# Time series aggregation efficiency

I commonly need to summarize a time series with irregular timing with a given aggregation function (i.e., sum, average, etc.). However, the current solution that I have seems inefficient and slow.

Take the aggregation function:

``````function aggArray = aggregate(array, groupIndex, collapseFn)

groups = unique(groupIndex, 'rows');
aggArray = nan(size(groups, 1), size(array, 2));

for iGr = 1:size(groups,1)
grIdx = all(groupIndex == repmat(groups(iGr,:), [size(groupIndex,1), 1]), 2);
for iSer = 1:size(array, 2)
aggArray(iGr,iSer) = collapseFn(array(grIdx,iSer));
end
end

end
``````

Note that both `array` and `groupIndex` can be 2D. Every column in `array` is an independent series to be aggregated, but the columns of `groupIndex` should be taken together (as a row) to specify a period.

Then when we bring an irregular time series to it (note the second period is one base period longer), the timing results are poor:

``````a = rand(20006,10);
b = transpose([ones(1,5) 2*ones(1,6) sort(repmat((3:4001), [1 5]))]);

tic; aggregate(a, b, @sum); toc
Elapsed time is 1.370001 seconds.
``````

Using the profiler, we can find out that the `grpIdx` line takes about 1/4 of the execution time (.28 s) and the `iSer` loop takes about 3/4 (1.17 s) of the total (1.48 s).

Compare this with the period-indifferent case:

``````tic; cumsum(a); toc
Elapsed time is 0.000930 seconds.
``````

Is there a more efficient way to aggregate this data?

## Timing Results

Taking each response and putting it in a separate function, here are the timing results I get with `timeit` with Matlab 2015b on Windows 7 with an Intel i7:

``````    original | 1.32451
felix1 | 0.35446
felix2 | 0.16432
divakar1 | 0.41905
divakar2 | 0.30509
divakar3 | 0.16738
matthewGunn1 | 0.02678
matthewGunn2 | 0.01977
``````

## Clarification on `groupIndex`

An example of a 2D `groupIndex` would be where both the year number and week number are specified for a set of daily data covering 1980-2015:

``````a2 = rand(36*52*5, 10);
b2 = [sort(repmat(1980:2015, [1 52*5]))' repmat(1:52, [1 36*5])'];
``````

Thus a "year-week" period are uniquely identified by a row of `groupIndex`. This is effectively handled through calling `unique(groupIndex, 'rows')` and taking the third output, so feel free to disregard this portion of the question.

• For each group, your code has to do a bunch of crap that's O(n) where n is size of whole data matrix. The line `grIdx = all(groupIndex == repmat(groups(iGr,:), [size(groupIndex,1), 1]), 2);` isn't going to be fast. I struggled with a similar problem: I had a matrix of data and a column vector signifying which group a row (of the data matrix) was a member of. For each group, I wanted to pull the group's data and do some calculations. I ended up writing a mex function in c++ that returned a cell array showing which group had data on which rows. Nov 10, 2015 at 18:33
• If groupIndex is just a column vector, there's possibly some mex c++ code I could post that you might find useful. It takes a groupIndex vector and for each group, shows what rows of groupIndex that group is on. Nov 10, 2015 at 18:50
• @MatthewGunn It'd be a start. But it won't replace the inner for-loop though, will it? I see the `grIdx` line as a definite part of the problem, but a good chunk of the execution time is spent on it `iSer` loop. Nov 10, 2015 at 19:19
• As long as each group has at least two observations, you could possibly replace that with: aggArray(iGr,:) = collapseFn(array(grIdx,:)) That would work with a lot of collapse functions like mean etc... but yeah, it's not as robust Nov 10, 2015 at 19:35
• I was doing that until I started getting weird errors and added that. Might be worth adding an if statement for that. I'll have to check what the profiler says. Nov 10, 2015 at 19:46

Method #1

You can create the mask corresponding to `grIdx` across all `groups` in one go with `bsxfun(@eq,..)`. Now, for `collapseFn` as `@sum`, you can bring in `matrix-multiplication` and thus have a completely vectorized approach, like so -

``````M = squeeze(all(bsxfun(@eq,groupIndex,permute(groups,[3 2 1])),2))
aggArray = M.'*array
``````

For `collapseFn` as `@mean`, you need to do a bit more work, as shown here -

``````M = squeeze(all(bsxfun(@eq,groupIndex,permute(groups,[3 2 1])),2))
aggArray = bsxfun(@rdivide,M,sum(M,1)).'*array
``````

Method #2

In case you are working with a generic `collapseFn`, you can use the 2D mask `M` created with the previous method to index into the rows of `array`, thus changing the complexity from `O(n^2)` to `O(n)`. Some quick tests suggest this to give appreciable speedup over the original loopy code. Here's the implementation -

``````n = size(groups,1);
M = squeeze(all(bsxfun(@eq,groupIndex,permute(groups,[3 2 1])),2));
out = zeros(n,size(array,2));
for iGr = 1:n
out(iGr,:) = collapseFn(array(M(:,iGr),:),1);
end
``````

Please note that the `1` in `collapseFn(array(M(:,iGr),:),1)` denotes the dimension along which `collapseFn` would be applied, so that `1` is essential there.

