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Suppose one below tree-like structure in networkx graph:

 |     |----n12
 |     |----n13
 |           |----n131 
 |----n2             | 
 |     |-----n21     X
 |     |-----n22     |
 |            |----n221 

  1. How to list all nodes with "subnode" and its depth, here: n,n1,n13,n2,n22,n4
  2. How to list all nodes without "subnode", here: n11,n12,n21,n41,n5
  3. How to list orphan node, here: n5 and how to list "orphan" edge, not belongs to root n edge, here n4-n41,
  4. How to list node with more than 2 "subnode", here n,n1
  5. How to deal with if n131,n221 have an edge exists in nodes traversal, will infinity loop happen?


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You should take a look at the networkX documentation of Graphs: networkx.lanl.gov/reference/classes.graph.html#networkx.Graph Most of your tasks can be solved with functionality from there and a bit of iteration. –  Michael Mauderer Aug 18 '12 at 16:18
@Michael Mauderer, is that so simple for nodes without attribute? –  user478514 Aug 18 '12 at 17:18
Attributes shouldn't make any difference for what you are doing. –  Michael Mauderer Aug 18 '12 at 17:49
You should give an example construction of the graph so we can help with each of these –  jterrace Aug 20 '12 at 16:56

1 Answer 1

up vote 8 down vote accepted

Graph construction:

>>> import networkx as nx
>>> G = nx.DiGraph()
>>> G.add_edges_from([('n', 'n1'), ('n', 'n2'), ('n', 'n3')])
>>> G.add_edges_from([('n4', 'n41'), ('n1', 'n11'), ('n1', 'n12'), ('n1', 'n13')])
>>> G.add_edges_from([('n2', 'n21'), ('n2', 'n22')])
>>> G.add_edges_from([('n13', 'n131'), ('n22', 'n221')])
>>> G.add_edges_from([('n131', 'n221'), ('n221', 'n131')]
>>> G.add_node('n5')
  1. Using the out_degree function to find all the nodes with children:

    >>> [k for k,v in G.out_degree().iteritems() if v > 0]
    ['n13', 'n', 'n131', 'n1', 'n22', 'n2', 'n221', 'n4']

    Note that n131 and n221 also show up here since they both have an edge to each other. You could filter these out if you want.

  2. All nodes without children:

    >>> [k for k,v in G.out_degree().iteritems() if v == 0]
    ['n12', 'n11', 'n3', 'n41', 'n21', 'n5']
  3. All orphan nodes, i.e. nodes with degree 0:

    >>> [k for k,v in G.degree().iteritems() if v == 0]

    To get all orphan "edges", you can get the list of components of the graph, filter out the ones that don't contain n and then keep only the ones that have edges:

    >>> [G.edges(component) for component in nx.connected_components(G.to_undirected()) if len(G.edges(component)) > 0 and 'n' not in component]
    [[('n4', 'n41')]]
  4. Nodes with more than 2 children:

    >>> [k for k,v in G.out_degree().iteritems() if v > 2]
    ['n', 'n1']
  5. If you traverse the tree, you will not get an infinite loop. NetworkX has traversal algorithms that are robust to this.

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thanks for this clear demonstration, but for 1 can you show a bit more to find out that n131 and n221 is the deepest node along their own path to n, if we take "n" as root? i cannot fig out a way that shortest_path(n, X) may working in that case, should neighbor() also involved? –  user478514 Aug 21 '12 at 2:51
Sorry, I don't understand what you're asking. –  jterrace Aug 21 '12 at 2:55
n221 should not be the children of n131 if n is root, vise visa. so how to detect this kind of nodes and define them as "no-children"? –  user478514 Aug 21 '12 at 3:21
If you have edges between siblings, it's not a tree. –  jterrace Aug 21 '12 at 3:22
Yes, techinally it is not a "tree" any more, i don't know how to name it, but this edge can do exists, the question is how to detect them in this "tree-like" structure? –  user478514 Aug 21 '12 at 4:10

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