# How to compare rational numbers?

This is a homework problem. Given class "Rational" with two integer fields, numerator and denominator, write a function to compare two "Rational" instances. Let `r1 = a/b` and `r2 = c/d`. The trivial solution is to compare `a*d` and `b*c`. Can we do better?

-
What's the definition of "better"? It looks pretty optimal to me. –  Paul Nov 26 '10 at 16:02

Usually the cost of a branch is more than the cost of a multiplication, so it's not worth trying to be to clever apart from that. If by integers you mean int32, then promote to int64 to perform the multiplication; if you mean larger integers then you need to manage the multiplication using the usual mechanisms, at which point the assumptions about branches can be invalidated.

-
-2 (a*d) is equal to -2 (b*c). –  stubbscroll Nov 27 '10 at 11:23

In the general case, no. If you expect to do a lot of comparisons, a preliminary processing step could take care of normalizing everything (by dividing both numerator and denominator by their gcd, and making the denominator positive), so that equality comparisons would compare a = c and b = d, but computing a*d = b*c is certainly not prohibitive by any means.

-

If you want the sophisticated solution, convert each of the two fractions to a continued fraction (using a variant of the GCD algorithm). This simple algorithm generates one integer at a time. Compare each pair of integers from the two partial continued fractions. If they are different, exit. Otherwise generate the next pair and continue while there are more. For rationals, the sequence is finite, so it will terminate soon. I believe this is the best method when a,b,c,d are big.

It has been proved that the continued fraction expansions for all square roots irrationals are recurring. So you can use this also to compare those irrationals, even if their binary computer representations would otherwise give you a wrong result (due to truncation). That means that as soon as you detect the repetition in the pattern, you can terminate, proving equality of the two irrationals.

-
I do not like `a*d b*c` solution because it may lead to unnecessary integer overflow if some of numerators and denominators are big. Although I have no better solution.
If you're using Java, then you can use the `java.math.BigInteger` class if and when you encounter overflow; otherwise, you can implement your own via byte-arrays.