sources/cxx-stl/llvm-libc++/test/std/utilities/tuple/tuple.tuple/tuple.cnstr/alloc_UTypes.pass.cpp - toolchain/prebuilts/ndk/r13 - Git at Google

 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 // <tuple>

 // template <class... Types> class tuple;

 // template <class Alloc, class... UTypes>
 //   tuple(allocator_arg_t, const Alloc& a, UTypes&&...);

 // UNSUPPORTED: c++98, c++03

 #include <tuple>
 #include <cassert>

 #include "MoveOnly.h"
 #include "allocators.h"
 #include "../alloc_first.h"
 #include "../alloc_last.h"

 template <class T = void>
 struct DefaultCtorBlowsUp {
   constexpr DefaultCtorBlowsUp() {
       static_assert(!std::is_same<T, T>::value, "Default Ctor instantiated");
   }

   explicit constexpr DefaultCtorBlowsUp(int x) : value(x) {}

   int value;
 };


 struct DerivedFromAllocArgT : std::allocator_arg_t {};


 // Make sure the _Up... constructor SFINAEs out when the number of initializers
 // is less that the number of elements in the tuple. Previously libc++ would
 // offer these constructers as an extension but they broke conforming code.
 void test_uses_allocator_sfinae_evaluation()
 {
      using BadDefault = DefaultCtorBlowsUp<>;
     {
         typedef std::tuple<MoveOnly, MoveOnly, BadDefault> Tuple;

         static_assert(!std::is_constructible<
             Tuple,
             std::allocator_arg_t, A1<int>, MoveOnly
         >::value, "");

         static_assert(std::is_constructible<
             Tuple,
             std::allocator_arg_t, A1<int>, MoveOnly, MoveOnly, BadDefault
         >::value, "");
     }
     {
         typedef std::tuple<MoveOnly, MoveOnly, BadDefault, BadDefault> Tuple;

         static_assert(!std::is_constructible<
             Tuple,
             std::allocator_arg_t, A1<int>, MoveOnly, MoveOnly
         >::value, "");

         static_assert(std::is_constructible<
             Tuple,
             std::allocator_arg_t, A1<int>, MoveOnly, MoveOnly, BadDefault, BadDefault
         >::value, "");
     }
 }

 struct Explicit {
   int value;
   explicit Explicit(int x) : value(x) {}
 };

 int main()
 {
     {
         std::tuple<Explicit> t{std::allocator_arg, std::allocator<void>{}, 42};
         assert(std::get<0>(t).value == 42);
     }
     {
         std::tuple<MoveOnly> t(std::allocator_arg, A1<int>(), MoveOnly(0));
         assert(std::get<0>(t) == 0);
     }
     {
         using T = DefaultCtorBlowsUp<>;
         std::tuple<T> t(std::allocator_arg, A1<int>(), T(42));
         assert(std::get<0>(t).value == 42);
     }
     {
         std::tuple<MoveOnly, MoveOnly> t(std::allocator_arg, A1<int>(),
                                          MoveOnly(0), MoveOnly(1));
         assert(std::get<0>(t) == 0);
         assert(std::get<1>(t) == 1);
     }
     {
         using T = DefaultCtorBlowsUp<>;
         std::tuple<T, T> t(std::allocator_arg, A1<int>(), T(42), T(43));
         assert(std::get<0>(t).value == 42);
         assert(std::get<1>(t).value == 43);
     }
     {
         std::tuple<MoveOnly, MoveOnly, MoveOnly> t(std::allocator_arg, A1<int>(),
                                                    MoveOnly(0),
                                                    1, 2);
         assert(std::get<0>(t) == 0);
         assert(std::get<1>(t) == 1);
         assert(std::get<2>(t) == 2);
     }
     {
         using T = DefaultCtorBlowsUp<>;
         std::tuple<T, T, T> t(std::allocator_arg, A1<int>(), T(1), T(2), T(3));
         assert(std::get<0>(t).value == 1);
         assert(std::get<1>(t).value == 2);
         assert(std::get<2>(t).value == 3);
     }
     {
         alloc_first::allocator_constructed = false;
         alloc_last::allocator_constructed = false;
         std::tuple<int, alloc_first, alloc_last> t(std::allocator_arg,
                                                    A1<int>(5), 1, 2, 3);
         assert(std::get<0>(t) == 1);
         assert(alloc_first::allocator_constructed);
         assert(std::get<1>(t) == alloc_first(2));
         assert(alloc_last::allocator_constructed);
         assert(std::get<2>(t) == alloc_last(3));
     }
     {
         // Check that uses-allocator construction is still selected when
         // given a tag type that derives from allocator_arg_t.
         DerivedFromAllocArgT tag;
         alloc_first::allocator_constructed = false;
         alloc_last::allocator_constructed = false;
         std::tuple<int, alloc_first, alloc_last> t(tag,
                                                    A1<int>(5), 1, 2, 3);
         assert(std::get<0>(t) == 1);
         assert(alloc_first::allocator_constructed);
         assert(std::get<1>(t) == alloc_first(2));
         assert(alloc_last::allocator_constructed);
         assert(std::get<2>(t) == alloc_last(3));
     }
     // Stress test the SFINAE on the uses-allocator constructors and
     // ensure that the "reduced-arity-initialization" extension is not offered
     // for these constructors.
     test_uses_allocator_sfinae_evaluation();
 }
	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	// <tuple>

