# explanation for networkx code python

I am new to coding python. I am hoping to modify this code to develop a bipartite two mode version. It is code from networkx used to make a geometrci random graph. I have got to grips with most of this function but I am having trouble understanding exactly what lines 94 to 99 are doing. I understand while, zip and nodes.pop() but other parts are confusing for a newbie. Can anyone help with an explanation for what this part of the code is doing more than the general # description given ?

``````G=nx.Graph()
G.name="Random Geometric Graph"
if pos is None:
# random positions
for n in G:
G.node[n]['pos']=[random.random() for i in range(0,dim)]
else:
nx.set_node_attributes(G,'pos',pos)
# connect nodes within "radius" of each other
# n^2 algorithm, could use a k-d tree implementation
nodes = G.nodes(data=True)
while nodes:             #line94
u,du = nodes.pop()
pu = du['pos']
for v,dv in nodes:
pv = dv['pos']
d = sum(((a-b)**2 for a,b in zip(pu,pv))) #line99
return G
``````
-

``````nodes = [some list]
while nodes:
a = nodes.pop()
for b in nodes:
# do something
``````

This piece of code is a quite frequently seen idiom to combine every node with every other node exactly once (so the order of `a` and `b` shouldn't matter for the operation performed in the `# do something` part).

It works because the empty list is considered a falsy value in the condition of the `while` loop, while non-empty lists are considered boolean true.

``````d = sum(((a-b)**2 for a,b in zip(pu,pv)))
``````

This line computes the square of the Euclidean distance of the two vectors `pu` and `pv`. This is best demonstrated by taking it apart:

``````>>> pu = (6,6,6)
>>> pv = (1,3,7)
>>> zip(pu, pv)
[(6, 1), (6, 3), (6, 7)]
>>> [(a-b) for a,b in zip(pu, pv)]
[5, 3, -1]
>>> [(a-b)**2 for a,b in zip(pu, pv)]
[25, 9, 1]
>>> sum((a-b)**2 for a,b in zip(pu, pv))
35
``````

In the last step, we don't use a list comprehension any more, because we don't need a list. `sum` just needs the values in some iterable form, so we use a generator expression instead.

-
minor correction: `d` is the square of the Euclidean distance. –  Avaris Apr 6 '12 at 10:46
@Avaris: Very true, it computes the term inside the root :) –  Niklas B. Apr 6 '12 at 10:47
Thank you very much this had really cleared some things out. If possible may i ask one final thing. I an not sure where exactly the u,du = nodes.pop() pu = du['pos'] comes from and whats happening. I thought i did but now i see your answer im not so sure. best wishes –  user1317221_G Apr 6 '12 at 11:23
@user: pop() removes the last element from a list and returns it (though the position is irrelevant). `pu = du['pos']` just extracts a value from the node and assigns it a simpler name. –  Niklas B. Apr 6 '12 at 11:29