third_party/v8/src/interpreter/bytecode-generator.h - cobalt - Git at Google

 // Copyright 2015 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_INTERPRETER_BYTECODE_GENERATOR_H_
 #define V8_INTERPRETER_BYTECODE_GENERATOR_H_

 #include "src/ast/ast.h"
 #include "src/interpreter/bytecode-array-builder.h"
 #include "src/interpreter/bytecode-label.h"
 #include "src/interpreter/bytecode-register.h"
 #include "src/interpreter/bytecodes.h"
 #include "src/objects/feedback-vector.h"
 #include "src/objects/function-kind.h"

 namespace v8 {
 namespace internal {

 class AstNodeSourceRanges;
 class AstStringConstants;
 class BytecodeArray;
 class UnoptimizedCompilationInfo;
 enum class SourceRangeKind;

 namespace interpreter {

 class TopLevelDeclarationsBuilder;
 class LoopBuilder;
 class BlockCoverageBuilder;
 class BytecodeJumpTable;

 class BytecodeGenerator final : public AstVisitor<BytecodeGenerator> {
  public:
   explicit BytecodeGenerator(
       Zone* zone, UnoptimizedCompilationInfo* info,
       const AstStringConstants* ast_string_constants,
       std::vector<FunctionLiteral*>* eager_inner_literals);

   void GenerateBytecode(uintptr_t stack_limit);
   template <typename LocalIsolate>
   Handle<BytecodeArray> FinalizeBytecode(LocalIsolate* isolate,
                                          Handle<Script> script);
   template <typename LocalIsolate>
   Handle<ByteArray> FinalizeSourcePositionTable(LocalIsolate* isolate);

 #ifdef DEBUG
   int CheckBytecodeMatches(BytecodeArray bytecode);
 #endif

 #define DECLARE_VISIT(type) void Visit##type(type* node);
   AST_NODE_LIST(DECLARE_VISIT)
 #undef DECLARE_VISIT

   // Visiting function for declarations list and statements are overridden.
   void VisitModuleDeclarations(Declaration::List* declarations);
   void VisitGlobalDeclarations(Declaration::List* declarations);
   void VisitDeclarations(Declaration::List* declarations);
   void VisitStatements(const ZonePtrList<Statement>* statments);

  private:
   class AccumulatorPreservingScope;
   class ContextScope;
   class ControlScope;
   class ControlScopeForBreakable;
   class ControlScopeForIteration;
   class ControlScopeForTopLevel;
   class ControlScopeForTryCatch;
   class ControlScopeForTryFinally;
   class CurrentScope;
   class EffectResultScope;
   class ExpressionResultScope;
   class FeedbackSlotCache;
   class IteratorRecord;
   class LoopScope;
   class NaryCodeCoverageSlots;
   class OptionalChainNullLabelScope;
   class RegisterAllocationScope;
   class TestResultScope;
   class TopLevelDeclarationsBuilder;
   class ValueResultScope;

   using ToBooleanMode = BytecodeArrayBuilder::ToBooleanMode;

   enum class TestFallthrough { kThen, kElse, kNone };
   enum class TypeHint { kAny, kBoolean, kString };
   enum class AccumulatorPreservingMode { kNone, kPreserve };

   // An assignment has to evaluate its LHS before its RHS, but has to assign to
   // the LHS after both evaluations are done. This class stores the data
   // computed in the LHS evaulation that has to live across the RHS evaluation,
   // and is used in the actual LHS assignment.
   class AssignmentLhsData {
    public:
     static AssignmentLhsData NonProperty(Expression* expr);
     static AssignmentLhsData NamedProperty(Expression* object_expr,
                                            Register object,
                                            const AstRawString* name);
     static AssignmentLhsData KeyedProperty(Register object, Register key);
     static AssignmentLhsData PrivateMethodOrAccessor(AssignType type,
                                                      Property* property);
     static AssignmentLhsData NamedSuperProperty(
         RegisterList super_property_args);
     static AssignmentLhsData KeyedSuperProperty(
         RegisterList super_property_args);

     AssignType assign_type() const { return assign_type_; }
     Expression* expr() const {
       DCHECK(assign_type_ == NON_PROPERTY || assign_type_ == PRIVATE_METHOD ||
              assign_type_ == PRIVATE_GETTER_ONLY ||
              assign_type_ == PRIVATE_SETTER_ONLY ||
              assign_type_ == PRIVATE_GETTER_AND_SETTER);
       return expr_;
     }
     Expression* object_expr() const {
       DCHECK_EQ(assign_type_, NAMED_PROPERTY);
       return object_expr_;
     }
     Register object() const {
       DCHECK(assign_type_ == NAMED_PROPERTY || assign_type_ == KEYED_PROPERTY);
       return object_;
     }
     Register key() const {
       DCHECK(assign_type_ == KEYED_PROPERTY);
       return key_;
     }
     const AstRawString* name() const {
       DCHECK(assign_type_ == NAMED_PROPERTY);
       return name_;
     }
     RegisterList super_property_args() const {
       DCHECK(assign_type_ == NAMED_SUPER_PROPERTY ||
              assign_type_ == KEYED_SUPER_PROPERTY);
       return super_property_args_;
     }

    private:
     AssignmentLhsData(AssignType assign_type, Expression* expr,
                       RegisterList super_property_args, Register object,
                       Register key, Expression* object_expr,
                       const AstRawString* name)
         : assign_type_(assign_type),
           expr_(expr),
           super_property_args_(super_property_args),
           object_(object),
           key_(key),
           object_expr_(object_expr),
           name_(name) {}

     AssignType assign_type_;

