third_party/LLVM/include/llvm/ADT/PointerUnion.h - SwiftShader - Git at Google

 //===- llvm/ADT/PointerUnion.h - Discriminated Union of 2 Ptrs --*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the PointerUnion class, which is a discriminated union of
 // pointer types.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ADT_POINTERUNION_H
 #define LLVM_ADT_POINTERUNION_H

 #include "llvm/ADT/PointerIntPair.h"

 namespace llvm {

   template <typename T>
   struct PointerUnionTypeSelectorReturn {
     typedef T Return;
   };

   /// \brief Get a type based on whether two types are the same or not. For:
   /// @code
   /// typedef typename PointerUnionTypeSelector<T1, T2, EQ, NE>::Return Ret;
   /// @endcode
   /// Ret will be EQ type if T1 is same as T2 or NE type otherwise.
   template <typename T1, typename T2, typename RET_EQ, typename RET_NE>
   struct PointerUnionTypeSelector {
     typedef typename PointerUnionTypeSelectorReturn<RET_NE>::Return Return;
   };

   template <typename T, typename RET_EQ, typename RET_NE>
   struct PointerUnionTypeSelector<T, T, RET_EQ, RET_NE> {
     typedef typename PointerUnionTypeSelectorReturn<RET_EQ>::Return Return;
   };

   template <typename T1, typename T2, typename RET_EQ, typename RET_NE>
   struct PointerUnionTypeSelectorReturn<
                             PointerUnionTypeSelector<T1, T2, RET_EQ, RET_NE> > {
     typedef typename PointerUnionTypeSelector<T1, T2, RET_EQ, RET_NE>::Return
         Return;
   };

   /// Provide PointerLikeTypeTraits for void* that is used by PointerUnion
   /// for the two template arguments.
   template <typename PT1, typename PT2>
   class PointerUnionUIntTraits {
   public:
     static inline void *getAsVoidPointer(void *P) { return P; }
     static inline void *getFromVoidPointer(void *P) { return P; }
     enum {
       PT1BitsAv = PointerLikeTypeTraits<PT1>::NumLowBitsAvailable,
       PT2BitsAv = PointerLikeTypeTraits<PT2>::NumLowBitsAvailable,
       NumLowBitsAvailable = PT1BitsAv < PT2BitsAv ? PT1BitsAv : PT2BitsAv
     };
   };

   /// PointerUnion - This implements a discriminated union of two pointer types,
   /// and keeps the discriminator bit-mangled into the low bits of the pointer.
   /// This allows the implementation to be extremely efficient in space, but
   /// permits a very natural and type-safe API.
   ///
   /// Common use patterns would be something like this:
   ///    PointerUnion<int*, float*> P;
   ///    P = (int*)0;
   ///    printf("%d %d", P.is<int*>(), P.is<float*>());  // prints "1 0"
   ///    X = P.get<int*>();     // ok.
   ///    Y = P.get<float*>();   // runtime assertion failure.
   ///    Z = P.get<double*>();  // runtime assertion failure (regardless of tag)
   ///    P = (float*)0;
   ///    Y = P.get<float*>();   // ok.
   ///    X = P.get<int*>();     // runtime assertion failure.
   template <typename PT1, typename PT2>
   class PointerUnion {
   public:
     typedef PointerIntPair<void*, 1, bool,
                            PointerUnionUIntTraits<PT1,PT2> > ValTy;
   private:
     ValTy Val;

     struct IsPT1 {
       static const int Num = 0;
     };
     struct IsPT2 {
       static const int Num = 1;
     };
     template <typename T>
     struct UNION_DOESNT_CONTAIN_TYPE { };

   public:
     PointerUnion() {}

     PointerUnion(PT1 V) {
       Val.setPointer(
          const_cast<void *>(PointerLikeTypeTraits<PT1>::getAsVoidPointer(V)));
       Val.setInt(0);
     }
     PointerUnion(PT2 V) {
       Val.setPointer(
          const_cast<void *>(PointerLikeTypeTraits<PT2>::getAsVoidPointer(V)));
       Val.setInt(1);
     }

