# MATLAB repeat numbers based on a vector of lengths

Is there a vectorised way to do the following? (shown by an example):

``````input_lengths = [ 1 1 1 4       3     2   1 ]
result =        [ 1 2 3 4 4 4 4 5 5 5 6 6 7 ]
``````

I have spaced out the input_lengths so it is easy to understand how the result is obtained

The resultant vector is of length: `sum(lengths)`. I currently calculate `result` using the following loop:

``````result = ones(1, sum(input_lengths ));
counter = 1;
for i = 1:length(input_lengths)
start_index = counter;
end_index = counter + input_lengths (i) - 1;

result(start_index:end_index) = i;
counter = end_index + 1;
end
``````

EDIT:

I can also do this using arrayfun (although that is not exactly a vectorised function)

``````cell_result = arrayfun(@(x) repmat(x, 1, input_lengths(x)), 1:length(input_lengths), 'UniformOutput', false);
cell_result : {[1], [2], [3], [4 4 4 4], [5 5 5], [6 6], [7]}

result = [cell_result{:}];
result : [ 1 2 3 4 4 4 4 5 5 5 6 6 7 ]
``````
• don't be sure that a "vectorized" function will be faster than a for loop here... you can test with arrayfun and see... also see here stackoverflow.com/questions/12522888/…
– bla
May 15, 2014 at 6:59
• Your `for` loop doesn't seem to work. `sum(input_lengths)` is bigger than `length(input_lengths)` so `input_lengths(i)` gives an error for me (Matlab). May 15, 2014 at 7:02
• Your `cell_result` code doesn't work either. May 15, 2014 at 7:02
• Sorry @David and Divakar I've fixed it. It was supposed to be length not sum. May 15, 2014 at 7:05
• Hey @Dan, I incorrectly assumed that my for-loop was slowing me down but it was actually elsewhere (due to the massive amount of data being pushed through this function). I also thought that it was an interesting challenge to be able to vectorise, I have certainly seen some elegant solutions to similar problems around the place. May 15, 2014 at 7:33

A fully vectorized version:

``````selector=bsxfun(@le,[1:max(input_lengths)]',input_lengths);
V=repmat([1:size(selector,2)],size(selector,1),1);
result=V(selector);
``````

Downside is, the memory usage is O(numel(input_lengths)*max(input_lengths))

• To avoid repmat you can use another `bsxfun` - `V = bsxfun(@times,selector,1:numel(input_lengths)); result = V(V~=0)` May 15, 2014 at 7:39
• @Divakar Please post this one as an answer, I think it worths it, and one can make a one-liner from this solution, great! May 15, 2014 at 7:56
• @Bentoy13 And that one-liner would be huge! :) May 15, 2014 at 8:05
• Great solution! You could also replace the last two line with `[~, result] = find(selector)`, haven't tested if it gives any performance improvement though
– Dan
May 15, 2014 at 8:45
• +1 for this approach, and for recognising its downside May 15, 2014 at 11:01

## Benchmark of all solutions

Following the previous benchmark, I group all solutions given here in a script and run it a few hours for a benchmark. I've done this because I think it's good to see what is the performance of each proposed solution with the input lenght as parameter - my intention is not here to put down the quality of the previous one, which gives additional information about the effect of JIT. Moreover, and every participant seems to agree with that, quite a good work was done in all answers, so this great post deserves a conclusion post.

I won't post the code of the script here, this is quite long and very uninteresting. The procedure of the benchmark is to run each solution for a set of different lengths of input vectors: 10, 20, 50, 100, 200, 500, 1000, 2000, 5000, 10000, 20000, 50000, 100000, 200000, 500000, 1000000. For each input length, I've generated a random input vector based on Poisson law with parameter 0.8 (to avoid big values):

``````input_lengths = round(-log(1-rand(1,ILen(i)))/poisson_alpha)+1;
``````

Finally, I average the computation times over 100 runs per input length.

I've run the script on my laptop computer (core I7) with Matlab R2013b; JIT is activated.

