375 lines
12 KiB
Python
375 lines
12 KiB
Python
import pytest
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import networkx as nx
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from networkx.testing.utils import assert_edges_equal
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from .test_graph import BaseAttrGraphTester
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from .test_graph import TestGraph as _TestGraph
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class BaseMultiGraphTester(BaseAttrGraphTester):
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def test_has_edge(self):
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G = self.K3
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assert G.has_edge(0, 1)
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assert not G.has_edge(0, -1)
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assert G.has_edge(0, 1, 0)
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assert not G.has_edge(0, 1, 1)
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def test_get_edge_data(self):
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G = self.K3
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assert G.get_edge_data(0, 1) == {0: {}}
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assert G[0][1] == {0: {}}
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assert G[0][1][0] == {}
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assert G.get_edge_data(10, 20) is None
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assert G.get_edge_data(0, 1, 0) == {}
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def test_adjacency(self):
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G = self.K3
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assert dict(G.adjacency()) == {
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0: {1: {0: {}}, 2: {0: {}}},
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1: {0: {0: {}}, 2: {0: {}}},
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2: {0: {0: {}}, 1: {0: {}}},
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}
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def deepcopy_edge_attr(self, H, G):
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assert G[1][2][0]["foo"] == H[1][2][0]["foo"]
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G[1][2][0]["foo"].append(1)
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assert G[1][2][0]["foo"] != H[1][2][0]["foo"]
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def shallow_copy_edge_attr(self, H, G):
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assert G[1][2][0]["foo"] == H[1][2][0]["foo"]
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G[1][2][0]["foo"].append(1)
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assert G[1][2][0]["foo"] == H[1][2][0]["foo"]
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def graphs_equal(self, H, G):
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assert G._adj == H._adj
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assert G._node == H._node
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assert G.graph == H.graph
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assert G.name == H.name
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if not G.is_directed() and not H.is_directed():
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assert H._adj[1][2][0] is H._adj[2][1][0]
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assert G._adj[1][2][0] is G._adj[2][1][0]
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else: # at least one is directed
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if not G.is_directed():
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G._pred = G._adj
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G._succ = G._adj
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if not H.is_directed():
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H._pred = H._adj
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H._succ = H._adj
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assert G._pred == H._pred
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assert G._succ == H._succ
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assert H._succ[1][2][0] is H._pred[2][1][0]
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assert G._succ[1][2][0] is G._pred[2][1][0]
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def same_attrdict(self, H, G):
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# same attrdict in the edgedata
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old_foo = H[1][2][0]["foo"]
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H.adj[1][2][0]["foo"] = "baz"
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assert G._adj == H._adj
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H.adj[1][2][0]["foo"] = old_foo
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assert G._adj == H._adj
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old_foo = H.nodes[0]["foo"]
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H.nodes[0]["foo"] = "baz"
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assert G._node == H._node
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H.nodes[0]["foo"] = old_foo
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assert G._node == H._node
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def different_attrdict(self, H, G):
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# used by graph_equal_but_different
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old_foo = H[1][2][0]["foo"]
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H.adj[1][2][0]["foo"] = "baz"
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assert G._adj != H._adj
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H.adj[1][2][0]["foo"] = old_foo
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assert G._adj == H._adj
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old_foo = H.nodes[0]["foo"]
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H.nodes[0]["foo"] = "baz"
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assert G._node != H._node
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H.nodes[0]["foo"] = old_foo
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assert G._node == H._node
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def test_to_undirected(self):
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G = self.K3
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self.add_attributes(G)
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H = nx.MultiGraph(G)
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self.is_shallow_copy(H, G)
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H = G.to_undirected()
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self.is_deepcopy(H, G)
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def test_to_directed(self):
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G = self.K3
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self.add_attributes(G)
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H = nx.MultiDiGraph(G)
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self.is_shallow_copy(H, G)
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H = G.to_directed()
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self.is_deepcopy(H, G)
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def test_number_of_edges_selfloops(self):
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G = self.K3
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G.add_edge(0, 0)
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G.add_edge(0, 0)
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G.add_edge(0, 0, key="parallel edge")
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G.remove_edge(0, 0, key="parallel edge")
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assert G.number_of_edges(0, 0) == 2
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G.remove_edge(0, 0)
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assert G.number_of_edges(0, 0) == 1
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def test_edge_lookup(self):
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G = self.Graph()
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G.add_edge(1, 2, foo="bar")
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G.add_edge(1, 2, "key", foo="biz")
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assert_edges_equal(G.edges[1, 2, 0], {"foo": "bar"})
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assert_edges_equal(G.edges[1, 2, "key"], {"foo": "biz"})
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def test_edge_attr4(self):
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G = self.Graph()
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G.add_edge(1, 2, key=0, data=7, spam="bar", bar="foo")
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assert_edges_equal(
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G.edges(data=True), [(1, 2, {"data": 7, "spam": "bar", "bar": "foo"})]
