runtime/vm/scopes.h - sdk.git - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_VM_SCOPES_H_
 #define RUNTIME_VM_SCOPES_H_

 #include <limits>

 #include "platform/assert.h"
 #include "platform/globals.h"
 #include "vm/allocation.h"
 #include "vm/growable_array.h"
 #include "vm/object.h"
 #include "vm/raw_object.h"
 #include "vm/symbols.h"
 #include "vm/token.h"

 namespace dart {

 class CompileType;
 class LocalScope;
 class Slot;

 // Indices of [LocalVariable]s are abstract and have little todo with the
 // actual frame layout!
 //
 // There are generally 4 different kinds of [LocalVariable]s:
 //
 //    a) [LocalVariable]s referring to a parameter: The indices for those
 //       variables are assigned by the flow graph builder. Parameter n gets
 //       assigned the index (function.num_parameters - n - 1). I.e. the last
 //       parameter has index 1.
 //
 //    b) [LocalVariable]s referring to actual variables in the body of a
 //       function (either from Dart code or specially injected ones. The
 //       indices of those variables are assigned by the scope builder
 //       from 0, -1, ... -(M-1) for M local variables.
 //
 //       -> These variables participate in full SSA renaming and can therefore
 //          be used with [StoreLocalInstr]s (in addition to [LoadLocal]s).
 //
 //    c) [LocalVariable]s referring to values on the expression stack. Those are
 //       assigned by the flow graph builder. The indices of those variables are
 //       assigned by the flow graph builder (it simulates the expression stack
 //       height), they go from -NumVariables - ExpressionHeight.
 //
 //       -> These variables participate only partially in SSA renaming and can
 //          therefore only be used with [LoadLocalInstr]s and with
 //          [StoreLocalInstr]s **where no phis are necessary**.
 //
 //    b) [LocalVariable]s referring to captured variables.  Those are never
 //       loaded/stored directly. Their only purpose is to tell the flow graph
 //       builder how many parent links to follow and into which context index to
 //       store.  The indices of those variables are assigned by the scope
 //       builder and they refer to indices into context objects.
 class VariableIndex {
  public:
   static constexpr int kInvalidIndex = std::numeric_limits<int>::min();

   explicit VariableIndex(int value = kInvalidIndex) : value_(value) {}

   bool operator==(const VariableIndex& other) const {
     return value_ == other.value_;
   }

   bool IsValid() const { return value_ != kInvalidIndex; }

   int value() const { return value_; }

  private:
   int value_;
 };

 class LocalVariable : public ZoneAllocated {
  public:
   static constexpr intptr_t kNoKernelOffset = -1;

   LocalVariable(TokenPosition declaration_pos,
                 TokenPosition token_pos,
                 const String& name,
                 const AbstractType& static_type,
                 intptr_t kernel_offset = kNoKernelOffset);

   LocalVariable(TokenPosition declaration_pos,
                 TokenPosition token_pos,
                 const String& name,
                 const AbstractType& static_type,
                 intptr_t kernel_offset,
                 CompileType* inferred_type,
                 CompileType* inferred_arg_type = nullptr,
                 const Object* inferred_arg_value = nullptr)
       : declaration_pos_(declaration_pos),
         token_pos_(token_pos),
         name_(name),
         kernel_offset_(kernel_offset),
         annotations_offset_(kNoKernelOffset),
         owner_(nullptr),
         static_type_(static_type),
         inferred_type_(inferred_type),
         inferred_arg_type_(inferred_arg_type),
         inferred_arg_value_(inferred_arg_value),
         covariance_mode_(kNotCovariant),
         late_init_offset_(0),
         type_check_mode_(kDoTypeCheck),
         index_(),
         is_awaiter_link_(IsAwaiterLink::kNotLink) {
     DEBUG_ASSERT(static_type.IsNotTemporaryScopedHandle());
     ASSERT(static_type.IsFinalized());
     ASSERT(inferred_type != nullptr);
     ASSERT(name.IsSymbol());
     if (IsFilteredIdentifier(name)) {
       set_invisible(true);
     }
   }

