clang-r468909b/include/clang/Analysis/FlowSensitive/DataflowAnalysisContext.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===-- DataflowAnalysisContext.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 a DataflowAnalysisContext class that owns objects that
 //  encompass the state of a program and stores context that is used during
 //  dataflow analysis.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWANALYSISCONTEXT_H
 #define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWANALYSISCONTEXT_H

 #include "clang/AST/Decl.h"
 #include "clang/AST/Expr.h"
 #include "clang/AST/TypeOrdering.h"
 #include "clang/Analysis/FlowSensitive/Solver.h"
 #include "clang/Analysis/FlowSensitive/StorageLocation.h"
 #include "clang/Analysis/FlowSensitive/Value.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/DenseSet.h"
 #include "llvm/Support/Compiler.h"
 #include <cassert>
 #include <memory>
 #include <type_traits>
 #include <utility>
 #include <vector>

 namespace clang {
 namespace dataflow {

 /// Skip past nodes that the CFG does not emit. These nodes are invisible to
 /// flow-sensitive analysis, and should be ignored as they will effectively not
 /// exist.
 ///
 ///   * `ParenExpr` - The CFG takes the operator precedence into account, but
 ///   otherwise omits the node afterwards.
 ///
 ///   * `ExprWithCleanups` - The CFG will generate the appropriate calls to
 ///   destructors and then omit the node.
 ///
 const Expr &ignoreCFGOmittedNodes(const Expr &E);
 const Stmt &ignoreCFGOmittedNodes(const Stmt &S);

 /// Returns the set of all fields in the type.
 llvm::DenseSet<const FieldDecl *> getObjectFields(QualType Type);

 /// Owns objects that encompass the state of a program and stores context that
 /// is used during dataflow analysis.
 class DataflowAnalysisContext {
 public:
   /// Constructs a dataflow analysis context.
   ///
   /// Requirements:
   ///
   ///  `S` must not be null.
   DataflowAnalysisContext(std::unique_ptr<Solver> S)
       : S(std::move(S)), TrueVal(createAtomicBoolValue()),
         FalseVal(createAtomicBoolValue()) {
     assert(this->S != nullptr);
   }

   /// Takes ownership of `Loc` 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) {
     assert(Loc != nullptr);
     Locs.push_back(std::move(Loc));
     return *cast<T>(Locs.back().get());
   }

   /// Takes ownership of `Val` 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) {
     assert(Val != nullptr);
     Vals.push_back(std::move(Val));
     return *cast<T>(Vals.back().get());
   }

   /// Returns a stable storage location appropriate for `Type`.
   ///
   /// Requirements:
   ///
   ///  `Type` must not be null.
   StorageLocation &getStableStorageLocation(QualType Type);

   /// Returns a stable storage location for `D`.
   StorageLocation &getStableStorageLocation(const VarDecl &D);

   /// Returns a stable storage location for `E`.
   StorageLocation &getStableStorageLocation(const Expr &E);

   /// Assigns `Loc` as the storage location of `D`.
   ///
   /// Requirements:
   ///
   ///  `D` must not be assigned a storage location.
   void setStorageLocation(const ValueDecl &D, StorageLocation &Loc) {
     assert(DeclToLoc.find(&D) == DeclToLoc.end());
     DeclToLoc[&D] = &Loc;
   }

   /// Returns the storage location assigned to `D` or null if `D` has no
   /// assigned storage location.
   StorageLocation *getStorageLocation(const ValueDecl &D) const {
     auto It = DeclToLoc.find(&D);
     return It == DeclToLoc.end() ? nullptr : It->second;
   }

   /// Assigns `Loc` as the storage location of `E`.
   ///
   /// Requirements:
   ///
   ///  `E` must not be assigned a storage location.
   void setStorageLocation(const Expr &E, StorageLocation &Loc) {
     const Expr &CanonE = ignoreCFGOmittedNodes(E);
     assert(ExprToLoc.find(&CanonE) == ExprToLoc.end());
     ExprToLoc[&CanonE] = &Loc;
   }

