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For example (not sure if most representative example though):

N <- 1e6
d1 <- data.frame(x=sample(N,N), y1=rnorm(N))
d2 <- data.frame(x=sample(N,N), y2=rnorm(N))

This is what I've got so far:

d <- merge(d1,d2)
# 7.6 sec

library(plyr)
d <- join(d1,d2)
# 2.9 sec

library(data.table)
dt1 <- data.table(d1, key="x")
dt2 <- data.table(d2, key="x")
d <- data.frame( dt1[dt2,list(x,y1,y2=dt2$y2)] )
# 4.9 sec

library(sqldf)
sqldf()
sqldf("create index ix1 on d1(x)")
sqldf("create index ix2 on d2(x)")
d <- sqldf("select * from d1 inner join d2 on d1.x=d2.x")
sqldf()
# 17.4 sec
share|improve this question
    
The proper way to do the sqldf way is pointed out below by Gabor: create only one index (say on d1) and use d1.main instead of d1 in the select statement (otherwise it won't use the index). Timing is in this case 13.6 sec. Building indexes on both tables is actually not necessary in the data.table case either, just do "dt2 <- data.table(d2)" and the timing will be 3.9 sec. –  datasmurf Dec 1 '10 at 23:16
    
Both answers provide valuable information, worth reading both (though only one can be "accepted"). –  datasmurf Dec 3 '10 at 16:47
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4 Answers

up vote 26 down vote accepted

The match approach works when there is a unique key in the second data frame for each key value in the first. If there are duplicates in the second data frame then the match and merge approaches are not the same. Match is, of course, faster since it is not doing as much. In particular it never looks for duplicate keys. (continued after code)


> DF1 = data.frame(a = c(1, 1, 2, 2), b = 1:4)
> DF2 = data.frame(b = c(1, 2, 3, 3, 4), c = letters[1:5])
> merge(DF1, DF2)
      b a c
    1 1 1 a
    2 2 1 b
    3 3 2 c
    4 3 2 d
    5 4 2 e
> DF1$c = DF2$c[match(DF1$b, DF2$b)]
> DF1$c
[1] a b c e
Levels: a b c d e
> DF1
  a b c
1 1 1 a
2 1 2 b
3 2 3 c
4 2 4 e

In the sqldf code that was posted in the question, it might appear that indexes were used on the two tables but, in fact, they are placed on tables which were overwritten before the sql select ever runs and that, in part, accounts for why its so slow. The idea of sqldf is that the data frames in your R session constitute the data base, not the tables in sqlite. Thus each time the code refers to an unqualified table name it will look in your R workspace for it -- not in sqlite's main database. Thus the select statement that was shown reads d1 and d2 from the workspace into sqlite's main database clobbering the ones that were there with the indexes. As a result it does a join with no indexes. If you wanted to make use of the versions of d1 and d2 that were in sqlite's main database you would have to refer to them as main.d1 and main.d2 and not as d1 and d2. Also, if you are trying to make it run as fast as possible then note that a simple join can't make use of indexes on both tables so you can save the time of creating one of the indexes. In the code below we illustrate these points.

Its worthwhile to notice that the precise computation can make a huge difference on which package is fastest. For example, we do a merge and an aggregate below. We see that the results are nearly reversed for the two. In the first example from fastest to slowest we get: data.table, plyr, merge and sqldf whereas in the second example sqldf, aggregate, data.table and plyr -- nearly the reverse of the first one. In the first example sqldf is 3x slower than data.table and in the second its 200x faster than plyr and 100 times faster than data.table. Below we show the input code, the output timings for the merge and the output timings for the aggregate. Its also worthwhile noting that sqldf is based on a database and therefore can handle objects larger than R can handle (if you use the dbname argument of sqldf) while the other approaches are limited to processing in main memory. Also we have illustrated sqldf with sqlite but it also supports the H2 and PostgreSQL databases as well.


