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C99 annex F (IEEE floating point support) says this:

pow(−∞, y) returns +∞ for y > 0 and not an odd integer.

But, say, (−∞)0.5 actually has the imaginary values ±∞i, not +∞. C99’s own sqrt(−∞) returns a NaN and generates a domain error as expected. Why then is pow required to return +∞?

(Most other languages use the C library directly or, like Python in this case, copy the behaviour required of it by standards, so in practice this affects more than just C99.)

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I'm not sure what you mean by "−∞<sup>0.5</sup> is actually the imaginary number ∞i"; where have imaginary numbers come from? – Oliver Charlesworth Apr 28 '12 at 19:54
@OliCharlesworth standard math - taking the sqrt of a negative number gives an imaginary number. – Alnitak Apr 28 '12 at 19:56
@Alnitak: I'm not sure concepts such as "∞i" are particularly meaningful... – Oliver Charlesworth Apr 28 '12 at 19:58
@OliCharlesworth that's what most people say about imaginary numbers and about infinity, but there's no reason I know of that they can't be combined. – Alnitak Apr 28 '12 at 20:02
@Alnitak: Well, standard complex analysis has the extended complex plane, which has a single value of infinity... – Oliver Charlesworth Apr 28 '12 at 20:04
up vote 10 down vote accepted

For odd integer y, it makes sense to define

pow(±0, y) = ±0

After all, raising to an odd power always preserves the sign. If we can preserve the sign of zero, we might as well do it. For positive non-integer y, we should define

pow(±0, y) = +0.

The sign is undefined. But we don't set this to NaN for -0 for the same reason we don't set sqrt(-0) equal to NaN: it just wouldn't make sense. (FWIW, this is also how it is defined in section 9.2.1 of the IEEE-754-2008 standard.)

Since 1/±0 = ±∞, and mathematically

pow(x,y) = 1/pow(1/x,y)

then setting x=±∞ in the above, leads to:

pow(±∞,y) = 1/pow(±0,y) = 1/+0 = +∞

for y a positive non-integer.

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What if you consider (±1)/0 = ±∞, considering that "-0" is the identical real number "0"? – Heath Hunnicutt Apr 28 '12 at 21:28
@HeathHunnicutt (-inf)^(1/2) = (-1/0)^(1/2) = (-1)^(1/2)/0 = nan/0 = nan – Chortos-2 Apr 28 '12 at 21:36
This moves the question to "Why have -0 at all?" Well, one reason is that -0 represents underflow from below. Another is that branch cuts in the complex plane, as they are traditionally defined, just work as expected with -0. – Jeffrey Sax Apr 28 '12 at 21:41
I still disagree with the standard about pow(−∞, y) (being able to derive positive infinity in addition to the two complex roots should only further support defining it as NaN), but this does explain where the standard behaviour comes from (or can come from). Thanks! – Chortos-2 Apr 28 '12 at 22:34
+1, the choice of IEEE to define pow this way doesn't make a lot of sense to me, but this is the first somewhat-reasonable argument I've seen for it. – R.. Apr 28 '12 at 22:50

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