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Basically, I have a large object that I want to perform some function on, that lends itself well to parallel processing. In this example, I have a large matrix and I want to compute all pairwise inner products between column vectors.

Please take a look at the following IPython Notebook.

I realise that the @interactive decorator is not necessary in this context and I tried removing the @require decorator but its impact is negligible.

My question is: Is there any way available to improve the performance of the parallel machinery?

I don't know the implementation details of the map methods, could I avoid overhead by pushing the function that is executed in parallel to the engines in the view? I can't imagine that it is sent with every argument, though.

Chunking the argument list myself and writing a function for remote use that works on that seems silly as well.

I tried the notebook on a four core machine and the results in the notebook are for a two core machine.

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up vote 1 down vote accepted

The main performance issue here is that the fortran-contiguous optimization you applied does not survive the network transfer, so mat on the engines is C-contiguous, not F-contiguous after the push.

You can see this with:

print mat.flags
%px print mat.flags


%px mat = numpy.asfortranarray(mat)

Should get your performance back (as illustrated in my tweaked version of your notebook).

For diagnosing this issue, I did my best to isolate where the bottlenecks were. Useful for this were the AsyncResult.serial_time and AsyncResult.wall_time. When the serial_time is long, that means the task is actually taking a long time on the engines, rather than spending lots of time in the IPython pipes. That led me to think that the task itself was slow on the engines, so I did the task remotely on one engine, and it was still slow (nothing parallel involved). Here's a notebook tracking down the issue.

Side note:

The @interactive decorator is only necessary for functions that are not interactively defined (i.e. module functions, not functions defined in the notebook), so it's redundant in your notebook.

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Awesome, thank you for your time and effort. I didn't even remotely think that the memory layout could change. – Midnighter Feb 19 '13 at 19:19
For zero-copy sends of arrays, IPython requires that they be contiguous. To do this, IPython uses ascontiguousarray, which actually ends up coercing F-contiguous arrays to C-contiguous, even though it probably doesn't need to (it may sometimes, depending on slicing). I will look into what would be involved in zero-copy send of F-contiguous arrays to avoid this weird case. – minrk Feb 19 '13 at 20:43

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