# Why is R slow on this random permutation function?

I am new to R (Revolution Analytics R) and have been translating some Matlab functions into R.

Question: Why is the function GRPdur(n) so slow?

``````GRPdur = function(n){
#
# Durstenfeld's Permute algorithm, CACM 1964
# generates a random permutation of {1,2,...n}
#
for (k in seq(n,2,-1)){
r    = 1+floor(runif(1)*k); # random integer between 1 and k
tmp  = p[k];
p[k] = p[r];                #  Swap(p(r),p(k)).
p[r] = tmp;
}
return(p)
}
``````

Here is what I get on a Dell Precision 690, 2xQuadcore Xeon 5345 @ 2.33 GHz, Windows 7 64-bit:

``````> system.time(GRPdur(10^6))
user  system elapsed
15.30    0.00   15.32
> system.time(sample(10^6))
user  system elapsed
0.03    0.00    0.03
``````

Here is what I get in Matlab 2011b

``````>> tic;p = GRPdur(10^6);disp(toc)
0.1364

tic;p = randperm(10^6);disp(toc)
0.1116
``````

Here is what I get in Matlab 2008a

``````>> tic;p=GRPdur(10^6);toc
Elapsed time is 0.124169 seconds.
>> tic;p=randperm(10^6);toc
Elapsed time is 0.211372 seconds.
>>
``````

LINKS : GRPdur is part of RPGlab, a package of Matlab functions that I wrote that generates and tests various random permutation generators. The notes can be viewed separately here: Notes on RPGlab.

The original Durstenfeld Algol program is here

-
Just curious: have you tried the for-loop code in Matlab? –  Dieter Menne Jan 14 '12 at 20:20
Because every time you modify an object in r, a copy is made. –  hadley Jan 14 '12 at 20:28
I can reduce the R version's time by a factor of 10 or so by properly vectorizing the creation of `r` outside the for loop and then using R's byte compiler on it (Matlab does JIT compiling by default right?). –  joran Jan 14 '12 at 20:33
@Dieter -- my GRPdur uses a for-loop, same as above –  Derek O'Connor Jan 15 '12 at 12:44
@joran -- Please show us exactly what you did. I "vectorized" the Matlab GPRdur by generating r(1:n) outside the loop. It took twice as long as the loopy version. Also it used extra space -- important for the size of permutations (> 10^6) I use. –  Derek O'Connor Jan 15 '12 at 12:54

Both Matlab and S (later R) started out as thin wrappers around FORTRAN functions for doing math stuff.

In S/R the for-loops have "always" been slow, but that has been OK because there are usually vectorized ways of expressing the problem. Also, R has thousands of functions in Fortran or C that do higher-level things quickly. For instance, the `sample` function which does exactly what your for-loop does - but much more quickly.

So why then is MATLAB much better at executing scripted for-loops? Two simple reasons: RESOURCES and PRIORITIES.

MathWorks who make MATLAB is a rather big company with around 2000 employees. They decided years ago to prioritize improving the performance of scripts. They hired a bunch of compiler experts and spent years developing a Just-In-Time compiler (JIT) that takes the script code and turns it into assembler code. They did a very good job too. Kudos to them!

R is open source, and the R core team works on improving R in their spare time. Luke Tierney of R core has worked hard and developed a compiler package for R that compiles R scripts to byte code. It does NOT turn it into assembler code however, but works pretty well. Kudos to him!

...But the amount of effort put into the R compiler vs. the MATLAB compiler is simply much less, and therefore the result is slower:

``````system.time(GRPdur(10^6)) # 9.50 secs

# Compile the function...
f <- compiler::cmpfun(GRPdur)
system.time(f(10^6)) # 3.69 secs
``````

As you can see, the for-loop became 3x faster by compiling it to byte code. Another difference is that the R JIT compiler is not enabled by default as it is in MATLAB.

