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

 //===-- Value.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 classes for values computed by abstract interpretation
 // during dataflow analysis.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_VALUE_H
 #define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_VALUE_H

 #include "clang/AST/Decl.h"
 #include "clang/Analysis/FlowSensitive/StorageLocation.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/StringMap.h"
 #include "llvm/ADT/StringRef.h"
 #include <cassert>
 #include <utility>

 namespace clang {
 namespace dataflow {

 /// Base class for all values computed by abstract interpretation.
 ///
 /// Don't use `Value` instances by value. All `Value` instances are allocated
 /// and owned by `DataflowAnalysisContext`.
 class Value {
 public:
   enum class Kind {
     Integer,
     Reference,
     Pointer,
     Struct,

     // Synthetic boolean values are either atomic values or composites that
     // represent conjunctions, disjunctions, and negations.
     AtomicBool,
     Conjunction,
     Disjunction,
     Negation
   };

   explicit Value(Kind ValKind) : ValKind(ValKind) {}

   // Non-copyable because addresses of values are used as their identities
   // throughout framework and user code. The framework is responsible for
   // construction and destruction of values.
   Value(const Value &) = delete;
   Value &operator=(const Value &) = delete;

   virtual ~Value() = default;

   Kind getKind() const { return ValKind; }

   /// Returns the value of the synthetic property with the given `Name` or null
   /// if the property isn't assigned a value.
   Value *getProperty(llvm::StringRef Name) const {
     auto It = Properties.find(Name);
     return It == Properties.end() ? nullptr : It->second;
   }

   /// Assigns `Val` as the value of the synthetic property with the given
   /// `Name`.
   void setProperty(llvm::StringRef Name, Value &Val) {
     Properties.insert_or_assign(Name, &Val);
   }

 private:
   Kind ValKind;
   llvm::StringMap<Value *> Properties;
 };

 /// Models a boolean.
 class BoolValue : public Value {
 public:
   explicit BoolValue(Kind ValueKind) : Value(ValueKind) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::AtomicBool ||
            Val->getKind() == Kind::Conjunction ||
            Val->getKind() == Kind::Disjunction ||
            Val->getKind() == Kind::Negation;
   }
 };

 /// Models an atomic boolean.
 class AtomicBoolValue : public BoolValue {
 public:
   explicit AtomicBoolValue() : BoolValue(Kind::AtomicBool) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::AtomicBool;
   }
 };

 /// Models a boolean conjunction.
 // FIXME: Consider representing binary and unary boolean operations similar
 // to how they are represented in the AST. This might become more pressing
 // when such operations need to be added for other data types.
 class ConjunctionValue : public BoolValue {
 public:
   explicit ConjunctionValue(BoolValue &LeftSubVal, BoolValue &RightSubVal)
       : BoolValue(Kind::Conjunction), LeftSubVal(LeftSubVal),
         RightSubVal(RightSubVal) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Conjunction;
   }

   /// Returns the left sub-value of the conjunction.
   BoolValue &getLeftSubValue() const { return LeftSubVal; }

   /// Returns the right sub-value of the conjunction.
   BoolValue &getRightSubValue() const { return RightSubVal; }

 private:
   BoolValue &LeftSubVal;
   BoolValue &RightSubVal;
 };

 /// Models a boolean disjunction.
 class DisjunctionValue : public BoolValue {
 public:
   explicit DisjunctionValue(BoolValue &LeftSubVal, BoolValue &RightSubVal)
       : BoolValue(Kind::Disjunction), LeftSubVal(LeftSubVal),
         RightSubVal(RightSubVal) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Disjunction;
   }

   /// Returns the left sub-value of the disjunction.
   BoolValue &getLeftSubValue() const { return LeftSubVal; }

   /// Returns the right sub-value of the disjunction.
   BoolValue &getRightSubValue() const { return RightSubVal; }

 private:
   BoolValue &LeftSubVal;
   BoolValue &RightSubVal;
 };

 /// Models a boolean negation.
 class NegationValue : public BoolValue {
 public:
   explicit NegationValue(BoolValue &SubVal)
       : BoolValue(Kind::Negation), SubVal(SubVal) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Negation;
   }

   /// Returns the sub-value of the negation.
   BoolValue &getSubVal() const { return SubVal; }

 private:
   BoolValue &SubVal;
 };

