Because while `generator()`

is an uniform distribution over `[generator.min(), generator.max()]`

, `generator() % n`

is not a uniform distribution over `[0, n)`

(unless `generator.max()`

is an exact multiple of `n`

, assuming generator.min() == 0).

Let's take an example: `min() == 0`

, `max() == 65'535`

and `n == 7`

.

`gen()`

will give numbers in the range `[0, 65'535]`

and in this range there are:

`9'363`

numbers such that `gen() % 7 == 0`

`9'363`

numbers such that `gen() % 7 == 1`

`9'362`

numbers such that `gen() % 7 == 2`

`9'362`

numbers such that `gen() % 7 == 3`

`9'362`

numbers such that `gen() % 7 == 4`

`9'362`

numbers such that `gen() % 7 == 5`

`9'362`

numbers such that `gen() % 7 == 6`

If you are wondering where did I get these numbers think of it like this: `65'534`

is an exact multiple of `7`

(`65'534 = 7 * 9'362`

). This means that in `[0, 65'533]`

there are exactly `9'362`

numbers who map to each of the `{0, 1, 2, 3, 4, 5, 6}`

by doing `gen() % 7`

. This leaves `65'534`

who maps to `0`

and `65'535`

who maps to `1`

So you see there is a bias towards `[0, 1]`

than to `[2, 6]`

, i.e.

`0`

and `1`

have a slightly higher chance (`9'363 / 65'536 ≈ 14.28680419921875 %`

) of appearing than
`2`

, `3`

, `4`

, `5`

and `6`

(`9'362 / 65'536 ≈ 14.2852783203125 %`

).

`std::uniformn_distribution`

doesn't have this problem and uses some mathematical woodo with possibly getting more random numbers from the generator to achieve a truly uniform distribution.