# Evenly distributed hash function

I need a hash function that takes a few (eg. 2 or 3) unsigned integers as input, and returns a floating point value between -1 and +1.

The collection of these returned values must be evenly distributed. A sequence of outputs from the function must appear to be a random sequence, even if the input numbers are sequential. Also the faster the better, i'm calling it a LOT of times.

I hope this isn't too much to ask :S...

-

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.

-
This works great, It is also much simpler than I had imagined! Thanks a bunch. –  Hannesh Sep 29 '10 at 16:30
@Nikita Rybak: This creates collision because of the squaring. Actually, each hash creates them, but here you get them a bit too easily. And for the 1-tuple sequence (-1), (0), (1) the result really doesn't appear random. Powering to 3 or maybe something like (n + 12345) * n could do better. –  maaartinus Sep 28 '12 at 17:14

Murmurhash is a very good (strong) and fast hash function which has had some serious testing done on it.

While it is not dedicated to integers per se, it can be quickly adjusted to do so. I have such an alternate formulation which might be more convenient for you if your words are not sequently laid out in memory:

#define MURMURHASH2A_R 24
#define MURMURHASH2A_MULTIPLIER 0x5bd1e995
#define MURMURHASH2A_SEED 2166136261U  // No seed suggested, so using FNV32_OFFSET_BASIS
#define murmurhash2a_init(h) do { h = MURMURHASH2A_SEED; } while (0)
#define murmurhash2a_update(h,word)                     \
do {                                                    \
u_int mmh2ak = (word) * MURMURHASH2A_MULTIPLIER;      \
mmh2ak ^= mmh2ak >> MURMURHASH2A_R;                   \
mmh2ak *= MURMURHASH2A_MULTIPLIER;                    \
h *= MURMURHASH2A_MULTIPLIER;                         \
h ^= mmh2ak;                                          \
} while (0)
#define murmurhash2a_final(h)                   \
do {                                            \
h ^= h >> 13;                                 \
h *= MURMURHASH2A_MULTIPLIER;                 \
h ^= h >> 15;                                 \
} while (0)

u_int hash;
murmurhash2a_init(hash);
murmurhash2a_update(hash,firstint);
murmurhash2a_update(hash,secondint);
[...]
murmurhash2a_final(hash);


Obviously this is returning 0-2^32-1. There is a 64 bit version on the murmurhash site. Conversion of integer to a float over a range is left as an excercise (in division) for the reader.

-