third_party/llvm-project/libcxx/test/std/algorithms/alg.modifying.operations/alg.transform/ranges.transform.binary.range.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
 //
 //===----------------------------------------------------------------------===//

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

 // <algorithm>

 // template<input_range R1, input_range R2, weakly_incrementable O,
 //          copy_constructible F, class Proj1 = identity, class Proj2 = identity>
 //   requires indirectly_writable<O, indirect_result_t<F&, projected<iterator_t<R1>, Proj1>,
 //                                          projected<iterator_t<R2>, Proj2>>>
 //   constexpr ranges::binary_transform_result<borrowed_iterator_t<R1>, borrowed_iterator_t<R2>, O>
 //     ranges::transform(R1&& r1, R2&& r2, O result,
 //                       F binary_op, Proj1 proj1 = {}, Proj2 proj2 = {});

 // The iterator overloads are tested in ranges.tranform.binary.iterator.pass.cpp.

 #include <algorithm>
 #include <array>
 #include <cassert>
 #include <functional>
 #include <ranges>

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

 struct BinaryFunc {
   int operator()(int, int);
 };

 template <class Range>
 concept HasTranformR = requires(Range r, int* out) { std::ranges::transform(r, r, out, BinaryFunc{}); };

 static_assert(HasTranformR<std::array<int, 1>>);
 static_assert(!HasTranformR<int>);
 static_assert(!HasTranformR<InputRangeNotDerivedFrom>);
 static_assert(!HasTranformR<InputRangeNotIndirectlyReadable>);
 static_assert(!HasTranformR<InputRangeNotInputOrOutputIterator>);
 static_assert(!HasTranformR<InputRangeNotSentinelSemiregular>);
 static_assert(!HasTranformR<InputRangeNotSentinelEqualityComparableWith>);

 template <class It>
 concept HasTransformOut = requires(int* it, int* sent, It out, std::array<int, 2> range) {
   std::ranges::transform(range, range, out, BinaryFunc{});
 };
 static_assert(HasTransformOut<int*>);
 static_assert(!HasTransformOut<WeaklyIncrementableNotMovable>);

 // check indirectly_readable
 static_assert(HasTransformOut<char*>);
 static_assert(!HasTransformOut<int**>);

 struct MoveOnlyFunctor {
   MoveOnlyFunctor(const MoveOnlyFunctor&) = delete;
   MoveOnlyFunctor(MoveOnlyFunctor&&)      = default;
   int operator()(int, int);
 };

 template <class Func>
 concept HasTransformFuncBinary = requires(int* it, int* sent, int* out, std::array<int, 2> range, Func func) {
   std::ranges::transform(range, range, out, func);
 };
 static_assert(HasTransformFuncBinary<BinaryFunc>);
 static_assert(!HasTransformFuncBinary<MoveOnlyFunctor>);

 static_assert(std::is_same_v<std::ranges::binary_transform_result<int, long, char>,
                              std::ranges::in_in_out_result<int, long, char>>);

 // clang-format off
 template <class In1, class In2, class Out, class Sent1, class Sent2>
 constexpr bool test_iterators() {
   { // simple
     int a[] = {1, 2, 3, 4, 5};
     int b[] = {5, 4, 3, 2, 1};
     int c[5];

     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 5)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 5)));

     std::same_as<std::ranges::in_in_out_result<In1, In2, Out>> decltype(auto) ret = std::ranges::transform(
         range1, range2, Out(c), [](int i, int j) { return i + j; });

     assert((std::to_array(c) == std::array{6, 6, 6, 6, 6}));
     assert(base(ret.in1) == a + 5);
     assert(base(ret.in2) == b + 5);
     assert(base(ret.out) == c + 5);
   }

   { // first range empty
     int a[] = {};
     int b[] = {5, 4, 3, 2, 1};
     int c[5];

     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 5)));

     auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

     assert(base(ret.in1) == a);
     assert(base(ret.in2) == b);
     assert(base(ret.out) == c);
   }

   { // second range empty
     int a[] = {5, 4, 3, 2, 1};
     int b[] = {};
     int c[5];

     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 5)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b)));

     auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

     assert(base(ret.in1) == a);
     assert(base(ret.in2) == b);
     assert(base(ret.out) == c);
   }

   { // both ranges empty
     int a[] = {};
     int b[] = {};
     int c[5];

     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b)));

     auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

     assert(base(ret.in1) == a);
     assert(base(ret.in2) == b);
     assert(base(ret.out) == c);
   }

   { // first range one element
     int a[] = {2};
     int b[] = {5, 4, 3, 2, 1};
     int c[5];

