# Given two arrays of distinct integers A and B of size m and n, what is the lower-bound complexity for finding one common element? [closed]

I have the following problem:

Given two arrays of distinct integers A and B of size m and n, what is the upper-bound complexity for finding the first common element? I can use at most O(k) memory in addition to the input arrays.

k is a constant (means that i can use only constant memory in addition to the input)

http://cs.stackexchange.com/questions/12182/lower-bound-complexities-for-finding-common-elements-between-two-unsorted-arrays

but didn't solved the problem

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May be a lack of coffee that makes me ask, but `O(k)` where `k` is what? –  Joachim Isaksson Jun 11 '13 at 7:54
Why do you care about the lower-bound Ω()? Such problems are usually expressed in terms of upper bound O(). –  srikanta Jun 11 '13 at 7:57
Lower bound makes no sense for this task. with luck the first test is a hit. i think you want to know the upper bound (worst case) –  AlexWien Jun 11 '13 at 8:15
Please tell me you know the difference between the lower-bound complexity of an algorithm and the complexity of the optimal algorithm on the same problem –  Khaled A Khunaifer Jun 11 '13 at 8:46
I just saw that the question was closed while I was typing my answer. I recommend you update this question to include the information in your original post on CS to get this question reopened. –  beaker Jun 11 '13 at 17:28

## closed as not a real question by Damien_The_Unbeliever, interjay, Daniel Fischer, Andrew Barber♦Jun 11 '13 at 17:16

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

I'm going to have a crack at the second problem in your original post on CS because I'm not sure your summarization of the problem is the best one.

Given two unsorted arrays of distinct integers, A and B, of size m and n; knowing that common elements between the arrays have the same relative order in both arrays and that for every couple of consecutive common elements, their distance is at most k(constant), determine all the common elements between the two arrays maintaining their relative order and using at most O(k) memory in addition to the input arrays.

I'll again use a heap as mentioned in the comments and in your edit on the original question, but this time we need only one heap.

Notice that in order to determine whether element A[i] has a match in array B, we need only check elements B[i-k]..B[i+k]. Construct a heap B' of these elements in O(k) time and 2k+1 = O(k) space using heapify on the subarray of B. Determining whether there exists a match for A[i] in B' takes O(log k). We then iterate through A for i=1..m, updating B' and checking for a match to A[i]. This maintains the relative order in the output. To determine whether there are matches for all m elements in A takes O(km log k), or O(m) time.

Notes:

• Obviously you should iterate through the smaller array, putting the elements of the larger array into the heap. I've assumed throughout that m <= n.
• You should never have to put more than k+1 elements into the heap at a time, which will happen when checking the first element of A. The heap can potentially grow to be up to 2k+1 elements while checking some element A[i], k < i < m-k. Outside of this range, the heap will always be smaller.
• Once i is in the range k < i < m-k, if there is no match on the current index you will only have to add one element and delete one element from the heap to check the next index.
• If there is a match, say at A[i] and B[j], you still have to add at most one element, but you can remove all of the elements from the heap with index less than or equal to j (since we know that elements have the same relative order, so A[i+1] will not match anything before B[j+1]). At some point it may become more efficient to simply rebuild the heap with elements B[j+1]..B[i+k].
• Once our heap has grown to its maximum size of 2k+1, we are always removing at least as many elements as we are adding. Therefore our heap will never be larger than 2k+1.
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thanks so much! –  user2473560 Jun 12 '13 at 11:42