I have very large tables (30 million rows) that I would like to load as a dataframes in R. read.table() has a lot of convenient features, but it seems like there is a lot of logic in the implementation that would slow things down. In my case, I am assuming I know the types of the columns ahead of time, the table does not contain any column headers or row names, and does not have any pathological characters that I have to worry about.

I know that reading in a table as a list using scan() can be quite fast, e.g.:

datalist <- scan('myfile',sep='\t',list(url='',popularity=0,mintime=0,maxtime=0)))

But some of my attempts to convert this to a dataframe appear to decrease the performance of the above by a factor of 6:

df <- as.data.frame(scan('myfile',sep='\t',list(url='',popularity=0,mintime=0,maxtime=0))))

Is there a better way of doing this? Or quite possibly completely different approach to the problem?


An update, several years later

This answer is old, and R has moved on. Tweaking read.table to run a bit faster has precious little benefit. Your options are:

  1. Using fread in data.table for importing data from csv/tab-delimited files directly into R. See mnel's answer.

  2. Using read_table in readr (on CRAN from April 2015). This works much like fread above. The readme in the link explains the difference between the two functions (readr currently claims to be "1.5-2x slower" than data.table::fread).

  3. read.csv.raw from iotools provides a third option for quickly reading CSV files.

  4. Trying to store as much data as you can in databases rather than flat files. (As well as being a better permanent storage medium, data is passed to and from R in a binary format, which is faster.) read.csv.sql in the sqldf package, as described in JD Long's answer, imports data into a temporary SQLite database and then reads it into R. See also: the RODBC package, and the reverse depends section of the DBI package page. MonetDB.R gives you a data type that pretends to be a data frame but is really a MonetDB underneath, increasing performance. Import data with its monetdb.read.csv function. dplyr allows you to work directly with data stored in several types of database.

  5. Storing data in binary formats can also be useful for improving performance. Use saveRDS/readRDS (see below), the h5 or rhdf5 packages for HDF5 format, or write_fst/read_fst from the fst package.

The original answer

There are a couple of simple things to try, whether you use read.table or scan.

  1. Set nrows=the number of records in your data (nmax in scan).

  2. Make sure that comment.char="" to turn off interpretation of comments.

  3. Explicitly define the classes of each column using colClasses in read.table.

  4. Setting multi.line=FALSE may also improve performance in scan.

If none of these thing work, then use one of the profiling packages to determine which lines are slowing things down. Perhaps you can write a cut down version of read.table based on the results.

The other alternative is filtering your data before you read it into R.

Or, if the problem is that you have to read it in regularly, then use these methods to read the data in once, then save the data frame as a binary blob with save saveRDS, then next time you can retrieve it faster with load readRDS.

  • 4
    Thanks for the tips Richie. I did a little testing, and it seems that the performance gains with using the nrow and colClasses options for read.table are quite modest. For example, reading a ~7M row table takes 78s without the options, and 67s with the options. (note: the table has 1 character column, 4 integer columns, and I read using comment.char='' and stringsAsFactors=FALSE). Using save() and load() when possible is a great tip - once stored with save(), that same table takes only 12s to load. – eytan Nov 14 '09 at 6:00
  • 1
    The "feather" package has a new binary format that plays nice with Python's pandas data frames – rsoren Mar 30 '16 at 9:53
  • 2
    I think maybe you need to update your post again with regards to the package feather. For reading data feather is much faster than fread. For example on a 4GB dataset I just loaded read_feather was about 4.5 times faster than fread. For saving data fwrite is still faster. blog.dominodatalab.com/the-r-data-i-o-shootout – Z boson Dec 8 '16 at 10:42
  • 2
    But the file sizes are much larger for feather than with RDS. I don't think it supports compression. The RDS file is 216 MB and the feather file is 4GB. So feather is faster for reading but it uses a lot more storage space. – Z boson Dec 8 '16 at 10:48
  • @Zboson If you need to store data frame in a file that can be accessed from both R and Python, then feather is a good option. If you only care about being able to read your data in R, rds is preferable. – Richie Cotton Dec 12 '16 at 15:05

Here is an example that utilizes fread from data.table 1.8.7

The examples come from the help page to fread, with the timings on my windows XP Core 2 duo E8400.

