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More robust CScheduler unit test
On a busy or slow system, the CScheduler unit test could fail because it assumed all threads would be done after a couple of milliseconds. Replace the hard-coded sleep with CScheduler stop() method that will cleanly exit the servicing threads when all tasks are completely finished.
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@ -8,7 +8,7 @@
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#include <boost/bind.hpp>
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#include <utility>
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CScheduler::CScheduler() : nThreadsServicingQueue(0)
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CScheduler::CScheduler() : nThreadsServicingQueue(0), stopRequested(false), stopWhenEmpty(false)
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{
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}
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@ -29,32 +29,37 @@ void CScheduler::serviceQueue()
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{
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boost::unique_lock<boost::mutex> lock(newTaskMutex);
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++nThreadsServicingQueue;
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stopRequested = false;
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stopWhenEmpty = false;
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// newTaskMutex is locked throughout this loop EXCEPT
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// when the thread is waiting or when the user's function
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// is called.
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while (1) {
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while (!shouldStop()) {
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try {
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while (taskQueue.empty()) {
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while (!shouldStop() && taskQueue.empty()) {
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// Wait until there is something to do.
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newTaskScheduled.wait(lock);
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}
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// Wait until either there is a new task, or until
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// the time of the first item on the queue:
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// Wait until either there is a new task, or until
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// the time of the first item on the queue:
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// wait_until needs boost 1.50 or later; older versions have timed_wait:
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#if BOOST_VERSION < 105000
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while (!taskQueue.empty() && newTaskScheduled.timed_wait(lock, toPosixTime(taskQueue.begin()->first))) {
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while (!shouldStop() && !taskQueue.empty() &&
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newTaskScheduled.timed_wait(lock, toPosixTime(taskQueue.begin()->first))) {
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// Keep waiting until timeout
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}
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#else
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while (!taskQueue.empty() && newTaskScheduled.wait_until(lock, taskQueue.begin()->first) != boost::cv_status::timeout) {
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while (!shouldStop() && !taskQueue.empty() &&
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newTaskScheduled.wait_until(lock, taskQueue.begin()->first) != boost::cv_status::timeout) {
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// Keep waiting until timeout
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}
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#endif
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// If there are multiple threads, the queue can empty while we're waiting (another
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// thread may service the task we were waiting on).
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if (taskQueue.empty())
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if (shouldStop() || taskQueue.empty())
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continue;
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Function f = taskQueue.begin()->second;
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@ -70,6 +75,19 @@ void CScheduler::serviceQueue()
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throw;
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}
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}
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--nThreadsServicingQueue;
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}
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void CScheduler::stop(bool drain)
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{
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{
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boost::unique_lock<boost::mutex> lock(newTaskMutex);
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if (drain)
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stopWhenEmpty = true;
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else
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stopRequested = true;
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}
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newTaskScheduled.notify_all();
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}
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void CScheduler::schedule(CScheduler::Function f, boost::chrono::system_clock::time_point t)
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@ -96,3 +114,15 @@ void CScheduler::scheduleEvery(CScheduler::Function f, int64_t deltaSeconds)
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{
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scheduleFromNow(boost::bind(&Repeat, this, f, deltaSeconds), deltaSeconds);
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}
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size_t CScheduler::getQueueInfo(boost::chrono::system_clock::time_point &first,
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boost::chrono::system_clock::time_point &last) const
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{
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boost::unique_lock<boost::mutex> lock(newTaskMutex);
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size_t result = taskQueue.size();
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if (!taskQueue.empty()) {
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first = taskQueue.begin()->first;
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last = taskQueue.rbegin()->first;
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}
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return result;
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}
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@ -60,11 +60,24 @@ public:
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// and interrupted using boost::interrupt_thread
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void serviceQueue();
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// Tell any threads running serviceQueue to stop as soon as they're
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// done servicing whatever task they're currently servicing (drain=false)
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// or when there is no work left to be done (drain=true)
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void stop(bool drain=false);
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// Returns number of tasks waiting to be serviced,
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// and first and last task times
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size_t getQueueInfo(boost::chrono::system_clock::time_point &first,
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boost::chrono::system_clock::time_point &last) const;
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private:
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std::multimap<boost::chrono::system_clock::time_point, Function> taskQueue;
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boost::condition_variable newTaskScheduled;
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boost::mutex newTaskMutex;
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mutable boost::mutex newTaskMutex;
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int nThreadsServicingQueue;
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bool stopRequested;
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bool stopWhenEmpty;
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bool shouldStop() { return stopRequested || (stopWhenEmpty && taskQueue.empty()); }
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};
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#endif
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@ -42,6 +42,8 @@ static void MicroSleep(uint64_t n)
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BOOST_AUTO_TEST_CASE(manythreads)
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{
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seed_insecure_rand(false);
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// Stress test: hundreds of microsecond-scheduled tasks,
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// serviced by 10 threads.
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//
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@ -54,10 +56,6 @@ BOOST_AUTO_TEST_CASE(manythreads)
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// counters should sum to the number of initial tasks performed.
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CScheduler microTasks;
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boost::thread_group microThreads;
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for (int i = 0; i < 5; i++)
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microThreads.create_thread(boost::bind(&CScheduler::serviceQueue, µTasks));
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boost::mutex counterMutex[10];
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int counter[10] = { 0 };
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boost::random::mt19937 rng(insecure_rand());
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@ -67,6 +65,9 @@ BOOST_AUTO_TEST_CASE(manythreads)
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boost::chrono::system_clock::time_point start = boost::chrono::system_clock::now();
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boost::chrono::system_clock::time_point now = start;
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boost::chrono::system_clock::time_point first, last;
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size_t nTasks = microTasks.getQueueInfo(first, last);
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BOOST_CHECK(nTasks == 0);
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for (int i = 0; i < 100; i++) {
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boost::chrono::system_clock::time_point t = now + boost::chrono::microseconds(randomMsec(rng));
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@ -77,9 +78,19 @@ BOOST_AUTO_TEST_CASE(manythreads)
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randomDelta(rng), tReschedule);
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microTasks.schedule(f, t);
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}
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nTasks = microTasks.getQueueInfo(first, last);
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BOOST_CHECK(nTasks == 100);
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BOOST_CHECK(first < last);
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BOOST_CHECK(last > now);
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// As soon as these are created they will start running and servicing the queue
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boost::thread_group microThreads;
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for (int i = 0; i < 5; i++)
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microThreads.create_thread(boost::bind(&CScheduler::serviceQueue, µTasks));
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MicroSleep(600);
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now = boost::chrono::system_clock::now();
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// More threads and more tasks:
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for (int i = 0; i < 5; i++)
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microThreads.create_thread(boost::bind(&CScheduler::serviceQueue, µTasks));
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@ -93,11 +104,9 @@ BOOST_AUTO_TEST_CASE(manythreads)
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microTasks.schedule(f, t);
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}
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// All 2,000 tasks should be finished within 2 milliseconds. Sleep a bit longer.
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MicroSleep(2100);
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microThreads.interrupt_all();
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microThreads.join_all();
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// Drain the task queue then exit threads
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microTasks.stop(true);
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microThreads.join_all(); // ... wait until all the threads are done
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int counterSum = 0;
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for (int i = 0; i < 10; i++) {
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