UPDATE Just for the record, a slightly more optimized R version (based on Knuth's algorithm), where the random generation has been vectorized as @joran suggested:

``````f <- function(n) {
p <- integer(n)
p[1] <- 1L
rv <- runif(n, 1, 1:n) # random integer between 1 and k
for (k in 2:n) {
r <- rv[k]
p[k] = p[r]         #  Swap(p(r),p(k)).
p[r] = k
}
p
}
g <- compiler::cmpfun(f)
system.time(f(1e6)) # 4.84
system.time(g(1e6)) # 0.98

# Compare to Joran's version:
system.time(GRPdur1(10^6)) # 6.43
system.time(GRPdur2(10^6)) # 1.66
``````

...still a magnitude slower than MATLAB. But again, just use `sample` or `sample.int` which apparently beats MATLAB's `randperm` by 3x!

``````system.time(sample.int(10^6)) # 0.03
``````
-
"In S/R the for-loops have "always" been slow": This is a dangerous myth "in general". See Hadley's comment for the real reason. –  Dieter Menne Jan 15 '12 at 8:59
@DieterMenne - Hadley is conceptually correct but technically wrong. R does not always make a copy when modifying a vector, and not in the for-loop in the question. –  Tommy Jan 15 '12 at 9:48
@Tommy -- Thanks, that was very helpful. –  Derek O'Connor Jan 15 '12 at 10:38
@Tommy -- Revo R 2.13.2 > system.time(GRPdur(10^6)) user 15.41 > GRPdurF <- compiler::cmpfun(GRPdur) > system.time(GRPdurF(10^6)) user 7.28, but still 50 times slower than Matlab. –  Derek O'Connor Jan 15 '12 at 13:23
@DerekO'Connor - Yes, that's the effort that has gone into MATLAB. But according to your measurements R's `sample` is 3x faster than MATLAB's `randperm`. And that is the correct way to do it in both programs! –  Tommy Jan 15 '12 at 21:31

Because you wrote a c-program in an R-skin

``````n = 10^6L
p = 1:n
system.time( sample(p,n))
0.03    0.00    0.03
``````
-
Nice. Would be even nicer if you used `<-` for assignment :) –  Dirk Eddelbuettel Jan 14 '12 at 20:42
or `sample(n)`. –  Martin Morgan Jan 15 '12 at 1:43
I promise that I will use <- the day Rcpp works on default Windows installations (with spaces) .-) –  Dieter Menne Jan 15 '12 at 8:57
@Dieter -- I have never written a C program, and never will, given my age. I wrote (translated) a Matlab function into an R function. –  Derek O'Connor Jan 15 '12 at 13:33
@DerekO'Connor never fear, the dedicated programmer can write C programs in any language (or, if you're old enough, Fortran programs). –  Hong Ooi Jan 16 '12 at 5:28

Responding to the OP's request was too long to fit in a comment, so here's what I was referring to:

``````#Create r outside for loop
GRPdur1 <- function(n){
p <- 1:n
k <- seq(n,2,-1)
r <- 1 + floor(runif(length(k)) * k)
for (i in 1:length(k)){
tmp <- p[k[i]];
p[k[i]] <- p[r[i]];
p[r[i]] <- tmp;
}
return(p)
}

library(compiler)
GRPdur2 <- cmpfun(GRPdur1)

set.seed(1)
out1 <- GRPdur(100)

set.seed(1)
out2 <- GRPdur1(100)

#Check the GRPdur1 is generating the identical output
identical(out1,out2)

system.time(GRPdur(10^6))
user  system elapsed
12.948   0.389  13.232
system.time(GRPdur2(10^6))
user  system elapsed
1.908   0.018   1.910
``````

Not quite 10x, but more than the 3x Tommy showed just using the compiler. For a somewhat more accurate timing:

``````library(rbenchmark)
benchmark(GRPdur(10^6),GRPdur2(10^6),replications = 10)
test replications elapsed relative user.self sys.self
1  GRPdur(10^6)           10 127.315 6.670946   124.358    3.656
2 GRPdur2(10^6)           10  19.085 1.000000    19.040    0.222
``````

So the 10x comment was (perhaps not surprisingly, being based on a single `system.time` run) optimistic, but the vectorization gains you a fair bit more speed over what the byte compiler does.

-
Thanks for your time and effort. This is very useful information for a beginner. –  Derek O'Connor Jan 15 '12 at 14:12