`rootn (float_t x, int_t n)`

is a function that computes the *n*-th root x^{1/n} and is supported by some programming languages such as OpenCL. When IEEE-754 floating-point numbers are used, efficient low-accuracy starting approximations for any `n`

can be generated based on simple manipulation of the underlying bit pattern, assuming only normalized operands `x`

need to be processed.

The binary exponent of `root (x, n)`

will be 1/n of the binary exponent of `x`

. The exponent field of an IEEE-754 floating-point number is biased. Instead of un-biasing the exponent, dividing it, and re-biasing the result, we can simply divide the biased exponent by `n`

, then apply an offset to compensate for the previously neglected bias. Furthermore, instead of extracting, then dividing, the exponent field, we can simply divide the entire operand `x`

, re-interpreted as an integer. The required offset is trivial to find as an argument of 1 will return a result of 1 for any `n`

.

If we have two helper functions at our disposal, `__int_as_float()`

which reinterpretes an IEEE-754 `binary32`

as `int32`

, and `__float_as_int()`

which reinterpretes an `int32`

operand as `binary32`

, we arrive at the following low-accuracy approximation to `rootn (x, n)`

in straightforward fashion:

```
rootn (x, n) ~= __int_as_float((int)(__float_as_int(1.0f)*(1.0-1.0/n)) + __float_as_int(x)/n)
```

The integer division `__float_as_int (x) / n`

can be reduced to a shift or multiplication plus shift by well-known optimizations of integer division by constant divisor. Some worked examples are:

```
rootn (x, 2) ~= __int_as_float (0x1fc00000 + __float_as_int (x) / 2) // sqrt (x)
rootn (x, 3) ~= __int_as_float (0x2a555556 + __float_as_int (x) / 3) // cbrt (x)
rootn (x, -1) ~= __int_as_float (0x7f000000 - __float_as_int (x) / 1) // rcp (x)
rootn (x, -2) ~= __int_as_float (0x5f400000 - __float_as_int (x) / 2) // rsqrt (x)
rootn (x, -3) ~= __int_as_float (0x54aaaaaa - __float_as_int (x) / 3) // rcbrt (x)
```

With all these approximations, the result will be exact only when `x`

= 2^{n*m} for integer `m`

. Otherwise, the approximation will provide an overestimation compared to the true mathematical result. We can approximately halve the *maximum relative error* by reducing the offset slightly, leading to a balanced mix of underestimation and overestimation. This is easily accomplished by a binary search for the optimal offset that uses all floating-point numbers in the interval [1, 2^{n}) as test cases. Doing so, we find:

```
rootn (x, 2) ~= __int_as_float (0x1fbb4f2e + __float_as_int(x)/2) // max rel err = 3.47474e-2
rootn (x, 3) ~= __int_as_float (0x2a51067f + __float_as_int(x)/3) // max rel err = 3.15547e-2
rootn (x,-1) ~= __int_as_float (0x7ef311c2 - __float_as_int(x)/1) // max rel err = 5.05103e-2
rootn (x,-2) ~= __int_as_float (0x5f37642f - __float_as_int(x)/2) // max rel err = 3.42128e-2
rootn (x,-3) ~= __int_as_float (0x54a232a3 - __float_as_int(x)/3) // max rel err = 3.42405e-2
```

Some may notice that the computation for `rootn (x,-2)`

is basically the initial portion of Quake's fast inverse square root.

Based on observing the differences between the original raw offset, and the final offset *optimized to minimize the maximum relative error*, I could formulate a heuristic for the secondary correction and thus the final, optimized, offset value.

However, I am wondering whether it is possible to determine the optimal offset by some closed-form formula, such that the maximum absolute value of the relative error, max (|(approx(x,n) - x^{1/n}) / x^{1/n}|), is minimized for all `x`

in [1,2^{n}). For ease of exposition, we can restrict to `binary32`

(IEEE-754 single-precision) numbers.

I am aware that in general, there is no closed-form solution for minimax approximations, however I am under the impression that closed-form solutions do exist for the case of polynomial approximations to algebraic functions like *n*-th root. In this case we have (piecewise) linear approximation.

slightlybased on the exact nature of the subsequent iteration. However for now I am wondering whether there is a close-formed expression just for an optimal approximation itself, which seems to be a hard enough problem.9more comments