Short answer:

A specialisation of `pow(x, n)`

to where `n`

is a natural number is often useful for *time performance*. But the standard library's generic `pow()`

still works pretty (*surprisingly!*) well for this purpose and it is absolutely critical to include as little as possible in the standard C library so it can be made as portable and as easy to implement as possible. On the other hand, that doesn't stop it at all from being in the C++ standard library or the STL, which I'm pretty sure nobody is planning on using in some kind of embedded platform.

Now, for the long answer.

`pow(x, n)`

can be made much faster in many cases by specialising `n`

to a natural number. I have had to use my own implementation of this function for almost every program I write (but I write a lot of mathematical programs in C). The specialised operation can be done in `O(log(n))`

time, but when `n`

is small, a simpler linear version can be faster. Here are implementations of both:

```
// Computes x^n, where n is a natural number.
double pown(double x, unsigned n)
{
double y = 1;
// n = 2*d + r. x^n = (x^2)^d * x^r.
unsigned d = n >> 1;
unsigned r = n & 1;
double x_2_d = d == 0? 1 : pown(x*x, d);
double x_r = r == 0? 1 : x;
return x_2_d*x_r;
}
// The linear implementation.
double pown_l(double x, unsigned n)
{
double y = 1;
for (unsigned i = 0; i < n; i++)
y *= x;
return y;
}
```

(I left `x`

and the return value as doubles because the result of `pow(double x, unsigned n)`

will fit in a double about as often as `pow(double, double)`

will.)

(Yes, `pown`

is recursive, but breaking the stack is absolutely impossible since the maximum stack size will roughly equal `log_2(n)`

and `n`

is an integer. If `n`

is a 64-bit integer, that gives you a maximum stack size of about 64. *Nobody* has such extreme memory limitations.)

As for performance, you'll be surprised by what a garden variety `pow(double, double)`

is capable of. I tested a hundred million iterations on my 5-year-old IBM Thinkpad with `x`

equal to the iteration number and `n`

equal to 10. In this scenario, `pown_l`

won. glibc `pow()`

took 12.0 user seconds, `pown`

took 7.4 user seconds, and `pown_l`

took only 6.5 user seconds. So that's not too surprising. We were more or less expecting this.

Then, I let `x`

be constant (I set it to 2.5), and I looped `n`

from 0 to 19 a hundred million times. This time, quite unexpectedly, glibc `pow`

won, and by a landslide! It took only 2.0 user seconds. My `pown`

took 9.6 seconds, and `pown_l`

took 12.2 seconds. What happened here? I did another test to find out.

I did the same thing as above only with `x`

equal to a million. This time, `pown`

won at 9.6s. `pown_l`

took 12.2s and glibc pow took 16.3s. Now, it's clear! glibc `pow`

performs better than the three when `x`

is low, but worst when `x`

is high. When `x`

is high, `pown_l`

performs best when `n`

is low, and `pown`

performs best when `x`

is high.

So here are three different algorithms, each capable of performing better than the others under the right circumstances. So, ultimately, which to use most likely depends on how you're planning on using `pow`

, but using the right version *is* worth it, and having all of the versions is nice. In fact, you could even automate the choice of algorithm with a function like this:

```
double pown_auto(double x, unsigned n, double x_expected, unsigned n_expected) {
if (x_expected < x_threshold)
return pow(x, n);
if (n_expected < n_threshold)
return pown_l(x, n);
return pown(x, n);
}
```

As long as `x_expected`

and `n_expected`

are constants decided at compile time, along with possibly some other caveats, an optimising compiler worth its salt will automatically remove the entire `pown_auto`

function call and replace it with the appropriate choice of the three algorithms. (Now, if you are actually going to attempt to *use* this, you'll probably have to toy with it a little, because I didn't exactly try *compiling* what I'd written above. ;))

On the other hand, glibc `pow`

*does work* and glibc is big enough already. The C standard is supposed to be portable, including to various *embedded devices* (in fact embedded developers everywhere generally agree that glibc is already too big for them), and it can't be portable if for every simple math function it needs to include every alternative algorithm that *might* be of use. So, that's why it isn't in the C standard.

footnote: In the time performance testing, I gave my functions relatively generous optimisation flags (`-s -O2`

) that are likely to be comparable to, if not worse than, what was likely used to compile glibc on my system (archlinux), so the results are probably fair. For a more rigorous test, I'd have to compile glibc myself and I *reeeally* don't feel like doing that. I used to use Gentoo, so I remember how long it takes, even when the task is *automated*. The results are conclusive (or rather inconclusive) enough for me. You're of course welcome to do this yourself.

Bonus round: A specialisation of `pow(x, n)`

to all integers is *instrumental* if an exact integer output is required, which does happen. Consider allocating memory for an N-dimensional array with p^N elements. Getting p^N off even by one will result in a possibly randomly occurring segfault.

`double pow(int base, int exponent)`

since C++11 (§26.8[c.math]/11 bullet point 2) – Cubbi Jun 13 '12 at 2:26