353 lines
11 KiB
Python
353 lines
11 KiB
Python
import pytest
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import networkx as nx
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from networkx.utils import edges_equal, nodes_equal
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# Note: SubGraph views are not tested here. They have their own testing file
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class TestReverseView:
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def setup_method(self):
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self.G = nx.path_graph(9, create_using=nx.DiGraph())
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self.rv = nx.reverse_view(self.G)
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def test_pickle(self):
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import pickle
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rv = self.rv
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prv = pickle.loads(pickle.dumps(rv, -1))
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assert rv._node == prv._node
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assert rv._adj == prv._adj
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assert rv.graph == prv.graph
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def test_contains(self):
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assert (2, 3) in self.G.edges
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assert (3, 2) not in self.G.edges
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assert (2, 3) not in self.rv.edges
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assert (3, 2) in self.rv.edges
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def test_iter(self):
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expected = sorted(tuple(reversed(e)) for e in self.G.edges)
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assert sorted(self.rv.edges) == expected
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def test_exceptions(self):
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nxg = nx.graphviews
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G = nx.Graph()
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pytest.raises(nx.NetworkXNotImplemented, nxg.reverse_view, G)
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def test_subclass(self):
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class MyGraph(nx.DiGraph):
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def my_method(self):
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return "me"
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def to_directed_class(self):
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return MyGraph()
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M = MyGraph()
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M.add_edge(1, 2)
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RM = nx.reverse_view(M)
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print("RM class", RM.__class__)
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RMC = RM.copy()
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print("RMC class", RMC.__class__)
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print(RMC.edges)
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assert RMC.has_edge(2, 1)
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assert RMC.my_method() == "me"
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class TestMultiReverseView:
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def setup_method(self):
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self.G = nx.path_graph(9, create_using=nx.MultiDiGraph())
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self.G.add_edge(4, 5)
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self.rv = nx.reverse_view(self.G)
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def test_pickle(self):
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import pickle
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rv = self.rv
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prv = pickle.loads(pickle.dumps(rv, -1))
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assert rv._node == prv._node
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assert rv._adj == prv._adj
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assert rv.graph == prv.graph
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def test_contains(self):
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assert (2, 3, 0) in self.G.edges
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assert (3, 2, 0) not in self.G.edges
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assert (2, 3, 0) not in self.rv.edges
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assert (3, 2, 0) in self.rv.edges
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assert (5, 4, 1) in self.rv.edges
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assert (4, 5, 1) not in self.rv.edges
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def test_iter(self):
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expected = sorted((v, u, k) for u, v, k in self.G.edges)
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assert sorted(self.rv.edges) == expected
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def test_exceptions(self):
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nxg = nx.graphviews
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MG = nx.MultiGraph(self.G)
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pytest.raises(nx.NetworkXNotImplemented, nxg.reverse_view, MG)
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def test_generic_multitype():
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nxg = nx.graphviews
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G = nx.DiGraph([(1, 2)])
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with pytest.raises(nx.NetworkXError):
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nxg.generic_graph_view(G, create_using=nx.MultiGraph)
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G = nx.MultiDiGraph([(1, 2)])
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with pytest.raises(nx.NetworkXError):
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nxg.generic_graph_view(G, create_using=nx.DiGraph)
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class TestToDirected:
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def setup_method(self):
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self.G = nx.path_graph(9)
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self.dv = nx.to_directed(self.G)
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self.MG = nx.path_graph(9, create_using=nx.MultiGraph())
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self.Mdv = nx.to_directed(self.MG)
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def test_directed(self):
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assert not self.G.is_directed()
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assert self.dv.is_directed()
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def test_already_directed(self):
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dd = nx.to_directed(self.dv)
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Mdd = nx.to_directed(self.Mdv)
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assert edges_equal(dd.edges, self.dv.edges)
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assert edges_equal(Mdd.edges, self.Mdv.edges)
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def test_pickle(self):
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import pickle
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dv = self.dv
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pdv = pickle.loads(pickle.dumps(dv, -1))
