third_party/llvm-project/libcxx/test/std/algorithms/alg.modifying.operations/alg.move/ranges.move.pass.cpp - cobalt - 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
 //
 //===----------------------------------------------------------------------===//

 // <algorithm>

 // UNSUPPORTED: c++03, c++11, c++14, c++17

 // template<input_iterator I, sentinel_for<I> S, weakly_incrementable O>
 //   requires indirectly_movable<I, O>
 //   constexpr ranges::move_result<I, O>
 //     ranges::move(I first, S last, O result);
 // template<input_range R, weakly_incrementable O>
 //   requires indirectly_movable<iterator_t<R>, O>
 //   constexpr ranges::move_result<borrowed_iterator_t<R>, O>
 //     ranges::move(R&& r, O result);

 #include <algorithm>
 #include <array>
 #include <cassert>
 #include <deque>
 #include <ranges>
 #include <vector>

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

 template <class In, class Out = In, class Sent = sentinel_wrapper<In>>
 concept HasMoveIt = requires(In in, Sent sent, Out out) { std::ranges::move(in, sent, out); };

 static_assert(HasMoveIt<int*>);
 static_assert(!HasMoveIt<InputIteratorNotDerivedFrom>);
 static_assert(!HasMoveIt<InputIteratorNotIndirectlyReadable>);
 static_assert(!HasMoveIt<InputIteratorNotInputOrOutputIterator>);
 static_assert(!HasMoveIt<int*, WeaklyIncrementableNotMovable>);
 struct NotIndirectlyMovable {};
 static_assert(!HasMoveIt<int*, NotIndirectlyMovable*>);
 static_assert(!HasMoveIt<int*, int*, SentinelForNotSemiregular>);
 static_assert(!HasMoveIt<int*, int*, SentinelForNotWeaklyEqualityComparableWith>);

 template <class Range, class Out>
 concept HasMoveR = requires(Range range, Out out) { std::ranges::move(range, out); };

 static_assert(HasMoveR<std::array<int, 10>, int*>);
 static_assert(!HasMoveR<InputRangeNotDerivedFrom, int*>);
 static_assert(!HasMoveR<InputRangeNotIndirectlyReadable, int*>);
 static_assert(!HasMoveR<InputRangeNotInputOrOutputIterator, int*>);
 static_assert(!HasMoveR<WeaklyIncrementableNotMovable, int*>);
 static_assert(!HasMoveR<UncheckedRange<NotIndirectlyMovable*>, int*>);
 static_assert(!HasMoveR<InputRangeNotSentinelSemiregular, int*>);
 static_assert(!HasMoveR<InputRangeNotSentinelEqualityComparableWith, int*>);
 static_assert(!HasMoveR<UncheckedRange<int*>, WeaklyIncrementableNotMovable>);

 static_assert(std::is_same_v<std::ranges::move_result<int, long>, std::ranges::in_out_result<int, long>>);

 template <class In, class Out, class Sent, int N>
 constexpr void test(std::array<int, N> in) {
   {
     std::array<int, N> out;
     std::same_as<std::ranges::in_out_result<In, Out>> decltype(auto) ret =
       std::ranges::move(In(in.data()), Sent(In(in.data() + in.size())), Out(out.data()));
     assert(in == out);
     assert(base(ret.in) == in.data() + in.size());
     assert(base(ret.out) == out.data() + out.size());
   }
   {
     std::array<int, N> out;
     auto range = std::ranges::subrange(In(in.data()), Sent(In(in.data() + in.size())));
     std::same_as<std::ranges::in_out_result<In, Out>> decltype(auto) ret =
         std::ranges::move(range, Out(out.data()));
     assert(in == out);
     assert(base(ret.in) == in.data() + in.size());
     assert(base(ret.out) == out.data() + out.size());
   }
 }

