src/v8/src/ast/variables.h - cobalt - Git at Google

 // Copyright 2011 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_AST_VARIABLES_H_
 #define V8_AST_VARIABLES_H_

 #include "src/ast/ast-value-factory.h"
 #include "src/globals.h"
 #include "src/zone/zone.h"

 namespace v8 {
 namespace internal {

 // The AST refers to variables via VariableProxies - placeholders for the actual
 // variables. Variables themselves are never directly referred to from the AST,
 // they are maintained by scopes, and referred to from VariableProxies and Slots
 // after binding and variable allocation.
 class Variable final : public ZoneObject {
  public:
   Variable(Scope* scope, const AstRawString* name, VariableMode mode,
            VariableKind kind, InitializationFlag initialization_flag,
            MaybeAssignedFlag maybe_assigned_flag = kNotAssigned)
       : scope_(scope),
         name_(name),
         local_if_not_shadowed_(nullptr),
         next_(nullptr),
         index_(-1),
         initializer_position_(kNoSourcePosition),
         bit_field_(MaybeAssignedFlagField::encode(maybe_assigned_flag) |
                    InitializationFlagField::encode(initialization_flag) |
                    VariableModeField::encode(mode) |
                    IsUsedField::encode(false) |
                    ForceContextAllocationField::encode(false) |
                    ForceHoleInitializationField::encode(false) |
                    LocationField::encode(VariableLocation::UNALLOCATED) |
                    VariableKindField::encode(kind)) {
     // Var declared variables never need initialization.
     DCHECK(!(mode == VAR && initialization_flag == kNeedsInitialization));
   }

   explicit Variable(Variable* other);

   // The source code for an eval() call may refer to a variable that is
   // in an outer scope about which we don't know anything (it may not
   // be the script scope). scope() is nullptr in that case. Currently the
   // scope is only used to follow the context chain length.
   Scope* scope() const { return scope_; }

   // This is for adjusting the scope of temporaries used when desugaring
   // parameter initializers.
   void set_scope(Scope* scope) { scope_ = scope; }

   Handle<String> name() const { return name_->string(); }
   const AstRawString* raw_name() const { return name_; }
   VariableMode mode() const { return VariableModeField::decode(bit_field_); }
   bool has_forced_context_allocation() const {
     return ForceContextAllocationField::decode(bit_field_);
   }
   void ForceContextAllocation() {
     DCHECK(IsUnallocated() || IsContextSlot() ||
            location() == VariableLocation::MODULE);
     bit_field_ = ForceContextAllocationField::update(bit_field_, true);
   }
   bool is_used() { return IsUsedField::decode(bit_field_); }
   void set_is_used() { bit_field_ = IsUsedField::update(bit_field_, true); }
   MaybeAssignedFlag maybe_assigned() const {
     return MaybeAssignedFlagField::decode(bit_field_);
   }
   void set_maybe_assigned() {
     bit_field_ = MaybeAssignedFlagField::update(bit_field_, kMaybeAssigned);
   }

   int initializer_position() { return initializer_position_; }
   void set_initializer_position(int pos) { initializer_position_ = pos; }

   bool IsUnallocated() const {
     return location() == VariableLocation::UNALLOCATED;
   }
   bool IsParameter() const { return location() == VariableLocation::PARAMETER; }
   bool IsStackLocal() const { return location() == VariableLocation::LOCAL; }
   bool IsStackAllocated() const { return IsParameter() || IsStackLocal(); }
   bool IsContextSlot() const { return location() == VariableLocation::CONTEXT; }
   bool IsLookupSlot() const { return location() == VariableLocation::LOOKUP; }
   bool IsGlobalObjectProperty() const;

   bool is_dynamic() const { return IsDynamicVariableMode(mode()); }

   // Returns the InitializationFlag this Variable was created with.
   // Scope analysis may allow us to relax this initialization
   // requirement, which will be reflected in the return value of
   // binding_needs_init().
   InitializationFlag initialization_flag() const {
     return InitializationFlagField::decode(bit_field_);
   }

   // Whether this variable needs to be initialized with the hole at
   // declaration time. Only returns valid results after scope analysis.
   bool binding_needs_init() const {
     DCHECK_IMPLIES(initialization_flag() == kNeedsInitialization,
                    IsLexicalVariableMode(mode()));
     DCHECK_IMPLIES(ForceHoleInitializationField::decode(bit_field_),
                    initialization_flag() == kNeedsInitialization);

