423A35C7/os_kernel_lab
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity

add python threading examples and intros for lec 18 spoc discuss

Browse Source
This commit is contained in:
yuchen 2015-05-06 12:41:12 +08:00
parent b233b49dcb
commit 340eebff1b
10 changed files with 629 additions and 0 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

337
related_info/lab7/semaphore_condition/README.md Normal file
View File

@ -0,0 +1,337 @@
From:
- http://www.laurentluce.com/posts/python-threads-synchronization-locks-rlocks-semaphores-conditions-events-and-queues/
- http://yoyzhou.github.io/blog/2013/02/28/python-threads-synchronization-locks/
- http://blog.chinaunix.net/uid-429659-id-3186991.html
- http://blog.csdn.net/yidangui/article/details/8707187
- http://blog.csdn.net/yidangui/article/details/8707205
- http://blog.csdn.net/yidangui/article/details/8707209
- http://blog.csdn.net/yidangui/article/details/8707197
## threads: Python threads synchronization: Locks, RLocks, Semaphores, Conditions, Events and Queues.
### threading简介
python是支持多线程的并且是native的线程。主要是通过thread和threading这两个模块来实现的。
#### 实现模块
- thread多线程的底层支持模块一般不建议使用
- threading对thread进行了封装将一些线程的操作对象化。
#### threading模块
- Timer与Thread类似但要等待一段时间后才开始运行
- Lock 锁原语,这个我们可以对全局变量互斥时使用;
- RLock 可重入锁,使单线程可以再次获得已经获得的锁;
- Condition 条件变量,能让一个线程停下来,等待其他线程满足某个“条件”;
- Event 通用的条件变量。多个线程可以等待某个事件发生,在事件发生后,所有的线程都被激活;
- Semaphore为等待锁的线程提供一个类似“等候室”的结构
- BoundedSemaphore 与semaphore类似但不允许超过初始值
- Queue实现了多生产者Producer、多消费者Consumer的队列支持锁原语能够在多个线程之间提供很好的同步支持。
thread是比较底层的模块threading是对thread做了一些包装的可以更加方便的被使用。创建thread的方式有
- 第一种方式:创建一个threading.Thread()的实例对象给它一个函数。在它的初始化函数__init__中将可调用对象作为参数传入
- 第二种方式:创建一个threading.Thread的实例传给它一个可调用类对象类中使用__call__()函数调用函数
- 第三种方式:是通过继承Thread类重写它的run方法
第一种和第三种常用。
第一种方式举例:
```
#coding=utf-8
import threading
def thread_fun(num):
for n in range(0, int(num)):
print " I come from %s, num: %s" %( threading.currentThread().getName(), n)
def main(thread_num):
thread_list = list();
# 先创建线程对象
for i in range(0, thread_num):
thread_name = "thread_%s" %i
thread_list.append(threading.Thread(target = thread_fun, name = thread_name, args = (20,)))
# 启动所有线程
for thread in thread_list:
thread.start()
# 主线程中等待所有子线程退出
for thread in thread_list:
thread.join()
if __name__ == "__main__":
main(3)
```
第三种方式举例1
```
#!/usr/bin/env python
import threading
import time
count=1
class KissThread(threading.Thread):
def run(self):
global count
print "Thread # %s:Pretending to do stuff" % count
count+=1
time.sleep(2)
print "done with stuff"
for t in range(5):
KissThread().start()
```
第三种方式举例2
```
import threading
class MyThread(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
print "I am %s" % (self.name)
if __name__ == "__main__":
for i in range(0, 5):
my_thread = MyThread()
my_thread.start()
```
### Thread类常用方法
#### getName(self)
返回线程的名字