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)
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G[1][2][0]["data"] = 10 # OK to set data like this
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assert_edges_equal(
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G.edges(data=True), [(1, 2, {"data": 10, "spam": "bar", "bar": "foo"})]
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)
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G.adj[1][2][0]["data"] = 20
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assert_edges_equal(
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G.edges(data=True), [(1, 2, {"data": 20, "spam": "bar", "bar": "foo"})]
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)
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G.edges[1, 2, 0]["data"] = 21 # another spelling, "edge"
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assert_edges_equal(
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G.edges(data=True), [(1, 2, {"data": 21, "spam": "bar", "bar": "foo"})]
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)
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G.adj[1][2][0]["listdata"] = [20, 200]
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G.adj[1][2][0]["weight"] = 20
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assert_edges_equal(
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G.edges(data=True),
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[
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(
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1,
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2,
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{
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"data": 21,
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"spam": "bar",
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"bar": "foo",
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"listdata": [20, 200],
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"weight": 20,
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},
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)
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],
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)
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class TestMultiGraph(BaseMultiGraphTester, _TestGraph):
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def setup_method(self):
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self.Graph = nx.MultiGraph
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# build K3
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ed1, ed2, ed3 = ({0: {}}, {0: {}}, {0: {}})
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self.k3adj = {0: {1: ed1, 2: ed2}, 1: {0: ed1, 2: ed3}, 2: {0: ed2, 1: ed3}}
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self.k3edges = [(0, 1), (0, 2), (1, 2)]
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self.k3nodes = [0, 1, 2]
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self.K3 = self.Graph()
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self.K3._adj = self.k3adj
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self.K3._node = {}
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self.K3._node[0] = {}
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self.K3._node[1] = {}
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self.K3._node[2] = {}
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def test_data_input(self):
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G = self.Graph({1: [2], 2: [1]}, name="test")
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assert G.name == "test"
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expected = [(1, {2: {0: {}}}), (2, {1: {0: {}}})]
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assert sorted(G.adj.items()) == expected
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def test_getitem(self):
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G = self.K3
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assert G[0] == {1: {0: {}}, 2: {0: {}}}
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with pytest.raises(KeyError):
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G.__getitem__("j")
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with pytest.raises(TypeError):
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G.__getitem__(["A"])
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def test_remove_node(self):
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G = self.K3
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G.remove_node(0)
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assert G.adj == {1: {2: {0: {}}}, 2: {1: {0: {}}}}
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with pytest.raises(nx.NetworkXError):
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G.remove_node(-1)
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def test_add_edge(self):
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G = self.Graph()
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G.add_edge(0, 1)
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assert G.adj == {0: {1: {0: {}}}, 1: {0: {0: {}}}}
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G = self.Graph()
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G.add_edge(*(0, 1))
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assert G.adj == {0: {1: {0: {}}}, 1: {0: {0: {}}}}
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def test_add_edge_conflicting_key(self):
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G = self.Graph()
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G.add_edge(0, 1, key=1)
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G.add_edge(0, 1)
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assert G.number_of_edges() == 2
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G = self.Graph()
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G.add_edges_from([(0, 1, 1, {})])
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G.add_edges_from([(0, 1)])
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assert G.number_of_edges() == 2
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def test_add_edges_from(self):
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G = self.Graph()
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G.add_edges_from([(0, 1), (0, 1, {"weight": 3})])
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assert G.adj == {
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0: {1: {0: {}, 1: {"weight": 3}}},
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1: {0: {0: {}, 1: {"weight": 3}}},
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}
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G.add_edges_from([(0, 1), (0, 1, {"weight": 3})], weight=2)
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assert G.adj == {
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0: {1: {0: {}, 1: {"weight": 3}, 2: {"weight": 2}, 3: {"weight": 3}}},
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1: {0: {0: {}, 1: {"weight": 3}, 2: {"weight": 2}, 3: {"weight": 3}}},
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}
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G = self.Graph()
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edges = [
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(0, 1, {"weight": 3}),
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(0, 1, (("weight", 2),)),
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(0, 1, 5),
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(0, 1, "s"),
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]
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G.add_edges_from(edges)
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keydict = {0: {"weight": 3}, 1: {"weight": 2}, 5: {}, "s": {}}
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assert G._adj == {0: {1: keydict}, 1: {0: keydict}}
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# too few in tuple
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with pytest.raises(nx.NetworkXError):
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G.add_edges_from([(0,)])
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# too many in tuple
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with pytest.raises(nx.NetworkXError):
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G.add_edges_from([(0, 1, 2, 3, 4)])
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# not a tuple
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with pytest.raises(TypeError):
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G.add_edges_from([0])
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def test_remove_edge(self):
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G = self.K3
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G.remove_edge(0, 1)
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assert G.adj == {0: {2: {0: {}}}, 1: {2: {0: {}}}, 2: {0: {0: {}}, 1: {0: {}}}}
