Sure, there are whole numbers that are not representable as double-precision floating points.

All whole numbers not exceeding `Pow(2, 53)`

or `9007199254740992`

, *are* representable. From `Pow(2, 53)`

to `Pow(2, 54)`

(that's `18014398509481984`

), only even numbers are representable. The odd numbers will be rounded.

Of course it continues like that. From `Pow(2, 54)`

to `Pow(2, 55)`

only the multiples of 4 (those whole numbers which 4 divides) are representable, from `Pow(2, 55)`

to `Pow(2, 56)`

only multiples of 8, and so on.

This is because the double-precision floating-point format has 53 bits (binary digits) for the mantissa (significand).

It is easy to verify my claims. For example, take the number `10000000000000001`

as an `integer64`

. Convert it to `double`

and then back to `integer64`

. You will see the precision loss.

When you take very large double-precision numbers, certainly a very little percentage of the whole numbers is representable. For example near `1E+300`

(which is between `Pow(2, 996)`

and `Pow(2, 997)`

) we are talking multiples of `Pow(2, 944)`

(`1.4870169084777831E+284`

). This is consistent with the fact that a `double`

is precise up to approximately 16 decimal figures. So a whole number with 300 figures will be "remembered" only by its first approx. 16 figures (actually 53 binary digits).

Addition: The first power of ten that is not exactly representable is `1E+23`

(or 100 sextillions, short scale naming style). Near that number, only integral multiples of `16777216`

(that is `Pow(2, 24)`

) are representable, but ten to the 23rd power is clearly not a multiple of two to the 24th power. The prime factorization is `10**23 == 2**23 * 5**23`

, so we can divide evenly by two only 23 times, not 24 times as required.