#### setName方法
可以指定每一个thread的name
```
def __init__(self):
threading.Thread.__init__(self)
self.setName("new" + self.name)
```
#### isAlive(self)
布尔标志,表示这个线程是否还在运行中
#### isDaemon(self)
返回线程的daemon标志
#### run(self)
定义线程的功能函数
#### start方法
启动线程
#### join方法
join方法原型如下这个方法是用来程序挂起直到线程结束如果给出timeout则最多阻塞timeout秒
```
def join(self, timeout=None):
```
#### setDaemon方法
当我们在程序运行中执行一个主线程如果主线程又创建一个子线程主线程和子线程就分兵两路当主线程完成想退出时会检验子线程是否完成。如果子线程未完成则主线程会等待子线程完成后再退出。但是有时候我们需要的是只要主线程完成了不管子线程是否完成都要和主线程一起退出这时就可以用setDaemon方法并设置其参数为True。
### Queue提供的类
- Queue队列
- LifoQueue后入先出LIFO队列
- PriorityQueue 优先队列
### 互斥锁
Python编程中引入了对象互斥锁的概念来保证共享数据操作的完整性。每个对象都对应于一个可称为" 互斥锁" 的标记这个标记用来保证在任一时刻只能有一个线程访问该对象。在Python中我们使用threading模块提供的Lock类。添加一个互斥锁变量mutex = threading.Lock()然后在争夺资源的时候之前我们会先抢占这把锁mutex.acquire()对资源使用完成之后我们在释放这把锁mutex.release()。
当一个线程调用Lock对象的acquire()方法获得锁时这把锁就进入“locked”状态。因为每次只有一个线程可以获得锁所以如果此时另一个线程试图获得这个锁该线程就会变为同步阻塞状态。直到拥有锁的线程调用锁的release()方法释放锁之后该锁进入“unlocked”状态。线程调度程序从处于同步阻塞状态的线程中选择一个来获得锁并使得该线程进入运行running状态。
```
import threading
import time
counter = 0
mutex = threading.Lock()
class MyThread(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
global counter, mutex
time.sleep(1);
if mutex.acquire():
counter += 1
print "I am %s, set counter:%s" % (self.name, counter)
mutex.release()
if __name__ == "__main__":
for i in range(0, 100):
my_thread = MyThread()
my_thread.start()
```
### Condition条件变量
Python提供的Condition对象提供了对复杂线程同步问题的支持。Condition被称为条件变量除了提供与Lock类似的acquire和release方法外还提供了wait和notify方法。使用Condition的主要方式为线程首先acquire一个条件变量然后判断一些条件。如果条件不满足则wait如果条件满足进行一些处理改变条件后通过notify方法通知其他线程其他处于wait状态的线程接到通知后会重新判断条件。不断的重复这一过程从而解决复杂的同步问题。
另外Condition对象的构造函数可以接受一个Lock/RLock对象作为参数如果没有指定则Condition对象会在内部自行创建一个RLock除了notify方法外Condition对象还提供了notifyAll方法可以通知waiting池中的所有线程尝试acquire内部锁。由于上述机制处于waiting状态的线程只能通过notify方法唤醒所以notifyAll的作用在于防止有线程永远处于沉默状态。
#### “生产者-消费者”模型
代码中主要实现了生产者和消费者线程双方将会围绕products来产生同步问题首先是2个生成者生产products 而接下来的4个消费者将会消耗products.
实现举例:
```
#coding=utf-8
#!/usr/bin/env python
import threading
import time
condition = threading.Condition()
products = 0
class Producer(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
global condition, products
while True:
if condition.acquire():
if products < 10:
products += 1;
print "Producer(%s):deliver one, now products:%s" %(self.name, products)
condition.notify()
else:
print "Producer(%s):already 10, stop deliver, now products:%s" %(self.name, products)
condition.wait();
condition.release()
time.sleep(1)
class Consumer(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
global condition, products
while True:
if condition.acquire():
if products > 1:
products -= 1
print "Consumer(%s):consume one, now products:%s" %(self.name, products)
condition.notify()
else:
print "Consumer(%s):only 1, stop consume, products:%s" %(self.name, products)