 /// Models an integer.
 class IntegerValue : public Value {
 public:
   explicit IntegerValue() : Value(Kind::Integer) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Integer;
   }
 };

 /// Models a dereferenced pointer. For example, a reference in C++ or an lvalue
 /// in C.
 class ReferenceValue final : public Value {
 public:
   explicit ReferenceValue(StorageLocation &ReferentLoc)
       : Value(Kind::Reference), ReferentLoc(ReferentLoc) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Reference;
   }

   StorageLocation &getReferentLoc() const { return ReferentLoc; }

 private:
   StorageLocation &ReferentLoc;
 };

 /// Models a symbolic pointer. Specifically, any value of type `T*`.
 class PointerValue final : public Value {
 public:
   explicit PointerValue(StorageLocation &PointeeLoc)
       : Value(Kind::Pointer), PointeeLoc(PointeeLoc) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Pointer;
   }

   StorageLocation &getPointeeLoc() const { return PointeeLoc; }

 private:
   StorageLocation &PointeeLoc;
 };

 /// Models a value of `struct` or `class` type, with a flat map of fields to
 /// child storage locations, containing all accessible members of base struct
 /// and class types.
 class StructValue final : public Value {
 public:
   StructValue() : StructValue(llvm::DenseMap<const ValueDecl *, Value *>()) {}

   explicit StructValue(llvm::DenseMap<const ValueDecl *, Value *> Children)
       : Value(Kind::Struct), Children(std::move(Children)) {}

   static bool classof(const Value *Val) {
     return Val->getKind() == Kind::Struct;
   }

   /// Returns the child value that is assigned for `D` or null if the child is
   /// not initialized.
   Value *getChild(const ValueDecl &D) const {
     auto It = Children.find(&D);
     if (It == Children.end())
       return nullptr;
     return It->second;
   }

   /// Assigns `Val` as the child value for `D`.
   void setChild(const ValueDecl &D, Value &Val) { Children[&D] = &Val; }

 private:
   llvm::DenseMap<const ValueDecl *, Value *> Children;
 };

 } // namespace dataflow
 } // namespace clang

 #endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_VALUE_H
	//===-- Value.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 classes for values computed by abstract interpretation
	// during dataflow analysis.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_VALUE_H
	#define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_VALUE_H

	#include "clang/AST/Decl.h"
	#include "clang/Analysis/FlowSensitive/StorageLocation.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/StringMap.h"
	#include "llvm/ADT/StringRef.h"
	#include <cassert>
	#include <utility>

	namespace clang {
	namespace dataflow {

	/// Base class for all values computed by abstract interpretation.
	///
	/// Don't use `Value` instances by value. All `Value` instances are allocated
	/// and owned by `DataflowAnalysisContext`.
	class Value {
	public:
	enum class Kind {
	Integer,
	Reference,
	Pointer,
	Struct,

	// Synthetic boolean values are either atomic values or composites that
	// represent conjunctions, disjunctions, and negations.
	AtomicBool,
	Conjunction,
	Disjunction,
	Negation
	};

	explicit Value(Kind ValKind) : ValKind(ValKind) {}

	// Non-copyable because addresses of values are used as their identities
	// throughout framework and user code. The framework is responsible for
	// construction and destruction of values.
	Value(const Value &) = delete;
	Value &operator=(const Value &) = delete;

	virtual ~Value() = default;

	Kind getKind() const { return ValKind; }

	/// Returns the value of the synthetic property with the given `Name` or null
	/// if the property isn't assigned a value.
	Value *getProperty(llvm::StringRef Name) const {
	auto It = Properties.find(Name);
	return It == Properties.end() ? nullptr : It->second;
	}

	/// Assigns `Val` as the value of the synthetic property with the given
	/// `Name`.
	void setProperty(llvm::StringRef Name, Value &Val) {
	Properties.insert_or_assign(Name, &Val);
	}

	private:
	Kind ValKind;
	llvm::StringMap<Value *> Properties;
	};

	/// Models a boolean.
	class BoolValue : public Value {
	public:
	explicit BoolValue(Kind ValueKind) : Value(ValueKind) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::AtomicBool \|\|
	Val->getKind() == Kind::Conjunction \|\|
	Val->getKind() == Kind::Disjunction \|\|
	Val->getKind() == Kind::Negation;
	}
	};

