arm/usr/include/clang/Analysis/FlowSensitive/DataflowEnvironment.h - manifest_repos/toolchain - Git at Google

 //===-- DataflowEnvironment.h -----------------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file defines an Environment class that is used by dataflow analyses
 //  that run over Control-Flow Graphs (CFGs) to keep track of the state of the
 //  program at given program points.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWENVIRONMENT_H
 #define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWENVIRONMENT_H

 #include "clang/AST/Decl.h"
 #include "clang/AST/DeclBase.h"
 #include "clang/AST/Expr.h"
 #include "clang/AST/Type.h"
 #include "clang/AST/TypeOrdering.h"
 #include "clang/Analysis/FlowSensitive/DataflowAnalysisContext.h"
 #include "clang/Analysis/FlowSensitive/DataflowLattice.h"
 #include "clang/Analysis/FlowSensitive/StorageLocation.h"
 #include "clang/Analysis/FlowSensitive/Value.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/DenseSet.h"
 #include <memory>
 #include <type_traits>
 #include <utility>

 namespace clang {
 namespace dataflow {

 /// Indicates what kind of indirections should be skipped past when retrieving
 /// storage locations or values.
 ///
 /// FIXME: Consider renaming this or replacing it with a more appropriate model.
 /// See the discussion in https://reviews.llvm.org/D116596 for context.
 enum class SkipPast {
   /// No indirections should be skipped past.
   None,
   /// An optional reference should be skipped past.
   Reference,
   /// An optional reference should be skipped past, then an optional pointer
   /// should be skipped past.
   ReferenceThenPointer,
 };

 /// Holds the state of the program (store and heap) at a given program point.
 ///
 /// WARNING: Symbolic values that are created by the environment for static
 /// local and global variables are not currently invalidated on function calls.
 /// This is unsound and should be taken into account when designing dataflow
 /// analyses.
 class Environment {
 public:
   /// Supplements `Environment` with non-standard comparison and join
   /// operations.
   class ValueModel {
   public:
     virtual ~ValueModel() = default;

     /// Returns true if and only if `Val1` is equivalent to `Val2`.
     ///
     /// Requirements:
     ///
     ///  `Val1` and `Val2` must be distinct.
     ///
     ///  `Val1` and `Val2` must model values of type `Type`.
     ///
     ///  `Val1` and `Val2` must be assigned to the same storage location in
     ///  `Env1` and `Env2` respectively.
     virtual bool compareEquivalent(QualType Type, const Value &Val1,
                                    const Environment &Env1, const Value &Val2,
                                    const Environment &Env2) {
       // FIXME: Consider adding QualType to StructValue and removing the Type
       // argument here.
       //
       // FIXME: default to a sound comparison and/or expand the comparison logic
       // built into the framework to support broader forms of equivalence than
       // strict pointer equality.
       return true;
     }

     /// Modifies `MergedVal` to approximate both `Val1` and `Val2`. This could
     /// be a strict lattice join or a more general widening operation.
     ///
     /// If this function returns true, `MergedVal` will be assigned to a storage
     /// location of type `Type` in `MergedEnv`.
     ///
     /// `Env1` and `Env2` can be used to query child values and path condition
     /// implications of `Val1` and `Val2` respectively.
     ///
     /// Requirements:
     ///
     ///  `Val1` and `Val2` must be distinct.
     ///
     ///  `Val1`, `Val2`, and `MergedVal` must model values of type `Type`.
     ///
     ///  `Val1` and `Val2` must be assigned to the same storage location in
     ///  `Env1` and `Env2` respectively.
     virtual bool merge(QualType Type, const Value &Val1,
                        const Environment &Env1, const Value &Val2,
                        const Environment &Env2, Value &MergedVal,
                        Environment &MergedEnv) {
       return true;
     }
   };

   /// Creates an environment that uses `DACtx` to store objects that encompass
   /// the state of a program.
   explicit Environment(DataflowAnalysisContext &DACtx);