   TokenPosition token_pos() const { return token_pos_; }
   TokenPosition declaration_token_pos() const { return declaration_pos_; }
   const String& name() const { return name_; }
   intptr_t kernel_offset() const { return kernel_offset_; }
   intptr_t annotations_offset() const { return annotations_offset_; }
   LocalScope* owner() const { return owner_; }
   void set_owner(LocalScope* owner) {
     ASSERT(owner_ == nullptr);
     owner_ = owner;
   }

   void set_annotations_offset(intptr_t offset) {
     annotations_offset_ = offset;
     is_awaiter_link_ = (offset == kNoKernelOffset) ? IsAwaiterLink::kNotLink
                                                    : IsAwaiterLink::kUnknown;
   }

   const AbstractType& static_type() const { return static_type_; }

   CompileType* inferred_type() const { return inferred_type_; }
   CompileType* inferred_arg_type() const { return inferred_arg_type_; }
   const Object* inferred_arg_value() const { return inferred_arg_value_; }

   bool is_final() const { return IsFinalBit::decode(bitfield_); }
   void set_is_final() { bitfield_ = IsFinalBit::update(true, bitfield_); }

   bool is_captured() const { return IsCapturedBit::decode(bitfield_); }
   void set_is_captured() { bitfield_ = IsCapturedBit::update(true, bitfield_); }

   bool ComputeIfIsAwaiterLink(const Library& library);
   void set_is_awaiter_link(bool value) {
     is_awaiter_link_ = value ? IsAwaiterLink::kLink : IsAwaiterLink::kNotLink;
   }

   bool is_late() const { return IsLateBit::decode(bitfield_); }
   void set_is_late() { bitfield_ = IsLateBit::update(true, bitfield_); }

   intptr_t late_init_offset() const { return late_init_offset_; }
   void set_late_init_offset(intptr_t late_init_offset) {
     late_init_offset_ = late_init_offset;
   }

   bool is_explicit_covariant_parameter() const {
     return covariance_mode_ == kExplicit;
   }
   void set_is_explicit_covariant_parameter() { covariance_mode_ = kExplicit; }

   bool needs_covariant_check_in_method() const {
     return covariance_mode_ != kNotCovariant;
   }
   void set_needs_covariant_check_in_method() {
     if (covariance_mode_ == kNotCovariant) {
       covariance_mode_ = kImplicit;
     }
   }

   enum TypeCheckMode {
     kDoTypeCheck,
     kSkipTypeCheck,
     kTypeCheckedByCaller,
   };

   // Returns true if this local variable represents a parameter that needs type
   // check when we enter the function.
   bool needs_type_check() const { return (type_check_mode_ == kDoTypeCheck); }

   // Returns true if this local variable represents a parameter which type is
   // guaranteed by the caller.
   bool was_type_checked_by_caller() const {
     return type_check_mode_ == kTypeCheckedByCaller;
   }

   TypeCheckMode type_check_mode() const { return type_check_mode_; }
   void set_type_check_mode(TypeCheckMode mode) { type_check_mode_ = mode; }

   bool HasIndex() const { return index_.IsValid(); }
   VariableIndex index() const {
     ASSERT(HasIndex());
     return index_;
   }

   // Assign an index to a local.
   void set_index(VariableIndex index) {
     ASSERT(index.IsValid());
     index_ = index;
   }

   // Invisible variables are not included into LocalVarDescriptors
   // and not displayed in the debugger.
   bool is_invisible() const { return IsInvisibleBit::decode(bitfield_); }
   void set_invisible(bool value) {
     bitfield_ = IsInvisibleBit::update(value, bitfield_);
   }

   bool Equals(const LocalVariable& other) const;

   void PrintTo(BaseTextBuffer* f,
                const char* label = "variable",
                int depth = 0,
                const LocalScope* scope = nullptr) const;
   const char* ToCString() const;

  private:
   // If true, this variable is readonly.
   using IsFinalBit = BitField<uint32_t, bool, 0, 1>;
   // If true, this variable lives in the context, otherwise
   // in the stack frame.
   using IsCapturedBit = BitField<uint32_t, bool, IsFinalBit::kNextBit, 1>;
   using IsInvisibleBit = BitField<uint32_t, bool, IsCapturedBit::kNextBit, 1>;
   using IsLateBit = BitField<uint32_t, bool, IsInvisibleBit ::kNextBit, 1>;

   enum CovarianceMode {
     kNotCovariant,
     kImplicit,
     kExplicit,
   };

   static constexpr int kUninitializedIndex = INT_MIN;

   static bool IsFilteredIdentifier(const String& name);

   const TokenPosition declaration_pos_;
   const TokenPosition token_pos_;
   const String& name_;
   const intptr_t kernel_offset_;
   intptr_t annotations_offset_;
   LocalScope* owner_;  // Local scope declaring this variable.

   const AbstractType& static_type_;  // Declaration type of local variable.

