同步锁

import  time, threading

def addNum():

    global num

    num -= 1

num = 100

thread_list = []

for i in range(100):

    t = threading.Thread(target=addNum)

    t.start()

    thread_list.append(t)

for t in thread_list:

    t.join()

print('final num:', num)

运行结果:

final num: 0

import  time, threading

def addNum():

    global num

    #num -= 1

    tmp = num

    time.sleep(0.00001)

    num = tmp - 1

num = 100

thread_list = []

for i in range(100):

    t = threading.Thread(target=addNum)

    t.start()

    thread_list.append(t)

for t in thread_list:

    t.join()

print('final num:', num)

运行结果:

final num: 93

或

final num: 91

或

final num: 94

原因：

第一个程序中，num -= 1 这种写法，程序执行动作太快(完成这个动作在 cup 切换的时间内)

第二个程序中，把 num -= 1 , 加入了 sleep 时间，100个线程存在没有执行完就进行了切换，导致全局的 num 没有正常返回。引用下大神的图发现总结得非常好：



在上面的例子中 使用 join 方法会把整个线程停住，造成了串行，失去了多线程的意义，我们只需要在涉及到计算公共数据的时候串行执行即可。

使用同步锁处理计算公共的数据

import  time, threading

def addNum():

    global num

    lock.acquire()

    tmp = num

    time.sleep(0.00001)

    num = tmp - 1

    lock.release()

num = 100

lock = threading.Lock()

thread_list = []

for i in range(100):

    t = threading.Thread(target=addNum)

    t.start()

    thread_list.append(t)

for t in thread_list:

    t.join()

print('final num:', num)

运算结果:

final num: 0

线程死锁和递归锁

import  threading, time

class myThread(threading.Thread):

    def doA(self):

        lockA.acquire()

        print(self.name, "gotlockA", time.ctime())

        time.sleep(3)

        lockB.acquire()

        print(self.name, "gotlockB", time.ctime())

        lockB.release()

        lockA.release()

    def doB(self):

        lockB.acquire()

        print(self.name, "gotlockB", time.ctime())

        time.sleep(2)

        lockA.acquire()

        print(self.name, "gotlockA", time.ctime())

        lockA.release()

        lockB.release()

    def run(self):

        self.doA()

        self.doB()

if __name__ == '__main__':

    lockA = threading.Lock()

    lockB = threading.Lock()

    threads = []

    for i in range(5):

        threads.append(myThread())

    for t in threads:

        t.start()

    for t in threads:

        t.join()

#运行结果:

Thread-1 gotlockA Sat Jul 28 15:09:31 2018

Thread-1 gotlockB Sat Jul 28 15:09:34 2018

Thread-1 gotlockB Sat Jul 28 15:09:34 2018

Thread-2 gotlockA Sat Jul 28 15:09:34 2018

使用递归锁

import  threading, time

class myThread(threading.Thread):

    def doA(self):

        lock.acquire()

        print(self.name, "gotlockA", time.ctime())

        time.sleep(3)

        lock.acquire()

        print(self.name, "gotlockB", time.ctime())

        lock.release()

        lock.release()

    def doB(self):

        lock.acquire()

        print(self.name, "gotlockB", time.ctime())

        time.sleep(2)

        lock.acquire()

        print(self.name, "gotlockA", time.ctime())

        lock.release()

        lock.release()

    def run(self):

        self.doA()

        self.doB()

if __name__ == '__main__':

    lock = threading.RLock()

    threads = []

    for i in range(5):

        threads.append(myThread())

    for t in threads:

        t.start()

    for t in threads:

        t.join()

运行结果:

Thread-1 gotlockA Sat Jul 28 15:19:35 2018

Thread-1 gotlockB Sat Jul 28 15:19:38 2018

Thread-1 gotlockB Sat Jul 28 15:19:38 2018

Thread-1 gotlockA Sat Jul 28 15:19:40 2018

Thread-3 gotlockA Sat Jul 28 15:19:40 2018

Thread-3 gotlockB Sat Jul 28 15:19:43 2018

Thread-3 gotlockB Sat Jul 28 15:19:43 2018

Thread-3 gotlockA Sat Jul 28 15:19:45 2018

Thread-5 gotlockA Sat Jul 28 15:19:45 2018

Thread-5 gotlockB Sat Jul 28 15:19:48 2018

Thread-5 gotlockB Sat Jul 28 15:19:48 2018

Thread-5 gotlockA Sat Jul 28 15:19:50 2018

Thread-4 gotlockA Sat Jul 28 15:19:50 2018

Thread-4 gotlockB Sat Jul 28 15:19:53 2018

Thread-4 gotlockB Sat Jul 28 15:19:53 2018

Thread-4 gotlockA Sat Jul 28 15:19:55 2018

Thread-2 gotlockA Sat Jul 28 15:19:55 2018

Thread-2 gotlockB Sat Jul 28 15:19:58 2018

Thread-2 gotlockB Sat Jul 28 15:19:58 2018

Thread-2 gotlockA Sat Jul 28 15:20:00 2018

信号量

信号量用来控制线程并发数的，BoundedSemaphore或Semaphore管理一个内置的计数 器，每当调用acquire()时-1，调用release()时+1,计数器不能小于0，当计数器为 0时，acquire()将阻塞线程至同步锁定状态，直到其他线程调用release()。(类似于停车位的概念)。

BoundedSemaphore与Semaphore的唯一区别在于前者将在调用release()时检查计数 器的值是否超过了计数器的初始值，如果超过了将抛出一个异常。

import threading, time

class myThread(threading.Thread):

    def run(self):

        if semaphore.acquire():

            print(self.name)

            time.sleep(5)

            semaphore.release()

if __name__ == "__main__":

    semaphore = threading.Semaphore(5)

    thrs = []

    for i in range(20):

        thrs.append(myThread())

    for t in thrs:

        t.start()

#运行结果:

Thread-1

Thread-2

Thread-3

Thread-4

Thread-5

Thread-6

Thread-7

Thread-9

Thread-10

Thread-8

Thread-11

Thread-13

Thread-14

Thread-12

Thread-15

Thread-18

Thread-16

Thread-17

Thread-19

Thread-20

import threading, time

class myThread(threading.Thread):

    def run(self):

        if semaphore.acquire():

            print(self.name)

            time.sleep(5)

            semaphore.release()

if __name__ == "__main__":

    semaphore = threading.BoundedSemaphore(5)

    thrs = []

    for i in range(20):

        thrs.append(myThread())

    for t in thrs:

        t.start()

#运行结果:

Thread-1

Thread-2

Thread-3

Thread-4

Thread-5

Thread-6

Thread-8

Thread-10

Thread-9

Thread-7

Thread-12

Thread-14

Thread-15

Thread-13

Thread-11

Thread-16

Thread-17

Thread-20

Thread-19

Thread-18