Yes, you can certainly try and work something out. Let me just give you some general ideas, you can fill in the details.

First, let's see why Carmack's root works:

We write *x* = *M* × 2^{E} in the usual way. Now recall that the IEEE float stores the exponent offset by a bias: If *e* denoted the exponent field, we have e = Bias + *E* ≥ 0. Rearranging, we get *E* = e − Bias.

Now for the inverse square root: *x*^{−1/2} = *M*^{-1/2} × 2^{−E/2}. The new exponent field is:

*e'* = Bias − *E*/2 = 3/2 Bias − e/2

With bit fiddling, we can get the value *e*/2 from *e* by shifting, and 3/2 Bias is just a constant.

Moreover, the mantissa *M* is stored as 1.0 + *x* with *x* < 1, and we can approximate *M*^{-1/2} as 1 + x/2. Again, the fact that only *x* is stored in binary means that we get the division by two by simple bit shifting.

Now we look at *x*^{−2}: this is equal to *M*^{−2} × 2^{−2 E}, and we are looking for an exponent field:

*e'* = Bias − 2 *E* = 3 Bias − 2 *e*

Again, 3 Bias is just a constant, and you can get 2 *e* from *e* by bitshifting. As for the mantissa, you can approximate (1 + x)^{−2} by 1 − 2 *x*, and so the problem reduces to obtaining 2 *x* from *x*.

Note that Carmack's magic floating point fiddling doesn't actually compute the result right aaway: Rather, it produces a remarkably accurate *estimate*, which is used as the starting point for a traditional, iterative computation. But because the estimate is so good, you only need very few rounds of subsequent iteration to get an acceptable result.

`x`

instead of`d`

on the 2nd line? – unwind Mar 16 '12 at 11:48`pow`

function is going to be slower than division. Actually, theexact sameassembly code will be emitted for`1.0/(x*x)`

and`pow(x, -2)`

when GCC uses`-ffast-math`

. – Dietrich Epp Mar 16 '12 at 12:09