import networkx as nx class TestDFS: @classmethod def setup_class(cls): # simple graph G = nx.Graph() G.add_edges_from([(0, 1), (1, 2), (1, 3), (2, 4), (3, 0), (0, 4)]) cls.G = G # simple graph, disconnected D = nx.Graph() D.add_edges_from([(0, 1), (2, 3)]) cls.D = D def test_preorder_nodes(self): assert list(nx.dfs_preorder_nodes(self.G, source=0)) == [0, 1, 2, 4, 3] assert list(nx.dfs_preorder_nodes(self.D)) == [0, 1, 2, 3] assert list(nx.dfs_preorder_nodes(self.D, source=2)) == [2, 3] def test_postorder_nodes(self): assert list(nx.dfs_postorder_nodes(self.G, source=0)) == [4, 2, 3, 1, 0] assert list(nx.dfs_postorder_nodes(self.D)) == [1, 0, 3, 2] assert list(nx.dfs_postorder_nodes(self.D, source=0)) == [1, 0] def test_successor(self): assert nx.dfs_successors(self.G, source=0) == {0: [1], 1: [2, 3], 2: [4]} assert nx.dfs_successors(self.G, source=1) == {0: [3, 4], 1: [0], 4: [2]} assert nx.dfs_successors(self.D) == {0: [1], 2: [3]} assert nx.dfs_successors(self.D, source=1) == {1: [0]} def test_predecessor(self): assert nx.dfs_predecessors(self.G, source=0) == {1: 0, 2: 1, 3: 1, 4: 2} assert nx.dfs_predecessors(self.D) == {1: 0, 3: 2} def test_dfs_tree(self): exp_nodes = sorted(self.G.nodes()) exp_edges = [(0, 1), (1, 2), (1, 3), (2, 4)] # Search from first node T = nx.dfs_tree(self.G, source=0) assert sorted(T.nodes()) == exp_nodes assert sorted(T.edges()) == exp_edges # Check source=None T = nx.dfs_tree(self.G, source=None) assert sorted(T.nodes()) == exp_nodes assert sorted(T.edges()) == exp_edges # Check source=None is the default T = nx.dfs_tree(self.G) assert sorted(T.nodes()) == exp_nodes assert sorted(T.edges()) == exp_edges def test_dfs_edges(self): edges = nx.dfs_edges(self.G, source=0) assert list(edges) == [(0, 1), (1, 2), (2, 4), (1, 3)] edges = nx.dfs_edges(self.D) assert list(edges) == [(0, 1), (2, 3)] def test_dfs_edges_sorting(self): G = nx.Graph([(0, 1), (1, 2), (1, 3), (2, 4), (3, 0), (0, 4)]) edges_asc = nx.dfs_edges(G, source=0, sort_neighbors=sorted) sorted_desc = lambda x: sorted(x, reverse=True) edges_desc = nx.dfs_edges(G, source=0, sort_neighbors=sorted_desc) assert list(edges_asc) == [(0, 1), (1, 2), (2, 4), (1, 3)] assert list(edges_desc) == [(0, 4), (4, 2), (2, 1), (1, 3)] def test_dfs_labeled_edges(self): edges = list(nx.dfs_labeled_edges(self.G, source=0)) forward = [(u, v) for (u, v, d) in edges if d == "forward"] assert forward == [(0, 0), (0, 1), (1, 2), (2, 4), (1, 3)] assert edges == [ (0, 0, "forward"), (0, 1, "forward"), (1, 0, "nontree"), (1, 2, "forward"), (2, 1, "nontree"), (2, 4, "forward"), (4, 2, "nontree"), (4, 0, "nontree"), (2, 4, "reverse"), (1, 2, "reverse"), (1, 3, "forward"), (3, 1, "nontree"), (3, 0, "nontree"), (1, 3, "reverse"), (0, 1, "reverse"), (0, 3, "nontree"), (0, 4, "nontree"), (0, 0, "reverse"), ] def test_dfs_labeled_edges_sorting(self): G = nx.Graph([(0, 1), (1, 2), (1, 3), (2, 4), (3, 0), (0, 4)]) edges_asc = nx.dfs_labeled_edges(G, source=0, sort_neighbors=sorted) sorted_desc = lambda x: sorted(x, reverse=True) edges_desc = nx.dfs_labeled_edges(G, source=0, sort_neighbors=sorted_desc) assert list(edges_asc) == [ (0, 0, "forward"), (0, 1, "forward"), (1, 0, "nontree"), (1, 2, "forward"), (2, 1, "nontree"), (2, 4, "forward"), (4, 0, "nontree"), (4, 2, "nontree"), (2, 4, "reverse"), (1, 2, "reverse"), (1, 3, "forward"), (3, 0, "nontree"), (3, 1, "nontree"), (1, 3, "reverse"), (0, 1, "reverse"), (0, 3, "nontree"), (0, 4, "nontree"), (0, 0, "reverse"), ] assert list(edges_desc) == [ (0, 0, "forward"), (0, 4, "forward"), (4, 2, "forward"), (2, 4, "nontree"), (2, 1, "forward"), (1, 3, "forward"), (3, 1, "nontree"), (3, 0, "nontree"), (1, 3, "reverse"), (1, 2, "nontree"), (1, 0, "nontree"), (2, 1, "reverse"), (4, 2, "reverse"), (4, 0, "nontree"), (0, 4, "reverse"), (0, 3, "nontree"), (0, 1, "nontree"), (0, 0, "reverse"), ] def test_dfs_labeled_disconnected_edges(self): edges = list(nx.dfs_labeled_edges(self.D)) forward = [(u, v) for (u, v, d) in edges if d == "forward"] assert forward == [(0, 0), (0, 1), (2, 2), (2, 3)] assert edges == [ (0, 0, "forward"), (0, 1, "forward"), (1, 0, "nontree"), (0, 1, "reverse"), (0, 0, "reverse"), (2, 2, "forward"), (2, 3, "forward"), (3, 2, "nontree"), (2, 3, "reverse"), (2, 2, "reverse"), ] def test_dfs_tree_isolates(self): G = nx.Graph() G.add_node(1) G.add_node(2) T = nx.dfs_tree(G, source=1) assert sorted(T.nodes()) == [1] assert sorted(T.edges()) == [] T = nx.dfs_tree(G, source=None) assert sorted(T.nodes()) == [1, 2] assert sorted(T.edges()) == [] class TestDepthLimitedSearch: @classmethod def setup_class(cls): # a tree G = nx.Graph() nx.add_path(G, [0, 1, 2, 3, 4, 5, 6]) nx.add_path(G, [2, 7, 8, 9, 10]) cls.G = G # a disconnected graph D = nx.Graph() D.add_edges_from([(0, 1), (2, 3)]) nx.add_path(D, [2, 7, 8, 9, 10]) cls.D = D def test_dls_preorder_nodes(self): assert list(nx.dfs_preorder_nodes(self.G, source=0, depth_limit=2)) == [0, 1, 2] assert list(nx.dfs_preorder_nodes(self.D, source=1, depth_limit=2)) == ([1, 0]) def test_dls_postorder_nodes(self): assert list(nx.dfs_postorder_nodes(self.G, source=3, depth_limit=3)) == [ 1, 7, 2, 5, 4, 3, ] assert list(nx.dfs_postorder_nodes(self.D, source=2, depth_limit=2)) == ( [3, 7, 2] ) def test_dls_successor(self): result = nx.dfs_successors(self.G, source=4, depth_limit=3) assert {n: set(v) for n, v in result.items()} == { 2: {1, 7}, 3: {2}, 4: {3, 5}, 5: {6}, } result = nx.dfs_successors(self.D, source=7, depth_limit=2) assert {n: set(v) for n, v in result.items()} == {8: {9}, 2: {3}, 7: {8, 2}} def test_dls_predecessor(self): assert nx.dfs_predecessors(self.G, source=0, depth_limit=3) == { 1: 0, 2: 1, 3: 2, 7: 2, } assert nx.dfs_predecessors(self.D, source=2, depth_limit=3) == { 8: 7, 9: 8, 3: 2, 7: 2, } def test_dls_tree(self): T = nx.dfs_tree(self.G, source=3, depth_limit=1) assert sorted(T.edges()) == [(3, 2), (3, 4)] def test_dls_edges(self): edges = nx.dfs_edges(self.G, source=9, depth_limit=4) assert list(edges) == [(9, 8), (8, 7), (7, 2), (2, 1), (2, 3), (9, 10)] def test_dls_labeled_edges_depth_1(self): edges = list(nx.dfs_labeled_edges(self.G, source=5, depth_limit=1)) forward = [(u, v) for (u, v, d) in edges if d == "forward"] assert forward == [(5, 5), (5, 4), (5, 6)] # Note: reverse-depth_limit edge types were not reported before gh-6240 assert edges == [ (5, 5, "forward"), (5, 4, "forward"), (5, 4, "reverse-depth_limit"), (5, 6, "forward"), (5, 6, "reverse-depth_limit"), (5, 5, "reverse"), ] def test_dls_labeled_edges_depth_2(self): edges = list(nx.dfs_labeled_edges(self.G, source=6, depth_limit=2)) forward = [(u, v) for (u, v, d) in edges if d == "forward"] assert forward == [(6, 6), (6, 5), (5, 4)] assert edges == [ (6, 6, "forward"), (6, 5, "forward"), (5, 4, "forward"), (5, 4, "reverse-depth_limit"), (5, 6, "nontree"), (6, 5, "reverse"), (6, 6, "reverse"), ] def test_dls_labeled_disconnected_edges(self): edges = list(nx.dfs_labeled_edges(self.D, depth_limit=1)) assert edges == [ (0, 0, "forward"), (0, 1, "forward"), (0, 1, "reverse-depth_limit"), (0, 0, "reverse"), (2, 2, "forward"), (2, 3, "forward"), (2, 3, "reverse-depth_limit"), (2, 7, "forward"), (2, 7, "reverse-depth_limit"), (2, 2, "reverse"), (8, 8, "forward"), (8, 7, "nontree"), (8, 9, "forward"), (8, 9, "reverse-depth_limit"), (8, 8, "reverse"), (10, 10, "forward"), (10, 9, "nontree"), (10, 10, "reverse"), ] # large depth_limit has no impact edges = list(nx.dfs_labeled_edges(self.D, depth_limit=19)) assert edges == [ (0, 0, "forward"), (0, 1, "forward"), (1, 0, "nontree"), (0, 1, "reverse"), (0, 0, "reverse"), (2, 2, "forward"), (2, 3, "forward"), (3, 2, "nontree"), (2, 3, "reverse"), (2, 7, "forward"), (7, 2, "nontree"), (7, 8, "forward"), (8, 7, "nontree"), (8, 9, "forward"), (9, 8, "nontree"), (9, 10, "forward"), (10, 9, "nontree"), (9, 10, "reverse"), (8, 9, "reverse"), (7, 8, "reverse"), (2, 7, "reverse"), (2, 2, "reverse"), ]