# Finding all cycles in a directed graph

How can I find (iterate over) ALL the cycles in a directed graph from/to a given node?

For example, I want something like this:

``````A->B->A
A->B->C->A
``````

but not: B->C->B

• Homework I assume? me.utexas.edu/~bard/IP/Handouts/cycles.pdf not that it's not a valid question :) Feb 13, 2009 at 16:57
• Note that this is at least NP Hard. Possibly PSPACE, I'd have to think about it, but it's too early in the morning for complexity theory B-) May 17, 2010 at 14:08
• If your input graph has v vertices and e edges then there are 2^(e - v +1)-1 different cycles (although not all might be simple cycles). That's quite a lot - you might not want to explicitly write all of them. Also, since the output size is exponential, the complexity of the algorithm cannot be polynomial. I think there is still no answer to this question. Mar 2, 2011 at 6:57
• My best option for me was this: personal.kent.edu/~rmuhamma/Algorithms/MyAlgorithms/GraphAlgor/… Mar 5, 2012 at 19:48
• Possible duplicate of Best algorithm for detecting cycles in a directed graph Apr 25, 2017 at 18:20

I found this page in my search and since cycles are not same as strongly connected components, I kept on searching and finally, I found an efficient algorithm which lists all (elementary) cycles of a directed graph. It is from Donald B. Johnson and the paper can be found in the following link:

http://www.cs.tufts.edu/comp/150GA/homeworks/hw1/Johnson%2075.PDF

A java implementation can be found in:

http://normalisiert.de/code/java/elementaryCycles.zip

Note: Actually, there are many algorithms for this problem. Some of them are listed in this article:

http://dx.doi.org/10.1137/0205007

According to the article, Johnson's algorithm is the fastest one.

• I find it such a hassle to implement from the paper, and ultimately this aglorithm still requires an implementation of Tarjan. And the Java-code is hideous too. :( Apr 29, 2011 at 23:05
• @Gleno Well, if you mean that you can use Tarjan to find all cycles in the graph instead of implementing the rest, you are wrong. Here, you can see the difference between strongly connected components and all cycles (The cycles c-d and g-h won't be returned by Tarjan's alg)(@batbrat The answer of your confusion is also hidden here: All possible cycles are not returned by Tarjan's alg, so its complexity could be smaller than exponential). The Java-Code could be better, but it saved me the effort of implementing from the paper. May 2, 2011 at 14:47
• This answer is much better than the answer selected. I struggled for quite a while trying to figure out how to get all simple cycles from the strongly connected components. It turns out this is non-trivial. The paper by Johnson contains a great algorithm, but is a little difficult to wade through. I looked at the Java implementation and rolled my own in Matlab. The code is available at gist.github.com/1260153. Oct 3, 2011 at 20:36
• @moteutsch: Maybe I'm missing something, but according to the Johnson paper (and other sources), a cycle is elementary if no vertex (apart from the start/finish) appears more than once. By that definition, isn't `A->B->C->A` elementary too? Dec 1, 2014 at 10:27
• Note for anyone using python for this: the Johnson algorithm is implemented as `simple_cycle` in networkx.
– Joel
Feb 12, 2016 at 21:15

Depth first search with backtracking should work here. Keep an array of boolean values to keep track of whether you visited a node before. If you run out of new nodes to go to (without hitting a node you have already been), then just backtrack and try a different branch.

The DFS is easy to implement if you have an adjacency list to represent the graph. For example adj[A] = {B,C} indicates that B and C are the children of A.

