Echoing Mike Allen's answer, but hoping to provide some additional context (would've left this as a comment rather than a separate answer, but SO's reputation feature wouldn't let me).
Integers have a maximum range of values defined as either 0 to 2^n (if it is an unsigned integer) or -2^(n-1) to 2^(n-1) (for signed integers) where n is the number of bits in the underlying implementation (n=32 in this case). If you wish to represent a number larger than 2^31 with a signed value, you can't use an int. A signed long will work up to 2^63. For anything larger than this, a signed float can go up to roughly 2^127.
One other thing to note is that these resolution issues are only in force when the value stored in the floating point number approaches the max. In this case, the subtraction operation causes a change in true value that is many orders of magnitude smaller than the first value. A float would not round off the difference between 100 and 101, but it might round off the difference between 10000000000000000000000000000 and 10000000000000000000000000001.
Same goes for small values. If you cast 0.1 to an integer, you get exactly 0. This is not generally considered a failing of the integer data type.
If you are operating on numbers that are many orders of magnitude different in size, and also not able to tolerate rounding errors, you will need data structures and algorithms that account for inherent limitations of binary data representation. One possible solution would be to use a floating point encoding with fewer bits of exponential, thereby limiting the max value but providing for greater resolution is less significant bits. For greater detail, check out: