异步io\数据库\队列\缓存

本节内容

1. Gevent协程
2. Select\Poll\Epoll异步IO与事件驱动
3. Python链接Mysql数据库操做
4. RabbitMQ队列
5. Redis\Memcached缓存
6. Paramiko SSH
7. Twsited网络框架

---

 

引子

到目前为止，咱们已经学了网络并发编程的2个套路， 多进程，多线程，这哥俩的优点和劣势都很是的明显，咱们一块儿来回顾下

协程

协程，又称微线程，纤程。英文名Coroutine。一句话说明什么是线程：协程是一种用户态的轻量级线程。

协程拥有本身的寄存器上下文和栈。协程调度切换时，将寄存器上下文和栈保存到其余地方，在切回来的时候，恢复先前保存的寄存器上下文和栈。所以：

协程能保留上一次调用时的状态（即全部局部状态的一个特定组合），每次过程重入时，就至关于进入上一次调用的状态，换种说法：进入上一次离开时所处逻辑流的位置。

 

协程的好处：

• 无需线程上下文切换的开销
• 无需原子操做锁定及同步的开销
  • 　　"原子操做(atomic operation)是不须要synchronized"，所谓原子操做是指不会被线程调度机制打断的操做；这种操做一旦开始，就一直运行到结束，中间不会有任何 context switch （切换到另外一个线程）。原子操做能够是一个步骤，也能够是多个操做步骤，可是其顺序是不能够被打乱，或者切割掉只执行部分。视做总体是原子性的核心。
• 方便切换控制流，简化编程模型
• 高并发+高扩展性+低成本：一个CPU支持上万的协程都不是问题。因此很适合用于高并发处理。

 

缺点：

• 没法利用多核资源：协程的本质是个单线程,它不能同时将 单个CPU 的多个核用上,协程须要和进程配合才能运行在多CPU上.固然咱们平常所编写的绝大部分应用都没有这个必要，除非是cpu密集型应用。
• 进行阻塞（Blocking）操做（如IO时）会阻塞掉整个程序

使用yield实现协程操做例子　　　　

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import  time import  queue def  consumer(name):      print ( "--->starting eating baozi..." )      while  True :          new_baozi  =  yield          print ( "[%s] is eating baozi %s"  %  (name,new_baozi))          #time.sleep(1)   def  producer():        r  =  con.__next__()      r  =  con2.__next__()      n  =  0      while  n <  5 :          n  + = 1          con.send(n)          con2.send(n)          print ( "\033[32;1m[producer]\033[0m is making baozi %s"  % n )     if  __name__  = =  '__main__' :      con  =  consumer( "c1" )      con2  =  consumer( "c2" )      p  =  producer()

看楼上的例子，我问你这算不算作是协程呢？你说，我他妈哪知道呀，你前面说了一堆废话，可是并没告诉我协程的标准形态呀，我腚眼一想，以为你说也对，那好，咱们先给协程一个标准定义，即符合什么条件就能称之为协程：

1. 必须在只有一个单线程里实现并发
2. 修改共享数据不需加锁
3. 用户程序里本身保存多个控制流的上下文栈
4. 一个协程遇到IO操做自动切换到其它协程

基于上面这4点定义，咱们刚才用yield实现的程并不能算是合格的线程，由于它有一点功能没实现，哪一点呢？

Greenlet

greenlet是一个用C实现的协程模块，相比与python自带的yield，它可使你在任意函数之间随意切换，而不需把这个函数先声明为generator

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# -*- coding:utf-8 -*-     from  greenlet  import  greenlet     def  test1():      print ( 12 )      gr2.switch()      print ( 34 )      gr2.switch()     def  test2():      print ( 56 )      gr1.switch()      print ( 78 )     gr1  =  greenlet(test1) gr2  =  greenlet(test2) gr1.switch()

感受确实用着比generator还简单了呢，但好像尚未解决一个问题，就是遇到IO操做，自动切换，对不对？

Gevent 

Gevent 是一个第三方库，能够轻松经过gevent实现并发同步或异步编程，在gevent中用到的主要模式是Greenlet, 它是以C扩展模块形式接入Python的轻量级协程。 Greenlet所有运行在主程序操做系统进程的内部，但它们被协做式地调度。

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import  gevent   def  func1():      print ( '\033[31;1m李闯在跟海涛搞...\033[0m' )      gevent.sleep( 2 )      print ( '\033[31;1m李闯又回去跟继续跟海涛搞...\033[0m' )   def  func2():      print ( '\033[32;1m李闯切换到了跟海龙搞...\033[0m' )      gevent.sleep( 1 )      print ( '\033[32;1m李闯搞完了海涛，回来继续跟海龙搞...\033[0m' )     gevent.joinall([      gevent.spawn(func1),      gevent.spawn(func2),      #gevent.spawn(func3), ])

输出：

李闯在跟海涛搞...
李闯切换到了跟海龙搞...
李闯搞完了海涛，回来继续跟海龙搞...

李闯又回去跟继续跟海涛搞...

同步与异步的性能区别 

import gevent
 
def task(pid):
    """
    Some non-deterministic task
    """
    gevent.sleep(0.5)
    print('Task %s done' % pid)
 
def synchronous():
    for i in range(1,10):
        task(i)
 
def asynchronous():
    threads = [gevent.spawn(task, i) for i in range(10)]
    gevent.joinall(threads)
 
print('Synchronous:')
synchronous()
 
print('Asynchronous:')
asynchronous()

上面程序的重要部分是将task函数封装到Greenlet内部线程的gevent.spawn。 初始化的greenlet列表存放在数组threads中，此数组被传给gevent.joinall 函数，后者阻塞当前流程，并执行全部给定的greenlet。执行流程只会在 全部greenlet执行完后才会继续向下走。　　

遇到IO阻塞时会自动切换任务

from gevent import monkey; monkey.patch_all()
import gevent
from  urllib.request import urlopen
 
def f(url):
    print('GET: %s' % url)
    resp = urlopen(url)
    data = resp.read()
    print('%d bytes received from %s.' % (len(data), url))
 
gevent.joinall([
        gevent.spawn(f, 'https://www.python.org/'),
        gevent.spawn(f, 'https://www.yahoo.com/'),
        gevent.spawn(f, 'https://github.com/'),
])