   /// Returns the storage location assigned to `E` or null if `E` has no
   /// assigned storage location.
   StorageLocation *getStorageLocation(const Expr &E) const {
     auto It = ExprToLoc.find(&ignoreCFGOmittedNodes(E));
     return It == ExprToLoc.end() ? nullptr : It->second;
   }

   /// Assigns `Loc` as the storage location of the `this` pointee.
   ///
   /// Requirements:
   ///
   ///  The `this` pointee must not be assigned a storage location.
   void setThisPointeeStorageLocation(StorageLocation &Loc) {
     assert(ThisPointeeLoc == nullptr);
     ThisPointeeLoc = &Loc;
   }

   /// Returns the storage location assigned to the `this` pointee or null if the
   /// `this` pointee has no assigned storage location.
   StorageLocation *getThisPointeeStorageLocation() const {
     return ThisPointeeLoc;
   }

   /// Returns a pointer value that represents a null pointer. Calls with
   /// `PointeeType` that are canonically equivalent will return the same result.
   /// A null `PointeeType` can be used for the pointee of `std::nullptr_t`.
   PointerValue &getOrCreateNullPointerValue(QualType PointeeType);

   /// Returns a symbolic boolean value that models a boolean literal equal to
   /// `Value`.
   AtomicBoolValue &getBoolLiteralValue(bool Value) const {
     return Value ? TrueVal : FalseVal;
   }

   /// Creates an atomic boolean value.
   AtomicBoolValue &createAtomicBoolValue() {
     return takeOwnership(std::make_unique<AtomicBoolValue>());
   }

   /// 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 &getOrCreateConjunction(BoolValue &LHS, BoolValue &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 &getOrCreateDisjunction(BoolValue &LHS, BoolValue &RHS);

   /// Returns a boolean value that represents the negation of `Val`. Subsequent
   /// calls with the same argument will return the same result.
   BoolValue &getOrCreateNegation(BoolValue &Val);

   /// Returns a boolean value that represents `LHS => RHS`. Subsequent calls
   /// with the same arguments, 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 &getOrCreateImplication(BoolValue &LHS, BoolValue &RHS);

   /// Returns a boolean value that 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 &getOrCreateIff(BoolValue &LHS, BoolValue &RHS);

   /// Creates a fresh flow condition and returns a token that identifies it. The
   /// token can be used to perform various operations on the flow condition such
   /// as adding constraints to it, forking it, joining it with another flow
   /// condition, or checking implications.
   AtomicBoolValue &makeFlowConditionToken();

   /// Adds `Constraint` to the flow condition identified by `Token`.
   void addFlowConditionConstraint(AtomicBoolValue &Token,
                                   BoolValue &Constraint);

   /// Creates a new flow condition with the same constraints as the flow
   /// condition identified by `Token` and returns its token.
   AtomicBoolValue &forkFlowCondition(AtomicBoolValue &Token);

   /// Creates a new flow condition that represents the disjunction of the flow
   /// conditions identified by `FirstToken` and `SecondToken`, and returns its
   /// token.
   AtomicBoolValue &joinFlowConditions(AtomicBoolValue &FirstToken,
                                       AtomicBoolValue &SecondToken);

   // FIXME: This function returns the flow condition expressed directly as its
   // constraints: (C1 AND C2 AND ...). This differs from the general approach in
   // the framework where a flow condition is represented as a token (an atomic
   // boolean) with dependencies and constraints tracked in `FlowConditionDeps`
   // and `FlowConditionConstraints`: (FC <=> C1 AND C2 AND ...).
   // Consider if we should make the representation of flow condition consistent,
   // returning an atomic boolean token with separate constraints instead.
   //
   /// Builds and returns the logical formula defining the flow condition
   /// identified by `Token`. If a value in the formula is present as a key in
   /// `Substitutions`, it will be substituted with the value it maps to.
   /// As an example, say we have flow condition tokens FC1, FC2, FC3 and
   /// FlowConditionConstraints: { FC1: C1,
   ///                             FC2: C2,
   ///                             FC3: (FC1 v FC2) ^ C3 }
   /// buildAndSubstituteFlowCondition(FC3, {{C1 -> C1'}}) will return a value
   /// corresponding to (C1' v C2) ^ C3.
   BoolValue &buildAndSubstituteFlowCondition(
       AtomicBoolValue &Token,
       llvm::DenseMap<AtomicBoolValue *, BoolValue *> Substitutions);

