# Portable way to check whether a floating point division would end in +-inf

I have a floating point division of the form `1.0f / x` with `x` as a `float`. How would I check beforehand whether the `x` is so close to `0.0f` that the result would be +-inf / undefined? I'm not sure if the epsilon from std limits is enough.

Regards.

• You can convert your floating point number in the string and then you can check the number after decimal. By checking number of 0s after decimal, you can decide how close this number is to '0.0f'. Sep 24, 2021 at 10:22
• @krpra You can do that with small floating point constants without having to convert to a string.
– Rup
Sep 24, 2021 at 10:24
• This doesn't sound like what I want. What I basically want is an epsilon that is large enough so I can be sure that for every x larger than it 1.0f / x will not yield inf or undefined. Sep 24, 2021 at 10:27
• I don't understand these questions that try to predict the future. Why wouldn't you just do the division and examine the result? Sep 25, 2021 at 3:57

We could search for the limit using trial and error:

``````#include <iostream>
#include <limits>

#include <cmath>

int main() {
float limit = 0.0f;
float result = 1.0f / limit;
while (
result == std::numeric_limits<float>::infinity()
or std::isnan(result)
) {
limit = std::nextafter(limit, 1.0f);
result = 1.0f / limit;
}
std::cout << "Limit = " << limit << std::endl;
std::cout << "1.0f / Limit = " << 1.0f / limit << std::endl;
}
``````

This outputs on my system:

``````Limit = 2.93874e-39
1.0f / Limit = 3.40282e+38
``````

This is however, not a very efficient solution. If we could make this algorithm `constexpr`, this would mitigate the issue but unfortunately `std::nextafter()` isn't `constexpr`.

If you know your environment is using IEEE-754 airthmetic, these limits are probably constant, but as you ask for portability, we can't always assume that.

• this can be made `constexpr` so that the constant is only calculated once at compile time Sep 24, 2021 at 11:22
• I also did some similar tests and arrived at a number very similar to `2.93874e-39`. But what surprises me is that that value is less than `std::numeric_limits<float>::min()` (which is `1.17549e-38`). Did I miss something? Sep 24, 2021 at 11:24
• I think `min()` might be smallest non subnormal or denormal float value. Perhaps the quoted figure is one of the subnormals or denormals? is the value smaller than `std::numeric_limits<float>::denorm_min()` ? Sep 24, 2021 at 11:25
• Alas, `nextafter()` does not appear to be `constexpr`, so I'm not sure this implementation can be made `constexpr`. Sep 24, 2021 at 11:39

## 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

Rounding at the end of the finite range is performed as if the exponent kept going. E.g., using decimal for illustration, if the highest representable finite number were 9.99•1017, the next representable number, if the exponent were not limited, would be 1.00•1018. The midpoint between those two is 9.995•1017, so numbers under that are rounded down and numbers above that are rounded up. With ties-to-even, 9.995•1017 is rounded up.

For a binary format, the greatest representable value is (2−ε)•2q, 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)•2q.

If 1/x < (2−½ε)•2q, the result is rounded downward. Otherwise, it is rounded upward, to ∞. Thus, the result is less than ∞ iff x > 1/((2−½ε)•2q) = 2q/(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, the result of `1/x` is less than ∞ iff x > 2q/2 = 2q−1.

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 2q−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.)

• Is there a reliable way to check for IEEE 754 support nowadays in C++? Some claim even std::numeric_limits<float>::is_iec559; isn't 100% reliable. Sep 24, 2021 at 14:44
• That's curious, do you know on what basis those claims of unreliability are made? Sep 24, 2021 at 15:51
• @saxbophone stackoverflow.com/questions/5777484/… The discussion after the answer. Sep 24, 2021 at 16:30

Since you're looking for constant values, we can actually use an SMT solver to find the minimum/maximum values of `x` where the division `1/x` will produce infinity. I did this using Microsoft's z3 SMT solver (https://github.com/Z3Prover/z3), scripting it from Haskell SBV bindings (http://leventerkok.github.io/sbv/). I get:

``````Prelude Data.SBV> optimize Lexicographic \$ do x <- sFloat "x"; constrain (fpIsInfinite (1/x)); minimize "x" x
Optimal model:
x   = -2.938736e-39 :: Float
x_0 =    2145386495 :: Word32
Prelude Data.SBV> optimize Lexicographic \$ do x <- sFloat "x"; constrain (fpIsInfinite (1/x)); maximize "x" x
Optimal model:
x   = 2.938736e-39 :: Float
x_0 =   2149580800 :: Word32
``````

If you squint at this, you'll find that the values it's suggesting are between `-2.938736e-39` and `2.938736e-39` where `1/x` becomes infinity.

If you want to write this "portably" without any rounding issues, you should use the hexadecimal notation, i.e., `-0x1p-128` and `0x1p-128`.

I believe these numbers match @Eric Postpischill's values; and his analysis is very useful of course, but this is another way of finding such values using automated theorem-proving techniques.