Bonus

By its name `groupIndex` seems like would hold integer values, which could be abused to have a more efficient `M` creation by considering each row of `groupIndex` as an indexing tuple and thus converting each row of `groupIndex` into a scalar and finally get a 1D array version of `groupIndex`. This must be more efficient as the datasize would be `0(n)` now. This `M` could be fed to all the approaches listed in this post. So, we would have `M` like so -

``````dims = max(groupIndex,[],1);
agg_dims = cumprod([1 dims(end:-1:2)]);
[~,~,idx] = unique(groupIndex*agg_dims(end:-1:1).'); %//'

m = size(groupIndex,1);
M = false(m,max(idx));
M((idx-1)*m + [1:m]') = 1;
``````
• clever. Big downside, it's specific to sum. mean would be easy too. I don't think this approach would work though for median, max, etc... Nov 12, 2015 at 21:37
• Yeah, it's specific to `sum` and `average` really. Nov 12, 2015 at 21:59
• @MatthewGunn Oh wait, just made it generic! Nov 13, 2015 at 7:14

## Mex Function 1

HAMMER TIME: Mex function to crush it: The base case test with original code from the question took 1.334139 seconds on my machine. IMHO, the 2nd fastest answer from @Divakar is:

``````groups2 = unique(groupIndex);
aggArray2 = squeeze(all(bsxfun(@eq,groupIndex,permute(groups,[3 2 1])),2)).'*array;
``````

Elapsed time is 0.589330 seconds.

Then my MEX function:

``````[groups3, aggArray3] = mg_aggregate(array, groupIndex, @(x) sum(x, 1));
``````

Elapsed time is 0.079725 seconds.

Testing that we get the same answer: `norm(groups2-groups3)` returns `0` and `norm(aggArray2 - aggArray3)` returns `2.3959e-15`. Results also match original code.

Code to generate the test conditions:

``````array = rand(20006,10);
groupIndex = transpose([ones(1,5) 2*ones(1,6) sort(repmat((3:4001), [1 5]))]);
``````

For pure speed, go mex. If the thought of compiling c++ code / complexity is too much of a pain, go with Divakar's answer. Another disclaimer: I haven't subject my function to robust testing.

### Mex Approach 2

Somewhat surprising to me, this code appears even faster than the full Mex version in some cases (eg. in this test took about .05 seconds). It uses a mex function mg_getRowsWithKey to figure out the indices of groups. I think it may be because my array copying in the full mex function isn't as fast as it could be and/or overhead from calling 'feval'. It's basically the same algorithmic complexity as the other version.

``````[unique_groups, map] = mg_getRowsWithKey(groupIndex);

results = zeros(length(unique_groups), size(array,2));

for iGr = 1:length(unique_groups)
array_subset             = array(map{iGr},:);

%// do your collapse function on array_subset. eg.
results(iGr,:)           = sum(array_subset, 1);
end
``````

When you do `array(groups(1)==groupIndex,:)` to pull out array entries associated with the full group, you're searching through the ENTIRE length of groupIndex. If you have millions of row entries, this will totally suck. `array(map{1},:)` is far more efficient.

There's still unnecessary copying of memory and other overhead associated with calling 'feval' on the collapse function. If you implement the aggregator function efficiently in c++ in such a way to avoid copying of memory, probably another 2x speedup can be achieved.

• An attribution for the `2nd fastest answer` would be nice I think. Nov 13, 2015 at 11:48
• How do you do that? Just @? Nov 13, 2015 at 11:51
• You ned to have the @(x) sum(x, 1) in there to get dimensions right. Yeah, should take any collapse function that returns double array of right dimensions. It's called with: `rhs = const_cast<mxArray *>(collapse_fn); rhs = group_j_array; mexCallMATLAB(1,&lhs,2,rhs,"feval");` Nov 13, 2015 at 11:58
• @Divakar is the master at `bsxfun/permute`. His answers using pure MATLAB syntax (i.e. just using `bsxfun/permute` etc.) are amongst the fastest I've seen... as competitive as writing your own MEX code. Nov 13, 2015 at 19:45
• Neat alternative for `accumarray` for the matrix case. And I honestly hadn't considered you could pass anonymous functions to MEX! Nov 24, 2015 at 7:23