   /// Returns true if and only if the constraints of the flow condition
   /// identified by `Token` imply that `Val` is true.
   bool flowConditionImplies(AtomicBoolValue &Token, BoolValue &Val);

   /// Returns true if and only if the constraints of the flow condition
   /// identified by `Token` are always true.
   bool flowConditionIsTautology(AtomicBoolValue &Token);

   /// Returns true if `Val1` is equivalent to `Val2`.
   /// Note: This function doesn't take into account constraints on `Val1` and
   /// `Val2` imposed by the flow condition.
   bool equivalentBoolValues(BoolValue &Val1, BoolValue &Val2);

   LLVM_DUMP_METHOD void dumpFlowCondition(AtomicBoolValue &Token);

 private:
   struct NullableQualTypeDenseMapInfo : private llvm::DenseMapInfo<QualType> {
     static QualType getEmptyKey() {
       // Allow a NULL `QualType` by using a different value as the empty key.
       return QualType::getFromOpaquePtr(reinterpret_cast<Type *>(1));
     }

     using DenseMapInfo::getHashValue;
     using DenseMapInfo::getTombstoneKey;
     using DenseMapInfo::isEqual;
   };

   /// Adds all constraints of the flow condition identified by `Token` and all
   /// of its transitive dependencies to `Constraints`. `VisitedTokens` is used
   /// to track tokens of flow conditions that were already visited by recursive
   /// calls.
   void addTransitiveFlowConditionConstraints(
       AtomicBoolValue &Token, llvm::DenseSet<BoolValue *> &Constraints,
       llvm::DenseSet<AtomicBoolValue *> &VisitedTokens);

   /// Returns the outcome of satisfiability checking on `Constraints`.
   /// Possible outcomes are:
   /// - `Satisfiable`: A satisfying assignment exists and is returned.
   /// - `Unsatisfiable`: A satisfying assignment does not exist.
   /// - `TimedOut`: The search for a satisfying assignment was not completed.
   Solver::Result querySolver(llvm::DenseSet<BoolValue *> Constraints);

   /// Returns true if the solver is able to prove that there is no satisfying
   /// assignment for `Constraints`
   bool isUnsatisfiable(llvm::DenseSet<BoolValue *> Constraints) {
     return querySolver(std::move(Constraints)).getStatus() ==
            Solver::Result::Status::Unsatisfiable;
   }

   /// Returns a boolean value as a result of substituting `Val` and its sub
   /// values based on entries in `SubstitutionsCache`. Intermediate results are
   /// stored in `SubstitutionsCache` to avoid reprocessing values that have
   /// already been visited.
   BoolValue &substituteBoolValue(
       BoolValue &Val,
       llvm::DenseMap<BoolValue *, BoolValue *> &SubstitutionsCache);

   /// Builds and returns the logical formula defining the flow condition
   /// identified by `Token`, sub values may be substituted based on entries in
   /// `SubstitutionsCache`. Intermediate results are stored in
   /// `SubstitutionsCache` to avoid reprocessing values that have already been
   /// visited.
   BoolValue &buildAndSubstituteFlowConditionWithCache(
       AtomicBoolValue &Token,
       llvm::DenseMap<BoolValue *, BoolValue *> &SubstitutionsCache);

   std::unique_ptr<Solver> S;

   // Storage for the state of a program.
   std::vector<std::unique_ptr<StorageLocation>> Locs;
   std::vector<std::unique_ptr<Value>> Vals;

   // Maps from program declarations and statements to storage locations that are
   // assigned to them. These assignments are global (aggregated across all basic
   // blocks) and are used to produce stable storage locations when the same
   // basic blocks are evaluated multiple times. The storage locations that are
   // in scope for a particular basic block are stored in `Environment`.
   llvm::DenseMap<const ValueDecl *, StorageLocation *> DeclToLoc;
   llvm::DenseMap<const Expr *, StorageLocation *> ExprToLoc;

