Here's a **short Python answer**:

```
def f(n):
m = -n if n % 2 == 0 else n
return m + sign(n)
```

**General Case**

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`

:

```
def g(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**

The map `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.