test/CXX/dcl.decl/dcl.decomp/p3.cpp - clang - Git at Google

 // RUN: %clang_cc1 -std=c++1z -verify %s

 using size_t = decltype(sizeof(0));

 struct A { int x, y; };
 struct B { int x, y; };

 void no_tuple_size_1() { auto [x, y] = A(); } // ok, decompose elementwise

 namespace std { template<typename T> struct tuple_size; }
 void no_tuple_size_2() { auto [x, y] = A(); } // ok, decompose elementwise

 struct Bad1 { int a, b; };
 template<> struct std::tuple_size<Bad1> {};
 void no_tuple_size_3() { auto [x, y] = Bad1(); } // expected-error {{cannot decompose this type; 'std::tuple_size<Bad1>::value' is not a valid integral constant expression}}

 struct Bad2 {};
 template<> struct std::tuple_size<Bad2> { const int value = 5; };
 void no_tuple_size_4() { auto [x, y] = Bad2(); } // expected-error {{cannot decompose this type; 'std::tuple_size<Bad2>::value' is not a valid integral constant expression}}

 template<> struct std::tuple_size<A> { static const int value = 3; };
 template<> struct std::tuple_size<B> { enum { value = 3 }; };

 void no_get_1() {
   {
     auto [a0, a1] = A(); // expected-error {{decomposes into 3 elements}}
     auto [b0, b1] = B(); // expected-error {{decomposes into 3 elements}}
   }
   auto [a0, a1, a2] = A(); // expected-error {{undeclared identifier 'get'}} expected-note {{in implicit initialization of binding declaration 'a0'}}
 }

 int get(A);

 void no_get_2() {
   // FIXME: This diagnostic is not great.
   auto [a0, a1, a2] = A(); // expected-error {{undeclared identifier 'get'}} expected-note {{in implicit initialization of binding declaration 'a0'}}
 }

 template<int> float &get(A);

 void no_tuple_element_1() {
   auto [a0, a1, a2] = A(); // expected-error-re {{'std::tuple_element<0U{{L*}}, A>::type' does not name a type}} expected-note {{in implicit}}
 }

 namespace std { template<size_t, typename> struct tuple_element; } // expected-note 2{{here}}

 void no_tuple_element_2() {
   auto [a0, a1, a2] = A(); // expected-error {{implicit instantiation of undefined template 'std::tuple_element<0, A>'}} expected-note {{in implicit}}
 }

 template<> struct std::tuple_element<0, A> { typedef float type; };

 void no_tuple_element_3() {
   auto [a0, a1, a2] = A(); // expected-error {{implicit instantiation of undefined template 'std::tuple_element<1, A>'}} expected-note {{in implicit}}
 }

 template<> struct std::tuple_element<1, A> { typedef float &type; };
 template<> struct std::tuple_element<2, A> { typedef const float &type; };

 template<int N> auto get(B) -> int (&)[N + 1];
 template<int N> struct std::tuple_element<N, B> { typedef int type[N +1 ]; };

 template<typename T> struct std::tuple_size<const T> : std::tuple_size<T> {};
 template<size_t N, typename T> struct std::tuple_element<N, const T> {
   typedef const typename std::tuple_element<N, T>::type type;
 };

 void referenced_type() {
   auto [a0, a1, a2] = A();
   auto [b0, b1, b2] = B();

   A a;
   B b;
   auto &[ar0, ar1, ar2] = a;
   auto &[br0, br1, br2] = b;

   auto &&[arr0, arr1, arr2] = A();
   auto &&[brr0, brr1, brr2] = B();

   const auto &[acr0, acr1, acr2] = A();
   const auto &[bcr0, bcr1, bcr2] = B();


   using Float = float;
   using Float = decltype(a0);
   using Float = decltype(ar0);
   using Float = decltype(arr0);

   using ConstFloat = const float;
   using ConstFloat = decltype(acr0);

   using FloatRef = float&;
   using FloatRef = decltype(a1);
   using FloatRef = decltype(ar1);
   using FloatRef = decltype(arr1);
   using FloatRef = decltype(acr1);

   using ConstFloatRef = const float&;
   using ConstFloatRef = decltype(a2);
   using ConstFloatRef = decltype(ar2);
   using ConstFloatRef = decltype(arr2);
   using ConstFloatRef = decltype(acr2);


   using Int1 = int[1];
   using Int1 = decltype(b0);
   using Int1 = decltype(br0);
   using Int1 = decltype(brr0);

   using ConstInt1 = const int[1];
   using ConstInt1 = decltype(bcr0);

   using Int2 = int[2];
   using Int2 = decltype(b1);
   using Int2 = decltype(br1);
   using Int2 = decltype(brr1);