     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 1)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 5)));

     auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

     assert(c[0] == 7);
     assert(base(ret.in1) == a + 1);
     assert(base(ret.in2) == b + 1);
     assert(base(ret.out) == c + 1);
   }

   { // second range contains one element
     int a[] = {5, 4, 3, 2, 1};
     int b[] = {4};
     int c[5];

     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 5)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 1)));

     auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

     assert(c[0] == 9);
     assert(base(ret.in1) == a + 1);
     assert(base(ret.in2) == b + 1);
     assert(base(ret.out) == c + 1);
   }

   { // check that the transform function and projection call counts are correct
     int predCount = 0;
     int proj1Count = 0;
     int proj2Count = 0;
     auto pred = [&](int, int) { ++predCount; return 1; };
     auto proj1 = [&](int) { ++proj1Count; return 0; };
     auto proj2 = [&](int) { ++proj2Count; return 0; };
     int a[] = {1, 2, 3, 4};
     int b[] = {1, 2, 3, 4};
     std::array<int, 4> c;
     auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 4)));
     auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 4)));
     std::ranges::transform(range1, range2, Out(c.data()), pred, proj1, proj2);
     assert(predCount == 4);
     assert(proj1Count == 4);
     assert(proj2Count == 4);
     assert((c == std::array{1, 1, 1, 1}));
   }

   return true;
 }
 // clang-format on

 template <class In2, class Out, class Sent2 = In2>
 constexpr void test_iterator_in1() {
   test_iterators<cpp17_input_iterator<int*>, In2, Out, sentinel_wrapper<cpp17_input_iterator<int*>>, Sent2>();
   test_iterators<cpp20_input_iterator<int*>, In2, Out, sentinel_wrapper<cpp20_input_iterator<int*>>, Sent2>();
   test_iterators<forward_iterator<int*>, In2, Out, forward_iterator<int*>, Sent2>();
   test_iterators<bidirectional_iterator<int*>, In2, Out, bidirectional_iterator<int*>, Sent2>();
   test_iterators<random_access_iterator<int*>, In2, Out, random_access_iterator<int*>, Sent2>();
   test_iterators<contiguous_iterator<int*>, In2, Out, contiguous_iterator<int*>, Sent2>();
   test_iterators<int*, In2, Out, int*, Sent2>();
   // static_asserting here to avoid hitting the constant evaluation step limit
   static_assert(test_iterators<cpp17_input_iterator<int*>, In2, Out, sentinel_wrapper<cpp17_input_iterator<int*>>, Sent2>());
   static_assert(test_iterators<cpp20_input_iterator<int*>, In2, Out, sentinel_wrapper<cpp20_input_iterator<int*>>, Sent2>());
   static_assert(test_iterators<forward_iterator<int*>, In2, Out, forward_iterator<int*>, Sent2>());
   static_assert(test_iterators<bidirectional_iterator<int*>, In2, Out, bidirectional_iterator<int*>, Sent2>());
   static_assert(test_iterators<random_access_iterator<int*>, In2, Out, random_access_iterator<int*>, Sent2>());
   static_assert(test_iterators<contiguous_iterator<int*>, In2, Out, contiguous_iterator<int*>, Sent2>());
   static_assert(test_iterators<int*, In2, Out, int*, Sent2>());
 }

 template <class Out>
 constexpr void test_iterators_in1_in2() {
   test_iterator_in1<cpp17_input_iterator<int*>, Out, sentinel_wrapper<cpp17_input_iterator<int*>>>();
   test_iterator_in1<cpp20_input_iterator<int*>, Out, sentinel_wrapper<cpp20_input_iterator<int*>>>();
   test_iterator_in1<forward_iterator<int*>, Out>();
   test_iterator_in1<bidirectional_iterator<int*>, Out>();
   test_iterator_in1<random_access_iterator<int*>, Out>();
   test_iterator_in1<contiguous_iterator<int*>, Out>();
   test_iterator_in1<int*, Out>();
 }

 constexpr bool test() {
   test_iterators_in1_in2<cpp17_output_iterator<int*>>();
   test_iterators_in1_in2<cpp20_output_iterator<int*>>();
   test_iterators_in1_in2<forward_iterator<int*>>();
   test_iterators_in1_in2<bidirectional_iterator<int*>>();
   test_iterators_in1_in2<random_access_iterator<int*>>();
   test_iterators_in1_in2<contiguous_iterator<int*>>();
   test_iterators_in1_in2<int*>();