library(plyr)
library(data.table)
library(sqldf)

set.seed(123) N <- 1e5 d1 <- data.frame(x=sample(N,N), y1=rnorm(N)) d2 <- data.frame(x=sample(N,N), y2=rnorm(N))

g1 <- sample(1:1000, N, replace = TRUE) g2<- sample(1:1000, N, replace = TRUE) d <- data.frame(d1, g1, g2)

library(rbenchmark)

benchmark(replications = 1, order = "elapsed", merge = merge(d1, d2), plyr = join(d1, d2), data.table = { dt1 <- data.table(d1, key = "x") dt2 <- data.table(d2, key = "x") data.frame( dt1[dt2,list(x,y1,y2=dt2$y2)] ) }, sqldf = sqldf(c("create index ix1 on d1(x)", "select * from main.d1 join d2 using(x)")) )

set.seed(123)
N <- 1e5
g1 <- sample(1:1000, N, replace = TRUE)
g2<- sample(1:1000, N, replace = TRUE)
d <- data.frame(x=sample(N,N), y=rnorm(N), g1, g2)

benchmark(replications = 1, order = "elapsed", aggregate = aggregate(d[c("x", "y")], d[c("g1", "g2")], mean), data.table = { dt <- data.table(d, key = "g1,g2") dt[, colMeans(cbind(x, y)), by = "g1,g2"] }, plyr = ddply(d, .(g1, g2), summarise, avx = mean(x), avy=mean(y)), sqldf = sqldf(c("create index ix on d(g1, g2)", "select g1, g2, avg(x), avg(y) from main.d group by g1, g2")) )

The outputs from the two benchmark call comparing the merge calculations are:

Joining by: x
        test replications elapsed relative user.self sys.self user.child sys.child
3 data.table            1    0.34 1.000000      0.31     0.01         NA        NA
2       plyr            1    0.44 1.294118      0.39     0.02         NA        NA
1      merge            1    1.17 3.441176      1.10     0.04         NA        NA
4      sqldf            1    3.34 9.823529      3.24     0.04         NA        NA

The output from the benchmark call comparing the aggregate calculations are:

        test replications elapsed  relative user.self sys.self user.child sys.child
4      sqldf            1    2.81  1.000000      2.73     0.02         NA        NA
1  aggregate            1   14.89  5.298932     14.89     0.00         NA        NA
2 data.table            1  132.46 47.138790    131.70     0.08         NA        NA
3       plyr            1  212.69 75.690391    211.57     0.56         NA        NA

share|improve this answer
    
Thank you, Gabor. Excellent points, I made some adjustments via comments to the original question. Actually I guess the order might change even in the "merge" case depending on the relative sizes of the tables, multiplicity of keys etc. (that's why I said I'm not sure if my example is representative). Nonetheless, it's nice to see all the different solutions to the problem. –  datasmurf Dec 1 '10 at 23:27
    
I appreciate also the comment about the "aggregation" case. Although this is different than the "merge" setup in the question, it is very relevant. I would have actually asked about it in a separate question, but there is already one here stackoverflow.com/questions/3685492/… . You might want to contribute to that one as well, as based on the results above, the sqldf solution might beat all the existing answers there ;) –  datasmurf Dec 1 '10 at 23:37
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The 132 seconds reported in Gabor's results for data.table is actually timing base functions colMeans and cbind (the memory allocation and copying induced by using those functions). There are good and bad ways of using data.table, too.

benchmark(replications = 1, order = "elapsed", 
  aggregate = aggregate(d[c("x", "y")], d[c("g1", "g2")], mean),
  data.tableBad = {
     dt <- data.table(d, key = "g1,g2") 
     dt[, colMeans(cbind(x, y)), by = "g1,g2"]
  }, 
  data.tableGood = {
     dt <- data.table(d, key = "g1,g2") 
     dt[, list(mean(x),mean(y)), by = "g1,g2"]
  }, 
  plyr = ddply(d, .(g1, g2), summarise, avx = mean(x), avy=mean(y)),
  sqldf = sqldf(c("create index ix on d(g1, g2)",
      "select g1, g2, avg(x), avg(y) from main.d group by g1, g2"))
  ) 

            test replications elapsed relative user.self sys.self
3 data.tableGood            1    0.15    1.000      0.16     0.00
5          sqldf            1    1.01    6.733      1.01     0.00
2  data.tableBad            1    1.63   10.867      1.61     0.01
1      aggregate            1    6.40   42.667      6.38     0.00
4           plyr            1  317.97 2119.800    265.12    51.05

packageVersion("data.table")
# [1] ‘1.8.2’
packageVersion("plyr")
# [1] ‘1.7.1’
packageVersion("sqldf")
# [1] ‘0.4.6.4’
R.version.string
# R version 2.15.1 (2012-06-22)

Please note that I don't know plyr well so please do check with Hadley before relying on the plyr timings here. Also note that the data.table do include the time to convert to data.table and set the key, for fareness.


