A very simple solution is to use a decent table-driven approximation. You don't actually need a lot of data if you reduce your inputs correctly. `exp(a)==exp(a/2)*exp(a/2)`

, which means you really only need to calculate `exp(x)`

for `1 < x < 2`

. Over that range, a runga-kutta approximation would give reasonable results with ~16 entries IIRC.

Similarly, `sqrt(a) == 2 * sqrt(a/4)`

which means you need only table entries for `1 < a < 4`

. Log(a) is a bit harder: `log(a) == 1 + log(a/e)`

. This is a rather slow iteration, but log(1024) is only 6.9 so you won't have many iterations.

You'd use a similar "integer-first" algorithm for pow: `pow(x,y)==pow(x, floor(y)) * pow(x, frac(y))`

. This works because `pow(double, int)`

is trivial (divide and conquer).

[edit] For the integral component of `log(a)`

, it may be useful to store a table `1, e, e^2, e^3, e^4, e^5, e^6, e^7`

so you can reduce `log(a) == n + log(a/e^n)`

by a simple hardcoded binary search of a in that table. The improvement from 7 to 3 steps isn't so big, but it means you only have to divide once by `e^n`

instead of `n`

times by `e`

.

[edit 2]
And for that last `log(a/e^n)`

term, you can use `log(a/e^n) = log((a/e^n)^8)/8`

- each iteration produces 3 more bits ~~by table lookup~~. That keeps your code and table size small. This is typically code for embedded systems, and they don't have large caches.

[edit 3]
That's stil not to smart on my side. `log(a) = log(2) + log(a/2)`

. You can just store the fixed-point value `log2=0.30102999566`

, count the number of leading zeroes, shift `a`

into the range used for your lookup table, and multiply that shift (integer) by the fixed-point constant `log2`

. Can be as low as 3 instructions.

Using `e`

for the reduction step just gives you a "nice" `log(e)=1.0`

constant but that's false optimization. 0.30102999566 is just as good a constant as 1.0; both are 32 bits constants in 10.22 fixed point. Using 2 as the constant for range reduction allows you to use a bit shift for a division.

You still get the trick from edit 2, `log(a/2^n) = log((a/2^n)^8)/8`

. Basically, this gets you a result `(a + b/8 + c/64 + d/512) * 0.30102999566`

- with b,c,d in the range [0,7]. `a.bcd`

really is an octal number. Not a surprise since we used 8 as the power. (The trick works equally well with power 2, 4 or 16.)

[edit 4]
Still had an open end. `pow(x, frac(y)`

is just `pow(sqrt(x), 2 * frac(y))`

and we have a decent `1/sqrt(x)`

. That gives us the far more efficient approach. Say `frac(y)=0.101`

binary, i.e. 1/2 plus 1/8. Then that means `x^0.101`

is `(x^1/2 * x^1/8)`

. But `x^1/2`

is just `sqrt(x)`

and `x^1/8`

is `(sqrt(sqrt(sqrt(x)))`

. Saving one more operation, Newton-Raphson `NR(x)`

gives us `1/sqrt(x)`

so we calculate `1.0/(NR(x)*NR((NR(NR(x)))`

. We only invert the end result, don't use the sqrt function directly.

fastfunctions, those`exp( y * log( x ) )`

implementations aren't going to cut it. – MSalters Jan 11 '11 at 12:23