# Cost-effective creation of a symmetric matrix in MATLAB

I'm fairly new to MATLAB and have a piece of code which creates a distance matrix. To be more precise, it creates a distance matrix D between points that lie on an undirected graph, such that Dij is the shortest path between the points on that graph. This matrix is obviously symmetric (because the graph is undirected) and the following is the code snippet that I use to create it:

``````D = zeros(size(data,1));
for i = 1:size(data, 1)
for j = 1:size(data, 1)
[D(i, j), ~, ~] = graphshortestpath(G, i, j, 'Directed', false);
end
end
``````

This is obviously very wasteful, since I'm not exploiting the symmetry of the matrix. Is there any way in which I can compute only the upper triangular part of the matrix and then somehow "append" the lower triangular part to it, such that I reduce my computations from n^2 to n^2 / 2?

Any help appreciated,

Jason

-

Sure. Just think about the order of iteration, to figure out which triangle is reached first.

``````D = zeros(size(data,1));
for i = 1:size(data, 1)
for j = 1:size(data, 1)
if j > i
[D(i, j), ~, ~] = graphshortestpath(G, i, j, 'Directed', false);
else
D(i, j) = D(j, i);
end
end
end
``````

If diagonal elements aren't identically zero, you can use `if j >= i` instead.

-
I'll go for this one, because I find it to be the simplest way and the only overhead is a reference copy. Thanks. – Jason Apr 16 '13 at 23:43

For undirected and unweighted graph, an alternative way of computing Distance matrix

May help if u are trying to reduce your runtime. In the case of Matlab, most of the time, I find scanning entry by entry is slower. I am just guessing your purpose of asking the question, sorry if I am out of topic.

Given a Adjacency Matix ( G ), I would compute the distance matrix in following way,

Assumptions: 1. G is undirected & unweighted ( matrix filled with '0' and '1' ) 2. N is the order of the graph with G is of size N x N

``````function [D,connect]=genDistance(G,N)

D = G;
B = G;
connect = 0;
i=1;
while((~connect)&&(i<N-1))    % the maximum distance from one vert to another
i = i + 1;                % is N-1
B = B * G;                % G to the power of i
D = D + i * (D==0&B>0);   % D==0 & B>0 the entries to be updated
connect = ( min(min(D)) )>0;  %check if D has zero entry
end
D ( eye(N) ) = 0 ; %clear diagonal entries
``````
• (i,j) entry in "G power k" will give you the number of walks of length k from Vi to Vj in G
• in the end, connect will tell you whether the graph is connected
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@yuk: Can I have a look at your test case? This method will only work on undirected and unweighted graph. This two assumptions will guarantee that G is symmetric and filled up with only '0' and '1'. This is kind of a special case. – chunyun Apr 17 '13 at 3:18
Take my comment back. The result of your code is symmetrical for symmetrical matrix. It's just not in the same style as from `graphshortestpath` with 1s and `Inf`s for edges without connection. This is really the fastest method. +1 – yuk Apr 17 '13 at 15:52

You can generate indices for the lower part of the matrix `G` with

``````N = length(G);
[irow, icol] = find(tril(ones(N),-1));
``````

Then you can loop through those indices:

``````D = zeros(size(G));
for i = 1:numel(irow)
[D(irow(i), icol(i)] = graphshortestpath(G, irow(i), icol(i), 'Directed', false);
end
D = D + D';
``````

Another option is to use ARRAYFUN with those indices and SQUAREFORM to convert the resulted vector into a square matrix:

``````D = arrayfun(@(x,y) graphshortestpath(G,x,y, 'Directed', false), irow, icol);
D = squareform(D);
``````
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That doesn't look like valid syntax. – Ben Voigt Apr 16 '13 at 4:10
Yes, corrected. – yuk Apr 16 '13 at 4:13
@yuk Are you computing the diagonal elements? – jucestain Apr 16 '13 at 4:14
@jucestain: When dealing with distance, diagonal elements should all be zero. – Ben Voigt Apr 16 '13 at 4:14
@yuk: I think you're computing the Cartesian product of the rows and columns returned by `find`. You want to instead iterate a pairwise list. – Ben Voigt Apr 16 '13 at 4:15