clang/test/SemaTemplate/cxx1z-fold-expressions.cpp - llvm-project - Git at Google

 // RUN: %clang_cc1 -std=c++1z -verify %s
 // RUN: %clang_cc1 -std=c++2a -verify %s

 template<typename ...T> constexpr auto sum(T ...t) { return (... + t); }
 template<typename ...T> constexpr auto product(T ...t) { return (t * ...); }
 template<typename ...T> constexpr auto all(T ...t) { return (true && ... && t); }
 template<typename ...T> constexpr auto dumb(T ...t) { return (false && ... && t); }

 static_assert(sum(1, 2, 3, 4, 5) == 15);
 static_assert(product(1, 2, 3, 4, 5) == 120);
 static_assert(!all(true, true, false, true, false));
 static_assert(all(true, true, true, true, true));
 static_assert(!dumb(true, true, true, true, true));

 struct S {
   int a, b, c, d, e;
 };
 template<typename ...T> constexpr auto increment_all(T &...t) {
   (++t, ...);
 }
 constexpr bool check() {
   S s = { 1, 2, 3, 4, 5 };
   increment_all(s.a, s.b, s.c, s.d, s.e);
   return s.a == 2 && s.b == 3 && s.c == 4 && s.d == 5 && s.e == 6;
 }
 static_assert(check());

 template<int ...N> void empty() {
   static_assert((N || ...) == false);
   static_assert((N && ...) == true);
   (N, ...);
 }
 template void empty<>();

 // An empty fold-expression isn't a null pointer just because it's an integer
 // with value 0. (This is no longer an issue since empty pack expansions don't
 // produce integers any more.)
 template<int ...N> void null_ptr() {
   void *p = (N || ...); // expected-error {{rvalue of type 'bool'}}
   void *q = (N , ...); // expected-error {{rvalue of type 'void'}}
 }
 template void null_ptr<>(); // expected-note {{in instantiation of}}

 template<int ...N> void bad_empty() {
   (N + ...); // expected-error {{empty expansion for operator '+' with no fallback}}
   (N * ...); // expected-error {{empty expansion for operator '*' with no fallback}}
   (N | ...); // expected-error {{empty expansion for operator '|' with no fallback}}
   (N & ...); // expected-error {{empty expansion for operator '&' with no fallback}}
   (N - ...); // expected-error {{empty expansion for operator '-' with no fallback}}
   (N / ...); // expected-error {{empty expansion for operator '/' with no fallback}}
   (N % ...); // expected-error {{empty expansion for operator '%' with no fallback}}
   (N = ...); // expected-error {{empty expansion for operator '=' with no fallback}}
 }
 template void bad_empty<>(); // expected-note {{in instantiation of}}

 template<int ...N> void empty_with_base() {
   extern int k;
   (k = ... = N); // expected-warning{{unused}}

   void (k = ... = N); // expected-error {{expected ')'}} expected-note {{to match}}
   void ((k = ... = N));
   (void) (k = ... = N);
 }
 template void empty_with_base<>(); // expected-note {{in instantiation of}}
 template void empty_with_base<1>();

 struct A {
   struct B {
     struct C {
       struct D {
         int e;
       } d;
     } c;
   } b;
 } a;
 template<typename T, typename ...Ts> constexpr decltype(auto) apply(T &t, Ts ...ts) {
   return (t.*....*ts);
 }
 static_assert(&apply(a, &A::b, &A::B::c, &A::B::C::d, &A::B::C::D::e) == &a.b.c.d.e);

 #if __cplusplus > 201703L
 // The <=> operator is unique among binary operators in not being a
 // fold-operator.
 // FIXME: This diagnostic is not great.
 template<typename ...T> constexpr auto spaceship1(T ...t) { return (t <=> ...); } // expected-error {{expected expression}}
 template<typename ...T> constexpr auto spaceship2(T ...t) { return (... <=> t); } // expected-error {{expected expression}}
 template<typename ...T> constexpr auto spaceship3(T ...t) { return (t <=> ... <=> 0); } // expected-error {{expected expression}}
 #endif

 // The GNU binary conditional operator ?: is not recognized as a fold-operator.
 // FIXME: Why not? This seems like it would be useful.
 template<typename ...T> constexpr auto binary_conditional1(T ...t) { return (t ?: ...); } // expected-error {{expected expression}}
 template<typename ...T> constexpr auto binary_conditional2(T ...t) { return (... ?: t); } // expected-error {{expected expression}}
 template<typename ...T> constexpr auto binary_conditional3(T ...t) { return (t ?: ... ?: 0); } // expected-error {{expected expression}}

 namespace PR41845 {
   template <int I> struct Constant {};

   template <int... Is> struct Sum {
     template <int... Js> using type = Constant<((Is + Js) + ... + 0)>; // expected-error {{pack expansion contains parameter pack 'Js' that has a different length (1 vs. 2) from outer parameter packs}}
   };