 template <class InContainer, class OutContainer, class In, class Out, class Sent = In>
 constexpr void test_containers() {
   {
     InContainer in {1, 2, 3, 4};
     OutContainer out(4);
     std::same_as<std::ranges::in_out_result<In, Out>> auto ret =
       std::ranges::move(In(in.begin()), Sent(In(in.end())), Out(out.begin()));
     assert(std::ranges::equal(in, out));
     assert(base(ret.in) == in.end());
     assert(base(ret.out) == out.end());
   }
   {
     InContainer in {1, 2, 3, 4};
     OutContainer out(4);
     auto range = std::ranges::subrange(In(in.begin()), Sent(In(in.end())));
     std::same_as<std::ranges::in_out_result<In, Out>> auto ret = std::ranges::move(range, Out(out.begin()));
     assert(std::ranges::equal(in, out));
     assert(base(ret.in) == in.end());
     assert(base(ret.out) == out.end());
   }
 }

 template <class In, class Out, class Sent = In>
 constexpr void test_iterators() {
   // simple test
   test<In, Out, Sent, 4>({1, 2, 3, 4});
   // check that an empty range works
   test<In, Out, Sent, 0>({});
 }

 template <template <class> class In, template <class> class Out>
 constexpr void test_sentinels() {
   test_iterators<In<int*>, Out<int*>>();
   test_iterators<In<int*>, Out<int*>, sized_sentinel<In<int*>>>();
   test_iterators<In<int*>, Out<int*>, sentinel_wrapper<In<int*>>>();

   if (!std::is_constant_evaluated()) {
     if constexpr (!std::is_same_v<In<int*>, contiguous_iterator<int*>> &&
                   !std::is_same_v<Out<int*>, contiguous_iterator<int*>> &&
                   !std::is_same_v<In<int*>, ContiguousProxyIterator<int*>> &&
                   !std::is_same_v<Out<int*>, ContiguousProxyIterator<int*>>) {
       test_containers<std::deque<int>,
                       std::deque<int>,
                       In<std::deque<int>::iterator>,
                       Out<std::deque<int>::iterator>>();
       test_containers<std::deque<int>,
                       std::vector<int>,
                       In<std::deque<int>::iterator>,
                       Out<std::vector<int>::iterator>>();
       test_containers<std::vector<int>,
                       std::deque<int>,
                       In<std::vector<int>::iterator>,
                       Out<std::deque<int>::iterator>>();
       test_containers<std::vector<int>,
                       std::vector<int>,
                       In<std::vector<int>::iterator>,
                       Out<std::vector<int>::iterator>>();
     }
   }
 }

 template <template <class> class Out>
 constexpr void test_in_iterators() {
   test_iterators<cpp20_input_iterator<int*>, Out<int*>, sentinel_wrapper<cpp20_input_iterator<int*>>>();
   test_sentinels<forward_iterator, Out>();
   test_sentinels<bidirectional_iterator, Out>();
   test_sentinels<random_access_iterator, Out>();
   test_sentinels<contiguous_iterator, Out>();
   test_sentinels<std::type_identity_t, Out>();
 }

 template <template <class> class Out>
 constexpr void test_proxy_in_iterators() {
   test_iterators<ProxyIterator<cpp20_input_iterator<int*>>,
                  Out<int*>,
                  sentinel_wrapper<ProxyIterator<cpp20_input_iterator<int*>>>>();
   test_sentinels<ForwardProxyIterator, Out>();
   test_sentinels<BidirectionalProxyIterator, Out>();
   test_sentinels<RandomAccessProxyIterator, Out>();
   test_sentinels<ContiguousProxyIterator, Out>();
   test_sentinels<ProxyIterator, Out>();
 }

 struct IteratorWithMoveIter {
   using value_type = int;
   using difference_type = int;
   explicit IteratorWithMoveIter() = default;
   int* ptr;
   constexpr IteratorWithMoveIter(int* ptr_) : ptr(ptr_) {}

   constexpr int& operator*() const; // iterator with iter_move should not be dereferenced

   constexpr IteratorWithMoveIter& operator++() { ++ptr; return *this; }
   constexpr IteratorWithMoveIter operator++(int) { auto ret = *this; ++*this; return ret; }

   friend constexpr int iter_move(const IteratorWithMoveIter&) { return 42; }

   constexpr bool operator==(const IteratorWithMoveIter& other) const = default;
 };

