Suppose we have switches S1 through S4; the forwarding-table destinations are the switches themselves. The tables for S2 and S3 are as below, where the next_hop value is specified in neighbor form:

S2: ⟨S1,S1⟩ ⟨S3,S3⟩ ⟨S4,S3⟩

S3: ⟨S1,S2⟩ ⟨S2,S2⟩ ⟨S4,S4⟩

From the above we can conclude that S2 must be directly connected to both S1 and S3 as its table lists them as next_hops; similarly, S3 must be directly connected to S2 and S4.

(a). The given tables are consistent with the network diagrammed in exercise 6.0. Are the tables also consistent with a network in which S1 and S4 are not directly connected? If so, give such a network; if not, explain why S1 and S4 must be connected.

(b). Now suppose S3’s table is changed to the following. Find a network layout consistent with these tables in which S1 and S4 are not directly connected. Do not add additional switches.

S3: ⟨S1,S4⟩ ⟨S2,S2⟩ ⟨S4,S4⟩

While the table for S4 is not given, you may assume that forwarding does work correctly. However, you should not assume that paths are the shortest possible. Hint: It follows from the S3 table above that the path from S3 to S1 starts S3 ⟶ S4; how will this path continue? The next switch along the path cannot be S1, because of the hypothesis that S1 and S4 are not directly connected.