     // Different assignment types use different fields:
     //
     // NON_PROPERTY: expr
     // NAMED_PROPERTY: object_expr, object, name
     // KEYED_PROPERTY, PRIVATE_METHOD: object, key
     // NAMED_SUPER_PROPERTY: super_property_args
     // KEYED_SUPER_PROPERT:  super_property_args
     Expression* expr_;
     RegisterList super_property_args_;
     Register object_;
     Register key_;
     Expression* object_expr_;
     const AstRawString* name_;
   };

   void GenerateBytecodeBody();
   template <typename LocalIsolate>
   void AllocateDeferredConstants(LocalIsolate* isolate, Handle<Script> script);

   DEFINE_AST_VISITOR_SUBCLASS_MEMBERS();

   // Dispatched from VisitBinaryOperation.
   void VisitArithmeticExpression(BinaryOperation* binop);
   void VisitCommaExpression(BinaryOperation* binop);
   void VisitLogicalOrExpression(BinaryOperation* binop);
   void VisitLogicalAndExpression(BinaryOperation* binop);
   void VisitNullishExpression(BinaryOperation* binop);

   // Dispatched from VisitNaryOperation.
   void VisitNaryArithmeticExpression(NaryOperation* expr);
   void VisitNaryCommaExpression(NaryOperation* expr);
   void VisitNaryLogicalOrExpression(NaryOperation* expr);
   void VisitNaryLogicalAndExpression(NaryOperation* expr);
   void VisitNaryNullishExpression(NaryOperation* expr);

   // Dispatched from VisitUnaryOperation.
   void VisitVoid(UnaryOperation* expr);
   void VisitTypeOf(UnaryOperation* expr);
   void VisitNot(UnaryOperation* expr);
   void VisitDelete(UnaryOperation* expr);

   // Visits a typeof expression for the value on which to perform the typeof.
   void VisitForTypeOfValue(Expression* expr);

   // Used by flow control routines to evaluate loop condition.
   void VisitCondition(Expression* expr);

   // Visit the arguments expressions in |args| and store them in |args_regs|,
   // growing |args_regs| for each argument visited.
   void VisitArguments(const ZonePtrList<Expression>* args,
                       RegisterList* arg_regs);

   // Visit a keyed super property load. The optional
   // |opt_receiver_out| register will have the receiver stored to it
   // if it's a valid register. The loaded value is placed in the
   // accumulator.
   void VisitKeyedSuperPropertyLoad(Property* property,
                                    Register opt_receiver_out);

   // Visit a named super property load. The optional
   // |opt_receiver_out| register will have the receiver stored to it
   // if it's a valid register. The loaded value is placed in the
   // accumulator.
   void VisitNamedSuperPropertyLoad(Property* property,
                                    Register opt_receiver_out);

   void VisitPropertyLoad(Register obj, Property* expr);
   void VisitPropertyLoadForRegister(Register obj, Property* expr,
                                     Register destination);

   AssignmentLhsData PrepareAssignmentLhs(
       Expression* lhs, AccumulatorPreservingMode accumulator_preserving_mode =
                            AccumulatorPreservingMode::kNone);
   void BuildAssignment(const AssignmentLhsData& data, Token::Value op,
                        LookupHoistingMode lookup_hoisting_mode);

   void BuildThisVariableLoad();

   void BuildDeclareCall(Runtime::FunctionId id);

   Expression* GetDestructuringDefaultValue(Expression** target);
   void BuildDestructuringArrayAssignment(
       ArrayLiteral* pattern, Token::Value op,
       LookupHoistingMode lookup_hoisting_mode);
   void BuildDestructuringObjectAssignment(
       ObjectLiteral* pattern, Token::Value op,
       LookupHoistingMode lookup_hoisting_mode);

   void BuildLoadNamedProperty(const Expression* object_expr, Register object,
                               const AstRawString* name);
   void BuildStoreNamedProperty(const Expression* object_expr, Register object,
                                const AstRawString* name);

   void BuildVariableLoad(Variable* variable, HoleCheckMode hole_check_mode,
                          TypeofMode typeof_mode = NOT_INSIDE_TYPEOF);
   void BuildVariableLoadForAccumulatorValue(
       Variable* variable, HoleCheckMode hole_check_mode,
       TypeofMode typeof_mode = NOT_INSIDE_TYPEOF);
   void BuildVariableAssignment(
       Variable* variable, Token::Value op, HoleCheckMode hole_check_mode,
       LookupHoistingMode lookup_hoisting_mode = LookupHoistingMode::kNormal);
   void BuildLiteralCompareNil(Token::Value compare_op,
                               BytecodeArrayBuilder::NilValue nil);
   void BuildReturn(int source_position = kNoSourcePosition);
   void BuildAsyncReturn(int source_position = kNoSourcePosition);
   void BuildAsyncGeneratorReturn();
   void BuildReThrow();
   void BuildHoleCheckForVariableAssignment(Variable* variable, Token::Value op);
   void BuildThrowIfHole(Variable* variable);

   void BuildNewLocalActivationContext();
   void BuildLocalActivationContextInitialization();
   void BuildNewLocalBlockContext(Scope* scope);
   void BuildNewLocalCatchContext(Scope* scope);
   void BuildNewLocalWithContext(Scope* scope);

   void BuildGeneratorPrologue();
   void BuildSuspendPoint(int position);

   void BuildAwait(int position = kNoSourcePosition);
   void BuildAwait(Expression* await_expr);

   void BuildFinalizeIteration(IteratorRecord iterator, Register done,
                               Register iteration_continuation_token);

   void BuildGetIterator(IteratorType hint);

   // Create an IteratorRecord with pre-allocated registers holding the next
   // method and iterator object.
   IteratorRecord BuildGetIteratorRecord(Register iterator_next,
                                         Register iterator_object,
                                         IteratorType hint);

