I don't know how to encode the float number using integer format.

There is a function for that: `f32::to_bits`

which returns an `u32`

. There is also the function for the other direction: `f32::from_bits`

which takes an `u32`

as argument. These functions are preferred over `mem::transmute`

as the latter is `unsafe`

and tricky to use.

With that, here is the implementation of `InvSqrt`

:

```
fn inv_sqrt(x: f32) -> f32 {
let i = x.to_bits();
let i = 0x5f3759df - (i >> 1);
let y = f32::from_bits(i);
y * (1.5 - 0.5 * x * y * y)
}
```

(Playground)

This function compiles to the following assembly on x86-64:

```
.LCPI0_0:
.long 3204448256 ; f32 -0.5
.LCPI0_1:
.long 1069547520 ; f32 1.5
example::inv_sqrt:
movd eax, xmm0
shr eax ; i << 1
mov ecx, 1597463007 ; 0x5f3759df
sub ecx, eax ; 0x5f3759df - ...
movd xmm1, ecx
mulss xmm0, dword ptr [rip + .LCPI0_0] ; x *= 0.5
mulss xmm0, xmm1 ; x *= y
mulss xmm0, xmm1 ; x *= y
addss xmm0, dword ptr [rip + .LCPI0_1] ; x += 1.5
mulss xmm0, xmm1 ; x *= y
ret
```

I have not found any reference assembly (if you have, please tell me!), but it seems fairly good to me. I am just not sure why the float was moved into `eax`

just to do the shift and integer subtraction. Maybe SSE registers do not support those operations?

clang 9.0 with `-O3`

compiles the C code to basically the same assembly. So that's a good sign.

It is worth pointing out that if you actually want to use this in practice: please don't. As benrg pointed out in the comments, modern x86 CPUs have a specialized instruction for this function which is faster and more accurate than this hack. Unfortunately, `1.0 / x.sqrt()`

does not seem to optimize to that instruction. So if you really need the speed, using the `_mm_rsqrt_ps`

intrinsics is probably the way to go. This, however, does again require `unsafe`

code. I won't go into much detail in this answer, as a minority of programmers will actually need it.

`union`

.`union`

works either.`memcpy`

definitely works, though it's verbose.`rsqrtss`

and`rsqrtps`

instructions, introduced with the Pentium III in 1999, are faster and more accurate than this code. ARM NEON has`vrsqrte`

which is similar. And whatever calculations Quake III used this for would probably be done on the GPU these days anyway.2more comments