Consider 2 Vectors A = [20000000 x 1] and B = [20000000 x 1 ]

I would need to find the sum of all A corresponding to every unique element of B.

Although this looks really easy, this is taking forever in MATLAB.

Currently, I am using

u = unique(B);
length_u = length(u);
C = zeros(length_u,1);

for i = 1:length_u
   C(i,1) = sum(A(B==u(i)));

Is there anyway to make it run faster? I tried splitting the loop and running 2 parfor loops using the parallel computing toolbox(because I have only 2 cores). Still takes hours.

P.S: Yes, I should get a better computer.

  • 1
    what is the bottleneck? the unique or the loop? – Shai Jun 26 '14 at 7:40
  • could you post your A and B matrices? For example, A=randi(100,[20000000,1]); etc. – Parag S. Chandakkar Jun 26 '14 at 7:40
  • @Shai Its the loop. Running over so many iterations. Matlab gets confused, I think. – enigmae Jun 26 '14 at 8:02
  • If I do a profile of your code it's the unique for me. – bdecaf Jun 26 '14 at 8:40
  • @bdecaf what did you use for A and B? if A has relatively small number of unique elements the loop is no longer the bottleneck, but if A is large with many unique elements than the unique becomes negligble – Shai Jun 26 '14 at 8:46

You must see this answer first.
If you must, you can use a combination of histc and accumarray

A = randi( 500, 1, 100000 );
B = randi( 500, 1, 100000 );

ub = unique( B );

[ignore idx] = histc( B, [ub-.5 ub(end)+.5] );
C = accumarray( idx', A' )';

see a toy comparison to the naive for-loop implementation on ideone.

How does it work?

We use the second outout of histc to map elements of B (and later A) to the bins defined by the elements of ub (the unique elements of B).
accumarray is then used to sum all entries of A accorind to the mapping defined by idx.
Note: I assume the unique elements of B are at least 0.5 apart.

  • What is ub here? – enigmae Jun 26 '14 at 8:03
  • @Nishanth uc was a typo. please see my edit. – Shai Jun 26 '14 at 8:06
  • @Shai The only thing which is not quite nice in your solution is the fact which you have written in your "Note". But really well done. I didn't think about histc. +1 – The Minion Jun 26 '14 at 8:33
  • @TheMinion the +.5 can be averted by looking at the smallest abs diff in ub - but I wanted to keep the code simple. – Shai Jun 26 '14 at 8:35
  • 1
    @AnderBiguri you are right. However, I am used to an old version of Matlab that does not support ~ :(... old habits die hard. – Shai Jun 26 '14 at 10:29

If B contains only integers, you can do it easily in one line, using the fact that sparse adds elements with the same index:

C = nonzeros(sparse(B,1,A));
  • Nice solution for integers. I didn't know sparse did this. – The Minion Jun 26 '14 at 9:09
  • @TheMinion Thanks! Yes, it's not a very well known feature of Matlab. It more or less turns sparse into an accumarray with the issparse option – Luis Mendo Jun 26 '14 at 9:16
  • @LuisMendo in that respect accumarray is an extension of sparse. Using accumarray with histc generalize to non-integers as well. – Shai Jun 26 '14 at 9:21

Further simplification of code suggested by Shai:

A = randi( 500, 1, 100000 );
B = randi( 500, 1, 100000 );

[~,~,idb] = unique( B );

C = accumarray( idb', A' )';

The "idb" here gives a vector same as that of "idx" in code suggested by Shai.

  • +1 superb! I completely forgot the extra outputs of unique... – Shai Jun 26 '14 at 11:26

I modified the sum. Instead of having to check each element rather it fits the case (B==u(i)) or not, I sorted the array and stopped the moment the element changed. While starting the next sum from that element. That way I only had to loop over each element in A ones, instead of length_u times. Here is the code I used:

A= rand(100000,1);
B= round(rand(100000,1)*25000);
u = unique(B);
length_u = length(u);
C = zeros(length_u,1);
E = zeros(length_u,1);
for k = 1:length_u
   C(k,1) = sum(A(B==u(k)));

D= sortrows([A,B],2);
for l=1:numel(u)
    while m<numel(B) && D(m+1,2)==u(l) 
    E(l,1) = sum(D(n:m,1));

I used your code as well. The elapsed time for your code was: t_OP=10.9398 and for my modification: t_trial=0.0962. Hopefully this helps. I made sure the code worked by building sum(E-C) which was 0.
EDIT: Speedtest
I compared it to @Shai's solution as well. THis resulted in

t_OP =

t_trial =

t_Shai =


EDIT: Comment by @moarningsun
Instead of using the while-loop. You can use the second output of unique if you sort your array before building the sum.

A = randi( 25000, 1, 100000 );
B = randi( 25000, 1, 100000 );
D= sortrows([A',B'],2);
[u, idx] = unique(D(:,2));
idx = [idx; numel(D(:,2))+1];
for l=1:numel(u)
    E(l,1) = sum(D(idx(l):idx(l+1)-1,1));
  • how does your method compares to histc and accumarray? – Shai Jun 26 '14 at 8:23
  • @Shai I edited my post. My modification resulted in a factor 100 compared to OP yours resulted in an aditional factor 10. So about 1000 times faster than OP. – The Minion Jun 26 '14 at 8:28
  • You could also sort B first and then get the "boundary" indices from [i, idx] = unique(B_sorted). It saves you the while loop. – user2379410 Jun 26 '14 at 8:50
  • @moarningsun You are right. I tried it but it didn't really change anything regarding run time. I will post it as a second Edit for future reference. – The Minion Jun 26 '14 at 9:03

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