A little late to the party, but a single loop using `accumarray` makes a huge difference:

``````function aggArray = aggregate_gnovice(array, groupIndex, collapseFn)

[groups, ~, index] = unique(groupIndex, 'rows');
numCols = size(array, 2);
aggArray = nan(numel(groups), numCols);
for col = 1:numCols
aggArray(:, col) = accumarray(index, array(:, col), [], collapseFn);
end

end
``````

Timing this using `timeit` in MATLAB R2016b for the sample data in the question gives the following:

``````original | 1.127141
gnovice | 0.002205
``````

Over a 500x speedup!

Doing away with the inner loop, i.e.

``````function aggArray = aggregate(array, groupIndex, collapseFn)

groups = unique(groupIndex, 'rows');
aggArray = nan(size(groups, 1), size(array, 2));

for iGr = 1:size(groups,1)
grIdx = all(groupIndex == repmat(groups(iGr,:), [size(groupIndex,1), 1]), 2);
aggArray(iGr,:) = collapseFn(array(grIdx,:));
end
``````

and calling the collapse function with a dimension parameter

``````res=aggregate(a, b, @(x)sum(x,1));
``````

gives some speedup (3x on my machine) already and avoids the errors e.g. sum or mean produce, when they encounter a single row of data without a dimension parameter and then collapse across columns rather than labels.

If you had just one group label vector, i.e. same group labels for all columns of data, you could speed further up:

``````function aggArray = aggregate(array, groupIndex, collapseFn)

ng=max(groupIndex);
aggArray = nan(ng, size(array, 2));

for iGr = 1:ng
aggArray(iGr,:) = collapseFn(array(groupIndex==iGr,:));
end
``````

The latter functions gives identical results for your example, with a 6x speedup, but cannot handle different group labels per data column.

Assuming a 2D test case for the group index (provided here as well with 10 different columns for groupIndex:

``````a = rand(20006,10);
B=[]; % make random length periods for each of the 10 signals
for i=1:size(a,2)
n0=randi(10);
b=transpose([ones(1,n0) 2*ones(1,11-n0) sort(repmat((3:4001), [1 5]))]);
B=[B b];
end
tic; erg0=aggregate(a, B, @sum); toc % original method
tic; erg1=aggregate2(a, B, @(x)sum(x,1)); toc %just remove the inner loop
tic; erg2=aggregate3(a, B, @(x)sum(x,1)); toc %use function below
``````

Elapsed time is 2.646297 seconds. Elapsed time is 1.214365 seconds. Elapsed time is 0.039678 seconds (!!!!).

``````function aggArray = aggregate3(array, groupIndex, collapseFn)

[groups,ix1,jx] = unique(groupIndex, 'rows','first');
[groups,ix2,jx] = unique(groupIndex, 'rows','last');

ng=size(groups,1);
aggArray = nan(ng, size(array, 2));

for iGr = 1:ng
aggArray(iGr,:) = collapseFn(array(ix1(iGr):ix2(iGr),:));
end
``````

I think this is as fast as it gets without using MEX. Thanks to the suggestion of Matthew Gunn! Profiling shows that 'unique' is really cheap here and getting out just the first and last index of the repeating rows in groupIndex speeds things up considerably. I get 88x speedup with this iteration of the aggregation.

• Ooops, I almost missed this reading the code... An IMPORTANT subtle/clever point is that Felix passed @(x) sum(x,1) as the aggregation function! If you don't do that, BAD things can happen! This code: `collapseFn(array(grIdx,:))` would not do what's intended if array(grldx,:) is a 1 row matrix and the coallpseFn were simply `sum`. Eg. this code would want `sum([1, 3, 5])` to return `[1 3 5]` BUT what will get returned is `9` Nov 10, 2015 at 21:39
• As a solution to the group label vector issue, you can take the 3rd output from `unique` called row-wise to get a vector. Nov 12, 2015 at 14:57

Well I have a solution that is almost as quick as the mex but only using matlab. The logic is the same as most of the above, creating a dummy 2D matrix but instead of using @eq I initialize a logical array from the start.

Elapsed time for mine is 0.172975 seconds. Elapsed time for Divakar 0.289122 seconds.

``````function aggArray = aggregate(array, group, collapseFn)
[m,~] = size(array);
n = max(group);
D = false(m,n);
row = (1:m)';
idx = m*(group(:) - 1) + row;
D(idx) = true;
out = zeros(m,size(array,2));
for ii = 1:n
out(ii,:) = collapseFn(array(D(:,ii),:),1);
end
end
``````