   Environment(const Environment &Other);
   Environment &operator=(const Environment &Other);

   Environment(Environment &&Other) = default;
   Environment &operator=(Environment &&Other) = default;

   /// Creates an environment that uses `DACtx` to store objects that encompass
   /// the state of a program.
   ///
   /// If `DeclCtx` is a function, initializes the environment with symbolic
   /// representations of the function parameters.
   ///
   /// If `DeclCtx` is a non-static member function, initializes the environment
   /// with a symbolic representation of the `this` pointee.
   Environment(DataflowAnalysisContext &DACtx, const DeclContext &DeclCtx);

   /// Returns true if and only if the environment is equivalent to `Other`, i.e
   /// the two environments:
   ///  - have the same mappings from declarations to storage locations,
   ///  - have the same mappings from expressions to storage locations,
   ///  - have the same or equivalent (according to `Model`) values assigned to
   ///    the same storage locations.
   ///
   /// Requirements:
   ///
   ///  `Other` and `this` must use the same `DataflowAnalysisContext`.
   bool equivalentTo(const Environment &Other,
                     Environment::ValueModel &Model) const;

   /// Joins the environment with `Other` by taking the intersection of storage
   /// locations and values that are stored in them. Distinct values that are
   /// assigned to the same storage locations in the environment and `Other` are
   /// merged using `Model`.
   ///
   /// Requirements:
   ///
   ///  `Other` and `this` must use the same `DataflowAnalysisContext`.
   LatticeJoinEffect join(const Environment &Other,
                          Environment::ValueModel &Model);

   // FIXME: Rename `createOrGetStorageLocation` to `getOrCreateStorageLocation`,
   // `getStableStorageLocation`, or something more appropriate.

   /// Creates a storage location appropriate for `Type`. Does not assign a value
   /// to the returned storage location in the environment.
   ///
   /// Requirements:
   ///
   ///  `Type` must not be null.
   StorageLocation &createStorageLocation(QualType Type);

   /// Creates a storage location for `D`. Does not assign the returned storage
   /// location to `D` in the environment. Does not assign a value to the
   /// returned storage location in the environment.
   StorageLocation &createStorageLocation(const VarDecl &D);

   /// Creates a storage location for `E`. Does not assign the returned storage
   /// location to `E` in the environment. Does not assign a value to the
   /// returned storage location in the environment.
   StorageLocation &createStorageLocation(const Expr &E);

   /// Assigns `Loc` as the storage location of `D` in the environment.
   ///
   /// Requirements:
   ///
   ///  `D` must not be assigned a storage location in the environment.
   void setStorageLocation(const ValueDecl &D, StorageLocation &Loc);

   /// Returns the storage location assigned to `D` in the environment, applying
   /// the `SP` policy for skipping past indirections, or null if `D` isn't
   /// assigned a storage location in the environment.
   StorageLocation *getStorageLocation(const ValueDecl &D, SkipPast SP) const;

   /// Assigns `Loc` as the storage location of `E` in the environment.
   ///
   /// Requirements:
   ///
   ///  `E` must not be assigned a storage location in the environment.
   void setStorageLocation(const Expr &E, StorageLocation &Loc);

   /// Returns the storage location assigned to `E` in the environment, applying
   /// the `SP` policy for skipping past indirections, or null if `E` isn't
   /// assigned a storage location in the environment.
   StorageLocation *getStorageLocation(const Expr &E, SkipPast SP) const;

   /// Returns the storage location assigned to the `this` pointee in the
   /// environment or null if the `this` pointee has no assigned storage location
   /// in the environment.
   StorageLocation *getThisPointeeStorageLocation() const;

   /// Creates a value appropriate for `Type`, if `Type` is supported, otherwise
   /// return null. If `Type` is a pointer or reference type, creates all the
   /// necessary storage locations and values for indirections until it finds a
   /// non-pointer/non-reference type.
   ///
   /// Requirements:
   ///
   ///  `Type` must not be null.
   Value *createValue(QualType Type);