经过gevent实现单线程下的多socket并发

server side 

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import  sys import  socket import  time import  gevent   from  gevent  import  socket,monkey monkey.patch_all()     def  server(port):      s  =  socket.socket()      s.bind(( '0.0.0.0' , port))      s.listen( 500 )      while  True :          cli, addr  =  s.accept()          gevent.spawn(handle_request, cli)       def  handle_request(conn):      try :          while  True :              data  =  conn.recv( 1024 )              print ( "recv:" , data)              conn.send(data)              if  not  data:                  conn.shutdown(socket.SHUT_WR)        except  Exception as  ex:          print (ex)      finally :          conn.close() if  __name__  = =  '__main__' :      server( 8001 )

client side 　　

import socket
 
HOST = 'localhost'    # The remote host
PORT = 8001           # The same port as used by the server
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
s.connect((HOST, PORT))
while True:
    msg = bytes(input(">>:"),encoding="utf8")
    s.sendall(msg)
    data = s.recv(1024)
    #print(data)
 
    print('Received', repr(data))
s.close()

import socket
import threading

def sock_conn():

    client = socket.socket()

    client.connect(("localhost",8001))
    count = 0
    while True:
        #msg = input(">>:").strip()
        #if len(msg) == 0:continue
        client.send( ("hello %s" %count).encode("utf-8"))

        data = client.recv(1024)

        print("[%s]recv from server:" % threading.get_ident(),data.decode()) #结果
        count +=1
    client.close()


for i in range(100):
    t = threading.Thread(target=sock_conn)
    t.start()

并发100个sock链接

 

论事件驱动与异步IO

一般，咱们写服务器处理模型的程序时，有如下几种模型：

（1）每收到一个请求，建立一个新的进程，来处理该请求；

（2）每收到一个请求，建立一个新的线程，来处理该请求；

（3）每收到一个请求，放入一个事件列表，让主进程经过非阻塞I/O方式来处理请求

上面的几种方式，各有千秋，

第（1）中方法，因为建立新的进程的开销比较大，因此，会致使服务器性能比较差,但实现比较简单。

第（2）种方式，因为要涉及到线程的同步，有可能会面临 死锁等问题。

第（3）种方式，在写应用程序代码时，逻辑比前面两种都复杂。

综合考虑各方面因素，通常广泛认为第（3）种方式是大多数 网络服务器采用的方式

 

看图说话讲事件驱动模型

在UI编程中，经常要对鼠标点击进行相应，首先如何得到鼠标点击呢？
方式一：建立一个线程，该线程一直循环检测是否有鼠标点击，那么这个方式有如下几个缺点：
1. CPU资源浪费，可能鼠标点击的频率很是小，可是扫描线程仍是会一直循环检测，这会形成不少的CPU资源浪费；若是扫描鼠标点击的接口是阻塞的呢？
2. 若是是堵塞的，又会出现下面这样的问题，若是咱们不但要扫描鼠标点击，还要扫描键盘是否按下，因为扫描鼠标时被堵塞了，那么可能永远不会去扫描键盘；
3. 若是一个循环须要扫描的设备很是多，这又会引来响应时间的问题；
因此，该方式是很是很差的。

方式二：就是事件驱动模型
目前大部分的UI编程都是事件驱动模型，如不少UI平台都会提供onClick()事件，这个事件就表明鼠标按下事件。事件驱动模型大致思路以下：
1. 有一个事件（消息）队列；
2. 鼠标按下时，往这个队列中增长一个点击事件（消息）；
3. 有个循环，不断从队列取出事件，根据不一样的事件，调用不一样的函数，如onClick()、onKeyDown()等；
4. 事件（消息）通常都各自保存各自的处理函数指针，这样，每一个消息都有独立的处理函数；

 

 

 

事件驱动编程是一种编程范式，这里程序的执行流由外部事件来决定。它的特色是包含一个事件循环，当外部事件发生时使用回调机制来触发相应的处理。另外两种常见的编程范式是（单线程）同步以及多线程编程。

让咱们用例子来比较和对比一下单线程、多线程以及事件驱动编程模型。下图展现了随着时间的推移，这三种模式下程序所作的工做。这个程序有3个任务须要完成，每一个任务都在等待I/O操做时阻塞自身。阻塞在I/O操做上所花费的时间已经用灰色框标示出来了。

 

 

在单线程同步模型中，任务按照顺序执行。若是某个任务由于I/O而阻塞，其余全部的任务都必须等待，直到它完成以后它们才能依次执行。这种明确的执行顺序和串行化处理的行为是很容易推断得出的。若是任务之间并无互相依赖的关系，但仍然须要互相等待的话这就使得程序没必要要的下降了运行速度。

在多线程版本中，这3个任务分别在独立的线程中执行。这些线程由操做系统来管理，在多处理器系统上能够并行处理，或者在单处理器系统上交错执行。这使得当某个线程阻塞在某个资源的同时其余线程得以继续执行。与完成相似功能的同步程序相比，这种方式更有效率，但程序员必须写代码来保护共享资源，防止其被多个线程同时访问。多线程程序更加难以推断，由于这类程序不得不经过线程同步机制如锁、可重入函数、线程局部存储或者其余机制来处理线程安全问题，若是实现不当就会致使出现微妙且使人痛不欲生的bug。

在事件驱动版本的程序中，3个任务交错执行，但仍然在一个单独的线程控制中。当处理I/O或者其余昂贵的操做时，注册一个回调到事件循环中，而后当I/O操做完成时继续执行。回调描述了该如何处理某个事件。事件循环轮询全部的事件，当事件到来时将它们分配给等待处理事件的回调函数。这种方式让程序尽量的得以执行而不须要用到额外的线程。事件驱动型程序比多线程程序更容易推断出行为，由于程序员不须要关心线程安全问题。

当咱们面对以下的环境时，事件驱动模型一般是一个好的选择：

1. 程序中有许多任务，并且…
2. 任务之间高度独立（所以它们不须要互相通讯，或者等待彼此）并且…
3. 在等待事件到来时，某些任务会阻塞。

当应用程序须要在任务间共享可变的数据时，这也是一个不错的选择，由于这里不须要采用同步处理。

网络应用程序一般都有上述这些特色，这使得它们可以很好的契合事件驱动编程模型。

 

此处要提出一个问题，就是，上面的事件驱动模型中，只要一遇到IO就注册一个事件，而后主程序就能够继续干其它的事情了，只到io处理完毕后，继续恢复以前中断的任务，这本质上是怎么实现的呢？哈哈，下面咱们就来一块儿揭开这神秘的面纱。。。。

 

 

Select\Poll\Epoll异步IO　

http://www.cnblogs.com/alex3714/p/4372426.html　

番外篇 http://www.cnblogs.com/alex3714/articles/5876749.html 

select 多并发socket 例子

#_*_coding:utf-8_*_
__author__ = 'Alex Li'

import select
import socket
import sys
import queue


server = socket.socket()
server.setblocking(0)

server_addr = ('localhost',10000)

print('starting up on %s port %s' % server_addr)
server.bind(server_addr)

server.listen(5)


inputs = [server, ] #本身也要监测呀,由于server自己也是个fd
outputs = []

message_queues = {}

while True:
    print("waiting for next event...")

