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.