test/SemaTemplate/current-instantiation.cpp - third_party/swift-clang - Git at Google

 // RUN: %clang_cc1 -fsyntax-only -verify %s

 // This test concerns the identity of dependent types within the
 // canonical type system, specifically focusing on the difference
 // between members of the current instantiation and members of an
 // unknown specialization. This considers C++ [temp.type], which
 // specifies type equivalence within a template, and C++0x
 // [temp.dep.type], which defines what it means to be a member of the
 // current instantiation.

 template<typename T, typename U>
 struct X0 {
   typedef T T_type;
   typedef U U_type;

   void f0(T&); // expected-note{{previous}}
   void f0(typename X0::U_type&);
   void f0(typename X0::T_type&); // expected-error{{redecl}}

   void f1(T&); // expected-note{{previous}}
   void f1(typename X0::U_type&);
   void f1(typename X0<T, U>::T_type&); // expected-error{{redecl}}

   void f2(T&); // expected-note{{previous}}
   void f2(typename X0::U_type&);
   void f2(typename X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

   void f3(T&); // expected-note{{previous}}
   void f3(typename X0::U_type&);
   void f3(typename ::X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

   struct X1 {
     typedef T my_T_type;

     void g0(T&); // expected-note{{previous}}
     void g0(typename X0::U_type&);
     void g0(typename X0::T_type&); // expected-error{{redecl}}

     void g1(T&); // expected-note{{previous}}
     void g1(typename X0::U_type&);
     void g1(typename X0<T, U>::T_type&); // expected-error{{redecl}}

     void g2(T&); // expected-note{{previous}}
     void g2(typename X0::U_type&);
     void g2(typename X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

     void g3(T&); // expected-note{{previous}}
     void g3(typename X0::U_type&);
     void g3(typename ::X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

     void g4(T&); // expected-note{{previous}}
     void g4(typename X0::U_type&);
     void g4(typename X1::my_T_type&); // expected-error{{redecl}}

     void g5(T&); // expected-note{{previous}}
     void g5(typename X0::U_type&);
     void g5(typename X0::X1::my_T_type&); // expected-error{{redecl}}

     void g6(T&); // expected-note{{previous}}
     void g6(typename X0::U_type&);
     void g6(typename X0<T, U>::X1::my_T_type&); // expected-error{{redecl}}

     void g7(T&); // expected-note{{previous}}
     void g7(typename X0::U_type&);
     void g7(typename ::X0<typename X1::my_T_type, U_type>::X1::my_T_type&); // expected-error{{redecl}}

     void g8(T&); // expected-note{{previous}}
     void g8(typename X0<U, T_type>::T_type&);
     void g8(typename ::X0<typename X0<T_type, U>::X1::my_T_type, U_type>::X1::my_T_type&); // expected-error{{redecl}}
   };
 };


 template<typename T, typename U>
 struct X0<T*, U*> {
   typedef T T_type;
   typedef U U_type;
   typedef T* Tptr;
   typedef U* Uptr;

   void f0(T&); // expected-note{{previous}}
   void f0(typename X0::U_type&);
   void f0(typename X0::T_type&); // expected-error{{redecl}}

   void f1(T&); // expected-note{{previous}}
   void f1(typename X0::U_type&);
   void f1(typename X0<T*, U*>::T_type&); // expected-error{{redecl}}

   void f2(T&); // expected-note{{previous}}
   void f2(typename X0::U_type&);
   void f2(typename X0<T_type*, U_type*>::T_type&); // expected-error{{redecl}}

   void f3(T&); // expected-note{{previous}}
   void f3(typename X0::U_type&);
   void f3(typename ::X0<T_type*, U_type*>::T_type&); // expected-error{{redecl}}

   void f4(T&); // expected-note{{previous}}
   void f4(typename X0::U_type&);
   void f4(typename ::X0<Tptr, Uptr>::T_type&); // expected-error{{redecl}}

   void f5(X0*); // expected-note{{previous}}
   void f5(::X0<T, U>*);
   void f5(::X0<T*, U*>*); // expected-error{{redecl}}

