third_party/llvm-project/libcxx/test/std/utilities/function.objects/func.invoke/invoke_r.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, c++20

 // <functional>

 // template<class R, class F, class... Args>
 // constexpr R invoke_r(F&& f, Args&&... args)              // C++23
 //     noexcept(is_nothrow_invocable_r_v<R, F, Args...>);

 #include <cassert>
 #include <concepts>
 #include <functional>
 #include <type_traits>
 #include <utility> // declval

 template <class R, class F, class ...Args>
 concept can_invoke_r = requires {
     { std::invoke_r<R>(std::declval<F>(), std::declval<Args>()...) } -> std::same_as<R>;
 };

 constexpr bool test() {
     // Make sure basic functionality works (i.e. we actually call the function and
     // return the right result).
     {
         auto f = [](int i) { return i + 3; };
         assert(std::invoke_r<int>(f, 4) == 7);
     }

     // Make sure invoke_r is SFINAE-friendly
     {
         auto f = [](int) -> char* { return nullptr; };
         static_assert( can_invoke_r<char*, decltype(f), int>);
         static_assert( can_invoke_r<void*, decltype(f), int>);
         static_assert( can_invoke_r<void,  decltype(f), int>);   // discard return type
         static_assert(!can_invoke_r<char*, decltype(f), void*>); // wrong argument type
         static_assert(!can_invoke_r<char*, decltype(f)>);        // missing argument
         static_assert(!can_invoke_r<int*,  decltype(f), int>);   // incompatible return type
         static_assert(!can_invoke_r<void,  decltype(f), void*>); // discard return type, invalid argument type
     }

     // Make sure invoke_r has the right noexcept specification
     {
         auto f = [](int) noexcept(true) -> char* { return nullptr; };
         auto g = [](int) noexcept(false) -> char* { return nullptr; };
         struct ConversionNotNoexcept {
             constexpr ConversionNotNoexcept(char*) noexcept(false) { }
         };
         static_assert( noexcept(std::invoke_r<char*>(f, 0)));
         static_assert(!noexcept(std::invoke_r<char*>(g, 0)));                 // function call is not noexcept
         static_assert(!noexcept(std::invoke_r<ConversionNotNoexcept>(f, 0))); // function call is noexcept, conversion isn't
         static_assert(!noexcept(std::invoke_r<ConversionNotNoexcept>(g, 0))); // function call and conversion are both not noexcept
     }

     // Make sure invoke_r works with cv-qualified void return type
     {
         auto check = []<class CV_Void> {
             bool was_called = false;
             auto f = [&](int) -> char* { was_called = true; return nullptr; };
             std::invoke_r<CV_Void>(f, 3);
             assert(was_called);
             static_assert(std::is_void_v<decltype(std::invoke_r<CV_Void>(f, 3))>);
         };
         check.template operator()<void>();
         check.template operator()<void const>();
         // volatile void is deprecated, so not testing it
         // const volatile void is deprecated, so not testing it
     }

     // Make sure invoke_r forwards its arguments
     {
         struct NonCopyable {
             NonCopyable() = default;
             NonCopyable(NonCopyable const&) = delete;
             NonCopyable(NonCopyable&&) = default;
         };
         // Forward argument, with void return
         {
             bool was_called = false;
             auto f = [&](NonCopyable) { was_called = true; };
             std::invoke_r<void>(f, NonCopyable());
             assert(was_called);
         }
         // Forward argument, with non-void return
         {
             bool was_called = false;
             auto f = [&](NonCopyable) -> int { was_called = true; return 0; };
             std::invoke_r<int>(f, NonCopyable());
             assert(was_called);
         }
         // Forward function object, with void return
         {
             struct MoveOnlyVoidFunction {
                 bool& was_called;
                 constexpr void operator()() && { was_called = true; }
             };
             bool was_called = false;
             std::invoke_r<void>(MoveOnlyVoidFunction{was_called});
             assert(was_called);
         }
         // Forward function object, with non-void return
         {
             struct MoveOnlyIntFunction {
                 bool& was_called;
                 constexpr int operator()() && { was_called = true; return 0; }
             };
             bool was_called = false;
             std::invoke_r<int>(MoveOnlyIntFunction{was_called});
             assert(was_called);
         }
     }

     // Make sure invoke_r performs an implicit conversion of the result
     {
         struct Convertible {
             constexpr operator int() const { return 42; }
         };
         auto f = []() -> Convertible { return Convertible{}; };
         int result = std::invoke_r<int>(f);
         assert(result == 42);
     }

     // Note: We don't test that `std::invoke_r` works with all kinds of callable types here,
     //       since that is extensively tested in the `std::invoke` tests.

