Speed up your R Work
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Introduction
In this note we will show how to speed up work in R
by partitioning data and process-level parallelization. We will show the technique with three different R
packages: rqdatatable
, data.table
, and dplyr
. The methods shown will also work with base-R
and other packages.
For each of the above packages we speed up work by using wrapr::execute_parallel
which in turn uses wrapr::partition_tables
to partition un-related data.frame
rows and then distributes them to different processors to be executed. rqdatatable::ex_data_table_parallel
conveniently bundles all of these steps together when working with rquery
pipelines.
The partitioning is specified by the user preparing a grouping column that tells the system which sets of rows must be kept together in a correct calculation. We are going to try to demonstrate everything with simple code examples, and minimal discussion.
Keep in mind: unless the pipeline steps have non-trivial cost, the overhead of partitioning and distributing the work may overwhelm any parallel speedup. Also data.table
itself already seems to exploit some thread-level parallelism (notice user time is greater than elapsed time). That being said, in this note we will demonstrate a synthetic example where computation is expensive due to a blow-up in an intermediate join step.
Our example
First we set up our execution environment and example (some details: OSX 10.13.4 on a 2.8 GHz Intel Core i5 Mac Mini (Late 2015 model) with 8GB RAM and hybrid disk drive).
library("rqdatatable")
## Loading required package: rquery
library("microbenchmark") library("ggplot2") library("WVPlots") suppressPackageStartupMessages(library("dplyr"))
## Warning: package 'dplyr' was built under R version 3.5.1
base::date()
## [1] "Sun Jul 8 09:05:25 2018"
R.version.string
## [1] "R version 3.5.0 (2018-04-23)"
parallel::detectCores()
## [1] 4
packageVersion("parallel")
## [1] '3.5.0'
packageVersion("rqdatatable")
## [1] '0.1.2'
packageVersion("rquery")
## [1] '0.5.1'
packageVersion("dplyr")
## [1] '0.7.6'
ncore <- parallel::detectCores() print(ncore)
## [1] 4
cl <- parallel::makeCluster(ncore) print(cl)
## socket cluster with 4 nodes on host 'localhost'
set.seed(2362) mk_example <- function(nkey, nrep, ngroup = 20) { keys <- paste0("key_", seq_len(nkey)) key_group <- sample(as.character(seq_len(ngroup)), length(keys), replace = TRUE) names(key_group) <- keys key_table <- data.frame( key = rep(keys, nrep), stringsAsFactors = FALSE) key_table$data <- runif(nrow(key_table)) instance_table <- data.frame( key = rep(keys, nrep), stringsAsFactors = FALSE) instance_table$id <- seq_len(nrow(instance_table)) instance_table$info <- runif(nrow(instance_table)) # groups should be no finer than keys key_table$key_group <- key_group[key_table$key] instance_table$key_group <- key_group[instance_table$key] list(key_table = key_table, instance_table = instance_table) } dlist <- mk_example(10, 10) data <- dlist$instance_table annotation <- dlist$key_table
rquery / rqdatatable
rquery
and rqdatatable
can implement a non-trivial calculation as follows.
# possible data lookup: find rows that # have lookup data <= info optree <- local_td(data) %.>% natural_join(., local_td(annotation), jointype = "INNER", by = "key") %.>% select_rows_nse(., data <= info) %.>% pick_top_k(., k = 1, partitionby = "id", orderby = "data", reverse = "data", keep_order_column = FALSE) %.>% orderby(., "id") cat(format(optree))
## table('data'; ## key, ## id, ## info, ## key_group) %.>% ## natural_join(., ## table('annotation'; ## key, ## data, ## key_group), ## j= INNER, by= key) %.>% ## select_rows(., ## data <= info) %.>% ## extend(., ## row_number := row_number(), ## p= id, ## o= "data" DESC) %.>% ## select_rows(., ## row_number <= 1) %.>% ## drop_columns(., ## row_number) %.>% ## orderby(., id)
res1 <- ex_data_table(optree) head(res1)
## data id info key key_group ## 1: 0.9152014 1 0.9860654 key_1 20 ## 2: 0.5599810 2 0.5857570 key_2 8 ## 3: 0.3011882 3 0.3334490 key_3 10 ## 4: 0.3650987 4 0.3960980 key_4 5 ## 5: 0.1469254 5 0.1753649 key_5 14 ## 6: 0.2567631 6 0.3510280 key_6 7
nrow(res1)
## [1] 94
And we can execute the operations in parallel.
