I would use a self-balancing binary tree as a set representation (e.g., the C++ standard `std::set<int>`

container).

The set would consist of all "unallocated" numbers up to and including one greater than the largest allocated number.

Initialize the set to contain `0`

(or `1`

, whatever your preference is).

To allocate a new number, grab the smallest element in the set and remove it. Call that number `n`

. If the set is now empty, put `n+1`

into the set.

To de-allocate a number, add it to the set. Then perform the following cleanup algorithm:

Step 1: If the set has one element, stop.

Step 2: If the largest element in the set minus the second-largest element is greater than 1, stop.

Step 3: Remove the largest element.

Step 4: Goto step 2.

With this data structure and algorithm, any sequence of `k`

allocate/deallocate operations requires O(k log k) time. (Even though the "cleanup" operation is O(k log k) time all by itself, you can only remove an element after you have inserted it, so the total time does not exceed O(k log k).)

Put another way, each allocate/deallocate takes logarithmic amortized time.