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i cannot understand a certain part of the paper published by Donald Johnson about finding cycles (Circuits) in a graph.

More specific i cannot understand what is the matrix Ak which is mentioned in the following line of the pseudo code :

Ak:=adjacency structure of strong component K with least vertex in subgraph of G induced by {s,s+1,....n};

to make things worse some lines after is mentins " for i in Vk do " without declaring what the Vk is...

As far i have understand we have the following: 1) in general, a strong component is a sub-graph of a graph, in which for every node of this sub-graph there is a path to any node of the sub-graph (in other words you can access any node of the sub-graph from any other node of the sub-graph)

2) a sub-graph induced by a list of nodes is a graph containing all these nodes plus all the edges connecting these nodes. in paper the mathematical definition is " F is a subgraph of G induced by W if W is subset of V and F = (W,{u,y)|u,y in W and (u,y) in E)}) where u,y are edges , E is the set of all the edges in the graph, W is a set of nodes.

3)in the code implementation the nodes are named by integer numbers 1 ... n.

4) I suspect that the Vk is the set of nodes of the strong component K.

now to the question. Lets say we have a graph G= (V,E) with V = {1,2,3,4,5,6,7,8,9} which it can be divided into 3 strong components the SC1 = {1,4,7,8} SC2= {2,3,9} SC3 = {5,6} (and their edges)

Can anybody give me an example for s =1, s= 2, s= 5 what if going to be the Vk and Ak according to the code?

The pseudo code is in my previous question in http://stackoverflow.com/questions/2908575/help-in-the-donalds-b-johnsons-algorithm-i-cannot-understand-the-pseudo-code

and the paper can be found at http://stackoverflow.com/questions/2908575/help-in-the-donalds-b-johnsons-algorithm-i-cannot-understand-the-pseudo-code

thank you in advance

share|improve this question

2 Answers 2

up vote 6 down vote accepted

It works! In an earlier iteration of the Johnson algorithm, I had supposed that A was an adjacency matrix. Instead, it appears to represent an adjacency list. In that example, implemented below, the vertices {a, b, c} are numbered {0, 1, 2}, yielding the following circuits.

Addendum: As noted in this proposed edit and helpful answer, the algorithm specifies that unblock() should remove the element having the value w, not the element having the index w.

list.remove(Integer.valueOf(w));

Sample output:

0 1 0
0 1 2 0
0 2 0
0 2 1 0
1 0 1
1 0 2 1
1 2 0 1
1 2 1
2 0 1 2
2 0 2
2 1 0 2
2 1 2

By default, the program starts with s = 0; implementing s := least vertex in V as an optimization remains.

import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
import java.util.Stack;

/**
 * @see http://dutta.csc.ncsu.edu/csc791_spring07/wrap/circuits_johnson.pdf
 * @see http://stackoverflow.com/questions/2908575
 * @see http://stackoverflow.com/questions/2939877
 * @see http://en.wikipedia.org/wiki/Adjacency_matrix
 * @see http://en.wikipedia.org/wiki/Adjacency_list
 */
public final class CircuitFinding {

    final Stack<Integer> stack = new Stack<Integer>();
    final List<List<Integer>> a;
    final List<List<Integer>> b;
    final boolean[] blocked;
    final int n;
    int s;

    public static void main(String[] args) {
        List<List<Integer>> a = new ArrayList<List<Integer>>();
        a.add(new ArrayList<Integer>(Arrays.asList(1, 2)));
        a.add(new ArrayList<Integer>(Arrays.asList(0, 2)));
        a.add(new ArrayList<Integer>(Arrays.asList(0, 1)));
        CircuitFinding cf = new CircuitFinding(a);
        cf.find();
    }

