test/SemaTemplate/instantiate-method.cpp - clang - Git at Google

 // RUN: clang-cc -fsyntax-only -verify %s
 template<typename T>
 class X {
 public:
   void f(T x); // expected-error{{argument may not have 'void' type}}
   void g(T*);

   static int h(T, T); // expected-error 2{{argument may not have 'void' type}}
 };

 int identity(int x) { return x; }

 void test(X<int> *xi, int *ip, X<int(int)> *xf) {
   xi->f(17);
   xi->g(ip);
   xf->f(&identity);
   xf->g(identity);
   X<int>::h(17, 25);
   X<int(int)>::h(identity, &identity);
 }

 void test_bad() {
   X<void> xv; // expected-note{{in instantiation of template class 'class X<void>' requested here}}
 }

 template<typename T, typename U>
 class Overloading {
 public:
   int& f(T, T); // expected-note{{previous declaration is here}}
   float& f(T, U); // expected-error{{functions that differ only in their return type cannot be overloaded}}
 };

 void test_ovl(Overloading<int, long> *oil, int i, long l) {
   int &ir = oil->f(i, i);
   float &fr = oil->f(i, l);
 }

 void test_ovl_bad() {
   Overloading<float, float> off; // expected-note{{in instantiation of template class 'class Overloading<float, float>' requested here}}
 }

 template<typename T>
 class HasDestructor {
 public:
   virtual ~HasDestructor() = 0;
 };

 int i = sizeof(HasDestructor<int>); // FIXME: forces instantiation, but
                 // the code below should probably instantiate by itself.
 int abstract_destructor[__is_abstract(HasDestructor<int>)? 1 : -1];


 template<typename T>
 class Constructors {
 public:
   Constructors(const T&);
   Constructors(const Constructors &other);
 };

 void test_constructors() {
   Constructors<int> ci1(17);
   Constructors<int> ci2 = ci1;
 }


 template<typename T>
 struct ConvertsTo {
   operator T();
 };

 void test_converts_to(ConvertsTo<int> ci, ConvertsTo<int *> cip) {
   int i = ci;
   int *ip = cip;
 }
	// RUN: clang-cc -fsyntax-only -verify %s
	template<typename T>
	class X {
	public:
	void f(T x); // expected-error{{argument may not have 'void' type}}
	void g(T*);

	static int h(T, T); // expected-error 2{{argument may not have 'void' type}}
	};

	int identity(int x) { return x; }

	void test(X<int> xi, int ip, X<int(int)> *xf) {
	xi->f(17);
	xi->g(ip);
	xf->f(&identity);
	xf->g(identity);
	X<int>::h(17, 25);
	X<int(int)>::h(identity, &identity);
	}

	void test_bad() {
	X<void> xv; // expected-note{{in instantiation of template class 'class X<void>' requested here}}
	}

	template<typename T, typename U>
	class Overloading {
	public:
	int& f(T, T); // expected-note{{previous declaration is here}}
	float& f(T, U); // expected-error{{functions that differ only in their return type cannot be overloaded}}
	};

	void test_ovl(Overloading<int, long> *oil, int i, long l) {
	int &ir = oil->f(i, i);
	float &fr = oil->f(i, l);
	}

	void test_ovl_bad() {
	Overloading<float, float> off; // expected-note{{in instantiation of template class 'class Overloading<float, float>' requested here}}
	}

	template<typename T>
	class HasDestructor {
	public:
	virtual ~HasDestructor() = 0;
	};

	int i = sizeof(HasDestructor<int>); // FIXME: forces instantiation, but
	// the code below should probably instantiate by itself.
	int abstract_destructor[__is_abstract(HasDestructor<int>)? 1 : -1];


	template<typename T>
	class Constructors {
	public:
	Constructors(const T&);
	Constructors(const Constructors &other);
	};

	void test_constructors() {
	Constructors<int> ci1(17);
	Constructors<int> ci2 = ci1;
	}


	template<typename T>
	struct ConvertsTo {
	operator T();
	};

	void test_converts_to(ConvertsTo<int> ci, ConvertsTo<int *> cip) {
	int i = ci;
	int *ip = cip;
	}