I'm working on a MATLAB implementation of an adaptive Matrix-Vector Multiplication for very large sparse matrices coming from a particular discretisation of a PDE (with known sparsity structure).

After a lot of pre-processing, I end up with a number of different blocks (greater than, say, 200), for which I want to calculate selected entries.

One of the pre-processing steps is to determine the (number of) entries per block I want to calculate, which gives me an almost perfect measure of the amount of time each block will take (for all intents and purposes the quadrature effort is the same for each entry).

Thanks to http://stackoverflow.com/a/9938666/2965879, I was able to make use of this by ordering the blocks in reverse order, thus goading MATLAB into starting with the biggest ones first.

However, the number of entries differs so wildly from block to block, that directly running parfor is limited severely by the blocks with the largest number of entries, even if they are fed into the loop in reverse.

My solution is to do the biggest blocks serially (but parallelised on the level of entries!), which is fine as long as the overhead per iterand doesn't matter too much, resp. the blocks don't get too small. The rest of the blocks I then do with parfor. Ideally, I'd let MATLAB decide how to handle this, but since a nested parfor-loop loses its parallelism, this doesn't work. Also, packaging both loops into one is (nigh) impossible.

My question now is about how to best determine this cut-off between the serial and the parallel regime, taking into account the information I have on the number of entries (the shape of the curve of ordered entries may differ for different problems), as well as the number of workers I have available.

So far, I had been working with the 12 workers available under a the standard PCT license, but since I've now started working on a cluster, determining this cut-off becomes more and more crucial (since for many cores the overhead of the serial loop becomes more and more costly in comparison to the parallel loop, but similarly, having blocks which hold up the rest are even more costly).

For 12 cores (resp. the configuration of the compute server I was working with), I had figured out a reasonable parameter of 100 entries per worker as a cut off, but this doesn't work well when the number of cores isn't small anymore in relation to the number of blocks (e.g 64 vs 200).

I've tried to deflate the number of cores with different powers (e.g. 1/2, 3/4), but this also doesn't work consistently. Next I tried to group the blocks into batches and determine the cut-off when entries are larger than the mean per batch, resp. the number of batches they are away from the end:

```
logical_sml = true(1,num_core); i = 0;
while all(logical_sml)
i = i+1;
m = mean(num_entr_asc(1:min(i*num_core,end))); % "asc" ~ ascending order
logical_sml = num_entr_asc(i*num_core+(1:num_core)) < i^(3/4)*m;
% if the small blocks were parallelised perfectly, i.e. all
% cores take the same time, the time would be proportional to
% i*m. To try to discount the different sizes (and imperfect
% parallelisation), we only scale with a power of i less than
% one to not end up with a few blocks which hold up the rest
end
num_block_big = num_block - (i+1)*num_core + sum(~logical_sml);
```

(Note: This code doesn't work for vectors `num_entr_asc`

whose length is not a multiple of `num_core`

, but I decided to omit the `min(...,end)`

constructions for legibility.)

I've also omitted the `< max(...,...)`

for combining both conditions (i.e. together with minimum entries per worker), which is necessary so that the cut-off isn't found too early. I thought a little about somehow using the variance as well, but so far all attempts have been unsatisfactory.

I'd be very grateful if someone has a good idea for how to solve this.

Thanks for reading this very long question,

Best regards,

Axel

Ps. Since my "Dear stackoverflow," seems to be filtered, let me say thanks for the numerous times I've already found the solution to a question of mine here.