Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am attempting to generate a random numbers with a logarithmic distribution.

Where n=1 occurs half of the time, n=2 occurs a quarter of the time, n=3 occurs an eighth of the time, etc.

    int maxN = 5;
    int t = 1 << (maxN); // 2^maxN
    int n = maxN -
            ((int) (Math.log((Math.random() * t))
            / Math.log(2))); // maxN - log2(1..maxN)
    System.out.println("n=" + n);

Most of the time, I am getting the result I need, however once every so often, I get a value of n that is larger than maxN.

Why is this so? The way I see it, the max value of Math.random() is 1.0;
therefore the max value of (Math.random() * t)) is t;
therefore the max value of log2(t) is maxN, since t = 2^maxN;

Where has my logic gone off track?

Thanks

share|improve this question
add comment

3 Answers

up vote 4 down vote accepted

logarithm of numbers less than 1.0 is negative. When the random number generated is such that it is less than 1.0, the expression ((int) (Math.log(Math.random() * t) / Math.log(2))) is a negative number and hence maxN - (the negative number) is more than maxN.

The following expression should give correct distribution.

n = Math.floor(Math.log((Math.random() * t) + 1)/Math.log(2))

Note that:

0.0 <= Math.random() <= 1.0
0.0 <= Math.random() * t <= t
1.0 <= (Math.random() * t) + 1 <= t + 1.0
0.0 <= Math.log((Math.random() * t) + 1) <= Math.log(t + 1.0)
0.0 <= Math.log((Math.random() * t) + 1)/Math.log(2) <= Math.log(t + 1.0)/Math.log(2)

Since t = 2^maxN,
Math.log(t + 1.0)/Math.log(2) is slightly larger than maxN.

So do a Math.floor and you get the correct result:
0.0 <= Math.floor(Math.log((Math.random() * t) + 1)/Math.log(2)) <= maxN
share|improve this answer
    
+1 @abhin4v : Thanks for the comment! –  bguiz Sep 19 '10 at 13:32
    
I had the check, then you took it! –  Leo Izen Sep 19 '10 at 13:47
    
+check @abhin4v : You're right about log(t)/log(2) > maxN The error was "hidden" due to the cast to int, but this is a more emathematically proper way. –  bguiz Sep 19 '10 at 13:47
    
@Leo Izen : Sorry about that! –  bguiz Sep 19 '10 at 13:49
add comment

If Math.random()*t is less that 1, then you will get a negative answer when you take Math.log(Math.random()*t), by the rules of Logarithms. This means that you will get a negative answer when you divide by Math.log(2) because that is 0.69314718055994530941723212145818. This is a negative number divided by a positive number. The answer is negative. maxN - a negative number = maxN + something positive, so n is greater than maxN. To fix this cast Math.random()*t to an int and add 1:

int n = maxN -
        ((int) (Math.log((int)((Math.random() * t)+1))
        / Math.log(2))); // maxN - log2(1..maxN)

Notice the cast inside the log, and the add of 1.

The purpose of adding one would be to avoid the 0. Can't take a log of 0. Also, without adding 1, you could never get maxN inside the log, because Math.random() never produces 1. This way, instead of getting 1 half, 2, a fourth, 3, and eighth, it just starts at 0. This gives 0, a half, 1 a fourth, 2 an eighth, etc.

share|improve this answer
    
Casting a number less than 1.0 to int will produce 0 and taking a log on it will produce -Infinity. Hence your suggestion is incorrect. –  Abhinav Sarkar Sep 19 '10 at 13:18
    
@abhin4v : How would you work around this then.. is there a way to do this without using an if-then-else type construct? –  bguiz Sep 19 '10 at 13:23
    
I just fixed that. –  Leo Izen Sep 19 '10 at 13:23
    
+1 & check @Leo Izen : Thanks, that hit the spot! –  bguiz Sep 19 '10 at 13:31
add comment

The problem is in the other end of the scale.

Consider what would happen if you get a very small random number.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.