# Convert graph to have outdegree 1 (except extra zero weight edges)

I am reading graphs such as http://www.dis.uniroma1.it/challenge9/data/rome/rome99.gr from http://www.dis.uniroma1.it/challenge9/download.shtml in python. For example, using this code.

#!/usr/bin/python
from igraph import *
fname = "rome99.gr"
g = Graph.Read_DIMACS(fname, directed=True )


(I need to change the line "p sp 3353 8870" " to "p max 3353 8870" to get this to work using igraph.)

I would like to convert the graph to one where all nodes have outdegree 1 (except for extra zero weight edges we are allowed to add) but still preserve all shortest paths. That is a path between two nodes in the original graph should be a shortest path in the new graph if and only if it is a shortest path in the converted graph. I will explain this a little more after an example.

One way to do this I was thinking is to replace each node v by a little linear subgraph with v.outdegree(mode=OUT) nodes. In the subgraph the nodes are connected in sequence by zero weight edges. We then connect nodes in the subgraph to the first node in other little subgraphs we have created.

I don't mind using igraph or networkx for this task but I am stuck with the syntax of how to do it.

For example, if we start with graph G:

I would like to convert it to graph H:

As the second graph has more nodes than the first we need to define what we mean by its having the same shortest paths as the first graph. I only consider paths between either nodes labelled with simple letters of with nodes labelled X1. In other words, in this example a path can't start or end in A2 or B2. We also merge all versions of a node when considering a path. So a path A1->A2->D in H is regarded as the same as A->D in G.

This is how far I have got. First I add the zero weight edges to the new graph

h = Graph(g.ecount(), directed=True)
#Connect the nodes with zero weight edges
gtoh = [0]*g.vcount()
i=0
for v in g.vs:
gtoh[v.index] = i
if (v.degree(mode=OUT) > 1):
for j in xrange(v.degree(mode=OUT)-1):
h.add_edge(i,i+1, weight = 0)
i = i+1
i  = i + 1


Then I add the main edges

#Now connect the nodes to the relevant "head" nodes.
for v in g.vs:
h_v_index = gtoh[v.index]
i = 0
for neighbour in g.neighbors(v, mode=OUT):
h.add_edge(gtoh[v.index]+i,gtoh[neighbour], weight = g.es[g.get_eid(v.index, neighbour)]["weight"])
i = i +1


Is there a nicer/better way of doing this? I feel there must be.

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B1 has out-degree 2 in the second graph. –  Gabor Csardi Dec 5 '13 at 20:50
@GaborCsardi I am not counting the extra out edges we add which have 0 weight. I added that to the question at some point, are you looking at the most current version? –  marshall Dec 5 '13 at 20:56
what is the advantage of changing the graph in this manner? not obvious why this is even necessary. –  Corley Brigman Dec 9 '13 at 16:54
@CorleyBrigman I need it in this format for a particular tool I am using. It can only cope with one non-zero weight outgoing edge per node. More generally, I would love to learn of elegant ways to do this sort of conversion just so I can get better at coding. –  marshall Dec 9 '13 at 17:31

The following code should work in igraph and Python 2.x; basically it does what you proposed: it creates a "linear subgraph" for every single node in the graph, and connects exactly one outgoing edge to each node in the linear subgraph corresponding to the old node.

#!/usr/bin/env python

from igraph import Graph
from itertools import izip

def pairs(l):
"""Given a list l, returns an iterable that yields pairs of the form
(l[i], l[i+1]) for all possible consecutive pairs of items in l"""
return izip(l, l[1:])

def convert(g):
# Get the old vertex names from g
if "name" in g.vertex_attributes():
old_names = map(str, g.vs["name"])
else:
old_names = map(str, xrange(g.vcount))

# Get the outdegree vector of the old graph
outdegs = g.outdegree()

# Create a mapping from old node IDs to the ID of the first node in
# the linear subgraph corresponding to the old node in the new graph
new_node_id = 0
old_to_new = []
new_names = []
for old_node_id in xrange(g.vcount()):
old_to_new.append(new_node_id)
new_node_id += outdegs[old_node_id]
old_name = old_names[old_node_id]
if outdegs[old_node_id] <= 1:
new_names.append(old_name)
else:
for i in xrange(1, outdegs[old_node_id]+1):
new_names.append(old_name + "." + str(i))

# Add a sentinel element to old_to_new just to make our job easier
old_to_new.append(new_node_id)

# Create the edge list of the new graph and the weights of the new
# edges
new_edgelist = []
new_weights = []

# 1) Create the linear subgraphs
for new_node_id, next_new_node_id in pairs(old_to_new):
for source, target in pairs(range(new_node_id, next_new_node_id)):
new_edgelist.append((source, target))
new_weights.append(0)

# 2) Create the new edges based on the old ones
for old_node_id in xrange(g.vcount()):
new_node_id = old_to_new[old_node_id]
for edge_id in g.incident(old_node_id, mode="out"):
neighbor = g.es[edge_id].target
new_edgelist.append((new_node_id, old_to_new[neighbor]))
new_node_id += 1
print g.es[edge_id].source, g.es[edge_id].target, g.es[edge_id]["weight"]
new_weights.append(g.es[edge_id]["weight"])

# Return the graph
vertex_attrs = {"name": new_names}
edge_attrs = {"weight": new_weights}
return Graph(new_edgelist, directed=True, vertex_attrs=vertex_attrs, \
edge_attrs=edge_attrs)

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