// Copyright 2012 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_HYDROGEN_H_ #define V8_HYDROGEN_H_ #include "src/v8.h" #include "src/accessors.h" #include "src/allocation.h" #include "src/ast.h" #include "src/compiler.h" #include "src/hydrogen-instructions.h" #include "src/scopes.h" #include "src/zone.h" namespace v8 { namespace internal { // Forward declarations. class BitVector; class FunctionState; class HEnvironment; class HGraph; class HLoopInformation; class HOsrBuilder; class HTracer; class LAllocator; class LChunk; class LiveRange; class HBasicBlock FINAL : public ZoneObject { public: explicit HBasicBlock(HGraph* graph); ~HBasicBlock() { } // Simple accessors. int block_id() const { return block_id_; } void set_block_id(int id) { block_id_ = id; } HGraph* graph() const { return graph_; } Isolate* isolate() const; const ZoneList* phis() const { return &phis_; } HInstruction* first() const { return first_; } HInstruction* last() const { return last_; } void set_last(HInstruction* instr) { last_ = instr; } HControlInstruction* end() const { return end_; } HLoopInformation* loop_information() const { return loop_information_; } HLoopInformation* current_loop() const { return IsLoopHeader() ? loop_information() : (parent_loop_header() != NULL ? parent_loop_header()->loop_information() : NULL); } const ZoneList* predecessors() const { return &predecessors_; } bool HasPredecessor() const { return predecessors_.length() > 0; } const ZoneList* dominated_blocks() const { return &dominated_blocks_; } const ZoneList* deleted_phis() const { return &deleted_phis_; } void RecordDeletedPhi(int merge_index) { deleted_phis_.Add(merge_index, zone()); } HBasicBlock* dominator() const { return dominator_; } HEnvironment* last_environment() const { return last_environment_; } int argument_count() const { return argument_count_; } void set_argument_count(int count) { argument_count_ = count; } int first_instruction_index() const { return first_instruction_index_; } void set_first_instruction_index(int index) { first_instruction_index_ = index; } int last_instruction_index() const { return last_instruction_index_; } void set_last_instruction_index(int index) { last_instruction_index_ = index; } bool is_osr_entry() { return is_osr_entry_; } void set_osr_entry() { is_osr_entry_ = true; } void AttachLoopInformation(); void DetachLoopInformation(); bool IsLoopHeader() const { return loop_information() != NULL; } bool IsStartBlock() const { return block_id() == 0; } void PostProcessLoopHeader(IterationStatement* stmt); bool IsFinished() const { return end_ != NULL; } void AddPhi(HPhi* phi); void RemovePhi(HPhi* phi); void AddInstruction(HInstruction* instr, HSourcePosition position); bool Dominates(HBasicBlock* other) const; bool EqualToOrDominates(HBasicBlock* other) const; int LoopNestingDepth() const; void SetInitialEnvironment(HEnvironment* env); void ClearEnvironment() { DCHECK(IsFinished()); DCHECK(end()->SuccessorCount() == 0); last_environment_ = NULL; } bool HasEnvironment() const { return last_environment_ != NULL; } void UpdateEnvironment(HEnvironment* env); HBasicBlock* parent_loop_header() const { return parent_loop_header_; } void set_parent_loop_header(HBasicBlock* block) { DCHECK(parent_loop_header_ == NULL); parent_loop_header_ = block; } bool HasParentLoopHeader() const { return parent_loop_header_ != NULL; } void SetJoinId(BailoutId ast_id); int PredecessorIndexOf(HBasicBlock* predecessor) const; HPhi* AddNewPhi(int merged_index); HSimulate* AddNewSimulate(BailoutId ast_id, HSourcePosition position, RemovableSimulate removable = FIXED_SIMULATE) { HSimulate* instr = CreateSimulate(ast_id, removable); AddInstruction(instr, position); return instr; } void AssignCommonDominator(HBasicBlock* other); void AssignLoopSuccessorDominators(); // If a target block is tagged as an inline function return, all // predecessors should contain the inlined exit sequence: // // LeaveInlined // Simulate (caller's environment) // Goto (target block) bool IsInlineReturnTarget() const { return is_inline_return_target_; } void MarkAsInlineReturnTarget(HBasicBlock* inlined_entry_block) { is_inline_return_target_ = true; inlined_entry_block_ = inlined_entry_block; } HBasicBlock* inlined_entry_block() { return inlined_entry_block_; } bool IsDeoptimizing() const { return end() != NULL && end()->IsDeoptimize(); } void MarkUnreachable(); bool IsUnreachable() const { return !is_reachable_; } bool IsReachable() const { return is_reachable_; } bool IsLoopSuccessorDominator() const { return dominates_loop_successors_; } void MarkAsLoopSuccessorDominator() { dominates_loop_successors_ = true; } bool IsOrdered() const { return is_ordered_; } void MarkAsOrdered() { is_ordered_ = true; } void MarkSuccEdgeUnreachable(int succ); inline Zone* zone() const; #ifdef DEBUG void Verify(); #endif protected: friend class HGraphBuilder; HSimulate* CreateSimulate(BailoutId ast_id, RemovableSimulate removable); void Finish(HControlInstruction* last, HSourcePosition position); void FinishExit(HControlInstruction* instruction, HSourcePosition position); void Goto(HBasicBlock* block, HSourcePosition position, FunctionState* state = NULL, bool add_simulate = true); void GotoNoSimulate(HBasicBlock* block, HSourcePosition position) { Goto(block, position, NULL, false); } // Add the inlined function exit sequence, adding an HLeaveInlined // instruction and updating the bailout environment. void AddLeaveInlined(HValue* return_value, FunctionState* state, HSourcePosition position); private: void RegisterPredecessor(HBasicBlock* pred); void AddDominatedBlock(HBasicBlock* block); int block_id_; HGraph* graph_; ZoneList phis_; HInstruction* first_; HInstruction* last_; HControlInstruction* end_; HLoopInformation* loop_information_; ZoneList predecessors_; HBasicBlock* dominator_; ZoneList dominated_blocks_; HEnvironment* last_environment_; // Outgoing parameter count at block exit, set during lithium translation. int argument_count_; // Instruction indices into the lithium code stream. int first_instruction_index_; int last_instruction_index_; ZoneList deleted_phis_; HBasicBlock* parent_loop_header_; // For blocks marked as inline return target: the block with HEnterInlined. HBasicBlock* inlined_entry_block_; bool is_inline_return_target_ : 1; bool is_reachable_ : 1; bool dominates_loop_successors_ : 1; bool is_osr_entry_ : 1; bool is_ordered_ : 1; }; OStream& operator<<(OStream& os, const HBasicBlock& b); class HPredecessorIterator FINAL BASE_EMBEDDED { public: explicit HPredecessorIterator(HBasicBlock* block) : predecessor_list_(block->predecessors()), current_(0) { } bool Done() { return current_ >= predecessor_list_->length(); } HBasicBlock* Current() { return predecessor_list_->at(current_); } void Advance() { current_++; } private: const ZoneList* predecessor_list_; int current_; }; class HInstructionIterator FINAL BASE_EMBEDDED { public: explicit HInstructionIterator(HBasicBlock* block) : instr_(block->first()) { next_ = Done() ? NULL : instr_->next(); } inline bool Done() const { return instr_ == NULL; } inline HInstruction* Current() { return instr_; } inline void Advance() { instr_ = next_; next_ = Done() ? NULL : instr_->next(); } private: HInstruction* instr_; HInstruction* next_; }; class HLoopInformation FINAL : public ZoneObject { public: HLoopInformation(HBasicBlock* loop_header, Zone* zone) : back_edges_(4, zone), loop_header_(loop_header), blocks_(8, zone), stack_check_(NULL) { blocks_.Add(loop_header, zone); } ~HLoopInformation() {} const ZoneList* back_edges() const { return &back_edges_; } const ZoneList* blocks() const { return &blocks_; } HBasicBlock* loop_header() const { return loop_header_; } HBasicBlock* GetLastBackEdge() const; void RegisterBackEdge(HBasicBlock* block); HStackCheck* stack_check() const { return stack_check_; } void set_stack_check(HStackCheck* stack_check) { stack_check_ = stack_check; } bool IsNestedInThisLoop(HLoopInformation* other) { while (other != NULL) { if (other == this) { return true; } other = other->parent_loop(); } return false; } HLoopInformation* parent_loop() { HBasicBlock* parent_header = loop_header()->parent_loop_header(); return parent_header != NULL ? parent_header->loop_information() : NULL; } private: void AddBlock(HBasicBlock* block); ZoneList back_edges_; HBasicBlock* loop_header_; ZoneList blocks_; HStackCheck* stack_check_; }; class