Finding all cycles in undirected graphs

I need a working algorithm for finding all simple cycles in an undirected graph. I know the cost can be exponential and the problem is NP-complete, but I am going to use it in a small graph (up to 20-30 vertices) and the cycles are small in number.

After a long research (mainly here) I still don't have a working approach. Here is a summary of my search:

Finding all cycles in an undirected graph

Cycles in an Undirected Graph -> detects only whether there is a cycle or not

Finding polygons within an undirected Graph -> very nice description, but no solution

Finding all cycles in graph -> finds cycles only in directed graphs

Detect cycles in undirected graph using boost graph library

The only answer I found, which approaches my problem, is this one:

Find all cycles in graph, redux

It seems that finding a basic set of cycles and XOR-ing them could do the trick. Finding a basic set of cycles is easy, but I don't understand how to combine them in order to obtain all cycles in the graph...

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5 Answers

The Matlab version missed something, function findNewCycles(path) should be:

function findNewCycles(path)

``````global graph cycles numCycles;
startNode = path(1);
nextNode = nan;
sub = [];

% visit each edge and each node of each edge
for i = 1:size(graph,1)
node1 = graph(i,1);
node2 = graph(i,2);
if (node1 == startNode) || (node2==startNode) %% this if is required
if node1 == startNode
nextNode = node2;
elseif node2 == startNode
nextNode = node1;
end
if ~(visited(nextNode, path))
% neighbor node not on path yet
sub = nextNode;
sub = [sub path];
% explore extended path
findNewCycles(sub);
elseif size(path,2) > 2 && nextNode == path(end)
% cycle found
p = rotate_to_smallest(path);
inv = invert(p);
if isNew(p) && isNew(inv)
numCycles = numCycles + 1;
cycles{numCycles} = p;
end
end
end
end
``````
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Here's just a very lame MATLAB version of this algorithm adapted from the python code above, for anyone who might need it as well.

``````function cycleList = searchCycles(edgeMap)

tic
global graph cycles numCycles;
graph = edgeMap;
numCycles = 0;
cycles = {};
for i = 1:size(graph,1)
for j = 1:2
findNewCycles(graph(i,j))
end
end
% print out all found cycles
for i = 1:size(cycles,2)
cycles{i}
end
% return the result
cycleList = cycles;
toc

function findNewCycles(path)

global graph cycles numCycles;
startNode = path(1);
nextNode = nan;
sub = [];

% visit each edge and each node of each edge
for i = 1:size(graph,1)
node1 = graph(i,1);
node2 = graph(i,2);
if node1 == startNode
nextNode = node2;
elseif node2 == startNode
nextNode = node1;
end
if ~(visited(nextNode, path))
% neighbor node not on path yet
sub = nextNode;
sub = [sub path];
% explore extended path
findNewCycles(sub);
elseif size(path,2) > 2 && nextNode == path(end)
% cycle found
p = rotate_to_smallest(path);
inv = invert(p);
if isNew(p) && isNew(inv)
numCycles = numCycles + 1;
cycles{numCycles} = p;
end
end
end

function inv = invert(path)
inv = rotate_to_smallest(path(end:-1:1));

% rotate cycle path such that it begins with the smallest node
function new_path = rotate_to_smallest(path)
[~,n] = min(path);
new_path = [path(n:end), path(1:n-1)];

function result = isNew(path)
global cycles
result = 1;
for i = 1:size(cycles,2)
if size(path,2) == size(cycles{i},2) && all(path == cycles{i})
result = 0;
break;
end
end

function result = visited(node,path)
result = 0;
if isnan(node) && any(isnan(path))
result = 1;
return
end
for i = 1:size(path,2)
if node == path(i)
result = 1;
break
end
end
``````
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For an undirected graph the standard approach is to look for a so called cycle base : a set of simple cycles from which one can generate through combinations all other cycles. These are not necessarily all simple cycles in the graph. Consider for example the following graph:

``````    A
/   \
B ----- C
\   /
D
``````

There are 3 simple cycles here : A-B-C-A, B-C-D-B and A-B-D-C-A. You can however take each 2 of these as a basis and obtain the 3d as a combination of the 2. This is a substantial difference from directed graphs where one can not combine so freely cycles due to the need to observe edge direction.

