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  • 2019 SDN大作业

    2019 SDN大作业--数据中心类型网络拓扑的搭建与连接

    贡献比例

    分组报告贡献比例

    学号 分工 比例
    031702345 提供资料,答辩 22%
    031702311 查找资料,ppt制作 21%
    031702428 提供资料 18%
    031702309 查找资料,ppt制作 21%
    131700101 提供资料 18%

    分组实验贡献比例

    学号 分工 比例
    031702345 代码实现,博客 28%
    031702311 思路设计,场景搭建 18%
    031702428 代码实现 18%
    031702309 思路设计,场景搭建 18%
    131700101 思路设计,视频 18%

    实验概述

    使用两个互为备份的中心交换机

    连接两两互为备份的共计四个交换机

    下接四组各连有两台主机的交换机

    作为数据中心类型网络拓扑的一个小型实现

    上、中、下层均可以扩展来实现对更多网络主机的支持

    实现在网络中心区域防止单个设备故障所引发的网络中断

    实验拓扑

    实验拓扑图如下
    由miniedit绘制

    由NSP绘制

    建立实验网络

    建立流程如下

    1.先打开OpenDayLigtht作为remote控制器,否则先运行mininet则不能连接到控制器

    2.运行mininet建立拓扑结构,运行代码如sudo mn --custom datacenter.py --topo mytopo --controller=remote,ip=127.0.0.1,port=6633 --switch ovsk,protocols=OpenFlow13

    3.打开http://127.0.0.1:8181/index.html#/topology来查看拓扑

    4.在mininet中输入net来获取网络接口信息,作为下发流表的依据

    mininet的拓扑结构的Python代码如下:

    #!/usr/bin/python
    #创建网络拓扑
    """Custom topology example
    Adding the 'topos' dict with a key/value pair to generate our newly defined
    topology enables one to pass in '--topo=mytopo' from the command line.
    """
     
    from mininet.topo import Topo
    from mininet.net import Mininet
    from mininet.node import RemoteController,CPULimitedHost
    from mininet.link import TCLink
    from mininet.util import dumpNodeConnections
     
    class MyTopo( Topo ):
        "Simple topology example."
     
        def __init__( self ):
            "Create custom topo."
     
            # Initialize topology
            Topo.__init__( self )
            L1 = 2
            L2 = L1 * 2 
            L3 = L2
            c = []
            a = []
            e = []
              
            # add core ovs  
            for i in range( L1 ):
                    sw = self.addSwitch( 'c{}'.format( i + 1 ) )
                    c.append( sw )
        
            # add aggregation ovs
            for i in range( L2 ):
                    sw = self.addSwitch( 'a{}'.format( L1 + i + 1 ) )
                    a.append( sw )
        
            # add edge ovs
            for i in range( L3 ):
                    sw = self.addSwitch( 'e{}'.format( L1 + L2 + i + 1 ) )
                    e.append( sw )
     
            # add links between core and aggregation ovs
            for i in range( L1 ):
                    sw1 = c[i]
                    for sw2 in a[i/2::L1/2]:
                    # self.addLink(sw2, sw1, bw=10, delay='5ms', loss=10, max_queue_size=1000, use_htb=True)
    			            self.addLink( sw2, sw1 )
     
            # add links between aggregation and edge ovs
            for i in range( 0, L2, 2 ):
                    for sw1 in a[i:i+2]:
    	                for sw2 in e[i:i+2]:
    			            self.addLink( sw2, sw1 )
     
            #add hosts and its links with edge ovs
            count = 1
            for sw1 in e:
                    for i in range(2):
                    	host = self.addHost( 'h{}'.format( count ) )
                    	self.addLink( sw1, host )
                    	count += 1
    topos = { 'mytopo': ( lambda: MyTopo() ) }
    

    OpenDayLigtht的远程控制器代码如下:

    先在控制台中运行./karaf打开容器

    接着按照顺序安装feature如下

    install odl-restconf
    install odl-l2switch-switch-ui
    install odl-openflowplugin-all
    install odl-mdsal-apidocs
    install odl-dlux-core
    install odl-dlux-node
    install odl-dlux-yangui
    

    在退出前执行logout退出

    运行完后在YangUI中可见拓扑结构如图

    节点编号与节点名称关系如下表(加载原因未能加载出全部)

    下发初始流表连接链路

    1.清空所有流表项

    sudo ovs-ofctl -O Openflow13 del-flows c1
    sudo ovs-ofctl -O Openflow13 del-flows c2
    sudo ovs-ofctl -O Openflow13 del-flows a3
    sudo ovs-ofctl -O Openflow13 del-flows a4
    sudo ovs-ofctl -O Openflow13 del-flows a5
    sudo ovs-ofctl -O Openflow13 del-flows a6
    sudo ovs-ofctl -O Openflow13 del-flows e7
    sudo ovs-ofctl -O Openflow13 del-flows e8
    sudo ovs-ofctl -O Openflow13 del-flows e9
    sudo ovs-ofctl -O Openflow13 del-flows e10
    

