if delivery_index is None: break while (len(current_delivery) < pizza_amount and len(pizzas) > 0): pizzas = heuristic_sort(pizzas, used_ingredients) current_delivery.append(pizzas[0]) for i in pizza_database[pizzas[0]]: used_ingredients.add(i) pizzas = pizzas[1:] deliveries[delivery_index].append(current_delivery) n_deliveries += 1 return deliveries, n_deliveries if __name__ == '__main__': if len(sys.argv) < 2: raise ValueError( "Filename needs to be passed as command-line argument.") filename = sys.argv[1] pizza_database, teams = read_input(filename) deliveries, n_deliveries = solve(list(range(len(pizza_database))), teams) if ".in" in filename: filename = filename.replace('.in', '.out') else: filename += ".out" write_output(filename, deliveries, n_deliveries)
def main(input_dir, radius, bins, num_evaluations): """ Run point cloud registration on Shenlan dataset """ registration_results = io.read_registration_results( os.path.join(input_dir, 'reg_result.txt')) # init output df_output = io.init_output() for i, r in progressbar.progressbar(list(registration_results.iterrows())): # for interactive visualization: if i >= num_evaluations: exit(0) # parse point cloud index: idx_target = int(r['idx1']) idx_source = int(r['idx2']) # load point clouds: pcd_source = io.read_point_cloud_bin( os.path.join(input_dir, 'point_clouds', f'{idx_source}.bin')) pcd_source, idx_inliers = pcd_source.remove_radius_outlier( nb_points=4, radius=radius) search_tree_source = o3d.geometry.KDTreeFlann(pcd_source) pcd_target = io.read_point_cloud_bin( os.path.join(input_dir, 'point_clouds', f'{idx_target}.bin')) pcd_target, idx_inliers = pcd_target.remove_radius_outlier( nb_points=4, radius=radius) search_tree_target = o3d.geometry.KDTreeFlann(pcd_target) # detect keypoints: keypoints_source = detect(pcd_source, search_tree_source, radius) keypoints_target = detect(pcd_target, search_tree_target, radius) # create descriptions: pcd_source_keypoints = pcd_source.select_by_index( keypoints_source['id'].values) fpfh_source_keypoints = o3d.registration.compute_fpfh_feature( pcd_source_keypoints, o3d.geometry.KDTreeSearchParamHybrid(radius=5 * radius, max_nn=100)).data pcd_target_keypoints = pcd_target.select_by_index( keypoints_target['id'].values) fpfh_target_keypoints = o3d.registration.compute_fpfh_feature( pcd_target_keypoints, o3d.geometry.KDTreeSearchParamHybrid(radius=5 * radius, max_nn=100)).data # generate matches: distance_threshold_init = 1.5 * radius distance_threshold_final = 1.0 * radius # RANSAC for initial estimation: init_result = ransac_match( pcd_source_keypoints, pcd_target_keypoints, fpfh_source_keypoints, fpfh_target_keypoints, ransac_params=RANSACParams( max_workers=5, num_samples=4, max_correspondence_distance=distance_threshold_init, max_iteration=200000, max_validation=500, max_refinement=30), checker_params=CheckerParams( max_correspondence_distance=distance_threshold_init, max_edge_length_ratio=0.9, normal_angle_threshold=None)) # exact ICP for refined estimation: final_result = exact_match(pcd_source, pcd_target, search_tree_target, init_result.transformation, distance_threshold_final, 60) # visualize: visualize.show_registration_result(pcd_source_keypoints, pcd_target_keypoints, init_result.correspondence_set, pcd_source, pcd_target, final_result.transformation) # add result: io.add_to_output(df_output, idx_target, idx_source, final_result.transformation) # write output: io.write_output(os.path.join(input_dir, 'reg_result_yaogefad.txt'), df_output)
def main(input_dir, radius, bins, num_evaluations): """ Run pose estimation on given point cloud pair """ # load source & target point clouds: pcd_source = o3d.io.read_point_cloud(os.path.join(input_dir, "first.pcd")) pcd_source = pcd_source.voxel_down_sample(voxel_size=0.05) pcd_source.estimate_normals( search_param=o3d.geometry.KDTreeSearchParamHybrid(radius=0.1, max_nn=30)) pcd_target = o3d.io.read_point_cloud(os.path.join(input_dir, "second.pcd")) pcd_target = pcd_target.voxel_down_sample(voxel_size=0.05) pcd_target.estimate_normals( search_param=o3d.geometry.KDTreeSearchParamHybrid(radius=0.1, max_nn=30)) # build search trees: pcd_source, idx_inliers = pcd_source.remove_radius_outlier(nb_points=4, radius=radius) search_tree_source = o3d.geometry.KDTreeFlann(pcd_source) pcd_target, idx_inliers = pcd_target.remove_radius_outlier(nb_points=4, radius=radius) search_tree_target = o3d.geometry.KDTreeFlann(pcd_target) # detect keypoints: keypoints_source = detect(pcd_source, search_tree_source, radius) keypoints_target = detect(pcd_target, search_tree_target, radius) # create descriptions: pcd_source_keypoints = pcd_source.select_by_index( keypoints_source['id'].values) fpfh_source_keypoints = o3d.registration.compute_fpfh_feature( pcd_source_keypoints, o3d.geometry.KDTreeSearchParamHybrid(radius=5 * radius, max_nn=100)).data pcd_target_keypoints = pcd_target.select_by_index( keypoints_target['id'].values) fpfh_target_keypoints = o3d.registration.compute_fpfh_feature( pcd_target_keypoints, o3d.geometry.KDTreeSearchParamHybrid(radius=5 * radius, max_nn=100)).data # generate matches: distance_threshold_init = 1.5 * radius distance_threshold_final = 1.0 * radius # RANSAC for initial estimation: init_result = ransac_match( pcd_source_keypoints, pcd_target_keypoints, fpfh_source_keypoints, fpfh_target_keypoints, ransac_params=RANSACParams( max_workers=5, num_samples=4, max_correspondence_distance=distance_threshold_init, max_iteration=200000, max_validation=500, max_refinement=30), checker_params=CheckerParams( max_correspondence_distance=distance_threshold_init, max_edge_length_ratio=0.9, normal_angle_threshold=None)) # exact ICP for refined estimation: final_result = exact_match(pcd_source, pcd_target, search_tree_target, init_result.transformation, distance_threshold_final, 60) # visualize: visualize.show_registration_result(pcd_source_keypoints, pcd_target_keypoints, init_result.correspondence_set, pcd_source, pcd_target, final_result.transformation) # init output df_output = io.init_output() # add result: io.add_to_output(df_output, 2, 1, final_result.transformation) # write output: io.write_output(os.path.join(input_dir, 'reg_result_yaogefad.txt'), df_output)