   // Create an IteratorRecord allocating new registers to hold the next method
   // and iterator object.
   IteratorRecord BuildGetIteratorRecord(IteratorType hint);
   void BuildIteratorNext(const IteratorRecord& iterator, Register next_result);
   void BuildIteratorClose(const IteratorRecord& iterator,
                           Expression* expr = nullptr);
   void BuildCallIteratorMethod(Register iterator, const AstRawString* method,
                                RegisterList receiver_and_args,
                                BytecodeLabel* if_called,
                                BytecodeLabels* if_notcalled);

   void BuildFillArrayWithIterator(IteratorRecord iterator, Register array,
                                   Register index, Register value,
                                   FeedbackSlot next_value_slot,
                                   FeedbackSlot next_done_slot,
                                   FeedbackSlot index_slot,
                                   FeedbackSlot element_slot);
   // Create Array literals. |expr| can be nullptr, but if provided,
   // a boilerplate will be used to create an initial array for elements
   // before the first spread.
   void BuildCreateArrayLiteral(const ZonePtrList<Expression>* elements,
                                ArrayLiteral* expr);
   void BuildCreateObjectLiteral(Register literal, uint8_t flags, size_t entry);
   void AllocateTopLevelRegisters();
   void VisitArgumentsObject(Variable* variable);
   void VisitRestArgumentsArray(Variable* rest);
   void VisitCallSuper(Call* call);
   void BuildInvalidPropertyAccess(MessageTemplate tmpl, Property* property);
   void BuildPrivateBrandCheck(Property* property, Register object,
                               MessageTemplate tmpl);
   void BuildPrivateGetterAccess(Register obj, Register access_pair);
   void BuildPrivateSetterAccess(Register obj, Register access_pair,
                                 Register value);
   void BuildPrivateMethods(ClassLiteral* expr, bool is_static,
                            Register home_object);
   void BuildClassLiteral(ClassLiteral* expr, Register name);
   void VisitClassLiteral(ClassLiteral* expr, Register name);
   void VisitNewTargetVariable(Variable* variable);
   void VisitThisFunctionVariable(Variable* variable);
   void BuildPrivateBrandInitialization(Register receiver);
   void BuildInstanceMemberInitialization(Register constructor,
                                          Register instance);
   void BuildGeneratorObjectVariableInitialization();
   void VisitBlockDeclarationsAndStatements(Block* stmt);
   void VisitSetHomeObject(Register value, Register home_object,
                           LiteralProperty* property);
   void VisitLiteralAccessor(Register home_object, LiteralProperty* property,
                             Register value_out);
   void VisitForInAssignment(Expression* expr);
   void VisitModuleNamespaceImports();

   // Visit a logical OR/AND within a test context, rewiring the jumps based
   // on the expression values.
   void VisitLogicalTest(Token::Value token, Expression* left, Expression* right,
                         int right_coverage_slot);
   void VisitNaryLogicalTest(Token::Value token, NaryOperation* expr,
                             const NaryCodeCoverageSlots* coverage_slots);

   // Visit a (non-RHS) test for a logical op, which falls through if the test
   // fails or jumps to the appropriate labels if it succeeds.
   void VisitLogicalTestSubExpression(Token::Value token, Expression* expr,
                                      BytecodeLabels* then_labels,
                                      BytecodeLabels* else_labels,
                                      int coverage_slot);

   // Helpers for binary and nary logical op value expressions.
   bool VisitLogicalOrSubExpression(Expression* expr, BytecodeLabels* end_labels,
                                    int coverage_slot);
   bool VisitLogicalAndSubExpression(Expression* expr,
                                     BytecodeLabels* end_labels,
                                     int coverage_slot);

   // Helper for binary and nary nullish op value expressions.
   bool VisitNullishSubExpression(Expression* expr, BytecodeLabels* end_labels,
                                  int coverage_slot);

   // Visit the body of a loop iteration.
   void VisitIterationBody(IterationStatement* stmt, LoopBuilder* loop_builder);

   // Visit a statement and switch scopes, the context is in the accumulator.
   void VisitInScope(Statement* stmt, Scope* scope);

   void BuildPushUndefinedIntoRegisterList(RegisterList* reg_list);

   void BuildLoadPropertyKey(LiteralProperty* property, Register out_reg);

   int AllocateBlockCoverageSlotIfEnabled(AstNode* node, SourceRangeKind kind);
   int AllocateNaryBlockCoverageSlotIfEnabled(NaryOperation* node, size_t index);

   void BuildIncrementBlockCoverageCounterIfEnabled(AstNode* node,
                                                    SourceRangeKind kind);
   void BuildIncrementBlockCoverageCounterIfEnabled(int coverage_array_slot);

   void BuildTest(ToBooleanMode mode, BytecodeLabels* then_labels,
                  BytecodeLabels* else_labels, TestFallthrough fallthrough);

   template <typename TryBodyFunc, typename CatchBodyFunc>
   void BuildTryCatch(TryBodyFunc try_body_func, CatchBodyFunc catch_body_func,
                      HandlerTable::CatchPrediction catch_prediction,
                      TryCatchStatement* stmt_for_coverage = nullptr);
   template <typename TryBodyFunc, typename FinallyBodyFunc>
   void BuildTryFinally(TryBodyFunc try_body_func,
                        FinallyBodyFunc finally_body_func,
                        HandlerTable::CatchPrediction catch_prediction,
                        TryFinallyStatement* stmt_for_coverage = nullptr);

   template <typename ExpressionFunc>
   void BuildOptionalChain(ExpressionFunc expression_func);

   // Visitors for obtaining expression result in the accumulator, in a
   // register, or just getting the effect. Some visitors return a TypeHint which
   // specifies the type of the result of the visited expression.
   TypeHint VisitForAccumulatorValue(Expression* expr);
   void VisitForAccumulatorValueOrTheHole(Expression* expr);
   V8_WARN_UNUSED_RESULT Register VisitForRegisterValue(Expression* expr);
   V8_INLINE void VisitForRegisterValue(Expression* expr, Register destination);
   void VisitAndPushIntoRegisterList(Expression* expr, RegisterList* reg_list);
   void VisitForEffect(Expression* expr);
   void VisitForTest(Expression* expr, BytecodeLabels* then_labels,
                     BytecodeLabels* else_labels, TestFallthrough fallthrough);
   void VisitForNullishTest(Expression* expr, BytecodeLabels* then_labels,
                            BytecodeLabels* test_next_labels,
                            BytecodeLabels* else_labels);

   void VisitInSameTestExecutionScope(Expression* expr);

