safecode/tools/clang/include/clang/Sema/Ownership.h - llvm-archive - Git at Google

 //===--- Ownership.h - Parser ownership helpers -----------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file contains classes for managing ownership of Stmt and Expr nodes.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_SEMA_OWNERSHIP_H
 #define LLVM_CLANG_SEMA_OWNERSHIP_H

 #include "clang/Basic/LLVM.h"
 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/PointerIntPair.h"

 //===----------------------------------------------------------------------===//
 // OpaquePtr
 //===----------------------------------------------------------------------===//

 namespace clang {
   class CXXCtorInitializer;
   class CXXBaseSpecifier;
   class Decl;
   class Expr;
   class ParsedTemplateArgument;
   class QualType;
   class Stmt;
   class TemplateName;
   class TemplateParameterList;

   /// \brief Wrapper for void* pointer.
   /// \tparam PtrTy Either a pointer type like 'T*' or a type that behaves like
   ///               a pointer.
   ///
   /// This is a very simple POD type that wraps a pointer that the Parser
   /// doesn't know about but that Sema or another client does.  The PtrTy
   /// template argument is used to make sure that "Decl" pointers are not
   /// compatible with "Type" pointers for example.
   template <class PtrTy>
   class OpaquePtr {
     void *Ptr;
     explicit OpaquePtr(void *Ptr) : Ptr(Ptr) {}

     typedef llvm::PointerLikeTypeTraits<PtrTy> Traits;

   public:
     OpaquePtr() : Ptr(nullptr) {}

     static OpaquePtr make(PtrTy P) { OpaquePtr OP; OP.set(P); return OP; }

     /// \brief Returns plain pointer to the entity pointed by this wrapper.
     /// \tparam PointeeT Type of pointed entity.
     ///
     /// It is identical to getPtrAs<PointeeT*>.
     template <typename PointeeT> PointeeT* getPtrTo() const {
       return get();
     }

     /// \brief Returns pointer converted to the specified type.
     /// \tparam PtrT Result pointer type.  There must be implicit conversion
     ///              from PtrTy to PtrT.
     ///
     /// In contrast to getPtrTo, this method allows the return type to be
     /// a smart pointer.
     template <typename PtrT> PtrT getPtrAs() const {
       return get();
     }

     PtrTy get() const {
       return Traits::getFromVoidPointer(Ptr);
     }

     void set(PtrTy P) {
       Ptr = Traits::getAsVoidPointer(P);
     }

     explicit operator bool() const { return Ptr != nullptr; }

     void *getAsOpaquePtr() const { return Ptr; }
     static OpaquePtr getFromOpaquePtr(void *P) { return OpaquePtr(P); }
   };

   /// UnionOpaquePtr - A version of OpaquePtr suitable for membership
   /// in a union.
   template <class T> struct UnionOpaquePtr {
     void *Ptr;

     static UnionOpaquePtr make(OpaquePtr<T> P) {
       UnionOpaquePtr OP = { P.getAsOpaquePtr() };
       return OP;
     }

     OpaquePtr<T> get() const { return OpaquePtr<T>::getFromOpaquePtr(Ptr); }
     operator OpaquePtr<T>() const { return get(); }

     UnionOpaquePtr &operator=(OpaquePtr<T> P) {
       Ptr = P.getAsOpaquePtr();
       return *this;
     }
   };
 }

 namespace llvm {
   template <class T>
   class PointerLikeTypeTraits<clang::OpaquePtr<T> > {
   public:
     static inline void *getAsVoidPointer(clang::OpaquePtr<T> P) {
       // FIXME: Doesn't work? return P.getAs< void >();
       return P.getAsOpaquePtr();
     }
     static inline clang::OpaquePtr<T> getFromVoidPointer(void *P) {
       return clang::OpaquePtr<T>::getFromOpaquePtr(P);
     }
     enum { NumLowBitsAvailable = 0 };
   };

   template <class T>
   struct isPodLike<clang::OpaquePtr<T> > { static const bool value = true; };
 }

 namespace clang {
   // Basic
   class DiagnosticBuilder;

