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i have a big performance problem in R. I wrote a function that iterates over an data.frame object. It simply adds a new col to a data.frame and accumulate sth. (simple operation). The data.frame has round about 850.000 rows. My PC is still working about 10h now and i have no idea about the runtime.

dayloop2 <- function(temp){
    for (i in 1:nrow(temp)){    
        temp[i,10] <- i
        if (i > 1) {             
            if ((temp[i,6] == temp[i-1,6]) & (temp[i,3] == temp[i-1,3])) { 
                temp[i,10] <- temp[i,9] + temp[i-1,10]                    
            } else {
                temp[i,10] <- temp[i,9]                                    
            }
        } else {
            temp[i,10] <- temp[i,9]
        }
    }
    names(temp)[names(temp) == "V10"] <- "Kumm."
    return(temp)
}

Any ideas how to speed up this operation ?

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6  
R is slow compared to what? How long is forever? –  Rafe Kettler Jun 28 '11 at 6:30
2  
Could you post the code and the structure and dimensions of your data set? Try Tinn-R for another editor, although Emacs and ESS are the (hard to learn) nonplusultra, in my opinion. –  Alexx Hardt Jun 28 '11 at 6:32
1  
I have been using R for a long time, and I think for a free scripting language it is not bad. But your question needs to be more precise. –  Alphaneo Jun 28 '11 at 6:34
    
You are free to use any editor of choice with R. However, your problem is probably with your code and not the editor. P.lease paste your specific code and we might be able to comment –  Andrie Jun 28 '11 at 7:50
9  
Googling around would have given you Tinn-R, Eclipse and StatET, Emacs and ESS as three widely used editors. For the rest : learn to use R correctly before you complain about it. If you drive a ferrari only in first gear, it will be a slow car as well. –  Joris Meys Jun 28 '11 at 10:16
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6 Answers

General strategies for speeding up R code

First, figure out where the slow part really is. There's no need to optimize code that isn't running slowly. For small amounts of code, simply thinking through it can work. If that fails, RProf and similar profiling tools can be helpful.

Once you figure out the bottleneck, think about more efficient algorithms for doing what you want. Calculations should be only run once if possible, so:

Using more efficient functions can produce moderate or large speed gains. For instance, paste0 produces a small efficiency gain but .colSums() and its relatives produce somewhat more pronounced gains. mean is particularly slow.

Then you can avoid some particularly common troubles:

  • cbind will slow you down really quickly.
  • Initialize your data structures, then fill them in, rather than expanding them each time.
  • Even with pre-allocation, you could switch to a pass-by-reference approach rather than a pass-by-value approach, but it may not be worth the hassle.
  • Take a look at the R Inferno for more pitfalls to avoid.

Try for better vectorization, which can often but not always help. In this regard, inherently vectorized commands like ifelse, diff, and the like will provide more improvement than the apply family of commands (which provide little to no speed boost over a well-written loop).

You can also try to provide more information to R functions. For instance, use vapply rather than sapply, and specify colClasses when reading in text-based data. Speed gains will be variable depending on how much guessing you eliminate.

Next, consider optimized packages: The data.table package can produce massive speed gains where its use is possible. If your bottleneck seems to be reading in large amounts of data, sqldf can help. Or, the new fread in data.table.

Next, try for speed gains through more efficient means of calling R:

  • Compile your R script. Or use the Ra and jit packages in concert for just-in-time compilation (Dirk has an example in this presentation).
  • Make sure you're using an optimized BLAS. These provide across-the-board speed gains. Honestly, it's a shame that R doesn't automatically use the most efficient library on install. Hopefully Revolution R will contribute the work that they've done here back to the overall community.
  • Radford Neal has done a bunch of optimizations, some of which were adopted into R Core, and many others which were forked off into pqR.

And lastly, if all of the above still doesn't get you quite as fast as you need, you may need to move to a faster language for the slow code snippet. The combination of Rcpp and inline here makes replacing only the slowest part of the algorithm with C++ code particularly easy. Here, for instance, is my first attempt at doing so, and it blows away even highly optimized R solutions.

If you're still left with troubles after all this, you just need more computing power. Look into parallelization (http://cran.r-project.org/web/views/HighPerformanceComputing.html) or even GPU-based solutions (gpu-tools).