   /// Assigns `Val` as the value of `Loc` in the environment.
   void setValue(const StorageLocation &Loc, Value &Val);

   /// Returns the value assigned to `Loc` in the environment or null if `Loc`
   /// isn't assigned a value in the environment.
   Value *getValue(const StorageLocation &Loc) const;

   /// Equivalent to `getValue(getStorageLocation(D, SP), SkipPast::None)` if `D`
   /// is assigned a storage location in the environment, otherwise returns null.
   Value *getValue(const ValueDecl &D, SkipPast SP) const;

   /// Equivalent to `getValue(getStorageLocation(E, SP), SkipPast::None)` if `E`
   /// is assigned a storage location in the environment, otherwise returns null.
   Value *getValue(const Expr &E, SkipPast SP) const;

   /// Transfers ownership of `Loc` to the analysis context and returns a
   /// reference to it.
   ///
   /// Requirements:
   ///
   ///  `Loc` must not be null.
   template <typename T>
   typename std::enable_if<std::is_base_of<StorageLocation, T>::value, T &>::type
   takeOwnership(std::unique_ptr<T> Loc) {
     return DACtx->takeOwnership(std::move(Loc));
   }

   /// Transfers ownership of `Val` to the analysis context and returns a
   /// reference to it.
   ///
   /// Requirements:
   ///
   ///  `Val` must not be null.
   template <typename T>
   typename std::enable_if<std::is_base_of<Value, T>::value, T &>::type
   takeOwnership(std::unique_ptr<T> Val) {
     return DACtx->takeOwnership(std::move(Val));
   }

   /// Returns a symbolic boolean value that models a boolean literal equal to
   /// `Value`
   AtomicBoolValue &getBoolLiteralValue(bool Value) const {
     return DACtx->getBoolLiteralValue(Value);
   }

   /// Returns an atomic boolean value.
   BoolValue &makeAtomicBoolValue() const {
     return DACtx->createAtomicBoolValue();
   }

   /// Returns a boolean value that represents the conjunction of `LHS` and
   /// `RHS`. Subsequent calls with the same arguments, regardless of their
   /// order, will return the same result. If the given boolean values represent
   /// the same value, the result will be the value itself.
   BoolValue &makeAnd(BoolValue &LHS, BoolValue &RHS) const {
     return DACtx->getOrCreateConjunctionValue(LHS, RHS);
   }

   /// Returns a boolean value that represents the disjunction of `LHS` and
   /// `RHS`. Subsequent calls with the same arguments, regardless of their
   /// order, will return the same result. If the given boolean values represent
   /// the same value, the result will be the value itself.
   BoolValue &makeOr(BoolValue &LHS, BoolValue &RHS) const {
     return DACtx->getOrCreateDisjunctionValue(LHS, RHS);
   }

   /// Returns a boolean value that represents the negation of `Val`. Subsequent
   /// calls with the same argument will return the same result.
   BoolValue &makeNot(BoolValue &Val) const {
     return DACtx->getOrCreateNegationValue(Val);
   }

   /// Returns a boolean value represents `LHS` => `RHS`. Subsequent calls with
   /// the same arguments, regardless of their order, will return the same
   /// result. If the given boolean values represent the same value, the result
   /// will be a value that represents the true boolean literal.
   BoolValue &makeImplication(BoolValue &LHS, BoolValue &RHS) const {
     return &LHS == &RHS ? getBoolLiteralValue(true) : makeOr(makeNot(LHS), RHS);
   }

   /// Returns a boolean value represents `LHS` <=> `RHS`. Subsequent calls with
   /// the same arguments, regardless of their order, will return the same
   /// result. If the given boolean values represent the same value, the result
   /// will be a value that represents the true boolean literal.
   BoolValue &makeIff(BoolValue &LHS, BoolValue &RHS) const {
     return &LHS == &RHS
                ? getBoolLiteralValue(true)
                : makeAnd(makeImplication(LHS, RHS), makeImplication(RHS, LHS));
   }