    /**
     * @param a adjacency structure of strong component K with
     * least vertex in subgraph of G induced by {s, s + 1, n};
     */
    public CircuitFinding(List<List<Integer>> a) {
        this.a = a;
        n = a.size();
        blocked = new boolean[n];
        b = new ArrayList<List<Integer>>();
        for (int i = 0; i < n; i++) {
            b.add(new ArrayList<Integer>());
        }
    }

    private void unblock(int u) {
        blocked[u] = false;
        List<Integer> list = b.get(u);
        for (int w : list) {
            //delete w from B(u);
            list.remove(Integer.valueOf(w));
            if (blocked[w]) {
                unblock(w);
            }
        }
    }

    private boolean circuit(int v) {
        boolean f = false;
        stack.push(v);
        blocked[v] = true;
        L1:
        for (int w : a.get(v)) {
            if (w == s) {
                //output circuit composed of stack followed by s;
                for (int i : stack) {
                    System.out.print(i + " ");
                }
                System.out.println(s);
                f = true;
            } else if (!blocked[w]) {
                if (circuit(w)) {
                    f = true;
                }
            }
        }
        L2:
        if (f) {
            unblock(v);
        } else {
            for (int w : a.get(v)) {
                //if (v∉B(w)) put v on B(w);
                if (!b.get(w).contains(v)) {
                    b.get(v).add(w);
                }
            }
        }
        v = stack.pop();
        return f;
    }

    public void find() {
        while (s < n) {
            if (a != null) {
                //s := least vertex in V;
                L3:
                circuit(s);
                s++;
            } else {
                s = n;
            }
        }
    }
}
share|improve this answer
    
+1 Wow, hope it wasn't his bachelor thesis. –  stacker Jun 1 '10 at 20:14
    
@stacker: I hope not! Paraphrasing Knuth: "Beware of bugs in the above code; I have only tried it, not proved it correct." –  trashgod Jun 2 '10 at 2:34
    
@trashgod Thank you for your kind and very usefull help @stacker basically is my a small part of my MSC dissertation but it's no problem as i have already wrote most of the code plus i use totally different structures. I haven't tested your code but still there is a minor problem. The Ak refers to subgraph of strong components (in your example the network all an SCC .. but what happens if it can be divided in 2 SCC? how is going to be the Ak then? ) That stil remains the big question mark. My idea is that propably ( i have to test to it to check for the correctness) the Ak is the adjaceny list –  Pitelk Jun 2 '10 at 18:26
    
of the subgraph containing the s, but with the edges from this SCC to all the other SCCs removed . For example let {0,1,2} be your example graph which is connected to the {3,4} with an edge from 2 -> 3 then the A0, A1,A2 will be the (already given by you) adjacency list plus the new one WITHOUT the edge from 2->3. –  Pitelk Jun 2 '10 at 18:34
    
All the fuss about the SCC is becuase you can divide the G to smaller one hence improve the perfomance of the algorithm ( as the algorithm has a complexity O(E*C) where C=number of cycles ..which C grows 2^n where n is the number of nodes...) Anyway, A million thanks for your all your help! –  Pitelk Jun 2 '10 at 18:35

I had sumbitted an edit request to @trashgod's code to fix the exception thrown in unblock(). Essentially, the algorithm states that the element w (which is not an index) is to be removed from the list. The code above used list.remove(w), which treats w as an index.

My edit request was rejected! Not sure why, because I have tested the above with my modification on a network of 20,000 nodes and 70,000 edges and it doesn't crash.

I have also modified Johnson's algorithm to be more adapted to undirected graphs. If anybody wants these modifications please contact me.

Below is my code for unblock().

private void unblock(int u) {
    blocked[u] = false;
    List<Integer> list = b.get(u);
    int w;
    for (int iw=0; iw < list.size(); iw++) {
        w = Integer.valueOf(list.get(iw));
        //delete w from B(u);
        list.remove(iw);
        if (blocked[w]) {
            unblock(w);
        }
    }
}
share|improve this answer
    
+1 for spotting this; I've updated my answer similarly. The edit request may have looked like an attempt to circumvent the comment threshold, but it's a good answer. –  trashgod Feb 12 '13 at 10:45

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