I wanted to point out first that if *k* is really a random number, then it might be worth considering that the problem might be completely different: asking for the k-th smallest element, with k uniformly at random in the range of the available elements is basically... picking an element at random. And it can be done much differently.

Here I'm assuming you actually need to select for some specific, if arbitrary, *k*.

Given your **strong** pre-condition that your elements are inserted in order, there is a simple solution:

- Since your elements are given in order, just add them one by one to an array; that is you have some (infinite) table
*T*, and a cursor *c*, initially *c := 1*, when adding an element, do *T[c] := x* and *c := c+1*.
- When you want to access the k-th smallest element, just look at T[k].

The problem, of course, is that as you *delete* elements, you create gaps in the table, such that element *T[k]* might not be the k-th smallest, but the j-th smallest with *j <= k*, because some cells before k are empty.

It then is enough to keep track of the elements which you have deleted, to know **how many** have been deleted that are smaller than *k*. How do you do this in time at most O(log n)? By using a range tree or a similar type of data structure. A range tree is a structure that lets you **add** integers and then **query** for all integers in between *X* and *Y*. So, whenever you delete an item, simply add it to the range tree; and when you are looking for the k-th smallest element, make a query for all integers between *0* and *k* that have been deleted; say that *delta* have been deleted, then the k-th element would be in T[k+delta].

There are two slight catches, which require some fixing:

The range tree returns the range in time O(log n), but to count the number of elements in the range, you must walk through each element in the range and so this adds a time O(D) where D is the number of deleted items in the range; to get rid of this, you must modify the range tree structure so as to keep track, at each node, of the number of distinct elements in the subtree. Maintaining this count will only cost O(log n) which doesn't impact the overall complexity, and it's a fairly trivial modification to do.

In truth, making just one query will not work. Indeed, if you get delta deleted elements in range 1 to k, then you need to make sure that there are no elements deleted in range k+1 to k+delta, and so on. The full algorithm would be something along the line of what is below.

```
KthSmallest(T,k) := {
a = 1; b = k; delta
do {
delta = deletedInRange(a, b)
a = b + 1
b = b + delta
while( delta > 0 )
return T[b]
}
```

The exact complexity of this operation depends on how exactly you make your deletions, but if your elements are deleted uniformly at random, then the number of iterations should be fairly small.

`k`

pre-defined? – amit May 7 '12 at 7:27`O(logn)`

insert+remove &`O(logk)`

find k - but I am short on time for detailed answer. The idea is to create an AVL tree with 3 modifications: (1) maintain`min`

- a pointer to the min element. (2) maintain the`father`

field for each node. (3) maintain`numberOfSons`

field for each node. Now, when you need the kth element, start from min, and go your way up, while using`numberOfSons`

to know how much elements you have already passed. You will need to go up at most`O(logk)`

nodes, and later go back down`O(logk)`

nodes, which results in`O(logk)`

find kth element – amit May 7 '12 at 8:04