C/C++ Qt QThread线程组件的具体使用_C/C++

QThread库是QT中提供的跨平台多线程实现方案,使用时需要继承QThread这个基类,并重写实现内部的Run方法,由于该库是基本库,默认依赖于QtCore.dll这个基础模块,在使用时无需引入其他模块.

实现简单多线程

QThread库提供了跨平台的多线程管理方案,通常一个QThread对象管理一个线程,在使用是需要从QThread类继承并重写内部的Run方法,并在Run方法内部实现多线程代码.

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									#include <QCoreApplication>

									#include <iostream>

									#include <QThread>

									class MyThread: public QThread

									{

									protected:

									    volatile bool m_to_stop;

									protected:

									    // 线程函数必须使用Run作为开始

									    void run()

									    {

									        for(int x=0; !m_to_stop && (x <10); x++)

									        {

									            msleep(1000);

									            std::cout << objectName().toStdString() << std::endl;

									        }

									    }

									public:

									    MyThread()

									    {

									        m_to_stop = false;

									    }

									    // 用于设置结束符号为真

									    void stop()

									    {

									        m_to_stop = true;

									    }

									    // 输出线程运行状态

									    void is_run()

									    {

									        std::cout << "Thread Running = " << isRunning() << std::endl;

									    }

									    // 输出线程完成状态(是否结束)

									    void is_finish()

									    {

									        std::cout << "Thread Finished = " << isFinished() << std::endl;

									    }

									};

									int main(int argc, char *argv[])

									{

									    QCoreApplication a(argc, argv);

									    // 定义线程数组

									    MyThread thread[10];

									    // 设置线程对象名字

									    for(int x=0;x<10;x++)

									    {

									        thread[x].setObjectName(QString("thread => %1").arg(x));

									    }

									    // 批量调用run执行

									    for(int x=0;x<10;x++)

									    {

									        thread[x].start();

									        thread[x].is_run();

									        thread[x].isFinished();

									    }

									    // 批量调用stop关闭

									    for(int x=0;x<10;x++)

									    {

									        thread[x].wait();

									        thread[x].stop();

									        thread[x].is_run();

									        thread[x].is_finish();

									    }

									    return a.exec();

									}

向线程中传递参数

线程在执行前可以通过调用MyThread中的自定义函数,并在函数内实现参数赋值,实现线程传参操作.

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									#include <QCoreApplication>

									#include <iostream>

									#include <QThread>

									class MyThread: public QThread

									{

									protected:

									    int m_begin;

									    int m_end;

									    int m_result;

									    void run()

									    {

									        m_result = m_begin + m_end;

									    }

									public:

									    MyThread()

									    {

									        m_begin = 0;

									        m_end = 0;

									        m_result = 0;

									    }

									    // 设置参数给当前线程

									    void set_value(int x,int y)

									    {

									        m_begin = x;

									        m_end = y;

									    }

									    // 获取当前线程名

									    void get_object_name()

									    {

									        std::cout << "this thread name => " << objectName().toStdString() << std::endl;

									    }

									    // 获取线程返回结果

									    int result()

									    {

									        return m_result;

									    }

									};

									int main(int argc, char *argv[])

									{

									    QCoreApplication a(argc, argv);

									    MyThread thread[3];

									    // 分别将不同的参数传入到线程函数内

									    for(int x=0; x<3; x++)

									    {

									        thread[x].set_value(1,2);

									        thread[x].setObjectName(QString("thread -> %1").arg(x));

									        thread[x].start();

									    }

									    // 等待所有线程执行结束

									    for(int x=0; x<3; x++)

									    {

									        thread[x].get_object_name();

									        thread[x].wait();

									    }

									    // 获取线程返回值并相加

									    int result = thread[0].result() + thread[1].result() + thread[2].result();

									    std::cout << "sum => " << result << std::endl;

									    return a.exec();

									}

QMutex 互斥同步线程锁

QMutex类是基于互斥量的线程同步锁,该锁lock()锁定与unlock()解锁必须配对使用,线程锁保证线程间的互斥,利用线程锁能够保证临界资源的安全性.

线程锁解决的问题: 多个线程同时操作同一个全局变量,为了防止资源的无序覆盖现象,从而需要增加锁,来实现多线程抢占资源时可以有序执行.
临界资源(Critical Resource): 每次只允许一个线程进行访问 (读/写)的资源.
线程间的互斥(竞争): 多个线程在同一时刻都需要访问临界资源.
一般性原则: 每一个临界资源都需要一个线程锁进行保护.

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									#include <QCoreApplication>

									#include <iostream>

									#include <QThread>

									#include <QMutex>

									static QMutex g_mutex;      // 线程锁

									static QString g_store;     // 定义全局变量

									class Producer : public QThread

									{

									protected:

									    void run()

									    {

									        int count = 0;

									        while(true)

									        {

									            // 加锁

									            g_mutex.lock();

									            g_store.append(QString::number((count++) % 10));

									            std::cout << "Producer -> "<< g_store.toStdString() << std::endl;

									            // 释放锁

									            g_mutex.unlock();

									            msleep(900);

									        }

									    }

									};

									class Customer : public QThread

									{

									protected:

									    void run()

									    {

									        while( true )

									        {

									            g_mutex.lock();

									            if( g_store != "" )

									            {

									                g_store.remove(0, 1);

									                std::cout << "Curstomer -> "<< g_store.toStdString() << std::endl;

									            }

									            g_mutex.unlock();

									            msleep(1000);

									        }

									    }

									};

									int main(int argc, char *argv[])

									{

									    QCoreApplication a(argc, argv);

									    Producer p;

									    Customer c;

									    p.setObjectName("producer");

									    c.setObjectName("curstomer");

									    p.start();

									    c.start();

									    return a.exec();

									}

QMutexLocker是在QMutex基础上简化版的线程锁,QMutexLocker会保护加锁区域,并自动实现互斥量的锁定和解锁操作,可以将其理解为是智能版的QMutex锁,该锁只需要在上方代码中稍加修改即可.