   StorageLocation *ThisPointeeLoc = nullptr;

   // Null pointer values, keyed by the canonical pointee type.
   //
   // FIXME: The pointer values are indexed by the pointee types which are
   // required to initialize the `PointeeLoc` field in `PointerValue`. Consider
   // creating a type-independent `NullPointerValue` without a `PointeeLoc`
   // field.
   llvm::DenseMap<QualType, PointerValue *, NullableQualTypeDenseMapInfo>
       NullPointerVals;

   AtomicBoolValue &TrueVal;
   AtomicBoolValue &FalseVal;

   // Indices that are used to avoid recreating the same composite boolean
   // values.
   llvm::DenseMap<std::pair<BoolValue *, BoolValue *>, ConjunctionValue *>
       ConjunctionVals;
   llvm::DenseMap<std::pair<BoolValue *, BoolValue *>, DisjunctionValue *>
       DisjunctionVals;
   llvm::DenseMap<BoolValue *, NegationValue *> NegationVals;

   // Flow conditions are tracked symbolically: each unique flow condition is
   // associated with a fresh symbolic variable (token), bound to the clause that
   // defines the flow condition. Conceptually, each binding corresponds to an
   // "iff" of the form `FC <=> (C1 ^ C2 ^ ...)` where `FC` is a flow condition
   // token (an atomic boolean) and `Ci`s are the set of constraints in the flow
   // flow condition clause. The set of constraints (C1 ^ C2 ^ ...) are stored in
   // the `FlowConditionConstraints` map, keyed by the token of the flow
   // condition.
   //
   // Flow conditions depend on other flow conditions if they are created using
   // `forkFlowCondition` or `joinFlowConditions`. The graph of flow condition
   // dependencies is stored in the `FlowConditionDeps` map.
   llvm::DenseMap<AtomicBoolValue *, llvm::DenseSet<AtomicBoolValue *>>
       FlowConditionDeps;
   llvm::DenseMap<AtomicBoolValue *, BoolValue *> FlowConditionConstraints;
 };

 } // namespace dataflow
 } // namespace clang

 #endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWANALYSISCONTEXT_H
	//===-- DataflowAnalysisContext.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 a DataflowAnalysisContext class that owns objects that
	// encompass the state of a program and stores context that is used during
	// dataflow analysis.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWANALYSISCONTEXT_H
	#define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWANALYSISCONTEXT_H

	#include "clang/AST/Decl.h"
	#include "clang/AST/Expr.h"
	#include "clang/AST/TypeOrdering.h"
	#include "clang/Analysis/FlowSensitive/Solver.h"
	#include "clang/Analysis/FlowSensitive/StorageLocation.h"
	#include "clang/Analysis/FlowSensitive/Value.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/DenseSet.h"
	#include "llvm/Support/Compiler.h"
	#include <cassert>
	#include <memory>
	#include <type_traits>
	#include <utility>
	#include <vector>

	namespace clang {
	namespace dataflow {

	/// Skip past nodes that the CFG does not emit. These nodes are invisible to
	/// flow-sensitive analysis, and should be ignored as they will effectively not
	/// exist.
	///
	/// * `ParenExpr` - The CFG takes the operator precedence into account, but
	/// otherwise omits the node afterwards.
	///
	/// * `ExprWithCleanups` - The CFG will generate the appropriate calls to
	/// destructors and then omit the node.
	///
	const Expr &ignoreCFGOmittedNodes(const Expr &E);
	const Stmt &ignoreCFGOmittedNodes(const Stmt &S);

	/// Returns the set of all fields in the type.
	llvm::DenseSet<const FieldDecl *> getObjectFields(QualType Type);

	/// Owns objects that encompass the state of a program and stores context that
	/// is used during dataflow analysis.
	class DataflowAnalysisContext {
	public:
	/// Constructs a dataflow analysis context.
	///
	/// Requirements:
	///
	/// `S` must not be null.
	DataflowAnalysisContext(std::unique_ptr<Solver> S)
	: S(std::move(S)), TrueVal(createAtomicBoolValue()),
	FalseVal(createAtomicBoolValue()) {
	assert(this->S != nullptr);
	}