condition.wait();
condition.release()
time.sleep(2)
if __name__ == "__main__":
for p in range(0, 2):
p = Producer()
p.start()
for c in range(0, 4):
c = Consumer()
c.start()
```
### 信号量semaphore
semaphore是一个变量控制着对公共资源或者临界区的访问。信号量维护着一个计数器指定可同时访问资源或者进入临界区的线程数。每次有一个线程获得信号量时计数器-1。若计数器为0其他线程就停止访问信号量直到另一个线程释放信号量。
```
#coding=utf-8
import threading
import random
import time
class SemaphoreThread(threading.Thread):
"""class using semaphore"""
availableTables=['A','B','C','D','E']
def __init__(self,threadName,semaphore):
"""initialize thread"""
threading.Thread.__init__(self,name=threadName)
self.sleepTime=random.randrange(1,6)
#set the semaphore as a data attribute of the class
self.threadSemaphore=semaphore
def run(self):
"""Print message and release semaphore"""
#acquire the semaphore
self.threadSemaphore.acquire()
#remove a table from the list
table=SemaphoreThread.availableTables.pop()
print "%s entered;seated at table %s." %(self.getName(),table),
print SemaphoreThread.availableTables
time.sleep(self.sleepTime)
#free a table
print " %s exiting;freeing table %s." %(self.getName(),table),
SemaphoreThread.availableTables.append(table)
print SemaphoreThread.availableTables
#release the semaphore after execution finishes
self.threadSemaphore.release()
threads=[] #list of threads
#semaphore allows five threads to enter critical section
threadSemaphore=threading.Semaphore(len(SemaphoreThread.availableTables))
#创建一个threading.Semaphore对象他最多允许5个线程访问临界区。
#Semaphore类的一个对象用计数器跟踪获取和释放信号量的线程数量
#create ten threads
for i in range(1,11):
threads.append(SemaphoreThread("thread"+str(i),threadSemaphore))
#创建一个列表该列表由SemaphoreThread对象构成start方法开始列表中的每个线程
#start each thread
for thread in threads:
thread.start()
```
SemaphoreThread类的每个对象代表饭馆里的一个客人。类属性availableTables跟踪饭馆中可用的桌子。
信号量有个内建的计数器用于跟踪他的acquire和release方法调用的次数。内部计数器的初始值可作为参数传给Semaphore构造函数。默认值为1.计数器大于0Semaphore的acquire方法就为线程获得信号量并计数器自减。
### 死锁现象
所谓死锁: 是指两个或两个以上的进程在执行过程中,因争夺资源而造成的一种互相等待的现象,若无外力作用,它们都将无法推进下去。此时称系统处于死锁状态或系统产生了死锁,这些永远在互相等待的进程称为死锁进程。 由于资源占用是互斥的,当某个进程提出申请资源后,使得有关进程在无外力协助下,永远分配不到必需的资源而无法继续运行,这就产生了一种特殊现象死锁。
```
import threading
counterA = 0
counterB = 0
mutexA = threading.Lock()
mutexB = threading.Lock()
class MyThread(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
self.fun1()
self.fun2()
def fun1(self):
global mutexA, mutexB
if mutexA.acquire():
print "I am %s , get res: %s" %(self.name, "ResA")
if mutexB.acquire():
print "I am %s , get res: %s" %(self.name, "ResB")
mutexB.release()
mutexA.release()
def fun2(self):
global mutexA, mutexB
if mutexB.acquire():
print "I am %s , get res: %s" %(self.name, "ResB")
if mutexA.acquire():
print "I am %s , get res: %s" %(self.name, "ResA")
mutexA.release()
mutexB.release()
if __name__ == "__main__":
for i in range(0, 100):
my_thread = MyThread()
my_thread.start()
```

