# Will RCpp speed up the evaluation of basic R functions?

Pardon me, but I do not know much about Rcpp, but I am trying to figure out if it would be good to learn it in order to improve a package I am writing.

I have written an R package that (is supposed to) efficiently and randomly samples uniformly from a high-dimensional, constrained space with an MCMC algorithm. It is (unfinished and) located at https://github.com/davidkane9/kmatching.

The problem is when I run a statistical test called the Gelman-Rubin diagnostic to see whether my MCMC algorithm has converged to a stationary distribution, I should get R = 1 for the statistic, but I get very high numbers, which basically tells me my sampling is bad and no one should use it. The solution is to take more samples and skip more (taking 1 out of ever 1000 instead of every 100). However this takes a lot of time. If you want some code to run, here is an example:

``````##install the package first
data(lalonde)
matchvars = c("age", "educ", "black")
k = kmatch(x = lalonde, weight.var = "treat", match.var = matchvars, n = 1000, skiplength = 1000, chains = 2, verbose = TRUE)
``````

Looking at an Rprof output of this I get that `rnorm` and `%*%` are taking most of the time:

``````                       total.time total.pct self.time self.pct
"kmatch"                  1453.14    100.00      0.00     0.00
"hitandrun"               1450.18     99.79    128.80     8.86
"%*%"                      757.00     52.09    757.00    52.09
"cat"                      343.18     23.62    329.82    22.70
"rnorm"                    106.34      7.32    103.50     7.12
"mirror"                    35.26      2.43     21.84     1.50
"paste"                     14.02      0.96     14.02     0.96
"stdout"                    13.36      0.92     13.36     0.92
"runif"                     13.32      0.92     13.32     0.92
"/"                         12.82      0.88     12.82     0.88
">"                          7.42      0.51      7.42     0.51
"<"                          6.22      0.43      6.22     0.43
"-"                          5.78      0.40      5.78     0.40
"max"                        5.18      0.36      5.18     0.36
"nchar"                      5.12      0.35      5.12     0.35
"*"                          4.84      0.33      4.84     0.33
"min"                        3.94      0.27      3.94     0.27
"sum"                        3.42      0.24      3.42     0.24
"gelman.diag"                2.90      0.20      0.00     0.00
"=="                         2.86      0.20      2.86     0.20
"ncol"                       2.84      0.20      2.84     0.20
"apply"                      2.72      0.19      0.26     0.02
"+"                          2.48      0.17      2.48     0.17
"FUN"                        2.32      0.16      1.66     0.11
"^"                          2.08      0.14      2.08     0.14
":"                          1.24      0.09      1.24     0.09
"sqrt"                       0.96      0.07      0.96     0.07
"%%"                         0.90      0.06      0.90     0.06
"mean.default"               0.62      0.04      0.62     0.04
"lapply"                     0.40      0.03      0.26     0.02
"("                          0.32      0.02      0.32     0.02
"unlist"                     0.26      0.02      0.00     0.00
"array"                      0.12      0.01      0.02     0.00
"sapply"                     0.12      0.01      0.00     0.00
"matrix"                     0.06      0.00      0.02     0.00
"Null"                       0.04      0.00      0.04     0.00
"print"                      0.04      0.00      0.00     0.00
"unique"                     0.04      0.00      0.00     0.00
"abs"                        0.02      0.00      0.02     0.00
"all"                        0.02      0.00      0.02     0.00
"aperm.default"              0.02      0.00      0.02     0.00
"as.matrix.mcmc"             0.02      0.00      0.02     0.00
"file.exists"                0.02      0.00      0.02     0.00
"list"                       0.02      0.00      0.02     0.00
"print.default"              0.02      0.00      0.02     0.00
"stopifnot"                  0.02      0.00      0.02     0.00
"unique.default"             0.02      0.00      0.02     0.00
"which.min"                  0.02      0.00      0.02     0.00
"<Anonymous>"                0.02      0.00      0.00     0.00
"aperm"                      0.02      0.00      0.00     0.00
"as.mcmc.list"               0.02      0.00      0.00     0.00
"as.mcmc.list.default"       0.02      0.00      0.00     0.00
"data"                       0.02      0.00      0.00     0.00
"mcmc.list"                  0.02      0.00      0.00     0.00
"print.gelman.diag"          0.02      0.00      0.00     0.00
"quantile.default"           0.02      0.00      0.00     0.00
"sort"                       0.02      0.00      0.00     0.00
"sort.default"               0.02      0.00      0.00     0.00
"sort.int"                   0.02      0.00      0.00     0.00
"summary"                    0.02      0.00      0.00     0.00
"summary.default"            0.02      0.00      0.00     0.00
``````

If I set verbose = F, the `cat` goes away, but then `%*%` takes about 70% of the time. I am wondering if it would be worthwhile to try to write my code in C++ and then use RCpp, or if because the functions that are taking so much time are basic functions (already written in C) it wouldn't be worth it and I'll just have to live with it or find a better algorithm.

Edit: According to Rprof, the one line that is holding me up is `u = Z %*% r` in `hitandrun`:

``````## This is the loop that is being run millions of times and taking forever
tmin<-0;tmax<-0;
## runs counts how many times tried to pick a direction, if
## too high fail.
runs = 0
while(tmin ==0 && tmax ==0) {
## r is a random unit vector in with basis in Z
r <- rnorm(ncol(Z))
r <- r/sqrt(sum(r^2))

## u is a unit vector in the appropriate k-plane pointing in a
## random direction Z %*% r is the same as in mirror
u <- Z%*%r
c <- y/u
## determine intersections of x + t*u with walls
## the limits on how far you can go backward and forward
## i.e. the maximum and minimum ratio y_i/u_i for negative and positive u.
tmin <- max(-c[u>0]); tmax <- min(-c[u<0]);
## unboundedness
if(tmin == -Inf || tmax == Inf){
stop("problem is unbounded")
}
## if stuck on boundary point
if(tmin==0 && tmax ==0) {
runs = runs + 1
if(runs >= 1000) stop("hitandrun found can't find feasible direction, cannot generate points")
}
}

## chose a point on the line segment
y <- y + (tmin + (tmax - tmin)*runif(1))*u;

## choose a point every 'skiplength' samples
if(i %% skiplength == 0) {
X[,index] <- y
index <- index + 1
}
if(verbose) for(j in 1:nchar(str)) cat("\b")
str <- paste(i)
if(verbose) cat(str)
}
``````

it is actually the only time I do matrix multiplication in my sampling loop, however I do it thousands of times, once per sample taking a million samples and throwing out 99%.

-
If you could provide the source code for the bottleneck, you'll be able to get better advice, but generally R is bad at the sorts of computations MCMC requires, and C++ is good. See e.g. gallery.rcpp.org/articles/gibbs-sampler –  hadley Aug 7 '13 at 17:02
Re-writing matrix multiplication is not going to be faster, since it will use the same underlying BLAS. If you want `%*%` to be faster, use an optimized BLAS. –  Joshua Ulrich Aug 7 '13 at 17:06
have you thought about running your code parallel (eg. parallel package) this could help, specially when you need a huge amount of random numbers. It is also quite conman to run different chains of the MCMC algorithm parallel.... –  holzben Aug 7 '13 at 17:08
@hadley I've added some of the source code, the whole file is rather long, if I should post more, let me know. –  Mike Flynn Aug 7 '13 at 17:09
@holzbrn yes that would be a good idea I am going to try doing that next, I just want to make sure (this is what Gelman-Rubin is testing) that the different chains are sampling reliably from the same distribution. –  Mike Flynn Aug 7 '13 at 17:13
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