    readable, writeable, exeptional = select.select(inputs,outputs,inputs) #若是没有任何fd就绪,那程序就会一直阻塞在这里

    for s in readable: #每一个s就是一个socket

        if s is server: #别忘记,上面咱们server本身也当作一个fd放在了inputs列表里,传给了select,若是这个s是server,表明server这个fd就绪了,
            #就是有活动了, 什么状况下它才有活动? 固然 是有新链接进来的时候 呀
            #新链接进来了,接受这个链接
            conn, client_addr = s.accept()
            print("new connection from",client_addr)
            conn.setblocking(0)
            inputs.append(conn) #为了避免阻塞整个程序,咱们不会马上在这里开始接收客户端发来的数据, 把它放到inputs里, 下一次loop时,这个新链接
            #就会被交给select去监听,若是这个链接的客户端发来了数据 ,那这个链接的fd在server端就会变成就续的,select就会把这个链接返回,返回到
            #readable 列表里,而后你就能够loop readable列表,取出这个链接,开始接收数据了, 下面就是这么干 的

            message_queues[conn] = queue.Queue() #接收到客户端的数据后,不马上返回 ,暂存在队列里,之后发送

        else: #s不是server的话,那就只能是一个 与客户端创建的链接的fd了
            #客户端的数据过来了,在这接收
            data = s.recv(1024)
            if data:
                print("收到来自[%s]的数据:" % s.getpeername()[0], data)
                message_queues[s].put(data) #收到的数据先放到queue里,一会返回给客户端
                if s not  in outputs:
                    outputs.append(s) #为了避免影响处理与其它客户端的链接 , 这里不马上返回数据给客户端


            else:#若是收不到data表明什么呢? 表明客户端断开了呀
                print("客户端断开了",s)

                if s in outputs:
                    outputs.remove(s) #清理已断开的链接

                inputs.remove(s) #清理已断开的链接

                del message_queues[s] ##清理已断开的链接


    for s in writeable:
        try :
            next_msg = message_queues[s].get_nowait()

        except queue.Empty:
            print("client [%s]" %s.getpeername()[0], "queue is empty..")
            outputs.remove(s)

        else:
            print("sending msg to [%s]"%s.getpeername()[0], next_msg)
            s.send(next_msg.upper())


    for s in exeptional:
        print("handling exception for ",s.getpeername())
        inputs.remove(s)
        if s in outputs:
            outputs.remove(s)
        s.close()

        del message_queues[s]

select socket server

 

#_*_coding:utf-8_*_
__author__ = 'Alex Li'


import socket
import sys

messages = [ b'This is the message. ',
             b'It will be sent ',
             b'in parts.',
             ]
server_address = ('localhost', 10000)

# Create a TCP/IP socket
socks = [ socket.socket(socket.AF_INET, socket.SOCK_STREAM),
          socket.socket(socket.AF_INET, socket.SOCK_STREAM),
          ]

# Connect the socket to the port where the server is listening
print('connecting to %s port %s' % server_address)
for s in socks:
    s.connect(server_address)

for message in messages:

    # Send messages on both sockets
    for s in socks:
        print('%s: sending "%s"' % (s.getsockname(), message) )
        s.send(message)

    # Read responses on both sockets
    for s in socks:
        data = s.recv(1024)
        print( '%s: received "%s"' % (s.getsockname(), data) )
        if not data:
            print(sys.stderr, 'closing socket', s.getsockname() )

select socket client

 

selectors模块

This module allows high-level and efficient I/O multiplexing, built upon the select module primitives. Users are encouraged to use this module instead, unless they want precise control over the OS-level primitives used.

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import  selectors import  socket   sel  =  selectors.DefaultSelector()   def  accept(sock, mask):      conn, addr  =  sock.accept()   # Should be ready      print ( 'accepted' , conn,  'from' , addr)      conn.setblocking( False )      sel.register(conn, selectors.EVENT_READ, read)   def  read(conn, mask):      data  =  conn.recv( 1000 )   # Should be ready      if  data:          print ( 'echoing' ,  repr (data),  'to' , conn)          conn.send(data)   # Hope it won't block      else :          print ( 'closing' , conn)          sel.unregister(conn)          conn.close()   sock  =  socket.socket() sock.bind(( 'localhost' ,  10000 )) sock.listen( 100 ) sock.setblocking( False ) sel.register(sock, selectors.EVENT_READ, accept)   while  True :      events  =  sel.select()      for  key, mask  in  events:          callback  =  key.data          callback(key.fileobj, mask)

　　

数据库操做与Paramiko模块 

http://www.cnblogs.com/wupeiqi/articles/5095821.html 

RabbitMQ队列　　

安装 http://www.rabbitmq.com/install-standalone-mac.html

安装python rabbitMQ module 

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pip install pika or easy_install pika or 源码    https: / / pypi.python.org / pypi / pika

实现最简单的队列通讯

send端

#!/usr/bin/env python
import pika
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
               'localhost'))
channel = connection.channel()
 
#声明queue
channel.queue_declare(queue='hello')
 
#n RabbitMQ a message can never be sent directly to the queue, it always needs to go through an exchange.
channel.basic_publish(exchange='',
                      routing_key='hello',
                      body='Hello World!')
print(" [x] Sent 'Hello World!'")
connection.close()

receive端

#_*_coding:utf-8_*_
__author__ = 'Alex Li'
import pika
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
               'localhost'))
channel = connection.channel()
 
 
#You may ask why we declare the queue again ‒ we have already declared it in our previous code.
# We could avoid that if we were sure that the queue already exists. For example if send.py program
#was run before. But we're not yet sure which program to run first. In such cases it's a good
# practice to repeat declaring the queue in both programs.
channel.queue_declare(queue='hello')
 
def callback(ch, method, properties, body):
    print(" [x] Received %r" % body)
 
channel.basic_consume(callback,
                      queue='hello',
                      no_ack=True)
 
print(' [*] Waiting for messages. To exit press CTRL+C')
channel.start_consuming()

Work Queues

 

在这种模式下，RabbitMQ会默认把p发的消息依次分发给各个消费者(c),跟负载均衡差很少

消息提供者代码

import pika
import time
connection = pika.BlockingConnection(pika.ConnectionParameters(
    'localhost'))
channel = connection.channel()
 
# 声明queue
channel.queue_declare(queue='task_queue')
 
# n RabbitMQ a message can never be sent directly to the queue, it always needs to go through an exchange.
import sys
 
message = ' '.join(sys.argv[1:]) or "Hello World! %s" % time.time()
channel.basic_publish(exchange='',
                      routing_key='task_queue',
                      body=message,
                      properties=pika.BasicProperties(
                          delivery_mode=2,  # make message persistent
                      )
                      )
print(" [x] Sent %r" % message)
connection.close()

