test/support/test.support/test_proxy.pass.cpp - llvm-project/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++03, c++11, c++14, c++17

 #include "MoveOnly.h"
 #include "test_iterators.h"

 #include <cassert>

 constexpr void testProxy() {
   // constructor value
   {
     Proxy<int> p{5};
     assert(p.data == 5);
   }

   // constructor reference
   {
     int i = 5;
     Proxy<int&> p{i};
     assert(&p.data == &i);
   }

   // constructor conversion
   {
     int i = 5;
     Proxy<int&> p1{i};
     Proxy<int> p2 = p1;
     assert(p2.data == 5);

     Proxy<int&> p3{p2};
     assert(&(p3.data) == &(p2.data));

     MoveOnly m1{8};
     Proxy<MoveOnly&&> p4 = std::move(m1);

     Proxy<MoveOnly> p5 = std::move(p4);
     assert(p5.data.get() == 8);
   }

   // assignment
   {
     Proxy<int> p1{5};
     Proxy<int> p2{6};
     p1 = p2;
     assert(p1.data == 6);

     MoveOnly m1{8};
     Proxy<MoveOnly&&> p3 = std::move(m1);
     Proxy<MoveOnly> p4{MoveOnly{9}};
     p4 = std::move(p3);
     assert(p4.data.get() == 8);

     // `T` is a reference type.
     int i = 5, j = 6, k = 7, x = 8;
     Proxy<int&> p5{i};
     // `Other` is a prvalue.
     p5 = Proxy<int&>{j};
     assert(p5.data == 6);
     // `Other` is a const lvalue.
     const Proxy<int&> p_ref{k};
     p5 = p_ref;
     assert(p5.data == 7);
     // `Other` is an xvalue.
     Proxy<int&> px{x};
     p5 = std::move(px);
     assert(p5.data == 8);
   }

   // const assignment
   {
     int i = 5;
     int j = 6;
     const Proxy<int&> p1{i};
     const Proxy<int&> p2{j};
     p1 = p2;
     assert(i == 6);

     MoveOnly m1{8};
     MoveOnly m2{9};
     Proxy<MoveOnly&&> p3       = std::move(m1);
     const Proxy<MoveOnly&&> p4 = std::move(m2);
     p4                         = std::move(p3);
     assert(p4.data.get() == 8);
   }

   // compare
   {
     Proxy<int> p1{5};
     Proxy<int> p2{6};
     assert(p1 != p2);
     assert(p1 < p2);

     // Comparing `T` and `T&`.
     int i = 5, j = 6;
     Proxy<int&> p_ref{i};
     Proxy<const int&> p_cref{j};
     assert(p1 == p_ref);
     assert(p2 == p_cref);
     assert(p_ref == p1);
     assert(p_cref == p2);
     assert(p_ref == p_ref);
     assert(p_cref == p_cref);
     assert(p_ref != p_cref);
   }
 }

 static_assert(std::input_iterator<ProxyIterator<cpp20_input_iterator<int*>>>);
 static_assert(!std::forward_iterator<ProxyIterator<cpp20_input_iterator<int*>>>);

 static_assert(std::forward_iterator<ProxyIterator<forward_iterator<int*>>>);
 static_assert(!std::bidirectional_iterator<ProxyIterator<forward_iterator<int*>>>);

 static_assert(std::bidirectional_iterator<ProxyIterator<bidirectional_iterator<int*>>>);
 static_assert(!std::random_access_iterator<ProxyIterator<bidirectional_iterator<int*>>>);

 static_assert(std::random_access_iterator<ProxyIterator<random_access_iterator<int*>>>);
 static_assert(!std::contiguous_iterator<ProxyIterator<random_access_iterator<int*>>>);

 static_assert(std::random_access_iterator<ProxyIterator<contiguous_iterator<int*>>>);
 static_assert(!std::contiguous_iterator<ProxyIterator<contiguous_iterator<int*>>>);

