safecode/tools/clang/include/clang/ASTMatchers/Dynamic/VariantValue.h - llvm-archive - Git at Google

 //===--- VariantValue.h - Polymorphic value type -*- C++ -*-===/
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Polymorphic value type.
 ///
 /// Supports all the types required for dynamic Matcher construction.
 ///  Used by the registry to construct matchers in a generic way.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ASTMATCHERS_DYNAMIC_VARIANTVALUE_H
 #define LLVM_CLANG_ASTMATCHERS_DYNAMIC_VARIANTVALUE_H

 #include "clang/ASTMatchers/ASTMatchers.h"
 #include "clang/ASTMatchers/ASTMatchersInternal.h"
 #include "llvm/ADT/IntrusiveRefCntPtr.h"
 #include "llvm/ADT/Optional.h"
 #include "llvm/ADT/Twine.h"
 #include <memory>
 #include <vector>

 namespace clang {
 namespace ast_matchers {
 namespace dynamic {

 /// \brief Kind identifier.
 ///
 /// It supports all types that VariantValue can contain.
 class ArgKind {
  public:
   enum Kind {
     AK_Matcher,
     AK_Unsigned,
     AK_String
   };
   /// \brief Constructor for non-matcher types.
   ArgKind(Kind K) : K(K) { assert(K != AK_Matcher); }

   /// \brief Constructor for matcher types.
   ArgKind(ast_type_traits::ASTNodeKind MatcherKind)
       : K(AK_Matcher), MatcherKind(MatcherKind) {}

   Kind getArgKind() const { return K; }
   ast_type_traits::ASTNodeKind getMatcherKind() const {
     assert(K == AK_Matcher);
     return MatcherKind;
   }

   /// \brief Determines if this type can be converted to \p To.
   ///
   /// \param To the requested destination type.
   ///
   /// \param Specificity value corresponding to the "specificity" of the
   ///   convertion.
   bool isConvertibleTo(ArgKind To, unsigned *Specificity) const;

   bool operator<(const ArgKind &Other) const {
     if (K == AK_Matcher && Other.K == AK_Matcher)
       return MatcherKind < Other.MatcherKind;
     return K < Other.K;
   }

   /// \brief String representation of the type.
   std::string asString() const;

 private:
   Kind K;
   ast_type_traits::ASTNodeKind MatcherKind;
 };

 using ast_matchers::internal::DynTypedMatcher;

 /// \brief A variant matcher object.
 ///
 /// The purpose of this object is to abstract simple and polymorphic matchers
 /// into a single object type.
 /// Polymorphic matchers might be implemented as a list of all the possible
 /// overloads of the matcher. \c VariantMatcher knows how to select the
 /// appropriate overload when needed.
 /// To get a real matcher object out of a \c VariantMatcher you can do:
 ///  - getSingleMatcher() which returns a matcher, only if it is not ambiguous
 ///    to decide which matcher to return. Eg. it contains only a single
 ///    matcher, or a polymorphic one with only one overload.
 ///  - hasTypedMatcher<T>()/getTypedMatcher<T>(): These calls will determine if
 ///    the underlying matcher(s) can unambiguously return a Matcher<T>.
 class VariantMatcher {
   /// \brief Methods that depend on T from hasTypedMatcher/getTypedMatcher.
   class MatcherOps {
   public:
     MatcherOps(ast_type_traits::ASTNodeKind NodeKind) : NodeKind(NodeKind) {}

     bool canConstructFrom(const DynTypedMatcher &Matcher,
                           bool &IsExactMatch) const;

     /// \brief Convert \p Matcher the destination type and return it as a new
     /// DynTypedMatcher.
     virtual DynTypedMatcher
     convertMatcher(const DynTypedMatcher &Matcher) const = 0;

     /// \brief Constructs a variadic typed matcher from \p InnerMatchers.
     /// Will try to convert each inner matcher to the destination type and
     /// return llvm::None if it fails to do so.
     llvm::Optional<DynTypedMatcher>
     constructVariadicOperator(DynTypedMatcher::VariadicOperator Op,
                               ArrayRef<VariantMatcher> InnerMatchers) const;

   protected:
     ~MatcherOps() = default;

   private:
     ast_type_traits::ASTNodeKind NodeKind;
   };

