• 实验 三:Mininet 实验——测量路径的损耗率


    实验 三:Mininet 实验——测量路径的损耗率

    一、实验目的

    在实验 2 的基础上进一步熟悉 Mininet 自定义拓扑脚本,以及与损耗率相关的设

    定;初步了解 Mininet 安装时自带的 POX 控制器脚本编写,测试路径损耗率。

    二、实验任务

    h0 向 h1 发送数据包,由于在 Mininet 脚本中设置了连接损耗率,在传输过程中

    会丢失一些包,本次实验的目的是展示如何通过控制器计算路径损耗速率(h0-

    s0-s1-h1)。这里假设控制器预先知道网络拓扑。控制器将向 s0 和 s1 发送

    flow_stats_request,当控制器接收到来自 s0 的 response 时,将特定流的数据包

    数保存在 input_pkts 中,当控制器接收到来自 s1 的 response 时,将接收到特定

    流的数据包数保存在 output_pkts 中,差值就是丢失的数据包数量。

    基于上述拓扑,编写 Mininet 脚本,设置特定的交换机间的路径损耗速率,然后

    编写 POX 控制器脚本,实现对路径的损耗率的测量。

    三、实验步骤

    1. 实验环境

    安装了 Ubuntu 16.04.5 Desktop amd64 的虚拟机实验过程。

    2.实验过程

    1.若pox被锁则输入:

    sudo chmod 777 pox

    2 利用sudo gedit编辑文件

    新建并编辑 pox 脚本 flowstat.py:

    在 pox 安装目录下(Mininet 完整安装包含了 pox)执行以下命令运行 pox 脚本

    $ ./pox.py

    脚本代码如下:

    #!/usr/bin/python
    # Copyright 2012 William Yu
    # wyu@ateneo.edu
    #
    # This file is part of POX.
    #
    # POX is free software: you can redistribute it and/or modify
    # it under the terms of the GNU General Public License as published by
    # the Free Software Foundation, either version 3 of the License, or
    # (at your option) any later version.
    #
    # POX is distributed in the hope that it will be useful,
    # but WITHOUT ANY WARRANTY; without even the implied warranty of
    # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
    # GNU General Public License for more details.
    #
    # You should have received a copy of the GNU General Public License
    # along with POX. If not, see <http://www.gnu.org/licenses/>.
    #
     
    """
    This is a demonstration file created to show how to obtain flow 
    and port statistics from OpenFlow 1.0-enabled switches. The flow
    statistics handler contains a summary of web-only traffic.
    """
     
    # standard includes
    from pox.core import core
    from pox.lib.util import dpidToStr
    import pox.openflow.libopenflow_01 as of
    from pox.lib.addresses import IPAddr, EthAddr
     
    # include as part of the betta branch
    from pox.openflow.of_json import *
    from pox.lib.recoco import Timer
    import time
     
    log = core.getLogger()
     
    src_dpid = 0
    dst_dpid = 0
    input_pkts = 0
    output_pkts = 0
     
    def getTheTime():  #fuction to create a timestamp
      flock = time.localtime()
      then = "[%s-%s-%s" %(str(flock.tm_year),str(flock.tm_mon),str(flock.tm_mday))
      
      if int(flock.tm_hour)<10:
        hrs = "0%s" % (str(flock.tm_hour))
      else:
        hrs = str(flock.tm_hour)
      if int(flock.tm_min)<10:
        mins = "0%s" % (str(flock.tm_min))
      else:
        mins = str(flock.tm_min)
      if int(flock.tm_sec)<10:
        secs = "0%s" % (str(flock.tm_sec))
      else:
        secs = str(flock.tm_sec)
      then +="]%s.%s.%s" % (hrs,mins,secs)
      return then
     
