/** * Licensed to the Apache Software Foundation (ASF) under one * or more contributor license agreements. See the NOTICE file * distributed with this work for additional information * regarding copyright ownership. The ASF licenses this file * to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance * with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. */ #ifndef LIB_BLOCKINGQUEUE_H_ #define LIB_BLOCKINGQUEUE_H_ #include <boost/circular_buffer.hpp> #include <condition_variable> #include <mutex> /** * Following structs are defined for holding a predicate in wait() call on condition variables. * This is done in order to avoid spurious wake up problem. * Details: https://www.justsoftwaresolutions.co.uk/threading/condition-variable-spurious-wakes.html */ template <typename Container> struct QueueNotEmpty { const Container& queue_; QueueNotEmpty(const Container& queue) : queue_(queue) {} bool operator()() const { return !queue_.isEmptyNoMutex() || queue_.isClosedNoMutex(); } }; template <typename Container> struct QueueNotFull { const Container& queue_; QueueNotFull(const Container& queue) : queue_(queue) {} bool operator()() const { return !queue_.isFullNoMutex() || queue_.isClosedNoMutex(); } }; template <typename T> class BlockingQueue { public: typedef typename boost::circular_buffer<T> Container; typedef typename Container::iterator iterator; typedef typename Container::const_iterator const_iterator; BlockingQueue(size_t maxSize) : maxSize_(maxSize), mutex_(), queue_(maxSize) {} bool push(const T& value) { Lock lock(mutex_); // If the queue is full, wait for space to be available queueFullCondition.wait(lock, QueueNotFull<BlockingQueue<T> >(*this)); if (isClosedNoMutex()) { return false; } bool wasEmpty = queue_.empty(); queue_.push_back(value); lock.unlock(); if (wasEmpty) { // Notify that an element is pushed queueEmptyCondition.notify_all(); } return true; } bool pop(T& value) { Lock lock(mutex_); // If the queue is empty, wait until an element is available to be popped queueEmptyCondition.wait(lock, QueueNotEmpty<BlockingQueue<T> >(*this)); if (isClosedNoMutex()) { return false; } value = queue_.front(); bool wasFull = isFullNoMutex(); queue_.pop_front(); lock.unlock(); if (wasFull) { // Notify that an element is popped queueFullCondition.notify_all(); } return true; } template <typename Duration> bool pop(T& value, const Duration& timeout) { Lock lock(mutex_); if (!queueEmptyCondition.wait_for(lock, timeout, QueueNotEmpty<BlockingQueue<T> >(*this))) { return false; } if (isClosedNoMutex()) { return false; } bool wasFull = isFullNoMutex(); value = queue_.front(); queue_.pop_front(); lock.unlock(); if (wasFull) { // Notify that an element is popped queueFullCondition.notify_all(); } return true; } /** * First peek data to the condition judgment, if true then pop it. * * @param value A reference to the value assigned after pop * @param condition A function that returns true if the value should be popped * @return true if the value was popped, false otherwise. */ bool popIf(T& value, std::function<bool(const T& peekValue)> condition) { Lock lock(mutex_); if (isEmptyNoMutex() || isClosedNoMutex()) { return false; } bool wasFull = isFullNoMutex(); auto peekValue = queue_.front(); if (condition(peekValue)) { value = peekValue; queue_.pop_front(); lock.unlock(); if (wasFull) { // Notify that an element is popped queueFullCondition.notify_all(); } return true; } else { return false; } } // Check the 1st element of the queue bool peek(T& value) { Lock lock(mutex_); if (queue_.empty()) { return false; } value = queue_.front(); return true; } // Remove all elements from the queue void clear() { Lock lock(mutex_); queue_.clear(); queueFullCondition.notify_all(); } size_t size() const { Lock lock(mutex_); return queue_.size(); } size_t maxSize() const { return maxSize_; } bool empty() const { Lock lock(mutex_); return isEmptyNoMutex(); } bool full() const { Lock lock(mutex_); return isFullNoMutex(); } const_iterator begin() const { return queue_.begin(); } const_iterator end() const { return queue_.end(); } iterator begin() { return queue_.begin(); } iterator end() { return queue_.end(); } void close() { Lock lock(mutex_); isClosed_ = true; queueEmptyCondition.notify_all(); queueFullCondition.notify_all(); } private: bool isEmptyNoMutex() const { return queue_.empty(); } bool isFullNoMutex() const { return queue_.size() == maxSize_; } bool isClosedNoMutex() const { return isClosed_; } const size_t maxSize_; mutable std::mutex mutex_; std::condition_variable queueFullCondition; std::condition_variable queueEmptyCondition; Container queue_; bool isClosed_ = false; typedef std::unique_lock<std::mutex> Lock; friend struct QueueNotEmpty<BlockingQueue<T> >; friend struct QueueNotFull<BlockingQueue<T> >; }; #endif /* LIB_BLOCKINGQUEUE_H_ */