libstdc++-v3/testsuite/30_threads/async/async.cc - gcc - Git at Google

 // { dg-do run }
 // { dg-additional-options "-pthread" { target pthread } }
 // { dg-require-effective-target c++11 }
 // { dg-require-gthreads "" }

 // Copyright (C) 2010-2021 Free Software Foundation, Inc.
 //
 // This file is part of the GNU ISO C++ Library.  This library is free
 // software; you can redistribute it and/or modify it under the
 // terms of the GNU General Public License as published by the
 // Free Software Foundation; either version 3, or (at your option)
 // any later version.

 // This library is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU General Public License for more details.

 // You should have received a copy of the GNU General Public License along
 // with this library; see the file COPYING3.  If not see
 // <http://www.gnu.org/licenses/>.


 #include <future>
 #include <thread>
 #include <testsuite_hooks.h>

 using namespace std;

 void work(mutex& m)
 {
   unique_lock<mutex> l(m);
 }

 void test01()
 {
   mutex m;
   unique_lock<mutex> l(m);
   future<void> f1 = async(launch::async, &work, ref(m));
   l.unlock();  // allow async thread to proceed
   f1.get();    // wait for it to finish
 }

 void test02()
 {
   mutex m;
   unique_lock<mutex> l(m);
   future<void> f1 = async(launch::async, &work, ref(m));
   std::future_status status;
   status = f1.wait_for(std::chrono::milliseconds(1));
   VERIFY( status == std::future_status::timeout );
   status = f1.wait_until(std::chrono::system_clock::now());
   VERIFY( status == std::future_status::timeout );
   status = f1.wait_until(std::chrono::steady_clock::now());
   VERIFY( status == std::future_status::timeout );
   l.unlock();  // allow async thread to proceed
   f1.wait();   // wait for it to finish
   status = f1.wait_for(std::chrono::milliseconds(0));
   VERIFY( status == std::future_status::ready );
   status = f1.wait_until(std::chrono::system_clock::now());
   VERIFY( status == std::future_status::ready );
   status = f1.wait_until(std::chrono::steady_clock::now());
   VERIFY( status == std::future_status::ready );
 }

 // This clock behaves exactly the same as steady_clock, but it is not
 // steady_clock which means that the generic clock overload of
 // future::wait_until is used.
 struct steady_clock_copy
 {
   using rep = std::chrono::steady_clock::rep;
   using period = std::chrono::steady_clock::period;
   using duration = std::chrono::steady_clock::duration;
   using time_point = std::chrono::time_point<steady_clock_copy, duration>;
   static constexpr bool is_steady = true;

   static time_point now()
   {
     const auto steady = std::chrono::steady_clock::now();
     return time_point{steady.time_since_epoch()};
   }
 };

 // This test is prone to failures if run on a loaded machine where the
 // kernel decides not to schedule us for several seconds. It also
 // assumes that no-one will warp CLOCK whilst the test is
 // running when CLOCK is std::chrono::system_clock.
 template<typename CLOCK>
 void test03()
 {
   auto const start = CLOCK::now();
   future<void> f1 = async(launch::async, []() {
       std::this_thread::sleep_for(std::chrono::seconds(2));
     });
   std::future_status status;

   status = f1.wait_for(std::chrono::milliseconds(500));
   VERIFY( status == std::future_status::timeout );

   status = f1.wait_until(start + std::chrono::seconds(1));
   VERIFY( status == std::future_status::timeout );

   status = f1.wait_until(start + std::chrono::seconds(5));
   VERIFY( status == std::future_status::ready );

   auto const elapsed = CLOCK::now() - start;
   VERIFY( elapsed >= std::chrono::seconds(2) );
   VERIFY( elapsed < std::chrono::seconds(5) );
 }