# Demo speedup
DT = data.table( a=sample(1:1000,n,replace=TRUE),
                 f=sample(1:1000,n,replace=TRUE) )

standard read.table

cat("File size (MB):",round(file.info("test.csv")$size/1024^2),"\n")    
## File size (MB): 51 

system.time(DF1 <- read.csv("test.csv",stringsAsFactors=FALSE))        
##    user  system elapsed 
##   24.71    0.15   25.42
# second run will be faster
system.time(DF1 <- read.csv("test.csv",stringsAsFactors=FALSE))        
##    user  system elapsed 
##   17.85    0.07   17.98

optimized read.table

system.time(DF2 <- read.table("test.csv",header=TRUE,sep=",",quote="",  

##    user  system elapsed 
##   10.20    0.03   10.32


system.time(DT <- fread("test.csv"))                                  
 ##    user  system elapsed 
##    3.12    0.01    3.22



system.time(SQLDF <- read.csv.sql("test.csv",dbname=NULL))             

##    user  system elapsed 
##   12.49    0.09   12.69

# sqldf as on SO

f <- file("test.csv")
system.time(SQLf <- sqldf("select * from f", dbname = tempfile(), file.format = list(header = T, row.names = F)))

##    user  system elapsed 
##   10.21    0.47   10.73

ff / ffdf


 system.time(FFDF <- read.csv.ffdf(file="test.csv",nrows=n))   
 ##    user  system elapsed 
 ##   10.85    0.10   10.99

In summary:

##    user  system elapsed  Method
##   24.71    0.15   25.42  read.csv (first time)
##   17.85    0.07   17.98  read.csv (second time)
##   10.20    0.03   10.32  Optimized read.table
##    3.12    0.01    3.22  fread
##   12.49    0.09   12.69  sqldf
##   10.21    0.47   10.73  sqldf on SO
##   10.85    0.10   10.99  ffdf
  • 37
    Great answer, and the benchmarking holds in other contexts. Just read in a 4GB file in well under a minute with fread. Had tried reading it in with the base R functions and it took about 15 hours. – Ari B. Friedman Sep 12 '13 at 13:55
  • 1
    my benchmark suggest even greater speed advantages for read.csv in data.table. note that data.table is not standard R, but (sadly) "just" nicely shared by its creators on CRAN. it is not even deemed standard enough to make the common R package list, much less qualify as a replacement for data frames. it has a lot of advantages, but also some very counterintuitive aspects. you may want to use as.data.frame(fread.csv("test.csv")) with the package to get back into the standard R data frame world. – ivo Welch Mar 17 '15 at 2:31
  • 5
    @ivoWelch you can use fread("test.csv", data.table=FALSE) – jangorecki Aug 8 '15 at 23:15
  • 3
    @mnel could you please re-run the benchmark and include readr? – jangorecki Dec 9 '15 at 2:33
  • 2
    Second @jangorecki. Also, given fread has some real competitors now, could be useful to add benchmarks for optimized fread usage -- specifying colClasses, etc. – MichaelChirico Feb 7 '16 at 20:23

I didn't see this question initially and asked a similar question a few days later. I am going to take my previous question down, but I thought I'd add an answer here to explain how I used sqldf() to do this.

There's been little bit of discussion as to the best way to import 2GB or more of text data into an R data frame. Yesterday I wrote a blog post about using sqldf() to import the data into SQLite as a staging area, and then sucking it from SQLite into R. This works really well for me. I was able to pull in 2GB (3 columns, 40mm rows) of data in < 5 minutes. By contrast, the read.csv command ran all night and never completed.

