# # # 0=================================0 # | Kernel Point Convolutions | # 0=================================0 # # # ---------------------------------------------------------------------------------------------------------------------- # # Callable script to test any model on any dataset # # ---------------------------------------------------------------------------------------------------------------------- # # Hugues THOMAS - 11/06/2018 # # ---------------------------------------------------------------------------------------------------------------------- # # Imports and global variables # \**********************************/ # # Common libs import os import torch import numpy as np import matplotlib.pyplot as plt from os.path import isfile, join, exists from os import listdir, remove, getcwd from sklearn.metrics import confusion_matrix import time # My libs from utils.config import Config from utils.metrics import IoU_from_confusions, smooth_metrics, fast_confusion from utils.ply import read_ply # Datasets from datasets.ModelNet40 import ModelNet40Dataset from datasets.S3DIS import S3DISDataset from datasets.SemanticKitti import SemanticKittiDataset # ---------------------------------------------------------------------------------------------------------------------- # # Utility functions # \***********************/ # def running_mean(signal, n, axis=0, stride=1): signal = np.array(signal) torch_conv = torch.nn.Conv1d(1, 1, kernel_size=2*n+1, stride=stride, bias=False) torch_conv.weight.requires_grad_(False) torch_conv.weight *= 0 torch_conv.weight += 1 / (2*n+1) if signal.ndim == 1: torch_signal = torch.from_numpy(signal.reshape([1, 1, -1]).astype(np.float32)) return torch_conv(torch_signal).squeeze().numpy() elif signal.ndim == 2: print('TODO implement with torch and stride here') smoothed = np.empty(signal.shape) if axis == 0: for i, sig in enumerate(signal): sig_sum = np.convolve(sig, np.ones((2*n+1,)), mode='same') sig_num = np.convolve(sig*0+1, np.ones((2*n+1,)), mode='same') smoothed[i, :] = sig_sum / sig_num elif axis == 1: for i, sig in enumerate(signal.T): sig_sum = np.convolve(sig, np.ones((2*n+1,)), mode='same') sig_num = np.convolve(sig*0+1, np.ones((2*n+1,)), mode='same') smoothed[:, i] = sig_sum / sig_num else: print('wrong axis') return smoothed else: print('wrong dimensions') return None def IoU_class_metrics(all_IoUs, smooth_n): # Get mean IoU per class for consecutive epochs to directly get a mean without further smoothing smoothed_IoUs = [] for epoch in range(len(all_IoUs)): i0 = max(epoch - smooth_n, 0) i1 = min(epoch + smooth_n + 1, len(all_IoUs)) smoothed_IoUs += [np.mean(np.vstack(all_IoUs[i0:i1]), axis=0)] smoothed_IoUs = np.vstack(smoothed_IoUs) smoothed_mIoUs = np.mean(smoothed_IoUs, axis=1) return smoothed_IoUs, smoothed_mIoUs def load_confusions(filename, n_class): with open(filename, 'r') as f: lines = f.readlines() confs = np.zeros((len(lines), n_class, n_class)) for i, line in enumerate(lines): C = np.array([int(value) for value in line.split()]) confs[i, :, :] = C.reshape((n_class, n_class)) return confs def load_training_results(path): filename = join(path, 'training.txt') with open(filename, 'r') as f: lines = f.readlines() epochs = [] steps = [] L_out = [] L_p = [] acc = [] t = [] for line in lines[1:]: line_info = line.split() if (len(line) > 0): epochs += [int(line_info[0])] steps += [int(line_info[1])] L_out += [float(line_info[2])] L_p += [float(line_info[3])] acc += [float(line_info[4])] t += [float(line_info[5])] else: break return epochs, steps, L_out, L_p, acc, t def load_single_IoU(filename, n_parts): with open(filename, 'r') as f: lines = f.readlines() # Load all IoUs all_IoUs = [] for i, line in enumerate(lines): all_IoUs += [np.reshape([float(IoU) for IoU in line.split()], [-1, n_parts])] return all_IoUs def load_snap_clouds(path, dataset, only_last=False): cloud_folders = np.array([join(path, f) for f in listdir(path) if f.startswith('val_preds')]) cloud_epochs = np.array([int(f.split('_')[-1]) for f in cloud_folders]) epoch_order = np.argsort(cloud_epochs) cloud_epochs = cloud_epochs[epoch_order] cloud_folders = cloud_folders[epoch_order] Confs = np.zeros((len(cloud_epochs), dataset.num_classes, dataset.num_classes), dtype=np.int32) for c_i, cloud_folder in enumerate(cloud_folders): if only_last and c_i < len(cloud_epochs) - 1: continue # Load confusion if previously saved conf_file = join(cloud_folder, 'conf.txt') if isfile(conf_file): Confs[c_i] += np.loadtxt(conf_file, dtype=np.int32) else: for f in listdir(cloud_folder): if f.endswith('.ply') and not f.endswith('sub.ply'): data = read_ply(join(cloud_folder, f)) labels = data['class'] preds = data['preds'] Confs[c_i] += fast_confusion(labels, preds, dataset.label_values).astype(np.int32) np.savetxt(conf_file, Confs[c_i], '%12d') # Erase ply to save disk memory if c_i < len(cloud_folders) - 1: for f in listdir(cloud_folder): if f.endswith('.ply'): remove(join(cloud_folder, f)) # Remove ignored labels from confusions for l_ind, label_value in reversed(list(enumerate(dataset.label_values))): if label_value in dataset.ignored_labels: Confs = np.delete(Confs, l_ind, axis=1) Confs = np.delete(Confs, l_ind, axis=2) return cloud_epochs, IoU_from_confusions(Confs) # ---------------------------------------------------------------------------------------------------------------------- # # Plot functions # \********************/ # def compare_trainings(list_of_paths, list_of_labels=None): # Parameters # ********** plot_lr = False smooth_epochs = 0.5 stride = 2 if list_of_labels is None: list_of_labels = [str(i) for i in range(len(list_of_paths))] # Read Training Logs # ****************** all_epochs = [] all_loss = [] all_lr = [] all_times = [] all_RAMs = [] for path in list_of_paths: print(path) if ('val_IoUs.txt' in [f.decode('ascii') for f in listdir(path)]) or ('val_confs.txt' in [f.decode('ascii') for f in listdir(path)]): config = Config() config.load(path) else: continue # Load results epochs, steps, L_out, L_p, acc, t = load_training_results(path) epochs = np.array(epochs, dtype=np.int32) epochs_d = np.array(epochs, dtype=np.float32) steps = np.array(steps, dtype=np.float32) # Compute number of steps per epoch max_e = np.max(epochs) first_e = np.min(epochs) epoch_n = [] for i in range(first_e, max_e): bool0 = epochs == i e_n = np.sum(bool0) epoch_n.append(e_n) epochs_d[bool0] += steps[bool0] / e_n smooth_n = int(np.mean(epoch_n) * smooth_epochs) smooth_loss = running_mean(L_out, smooth_n, stride=stride) all_loss += [smooth_loss] all_epochs += [epochs_d[smooth_n:-smooth_n:stride]] all_times += [t[smooth_n:-smooth_n:stride]] # Learning rate if plot_lr: lr_decay_v = np.array([lr_d for ep, lr_d in config.lr_decays.items()]) lr_decay_e = np.array([ep for ep, lr_d in config.lr_decays.items()]) max_e = max(np.max(all_epochs[-1]) + 1, np.max(lr_decay_e) + 1) lr_decays = np.ones(int(np.ceil(max_e)), dtype=np.float32) lr_decays[0] = float(config.learning_rate) lr_decays[lr_decay_e] = lr_decay_v lr = np.cumprod(lr_decays) all_lr += [lr[np.floor(all_epochs[-1]).astype(np.int32)]] # Plots learning rate # ******************* if plot_lr: # Figure fig = plt.figure('lr') for i, label in enumerate(list_of_labels): plt.plot(all_epochs[i], all_lr[i], linewidth=1, label=label) # Set