# Implementing Bron–Kerbosch algorithm in python

for a college project I'm trying to implement the Bron–Kerbosch algorithm, that is, listing all maximal cliques in a given graph.

I'm trying to implement the first algorithm (without pivoting) , but my code doesn't yield all the answers after testing it on the Wikipedia's example , my code so far is :

``````# dealing with a graph as list of lists
graph = [[0,1,0,0,1,0],[1,0,1,0,1,0],[0,1,0,1,0,0],[0,0,1,0,1,1],[1,1,0,1,0,0],[0,0,0,1,0,0]]

#function determines the neighbors of a given vertex
def N(vertex):
c = 0
l = []
for i in graph[vertex]:
if i is 1 :
l.append(c)
c+=1
return l

#the Bron-Kerbosch recursive algorithm
def bronk(r,p,x):
if len(p) == 0 and len(x) == 0:
print r
return
for vertex in p:
r_new = r[::]
r_new.append(vertex)
p_new = [val for val in p if val in N(vertex)] # p intersects N(vertex)
x_new = [val for val in x if val in N(vertex)] # x intersects N(vertex)
bronk(r_new,p_new,x_new)
p.remove(vertex)
x.append(vertex)

bronk([], [0,1,2,3,4,5], [])
``````

Any help why I'm getting only a part of the answer ?

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First thing - don't use `is` for value comparison - that's what `==` is for – Jon Clements Dec 16 '12 at 19:22
I would advise against using recursion with side effects (recursion itself is tricky enough to get ones head around!). Also, you could write `N` using a list comprehension and `enumerate`. – Andy Hayden Dec 16 '12 at 19:26

Python is getting confused because you are modifying the list that it is iterating over.

Change

``````for vertex in p:
``````

to

``````for vertex in p[:]:
``````

this will cause it to iterate over a copy of p instead.

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Thanks very much! that was the problem there. – a.u.r Dec 16 '12 at 19:41

As @VaughnCato correctly points out the error was iterating over `P[:]`. I thought it worth noting that you can "yield" this result, rather than printing, as follows (in this refactored code):

``````def bronk2(R, P, X, g):
if not any((P, X)):
yield R
for v in P[:]:
R_v = R + [v]
P_v = [v1 for v1 in P if v1 in N(v, g)]
X_v = [v1 for v1 in X if v1 in N(v, g)]
for r in bronk2(R_v, P_v, X_v, g):
yield r
P.remove(v)
X.append(v)
def N(v, g):
return [i for i, n_v in enumerate(g[v]) if n_v]

In [99]: list(bronk2([], range(6), [], graph))
Out[99]: [[0, 1, 4], [1, 2], [2, 3], [3, 4], [3, 5]]
``````

In case someone is looking for a Bron–Kerbosch algorithm implementation in the future...

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