Yes, these queries can be answered in polylog time if `O(n log n)`

space is available.

Preprocess given array by constructing segment tree with depth `log(n)`

. So that leaf nodes are identical to source array, next-depth nodes contain sorted 2-element sub-arrays, next level consists of 4-element arrays produced by merging those 2-element arrays, etc. In other words, perform merge sort but keep results of each merge step in separate array. Here is an example:

```
root: | 1 2 3 5 5 7 8 9 |
| 1 2 5 8 | 3 5 7 9 |
| 1 5 | 2 8 | 7 9 | 3 5 |
source: | 5 | 1 | 2 | 8 | 7 | 9 | 5 | 3 |
```

To answer a query, split given range (into at most 2*log(n) subranges). For example, range `[0, 4]`

should be split into `[0, 3]`

and `[4]`

, which gives two sorted arrays `[1 2 5 8]`

and `[7]`

. Now the problem is simplified to finding k-th element in several sorted arrays. The easiest way to solve it is nested binary search: first use binary search to choose some candidate element from every array starting from largest one; then use binary search in other (smaller) arrays to determine rank of this candidate element. This allows to get k-th element in `O(log(n)^4)`

time. Probably some optimization (like fractional cascading) or some other algorithm could do this faster...

ka constant across queries?