test/SemaCXX/enable_if.cpp - third_party/swift-clang - Git at Google

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

 typedef int (*fp)(int);
 int surrogate(int);
 struct Incomplete;  // expected-note{{forward declaration of 'Incomplete'}} \
                     // expected-note {{forward declaration of 'Incomplete'}}

 struct X {
   X() = default;  // expected-note{{candidate constructor not viable: requires 0 arguments, but 1 was provided}}
   X(const X&) = default;  // expected-note{{candidate constructor not viable: no known conversion from 'bool' to 'const X' for 1st argument}}
   X(bool b) __attribute__((enable_if(b, "chosen when 'b' is true")));  // expected-note{{candidate disabled: chosen when 'b' is true}}

   void f(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero")));
   void f(int n) __attribute__((enable_if(n == 1, "chosen when 'n' is one")));  // expected-note{{member declaration nearly matches}} expected-note 2{{candidate disabled: chosen when 'n' is one}}

   void g(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero")));  // expected-note{{candidate disabled: chosen when 'n' is zero}}

   void h(int n, int m = 0) __attribute__((enable_if(m == 0, "chosen when 'm' is zero")));  // expected-note{{candidate disabled: chosen when 'm' is zero}}

   static void s(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero")));  // expected-note2{{candidate disabled: chosen when 'n' is zero}}

   void conflict(int n) __attribute__((enable_if(n+n == 10, "chosen when 'n' is five")));  // expected-note{{candidate function}}
   void conflict(int n) __attribute__((enable_if(n*2 == 10, "chosen when 'n' is five")));  // expected-note{{candidate function}}

   void hidden_by_argument_conversion(Incomplete n, int m = 0) __attribute__((enable_if(m == 10, "chosen when 'm' is ten")));
   Incomplete hidden_by_incomplete_return_value(int n = 0) __attribute__((enable_if(n == 10, "chosen when 'n' is ten"))); // expected-note{{'hidden_by_incomplete_return_value' declared here}}

   operator long() __attribute__((enable_if(true, "chosen on your platform")));
   operator int() __attribute__((enable_if(false, "chosen on other platform")));

   operator fp() __attribute__((enable_if(false, "never enabled"))) { return surrogate; }  // expected-note{{conversion candidate of type 'int (*)(int)'}}  // FIXME: the message is not displayed
 };

 void X::f(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero")))  // expected-note{{member declaration nearly matches}} expected-note 2{{candidate disabled: chosen when 'n' is zero}}
 {
 }

 void X::f(int n) __attribute__((enable_if(n == 2, "chosen when 'n' is two")))  // expected-error{{out-of-line definition of 'f' does not match any declaration in 'X'}}
 {
 }

 X x1(true);
 X x2(false); // expected-error{{no matching constructor for initialization of 'X'}}

 __attribute__((deprecated)) constexpr int old() { return 0; }  // expected-note2{{'old' has been explicitly marked deprecated here}}
 void deprec1(int i) __attribute__((enable_if(old() == 0, "chosen when old() is zero")));  // expected-warning{{'old' is deprecated}}
 void deprec2(int i) __attribute__((enable_if(old() == 0, "chosen when old() is zero")));  // expected-warning{{'old' is deprecated}}

 void overloaded(int);
 void overloaded(long);

 struct Int {
   constexpr Int(int i) : i(i) { }
   constexpr operator int() const { return i; }
   int i;
 };

 void default_argument(int n, int m = 0) __attribute__((enable_if(m == 0, "chosen when 'm' is zero")));  // expected-note{{candidate disabled: chosen when 'm' is zero}}
 void default_argument_promotion(int n, int m = Int(0)) __attribute__((enable_if(m == 0, "chosen when 'm' is zero")));  // expected-note{{candidate disabled: chosen when 'm' is zero}}

 struct Nothing { };
 template<typename T> void typedep(T t) __attribute__((enable_if(t, "")));  // expected-note{{candidate disabled:}}  expected-error{{value of type 'Nothing' is not contextually convertible to 'bool'}}
 template<int N> void valuedep() __attribute__((enable_if(N == 1, "")));

