""" Algorithms for asteroidal triples and asteroidal numbers in graphs. An asteroidal triple in a graph G is a set of three non-adjacent vertices u, v and w such that there exist a path between any two of them that avoids closed neighborhood of the third. More formally, v_j, v_k belongs to the same connected component of G - N[v_i], where N[v_i] denotes the closed neighborhood of v_i. A graph which does not contain any asteroidal triples is called an AT-free graph. The class of AT-free graphs is a graph class for which many NP-complete problems are solvable in polynomial time. Amongst them, independent set and coloring. """ import networkx as nx from networkx.utils import not_implemented_for __all__ = ["is_at_free", "find_asteroidal_triple"] @not_implemented_for("directed") @not_implemented_for("multigraph") def find_asteroidal_triple(G): r"""Find an asteroidal triple in the given graph. An asteroidal triple is a triple of non-adjacent vertices such that there exists a path between any two of them which avoids the closed neighborhood of the third. It checks all independent triples of vertices and whether they are an asteroidal triple or not. This is done with the help of a data structure called a component structure. A component structure encodes information about which vertices belongs to the same connected component when the closed neighborhood of a given vertex is removed from the graph. The algorithm used to check is the trivial one, outlined in [1]_, which has a runtime of :math:`O(|V||\overline{E} + |V||E|)`, where the second term is the creation of the component structure. Parameters ---------- G : NetworkX Graph The graph to check whether is AT-free or not Returns ------- list or None An asteroidal triple is returned as a list of nodes. If no asteroidal triple exists, i.e. the graph is AT-free, then None is returned. The returned value depends on the certificate parameter. The default option is a bool which is True if the graph is AT-free, i.e. the given graph contains no asteroidal triples, and False otherwise, i.e. if the graph contains at least one asteroidal triple. Notes ----- The component structure and the algorithm is described in [1]_. The current implementation implements the trivial algorithm for simple graphs. References ---------- .. [1] Ekkehard Köhler, "Recognizing Graphs without asteroidal triples", Journal of Discrete Algorithms 2, pages 439-452, 2004. https://www.sciencedirect.com/science/article/pii/S157086670400019X """ V = set(G.nodes) if len(V) < 6: # An asteroidal triple cannot exist in a graph with 5 or less vertices. return None component_structure = create_component_structure(G) E_complement = set(nx.complement(G).edges) for e in E_complement: u = e[0] v = e[1] u_neighborhood = set(G[u]).union([u]) v_neighborhood = set(G[v]).union([v]) union_of_neighborhoods = u_neighborhood.union(v_neighborhood) for w in V - union_of_neighborhoods: # Check for each pair of vertices whether they belong to the # same connected component when the closed neighborhood of the # third is removed. if ( component_structure[u][v] == component_structure[u][w] and component_structure[v][u] == component_structure[v][w] and component_structure[w][u] == component_structure[w][v] ): return [u, v, w] return None @not_implemented_for("directed") @not_implemented_for("multigraph") def is_at_free(G): """Check if a graph is AT-free. The method uses the `find_asteroidal_triple` method to recognize an AT-free graph. If no asteroidal triple is found the graph is AT-free and True is returned. If at least one asteroidal triple is found the graph is not AT-free and False is returned. Parameters ---------- G : NetworkX Graph The graph to check whether is AT-free or not. Returns ------- bool True if G is AT-free and False otherwise. Examples -------- >>> G = nx.Graph([(0, 1), (0, 2), (1, 2), (1, 3), (1, 4), (4, 5)]) >>> nx.is_at_free(G) True >>> G = nx.cycle_graph(6) >>> nx.is_at_free(G) False """ return find_asteroidal_triple(G) is None @not_implemented_for("directed") @not_implemented_for("multigraph") def create_component_structure(G): r"""Create component structure for G. A *component structure* is an `nxn` array, denoted `c`, where `n` is the number of vertices, where each row and column corresponds to a vertex. .. math:: c_{uv} = \begin{cases} 0, if v \in N[u] \\ k, if v \in component k of G \setminus N[u] \end{cases} Where `k` is an arbitrary label for each component. The structure is used to simplify the detection of asteroidal triples. Parameters ---------- G : NetworkX Graph Undirected, simple graph. Returns ------- component_structure : dictionary A dictionary of dictionaries, keyed by pairs of vertices. """ V = set(G.nodes) component_structure = {} for v in V: label = 0 closed_neighborhood = set(G[v]).union({v}) row_dict = {} for u in closed_neighborhood: row_dict[u] = 0 G_reduced = G.subgraph(set(G.nodes) - closed_neighborhood) for cc in nx.connected_components(G_reduced): label += 1 for u in cc: row_dict[u] = label component_structure[v] = row_dict return component_structure