BoundsCheckTable; class InductionVariableBlocksTable; class HGraph FINAL : public ZoneObject { public: explicit HGraph(CompilationInfo* info); Isolate* isolate() const { return isolate_; } Zone* zone() const { return zone_; } CompilationInfo* info() const { return info_; } const ZoneList* blocks() const { return &blocks_; } const ZoneList* phi_list() const { return phi_list_; } HBasicBlock* entry_block() const { return entry_block_; } HEnvironment* start_environment() const { return start_environment_; } void FinalizeUniqueness(); bool ProcessArgumentsObject(); void OrderBlocks(); void AssignDominators(); void RestoreActualValues(); // Returns false if there are phi-uses of the arguments-object // which are not supported by the optimizing compiler. bool CheckArgumentsPhiUses(); // Returns false if there are phi-uses of an uninitialized const // which are not supported by the optimizing compiler. bool CheckConstPhiUses(); void CollectPhis(); HConstant* GetConstantUndefined(); HConstant* GetConstant0(); HConstant* GetConstant1(); HConstant* GetConstantMinus1(); HConstant* GetConstantTrue(); HConstant* GetConstantFalse(); HConstant* GetConstantHole(); HConstant* GetConstantNull(); HConstant* GetInvalidContext(); bool IsConstantUndefined(HConstant* constant); bool IsConstant0(HConstant* constant); bool IsConstant1(HConstant* constant); bool IsConstantMinus1(HConstant* constant); bool IsConstantTrue(HConstant* constant); bool IsConstantFalse(HConstant* constant); bool IsConstantHole(HConstant* constant); bool IsConstantNull(HConstant* constant); bool IsStandardConstant(HConstant* constant); HBasicBlock* CreateBasicBlock(); HArgumentsObject* GetArgumentsObject() const { return arguments_object_.get(); } void SetArgumentsObject(HArgumentsObject* object) { arguments_object_.set(object); } int GetMaximumValueID() const { return values_.length(); } int GetNextBlockID() { return next_block_id_++; } int GetNextValueID(HValue* value) { DCHECK(!disallow_adding_new_values_); values_.Add(value, zone()); return values_.length() - 1; } HValue* LookupValue(int id) const { if (id >= 0 && id < values_.length()) return values_[id]; return NULL; } void DisallowAddingNewValues() { disallow_adding_new_values_ = true; } bool Optimize(BailoutReason* bailout_reason); #ifdef DEBUG void Verify(bool do_full_verify) const; #endif bool has_osr() { return osr_ != NULL; } void set_osr(HOsrBuilder* osr) { osr_ = osr; } HOsrBuilder* osr() { return osr_; } int update_type_change_checksum(int delta) { type_change_checksum_ += delta; return type_change_checksum_; } void update_maximum_environment_size(int environment_size) { if (environment_size > maximum_environment_size_) { maximum_environment_size_ = environment_size; } } int maximum_environment_size() { return maximum_environment_size_; } bool use_optimistic_licm() { return use_optimistic_licm_; } void set_use_optimistic_licm(bool value) { use_optimistic_licm_ = value; } void MarkRecursive() { is_recursive_ = true; } bool is_recursive() const { return is_recursive_; } void MarkDependsOnEmptyArrayProtoElements() { // Add map dependency if not already added. if (depends_on_empty_array_proto_elements_) return; Map::AddDependentCompilationInfo( handle(isolate()->initial_object_prototype()->map()), DependentCode::kElementsCantBeAddedGroup, info()); Map::AddDependentCompilationInfo( handle(isolate()->initial_array_prototype()->map()), DependentCode::kElementsCantBeAddedGroup, info()); depends_on_empty_array_proto_elements_ = true; } bool depends_on_empty_array_proto_elements() { return depends_on_empty_array_proto_elements_; } bool has_uint32_instructions() { DCHECK(uint32_instructions_ == NULL || !uint32_instructions_->is_empty()); return uint32_instructions_ != NULL; } ZoneList* uint32_instructions() { DCHECK(uint32_instructions_ == NULL || !uint32_instructions_->is_empty()); return uint32_instructions_; } void RecordUint32Instruction(HInstruction* instr) { DCHECK(uint32_instructions_ == NULL || !uint32_instructions_->is_empty()); if (uint32_instructions_ == NULL) { uint32_instructions_ = new(zone()) ZoneList(4, zone()); } uint32_instructions_->Add(instr, zone()); } void IncrementInNoSideEffectsScope() { no_side_effects_scope_count_++; } void DecrementInNoSideEffectsScope() { no_side_effects_scope_count_--; } bool IsInsideNoSideEffectsScope() { return no_side_effects_scope_count_ > 0; } // If we are tracking source positions then this function assigns a unique // identifier to each inlining and dumps function source if it was inlined // for the first time during the current optimization. int TraceInlinedFunction(Handle shared, HSourcePosition position); // Converts given HSourcePosition to the absolute offset from the start of // the corresponding script. int SourcePositionToScriptPosition(HSourcePosition position); private: HConstant* ReinsertConstantIfNecessary(HConstant* constant); HConstant* GetConstant(SetOncePointer* pointer, int32_t integer_value); template void Run() { Phase phase(this); phase.Run(); } void EliminateRedundantBoundsChecksUsingInductionVariables(); Isolate* isolate_; int next_block_id_; HBasicBlock* entry_block_; HEnvironment* start_environment_; ZoneList blocks_; ZoneList values_; ZoneList* phi_list_; ZoneList* uint32_instructions_; SetOncePointer constant_undefined_; SetOncePointer constant_0_; SetOncePointer constant_1_; SetOncePointer constant_minus1_; SetOncePointer constant_true_; SetOncePointer constant_false_; SetOncePointer constant_the_hole_; SetOncePointer constant_null_; SetOncePointer constant_invalid_context_; SetOncePointer arguments_object_; HOsrBuilder* osr_; CompilationInfo* info_; Zone* zone_; bool is_recursive_; bool use_optimistic_licm_; bool depends_on_empty_array_proto_elements_; int type_change_checksum_; int maximum_environment_size_; int no_side_effects_scope_count_; bool disallow_adding_new_values_; class InlinedFunctionInfo { public: explicit InlinedFunctionInfo(Handle shared) : shared_(shared), start_position_(shared->start_position()) { } Handle shared() const { return shared_; } int start_position() const { return start_position_; } private: Handle shared_; int start_position_; }; int next_inline_id_; ZoneList inlined_functions_; DISALLOW_COPY_AND_ASSIGN(HGraph); }; Zone* HBasicBlock::zone() const { return graph_->zone(); } // Type of stack frame an environment might refer to. enum FrameType { JS_FUNCTION, JS_CONSTRUCT, JS_GETTER, JS_SETTER, ARGUMENTS_ADAPTOR, STUB }; class HEnvironment FINAL : public ZoneObject { public: HEnvironment(HEnvironment* outer, Scope* scope, Handle closure, Zone* zone); HEnvironment(Zone* zone, int parameter_count); HEnvironment* arguments_environment() { return outer()->frame_type() == ARGUMENTS_ADAPTOR ? outer() : this; } // Simple accessors. Handle closure() const { return closure_; } const ZoneList* values() const { return &values_; } const GrowableBitVector* assigned_variables() const { return &assigned_variables_; } FrameType frame_type() const { return frame_type_; } int parameter_count() const { return parameter_count_; } int specials_count() const { return specials_count_; } int local_count() const { return local_count_; } HEnvironment* outer() const { return outer_; } int pop_count() const { return pop_count_; } int push_count() const { return push_count_; } BailoutId ast_id() const { return ast_id_; } void set_ast_id(BailoutId id) { ast_id_ = id; } HEnterInlined* entry() const { return entry_; } void set_entry(HEnterInlined* entry) { entry_ = entry; } int length() const { return values_.length(); } int first_expression_index() const { return parameter_count() + specials_count() + local_count(); } int first_local_index() const { return parameter_count() + specials_count(); } void Bind(Variable* variable, HValue* value) { Bind(IndexFor(variable), value); } void Bind(int index, HValue* value); void BindContext(HValue* value) { Bind(parameter_count(), value); } HValue* Lookup(Variable* variable) const { return Lookup(IndexFor(variable)); } HValue* Lookup(int index) const { HValue* result = values_[index]; DCHECK(result != NULL); return result; } HValue* context() const { // Return first special. return Lookup(parameter_count()); } void Push(HValue* value) { DCHECK(value != NULL); ++push_count_; values_.Add(value, zone()); } HValue* Pop() { DCHECK(!ExpressionStackIsEmpty()); if (push_count_ > 0) { --push_count_; } else { ++pop_count_; } return