消费者代码

#_*_coding:utf-8_*_
 
import pika, time
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
    'localhost'))
channel = connection.channel()
 
 
def callback(ch, method, properties, body):
    print(" [x] Received %r" % body)
    time.sleep(20)
    print(" [x] Done")
    print("method.delivery_tag",method.delivery_tag)
    ch.basic_ack(delivery_tag=method.delivery_tag)
 
 
channel.basic_consume(callback,
                      queue='task_queue',
                      no_ack=True
                      )
 
print(' [*] Waiting for messages. To exit press CTRL+C')
channel.start_consuming()

此时，先启动消息生产者，而后再分别启动3个消费者，经过生产者多发送几条消息，你会发现，这几条消息会被依次分配到各个消费者身上　　

Doing a task can take a few seconds. You may wonder what happens if one of the consumers starts a long task and dies with it only partly done. With our current code once RabbitMQ delivers message to the customer it immediately removes it from memory. In this case, if you kill a worker we will lose the message it was just processing. We'll also lose all the messages that were dispatched to this particular worker but were not yet handled.

But we don't want to lose any tasks. If a worker dies, we'd like the task to be delivered to another worker.

In order to make sure a message is never lost, RabbitMQ supports message acknowledgments. An ack(nowledgement) is sent back from the consumer to tell RabbitMQ that a particular message had been received, processed and that RabbitMQ is free to delete it.

If a consumer dies (its channel is closed, connection is closed, or TCP connection is lost) without sending an ack, RabbitMQ will understand that a message wasn't processed fully and will re-queue it. If there are other consumers online at the same time, it will then quickly redeliver it to another consumer. That way you can be sure that no message is lost, even if the workers occasionally die.

There aren't any message timeouts; RabbitMQ will redeliver the message when the consumer dies. It's fine even if processing a message takes a very, very long time.

Message acknowledgments are turned on by default. In previous examples we explicitly turned them off via the no_ack=True flag. It's time to remove this flag and send a proper acknowledgment from the worker, once we're done with a task.

1 2 3 4 5 6 7 8

def  callback(ch, method, properties, body):      print  " [x] Received %r"  %  (body,)      time.sleep( body.count( '.' ) )      print  " [x] Done"      ch.basic_ack(delivery_tag  =  method.delivery_tag)   channel.basic_consume(callback,                        queue = 'hello' )

　　Using this code we can be sure that even if you kill a worker using CTRL+C while it was processing a message, nothing will be lost. Soon after the worker dies all unacknowledged messages will be redelivered

　　　　

消息持久化　　

We have learned how to make sure that even if the consumer dies, the task isn't lost(by default, if wanna disable  use no_ack=True). But our tasks will still be lost if RabbitMQ server stops.

When RabbitMQ quits or crashes it will forget the queues and messages unless you tell it not to. Two things are required to make sure that messages aren't lost: we need to mark both the queue and messages as durable.

First, we need to make sure that RabbitMQ will never lose our queue. In order to do so, we need to declare it as durable:

1	channel.queue_declare(queue = 'hello' , durable = True )

　　

Although this command is correct by itself, it won't work in our setup. That's because we've already defined a queue called hello which is not durable. RabbitMQ doesn't allow you to redefine an existing queue with different parameters and will return an error to any program that tries to do that. But there is a quick workaround - let's declare a queue with different name, for exampletask_queue:

1	channel.queue_declare(queue = 'task_queue' , durable = True )

　　

This queue_declare change needs to be applied to both the producer and consumer code.

At that point we're sure that the task_queue queue won't be lost even if RabbitMQ restarts. Now we need to mark our messages as persistent - by supplying a delivery_mode property with a value 2.

1 2 3 4 5 6

channel.basic_publish(exchange = '',                        routing_key = "task_queue" ,                        body = message,                        properties = pika.BasicProperties(                           delivery_mode  =  2 ,  # make message persistent                        ))

　　

消息公平分发

若是Rabbit只管按顺序把消息发到各个消费者身上，不考虑消费者负载的话，极可能出现，一个机器配置不高的消费者那里堆积了不少消息处理不完，同时配置高的消费者却一直很轻松。为解决此问题，能够在各个消费者端，配置perfetch=1,意思就是告诉RabbitMQ在我这个消费者当前消息还没处理完的时候就不要再给我发新消息了。

 

 

1	channel.basic_qos(prefetch_count = 1 )

 

 

带消息持久化+公平分发的完整代码

生产者端


#!/usr/bin/env python
import pika
import sys
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.queue_declare(queue='task_queue', durable=True)
 
message = ' '.join(sys.argv[1:]) or "Hello World!"
channel.basic_publish(exchange='',
                      routing_key='task_queue',
                      body=message,
                      properties=pika.BasicProperties(
                         delivery_mode = 2, # make message persistent
                      ))
print(" [x] Sent %r" % message)
connection.close()



消费者端

#!/usr/bin/env python
import pika
import time
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.queue_declare(queue='task_queue', durable=True)
print(' [*] Waiting for messages. To exit press CTRL+C')
 
def callback(ch, method, properties, body):
    print(" [x] Received %r" % body)
    time.sleep(body.count(b'.'))
    print(" [x] Done")
    ch.basic_ack(delivery_tag = method.delivery_tag)
 
channel.basic_qos(prefetch_count=1)
channel.basic_consume(callback,
                      queue='task_queue')
 
channel.start_consuming()

　　

 

Publish\Subscribe(消息发布\订阅)　

以前的例子都基本都是1对1的消息发送和接收，即消息只能发送到指定的queue里，但有些时候你想让你的消息被全部的Queue收到，相似广播的效果，这时候就要用到exchange了，

An exchange is a very simple thing. On one side it receives messages from producers and the other side it pushes them to queues. The exchange must know exactly what to do with a message it receives. Should it be appended to a particular queue? Should it be appended to many queues? Or should it get discarded. The rules for that are defined by the exchange type.

