13

For clever usage of linear indexing or accumarray, I've sometimes felt the need to generate sequences based on run-length encoding. As there is no built-in function for this, I am asking for the most efficient way to decode a sequence encoded in RLE.

Specification:

As to make this a fair comparison I would like to set up some specifications for the function:

  • If optional second argument values of same length is specified, the output should be according to those values, otherwise just the values 1:length(runLengths).
  • Gracefully handle:
    • zeros in runLengths
    • values being a cell array.
  • Output vector should have same column/row format as runLengths

In short: The function should be equivalent to the following code:

function V = runLengthDecode(runLengths, values)
[~,V] = histc(1:sum(runLengths), cumsum([1,runLengths(:).']));
if nargin>1
    V = reshape(values(V), 1, []);
end
V = shiftdim(V, ~isrow(runLengths));
end

Examples:

Here are a few test cases

runLengthDecode([0,1,0,2])
runLengthDecode([0,1,0,4], [1,2,4,5].')
runLengthDecode([0,1,0,2].', [10,20,30,40])
runLengthDecode([0,3,1,0], {'a','b',1,2})

and their output:

>> runLengthDecode([0,1,0,2])
ans =
     2     4     4

>> runLengthDecode([0,1,0,4], [1,2,4,5].')
ans =    
     2     5     5     5     5

>> runLengthDecode([0,1,0,2].', [10,20,30,40])
ans =
    20
    40
    40

>> runLengthDecode([0,3,1,0],{'a','b',1,2})
ans = 
    'b'    'b'    'b'    [1]
28
  • 1
    It seems you just need to decorate this question's accepted answer with varargins.
    – Divakar
    Feb 13, 2015 at 14:16
  • 1
    Hm. Neither of the other questions really clarifies what is the fastest solution and most of them don't handle zeros correctly. So I'm not perfectly content with closing the question.
    – knedlsepp
    Feb 13, 2015 at 15:00
  • 1
    @LuisMendo: I've recently done a benchmarking-code for euclidean distances, so we could harvest it.
    – knedlsepp
    Feb 13, 2015 at 15:22
  • 1
    @LuisMendo: I'll just put on this and go into waiting mode. ;-)
    – knedlsepp
    Feb 15, 2015 at 17:04
  • 1
    @Daniel: I guess it was time to introduce repelem; finally.
    – knedlsepp
    Mar 15, 2015 at 21:41

4 Answers 4

6

To find out which one is the most efficient solution, we provide a test-script that evaluates the performance. The first plot depicts runtimes for growing length of the vector runLengths, where the entries are uniformly distributed with maximum length 200. A modification of gnovice's solution is the fastest, with Divakar's solution being second place. Speed comparison

This second plot uses nearly the same test data except it includes an initial run of length 2000. This mostly affects both bsxfun solutions, whereas the other solutions will perform quite similarly.

Speed comparison

The tests suggest that a modification of gnovice's original answer will be the most performant.


If you want to do the speed comparison yourself, here's the code used to generate the plot above.

function theLastRunLengthDecodingComputationComparisonYoullEverNeed()
Funcs =  {@knedlsepp0, ...
          @LuisMendo1bsxfun, ...
          @LuisMendo2cumsum, ...
          @gnovice3cumsum, ...
          @Divakar4replicate_bsxfunmask, ...
          @knedlsepp5cumsumaccumarray
          };    
%% Growing number of runs, low maximum sizes in runLengths
ns = 2.^(1:25);
paramGenerators{1} = arrayfun(@(n) @(){randi(200,n,1)}, ns,'uni',0);
paramGenerators{2} = arrayfun(@(n) @(){[2000;randi(200,n,1)]}, ns,'uni',0);
for i = 1:2
    times = compareFunctions(Funcs, paramGenerators{i}, 0.5);
    finishedComputations = any(~isnan(times),2);
    h = figure('Visible', 'off');
    loglog(ns(finishedComputations), times(finishedComputations,:));
    legend(cellfun(@func2str,Funcs,'uni',0),'Location','NorthWest','Interpreter','none');
    title('Runtime comparison for run length decoding - Growing number of runs');
    xlabel('length(runLengths)'); ylabel('seconds');
    print(['-f',num2str(h)],'-dpng','-r100',['RunLengthComparsion',num2str(i)]);
end
end