values_.RemoveLast(); } void Drop(int count); HValue* Top() const { return ExpressionStackAt(0); } bool ExpressionStackIsEmpty() const; HValue* ExpressionStackAt(int index_from_top) const { int index = length() - index_from_top - 1; DCHECK(HasExpressionAt(index)); return values_[index]; } void SetExpressionStackAt(int index_from_top, HValue* value); HEnvironment* Copy() const; HEnvironment* CopyWithoutHistory() const; HEnvironment* CopyAsLoopHeader(HBasicBlock* block) const; // Create an "inlined version" of this environment, where the original // environment is the outer environment but the top expression stack // elements are moved to an inner environment as parameters. HEnvironment* CopyForInlining(Handle target, int arguments, FunctionLiteral* function, HConstant* undefined, InliningKind inlining_kind) const; HEnvironment* DiscardInlined(bool drop_extra) { HEnvironment* outer = outer_; while (outer->frame_type() != JS_FUNCTION) outer = outer->outer_; if (drop_extra) outer->Drop(1); return outer; } void AddIncomingEdge(HBasicBlock* block, HEnvironment* other); void ClearHistory() { pop_count_ = 0; push_count_ = 0; assigned_variables_.Clear(); } void SetValueAt(int index, HValue* value) { DCHECK(index < length()); values_[index] = value; } // Map a variable to an environment index. Parameter indices are shifted // by 1 (receiver is parameter index -1 but environment index 0). // Stack-allocated local indices are shifted by the number of parameters. int IndexFor(Variable* variable) const { DCHECK(variable->IsStackAllocated()); int shift = variable->IsParameter() ? 1 : parameter_count_ + specials_count_; return variable->index() + shift; } bool is_local_index(int i) const { return i >= first_local_index() && i < first_expression_index(); } bool is_parameter_index(int i) const { return i >= 0 && i < parameter_count(); } bool is_special_index(int i) const { return i >= parameter_count() && i < parameter_count() + specials_count(); } Zone* zone() const { return zone_; } private: HEnvironment(const HEnvironment* other, Zone* zone); HEnvironment(HEnvironment* outer, Handle closure, FrameType frame_type, int arguments, Zone* zone); // Create an artificial stub environment (e.g. for argument adaptor or // constructor stub). HEnvironment* CreateStubEnvironment(HEnvironment* outer, Handle target, FrameType frame_type, int arguments) const; // True if index is included in the expression stack part of the environment. bool HasExpressionAt(int index) const; void Initialize(int parameter_count, int local_count, int stack_height); void Initialize(const HEnvironment* other); Handle closure_; // Value array [parameters] [specials] [locals] [temporaries]. ZoneList values_; GrowableBitVector assigned_variables_; FrameType frame_type_; int parameter_count_; int specials_count_; int local_count_; HEnvironment* outer_; HEnterInlined* entry_; int pop_count_; int push_count_; BailoutId ast_id_; Zone* zone_; }; OStream& operator<<(OStream& os, const HEnvironment& env); class HOptimizedGraphBuilder; enum ArgumentsAllowedFlag { ARGUMENTS_NOT_ALLOWED, ARGUMENTS_ALLOWED }; class HIfContinuation; // This class is not BASE_EMBEDDED because our inlining implementation uses // new and delete. class AstContext { public: bool IsEffect() const { return kind_ == Expression::kEffect; } bool IsValue() const { return kind_ == Expression::kValue; } bool IsTest() const { return kind_ == Expression::kTest; } // 'Fill' this context with a hydrogen value. The value is assumed to // have already been inserted in the instruction stream (or not need to // be, e.g., HPhi). Call this function in tail position in the Visit // functions for expressions. virtual void ReturnValue(HValue* value) = 0; // Add a hydrogen instruction to the instruction stream (recording an // environment simulation if necessary) and then fill this context with // the instruction as value. virtual void ReturnInstruction(HInstruction* instr, BailoutId ast_id) = 0; // Finishes the current basic block and materialize a boolean for // value context, nothing for effect, generate a branch for test context. // Call this function in tail position in the Visit functions for // expressions. virtual void ReturnControl(HControlInstruction* instr, BailoutId ast_id) = 0; // Finishes the current basic block and materialize a boolean for // value context, nothing for effect, generate a branch for test context. // Call this function in tail position in the Visit functions for // expressions that use an IfBuilder. virtual void ReturnContinuation(HIfContinuation* continuation, BailoutId ast_id) = 0; void set_for_typeof(bool for_typeof) { for_typeof_ = for_typeof; } bool is_for_typeof() { return for_typeof_; } protected: AstContext(HOptimizedGraphBuilder* owner, Expression::Context kind); virtual ~AstContext(); HOptimizedGraphBuilder* owner() const { return owner_; } inline Zone* zone() const; // We want to be able to assert, in a context-specific way, that the stack // height makes sense when the context is filled. #ifdef DEBUG int original_length_; #endif private: HOptimizedGraphBuilder* owner_; Expression::Context kind_; AstContext* outer_; bool for_typeof_; }; class EffectContext FINAL : public AstContext { public: explicit EffectContext(HOptimizedGraphBuilder* owner) : AstContext(owner, Expression::kEffect) { } virtual ~EffectContext(); virtual void ReturnValue(HValue* value) OVERRIDE; virtual void ReturnInstruction(HInstruction* instr, BailoutId ast_id) OVERRIDE; virtual void ReturnControl(HControlInstruction* instr, BailoutId ast_id) OVERRIDE; virtual void ReturnContinuation(HIfContinuation* continuation, BailoutId ast_id) OVERRIDE; }; class ValueContext FINAL : public AstContext { public: ValueContext(HOptimizedGraphBuilder* owner, ArgumentsAllowedFlag flag) : AstContext(owner, Expression::kValue), flag_(flag) { } virtual ~ValueContext(); virtual void ReturnValue(HValue* value) OVERRIDE; virtual void ReturnInstruction(HInstruction* instr, BailoutId ast_id) OVERRIDE; virtual void ReturnControl(HControlInstruction* instr, BailoutId ast_id) OVERRIDE; virtual void ReturnContinuation(HIfContinuation* continuation, BailoutId ast_id) OVERRIDE; bool arguments_allowed() { return flag_ == ARGUMENTS_ALLOWED; } private: ArgumentsAllowedFlag flag_; }; class TestContext FINAL : public AstContext { public: TestContext(HOptimizedGraphBuilder* owner, Expression* condition, HBasicBlock* if_true, HBasicBlock* if_false) : AstContext(owner, Expression::kTest), condition_(condition), if_true_(if_true), if_false_(if_false) { } virtual void ReturnValue(HValue* value) OVERRIDE; virtual void ReturnInstruction(HInstruction* instr, BailoutId ast_id) OVERRIDE; virtual void ReturnControl(HControlInstruction* instr, BailoutId ast_id) OVERRIDE; virtual void ReturnContinuation(HIfContinuation* continuation, BailoutId ast_id) OVERRIDE; static TestContext* cast(AstContext* context) { DCHECK(context->IsTest()); return reinterpret_cast(context); } Expression* condition() const { return condition_; } HBasicBlock* if_true() const { return if_true_; } HBasicBlock* if_false() const { return if_false_; } private: // Build the shared core part of the translation unpacking a value into // control flow. void BuildBranch(HValue* value); Expression* condition_; HBasicBlock* if_true_; HBasicBlock* if_false_; }; class FunctionState FINAL { public: FunctionState(HOptimizedGraphBuilder* owner, CompilationInfo* info, InliningKind inlining_kind, int inlining_id); ~FunctionState(); CompilationInfo* compilation_info() { return compilation_info_; } AstContext* call_context() { return call_context_; } InliningKind inlining_kind() const { return inlining_kind_; } HBasicBlock* function_return() { return function_return_; } TestContext* test_context() { return test_context_; } void ClearInlinedTestContext() { delete test_context_; test_context_ = NULL; } FunctionState* outer() { return outer_; } HEnterInlined* entry() { return entry_; } void set_entry(HEnterInlined* entry) { entry_ = entry; } HArgumentsObject* arguments_object() { return arguments_object_; } void set_arguments_object(HArgumentsObject* arguments_object) { arguments_object_ = arguments_object; } HArgumentsElements* arguments_elements() { return arguments_elements_; } void set_arguments_elements(HArgumentsElements* arguments_elements) { arguments_elements_ = arguments_elements; } bool arguments_pushed() { return