Exchange在定义的时候是有类型的，以决定究竟是哪些Queue符合条件，能够接收消息

fanout: 全部bind到此exchange的queue均可以接收消息
direct: 经过routingKey和exchange决定的那个惟一的queue能够接收消息
topic:全部符合routingKey(此时能够是一个表达式)的routingKey所bind的queue能够接收消息

　　 表达式符号说明：#表明一个或多个字符，*表明任何字符
      例：#.a会匹配a.a，aa.a，aaa.a等
          *.a会匹配a.a，b.a，c.a等
     注：使用RoutingKey为#，Exchange Type为topic的时候至关于使用fanout　

headers: 经过headers 来决定把消息发给哪些queue

消息publisher

消息publisher


import pika
import sys
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.exchange_declare(exchange='logs',
                         type='fanout')
 
message = ' '.join(sys.argv[1:]) or "info: Hello World!"
channel.basic_publish(exchange='logs',
                      routing_key='',
                      body=message)
print(" [x] Sent %r" % message)
connection.close()





消息subscriber


#_*_coding:utf-8_*_
__author__ = 'Alex Li'
import pika
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.exchange_declare(exchange='logs',
                         type='fanout')
 
result = channel.queue_declare(exclusive=True) #不指定queue名字,rabbit会随机分配一个名字,exclusive=True会在使用此queue的消费者断开后,自动将queue删除
queue_name = result.method.queue
 
channel.queue_bind(exchange='logs',
                   queue=queue_name)
 
print(' [*] Waiting for logs. To exit press CTRL+C')
 
def callback(ch, method, properties, body):
    print(" [x] %r" % body)
 
channel.basic_consume(callback,
                      queue=queue_name,
                      no_ack=True)
 
channel.start_consuming()

有选择的接收消息(exchange type=direct)　

RabbitMQ还支持根据关键字发送，即：队列绑定关键字，发送者将数据根据关键字发送到消息exchange，exchange根据 关键字 断定应该将数据发送至指定队列。

 

publisher

import pika
import sys
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.exchange_declare(exchange='direct_logs',
                         type='direct')
 
severity = sys.argv[1] if len(sys.argv) > 1 else 'info'
message = ' '.join(sys.argv[2:]) or 'Hello World!'
channel.basic_publish(exchange='direct_logs',
                      routing_key=severity,
                      body=message)
print(" [x] Sent %r:%r" % (severity, message))
connection.close()

subscriber

import pika
import sys
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.exchange_declare(exchange='direct_logs',
                         type='direct')
 
result = channel.queue_declare(exclusive=True)
queue_name = result.method.queue
 
severities = sys.argv[1:]
if not severities:
    sys.stderr.write("Usage: %s [info] [warning] [error]\n" % sys.argv[0])
    sys.exit(1)
 
for severity in severities:
    channel.queue_bind(exchange='direct_logs',
                       queue=queue_name,
                       routing_key=severity)
 
print(' [*] Waiting for logs. To exit press CTRL+C')
 
def callback(ch, method, properties, body):
    print(" [x] %r:%r" % (method.routing_key, body))
 
channel.basic_consume(callback,
                      queue=queue_name,
                      no_ack=True)
 
channel.start_consuming()

更细致的消息过滤

Although using the direct exchange improved our system, it still has limitations - it can't do routing based on multiple criteria.

In our logging system we might want to subscribe to not only logs based on severity, but also based on the source which emitted the log. You might know this concept from the syslog unix tool, which routes logs based on both severity (info/warn/crit...) and facility (auth/cron/kern...).

That would give us a lot of flexibility - we may want to listen to just critical errors coming from 'cron' but also all logs from 'kern'.

publisher


import pika
import sys
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.exchange_declare(exchange='topic_logs',
                         type='topic')
 
routing_key = sys.argv[1] if len(sys.argv) > 1 else 'anonymous.info'
message = ' '.join(sys.argv[2:]) or 'Hello World!'
channel.basic_publish(exchange='topic_logs',
                      routing_key=routing_key,
                      body=message)
print(" [x] Sent %r:%r" % (routing_key, message))
connection.close()





subscriber

import pika
import sys
 
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
channel = connection.channel()
 
channel.exchange_declare(exchange='topic_logs',
                         type='topic')
 
result = channel.queue_declare(exclusive=True)
queue_name = result.method.queue
 
binding_keys = sys.argv[1:]
if not binding_keys:
    sys.stderr.write("Usage: %s [binding_key]...\n" % sys.argv[0])
    sys.exit(1)
 
for binding_key in binding_keys:
    channel.queue_bind(exchange='topic_logs',
                       queue=queue_name,
                       routing_key=binding_key)
 
print(' [*] Waiting for logs. To exit press CTRL+C')
 
def callback(ch, method, properties, body):
    print(" [x] %r:%r" % (method.routing_key, body))
 
channel.basic_consume(callback,
                      queue=queue_name,
                      no_ack=True)
 
channel.start_consuming()

To receive all the logs run:

python receive_logs_topic.py "#"

To receive all logs from the facility "kern":

python receive_logs_topic.py "kern.*"

Or if you want to hear only about "critical" logs:

python receive_logs_topic.py "*.critical"

You can create multiple bindings:

python receive_logs_topic.py "kern.*" "*.critical" 

And to emit a log with a routing key "kern.critical" type:

python emit_log_topic.py "kern.critical" "A critical kernel error"

　　

Remote procedure call (RPC)

To illustrate how an RPC service could be used we're going to create a simple client class. It's going to expose a method named call which sends an RPC request and blocks until the answer is received:

1 2 3

fibonacci_rpc  =  FibonacciRpcClient() result  =  fibonacci_rpc.call( 4 ) print ( "fib(4) is %r"  %  result)

RPC server

#_*_coding:utf-8_*_
__author__ = 'Alex Li'
import pika
import time
connection = pika.BlockingConnection(pika.ConnectionParameters(
        host='localhost'))
 
channel = connection.channel()
 
channel.queue_declare(queue='rpc_queue')
 
def fib(n):
    if n == 0:
        return 0
    elif n == 1:
        return 1
    else:
        return fib(n-1) + fib(n-2)
 
def on_request(ch, method, props, body):
    n = int(body)
 
    print(" [.] fib(%s)" % n)
    response = fib(n)
 
    ch.basic_publish(exchange='',
                     routing_key=props.reply_to,
                     properties=pika.BasicProperties(correlation_id = \
                                                         props.correlation_id),
                     body=str(response))
    ch.basic_ack(delivery_tag = method.delivery_tag)
 
channel.basic_qos(prefetch_count=1)
channel.basic_consume(on_request, queue='rpc_queue')
 
print(" [x] Awaiting RPC requests")
channel.start_consuming()

RPC client

import pika
import uuid
 
class FibonacciRpcClient(object):
    def __init__(self):
        self.connection = pika.BlockingConnection(pika.ConnectionParameters(
                host='localhost'))
 
        self.channel = self.connection.channel()
 
        result = self.channel.queue_declare(exclusive=True)
        self.callback_queue = result.method.queue
 
        self.channel.basic_consume(self.on_response, no_ack=True,
                                   queue=self.callback_queue)
 
    def on_response(self, ch, method, props, body):
        if self.corr_id == props.correlation_id:
            self.response = body
 
    def call(self, n):
        self.response = None
        self.corr_id = str(uuid.uuid4())
        self.channel.basic_publish(exchange='',
                                   routing_key='rpc_queue',
                                   properties=pika.BasicProperties(
                                         reply_to = self.callback_queue,
                                         correlation_id = self.corr_id,
                                         ),
                                   body=str(n))
        while self.response is None:
            self.connection.process_data_events()
        return int(self.response)
 
fibonacci_rpc = FibonacciRpcClient()
 
print(" [x] Requesting fib(30)")
response = fibonacci_rpc.call(30)
print(" [.] Got %r" % response)