   { // check that std::ranges::dangling is returned properly
     {
       int b[] = {2, 5, 4, 3, 1};
       std::array<int, 5> c;
       std::same_as<std::ranges::in_in_out_result<std::ranges::dangling, int*, int*>> auto ret =
           std::ranges::transform(std::array{1, 2, 3, 5, 4}, b, c.data(), [](int i, int j) { return i * j; });
       assert((c == std::array{2, 10, 12, 15, 4}));
       assert(ret.in2 == b + 5);
       assert(ret.out == c.data() + c.size());
     }
     {
       int a[] = {2, 5, 4, 3, 1, 4, 5, 6};
       std::array<int, 8> c;
       std::same_as<std::ranges::in_in_out_result<int*, std::ranges::dangling, int*>> auto ret =
           std::ranges::transform(a, std::array{1, 2, 3, 5, 4, 5, 6, 7}, c.data(), [](int i, int j) { return i * j; });
       assert((c == std::array{2, 10, 12, 15, 4, 20, 30, 42}));
       assert(ret.in1 == a + 8);
       assert(ret.out == c.data() + c.size());
     }
     {
       std::array<int, 3> c;
       std::same_as<std::ranges::in_in_out_result<std::ranges::dangling, std::ranges::dangling, int*>> auto ret =
           std::ranges::transform(std::array{4, 4, 4}, std::array{4, 4, 4}, c.data(), [](int i, int j) { return i * j; });
       assert((c == std::array{16, 16, 16}));
       assert(ret.out == c.data() + c.size());
     }
   }

   { // check that returning another type from the projection works
     struct S { int i; int other; };
     S a[] = { S{0, 0}, S{1, 0}, S{3, 0}, S{10, 0} };
     S b[] = { S{0, 10}, S{1, 20}, S{3, 30}, S{10, 40} };
     std::array<int, 4> c;
     std::ranges::transform(a, b, c.begin(), [](S s1, S s2) { return s1.i + s2.other; });
     assert((c == std::array{10, 21, 33, 50}));
   }

   { // check that std::invoke is used
     struct S { int i; };
     S a[] = { S{1}, S{3}, S{2} };
     S b[] = { S{2}, S{5}, S{3} };
     std::array<int, 3> c;
     auto ret = std::ranges::transform(a, b, c.data(), [](int i, int j) { return i + j + 2; }, &S::i, &S::i);
     assert((c == std::array{5, 10, 7}));
     assert(ret.out == c.data() + 3);
   }

   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

	// <algorithm>

	// template<input_range R1, input_range R2, weakly_incrementable O,
	// copy_constructible F, class Proj1 = identity, class Proj2 = identity>
	// requires indirectly_writable<O, indirect_result_t<F&, projected<iterator_t<R1>, Proj1>,
	// projected<iterator_t<R2>, Proj2>>>
	// constexpr ranges::binary_transform_result<borrowed_iterator_t<R1>, borrowed_iterator_t<R2>, O>
	// ranges::transform(R1&& r1, R2&& r2, O result,
	// F binary_op, Proj1 proj1 = {}, Proj2 proj2 = {});

	// The iterator overloads are tested in ranges.tranform.binary.iterator.pass.cpp.

	#include <algorithm>
	#include <array>
	#include <cassert>
	#include <functional>
	#include <ranges>

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

	struct BinaryFunc {
	int operator()(int, int);
	};

	template <class Range>
	concept HasTranformR = requires(Range r, int* out) { std::ranges::transform(r, r, out, BinaryFunc{}); };

	static_assert(HasTranformR<std::array<int, 1>>);
	static_assert(!HasTranformR<int>);
	static_assert(!HasTranformR<InputRangeNotDerivedFrom>);
	static_assert(!HasTranformR<InputRangeNotIndirectlyReadable>);
	static_assert(!HasTranformR<InputRangeNotInputOrOutputIterator>);
	static_assert(!HasTranformR<InputRangeNotSentinelSemiregular>);
	static_assert(!HasTranformR<InputRangeNotSentinelEqualityComparableWith>);

	template <class It>
	concept HasTransformOut = requires(int* it, int* sent, It out, std::array<int, 2> range) {
	std::ranges::transform(range, range, out, BinaryFunc{});
	};
	static_assert(HasTransformOut<int*>);
	static_assert(!HasTransformOut<WeaklyIncrementableNotMovable>);

