def test(self): degree = 40 n_nodes = 15 # initialize kr generator = kr_util() kr = generator.build_kr(n_nodes, degree, print_debug=True) # generate graph and arbitrary matching g_p = graph_util().generate_random_regular_bipartite(n_nodes, degree) arbitrary_p = graph_util().generate_random_regular_bipartite(n_nodes, 1) # create the C versions of the graphs, and copies g_c_structure = graph.create_graph_structure_test(n_nodes) g_c = graph.create_graph_edges_test(n_nodes) g_c_copy = graph.create_graph_edges_test(n_nodes) for edge in g_p.edges_iter(): graph.add_edge(g_c_structure, g_c, edge[0], edge[1]) graph.copy_edges(g_c, g_c_copy, n_nodes) self.assertEqual(graph.get_max_degree(g_c, n_nodes), degree) self.assertEqual(graph.get_max_degree(g_c_copy, n_nodes), degree) arbitrary_c = graph.create_graph_edges_test(n_nodes) for edge in arbitrary_p.edges_iter(): graph.add_edge(g_c_structure, g_c, edge[0], edge[1]) graph.set_edge(g_c_structure, g_c_copy, arbitrary_c, edge[0], edge[1]) self.assertEqual(graph.get_max_degree(arbitrary_c, n_nodes), 1) # solve solution = kapoorrizzi.create_matching_set() kapoorrizzi.solve(kr, g_c_structure, g_c_copy, arbitrary_c, solution) # check solution # check that we have the correct number of matchings num_matchings = kapoorrizzi.get_num_matchings(solution) self.assertEqual(num_matchings, degree + 1) # check that each matching is a perfect matching for i in range(num_matchings): matching = kapoorrizzi.get_matching(solution, i) self.assertTrue(graph.is_perfect_matching(matching, n_nodes)) # check sum of matchings equals the original graph matchings_graph_c = graph.create_graph_edges_test(n_nodes) for i in range(num_matchings): matching = kapoorrizzi.get_matching(solution, i) graph.add_edges(matchings_graph_c, matching, n_nodes) self.assertTrue(graph.are_equal(matchings_graph_c, g_c, n_nodes)) # clean up kapoorrizzi.destroy_kr(kr) kapoorrizzi.destroy_matching_set(solution) graph.destroy_graph_structure_test(g_c_structure) graph.destroy_graph_edges_test(g_c) graph.destroy_graph_edges_test(g_c_copy) graph.destroy_graph_edges_test(arbitrary_c) pass
def test_keeps_edge_set(self): generator = graph_util() for deg in xrange(2, 11, 2): for n_side in xrange(2 * deg + 4, 33, 7): g_p = generator.generate_random_regular_bipartite(n_side, deg) # Create the graph in C g_c_structure = graph.create_graph_structure_test(n_side) g_c = graph.create_graph_edges_test(n_side) g_c_copy = graph.create_graph_edges_test(n_side) for edge in g_p.edges_iter(): graph.add_edge(g_c_structure, g_c, edge[0], edge[1]) graph.copy_edges(g_c, g_c_copy, n_side) self.assertEqual(graph.get_max_degree(g_c, n_side), deg) self.assertEqual(graph.get_max_degree(g_c_copy, n_side), deg) # Create the output graphs g1_c = graph.create_graph_edges_test(n_side) g2_c = graph.create_graph_edges_test(n_side) eulersplit.split(g_c_structure, g_c_copy, g1_c, g2_c) # Check that the input graph is now empty self.assertEqual(graph.get_max_degree(g_c_copy, n_side), 0) for node in xrange(2 * n_side): self.assertEqual(graph.get_degree(g_c_copy, node), 0) # Check that graphs have the correct degree self.assertEqual(graph.get_max_degree(g1_c, n_side), deg / 2) self.assertEqual(graph.get_max_degree(g2_c, n_side), deg / 2) # Check that vertices have the correct degree for node in xrange(2 * n_side): self.assertEqual(graph.get_degree(g1_c, node), deg / 2) self.assertEqual(graph.get_degree(g2_c, node), deg / 2) # Check that the combination of the two graphs equals the original graph graph.add_edges(g1_c, g2_c, n_side) self.assertTrue(graph.are_equal(g_c, g1_c, n_side)) graph.destroy_graph_structure_test(g_c_structure) graph.destroy_graph_edges_test(g_c) graph.destroy_graph_edges_test(g_c_copy) graph.destroy_graph_edges_test(g1_c) graph.destroy_graph_edges_test(g2_c) pass
