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I am looking for a concurrent algorithm which would help me in detecting cycles in a directed graph.

I know that the sequential algorithm uses a dfs with colouring, however I think that it will fail in a multi threaded environment. One example of a directed graph to illustrate it:

A->(B, C), B-> (D), D-> (E), C-> (E), E-> (F)

                         A
                        / \
                       B   C
                       |   |
                       D   |
                        \ /
                         E
                         |
                         F

(I hope the above makes it clear. The edges in the graph are all top to botton)

For the above directed graph, the following execution is possible during concurrent execution.

(the colouring scheme I assumed is white - unvisited, grey - execution of dfs not finished and black - finished execution and visit)

Dfs(B) by thread 1, which eventually colour E as grey and does a dfs(E) (leading to F). Before this is finished, thread 2 executes dfs(C). It realises that E is grey and reports a cycle which is obviously not the case.

I checked that Tarjan's algo could also be used for cycle detection, but again I do not think its execution will be correct in a multi threaded environment.

Could somebody please help me out on this?

Thanks.

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As Ira states let each thread use its own colour.

But, If you have a fixed number of threads use a bit map for each of the colours. As, long as you processor supports an atomic bit test and set (i.e. BTST on x86) you wont event need locking as each thread will be testing and setting a different bit.

If the bit is set then the item is coloured grey.

PS: If you need more colours then you can use more bits.

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Thanks for the reply. "as Ira states" ? sorry but I cant see any reply from Ira if that is what you mean. Also, I did think about different colours for each thread, but how would you handle a cycle that spans more than 1 thread? – Harsha May 22 '12 at 9:24
    
he deleted his answer. – PAntoine May 22 '12 at 9:49
    
You have access to all the other threads colours (in the bit array). So you could check to see if it has been visited by someone else. If you skip the ones visited by other threads (copy the colour) then that might work? Do you care about cycles in other threads? – PAntoine May 22 '12 at 9:54
    
I need to ensure that the whole graph does not have a cycle. Skipping does not completely help me, as I think it would not detect some of the cycles. Could you please elaborate the algorithm that you are thinking of? – Harsha May 22 '12 at 10:15
    
If another thread has already coloured the item, ignore it (or copy the colour) then you can move onto the next item (i assume there is a processing step for each item). So essentially each thread walks the whole tree as if it is single threaded. You will probably need another colour for start processing, as a semaphore so that two items don't try to process the same item. – PAntoine May 22 '12 at 10:23

You should easily find distributed deadlock detection algorithms, that adress the cycle detection problem.

I understand that distributed isn't exactly multithread, but you should still find hints there.

Edit : added a restricted solution.

share|improve this answer
    
Thanks @Pyra, I did come across a distributed algorithm and will eventually try and implement something similar if I do not get anything better, but I am really hoping I would not have to do that. My main problem is that for distributed algos to work efficiently (I am guessing) there should be minimal edges from one distributed component (of the graph) to the other, which would not be the case for the multi threaded implementation (unless some separation is done before the start of the algorithm) – Harsha May 22 '12 at 10:20
    
Could you clarify your thought ? The paradigm behind most of these distributed algorithm is that every node stores and processes informations, based on the messages that are sent to them. Using a thread, you could easily assume that one step of your thread's walk is a message sent, and that the methods executed by your thread when he visits a node are algorithms executed by that node. Your threaded program would be like a distributed algorithm, with a specific scheduling dictated by the thread's walk order. – Pyra May 22 '12 at 11:36
    
Do you have specific constraints on the datamodel or the way you can walk the graph ? – Pyra May 22 '12 at 11:41
    
For instance, a simple solution which depends on available data (can determine which nodes are roots, can access infos that are on predecessor node) : Each node holds a variable V whose value is initially equal to the number of predecessor this node has. Each thread start in one of the roots of the graph, and walks the graph. In each node, the thread lowers the value of V by 1. If V > 0, this node is treated as a leaf, otherwise, the thread may explore its sons. Once this first walk is done, you do a second walk. If any node vas V>0, then there is a cycle. – Pyra May 22 '12 at 12:02
    
Ok I took two examples to try your solution and understand it. A->B B->C C->B. V for A CB C would be 0 2 1. V(B) would 1 after it is accessed via A and then 0 via C (cycle not detected). However if I say B has been accessed and hence V(B) should remain at 1, then the other example I have proves the algorithm to be wrong. A->C,B->C,C->D. V(C) is 2 and will come down to 1 and if I assume that C has been accessed then V(C) stays at 1 and cycle is reported. Please let me know if I have not understood your algorithm correctly. – Harsha May 23 '12 at 6:58

I have come across this algorithm which I thought to share here

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That link appears to be dead. Can you post an updated one? – templatetypedef Oct 7 '13 at 22:56
    
[mcndfs]{eprints.eemcs.utwente.nl/20337/01/mcndfs.pdf} – Trojosh Oct 8 '13 at 23:17

For multithreaded cycle detection, it's better to use a variant of the Kahn algorithm (for topological sort) instead of DFS. This uses the facts that:

1) If a directed graph is acyclic, then it has at least one vertex with no in-edges, and at least one vertex with no out-edges;

2) A vertex with no in-edges or no out-edges cannot participate in a cycle; so

3) If you remove a vertex with no in-edges or no out-edges, you're left with a smaller directed graph with the same cycles as the original.

So, to do a parallel cycle detection, you can:

1) First, use a parallel BFS to build a data structure that keeps track of the in-degree and out-degree of each vertex.

2) Then, in parallel, remove vertices with in-degree or out-degree 0. Note that removing a vertex will decrement the in-degrees or out-degrees of adjacent nodes.

3) When you're out of vertices to remove, you're left with all the vertices that are involved in cycles. If there aren't any, then the original graph was acyclic.

Both the parallel BFS (step 1) and parallel vertex removal (step 2) are easily accomplished with parallel work queues. In step 1, when you see a vertex for the first time, add a task to the queue that processes adjacent vertices. In step 2, when you decrement a vertex's in-degree or out-degree to 0, add a task to remove it from the graph.

Note that this algorithm works just as well if you remove only nodes with in-degree 0 or nodes with out-degree 0, but opportunities for parallelism are somewhat reduced.

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