	// template <class... Types> class tuple;

	// template <class Alloc, class... UTypes>
	// tuple(allocator_arg_t, const Alloc& a, UTypes&&...);

	// UNSUPPORTED: c++98, c++03

	#include <tuple>
	#include <cassert>

	#include "MoveOnly.h"
	#include "allocators.h"
	#include "../alloc_first.h"
	#include "../alloc_last.h"

	template <class T = void>
	struct DefaultCtorBlowsUp {
	constexpr DefaultCtorBlowsUp() {
	static_assert(!std::is_same<T, T>::value, "Default Ctor instantiated");
	}

	explicit constexpr DefaultCtorBlowsUp(int x) : value(x) {}

	int value;
	};


	struct DerivedFromAllocArgT : std::allocator_arg_t {};


	// Make sure the _Up... constructor SFINAEs out when the number of initializers
	// is less that the number of elements in the tuple. Previously libc++ would
	// offer these constructers as an extension but they broke conforming code.
	void test_uses_allocator_sfinae_evaluation()
	{
	using BadDefault = DefaultCtorBlowsUp<>;
	{
	typedef std::tuple<MoveOnly, MoveOnly, BadDefault> Tuple;

	static_assert(!std::is_constructible<
	Tuple,
	std::allocator_arg_t, A1<int>, MoveOnly
	>::value, "");

	static_assert(std::is_constructible<
	Tuple,
	std::allocator_arg_t, A1<int>, MoveOnly, MoveOnly, BadDefault
	>::value, "");
	}
	{
	typedef std::tuple<MoveOnly, MoveOnly, BadDefault, BadDefault> Tuple;

	static_assert(!std::is_constructible<
	Tuple,
	std::allocator_arg_t, A1<int>, MoveOnly, MoveOnly
	>::value, "");

	static_assert(std::is_constructible<
	Tuple,
	std::allocator_arg_t, A1<int>, MoveOnly, MoveOnly, BadDefault, BadDefault
	>::value, "");
	}
	}

	struct Explicit {
	int value;
	explicit Explicit(int x) : value(x) {}
	};

	int main()
	{
	{
	std::tuple<Explicit> t{std::allocator_arg, std::allocator<void>{}, 42};
	assert(std::get<0>(t).value == 42);
	}
	{
	std::tuple<MoveOnly> t(std::allocator_arg, A1<int>(), MoveOnly(0));
	assert(std::get<0>(t) == 0);
	}
	{
	using T = DefaultCtorBlowsUp<>;
	std::tuple<T> t(std::allocator_arg, A1<int>(), T(42));
	assert(std::get<0>(t).value == 42);
	}
	{
	std::tuple<MoveOnly, MoveOnly> t(std::allocator_arg, A1<int>(),
	MoveOnly(0), MoveOnly(1));
	assert(std::get<0>(t) == 0);
	assert(std::get<1>(t) == 1);
	}
	{
	using T = DefaultCtorBlowsUp<>;
	std::tuple<T, T> t(std::allocator_arg, A1<int>(), T(42), T(43));
	assert(std::get<0>(t).value == 42);
	assert(std::get<1>(t).value == 43);
	}
	{
	std::tuple<MoveOnly, MoveOnly, MoveOnly> t(std::allocator_arg, A1<int>(),
	MoveOnly(0),
	1, 2);
	assert(std::get<0>(t) == 0);
	assert(std::get<1>(t) == 1);
	assert(std::get<2>(t) == 2);
	}
	{
	using T = DefaultCtorBlowsUp<>;
	std::tuple<T, T, T> t(std::allocator_arg, A1<int>(), T(1), T(2), T(3));
	assert(std::get<0>(t).value == 1);
	assert(std::get<1>(t).value == 2);
	assert(std::get<2>(t).value == 3);
	}
	{
	alloc_first::allocator_constructed = false;
	alloc_last::allocator_constructed = false;
	std::tuple<int, alloc_first, alloc_last> t(std::allocator_arg,
	A1<int>(5), 1, 2, 3);
	assert(std::get<0>(t) == 1);
	assert(alloc_first::allocator_constructed);
	assert(std::get<1>(t) == alloc_first(2));
	assert(alloc_last::allocator_constructed);
	assert(std::get<2>(t) == alloc_last(3));
	}
	{
	// Check that uses-allocator construction is still selected when
	// given a tag type that derives from allocator_arg_t.
	DerivedFromAllocArgT tag;
	alloc_first::allocator_constructed = false;
	alloc_last::allocator_constructed = false;
	std::tuple<int, alloc_first, alloc_last> t(tag,
	A1<int>(5), 1, 2, 3);
	assert(std::get<0>(t) == 1);
	assert(alloc_first::allocator_constructed);
	assert(std::get<1>(t) == alloc_first(2));
	assert(alloc_last::allocator_constructed);
	assert(std::get<2>(t) == alloc_last(3));
	}
	// Stress test the SFINAE on the uses-allocator constructors and
	// ensure that the "reduced-arity-initialization" extension is not offered
	// for these constructors.
	test_uses_allocator_sfinae_evaluation();
	}