arguments_elements() != NULL; } int inlining_id() const { return inlining_id_; } private: HOptimizedGraphBuilder* owner_; CompilationInfo* compilation_info_; // During function inlining, expression context of the call being // inlined. NULL when not inlining. AstContext* call_context_; // The kind of call which is currently being inlined. InliningKind inlining_kind_; // When inlining in an effect or value context, this is the return block. // It is NULL otherwise. When inlining in a test context, there are a // pair of return blocks in the context. When not inlining, there is no // local return point. HBasicBlock* function_return_; // When inlining a call in a test context, a context containing a pair of // return blocks. NULL in all other cases. TestContext* test_context_; // When inlining HEnterInlined instruction corresponding to the function // entry. HEnterInlined* entry_; HArgumentsObject* arguments_object_; HArgumentsElements* arguments_elements_; int inlining_id_; HSourcePosition outer_source_position_; FunctionState* outer_; }; class HIfContinuation FINAL { public: HIfContinuation() : continuation_captured_(false), true_branch_(NULL), false_branch_(NULL) {} HIfContinuation(HBasicBlock* true_branch, HBasicBlock* false_branch) : continuation_captured_(true), true_branch_(true_branch), false_branch_(false_branch) {} ~HIfContinuation() { DCHECK(!continuation_captured_); } void Capture(HBasicBlock* true_branch, HBasicBlock* false_branch) { DCHECK(!continuation_captured_); true_branch_ = true_branch; false_branch_ = false_branch; continuation_captured_ = true; } void Continue(HBasicBlock** true_branch, HBasicBlock** false_branch) { DCHECK(continuation_captured_); *true_branch = true_branch_; *false_branch = false_branch_; continuation_captured_ = false; } bool IsTrueReachable() { return true_branch_ != NULL; } bool IsFalseReachable() { return false_branch_ != NULL; } bool TrueAndFalseReachable() { return IsTrueReachable() || IsFalseReachable(); } HBasicBlock* true_branch() const { return true_branch_; } HBasicBlock* false_branch() const { return false_branch_; } private: bool continuation_captured_; HBasicBlock* true_branch_; HBasicBlock* false_branch_; }; class HAllocationMode FINAL BASE_EMBEDDED { public: explicit HAllocationMode(Handle feedback_site) : current_site_(NULL), feedback_site_(feedback_site), pretenure_flag_(NOT_TENURED) {} explicit HAllocationMode(HValue* current_site) : current_site_(current_site), pretenure_flag_(NOT_TENURED) {} explicit HAllocationMode(PretenureFlag pretenure_flag) : current_site_(NULL), pretenure_flag_(pretenure_flag) {} HAllocationMode() : current_site_(NULL), pretenure_flag_(NOT_TENURED) {} HValue* current_site() const { return current_site_; } Handle feedback_site() const { return feedback_site_; } bool CreateAllocationMementos() const WARN_UNUSED_RESULT { return current_site() != NULL; } PretenureFlag GetPretenureMode() const WARN_UNUSED_RESULT { if (!feedback_site().is_null()) return feedback_site()->GetPretenureMode(); return pretenure_flag_; } private: HValue* current_site_; Handle feedback_site_; PretenureFlag pretenure_flag_; }; class HGraphBuilder { public: explicit HGraphBuilder(CompilationInfo* info) : info_(info), graph_(NULL), current_block_(NULL), scope_(info->scope()), position_(HSourcePosition::Unknown()), start_position_(0) {} virtual ~HGraphBuilder() {} Scope* scope() const { return scope_; } void set_scope(Scope* scope) { scope_ = scope; } HBasicBlock* current_block() const { return current_block_; } void set_current_block(HBasicBlock* block) { current_block_ = block; } HEnvironment* environment() const { return current_block()->last_environment(); } Zone* zone() const { return info_->zone(); } HGraph* graph() const { return graph_; } Isolate* isolate() const { return graph_->isolate(); } CompilationInfo* top_info() { return info_; } HGraph* CreateGraph(); // Bailout environment manipulation. void Push(HValue* value) { environment()->Push(value); } HValue* Pop() { return environment()->Pop(); } virtual HValue* context() = 0; // Adding instructions. HInstruction* AddInstruction(HInstruction* instr); void FinishCurrentBlock(HControlInstruction* last); void FinishExitCurrentBlock(HControlInstruction* instruction); void Goto(HBasicBlock* from, HBasicBlock* target, FunctionState* state = NULL, bool add_simulate = true) { from->Goto(target, source_position(), state, add_simulate); } void Goto(HBasicBlock* target, FunctionState* state = NULL, bool add_simulate = true) { Goto(current_block(), target, state, add_simulate); } void GotoNoSimulate(HBasicBlock* from, HBasicBlock* target) { Goto(from, target, NULL, false); } void GotoNoSimulate(HBasicBlock* target) { Goto(target, NULL, false); } void AddLeaveInlined(HBasicBlock* block, HValue* return_value, FunctionState* state) { block->AddLeaveInlined(return_value, state, source_position()); } void AddLeaveInlined(HValue* return_value, FunctionState* state) { return AddLeaveInlined(current_block(), return_value, state); } template HInstruction* NewUncasted() { return I::New(zone(), context()); } template I* New() { return I::New(zone(), context()); } template HInstruction* AddUncasted() { return AddInstruction(NewUncasted());} template I* Add() { return AddInstructionTyped(New());} template HInstruction* NewUncasted(P1 p1) { return I::New(zone(), context(), p1); } template I* New(P1 p1) { return I::New(zone(), context(), p1); } template HInstruction* AddUncasted(P1 p1) { HInstruction* result = AddInstruction(NewUncasted(p1)); // Specializations must have their parameters properly casted // to avoid landing here. DCHECK(!result->IsReturn() && !result->IsSimulate() && !result->IsDeoptimize()); return result; } template I* Add(P1 p1) { I* result = AddInstructionTyped(New(p1)); // Specializations must have their parameters properly casted // to avoid landing here. DCHECK(!result->IsReturn() && !result->IsSimulate() && !result->IsDeoptimize()); return result; } template HInstruction* NewUncasted(P1 p1, P2 p2) { return I::New(zone(), context(), p1, p2); } template I* New(P1 p1, P2 p2) { return I::New(zone(), context(), p1, p2); } template HInstruction* AddUncasted(P1 p1, P2 p2) { HInstruction* result = AddInstruction(NewUncasted(p1, p2)); // Specializations must have their parameters properly casted // to avoid landing here. DCHECK(!result->IsSimulate()); return result; } template I* Add(P1 p1, P2 p2) { I* result = AddInstructionTyped(New(p1, p2)); // Specializations must have their parameters properly casted // to avoid landing here. DCHECK(!result->IsSimulate()); return result; } template HInstruction* NewUncasted(P1 p1, P2 p2, P3 p3) { return I::New(zone(), context(), p1, p2, p3); } template I* New(P1 p1, P2 p2, P3 p3) { return I::New(zone(), context(), p1, p2, p3); } template HInstruction* AddUncasted(P1 p1, P2 p2, P3 p3) { return AddInstruction(NewUncasted(p1, p2, p3)); } template I* Add(P1 p1, P2 p2, P3 p3) { return AddInstructionTyped(New(p1, p2, p3)); } template HInstruction* NewUncasted(P1 p1, P2 p2, P3 p3, P4 p4) { return I::New(zone(), context(), p1, p2, p3, p4); } template I* New(P1 p1, P2 p2, P3 p3, P4 p4) { return I::New(zone(), context(), p1, p2, p3, p4); } template HInstruction* AddUncasted(P1 p1, P2 p2, P3 p3, P4 p4) { return AddInstruction(NewUncasted(p1, p2, p3, p4)); } template I* Add(P1 p1, P2 p2, P3 p3, P4 p4) { return AddInstructionTyped(New(p1, p2, p3, p4)); } template HInstruction* NewUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5) { return I::New(zone(), context(), p1, p2, p3, p4, p5); } template I* New(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5) { return I::New(zone(), context(), p1, p2, p3, p4, p5); } template HInstruction* AddUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5) { return AddInstruction(NewUncasted(p1, p2, p3, p4, p5)); } template I* Add(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5) { return AddInstructionTyped(New(p1, p2, p3, p4, p5)); } template HInstruction* NewUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6) { return I::New(zone(), context(), p1, p2, p3, p4, p5, p6); } template I* New(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6) { return I::New(zone(), context(), p1, p2, p3, p4, p5, p6); } template HInstruction* AddUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6) { return AddInstruction(NewUncasted(p1, p2, p3, p4, p5, p6)); } template