test/std/utilities/tuple/tuple.tuple/tuple.cnstr/implicit_deduction_guides.pass.cpp - libcxx - Git at Google

 //===----------------------------------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 // UNSUPPORTED: c++98, c++03, c++11, c++14
 // UNSUPPORTED: libcpp-no-deduction-guides

 // GCC's implementation of class template deduction is still immature and runs
 // into issues with libc++. However GCC accepts this code when compiling
 // against libstdc++.
 // XFAIL: gcc

 // <tuple>

 // Test that the constructors offered by std::tuple are formulated
 // so they're compatible with implicit deduction guides, or if that's not
 // possible that they provide explicit guides to make it work.

 #include <tuple>
 #include <memory>
 #include <cassert>

 #include "test_macros.h"
 #include "archetypes.hpp"


 // Overloads
 //  using A = Allocator
 //  using AT = std::allocator_arg_t
 // ---------------
 // (1)  tuple(const Types&...) -> tuple<Types...>
 // (2)  explicit tuple(const Types&...) -> tuple<Types...>
 // (3)  tuple(AT, A const&, Types const&...) -> tuple<Types...>
 // (4)  explicit tuple(AT, A const&, Types const&...) -> tuple<Types...>
 // (5)  tuple(tuple const& t) -> decltype(t)
 // (6)  tuple(tuple&& t) -> decltype(t)
 // (7)  tuple(AT, A const&, tuple const& t) -> decltype(t)
 // (8)  tuple(AT, A const&, tuple&& t) -> decltype(t)
 void test_primary_template()
 {
   const std::allocator<int> A;
   const auto AT = std::allocator_arg;
   { // Testing (1)
     int x = 101;
     std::tuple t1(42);
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<int>);
     std::tuple t2(x, 0.0, nullptr);
     ASSERT_SAME_TYPE(decltype(t2), std::tuple<int, double, decltype(nullptr)>);
   }
   { // Testing (2)
     using T = ExplicitTestTypes::TestType;
     static_assert(!std::is_convertible<T const&, T>::value, "");

     std::tuple t1(T{});
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<T>);

     const T v{};
     std::tuple t2(T{}, 101l, v);
     ASSERT_SAME_TYPE(decltype(t2), std::tuple<T, long, T>);
   }
   { // Testing (3)
     int x = 101;
     std::tuple t1(AT, A, 42);
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<int>);

     std::tuple t2(AT, A, 42, 0.0, x);
     ASSERT_SAME_TYPE(decltype(t2), std::tuple<int, double, int>);
   }
   { // Testing (4)
     using T = ExplicitTestTypes::TestType;
     static_assert(!std::is_convertible<T const&, T>::value, "");

     std::tuple t1(AT, A, T{});
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<T>);

     const T v{};
     std::tuple t2(AT, A, T{}, 101l, v);
     ASSERT_SAME_TYPE(decltype(t2), std::tuple<T, long, T>);
   }
   { // Testing (5)
     using Tup = std::tuple<int, decltype(nullptr)>;
     const Tup t(42, nullptr);

     std::tuple t1(t);
     ASSERT_SAME_TYPE(decltype(t1), Tup);
   }
   { // Testing (6)
     using Tup = std::tuple<void*, unsigned, char>;
     std::tuple t1(Tup(nullptr, 42, 'a'));
     ASSERT_SAME_TYPE(decltype(t1), Tup);
   }
   { // Testing (7)
     using Tup = std::tuple<int, decltype(nullptr)>;
     const Tup t(42, nullptr);

     std::tuple t1(AT, A, t);
     ASSERT_SAME_TYPE(decltype(t1), Tup);
   }
   { // Testing (8)
     using Tup = std::tuple<void*, unsigned, char>;
     std::tuple t1(AT, A, Tup(nullptr, 42, 'a'));
     ASSERT_SAME_TYPE(decltype(t1), Tup);
   }
 }

 // Overloads
 //  using A = Allocator
 //  using AT = std::allocator_arg_t
 // ---------------
 // (1)  tuple() -> tuple<>
 // (2)  tuple(AT, A const&) -> tuple<>
 // (3)  tuple(tuple const&) -> tuple<>
 // (4)  tuple(tuple&&) -> tuple<>
 // (5)  tuple(AT, A const&, tuple const&) -> tuple<>
 // (6)  tuple(AT, A const&, tuple&&) -> tuple<>
 void test_empty_specialization()
 {
   std::allocator<int> A;
   const auto AT = std::allocator_arg;
   { // Testing (1)
     std::tuple t1{};
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
   }
   { // Testing (2)
     std::tuple t1{AT, A};
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
   }
   { // Testing (3)
     const std::tuple<> t{};
     std::tuple t1(t);
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
   }
   { // Testing (4)
     std::tuple t1(std::tuple<>{});
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
   }
   { // Testing (5)
     const std::tuple<> t{};
     std::tuple t1(AT, A, t);
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
   }
   { // Testing (6)
     std::tuple t1(AT, A, std::tuple<>{});
     ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
   }
 }

 int main(int, char**) {
   test_primary_template();
   test_empty_specialization();

   return 0;
 }
	//===----------------------------------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	// UNSUPPORTED: c++98, c++03, c++11, c++14
	// UNSUPPORTED: libcpp-no-deduction-guides

	// GCC's implementation of class template deduction is still immature and runs
	// into issues with libc++. However GCC accepts this code when compiling
	// against libstdc++.
	// XFAIL: gcc

	// <tuple>

	// Test that the constructors offered by std::tuple are formulated
	// so they're compatible with implicit deduction guides, or if that's not
	// possible that they provide explicit guides to make it work.