parallel::clusterEvalQ(cl, library("rqdatatable"))
## [[1]] ## [1] "rqdatatable" "rquery" "stats" "graphics" "grDevices" ## [6] "utils" "datasets" "methods" "base" ## ## [[2]] ## [1] "rqdatatable" "rquery" "stats" "graphics" "grDevices" ## [6] "utils" "datasets" "methods" "base" ## ## [[3]] ## [1] "rqdatatable" "rquery" "stats" "graphics" "grDevices" ## [6] "utils" "datasets" "methods" "base" ## ## [[4]] ## [1] "rqdatatable" "rquery" "stats" "graphics" "grDevices" ## [6] "utils" "datasets" "methods" "base"
res2 <- ex_data_table_parallel(optree, "key_group", cl) head(res2)
## data id info key key_group ## 1: 0.9152014 1 0.9860654 key_1 20 ## 2: 0.5599810 2 0.5857570 key_2 8 ## 3: 0.3011882 3 0.3334490 key_3 10 ## 4: 0.3650987 4 0.3960980 key_4 5 ## 5: 0.1469254 5 0.1753649 key_5 14 ## 6: 0.2567631 6 0.3510280 key_6 7
nrow(res2)
## [1] 94
data.table
data.table
can implement the same function.
library("data.table")
## ## Attaching package: 'data.table' ## The following objects are masked from 'package:dplyr': ## ## between, first, last
packageVersion("data.table")
## [1] '1.11.4'
data_table_f <- function(data, annotation) { data <- data.table::as.data.table(data) annotation <- data.table::as.data.table(annotation) joined <- merge(data, annotation, by = "key", all=FALSE, allow.cartesian=TRUE) joined <- joined[joined$data <= joined$info, ] data.table::setorderv(joined, cols = "data") joined <- joined[, .SD[.N], id] data.table::setorderv(joined, cols = "id") } resdt <- data_table_f(data, annotation) head(resdt)
## id key info key_group.x data key_group.y ## 1: 1 key_1 0.9860654 20 0.9152014 20 ## 2: 2 key_2 0.5857570 8 0.5599810 8 ## 3: 3 key_3 0.3334490 10 0.3011882 10 ## 4: 4 key_4 0.3960980 5 0.3650987 5 ## 5: 5 key_5 0.1753649 14 0.1469254 14 ## 6: 6 key_6 0.3510280 7 0.2567631 7
nrow(resdt)
## [1] 94
We can also run data.table
in parallel using wrapr::execute_parallel
.
parallel::clusterEvalQ(cl, library("data.table"))
## [[1]] ## [1] "data.table" "rqdatatable" "rquery" "stats" "graphics" ## [6] "grDevices" "utils" "datasets" "methods" "base" ## ## [[2]] ## [1] "data.table" "rqdatatable" "rquery" "stats" "graphics" ## [6] "grDevices" "utils" "datasets" "methods" "base" ## ## [[3]] ## [1] "data.table" "rqdatatable" "rquery" "stats" "graphics" ## [6] "grDevices" "utils" "datasets" "methods" "base" ## ## [[4]] ## [1] "data.table" "rqdatatable" "rquery" "stats" "graphics" ## [6] "grDevices" "utils" "datasets" "methods" "base"
parallel::clusterExport(cl, "data_table_f") dt_f <- function(tables_list) { data <- tables_list$data annotation <- tables_list$annotation data_table_f(data, annotation) } data_table_parallel_f <- function(data, annotation) { respdt <- wrapr::execute_parallel( tables = list(data = data, annotation = annotation), f = dt_f, partition_column = "key_group", cl = cl) %.>% data.table::rbindlist(.) data.table::setorderv(respdt, cols = "id") respdt } respdt <- data_table_parallel_f(data, annotation) head(respdt)
## id key info key_group.x data key_group.y ## 1: 1 key_1 0.9860654 20 0.9152014 20 ## 2: 2 key_2 0.5857570 8 0.5599810 8 ## 3: 3 key_3 0.3334490 10 0.3011882 10 ## 4: 4 key_4 0.3960980 5 0.3650987 5 ## 5: 5 key_5 0.1753649 14 0.1469254 14 ## 6: 6 key_6 0.3510280 7 0.2567631 7
nrow(respdt)
## [1] 94
dplyr
dplyr
can also implement the example.
dplyr_pipeline <- function(data, annotation) { res <- data %>% inner_join(annotation, by = "key") %>% filter(data <= info) %>% group_by(id) %>% arrange(-data) %>% mutate(rownum = row_number()) %>% ungroup() %>% filter(rownum == 1) %>% arrange(id) res } resd <- dplyr_pipeline(data, annotation) head(resd)
## # A tibble: 6 x 7 ## key id info key_group.x data key_group.y rownum ## <chr> <int> <dbl> <chr> <dbl> <chr> <int> ## 1 key_1 1 0.986 20 0.915 20 1 ## 2 key_2 2 0.586 8 0.560 8 1 ## 3 key_3 3 0.333 10 0.301 10 1 ## 4 key_4 4 0.396 5 0.365 5 1 ## 5 key_5 5 0.175 14 0.147 14 1 ## 6 key_6 6 0.351 7 0.257 7 1
nrow(resd)
## [1] 94
And we can use wrapr::execute_parallel
to parallelize the dplyr
solution.
