死锁
互斥锁:Lock(),互斥锁只能acquire一次
递归锁: RLock(),可以连续acquire多次,每acquire一次计数器+1,只有计数为0时,才能被抢到acquire
# 死锁
from threading import Thread,Lock
import time mutexA = Lock()
mutexB = Lock() class MyThread(Thread):
def run(self):
self.f1()
self.f2() def f1(self):
mutexA.acquire()
print('%s 拿到了A锁' %self.name) mutexB.acquire()
print('%s 拿到了B锁' % self.name)
mutexB.release()
mutexA.release() def f2(self):
mutexB.acquire()
print('%s 拿到了B锁' % self.name)
time.sleep(0.1) mutexA.acquire()
print('%s 拿到了A锁' % self.name)
mutexB.release()
mutexA.release() if __name__ == '__main__':
for i in range(10):
t=MyThread()
t.start()
'''
打印结果:
Thread-1 拿到了A锁
Thread-1 拿到了B锁
Thread-1 拿到了B锁
Thread-2 拿到了A锁
'''
死锁
#互斥锁只能acquire一次
from threading import Thread,Lock
mutexA = Lock()
mutexA.acquire()
mutexA.release() #递归锁:可以连续acquire多次,每acquier一次计数器就+1,只有计数为0时,才能被其他线程强到
from threading import Thread,RLock
import time mutexB = mutexA = RLock() class MyThread(Thread):
def run(self):
self.f1()
self.f2() def f1(self):
mutexA.acquire()
print('%s 拿到了A锁' %self.name) mutexB.acquire()
print('%s 拿到了B锁' % self.name)
mutexB.release()
mutexA.release() def f2(self):
mutexB.acquire()
print('%s 拿到了B锁' % self.name)
time.sleep(2) mutexA.acquire()
print('%s 拿到了A锁' % self.name)
mutexB.release()
mutexA.release() if __name__ == '__main__':
for i in range(10):
t=MyThread()
t.start()
'''
打印结果:
Thread-1 拿到了A锁
Thread-1 拿到了B锁
Thread-1 拿到了B锁
Thread-1 拿到了A锁
Thread-2 拿到了A锁
Thread-2 拿到了B锁
Thread-2 拿到了B锁
Thread-2 拿到了A锁
Thread-4 拿到了A锁
Thread-4 拿到了B锁
Thread-4 拿到了B锁
Thread-4 拿到了A锁
Thread-6 拿到了A锁
Thread-6 拿到了B锁
Thread-6 拿到了B锁
Thread-6 拿到了A锁
Thread-8 拿到了A锁
Thread-8 拿到了B锁
Thread-8 拿到了B锁
Thread-8 拿到了A锁
Thread-10 拿到了A锁
Thread-10 拿到了B锁
Thread-10 拿到了B锁
Thread-10 拿到了A锁
Thread-5 拿到了A锁
Thread-5 拿到了B锁
Thread-5 拿到了B锁
Thread-5 拿到了A锁
Thread-9 拿到了A锁
Thread-9 拿到了B锁
Thread-9 拿到了B锁
Thread-9 拿到了A锁
Thread-7 拿到了A锁
Thread-7 拿到了B锁
Thread-7 拿到了B锁
Thread-7 拿到了A锁
Thread-3 拿到了A锁
Thread-3 拿到了B锁
Thread-3 拿到了B锁
Thread-3 拿到了A锁
'''
递归锁
信号量
信号量也是一把锁,可以指定信号量为5,对比互斥锁同一时间只能有一个任务抢到锁去执行
信号量同一时间可以有5个任务拿到锁去执行
信号量:同一时间有多个线程在进行
from threading import Thread,Semaphore,currentThread
import time,random sm=Semaphore(3) #厕所的坑 def task():
# sm.acquire()
# print('%s in' %currentThread.getName())
# sm.release()
with sm:
print('%s in' %currentThread().getName())
time.sleep(random.randint(2,3)) if __name__ == '__main__':
for i in range(10):
t=Thread(target=task)
t.start()
'''
打印结果:
Thread-1 in
Thread-2 in
Thread-3 in Thread-4 in Thread-5 in
Thread-6 in Thread-7 in Thread-9 in
Thread-8 in
Thread-10 in
'''
信号量
Event事件
event.isSet(): 返回event的状态值
event.wait():如果 event.isSet()==False将阻塞线程
event.set(): 设置event的状态值为True,所有阻塞池的线程激活进入就绪状态,等待操作系统调度
event.clear(): 恢复event的状态值为False
from threading import Thread,Event
import time event = Event()
# event.wait() 在原地等,指导执行到event.set()
# event.set() 等待结束 def student(name):
print('学生%s 正在听课' %name)
event.wait(2)
print('学生%s 课间活动' %name) def teacher(name):
print('老师%s 正在授课' %name)
time.sleep(5)
event.set() if __name__ == '__main__':
stu1 = Thread(target=student,args=('alex',))
stu2 = Thread(target=student,args=('yang',))
stu3 = Thread(target=student,args=('hang',))
tea1 = Thread(target=teacher,args=('ding',)) stu1.start()
stu2.start()
stu3.start()
tea1.start()
'''
打印结果:
学生alex 正在听课
学生yang 正在听课
学生hang 正在听课
老师ding 正在授课
学生hang 课间活动
学生yang 课间活动
学生alex 课间活动
''' #设置连接的超时时间
from threading import Thread,Event,currentThread
import time event = Event() def conn():
n=0
while not event.is_set():
if n == 3:
print('%s try too many' %currentThread().getName())
return
print('%s try %s' %(currentThread().getName(),n))
event.wait(0.5)
n+=1 print('%s is connecting' %currentThread().getName()) def check():
print('%s is checking' %currentThread().getName())
time.sleep(5)
event.set() if __name__ == '__main__':
for i in range(3):
t=Thread(target=conn)
t.start()
t=Thread(target=check)
t.start()
'''
打印结果:
Thread-1 try 0
Thread-2 try 0
Thread-3 try 0
Thread-4 is checking
Thread-1 try 1
Thread-3 try 1
Thread-2 try 1
Thread-1 try 2
Thread-3 try 2
Thread-2 try 2
Thread-1 try too many
Thread-3 try too many
Thread-2 try too many
'''
Event
定时器
定时器:隔一段时间,执行一个任务,每启动一个定时器,就等于启动一个线程
t=Timer(5,task,args=('egon',))
t.start()
t.cancel()
# from threading import Timer
#
# def task(name):
# print('hello %s' %name)
#
# t=Timer(5,task,args=('egon',))
# t.start() #验证码
from threading import Timer
import random class Code:
def __init__(self):
self.make_cache() def make_cache(self,interval=60):
self.cache = self.make_code()
print(self.cache)
self.t = Timer(interval,self.make_cache)
self.t.start() def make_code(self,n=4):
res=''
for i in range(n):
s1 = str(random.randint(0,9))
s2 = chr(random.randint(65,90))
res+=random.choice([s1,s2])
return res def check(self):
while True:
code = input('输入你的验证码>>: ').strip()
if code.upper() == self.cache:
print('验证码输入正确')
self.t.cancel()
break obj=Code()
obj.check() '''
打印结果:
X095
输入你的验证码>>: X095
验证码输入正确
'''
定时器