For example, pseudo-code below. "start" is the node you start from.

``````dfs(adj,node,visited):
if (visited[node]):
if (node == start):
"found a path"
return;
visited[node]=YES;
visited[node]=NO;
``````

Call the above function with the start node:

``````visited = {}
``````
• Thanks. I prefer this approach to some of the others noted here as it is simple(r) to understand and has reasonable time complexity, albeit perhaps not optimal. Jul 17, 2011 at 23:26
• how does this find all the cycles? Nov 27, 2013 at 9:06
• `if (node == start): ` -- what is `node and start` in the first call Nov 27, 2013 at 9:16
• @user1988876 This appears to find all cycles involving a given vertex (which would be `start`). It starts at that vertex and does a DFS until it gets back to that vertex again, then it knows it found a cycle. But it doesn't actually output the cycles, just a count of them (but modifying it to do that instead shouldn't be too difficult). Dec 13, 2013 at 3:03
• @user1988876 Well, it just prints "found a path" an amount of times equal to the number of cycles found (this can easily be replaced by a count). Yes, it will detect cycles only from `start`. You don't really need to clear the visited flags as each visited flag will be cleared due to `visited[node]=NO;`. But keep in mind that if you have a cycle `A->B->C->A`, you'll detect that 3 times, as `start` can be any 3 of those. One idea to prevent this is to have another visited array where every node that has been the `start` node at some point is set, and then you don't revisit these. Dec 13, 2013 at 21:55

First of all - you do not really want to try find literally all cycles because if there is 1 then there is an infinite number of those. For example A-B-A, A-B-A-B-A etc. Or it may be possible to join together 2 cycles into an 8-like cycle etc., etc... The meaningful approach is to look for all so called simple cycles - those that do not cross themselves except in the start/end point. Then if you wish you can generate combinations of simple cycles.

One of the baseline algorithms for finding all simple cycles in a directed graph is this: Do a depth-first traversal of all simple paths (those that do not cross themselves) in the graph. Every time when the current node has a successor on the stack a simple cycle is discovered. It consists of the elements on the stack starting with the identified successor and ending with the top of the stack. Depth first traversal of all simple paths is similar to depth first search but you do not mark/record visited nodes other than those currently on the stack as stop points.

The brute force algorithm above is terribly inefficient and in addition to that generates multiple copies of the cycles. It is however the starting point of multiple practical algorithms which apply various enhancements in order to improve performance and avoid cycle duplication. I was surprised to find out some time ago that these algorithms are not readily available in textbooks and on the web. So I did some research and implemented 4 such algorithms and 1 algorithm for cycles in undirected graphs in an open source Java library here : http://code.google.com/p/niographs/ .

BTW, since I mentioned undirected graphs : The algorithm for those is different. Build a spanning tree and then every edge which is not part of the tree forms a simple cycle together with some edges in the tree. The cycles found this way form a so called cycle base. All simple cycles can then be found by combining 2 or more distinct base cycles. For more details see e.g. this : http://dspace.mit.edu/bitstream/handle/1721.1/68106/FTL_R_1982_07.pdf .

The simplest choice I found to solve this problem was using the python lib called `networkx`.

It implements the Johnson's algorithm mentioned in the best answer of this question but it makes quite simple to execute.

In short you need the following:

``````import networkx as nx
import matplotlib.pyplot as plt

# Create Directed Graph
G=nx.DiGraph()

# Add a list of nodes:

# Add a list of edges:

#Return a list of cycles described as a list o nodes
list(nx.simple_cycles(G))
``````

Answer: [['a', 'b', 'd', 'e'], ['a', 'b', 'c']]

• You can also cnovert a dictionary to a networkx graph: `nx.DiGraph({'a': ['b'], 'b': ['c','d'], 'c': ['a'], 'd': ['e'], 'e':['a']})` Sep 3, 2017 at 14:51
• How do I specify a starting vertex? Dec 18, 2019 at 7:01

The DFS-based variants with back edges will find cycles indeed, but in many cases it will NOT be minimal cycles. In general DFS gives you the flag that there is a cycle but it is not good enough to actually find cycles. For example, imagine 5 different cycles sharing two edges. There is no simple way to identify cycles using just DFS (including backtracking variants).

Johnson's algorithm is indeed gives all unique simple cycles and has good time and space complexity.

But if you want to just find MINIMAL cycles (meaning that there may be more then one cycle going through any vertex and we are interested in finding minimal ones) AND your graph is not very large, you can try to use the simple method below. It is VERY simple but rather slow compared to Johnson's.

So, one of the absolutely easiest way to find MINIMAL cycles is to use Floyd's algorithm to find minimal paths between all the vertices using adjacency matrix. This algorithm is nowhere near as optimal as Johnson's, but it is so simple and its inner loop is so tight that for smaller graphs (<=50-100 nodes) it absolutely makes sense to use it. Time complexity is O(n^3), space complexity O(n^2) if you use parent tracking and O(1) if you don't. First of all let's find the answer to the question if there is a cycle. The algorithm is dead-simple. Below is snippet in Scala.

``````  val NO_EDGE = Integer.MAX_VALUE / 2

def shortestPath(weights: Array[Array[Int]]) = {
for (k <- weights.indices;
i <- weights.indices;
j <- weights.indices) {
val throughK = weights(i)(k) + weights(k)(j)
if (throughK < weights(i)(j)) {
weights(i)(j) = throughK
}
}
}
``````

Originally this algorithm operates on weighted-edge graph to find all shortest paths between all pairs of nodes (hence the weights argument). For it to work correctly you need to provide 1 if there is a directed edge between the nodes or NO_EDGE otherwise. After algorithm executes, you can check the main diagonal, if there are values less then NO_EDGE than this node participates in a cycle of length equal to the value. Every other node of the same cycle will have the same value (on the main diagonal).

To reconstruct the cycle itself we need to use slightly modified version of algorithm with parent tracking.

``````  def shortestPath(weights: Array[Array[Int]], parents: Array[Array[Int]]) = {
for (k <- weights.indices;
i <- weights.indices;
j <- weights.indices) {
val throughK = weights(i)(k) + weights(k)(j)
if (throughK < weights(i)(j)) {
parents(i)(j) = k
weights(i)(j) = throughK
}
}
}
``````

Parents matrix initially should contain source vertex index in an edge cell if there is an edge between the vertices and -1 otherwise. After function returns, for each edge you will have reference to the parent node in the shortest path tree. And then it's easy to recover actual cycles.

All in all we have the following program to find all minimal cycles

``````  val NO_EDGE = Integer.MAX_VALUE / 2;

def shortestPathWithParentTracking(
weights: Array[Array[Int]],
parents: Array[Array[Int]]) = {
for (k <- weights.indices;
i <- weights.indices;
j <- weights.indices) {
val throughK = weights(i)(k) + weights(k)(j)
if (throughK < weights(i)(j)) {
parents(i)(j) = parents(i)(k)
weights(i)(j) = throughK
}
}
}

def recoverCycles(
cycleNodes: Seq[Int],
parents: Array[Array[Int]]): Set[Seq[Int]] = {
val res = new mutable.HashSet[Seq[Int]]()
for (node <- cycleNodes) {
var cycle = new mutable.ArrayBuffer[Int]()
cycle += node
var other = parents(node)(node)
do {
cycle += other
other = parents(other)(node)
} while(other != node)
res += cycle.sorted
}
res.toSet
}
``````

and a small main method just to test the result

``````  def main(args: Array[String]): Unit = {
val n = 3
val weights = Array(Array(NO_EDGE, 1, NO_EDGE), Array(NO_EDGE, NO_EDGE, 1), Array(1, NO_EDGE, NO_EDGE))
val parents = Array(Array(-1, 1, -1), Array(-1, -1, 2), Array(0, -1, -1))
shortestPathWithParentTracking(weights, parents)
val cycleNodes = parents.indices.filter(i => parents(i)(i) < NO_EDGE)
val cycles: Set[Seq[Int]] = recoverCycles(cycleNodes, parents)
println("The following minimal cycle found:")
cycles.foreach(c => println(c.mkString))
println(s"Total: \${cycles.size} cycle found")
}
``````

and the output is

``````The following minimal cycle found:
012
Total: 1 cycle found
``````

To clarify:

1. Strongly Connected Components will find all subgraphs that have at least one cycle in them, not all possible cycles in the graph. e.g. if you take all strongly connected components and collapse/group/merge each one of them into one node (i.e. a node per component), you'll get a tree with no cycles (a DAG actually). Each component (which is basically a subgraph with at least one cycle in it) can contain many more possible cycles internally, so SCC will NOT find all possible cycles, it will find all possible groups that have at least one cycle, and if you group them, then the graph will not have cycles.

2. to find all simple cycles in a graph, as others mentioned, Johnson's algorithm is a candidate.

I was given this as an interview question once, I suspect this has happened to you and you are coming here for help. Break the problem into three questions and it becomes easier.

1. how do you determine the next valid route
2. how do you determine if a point has been used
3. how do you avoid crossing over the same point again

Problem 1) Use the iterator pattern to provide a way of iterating route results. A good place to put the logic to get the next route is probably the "moveNext" of your iterator. To find a valid route, it depends on your data structure. For me it was a sql table full of valid route possibilities so I had to build a query to get the valid destinations given a source.

Problem 2) Push each node as you find them into a collection as you get them, this means that you can see if you are "doubling back" over a point very easily by interrogating the collection you are building on the fly.

Problem 3) If at any point you see you are doubling back, you can pop things off the collection and "back up". Then from that point try to "move forward" again.

Hack: if you are using Sql Server 2008 there is are some new "hierarchy" things you can use to quickly solve this if you structure your data in a tree.

In the case of undirected graph, a paper recently published (Optimal listing of cycles and st-paths in undirected graphs) offers an asymptotically optimal solution. You can read it here http://arxiv.org/abs/1205.2766 or here http://dl.acm.org/citation.cfm?id=2627951 I know it doesn't answer your question, but since the title of your question doesn't mention direction, it might still be useful for Google search

Start at node X and check for all child nodes (parent and child nodes are equivalent if undirected). Mark those child nodes as being children of X. From any such child node A, mark it's children of being children of A, X', where X' is marked as being 2 steps away.). If you later hit X and mark it as being a child of X'', that means X is in a 3 node cycle. Backtracking to it's parent is easy (as-is, the algorithm has no support for this so you'd find whichever parent has X').

Note: If graph is undirected or has any bidirectional edges, this algorithm gets more complicated, assuming you don't want to traverse the same edge twice for a cycle.

If what you want is to find all elementary circuits in a graph you can use the EC algorithm, by JAMES C. TIERNAN, found on a paper since 1970.

The very original EC algorithm as I managed to implement it in php (hope there are no mistakes is shown below). It can find loops too if there are any. The circuits in this implementation (that tries to clone the original) are the non zero elements. Zero here stands for non-existence (null as we know it).

Apart from that below follows an other implementation that gives the algorithm more independece, this means the nodes can start from anywhere even from negative numbers, e.g -4,-3,-2,.. etc.

In both cases it is required that the nodes are sequential.

You might need to study the original paper, James C. Tiernan Elementary Circuit Algorithm

``````<?php
echo  "<pre><br><br>";

\$G = array(
1=>array(1,2,3),
2=>array(1,2,3),
3=>array(1,2,3)
);

define('N',key(array_slice(\$G, -1, 1, true)));
\$P = array(1=>0,2=>0,3=>0,4=>0,5=>0);
\$H = array(1=>\$P, 2=>\$P, 3=>\$P, 4=>\$P, 5=>\$P );
\$k = 1;
\$P[\$k] = key(\$G);
\$Circ = array();

#[Path Extension]
EC2_Path_Extension:
foreach(\$G[\$P[\$k]] as \$j => \$child ){
if( \$child>\$P[1] and in_array(\$child, \$P)===false and in_array(\$child, \$H[\$P[\$k]])===false ){
\$k++;
\$P[\$k] = \$child;
goto EC2_Path_Extension;
}   }

#[EC3 Circuit Confirmation]
if( in_array(\$P[1], \$G[\$P[\$k]])===true ){//if PATH[1] is not child of PATH[current] then don't have a cycle
\$Circ[] = \$P;
}

#[EC4 Vertex Closure]
if(\$k===1){
}
//afou den ksana theoreitai einai asfales na svisoume
for( \$m=1; \$m<=N; \$m++){//H[P[k], m] <- O, m = 1, 2, . . . , N
if( \$H[\$P[\$k-1]][\$m]===0 ){
\$H[\$P[\$k-1]][\$m]=\$P[\$k];
break(1);
}
}
for( \$m=1; \$m<=N; \$m++ ){//H[P[k], m] <- O, m = 1, 2, . . . , N
\$H[\$P[\$k]][\$m]=0;
}
\$P[\$k]=0;
\$k--;
goto EC2_Path_Extension;

if(\$P[1] === N){
goto EC6_Terminate;
}
\$P[1]++;
\$k=1;
\$H=array(
1=>array(1=>0,2=>0,3=>0,4=>0,5=>0),
2=>array(1=>0,2=>0,3=>0,4=>0,5=>0),
3=>array(1=>0,2=>0,3=>0,4=>0,5=>0),
4=>array(1=>0,2=>0,3=>0,4=>0,5=>0),
5=>array(1=>0,2=>0,3=>0,4=>0,5=>0)
);
goto EC2_Path_Extension;

EC6_Terminate:
print_r(\$Circ);
?>
``````

