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How do I check if a directed graph is acyclic? And how is the algorithm called? I would appreciate a reference.

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Are you looking for an abstract algorithm or a concrete implementation? –  Mark Johnson Feb 24 '09 at 22:26
    
Another case in favor of some way to "fix" wrong answers on SO. –  Sparr Feb 24 '09 at 22:33
2  
So, umm, I am mostly interested in the time needed to find it. So, I just need the abstract algorithm. –  nes1983 Feb 24 '09 at 22:39
    
you must traverse all edges and check all vertices so lower bound is O(|V| + |E|). DFS and BFS are both the same complexity but DFS is easier to code if you have recursion as that manages the stack for you... –  ShuggyCoUk Feb 24 '09 at 22:43
    
DFS is not the same complexity. Consider the graph with nodes { 1 .. N }, and edges in the form { (a, b) | a < b }. That graph is acyclic, and yet DFS would be O(n!) –  FryGuy Feb 25 '09 at 3:04

8 Answers 8

up vote 57 down vote accepted

I would try to sort the graph topologically, and if you can't, then it has cycles.

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How did this have no votes?? It's linear on nodes + edges, far superior to the O(n^2) solutions! –  Loren Pechtel Feb 25 '09 at 2:52
    
I just answered it :) –  FryGuy Feb 25 '09 at 2:59
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In many cases, a DFS (see J.Conrod's answer) may be easier, especially if a DFS needs to be performed anyway. But of course this depends on the context. –  sleske Sep 30 '09 at 15:41

Doing a simple depth-first-search is not good enough to find a cycle. It is possible to visit a node multiple times in a DFS without a cycle existing. Depending on where you start, you also might not visit the entire graph.

You can check for cycles in a connected component of a graph as follows. Find a node which has only outgoing edges. If there is no such node, then there is a cycle. Start a DFS at that node. When traversing each edge, check whether the edge points back to a node already on your stack. This indicates the existence of a cycle. If you find no such edge, there are no cycles in that connected component.

As Rutger Prins points out, if your graph is not connected, you need to repeat the search on each connected component.

As a reference, Tarjan's strongly connected component algorithm is closely related. It will also help you find the cycles, not just report whether they exist.

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BTW: An edge that "points back to a node already on your stack" is often called a "back edge" in the literature, for obvious reasons. And yes, this may be simpler than sorting the graph topologically, especially if you need to do a DFS anyway. –  sleske Sep 30 '09 at 15:40
    
For the graph to be acyclic, you say that each connected component must contain a node with only outgoing edges. Can you recommend an algorithm to find the connected components (as opposed to "strongly" connected components) of a directed graph, for use by your main algorithm? –  kostmo Sep 21 '10 at 4:17
    
@kostmo, if the graph has more than one connected component, then you will not visit all the nodes in your first DFS. Keep track of the nodes you've visited, and repeat the algorithm with unvisited nodes until you reach them all. This is basically how a connected components algorithm works anyway. –  Jay Conrod Sep 22 '10 at 1:07
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While the intent of this answer is correct, the answer is confusing if using a stack-based implementation of DFS: the stack used to implement DFS will not contain the correct elements to test against. It's necessary to add an additional stack to the algorithm used to keep track of the set of ancestor nodes. –  Theodore Murdock Apr 2 '12 at 21:18

Lemma 22.11 on the Book Introduction to Algorithms (Second Edition) states that:

"A directed graph G is acyclic if and only if a depth-first search of G yields no back edges"

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This is basically just an abbreviated version of Jay Conrod's answer :-). –  sleske Sep 30 '09 at 15:52
    
One of the problems from the same book seems to suggest there is a |V| time algorithm. It is answered here: stackoverflow.com/questions/526331/… –  Justin Mar 13 '11 at 21:12

The solution given by ShuggyCoUk is incomplete because it might not check all nodes.


def isDAG(nodes V):
    while there is an unvisited node v in V:
        bool cycleFound = dfs(v)
        if cyclefound:
            return false
    return true

This has timecomplexity O(n+m) or O(n^2)

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mine is indeed incorrect - I deleted it though so your's now seems a little out of context –  ShuggyCoUk Feb 25 '09 at 8:35
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O(n+m) <= O(n+n) = O(2n), O(2n) != O(n^2) –  Artru Dec 13 '11 at 5:35

I know this is an old topic but for future searchers here is a C# implementation I created (no claim that it's most efficient!). This is designed to use a simple integer to identify each node. You can decorate that however you like provided your node object hashes and equals properly.

For Very deep graphs this may have high overhead, as it creates a hashset at each node in depth (they are destroyed over breadth).

You input the node from which you want to search and the path take to that node.

  • For a graph with a single root node you send that node and an empty hashset
  • For a graph having multiple root nodes you wrap this in a foreach over those nodes and pass a new empty hashset for each iteration
  • When checking for cycles below any given node, just pass that node along with an empty hashset

    private bool FindCycle(int node, HashSet<int> path)
    {
    
        if (path.Contains(node))
            return true;
    
        var extendedPath = new HashSet<int>(path) {node};
    
        foreach (var child in GetChildren(node))
        {
            if (FindCycle(child, extendedPath))
                return true;
        }
    
        return false;
    }
    
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Here is a good tutorial to check DAG,

http://www.cs.hmc.edu/~keller/courses/cs60/s98/examples/acyclic/

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Here is my ruby implementation of the peel off leaf node algorithm.

def detect_cycles(initial_graph, number_of_iterations=-1)
    # If we keep peeling off leaf nodes, one of two things will happen
    # A) We will eventually peel off all nodes: The graph is acyclic.
    # B) We will get to a point where there is no leaf, yet the graph is not empty: The graph is cyclic.
    graph = initial_graph
    iteration = 0
    loop do
        iteration += 1
        if number_of_iterations > 0 && iteration > number_of_iterations
            raise "prevented infinite loop"
        end

        if graph.nodes.empty?
            #puts "the graph is without cycles"
            return false
        end

        leaf_nodes = graph.nodes.select { |node| node.leaving_edges.empty? }

        if leaf_nodes.empty?
            #puts "the graph contain cycles"
            return true
        end

        nodes2 = graph.nodes.reject { |node| leaf_nodes.member?(node) }
        edges2 = graph.edges.reject { |edge| leaf_nodes.member?(edge.destination) }
        graph = Graph.new(nodes2, edges2)
    end
    raise "should not happen"
end
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Solution1Kahn algorithm to check cycle. Main idea: Maintain a queue where node with zero in-degree will be added into queue. Then peel off node one by one until queue is empty. Check if any node's in-edges are existed.

Solution2: Tarjan algorithm to check Strong connected component.

Solution3: DFS. Use integer array to tag current status of node: i.e. 0 --means this node hasn't been visited before. -1 -- means this node has been visited, and its children nodes are being visited. 1 -- means this node has been visited, and it's done. So if a node's status is -1 while doing DFS, it means there must be a cycle existed.

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