test/SemaCXX/conversion-function.cpp - fp2-dev/platform/external/clang - Gitiles

 // RUN: %clang_cc1 -fsyntax-only -verify %s
 class X {
 public:
   operator bool();
   operator int() const;

   bool f() {
     return operator bool();
   }

   float g() {
     return operator float(); // expected-error{{use of undeclared 'operator float'}}
   }
 };

 operator int(); // expected-error{{conversion function must be a non-static member function}}

 operator int; // expected-error{{'operator int' cannot be the name of a variable or data member}}

 typedef int func_type(int);
 typedef int array_type[10];

 class Y {
 public:
   void operator bool(int, ...) const; // expected-error{{conversion function cannot have a return type}} \
   // expected-error{{conversion function cannot have any parameters}}

   operator float(...) const;  // expected-error{{conversion function cannot be variadic}}


   operator func_type(); // expected-error{{conversion function cannot convert to a function type}}
   operator array_type(); // expected-error{{conversion function cannot convert to an array type}}
 };


 typedef int INT;
 typedef INT* INT_PTR;

 class Z {
   operator int(); // expected-note {{previous declaration is here}}
   operator int**(); // expected-note {{previous declaration is here}}

   operator INT();  // expected-error{{conversion function cannot be redeclared}}
   operator INT_PTR*(); // expected-error{{conversion function cannot be redeclared}}
 };


 class A { };

 class B : public A {
 public:
   operator A&() const; // expected-warning{{conversion function converting 'B' to its base class 'A' will never be used}}
   operator const void() const; // expected-warning{{conversion function converting 'B' to 'const void' will never be used}}
   operator const B(); // expected-warning{{conversion function converting 'B' to itself will never be used}}
 };

 // This used to crash Clang.
 struct Flip;
 struct Flop {
   Flop();
   Flop(const Flip&); // expected-note{{candidate constructor}}
 };
 struct Flip {
   operator Flop() const; // expected-note{{candidate function}}
 };
 Flop flop = Flip(); // expected-error {{conversion from 'Flip' to 'Flop' is ambiguous}}

 // This tests that we don't add the second conversion declaration to the list of user conversions
 struct C {
   operator const char *() const;
 };

 C::operator const char*() const { return 0; }

 void f(const C& c) {
   const char* v = c;
 }

 // Test. Conversion in base class is visible in derived class.
 class XB {
 public:
   operator int(); // expected-note {{candidate function}}
 };

 class Yb : public XB {
 public:
   operator char(); // expected-note {{candidate function}}
 };

 void f(Yb& a) {
   if (a) { } // expected-error {{conversion from 'Yb' to 'bool' is ambiguous}}
   int i = a; // OK. calls XB::operator int();
   char ch = a;  // OK. calls Yb::operator char();
 }

 // Test conversion + copy construction.
 class AutoPtrRef { };

 class AutoPtr {
   AutoPtr(AutoPtr &); // expected-note{{declared private here}}

 public:
   AutoPtr();
   AutoPtr(AutoPtrRef);

   operator AutoPtrRef();
 };

 AutoPtr make_auto_ptr();

 AutoPtr test_auto_ptr(bool Cond) {
   AutoPtr p1( make_auto_ptr() );

   AutoPtr p;
   if (Cond)
     return p; // expected-error{{calling a private constructor}}

   return AutoPtr();
 }

 struct A1 {
   A1(const char *);
   ~A1();

 private:
   A1(const A1&); // expected-note 2 {{declared private here}}
 };

 A1 f() {
   // FIXME: redundant diagnostics!
   return "Hello"; // expected-error {{calling a private constructor}} expected-warning {{an accessible copy constructor}}
 }

 namespace source_locations {
   template<typename T>
   struct sneaky_int {
     typedef int type;
   };

   template<typename T, typename U>
   struct A { };

   template<typename T>
   struct A<T, T> : A<T, int> { };

   struct E {
     template<typename T>
     operator A<T, typename sneaky_int<T>::type>&() const; // expected-note{{candidate function}}
   };

   void f() {
     A<float, float> &af = E(); // expected-error{{no viable conversion}}
     A<float, int> &af2 = E();
     const A<float, int> &caf2 = E();
   }

   // Check
   template<typename T>
   struct E2 {
     operator T
     * // expected-error{{pointer to a reference}}
     () const;
   };

   E2<int&> e2i; // expected-note{{in instantiation}}
 }

 namespace crazy_declarators {
   struct A {
     (&operator bool())(); // expected-error {{must use a typedef to declare a conversion to 'bool (&)()'}}