Here's my test code:

Set up the test data:

bigdf <- data.frame(dim=sample(letters, replace=T, 4e7), fact1=rnorm(4e7), fact2=rnorm(4e7, 20, 50))
write.csv(bigdf, 'bigdf.csv', quote = F)

I restarted R before running the following import routine:

f <- file("bigdf.csv")
system.time(bigdf <- sqldf("select * from f", dbname = tempfile(), file.format = list(header = T, row.names = F)))

I let the following line run all night but it never completed:

system.time(big.df <- read.csv('bigdf.csv'))
  • 11
    See also read.csv.sql – James Sep 28 '10 at 15:00
  • 1
    Hi. How woul you use it as an input for other packages such as zoo, designed to be used with all data simultenously? – skan Mar 27 '13 at 1:15
  • @skan the end object is a data frame. So you have to convert it to a zoo object in order to use it with zoo. Look at the examples in the zoo docs for illustrations. – JD Long Apr 2 '13 at 12:48
  • @JD Long. Hi, the problem is that when you convert it to a zoo object it tries to fit it on the memory. If it's too big it produces an error. And if the result of the zoo object (for example an aggregation of two series) is also too it would need to be a sql or ff object too. – skan Apr 3 '13 at 14:03
  • 1
    @what m is thousand so mm is thousand thousand, or million. I probably should have capitalized it as MM. But I find that just about any million abbreviation can be confusing to someone if you have a diverse enough audience. In my attempt to be overly verbose, I'm sorry that I made it more confusing! accountingcoach.com/blog/what-does-m-and-mm-stand-for – JD Long Jan 4 '16 at 19:13

Strangely, no one answered the bottom part of the question for years even though this is an important one -- data.frames are simply lists with the right attributes, so if you have large data you don't want to use as.data.frame or similar for a list. It's much faster to simply "turn" a list into a data frame in-place:

attr(df, "row.names") <- .set_row_names(length(df[[1]]))
class(df) <- "data.frame"

This makes no copy of the data so it's immediate (unlike all other methods). It assumes that you have already set names() on the list accordingly.

[As for loading large data into R -- personally, I dump them by column into binary files and use readBin() - that is by far the fastest method (other than mmapping) and is only limited by the disk speed. Parsing ASCII files is inherently slow (even in C) compared to binary data.]

  • 6
    Using tracmem suggests that attr<- and class<- make copies internally. bit::setattr or data.table::setattr will not. – mnel Dec 20 '12 at 4:20
  • 6
    Maybe you used the wrong order? There is no copy if you use df=scan(...); names(df)=...; attr...; class... - see tracemem() (tested in R 2.15.2) – Simon Urbanek Dec 20 '12 at 4:31
  • 1
    Odd. I could have sworn I managed to replicate my copying..... But not again. – mnel Dec 20 '12 at 4:49
  • 3
    Can you elaborate on how you dump the large data by column into binary files? – dabsingh Sep 14 '16 at 23:32

This was previously asked on R-Help, so that's worth reviewing.

One suggestion there was to use readChar() and then do string manipulation on the result with strsplit() and substr(). You can see the logic involved in readChar is much less than read.table.

I don't know if memory is an issue here, but you might also want to take a look at the HadoopStreaming package. This uses Hadoop, which is a MapReduce framework designed for dealing with large data sets. For this, you would use the hsTableReader function. This is an example (but it has a learning curve to learn Hadoop):

str <- "key1\t3.9\nkey1\t8.9\nkey1\t1.2\nkey1\t3.9\nkey1\t8.9\nkey1\t1.2\nkey2\t9.9\nkey2\"
cols = list(key='',val=0)
con <- textConnection(str, open = "r")

The basic idea here is to break the data import into chunks. You could even go so far as to use one of the parallel frameworks (e.g. snow) and run the data import in parallel by segmenting the file, but most likely for large data sets that won't help since you will run into memory constraints, which is why map-reduce is a better approach.

