emsApplication/sdk/include/hv/hthreadpool.h

#ifndef HV_THREAD_POOL_H_
#define HV_THREAD_POOL_H_

#include <time.h>
#include <thread>
#include <list>
#include <queue>
#include <functional>
#include <atomic>
#include <mutex>
#include <condition_variable>
#include <future>
#include <memory>
#include <utility>
#include <chrono>

#define DEFAULT_THREAD_POOL_MIN_THREAD_NUM  1
#define DEFAULT_THREAD_POOL_MAX_THREAD_NUM  std::thread::hardware_concurrency()
#define DEFAULT_THREAD_POOL_MAX_IDLE_TIME   60000 // ms

class HThreadPool {
public:
    using Task = std::function<void()>;

    HThreadPool(int min_threads = DEFAULT_THREAD_POOL_MIN_THREAD_NUM,
                int max_threads = DEFAULT_THREAD_POOL_MAX_THREAD_NUM,
                int max_idle_ms = DEFAULT_THREAD_POOL_MAX_IDLE_TIME)
        : min_thread_num(min_threads)
        , max_thread_num(max_threads)
        , max_idle_time(max_idle_ms)
        , status(STOP)
        , cur_thread_num(0)
        , idle_thread_num(0)
    {}

    virtual ~HThreadPool() {
        stop();
    }

    void setMinThreadNum(int min_threads) {
        min_thread_num = min_threads;
    }
    void setMaxThreadNum(int max_threads) {
        max_thread_num = max_threads;
    }
    void setMaxIdleTime(int ms) {
        max_idle_time = ms;
    }
    int currentThreadNum() {
        return cur_thread_num;
    }
    int idleThreadNum() {
        return idle_thread_num;
    }
    bool isStarted() {
        return status != STOP;
    }
    bool isStopped() {
        return status == STOP;
    }

    int start(int start_threads = 0) {
        if (status != STOP) return -1;
        status = RUNNING;
        if (start_threads < min_thread_num) start_threads = min_thread_num;
        if (start_threads > max_thread_num) start_threads = max_thread_num;
        for (int i = 0; i < start_threads; ++i) {
            createThread();
        }
        return 0;
    }

    int stop() {
        if (status == STOP) return -1;
        status = STOP;
        task_cond.notify_all();
        for (auto& i : threads) {
            if (i.thread->joinable()) {
                i.thread->join();
            }
        }
        threads.clear();
        cur_thread_num = 0;
        idle_thread_num = 0;
        return 0;
    }

    int pause() {
        if (status == RUNNING) {
            status = PAUSE;
        }
        return 0;
    }

    int resume() {
        if (status == PAUSE) {
            status = RUNNING;
        }
        return 0;
    }

    int wait() {
        while (1) {
            if (status == STOP || (tasks.empty() && idle_thread_num == cur_thread_num)) {
                break;
            }
            std::this_thread::yield();
        }
        return 0;
    }

    /*
     * return a future, calling future.get() will wait task done and return RetType.
     * commit(fn, args...)
     * commit(std::bind(&Class::mem_fn, &obj))
     * commit(std::mem_fn(&Class::mem_fn, &obj))
     *
     */
    template<class Fn, class... Args>
    auto commit(Fn&& fn, Args&&... args) -> std::future<decltype(fn(args...))> {
        if (status == STOP) start();
        if (idle_thread_num == 0 && cur_thread_num < max_thread_num) {
            createThread();
        }
        using RetType = decltype(fn(args...));
        auto task = std::make_shared<std::packaged_task<RetType()> >(
            std::bind(std::forward<Fn>(fn), std::forward<Args>(args)...));
        std::future<RetType> future = task->get_future();
        {
            std::lock_guard<std::mutex> locker(task_mutex);
            tasks.emplace([task]{
                (*task)();
            });
        }

        task_cond.notify_one();
        return future;
    }

protected:
    bool createThread() {
        if (cur_thread_num >= max_thread_num) return false;
        std::thread* thread = new std::thread([this] {
            while (status != STOP) {
                while (status == PAUSE) {
                    std::this_thread::yield();
                }

