利用C++11的特性来实现线程池
在实现线程池之前呢,我们还是要先了解一下线程池的组成:
1、线程池管理器
创建一定数量的线程,启动线程,调配任务,管理着线程池。
append()添加任务.
2、工作线程
线程池中线程,在线程池中等待并执行分配的任务.
这里选用条件变量实现等待与通知机制.
3、任务接口
添加任务的接口,以供工作线程调度任务的执行。
4、任务队列
用于存放没有处理的任务。提供一种缓冲机制
同时任务队列具有调度功能,这里选用queue作为任务队列
代码如下:参考链接:https://www.cnblogs.com/Tattoo-Welkin/p/10335254.html
#include<iostream> #include<vector> #include<queue> #include<stdexcept> #include<mutex> #include<memory> #include<condition_variable> #include<thread> using namespace std; const int MAX_THREAD = 100; template<class T> class ThreadPool { public: ThreadPool(int number = 1); ~ThreadPool(); bool append(T* task); private: static void *work(void *arg); void run(); private: vector<thread> workthreads; queue<T *> tasks; mutex queue_mutex; condition_variable condition; bool stop; }; template<class T> ThreadPool<T>::ThreadPool(int number):stop(false) { if(number <=0 || number > MAX_THREAD) throw exception(); for(int i = 0; i < number; ++i) { cout << "create the " << i << "thread" << endl; workthreads.emplace_back(work, this); } } template<class T> ThreadPool<T>::~ThreadPool() { unique_lock<std::mutex> lock(queue_mutex); stop = true; condition.notify_all(); for(auto &ww: workthreads) ww.join(); } template<class T> bool ThreadPool<T>::append(T* task) { queue_mutex.lock(); tasks.push(task); queue_mutex.unlock(); condition.notify_one(); return true; } template<class T> void* ThreadPool<T>::work(void *arg) { ThreadPool* pool = (ThreadPool*)arg; pool->run(); return pool; } template<class T> void ThreadPool<T>::run() { while(!stop) { unique_lock<std::mutex> lk(this->queue_mutex); this->condition.wait(lk, [this] { return !this->tasks.empty();}); if(this->tasks.empty()) { continue; } else { T* request = tasks.front(); tasks.pop(); if(request) request->process(); } } } class Task { public: void process() { cout << "run ......" << endl; } }; int main() { ThreadPool<Task> pool(6); while(1) { Task* tt = new Task(); pool.append(tt); delete tt; } return 0; }
测试程序运行结果: