dbt-selly/dbt-env/lib/python3.8/site-packages/networkx/tests/test_convert.py

import pytest

import networkx as nx
from networkx.utils import nodes_equal, edges_equal, graphs_equal
from networkx.convert import (
    to_networkx_graph,
    to_dict_of_dicts,
    from_dict_of_dicts,
    to_dict_of_lists,
    from_dict_of_lists,
)
from networkx.generators.classic import barbell_graph, cycle_graph


class TestConvert:
    def edgelists_equal(self, e1, e2):
        return sorted(sorted(e) for e in e1) == sorted(sorted(e) for e in e2)

    def test_simple_graphs(self):
        for dest, source in [
            (to_dict_of_dicts, from_dict_of_dicts),
            (to_dict_of_lists, from_dict_of_lists),
        ]:
            G = barbell_graph(10, 3)
            G.graph = {}
            dod = dest(G)

            # Dict of [dicts, lists]
            GG = source(dod)
            assert graphs_equal(G, GG)
            GW = to_networkx_graph(dod)
            assert graphs_equal(G, GW)
            GI = nx.Graph(dod)
            assert graphs_equal(G, GI)

            # With nodelist keyword
            P4 = nx.path_graph(4)
            P3 = nx.path_graph(3)
            P4.graph = {}
            P3.graph = {}
            dod = dest(P4, nodelist=[0, 1, 2])
            Gdod = nx.Graph(dod)
            assert graphs_equal(Gdod, P3)

    def test_exceptions(self):
        # NX graph
        class G:
            adj = None

        pytest.raises(nx.NetworkXError, to_networkx_graph, G)

        # pygraphviz  agraph
        class G:
            is_strict = None

        pytest.raises(nx.NetworkXError, to_networkx_graph, G)

        # Dict of [dicts, lists]
        G = {"a": 0}
        pytest.raises(TypeError, to_networkx_graph, G)

        # list or generator of edges
        class G:
            next = None

        pytest.raises(nx.NetworkXError, to_networkx_graph, G)

        # no match
        pytest.raises(nx.NetworkXError, to_networkx_graph, "a")

    def test_digraphs(self):
        for dest, source in [
            (to_dict_of_dicts, from_dict_of_dicts),
            (to_dict_of_lists, from_dict_of_lists),
        ]:
            G = cycle_graph(10)

            # Dict of [dicts, lists]
            dod = dest(G)
            GG = source(dod)
            assert nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))
            assert edges_equal(sorted(G.edges()), sorted(GG.edges()))
            GW = to_networkx_graph(dod)
            assert nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))
            assert edges_equal(sorted(G.edges()), sorted(GW.edges()))
            GI = nx.Graph(dod)
            assert nodes_equal(sorted(G.nodes()), sorted(GI.nodes()))
            assert edges_equal(sorted(G.edges()), sorted(GI.edges()))

            G = cycle_graph(10, create_using=nx.DiGraph)
            dod = dest(G)
            GG = source(dod, create_using=nx.DiGraph)
            assert sorted(G.nodes()) == sorted(GG.nodes())
            assert sorted(G.edges()) == sorted(GG.edges())
            GW = to_networkx_graph(dod, create_using=nx.DiGraph)
            assert sorted(G.nodes()) == sorted(GW.nodes())
            assert sorted(G.edges()) == sorted(GW.edges())
            GI = nx.DiGraph(dod)
            assert sorted(G.nodes()) == sorted(GI.nodes())
            assert sorted(G.edges()) == sorted(GI.edges())

    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)))

    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)
        assert nodes_equal(sorted(XGM.nodes()), sorted(GI.nodes()))
        assert 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()))

    def test_edgelists(self):
        P = nx.path_graph(4)
        e = [(0, 1), (1, 2), (2, 3)]
        G = nx.Graph(e)
        assert nodes_equal(sorted(G.nodes()), sorted(P.nodes()))
        assert edges_equal(sorted(G.edges()), sorted(P.edges()))
        assert edges_equal(sorted(G.edges(data=True)), sorted(P.edges(data=True)))

        e = [(0, 1, {}), (1, 2, {}), (2, 3, {})]
        G = nx.Graph(e)
        assert nodes_equal(sorted(G.nodes()), sorted(P.nodes()))
        assert edges_equal(sorted(G.edges()), sorted(P.edges()))
        assert edges_equal(sorted(G.edges(data=True)), sorted(P.edges(data=True)))

        e = ((n, n + 1) for n in range(3))
        G = nx.Graph(e)
        assert nodes_equal(sorted(G.nodes()), sorted(P.nodes()))
        assert edges_equal(sorted(G.edges()), sorted(P.edges()))
        assert edges_equal(sorted(G.edges(data=True)), sorted(P.edges(data=True)))