The standard baseline algorithm for finding a cycle base for an undirected graph is this : Build a spanning tree and then for each edge which is not part of the tree build a cycle from that edge and some edges on the tree. Such cycle must exist because otherwise the edge would be part of the tree.

For the sample graph above one spanning tree is e.g. this:

``````    A
/   \
B      C
\
D
``````

The 2 edges not in the tree are B-C and C-D. And the correspondent simple cycles are A-B-C-A and A-B-D-C-A.

You can also build the following spanning tree:

``````    A
/
B ----- C
\
D
``````

And then the simple cycles you get are A-B-C-A and B-C-D-B.

The baseline algorithm can be refined in different ways. To the best of my knowledge the best refinement belongs to Paton (K. Paton, An algorithm for finding a fundamental set of cycles for an undirected linear graph, Comm. ACM 12 (1969), pp. 514-518.). An open source implementation in Java is available here : http://code.google.com/p/niographs/ .

I should have mentioned how you combine simple cycles from the cycle base to form new simple cycles. You start off by listing in any (but fixed hereafter) order all edges of the graph. Then you represent cycles by sequences of zeros and ones by placing ones in the positions of edges which belong to the cycle and zeros in the positions of edges which are not part of the cycle. Then you do bitwise exclusive OR (XOR) of the sequences. The reason you do XOR is that you want to exclude edges which belong to both cycles and thus make the combined cycle non-simple. You need to check also that the 2 cycles have SOME common edges by checking that the bitwise AND of the sequences is not all zeros. Otherwise the result of XOR will be 2 disjoint cycles rather than a new simple cycle.

Here is an example for the sample graph above:

We start by listing the edges : ((AB), (AC), (BC), (BD), (CD)). Then the simple cycles A-B-C-A, B-D-C-B and A-B-D-C-A are represented as (1, 1, 1, 0, 0), (0, 0, 1, 1, 1) and (1, 1, 0, 1, 1). Now we can for example XOR A-B-C-A with B-D-C-B and the result is (1, 1, 0, 1, 1) which is exactly A-B-D-C-A. Or we can XOR A-B-C-A and A-B-D-C-A with the result being (0, 0, 1, 1, 1). Which is exactly B-D-C-B.

Given a cycle base you can discover all simple cycles by examining all possible combinations of 2 or more distinct base cycles. The procedure is described in more detail here : http://dspace.mit.edu/bitstream/handle/1721.1/68106/FTL_R_1982_07.pdf on page 14.

For the sake of completeness, I would notice that it seems possible (and inefficient) to use algorithms for finding all simple cycles of a directed graph. Every edge of the undirected graph can be replaced by 2 directed edges going in opposite directions. Then algorithms for directed graphs should work. There will be 1 "false" 2-node cycle for every edge of the undirected graph which will have to be ignored and there will be a clockwise and a counterclockwise version of every simple cycle of the undirected graph. Open source implementation in Java of algorithms for finding all cycles in a directed graph can be found at the link I already quoted.

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The following is a demo implementation in C# (and Java, see end of answer) based on depth first search.

An outer loop scans all nodes of the graph and starts a search from every node. Node neighbours (according to the list of edges) are added to the cycle path. Recursion ends if no more non-visited neighbours can be added. A new cycle is found if the path is longer than two nodes and the next neighbour is the start of the path. To avoid duplicate cycles, the cycles are normalized by rotating the smallest node to the start. Cycles in inverted ordering are also taken into account.

This is just a naive implementation. The classical paper is: Donald B. Johnson. Finding all the elementary circuits of a directed graph. SIAM J. Comput., 4(1):77–84, 1975.

A recent survey of modern algorithms can be found here

``````using System;
using System.Collections.Generic;

namespace akCyclesInUndirectedGraphs
{
class Program
{
//  Graph modelled as list of edges
static int[,] graph =
{
{1, 2}, {1, 3}, {1, 4}, {2, 3},
{3, 4}, {2, 6}, {4, 6}, {7, 8},
{8, 9}, {9, 7}
};

static List<int[]> cycles = new List<int[]>();

static void Main(string[] args)
{
for (int i = 0; i < graph.GetLength(0); i++)
for (int j = 0; j < graph.GetLength(1); j++)
{
findNewCycles(new int[] {graph[i, j]});
}

foreach (int[] cy in cycles)
{
string s = "" + cy[0];

for (int i = 1; i < cy.Length; i++)
s += "," + cy[i];

Console.WriteLine(s);
}
}

static void findNewCycles(int[] path)
{
int n = path[0];
int x;
int[] sub = new int[path.Length + 1];

for (int i = 0; i < graph.GetLength(0); i++)
for (int y = 0; y <= 1; y++)
if (graph[i, y] == n)
//  edge referes to our current node
{
x = graph[i, (y + 1) % 2];
if (!visited(x, path))
//  neighbor node not on path yet
{
sub[0] = x;
Array.Copy(path, 0, sub, 1, path.Length);
//  explore extended path
findNewCycles(sub);
}
else if ((path.Length > 2) && (x == path[path.Length - 1]))
//  cycle found
{
int[] p = normalize(path);
int[] inv = invert(p);
if (isNew(p) && isNew(inv))
cycles.Add(p);
}
}
}

static bool equals(int[] a, int[] b)
{
bool ret = (a[0] == b[0]) && (a.Length == b.Length);

for (int i = 1; ret && (i < a.Length); i++)
if (a[i] != b[i])
{
ret = false;
}

return ret;
}

static int[] invert(int[] path)
{
int[] p = new int[path.Length];

for (int i = 0; i < path.Length; i++)
p[i] = path[path.Length - 1 - i];

return normalize(p);
}

//  rotate cycle path such that it begins with the smallest node
static int[] normalize(int[] path)
{
int[] p = new int[path.Length];
int x = smallest(path);
int n;

Array.Copy(path, 0, p, 0, path.Length);

while (p[0] != x)
{
n = p[0];
Array.Copy(p, 1, p, 0, p.Length - 1);
p[p.Length - 1] = n;
}

return p;
}

static bool isNew(int[] path)
{
bool ret = true;

foreach(int[] p in cycles)
if (equals(p, path))
{
ret = false;
break;
}

return ret;
}

static int smallest(int[] path)
{
int min = path[0];

foreach (int p in path)
if (p < min)
min = p;

return min;
}

static bool visited(int n, int[] path)
{
bool ret = false;

foreach (int p in path)
if (p == n)
{
ret = true;
break;
}

return ret;
}
}
}
``````

The cycles for the demo graph:

``````1,3,2
1,4,3,2
1,4,6,2
1,3,4,6,2
1,4,6,2,3
1,4,3
2,6,4,3
7,9,8
``````