    # handler for timer function that sends the requests to all the
    # switches connected to the controller.
    def _timer_func ():
      for connection in core.openflow._connections.values():
        connection.send(of.ofp_stats_request(body=of.ofp_flow_stats_request()))
        connection.send(of.ofp_stats_request(body=of.ofp_port_stats_request()))
      log.debug("Sent %i flow/port stats request(s)", len(core.openflow._connections))
     
    # handler to display flow statistics received in JSON format
    # structure of event.stats is defined by ofp_flow_stats()
    def _handle_flowstats_received (event):
       #stats = flow_stats_to_list(event.stats)
       #log.debug("FlowStatsReceived from %s: %s", dpidToStr(event.connection.dpid), stats)
       global src_dpid, dst_dpid, input_pkts, output_pkts
       #print "src_dpid=", dpidToStr(src_dpid), "dst_dpid=", dpidToStr(dst_dpid)
       for f in event.stats:
         if f.match.dl_type==0x0800 and f.match.nw_dst==IPAddr("192.168.123.2") and f.match.nw_tos==0x64 and event.connection.dpid==src_dpid: 
           #print "input: ", f.byte_count, f.packet_count
           input_pkts = f.packet_count
         if f.match.dl_type==0x0800 and f.match.nw_dst==IPAddr("192.168.123.2") and f.match.nw_tos==0x64 and event.connection.dpid==dst_dpid:
           #print "output: ", f.byte_count, f.packet_count  
           output_pkts = f.packet_count
           if input_pkts !=0:
             print getTheTime(), "Path Loss Rate =", (input_pkts-output_pkts)*1.0/input_pkts*100, "%"
     
    # handler to display port statistics received in JSON format
    def _handle_portstats_received (event):
       #print "
    <<<STATS-REPLY: Return PORT stats for Switch", event.connection.dpid,"at ",getTheTime()
       #for f in event.stats:
          #if int(f.port_no)<65534:
            #print "   PortNo:", f.port_no, " Fwd's Pkts:", f.tx_packets, " Fwd's Bytes:", f.tx_bytes, " Rc'd Pkts:", f.rx_packets, " Rc's Bytes:", f.rx_bytes
            #print "   PortNo:", f.port_no,  " TxDrop:", f.tx_dropped, " RxDrop:", f.rx_dropped, " TxErr:", f.tx_errors, " RxErr:", f.rx_errors, " CRC:", f.rx_crc_err, " Coll:", f.collisions 
      stats = flow_stats_to_list(event.stats)
      log.debug("PortStatsReceived from %s: %s", dpidToStr(event.connection.dpid), stats)
     
    def _handle_ConnectionUp (event):
      global src_dpid, dst_dpid
      print "ConnectionUp: ", dpidToStr(event.connection.dpid)
      for m in event.connection.features.ports:
        if m.name == "s0-eth0":
          src_dpid = event.connection.dpid
        elif m.name == "s1-eth0":
          dst_dpid = event.connection.dpid
     
      msg = of.ofp_flow_mod()
      msg.priority =1
      msg.idle_timeout = 0
      msg.match.in_port =1
      msg.actions.append(of.ofp_action_output(port = of.OFPP_ALL))
      event.connection.send(msg)
     
      msg = of.ofp_flow_mod()
      msg.priority =1
      msg.idle_timeout = 0
      msg.match.in_port =2
      msg.actions.append(of.ofp_action_output(port = of.OFPP_ALL))
      event.connection.send(msg)
     
      msg = of.ofp_flow_mod()
      msg.priority =10
      msg.idle_timeout = 0
      msg.hard_timeout = 0
      msg.match.dl_type = 0x0800
      msg.match.nw_tos = 0x64
      msg.match.in_port=1
      msg.match.nw_dst = "192.168.123.2"
      msg.actions.append(of.ofp_action_output(port = 2))
      event.connection.send(msg)
     
      msg = of.ofp_flow_mod()
      msg.priority =10
      msg.idle_timeout = 0
      msg.hard_timeout = 0
      msg.match.dl_type = 0x0800
      msg.match.nw_tos = 0x64
      msg.match.nw_dst = "192.168.123.1"
      msg.actions.append(of.ofp_action_output(port = 1))
      event.connection.send(msg)
        