   using ConstInt2 = const int[2];
   using ConstInt2 = decltype(bcr1);

   using Int3 = int[3];
   using Int3 = decltype(b2);
   using Int3 = decltype(br2);
   using Int3 = decltype(brr2);

   using ConstInt3 = const int[3];
   using ConstInt3 = decltype(bcr2);
 }

 struct C { template<int> int get(); };
 template<> struct std::tuple_size<C> { static const int value = 1; };
 template<> struct std::tuple_element<0, C> { typedef int type; };

 int member_get() {
   auto [c] = C();
   using T = int;
   using T = decltype(c);
   return c;
 }

 struct D { template<int> struct get {}; }; // expected-note {{declared here}}
 template<> struct std::tuple_size<D> { static const int value = 1; };
 template<> struct std::tuple_element<0, D> { typedef D::get<0> type; };
 void member_get_class_template() {
   auto [d] = D(); // expected-error {{cannot refer to member 'get' in 'D' with '.'}} expected-note {{in implicit init}}
 }

 struct E { int get(); };
 template<> struct std::tuple_size<E> { static const int value = 1; };
 template<> struct std::tuple_element<0, E> { typedef int type; };
 void member_get_non_template() {
   // FIXME: This diagnostic is not very good.
   auto [e] = E(); // expected-error {{no member named 'get'}} expected-note {{in implicit init}}
 }

 namespace ADL {
   struct X {};
 };
 template<int> int get(ADL::X);
 template<> struct std::tuple_size<ADL::X> { static const int value = 1; };
 template<> struct std::tuple_element<0, ADL::X> { typedef int type; };
 void adl_only_bad() {
   auto [x] = ADL::X(); // expected-error {{undeclared identifier 'get'}} expected-note {{in implicit init}}
 }

 template<typename ElemType, typename GetTypeLV, typename GetTypeRV>
 struct wrap {
   template<size_t> GetTypeLV get() &;
   template<size_t> GetTypeRV get() &&;
 };
 template<typename ET, typename GTL, typename GTR>
 struct std::tuple_size<wrap<ET, GTL, GTR>> {
   static const int value = 1;
 };
 template<typename ET, typename GTL, typename GTR>
 struct std::tuple_element<0, wrap<ET, GTL, GTR>> {
   using type = ET;
 };

 template<typename T> T &lvalue();

 void test_value_category() {
   // If the declared variable is an lvalue reference, the operand to get is an
   // lvalue. Otherwise it's an xvalue.
   { auto [a] = wrap<int, void, int>(); }
   { auto &[a] = lvalue<wrap<int, int, void>>(); }
   { auto &&[a] = wrap<int, void, int>(); }
   // If the initializer (call to get) is an lvalue, the binding is an lvalue
   // reference to the element type. Otherwise it's an rvalue reference to the
   // element type.
   { auto [a] = wrap<int, void, int&>(); }
   { auto [a] = wrap<int&, void, int&>(); }
   { auto [a] = wrap<int&&, void, int&>(); } // ok, reference collapse to int&

   { auto [a] = wrap<int, void, int&&>(); }
   { auto [a] = wrap<int&, void, int&&>(); } // expected-error {{non-const lvalue reference to type 'int' cannot bind}} expected-note {{in implicit}}
   { auto [a] = wrap<const int&, void, int&&>(); }
   { auto [a] = wrap<int&&, void, int&&>(); }

   { auto [a] = wrap<int, void, float&>(); } // expected-error {{cannot bind}} expected-note {{implicit}}
   { auto [a] = wrap<const int, void, float&>(); } // ok, const int &a can bind to float
   { auto [a] = wrap<int, void, float>(); } // ok, int &&a can bind to float
 }

 namespace constant {
   struct Q {};
   template<int N> constexpr int get(Q &&) { return N * N; }
 }
 template<> struct std::tuple_size<constant::Q> { static const int value = 3; };
 template<int N> struct std::tuple_element<N, constant::Q> { typedef int type; };
 namespace constant {
   Q q;
   // This creates and lifetime-extends a temporary to hold the result of each get() call.
   auto [a, b, c] = q;    // expected-note {{temporary}}
   static_assert(a == 0); // expected-error {{constant expression}} expected-note {{temporary}}

   constexpr bool f() {
     auto [a, b, c] = q;
     return a == 0 && b == 1 && c == 4;
   }
   static_assert(f());

   constexpr int g() {
     int *p = nullptr;
     {
       auto [a, b, c] = q;
       p = &c;
     }
     return *p; // expected-note {{read of object outside its lifetime}}
   }
   static_assert(g() == 4); // expected-error {{constant}} expected-note {{in call to 'g()'}}
 }
	// RUN: %clang_cc1 -std=c++1z -verify %s

