); NEXT_OPCODE(op_is_number); } case op_is_string: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsString, value)); NEXT_OPCODE(op_is_string); } case op_is_object: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsObject, value)); NEXT_OPCODE(op_is_object); } case op_is_object_or_null: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsObjectOrNull, value)); NEXT_OPCODE(op_is_object_or_null); } case op_is_function: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(IsFunction, value)); NEXT_OPCODE(op_is_function); } case op_not: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(LogicalNot, value)); NEXT_OPCODE(op_not); } case op_to_primitive: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(ToPrimitive, value)); NEXT_OPCODE(op_to_primitive); } case op_strcat: { int startOperand = currentInstruction[2].u.operand; int numOperands = currentInstruction[3].u.operand; #if CPU(X86) // X86 doesn't have enough registers to compile MakeRope with three arguments. The // StrCat we emit here may be turned into a MakeRope. Rather than try to be clever, // we just make StrCat dumber on this processor. const unsigned maxArguments = 2; #else const unsigned maxArguments = 3; #endif Node* operands[AdjacencyList::Size]; unsigned indexInOperands = 0; for (unsigned i = 0; i < AdjacencyList::Size; ++i) operands[i] = 0; for (int operandIdx = 0; operandIdx < numOperands; ++operandIdx) { if (indexInOperands == maxArguments) { operands[0] = addToGraph(StrCat, operands[0], operands[1], operands[2]); for (unsigned i = 1; i < AdjacencyList::Size; ++i) operands[i] = 0; indexInOperands = 1; } ASSERT(indexInOperands < AdjacencyList::Size); ASSERT(indexInOperands < maxArguments); operands[indexInOperands++] = get(VirtualRegister(startOperand - operandIdx)); } set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(StrCat, operands[0], operands[1], operands[2])); NEXT_OPCODE(op_strcat); } case op_less: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareLess, op1, op2)); NEXT_OPCODE(op_less); } case op_lesseq: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareLessEq, op1, op2)); NEXT_OPCODE(op_lesseq); } case op_greater: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareGreater, op1, op2)); NEXT_OPCODE(op_greater); } case op_greatereq: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareGreaterEq, op1, op2)); NEXT_OPCODE(op_greatereq); } case op_eq: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareEq, op1, op2)); NEXT_OPCODE(op_eq); } case op_eq_null: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); Node* nullConstant = addToGraph(JSConstant, OpInfo(m_constantNull)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareEq, value, nullConstant)); NEXT_OPCODE(op_eq_null); } case op_stricteq: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(CompareStrictEq, op1, op2)); NEXT_OPCODE(op_stricteq); } case op_neq: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(LogicalNot, addToGraph(CompareEq, op1, op2))); NEXT_OPCODE(op_neq); } case op_neq_null: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); Node* nullConstant = addToGraph(JSConstant, OpInfo(m_constantNull)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(LogicalNot, addToGraph(CompareEq, value, nullConstant))); NEXT_OPCODE(op_neq_null); } case op_nstricteq: { Node* op1 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[3].u.operand)); Node* invertedResult; invertedResult = addToGraph(CompareStrictEq, op1, op2); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(LogicalNot, invertedResult)); NEXT_OPCODE(op_nstricteq); } // === Property access operations === case op_get_by_val: { SpeculatedType prediction = getPredictionWithoutOSRExit(); Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); Node* property = get(VirtualRegister(currentInstruction[3].u.operand)); bool compiledAsGetById = false; GetByIdStatus getByIdStatus; unsigned identifierNumber = 0; { ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); ByValInfo* byValInfo = m_inlineStackTop->m_byValInfos.get(CodeOrigin(currentCodeOrigin().bytecodeIndex)); // FIXME: When the bytecode is not compiled in the baseline JIT, byValInfo becomes null. // At that time, there is no information. if (byValInfo && byValInfo->stubInfo && !byValInfo->tookSlowPath && !m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadIdent)) { compiledAsGetById = true; identifierNumber = m_graph.identifiers().ensure(byValInfo->cachedId.impl()); UniquedStringImpl* uid = m_graph.identifiers()[identifierNumber]; addToGraph(CheckIdent, OpInfo(uid), property); getByIdStatus = GetByIdStatus::computeForStubInfo( locker, m_inlineStackTop->m_profiledBlock, byValInfo->stubInfo, currentCodeOrigin(), uid); } } if (compiledAsGetById) handleGetById(currentInstruction[1].u.operand, prediction, base, identifierNumber, getByIdStatus, AccessType::Get); else { ArrayMode arrayMode = getArrayMode(currentInstruction[4].u.arrayProfile, Array::Read); Node* getByVal = addToGraph(GetByVal, OpInfo(arrayMode.asWord()), OpInfo(prediction), base, property); m_exitOK = false; // GetByVal must be treated as if it clobbers exit state, since FixupPhase may make it generic. set(VirtualRegister(currentInstruction[1].u.operand), getByVal); } NEXT_OPCODE(op_get_by_val); } case op_get_by_val_with_this: { Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); Node* thisValue = get(VirtualRegister(currentInstruction[3].u.operand)); Node* property = get(VirtualRegister(currentInstruction[4].u.operand)); Node* getByValWithThis = addToGraph(GetByValWithThis, base, thisValue, property); set(VirtualRegister(currentInstruction[1].u.operand), getByValWithThis); NEXT_OPCODE(op_get_by_val_with_this); } case op_put_by_val_direct: case op_put_by_val: { Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); Node* property = get(VirtualRegister(currentInstruction[2].u.operand)); Node* value = get(VirtualRegister(currentInstruction[3].u.operand)); bool isDirect = opcodeID == op_put_by_val_direct; bool compiledAsPutById = false; { ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); ByValInfo* byValInfo = m_inlineStackTop->m_byValInfos.get(CodeOrigin(currentCodeOrigin().bytecodeIndex)); // FIXME: When the bytecode is not compiled in the baseline JIT, byValInfo becomes null. // At that time, there is no information. if (byValInfo && byValInfo->stubInfo && !byValInfo->tookSlowPath && !m_inlineStackTop->m_exitProfile.hasExitSite(m_currentIndex, BadIdent)) { compiledAsPutById = true; unsigned identifierNumber = m_graph.identifiers().ensure(byValInfo->cachedId.impl()); UniquedStringImpl* uid = m_graph.identifiers()[identifierNumber]; addToGraph(CheckIdent, OpInfo(uid), property); PutByIdStatus putByIdStatus = PutByIdStatus::computeForStubInfo( locker, m_inlineStackTop->m_profiledBlock, byValInfo->stubInfo, currentCodeOrigin(), uid); handlePutById(base, identifierNumber, value, putByIdStatus, isDirect); } } if (!compiledAsPutById) { ArrayMode arrayMode = getArrayMode(currentInstruction[4].u.arrayProfile, Array::Write); addVarArgChild(base); addVarArgChild(property); addVarArgChild(value); addVarArgChild(0); // Leave room for property storage. addVarArgChild(0); // Leave room for length. addToGraph(Node::VarArg, isDirect ? PutByValDirect : PutByVal, OpInfo(arrayMode.asWord()), OpInfo(0)); } NEXT_OPCODE(op_put_by_val); } case op_put_by_val_with_this: { Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); Node* thisValue = get(VirtualRegister(currentInstruction[2].u.operand)); Node* property = get(VirtualRegister(currentInstruction[3].u.operand)); Node* value = get(VirtualRegister(currentInstruction[4].u.operand)); addVarArgChild(base); addVarArgChild(thisValue); addVarArgChild(property); addVarArgChild(value); addToGraph(Node::VarArg, PutByValWithThis, OpInfo(0), OpInfo(0)); NEXT_OPCODE(op_put_by_val_with_this); } case op_try_get_by_id: { Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[3].u.operand]; UniquedStringImpl* uid = m_graph.identifiers()[identifierNumber]; GetByIdStatus getByIdStatus = GetByIdStatus::computeFor( m_inlineStackTop->m_profiledBlock, m_dfgCodeBlock, m_inlineStackTop->m_stubInfos, m_dfgStubInfos, currentCodeOrigin(), uid); handleGetById(currentInstruction[1].u.operand, SpecHeapTop, base, identifierNumber, getByIdStatus, AccessType::GetPure); NEXT_OPCODE(op_try_get_by_id); } case op_get_by_id: case op_get_by_id_proto_load: case op_get_by_id_unset: case op_get_array_length: { SpeculatedType prediction = getPrediction(); Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[3].u.operand]; UniquedStringImpl* uid = m_graph.identifiers()[identifierNumber]; GetByIdStatus getByIdStatus = GetByIdStatus::computeFor( m_inlineStackTop->m_profiledBlock, m_dfgCodeBlock, m_inlineStackTop->m_stubInfos, m_dfgStubInfos, currentCodeOrigin(), uid); handleGetById( currentInstruction[1].u.operand, prediction, base, identifierNumber, getByIdStatus, AccessType::Get); NEXT_OPCODE(op_get_by_id); } case op_get_by_id_with_this: { Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); Node* thisValue = get(VirtualRegister(currentInstruction[3].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[4].u.operand]; set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(GetByIdWithThis, OpInfo(identifierNumber), base, thisValue)); NEXT_OPCODE(op_get_by_id_with_this); } case op_put_by_id: { Node* value = get(VirtualRegister(currentInstruction[3].u.operand)); Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[2].u.operand]; bool direct = currentInstruction[8].u.putByIdFlags & PutByIdIsDirect; PutByIdStatus putByIdStatus = PutByIdStatus::computeFor( m_inlineStackTop->m_profiledBlock, m_dfgCodeBlock, m_inlineStackTop->m_stubInfos, m_dfgStubInfos, currentCodeOrigin(), m_graph.identifiers()[identifierNumber]); handlePutById(base, identifierNumber, value, putByIdStatus, direct); NEXT_OPCODE(op_put_by_id); } case op_put_by_id_with_this: { Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); Node* thisValue = get(VirtualRegister(currentInstruction[2].u.operand)); Node* value = get(VirtualRegister(currentInstruction[4].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[3].u.operand]; addToGraph(PutByIdWithThis, OpInfo(identifierNumber), base, thisValue, value); NEXT_OPCODE(op_put_by_id_with_this); } case op_put_getter_by_id: case op_put_setter_by_id: { Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[2].u.operand]; unsigned attributes = currentInstruction[3].u.operand; Node* accessor = get(VirtualRegister(currentInstruction[4].u.operand)); NodeType op = (opcodeID == op_put_getter_by_id) ? PutGetterById : PutSetterById; addToGraph(op, OpInfo(identifierNumber), OpInfo(attributes), base, accessor); NEXT_OPCODE(op_put_getter_by_id); } case op_put_getter_setter_by_id: { Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[2].u.operand]; unsigned attributes = currentInstruction[3].u.operand; Node* getter = get(VirtualRegister(currentInstruction[4].u.operand)); Node* setter = get(VirtualRegister(currentInstruction[5].u.operand)); addToGraph(PutGetterSetterById, OpInfo(identifierNumber), OpInfo(attributes), base, getter, setter); NEXT_OPCODE(op_put_getter_setter_by_id); } case op_put_getter_by_val: case op_put_setter_by_val: { Node* base = get(VirtualRegister(currentInstruction[1].u.operand)); Node* subscript = get(VirtualRegister(currentInstruction[2].u.operand)); unsigned attributes = currentInstruction[3].u.operand; Node* accessor = get(VirtualRegister(currentInstruction[4].u.operand)); NodeType op = (opcodeID == op_put_getter_by_val) ? PutGetterByVal : PutSetterByVal; addToGraph(op, OpInfo(attributes), base, subscript, accessor); NEXT_OPCODE(op_put_getter_by_val); } case op_del_by_id: { Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[3].u.operand]; set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(DeleteById, OpInfo(identifierNumber), base)); NEXT_OPCODE(op_del_by_id); } case op_del_by_val: { int dst = currentInstruction[1].u.operand; Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); Node* key = get(VirtualRegister(currentInstruction[3].u.operand)); set(VirtualRegister(dst), addToGraph(DeleteByVal, base, key)); NEXT_OPCODE(op_del_by_val); } case op_profile_type: { Node* valueToProfile = get(VirtualRegister(currentInstruction[1].u.operand)); addToGraph(ProfileType, OpInfo(currentInstruction[2].u.location), valueToProfile); NEXT_OPCODE(op_profile_type); } case op_profile_control_flow: { BasicBlockLocation* basicBlockLocation = currentInstruction[1].u.basicBlockLocation; addToGraph(ProfileControlFlow, OpInfo(basicBlockLocation)); NEXT_OPCODE(op_profile_control_flow); } // === Block terminators. === case op_jmp: { ASSERT(!m_currentBlock->terminal()); int relativeOffset = currentInstruction[1].u.operand; addToGraph(Jump, OpInfo(m_currentIndex + relativeOffset)); if (relativeOffset <= 0) flushForTerminal(); LAST_OPCODE(op_jmp); } case op_jtrue: { unsigned relativeOffset = currentInstruction[2].u.operand; Node* condition = get(VirtualRegister(currentInstruction[1].u.operand)); addToGraph(Branch, OpInfo(branchData(m_currentIndex + relativeOffset, m_currentIndex + OPCODE_LENGTH(op_jtrue))), condition); LAST_OPCODE(op_jtrue); } case op_jfalse: { unsigned relativeOffset = currentInstruction[2].u.operand; Node* condition = get(VirtualRegister(currentInstruction[1].u.operand)); addToGraph(Branch, OpInfo(branchData(m_currentIndex + OPCODE_LENGTH(op_jfalse), m_currentIndex + relativeOffset)), condition); LAST_OPCODE(op_jfalse); } case op_jeq_null: { unsigned relativeOffset = currentInstruction[2].u.operand; Node* value = get(VirtualRegister(currentInstruction[1].u.operand)); Node* nullConstant = addToGraph(JSConstant, OpInfo(m_constantNull)); Node* condition = addToGraph(CompareEq, value, nullConstant); addToGraph(Branch, OpInfo(branchData(m_currentIndex + relativeOffset, m_currentIndex + OPCODE_LENGTH(op_jeq_null))), condition); LAST_OPCODE(op_jeq_null); } case op_jneq_null: { unsigned relativeOffset = currentInstruction[2].u.operand; Node* value = get(VirtualRegister(currentInstruction[1].u.operand)); Node* nullConstant = addToGraph(JSConstant, OpInfo(m_constantNull)); Node* condition = addToGraph(CompareEq, value, nullConstant); addToGraph(Branch, OpInfo(branchData(m_currentIndex + OPCODE_LENGTH(op_jneq_null), m_currentIndex + relativeOffset)), condition); LAST_OPCODE(op_jneq_null); } case op_jless: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareLess, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + relativeOffset, m_currentIndex + OPCODE_LENGTH(op_jless))), condition); LAST_OPCODE(op_jless); } case op_jlesseq: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareLessEq, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + relativeOffset, m_currentIndex + OPCODE_LENGTH(op_jlesseq))), condition); LAST_OPCODE(op_jlesseq); } case