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.