   /// Returns the token that identifies the flow condition of the environment.
   AtomicBoolValue &getFlowConditionToken() const { return *FlowConditionToken; }

   /// Adds `Val` to the set of clauses that constitute the flow condition.
   void addToFlowCondition(BoolValue &Val);

   /// Returns true if and only if the clauses that constitute the flow condition
   /// imply that `Val` is true.
   bool flowConditionImplies(BoolValue &Val) const;

 private:
   /// Creates a value appropriate for `Type`, if `Type` is supported, otherwise
   /// return null.
   ///
   /// Recursively initializes storage locations and values until it sees a
   /// self-referential pointer or reference type. `Visited` is used to track
   /// which types appeared in the reference/pointer chain in order to avoid
   /// creating a cyclic dependency with self-referential pointers/references.
   ///
   /// Requirements:
   ///
   ///  `Type` must not be null.
   Value *createValueUnlessSelfReferential(QualType Type,
                                           llvm::DenseSet<QualType> &Visited,
                                           int Depth, int &CreatedValuesCount);

   StorageLocation &skip(StorageLocation &Loc, SkipPast SP) const;
   const StorageLocation &skip(const StorageLocation &Loc, SkipPast SP) const;

   // `DACtx` is not null and not owned by this object.
   DataflowAnalysisContext *DACtx;

   // Maps from program declarations and statements to storage locations that are
   // assigned to them. Unlike the maps in `DataflowAnalysisContext`, these
   // include only storage locations that are in scope for a particular basic
   // block.
   llvm::DenseMap<const ValueDecl *, StorageLocation *> DeclToLoc;
   llvm::DenseMap<const Expr *, StorageLocation *> ExprToLoc;

   llvm::DenseMap<const StorageLocation *, Value *> LocToVal;

   // Maps locations of struct members to symbolic values of the structs that own
   // them and the decls of the struct members.
   llvm::DenseMap<const StorageLocation *,
                  std::pair<StructValue *, const ValueDecl *>>
       MemberLocToStruct;

   AtomicBoolValue *FlowConditionToken;
 };

 } // namespace dataflow
 } // namespace clang

 #endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWENVIRONMENT_H
	//===-- DataflowEnvironment.h ------------------------------------ C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines an Environment class that is used by dataflow analyses
	// that run over Control-Flow Graphs (CFGs) to keep track of the state of the
	// program at given program points.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWENVIRONMENT_H
	#define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWENVIRONMENT_H

	#include "clang/AST/Decl.h"
	#include "clang/AST/DeclBase.h"
	#include "clang/AST/Expr.h"
	#include "clang/AST/Type.h"
	#include "clang/AST/TypeOrdering.h"
	#include "clang/Analysis/FlowSensitive/DataflowAnalysisContext.h"
	#include "clang/Analysis/FlowSensitive/DataflowLattice.h"
	#include "clang/Analysis/FlowSensitive/StorageLocation.h"
	#include "clang/Analysis/FlowSensitive/Value.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/DenseSet.h"
	#include <memory>
	#include <type_traits>
	#include <utility>

	namespace clang {
	namespace dataflow {

	/// Indicates what kind of indirections should be skipped past when retrieving
	/// storage locations or values.
	///
	/// FIXME: Consider renaming this or replacing it with a more appropriate model.
	/// See the discussion in https://reviews.llvm.org/D116596 for context.
	enum class SkipPast {
	/// No indirections should be skipped past.
	None,
	/// An optional reference should be skipped past.
	Reference,
	/// An optional reference should be skipped past, then an optional pointer
	/// should be skipped past.
	ReferenceThenPointer,
	};

	/// Holds the state of the program (store and heap) at a given program point.
	///
	/// WARNING: Symbolic values that are created by the environment for static
	/// local and global variables are not currently invalidated on function calls.
	/// This is unsound and should be taken into account when designing dataflow
	/// analyses.
	class Environment {
	public:
	/// Supplements `Environment` with non-standard comparison and join
	/// operations.
	class ValueModel {
	public:
	virtual ~ValueModel() = default;

