# How do I find all paths in a sequence of edges in a fast way?

Let E be a given directed edge set. Suppose it is known that the edges in E can form a directed tree T with all the nodes (except the root node) has only 1 in-degree. The problem is how to efficiently traverse the edge set E, in order to find all the paths in T?

For example, Given a directed edge set E={(1,2),(1,5),(5,6),(1,4),(2,3)}. We know that such a set E can generate a directed tree T with only 1 in-degree (except the root node). Is there any fast method to traverse the edge set E, in order to find all the paths as follows:

``````Path1 = {(1,2),(2,3)}
Path2 = {(1,4)}
Path3 = {(1,5),(5,6)}
``````

By the way, suppose the number of edges in E is |E|, is there complexity bound to find all the paths?

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I have not worked on this kind of problems earlier. So just tried out a simple solution. Check this out.

``````public class PathFinder
{
private static Dictionary<string, Path> pathsDictionary = new Dictionary<string, Path>();
private static List<Path> newPaths = new List<Path>();
public static Dictionary<string, Path> GetBestPaths(List<Edge> edgesInTree)
{
foreach (var e in edgesInTree)
{
UpdatePaths();
}
return pathsDictionary;
}
{
newPaths.Clear();
newPaths.Add(new Path(new List<Edge> { currentEdge }));
if (!pathsDictionary.ContainsKey(currentEdge.PathKey()))
{
var pathKeys = pathsDictionary.Keys.Where(c => c.Split(",".ToCharArray())[1] == currentEdge.StartPoint.ToString()).ToList();
pathKeys =  pathsDictionary.Keys.Where(c => c.Split(",".ToCharArray())[0] == currentEdge.EndPoint.ToString()).ToList();
pathKeys.ForEach(key => { var newPath = new Path(pathsDictionary[key].ConnectedEdges); newPath.ConnectedEdges.Insert(0, currentEdge); newPaths.Add(newPath); });
}
}
private static void UpdatePaths()
{
Path oldPath = null;
foreach (Path newPath in newPaths)
{
if (!pathsDictionary.ContainsKey(newPath.PathKey()))
else
{
oldPath = pathsDictionary[newPath.PathKey()];
if (newPath.PathWeights < oldPath.PathWeights)
pathsDictionary[newPath.PathKey()] = newPath;
}
}
}
}

public static class Extensions
{
public static bool IsNullOrEmpty(this IEnumerable<object> collection) { return collection == null || collection.Count() > 0; }
public static string PathKey(this ILine line) { return string.Format("{0},{1}", line.StartPoint, line.EndPoint); }
}
public interface ILine
{
int StartPoint { get; }
int EndPoint { get; }
}
public class Edge :ILine
{
public int StartPoint { get; set; }
public int EndPoint { get; set; }

public Edge(int startPoint, int endPoint)
{
this.EndPoint = endPoint;
this.StartPoint = startPoint;
}
}
public class Path :ILine
{
private List<Edge> connectedEdges = new List<Edge>();
public Path(List<Edge> edges) { this.connectedEdges = edges; }
public int StartPoint { get { return this.IsValid ? this.connectedEdges.First().StartPoint : 0; } }
public int EndPoint { get { return this.IsValid ? this.connectedEdges.Last().EndPoint : 0; } }
public bool IsValid { get { return this.EdgeCount > 0; } }
public int EdgeCount { get { return this.connectedEdges.Count; } }
// For now as no weights logics are defined
public int PathWeights { get { return this.EdgeCount; } }
public List<Edge> ConnectedEdges { get { return this.connectedEdges; } }
}
``````
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I think DFS(Depth First Search) should suit your requirements. Have a look at it here - Depth First Search - Wikipedia. You can tailor it to print the paths in the format that you require. As regards the complexity, since every node in your tree has in-degree one , the number of edges for your tree is bounded as - |E| = O(|V|). Since DFS operates with a complexity of O(|V|+|E|), your overall complexity comes out to be O(|V|).

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DFS is used for graphs, is there any fast algorithm for such trees? – John Smith Jun 16 '12 at 15:41
@JohnSmith isn't a tree just a graph with no cycles? i.e. a special case of a graph. If you look at the DFS wiki page the picture on the right of the page shows a graph - which is also a tree since it has no cycles. – Sean Jun 16 '12 at 15:52

I did this question as a part of a my assignment. The gentleman above has correctly pointed out to use pathID. You must visit each edge atleast once hence the complexity bound is O(V+E) but for tree E=O(V) therefore the complexity is O(v). I will give you a glimpse since the details are bit involved -

you will label each path with a unique ID and the path are alloted IDs in the incremental values such as 0,1,2.... A pathID of a path is the sum of weights of the edges on the path. So using DFS allocate weights to the path. You may begin by using 0 for edges until you encounter your first path and then you keep adding 1 and so on. You will also have to argue the correctness and properly allocate the weights. DFS will do the trick.

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