   // Inferred variable type.
   CompileType* const inferred_type_;
   // nullptr or inferred type of incoming argument.
   CompileType* const inferred_arg_type_;
   // nullptr or inferred value of incoming argument.
   const Object* const inferred_arg_value_;

   uint32_t bitfield_ = 0;
   CovarianceMode covariance_mode_;
   intptr_t late_init_offset_;
   TypeCheckMode type_check_mode_;
   VariableIndex index_;

   enum class IsAwaiterLink {
     kUnknown,
     kNotLink,
     kLink,
   };
   IsAwaiterLink is_awaiter_link_;

   friend class LocalScope;
   DISALLOW_COPY_AND_ASSIGN(LocalVariable);
 };

 // Accumulates local variable descriptors while building
 // LocalVarDescriptors object.
 class LocalVarDescriptorsBuilder : public ValueObject {
  public:
   struct VarDesc {
     const String* name;
     UntaggedLocalVarDescriptors::VarInfo info;
   };

   LocalVarDescriptorsBuilder() : vars_(8) {}

   // Add variable descriptor.
   void Add(const VarDesc& var_desc) { vars_.Add(var_desc); }

   // Add all variable descriptors from given [LocalVarDescriptors] object.
   void AddAll(Zone* zone, const LocalVarDescriptors& var_descs);

   // Record deopt-id -> context-level mappings, using ranges of deopt-ids with
   // the same context-level. [context_level_array] contains (deopt_id,
   // context_level) tuples.
   void AddDeoptIdToContextLevelMappings(
       ZoneGrowableArray<intptr_t>* context_level_array);

   // Finish building LocalVarDescriptor object.
   LocalVarDescriptorsPtr Done();

  private:
   GrowableArray<VarDesc> vars_;
 };

 class LocalScope : public ZoneAllocated {
  public:
   LocalScope(LocalScope* parent, int function_level, int loop_level);

   LocalScope* parent() const { return parent_; }
   LocalScope* child() const { return child_; }
   LocalScope* sibling() const { return sibling_; }
   int function_level() const { return function_level_; }
   int loop_level() const { return loop_level_; }

   // Check if this scope is nested within the passed in scope.
   bool IsNestedWithin(LocalScope* scope) const;

   // The context level is only set in a scope that is either the owner scope of
   // a captured variable or that is the owner scope of a context.
   bool HasContextLevel() const {
     return context_level_ != kUninitializedContextLevel;
   }
   int context_level() const {
     ASSERT(HasContextLevel());
     return context_level_;
   }
   void set_context_level(int context_level) {
     ASSERT(!HasContextLevel());
     ASSERT(context_level != kUninitializedContextLevel);
     context_level_ = context_level;
   }

   TokenPosition begin_token_pos() const { return begin_token_pos_; }
   void set_begin_token_pos(TokenPosition value) { begin_token_pos_ = value; }

   TokenPosition end_token_pos() const { return end_token_pos_; }
   void set_end_token_pos(TokenPosition value) { end_token_pos_ = value; }

   // Return the list of variables allocated in the context and belonging to this
   // scope and to its children at the same loop level.
   const GrowableArray<LocalVariable*>& context_variables() const {
     return context_variables_;
   }

   const ZoneGrowableArray<const Slot*>& context_slots() const {
     return *context_slots_;
   }

   // The number of variables allocated in the context and belonging to this
   // scope and to its children at the same loop level.
   int num_context_variables() const { return context_variables().length(); }

   // Add a variable to the scope. Returns false if a variable with the
   // same name and kernel offset is already present.
   bool AddVariable(LocalVariable* variable);

   // Add a variable to the scope as a context allocated variable and assigns
   // it an index within the context. Does not check if the scope already
   // contains this variable or a variable with the same name.
   void AddContextVariable(LocalVariable* var);

