Exemplo n.º 1
0
    def test_graph(self):
        g = nx.cycle_graph(10)
        G = nx.Graph()
        G.add_nodes_from(g)
        G.add_weighted_edges_from((u, v, u) for u, v in g.edges())

        # Dict of dicts
        dod = to_dict_of_dicts(G)
        GG = from_dict_of_dicts(dod, create_using=nx.Graph())
        assert_nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GG.edges()))
        GW = to_networkx_graph(dod, create_using=nx.Graph())
        assert_nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GW.edges()))
        GI = nx.Graph(dod)
        assert_equal(sorted(G.nodes()), sorted(GI.nodes()))
        assert_equal(sorted(G.edges()), sorted(GI.edges()))

        # Dict of lists
        dol = to_dict_of_lists(G)
        GG = from_dict_of_lists(dol, create_using=nx.Graph())
        # dict of lists throws away edge data so set it to none
        enone = [(u, v, {}) for (u, v, d) in G.edges(data=True)]
        assert_nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
        assert_edges_equal(enone, sorted(GG.edges(data=True)))
        GW = to_networkx_graph(dol, create_using=nx.Graph())
        assert_nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
        assert_edges_equal(enone, sorted(GW.edges(data=True)))
        GI = nx.Graph(dol)
        assert_nodes_equal(sorted(G.nodes()), sorted(GI.nodes()))
        assert_edges_equal(enone, sorted(GI.edges(data=True)))
Exemplo n.º 2
0
    def test_graph(self):
        g = nx.cycle_graph(10)
        G = nx.Graph()
        G.add_nodes_from(g)
        G.add_weighted_edges_from((u, v, u) for u, v in g.edges())

        # Dict of dicts
        dod = to_dict_of_dicts(G)
        GG = from_dict_of_dicts(dod, create_using=nx.Graph)
        assert_nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GG.edges()))
        GW = to_networkx_graph(dod, create_using=nx.Graph)
        assert_nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GW.edges()))
        GI = nx.Graph(dod)
        assert sorted(G.nodes()) == sorted(GI.nodes())
        assert sorted(G.edges()) == sorted(GI.edges())

        # Dict of lists
        dol = to_dict_of_lists(G)
        GG = from_dict_of_lists(dol, create_using=nx.Graph)
        # dict of lists throws away edge data so set it to none
        enone = [(u, v, {}) for (u, v, d) in G.edges(data=True)]
        assert_nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
        assert_edges_equal(enone, sorted(GG.edges(data=True)))
        GW = to_networkx_graph(dol, create_using=nx.Graph)
        assert_nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
        assert_edges_equal(enone, sorted(GW.edges(data=True)))
        GI = nx.Graph(dol)
        assert_nodes_equal(sorted(G.nodes()), sorted(GI.nodes()))
        assert_edges_equal(enone, sorted(GI.edges(data=True)))
Exemplo n.º 3
0
    def test_with_multiedges_self_loops(self):
        G = cycle_graph(10)
        XG = nx.Graph()
        XG.add_nodes_from(G)
        XG.add_weighted_edges_from((u, v, u) for u, v in G.edges())
        XGM = nx.MultiGraph()
        XGM.add_nodes_from(G)
        XGM.add_weighted_edges_from((u, v, u) for u, v in G.edges())
        XGM.add_edge(0, 1, weight=2)  # multiedge
        XGS = nx.Graph()
        XGS.add_nodes_from(G)
        XGS.add_weighted_edges_from((u, v, u) for u, v in G.edges())
        XGS.add_edge(0, 0, weight=100)  # self loop

        # Dict of dicts
        # with self loops, OK
        dod = to_dict_of_dicts(XGS)
        GG = from_dict_of_dicts(dod, create_using=nx.Graph)
        assert_nodes_equal(XGS.nodes(), GG.nodes())
        assert_edges_equal(XGS.edges(), GG.edges())
        GW = to_networkx_graph(dod, create_using=nx.Graph)
        assert_nodes_equal(XGS.nodes(), GW.nodes())
        assert_edges_equal(XGS.edges(), GW.edges())
        GI = nx.Graph(dod)
        assert_nodes_equal(XGS.nodes(), GI.nodes())
        assert_edges_equal(XGS.edges(), GI.edges())

        # Dict of lists
        # with self loops, OK
        dol = to_dict_of_lists(XGS)
        GG = from_dict_of_lists(dol, create_using=nx.Graph)
        # dict of lists throws away edge data so set it to none
        enone = [(u, v, {}) for (u, v, d) in XGS.edges(data=True)]
        assert_nodes_equal(sorted(XGS.nodes()), sorted(GG.nodes()))
        assert_edges_equal(enone, sorted(GG.edges(data=True)))
        GW = to_networkx_graph(dol, create_using=nx.Graph)
        assert_nodes_equal(sorted(XGS.nodes()), sorted(GW.nodes()))
        assert_edges_equal(enone, sorted(GW.edges(data=True)))
        GI = nx.Graph(dol)
        assert_nodes_equal(sorted(XGS.nodes()), sorted(GI.nodes()))
        assert_edges_equal(enone, sorted(GI.edges(data=True)))