     // FIXME: This diagnostic is misleading (the correct spelling
     // would be 'operator int*'), but it's a corner case of a
     // rarely-used syntax extension.
     *operator int();  // expected-error {{must use a typedef to declare a conversion to 'int *'}}
   };
 }

 namespace smart_ptr {
   class Y {
     class YRef { };

     Y(Y&);

   public:
     Y();
     Y(YRef);

     operator YRef(); // expected-note{{candidate function}}
   };

   struct X { // expected-note{{candidate constructor (the implicit copy constructor) not}}
     explicit X(Y);
   };

   Y make_Y();

   X f() {
     X x = make_Y(); // expected-error{{no viable conversion from 'smart_ptr::Y' to 'smart_ptr::X'}}
     X x2(make_Y());
     return X(Y());
   }
 }

 struct Any {
   Any(...);
 };

 struct Other {
   Other(const Other &);
   Other();
 };

 void test_any() {
   Any any = Other(); // expected-error{{cannot pass object of non-POD type 'Other' through variadic constructor; call will abort at runtime}}
 }

 namespace PR7055 {
   // Make sure that we don't allow too many conversions in an
   // auto_ptr-like template. In particular, we can't create multiple
   // temporary objects when binding to a reference.
   struct auto_ptr {
     struct auto_ptr_ref { };

     auto_ptr(auto_ptr&);
     auto_ptr(auto_ptr_ref);
     explicit auto_ptr(int *);

     operator auto_ptr_ref();
   };

   struct X {
     X(auto_ptr);
   };

   X f() {
     X x(auto_ptr(new int));
     return X(auto_ptr(new int));
   }

   auto_ptr foo();

   X e(foo());

   struct Y {
     Y(X);
   };

   Y f2(foo());
 }

 namespace PR7934 {
   typedef unsigned char uint8;

   struct MutablePtr {
     MutablePtr() : ptr(0) {}
     void *ptr;

     operator void*() { return ptr; }

   private:
     operator uint8*() { return reinterpret_cast<uint8*>(ptr); }
     operator const char*() const { return reinterpret_cast<const char*>(ptr); }
   };

   void fake_memcpy(const void *);

   void use() {
     MutablePtr ptr;
     fake_memcpy(ptr);
   }
 }

 namespace rdar8018274 {
   struct X { };
   struct Y {
     operator const struct X *() const;
   };

   struct Z : Y {
     operator struct X * ();
   };

   void test() {
     Z x;
     (void) (x != __null);
   }


   struct Base {
     operator int();
   };

   struct Derived1 : Base { };

   struct Derived2 : Base { };

   struct SuperDerived : Derived1, Derived2 {
     using Derived1::operator int;
   };

   struct UeberDerived : SuperDerived {
     operator long();
   };

   void test2(UeberDerived ud) {
     int i = ud; // expected-error{{ambiguous conversion from derived class 'rdar8018274::SuperDerived' to base class 'rdar8018274::Base'}}
   }

   struct Base2 {
     operator int();
   };

   struct Base3 {
     operator int();
   };

   struct Derived23 : Base2, Base3 {
     using Base2::operator int;
   };

   struct ExtraDerived23 : Derived23 { };

   void test3(ExtraDerived23 ed) {
     int i = ed;
   }
 }

 namespace PR8065 {
   template <typename T> struct Iterator;
   template <typename T> struct Container;

   template<>
   struct Iterator<int> {
     typedef Container<int> container_type;
   };

   template <typename T>
   struct Container {
     typedef typename Iterator<T>::container_type X;
     operator X(void) { return X(); }
   };

   Container<int> test;
 }

 namespace PR8034 {
   struct C {
     operator int();

   private:
     template <typename T> operator T();
   };
   int x = C().operator int();
 }

 namespace PR9336 {
   template<class T>
   struct generic_list
   {
     template<class Container>
     operator Container()
     {
       Container ar;
       T* i;
       ar[0]=*i;
       return ar;
     }
   };

   template<class T>
   struct array
   {
     T& operator[](int);
     const T& operator[](int)const;
   };

   generic_list<generic_list<int> > l;
   array<array<int> > a = l;
 }

 namespace PR8800 {
   struct A;
   struct C {
     operator A&();
   };
   void f() {
     C c;
     A& a1(c);
     A& a2 = c;
     A& a3 = static_cast<A&>(c);
     A& a4 = (A&)c;
   }
 }

 namespace PR12712 {
   struct A {};
   struct B {
     operator A();
     operator A() const;
   };
   struct C : B {};

