# Compile time optimization of Math.pow

I've read that it's possible to optimize multiplication by a known constant at compile time by generating code which makes clever use of bit shifting and compiler-generated magic constants.

I'm interested in possibilities for optimizing exponentiation in a similar hacky manner. I know about exponentiation by squaring, so I guess you could aggressively optimize

``````pow(CONSTANT, n)
``````

by embedding precomputed successive squares of CONSTANT into the executable. I'm not sure whether this is actually a good idea.

But when it comes to

``````pow(n, CONSTANT)
``````

I can't think of anything. Is there a known way to do this efficiently? Do the minds of StackOverflow have ideas, on either problem?

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Not sure I follow. Are you trying to implement `pow()` yourself, or are you assuming that the implementors of this function on your platform did a bad job and didn't try to optimize the easy cases? –  Ernest Friedman-Hill Oct 5 '11 at 3:01
I think the point is that compilers can take advantage of information that's not available to the function. For example, `pow(x, 2)` can be implemented as `x * x`, but only at the expense of a run-time check that the second argument is 2; a compiler can replace the function call by an in-line multiplication no overhead for the test. –  Keith Thompson Oct 5 '11 at 5:05

## 2 Answers

Assuming `pow(a,b)` is implemented as `exp(b * log(a))` (which it probably is), if `a` is a constant then you can precompute its `log`. If `b` is a constant, it only helps if it is also an integer.

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Exponentiation by squaring is ideal for the second case, just basically unroll the loop and embed the constants. But only if CONSTANT is an integer of course.

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