   // Insert a formal parameter variable to the scope at the given position,
   // possibly in front of aliases already added with AddVariable.
   // Returns false if a variable with the same name is already present.
   bool InsertParameterAt(intptr_t pos, LocalVariable* parameter);

   // Lookup a variable in this scope only.
   LocalVariable* LocalLookupVariable(const String& name,
                                      intptr_t kernel_offset) const;

   // Lookup a variable in this scope and its parents. If the variable
   // is found in a parent scope and 'test_only' is not true, we insert
   // aliases of the variable in the current and intermediate scopes up to
   // the declaration scope in order to detect "used before declared" errors.
   // We mark a variable as 'captured' when applicable.
   LocalVariable* LookupVariable(const String& name,
                                 intptr_t kernel_offset,
                                 bool test_only);

   // Lookup a variable in this scope and its parents by name.
   LocalVariable* LookupVariableByName(const String& name);

   // Mark this variable as captured by this scope.
   void CaptureVariable(LocalVariable* variable);

   // Accessing the variables in the scope.
   intptr_t num_variables() const { return variables_.length(); }
   LocalVariable* VariableAt(intptr_t index) const {
     ASSERT((index >= 0) && (index < variables_.length()));
     return variables_[index];
   }

   // Count the captured variables belonging to outer scopes and referenced in
   // this local scope.
   int NumCapturedVariables() const;

   // Allocate both captured and non-captured variables declared in this scope
   // and in its children scopes of the same function level. Allocating means
   // assigning a frame slot index or a context slot index.
   // Parameters to be allocated in the frame must all appear in the top scope
   // and not in its children (we do not yet handle register parameters).
   // Locals must be listed after parameters in top scope and in its children.
   // Two locals in different sibling scopes may share the same frame slot.
   //
   // Return the index of the next available frame slot.
   VariableIndex AllocateVariables(const Function& function,
                                   VariableIndex first_parameter_index,
                                   int num_parameters,
                                   VariableIndex first_local_index,
                                   LocalScope* context_owner,
                                   bool* found_captured_variables);

   // Creates variable info for the scope and all its nested scopes.
   // Must be called after AllocateVariables() has been called.
   LocalVarDescriptorsPtr GetVarDescriptors(
       const Function& func,
       ZoneGrowableArray<intptr_t>* context_level_array);

   // Create a ContextScope object describing all captured variables referenced
   // from this scope and belonging to outer scopes.
   ContextScopePtr PreserveOuterScope(const Function& function,
                                      intptr_t current_context_level) const;

   // Creates a LocalScope representing the outer scope of a local function to be
   // compiled. This outer scope contains the variables captured by the function
   // as specified by the given ContextScope, which was created during the
   // compilation of the enclosing function.
   static LocalScope* RestoreOuterScope(const ContextScope& context_scope);

   // Create a ContextScope object which will capture "this" for an implicit
   // closure object.
   static ContextScopePtr CreateImplicitClosureScope(const Function& func);

   void PrintTo(BaseTextBuffer* f, int depth = 0) const;
   const char* ToCString() const;

  private:
   // Allocate the variable in the current context, possibly updating the current
   // context owner scope, if the variable is the first one to be allocated at
   // this loop level.
   // The variable may belong to this scope or to any of its children, but at the
   // same loop level.
   void AllocateContextVariable(LocalVariable* variable,
                                LocalScope** context_owner);

   void CollectLocalVariables(LocalVarDescriptorsBuilder* vars,
                              int16_t* scope_id);

   static constexpr int kUninitializedContextLevel = INT_MIN;
   LocalScope* parent_;
   LocalScope* child_;
   LocalScope* sibling_;
   int function_level_;  // Reflects the nesting level of local functions.
   int loop_level_;      // Reflects the loop nesting level.
   int context_level_;   // Reflects the level of the runtime context.
   TokenPosition begin_token_pos_;  // Token index of beginning of scope.
   TokenPosition end_token_pos_;    // Token index of end of scope.
   GrowableArray<LocalVariable*> variables_;

   // List of variables allocated into the context which is owned by this scope,
   // and their corresponding Slots.
   GrowableArray<LocalVariable*> context_variables_;
   ZoneGrowableArray<const Slot*>* context_slots_;