   /// \brief Payload interface to be specialized by each matcher type.
   ///
   /// It follows a similar interface as VariantMatcher itself.
   class Payload : public RefCountedBaseVPTR {
   public:
     ~Payload() override;
     virtual llvm::Optional<DynTypedMatcher> getSingleMatcher() const = 0;
     virtual std::string getTypeAsString() const = 0;
     virtual llvm::Optional<DynTypedMatcher>
     getTypedMatcher(const MatcherOps &Ops) const = 0;
     virtual bool isConvertibleTo(ast_type_traits::ASTNodeKind Kind,
                                  unsigned *Specificity) const = 0;
   };

 public:
   /// \brief A null matcher.
   VariantMatcher();

   /// \brief Clones the provided matcher.
   static VariantMatcher SingleMatcher(const DynTypedMatcher &Matcher);

   /// \brief Clones the provided matchers.
   ///
   /// They should be the result of a polymorphic matcher.
   static VariantMatcher
   PolymorphicMatcher(std::vector<DynTypedMatcher> Matchers);

   /// \brief Creates a 'variadic' operator matcher.
   ///
   /// It will bind to the appropriate type on getTypedMatcher<T>().
   static VariantMatcher
   VariadicOperatorMatcher(DynTypedMatcher::VariadicOperator Op,
                           std::vector<VariantMatcher> Args);

   /// \brief Makes the matcher the "null" matcher.
   void reset();

   /// \brief Whether the matcher is null.
   bool isNull() const { return !Value; }

   /// \brief Return a single matcher, if there is no ambiguity.
   ///
   /// \returns the matcher, if there is only one matcher. An empty Optional, if
   /// the underlying matcher is a polymorphic matcher with more than one
   /// representation.
   llvm::Optional<DynTypedMatcher> getSingleMatcher() const;

   /// \brief Determines if the contained matcher can be converted to
   ///   \c Matcher<T>.
   ///
   /// For the Single case, it returns true if it can be converted to
   /// \c Matcher<T>.
   /// For the Polymorphic case, it returns true if one, and only one, of the
   /// overloads can be converted to \c Matcher<T>. If there are more than one
   /// that can, the result would be ambiguous and false is returned.
   template <class T>
   bool hasTypedMatcher() const {
     if (!Value) return false;
     return Value->getTypedMatcher(TypedMatcherOps<T>()).hasValue();
   }

   /// \brief Determines if the contained matcher can be converted to \p Kind.
   ///
   /// \param Kind the requested destination type.
   ///
   /// \param Specificity value corresponding to the "specificity" of the
   ///   convertion.
   bool isConvertibleTo(ast_type_traits::ASTNodeKind Kind,
                        unsigned *Specificity) const {
     if (Value)
       return Value->isConvertibleTo(Kind, Specificity);
     return false;
   }

   /// \brief Return this matcher as a \c Matcher<T>.
   ///
   /// Handles the different types (Single, Polymorphic) accordingly.
   /// Asserts that \c hasTypedMatcher<T>() is true.
   template <class T>
   ast_matchers::internal::Matcher<T> getTypedMatcher() const {
     assert(hasTypedMatcher<T>() && "hasTypedMatcher<T>() == false");
     return Value->getTypedMatcher(TypedMatcherOps<T>())
         ->template convertTo<T>();
   }

   /// \brief String representation of the type of the value.
   ///
   /// If the underlying matcher is a polymorphic one, the string will show all
   /// the types.
   std::string getTypeAsString() const;

 private:
   explicit VariantMatcher(Payload *Value) : Value(Value) {}

   template <typename T> struct TypedMatcherOps;

   class SinglePayload;
   class PolymorphicPayload;
   class VariadicOpPayload;

   IntrusiveRefCntPtr<const Payload> Value;
 };

 template <typename T>
 struct VariantMatcher::TypedMatcherOps final : VariantMatcher::MatcherOps {
   TypedMatcherOps()
       : MatcherOps(ast_type_traits::ASTNodeKind::getFromNodeKind<T>()) {}
   typedef ast_matchers::internal::Matcher<T> MatcherT;

   DynTypedMatcher
   convertMatcher(const DynTypedMatcher &Matcher) const override {
     return DynTypedMatcher(Matcher.convertTo<T>());
   }
 };

 /// \brief Variant value class.
 ///
 /// Basically, a tagged union with value type semantics.
 /// It is used by the registry as the return value and argument type for the
 /// matcher factory methods.
 /// It can be constructed from any of the supported types. It supports
 /// copy/assignment.
 ///
 /// Supported types:
 ///  - \c unsigned
 ///  - \c llvm::StringRef
 ///  - \c VariantMatcher (\c DynTypedMatcher / \c Matcher<T>)
 class VariantValue {
 public:
   VariantValue() : Type(VT_Nothing) {}