 // FIXME: we skip potential constant expression evaluation on value dependent
 // enable-if expressions
 int not_constexpr();
 template<int N> void valuedep() __attribute__((enable_if(N == not_constexpr(), "")));

 template <typename T> void instantiationdep() __attribute__((enable_if(sizeof(sizeof(T)) != 0, "")));

 void test() {
   X x;
   x.f(0);
   x.f(1);
   x.f(2);  // expected-error{{no matching member function for call to 'f'}}
   x.f(3);  // expected-error{{no matching member function for call to 'f'}}

   x.g(0);
   x.g(1);  // expected-error{{no matching member function for call to 'g'}}

   x.h(0);
   x.h(1, 2);  // expected-error{{no matching member function for call to 'h'}}

   x.s(0);
   x.s(1);  // expected-error{{no matching member function for call to 's'}}

   X::s(0);
   X::s(1);  // expected-error{{no matching member function for call to 's'}}

   x.conflict(5);  // expected-error{{call to member function 'conflict' is ambiguous}}

   x.hidden_by_argument_conversion(10);  // expected-error{{argument type 'Incomplete' is incomplete}}
   x.hidden_by_incomplete_return_value(10);  // expected-error{{calling 'hidden_by_incomplete_return_value' with incomplete return type 'Incomplete'}}

   deprec2(0);

   overloaded(x);

   default_argument(0);
   default_argument(1, 2);  // expected-error{{no matching function for call to 'default_argument'}}

   default_argument_promotion(0);
   default_argument_promotion(1, 2);  // expected-error{{no matching function for call to 'default_argument_promotion'}}

   int i = x(1);  // expected-error{{no matching function for call to object of type 'X'}}

   Nothing n;
   typedep(0);  // expected-error{{no matching function for call to 'typedep'}}
   typedep(1);
   typedep(n);  // expected-note{{in instantiation of function template specialization 'typedep<Nothing>' requested here}}
 }

 template <typename T> class C {
   void f() __attribute__((enable_if(T::expr == 0, ""))) {}
   void g() { f(); }
 };

 int fn3(bool b) __attribute__((enable_if(b, "")));
 template <class T> void test3() {
   fn3(sizeof(T) == 1);
 }

 template <typename T>
 struct Y {
   T h(int n, int m = 0) __attribute__((enable_if(m == 0, "chosen when 'm' is zero")));  // expected-note{{candidate disabled: chosen when 'm' is zero}}
 };

 void test4() {
   Y<int> y;

   int t0 = y.h(0);
   int t1 = y.h(1, 2);  // expected-error{{no matching member function for call to 'h'}}
 }

 // FIXME: issue an error (without instantiation) because ::h(T()) is not
 // convertible to bool, because return types aren't overloadable.
 void h(int);
 template <typename T> void outer() {
   void local_function() __attribute__((enable_if(::h(T()), "")));
   local_function();
 };

 namespace PR20988 {
   struct Integer {
     Integer(int);
   };

   int fn1(const Integer &) __attribute__((enable_if(true, "")));
   template <class T> void test1() {
     int &expr = T::expr();
     fn1(expr);
   }

   int fn2(const Integer &) __attribute__((enable_if(false, "")));  // expected-note{{candidate disabled}}
   template <class T> void test2() {
     int &expr = T::expr();
     fn2(expr);  // expected-error{{no matching function for call to 'fn2'}}
   }

   int fn3(bool b) __attribute__((enable_if(b, "")));
   template <class T> void test3() {
     fn3(sizeof(T) == 1);
   }
 }

 namespace FnPtrs {
   int ovlFoo(int m) __attribute__((enable_if(m > 0, "")));
   int ovlFoo(int m);

   void test() {
     // Assignment gives us a different code path than declarations, and `&foo`
     // gives us a different code path than `foo`
     int (*p)(int) = ovlFoo;
     int (*p2)(int) = &ovlFoo;
     int (*a)(int);
     a = ovlFoo;
     a = &ovlFoo;
   }

   int ovlBar(int) __attribute__((enable_if(true, "")));
   int ovlBar(int m) __attribute__((enable_if(false, "")));
   void test2() {
     int (*p)(int) = ovlBar;
     int (*p2)(int) = &ovlBar;
     int (*a)(int);
     a = ovlBar;
     a = &ovlBar;
   }

   int ovlConflict(int m) __attribute__((enable_if(true, "")));
   int ovlConflict(int m) __attribute__((enable_if(1, "")));
   void test3() {
     int (*p)(int) = ovlConflict; // expected-error{{address of overloaded function 'ovlConflict' is ambiguous}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
     int (*p2)(int) = &ovlConflict; // expected-error{{address of overloaded function 'ovlConflict' is ambiguous}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
     int (*a)(int);
     a = ovlConflict; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
     a = &ovlConflict; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
   }