　　

Memcached & Redis使用　

memcached 

http://www.cnblogs.com/wupeiqi/articles/5132791.html 　

 

redis 使用

http://www.cnblogs.com/alex3714/articles/6217453.html　　

Twsited异步网络框架

Twisted是一个事件驱动的网络框架，其中包含了诸多功能，例如：网络协议、线程、数据库管理、网络操做、电子邮件等。　

事件驱动

简而言之，事件驱动分为二个部分：第一，注册事件；第二，触发事件。

自定义事件驱动框架，命名为：“弑君者”：

#!/usr/bin/env python
# -*- coding:utf-8 -*-
 
# event_drive.py
 
event_list = []
 
 
def run():
    for event in event_list:
        obj = event()
        obj.execute()
 
 
class BaseHandler(object):
    """
    用户必须继承该类，从而规范全部类的方法（相似于接口的功能）
    """
    def execute(self):
        raise Exception('you must overwrite execute')
 
最牛逼的事件驱动框架

程序员使用“弑君者框架”：

#!/usr/bin/env python
# -*- coding:utf-8 -*-
 
from source import event_drive
 
 
class MyHandler(event_drive.BaseHandler):
 
    def execute(self):
        print 'event-drive execute MyHandler'
 
 
event_drive.event_list.append(MyHandler)
event_drive.run()

Protocols

Protocols描述了如何以异步的方式处理网络中的事件。HTTP、DNS以及IMAP是应用层协议中的例子。Protocols实现了IProtocol接口，它包含以下的方法：

makeConnection 在transport对象和服务器之间创建一条链接 connectionMade 链接创建起来后调用 dataReceived 接收数据时调用 connectionLost 关闭链接时调用

Transports

Transports表明网络中两个通讯结点之间的链接。Transports负责描述链接的细节，好比链接是面向流式的仍是面向数据报的，流控以及可靠性。TCP、UDP和Unix套接字可做为transports的例子。它们被设计为“知足最小功能单元，同时具备最大程度的可复用性”，并且从协议实现中分离出来，这让许多协议能够采用相同类型的传输。Transports实现了ITransports接口，它包含以下的方法：

write 以非阻塞的方式按顺序依次将数据写到物理链接上 writeSequence 将一个字符串列表写到物理链接上 loseConnection 将全部挂起的数据写入，而后关闭链接 getPeer 取得链接中对端的地址信息 getHost 取得链接中本端的地址信息

将transports从协议中分离出来也使得对这两个层次的测试变得更加简单。能够经过简单地写入一个字符串来模拟传输，用这种方式来检查。

 

EchoServer

from twisted.internet import protocol
from twisted.internet import reactor
 
class Echo(protocol.Protocol):
    def dataReceived(self, data):
        self.transport.write(data)
 
def main():
    factory = protocol.ServerFactory()
    factory.protocol = Echo
 
    reactor.listenTCP(1234,factory)
    reactor.run()
 
if __name__ == '__main__':
    main()
　　

EchoClient

from twisted.internet import reactor, protocol
 
 
# a client protocol
 
class EchoClient(protocol.Protocol):
    """Once connected, send a message, then print the result."""
 
    def connectionMade(self):
        self.transport.write("hello alex!")
 
    def dataReceived(self, data):
        "As soon as any data is received, write it back."
        print "Server said:", data
        self.transport.loseConnection()
 
    def connectionLost(self, reason):
        print "connection lost"
 
class EchoFactory(protocol.ClientFactory):
    protocol = EchoClient
 
    def clientConnectionFailed(self, connector, reason):
        print "Connection failed - goodbye!"
        reactor.stop()
 
    def clientConnectionLost(self, connector, reason):
        print "Connection lost - goodbye!"
        reactor.stop()
 
 
# this connects the protocol to a server running on port 8000
def main():
    f = EchoFactory()
    reactor.connectTCP("localhost", 1234, f)
    reactor.run()
 
# this only runs if the module was *not* imported
if __name__ == '__main__':
    main()

　　

运行服务器端脚本将启动一个TCP服务器，监听端口1234上的链接。服务器采用的是Echo协议，数据经TCP transport对象写出。运行客户端脚本将对服务器发起一个TCP链接，回显服务器端的回应而后终止链接并中止reactor事件循环。这里的Factory用来对链接的双方生成protocol对象实例。两端的通讯是异步的，connectTCP负责注册回调函数到reactor事件循环中，当socket上有数据可读时通知回调处理。

一个传送文件的例子 

server side 

 

#_*_coding:utf-8_*_
# This is the Twisted Fast Poetry Server, version 1.0
 
import optparse, os
 
from twisted.internet.protocol import ServerFactory, Protocol
 
 
def parse_args():
    usage = """usage: %prog [options] poetry-file
 
This is the Fast Poetry Server, Twisted edition.
Run it like this:
 
  python fastpoetry.py <path-to-poetry-file>
 
If you are in the base directory of the twisted-intro package,
you could run it like this:
 
  python twisted-server-1/fastpoetry.py poetry/ecstasy.txt
 
to serve up John Donne's Ecstasy, which I know you want to do.
"""
 
    parser = optparse.OptionParser(usage)
 
    help = "The port to listen on. Default to a random available port."
    parser.add_option('--port', type='int', help=help)
 
    help = "The interface to listen on. Default is localhost."
    parser.add_option('--iface', help=help, default='localhost')
 
    options, args = parser.parse_args()
    print("--arg:",options,args)
 
    if len(args) != 1:
        parser.error('Provide exactly one poetry file.')
 
    poetry_file = args[0]
 
    if not os.path.exists(args[0]):
        parser.error('No such file: %s' % poetry_file)
 
    return options, poetry_file
 
 
class PoetryProtocol(Protocol):
 
    def connectionMade(self):
        self.transport.write(self.factory.poem)
        self.transport.loseConnection()
 
 
class PoetryFactory(ServerFactory):
 
    protocol = PoetryProtocol
 
    def __init__(self, poem):
        self.poem = poem
 
 
def main():
    options, poetry_file = parse_args()
 
    poem = open(poetry_file).read()
 
    factory = PoetryFactory(poem)
 
    from twisted.internet import reactor
 
    port = reactor.listenTCP(options.port or 9000, factory,
                             interface=options.iface)
 
    print 'Serving %s on %s.' % (poetry_file, port.getHost())
 
    reactor.run()
 
 
if __name__ == '__main__':
    main()

client side 　　

# This is the Twisted Get Poetry Now! client, version 3.0.
 
# NOTE: This should not be used as the basis for production code.
 
import optparse
 
from twisted.internet.protocol import Protocol, ClientFactory
 
 
def parse_args():
    usage = """usage: %prog [options] [hostname]:port ...
 
