One solution is to replicate the row indices in
labels and add another column of column indices. Then you can reshape
X into a column vector and apply
labels = [repmat(labels(:),nCols,1) ... % Replicate the row indices
kron(1:nCols,ones(1,numel(labels))).']; % Create column indices
totals = accumarray(labels,X(:)); % I used "totals" instead of "means"
How it works...
A = accumarray(subs,val) for a column vector
subs and vector
val works by adding the number in
val(i) to the total in row
subs(i) in the output column vector
subs can contain more than just row indices. It can contain subscript indices for multiple dimensions to assign values to in the output. This feature is what allows you to handle an input
val that is a matrix instead of a vector.
First, the input for
val can be reshaped into a column vector using the colon operator
X(:). Next, in order to keep track of which column in the output the values in
X(:) should be placed, we can modify the input
subs to include an additional column index. To illustrate how this works, I'll use these sample inputs:
labels = [3; 1; 1];
X = [1 2 3; ...
4 5 6; ...
7 8 9];
nCols = 3
And here are what the variables in the above code end up looking like:
labels = 3 1 X(:) = 1 totals = 11 13 15
1 1 4 0 0 0
1 1 7 1 2 3
3 2 2
1 2 5
1 2 8
3 3 3
1 3 6
1 3 9
Notice, for example, that the values
1 4 7 that were originally in the first column of
X will only be accumulated in the first column of the output, as denoted by the ones in the first three rows of the second column of
labels. The resulting output should be the same as what you would have gotten by using the code in the question where you loop over each column to perform the accumulation.