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One of the assignments in my algorithms class is to design an exhaustive search algorithm to solve the clique problem. That is, given a graph of size n, the algorithm is supposed to determine if there is a complete sub-graph of size k. I think I've gotten the answer, but I can't help but think it could be improved. Here's what I have:

Version 1

input: A graph represented by an array A[0,...n-1], the size k of the subgraph to find.

output: True if a subgraph exists, False otherwise

Algorithm (in python-like pseudocode):

def clique(A, k):
    P = A x A x A //Cartesian product
    for tuple in P:
        if connected(tuple):
            return true
    return false

def connected(tuple):
    unconnected = tuple
    for vertex in tuple:
        for test_vertex in unconnected:
            if vertex is linked to test_vertex:
                remove test_vertex from unconnected
    if unconnected is empty:
        return true
        return false

Version 2

input: An adjacency matrix of size n by n, and k the size of the subgraph to find

output: All complete subgraphs in A of size k.

Algorithm (this time in functional/Python pseudocode):

//Base case:  return all vertices in a list since each
//one is a 1-clique
def clique(A, 1):
    S = new list
    for i in range(0 to n-1):
        add i to S
    return S

//Get a tuple representing all the cliques where
//k = k - 1, then find any cliques for k
def clique(A,k):
    C = clique(A, k-1)
    S = new list
    for tuple in C:
        for i in range(0 to n-1):
            //make sure the ith vertex is linked to each
            //vertex in tuple
            for j in tuple:
                if A[i,j] != 1:
            //This means that vertex i makes a clique
            if j is the last element:
                newtuple = (i | tuple) //make a new tuple with i added
                add newtuple to S
    //Return the list of k-cliques
    return S

Does anybody have any thoughts, comments, or suggestions? This includes bugs I might have missed as well as ways to make this more readable (I'm not used to using much pseudocode).

Version 3

Fortunately, I talked to my professor before submitting the assignment. When I showed him the pseudo-code I had written, he smiled and told me that I did way too much work. For one, I didn't have to submit pseudo-code; I just had to demonstrate that I understood the problem. And two, he was wanting the brute force solution. So what I turned in looked something like this:

input: A graph G = (V,E), the size of the clique to find k

output: True if a clique does exist, false otherwise


  1. Find the Cartesian Product Vk.
  2. For each tuple in the result, test whether each vertex is connected to every other. If all are connected, return true and exit.
  3. Return false and exit.

UPDATE: Added second version. I think this is getting better although I haven't added any fancy dynamic programming (that I know of).

UPDATE 2: Added some more commenting and documentation to make version 2 more readable. This will probably be the version I turn in today. Thanks for everyone's help! I wish I could accept more than one answer, but I accepted the answer by the person that's helped me out the most. I'll let you guys know what my professor thinks.

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You meant complete subgraph of size k right? Also, I think k isn't used in your pseudocode. –  Zach Scrivena Feb 4 '09 at 2:08
Yup, you're correct on both counts. :-) –  Jason Baker Feb 4 '09 at 2:24
@Jason: There are n vertices right, i.e. A[1,...,n]? –  Zach Scrivena Feb 4 '09 at 2:30
Arghhh... I got it wrong in the above. I meant A[0,...,n-1] though I suppose A[1,...,n] would work as well. –  Jason Baker Feb 4 '09 at 2:37
@Jason: Suggestion: Could you document what the two functions are suppose to do? –  Zach Scrivena Feb 4 '09 at 8:19
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5 Answers

up vote 5 down vote accepted

Some comments:

  • You only need to consider n-choose-k combinations of vertices, not all k-tuples (n^k of them).
  • connected(tuple) doesn't look right. Don't you need to reset unconnected inside the loop?
  • As the others have suggested, there are better ways of brute-forcing this. Consider the following recursive relation: A (k+1)-subgraph is a clique if the first k vertices form a clique and vertex (k+1) is adjacent to each of the first k vertices. You can apply this in two directions:
    • Start with a 1-clique and gradually expand the clique until you get the desired size. For example, if m is the largest vertex in the current clique, try to add vertex {m+1, m+2, ..., n-1} to get a clique that is one vertex larger. (This is similar to a depth-first tree traversal, where the children of a tree node are the vertices larger than the largest vertex in the current clique.)
    • Start with a subgraph of the desired size and check if it is a clique, using the recursive relation. Set up a memoization table to store results along the way.
  • (implementation suggestion) Use an adjacency matrix (0-1) to represent edges in the graph.
  • (initial pruning) Throw away all vertices with degree less than k.
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The algorithm "for each k-tuple of vertices, if it is a clique, then return true" works for sure. However, it's brute force, which is probably not what an algorithms course is searching for. Instead, consider the following:

  1. Every vertex is a 1-clique.
  2. For every 1-clique, every vertex that connects to the vertex in the 1-clique contributes to a 2-clique.
  3. For every 2-clique, every vertex that connects to each vertex in the 2-clique contributes to a 3-clique.
  4. ...
  5. For every (k-1)-clique, every vertex that connects to each vertex in the (k-1) clique contributes to a k-clique.

This idea might lead to a better approach.

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Perhaps try a dynamic programming technique.

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I once implemented an algorithm to find all maximal cliques in a graph, which is a similar problem to yours. The way I did it was based on this paper: http://portal.acm.org/citation.cfm?doid=362342.362367 - it described a backtracking solution which I found very useful as a guide, although I changed quite a lot from that paper. You'd need a subscription to get at that though, but I presume your University would have one available.

One thing about that paper though is I really think they should have named the "not set" the "already considered set" because it's just too confusing otherwise.

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It's amazing what typing things down as a question will show you about what you've just written. This line:

P = A x A x A  //Cartesian product

should be this:

P = A k //Cartesian product

What do you mean by A^k? Are you taking a matrix product? If so, is A the adjacency matrix (you said it was an array of n+1 elements)?

In setbuilder notation, it would look something like this:

P = {(x0, x1, ... xk) | x0 ∈ A and x1 ∈ A ... and xk ∈ A}

It's basically just a Cartesian product of A taken k times. On paper, I wrote it down as k being a superscript of A (I just now figured out how to do that using markdown).

Plus, A is just an array of each individual vertex without regard for adjacency.

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What do you mean by A^k? Are you taking a matrix product? If so, is A the adjacency matrix (you said it was an array of n+1 elements)? –  Zach Scrivena Feb 4 '09 at 2:10
I believe A is an unordered list of nodes, ie 1, 2, 3, ... ,n. A^k gives every possible length-k combination of them. Then he checks whether any given combination is connected, ie, a clique. –  Paul Feb 4 '09 at 2:21
@Zach: A^k is just the Cartesian product A×A×…A (k times), as the comment and the answer says. [It consists of k-tuples (u,v,w,...) where each of the elements is in A.] –  ShreevatsaR Feb 4 '09 at 2:22
Thank you Paul. You said it better than I could. :-) I'll take this as a prompt that I might need to reconsider a more readable way of doing this. –  Jason Baker Feb 4 '09 at 2:22
Ah I see. So the edges in the graph are not explicit in your code right? –  Zach Scrivena Feb 4 '09 at 2:25
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