	using size_t = decltype(sizeof(0));

	struct A { int x, y; };
	struct B { int x, y; };

	void no_tuple_size_1() { auto [x, y] = A(); } // ok, decompose elementwise

	namespace std { template<typename T> struct tuple_size; }
	void no_tuple_size_2() { auto [x, y] = A(); } // ok, decompose elementwise

	struct Bad1 { int a, b; };
	template<> struct std::tuple_size<Bad1> {};
	void no_tuple_size_3() { auto [x, y] = Bad1(); } // expected-error {{cannot decompose this type; 'std::tuple_size<Bad1>::value' is not a valid integral constant expression}}

	struct Bad2 {};
	template<> struct std::tuple_size<Bad2> { const int value = 5; };
	void no_tuple_size_4() { auto [x, y] = Bad2(); } // expected-error {{cannot decompose this type; 'std::tuple_size<Bad2>::value' is not a valid integral constant expression}}

	template<> struct std::tuple_size<A> { static const int value = 3; };
	template<> struct std::tuple_size<B> { enum { value = 3 }; };

	void no_get_1() {
	{
	auto [a0, a1] = A(); // expected-error {{decomposes into 3 elements}}
	auto [b0, b1] = B(); // expected-error {{decomposes into 3 elements}}
	}
	auto [a0, a1, a2] = A(); // expected-error {{undeclared identifier 'get'}} expected-note {{in implicit initialization of binding declaration 'a0'}}
	}

	int get(A);

	void no_get_2() {
	// FIXME: This diagnostic is not great.
	auto [a0, a1, a2] = A(); // expected-error {{undeclared identifier 'get'}} expected-note {{in implicit initialization of binding declaration 'a0'}}
	}

	template<int> float &get(A);

	void no_tuple_element_1() {
	auto [a0, a1, a2] = A(); // expected-error-re {{'std::tuple_element<0U{{L*}}, A>::type' does not name a type}} expected-note {{in implicit}}
	}

	namespace std { template<size_t, typename> struct tuple_element; } // expected-note 2{{here}}

	void no_tuple_element_2() {
	auto [a0, a1, a2] = A(); // expected-error {{implicit instantiation of undefined template 'std::tuple_element<0, A>'}} expected-note {{in implicit}}
	}

	template<> struct std::tuple_element<0, A> { typedef float type; };

	void no_tuple_element_3() {
	auto [a0, a1, a2] = A(); // expected-error {{implicit instantiation of undefined template 'std::tuple_element<1, A>'}} expected-note {{in implicit}}
	}

	template<> struct std::tuple_element<1, A> { typedef float &type; };
	template<> struct std::tuple_element<2, A> { typedef const float &type; };

	template<int N> auto get(B) -> int (&)[N + 1];
	template<int N> struct std::tuple_element<N, B> { typedef int type[N +1 ]; };

	template<typename T> struct std::tuple_size<const T> : std::tuple_size<T> {};
	template<size_t N, typename T> struct std::tuple_element<N, const T> {
	typedef const typename std::tuple_element<N, T>::type type;
	};

	void referenced_type() {
	auto [a0, a1, a2] = A();
	auto [b0, b1, b2] = B();

	A a;
	B b;
	auto &[ar0, ar1, ar2] = a;
	auto &[br0, br1, br2] = b;

	auto &&[arr0, arr1, arr2] = A();
	auto &&[brr0, brr1, brr2] = B();

	const auto &[acr0, acr1, acr2] = A();
	const auto &[bcr0, bcr1, bcr2] = B();


	using Float = float;
	using Float = decltype(a0);
	using Float = decltype(ar0);
	using Float = decltype(arr0);

	using ConstFloat = const float;
	using ConstFloat = decltype(acr0);

	using FloatRef = float&;
	using FloatRef = decltype(a1);
	using FloatRef = decltype(ar1);
	using FloatRef = decltype(arr1);
	using FloatRef = decltype(acr1);

	using ConstFloatRef = const float&;
	using ConstFloatRef = decltype(a2);
	using ConstFloatRef = decltype(ar2);
	using ConstFloatRef = decltype(arr2);
	using ConstFloatRef = decltype(acr2);


	using Int1 = int[1];
	using Int1 = decltype(b0);
	using Int1 = decltype(br0);
	using Int1 = decltype(brr0);

	using ConstInt1 = const int[1];
	using ConstInt1 = decltype(bcr0);

	using Int2 = int[2];
	using Int2 = decltype(b1);
	using Int2 = decltype(br1);
	using Int2 = decltype(brr1);