 // cpp17_intput_iterator has a defaulted template argument
 template <class Iter>
 using Cpp17InIter = cpp17_input_iterator<Iter>;

 constexpr bool test() {
   test_in_iterators<cpp17_output_iterator>();
   test_in_iterators<cpp20_output_iterator>();
   test_in_iterators<Cpp17InIter>();
   test_in_iterators<cpp20_input_iterator>();
   test_in_iterators<forward_iterator>();
   test_in_iterators<bidirectional_iterator>();
   test_in_iterators<random_access_iterator>();
   test_in_iterators<contiguous_iterator>();
   test_in_iterators<std::type_identity_t>();

   test_proxy_in_iterators<Cpp20InputProxyIterator>();
   test_proxy_in_iterators<ForwardProxyIterator>();
   test_proxy_in_iterators<BidirectionalProxyIterator>();
   test_proxy_in_iterators<RandomAccessProxyIterator>();
   test_proxy_in_iterators<ContiguousProxyIterator>();
   test_proxy_in_iterators<ProxyIterator>();

   { // check that a move-only type works
     {
       MoveOnly a[] = {1, 2, 3};
       MoveOnly b[3];
       std::ranges::move(a, std::begin(b));
       assert(b[0].get() == 1);
       assert(b[1].get() == 2);
       assert(b[2].get() == 3);
     }
     {
       MoveOnly a[] = {1, 2, 3};
       MoveOnly b[3];
       std::ranges::move(std::begin(a), std::end(a), std::begin(b));
       assert(b[0].get() == 1);
       assert(b[1].get() == 2);
       assert(b[2].get() == 3);
     }
   }

   { // check that a move-only type works for ProxyIterator
     {
       MoveOnly a[] = {1, 2, 3};
       MoveOnly b[3];
       ProxyRange proxyA{a};
       ProxyRange proxyB{b};
       std::ranges::move(proxyA, std::begin(proxyB));
       assert(b[0].get() == 1);
       assert(b[1].get() == 2);
       assert(b[2].get() == 3);
     }
     {
       MoveOnly a[] = {1, 2, 3};
       MoveOnly b[3];
       ProxyRange proxyA{a};
       ProxyRange proxyB{b};
       std::ranges::move(std::begin(proxyA), std::end(proxyA), std::begin(proxyB));
       assert(b[0].get() == 1);
       assert(b[1].get() == 2);
       assert(b[2].get() == 3);
     }
   }

   { // check that ranges::dangling is returned
     std::array<int, 4> out;
     std::same_as<std::ranges::in_out_result<std::ranges::dangling, int*>> decltype(auto) ret =
       std::ranges::move(std::array {1, 2, 3, 4}, out.data());
     assert(ret.out == out.data() + 4);
     assert((out == std::array{1, 2, 3, 4}));
   }

   { // check that an iterator is returned with a borrowing range
     std::array in {1, 2, 3, 4};
     std::array<int, 4> out;
     std::same_as<std::ranges::in_out_result<int*, int*>> decltype(auto) ret =
         std::ranges::move(std::views::all(in), out.data());
     assert(ret.in == in.data() + 4);
     assert(ret.out == out.data() + 4);
     assert(in == out);
   }

   { // check that every element is moved exactly once
     struct MoveOnce {
       bool moved = false;
       constexpr MoveOnce() = default;
       constexpr MoveOnce(const MoveOnce& other) = delete;
       constexpr MoveOnce& operator=(MoveOnce&& other) {
         assert(!other.moved);
         moved = true;
         return *this;
       }
     };
     {
       std::array<MoveOnce, 4> in {};
       std::array<MoveOnce, 4> out {};
       auto ret = std::ranges::move(in.begin(), in.end(), out.begin());
       assert(ret.in == in.end());
       assert(ret.out == out.end());
       assert(std::all_of(out.begin(), out.end(), [](const auto& e) { return e.moved; }));
     }
     {
       std::array<MoveOnce, 4> in {};
       std::array<MoveOnce, 4> out {};
       auto ret = std::ranges::move(in, out.begin());
       assert(ret.in == in.end());
       assert(ret.out == out.end());
       assert(std::all_of(out.begin(), out.end(), [](const auto& e) { return e.moved; }));
     }
   }