 template <class Iter>
 constexpr void testInputIteratorOperation() {
   int data[] = {1, 2};
   ProxyIterator<Iter> iter{Iter{data}};
   sentinel_wrapper<ProxyIterator<Iter>> sent{ProxyIterator<Iter>{Iter{data + 2}}};

   std::same_as<Proxy<int&>> decltype(auto) result = *iter;
   assert(result.data == 1);
   auto& iter2 = ++iter;
   static_assert(std::is_same_v<decltype(++iter), ProxyIterator<Iter>&>);
   assert(&iter2 == &iter);
   assert((*iter).data == 2);
   ++iter;
   assert(iter == sent);
 }

 template <class Iter>
 constexpr void testForwardIteratorOperation() {
   int data[] = {1, 2};
   ProxyIterator<Iter> iter{Iter{data}};

   std::same_as<ProxyIterator<Iter>> decltype(auto) it2 = iter++;
   assert((*it2).data == 1);
   assert((*iter).data == 2);
 }

 template <class Iter>
 constexpr void testBidirectionalIteratorOperation() {
   int data[] = {1, 2};
   ProxyIterator<Iter> iter{Iter{data}};
   ++iter;
   assert((*iter).data == 2);

   auto& iter2 = --iter;
   static_assert(std::is_same_v<decltype(--iter), ProxyIterator<Iter>&>);
   assert(&iter2 == &iter);
   assert((*iter).data == 1);
   ++iter;

   std::same_as<ProxyIterator<Iter>> decltype(auto) iter3 = iter--;
   assert((*iter).data == 1);
   assert((*iter3).data == 2);
 }

 template <class Iter>
 constexpr void testRandomAccessIteratorOperation() {
   int data[] = {1, 2, 3, 4, 5};
   ProxyIterator<Iter> iter{Iter{data}};

   auto& iter2 = iter += 2;
   static_assert(std::is_same_v<decltype(iter += 2), ProxyIterator<Iter>&>);
   assert(&iter2 == &iter);
   assert((*iter).data == 3);

   auto& iter3 = iter -= 1;
   static_assert(std::is_same_v<decltype(iter -= 1), ProxyIterator<Iter>&>);
   assert(&iter3 == &iter);
   assert((*iter).data == 2);

   std::same_as<Proxy<int&>> decltype(auto) r = iter[2];
   assert(r.data == 4);

   std::same_as<ProxyIterator<Iter>> decltype(auto) iter4 = iter - 1;
   assert((*iter4).data == 1);

   std::same_as<ProxyIterator<Iter>> decltype(auto) iter5 = iter4 + 2;
   assert((*iter5).data == 3);

   std::same_as<ProxyIterator<Iter>> decltype(auto) iter6 = 3 + iter4;
   assert((*iter6).data == 4);

   std::same_as<std::iter_difference_t<Iter>> decltype(auto) n = iter6 - iter5;
   assert(n == 1);

   assert(iter4 < iter5);
   assert(iter3 <= iter5);
   assert(iter5 > iter4);
   assert(iter6 >= iter4);
 }

 constexpr void testProxyIterator() {
   // input iterator operations
   {
     testInputIteratorOperation<cpp20_input_iterator<int*>>();
     testInputIteratorOperation<forward_iterator<int*>>();
     testInputIteratorOperation<bidirectional_iterator<int*>>();
     testInputIteratorOperation<random_access_iterator<int*>>();
     testInputIteratorOperation<contiguous_iterator<int*>>();
   }

   // forward iterator operations
   {
     testForwardIteratorOperation<forward_iterator<int*>>();
     testForwardIteratorOperation<bidirectional_iterator<int*>>();
     testForwardIteratorOperation<random_access_iterator<int*>>();
     testForwardIteratorOperation<contiguous_iterator<int*>>();
   }

   // bidirectional iterator operations
   {
     testBidirectionalIteratorOperation<bidirectional_iterator<int*>>();
     testBidirectionalIteratorOperation<random_access_iterator<int*>>();
     testBidirectionalIteratorOperation<contiguous_iterator<int*>>();
   }