   DISALLOW_COPY_AND_ASSIGN(LocalScope);
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_SCOPES_H_
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_VM_SCOPES_H_
	#define RUNTIME_VM_SCOPES_H_

	#include <limits>

	#include "platform/assert.h"
	#include "platform/globals.h"
	#include "vm/allocation.h"
	#include "vm/growable_array.h"
	#include "vm/object.h"
	#include "vm/raw_object.h"
	#include "vm/symbols.h"
	#include "vm/token.h"

	namespace dart {

	class CompileType;
	class LocalScope;
	class Slot;

	// Indices of [LocalVariable]s are abstract and have little todo with the
	// actual frame layout!
	//
	// There are generally 4 different kinds of [LocalVariable]s:
	//
	// a) [LocalVariable]s referring to a parameter: The indices for those
	// variables are assigned by the flow graph builder. Parameter n gets
	// assigned the index (function.num_parameters - n - 1). I.e. the last
	// parameter has index 1.
	//
	// b) [LocalVariable]s referring to actual variables in the body of a
	// function (either from Dart code or specially injected ones. The
	// indices of those variables are assigned by the scope builder
	// from 0, -1, ... -(M-1) for M local variables.
	//
	// -> These variables participate in full SSA renaming and can therefore
	// be used with [StoreLocalInstr]s (in addition to [LoadLocal]s).
	//
	// c) [LocalVariable]s referring to values on the expression stack. Those are
	// assigned by the flow graph builder. The indices of those variables are
	// assigned by the flow graph builder (it simulates the expression stack
	// height), they go from -NumVariables - ExpressionHeight.
	//
	// -> These variables participate only partially in SSA renaming and can
	// therefore only be used with [LoadLocalInstr]s and with
	// [StoreLocalInstr]s where no phis are necessary.
	//
	// b) [LocalVariable]s referring to captured variables. Those are never
	// loaded/stored directly. Their only purpose is to tell the flow graph
	// builder how many parent links to follow and into which context index to
	// store. The indices of those variables are assigned by the scope
	// builder and they refer to indices into context objects.
	class VariableIndex {
	public:
	static constexpr int kInvalidIndex = std::numeric_limits<int>::min();

	explicit VariableIndex(int value = kInvalidIndex) : value_(value) {}

	bool operator==(const VariableIndex& other) const {
	return value_ == other.value_;
	}

	bool IsValid() const { return value_ != kInvalidIndex; }

	int value() const { return value_; }

	private:
	int value_;
	};

	class LocalVariable : public ZoneAllocated {
	public:
	static constexpr intptr_t kNoKernelOffset = -1;

	LocalVariable(TokenPosition declaration_pos,
	TokenPosition token_pos,
	const String& name,
	const AbstractType& static_type,
	intptr_t kernel_offset = kNoKernelOffset);

	LocalVariable(TokenPosition declaration_pos,
	TokenPosition token_pos,
	const String& name,
	const AbstractType& static_type,
	intptr_t kernel_offset,
	CompileType* inferred_type,
	CompileType* inferred_arg_type = nullptr,
	const Object* inferred_arg_value = nullptr)
	: declaration_pos_(declaration_pos),
	token_pos_(token_pos),
	name_(name),
	kernel_offset_(kernel_offset),
	annotations_offset_(kNoKernelOffset),
	owner_(nullptr),
	static_type_(static_type),
	inferred_type_(inferred_type),
	inferred_arg_type_(inferred_arg_type),
	inferred_arg_value_(inferred_arg_value),
	covariance_mode_(kNotCovariant),
	late_init_offset_(0),
	type_check_mode_(kDoTypeCheck),
	index_(),
	is_awaiter_link_(IsAwaiterLink::kNotLink) {
	DEBUG_ASSERT(static_type.IsNotTemporaryScopedHandle());
	ASSERT(static_type.IsFinalized());
	ASSERT(inferred_type != nullptr);
	ASSERT(name.IsSymbol());
	if (IsFilteredIdentifier(name)) {
	set_invisible(true);
	}
	}