	/// Returns true if and only if `Val1` is equivalent to `Val2`.
	///
	/// Requirements:
	///
	/// `Val1` and `Val2` must be distinct.
	///
	/// `Val1` and `Val2` must model values of type `Type`.
	///
	/// `Val1` and `Val2` must be assigned to the same storage location in
	/// `Env1` and `Env2` respectively.
	virtual bool compareEquivalent(QualType Type, const Value &Val1,
	const Environment &Env1, const Value &Val2,
	const Environment &Env2) {
	// FIXME: Consider adding QualType to StructValue and removing the Type
	// argument here.
	//
	// FIXME: default to a sound comparison and/or expand the comparison logic
	// built into the framework to support broader forms of equivalence than
	// strict pointer equality.
	return true;
	}

	/// Modifies `MergedVal` to approximate both `Val1` and `Val2`. This could
	/// be a strict lattice join or a more general widening operation.
	///
	/// If this function returns true, `MergedVal` will be assigned to a storage
	/// location of type `Type` in `MergedEnv`.
	///
	/// `Env1` and `Env2` can be used to query child values and path condition
	/// implications of `Val1` and `Val2` respectively.
	///
	/// Requirements:
	///
	/// `Val1` and `Val2` must be distinct.
	///
	/// `Val1`, `Val2`, and `MergedVal` must model values of type `Type`.
	///
	/// `Val1` and `Val2` must be assigned to the same storage location in
	/// `Env1` and `Env2` respectively.
	virtual bool merge(QualType Type, const Value &Val1,
	const Environment &Env1, const Value &Val2,
	const Environment &Env2, Value &MergedVal,
	Environment &MergedEnv) {
	return true;
	}
	};

	/// Creates an environment that uses `DACtx` to store objects that encompass
	/// the state of a program.
	explicit Environment(DataflowAnalysisContext &DACtx);

	Environment(const Environment &Other);
	Environment &operator=(const Environment &Other);

	Environment(Environment &&Other) = default;
	Environment &operator=(Environment &&Other) = default;

	/// Creates an environment that uses `DACtx` to store objects that encompass
	/// the state of a program.
	///
	/// If `DeclCtx` is a function, initializes the environment with symbolic
	/// representations of the function parameters.
	///
	/// If `DeclCtx` is a non-static member function, initializes the environment
	/// with a symbolic representation of the `this` pointee.
	Environment(DataflowAnalysisContext &DACtx, const DeclContext &DeclCtx);

	/// Returns true if and only if the environment is equivalent to `Other`, i.e
	/// the two environments:
	/// - have the same mappings from declarations to storage locations,
	/// - have the same mappings from expressions to storage locations,
	/// - have the same or equivalent (according to `Model`) values assigned to
	/// the same storage locations.
	///
	/// Requirements:
	///
	/// `Other` and `this` must use the same `DataflowAnalysisContext`.
	bool equivalentTo(const Environment &Other,
	Environment::ValueModel &Model) const;

	/// Joins the environment with `Other` by taking the intersection of storage
	/// locations and values that are stored in them. Distinct values that are
	/// assigned to the same storage locations in the environment and `Other` are
	/// merged using `Model`.
	///
	/// Requirements:
	///
	/// `Other` and `this` must use the same `DataflowAnalysisContext`.
	LatticeJoinEffect join(const Environment &Other,
	Environment::ValueModel &Model);

	// FIXME: Rename `createOrGetStorageLocation` to `getOrCreateStorageLocation`,
	// `getStableStorageLocation`, or something more appropriate.

