# delete random edges of a node till degree = 1 networkx

If I create a bipartite graph G using random geomtric graph where nodes are connected within a radius. I then want to make sure all nodes have a particular degree (i.e. only one or two edges). My main aim is to take one of the node sets (i.e node type a) and for each node make sure it has a maximum degree set by me. So for instance if a take node i that has a degree of 4, delete random edges of node i until its degree is 1.

I wrote the following code to run in the graph generator after generating edges. It deletes edges but not until all nodes have the degree of 1.

``````for n in G:
mu = du['G.degree(n)']
while mu > 1:
G.remove_edge(u,v)
if mu <=1:
break
return G
``````

full function below:

``````import networkx as nx
import random

def my_bipartite_geom_graph(a, b, radius, dim):

G=nx.Graph()
for n in range(a):
G.node[n]['pos']=[random.random() for i in range(0,dim)]
G.node[n]['type'] = 'A'

for n in range(a, a+b):
G.node[n]['pos']=[random.random() for i in range(0,dim)]
G.node[n]['type'] = 'B'

nodesa = [(node, data) for node, data in G.nodes(data=True) if data['type'] == 'A']
nodesb = [(node, data) for node, data in G.nodes(data=True) if data['type'] == 'B']

while nodesa:
u,du = nodesa.pop()
pu = du['pos']
for v,dv in nodesb:
pv = dv['pos']
d = sum(((a-b)**2 for a,b in zip(pu,pv)))
if d <= radius**2:

for n in nodesa:
mu = du['G.degree(n)']
while mu > 1:
G.remove_edge(u,v)
if mu <=1:
break
return G
``````

Reply to words like jared. I tried using you code plus a couple changes I had to make:

``````def hamiltPath(graph):

maxDegree = 2
remaining = graph.nodes()
newGraph = nx.Graph()
while len(remaining) > 0:
node = remaining.pop()
neighbors = [n for n in graph.neighbors(node) if n in remaining]
if len(neighbors) > 0:
neighbor = neighbors[0]
if len(newGraph.neighbors(neighbor)) >= maxDegree:
remaining.remove(neighbor)

return newGraph
``````

This ends up removing nodes from the final graph which I had hoped it would not.

-
I am not sure, how you intend to achieve it. Consider a star graph. How would you reduce the degree of each node to 1? –  Abhijit Apr 7 '12 at 16:59
thanks for your comment Abhijit, I am actually working with a bipartite graph. I left this info out to simplify things but I now realise it actually complicates them. So the main aim is to return one of the node sets to all have a degree of one. So technically in my code replace "for n in G" with "for in nodesetA" –  user1317221_G Apr 7 '12 at 17:10
Please provide the full function if it is not too big. If it is too big, try to isolate your problem into a smaller one. Then try to explain what is the expect output, and what you are getting. –  Simon Apr 7 '12 at 17:34
I know they claim it experimental but still have you tried with bipartite_random_regular_graph –  Abhijit Apr 7 '12 at 17:37
I would like u,v to be a random edge of node n. mu shuld be the degree of the node and so will be an the range of 1-number of nodes yes. –  user1317221_G Apr 7 '12 at 17:42

Suppose we have a Bipartite graph. If you want each node to have degree 0, 1 or 2, one way to do this would be the following. If you want to do a matching, either look up the algorithm (I don't remember it), or change maxDegree to 1 and I think it should work as a matching instead. Regardless, let me know if this doesn't do what you want.

``````def hamiltPath(graph):
"""This partitions a bipartite graph into a set of components with each
component consisting of a hamiltonian path."""
# The maximum degree
maxDegree = 2

# Get all the nodes.  We will process each of these.
remaining = graph.vertices()
# Create a new empty graph to which we will add pairs of nodes.
newGraph = Graph()
# Loop while there's a remaining vertex.
while len(remaining) > 0:
# Get the next arbitrary vertex.
node = remaining.pop()
# Now get its neighbors that are in the remaining set.
neighbors = [n for n in graph.neighbors(node) if n in remaining]
# If this list of neighbors is non empty, then add (node, neighbors[0])
# to the new graph.
if len(neighbors) > 0:
# If this is not an optimal algorithm, I suspect the selection
# a vertex in this indexing step is the crux.  Improve this
# selection and the algorthim might be optimized, if it isn't
# already (optimized in result not time or space complexity).
neighbor = neighbors[0]
# "node" has already been removed from the remaining vertices.
# We need to remove "neighbor" if its degree is too high.
if len(newGraph.neighbors(neighbor)) >= maxDegree:
remaining.remove(neighbor)

return newGraph

class Graph:
"""A graph that is represented by pairs of vertices.  This was created
For conciseness, not efficiency"""

def __init__(self):
self.graph = set()

def addEdge(self, a, b):
"""Adds the vertex (a, b) to the graph"""
self.graph = self.graph.union({(a, b)})

def neighbors(self, node):
"""Returns all of the neighbors of a as a set. This is safe to
modify."""
return (set(a[0] for a in self.graph if a[1] == node).
union(
set(a[1] for a in self.graph if a[0] == node)
))

def vertices(self):
"""Returns a set of all of the vertices. This is safe to modify."""
return (set(a[1] for a in self.graph).
union(
set(a[0] for a in self.graph)
))

def __repr__(self):
result = "\n"
for (a, b) in self.graph:
result += str(a) + "," + str(b) + "\n"
# Remove the leading and trailing white space.
result = result[1:-1]
return result

graph = Graph()

print(graph)
print()
print(hamiltPath(graph))
# Result of this is:
# 10,3
# 1,8
# 2,8
# 11,3
# 0,4
``````
-
Thank you for your answer jared, I have been looking at your code but I am unsureits doing what I hope. Sorry I will continue to work on this. –  user1317221_G Apr 8 '12 at 14:18
Could you give some example input and output graphs, then? –  Words Like Jared Apr 8 '12 at 17:24
def addEdge(self, a, b): """Adds the vertex (a, b) to the graph""" self.graph = self.graph.union({(a, b)}) syntax eror –  user1317221_G Apr 8 '12 at 18:38
What version of Python are you using? –  Words Like Jared Apr 8 '12 at 19:00
2.6 for now, usually 2.7 –  user1317221_G Apr 8 '12 at 19:06

I don't know if it is your problem but my wtf detector is going crazy when I read those two final blocks:

``````while nodesa:
u,du = nodesa.pop()
pu = du['pos']
for v,dv in nodesb:
pv = dv['pos']
d = sum(((a-b)**2 for a,b in zip(pu,pv)))
if d <= radius**2:

for n in nodesa:
mu = du['G.degree(n)']
while mu > 1:
G.remove_edge(u,v)
if mu <=1:
break
``````
• you never go inside the for loop, since nodesa needs to be empty to reach it
• even if nodesa is not empty, if mu is an `int`, you have an infinite loop in in your last nested `while` since you never modify it.
• even if you manage to break from this `while` statement, then you have `mu > 1 == False`. So you immediatly break out of your `for` loop

Are you sure you are doing what you want here? can you add some comments to explain what is going on in this part?

-
Hi Simon, Thanks for your comment. After posting this have realised just how flawed this code is, much more than I thought. Basically what my beginners brain was trying to do was go through all the nodesa after network formation. and for every nodea i wanted to delete a random edge from the node until all nodesa only have one edge each. –  user1317221_G Apr 8 '12 at 10:40
@user1317221 I think you need to work on your code. Your question is currently unanswerable. You should work on your own, and come back you you have a precise problem –  Simon Apr 8 '12 at 11:29