	TokenPosition token_pos() const { return token_pos_; }
	TokenPosition declaration_token_pos() const { return declaration_pos_; }
	const String& name() const { return name_; }
	intptr_t kernel_offset() const { return kernel_offset_; }
	intptr_t annotations_offset() const { return annotations_offset_; }
	LocalScope* owner() const { return owner_; }
	void set_owner(LocalScope* owner) {
	ASSERT(owner_ == nullptr);
	owner_ = owner;
	}

	void set_annotations_offset(intptr_t offset) {
	annotations_offset_ = offset;
	is_awaiter_link_ = (offset == kNoKernelOffset) ? IsAwaiterLink::kNotLink
	: IsAwaiterLink::kUnknown;
	}

	const AbstractType& static_type() const { return static_type_; }

	CompileType* inferred_type() const { return inferred_type_; }
	CompileType* inferred_arg_type() const { return inferred_arg_type_; }
	const Object* inferred_arg_value() const { return inferred_arg_value_; }

	bool is_final() const { return IsFinalBit::decode(bitfield_); }
	void set_is_final() { bitfield_ = IsFinalBit::update(true, bitfield_); }

	bool is_captured() const { return IsCapturedBit::decode(bitfield_); }
	void set_is_captured() { bitfield_ = IsCapturedBit::update(true, bitfield_); }

	bool ComputeIfIsAwaiterLink(const Library& library);
	void set_is_awaiter_link(bool value) {
	is_awaiter_link_ = value ? IsAwaiterLink::kLink : IsAwaiterLink::kNotLink;
	}

	bool is_late() const { return IsLateBit::decode(bitfield_); }
	void set_is_late() { bitfield_ = IsLateBit::update(true, bitfield_); }

	intptr_t late_init_offset() const { return late_init_offset_; }
	void set_late_init_offset(intptr_t late_init_offset) {
	late_init_offset_ = late_init_offset;
	}

	bool is_explicit_covariant_parameter() const {
	return covariance_mode_ == kExplicit;
	}
	void set_is_explicit_covariant_parameter() { covariance_mode_ = kExplicit; }

	bool needs_covariant_check_in_method() const {
	return covariance_mode_ != kNotCovariant;
	}
	void set_needs_covariant_check_in_method() {
	if (covariance_mode_ == kNotCovariant) {
	covariance_mode_ = kImplicit;
	}
	}

	enum TypeCheckMode {
	kDoTypeCheck,
	kSkipTypeCheck,
	kTypeCheckedByCaller,
	};

	// Returns true if this local variable represents a parameter that needs type
	// check when we enter the function.
	bool needs_type_check() const { return (type_check_mode_ == kDoTypeCheck); }

	// Returns true if this local variable represents a parameter which type is
	// guaranteed by the caller.
	bool was_type_checked_by_caller() const {
	return type_check_mode_ == kTypeCheckedByCaller;
	}

	TypeCheckMode type_check_mode() const { return type_check_mode_; }
	void set_type_check_mode(TypeCheckMode mode) { type_check_mode_ = mode; }

	bool HasIndex() const { return index_.IsValid(); }
	VariableIndex index() const {
	ASSERT(HasIndex());
	return index_;
	}

	// Assign an index to a local.
	void set_index(VariableIndex index) {
	ASSERT(index.IsValid());
	index_ = index;
	}

	// Invisible variables are not included into LocalVarDescriptors
	// and not displayed in the debugger.
	bool is_invisible() const { return IsInvisibleBit::decode(bitfield_); }
	void set_invisible(bool value) {
	bitfield_ = IsInvisibleBit::update(value, bitfield_);
	}

	bool Equals(const LocalVariable& other) const;

	void PrintTo(BaseTextBuffer* f,
	const char* label = "variable",
	int depth = 0,
	const LocalScope* scope = nullptr) const;
	const char* ToCString() const;

	private:
	// If true, this variable is readonly.
	using IsFinalBit = BitField<uint32_t, bool, 0, 1>;
	// If true, this variable lives in the context, otherwise
	// in the stack frame.
	using IsCapturedBit = BitField<uint32_t, bool, IsFinalBit::kNextBit, 1>;
	using IsInvisibleBit = BitField<uint32_t, bool, IsCapturedBit::kNextBit, 1>;
	using IsLateBit = BitField<uint32_t, bool, IsInvisibleBit ::kNextBit, 1>;

	enum CovarianceMode {
	kNotCovariant,
	kImplicit,
	kExplicit,
	};

	static constexpr int kUninitializedIndex = INT_MIN;

	static bool IsFilteredIdentifier(const String& name);

	const TokenPosition declaration_pos_;
	const TokenPosition token_pos_;
	const String& name_;
	const intptr_t kernel_offset_;
	intptr_t annotations_offset_;
	LocalScope* owner_; // Local scope declaring this variable.

	const AbstractType& static_type_; // Declaration type of local variable.

