Algorithm for merging sets that share at least 2 elements

Given a list of sets:

• S_1 : [ 1, 2, 3, 4 ]
• S_2 : [ 3, 4, 5, 6, 7 ]
• S_3 : [ 8, 9, 10, 11 ]
• S_4 : [ 1, 8, 12, 13 ]
• S_5 : [ 6, 7, 14, 15, 16, 17 ]

What the most efficient way to merge all sets that share at least 2 elements? I suppose this is similar to a connected components problem. So the result would be:

• [ 1, 2, 3, 4, 5, 6, 7, 14, 15, 16, 17] (S_1 UNION S_2 UNION S_5)
• [ 8, 9, 10, 11 ]
• [ 1, 8, 12, 13 ] (S_4 shares 1 with S_1, and 8 with S_3, but not merged because they only share one element in each)

The naive implementation is O(N^2), where N is the number of sets, which is unworkable for us. This would need to be efficient for millions of sets.

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What range of values can be in the sets? – The Archetypal Paul Nov 23 '08 at 20:35
Are there integers? and can they repeat within a set? – EvilTeach Nov 23 '08 at 20:38
The values in the sets are integers, and they do not repeat within each set – bajafresh4life Nov 23 '08 at 20:47
Just to clarify: In your example, should the first merge also include S_3, since it shares four elements with S_5? – e.James Nov 23 '08 at 20:53
If we have A:[1,2,3], B:[1,2,4] and C:[3,4,5]. Do we first merge A and B to [1,2,3,4] and then merge it with C (because A+B has 2 in common with C while neither A or B has 2 in common with C? – Toon Krijthe Nov 23 '08 at 20:54

Let there be a list of many Sets named (S)

``````Perform a pass through all elements of S, to determine the range (LOW .. HIGH).

Create an array of pointer to Set, of dimensions (LOW, HIGH), named (M).

do
Init all elements of M to NULL.

Iterate though S, processing them one Set at a time, named (Si).

Permutate all ordered pairs in Si. (P1, P2) where P1 <= P2.
For each pair examine M(P1, P2)
if M(P1, P2) is NULL
Continue with the next pair.
otherwise
Merge Si, into the Set pointed to by, M(P1, P2).
Remove Si from S, as it has been merged.
Move on to processing Set S(i + 1)

If Si was not merged,
Permutate again through Si
For each pair, make M(P1, P2) point to Si.

while At least one set was merged during the pass.
``````

My head is saying this is about Order (2N ln N). Take that with a grain of salt.

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this assumes a set has all the elements between low and high in it, which isn't true - or am i mistaken? – Claudiu Nov 24 '08 at 4:26
After you merge Si, you still have to permute through all pairs in Si and add them to M (pointed to M(P1, P2)) before moving on to Set S(i + 1), right? Otherwise, this looks good. – bajafresh4life Nov 24 '08 at 14:26
What is supposed to happen with sets {1, 2, 3}, {2, 3, 4} and {1, 4}? First and second get merged, and the merged set has two duplicates with the third - should the third get merged, or is it only the original content of the sets that counts? I think this answer does the former, and not the latter – The Archetypal Paul Nov 24 '08 at 17:29
Paul: yeah, this is the problem that I was trying to get at with my previous comment. When {2, 3, 4} gets merged with {1, 2, 3}, the permuted pairs from the new merged set need to be added to M. – bajafresh4life Nov 24 '08 at 19:14
@Claudiu. No the set is not required to be contigueous. – EvilTeach Nov 24 '08 at 20:25

If you can order the elements in the set, you can look into using Mergesort on the sets. The only modification needed is to check for duplicates during the merge phase. If one is found, just discard the duplicate. Since mergesort is O(n*log(n)), this will offer imrpoved speed when compared to the naive O(n^2) algorithm.

However, to really be effective, you should maintain a sorted set and keep it sorted, so that you can skip the sort phase and go straight to the merge phase.

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i don't see how this addresses the issue of finding which sets have 2 or more elements in common. this just shows how to find the union of two sets, which i think is the easier part of this problem. – Claudiu Nov 24 '08 at 4:25
I don't think knowing if a set has 2 or more elements in common helps at all. Since you don't know how many duplicates there are, there's no way you can stop checking for them. – Kyle Cronin Nov 24 '08 at 5:20

One side note: It depends on how often this occurs. If most pairs of sets do share at least two elements, it might be most efficient to build the new set at the same time as you are stepping through the comparison, and throw it away if they don't match the condition. If most pairs do not share at least two elements, then deferring the building of the new set until confirmation of the condition might be more efficient.

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I don't see how this can be done in less than O(n^2).

Every set needs to be compared to every other one to see if they contain 2 or more shared elements. That's n*(n-1)/2 comparisons, therefore O(n^2), even if the check for shared elements takes constant time.

In sorting, the naive implementation is O(n^2) but you can take advantage of the transitive nature of ordered comparison (so, for example, you know nothing in the lower partition of quicksort needs to be compared to anything in the upper partition, as it's already been compared to the pivot). This is what result in sorting being O(n * log n).

This doesn't apply here. So unless there's something special about the sets that allows us to skip comparisons based on the results of previous comparisons, it's going to be O(n^2) in general.

Paul.

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If the elements in the set can be ordered, duplicate items will always be adjacent to one another. This allows us to confine our search for them to the adjacent items, an O(1) operation, instead of searching for them every time, an O(n) operation. – Kyle Cronin Nov 24 '08 at 8:46
"the elements in the set can be ordered..." Even if duplicate detection is O(1), there are still O(N^2) comparisons to do. And anyway, we're not looking for duplicate items within a set. We're looking for items duplicated between two sets. and they could be the first or last or any other. – The Archetypal Paul Nov 24 '08 at 17:03
Ordering the elements in the set, does not in any way imply that the duplicate items will be adjecent. A pair is duplicate iff there is an identical pair in another set. – EvilTeach Nov 24 '08 at 20:53
I tend to think you are correct Paul. The multipass thing i did above could have O(N*N) behavior. It really is a fuction of what the distribution of duplicates around the sets are. It may be that Set 1 and 2 merge, then next pass set 3 merges... all the way up to N. Kinda like quicksort. – EvilTeach Nov 24 '08 at 20:56

If your elements are numerical in nature, or can be naturally ordered (ie. you can assign a value such as 1, 2, 42 etc...), I would suggest using a radix sort on the merged sets, and make a second pass to pick up on the unique elements.

This algorithm should be of O(n), and you can optimize the radix sort quite a bit using bitwise shift operators and bit masks. I have done something similar for a project I was working on, and it works like a charm.

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