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assert dv._node == pdv._node
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assert dv._succ == pdv._succ
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assert dv._pred == pdv._pred
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assert dv.graph == pdv.graph
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def test_contains(self):
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assert (2, 3) in self.G.edges
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assert (3, 2) in self.G.edges
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assert (2, 3) in self.dv.edges
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assert (3, 2) in self.dv.edges
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def test_iter(self):
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revd = [tuple(reversed(e)) for e in self.G.edges]
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expected = sorted(list(self.G.edges) + revd)
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assert sorted(self.dv.edges) == expected
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class TestToUndirected:
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def setup_method(self):
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self.DG = nx.path_graph(9, create_using=nx.DiGraph())
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self.uv = nx.to_undirected(self.DG)
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self.MDG = nx.path_graph(9, create_using=nx.MultiDiGraph())
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self.Muv = nx.to_undirected(self.MDG)
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def test_directed(self):
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assert self.DG.is_directed()
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assert not self.uv.is_directed()
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def test_already_directed(self):
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uu = nx.to_undirected(self.uv)
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Muu = nx.to_undirected(self.Muv)
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assert edges_equal(uu.edges, self.uv.edges)
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assert edges_equal(Muu.edges, self.Muv.edges)
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def test_pickle(self):
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import pickle
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uv = self.uv
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puv = pickle.loads(pickle.dumps(uv, -1))
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assert uv._node == puv._node
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assert uv._adj == puv._adj
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assert uv.graph == puv.graph
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assert hasattr(uv, "_graph")
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def test_contains(self):
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assert (2, 3) in self.DG.edges
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assert (3, 2) not in self.DG.edges
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assert (2, 3) in self.uv.edges
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assert (3, 2) in self.uv.edges
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def test_iter(self):
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expected = sorted(self.DG.edges)
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assert sorted(self.uv.edges) == expected
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class TestChainsOfViews:
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@classmethod
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def setup_class(cls):
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cls.G = nx.path_graph(9)
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cls.DG = nx.path_graph(9, create_using=nx.DiGraph())
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cls.MG = nx.path_graph(9, create_using=nx.MultiGraph())
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cls.MDG = nx.path_graph(9, create_using=nx.MultiDiGraph())
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cls.Gv = nx.to_undirected(cls.DG)
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cls.DGv = nx.to_directed(cls.G)
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cls.MGv = nx.to_undirected(cls.MDG)
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cls.MDGv = nx.to_directed(cls.MG)
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cls.Rv = cls.DG.reverse()
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cls.MRv = cls.MDG.reverse()
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cls.graphs = [
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cls.G,
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cls.DG,
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cls.MG,
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cls.MDG,
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cls.Gv,
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cls.DGv,
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cls.MGv,
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cls.MDGv,
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cls.Rv,
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cls.MRv,
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]
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for G in cls.graphs:
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G.edges, G.nodes, G.degree
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def test_pickle(self):
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import pickle
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for G in self.graphs:
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H = pickle.loads(pickle.dumps(G, -1))
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assert edges_equal(H.edges, G.edges)
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assert nodes_equal(H.nodes, G.nodes)
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def test_subgraph_of_subgraph(self):
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SGv = nx.subgraph(self.G, range(3, 7))
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SDGv = nx.subgraph(self.DG, range(3, 7))
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SMGv = nx.subgraph(self.MG, range(3, 7))
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SMDGv = nx.subgraph(self.MDG, range(3, 7))
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for G in self.graphs + [SGv, SDGv, SMGv, SMDGv]:
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SG = nx.induced_subgraph(G, [4, 5, 6])
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assert list(SG) == [4, 5, 6]
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SSG = SG.subgraph([6, 7])
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assert list(SSG) == [6]
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# subgraph-subgraph chain is short-cut in base class method
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assert SSG._graph is G
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def test_restricted_induced_subgraph_chains(self):
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"""Test subgraph chains that both restrict and show nodes/edges.
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A restricted_view subgraph should allow induced subgraphs using
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G.subgraph that automagically without a chain (meaning the result
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is a subgraph view of the original graph not a subgraph-of-subgraph.
