Here are some of the main variants offered so far

```
f0 <- function(v, n) {
sidx = seq.int(from=1, to=length(v), by=n)
eidx = c((sidx-1)[2:length(sidx)], length(v))
sapply(1:length(sidx), function(i) sum(v[sidx[i]:eidx[i]]))
}
f1 <- function(v, n, na.rm=TRUE) { # 'tapply'
unname(tapply(v, (seq_along(v)-1) %/% n, sum, na.rm=na.rm))
}
f2 <- function(v, n, na.rm=TRUE) { # 'matrix'
nv <- length(v)
if (nv %% n)
v[ceiling(nv / n) * n] <- NA
colSums(matrix(v, n), na.rm=na.rm)
}
f3 <- function(v, n) { # 'cumsum'
nv = length(v)
i <- c(seq_len(nv %/% n) * n, if (nv %% n) nv else NULL)
diff(c(0L, cumsum(v)[i]))
}
```

Basic test cases might be

```
v = list(1:4, 1:5, c(NA, 2:4), integer())
n = 2
```

`f0`

fails with the final test, but this could probably be fixed

```
> f0(integer(), n)
Error in sidx[i]:eidx[i] : NA/NaN argument
```

The cumsum approach `f3`

is subject to rounding error, and the presence of an NA early in `v`

'poisons' later results

```
> f3(c(NA, 2:4), n)
[1] NA NA
```

In terms of performance, the original solution is not bad

```
> library(rbenchmark)
> cols <- c("test", "elapsed", "relative")
> v <- 1:100; n <- 10
> benchmark(f0(v, n), f1(v, n), f2(v, n), f3(v, n),
+ columns=cols)
test elapsed relative
1 f0(v, n) 0.012 3.00
2 f1(v, n) 0.065 16.25
3 f2(v, n) 0.004 1.00
4 f3(v, n) 0.004 1.00
```

but the matrix solution `f2`

seems to be both fast and flexible (e.g., adjusting the handling of that trailing chunk of fewer than `n`

elements)

```
> v <- runif(1e6); n <- 10
> benchmark(f0(v, n), f2(v, n), f3(v, n), columns=cols, replications=10)
test elapsed relative
1 f0(v, n) 5.804 34.141
2 f2(v, n) 0.170 1.000
3 f3(v, n) 0.251 1.476
```