I tested the performance gain of parallelizing the (nearly) "embarassingly parallel" (i.e. perfectly parallelizable) algorithm of summing up the first
The serial algorithm is simply:
N = 100000000 print sum(range(N))
Execution time on my dual core laptop (Lenovo X200): 0m21.111s.
The parallelized (with mpi4py) version uses 3 nodes; node 0 calculates the sum of the lower half of the interger, node 1 calculates the sum of the upper half. The both send their results (via
comm.send) to node 2 which sums up both numbers and prints the result:
from mpi4py import MPI comm = MPI.COMM_WORLD rank = comm.Get_rank() N = 100000000 if rank == 0: s = sum(range(N/2)) comm.send(s,dest=2,tag=11) elif rank == 1: s = sum(range(N/2+1,N)) comm.send(s,dest=2,tag=11) elif rank == 2: s1 = comm.recv(source=0, tag=11) s2 = comm.recv(source=1, tag=11) print s1+s2
Both cores of my dual-core-laptop are fully used; Execution time now: 15.746s.
My Question: At least in theory, the execution time should nearly be halfed. Which overhead eats the missing 4 seconds? (surely not s1+s2). Are those send- / receive-Commands that time-consuming??
Edit: After reading the answers and rethinking the question, I think the 4 seconds (in some runs even more than that) are eaten by the high memory traffic caused by the generation of two lists of length 50000000; the two cores of my laptop share a common memory (at least main memory; I think they have separate L2-Caches) and exactly this is the bottleneck: so, very often, both cores want to access memory at the same time (for getting the next list element) and one of them has to wait...
If I use
xrange instead of
range, the next list elements are generated lazily and little memory is allocated.
I tested it and running the same programm as above with xrange takes just 11 seconds!