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with pytest.raises(nx.NetworkXError):
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G.remove_edge(-1, 0)
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with pytest.raises(nx.NetworkXError):
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G.remove_edge(0, 2, key=1)
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def test_remove_edges_from(self):
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G = self.K3.copy()
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G.remove_edges_from([(0, 1)])
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kd = {0: {}}
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assert G.adj == {0: {2: kd}, 1: {2: kd}, 2: {0: kd, 1: kd}}
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G.remove_edges_from([(0, 0)]) # silent fail
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self.K3.add_edge(0, 1)
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G = self.K3.copy()
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G.remove_edges_from(list(G.edges(data=True, keys=True)))
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assert G.adj == {0: {}, 1: {}, 2: {}}
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G = self.K3.copy()
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G.remove_edges_from(list(G.edges(data=False, keys=True)))
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assert G.adj == {0: {}, 1: {}, 2: {}}
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G = self.K3.copy()
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G.remove_edges_from(list(G.edges(data=False, keys=False)))
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assert G.adj == {0: {}, 1: {}, 2: {}}
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G = self.K3.copy()
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G.remove_edges_from([(0, 1, 0), (0, 2, 0, {}), (1, 2)])
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assert G.adj == {0: {1: {1: {}}}, 1: {0: {1: {}}}, 2: {}}
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def test_remove_multiedge(self):
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G = self.K3
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G.add_edge(0, 1, key="parallel edge")
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G.remove_edge(0, 1, key="parallel edge")
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assert G.adj == {
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0: {1: {0: {}}, 2: {0: {}}},
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1: {0: {0: {}}, 2: {0: {}}},
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2: {0: {0: {}}, 1: {0: {}}},
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}
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G.remove_edge(0, 1)
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kd = {0: {}}
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assert G.adj == {0: {2: kd}, 1: {2: kd}, 2: {0: kd, 1: kd}}
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with pytest.raises(nx.NetworkXError):
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G.remove_edge(-1, 0)
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class TestEdgeSubgraph:
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"""Unit tests for the :meth:`MultiGraph.edge_subgraph` method."""
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def setup_method(self):
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# Create a doubly-linked path graph on five nodes.
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G = nx.MultiGraph()
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nx.add_path(G, range(5))
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nx.add_path(G, range(5))
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# Add some node, edge, and graph attributes.
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for i in range(5):
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G.nodes[i]["name"] = f"node{i}"
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G.adj[0][1][0]["name"] = "edge010"
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G.adj[0][1][1]["name"] = "edge011"
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G.adj[3][4][0]["name"] = "edge340"
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G.adj[3][4][1]["name"] = "edge341"
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G.graph["name"] = "graph"
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# Get the subgraph induced by one of the first edges and one of
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# the last edges.
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self.G = G
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self.H = G.edge_subgraph([(0, 1, 0), (3, 4, 1)])
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def test_correct_nodes(self):
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"""Tests that the subgraph has the correct nodes."""
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assert [0, 1, 3, 4] == sorted(self.H.nodes())
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def test_correct_edges(self):
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"""Tests that the subgraph has the correct edges."""
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assert [(0, 1, 0, "edge010"), (3, 4, 1, "edge341")] == sorted(
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self.H.edges(keys=True, data="name")
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)
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def test_add_node(self):
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"""Tests that adding a node to the original graph does not
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affect the nodes of the subgraph.
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"""
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self.G.add_node(5)
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assert [0, 1, 3, 4] == sorted(self.H.nodes())
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def test_remove_node(self):
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"""Tests that removing a node in the original graph does
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affect the nodes of the subgraph.
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"""
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self.G.remove_node(0)
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assert [1, 3, 4] == sorted(self.H.nodes())
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def test_node_attr_dict(self):
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"""Tests that the node attribute dictionary of the two graphs is
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the same object.
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"""
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for v in self.H:
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assert self.G.nodes[v] == self.H.nodes[v]
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# Making a change to G should make a change in H and vice versa.
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self.G.nodes[0]["name"] = "foo"
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assert self.G.nodes[0] == self.H.nodes[0]
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self.H.nodes[1]["name"] = "bar"
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assert self.G.nodes[1] == self.H.nodes[1]
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def test_edge_attr_dict(self):
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"""Tests that the edge attribute dictionary of the two graphs is
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the same object.
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"""
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for u, v, k in self.H.edges(keys=True):
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assert self.G._adj[u][v][k] == self.H._adj[u][v][k]
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# Making a change to G should make a change in H and vice versa.
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self.G._adj[0][1][0]["name"] = "foo"
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assert self.G._adj[0][1][0]["name"] == self.H._adj[0][1][0]["name"]
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self.H._adj[3][4][1]["name"] = "bar"
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assert self.G._adj[3][4][1]["name"] == self.H._adj[3][4][1]["name"]
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def test_graph_attr_dict(self):
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"""Tests that the graph attribute dictionary of the two graphs
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is the same object.
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"""
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assert self.G.graph is self.H.graph
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