Floating point values are inexact, which is why we should rarely use strict numerical equality in comparisons. For example, in Java this prints `false`

(as seen on ideone.com):

```
System.out.println(.1 + .2 == .3);
// false
```

Usually the correct way to compare results of floating point calculations is to see if the absolute difference against some expected value is less than some tolerated epsilon.

```
System.out.println(Math.abs(.1 + .2 - .3) < .00000000000001);
// true
```

The question is about whether or not *some* operations can yield exact result. We know that for any non-finite floating point value `x`

(i.e. either `NaN`

or an infinity), `x - x`

is *ALWAYS* `NaN`

.

But if `x`

is finite, is any of this guaranteed?

`x * -1 == -x`

`x - x == 0`

_{(In particular I'm most interested in Java behavior, but discussions for other languages are also welcome.)}

For what it's worth, I think (and I may be wrong here) the answer is *YES!* I think it boils down to whether or not for any finite IEEE-754 floating point value, its additive inverse is always computable exactly. Since e.g. `float`

and `double`

has one dedicated bit just for the sign, this seems to be the case, since it only needs flipping of the sign bit to find the additive inverse (i.e. the significand should be left intact).