I've got a set of strings, and need to build a graph where strings are the nodes, and there's an edge between any pair of adjacent strings.

To strings `A` and `B` are said to be adjacent if by adding, removing, or replacing a single character of `A` (at whatever position) you get `B`.

For example `scar` and `car` are adjacent (removing the `s` from `scar`), so are `car` and `far` (replacing `c` with `f`) and so are `far` and `farm` (adding `m`).

Is it possible to do this in less than `O(n^2)`?

-

You have to compute `n(n - 1)/2 = O(n^2)` entries in the adjacency matrix (the entries are 1 if the Levenshtein distance is 1, and 0 otherwise). There is no way to avoid this.

(Note that given `n`, I can find an alphabet and a collection of words on that alphabet such that all `n` words are neighbors and the graph would be complete.)

-
As the Edit Distance is a distance, the triangular inequality holds. I think that in the general case you can partition the space recursively holding subsets with distance <= 2 to the last point examined as candidates, and discard to calculate the other elements of the AM. In the worst case, all elements will stay in the same subset forever. –  belisarius Nov 16 '10 at 16:49
That's the point of my complete graph example. It is the worst case. –  Jason Nov 17 '10 at 1:28
The graph doesn't have to be stored as an adjacency matrix. –  Nabb Nov 17 '10 at 9:05
@Nabb: What's your point? There are `n choose 2` possible edges. It has to be determined for each possible edge whether or not it is in the graph. In the worst case every edge must be explicitly checked. –  Jason Nov 17 '10 at 14:07

I think it is not possible.

In the worst case, all words are neighbors. Example 6 words={cat, fat, rat, mat, sat, at}.

In this example you need to establish (n) * (n-1)/2 = 6 * 5/2 = 15 edges.

So you need O(n^2) operations just to set up the edges in the worst case ... no matter how many comparisons or loops you need, you can't better that.

-