     /// isNull - Return true if the pointer held in the union is null,
     /// regardless of which type it is.
     bool isNull() const {
       // Convert from the void* to one of the pointer types, to make sure that
       // we recursively strip off low bits if we have a nested PointerUnion.
       return !PointerLikeTypeTraits<PT1>::getFromVoidPointer(Val.getPointer());
     }
     operator bool() const { return !isNull(); }

     /// is<T>() return true if the Union currently holds the type matching T.
     template<typename T>
     int is() const {
       typedef typename
         ::llvm::PointerUnionTypeSelector<PT1, T, IsPT1,
           ::llvm::PointerUnionTypeSelector<PT2, T, IsPT2,
                                     UNION_DOESNT_CONTAIN_TYPE<T> > >::Return Ty;
       int TyNo = Ty::Num;
       return static_cast<int>(Val.getInt()) == TyNo;
     }

     /// get<T>() - Return the value of the specified pointer type. If the
     /// specified pointer type is incorrect, assert.
     template<typename T>
     T get() const {
       assert(is<T>() && "Invalid accessor called");
       return PointerLikeTypeTraits<T>::getFromVoidPointer(Val.getPointer());
     }

     /// dyn_cast<T>() - If the current value is of the specified pointer type,
     /// return it, otherwise return null.
     template<typename T>
     T dyn_cast() const {
       if (is<T>()) return get<T>();
       return T();
     }

     /// \brief If the union is set to the first pointer type we can get an
     /// address pointing to it.
     template <typename T>
     PT1 const *getAddrOf() const {
       assert(is<PT1>() && "Val is not the first pointer");
       assert(get<PT1>() == Val.getPointer() &&
          "Can't get the address because PointerLikeTypeTraits changes the ptr");
       T const *can_only_get_address_of_first_pointer_type
                         = reinterpret_cast<PT1 const *>(Val.getAddrOfPointer());
       return can_only_get_address_of_first_pointer_type;
     }

     /// Assignment operators - Allow assigning into this union from either
     /// pointer type, setting the discriminator to remember what it came from.
     const PointerUnion &operator=(const PT1 &RHS) {
       Val.setPointer(
          const_cast<void *>(PointerLikeTypeTraits<PT1>::getAsVoidPointer(RHS)));
       Val.setInt(0);
       return *this;
     }
     const PointerUnion &operator=(const PT2 &RHS) {
       Val.setPointer(
         const_cast<void *>(PointerLikeTypeTraits<PT2>::getAsVoidPointer(RHS)));
       Val.setInt(1);
       return *this;
     }

     void *getOpaqueValue() const { return Val.getOpaqueValue(); }
     static inline PointerUnion getFromOpaqueValue(void *VP) {
       PointerUnion V;
       V.Val = ValTy::getFromOpaqueValue(VP);
       return V;
     }
   };

   // Teach SmallPtrSet that PointerUnion is "basically a pointer", that has
   // # low bits available = min(PT1bits,PT2bits)-1.
   template<typename PT1, typename PT2>
   class PointerLikeTypeTraits<PointerUnion<PT1, PT2> > {
   public:
     static inline void *
     getAsVoidPointer(const PointerUnion<PT1, PT2> &P) {
       return P.getOpaqueValue();
     }
     static inline PointerUnion<PT1, PT2>
     getFromVoidPointer(void *P) {
       return PointerUnion<PT1, PT2>::getFromOpaqueValue(P);
     }

     // The number of bits available are the min of the two pointer types.
     enum {
       NumLowBitsAvailable =
         PointerLikeTypeTraits<typename PointerUnion<PT1,PT2>::ValTy>
           ::NumLowBitsAvailable
     };
   };