	/// Creates a storage location appropriate for `Type`. Does not assign a value
	/// to the returned storage location in the environment.
	///
	/// Requirements:
	///
	/// `Type` must not be null.
	StorageLocation &createStorageLocation(QualType Type);

	/// Creates a storage location for `D`. Does not assign the returned storage
	/// location to `D` in the environment. Does not assign a value to the
	/// returned storage location in the environment.
	StorageLocation &createStorageLocation(const VarDecl &D);

	/// Creates a storage location for `E`. Does not assign the returned storage
	/// location to `E` in the environment. Does not assign a value to the
	/// returned storage location in the environment.
	StorageLocation &createStorageLocation(const Expr &E);

	/// Assigns `Loc` as the storage location of `D` in the environment.
	///
	/// Requirements:
	///
	/// `D` must not be assigned a storage location in the environment.
	void setStorageLocation(const ValueDecl &D, StorageLocation &Loc);

	/// Returns the storage location assigned to `D` in the environment, applying
	/// the `SP` policy for skipping past indirections, or null if `D` isn't
	/// assigned a storage location in the environment.
	StorageLocation *getStorageLocation(const ValueDecl &D, SkipPast SP) const;

	/// Assigns `Loc` as the storage location of `E` in the environment.
	///
	/// Requirements:
	///
	/// `E` must not be assigned a storage location in the environment.
	void setStorageLocation(const Expr &E, StorageLocation &Loc);

	/// Returns the storage location assigned to `E` in the environment, applying
	/// the `SP` policy for skipping past indirections, or null if `E` isn't
	/// assigned a storage location in the environment.
	StorageLocation *getStorageLocation(const Expr &E, SkipPast SP) const;

	/// Returns the storage location assigned to the `this` pointee in the
	/// environment or null if the `this` pointee has no assigned storage location
	/// in the environment.
	StorageLocation *getThisPointeeStorageLocation() const;

	/// Creates a value appropriate for `Type`, if `Type` is supported, otherwise
	/// return null. If `Type` is a pointer or reference type, creates all the
	/// necessary storage locations and values for indirections until it finds a
	/// non-pointer/non-reference type.
	///
	/// Requirements:
	///
	/// `Type` must not be null.
	Value *createValue(QualType Type);

	/// Assigns `Val` as the value of `Loc` in the environment.
	void setValue(const StorageLocation &Loc, Value &Val);

	/// Returns the value assigned to `Loc` in the environment or null if `Loc`
	/// isn't assigned a value in the environment.
	Value *getValue(const StorageLocation &Loc) const;

	/// Equivalent to `getValue(getStorageLocation(D, SP), SkipPast::None)` if `D`
	/// is assigned a storage location in the environment, otherwise returns null.
	Value *getValue(const ValueDecl &D, SkipPast SP) const;

	/// Equivalent to `getValue(getStorageLocation(E, SP), SkipPast::None)` if `E`
	/// is assigned a storage location in the environment, otherwise returns null.
	Value *getValue(const Expr &E, SkipPast SP) const;

	/// Transfers ownership of `Loc` to the analysis context and returns a
	/// reference to it.
	///
	/// Requirements:
	///
	/// `Loc` must not be null.
	template <typename T>
	typename std::enable_if<std::is_base_of<StorageLocation, T>::value, T &>::type
	takeOwnership(std::unique_ptr<T> Loc) {
	return DACtx->takeOwnership(std::move(Loc));
	}

	/// Transfers ownership of `Val` to the analysis context and returns a
	/// reference to it.
	///
	/// Requirements:
	///
	/// `Val` must not be null.
	template <typename T>
	typename std::enable_if<std::is_base_of<Value, T>::value, T &>::type
	takeOwnership(std::unique_ptr<T> Val) {
	return DACtx->takeOwnership(std::move(Val));
	}

	/// Returns a symbolic boolean value that models a boolean literal equal to
	/// `Value`
	AtomicBoolValue &getBoolLiteralValue(bool Value) const {
	return DACtx->getBoolLiteralValue(Value);
	}

	/// Returns an atomic boolean value.
	BoolValue &makeAtomicBoolValue() const {
	return DACtx->createAtomicBoolValue();
	}

