Binary search.

## The basic algorithm:

(not quite the same as the other answer - the number is only generated at the end)

Start in the middle of `K`

.

By looking at the current value and it's index, we can determine the number of pickable numbers (numbers not in `K`

) to the left.

Similarly, by including `N`

, we can determine the number of pickable numbers to the right.

Now randomly go either left or right, weighted based on the count of pickable numbers on each side.

Repeat in the chosen subarray until the subarray is empty.

Then generate a random number in the range consisting of the numbers before and after the subarray in the array.

The running time would be `O(log |K|)`

, and, since `|K| < N-1`

, `O(log N)`

.

The exact mathematics for number counts and weights can be derived from the example below.

## Extension with K containing a bigger range:

Now let's say (for enrichment purposes) `K`

can also contain values `N`

or larger.

Then, instead of starting with the entire `K`

, we start with a subarray up to position `min(N, |K|)`

, and start in the middle of that.

It's easy to see that the `N`

-th position in `K`

(if one exists) will be `>= N`

, so this chosen range includes any possible number we can generate.

From here, we need to do a binary search for `N`

(which would give us a point where all values to the left are `< N`

, even if `N`

could not be found) (the above algorithm doesn't deal with `K`

containing values greater than `N`

).

Then we just run the algorithm as above with the subarray ending at the last value `< N`

.

The running time would be `O(log N)`

, or, more specifically, `O(log min(N, |K|))`

.

## Example:

```
N = 10
K = {0, 1, 4, 5, 8}
```

So we start in the middle - `4`

.

Given that we're at index 2, we know there are 2 elements to the left, and the value is 4, so there are `4 - 2 = 2`

pickable values to the left.

Similarly, there are `10 - (4+1) - 2 = 3`

pickable values to the right.

So now we go left with probability `2/(2+3)`

and right with probability `3/(2+3)`

.

Let's say we went right, and our next middle value is `5`

.

We are at the first position in this subarray, and the previous value is `4`

, so we have `5 - (4+1) = 0`

pickable values to the left.

And there are `10 - (5+1) - 1 = 3`

pickable values to the right.

We can't go left (0 probability). If we go right, our next middle value would be `8`

.

There would be `2`

pickable values to the left, and `1`

to the right.

If we go left, we'd have an empty subarray.

So then we'd generate a number between `5`

and `8`

, which would be `6`

or `7`

with equal probability.

`O(N)`

complexity. If the algorithm doesn't use all its input, it is incorrect, so complexity less than`O(N)`

is impossible. However, maybe you need to improve amortized complexity (run the algorithm N times, or some other number of times)? – anatolyg Jun 4 '14 at 18:496more comments