   Register GetRegisterForLocalVariable(Variable* variable);

   // Returns the runtime function id for a store to super for the function's
   // language mode.
   inline Runtime::FunctionId StoreToSuperRuntimeId();
   inline Runtime::FunctionId StoreKeyedToSuperRuntimeId();

   // Returns a cached slot, or create and cache a new slot if one doesn't
   // already exists.
   FeedbackSlot GetCachedLoadGlobalICSlot(TypeofMode typeof_mode,
                                          Variable* variable);
   FeedbackSlot GetCachedStoreGlobalICSlot(LanguageMode language_mode,
                                           Variable* variable);
   FeedbackSlot GetCachedLoadICSlot(const Expression* expr,
                                    const AstRawString* name);
   FeedbackSlot GetCachedLoadSuperICSlot(const AstRawString* name);
   FeedbackSlot GetCachedStoreICSlot(const Expression* expr,
                                     const AstRawString* name);
   FeedbackSlot GetDummyCompareICSlot();

   int GetCachedCreateClosureSlot(FunctionLiteral* literal);

   void AddToEagerLiteralsIfEager(FunctionLiteral* literal);

   // Checks if the visited expression is one shot, i.e executed only once. Any
   // expression either in a top level code or an IIFE that is not within a loop
   // is eligible for one shot optimizations.
   inline bool ShouldOptimizeAsOneShot() const;

   static constexpr ToBooleanMode ToBooleanModeFromTypeHint(TypeHint type_hint) {
     return type_hint == TypeHint::kBoolean ? ToBooleanMode::kAlreadyBoolean
                                            : ToBooleanMode::kConvertToBoolean;
   }

   inline Register generator_object() const;

   inline BytecodeArrayBuilder* builder() { return &builder_; }
   inline Zone* zone() const { return zone_; }
   inline DeclarationScope* closure_scope() const { return closure_scope_; }
   inline UnoptimizedCompilationInfo* info() const { return info_; }
   inline const AstStringConstants* ast_string_constants() const {
     return ast_string_constants_;
   }

   inline Scope* current_scope() const { return current_scope_; }
   inline void set_current_scope(Scope* scope) { current_scope_ = scope; }

   inline ControlScope* execution_control() const { return execution_control_; }
   inline void set_execution_control(ControlScope* scope) {
     execution_control_ = scope;
   }
   inline ContextScope* execution_context() const { return execution_context_; }
   inline void set_execution_context(ContextScope* context) {
     execution_context_ = context;
   }
   inline void set_execution_result(ExpressionResultScope* execution_result) {
     execution_result_ = execution_result;
   }
   ExpressionResultScope* execution_result() const { return execution_result_; }
   BytecodeRegisterAllocator* register_allocator() {
     return builder()->register_allocator();
   }

   TopLevelDeclarationsBuilder* top_level_builder() {
     DCHECK_NOT_NULL(top_level_builder_);
     return top_level_builder_;
   }
   inline LanguageMode language_mode() const;
   inline FunctionKind function_kind() const;
   inline FeedbackVectorSpec* feedback_spec();
   inline int feedback_index(FeedbackSlot slot) const;

   inline FeedbackSlotCache* feedback_slot_cache() {
     return feedback_slot_cache_;
   }

   inline HandlerTable::CatchPrediction catch_prediction() const {
     return catch_prediction_;
   }
   inline void set_catch_prediction(HandlerTable::CatchPrediction value) {
     catch_prediction_ = value;
   }

   LoopScope* current_loop_scope() const { return current_loop_scope_; }
   void set_current_loop_scope(LoopScope* loop_scope) {
     current_loop_scope_ = loop_scope;
   }

   Zone* zone_;
   BytecodeArrayBuilder builder_;
   UnoptimizedCompilationInfo* info_;
   const AstStringConstants* ast_string_constants_;
   DeclarationScope* closure_scope_;
   Scope* current_scope_;

   // External vector of literals to be eagerly compiled.
   std::vector<FunctionLiteral*>* eager_inner_literals_;

   FeedbackSlotCache* feedback_slot_cache_;

   TopLevelDeclarationsBuilder* top_level_builder_;
   BlockCoverageBuilder* block_coverage_builder_;
   ZoneVector<std::pair<FunctionLiteral*, size_t>> function_literals_;
   ZoneVector<std::pair<NativeFunctionLiteral*, size_t>>
       native_function_literals_;
   ZoneVector<std::pair<ObjectLiteral*, size_t>> object_literals_;
   ZoneVector<std::pair<ArrayLiteral*, size_t>> array_literals_;
   ZoneVector<std::pair<ClassLiteral*, size_t>> class_literals_;
   ZoneVector<std::pair<GetTemplateObject*, size_t>> template_objects_;

   ControlScope* execution_control_;
   ContextScope* execution_context_;
   ExpressionResultScope* execution_result_;

   Register incoming_new_target_or_generator_;

   BytecodeLabels* optional_chaining_null_labels_;

   // Dummy feedback slot for compare operations, where we don't care about
   // feedback
   SharedFeedbackSlot dummy_feedback_slot_;

   BytecodeJumpTable* generator_jump_table_;
   int suspend_count_;
   // TODO(solanes): assess if we can move loop_depth_ into LoopScope.
   int loop_depth_;

   LoopScope* current_loop_scope_;

   HandlerTable::CatchPrediction catch_prediction_;
 };