	// check indirectly_readable
	static_assert(HasTransformOut<char*>);
	static_assert(!HasTransformOut<int**>);

	struct MoveOnlyFunctor {
	MoveOnlyFunctor(const MoveOnlyFunctor&) = delete;
	MoveOnlyFunctor(MoveOnlyFunctor&&) = default;
	int operator()(int, int);
	};

	template <class Func>
	concept HasTransformFuncBinary = requires(int* it, int* sent, int* out, std::array<int, 2> range, Func func) {
	std::ranges::transform(range, range, out, func);
	};
	static_assert(HasTransformFuncBinary<BinaryFunc>);
	static_assert(!HasTransformFuncBinary<MoveOnlyFunctor>);

	static_assert(std::is_same_v<std::ranges::binary_transform_result<int, long, char>,
	std::ranges::in_in_out_result<int, long, char>>);

	// clang-format off
	template <class In1, class In2, class Out, class Sent1, class Sent2>
	constexpr bool test_iterators() {
	{ // simple
	int a[] = {1, 2, 3, 4, 5};
	int b[] = {5, 4, 3, 2, 1};
	int c[5];

	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 5)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 5)));

	std::same_as<std::ranges::in_in_out_result<In1, In2, Out>> decltype(auto) ret = std::ranges::transform(
	range1, range2, Out(c), [](int i, int j) { return i + j; });

	assert((std::to_array(c) == std::array{6, 6, 6, 6, 6}));
	assert(base(ret.in1) == a + 5);
	assert(base(ret.in2) == b + 5);
	assert(base(ret.out) == c + 5);
	}

	{ // first range empty
	int a[] = {};
	int b[] = {5, 4, 3, 2, 1};
	int c[5];

	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 5)));

	auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

	assert(base(ret.in1) == a);
	assert(base(ret.in2) == b);
	assert(base(ret.out) == c);
	}

	{ // second range empty
	int a[] = {5, 4, 3, 2, 1};
	int b[] = {};
	int c[5];

	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 5)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b)));

	auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

	assert(base(ret.in1) == a);
	assert(base(ret.in2) == b);
	assert(base(ret.out) == c);
	}

	{ // both ranges empty
	int a[] = {};
	int b[] = {};
	int c[5];

	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b)));

	auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

	assert(base(ret.in1) == a);
	assert(base(ret.in2) == b);
	assert(base(ret.out) == c);
	}

	{ // first range one element
	int a[] = {2};
	int b[] = {5, 4, 3, 2, 1};
	int c[5];

	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 1)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 5)));

	auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

	assert(c[0] == 7);
	assert(base(ret.in1) == a + 1);
	assert(base(ret.in2) == b + 1);
	assert(base(ret.out) == c + 1);
	}

	{ // second range contains one element
	int a[] = {5, 4, 3, 2, 1};
	int b[] = {4};
	int c[5];

	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 5)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 1)));

	auto ret = std::ranges::transform(range1, range2, Out(c), [](int i, int j) { return i + j; });

	assert(c[0] == 9);
	assert(base(ret.in1) == a + 1);
	assert(base(ret.in2) == b + 1);
	assert(base(ret.out) == c + 1);
	}

	{ // check that the transform function and projection call counts are correct
	int predCount = 0;
	int proj1Count = 0;
	int proj2Count = 0;
	auto pred = [&](int, int) { ++predCount; return 1; };
	auto proj1 = [&](int) { ++proj1Count; return 0; };
	auto proj2 = [&](int) { ++proj2Count; return 0; };
	int a[] = {1, 2, 3, 4};
	int b[] = {1, 2, 3, 4};
	std::array<int, 4> c;
	auto range1 = std::ranges::subrange(In1(a), Sent1(In1(a + 4)));
	auto range2 = std::ranges::subrange(In2(b), Sent2(In2(b + 4)));
	std::ranges::transform(range1, range2, Out(c.data()), pred, proj1, proj2);
	assert(predCount == 4);
	assert(proj1Count == 4);
	assert(proj2Count == 4);
	assert((c == std::array{1, 1, 1, 1}));
	}