   { // check that the range is moved forwards
     struct OnlyForwardsMovable {
       OnlyForwardsMovable* next = nullptr;
       bool canMove = false;
       OnlyForwardsMovable() = default;
       constexpr OnlyForwardsMovable& operator=(OnlyForwardsMovable&&) {
         assert(canMove);
         if (next != nullptr)
           next->canMove = true;
         return *this;
       }
     };
     {
       std::array<OnlyForwardsMovable, 3> in {};
       std::array<OnlyForwardsMovable, 3> out {};
       out[0].next = &out[1];
       out[1].next = &out[2];
       out[0].canMove = true;
       auto ret = std::ranges::move(in.begin(), in.end(), out.begin());
       assert(ret.in == in.end());
       assert(ret.out == out.end());
       assert(out[0].canMove);
       assert(out[1].canMove);
       assert(out[2].canMove);
     }
     {
       std::array<OnlyForwardsMovable, 3> in {};
       std::array<OnlyForwardsMovable, 3> out {};
       out[0].next = &out[1];
       out[1].next = &out[2];
       out[0].canMove = true;
       auto ret = std::ranges::move(in, out.begin());
       assert(ret.in == in.end());
       assert(ret.out == out.end());
       assert(out[0].canMove);
       assert(out[1].canMove);
       assert(out[2].canMove);
     }
   }

   { // check that iter_move is used properly
     {
       int a[] = {1, 2, 3, 4};
       std::array<int, 4> b;
       auto ret = std::ranges::move(IteratorWithMoveIter(a), IteratorWithMoveIter(a + 4), b.data());
       assert(ret.in == a + 4);
       assert(ret.out == b.data() + 4);
       assert((b == std::array {42, 42, 42, 42}));
     }
     {
       int a[] = {1, 2, 3, 4};
       std::array<int, 4> b;
       auto range = std::ranges::subrange(IteratorWithMoveIter(a), IteratorWithMoveIter(a + 4));
       auto ret = std::ranges::move(range, b.data());
       assert(ret.in == a + 4);
       assert(ret.out == b.data() + 4);
       assert((b == std::array {42, 42, 42, 42}));
     }
   }

   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
	//
	//===----------------------------------------------------------------------===//

	// <algorithm>

	// UNSUPPORTED: c++03, c++11, c++14, c++17

	// template<input_iterator I, sentinel_for<I> S, weakly_incrementable O>
	// requires indirectly_movable<I, O>
	// constexpr ranges::move_result<I, O>
	// ranges::move(I first, S last, O result);
	// template<input_range R, weakly_incrementable O>
	// requires indirectly_movable<iterator_t<R>, O>
	// constexpr ranges::move_result<borrowed_iterator_t<R>, O>
	// ranges::move(R&& r, O result);

	#include <algorithm>
	#include <array>
	#include <cassert>
	#include <deque>
	#include <ranges>
	#include <vector>

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

	template <class In, class Out = In, class Sent = sentinel_wrapper<In>>
	concept HasMoveIt = requires(In in, Sent sent, Out out) { std::ranges::move(in, sent, out); };

	static_assert(HasMoveIt<int*>);
	static_assert(!HasMoveIt<InputIteratorNotDerivedFrom>);
	static_assert(!HasMoveIt<InputIteratorNotIndirectlyReadable>);
	static_assert(!HasMoveIt<InputIteratorNotInputOrOutputIterator>);
	static_assert(!HasMoveIt<int*, WeaklyIncrementableNotMovable>);
	struct NotIndirectlyMovable {};
	static_assert(!HasMoveIt<int, NotIndirectlyMovable>);
	static_assert(!HasMoveIt<int, int, SentinelForNotSemiregular>);
	static_assert(!HasMoveIt<int, int, SentinelForNotWeaklyEqualityComparableWith>);

	template <class Range, class Out>
	concept HasMoveR = requires(Range range, Out out) { std::ranges::move(range, out); };