This is the Get Poetry Now! client, Twisted version 3.0
Run it like this:
 
  python get-poetry-1.py port1 port2 port3 ...
"""
 
    parser = optparse.OptionParser(usage)
 
    _, addresses = parser.parse_args()
 
    if not addresses:
        print parser.format_help()
        parser.exit()
 
    def parse_address(addr):
        if ':' not in addr:
            host = '127.0.0.1'
            port = addr
        else:
            host, port = addr.split(':', 1)
 
        if not port.isdigit():
            parser.error('Ports must be integers.')
 
        return host, int(port)
 
    return map(parse_address, addresses)
 
 
class PoetryProtocol(Protocol):
 
    poem = ''
 
    def dataReceived(self, data):
        self.poem += data
 
    def connectionLost(self, reason):
        self.poemReceived(self.poem)
 
    def poemReceived(self, poem):
        self.factory.poem_finished(poem)
 
 
class PoetryClientFactory(ClientFactory):
 
    protocol = PoetryProtocol
 
    def __init__(self, callback):
        self.callback = callback
 
    def poem_finished(self, poem):
        self.callback(poem)
 
 
def get_poetry(host, port, callback):
    """
    Download a poem from the given host and port and invoke
 
      callback(poem)
 
    when the poem is complete.
    """
    from twisted.internet import reactor
    factory = PoetryClientFactory(callback)
    reactor.connectTCP(host, port, factory)
 
 
def poetry_main():
    addresses = parse_args()
 
    from twisted.internet import reactor
 
    poems = []
 
    def got_poem(poem):
        poems.append(poem)
        if len(poems) == len(addresses):
            reactor.stop()
 
    for address in addresses:
        host, port = address
        get_poetry(host, port, got_poem)
 
    reactor.run()
 
    for poem in poems:
        print poem
 
 
if __name__ == '__main__':
    poetry_main()

　　

Twisted深刻

http://krondo.com/an-introduction-to-asynchronous-programming-and-twisted/ 

http://blog.csdn.net/hanhuili/article/details/9389433 

　　

　　

SqlAlchemy ORM　　

SQLAlchemy是Python编程语言下的一款ORM框架，该框架创建在数据库API之上，使用关系对象映射进行数据库操做，简言之即是：将对象转换成SQL，而后使用数据API执行SQL并获取执行结果

Dialect用于和数据API进行交流，根据配置文件的不一样调用不一样的数据库API，从而实现对数据库的操做，如：

MySQL-Python
    mysql+mysqldb://<user>:<password>@<host>[:<port>]/<dbname>
  
pymysql
    mysql+pymysql://<username>:<password>@<host>/<dbname>[?<options>]
  
MySQL-Connector
    mysql+mysqlconnector://<user>:<password>@<host>[:<port>]/<dbname>
  
cx_Oracle
    oracle+cx_oracle://user:pass@host:port/dbname[?key=value&key=value...]
  
更多详见：http://docs.sqlalchemy.org/en/latest/dialects/index.html

步骤一：

使用 Engine/ConnectionPooling/Dialect 进行数据库操做，Engine使用ConnectionPooling链接数据库，而后再经过Dialect执行SQL语句。

#!/usr/bin/env python
# -*- coding:utf-8 -*-
  
from sqlalchemy import create_engine
  
  
engine = create_engine("mysql+mysqldb://root:123@127.0.0.1:3306/s11", max_overflow=5)
  
engine.execute(
    "INSERT INTO ts_test (a, b) VALUES ('2', 'v1')"
)
  
engine.execute(
     "INSERT INTO ts_test (a, b) VALUES (%s, %s)",
    ((555, "v1"),(666, "v1"),)
)
engine.execute(
    "INSERT INTO ts_test (a, b) VALUES (%(id)s, %(name)s)",
    id=999, name="v1"
)
  
result = engine.execute('select * from ts_test')
result.fetchall()

步骤二：

使用 Schema Type/SQL Expression Language/Engine/ConnectionPooling/Dialect 进行数据库操做。Engine使用Schema Type建立一个特定的结构对象，以后经过SQL Expression Language将该对象转换成SQL语句，而后经过 ConnectionPooling 链接数据库，再而后经过 Dialect 执行SQL，并获取结果。

#!/usr/bin/env python
# -*- coding:utf-8 -*-
 
from sqlalchemy import create_engine, Table, Column, Integer, String, MetaData, ForeignKey
 
metadata = MetaData()
 
user = Table('user', metadata,
    Column('id', Integer, primary_key=True),
    Column('name', String(20)),
)
 
color = Table('color', metadata,
    Column('id', Integer, primary_key=True),
    Column('name', String(20)),
)
engine = create_engine("mysql+mysqldb://root@localhost:3306/test", max_overflow=5)
 
metadata.create_all(engine)

增删改查

#!/usr/bin/env python
# -*- coding:utf-8 -*-
 
from sqlalchemy import create_engine, Table, Column, Integer, String, MetaData, ForeignKey
 
metadata = MetaData()
 
user = Table('user', metadata,
    Column('id', Integer, primary_key=True),
    Column('name', String(20)),
)
 
color = Table('color', metadata,
    Column('id', Integer, primary_key=True),
    Column('name', String(20)),
)
engine = create_engine("mysql+mysqldb://root:123@127.0.0.1:3306/s11", max_overflow=5)
 
conn = engine.connect()
 
# 建立SQL语句，INSERT INTO "user" (id, name) VALUES (:id, :name)
conn.execute(user.insert(),{'id':7,'name':'seven'})
conn.close()
 
# sql = user.insert().values(id=123, name='wu')
# conn.execute(sql)
# conn.close()
 
# sql = user.delete().where(user.c.id > 1)
 
# sql = user.update().values(fullname=user.c.name)
# sql = user.update().where(user.c.name == 'jack').values(name='ed')
 
# sql = select([user, ])
# sql = select([user.c.id, ])
# sql = select([user.c.name, color.c.name]).where(user.c.id==color.c.id)
# sql = select([user.c.name]).order_by(user.c.name)
# sql = select([user]).group_by(user.c.name)
 
# result = conn.execute(sql)
# print result.fetchall()
# conn.close()

　　