   // Determines whether the low bit of the result pointer for the
   // given UID is always zero. If so, ActionResult will use that bit
   // for it's "invalid" flag.
   template<class Ptr>
   struct IsResultPtrLowBitFree {
     static const bool value = false;
   };

   /// ActionResult - This structure is used while parsing/acting on
   /// expressions, stmts, etc.  It encapsulates both the object returned by
   /// the action, plus a sense of whether or not it is valid.
   /// When CompressInvalid is true, the "invalid" flag will be
   /// stored in the low bit of the Val pointer.
   template<class PtrTy,
            bool CompressInvalid = IsResultPtrLowBitFree<PtrTy>::value>
   class ActionResult {
     PtrTy Val;
     bool Invalid;

   public:
     ActionResult(bool Invalid = false)
       : Val(PtrTy()), Invalid(Invalid) {}
     ActionResult(PtrTy val) : Val(val), Invalid(false) {}
     ActionResult(const DiagnosticBuilder &) : Val(PtrTy()), Invalid(true) {}

     // These two overloads prevent void* -> bool conversions.
     ActionResult(const void *);
     ActionResult(volatile void *);

     bool isInvalid() const { return Invalid; }
     bool isUsable() const { return !Invalid && Val; }
     bool isUnset() const { return !Invalid && !Val; }

     PtrTy get() const { return Val; }
     template <typename T> T *getAs() { return static_cast<T*>(get()); }

     void set(PtrTy V) { Val = V; }

     const ActionResult &operator=(PtrTy RHS) {
       Val = RHS;
       Invalid = false;
       return *this;
     }
   };

   // This ActionResult partial specialization places the "invalid"
   // flag into the low bit of the pointer.
   template<typename PtrTy>
   class ActionResult<PtrTy, true> {
     // A pointer whose low bit is 1 if this result is invalid, 0
     // otherwise.
     uintptr_t PtrWithInvalid;
     typedef llvm::PointerLikeTypeTraits<PtrTy> PtrTraits;
   public:
     ActionResult(bool Invalid = false)
       : PtrWithInvalid(static_cast<uintptr_t>(Invalid)) { }

     ActionResult(PtrTy V) {
       void *VP = PtrTraits::getAsVoidPointer(V);
       PtrWithInvalid = reinterpret_cast<uintptr_t>(VP);
       assert((PtrWithInvalid & 0x01) == 0 && "Badly aligned pointer");
     }
     ActionResult(const DiagnosticBuilder &) : PtrWithInvalid(0x01) { }

     // These two overloads prevent void* -> bool conversions.
     ActionResult(const void *);
     ActionResult(volatile void *);

     bool isInvalid() const { return PtrWithInvalid & 0x01; }
     bool isUsable() const { return PtrWithInvalid > 0x01; }
     bool isUnset() const { return PtrWithInvalid == 0; }

     PtrTy get() const {
       void *VP = reinterpret_cast<void *>(PtrWithInvalid & ~0x01);
       return PtrTraits::getFromVoidPointer(VP);
     }
     template <typename T> T *getAs() { return static_cast<T*>(get()); }

     void set(PtrTy V) {
       void *VP = PtrTraits::getAsVoidPointer(V);
       PtrWithInvalid = reinterpret_cast<uintptr_t>(VP);
       assert((PtrWithInvalid & 0x01) == 0 && "Badly aligned pointer");
     }

     const ActionResult &operator=(PtrTy RHS) {
       void *VP = PtrTraits::getAsVoidPointer(RHS);
       PtrWithInvalid = reinterpret_cast<uintptr_t>(VP);
       assert((PtrWithInvalid & 0x01) == 0 && "Badly aligned pointer");
       return *this;
     }

     // For types where we can fit a flag in with the pointer, provide
     // conversions to/from pointer type.
     static ActionResult getFromOpaquePointer(void *P) {
       ActionResult Result;
       Result.PtrWithInvalid = (uintptr_t)P;
       return Result;
     }
     void *getAsOpaquePointer() const { return (void*)PtrWithInvalid; }
   };

   /// An opaque type for threading parsed type information through the
   /// parser.
   typedef OpaquePtr<QualType> ParsedType;
   typedef UnionOpaquePtr<QualType> UnionParsedType;