   A f(const C c) { return c; }
 }
	// RUN: %clang_cc1 -fsyntax-only -verify %s
	class X {
	public:
	operator bool();
	operator int() const;

	bool f() {
	return operator bool();
	}

	float g() {
	return operator float(); // expected-error{{use of undeclared 'operator float'}}
	}
	};

	operator int(); // expected-error{{conversion function must be a non-static member function}}

	operator int; // expected-error{{'operator int' cannot be the name of a variable or data member}}

	typedef int func_type(int);
	typedef int array_type[10];

	class Y {
	public:
	void operator bool(int, ...) const; // expected-error{{conversion function cannot have a return type}} \
	// expected-error{{conversion function cannot have any parameters}}

	operator float(...) const; // expected-error{{conversion function cannot be variadic}}


	operator func_type(); // expected-error{{conversion function cannot convert to a function type}}
	operator array_type(); // expected-error{{conversion function cannot convert to an array type}}
	};


	typedef int INT;
	typedef INT* INT_PTR;

	class Z {
	operator int(); // expected-note {{previous declaration is here}}
	operator int**(); // expected-note {{previous declaration is here}}

	operator INT(); // expected-error{{conversion function cannot be redeclared}}
	operator INT_PTR*(); // expected-error{{conversion function cannot be redeclared}}
	};


	class A { };

	class B : public A {
	public:
	operator A&() const; // expected-warning{{conversion function converting 'B' to its base class 'A' will never be used}}
	operator const void() const; // expected-warning{{conversion function converting 'B' to 'const void' will never be used}}
	operator const B(); // expected-warning{{conversion function converting 'B' to itself will never be used}}
	};

	// This used to crash Clang.
	struct Flip;
	struct Flop {
	Flop();
	Flop(const Flip&); // expected-note{{candidate constructor}}
	};
	struct Flip {
	operator Flop() const; // expected-note{{candidate function}}
	};
	Flop flop = Flip(); // expected-error {{conversion from 'Flip' to 'Flop' is ambiguous}}

	// This tests that we don't add the second conversion declaration to the list of user conversions
	struct C {
	operator const char *() const;
	};

	C::operator const char*() const { return 0; }

	void f(const C& c) {
	const char* v = c;
	}

	// Test. Conversion in base class is visible in derived class.
	class XB {
	public:
	operator int(); // expected-note {{candidate function}}
	};

	class Yb : public XB {
	public:
	operator char(); // expected-note {{candidate function}}
	};

	void f(Yb& a) {
	if (a) { } // expected-error {{conversion from 'Yb' to 'bool' is ambiguous}}
	int i = a; // OK. calls XB::operator int();
	char ch = a; // OK. calls Yb::operator char();
	}

	// Test conversion + copy construction.
	class AutoPtrRef { };

	class AutoPtr {
	AutoPtr(AutoPtr &); // expected-note{{declared private here}}

	public:
	AutoPtr();
	AutoPtr(AutoPtrRef);

	operator AutoPtrRef();
	};

	AutoPtr make_auto_ptr();

	AutoPtr test_auto_ptr(bool Cond) {
	AutoPtr p1( make_auto_ptr() );

	AutoPtr p;
	if (Cond)
	return p; // expected-error{{calling a private constructor}}

	return AutoPtr();
	}

	struct A1 {
	A1(const char *);
	~A1();

	private:
	A1(const A1&); // expected-note 2 {{declared private here}}
	};

	A1 f() {
	// FIXME: redundant diagnostics!
	return "Hello"; // expected-error {{calling a private constructor}} expected-warning {{an accessible copy constructor}}
	}

	namespace source_locations {
	template<typename T>
	struct sneaky_int {
	typedef int type;
	};

	template<typename T, typename U>
	struct A { };

	template<typename T>
	struct A<T, T> : A<T, int> { };

	struct E {
	template<typename T>
	operator A<T, typename sneaky_int<T>::type>&() const; // expected-note{{candidate function}}
	};

	void f() {
	A<float, float> &af = E(); // expected-error{{no viable conversion}}
	A<float, int> &af2 = E();
	const A<float, int> &caf2 = E();
	}

	// Check
	template<typename T>
	struct E2 {
	operator T
	* // expected-error{{pointer to a reference}}
	() const;
	};

	E2<int&> e2i; // expected-note{{in instantiation}}
	}

	namespace crazy_declarators {
	struct A {
	(&operator bool())(); // expected-error {{must use a typedef to declare a conversion to 'bool (&)()'}}

