MaxCliqueDyn algorithm

Developers:	Insilab (National Institute of Chemistry Slovenia)
Development status:	Active
Written in:	C++
Type:	graph theory, maximum clique algorithm, clique problem
License:	GNU General Public License
Website:	insilab.org/maxclique/

The MaxCliqueDyn algorithm is an algorithm for finding a maximum clique in an undirected graph.

MaxCliqueDyn is based on the MaxClique algorithm, which finds a maximum clique of bounded size. The bound is found using a coloring algorithm. MaxCliqueDyn extends MaxClique to include dynamically varying bounds.

This algorithm was designed by Janez Konc and its description was published in 2007.^[1] In comparison to earlier algorithms, MaxCliqueDyn has an improved coloring algorithm (ColorSort) and applies tighter, more computationally expensive upper bounds on a fraction of the search space.^[1] Both improvements reduce time to find maximum clique. In addition to reducing time, the improved coloring algorithm also reduces the number of steps needed to find a maximum clique.

MaxClique algorithm edit

The MaxClique algorithm^[2] is the basic algorithm from which MaxCliqueDyn is extended. The pseudocode of the algorithm is:

procedure MaxClique(R, C) is
    Q = Ø, Q_max = Ø

    while R ≠ Ø do
        choose a vertex p with a maximum color C(p) from set R
        R := R\{p}
        if |Q| + C(p)>|Q_max| then
            Q := Q ⋃ {p}
            if R ⋂ Γ(p) ≠ Ø then
                obtain a vertex-coloring C' of G(R ⋂ Γ(p))
                MaxClique(R ⋂ Γ(p), C')
            else if |Q|>|Q_max| then Q_max := Q
            Q := Q\{p}
        else
            return
    end while

where Q is a set of vertices of the currently growing clique, Q_max is a set of vertices of the largest clique currently found, R is a set of candidate vertices, and C its corresponding set of color classes. The MaxClique algorithm recursively searches for a maximum clique by adding and removing vertices to and from Q.

Coloring algorithms edit

Approximate coloring algorithm edit

MaxClique uses an approximate coloring algorithm^[2] to obtain set of color classes C. In the approximate coloring algorithm, vertices are colored one by one in the same order as they appear in a set of candidate vertices R, so that if the next vertex p is non-adjacent to all vertices in the same color class, it is added to this class, and if p is adjacent to at least one vertex in every one of existing color classes, it is put into a new color class.

The MaxClique algorithm returns vertices R ordered by their colors. Vertices $v\in R$ with colors $C(v)<{|Q_{max}|}-{|Q|}+1$ are never added to the current clique Q. Therefore, sorting those vertices by color is of no use to MaxClique algorithm.

ColorSort edit

The ColorSort algorithm improves on the approximate coloring algorithm by taking into consideration the above observation. Each vertex is assigned to a color class $C_{k}$ . If $k<{|Q_{max}|}-{|Q|}+1$ , the vertex is moved to the set R (behind the last vertex in R). If $k\geq {|Q_{max}|}-{|Q|}+1$ , then the vertex stays in $C_{k}$ and is not moved to R. At the end, all of the vertices remaining in $C_{k}$ (where $k\geq {|Q_{max}|}-{|Q|}+1$ ) are added to the back of R as they appear in each $C_{k}$ and in increasing order with respect to index $k$ . In the ColorSort algorithm, only these vertices are assigned colors $C(v)=k$ .

The pseudocode of the ColorSort algorithm is:^[1]

procedure ColorSort(R, C) is
    max_no := 1;
    k_min := |Q_max| − |Q| + 1;
    if k_min ≤ 0 then k_min := 1;
    j := 0;
    C₁ := Ø; C₂ := Ø;

    for i := 0 to |R| − 1 do
        p := R[i]; {the i-th vertex in R}
        k := 1;
        while C_k ⋂ Γ(p) ≠ Ø do
            k := k+1;
        if k > max_no then
            max_no := k;
            C_{max_no+1} := Ø;
        end if
        C_k := C_k ⋃ {p};
        if k < k_min then
            R[j] := R[i];
            j := j+1;
        end if
    end for

    C[j−1] := 0;

    for k := k_min to max_no do
        for i := 1 to |C_k| do
            R[j] := C_k[i];
            C[j] := k;
            j := j+1;
        end for
    end for