op_jgreater: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareGreater, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + relativeOffset, m_currentIndex + OPCODE_LENGTH(op_jgreater))), condition); LAST_OPCODE(op_jgreater); } case op_jgreatereq: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareGreaterEq, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + relativeOffset, m_currentIndex + OPCODE_LENGTH(op_jgreatereq))), condition); LAST_OPCODE(op_jgreatereq); } case op_jnless: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareLess, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + OPCODE_LENGTH(op_jnless), m_currentIndex + relativeOffset)), condition); LAST_OPCODE(op_jnless); } case op_jnlesseq: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareLessEq, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + OPCODE_LENGTH(op_jnlesseq), m_currentIndex + relativeOffset)), condition); LAST_OPCODE(op_jnlesseq); } case op_jngreater: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareGreater, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + OPCODE_LENGTH(op_jngreater), m_currentIndex + relativeOffset)), condition); LAST_OPCODE(op_jngreater); } case op_jngreatereq: { unsigned relativeOffset = currentInstruction[3].u.operand; Node* op1 = get(VirtualRegister(currentInstruction[1].u.operand)); Node* op2 = get(VirtualRegister(currentInstruction[2].u.operand)); Node* condition = addToGraph(CompareGreaterEq, op1, op2); addToGraph(Branch, OpInfo(branchData(m_currentIndex + OPCODE_LENGTH(op_jngreatereq), m_currentIndex + relativeOffset)), condition); LAST_OPCODE(op_jngreatereq); } case op_switch_imm: { SwitchData& data = *m_graph.m_switchData.add(); data.kind = SwitchImm; data.switchTableIndex = m_inlineStackTop->m_switchRemap[currentInstruction[1].u.operand]; data.fallThrough.setBytecodeIndex(m_currentIndex + currentInstruction[2].u.operand); SimpleJumpTable& table = m_codeBlock->switchJumpTable(data.switchTableIndex); for (unsigned i = 0; i < table.branchOffsets.size(); ++i) { if (!table.branchOffsets[i]) continue; unsigned target = m_currentIndex + table.branchOffsets[i]; if (target == data.fallThrough.bytecodeIndex()) continue; data.cases.append(SwitchCase::withBytecodeIndex(m_graph.freeze(jsNumber(static_cast(table.min + i))), target)); } addToGraph(Switch, OpInfo(&data), get(VirtualRegister(currentInstruction[3].u.operand))); flushIfTerminal(data); LAST_OPCODE(op_switch_imm); } case op_switch_char: { SwitchData& data = *m_graph.m_switchData.add(); data.kind = SwitchChar; data.switchTableIndex = m_inlineStackTop->m_switchRemap[currentInstruction[1].u.operand]; data.fallThrough.setBytecodeIndex(m_currentIndex + currentInstruction[2].u.operand); SimpleJumpTable& table = m_codeBlock->switchJumpTable(data.switchTableIndex); for (unsigned i = 0; i < table.branchOffsets.size(); ++i) { if (!table.branchOffsets[i]) continue; unsigned target = m_currentIndex + table.branchOffsets[i]; if (target == data.fallThrough.bytecodeIndex()) continue; data.cases.append( SwitchCase::withBytecodeIndex(LazyJSValue::singleCharacterString(table.min + i), target)); } addToGraph(Switch, OpInfo(&data), get(VirtualRegister(currentInstruction[3].u.operand))); flushIfTerminal(data); LAST_OPCODE(op_switch_char); } case op_switch_string: { SwitchData& data = *m_graph.m_switchData.add(); data.kind = SwitchString; data.switchTableIndex = currentInstruction[1].u.operand; data.fallThrough.setBytecodeIndex(m_currentIndex + currentInstruction[2].u.operand); StringJumpTable& table = m_codeBlock->stringSwitchJumpTable(data.switchTableIndex); StringJumpTable::StringOffsetTable::iterator iter; StringJumpTable::StringOffsetTable::iterator end = table.offsetTable.end(); for (iter = table.offsetTable.begin(); iter != end; ++iter) { unsigned target = m_currentIndex + iter->value.branchOffset; if (target == data.fallThrough.bytecodeIndex()) continue; data.cases.append( SwitchCase::withBytecodeIndex(LazyJSValue::knownStringImpl(iter->key.get()), target)); } addToGraph(Switch, OpInfo(&data), get(VirtualRegister(currentInstruction[3].u.operand))); flushIfTerminal(data); LAST_OPCODE(op_switch_string); } case op_ret: ASSERT(!m_currentBlock->terminal()); if (inlineCallFrame()) { flushForReturn(); if (m_inlineStackTop->m_returnValue.isValid()) setDirect(m_inlineStackTop->m_returnValue, get(VirtualRegister(currentInstruction[1].u.operand)), ImmediateSetWithFlush); m_inlineStackTop->m_didReturn = true; if (m_inlineStackTop->m_unlinkedBlocks.isEmpty()) { // If we're returning from the first block, then we're done parsing. ASSERT(m_inlineStackTop->m_callsiteBlockHead == m_graph.lastBlock()); shouldContinueParsing = false; LAST_OPCODE(op_ret); } else { // If inlining created blocks, and we're doing a return, then we need some // special linking. ASSERT(m_inlineStackTop->m_unlinkedBlocks.last().m_block == m_graph.lastBlock()); m_inlineStackTop->m_unlinkedBlocks.last().m_needsNormalLinking = false; } if (m_currentIndex + OPCODE_LENGTH(op_ret) != m_inlineStackTop->m_codeBlock->instructions().size() || m_inlineStackTop->m_didEarlyReturn) { ASSERT(m_currentIndex + OPCODE_LENGTH(op_ret) <= m_inlineStackTop->m_codeBlock->instructions().size()); addToGraph(Jump, OpInfo(0)); m_inlineStackTop->m_unlinkedBlocks.last().m_needsEarlyReturnLinking = true; m_inlineStackTop->m_didEarlyReturn = true; } LAST_OPCODE(op_ret); } addToGraph(Return, get(VirtualRegister(currentInstruction[1].u.operand))); flushForReturn(); LAST_OPCODE(op_ret); case op_end: ASSERT(!inlineCallFrame()); addToGraph(Return, get(VirtualRegister(currentInstruction[1].u.operand))); flushForReturn(); LAST_OPCODE(op_end); case op_throw: addToGraph(Throw, get(VirtualRegister(currentInstruction[1].u.operand))); flushForTerminal(); addToGraph(Unreachable); LAST_OPCODE(op_throw); case op_throw_static_error: addToGraph(ThrowReferenceError); flushForTerminal(); addToGraph(Unreachable); LAST_OPCODE(op_throw_static_error); case op_catch: m_graph.m_hasExceptionHandlers = true; NEXT_OPCODE(op_catch); case op_call: handleCall(currentInstruction, Call, CallMode::Regular); // Verify that handleCall(), which could have inlined the callee, didn't trash m_currentInstruction. ASSERT(m_currentInstruction == currentInstruction); NEXT_OPCODE(op_call); case op_tail_call: { flushForReturn(); Terminality terminality = handleCall(currentInstruction, TailCall, CallMode::Tail); // Verify that handleCall(), which could have inlined the callee, didn't trash m_currentInstruction. ASSERT(m_currentInstruction == currentInstruction); // If the call is terminal then we should not parse any further bytecodes as the TailCall will exit the function. // If the call is not terminal, however, then we want the subsequent op_ret/op_jumpt to update metadata and clean // things up. if (terminality == NonTerminal) { NEXT_OPCODE(op_tail_call); } else { LAST_OPCODE(op_tail_call); } } case op_construct: handleCall(currentInstruction, Construct, CallMode::Construct); NEXT_OPCODE(op_construct); case op_call_varargs: { handleVarargsCall(currentInstruction, CallVarargs, CallMode::Regular); NEXT_OPCODE(op_call_varargs); } case op_tail_call_varargs: { flushForReturn(); Terminality terminality = handleVarargsCall(currentInstruction, TailCallVarargs, CallMode::Tail); // If the call is terminal then we should not parse any further bytecodes as the TailCall will exit the function. // If the call is not terminal, however, then we want the subsequent op_ret/op_jumpt to update