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Let's say we have a fully connected directed graph G. The vertices are [a,b,c]. There are edges in both directions between each vertex.

Given a starting vertex a, I would like to traverse the graph in all directions and save the path only when I hit a vertex which is already in the path.

So, the function full_paths(a,G) should return:

- [{a,b}, {b,c}, {c,d}]
- [{a,b}, {b,d}, {d,c}]
- [{a,c}, {c,b}, {b,d}]
- [{a,c}, {c,d}, {d,b}]
- [{a,d}, {d,c}, {c,b}]
- [{a,d}, {d,b}, {b,c}]

I do not need 'incomplete' results like [{a,b}] or [{a,b}, {b,c}], because it is contained in the first result already.

Is there any other way to do it except of generating a powerset of G and filtering out results of certain size?

How can I calculate this?

Edit: As Ethan pointed out, this could be solved with depth-first search method, but unfortunately I do not understand how to modify it, making it store a path before it backtracks (I use Ruby Gratr to implement my algorithm)

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2 Answers 2

up vote 1 down vote accepted

Have you looked into depth first search or some variation? A depth first search traverses as far as possible and then backtracks. You can record the path each time you need to backtrack.

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Ethan, I thought about dfs, but I don't get how I can exactly record each path. –  skanatek Nov 11 '11 at 19:53
Look at the callback options and the example given in the documentation for bfs. You can use the callbacks to keep track of the edges traversed and the vertexes visited to keep track of each path. –  ethan Nov 11 '11 at 20:13

If you know your graph G is fully connected there is N! paths of length N when N is number of vertices in graph G. You can easily compute it in this way. You have N possibilities of choice starting point, then for each starting point you can choose N-1 vertices as second vertex on a path and so on when you can chose only last not visited vertex on each path. So you have N*(N-1)*...*2*1 = N! possible paths. When you can't chose starting point i.e. it is given it is same as finding paths in graph G' with N-1 vertices. All possible paths are permutation of set of all vertices i.e. in your case all vertices except starting point. When you have permutation you can generate path by:

perm_to_path([A|[B|_]=T]) -> [{A,B}|perm_to_path(T)];
perm_to_path(_) -> [].

simplest way how to generate permutations is

permutations([]) -> [];
permutations(L) ->
  [[H|T] || H <- L, T <- permutations(L--[H])].

So in your case:

paths(A, GV) -> [perm_to_path([A|P]) || P <- permutations(GV--[A])].

where GV is list of vertices of graph G.

If you would like more efficient version it would need little bit more trickery.

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