一个简单的完整例子

from sqlalchemy import create_engine
from sqlalchemy.ext.declarative import declarative_base
from sqlalchemy import Column, Integer, String
from  sqlalchemy.orm import sessionmaker
 
Base = declarative_base() #生成一个SqlORM 基类
 
 
engine = create_engine("mysql+mysqldb://root@localhost:3306/test",echo=False)
 
 
class Host(Base):
    __tablename__ = 'hosts'
    id = Column(Integer,primary_key=True,autoincrement=True)
    hostname = Column(String(64),unique=True,nullable=False)
    ip_addr = Column(String(128),unique=True,nullable=False)
    port = Column(Integer,default=22)
 
Base.metadata.create_all(engine) #建立全部表结构
 
if __name__ == '__main__':
    SessionCls = sessionmaker(bind=engine) #建立与数据库的会话session class ,注意,这里返回给session的是个class,不是实例
    session = SessionCls()
    #h1 = Host(hostname='localhost',ip_addr='127.0.0.1')
    #h2 = Host(hostname='ubuntu',ip_addr='192.168.2.243',port=20000)
    #h3 = Host(hostname='ubuntu2',ip_addr='192.168.2.244',port=20000)
    #session.add(h3)
    #session.add_all( [h1,h2])
    #h2.hostname = 'ubuntu_test' #只要没提交,此时修改也没问题
    #session.rollback()
    #session.commit() #提交
    res = session.query(Host).filter(Host.hostname.in_(['ubuntu2','localhost'])).all()
    print(res)

更多内容详见：

    http://www.jianshu.com/p/e6bba189fcbd

    http://docs.sqlalchemy.org/en/latest/core/expression_api.html

注：SQLAlchemy没法修改表结构，若是须要可使用SQLAlchemy开发者开源的另一个软件Alembic来完成。

步骤三：

使用 ORM/Schema Type/SQL Expression Language/Engine/ConnectionPooling/Dialect 全部组件对数据进行操做。根据类建立对象，对象转换成SQL，执行SQL。

#!/usr/bin/env python
# -*- coding:utf-8 -*-
  
from sqlalchemy.ext.declarative import declarative_base
from sqlalchemy import Column, Integer, String
from sqlalchemy.orm import sessionmaker
from sqlalchemy import create_engine
  
engine = create_engine("mysql+mysqldb://root:123@127.0.0.1:3306/s11", max_overflow=5)
  
Base = declarative_base()
  
  
class User(Base):
    __tablename__ = 'users'
    id = Column(Integer, primary_key=True)
    name = Column(String(50))
  
# 寻找Base的全部子类，按照子类的结构在数据库中生成对应的数据表信息
# Base.metadata.create_all(engine)
  
Session = sessionmaker(bind=engine)
session = Session()
  
  
# ########## 增 ##########
# u = User(id=2, name='sb')
# session.add(u)
# session.add_all([
#     User(id=3, name='sb'),
#     User(id=4, name='sb')
# ])
# session.commit()
  
# ########## 删除 ##########
# session.query(User).filter(User.id > 2).delete()
# session.commit()
  
# ########## 修改 ##########
# session.query(User).filter(User.id > 2).update({'cluster_id' : 0})
# session.commit()
# ########## 查 ##########
# ret = session.query(User).filter_by(name='sb').first()
  
# ret = session.query(User).filter_by(name='sb').all()
# print ret
  
# ret = session.query(User).filter(User.name.in_(['sb','bb'])).all()
# print ret
  
# ret = session.query(User.name.label('name_label')).all()
# print ret,type(ret)
  
# ret = session.query(User).order_by(User.id).all()
# print ret
  
# ret = session.query(User).order_by(User.id)[1:3]
# print ret
# session.commit()

View Code

 

　　

外键关联

A one to many relationship places a foreign key on the child table referencing the parent.relationship() is then specified on the parent, as referencing a collection of items represented by the child

from sqlalchemy import Table, Column, Integer, ForeignKey
from sqlalchemy.orm import relationship
from sqlalchemy.ext.declarative import declarative_base

Base = declarative_base()

<br>class Parent(Base):
    __tablename__ = 'parent'
    id = Column(Integer, primary_key=True)
    children = relationship("Child")
 
class Child(Base):
    __tablename__ = 'child'
    id = Column(Integer, primary_key=True)
    parent_id = Column(Integer, ForeignKey('parent.id'))

　　

To establish a bidirectional relationship in one-to-many, where the “reverse” side is a many to one, specify an additional relationship() and connect the two using therelationship.back_populates parameter:

class Parent(Base):
    __tablename__ = 'parent'
    id = Column(Integer, primary_key=True)
    children = relationship("Child", back_populates="parent")
 
class Child(Base):
    __tablename__ = 'child'
    id = Column(Integer, primary_key=True)
    parent_id = Column(Integer, ForeignKey('parent.id'))
    parent = relationship("Parent", back_populates="children")

Child will get a parent attribute with many-to-one semantics.

Alternatively, the backref option may be used on a single relationship() instead of usingback_populates:

class Parent(Base):
    __tablename__ = 'parent'
    id = Column(Integer, primary_key=True)
    children = relationship("Child", backref="parent")

 

　　

附，原生sql join查询

几个Join的区别 http://stackoverflow.com/questions/38549/difference-between-inner-and-outer-joins 

• INNER JOIN: Returns all rows when there is at least one match in BOTH tables
• LEFT JOIN: Return all rows from the left table, and the matched rows from the right table
• RIGHT JOIN: Return all rows from the right table, and the matched rows from the left table

select host.id,hostname,ip_addr,port,host_group.name from host right join host_group on host.id = host_group.host_id

in SQLAchemy

session.query(Host).join(Host.host_groups).filter(HostGroup.name=='t1').group_by("Host").all()

group by 查询

select name,count(host.id) as NumberOfHosts from host right join host_group on host.id= host_group.host_id group by name;

in SQLAchemy

from sqlalchemy import func
session.query(HostGroup, func.count(HostGroup.name )).group_by(HostGroup.name).all()
 
#another example
session.query(func.count(User.name), User.name).group_by(User.name).all() SELECT count(users.name) AS count_1, users.name AS users_name
FROM users GROUP BY users.name

　　

　　

　　

更多ORM内容猛点这里　　

　　

本节做业一

题目:IO多路复用版FTP

需求:

1. 实现文件上传及下载功能
2. 支持多链接并发传文件
3. 使用select or selectors

 

本节做业二

题目：rpc命令端

需求：

1. 能够异步的执行多个命令
2. 对多台机器

>>:run "df -h" --hosts 192.168.3.55 10.4.3.4 task id: 45334>>: check_task 45334