11

I'm trying to compare parallelization options. Specifically, I'm comparing the standard SNOW and mulitcore implementations to those using doSNOW or doMC and foreach. As a sample problem, I'm illustrating the central limit theorem by computing the means of samples drawn from a standard normal distribution many times. Here's the standard code:

CltSim <- function(nSims=1000, size=100, mu=0, sigma=1){
  sapply(1:nSims, function(x){
    mean(rnorm(n=size, mean=mu, sd=sigma))
  })
}

Here's the SNOW implementation:

library(snow)
cl <- makeCluster(2)

ParCltSim <- function(cluster, nSims=1000, size=100, mu=0, sigma=1){
  parSapply(cluster, 1:nSims, function(x){
    mean(rnorm(n=size, mean=mu, sd=sigma))
  })
}

Next, the doSNOW method:

library(foreach)
library(doSNOW)
registerDoSNOW(cl)

FECltSim <- function(nSims=1000, size=100, mu=0, sigma=1) {
  x <- numeric(nSims)
  foreach(i=1:nSims, .combine=cbind) %dopar% {
    x[i] <- mean(rnorm(n=size, mean=mu, sd=sigma))
  }
}

I get the following results:

> system.time(CltSim(nSims=10000, size=100))
   user  system elapsed 
  0.476   0.008   0.484 
> system.time(ParCltSim(cluster=cl, nSims=10000, size=100))
   user  system elapsed 
  0.028   0.004   0.375 
> system.time(FECltSim(nSims=10000, size=100))
   user  system elapsed 
  8.865   0.408  11.309 

The SNOW implementation shaves off about 23% of computing time relative to an unparallelized run (time savings get bigger as the number of simulations increase, as we would expect). The foreach attempt actually increases run time by a factor of 20. Additionally, if I change %dopar% to %do% and check the unparallelized version of the loop, it takes over 7 seconds.

Additionally, we can consider the multicore package. The simulation written for multicore is

library(multicore)
MCCltSim <- function(nSims=1000, size=100, mu=0, sigma=1){
  unlist(mclapply(1:nSims, function(x){
    mean(rnorm(n=size, mean=mu, sd=sigma))
  }))
}

We get an even better speed improvement than SNOW:

> system.time(MCCltSim(nSims=10000, size=100))
   user  system elapsed 
  0.924   0.032   0.307 

Starting a new R session, we can attempt the foreach implementation using doMC instead of doSNOW, calling

library(doMC)
registerDoMC()

then running FECltSim() as above, still finding

> system.time(FECltSim(nSims=10000, size=100))
   user  system elapsed 
  6.800   0.024   6.887 

This is "only" a 14-fold increase over the non-parallelized runtime.

Conclusion: My foreach code is not running efficiently under either doSNOW or doMC. Any idea why?

Thanks, Charlie

4

To start with, you could write your foreach code a bit more concise :

FECltSim <- function(nSims=1000, size=100, mu=0, sigma=1) {
  foreach(i=1:nSims, .combine=c) %dopar% {
    mean(rnorm(n=size, mean=mu, sd=sigma))
  }
}

This gives you a vector, no need to explicitly make it within the loop. Also no need to use cbind, as your result is every time just a single number. So .combine=c will do

The thing with foreach is that it creates quite a lot of overhead to communicate between the cores and get the results of the different cores fit together. A quick look at the profile shows this pretty clearly :

$by.self
                         self.time self.pct total.time total.pct
$                             5.46    41.30       5.46     41.30
$<-                           0.76     5.75       0.76      5.75
.Call                         0.76     5.75       0.76      5.75
...

More than 40% of the time it is busy selecting things. It also uses a lot of other functions for the whole operation. Actually, foreach is only advisable if you have relatively few rounds through very time consuming functions.

The other two solutions are built on a different technology, and do far less in R. On a sidenode, snow is actually initially developed to work on clusters more than on single workstations, like multicore is.

5
  • Thanks again, Jons. I actually haven't used Rprof before, would you be able to explain how to interpret this output or point me to a resource that could? I looked at R's native help files for summaryRprof and it wasn't that helpful. – Charlie Feb 16 '11 at 16:13
  • @Charlie : self.time is the time that is spent in the function itself. self.pct is then the percentage of the total time that is spent in the function itself. total.time is the time spent in that function or any other function it calls. eg : f1 <- function(x){f2(x)}, then self.time is the time in f1() alone, and total.time is the time in f1() and f2()-if called from f1() !. total.pct is again the percentage of the total time. It's a bit confusing in the beginning, but very powerful for optimization. – Joris Meys Feb 16 '11 at 16:17
  • Thanks. How about $, $<-, .Call, and I'm guessing others? Is there a document that explains what each of these represents? – Charlie Feb 16 '11 at 18:49
  • I checked the help files (summaryRprof and Rprof), but they didn't discuss the interpretation. – Charlie Feb 18 '11 at 5:33
  • @Charlie : I meant the help files of .Call, '$' and so on. – Joris Meys Feb 18 '11 at 10:30
5

To follow on something Joris said, foreach() is best when the number of jobs does not hugely exceed the number of processors you will be using. Or more generally, when each job takes a significant amount of time on its own (seconds or minutes, say). There is a lot of overhead in creating the threads, so you really don't want to use it for lots of small jobs. If you were doing 10 million sims rather than 10 thousand, and you structured your code like this:

nSims = 1e7
nBatch = 1e6
foreach(i=1:(nSims/nBatch), .combine=c) %dopar% {
  replicate(nBatch, mean(rnorm(n=size, mean=mu, sd=sigma))
}

I bet you would find that foreach was doing pretty well.

Also note the use of replicate() for this kind of application rather than sapply. Actually, the foreach package has a similar convenience function, times(), which could be applied in this case. Of course, if your code is not doing a simple simulations with identical parameters every time, you will need sapply() and foreach().

1
  • Thanks for the suggestion of breaking the process into batches; I'll bet that'll save a good bit of communication time. I had seen replicate before, but not times. – Charlie Feb 17 '11 at 16:19

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