I* Add(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6) { return AddInstructionTyped(New(p1, p2, p3, p4, p5, p6)); } template HInstruction* NewUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7) { return I::New(zone(), context(), p1, p2, p3, p4, p5, p6, p7); } template I* New(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7) { return I::New(zone(), context(), p1, p2, p3, p4, p5, p6, p7); } template HInstruction* AddUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7) { return AddInstruction(NewUncasted(p1, p2, p3, p4, p5, p6, p7)); } template I* Add(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7) { return AddInstructionTyped(New(p1, p2, p3, p4, p5, p6, p7)); } template HInstruction* NewUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7, P8 p8) { return I::New(zone(), context(), p1, p2, p3, p4, p5, p6, p7, p8); } template I* New(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7, P8 p8) { return I::New(zone(), context(), p1, p2, p3, p4, p5, p6, p7, p8); } template HInstruction* AddUncasted(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7, P8 p8) { return AddInstruction(NewUncasted(p1, p2, p3, p4, p5, p6, p7, p8)); } template I* Add(P1 p1, P2 p2, P3 p3, P4 p4, P5 p5, P6 p6, P7 p7, P8 p8) { return AddInstructionTyped(New(p1, p2, p3, p4, p5, p6, p7, p8)); } void AddSimulate(BailoutId id, RemovableSimulate removable = FIXED_SIMULATE); // When initializing arrays, we'll unfold the loop if the number of elements // is known at compile time and is <= kElementLoopUnrollThreshold. static const int kElementLoopUnrollThreshold = 8; protected: virtual bool BuildGraph() = 0; HBasicBlock* CreateBasicBlock(HEnvironment* env); HBasicBlock* CreateLoopHeaderBlock(); template HValue* BuildDecodeField(HValue* encoded_field) { HValue* mask_value = Add(static_cast(BitFieldClass::kMask)); HValue* masked_field = AddUncasted(Token::BIT_AND, encoded_field, mask_value); return AddUncasted(masked_field, Add(static_cast(BitFieldClass::kShift))); } HValue* BuildGetElementsKind(HValue* object); HValue* BuildCheckHeapObject(HValue* object); HValue* BuildCheckString(HValue* string); HValue* BuildWrapReceiver(HValue* object, HValue* function); // Building common constructs HValue* BuildCheckForCapacityGrow(HValue* object, HValue* elements, ElementsKind kind, HValue* length, HValue* key, bool is_js_array, PropertyAccessType access_type); HValue* BuildCopyElementsOnWrite(HValue* object, HValue* elements, ElementsKind kind, HValue* length); void BuildTransitionElementsKind(HValue* object, HValue* map, ElementsKind from_kind, ElementsKind to_kind, bool is_jsarray); HValue* BuildNumberToString(HValue* object, Type* type); void BuildJSObjectCheck(HValue* receiver, int bit_field_mask); // Checks a key value that's being used for a keyed element access context. If // the key is a index, i.e. a smi or a number in a unique string with a cached // numeric value, the "true" of the continuation is joined. Otherwise, // if the key is a name or a unique string, the "false" of the continuation is // joined. Otherwise, a deoptimization is triggered. In both paths of the // continuation, the key is pushed on the top of the environment. void BuildKeyedIndexCheck(HValue* key, HIfContinuation* join_continuation); // Checks the properties of an object if they are in dictionary case, in which // case "true" of continuation is taken, otherwise the "false" void BuildTestForDictionaryProperties(HValue* object, HIfContinuation* continuation); void BuildNonGlobalObjectCheck(HValue* receiver); HValue* BuildKeyedLookupCacheHash(HValue* object, HValue* key); HValue* BuildUncheckedDictionaryElementLoad(HValue* receiver, HValue* elements, HValue* key, HValue* hash); HValue* BuildRegExpConstructResult(HValue* length, HValue* index, HValue* input); // Allocates a new object according with the given allocation properties. HAllocate* BuildAllocate(HValue* object_size, HType type, InstanceType instance_type, HAllocationMode allocation_mode); // Computes the sum of two string lengths, taking care of overflow handling. HValue* BuildAddStringLengths(HValue* left_length, HValue* right_length); // Creates a cons string using the two input strings. HValue* BuildCreateConsString(HValue* length, HValue* left, HValue* right, HAllocationMode allocation_mode); // Copies characters from one sequential string to another. void BuildCopySeqStringChars(HValue* src, HValue* src_offset, String::Encoding src_encoding, HValue* dst, HValue* dst_offset, String::Encoding dst_encoding, HValue* length); // Align an object size to object alignment boundary HValue* BuildObjectSizeAlignment(HValue* unaligned_size, int header_size); // Both operands are non-empty strings. HValue* BuildUncheckedStringAdd(HValue* left, HValue* right, HAllocationMode allocation_mode); // Add two strings using allocation mode, validating type feedback. HValue* BuildStringAdd(HValue* left, HValue* right, HAllocationMode allocation_mode); HInstruction* BuildUncheckedMonomorphicElementAccess( HValue* checked_object, HValue* key, HValue* val, bool is_js_array, ElementsKind elements_kind, PropertyAccessType access_type, LoadKeyedHoleMode load_mode, KeyedAccessStoreMode store_mode); HInstruction* AddElementAccess( HValue* elements, HValue* checked_key, HValue* val, HValue* dependency, ElementsKind elements_kind, PropertyAccessType access_type, LoadKeyedHoleMode load_mode = NEVER_RETURN_HOLE); HInstruction* AddLoadStringInstanceType(HValue* string); HInstruction* AddLoadStringLength(HValue* string); HStoreNamedField* AddStoreMapConstant(HValue* object, Handle map) { return Add(object, HObjectAccess::ForMap(), Add(map)); } HLoadNamedField* AddLoadMap(HValue* object, HValue* dependency = NULL); HLoadNamedField* AddLoadElements(HValue* object, HValue* dependency = NULL); bool MatchRotateRight(HValue* left, HValue* right, HValue** operand, HValue** shift_amount); HValue* BuildBinaryOperation(Token::Value op, HValue* left, HValue* right, Type* left_type, Type* right_type, Type* result_type, Maybe fixed_right_arg, HAllocationMode allocation_mode); HLoadNamedField* AddLoadFixedArrayLength(HValue *object, HValue *dependency = NULL); HLoadNamedField* AddLoadArrayLength(HValue *object, ElementsKind kind, HValue *dependency = NULL); HValue* AddLoadJSBuiltin(Builtins::JavaScript builtin); HValue* EnforceNumberType(HValue* number, Type* expected); HValue* TruncateToNumber(HValue* value, Type** expected); void FinishExitWithHardDeoptimization(const char* reason); void AddIncrementCounter(StatsCounter* counter); class IfBuilder FINAL { public: // If using this constructor, Initialize() must be called explicitly! IfBuilder(); explicit IfBuilder(HGraphBuilder* builder); IfBuilder(HGraphBuilder* builder, HIfContinuation* continuation); ~IfBuilder() { if (!finished_) End(); } void Initialize(HGraphBuilder* builder); template Condition* If(HValue *p) { Condition* compare = builder()->New(p); AddCompare(compare); return compare; } template Condition* If(HValue* p1, P2 p2) { Condition* compare = builder()->New(p1, p2); AddCompare(compare); return compare; } template Condition* If(HValue* p1, P2 p2, P3 p3) { Condition* compare = builder()->New(p1, p2, p3); AddCompare(compare); return compare; } template Condition* IfNot(HValue* p) { Condition* compare = If(p); compare->Not(); return compare; } template Condition* IfNot(HValue* p1, P2 p2) { Condition* compare = If(p1, p2); compare->Not(); return compare; } template Condition* IfNot(HValue* p1, P2 p2, P3 p3) { Condition* compare = If(p1, p2, p3); compare->Not(); return compare; } template Condition* OrIf(HValue *p) { Or(); return If(p); } template Condition* OrIf(HValue* p1, P2 p2) { Or(); return If(p1, p2); } template Condition* OrIf(HValue* p1, P2 p2, P3 p3) { Or(); return If(p1, p2, p3); } template Condition* AndIf(HValue *p) { And(); return If(p); } template Condition* AndIf(HValue* p1, P2 p2) { And(); return If(p1, p2); } template Condition* AndIf(HValue* p1, P2 p2, P3 p3) { And(); return If(p1, p2, p3); } void Or(); void And(); // Captures the current state of this IfBuilder in the specified // continuation and ends this IfBuilder. void CaptureContinuation(HIfContinuation* continuation); // Joins the specified continuation from this IfBuilder and ends this // IfBuilder. This appends a Goto instruction from the true branch of // this IfBuilder to the true branch of the continuation unless the // true branch