Cycles in an Undirected Graph

Given an undirected graph G=(V,E) with n vertices ( |V| = n ), how do you find if it contains a cycle in O(n) ?

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I think that depth first search solves it. If an unexplored edge leads to a node visited before, then the graph contains a cycle. This condition also makes it O(n), since you can explore maximum n edges without setting it to true or being left with no unexplored edges.

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and if you go the breadth first search route, then an unexplored edge leading to a node "discovered" before, then the graph contains a cycle. BTW, IIRC the runtime of graph algorithms is usually described in terms of V and E. –  paxos1977 Feb 10 '09 at 1:04
Hmmm...this could devolve into an O(n^2) algorithm if you aren't careful, no? If you check for a node visited before by keeping all of the nodes in a linked list (new nodes to the end) then you'll have to scan your node list (the scan is O(n) in itself) on each check. Ergo - O(n^2). –  Mark Brittingham Feb 10 '09 at 1:14
If you mark each node, though, it is definitely O(n). –  Mark Brittingham Feb 10 '09 at 2:25
This condition is also known as a back edge. After running DFS, if the resulting DFS tree contains any back edges (an edge pointing to an ancestor in the tree), you know there's a cycle. This also works for a directed graph. –  rahulmehta95 Nov 10 '12 at 18:46
@Sky It is the other way around - it only works in an undirected graph. –  Rafał Dowgird Feb 22 at 15:09

Actually, depth first (or indeed breadth first) search isn't quite enough. You need a sightly more complex algorithm.

For instance, suppose there is graph with nodes {a,b,c,d} and edges {(a,b),(b,c),(b,d),(d,c)} where an edge (x,y) is an edge from x to y. (looks something like this, with all edges directed downwards.)

    (a)
|
|
(b)
/ \
(d)  |
|   |
\ /
(c)


Then doing depth first search may visit node a, then b then c then backtrack to c then visit d and finally visit c again and conclude there is a cycle when there isn't. A similar thing happens with breadth first.

What you need to do is keep track of which nodes your in the middle of visiting. In the example above, when the algorithm reaches (d) it has finished visiting (c) but not (a) or (b). So revisiting a finished node is fine, but visiting an unfinished node means you have a cycle. The usual way to do this is colour each node white(not yet visited), grey(visiting descendants) or black(finished visiting).

here is some pseudo code!

define visit(node n):
if n.colour == grey: //if we're still visiting this node or its descendants
throw exception("Cycle found")

n.colour = grey //to indicate this node is being visited
for node child in n.children():
if child.colour == white: //if the child is unexplored
visit(child)

n.colour = black //to show we're done visiting this node
return


then running visit(root_node) will throw an exception if and only if there is a cycle (initially all nodes should be white).

Sorry if you knew all this already, it may well be what you meant by depth first search anyway, but I hope it helps.

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Hah, so it is...Guess I should read things more carefully! –  Anonymous Feb 10 '09 at 16:22
but still well answered and explained!! –  dimazaid Mar 2 '12 at 11:58
The if statement at line 2 is always false( check the if statement at line 7 ) –  Rontogiannis Aristofanis Oct 8 '12 at 17:14
for a directed graph, run topological search. if it succeeded: no cycles. otherwise: cycles exist. –  Alaa M. May 15 '13 at 13:42

The answer is, really, breadth first search (or depth first search, it doesn't really matter). The details lie in the analysis.

Now, how fast is the algorithm?

First, imagine the graph has no cycles. The number of edges is then O(V), the graph is a forest, goal reached.

Now, imagine the graph has cycles, and your searching algorithm will finish and report success in the first of them. The graph is undirected, and therefore, the when the algorithm inspects an edge, there are only two possibilities: Either it has visited the other end of the edge, or it has and then, this edge closes a circle. And once it sees the other vertex of the edge, that vertex is "inspected", so there are only O(V) of these operations. The second case will be reached only once throughout the run of the algorithm.

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You can solve it using DFS. Time complexity: O(n)

The essence of the algorithm is that if a connected component/graph does NOT contain a CYCLE, it will always be a TREE.See here for proof

Let us assume the graph has no cycle, i.e. it is a tree. And if we look at a tree, each edge from a node:

1.either reaches to its one and only parent, which is one level above it.

2.or reaches to its children, which are one level below it.

So if a node has any other edge which is not among the two described above, it will obviously connect the node to one of its ancestors other than its parent. This will form a CYCLE.

Now that the facts are clear, all you have to do is run a DFS for the graph (considering your graph is connected, otherwise do it for all unvisited vertices), and IF you find a neighbor of the node which is VISITED and NOT its parent, then my friend there is a CYCLE in the graph, and you're DONE.

You can keep track of parent by simply passing the parent as parameter when you do DFS for its neighbors. And Since you only need to examine n edges at the most, the time complexity will be O(n).

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This is a nice observation with this tree. It means if you just want a yes/no answer, you can count the number of edges in every connected component, and compare it to (n-1), n = count of nodes in the component (or whole connected graph). –  Tomasz Gandor Mar 12 at 12:48
Thanks. Indeed that was the observation. –  mb1994 Apr 13 at 16:08

By the way, if you happen to know that it is connected, then simply it is a tree (thus no cycles) if and only if |E|=|V|-1. Of course that's not a small amount of information :)

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I believe that the assumption that the graph is connected can be handful. thus, you can use the proof shown above, that the running time is O(|V|). if not, then |E|>|V|. reminder: the running time of DFS is O(|V|+|E|).

