clang/test/SemaCXX/addr-of-overloaded-function.cpp - toolchain/llvm-project - Gitiles

 // RUN: %clang_cc1 -fsyntax-only -verify %s
 int f(double); // expected-note{{candidate function}}
 int f(int); // expected-note{{candidate function}}

 int (*pfd)(double) = f; // selects f(double)
 int (*pfd2)(double) = &f; // selects f(double)
 int (*pfd3)(double) = ((&((f)))); // selects f(double)
 int (*pfi)(int) = &f;    // selects f(int)
 // FIXME: This error message is not very good. We need to keep better
 // track of what went wrong when the implicit conversion failed to
 // give a better error message here.
 int (*pfe)(...) = &f;    // expected-error{{address of overloaded function 'f' does not match required type 'int (...)'}}
 int (&rfi)(int) = f;     // selects f(int)
 int (&rfd)(double) = f;  // selects f(double)

 void g(int (*fp)(int));   // expected-note{{candidate function}}
 void g(int (*fp)(float));
 void g(int (*fp)(double)); // expected-note{{candidate function}}

 int g1(int);
 int g1(char);

 int g2(int);
 int g2(double);

 template<typename T> T g3(T);
 int g3(int);
 int g3(char);

 void g_test() {
   g(g1);
   g(g2); // expected-error{{call to 'g' is ambiguous}}
   g(g3);
 }

 template<typename T> T h1(T);
 template<typename R, typename A1> R h1(A1);
 int h1(char);

 void ha(int (*fp)(int));
 void hb(int (*fp)(double));

 void h_test() {
   ha(h1);
   hb(h1);
 }

 struct A { };
 void f(void (*)(A *));

 struct B
 {
   void g() { f(d); }
   void d(void *);
   static void d(A *);
 };

 struct C {
   C &getC() {
     return makeAC; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
   }

   // FIXME: filter by const so we can unambiguously suggest '()' & point to just the one candidate, probably
   C &makeAC(); // expected-note{{possible target for call}}
   const C &makeAC() const; // expected-note{{possible target for call}}

   static void f(); // expected-note{{candidate function}}
   static void f(int); // expected-note{{candidate function}}

   void g() {
     int (&fp)() = f; // expected-error{{address of overloaded function 'f' does not match required type 'int ()'}}
   }

   template<typename T>
   void q1(int); // expected-note{{possible target for call}}
   template<typename T>
   void q2(T t = T()); // expected-note{{possible target for call}}
   template<typename T>
   void q3(); // expected-note{{possible target for call}}
   template<typename T1, typename T2>
   void q4(); // expected-note{{possible target for call}}
   template<typename T1 = int> // expected-warning{{default template arguments for a function template are a C++11 extension}}
   void q5(); // expected-note{{possible target for call}}

   void h() {
     // Do not suggest '()' since an int argument is required
     q1<int>; // expected-error-re{{reference to non-static member function must be called{{$}}}}
     // Suggest '()' since there's a default value for the only argument & the
     // type argument is already provided
     q2<int>; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
     // Suggest '()' since no arguments are required & the type argument is
     // already provided
     q3<int>; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
     // Do not suggest '()' since another type argument is required
     q4<int>; // expected-error-re{{reference to non-static member function must be called{{$}}}}
     // Suggest '()' since the type parameter has a default value
     q5; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
   }
 };

 // PR6886
 namespace test0 {
   void myFunction(void (*)(void *));

   class Foo {
     void foo();

     static void bar(void*);
     static void bar();
   };

   void Foo::foo() {
     myFunction(bar);
   }
 }

 namespace PR7971 {
   struct S {
     void g() {
       f(&g);
     }
     void f(bool (*)(int, char));
     static bool g(int, char);
   };
 }

 namespace PR8033 {
   template <typename T1, typename T2> int f(T1 *, const T2 *); // expected-note {{candidate function [with T1 = const int, T2 = int]}} \
   // expected-note{{candidate function}}
   template <typename T1, typename T2> int f(const T1 *, T2 *); // expected-note {{candidate function [with T1 = int, T2 = const int]}} \
   // expected-note{{candidate function}}
   int (*p)(const int *, const int *) = f; // expected-error{{address of overloaded function 'f' is ambiguous}} \
   // expected-error{{address of overloaded function 'f' is ambiguous}}

