i have a distance matrix that is 1000x1000 in dimension and symmetric with 0s along the diagonal. i want to form groupings of distances (clusters) by simultaneously reordering the rows and columns of the matrix. this is like reordering a matrix before you visualize its clusters with a heatmap. i feel like this should be an easy problem, but i am not having much luck finding code that does the permutations online. can anyone help?

What does "online" mean here? In reference to clustering it usually means data are processed as they come in, rather than stored in memory all at once. But you have a 1000x1000 matrix, so that does not seem to be the case. If "online" means in a browser by means of javascript, then the problem is simply that of computing all pairwise row, resp. column similarities, followed by clustering. David's answer works; another algorithm, simple to implement (but benefiting from a more trickier and sparse implementation), is the Markov Cluster algorithm, which is used a lot in bioinformatics.– micansSep 23, 2011 at 9:56

1@micans, he meant he can't find it online = on the web.– cyborgOct 9, 2011 at 21:40

@cyborg you're very likely right, that makes my comment moderately hilarious. user439463 seems to have left the conversation, unfortunately.– micansOct 10, 2011 at 10:52
2 Answers
Here is one approach that came to mind:
 "Sparsify" the matrix so that only "sufficiently close" neighbors have a nonzero value in the matrix.
 Use a CuthillMcKee algorithm to compress the bandwidth of the sparse matrix.
 Do a symmetric reordering of the original matrix using the results from Step 2.
Example
I will use Octave (everything I am doing should also work in Matlab) since it has a Reverse CuthillMcKee (RCM) implementation built in.
First, we need to generate a distance matrix. This function creates a random set of points and their distance matrix:
function [x, y, A] = make_rand_dist_matrix(n)
x = rand(n, 1);
y = rand(n, 1);
A = sqrt((repmat(x, 1, n)  repmat(x', n, 1)).^2 +
(repmat(y, 1, n)  repmat(y', n, 1)).^2);
end
Let's use that to generate and visualize a 100point example.
[x, y, A] = make_rand_dist_matrix(100);
surf(A);
Viewing the surface plot from above gets the image below (yours will be different, of course).
Warm colors represent greater distances than cool colors. Row (or column, if you prefer) i
in the matrix contains the distances between point i
and all points. The distance between point i
and point j
is in entry A(i, j)
. Our goal is to reorder the matrix so that the row corresponding to point i
is near rows corresponding to points a short distance from i
.
A simple way to sparsify A
is to make all entries greater than some threshold zero, and that is what is done below, although more sophisticated approaches may prove more effective.
B = A < 0.2; % sparsify A  only values less than 0.2 are nonzeros in B
p = symrcm(B); % compute reordering by Reverse CuthillMcKee
surf(A(p, p)); % visualize reordered distance matrix
The matrix is now ordered in a way that brings nearby points closer together in the matrix. This result is not optimal, of course. Sparse matrix bandwidth compression is computed using heuristics, and RCM is a very simple approach. As I mentioned above, more sophisticated approaches for producing the sparse matrix may give better results, and different algorithms may also yield better results for the problem.
Just for Fun
Another way to look at what happened is to plot the points and connect a pair of points if their corresponding rows in the matrix are adjacent. Your goal is to have the lines connecting pairs of points that are near each other. For a more dramatic effect, we use a larger set of points than above.
[x, y, A] = make_rand_dist_matrix(2000);
plot(x, y); % plot the points in their initial, random order
Clearly, connections are all over the place and are occurring over a wide variety of distances.
B = A < 0.2; % sparsify A
p = symrcm(B);
plot(x(p), y(p)) % plot the reordered points
After reordering, the connections tend to be over much smaller distances and much more orderly.

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