# Merging sorted arrays, what is the optimum time complexity?

I have m arrays, every array is of length n. Each array is sorted. I want to create a single array of length m*n, containing all the values of the previous arrays (including repeating values), sorted. I have to merge these arrays..

I think the optimum time complexity is m*n*log(m)

Here's the sketch of the algorithm..

I create a support array H of lenth m, containing all the values of the first element of each array.

I then sort this array (m log m), and move the min value to the output array.

I then replace the moved value with the next one, from the array it was taken. Actually I don't replace it, but I insert it in the right (sorted) position. This take log m I think.

And I repeat this for all m*n values... therefore m*n*log m

My question.. can you think of a more efficient algorithm? If mnlogm is actually optimum, can you at least think of a simpler, more elegant algorith?

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How would inserting an element in a sorted array take logarithmic time? – codaddict Feb 25 '11 at 10:33

The complexity is right! However, there's a small flaw in your algorithm idea: You cannot insert an item in a sorted array in `log m`. You can find its position using binary search in that complexity, but you might have to move elements around to actually place it there. To fix this problem, you can use a heap data-structure instead!

Multi-way merge (which is the common name of your algorithm) is usually implemented with yet another 'merging' data-structure: the tournament-tree. You can find a description in Knuth's "The Art of Computer Programming" (Chapter on Sorting, iirc). It has a lower constant factor in theory and in practice when compared to heaps in this specific case.

If you want to look implementations, I'm pretty sure that the parallel multi-way merge in the GNU C++ Standard library parallel-extensions is implemented this way.

Edit: I referenced the wrong book, which is fixed now.

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Do they "Multi-way merge with min heap" and "Multi-way merge with tournament-tree" both have the same time complexity? (Here, O(m n logm)) If not, which one is more efficient? Thanks – Hengameh Jun 3 '15 at 10:20
Yes, they have the same asymptotic time complexity, if that's what you're asking! – ltjax Jun 7 '15 at 14:09

Best you can do is O(m*n + d). Similar to counting sort: http://en.wikipedia.org/wiki/Counting_sort If you know the range of values possible (d, say) you can initialize an array of length d, and then scan through each of the m arrays adding 1 to each 'bin' in d for each value corresponding to that bin. Then in your new array of length m*n for each value in d you add however many counts that bin has.

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As you wrote, this only works if you know 'd' and if there's an easy mapping from your value-space to integers. Also, the memory complexity is a linear in 'd', which can be bad if you have a large value-range. So this is not necessarily better. – ltjax Feb 25 '11 at 10:50
Yeah, depends on his data set I suppose – Chimoo Feb 25 '11 at 10:53
I do this in ConcurrentLinkedHashMap prior to applying the pending LRU operations so that they are performed in strict order. I chain on a conflict, e.g. closed-addressing. I think that this approach is called a bounded-height priority queue. – Ben Manes Feb 26 '11 at 7:49