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# Partition a list of sets by shared elements

Here's the jist of the problem: Given a list of sets, such as:

``````[ (1,2,3), (5,2,6), (7,8,9), (6,12,13), (21,8,34), (19,20) ]
``````

Return a list of groups of the sets, such that sets that have a shared element are in the same group.

``````[ [ (1,2,3), (5,2,6), (6,12,13) ], [ (7,8,9), (21,8,34) ], [ (19,20) ] ]
``````

Note the stickeyness - the set (6,12,13) doesn't have a shared element with (1,2,3), but they get put in the same group because of (5,2,6).

To complicate matters, I should mention that I don't really have these neat sets, but rather a DB table with several million rows that looks like:

``````element | set_id
----------------
1       | 1
2       | 1
3       | 1
5       | 2
2       | 2
6       | 2
``````

and so on. So I would love a way to do it in SQL, but I would be happy with a general direction for the solution.

EDIT: Changed the table column names to (element, set_id) instead of (key, group_id), to make the terms more consistent. Note that Kev's answer uses the old column names.

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The problem is exactly the computation of the connected components of an hypergraph: the integers are the vertices, and the sets are the hyperedges. A usual way of computing the connected components is by flooding them one after the other:

• for all i = 1 to N, do:
• if i has been tagged by some j < i, then continue (I mean skip to the next i)
• else flood_from(i,i)

where flood_from(i,j) would be defined as

• for each set S containing i, if it is not already tagged by j then:
• tag S by j and for each element k of S, if k is not already tagged by j, then tag it by j, and call flood_from(k,j)

The tags of the sets then give you the connected components you are looking for.

In terms of databases, the algorithm can be expressed as follows: you add a TAG column to your database, and you compute the connected component of set i by doing

• S = select all rows where set_id == i
• set TAG to i for the rows in S
• S' = select all rows where TAG is not set and where element is in element(S)
• while S' is not empty, do
• ---- set TAG to i for the rows in S'
• ---- S'' = select all rows where TAG is not set and where element is in element(S')
• ---- S = S union S'
• ---- S' = S''
• return set_id(S)

Another (theoretical) way of presenting this algorithm would be to say that you are looking for the fixed points of a mapping:

• if A = {A1, ..., An} is a set of sets, define union(A) = A1 union ... union An
• if K = {k1, ..., kp} is a set of integers, define incidences(K) = the set of sets which intersect K

Then if S is a set, the connected component of S is obtained by iterating (incidences)o(union) on S until a fixed point is reached:

1. K = S
2. K' = incidences(union(K)).
3. if K == K', then return K, else K = K' and go to 2.
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Kudos for the effort! Can you take a look at my answer and tell me if it's wrong, basically the same as your solution, or just a different solution? – itsadok Oct 8 '08 at 8:48
It seems to me that you would need some merging step for your solution to be complete: you may start different goup_ids for sets that should be in the same group, because you have not discovered that yet. If you have a duplicate and both sets are in different groups, merge the two groups. – Camille Oct 8 '08 at 9:05

You could think of it as a graph problem where the set (1,2,3) is connected to the set (5,2,6) via the 2. And then use a standard algorithm to fine the connected sub-graphs.

Here's a quick python implementation:

``````nodes = [ [1,2,3], [2,4,5], [6,7,8], [10,11,12], [7,10,13], [12], [] ]
links = [ set() for x in nodes ]

for n in range(len(nodes)):
for item in nodes[n]:
for m in range(n+1, len(nodes)):
if (item in nodes[m]):

sets = []
nodes_not_in_a_set = range(len(nodes))

while len(nodes_not_in_a_set) > 0:
nodes_to_explore = [nodes_not_in_a_set.pop()]
current_set = set()
while len(nodes_to_explore) > 0:
current_node = nodes_to_explore.pop()
if current_node in nodes_not_in_a_set:
nodes_not_in_a_set.remove(current_node)
if l not in current_set and l not in nodes_to_explore:
nodes_to_explore.append(l)
if len(current_set) > 0:
sets.append(current_set)

for s in sets:
print [nodes[n] for n in s]
``````

output:

``````[[]]
[[6, 7, 8], [10, 11, 12], [7, 10, 13], [12]]
[[1, 2, 3], [2, 4, 5]]
``````
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Could you elaborate a little? – itsadok Oct 7 '08 at 15:37
This is tough to do without lft,rgt strategy (unless you want loops galore for the tree traversal) – Pittsburgh DBA Oct 7 '08 at 18:21

This is likely pretty inefficient, but it should work, at least: Start with a key, select all the groups containing that key, select all the keys of those groups, select all the groups containing those keys, etc., and as soon as a step adds no new keys or groups, you have a list of all the groups of one sub-graph. Exclude those and repeat from the beginning until you have no data left.

In terms of SQL this would need a stored procedure, I think. WITH RECURSIVE might help you somehow, but I don't have any experience with it yet, and I'm not sure it's available on your DB backend.

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1. Create a table called `groups` with columns `(group_id, set_id)`
2. Sort the `sets` table by `element`. Now it should be easy to find duplicate elements.
3. Iterate through the sets table, and when you find a duplicate element do:
1. if one of the `set_id` fields exists in the `groups` table, add the other one with the same `group_id`.
2. If neither `set_id` exists in the `groups` table, generate a new group ID, and add both `set_id`s to the `groups` table.

In the end I should have a `groups` table containing all the sets.

This is not pure SQL, but seems like O(nlogn), so I guess I can live with that.

Matt's answer seems more correct, but I'm not sure how to implement it in my case.

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