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I have an outgoing neighborhood structure of a directed graph:

a{f}=[d e];
a{d}=[c];
a{e}=[c h];
a{h}=[b];
a{c}=[a b];

where a{f}=[d e] means that nodes d and e are the outgoing neighborhood of node f.

Now, my goal is to determine whether there exist two paths, one is from f to a, the other is from f to b, whose nodes are not allowed to be intersected each other?

For this example, the answer is affirmative, because we can find the two paths:

p1: f->d->c->a
p2: f->e->h->b

But when we delete the edge h->b in the graph, the answer is NO, because even if there are two paths:

p1: f->d->c->a
p3: f->e->c->b

however, the path p3 has a node c intersected with path p1.

  f
 / \
d   e
 \ / \
  c   h
 / \ /
a   b

My question is: is there any algorithms to check the existence of the two paths?

share|improve this question
    
The Hopcroft-Karp algorithm checks for node-disjoint shortest augmenting paths to compute a maximum matching in bipartite graphs; using a similar technique to the one used in that algorithm, you might get what you want in time O(|V|^0.5 * |E|) which is the time complexity of Hopcroft-Karp. That's what I'd have a look at, apart from the suggestions in the answers that were already posted. Note one thing though, Hopcroft-Karp out of the box only finds node-disjoint paths of equal length. You'd also have to adapt it so the "source" f doesn't mess it up. – G. Bach May 27 '13 at 17:56

What you are looking for are the dominators of A and B in a flowgraph with starting point F. V dominates A if every path from F to A passes through V. So, for your particular problem, you can:

  • Compute and go through all the dominators of A, mark those vertices except F
  • Compute and go through all the dominators of B, and if any of those vertices are marked:

    -> A and B have at least one common dominator D, so no two vertex-disjoint (apart from both containing F) paths F->A and F->B can exist, because every path F->A and every path F->B passes through D.

See http://en.wikipedia.org/wiki/Dominator_(graph_theory)#Algorithms

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You could solve this with a max-flow algorithm by:

  1. Construct a directed graph by splitting each of your vertices into an entry vertex and exit vertex
  2. Add an edge from entry(i) to exit(i) with capacity 1 for each pair based on vertex i
  3. Add an edge from exit(i) to entry(j) with capacity 1 for each edge i->j in your original graph
  4. Add an extra terminal vertex e
  5. Add an edge from the exit vertex for every destination (in your case exit(a) and exit(b)) to vertex e with capacity 1
  6. Compute the maximum flow from exit(f) to e

If and only if the max flow is 2, then there are two vertex-disjoint paths from f to a/b.

Example Python code

import networkx as nx
G=nx.DiGraph()
a={'f':'de','d':'c','e':'ch','h':'b','c':'ab','a':'','b':''}
for v in a:
    i='entry_'+v
    j='exit_'+v
    G.add_edge(i,j,capacity=1)
    for dest in a[v]:
        G.add_edge(j,'entry_'+dest,capacity=1)
for dest in 'ab':
    G.add_edge('exit_'+dest,'e',capacity=1)
print nx.max_flow(G,'exit_f','e')

G.remove_edge('exit_h','entry_b')
print nx.max_flow(G,'exit_f','e')

This prints

2 (meaning that in the original graph there are 2 vertex disjoint paths)
1 (meaning that once we remove h->b, there is only 1 vertex disjoint path)
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