   /// PointerUnion3 - This is a pointer union of three pointer types.  See
   /// documentation for PointerUnion for usage.
   template <typename PT1, typename PT2, typename PT3>
   class PointerUnion3 {
   public:
     typedef PointerUnion<PT1, PT2> InnerUnion;
     typedef PointerUnion<InnerUnion, PT3> ValTy;
   private:
     ValTy Val;

     struct IsInnerUnion {
       ValTy Val;
       IsInnerUnion(ValTy val) : Val(val) { }
       template<typename T>
       int is() const {
         return Val.template is<InnerUnion>() &&
                Val.template get<InnerUnion>().template is<T>();
       }
       template<typename T>
       T get() const {
         return Val.template get<InnerUnion>().template get<T>();
       }
     };

     struct IsPT3 {
       ValTy Val;
       IsPT3(ValTy val) : Val(val) { }
       template<typename T>
       int is() const {
         return Val.template is<T>();
       }
       template<typename T>
       T get() const {
         return Val.template get<T>();
       }
     };

   public:
     PointerUnion3() {}

     PointerUnion3(PT1 V) {
       Val = InnerUnion(V);
     }
     PointerUnion3(PT2 V) {
       Val = InnerUnion(V);
     }
     PointerUnion3(PT3 V) {
       Val = V;
     }

     /// isNull - Return true if the pointer held in the union is null,
     /// regardless of which type it is.
     bool isNull() const { return Val.isNull(); }
     operator bool() const { return !isNull(); }

     /// is<T>() return true if the Union currently holds the type matching T.
     template<typename T>
     int is() const {
       // If T is PT1/PT2 choose IsInnerUnion otherwise choose IsPT3.
       typedef typename
         ::llvm::PointerUnionTypeSelector<PT1, T, IsInnerUnion,
           ::llvm::PointerUnionTypeSelector<PT2, T, IsInnerUnion, IsPT3 >
                                                                    >::Return Ty;
       return Ty(Val).template is<T>();
     }

     /// get<T>() - Return the value of the specified pointer type. If the
     /// specified pointer type is incorrect, assert.
     template<typename T>
     T get() const {
       assert(is<T>() && "Invalid accessor called");
       // If T is PT1/PT2 choose IsInnerUnion otherwise choose IsPT3.
       typedef typename
         ::llvm::PointerUnionTypeSelector<PT1, T, IsInnerUnion,
           ::llvm::PointerUnionTypeSelector<PT2, T, IsInnerUnion, IsPT3 >
                                                                    >::Return Ty;
       return Ty(Val).template get<T>();
     }

     /// dyn_cast<T>() - If the current value is of the specified pointer type,
     /// return it, otherwise return null.
     template<typename T>
     T dyn_cast() const {
       if (is<T>()) return get<T>();
       return T();
     }

     /// Assignment operators - Allow assigning into this union from either
     /// pointer type, setting the discriminator to remember what it came from.
     const PointerUnion3 &operator=(const PT1 &RHS) {
       Val = InnerUnion(RHS);
       return *this;
     }
     const PointerUnion3 &operator=(const PT2 &RHS) {
       Val = InnerUnion(RHS);
       return *this;
     }
     const PointerUnion3 &operator=(const PT3 &RHS) {
       Val = RHS;
       return *this;
     }

     void *getOpaqueValue() const { return Val.getOpaqueValue(); }
     static inline PointerUnion3 getFromOpaqueValue(void *VP) {
       PointerUnion3 V;
       V.Val = ValTy::getFromOpaqueValue(VP);
       return V;
     }
   };

   // Teach SmallPtrSet that PointerUnion3 is "basically a pointer", that has
   // # low bits available = min(PT1bits,PT2bits,PT2bits)-2.
   template<typename PT1, typename PT2, typename PT3>
   class PointerLikeTypeTraits<PointerUnion3<PT1, PT2, PT3> > {
   public:
     static inline void *
     getAsVoidPointer(const PointerUnion3<PT1, PT2, PT3> &P) {
       return P.getOpaqueValue();
     }
     static inline PointerUnion3<PT1, PT2, PT3>
     getFromVoidPointer(void *P) {
       return PointerUnion3<PT1, PT2, PT3>::getFromOpaqueValue(P);
     }

     // The number of bits available are the min of the two pointer types.
     enum {
       NumLowBitsAvailable =
         PointerLikeTypeTraits<typename PointerUnion3<PT1, PT2, PT3>::ValTy>
           ::NumLowBitsAvailable
     };
   };

