If your hardware has a sufficiently fast integer multiplier (say 4-5 cycles), using an iterative approach to compute recip = 1 / divisor is likely to be the fastest approach. You would then compute the quotient as dividend * recip. It is very helpful for the necessary fixed-point computations if the hardware offers either integer multiplication with double-width result (i.e. the full product) or a "mulhi" instruction that delivers the upper 32 bits of the product of two 32 bit integers.

You will need to re-scale the fixed-point computations on the fly to retain close to 32 bits in intermediate results to derive a result that is accurate to the 24 bits that are required for the final result after rounding.

The fastest approach is likely generating a 9-bit starting approximation "approx" to 1 / divisor followed by a cubically convergent iteration for the reciprocal:

```
e = 1 - divisor * approx
e = e * e + e
recip = e * approx + approx
```

It is easiest to precompute the starting approximation and sstore it in an array of 256 bytes, indexed by bits 23:16 of the divisor (i.e. the 8 most significant fractional bits of the mantissa). As all approximation values are numbers in the range 0x100 ... 0x1FF (corresponding to 0.5 to 0.998046875) there is no need to store the most significant bit of each value as it will be '1'. Simply add 0x100 to the table element retrieved to get the final value of the initial approximation.

If you cannot afford 256 bytes of table storage, an alternative way to generate a starting approximation accurate to 9 bits would be a polynomial of degree 3 that approximates 1 / (1+f) where f is the fractional part of the divisor mantissa, m. Since with IEEE-754, m is known to be in [1.0,2.0), f is in [0.0,1.0).

Correct rounding to nearest-or-even (if required) could be implemented by the back-multiplication of the preliminary quotient by the divisor to establish the remainder, and selecting the final quotient such that the remainder is minimized.

The following code demonstrates the approximation principles discussed above, using the simpler case of the reciprocal, with proper rounding according to IEEE-754 nearest-or-even mode, and with appropriate handling of special cases (zero, denormals, infinity, NaNs). It assumes that a 32-bit IEEE-754 single-precision float can be transferred bit-wise from and to a 32-bit unsigned int. All operations are then performed on 32-bit integers.

```
unsigned int frcp_rn_core (unsigned int z)
{
unsigned int x, y;
int sign;
int expo;
sign = z & 0x80000000;
expo = (z >> 23) & 0xff;
x = expo - 1;
if (x > 0xfd) {
/* handle special cases */
x = z << 1;
/* zero or small denormal returns infinity of like sign */
if (x <= 0x00400000) {
return sign | 0x7f800000;
}
/* infinity returns zero of like sign */
else if (x == 0xff000000) {
return sign;
}
/* convert SNaNs to QNaNs */
else if (x > 0xff000000) {
return z | 0x00400000;
}
/* large denormal, normalize it */
else {
y = x < 0x00800000;
z = x << y;
expo = expo - y;
}
}
y = z & 0x007fffff;
#if USE_TABLE
z = 256 + rcp_tab[y >> 15]; /* approx */
#else
x = y << 3;
z = 0xe39ad7a0;
z = mul_32_hi (x, z) + 0x0154bde4;
z = mul_32_hi (x, z) + 0xfff87521;
z = mul_32_hi (x, z) + 0x00001ffa;
z = z >> 4;
#endif /* USE_TABLE */
y = y | 0x00800000;
/* cubically convergent approximation to reciprocal */
x = (unsigned int)-(int)(y * z); /* x = 1 - arg * approx */
x = mul_32_hi (x, x) + x; /* x = x * x + x */
z = z << 15;
z = mul_32_hi (x, z) + z; /* approx = x * approx + approx */
/* compute result exponent */
expo = 252 - expo;
if (expo >= 0) {
/* result is a normal */
x = y * z + y;
z = (expo << 23) + z;
z = z | sign;
/* round result */
if ((int)x <= (int)(y >> 1)) {
z++;
}
return z;
}
/* result is a denormal */
expo = -expo;
z = z >> expo;
x = y * z + y;
z = z | sign;
/* round result */
if ((int)x <= (int)(y >> 1)) {
z++;
}
return z;
}
```

The function mul_32_high() is a placeholder for a machine-specific operation that returns the upper 32 bits of a signed multiplication of two 32-bit bit integers. A semi-portable implementation in lieu of a machine-specific version is

```
/* 32-bit int, 64-bit long long int */
int mul_32_hi (int a, int b)
{
return (int)(unsigned int)(((unsigned long long)(((long long)a)*b)) >> 32);
}
```

The 256-entry reciprocal table used by the table-based variant can be constructed as follows:

```
static unsigned char rcp_tab[256];
for (int i = 0; i < 256; i++) {
rcp_tab[i] = (unsigned char)(((1./(1.+((i+.5)/256.)))*512.+.5)-256.);
}
```