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I'm running R on linux box that has 8 multicore processors, and have an optimization problem I'd like to speed up by parallelizing the optimization routine itself. Importantly, this problem involves (1) multiple parameters, and (2) inherently slow model runs. A fairly common problem!

Anyone know of a parallelized optimizer for such occasions?

More specifically, solvers like nlm() run multiple model evaluations (two per parameter value) each time the algorithm takes a step in parameter space, so parallelizing that instance of multiple model runs would greatly speed things up in these situations when more than a few parameter values are being fit.

It seems like code that makes use of the package parallel could be written in a way that the user would have to do minimal code modification to move from using nlm() or optim() to this parallelized optimization routine. That is, it seems one could rewrite these routines basically with no changes, except that the step of calling the model multiple times, as is common in gradient-based methods, would be done in parallel.

Ideally, something like nlmPara() would take code that looks like

fit <- nlm(MyObjFunc, params0);

and require only minor modifications, e.g.,

fit <- nlmPara(MyObjFunc, params0, ncores=6);

Thoughts/suggestions?

PS: I've taken steps to speed up those model runs, but they're slow for a variety of reasons (i.e. I don't need advice on speeding up the model runs! ;-) ).

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A little more reading into the different optimizers, and it looks like this sort of hack would require rewriting C code (e.g., rewriting the C port of the OPTIF9 routine to use multiple threads) or writing a native R optimizer to take advantage of the higher level parallelization option like parallel, multicore, snow, etc. –  Paul J Hurtado Mar 14 '13 at 1:40
2  
The optimx/optimplus package has native-R versions of a lot of optimization algorithms: maybe easiest to start from there ... ? –  Ben Bolker Mar 20 '13 at 16:51
    
Thanks Ben :-) optimx allows you to input a gradient function. I'll try it out and see if I can't just hand it a parallelized block of code, which should do the trick. –  Paul J Hurtado Mar 20 '13 at 17:18
    
I have a couple more thoughts -- there might be some parallel + memoization tricks? Several of the built-in optim() optimizers also take optional gr arguments –  Ben Bolker Mar 20 '13 at 18:52
    
Would the rgenoud package work for you? The genoud function from that package takes a cluster argument that supports parallel computing via the snow package, although you'd have to use cluster=rep('localhost', 6) rather than cluster=6. –  Steve Weston Mar 22 '13 at 14:01

3 Answers 3

Here is a rough solution, that at least has some promise. Big thanks to Ben Bolker for pointing out that many/most optimization routines allow user-specified gradient functions.

A test problem with more parameter values might show more significant improvements, but on an 8 core machine the run using the parallelized gradient function takes about 70% as long as the serial version. Note the crude gradient approximation used here seems to slow convergence and thus adds some time to the process.

## Set up the cluster
require("parallel");
.nlocalcores = NULL; # Default to "Cores available - 1" if NULL.
if(is.null(.nlocalcores)) { .nlocalcores = detectCores() - 1; }
if(.nlocalcores < 1) { print("Multiple cores unavailable! See code!!"); return()}
print(paste("Using ",.nlocalcores,"cores for parallelized gradient computation."))
.cl=makeCluster(.nlocalcores);
print(.cl)


# Now define a gradient function: both in serial and in parallel
mygr <- function(.params, ...) {
  dp = cbind(rep(0,length(.params)),diag(.params * 1e-8)); # TINY finite difference
  Fout = apply(dp,2, function(x) fn(.params + x,...));     # Serial 
  return((Fout[-1]-Fout[1])/diag(dp[,-1]));                # finite difference 
}

mypgr <- function(.params, ...) { # Now use the cluster 
  dp = cbind(rep(0,length(.params)),diag(.params * 1e-8));   
  Fout = parCapply(.cl, dp, function(x) fn(.params + x,...)); # Parallel 
  return((Fout[-1]-Fout[1])/diag(dp[,-1]));                  #
}