then this is the other implementation, more independent of the graph, without goto and without array values, instead it uses array keys, the path, the graph and circuits are stored as array keys (use array values if you like, just change the required lines). The example graph start from -4 to show its independence.

``````<?php

\$G = array(
-4=>array(-4=>true,-3=>true,-2=>true),
-3=>array(-4=>true,-3=>true,-2=>true),
-2=>array(-4=>true,-3=>true,-2=>true)
);

\$C = array();

EC(\$G,\$C);
echo "<pre>";
print_r(\$C);
function EC(\$G, &\$C){

\$CNST_not_closed =  false;                          // this flag indicates no closure
\$CNST_closed        = true;                         // this flag indicates closure
// define the state where there is no closures for some node
\$tmp_first_node  =  key(\$G);                        // first node = first key
\$tmp_last_node  =   \$tmp_first_node-1+count(\$G);    // last node  = last  key
\$CNST_closure_reset = array();
for(\$k=\$tmp_first_node; \$k<=\$tmp_last_node; \$k++){
\$CNST_closure_reset[\$k] = \$CNST_not_closed;
}
// define the state where there is no closure for all nodes
for(\$k=\$tmp_first_node; \$k<=\$tmp_last_node; \$k++){
\$H[\$k] = \$CNST_closure_reset;   // Key in the closure arrays represent nodes
}
unset(\$tmp_first_node);
unset(\$tmp_last_node);

# Start algorithm
#[Initial Node Set]
\$P = array();                   // declare at starup, remove the old \$init_node from path on loop
\$P[\$init_node]=true;            // the first key in P is always the new initial node
\$k=\$init_node;                  // update the current node
// On loop H[old_init_node] is not cleared cause is never checked again
do{#Path 1,3,7,4 jump here to extend father 7
do{#Path from 1,3,8,5 became 2,4,8,5,6 jump here to extend child 6
\$new_expansion = false;
foreach( \$G[\$k] as \$child => \$foo ){#Consider each child of 7 or 6
if( \$child>\$init_node and isset(\$P[\$child])===false and \$H[\$k][\$child]===\$CNST_not_closed ){
\$P[\$child]=true;    // add this child to the path
\$k = \$child;        // update the current node
\$new_expansion=true;// set the flag for expanding the child of k
break(1);           // we are done, one child at a time
}   }   }while((\$new_expansion===true));// Do while a new child has been added to the path

# If the first node is child of the last we have a circuit
if( isset(\$G[\$k][\$init_node])===true ){
\$C[] = \$P;  // Leaving this out of closure will catch loops to
}

# Closure
if(\$k>\$init_node){                  //if k>init_node then alwaya count(P)>1, so proceed to closure
\$new_expansion=true;            // \$new_expansion is never true, set true to expand father of k
unset(\$P[\$k]);                  // remove k from path
end(\$P); \$k_father = key(\$P);   // get father of k
\$H[\$k_father][\$k]=\$CNST_closed; // mark k as closed
\$H[\$k] = \$CNST_closure_reset;   // reset k closure
\$k = \$k_father;                 // update k
}   } while(\$new_expansion===true);//if we don't wnter the if block m has the old k\$k_father_old = \$k;
}//foreach initial

}//function

?>
``````

I have analized and documented the EC but unfortunately the documentation is in Greek.

