# Find equal rows between two Matlab matrices

I have a matrix `index` in Matlab with size `GxN` and a matrix `A` with size `MxN`.

Let me provide an example before presenting my question.

``````clear
N=3;
G=2;
M=5;

index=[1  2  3;
13 14 15]; %GxN

A=[1  2  3;
5  6  7;
21 22 23;
1  2  3;
13 14 15]; %MxN
``````

I would like your help to construct a matrix `Response` with size `GxM` with `Response(g,m)=1` if the row `A(m,:)` is equal to `index(g,:)` and zero otherwise.

Continuing the example above

``````Response= [1 0 0 1 0;
0 0 0 0 1]; %GxM
``````

This code does what I want (taken from a previous question of mine - just to clarify: the current question is different)

``````Response=permute(any(all(bsxfun(@eq, reshape(index.', N, [], G), permute(A, [2 3 4 1])), 1), 2), [3 4 1 2]);
``````

However, the command is extremely slow for my real matrix sizes (`N=19, M=500, G=524288`). I understand that I will not be able to get huge speed but anything that can improve on this is welcome.

• I highly doubt this is much more improveable. You may be able to do it by instead of using 1-liners, break the code into pieces and time it – Ander Biguri Oct 3 '18 at 10:16

# Aproach 1: computing distances

If you have the Statistics Toolbox:

``````Response = ~(pdist2(index, A));
``````

or:

``````Response = ~(pdist2(index, A, 'hamming'));
``````

This works because `pdist2` computes the distance between each pair of rows. Equal rows have distance `0`. The logical negation `~` gives `1` for those pairs of rows, and `0` otherwise.

# Approach 2: reducing rows to unique integer labels

This approach is faster on my machine:

``````[~,~,u] = unique([index; A], 'rows');
Response = bsxfun(@eq, u(1:G), u(G+1:end).');
``````

It works by reducing rows to unique integer labels (using the third output of `unique`), and comparing the latter instead of the former.

For your size values this takes approximately 1 second on my computer:

``````clear
N = 19; M = 500; G = 524288;
index = randi(5,G,N); A = randi(5,M,N);
tic
[~,~,u] = unique([index; A], 'rows');
Response = bsxfun(@eq, u(1:G), u(G+1:end).');
toc
``````

gives

``````Elapsed time is 1.081043 seconds.
``````
• `findgroups` might be quicker than using the 3rd output of `unique`. Not done speed tests in the past but believe it does the same thing. – Wolfie Oct 3 '18 at 13:18
• @Wolfie I think `findgroups` requires grouping variables to be vectors. So the matrices here would have to be split into their columns, which takes time. Also, `findgroups` internally uses the third output of `unique`, so I doubt it's faster – Luis Mendo Oct 3 '18 at 13:22
• Ah ignore me then, didn't realise the two were intertwined! The 2nd option is quite a bit quicker than my reshaping method which surprised me. – Wolfie Oct 3 '18 at 13:24
• @Wolfie Yes, for the OP's sizes your method takes 5 times more than my second approach on my computer. I guess when sizes are large it's beneficial to reduce a dimension as soon as possible (my second approach) even if that takes time – Luis Mendo Oct 3 '18 at 13:27

MATLAB has a multitude of functions for working with sets, including `setdiff`, `intersect`, `union` etc. In this case, you can use the `ismember` function:

``````[~, Loc] = ismember(A,index,'rows');
``````

Which gives:

``````Loc =
1
0
0
1
2
``````

And `Response` would be constructed as follows:

``````Response = (1:size(index,1) == Loc).';
``````

``````Response =
2×5 logical array
1   0   0   1   0
0   0   0   0   1
``````
• Thanks, but I can't see how to get `Response` from there. – user3285148 Oct 3 '18 at 10:59

You could `reshape` the matrices so that each row instead lies along the 3rd dimension. Then we can use implicit expansion (see `bsxfun` for R2016b or earlier) for equality of all elements, and `all` to aggregate on the rows (i.e. false if not all equal for a given row).

``````Response = all( reshape( index, [], 1, size(index,2) ) == reshape( A, 1, [], size(A,2) ), 3 );
``````

You might even be able to avoid some reshaping by using `all` in another dimension, but it's easier for me to visualise it this way.