24
related_info/lab7/semaphore_condition/thr-ex0.py Normal file
View File

@ -0,0 +1,24 @@
#coding=utf-8
import threading
def thread_fun(num):
for n in range(0, int(num)):
print " I come from %s, num: %s" %( threading.currentThread().getName(), n)
def main(thread_num):
thread_list = list();
# 先创建线程对象
for i in range(0, thread_num):
thread_name = "thread_%s" %i
thread_list.append(threading.Thread(target = thread_fun, name = thread_name, args = (20,)))
# 启动所有线程
for thread in thread_list:
thread.start()
# 主线程中等待所有子线程退出
for thread in thread_list:
thread.join()
if __name__ == "__main__":
main(3)

43
related_info/lab7/semaphore_condition/thr-ex1.py Normal file
View File

@ -0,0 +1,43 @@
#!/bin/env python
# -*- coding: utf-8 -*-
#filename: peartest.py
import threading, signal
is_exit = False
def doStress(i, cc):
global is_exit
idx = i
while not is_exit:
if (idx < 10000000):
print "thread[%d]: idx=%d"%(i, idx)
idx = idx + cc
else:
break
if is_exit:
print "receive a signal to exit, thread[%d] stop."%i
else:
print "thread[%d] complete."%i
def handler(signum, frame):
global is_exit
is_exit = True
print "receive a signal %d, is_exit = %d"%(signum, is_exit)
if __name__ == "__main__":
signal.signal(signal.SIGINT, handler)
signal.signal(signal.SIGTERM, handler)
cc = 5
threads = []
for i in range(cc):
t = threading.Thread(target=doStress, args=(i,cc))
t.setDaemon(True)
threads.append(t)
t.start()
while 1:
alive = False
for i in range(cc):
alive = alive or threads[i].isAlive()
if not alive:
break

16
related_info/lab7/semaphore_condition/thr-ex2.py Normal file
View File

@ -0,0 +1,16 @@
#!/usr/bin/env python
import threading
import time
count=1
class KissThread(threading.Thread):
def run(self):
global count
print "Thread # %s:Pretending to do stuff" % count
count+=1
time.sleep(2)
print "done with stuff"
for t in range(5):
KissThread().start()

33
related_info/lab7/semaphore_condition/thr-ex3.py Normal file
View File

@ -0,0 +1,33 @@
#coding=utf-8
#!/usr/bin/env python
import subprocess
from threading import Thread
from Queue import Queue
num_thread=3 #定义线程的数量
queue=Queue() #创建队列实例
ips=['192.168.1.100','192.168.1.110','192.168.1.120','192.168.1.130','192.168.1.200']
def pinger(i,q):
while True:
ip=q.get() #获取Queue队列传过来的ip队列使用队列实例queue.put(ip)传入ip通过q.get() 获得
print "Thread %s:Pinging %s" %(i,ip)
ret=subprocess.call("ping -c 1 %s" % ip,shell=True,stdout=open('/dev/null','w'),stderr=subprocess.STDOUT)
#调用子进程执行命令获取退出状态。不能使用subprocess.Popen也可以
if ret==0:
print "%s:is alive" % ip
else:
print "%s:did not respond" % ip
q.task_done() #告诉queue.join()已完成队列中提取元组的工作
for i in range(num_thread):#各线程开始工作
worker=Thread(target=pinger,args=(i,queue)) #创建一个threading.Thread()的实例,给它一个函数以及函数的参数
worker.setDaemon(True) #在start方法被调用之前如果没有进行设置程序会不定期挂起。
worker.start() #开始线程的工作没有设置程序会挂起不会开始线程的工作因为pinger程序是while True循环
for ip in ips:
queue.put(ip) #将IP放入队列中。函数中使用q.get(ip)获取
print "Main Thread Waiting"
queue.join() #防止主线程在其他线程获得机会完成队列中任务之前从程序中退出。
print "Done"

13
related_info/lab7/semaphore_condition/thr-ex4.py Normal file
View File

@ -0,0 +1,13 @@
import threading
class MyThread(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
print "I am %s" % (self.name)
if __name__ == "__main__":
for i in range(0, 5):
my_thread = MyThread()
my_thread.start()

