# R grouping by condition in data.table

In R, I have a large data.table. For every row, I want to count rows with a similar value of x1 (+/- some tolerance, tol). I can get this to work using adply, but it's too slow. It seems like the sort of thing data.table would be good for - in fact, I'm already using data.table for part of the computation.

Is there a way to do this entirely with data.table? Here is an example:

``````library(data.table)
library(plyr)
my.df = data.table(x1 = 1:1000,
x2 = 4:1003)
tol = 3
adply(my.df, 1, function(df) my.df[x1 > (df\$x1 - tol) & x1 < (df\$x1 + tol), .N])
``````

Results:

``````        x1   x2 V1
1:    1    4  3
2:    2    5  4
3:    3    6  5
4:    4    7  5
5:    5    8  5
---
996:  996  999  5
997:  997 1000  5
998:  998 1001  5
999:  999 1002  4
1000: 1000 1003  3
``````

## Update:

Here's a sample dataset that is a little closer to my real data:

``````set.seed(10)
x = seq(1,100000000,100000)
x = x + sample(1:50000, length(x), replace=T)
x2 = x + sample(1:50000, length(x), replace=T)
my.df = data.table(x1 = x,
x2 = x2)
setkey(my.df,x1)
tol = 100000

og = function(my.df) {
adply(my.df, 1, function(df) my.df[x1 > (df\$x1 - tol) & x1 < (df\$x1 + tol), .N])
}

microbenchmark(r_ed <- ed(copy(my.df)),
r_ar <- ar(copy(my.df)),
r_og <- og(copy(my.df)),
times = 1)

Unit: milliseconds
expr         min          lq      median          uq         max neval
r_ed <- ed(copy(my.df))    8.553137    8.553137    8.553137    8.553137    8.553137     1
r_ar <- ar(copy(my.df))   10.229438   10.229438   10.229438   10.229438   10.229438     1
r_og <- og(copy(my.df)) 1424.472844 1424.472844 1424.472844 1424.472844 1424.472844     1
``````

Obviously, solutions from both @eddi and @Arun are much faster than mine. Now I just have to try to understand rolls.

-

Here's a faster `data.table` solution. The idea is to use the rolling merge functionality of `data.table`, but before we do that we need to modify the data slightly and make the column `x1` numeric instead of integer. This is because OP is using strict inequality and to use rolling joins with that we're going to have to decrease the tolerance by a tiny amount, making it a floating point number.

``````my.df[, x1 := as.numeric(x1)]

# set the key to x1 for the merges and to sort
# (note, if data already sorted can make this step instantaneous using setattr)
setkey(my.df, x1)

# and now we're going to do two rolling merges, one with the upper bound
# and one with lower, then get the index of the match and subtract the ends
# (+1, to get the count)
my.df[, res := my.df[J(x1 + tol - 1e-6), list(ind = .I), roll = Inf]\$ind -
my.df[J(x1 - tol + 1e-6), list(ind = .I), roll = -Inf]\$ind + 1]

# and here's the bench vs @Arun's solution
ed = function(my.df) {
my.df[, x1 := as.numeric(x1)]
setkey(my.df, x1)
my.df[, res := my.df[J(x1 + tol - 1e-6), list(ind = .I), roll = Inf]\$ind -
my.df[J(x1 - tol + 1e-6), list(ind = .I), roll = -Inf]\$ind + 1]
}

microbenchmark(ed(copy(my.df)), ar(copy(my.df)))
#Unit: milliseconds
#            expr       min       lq   median       uq      max neval
# ed(copy(my.df))  7.297928 10.09947 10.87561 11.80083 23.05907   100
# ar(copy(my.df)) 10.825521 15.38151 16.36115 18.15350 21.98761   100
``````

Note: as both Arun and Matthew pointed out, if `x1` is integer, one doesn't have to convert to numeric and subtract a small amount from `tol` and can use `tol - 1L` instead of `tol - 1e-6` above.

-
+1 indeed, this is faster. –  Arun Aug 8 '13 at 17:56
+1 Can x1 be kept as integer and just +1L and -1L handles strict inequality i.e. J(x1 + tol - 1L)? Should be faster to keep as integer. –  Matt Dowle Aug 9 '13 at 14:09
@MatthewDowle we had comments roughly to that effect with @Arun, although I didn't realize that `1L` vs `1` makes a difference, probably should've left them here - the `1L` comparison indeed works for integer `x1`, but fails if the minimum distance between different `x1`'s is less than 1 –  eddi Aug 9 '13 at 14:49
@eddi Ah I see. For when `tol` is less than 1 (say 0.8 numeric) but `x1` is integer, how about `J(x1+as.integer(ceiling(tol)-1))`. And if I've understand correctly, maybe `rollequal` TRUE/FALSE could be added to data.table to build strict inequality in, alongside `roll` and `rollends`. –  Matt Dowle Aug 12 '13 at 9:17
Btw: `DT[,list(ind = .I),]\$ind` can be just `DT[,.I,]\$I`. When `.I` is unnamed, the dot is automatically dropped so it can be distinguished from `.I` in any compound query on the result. –  Matt Dowle Aug 12 '13 at 9:27

### See @eddi's answer for a faster solution (to this particular problem). It also works when `x1` is not an integer.

The algorithm you're looking for is Interval Tree. And there's a bioconductor package called IRanges that accomplishes this task. It's hard to beat that.

``````require(IRanges)
require(data.table)
my.df[, res := countOverlaps(IRanges(my.df\$x1, width=1),
IRanges(my.df\$x1-tol+1, my.df\$x1+tol-1))]
``````