	/// Returns a boolean value that represents the conjunction of `LHS` and
	/// `RHS`. Subsequent calls with the same arguments, regardless of their
	/// order, will return the same result. If the given boolean values represent
	/// the same value, the result will be the value itself.
	BoolValue &makeAnd(BoolValue &LHS, BoolValue &RHS) const {
	return DACtx->getOrCreateConjunctionValue(LHS, RHS);
	}

	/// Returns a boolean value that represents the disjunction of `LHS` and
	/// `RHS`. Subsequent calls with the same arguments, regardless of their
	/// order, will return the same result. If the given boolean values represent
	/// the same value, the result will be the value itself.
	BoolValue &makeOr(BoolValue &LHS, BoolValue &RHS) const {
	return DACtx->getOrCreateDisjunctionValue(LHS, RHS);
	}

	/// Returns a boolean value that represents the negation of `Val`. Subsequent
	/// calls with the same argument will return the same result.
	BoolValue &makeNot(BoolValue &Val) const {
	return DACtx->getOrCreateNegationValue(Val);
	}

	/// Returns a boolean value represents `LHS` => `RHS`. Subsequent calls with
	/// the same arguments, regardless of their order, will return the same
	/// result. If the given boolean values represent the same value, the result
	/// will be a value that represents the true boolean literal.
	BoolValue &makeImplication(BoolValue &LHS, BoolValue &RHS) const {
	return &LHS == &RHS ? getBoolLiteralValue(true) : makeOr(makeNot(LHS), RHS);
	}

	/// Returns a boolean value represents `LHS` <=> `RHS`. Subsequent calls with
	/// the same arguments, regardless of their order, will return the same
	/// result. If the given boolean values represent the same value, the result
	/// will be a value that represents the true boolean literal.
	BoolValue &makeIff(BoolValue &LHS, BoolValue &RHS) const {
	return &LHS == &RHS
	? getBoolLiteralValue(true)
	: makeAnd(makeImplication(LHS, RHS), makeImplication(RHS, LHS));
	}

	/// Returns the token that identifies the flow condition of the environment.
	AtomicBoolValue &getFlowConditionToken() const { return *FlowConditionToken; }

	/// Adds `Val` to the set of clauses that constitute the flow condition.
	void addToFlowCondition(BoolValue &Val);

	/// Returns true if and only if the clauses that constitute the flow condition
	/// imply that `Val` is true.
	bool flowConditionImplies(BoolValue &Val) const;

	private:
	/// Creates a value appropriate for `Type`, if `Type` is supported, otherwise
	/// return null.
	///
	/// Recursively initializes storage locations and values until it sees a
	/// self-referential pointer or reference type. `Visited` is used to track
	/// which types appeared in the reference/pointer chain in order to avoid
	/// creating a cyclic dependency with self-referential pointers/references.
	///
	/// Requirements:
	///
	/// `Type` must not be null.
	Value *createValueUnlessSelfReferential(QualType Type,
	llvm::DenseSet<QualType> &Visited,
	int Depth, int &CreatedValuesCount);

	StorageLocation &skip(StorageLocation &Loc, SkipPast SP) const;
	const StorageLocation &skip(const StorageLocation &Loc, SkipPast SP) const;

	// `DACtx` is not null and not owned by this object.
	DataflowAnalysisContext *DACtx;

	// Maps from program declarations and statements to storage locations that are
	// assigned to them. Unlike the maps in `DataflowAnalysisContext`, these
	// include only storage locations that are in scope for a particular basic
	// block.
	llvm::DenseMap<const ValueDecl , StorageLocation > DeclToLoc;
	llvm::DenseMap<const Expr , StorageLocation > ExprToLoc;

	llvm::DenseMap<const StorageLocation , Value > LocToVal;

	// Maps locations of struct members to symbolic values of the structs that own
	// them and the decls of the struct members.
	llvm::DenseMap<const StorageLocation *,
	std::pair<StructValue , const ValueDecl >>
	MemberLocToStruct;

	AtomicBoolValue *FlowConditionToken;
	};

	} // namespace dataflow
	} // namespace clang

	#endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWENVIRONMENT_H