	using ConstInt2 = const int[2];
	using ConstInt2 = decltype(bcr1);

	using Int3 = int[3];
	using Int3 = decltype(b2);
	using Int3 = decltype(br2);
	using Int3 = decltype(brr2);

	using ConstInt3 = const int[3];
	using ConstInt3 = decltype(bcr2);
	}

	struct C { template<int> int get(); };
	template<> struct std::tuple_size<C> { static const int value = 1; };
	template<> struct std::tuple_element<0, C> { typedef int type; };

	int member_get() {
	auto [c] = C();
	using T = int;
	using T = decltype(c);
	return c;
	}

	struct D { template<int> struct get {}; }; // expected-note {{declared here}}
	template<> struct std::tuple_size<D> { static const int value = 1; };
	template<> struct std::tuple_element<0, D> { typedef D::get<0> type; };
	void member_get_class_template() {
	auto [d] = D(); // expected-error {{cannot refer to member 'get' in 'D' with '.'}} expected-note {{in implicit init}}
	}

	struct E { int get(); };
	template<> struct std::tuple_size<E> { static const int value = 1; };
	template<> struct std::tuple_element<0, E> { typedef int type; };
	void member_get_non_template() {
	// FIXME: This diagnostic is not very good.
	auto [e] = E(); // expected-error {{no member named 'get'}} expected-note {{in implicit init}}
	}

	namespace ADL {
	struct X {};
	};
	template<int> int get(ADL::X);
	template<> struct std::tuple_size<ADL::X> { static const int value = 1; };
	template<> struct std::tuple_element<0, ADL::X> { typedef int type; };
	void adl_only_bad() {
	auto [x] = ADL::X(); // expected-error {{undeclared identifier 'get'}} expected-note {{in implicit init}}
	}

	template<typename ElemType, typename GetTypeLV, typename GetTypeRV>
	struct wrap {
	template<size_t> GetTypeLV get() &;
	template<size_t> GetTypeRV get() &&;
	};
	template<typename ET, typename GTL, typename GTR>
	struct std::tuple_size<wrap<ET, GTL, GTR>> {
	static const int value = 1;
	};
	template<typename ET, typename GTL, typename GTR>
	struct std::tuple_element<0, wrap<ET, GTL, GTR>> {
	using type = ET;
	};

	template<typename T> T &lvalue();

	void test_value_category() {
	// If the declared variable is an lvalue reference, the operand to get is an
	// lvalue. Otherwise it's an xvalue.
	{ auto [a] = wrap<int, void, int>(); }
	{ auto &[a] = lvalue<wrap<int, int, void>>(); }
	{ auto &&[a] = wrap<int, void, int>(); }
	// If the initializer (call to get) is an lvalue, the binding is an lvalue
	// reference to the element type. Otherwise it's an rvalue reference to the
	// element type.
	{ auto [a] = wrap<int, void, int&>(); }
	{ auto [a] = wrap<int&, void, int&>(); }
	{ auto [a] = wrap<int&&, void, int&>(); } // ok, reference collapse to int&

	{ auto [a] = wrap<int, void, int&&>(); }
	{ auto [a] = wrap<int&, void, int&&>(); } // expected-error {{non-const lvalue reference to type 'int' cannot bind}} expected-note {{in implicit}}
	{ auto [a] = wrap<const int&, void, int&&>(); }
	{ auto [a] = wrap<int&&, void, int&&>(); }

	{ auto [a] = wrap<int, void, float&>(); } // expected-error {{cannot bind}} expected-note {{implicit}}
	{ auto [a] = wrap<const int, void, float&>(); } // ok, const int &a can bind to float
	{ auto [a] = wrap<int, void, float>(); } // ok, int &&a can bind to float
	}

	namespace constant {
	struct Q {};
	template<int N> constexpr int get(Q &&) { return N * N; }
	}
	template<> struct std::tuple_size<constant::Q> { static const int value = 3; };
	template<int N> struct std::tuple_element<N, constant::Q> { typedef int type; };
	namespace constant {
	Q q;
	// This creates and lifetime-extends a temporary to hold the result of each get() call.
	auto [a, b, c] = q; // expected-note {{temporary}}
	static_assert(a == 0); // expected-error {{constant expression}} expected-note {{temporary}}

	constexpr bool f() {
	auto [a, b, c] = q;
	return a == 0 && b == 1 && c == 4;
	}
	static_assert(f());

	constexpr int g() {
	int *p = nullptr;
	{
	auto [a, b, c] = q;
	p = &c;
	}
	return *p; // expected-note {{read of object outside its lifetime}}
	}
	static_assert(g() == 4); // expected-error {{constant}} expected-note {{in call to 'g()'}}
	}