class TestUndirectedGraphTriangulation(unittest.TestCase): def setUp(self): self.graph = MarkovModel() def test_check_clique(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'a')]) self.assertTrue(self.graph.check_clique(['a', 'b', 'c'])) def test_is_triangulated(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'a')]) self.assertTrue(self.graph.is_triangulated()) def test_triangulation_h1_inplace(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) self.graph.triangulate(heuristic='H1', inplace=True) self.assertTrue(self.graph.is_triangulated()) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['a', 'c'], ['a', 'd'], ['b', 'c'], ['c', 'd']]) def test_triangulation_h2_inplace(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) self.graph.triangulate(heuristic='H2', inplace=True) self.assertTrue(self.graph.is_triangulated()) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['a', 'c'], ['a', 'd'], ['b', 'c'], ['c', 'd']]) def test_triangulation_h3_inplace(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) self.graph.triangulate(heuristic='H3', inplace=True) self.assertTrue(self.graph.is_triangulated()) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_triangulation_h4_inplace(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) self.graph.triangulate(heuristic='H4', inplace=True) self.assertTrue(self.graph.is_triangulated()) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_triangulation_h5_inplace(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) self.graph.triangulate(heuristic='H4', inplace=True) self.assertTrue(self.graph.is_triangulated()) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_triangulation_h6_inplace(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) self.graph.triangulate(heuristic='H4', inplace=True) self.assertTrue(self.graph.is_triangulated()) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_cardinality_mismatch_raises_error(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) factor_list = [ DiscreteFactor(edge, [2, 2], np.random.rand(4)) for edge in self.graph.edges() ] self.graph.add_factors(*factor_list) self.graph.add_factors( DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6))) self.assertRaises(ValueError, self.graph.triangulate) def test_triangulation_h1_create_new(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) H = self.graph.triangulate(heuristic='H1', inplace=True) self.assertListEqual( hf.recursive_sorted(H.edges()), [['a', 'b'], ['a', 'c'], ['a', 'd'], ['b', 'c'], ['c', 'd']]) def test_triangulation_h2_create_new(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) H = self.graph.triangulate(heuristic='H2', inplace=True) self.assertListEqual( hf.recursive_sorted(H.edges()), [['a', 'b'], ['a', 'c'], ['a', 'd'], ['b', 'c'], ['c', 'd']]) def test_triangulation_h3_create_new(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) H = self.graph.triangulate(heuristic='H3', inplace=True) self.assertListEqual( hf.recursive_sorted(H.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_triangulation_h4_create_new(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) H = self.graph.triangulate(heuristic='H4', inplace=True) self.assertListEqual( hf.recursive_sorted(H.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_triangulation_h5_create_new(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) H = self.graph.triangulate(heuristic='H5', inplace=True) self.assertListEqual( hf.recursive_sorted(H.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_triangulation_h6_create_new(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c'), ('c', 'd'), ('d', 'a')]) phi1 = DiscreteFactor(['a', 'b'], [2, 3], np.random.rand(6)) phi2 = DiscreteFactor(['b', 'c'], [3, 4], np.random.rand(12)) phi3 = DiscreteFactor(['c', 'd'], [4, 5], np.random.rand(20)) phi4 = DiscreteFactor(['d', 'a'], [5, 2], np.random.random(10)) self.graph.add_factors(phi1, phi2, phi3, phi4) H = self.graph.triangulate(heuristic='H6', inplace=True) self.assertListEqual( hf.recursive_sorted(H.edges()), [['a', 'b'], ['a', 'd'], ['b', 'c'], ['b', 'd'], ['c', 'd']]) def test_copy(self): # Setup the original graph self.graph.add_nodes_from(['a', 'b']) self.graph.add_edges_from([('a', 'b')]) # Generate the copy copy = self.graph.copy() # Ensure the copied model is correct self.assertTrue(copy.check_model()) # Basic sanity checks to ensure the graph was copied correctly self.assertEqual(len(copy.nodes()), 2) self.assertListEqual(copy.neighbors('a'), ['b']) self.assertListEqual(copy.neighbors('b'), ['a']) # Modify the original graph ... self.graph.add_nodes_from(['c']) self.graph.add_edges_from([('c', 