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I want to vectorize the following MATLAB code. I think it must be simple but I'm finding it confusing nevertheless.

r = some constant less than m or n
[m,n] = size(C);
S = zeros(m-r,n-r);
for i=1:m-r+1
    for j=1:n-r+1
        S(i,j) = sum(diag(C(i:i+r-1,j:j+r-1)));

The code calculates a table of scores, S, for a dynamic programming algorithm, from another score table, C.
The diagonal summing is to generate scores for individual pieces of the data used to generate C, for all possible pieces (of size r).

Thanks in advance for any answers! Sorry if this one should be obvious...

The built-in conv2 turned out to be faster than convnfft, because my eye(r) is quite small ( 5 <= r <= 20 ). convnfft.m states that r should be > 20 for any benefit to manifest.

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4 Answers 4

up vote 8 down vote accepted

If I understand correctly, you're trying to calculate the diagonal sum of every subarray of C, where you have removed the last row and column of C (if you should not remove the row/col, you need to loop to m-r+1, and you need to pass the entire array C to the function in my solution below).

You can do this operation via a convolution, like so:

S = conv2(C(1:end-1,1:end-1),eye(r),'valid');

If C and r are large, you may want to have a look at CONVNFFT from the Matlab File Exchange to speed up calculations.

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Awesome, thank you. I will look at CONVNFFT tomorrow. On the subset of data I use for testing (approx. 500 times smaller than real data) the built-in conv2 function achieves a 69,652 times reduction in the number of calls and 34.56 times decrease in execution time in comparison to the loops (23.5 vs 0.68 s). –  reve_etrange May 19 '10 at 12:33

Based on the idea of JS, and as Jonas pointed out in the comments, this can be done in two lines using IM2COL with some array manipulation:

B = im2col(C, [r r], 'sliding');
S = reshape( sum(B(1:r+1:end,:)), size(C)-r+1 );

Basically B contains the elements of all sliding blocks of size r-by-r over the matrix C. Then we take the elements on the diagonal of each of these blocks B(1:r+1:end,:), compute their sum, and reshape the result to the expected size.

Comparing this to the convolution-based solution by Jonas, this does not perform any matrix multiplication, only indexing...

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If you can afford the memory, im2col is usually a great way to go. –  Jonas May 21 '10 at 22:34
im2col returns values rather than indices, so the second line should have reshape( sum(B(1:r+1:end,:)) ),size(C)-r+1);. –  reve_etrange Nov 26 '10 at 0:27
@reve_etrange: you are absolutely right, thanks for pointing it out –  Amro Nov 26 '10 at 5:20
I've also now benchmarked conv2 vs. im2col & reshape. Wrote a function taking arguments for size(C) and r, which preallocates answers and tries each method ten times. Looks like conv2 is faster, regardless of size(C), r combinations. I assume it's because the im2col matrix is quite large. –  reve_etrange Nov 27 '10 at 4:58

I would think you might need to rearrange C into a 3D matrix before summing it along one of the dimensions. I'll post with an answer shortly.


I didn't manage to find a way to vectorise it cleanly, but I did find the function accumarray, which might be of some help. I'll look at it in more detail when I am home.


Found a simpler solution by using linear indexing, but this could be memory-intensive.

At C(1,1), the indexes we want to sum are 1+[0, m+1, 2*m+2, 3*m+3, 4*m+4, ... ], or (0:r-1)+(0:m:(r-1)*m)

sum_ind = (0:r-1)+(0:m:(r-1)*m);

create S_offset, an (m-r) by (n-r) by r matrix, such that S_offset(:,:,1) = 0, S_offset(:,:,2) = m+1, S_offset(:,:,3) = 2*m+2, and so on.

S_offset = permute(repmat( sum_ind, [m-r, 1, n-r] ), [1, 3, 2]);

create S_base, a matrix of base array addresses from which the offset will be calculated.

S_base = reshape(1:m*n,[m n]);
S_base = repmat(S_base(1:m-r,1:n-r), [1, 1, r]);

Finally, use S_base+S_offset to address the values of C.

S = sum(C(S_base+S_offset), 3);

You can, of course, use bsxfun and other methods to make it more efficient; here I chose to lay it out for clarity. I have yet to benchmark this to see how it compares with the double-loop method though; I need to head home for dinner first!

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Hm, with the diagonal from a 2D index becoming the third dimension at that index? –  reve_etrange May 19 '10 at 9:36
@JS: Nice idea. im2col could probably save you a few lines of code here. –  Jonas May 20 '10 at 1:30
@Jonas: I added a solution that does that exactly! –  Amro May 21 '10 at 21:02
Looking at the online documentation, im2col would definitely save a few lines of code; pity I didn't have the required toolbox. Perhaps I should look into getting a few additional toolboxes at the end of this year. –  JS Ng May 22 '10 at 5:44

Is this what you're looking for? This function adds the diagonals and puts them into a vector similar to how the function 'sum' adds up all of the columns in a matrix and puts them into a vector.

function [diagSum] = diagSumCalc(squareMatrix, LLUR0_ULLR1)
% Input: squareMatrix: A square matrix.
%        LLUR0_ULLR1:  LowerLeft to UpperRight addition = 0     
%                      UpperLeft to LowerRight addition = 1
% Output: diagSum: A vector of the sum of the diagnols of the matrix.
% Example: 
% >> squareMatrix = [1 2 3; 
%                    4 5 6;
%                    7 8 9];
% >> diagSum = diagSumCalc(squareMatrix, 0);
% diagSum = 
%       1 6 15 14 9
% >> diagSum = diagSumCalc(squareMatrix, 1);
% diagSum = 
%       7 12 15 8 3
% Written by M. Phillips
% Oct. 16th, 2013
% MIT Open Source Copywrite
% Contact mphillips@hmc.edu fmi.

if (nargin < 2)
    disp('Error on input. Needs two inputs.');

if (LLUR0_ULLR1 ~= 0 && LLUR0_ULLR1~= 1)
    disp('Error on input. Only accepts 0 or 1 as input for second condition.');

[M, N] = size(squareMatrix);

if (M ~= N)
    disp('Error on input. Only accepts a square matrix as input.');

diagSum = zeros(1, M+N-1);

if LLUR0_ULLR1 == 1
    squareMatrix = rot90(squareMatrix, -1);

for i = 1:length(diagSum)
    if i <= M
        countUp = 1;
        countDown = i;
        while countDown ~= 0
            diagSum(i) = squareMatrix(countUp, countDown) + diagSum(i);
            countUp = countUp+1;
            countDown = countDown-1;
    if i > M
        countUp = i-M+1;
        countDown = M;
        while countUp ~= M+1
            diagSum(i) = squareMatrix(countUp, countDown) + diagSum(i);
            countUp = countUp+1;
            countDown = countDown-1;


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