                Task task;
                {
                    std::unique_lock<std::mutex> locker(task_mutex);
                    task_cond.wait_for(locker, std::chrono::milliseconds(max_idle_time), [this]() {
                        return status == STOP || !tasks.empty();
                    });
                    if (status == STOP) return;
                    if (tasks.empty()) {
                        if (cur_thread_num > min_thread_num) {
                            delThread(std::this_thread::get_id());
                            return;
                        }
                        continue;
                    }
                    --idle_thread_num;
                    task = std::move(tasks.front());
                    tasks.pop();
                }
                if (task) {
                    task();
                    ++idle_thread_num;
                }
            }
        });
        addThread(thread);
        return true;
    }

    void addThread(std::thread* thread) {
        thread_mutex.lock();
        ++cur_thread_num;
        ++idle_thread_num;
        ThreadData data;
        data.thread = std::shared_ptr<std::thread>(thread);
        data.id = thread->get_id();
        data.status = RUNNING;
        data.start_time = time(NULL);
        threads.emplace_back(data);
        thread_mutex.unlock();
    }

    void delThread(std::thread::id id) {
        time_t now = time(NULL);
        thread_mutex.lock();
        --cur_thread_num;
        --idle_thread_num;
        auto iter = threads.begin();
        while (iter != threads.end()) {
            if (iter->status == STOP && now > iter->stop_time) {
                if (iter->thread->joinable()) {
                    iter->thread->join();
                    iter = threads.erase(iter);
                    continue;
                }
            } else if (iter->id == id) {
                iter->status = STOP;
                iter->stop_time = time(NULL);
            }
            ++iter;
        }
        thread_mutex.unlock();
    }

public:
    int min_thread_num;
    int max_thread_num;
    int max_idle_time;

protected:
    enum Status {
        STOP,
        RUNNING,
        PAUSE,
    };
    struct ThreadData {
        std::shared_ptr<std::thread> thread;
        std::thread::id id;
        Status          status;
        time_t          start_time;
        time_t          stop_time;
    };
    std::atomic<Status>     status;
    std::atomic<int>        cur_thread_num;
    std::atomic<int>        idle_thread_num;
    std::list<ThreadData>   threads;
    std::mutex              thread_mutex;
    std::queue<Task>        tasks;
    std::mutex              task_mutex;
    std::condition_variable task_cond;
};

#endif // HV_THREAD_POOL_H_
s 2024-05-24 12:23:42 +08:00			`#ifndef HV_THREAD_POOL_H_`
			`#define HV_THREAD_POOL_H_`

			`#include <time.h>`
			`#include <thread>`
			`#include <list>`
			`#include <queue>`
			`#include <functional>`
			`#include <atomic>`
			`#include <mutex>`
			`#include <condition_variable>`
			`#include <future>`
			`#include <memory>`
			`#include <utility>`
			`#include <chrono>`

			`#define DEFAULT_THREAD_POOL_MIN_THREAD_NUM 1`
			`#define DEFAULT_THREAD_POOL_MAX_THREAD_NUM std::thread::hardware_concurrency()`
			`#define DEFAULT_THREAD_POOL_MAX_IDLE_TIME 60000 // ms`

			`class HThreadPool {`
			`public:`
			`using Task = std::function<void()>;`

			`HThreadPool(int min_threads = DEFAULT_THREAD_POOL_MIN_THREAD_NUM,`
			`int max_threads = DEFAULT_THREAD_POOL_MAX_THREAD_NUM,`
			`int max_idle_ms = DEFAULT_THREAD_POOL_MAX_IDLE_TIME)`
			`: min_thread_num(min_threads)`
			`, max_thread_num(max_threads)`
			`, max_idle_time(max_idle_ms)`
			`, status(STOP)`
			`, cur_thread_num(0)`
			`, idle_thread_num(0)`
			`{}`

			`virtual ~HThreadPool() {`
			`stop();`
			`}`

			`void setMinThreadNum(int min_threads) {`
			`min_thread_num = min_threads;`
			`}`
			`void setMaxThreadNum(int max_threads) {`
			`max_thread_num = max_threads;`
			`}`
			`void setMaxIdleTime(int ms) {`
			`max_idle_time = ms;`
			`}`
			`int currentThreadNum() {`
			`return cur_thread_num;`
			`}`
			`int idleThreadNum() {`
			`return idle_thread_num;`
			`}`
			`bool isStarted() {`
			`return status != STOP;`
			`}`
			`bool isStopped() {`
			`return status == STOP;`
			`}`

			`int start(int start_threads = 0) {`
			`if (status != STOP) return -1;`
			`status = RUNNING;`
			`if (start_threads < min_thread_num) start_threads = min_thread_num;`
			`if (start_threads > max_thread_num) start_threads = max_thread_num;`
			`for (int i = 0; i < start_threads; ++i) {`
			`createThread();`
			`}`
			`return 0;`
			`}`

			`int stop() {`
			`if (status == STOP) return -1;`
			`status = STOP;`
			`task_cond.notify_all();`
			`for (auto& i : threads) {`
			`if (i.thread->joinable()) {`
			`i.thread->join();`
			`}`
			`}`
			`threads.clear();`
			`cur_thread_num = 0;`
			`idle_thread_num = 0;`
			`return 0;`
			`}`

