libcxx/test/std/thread/thread.condition/thread.condition.condvarany/wait_until_pred.pass.cpp - rust-lang/llvm-project - 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: no-threads, c++03

 // <condition_variable>

 // class condition_variable_any;

 // template <class Lock, class Duration, class Predicate>
 //     bool
 //     wait_until(Lock& lock,
 //                const chrono::time_point<Clock, Duration>& abs_time,
 //                Predicate pred);

 #include <condition_variable>
 #include <atomic>
 #include <cassert>
 #include <chrono>
 #include <mutex>
 #include <thread>

 #include "make_test_thread.h"
 #include "test_macros.h"

 struct TestClock {
   typedef std::chrono::milliseconds duration;
   typedef duration::rep rep;
   typedef duration::period period;
   typedef std::chrono::time_point<TestClock> time_point;
   static const bool is_steady = true;

   static time_point now() {
     using namespace std::chrono;
     return time_point(duration_cast<duration>(steady_clock::now().time_since_epoch()));
   }
 };

 template <class Mutex>
 struct MyLock : std::unique_lock<Mutex> {
   using std::unique_lock<Mutex>::unique_lock;
 };

 template <class Lock, class Clock>
 void test() {
   using Mutex = typename Lock::mutex_type;
   // Test unblocking via a call to notify_one() in another thread.
   //
   // To test this, we set a very long timeout in wait_until() and we try to minimize
   // the likelihood that we got awoken by a spurious wakeup by updating the
   // likely_spurious flag only immediately before we perform the notification.
   {
     std::atomic<bool> ready(false);
     std::atomic<bool> likely_spurious(true);
     auto timeout = Clock::now() + std::chrono::seconds(3600);
     std::condition_variable_any cv;
     Mutex mutex;

     std::thread t1 = support::make_test_thread([&] {
       Lock lock(mutex);
       ready       = true;
       bool result = cv.wait_until(lock, timeout, [&] { return !likely_spurious; });
       assert(result); // return value should be true since we didn't time out
       assert(Clock::now() < timeout);
     });

     std::thread t2 = support::make_test_thread([&] {
       while (!ready) {
         // spin
       }

       // Acquire the same mutex as t1. This ensures that the condition variable has started
       // waiting (and hence released that mutex).
       Lock lock(mutex);

       likely_spurious = false;
       lock.unlock();
       cv.notify_one();
     });

     t2.join();
     t1.join();
   }

   // Test unblocking via a timeout.
   //
   // To test this, we create a thread that waits on a condition variable with a certain
   // timeout, and we never awaken it. The "stop waiting" predicate always returns false,
   // which means that we can't get out of the wait via a spurious wakeup.
   {
     auto timeout = Clock::now() + std::chrono::milliseconds(250);
     std::condition_variable_any cv;
     Mutex mutex;

     std::thread t1 = support::make_test_thread([&] {
       Lock lock(mutex);
       bool result = cv.wait_until(lock, timeout, [] { return false; }); // never stop waiting (until timeout)
       assert(!result); // return value should be false since the predicate returns false after the timeout
       assert(Clock::now() >= timeout);
     });

     t1.join();
   }

   // Test unblocking via a spurious wakeup.
   //
   // To test this, we set a fairly long timeout in wait_until() and we basically never
   // wake up the condition variable. This way, we are hoping to get out of the wait
   // via a spurious wakeup.
   //
   // However, since spurious wakeups are not required to even happen, this test is
   // only trying to trigger that code path, but not actually asserting that it is
   // taken. In particular, we do need to eventually ensure we get out of the wait
   // by standard means, so we actually wake up the thread at the end.
   {
     std::atomic<bool> ready(false);
     std::atomic<bool> awoken(false);
     auto timeout = Clock::now() + std::chrono::seconds(3600);
     std::condition_variable_any cv;
     Mutex mutex;

     std::thread t1 = support::make_test_thread([&] {
       Lock lock(mutex);
       ready       = true;
       bool result = cv.wait_until(lock, timeout, [&] { return true; });
       awoken      = true;
       assert(result);                 // return value should be true since we didn't time out
       assert(Clock::now() < timeout); // can technically fail if t2 never executes and we timeout, but very unlikely
     });

     std::thread t2 = support::make_test_thread([&] {
       while (!ready) {
         // spin
       }