And here are the plotted results (sorry, color lines), in a log-log scale (x-axis: input length; y-axis: computation time in seconds):

So Luis Mendo is the clear winner, congrats!

For anyone who wants the numerical results and/or wants to replot them, here they are (cut the table into 2 parts and approximated to 3 digits, for a better display):

``````N                   10          20          50          100         200         500         1e+03       2e+03
-------------------------------------------------------------------------------------------------------------
OP's for-loop       8.02e-05    0.000133    0.00029     0.00036     0.000581    0.00137     0.00248     0.00542
OP's arrayfun       0.00072     0.00117     0.00255     0.00326     0.00514     0.0124      0.0222      0.047
Daniel              0.000132    0.000132    0.000148    0.000118    0.000126    0.000325    0.000397    0.000651
Divakar             0.00012     0.000114    0.000132    0.000106    0.000115    0.000292    0.000367    0.000641
David's for-loop    9.15e-05    0.000149    0.000322    0.00041     0.000654    0.00157     0.00275     0.00622
David's arrayfun    0.00052     0.000761    0.00152     0.00188     0.0029      0.00689     0.0122      0.0272
Luis Mendo          4.15e-05    4.37e-05    4.66e-05    3.49e-05    3.36e-05    4.37e-05    5.87e-05    0.000108
Bentoy13's cumsum   0.000104    0.000107    0.000111    7.9e-05     7.19e-05    8.69e-05    0.000102    0.000165
Bentoy13's sparse   8.9e-05     8.82e-05    9.23e-05    6.78e-05    6.44e-05    8.61e-05    0.000114    0.0002
Luis Mendo's optim. 3.99e-05    3.96e-05    4.08e-05    4.3e-05     4.61e-05    5.86e-05    7.66e-05    0.000111

N                   5e+03       1e+04       2e+04       5e+04       1e+05       2e+05       5e+05       1e+06
-------------------------------------------------------------------------------------------------------------
OP's for-loop       0.0138      0.0278      0.0588      0.16        0.264       0.525       1.35        2.73
OP's arrayfun       0.118       0.239       0.533       1.46        2.42        4.83        12.2        24.8
Daniel              0.00105     0.0021      0.00461     0.0138      0.0242      0.0504      0.126       0.264
Divakar             0.00127     0.00284     0.00655     0.0203      0.0335      0.0684      0.185       0.396
David's for-loop    0.015       0.0286      0.065       0.175       0.3         0.605       1.56        3.16
David's arrayfun    0.0668      0.129       0.299       0.803       1.33        2.64        6.76        13.6
Luis Mendo          0.000236    0.000446    0.000863    0.00221     0.0049      0.0118      0.0299      0.0637
Bentoy13's cumsum   0.000318    0.000638    0.00107     0.00261     0.00498     0.0114      0.0283      0.0526
Bentoy13's sparse   0.000414    0.000774    0.00148     0.00451     0.00814     0.0191      0.0441      0.0877
Luis Mendo's optim. 0.000224    0.000413    0.000754    0.00207     0.00353     0.00832     0.0216      0.0441
``````

Ok, I've added another solution to the list ... I could not prevent myself to optimize the best-so-far solution of Luis Mendo. No credit for that, it's just a variant from Luis Mendo's, I'll explain it later.

Clearly, the solutions using `arrayfun` are very time-consuming. The solutions using an explicit for loop are faster, yet still slow compared with others solutions. So yes, vectorizing is still a major option for optimizing a Matlab script.

Since I've seen a big dispersion on the computing times of the fastest solutions, especially with input lengths between 100 and 10000, I decide to benchmark more precisely. So I've put the slowest apart (sorry), and redo the benchmark over the 6 other solutions which run much faster. The second benchmark over this reduced list of solutions is identical except that I've average over 1000 runs.

(No table here, unless you really want to, it's quite the same numbers as before)

As it was remarked, the solution by Daniel is a little faster than the one by Divakar because it seems that the use of `bsxfun` with @times is slower than using `repmat`. Still, they are 10 times faster than for-loop solutions: clearly, vectorizing in Matlab is a good thing.