def test_keeps_edge_set(self): generator = graph_util() for deg in xrange(2, 11, 2): for n_side in xrange(2*deg+4,33,7): g_p = generator.generate_random_regular_bipartite(n_side, deg) # Create the graph in C g_c_structure = graph.create_graph_structure_test(n_side); g_c = graph.create_graph_edges_test(n_side); g_c_copy = graph.create_graph_edges_test(n_side) for edge in g_p.edges_iter(): graph.add_edge(g_c_structure, g_c, edge[0], edge[1]) graph.copy_edges(g_c, g_c_copy, n_side) self.assertEqual(graph.get_max_degree(g_c, n_side), deg) self.assertEqual(graph.get_max_degree(g_c_copy, n_side), deg) # Create the output graphs g1_c = graph.create_graph_edges_test(n_side) g2_c = graph.create_graph_edges_test(n_side) eulersplit.split(g_c_structure, g_c_copy, g1_c, g2_c) # Check that the input graph is now empty self.assertEqual(graph.get_max_degree(g_c_copy, n_side), 0) for node in xrange(2 * n_side): self.assertEqual(graph.get_degree(g_c_copy, node), 0) # Check that graphs have the correct degree self.assertEqual(graph.get_max_degree(g1_c, n_side), deg / 2) self.assertEqual(graph.get_max_degree(g2_c, n_side), deg / 2) # Check that vertices have the correct degree for node in xrange(2 * n_side): self.assertEqual(graph.get_degree(g1_c, node), deg / 2) self.assertEqual(graph.get_degree(g2_c, node), deg / 2) # Check that the combination of the two graphs equals the original graph graph.add_edges(g1_c, g2_c, n_side) self.assertTrue(graph.are_equal(g_c, g1_c, n_side)) graph.destroy_graph_structure_test(g_c_structure) graph.destroy_graph_edges_test(g_c) graph.destroy_graph_edges_test(g_c_copy) graph.destroy_graph_edges_test(g1_c) graph.destroy_graph_edges_test(g2_c) pass
def test(self): degree = 40 n_nodes = 15 # initialize kr generator = kr_util() kr = generator.build_kr(n_nodes, degree, print_debug=True) # generate graph and arbitrary matching g_p = graph_util().generate_random_regular_bipartite(n_nodes, degree) arbitrary_p = graph_util().generate_random_regular_bipartite( n_nodes, 1) # create the C versions of the graphs, and copies g_c_structure = graph.create_graph_structure_test(n_nodes) g_c = graph.create_graph_edges_test(n_nodes) g_c_copy = graph.create_graph_edges_test(n_nodes) for edge in g_p.edges_iter(): graph.add_edge(g_c_structure, g_c, edge[0], edge[1]) graph.copy_edges(g_c, g_c_copy, n_nodes) self.assertEqual(graph.get_max_degree(g_c, n_nodes), degree) self.assertEqual(graph.get_max_degree(g_c_copy, n_nodes), degree) arbitrary_c = graph.create_graph_edges_test(n_nodes) for edge in arbitrary_p.edges_iter(): graph.add_edge(g_c_structure, g_c, edge[0], edge[1]) graph.set_edge(g_c_structure, g_c_copy, arbitrary_c, edge[0], edge[1]) self.assertEqual(graph.get_max_degree(arbitrary_c, n_nodes), 1) # solve solution = kapoorrizzi.create_matching_set() kapoorrizzi.solve(kr, g_c_structure, g_c_copy, arbitrary_c, solution) # check solution # check that we have the correct number of matchings num_matchings = kapoorrizzi.get_num_matchings(solution) self.assertEqual(num_matchings, degree + 1) # check that each matching is a perfect matching for i in range(num_matchings): matching = kapoorrizzi.get_matching(solution, i) self.assertTrue(graph.is_perfect_matching(matching, n_nodes)) # check sum of matchings equals the original graph matchings_graph_c = graph.create_graph_edges_test(n_nodes) for i in range(num_matchings): matching = kapoorrizzi.get_matching(solution, i) graph.add_edges(matchings_graph_c, matching, n_nodes) self.assertTrue(graph.are_equal(matchings_graph_c, g_c, n_nodes)) # clean up kapoorrizzi.destroy_kr(kr) kapoorrizzi.destroy_matching_set(solution) graph.destroy_graph_structure_test(g_c_structure) graph.destroy_graph_edges_test(g_c) graph.destroy_graph_edges_test(g_c_copy) graph.destroy_graph_edges_test(arbitrary_c) pass