Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am computing a similarity matrix based on Euclidean distance in MATLAB. My code is as follows:

for i=1:N % M,N is the size of the matrix x for whose elements I am computing similarity matrix
 for j=1:N
  D(i,j) = sqrt(sum(x(:,i)-x(:,j)).^2)); % D is the similarity matrix
 end
end

Can any help with optimizing this = reducing the for loops as my matrix x is of dimension 256x30000.

Thanks a lot!

--Aditya

share|improve this question
1  
If you have Statistics toolbox the function pdist does exactly this in an optimised way. help pdist; help squareform –  robince Apr 24 '11 at 8:40
2  
Its true that pdist is a Matlab function but its FAR from being optimized. –  twerdster Apr 24 '11 at 10:42

4 Answers 4

up vote 5 down vote accepted

The function to do so in matlab is called pdist. Unfortunately it is painfully slow and doesnt take Matlabs vectorization abilities into account.

The following is code I wrote for a project. Let me know what kind of speed up you get.

   Qx=repmat(dot(x,x,2),1,size(x,1));
   D=sqrt(Qx+Qx'-2*x*x');

Note though that this will only work if your data points are in the rows and your dimensions the columns. So for example lets say I have 256 data points and 100000 dimensions then on my mac using x=rand(256,100000) and the above code produces a 256x256 matrix in about half a second.

share|improve this answer
1  
+1, that's a sweet solution! Although mine is vectorized, just storing the indices and accessing them bogs it down at large N. Yours works great even when # of dimensions is 256 and # of points is 20000. It gave me a 2e4x2e4 matrix in about 10 seconds, whereas mine ran out of memory. –  r.m. Apr 24 '11 at 15:22
    
I initially had the same problem which is why I had to figure out the correct way to do it. That simple bit of code took ages to arrive at. But it saved days of computing time:) –  twerdster Apr 24 '11 at 17:30
    
you're right. Unless you really need it, that's not a solution you'd think of right away. Since my needs until now were for 1000x3 or similar sizes, my solution seemed blazing fast when compared to loops. Not once did I think of its performance for large N. Kudos to you :) –  r.m. Apr 24 '11 at 17:36

There's probably a better way to do it, but the first thing I noticed was that you could cut the runtime in half by exploiting the symmetry D(i,j)==D(i,j)

You can also use the function norm(x(:,i)-x(:,j),2)

share|improve this answer
    
Norm is the right way to do it per entry. However its quite easy to vectorize it. –  twerdster Apr 24 '11 at 10:40

I think this is what you're looking for.

D=zeros(N);    
jIndx=repmat(1:N,N,1);iIndx=jIndx'; %'# fix SO's syntax highlighting
D(:)=sqrt(sum((x(iIndx(:),:)-x(jIndx(:),:)).^2,2));

Here, I have assumed that the distance vector, x is initalized as an NxM array, where M is the number of dimensions of the system and N is the number of points. So if your ordering is different, you'll have to make changes accordingly.

share|improve this answer
3  
Props to you for doing it without explicit looping, but this code doesn't scale to the size of the problem at hand, and at least on my machine with MATLAB 2009b, is still single-threaded. With M=256, memory usage passes 4GB when N grows a bit beyond 1000 (and that's after I switched to 32-bit data types). The question wants N=30000. At that size, the intermediate matrices like x(iIndx(:),:) will take up a total of about 2TB. Unless more recent versions of MATLAB are very good at lazy evaluation, this can't work. –  user57368 Apr 24 '11 at 3:27
1  
ah good catch, I hadn't seen the size of the array! In fact, just the D matrix, no matter what method you use to arrive at it, is ~6GB! –  r.m. Apr 24 '11 at 4:08
2  
You dont need to store the values. Each matrix entry is just |x|^2-2*x'*y+|y|^2. This can be evaluated quite fast using Matlab vectorization –  twerdster Apr 24 '11 at 10:39

To start with, you are computing twice as much as you need to here, because D will be symmetric. You don't need to calculate the (i,j) entry and the (j,i) entry separately. Change your inner loop to for j=1:i, and add in the body of that loop D(j,i)=D(i,j);

After that, there's really not much redundancy left in what that code does, so your only room left for improvement is to parallelize it: if you have the Parallel Computing Toolbox, convert your outer loop to a parfor and before you run it, say matlabpool(n), where n is the number of threads to use.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.