	static_assert(HasMoveR<std::array<int, 10>, int*>);
	static_assert(!HasMoveR<InputRangeNotDerivedFrom, int*>);
	static_assert(!HasMoveR<InputRangeNotIndirectlyReadable, int*>);
	static_assert(!HasMoveR<InputRangeNotInputOrOutputIterator, int*>);
	static_assert(!HasMoveR<WeaklyIncrementableNotMovable, int*>);
	static_assert(!HasMoveR<UncheckedRange<NotIndirectlyMovable>, int>);
	static_assert(!HasMoveR<InputRangeNotSentinelSemiregular, int*>);
	static_assert(!HasMoveR<InputRangeNotSentinelEqualityComparableWith, int*>);
	static_assert(!HasMoveR<UncheckedRange<int*>, WeaklyIncrementableNotMovable>);

	static_assert(std::is_same_v<std::ranges::move_result<int, long>, std::ranges::in_out_result<int, long>>);

	template <class In, class Out, class Sent, int N>
	constexpr void test(std::array<int, N> in) {
	{
	std::array<int, N> out;
	std::same_as<std::ranges::in_out_result<In, Out>> decltype(auto) ret =
	std::ranges::move(In(in.data()), Sent(In(in.data() + in.size())), Out(out.data()));
	assert(in == out);
	assert(base(ret.in) == in.data() + in.size());
	assert(base(ret.out) == out.data() + out.size());
	}
	{
	std::array<int, N> out;
	auto range = std::ranges::subrange(In(in.data()), Sent(In(in.data() + in.size())));
	std::same_as<std::ranges::in_out_result<In, Out>> decltype(auto) ret =
	std::ranges::move(range, Out(out.data()));
	assert(in == out);
	assert(base(ret.in) == in.data() + in.size());
	assert(base(ret.out) == out.data() + out.size());
	}
	}

	template <class InContainer, class OutContainer, class In, class Out, class Sent = In>
	constexpr void test_containers() {
	{
	InContainer in {1, 2, 3, 4};
	OutContainer out(4);
	std::same_as<std::ranges::in_out_result<In, Out>> auto ret =
	std::ranges::move(In(in.begin()), Sent(In(in.end())), Out(out.begin()));
	assert(std::ranges::equal(in, out));
	assert(base(ret.in) == in.end());
	assert(base(ret.out) == out.end());
	}
	{
	InContainer in {1, 2, 3, 4};
	OutContainer out(4);
	auto range = std::ranges::subrange(In(in.begin()), Sent(In(in.end())));
	std::same_as<std::ranges::in_out_result<In, Out>> auto ret = std::ranges::move(range, Out(out.begin()));
	assert(std::ranges::equal(in, out));
	assert(base(ret.in) == in.end());
	assert(base(ret.out) == out.end());
	}
	}

	template <class In, class Out, class Sent = In>
	constexpr void test_iterators() {
	// simple test
	test<In, Out, Sent, 4>({1, 2, 3, 4});
	// check that an empty range works
	test<In, Out, Sent, 0>({});
	}

	template <template <class> class In, template <class> class Out>
	constexpr void test_sentinels() {
	test_iterators<In<int>, Out<int>>();
	test_iterators<In<int>, Out<int>, sized_sentinel<In<int*>>>();
	test_iterators<In<int>, Out<int>, sentinel_wrapper<In<int*>>>();

	if (!std::is_constant_evaluated()) {
	if constexpr (!std::is_same_v<In<int>, contiguous_iterator<int>> &&
	!std::is_same_v<Out<int>, contiguous_iterator<int>> &&
	!std::is_same_v<In<int>, ContiguousProxyIterator<int>> &&
	!std::is_same_v<Out<int>, ContiguousProxyIterator<int>>) {
	test_containers<std::deque<int>,
	std::deque<int>,
	In<std::deque<int>::iterator>,
	Out<std::deque<int>::iterator>>();
	test_containers<std::deque<int>,
	std::vector<int>,
	In<std::deque<int>::iterator>,
	Out<std::vector<int>::iterator>>();
	test_containers<std::vector<int>,
	std::deque<int>,
	In<std::vector<int>::iterator>,
	Out<std::deque<int>::iterator>>();
	test_containers<std::vector<int>,
	std::vector<int>,
	In<std::vector<int>::iterator>,
	Out<std::vector<int>::iterator>>();
	}
	}
	}

