# Algorithm: find connections between towns with a limit of train changes

What algorithm would you use to create an application that given appropriate data (list of cities, train routes, train stations) is capable of returning a list of connection between any two user-selected cities? The application has to choose only those connections that fall into the limit of accepted train-changes.

Example: I ask the application which train to take if I need to travel from Paris to Moscow with max. 1 stop/switch - the application returns a route: Train 1 (Paris-Berlin) -> Train 2 (Berlin->Moscow) (No direct connection exists).

Graphical example

http://i.imgur.com/KEJ3I.png

If I ask the system about possible connections from Town A to Town G I get a response:

• Brown Line (0 switches = direct)
• Brown Line to Town B / Orange Line to Town G (1 switch)
• Brown Line to Town B / Orange Line to Town D / Red Line to G (2 switch)
• ... all other possibilities

And thouh the 2nd and 3rd options are shorter than the 1st, it's the 1st that should have priority (since no train-switching is involved).

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Assuming the only thing important is "number of stops/switches", then the problem is actually finding a shortest path in an unweighted directed graph.

The graph model is G = (V,E) where V = {all possible stations} and E = { (u,v) | there is a train/route from station u to station v }
Note: let's say you have a train which starts at a_0, and paths through a_1, a_2,...a_n: then E will contain: (a_0,a_1),(a_0,a_2),..,(a_0,a_n) and also (a_1,a_2),(a_1,a_3),... formally: for each i < j : (a_i,a_j) ∈ E.

BFS solves this problem, and is both complete [always finds a solution if there is one] and optimal [finds the shortest path].

If the edges [routes] are weighted, something like dijkstra's algorithm will be needed instead.

If you want a list of all possible routes, Iterative-Deepening DFS could be used, without maintaining a visited set, and print all the paths found to the target up to the relevant depth. [BFS fails to return all paths with the counter example of a clique]

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I updated my question. Are you sure about the answer?? – Queequeg Apr 4 '12 at 16:28
@Queequeg The answer still holds. Given a source city s and target city t, run BFS from s. The path found by BFS is the shortest, and thus requires less switches then any other path. <br/>But BFS would count every city/node as a switch and thats not true - i.e. brown line would not be chosen by BFS but its THE optimal solution – Queequeg Apr 4 '12 at 16:32
@Queequeg: I understand where your confusion was. I updated the answer [see the bolded Note], brown line will be chosen, since you will add a direct edge from townA to townG, so the shortest path found by BFS is (townA,townG) - which is the path without switches, as expected. – amit Apr 4 '12 at 16:38
I get it. Nice idea! But the memory-overhead would be huge wouldnt it? – Queequeg Apr 4 '12 at 16:40
@Queequeg: Traditionally for graphs, |E|=O(|V|^2), the number of edges is at most quadric to the number of vertices. This case is not different- since at the "worst case" you have a train that paths through all stations from each source, so E = V x V [you have a clique!], and you get |E|=O(|V|^2). For this specific case, you get |E| = O(|V|*longest_train_path), which is not worse then O(|V|^2) – amit Apr 4 '12 at 16:46

I think you need to compute all pairs shortest paths. Check http://en.wikipedia.org/wiki/Floyd%E2%80%93Warshall_algorithm.

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I updated my question - please take a look – Queequeg Apr 4 '12 at 16:28