# Overlap join with start and end positions

Consider the following `data.table`s. The first defines a set of regions with start and end positions for each group 'x':

``````library(data.table)

d1 <- data.table(x = letters[1:5], start = c(1,5,19,30, 7), end = c(3,11,22,39,25))
setkey(d1, x, start)

#    x start end
# 1: a     1   3
# 2: b     5  11
# 3: c    19  22
# 4: d    30  39
# 5: e     7  25
``````

The second data set has the same grouping variable 'x', and positions 'pos' within each group:

``````d2 <- data.table(x = letters[c(1,1,2,2,3:5)], pos = c(2,3,3,12,20,52,10))
setkey(d2, x, pos)

#    x pos
# 1: a   2
# 2: a   3
# 3: b   3
# 4: b  12
# 5: c  20
# 6: d  52
# 7: e  10
``````

Ultimately I'd like to extract the rows in 'd2' where 'pos' falls within the range defined by 'start' and 'end', within each group `x`. The desired result is

``````#    x pos start  end
# 1: a   2     1    3
# 2: a   3     1    3
# 3: c  20    19   22
# 4: e  10     7   25
``````

The start/end positions for any group `x` will never overlap but there may be gaps of values not in any region.

Now, I believe I should be using a rolling join. From what i can tell, I cannot use the "end" column in the join.

I've tried

``````d1[d2, roll = TRUE, nomatch = 0, mult = "all"][start <= end]
``````

and got

``````#    x start end
# 1: a     2   3
# 2: a     3   3
# 3: c    20  22
# 4: e    10  25
``````

which is the right set of rows I want; However "pos" has become "start" and the original "start" has been lost. Is there a way to preserve all the columns with the roll join so i could report "start", "pos", "end" as desired?

Overlap joins was implemented with commit 1375 in data.table v1.9.3, and is available in the current stable release, v1.9.4. The function is called `foverlaps`. From NEWS:

29) `Overlap joins` #528 is now here, finally!! Except for `type="equal"` and `maxgap` and `minoverlap` arguments, everything else is implemented. Check out `?foverlaps` and the examples there on its usage. This is a major feature addition to `data.table`.

Let's consider x, an interval defined as `[a, b]`, where `a <= b`, and y, another interval defined as `[c, d]`, where `c <= d`. The interval y is said to overlap x at all, iff `d >= a` and `c <= b` 1. And y is entirely contained within x, iff `a <= c,d <= b` 2. For the different types of overlaps implemented, please have a look at `?foverlaps`.

Your question is a special case of an overlap join: in `d1` you have true physical intervals with `start` and `end` positions. In `d2` on the other hand, there are only positions (`pos`), not intervals. To be able to do an overlap join, we need to create intervals also in `d2`. This is achieved by creating an additional variable `pos2`, which is identical to `pos` (`d2[, pos2 := pos]`). Thus, we now have an interval in `d2`, albeit with identical start and end coordinates. This 'virtual, zero-width interval' in `d2` can then be used in `foverlap` to do an overlap join with `d1`:

``````require(data.table) ## 1.9.3
setkey(d1)
d2[, pos2 := pos]
foverlaps(d2, d1, by.x = names(d2), type = "within", mult = "all", nomatch = 0L)
#    x start end pos pos2
# 1: a     1   3   2    2
# 2: a     1   3   3    3
# 3: c    19  22  20   20
# 4: e     7  25  10   10
``````

`by.y` by default is `key(y)`, so we skipped it. `by.x` by default takes `key(x)` if it exists, and if not takes `key(y)`. But a key doesn't exist for `d2`, and we can't set the columns from `y`, because they don't have the same names. So, we set `by.x` explicitly.

The type of overlap is within, and we'd like to have all matches, only if there is a match.

NB: `foverlaps` uses data.table's binary search feature (along with `roll` where necessary) under the hood, but some function arguments (types of overlaps, maxgap, minoverlap etc..) are inspired by the function `findOverlaps()` from the Bioconductor package `IRanges`, an excellent package (and so is `GenomicRanges`, which extends `IRanges` for Genomics).

So what's the advantage?

A benchmark on the code above on your data results in `foverlaps()` slower than Gabor's answer (Timings: Gabor's data.table solution = 0.004 vs foverlaps = 0.021 seconds). But does it really matter at this granularity?

What would be really interesting is to see how well it scales - in terms of both speed and memory. In Gabor's answer, we join based on the key column `x`. And then filter the results.

What if `d1` has about 40K rows and `d2` has a 100K rows (or more)? For each row in `d2` that matches `x` in `d1`, all those rows will be matched and returned, only to be filtered later. Here's an example of your Q scaled only slightly:

### Generate data:

``````require(data.table)
set.seed(1L)
n = 20e3L; k = 100e3L
idx1 = sample(100, n, TRUE)
idx2 = sample(100, n, TRUE)
d1 = data.table(x = sample(letters[1:5], n, TRUE),
start = pmin(idx1, idx2),
end = pmax(idx1, idx2))

d2 = data.table(x = sample(letters[1:15], k, TRUE),
pos1 = sample(60:150, k, TRUE))
``````

### foverlaps:

``````system.time({
setkey(d1)
d2[, pos2 := pos1]
ans1 = foverlaps(d2, d1, by.x=1:3, type="within", nomatch=0L)
})
# user  system elapsed
#   3.028   0.635   3.745
``````

This took ~ 1GB of memory in total, out of which `ans1` is 420MB. Most of the time spent here is on subset really. You can check it by setting the argument `verbose=TRUE`.

### Gabor's solutions:

``````## new session - data.table solution
system.time({
setkey(d1, x)
ans2 <- d1[d2, allow.cartesian=TRUE, nomatch=0L][between(pos1, start, end)]
})
#   user  system elapsed
# 15.714   4.424  20.324
``````

And this took a total of ~3.5GB.

