Assume that there is a function f that determines the results of a set of n embarrassingly parallel computations, and immediately terminates upon finding the answer to the last problem. Each of the n processes takes some non-negligable amount of time unique to that process, and there is a perfect linear correlation between time spent on a computation and work done during that computation.

In more math-y terms, every ith parallelized subproblem n_i takes time t_i to terminate, and each t_i is unique to each parallelized subproblem.

Given those conditions and an infinite number of processors, it is easy to see that the total runtime of the algorithm is exactly max(t). However, the computers people program on have a bounded number of processors p, after which introducing any more subprocesses overwhelms the realistic system and actually increases the total running time of f.

My question is - given this practical scenario where the number of subprocesses is bounded by p - what is the fastest algorithm that can determine how to optimally schedule the set of parallelized subproblems n across the p processors in order to minimize the total runtime of the function f?

  • Sounds like the bin packing problem. – stark Aug 1 '17 at 20:03

Thanks to stark's comment about the bin packing problem, I found that this problem actually has a name! It's called, quite sensibly, the Multiprocessor Scheduling Problem. As I suspected, it's in NP, which means there's no efficient algorithm for solving it. That's quite unfortunate news in the context of the application I'm programming at the moment, but useful to know nonetheless!

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