     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, c++20

	// <functional>

	// template<class R, class F, class... Args>
	// constexpr R invoke_r(F&& f, Args&&... args) // C++23
	// noexcept(is_nothrow_invocable_r_v<R, F, Args...>);

	#include <cassert>
	#include <concepts>
	#include <functional>
	#include <type_traits>
	#include <utility> // declval

	template <class R, class F, class ...Args>
	concept can_invoke_r = requires {
	{ std::invoke_r<R>(std::declval<F>(), std::declval<Args>()...) } -> std::same_as<R>;
	};

	constexpr bool test() {
	// Make sure basic functionality works (i.e. we actually call the function and
	// return the right result).
	{
	auto f = [](int i) { return i + 3; };
	assert(std::invoke_r<int>(f, 4) == 7);
	}

	// Make sure invoke_r is SFINAE-friendly
	{
	auto f = [](int) -> char* { return nullptr; };
	static_assert( can_invoke_r<char*, decltype(f), int>);
	static_assert( can_invoke_r<void*, decltype(f), int>);
	static_assert( can_invoke_r<void, decltype(f), int>); // discard return type
	static_assert(!can_invoke_r<char, decltype(f), void>); // wrong argument type
	static_assert(!can_invoke_r<char*, decltype(f)>); // missing argument
	static_assert(!can_invoke_r<int*, decltype(f), int>); // incompatible return type
	static_assert(!can_invoke_r<void, decltype(f), void*>); // discard return type, invalid argument type
	}

	// Make sure invoke_r has the right noexcept specification
	{
	auto f = [](int) noexcept(true) -> char* { return nullptr; };
	auto g = [](int) noexcept(false) -> char* { return nullptr; };
	struct ConversionNotNoexcept {
	constexpr ConversionNotNoexcept(char*) noexcept(false) { }
	};
	static_assert( noexcept(std::invoke_r<char*>(f, 0)));
	static_assert(!noexcept(std::invoke_r<char*>(g, 0))); // function call is not noexcept
	static_assert(!noexcept(std::invoke_r<ConversionNotNoexcept>(f, 0))); // function call is noexcept, conversion isn't
	static_assert(!noexcept(std::invoke_r<ConversionNotNoexcept>(g, 0))); // function call and conversion are both not noexcept
	}

	// Make sure invoke_r works with cv-qualified void return type
	{
	auto check = []<class CV_Void> {
	bool was_called = false;
	auto f = [&](int) -> char* { was_called = true; return nullptr; };
	std::invoke_r<CV_Void>(f, 3);
	assert(was_called);
	static_assert(std::is_void_v<decltype(std::invoke_r<CV_Void>(f, 3))>);
	};
	check.template operator()<void>();
	check.template operator()<void const>();
	// volatile void is deprecated, so not testing it
	// const volatile void is deprecated, so not testing it
	}

	// Make sure invoke_r forwards its arguments
	{
	struct NonCopyable {
	NonCopyable() = default;
	NonCopyable(NonCopyable const&) = delete;
	NonCopyable(NonCopyable&&) = default;
	};
	// Forward argument, with void return
	{
	bool was_called = false;
	auto f = [&](NonCopyable) { was_called = true; };
	std::invoke_r<void>(f, NonCopyable());
	assert(was_called);
	}
	// Forward argument, with non-void return
	{
	bool was_called = false;
	auto f = [&](NonCopyable) -> int { was_called = true; return 0; };
	std::invoke_r<int>(f, NonCopyable());
	assert(was_called);
	}
	// Forward function object, with void return
	{
	struct MoveOnlyVoidFunction {
	bool& was_called;
	constexpr void operator()() && { was_called = true; }
	};
	bool was_called = false;
	std::invoke_r<void>(MoveOnlyVoidFunction{was_called});
	assert(was_called);
	}
	// Forward function object, with non-void return
	{
	struct MoveOnlyIntFunction {
	bool& was_called;
	constexpr int operator()() && { was_called = true; return 0; }
	};
	bool was_called = false;
	std::invoke_r<int>(MoveOnlyIntFunction{was_called});
	assert(was_called);
	}
	}

	// Make sure invoke_r performs an implicit conversion of the result
	{
	struct Convertible {
	constexpr operator int() const { return 42; }
	};
	auto f = []() -> Convertible { return Convertible{}; };
	int result = std::invoke_r<int>(f);
	assert(result == 42);
	}

	// Note: We don't test that `std::invoke_r` works with all kinds of callable types here,
	// since that is extensively tested in the `std::invoke` tests.

	return true;
	}

	int main(int, char**) {
	test();
	static_assert(test());
	return 0;
	}