 }

 namespace PR8196 {
   template <typename T> struct mcdata {
     typedef int result_type;
   };
   template <class T>
     typename mcdata<T>::result_type wrap_mean(mcdata<T> const&);
   void add_property(double(*)(mcdata<double> const &)); // expected-note{{candidate function not viable: no overload of 'wrap_mean' matching}}
   void f() {
     add_property(&wrap_mean); // expected-error{{no matching function for call to 'add_property'}}
   }
 }

 namespace PR7425 {
   template<typename T>
   void foo()
   {
   }

   struct B
   {
     template<typename T>
     B(const T&)
     {
     }
   };

   void bar(const B& b)
   {
   }

   void bar2(const B& b = foo<int>)
   {
   }

   void test(int argc, char** argv)
   {
     bar(foo<int>);
     bar2();
   }
 }

 namespace test1 {
   void fun(int x) {}

   void parameter_number() {
     void (*ptr1)(int, int) = &fun; // expected-error {{cannot initialize a variable of type 'void (*)(int, int)' with an rvalue of type 'void (*)(int)': different number of parameters (2 vs 1)}}
     void (*ptr2)(int, int);
     ptr2 = &fun;  // expected-error {{assigning to 'void (*)(int, int)' from incompatible type 'void (*)(int)': different number of parameters (2 vs 1)}}
   }

   void parameter_mismatch() {
     void (*ptr1)(double) = &fun; // expected-error {{cannot initialize a variable of type 'void (*)(double)' with an rvalue of type 'void (*)(int)': type mismatch at 1st parameter ('double' vs 'int')}}
     void (*ptr2)(double);
     ptr2 = &fun; // expected-error {{assigning to 'void (*)(double)' from incompatible type 'void (*)(int)': type mismatch at 1st parameter ('double' vs 'int')}}
   }

   void return_type_test() {
     int (*ptr1)(int) = &fun; // expected-error {{cannot initialize a variable of type 'int (*)(int)' with an rvalue of type 'void (*)(int)': different return type ('int' vs 'void')}}
     int (*ptr2)(int);
     ptr2 = &fun;  // expected-error {{assigning to 'int (*)(int)' from incompatible type 'void (*)(int)': different return type ('int' vs 'void')}}
   }

   int foo(double x, double y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
   int foo(int x, int y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
   int foo(double x) {return 0;} // expected-note {{candidate function has type mismatch at 1st parameter (expected 'int' but has 'double')}}
   double foo(float x, float y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
   double foo(int x, float y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
   double foo(float x) {return 0;} // expected-note {{candidate function has type mismatch at 1st parameter (expected 'int' but has 'float')}}
   double foo(int x) {return 0;} // expected-note {{candidate function has different return type ('int' expected but has 'double')}}

   int (*ptr)(int) = &foo; // expected-error {{address of overloaded function 'foo' does not match required type 'int (int)'}}

   struct Qualifiers {
     void N() {};
     void C() const {};
     void V() volatile {};
     void R() __restrict {};
     void CV() const volatile {};
     void CR() const __restrict {};
     void VR() volatile __restrict {};
     void CVR() const volatile __restrict {};
   };


   void QualifierTest() {
     void (Qualifiers::*X)();
     X = &Qualifiers::C; // expected-error-re {{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} const': different qualifiers (none vs const)}}
     X = &Qualifiers::V; // expected-error-re{{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} volatile': different qualifiers (none vs volatile)}}
     X = &Qualifiers::R; // expected-error-re{{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} restrict': different qualifiers (none vs restrict)}}
     X = &Qualifiers::CV; // expected-error-re{{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} const volatile': different qualifiers (none vs const and volatile)}}
     X = &Qualifiers::CR; // expected-error-re{{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} const restrict': different qualifiers (none vs const and restrict)}}
     X = &Qualifiers::VR; // expected-error-re{{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} volatile restrict': different qualifiers (none vs volatile and restrict)}}
     X = &Qualifiers::CVR; // expected-error-re{{assigning to 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}} const volatile restrict': different qualifiers (none vs const, volatile, and restrict)}}
   }

   struct Dummy {
     void N() {};
   };

   void (Qualifiers::*X)() = &Dummy::N; // expected-error-re{{cannot initialize a variable of type 'void (test1::Qualifiers::*)(){{( __attribute__\(\(thiscall\)\))?}}' with an rvalue of type 'void (test1::Dummy::*)(){{( __attribute__\(\(thiscall\)\))?}}': different classes ('test1::Qualifiers' vs 'test1::Dummy')}}
 }