The algorithm coded in Java:

``````import java.util.ArrayList;
import java.util.List;

public class GraphCycleFinder {

//  Graph modeled as list of edges
static int[][] graph =
{
{1, 2}, {1, 3}, {1, 4}, {2, 3},
{3, 4}, {2, 6}, {4, 6}, {7, 8},
{8, 9}, {9, 7}
};

static List<int[]> cycles = new ArrayList<int[]>();

/**
* @param args
*/
public static void main(String[] args) {

for (int i = 0; i < graph.length; i++)
for (int j = 0; j < graph[i].length; j++)
{
findNewCycles(new int[] {graph[i][j]});
}

for (int[] cy : cycles)
{
String s = "" + cy[0];

for (int i = 1; i < cy.length; i++)
{
s += "," + cy[i];
}

o(s);
}

}

static void findNewCycles(int[] path)
{
int n = path[0];
int x;
int[] sub = new int[path.length + 1];

for (int i = 0; i < graph.length; i++)
for (int y = 0; y <= 1; y++)
if (graph[i][y] == n)
//  edge refers to our current node
{
x = graph[i][(y + 1) % 2];
if (!visited(x, path))
//  neighbor node not on path yet
{
sub[0] = x;
System.arraycopy(path, 0, sub, 1, path.length);
//  explore extended path
findNewCycles(sub);
}
else if ((path.length > 2) && (x == path[path.length - 1]))
//  cycle found
{
int[] p = normalize(path);
int[] inv = invert(p);
if (isNew(p) && isNew(inv))
{
cycles.add(p);
}
}
}
}

//  check of both arrays have same lengths and contents
static Boolean equals(int[] a, int[] b)
{
Boolean ret = (a[0] == b[0]) && (a.length == b.length);

for (int i = 1; ret && (i < a.length); i++)
{
if (a[i] != b[i])
{
ret = false;
}
}

return ret;
}

//  create a path array with reversed order
static int[] invert(int[] path)
{
int[] p = new int[path.length];

for (int i = 0; i < path.length; i++)
{
p[i] = path[path.length - 1 - i];
}

return normalize(p);
}

//  rotate cycle path such that it begins with the smallest node
static int[] normalize(int[] path)
{
int[] p = new int[path.length];
int x = smallest(path);
int n;

System.arraycopy(path, 0, p, 0, path.length);

while (p[0] != x)
{
n = p[0];
System.arraycopy(p, 1, p, 0, p.length - 1);
p[p.length - 1] = n;
}

return p;
}

//  compare path against known cycles
//  return true, iff path is not a known cycle
static Boolean isNew(int[] path)
{
Boolean ret = true;

for(int[] p : cycles)
{
if (equals(p, path))
{
ret = false;
break;
}
}

return ret;
}

static void o(String s)
{
System.out.println(s);
}

//  return the int of the array which is the smallest
static int smallest(int[] path)
{
int min = path[0];

for (int p : path)
{
if (p < min)
{
min = p;
}
}

return min;
}

//  check if vertex n is contained in path
static Boolean visited(int n, int[] path)
{
Boolean ret = false;

for (int p : path)
{
if (p == n)
{
ret = true;
break;
}
}

return ret;
}

}
``````
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Axel, I've translated your code to python. About 1/4th the lines of code and clearer to read.

``````graph = [[1, 2], [1, 3], [1, 4], [2, 3], [3, 4], [2, 6], [4, 6], [8, 7], [8, 9], [9, 7]]
cycles = []

def main():
global graph
global cycles
for edge in graph:
for node in edge:
findNewCycles([node])
for cy in cycles:
path = [str(node) for node in cy]
s = ",".join(path)
print(s)

def findNewCycles(path):
start_node = path[0]
next_node= None
sub = []

#visit each edge and each node of each edge
for edge in graph:
node1, node2 = edge
if start_node in edge:
if node1 == start_node:
next_node = node2
else:
next_node = node1
if not visited(next_node, path):
# neighbor node not on path yet
sub = [next_node]
sub.extend(path)
# explore extended path
findNewCycles(sub);
elif len(path) > 2  and next_node == path[-1]:
# cycle found
p = rotate_to_smallest(path);
inv = invert(p)
if isNew(p) and isNew(inv):
cycles.append(p)

def invert(path):
return rotate_to_smallest(path[::-1])

#  rotate cycle path such that it begins with the smallest node
def rotate_to_smallest(path):
n = path.index(min(path))
return path[n:]+path[:n]

def isNew(path):
return not path in cycles

def visited(node, path):
return node in path

main()
``````
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Yes, that's pretty compact and comprehensible. –  Axel Kemper Jun 23 '13 at 11:19
Thanks man, that was really useful! –  Sebastialonso Jun 17 at 0:06
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