	/// Takes ownership of `Loc` 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) {
	assert(Loc != nullptr);
	Locs.push_back(std::move(Loc));
	return *cast<T>(Locs.back().get());
	}

	/// Takes ownership of `Val` 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) {
	assert(Val != nullptr);
	Vals.push_back(std::move(Val));
	return *cast<T>(Vals.back().get());
	}

	/// Returns a stable storage location appropriate for `Type`.
	///
	/// Requirements:
	///
	/// `Type` must not be null.
	StorageLocation &getStableStorageLocation(QualType Type);

	/// Returns a stable storage location for `D`.
	StorageLocation &getStableStorageLocation(const VarDecl &D);

	/// Returns a stable storage location for `E`.
	StorageLocation &getStableStorageLocation(const Expr &E);

	/// Assigns `Loc` as the storage location of `D`.
	///
	/// Requirements:
	///
	/// `D` must not be assigned a storage location.
	void setStorageLocation(const ValueDecl &D, StorageLocation &Loc) {
	assert(DeclToLoc.find(&D) == DeclToLoc.end());
	DeclToLoc[&D] = &Loc;
	}

	/// Returns the storage location assigned to `D` or null if `D` has no
	/// assigned storage location.
	StorageLocation *getStorageLocation(const ValueDecl &D) const {
	auto It = DeclToLoc.find(&D);
	return It == DeclToLoc.end() ? nullptr : It->second;
	}

	/// Assigns `Loc` as the storage location of `E`.
	///
	/// Requirements:
	///
	/// `E` must not be assigned a storage location.
	void setStorageLocation(const Expr &E, StorageLocation &Loc) {
	const Expr &CanonE = ignoreCFGOmittedNodes(E);
	assert(ExprToLoc.find(&CanonE) == ExprToLoc.end());
	ExprToLoc[&CanonE] = &Loc;
	}

	/// Returns the storage location assigned to `E` or null if `E` has no
	/// assigned storage location.
	StorageLocation *getStorageLocation(const Expr &E) const {
	auto It = ExprToLoc.find(&ignoreCFGOmittedNodes(E));
	return It == ExprToLoc.end() ? nullptr : It->second;
	}

	/// Assigns `Loc` as the storage location of the `this` pointee.
	///
	/// Requirements:
	///
	/// The `this` pointee must not be assigned a storage location.
	void setThisPointeeStorageLocation(StorageLocation &Loc) {
	assert(ThisPointeeLoc == nullptr);
	ThisPointeeLoc = &Loc;
	}

	/// Returns the storage location assigned to the `this` pointee or null if the
	/// `this` pointee has no assigned storage location.
	StorageLocation *getThisPointeeStorageLocation() const {
	return ThisPointeeLoc;
	}

	/// Returns a pointer value that represents a null pointer. Calls with
	/// `PointeeType` that are canonically equivalent will return the same result.
	/// A null `PointeeType` can be used for the pointee of `std::nullptr_t`.
	PointerValue &getOrCreateNullPointerValue(QualType PointeeType);

	/// Returns a symbolic boolean value that models a boolean literal equal to
	/// `Value`.
	AtomicBoolValue &getBoolLiteralValue(bool Value) const {
	return Value ? TrueVal : FalseVal;
	}

	/// Creates an atomic boolean value.
	AtomicBoolValue &createAtomicBoolValue() {
	return takeOwnership(std::make_unique<AtomicBoolValue>());
	}

	/// 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 &getOrCreateConjunction(BoolValue &LHS, BoolValue &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 &getOrCreateDisjunction(BoolValue &LHS, BoolValue &RHS);

	/// Returns a boolean value that represents the negation of `Val`. Subsequent
	/// calls with the same argument will return the same result.
	BoolValue &getOrCreateNegation(BoolValue &Val);

	/// Returns a boolean value that represents `LHS => RHS`. Subsequent calls
	/// with the same arguments, 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 &getOrCreateImplication(BoolValue &LHS, BoolValue &RHS);