names for axes plt.xlabel('epochs') plt.ylabel('lr') plt.yscale('log') # Display legends and title plt.legend(loc=1) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') # ax.set_yticks(np.arange(0.8, 1.02, 0.02)) # Plots loss # ********** # Figure fig = plt.figure('loss') for i, label in enumerate(list_of_labels): plt.plot(all_epochs[i], all_loss[i], linewidth=1, label=label) # Set names for axes plt.xlabel('epochs') plt.ylabel('loss') plt.yscale('log') # Display legends and title plt.legend(loc=1) plt.title('Losses compare') # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') # ax.set_yticks(np.arange(0.8, 1.02, 0.02)) # Plot Times # ********** # Figure fig = plt.figure('time') for i, label in enumerate(list_of_labels): plt.plot(all_epochs[i], np.array(all_times[i]) / 3600, linewidth=1, label=label) # Set names for axes plt.xlabel('epochs') plt.ylabel('time') # plt.yscale('log') # Display legends and title plt.legend(loc=0) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') # ax.set_yticks(np.arange(0.8, 1.02, 0.02)) # Show all plt.show() def compare_convergences_segment(dataset, list_of_paths, list_of_names=None): # Parameters # ********** smooth_n = 10 if list_of_names is None: list_of_names = [str(i) for i in range(len(list_of_paths))] # Read Logs # ********* all_pred_epochs = [] all_mIoUs = [] all_class_IoUs = [] all_snap_epochs = [] all_snap_IoUs = [] # Load parameters config = Config() config.load(list_of_paths[0]) class_list = [dataset.label_to_names[label] for label in dataset.label_values if label not in dataset.ignored_labels] s = '{:^10}|'.format('mean') for c in class_list: s += '{:^10}'.format(c) print(s) print(10*'-' + '|' + 10*config.num_classes*'-') for path in list_of_paths: # Get validation IoUs file = join(path, 'val_IoUs.txt') val_IoUs = load_single_IoU(file, config.num_classes) # Get mean IoU class_IoUs, mIoUs = IoU_class_metrics(val_IoUs, smooth_n) # Aggregate results all_pred_epochs += [np.array([i for i in range(len(val_IoUs))])] all_mIoUs += [mIoUs] all_class_IoUs += [class_IoUs] s = '{:^10.1f}|'.format(100*mIoUs[-1]) for IoU in class_IoUs[-1]: s += '{:^10.1f}'.format(100*IoU) print(s) # Get optional full validation on clouds snap_epochs, snap_IoUs = load_snap_clouds(path, dataset) all_snap_epochs += [snap_epochs] all_snap_IoUs += [snap_IoUs] print(10*'-' + '|' + 10*config.num_classes*'-') for snap_IoUs in all_snap_IoUs: if len(snap_IoUs) > 0: s = '{:^10.1f}|'.format(100*np.mean(snap_IoUs[-1])) for IoU in snap_IoUs[-1]: s += '{:^10.1f}'.format(100*IoU) else: s = '{:^10s}'.format('-') for _ in range(config.num_classes): s += '{:^10s}'.format('-') print(s) # Plots # ***** # Figure fig = plt.figure('mIoUs') for i, name in enumerate(list_of_names): p = plt.plot(all_pred_epochs[i], all_mIoUs[i], '--', linewidth=1, label=name) plt.plot(all_snap_epochs[i], np.mean(all_snap_IoUs[i], axis=1), linewidth=1, color=p[-1].get_color()) plt.xlabel('epochs') plt.ylabel('IoU') # Set limits for y axis #plt.ylim(0.55, 0.95) # Display legends and title plt.legend(loc=4) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') #ax.set_yticks(np.arange(0.8, 1.02, 0.02)) displayed_classes = [0, 1, 2, 3, 4, 5, 6, 7] displayed_classes = [] for c_i, c_name in enumerate(class_list): if c_i in displayed_classes: # Figure fig = plt.figure(c_name + ' IoU') for i, name in enumerate(list_of_names): plt.plot(all_pred_epochs[i], all_class_IoUs[i][:, c_i], linewidth=1, label=name) plt.xlabel('epochs') plt.ylabel('IoU') # Set limits for y axis #plt.ylim(0.8, 1) # Display legends and title plt.legend(loc=4) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') #ax.set_yticks(np.arange(0.8, 