of this IfBuilder is already finished. And vice versa // for the false branch. // // The basic idea is as follows: You have several nested IfBuilder's // that you want to join based on two possible outcomes (i.e. success // and failure, or whatever). You can do this easily using this method // now, for example: // // HIfContinuation cont(graph()->CreateBasicBlock(), // graph()->CreateBasicBlock()); // ... // IfBuilder if_whatever(this); // if_whatever.If(arg); // if_whatever.Then(); // ... // if_whatever.Else(); // ... // if_whatever.JoinContinuation(&cont); // ... // IfBuilder if_something(this); // if_something.If(arg1, arg2); // if_something.Then(); // ... // if_something.Else(); // ... // if_something.JoinContinuation(&cont); // ... // IfBuilder if_finally(this, &cont); // if_finally.Then(); // // continues after then code of if_whatever or if_something. // ... // if_finally.Else(); // // continues after else code of if_whatever or if_something. // ... // if_finally.End(); void JoinContinuation(HIfContinuation* continuation); void Then(); void Else(); void End(); void Deopt(const char* reason); void ThenDeopt(const char* reason) { Then(); Deopt(reason); } void ElseDeopt(const char* reason) { Else(); Deopt(reason); } void Return(HValue* value); private: void InitializeDontCreateBlocks(HGraphBuilder* builder); HControlInstruction* AddCompare(HControlInstruction* compare); HGraphBuilder* builder() const { DCHECK(builder_ != NULL); // Have you called "Initialize"? return builder_; } void AddMergeAtJoinBlock(bool deopt); void Finish(); void Finish(HBasicBlock** then_continuation, HBasicBlock** else_continuation); class MergeAtJoinBlock : public ZoneObject { public: MergeAtJoinBlock(HBasicBlock* block, bool deopt, MergeAtJoinBlock* next) : block_(block), deopt_(deopt), next_(next) {} HBasicBlock* block_; bool deopt_; MergeAtJoinBlock* next_; }; HGraphBuilder* builder_; bool finished_ : 1; bool did_then_ : 1; bool did_else_ : 1; bool did_else_if_ : 1; bool did_and_ : 1; bool did_or_ : 1; bool captured_ : 1; bool needs_compare_ : 1; bool pending_merge_block_ : 1; HBasicBlock* first_true_block_; HBasicBlock* first_false_block_; HBasicBlock* split_edge_merge_block_; MergeAtJoinBlock* merge_at_join_blocks_; int normal_merge_at_join_block_count_; int deopt_merge_at_join_block_count_; }; class LoopBuilder FINAL { public: enum Direction { kPreIncrement, kPostIncrement, kPreDecrement, kPostDecrement, kWhileTrue }; explicit LoopBuilder(HGraphBuilder* builder); // while (true) {...} LoopBuilder(HGraphBuilder* builder, HValue* context, Direction direction); LoopBuilder(HGraphBuilder* builder, HValue* context, Direction direction, HValue* increment_amount); ~LoopBuilder() { DCHECK(finished_); } HValue* BeginBody( HValue* initial, HValue* terminating, Token::Value token); void BeginBody(int drop_count); void Break(); void EndBody(); private: void Initialize(HGraphBuilder* builder, HValue* context, Direction direction, HValue* increment_amount); Zone* zone() { return builder_->zone(); } HGraphBuilder* builder_; HValue* context_; HValue* increment_amount_; HInstruction* increment_; HPhi* phi_; HBasicBlock* header_block_; HBasicBlock* body_block_; HBasicBlock* exit_block_; HBasicBlock* exit_trampoline_block_; Direction direction_; bool finished_; }; template void DeoptimizeIf(P1 p1, char* const reason) { IfBuilder builder(this); builder.If(p1); builder.ThenDeopt(reason); } template void DeoptimizeIf(P1 p1, P2 p2, const char* reason) { IfBuilder builder(this); builder.If (p1, p2); builder.ThenDeopt(reason); } template void DeoptimizeIf(P1 p1, P2 p2, P3 p3, const char* reason) { IfBuilder builder(this); builder.If (p1, p2, p3); builder.ThenDeopt(reason); } HValue* BuildNewElementsCapacity(HValue* old_capacity); class JSArrayBuilder FINAL { public: JSArrayBuilder(HGraphBuilder* builder, ElementsKind kind, HValue* allocation_site_payload, HValue* constructor_function, AllocationSiteOverrideMode override_mode); JSArrayBuilder(HGraphBuilder* builder, ElementsKind kind, HValue* constructor_function = NULL); enum FillMode { DONT_FILL_WITH_HOLE, FILL_WITH_HOLE }; ElementsKind kind() { return kind_; } HAllocate* elements_location() { return elements_location_; } HAllocate* AllocateEmptyArray(); HAllocate* AllocateArray(HValue* capacity, HValue* length_field, FillMode fill_mode = FILL_WITH_HOLE); // Use these allocators when capacity could be unknown at compile time // but its limit is known. For constant |capacity| the value of // |capacity_upper_bound| is ignored and the actual |capacity| // value is used as an upper bound. HAllocate* AllocateArray(HValue* capacity, int capacity_upper_bound, HValue* length_field, FillMode fill_mode = FILL_WITH_HOLE); HAllocate* AllocateArray(HValue* capacity, HConstant* capacity_upper_bound, HValue* length_field, FillMode fill_mode = FILL_WITH_HOLE); HValue* GetElementsLocation() { return elements_location_; } HValue* EmitMapCode(); private: Zone* zone() const { return builder_->zone(); } int elements_size() const { return IsFastDoubleElementsKind(kind_) ? kDoubleSize : kPointerSize; } HGraphBuilder* builder() { return builder_; } HGraph* graph() { return builder_->graph(); } int initial_capacity() { STATIC_ASSERT(JSArray::kPreallocatedArrayElements > 0); return JSArray::kPreallocatedArrayElements; } HValue* EmitInternalMapCode(); HGraphBuilder* builder_; ElementsKind kind_; AllocationSiteMode mode_; HValue* allocation_site_payload_; HValue* constructor_function_; HAllocate* elements_location_; }; HValue* BuildAllocateArrayFromLength(JSArrayBuilder* array_builder, HValue* length_argument); HValue* BuildCalculateElementsSize(ElementsKind kind, HValue* capacity); HAllocate* AllocateJSArrayObject(AllocationSiteMode mode); HConstant* EstablishElementsAllocationSize(ElementsKind kind, int capacity); HAllocate* BuildAllocateElements(ElementsKind kind, HValue* size_in_bytes); void BuildInitializeElementsHeader(HValue* elements, ElementsKind kind, HValue* capacity); HValue* BuildAllocateElementsAndInitializeElementsHeader(ElementsKind kind, HValue* capacity); // |array| must have been allocated with enough room for // 1) the JSArray and 2) an AllocationMemento if mode requires it. // If the |elements| value provided is NULL then the array elements storage // is initialized with empty array. void BuildJSArrayHeader(HValue* array, HValue* array_map, HValue* elements, AllocationSiteMode mode, ElementsKind elements_kind, HValue* allocation_site_payload, HValue* length_field); HValue* BuildGrowElementsCapacity(HValue* object, HValue* elements, ElementsKind kind, ElementsKind new_kind, HValue* length, HValue* new_capacity); void BuildFillElementsWithValue(HValue* elements, ElementsKind elements_kind, HValue* from, HValue* to, HValue* value); void BuildFillElementsWithHole(HValue* elements, ElementsKind elements_kind, HValue* from, HValue* to); void BuildCopyElements(HValue* from_elements, ElementsKind from_elements_kind, HValue* to_elements, ElementsKind to_elements_kind, HValue* length, HValue* capacity); HValue* BuildCloneShallowArrayCow(HValue* boilerplate, HValue* allocation_site, AllocationSiteMode mode, ElementsKind kind); HValue* BuildCloneShallowArrayEmpty(HValue* boilerplate, HValue* allocation_site, AllocationSiteMode mode); HValue* BuildCloneShallowArrayNonEmpty(HValue* boilerplate, HValue* allocation_site, AllocationSiteMode mode, ElementsKind kind); HValue* BuildElementIndexHash(HValue* index); void BuildCompareNil( HValue* value, Type* type, HIfContinuation* continuation); void BuildCreateAllocationMemento(HValue* previous_object, HValue* previous_object_size, HValue* payload); HInstruction* BuildConstantMapCheck(Handle constant); HInstruction* BuildCheckPrototypeMaps(Handle prototype, Handle holder); HInstruction* BuildGetNativeContext(HValue* closure); HInstruction* BuildGetNativeContext(); HInstruction* BuildGetArrayFunction(); protected: void SetSourcePosition(int position) { DCHECK(position != RelocInfo::kNoPosition); position_.set_position(position - start_position_); } void EnterInlinedSource(int start_position, int id) { if (FLAG_hydrogen_track_positions) { start_position_ = start_position; position_.set_inlining_id(id); } } // Convert the given absolute offset from the start of the script to // the HSourcePosition assuming that this position corresponds to the // same function as current position_. HSourcePosition