function times = compareFunctions(Funcs, paramGenerators, timeLimitInSeconds)
if nargin<3
    timeLimitInSeconds = Inf;
end
times = zeros(numel(paramGenerators),numel(Funcs));
for i = 1:numel(paramGenerators)
    Params = feval(paramGenerators{i});
    for j = 1:numel(Funcs)
        if max(times(:,j))<timeLimitInSeconds
            times(i,j) = timeit(@()feval(Funcs{j},Params{:}));
        else
            times(i,j) = NaN;
        end
    end
end
end
%% // #################################
%% // HERE COME ALL THE FANCY FUNCTIONS
%% // #################################
function V = knedlsepp0(runLengths, values)
[~,V] = histc(1:sum(runLengths), cumsum([1,runLengths(:).']));%'
if nargin>1
    V = reshape(values(V), 1, []);
end
V = shiftdim(V, ~isrow(runLengths));
end

%% // #################################
function V = LuisMendo1bsxfun(runLengths, values)
nn = 1:numel(runLengths);
if nargin==1 %// handle one-input case
    values = nn;
end
V = values(nonzeros(bsxfun(@times, nn,...
    bsxfun(@le, (1:max(runLengths)).', runLengths(:).'))));
if size(runLengths,1)~=size(values,1) %// adjust orientation of output vector
    V = V.'; %'
end
end

%% // #################################
function V = LuisMendo2cumsum(runLengths, values)
if nargin==1 %// handle one-input case
    values = 1:numel(runLengths);
end
[ii, ~, jj] = find(runLengths(:));
V(cumsum(jj(end:-1:1))) = 1;
V = values(ii(cumsum(V(end:-1:1))));
if size(runLengths,1)~=size(values,1) %// adjust orientation of output vector
    V = V.'; %'
end
end

%% // #################################
function V = gnovice3cumsum(runLengths, values)
isColumnVector =  size(runLengths,1)>1;
if nargin==1 %// handle one-input case
    values = 1:numel(runLengths);
end
values = reshape(values(runLengths~=0),1,[]);
if isempty(values) %// If there are no runs
    V = []; return;
end
runLengths = nonzeros(runLengths(:));
index = zeros(1,sum(runLengths));
index(cumsum([1;runLengths(1:end-1)])) = 1;
V = values(cumsum(index));
if isColumnVector %// adjust orientation of output vector
    V = V.'; %'
end
end
%% // #################################
function V = Divakar4replicate_bsxfunmask(runLengths, values)
if nargin==1   %// Handle one-input case
    values = 1:numel(runLengths);
end

%// Do size checking to make sure that both values and runlengths are row vectors.
if size(values,1) > 1
    values = values.'; %//'
end
if size(runLengths,1) > 1
    yes_transpose_output = false;
    runLengths = runLengths.'; %//'
else
    yes_transpose_output = true;
end

maxlen = max(runLengths);

all_values = repmat(values,maxlen,1);
%// OR all_values = values(ones(1,maxlen),:);

V = all_values(bsxfun(@le,(1:maxlen)',runLengths)); %//'

%// Bring the shape of V back to the shape of runlengths
if yes_transpose_output
    V = V.'; %//'
end
end
%% // #################################
function V = knedlsepp5cumsumaccumarray(runLengths, values)
isRowVector = size(runLengths,2)>1;
%// Actual computation using column vectors
V = cumsum(accumarray(cumsum([1; runLengths(:)]), 1));
V = V(1:end-1);
%// In case of second argument
if nargin>1
    V = reshape(values(V),[],1);
end
%// If original was a row vector, transpose
if isRowVector
    V = V.'; %'
end
end
18
  • Do you think it's a good idea to use feval within timeit? Won't that time affected by 'feval's overhead? I usually build an anonymous function or handle and feed that into timeit
    – Luis Mendo
    Feb 13, 2015 at 17:04
  • @LuisMendo: The performance difference is not measurable for me if compared to timeit(@()Funcs{j}(Params{:})), sometimes even feval is faster.
    – knedlsepp
    Feb 13, 2015 at 17:12
  • @LuisMendo: Great, I'll just add the resulting plot.
    – knedlsepp
    Feb 13, 2015 at 17:15
  • @knedlsepp We should perhaps add a version based on gnovice's approach. I can do that if you want (I don't want to keep throwing you things to do!), I mean write the function in the wiki answer.
    – Luis Mendo
    Feb 13, 2015 at 17:22
  • @LuisMendo: Ok, just tell me when you've got the code so I can regenerate the plot. I just quickly add my edit that exports the figure without need to open the matlab gui.
    – knedlsepp
    Feb 13, 2015 at 17:25
5