  • I just did a quick test and readChar does seem to be much faster than even readLines for some inexplicable reason. However, it is still slow as sin compared to a simple C test. At the simple task of reading 100 megs, R is about 5 - 10x slower than C – Jonathan Chang Nov 13 '09 at 20:12
  • 1
    Don't understand your point. The point of Hadoop is to handle very large data, which is what the question was about. – Shane Jan 23 '10 at 1:33
  • 1
    Despite the name, hsTableReader doesn't have anything to do with Hadoop per se, it's for processing large data in pieces. It reads from con, a chunk of rows at a time, and passes each chunk as a data.frame to FUN for processing. With ignoreKey=FALSE, it does some extra grouping by key (the entry in the first column), which is relevant to Map/Reduce approaches. – DavidR Mar 4 '13 at 22:46
  • Hi. How would you use this Hadoop data as an input for other packages such as zoo, designed to be used with all data simultenously? – skan Mar 27 '13 at 1:15

A minor additional points worth mentioning. If you have a very large file you can on the fly calculate the number of rows (if no header) using (where bedGraph is the name of your file in your working directory):

>numRow=as.integer(system(paste("wc -l", bedGraph, "| sed 's/[^0-9.]*\\([0-9.]*\\).*/\\1/'"), intern=T))

You can then use that either in read.csv , read.table ...

>system.time((BG=read.table(bedGraph, nrows=numRow, col.names=c('chr', 'start', 'end', 'score'),colClasses=c('character', rep('integer',3)))))
   user  system elapsed 
 25.877   0.887  26.752 
203949432 bytes

An alternative is to use the vroom package. Now on CRAN. vroom doesn't load the entire file, it indexes where each record is located, and is read later when you use it.

Only pay for what you use.

See Introduction to vroom, Get started with vroom and the vroom benchmarks.

The basic overview is that the initial read of a huge file, will be much faster, and subsequent modifications to the data may be slightly slower. So depending on what your use is, it could be the best option.

See a simplified example from vroom benchmarks below, the key parts to see is the super fast read times, but slightly sower operations like aggregate etc..

package                 read    print   sample   filter  aggregate   total
read.delim              1m      21.5s   1ms      315ms   764ms       1m 22.6s
readr                   33.1s   90ms    2ms      202ms   825ms       34.2s
data.table              15.7s   13ms    1ms      129ms   394ms       16.3s
vroom (altrep) dplyr    1.7s    89ms    1.7s     1.3s    1.9s        6.7s

Often times I think it is just good practice to keep larger databases inside a database (e.g. Postgres). I don't use anything too much larger than (nrow * ncol) ncell = 10M, which is pretty small; but I often find I want R to create and hold memory intensive graphs only while I query from multiple databases. In the future of 32 GB laptops, some of these types of memory problems will disappear. But the allure of using a database to hold the data and then using R's memory for the resulting query results and graphs still may be useful. Some advantages are:

(1) The data stays loaded in your database. You simply reconnect in pgadmin to the databases you want when you turn your laptop back on.

(2) It is true R can do many more nifty statistical and graphing operations than SQL. But I think SQL is better designed to query large amounts of data than R.

# Looking at Voter/Registrant Age by Decade


con <- dbConnect(PostgreSQL(), user= "postgres", password="password",
                 port="2345", host="localhost", dbname="WC2014_08_01_2014")

Decade_BD_1980_42 <- dbGetQuery(con,"Select PrecinctID,Count(PrecinctID),extract(DECADE from Birthdate) from voterdb where extract(DECADE from Birthdate)::numeric > 198 and PrecinctID in (Select * from LD42) Group By PrecinctID,date_part Order by Count DESC;")

Decade_RD_1980_42 <- dbGetQuery(con,"Select PrecinctID,Count(PrecinctID),extract(DECADE from RegistrationDate) from voterdb where extract(DECADE from RegistrationDate)::numeric > 198 and PrecinctID in (Select * from LD42) Group By PrecinctID,date_part Order by Count DESC;")

with(Decade_BD_1980_42,(barchart(~count | as.factor(precinctid))));
mtext("42LD Birthdays later than 1980 by Precinct",side=1,line=0)

with(Decade_RD_1980_42,(barchart(~count | as.factor(precinctid))));
mtext("42LD Registration Dates later than 1980 by Precinct",side=1,line=0)

Instead of the conventional read.table I feel fread is a faster function. Specifying additional attributes like select only the required columns, specifying colclasses and string as factors will reduce the time take to import the file.

data_frame <- fread("filename.csv",sep=",",header=FALSE,stringsAsFactors=FALSE,select=c(1,4,5,6,7),colClasses=c("as.numeric","as.character","as.numeric","as.Date","as.Factor"))

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