Is this is a feature of the design, an mathematical artifact, or some optimisation done by compilers and runtime environments?

It's a feature of the real numbers. A theorem from modern algebra (modern algebra, not high school algebra; math majors take a class in modern algebra after their basic calculus and linear algebra classes) says that for some positive integer *b*, any positive real number *r* can be expressed as *r = a* * *b*^{p}, where *a* is in [1,*b*) and *p* is some integer. For example, 1024_{10} = 1.024_{10}*10^{3}. It is this theorem that justifies our use of scientific notation.

That number *a* can be classified as terminal (e.g. 1.0), repeating (1/3=0.333...), or non-repeating (the representation of pi). There's a minor issue here with terminal numbers. Any terminal number can be also be represented as a repeating number. For example, 0.999... and 1 are the same number. This ambiguity in representation can be resolved by specifying that numbers that can be represented as terminal numbers are represented as such.

What you have discovered is a consequence of the fact that all integers have a terminal representation in any base.

There is an issue here with how the reals are represented in a computer. Just as `int`

and `long long int`

don't represent all of integers, `float`

and `double`

don't represent all of the reals. The scheme used on most computer to represent a real number *r* is to represent in the form *r = a**2^{p}, but with the mantissa (or significand) *a* truncated to a certain number of bits and the exponent *p* limited to some finite number. What this means is that some integers cannot be represented exactly. For example, even though a googol (10^{100}) is an integer, it's floating point representation is not exact. The base 2 representation of a googol is a 333 bit number. This 333 bit mantissa is truncated to 52+1 bits.

On consequence of this is that double precision arithmetic is no longer exact, even for integers if the integers in question are greater than 2^{53}. Try your experiment using the type `unsigned long long int`

on values between 2^{53} and 2^{64}. You'll find that double precision arithmetic is no longer exact for these large integers.

`2^53`

and you'll see. :) – Mysticial Oct 25 '12 at 8:39`22334455667788`

an integer or a floating-point constant in Javascript? – Andrey Oct 25 '12 at 8:44didn'tchoose. Can only pick one @_@ – MarcWan Oct 26 '12 at 4:42