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As others have mentioned... A depth first search will solve it. In general depth first search takes O(V + E) but in this case you know the graph has at most O(V) edges. So you can simply run a DFS and once you see a new edge increase a counter. When the counter has reached V you don't have to continue because the graph has certainly a cycle. Obviously this takes O(v).

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I believe using DFS correctly also depends on how are you going to represent your graph in the code. For example suppose you are using adjacent lists to keep track of neighbor nodes and your graph has 2 vertices and only one edge: V={1,2} and E={(1,2)}. In this case starting from vertex 1, DFS will mark it as VISITED and will put 2 in the queue. After that it will pop vertex 2 and since 1 is adjacent to 2, and 1 is VISITED, DFS will conclude that there is a cycle (which is wrong). In other words in Undirected graphs (1,2) and (2,1) are the same edge and you should code in a way for DFS not to consider them different edges. Keeping parent node for each visited node will help to handle this situation.

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Here is the code I've written in C based on DFS to find out whether a given graph is connected/cyclic or not. with some sample output at the end. Hope it'll be helpful :)

#include<stdio.h>
#include<stdlib.h>

/****Global Variables****/
int A[20][20],visited[20],v=0,count=0,n;
int seq[20],s=0,connected=1,acyclic=1;

/****DFS Function Declaration****/
void DFS();

/****DFSearch Function Declaration****/
void DFSearch(int cur);

/****Main Function****/
int main()
{
int i,j;

printf("\nEnter no of Vertices: ");
scanf("%d",&n);

for(i=1;i<=n;i++)
for(j=1;j<=n;j++)
scanf("%d",&A[i][j]);

printf("\nThe Depth First Search Traversal:\n");

DFS();

for(i=1;i<=n;i++)
printf("%c,%d\t",'a'+seq[i]-1,i);

if(connected && acyclic)    printf("\n\nIt is a Connected, Acyclic Graph!");
if(!connected && acyclic)   printf("\n\nIt is a Not-Connected, Acyclic Graph!");
if(connected && !acyclic)   printf("\n\nGraph is a Connected, Cyclic Graph!");
if(!connected && !acyclic)  printf("\n\nIt is a Not-Connected, Cyclic Graph!");

printf("\n\n");
return 0;
}

/****DFS Function Definition****/
void DFS()
{
int i;
for(i=1;i<=n;i++)
if(!visited[i])
{
if(i>1) connected=0;
DFSearch(i);
}
}

/****DFSearch Function Definition****/
void DFSearch(int cur)
{
int i,j;
visited[cur]=++count;

seq[count]=cur;
for(i=1;i<count-1;i++)
if(A[cur][seq[i]])
acyclic=0;

for(i=1;i<=n;i++)
if(A[cur][i] && !visited[i])
DFSearch(i);

}


/*Sample Output:

majid@majid-K53SC:~/Desktop$gcc BFS.c majid@majid-K53SC:~/Desktop$ ./a.out
************************************

Enter no of Vertices: 10

0 0 1 1 1 0 0 0 0 0
0 0 0 0 1 0 0 0 0 0
0 0 0 1 0 1 0 0 0 0
0 0 0 0 0 0 0 0 0 0
0 0 0 0 0 0 0 0 0 0
0 1 0 0 1 0 0 0 0 0
0 0 0 0 0 0 0 1 0 0
0 0 0 0 0 0 0 0 1 0
0 0 0 0 0 0 0 0 0 1
0 0 0 0 0 0 1 0 0 0

The Depdth First Search Traversal:
a,1 c,2 d,3 f,4 b,5 e,6 g,7 h,8 i,9 j,10

It is a Not-Connected, Cyclic Graph!

majid@majid-K53SC:~/Desktop$./a.out ************************************ Enter no of Vertices: 4 Enter the Adjacency Matrix(1/0): 0 0 1 1 0 0 1 0 1 1 0 0 0 0 0 1 The Depth First Search Traversal: a,1 c,2 b,3 d,4 It is a Connected, Acyclic Graph! majid@majid-K53SC:~/Desktop$ ./a.out
************************************

Enter no of Vertices: 5

0 0 0 1 0
0 0 0 1 0
0 0 0 0 1
1 1 0 0 0
0 0 1 0 0

The Depth First Search Traversal:
a,1 d,2 b,3 c,4 e,5

It is a Not-Connected, Acyclic Graph!

*/

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A simple DFS does the work of checking if the given undirected graph has a cycle or not.

Here's the C++ code to the same.

The idea used in the above code is:

If a node which is already discovered/visited is found again and is not the parent node , then we have a cycle.

This can also be explained as below(mentioned by @Rafał Dowgird

If an unexplored edge leads to a node visited before, then the graph contains a cycle.

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An undirected graph without cycle has |E| < |V|-1.

public boolean hasCycle(Graph g) {

int totalEdges = 0;
for(Vertex v : g.getVertices()) {
totalEdges += v.getNeighbors().size();
}