   struct X2 {
     typedef T my_T_type;

     void g0(T&); // expected-note{{previous}}
     void g0(typename X0::U_type&);
     void g0(typename X0::T_type&); // expected-error{{redecl}}

     void g1(T&); // expected-note{{previous}}
     void g1(typename X0::U_type&);
     void g1(typename X0<T*, U*>::T_type&); // expected-error{{redecl}}

     void g2(T&); // expected-note{{previous}}
     void g2(typename X0::U_type&);
     void g2(typename X0<T_type*, U_type*>::T_type&); // expected-error{{redecl}}

     void g3(T&); // expected-note{{previous}}
     void g3(typename X0::U_type&);
     void g3(typename ::X0<T_type*, U_type*>::T_type&); // expected-error{{redecl}}

     void g4(T&); // expected-note{{previous}}
     void g4(typename X0::U_type&);
     void g4(typename X2::my_T_type&); // expected-error{{redecl}}

     void g5(T&); // expected-note{{previous}}
     void g5(typename X0::U_type&);
     void g5(typename X0::X2::my_T_type&); // expected-error{{redecl}}

     void g6(T&); // expected-note{{previous}}
     void g6(typename X0::U_type&);
     void g6(typename X0<T*, U*>::X2::my_T_type&); // expected-error{{redecl}}

     void g7(T&); // expected-note{{previous}}
     void g7(typename X0::U_type&);
     void g7(typename ::X0<typename X2::my_T_type*, U_type*>::X2::my_T_type&); // expected-error{{redecl}}

     void g8(T&); // expected-note{{previous}}
     void g8(typename X0<U, T_type>::T_type&);
     void g8(typename ::X0<typename X0<T_type*, U*>::X2::my_T_type*, U_type*>::X2::my_T_type&); // expected-error{{redecl}}
   };
 };

 template<typename T>
 struct X1 {
   static int *a;
   void f(float *b) {
     X1<T>::a = b; // expected-error{{incompatible}}
     X1<T*>::a = b;
   }
 };

 namespace ConstantInCurrentInstantiation {
   template<typename T>
   struct X {
     static const int value = 2;
     static int array[value];
   };

   template<typename T> const int X<T>::value;

   template<typename T>
   int X<T>::array[X<T>::value] = { 1, 2 };
 }

 namespace Expressions {
   template <bool b>
   struct Bool {
     enum anonymous_enum { value = b };
   };
   struct True : public Bool<true> {};
   struct False : public Bool<false> {};

   template <typename T1, typename T2>
   struct Is_Same : public False {};
   template <typename T>
   struct Is_Same<T, T> : public True {};

   template <bool b, typename T = void>
   struct Enable_If {};
   template <typename T>
   struct Enable_If<true, T>  {
     typedef T type;
   };

   template <typename T>
   class Class {
   public:
     template <typename U>
     typename Enable_If<Is_Same<U, Class>::value, void>::type
     foo();
   };


   template <typename T>
   template <typename U>
   typename Enable_If<Is_Same<U, Class<T> >::value, void>::type
   Class<T>::foo() {}
 }

 namespace PR9255 {
   template<typename T>
   class X0  {
   public:
     class Inner1;

     class Inner2  {
     public:
       void f()
       {
         Inner1::f.g();
       }
     };
   };
 }

 namespace rdar10194295 {
   template<typename XT>
   class X {
   public:
     enum Enum { Yes, No };
     template<Enum> void foo();
     template<Enum> class Inner;
   };

   template<typename XT>
   template<typename X<XT>::Enum>
   void X<XT>::foo()
   {
   }

   template<typename XT>
   template<typename X<XT>::Enum>
   class X<XT>::Inner { };
 }

 namespace RebuildDependentScopeDeclRefExpr {
   template<int> struct N {};
   template<typename T> struct X {
     static const int thing = 0;
     N<thing> data();
     N<thing> foo();
   };
   template<typename T> N<X<T>::thing> X<T>::data() {}
   // FIXME: We should issue a typo-correction here.
   template<typename T> N<X<T>::think> X<T>::foo() {} // expected-error {{no member named 'think' in 'X<T>'}}
 }
	// RUN: %clang_cc1 -fsyntax-only -verify %s