   VariantValue(const VariantValue &Other);
   ~VariantValue();
   VariantValue &operator=(const VariantValue &Other);

   /// \brief Specific constructors for each supported type.
   VariantValue(unsigned Unsigned);
   VariantValue(StringRef String);
   VariantValue(const VariantMatcher &Matchers);

   /// \brief Returns true iff this is not an empty value.
   explicit operator bool() const { return hasValue(); }
   bool hasValue() const { return Type != VT_Nothing; }

   /// \brief Unsigned value functions.
   bool isUnsigned() const;
   unsigned getUnsigned() const;
   void setUnsigned(unsigned Unsigned);

   /// \brief String value functions.
   bool isString() const;
   const std::string &getString() const;
   void setString(StringRef String);

   /// \brief Matcher value functions.
   bool isMatcher() const;
   const VariantMatcher &getMatcher() const;
   void setMatcher(const VariantMatcher &Matcher);

   /// \brief Determines if the contained value can be converted to \p Kind.
   ///
   /// \param Kind the requested destination type.
   ///
   /// \param Specificity value corresponding to the "specificity" of the
   ///   convertion.
   bool isConvertibleTo(ArgKind Kind, unsigned* Specificity) const;

   /// \brief Determines if the contained value can be converted to any kind
   /// in \p Kinds.
   ///
   /// \param Kinds the requested destination types.
   ///
   /// \param Specificity value corresponding to the "specificity" of the
   ///   convertion. It is the maximum specificity of all the possible
   ///   conversions.
   bool isConvertibleTo(ArrayRef<ArgKind> Kinds, unsigned *Specificity) const;

   /// \brief String representation of the type of the value.
   std::string getTypeAsString() const;

 private:
   void reset();

   /// \brief All supported value types.
   enum ValueType {
     VT_Nothing,
     VT_Unsigned,
     VT_String,
     VT_Matcher
   };

   /// \brief All supported value types.
   union AllValues {
     unsigned Unsigned;
     std::string *String;
     VariantMatcher *Matcher;
   };

   ValueType Type;
   AllValues Value;
 };

 } // end namespace dynamic
 } // end namespace ast_matchers
 } // end namespace clang

 #endif  // LLVM_CLANG_AST_MATCHERS_DYNAMIC_VARIANT_VALUE_H
	//===--- VariantValue.h - Polymorphic value type -- C++ --===/
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Polymorphic value type.
	///
	/// Supports all the types required for dynamic Matcher construction.
	/// Used by the registry to construct matchers in a generic way.
	///
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ASTMATCHERS_DYNAMIC_VARIANTVALUE_H
	#define LLVM_CLANG_ASTMATCHERS_DYNAMIC_VARIANTVALUE_H

	#include "clang/ASTMatchers/ASTMatchers.h"
	#include "clang/ASTMatchers/ASTMatchersInternal.h"
	#include "llvm/ADT/IntrusiveRefCntPtr.h"
	#include "llvm/ADT/Optional.h"
	#include "llvm/ADT/Twine.h"
	#include <memory>
	#include <vector>

	namespace clang {
	namespace ast_matchers {
	namespace dynamic {

	/// \brief Kind identifier.
	///
	/// It supports all types that VariantValue can contain.
	class ArgKind {
	public:
	enum Kind {
	AK_Matcher,
	AK_Unsigned,
	AK_String
	};
	/// \brief Constructor for non-matcher types.
	ArgKind(Kind K) : K(K) { assert(K != AK_Matcher); }

	/// \brief Constructor for matcher types.
	ArgKind(ast_type_traits::ASTNodeKind MatcherKind)
	: K(AK_Matcher), MatcherKind(MatcherKind) {}

	Kind getArgKind() const { return K; }
	ast_type_traits::ASTNodeKind getMatcherKind() const {
	assert(K == AK_Matcher);
	return MatcherKind;
	}

	/// \brief Determines if this type can be converted to \p To.
	///
	/// \param To the requested destination type.
	///
	/// \param Specificity value corresponding to the "specificity" of the
	/// convertion.
	bool isConvertibleTo(ArgKind To, unsigned *Specificity) const;

	bool operator<(const ArgKind &Other) const {
	if (K == AK_Matcher && Other.K == AK_Matcher)
	return MatcherKind < Other.MatcherKind;
	return K < Other.K;
	}