metadata and clean // things up. if (terminality == NonTerminal) { NEXT_OPCODE(op_tail_call_varargs); } else { LAST_OPCODE(op_tail_call_varargs); } } case op_construct_varargs: { handleVarargsCall(currentInstruction, ConstructVarargs, CallMode::Construct); NEXT_OPCODE(op_construct_varargs); } case op_jneq_ptr: // Statically speculate for now. It makes sense to let speculate-only jneq_ptr // support simmer for a while before making it more general, since it's // already gnarly enough as it is. ASSERT(pointerIsFunction(currentInstruction[2].u.specialPointer)); addToGraph( CheckCell, OpInfo(m_graph.freeze(static_cast(actualPointerFor( m_inlineStackTop->m_codeBlock, currentInstruction[2].u.specialPointer)))), get(VirtualRegister(currentInstruction[1].u.operand))); NEXT_OPCODE(op_jneq_ptr); case op_resolve_scope: { int dst = currentInstruction[1].u.operand; ResolveType resolveType = static_cast(currentInstruction[4].u.operand); unsigned depth = currentInstruction[5].u.operand; int scope = currentInstruction[2].u.operand; if (needsDynamicLookup(resolveType, op_resolve_scope)) { unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[3].u.operand]; set(VirtualRegister(dst), addToGraph(ResolveScope, OpInfo(identifierNumber), get(VirtualRegister(scope)))); NEXT_OPCODE(op_resolve_scope); } // get_from_scope and put_to_scope depend on this watchpoint forcing OSR exit, so they don't add their own watchpoints. if (needsVarInjectionChecks(resolveType)) addToGraph(VarInjectionWatchpoint); switch (resolveType) { case GlobalProperty: case GlobalVar: case GlobalPropertyWithVarInjectionChecks: case GlobalVarWithVarInjectionChecks: case GlobalLexicalVar: case GlobalLexicalVarWithVarInjectionChecks: { JSScope* constantScope = JSScope::constantScopeForCodeBlock(resolveType, m_inlineStackTop->m_codeBlock); RELEASE_ASSERT(constantScope); RELEASE_ASSERT(static_cast(currentInstruction[6].u.pointer) == constantScope); set(VirtualRegister(dst), weakJSConstant(constantScope)); addToGraph(Phantom, get(VirtualRegister(scope))); break; } case ModuleVar: { // Since the value of the "scope" virtual register is not used in LLInt / baseline op_resolve_scope with ModuleVar, // we need not to keep it alive by the Phantom node. JSModuleEnvironment* moduleEnvironment = jsCast(currentInstruction[6].u.jsCell.get()); // Module environment is already strongly referenced by the CodeBlock. set(VirtualRegister(dst), weakJSConstant(moduleEnvironment)); break; } case LocalClosureVar: case ClosureVar: case ClosureVarWithVarInjectionChecks: { Node* localBase = get(VirtualRegister(scope)); addToGraph(Phantom, localBase); // OSR exit cannot handle resolve_scope on a DCE'd scope. // We have various forms of constant folding here. This is necessary to avoid // spurious recompiles in dead-but-foldable code. if (SymbolTable* symbolTable = currentInstruction[6].u.symbolTable.get()) { InferredValue* singleton = symbolTable->singletonScope(); if (JSValue value = singleton->inferredValue()) { m_graph.watchpoints().addLazily(singleton); set(VirtualRegister(dst), weakJSConstant(value)); break; } } if (JSScope* scope = localBase->dynamicCastConstant()) { for (unsigned n = depth; n--;) scope = scope->next(); set(VirtualRegister(dst), weakJSConstant(scope)); break; } for (unsigned n = depth; n--;) localBase = addToGraph(SkipScope, localBase); set(VirtualRegister(dst), localBase); break; } case UnresolvedProperty: case UnresolvedPropertyWithVarInjectionChecks: { addToGraph(Phantom, get(VirtualRegister(scope))); addToGraph(ForceOSRExit); set(VirtualRegister(dst), addToGraph(JSConstant, OpInfo(m_constantNull))); break; } case Dynamic: RELEASE_ASSERT_NOT_REACHED(); break; } NEXT_OPCODE(op_resolve_scope); } case op_get_from_scope: { int dst = currentInstruction[1].u.operand; int scope = currentInstruction[2].u.operand; unsigned identifierNumber = m_inlineStackTop->m_identifierRemap[currentInstruction[3].u.operand]; UniquedStringImpl* uid = m_graph.identifiers()[identifierNumber]; ResolveType resolveType = GetPutInfo(currentInstruction[4].u.operand).resolveType(); Structure* structure = 0; WatchpointSet* watchpoints = 0; uintptr_t operand; { ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); if (resolveType == GlobalVar || resolveType == GlobalVarWithVarInjectionChecks || resolveType == GlobalLexicalVar || resolveType == GlobalLexicalVarWithVarInjectionChecks) watchpoints = currentInstruction[5].u.watchpointSet; else if (resolveType != UnresolvedProperty && resolveType != UnresolvedPropertyWithVarInjectionChecks) structure = currentInstruction[5].u.structure.get(); operand = reinterpret_cast(currentInstruction[6].u.pointer); } if (needsDynamicLookup(resolveType, op_get_from_scope)) { set(VirtualRegister(dst), addToGraph(GetDynamicVar, OpInfo(identifierNumber), OpInfo(currentInstruction[4].u.operand), get(VirtualRegister(scope)))); NEXT_OPCODE(op_get_from_scope); } UNUSED_PARAM(watchpoints); // We will use this in the future. For now we set it as a way of documenting the fact that that's what index 5 is in GlobalVar mode. JSGlobalObject* globalObject = m_inlineStackTop->m_codeBlock->globalObject(); switch (resolveType) { case GlobalProperty: case GlobalPropertyWithVarInjectionChecks: { SpeculatedType prediction = getPrediction(); GetByIdStatus status = GetByIdStatus::computeFor(structure, uid); if (status.state() != GetByIdStatus::Simple || status.numVariants() != 1 || status[0].structureSet().size() != 1) { set(VirtualRegister(dst), addToGraph(GetByIdFlush, OpInfo(identifierNumber), OpInfo(prediction), get(VirtualRegister(scope)))); break; } Node* base = weakJSConstant(globalObject); Node* result = load(prediction, base, identifierNumber, status[0]); addToGraph(Phantom, get(VirtualRegister(scope))); set(VirtualRegister(dst), result); break; } case GlobalVar: case GlobalVarWithVarInjectionChecks: case GlobalLexicalVar: case GlobalLexicalVarWithVarInjectionChecks: { addToGraph(Phantom, get(VirtualRegister(scope))); WatchpointSet* watchpointSet; ScopeOffset offset; JSSegmentedVariableObject* scopeObject = jsCast(JSScope::constantScopeForCodeBlock(resolveType, m_inlineStackTop->m_codeBlock)); { ConcurrentJITLocker locker(scopeObject->symbolTable()->m_lock); SymbolTableEntry entry = scopeObject->symbolTable()->get(locker, uid); watchpointSet = entry.watchpointSet(); offset = entry.scopeOffset(); } if (watchpointSet && watchpointSet->state() == IsWatched) { // This has a fun concurrency story. There is the possibility of a race in two // directions: // // We see that the set IsWatched, but in the meantime it gets invalidated: this is // fine because if we saw that it IsWatched then we add a watchpoint. If it gets // invalidated, then this compilation is invalidated. Note that in the meantime we // may load an absurd value from the global object. It's fine to load an absurd // value if the compilation is invalidated anyway. // // We see that the set IsWatched, but the value isn't yet initialized: this isn't // possible because of the ordering of operations. // // Here's how we order operations: // // Main thread stores to the global object: always store a value first, and only // after that do we touch the watchpoint set. There is a fence in the touch, that // ensures that the store to the global object always happens before the touch on the // set. // // Compilation thread: always first load the state of the watchpoint set, and then // load the