# Surprisingly Slow Standard Deviation in R

I am calculating standard deviations on an expanding window where at each point I recalculate the standard deviation. This seems like a fairly straightforward thing to do that should be relatively fast. However, it takes a lot longer than you might think (~45 seconds). Am I missing something here? In Matlab this is quite fast.

``````t0 <- proc.time()[[3]]
z <- rep(0, 7000)
x <- rnorm(8000)
for(i in 1000:8000){
##    print(i)
z[i] <- sd(x[1:i])
}
print(proc.time()[[3]]- t0)
``````
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It's probably the for loop with memory slicing that's killing you. The call to sd will not be the bottleneck. –  David Heffernan Sep 19 '11 at 17:39
Also you're having to grow `z` because you start it with only 7000 but then put something in spots 7001:8000. –  Aaron Sep 19 '11 at 18:03
And your loop contains 7001 iterations. –  James Sep 20 '11 at 9:55

You might also try an algorithm that updates the standard deviation (well, actually, the sum of squares of differences from the mean) as you go. On my system this reduces the time from ~0.8 seconds to ~0.002 seconds.

``````n <- length(x)
m <- cumsum(x)/(1:n)
m1 <- c(NA,m[1:(n-1)])
ssd <- (x-m)*(x-m1)
v <- c(0,cumsum(ssd[-1])/(1:(n-1)))
z <- sqrt(v)
``````

Also see the answers to this question: Efficient calculation of matrix cumulative standard deviation in r

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Yep: always better to vectorize than to use *apply, and always better to use *apply than for/while . –  Carl Witthoft Sep 19 '11 at 18:41
@Carl Witthoft: "Yes" to your first assertion, "no" to your second. `apply` is just a wrapper using a for-loop. Look at the code. –  BondedDust Sep 19 '11 at 18:46
And even better to use a more appropriate algorithm. –  Aaron Sep 19 '11 at 18:49
@Dwin - `apply` might simply use a scripted for-loop but `lapply` and `vapply` certainly do not... And R core can improve `apply` in future releases... –  Tommy Sep 19 '11 at 22:44
@DWin - The compiler in R 2.14 can probably help, but currently the function lookup within a for-loop is not as efficient as the one in `lappy`/`vapply`. So calling a function that does some simple thing is much faster with `lapply`/`vapply`. I have a sample that doesn't fit here that is 4x faster with `vapply`... –  Tommy Sep 19 '11 at 23:32

Edited to fix some typos, sorry.

This takes ~1.3 seconds on my machine:

``````t0 <- proc.time()[[3]]
x <- rnorm(8000)
z <- sapply(1000:8000,function(y){sd(x[seq_len(y)])})
print(proc.time()[[3]]- t0)
``````

and I'd be willing to bet there are even faster ways of doing this. Avoid explicit `for` loops!

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Take the `rnorm()` call out of the timing on both approaches as it is fixed. –  Dirk Eddelbuettel Sep 19 '11 at 17:54
Yes, there are definitely better ways of doing this, this is more a thought experiment. However, another interesting conclusion is that when I run this on my windows version of R it is much faster (~.8 seconds). I am currently using a shared UNIX server with (with solaris operating system) which is probably contributing to the slowness. –  Bob Sep 19 '11 at 17:56

When a somewhat similar question about a cumulative variance and a cumularive kurtosis operation came up in rhelp a few days ago, here is what I offered :

``````daily <- rnorm(1000000)
mbar <- mean(daily)
cumvar <-  cumsum( (daily-cumsum(daily)/1:length(daily) )^2)
cumskew <- cumsum( (daily-cumsum(daily)/1:length(daily))^3)/cumvar^(3/2)
``````

It's certainly faster than the sapply method but may be comparable to Aaron's.

`````` system.time( cumvar <-  cumsum( (daily-cumsum(daily)/1:length(daily) )^2) )
user  system elapsed
0.037   0.026   0.061
system.time(cumsd <- sqrt(cumvar) )
user  system elapsed
0.009   0.005   0.013
``````
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Are you sure this is giving the right answer? I think the cumulative means aren't being used properly. Compare `cumvar[5]` with `var(daily[1:5])`. –  Aaron Sep 19 '11 at 19:25
My cumvar()iances are (supposed to be) the sums of variances to an index. Perhaps not the same as was requested. May need to take out one of the cumsums and get the denominator fixed before there is agreement. –  BondedDust Sep 19 '11 at 20:08
No, not quite the same as here. –  Aaron Sep 19 '11 at 20:26