As the other answers have pointed out, there is something a bit non-reproducible/strange about your results so far. Nevertheless, if you really must do exact calculations on large integers, you probably need an interface between R and some other system.

Some of your choices are:

- the
`gmp`

package (see this page and scroll down to R
- an interface to the
`bc`

calculator on googlecode
- there is a high precision arithmetic page on the R wiki which compares interfaces to Yacas, bc, and MPFR/GMP
there is a limited interface to the PARI/GP package in the `elliptical`

package, but this is probably (much) less immediately useful than the preceding three choices

Most Unix or Cygwin systems should have bc installed already. GMP and Yacas are easy to install on modern Linux systems ...

Here's an extended example, with a function that can choose among numeric, integer, or `bigz`

computation.

```
f1 <- function(ol=1L,oh=1L,N=16569L,type=c("num","int","bigz")) {
type <- match.arg(type)
## convert all values to appropriate type
if (type=="int") {
ol <- as.integer(ol)
oh <- as.integer(oh)
N <- as.integer(N)
one <- 1L
two <- 2L
six <- 6L
cc <- as.integer
} else if (type=="bigz") {
one <- as.bigz(1)
two <- as.bigz(2)
six <- as.bigz(6)
N <- as.bigz(N)
ol <- as.bigz(ol)
oh <- as.bigz(oh)
cc <- as.bigz
} else {
one <- 1
two <- 2
six <- 6
N <- as.numeric(N)
oh <- as.numeric(oh)
ol <- as.numeric(ol)
cc <- as.numeric
}
## if using bigz mode, the ratio needs to be converted back to bigz;
## defining cc() as above seemed to be the most transparent way to do it
N*ol^two + cc(N*(N+one)*(two*N+one)/six) -
ol*(N*N+one) + two*N*ol*(N-oh+one) +
(N-oh+one)*N^two + two*N*(oh-N-one)*(oh+N)
}
```

I removed a lot of unnecessary parentheses, which actually made it harder to see what was going on. It is indeed true that for the (1,1) case the final result is not bigger than `.Machine$integer.max`

but some of the intermediate steps are ... (for the (1,1) case this actually reduces to $$-1/6*(N+2)*(4*N^2-5*N+3)$$ ...)

```
f1() ## -3.032615e+12
f1() > .Machine$integer.max ## FALSE
N <- 16569L
N*(N+1)*(2*N+1) > .Machine$integer.max ## TRUE
N*(N+1L)*(2L*N+1L) ## integer overflow (NA)
f1(type="int") ## integer overflow
f1(type="bigz") ## "-3032615078557"
print(f1(),digits=20) ## -3032615078557: no actual loss of precision in this case
```

PS: you have a `(N*N+1)`

term in your equation. Should that really be `N*(N+1)`

, or did you really mean `N^2+1`

?

`NA`

in both cases. Even more, if I store it as double and ask format(x,scientific=FALSE), I get another number. – Joris Meys May 18 '11 at 12:18