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As the title states, what is the overhead of the different forms of parallelism, at least in the current implementation of Julia (v0.5, in case the implementation changes drastically in the future)? I am looking for some "practical measures", some general heuristics or ballparks to keep in my head for when it can be useful. For example, it's pretty obvious that multiprocessing won't give you gains in a loop like:

addprocs(4)
@parallel (+) for i=1:4
  rand()
end

doesn't give you performance gains because each process is only taking one random number, but is there general heuristic for knowing when it will be worthwhile? Also, what about a heuristic for threading. It's surely a lower overhead than multiprocessing, but for example, with 4 threads, for what N is it a good idea to multithread:

A = rand(4)
Base.@threads (+) for i = 1:N
  A[i%4+1] 
end

(I know there isn't a threaded reduction right now, but let's act like there is, or edit with a better example). Sure, I can benchmark every example, but some good rules to keep in mind would go a long way.

In more concrete terms: what are some good rules of thumb?

  • How many numbers do you need to be adding/multiplying before threading gives performance enhancements, or before multiprocessing gives performance enhancements?
  • How much does the depend on Julia's current implementation?
  • How much does it depend on the number of threads/processes?
  • How much does the depend on the architecture? Are there good rules for knowing when the threshold should be higher/lower on a particular system?
  • What kinds of applications violate these heuristics?

Again, I'm not looking for hard rules, just general guidelines to guide development.

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  • You should be able to measure this yourself relatively easily. Details left to OP.
    – Ira Baxter
    Oct 4, 2016 at 4:07

1 Answer 1

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A few caveats: 1. I'm speaking from experience with version 0.4.6, (and prior), haven't played with 0.5 yet (but, as I hope my answer below demonstrates, I don't think this is essential vis-a-vis the response I give). 2. this isn't a fully comprehensive answer.

Nevertheless, from my experience, the overhead for multiple processes itself is very small provided that you aren't dealing with data movement issues. In other words, in my experience, any time that you ever find yourself in a situation of wishing something were faster than a single process on your CPU can manage, you're well past the point where parallelism will be beneficial. For instance, in the sum of random numbers example that you gave, I found through testing just now that the break-even point was somewhere around 10,000 random numbers. Anything more and parallelism was the clear winner. Generating 10,000 random number is trivial for modern computers, taking a tiny fraction of a second, and is well below the threshold where I'd start getting frustrated by the slowness of my scripts and want parallelism to speed them up.

Thus, I at least am of the opinion, that although there are probably even more wonderful things that the Julia developers could do to cut down on the overhead even more, at this point, anything pertinent to Julia isn't going to be so much of your limiting factor, at least in terms of the computation aspects of parallelism. I think that there are still improvements to be made in terms of enhancing both the ease and the efficiency of parallel data movement (I like the package that you've started on that topic as a good step. You and I would probably both agree there's still a ways more to go). But, the big limiting factors will be:

  1. How much data do you need to be moving around between processes?
  2. How much read/write to your memory do you need to be doing during your computations? (e.g. flops per read/write)

Aspect 1. might at times lean against using parallelism. Aspect 2. is more likely just to mean that you won't get so much benefit from it. And, at least as I interpret "overhead," neither of these really fall so directly into that specific consideration. And, both of these are, I believe, going to be far more heavily determined by your system hardware than by Julia.

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  • @ChrisRackauckas I'm not really sure, I haven't played with threads in Julia yet, since they're just coming online. Generally, threads are even lighter than processes, but I'll let those who are more familiar with them in a Julia context fill in more details. Aug 8, 2016 at 4:19
  • Do you have any good examples to back this up? This seems to give a number for while a parallel reduction (+) gets gains, proof? (Sometimes that's hard to make because the compiler optimizes away easy examples...). What about when using SharedArrays, where does this break-even point land at? (BTW, I'm doing some work on benchmarking this as well, just trying to find out what others are getting) Aug 8, 2016 at 15:33

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