Approach 1

This should be reasonably fast. It uses bsxfun to create a matrix of size numel(runLengths)xnumel(runLengths), so it may not be suitable for huge input sizes.

function V = runLengthDecode(runLengths, values)
nn = 1:numel(runLengths);
if nargin==1 %// handle one-input case
    values = nn;
end
V = values(nonzeros(bsxfun(@times, nn,...
    bsxfun(@le, (1:max(runLengths)).', runLengths(:).'))));
if size(runLengths,1)~=size(values,1) %// adjust orientation of output vector
    V = V.';
end

Approach 2

This approach, based on cumsum, is an adaptation of that used in this other answer. It uses less memory than approach 1.

function V = runLengthDecode2(runLengths, values)
if nargin==1 %// handle one-input case
    values = 1:numel(runLengths);
end
[ii, ~, jj] = find(runLengths(:));
V(cumsum(jj(end:-1:1))) = 1;
V = values(ii(cumsum(V(end:-1:1))));
if size(runLengths,1)~=size(values,1) %// adjust orientation of output vector
    V = V.';
end
1
  • @knedlsepp Yes, gnovice's approach is probably faster
    – Luis Mendo
    Feb 13, 2015 at 16:59
5
+100

As of R2015a, the function repelem is the best choice to do this:

function V = runLengthDecode(runLengths, values)
if nargin<2
    values = 1:numel(runLengths);
end
V = repelem(values, runLengths);
end

For versions before R2015a this is a fast alternative:

Alternative to repelem:

I had the feeling gnovice's approach could be improved upon by using a better zero-runLength fix than the preprocessing mask. So I gave accumarray a shot. It seems this gives the solution yet another boost:

function V = runLengthDecode(runLengths, values)
%// Actual computation using column vectors
V = cumsum(accumarray(cumsum([1; runLengths(:)]), 1));
V = V(1:end-1);
%// In case of second argument
if nargin>1
    V = reshape(values(V),[],1);
end
%// If original was a row vector, transpose
if size(runLengths,2)>1
    V = V.'; %'
end
end
5
  • 2
    Looks promising indeed from the new runtime plots!
    – Divakar
    Feb 21, 2015 at 18:55
  • @LuisMendo: Well, thanks for all the internet coins then! :-)
    – knedlsepp
    Feb 22, 2015 at 17:50
  • @LuisMendo: It seems it wasn't enough incentive for anybody else to add their solutions though...
    – knedlsepp
    Feb 22, 2015 at 17:56
  • 1
    @knedlsepp Well, Divakar did contribute, and the question has been viewed over 250 times! :-)
    – Luis Mendo
    Feb 22, 2015 at 18:08
  • @LuisMendo: Oh yeah, forgot you set the bounty before Divakar joined in.
    – knedlsepp
    Feb 22, 2015 at 18:44
4

The solution presented here basically does the run-length decoding in two steps -

  1. Replicate all values upto the maximum number of runLengths.
  2. Use bsxfun's masking capability to select from each column the corresponding runlengths.

Rest of the stuffs inside the function code are to take care of the input and output sizes to satisfy the requirements set in the question.