	// FIXME: This diagnostic is misleading (the correct spelling
	// would be 'operator int*'), but it's a corner case of a
	// rarely-used syntax extension.
	operator int(); // expected-error {{must use a typedef to declare a conversion to 'int '}}
	};
	}

	namespace smart_ptr {
	class Y {
	class YRef { };

	Y(Y&);

	public:
	Y();
	Y(YRef);

	operator YRef(); // expected-note{{candidate function}}
	};

	struct X { // expected-note{{candidate constructor (the implicit copy constructor) not}}
	explicit X(Y);
	};

	Y make_Y();

	X f() {
	X x = make_Y(); // expected-error{{no viable conversion from 'smart_ptr::Y' to 'smart_ptr::X'}}
	X x2(make_Y());
	return X(Y());
	}
	}

	struct Any {
	Any(...);
	};

	struct Other {
	Other(const Other &);
	Other();
	};

	void test_any() {
	Any any = Other(); // expected-error{{cannot pass object of non-POD type 'Other' through variadic constructor; call will abort at runtime}}
	}

	namespace PR7055 {
	// Make sure that we don't allow too many conversions in an
	// auto_ptr-like template. In particular, we can't create multiple
	// temporary objects when binding to a reference.
	struct auto_ptr {
	struct auto_ptr_ref { };

	auto_ptr(auto_ptr&);
	auto_ptr(auto_ptr_ref);
	explicit auto_ptr(int *);

	operator auto_ptr_ref();
	};

	struct X {
	X(auto_ptr);
	};

	X f() {
	X x(auto_ptr(new int));
	return X(auto_ptr(new int));
	}

	auto_ptr foo();

	X e(foo());

	struct Y {
	Y(X);
	};

	Y f2(foo());
	}

	namespace PR7934 {
	typedef unsigned char uint8;

	struct MutablePtr {
	MutablePtr() : ptr(0) {}
	void *ptr;

	operator void*() { return ptr; }

	private:
	operator uint8() { return reinterpret_cast<uint8>(ptr); }
	operator const char() const { return reinterpret_cast<const char>(ptr); }
	};

	void fake_memcpy(const void *);

	void use() {
	MutablePtr ptr;
	fake_memcpy(ptr);
	}
	}

	namespace rdar8018274 {
	struct X { };
	struct Y {
	operator const struct X *() const;
	};

	struct Z : Y {
	operator struct X * ();
	};

	void test() {
	Z x;
	(void) (x != __null);
	}


	struct Base {
	operator int();
	};

	struct Derived1 : Base { };

	struct Derived2 : Base { };

	struct SuperDerived : Derived1, Derived2 {
	using Derived1::operator int;
	};

	struct UeberDerived : SuperDerived {
	operator long();
	};

	void test2(UeberDerived ud) {
	int i = ud; // expected-error{{ambiguous conversion from derived class 'rdar8018274::SuperDerived' to base class 'rdar8018274::Base'}}
	}

	struct Base2 {
	operator int();
	};

	struct Base3 {
	operator int();
	};

	struct Derived23 : Base2, Base3 {
	using Base2::operator int;
	};

	struct ExtraDerived23 : Derived23 { };

	void test3(ExtraDerived23 ed) {
	int i = ed;
	}
	}

	namespace PR8065 {
	template <typename T> struct Iterator;
	template <typename T> struct Container;

	template<>
	struct Iterator<int> {
	typedef Container<int> container_type;
	};

	template <typename T>
	struct Container {
	typedef typename Iterator<T>::container_type X;
	operator X(void) { return X(); }
	};

	Container<int> test;
	}

	namespace PR8034 {
	struct C {
	operator int();

	private:
	template <typename T> operator T();
	};
	int x = C().operator int();
	}

	namespace PR9336 {
	template<class T>
	struct generic_list
	{
	template<class Container>
	operator Container()
	{
	Container ar;
	T* i;
	ar[0]=*i;
	return ar;
	}
	};

	template<class T>
	struct array
	{
	T& operator[](int);
	const T& operator[](int)const;
	};

	generic_list<generic_list<int> > l;
	array<array<int> > a = l;
	}

	namespace PR8800 {
	struct A;
	struct C {
	operator A&();
	};
	void f() {
	C c;
	A& a1(c);
	A& a2 = c;
	A& a3 = static_cast<A&>(c);
	A& a4 = (A&)c;
	}
	}

	namespace PR12712 {
	struct A {};
	struct B {
	operator A();
	operator A() const;
	};
	struct C : B {};

	A f(const C c) { return c; }
	}