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Javascript's MATH object has a random method that returns from the set [0,1) 0 inclusive, 1 exclusive. Is there a way to return a truly random method that includes 1.

e.g.

var rand = MATH.random()*2;

if(rand > 1)
{
   rand = MATH.floor(rand);
}

return rand; 

While this always returns a number from the set [0,1] it is not truly random.

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2  
define random :) – Luca Matteis Jan 27 '10 at 0:22
1  
I'm wondering what the use of specifically including 1? – bryantsai Jan 27 '10 at 0:26
2  
It is random; just not uniformly random. – Will Vousden Jan 27 '10 at 0:26
    
apologies, i mean uniformly random. – Adrian Adkison Jan 27 '10 at 0:28
    
as far as the application of this, just curious :) – Adrian Adkison Jan 27 '10 at 0:33
up vote 8 down vote accepted

Whether it's inclusive of the boundaries shouldn't matter; indeed, strictly speaking what you're trying to do doesn't really make sense. Remember that under a continuous probability distribution, the probability of getting a specific value is infinitesimal anyway, so mathematically speaking, you'll never see the exact value of 1.

Of course, in the world of computers, the distribution of an RNG isn't truly continuous, so it's "possible" that you'll encounter a specific value (whatever that means), but the fact that you're relying on an a limitation of how real numbers are stored hints at problems with your approach to whatever problem you're trying to solve.

share|improve this answer
    
Thanks for your reply. I think it's just a poorly formed exercise that I am doing. The exercise is to write your own Math object with a random method that has takes min,max and inclusive as arguments. The inclusive argument being a boolean that says whether you want the set to be inclusive or exclusive. Now as i pointed out in my initial question that the Math.random() function is neither inclusive or exclusive becuase it inludes 0 but excludes 1. So to write a random method that is truly inclusive or exclusive and uniformly distributed is not possible, right? – Adrian Adkison Jan 27 '10 at 0:42
    
It's not impossible, since there is actually only a finite number of values that can be generated by the RNG between 0 and 1 (rather than a continuum). It is, however, mathematically nonsensical to do so. Either the exercise is referring specifically to integers, or it's a bad question. Furthermore, extending a discrete uniform distribution to form another uniform distribution is non-trivial. Trevor's and Brian McKenna's solutions are very close, but not perfectly uniform. – Will Vousden Jan 27 '10 at 0:48

This will return [0,1] inclusive:

if(MATH.random() == 0)
    return 1;
else
    return MATH.random();

Explanation: If the first call to random() returns 0, return 1. Otherwise, call random again, which will be [0,1). Therefore, it will return [0,1] all inclusive.

share|improve this answer
    
why random twice. what if you still get 0 ... – bryantsai Jan 27 '10 at 0:31
    
This will not include 0 either, as you mention in your comment to nickf – Gaby aka G. Petrioli Jan 27 '10 at 0:33
1  
If the first random() call isn't 0, the second random() call might be. – Trevor Jan 27 '10 at 0:35
    
I guess it's hard to say uniform, but +1 for bring 1 back in. – bryantsai Jan 27 '10 at 0:38
7  
This isn't quite uniform, but it's very close. – Will Vousden Jan 27 '10 at 0:42

The Math.random function returns a random number between 0 and 1, where 0 is inclusive and 1 is exclusive. This means that the only way to properly distribute the random numbers as integers in an interval is to use an exclusive upper limit.

To specify an inclusive upper limit, you just add one to it to make it exclusive in the calculation. This will distribute the random numbers correctly between 7 and 12, inclusive:

var min = 7;
var max = 12;
var rnd = min + Math.floor(Math.random() * (max - min + 1));
share|improve this answer
    
+1 For the classic approach to defining an arbitrary random range – Justin Johnson Jan 27 '10 at 2:45

You want it to include 1?

return 1 - Math.random();

However, I think this is one of those questions which hints at other problems. Why do you need to include 1? There's probably a better way to do it.

share|improve this answer
4  
But it won't include 0 – Trevor Jan 27 '10 at 0:32
    
that would be 0 exclusive now .. wouldn't it ? – Gaby aka G. Petrioli Jan 27 '10 at 0:32
4  
Yes, but he didn't say that excluding 0 was a problem, only that excluding 1 was. – John Knoeller Jan 27 '10 at 0:47

Addendum:

Taking a look at the java.util.Random source code included with the distribution of Oracle JDK 7 ("Copyright (c) 1995, 2010, Oracle and/or its affiliates. All rights reserved. ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms") shows this simple code:

class Random {

    public float nextFloat() {
        return next(24) / ((float)(1 << 24));
    }

    protected int next(int bits) {
        long oldseed, nextseed;
        AtomicLong seed = this.seed;
        do {
            oldseed = seed.get();
            nextseed = (oldseed * multiplier + addend) & mask;
        } while (!seed.compareAndSet(oldseed, nextseed));
        return (int)(nextseed >>> (48 - bits));
    }
}

Thus, for nextFloat():

  1. Take a "random integer value" between 0 and 2^24-1 (or rather, a random 24-bit bitpattern interpreted as an integer value),
  2. Convert it to float (in Java, "float" is mandated to be an IEEE 724 32-bit floating point, which can represent up to 2^24 with no loss of precision, and this will thus be a value between 0 and 1.6777215E7)
  3. Then divide it by the float representation of 2^24, again just representable with no loss of precision as 1.6777216E7. 2^24+1 = 16777217 would drop down to 1.6777216E7 when forced to be float. In the code, this should really be a constant. Hey Sun, cycles don't grow on trees!!
  4. Division results in a float in [0.0 .. 0.99999994] (the correct division result would be around 0.999999940395355224609375), with, I think, all the possible IEEE 724 floating point values in between 'equally possible'.

