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')
```

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.

All nodes without children:

```
>>> [k for k,v in G.out_degree().iteritems() if v == 0]
['n12', 'n11', 'n3', 'n41', 'n21', 'n5']
```

All orphan nodes, i.e. nodes with degree 0:

```
>>> [k for k,v in G.degree().iteritems() if v == 0]
['n5']
```

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')]]
```

Nodes with more than 2 children:

```
>>> [k for k,v in G.out_degree().iteritems() if v > 2]
['n', 'n1']
```

If you traverse the tree, you will not get an infinite loop. NetworkX has traversal algorithms that are robust to this.