# Random contraction algorithm for finding Min Cuts in a graph

Okay so here's my algorithm for finding a Cut in a graph (I'm not talking about a min cut here)

Say we're given an adjacency list of a non-directed graph.

1. Choose any vertice on the graph (let this be denoted by pivot)
2. Choose any other vertice on the graph (randomly). (denote this by x)
3. If the two vertices have an edge between them, then remove that edge from the graph. And dump all the vertices that x is connected to, onto pivot. (if not then go back to Step 2.
4. If any other vertices were connected to x, then change the adjacency list so that now x is replaced by pivot. Ie they're connected to Pivot.
5. If number of vertices is greater than 2 (go back to step 2)
6. If equal to 2. Just count number of vertices present in adjacency list of either of the 2 points. This will give the cut

My question is, is this algorithm correct?

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Does it work for a couple of demo examples? If so then most likely yes. –  Matt Apr 7 '12 at 14:19
I'm sorry, what do you mean by dump all the vertices? –  kilotaras Apr 7 '12 at 14:40
Is this not a question for the mathematics StackExchange site? –  Geoff Apr 7 '12 at 15:18

That is a nice explanation of Krager's Min-Cut Algorithm for undirected graphs.

I think there might one detail you missed. Or perhaps I just mis-read your description.

You want to remove all self-loops.

For instance, after you remove a vertex and run through your algorithm, Vertex A may now have an edge that goes from Vertex A to Vertex A. This is called a self-loop. And they are generated frequently in process of contracting two vertices. As a first step, you can simply check the whole graph for self-loops, though there are some more sophisticated approaches.

Does that make sense?

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Yea it is Krager's Min-Cut Algorithm. I don't think there are any self loops being generated. But other than that, it all seems right, right? –  Ole Gooner Apr 9 '12 at 11:48
Yeah, totally, other than that it seems great. But check for self-loops. Consider, for instance, when your step 3, when you dump all of one vertexes edges onto another vertex. They were connected before, so there should be at least one (if not multiple) "self-loops" generated at that point. That's usually what happens. Anyway, you may have this covered, I just thought I'd mention it. Good work! –  theJollySin Apr 9 '12 at 16:41
Anyway, it wouldn't hurt to check for them the first time or two you run your code. Just in case. –  theJollySin Apr 9 '12 at 22:23

After choosing first vertex, choose another from his adjacency list. Now you are sure that two vertices have the edge between them. Next step is finding the vertex from adjancecy list.

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Agree that you should definitely remove self-loop. Also another point I want to add is after you randomly choose the first vertice, you don't have to randomly choose another node until you have one that is connected to the first node, you can simply choose from the ones that are connected to the first vertice because you know how many nodes are the first chosen one connects to. So a second random selection within a smaller range. This is just effectively randomly choosing an edge (determined by two nodes/vertices). I have some c# code implementing krager's algorithm you can play around. It's not the most efficient code (especially a more efficient data structure can be used) as I tested it on a 200 nodes graph, for 10000 iterations it takes about 30 seconds to run.

``````using System;
using System.Collections.Generic;
using System.Linq;

namespace MinCut
{
internal struct Graph
{
public int N { get; private set; }
public Graph(int n) : this()
{
N = n;
Connections = new List<int>();
}

public override bool Equals(object obj)
{
return Equals((Graph)obj);
}

public override int GetHashCode()
{
return base.GetHashCode();
}

private bool Equals(Graph g)
{
return N == g.N;
}
}

internal sealed class GraphContraction
{
public static void Run(IList<Graph> graphs, int i)
{
var liveGraphs = graphs.Count;
if (i >= liveGraphs)
{
throw new Exception("Wrong random index generation; index cannot be larger than the number of nodes");
}
var leftV = graphs[i];

var r = new Random();
var index = r.Next(0, leftV.Connections.Count);
var rightV = graphs.Where(x=>x.N == leftV.Connections[index]).Single();

foreach (var v in graphs.Where(x => !x.Equals(leftV) && x.Connections.Contains(leftV.N)))
{
v.Connections.RemoveAll(x => x == leftV.N);
}
foreach (var c in leftV.Connections)
{
if (c != rightV.N)
{
int c1 = c;
}
}
graphs.Remove(leftV);
}
}
``````

}

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can you (or some other reader) show or link to why this randomization method is "effective?" That's a strong statement to make without support--please share why you are confident Pr(any edge on whole graph)=1/m for all graphs, ever. –  newcoder Nov 8 '14 at 1:02
@newcoder, in theory to get probability of 1/m you need to run m^2*log(m) iterations. It involves quite a bit maths to prove this and you can refer to many online resources to get a detailed proof such as en.wikipedia.org/wiki/Karger's_algorithm –  stt106 Nov 8 '14 at 20:41
Perhaps I was unclear; my previous comment referred to the probability of choosing any given edge for contraction being 1/m, where m is the number of edges remaining. The algorithm relies on this probability being uniform for all edges. Choosing edges in the way you and @stupi suggest does not actually meet this requirement. –  newcoder Nov 10 '14 at 5:24
To illustrate, consider the following graph: [(0):1,2,2,3] [(1):0] [(2):0,0] [(3):0] For this graph, m=4 , so any method purporting to choose a uniformly random edge should calculate to Pr(0,1)=1/4 , Pr(0,2)=1/4 , and Pr(0,3)=1/4 By first choosing a vertex uniformly at random and then choosing a vertex uniformly at random from its adjacency list, we have Pr(0,1)=5/16 , Pr(0,2)=6/16 , and Pr(0,3)=5/16 . –  newcoder Nov 10 '14 at 5:41
I am not sure how you calculated your P(0,1) = 5/16, P(0,2) = 6/16 and P(0,3) = 5/16. Here is my calculation: P(0,1) in fact is a conditional probability of randomly choosing vertex 1 given vertex 0 has been chosen already, namely it's P(1|0) = P(0 and 1) / P(0); because each selection is independent hence P(0 and 1) = P(0) * P(1), so P(1|0) = P(1) = 1/4, similarly P(2|0) = P(2) = 2/4 = 1/2; P(3|0) = 1/4. –  stt106 Nov 11 '14 at 10:26