Let's assume I have the following 9 x 5 matrix:

```
myArray = [
54.7 8.1 81.7 55.0 22.5
29.6 92.9 79.4 62.2 17.0
74.4 77.5 64.4 58.7 22.7
18.8 48.6 37.8 20.7 43.5
68.6 43.5 81.1 30.1 31.1
18.3 44.6 53.2 47.0 92.3
36.8 30.6 35.0 23.0 43.0
62.5 50.8 93.9 84.4 18.4
78.0 51.0 87.5 19.4 90.4
];
```

I have 11 "subsets" of this matrix and I need to run a function (let's say `max`

) on each of these subsets. The subsets can be identified with the following matirx of logicals (identified column-wise, not row-wise):

```
myLogicals = logical([
0 1 0 1 1
1 1 0 1 1
1 1 0 0 0
0 1 0 1 1
1 0 1 1 1
1 1 1 1 0
0 1 1 0 1
1 1 0 0 1
1 1 0 0 1
]);
```

or via linear indexing:

```
starts = [2 5 8 10 15 23 28 31 37 40 43]; #%index start of each subset
ends = [3 6 9 13 18 25 29 33 38 41 45]; #%index end of each subset
```

such that the first subset is 2:3, the second is 5:6, and so on.

I can find the `max`

of each subset and store it in a vector as follows:

```
finalAnswers = NaN(11,1);
for n=1:length(starts) #%i.e. 1 through the number of subsets
finalAnswers(n) = max(myArray(starts(n):ends(n)));
end
```

After the loop runs, `finalAnswers`

contains the maximum value of each of the data subsets:

```
74.4 68.6 78.0 92.9 51.0 81.1 62.2 47.0 22.5 43.5 90.4
```

Is it possible to obtain the same result without the use of a `for`

loop? In other words, can this code be vectorized? Would such an approach be more efficient than the current one?

EDIT: I did some testing of the proposed solutions. The data I used was a 1,510 x 2,185 matrix with 10,103 subsets that varied in length from 2 to 916 with a standard deviation of subset length of 101.92.

I wrapped each solution in `tic;for k=1:1000 [code here] end; toc;`

and here are the results:

`for`

loop approach ---`Elapsed time is 16.237400 seconds.`

- Shai's approach ---
`Elapsed time is 153.707076 seconds.`

- Dan's approach ---
`Elapsed time is 44.774121 seconds.`

- Divakar's approach #2 ---
`Elapsed time is 127.621515 seconds.`

Notes:

- I also tried benchmarking Dan's approach by wrapping the
`k=1:1000 for`

loop around just the`accumarray`

line (since the rest could be theoretically run just once). In this case the time was 28.29 seconds. - Benchmarking Shai's approach, while leaving the
`lb = ...`

line out of the`k`

loop, the time was 113.48 seconds. - When I ran Divakar's code, I got
`Non-singleton dimensions of the two input arrays must match each other.`

errors for the`bsxfun`

lines. I "fixed" this by using conjugate transposition (the apostrophe operator`'`

) on`trade_starts(1:starts_extent)`

and`intv(1:starts_extent)`

in the lines of code calling`bsxfun`

. I'm not sure why this error was occuring...

I'm not sure if my benchmarking setup is correct, but it appears that the `for`

loop actually runs the fastest in this case.

`myLogicals`

from`starts`

and`ends`

or is it there just like`starts`

and`ends`

or maybe the other way around? – Divakar Sep 29 '14 at 15:05. – Divakar Sep 29 '14 at 18:31`gpuArrays`

`myLogicals`

first and then get`starts`

and`ends`

from that. Question 2: I do have access to a relatively powerful GPU (680 GTX), but I am completely unfamiliar with`gpuArrays`

. Do you happen to have a link to a good source online where I could learn more? This sounds really interesting – Alarik Sep 30 '14 at 0:02`"10,103 subsets that varied in length from 2 to 916 with a standard deviation of subset length of 101.92"`

. Is that your actual data or you are just doing that to benchmark the solutions. Vectorization yields good result when you are working with large data chunk of homogeneous data, but with such a high value of standard deviation -`101.92`

, it's just not suitable for vectorization techniques and as such for-loop would always be the best solution. – Divakar Sep 30 '14 at 3:42`starts`

and`ends`

to have sorted data and there mustn't be any overlap between two subsets. Are these criteria maintained? – Divakar Sep 30 '14 at 3:56