	#include <tuple>
	#include <memory>
	#include <cassert>

	#include "test_macros.h"
	#include "archetypes.hpp"


	// Overloads
	// using A = Allocator
	// using AT = std::allocator_arg_t
	// ---------------
	// (1) tuple(const Types&...) -> tuple<Types...>
	// (2) explicit tuple(const Types&...) -> tuple<Types...>
	// (3) tuple(AT, A const&, Types const&...) -> tuple<Types...>
	// (4) explicit tuple(AT, A const&, Types const&...) -> tuple<Types...>
	// (5) tuple(tuple const& t) -> decltype(t)
	// (6) tuple(tuple&& t) -> decltype(t)
	// (7) tuple(AT, A const&, tuple const& t) -> decltype(t)
	// (8) tuple(AT, A const&, tuple&& t) -> decltype(t)
	void test_primary_template()
	{
	const std::allocator<int> A;
	const auto AT = std::allocator_arg;
	{ // Testing (1)
	int x = 101;
	std::tuple t1(42);
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<int>);
	std::tuple t2(x, 0.0, nullptr);
	ASSERT_SAME_TYPE(decltype(t2), std::tuple<int, double, decltype(nullptr)>);
	}
	{ // Testing (2)
	using T = ExplicitTestTypes::TestType;
	static_assert(!std::is_convertible<T const&, T>::value, "");

	std::tuple t1(T{});
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<T>);

	const T v{};
	std::tuple t2(T{}, 101l, v);
	ASSERT_SAME_TYPE(decltype(t2), std::tuple<T, long, T>);
	}
	{ // Testing (3)
	int x = 101;
	std::tuple t1(AT, A, 42);
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<int>);

	std::tuple t2(AT, A, 42, 0.0, x);
	ASSERT_SAME_TYPE(decltype(t2), std::tuple<int, double, int>);
	}
	{ // Testing (4)
	using T = ExplicitTestTypes::TestType;
	static_assert(!std::is_convertible<T const&, T>::value, "");

	std::tuple t1(AT, A, T{});
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<T>);

	const T v{};
	std::tuple t2(AT, A, T{}, 101l, v);
	ASSERT_SAME_TYPE(decltype(t2), std::tuple<T, long, T>);
	}
	{ // Testing (5)
	using Tup = std::tuple<int, decltype(nullptr)>;
	const Tup t(42, nullptr);

	std::tuple t1(t);
	ASSERT_SAME_TYPE(decltype(t1), Tup);
	}
	{ // Testing (6)
	using Tup = std::tuple<void*, unsigned, char>;
	std::tuple t1(Tup(nullptr, 42, 'a'));
	ASSERT_SAME_TYPE(decltype(t1), Tup);
	}
	{ // Testing (7)
	using Tup = std::tuple<int, decltype(nullptr)>;
	const Tup t(42, nullptr);

	std::tuple t1(AT, A, t);
	ASSERT_SAME_TYPE(decltype(t1), Tup);
	}
	{ // Testing (8)
	using Tup = std::tuple<void*, unsigned, char>;
	std::tuple t1(AT, A, Tup(nullptr, 42, 'a'));
	ASSERT_SAME_TYPE(decltype(t1), Tup);
	}
	}

	// Overloads
	// using A = Allocator
	// using AT = std::allocator_arg_t
	// ---------------
	// (1) tuple() -> tuple<>
	// (2) tuple(AT, A const&) -> tuple<>
	// (3) tuple(tuple const&) -> tuple<>
	// (4) tuple(tuple&&) -> tuple<>
	// (5) tuple(AT, A const&, tuple const&) -> tuple<>
	// (6) tuple(AT, A const&, tuple&&) -> tuple<>
	void test_empty_specialization()
	{
	std::allocator<int> A;
	const auto AT = std::allocator_arg;
	{ // Testing (1)
	std::tuple t1{};
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
	}
	{ // Testing (2)
	std::tuple t1{AT, A};
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
	}
	{ // Testing (3)
	const std::tuple<> t{};
	std::tuple t1(t);
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
	}
	{ // Testing (4)
	std::tuple t1(std::tuple<>{});
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
	}
	{ // Testing (5)
	const std::tuple<> t{};
	std::tuple t1(AT, A, t);
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
	}
	{ // Testing (6)
	std::tuple t1(AT, A, std::tuple<>{});
	ASSERT_SAME_TYPE(decltype(t1), std::tuple<>);
	}
	}

	int main(int, char**) {
	test_primary_template();
	test_empty_specialization();

	return 0;
	}