53
related_info/lab7/semaphore_condition/thr-ex5.py Normal file
View File

@ -0,0 +1,53 @@
#coding=utf-8
#!/usr/bin/env python
import threading
import time
condition = threading.Condition()
products = 0
class Producer(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
global condition, products
while True:
if condition.acquire():
if products < 10:
products += 1;
print "Producer(%s):deliver one, now products:%s" %(self.name, products)
condition.notify()
else:
print "Producer(%s):already 10, stop deliver, now products:%s" %(self.name, products)
condition.wait();
condition.release()
time.sleep(2)
class Consumer(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
global condition, products
while True:
if condition.acquire():
if products > 1:
products -= 1
print "Consumer(%s):consume one, now products:%s" %(self.name, products)
condition.notify()
else:
print "Consumer(%s):only 1, stop consume, products:%s" %(self.name, products)
condition.wait();
condition.release()
time.sleep(2)
if __name__ == "__main__":
for p in range(0, 2):
p = Producer()
p.start()
for c in range(0, 10):
c = Consumer()
c.start()

22
related_info/lab7/semaphore_condition/thr-ex6.py Normal file
View File

@ -0,0 +1,22 @@
import threading
import time
counter = 0
mutex = threading.Lock()
class MyThread(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
global counter, mutex
time.sleep(1);
if mutex.acquire():
counter += 1
print "I am %s, set counter:%s" % (self.name, counter)
mutex.release()
if __name__ == "__main__":
for i in range(0, 100):
my_thread = MyThread()
my_thread.start()

46
related_info/lab7/semaphore_condition/thr-ex7.py Normal file
View File

@ -0,0 +1,46 @@
#coding=utf-8
import threading
import random
import time
class SemaphoreThread(threading.Thread):
"""classusing semaphore"""
availableTables=['A','B','C','D','E']
def __init__(self,threadName,semaphore):
"""initialize thread"""
threading.Thread.__init__(self,name=threadName)
self.sleepTime=random.randrange(1,6)
#set the semaphore as a data attribute of the class
self.threadSemaphore=semaphore
def run(self):
"""Print message and release semaphore"""
#acquire the semaphore
self.threadSemaphore.acquire()
#remove a table from the list
table=SemaphoreThread.availableTables.pop()
print "%s entered;seated at table %s." %(self.getName(),table),
print SemaphoreThread.availableTables
time.sleep(self.sleepTime)
#free a table
print " %s exiting;freeing table %s." %(self.getName(),table),
SemaphoreThread.availableTables.append(table)
print SemaphoreThread.availableTables
#release the semaphore after execution finishes
self.threadSemaphore.release()
threads=[] #list of threads
#semaphore allows five threads to enter critical section
threadSemaphore=threading.Semaphore(len(SemaphoreThread.availableTables))
#创建一个threading.Semaphore对象他最多允许5个线程访问临界区。
#Semaphore类的一个对象用计数器跟踪获取和释放信号机的线程数量。
#create ten threads
for i in range(1,11):
threads.append(SemaphoreThread("thread"+str(i),threadSemaphore))
#创建一个列表该列表由SemaphoreThread对象构成start方法开始列表中的每个线程
#start each thread
for thread in threads:
thread.start()

42
related_info/lab7/semaphore_condition/thr-ex8.py Normal file
View File

@ -0,0 +1,42 @@
import threading
counterA = 0
counterB = 0
mutexA = threading.Lock()
mutexB = threading.Lock()
class MyThread(threading.Thread):
def __init__(self):
threading.Thread.__init__(self)
def run(self):
self.fun1()
self.fun2()
def fun1(self):
global mutexA, mutexB
if mutexA.acquire():
print "I am %s , get res: %s" %(self.name, "ResA")
if mutexB.acquire():
print "I am %s , get res: %s" %(self.name, "ResB")
mutexB.release()
mutexA.release()
def fun2(self):
global mutexA, mutexB
if mutexB.acquire():
print "I am %s , get res: %s" %(self.name, "ResB")
if mutexA.acquire():
print "I am %s , get res: %s" %(self.name, "ResA")
mutexA.release()
mutexB.release()
if __name__ == "__main__":
for i in range(0, 100):
my_thread = MyThread()
my_thread.start()