# Find a simple cycle in a weighted undirected graph whose length lies in a given user defined range

EDITED - 12/03/12 @ 1:05 AM PST

I have edited my code as follows. However, I am still not getting it to return any paths.

Again, this code is to compute a path, with a specified starting vertex and distance by the user. The program is to return all of the appropriate paths which match the specified data.

Here is my code this far:

``````vector<vector<Vertex>> Graph::FindPaths(Graph &g, int startingIntersection, float distanceInMiles)
{
/* A vector which contains vectors which will contain all of the suitable found paths. */
vector<vector<Vertex>> paths;

/* Create an empty set to store the visited nodes. */
unordered_set<int> visited;

/* Vector which will be used to the hold the current path. */
vector<Vertex> CurrentPathList;

/* Will be used to store the currerntVertex being examined. */
Vertex currentVertex;

/* Will be used to store the next vertex ID to be evaluated. */
int nextVertex;

/* Will be used to determine the location of the start ID of a vertex within the VertexList. */
int start;

/* Stack containing the current paths. */
stack<Vertex> currentPaths;

/* CurrentPathDistance will be used to determine the currernt distance of the path. */
float currentPathDistance = 0;

/* The startingIntersection location must be found within the VertexList.  This is because there is
* no guarantee that the VertexList will hold sequential data.
*
* For example, the user inputs a startingIntersection of 73.  The Vertex for intersection #73 may
* be located at the 20th position of the VertexList (i.e. VertexList[20]). */
start = g.FindStartingIntersection(g, startingIntersection);

/* Push the startingIntersection onto the stack. */
currentPaths.push(g.VertexList[start]);

/* Continue to iterate through the stack until it is empty.  Once it is empty we have exhaused all
* possible paths. */
while(!currentPaths.empty())
{
/* Assign the top value of the stack to the currentVertex. */
currentVertex = currentPaths.top();

/* Pop the top element off of the stack. */
currentPaths.pop();

/* Check to see if we are back to the startingIntersection.  As a note, if we are just starting, it will
* put the startingIntersection into the paths. */
if(currentVertex.id == startingIntersection)
{
/* Add currentVertex to a list. */
CurrentPathList.push_back(currentVertex);

/* Find the current path distance. */
currentPathDistance = FindPathDistance(g, CurrentPathList);

/* Check the currentPathDistance.  If it is within +/- 1 mile of the specified distance, then place
* it into the vector of possible paths. */
if((currentPathDistance + 1 >= distanceInMiles) && (currentPathDistance - 1 <= distanceInMiles))
{
paths.push_back(CurrentPathList);
}
}
else /* The ending vertex was not the user specified starting vertex. */
{
/* Remove all elements from the stack. */
while(!currentPaths.empty())
{
currentPaths.pop();
}
}

nextVertex = FindUnvisitedNeighbor(g, currentVertex, visited);

// repeat while current has unvisited neighbors
while(nextVertex != -1)
{
/* Find the new starting vertex. */
start = g.FindStartingIntersection(g, nextVertex);

/* Push the startingIntersection onto the stack. */
currentPaths.push(g.VertexList[start]);

/* Push the next vertex into the visted list. */
visited.insert(nextVertex);

nextVertex = FindUnvisitedNeighbor(g, currentVertex, visited);
}
}

/* Return the vector of paths that meet the criteria specified by the user. */
return paths;
``````

My code for `FindingUnvistedNeighbor()` is as follows:

``````int FindUnvisitedNeighbor(Graph &g, Vertex v, unordered_set<int> visited)
{
/* Traverse through vertex "v"'s EdgeList. */
for(int i = 0; i + 1 <= v.EdgeList.size(); i++)
{
/* Create interator to traverse through the visited list to find a specified vertex. */
unordered_set<int>::const_iterator got = visited.find(v.EdgeList[i].intersection_ID_second);

if(got == visited.end())
{

return v.EdgeList[i].intersection_ID_second;
}
}

return -1;
}
``````
-
2 suggestions: 1. remove the above code snippets. They are not related to your question, and your question is very long. 2. Change the title to something like "Find a simple cycle in a weighted undirected graph whose length lies in a given range" – Haozhun Dec 2 '12 at 5:59
Please clarify. Does this graph satisfy triangle inequality? – Haozhun Dec 2 '12 at 6:00
Thanks for the input! I have edited the question and title as per your suggestion. Unfortunately I do not know what you mean by "triangle inequality" =( So I am going to say that it does not as I have not heard of that term in my classes. – Christopher Cheuvront Dec 2 '12 at 6:06
You forgot to answer my question. Does this graph satisfy triangle inequality? If it is a real-world map, it does. – Haozhun Dec 2 '12 at 6:08
I do not think he should assume the triangle-inequality holds. Imagine three paths near a hill. Two of the paths connect to go around the hill from point A on one side to point B on the other side in segments of 2 miles each. Going over the hill from point A to point B is 4.4 miles. – Jive Dadson Dec 2 '12 at 13:16