    # main functiont to launch the module
    def launch ():
      # attach handsers to listners
      core.openflow.addListenerByName("FlowStatsReceived", 
        _handle_flowstats_received) 
      core.openflow.addListenerByName("PortStatsReceived", 
        _handle_portstats_received) 
      core.openflow.addListenerByName("ConnectionUp", _handle_ConnectionUp)
     
      # timer set to execute every five seconds
      Timer(1, _timer_func, recurring=True)
    

    结果如图:

    代码解释:

    第 7 行开始, h0 ping h1****,监测 s0 s1 之间的链路

    ⚫ 如果匹配到以太网类型的包头(0x0800),并且数据包的目的 IP 地址是

    192.168.123.2(对照后面 Mininet 的脚本发现是 h1),并且连接到控制器的数

    据平面设备 id 是 s0(h0 ping h1****,链路 s0-s1 上数据包是从 s0 流向 s1s0

    源,****s1 为目的地),执行 input_pkts = f.packet_count,把数据包数量存入

    input_pkts;

    ⚫ 同理,如果连接到控制器的数据平面设备 id 是 s1,执行 output_pkts =

    f.packet_count,把数据包数量存入 output_pkts。

    ⚫ 最后求 input_pkts 和 output_pkts 的差值。一般情况下差值为正,说明链路上

    数据包有损耗。

    3 编辑 Mininet 脚本 mymininet3.py

    参照拓扑图,新建并编辑 Mininet 脚本 mymininet3.py,控制器因为安装在本机,

    所以需修改参考资料代码中的控制器地址为 127.0.0.1:6633

    switch.cmd( 'ovs-vsctl set-controller dp0 tcp:127.0.0.1:6633' )
    
    switch1.cmd( 'ovs-vsctl set-controller dp1 tcp:127.0.0.1:6633' )
    

    设置 s0 和 s1 之间链路的丢包率为 0

    info( " Creating links
    " )
     linkopts0=dict(bw=100, delay='1ms', loss=0)
     linkopts1=dict(bw=100, delay='1ms', loss=0)
     link0=TCLink( h0, switch, **linkopts0)
     link1 = TCLink( switch, switch1, **linkopts1) 
     link2 = TCLink( h1, switch1, **linkopts0)
    

    再执行命令运行 Mininet 脚本 mymininet3.py

    $ sudo python mymininet3.py

    结果如下:

    解释:Ping 默认是每 1 秒钟测一次,ping 的结果会显示一个丢包率,这里的丢包率是根 据 ping 不通的次数占总次数的百分比计算得到的。上图中由于一共 ping 了 20次,每次都能通,所以丢包率是 0。观察 pox 侧的实时状态更新平均丢包率为 0,结果符合 Mininet 脚本中设置的损耗率,也有可能出现负值,可以认为没有丢包。

    如果修改代码中 s0 和 s1 之间链路的丢包率为 10。

    info( "Creating links
    " )
     linkopts0=dict(bw=100, delay='1ms', loss=0)
     linkopts1=dict(bw=100, delay='1ms', loss=10)
     link0=TCLink( h0, switch, **linkopts0)
     link1 = TCLink( switch, switch1, **linkopts1) 
     link2 = TCLink( h1, switch1, **linkopts0)
    

    重新运行 Mininet 脚本 mymininet3.py,20 秒时间的 ping 过程中有 icmp_seq 为2/4/14/16/19/20 共 6 次 ping 不通,所以丢包率计算为 30%。

    结果如下:

    POX 端重新测试,会发现出现丢包现象,但是实际测量出的丢包率会有浮动,链路的性能总体受到了限制。

    四、心得体会

    一开始做实验的时候,丢包率一直为0。

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  • 原文地址:https://www.cnblogs.com/runrun225/p/13709528.html
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