You can employ standard scheme for such tasks: `(a0 + Q*a1 + Q^2*a2 + Q^3*a3 + ...) % M`

where `M`

is a very large prime number and `Q`

is coefficient of your choice.

Once you have random enough hash in range `[0, M)`

, converting it to floating point number `[-1, 1]`

is trivial.

Or you can remove `% M`

and allow integer overflow to happen, although I'm not sure how secure it is (from 'evenly distributed' perspective).

*A sequence of outputs from the function must appear to be a random sequence, even if the input numbers are sequential.*

For this you can instead of `ai`

use `ai*ai`

in the expression. Anyway, here's the simple implementation in Java.

```
double hash(int... a) {
int Q = 433494437;
int result = 0;
for (int n : a) {
result = result * Q + n * n;
}
result *= Q;
return (double) result / Integer.MIN_VALUE;
}
```

Output does look random even for consecutive numbers. You can also use 64-bit integer for more precision.