     // Always initialize if hole initialization was forced during
     // scope analysis.
     if (ForceHoleInitializationField::decode(bit_field_)) return true;

     // If initialization was not forced, no need for initialization
     // for stack allocated variables, since UpdateNeedsHoleCheck()
     // in scopes.cc has proven that no VariableProxy refers to
     // this variable in such a way that a runtime hole check
     // would be generated.
     if (IsStackAllocated()) return false;

     // Otherwise, defer to the flag set when this Variable was constructed.
     return initialization_flag() == kNeedsInitialization;
   }

   // Called during scope analysis when a VariableProxy is found to
   // reference this Variable in such a way that a hole check will
   // be required at runtime.
   void ForceHoleInitialization() {
     DCHECK_EQ(kNeedsInitialization, initialization_flag());
     DCHECK(IsLexicalVariableMode(mode()));
     bit_field_ = ForceHoleInitializationField::update(bit_field_, true);
   }

   bool throw_on_const_assignment(LanguageMode language_mode) const {
     return kind() != SLOPPY_FUNCTION_NAME_VARIABLE || is_strict(language_mode);
   }

   bool is_function() const { return kind() == FUNCTION_VARIABLE; }
   bool is_this() const { return kind() == THIS_VARIABLE; }
   bool is_sloppy_function_name() const {
     return kind() == SLOPPY_FUNCTION_NAME_VARIABLE;
   }

   Variable* local_if_not_shadowed() const {
     DCHECK(mode() == DYNAMIC_LOCAL && local_if_not_shadowed_ != nullptr);
     return local_if_not_shadowed_;
   }

   void set_local_if_not_shadowed(Variable* local) {
     local_if_not_shadowed_ = local;
   }

   VariableLocation location() const {
     return LocationField::decode(bit_field_);
   }
   VariableKind kind() const { return VariableKindField::decode(bit_field_); }

   int index() const { return index_; }

   bool IsReceiver() const {
     DCHECK(IsParameter());

     return index_ == -1;
   }

   bool IsExport() const {
     DCHECK_EQ(location(), VariableLocation::MODULE);
     DCHECK_NE(index(), 0);
     return index() > 0;
   }

   void AllocateTo(VariableLocation location, int index) {
     DCHECK(IsUnallocated() ||
            (this->location() == location && this->index() == index));
     DCHECK_IMPLIES(location == VariableLocation::MODULE, index != 0);
     bit_field_ = LocationField::update(bit_field_, location);
     DCHECK_EQ(location, this->location());
     index_ = index;
   }

   static InitializationFlag DefaultInitializationFlag(VariableMode mode) {
     DCHECK(IsDeclaredVariableMode(mode));
     return mode == VAR ? kCreatedInitialized : kNeedsInitialization;
   }

   typedef ThreadedList<Variable> List;

  private:
   Scope* scope_;
   const AstRawString* name_;

   // If this field is set, this variable references the stored locally bound
   // variable, but it might be shadowed by variable bindings introduced by
   // sloppy 'eval' calls between the reference scope (inclusive) and the
   // binding scope (exclusive).
   Variable* local_if_not_shadowed_;
   Variable* next_;
   int index_;
   int initializer_position_;
   uint16_t bit_field_;

   class VariableModeField : public BitField16<VariableMode, 0, 3> {};
   class VariableKindField
       : public BitField16<VariableKind, VariableModeField::kNext, 3> {};
   class LocationField
       : public BitField16<VariableLocation, VariableKindField::kNext, 3> {};
   class ForceContextAllocationField
       : public BitField16<bool, LocationField::kNext, 1> {};
   class IsUsedField
       : public BitField16<bool, ForceContextAllocationField::kNext, 1> {};
   class InitializationFlagField
       : public BitField16<InitializationFlag, IsUsedField::kNext, 1> {};
   class ForceHoleInitializationField
       : public BitField16<bool, InitializationFlagField::kNext, 1> {};
   class MaybeAssignedFlagField
       : public BitField16<MaybeAssignedFlag,
                           ForceHoleInitializationField::kNext, 1> {};
   Variable** next() { return &next_; }
   friend List;
 };
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_AST_VARIABLES_H_
	// Copyright 2011 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_AST_VARIABLES_H_
	#define V8_AST_VARIABLES_H_

