# Please help me get my random number generating working in Java

I am trying to make a Java implementation of the Park-Miller-Carta PRNG random number generator (maybe faster?)

Below is the implementation of the Random function in ActionScript 3 from here.

``````return (_currentSeed = (_currentSeed * 16807) % 2147483647) / 0x7FFFFFFF
+ 0.000000000233;
``````

I am not having much luck getting this to work in Java:

``````int seed = 20; //for example.

public double random() {
seed = (seed * 16807) % 2147483647;
return seed / 0x7FFFFFFF + 0.000000000233;
}
``````

This always returns `2.33E-10`. Any ideas what I am doing wrong in Java? (the AS3 code returns `0.0001565276181885122`, then `0.6307557630963248` for the first two responses with a seed of `20`).

-
Why? If it's for your own edification, that's one thing, but for production code really good (ie cryptographically secure) random number generation is exceedingly difficult to do right. The RNG is probably the biggest technical vulnerability in most cryptosystems. –  Chris Upchurch Apr 15 '09 at 3:05
@Chris AND Park-Miller-Carta is rather bad. –  Varkhan Apr 15 '09 at 4:06

## 4 Answers

``````seed / 0x7FFFFFFF
``````

is an integer operation, since both arguments are integers. Integer division always rounds the "true" result downwards. In this case, the true result is between 0 and 1, so the operation always returns 0.

To get a floating-point result, at least one of the arguments must be a float, which can be achieved like this:

``````return (double)seed / 0x7FFFFFFF + 0.000000000233;
``````
-

OK, so the essential problem is that you need to do floating-point division, not integer division, as others have pointed out.

But I think fixing this particular code is sort of besides the point. Why bother with it in the first place? It's using essentially the same class of algorithm is java.lang.Random!

If you want a fast generator, consider an XORShift generator. If you want a good-quality generator, you have SecureRandom out of the box (though it's much slower), consider the Numerical Recipes algorithm (a fairly fast, combined generator), which you could implement in Java as follows:

``````public class HighQualityRandom extends Random {

private Lock l = new ReentrantLock();
private long u;
private long v = 4101842887655102017L;
private long w = 1;

public HighQualityRandom() {
this(System.nanoTime());
}
public HighQualityRandom(long seed) {
l.lock();
u = seed ^ v;
nextLong();
v = u;
nextLong();
w = v;
nextLong();
l.unlock();
}

@Override
public long nextLong() {
l.lock();
try {
u = u * 2862933555777941757L + 7046029254386353087L;
v ^= v >>> 17;
v ^= v << 31;
v ^= v >>> 8;
w = 4294957665L * (w & 0xffffffff) + (w >>> 32);
long x = u ^ (u << 21);
x ^= x >>> 35;
x ^= x << 4;
return (x + v) ^ w;
} finally {
l.unlock();
}
}

protected int next(int bits) {
return (int) (nextLong() >>> (64-bits));
}

}
``````

This is copied from some code where I needed it to be concurrent; you could get rid of the lock in principle, or just use regular synchronization.

If you absolutely insist on using Park-Miller-Carta, I'd at least wrap it in a Random subclass, and let java.util.Random take care of converting ints to doubles etc-- after all, that's what extensible libraries in an object-oriented language are for...

-

Replace:

``````return seed / 0x7FFFFFFF+0.000000000233;
``````

with:

``````return (double)seed / 0x7FFFFFFF+0.000000000233;
``````
-

Operator precedence.

``````(seed / 0x7FFFFFFF)+0.000000000233;
``````

is what you really have. Is it what you meant?

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That's what the AS3 code did. So yes, it must be. –  Artelius Apr 15 '09 at 3:17
No, the precedence rules could be different. Also, the semantics of the division operator can be different, which is what appears to have happened. –  Charlie Martin Apr 15 '09 at 16:13