def test_properties_named_small_graphs(self): G = nx.bull_graph() assert G.number_of_nodes() == 5 assert G.number_of_edges() == 5 assert sorted(d for n, d in G.degree()) == [1, 1, 2, 3, 3] assert nx.diameter(G) == 3 assert nx.radius(G) == 2 G = nx.chvatal_graph() assert G.number_of_nodes() == 12 assert G.number_of_edges() == 24 assert list(d for n, d in G.degree()) == 12 * [4] assert nx.diameter(G) == 2 assert nx.radius(G) == 2 G = nx.cubical_graph() assert G.number_of_nodes() == 8 assert G.number_of_edges() == 12 assert list(d for n, d in G.degree()) == 8 * [3] assert nx.diameter(G) == 3 assert nx.radius(G) == 3 G = nx.desargues_graph() assert G.number_of_nodes() == 20 assert G.number_of_edges() == 30 assert list(d for n, d in G.degree()) == 20 * [3] G = nx.diamond_graph() assert G.number_of_nodes() == 4 assert sorted(d for n, d in G.degree()) == [2, 2, 3, 3] assert nx.diameter(G) == 2 assert nx.radius(G) == 1 G = nx.dodecahedral_graph() assert G.number_of_nodes() == 20 assert G.number_of_edges() == 30 assert list(d for n, d in G.degree()) == 20 * [3] assert nx.diameter(G) == 5 assert nx.radius(G) == 5 G = nx.frucht_graph() assert G.number_of_nodes() == 12 assert G.number_of_edges() == 18 assert list(d for n, d in G.degree()) == 12 * [3] assert nx.diameter(G) == 4 assert nx.radius(G) == 3 G = nx.heawood_graph() assert G.number_of_nodes() == 14 assert G.number_of_edges() == 21 assert list(d for n, d in G.degree()) == 14 * [3] assert nx.diameter(G) == 3 assert nx.radius(G) == 3 G = nx.hoffman_singleton_graph() assert G.number_of_nodes() == 50 assert G.number_of_edges() == 175 assert list(d for n, d in G.degree()) == 50 * [7] assert nx.diameter(G) == 2 assert nx.radius(G) == 2 G = nx.house_graph() assert G.number_of_nodes() == 5 assert G.number_of_edges() == 6 assert sorted(d for n, d in G.degree()) == [2, 2, 2, 3, 3] assert nx.diameter(G) == 2 assert nx.radius(G) == 2 G = nx.house_x_graph() assert G.number_of_nodes() == 5 assert G.number_of_edges() == 8 assert sorted(d for n, d in G.degree()) == [2, 3, 3, 4, 4] assert nx.diameter(G) == 2 assert nx.radius(G) == 1 G = nx.icosahedral_graph() assert G.number_of_nodes() == 12 assert G.number_of_edges() == 30 assert (list( d for n, d in G.degree()) == [5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5]) assert nx.diameter(G) == 3 assert nx.radius(G) == 3 G = nx.krackhardt_kite_graph() assert G.number_of_nodes() == 10 assert G.number_of_edges() == 18 assert (sorted( d for n, d in G.degree()) == [1, 2, 3, 3, 3, 4, 4, 5, 5, 6]) G = nx.moebius_kantor_graph() assert G.number_of_nodes() == 16 assert G.number_of_edges() == 24 assert list(d for n, d in G.degree()) == 16 * [3] assert nx.diameter(G) == 4 G = nx.octahedral_graph() assert G.number_of_nodes() == 6 assert G.number_of_edges() == 12 assert list(d for n, d in G.degree()) == 6 * [4] assert nx.diameter(G) == 2 assert nx.radius(G) == 2 G = nx.pappus_graph() assert G.number_of_nodes() == 18 assert G.number_of_edges() == 27 assert list(d for n, d in G.degree()) == 18 * [3] assert nx.diameter(G) == 4 G = nx.petersen_graph() assert G.number_of_nodes() == 10 assert G.number_of_edges() == 15 assert list(d for n, d in G.degree()) == 10 * [3] assert nx.diameter(G) == 2 assert nx.radius(G) == 2 G = nx.sedgewick_maze_graph() assert G.number_of_nodes() == 8 assert G.number_of_edges() == 10 assert sorted(d for n, d in G.degree()) == [1, 2, 2, 2, 3, 3, 3, 4] G = nx.tetrahedral_graph() assert G.number_of_nodes() == 4 