 // This clock is supposed to run at a tenth of normal speed, but we
 // don't have to worry about rounding errors causing us to wake up
 // slightly too early below if we actually run it at an eleventh of
 // normal speed. It is used to exercise the
 // __atomic_futex_unsigned::_M_load_when_equal_until overload that
 // takes an arbitrary clock.
 struct slow_clock
 {
   using rep = std::chrono::steady_clock::rep;
   using period = std::chrono::steady_clock::period;
   using duration = std::chrono::steady_clock::duration;
   using time_point = std::chrono::time_point<slow_clock, duration>;
   static constexpr bool is_steady = true;

   static time_point now()
   {
     const auto steady = std::chrono::steady_clock::now();
     return time_point{steady.time_since_epoch() / 11};
   }
 };

 void test04()
 {
   using namespace std::chrono;

   auto const slow_start = slow_clock::now();
   future<void> f1 = async(launch::async, []() {
       std::this_thread::sleep_for(std::chrono::seconds(2));
     });

   // Wait for ~1s
   {
     auto const steady_begin = steady_clock::now();
     auto const status = f1.wait_until(slow_start + milliseconds(100));
     VERIFY(status == std::future_status::timeout);
     auto const elapsed = steady_clock::now() - steady_begin;
     VERIFY(elapsed >= seconds(1));
     VERIFY(elapsed < seconds(2));
   }

   // Wait for up to ~2s more
   {
     auto const steady_begin = steady_clock::now();
     auto const status = f1.wait_until(slow_start + milliseconds(300));
     VERIFY(status == std::future_status::ready);
     auto const elapsed = steady_clock::now() - steady_begin;
     VERIFY(elapsed < seconds(2));
   }
 }

 void test_pr91486_wait_for()
 {
   future<void> f1 = async(launch::async, []() {
       std::this_thread::sleep_for(std::chrono::seconds(1));
     });

   std::chrono::duration<float> const wait_time = std::chrono::seconds(1);
   auto const start_steady = chrono::steady_clock::now();
   auto status = f1.wait_for(wait_time);
   auto const elapsed_steady = chrono::steady_clock::now() - start_steady;

   VERIFY( elapsed_steady >= std::chrono::seconds(1) );
 }

 // This is a clock with a very recent epoch which ensures that the difference
 // between now() and one second in the future is representable in a float so
 // that when the generic clock version of
 // __atomic_futex_unsigned::_M_load_when_equal_until calculates the delta it
 // gets a duration of 1.0f.  When chrono::steady_clock has moved sufficiently
 // far from its epoch (about 208.5 days in my testing - about 2^54ns because
 // there's a promotion to double happening too somewhere) adding 1.0f to the
 // current time has no effect.  Using this clock ensures that
 // __atomic_futex_unsigned::_M_load_when_equal_until is using
 // chrono::__detail::ceil correctly so that the function actually sleeps rather
 // than spinning.
 struct float_steady_clock
 {
   using duration = std::chrono::duration<float>;
   using rep = typename duration::rep;
   using period = typename duration::period;
   using time_point = std::chrono::time_point<float_steady_clock, duration>;
   static constexpr bool is_steady = true;

   static chrono::steady_clock::time_point epoch;
   static int call_count;

   static time_point now()
   {
     ++call_count;
     auto real = std::chrono::steady_clock::now();
     return time_point{real - epoch};
   }
 };

 chrono::steady_clock::time_point float_steady_clock::epoch = chrono::steady_clock::now();
 int float_steady_clock::call_count = 0;

 void test_pr91486_wait_until()
 {
   future<void> f1 = async(launch::async, []() {
       std::this_thread::sleep_for(std::chrono::seconds(1));
     });

   float_steady_clock::time_point const now = float_steady_clock::now();

   std::chrono::duration<float> const wait_time = std::chrono::seconds(1);
   float_steady_clock::time_point const expire = now + wait_time;
   VERIFY( expire > now );

   auto const start_steady = chrono::steady_clock::now();
   auto status = f1.wait_until(expire);
   auto const elapsed_steady = chrono::steady_clock::now() - start_steady;

   // This checks that we didn't come back too soon
   VERIFY( elapsed_steady >= std::chrono::seconds(1) );

   // This checks that wait_until didn't busy wait checking the clock more times
   // than necessary.
   VERIFY( float_steady_clock::call_count <= 3 );
 }

 int main()
 {
   test01();
   test02();
   test03<std::chrono::system_clock>();
   test03<std::chrono::steady_clock>();
   test03<steady_clock_copy>();
   test04();
   test_pr91486_wait_for();
   test_pr91486_wait_until();
   return 0;
 }
	// { dg-do run }
	// { dg-additional-options "-pthread" { target pthread } }
	// { dg-require-effective-target c++11 }
	// { dg-require-gthreads "" }

	// Copyright (C) 2010-2021 Free Software Foundation, Inc.
	//
	// This file is part of the GNU ISO C++ Library. This library is free
	// software; you can redistribute it and/or modify it under the
	// terms of the GNU General Public License as published by the
	// Free Software Foundation; either version 3, or (at your option)
	// any later version.

