I am thinking about different solutions for one problem. Assume we have K sorted linked lists and we are merging them into one. All these lists together have N elements.

The well known solution is to use priority queue and pop / push first elements from every lists and I can understand why it takes `O(N log K)`

time.

But let's take a look at another approach. Suppose we have some `MERGE_LISTS(LIST1, LIST2)`

procedure, that merges two sorted lists and it would take `O(T1 + T2)`

time, where `T1`

and `T2`

stand for `LIST1`

and `LIST2`

sizes.

What we do now generally means pairing these lists and merging them pair-by-pair (if the number is odd, last list, for example, could be ignored at first steps). This generally means we have to make the following "tree" of merge operations:

`N1, N2, N3...`

stand for `LIST1, LIST2, LIST3`

sizes

`O(N1 + N2) + O(N3 + N4) + O(N5 + N6) + ...`

`O(N1 + N2 + N3 + N4) + O(N5 + N6 + N7 + N8) + ...`

`O(N1 + N2 + N3 + N4 + .... + NK)`

*It looks obvious that there will be log(K) of these rows, each of them implementing O(N) operations, so time for MERGE(LIST1, LIST2, ... , LISTK) operation would actually equal O(N log K).*

**My friend told me (two days ago) it would take O(K N) time. So, the question is - did I f%ck up somewhere or is he actually wrong about this? And if I am right, why doesn't this 'divide&conquer' approach can't be used instead of priority queue approach?**

`N`

in this problem defines the total number of elements in ALL lists, not the average number of elements for one of the lists. – Costantino Rupert Apr 24 '10 at 17:14K elements that would be touched upon no matter what strategy you use. So, complexity can not be brought down from O(NK). – user3401643 Jan 17 '15 at 9:49