Dynamic Distribution Algorithm

I've been racking my brain all morning trying to come up with the following algorithm, this is especially frustrating because I'm sure that it's possible.

What I need is a class that has a function that returns `boolean`. It can be called any number of times and will return true `XX%` of the time. This CANNOT be a random distribution, for example:

If the ratio `X` is set to `0.6` and the function is called `100` times, we need to return exactly `60` true results. In which order "left overs" are used doesn't matter, for example: if the function was called `99` times it would be OK to return either `59` or `60` true values.

The trick here is that the ratio needs to be variable.

For some setup, I'm working in a multi threaded environment so I'm keeping my "hitNumber" variable in an `AtomicLong` in order to avoid `synchronization` issues.

Thanks!

-
what have you tried so far? –  andy mccullough Sep 30 '13 at 15:15
What is this boolean result testing for? Or is it just returning a semi-randomized result? –  StormeHawke Sep 30 '13 at 15:15
Fill a boolean array with `X` true values. Shuffle. Retrieve in order. –  Geobits Sep 30 '13 at 15:16
hah. I was just typing out what @Geobits just recommended, but he beat me to it –  StormeHawke Sep 30 '13 at 15:17
@MattKlooster Ah, then go with that. I read it as "a non-random distribution in a random order". –  Geobits Sep 30 '13 at 15:26

If all you want is to maintain the overall percentage, just keep track of the percentage so far (probably as an explicit rational), and return `true` if you're under the target percentage, or `false` if you're over it.

-

Your criterion that it can't be random is pretty ill-defined. I suppose you mean that the quantity T/(T+F) is as close to the ratio as integer T and F will allow.

So you'll end up with something like this:

``````class TrueFalseGenerator {

final double ratio;
long nTrue, nFalse;

TrueFalseGenerator(double ratio) {
this.ratio = ratio;
nTrue = nFalse = 0;
}

synchronized boolean next() {
long den = nTrue + nFalse;
if (den == 0 || (double)nTrue / den < ratio) {
nTrue++;
return true;
} else {
nFalse++;
return false;
}
}
}
``````
-

To build on Ben's answer, you can maintain static class variables to keep track of past function calls. Something like:

``````bool myFunc( float true_percentage ) {

count++; // where count and count_true are class static variables initialized to zero.

if ( float( count_true ) / count >= true_percentage )
return false;

count_true++;
return true;

}
``````
-
This looks like C/C++ code a lot more than Java. ;) Java doesn't support local static variables. It'd be better to store the two counts as non-static instance variables. –  yshavit Sep 30 '13 at 15:27
He did tag this java... –  Gene Sep 30 '13 at 15:30
Yes sorry, missed the tag. I have changed them to class static variables. –  user1990169 Sep 30 '13 at 15:52

This version uses only integer arithmetic and doesn't need any counter:

``````public class Distribution {
private int numerator;
private int denominator;
private int error;

public Distribution(int numerator, int denominator) {
this.numerator = numerator;
this.denominator = denominator;
}

public synchronized boolean next() {
error += numerator;
if (error >= denominator) {
error %= denominator;
return true;
}

return false;
}
}
``````

Usage:

``````Distribution dist = new Distribution(6, 10); // 6 trues out of 10
dist.next(); // get next bool
``````
-
"doesn't need any counter" you're using a counter –  Cruncher Sep 30 '13 at 15:36
No, I'm just calculating an error value that never gets greater than denominator+numerator-1. –  isnot2bad Sep 30 '13 at 15:40
to stay as close to the numerator/denominator ratio as possible after every call, the first next() should return true here, but it's false. –  Cruncher Sep 30 '13 at 15:45
``````//algorithm
//1st call randomize(x) from main with x as percentage
//this calls fischershuffle to shuffle the boolean array
//den calls to return bool are randomized with x trues and 100-x falses per 100 calls

class A{
public static int count=0;
public static boolean fill[]=new boolean[100];

public static void randomize(double x)
{
double totaltrue=x*100;
double totalfalse=100-totaltrue;

for(int i=0;i<100;i++)
{
if(totaltrue>0.00)
{
fill[i]=true;
totaltrue-=1.00;
}
else
{
fill[i]=false;
totalfalse-=1.00;
}
}

fill=fischershuffle(fill);

}

static boolean fischershuffle(boolean[] ar)
{
Random rnd = new Random();
for (int i = ar.length - 1; i > 0; i--)
{
int index = rnd.nextInt(i + 1);
boolean a = ar[index];
ar[index] = ar[i];
ar[i] = a;
}
return ar;
}

public static boolean retunbool()
{
if(count<=100)
{
count++;
return fill[count];
}
else{
count=0;//resets after 100 for next 100 calls
}
``````
-
expanded on geobits answer –  Kaushik Sivakumar Sep 30 '13 at 15:41
Just to let you know, my comment was based on an incorrect assumption, so this answer doesn't really solve the problem in the way it was intended. –  Geobits Sep 30 '13 at 15:42