        # Dict of dicts
        # with multiedges, OK
        dod = to_dict_of_dicts(XGM)
        GG = from_dict_of_dicts(dod,
                                create_using=nx.MultiGraph,
                                multigraph_input=True)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GG.nodes()))
        assert_edges_equal(sorted(XGM.edges()), sorted(GG.edges()))
        GW = to_networkx_graph(dod,
                               create_using=nx.MultiGraph,
                               multigraph_input=True)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GW.nodes()))
        assert_edges_equal(sorted(XGM.edges()), sorted(GW.edges()))
        GI = nx.MultiGraph(
            dod)  # convert can't tell whether to duplicate edges!
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GI.nodes()))
        # assert_not_equal(sorted(XGM.edges()), sorted(GI.edges()))
        assert not sorted(XGM.edges()) == sorted(GI.edges())
        GE = from_dict_of_dicts(dod,
                                create_using=nx.MultiGraph,
                                multigraph_input=False)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GE.nodes()))
        assert sorted(XGM.edges()) != sorted(GE.edges())
        GI = nx.MultiGraph(XGM)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GI.nodes()))
        assert_edges_equal(sorted(XGM.edges()), sorted(GI.edges()))
        GM = nx.MultiGraph(G)
        assert_nodes_equal(sorted(GM.nodes()), sorted(G.nodes()))
        assert_edges_equal(sorted(GM.edges()), sorted(G.edges()))

        # Dict of lists
        # with multiedges, OK, but better write as DiGraph else you'll
        # get double edges
        dol = to_dict_of_lists(G)
        GG = from_dict_of_lists(dol, create_using=nx.MultiGraph)
        assert_nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GG.edges()))
        GW = to_networkx_graph(dol, create_using=nx.MultiGraph)
        assert_nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GW.edges()))
        GI = nx.MultiGraph(dol)
        assert_nodes_equal(sorted(G.nodes()), sorted(GI.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GI.edges()))
Exemplo n.º 4
0
    def test_with_multiedges_self_loops(self):
        G = cycle_graph(10)
        XG = nx.Graph()
        XG.add_nodes_from(G)
        XG.add_weighted_edges_from((u, v, u) for u, v in G.edges())
        XGM = nx.MultiGraph()
        XGM.add_nodes_from(G)
        XGM.add_weighted_edges_from((u, v, u) for u, v in G.edges())
        XGM.add_edge(0, 1, weight=2)  # multiedge
        XGS = nx.Graph()
        XGS.add_nodes_from(G)
        XGS.add_weighted_edges_from((u, v, u) for u, v in G.edges())
        XGS.add_edge(0, 0, weight=100)  # self loop

        # Dict of dicts
        # with self loops, OK
        dod = to_dict_of_dicts(XGS)
        GG = from_dict_of_dicts(dod, create_using=nx.Graph())
        assert_nodes_equal(XGS.nodes(), GG.nodes())
        assert_edges_equal(XGS.edges(), GG.edges())
        GW = to_networkx_graph(dod, create_using=nx.Graph())
        assert_nodes_equal(XGS.nodes(), GW.nodes())
        assert_edges_equal(XGS.edges(), GW.edges())
        GI = nx.Graph(dod)
        assert_nodes_equal(XGS.nodes(), GI.nodes())
        assert_edges_equal(XGS.edges(), GI.edges())

        # Dict of lists
        # with self loops, OK
        dol = to_dict_of_lists(XGS)
        GG = from_dict_of_lists(dol, create_using=nx.Graph())
        # dict of lists throws away edge data so set it to none
        enone = [(u, v, {}) for (u, v, d) in XGS.edges(data=True)]
        assert_nodes_equal(sorted(XGS.nodes()), sorted(GG.nodes()))
        assert_edges_equal(enone, sorted(GG.edges(data=True)))
        GW = to_networkx_graph(dol, create_using=nx.Graph())
        assert_nodes_equal(sorted(XGS.nodes()), sorted(GW.nodes()))
        assert_edges_equal(enone, sorted(GW.edges(data=True)))
        GI = nx.Graph(dol)
        assert_nodes_equal(sorted(XGS.nodes()), sorted(GI.nodes()))
        assert_edges_equal(enone, sorted(GI.edges(data=True)))

        # Dict of dicts
        # with multiedges, OK
        dod = to_dict_of_dicts(XGM)
        GG = from_dict_of_dicts(dod, create_using=nx.MultiGraph(),
                                multigraph_input=True)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GG.nodes()))
        assert_edges_equal(sorted(XGM.edges()), sorted(GG.edges()))
        GW = to_networkx_graph(dod, create_using=nx.MultiGraph(), multigraph_input=True)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GW.nodes()))
        assert_edges_equal(sorted(XGM.edges()), sorted(GW.edges()))
        GI = nx.MultiGraph(dod)  # convert can't tell whether to duplicate edges!
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GI.nodes()))
        #assert_not_equal(sorted(XGM.edges()), sorted(GI.edges()))
        assert_false(sorted(XGM.edges()) == sorted(GI.edges()))
        GE = from_dict_of_dicts(dod, create_using=nx.MultiGraph(),
                                multigraph_input=False)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GE.nodes()))
        assert_not_equal(sorted(XGM.edges()), sorted(GE.edges()))
        GI = nx.MultiGraph(XGM)
        assert_nodes_equal(sorted(XGM.nodes()), sorted(GI.nodes()))
        assert_edges_equal(sorted(XGM.edges()), sorted(GI.edges()))
        GM = nx.MultiGraph(G)
        assert_nodes_equal(sorted(GM.nodes()), sorted(G.nodes()))
        assert_edges_equal(sorted(GM.edges()), sorted(G.edges()))

        # Dict of lists
        # with multiedges, OK, but better write as DiGraph else you'll
        # get double edges
        dol = to_dict_of_lists(G)
        GG = from_dict_of_lists(dol, create_using=nx.MultiGraph())
        assert_nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GG.edges()))
        GW = to_networkx_graph(dol, create_using=nx.MultiGraph())
        assert_nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GW.edges()))
        GI = nx.MultiGraph(dol)
        assert_nodes_equal(sorted(G.nodes()), sorted(GI.nodes()))
        assert_edges_equal(sorted(G.edges()), sorted(GI.edges()))