Spaces:
Runtime error
Runtime error
| import logging | |
| import numpy as np | |
| from tqdm import tqdm | |
| import os | |
| import torch | |
| from torch import nn | |
| from torch import optim | |
| from torch.nn import functional as F | |
| from torch.utils.data import DataLoader,Dataset | |
| from models.base import BaseLearner | |
| from utils.inc_net import CosineIncrementalNet, FOSTERNet, IncrementalNet | |
| from utils.toolkit import count_parameters, target2onehot, tensor2numpy | |
| EPSILON = 1e-8 | |
| class PASS(BaseLearner): | |
| def __init__(self, args): | |
| super().__init__(args) | |
| self.args = args | |
| self._network = IncrementalNet(args, False) | |
| self._protos = [] | |
| self._radius = 0 | |
| self._radiuses = [] | |
| def after_task(self): | |
| self._known_classes = self._total_classes | |
| self._old_network = self._network.copy().freeze() | |
| if hasattr(self._old_network,"module"): | |
| self.old_network_module_ptr = self._old_network.module | |
| else: | |
| self.old_network_module_ptr = self._old_network | |
| #self.save_checkpoint("{}_{}_{}".format(self.args["model_name"],self.args["init_cls"],self.args["increment"])) | |
| def incremental_train(self, data_manager): | |
| self.data_manager = data_manager | |
| self._cur_task += 1 | |
| self._total_classes = self._known_classes + \ | |
| data_manager.get_task_size(self._cur_task) | |
| self._network.update_fc(self._total_classes*4) | |
| self._network_module_ptr = self._network | |
| logging.info( | |
| 'Learning on {}-{}'.format(self._known_classes, self._total_classes)) | |
| logging.info('All params: {}'.format(count_parameters(self._network))) | |
| logging.info('Trainable params: {}'.format( | |
| count_parameters(self._network, True))) | |
| train_dataset = data_manager.get_dataset(np.arange(self._known_classes, self._total_classes), source='train', | |
| mode='train', appendent=self._get_memory()) | |
| self.train_loader = DataLoader( | |
| train_dataset, batch_size=self.args["batch_size"], shuffle=True, num_workers=self.args["num_workers"], pin_memory=True) | |
| test_dataset = data_manager.get_dataset( | |
| np.arange(0, self._total_classes), source='test', mode='test') | |
| self.test_loader = DataLoader( | |
| test_dataset, batch_size=self.args["batch_size"], shuffle=False, num_workers=self.args["num_workers"]) | |
| if len(self._multiple_gpus) > 1: | |
| self._network = nn.DataParallel(self._network, self._multiple_gpus) | |
| self._train(self.train_loader, self.test_loader) | |
| if len(self._multiple_gpus) > 1: | |
| self._network = self._network.module | |
| def _train(self, train_loader, test_loader): | |
| resume = False | |
| if self._cur_task in []: | |
| self._network.load_state_dict(torch.load("{}_{}_{}_{}.pkl".format(self.args["model_name"],self.args["init_cls"],self.args["increment"],self._cur_task))["model_state_dict"]) | |
| resume = True | |
| self._network.to(self._device) | |
| if hasattr(self._network, "module"): | |
| self._network_module_ptr = self._network.module | |
| if not resume: | |
| self._epoch_num = self.args["epochs"] | |
| optimizer = torch.optim.Adam(self._network.parameters(), lr=self.args["lr"], weight_decay=self.args["weight_decay"]) | |
| scheduler = torch.optim.lr_scheduler.StepLR(optimizer, step_size=self.args["step_size"], gamma=self.args["gamma"]) | |
| self._train_function(train_loader, test_loader, optimizer, scheduler) | |
| self._build_protos() | |
| def _build_protos(self): | |
| with torch.no_grad(): | |
| for class_idx in range(self._known_classes, self._total_classes): | |
| data, targets, idx_dataset = self.data_manager.get_dataset(np.arange(class_idx, class_idx+1), source='train', | |
| mode='test', ret_data=True) | |
| idx_loader = DataLoader(idx_dataset, batch_size=self.args["batch_size"], shuffle=False, num_workers=4) | |
| vectors, _ = self._extract_vectors(idx_loader) | |
| class_mean = np.mean(vectors, axis=0) | |
| self._protos.append(class_mean) | |
| cov = np.cov(vectors.T) | |
| self._radiuses.append(np.trace(cov)/vectors.shape[1]) | |
| self._radius = np.sqrt(np.mean(self._radiuses)) | |
| def _train_function(self, train_loader, test_loader, optimizer, scheduler): | |
| prog_bar = tqdm(range(self._epoch_num)) | |
| for _, epoch in enumerate(prog_bar): | |
| self._network.train() | |
| losses = 0. | |
| losses_clf, losses_fkd, losses_proto = 0., 0., 0. | |
| correct, total = 0, 0 | |
| for i, (_, inputs, targets) in enumerate(train_loader): | |
| inputs, targets = inputs.to( | |
| self._device, non_blocking=True), targets.to(self._device, non_blocking=True) | |
| inputs = torch.stack([torch.rot90(inputs, k, (2, 3)) for k in range(4)], 1) | |
| inputs = inputs.view(-1, 3, 320, 320) | |
| targets = torch.stack([targets * 4 + k for k in range(4)], 1).view(-1) | |
| logits, loss_clf, loss_fkd, loss_proto = self._compute_pass_loss(inputs,targets) | |
