Here's my implementation. It's a function chunkmap
that takes a
vectorized function, a list of arguments that should be vectorized,
and a list of arguments that should not be vectorized (i.e.
constants), and returns the same result as calling the function on the
arguments directly, except that the result is calculated in parallel.
For a function f
, vector arguments v1
, v2
, v3
, and scalar
arguments s1
, s2
, the following should return identical results:
f(a=v1, b=v2, c=v3, d=s1, e=s2)
f(c=v3, b=v2, e=s2, a=v1, d=s1)
chunkapply(FUN=f, VECTOR.ARGS=list(a=v1, b=v2, c=v3), SCALAR.ARGS=list(d=s1, e=s2))
chunkapply(FUN=f, SCALAR.ARGS=list(e=s2, d=s1), VECTOR.ARGS=list(a=v1, c=v3, b=v2))
Since it is impossible for the chunkapply
function to know which
arguments of f
are vectorized and which are not, it is up to you to
specify when you call it, or else you will get the wrong results. You
should generally name your arguments to ensure that they get bound
correctly.
library(foreach)
library(iterators)
# Use your favorite doPar backend here
library(doMC)
registerDoMC()
get.chunk.size <- function(vec.length,
min.chunk.size=NULL, max.chunk.size=NULL,
max.chunks=NULL) {
if (is.null(max.chunks)) {
max.chunks <- getDoParWorkers()
}
size <- vec.length / max.chunks
if (!is.null(max.chunk.size)) {
size <- min(size, max.chunk.size)
}
if (!is.null(min.chunk.size)) {
size <- max(size, min.chunk.size)
}
num.chunks <- ceiling(vec.length / size)
actual.size <- ceiling(vec.length / num.chunks)
return(actual.size)
}
ichunk.vectors <- function(vectors=NULL,
min.chunk.size=NULL,
max.chunk.size=NULL,
max.chunks=NULL) {
## Calculate number of chunks
recycle.length <- max(sapply(vectors, length))
actual.chunk.size <- get.chunk.size(recycle.length, min.chunk.size, max.chunk.size, max.chunks)
num.chunks <- ceiling(recycle.length / actual.chunk.size)
## Make the chunk iterator
i <- 1
it <- idiv(recycle.length, chunks=num.chunks)
nextEl <- function() {
n <- nextElem(it)
ix <- seq(i, length = n)
i <<- i + n
vchunks <- foreach(v=vectors) %do% v[1+ (ix-1) %% length(v)]
names(vchunks) <- names(vectors)
vchunks
}
obj <- list(nextElem = nextEl)
class(obj) <- c("ichunk", "abstractiter", "iter")
obj
}
chunkapply <- function(FUN, VECTOR.ARGS, SCALAR.ARGS=list(), MERGE=TRUE, ...) {
## Check that the arguments make sense
stopifnot(is.list(VECTOR.ARGS))
stopifnot(length(VECTOR.ARGS) >= 1)
stopifnot(is.list(SCALAR.ARGS))
## Choose appropriate combine function
if (MERGE) {
combine.fun <- append
} else {
combine.fun <- foreach:::defcombine
}
## Chunk and apply, and maybe merge
foreach(vchunk=ichunk.vectors(vectors=VECTOR.ARGS, ...),
.combine=combine.fun,
.options.multicore = mcoptions) %dopar%
{
do.call(FUN, args=append(vchunk, SCALAR.ARGS))
}
}
## Only do chunkapply if it will run in parallel
maybe.chunkapply <- function(FUN, VECTOR.ARGS, SCALAR.ARGS=list(), ...) {
if (getDoParWorkers() > 1) {
chunkapply(FUN, VECTOR.ARGS, SCALAR.ARGS, ...)
} else {
do.call(FUN, append(VECTOR.ARGS, SCALAR.ARGS))
}
}
Here are some examples showing that chunkapply(f,list(x))
produces identical results to f(x)
. I have set the max.chunk.size extremely small to ensure that the chunking algorithm is actually used.
> # Generate all even integers from 2 to 100 inclusive
> identical(chunkapply(function(x,y) x*y, list(1:50), list(2), max.chunk.size=10), 1:50 * 2)
[1] TRUE
> ## Sample from a standard normal distribution, then discard values greater than 1
> a <- rnorm(n=100)
> cutoff <- 1
> identical(chunkapply(function(x,limit) x[x<=limit], list(x=a), list(limit=cutoff), max.chunk.size=10), a[a<cutoff])
[1] TRUE
If anyone has a better name than "chunkapply", please suggest it.
Edit:
As another answer points out, there is a function called pvec
in the multicore pacakge that has very similar functionality to what I have written. For simple cases, you should us that, and you should vote up Jonas Rauch's answer for it. However, my function is a bit more general, so if any of the following apply to you, you might want to consider using my function instead:
- You need to use a parallel backend other than multicore (e.g. MPI). My function uses foreach, so you can use any parallelization framework that provides a backend for foreach.
- You need to pass multiple vectorized arguments.
pvec
only vectorizes over a single argument, so you couldn't easily implement parallel vectorized addition with pvec
, for example. My function allows you to specify arbitrary arguments.
f
transparently makes use of MPI for parallelization if it finds it. So now I just have to figure out how to set up MPI.X
is an instance of this class. But the point is that it is vectorized, i.e.f(X)
is exactly what I want to do, only faster. Expanding on my previous comment, the implementation off
automatically uses MPI if it is set up correctly. So I guess I now have to decide whether it is easier to set up MPI on this one server, or to do the chunking myself.p
, subjects
andcores=2
e.g.,tasks <- split(seq_along(p), cut(seq_along(p), cores))
andmclapply(tasks, function(i, p, ...) pairwiseAlignment(p[i], ...), p, s, scoreOnly=TRUE)
versuspairwiseAlignment(p, s, scoreOnly=TRUE)
. Execution time is 2x (for my two cores) and results are identical. More challenging to merge the objects if not scoresOnly.