I am trying to determine the `double`

machine epsilon in Java, using the definition of it being the smallest representable `double`

value `x`

such that `1.0 + x != 1.0`

, just as in C/C++. According to wikipedia, this machine epsilon is equal to `2^-52`

(with 52 being the number of `double`

mantissa bits - 1).

My implementation uses the `Math.ulp()`

function:

```
double eps = Math.ulp(1.0);
System.out.println("eps = " + eps);
System.out.println("eps == 2^-52? " + (eps == Math.pow(2, -52)));
```

and the results are what I expected:

```
eps = 2.220446049250313E-16
eps == 2^-52? true
```

So far, so good. However, if I check that the given `eps`

is indeed the *smallest* `x`

such that `1.0 + x != 1.0`

, there seems to be a smaller one, aka the *previous* `double`

value according to `Math.nextAfter()`

:

```
double epsPred = Math.nextAfter(eps, Double.NEGATIVE_INFINITY);
System.out.println("epsPred = " + epsPred);
System.out.println("epsPred < eps? " + (epsPred < eps));
System.out.println("1.0 + epsPred == 1.0? " + (1.0 + epsPred == 1.0));
```

Which yields:

```
epsPred = 2.2204460492503128E-16
epsPred < eps? true
1.0 + epsPred == 1.0? false
```

As we see, we have a smaller than machine epsilon such which, added to 1, yields not 1, in contradiction to the definition.

So what is wrong with the commonly accepted value for machine epsilon according to this definition? Or did I miss something? I suspect another esoteric aspect of floating-point maths, but I can't see where I went wrong...

**EDIT:** Thanks to the commenters, I finally got it. I actually used the wrong definition! `eps = Math.ulp(1.0)`

computes the distance to the smallest representable double > `1.0`

, but -- and that's the point -- that `eps`

is *not* the smallest `x`

with `1.0 + x != 1.0`

, but rather about *twice* that value: Adding `1.0 + Math.nextAfter(eps/2)`

is rounded *up* to `1.0 + eps`

.

`strictfp`

?`strictfp`

didn't help here.