'b')]) # ... and ensure none of those changes get propagated self.assertEqual(len(copy.nodes()), 2) self.assertListEqual(copy.neighbors('a'), ['b']) self.assertListEqual(copy.neighbors('b'), ['a']) with self.assertRaises(nx.NetworkXError): copy.neighbors('c') # Ensure the copy has no factors at this point self.assertEqual(len(copy.get_factors()), 0) # Add factors to the original graph phi1 = DiscreteFactor(['a', 'b'], [2, 2], [[0.3, 0.7], [0.9, 0.1]]) self.graph.add_factors(phi1) # The factors should not get copied over with self.assertRaises(AssertionError): self.assertListEqual(copy.get_factors(), self.graph.get_factors()) # Create a fresh copy del copy copy = self.graph.copy() self.assertListEqual(copy.get_factors(), self.graph.get_factors()) # If we change factors in the original, it should not be passed to the clone phi1.values = np.array([[0.5, 0.5], [0.5, 0.5]]) self.assertNotEqual(self.graph.get_factors(), copy.get_factors()) # Start with a fresh copy del copy self.graph.add_nodes_from(['d']) copy = self.graph.copy() # Ensure an unconnected node gets copied over as well self.assertEqual(len(copy.nodes()), 4) self.assertListEqual(self.graph.neighbors('a'), ['b']) self.assertTrue('a' in self.graph.neighbors('b')) self.assertTrue('c' in self.graph.neighbors('b')) self.assertListEqual(self.graph.neighbors('c'), ['b']) self.assertListEqual(self.graph.neighbors('d'), []) # Verify that changing the copied model should not update the original copy.add_nodes_from(['e']) self.assertListEqual(copy.neighbors('e'), []) with self.assertRaises(nx.NetworkXError): self.graph.neighbors('e') # Verify that changing edges in the copy doesn't create edges in the original copy.add_edges_from([('d', 'b')]) self.assertTrue('a' in copy.neighbors('b')) self.assertTrue('c' in copy.neighbors('b')) self.assertTrue('d' in copy.neighbors('b')) self.assertTrue('a' in self.graph.neighbors('b')) self.assertTrue('c' in self.graph.neighbors('b')) self.assertFalse('d' in self.graph.neighbors('b')) # If we remove factors from the copied model, it should not reflect in the original copy.remove_factors(phi1) self.assertEqual(len(self.graph.get_factors()), 1) self.assertEqual(len(copy.get_factors()), 0) def tearDown(self): del self.graph
class TestMarkovModelCreation(unittest.TestCase): def setUp(self): self.graph = MarkovModel() def test_class_init_without_data(self): self.assertIsInstance(self.graph, MarkovModel) def test_class_init_with_data_string(self): self.g = MarkovModel([('a', 'b'), ('b', 'c')]) self.assertListEqual(sorted(self.g.nodes()), ['a', 'b', 'c']) self.assertListEqual(hf.recursive_sorted(self.g.edges()), [['a', 'b'], ['b', 'c']]) def test_class_init_with_data_nonstring(self): self.g = MarkovModel([(1, 2), (2, 3)]) def test_add_node_string(self): self.graph.add_node('a') self.assertListEqual(self.graph.nodes(), ['a']) def test_add_node_nonstring(self): self.graph.add_node(1) def test_add_nodes_from_string(self): self.graph.add_nodes_from(['a', 'b', 'c', 'd']) self.assertListEqual(sorted(self.graph.nodes()), ['a', 'b', 'c', 'd']) def test_add_nodes_from_non_string(self): self.graph.add_nodes_from([1, 2, 3, 4]) def test_add_edge_string(self): self.graph.add_edge('d', 'e') self.assertListEqual(sorted(self.graph.nodes()), ['d', 'e']) self.assertListEqual(hf.recursive_sorted(self.graph.edges()), [['d', 'e']]) self.graph.add_nodes_from(['a', 'b', 'c']) self.graph.add_edge('a', 'b') self.assertListEqual(hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['d', 'e']]) def test_add_edge_nonstring(self): self.graph.add_edge(1, 2) def test_add_edge_selfloop(self): self.assertRaises(ValueError, self.graph.add_edge, 'a', 'a') def test_add_edges_from_string(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c')]) self.assertListEqual(sorted(self.graph.nodes()), ['a', 'b', 'c']) self.assertListEqual(hf.recursive_sorted(self.graph.edges()), [['a', 'b'], ['b', 'c']]) self.graph.add_nodes_from(['d', 'e', 'f']) self.graph.add_edges_from([('d', 'e'), ('e', 'f')]) self.assertListEqual(sorted(self.graph.nodes()), ['a', 'b', 'c', 'd', 'e', 'f']) self.assertListEqual( hf.recursive_sorted(self.graph.edges()), hf.recursive_sorted([('a', 'b'), ('b', 'c'), ('d', 'e'), ('e', 'f')])) def test_add_edges_from_nonstring(self): self.graph.add_edges_from([(1, 2), (2, 3)]) def test_add_edges_from_self_loop(self): self.assertRaises(ValueError, self.graph.add_edges_from, [('a', 'a')]) def test_number_of_neighbors(self): self.graph.add_edges_from([('a', 'b'), ('b', 'c')]) self.assertEqual(len(self.graph.neighbors('b')), 2) def tearDown(self): del self.graph