   template <typename T>
   T templated(T m) __attribute__((enable_if(true, ""))) { return T(); }
   template <typename T>
   T templated(T m) __attribute__((enable_if(false, ""))) { return T(); }
   void test4() {
     int (*p)(int) = templated<int>;
     int (*p2)(int) = &templated<int>;
     int (*a)(int);
     a = templated<int>;
     a = &templated<int>;
   }

   template <typename T>
   T templatedBar(T m) __attribute__((enable_if(m > 0, ""))) { return T(); }
   void test5() {
     int (*p)(int) = templatedBar<int>; // expected-error{{address of overloaded function 'templatedBar' does not match required type 'int (int)'}} expected-note@214{{candidate function made ineligible by enable_if}}
     int (*p2)(int) = &templatedBar<int>; // expected-error{{address of overloaded function 'templatedBar' does not match required type 'int (int)'}} expected-note@214{{candidate function made ineligible by enable_if}}
     int (*a)(int);
     a = templatedBar<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@214{{candidate function made ineligible by enable_if}}
     a = &templatedBar<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@214{{candidate function made ineligible by enable_if}}
   }

   template <typename T>
   T templatedConflict(T m) __attribute__((enable_if(false, ""))) { return T(); }
   template <typename T>
   T templatedConflict(T m) __attribute__((enable_if(true, ""))) { return T(); }
   template <typename T>
   T templatedConflict(T m) __attribute__((enable_if(1, ""))) { return T(); }
   void test6() {
     int (*p)(int) = templatedConflict<int>; // expected-error{{address of overloaded function 'templatedConflict' is ambiguous}} expected-note@224{{candidate function made ineligible by enable_if}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
     int (*p0)(int) = &templatedConflict<int>; // expected-error{{address of overloaded function 'templatedConflict' is ambiguous}} expected-note@224{{candidate function made ineligible by enable_if}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
     int (*a)(int);
     a = templatedConflict<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
     a = &templatedConflict<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
   }
 }
	// RUN: %clang_cc1 -std=c++11 -verify %s

	typedef int (*fp)(int);
	int surrogate(int);
	struct Incomplete; // expected-note{{forward declaration of 'Incomplete'}} \
	// expected-note {{forward declaration of 'Incomplete'}}

	struct X {
	X() = default; // expected-note{{candidate constructor not viable: requires 0 arguments, but 1 was provided}}
	X(const X&) = default; // expected-note{{candidate constructor not viable: no known conversion from 'bool' to 'const X' for 1st argument}}
	X(bool b) __attribute__((enable_if(b, "chosen when 'b' is true"))); // expected-note{{candidate disabled: chosen when 'b' is true}}

	void f(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero")));
	void f(int n) __attribute__((enable_if(n == 1, "chosen when 'n' is one"))); // expected-note{{member declaration nearly matches}} expected-note 2{{candidate disabled: chosen when 'n' is one}}

	void g(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero"))); // expected-note{{candidate disabled: chosen when 'n' is zero}}

	void h(int n, int m = 0) __attribute__((enable_if(m == 0, "chosen when 'm' is zero"))); // expected-note{{candidate disabled: chosen when 'm' is zero}}

	static void s(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero"))); // expected-note2{{candidate disabled: chosen when 'n' is zero}}

	void conflict(int n) __attribute__((enable_if(n+n == 10, "chosen when 'n' is five"))); // expected-note{{candidate function}}
	void conflict(int n) __attribute__((enable_if(n*2 == 10, "chosen when 'n' is five"))); // expected-note{{candidate function}}

	void hidden_by_argument_conversion(Incomplete n, int m = 0) __attribute__((enable_if(m == 10, "chosen when 'm' is ten")));
	Incomplete hidden_by_incomplete_return_value(int n = 0) __attribute__((enable_if(n == 10, "chosen when 'n' is ten"))); // expected-note{{'hidden_by_incomplete_return_value' declared here}}

	operator long() __attribute__((enable_if(true, "chosen on your platform")));
	operator int() __attribute__((enable_if(false, "chosen on other platform")));

	operator fp() __attribute__((enable_if(false, "never enabled"))) { return surrogate; } // expected-note{{conversion candidate of type 'int (*)(int)'}} // FIXME: the message is not displayed
	};

	void X::f(int n) __attribute__((enable_if(n == 0, "chosen when 'n' is zero"))) // expected-note{{member declaration nearly matches}} expected-note 2{{candidate disabled: chosen when 'n' is zero}}
	{
	}

	void X::f(int n) __attribute__((enable_if(n == 2, "chosen when 'n' is two"))) // expected-error{{out-of-line definition of 'f' does not match any declaration in 'X'}}
	{
	}