	// This test concerns the identity of dependent types within the
	// canonical type system, specifically focusing on the difference
	// between members of the current instantiation and members of an
	// unknown specialization. This considers C++ [temp.type], which
	// specifies type equivalence within a template, and C++0x
	// [temp.dep.type], which defines what it means to be a member of the
	// current instantiation.

	template<typename T, typename U>
	struct X0 {
	typedef T T_type;
	typedef U U_type;

	void f0(T&); // expected-note{{previous}}
	void f0(typename X0::U_type&);
	void f0(typename X0::T_type&); // expected-error{{redecl}}

	void f1(T&); // expected-note{{previous}}
	void f1(typename X0::U_type&);
	void f1(typename X0<T, U>::T_type&); // expected-error{{redecl}}

	void f2(T&); // expected-note{{previous}}
	void f2(typename X0::U_type&);
	void f2(typename X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void f3(T&); // expected-note{{previous}}
	void f3(typename X0::U_type&);
	void f3(typename ::X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	struct X1 {
	typedef T my_T_type;

	void g0(T&); // expected-note{{previous}}
	void g0(typename X0::U_type&);
	void g0(typename X0::T_type&); // expected-error{{redecl}}

	void g1(T&); // expected-note{{previous}}
	void g1(typename X0::U_type&);
	void g1(typename X0<T, U>::T_type&); // expected-error{{redecl}}

	void g2(T&); // expected-note{{previous}}
	void g2(typename X0::U_type&);
	void g2(typename X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void g3(T&); // expected-note{{previous}}
	void g3(typename X0::U_type&);
	void g3(typename ::X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void g4(T&); // expected-note{{previous}}
	void g4(typename X0::U_type&);
	void g4(typename X1::my_T_type&); // expected-error{{redecl}}

	void g5(T&); // expected-note{{previous}}
	void g5(typename X0::U_type&);
	void g5(typename X0::X1::my_T_type&); // expected-error{{redecl}}

	void g6(T&); // expected-note{{previous}}
	void g6(typename X0::U_type&);
	void g6(typename X0<T, U>::X1::my_T_type&); // expected-error{{redecl}}

	void g7(T&); // expected-note{{previous}}
	void g7(typename X0::U_type&);
	void g7(typename ::X0<typename X1::my_T_type, U_type>::X1::my_T_type&); // expected-error{{redecl}}

	void g8(T&); // expected-note{{previous}}
	void g8(typename X0<U, T_type>::T_type&);
	void g8(typename ::X0<typename X0<T_type, U>::X1::my_T_type, U_type>::X1::my_T_type&); // expected-error{{redecl}}
	};
	};


	template<typename T, typename U>
	struct X0<T, U> {
	typedef T T_type;
	typedef U U_type;
	typedef T* Tptr;
	typedef U* Uptr;

	void f0(T&); // expected-note{{previous}}
	void f0(typename X0::U_type&);
	void f0(typename X0::T_type&); // expected-error{{redecl}}

	void f1(T&); // expected-note{{previous}}
	void f1(typename X0::U_type&);
	void f1(typename X0<T, U>::T_type&); // expected-error{{redecl}}

	void f2(T&); // expected-note{{previous}}
	void f2(typename X0::U_type&);
	void f2(typename X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void f3(T&); // expected-note{{previous}}
	void f3(typename X0::U_type&);
	void f3(typename ::X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void f4(T&); // expected-note{{previous}}
	void f4(typename X0::U_type&);
	void f4(typename ::X0<Tptr, Uptr>::T_type&); // expected-error{{redecl}}

	void f5(X0*); // expected-note{{previous}}
	void f5(::X0<T, U>*);
	void f5(::X0<T, U>*); // expected-error{{redecl}}

