diff options
Diffstat (limited to 'python/altgraph/altgraph_tests/test_graph.py')
| -rw-r--r-- | python/altgraph/altgraph_tests/test_graph.py | 644 |
1 files changed, 644 insertions, 0 deletions
diff --git a/python/altgraph/altgraph_tests/test_graph.py b/python/altgraph/altgraph_tests/test_graph.py new file mode 100644 index 000000000..553549f5a --- /dev/null +++ b/python/altgraph/altgraph_tests/test_graph.py @@ -0,0 +1,644 @@ +import unittest + +from altgraph import GraphError +from altgraph.Graph import Graph + +class TestGraph (unittest.TestCase): + + def test_nodes(self): + graph = Graph() + + self.assertEqual(graph.node_list(), []) + + o1 = object() + o1b = object() + o2 = object() + graph.add_node(1, o1) + graph.add_node(1, o1b) + graph.add_node(2, o2) + graph.add_node(3) + + self.assertRaises(TypeError, graph.add_node, []) + + self.assertTrue(graph.node_data(1) is o1) + self.assertTrue(graph.node_data(2) is o2) + self.assertTrue(graph.node_data(3) is None) + + self.assertTrue(1 in graph) + self.assertTrue(2 in graph) + self.assertTrue(3 in graph) + + self.assertEqual(graph.number_of_nodes(), 3) + self.assertEqual(graph.number_of_hidden_nodes(), 0) + self.assertEqual(graph.hidden_node_list(), []) + self.assertEqual(list(sorted(graph)), [1, 2, 3]) + + graph.hide_node(1) + graph.hide_node(2) + graph.hide_node(3) + + + self.assertEqual(graph.number_of_nodes(), 0) + self.assertEqual(graph.number_of_hidden_nodes(), 3) + self.assertEqual(list(sorted(graph.hidden_node_list())), [1, 2, 3]) + + self.assertFalse(1 in graph) + self.assertFalse(2 in graph) + self.assertFalse(3 in graph) + + graph.add_node(1) + self.assertFalse(1 in graph) + + graph.restore_node(1) + self.assertTrue(1 in graph) + self.assertFalse(2 in graph) + self.assertFalse(3 in graph) + + graph.restore_all_nodes() + self.assertTrue(1 in graph) + self.assertTrue(2 in graph) + self.assertTrue(3 in graph) + + self.assertEqual(list(sorted(graph.node_list())), [1, 2, 3]) + + v = graph.describe_node(1) + self.assertEqual(v, (1, o1, [], [])) + + def test_edges(self): + graph = Graph() + graph.add_node(1) + graph.add_node(2) + graph.add_node(3) + graph.add_node(4) + graph.add_node(5) + + self.assertTrue(isinstance(graph.edge_list(), list)) + + graph.add_edge(1, 2) + graph.add_edge(4, 5, 'a') + + self.assertRaises(GraphError, graph.add_edge, 'a', 'b', create_nodes=False) + + self.assertEqual(graph.number_of_hidden_edges(), 0) + self.assertEqual(graph.number_of_edges(), 2) + e = graph.edge_by_node(1, 2) + self.assertTrue(isinstance(e, int)) + graph.hide_edge(e) + self.assertEqual(graph.number_of_hidden_edges(), 1) + self.assertEqual(graph.number_of_edges(), 1) + e2 = graph.edge_by_node(1, 2) + self.assertTrue(e2 is None) + + graph.restore_edge(e) + e2 = graph.edge_by_node(1, 2) + self.assertEqual(e, e2) + self.assertEqual(graph.number_of_hidden_edges(), 0) + + self.assertEqual(graph.number_of_edges(), 2) + + e1 = graph.edge_by_node(1, 2) + e2 = graph.edge_by_node(4, 5) + graph.hide_edge(e1) + graph.hide_edge(e2) + + self.assertEqual(graph.number_of_edges(), 0) + graph.restore_all_edges() + self.assertEqual(graph.number_of_edges(), 2) + + self.assertEqual(graph.edge_by_id(e1), (1,2)) + self.assertRaises(GraphError, graph.edge_by_id, (e1+1)*(e2+1)+1) + + self.assertEqual(list(sorted(graph.edge_list())), [e1, e2]) + + self.assertEqual(graph.describe_edge(e1), (e1, 1, 1, 2)) + self.assertEqual(graph.describe_edge(e2), (e2, 'a', 4, 5)) + + self.assertEqual(graph.edge_data(e1), 1) + self.assertEqual(graph.edge_data(e2), 'a') + + self.assertEqual(graph.head(e2), 4) + self.assertEqual(graph.tail(e2), 5) + + graph.add_edge(1, 3) + graph.add_edge(1, 5) + graph.add_edge(4, 1) + + self.assertEqual(list(sorted(graph.out_nbrs(1))), [2, 3, 5]) + self.assertEqual(list(sorted(graph.inc_nbrs(1))), [4]) + self.assertEqual(list(sorted(graph.inc_nbrs(5))), [1, 4]) + self.assertEqual(list(sorted(graph.all_nbrs(1))), [2, 3, 4, 5]) + + graph.add_edge(5, 1) + self.assertEqual(list(sorted(graph.all_nbrs(5))), [1, 4]) + + self.assertEqual(graph.out_degree(1), 3) + self.assertEqual(graph.inc_degree(2), 1) + self.assertEqual(graph.inc_degree(5), 2) + self.assertEqual(graph.all_degree(5), 3) + + v = graph.out_edges(4) + self.assertTrue(isinstance(v, list)) + self.assertEqual(graph.edge_by_id(v[0]), (4, 5)) + + v = graph.out_edges(1) + for e in v: + self.assertEqual(graph.edge_by_id(e)[0], 1) + + v = graph.inc_edges(1) + self.assertTrue(isinstance(v, list)) + self.assertEqual(graph.edge_by_id(v[0]), (4, 1)) + + v = graph.inc_edges(5) + for e in v: + self.assertEqual(graph.edge_by_id(e)[1], 5) + + v = graph.all_edges(5) + for e in v: + self.assertTrue(graph.edge_by_id(e)[1] == 5 or graph.edge_by_id(e)[0] == 5) + + e1 = graph.edge_by_node(1, 2) + self.assertTrue(isinstance(e1, int)) + graph.hide_node(1) + self.assertRaises(GraphError, graph.edge_by_node, 1, 2) + graph.restore_node(1) + e2 = graph.edge_by_node(1, 2) + self.assertEqual(e1, e2) + + + + def test_toposort(self): + graph = Graph() + graph.add_node(1) + graph.add_node(2) + graph.add_node(3) + graph.add_node(4) + graph.add_node(5) + + graph.add_edge(1, 2) + graph.add_edge(1, 3) + graph.add_edge(2, 4) + graph.add_edge(3, 5) + + ok, result = graph.forw_topo_sort() + self.assertTrue(ok) + for idx in range(1, 6): + self.assertTrue(idx in result) + + self.assertTrue(result.index(1) < result.index(2)) + self.assertTrue(result.index(1) < result.index(3)) + self.assertTrue(result.index(2) < result.index(4)) + self.assertTrue(result.index(3) < result.index(5)) + + ok, result = graph.back_topo_sort() + self.assertTrue(ok) + for idx in range(1, 6): + self.assertTrue(idx in result) + self.assertTrue(result.index(2) < result.index(1)) + self.assertTrue(result.index(3) < result.index(1)) + self.assertTrue(result.index(4) < result.index(2)) + self.assertTrue(result.index(5) < result.index(3)) + + + # Same graph as before, but with edges + # reversed, which means we should get + # the same results as before if using + # back_topo_sort rather than forw_topo_sort + # (and v.v.) + + graph = Graph() + graph.add_node(1) + graph.add_node(2) + graph.add_node(3) + graph.add_node(4) + graph.add_node(5) + + graph.add_edge(2, 1) + graph.add_edge(3, 1) + graph.add_edge(4, 2) + graph.add_edge(5, 3) + + ok, result = graph.back_topo_sort() + self.assertTrue(ok) + for idx in range(1, 6): + self.assertTrue(idx in result) + + self.assertTrue(result.index(1) < result.index(2)) + self.assertTrue(result.index(1) < result.index(3)) + self.assertTrue(result.index(2) < result.index(4)) + self.assertTrue(result.index(3) < result.index(5)) + + ok, result = graph.forw_topo_sort() + self.assertTrue(ok) + for idx in range(1, 6): + self.assertTrue(idx in result) + self.assertTrue(result.index(2) < result.index(1)) + self.assertTrue(result.index(3) < result.index(1)) + self.assertTrue(result.index(4) < result.index(2)) + self.assertTrue(result.index(5) < result.index(3)) + + + # Create a cycle + graph.add_edge(1, 5) + ok, result = graph.forw_topo_sort() + self.assertFalse(ok) + ok, result = graph.back_topo_sort() + self.assertFalse(ok) + + def test_bfs_subgraph(self): + graph = Graph() + graph.add_edge(1, 2) + graph.add_edge(1, 4) + graph.add_edge(2, 4) + graph.add_edge(4, 8) + graph.add_edge(4, 9) + graph.add_edge(4, 10) + graph.add_edge(8, 10) + + subgraph = graph.forw_bfs_subgraph(10) + self.assertTrue(isinstance(subgraph, Graph)) + self.assertEqual(subgraph.number_of_nodes(), 1) + self.assertTrue(10 in subgraph) + self.assertEqual(subgraph.number_of_edges(), 0) + + subgraph = graph.forw_bfs_subgraph(4) + self.assertTrue(isinstance(subgraph, Graph)) + self.assertEqual(subgraph.number_of_nodes(), 4) + self.assertTrue(4 in subgraph) + self.assertTrue(8 in subgraph) + self.assertTrue(9 in subgraph) + self.assertTrue(10 in subgraph) + self.assertEqual(subgraph.number_of_edges(), 4) + e = subgraph.edge_by_node(4, 8) + e = subgraph.edge_by_node(4, 9) + e = subgraph.edge_by_node(4, 10) + e = subgraph.edge_by_node(8, 10) + + # same graph as before, but switch around + # edges. This results in the same test results + # but now for back_bfs_subgraph rather than + # forw_bfs_subgraph + + graph = Graph() + graph.add_edge(2, 1) + graph.add_edge(4, 1) + graph.add_edge(4, 2) + graph.add_edge(8, 4) + graph.add_edge(9, 4) + graph.add_edge(10, 4) + graph.add_edge(10, 8) + + subgraph = graph.back_bfs_subgraph(10) + self.assertTrue(isinstance(subgraph, Graph)) + self.assertEqual(subgraph.number_of_nodes(), 1) + self.assertTrue(10 in subgraph) + self.assertEqual(subgraph.number_of_edges(), 0) + + subgraph = graph.back_bfs_subgraph(4) + self.assertTrue(isinstance(subgraph, Graph)) + self.assertEqual(subgraph.number_of_nodes(), 4) + self.assertTrue(4 in subgraph) + self.assertTrue(8 in subgraph) + self.assertTrue(9 in subgraph) + self.assertTrue(10 in subgraph) + self.assertEqual(subgraph.number_of_edges(), 