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Problem: given an undirected graph G, a subset H of the vertex set V, (i.e. H is a subset of V) and a starting vertex s (s is in V).

Design an algorithm that finds the lengths of the shortest paths from s to all vertices such that the paths don’t go through any intermediate vertex in H (meaning that you can end at a vertex in H but you cannot go through any vertex in H.) (If no such path exists then set the length to ∞. All edges are the same length.)

(The output of the algorithm should be an array similar to the dist array of BFS and Dijkstra’s.)

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    I’m voting to close this question because it about designing an algorithm and not about programming. – AdrianHHH Oct 20 '20 at 20:05
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    @AdrianHHH I agree that this question should be closed, but not because its about designing algorithms. I'm pretty sure thats on-topic. Instead, I believe this to be off topic because the question is a requirements list and includes no attempt at a solution or indication of research. This puts it into the "no detail or clarity" close reason. – code11 Oct 21 '20 at 15:12
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    I don't see a question here, just a problem statement. Is this something you're trying to accomplish? Have you made an attempt and run into a problem? – TylerH Oct 21 '20 at 15:33
  • @code11 The link you provide does not have any conclusion or preferred approach. The comments seem to me to say that design of an algorithm is off-topic whereas help on implementation may be on-topic. – AdrianHHH Oct 21 '20 at 21:25
  • Good catch. That was the best sounding guidance but you're right that there is no consensus there. This seems to indicate that some questions are better moved to CS. But this particular one seems more likely to belong on SO, as long as OP edits it to include a question. – code11 Oct 22 '20 at 13:16
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There is a straightforward way to solve this:

  1. Run Dijkstra's for V - H, i.e. all nodes except those in H. Let the output be dist.
  2. For every node i in H, the shortest path will be of length min {dist[j] + w[i][j]}, where min is applied across nodes j in V-H (can be made efficient if we have an adjacency list instead of matrix).

So basically, with Dijkstra, find the shortest paths to nodes not in H. Then, the shortest path to nodes in H is simply the shortest extension from a node in V-H to itself. (And for nodes in H that are not directly connected to V-H, they'd have ∞ as question states).

Noticed per @jrook's comment that you mentioned all edges are of same length. Then BFS can be used instead of Dijkstra's as well.

Another solution is running BFS on a modified version of the graph:

  • Remove all edges within nodes in H among themselves.
  • Make the edges between nodes in V-H and H directed, with the direction being from V-H to H.
  • Make all other edges (i.e. those between nodes in V-H) directed by adding a directed edge in both directions.

In this modified and directed graph, you can apply BFS or Dijkstra to find the shortest paths of desired condition.

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  • Why not just run SP with H added back? H can have inner nodes too. So we can not necessarily rely on V - H to calculate SPs ending in H. – jrook Oct 20 '20 at 16:46
  • Inner nodes would simply have infinity length then, as question states. We can't use them in our paths -- the question says nodes in H can only be the ending nodes of a path. – Cihan Oct 20 '20 at 16:48
  • Perhaps the OP should clarify. But I don't see inner nodes having infinite weights. The question indeed states that : "All edges are the same length". So it could be the case that a node within H can be reached faster without going through V-H first. – jrook Oct 20 '20 at 16:51
  • The question only forbids paths going through H for destinations outside of H, but does not say anything about weights in H per se. – jrook Oct 20 '20 at 16:52
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    (1) I didn't notice "all edges are same length", then in my answer we can replace Dijkstra's with BFS. (2) The question says "...paths don’t go through any intermediate vertex in H...". I think it's pretty clear that we can only use vertices in H as the last node in a path. – Cihan Oct 20 '20 at 16:54

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