   Sum<1>::type<1, 2> x; // expected-note {{instantiation of}}
 }

 namespace PR30738 {
   namespace N {
     struct S {};
   }

   namespace T {
     void operator+(N::S, N::S) {}
     template<typename ...Ts> void f() { (Ts{} + ...); }
   }

   void g() { T::f<N::S, N::S>(); }

   template<typename T, typename ...U> auto h(U ...v) {
     T operator+(T, T); // expected-note {{candidate}}
     return (v + ...); // expected-error {{invalid operands}}
   }
   int test_h1 = h<N::S>(1, 2, 3);
   N::S test_h2 = h<N::S>(N::S(), N::S(), N::S());
   int test_h3 = h<struct X>(1, 2, 3);
   N::S test_h4 = h<struct X>(N::S(), N::S(), N::S()); // expected-note {{instantiation of}}
 }
	// RUN: %clang_cc1 -std=c++1z -verify %s
	// RUN: %clang_cc1 -std=c++2a -verify %s

	template<typename ...T> constexpr auto sum(T ...t) { return (... + t); }
	template<typename ...T> constexpr auto product(T ...t) { return (t * ...); }
	template<typename ...T> constexpr auto all(T ...t) { return (true && ... && t); }
	template<typename ...T> constexpr auto dumb(T ...t) { return (false && ... && t); }

	static_assert(sum(1, 2, 3, 4, 5) == 15);
	static_assert(product(1, 2, 3, 4, 5) == 120);
	static_assert(!all(true, true, false, true, false));
	static_assert(all(true, true, true, true, true));
	static_assert(!dumb(true, true, true, true, true));

	struct S {
	int a, b, c, d, e;
	};
	template<typename ...T> constexpr auto increment_all(T &...t) {
	(++t, ...);
	}
	constexpr bool check() {
	S s = { 1, 2, 3, 4, 5 };
	increment_all(s.a, s.b, s.c, s.d, s.e);
	return s.a == 2 && s.b == 3 && s.c == 4 && s.d == 5 && s.e == 6;
	}
	static_assert(check());

	template<int ...N> void empty() {
	static_assert((N \|\| ...) == false);
	static_assert((N && ...) == true);
	(N, ...);
	}
	template void empty<>();

	// An empty fold-expression isn't a null pointer just because it's an integer
	// with value 0. (This is no longer an issue since empty pack expansions don't
	// produce integers any more.)
	template<int ...N> void null_ptr() {
	void *p = (N \|\| ...); // expected-error {{rvalue of type 'bool'}}
	void *q = (N , ...); // expected-error {{rvalue of type 'void'}}
	}
	template void null_ptr<>(); // expected-note {{in instantiation of}}

	template<int ...N> void bad_empty() {
	(N + ...); // expected-error {{empty expansion for operator '+' with no fallback}}
	(N * ...); // expected-error {{empty expansion for operator '*' with no fallback}}
	(N \| ...); // expected-error {{empty expansion for operator '\|' with no fallback}}
	(N & ...); // expected-error {{empty expansion for operator '&' with no fallback}}
	(N - ...); // expected-error {{empty expansion for operator '-' with no fallback}}
	(N / ...); // expected-error {{empty expansion for operator '/' with no fallback}}
	(N % ...); // expected-error {{empty expansion for operator '%' with no fallback}}
	(N = ...); // expected-error {{empty expansion for operator '=' with no fallback}}
	}
	template void bad_empty<>(); // expected-note {{in instantiation of}}

	template<int ...N> void empty_with_base() {
	extern int k;
	(k = ... = N); // expected-warning{{unused}}

	void (k = ... = N); // expected-error {{expected ')'}} expected-note {{to match}}
	void ((k = ... = N));
	(void) (k = ... = N);
	}
	template void empty_with_base<>(); // expected-note {{in instantiation of}}
	template void empty_with_base<1>();

	struct A {
	struct B {
	struct C {
	struct D {
	int e;
	} d;
	} c;
	} b;
	} a;
	template<typename T, typename ...Ts> constexpr decltype(auto) apply(T &t, Ts ...ts) {
	return (t.....ts);
	}
	static_assert(&apply(a, &A::b, &A::B::c, &A::B::C::d, &A::B::C::D::e) == &a.b.c.d.e);

	#if __cplusplus > 201703L
	// The <=> operator is unique among binary operators in not being a
	// fold-operator.
	// FIXME: This diagnostic is not great.
	template<typename ...T> constexpr auto spaceship1(T ...t) { return (t <=> ...); } // expected-error {{expected expression}}
	template<typename ...T> constexpr auto spaceship2(T ...t) { return (... <=> t); } // expected-error {{expected expression}}
	template<typename ...T> constexpr auto spaceship3(T ...t) { return (t <=> ... <=> 0); } // expected-error {{expected expression}}
	#endif

	// The GNU binary conditional operator ?: is not recognized as a fold-operator.
	// FIXME: Why not? This seems like it would be useful.
	template<typename ...T> constexpr auto binary_conditional1(T ...t) { return (t ?: ...); } // expected-error {{expected expression}}
	template<typename ...T> constexpr auto binary_conditional2(T ...t) { return (... ?: t); } // expected-error {{expected expression}}
	template<typename ...T> constexpr auto binary_conditional3(T ...t) { return (t ?: ... ?: 0); } // expected-error {{expected expression}}

	namespace PR41845 {
	template <int I> struct Constant {};

	template <int... Is> struct Sum {
	template <int... Js> using type = Constant<((Is + Js) + ... + 0)>; // expected-error {{pack expansion contains parameter pack 'Js' that has a different length (1 vs. 2) from outer parameter packs}}
	};

	Sum<1>::type<1, 2> x; // expected-note {{instantiation of}}
	}

	namespace PR30738 {
	namespace N {
	struct S {};
	}

	namespace T {
	void operator+(N::S, N::S) {}
	template<typename ...Ts> void f() { (Ts{} + ...); }
	}

	void g() { T::f<N::S, N::S>(); }

	template<typename T, typename ...U> auto h(U ...v) {
	T operator+(T, T); // expected-note {{candidate}}
	return (v + ...); // expected-error {{invalid operands}}
	}
	int test_h1 = h<N::S>(1, 2, 3);
	N::S test_h2 = h<N::S>(N::S(), N::S(), N::S());
	int test_h3 = h<struct X>(1, 2, 3);
	N::S test_h4 = h<struct X>(N::S(), N::S(), N::S()); // expected-note {{instantiation of}}
	}