	// This library is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.

	// You should have received a copy of the GNU General Public License along
	// with this library; see the file COPYING3. If not see
	// <http://www.gnu.org/licenses/>.


	#include <future>
	#include <thread>
	#include <testsuite_hooks.h>

	using namespace std;

	void work(mutex& m)
	{
	unique_lock<mutex> l(m);
	}

	void test01()
	{
	mutex m;
	unique_lock<mutex> l(m);
	future<void> f1 = async(launch::async, &work, ref(m));
	l.unlock(); // allow async thread to proceed
	f1.get(); // wait for it to finish
	}

	void test02()
	{
	mutex m;
	unique_lock<mutex> l(m);
	future<void> f1 = async(launch::async, &work, ref(m));
	std::future_status status;
	status = f1.wait_for(std::chrono::milliseconds(1));
	VERIFY( status == std::future_status::timeout );
	status = f1.wait_until(std::chrono::system_clock::now());
	VERIFY( status == std::future_status::timeout );
	status = f1.wait_until(std::chrono::steady_clock::now());
	VERIFY( status == std::future_status::timeout );
	l.unlock(); // allow async thread to proceed
	f1.wait(); // wait for it to finish
	status = f1.wait_for(std::chrono::milliseconds(0));
	VERIFY( status == std::future_status::ready );
	status = f1.wait_until(std::chrono::system_clock::now());
	VERIFY( status == std::future_status::ready );
	status = f1.wait_until(std::chrono::steady_clock::now());
	VERIFY( status == std::future_status::ready );
	}

	// This clock behaves exactly the same as steady_clock, but it is not
	// steady_clock which means that the generic clock overload of
	// future::wait_until is used.
	struct steady_clock_copy
	{
	using rep = std::chrono::steady_clock::rep;
	using period = std::chrono::steady_clock::period;
	using duration = std::chrono::steady_clock::duration;
	using time_point = std::chrono::time_point<steady_clock_copy, duration>;
	static constexpr bool is_steady = true;

	static time_point now()
	{
	const auto steady = std::chrono::steady_clock::now();
	return time_point{steady.time_since_epoch()};
	}
	};

	// This test is prone to failures if run on a loaded machine where the
	// kernel decides not to schedule us for several seconds. It also
	// assumes that no-one will warp CLOCK whilst the test is
	// running when CLOCK is std::chrono::system_clock.
	template<typename CLOCK>
	void test03()
	{
	auto const start = CLOCK::now();
	future<void> f1 = async(launch::async, []() {
	std::this_thread::sleep_for(std::chrono::seconds(2));
	});
	std::future_status status;

	status = f1.wait_for(std::chrono::milliseconds(500));
	VERIFY( status == std::future_status::timeout );

	status = f1.wait_until(start + std::chrono::seconds(1));
	VERIFY( status == std::future_status::timeout );

	status = f1.wait_until(start + std::chrono::seconds(5));
	VERIFY( status == std::future_status::ready );

	auto const elapsed = CLOCK::now() - start;
	VERIFY( elapsed >= std::chrono::seconds(2) );
	VERIFY( elapsed < std::chrono::seconds(5) );
	}

