The example is presented below. OpenFlow Example: datagrams from hosts h5 and h6 should be sent to h3 or h4, via s1 and from there to s2 match IP Src = 10.3.*.* IP Dst 10.2.*.* match ingress port = 1 IP Src = 10.3.*.* IP Dst= 10.2.*.* action forward(3) Host h5 10.3.0.5 Host h1 10.1.0.1 action forward(4) Host h6 10.3.0.6 s3 Host h2 10.1.0.2 OpenFlow controller Host h3 10.2.0.3 s2 Host h4 10.2.0.4 match ingress port = 2 IP Dst = 10.2.0.3 ingress port = 2 IP Dst = 10.2.0.4 action forward(3) forward(4) Question 1 [ 5 2 1 1 5 2 Figure 1: Traffic Engineering with Open Flow Figure 1 reveals a network where the traffic flowing from the first host which is attached to routeru to the server which is attached to router z needs to be routed along the path u.v.w.z while the traffic flowing from the second host attached to router x router to the server which is attached to router z needs to be routed along the path x,w.y.z. Please describe the local flow table of each of the switches u.x.x.w.x.z (in terms of match and action rules) to enable the routing of the two traffic flows according to the constraints described above. The following IP addresses will be used for the two hosts and the server. The first host belongs to the subnetwork 10.1.0.0/16. It is attached to router U and has an IP address of 10.1.0.1 The second host belongs to subnetwork 10.5.0.0/16. It is attached to router X and has an IP address of 10.5.0.1 The server belongs to the subnetwork 10.11.0.0/16. It is attached to router Z and has an IP address of 10.11.0.1 The example is presented below.
The example is presented below. OpenFlow Example: datagrams from hosts h5 and h6 should be sent to h3 or h4, via s1 and from there to s2 match IP Src = 10.3.*.* IP Dst 10.2.*.* match ingress port = 1 IP Src = 10.3.*.* IP Dst= 10.2.*.* action forward(3) Host h5 10.3.0.5 Host h1 10.1.0.1 action forward(4) Host h6 10.3.0.6 s3 Host h2 10.1.0.2 OpenFlow controller Host h3 10.2.0.3 s2 Host h4 10.2.0.4 match ingress port = 2 IP Dst = 10.2.0.3 ingress port = 2 IP Dst = 10.2.0.4 action forward(3) forward(4) Question 1 [ 5 2 1 1 5 2 Figure 1: Traffic Engineering with Open Flow Figure 1 reveals a network where the traffic flowing from the first host which is attached to routeru to the server which is attached to router z needs to be routed along the path u.v.w.z while the traffic flowing from the second host attached to router x router to the server which is attached to router z needs to be routed along the path x,w.y.z. Please describe the local flow table of each of the switches u.x.x.w.x.z (in terms of match and action rules) to enable the routing of the two traffic flows according to the constraints described above. The following IP addresses will be used for the two hosts and the server. The first host belongs to the subnetwork 10.1.0.0/16. It is attached to router U and has an IP address of 10.1.0.1 The second host belongs to subnetwork 10.5.0.0/16. It is attached to router X and has an IP address of 10.5.0.1 The server belongs to the subnetwork 10.11.0.0/16. It is attached to router Z and has an IP address of 10.11.0.1 The example is presented below.
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