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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.

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

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

share|improve this question
    
I don't know for R but the same is happening in Python on my machine together with the similarly wrong: 1**nan returning 1.0 – hivert Jul 25 '13 at 22:40
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@hivert at least in the case of R ^ 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
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I'm not convinced 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
    
Just a comment about this: "any number raised to 0 will give 1, including -Inf and Inf": for -Inf and +Inf, the value should be NaN, as these are undeterminate limits. Think of (1 + 1/x)^x when x approaches 0. – Yves Daoust Jul 31 '13 at 5:50
up vote 25 down vote accepted

This is referenced in the help page referenced by ?'NaN'

"The IEC 60559 standard, also known as the ANSI/IEEE 754 Floating-Point Standard.

http://en.wikipedia.org/wiki/NaN."

And there you find this statement regarding what should create a NaN:

 "There are three kinds of operations that can return NaN:[5]
       Operations with a NaN as at least one operand.

It is probably is from the particular C compiler, as signified by the Note you referenced. This is what the GNU C documentation says:

http://www.gnu.org/software/libc/manual/html_node/Infinity-and-NaN.html

" NaN, on the other hand, infects any calculation that involves it. Unless the calculation would produce the same result no matter what real value replaced NaN, the result is NaN."

So it seems that the GNU-C people have a different standard in mind when writing their code. And the 2008 version of ANSI/IEEE 754 Floating-Point Standard is reported to make that suggestion:

http://en.wikipedia.org/wiki/NaN#Function_definition

The published standard is not free. So if you are have access rights or money you can look here:

http://ieeexplore.ieee.org/xpl/mostRecentIssue.jsp?punumber=4610933

share|improve this answer
1  
I added the Note from the help page. (I certainly wasn't intending to cover "all possible compilers".) And I would say that the current behavior with the GNU-C compiler is not agreeing the "Note". – 42- Jul 25 '13 at 21:37
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@BlueRaja-DannyPflughoeft the equivalent C function is pow. The inbuilt exponentiation function, ^ in R calls pow via some checks on the arguments that were passed to it. NaN^0 is equivalent in R to `^`(NaN,0). See my comment below the OP for the R source code (written in C) that is executed before pow is called. I think DWin is pretty familiar with R. – Simon O'Hanlon Jul 25 '13 at 22:48
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@BlueRaja-DannyPflughoeft: I started the search for authoritative descriptions with the help page for 'NaN'. It directed me to the IEEE standard. R is written in C, so it seemed possible that an edge case like this might be determined in practice by the "usual" behavior of NaN with "^" in the GNU-C-compiler. Answers come in many flavors, oftentimes historical, as appears to be the case here. – 42- Jul 25 '13 at 22:56
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It also says "In R, basically all mathematical functions (including basic ‘Arithmetic’), are supposed to work properly with ‘+/- Inf’ and ‘NaN’ as input or output." So I think this is a bug in R - in particular, `NA ^ 0 == 1" is definitely wrong. – hadley Jul 26 '13 at 13:38
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@SimonO101 I don't see why the class of the element is relevant: NA_real_ ^ 0 is 1, clearly defying the usual missing value propagation rules: NA_real_ * 0, is NA, not 0. – hadley Jul 28 '13 at 1:02

The answer can be summed up by "for historical reasons".

It seems that IEEE 754 introduced two different power functions - pow and powr, with the latter preserving NaN's in the OP case and also returning NaN for Inf^0, 0^0, 1^Inf, but eventually the latter was dropped as explained briefly here.

Conceptually, I'm in the NaN preserving camp, because I'm coming at the issue from viewpoint of limits, but from convenience point of view I expect current conventions are slightly easier to deal with, even if they don't make a lot of sense in some cases (e.g. sqrt(-1)^0 being equal to 1 while all operations are on real numbers makes little sense if any).