	struct X2 {
	typedef T my_T_type;

	void g0(T&); // expected-note{{previous}}
	void g0(typename X0::U_type&);
	void g0(typename X0::T_type&); // expected-error{{redecl}}

	void g1(T&); // expected-note{{previous}}
	void g1(typename X0::U_type&);
	void g1(typename X0<T, U>::T_type&); // expected-error{{redecl}}

	void g2(T&); // expected-note{{previous}}
	void g2(typename X0::U_type&);
	void g2(typename X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void g3(T&); // expected-note{{previous}}
	void g3(typename X0::U_type&);
	void g3(typename ::X0<T_type, U_type>::T_type&); // expected-error{{redecl}}

	void g4(T&); // expected-note{{previous}}
	void g4(typename X0::U_type&);
	void g4(typename X2::my_T_type&); // expected-error{{redecl}}

	void g5(T&); // expected-note{{previous}}
	void g5(typename X0::U_type&);
	void g5(typename X0::X2::my_T_type&); // expected-error{{redecl}}

	void g6(T&); // expected-note{{previous}}
	void g6(typename X0::U_type&);
	void g6(typename X0<T, U>::X2::my_T_type&); // expected-error{{redecl}}

	void g7(T&); // expected-note{{previous}}
	void g7(typename X0::U_type&);
	void g7(typename ::X0<typename X2::my_T_type, U_type>::X2::my_T_type&); // expected-error{{redecl}}

	void g8(T&); // expected-note{{previous}}
	void g8(typename X0<U, T_type>::T_type&);
	void g8(typename ::X0<typename X0<T_type, U>::X2::my_T_type, U_type>::X2::my_T_type&); // expected-error{{redecl}}
	};
	};

	template<typename T>
	struct X1 {
	static int *a;
	void f(float *b) {
	X1<T>::a = b; // expected-error{{incompatible}}
	X1<T*>::a = b;
	}
	};

	namespace ConstantInCurrentInstantiation {
	template<typename T>
	struct X {
	static const int value = 2;
	static int array[value];
	};

	template<typename T> const int X<T>::value;

	template<typename T>
	int X<T>::array[X<T>::value] = { 1, 2 };
	}

	namespace Expressions {
	template <bool b>
	struct Bool {
	enum anonymous_enum { value = b };
	};
	struct True : public Bool<true> {};
	struct False : public Bool<false> {};

	template <typename T1, typename T2>
	struct Is_Same : public False {};
	template <typename T>
	struct Is_Same<T, T> : public True {};

	template <bool b, typename T = void>
	struct Enable_If {};
	template <typename T>
	struct Enable_If<true, T> {
	typedef T type;
	};

	template <typename T>
	class Class {
	public:
	template <typename U>
	typename Enable_If<Is_Same<U, Class>::value, void>::type
	foo();
	};


	template <typename T>
	template <typename U>
	typename Enable_If<Is_Same<U, Class<T> >::value, void>::type
	Class<T>::foo() {}
	}

	namespace PR9255 {
	template<typename T>
	class X0 {
	public:
	class Inner1;

	class Inner2 {
	public:
	void f()
	{
	Inner1::f.g();
	}
	};
	};
	}

	namespace rdar10194295 {
	template<typename XT>
	class X {
	public:
	enum Enum { Yes, No };
	template<Enum> void foo();
	template<Enum> class Inner;
	};

	template<typename XT>
	template<typename X<XT>::Enum>
	void X<XT>::foo()
	{
	}

	template<typename XT>
	template<typename X<XT>::Enum>
	class X<XT>::Inner { };
	}

	namespace RebuildDependentScopeDeclRefExpr {
	template<int> struct N {};
	template<typename T> struct X {
	static const int thing = 0;
	N<thing> data();
	N<thing> foo();
	};
	template<typename T> N<X<T>::thing> X<T>::data() {}
	// FIXME: We should issue a typo-correction here.
	template<typename T> N<X<T>::think> X<T>::foo() {} // expected-error {{no member named 'think' in 'X<T>'}}
	}