The function code listed next would be a "cleaned-up" version of one of my previous answers to a similar problem. Here's the code -

function V = replicate_bsxfunmask(runLengths, values)

if nargin==1   %// Handle one-input case
    values = 1:numel(runLengths);
end

%// Do size checking to make sure that both values and runlengths are row vectors.
if size(values,1) > 1
    values = values.'; %//'
end
if size(runLengths,1) > 1
    yes_transpose_output = false;
    runLengths = runLengths.'; %//'
else
    yes_transpose_output = true;
end

maxlen = max(runLengths);

all_values = repmat(values,maxlen,1);
%// OR all_values = values(ones(1,maxlen),:);

V = all_values(bsxfun(@le,(1:maxlen)',runLengths)); %//'

%// Bring the shape of V back to the shape of runlengths
if yes_transpose_output
    V = V.'; %//'
end

return;

The code listed next would be a hybrid (cumsum + replicate_bsxfunmask) and would be suitable when you have a good number of outliers or really huge outliers. Also to keep it simple, for now this works on numeric arrays only. Here's the implementation -

function out = replicate_bsxfunmask_v2(runLengths, values)

if nargin==1                       %// Handle one-input case
    values = 1:numel(runLengths);
end

if size(values,1) > 1
    values = values.';  %//'
end

if size(runLengths,1) > 1
    yes_transpose_output = true;
    runLengths = runLengths.';  %//'
else
    yes_transpose_output = false;
end

%// Regularize inputs
values = values(runLengths>0);
runLengths = runLengths(runLengths>0);

%// Main portion of code
thresh = 200; %// runlengths threshold that are to be processed with cumsum

crunLengths = cumsum(runLengths); %%// cumsums of runlengths
mask = runLengths >= thresh; %// mask of runlengths above threshold
starts = [1 crunLengths(1:end-1)+1]; %// starts of each group of runlengths

mask_ind = find(mask); %// indices of mask

post_mark = starts(mask);
negt_mark = crunLengths(mask)+1;

if  ~isempty(negt_mark) && negt_mark(end) > crunLengths(end)
    negt_mark(end) = [];
end

%// Create array & set starts markers for starts of runlengths above thresh
marked_out = zeros(1,crunLengths(end));
marked_out(post_mark) = mask_ind;
marked_out(negt_mark) = marked_out(negt_mark) -1*mask_ind(1:numel(negt_mark));

%// Setup output array with the cumsumed version of marked array
out = cumsum(marked_out);

%// Mask for final ouput to decide between large and small runlengths
thresh_mask = out~=0;

%// Fill output array with cumsum and then rep-bsxfun based approaches
out(thresh_mask) = values(out(thresh_mask));

values = values(~mask);
runLengths = runLengths(~mask);

maxlen = max(runLengths);
all_values = repmat(values,maxlen,1);
out(~thresh_mask) = all_values(bsxfun(@le,(1:maxlen)',runLengths)); %//'

if yes_transpose_output
    out = out.';  %//'
end

return;
5
  • I was expecting an answer from you! Great job, very fast!
    – Luis Mendo
    Feb 15, 2015 at 22:13
  • Perhaps you could save some time by using the trick you suggested regarding Gnovices' approach? That is, use only the non-zero values of runLengths. That way you would avoid all-zero columns in bsxfun(@le,(1:maxlen)',runLengths). Not sure it that would speed or slow things, though
    – Luis Mendo
    Feb 16, 2015 at 10:55
  • 1
    This is good code until memory becomes an issue, or there are large outliers in the runlengths as pointed out by @knedlsepp... You can mitigate this by checking max array size left with memory then blocklooping over blocks of size: max array divided by max runlength... I've implemented the solution if anyone cares, I could post it if necessary. There could even be ways of adaptively blocklooping in function of the maximum runlength in the next block which would be computationally very efficient I think and even smarter, but no time to explore that... Feb 16, 2015 at 11:38
  • 1
    @reverse_engineer Well I did try with a hybrid approach (cumsum + replicate_bsxfunmask) and the runtimes seemed to be really bad, still I have added that here. Still, would be interesting to see what you have in mind, so maybe post what you tried?
    – Divakar
    Feb 17, 2015 at 5:13
  • @LuisMendo Well I did try with a hybrid approach (cumsum + replicate_bsxfunmask) and the runtimes seemed to be really bad, at least for the original data-generated model of randi(200,n,1), still have added that here!
    – Divakar
    Feb 17, 2015 at 5:13

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