# Algorithm for counting connected components of a graph in Python

I try to write a script that counts connected components of a graph and I can't get the right solution. I have a simple graph with 6 nodes (vertexes), nodes 1 and 2 are connected, and nodes 3 and 4 are connected (6 vertexes; 1-2,3-4,5,6). So the graph contains 4 connected components. I use following script to count connected components, but I get wrong result (2).

``````nodes = [[1, [2], False], [2, [1], False], [3, [4], False], [4, [3], False], [5, [], False], [6, [], False]]
# 6 nodes, every node has an id, list of connected nodes and boolean whether the node has already been visited

componentsCount = 0

def mark_nodes( list_of_nodes):
global componentsCount
componentsCount = 0
for node in list_of_nodes:
node[2] = False
mark_node_auxiliary( node)

def mark_node_auxiliary( node):
global componentsCount
if not node[2] == True:
node[2] = True
for neighbor in node[1]:
nodes[neighbor - 1][2] = True
mark_node_auxiliary( nodes[neighbor - 1])
else:
unmarkedNodes = []
for neighbor in node[1]:
if not nodes[neighbor - 1][2] == True:  # This condition is never met. WHY???
unmarkedNodes.append( neighbor)
componentsCount += 1
for unmarkedNode in unmarkedNodes:
mark_node_auxiliary( nodes[unmarkedNode - 1])

def get_connected_components_number( graph):
result = componentsCount
mark_nodes( graph)
for node in nodes:
if len( node[1]) == 0:      # For every vertex without neighbor...
result += 1               # ... increment number of connected components by 1.
return result

print get_connected_components_number( nodes)
``````

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In `get_connected_components_number(graph)`, it would appear that you mark all the nodes as visited, then count the number of nodes without connections (which is obviously 2). I honestly don't know what you're trying to do with this program. –  dln385 Oct 23 '10 at 18:09

Sometimes it's easier to write code than to read it.

Put this through some tests, I'm pretty sure it'll always work as long as every connection is bidirectional (such as in your example).

``````def recursivelyMark(nodeID, nodes):
(connections, visited) = nodes[nodeID]
if visited:
return
nodes[nodeID][1] = True
for connectedNodeID in connections:
recursivelyMark(connectedNodeID, nodes)

def main():
nodes = [[[1], False], [[0], False], [[3], False], [[2], False], [[], False], [[], False]]
componentsCount = 0
for (nodeID, (connections, visited)) in enumerate(nodes):
if visited == False:
componentsCount += 1
recursivelyMark(nodeID, nodes)
print(componentsCount)

if __name__ == '__main__':
main()
``````

Note that I removed the ID from the node information since its position in the array is its ID. Let me know if this program doesn't do what you need.

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Thank you very much, your code works fine for the given input, but still probably isn't quite right. For example, for input nodes = [[[2,3], False], [[1,3], False], [[1,2], False], [[5,6], False], [[4,6], False], [[4,5], False],[[8], False], [[7,9], False], [[8], False], [[], False], [[], False], [[], False]] it should return 6. (Graph with 6 connected components - "1-2-3-1 , 4-5-6-4 , 7-8-9 , 10 , 11 , 12) –  Tomas Novotny Oct 24 '10 at 8:54
I changed the point ID to its position in the array. So the first point is ID 0, the second point is ID 1, etc. Here's the input nodes you gave with each ID decremented by 1, which gives the correct answer of 6: [[[1,2], False], [[0,2], False], [[0,1], False], [[4,5], False], [[3,5], False], [[3,4], False],[[7], False], [[6,8], False], [[7], False], [[], False], [[], False], [[], False]] –  dln385 Oct 24 '10 at 12:36
Thank you, it works perfectly. –  Tomas Novotny Oct 24 '10 at 15:46

A disjoint-set datastructure will really help you to write clear code here (http://en.wikipedia.org/wiki/Disjoint-set_data_structure).

The basic idea is that you associate a set with each node in your graph, and for each edge you merge the sets of its two endpoints. Two sets `x` and `y` are the same if `x.find() == y.find()`

Here's the most naive implementation (which has bad worst-case complexity), but there's a couple of optimisations of the DisjointSet class on the wikipedia page above which in a handful of extra lines of code make this efficient. I omitted them for clarity.

``````nodes = [[1, [2]], [2, [1]], [3, [4]], [4, [3]], [5, []], [6, []]]

def count_components(nodes):
sets = {}
for node in nodes:
sets[node[0]] = DisjointSet()
for node in nodes:
for vtx in node[1]:
sets[node[0]].union(sets[vtx])
return len(set(x.find() for x in sets.itervalues()))

class DisjointSet(object):
def __init__(self):
self.parent = None

def find(self):
if self.parent is None: return self
return self.parent.find()

def union(self, other):
them = other.find()
us = self.find()
if them != us:
us.parent = them

print count_components(nodes)
``````
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This solution works even when the connections are not bidirectional and the nodes do not form a hierarchical tree structure. Very impressive. –  dln385 Oct 25 '10 at 21:12