	// Inferred variable type.
	CompileType* const inferred_type_;
	// nullptr or inferred type of incoming argument.
	CompileType* const inferred_arg_type_;
	// nullptr or inferred value of incoming argument.
	const Object* const inferred_arg_value_;

	uint32_t bitfield_ = 0;
	CovarianceMode covariance_mode_;
	intptr_t late_init_offset_;
	TypeCheckMode type_check_mode_;
	VariableIndex index_;

	enum class IsAwaiterLink {
	kUnknown,
	kNotLink,
	kLink,
	};
	IsAwaiterLink is_awaiter_link_;

	friend class LocalScope;
	DISALLOW_COPY_AND_ASSIGN(LocalVariable);
	};

	// Accumulates local variable descriptors while building
	// LocalVarDescriptors object.
	class LocalVarDescriptorsBuilder : public ValueObject {
	public:
	struct VarDesc {
	const String* name;
	UntaggedLocalVarDescriptors::VarInfo info;
	};

	LocalVarDescriptorsBuilder() : vars_(8) {}

	// Add variable descriptor.
	void Add(const VarDesc& var_desc) { vars_.Add(var_desc); }

	// Add all variable descriptors from given [LocalVarDescriptors] object.
	void AddAll(Zone* zone, const LocalVarDescriptors& var_descs);

	// Record deopt-id -> context-level mappings, using ranges of deopt-ids with
	// the same context-level. [context_level_array] contains (deopt_id,
	// context_level) tuples.
	void AddDeoptIdToContextLevelMappings(
	ZoneGrowableArray<intptr_t>* context_level_array);

	// Finish building LocalVarDescriptor object.
	LocalVarDescriptorsPtr Done();

	private:
	GrowableArray<VarDesc> vars_;
	};

	class LocalScope : public ZoneAllocated {
	public:
	LocalScope(LocalScope* parent, int function_level, int loop_level);

	LocalScope* parent() const { return parent_; }
	LocalScope* child() const { return child_; }
	LocalScope* sibling() const { return sibling_; }
	int function_level() const { return function_level_; }
	int loop_level() const { return loop_level_; }

	// Check if this scope is nested within the passed in scope.
	bool IsNestedWithin(LocalScope* scope) const;

	// The context level is only set in a scope that is either the owner scope of
	// a captured variable or that is the owner scope of a context.
	bool HasContextLevel() const {
	return context_level_ != kUninitializedContextLevel;
	}
	int context_level() const {
	ASSERT(HasContextLevel());
	return context_level_;
	}
	void set_context_level(int context_level) {
	ASSERT(!HasContextLevel());
	ASSERT(context_level != kUninitializedContextLevel);
	context_level_ = context_level;
	}

	TokenPosition begin_token_pos() const { return begin_token_pos_; }
	void set_begin_token_pos(TokenPosition value) { begin_token_pos_ = value; }

	TokenPosition end_token_pos() const { return end_token_pos_; }
	void set_end_token_pos(TokenPosition value) { end_token_pos_ = value; }

	// Return the list of variables allocated in the context and belonging to this
	// scope and to its children at the same loop level.
	const GrowableArray<LocalVariable*>& context_variables() const {
	return context_variables_;
	}

	const ZoneGrowableArray<const Slot*>& context_slots() const {
	return *context_slots_;
	}

	// The number of variables allocated in the context and belonging to this
	// scope and to its children at the same loop level.
	int num_context_variables() const { return context_variables().length(); }

	// Add a variable to the scope. Returns false if a variable with the
	// same name and kernel offset is already present.
	bool AddVariable(LocalVariable* variable);

	// Add a variable to the scope as a context allocated variable and assigns
	// it an index within the context. Does not check if the scope already
	// contains this variable or a variable with the same name.
	void AddContextVariable(LocalVariable* var);