parallel::clusterEvalQ(cl, library("dplyr"))
## [[1]] ## [1] "dplyr" "data.table" "rqdatatable" "rquery" "stats" ## [6] "graphics" "grDevices" "utils" "datasets" "methods" ## [11] "base" ## ## [[2]] ## [1] "dplyr" "data.table" "rqdatatable" "rquery" "stats" ## [6] "graphics" "grDevices" "utils" "datasets" "methods" ## [11] "base" ## ## [[3]] ## [1] "dplyr" "data.table" "rqdatatable" "rquery" "stats" ## [6] "graphics" "grDevices" "utils" "datasets" "methods" ## [11] "base" ## ## [[4]] ## [1] "dplyr" "data.table" "rqdatatable" "rquery" "stats" ## [6] "graphics" "grDevices" "utils" "datasets" "methods" ## [11] "base"
parallel::clusterExport(cl, "dplyr_pipeline") dplyr_f <- function(tables_list) { data <- tables_list$data annotation <- tables_list$annotation dplyr_pipeline(data, annotation) } dplyr_parallel_f <- function(data, annotation) { respdt <- wrapr::execute_parallel( tables = list(data = data, annotation = annotation), f = dplyr_f, partition_column = "key_group", cl = cl) %>% dplyr::bind_rows() %>% arrange(id) } respdplyr <- dplyr_parallel_f(data, annotation) head(respdplyr)
## # A tibble: 6 x 7 ## key id info key_group.x data key_group.y rownum ## <chr> <int> <dbl> <chr> <dbl> <chr> <int> ## 1 key_1 1 0.986 20 0.915 20 1 ## 2 key_2 2 0.586 8 0.560 8 1 ## 3 key_3 3 0.333 10 0.301 10 1 ## 4 key_4 4 0.396 5 0.365 5 1 ## 5 key_5 5 0.175 14 0.147 14 1 ## 6 key_6 6 0.351 7 0.257 7 1
nrow(respdplyr)
## [1] 94
Benchmark
We can benchmark the various realizations.
dlist <- mk_example(300, 300) data <- dlist$instance_table annotation <- dlist$key_table timings <- microbenchmark( data_table_parallel = nrow(data_table_parallel_f(data, annotation)), data_table = nrow(data_table_f(data, annotation)), rqdatatable_parallel = nrow(ex_data_table_parallel(optree, "key_group", cl)), rqdatatable = nrow(ex_data_table(optree)), dplyr_parallel = nrow(dplyr_parallel_f(data, annotation)), dplyr = nrow(dplyr_pipeline(data, annotation)), times = 10L) saveRDS(timings, "Parallel_rqdatatable_timings.RDS")
Conclusion
print(timings)
## Unit: seconds ## expr min lq mean median uq ## data_table_parallel 5.274560 5.457105 5.609827 5.546554 5.686829 ## data_table 9.401677 9.496280 9.701807 9.541218 9.748159 ## rqdatatable_parallel 7.165216 7.497561 7.587663 7.563883 7.761987 ## rqdatatable 12.490469 12.700474 13.320480 12.898154 14.229233 ## dplyr_parallel 6.492262 6.572062 6.784865 6.787277 6.875076 ## dplyr 20.056555 20.450064 20.647073 20.564529 20.800350 ## max neval ## 6.265888 10 ## 10.419316 10 ## 7.949404 10 ## 14.282269 10 ## 7.328223 10 ## 21.332103 10
# autoplot(timings) timings <- as.data.frame(timings) timings$seconds <- timings$time/1e+9 ScatterBoxPlotH(timings, xvar = "seconds", yvar = "expr", title="task duration by method")
The benchmark timings show parallelized data.table
is the fastest, followed by parallelized dplyr
, and parallelized rqdatatable
. In the non-paraellized case data.table
is the fastest, followed by rqdatatable
, and then dplyr
.
A reason dplyr
sees greater speedup relative to its own non-parallel implementation (yet does not beat data.table
) is that data.table
starts already multi-threaded, so data.table
is exploiting some parallelism even before we added the process level parallelism (and hence sees less of a speed up, though it is fastest).
rquery
pipelines exhibit superior performance on big data systems (Spark, PostgreSQL, Amazon Redshift, and hopefully soon Google bigquery), and rqdatatable
supplies a very good in-memory implementation of the rquery
system based on data.table
. rquery
also speeds up solution development by supplying higher order operators and early debugging features.
In this note we have demonstrated simple procedures to reliably parallelize any of rqdatatable
, data.table
, or dplyr
.
Note: we did not include alternatives such as multidplyr
or dtplyr
in the timings, as they did not appear to work on this example.
Materials
The original rendering of this article can be found here, source code here, and raw timings here.
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