Your approach vs. the proposed one with sorting seems to be a classical trade-off of which operations is cheap and which one is expensive.

I find your notation a bit confusing, so please allow me to use my own:

Let `S`

be the set. Let `n`

be the number of items in the set: `n = |S|`

. Let `max`

be the biggest number in the set: `max = max(S)`

. Let `k`

be the number of elements not in the set: `k = |{0,...,max} \ S|`

.

For the sorting solution, we could very cheaply insert all `n`

elements into `S`

using hashing. That would take expected `O(n)`

. Then for finding the `k`

missing elements, we sort the set in `O(nlogn)`

, and then determine the missing elements in `O(n)`

.

That is, the overall cost for adding `n`

elements and then finding the missing `k`

elements takes expected `O(n) + O(nlogn) + O(n) = O(nlogn)`

.

You suggest a different approach in which we represent the set as a list of dense subsets of `S`

. How would you implement such a data structure? I suggest a sorted tree (instead of a list) so that an insert becomes efficient. Because what do you have to do for an insert of a new element `e`

? I think you have to:

- Find the potential candidate subset(s) in the tree where
`e`

could be added
- If a subset already contains
`e`

, nothing has to be done.
- If a subset contains
`e+1`

and another subset contains `e-1`

, merge the subsets together and add `e`

to the result
- If a subset already contains
`e+1`

, but `e-1`

is not contained in `S`

, add `e`

to that subset
- If a subset already contains
`e-1`

, but `e+1`

is not contained in `S`

, add `e`

to that subset
- Otherwise, create a new subset holding only the element
`e`

and insert it into the tree.

We can expect that finding the subsets needed for the above operations takes `O(logn)`

. The operations of 4. or 5. take constant time if we represent the subsets as pairs of integers (we just have to decrement the lower or increment the upper boundary). 3. and 6. potentially require changing the tree structure, but we expect that to take at most `O(logn)`

, so the whole "insert" will not take more than `O(logn)`

.

Now with such a datastructure in place, we can easily determine the `k`

missing numbers by traversing the tree in order and collecting the numbers not in any of the subsets. The costs are linear in the number of nodes in the tree, which is `<= n/2`

, so the total costs are `O(n)`

for that.

However, if we consider again the complete sequence operations, we get for `n`

inserts `O(nlogn)`

+ `O(n)`

for finding the k missing numbers, so the overall costs are again `O(nlogn)`

.

This is not better than the expected costs of the first algorithm.

A third solution is to use a boolean `array`

to represent the set and a single integer `max`

for the biggest element in the set.

If an element `e`

is added to the Set, you set `array[e] = true`

. You can implement the variable size of the set using table expansion, so the costs for inserting an element into the array is constant.

To retrieve the missing elements, you just collect those elements `f`

where `array[f] == false`

. This will take `O(max)`

.

The overall costs for inserting n elements and finding the k missing ones is thus: `O(n) + O(max)`

. However, `max = n + k`

, and so we get as the overall costs `O(n + k)`

.

A fourth method which is a cross-over between the third one and the one using hashing is the following one, which also uses hashing, but doesn't require sorting.

Store your set `S`

in a hash set, and also store the maximum element in `S`

in a variable `max`

. To find the `k`

missing ones, first generate a result set R containing all numbers `{0,...,max}`

. Then iterate over `S`

and delete every element in `S`

from `R`

.

The costs for that are also `O(n + k)`

.