## Lets try it out!
fr <- function(x, slow=FALSE) { ## Rosenbrock Banana function from optim() documentation.
  if(slow) { Sys.sleep(0.1); }   ## Modified to be a little slow, if needed.
  x1 <- x[1]
  x2 <- x[2]
  100 * (x2 - x1 * x1)^2 + (1 - x1)^2
}

grr <- function(x, slow=FALSE) { ## Gradient of 'fr'
  if(slow) { Sys.sleep(0.1); }   ## Modified to be a little slow, if needed.
  x1 <- x[1]
  x2 <- x[2]
  c(-400 * x1 * (x2 - x1 * x1) - 2 * (1 - x1),
    200 *      (x2 - x1 * x1))
}

## Make sure the nodes can see these functions & other objects as called by the optimizer
fn <- fr;  # A bit of a hack
clusterExport(cl, "fn");

# First, test our gradient approximation function mypgr
print( mypgr(c(-1.2,1)) - grr(c(-1.2,1)))

## Some test calls, following the examples in the optim() documentation
tic = Sys.time();
fit1 = optim(c(-1.2,1), fr, slow=FALSE);                          toc1=Sys.time()-tic
fit2 = optim(c(-1.2,1), fr, gr=grr, slow=FALSE, method="BFGS");   toc2=Sys.time()-tic-toc1
fit3 = optim(c(-1.2,1), fr, gr=mygr, slow=FALSE, method="BFGS");  toc3=Sys.time()-tic-toc1-toc2
fit4 = optim(c(-1.2,1), fr, gr=mypgr, slow=FALSE, method="BFGS"); toc4=Sys.time()-tic-toc1-toc2-toc3


## Now slow it down a bit
tic = Sys.time();
fit5 = optim(c(-1.2,1), fr, slow=TRUE);                           toc5=Sys.time()-tic
fit6 = optim(c(-1.2,1), fr, gr=grr, slow=TRUE, method="BFGS");    toc6=Sys.time()-tic-toc5
fit7 = optim(c(-1.2,1), fr, gr=mygr, slow=TRUE, method="BFGS");   toc7=Sys.time()-tic-toc5-toc6
fit8 = optim(c(-1.2,1), fr, gr=mypgr, slow=TRUE, method="BFGS");  toc8=Sys.time()-tic-toc5-toc6-toc7

print(cbind(fast=c(default=toc1,exact.gr=toc2,serial.gr=toc3,parallel.gr=toc4),
            slow=c(toc5,toc6,toc7,toc8)))
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As you have not accepted an answer, this idea might help: For global optimisation the package DEoptim() has an in-built option for parallel optimisation. Nice thing is, it's easy to use and documentation well written.

c.f. http://www.jstatsoft.org/v40/i06/paper (currently down)

http://cran.r-project.org/web/packages/DEoptim/index.html

Beware: Differential Evolglobal optimizers might still run into locals.

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by the way, optimisation with DE often converges faster if you use latin hypercube sampling as described in the lhs package for your initial population. –  Toby Apr 12 '14 at 14:01

I used the package doSNOW to run a code on 8 cores. I can just copy&paste the part of the code that refers to this package. Hope it helps!

    # use multicore libraries
      # specify number of cores to use
    cores<- 8
      cluster <- makeCluster(cores, type="SOCK")
      registerDoSNOW(cluster)

      # check how many cores will be used
      ncores <- getDoParWorkers()
    print(paste("Computing algorithm for ", cores, " cores", sep=""))
      fph <- rep(-100,12)

      # start multicore cicle on 12  subsets
      fph <- foreach(i=1:12, .combine='c') %dopar% {
        PhenoRiceRun(sub=i, mpath=MODIS_LOCAL_DIR, masklocaldir=MASK_LOCAL_DIR, startYear=startYear, tile=tile, evismoothopt=FALSE)
      }


  stopCluster(cluster) # check if gives error
  gc(verbose=FALSE)
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Thanks FraNut, however the problem isn't how to run something in parallel in R, I was specifically looking for a gradient-based optimization routine that automatically parallelized the gradient computation. See the comments below my question above -- I think Ben's suggestion lead to a workable solution –  Paul J Hurtado Mar 20 '13 at 17:17
    
Specifically, optimx allows user-defined gradient functions, which still requires the user to write code using parallel (or doSNOW, etc.) but presumably this will be a fairly straightforward solution to the problem. –  Paul J Hurtado Mar 20 '13 at 17:34

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