This problem can be solved easily and efficiently using a **binary search** (which runs in O(log n), faster than a linear search, which is O(n)). The basic idea is that if and only if all the numbers are present up to a certain index, then list[index] = index + 1 (e.g. list[0] = 1, list[1] = 2, etc). This property can be used to determine whether the smallest missing number is before or after a certain element of the list, allowing for a binary search.

The implementation is simple (I don't know php, so here's pseudocode)

```
lower_bound = 0
upper_bound = length(list) - 1
index = floor((lower_bound + upper_bound) / 2)
while (lower_bound != upper_bound)
if(list[index] = index + 1) // missing number is after index
lower_bound = index + 1
index = floor((lower_bound + upper_bound) / 2)
else // missing number is at or before index
upper_bound = index
index = floor((lower_bound + upper_bound) / 2)
missing_number = upper_bound + 1 // add 1 because upper_bound is the index
```

And `missing_number`

will be the smallest missing number, or if there are no missing numbers it will be `length(list) + 1`

.

Or using recursion, which I hear is less efficient

```
first_missing_number(list, lower_bound, upper_bound) {
if(lower_bound = upper_bound) // found the first missing number
return upper_bound + 1 // add 1 because upper_bound is the index
index = floor((lower_bound + upper_bound) / 2)
if (list[index] = index + 1) // missing number is after index
first_missing_number(list, index + 1, upper_bound)
else // missing number is at or before index
first_missing_number(list, lower_bound, index)
}
```

In which case `first_missing_number(list, 0, length(list) - 1)`

will return the first number missing from the list. If there are no numbers missing, it returns `length(list) + 1`

.

I hope this helps!

upd: php version

```
function first_free($list) {
$lwr = 0;
$upr = count($list);
while ($lwr < $upr) {
$m = ($lwr + $upr) >> 1;
if($list[$m] == $m + 1)
$lwr = $m + 1;
else
$upr = $m;
}
return $upr + 1;
}
```