ScriptPositionToSourcePosition(int position) { HSourcePosition pos = position_; pos.set_position(position - start_position_); return pos; } HSourcePosition source_position() { return position_; } void set_source_position(HSourcePosition position) { position_ = position; } template void BuildArrayBufferViewInitialization(HValue* obj, HValue* buffer, HValue* byte_offset, HValue* byte_length); private: HGraphBuilder(); template I* AddInstructionTyped(I* instr) { return I::cast(AddInstruction(instr)); } CompilationInfo* info_; HGraph* graph_; HBasicBlock* current_block_; Scope* scope_; HSourcePosition position_; int start_position_; }; template<> inline HDeoptimize* HGraphBuilder::Add( const char* reason, Deoptimizer::BailoutType type) { if (type == Deoptimizer::SOFT) { isolate()->counters()->soft_deopts_requested()->Increment(); if (FLAG_always_opt) return NULL; } if (current_block()->IsDeoptimizing()) return NULL; HBasicBlock* after_deopt_block = CreateBasicBlock( current_block()->last_environment()); HDeoptimize* instr = New(reason, type, after_deopt_block); if (type == Deoptimizer::SOFT) { isolate()->counters()->soft_deopts_inserted()->Increment(); } FinishCurrentBlock(instr); set_current_block(after_deopt_block); return instr; } template<> inline HInstruction* HGraphBuilder::AddUncasted( const char* reason, Deoptimizer::BailoutType type) { return Add(reason, type); } template<> inline HSimulate* HGraphBuilder::Add( BailoutId id, RemovableSimulate removable) { HSimulate* instr = current_block()->CreateSimulate(id, removable); AddInstruction(instr); return instr; } template<> inline HSimulate* HGraphBuilder::Add( BailoutId id) { return Add(id, FIXED_SIMULATE); } template<> inline HInstruction* HGraphBuilder::AddUncasted(BailoutId id) { return Add(id, FIXED_SIMULATE); } template<> inline HReturn* HGraphBuilder::Add(HValue* value) { int num_parameters = graph()->info()->num_parameters(); HValue* params = AddUncasted(num_parameters); HReturn* return_instruction = New(value, params); FinishExitCurrentBlock(return_instruction); return return_instruction; } template<> inline HReturn* HGraphBuilder::Add(HConstant* value) { return Add(static_cast(value)); } template<> inline HInstruction* HGraphBuilder::AddUncasted(HValue* value) { return Add(value); } template<> inline HInstruction* HGraphBuilder::AddUncasted(HConstant* value) { return Add(value); } template<> inline HCallRuntime* HGraphBuilder::Add( Handle name, const Runtime::Function* c_function, int argument_count) { HCallRuntime* instr = New(name, c_function, argument_count); if (graph()->info()->IsStub()) { // When compiling code stubs, we don't want to save all double registers // upon entry to the stub, but instead have the call runtime instruction // save the double registers only on-demand (in the fallback case). instr->set_save_doubles(kSaveFPRegs); } AddInstruction(instr); return instr; } template<> inline HInstruction* HGraphBuilder::AddUncasted( Handle name, const Runtime::Function* c_function, int argument_count) { return Add(name, c_function, argument_count); } template<> inline HContext* HGraphBuilder::New() { return HContext::New(zone()); } template<> inline HInstruction* HGraphBuilder::NewUncasted() { return New(); } class HOptimizedGraphBuilder : public HGraphBuilder, public AstVisitor { public: // A class encapsulating (lazily-allocated) break and continue blocks for // a breakable statement. Separated from BreakAndContinueScope so that it // can have a separate lifetime. class BreakAndContinueInfo FINAL BASE_EMBEDDED { public: explicit BreakAndContinueInfo(BreakableStatement* target, Scope* scope, int drop_extra = 0) : target_(target), break_block_(NULL), continue_block_(NULL), scope_(scope), drop_extra_(drop_extra) { } BreakableStatement* target() { return target_; } HBasicBlock* break_block() { return break_block_; } void set_break_block(HBasicBlock* block) { break_block_ = block; } HBasicBlock* continue_block() { return continue_block_; } void set_continue_block(HBasicBlock* block) { continue_block_ = block; } Scope* scope() { return scope_; } int drop_extra() { return drop_extra_; } private: BreakableStatement* target_; HBasicBlock* break_block_; HBasicBlock* continue_block_; Scope* scope_; int drop_extra_; }; // A helper class to maintain a stack of current BreakAndContinueInfo // structures mirroring BreakableStatement nesting. class BreakAndContinueScope FINAL BASE_EMBEDDED { public: BreakAndContinueScope(BreakAndContinueInfo* info, HOptimizedGraphBuilder* owner) : info_(info), owner_(owner), next_(owner->break_scope()) { owner->set_break_scope(this); } ~BreakAndContinueScope() { owner_->set_break_scope(next_); } BreakAndContinueInfo* info() { return info_; } HOptimizedGraphBuilder* owner() { return owner_; } BreakAndContinueScope* next() { return next_; } // Search the break stack for a break or continue target. enum BreakType { BREAK, CONTINUE }; HBasicBlock* Get(BreakableStatement* stmt, BreakType type, Scope** scope, int* drop_extra); private: BreakAndContinueInfo* info_; HOptimizedGraphBuilder* owner_; BreakAndContinueScope* next_; }; explicit HOptimizedGraphBuilder(CompilationInfo* info); virtual bool BuildGraph() OVERRIDE; // Simple accessors. BreakAndContinueScope* break_scope() const { return break_scope_; } void set_break_scope(BreakAndContinueScope* head) { break_scope_ = head; } bool inline_bailout() { return inline_bailout_; } HValue* context() { return environment()->context(); } HOsrBuilder* osr() const { return osr_; } void Bailout(BailoutReason reason); HBasicBlock* CreateJoin(HBasicBlock* first, HBasicBlock* second, BailoutId join_id); FunctionState* function_state() const { return function_state_; } void VisitDeclarations(ZoneList* declarations); void* operator new(size_t size, Zone* zone) { return zone->New(static_cast(size)); } void operator delete(void* pointer, Zone* zone) { } void operator delete(void* pointer) { } DEFINE_AST_VISITOR_SUBCLASS_MEMBERS(); protected: // Type of a member function that generates inline code for a native function. typedef void (HOptimizedGraphBuilder::*InlineFunctionGenerator) (CallRuntime* call); // Forward declarations for inner scope classes. class SubgraphScope; static const InlineFunctionGenerator kInlineFunctionGenerators[]; static const int kMaxCallPolymorphism = 4; static const int kMaxLoadPolymorphism = 4; static const int kMaxStorePolymorphism = 4; // Even in the 'unlimited' case we have to have some limit in order not to // overflow the stack. static const int kUnlimitedMaxInlinedSourceSize = 100000; static const int kUnlimitedMaxInlinedNodes = 10000; static const int kUnlimitedMaxInlinedNodesCumulative = 10000; // Maximum depth and total number of elements and properties for literal // graphs to be considered for fast deep-copying. static const int kMaxFastLiteralDepth = 3; static const int kMaxFastLiteralProperties = 8; // Simple accessors. void set_function_state(FunctionState* state) { function_state_ = state; } AstContext* ast_context() const { return ast_context_; } void set_ast_context(AstContext* context) { ast_context_ = context; } // Accessors forwarded to the function state. CompilationInfo* current_info() const { return function_state()->compilation_info(); } AstContext* call_context() const { return function_state()->call_context(); } HBasicBlock* function_return() const { return function_state()->function_return(); } TestContext* inlined_test_context() const { return function_state()->test_context(); } void ClearInlinedTestContext() { function_state()->ClearInlinedTestContext(); } StrictMode function_strict_mode() { return function_state()->compilation_info()->strict_mode(); } // Generators for inline runtime functions. #define INLINE_FUNCTION_GENERATOR_DECLARATION(Name, argc, ressize) \ void Generate##Name(CallRuntime* call); INLINE_FUNCTION_LIST(INLINE_FUNCTION_GENERATOR_DECLARATION) INLINE_OPTIMIZED_FUNCTION_LIST(INLINE_FUNCTION_GENERATOR_DECLARATION) #undef INLINE_FUNCTION_GENERATOR_DECLARATION void VisitDelete(UnaryOperation* expr); void VisitVoid(UnaryOperation* expr); void VisitTypeof(UnaryOperation* expr); void VisitNot(UnaryOperation* expr); void VisitComma(BinaryOperation* expr); void VisitLogicalExpression(BinaryOperation* expr); void VisitArithmeticExpression(BinaryOperation* expr); bool PreProcessOsrEntry(IterationStatement* statement); void VisitLoopBody(IterationStatement* stmt, HBasicBlock* loop_entry); // Create