In MATLAB, I have a
for loop which has a lot of interations to go through and fill a
sparse matrix. The program is very slow and I would like to optimize it to see it finish some time soon. In two lines I use the command
find, and the editor of MATLAB, warns me that the use of
logical indexing instead of
find will improve performace. My code is quite similar to that presented to the mathworks newreader, mathworks newsreader recommendation, where there is a vector of values and a vector of unique value generated from it. Uses
find to obtain the index in the unique values (for updating the values in a matrix). To be brief, the code given is:
positions = find(X0_outputs == unique_outputs(j,1)); % should read positions = X0_outputs == unique_outputs(j,1);
But the last line is not the index, but a vector of zeros and ones.
I have an illustrative example, make a set of indices;
tt = 3 7 1 7 1 7
Make a unique vector;
ttUNI = 1 3 7
Use find to get the position index of the value in the set of unique values;
find(ttUNI(:) == tt(1))
ans = 2
Compare with using logical indexing;
(ttUNI(:) == tt(1))
ans = 0 1 0
Having the value
2 is alot more useful than that binary vector when I need to update the indices for a matrix. For my matrix, I can say
mat(find(ttUNI(:) == tt(1)), 4) and that works. Whereas using
(ttUNI(:) == tt(1)) needs post processing.
Is there a neat and efficient way of doing what is needed? Or is the use of
find unavoidable in circumstances such as these?
UPDATE: I will include code here as recommended by user: @Jonas to give better insight into the problem which I am having and report some of the profiler tool's results.
ALL_NODES = horzcat(network(:,1)',network(:,2)'); NUM_UNIQUE = unique(ALL_NODES);%unique and sorted UNIQUE_LENGTH = length(NUM_UNIQUE); TIME_MAX = max(network(:,3)); WEEK_NUM = floor((((TIME_MAX/60)/60)/24)/7);%divide seconds for minutes, for hours, for days and how many weeks %initialize tensor of temporal networks temp = length(NUM_UNIQUE); %making the tensor a sparse 2D tensor!!! So each week is another replica of %the matrix below Atensor = sparse(length(NUM_UNIQUE)*WEEK_NUM,length(NUM_UNIQUE)); WEEK_SECONDS = 60*60*24*7;%number of seconds in a week for ii=1:size(network,1)%go through all rows/observations WEEK_NOW = floor(network(ii,3)/WEEK_SECONDS) + 1; if(WEEK_NOW > WEEK_NUM) disp('end of weeks') break end data_node_i = network(ii,1); Atensor_row_num = find(NUM_UNIQUE(:) == data_node_i)... + (WEEK_NOW-1)*UNIQUE_LENGTH; data_node_j = network(ii,2); Atensor_col_num = find(NUM_UNIQUE(:) == data_node_j); %Atensor is sparse Atensor(Atensor_row_num,Atensor_col_num) = 1; end
UNIQUE_LENGTH = 223482 and
size(network,1)=273209. I rand the
profiler tool for a few minutes, which was not enough time needed for the program to finish, but to reach a steady state when the ratio of times would not change too much.
Atensor_row_num = find(NUM_UNI.. is 45.6% and
Atensor_col_num = find(NUM_UNI... is 43.4%. The line with
Atensor(Atensor_row_num,Atenso... which allocates values to the
sparse matrix, is only 8.9%. The length of the
NUM_UNIQUE vector is quite large, so
find is an important aspect of the code; even more important than the sparse matrix manipulation. Any improvement here would be significant. I don't know if there is a more efficient logical progression for this algorithm to proceed as well rather than taking the straightforward approach of replacing