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That link is interesting reading. I would have liked R's min and max to ignore NaN's, but for NaN^1 to be NaN. Ya' can't always get what you want. – 42- Jul 25 '13 at 17:57
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+1 thanks, that second link is quite interesting. – Simon O'Hanlon Jul 25 '13 at 19:13
    
I believe the final version of the IEEE754-2008 standard does in fact have both pow and powr, as well as pown for raising an arbitrary float to an integral power. pow(qNaN, 0) and pown(qNaN, 0) are defined as 1; powr(qNaN, 0) signals the invalid operation exception, and so returns a qNaN under default FP exception handling. – Mark Dickinson Jul 26 '13 at 12:19
    
Very interesting reading on history of IEEE 754. NaN preserving has another advantage (for min/max or for anything else): NaN may have appeared in a previous computation, which, in other circumstances would have given a usable double value, which could have been compared/used/... NaN is then viewed as an exceptional value, and merely an error (for some reason, as overflow, the computation gone bad). Preserving NaN allows to at least see in the end that there was an error somewhere, and won't give silently an incorrect answer. Signaling NaNs are also a way to trap the error when it happens. – user1220978 Aug 21 '13 at 13:50
    
The "NaN preserving" concept is practically identical to "NA preserving". So in numerical computations, NA and NaN are always (?, can you find an exeption ?) treated equally / analogously. More in a separate "reply" below. Re sqrt(-1)^0 : this is exactly a good example why NaN^0 should give 1: sqrt(-1 + 0i)^0 indeed gives 1 (+0i): sqrt(-1+0i)^0 == 1 is indeed TRUE – Martin Mächler Nov 23 '13 at 17:20

Yes, I'm late here, but as R Core member who was involved in this design, let me recall what I commented above. NaN preserving and NA preserving work "equivalently" in R, so if you agree that NA^0 should give 1, NaN^0 |-> 1 is a consequence.

Indeed (as others said) you should really read R's help pages and not C or IEEE standards, to answer such questions, and SimonO101 correctly cited

1 ^ y and y ^ 0 are 1, always

and I'm pretty sure that I was heavily involved (if not the author) of that. Note that it is good, not bad, to be able to provide non-NaN answers, also in cases other programming languages do differently. The consequence of such a rule is that more things work automatically correctly; in the other case, the R programmer would have been urged to do more special casing herself.

Or put differently, a simple rule as the above (returning non-NaN in all cases) is a good rule, because it propagates continuity in a mathematical sense: lim_x f(x) = f(lim x). We have had a few cases where it was clearly adavantageous (i.e. did not need special casing, I'm repeating..) to adhere to the above "= 1" rule, rather than to propagate NaN. As I said further up, the sqrt(-1)^0 is also such an example, as 1 is the correct result as soon as you extend to the complex plane.

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lol, why would anyone agree that NA^0 should give 1 if they think NaN^0 should not? NA is a superset of NaN. You got the if-else direction wrong. – eddi Nov 23 '13 at 17:40
    
Well, the OP did exactly say that! – Martin Mächler Nov 23 '13 at 18:26
    
:) fair enough - both of you should know better then – eddi Nov 23 '13 at 18:43
    
and why on earth was my summarizing remarks, from the one person who knew the answer to the question "why?" because I've co-implemented it, be downvoted. .. heaven gracious! – Martin Mächler Nov 23 '13 at 19:00
    
the -1 is from me and is mainly because you state that this choice is "good" without any argument to support it – eddi Nov 23 '13 at 22:06

Here's one reasoning. From Goldberg:

In IEEE 754, NaNs are often represented as floating-point numbers with the exponent e_max + 1 and nonzero significands.

So NaN is a floating-point number, though with a special meaning. Raising a number to the power zero sets its exponent to zero, therefore it will no longer be NaN.

Also note:

> 1^NaN
[1] 1

One is a number whose exponent is zero already.

share|improve this answer
    
So, your claim is that they wanted to avoid having to deal with special cases? But, floating-point computations already have to deal with a number of special cases caused by NaN (as well as+/- Inf, +/- 0, and denormalized numbers), so... – BlueRaja - Danny Pflughoeft Jul 25 '13 at 22:48
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And if it so happened that NaN was represented as e.g. 2, by your logic 1+NaN would be equal to 3. You can't draw conclusions on what some result should be from how you choose to represent it. – eddi Nov 23 '13 at 18:30

Conceptually, the only problem with NaN^0 == 1 is that zero values can come about at least four different ways, but the IEEE format uses the same representation for three of them. The above formula equality sense for the most common case (which is one of the three), but not for the others.

BTW, the four cases I would recognize would be:

  • A literal zero
  • Unsigned zero: the difference between two numbers that are indistinguishable
  • Positive infinitesimal: The product or quotient of two numbers of matching sign, which is too small to be distinguished from zero.
  • Negative infinitesimal: The product or quotient of two numbers of opposite sign, which is too small to be distinguished from zero.

Some of these may be produced via other means (e.g. literal zero could be produced as the sum of two literal zeros; positive infinitesimal by the division of a very small number by a very large one, etc.).