	// This clock is supposed to run at a tenth of normal speed, but we
	// don't have to worry about rounding errors causing us to wake up
	// slightly too early below if we actually run it at an eleventh of
	// normal speed. It is used to exercise the
	// __atomic_futex_unsigned::_M_load_when_equal_until overload that
	// takes an arbitrary clock.
	struct slow_clock
	{
	using rep = std::chrono::steady_clock::rep;
	using period = std::chrono::steady_clock::period;
	using duration = std::chrono::steady_clock::duration;
	using time_point = std::chrono::time_point<slow_clock, duration>;
	static constexpr bool is_steady = true;

	static time_point now()
	{
	const auto steady = std::chrono::steady_clock::now();
	return time_point{steady.time_since_epoch() / 11};
	}
	};

	void test04()
	{
	using namespace std::chrono;

	auto const slow_start = slow_clock::now();
	future<void> f1 = async(launch::async, []() {
	std::this_thread::sleep_for(std::chrono::seconds(2));
	});

	// Wait for ~1s
	{
	auto const steady_begin = steady_clock::now();
	auto const status = f1.wait_until(slow_start + milliseconds(100));
	VERIFY(status == std::future_status::timeout);
	auto const elapsed = steady_clock::now() - steady_begin;
	VERIFY(elapsed >= seconds(1));
	VERIFY(elapsed < seconds(2));
	}

	// Wait for up to ~2s more
	{
	auto const steady_begin = steady_clock::now();
	auto const status = f1.wait_until(slow_start + milliseconds(300));
	VERIFY(status == std::future_status::ready);
	auto const elapsed = steady_clock::now() - steady_begin;
	VERIFY(elapsed < seconds(2));
	}
	}

	void test_pr91486_wait_for()
	{
	future<void> f1 = async(launch::async, []() {
	std::this_thread::sleep_for(std::chrono::seconds(1));
	});

	std::chrono::duration<float> const wait_time = std::chrono::seconds(1);
	auto const start_steady = chrono::steady_clock::now();
	auto status = f1.wait_for(wait_time);
	auto const elapsed_steady = chrono::steady_clock::now() - start_steady;

	VERIFY( elapsed_steady >= std::chrono::seconds(1) );
	}

	// This is a clock with a very recent epoch which ensures that the difference
	// between now() and one second in the future is representable in a float so
	// that when the generic clock version of
	// __atomic_futex_unsigned::_M_load_when_equal_until calculates the delta it
	// gets a duration of 1.0f. When chrono::steady_clock has moved sufficiently
	// far from its epoch (about 208.5 days in my testing - about 2^54ns because
	// there's a promotion to double happening too somewhere) adding 1.0f to the
	// current time has no effect. Using this clock ensures that
	// __atomic_futex_unsigned::_M_load_when_equal_until is using
	// chrono::__detail::ceil correctly so that the function actually sleeps rather
	// than spinning.
	struct float_steady_clock
	{
	using duration = std::chrono::duration<float>;
	using rep = typename duration::rep;
	using period = typename duration::period;
	using time_point = std::chrono::time_point<float_steady_clock, duration>;
	static constexpr bool is_steady = true;

	static chrono::steady_clock::time_point epoch;
	static int call_count;

	static time_point now()
	{
	++call_count;
	auto real = std::chrono::steady_clock::now();
	return time_point{real - epoch};
	}
	};

	chrono::steady_clock::time_point float_steady_clock::epoch = chrono::steady_clock::now();
	int float_steady_clock::call_count = 0;

	void test_pr91486_wait_until()
	{
	future<void> f1 = async(launch::async, []() {
	std::this_thread::sleep_for(std::chrono::seconds(1));
	});

	float_steady_clock::time_point const now = float_steady_clock::now();

	std::chrono::duration<float> const wait_time = std::chrono::seconds(1);
	float_steady_clock::time_point const expire = now + wait_time;
	VERIFY( expire > now );

	auto const start_steady = chrono::steady_clock::now();
	auto status = f1.wait_until(expire);
	auto const elapsed_steady = chrono::steady_clock::now() - start_steady;

	// This checks that we didn't come back too soon
	VERIFY( elapsed_steady >= std::chrono::seconds(1) );

	// This checks that wait_until didn't busy wait checking the clock more times
	// than necessary.
	VERIFY( float_steady_clock::call_count <= 3 );
	}

	int main()
	{
	test01();
	test02();
	test03<std::chrono::system_clock>();
	test03<std::chrono::steady_clock>();
	test03<steady_clock_copy>();
	test04();
	test_pr91486_wait_for();
	test_pr91486_wait_until();
	return 0;
	}