Links to other guidance

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As Ari mentioned at the end of his answer, the Rcpp and inline packages make it incredibly easy to make things fast. As an example, try this inline code (warning: not tested):

body <- 'Rcpp::NumericMatrix nm(temp);
         int nrtemp = Rccp::as<int>(nrt);
         for (int i = 0; i < nrtemp; ++i) {
             temp(i, 9) = i
             if (i > 1) {
                 if ((temp(i, 5) == temp(i - 1, 5) && temp(i, 2) == temp(i - 1, 2) {
                     temp(i, 9) = temp(i, 8) + temp(i - 1, 9)
                 } else {
                     temp(i, 9) = temp(i, 8)
                 }
             } else {
                 temp(i, 9) = temp(i, 8)
             }
         return Rcpp::wrap(nm);
        '

settings <- getPlugin("Rcpp")
# settings$env$PKG_CXXFLAGS <- paste("-I", getwd(), sep="") if you want to inc files in wd
dayloop <- cxxfunction(signature(nrt="numeric", temp="numeric"), body-body,
    plugin="Rcpp", settings=settings, cppargs="-I/usr/include")

dayloop2 <- function(temp) {
    # extract a numeric matrix from temp, put it in tmp
    nc <- ncol(temp)
    nm <- dayloop(nc, temp)
    names(temp)[names(temp) == "V10"] <- "Kumm."
    return(temp)
}

There's a similar procedure for #includeing things, where you just pass a parameter

inc <- '#include <header.h>

to cxxfunction, as include=inc. What's really cool about this is that it does all of the linking and compilation for you, so prototyping is really fast.

Disclaimer: I'm not totally sure that the class of tmp should be numeric and not numeric matrix or something else. But I'm mostly sure.

Edit: if you still need more speed after this, OpenMP is a parallelization facility good for C++. I haven't tried using it from inline, but it should work. The idea would be to, in the case of n cores, have loop iteration k be carried out by k % n. A suitable introduction is found in Matloff's The Art of R Programming, available here, in chapter 16, Resorting to C.

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If you are using for loops, you are most likely coding R as if it was C or Java or something else. R code that is properly vectorised is extremely fast.

Take for example these two simple bits of code to generate a list of 10,000 integers in sequence:

The first code example is how one would code a loop using a traditional coding paradigm. It takes 28 seconds to complete

system.time({
    a <- NULL
    for(i in 1:1e5)a[i] <- i
})
   user  system elapsed 
  28.36    0.07   28.61 

You can get an almost 100-times improvement by the simple action of pre-allocating memory:

system.time({
    a <- rep(1, 1e5)
    for(i in 1:1e5)a[i] <- i
})

   user  system elapsed 
   0.30    0.00    0.29 

But using the base R vector operation using the colon operator : this operation is virtually instantaneous:

system.time(a <- 1:1e5)

   user  system elapsed 
      0       0       0 
share|improve this answer
    
+1 though I would regard your second example as unconvincing as a[i] does not change. But system.time({a <- NULL; for(i in 1:1e5){a[i] <- 2*i} }); system.time({a <- 1:1e5; for(i in 1:1e5){a[i] <- 2*i} }); system.time({a <- NULL; a <- 2*(1:1e5)}) has a similar result. –  Henry Jun 28 '11 at 7:06
    
@Henry, fair comment, but as you point out, the results are the same. I have modified the example to initialise a to rep(1, 1e5) - the timings are identical. –  Andrie Jun 28 '11 at 7:32
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Biggest problem and root of ineffectiveness is indexing data.frame, I mean all this lines where you use temp[,].
Try to avoid this as much as possible. I took your function, change indexing and here version_A

dayloop2_A <- function(temp){
    res <- numeric(nrow(temp))
    for (i in 1:nrow(temp)){    
        res[i] <- i
        if (i > 1) {             
            if ((temp[i,6] == temp[i-1,6]) & (temp[i,3] == temp[i-1,3])) { 
                res[i] <- temp[i,9] + res[i-1]                   
            } else {
                res[i] <- temp[i,9]                                    
            }
        } else {
            res[i] <- temp[i,9]
        }
    }
    temp$`Kumm.` <- res
    return(temp)
}

As you can see I create vector res which gather results. At the end I add it to data.frame and I don't need to mess with names. So how better is it?

I run each function for data.frame with nrow from 1,000 to 10,000 by 1,000 and measure time with system.time

X <- as.data.frame(matrix(sample(1:10, n*9, TRUE), n, 9))
system.time(dayloop2(X))

Result is

performance

You can see that your version depends exponentially from nrow(X). Modified version has linear relation, and simple lm model predict that for 850,000 rows computation takes 6 minutes and 10 seconds.