value. The WatchpointSet::state() method does fences for us to ensure // that the load of the state happens before our load of the value. // // Finalizing compilation: this happens on the main thread and synchronously checks // validity of all watchpoint sets. // // We will only perform optimizations if the load of the state yields IsWatched. That // means that at least one store would have happened to initialize the original value // of the variable (that is, the value we'd like to constant fold to). There may be // other stores that happen after that, but those stores will invalidate the // watchpoint set and also the compilation. // Note that we need to use the operand, which is a direct pointer at the global, // rather than looking up the global by doing variableAt(offset). That's because the // internal data structures of JSSegmentedVariableObject are not thread-safe even // though accessing the global itself is. The segmentation involves a vector spine // that resizes with malloc/free, so if new globals unrelated to the one we are // reading are added, we might access freed memory if we do variableAt(). WriteBarrier* pointer = bitwise_cast*>(operand); ASSERT(scopeObject->findVariableIndex(pointer) == offset); JSValue value = pointer->get(); if (value) { m_graph.watchpoints().addLazily(watchpointSet); set(VirtualRegister(dst), weakJSConstant(value)); break; } } SpeculatedType prediction = getPrediction(); NodeType nodeType; if (resolveType == GlobalVar || resolveType == GlobalVarWithVarInjectionChecks) nodeType = GetGlobalVar; else nodeType = GetGlobalLexicalVariable; Node* value = addToGraph(nodeType, OpInfo(operand), OpInfo(prediction)); if (resolveType == GlobalLexicalVar || resolveType == GlobalLexicalVarWithVarInjectionChecks) addToGraph(CheckNotEmpty, value); set(VirtualRegister(dst), value); break; } case LocalClosureVar: case ClosureVar: case ClosureVarWithVarInjectionChecks: { Node* scopeNode = get(VirtualRegister(scope)); // Ideally we wouldn't have to do this Phantom. But: // // For the constant case: we must do it because otherwise we would have no way of knowing // that the scope is live at OSR here. // // For the non-constant case: GetClosureVar could be DCE'd, but baseline's implementation // won't be able to handle an Undefined scope. addToGraph(Phantom, scopeNode); // Constant folding in the bytecode parser is important for performance. This may not // have executed yet. If it hasn't, then we won't have a prediction. Lacking a // prediction, we'd otherwise think that it has to exit. Then when it did execute, we // would recompile. But if we can fold it here, we avoid the exit. if (JSValue value = m_graph.tryGetConstantClosureVar(scopeNode, ScopeOffset(operand))) { set(VirtualRegister(dst), weakJSConstant(value)); break; } SpeculatedType prediction = getPrediction(); set(VirtualRegister(dst), addToGraph(GetClosureVar, OpInfo(operand), OpInfo(prediction), scopeNode)); break; } case UnresolvedProperty: case UnresolvedPropertyWithVarInjectionChecks: case ModuleVar: case Dynamic: RELEASE_ASSERT_NOT_REACHED(); break; } NEXT_OPCODE(op_get_from_scope); } case op_put_to_scope: { unsigned scope = currentInstruction[1].u.operand; unsigned identifierNumber = currentInstruction[2].u.operand; if (identifierNumber != UINT_MAX) identifierNumber = m_inlineStackTop->m_identifierRemap[identifierNumber]; unsigned value = currentInstruction[3].u.operand; GetPutInfo getPutInfo = GetPutInfo(currentInstruction[4].u.operand); ResolveType resolveType = getPutInfo.resolveType(); UniquedStringImpl* uid; if (identifierNumber != UINT_MAX) uid = m_graph.identifiers()[identifierNumber]; else uid = nullptr; Structure* structure = nullptr; WatchpointSet* watchpoints = nullptr; uintptr_t operand; { ConcurrentJITLocker locker(m_inlineStackTop->m_profiledBlock->m_lock); if (resolveType == GlobalVar || resolveType == GlobalVarWithVarInjectionChecks || resolveType == LocalClosureVar || resolveType == GlobalLexicalVar || resolveType == GlobalLexicalVarWithVarInjectionChecks) watchpoints = currentInstruction[5].u.watchpointSet; else if (resolveType != UnresolvedProperty && resolveType != UnresolvedPropertyWithVarInjectionChecks) structure = currentInstruction[5].u.structure.get(); operand = reinterpret_cast(currentInstruction[6].u.pointer); } JSGlobalObject* globalObject = m_inlineStackTop->m_codeBlock->globalObject(); if (needsDynamicLookup(resolveType, op_put_to_scope)) { ASSERT(identifierNumber != UINT_MAX); addToGraph(PutDynamicVar, OpInfo(identifierNumber), OpInfo(currentInstruction[4].u.operand), get(VirtualRegister(scope)), get(VirtualRegister(value))); NEXT_OPCODE(op_put_to_scope); } switch (resolveType) { case GlobalProperty: case GlobalPropertyWithVarInjectionChecks: { PutByIdStatus status; if (uid) status = PutByIdStatus::computeFor(globalObject, structure, uid, false); else status = PutByIdStatus(PutByIdStatus::TakesSlowPath); if (status.numVariants() != 1 || status[0].kind() != PutByIdVariant::Replace || status[0].structure().size() != 1) { addToGraph(PutById, OpInfo(identifierNumber), get(VirtualRegister(scope)), get(VirtualRegister(value))); break; } Node* base = weakJSConstant(globalObject); store(base, identifierNumber, status[0], get(VirtualRegister(value))); // Keep scope alive until after put. addToGraph(Phantom, get(VirtualRegister(scope))); break; } case GlobalLexicalVar: case GlobalLexicalVarWithVarInjectionChecks: case GlobalVar: case GlobalVarWithVarInjectionChecks: { if (!isInitialization(getPutInfo.initializationMode()) && (resolveType == GlobalLexicalVar || resolveType == GlobalLexicalVarWithVarInjectionChecks)) { SpeculatedType prediction = SpecEmpty; Node* value = addToGraph(GetGlobalLexicalVariable, OpInfo(operand), OpInfo(prediction)); addToGraph(CheckNotEmpty, value); } JSSegmentedVariableObject* scopeObject = jsCast(JSScope::constantScopeForCodeBlock(resolveType, m_inlineStackTop->m_codeBlock)); if (watchpoints) { SymbolTableEntry entry = scopeObject->symbolTable()->get(uid); ASSERT_UNUSED(entry, watchpoints == entry.watchpointSet()); } Node* valueNode = get(VirtualRegister(value)); addToGraph(PutGlobalVariable, OpInfo(operand), weakJSConstant(scopeObject), valueNode); if (watchpoints && watchpoints->state() != IsInvalidated) { // Must happen after the store. See comment for GetGlobalVar. addToGraph(NotifyWrite, OpInfo(watchpoints)); } // Keep scope alive until after put. addToGraph(Phantom, get(VirtualRegister(scope))); break; } case LocalClosureVar: case ClosureVar: case ClosureVarWithVarInjectionChecks: { Node* scopeNode = get(VirtualRegister(scope)); Node* valueNode = get(VirtualRegister(value)); addToGraph(PutClosureVar, OpInfo(operand), scopeNode, valueNode); if (watchpoints && watchpoints->state() != IsInvalidated) { // Must happen after the store. See comment for GetGlobalVar. addToGraph(NotifyWrite, OpInfo(watchpoints)); } break; } case ModuleVar: // Need not to keep "scope" and "value" register values here by Phantom because // they are not used in LLInt / baseline op_put_to_scope with ModuleVar. addToGraph(ForceOSRExit); break; case Dynamic: case UnresolvedProperty: case UnresolvedPropertyWithVarInjectionChecks: RELEASE_ASSERT_NOT_REACHED(); break; } NEXT_OPCODE(op_put_to_scope); } case op_loop_hint: { // Baseline->DFG OSR jumps between loop hints. The DFG assumes that Baseline->DFG // OSR can only happen at basic block boundaries. Assert that these