// BronKerbosch returns the set of maximal cliques of the undirected graph g. func BronKerbosch(g graph.Undirected) [][]graph.Node { nodes := g.Nodes() // The algorithm used here is essentially BronKerbosch3 as described at // http://en.wikipedia.org/w/index.php?title=Bron%E2%80%93Kerbosch_algorithm&oldid=656805858 p := make(internal.Set, len(nodes)) for _, n := range nodes { p.Add(n) } x := make(internal.Set) var bk bronKerbosch order, _ := VertexOrdering(g) for _, v := range order { neighbours := g.From(v) nv := make(internal.Set, len(neighbours)) for _, n := range neighbours { nv.Add(n) } bk.maximalCliquePivot(g, []graph.Node{v}, make(internal.Set).Intersect(p, nv), make(internal.Set).Intersect(x, nv)) p.Remove(v) x.Add(v) } return bk }
func benchmarkWalkAllDepthFirst(b *testing.B, g graph.Undirected) { n := len(g.Nodes()) b.ResetTimer() var dft DepthFirst for i := 0; i < b.N; i++ { dft.WalkAll(g, nil, nil, nil) } if dft.visited.Len() != n { b.Fatalf("unexpected number of nodes visited: want: %d got %d", n, dft.visited.Len()) } }
// WalkAll calls Walk for each unvisited node of the graph g using edges independent // of their direction. The functions before and after are called prior to commencing // and after completing each walk if they are non-nil respectively. The function // during is called on each node as it is traversed. func (b *BreadthFirst) WalkAll(g graph.Undirected, before, after func(), during func(graph.Node)) { b.Reset() for _, from := range g.Nodes() { if b.Visited(from) { continue } if before != nil { before() } b.Walk(g, from, func(n graph.Node, _ int) bool { if during != nil { during(n) } return false }) if after != nil { after() } } }
// Q returns the modularity Q score of the graph g subdivided into the // given communities at the given resolution. If communities is nil, the // unclustered modularity score is returned. The resolution parameter // is γ as defined in Reichardt and Bornholdt doi:10.1103/PhysRevE.74.016110. // Q will panic if g has any edge with negative edge weight. // // graph.Undirect may be used as a shim to allow calculation of Q for // directed graphs. func Q(g graph.Undirected, communities [][]graph.Node, resolution float64) float64 { nodes := g.Nodes() weight := weightFuncFor(g) // Calculate the total edge weight of the graph // and the table of penetrating edge weight sums. var m2 float64 k := make(map[int]float64, len(nodes)) for _, u := range nodes { w := weight(u, u) for _, v := range g.From(u) { w += weight(u, v) } m2 += w k[u.ID()] = w } if communities == nil { var q float64 for _, u := range nodes { kU := k[u.ID()] q += weight(u, u) - resolution*kU*kU/m2 } return q / m2 } // Iterate over the communities, calculating // the non-self edge weights for the upper // triangle and adjust the diagonal. var q float64 for _, c := range communities { for i, u := range c { kU := k[u.ID()] q += weight(u, u) - resolution*kU*kU/m2 for _, v := range c[i+1:] { q += 2 * (weight(u, v) - resolution*kU*k[v.ID()]/m2) } } } return q / m2 }
// VertexOrdering returns the vertex ordering and the k-cores of // the undirected graph g. func VertexOrdering(g graph.Undirected) (order []graph.Node, cores [][]graph.Node) { nodes := g.Nodes() // The algorithm used here is essentially as described at // http://en.wikipedia.org/w/index.php?title=Degeneracy_%28graph_theory%29&oldid=640308710 // Initialize an output list L. var l []graph.Node // Compute a number d_v for each vertex v in G, // the number of neighbors of v that are not already in L. // Initially, these numbers are just the degrees of the vertices. dv := make(map[int]int, len(nodes)) var ( maxDegree int neighbours = make(map[int][]graph.Node) ) for _, n := range nodes { adj := g.From(n) neighbours[n.ID()] = adj dv[n.ID()] = len(adj) if len(adj) > maxDegree { maxDegree = len(adj) } } // Initialize an array D such that D[i] contains a list of the // vertices v that are not already in L for which d_v = i. d := make([][]graph.Node, maxDegree+1) for _, n := range nodes { deg := dv[n.ID()] d[deg] = append(d[deg], n) } // Initialize