	/// Models an atomic boolean.
	class AtomicBoolValue : public BoolValue {
	public:
	explicit AtomicBoolValue() : BoolValue(Kind::AtomicBool) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::AtomicBool;
	}
	};

	/// Models a boolean conjunction.
	// FIXME: Consider representing binary and unary boolean operations similar
	// to how they are represented in the AST. This might become more pressing
	// when such operations need to be added for other data types.
	class ConjunctionValue : public BoolValue {
	public:
	explicit ConjunctionValue(BoolValue &LeftSubVal, BoolValue &RightSubVal)
	: BoolValue(Kind::Conjunction), LeftSubVal(LeftSubVal),
	RightSubVal(RightSubVal) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Conjunction;
	}

	/// Returns the left sub-value of the conjunction.
	BoolValue &getLeftSubValue() const { return LeftSubVal; }

	/// Returns the right sub-value of the conjunction.
	BoolValue &getRightSubValue() const { return RightSubVal; }

	private:
	BoolValue &LeftSubVal;
	BoolValue &RightSubVal;
	};

	/// Models a boolean disjunction.
	class DisjunctionValue : public BoolValue {
	public:
	explicit DisjunctionValue(BoolValue &LeftSubVal, BoolValue &RightSubVal)
	: BoolValue(Kind::Disjunction), LeftSubVal(LeftSubVal),
	RightSubVal(RightSubVal) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Disjunction;
	}

	/// Returns the left sub-value of the disjunction.
	BoolValue &getLeftSubValue() const { return LeftSubVal; }

	/// Returns the right sub-value of the disjunction.
	BoolValue &getRightSubValue() const { return RightSubVal; }

	private:
	BoolValue &LeftSubVal;
	BoolValue &RightSubVal;
	};

	/// Models a boolean negation.
	class NegationValue : public BoolValue {
	public:
	explicit NegationValue(BoolValue &SubVal)
	: BoolValue(Kind::Negation), SubVal(SubVal) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Negation;
	}

	/// Returns the sub-value of the negation.
	BoolValue &getSubVal() const { return SubVal; }

	private:
	BoolValue &SubVal;
	};

	/// Models an integer.
	class IntegerValue : public Value {
	public:
	explicit IntegerValue() : Value(Kind::Integer) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Integer;
	}
	};

	/// Models a dereferenced pointer. For example, a reference in C++ or an lvalue
	/// in C.
	class ReferenceValue final : public Value {
	public:
	explicit ReferenceValue(StorageLocation &ReferentLoc)
	: Value(Kind::Reference), ReferentLoc(ReferentLoc) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Reference;
	}

	StorageLocation &getReferentLoc() const { return ReferentLoc; }

	private:
	StorageLocation &ReferentLoc;
	};

	/// Models a symbolic pointer. Specifically, any value of type `T*`.
	class PointerValue final : public Value {
	public:
	explicit PointerValue(StorageLocation &PointeeLoc)
	: Value(Kind::Pointer), PointeeLoc(PointeeLoc) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Pointer;
	}

	StorageLocation &getPointeeLoc() const { return PointeeLoc; }

	private:
	StorageLocation &PointeeLoc;
	};

	/// Models a value of `struct` or `class` type, with a flat map of fields to
	/// child storage locations, containing all accessible members of base struct
	/// and class types.
	class StructValue final : public Value {
	public:
	StructValue() : StructValue(llvm::DenseMap<const ValueDecl , Value >()) {}

	explicit StructValue(llvm::DenseMap<const ValueDecl , Value > Children)
	: Value(Kind::Struct), Children(std::move(Children)) {}

	static bool classof(const Value *Val) {
	return Val->getKind() == Kind::Struct;
	}

	/// Returns the child value that is assigned for `D` or null if the child is
	/// not initialized.
	Value *getChild(const ValueDecl &D) const {
	auto It = Children.find(&D);
	if (It == Children.end())
	return nullptr;
	return It->second;
	}

	/// Assigns `Val` as the child value for `D`.
	void setChild(const ValueDecl &D, Value &Val) { Children[&D] = &Val; }

	private:
	llvm::DenseMap<const ValueDecl , Value > Children;
	};

	} // namespace dataflow
	} // namespace clang

	#endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE_VALUE_H