test/SemaTemplate/dependent-type-identity.cpp - clang - Git at Google

 // RUN: %clang_cc1 -fsyntax-only -verify -std=c++11 %s

 // This test concerns the identity of dependent types within the
 // canonical type system. This corresponds to C++ [temp.type], which
 // specifies type equivalence within a template.
 //
 // FIXME: template template parameters

 namespace N {
   template<typename T>
   struct X2 {
     template<typename U>
     struct apply {
       typedef U* type;
     };
   };
 }

 namespace Nalias = N;

 template<typename T>
 struct X0 { };

 using namespace N;

 template<typename T, typename U>
 struct X1 {
   typedef T type;
   typedef U U_type;

   void f0(T); // expected-note{{previous}}
   void f0(U);
   void f0(type); // expected-error{{redeclar}}

   void f1(T*); // expected-note{{previous}}
   void f1(U*);
   void f1(type*); // expected-error{{redeclar}}

   void f2(X0<T>*); // expected-note{{previous}}
   void f2(X0<U>*);
   void f2(X0<type>*); // expected-error{{redeclar}}

   void f3(X0<T>*); // expected-note{{previous}}
   void f3(X0<U>*);
   void f3(::X0<type>*); // expected-error{{redeclar}}

   void f4(typename T::template apply<U>*); // expected-note{{previous}}
   void f4(typename U::template apply<U>*);
   void f4(typename type::template apply<T>*);
   void f4(typename type::template apply<U_type>*); // expected-error{{redeclar}}

   void f5(typename T::template apply<U>::type*); // expected-note{{previous}}
   void f5(typename U::template apply<U>::type*);
   void f5(typename U::template apply<T>::type*);
   void f5(typename type::template apply<T>::type*);
   void f5(typename type::template apply<U_type>::type*); // expected-error{{redeclar}}

   void f6(typename N::X2<T>::template apply<U> *); // expected-note{{previous}}
   void f6(typename N::X2<U>::template apply<U> *);
   void f6(typename N::X2<U>::template apply<T> *);
   void f6(typename ::N::X2<type>::template apply<U_type> *); // expected-error{{redeclar}}

   void f7(typename N::X2<T>::template apply<U> *); // expected-note{{previous}}
   void f7(typename N::X2<U>::template apply<U> *);
   void f7(typename N::X2<U>::template apply<T> *);
   void f7(typename X2<type>::template apply<U_type> *); // expected-error{{redeclar}}

   void f8(typename N::X2<T>::template apply<U> *); // expected-note{{previous}}
   void f8(typename N::X2<U>::template apply<U> *);
   void f8(typename N::X2<U>::template apply<T> *);
   void f8(typename ::Nalias::X2<type>::template apply<U_type> *); // expected-error{{redeclar}}
 };

 namespace PR6851 {
   template <bool v>
   struct S;

   struct N {
     template <bool w>
     S< S<w>::cond && 1 > foo();
   };

   struct Arrow { Arrow *operator->(); int n; };
   template<typename T> struct M {
     Arrow a;
     auto f() -> M<decltype(a->n)>;
   };

   struct Alien;
   bool operator&&(const Alien&, const Alien&);

   template <bool w>
   S< S<w>::cond && 1 > N::foo() { }

   template<typename T>
   auto M<T>::f() -> M<decltype(a->n)> {}
 }

 namespace PR7460 {
   template <typename T>
   struct TemplateClass2
   {
     enum { SIZE = 100 };
     static T member[SIZE];
   };

   template <typename T>
   T TemplateClass2<T>::member[TemplateClass2<T>::SIZE];
 }

 namespace PR18275 {
   template<typename T> struct A {
     void f(const int);
     void g(int);
     void h(const T);
     void i(T);
   };

   template<typename T>
   void A<T>::f(int x) { x = 0; }

   template<typename T>
   void A<T>::g(const int x) {  // expected-note {{declared const here}}
     x = 0; // expected-error {{cannot assign to variable 'x'}}
   }

   template<typename T>
   void A<T>::h(T) {} // FIXME: Should reject this. Type is different from prior decl if T is an array type.

   template<typename T>
   void A<T>::i(const T) {} // FIXME: Should reject this. Type is different from prior decl if T is an array type.

   template struct A<int>;
   template struct A<int[1]>;
 }

 namespace PR21289 {
   template<typename T> using X = int;
   template<typename T, decltype(sizeof(0))> using Y = int;
   template<typename ...Ts> struct S {};
   template<typename ...Ts> void f() {
     // This is a dependent type. It is *not* S<int>, even though it canonically
     // contains no template parameters.
     using Type = S<X<Ts>...>;
     Type s;
     using Type = S<int, int, int>;
   }
   void g() { f<void, void, void>(); }

   template<typename ...Ts> void h(S<int>) {}
   // Pending a core issue, it's not clear if these are redeclarations, but they
   // are probably intended to be... even though substitution can succeed for one
   // of them but fail for the other!
   template<typename ...Ts> void h(S<X<Ts>...>) {} // expected-note {{previous}}
   template<typename ...Ts> void h(S<Y<Ts, sizeof(Ts)>...>) {} // expected-error {{redefinition}}
 }
	// RUN: %clang_cc1 -fsyntax-only -verify -std=c++11 %s