This answer has been updated since originally answered in Dec 2010. The previous benchmark results are below. Please see revision history of this answer to see what changed.

              test replications elapsed   relative user.self sys.self
4   data.tableBest            1   0.532   1.000000     0.488    0.020
7            sqldf            1   2.059   3.870301     2.041    0.008
3 data.tableBetter            1   9.580  18.007519     9.213    0.220
1        aggregate            1  14.864  27.939850    13.937    0.316
2  data.tableWorst            1 152.046 285.800752   150.173    0.556
6 plyrwithInternal            1 198.283 372.712406   189.391    7.665
5             plyr            1 225.726 424.296992   208.013    8.004
share|improve this answer
    
Because ddply works only with data frames, this is example yields worst case performance. I hope to have a better interface for this type of common operation in a future version. –  hadley Dec 19 '10 at 17:35
    
FYI: you can't use .Internal calls in CRAN packages, see the CRAN Repository Policy. –  Joshua Ulrich Oct 29 '12 at 15:54
    
@JoshuaUlrich You could when the answer was written nearly 2 years ago, iirc. I'll update this answer as data.table automatically optimizes mean now (without calling .Internal internally). –  Matt Dowle Oct 29 '12 at 16:46
    
@JoshuaUlrich Now updated. Thanks for highlighting. –  Matt Dowle Oct 29 '12 at 17:30
    
@MatthewDowle: Yeah, I'm not sure when/if it changed. I just know it's the case now. And it's perfectly fine in your answer, just won't work in packages. –  Joshua Ulrich Oct 29 '12 at 17:41
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For simple task (unique values on both sides of join) I use match:

system.time({
    d <- d1
    d$y2 <- d2$y2[match(d1$x,d2$x)]
})

It's far more faster than merge (on my machine 0.13s to 3.37s).

My timings:

  • merge: 3.32s
  • plyr: 0.84s
  • match: 0.12s
share|improve this answer
4  
Thank you, Marek. Some explanation of why this is so fast (builds an index/hash table) can be found here: tolstoy.newcastle.edu.au/R/help/01c/2739.html –  datasmurf Dec 1 '10 at 22:59
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Thought it would be interesting to post a benchmark with dplyr in the mix: (had a lot of things running)

            test replications elapsed relative user.self sys.self
5          dplyr            1    0.25     1.00      0.25     0.00
3 data.tableGood            1    0.28     1.12      0.27     0.00
6          sqldf            1    0.58     2.32      0.57     0.00
2  data.tableBad            1    1.10     4.40      1.09     0.01
1      aggregate            1    4.79    19.16      4.73     0.02
4           plyr            1  186.70   746.80    152.11    30.27

packageVersion("data.table")
[1] ‘1.8.10’
packageVersion("plyr")
[1] ‘1.8’
packageVersion("sqldf")
[1] ‘0.4.7’
packageVersion("dplyr")
[1] ‘0.1.2’
R.version.string
[1] "R version 3.0.2 (2013-09-25)"

Just added:

dplyr = summarise(dt_dt, avx = mean(x), avy = mean(y))

and setup the data for dplyr with a data table:

dt <- tbl_dt(d)
dt_dt <- group_by(dt, g1, g2)

Updated: I removed data.tableBad and plyr and nothing but RStudio open (i7, 16GB ram).

With data.table 1.9 and dplyr with data frame:

            test replications elapsed relative user.self sys.self
2 data.tableGood            1    0.02      1.0      0.02     0.00
3          dplyr            1    0.04      2.0      0.04     0.00
4          sqldf            1    0.46     23.0      0.46     0.00
1      aggregate            1    6.11    305.5      6.10     0.02

With data.table 1.9 and dplyr with data table:

            test replications elapsed relative user.self sys.self
2 data.tableGood            1    0.02        1      0.02     0.00
3          dplyr            1    0.02        1      0.02     0.00
4          sqldf            1    0.44       22      0.43     0.02
1      aggregate            1    6.14      307      6.10     0.01

packageVersion("data.table")
[1] '1.9.0'
packageVersion("dplyr")
[1] '0.1.2'

For consistency here is the original with all and data.table 1.9 and dplyr using a data table:

            test replications elapsed relative user.self sys.self
5          dplyr            1    0.01        1      0.02     0.00
3 data.tableGood            1    0.02        2      0.01     0.00
6          sqldf            1    0.47       47      0.46     0.00
1      aggregate            1    6.16      616      6.16     0.00
2  data.tableBad            1   15.45     1545     15.38     0.01
4           plyr            1  110.23    11023     90.46    19.52

I think this data is too small for the new data.table and dplyr :)

Larger data set:

N <- 1e8
g1 <- sample(1:50000, N, replace = TRUE)
g2<- sample(1:50000, N, replace = TRUE)
d <- data.frame(x=sample(N,N), y=rnorm(N), g1, g2)

Took around 10-13GB of ram just to hold the data before running the benchmark.

Results:

            test replications elapsed relative user.self sys.self
1          dplyr            1   14.88        1      6.24     7.52
2 data.tableGood            1   28.41        1     18.55      9.4

Tried a 1 billion but blew up ram. 32GB will handle it no problem.


[Edit by Arun] (dotcomken , could you please run this code and paste your benchmarking results? Thanks).

require(data.table)
require(dplyr)
require(rbenchmark)

N <- 1e8
g1 <- sample(1:50000, N, replace = TRUE)
g2 <- sample(1:50000, N, replace = TRUE)
d <- data.frame(x=sample(N,N), y=rnorm(N), g1, g2)

benchmark(replications = 5, order = "elapsed", 
  data.table = {
     dt <- as.data.table(d) 
     dt[, lapply(.SD, mean), by = "g1,g2"]
  }, 
  dplyr_DF = d %.% group_by(g1, g2) %.% summarise(avx = mean(x), avy=mean(y))
) 

As per Arun's request here the output of what you provided me to run:

        test replications elapsed relative user.self sys.self
1 data.table            5   15.35     1.00     13.77     1.57
2   dplyr_DF            5  137.84     8.98    136.31     1.44

Sorry for the confusion, late night got to me.

Using dplyr with data frame seems to be the less efficient way to process summaries. Is this methods to compare the exact functionality of data.table and dplyr with their data structure methods included? I'd almost prefer to separate that as most data will need to be cleaned before we group_by or create the data.table. It could be a matter of taste but I think the most important part is how efficiently the data can be modeled.

share|improve this answer
    
I think you're benchmarking with data.table 1.8.10. Using 1.8.11 I get data.table 18x faster than dplyr (with data.frame) = 0.050 vs 0.894 seconds. I'll update Matt's post once 1.9.0 is updated on CRAN. –  Arun Feb 26 at 23:24
    
Nice update. Thanks. I think your machine is a beast compared to this data set.. What's the size of your L2 cache (and L3 if exists)? –  Arun Feb 27 at 6:51
    
i7 L2 is 2x256 KB 8-way, L3 is 4 MB 16-way. 128 GB SSD, Win 7 on a Dell inspiron –  dotcomken Feb 27 at 7:18
    
dotcomken, great, thanks. Two additional things. 1) Could you please remove dplyr using data.table tests (preferred) or change their names to dplyr_dt or something? It's terribly confusing. 2) Could you also show your functions as to how you're benchmarking.. Thanks. Oh and make sure that you don't set the key during data.table creation (Matt has set the key), as it's not necessary. –  Arun Feb 27 at 7:21
    
The dplyr command you should be benchmarking is d %.% group_by(g1, g2) %.% summarise(avx = mean(x), avy = mean(y)) (that is, including group_by) - it seems like you've missed out on group_by; the most time consuming step. –  Arun Feb 27 at 7:33
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