If a floating-point recognized the above, it could usefully regard raising NaN to a literal zero as yielding one, and raising it to any other kind of zero as yielding NaN; such a rule would allow a constant result to be assumed in many cases where something that might be NaN would be raised to something the compiler could identify as a constant zero, without such assumption altering program semantics. Otherwise, I think the issue is that most code isn't going to care whether x^0 might would NaN if x is NaN, and there's not much point to having a compiler add code for conditions code isn't going to care about. Note that the issue isn't just the code to compute x^0, but for any computations based on that which would be constant if x^0 was.

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NaN is often used to e.g. indicate that the result is not in the real domain e.g. sqrt(-1). In your custom function it could be smth a lot more exotic than a complex number, that wouldn't necessarily even have the ^ operator defined for it, in which case it would be irrelevant what "kind" if a zero you're looking at. – eddi Nov 23 '13 at 18:36
    
@eddi: If the semantic meaning of x^literalZero is defined as "ignore x and return 1", then the correct result of sqrt(-1)^0 should be 1. One may question whether that is the most desirable way to define the exponentiation operator, but I would posit that languages should avoid defining corner cases whose handling would require extra code. Incidentally, does the language you're using distinguish cases where the right-hand operator is an integer from those where it is floating-point? In some languages, (-2.0)^2 is 4.0, but (-2.0)^(2.0) is invalid. If the zero is an integer... – supercat Nov 23 '13 at 19:14
    
...then I don't think IEEE-754 NaN handling wouldn be relevant (since it doesn't mention exponentiation by integer) and I would not favor requiring a language to code the zero case as if (exponent==0) return (isNan(base) ? NaN : 1.0); as opposed to simply if (exponent==0) return 1;. – supercat Nov 23 '13 at 19:16
    
Take a function f = function(x) {if (x > 0) x else "boo"}. Then f(-1)^0 would correctly give you an error. Now imagine someone wants to represent this function in the reals-only domain. The way they would do it is: f_real = function(x) {if (x > 0) x else NaN}. And R would them proceed to give an incorrect answer when they try to do f_real(-1)^0. – eddi Nov 23 '13 at 22:03
    
@eddi: Do you mean f_real(-1)^0, or f_real^0.0? I would posit that mathematically, f(x)^N may be defined as {1 when N=0, (f(x)^(N-1))*f(x) when N > 0, and (f(x)^(N+1)) when N < 0}. As such, it requires that the function be evaluated abs(N) times; since math has no concept of functions with side-effects, evaluating the function abs(N) times is equivalent to evaluating it exactly once, provided that one only cares what happens if one actually uses the result. Note that my disagreement only extends to the case where the exponent is "integer" zero. Incidentally, I was wrong about IEEE not... – supercat Nov 25 '13 at 16:07

If you look at the type of NaN, it is still a number, it's just not a specific number that can be represented by the numeric type.

EDIT:

For example, if you were to take 0/0. What is the result? If you tried to solve this equation on paper, you get stuck at the very first digit, how many zero's fit into another 0? You can put 0, you can put 1, you can put 8, they all fit into 0*x=0 but it's impossible to know which one the correct answer is. However, that does not mean the answer is no longer a number, it's just not a number that can be represented.

Regardless, any number, even a number that you can't represent, to the power of zero is still 1. If you break down some math x^8 * x^0 can be further simplified by x^(8+0) which equates to x^8, where did the x^0 go? It makes sense if x^0 = 1 because then the equation x^8 * 1 explains why x^0 just sort of disappears from existence.

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So are you basically saying that "not a number is a number"? – user529758 Jul 25 '13 at 16:38
    
@H2CO3 According to R, yes because is.numeric(NaN) is TRUE – dickoa Jul 25 '13 at 16:39
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@H2CO3 I know you know. Just having a bit of innocent fun. – Daniel Fischer Jul 25 '13 at 16:42
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@eddi I really wish someone would just write an answer that says "because R is following X standard and that's what the standard says" so we can all upvote that and done with this. – joran Jul 25 '13 at 17:11
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@joran: Well, I'm not sure what guarantees R makes about following any standards, but the overwhelmingly dominant standard in this area is IEEE 754, and that says (in section 9.2.1): "pow (x, ±0) is 1 for any x (even a zero, quiet NaN, or infinity)". It's not 100% clear to me from the wording of the standard whether this is a recommendation or a requirement. – Mark Dickinson Jul 25 '13 at 17:22

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