### Some explanation:

If you break down the code, you can write it in three lines:

``````ir1 <- IRanges(my.df\$x1, width=1)
ir2 <- IRanges(my.df\$x1-tol+1, my.df\$x1+tol-1)
cnt <- countOverlaps(ir1, ir2)
``````

What we essentially do is to is to create two "ranges" (just type `ir1` and `ir2` to see how they are). Then we ask, for each entry in `ir1` how many do they overlap in `ir2` (this is the "interval tree" part). And this is very efficient. Implicitly the argument `type` to `countOverlaps`, by default is "type = any". You can explore the other types if you want. It's extremely useful. Also of relevance is `findOverlaps` function.

Note: There can be faster solutions (in fact there is, see @eddi's) for this particular case, where width of ir1 = 1. But for problems where widths are variable and/or > 1, this should be the fastest.

### Benchmarking:

``````ag <- function(my.df) my.df[, res := sum(abs(my.df\$x1-x1) < tol), by=x1]
ro <- function(my.df) {
my.df[,res:= { y = my.df\$x1
sum(y > (x1 - tol) & y < (x1 + tol))
}, by=x1]
}
ar <- function(my.df) {
my.df[, res := countOverlaps(IRanges(my.df\$x1, width=1),
IRanges(my.df\$x1-tol+1, my.df\$x1+tol-1))]
}

require(microbenchmark)
microbenchmark(r1 <- ag(copy(my.df)), r2 <- ro(copy(my.df)),
r3 <- ar(copy(my.df)), times=100)

Unit: milliseconds
expr      min       lq   median       uq       max neval
r1 <- ag(copy(my.df)) 33.15940 39.63531 41.61555 44.56616 208.99067   100
r2 <- ro(copy(my.df)) 69.35311 76.66642 80.23917 84.67419 344.82031   100
r3 <- ar(copy(my.df)) 11.22027 12.14113 13.21196 14.72830  48.61417   100 <~~~

identical(r1, r2) # TRUE
identical(r1, r3) # TRUE
``````
-
+1 well put !!! –  agstudy Aug 8 '13 at 12:07
Arun, I tried your solution with a dataset that is more similar to my dataset, and got an error: ` set.seed(10)` ` x = seq(1,100000000,100000)` ` x = x + sample(1:50000, length(x), replace=T)` ` x2 = x + sample(1:50000, length(x), replace=T)` ` my.df = data.table(x1 = x, x2 = x2)` ` setkey(my.df,x1)` ` tol = 100000` –  benjamin Aug 8 '13 at 20:50
Sorry - I'm having trouble figuring out the comment markdown.. The error is: Error in countOverlaps(IRanges(my.df\$x1, width = 1), IRanges(pmax(1, my.df\$x1 - : error in evaluating the argument 'subject' in selecting a method for function 'countOverlaps': Error in .Call2("solve_user_SEW0", start, end, width, PACKAGE = "IRanges") : solving row 2: negative widths are not allowed –  benjamin Aug 8 '13 at 20:56
Found the reason. Made the edit. Try it now. The problem was with `pmax(nrow(my.df)...)`... It's not necessary. The edit should work just fine. –  Arun Aug 8 '13 at 20:58
Yup, works now. Do you do much with Bioconductor? I've been meaning to try it out for a while now. I accidentally attended a Bioconductor conference a few weeks ago in Seattle. –  benjamin Aug 8 '13 at 21:10

Here is a pure data.table solution:

``````my.df[, res:=sum(my.df\$x1 > (x1 - tol) & my.df\$x1 < (x1 + tol)), by=x1]

my.df <- adply(my.df, 1,
function(df) my.df[x1 > (df\$x1 - tol) & x1 < (df\$x1 + tol), .N])

identical(my.df[,res],my.df[,V1])
#[1] TRUE
``````

However, this will still be relatively slow if you have many unique `x1`. After all, you need to do a huge number of comparisons and I can't think of a way to avoid that right now.

-

Using the fact that

`````` abs(x-y) < tol ~    y-tol <= x <= y+ tol
``````

you can enhance performance by a factor of 2.

``````## wrap codes in 2 function for benchmarking
library(data.table)
library(plyr)
my.df = data.table(x1 = 1:1000,
x2 = 4:1003)
tol = 3
ag <- function()
my.df[, res := sum(abs(my.df\$x1-x1) < tol), by=x1]
ro <- function()
my.df[,res:= { y = my.df\$x1
sum(y > (x1 - tol) & y < (x1 + tol))
}, by=x1]
## check equal results
identical(ag(),ro())
TRUE
library(microbenchmark)
## benchmarks
microbenchmark(ag(),
ro(),times=1)

Unit: milliseconds
expr      min       lq   median       uq      max neval
ag() 32.75638 32.75638 32.75638 32.75638 32.75638     1
ro() 63.50043 63.50043 63.50043 63.50043 63.50043     1
``````
-
Part of it is the subsetting. With `\$` your function is faster by roughly a factor of two as is to be expected. I have always problems to remember which subsetting function is the fastest. Changed it in my answer. –  Roland Aug 8 '13 at 9:53
@Roland it is right. I update my benchmarkings. –  agstudy Aug 8 '13 at 10:09