# Repeat copies of array elements: Run-length decoding in MATLAB

I'm trying to insert multiple values into an array using a 'values' array and a 'counter' array. For example, if:

``````a=[1,3,2,5]
b=[2,2,1,3]
``````

I want the output of some function

``````c=somefunction(a,b)
``````

to be

``````c=[1,1,3,3,2,5,5,5]
``````

Where a(1) recurs b(1) number of times, a(2) recurs b(2) times, etc...

Is there a built-in function in MATLAB that does this? I'd like to avoid using a for loop if possible. I've tried variations of 'repmat()' and 'kron()' to no avail.

This is basically `Run-length encoding`.

-

## Problem Statement

We have an array of values, `vals` and runlengths, `runlens`:

``````vals     = [1,3,2,5]
runlens  = [2,2,1,3]
``````

We are needed to repeat each element in `vals` times each corresponding element in `runlens`. Thus, the final output would be:

``````output = [1,1,3,3,2,5,5,5]
``````

## Prospective Approach

One of the fastest tools with MATLAB is `cumsum` and is very useful when dealing with vectorizing problems that work on irregular patterns. In the stated problem, the irregularity comes with the different elements in `runlens`.

Now, to exploit `cumsum`, we need to do two things here: Initialize an array of `zeros` and place "appropriate" values at "key" positions over the zeros array, such that after "`cumsum`" is applied, we would end up with a final array of repeated `vals` of `runlens` times.

Steps: Let's number the above mentioned steps to give the prospective approach an easier perspective:

1) Initialize zeros array: What must be the length? Since we are repeating `runlens` times, the length of the zeros array must be the summation of all `runlens`.

2) Find key positions/indices: Now these key positions are places along the zeros array where each element from `vals` start to repeat. Thus, for `runlens = [2,2,1,3]`, the key positions mapped onto the zeros array would be:

``````[X 0 X 0 X X 0 0], where X's are those key positions.
``````

3) Find appropriate values: The final nail to be hammered before using `cumsum` would be to put "appropriate" values into those key positions. Now, since we would be doing `cumsum` soon after, if you think closely, you would need a `differentiated` version of `values` with `diff`, so that `cumsum` on those would bring back our `values`. Since these differentiated values would be placed on a zeros array at places separated by the `runlens` distances, after using `cumsum` we would have each `vals` element repeated `runlens` times as the final output.

Solution Code

Here's the implementation stitching up all the above mentioned steps -

``````%// Calculate cumsumed values of runLengths.
%// We would need this to initialize zeros array and find key positions later on.
clens = cumsum(runlens)

%// Initalize zeros array
array = zeros(1,(clens(end)))

%// Find key positions/indices
key_pos = [1 clens(1:end-1)+1]

%// Find appropriate values
app_vals = diff([0 vals])

%// Map app_values at key_pos on array
array(pos) = app_vals

%// cumsum array for final output
output = cumsum(array)
``````

Pre-allocation Hack

As could be seen that the above listed code uses pre-allocation with zeros. Now, according to this `UNDOCUMENTED MATLAB blog on faster pre-allocation`, one can achieve much faster pre-allocation with -

```````array(clens(end)) = 0` instead of `array = zeros(1,(clens(end)))`
``````

Wrapping up: Function Code

To wrap up everything, we would have a compact function code to achieve this run-length decoding like so -

``````function out = rle_cumsum_diff(vals,runlens)
clens = cumsum(runlens);
idx(clens(end))=0;
idx([1 clens(1:end-1)+1]) = diff([0 vals]);
out = cumsum(idx);
return;
``````

## Benchmarking

Benchmarking Code

Listed next is the benchmarking code to compare runtimes and speedups for the stated `cumsum+diff` approach in this post over the other `cumsum-only` based approach on `MATLAB 2014B`-

``````datasizes = [reshape(linspace(10,70,4).'*10.^(0:4),1,[]) 10^6 2*10^6]; %//'
fcns = {'rld_cumsum','rld_cumsum_diff'}; %// approaches to be benchmarked

for k1 = 1:numel(datasizes)
n = datasizes(k1); %// Create random inputs
vals = randi(200,1,n);
runs = [5000 randi(200,1,n-1)]; %// 5000 acts as an aberration
for k2 = 1:numel(fcns) %// Time approaches
tsec(k2,k1) = timeit(@() feval(fcns{k2}, vals,runs), 1);
end
end

figure,      %// Plot runtimes
loglog(datasizes,tsec(1,:),'-bo'), hold on
loglog(datasizes,tsec(2,:),'-k+')
set(gca,'xgrid','on'),set(gca,'ygrid','on'),
xlabel('Datasize ->'), ylabel('Runtimes (s)')
legend(upper(strrep(fcns,'_',' '))),title('Runtime Plot')

figure,      %// Plot speedups
semilogx(datasizes,tsec(1,:)./tsec(2,:),'-rx')
set(gca,'ygrid','on'), xlabel('Datasize ->')
legend('Speedup(x) with cumsum+diff over cumsum-only'),title('Speedup Plot')
``````

Associated function code for `rld_cumsum.m`:

``````function out = rld_cumsum(vals,runlens)
index = zeros(1,sum(runlens));
index([1 cumsum(runlens(1:end-1))+1]) = 1;
out = vals(cumsum(index));
return;
``````

Runtime and Speedup Plots

## Conclusions

The proposed approach seems to be giving us a noticeable speedup over the `cumsum-only` approach, which is about `3x`!

