clang/test/SemaTemplate/instantiate-init.cpp - llvm-project - Git at Google

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

 namespace std {
   template<typename T> struct initializer_list {
     const T *p;
     __SIZE_TYPE__ n;
     initializer_list(const T*, __SIZE_TYPE__);
   };
 }

 struct X0 { // expected-note 8{{candidate}}
   X0(int*, float*); // expected-note 4{{candidate}}
 };

 template<typename T, typename U>
 X0 f0(T t, U u) {
   X0 x0(t, u); // expected-error{{no matching}}
   return X0(t, u); // expected-error{{no matching}}
 }

 void test_f0(int *ip, float *fp, double *dp) {
   f0(ip, fp);
   f0(ip, dp); // expected-note{{instantiation}}
 }

 template<typename Ret, typename T, typename U>
 Ret f1(Ret *retty, T t, U u) {
   Ret r0(t, u); // expected-error{{no matching}}
   return Ret(t, u); // expected-error{{no matching}}
 }

 void test_f1(X0 *x0, int *ip, float *fp, double *dp) {
   f1(x0, ip, fp);
   f1(x0, ip, dp); // expected-note{{instantiation}}
 }

 namespace PR6457 {
   template <typename T> struct X { explicit X(T* p = 0) { }; };
   template <typename T> struct Y { Y(int, const T& x); };
   struct A { };
   template <typename T>
   struct B {
     B() : y(0, X<A>()) { }
     Y<X<A> > y;
   };
   B<int> b;
 }

 namespace PR6657 {
   struct X
   {
     X (int, int) { }
   };

   template <typename>
   void f0()
   {
     X x = X(0, 0);
   }

   void f1()
   {
     f0<int>();
   }
 }

 // Instantiate out-of-line definitions of static data members which complete
 // types through an initializer even when the only use of the member that would
 // cause instantiation is in an unevaluated context, but one requiring its
 // complete type.
 namespace PR10001 {
   template <typename T> struct S {
     static const int arr[];
     static const int x;
     static int f();
   };

   template <typename T> const int S<T>::arr[] = { 1, 2, 3 };
   template <typename T> const int S<T>::x = sizeof(arr) / sizeof(arr[0]);
   template <typename T> int S<T>::f() { return x; }

   int x = S<int>::f();
 }

 namespace PR7985 {
   template<int N> struct integral_c { };

   template <typename T, int N>
   integral_c<N> array_lengthof(T (&x)[N]) { return integral_c<N>(); } // expected-note 2{{candidate template ignored: could not match 'T[N]' against 'const Data<}}

   template<typename T>
   struct Data {
     T x;
   };

   template<typename T>
   struct Description {
     static const Data<T> data[];
   };

   template<typename T>
   const Data<T> Description<T>::data[] = {{ 1 }}; // expected-error{{cannot initialize a member subobject of type 'int *' with an rvalue of type 'int'}}

   template<>
   const Data<float*> Description<float*>::data[];

   void test() {
     integral_c<1> ic1 = array_lengthof(Description<int>::data);
     (void)sizeof(array_lengthof(Description<float>::data));

     (void)sizeof(array_lengthof( // expected-error{{no matching function for call to 'array_lengthof'}}
                           Description<int*>::data // expected-note{{in instantiation of static data member 'PR7985::Description<int *>::data' requested here}}
                           ));

     array_lengthof(Description<float*>::data); // expected-error{{no matching function for call to 'array_lengthof'}}
   }
 }

 namespace PR13064 {
   // Ensure that in-class direct-initialization is instantiated as
   // direct-initialization and likewise copy-initialization is instantiated as
   // copy-initialization.
   struct A { explicit A(int); }; // expected-note{{here}}
   template<typename T> struct B { T a { 0 }; };
   B<A> b;
   template <typename T> struct C { // expected-note {{in instantiation of default member initializer}}
     T a = {0}; // expected-error{{explicit}}
   };
   C<A> c; // expected-note {{in evaluation of exception spec}}
 }

 namespace PR16903 {
   // Make sure we properly instantiate list-initialization.
   template<typename T>
   void fun (T it) {
   	int m = 0;
   	for (int i = 0; i < 4; ++i, ++it){
   		m |= long{char{*it}};
   	}
   }
   int test() {
   	char in[4] = {0,0,0,0};
   	fun(in);
   }
 }

 namespace ReturnStmtIsInitialization {
   struct X {
     X() {}
     X(const X &) = delete;
   };
   template<typename T> X f() { return {}; }
   auto &&x = f<void>();
 }

 namespace InitListUpdate {
   struct A { int n; };
   using AA = A[1];

   // Check that an init list update doesn't "lose" the pack-ness of an expression.
   template <int... N> void f() {
     g(AA{0, [0].n = N} ...); // expected-warning 3{{extension}} expected-note {{here}} expected-warning 3{{overrides prior init}} expected-note 3{{previous init}}
     g(AA{N, [0].n = 0} ...); // expected-warning 3{{extension}} expected-note {{here}} expected-warning 3{{overrides prior init}} expected-note 3{{previous init}}
   };

   void g(AA, AA);
   void h() { f<1, 2>(); } // expected-note {{instantiation of}}
 }

 namespace RebuildStdInitList {
   struct A { A(std::initializer_list<int>, int = 0) {} };
   struct B : A { using A::A; };
   struct PES { PES(B); };