	X x1(true);
	X x2(false); // expected-error{{no matching constructor for initialization of 'X'}}

	__attribute__((deprecated)) constexpr int old() { return 0; } // expected-note2{{'old' has been explicitly marked deprecated here}}
	void deprec1(int i) __attribute__((enable_if(old() == 0, "chosen when old() is zero"))); // expected-warning{{'old' is deprecated}}
	void deprec2(int i) __attribute__((enable_if(old() == 0, "chosen when old() is zero"))); // expected-warning{{'old' is deprecated}}

	void overloaded(int);
	void overloaded(long);

	struct Int {
	constexpr Int(int i) : i(i) { }
	constexpr operator int() const { return i; }
	int i;
	};

	void default_argument(int n, int m = 0) __attribute__((enable_if(m == 0, "chosen when 'm' is zero"))); // expected-note{{candidate disabled: chosen when 'm' is zero}}
	void default_argument_promotion(int n, int m = Int(0)) __attribute__((enable_if(m == 0, "chosen when 'm' is zero"))); // expected-note{{candidate disabled: chosen when 'm' is zero}}

	struct Nothing { };
	template<typename T> void typedep(T t) __attribute__((enable_if(t, ""))); // expected-note{{candidate disabled:}} expected-error{{value of type 'Nothing' is not contextually convertible to 'bool'}}
	template<int N> void valuedep() __attribute__((enable_if(N == 1, "")));

	// FIXME: we skip potential constant expression evaluation on value dependent
	// enable-if expressions
	int not_constexpr();
	template<int N> void valuedep() __attribute__((enable_if(N == not_constexpr(), "")));

	template <typename T> void instantiationdep() __attribute__((enable_if(sizeof(sizeof(T)) != 0, "")));

	void test() {
	X x;
	x.f(0);
	x.f(1);
	x.f(2); // expected-error{{no matching member function for call to 'f'}}
	x.f(3); // expected-error{{no matching member function for call to 'f'}}

	x.g(0);
	x.g(1); // expected-error{{no matching member function for call to 'g'}}

	x.h(0);
	x.h(1, 2); // expected-error{{no matching member function for call to 'h'}}

	x.s(0);
	x.s(1); // expected-error{{no matching member function for call to 's'}}

	X::s(0);
	X::s(1); // expected-error{{no matching member function for call to 's'}}

	x.conflict(5); // expected-error{{call to member function 'conflict' is ambiguous}}

	x.hidden_by_argument_conversion(10); // expected-error{{argument type 'Incomplete' is incomplete}}
	x.hidden_by_incomplete_return_value(10); // expected-error{{calling 'hidden_by_incomplete_return_value' with incomplete return type 'Incomplete'}}

	deprec2(0);

	overloaded(x);

	default_argument(0);
	default_argument(1, 2); // expected-error{{no matching function for call to 'default_argument'}}

	default_argument_promotion(0);
	default_argument_promotion(1, 2); // expected-error{{no matching function for call to 'default_argument_promotion'}}

	int i = x(1); // expected-error{{no matching function for call to object of type 'X'}}

	Nothing n;
	typedep(0); // expected-error{{no matching function for call to 'typedep'}}
	typedep(1);
	typedep(n); // expected-note{{in instantiation of function template specialization 'typedep<Nothing>' requested here}}
	}

	template <typename T> class C {
	void f() __attribute__((enable_if(T::expr == 0, ""))) {}
	void g() { f(); }
	};

	int fn3(bool b) __attribute__((enable_if(b, "")));
	template <class T> void test3() {
	fn3(sizeof(T) == 1);
	}

	template <typename T>
	struct Y {
	T h(int n, int m = 0) __attribute__((enable_if(m == 0, "chosen when 'm' is zero"))); // expected-note{{candidate disabled: chosen when 'm' is zero}}
	};

	void test4() {
	Y<int> y;

	int t0 = y.h(0);
	int t1 = y.h(1, 2); // expected-error{{no matching member function for call to 'h'}}
	}