Power of vectorization

As Shane and Calimo states in theirs answers vectorization is a key to better performance. From your code you could move outside of loop:

  • conditioning
  • initialization of the results (which are temp[i,9])

This leads to this code

dayloop2_B <- function(temp){
    cond <- c(FALSE, (temp[-nrow(temp),6] == temp[-1,6]) & (temp[-nrow(temp),3] == temp[-1,3]))
    res <- temp[,9]
    for (i in 1:nrow(temp)) {
        if (cond[i]) res[i] <- temp[i,9] + res[i-1]
    }
    temp$`Kumm.` <- res
    return(temp)
}

Compare result for this functions, this time for nrow from 10,000 to 100,000 by 10,000.

performance

Tuning the tuned

Another tweak is to changing in a loop indexing temp[i,9] to res[i] (which are exact the same in i-th loop iteration). It's again difference between indexing a vector and indexing a data.frame.
Second thing: when you look on the loop you can see that there is no need to loop over all i, but only for the ones that fit condition.
So here we go

dayloop2_D <- function(temp){
    cond <- c(FALSE, (temp[-nrow(temp),6] == temp[-1,6]) & (temp[-nrow(temp),3] == temp[-1,3]))
    res <- temp[,9]
    for (i in (1:nrow(temp))[cond]) {
        res[i] <- res[i] + res[i-1]
    }
    temp$`Kumm.` <- res
    return(temp)
}

Performance which you gain highly depends on a data structure. Precisely - on percent of TRUE values in the condition. For my simulated data it takes computation time for 850,000 rows below the one second.

performance

I you want you can go further, I see at least two things which can be done:

  • write a C code to do conditional cumsum
  • if you know that in your data max sequence isn't large then you can change loop to vectorized while, something like

    while (any(cond)) {
        indx <- c(FALSE, cond[-1] & !cond[-n])
        res[indx] <- res[indx] + res[which(indx)-1]
        cond[indx] <- FALSE
    }
    
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6  
Excellent answer! –  Dr. ABT Jul 30 '11 at 14:38
3  
This answer is money. I hope you win a badge or something :) –  nielsbot Dec 12 '11 at 18:31
2  
Woa. I stumbled on this by checking why someone got a necromancer badge, and saw this answer. Very, very good stuff! I don't even use R. I have, but not more than once. :) –  Almo Feb 9 '12 at 20:01
    
this is so nice! thanks a lot! –  te_ar Oct 18 '12 at 13:16
1  
As I can't find a way of asking Marek privatly, how were those graphs generated? –  carbontwelve Jul 25 '13 at 11:11
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This could be made much faster by skipping the loops by using indexes or nested ifelse() statements.

idx <- 1:nrow(temp)
temp[,10] <- idx
idx1 <- c(FALSE, (temp[-nrow(temp),6] == temp[-1,6]) & (temp[-nrow(temp),3] == temp[-1,3]))
temp[idx1,10] <- temp[idx1,9] + temp[which(idx1)-1,10] 
temp[!idx1,10] <- temp[!idx1,9]    
temp[1,10] <- temp[1,9]
names(temp)[names(temp) == "V10"] <- "Kumm."
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I just discovered ifelse last night, amazed at how much it has sped up some of my code. –  Stedy May 25 '10 at 23:08
    
Thanks for the answer. I try to understand your statements. The line 4: "temp[idx1,10] <- temp[idx1,9] + temp[which(idx1)-1,10]" caused an error because the length of longer object is not a multiple of the length of the shorter object. "temp[idx1,9] = num [1:11496]" and "temp[which(idx1)-1,10] = int [1:11494]" so 2 rows are missing. –  Kay May 26 '10 at 2:12
    
If you provide a data sample (use dput() with a few rows) then I'll fix it for you. Because of the which()-1 bit, the indexes are unequal. But you should see how it works from here: there's no need for any looping or applying; just use vectorized functions. –  Shane May 26 '10 at 14:20
1  
Wow! I've just changed an nested if..else function block and mapply, to a nested ifelse function and got a 200x speedup! –  James May 26 '10 at 16:16
    
Your general advice is aright, but in code you missed fact, that i-th value depends on i-1-th so they can't be set in way you do it (using which()-1). –  Marek Jun 4 '10 at 10:01
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In R, you can often speed-up loop processing by using the apply family functions (in your case, it would probably be replicate). Have a look at the plyr package that provides progress bars.

Another option is to avoid loops altogether and replace them with vectorized arithmetics. I'm not sure exactly what you are doing, but you can probably apply your function to all rows at once:

temp[1:nrow(temp), 10] <- temp[1:nrow(temp), 9] + temp[0:(nrow(temp)-1), 10]

This will be much much faster, and then you can filter the rows with your condition:

cond.i <- (temp[i, 6] == temp[i-1, 6]) & (temp[i, 3] == temp[i-1, 3])
temp[cond.i, 10] <- temp[cond.i, 9]

Vectorized arithmetics requires more time and thinking about the problem, but then you can sometimes save several orders of magnitude in execution time.

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6  
you're spot on that vector functions will be faster than loops or apply() but it's not true that apply() is faster than loops. In many cases apply() is simply abstracting the loop away from the user but still looping. See this previous question: stackoverflow.com/questions/2275896/… –  JD Long May 26 '10 at 16:03
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