 }  // namespace interpreter
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_INTERPRETER_BYTECODE_GENERATOR_H_
	// Copyright 2015 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_INTERPRETER_BYTECODE_GENERATOR_H_
	#define V8_INTERPRETER_BYTECODE_GENERATOR_H_

	#include "src/ast/ast.h"
	#include "src/interpreter/bytecode-array-builder.h"
	#include "src/interpreter/bytecode-label.h"
	#include "src/interpreter/bytecode-register.h"
	#include "src/interpreter/bytecodes.h"
	#include "src/objects/feedback-vector.h"
	#include "src/objects/function-kind.h"

	namespace v8 {
	namespace internal {

	class AstNodeSourceRanges;
	class AstStringConstants;
	class BytecodeArray;
	class UnoptimizedCompilationInfo;
	enum class SourceRangeKind;

	namespace interpreter {

	class TopLevelDeclarationsBuilder;
	class LoopBuilder;
	class BlockCoverageBuilder;
	class BytecodeJumpTable;

	class BytecodeGenerator final : public AstVisitor<BytecodeGenerator> {
	public:
	explicit BytecodeGenerator(
	Zone* zone, UnoptimizedCompilationInfo* info,
	const AstStringConstants* ast_string_constants,
	std::vector<FunctionLiteral> eager_inner_literals);

	void GenerateBytecode(uintptr_t stack_limit);
	template <typename LocalIsolate>
	Handle<BytecodeArray> FinalizeBytecode(LocalIsolate* isolate,
	Handle<Script> script);
	template <typename LocalIsolate>
	Handle<ByteArray> FinalizeSourcePositionTable(LocalIsolate* isolate);

	#ifdef DEBUG
	int CheckBytecodeMatches(BytecodeArray bytecode);
	#endif

	#define DECLARE_VISIT(type) void Visit##type(type* node);
	AST_NODE_LIST(DECLARE_VISIT)
	#undef DECLARE_VISIT

	// Visiting function for declarations list and statements are overridden.
	void VisitModuleDeclarations(Declaration::List* declarations);
	void VisitGlobalDeclarations(Declaration::List* declarations);
	void VisitDeclarations(Declaration::List* declarations);
	void VisitStatements(const ZonePtrList<Statement>* statments);

	private:
	class AccumulatorPreservingScope;
	class ContextScope;
	class ControlScope;
	class ControlScopeForBreakable;
	class ControlScopeForIteration;
	class ControlScopeForTopLevel;
	class ControlScopeForTryCatch;
	class ControlScopeForTryFinally;
	class CurrentScope;
	class EffectResultScope;
	class ExpressionResultScope;
	class FeedbackSlotCache;
	class IteratorRecord;
	class LoopScope;
	class NaryCodeCoverageSlots;
	class OptionalChainNullLabelScope;
	class RegisterAllocationScope;
	class TestResultScope;
	class TopLevelDeclarationsBuilder;
	class ValueResultScope;

	using ToBooleanMode = BytecodeArrayBuilder::ToBooleanMode;

	enum class TestFallthrough { kThen, kElse, kNone };
	enum class TypeHint { kAny, kBoolean, kString };
	enum class AccumulatorPreservingMode { kNone, kPreserve };

	// An assignment has to evaluate its LHS before its RHS, but has to assign to
	// the LHS after both evaluations are done. This class stores the data
	// computed in the LHS evaulation that has to live across the RHS evaluation,
	// and is used in the actual LHS assignment.
	class AssignmentLhsData {
	public:
	static AssignmentLhsData NonProperty(Expression* expr);
	static AssignmentLhsData NamedProperty(Expression* object_expr,
	Register object,
	const AstRawString* name);
	static AssignmentLhsData KeyedProperty(Register object, Register key);
	static AssignmentLhsData PrivateMethodOrAccessor(AssignType type,
	Property* property);
	static AssignmentLhsData NamedSuperProperty(
	RegisterList super_property_args);
	static AssignmentLhsData KeyedSuperProperty(
	RegisterList super_property_args);

	AssignType assign_type() const { return assign_type_; }
	Expression* expr() const {
	DCHECK(assign_type_ == NON_PROPERTY \|\| assign_type_ == PRIVATE_METHOD \|\|
	assign_type_ == PRIVATE_GETTER_ONLY \|\|
	assign_type_ == PRIVATE_SETTER_ONLY \|\|
	assign_type_ == PRIVATE_GETTER_AND_SETTER);
	return expr_;
	}
	Expression* object_expr() const {
	DCHECK_EQ(assign_type_, NAMED_PROPERTY);
	return object_expr_;
	}
	Register object() const {
	DCHECK(assign_type_ == NAMED_PROPERTY \|\| assign_type_ == KEYED_PROPERTY);
	return object_;
	}
	Register key() const {
	DCHECK(assign_type_ == KEYED_PROPERTY);
	return key_;
	}
	const AstRawString* name() const {
	DCHECK(assign_type_ == NAMED_PROPERTY);
	return name_;
	}
	RegisterList super_property_args() const {
	DCHECK(assign_type_ == NAMED_SUPER_PROPERTY \|\|
	assign_type_ == KEYED_SUPER_PROPERTY);
	return super_property_args_;
	}

	private:
	AssignmentLhsData(AssignType assign_type, Expression* expr,
	RegisterList super_property_args, Register object,
	Register key, Expression* object_expr,
	const AstRawString* name)
	: assign_type_(assign_type),
	expr_(expr),
	super_property_args_(super_property_args),
	object_(object),
	key_(key),
	object_expr_(object_expr),
	name_(name) {}

	AssignType assign_type_;