	// FIXME: issue an error (without instantiation) because ::h(T()) is not
	// convertible to bool, because return types aren't overloadable.
	void h(int);
	template <typename T> void outer() {
	void local_function() __attribute__((enable_if(::h(T()), "")));
	local_function();
	};

	namespace PR20988 {
	struct Integer {
	Integer(int);
	};

	int fn1(const Integer &) __attribute__((enable_if(true, "")));
	template <class T> void test1() {
	int &expr = T::expr();
	fn1(expr);
	}

	int fn2(const Integer &) __attribute__((enable_if(false, ""))); // expected-note{{candidate disabled}}
	template <class T> void test2() {
	int &expr = T::expr();
	fn2(expr); // expected-error{{no matching function for call to 'fn2'}}
	}

	int fn3(bool b) __attribute__((enable_if(b, "")));
	template <class T> void test3() {
	fn3(sizeof(T) == 1);
	}
	}

	namespace FnPtrs {
	int ovlFoo(int m) __attribute__((enable_if(m > 0, "")));
	int ovlFoo(int m);

	void test() {
	// Assignment gives us a different code path than declarations, and `&foo`
	// gives us a different code path than `foo`
	int (*p)(int) = ovlFoo;
	int (*p2)(int) = &ovlFoo;
	int (*a)(int);
	a = ovlFoo;
	a = &ovlFoo;
	}

	int ovlBar(int) __attribute__((enable_if(true, "")));
	int ovlBar(int m) __attribute__((enable_if(false, "")));
	void test2() {
	int (*p)(int) = ovlBar;
	int (*p2)(int) = &ovlBar;
	int (*a)(int);
	a = ovlBar;
	a = &ovlBar;
	}

	int ovlConflict(int m) __attribute__((enable_if(true, "")));
	int ovlConflict(int m) __attribute__((enable_if(1, "")));
	void test3() {
	int (*p)(int) = ovlConflict; // expected-error{{address of overloaded function 'ovlConflict' is ambiguous}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
	int (*p2)(int) = &ovlConflict; // expected-error{{address of overloaded function 'ovlConflict' is ambiguous}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
	int (*a)(int);
	a = ovlConflict; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
	a = &ovlConflict; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@191{{candidate function}} expected-note@192{{candidate function}}
	}

	template <typename T>
	T templated(T m) __attribute__((enable_if(true, ""))) { return T(); }
	template <typename T>
	T templated(T m) __attribute__((enable_if(false, ""))) { return T(); }
	void test4() {
	int (*p)(int) = templated<int>;
	int (*p2)(int) = &templated<int>;
	int (*a)(int);
	a = templated<int>;
	a = &templated<int>;
	}

	template <typename T>
	T templatedBar(T m) __attribute__((enable_if(m > 0, ""))) { return T(); }
	void test5() {
	int (*p)(int) = templatedBar<int>; // expected-error{{address of overloaded function 'templatedBar' does not match required type 'int (int)'}} expected-note@214{{candidate function made ineligible by enable_if}}
	int (*p2)(int) = &templatedBar<int>; // expected-error{{address of overloaded function 'templatedBar' does not match required type 'int (int)'}} expected-note@214{{candidate function made ineligible by enable_if}}
	int (*a)(int);
	a = templatedBar<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@214{{candidate function made ineligible by enable_if}}
	a = &templatedBar<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@214{{candidate function made ineligible by enable_if}}
	}

	template <typename T>
	T templatedConflict(T m) __attribute__((enable_if(false, ""))) { return T(); }
	template <typename T>
	T templatedConflict(T m) __attribute__((enable_if(true, ""))) { return T(); }
	template <typename T>
	T templatedConflict(T m) __attribute__((enable_if(1, ""))) { return T(); }
	void test6() {
	int (*p)(int) = templatedConflict<int>; // expected-error{{address of overloaded function 'templatedConflict' is ambiguous}} expected-note@224{{candidate function made ineligible by enable_if}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
	int (*p0)(int) = &templatedConflict<int>; // expected-error{{address of overloaded function 'templatedConflict' is ambiguous}} expected-note@224{{candidate function made ineligible by enable_if}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
	int (*a)(int);
	a = templatedConflict<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
	a = &templatedConflict<int>; // expected-error{{assigning to 'int (*)(int)' from incompatible type '<overloaded function type>'}} expected-note@226{{candidate function}} expected-note@228{{candidate function}}
	}
	}