test/SemaTemplate/member-template-access-expr.cpp - clang - Git at Google

 // RUN: %clang_cc1 -fsyntax-only -verify %s
 template<typename U, typename T>
 U f0(T t) {
   return t.template get<U>();
 }

 template<typename U, typename T>
 int &f1(T t) {
   // FIXME: When we pretty-print this, we lose the "template" keyword.
   return t.U::template get<int&>();
 }

 struct X {
   template<typename T> T get();
 };

 void test_f0(X x) {
   int i = f0<int>(x);
   int &ir = f0<int&>(x);
 }

 struct XDerived : public X {
 };

 void test_f1(XDerived xd) {
   int &ir = f1<X>(xd);
 }

 // PR5213
 template <class T>
 struct A {};

 template<class T>
 class B
 {
   A<T> a_;

 public:
   void destroy();
 };

 template<class T>
 void
 B<T>::destroy()
 {
   a_.~A<T>();
 }

 void do_destroy_B(B<int> b) {
   b.destroy();
 }

 struct X1 {
   int* f1(int);
   template<typename T> float* f1(T);

   static int* f2(int);
   template<typename T> static float* f2(T);
 };

 void test_X1(X1 x1) {
   float *fp1 = x1.f1<>(17);
   float *fp2 = x1.f1<int>(3.14); // expected-warning {{implicit conversion from 'double' to 'int' changes value from 3.14 to 3}}
   int *ip1 = x1.f1(17);
   float *ip2 = x1.f1(3.14);

   float* (X1::*mf1)(int) = &X1::f1;
   float* (X1::*mf2)(int) = &X1::f1<>;
   float* (X1::*mf3)(float) = &X1::f1<float>;

   float* (*fp3)(int) = &X1::f2;
   float* (*fp4)(int) = &X1::f2<>;
   float* (*fp5)(float) = &X1::f2<float>;
   float* (*fp6)(int) = X1::f2;
   float* (*fp7)(int) = X1::f2<>;
   float* (*fp8)(float) = X1::f2<float>;
 }

 template<int A> struct X2 {
   int m;
 };

 template<typename T>
 struct X3 : T { };

 template<typename T>
 struct X4 {
   template<typename U>
   void f(X2<sizeof(X3<U>().U::m)>);
 };

 void f(X4<X3<int> > x4i) {
   X2<sizeof(int)> x2;
   x4i.f<X2<sizeof(int)> >(x2);
 }

 template<typename T>
 struct X5 {
   template<typename U>
   void f();

   void g() {
     this->f<T*>();
   }
 };

 namespace PR6021 {
   template< class T1, class T2 >
   class Outer
   {
   public: // Range operations
     template< class X > X tmpl( const X* = 0 ) const;

     struct Inner
     {
       const Outer& o;

       template< class X >
       operator X() const
       {
         return o.tmpl<X>();
       }
     };
   };
 }

 namespace rdar8198511 {
   template<int, typename U>
   struct Base {
     void f();
   };

   template<typename T>
   struct X0 : Base<1, T> { };

   template<typename T>
   struct X1 {
     X0<int> x0;

     void f() {
       this->x0.Base<1, int>::f();
     }
   };
 }
	// RUN: %clang_cc1 -fsyntax-only -verify %s
	template<typename U, typename T>
	U f0(T t) {
	return t.template get<U>();
	}

	template<typename U, typename T>
	int &f1(T t) {
	// FIXME: When we pretty-print this, we lose the "template" keyword.
	return t.U::template get<int&>();
	}

	struct X {
	template<typename T> T get();
	};

	void test_f0(X x) {
	int i = f0<int>(x);
	int &ir = f0<int&>(x);
	}

	struct XDerived : public X {
	};

	void test_f1(XDerived xd) {
	int &ir = f1<X>(xd);
	}

	// PR5213
	template <class T>
	struct A {};

	template<class T>
	class B
	{
	A<T> a_;

	public:
	void destroy();
	};

	template<class T>
	void
	B<T>::destroy()
	{
	a_.~A<T>();
	}

	void do_destroy_B(B<int> b) {
	b.destroy();
	}

	struct X1 {
	int* f1(int);
	template<typename T> float* f1(T);

	static int* f2(int);
	template<typename T> static float* f2(T);
	};

	void test_X1(X1 x1) {
	float *fp1 = x1.f1<>(17);
	float *fp2 = x1.f1<int>(3.14); // expected-warning {{implicit conversion from 'double' to 'int' changes value from 3.14 to 3}}
	int *ip1 = x1.f1(17);
	float *ip2 = x1.f1(3.14);

	float* (X1::*mf1)(int) = &X1::f1;
	float* (X1::*mf2)(int) = &X1::f1<>;
	float* (X1::*mf3)(float) = &X1::f1<float>;

	float* (*fp3)(int) = &X1::f2;
	float* (*fp4)(int) = &X1::f2<>;
	float* (*fp5)(float) = &X1::f2<float>;
	float* (*fp6)(int) = X1::f2;
	float* (*fp7)(int) = X1::f2<>;
	float* (*fp8)(float) = X1::f2<float>;
	}

	template<int A> struct X2 {
	int m;
	};

	template<typename T>
	struct X3 : T { };

	template<typename T>
	struct X4 {
	template<typename U>
	void f(X2<sizeof(X3<U>().U::m)>);
	};

	void f(X4<X3<int> > x4i) {
	X2<sizeof(int)> x2;
	x4i.f<X2<sizeof(int)> >(x2);
	}

	template<typename T>
	struct X5 {
	template<typename U>
	void f();

	void g() {
	this->f<T*>();
	}
	};

	namespace PR6021 {
	template< class T1, class T2 >
	class Outer
	{
	public: // Range operations
	template< class X > X tmpl( const X* = 0 ) const;

	struct Inner
	{
	const Outer& o;

	template< class X >
	operator X() const
	{
	return o.tmpl<X>();
	}
	};
	};
	}

	namespace rdar8198511 {
	template<int, typename U>
	struct Base {
	void f();
	};

	template<typename T>
	struct X0 : Base<1, T> { };

	template<typename T>
	struct X1 {
	X0<int> x0;

	void f() {
	this->x0.Base<1, int>::f();
	}
	};
	}