So I know about floating point precision (and how things like 1.1 can't be expressed exactly in binary) and all that, but I'm wondering: how then, do mathrelated libraries implement infinite precision? In other words, how would you represent, for example, 1.1 accurately in binary? Just a brief description would be great, I can figure out the exact details myself. Thanks. :)
There are no infinite precision libraries, but there are arbitrary precision libraries. For details of how these are implemented, read some documentation :) To represent 1.1 exactly in binary, floating point can't be used as you correctly point out. It can be represented if you store the integral part (1) as an integer, and the fractional part (.1) as another integer, and then you need to create the logic to deal with these structures. Alternatively, it could be stored as a fraction (11/10) with both the denominator and the numerator stored as integers. 


You could also represent numbers in decimal and do decimal arithmetic. The underlying representation is binary in the sense that each digit is represented with a binary code. Each digit  whether to the left or right of the decimal point  is treated as an integer. Arithmetic is then done ``manually'', digitbydigit. One example of a decimalbased library is BCMath in PHP. 


If you really mean infinite precision there are two options:



There are certain geometric algorithms that depend on exact arithmetic, so if you look in the CGAL library you will find a variety of exact numeric types that are "closed" under various operations. That is, there is no way to use the supported operations to produce a result that can't be represented exactly. Some examples:



While Pax is totally right here when we're talking about floating points and numbers, I believe there is a solution but it's very inefficient. 


Mathematical libraries with infinite precision are not implemented. It cannot be done. The number 1/3 cannot be represented in a finite number of bits other than as a fraction. Transcendent numbers like pi and e cannot be represented completely in any fashion. On the other hand, it is possible to create math libraries with huge precision. It's all a matter of allocating enough bits for the mantissa of the floating point value. 

