# A fast way to find connected component in a 1-NN graph?

First of all, I got a N*N distance matrix, for each point, I calculated its nearest neighbor, so we had a N*2 matrix, It seems like this:

``````0 -> 1
1 -> 2
2 -> 3
3 -> 2
4 -> 2
5 -> 6
6 -> 7
7 -> 6
8 -> 6
9 -> 8
``````

the second column was the nearest neighbor's index. So this was a special kind of directed graph, with each vertex had and only had one out-degree.

Of course, we could first transform the N*2 matrix to a standard graph representation, and perform BFS/DFS to get the connected components.

But, given the characteristic of this special graph, is there any other fast way to do the job ?

I will be really appreciated.

Update:

I've implemented a simple algorithm for this case here.

Look, I did not use a union-find algorithm, because the data structure may make things not that easy, and I doubt whether It's the fastest way in my case(I meant practically).

You could argue that the _merge process could be time consuming, but if we swap the edges into the continuous place while assigning new label, the merging may cost little, but it need another N spaces to trace the original indices.

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The fastest algorithm for finding connected components given an edge list is the union-find algorithm: for each node, hold the pointer to a node in the same set, with all edges converging to the same node, if you find a path of length at least 2, reconnect the bottom node upwards.

This will definitely run in linear time:

``````- push all edges into a union-find structure: O(n)
- store each node in its set (the union-find root)
and update the set of non-empty sets: O(n)
- return the set of non-empty sets (graph components).
``````

Since the list of edges already almost forms a union-find tree, it is possible to skip the first step:

``````for each node
- if the node is not marked as collected
-- walk along the edges until you find an order-1 or order-2 loop,
collecting nodes en-route
-- reconnect all nodes to the end of the path and consider it a root for the set.
-- store all nodes in the set for the root.
-- update the set of non-empty sets.
-- mark all nodes as collected.
return the set of non-empty sets
``````

The second algorithm is linear as well, but only a benchmark will tell if it's actually faster. The strength of the union-find algorithm is its optimization. This delays the optimization to the second step but removes the first step completely.

You can probably squeeze out a little more performance if you join the union step with the nearest neighbor calculation, then collect the sets in the second pass.

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thanks very much. – blackball Nov 2 '12 at 14:07

Since each node has only one outgoing edge, you can just traverse the graph one edge at a time until you get to a vertex you've already visited. An out-degree of 1 means any further traversal at this point will only take you where you've already been. The traversed vertices in that path are all in the same component.

``````0->1->2->3->2, so [0,1,2,3] is a component
4->2, so update the component to [0,1,2,3,4]
5->6->7->6, so [5,6,7] is a component
8->6, so update the compoent to [5,6,7,8]
9->8, so update the compoent to [5,6,7,8,9]
``````

You can visit each node exactly once, so time is O(n). Space is O(n) since all you need is a component id for each node, and a list of component ids.

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In fact, my example maybe too special for your idea, for it's lack a kind of merging operation. O(n) is just the best case. – blackball Nov 2 '12 at 19:30

Long time ago question....as a complement, here is a efficient implementation: https://gist.github.com/blackball/4002163

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