	#include "src/ast/ast-value-factory.h"
	#include "src/globals.h"
	#include "src/zone/zone.h"

	namespace v8 {
	namespace internal {

	// The AST refers to variables via VariableProxies - placeholders for the actual
	// variables. Variables themselves are never directly referred to from the AST,
	// they are maintained by scopes, and referred to from VariableProxies and Slots
	// after binding and variable allocation.
	class Variable final : public ZoneObject {
	public:
	Variable(Scope* scope, const AstRawString* name, VariableMode mode,
	VariableKind kind, InitializationFlag initialization_flag,
	MaybeAssignedFlag maybe_assigned_flag = kNotAssigned)
	: scope_(scope),
	name_(name),
	local_if_not_shadowed_(nullptr),
	next_(nullptr),
	index_(-1),
	initializer_position_(kNoSourcePosition),
	bit_field_(MaybeAssignedFlagField::encode(maybe_assigned_flag) \|
	InitializationFlagField::encode(initialization_flag) \|
	VariableModeField::encode(mode) \|
	IsUsedField::encode(false) \|
	ForceContextAllocationField::encode(false) \|
	ForceHoleInitializationField::encode(false) \|
	LocationField::encode(VariableLocation::UNALLOCATED) \|
	VariableKindField::encode(kind)) {
	// Var declared variables never need initialization.
	DCHECK(!(mode == VAR && initialization_flag == kNeedsInitialization));
	}

	explicit Variable(Variable* other);

	// The source code for an eval() call may refer to a variable that is
	// in an outer scope about which we don't know anything (it may not
	// be the script scope). scope() is nullptr in that case. Currently the
	// scope is only used to follow the context chain length.
	Scope* scope() const { return scope_; }

	// This is for adjusting the scope of temporaries used when desugaring
	// parameter initializers.
	void set_scope(Scope* scope) { scope_ = scope; }

	Handle<String> name() const { return name_->string(); }
	const AstRawString* raw_name() const { return name_; }
	VariableMode mode() const { return VariableModeField::decode(bit_field_); }
	bool has_forced_context_allocation() const {
	return ForceContextAllocationField::decode(bit_field_);
	}
	void ForceContextAllocation() {
	DCHECK(IsUnallocated() \|\| IsContextSlot() \|\|
	location() == VariableLocation::MODULE);
	bit_field_ = ForceContextAllocationField::update(bit_field_, true);
	}
	bool is_used() { return IsUsedField::decode(bit_field_); }
	void set_is_used() { bit_field_ = IsUsedField::update(bit_field_, true); }
	MaybeAssignedFlag maybe_assigned() const {
	return MaybeAssignedFlagField::decode(bit_field_);
	}
	void set_maybe_assigned() {
	bit_field_ = MaybeAssignedFlagField::update(bit_field_, kMaybeAssigned);
	}

	int initializer_position() { return initializer_position_; }
	void set_initializer_position(int pos) { initializer_position_ = pos; }

	bool IsUnallocated() const {
	return location() == VariableLocation::UNALLOCATED;
	}
	bool IsParameter() const { return location() == VariableLocation::PARAMETER; }
	bool IsStackLocal() const { return location() == VariableLocation::LOCAL; }
	bool IsStackAllocated() const { return IsParameter() \|\| IsStackLocal(); }
	bool IsContextSlot() const { return location() == VariableLocation::CONTEXT; }
	bool IsLookupSlot() const { return location() == VariableLocation::LOOKUP; }
	bool IsGlobalObjectProperty() const;

	bool is_dynamic() const { return IsDynamicVariableMode(mode()); }

	// Returns the InitializationFlag this Variable was created with.
	// Scope analysis may allow us to relax this initialization
	// requirement, which will be reflected in the return value of
	// binding_needs_init().
	InitializationFlag initialization_flag() const {
	return InitializationFlagField::decode(bit_field_);
	}

	// Whether this variable needs to be initialized with the hole at
	// declaration time. Only returns valid results after scope analysis.
	bool binding_needs_init() const {
	DCHECK_IMPLIES(initialization_flag() == kNeedsInitialization,
	IsLexicalVariableMode(mode()));
	DCHECK_IMPLIES(ForceHoleInitializationField::decode(bit_field_),
	initialization_flag() == kNeedsInitialization);