    2.下发下层流表

    #e7
    sudo ovs-ofctl -O OpenFlow13 add-flow e7 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e7 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e7 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e7 priority=2,in_port=4,actions=output:1,output:2,output:3
    #e8
    sudo ovs-ofctl -O OpenFlow13 add-flow e8 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e8 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e8 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e8 priority=2,in_port=4,actions=output:1,output:2,output:3
    #e9
    sudo ovs-ofctl -O OpenFlow13 add-flow e9 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e9 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e9 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e9 priority=2,in_port=4,actions=output:1,output:2,output:3
    #e10
    sudo ovs-ofctl -O OpenFlow13 add-flow e10 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e10 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e10 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow e10 priority=2,in_port=4,actions=output:1,output:2,output:3
    

    3.下发中层流表

    #a3
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=4,actions=output:1,output:2,output:3
    #a4
    sudo ovs-ofctl -O OpenFlow13 add-flow a4 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a4 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a4 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a4 priority=2,in_port=4,actions=output:1,output:2,output:3
    #a5
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=4,actions=output:1,output:2,output:3
    #a6
    sudo ovs-ofctl -O OpenFlow13 add-flow a6 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a6 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a6 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a6 priority=2,in_port=4,actions=output:1,output:2,output:3
    

    4.下发上层流表

    #c1
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=3,actions=output:1,output:2
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=4,actions=output:1,output:2
    #c2
    sudo ovs-ofctl -O OpenFlow13 add-flow c2 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow c2 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow c2 priority=2,in_port=3,actions=output:1,output:2
    sudo ovs-ofctl -O OpenFlow13 add-flow c2 priority=2,in_port=4,actions=output:1,output:2
    

    5.把上述代码封装入shell文件中可以实现一键下发和清空流表

    测试链路可用性

    1.在mininet中运行pingall命令

    说明链路已经连接成功

    2.在OpenDayLigtht拓扑图中可以清晰地看到每一个客户端

    Iperf链路性能测试

    h1连接h2测试:

    可以看到带宽为9.92Gbits/sec

    h1连接h3测试:

    可以看到带宽为2.41Gbits/sec

    h1连接h8测试:

    可以看到带宽为122Mbits/sec

    结论是随着跨交换机网络的转发,性能随着跨交换机网络而减弱,解决方法是用分时间片的方法来负载均衡。

    负载均衡的实现

    通过将某段时间流表设置成c1,a3,a5一组和c2,a4,a6一组来达到交换机的负载均衡,以提高性能。

    负载均衡后再次执行链路性能测试

    h1连接h2因为没有链路变化所以带宽基本不变

    h1连接h3可以看到带宽从2.41Gbit/sec提高到了3.87Gbit/sec

    h1连接h8可以看到带宽从122Mbit/sec提升到了292Mbit/sec

    成组打开并关闭代码:

    import os
    import time
    def runteam1():
    	os.system("./addt1.sh")
    	time.sleep(1)
    	os.system("./delt2.sh")
    	return 1;
    def runteam2():
    	os.system("./addt2.sh")
    	time.sleep(1)
    	os.system("./delt1.sh")
    	return 1;
    os.system("./delflows.sh")
    os.system("./inite.sh")
    while(True):
    	runteam1()
    	runteam2()
    

    addt1.sh代码:

    #c1
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=3,actions=output:1,output:2
    sudo ovs-ofctl -O OpenFlow13 add-flow c1 priority=2,in_port=4,actions=output:1,output:2
    #a3
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a3 priority=2,in_port=4,actions=output:1,output:2,output:3
    #a5
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=1,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=2,actions=output:3,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=3,actions=output:1,output:2,output:4
    sudo ovs-ofctl -O OpenFlow13 add-flow a5 priority=2,in_port=4,actions=output:1,output:2,output:3
    

    delt1.sh代码:

    sudo ovs-ofctl -O Openflow13 del-flows c1
    sudo ovs-ofctl -O Openflow13 del-flows a3
    sudo ovs-ofctl -O Openflow13 del-flows a5
    
    

    addt2.sh、delt2.sh、inite.sh、delflows.sh的代码和上述示例十分接近,故不在赘述

    本次实验因为是在本机进行,所以使用的是ovs-ofctl命令,若要进行远程的流表的下发,则需要使用Restful接口远程下发流表,下发内容与以上近似。

    实验总结

    经过本次实验,对OpenFlow、Mininet、OpenDayLight、OVS控制器等有了更加深入的理解,对软件定义网络也更加熟悉和清晰。

    代码链接

    https://github.com/opsiff/SDNExample

    视频链接

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  • 原文地址:https://www.cnblogs.com/phd1999/p/12154363.html
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