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=round(rand(1,6)*10)`

:

```
tt = 3 7 1 7 1 7
```

Make a unique vector; `ttUNI=unique(tt)`

```
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
```

Here `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 `find`

.