a back edge in the flow graph. body_exit is the predecessor // block and loop_entry is the successor block. loop_successor is the // block where control flow exits the loop normally (e.g., via failure of // the condition) and break_block is the block where control flow breaks // from the loop. All blocks except loop_entry can be NULL. The return // value is the new successor block which is the join of loop_successor // and break_block, or NULL. HBasicBlock* CreateLoop(IterationStatement* statement, HBasicBlock* loop_entry, HBasicBlock* body_exit, HBasicBlock* loop_successor, HBasicBlock* break_block); // Build a loop entry HBasicBlock* BuildLoopEntry(); // Builds a loop entry respectful of OSR requirements HBasicBlock* BuildLoopEntry(IterationStatement* statement); HBasicBlock* JoinContinue(IterationStatement* statement, HBasicBlock* exit_block, HBasicBlock* continue_block); HValue* Top() const { return environment()->Top(); } void Drop(int n) { environment()->Drop(n); } void Bind(Variable* var, HValue* value) { environment()->Bind(var, value); } bool IsEligibleForEnvironmentLivenessAnalysis(Variable* var, int index, HValue* value, HEnvironment* env) { if (!FLAG_analyze_environment_liveness) return false; // |this| and |arguments| are always live; zapping parameters isn't // safe because function.arguments can inspect them at any time. return !var->is_this() && !var->is_arguments() && !value->IsArgumentsObject() && env->is_local_index(index); } void BindIfLive(Variable* var, HValue* value) { HEnvironment* env = environment(); int index = env->IndexFor(var); env->Bind(index, value); if (IsEligibleForEnvironmentLivenessAnalysis(var, index, value, env)) { HEnvironmentMarker* bind = Add(HEnvironmentMarker::BIND, index); USE(bind); #ifdef DEBUG bind->set_closure(env->closure()); #endif } } HValue* LookupAndMakeLive(Variable* var) { HEnvironment* env = environment(); int index = env->IndexFor(var); HValue* value = env->Lookup(index); if (IsEligibleForEnvironmentLivenessAnalysis(var, index, value, env)) { HEnvironmentMarker* lookup = Add(HEnvironmentMarker::LOOKUP, index); USE(lookup); #ifdef DEBUG lookup->set_closure(env->closure()); #endif } return value; } // The value of the arguments object is allowed in some but not most value // contexts. (It's allowed in all effect contexts and disallowed in all // test contexts.) void VisitForValue(Expression* expr, ArgumentsAllowedFlag flag = ARGUMENTS_NOT_ALLOWED); void VisitForTypeOf(Expression* expr); void VisitForEffect(Expression* expr); void VisitForControl(Expression* expr, HBasicBlock* true_block, HBasicBlock* false_block); // Visit a list of expressions from left to right, each in a value context. void VisitExpressions(ZoneList* exprs); // Remove the arguments from the bailout environment and emit instructions // to push them as outgoing parameters. template HInstruction* PreProcessCall(Instruction* call); void PushArgumentsFromEnvironment(int count); void SetUpScope(Scope* scope); virtual void VisitStatements(ZoneList* statements) OVERRIDE; #define DECLARE_VISIT(type) virtual void Visit##type(type* node) OVERRIDE; AST_NODE_LIST(DECLARE_VISIT) #undef DECLARE_VISIT Type* ToType(Handle map) { return IC::MapToType(map, zone()); } private: // Helpers for flow graph construction. enum GlobalPropertyAccess { kUseCell, kUseGeneric }; GlobalPropertyAccess LookupGlobalProperty(Variable* var, LookupIterator* it, PropertyAccessType access_type); void EnsureArgumentsArePushedForAccess(); bool TryArgumentsAccess(Property* expr); // Try to optimize fun.apply(receiver, arguments) pattern. bool TryCallApply(Call* expr); bool TryHandleArrayCall(Call* expr, HValue* function); bool TryHandleArrayCallNew(CallNew* expr, HValue* function); void BuildArrayCall(Expression* expr, int arguments_count, HValue* function, Handle cell); enum ArrayIndexOfMode { kFirstIndexOf, kLastIndexOf }; HValue* BuildArrayIndexOf(HValue* receiver, HValue* search_element, ElementsKind kind, ArrayIndexOfMode mode); HValue* ImplicitReceiverFor(HValue* function, Handle target); int InliningAstSize(Handle target); bool TryInline(Handle target, int arguments_count, HValue* implicit_return_value, BailoutId ast_id, BailoutId return_id, InliningKind inlining_kind, HSourcePosition position); bool TryInlineCall(Call* expr); bool TryInlineConstruct(CallNew* expr, HValue* implicit_return_value); bool TryInlineGetter(Handle getter, Handle receiver_map, BailoutId ast_id, BailoutId return_id); bool TryInlineSetter(Handle setter, Handle receiver_map, BailoutId id, BailoutId assignment_id, HValue* implicit_return_value); bool TryInlineApply(Handle function, Call* expr, int arguments_count); bool TryInlineBuiltinMethodCall(Call* expr, HValue* receiver, Handle receiver_map); bool TryInlineBuiltinFunctionCall(Call* expr); enum ApiCallType { kCallApiFunction, kCallApiMethod, kCallApiGetter, kCallApiSetter }; bool TryInlineApiMethodCall(Call* expr, HValue* receiver, SmallMapList* receiver_types); bool TryInlineApiFunctionCall(Call* expr, HValue* receiver); bool TryInlineApiGetter(Handle function, Handle receiver_map, BailoutId ast_id); bool TryInlineApiSetter(Handle function, Handle receiver_map, BailoutId ast_id); bool TryInlineApiCall(Handle function, HValue* receiver, SmallMapList* receiver_maps, int argc, BailoutId ast_id, ApiCallType call_type); // If --trace-inlining, print a line of the inlining trace. Inlining // succeeded if the reason string is NULL and failed if there is a // non-NULL reason string. void TraceInline(Handle target, Handle caller, const char* failure_reason); void HandleGlobalVariableAssignment(Variable* var, HValue* value, BailoutId ast_id); void HandlePropertyAssignment(Assignment* expr); void HandleCompoundAssignment(Assignment* expr); void HandlePolymorphicNamedFieldAccess(PropertyAccessType access_type, Expression* expr, BailoutId ast_id, BailoutId return_id, HValue* object, HValue* value, SmallMapList* types, Handle name); HValue* BuildAllocateExternalElements( ExternalArrayType array_type, bool is_zero_byte_offset, HValue* buffer, HValue* byte_offset, HValue* length); HValue* BuildAllocateFixedTypedArray( ExternalArrayType array_type, size_t element_size, ElementsKind fixed_elements_kind, HValue* byte_length, HValue* length); Handle array_function() { return handle(isolate()->native_context()->array_function()); } bool IsCallArrayInlineable(int argument_count, Handle site); void BuildInlinedCallArray(Expression* expression, int argument_count, Handle site); class PropertyAccessInfo { public: PropertyAccessInfo(HOptimizedGraphBuilder* builder, PropertyAccessType access_type, Type* type, Handle name) : lookup_(builder->isolate()), builder_(builder), access_type_(access_type), type_(type), name_(name), field_type_(HType::Tagged()), access_(HObjectAccess::ForMap()) { } // Checkes whether this PropertyAccessInfo can be handled as a monomorphic // load named. It additionally fills in the fields necessary to generate the // lookup code. bool CanAccessMonomorphic(); // Checks whether all types behave uniform when loading name. If all maps // behave the same, a single monomorphic load instruction can be emitted, // guarded by a single map-checks instruction that whether the receiver is // an instance of any of the types. // This method skips the first type in types, assuming that this // PropertyAccessInfo is built for types->first(). bool CanAccessAsMonomorphic(SmallMapList* types); Handle map(); Type* type() const { return type_; } Handle name() const { return name_; } bool IsJSObjectFieldAccessor() { int offset; // unused return Accessors::IsJSObjectFieldAccessor(type_, name_, &offset); } bool GetJSObjectFieldAccess(HObjectAccess* access) { int offset; if (Accessors::IsJSObjectFieldAccessor(type_, name_, &offset)) { if (type_->Is(Type::String())) { DCHECK(String::Equals(isolate()->factory()->length_string(), name_)); *access = HObjectAccess::ForStringLength(); } else if (type_->Is(Type::Array())) { DCHECK(String::Equals(isolate()->factory()->length_string(), name_)); *access = HObjectAccess::ForArrayLength(map()->elements_kind()); } else { *access = HObjectAccess::ForMapAndOffset(map(), offset); } return true; } return false; } bool has_holder() { return !holder_.is_null(); } bool IsLoad() const { return access_type_ == LOAD; } Handle holder() { return holder_; } Handle accessor() { return accessor_; } Handle