I have been reading about how read.table is not efficient for large data files. Also how R is not suited for large data sets. So I was wondering where I can find what the practical limits are and any performance charts for (1) Reading in data of various sizes (2) working with data of varying sizes.

In effect, I want to know when the performance deteriorates and when I hit a road block. Also any comparison against C++/MATLAB or other languages would be really helpful. finally if there is any special performance comparison for Rcpp and RInside, that would be great!


R is suited for large data sets, but you may have to change your way of working somewhat from what the introductory textbooks teach you. I did a post on Big Data for R which crunches a 30 GB data set and which you may find useful for inspiration.

The usual sources for information to get started are High-Performance Computing Task View and the R-SIG HPC mailing list at R-SIG HPC.

The main limit you have to work around is a historic limit on the length of a vector to 2^31-1 elements which wouldn't be so bad if R did not store matrices as vectors. (The limit is for compatibility with some BLAS libraries.)

We regularly analyse telco call data records and marketing databases with multi-million customers using R, so would be happy to talk more if you are interested.

  • Do you have any statistics on how much data crunching you are doing using R and how much slower is it than say C++ like languages ? Thnx - Egon – Egon Mar 8 '11 at 16:14
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    @Egon: My background is such that my first instinct on any data analysis problem is to fire up a text editor and a Fortran compiler. But these days I find that the limiting factor in the analysis is much more my time figuring out the right approach and translating that into code. For that, R is so much more productive for me. For sure I have to think performance carefully when using R, but in truth so must you with compiled code. I do have some elements that we have compiled, but they are relative few and they were almost all designed and tested in R first. That's why R is faster. – Allan Engelhardt Mar 8 '11 at 19:16

The physical limits arise from the use of 32-bit indexes on vectors. As a result, vectors up to 2^31 - 1 are allowed. Matrices are vectors with dimensions, so the product of nrow(mat) and ncol(mat) must be within 2^31 - 1. Data frames and lists are general vectors, so each component can take 2^31 - 1 entries, which for data frames means you can have that many rows and columns. For lists you can have 2^31 - 1 components, each of 2^31 - 1 elements. This is drawn from a recent posting by Duncan Murdoch in reply to a Q on R-Help

Now that all has to fit in RAM with standard R so that might be a more pressing limit, but the High-Performance Computing Task View that others have mentioned contains details of packages that can circumvent the in-memory issues.


1) The R Import / Export manual should be the first port of call for questions about importing data - there are many options and what will work for your could be very specific.


read.table specifically has greatly improved performance if the options provided to it are used, particular colClasses, comment.char, and nrows - this is because this information has to be inferred from the data itself, which can be costly.

2) There is a specific limit for the length (total number of elements) for any vector, matrix, array, column in a data.frame, or list. This is due to a 32-bit index used under the hood, and is true for 32-bit and 64-bit R. The number is 2^31 - 1. This is the maximum number of rows for a data.frame, but it is so large you are far more likely to run out of memory for even single vectors before you start collecting several of them.

See help(Memory-limits) and help(Memory) for details.

A single vector of that length will take many gigabytes of memory (depends on the type and storage mode of each vector - 17.1 for numeric) so it's unlikely to be a proper limit unless you are really pushing things. If you really need to push things past the available system memory (64-bit is mandatory here) then standard database techniques as discussed in the import/export manual, or memory-mapped file options (like the ff package), are worth considering. The CRAN Task View High Performance Computing is a good resource for this end of things.

Finally, if you have stacks of RAM (16Gb or more) and need 64-bit indexing it might come in a future release of R. http://www.mail-archive.com/r-help@r-project.org/msg92035.html

Also, Ross Ihaka discusses some of the historical decisions and future directions for an R like language in papers and talks here: http://www.stat.auckland.ac.nz/~ihaka/?Papers_and_Talks


I can only answer the one about read.table, since I don't have any experience with large data sets. read.table performs poorly if you don't provide colClasses arguments. Without it, read.table defaults to NA and tries to guess a class of every column, and that can be slow, especially when you have a lot of columns.


When reading large csv files x GB <=> y.1e6 rows I think data.table::fread (as of version 1.8.7) is the quickest alternative you can get it doing install.packages("data.table", repos="http://R-Forge.R-project.org")

You usually gain a factor 5 to 10 (and all sep, row.names etc are dealt by the function itself). If you have many files and a decent enough computer (several cores), I recommend using the parallel package (as part of R.2.14) to load one file per core.

Last time I did this between monothreaded loading with read.csv and multithreaded on 4 cores use of fread I went from 5 minutes to 20 seconds

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