two statements // are compatible. RELEASE_ASSERT(m_currentIndex == blockBegin); // We never do OSR into an inlined code block. That could not happen, since OSR // looks up the code block that is the replacement for the baseline JIT code // block. Hence, machine code block = true code block = not inline code block. if (!m_inlineStackTop->m_caller) m_currentBlock->isOSRTarget = true; addToGraph(LoopHint); NEXT_OPCODE(op_loop_hint); } case op_watchdog: { addToGraph(CheckWatchdogTimer); NEXT_OPCODE(op_watchdog); } case op_create_lexical_environment: { VirtualRegister symbolTableRegister(currentInstruction[3].u.operand); VirtualRegister initialValueRegister(currentInstruction[4].u.operand); ASSERT(symbolTableRegister.isConstant() && initialValueRegister.isConstant()); FrozenValue* symbolTable = m_graph.freezeStrong(m_inlineStackTop->m_codeBlock->getConstant(symbolTableRegister.offset())); FrozenValue* initialValue = m_graph.freezeStrong(m_inlineStackTop->m_codeBlock->getConstant(initialValueRegister.offset())); Node* scope = get(VirtualRegister(currentInstruction[2].u.operand)); Node* lexicalEnvironment = addToGraph(CreateActivation, OpInfo(symbolTable), OpInfo(initialValue), scope); set(VirtualRegister(currentInstruction[1].u.operand), lexicalEnvironment); NEXT_OPCODE(op_create_lexical_environment); } case op_get_parent_scope: { Node* currentScope = get(VirtualRegister(currentInstruction[2].u.operand)); Node* newScope = addToGraph(SkipScope, currentScope); set(VirtualRegister(currentInstruction[1].u.operand), newScope); addToGraph(Phantom, currentScope); NEXT_OPCODE(op_get_parent_scope); } case op_get_scope: { // Help the later stages a bit by doing some small constant folding here. Note that this // only helps for the first basic block. It's extremely important not to constant fold // loads from the scope register later, as that would prevent the DFG from tracking the // bytecode-level liveness of the scope register. Node* callee = get(VirtualRegister(JSStack::Callee)); Node* result; if (JSFunction* function = callee->dynamicCastConstant()) result = weakJSConstant(function->scope()); else result = addToGraph(GetScope, callee); set(VirtualRegister(currentInstruction[1].u.operand), result); NEXT_OPCODE(op_get_scope); } case op_argument_count: { Node* sub = addToGraph(ArithSub, OpInfo(Arith::Unchecked), OpInfo(SpecInt32Only), getArgumentCount(), addToGraph(JSConstant, OpInfo(m_constantOne))); set(VirtualRegister(currentInstruction[1].u.operand), sub); NEXT_OPCODE(op_argument_count); } case op_create_direct_arguments: { noticeArgumentsUse(); Node* createArguments = addToGraph(CreateDirectArguments); set(VirtualRegister(currentInstruction[1].u.operand), createArguments); NEXT_OPCODE(op_create_direct_arguments); } case op_create_scoped_arguments: { noticeArgumentsUse(); Node* createArguments = addToGraph(CreateScopedArguments, get(VirtualRegister(currentInstruction[2].u.operand))); set(VirtualRegister(currentInstruction[1].u.operand), createArguments); NEXT_OPCODE(op_create_scoped_arguments); } case op_create_cloned_arguments: { noticeArgumentsUse(); Node* createArguments = addToGraph(CreateClonedArguments); set(VirtualRegister(currentInstruction[1].u.operand), createArguments); NEXT_OPCODE(op_create_cloned_arguments); } case op_get_from_arguments: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph( GetFromArguments, OpInfo(currentInstruction[3].u.operand), OpInfo(getPrediction()), get(VirtualRegister(currentInstruction[2].u.operand)))); NEXT_OPCODE(op_get_from_arguments); } case op_put_to_arguments: { addToGraph( PutToArguments, OpInfo(currentInstruction[2].u.operand), get(VirtualRegister(currentInstruction[1].u.operand)), get(VirtualRegister(currentInstruction[3].u.operand))); NEXT_OPCODE(op_put_to_arguments); } case op_new_func: case op_new_generator_func: { FunctionExecutable* decl = m_inlineStackTop->m_profiledBlock->functionDecl(currentInstruction[3].u.operand); FrozenValue* frozen = m_graph.freezeStrong(decl); NodeType op = (opcodeID == op_new_generator_func) ? NewGeneratorFunction : NewFunction; set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(op, OpInfo(frozen), get(VirtualRegister(currentInstruction[2].u.operand)))); static_assert(OPCODE_LENGTH(op_new_func) == OPCODE_LENGTH(op_new_generator_func), "The length of op_new_func should eqaual to one of op_new_generator_func"); NEXT_OPCODE(op_new_func); } case op_new_func_exp: case op_new_generator_func_exp: { FunctionExecutable* expr = m_inlineStackTop->m_profiledBlock->functionExpr(currentInstruction[3].u.operand); FrozenValue* frozen = m_graph.freezeStrong(expr); NodeType op = (opcodeID == op_new_generator_func_exp) ? NewGeneratorFunction : NewFunction; set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(op, OpInfo(frozen), get(VirtualRegister(currentInstruction[2].u.operand)))); static_assert(OPCODE_LENGTH(op_new_func_exp) == OPCODE_LENGTH(op_new_generator_func_exp), "The length of op_new_func_exp should eqaual to one of op_new_generator_func_exp"); NEXT_OPCODE(op_new_func_exp); } case op_set_function_name: { Node* func = get(VirtualRegister(currentInstruction[1].u.operand)); Node* name = get(VirtualRegister(currentInstruction[2].u.operand)); addToGraph(SetFunctionName, func, name); NEXT_OPCODE(op_set_function_name); } case op_typeof: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(TypeOf, get(VirtualRegister(currentInstruction[2].u.operand)))); NEXT_OPCODE(op_typeof); } case op_to_number: { Node* node = get(VirtualRegister(currentInstruction[2].u.operand)); addToGraph(Phantom, Edge(node, NumberUse)); set(VirtualRegister(currentInstruction[1].u.operand), node); NEXT_OPCODE(op_to_number); } case op_to_string: { Node* value = get(VirtualRegister(currentInstruction[2].u.operand)); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(ToString, value)); NEXT_OPCODE(op_to_string); } case op_in: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(In, get(VirtualRegister(currentInstruction[2].u.operand)), get(VirtualRegister(currentInstruction[3].u.operand)))); NEXT_OPCODE(op_in); } case op_get_enumerable_length: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(GetEnumerableLength, get(VirtualRegister(currentInstruction[2].u.operand)))); NEXT_OPCODE(op_get_enumerable_length); } case op_has_generic_property: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(HasGenericProperty, get(VirtualRegister(currentInstruction[2].u.operand)), get(VirtualRegister(currentInstruction[3].u.operand)))); NEXT_OPCODE(op_has_generic_property); } case op_has_structure_property: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(HasStructureProperty, get(VirtualRegister(currentInstruction[2].u.operand)), get(VirtualRegister(currentInstruction[3].u.operand)), get(VirtualRegister(currentInstruction[4].u.operand)))); NEXT_OPCODE(op_has_structure_property); } case op_has_indexed_property: { Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); ArrayMode arrayMode = getArrayMode(currentInstruction[4].u.arrayProfile, Array::Read); Node* property = get(VirtualRegister(currentInstruction[3].u.operand)); Node* hasIterableProperty = addToGraph(HasIndexedProperty, OpInfo(arrayMode.asWord()), base, property); set(VirtualRegister(currentInstruction[1].u.operand), hasIterableProperty); NEXT_OPCODE(op_has_indexed_property); } case op_get_direct_pname: { SpeculatedType prediction = getPredictionWithoutOSRExit(); Node* base = get(VirtualRegister(currentInstruction[2].u.operand)); Node* property = get(VirtualRegister(currentInstruction[3].u.operand)); Node* index = get(VirtualRegister(currentInstruction[4].u.operand)); Node* enumerator = get(VirtualRegister(currentInstruction[5].u.operand)); addVarArgChild(base); addVarArgChild(property); addVarArgChild(index); addVarArgChild(enumerator); set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(Node::VarArg, GetDirectPname, OpInfo(0), OpInfo(prediction))); NEXT_OPCODE(op_get_direct_pname); } case op_get_property_enumerator: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(GetPropertyEnumerator, get(VirtualRegister(currentInstruction[2].u.operand)))); NEXT_OPCODE(op_get_property_enumerator); } case op_enumerator_structure_pname: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(GetEnumeratorStructurePname, get(VirtualRegister(currentInstruction[2].u.operand)), get(VirtualRegister(currentInstruction[3].u.operand)))); NEXT_OPCODE(op_enumerator_structure_pname); } case op_enumerator_generic_pname: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(GetEnumeratorGenericPname, get(VirtualRegister(currentInstruction[2].u.operand)), get(VirtualRegister(currentInstruction[3].u.operand)))); NEXT_OPCODE(op_enumerator_generic_pname); } case op_to_index_string: { set(VirtualRegister(currentInstruction[1].u.operand), addToGraph(ToIndexString, get(VirtualRegister(currentInstruction[2].u.operand)))); NEXT_OPCODE(op_to_index_string); } case op_log_shadow_chicken_prologue: { if (!m_inlineStackTop->m_inlineCallFrame) addToGraph(LogShadowChickenPrologue, get(VirtualRegister(currentInstruction[1].u.operand))); NEXT_OPCODE(op_log_shadow_chicken_prologue); } case op_log_shadow_chicken_tail: { if (!m_inlineStackTop->m_inlineCallFrame) { // FIXME: The right solution for inlining is to elide these whenever the tail call // ends up being inlined. // https://bugs.webkit.org/show_bug.cgi?id=155686 addToGraph(LogShadowChickenTail, get(VirtualRegister(currentInstruction[1].u.operand)), get(VirtualRegister(currentInstruction[2].u.operand))); } NEXT_OPCODE(op_log_shadow_chicken_tail); } default: // Parse failed! This should not happen because the capabilities checker // should have caught it. RELEASE_ASSERT_NOT_REACHED(); return false; } } } void ByteCodeParser::linkBlock(BasicBlock* block, Vector& possibleTargets) { ASSERT(!block->isLinked); ASSERT(!block->isEmpty()); Node* node = block->terminal(); ASSERT(node->isTerminal()); switch (node->op()) { case Jump: node->targetBlock() = blockForBytecodeOffset(possibleTargets, node->targetBytecodeOffsetDuringParsing()); break; case Branch: { BranchData* data = node->branchData(); data->taken.block = blockForBytecodeOffset(possibleTargets, data->takenBytecodeIndex()); data->notTaken.block = blockForBytecodeOffset(possibleTargets, data->notTakenBytecodeIndex()); break; } case Switch: { SwitchData* data = node->switchData(); for (unsigned i = node->switchData()->cases.size(); i--;) data->cases[i].target.block = blockForBytecodeOffset(possibleTargets, data->cases[i].target.bytecodeIndex()); data->fallThrough.block = blockForBytecodeOffset(possibleTargets, data->fallThrough.bytecodeIndex()); break; } default: break; } if (verbose) dataLog("Marking ", RawPointer(block), " as linked (actually did linking)\n"); block->didLink(); } void ByteCodeParser::linkBlocks(Vector& unlinkedBlocks, Vector& possibleTargets) { for (size_t i = 0; i < unlinkedBlocks.size(); ++i) { if (verbose) dataLog("Attempting to link ", RawPointer(unlinkedBlocks[i].m_block), "\n"); if (unlinkedBlocks[i].m_needsNormalLinking) { if (verbose) dataLog(" Does need normal linking.\n"); linkBlock(unlinkedBlocks[i].m_block, possibleTargets); unlinkedBlocks[i].m_needsNormalLinking = false; } } } ByteCodeParser::InlineStackEntry::InlineStackEntry( ByteCodeParser* byteCodeParser, CodeBlock* codeBlock, CodeBlock* profiledBlock, BasicBlock* callsiteBlockHead, JSFunction* callee, // Null if this is a closure call. VirtualRegister returnValueVR, VirtualRegister inlineCallFrameStart, int argumentCountIncludingThis, InlineCallFrame::Kind kind) : m_byteCodeParser(byteCodeParser) , m_codeBlock(codeBlock) , m_profiledBlock(profiledBlock) , m_callsiteBlockHead(callsiteBlockHead) , m_returnValue(returnValueVR) , m_didReturn(false) , m_didEarlyReturn(false) , m_caller(byteCodeParser->m_inlineStackTop) { { ConcurrentJITLocker locker(m_profiledBlock->m_lock); m_lazyOperands.initialize(locker, m_profiledBlock->lazyOperandValueProfiles()); m_exitProfile.initialize(locker, profiledBlock->exitProfile()); // We do this while holding the lock because we want to encourage StructureStubInfo's // to be potentially added to operations and because the profiled block could be in the // middle of LLInt->JIT tier-up in which case we would be adding the info's right now. if (m_profiledBlock->hasBaselineJITProfiling()) { m_profiledBlock->getStubInfoMap(locker, m_stubInfos); m_profiledBlock->getCallLinkInfoMap(locker, m_callLinkInfos); m_profiledBlock->getByValInfoMap(locker, m_byValInfos); } } m_argumentPositions.resize(argumentCountIncludingThis); for (int i = 0; i < argumentCountIncludingThis; ++i) { byteCodeParser->m_graph.m_argumentPositions.append(ArgumentPosition()); ArgumentPosition* argumentPosition = &byteCodeParser->m_graph.m_argumentPositions.last(); m_argumentPositions[i] = argumentPosition; } if (m_caller) { // Inline case. ASSERT(codeBlock != byteCodeParser->m_codeBlock); ASSERT(inlineCallFrameStart.isValid()); ASSERT(callsiteBlockHead); m_inlineCallFrame = byteCodeParser->m_graph.m_plan.inlineCallFrames->add(); byteCodeParser->m_graph.freeze(codeBlock->baselineVersion()); // The owner is the machine code block, and we already have a barrier on that when the // plan finishes. m_inlineCallFrame->baselineCodeBlock.setWithoutWriteBarrier(codeBlock->baselineVersion()); m_inlineCallFrame->setStackOffset(inlineCallFrameStart.offset() - JSStack::CallFrameHeaderSize); if (callee) { m_inlineCallFrame->calleeRecovery = ValueRecovery::constant(callee); m_inlineCallFrame->isClosureCall = false; } else m_inlineCallFrame->isClosureCall = true; m_inlineCallFrame->directCaller = byteCodeParser->currentCodeOrigin(); m_inlineCallFrame->arguments.resizeToFit(argumentCountIncludingThis); // Set the number of arguments including this, but don't configure the value recoveries, yet. m_inlineCallFrame->kind = kind; m_identifierRemap.resize(codeBlock->numberOfIdentifiers()); m_constantBufferRemap.resize(codeBlock->numberOfConstantBuffers()); m_switchRemap.resize(codeBlock->numberOfSwitchJumpTables()); for (size_t i = 0; i < codeBlock->numberOfIdentifiers(); ++i) { UniquedStringImpl* rep = codeBlock->identifier(i).impl(); unsigned index = byteCodeParser->m_graph.identifiers().ensure(rep); m_identifierRemap[i] = index; } for (unsigned i = 0; i < codeBlock->numberOfConstantBuffers(); ++i) { // If we inline the same code block multiple times, we don't want to needlessly // duplicate its constant buffers. HashMap::iterator iter = byteCodeParser->m_constantBufferCache.find(ConstantBufferKey(codeBlock, i)); if (iter != byteCodeParser->m_constantBufferCache.end()) { m_constantBufferRemap[i] = iter->value; continue; } Vector& buffer = codeBlock->constantBufferAsVector(i); unsigned newIndex = byteCodeParser->m_codeBlock->addConstantBuffer(buffer); m_constantBufferRemap[i] = newIndex; byteCodeParser->m_constantBufferCache.add(ConstantBufferKey(codeBlock, i), newIndex); } for (unsigned i = 0; i < codeBlock->numberOfSwitchJumpTables(); ++i) { m_switchRemap[i] = byteCodeParser->m_codeBlock->numberOfSwitchJumpTables(); byteCodeParser->m_codeBlock->addSwitchJumpTable() = codeBlock->switchJumpTable(i); } m_callsiteBlockHeadNeedsLinking = true; } else { // Machine code block case. ASSERT(codeBlock == byteCodeParser->m_codeBlock); ASSERT(!callee); ASSERT(!returnValueVR.isValid()); ASSERT(!inlineCallFrameStart.isValid()); ASSERT(!callsiteBlockHead); m_inlineCallFrame = 0; m_identifierRemap.resize(codeBlock->numberOfIdentifiers()); m_constantBufferRemap.resize(codeBlock->numberOfConstantBuffers()); m_switchRemap.resize(codeBlock->numberOfSwitchJumpTables()); for (size_t i = 0; i < codeBlock->numberOfIdentifiers(); ++i) m_identifierRemap[i] = i; for (size_t i = 0; i < codeBlock->numberOfConstantBuffers(); ++i) m_constantBufferRemap[i] = i; for (size_t i = 0; i < codeBlock->numberOfSwitchJumpTables(); ++i) m_switchRemap[i] = i; m_callsiteBlockHeadNeedsLinking = false; } byteCodeParser->m_inlineStackTop = this; } void ByteCodeParser::parseCodeBlock() { clearCaches(); CodeBlock* codeBlock = m_inlineStackTop->m_codeBlock; if (m_graph.compilation()) { m_graph.compilation()->addProfiledBytecodes( *m_vm->m_perBytecodeProfiler, m_inlineStackTop->m_profiledBlock); } if (UNLIKELY(Options::dumpSourceAtDFGTime())) { Vector& deferredSourceDump = m_graph.m_plan.callback->ensureDeferredSourceDump(); if (inlineCallFrame()) { DeferredSourceDump dump(codeBlock->baselineVersion(), m_codeBlock, JITCode::DFGJIT, inlineCallFrame()->directCaller); deferredSourceDump.append(dump); } else deferredSourceDump.append(DeferredSourceDump(codeBlock->baselineVersion())); } if (Options::dumpBytecodeAtDFGTime()) { dataLog("Parsing ", *codeBlock); if (inlineCallFrame()) { dataLog( " for inlining at ", CodeBlockWithJITType(m_codeBlock, JITCode::DFGJIT), " ", inlineCallFrame()->directCaller); } dataLog( ", isStrictMode = ", codeBlock->ownerScriptExecutable()->isStrictMode(), "\n"); codeBlock->baselineVersion()->dumpBytecode(); } Vector jumpTargets; computePreciseJumpTargets(codeBlock, jumpTargets); if (Options::dumpBytecodeAtDFGTime()) { dataLog("Jump targets: "); CommaPrinter comma; for (unsigned i = 0; i < jumpTargets.size(); ++i) dataLog(comma, jumpTargets[i]); dataLog("\n"); } for (unsigned jumpTargetIndex = 0; jumpTargetIndex <= jumpTargets.size(); ++jumpTargetIndex) { // The maximum bytecode offset to go into the current basicblock is either the next jump target, or the end of the instructions. unsigned limit = jumpTargetIndex < jumpTargets.size() ? jumpTargets[jumpTargetIndex] : codeBlock->instructions().size(); ASSERT(m_currentIndex < limit); // Loop until we reach the current limit (i.e. next jump target). do { if (!m_currentBlock) { // Check if we can use the last block. if (m_graph.numBlocks() && m_graph.lastBlock()->isEmpty()) { // This must be a block belonging to us. ASSERT(m_inlineStackTop->m_unlinkedBlocks.last().m_block == m_graph.lastBlock()); // Either the block is linkable or it isn't. If it's linkable then it's the last // block in the blockLinkingTargets list. If it's not then the last block will // have a lower bytecode index that the one we're about to give to this block. if (m_inlineStackTop->m_blockLinkingTargets.isEmpty() || m_inlineStackTop->m_blockLinkingTargets.last()->bytecodeBegin != m_currentIndex) { // Make the block linkable. ASSERT(m_inlineStackTop->m_blockLinkingTargets.isEmpty() || m_inlineStackTop->m_blockLinkingTargets.last()->bytecodeBegin < m_currentIndex); m_inlineStackTop->m_blockLinkingTargets.append(m_graph.lastBlock()); } // Change its bytecode begin and continue. m_currentBlock = m_graph.lastBlock(); m_currentBlock->bytecodeBegin = m_currentIndex; } else { RefPtr block = adoptRef(new BasicBlock(m_currentIndex, m_numArguments, m_numLocals, 1)); m_currentBlock = block.get(); // This assertion checks two things: // 1) If the bytecodeBegin is greater than currentIndex, then something has gone // horribly wrong. So, we're probably generating incorrect code. // 2) If the bytecodeBegin is equal to the currentIndex, then we failed to do // a peephole coalescing of this block in the if statement above. So, we're // generating suboptimal code and leaving more work for the CFG simplifier. if (!m_inlineStackTop->m_unlinkedBlocks.isEmpty()) { unsigned lastBegin = m_inlineStackTop->m_unlinkedBlocks.last().m_block->bytecodeBegin; ASSERT_UNUSED( lastBegin, lastBegin == UINT_MAX || lastBegin < m_currentIndex); } m_inlineStackTop->m_unlinkedBlocks.append(UnlinkedBlock(block.get())); m_inlineStackTop->m_blockLinkingTargets.append(block.get()); // The first block is definitely an OSR target. if (!m_graph.numBlocks()) block->isOSRTarget = true; m_graph.appendBlock(block); prepareToParseBlock(); } } bool shouldContinueParsing = parseBlock(limit); // We should not have gone beyond the limit. ASSERT(m_currentIndex <= limit); // We should have planted a terminal, or we just gave up because // we realized that the jump target information is imprecise, or we // are at the end of an inline function, or we realized that we // should stop parsing because there was a return in the first // basic block. ASSERT(m_currentBlock->isEmpty() || m_currentBlock->terminal() || (m_currentIndex == codeBlock->instructions().size() && inlineCallFrame()) || !shouldContinueParsing); if (!shouldContinueParsing) { if (Options::verboseDFGByteCodeParsing()) dataLog("Done parsing ", *codeBlock, "\n"); return; } m_currentBlock = nullptr; } while (m_currentIndex < limit); } // Should have reached the end of the instructions. ASSERT(m_currentIndex == codeBlock->instructions().size()); if (Options::verboseDFGByteCodeParsing()) dataLog("Done parsing ", *codeBlock, " (fell off end)\n"); } bool ByteCodeParser::parse() { // Set during construction. ASSERT(!m_currentIndex); if (Options::verboseDFGByteCodeParsing()) dataLog("Parsing ", *m_codeBlock, "\n"); m_dfgCodeBlock = m_graph.m_plan.profiledDFGCodeBlock; if (isFTL(m_graph.m_plan.mode) && m_dfgCodeBlock && Options::usePolyvariantDevirtualization()) { if (Options::usePolyvariantCallInlining()) CallLinkStatus::computeDFGStatuses(m_dfgCodeBlock, m_callContextMap); if (Options::usePolyvariantByIdInlining()) m_dfgCodeBlock->getStubInfoMap(m_dfgStubInfos); } InlineStackEntry inlineStackEntry( this, m_codeBlock, m_profiledBlock, 0, 0, VirtualRegister(), VirtualRegister(), m_codeBlock->numParameters(), InlineCallFrame::Call); parseCodeBlock(); linkBlocks(inlineStackEntry.m_unlinkedBlocks, inlineStackEntry.m_blockLinkingTargets); m_graph.determineReachability(); m_graph.killUnreachableBlocks(); for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) { BasicBlock* block = m_graph.block(blockIndex); if (!block) continue; ASSERT(block->variablesAtHead.numberOfLocals() == m_graph.block(0)->variablesAtHead.numberOfLocals()); ASSERT(block->variablesAtHead.numberOfArguments() == m_graph.block(0)->variablesAtHead.numberOfArguments()); ASSERT(block->variablesAtTail.numberOfLocals() == m_graph.block(0)->variablesAtHead.numberOfLocals()); ASSERT(block->variablesAtTail.numberOfArguments() == m_graph.block(0)->variablesAtHead.numberOfArguments()); } m_graph.m_localVars = m_numLocals; m_graph.m_parameterSlots = m_parameterSlots; return true; } bool parse(Graph& graph) { return ByteCodeParser(graph).parse(); } } } // namespace JSC::DFG #endif