Here's a short Python answer:
m = -n if n % 2 == 0 else n
return m + sign(n)
A slight tweak to the above can handle the case where we want
k self-calls to negate the input -- for example, if
k = 3, this would mean
g(g(g(n))) = -n:
if n % k: return n + sign(n)
return -n + (k - 1) * sign(n)
This works by leaving 0 in place and creating cycles of length 2 * k so that, within any cycle, n and -n are distance k apart. Specifically, each cycle looks like:
N * k + 1, N * k + 2, ... , N * k + (k - 1), - N * k - 1, ... , - N * k - (k - 1)
or, to make it easier to understand, here are example cycles with
k = 3:
1, 2, 3, -1, -2, -3
4, 5, 6, -4, -5, -6
This set of cycles maximizes the ranges of inputs that will work within any machine type centered around zero, such as signed int32 or signed int64 types.
Analysis of compatible ranges
x -> f(x) in fact must form cycles of length
2 * k, where
x = 0 is a special case 1-length cycle since -0 = 0. So the problem for general
k is solvable if and only if the range of the input - 1 (to compensate for 0) is a multiple of 2 * k, and the positive and negative ranges are opposites.
For signed integer representations, we always have a smallest negative number with no positive counterpart in the range, so the problem becomes unsolveable on the complete range. For example, a
signed char has range [-128, 127], so it's impossible for
f(f(-128)) = 128 within the given range.