4) + e = subgraph.edge_by_node(4, 8) + e = subgraph.edge_by_node(4, 9) + e = subgraph.edge_by_node(4, 10) + e = subgraph.edge_by_node(8, 10) + + def test_iterdfs(self): + graph = Graph() + graph.add_edge("1", "1.1") + graph.add_edge("1", "1.2") + graph.add_edge("1", "1.3") + graph.add_edge("1.1", "1.1.1") + graph.add_edge("1.1", "1.1.2") + graph.add_edge("1.2", "1.2.1") + graph.add_edge("1.2", "1.2.2") + graph.add_edge("1.2.2", "1.2.2.1") + graph.add_edge("1.2.2", "1.2.2.2") + graph.add_edge("1.2.2", "1.2.2.3") + + result = list(graph.iterdfs("1")) + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1', '1.1', '1.1.2', '1.1.1' + ]) + result = list(graph.iterdfs("1", "1.2.1")) + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1' + ]) + + result = graph.forw_dfs("1") + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1', '1.1', '1.1.2', '1.1.1' + ]) + result = graph.forw_dfs("1", "1.2.1") + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1' + ]) + + graph = Graph() + graph.add_edge("1.1", "1") + graph.add_edge("1.2", "1") + graph.add_edge("1.3", "1") + graph.add_edge("1.1.1", "1.1") + graph.add_edge("1.1.2", "1.1") + graph.add_edge("1.2.1", "1.2") + graph.add_edge("1.2.2", "1.2") + graph.add_edge("1.2.2.1", "1.2.2") + graph.add_edge("1.2.2.2", "1.2.2") + graph.add_edge("1.2.2.3", "1.2.2") + + result = list(graph.iterdfs("1", forward=False)) + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1', '1.1', '1.1.2', '1.1.1' + ]) + result = list(graph.iterdfs("1", "1.2.1", forward=False)) + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1' + ]) + result = graph.back_dfs("1") + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1', '1.1', '1.1.2', '1.1.1' + ]) + result = graph.back_dfs("1", "1.2.1") + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1' + ]) + + + # Introduce cyle: + graph.add_edge("1", "1.2") + result = list(graph.iterdfs("1", forward=False)) + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1', '1.1', '1.1.2', '1.1.1' + ]) + + result = graph.back_dfs("1") + self.assertEqual(result, [ + '1', '1.3', '1.2', '1.2.2', '1.2.2.3', '1.2.2.2', + '1.2.2.1', '1.2.1', '1.1', '1.1.2', '1.1.1' + ]) + + + def test_iterdata(self): + graph = Graph() + graph.add_node("1", "I") + graph.add_node("1.1", "I.I") + graph.add_node("1.2", "I.II") + graph.add_node("1.3", "I.III") + graph.add_node("1.1.1", "I.I.I") + graph.add_node("1.1.2", "I.I.II") + graph.add_node("1.2.1", "I.II.I") + graph.add_node("1.2.2", "I.II.II") + graph.add_node("1.2.2.1", "I.II.II.I") + graph.add_node("1.2.2.2", "I.II.II.II") + graph.add_node("1.2.2.3", "I.II.II.III") + + graph.add_edge("1", "1.1") + graph.add_edge("1", "1.2") + graph.add_edge("1", "1.3") + graph.add_edge("1.1", "1.1.1") + graph.add_edge("1.1", "1.1.2") + graph.add_edge("1.2", "1.2.1") + graph.add_edge("1.2", "1.2.2") + graph.add_edge("1.2.2", "1.2.2.1") + graph.add_edge("1.2.2", "1.2.2.2") + graph.add_edge("1.2.2", "1.2.2.3") + + result = list(graph.iterdata("1", forward=True)) + self.assertEqual(result, [ + 'I', 'I.III', 'I.II', 'I.II.II', 'I.II.II.III', 'I.II.II.II', + 'I.II.II.I', 'I.II.I', 'I.I', 'I.I.II', 'I.I.I' + ]) + + result = list(graph.iterdata("1", end="1.2.1", forward=True)) + self.assertEqual(result, [ + 'I', 'I.III', 'I.II', 'I.II.II', 'I.II.II.III', 'I.II.II.II', + 'I.II.II.I', 'I.II.I' + ]) + + result = list(graph.iterdata("1", condition=lambda n: len(n) < 6, forward=True)) + self.assertEqual(result, [ + 'I', 'I.III', 'I.II', + 'I.I', 'I.I.I' + ]) + + + # And the revese option: + graph = Graph() + graph.add_node("1", "I") + graph.add_node("1.1", "I.I") + graph.add_node("1.2", "I.II") + graph.add_node("1.3", "I.III") + graph.add_node("1.1.1", "I.I.I") + graph.add_node("1.1.2", "I.I.II") + graph.add_node("1.2.1", "I.II.I") + graph.add_node("1.2.2", "I.II.II") + graph.add_node("1.2.2.1", "I.II.II.I") + graph.add_node("1.2.2.2", "I.II.II.II") + graph.add_node("1.2.2.3", "I.II.II.III") + + graph.add_edge("1.1", "1") + graph.add_edge("1.2", "1") + graph.add_edge("1.3", "1") + graph.add_edge("1.1.1", "1.1") + graph.add_edge("1.1.2", "1.1") + graph.add_edge("1.2.1", "1.2") + graph.add_edge("1.2.2", "1.2") + graph.add_edge("1.2.2.1", "1.2.2") + graph.add_edge("1.2.2.2", "1.2.2") + graph.add_edge("1.2.2.3", "1.2.2") + + result = list(graph.iterdata("1", forward=False)) + self.assertEqual(result, [ + 'I', 'I.III', 'I.II', 'I.II.II', 'I.II.II.III', 'I.II.II.II', + 'I.II.II.I', 'I.II.I', 'I.I', 'I.I.II', 'I.I.I' + ]) + + result = list(graph.iterdata("1", end="1.2.1", forward=False)) + self.assertEqual(result, [ + 'I', 'I.III', 'I.II', 'I.II.II', 'I.II.II.III', 'I.II.II.II', + 'I.II.II.I', 'I.II.I' + ]) + + result = list(graph.iterdata("1", condition=lambda n: len(n) < 6, forward=False)) + self.assertEqual(result, [ + 'I', 'I.III', 'I.II', + 'I.I', 'I.I.I' + ]) + + def test_bfs(self): + graph = Graph() + graph.add_edge("1", "1.1") + graph.add_edge("1.1", "1.1.1") + graph.add_edge("1.1", "1.1.2") + graph.add_edge("1.1.2", "1.1.2.1") + graph.add_edge("1.1.2", "1.1.2.2") + graph.add_edge("1", "1.2") + graph.add_edge("1", "1.3") + graph.add_edge("1.2", "1.2.1") + + self.assertEqual(graph.forw_bfs("1"), + ['1', '1.1', '1.2', '1.3', '1.1.1', '1.1.2', '1.2.1', '1.1.2.1', '1.1.2.2']) + self.assertEqual(graph.forw_bfs("1", "1.1.1"), + ['1', '1.1', '1.2', '1.3', '1.1.1']) + + + # And the "reverse" graph + graph = Graph() + graph.add_edge("1.1", "1") + graph.add_edge("1.1.1", "1.1") + graph.add_edge("1.1.2", "1.1") + graph.add_edge("1.1.2.1", "1.1.2") + graph.add_edge("1.1.2.2", "1.1.2") + graph.add_edge("1.2", "1") + graph.add_edge("1.3", "1") + graph.add_edge("1.2.1", "1.2") + + self.assertEqual(graph.back_bfs("1"), + ['1', '1.1', '1.2', '1.3', '1.1.1', '1.1.2', '1.2.1', '1.1.2.1', '1.1.2.2']) + self.assertEqual(graph.back_bfs("1", "1.1.1"), + ['1', '1.1', '1.2', '1.3', '1.1.1']) + + + + # check cycle handling + graph.add_edge("1", "1.2.1") + self.assertEqual(graph.back_bfs("1"), + ['1', '1.1', '1.2', '1.3', '1.1.1', '1.1.2', '1.2.1', '1.1.2.1', '1.1.2.2']) + + + def test_connected(self): + graph = Graph() + graph.add_node(1) + graph.add_node(2) + graph.add_node(3) + graph.add_node(4) + + self.assertFalse(graph.connected()) + + graph.add_edge(1, 2) + graph.add_edge(3, 4) + self.assertFalse(graph.connected()) + + graph.add_edge(2, 3) + graph.add_edge(4, 1) + self.assertTrue(graph.connected()) + + def test_edges_complex(self): + g = Graph() + g.add_edge(1, 2) + e = g.edge_by_node(1,2) + g.hide_edge(e) + g.hide_node(2) + self.assertRaises(GraphError, g.restore_edge, e) + + g.restore_all_edges() + self.assertRaises(GraphError, g.edge_by_id, e) + + def test_clust_coef(self): + g = Graph() + g.add_edge(1, 2) + g.add_edge(1, 3) + g.add_edge(1, 4) + self.assertEqual(g.clust_coef(1), 0) + + g.add_edge(2, 5) + g.add_edge(3, 5) + g.add_edge(4, 5) + self.assertEqual(g.clust_coef(1), 0) + + g.add_edge(2, 3) + self.assertEqual(g.clust_coef(1), 1./6) + g.add_edge(2, 4) + self.assertEqual(g.clust_coef(1), 2./6) + g.add_edge(4, 2) + self.assertEqual(g.clust_coef(1), 3./6) + + g.add_edge(2, 3) + g.add_edge(2, 4) + g.add_edge(3, 4) + g.add_edge(3, 2) + g.add_edge(4, 2) + g.add_edge(4, 3) + self.assertEqual(g.clust_coef(1), 1) + + + def test_get_hops(self): + graph = Graph() + graph.add_edge(1, 2) + graph.add_edge(1, 3) + graph.add_edge(2, 4) + graph.add_edge(4, 5) + graph.add_edge(5, 7) + graph.add_edge(7, 8) + + self.assertEqual(graph.get_hops(1), + [(1, 0), (2, 1), (3, 1), (4, 2), (5, 3), (7, 4), (8, 5)]) + + self.assertEqual(graph.get_hops(1, 5), + [(1, 0), (2, 1), (3, 1), (4, 2), (5, 3)]) + + graph.add_edge(5, 1) + graph.add_edge(7, 1) + graph.add_edge(7, 4) + + self.assertEqual(graph.get_hops(1), + [(1, 0), (2, 1), (3, 1), (4, 2), (5, 3), (7, 4), (8, 5)]) + + # And the reverse graph + graph = Graph() + graph.add_edge(2, 1) + graph.add_edge(3, 1) + graph.add_edge(4, 2) + graph.add_edge(5, 4) + graph.add_edge(7, 5) + graph.add_edge(8, 7) + + self.assertEqual(graph.get_hops(1, forward=False), + [(1, 0), (2, 1), (3, 1), (4, 2), (5, 3), (7, 4), (8, 5)]) + + self.assertEqual(graph.get_hops(1, 5, forward=False), + [(1, 0), (2, 1), (3, 1), (4, 2), (5, 3)]) + + graph.add_edge(1, 5) + graph.add_edge(1, 7) + graph.add_edge(4, 7) + + self.assertEqual(graph.get_hops(1, forward=False), + [(1, 0), (2, 1), (3, 1), (4, 2), (5, 3), (7, 4), (8, 5)]) + + + def test_constructor(self): + graph = Graph(iter([ + (1, 2), + (2, 3, 'a'), + (1, 3), + (3, 4), + ])) + self.assertEqual(graph.number_of_nodes(), 4) + self.assertEqual(graph.number_of_edges(), 4) + try: + graph.edge_by_node(1,2) + graph.edge_by_node(2,3) + graph.edge_by_node(1,3) + graph.edge_by_node(3,4) + except GraphError: + self.fail("Incorrect graph") + + self.assertEqual(graph.edge_data(graph.edge_by_node(2, 3)), 'a') + + self.assertRaises(GraphError, Graph, [(1,2,3,4)]) + +if __name__ == "__main__": # pragma: no cover + unittest.main() |