Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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.

share|improve this question

3 Answers 3

up vote 3 down vote accepted

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.

share|improve this answer
    
thanks very much. –  user1786323 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.

In your example:

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.

share|improve this answer
    
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. –  user1786323 Nov 2 '12 at 19:30

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

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.