	// Always initialize if hole initialization was forced during
	// scope analysis.
	if (ForceHoleInitializationField::decode(bit_field_)) return true;

	// If initialization was not forced, no need for initialization
	// for stack allocated variables, since UpdateNeedsHoleCheck()
	// in scopes.cc has proven that no VariableProxy refers to
	// this variable in such a way that a runtime hole check
	// would be generated.
	if (IsStackAllocated()) return false;

	// Otherwise, defer to the flag set when this Variable was constructed.
	return initialization_flag() == kNeedsInitialization;
	}

	// Called during scope analysis when a VariableProxy is found to
	// reference this Variable in such a way that a hole check will
	// be required at runtime.
	void ForceHoleInitialization() {
	DCHECK_EQ(kNeedsInitialization, initialization_flag());
	DCHECK(IsLexicalVariableMode(mode()));
	bit_field_ = ForceHoleInitializationField::update(bit_field_, true);
	}

	bool throw_on_const_assignment(LanguageMode language_mode) const {
	return kind() != SLOPPY_FUNCTION_NAME_VARIABLE \|\| is_strict(language_mode);
	}

	bool is_function() const { return kind() == FUNCTION_VARIABLE; }
	bool is_this() const { return kind() == THIS_VARIABLE; }
	bool is_sloppy_function_name() const {
	return kind() == SLOPPY_FUNCTION_NAME_VARIABLE;
	}

	Variable* local_if_not_shadowed() const {
	DCHECK(mode() == DYNAMIC_LOCAL && local_if_not_shadowed_ != nullptr);
	return local_if_not_shadowed_;
	}

	void set_local_if_not_shadowed(Variable* local) {
	local_if_not_shadowed_ = local;
	}

	VariableLocation location() const {
	return LocationField::decode(bit_field_);
	}
	VariableKind kind() const { return VariableKindField::decode(bit_field_); }

	int index() const { return index_; }

	bool IsReceiver() const {
	DCHECK(IsParameter());

	return index_ == -1;
	}

	bool IsExport() const {
	DCHECK_EQ(location(), VariableLocation::MODULE);
	DCHECK_NE(index(), 0);
	return index() > 0;
	}

	void AllocateTo(VariableLocation location, int index) {
	DCHECK(IsUnallocated() \|\|
	(this->location() == location && this->index() == index));
	DCHECK_IMPLIES(location == VariableLocation::MODULE, index != 0);
	bit_field_ = LocationField::update(bit_field_, location);
	DCHECK_EQ(location, this->location());
	index_ = index;
	}

	static InitializationFlag DefaultInitializationFlag(VariableMode mode) {
	DCHECK(IsDeclaredVariableMode(mode));
	return mode == VAR ? kCreatedInitialized : kNeedsInitialization;
	}

	typedef ThreadedList<Variable> List;

	private:
	Scope* scope_;
	const AstRawString* name_;

	// If this field is set, this variable references the stored locally bound
	// variable, but it might be shadowed by variable bindings introduced by
	// sloppy 'eval' calls between the reference scope (inclusive) and the
	// binding scope (exclusive).
	Variable* local_if_not_shadowed_;
	Variable* next_;
	int index_;
	int initializer_position_;
	uint16_t bit_field_;

	class VariableModeField : public BitField16<VariableMode, 0, 3> {};
	class VariableKindField
	: public BitField16<VariableKind, VariableModeField::kNext, 3> {};
	class LocationField
	: public BitField16<VariableLocation, VariableKindField::kNext, 3> {};
	class ForceContextAllocationField
	: public BitField16<bool, LocationField::kNext, 1> {};
	class IsUsedField
	: public BitField16<bool, ForceContextAllocationField::kNext, 1> {};
	class InitializationFlagField
	: public BitField16<InitializationFlag, IsUsedField::kNext, 1> {};
	class ForceHoleInitializationField
	: public BitField16<bool, InitializationFlagField::kNext, 1> {};
	class MaybeAssignedFlagField
	: public BitField16<MaybeAssignedFlag,
	ForceHoleInitializationField::kNext, 1> {};
	Variable** next() { return &next_; }
	friend List;
	};
	} // namespace internal
	} // namespace v8

	#endif // V8_AST_VARIABLES_H_