See also IEEE floating point and Floating-Point Arithmetic on the JVM.

The Javadoc comments for `next() is:

/**
 * Generates the next pseudorandom number. Subclasses should
 * override this, as this is used by all other methods.
 *
 * <p>The general contract of {@code next} is that it returns an
 * {@code int} value and if the argument {@code bits} is between
 * {@code 1} and {@code 32} (inclusive), then that many low-order
 * bits of the returned value will be (approximately) independently
 * chosen bit values, each of which is (approximately) equally
 * likely to be {@code 0} or {@code 1}. The method {@code next} is
 * implemented by class {@code Random} by atomically updating the seed to
 *  <pre>{@code (seed * 0x5DEECE66DL + 0xBL) & ((1L << 48) - 1)}</pre>
 * and returning
 *  <pre>{@code (int)(seed >>> (48 - bits))}.</pre>
 *
 * This is a linear congruential pseudorandom number generator, as
 * defined by D. H. Lehmer and described by Donald E. Knuth in
 * <i>The Art of Computer Programming,</i> Volume 3:
 * <i>Seminumerical Algorithms</i>, section 3.2.1.
 *
 * @param  bits random bits
 * @return the next pseudorandom value from this random number
 *         generator's sequence
 * @since  1.1
 */

The Javadoc comments for nextFloat() is:

/**
 * Returns the next pseudorandom, uniformly distributed {@code float}
 * value between {@code 0.0} and {@code 1.0} from this random
 * number generator's sequence.
 *
 * <p>The general contract of {@code nextFloat} is that one
 * {@code float} value, chosen (approximately) uniformly from the
 * range {@code 0.0f} (inclusive) to {@code 1.0f} (exclusive), is
 * pseudorandomly generated and returned. All 2<font
 * size="-1"><sup>24</sup></font> possible {@code float} values
 * of the form <i>m&nbsp;x&nbsp</i>2<font
 * size="-1"><sup>-24</sup></font>, where <i>m</i> is a positive
 * integer less than 2<font size="-1"><sup>24</sup> </font>, are
 * produced with (approximately) equal probability.
 *
 * <p>The method {@code nextFloat} is implemented by class {@code Random}
 * as if by:
 *  <pre> {@code
 * public float nextFloat() {
 *   return next(24) / ((float)(1 << 24));
 * }}</pre>
 *
 * <p>The hedge "approximately" is used in the foregoing description only
 * because the next method is only approximately an unbiased source of
 * independently chosen bits. If it were a perfect source of randomly
 * chosen bits, then the algorithm shown would choose {@code float}
 * values from the stated range with perfect uniformity.<p>
 * [In early versions of Java, the result was incorrectly calculated as:
 *  <pre> {@code
 *   return next(30) / ((float)(1 << 30));}</pre>
 * This might seem to be equivalent, if not better, but in fact it
 * introduced a slight nonuniformity because of the bias in the rounding
 * of floating-point numbers: it was slightly more likely that the
 * low-order bit of the significand would be 0 than that it would be 1.]
 *
 * @return the next pseudorandom, uniformly distributed {@code float}
 *         value between {@code 0.0} and {@code 1.0} from this
 *         random number generator's sequence
 */
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From what I can see from the JavaScript console in Chrome, Math.random() generates a number from 0 up to 0.9999999999999999. Taking this into account, you can get what you want by adding a modifier. For example, here's a function that will give you quasi-random float between 0 and 1, with 1 being inclusive:

function randFloat() {
  // Assume random() returns 0 up to 0.9999999999999999
  return Math.random()*(1+2.5e-16);
}

You can try this in the console by enter 0.9999999999999999*(1+2.5e-16) -- it will return exactly 1. You can take this further and return a float between 0 and 1024 (inclusive) with this function:

function randFloat(nMax) {
  // Assume random() returns 0 up to 0.9999999999999999
  // nMax should be a float in the range 1-1024
  var nMod;
  if (nMax<4) nMod = 2.5e-16;
  else if (nMax<16) nMod = 1e-15;
  else if (nMax<32) nMod = 3.5e-15;
  else if (nMax<128) nMod = 1e-14;
  else if (nMax<512) nMod = 3.5e-14;
  else if (nMax<1024) nMod = 1e-13;
  return Math.random()*(nMax+nMod);
}

There's probably a more efficient algorithm to be had somewhere.

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