       // Acquire the same mutex as t1. This ensures that the condition variable has started
       // waiting (and hence released that mutex).
       Lock lock(mutex);
       lock.unlock();

       // Give some time for t1 to be awoken spuriously so that code path is used.
       std::this_thread::sleep_for(std::chrono::seconds(1));

       // We would want to assert that the thread has been awoken after this time,
       // however nothing guarantees us that it ever gets spuriously awoken, so
       // we can't really check anything. This is still left here as documentation.
       bool woke = awoken.load();
       assert(woke || !woke);

       // Whatever happened, actually awaken the condition variable to ensure the test
       // doesn't keep running until the timeout.
       cv.notify_one();
     });

     t2.join();
     t1.join();
   }
 }

 int main(int, char**) {
   // Run on multiple threads to speed up the test, and because it ought to work anyways.
   std::thread tests[] = {
       support::make_test_thread([] {
         test<std::unique_lock<std::mutex>, TestClock>();
         test<std::unique_lock<std::mutex>, std::chrono::steady_clock>();
       }),
       support::make_test_thread([] {
         test<std::unique_lock<std::timed_mutex>, TestClock>();
         test<std::unique_lock<std::timed_mutex>, std::chrono::steady_clock>();
       }),
       support::make_test_thread([] {
         test<MyLock<std::mutex>, TestClock>();
         test<MyLock<std::mutex>, std::chrono::steady_clock>();
       }),
       support::make_test_thread([] {
         test<MyLock<std::timed_mutex>, TestClock>();
         test<MyLock<std::timed_mutex>, std::chrono::steady_clock>();
       })};

   for (std::thread& t : tests)
     t.join();

   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: no-threads, c++03

	// <condition_variable>

	// class condition_variable_any;

	// template <class Lock, class Duration, class Predicate>
	// bool
	// wait_until(Lock& lock,
	// const chrono::time_point<Clock, Duration>& abs_time,
	// Predicate pred);

	#include <condition_variable>
	#include <atomic>
	#include <cassert>
	#include <chrono>
	#include <mutex>
	#include <thread>

	#include "make_test_thread.h"
	#include "test_macros.h"

	struct TestClock {
	typedef std::chrono::milliseconds duration;
	typedef duration::rep rep;
	typedef duration::period period;
	typedef std::chrono::time_point<TestClock> time_point;
	static const bool is_steady = true;

	static time_point now() {
	using namespace std::chrono;
	return time_point(duration_cast<duration>(steady_clock::now().time_since_epoch()));
	}
	};

	template <class Mutex>
	struct MyLock : std::unique_lock<Mutex> {
	using std::unique_lock<Mutex>::unique_lock;
	};

	template <class Lock, class Clock>
	void test() {
	using Mutex = typename Lock::mutex_type;
	// Test unblocking via a call to notify_one() in another thread.
	//
	// To test this, we set a very long timeout in wait_until() and we try to minimize
	// the likelihood that we got awoken by a spurious wakeup by updating the
	// likely_spurious flag only immediately before we perform the notification.
	{
	std::atomic<bool> ready(false);
	std::atomic<bool> likely_spurious(true);
	auto timeout = Clock::now() + std::chrono::seconds(3600);
	std::condition_variable_any cv;
	Mutex mutex;

	std::thread t1 = support::make_test_thread([&] {
	Lock lock(mutex);
	ready = true;
	bool result = cv.wait_until(lock, timeout, [&] { return !likely_spurious; });
	assert(result); // return value should be true since we didn't time out
	assert(Clock::now() < timeout);
	});

