So the answer is no. This information doesn't really help. It may get you a little better, but not in big O.

To everyone who suggested hashing to get linear time, you can just as well do the same for sorting. This method is called radix/hash sort. It blows up your memory usage.

When there are more restrictions, you can even use cooler tricks (i.e. sum, xor, etc.)

However, for an algorithm that uses comparison only on a generalized array, you're not buying much by reducing the problem this way.

To give a simple intuition for this, suppose you have 1 redundancy for each element, so your array is a1,a1,...an,an (total of 2n elements of n unique numbers).

The size of the solution space is n! (so long as aj-aj are paired, you can permute the pair anyway you want as specified in your problem statement). The size of the input space is (2n)!/(2^(n)).

This means your algorithm needs to produce enough information to arrange ((2n)!/n!)/(2^n) = (n*(n+1)*...2n)/(2^n) elements. Each comparison gives you 1 bit of information. The number of required comparison iterations is log(n)+log(n+1)...+log(2n)-n which is big_omega(nlog(n)). This is not better or worse than sorting.

Here's a semi-rigorous treatment for sorting:
http://www.cs.cmu.edu/~avrim/451f11/lectures/lect0913.pdf

I can probably be bribed to generate a similar proof for the current question.

`n^2`

and`n^3`

runtime, so that's obviously worse than a sort. It may be simpler for your problem though... – nbrooks Dec 24 '12 at 15:31