This seems like a fundamentally algorithmic problem, rather than an implementation-specific one, so I have provided detailed, high-level pseudocode for the algorithm rather than actual code. Also, I don't know C++. Let me know if any of the syntax/logic is unclear, and I can clarify some more. It essentially does a DFS, but doesn't stop when it finds the value: it continues searching, and reports all paths to the value (which meet the given distance criterion).

``````// Input: Graph G, Vertex start, Integer targetDistance
// Output: Set< List<Vertex> > paths
FindPaths ( G, start, targetDistance ):
create an empty set, paths
create an empty set, visited
create an empty stack, currentPath

// Iterative Exhaustive DFS
push start on currentPath
while ( currentPath is not empty ):
current = pop ( currentPath )

if ( current equals start ):
copy currentPath to a list, L (reversed order doesn't matter)
// find its weight
w = FindPathWeight ( L, G )

if ( w+1 >= targetDistance AND w-1 <= targetDistance ):

else if ( current is a dead-end ): drop it completely, it's useless

x = FindUnvisitedNeighbor ( current, G, visited )
// repeat while current has unvisited neighbors
while ( x ):
push x on currentPath
x = FindUnvisitedNeighbor ( current, G, visited )

return paths
//EndFindPaths
``````

``````// Input: List path, Graph G
// Output: Integer weight
FindPathWeight ( path, G ):
Integer weight = 0;

for each ( Vertex v in path ):

if ( v is the end of the path ): break

Consider the next vertex in the list, u
Find the edge v——u in the graph, call it e
Get the weight of e, w
weight = weight + w

return weight
//EndFindPathWeight
``````

``````// Input: Vertex v, Graph G, Set visited
// Output: Vertex u (or null, if there are none)
FindUnvisitedNeighbor ( v, G, visited ):

for each ( Edge v——u in G.EdgeList ):

if ( u in visited ): continue

// u is the first unvisited neighbor
return u

return null
//EndFindUnvisitedNeighbor
``````
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Thanks for the algorithm! I'm going to give this a shot. – Christopher Cheuvront Dec 2 '12 at 18:38
Hello again, so I have tried my best to implement this algorithm. However, I am now having a hard time figuring out how to go through the unvisted neighbors and also how to calculate the distance. I am editing my original post with what I have done with the code. – Christopher Cheuvront Dec 2 '12 at 23:43
@Christopher You need the `set visited` to keep track of the visited nodes. C++ seems to have a built-in `unordered_set` which is perfect for this: it's a hash-set, so you can check if it contains an element very quickly, in `O(1)`. `current` in my pseudocode is a single vertex, but it looks like you may have used a different data structure there. `paths` is a set of lists of vertices. I will add two additional functions for finding weight, and finding neighbors. – nbrooks Dec 3 '12 at 1:03
@Christopher Also, since you're `current` is a vector, you're using an index `i` but you never actually increment it. I don't think that needs to be a vector at all... – nbrooks Dec 3 '12 at 1:08
Thanks for the help! Working on it now =) – Christopher Cheuvront Dec 3 '12 at 2:14

depth first is fine. you have to abort when

``````* path too long (bad)
* starting vertex visited (found a solution)
``````

for detecting these conditions you have to keep track of the so far visited edges/vertices

the depth firs walk looks like this (completely unchecked) pseudocode
anyway you should get the idea

``````edge
pair of node
length

node
list of edge

arrow               // incoming edge, node
pair of edge, node

path
list of arrow

check_node(arrow)   // incoming edge, node
current_path.push(arrow)
if length(current_path) > limit
// abort too long
current_path.pop(arrow)
return
if length(current_path) > 0 && current_path.first.node == current_path.last,node
// found solution
solutions.push(current_path)  // store the found solution and continue search
current_path.pop(arrow)
return
if node in current_path
// abort cycle
current_path.pop(arrow)
return
for each edge in node
// go deeper
check(arrow(edge, edge.other_node))
current_path.pop(arrow)
return

main
path current_path
list of path solutions    // will hold all possible solutions after the check

make_graph

check_node(NULL, graph.start)

for each solution in solutions   // print 0 .. n solutions
print solution
``````
-
Yep, that's what I need to do. However, I need it to keep finding solutions (if more than one exists) that meet the distance criteria. – Christopher Cheuvront Dec 2 '12 at 18:39
it DOES search all solutions. i added some more comments in the pseudocode (intendation indicates a block) – stefan Dec 4 '12 at 20:26