   // random access iterator operations
   {
     testRandomAccessIteratorOperation<random_access_iterator<int*>>();
     testRandomAccessIteratorOperation<contiguous_iterator<int*>>();
   }
 }

 constexpr void testProxyRange() {
   int data[] = {3, 4, 5};
   ProxyRange r{data};
   std::same_as<ProxyIterator<int*>> decltype(auto) it = std::ranges::begin(r);
   assert((*it).data == 3);
   it += 3;
   assert(it == std::ranges::end(r));
 }

 template <class Iter>
 concept StdMoveWorks = requires(std::iter_value_t<Iter> val, Iter iter) { val = std::move(*iter); };

 static_assert(StdMoveWorks<MoveOnly*>);
 static_assert(!StdMoveWorks<ProxyIterator<MoveOnly*>>);

 // although this "works" but it actually creates a copy instead of move
 static_assert(StdMoveWorks<ProxyIterator<int*>>);

 using std::swap;

 template <class Iter>
 concept SwapWorks = requires(Iter iter1, Iter iter2) { swap(*iter1, *iter2); };

 static_assert(SwapWorks<int*>);
 static_assert(!SwapWorks<ProxyIterator<int*>>);

 constexpr bool test() {
   testProxy();
   testProxyIterator();
   testProxyRange();

   // iter_move
   {
     MoveOnly data[] = {5, 6, 7};
     ProxyRange r{data};
     auto it                               = r.begin();
     std::iter_value_t<decltype(it)> moved = std::ranges::iter_move(it);
     assert(moved.data.get() == 5);
   }

   // iter_swap
   {
     MoveOnly data[] = {5, 6, 7};
     ProxyRange r{data};
     auto it1 = r.begin();
     auto it2 = it1 + 2;
     std::ranges::iter_swap(it1, it2);
     assert(data[0].get() == 7);
     assert(data[2].get() == 5);
   }

   return true;
 }

 int main(int, char**) {
   test();
   static_assert(test());

   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++03, c++11, c++14, c++17

	#include "MoveOnly.h"
	#include "test_iterators.h"

	#include <cassert>

	constexpr void testProxy() {
	// constructor value
	{
	Proxy<int> p{5};
	assert(p.data == 5);
	}

	// constructor reference
	{
	int i = 5;
	Proxy<int&> p{i};
	assert(&p.data == &i);
	}

	// constructor conversion
	{
	int i = 5;
	Proxy<int&> p1{i};
	Proxy<int> p2 = p1;
	assert(p2.data == 5);

	Proxy<int&> p3{p2};
	assert(&(p3.data) == &(p2.data));

	MoveOnly m1{8};
	Proxy<MoveOnly&&> p4 = std::move(m1);

	Proxy<MoveOnly> p5 = std::move(p4);
	assert(p5.data.get() == 8);
	}

	// assignment
	{
	Proxy<int> p1{5};
	Proxy<int> p2{6};
	p1 = p2;
	assert(p1.data == 6);

	MoveOnly m1{8};
	Proxy<MoveOnly&&> p3 = std::move(m1);
	Proxy<MoveOnly> p4{MoveOnly{9}};
	p4 = std::move(p3);
	assert(p4.data.get() == 8);

	// `T` is a reference type.
	int i = 5, j = 6, k = 7, x = 8;
	Proxy<int&> p5{i};
	// `Other` is a prvalue.
	p5 = Proxy<int&>{j};
	assert(p5.data == 6);
	// `Other` is a const lvalue.
	const Proxy<int&> p_ref{k};
	p5 = p_ref;
	assert(p5.data == 7);
	// `Other` is an xvalue.
	Proxy<int&> px{x};
	p5 = std::move(px);
	assert(p5.data == 8);
	}

	// const assignment
	{
	int i = 5;
	int j = 6;
	const Proxy<int&> p1{i};
	const Proxy<int&> p2{j};
	p1 = p2;
	assert(i == 6);