	template <template <class> class Out>
	constexpr void test_in_iterators() {
	test_iterators<cpp20_input_iterator<int>, Out<int>, sentinel_wrapper<cpp20_input_iterator<int*>>>();
	test_sentinels<forward_iterator, Out>();
	test_sentinels<bidirectional_iterator, Out>();
	test_sentinels<random_access_iterator, Out>();
	test_sentinels<contiguous_iterator, Out>();
	test_sentinels<std::type_identity_t, Out>();
	}

	template <template <class> class Out>
	constexpr void test_proxy_in_iterators() {
	test_iterators<ProxyIterator<cpp20_input_iterator<int*>>,
	Out<int*>,
	sentinel_wrapper<ProxyIterator<cpp20_input_iterator<int*>>>>();
	test_sentinels<ForwardProxyIterator, Out>();
	test_sentinels<BidirectionalProxyIterator, Out>();
	test_sentinels<RandomAccessProxyIterator, Out>();
	test_sentinels<ContiguousProxyIterator, Out>();
	test_sentinels<ProxyIterator, Out>();
	}

	struct IteratorWithMoveIter {
	using value_type = int;
	using difference_type = int;
	explicit IteratorWithMoveIter() = default;
	int* ptr;
	constexpr IteratorWithMoveIter(int* ptr_) : ptr(ptr_) {}

	constexpr int& operator*() const; // iterator with iter_move should not be dereferenced

	constexpr IteratorWithMoveIter& operator++() { ++ptr; return *this; }
	constexpr IteratorWithMoveIter operator++(int) { auto ret = this; ++this; return ret; }

	friend constexpr int iter_move(const IteratorWithMoveIter&) { return 42; }

	constexpr bool operator==(const IteratorWithMoveIter& other) const = default;
	};

	// cpp17_intput_iterator has a defaulted template argument
	template <class Iter>
	using Cpp17InIter = cpp17_input_iterator<Iter>;

	constexpr bool test() {
	test_in_iterators<cpp17_output_iterator>();
	test_in_iterators<cpp20_output_iterator>();
	test_in_iterators<Cpp17InIter>();
	test_in_iterators<cpp20_input_iterator>();
	test_in_iterators<forward_iterator>();
	test_in_iterators<bidirectional_iterator>();
	test_in_iterators<random_access_iterator>();
	test_in_iterators<contiguous_iterator>();
	test_in_iterators<std::type_identity_t>();

	test_proxy_in_iterators<Cpp20InputProxyIterator>();
	test_proxy_in_iterators<ForwardProxyIterator>();
	test_proxy_in_iterators<BidirectionalProxyIterator>();
	test_proxy_in_iterators<RandomAccessProxyIterator>();
	test_proxy_in_iterators<ContiguousProxyIterator>();
	test_proxy_in_iterators<ProxyIterator>();

	{ // check that a move-only type works
	{
	MoveOnly a[] = {1, 2, 3};
	MoveOnly b[3];
	std::ranges::move(a, std::begin(b));
	assert(b[0].get() == 1);
	assert(b[1].get() == 2);
	assert(b[2].get() == 3);
	}
	{
	MoveOnly a[] = {1, 2, 3};
	MoveOnly b[3];
	std::ranges::move(std::begin(a), std::end(a), std::begin(b));
	assert(b[0].get() == 1);
	assert(b[1].get() == 2);
	assert(b[2].get() == 3);
	}
	}

	{ // check that a move-only type works for ProxyIterator
	{
	MoveOnly a[] = {1, 2, 3};
	MoveOnly b[3];
	ProxyRange proxyA{a};
	ProxyRange proxyB{b};
	std::ranges::move(proxyA, std::begin(proxyB));
	assert(b[0].get() == 1);
	assert(b[1].get() == 2);
	assert(b[2].get() == 3);
	}
	{
	MoveOnly a[] = {1, 2, 3};
	MoveOnly b[3];
	ProxyRange proxyA{a};
	ProxyRange proxyB{b};
	std::ranges::move(std::begin(proxyA), std::end(proxyA), std::begin(proxyB));
	assert(b[0].get() == 1);
	assert(b[1].get() == 2);
	assert(b[2].get() == 3);
	}
	}