	/// Returns a boolean value that 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 &getOrCreateIff(BoolValue &LHS, BoolValue &RHS);

	/// Creates a fresh flow condition and returns a token that identifies it. The
	/// token can be used to perform various operations on the flow condition such
	/// as adding constraints to it, forking it, joining it with another flow
	/// condition, or checking implications.
	AtomicBoolValue &makeFlowConditionToken();

	/// Adds `Constraint` to the flow condition identified by `Token`.
	void addFlowConditionConstraint(AtomicBoolValue &Token,
	BoolValue &Constraint);

	/// Creates a new flow condition with the same constraints as the flow
	/// condition identified by `Token` and returns its token.
	AtomicBoolValue &forkFlowCondition(AtomicBoolValue &Token);

	/// Creates a new flow condition that represents the disjunction of the flow
	/// conditions identified by `FirstToken` and `SecondToken`, and returns its
	/// token.
	AtomicBoolValue &joinFlowConditions(AtomicBoolValue &FirstToken,
	AtomicBoolValue &SecondToken);

	// FIXME: This function returns the flow condition expressed directly as its
	// constraints: (C1 AND C2 AND ...). This differs from the general approach in
	// the framework where a flow condition is represented as a token (an atomic
	// boolean) with dependencies and constraints tracked in `FlowConditionDeps`
	// and `FlowConditionConstraints`: (FC <=> C1 AND C2 AND ...).
	// Consider if we should make the representation of flow condition consistent,
	// returning an atomic boolean token with separate constraints instead.
	//
	/// Builds and returns the logical formula defining the flow condition
	/// identified by `Token`. If a value in the formula is present as a key in
	/// `Substitutions`, it will be substituted with the value it maps to.
	/// As an example, say we have flow condition tokens FC1, FC2, FC3 and
	/// FlowConditionConstraints: { FC1: C1,
	/// FC2: C2,
	/// FC3: (FC1 v FC2) ^ C3 }
	/// buildAndSubstituteFlowCondition(FC3, {{C1 -> C1'}}) will return a value
	/// corresponding to (C1' v C2) ^ C3.
	BoolValue &buildAndSubstituteFlowCondition(
	AtomicBoolValue &Token,
	llvm::DenseMap<AtomicBoolValue , BoolValue > Substitutions);

	/// Returns true if and only if the constraints of the flow condition
	/// identified by `Token` imply that `Val` is true.
	bool flowConditionImplies(AtomicBoolValue &Token, BoolValue &Val);

	/// Returns true if and only if the constraints of the flow condition
	/// identified by `Token` are always true.
	bool flowConditionIsTautology(AtomicBoolValue &Token);

	/// Returns true if `Val1` is equivalent to `Val2`.
	/// Note: This function doesn't take into account constraints on `Val1` and
	/// `Val2` imposed by the flow condition.
	bool equivalentBoolValues(BoolValue &Val1, BoolValue &Val2);

	LLVM_DUMP_METHOD void dumpFlowCondition(AtomicBoolValue &Token);

	private:
	struct NullableQualTypeDenseMapInfo : private llvm::DenseMapInfo<QualType> {
	static QualType getEmptyKey() {
	// Allow a NULL `QualType` by using a different value as the empty key.
	return QualType::getFromOpaquePtr(reinterpret_cast<Type *>(1));
	}

	using DenseMapInfo::getHashValue;
	using DenseMapInfo::getTombstoneKey;
	using DenseMapInfo::isEqual;
	};

	/// Adds all constraints of the flow condition identified by `Token` and all
	/// of its transitive dependencies to `Constraints`. `VisitedTokens` is used
	/// to track tokens of flow conditions that were already visited by recursive
	/// calls.
	void addTransitiveFlowConditionConstraints(
	AtomicBoolValue &Token, llvm::DenseSet<BoolValue *> &Constraints,
	llvm::DenseSet<AtomicBoolValue *> &VisitedTokens);

	/// Returns the outcome of satisfiability checking on `Constraints`.
	/// Possible outcomes are:
	/// - `Satisfiable`: A satisfying assignment exists and is returned.
	/// - `Unsatisfiable`: A satisfying assignment does not exist.
	/// - `TimedOut`: The search for a satisfying assignment was not completed.
	Solver::Result querySolver(llvm::DenseSet<BoolValue *> Constraints);

