edit) Okay, this method isn't as sound as I initially thought. eBusiness's solution is much simpler and works correctly for cases such as n=4, m=2.
We can generalise the xor method to work with arbitrary m and n. We first need to pick a base b such that gcd(n, b) = b, and gcd(m, b) < b. As odd n/even m pairs satisfy this for base 2, the standard binary xor works for these pairs.
Firstly we define (a^^n) to mean (a^a^...^a) for n a's, with generalised xor of base b. For example, with standard binary xor, a^^2 = 0.
We need to define our generalised xor. The properties we desire are basically the same as of addition (commutativity, associativity), and we need a^^b = 0. The obvious solution is (x^y) = (x+y)%b for each digit in the base b representation (convince yourself this works, and is the same as binary xor for base 2). Then, we simply apply this to all numbers in the sequence, and end up with result = s^^(m%b), where s is the special number.
Lastly, we need to revert our 'xor'ed base b number to the expected number. We can simply compute i^^(m%b) for i=0..b-1, and then look up which value we have in s for each digit in result.
This algorithm is be O(N). For each number in the list, we have a constant number of operations to do, because we have at most 64 digits. Reverting at the end is at worst O(N) for large b. We can do this last step in constant space by computing i^^(m%b) for all i for each digit (again, we have a constant number of digits).
n = 3, m = 2. list =
[5 11 5 2 11 5 2 11]
First we choose a base b. Obviously we have to choose base 3.
The xor table for reference:
5 11 5 2 11 5 2 11
0^0=0. 0^1=1. 1^0=1. 1^0=1. 1^1=2. 2^0=2. 2^0=2. 2^1=0.
0^1=1. 1^0=1. 1^1=2. 2^0=2. 2^0=2. 2^1=0. 0^0=0. 0^0=0.
0^2=2. 2^2=1. 1^2=0. 0^2=2. 2^2=1. 1^2=0. 0^2=2. 2^2=1.
m % b = 2.
Thus we have s^^2 = . We generate a table of i^^2 for each digit i, and then do a reverse lookup.
i | 0 | 1 | 2 |
i^^2 | 0 | 2 | 1 |
0 -> 0
0 -> 0
1 -> 2
We lastly convert our result back into binary/decimal.  = 2.