I just noted that Gabor already mentions the memory required for intermediate results. So, trying out `sqldf`:

``````# new session - sqldf solution
system.time(ans3 <- sqldf("select * from d1 join
d2 using (x) where pos1 between start and end"))
#   user  system elapsed
# 73.955   1.605  77.049
``````

Took a total of ~1.4GB. So, it definitely uses less memory than the one shown above.

[The answers were verified to be identical after removing `pos2` from `ans1` and setting key on both answers.]

Note that this overlap join is designed with problems where `d2` doesn't necessarily have identical start and end coordinates (ex: genomics, the field where I come from, where `d2` is usually about 30-150 million or more rows).

`foverlaps()` is stable, but is still under development, meaning some arguments and names might get changed.

NB: Since I mentioned `GenomicRanges` above, it is also perfectly capable of solving this problem. It uses interval trees under the hood, and is quite memory efficient as well. In my benchmarks on genomics data, `foverlaps()` is faster. But that's for another (blog) post, some other time.

1) sqldf This is not data.table but complex join criteria are easy to specify in a straight forward manner in SQL:

``````library(sqldf)

sqldf("select * from d1 join d2 using (x) where pos between start and end")
``````

giving:

``````  x start end pos
1 a     1   3   2
2 a     1   3   3
3 c    19  22  20
4 e     7  25  10
``````

2) data.table For a data.table answer try this:

``````library(data.table)

setkey(d1, x)
setkey(d2, x)
d1[d2][between(pos, start, end)]
``````

giving:

``````   x start end pos
1: a     1   3   2
2: a     1   3   3
3: c    19  22  20
4: e     7  25  10
``````

Note that this does have the disadvantage of forming the possibly large intermeidate result `d1[d2]` which SQL may not do. The remaining solutions may have this problem too.

3) dplyr This suggests the corresponding dplyr solution. We also use `between` from data.table:

``````library(dplyr)
library(data.table) # between

d1 %>%
inner_join(d2) %>%
filter(between(pos, start, end))
``````

giving:

``````Joining by: "x"
x start end pos
1 a     1   3   2
2 a     1   3   3
3 c    19  22  20
4 e     7  25  10
``````

4) merge/subset Using only the base of R:

``````subset(merge(d1, d2), start <= pos & pos <= end)
``````

giving:

``````   x start end pos
1: a     1   3   2
2: a     1   3   3
3: c    19  22  20
4: e     7  25  10
``````

Added Note that the data table solution here is much faster than the one in the other answer:

``````dt1 <- function() {
d1 <- data.table(x=letters[1:5], start=c(1,5,19,30, 7), end=c(3,11,22,39,25))
d2 <- data.table(x=letters[c(1,1,2,2,3:5)], pos=c(2,3,3,12,20,52,10))
setkey(d1, x, start)
idx1 = d1[d2, which=TRUE, roll=Inf] # last observation carried forwards

setkey(d1, x, end)
idx2 = d1[d2, which=TRUE, roll=-Inf] # next observation carried backwards

idx = which(!is.na(idx1) & !is.na(idx2))
ans1 <<- cbind(d1[idx1[idx]], d2[idx, list(pos)])
}

dt2 <- function() {
d1 <- data.table(x=letters[1:5], start=c(1,5,19,30, 7), end=c(3,11,22,39,25))
d2 <- data.table(x=letters[c(1,1,2,2,3:5)], pos=c(2,3,3,12,20,52,10))
setkey(d1, x)
ans2 <<- d1[d2][between(pos, start, end)]
}

all.equal(as.data.frame(ans1), as.data.frame(ans2))
## TRUE

benchmark(dt1(), dt2())[1:4]
##     test replications elapsed relative
##  1 dt1()          100    1.45    1.667
##  2 dt2()          100    0.87    1.000  <-- from (2) above
``````
• I do appreciate your comprehensiveness. I just really wanted something to take advantage of the optimized tree search implemented in the data.table roll join. Thanks for the `sqldf` suggestion. I was accustomed to writing joins like `sqldf("select * from d1 join d2 on d1.x==d2.x and d2.pos>=d1.start and d2.pos<=d1.end")` in SQL Server which were nice when you could add indexes to table. I think this may avoid creating a full outer join in memory (but didn't test) – MrFlick Jun 30 '14 at 20:35
• However, note that the data.table code here is shorter and faster. – G. Grothendieck Jul 1 '14 at 3:36
• You are right, `between` is faster. I also tested `d1[d2, roll=T, nomatch=0, mult="all"][start<=end]` with your harness and was close to between. It just goes to show you have to test everything because you never know what will be faster. Thanks for taking the time to check these. Very interesting. Maybe when @Arun implements "range join" in data.table he can make it faster. – MrFlick Jul 1 '14 at 3:45
• Could you explain how "d1[d2][between(pos, start, end)]" works, please? – skan Mar 4 '15 at 20:00
• `d1[d2]` joins `d1` and `d2` along `x` and `[between(...)]` selects those rows for which the `between(...)` is TRUE. – G. Grothendieck Mar 4 '15 at 21:36

`data.table v1.9.8+` has a new feature - non-equi joins. With that, this operation becomes even more straightforward:

``````require(data.table) #v1.9.8+
# no need to set keys on `d1` or `d2`
d2[d1, .(x, pos=x.pos, start, end), on=.(x, pos>=start, pos<=end), nomatch=0L]
#    x pos start end
# 1: a   2     1   3
# 2: a   3     1   3
# 3: c  20    19  22
# 4: e  10     7  25
``````
• would you mind adding memory-usage and timing for this approach – Rentrop Aug 4 '16 at 19:37