One way to create many solutions is to notice that if we have a partition of the integers into two sets S and R s.t -S=S, -R=R, and a function g s.t g(R) = S
then we can create f as follows:
if x is in R then f(x) = g(x)
if x is in S then f(x) = -invg(x)
where invg(g(x))=x so invg is the inverse function for g.
The first solution mentioned above is the partition R=even numbers, R= odd numbers, g(x)=x+1.
We could take any two infinite sets T,P s.t T+U= the set of integers and take S=T+(-T), R=U+(-U).
Then -S=S and -R=R by their definitions and we can take g to be any 1-1 correspondence from S to R, which must exist since both sets are infinite and countable, will work.
So this will give us many solutions however not all of course could be programmed as they would not be finitely defined.
An example of one that can be is:
R= numbers divisible by 3 and S= numbers not divisible by 3.
Then we take g(6r) = 3r+1, g(6r+3) = 3r+2.