   /// PointerUnion4 - This is a pointer union of four pointer types.  See
   /// documentation for PointerUnion for usage.
   template <typename PT1, typename PT2, typename PT3, typename PT4>
   class PointerUnion4 {
   public:
     typedef PointerUnion<PT1, PT2> InnerUnion1;
     typedef PointerUnion<PT3, PT4> InnerUnion2;
     typedef PointerUnion<InnerUnion1, InnerUnion2> ValTy;
   private:
     ValTy Val;
   public:
     PointerUnion4() {}

     PointerUnion4(PT1 V) {
       Val = InnerUnion1(V);
     }
     PointerUnion4(PT2 V) {
       Val = InnerUnion1(V);
     }
     PointerUnion4(PT3 V) {
       Val = InnerUnion2(V);
     }
     PointerUnion4(PT4 V) {
       Val = InnerUnion2(V);
     }

     /// isNull - Return true if the pointer held in the union is null,
     /// regardless of which type it is.
     bool isNull() const { return Val.isNull(); }
     operator bool() const { return !isNull(); }

     /// is<T>() return true if the Union currently holds the type matching T.
     template<typename T>
     int is() const {
       // If T is PT1/PT2 choose InnerUnion1 otherwise choose InnerUnion2.
       typedef typename
         ::llvm::PointerUnionTypeSelector<PT1, T, InnerUnion1,
           ::llvm::PointerUnionTypeSelector<PT2, T, InnerUnion1, InnerUnion2 >
                                                                    >::Return Ty;
       return Val.template is<Ty>() &&
              Val.template get<Ty>().template is<T>();
     }

     /// get<T>() - Return the value of the specified pointer type. If the
     /// specified pointer type is incorrect, assert.
     template<typename T>
     T get() const {
       assert(is<T>() && "Invalid accessor called");
       // If T is PT1/PT2 choose InnerUnion1 otherwise choose InnerUnion2.
       typedef typename
         ::llvm::PointerUnionTypeSelector<PT1, T, InnerUnion1,
           ::llvm::PointerUnionTypeSelector<PT2, T, InnerUnion1, InnerUnion2 >
                                                                    >::Return Ty;
       return Val.template get<Ty>().template get<T>();
     }

     /// dyn_cast<T>() - If the current value is of the specified pointer type,
     /// return it, otherwise return null.
     template<typename T>
     T dyn_cast() const {
       if (is<T>()) return get<T>();
       return T();
     }

     /// Assignment operators - Allow assigning into this union from either
     /// pointer type, setting the discriminator to remember what it came from.
     const PointerUnion4 &operator=(const PT1 &RHS) {
       Val = InnerUnion1(RHS);
       return *this;
     }
     const PointerUnion4 &operator=(const PT2 &RHS) {
       Val = InnerUnion1(RHS);
       return *this;
     }
     const PointerUnion4 &operator=(const PT3 &RHS) {
       Val = InnerUnion2(RHS);
       return *this;
     }
     const PointerUnion4 &operator=(const PT4 &RHS) {
       Val = InnerUnion2(RHS);
       return *this;
     }

     void *getOpaqueValue() const { return Val.getOpaqueValue(); }
     static inline PointerUnion4 getFromOpaqueValue(void *VP) {
       PointerUnion4 V;
       V.Val = ValTy::getFromOpaqueValue(VP);
       return V;
     }
   };

   // Teach SmallPtrSet that PointerUnion4 is "basically a pointer", that has
   // # low bits available = min(PT1bits,PT2bits,PT2bits)-2.
   template<typename PT1, typename PT2, typename PT3, typename PT4>
   class PointerLikeTypeTraits<PointerUnion4<PT1, PT2, PT3, PT4> > {
   public:
     static inline void *
     getAsVoidPointer(const PointerUnion4<PT1, PT2, PT3, PT4> &P) {
       return P.getOpaqueValue();
     }
     static inline PointerUnion4<PT1, PT2, PT3, PT4>
     getFromVoidPointer(void *P) {
       return PointerUnion4<PT1, PT2, PT3, PT4>::getFromOpaqueValue(P);
     }

     // The number of bits available are the min of the two pointer types.
     enum {
       NumLowBitsAvailable =
         PointerLikeTypeTraits<typename PointerUnion4<PT1, PT2, PT3, PT4>::ValTy>
           ::NumLowBitsAvailable
     };
   };
 }