Example

The graph above can be described as a candidate set of vertices R = {7⁽⁵⁾, 1⁽⁴⁾, 4⁽⁴⁾, 2⁽³⁾, 3⁽³⁾, 6⁽³⁾, 5⁽²⁾, 8⁽²⁾}, and used as input for both the approximate coloring algorithm and the ColorSort algorithm. Either algorithm can be used to construct the following table:

k	C_k
1	7⁽⁵⁾, 5⁽²⁾
2	1⁽⁴⁾, 6⁽³⁾, 8⁽²⁾
3	4⁽⁴⁾, 2⁽³⁾, 3⁽³⁾

The approximate coloring algorithm returns set of vertices R = {7⁽⁵⁾, 5⁽²⁾, 1⁽⁴⁾, 6⁽³⁾, 8⁽²⁾, 4⁽⁴⁾, 2⁽³⁾, 3⁽³⁾} and its corresponding set of color classes C = {1,1,2,2,2,3,3,3}. The ColorSort algorithm returns set of vertices R = {7⁽⁵⁾, 1⁽⁴⁾, 6⁽³⁾, 5⁽²⁾, 8⁽²⁾, 4⁽⁴⁾, 2⁽³⁾, 3⁽³⁾} and its corresponding set of color classes C = {–,–,–,–,–,3,3,3}, where – represents unknown color class with k < 3.

MaxCliqueDyn algorithm edit

The MaxCliqueDyn algorithm extends the MaxClique algorithm by using the ColorSort algorithm instead of approximate coloring algorithm for determining color classes. On each step of MaxClique, the MaxCliqueDyn algorithm also recalculates the degrees of vertices in R regarding the vertex the algorithm is currently on. These vertices are then sorted by decreasing order with respect to their degrees in the graph G(R). Then the ColorSort algorithm considers vertices in R sorted by their degrees in the induced graph G(R) rather than in G. By doing so, the number of steps required to find the maximum clique is reduced to the minimum. Even so, the overall running time of the MaxClique algorithm is not improved, because the computational expense $O(|R|^{2})$ of the determination of the degrees and sorting of vertices in R stays the same.

The pseudocode of the MaxCliqueDyn algorithm is:^[1]

procedure MaxCliqueDyn(R, C, level) is
    S[level] := S[level] + S[level−1] − S_old[level];
    S_old[level] := S[level−1];

    while R ≠ Ø do
        choose a vertex p with maximum C(p) (last vertex) from R;
        R := R\{p};
        if |Q| + C[index of p in R] > |Q_max| then
            Q := Q ⋃ {p};
            if R ⋂ Γ(p) ≠ Ø then
                if S[level]/ALL STEPS < T_limit then
                    calculate the degrees of vertices in G(R ⋂ Γ(p));
                    sort vertices in R ⋂ Γ(p) in a descending order
                    with respect to their degrees;
                end if
                ColorSort(R ⋂ Γ(p), C')
                S[level] := S[level] + 1;
                ALL STEPS := ALL STEPS + 1;
                MaxCliqueDyn(R ⋂ Γ(p), C', level + 1);
            else if |Q| > |Q_max| then Q_max := Q;
            Q := Q\{p};
        else
            return
    end while

Value T_limit can be determined by experimenting on random graphs. In the original article it was determined that algorithm works best for T_limit = 0.025.

References edit

^ ^a ^b ^c ^d Janez Konc; Dusanka Janezic (2007). "An improved branch and bound algorithm for the maximum clique problem" (PDF). MATCH Communications in Mathematical and in Computer Chemistry. 58 (3): 569–590. Source code
^ ^a ^b Tomita, Etsuji; Seki, Tomokazu (2003). "An Efficient Branch-and-Bound Algorithm for Finding a Maximum Clique" (PDF). In Calude, C. S.; Dinneen, M. J.; Vajnovszki, V. (eds.). DMTCS 2003. LNCS. pp. 278–289. See also: E. Tomita; T. Seki (2007). "An Efficient Branch-and-Bound Algorithm for Finding a Maximum Clique". J Glob Optim. 37: 95–111. doi:10.1007/s10898-006-9039-7.

[Konc2007-1] Janez Konc; Dusanka Janezic (2007). "An improved branch and bound algorithm for the maximum clique problem" (PDF). MATCH Communications in Mathematical and in Computer Chemistry. 58 (3): 569–590. Source code

[Tomita2003-2] Tomita, Etsuji; Seki, Tomokazu (2003). "An Efficient Branch-and-Bound Algorithm for Finding a Maximum Clique" (PDF). In Calude, C. S.; Dinneen, M. J.; Vajnovszki, V. (eds.). DMTCS 2003. LNCS. pp. 278–289. See also: E. Tomita; T. Seki (2007). "An Efficient Branch-and-Bound Algorithm for Finding a Maximum Clique". J Glob Optim. 37: 95–111. doi:10.1007/s10898-006-9039-7.

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