	{ // check that ranges::dangling is returned
	std::array<int, 4> out;
	std::same_as<std::ranges::in_out_result<std::ranges::dangling, int*>> decltype(auto) ret =
	std::ranges::move(std::array {1, 2, 3, 4}, out.data());
	assert(ret.out == out.data() + 4);
	assert((out == std::array{1, 2, 3, 4}));
	}

	{ // check that an iterator is returned with a borrowing range
	std::array in {1, 2, 3, 4};
	std::array<int, 4> out;
	std::same_as<std::ranges::in_out_result<int, int>> decltype(auto) ret =
	std::ranges::move(std::views::all(in), out.data());
	assert(ret.in == in.data() + 4);
	assert(ret.out == out.data() + 4);
	assert(in == out);
	}

	{ // check that every element is moved exactly once
	struct MoveOnce {
	bool moved = false;
	constexpr MoveOnce() = default;
	constexpr MoveOnce(const MoveOnce& other) = delete;
	constexpr MoveOnce& operator=(MoveOnce&& other) {
	assert(!other.moved);
	moved = true;
	return *this;
	}
	};
	{
	std::array<MoveOnce, 4> in {};
	std::array<MoveOnce, 4> out {};
	auto ret = std::ranges::move(in.begin(), in.end(), out.begin());
	assert(ret.in == in.end());
	assert(ret.out == out.end());
	assert(std::all_of(out.begin(), out.end(), [](const auto& e) { return e.moved; }));
	}
	{
	std::array<MoveOnce, 4> in {};
	std::array<MoveOnce, 4> out {};
	auto ret = std::ranges::move(in, out.begin());
	assert(ret.in == in.end());
	assert(ret.out == out.end());
	assert(std::all_of(out.begin(), out.end(), [](const auto& e) { return e.moved; }));
	}
	}

	{ // check that the range is moved forwards
	struct OnlyForwardsMovable {
	OnlyForwardsMovable* next = nullptr;
	bool canMove = false;
	OnlyForwardsMovable() = default;
	constexpr OnlyForwardsMovable& operator=(OnlyForwardsMovable&&) {
	assert(canMove);
	if (next != nullptr)
	next->canMove = true;
	return *this;
	}
	};
	{
	std::array<OnlyForwardsMovable, 3> in {};
	std::array<OnlyForwardsMovable, 3> out {};
	out[0].next = &out[1];
	out[1].next = &out[2];
	out[0].canMove = true;
	auto ret = std::ranges::move(in.begin(), in.end(), out.begin());
	assert(ret.in == in.end());
	assert(ret.out == out.end());
	assert(out[0].canMove);
	assert(out[1].canMove);
	assert(out[2].canMove);
	}
	{
	std::array<OnlyForwardsMovable, 3> in {};
	std::array<OnlyForwardsMovable, 3> out {};
	out[0].next = &out[1];
	out[1].next = &out[2];
	out[0].canMove = true;
	auto ret = std::ranges::move(in, out.begin());
	assert(ret.in == in.end());
	assert(ret.out == out.end());
	assert(out[0].canMove);
	assert(out[1].canMove);
	assert(out[2].canMove);
	}
	}

	{ // check that iter_move is used properly
	{
	int a[] = {1, 2, 3, 4};
	std::array<int, 4> b;
	auto ret = std::ranges::move(IteratorWithMoveIter(a), IteratorWithMoveIter(a + 4), b.data());
	assert(ret.in == a + 4);
	assert(ret.out == b.data() + 4);
	assert((b == std::array {42, 42, 42, 42}));
	}
	{
	int a[] = {1, 2, 3, 4};
	std::array<int, 4> b;
	auto range = std::ranges::subrange(IteratorWithMoveIter(a), IteratorWithMoveIter(a + 4));
	auto ret = std::ranges::move(range, b.data());
	assert(ret.in == a + 4);
	assert(ret.out == b.data() + 4);
	assert((b == std::array {42, 42, 42, 42}));
	}
	}

	return true;
	}

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

	return 0;
	}