    def test_directed_to_undirected(self):
        edges1 = [(0, 1), (1, 2), (2, 0)]
        edges2 = [(0, 1), (1, 2), (0, 2)]
        assert self.edgelists_equal(nx.Graph(nx.DiGraph(edges1)).edges(), edges1)
        assert self.edgelists_equal(nx.Graph(nx.DiGraph(edges2)).edges(), edges1)
        assert self.edgelists_equal(nx.MultiGraph(nx.DiGraph(edges1)).edges(), edges1)
        assert self.edgelists_equal(nx.MultiGraph(nx.DiGraph(edges2)).edges(), edges1)

        assert self.edgelists_equal(
            nx.MultiGraph(nx.MultiDiGraph(edges1)).edges(), edges1
        )
        assert self.edgelists_equal(
            nx.MultiGraph(nx.MultiDiGraph(edges2)).edges(), edges1
        )

        assert self.edgelists_equal(nx.Graph(nx.MultiDiGraph(edges1)).edges(), edges1)
        assert self.edgelists_equal(nx.Graph(nx.MultiDiGraph(edges2)).edges(), edges1)

    def test_attribute_dict_integrity(self):
        # we must not replace dict-like graph data structures with dicts
        G = nx.OrderedGraph()
        G.add_nodes_from("abc")
        H = to_networkx_graph(G, create_using=nx.OrderedGraph)
        assert list(H.nodes) == list(G.nodes)
        H = nx.OrderedDiGraph(G)
        assert list(H.nodes) == list(G.nodes)

    def test_to_edgelist(self):
        G = nx.Graph([(1, 1)])
        elist = nx.to_edgelist(G, nodelist=list(G))
        assert edges_equal(G.edges(data=True), elist)

    def test_custom_node_attr_dict_safekeeping(self):
        class custom_dict(dict):
            pass

        class Custom(nx.Graph):
            node_attr_dict_factory = custom_dict

        g = nx.Graph()
        g.add_node(1, weight=1)

        h = Custom(g)
        assert isinstance(g._node[1], dict)
        assert isinstance(h._node[1], custom_dict)

        # this raise exception
        # h._node.update((n, dd.copy()) for n, dd in g.nodes.items())
        # assert isinstance(h._node[1], custom_dict)


@pytest.mark.parametrize(
    "edgelist",
    (
        # Graph with no edge data
        [(0, 1), (1, 2)],
        # Graph with edge data
        [(0, 1, {"weight": 1.0}), (1, 2, {"weight": 2.0})],
    ),
)
def test_to_dict_of_dicts_with_edgedata_param(edgelist):
    G = nx.Graph()
    G.add_edges_from(edgelist)
    # Innermost dict value == edge_data when edge_data != None.
    # In the case when G has edge data, it is overwritten
    expected = {0: {1: 10}, 1: {0: 10, 2: 10}, 2: {1: 10}}
    assert nx.to_dict_of_dicts(G, edge_data=10) == expected


def test_to_dict_of_dicts_with_edgedata_and_nodelist():
    G = nx.path_graph(5)
    nodelist = [2, 3, 4]
    expected = {2: {3: 10}, 3: {2: 10, 4: 10}, 4: {3: 10}}
    assert nx.to_dict_of_dicts(G, nodelist=nodelist, edge_data=10) == expected


def test_to_dict_of_dicts_with_edgedata_multigraph():
    """Multi edge data overwritten when edge_data != None"""
    G = nx.MultiGraph()
    G.add_edge(0, 1, key="a")
    G.add_edge(0, 1, key="b")
    # Multi edge data lost when edge_data is not None
    expected = {0: {1: 10}, 1: {0: 10}}
    assert nx.to_dict_of_dicts(G, edge_data=10) == expected


def test_to_networkx_graph_non_edgelist():
    invalid_edgelist = [1, 2, 3]
    with pytest.raises(nx.NetworkXError, match="Input is not a valid edge list"):
        nx.to_networkx_graph(invalid_edgelist)
fix order deliveries 2022-03-22 15:13:27 +00:00			`import pytest`

			`import networkx as nx`
			`from networkx.utils import nodes_equal, edges_equal, graphs_equal`
			`from networkx.convert import (`
			`to_networkx_graph,`
			`to_dict_of_dicts,`
			`from_dict_of_dicts,`
			`to_dict_of_lists,`
			`from_dict_of_lists,`
			`)`
			`from networkx.generators.classic import barbell_graph, cycle_graph`


