# Cycle detection with BFS

I am trying to detect cycles with BFS algoritm in a directed graph. My main idea to detect the cycles is: since BFS visites each node (and edge) only once, if I encounter an already visited node again; it causes a cycle. However, my code sometimes finds the cycle, sometimes not.

The pseudo code I modified from Wikipedia is below:

``````1  procedure BFS(G,v):
2      create a queue Q
3      enqueue v onto Q
4      mark v
5      while Q is not empty:
6          t <- Q.dequeue()
7          if t is what we are looking for:
8              return t
9          for all edges e in G.adjacentEdges(t) do
13             if u is not marked:
14                  mark u
15                  enqueue u onto Q
16             else:
17                  print "Cycle detected!" //since we saw this node before
``````

What am I missing?

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Are you traversing all nodes when you want to detect cycles? – keyser Jan 24 '13 at 19:06
Where are you getting `t` from since it's not part of the signature `procedure BFS(G,v):` – Konsol Labapen Jan 25 '13 at 13:11

The algorithm you've given may find the target node (and therefore quit) before it finds the cycle.

Which is more important to you: finding the target as quickly as possible or finding the cycle? If you don't care at all about the target, you can remove that part of your algorithm.

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The problem with your implementation is that it assumes the graph is connected. But the reality is you may be deal with a graph that has two connected portion, so that if you start with `v` you will never get into the other portion. To solve your problem, you need to find a way to identify subgraphs that may not be connected. You may find some suggestions on wikipedia http://en.wikipedia.org/wiki/Topological_sorting#Algorithms where they talk about

`````` S ← Set of all nodes with no incoming edges
``````

EDIT:

actually an easy change you can make is instead of enqueueing `v`, enqueue all the nodes Dijkstra style. That way you should always find your cycle. Also where are you getting `t` from since it's not part of the method signature?

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The algorithm you have given might report the existence of a cycle even if no cycle exists. In line number 12, you we have u adjacent to t. A parent of t in BFS tree also lies in it's adjacency list. `So, line 13 might return false even when no cycle exist because a parent of t is marked and is a part of t's adjacency list.`

So, I think this algorithm will report a cycle if it is present but it might also report a cycle even when there is none.

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