ContextSV/ThreadPool_8h_source.html

#ifndef THREAD_POOL_H

#define THREAD_POOL_H


#include <vector>

#include <queue>

#include <memory>

#include <thread>

#include <mutex>

#include <condition_variable>

#include <future>

#include <functional>

#include <stdexcept>


class ThreadPool {

public:

    ThreadPool(size_t);

    template<class F, class... Args>

    auto enqueue(F&& f, Args&&... args)

        -> std::future<typename std::result_of<F(Args...)>::type>;

    ~ThreadPool();

private:

    // need to keep track of threads so we can join them

    std::vector< std::thread > workers;

    // the task queue

    std::queue< std::function<void()> > tasks;


    // synchronization

    std::mutex queue_mutex;

    std::condition_variable condition;

    bool stop;

};


// the constructor just launches some amount of workers


inline ThreadPool::ThreadPool(size_t threads)

    :   stop(false)

{

    for(size_t i = 0;i<threads;++i)

        workers.emplace_back(

            [this]

            {

                for(;;)

                {

                    std::function<void()> task;


                    {

                        std::unique_lock<std::mutex> lock(this->queue_mutex);

                        this->condition.wait(lock,

                            [this]{ return this->stop || !this->tasks.empty(); });

                        if(this->stop && this->tasks.empty())

                            return;

                        task = std::move(this->tasks.front());

                        this->tasks.pop();

                    }


                    task();

                }

            }

        );

}


// add new work item to the pool

template<class F, class... Args>


auto ThreadPool::enqueue(F&& f, Args&&... args)

    -> std::future<typename std::result_of<F(Args...)>::type>

{

    using return_type = typename std::result_of<F(Args...)>::type;


    auto task = std::make_shared< std::packaged_task<return_type()> >(

            std::bind(std::forward<F>(f), std::forward<Args>(args)...)

        );


    std::future<return_type> res = task->get_future();

    {

        std::unique_lock<std::mutex> lock(queue_mutex);


        // don't allow enqueueing after stopping the pool

        if(stop)

            throw std::runtime_error("enqueue on stopped ThreadPool");


        tasks.emplace([task](){ (*task)(); });

    }

    condition.notify_one();

    return res;

}


// the destructor joins all threads


inline ThreadPool::~ThreadPool()

{

    {

        std::unique_lock<std::mutex> lock(queue_mutex);

        stop = true;

    }

    condition.notify_all();

    for(std::thread &worker: workers)

        worker.join();

}


#endif

ThreadPool
Definition ThreadPool.h:14

ThreadPool::~ThreadPool
~ThreadPool()
Definition ThreadPool.h:87

ThreadPool::enqueue
auto enqueue(F &&f, Args &&... args) -> std::future< typename std::result_of< F(Args...)>::type >
Definition ThreadPool.h:63

ThreadPool::ThreadPool
ThreadPool(size_t)
Definition ThreadPool.h:34