/* Copyright (C) 2007, 2008, 2009, 2010, 2011 Her Majesty the Queen in Right of Canada (Communications Research Center Canada) Copyright (C) 2018 Matthias P. Braendli, matthias.braendli@mpb.li An implementation for a threadsafe queue, depends on C++11 When creating a ThreadsafeQueue, one can specify the minimal number of elements it must contain before it is possible to take one element out. */ /* This program 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 of the License, or (at your option) any later version. This program 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 program. If not, see . */ #pragma once #include #include #include #include /* This queue is meant to be used by two threads. One producer * that pushes elements into the queue, and one consumer that * retrieves the elements. * * The queue can make the consumer block until an element * is available, or a wakeup requested. */ /* Class thrown by blocking pop to tell the consumer * that there's a wakeup requested. */ class ThreadsafeQueueWakeup {}; template class ThreadsafeQueue { public: /* Push one element into the queue, and notify another thread that * might be waiting. * * returns the new queue size. */ size_t push(T const& val) { std::unique_lock lock(the_mutex); the_queue.push(val); size_t queue_size = the_queue.size(); lock.unlock(); the_rx_notification.notify_one(); return queue_size; } size_t push(T&& val) { std::unique_lock lock(the_mutex); the_queue.emplace(std::move(val)); size_t queue_size = the_queue.size(); lock.unlock(); the_rx_notification.notify_one(); return queue_size; } /* Push one element into the queue, but wait until the * queue size goes below the threshold. * * Notify waiting thread. * * returns the new queue size. */ size_t push_wait_if_full(T const& val, size_t threshold) { std::unique_lock lock(the_mutex); while (the_queue.size() >= threshold) { the_tx_notification.wait(lock); } the_queue.push(val); size_t queue_size = the_queue.size(); lock.unlock(); the_rx_notification.notify_one(); return queue_size; } /* Trigger a wakeup event on a blocking consumer, which * will receive a ThreadsafeQueueWakeup exception. */ void trigger_wakeup(void) { std::unique_lock lock(the_mutex); wakeup_requested = true; lock.unlock(); the_rx_notification.notify_one(); } /* Send a notification for the receiver thread */ void notify(void) { the_rx_notification.notify_one(); } bool empty() const { std::unique_lock lock(the_mutex); return the_queue.empty(); } size_t size() const { std::unique_lock lock(the_mutex); return the_queue.size(); } bool try_pop(T& popped_value) { std::unique_lock lock(the_mutex); if (the_queue.empty()) { return false; } popped_value = the_queue.front(); the_queue.pop(); lock.unlock(); the_tx_notification.notify_one(); return true; } void wait_and_pop(T& popped_value, size_t prebuffering = 1) { std::unique_lock lock(the_mutex); while (the_queue.size() < prebuffering and not wakeup_requested) { the_rx_notification.wait(lock); } if (wakeup_requested) { wakeup_requested = false; throw ThreadsafeQueueWakeup(); } else { std::swap(popped_value, the_queue.front()); the_queue.pop(); lock.unlock(); the_tx_notification.notify_one(); } } private: std::queue the_queue; mutable std::mutex the_mutex; std::condition_variable the_rx_notification; std::condition_variable the_tx_notification; bool wakeup_requested = false; };