| loss = loss_clf + loss_fkd + loss_proto | |
| optimizer.zero_grad() | |
| loss.backward() | |
| optimizer.step() | |
| losses += loss.item() | |
| losses_clf += loss_clf.item() | |
| losses_fkd += loss_fkd.item() | |
| losses_proto += loss_proto.item() | |
| _, preds = torch.max(logits, dim=1) | |
| correct += preds.eq(targets.expand_as(preds)).cpu().sum() | |
| total += len(targets) | |
| scheduler.step() | |
| train_acc = np.around(tensor2numpy( | |
| correct)*100 / total, decimals=2) | |
| if epoch % 5 != 0: | |
| info = 'Task {}, Epoch {}/{} => Loss {:.3f}, Loss_clf {:.3f}, Loss_fkd {:.3f}, Loss_proto {:.3f}, Train_accy {:.2f}'.format( | |
| self._cur_task, epoch+1, self._epoch_num, losses/len(train_loader), losses_clf/len(train_loader), losses_fkd/len(train_loader), losses_proto/len(train_loader), train_acc) | |
| else: | |
| test_acc = self._compute_accuracy(self._network, test_loader) | |
| info = 'Task {}, Epoch {}/{} => Loss {:.3f}, Loss_clf {:.3f}, Loss_fkd {:.3f}, Loss_proto {:.3f}, Train_accy {:.2f}, Test_accy {:.2f}'.format( | |
| self._cur_task, epoch+1, self._epoch_num, losses/len(train_loader), losses_clf/len(train_loader), losses_fkd/len(train_loader), losses_proto/len(train_loader), train_acc, test_acc) | |
| prog_bar.set_description(info) | |
| logging.info(info) | |
| def _compute_pass_loss(self,inputs, targets): | |
| logits = self._network(inputs)["logits"] | |
| loss_clf = F.cross_entropy(logits/self.args["temp"], targets) | |
| if self._cur_task == 0: | |
| return logits, loss_clf, torch.tensor(0.), torch.tensor(0.) | |
| features = self._network_module_ptr.extract_vector(inputs) | |
| features_old = self.old_network_module_ptr.extract_vector(inputs) | |
| loss_fkd = self.args["lambda_fkd"] * torch.dist(features, features_old, 2) | |
| # index = np.random.choice(range(self._known_classes),size=self.args["batch_size"],replace=True) | |
| index = np.random.choice(range(self._known_classes),size=self.args["batch_size"]*int(self._known_classes/(self._total_classes-self._known_classes)),replace=True) | |
| # print(index) | |
| # print(np.concatenate(self._protos)) | |
| proto_features = np.array(self._protos)[index] | |
| # print(proto_features) | |
| proto_targets = 4*index | |
| proto_features = proto_features + np.random.normal(0,1,proto_features.shape)*self._radius | |
| proto_features = torch.from_numpy(proto_features).float().to(self._device,non_blocking=True) | |
| proto_targets = torch.from_numpy(proto_targets).to(self._device,non_blocking=True) | |
| proto_logits = self._network_module_ptr.fc(proto_features)["logits"] | |
| loss_proto = self.args["lambda_proto"] * F.cross_entropy(proto_logits/self.args["temp"], proto_targets) | |
| return logits, loss_clf, loss_fkd, loss_proto | |
| def _compute_accuracy(self, model, loader): | |
| model.eval() | |
| correct, total = 0, 0 | |
| for i, (_, inputs, targets) in enumerate(loader): | |
| inputs = inputs.to(self._device) | |
| with torch.no_grad(): | |
| outputs = model(inputs)["logits"][:,::4] | |
| predicts = torch.max(outputs, dim=1)[1] | |
| correct += (predicts.cpu() == targets).sum() | |
| total += len(targets) | |
| return np.around(tensor2numpy(correct)*100 / total, decimals=2) | |
| def _eval_cnn(self, loader): | |
| self._network.eval() | |
| y_pred, y_true = [], [] | |
| for _, (_, inputs, targets) in enumerate(loader): | |
| inputs = inputs.to(self._device) | |
| with torch.no_grad(): | |
| outputs = self._network(inputs)["logits"][:,::4] | |
| predicts = torch.topk(outputs, k=self.topk, dim=1, largest=True, sorted=True)[1] | |
| y_pred.append(predicts.cpu().numpy()) | |
| y_true.append(targets.cpu().numpy()) | |
| return np.concatenate(y_pred), np.concatenate(y_true) | |
| def eval_task(self, save_conf=True): | |
| y_pred, y_true = self._eval_cnn(self.test_loader) | |
| cnn_accy = self._evaluate(y_pred, y_true) | |
| if hasattr(self, '_class_means'): | |
| y_pred, y_true = self._eval_nme(self.test_loader, self._class_means) | |
| nme_accy = self._evaluate(y_pred, y_true) | |
| elif hasattr(self, '_protos'): | |
| y_pred, y_true = self._eval_nme(self.test_loader, self._protos/np.linalg.norm(self._protos,axis=1)[:,None]) | |
| nme_accy = self._evaluate(y_pred, y_true) | |
| else: | |
| nme_accy = None | |
| if save_conf: | |
| _pred = y_pred.T[0] | |
| _pred_path = os.path.join(self.args['logfilename'], "pred.npy") | |
| _target_path = os.path.join(self.args['logfilename'], "target.npy") | |
| np.save(_pred_path, _pred) | |
| np.save(_target_path, y_true) | |
| _save_dir = os.path.join(f"./results/{self.args['model_name']}/conf_matrix/{self.args['prefix']}") | |
| os.makedirs(_save_dir, exist_ok=True) | |
| _save_path = os.path.join(_save_dir, f"{self.args['csv_name']}.csv") | |
| with open(_save_path, "a+") as f: | |
| f.write(f"{self.args['model_name']},{_pred_path},{_target_path} \n") | |
| return cnn_accy, nme_accy |