	// Different assignment types use different fields:
	//
	// NON_PROPERTY: expr
	// NAMED_PROPERTY: object_expr, object, name
	// KEYED_PROPERTY, PRIVATE_METHOD: object, key
	// NAMED_SUPER_PROPERTY: super_property_args
	// KEYED_SUPER_PROPERT: super_property_args
	Expression* expr_;
	RegisterList super_property_args_;
	Register object_;
	Register key_;
	Expression* object_expr_;
	const AstRawString* name_;
	};

	void GenerateBytecodeBody();
	template <typename LocalIsolate>
	void AllocateDeferredConstants(LocalIsolate* isolate, Handle<Script> script);

	DEFINE_AST_VISITOR_SUBCLASS_MEMBERS();

	// Dispatched from VisitBinaryOperation.
	void VisitArithmeticExpression(BinaryOperation* binop);
	void VisitCommaExpression(BinaryOperation* binop);
	void VisitLogicalOrExpression(BinaryOperation* binop);
	void VisitLogicalAndExpression(BinaryOperation* binop);
	void VisitNullishExpression(BinaryOperation* binop);

	// Dispatched from VisitNaryOperation.
	void VisitNaryArithmeticExpression(NaryOperation* expr);
	void VisitNaryCommaExpression(NaryOperation* expr);
	void VisitNaryLogicalOrExpression(NaryOperation* expr);
	void VisitNaryLogicalAndExpression(NaryOperation* expr);
	void VisitNaryNullishExpression(NaryOperation* expr);

	// Dispatched from VisitUnaryOperation.
	void VisitVoid(UnaryOperation* expr);
	void VisitTypeOf(UnaryOperation* expr);
	void VisitNot(UnaryOperation* expr);
	void VisitDelete(UnaryOperation* expr);

	// Visits a typeof expression for the value on which to perform the typeof.
	void VisitForTypeOfValue(Expression* expr);

	// Used by flow control routines to evaluate loop condition.
	void VisitCondition(Expression* expr);

	// Visit the arguments expressions in \|args\| and store them in \|args_regs\|,
	// growing \|args_regs\| for each argument visited.
	void VisitArguments(const ZonePtrList<Expression>* args,
	RegisterList* arg_regs);

	// Visit a keyed super property load. The optional
	// \|opt_receiver_out\| register will have the receiver stored to it
	// if it's a valid register. The loaded value is placed in the
	// accumulator.
	void VisitKeyedSuperPropertyLoad(Property* property,
	Register opt_receiver_out);

	// Visit a named super property load. The optional
	// \|opt_receiver_out\| register will have the receiver stored to it
	// if it's a valid register. The loaded value is placed in the
	// accumulator.
	void VisitNamedSuperPropertyLoad(Property* property,
	Register opt_receiver_out);

	void VisitPropertyLoad(Register obj, Property* expr);
	void VisitPropertyLoadForRegister(Register obj, Property* expr,
	Register destination);

	AssignmentLhsData PrepareAssignmentLhs(
	Expression* lhs, AccumulatorPreservingMode accumulator_preserving_mode =
	AccumulatorPreservingMode::kNone);
	void BuildAssignment(const AssignmentLhsData& data, Token::Value op,
	LookupHoistingMode lookup_hoisting_mode);

	void BuildThisVariableLoad();

	void BuildDeclareCall(Runtime::FunctionId id);

	Expression* GetDestructuringDefaultValue(Expression** target);
	void BuildDestructuringArrayAssignment(
	ArrayLiteral* pattern, Token::Value op,
	LookupHoistingMode lookup_hoisting_mode);
	void BuildDestructuringObjectAssignment(
	ObjectLiteral* pattern, Token::Value op,
	LookupHoistingMode lookup_hoisting_mode);

	void BuildLoadNamedProperty(const Expression* object_expr, Register object,
	const AstRawString* name);
	void BuildStoreNamedProperty(const Expression* object_expr, Register object,
	const AstRawString* name);

	void BuildVariableLoad(Variable* variable, HoleCheckMode hole_check_mode,
	TypeofMode typeof_mode = NOT_INSIDE_TYPEOF);
	void BuildVariableLoadForAccumulatorValue(
	Variable* variable, HoleCheckMode hole_check_mode,
	TypeofMode typeof_mode = NOT_INSIDE_TYPEOF);
	void BuildVariableAssignment(
	Variable* variable, Token::Value op, HoleCheckMode hole_check_mode,
	LookupHoistingMode lookup_hoisting_mode = LookupHoistingMode::kNormal);
	void BuildLiteralCompareNil(Token::Value compare_op,
	BytecodeArrayBuilder::NilValue nil);
	void BuildReturn(int source_position = kNoSourcePosition);
	void BuildAsyncReturn(int source_position = kNoSourcePosition);
	void BuildAsyncGeneratorReturn();
	void BuildReThrow();
	void BuildHoleCheckForVariableAssignment(Variable* variable, Token::Value op);
	void BuildThrowIfHole(Variable* variable);

	void BuildNewLocalActivationContext();
	void BuildLocalActivationContextInitialization();
	void BuildNewLocalBlockContext(Scope* scope);
	void BuildNewLocalCatchContext(Scope* scope);
	void BuildNewLocalWithContext(Scope* scope);

	void BuildGeneratorPrologue();
	void BuildSuspendPoint(int position);

	void BuildAwait(int position = kNoSourcePosition);
	void BuildAwait(Expression* await_expr);

	void BuildFinalizeIteration(IteratorRecord iterator, Register done,
	Register iteration_continuation_token);

	void BuildGetIterator(IteratorType hint);

	// Create an IteratorRecord with pre-allocated registers holding the next
	// method and iterator object.
	IteratorRecord BuildGetIteratorRecord(Register iterator_next,
	Register iterator_object,
	IteratorType hint);

