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This question does not have an answer in What is the easiest way to parallelize a vectorized function in R? as I am not asking for an easy way, but for an extra control on what the processes do and when then die, through a master/slave system.

Here is my problem: I used successfully mcparallel and mccollect to parallelize some tasks, along the following lines (X is a list) :

p1 <- mcparallel( lapply( X[1:25],  function(x) my.function(x, theta) ) )
p2 <- mcparallel( lapply( X[26:50], function(x) my.function(x, theta) ) )
p3 <- mcparallel( lapply( X[51:75], function(x) my.function(x, theta) ) )
x4 <- lapply(X[76:100], function(x) my.function(x, theta) )

c( mccollect(p1), mccollect(p2), mccollect(p3), x4 )

The elements of X are big, the parameter theta is small, and the aim is to perform optimization on theta. Note that mclapply(X, ...) performs very badly on my problem (almost no time gained). I also tried %dopar% from the foreach package: no time gained at all!

To reduce the overhead and avoid new forks at each computation, I’d like to use a master/slave logic as exemplified in this Rmpi tutorial. I could feed the slaves new values of theta, this would avoid new forks at each new computation, with (I guess) copying the whole memory at each new fork, and so. As theta is small, and so are the results of my.function, the computation between the process would be fast and this would allow to gain a substantial amount of time in the subsequent computations.

However, I am told that MPI is a protocol which is more suited for using several computers. I use a multicore computer (16 cores), and I am told lighter protocols would be suited.

Can you give me an advice? In particular, is it possible to implement a master/slave system on a multicore computer, using the parallel package?

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I take it that the elements of X are reasonably long vectors, but that you can't concatenate them in order to call my.function fewer times. Is that true? If so, there may not be much you can do. But how much time do the different implementations actually take to run? – Steve Weston Mar 16 '13 at 1:08
    
The elements of X are complex data structures, that have to be analyzed one at a time. The current implementation, on reasonably complex problems, runs in, say, one minute for the unparallelized version, and 20 secondes for the parallelized one, or so. Cutting in smaller chunks does not help much, the overhead being greater. – Elvis Mar 16 '13 at 7:43
    
I guess I am just asking for a way, using parallel, to implement a master/slave system just as described in Rmpi. I’ll edit my question to make this clearer. This is not a duplicate of this previous question, I am not asking for an easy way (which would be for example mclapply). – Elvis Mar 16 '13 at 7:46
    
@RyanThompson None of the answers given in this other question apply. I just want that the process created in the parallelization don’t die, as I think it will reduce the overhead in the next computations. My problem is really specific and different. – Elvis Mar 16 '13 at 7:50
up vote 0 down vote accepted

I sort of found a solution.

> library('parallel')
> makeCluster(2) -> cl
> # loading data to nodes:
> invisible(clusterApply( cl, 4:5, function(t) a <<- t ))
> # computations on these data with different arguments
> clusterApply( cl, 1:2, function(t) a+t )
[[1]]
[1] 5

[[2]]
[1] 7
> clusterApply( cl, 10:11, function(t) a+t )
[[1]]
[1] 14

[[2]]
[1] 16
> stopCluster(cl)

I think it will do what I want, but I still wait for other suggestions (hence I don’t accept my own answer).

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