This answer assumes that the primary concern here is robustness with regard to accuracy, rather than robustness with regard to overflow or underflow in intermediate floating-point computations. The question indicates an awareness of the problem of subtractive cancellation when the commonly used mathematical formula is applied directly using floating-point arithmetic, and the techniques to work around it.

An additional issue to be considered is the accurate computation of the term `b²-4ac`

. It is examined in detail in the following research note:

William Kahan, "On the Cost of Floating-Point Computation Without Extra-Precise Arithmetic", Nov. 21, 2004 (online)

Recent follow-up work to Kahan's note looked at the more general issue of computing the difference of two products `ab-cd`

:

Claude-Pierre Jeannerod, Nicolas Louvet, Jean-Michel Muller, "Further analysis of Kahan's algorithm for the accurate computation of 2 x 2 determinants." *Mathematics of Computation*, Vol. 82, No. 284, Oct. 2013, pp. 2245-2264 (online)

This makes use of the fused multiply-add operation, or FMA, which is available on almost all modern processors including x86-64, ARM64, and GPUs. It is exposed in C/C++ as a standard math function `fma()`

. Note that on platforms without hardware support for FMA, `fma()`

must use emulation, which is often quite slow, and some emulations have been found to have serious functional deficiencies.

FMA computes `a*b+c`

using the full product (neither rounded nor truncated in any way) and applies a single rounding at the end. This allows the accurate computation of the product of two native-precision floating-point numbers as the unevaluated sum of two native-precision floating-point numbers, without resorting to the use of extended-precision arithmetic in intermediate computation: `h = a * b`

and `l = fma (a, b,- h)`

where `h+l`

represents the product `a*b`

*exactly*. This provides for the efficient computation of `ab-cd`

as follows:

```
/*
diff_of_products() computes a*b-c*d with a maximum error <= 1.5 ulp
Claude-Pierre Jeannerod, Nicolas Louvet, and Jean-Michel Muller,
"Further Analysis of Kahan's Algorithm for the Accurate Computation
of 2x2 Determinants". Mathematics of Computation, Vol. 82, No. 284,
Oct. 2013, pp. 2245-2264
*/
double diff_of_products (double a, double b, double c, double d)
{
double w = d * c;
double e = fma (-d, c, w);
double f = fma (a, b, -w);
return f + e;
}
```

With this building block, the real roots of a quadratic equation can be computed with high accuracy as follows, provided the discriminant is positive:

```
/* compute the real roots of a quadratic equation: ax² + bx + c = 0,
provided the discriminant b²-4ac is positive
*/
void solve_quadratic (double a, double b, double c, double *x0, double *x1)
{
double q = -0.5 * (b + copysign (sqrt (diff_of_products (b, b, 4.0*a, c)), b));
*x0 = q / a;
*x1 = c / q;
}
```

In extensive testing with test cases that do not overflow or underflow in intermediate computation, the maximum error observed in the computed solutions never exceeded 3 ulps.