	// Create an IteratorRecord allocating new registers to hold the next method
	// and iterator object.
	IteratorRecord BuildGetIteratorRecord(IteratorType hint);
	void BuildIteratorNext(const IteratorRecord& iterator, Register next_result);
	void BuildIteratorClose(const IteratorRecord& iterator,
	Expression* expr = nullptr);
	void BuildCallIteratorMethod(Register iterator, const AstRawString* method,
	RegisterList receiver_and_args,
	BytecodeLabel* if_called,
	BytecodeLabels* if_notcalled);

	void BuildFillArrayWithIterator(IteratorRecord iterator, Register array,
	Register index, Register value,
	FeedbackSlot next_value_slot,
	FeedbackSlot next_done_slot,
	FeedbackSlot index_slot,
	FeedbackSlot element_slot);
	// Create Array literals. \|expr\| can be nullptr, but if provided,
	// a boilerplate will be used to create an initial array for elements
	// before the first spread.
	void BuildCreateArrayLiteral(const ZonePtrList<Expression>* elements,
	ArrayLiteral* expr);
	void BuildCreateObjectLiteral(Register literal, uint8_t flags, size_t entry);
	void AllocateTopLevelRegisters();
	void VisitArgumentsObject(Variable* variable);
	void VisitRestArgumentsArray(Variable* rest);
	void VisitCallSuper(Call* call);
	void BuildInvalidPropertyAccess(MessageTemplate tmpl, Property* property);
	void BuildPrivateBrandCheck(Property* property, Register object,
	MessageTemplate tmpl);
	void BuildPrivateGetterAccess(Register obj, Register access_pair);
	void BuildPrivateSetterAccess(Register obj, Register access_pair,
	Register value);
	void BuildPrivateMethods(ClassLiteral* expr, bool is_static,
	Register home_object);
	void BuildClassLiteral(ClassLiteral* expr, Register name);
	void VisitClassLiteral(ClassLiteral* expr, Register name);
	void VisitNewTargetVariable(Variable* variable);
	void VisitThisFunctionVariable(Variable* variable);
	void BuildPrivateBrandInitialization(Register receiver);
	void BuildInstanceMemberInitialization(Register constructor,
	Register instance);
	void BuildGeneratorObjectVariableInitialization();
	void VisitBlockDeclarationsAndStatements(Block* stmt);
	void VisitSetHomeObject(Register value, Register home_object,
	LiteralProperty* property);
	void VisitLiteralAccessor(Register home_object, LiteralProperty* property,
	Register value_out);
	void VisitForInAssignment(Expression* expr);
	void VisitModuleNamespaceImports();

	// Visit a logical OR/AND within a test context, rewiring the jumps based
	// on the expression values.
	void VisitLogicalTest(Token::Value token, Expression* left, Expression* right,
	int right_coverage_slot);
	void VisitNaryLogicalTest(Token::Value token, NaryOperation* expr,
	const NaryCodeCoverageSlots* coverage_slots);

	// Visit a (non-RHS) test for a logical op, which falls through if the test
	// fails or jumps to the appropriate labels if it succeeds.
	void VisitLogicalTestSubExpression(Token::Value token, Expression* expr,
	BytecodeLabels* then_labels,
	BytecodeLabels* else_labels,
	int coverage_slot);

	// Helpers for binary and nary logical op value expressions.
	bool VisitLogicalOrSubExpression(Expression* expr, BytecodeLabels* end_labels,
	int coverage_slot);
	bool VisitLogicalAndSubExpression(Expression* expr,
	BytecodeLabels* end_labels,
	int coverage_slot);

	// Helper for binary and nary nullish op value expressions.
	bool VisitNullishSubExpression(Expression* expr, BytecodeLabels* end_labels,
	int coverage_slot);

	// Visit the body of a loop iteration.
	void VisitIterationBody(IterationStatement* stmt, LoopBuilder* loop_builder);

	// Visit a statement and switch scopes, the context is in the accumulator.
	void VisitInScope(Statement* stmt, Scope* scope);

	void BuildPushUndefinedIntoRegisterList(RegisterList* reg_list);

	void BuildLoadPropertyKey(LiteralProperty* property, Register out_reg);

	int AllocateBlockCoverageSlotIfEnabled(AstNode* node, SourceRangeKind kind);
	int AllocateNaryBlockCoverageSlotIfEnabled(NaryOperation* node, size_t index);

	void BuildIncrementBlockCoverageCounterIfEnabled(AstNode* node,
	SourceRangeKind kind);
	void BuildIncrementBlockCoverageCounterIfEnabled(int coverage_array_slot);

	void BuildTest(ToBooleanMode mode, BytecodeLabels* then_labels,
	BytecodeLabels* else_labels, TestFallthrough fallthrough);

	template <typename TryBodyFunc, typename CatchBodyFunc>
	void BuildTryCatch(TryBodyFunc try_body_func, CatchBodyFunc catch_body_func,
	HandlerTable::CatchPrediction catch_prediction,
	TryCatchStatement* stmt_for_coverage = nullptr);
	template <typename TryBodyFunc, typename FinallyBodyFunc>
	void BuildTryFinally(TryBodyFunc try_body_func,
	FinallyBodyFunc finally_body_func,
	HandlerTable::CatchPrediction catch_prediction,
	TryFinallyStatement* stmt_for_coverage = nullptr);

	template <typename ExpressionFunc>
	void BuildOptionalChain(ExpressionFunc expression_func);

	// Visitors for obtaining expression result in the accumulator, in a
	// register, or just getting the effect. Some visitors return a TypeHint which
	// specifies the type of the result of the visited expression.
	TypeHint VisitForAccumulatorValue(Expression* expr);
	void VisitForAccumulatorValueOrTheHole(Expression* expr);
	V8_WARN_UNUSED_RESULT Register VisitForRegisterValue(Expression* expr);
	V8_INLINE void VisitForRegisterValue(Expression* expr, Register destination);
	void VisitAndPushIntoRegisterList(Expression* expr, RegisterList* reg_list);
	void VisitForEffect(Expression* expr);
	void VisitForTest(Expression* expr, BytecodeLabels* then_labels,
	BytecodeLabels* else_labels, TestFallthrough fallthrough);
	void VisitForNullishTest(Expression* expr, BytecodeLabels* then_labels,
	BytecodeLabels* test_next_labels,
	BytecodeLabels* else_labels);

	void VisitInSameTestExecutionScope(Expression* expr);