	return true;
	}
	// clang-format on

	template <class In2, class Out, class Sent2 = In2>
	constexpr void test_iterator_in1() {
	test_iterators<cpp17_input_iterator<int>, In2, Out, sentinel_wrapper<cpp17_input_iterator<int>>, Sent2>();
	test_iterators<cpp20_input_iterator<int>, In2, Out, sentinel_wrapper<cpp20_input_iterator<int>>, Sent2>();
	test_iterators<forward_iterator<int>, In2, Out, forward_iterator<int>, Sent2>();
	test_iterators<bidirectional_iterator<int>, In2, Out, bidirectional_iterator<int>, Sent2>();
	test_iterators<random_access_iterator<int>, In2, Out, random_access_iterator<int>, Sent2>();
	test_iterators<contiguous_iterator<int>, In2, Out, contiguous_iterator<int>, Sent2>();
	test_iterators<int, In2, Out, int, Sent2>();
	// static_asserting here to avoid hitting the constant evaluation step limit
	static_assert(test_iterators<cpp17_input_iterator<int>, In2, Out, sentinel_wrapper<cpp17_input_iterator<int>>, Sent2>());
	static_assert(test_iterators<cpp20_input_iterator<int>, In2, Out, sentinel_wrapper<cpp20_input_iterator<int>>, Sent2>());
	static_assert(test_iterators<forward_iterator<int>, In2, Out, forward_iterator<int>, Sent2>());
	static_assert(test_iterators<bidirectional_iterator<int>, In2, Out, bidirectional_iterator<int>, Sent2>());
	static_assert(test_iterators<random_access_iterator<int>, In2, Out, random_access_iterator<int>, Sent2>());
	static_assert(test_iterators<contiguous_iterator<int>, In2, Out, contiguous_iterator<int>, Sent2>());
	static_assert(test_iterators<int, In2, Out, int, Sent2>());
	}

	template <class Out>
	constexpr void test_iterators_in1_in2() {
	test_iterator_in1<cpp17_input_iterator<int>, Out, sentinel_wrapper<cpp17_input_iterator<int>>>();
	test_iterator_in1<cpp20_input_iterator<int>, Out, sentinel_wrapper<cpp20_input_iterator<int>>>();
	test_iterator_in1<forward_iterator<int*>, Out>();
	test_iterator_in1<bidirectional_iterator<int*>, Out>();
	test_iterator_in1<random_access_iterator<int*>, Out>();
	test_iterator_in1<contiguous_iterator<int*>, Out>();
	test_iterator_in1<int*, Out>();
	}

	constexpr bool test() {
	test_iterators_in1_in2<cpp17_output_iterator<int*>>();
	test_iterators_in1_in2<cpp20_output_iterator<int*>>();
	test_iterators_in1_in2<forward_iterator<int*>>();
	test_iterators_in1_in2<bidirectional_iterator<int*>>();
	test_iterators_in1_in2<random_access_iterator<int*>>();
	test_iterators_in1_in2<contiguous_iterator<int*>>();
	test_iterators_in1_in2<int*>();

	{ // check that std::ranges::dangling is returned properly
	{
	int b[] = {2, 5, 4, 3, 1};
	std::array<int, 5> c;
	std::same_as<std::ranges::in_in_out_result<std::ranges::dangling, int, int>> auto ret =
	std::ranges::transform(std::array{1, 2, 3, 5, 4}, b, c.data(), [](int i, int j) { return i * j; });
	assert((c == std::array{2, 10, 12, 15, 4}));
	assert(ret.in2 == b + 5);
	assert(ret.out == c.data() + c.size());
	}
	{
	int a[] = {2, 5, 4, 3, 1, 4, 5, 6};
	std::array<int, 8> c;
	std::same_as<std::ranges::in_in_out_result<int, std::ranges::dangling, int>> auto ret =
	std::ranges::transform(a, std::array{1, 2, 3, 5, 4, 5, 6, 7}, c.data(), [](int i, int j) { return i * j; });
	assert((c == std::array{2, 10, 12, 15, 4, 20, 30, 42}));
	assert(ret.in1 == a + 8);
	assert(ret.out == c.data() + c.size());
	}
	{
	std::array<int, 3> c;
	std::same_as<std::ranges::in_in_out_result<std::ranges::dangling, std::ranges::dangling, int*>> auto ret =
	std::ranges::transform(std::array{4, 4, 4}, std::array{4, 4, 4}, c.data(), [](int i, int j) { return i * j; });
	assert((c == std::array{16, 16, 16}));
	assert(ret.out == c.data() + c.size());
	}
	}

	{ // check that returning another type from the projection works
	struct S { int i; int other; };
	S a[] = { S{0, 0}, S{1, 0}, S{3, 0}, S{10, 0} };
	S b[] = { S{0, 10}, S{1, 20}, S{3, 30}, S{10, 40} };
	std::array<int, 4> c;
	std::ranges::transform(a, b, c.begin(), [](S s1, S s2) { return s1.i + s2.other; });
	assert((c == std::array{10, 21, 33, 50}));
	}

	{ // check that std::invoke is used
	struct S { int i; };
	S a[] = { S{1}, S{3}, S{2} };
	S b[] = { S{2}, S{5}, S{3} };
	std::array<int, 3> c;
	auto ret = std::ranges::transform(a, b, c.data(), [](int i, int j) { return i + j + 2; }, &S::i, &S::i);
	assert((c == std::array{5, 10, 7}));
	assert(ret.out == c.data() + 3);
	}

	return true;
	}

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

	return 0;
	}