Time complexity for merging two sorted arrays of size n and m

I was just wondering what is the time complexty of merging two sorted arrays of size n and m, given that n is always greater than m.

I was thinking of using merge sort, which I assume in this case will consume O(log n+m).

I am not really good with big-oh and stuff. Please suggest me the time complexity for this problem and let me know if there is an even optimized way of solving the problem.

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Should be summer time now, but homework? –  Windle Jun 14 '12 at 18:59

The complexity is O(m log n).

Let the long array be called `a` and the short array be `b` then the algorithm you described can be written as

``````  for each x in b
insert x into a
``````

There are m iterations of the loop. Each insertion into a sorted array is an O(log n) operation. Therefore the overall complexity is O (m log n).

Since `b` is sorted the above algorithm can be made more efficient

``````  for q from 1 to m
if q == 1 then insert b[q] into a
else
insert b[q] into a starting from the position of b[q-1]
``````

Can this give better asymptotic complexity? Not really.

Suppose elements from `b` are evenly spread along `a`. Then each insertion will take `O(log (n/m))` and the overall complexity will be `O(m log(n/m) )`. If there exists a constant `k>1` that does not depend on `n` or `m` such that `n > k * m` then `O(log(n/m)) = O(log(n))` and we get the same asymptotic complexity as above.

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The operation can be done in O(m+n) = O(n) since m<n. Use the arrays like queues by keeping a pointer to the next element to be used in each array, compare both values before inserting them in the new array. There are exactly n+m comparisons, runtime is O(n). Depending on how different m and n are (for example, if m is in Theta(n)), your solution may be logarithmically slower than that. It may also be exponentially faster if for example m is in O(1). –  G. Bach Feb 1 '13 at 22:15
Btw sorry for the downvote - I originally thought your answer simply was inefficient, but have come to understand it isn't. SO won't let me upvote again though unless the answer is edited; maybe you could do that? –  G. Bach Feb 1 '13 at 22:55
"Therefore the overall complexity is O (m log n)." Insertion into an array of n elements is itself an O(n) operation because every element has to be shifted to right. So would O(m * log n) in quoted sentence above actually be O (mn log n)? –  bytefire Nov 12 '13 at 11:51

The time to merge two sorted lists is definitely not O(m log n). It is O(n+m).

The code looks something like this:

``````allocate c with length n+m
i = 1
j = 1
while i < n or j < m
if i = n
copy rest of b into c
break
if j = m
copy rest of a into c
break
if a[i] < b[j]
copy a[i] into c
i=i+1
continue
if b[j] < a[i]
copy b[j] into c
j=j+1
continue
``````

Now if we don't have enough memory to allocate c this can be modified to still be O(n+m) time as most hardware (both RAM and hard disks for instance) allow for block operations. when we need to insert a single item into the middle of the array it is a single operation to move the tail end of the block over one to make room. If you were on hardware that didn't allow this then you'd perhaps have O(n) for each insert, which would then be O(n+mn) complexity. Since we only need to insert elements of the smaller array into the larger we never need to shift pieces of the larger array when the element from that one is already in the right place. Hence, the n stays the same and the complexity of the m-bit is increased. This is worst case shown when all of array b with length m is properly placed in front of array a of length n.

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Depending on whether m is in Theta(n) or not makes O(n+m) slower than O(m log n). I didn't check your algorithm, but it definitely can be done in O(n), see my comment on the answer by Dmitri. –  G. Bach Feb 1 '13 at 22:23
Shouldn't we consider the case: a[i] = b[j]? –  DDC Jan 13 at 14:09