	MoveOnly m1{8};
	MoveOnly m2{9};
	Proxy<MoveOnly&&> p3 = std::move(m1);
	const Proxy<MoveOnly&&> p4 = std::move(m2);
	p4 = std::move(p3);
	assert(p4.data.get() == 8);
	}

	// compare
	{
	Proxy<int> p1{5};
	Proxy<int> p2{6};
	assert(p1 != p2);
	assert(p1 < p2);

	// Comparing `T` and `T&`.
	int i = 5, j = 6;
	Proxy<int&> p_ref{i};
	Proxy<const int&> p_cref{j};
	assert(p1 == p_ref);
	assert(p2 == p_cref);
	assert(p_ref == p1);
	assert(p_cref == p2);
	assert(p_ref == p_ref);
	assert(p_cref == p_cref);
	assert(p_ref != p_cref);
	}
	}

	static_assert(std::input_iterator<ProxyIterator<cpp20_input_iterator<int*>>>);
	static_assert(!std::forward_iterator<ProxyIterator<cpp20_input_iterator<int*>>>);

	static_assert(std::forward_iterator<ProxyIterator<forward_iterator<int*>>>);
	static_assert(!std::bidirectional_iterator<ProxyIterator<forward_iterator<int*>>>);

	static_assert(std::bidirectional_iterator<ProxyIterator<bidirectional_iterator<int*>>>);
	static_assert(!std::random_access_iterator<ProxyIterator<bidirectional_iterator<int*>>>);

	static_assert(std::random_access_iterator<ProxyIterator<random_access_iterator<int*>>>);
	static_assert(!std::contiguous_iterator<ProxyIterator<random_access_iterator<int*>>>);

	static_assert(std::random_access_iterator<ProxyIterator<contiguous_iterator<int*>>>);
	static_assert(!std::contiguous_iterator<ProxyIterator<contiguous_iterator<int*>>>);

	template <class Iter>
	constexpr void testInputIteratorOperation() {
	int data[] = {1, 2};
	ProxyIterator<Iter> iter{Iter{data}};
	sentinel_wrapper<ProxyIterator<Iter>> sent{ProxyIterator<Iter>{Iter{data + 2}}};

	std::same_as<Proxy<int&>> decltype(auto) result = *iter;
	assert(result.data == 1);
	auto& iter2 = ++iter;
	static_assert(std::is_same_v<decltype(++iter), ProxyIterator<Iter>&>);
	assert(&iter2 == &iter);
	assert((*iter).data == 2);
	++iter;
	assert(iter == sent);
	}

	template <class Iter>
	constexpr void testForwardIteratorOperation() {
	int data[] = {1, 2};
	ProxyIterator<Iter> iter{Iter{data}};

	std::same_as<ProxyIterator<Iter>> decltype(auto) it2 = iter++;
	assert((*it2).data == 1);
	assert((*iter).data == 2);
	}

	template <class Iter>
	constexpr void testBidirectionalIteratorOperation() {
	int data[] = {1, 2};
	ProxyIterator<Iter> iter{Iter{data}};
	++iter;
	assert((*iter).data == 2);

	auto& iter2 = --iter;
	static_assert(std::is_same_v<decltype(--iter), ProxyIterator<Iter>&>);
	assert(&iter2 == &iter);
	assert((*iter).data == 1);
	++iter;

	std::same_as<ProxyIterator<Iter>> decltype(auto) iter3 = iter--;
	assert((*iter).data == 1);
	assert((*iter3).data == 2);
	}

	template <class Iter>
	constexpr void testRandomAccessIteratorOperation() {
	int data[] = {1, 2, 3, 4, 5};
	ProxyIterator<Iter> iter{Iter{data}};

	auto& iter2 = iter += 2;
	static_assert(std::is_same_v<decltype(iter += 2), ProxyIterator<Iter>&>);
	assert(&iter2 == &iter);
	assert((*iter).data == 3);

