Using IEEE 754 rounding, let's see what's going on.

In IEEE 754 single-precision floating point, the value of a finite number is dictated by the following:

-1^{sign} × 2^{exponent} × (1 + mantissa × 2^{-23})

Where

*sign* is 0 if positive, otherwise 1;
*exponent* is a value between -126 and 127 (-127 and 128 are special); and
*mantissa* is a value between 0 and 8388607 (because it's a 23 bit integer).

If we substitute *sign* with 0 and *exponent* with -2, then we're guaranteed a value between 0.25 and 0.5. Why?

1 × 2^{-2}

is ¼. The value of

1 + mantissa × 2^{-23}

is guaranteed to be between 1 and 2, so that's our sign and exponent sorted.

Moving on, we can work out fairly quickly that there are two values which can be used as the *mantissa* value: 2796202 and 2796203.

Substituting each in, we get the following two values (one lower, one higher):

- 0.333333313465118408203125 (for
*mantissa* = 2796202)
- 0.3333333432674407958984375 (for
*mantissa* = 2796203)

The binary representation of the exact value (up to 22 digits) is:

```
1010101010101010101010...
```

As the next digit would be `1`

, that would mean the value rounds *up*, not down. For this reason, the higher one has a less significant error than the lower one:

- 0.333333313465118408203125 - ⅓ ≑ -1.987 × 10
^{-8}
- 0.3333333432674407958984375 - ⅓ ≑ 9.934 × 10
^{-9}

And since it's larger than the exact value, when multiplied back it will be more than 1. That's why it uses a value that appears off initially -- binary rounding sometimes goes in the opposite direction of decimal rounding.

representable value. It is not like decimal rounding. – Marc Gravell♦ Feb 15 '14 at 9:13