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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:

enter image description here

I would like to convert it to graph H:

enter image description here

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.

share|improve this question
    
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

1 Answer 1

up vote 2 down vote accepted
+100

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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