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I know there are two ways to represent my graph: one is using a matrix, and the other one is using a list.

If I use a matrix, I have to flip all the bits in the matrix. Doesn't that take O(V^2) time?

If I use a list, wouldn't I have to traverse each list, one by one, and create a new set? That would seem to take O(V+E) time which is linear. Am I correct?

So, I got another question here. Consider, for example, that I use the Dijkstra algorithm on my graph (either a matrix or a list), and we use a priority queue for the data structure behind the scene. Is there any relation of graph representation and the use of data structure? Will it affect the performance of the algorithm?

Suppose I were to use a list for representations and a priority queue for the Dijkstra algorithm, would there be a difference between matrix and use priority queue for Dijkstra?

I guess it relates to makeQueue operation only? Or they don't have different at all?

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You are muddling around, confused, with no apparent goal in mind. Do you have a specific goal in mind? If so, please enlighten us so we can help unmuddle you; If not, SO may not be the correct forum for this particular adventure. –  Pieter Geerkens Apr 23 '13 at 2:48
    
Traversal of adjacency lists does Not Happen in linear Time in General as E=O(V^2). –  collapsar Apr 23 '13 at 7:26
    
@collapsar It always happens in linear time with relation to the vertices and edges. To define time complexity only on a part of the input (i.e. just vertices) (without explicitly stating it) seems somewhat illogical, especially when the time is directly related to another part of the input (but I can't argue that many people may define it as you did). And E = O(V^2) is for dense graphs. Sparse graphs are E = O(V). –  Dukeling Apr 23 '13 at 7:53
    
@dukeling you are right in pointing out that reducing the 'size' of a problem to a single scalar involves a lack of precision. otoh, big-Oh notation describes the worst case and, considering graphs, without additional constraints worst case means E=O(V^2). being precise, O(V^2) is not correct for edge reversal on an adjacency matrix either - if the representation sports a flag row-major vs. col-major, transposition is O(1). –  collapsar Apr 23 '13 at 8:50

2 Answers 2

up vote 8 down vote accepted

Reversing adjacency lists of Directional Graph can be done in linear time. We traverse the graph only once. Order of complexity will be O(|V|+|E|).

  1. Maintain a HashMap of Adjaceny Lists where key is the vertex label and value is ArrayList of adjacent vertices of the key vertex.
  2. For reversing, create a new HashMap of the similar kind. Scan the original hash map and for each key you come across, traverse the corresponding list.
  3. For each vertex found in the value list, add a key in new hashMap with putting key of original HashMap as an entry in ArrayList.
public static HashMap<Character,ArrayList <Character>> getReversedAdjLists(RGraph g)
{
    HashMap <Character, ArrayList<Character>> revAdjListMap = new HashMap <Character, ArrayList<Character>>();
    Set <Character> oldLabelSet = g.adjListMap.keySet();

    for(char oldLabel:oldLabelSet)
    {
        ArrayList<Character> oldLabelList = g.adjListMap.get(oldLabel);

        for (char newLabel : oldLabelList)
        {
            ArrayList<Character> newLabelList = revAdjListMap.get(newLabel);

            if (newLabelList == null)
            {
                newLabelList = new ArrayList<Character>();
                newLabelList.add(oldLabel);
            }
            else if ( ! newLabelList.contains(oldLabel))
            {
                newLabelList.add(oldLabel);
            }

            revAdjListMap.put(newLabel, newLabelList);
        }
    }

    return revAdjListMap;
}
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I think reversing the graph by traversing the list takes O(V2), since for each vertex you must add or delete (V-1) edges.

As for Dijkstra's algorithm, as I understand it, if you represent the graph as a matrix or list the algorithm takes O(V2), but some other data structures are faster. The fastest known is a Fibonacci heap, which gives O(E + VlogV).

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How about if I keep two lists? The incoming edges list and outgoing edges list, this seems to be a good idea? –  Timothy Leung Apr 23 '13 at 2:03
    
@TimothyLeung: Why? I don't see how that would give any advantage over one list of outgoing edges. –  Beta Apr 23 '13 at 4:40
    
@Beta I imagine it would only be O(V^2) when the graph is dense. Consider no edges. You'd only do O(1) work at every vertex, thus O(V). Thus edges has to come into play in the complexity. –  Dukeling Apr 23 '13 at 7:27
    
@Dukeling: are you talking about reversal or Dijkstra? –  Beta Apr 23 '13 at 13:55
    
@Beta Reversal, as in reverse the direction of all the edges. It looks like you may have interpreted it as a complement operation (removing all existing edges and creating edges where there didn't exist any). Maybe this is what OP wanted, I'm not sure. –  Dukeling Apr 23 '13 at 14:04

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