How many unique values are there between 0 and 1 of a standard float?

This is not really the question you want an answer for, but the answer is, not including `0`

and `1`

themselves, that there are `2**23 - 1`

subnormal numbers and `126 * 2**23`

normal numbers in this range, for a total of `127 * 2**23 - 1`

, or `1,065,353,215`

.

But note that these numbers are *not* evenly distributed on the interval between `0`

and `1`

. Using a "delta" of `1f / 1065353215f`

in a loop from `0f`

to `1f`

will not work for you.

If you want to step from 0.0 to 1.0 with eqally long steps of the (decimal) form 0.00...01, maybe you should use `decimal`

instead of `float`

. It will represent numbers like that exactly.

If you stick to `float`

, try with `0.000001`

(ten times greater than your proposed value), but note that errors can build up when performing very many additions with a non-representable number.

**Also note:** There are a few "domains" where you can't even count on the first seven significant decimal digits of a `float`

. Try for example saving the value `0.000986f`

or `0.000987f`

to a `float`

variable (be sure the optimization doesn't hold the value in a "wider" storage location) and write out that variable. The first seven digits are not identical to `0.0009860000`

resp. `0.0009870000`

. Again you can use `decimal`

if you want to work with numbers whose decimal expansions are "short".

**Edit:** If you can use a "binary" step for your loop, try with:

```
float delta = (float)Math.Pow(2, -24);
```

or equivalently as a literal:

```
const float delta = 5.96046448e-8f;
```

The good thing about this delta is that all values you encouter through the loop are exactly representable in your `float`

. Just before (under) `1f`

, you will be taking the shortest possible steps possible for that magnitude.

significant figures. But you need to work take denormal numbers etc into account too. – Jon Skeet Jul 30 '13 at 14:30`float`

really works. – harold Jul 30 '13 at 14:52`float`

has an absolute precision. Instead, its precision changes with its scale. – Russell Borogove Jul 30 '13 at 19:28