Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Can anyone tell me, where on the web I can find an explanation for Bron-Kerbosch algorithm for clique finding or explain here how it works?

I know it was published in "Algorithm 457: finding all cliques of an undirected graph" book, but I can't find free source that will describe the algorithm.

I don't need a source code for the algorithm, I need an explanation of how it works.

share|improve this question
2  
Alex I bet that post was down-voted for "tell me, where on the web..." Don't ask people to do you job. Just ask them to clarify how it works –  aku Sep 27 '08 at 6:52
    
I meant on the web as in not in the book, since I won't have any access to library for about two weeks :( –  Alex Reitbort Sep 27 '08 at 8:33
1  
Rather than asking for a source, better to say "tell me how ... works", along with a description of what's specifically puzzling you, then the answer (and context of your question) will be here for others encountering it in future. The accepted answer here is near-useless. –  SimonJ Nov 13 '10 at 23:28
add comment

7 Answers

up vote 3 down vote accepted

Try finding someone with an ACM student account who can give you a copy of the paper, which is here: http://portal.acm.org/citation.cfm?doid=362342.362367

I just downloaded it, and it's only two pages long, with an implementation in Algol 60!

share|improve this answer
    
can you please send it to me at joker99+bron@gmail.com ? –  Alex Reitbort Sep 27 '08 at 13:26
add comment

i find the explanation of the algorithm here: http://www.dfki.de/~neumann/ie-seminar/presentations/finding_cliques.pdf it's a good explanation... but i need a library or implementation in C# -.-'

share|improve this answer
add comment

There is the algorithm right here I have rewritten it using Java linkedlists as the sets R,P,X and it works like a charm (o good thing is to use the function "retainAll" when doing set operations according to the algorithm).

I suggest you think a little about the implementation because of the optimization issues when rewriting the algorithm

share|improve this answer
add comment

For what it is worth, I found a Java implementation: http://joelib.cvs.sourceforge.net/joelib/joelib2/src/joelib2/algo/clique/BronKerbosch.java?view=markup

HTH.

share|improve this answer
    
I found 2 java implementations and one C implementation. May be it works, but I also need an understanding of how does it work, and source code doesn't have a lot of comments about how does it works. –  Alex Reitbort Sep 27 '08 at 13:25
add comment

I have implemented both versions specified in the paper. I learned that, the unoptimized version, if solved recursively helps a lot to understand the algorithm. Here is python implementation for version 1 (unoptimized):

def bron(compsub, _not, candidates, graph, cliques):
    if len(candidates) == 0 and len(_not) == 0:
        cliques.append(tuple(compsub))
        return
    if len(candidates) == 0: return
    sel = candidates[0]
    candidates.remove(sel)
    newCandidates = removeDisconnected(candidates, sel, graph)
    newNot = removeDisconnected(_not, sel, graph)
    compsub.append(sel)
    bron(compsub, newNot, newCandidates, graph, cliques)
    compsub.remove(sel)
    _not.append(sel)
    bron(compsub, _not, candidates, graph, cliques)

And you invoke this function:

graph = # 2x2 boolean matrix
cliques = []
bron([], [], graph, cliques)

The variable cliques will contain cliques found.

Once you understand this it's easy to implement optimized one.

share|improve this answer
    
Shouldn't even version 1 of the algorithm check if not contains an element which is a neighbor of every element in candidates and backtrack if that is the case? –  Andreas Vinter-Hviid May 24 at 17:56
add comment

Boost::Graph has an excellent implementation of Bron-Kerbosh algorithm, give it a check.

share|improve this answer
add comment

I was also trying to wrap my head around the Bron-Kerbosch algorithm, so I wrote my own implementation in python. It includes a test case and some comments. Hope this helps.

class Node(object):

    def __init__(self, name):
        self.name = name
        self.neighbors = []

    def __repr__(self):
        return self.name

A = Node('A')
B = Node('B')
C = Node('C')
D = Node('D')
E = Node('E')

A.neighbors = [B, C]
B.neighbors = [A, C]
C.neighbors = [A, B, D]
D.neighbors = [C, E]
E.neighbors = [D]

all_nodes = [A, B, C, D, E]

def find_cliques(potential_clique=[], remaining_nodes=[], skip_nodes=[], depth=0):

    # To understand the flow better, uncomment this:
    # print (' ' * depth), 'potential_clique:', potential_clique, 'remaining_nodes:', remaining_nodes, 'skip_nodes:', skip_nodes

    if len(remaining_nodes) == 0 and len(skip_nodes) == 0:
        print 'This is a clique:', potential_clique
        return

    for node in remaining_nodes:

        # Try adding the node to the current potential_clique to see if we can make it work.
        new_potential_clique = potential_clique + [node]
        new_remaining_nodes = [n for n in remaining_nodes if n in node.neighbors]
        new_skip_list = [n for n in skip_nodes if n in node.neighbors]
        find_cliques(new_potential_clique, new_remaining_nodes, new_skip_list, depth + 1)

        # We're done considering this node.  If there was a way to form a clique with it, we
        # already discovered its maximal clique in the recursive call above.  So, go ahead
        # and remove it from the list of remaining nodes and add it to the skip list.
        remaining_nodes.remove(node)
        skip_nodes.append(node)

find_cliques(remaining_nodes=all_nodes)
share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.