What you are looking for is a **cut**. Given a graph, a cut is a set of edges that partitions the vertices into two disjoint subsets.

Assuming you are trying to get the smallest cut possible, this is the classic **min-cut** problem. Here is a pseudo code version of the Ford-fulkerson algorithm, reworked for your case (undirected, unweighted graphs). I'm pretty sure it should work, but I am not sure I'm being the most efficient / idiomatic here.

```
reorganize your graph into a directed graph,
with two directed edges (u->v, v->u) for each original edge (u-v)
while there is a path P from A to H:
(hint: use breadth first search to find paths - long story here)
//augment the path P:
for each edge (u->v) in P:
remove (u->v) from the graph and add (v->u) to it
(if v->u isn't there already)
Label all vertices as reacheable or not reacheable from A.
The bottleneck edges is the set of edges
that connect a reacheable and a unreacheable vertex
```

For example, in your case BFS would give us the path A-B-E-H. After removing these edges, we would still be able to find the path A-D-G-H. After these edges are removed, the graph is partitioned into the reacheable vertices {A,B,C,D} and the unreacheable {E,F,G,H}. The edges that have a vertex from each (B-E and D-G) set are the bottleneck edges.

orDG must always be traversed? – sawa Apr 28 '11 at 12:19