	auto& iter3 = iter -= 1;
	static_assert(std::is_same_v<decltype(iter -= 1), ProxyIterator<Iter>&>);
	assert(&iter3 == &iter);
	assert((*iter).data == 2);

	std::same_as<Proxy<int&>> decltype(auto) r = iter[2];
	assert(r.data == 4);

	std::same_as<ProxyIterator<Iter>> decltype(auto) iter4 = iter - 1;
	assert((*iter4).data == 1);

	std::same_as<ProxyIterator<Iter>> decltype(auto) iter5 = iter4 + 2;
	assert((*iter5).data == 3);

	std::same_as<ProxyIterator<Iter>> decltype(auto) iter6 = 3 + iter4;
	assert((*iter6).data == 4);

	std::same_as<std::iter_difference_t<Iter>> decltype(auto) n = iter6 - iter5;
	assert(n == 1);

	assert(iter4 < iter5);
	assert(iter3 <= iter5);
	assert(iter5 > iter4);
	assert(iter6 >= iter4);
	}

	constexpr void testProxyIterator() {
	// input iterator operations
	{
	testInputIteratorOperation<cpp20_input_iterator<int*>>();
	testInputIteratorOperation<forward_iterator<int*>>();
	testInputIteratorOperation<bidirectional_iterator<int*>>();
	testInputIteratorOperation<random_access_iterator<int*>>();
	testInputIteratorOperation<contiguous_iterator<int*>>();
	}

	// forward iterator operations
	{
	testForwardIteratorOperation<forward_iterator<int*>>();
	testForwardIteratorOperation<bidirectional_iterator<int*>>();
	testForwardIteratorOperation<random_access_iterator<int*>>();
	testForwardIteratorOperation<contiguous_iterator<int*>>();
	}

	// bidirectional iterator operations
	{
	testBidirectionalIteratorOperation<bidirectional_iterator<int*>>();
	testBidirectionalIteratorOperation<random_access_iterator<int*>>();
	testBidirectionalIteratorOperation<contiguous_iterator<int*>>();
	}

	// random access iterator operations
	{
	testRandomAccessIteratorOperation<random_access_iterator<int*>>();
	testRandomAccessIteratorOperation<contiguous_iterator<int*>>();
	}
	}

	constexpr void testProxyRange() {
	int data[] = {3, 4, 5};
	ProxyRange r{data};
	std::same_as<ProxyIterator<int*>> decltype(auto) it = std::ranges::begin(r);
	assert((*it).data == 3);
	it += 3;
	assert(it == std::ranges::end(r));
	}

	template <class Iter>
	concept StdMoveWorks = requires(std::iter_value_t<Iter> val, Iter iter) { val = std::move(*iter); };

	static_assert(StdMoveWorks<MoveOnly*>);
	static_assert(!StdMoveWorks<ProxyIterator<MoveOnly*>>);

	// although this "works" but it actually creates a copy instead of move
	static_assert(StdMoveWorks<ProxyIterator<int*>>);

	using std::swap;

	template <class Iter>
	concept SwapWorks = requires(Iter iter1, Iter iter2) { swap(iter1, iter2); };

	static_assert(SwapWorks<int*>);
	static_assert(!SwapWorks<ProxyIterator<int*>>);

	constexpr bool test() {
	testProxy();
	testProxyIterator();
	testProxyRange();

	// iter_move
	{
	MoveOnly data[] = {5, 6, 7};
	ProxyRange r{data};
	auto it = r.begin();
	std::iter_value_t<decltype(it)> moved = std::ranges::iter_move(it);
	assert(moved.data.get() == 5);
	}

	// iter_swap
	{
	MoveOnly data[] = {5, 6, 7};
	ProxyRange r{data};
	auto it1 = r.begin();
	auto it2 = it1 + 2;
	std::ranges::iter_swap(it1, it2);
	assert(data[0].get() == 7);
	assert(data[2].get() == 5);
	}

	return true;
	}

	int main(int, char**) {
	test();
	static_assert(test());

	return 0;
	}