This question is interesting, but raises some issues. First, you will never be able to represent *all* the real numbers using a (even theoretically infinite) computer, for cardinality reasons.

What you are looking for is a "symbolic numbers" datatype. You can imagine some sort of expression tree, with predefined constants, arithmetical operations, and perhaps algebraic (roots of polynomials) and transcendantal (exp, sin, cos, log, etc) functions.

Now the fun part of the story: you cannot find an algorithm which tells whether two such trees are representing the same number (or equivalently, which test whether such a tree is zero). I won't state anything precise, but as a hint, this is similar to the Halting Problem (for computer scientists) or the Gödel Incompleteness Theorem (for mathematicians).

This renders such a class pretty useless.

For some subfields of the reals, you have *canonical forms*, like a/b for the rationals, or finite algebraic extensions of the rationals (a/b + ic/d for complex rationals, a/b + sqrt(2) * a/b for Q[sqrt(2)], etc). These can be used to represent *some particular sets of* algebraic numbers.

In practice, this is the most complicated thing you will need. If you have a particular necessity, like *ranges of floating point numbers* (to *prove* some result is whithin a specified interval, this is probably the closest you can get to *real numbers*), or *arbitrary precision numbers*, you have freely available classes everywhere. Google `boost::range`

for the former, and `gmp`

for the latter.

`[0,1)`

) in finite space. So there is a firm theoretical requirement that you can only get real-like. Then it becomes a matter of picking the approximation that best suits your needs. – dmckee Sep 17 '10 at 17:08