I implemented the idea given by the answer from woliveirajr: using the Blum Blum Shub pseudo random number generator in its explicit (non-iterative) form, together with a message digest to produce the right index from the arguments.

(You also can take this source from my github repository.)

```
package de.fencing_game.paul.examples;
import java.math.BigInteger;
import java.security.MessageDigest;
import java.security.NoSuchAlgorithmException;
import java.util.Random;
/**
* A pseudo random number generator, which does not
* produce a series of numbers, but each number determined by
* some input (and independent of earlier numbers).
*<p>
* This is based on the
* <a href="http://en.wikipedia.org/wiki/Blum_Blum_Shub">Blum Blum Shub
* algorithm</a>, combined with the SHA-1 message digest to get the
* right index.
*</p>
*<p>
* Inspired by the question
* <a href="http://stackoverflow.com/q/6586042/600500">Algorithm
* for generating a three dimensional random number space</a> on
* Stack Overflow, and the answer from woliveirajr.
*/
public class PseudoRandom {
/**
* An instance of this class represents a range of
* integer numbers, both endpoints inclusive.
*/
public static final class Range {
public int min;
public int max;
public Range(int min, int max) {
this.min = min;
this.max = max;
}
/**
* clips a (positive) BigInteger to the range represented
* by this object.
* @returns an integer between min and max, inclusive.
*/
final int clip(BigInteger bigVal) {
BigInteger modulus =
BigInteger.valueOf(max + 1L - min);
return (int)(min + bigVal.mod(modulus).longValue());
}
}
/* M = p * q =
510458987753305598818664158496165644577818051165198667838943583049282929852810917684801057127 *
1776854827630587786961501611493551956300146782768206322414884019587349631246969724030273647
*/
/**
* A big number, composed of two large primes.
*/
private static final BigInteger M =
new BigInteger("90701151669688414188903413878244126959941449657"+
"82009133495922185615411523457607691918744187485"+
"10492533485214517262505932675573506751182663319"+
"285975046876611245165890299147416689632169");
/* λ(M) = lcm(p-1, q-1) */
/**
* The value of λ(M), where λ is the Carmichael function.
* This is the lowest common multiple of the predecessors of
* the two factors of M.
*/
private static final BigInteger lambdaM =
new BigInteger("53505758348442070944517069391220634799707248289"+
"10045667479610928077057617288038459593720911813"+
"73249762745139558184229125081884863164923576762"+
"05906844204771187443203120630003929150698");
/**
* The number 2 as a BigInteger, for use in the calculations.
*/
private static final BigInteger TWO = BigInteger.valueOf(2);
/**
* the modular square of the seed value.
*/
private BigInteger s_0;
/**
* The MessageDigest used to convert input data
* to an index for our PRNG.
*/
private MessageDigest md;
/**
* Creates a new PseudoRandom instance, using the given seed.
*/
public PseudoRandom(BigInteger seed) {
try {
this.md = MessageDigest.getInstance("SHA-1");
}
catch(NoSuchAlgorithmException ex) {
throw new RuntimeException(ex);
}
initializeSeed(seed);
}
/**
* Creates a new PseudoRandom instance, seeded by the given seed.
*/
public PseudoRandom(byte[] seed) {
this(new BigInteger(1, seed));
}
/**
* Creates a new PseudoRandom instance,
* seeded by the current system time.
*/
public PseudoRandom() {
this(BigInteger.valueOf(System.currentTimeMillis()));
}
/**
* Transforms the initial seed into some value that is
* usable by the generator. (This is completely deterministic.)
*/
private void initializeSeed(BigInteger proposal) {
// we want our seed be big enough so s^2 > M.
BigInteger s = proposal;
while(s.bitLength() <= M.bitLength()/2) {
s = s.shiftLeft(10);
}
// we want gcd(s, M) = 1
while(!M.gcd(s).equals(BigInteger.ONE)) {
s = s.add(BigInteger.ONE);
}
// we save s_0 = s^2 mod M
this.s_0 = s.multiply(s).mod(M);
}
/**
* calculates {@code x_k = r.clip( s_k )}.
*/
private int calculate(Range r, BigInteger k) {
BigInteger exp = TWO.modPow(k, lambdaM);
BigInteger s_k = s_0.modPow(exp, M);
return r.clip(s_k);
}
/**
* returns a number given by a range, determined by the given input.
*/
public int getNumber(Range r, byte[] input) {
byte[] dig;
synchronized(md) {
md.reset();
md.update(input);
dig = md.digest();
}
return calculate(r, new BigInteger(1, dig));
}
/**
* returns a number given by a range, determined by the given input.
*/
public int getNumber(Range r, int... input) {
byte[] dig;
synchronized(md) {
md.reset();
for(int i : input) {
md.update(new byte[]{ (byte)(i >> 24), (byte)(i >> 16),
(byte)(i >> 8), (byte)(i >> 0)} );
}
dig = md.digest();
}
return calculate(r, new BigInteger(1, dig));
}
/**
* Test method.
*/
public static void main(String[] test) {
PseudoRandom pr = new PseudoRandom("Hallo Welt".getBytes());
Range r = new Range(10, 30);
for(int i = 0; i < 10; i++) {
System.out.println("x("+i+") = " + pr.getNumber(r, i));
}
for(int i = 0; i < 5; i++) {
for(int j = 0; j < 5; j++) {
System.out.println("x("+i+", "+j+") = " +
pr.getNumber(r, i, j));
}
}
// to show that it really is deterministic:
for(int i = 0; i < 10; i++) {
System.out.println("x("+i+") = " + pr.getNumber(r, i));
}
}
}
```

I arbitrarily selected these big prime numbers - I don't know if they are really cryptographically secure (e.g. whether `p-1`

and `q-1`

have the necessary factorization properties). If you really need security, you should keep these numbers secret (e.g. generate them yourself).

Also, I use the input seed to generate `s`

(and `s_0`

) - instead one could have used a fixed `s`

(with known *good* properties, like a large period), and use the seed as input to the message digest (together with the input I'm using here).

Of course, one also could have directly used the message digest's output, instead of using it only as an index to BBS.

`hash generator`

that should receive, as a parameter, n-coordinates, each being able to be 32 or 64 bits long (as stated in a commment below), and a seed, and output some value – woliveirajr Jul 6 '11 at 11:16