Data Structure to find median

This is an interview question. Design a class, which stores integers and provides two operations:

```void insert(int k)
int getMedian()
```

I guess I can use BST so that `insert` takes O(logN) and `getMedian` takes O(logN) (for `getMedian` I should add the number of of left/right children for each node).

Now I wonder if this is the most efficient solution and there is no better one.

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With your scheme you can improve `getMedian` to `O(1)`: just look it up after every insert (which does no harm to the complexity) and store the value. –  Steve Jessop Jul 6 '12 at 11:59
For an alternative structure, think about priority queueS. –  Steve Jessop Jul 6 '12 at 12:00
@SteveJessop Could you please elaborate on how to improve `getMedian` to O(1)? –  Michael Jul 6 '12 at 12:41
I mean that your data structure would have a data member `int currentMedian;`. Immediately after you insert an element into your BST, find the new median, and store that value into `currentMedian` before returning from `insert`. Then you can implement `int getMedian() { return currentMedian; }`, which is `O(1)`. –  Steve Jessop Jul 6 '12 at 12:48
On further reflection, you can probably do something with a skip list too. That inserts in expected/amortized `O(log(n))`, and you can track the median node (and whether the number of elements is odd or even). Then each time you insert you just need to check whether to move the median one step to the left or right, according to whether you inserted on the left or right of the old median and whether the new size is odd or even. –  Steve Jessop Jul 6 '12 at 12:55

You can use 2 heaps, that we will call `Left` and `Right`.
`Left` is a `Max-Heap`.
`Right` is a `Min-Heap`.
Insertion is done like this:

• If the new element `x` is smaller than the root of `Left` then we insert `x` to `Left`.
• Else we insert `x` to `Right`.
• If after insertion `Left` has count of elements that is greater than 1 from the count of elements of `Right`, then we call Extract-Max on `Left` and insert it to `Right`.
• Else if after insertion `Right` has count of elements that is greater than the count of elements of `Left`, then we call Extract-Min on `Right` and insert it to `Left`.

The median is always the root of `Left`.

So insertion is done in `O(lg n)` time and getting the median is done in `O(1)` time.

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You could consider a self-balancing tree, too. If the tree is fully balanced, then the root node is your median. Say, the tree is one-level deeper on one end. Then, you just need to know how many nodes are there in the deeper-side to pick the correct median.

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Suppose your maximally-balanced tree has an even number of nodes, then the median is the mean of two values. One of those values is the root node, and the other one is buried `(log n)` levels deep in the tree, since it's either the leftmost node of the right subtree or else the rightmost node of the left subtree. So you do need to track slightly more than just the root node and subtree sizes in order to access the median in `O(1)`, but the root alone is sufficient for `O(log n)`. –  Steve Jessop Jul 6 '12 at 16:24

See this Stack Overflow question for a solution that involves two heaps.

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For large data this would suffer from the fact that `insert` is `O(n)`, but if the number of values stored is small this is probably the best way. –  Steve Jessop Jul 6 '12 at 12:50