Parallelize or vectorize all-against-all operation on a large number of matrices?

I have approximately 5,000 matrices with the same number of rows and varying numbers of columns (20 x ~200). Each of these matrices must be compared against every other in a dynamic programming algorithm.

In this question, I asked how to perform the comparison quickly and was given an excellent answer involving a 2D convolution. Serially, iteratively applying that method, like so

``````list = who('data_matrix_prefix*')
H = cell(numel(list),numel(list));
for i=1:numel(list)
for j=1:numel(list)
if i ~= j
eval([ 'H{i,j} = compare(' char(list(i)) ',' char(list(j)) ');']);
end
end
end
``````

is fast for small subsets of the data (e.g. for 9 matrices, 9*9 - 9 = 72 calls are made in ~1 s, 870 calls in ~2.5 s).
However, operating on all the data requires almost 25 million calls.
I have also tried using deal() to make a cell array composed entirely of the next element in data, so I could use cellfun() in a single loop:

``````# who(), load() and struct2cell() calls place k data matrices in a 1D cell array called data.
nextData = cell(k,1);
for i=1:k
[nextData{:}] = deal(data{i});
H{:,i} = cellfun(@compare,data,nextData,'UniformOutput',false);
end
``````

Unfortunately, this is not really any faster, because all the time is in compare(). Both of these code examples seem ill-suited for parallelization. I'm having trouble figuring out how to make my variables sliced.
compare() is totally vectorized; it uses matrix multiplication and conv2() exclusively (I am under the impression that all of these operations, including the cellfun(), should be multithreaded in MATLAB?).

Does anyone see a (explicitly) parallelized solution or better vectorization of the problem?

Note
I realize both my examples are inefficient - the first would be twice as fast if it calculated a triangular cell array, and the second is still calculating the self comparisons, as well. But the time savings for a good parallelization are more like a factor of 16 (or 72 if I install MATLAB on everyone's machines).

Aside
There is also a memory issue. I used a couple of evals to append each column of H into a file, with names like H1, H2, etc. and then clear Hi. Unfortunately, the saves are very slow...

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What does `compare` do? What is an example row of the list? –  Jonas May 20 '10 at 11:04
For data matrices A and B it calculates A' * B and convolves the product with an identity matrix. The matrices are normalized; rows and columns contain values from 0 to 1 that sum to 1. The matrix resulting from compare contains values from -30 to 30 which roughly follow an extreme value distribution. –  reve_etrange May 20 '10 at 11:11
What's the reason to use `eval`, then? –  Jonas May 20 '10 at 11:17
Sorry, I think I misunderstood. The variable I called list above has the names of the matrices as its rows. –  reve_etrange May 20 '10 at 11:36

The second example can be easily sliced for use with the Parallel Processing Toolbox. This toolbox distributes iterations of your code among up to 8 different local processors. If you want to run the code on a cluster, you also need the Distributed Computing Toolbox.

``````%# who(), load() and struct2cell() calls place k data matrices in a 1D cell array called data.

parfor i=1:k-1 %# this will run the loop in parallel with the parallel processing toolbox
%# only make the necessary comparisons
H{i+1:k,i} = cellfun(@compare,data(i+1:k),repmat(data(i),k-i,1),'UniformOutput',false);

%# if the above doesn't work, try this
hSlice = cell(k,1);
hSlice{i+1:k} = cellfun(@compare,data(i+1:k),repmat(data(i),k-i,1),'UniformOutput',false);
H{:,i} = hSlice;
end
``````
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"PARFOR loop cannot run due to the way nextData is used." Also it doesn't want to slice data (which is a 1D cell array). –  reve_etrange May 20 '10 at 11:31
It won't slice `data`, because you use the entire array `data` in your call to cellfun. Also, I fixed the problem with `nextData` –  Jonas May 20 '10 at 12:33
Thank you...now M-Lint is happy. But can repmat return a cell array repeating element of data? It is concatenating them all together and creating a large matrix. –  reve_etrange May 20 '10 at 20:25
@reve_etrange. D'oh! You need to do repmat with data(i) instead data{i}. Fixed –  Jonas May 20 '10 at 21:10
@reve_etrange: I've also updated the solution so that you only make the necessary comparisons –  Jonas May 20 '10 at 21:16

Does

``````compare(a,b) == compare(b,a)
``````

and

``````compare(a,a) == 1
``````

``````for i=1:numel(list)
for j=1:numel(list)
...
end
end
``````

to

``````for i=1:numel(list)
for j= i+1 : numel(list)
...
end
end
``````

and deal with the symmetry and identity case. This will cut your calculation time by half.

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I should have seen that. +1 –  Jonas May 20 '10 at 13:47
The symmetry cases are transposes and the identity case is not 1, but is not useful. Thanks, I think it will help my memory troubles as well. –  reve_etrange May 20 '10 at 20:31

If I understand correctly you have to perform 5000^2 matrix comparisons ? Rather than try to parallelise the compare function, perhaps you should think of your problem being composed of 5000^2 tasks ? The Matlab Parallel Compute Toolbox supports task-based parallelism. Unfortunately my experience with PCT is with parallelisation of large linear algebra type problems so I can't really tell you much more than that. The documentation will undoubtedly help you more.

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