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The futurize package allows you to easily turn sequential code
into parallel code by piping the sequential code to the futurize()
function. Easy!
You can use futurize to make BiocParallel functions parallelize via any of the [parallel backends] supported by Futureverse, e.g.
library(futurize)
plan(multisession)
library(BiocParallel)
slow_fcn <- function(x) {
message("x = ", x)
Sys.sleep(0.1) # emulate work
x^2
}
xs <- 1:10
ys <- bplapply(xs, slow_fcn) |> futurize()
This vignette demonstrates how to use this approach to parallelize
functions such as bplapply(), bpmapply(), and bpvec() in the
BiocParallel package. For example, consider the bplapply()
function. It works like base-R lapply(), but uses the
BiocParallel framework to process the tasks concurrently. It is
commonly used something like:
library(BiocParallel)
xs <- 1:1000
ys <- bplapply(xs, slow_fcn)
The parallel backend is controlled by the BiocParallel::register(),
similar to how we use future::plan() in Futureverse. We can use
the futurize package to tell BiocParallel to hand over the
orchestration of parallel tasks to Futureverse. All we need to do is
to pass the expression to futurize() as in:
library(BiocParallel)
library(futurize)
plan(multisession) ## parallelize on local machine
xs <- 1:1000
ys <- bplapply(xs, slow_fcn) |> futurize()
#> x = 1
#> x = 2
#> x = 3
#> ...
#> x = 10
Note how messages produced on parallel workers are relayed as-is back
to the main R session as they complete. Not only messages, but also
warnings and other types of conditions are relayed back as-is.
Likewise, standard output produced by cat(), print(), str(), and
so on is relayed in the same way. This is a unique feature of
Futureverse - other parallel frameworks in R, such as parallel,
foreach with doParallel, and BiocParallel, silently drop
standard output, messages, and warnings produced on workers. With
futurize, your code behaves the same whether it runs sequentially
or in parallel: nothing is lost in translation.
The built-in multisession backend parallelizes on your local
computer and it works on all operating systems. There are other
parallel backends to choose from, including alternatives to
parallelize locally as well as distributed across remote machines,
e.g.
plan(future.mirai::mirai_multisession)
and
plan(future.batchtools::batchtools_slurm)
The futurize() function supports parallelization of all
BiocParallel functions that take argument
BPPARAM. Specifically,
bplapply() and .bplapply_impl()bpmapply() and .bpmapply_impl()bpvec()bpaggregate()The following functions are currently not supported:
bpiterate() - technically supported, but because this
function does not support using DoparParam() with it, it
effectively does not work with futurize()bpvectorize()register()Most Bioconductor packages that support parallelization do so via
BiocParallel internally. These packages typically expose a
BPPARAM argument in their functions, which controls the parallel
backend used. For example, DESeq2::DESeq() has a BPPARAM argument
that defaults to BiocParallel::bpparam(), which corresponds to the
currently registered BiocParallel backend. This means that, in
order to parallelize such a function, one can call
BiocParallel::register() to set a parallel backend, and then the
function will use it automatically.
However, not all packages default to bpparam(). For example,
sva::ComBat() defaults to bpparam("SerialParam"), which means it
always runs sequentially unless you explicitly pass a parallel
BPPARAM argument. Because of this, one cannot count on bpparam()
being the default everywhere - some functions require an explicit
BPPARAM to parallelize. With futurize, this is handled
automatically: futurize() injects the appropriate BPPARAM argument
regardless of what the default is, so that the parallel execution is
performed via the Futureverse, where the parallel backend is
controlled by future::plan().
For progress reporting, please see the [progressr] package. It is
specially designed to work with the Futureverse ecosystem and provide
progress updates from parallelized computations in a near-live
fashion. See the vignette("futurize-11-apply", package = "futurize")
for more details and an example.