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# concatMap in matlab

## 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)];
end
``````

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?

Thanks!

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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

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
``````
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+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).

-

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;
end
``````

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.

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