 #endif
	//===- llvm/ADT/PointerUnion.h - Discriminated Union of 2 Ptrs --- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the PointerUnion class, which is a discriminated union of
	// pointer types.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ADT_POINTERUNION_H
	#define LLVM_ADT_POINTERUNION_H

	#include "llvm/ADT/PointerIntPair.h"

	namespace llvm {

	template <typename T>
	struct PointerUnionTypeSelectorReturn {
	typedef T Return;
	};

	/// \brief Get a type based on whether two types are the same or not. For:
	/// @code
	/// typedef typename PointerUnionTypeSelector<T1, T2, EQ, NE>::Return Ret;
	/// @endcode
	/// Ret will be EQ type if T1 is same as T2 or NE type otherwise.
	template <typename T1, typename T2, typename RET_EQ, typename RET_NE>
	struct PointerUnionTypeSelector {
	typedef typename PointerUnionTypeSelectorReturn<RET_NE>::Return Return;
	};

	template <typename T, typename RET_EQ, typename RET_NE>
	struct PointerUnionTypeSelector<T, T, RET_EQ, RET_NE> {
	typedef typename PointerUnionTypeSelectorReturn<RET_EQ>::Return Return;
	};

	template <typename T1, typename T2, typename RET_EQ, typename RET_NE>
	struct PointerUnionTypeSelectorReturn<
	PointerUnionTypeSelector<T1, T2, RET_EQ, RET_NE> > {
	typedef typename PointerUnionTypeSelector<T1, T2, RET_EQ, RET_NE>::Return
	Return;
	};

	/// Provide PointerLikeTypeTraits for void* that is used by PointerUnion
	/// for the two template arguments.
	template <typename PT1, typename PT2>
	class PointerUnionUIntTraits {
	public:
	static inline void getAsVoidPointer(void P) { return P; }
	static inline void getFromVoidPointer(void P) { return P; }
	enum {
	PT1BitsAv = PointerLikeTypeTraits<PT1>::NumLowBitsAvailable,
	PT2BitsAv = PointerLikeTypeTraits<PT2>::NumLowBitsAvailable,
	NumLowBitsAvailable = PT1BitsAv < PT2BitsAv ? PT1BitsAv : PT2BitsAv
	};
	};

	/// PointerUnion - This implements a discriminated union of two pointer types,
	/// and keeps the discriminator bit-mangled into the low bits of the pointer.
	/// This allows the implementation to be extremely efficient in space, but
	/// permits a very natural and type-safe API.
	///
	/// Common use patterns would be something like this:
	/// PointerUnion<int, float> P;
	/// P = (int*)0;
	/// printf("%d %d", P.is<int>(), P.is<float>()); // prints "1 0"
	/// X = P.get<int*>(); // ok.
	/// Y = P.get<float*>(); // runtime assertion failure.
	/// Z = P.get<double*>(); // runtime assertion failure (regardless of tag)
	/// P = (float*)0;
	/// Y = P.get<float*>(); // ok.
	/// X = P.get<int*>(); // runtime assertion failure.
	template <typename PT1, typename PT2>
	class PointerUnion {
	public:
	typedef PointerIntPair<void*, 1, bool,
	PointerUnionUIntTraits<PT1,PT2> > ValTy;
	private:
	ValTy Val;

	struct IsPT1 {
	static const int Num = 0;
	};
	struct IsPT2 {
	static const int Num = 1;
	};
	template <typename T>
	struct UNION_DOESNT_CONTAIN_TYPE { };

	public:
	PointerUnion() {}

	PointerUnion(PT1 V) {
	Val.setPointer(
	const_cast<void *>(PointerLikeTypeTraits<PT1>::getAsVoidPointer(V)));
	Val.setInt(0);
	}
	PointerUnion(PT2 V) {
	Val.setPointer(
	const_cast<void *>(PointerLikeTypeTraits<PT2>::getAsVoidPointer(V)));
	Val.setInt(1);
	}