   // We can re-use the low bit of expression, statement, base, and
   // member-initializer pointers for the "invalid" flag of
   // ActionResult.
   template<> struct IsResultPtrLowBitFree<Expr*> {
     static const bool value = true;
   };
   template<> struct IsResultPtrLowBitFree<Stmt*> {
     static const bool value = true;
   };
   template<> struct IsResultPtrLowBitFree<CXXBaseSpecifier*> {
     static const bool value = true;
   };
   template<> struct IsResultPtrLowBitFree<CXXCtorInitializer*> {
     static const bool value = true;
   };

   typedef ActionResult<Expr*> ExprResult;
   typedef ActionResult<Stmt*> StmtResult;
   typedef ActionResult<ParsedType> TypeResult;
   typedef ActionResult<CXXBaseSpecifier*> BaseResult;
   typedef ActionResult<CXXCtorInitializer*> MemInitResult;

   typedef ActionResult<Decl*> DeclResult;
   typedef OpaquePtr<TemplateName> ParsedTemplateTy;

   typedef MutableArrayRef<Expr*> MultiExprArg;
   typedef MutableArrayRef<Stmt*> MultiStmtArg;
   typedef MutableArrayRef<ParsedTemplateArgument> ASTTemplateArgsPtr;
   typedef MutableArrayRef<ParsedType> MultiTypeArg;
   typedef MutableArrayRef<TemplateParameterList*> MultiTemplateParamsArg;

   inline ExprResult ExprError() { return ExprResult(true); }
   inline StmtResult StmtError() { return StmtResult(true); }

   inline ExprResult ExprError(const DiagnosticBuilder&) { return ExprError(); }
   inline StmtResult StmtError(const DiagnosticBuilder&) { return StmtError(); }

   inline ExprResult ExprEmpty() { return ExprResult(false); }
   inline StmtResult StmtEmpty() { return StmtResult(false); }

   inline Expr *AssertSuccess(ExprResult R) {
     assert(!R.isInvalid() && "operation was asserted to never fail!");
     return R.get();
   }

   inline Stmt *AssertSuccess(StmtResult R) {
     assert(!R.isInvalid() && "operation was asserted to never fail!");
     return R.get();
   }
 }

 #endif
	//===--- Ownership.h - Parser ownership helpers ------------------ C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains classes for managing ownership of Stmt and Expr nodes.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_SEMA_OWNERSHIP_H
	#define LLVM_CLANG_SEMA_OWNERSHIP_H

	#include "clang/Basic/LLVM.h"
	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/PointerIntPair.h"

	//===----------------------------------------------------------------------===//
	// OpaquePtr
	//===----------------------------------------------------------------------===//

	namespace clang {
	class CXXCtorInitializer;
	class CXXBaseSpecifier;
	class Decl;
	class Expr;
	class ParsedTemplateArgument;
	class QualType;
	class Stmt;
	class TemplateName;
	class TemplateParameterList;

	/// \brief Wrapper for void* pointer.
	/// \tparam PtrTy Either a pointer type like 'T*' or a type that behaves like
	/// a pointer.
	///
	/// This is a very simple POD type that wraps a pointer that the Parser
	/// doesn't know about but that Sema or another client does. The PtrTy
	/// template argument is used to make sure that "Decl" pointers are not
	/// compatible with "Type" pointers for example.
	template <class PtrTy>
	class OpaquePtr {
	void *Ptr;
	explicit OpaquePtr(void *Ptr) : Ptr(Ptr) {}

	typedef llvm::PointerLikeTypeTraits<PtrTy> Traits;

	public:
	OpaquePtr() : Ptr(nullptr) {}

	static OpaquePtr make(PtrTy P) { OpaquePtr OP; OP.set(P); return OP; }

	/// \brief Returns plain pointer to the entity pointed by this wrapper.
	/// \tparam PointeeT Type of pointed entity.
	///
	/// It is identical to getPtrAs<PointeeT*>.
	template <typename PointeeT> PointeeT* getPtrTo() const {
	return get();
	}

	/// \brief Returns pointer converted to the specified type.
	/// \tparam PtrT Result pointer type. There must be implicit conversion
	/// from PtrTy to PtrT.
	///
	/// In contrast to getPtrTo, this method allows the return type to be
	/// a smart pointer.
	template <typename PtrT> PtrT getPtrAs() const {
	return get();
	}

	PtrTy get() const {
	return Traits::getFromVoidPointer(Ptr);
	}

	void set(PtrTy P) {
	Ptr = Traits::getAsVoidPointer(P);
	}

	explicit operator bool() const { return Ptr != nullptr; }

	void *getAsOpaquePtr() const { return Ptr; }
	static OpaquePtr getFromOpaquePtr(void *P) { return OpaquePtr(P); }
	};

	/// UnionOpaquePtr - A version of OpaquePtr suitable for membership
	/// in a union.
	template <class T> struct UnionOpaquePtr {
	void *Ptr;

	static UnionOpaquePtr make(OpaquePtr<T> P) {
	UnionOpaquePtr OP = { P.getAsOpaquePtr() };
	return OP;
	}

	OpaquePtr<T> get() const { return OpaquePtr<T>::getFromOpaquePtr(Ptr); }
	operator OpaquePtr<T>() const { return get(); }

	UnionOpaquePtr &operator=(OpaquePtr<T> P) {
	Ptr = P.getAsOpaquePtr();
	return *this;
	}
	};
	}

	namespace llvm {
	template <class T>
	class PointerLikeTypeTraits<clang::OpaquePtr<T> > {
	public:
	static inline void *getAsVoidPointer(clang::OpaquePtr<T> P) {
	// FIXME: Doesn't work? return P.getAs< void >();
	return P.getAsOpaquePtr();
	}
	static inline clang::OpaquePtr<T> getFromVoidPointer(void *P) {
	return clang::OpaquePtr<T>::getFromOpaquePtr(P);
	}
	enum { NumLowBitsAvailable = 0 };
	};

	template <class T>
	struct isPodLike<clang::OpaquePtr<T> > { static const bool value = true; };
	}

	namespace clang {
	// Basic
	class DiagnosticBuilder;

	// Determines whether the low bit of the result pointer for the
	// given UID is always zero. If so, ActionResult will use that bit
	// for it's "invalid" flag.
	template<class Ptr>
	struct IsResultPtrLowBitFree {
	static const bool value = false;
	};

	/// ActionResult - This structure is used while parsing/acting on
	/// expressions, stmts, etc. It encapsulates both the object returned by
	/// the action, plus a sense of whether or not it is valid.
	/// When CompressInvalid is true, the "invalid" flag will be
	/// stored in the low bit of the Val pointer.
	template<class PtrTy,
	bool CompressInvalid = IsResultPtrLowBitFree<PtrTy>::value>
	class ActionResult {
	PtrTy Val;
	bool Invalid;

	public:
	ActionResult(bool Invalid = false)
	: Val(PtrTy()), Invalid(Invalid) {}
	ActionResult(PtrTy val) : Val(val), Invalid(false) {}
	ActionResult(const DiagnosticBuilder &) : Val(PtrTy()), Invalid(true) {}

	// These two overloads prevent void* -> bool conversions.
	ActionResult(const void *);
	ActionResult(volatile void *);

	bool isInvalid() const { return Invalid; }
	bool isUsable() const { return !Invalid && Val; }
	bool isUnset() const { return !Invalid && !Val; }

	PtrTy get() const { return Val; }
	template <typename T> T getAs() { return static_cast<T>(get()); }

	void set(PtrTy V) { Val = V; }

	const ActionResult &operator=(PtrTy RHS) {
	Val = RHS;
	Invalid = false;
	return *this;
	}
	};

	// This ActionResult partial specialization places the "invalid"
	// flag into the low bit of the pointer.
	template<typename PtrTy>
	class ActionResult<PtrTy, true> {
	// A pointer whose low bit is 1 if this result is invalid, 0
	// otherwise.
	uintptr_t PtrWithInvalid;
	typedef llvm::PointerLikeTypeTraits<PtrTy> PtrTraits;
	public:
	ActionResult(bool Invalid = false)
	: PtrWithInvalid(static_cast<uintptr_t>(Invalid)) { }