k to 0. k := 0 // Repeat n times: s := []int{0} for _ = range nodes { // TODO(kortschak): Remove blank assignment when go1.3.3 is no longer supported. // Scan the array cells D[0], D[1], ... until // finding an i for which D[i] is nonempty. var ( i int di []graph.Node ) for i, di = range d { if len(di) != 0 { break } } // Set k to max(k,i). if i > k { k = i s = append(s, make([]int, k-len(s)+1)...) } // Select a vertex v from D[i]. Add v to the // beginning of L and remove it from D[i]. var v graph.Node v, d[i] = di[len(di)-1], di[:len(di)-1] l = append(l, v) s[k]++ delete(dv, v.ID()) // For each neighbor w of v not already in L, // subtract one from d_w and move w to the // cell of D corresponding to the new value of d_w. for _, w := range neighbours[v.ID()] { dw, ok := dv[w.ID()] if !ok { continue } for i, n := range d[dw] { if n.ID() == w.ID() { d[dw][i], d[dw] = d[dw][len(d[dw])-1], d[dw][:len(d[dw])-1] dw-- d[dw] = append(d[dw], w) break } } dv[w.ID()] = dw } } for i, j := 0, len(l)-1; i < j; i, j = i+1, j-1 { l[i], l[j] = l[j], l[i] } cores = make([][]graph.Node, len(s)) offset := len(l) for i, n := range s { cores[i] = l[offset-n : offset] offset -= n } return l, cores }
// reduce returns a reduced graph constructed from g divided // into the given communities. The communities value is mutated // by the call to reduce. If communities is nil and g is a // ReducedUndirected, it is returned unaltered. func reduce(g graph.Undirected, communities [][]graph.Node) *ReducedUndirected { if communities == nil { if r, ok := g.(*ReducedUndirected); ok { return r } nodes := g.Nodes() // TODO(kortschak) This sort is necessary really only // for testing. In practice we would not be using the // community provided by the user for a Q calculation. // Probably we should use a function to map the // communities in the test sets to the remapped order. sort.Sort(ordered.ByID(nodes)) communities = make([][]graph.Node, len(nodes)) for i := range nodes { communities[i] = []graph.Node{node(i)} } weight := weightFuncFor(g) r := ReducedUndirected{ nodes: make([]community, len(nodes)), edges: make([][]int, len(nodes)), weights: make(map[[2]int]float64), communities: communities, } communityOf := make(map[int]int, len(nodes)) for i, n := range nodes { r.nodes[i] = community{id: i, nodes: []graph.Node{n}} communityOf[n.ID()] = i } for _, u := range nodes { var out []int uid := communityOf[u.ID()] for _, v := range g.From(u) { vid := communityOf[v.ID()] if vid != uid { out = append(out, vid) } if uid < vid { // Only store the weight once. r.weights[[2]int{uid, vid}] = weight(u, v) } } r.edges[uid] = out } return &r } // Remove zero length communities destructively. var commNodes int for i := 0; i < len(communities); { comm := communities[i] if len(comm) == 0 { communities[i] = communities[len(communities)-1] communities[len(communities)-1] = nil communities = communities[:len(communities)-1] } else { commNodes += len(comm) i++ } } r := ReducedUndirected{ nodes: make([]community, len(communities)), edges: make([][]int, len(communities)), weights: make(map[[2]int]float64), } r.communities = make([][]graph.Node, len(communities)) for i := range r.communities { r.communities[i] = []graph.Node{node(i)} } if g, ok := g.(*ReducedUndirected); ok { // Make sure we retain the truncated // community structure. g.communities = communities r.parent = g } weight := weightFuncFor(g) communityOf := make(map[int]int, commNodes) for i, comm := range communities { r.nodes[i] = community{id: i, nodes: comm} for _, n := range comm { communityOf[n.ID()] = i } } for uid, comm := range communities { var out []int for i, u := range comm { r.nodes[uid].weight += weight(u, u) for _, v := range comm[i+1:] { r.nodes[uid].weight += 2 * weight(u, v) } for _, v := range g.From(u) { vid := communityOf[v.ID()] found := false for _, e := range out { if e == vid { found = true break } } if !found && vid != uid { out = append(out, vid) } if uid < vid { // Only store the weight once. r.weights[[2]int{uid, vid}] += weight(u, v) } } } r.edges[uid] = out } return &r }