Out of curiosity, what do you think the proportion of all R users is for whom performance/speed of R is basically never going to be a limiting factor as long as they write "reasonable" code?
@joran That's going to be really hard to determine. R users are so diverse, I don't think anyone knows enough about all the different disciplines to make anything more than a wild guess.
Well, I wasn't hoping to be all scientific about it. I just think that there's a pretty simple explanation for "why R is so popular despite all its drawbacks": its drawbacks simply don't matter to a very large proportion of its users.
Wild guess: Most users are not speed limited, but are memory limited. I bet 10x more users run into "can not allocate vector of size..." than speed problems
@Andrie In your own work do you routinely find that even with well written code R's performance (i.e. speed) isn't good enough, and you have to turn to other languages or supplements (like Rcpp or something)?
joran, if you want to start counting: I'm continuously hitting memory limits. Memory limits cause speed limits: how much I can parallelize is usually determined by available memory. In a few weeks you can hopefully mark me as real speed limitation as well. So far, everything could be done within a few nights....
@joran No, not really. Properly written R code is really quite fast. But it does mean I have had to jump through all kinds of hoops to replace plyr with base R code or data.table, and to rewrite a bunch of graphics in lattice where I had it in ggplot2 in the first place.
@Andrie That matches my experience as well: it's not that R can't be fast, its that making it fast isn't nearly as straightforward or convenient folks expect.
@joran Agreed. And some stuff is just slow. Like reading a large csv file. (150K rows takes 6 seconds, for example, but using native Linux tools this is pretty much instantaneous.) And I have not seen any way around this.
I have 3 files A ,B ,C as binary files. C represents the values of tepm measured every 3 hours for one month so it has 674200 columns and 248 rows.values of A represent the correspond lines(these values could be within 1to360) and , while values of B represent the correspond pixel(1to720) for eac...
@Tommy I regularly have to read in 4M line csv files and it is quite slow. The other slow step is writing out plots to files. (I'm on an i7 with a SSD...)
@Tommy ggplot2 used to be slow in general. The latest version might be quicker, I'm not sure.
But no - everything has the possibility of being slow, unless you are very careful.
In my case, I do a lot of survey analysis. A single question might only take 2-5 seconds to analyse, including analysis, creating plots and writing results to file (I wrote a memory caching system, so the file write isn't the bottle neck.)
But do that on just 25 qeustions with 4 cross-breaks each, and you're suddenly looking at report generation time of ~6 minutes.
So I had to write another caching system that checks whether things changed between the last run and this run, and cache the plots to disk, then compare the MD5 sum, then... you get the picture.
@JoshuaUlrich: Unfortunately only 8 GB for 12 cores (but yes, of course they are 64 bit). But our imaging instrument can produce something like 250 GB of good quality spectral images a day... The 8 GB server was bought by computational phyicists: they need computational power but not that much memory. We usually have computationally rather easy problems, but quite larger data...
@Andrie - could you elaborate on the analysis step then?
@cbeleites - What kind of analysis do you do? Would less memory-intense algorithms be the solution for you then? - Or perhaps just buying more memory ;-)
just, you know: it is another group who own it. And our project is incredibly picky about what money is to be spent on what... I tried to argue that an external HD for backups is a consumable, but no way...
On the whole, if I have, say 250.000 spectra x 400 data points (there could be more, but I don't take more - someone has to analyse all the data...) that amounts to 750 MB. I can comfortably live with that as long as my colleague stays away from the server with his data. Fortunately, our desks are side by side, so this kind of communication is easy: "Do you need the server for the next hours?" "Go ahead, you can have it"
I mean, obviously the things you do with the data will depend on what resources you have. Fortunately the imaging spectrometer produces the raw data in files of 64 x 64 spatial pixels x typically ca. 4000 wavelengths, i.e. chunks of 128 MB. So I do a whole lot of data reduction pre-processing first with moderate parallelisation (say, 4 threads), and decide parameters on a small random sample of the data.
I keep thinking that what I'd really need is a pre-processing that clustes together everything up to a given level of dissimilarity. But with other (for us, mainly k-means and fuzzy c-means) clustering, I've had the experience that I missed small but very different and interesting clusters, even though I was running the k-means a couple of times.
Actually, what I found powerful technique is a combination of HCA and then fuzzy clustering with the start centroids from the HCA: the dendrogram is very useful in judging the number of clusters.