## Prerequisites

C++ does not mandate IEEE-754 or a particular rounding method. For this answer, I will assume IEEE-754 is used with a binary format and round-to-nearest, ties-to-even.

## Conclusion

`1/x`

overflows iff `fabs(x) <= std::ldexp(1, -std::numeric_limits<float>::max_exponent)`

. For a constant expression, you can use `std::numeric_limits<float>::min()/4`

.

## Discussion

The choice of rounding direction at the end of the finite range is made as if the exponent range kept going. E.g., using decimal for illustration, if the highest representable finite number were 9.99•10^{17}, the next representable number, if the exponent were not limited, would be 1.00•10^{18}. The midpoint between those two is 9.995•10^{17}, so numbers under that are rounded down and numbers above that are rounded up. With ties-to-even, 9.995•10^{17} is rounded up.

For a binary format, the greatest representable value is (2−ε)•2^{q}, where ε is the “machine epsilon” (the ULP of 1, so 2-ε is the greatest representable significand) and *q* is the maximum exponent. Then the point where rounding occurs is (2−½ε)•2^{q}.

For positive *x*, if 1/*x* < (2−½ε)•2^{q}, the result is rounded downward. Otherwise, it is rounded upward, to ∞. Thus, the result is less than ∞ iff *x* > 1/((2−½ε)•2^{q}) = 2^{−q}/(2-½ε).

1/(2-½ε) is slightly greater than ½, by less than ½ε, so the greatest representable value less than or equal to it is ½. Thus, for positive *x*, the result of `1/x`

is less than ∞ iff *x* > 2^{−q}/2 = 2^{−q−1}, and the situation is symmetric for negative *x*.

C++ tells us the maximum exponent with `std::numeric_limits<double>::max_exponent`

(defined in the header `<limits>`

). However, C++ calibrates this exponent for a significand range of [½, 1) instead of IEEE-754’s [1, 2), so it is one greater than *q*. Thus the −*q*−1 we want is simply `-std::numeric_limits<double>::max_exponent`

.

We can calculate 2^{−q−1} with the `ldexp`

function (declared in `<cmath>`

): `std::ldexp(1, -std::numeric_limits<float>::max_exponent)`

.

With Apple Clang 11, this program:

```
#include <cmath>
#include <iomanip>
#include <iostream>
#include <limits>
int main(void)
{
float x = std::ldexp(1, -std::numeric_limits<float>::max_exponent);
std::cout << std::setprecision(20) << x << " is too small, result will overflow:\n";
std::cout << "\t" << 1/x << ".\n";
x = std::nexttoward(x, INFINITY);
std::cout << std::setprecision(20) << x << " is just big enough, result will not overflow:\n";
std::cout << "\t" << 1/x << ".\n";
}
```

produces:

2.9387358770557187699e-39 is too small, result will overflow:
inf.
2.9387372783541830947e-39 is just big enough, result will not overflow:
3.4028220466166163425e+38.

Accounting for negative numbers as well, `1/x`

overflows iff `fabs(x) <= std::ldexp(1, -std::numeric_limits<float>::max_exponent)`

.

Because of the way IEEE-754 specifies the exponent range, `std::ldexp(1, -std::numeric_limits<float>::max_exponent)`

equals `std::numeric_limits<float>::min()/4`

. (IEEE-754 specifies the minimum normal exponent to be 1−*q*, so the −*q*−1 we desire is (1-*q*)-2.)

`x`

is`0`

..?