A very minor correction to hielsnoppe's answer:

In an `n`

-element array (`n > 0`

), the element to compare is at index `m = floor((n-1)/2)`

. So there are three possibilities

`A[m] < K`

, then after one comparison, the search continues in an `n-1-m = ceiling((n-1)/2)`

-element array.
`A[m] > K`

, then after two comparisons, the search continues in an `m`

-element array.
`A[m] == K`

, then we're done after two comparisons.

So if we denote the maximal (worst-case) number of comparisons for a search in an `n`

-element array by `C(n)`

, we have

```
C(0) = 0
C(n) = max { 1 + C(ceiling((n-1)/2), 2 + C(floor((n-1)/2) }, n > 0
```

For odd `n = 2k+1`

, the floor and ceiling are identical, so the maximum is evidently the latter,

```
C(2k+1) = 2 + C(k)
```

and for even `n = 2k`

, we find

```
C(2k) = max { 1 + C(k), 2 + C(k-1) }.
```

For `n = 2`

, that resolves to `C(2) = 1 + C(1) = 1 + 2 = 3`

, for all larger even `n`

, the maximum is `2 + C(k-1)`

, since for `n >= 1`

we have `C(n) <= C(n+1) <= C(n) + 1`

.

Evaluating the recursion for the first few `n`

, we find

```
C(0) = 0
C(1) = 2
C(2) = 3
C(3) = C(4) = 4
C(5) = C(6) = 5
C(7) = C(8) = C(9) = C(10) = 6
C(11) = ... = C(14) = 7
C(15) = ... = C(22) = 8
C(23) = ... = C(30) = 9
```

So by induction we prove

```
C(n) = 2k, if 2^k <= n+1 < 2k + 2^(k-1), and
C(n) = 2k+1, if 2^k + 2^(k-1) <= n+1 < 2^(k+1)
```

or

```
C(n) = 2*log2(n+1) + floor(2*(n+1)/(3*2^floor(log2(n+1)))).
```

This is an exact upper bound.

`if K > A[m] then return l ← m+1`

should be`if K > A[m] then l ← m+1`

without the`return`

. – Gumbo May 13 '12 at 11:29