The solutions of Bentoy13 and Luis Mendo are very close; the first one uses more instructions, but the second one uses an extra allocation when concatenating 1 to `cumsum(input_lengths(1:end-1))`. And that's why we see that Bentoy13's solution tends to be a bit faster with big input lengths (above 5.10^5), because there is no extra allocation. From this consideration, I've made an optimized solution where there is no extra allocation; here is the code (Luis Mendo can put this one in his answer if he wants to :) ):

``````result = zeros(1,sum(input_lengths));
result(1) = 1;
result(1+cumsum(input_lengths(1:end-1))) = 1;
result = cumsum(result);
``````

Any comment for improvement is welcome.

• This is amazing, I wish I wasn't colourblind! May 16, 2014 at 0:03
• Thank you very much, I expand it right now with new results. @SamuelO'Malley I apologize for colorful plotting, I thought it was the best display I can offer here considering that the picture should be a little small. But I put the numbers, so it won't be a problem anymore! May 16, 2014 at 13:32
• @Bentoy Thanks. I've added your optimized version in my answer, with due credit :-) May 21, 2014 at 12:04

More of a comment than anything, but I did some tests. I tried a `for` loop, and an `arrayfun`, and I tested your `for` loop and `arrayfun` version. Your `for` loop was the fastest. I think this is because it is simple, and allows the JIT compilation to do the most optimisation. I am using Matlab, octave might be different.

And the timing:

``````Solution:     With JIT   Without JIT
Sam for       0.74       1.22
Sam arrayfun  2.85       2.85
My for        0.62       2.57
My arrayfun   1.27       3.81
Divakar       0.26       0.28
Bentoy        0.07       0.06
Daniel        0.15       0.16
Luis Mendo    0.07       0.06
``````

So Bentoy's code is really fast, and Luis Mendo's is almost exactly the same speed. And I rely on JIT way too much!

And the code for my attempts

``````clc,clear
input_lengths = randi(20,[1 10000]);

% My for loop
tic()
C=cumsum(input_lengths);
D=diff(C);
results=zeros(1,C(end));
results(1,1:C(1))=1;
for i=2:length(input_lengths)
results(1,C(i-1)+1:C(i))=i*ones(1,D(i-1));
end
toc()

tic()
A=arrayfun(@(i) i*ones(1,input_lengths(i)),1:length(input_lengths),'UniformOutput',false);
R=[A{:}];
toc()
``````
• Just a detail: `D=diff(C);` is useless, it's equal to `input_lengths(2:end)`. May 15, 2014 at 7:42
• @David would be interesting to add the `bsxfun`/`repmat` by Daniel/Divakar and the flippy-`cumsum` solution of Bentoy to your benchmark tests
– Dan
May 15, 2014 at 8:37
• @David I just posted another answer. Would you mind including it in your tests? Thanks in advance! May 15, 2014 at 10:45
• @LuisMendo Done :) Your code is pretty quick! I feel dumb now! `:D` May 15, 2014 at 12:05
• Thank you so much everyone who contributed. I am blown away by the quality of the answers here and I loved how they all built on each other to find the simplest and best solution. May 15, 2014 at 23:51
``````result = zeros(1,sum(input_lengths));
result(cumsum([1 input_lengths(1:end-1)])) = 1;
result = cumsum(result);
``````

This should be pretty fast. And memory usage is the minimum possible.

An optimized version of the above code, due to Bentoy13 (see his very detailed benchmarking):

``````result = zeros(1,sum(input_lengths));
result(1) = 1;
result(1+cumsum(input_lengths(1:end-1))) = 1;
result = cumsum(result);
``````
• Simpler than mine, I've looked for this more concise way to compute indexes. Following the current benchmark, I think you should be the fastest. May 15, 2014 at 11:04
• @Bentoy13 Thanks! I've asked David to include my solution in his tests, so we'll see May 15, 2014 at 11:12
• Thanks @LuisMendo, I am accepting your answer because it is the simplest and fastest, I wish I could accept more than one answer because everyone contributed a lot May 15, 2014 at 23:57
• @SamuelO'Malley Yes, it was an interesting question, and fun for all of us! May 15, 2014 at 23:59
• Yes, sorry I meant logical index. Okay thank you for that. I've managed to bring our code down from a three level nested for-loop taking up to 10 minutes, down to less than a 30 seconds by using this method and eliminating the for-loops May 16, 2014 at 0:55