	ActionResult(PtrTy V) {
	void *VP = PtrTraits::getAsVoidPointer(V);
	PtrWithInvalid = reinterpret_cast<uintptr_t>(VP);
	assert((PtrWithInvalid & 0x01) == 0 && "Badly aligned pointer");
	}
	ActionResult(const DiagnosticBuilder &) : PtrWithInvalid(0x01) { }

	// These two overloads prevent void* -> bool conversions.
	ActionResult(const void *);
	ActionResult(volatile void *);

	bool isInvalid() const { return PtrWithInvalid & 0x01; }
	bool isUsable() const { return PtrWithInvalid > 0x01; }
	bool isUnset() const { return PtrWithInvalid == 0; }

	PtrTy get() const {
	void VP = reinterpret_cast<void >(PtrWithInvalid & ~0x01);
	return PtrTraits::getFromVoidPointer(VP);
	}
	template <typename T> T getAs() { return static_cast<T>(get()); }

	void set(PtrTy V) {
	void *VP = PtrTraits::getAsVoidPointer(V);
	PtrWithInvalid = reinterpret_cast<uintptr_t>(VP);
	assert((PtrWithInvalid & 0x01) == 0 && "Badly aligned pointer");
	}

	const ActionResult &operator=(PtrTy RHS) {
	void *VP = PtrTraits::getAsVoidPointer(RHS);
	PtrWithInvalid = reinterpret_cast<uintptr_t>(VP);
	assert((PtrWithInvalid & 0x01) == 0 && "Badly aligned pointer");
	return *this;
	}

	// For types where we can fit a flag in with the pointer, provide
	// conversions to/from pointer type.
	static ActionResult getFromOpaquePointer(void *P) {
	ActionResult Result;
	Result.PtrWithInvalid = (uintptr_t)P;
	return Result;
	}
	void getAsOpaquePointer() const { return (void)PtrWithInvalid; }
	};

	/// An opaque type for threading parsed type information through the
	/// parser.
	typedef OpaquePtr<QualType> ParsedType;
	typedef UnionOpaquePtr<QualType> UnionParsedType;

	// We can re-use the low bit of expression, statement, base, and
	// member-initializer pointers for the "invalid" flag of
	// ActionResult.
	template<> struct IsResultPtrLowBitFree<Expr*> {
	static const bool value = true;
	};
	template<> struct IsResultPtrLowBitFree<Stmt*> {
	static const bool value = true;
	};
	template<> struct IsResultPtrLowBitFree<CXXBaseSpecifier*> {
	static const bool value = true;
	};
	template<> struct IsResultPtrLowBitFree<CXXCtorInitializer*> {
	static const bool value = true;
	};

	typedef ActionResult<Expr*> ExprResult;
	typedef ActionResult<Stmt*> StmtResult;
	typedef ActionResult<ParsedType> TypeResult;
	typedef ActionResult<CXXBaseSpecifier*> BaseResult;
	typedef ActionResult<CXXCtorInitializer*> MemInitResult;

	typedef ActionResult<Decl*> DeclResult;
	typedef OpaquePtr<TemplateName> ParsedTemplateTy;

	typedef MutableArrayRef<Expr*> MultiExprArg;
	typedef MutableArrayRef<Stmt*> MultiStmtArg;
	typedef MutableArrayRef<ParsedTemplateArgument> ASTTemplateArgsPtr;
	typedef MutableArrayRef<ParsedType> MultiTypeArg;
	typedef MutableArrayRef<TemplateParameterList*> MultiTemplateParamsArg;

	inline ExprResult ExprError() { return ExprResult(true); }
	inline StmtResult StmtError() { return StmtResult(true); }

	inline ExprResult ExprError(const DiagnosticBuilder&) { return ExprError(); }
	inline StmtResult StmtError(const DiagnosticBuilder&) { return StmtError(); }

	inline ExprResult ExprEmpty() { return ExprResult(false); }
	inline StmtResult StmtEmpty() { return StmtResult(false); }

	inline Expr *AssertSuccess(ExprResult R) {
	assert(!R.isInvalid() && "operation was asserted to never fail!");
	return R.get();
	}

	inline Stmt *AssertSuccess(StmtResult R) {
	assert(!R.isInvalid() && "operation was asserted to never fail!");
	return R.get();
	}
	}

	#endif