There are two steps (algorithms) involved in finding all cycles in a DAG.

The first step is to use Tarjan's algorithm to find the set of strongly connected components.

1. Start from any arbitrary vertex.
2. DFS from that vertex. For each node x, keep two numbers, dfs_index[x] and dfs_lowval[x]. dfs_index[x] stores when that node is visited, while dfs_lowval[x] = min(dfs_low[k]) where k is all the children of x that is not the directly parent of x in the dfs-spanning tree.
3. All nodes with the same dfs_lowval[x] are in the same strongly connected component.

The second step is to find cycles (paths) within the connected components. My suggestion is to use a modified version of Hierholzer's algorithm.

The idea is:

1. Choose any starting vertex v, and follow a trail of edges from that vertex until you return to v. It is not possible to get stuck at any vertex other than v, because the even degree of all vertices ensures that, when the trail enters another vertex w there must be an unused edge leaving w. The tour formed in this way is a closed tour, but may not cover all the vertices and edges of the initial graph.
2. As long as there exists a vertex v that belongs to the current tour but that has adjacent edges not part of the tour, start another trail from v, following unused edges until you return to v, and join the tour formed in this way to the previous tour.

Here is the link to a Java implementation with a test case:

http://stones333.blogspot.com/2013/12/find-cycles-in-directed-graph-dag.html

• How can a cycle exist in a DAG(Directed Acyclic Graph)? Jan 29, 2016 at 9:47
• This does not find all cycles. Aug 19, 2019 at 10:51

I stumbled over the following algorithm which seems to be more efficient than Johnson's algorithm (at least for larger graphs). I am however not sure about its performance compared to Tarjan's algorithm.
Additionally, I only checked it out for triangles so far. If interested, please see "Arboricity and Subgraph Listing Algorithms" by Norishige Chiba and Takao Nishizeki (http://dx.doi.org/10.1137/0214017)

DFS from the start node s, keep track of the DFS path during traversal, and record the path if you find an edge from node v in the path to s. (v,s) is a back-edge in the DFS tree and thus indicates a cycle containing s.

• Good, but this is not what OP is looking for: find all cycle, likely minimal. Sep 24, 2018 at 23:54

You can try this code (enter the size and the digits number):

``````# include<cstdio>
using namespace std;

int main()
{
int n;
scanf("%d",&n);

int num[1000];
int visited[1000]={0};
int vindex[2000];
for(int i=1;i<=n;i++)
scanf("%d",&num[i]);

int t_visited=0;
int cycles=0;
int start=0, index;

while(t_visited < n)
{
for(int i=1;i<=n;i++)
{
if(visited[i]==0)
{
vindex[start]=i;
visited[i]=1;
t_visited++;
index=start;
break;
}
}
while(true)
{
index++;
vindex[index]=num[vindex[index-1]];

if(vindex[index]==vindex[start])
break;
visited[vindex[index]]=1;
t_visited++;
}
vindex[++index]=0;
start=index+1;
cycles++;
}

printf("%d\n",cycles,vindex[0]);

for(int i=0;i<(n+2*cycles);i++)
{
if(vindex[i]==0)
printf("\n");
else
printf("%d ",vindex[i]);
}
}
``````

DFS c++ version for the pseudo-code in second floor's answer:

``````void findCircleUnit(int start, int v, bool* visited, vector<int>& path) {
if(visited[v]) {
if(v == start) {
for(auto c : path)
cout << c << " ";
cout << endl;
return;
}
else
return;
}
visited[v] = true;
path.push_back(v);
for(auto i : G[v])
findCircleUnit(start, i, visited, path);
visited[v] = false;
path.pop_back();
}
``````
• The question was about removing cycles in directed graphs, but this document is on undirected ones. Apr 29, 2013 at 2:06

The CXXGraph library give a set of algorithms and functions to detect cycles.

For a full algorithm explanation visit the wiki.