	std::thread t2 = support::make_test_thread([&] {
	while (!ready) {
	// spin
	}

	// Acquire the same mutex as t1. This ensures that the condition variable has started
	// waiting (and hence released that mutex).
	Lock lock(mutex);

	likely_spurious = false;
	lock.unlock();
	cv.notify_one();
	});

	t2.join();
	t1.join();
	}

	// Test unblocking via a timeout.
	//
	// To test this, we create a thread that waits on a condition variable with a certain
	// timeout, and we never awaken it. The "stop waiting" predicate always returns false,
	// which means that we can't get out of the wait via a spurious wakeup.
	{
	auto timeout = Clock::now() + std::chrono::milliseconds(250);
	std::condition_variable_any cv;
	Mutex mutex;

	std::thread t1 = support::make_test_thread([&] {
	Lock lock(mutex);
	bool result = cv.wait_until(lock, timeout, [] { return false; }); // never stop waiting (until timeout)
	assert(!result); // return value should be false since the predicate returns false after the timeout
	assert(Clock::now() >= timeout);
	});

	t1.join();
	}

	// Test unblocking via a spurious wakeup.
	//
	// To test this, we set a fairly long timeout in wait_until() and we basically never
	// wake up the condition variable. This way, we are hoping to get out of the wait
	// via a spurious wakeup.
	//
	// However, since spurious wakeups are not required to even happen, this test is
	// only trying to trigger that code path, but not actually asserting that it is
	// taken. In particular, we do need to eventually ensure we get out of the wait
	// by standard means, so we actually wake up the thread at the end.
	{
	std::atomic<bool> ready(false);
	std::atomic<bool> awoken(false);
	auto timeout = Clock::now() + std::chrono::seconds(3600);
	std::condition_variable_any cv;
	Mutex mutex;

	std::thread t1 = support::make_test_thread([&] {
	Lock lock(mutex);
	ready = true;
	bool result = cv.wait_until(lock, timeout, [&] { return true; });
	awoken = true;
	assert(result); // return value should be true since we didn't time out
	assert(Clock::now() < timeout); // can technically fail if t2 never executes and we timeout, but very unlikely
	});

	std::thread t2 = support::make_test_thread([&] {
	while (!ready) {
	// spin
	}

	// Acquire the same mutex as t1. This ensures that the condition variable has started
	// waiting (and hence released that mutex).
	Lock lock(mutex);
	lock.unlock();

	// Give some time for t1 to be awoken spuriously so that code path is used.
	std::this_thread::sleep_for(std::chrono::seconds(1));

	// We would want to assert that the thread has been awoken after this time,
	// however nothing guarantees us that it ever gets spuriously awoken, so
	// we can't really check anything. This is still left here as documentation.
	bool woke = awoken.load();
	assert(woke \|\| !woke);

	// Whatever happened, actually awaken the condition variable to ensure the test
	// doesn't keep running until the timeout.
	cv.notify_one();
	});

	t2.join();
	t1.join();
	}
	}

	int main(int, char**) {
	// Run on multiple threads to speed up the test, and because it ought to work anyways.
	std::thread tests[] = {
	support::make_test_thread([] {
	test<std::unique_lock<std::mutex>, TestClock>();
	test<std::unique_lock<std::mutex>, std::chrono::steady_clock>();
	}),
	support::make_test_thread([] {
	test<std::unique_lock<std::timed_mutex>, TestClock>();
	test<std::unique_lock<std::timed_mutex>, std::chrono::steady_clock>();
	}),
	support::make_test_thread([] {
	test<MyLock<std::mutex>, TestClock>();
	test<MyLock<std::mutex>, std::chrono::steady_clock>();
	}),
	support::make_test_thread([] {
	test<MyLock<std::timed_mutex>, TestClock>();
	test<MyLock<std::timed_mutex>, std::chrono::steady_clock>();
	})};

	for (std::thread& t : tests)
	t.join();

	return 0;
	}