	/// \brief String representation of the type.
	std::string asString() const;

	private:
	Kind K;
	ast_type_traits::ASTNodeKind MatcherKind;
	};

	using ast_matchers::internal::DynTypedMatcher;

	/// \brief A variant matcher object.
	///
	/// The purpose of this object is to abstract simple and polymorphic matchers
	/// into a single object type.
	/// Polymorphic matchers might be implemented as a list of all the possible
	/// overloads of the matcher. \c VariantMatcher knows how to select the
	/// appropriate overload when needed.
	/// To get a real matcher object out of a \c VariantMatcher you can do:
	/// - getSingleMatcher() which returns a matcher, only if it is not ambiguous
	/// to decide which matcher to return. Eg. it contains only a single
	/// matcher, or a polymorphic one with only one overload.
	/// - hasTypedMatcher<T>()/getTypedMatcher<T>(): These calls will determine if
	/// the underlying matcher(s) can unambiguously return a Matcher<T>.
	class VariantMatcher {
	/// \brief Methods that depend on T from hasTypedMatcher/getTypedMatcher.
	class MatcherOps {
	public:
	MatcherOps(ast_type_traits::ASTNodeKind NodeKind) : NodeKind(NodeKind) {}

	bool canConstructFrom(const DynTypedMatcher &Matcher,
	bool &IsExactMatch) const;

	/// \brief Convert \p Matcher the destination type and return it as a new
	/// DynTypedMatcher.
	virtual DynTypedMatcher
	convertMatcher(const DynTypedMatcher &Matcher) const = 0;

	/// \brief Constructs a variadic typed matcher from \p InnerMatchers.
	/// Will try to convert each inner matcher to the destination type and
	/// return llvm::None if it fails to do so.
	llvm::Optional<DynTypedMatcher>
	constructVariadicOperator(DynTypedMatcher::VariadicOperator Op,
	ArrayRef<VariantMatcher> InnerMatchers) const;

	protected:
	~MatcherOps() = default;

	private:
	ast_type_traits::ASTNodeKind NodeKind;
	};

	/// \brief Payload interface to be specialized by each matcher type.
	///
	/// It follows a similar interface as VariantMatcher itself.
	class Payload : public RefCountedBaseVPTR {
	public:
	~Payload() override;
	virtual llvm::Optional<DynTypedMatcher> getSingleMatcher() const = 0;
	virtual std::string getTypeAsString() const = 0;
	virtual llvm::Optional<DynTypedMatcher>
	getTypedMatcher(const MatcherOps &Ops) const = 0;
	virtual bool isConvertibleTo(ast_type_traits::ASTNodeKind Kind,
	unsigned *Specificity) const = 0;
	};

	public:
	/// \brief A null matcher.
	VariantMatcher();

	/// \brief Clones the provided matcher.
	static VariantMatcher SingleMatcher(const DynTypedMatcher &Matcher);

	/// \brief Clones the provided matchers.
	///
	/// They should be the result of a polymorphic matcher.
	static VariantMatcher
	PolymorphicMatcher(std::vector<DynTypedMatcher> Matchers);

	/// \brief Creates a 'variadic' operator matcher.
	///
	/// It will bind to the appropriate type on getTypedMatcher<T>().
	static VariantMatcher
	VariadicOperatorMatcher(DynTypedMatcher::VariadicOperator Op,
	std::vector<VariantMatcher> Args);

	/// \brief Makes the matcher the "null" matcher.
	void reset();

	/// \brief Whether the matcher is null.
	bool isNull() const { return !Value; }

	/// \brief Return a single matcher, if there is no ambiguity.
	///
	/// \returns the matcher, if there is only one matcher. An empty Optional, if
	/// the underlying matcher is a polymorphic matcher with more than one
	/// representation.
	llvm::Optional<DynTypedMatcher> getSingleMatcher() const;

	/// \brief Determines if the contained matcher can be converted to
	/// \c Matcher<T>.
	///
	/// For the Single case, it returns true if it can be converted to
	/// \c Matcher<T>.
	/// For the Polymorphic case, it returns true if one, and only one, of the
	/// overloads can be converted to \c Matcher<T>. If there are more than one
	/// that can, the result would be ambiguous and false is returned.
	template <class T>
	bool hasTypedMatcher() const {
	if (!Value) return false;
	return Value->getTypedMatcher(TypedMatcherOps<T>()).hasValue();
	}

