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background about the question

I am reading a algorithm book. There is a chapter, which is regarding Randoms. after the chapter, there is an exercise section. but the book has no answers to those exercises. The question is one exercise question. But it is not homework from school.


There is known RANDOM(0,1) function, it is a uniformed random function, which means, it will give 0 or 1, with probability 50%. Now design an algorithm, only using this known RANDOM(0,1), to generate random number in range a,b(inclusive).

what I though so far is, put the range a-b in a 0 based array, then I have index 0, 1, 2...b-a.

then call the RANDOM(0,1) b-a times, sum the results as generated idx. and return the element.

however since there is no answer in the book, I don't know if this way is correct or the best. How to prove that the probability of returning each element is exactly same and is 1/(b-a+1) ?

And what is the right/better way to do this? (if there was.)

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Possible duplicate: How to get random numbers with the wrong generator –  PengOne Dec 10 '11 at 22:00
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4 Answers

up vote 6 down vote accepted

If your RANDOM(0, 1) returns either 0 or 1, each with probability 0.5 then you can generate bits until you have enough to represent the number (b-a+1) in binary. This gives you a random number in a slightly too large range: you can test and repeat if it fails. Something like this (in Python).

def rand_pow2(bit_count):
    """Return a random number with the given number of bits."""
    result = 0
    for i in xrange(bit_count):
        result = 2 * result + RANDOM(0, 1)
    return result

def random_range(a, b):
    """Return a random integer in the closed interval [a, b]."""
    bit_count = math.ceil(math.log2(b - a + 1))
    while True:
        r = rand_pow2(bit_count)
        if a + r <= b:
            return a + r
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This solution produces a uniform distribution by producing a uniform distribution over 0..(2^N-1) then discarding the result if it's out of the required range to construct a uniform distribution over a non-power of 2. Your solution constructs a binomial distribution. –  user97370 Dec 10 '11 at 22:00
i got it, your way is correct. but the result line would be result += RANDOM(0,1) * 2 ** i right? –  Kent Dec 10 '11 at 22:12
Yes, you can construct it either way, or even result += RANDOM(0, 1) << i. –  user97370 Dec 10 '11 at 22:15
thanx. accepted & +1 –  Kent Dec 10 '11 at 22:18
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When you sum random numbers, the result is not longer evenly distributed - it looks like a Gaussian function. Look up "law of large numbers" or read any probability book / article. Just like flipping coins 100 times is highly highly unlikely to give 100 heads. It's likely to give close to 50 heads and 50 tails.

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thanks for the information, I will search some related articles to read. –  Kent Dec 10 '11 at 20:39
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Your inclination to put the range from 0 to a-b first is correct. However, you cannot do it as you stated. This question asks exactly how to do that, and the answer utilizes unique factorization. Write m=a-b in base 2, keeping track of the largest needed exponent, say e. Then, find the biggest multiple of m that is smaller than 2^e, call it k. Finally, generate e numbers with RANDOM(0,1), take them as the base 2 expansion of some number x, if x < k*m, return x, otherwise try again. The program looks something like this (simple case when m<2^2):

int RANDOM(0,m) {

    // find largest power of n needed to write m in base 2
    int e=0;
    while (m > 2^e) {

    // find largest multiple of m less than 2^e
    int k=1;
    while (k*m < 2^2) {
    --k; // we went one too far

    while (1) {
        // generate a random number in base 2
        int x = 0;
        for (int i=0; i<e; ++i) {
            x = x*2 + RANDOM(0,1); 
        // if x isn't too large, return it x modulo m
        if (x < m*k) 
            return (x % m);

Now you can simply add a to the result to get uniformly distributed numbers between a and b.

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Divide and conquer could help us in generating a random number in range [a,b] using random(0,1). The idea is

  1. if a is equal to b, then random number is a
  2. Find mid of the range [a,b]
  3. Generate random(0,1)
  4. If above is 0, return a random number in range [a,mid] using recursion
  5. else return a random number in range [mid+1, b] using recursion

The working 'C' code is as follows.

int random(int a, int b)
    if(a == b)
        return a;

    int c = RANDOM(0,1); // Returns 0 or 1 with probability 0.5
    int mid = a + (b-a)/2;

    if(c == 0)
       return random(a, mid);
       return random(mid + 1, b);
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This will only result in a uniform distribution if all subranges are equal in size, which only happens if the range is a power of 2. It's mathematically equivalent to generating the bits, and you only get uniformity if you reject the bit-sets that are outside the range for ranges that aren't powers of 2. –  pjs 8 hours ago
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