Well, you are close - but there is still something missing, since inserting/deleting from a sorted array is
O(n) (because at probability 1/2 the inserted element is at the first half of the array, and you will have to shift to the right all the following elements, and there are at least n/2 of these, so total complexity of this operation is
O(n) on average + worst case)
However, if you switch your sorted DS to a skip list/ balanced BST - you are going to get
O(logn) insertion/deletion and
O(1) minimum/maximum/median/size (with caching)
You cannot get better then
O(logN) for insertion (unless you decrease the
Omega(logN)), because that will enable you to sort better then
First, note that the median moves one element to the right for each "high" elements you insert (in here, high means >= the current max).
So, by iteratively doing:
while peekMedian() != MAX:
you can find the "higher" half of the sorted array.
Using the same approach with
insert(MIN) you can get the lowest half of the array.
Assuming you have
o(logN) (small o notation, better then
Theta(logN) insertion and O(1)
peekMedian(), you got yourself a sort better then
O(NlogN), but sorting is
insert() cannot be better then
O(logN), with median still being
EDIT2: Modifying the median in insertions:
If the tree size before insertion is 2n+1 (odd) then the old median is at index n+1, and the new median is at the same index (n+1), so if the element was added before the old median - you need to get the preceding node of the last median - and that's the new median. If it was added after it - do nothing, the old median is the new one as well.
If the list is even (2n elements), then after the insertion, you should increase an index (from n to n+1), so if the new element was added before the median - do nothing, if it was added after the old median, you need to set the new median as the following node from the old median.
note: In here next nodes and preceding nodes are those that follow according to the key, and index means the "place" of the node (smallest is 1st and biggest is last).
I only explained how to do it for insertion, the same ideas hold for deletion.