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Given an n-dimensional matrix of values: what is the most efficient way of retrieving values by arbitrary indices (i.e. coordinates)?

E.g. in a random 5x5 matrix, if I want the values at (1,1) (2,3) and (4,5) what is the most efficient way of returning just the values at these coordinates?

If I provide these coordinates in a separate matrix for example is there a one line of MATLAB which can do the job? Something like:




Except that doesn't work.

One caveat however, for various reasons I am unable to use linear indexing - the results must be returned using the original indices. And the size of these matrices is potentially very large so I don't want to use loops either.

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What should your output look like? Suppose x = [1 2 3;4 5 6;7 8 9] and y = [1 1;2 3;3 1], what should z look like? – Jacob Nov 5 '09 at 13:31
maybe you want a mask? make Y the same size as x with "1"s at the coordinates of interest and 0 everywhere else, then take the point-by-point multiplication of the two matrices? – Mikeb Nov 5 '09 at 13:36
@unknown: You mention in a comment below that the matrix is chunked by a toolkit you are using. Do you have any way to access information about the chunking pattern at the time the indexing is done? – gnovice Nov 5 '09 at 16:30
@unknown: A couple of additional questions... What sort of error do you get when you try to use linear indexing? Are you trying to do linear indexing like in your example above (because what you're doing in that example is not linear indexing)? – gnovice Nov 5 '09 at 21:48
up vote 4 down vote accepted

If you're against using linear indexing and loops, the only other alternative, AFAIK, is logical indexing. But if y always comes in the form you've suggested, you'll need to create a logical matrix from the indices specified in y.

Could you explain why linear indexing is not allowed?

Anyway, if you want a really stupid answer (which is all I can provide with this much information):

z = diag(x(y(:,1),y(:,2)))

Of course, this will needlessly create a huge matrix and extract the diagonal elements (the ones you need) from it - but it gets it done in one line, etc.

EDIT: If the restriction is using linear indexing on the original data, then you can use linear indexing to create a logical matrix and index x with that. E.g.

% Each element of L is only one byte
L = false(size(x)); 
% Create the logical mask
L(sub2ind(size(x),y(:,1),y(:,2))) = true;
% Extract the required elements
z = x(L);

Similarly, for a 3-dimensional matrix:

x = rand(3,3,3);
y = [1 1 1;2 2 2;3 3 3];
L = false(size(x));
L(sub2ind(size(x),y(:,1),y(:,2),y(:,3))) = true;
z = x(L);

Also, logical indexing is supposed to be faster than linear indexing, so apart from building the mask, you're in good shape.

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Linear indexing is not an option because the matrices are very large and are chunked by the underlying toolkit we are using - in fact this question came from the fact that the toolkit fails when you try and use linear indexing to access the data. The diag idea would work except that we are using 3 dimensional data so the size of the resulting matrix would be the cube of the original matrix which as you say is needlessly huge. Thanks anyway – empedia Nov 5 '09 at 14:04
Ok, created a logical mask using linear indexing and used it to query x. – Jacob Nov 5 '09 at 14:16
Thanks for the alternative option, its interesting. In the meantime we worked out the problem came from trying to access data from different chunks when the chunks weren't all in memory. By ordering the coordinate access first we have worked around the problem. – empedia Nov 6 '09 at 10:23

why isn't sub2ind alone suitable for this problem? I don't see the need for the logical mask; e.g.

z = x(sub2ind(size(x),y(:,1),y(:,2)))

should work as well.

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I thought the same thing, until I noticed the comment the OP left on Jacob's answer. Linear indexing seems to be out of the question. – gnovice Nov 5 '09 at 19:17
I'm not sure what one means by 'linear indexing is out of the question'; it sounded like either the OP wasn't aware of sub2ind or wanted to attach shape to the LHS variable, z, based on y? – shabbychef Nov 5 '09 at 20:26
@shabychef: It doesn't make much sense to me either, which is why I asked for a little more info from the OP. It may be that the "linear indexing" they were trying to do was actually not linear indexing at all and was just flat out wrong. It's hard to say without more detail about this "toolkit" they are using. – gnovice Nov 5 '09 at 20:38
The "toolkit" is a specialised toolbox for processing fMRI data. The problem with linear indexing is simply that there are bugs in the toolbox which causes the linear index to return the wrong values because of the way the toolbox handles very large data files to get around memory constraints by not reading the whole file in at one time. If it worked properly I would use sub2ind (in fact that was my original solution). – empedia Nov 6 '09 at 10:22

Coming to the party long after the music has stopped, but I couldn't help myself...

If you need "full" indexing because of a bug in the toolbox, and the toolbox is loading only a part of the matrix at one time, you might consider following along with the behavior of the toolbox. A big efficiency gain with large matrices is gained with two things

1) don't make copies of things that don't need to be copied; this includes, for example, creating a logical array of the size of the original matrix (although it's nominally "efficient", it takes one byte per element. If your matrix is too large to fit in memory all at once, even a matrix that is 1/8 the size is probably significant)

2) preserve memory coherence: access memory "in the same region", or find yourself slowed down by lots of disk swapping; even when everything fits in memory, preserving "cache coherence" can result in significant performance improvements. If you can access matrix elements in the order in which they are stored, things speed up considerably.

To address the first point, you need to look for a method that doesn't require creating a complete copy (so Jacob's answer would be out). To address the second, you need to sort your indices before accessing the matrix - in that way, any elements that can be accessed "from the same block of memory", will be.

The two techniques are combined in the following. I am assuming that numel(y) << numel(x) - in other words you are only interested in looking at a relatively small number of elements of x. If that's not the case, sorting the y vector would actually slow you down a lot:

x = rand(5,5);
y = [1 1; 2 3; 4 5];
s = sub2ind(size(x), y(:,1), y(:,2)); % from the linear index we get access order
[ySorted yOrder] = sort(s);

% find the first, second index in the right access order:
y1 = y(yOrder, 1);
y2 = y(yOrder, 2);

% access the array using conventional indexing:
z = arrayfun(@(a,b)x(a,b), y1, y2);

% now put things back in the right order:
[rev revOrder] = sort(yOrder);
z = z(revOrder);

I benchmarked this using a 10000x10000 matrix x and a 5000x2 random element lookup vector y. Comparing against Jacob's code, I obtained

my method:   51 ms
his method: 225 ms

Increasing the size of the lookup vector to 50000x2, the values are

my method:  523 ms
his method: 305 ms

In other words - which method will work better depends on the number of elements you want to access. Note also that the use of the logical L matrix implicitly results in sequential access of the large x matrix - but that during the creation of that matrix you are randomly accessing the memory...

Note by the way that one question you had was "is there a one liner" - and the answer is "yes". If you have your arrays x and y as defined, then

z = arrayfun(@(a,b)x(a,b),y(:,1),y(:,2));

is indeed just one line, and doesn't use linear indexing...

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