 template <typename T> class PR16561 {
   virtual bool f() { if (f) {} return false; } // expected-error {{reference to non-static member function must be called}}
 };
	// RUN: %clang_cc1 -fsyntax-only -verify %s
	int f(double); // expected-note{{candidate function}}
	int f(int); // expected-note{{candidate function}}

	int (*pfd)(double) = f; // selects f(double)
	int (*pfd2)(double) = &f; // selects f(double)
	int (*pfd3)(double) = ((&((f)))); // selects f(double)
	int (*pfi)(int) = &f; // selects f(int)
	// FIXME: This error message is not very good. We need to keep better
	// track of what went wrong when the implicit conversion failed to
	// give a better error message here.
	int (*pfe)(...) = &f; // expected-error{{address of overloaded function 'f' does not match required type 'int (...)'}}
	int (&rfi)(int) = f; // selects f(int)
	int (&rfd)(double) = f; // selects f(double)

	void g(int (*fp)(int)); // expected-note{{candidate function}}
	void g(int (*fp)(float));
	void g(int (*fp)(double)); // expected-note{{candidate function}}

	int g1(int);
	int g1(char);

	int g2(int);
	int g2(double);

	template<typename T> T g3(T);
	int g3(int);
	int g3(char);

	void g_test() {
	g(g1);
	g(g2); // expected-error{{call to 'g' is ambiguous}}
	g(g3);
	}

	template<typename T> T h1(T);
	template<typename R, typename A1> R h1(A1);
	int h1(char);

	void ha(int (*fp)(int));
	void hb(int (*fp)(double));

	void h_test() {
	ha(h1);
	hb(h1);
	}

	struct A { };
	void f(void ()(A ));

	struct B
	{
	void g() { f(d); }
	void d(void *);
	static void d(A *);
	};

	struct C {
	C &getC() {
	return makeAC; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
	}

	// FIXME: filter by const so we can unambiguously suggest '()' & point to just the one candidate, probably
	C &makeAC(); // expected-note{{possible target for call}}
	const C &makeAC() const; // expected-note{{possible target for call}}

	static void f(); // expected-note{{candidate function}}
	static void f(int); // expected-note{{candidate function}}

	void g() {
	int (&fp)() = f; // expected-error{{address of overloaded function 'f' does not match required type 'int ()'}}
	}

	template<typename T>
	void q1(int); // expected-note{{possible target for call}}
	template<typename T>
	void q2(T t = T()); // expected-note{{possible target for call}}
	template<typename T>
	void q3(); // expected-note{{possible target for call}}
	template<typename T1, typename T2>
	void q4(); // expected-note{{possible target for call}}
	template<typename T1 = int> // expected-warning{{default template arguments for a function template are a C++11 extension}}
	void q5(); // expected-note{{possible target for call}}

	void h() {
	// Do not suggest '()' since an int argument is required
	q1<int>; // expected-error-re{{reference to non-static member function must be called{{$}}}}
	// Suggest '()' since there's a default value for the only argument & the
	// type argument is already provided
	q2<int>; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
	// Suggest '()' since no arguments are required & the type argument is
	// already provided
	q3<int>; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
	// Do not suggest '()' since another type argument is required
	q4<int>; // expected-error-re{{reference to non-static member function must be called{{$}}}}
	// Suggest '()' since the type parameter has a default value
	q5; // expected-error{{reference to non-static member function must be called; did you mean to call it with no arguments?}}
	}
	};

	// PR6886
	namespace test0 {
	void myFunction(void ()(void ));

	class Foo {
	void foo();

	static void bar(void*);
	static void bar();
	};

	void Foo::foo() {
	myFunction(bar);
	}
	}

	namespace PR7971 {
	struct S {
	void g() {
	f(&g);
	}
	void f(bool (*)(int, char));
	static bool g(int, char);
	};
	}

	namespace PR8033 {
	template <typename T1, typename T2> int f(T1 , const T2 ); // expected-note {{candidate function [with T1 = const int, T2 = int]}} \
	// expected-note{{candidate function}}
	template <typename T1, typename T2> int f(const T1 , T2 ); // expected-note {{candidate function [with T1 = int, T2 = const int]}} \
	// expected-note{{candidate function}}
	int (p)(const int , const int *) = f; // expected-error{{address of overloaded function 'f' is ambiguous}} \
	// expected-error{{address of overloaded function 'f' is ambiguous}}

