So we have `randomBit()`

returning 0 or 1 independently, uniformly at random and we want a function `random(a, b)`

that returns a value in the range `[a,b]`

uniformly at random. Let's actually make that the range `[a, b)`

because half-open ranges are easier to work with and equivalent. In fact, it is easy to see that we can just consider the case where `a == 0`

(and `b > 0`

), i.e. we just want to generate a random integer in the range `[0, b)`

.

Let's start with the simple answer suggested elsewhere. (Forgive me for using c++ syntax, the concept is the same in Java)

```
int random2n(int n) {
int ret = n ? randomBit() + (random2n(n - 1) << 1) : 0;
}
int random(int b) {
int n = ceil(log2(b)), v;
while ((v = random2n(n)) >= b);
return v;
}
```

That is-- it is easy to generate a value in the range `[0, 2^n)`

given `randomBit()`

. So to get a value in `[0, b)`

, we repeatedly generate something in the range `[0, 2^ceil(log2(b))]`

until we get something in the correct range. It is rather trivial to show that this selects from the range `[0, b)`

uniformly at random.

As stated before, the worst case expected number of calls to `randomBit()`

for this is `(1 + 1/2 + 1/4 + ...) ceil(log2(b)) = 2 ceil(log2(b))`

. Most of those calls are a waste, we really only need `log2(n)`

bits of entropy and so we should try to get as close to that as possible. Even a clever implementation of this that calculates the high bits early and bails out as soon as it exits the wanted range has the same expected number of calls to `randomBit()`

in the worst case.

We can devise a more efficient (in terms of calls to `randomBit()`

) method quite easily. Let's say we want to generate a number in the range `[0, b)`

. With a single call to `randomBit()`

, we should be able to approximately cut our target range in half. In fact, if `b`

is even, we can do that. If `b`

is odd, we will have a (very) small chance that we have to "re-roll". Consider the function:

```
int random(int b) {
if (b < 2) return 0;
int mid = (b + 1) / 2, ret = b;
while (ret == b) {
ret = (randomBit() ? mid : 0) + random(mid);
}
return ret;
}
```

This function essentially uses each random bit to select between two halves of the wanted range and then recursively generates a value in that half. While the function is fairly simple, the analysis of it is a bit more complex. By induction one can prove that this generates a value in the range `[0, b)`

uniformly at random. Also, it can be shown that, in the worst case, this is expected to require `ceil(log2(b)) + 2`

calls to `randomBit()`

. When `randomBit()`

is slow, as may be the case for a true random generator, this is expected to waste only a constant number of calls rather than a linear amount as in the first solution.