Prompted by a spot of earlier code golfing why would:

```
>NaN^0
[1] 1
```

It makes perfect sense for `NA^0`

to be 1 because `NA`

is missing data, and *any* number raised to 0 will give 1, including `-Inf`

and `Inf`

. However `NaN`

is supposed to represent *not-a-number*, so why would this be so? This is even more confusing/worrying when the help page for `?NaN`

states:

In R, basically all mathematical functions (including basic Arithmetic), are supposed to work properly with +/- Inf and NaN as input or output.

The basic rule should be that calls and relations with Infs really are statements with a proper mathematical limit.

: which of those two is not guaranteed and may depend on the R platform (since compilers may re-order computations).Computations involving NaN will return NaN or perhaps NA

Is there a philosophical reason behind this, or is it just to do with how R represents these constants?

`^`

is a function that doesn't just call the`C`

function`pow`

, it checks for the case where the base is 1 or the exponent is 0 and if either is`TRUE`

it returns`1.`

before ever calling`pow`

:`if((x1 = INTEGER(s1)[i1]) == 1 || (x2 = INTEGER(s2)[i2]) == 0); REAL(ans)[i] = 1.;`

– Simon O'Hanlon Jul 25 '13 at 22:44`NA^0 == 1`

makes much sense either because`Inf^0`

is an indeterminate form. That is, when viewed as a limit we cannot determine from this form alone what the value of the original limit was. For example, as n approach infinity,`exp(n)^*(1/n)`

approaches e, but`n^(1/n)`

approaches 1 even though both look like`Inf^0`

. – orizon Jul 26 '13 at 0:34