Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

Short Version

How can I do concatMap in matlab? I'm trying to build a single vector from a series of smaller, differently sized vectors. I know I can do

result = [];
for i=1:N
    result = [result nextPart(i)];

but that has a serious speed impact and there must be a smarter way to do concatMap.

Long Version

I'm trying to write a matlab function that returns the counterdiagonals of a block. For example, if you have the block:

1 2 4
3 5 6
6 7 8

then counterDiagonals(block) should return [1 2 3 4 5 6 7 8]

I have a function that will find a single counter diagonal of a block. i.e. counterDiagonal(x, 3) will return [4 5 6].

Therefore, counterDiagonals should be as simple as concatMap counterDiagonal(x, i) (1:N) where N is (2*length(block)-1). How can I do this in matlab in an efficient way?


share|improve this question
possible duplicate of transforming a matrix into a vector along its diagonals –  gnovice Nov 29 '10 at 15:32
@gnovice: as was recently discussed by Jeff Atwood, having multiple variations of the same question isn't so bad after all :) blog.stackoverflow.com/2010/11/… –  Amro Nov 29 '10 at 17:04
@Amro: True. I saw that post, and I agree some amount of duplication is unavoidable and maybe even beneficial. But the way I interpreted it was that Jeff still encouraged closing and potentially merging some, but not deleting them. –  gnovice Nov 29 '10 at 17:51

3 Answers 3

up vote 3 down vote accepted

I believe what you want to do can be accomplished using the functions ROT90 and SPDIAGS:

A = [1 2 4; 3 5 7; 6 8 9];  %# Sample matrix
result = rot90(A);          %# Rotate the matrix counter-clockwise
result = spdiags(result);   %# Find all the diagonals
result = result(result ~= 0).';  %'# Remove zero padding and format the results
                                  %#   into a row vector

And you should end up with result = [1 2 3 4 5 6 7 8 9].

EDIT: As Amro mentions in a comment, the above code assumes that there are no zeroes in the original matrix A. If there are zeroes in the original matrix, one solution is to replace them with a non-zero flag value that you know doesn't appear in the original matrix (like, for example, NaN), run the above code, then replace the flag values in the result:

A = [0 2 4; 3 0 7; 6 8 0];  %# Sample matrix
result = rot90(A);          %# Rotate the matrix counter-clockwise
result(result == 0) = nan;  %# Replace zeroes with NaN
result = spdiags(result);   %# Find all the diagonals
result = result(result ~= 0).';  %'# Remove zero padding and format the results
                                  %#   into a row vector
result(isnan(result)) = 0;  %# Put the original zeroes back
share|improve this answer
+1 for using rot90 - I'd have used fliplr and have suffered. –  Jonas Nov 29 '10 at 3:42
you will get incorrect results if the original matrix contained zeros. See my post below. –  Amro Nov 29 '10 at 15:29
@Amro: That's correct, but I was just going on the sample matrix provided. –  gnovice Nov 29 '10 at 15:30
using NaN's is probably easier than my solution +1 –  Amro Nov 29 '10 at 17:06

One problem with the accepted answer: if the matrix A had zeros, they will be incorrectly removed from the result.. Instead you should work on the indices of the elements:

A = [0 2 4; 3 5 7; 6 8 9];               %# Sample matrix (contains zeros)

ind = reshape(1:numel(A), size(A));      %# indices of elements
ind = fliplr( spdiags( fliplr(ind) ) );  %# get the anti-diagonals (or use ROT90)
ind(ind==0) = [];                        %# keep non-zero indices
result = A(ind);                         %# get elements in desired order

This is very similar to this answer I gave in a previous question (the difference was that the anti-digaonals were in reverse order).

share|improve this answer

Short version:

If you preassign your result array, everything will be a lot faster.

result = zeros(1,knownLengthOfResultsArray); %# such as "numel(block)"
ct = 1;
for i=1:N
    tmp = nextPart(i);
    nTmp = length(tmp);
    result(ct:ct+nTmp-1) = tmp;
    ct = ct + nTmp;

Long version:

However, it may be even more efficient to rewrite your algorithm. See e.g. the answers to this question (use fliplr on your array first), or @gnovice's answer.

share|improve this answer

Your Answer


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.