	/// isNull - Return true if the pointer held in the union is null,
	/// regardless of which type it is.
	bool isNull() const {
	// Convert from the void* to one of the pointer types, to make sure that
	// we recursively strip off low bits if we have a nested PointerUnion.
	return !PointerLikeTypeTraits<PT1>::getFromVoidPointer(Val.getPointer());
	}
	operator bool() const { return !isNull(); }

	/// is<T>() return true if the Union currently holds the type matching T.
	template<typename T>
	int is() const {
	typedef typename
	::llvm::PointerUnionTypeSelector<PT1, T, IsPT1,
	::llvm::PointerUnionTypeSelector<PT2, T, IsPT2,
	UNION_DOESNT_CONTAIN_TYPE<T> > >::Return Ty;
	int TyNo = Ty::Num;
	return static_cast<int>(Val.getInt()) == TyNo;
	}

	/// get<T>() - Return the value of the specified pointer type. If the
	/// specified pointer type is incorrect, assert.
	template<typename T>
	T get() const {
	assert(is<T>() && "Invalid accessor called");
	return PointerLikeTypeTraits<T>::getFromVoidPointer(Val.getPointer());
	}

	/// dyn_cast<T>() - If the current value is of the specified pointer type,
	/// return it, otherwise return null.
	template<typename T>
	T dyn_cast() const {
	if (is<T>()) return get<T>();
	return T();
	}

	/// \brief If the union is set to the first pointer type we can get an
	/// address pointing to it.
	template <typename T>
	PT1 const *getAddrOf() const {
	assert(is<PT1>() && "Val is not the first pointer");
	assert(get<PT1>() == Val.getPointer() &&
	"Can't get the address because PointerLikeTypeTraits changes the ptr");
	T const *can_only_get_address_of_first_pointer_type
	= reinterpret_cast<PT1 const *>(Val.getAddrOfPointer());
	return can_only_get_address_of_first_pointer_type;
	}

	/// Assignment operators - Allow assigning into this union from either
	/// pointer type, setting the discriminator to remember what it came from.
	const PointerUnion &operator=(const PT1 &RHS) {
	Val.setPointer(
	const_cast<void *>(PointerLikeTypeTraits<PT1>::getAsVoidPointer(RHS)));
	Val.setInt(0);
	return *this;
	}
	const PointerUnion &operator=(const PT2 &RHS) {
	Val.setPointer(
	const_cast<void *>(PointerLikeTypeTraits<PT2>::getAsVoidPointer(RHS)));
	Val.setInt(1);
	return *this;
	}

	void *getOpaqueValue() const { return Val.getOpaqueValue(); }
	static inline PointerUnion getFromOpaqueValue(void *VP) {
	PointerUnion V;
	V.Val = ValTy::getFromOpaqueValue(VP);
	return V;
	}
	};

	// Teach SmallPtrSet that PointerUnion is "basically a pointer", that has
	// # low bits available = min(PT1bits,PT2bits)-1.
	template<typename PT1, typename PT2>
	class PointerLikeTypeTraits<PointerUnion<PT1, PT2> > {
	public:
	static inline void *
	getAsVoidPointer(const PointerUnion<PT1, PT2> &P) {
	return P.getOpaqueValue();
	}
	static inline PointerUnion<PT1, PT2>
	getFromVoidPointer(void *P) {
	return PointerUnion<PT1, PT2>::getFromOpaqueValue(P);
	}

	// The number of bits available are the min of the two pointer types.
	enum {
	NumLowBitsAvailable =
	PointerLikeTypeTraits<typename PointerUnion<PT1,PT2>::ValTy>
	::NumLowBitsAvailable
	};
	};