	// This test concerns the identity of dependent types within the
	// canonical type system. This corresponds to C++ [temp.type], which
	// specifies type equivalence within a template.
	//
	// FIXME: template template parameters

	namespace N {
	template<typename T>
	struct X2 {
	template<typename U>
	struct apply {
	typedef U* type;
	};
	};
	}

	namespace Nalias = N;

	template<typename T>
	struct X0 { };

	using namespace N;

	template<typename T, typename U>
	struct X1 {
	typedef T type;
	typedef U U_type;

	void f0(T); // expected-note{{previous}}
	void f0(U);
	void f0(type); // expected-error{{redeclar}}

	void f1(T*); // expected-note{{previous}}
	void f1(U*);
	void f1(type*); // expected-error{{redeclar}}

	void f2(X0<T>*); // expected-note{{previous}}
	void f2(X0<U>*);
	void f2(X0<type>*); // expected-error{{redeclar}}

	void f3(X0<T>*); // expected-note{{previous}}
	void f3(X0<U>*);
	void f3(::X0<type>*); // expected-error{{redeclar}}

	void f4(typename T::template apply<U>*); // expected-note{{previous}}
	void f4(typename U::template apply<U>*);
	void f4(typename type::template apply<T>*);
	void f4(typename type::template apply<U_type>*); // expected-error{{redeclar}}

	void f5(typename T::template apply<U>::type*); // expected-note{{previous}}
	void f5(typename U::template apply<U>::type*);
	void f5(typename U::template apply<T>::type*);
	void f5(typename type::template apply<T>::type*);
	void f5(typename type::template apply<U_type>::type*); // expected-error{{redeclar}}

	void f6(typename N::X2<T>::template apply<U> *); // expected-note{{previous}}
	void f6(typename N::X2<U>::template apply<U> *);
	void f6(typename N::X2<U>::template apply<T> *);
	void f6(typename ::N::X2<type>::template apply<U_type> *); // expected-error{{redeclar}}

	void f7(typename N::X2<T>::template apply<U> *); // expected-note{{previous}}
	void f7(typename N::X2<U>::template apply<U> *);
	void f7(typename N::X2<U>::template apply<T> *);
	void f7(typename X2<type>::template apply<U_type> *); // expected-error{{redeclar}}

	void f8(typename N::X2<T>::template apply<U> *); // expected-note{{previous}}
	void f8(typename N::X2<U>::template apply<U> *);
	void f8(typename N::X2<U>::template apply<T> *);
	void f8(typename ::Nalias::X2<type>::template apply<U_type> *); // expected-error{{redeclar}}
	};

	namespace PR6851 {
	template <bool v>
	struct S;

	struct N {
	template <bool w>
	S< S<w>::cond && 1 > foo();
	};

	struct Arrow { Arrow *operator->(); int n; };
	template<typename T> struct M {
	Arrow a;
	auto f() -> M<decltype(a->n)>;
	};

	struct Alien;
	bool operator&&(const Alien&, const Alien&);

	template <bool w>
	S< S<w>::cond && 1 > N::foo() { }

	template<typename T>
	auto M<T>::f() -> M<decltype(a->n)> {}
	}

	namespace PR7460 {
	template <typename T>
	struct TemplateClass2
	{
	enum { SIZE = 100 };
	static T member[SIZE];
	};

	template <typename T>
	T TemplateClass2<T>::member[TemplateClass2<T>::SIZE];
	}

	namespace PR18275 {
	template<typename T> struct A {
	void f(const int);
	void g(int);
	void h(const T);
	void i(T);
	};

	template<typename T>
	void A<T>::f(int x) { x = 0; }

	template<typename T>
	void A<T>::g(const int x) { // expected-note {{declared const here}}
	x = 0; // expected-error {{cannot assign to variable 'x'}}
	}

	template<typename T>
	void A<T>::h(T) {} // FIXME: Should reject this. Type is different from prior decl if T is an array type.

	template<typename T>
	void A<T>::i(const T) {} // FIXME: Should reject this. Type is different from prior decl if T is an array type.

	template struct A<int>;
	template struct A<int[1]>;
	}

	namespace PR21289 {
	template<typename T> using X = int;
	template<typename T, decltype(sizeof(0))> using Y = int;
	template<typename ...Ts> struct S {};
	template<typename ...Ts> void f() {
	// This is a dependent type. It is not S<int>, even though it canonically
	// contains no template parameters.
	using Type = S<X<Ts>...>;
	Type s;
	using Type = S<int, int, int>;
	}
	void g() { f<void, void, void>(); }

	template<typename ...Ts> void h(S<int>) {}
	// Pending a core issue, it's not clear if these are redeclarations, but they
	// are probably intended to be... even though substitution can succeed for one
	// of them but fail for the other!
	template<typename ...Ts> void h(S<X<Ts>...>) {} // expected-note {{previous}}
	template<typename ...Ts> void h(S<Y<Ts, sizeof(Ts)>...>) {} // expected-error {{redefinition}}
	}