   // Check we can rebuild the use of the default argument here. This requires
   // going to the original (base class) constructor, because we don't copy
   // default arguments onto our fake derived class inherited constructors.
   template<typename U> void f() { PES({1, 2, 3}); }
   void g() { f<int>(); }
 }
	// RUN: %clang_cc1 -fsyntax-only -verify -std=c++11 %s

	namespace std {
	template<typename T> struct initializer_list {
	const T *p;
	__SIZE_TYPE__ n;
	initializer_list(const T*, __SIZE_TYPE__);
	};
	}

	struct X0 { // expected-note 8{{candidate}}
	X0(int, float); // expected-note 4{{candidate}}
	};

	template<typename T, typename U>
	X0 f0(T t, U u) {
	X0 x0(t, u); // expected-error{{no matching}}
	return X0(t, u); // expected-error{{no matching}}
	}

	void test_f0(int ip, float fp, double *dp) {
	f0(ip, fp);
	f0(ip, dp); // expected-note{{instantiation}}
	}

	template<typename Ret, typename T, typename U>
	Ret f1(Ret *retty, T t, U u) {
	Ret r0(t, u); // expected-error{{no matching}}
	return Ret(t, u); // expected-error{{no matching}}
	}

	void test_f1(X0 x0, int ip, float fp, double dp) {
	f1(x0, ip, fp);
	f1(x0, ip, dp); // expected-note{{instantiation}}
	}

	namespace PR6457 {
	template <typename T> struct X { explicit X(T* p = 0) { }; };
	template <typename T> struct Y { Y(int, const T& x); };
	struct A { };
	template <typename T>
	struct B {
	B() : y(0, X<A>()) { }
	Y<X<A> > y;
	};
	B<int> b;
	}

	namespace PR6657 {
	struct X
	{
	X (int, int) { }
	};

	template <typename>
	void f0()
	{
	X x = X(0, 0);
	}

	void f1()
	{
	f0<int>();
	}
	}

	// Instantiate out-of-line definitions of static data members which complete
	// types through an initializer even when the only use of the member that would
	// cause instantiation is in an unevaluated context, but one requiring its
	// complete type.
	namespace PR10001 {
	template <typename T> struct S {
	static const int arr[];
	static const int x;
	static int f();
	};

	template <typename T> const int S<T>::arr[] = { 1, 2, 3 };
	template <typename T> const int S<T>::x = sizeof(arr) / sizeof(arr[0]);
	template <typename T> int S<T>::f() { return x; }

	int x = S<int>::f();
	}

	namespace PR7985 {
	template<int N> struct integral_c { };

	template <typename T, int N>
	integral_c<N> array_lengthof(T (&x)[N]) { return integral_c<N>(); } // expected-note 2{{candidate template ignored: could not match 'T[N]' against 'const Data<}}

	template<typename T>
	struct Data {
	T x;
	};

	template<typename T>
	struct Description {
	static const Data<T> data[];
	};

	template<typename T>
	const Data<T> Description<T>::data[] = {{ 1 }}; // expected-error{{cannot initialize a member subobject of type 'int *' with an rvalue of type 'int'}}

	template<>
	const Data<float> Description<float>::data[];

	void test() {
	integral_c<1> ic1 = array_lengthof(Description<int>::data);
	(void)sizeof(array_lengthof(Description<float>::data));

	(void)sizeof(array_lengthof( // expected-error{{no matching function for call to 'array_lengthof'}}
	Description<int>::data // expected-note{{in instantiation of static data member 'PR7985::Description<int >::data' requested here}}
	));

	array_lengthof(Description<float*>::data); // expected-error{{no matching function for call to 'array_lengthof'}}
	}
	}

	namespace PR13064 {
	// Ensure that in-class direct-initialization is instantiated as
	// direct-initialization and likewise copy-initialization is instantiated as
	// copy-initialization.
	struct A { explicit A(int); }; // expected-note{{here}}
	template<typename T> struct B { T a { 0 }; };
	B<A> b;
	template <typename T> struct C { // expected-note {{in instantiation of default member initializer}}
	T a = {0}; // expected-error{{explicit}}
	};
	C<A> c; // expected-note {{in evaluation of exception spec}}
	}

	namespace PR16903 {
	// Make sure we properly instantiate list-initialization.
	template<typename T>
	void fun (T it) {
	int m = 0;
	for (int i = 0; i < 4; ++i, ++it){
	m \|= long{char{*it}};
	}
	}
	int test() {
	char in[4] = {0,0,0,0};
	fun(in);
	}
	}

	namespace ReturnStmtIsInitialization {
	struct X {
	X() {}
	X(const X &) = delete;
	};
	template<typename T> X f() { return {}; }
	auto &&x = f<void>();
	}

	namespace InitListUpdate {
	struct A { int n; };
	using AA = A[1];

	// Check that an init list update doesn't "lose" the pack-ness of an expression.
	template <int... N> void f() {
	g(AA{0, [0].n = N} ...); // expected-warning 3{{extension}} expected-note {{here}} expected-warning 3{{overrides prior init}} expected-note 3{{previous init}}
	g(AA{N, [0].n = 0} ...); // expected-warning 3{{extension}} expected-note {{here}} expected-warning 3{{overrides prior init}} expected-note 3{{previous init}}
	};

	void g(AA, AA);
	void h() { f<1, 2>(); } // expected-note {{instantiation of}}
	}

	namespace RebuildStdInitList {
	struct A { A(std::initializer_list<int>, int = 0) {} };
	struct B : A { using A::A; };
	struct PES { PES(B); };

	// Check we can rebuild the use of the default argument here. This requires
	// going to the original (base class) constructor, because we don't copy
	// default arguments onto our fake derived class inherited constructors.
	template<typename U> void f() { PES({1, 2, 3}); }
	void g() { f<int>(); }
	}