This is a slight variant of @Daniel's answer. The crux of this solution is based on that solution. Now this one avoids `repmat`, so in that way it's little-more "vectorized" maybe. Here's the code -

``````selector=bsxfun(@le,[1:max(input_lengths)]',input_lengths); %//'
V = bsxfun(@times,selector,1:numel(input_lengths));
result = V(V~=0)
``````

For all the desperate one-liner searching people -

``````result = nonzeros(bsxfun(@times,bsxfun(@le,[1:max(input_lengths)]',input_lengths),1:numel(input_lengths)))
``````

I search an elegant solution, and I think David's solution is a good start. What I have in mind is that one can generate the indexes where to add one from previous element.

For that, if we compute the `cumsum` of the input vector, we get:

``````cumsum(input_lengths)
ans = 1     2     3     7    10    12    13
``````

This is the indexes of the ends of sequences of identical numbers. That is not what we want, so we flip the vector twice to get the beginnings:

``````fliplr(sum(input_lengths)+1-cumsum(fliplr(input_lengths)))
ans = 1     2     3     4     8    11    13
``````

Here is the trick. You flip the vector, cumsum it to get the ends of the flipped vector, and then flip back; but you must substract the vector from the total length of the output vector (+1 because index starts at 1) because cumsum applies on the flipped vector.

Once you have done this, it's very straightforward, you just have to put 1 at computed indexes and 0 elsewhere, and cumsum it:

``````idx_begs = fliplr(sum(input_lengths)+1-cumsum(fliplr(input_lengths)));
result = zeros(1,sum(input_lengths));
result(idx_begs) = 1;
result = cumsum(result);
``````

EDIT

First, please have a look at Luis Mendo's solution, it is very close to mine but is more simpler and a bit faster (I won't edit mine even it is very close). I think at this date this is the fastest solution from all.

Second, while looking at others solutions, I've made up another one-liner, a little different from my initial solution and from the other one-liner. Ok, this won't be very readable, so take a breath:

``````result = cumsum( full(sparse(cumsum([1,input_lengths(1:end-1)]), ...
ones(1,length(input_lengths)), 1, sum(input_lengths),1)) );
``````

I cut it on two lines. Ok now let's explain it.

The similar part is to build the array of the indexes where to increment the value of the current element. I use the solution of Luis Mendo's for that. To build in one line the solution vector, I use here the fact that it is in fact a sparse representation of the binary vector, the one we will cumsum at the very end. This sparse vector is build using our computed index vector as x positions, a vector of 1 as y positions, and 1 as the value to put at these locations. A fourth argument is given to precise the total size of the vector (important if the last element of `input_lengths` is not 1). Then we get the full representation of this sparse vector (else the result is a sparse vector with no empty element) and we can cumsum.

There is no use of this solution other than to give another solution to this problem. A benchmark can show that it is slower than my original solution, because of a heavier memory load.

• Great solution and explanation!
– Dan
May 15, 2014 at 8:40
• I think this puts 1 too many of the final digit in `result`. It's very fast though! May 15, 2014 at 9:23
• @Bentoy13 Looks like David is right about the extra digit, why the `+1` in `result = zeros(1,sum(input_lengths)+1);`? Looks like you get the correct answer without it
– Dan
May 15, 2014 at 9:30
• @ Dan & David: I correct it; I really don't know why I put this +1 in zeros. Thank you very much! May 15, 2014 at 9:48
• isn't idx_begs = [1 cumsum(input_lengths(1:end-1))+1] an equivalent and simpler solution? It is based on the fact that the indexes of beginning of sequences are the indexes of the ending of sequences +1 (except the first and last elements, that are easy to compute). May 15, 2014 at 11:33