Edit: I know floating point arithmetic is not exact. And the arithmetic isn't even my problem. The addition gives the result I expected. `8099.99975f`

doesn't.

So I have this little program:

```
public class Test {
public static void main(String[] args) {
System.out.println(8099.99975f); // 8099.9995
System.out.println(8099.9995f + 0.00025f); // 8100.0
System.out.println(8100f == 8099.99975f); // false
System.out.println(8099.9995f + 0.00025f == 8099.99975f); // false
// I know comparing floats with == can be troublesome
// but here they really should be equal in every bit.
}
}
```

I wrote it to check if `8099.99975`

is rounded to `8100`

when written as an IEEE 754 single precision float. To my surprise Java converts it to `8099.9995`

when written as a float literal (`8099.99975f`

). I checked my calculations and the IEEE standard again but couldn't find any mistakes. `8100`

is just as far away from `8099.99975`

as `8099.9995`

but the last bit of `8100`

is `0`

which should make it the right represantation.

So I checked the Java language spec to see if I missed something. After a quick search I found two things:

The Java programming language requires that floating-point arithmetic behave as if every floating-point operator rounded its floating-point result to the result precision. Inexact results must be rounded to the representable value nearest to the infinitely precise result; if the two nearest representable values are equally near, the one with its least significant bit zero is chosen.

The Java programming language uses round toward zero when converting a floating value to an integer [...].

I noticed here that nothing was said about float literals. So I thought that float literals maybe are just doubles which when cast to float are rounded to zero similarly to the float to int casting. That would explain why `8099.99975f`

was rounded to zero.

I wrote the little programm you can see above to check my theory and indeed found that when adding two float literals that should result in `8100`

the correct float is computed. (Note here that `8099.9995`

and `0.00025`

can be represented exactly as single floats so there's no rounding that could lead to a different result) This confused me since it didn't make much sense to me that float literals and computed floats behaved differently so I dug around in the language spec some more and found this:

A floating-point literal is of type float if it is suffixed with an ASCII letter F or f [...]. The elements of the types float [...] are those values that can be represented using the IEEE 754 32-bit single-precision [...] binary floating-point formats.

This ultimatively states that the literal should be rounded accourding to the IEEE standard which in this case is to `8100`

. So why is it `8099.9995`

?

`println`

is a dirty liar - I suspect it is rounding unexpectedly and throwing off the test-case results/observations. Try with an explicit String.format. – user2864740 Nov 25 '13 at 1:17`println(String.format("%.20f", v))`

should result in representative display values. – user2864740 Nov 25 '13 at 1:23`println`

was the problem, I'd still expect`8099.9995f + 0.00025f == 8099.99975f`

to be true. And I know that floating point arithmetic isn't exact. I know that my result is not going to be exactly 8099.99975. But the first two numbers are represented exactly. They aren't rounded or anything. I don't see why the addition of two numbers doesn't result in the same result as the decimal to single float conversion. – IchBinKeinBaum Nov 25 '13 at 1:30`new BigDecimal(8099.99975f).toString()`

etc. The BigDecimal constructor and its toString() are both exact. – Patricia Shanahan Nov 25 '13 at 3:09