	}

	namespace PR8196 {
	template <typename T> struct mcdata {
	typedef int result_type;
	};
	template <class T>
	typename mcdata<T>::result_type wrap_mean(mcdata<T> const&);
	void add_property(double(*)(mcdata<double> const &)); // expected-note{{candidate function not viable: no overload of 'wrap_mean' matching}}
	void f() {
	add_property(&wrap_mean); // expected-error{{no matching function for call to 'add_property'}}
	}
	}

	namespace PR7425 {
	template<typename T>
	void foo()
	{
	}

	struct B
	{
	template<typename T>
	B(const T&)
	{
	}
	};

	void bar(const B& b)
	{
	}

	void bar2(const B& b = foo<int>)
	{
	}

	void test(int argc, char** argv)
	{
	bar(foo<int>);
	bar2();
	}
	}

	namespace test1 {
	void fun(int x) {}

	void parameter_number() {
	void (ptr1)(int, int) = &fun; // expected-error {{cannot initialize a variable of type 'void ()(int, int)' with an rvalue of type 'void (*)(int)': different number of parameters (2 vs 1)}}
	void (*ptr2)(int, int);
	ptr2 = &fun; // expected-error {{assigning to 'void ()(int, int)' from incompatible type 'void ()(int)': different number of parameters (2 vs 1)}}
	}

	void parameter_mismatch() {
	void (ptr1)(double) = &fun; // expected-error {{cannot initialize a variable of type 'void ()(double)' with an rvalue of type 'void (*)(int)': type mismatch at 1st parameter ('double' vs 'int')}}
	void (*ptr2)(double);
	ptr2 = &fun; // expected-error {{assigning to 'void ()(double)' from incompatible type 'void ()(int)': type mismatch at 1st parameter ('double' vs 'int')}}
	}

	void return_type_test() {
	int (ptr1)(int) = &fun; // expected-error {{cannot initialize a variable of type 'int ()(int)' with an rvalue of type 'void (*)(int)': different return type ('int' vs 'void')}}
	int (*ptr2)(int);
	ptr2 = &fun; // expected-error {{assigning to 'int ()(int)' from incompatible type 'void ()(int)': different return type ('int' vs 'void')}}
	}

	int foo(double x, double y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
	int foo(int x, int y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
	int foo(double x) {return 0;} // expected-note {{candidate function has type mismatch at 1st parameter (expected 'int' but has 'double')}}
	double foo(float x, float y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
	double foo(int x, float y) {return 0;} // expected-note {{candidate function has different number of parameters (expected 1 but has 2)}}
	double foo(float x) {return 0;} // expected-note {{candidate function has type mismatch at 1st parameter (expected 'int' but has 'float')}}
	double foo(int x) {return 0;} // expected-note {{candidate function has different return type ('int' expected but has 'double')}}

	int (*ptr)(int) = &foo; // expected-error {{address of overloaded function 'foo' does not match required type 'int (int)'}}

	struct Qualifiers {
	void N() {};
	void C() const {};
	void V() volatile {};
	void R() __restrict {};
	void CV() const volatile {};
	void CR() const __restrict {};
	void VR() volatile __restrict {};
	void CVR() const volatile __restrict {};
	};


	void QualifierTest() {
	void (Qualifiers::*X)();
	X = &Qualifiers::C; // expected-error-re {{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} const': different qualifiers (none vs const)}}
	X = &Qualifiers::V; // expected-error-re{{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} volatile': different qualifiers (none vs volatile)}}
	X = &Qualifiers::R; // expected-error-re{{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} restrict': different qualifiers (none vs restrict)}}
	X = &Qualifiers::CV; // expected-error-re{{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} const volatile': different qualifiers (none vs const and volatile)}}
	X = &Qualifiers::CR; // expected-error-re{{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} const restrict': different qualifiers (none vs const and restrict)}}
	X = &Qualifiers::VR; // expected-error-re{{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} volatile restrict': different qualifiers (none vs volatile and restrict)}}
	X = &Qualifiers::CVR; // expected-error-re{{assigning to 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' from incompatible type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}} const volatile restrict': different qualifiers (none vs const, volatile, and restrict)}}
	}

	struct Dummy {
	void N() {};
	};

	void (Qualifiers::X)() = &Dummy::N; // expected-error-re{{cannot initialize a variable of type 'void (test1::Qualifiers::)(){{( __attribute__\(\(thiscall\)\))?}}' with an rvalue of type 'void (test1::Dummy::*)(){{( __attribute__\(\(thiscall\)\))?}}': different classes ('test1::Qualifiers' vs 'test1::Dummy')}}
	}

	template <typename T> class PR16561 {
	virtual bool f() { if (f) {} return false; } // expected-error {{reference to non-static member function must be called}}
	};