One way is:

```
require(data.table)
dt <- data.table(sample_data)
# multiple seems to be a character, convert to numeric
dt[, multiple := as.numeric(multiple)]
setkey(dt, "multiple")
dt[J(rep(unique(multiple), unique(multiple))), allow.cartesian=TRUE]
```

Everything except the last line should be straightforward. The last line uses a subset using key column with the help of `J(.)`

. For each value in `J(.)`

the corresponding value is matched with "key column" and the matched subset is returned.

That is, if you do `dt[J(1)]`

you'll get the subset where `multiple = 1`

. And if you note carefully, by doing `dt[J(rep(1,2)]`

gives you the same subset, but twice. Note that there's a difference between passing `dt[J(1,1)]`

and `dt[J(rep(1,2)]`

. The former is matching values of (1,1) with the *first-two-key-columns* of the data.table respectively, where as the latter is subsetting by matching (1 and 2) against the *first-key* column of the data.table.

So, if we were to pass the same value of the column 2 times in `J(.)`

, then it gets be duplicated twice. We use this trick to pass 1 1-time, 2 2-times etc.. and that's what the `rep(.)`

part does. `rep(.)`

gives 1,2,2,3,3,3,4,4,4,4.

And if the join results in more rows than `max(nrow(dt), nrow(i))`

(i is the rep vector that's inside `J(.)`

), you've to explicitly use `allow.cartesian = TRUE`

to perform this join (I guess this is a new feature from data.table 1.8.8).

**Edit:** Here's some benchmarking I did on a "relatively" big data. I don't see any spike in memory allocations in both methods. But I've yet to find a way to monitor peak memory usage within a function in R. I am sure I've seen such a post here on SO, but it slips me at the moment. I'll write back again. For now, here's a test data and some preliminary results in case anyone is interested/wants to run it for themselves.

```
# dummy data
set.seed(45)
yr <- 1900:2013
sz <- sample(10:50, length(yr), replace = TRUE)
token <- unlist(sapply(sz, function(x) do.call(paste0, data.frame(matrix(sample(letters, x*4, replace=T), ncol=4)))))
multiple <- rep(sample(500:5000, length(yr), replace=TRUE), sz)
DF <- data.frame(yr = rep(yr, sz),
token = token,
multiple = multiple, stringsAsFactors=FALSE)
# Arun's solution
ARUN.DT <- function(dt) {
setkey(dt, "multiple")
idx <- unique(dt$multiple)
dt[J(rep(idx,idx)), allow.cartesian=TRUE]
}
# Ricardo's solution
RICARDO.DT <- function(dt) {
setkey(dt, key="yr")
newDT <- setkey(dt[, rep(NA, list(rows=length(token) * unique(multiple))), by=yr][, list(yr)], 'yr')
newDT[, tokenReps := as.character(NA)]
# Add the rep'd tokens into newDT, using recycling
newDT[, tokenReps := dt[.(y)][, token], by=list(y=yr)]
newDT
}
# create data.table
require(data.table)
DT <- data.table(DF)
# benchmark both versions
require(rbenchmark)
benchmark(res1 <- ARUN.DT(DT), res2 <- RICARDO.DT(DT), replications=10, order="elapsed")
# test replications elapsed relative user.self sys.self
# 1 res1 <- ARUN.DT(DT) 10 9.542 1.000 7.218 1.394
# 2 res2 <- RICARDO.DT(DT) 10 17.484 1.832 14.270 2.888
```

But as Ricardo says, it may not matter if you run out of memory. So, in that case, there has to be a trade-off between speed and memory. What I'd like to verify is the peak memory used in both methods here to say definitively if using `Join`

is better.