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"""
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hide_nodes = [3, 4, 5]
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hide_edges = [(6, 7)]
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RG = nx.restricted_view(self.G, hide_nodes, hide_edges)
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nodes = [4, 5, 6, 7, 8]
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SG = nx.induced_subgraph(RG, nodes)
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SSG = RG.subgraph(nodes)
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assert RG._graph is self.G
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assert SSG._graph is self.G
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assert SG._graph is RG
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assert edges_equal(SG.edges, SSG.edges)
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# should be same as morphing the graph
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CG = self.G.copy()
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CG.remove_nodes_from(hide_nodes)
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CG.remove_edges_from(hide_edges)
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assert edges_equal(CG.edges(nodes), SSG.edges)
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CG.remove_nodes_from([0, 1, 2, 3])
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assert edges_equal(CG.edges, SSG.edges)
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# switch order: subgraph first, then restricted view
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SSSG = self.G.subgraph(nodes)
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RSG = nx.restricted_view(SSSG, hide_nodes, hide_edges)
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assert RSG._graph is not self.G
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assert edges_equal(RSG.edges, CG.edges)
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def test_subgraph_copy(self):
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for origG in self.graphs:
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G = nx.OrderedGraph(origG)
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SG = G.subgraph([4, 5, 6])
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H = SG.copy()
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assert type(G) == type(H)
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def test_subgraph_todirected(self):
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SG = nx.induced_subgraph(self.G, [4, 5, 6])
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SSG = SG.to_directed()
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assert sorted(SSG) == [4, 5, 6]
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assert sorted(SSG.edges) == [(4, 5), (5, 4), (5, 6), (6, 5)]
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def test_subgraph_toundirected(self):
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SG = nx.induced_subgraph(self.G, [4, 5, 6])
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SSG = SG.to_undirected()
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assert list(SSG) == [4, 5, 6]
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assert sorted(SSG.edges) == [(4, 5), (5, 6)]
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def test_reverse_subgraph_toundirected(self):
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G = self.DG.reverse(copy=False)
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SG = G.subgraph([4, 5, 6])
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SSG = SG.to_undirected()
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assert list(SSG) == [4, 5, 6]
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assert sorted(SSG.edges) == [(4, 5), (5, 6)]
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def test_reverse_reverse_copy(self):
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G = self.DG.reverse(copy=False)
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H = G.reverse(copy=True)
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assert H.nodes == self.DG.nodes
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assert H.edges == self.DG.edges
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G = self.MDG.reverse(copy=False)
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H = G.reverse(copy=True)
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assert H.nodes == self.MDG.nodes
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assert H.edges == self.MDG.edges
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def test_subgraph_edgesubgraph_toundirected(self):
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G = self.G.copy()
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SG = G.subgraph([4, 5, 6])
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SSG = SG.edge_subgraph([(4, 5), (5, 4)])
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USSG = SSG.to_undirected()
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assert list(USSG) == [4, 5]
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assert sorted(USSG.edges) == [(4, 5)]
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def test_copy_subgraph(self):
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G = self.G.copy()
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SG = G.subgraph([4, 5, 6])
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CSG = SG.copy(as_view=True)
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DCSG = SG.copy(as_view=False)
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assert hasattr(CSG, "_graph") # is a view
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assert not hasattr(DCSG, "_graph") # not a view
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def test_copy_disubgraph(self):
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G = self.DG.copy()
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SG = G.subgraph([4, 5, 6])
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CSG = SG.copy(as_view=True)
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DCSG = SG.copy(as_view=False)
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assert hasattr(CSG, "_graph") # is a view
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assert not hasattr(DCSG, "_graph") # not a view
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def test_copy_multidisubgraph(self):
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G = self.MDG.copy()
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SG = G.subgraph([4, 5, 6])
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CSG = SG.copy(as_view=True)
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DCSG = SG.copy(as_view=False)
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assert hasattr(CSG, "_graph") # is a view
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assert not hasattr(DCSG, "_graph") # not a view
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def test_copy_multisubgraph(self):
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G = self.MG.copy()
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SG = G.subgraph([4, 5, 6])
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CSG = SG.copy(as_view=True)
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DCSG = SG.copy(as_view=False)
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assert hasattr(CSG, "_graph") # is a view
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assert not hasattr(DCSG, "_graph") # not a view
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def test_copy_of_view(self):
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G = nx.OrderedMultiGraph(self.MGv)
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assert G.__class__.__name__ == "OrderedMultiGraph"
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G = G.copy(as_view=True)
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assert G.__class__.__name__ == "OrderedMultiGraph"
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def test_subclass(self):
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class MyGraph(nx.DiGraph):
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def my_method(self):
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return "me"
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def to_directed_class(self):
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return MyGraph()
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for origG in self.graphs:
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G = MyGraph(origG)
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SG = G.subgraph([4, 5, 6])
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H = SG.copy()
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assert SG.my_method() == "me"
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assert H.my_method() == "me"
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assert not 3 in H or 3 in SG
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