	Register GetRegisterForLocalVariable(Variable* variable);

	// Returns the runtime function id for a store to super for the function's
	// language mode.
	inline Runtime::FunctionId StoreToSuperRuntimeId();
	inline Runtime::FunctionId StoreKeyedToSuperRuntimeId();

	// Returns a cached slot, or create and cache a new slot if one doesn't
	// already exists.
	FeedbackSlot GetCachedLoadGlobalICSlot(TypeofMode typeof_mode,
	Variable* variable);
	FeedbackSlot GetCachedStoreGlobalICSlot(LanguageMode language_mode,
	Variable* variable);
	FeedbackSlot GetCachedLoadICSlot(const Expression* expr,
	const AstRawString* name);
	FeedbackSlot GetCachedLoadSuperICSlot(const AstRawString* name);
	FeedbackSlot GetCachedStoreICSlot(const Expression* expr,
	const AstRawString* name);
	FeedbackSlot GetDummyCompareICSlot();

	int GetCachedCreateClosureSlot(FunctionLiteral* literal);

	void AddToEagerLiteralsIfEager(FunctionLiteral* literal);

	// Checks if the visited expression is one shot, i.e executed only once. Any
	// expression either in a top level code or an IIFE that is not within a loop
	// is eligible for one shot optimizations.
	inline bool ShouldOptimizeAsOneShot() const;

	static constexpr ToBooleanMode ToBooleanModeFromTypeHint(TypeHint type_hint) {
	return type_hint == TypeHint::kBoolean ? ToBooleanMode::kAlreadyBoolean
	: ToBooleanMode::kConvertToBoolean;
	}

	inline Register generator_object() const;

	inline BytecodeArrayBuilder* builder() { return &builder_; }
	inline Zone* zone() const { return zone_; }
	inline DeclarationScope* closure_scope() const { return closure_scope_; }
	inline UnoptimizedCompilationInfo* info() const { return info_; }
	inline const AstStringConstants* ast_string_constants() const {
	return ast_string_constants_;
	}

	inline Scope* current_scope() const { return current_scope_; }
	inline void set_current_scope(Scope* scope) { current_scope_ = scope; }

	inline ControlScope* execution_control() const { return execution_control_; }
	inline void set_execution_control(ControlScope* scope) {
	execution_control_ = scope;
	}
	inline ContextScope* execution_context() const { return execution_context_; }
	inline void set_execution_context(ContextScope* context) {
	execution_context_ = context;
	}
	inline void set_execution_result(ExpressionResultScope* execution_result) {
	execution_result_ = execution_result;
	}
	ExpressionResultScope* execution_result() const { return execution_result_; }
	BytecodeRegisterAllocator* register_allocator() {
	return builder()->register_allocator();
	}

	TopLevelDeclarationsBuilder* top_level_builder() {
	DCHECK_NOT_NULL(top_level_builder_);
	return top_level_builder_;
	}
	inline LanguageMode language_mode() const;
	inline FunctionKind function_kind() const;
	inline FeedbackVectorSpec* feedback_spec();
	inline int feedback_index(FeedbackSlot slot) const;

	inline FeedbackSlotCache* feedback_slot_cache() {
	return feedback_slot_cache_;
	}

	inline HandlerTable::CatchPrediction catch_prediction() const {
	return catch_prediction_;
	}
	inline void set_catch_prediction(HandlerTable::CatchPrediction value) {
	catch_prediction_ = value;
	}

	LoopScope* current_loop_scope() const { return current_loop_scope_; }
	void set_current_loop_scope(LoopScope* loop_scope) {
	current_loop_scope_ = loop_scope;
	}

	Zone* zone_;
	BytecodeArrayBuilder builder_;
	UnoptimizedCompilationInfo* info_;
	const AstStringConstants* ast_string_constants_;
	DeclarationScope* closure_scope_;
	Scope* current_scope_;

	// External vector of literals to be eagerly compiled.
	std::vector<FunctionLiteral> eager_inner_literals_;

	FeedbackSlotCache* feedback_slot_cache_;

	TopLevelDeclarationsBuilder* top_level_builder_;
	BlockCoverageBuilder* block_coverage_builder_;
	ZoneVector<std::pair<FunctionLiteral*, size_t>> function_literals_;
	ZoneVector<std::pair<NativeFunctionLiteral*, size_t>>
	native_function_literals_;
	ZoneVector<std::pair<ObjectLiteral*, size_t>> object_literals_;
	ZoneVector<std::pair<ArrayLiteral*, size_t>> array_literals_;
	ZoneVector<std::pair<ClassLiteral*, size_t>> class_literals_;
	ZoneVector<std::pair<GetTemplateObject*, size_t>> template_objects_;

	ControlScope* execution_control_;
	ContextScope* execution_context_;
	ExpressionResultScope* execution_result_;

	Register incoming_new_target_or_generator_;

	BytecodeLabels* optional_chaining_null_labels_;

	// Dummy feedback slot for compare operations, where we don't care about
	// feedback
	SharedFeedbackSlot dummy_feedback_slot_;

	BytecodeJumpTable* generator_jump_table_;
	int suspend_count_;
	// TODO(solanes): assess if we can move loop_depth_ into LoopScope.
	int loop_depth_;

	LoopScope* current_loop_scope_;

	HandlerTable::CatchPrediction catch_prediction_;
	};

	} // namespace interpreter
	} // namespace internal
	} // namespace v8

	#endif // V8_INTERPRETER_BYTECODE_GENERATOR_H_