			`int pause() {`
			`if (status == RUNNING) {`
			`status = PAUSE;`
			`}`
			`return 0;`
			`}`

			`int resume() {`
			`if (status == PAUSE) {`
			`status = RUNNING;`
			`}`
			`return 0;`
			`}`

			`int wait() {`
			`while (1) {`
			`if (status == STOP \|\| (tasks.empty() && idle_thread_num == cur_thread_num)) {`
			`break;`
			`}`
			`std::this_thread::yield();`
			`}`
			`return 0;`
			`}`

			`/*`
			`* return a future, calling future.get() will wait task done and return RetType.`
			`* commit(fn, args...)`
			`* commit(std::bind(&Class::mem_fn, &obj))`
			`* commit(std::mem_fn(&Class::mem_fn, &obj))`
			`*`
			`*/`
			`template<class Fn, class... Args>`
			`auto commit(Fn&& fn, Args&&... args) -> std::future<decltype(fn(args...))> {`
			`if (status == STOP) start();`
			`if (idle_thread_num == 0 && cur_thread_num < max_thread_num) {`
			`createThread();`
			`}`
			`using RetType = decltype(fn(args...));`
			`auto task = std::make_shared<std::packaged_task<RetType()> >(`
			`std::bind(std::forward<Fn>(fn), std::forward<Args>(args)...));`
			`std::future<RetType> future = task->get_future();`
			`{`
			`std::lock_guard<std::mutex> locker(task_mutex);`
			`tasks.emplace([task]{`
			`(*task)();`
			`});`
			`}`

			`task_cond.notify_one();`
			`return future;`
			`}`

			`protected:`
			`bool createThread() {`
			`if (cur_thread_num >= max_thread_num) return false;`
			`std::thread* thread = new std::thread([this] {`
			`while (status != STOP) {`
			`while (status == PAUSE) {`
			`std::this_thread::yield();`
			`}`

			`Task task;`
			`{`
			`std::unique_lock<std::mutex> locker(task_mutex);`
			`task_cond.wait_for(locker, std::chrono::milliseconds(max_idle_time), [this]() {`
			`return status == STOP \|\| !tasks.empty();`
			`});`
			`if (status == STOP) return;`
			`if (tasks.empty()) {`
			`if (cur_thread_num > min_thread_num) {`
			`delThread(std::this_thread::get_id());`
			`return;`
			`}`
			`continue;`
			`}`
			`--idle_thread_num;`
			`task = std::move(tasks.front());`
			`tasks.pop();`
			`}`
			`if (task) {`
			`task();`
			`++idle_thread_num;`
			`}`
			`}`
			`});`
			`addThread(thread);`
			`return true;`
			`}`

			`void addThread(std::thread* thread) {`
			`thread_mutex.lock();`
			`++cur_thread_num;`
			`++idle_thread_num;`
			`ThreadData data;`
			`data.thread = std::shared_ptr<std::thread>(thread);`
			`data.id = thread->get_id();`
			`data.status = RUNNING;`
			`data.start_time = time(NULL);`
			`threads.emplace_back(data);`
			`thread_mutex.unlock();`
			`}`

			`void delThread(std::thread::id id) {`
			`time_t now = time(NULL);`
			`thread_mutex.lock();`
			`--cur_thread_num;`
			`--idle_thread_num;`
			`auto iter = threads.begin();`
			`while (iter != threads.end()) {`
			`if (iter->status == STOP && now > iter->stop_time) {`
			`if (iter->thread->joinable()) {`
			`iter->thread->join();`
			`iter = threads.erase(iter);`
			`continue;`
			`}`
			`} else if (iter->id == id) {`
			`iter->status = STOP;`
			`iter->stop_time = time(NULL);`
			`}`
			`++iter;`
			`}`
			`thread_mutex.unlock();`
			`}`

			`public:`
			`int min_thread_num;`
			`int max_thread_num;`
			`int max_idle_time;`

			`protected:`
			`enum Status {`
			`STOP,`
			`RUNNING,`
			`PAUSE,`
			`};`
			`struct ThreadData {`
			`std::shared_ptr<std::thread> thread;`
			`std::thread::id id;`
			`Status status;`
			`time_t start_time;`
			`time_t stop_time;`
			`};`
			`std::atomic<Status> status;`
			`std::atomic<int> cur_thread_num;`
			`std::atomic<int> idle_thread_num;`
			`std::list<ThreadData> threads;`
			`std::mutex thread_mutex;`
			`std::queue<Task> tasks;`
			`std::mutex task_mutex;`
			`std::condition_variable task_cond;`
			`};`

			`#endif // HV_THREAD_POOL_H_`