	/// PointerUnion3 - This is a pointer union of three pointer types. See
	/// documentation for PointerUnion for usage.
	template <typename PT1, typename PT2, typename PT3>
	class PointerUnion3 {
	public:
	typedef PointerUnion<PT1, PT2> InnerUnion;
	typedef PointerUnion<InnerUnion, PT3> ValTy;
	private:
	ValTy Val;

	struct IsInnerUnion {
	ValTy Val;
	IsInnerUnion(ValTy val) : Val(val) { }
	template<typename T>
	int is() const {
	return Val.template is<InnerUnion>() &&
	Val.template get<InnerUnion>().template is<T>();
	}
	template<typename T>
	T get() const {
	return Val.template get<InnerUnion>().template get<T>();
	}
	};

	struct IsPT3 {
	ValTy Val;
	IsPT3(ValTy val) : Val(val) { }
	template<typename T>
	int is() const {
	return Val.template is<T>();
	}
	template<typename T>
	T get() const {
	return Val.template get<T>();
	}
	};

	public:
	PointerUnion3() {}

	PointerUnion3(PT1 V) {
	Val = InnerUnion(V);
	}
	PointerUnion3(PT2 V) {
	Val = InnerUnion(V);
	}
	PointerUnion3(PT3 V) {
	Val = V;
	}

	/// isNull - Return true if the pointer held in the union is null,
	/// regardless of which type it is.
	bool isNull() const { return Val.isNull(); }
	operator bool() const { return !isNull(); }

	/// is<T>() return true if the Union currently holds the type matching T.
	template<typename T>
	int is() const {
	// If T is PT1/PT2 choose IsInnerUnion otherwise choose IsPT3.
	typedef typename
	::llvm::PointerUnionTypeSelector<PT1, T, IsInnerUnion,
	::llvm::PointerUnionTypeSelector<PT2, T, IsInnerUnion, IsPT3 >
	>::Return Ty;
	return Ty(Val).template is<T>();
	}

	/// get<T>() - Return the value of the specified pointer type. If the
	/// specified pointer type is incorrect, assert.
	template<typename T>
	T get() const {
	assert(is<T>() && "Invalid accessor called");
	// If T is PT1/PT2 choose IsInnerUnion otherwise choose IsPT3.
	typedef typename
	::llvm::PointerUnionTypeSelector<PT1, T, IsInnerUnion,
	::llvm::PointerUnionTypeSelector<PT2, T, IsInnerUnion, IsPT3 >
	>::Return Ty;
	return Ty(Val).template get<T>();
	}

	/// dyn_cast<T>() - If the current value is of the specified pointer type,
	/// return it, otherwise return null.
	template<typename T>
	T dyn_cast() const {
	if (is<T>()) return get<T>();
	return T();
	}

	/// Assignment operators - Allow assigning into this union from either
	/// pointer type, setting the discriminator to remember what it came from.
	const PointerUnion3 &operator=(const PT1 &RHS) {
	Val = InnerUnion(RHS);
	return *this;
	}
	const PointerUnion3 &operator=(const PT2 &RHS) {
	Val = InnerUnion(RHS);
	return *this;
	}
	const PointerUnion3 &operator=(const PT3 &RHS) {
	Val = RHS;
	return *this;
	}

	void *getOpaqueValue() const { return Val.getOpaqueValue(); }
	static inline PointerUnion3 getFromOpaqueValue(void *VP) {
	PointerUnion3 V;
	V.Val = ValTy::getFromOpaqueValue(VP);
	return V;
	}
	};

	// Teach SmallPtrSet that PointerUnion3 is "basically a pointer", that has
	// # low bits available = min(PT1bits,PT2bits,PT2bits)-2.
	template<typename PT1, typename PT2, typename PT3>
	class PointerLikeTypeTraits<PointerUnion3<PT1, PT2, PT3> > {
	public:
	static inline void *
	getAsVoidPointer(const PointerUnion3<PT1, PT2, PT3> &P) {
	return P.getOpaqueValue();
	}
	static inline PointerUnion3<PT1, PT2, PT3>
	getFromVoidPointer(void *P) {
	return PointerUnion3<PT1, PT2, PT3>::getFromOpaqueValue(P);
	}

	// The number of bits available are the min of the two pointer types.
	enum {
	NumLowBitsAvailable =
	PointerLikeTypeTraits<typename PointerUnion3<PT1, PT2, PT3>::ValTy>
	::NumLowBitsAvailable
	};
	};

