I recently came across this (Edit: Problem A) interesting problem from Spotify's hacker challenge earlier this year which involves determining the switching at train truck junctions to route a train back to it's starting point. The train must arrive facing the same direction it left and the train can never reverse on the tracks.
As I understand it, the problem can be modeled as an undirected(?) graph where we must find the shortest cycle from a certain vertex, or detect that no such cycle exists. However, the interesting part is that for a vertex, v, the vertices adjacent to v are dependent on the path taken to v, so in a sense the graph could be considered directed, though this direction is path-dependent.
My first thought was to model each node as 3 separate vertices, A, B and C, where A <-> B and A <-> C, and then use a breadth-first search to build a search tree until we find the original vertex, but this is complicated by the caveat above, namely that the adjacencies for a given vertex depend on the previous vertex we visited. This means that in our BFS tree, nodes can have multiple parents.
Obviously a simple BFS search won't be sufficient to solve this problem. I know there are algorithms that exist to detect cycles in a graph. One approach might be to detect all the cycles, then for each cycle, detect whether the path is valid. (i.e., does not reverse direction)
Does anyone else have any insights on approaches to solving this problem?
UPDATE: I followed the approach suggested by @Karussell in the comments.
The trick was to model the situation using an edge-based graph, not a traditional vertex-based graph. The input file supplied in the contest is conveniently specified in terms of edges already, so this file can be easily used to build an edge-based graph.
The program uses two important classes: Road and Solver. A Road has two integer fields, j1 and j2. j1 represents the source junction and j2 represents the target junction. Each road is one-way, meaning that you can only travel from j1 to j2. Each Road also includes a LinkedList of adjacent Roads and a parent Road. The Road class also includes static methods to convert between the Strings used in the input file and integer indexes representing the A, B, and C points at each junction.
For each entry in the input file, we add two Roads to a HashMap, one Road for each direction between the two junctions. We now have a list of all of the Roads that run between junctions. We just need to connect the roads together at the junctions through the A, B and C switches. If a Road ends at Junction.A, we look up the roads that begin at Junction.B and Junction.C and add these roads as adjacencies. The buildGraph() function returns the Road whose target junction (j2) is "1A" == index 0.
At this point, our graph is constructed. To find the shortest path I simply used a BFS to traverse the graph. We leave the root unmarked and begin by queueing the root's adjacencies. If we find a road whose target junction is "1A" (index 0) then we have found the shortest cycle through the starting point. Once we reconstruct the path using each Road's parent property, it's a trivial matter to set the switches appropriately as required in the problem.
Thanks to Karussell for suggesting this approach. If you want to put your comment in answer form with a short explanation, I will accept it. Thanks to @Origin, as well. I must admit that I did not fully follow the logic of your answer, but that is certainly not to say that it is not correct. If anyone solves this problem using your solution, I would be very interested to see it.