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)

**EDIT:**

You cannot get better then `O(logN)`

for insertion (unless you decrease the `peekMedian()`

to `Omega(logN)`

), because that will enable you to sort better then `O(NlogN)`

:

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:
peekMedian()
insert(MAX)
insert(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 `Omega(NlogN)`

problem.

=><=

Thus `insert()`

cannot be better then `O(logN)`

, with median still being `O(1)`

.

**QED**

**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.

`maintain sorted array`

is O(n) per insertion/deletion (worst case) – amit Jan 16 '13 at 16:38