	/// \brief Determines if the contained matcher can be converted to \p Kind.
	///
	/// \param Kind the requested destination type.
	///
	/// \param Specificity value corresponding to the "specificity" of the
	/// convertion.
	bool isConvertibleTo(ast_type_traits::ASTNodeKind Kind,
	unsigned *Specificity) const {
	if (Value)
	return Value->isConvertibleTo(Kind, Specificity);
	return false;
	}

	/// \brief Return this matcher as a \c Matcher<T>.
	///
	/// Handles the different types (Single, Polymorphic) accordingly.
	/// Asserts that \c hasTypedMatcher<T>() is true.
	template <class T>
	ast_matchers::internal::Matcher<T> getTypedMatcher() const {
	assert(hasTypedMatcher<T>() && "hasTypedMatcher<T>() == false");
	return Value->getTypedMatcher(TypedMatcherOps<T>())
	->template convertTo<T>();
	}

	/// \brief String representation of the type of the value.
	///
	/// If the underlying matcher is a polymorphic one, the string will show all
	/// the types.
	std::string getTypeAsString() const;

	private:
	explicit VariantMatcher(Payload *Value) : Value(Value) {}

	template <typename T> struct TypedMatcherOps;

	class SinglePayload;
	class PolymorphicPayload;
	class VariadicOpPayload;

	IntrusiveRefCntPtr<const Payload> Value;
	};

	template <typename T>
	struct VariantMatcher::TypedMatcherOps final : VariantMatcher::MatcherOps {
	TypedMatcherOps()
	: MatcherOps(ast_type_traits::ASTNodeKind::getFromNodeKind<T>()) {}
	typedef ast_matchers::internal::Matcher<T> MatcherT;

	DynTypedMatcher
	convertMatcher(const DynTypedMatcher &Matcher) const override {
	return DynTypedMatcher(Matcher.convertTo<T>());
	}
	};

	/// \brief Variant value class.
	///
	/// Basically, a tagged union with value type semantics.
	/// It is used by the registry as the return value and argument type for the
	/// matcher factory methods.
	/// It can be constructed from any of the supported types. It supports
	/// copy/assignment.
	///
	/// Supported types:
	/// - \c unsigned
	/// - \c llvm::StringRef
	/// - \c VariantMatcher (\c DynTypedMatcher / \c Matcher<T>)
	class VariantValue {
	public:
	VariantValue() : Type(VT_Nothing) {}

	VariantValue(const VariantValue &Other);
	~VariantValue();
	VariantValue &operator=(const VariantValue &Other);

	/// \brief Specific constructors for each supported type.
	VariantValue(unsigned Unsigned);
	VariantValue(StringRef String);
	VariantValue(const VariantMatcher &Matchers);

	/// \brief Returns true iff this is not an empty value.
	explicit operator bool() const { return hasValue(); }
	bool hasValue() const { return Type != VT_Nothing; }

	/// \brief Unsigned value functions.
	bool isUnsigned() const;
	unsigned getUnsigned() const;
	void setUnsigned(unsigned Unsigned);

	/// \brief String value functions.
	bool isString() const;
	const std::string &getString() const;
	void setString(StringRef String);

	/// \brief Matcher value functions.
	bool isMatcher() const;
	const VariantMatcher &getMatcher() const;
	void setMatcher(const VariantMatcher &Matcher);

	/// \brief Determines if the contained value can be converted to \p Kind.
	///
	/// \param Kind the requested destination type.
	///
	/// \param Specificity value corresponding to the "specificity" of the
	/// convertion.
	bool isConvertibleTo(ArgKind Kind, unsigned* Specificity) const;

	/// \brief Determines if the contained value can be converted to any kind
	/// in \p Kinds.
	///
	/// \param Kinds the requested destination types.
	///
	/// \param Specificity value corresponding to the "specificity" of the
	/// convertion. It is the maximum specificity of all the possible
	/// conversions.
	bool isConvertibleTo(ArrayRef<ArgKind> Kinds, unsigned *Specificity) const;

	/// \brief String representation of the type of the value.
	std::string getTypeAsString() const;

	private:
	void reset();

	/// \brief All supported value types.
	enum ValueType {
	VT_Nothing,
	VT_Unsigned,
	VT_String,
	VT_Matcher
	};

	/// \brief All supported value types.
	union AllValues {
	unsigned Unsigned;
	std::string *String;
	VariantMatcher *Matcher;
	};

	ValueType Type;
	AllValues Value;
	};

	} // end namespace dynamic
	} // end namespace ast_matchers
	} // end namespace clang

	#endif // LLVM_CLANG_AST_MATCHERS_DYNAMIC_VARIANT_VALUE_H