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.

I have an undirected graph. One edge in that graph is special. I want to find all other edges that are part of a even cycle containing the first edge.

I don't need to enumerate all the cycles, that would be inherently NP I think. I just need to know, for each each edge, whether it satisfies the conditions above.

A brute force search works of course but is too slow, and I'm struggling to come up with anything better. Any help appreciated.

share|improve this question
    
There is insufficient information here to provide an answer of the quality you are seeking. How far ahead of time do you know which edge is special? Are you allowed to preprocess the data? How much do you touch the data beforehand (e.g. load it), and can you modify how you preprocess the data? –  ninjagecko Aug 26 '12 at 8:22
    
Furthermore, you might possibly need to look at all the cycles if you cannot abuse preprocessing, though I can't think of a proof of that assertion one way or another. –  ninjagecko Aug 26 '12 at 8:22
1  
@ninjagecko The graph represents a chemical structure, i.e. the vertices are atoms and the edges are chemical bonds between those atoms. The chemical structure is being continuously edited by the user and this algorithm is expected to run in real time as the user performs edits. We use a simple adjacency list structure for the graph, although we do maintain a few other structures as well (for instance we know at all times whether an edge is part of a cycle or not). If I understand you right, preprocessing is not an option, since the graph (and the special edge) are always changing. –  john Aug 26 '12 at 8:28
    
"although we do maintain a few other structures as well (for instance we know at all times whether an edge is part of a cycle or not)" -- perhaps this structure be modified to keep track of whether it's part of an even cycle? What kind of structure is it? (Preprocessing should be doable since the user loads the chemical from a file or it's generated somehow which is an O(N) operation, but may not be necessary.) –  ninjagecko Aug 26 '12 at 8:48
2  
Are the cycles restricted to simple cycles? Would two triangles connected by an edge between their tips (kind of an hourglass shape) count as a length 8 cycle, with the middle edge being used twice? –  Chris Okasaki Aug 26 '12 at 17:37
show 7 more comments

2 Answers

I think we have an answer (I must credit my colleague with the idea). Essentially his idea is to do a flood fill algorithm through the space of even cycles. This works because if you have a large even cycle formed by merging two smaller cycles then the smaller cycles must have been both even or both odd. Similarly merging an odd and even cycle always forms a larger odd cycle.

This is a practical option only because I can imagine pathological cases consisting of alternating even and odd cycles. In this case we would never find two adjacent even cycles and so the algorithm would be slow. But I'm confident that such cases don't arise in real chemistry. At least in chemistry as it's currently known, 30 years ago we'd never heard of fullerenes.

share|improve this answer
add comment

If your graph has a small node degree, you might consider using a different graph representation:

Let three atoms u,v,w and two chemical bonds e=(u,v) and k=(v,w). A typical way of representing such data is to store u,v,w as nodes and e,k as edges in a graph.

However, one may represent e and k as nodes in the graph, having edges like f=(e,k) where f represents a 2-step link from u to w, f=(e,k) or f=(u,v,w). Running any algorithm to find cycles on such a graph will return all even cycles on the original graph.

Of course, this is efficient only if the original graph has a small node degree. When a user performs an edit, you can easily edit accordingly the alternative representation.

share|improve this answer
add comment

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.