assert G.number_of_edges() == 6 assert list(d for n, d in G.degree()) == [3, 3, 3, 3] assert nx.diameter(G) == 1 assert nx.radius(G) == 1 G = nx.truncated_cube_graph() assert G.number_of_nodes() == 24 assert G.number_of_edges() == 36 assert list(d for n, d in G.degree()) == 24 * [3] G = nx.truncated_tetrahedron_graph() assert G.number_of_nodes() == 12 assert G.number_of_edges() == 18 assert list(d for n, d in G.degree()) == 12 * [3] G = nx.tutte_graph() assert G.number_of_nodes() == 46 assert G.number_of_edges() == 69 assert list(d for n, d in G.degree()) == 46 * [3] # Test create_using with directed or multigraphs on small graphs pytest.raises(nx.NetworkXError, nx.tutte_graph, create_using=nx.DiGraph) MG = nx.tutte_graph(create_using=nx.MultiGraph) assert sorted(MG.edges()) == sorted(G.edges())
'diamond': nx.diamond_graph(), # 2-connected planar 'dodecahedral': nx.dodecahedral_graph(), # 3-connected planar 'frucht': nx.frucht_graph(), # 3-connected planar 'heawood': nx.heawood_graph(), # 3-connected non-planar 'house': nx.house_graph(), # 2-connected planar 'house_x': nx.house_x_graph(), # 2-connected planar 'icosahedral': nx.icosahedral_graph(), # 5-connected planar 'krackhardt': nx.krackhardt_kite_graph(), # 1-connected planar 'moebius': nx.moebius_kantor_graph(), # non-planar 'octahedral': nx.octahedral_graph(), # 4-connected planar 'pappus': nx.pappus_graph(), # 3-connected non-planar 'petersen': nx.petersen_graph(), # 3-connected non-planar 'sedgewick': nx.sedgewick_maze_graph(), # 1-connected planar 'tetrahedral': nx.tetrahedral_graph(), # 3-connected planar 'truncated_cube': nx.truncated_cube_graph(), # 3-conn. planar 'truncated_tetrahedron': nx.truncated_tetrahedron_graph(), # 3-connected planar 'tutte': nx.tutte_graph() } # 3-connected planar for g_name, g in targets.items(): print g_name, is_planar(g) # g = nx.petersen_graph() # g = nx.frucht_graph() # g = nx.krackhardt_kite_graph() # g = nx.icosahedral_graph() # g = nx.tutte_graph() # print is_planarity(g) # from matplotlib import pyplot as plt # nx.draw_networkx(g)
import networkx as nx import matplotlib.pylab as plt from plot_multigraph import plot_multigraph graphs = [ ("bull", nx.bull_graph()), ("chvatal", nx.chvatal_graph()), ("cubical", nx.cubical_graph()), ("desargues", nx.desargues_graph()), ("diamond", nx.diamond_graph()), ("dodecahedral", nx.dodecahedral_graph()), ("frucht", nx.frucht_graph()), ("heawood", nx.heawood_graph()), ("house", nx.house_graph()), ("house_x", nx.house_x_graph()), ("icosahedral", nx.icosahedral_graph()), ("krackhardt_kite", nx.krackhardt_kite_graph()), ("moebius_kantor", nx.moebius_kantor_graph()), ("octahedral", nx.octahedral_graph()), ("pappus", nx.pappus_graph()), ("petersen", nx.petersen_graph()), ("sedgewick_maze", nx.sedgewick_maze_graph()), ("tetrahedral", nx.tetrahedral_graph()), ("truncated_cube", nx.truncated_cube_graph()), ("truncated_tetrahedron", nx.truncated_tetrahedron_graph()), ] plot_multigraph(graphs, 4, 5, node_size=50) plt.savefig('graphs/small.png')
break elif mode == 10: nodes = int(input("Number of nodes: ")) G = nx.path_graph(nodes) pos = nx.circular_layout(G) break elif mode == 11: G = nx.moebius_kantor_graph() pos = nx.spectral_layout(G) break elif mode == 12: G = nx.tutte_graph() pos = nx.spectral_layout(G) break elif mode == 13: G = nx.truncated_tetrahedron_graph() pos = nx.spectral_layout(G) break elif mode == 14: G = nx.truncated_cube_graph() pos = nx.spectral_layout(G) break elif mode == 15: G = nx.sedgewick_maze_graph() pos = nx.spectral_layout(G) break elif mode == 16: G = nx.pappus_graph() pos = nx.spectral_layout(G) break elif mode == 17:
def test_truncated_tetrahedron(self): expected = True actual = is_planar(nx.truncated_tetrahedron_graph()) self.assertEqual(expected, actual)
'bull': nx.bull_graph(), # 1-connected planar 'chvatal': nx.chvatal_graph(), # 4-connected non-planar 'cubical': nx.cubical_graph(), # 3-connected planar 'desargues': nx.desargues_graph(), # 3-connected non-planar 'diamond': nx.diamond_graph(), # 2-connected planar 'dodecahedral': nx.dodecahedral_graph(), # 3-connected planar 'frucht': nx.frucht_graph(), # 3-connected planar 'heawood': nx.heawood_graph(), # 3-connected planar 'house': nx.house_graph(), # 2-connected planar 'house_x': nx.house_x_graph(), # 2-connected planar 'icosahedral': nx.icosahedral_graph(), # 5-connected planar 'krackhardt': nx.krackhardt_kite_graph(), # 1-connected planar 'moebius': nx.moebius_kantor_graph(), # non-planar 'octahedral': nx.octahedral_graph(), # 4-connected planar 'pappus': nx.pappus_graph(), # 3-connected non-planar 'petersen': nx.petersen_graph(), # 3-connected non-planar 'sedgewick': nx.sedgewick_maze_graph(), # 1-connected planar 'tetrahedral': nx.tetrahedral_graph(), # 3-connected planar 'truncated_cube': nx.truncated_cube_graph(), # 3-connected planar 'truncated_tetrahedron': nx.truncated_tetrahedron_graph(), # 3-connected planar 'tutte': nx.tutte_graph() } # 3-connected planar for g_name, g in targets.items(): tree_decomps = [ maximum_cardinality_search(g), min_fill(g), min_degree(g) ] draw(g, tree_decomps, h_names, g_name)
def small_graphs(): print("Make small graph") G = nx.make_small_graph( ["adjacencylist", "C_4", 4, [[2, 4], [1, 3], [2, 4], [1, 3]]]) draw_graph(G) G = nx.make_small_graph( ["adjacencylist", "C_4", 4, [[2, 4], [3], [4], []]]) draw_graph(G) G = nx.make_small_graph( ["edgelist", "C_4", 4, [[1, 2], [3, 4], [2, 3], [4, 1]]]) draw_graph(G) print("LCF graph") G = nx.LCF_graph(6, [3, -3], 3) draw_graph(G) G = nx.LCF_graph(14, [5, -5], 7) draw_graph(G) print("Bull graph") G = nx.bull_graph() draw_graph(G) print("Chvátal graph") G = nx.chvatal_graph() draw_graph(G) print("Cubical graph") G = nx.cubical_graph() draw_graph(G) print("Desargues graph") G = nx.desargues_graph() draw_graph(G) print("Diamond graph") G = nx.diamond_graph() draw_graph(G) print("Dodechaedral graph") G = nx.dodecahedral_graph() draw_graph(G) print("Frucht graph") G = nx.frucht_graph() draw_graph(G) print("Heawood graph") G = nx.heawood_graph() draw_graph(G) print("House graph") G = nx.house_graph() draw_graph(G) print("House X graph") G = nx.house_x_graph() draw_graph(G) print("Icosahedral graph") G = nx.icosahedral_graph() draw_graph(G) print("Krackhardt kite graph") G = nx.krackhardt_kite_graph() draw_graph(G) print("Moebius kantor graph") G = nx.moebius_kantor_graph() draw_graph(G) print("Octahedral graph") G = nx.octahedral_graph() draw_graph(G) print("Pappus graph") G = nx.pappus_graph() draw_graph(G) print("Petersen graph") G = nx.petersen_graph() draw_graph(G) print("Sedgewick maze graph") G = nx.sedgewick_maze_graph() draw_graph(G) print("Tetrahedral graph") G = nx.tetrahedral_graph() draw_graph(G) print("Truncated cube graph") G = nx.truncated_cube_graph() draw_graph(G) print("Truncated tetrahedron graph") G = nx.truncated_tetrahedron_graph() draw_graph(G) print("Tutte graph") G = nx.tutte_graph() draw_graph(G)