	/// PointerUnion4 - This is a pointer union of four pointer types. See
	/// documentation for PointerUnion for usage.
	template <typename PT1, typename PT2, typename PT3, typename PT4>
	class PointerUnion4 {
	public:
	typedef PointerUnion<PT1, PT2> InnerUnion1;
	typedef PointerUnion<PT3, PT4> InnerUnion2;
	typedef PointerUnion<InnerUnion1, InnerUnion2> ValTy;
	private:
	ValTy Val;
	public:
	PointerUnion4() {}

	PointerUnion4(PT1 V) {
	Val = InnerUnion1(V);
	}
	PointerUnion4(PT2 V) {
	Val = InnerUnion1(V);
	}
	PointerUnion4(PT3 V) {
	Val = InnerUnion2(V);
	}
	PointerUnion4(PT4 V) {
	Val = InnerUnion2(V);
	}

	/// isNull - Return true if the pointer held in the union is null,
	/// regardless of which type it is.
	bool isNull() const { return Val.isNull(); }
	operator bool() const { return !isNull(); }

	/// is<T>() return true if the Union currently holds the type matching T.
	template<typename T>
	int is() const {
	// If T is PT1/PT2 choose InnerUnion1 otherwise choose InnerUnion2.
	typedef typename
	::llvm::PointerUnionTypeSelector<PT1, T, InnerUnion1,
	::llvm::PointerUnionTypeSelector<PT2, T, InnerUnion1, InnerUnion2 >
	>::Return Ty;
	return Val.template is<Ty>() &&
	Val.template get<Ty>().template is<T>();
	}

	/// get<T>() - Return the value of the specified pointer type. If the
	/// specified pointer type is incorrect, assert.
	template<typename T>
	T get() const {
	assert(is<T>() && "Invalid accessor called");
	// If T is PT1/PT2 choose InnerUnion1 otherwise choose InnerUnion2.
	typedef typename
	::llvm::PointerUnionTypeSelector<PT1, T, InnerUnion1,
	::llvm::PointerUnionTypeSelector<PT2, T, InnerUnion1, InnerUnion2 >
	>::Return Ty;
	return Val.template get<Ty>().template get<T>();
	}

	/// dyn_cast<T>() - If the current value is of the specified pointer type,
	/// return it, otherwise return null.
	template<typename T>
	T dyn_cast() const {
	if (is<T>()) return get<T>();
	return T();
	}

	/// Assignment operators - Allow assigning into this union from either
	/// pointer type, setting the discriminator to remember what it came from.
	const PointerUnion4 &operator=(const PT1 &RHS) {
	Val = InnerUnion1(RHS);
	return *this;
	}
	const PointerUnion4 &operator=(const PT2 &RHS) {
	Val = InnerUnion1(RHS);
	return *this;
	}
	const PointerUnion4 &operator=(const PT3 &RHS) {
	Val = InnerUnion2(RHS);
	return *this;
	}
	const PointerUnion4 &operator=(const PT4 &RHS) {
	Val = InnerUnion2(RHS);
	return *this;
	}

	void *getOpaqueValue() const { return Val.getOpaqueValue(); }
	static inline PointerUnion4 getFromOpaqueValue(void *VP) {
	PointerUnion4 V;
	V.Val = ValTy::getFromOpaqueValue(VP);
	return V;
	}
	};

	// Teach SmallPtrSet that PointerUnion4 is "basically a pointer", that has
	// # low bits available = min(PT1bits,PT2bits,PT2bits)-2.
	template<typename PT1, typename PT2, typename PT3, typename PT4>
	class PointerLikeTypeTraits<PointerUnion4<PT1, PT2, PT3, PT4> > {
	public:
	static inline void *
	getAsVoidPointer(const PointerUnion4<PT1, PT2, PT3, PT4> &P) {
	return P.getOpaqueValue();
	}
	static inline PointerUnion4<PT1, PT2, PT3, PT4>
	getFromVoidPointer(void *P) {
	return PointerUnion4<PT1, PT2, PT3, PT4>::getFromOpaqueValue(P);
	}

	// The number of bits available are the min of the two pointer types.
	enum {
	NumLowBitsAvailable =
	PointerLikeTypeTraits<typename PointerUnion4<PT1, PT2, PT3, PT4>::ValTy>
	::NumLowBitsAvailable
	};
	};
	}

	#endif