	/// Returns true if the solver is able to prove that there is no satisfying
	/// assignment for `Constraints`
	bool isUnsatisfiable(llvm::DenseSet<BoolValue *> Constraints) {
	return querySolver(std::move(Constraints)).getStatus() ==
	Solver::Result::Status::Unsatisfiable;
	}

	/// Returns a boolean value as a result of substituting `Val` and its sub
	/// values based on entries in `SubstitutionsCache`. Intermediate results are
	/// stored in `SubstitutionsCache` to avoid reprocessing values that have
	/// already been visited.
	BoolValue &substituteBoolValue(
	BoolValue &Val,
	llvm::DenseMap<BoolValue , BoolValue > &SubstitutionsCache);

	/// Builds and returns the logical formula defining the flow condition
	/// identified by `Token`, sub values may be substituted based on entries in
	/// `SubstitutionsCache`. Intermediate results are stored in
	/// `SubstitutionsCache` to avoid reprocessing values that have already been
	/// visited.
	BoolValue &buildAndSubstituteFlowConditionWithCache(
	AtomicBoolValue &Token,
	llvm::DenseMap<BoolValue , BoolValue > &SubstitutionsCache);

	std::unique_ptr<Solver> S;

	// Storage for the state of a program.
	std::vector<std::unique_ptr<StorageLocation>> Locs;
	std::vector<std::unique_ptr<Value>> Vals;

	// Maps from program declarations and statements to storage locations that are
	// assigned to them. These assignments are global (aggregated across all basic
	// blocks) and are used to produce stable storage locations when the same
	// basic blocks are evaluated multiple times. The storage locations that are
	// in scope for a particular basic block are stored in `Environment`.
	llvm::DenseMap<const ValueDecl , StorageLocation > DeclToLoc;
	llvm::DenseMap<const Expr , StorageLocation > ExprToLoc;

	StorageLocation *ThisPointeeLoc = nullptr;

	// Null pointer values, keyed by the canonical pointee type.
	//
	// FIXME: The pointer values are indexed by the pointee types which are
	// required to initialize the `PointeeLoc` field in `PointerValue`. Consider
	// creating a type-independent `NullPointerValue` without a `PointeeLoc`
	// field.
	llvm::DenseMap<QualType, PointerValue *, NullableQualTypeDenseMapInfo>
	NullPointerVals;

	AtomicBoolValue &TrueVal;
	AtomicBoolValue &FalseVal;

	// Indices that are used to avoid recreating the same composite boolean
	// values.
	llvm::DenseMap<std::pair<BoolValue , BoolValue >, ConjunctionValue *>
	ConjunctionVals;
	llvm::DenseMap<std::pair<BoolValue , BoolValue >, DisjunctionValue *>
	DisjunctionVals;
	llvm::DenseMap<BoolValue , NegationValue > NegationVals;

	// Flow conditions are tracked symbolically: each unique flow condition is
	// associated with a fresh symbolic variable (token), bound to the clause that
	// defines the flow condition. Conceptually, each binding corresponds to an
	// "iff" of the form `FC <=> (C1 ^ C2 ^ ...)` where `FC` is a flow condition
	// token (an atomic boolean) and `Ci`s are the set of constraints in the flow
	// flow condition clause. The set of constraints (C1 ^ C2 ^ ...) are stored in
	// the `FlowConditionConstraints` map, keyed by the token of the flow
	// condition.
	//
	// Flow conditions depend on other flow conditions if they are created using
	// `forkFlowCondition` or `joinFlowConditions`. The graph of flow condition
	// dependencies is stored in the `FlowConditionDeps` map.
	llvm::DenseMap<AtomicBoolValue , llvm::DenseSet<AtomicBoolValue >>
	FlowConditionDeps;
	llvm::DenseMap<AtomicBoolValue , BoolValue > FlowConditionConstraints;
	};

	} // namespace dataflow
	} // namespace clang

	#endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_DATAFLOWANALYSISCONTEXT_H