For the simple and efficient implementation of fast math functions with reasonable accuracy, polynomial minimax approximations are often the method of choice. Minimax approximations are typically generated with a variant of the Remez algorithm. Various widely available tools such as Maple and Mathematica have built-in functionality for this. The generated coefficients are typically computed using high-precision arithmetic. It is well-known that simply rounding those coefficients to machine precision leads to suboptimal accuracy in the resulting implementation.

Instead, one searches for closely related sets of coefficients that are exactly representable as machine numbers to generate a machine-optimized approximation. Two relevant papers are:

*Nicolas Brisebarre, Jean-Michel Muller, and Arnaud Tisserand, "Computing Machine-Efficient Polynomial Approximations", ACM Transactions on Mathematical Software, Vol. 32, No. 2, June 2006, pp. 236–256.*

*Nicolas Brisebarre and Sylvain Chevillard, "Efficient polynomial L∞-approximations", 18th IEEE Symposium on Computer Arithmetic (ARITH-18), Montpellier (France), June 2007, pp. 169-176.*

An implementation of the LLL-algorithm from the latter paper is available as the `fpminimax()`

command of the Sollya tool. It is my understanding that all algorithms proposed for the generation of machine-optimized approximations are based on heuristics, and that it is therefore generally unknown what accuracy can be achieved by an optimal approximation. It is not clear to me whether the availability of FMA (fused multiply-add) for the evaluation of the approximation has an influence on the answer to that question. It seems to me naively that it should.

I am currently looking at a simple polynomial approximation for arctangent on [-1,1] that is evaluated in IEEE-754 single-precision arithmetic, using the Horner scheme and FMA. See function `atan_poly()`

in the C99 code below. For lack of access to a Linux machine at the moment, I did not use Sollya to generate these coefficients, but used my own heuristic that could be loosely described as a mixture of steepest decent and simulated annealing (to avoid getting stuck on local minima). The maximum error of my machine-optimized polynomial is very close to 1 ulp, but ideally I would like the maximum ulp error to be below 1 ulp.

I am aware that I could change my computation to increase the accuracy, for example by using a leading coefficient represented to more than single-precision precision, but I would like to keep the code exactly as is (that is, as simple as possible) adjusting only the coefficients to deliver the most accurate result possible.

A "proven" optimal set of coefficients would be ideal, pointers to relevant literature are welcome. I did a literature search but could not find any paper that advances the state of the art meaningfully beyond Sollya's `fpminimax()`

, and none that examine the role of FMA (if any) in this issue.

```
// max ulp err = 1.03143
float atan_poly (float a)
{
float r, s;
s = a * a;
r = 0x1.7ed1ccp-9f;
r = fmaf (r, s, -0x1.0c2c08p-6f);
r = fmaf (r, s, 0x1.61fdd0p-5f);
r = fmaf (r, s, -0x1.3556b2p-4f);
r = fmaf (r, s, 0x1.b4e128p-4f);
r = fmaf (r, s, -0x1.230ad2p-3f);
r = fmaf (r, s, 0x1.9978ecp-3f);
r = fmaf (r, s, -0x1.5554dcp-2f);
r = r * s;
r = fmaf (r, a, a);
return r;
}
// max ulp err = 1.52637
float my_atanf (float a)
{
float r, t;
t = fabsf (a);
r = t;
if (t > 1.0f) {
r = 1.0f / r;
}
r = atan_poly (r);
if (t > 1.0f) {
r = fmaf (0x1.ddcb02p-1f, 0x1.aee9d6p+0f, -r); // pi/2 - r
}
r = copysignf (r, a);
return r;
}
```

`float`

it only took seconds to arrive at the "optimal" factoring. – njuffa Nov 1 '14 at 21:51as real polynomials, are good approximations of the target function). In other words, they take into account the fact that the coefficients will have to be represented as floating-point constants, but not the fact that the operations will be floating-point operations. Nothing changes when you add FMA to the equation because operation errors were being ignored in the first place. – Pascal Cuoq Nov 2 '14 at 17:13`ulp = 1.02852 @ -9.31304693e-001 -0x1.dcd3f8p-1`

is the largest positive error,`ulp = -1.03143 @ -9.84267354e-001 -0x1.f7f1e4p-1`

the largest negative one. – njuffa Nov 3 '14 at 6:49