			`class TestConvert:`
			`def edgelists_equal(self, e1, e2):`
			`return sorted(sorted(e) for e in e1) == sorted(sorted(e) for e in e2)`

			`def test_simple_graphs(self):`
			`for dest, source in [`
			`(to_dict_of_dicts, from_dict_of_dicts),`
			`(to_dict_of_lists, from_dict_of_lists),`
			`]:`
			`G = barbell_graph(10, 3)`
			`G.graph = {}`
			`dod = dest(G)`

			`# Dict of [dicts, lists]`
			`GG = source(dod)`
			`assert graphs_equal(G, GG)`
			`GW = to_networkx_graph(dod)`
			`assert graphs_equal(G, GW)`
			`GI = nx.Graph(dod)`
			`assert graphs_equal(G, GI)`

			`# With nodelist keyword`
			`P4 = nx.path_graph(4)`
			`P3 = nx.path_graph(3)`
			`P4.graph = {}`
			`P3.graph = {}`
			`dod = dest(P4, nodelist=[0, 1, 2])`
			`Gdod = nx.Graph(dod)`
			`assert graphs_equal(Gdod, P3)`

			`def test_exceptions(self):`
			`# NX graph`
			`class G:`
			`adj = None`

			`pytest.raises(nx.NetworkXError, to_networkx_graph, G)`

			`# pygraphviz agraph`
			`class G:`
			`is_strict = None`

			`pytest.raises(nx.NetworkXError, to_networkx_graph, G)`

			`# Dict of [dicts, lists]`
			`G = {"a": 0}`
			`pytest.raises(TypeError, to_networkx_graph, G)`

			`# list or generator of edges`
			`class G:`
			`next = None`

			`pytest.raises(nx.NetworkXError, to_networkx_graph, G)`

			`# no match`
			`pytest.raises(nx.NetworkXError, to_networkx_graph, "a")`

			`def test_digraphs(self):`
			`for dest, source in [`
			`(to_dict_of_dicts, from_dict_of_dicts),`
			`(to_dict_of_lists, from_dict_of_lists),`
			`]:`
			`G = cycle_graph(10)`

			`# Dict of [dicts, lists]`
			`dod = dest(G)`
			`GG = source(dod)`
			`assert nodes_equal(sorted(G.nodes()), sorted(GG.nodes()))`
			`assert edges_equal(sorted(G.edges()), sorted(GG.edges()))`
			`GW = to_networkx_graph(dod)`
			`assert nodes_equal(sorted(G.nodes()), sorted(GW.nodes()))`
			`assert edges_equal(sorted(G.edges()), sorted(GW.edges()))`
			`GI = nx.Graph(dod)`
			`assert nodes_equal(sorted(G.nodes()), sorted(GI.nodes()))`
			`assert edges_equal(sorted(G.edges()), sorted(GI.edges()))`

			`G = cycle_graph(10, create_using=nx.DiGraph)`
			`dod = dest(G)`
			`GG = source(dod, create_using=nx.DiGraph)`
			`assert sorted(G.nodes()) == sorted(GG.nodes())`
			`assert sorted(G.edges()) == sorted(GG.edges())`
			`GW = to_networkx_graph(dod, create_using=nx.DiGraph)`
			`assert sorted(G.nodes()) == sorted(GW.nodes())`
			`assert sorted(G.edges()) == sorted(GW.edges())`
			`GI = nx.DiGraph(dod)`
			`assert sorted(G.nodes()) == sorted(GI.nodes())`
			`assert sorted(G.edges()) == sorted(GI.edges())`

			`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)))`

			`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)`
			`assert nodes_equal(sorted(XGM.nodes()), sorted(GI.nodes()))`
			`assert 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()))`

			`def test_edgelists(self):`
			`P = nx.path_graph(4)`
			`e = [(0, 1), (1, 2), (2, 3)]`
			`G = nx.Graph(e)`
			`assert nodes_equal(sorted(G.nodes()), sorted(P.nodes()))`
			`assert edges_equal(sorted(G.edges()), sorted(P.edges()))`
			`assert edges_equal(sorted(G.edges(data=True)), sorted(P.edges(data=True)))`

			`e = [(0, 1, {}), (1, 2, {}), (2, 3, {})]`
			`G = nx.Graph(e)`
			`assert nodes_equal(sorted(G.nodes()), sorted(P.nodes()))`
			`assert edges_equal(sorted(G.edges()), sorted(P.edges()))`
			`assert edges_equal(sorted(G.edges(data=True)), sorted(P.edges(data=True)))`