1.02, 0.02)) # Show all plt.show() def compare_convergences_classif(list_of_paths, list_of_labels=None): # Parameters # ********** steps_per_epoch = 0 smooth_n = 12 if list_of_labels is None: list_of_labels = [str(i) for i in range(len(list_of_paths))] # Read Logs # ********* all_pred_epochs = [] all_val_OA = [] all_train_OA = [] all_vote_OA = [] all_vote_confs = [] for path in list_of_paths: # Load parameters config = Config() config.load(list_of_paths[0]) # Get the number of classes n_class = config.num_classes # Load epochs epochs, _, _, _, _, _ = load_training_results(path) first_e = np.min(epochs) # Get validation confusions file = join(path, 'val_confs.txt') val_C1 = load_confusions(file, n_class) val_PRE, val_REC, val_F1, val_IoU, val_ACC = smooth_metrics(val_C1, smooth_n=smooth_n) # Get vote confusions file = join(path, 'vote_confs.txt') if exists(file): vote_C2 = load_confusions(file, n_class) vote_PRE, vote_REC, vote_F1, vote_IoU, vote_ACC = smooth_metrics(vote_C2, smooth_n=2) else: vote_C2 = val_C1 vote_PRE, vote_REC, vote_F1, vote_IoU, vote_ACC = (val_PRE, val_REC, val_F1, val_IoU, val_ACC) # Aggregate results all_pred_epochs += [np.array([i+first_e for i in range(len(val_ACC))])] all_val_OA += [val_ACC] all_vote_OA += [vote_ACC] all_vote_confs += [vote_C2] print() # Best scores # *********** for i, label in enumerate(list_of_labels): print('\n' + label + '\n' + '*' * len(label) + '\n') print(list_of_paths[i]) best_epoch = np.argmax(all_vote_OA[i]) print('Best Accuracy : {:.1f} % (epoch {:d})'.format(100 * all_vote_OA[i][best_epoch], best_epoch)) confs = all_vote_confs[i] """ s = '' for cc in confs[best_epoch]: for c in cc: s += '{:.0f} '.format(c) s += '\n' print(s) """ TP_plus_FN = np.sum(confs, axis=-1, keepdims=True) class_avg_confs = confs.astype(np.float32) / TP_plus_FN.astype(np.float32) diags = np.diagonal(class_avg_confs, axis1=-2, axis2=-1) class_avg_ACC = np.sum(diags, axis=-1) / np.sum(class_avg_confs, axis=(-1, -2)) print('Corresponding mAcc : {:.1f} %'.format(100 * class_avg_ACC[best_epoch])) # Plots # ***** for fig_name, OA in zip(['Validation', 'Vote'], [all_val_OA, all_vote_OA]): # Figure fig = plt.figure(fig_name) for i, label in enumerate(list_of_labels): plt.plot(all_pred_epochs[i], OA[i], linewidth=1, label=label) plt.xlabel('epochs') plt.ylabel(fig_name + ' Accuracy') # Set limits for y axis #plt.ylim(0.55, 0.95) # Display legends and title plt.legend(loc=4) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') #ax.set_yticks(np.arange(0.8, 1.02, 0.02)) #for i, label in enumerate(list_of_labels): # print(label, np.max(all_train_OA[i]), np.max(all_val_OA[i])) # Show all plt.show() def compare_convergences_SLAM(dataset, list_of_paths, list_of_names=None): # Parameters # ********** smooth_n = 10 if list_of_names is None: list_of_names = [str(i) for i in range(len(list_of_paths))] # Read Logs # ********* all_pred_epochs = [] all_val_mIoUs = [] all_val_class_IoUs = [] all_subpart_mIoUs = [] all_subpart_class_IoUs = [] # Load parameters config = Config() config.load(list_of_paths[0]) class_list = [dataset.label_to_names[label] for label in dataset.label_values if label not in dataset.ignored_labels] s = '{:^6}|'.format('mean') for c in class_list: s += '{:^6}'.format(c[:4]) print(s) print(6*'-' + '|' + 6*config.num_classes*'-') for path in list_of_paths: # Get validation IoUs nc_model = dataset.num_classes - len(dataset.ignored_labels) file = join(path, 'val_IoUs.txt') val_IoUs = load_single_IoU(file, nc_model) # Get Subpart IoUs file = join(path, 'subpart_IoUs.txt') subpart_IoUs = load_single_IoU(file, nc_model) # Get mean IoU val_class_IoUs, val_mIoUs = IoU_class_metrics(val_IoUs, smooth_n) subpart_class_IoUs, subpart_mIoUs = IoU_class_metrics(subpart_IoUs, smooth_n) # Aggregate results all_pred_epochs += [np.array([i for i in range(len(val_IoUs))])] all_val_mIoUs += [val_mIoUs] all_val_class_IoUs += [val_class_IoUs] all_subpart_mIoUs += [subpart_mIoUs] all_subpart_class_IoUs += [subpart_class_IoUs] s = '{:^6.1f}|'.format(100*subpart_mIoUs[-1]) for IoU in subpart_class_IoUs[-1]: s += '{:^6.1f}'.format(100*IoU) print(s) print(6*'-' + '|' + 6*config.num_classes*'-') for snap_IoUs in all_val_class_IoUs: if len(snap_IoUs) > 0: s = '{:^6.1f}|'.format(100*np.mean(snap_IoUs[-1])) for IoU in snap_IoUs[-1]: s += '{:^6.1f}'.format(100*IoU) else: s = '{:^6s}'.format('-') for _ in range(config.num_classes): s += '{:^6s}'.format('-') print(s) # Plots # ***** # Figure fig = plt.figure('mIoUs') for i, name in enumerate(list_of_names): p = plt.plot(all_pred_epochs[i], all_subpart_mIoUs[i], '--', linewidth=1, label=name) plt.plot(all_pred_epochs[i], all_val_mIoUs[i], linewidth=1, color=p[-1].get_color()) plt.xlabel('epochs') plt.ylabel('IoU') # Set limits for y axis #plt.ylim(0.55, 0.95) # Display legends and title plt.legend(loc=4) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') #ax.set_yticks(np.arange(0.8, 1.02, 0.02)) displayed_classes = [0, 1, 2, 3, 4, 5, 6, 7] #displayed_classes = [] for c_i, c_name in enumerate(class_list): if c_i in displayed_classes: # Figure fig = plt.figure(c_name + ' IoU') for i, name in enumerate(list_of_names): plt.plot(all_pred_epochs[i], all_val_class_IoUs[i][:, c_i], linewidth=1, label=name) plt.xlabel('epochs') plt.ylabel('IoU') # Set limits for y axis #plt.ylim(0.8, 1) # Display legends and title plt.legend(loc=4) # Customize the graph ax = fig.gca() ax.grid(linestyle='-.', which='both') #ax.set_yticks(np.arange(0.8, 1.02, 0.02)) # Show all plt.show() # ---------------------------------------------------------------------------------------------------------------------- # # Experiments # \*****************/ # def experiment_name_1(): """ In this function you choose the results you want to plot together, to compare them as an experiment. Just return the list of log paths (like 'results/Log_2020-04-04_10-04-42' for example), and the associated names of these logs. Below an example of how to automatically gather all logs between two dates, and name them. """ # Using the dates of the logs, you can easily gather consecutive ones. All logs should be of the same dataset. start = 'Log_2020-04-22_11-52-58' end = 'Log_2023-07-29_12-40-27' # Name of the result path res_path = 'results' # Gather logs and sort by date logs = np.sort([join(res_path, l) for l in listdir(res_path) if start <= l <= end]) # Give names to the logs (for plot legends) logs_names = ['name_log_1'] # safe check log names logs_names = np.array(logs_names[:len(logs)]) return logs, logs_names def experiment_name_2(): """ In this function you choose the results you want to plot together, to compare them as an experiment. Just return the list of log paths (like 'results/Log_2020-04-04_10-04-42' for example), and the associated names of these logs. Below an example of how to automatically gather all logs between two dates, and name them. """ # Using the dates of the logs, you can easily gather consecutive ones. All logs should be of the same dataset. start = 'Log_2020-04-22_11-52-58' end = 'Log_2020-05-22_11-52-58' # Name of the result path res_path = 'results' # Gather logs and sort by date logs = np.sort([join(res_path, l) for l in listdir(res_path) if start <= l <= end]) # Optionally add a specific log at a specific place in the log list logs = logs.astype('