Why is this new `cumsum+diff` based approach better than the previous `cumsum-only` approach?

Well, the essence of the reason lies at the final step of the `cumsum-only` approach that needs to map the "cumsumed" values into `vals`. In the new `cumsum+diff` based approach, we are doing `diff(vals)` instead for which MATLAB is processing only `n` elements (where n is the number of runLengths) as compared to the mapping of `sum(runLengths)` number of elements for the `cumsum-only` approach and this number must be many times more than `n` and therefore the noticeable speedup with this new approach!

-
Thank you for the excellent answer. I think it may be one of the most thorough and well explained I've ever gotten on SO. –  Doresoom Mar 16 at 15:21
Nice optimization! Out of curiosity, where does the built-in MATLAB function fit on the curve? It might be useful to add it as a baseline. –  chappjc Mar 16 at 15:37
@chappjc Thanks! Well that's the issue really, don't have access to `MATLAB 2015A`! Looking for volunteers on that, as stated in the bounty comment! :) –  Divakar Mar 16 at 15:46
@Doresoom Glad to be of help on this! Seems like run-length decoding is quite useful and this `cumsum+diff` trick struck me recently! –  Divakar Mar 16 at 15:49
Interesting idea. Even beats the new builtin! It has its downsides though, as it won't work correctly with integer types e.g. `vals = int8([120,-120])` or doubles with large variance `vals = [1e16, 1]` or `Inf`s/`Nan`s. –  knedlsepp Mar 16 at 22:43

There's no built-in function I know of, but here's one solution:

``````index = zeros(1,sum(b));
index([1 cumsum(b(1:end-1))+1]) = 1;
c = a(cumsum(index));
``````

## Explanation:

A vector of zeroes is first created of the same length as the output array (i.e. the sum of all the replications in `b`). Ones are then placed in the first element and each subsequent element representing where the start of a new sequence of values will be in the output. The cumulative sum of the vector `index` can then be used to index into `a`, replicating each value the desired number of times.

For the sake of clarity, this is what the various vectors look like for the values of `a` and `b` given in the question:

``````        index = [1 0 1 0 1 1 0 0]
cumsum(index) = [1 1 2 2 3 4 4 4]
c = [1 1 3 3 2 5 5 5]
``````

EDIT: For the sake of completeness, there is another alternative using ARRAYFUN, but this seems to take anywhere from 20-100 times longer to run than the above solution with vectors up to 10,000 elements long:

``````c = arrayfun(@(x,y) x.*ones(1,y),a,b,'UniformOutput',false);
c = [c{:}];
``````
-
Thanks gnovice! This code is about 15x faster than what I had before. –  Doresoom Dec 29 '09 at 17:58
That's a cool way to do it and very vectorized. –  Alex Feinman Dec 29 '09 at 18:13

There is finally (as of R2015a) a built-in and documented function to do this, `repelem`. The following syntax, where the second argument is a vector, is relevant here:

`W = repelem(V,N)`, with vector `V` and vector `N`, creates a vector `W` where element `V(i)` is repeated `N(i)` times.

Or put another way, "Each element of `N` specifies the number of times to repeat the corresponding element of `V`."

Example:

``````>> a=[1,3,2,5]
a =
1     3     2     5
>> b=[2,2,1,3]
b =
2     2     1     3
>> repelem(a,b)
ans =
1     1     3     3     2     5     5     5
``````
-

## Benchmarks

Tested functions:

1. MATLAB's built-in `repelem` function that was added in R2015a
2. gnovice's `cumsum` solution (`rld_cumsum`)
3. Divakar's `cumsum`+`diff` solution (`rld_cumsum_diff`)
4. knedlsepp's `accumarray` solution (`knedlsepp5cumsumaccumarray`) from this post
5. Naive loop-based implementation (`naive_jit_test.m`) to test the just-in-time compiler

Results of `test_rld.m`:

Findings:

• `rld_cumsum_diff` is consistently faster than `rld_cumsum`.
• `repelem` is fastest for small data sizes (less than about 300-500 elements)
• `rld_cumsum_diff` becomes significantly faster than `repelem` around 5 000 elements
• `repelem` becomes slower than `rld_cumsum` somewhere between 30 000 and 300 000 elements (TODO: run this with more resolution since this seems to change a bit from trial-to-trial)
• `rld_cumsum` has roughly the same performance as `knedlsepp5cumsumaccumarray`
• `naive_jit_test.m` has nearly constant speed and on par with `rld_cumsum` and `knedlsepp5cumsumaccumarray`

Conclusion

Use `repelem` below about 5 000 elements and the `cumsum`+`diff` solution above.

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It would be nice to add the fastest function from this similar question here, namely `knedlsepp5cumsumaccumarray`. To be fair, it would have to be stripped down to `V = cumsum(accumarray(cumsum([1; runLengths(:)]), 1)); V = values(V(1:end-1));` (no checking etc). On my R2014b it's slower, though –  Luis Mendo Mar 16 at 21:56
@LuisMendo Added! :) –  chappjc Mar 16 at 23:39
@chappjc Thanks for adding JIT and knedlsepp's solutions! –  Divakar Mar 17 at 3:40
Seems like `for` will be sitting at the cool kids' table after all! –  knedlsepp Mar 17 at 9:58
@knedlsepp It almost pains me to write code like that in MATLAB, but that's shows how much it has improved... It's like writing in C. Very odd. –  chappjc Mar 17 at 15:24