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									#include <QMutex>

									#include <QMutexLocker>

									static QMutex g_mutex;      // 线程锁

									static QString g_store;     // 定义全局变量

									class Producer : public QThread

									{

									protected:

									    void run()

									    {

									        int count = 0;

									        while(true)

									        {

									            // 增加智能线程锁

									            QMutexLocker Locker(&g_mutex);

									            g_store.append(QString::number((count++) % 10));

									            std::cout << "Producer -> "<< g_store.toStdString() << std::endl;

									            msleep(900);

									        }

									    }

									};

互斥锁存在一个问题,每次只能有一个线程获得互斥量的权限,如果在程序中有多个线程来同时读取某个变量,那么使用互斥量必须排队,效率上会大打折扣,基于QReadWriteLock读写模式进行代码段锁定,即可解决互斥锁存在的问题.

QReadWriteLock 读写同步线程锁

该锁允许用户以同步读lockForRead()或同步写lockForWrite()两种方式实现保护资源,但只要有一个线程在以写的方式操作资源,其他线程也会等待写入操作结束后才可继续读资源.

				?

									#include <QCoreApplication>

									#include <iostream>

									#include <QThread>

									#include <QMutex>

									#include <QReadWriteLock>

									static QReadWriteLock g_mutex;      // 线程锁

									static QString g_store;             // 定义全局变量

									class Producer : public QThread

									{

									protected:

									    void run()

									    {

									        int count = 0;

									        while(true)

									        {

									            // 以写入方式锁定资源

									            g_mutex.lockForWrite();

									            g_store.append(QString::number((count++) % 10));

									            // 写入后解锁资源

									            g_mutex.unlock();

									            msleep(900);

									        }

									    }

									};

									class Customer : public QThread

									{

									protected:

									    void run()

									    {

									        while( true )

									        {

									            // 以读取方式写入资源

									            g_mutex.lockForRead();

									            if( g_store != "" )

									            {

									                std::cout << "Curstomer -> "<< g_store.toStdString() << std::endl;

									            }

									            // 读取到后解锁资源

									            g_mutex.unlock();

									            msleep(1000);

									        }

									    }

									};

									int main(int argc, char *argv[])

									{

									    QCoreApplication a(argc, argv);

									    Producer p1,p2;

									    Customer c1,c2;

									    p1.setObjectName("producer 1");

									    p2.setObjectName("producer 2");

									    c1.setObjectName("curstomer 1");

									    c2.setObjectName("curstomer 2");

									    p1.start();

									    p2.start();

									    c1.start();

									    c2.start();

									    return a.exec();

									}

QSemaphore 基于信号线程锁

信号量是特殊的线程锁,信号量允许N个线程同时访问临界资源,通过acquire()获取到指定资源,release()释放指定资源.

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									#include <QCoreApplication>

									#include <iostream>

									#include <QThread>

									#include <QSemaphore>

									const int SIZE = 5;

									unsigned char g_buff[SIZE] = {0};

									QSemaphore g_sem_free(SIZE); // 5个可生产资源

									QSemaphore g_sem_used(0);    // 0个可消费资源

									// 生产者生产产品

									class Producer : public QThread

									{

									protected:

									    void run()

									    {

									        while( true )

									        {

									            int value = qrand() % 256;

									            // 若无法获得可生产资源，阻塞在这里

									            g_sem_free.acquire();

									            for(int i=0; i<SIZE; i++)

									            {

									                if( !g_buff[i] )

									                {

									                    g_buff[i] = value;

									                    std::cout << objectName().toStdString() << " --> " << value << std::endl;

									                    break;

									                }

									            }

									            // 可消费资源数+1

									            g_sem_used.release();

									            sleep(2);

									        }

									    }

									};

									// 消费者消费产品

									class Customer : public QThread

									{

									protected:

									    void run()

									    {

									        while( true )

									        {

									            // 若无法获得可消费资源，阻塞在这里

									            g_sem_used.acquire();

									            for(int i=0; i<SIZE; i++)

									            {

									                if( g_buff[i] )

									                {

									                    int value = g_buff[i];

									                    g_buff[i] = 0;

									                    std::cout << objectName().toStdString() << " --> " << value << std::endl;

									                    break;

									                }

									            }

									            // 可生产资源数+1

									            g_sem_free.release();

									            sleep(1);

									        }

									    }

									};

									int main(int argc, char *argv[])

									{

									    QCoreApplication a(argc, argv);

									    Producer p1;

									    Customer c1;

									    p1.setObjectName("producer");

									    c1.setObjectName("curstomer");

									    p1.start();

									    c1.start();

									    return a.exec();

									}