# Creating a random number generator from a coin toss

Given a function `f() = 0 or 1` with a perfect 1:1 distribution, create a function `f(n) = 0, 1, 2, ..., n-1` each with probability 1/n

I could come up with a solution for if n is a natural power of 2, ie use `f()` to generate the bits of a binary number of `k=ln_2 n`. But this obviously wouldn't work for, say, n=5 as this would generate `f(5) = 5,6,7` which we do not want.

Does anyone know a solution?

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Here don't you mean given a number `n` which is either 0 or 1, create an f(n) = 0, 1, 2, ..., n - 1? –  Killercam Nov 3 '12 at 12:39

You can build a rng for the smallest power of two greater than `n` as you described. Then whenever this algorithm generates a number larger than `n-1`, throw that number away and try again. This is called the method of rejection.

The algorithm is

``````Let m = 2^k >= n where k is is as small as possible.
do
Let r = random number in 0 .. m-1 generated by k coin flips
while r >= n
return r
``````

The probability that this loop stops with at most `i` iterations is bounded by `1 - (1/2)^i`. This goes to 1 very rapidly: The loop is still running after 30 iterations with probability less than one-billionth.

You can decrease the expected number of iterations with a slightly modified algorithm:

``````Choose p >= 1
Let m = 2^k >= p n where k is is as small as possible.
do
Let r = random number in 0 .. m-1 generated by k coin flips
while r >= p n
return floor(r / p)
``````

For example if we are trying to generate 0 .. 4 (n = 5) with the simpler algorithm, we would reject 5, 6 and 7, which is 3/8 of the results. With `p = 3` (for example), `pn = 15`, we'd have m = 16 and would reject only 15, or 1/16 of the results. The price is needing four coin flips rather than 3 and a division op. You can continue to increase `p` and add coin flips to decrease rejections as far as you wish.

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How is this going to produce the range 0, 1, 2, ..., n - 2, n - 1? –  Killercam Nov 3 '12 at 12:37
by interpreting `k` consecutive tosses as a binary number in the range `0..2^k-1` –  Andre Holzner Nov 3 '12 at 12:52
A useful method, but note that it can in theory take an infinitely long time to run. The probability of needing at least m+1 "rolls" (each of k coin-flips) is (2^k - n)^m/2^k, which goes down quickly with increasing m, but never reaches zero. –  j_random_hacker Nov 3 '12 at 14:08
Now it seems so obvious, but not necessarily when the pressure is on in an interview! Thanks a lot. –  fophillips Nov 3 '12 at 15:27
`````` initialize: x[0] arbitrarily