	// Insert a formal parameter variable to the scope at the given position,
	// possibly in front of aliases already added with AddVariable.
	// Returns false if a variable with the same name is already present.
	bool InsertParameterAt(intptr_t pos, LocalVariable* parameter);

	// Lookup a variable in this scope only.
	LocalVariable* LocalLookupVariable(const String& name,
	intptr_t kernel_offset) const;

	// Lookup a variable in this scope and its parents. If the variable
	// is found in a parent scope and 'test_only' is not true, we insert
	// aliases of the variable in the current and intermediate scopes up to
	// the declaration scope in order to detect "used before declared" errors.
	// We mark a variable as 'captured' when applicable.
	LocalVariable* LookupVariable(const String& name,
	intptr_t kernel_offset,
	bool test_only);

	// Lookup a variable in this scope and its parents by name.
	LocalVariable* LookupVariableByName(const String& name);

	// Mark this variable as captured by this scope.
	void CaptureVariable(LocalVariable* variable);

	// Accessing the variables in the scope.
	intptr_t num_variables() const { return variables_.length(); }
	LocalVariable* VariableAt(intptr_t index) const {
	ASSERT((index >= 0) && (index < variables_.length()));
	return variables_[index];
	}

	// Count the captured variables belonging to outer scopes and referenced in
	// this local scope.
	int NumCapturedVariables() const;

	// Allocate both captured and non-captured variables declared in this scope
	// and in its children scopes of the same function level. Allocating means
	// assigning a frame slot index or a context slot index.
	// Parameters to be allocated in the frame must all appear in the top scope
	// and not in its children (we do not yet handle register parameters).
	// Locals must be listed after parameters in top scope and in its children.
	// Two locals in different sibling scopes may share the same frame slot.
	//
	// Return the index of the next available frame slot.
	VariableIndex AllocateVariables(const Function& function,
	VariableIndex first_parameter_index,
	int num_parameters,
	VariableIndex first_local_index,
	LocalScope* context_owner,
	bool* found_captured_variables);

	// Creates variable info for the scope and all its nested scopes.
	// Must be called after AllocateVariables() has been called.
	LocalVarDescriptorsPtr GetVarDescriptors(
	const Function& func,
	ZoneGrowableArray<intptr_t>* context_level_array);

	// Create a ContextScope object describing all captured variables referenced
	// from this scope and belonging to outer scopes.
	ContextScopePtr PreserveOuterScope(const Function& function,
	intptr_t current_context_level) const;

	// Creates a LocalScope representing the outer scope of a local function to be
	// compiled. This outer scope contains the variables captured by the function
	// as specified by the given ContextScope, which was created during the
	// compilation of the enclosing function.
	static LocalScope* RestoreOuterScope(const ContextScope& context_scope);

	// Create a ContextScope object which will capture "this" for an implicit
	// closure object.
	static ContextScopePtr CreateImplicitClosureScope(const Function& func);

	void PrintTo(BaseTextBuffer* f, int depth = 0) const;
	const char* ToCString() const;

	private:
	// Allocate the variable in the current context, possibly updating the current
	// context owner scope, if the variable is the first one to be allocated at
	// this loop level.
	// The variable may belong to this scope or to any of its children, but at the
	// same loop level.
	void AllocateContextVariable(LocalVariable* variable,
	LocalScope** context_owner);

	void CollectLocalVariables(LocalVarDescriptorsBuilder* vars,
	int16_t* scope_id);

	static constexpr int kUninitializedContextLevel = INT_MIN;
	LocalScope* parent_;
	LocalScope* child_;
	LocalScope* sibling_;
	int function_level_; // Reflects the nesting level of local functions.
	int loop_level_; // Reflects the loop nesting level.
	int context_level_; // Reflects the level of the runtime context.
	TokenPosition begin_token_pos_; // Token index of beginning of scope.
	TokenPosition end_token_pos_; // Token index of end of scope.
	GrowableArray<LocalVariable*> variables_;

	// List of variables allocated into the context which is owned by this scope,
	// and their corresponding Slots.
	GrowableArray<LocalVariable*> context_variables_;
	ZoneGrowableArray<const Slot> context_slots_;

	DISALLOW_COPY_AND_ASSIGN(LocalScope);
	};

	} // namespace dart

	#endif // RUNTIME_VM_SCOPES_H_