# Networkx: extract the smallest connected subgraph

I am trying to extract from a big graph the sub-graph of all connected nodes containing a specific node.

Is there a solution in the Networkx library?

[EDIT]
My graph is a DiGraph

[EDIT]
Rephrased simply:
I want the part of my graph that contain my specific node N_i and and all the nodes that are connected directly or indirectly (passing by other nodes) using any incoming or outcoming edges.
Example:

``````>>> g = nx.DiGraph()
>>> g.edges()
[('A', 'B'), ('B', 'C'), ('Y', 'Z'), ('X', 'Y')]
``````

My desired result would be:

``````>>> g2 = getSubGraph(g, 'B')
>>> g2.nodes()
['A', 'B', 'C']
>>> g2.edges()
[('A', 'B'), ('B', 'C')]
``````
-
It's not clear from your question what subgraph you want. If you want a subgraph that contains node N_i with no isolated nodes then e.g. the neighbors of N_i satisfy that. If you want the largest subgraph containing N_i but with with no isolated nodes then removing all isolated nodes from the graph would work (as long as N_i isn't degree 0). That graph won't necessarily be connected. If you want all of the nodes reachable from N_i consider nx.shortest_path(G,N_i)... –  Aric Dec 18 '12 at 0:57

You can use shortest_path() to find all of the nodes reachable from a given node. In your case you need to first convert the graph to an undirected representation so both in- and out-edges are followed.

``````In [1]: import networkx as nx

In [2]: >>> g = nx.DiGraph()

In [3]: >>> g.add_path(['A','B','C',])

In [4]: >>> g.add_path(['X','Y','Z',])

In [5]: u = g.to_undirected()

In [6]: nodes = nx.shortest_path(u,'B').keys()

In [7]: nodes
Out[7]: ['A', 'C', 'B']

In [8]: s = g.subgraph(nodes)

In [9]: s.edges()
Out[9]: [('A', 'B'), ('B', 'C')]
``````

Or in one line

``````In [10]: s = g.subgraph(nx.shortest_path(g.to_undirected(),'B'))

In [11]: s.edges()
Out[11]: [('A', 'B'), ('B', 'C')]
``````
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Excellent !!! Thanks –  Alban Soupper Dec 18 '12 at 13:52

Simply loop through the subgraphs until the target node is contained within the subgraph.

For directed graphs, I assume a subgraph is a graph such that every node is accessible from every other node. This is a strongly connected subgraph and the `networkx` function for that is `strongly_connected_component_subgraphs`.

(MWE) Minimal working example:

``````import networkx as nx
import pylab as plt

G = nx.erdos_renyi_graph(30,.05)
target_node = 13

pos=nx.graphviz_layout(G,prog="neato")

for h in nx.connected_component_subgraphs(G):
if target_node in h:
nx.draw(h,pos,node_color='red')
else:
nx.draw(h,pos,node_color='white')

plt.show()
``````

For a directed subgraph (digraph) example change the corresponding lines to:

``````G = nx.erdos_renyi_graph(30,.05, directed=True)
...
for h in nx.strongly_connected_component_subgraphs(G):
``````

Note that one of the nodes is in the connected component but not in the strongly connected component!

-
This is interesting but this does not work with DiGraph :( –  Alban Soupper Dec 17 '12 at 15:44
@AlbanSoupper As noted `strongly_connected_component_subgraphs` does work with directed graphs (digraphs). –  Hooked Dec 17 '12 at 15:47
I am novice in graph, but to my point of view in a directed graph the subgraph is not strongly connected... Think about a directed path_graph... –  Alban Soupper Dec 17 '12 at 15:53
@AlbanSoupper It is not clear what you are intending when you say subgraph then... without a link to a mathematical definition it will be hard to help you. Also details like a directed or undirected graph are important when you first ask the question! –  Hooked Dec 17 '12 at 15:56
Sorry, I will rephrase my question, let me 5 min –  Alban Soupper Dec 17 '12 at 15:59

Use the example at the end of the page connected_component_subgraphs.

Just ensure to refer the last element from the list rather than the first

``````>>> G=nx.path_graph(4)
@Hooked: I got mislead with the subject `extract the smallest connected subgraph`, which in this case would as the list returned is sorted in descending order of size,. Instead if OP wants the subgraph with the specific node, your solution makes sense –  Abhijit Dec 17 '12 at 15:56