example/client-cpp-example/src/ThreadPool/ThreadPool.h - iotdb - Git at Google

 #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
	#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