You can use the `rollsumr`

function from the `zoo`

package for this:

```
library(zoo)
test$sums <- rollsumr(test$vals, k = 3, fill = NA)
```

which gives:

```
> test
id vals sums
1 1 4 NA
2 2 7 NA
3 3 2 13
4 4 9 18
5 5 7 18
6 6 0 16
7 7 4 11
8 8 6 10
9 9 1 11
10 10 8 15
```

This is the same as using the `rollsum`

function with the `align = 'right'`

parameter:

```
rollsum(test$vals, k = 3, fill = NA, align = 'right')
```

As an alternative, you can use `Reduce`

with `shift`

from the data.table package:

```
library(data.table)
setDT(test)[, sums := Reduce(`+`, shift(vals, 0:2))]
```

which gives the same result:

```
> test
id vals sums
1: 1 4 NA
2: 2 7 NA
3: 3 2 13
4: 4 9 18
5: 5 7 18
6: 6 0 16
7: 7 4 11
8: 8 6 10
9: 9 1 11
10: 10 8 15
```

Recently, fast rolling functions were added to data.table. Thus, another option would be:

```
setDT(test)[, sums := frollsum(vals, 3)]
```

A nice base R alternative as proposed by @alexis_laz in the comments:

```
n <- 3
cs <- cumsum(test$vals)
test$sums <- c(rep_len(NA, n - 1), tail(cs, -(n - 1)) - c(0, head(cs, -n)))
```

Another two option as proposed by @Khashaa in the comments:

```
# with base R
n <- 3
test$sums <- c(rep_len(NA, n - 1), rowSums(embed(test$vals, n)))
# with RcppRoll
library(RcppRoll)
test$sums <- roll_sumr(test$vals, 3)
```

### Benchmarks:

As @alexis_laz noted in the comments, some of the solutions might create overhead in recalculating sums and re-creating `length`

-vectors. This may result in differences in computation speed. As a benchmark on such a small dataset isn't really meaningful, I'll benchmark the different solutions on a large dataset that mimics the example dataset:

```
# window size
n <- 3
# creating functions of the different solutions:
alexis_laz <- function(test) {cs <- cumsum(test$vals); test$sums <- c(rep_len(NA, n - 1), tail(cs, -(n - 1)) - c(0, head(cs, -n)))}
khashaa <- function(test) {test$sums <- c(rep_len(NA, n - 1), rowSums(embed(test$vals, n)))}
rcpp_roll <- function(test) test$sums <- roll_sumr(test$vals, n)
zoo_roll <- function(test) test$sums <- rollsumr(test$vals, k=n, fill=NA)
dt_reduce <- function(test) setDT(test)[, sums := Reduce(`+`, shift(vals, 0:(n-1)))]
dt_froll <- function(test) setDT(test)[, sums := frollsum(vals, n)]
# load the 'bench' package
library(bench)
# create a big test dataset
test <- data.frame(id=rep(1:10,1e7), vals=sample(c(4,7,2,9,7,0,4,6,1,8),1e7,TRUE))
# run the benchmark
big_bm <- mark(alexis_laz(test),
khashaa(test),
rcpp_roll(test),
zoo_roll(test),
dt_reduce(test),
dt_froll(test),
iterations = 1,
check = FALSE)
# extract some core measures and sort them
big_bm %>% select(expression, median, mem_alloc) %>% arrange(median)
```

which gives:

```
expression median mem_alloc
<bch:expr> <bch:tm> <bch:byt>
1 dt_froll(test) 776.35ms 1.49GB
2 rcpp_roll(test) 1.23s 762.94MB
3 dt_reduce(test) 2.12s 4.47GB
4 alexis_laz(test) 3.68s 4.47GB
5 khashaa(test) 8.35s 5.21GB
6 zoo_roll(test) 33.32s 22.63GB
```

As you can see, the new `frollsum`

-function from the data.table-package is the clear winner with regard to speed. When considering memory allocation, `roll_sumr`

from rcpproll needs the least amount of memory.