			`e = ((n, n + 1) for n in range(3))`
			`G = nx.Graph(e)`
			`assert nodes_equal(sorted(G.nodes()), sorted(P.nodes()))`
			`assert edges_equal(sorted(G.edges()), sorted(P.edges()))`
			`assert edges_equal(sorted(G.edges(data=True)), sorted(P.edges(data=True)))`

			`def test_directed_to_undirected(self):`
			`edges1 = [(0, 1), (1, 2), (2, 0)]`
			`edges2 = [(0, 1), (1, 2), (0, 2)]`
			`assert self.edgelists_equal(nx.Graph(nx.DiGraph(edges1)).edges(), edges1)`
			`assert self.edgelists_equal(nx.Graph(nx.DiGraph(edges2)).edges(), edges1)`
			`assert self.edgelists_equal(nx.MultiGraph(nx.DiGraph(edges1)).edges(), edges1)`
			`assert self.edgelists_equal(nx.MultiGraph(nx.DiGraph(edges2)).edges(), edges1)`

			`assert self.edgelists_equal(`
			`nx.MultiGraph(nx.MultiDiGraph(edges1)).edges(), edges1`
			`)`
			`assert self.edgelists_equal(`
			`nx.MultiGraph(nx.MultiDiGraph(edges2)).edges(), edges1`
			`)`

			`assert self.edgelists_equal(nx.Graph(nx.MultiDiGraph(edges1)).edges(), edges1)`
			`assert self.edgelists_equal(nx.Graph(nx.MultiDiGraph(edges2)).edges(), edges1)`

			`def test_attribute_dict_integrity(self):`
			`# we must not replace dict-like graph data structures with dicts`
			`G = nx.OrderedGraph()`
			`G.add_nodes_from("abc")`
			`H = to_networkx_graph(G, create_using=nx.OrderedGraph)`
			`assert list(H.nodes) == list(G.nodes)`
			`H = nx.OrderedDiGraph(G)`
			`assert list(H.nodes) == list(G.nodes)`

			`def test_to_edgelist(self):`
			`G = nx.Graph([(1, 1)])`
			`elist = nx.to_edgelist(G, nodelist=list(G))`
			`assert edges_equal(G.edges(data=True), elist)`

			`def test_custom_node_attr_dict_safekeeping(self):`
			`class custom_dict(dict):`
			`pass`

			`class Custom(nx.Graph):`
			`node_attr_dict_factory = custom_dict`

			`g = nx.Graph()`
			`g.add_node(1, weight=1)`

			`h = Custom(g)`
			`assert isinstance(g._node[1], dict)`
			`assert isinstance(h._node[1], custom_dict)`

			`# this raise exception`
			`# h._node.update((n, dd.copy()) for n, dd in g.nodes.items())`
			`# assert isinstance(h._node[1], custom_dict)`


			`@pytest.mark.parametrize(`
			`"edgelist",`
			`(`
			`# Graph with no edge data`
			`[(0, 1), (1, 2)],`
			`# Graph with edge data`
			`[(0, 1, {"weight": 1.0}), (1, 2, {"weight": 2.0})],`
			`),`
			`)`
			`def test_to_dict_of_dicts_with_edgedata_param(edgelist):`
			`G = nx.Graph()`
			`G.add_edges_from(edgelist)`
			`# Innermost dict value == edge_data when edge_data != None.`
			`# In the case when G has edge data, it is overwritten`
			`expected = {0: {1: 10}, 1: {0: 10, 2: 10}, 2: {1: 10}}`
			`assert nx.to_dict_of_dicts(G, edge_data=10) == expected`


			`def test_to_dict_of_dicts_with_edgedata_and_nodelist():`
			`G = nx.path_graph(5)`
			`nodelist = [2, 3, 4]`
			`expected = {2: {3: 10}, 3: {2: 10, 4: 10}, 4: {3: 10}}`
			`assert nx.to_dict_of_dicts(G, nodelist=nodelist, edge_data=10) == expected`


			`def test_to_dict_of_dicts_with_edgedata_multigraph():`
			`"""Multi edge data overwritten when edge_data != None"""`
			`G = nx.MultiGraph()`
			`G.add_edge(0, 1, key="a")`
			`G.add_edge(0, 1, key="b")`
			`# Multi edge data lost when edge_data is not None`
			`expected = {0: {1: 10}, 1: {0: 10}}`
			`assert nx.to_dict_of_dicts(G, edge_data=10) == expected`


			`def test_to_networkx_graph_non_edgelist():`
			`invalid_edgelist = [1, 2, 3]`
			`with pytest.raises(nx.NetworkXError, match="Input is not a valid edge list"):`
			`nx.to_networkx_graph(invalid_edgelist)`