def test_predict(): autoencoder = Mock() autoencoder.return_value = torch.zeros(10, 100) dataset = TensorDataset(torch.zeros(100, 100), torch.zeros(100, 1)) output = predict(dataset, autoencoder, batch_size=10, cuda=False) assert autoencoder.call_count == 10 assert output.shape == (100, )
def main(data_dir, cuda, batch_size, pretrain_epochs, finetune_epochs, testing_mode): writer = SummaryWriter() # create the TensorBoard object # callback function to call during training, uses writer from the scope def training_callback(epoch, lr, loss, validation_loss): writer.add_scalars('data/autoencoder', { 'lr': lr, 'loss': loss, 'validation_loss': validation_loss, }, epoch) device = 'cuda' if torch.cuda.is_available() else 'cpu' ds_train = CachedMNIST(data_dir, is_train=True, device=device, testing_mode=testing_mode) # training dataset ds_val = CachedMNIST(data_dir, is_train=False, device=device, testing_mode=testing_mode) # evaluation dataset autoencoder = StackedDenoisingAutoEncoder([28 * 28, 500, 500, 2000, 10], final_activation=None) autoencoder = autoencoder.to(device) print('Pretraining stage.') ae.pretrain( ds_train, autoencoder, device=device, validation=ds_val, epochs=pretrain_epochs, batch_size=batch_size, silent=True, optimizer=lambda model: SGD(model.parameters(), lr=0.1, momentum=0.9), scheduler=lambda x: StepLR(x, 20000, gamma=0.1), corruption=0.2) print('Training stage.') ae_optimizer = SGD(params=autoencoder.parameters(), lr=0.1, momentum=0.9) ae.train(ds_train, autoencoder, device=device, validation=ds_val, epochs=finetune_epochs, batch_size=batch_size, silent=True, optimizer=ae_optimizer, scheduler=StepLR(ae_optimizer, 20000, gamma=0.1), corruption=0.2, update_callback=training_callback) print('DEC stage.') model = DEC(cluster_number=10, embedding_dimension=28 * 28, hidden_dimension=10, encoder=autoencoder.encoder) model = model.to(device) dec_optimizer = SGD(model.parameters(), lr=0.01, momentum=0.9) train(dataset=ds_train, model=model, epochs=20000, batch_size=256, silent=True, optimizer=dec_optimizer, stopping_delta=0.000001, cuda=cuda) predicted, actual = predict(ds_train, model, 1024, silent=True, return_actual=True, cuda=cuda) actual = actual.cpu().numpy() predicted = predicted.cpu().numpy() reassignment, accuracy = cluster_accuracy(actual, predicted) print('Final DEC accuracy: %s' % accuracy) if not testing_mode: predicted_reassigned = [reassignment[item] for item in predicted] # TODO numpify confusion = confusion_matrix(actual, predicted_reassigned) normalised_confusion = confusion.astype('float') / confusion.sum( axis=1)[:, np.newaxis] confusion_id = uuid.uuid4().hex sns.heatmap(normalised_confusion).get_figure().savefig( 'confusion_%s.png' % confusion_id) print('Writing out confusion diagram with UUID: %s' % confusion_id) writer.close()
def main(cuda, batch_size, pretrain_epochs, finetune_epochs, testing_mode): writer = SummaryWriter() # create the TensorBoard object # callback function to call during training, uses writer from the scope def training_callback(epoch, lr, loss, validation_loss): writer.add_scalars( "data/autoencoder", { "lr": lr, "loss": loss, "validation_loss": validation_loss, }, epoch, ) ds_train = CachedMNIST(train=True, cuda=cuda, testing_mode=testing_mode) # training dataset ds_val = CachedMNIST(train=False, cuda=cuda, testing_mode=testing_mode) # evaluation dataset autoencoder = StackedDenoisingAutoEncoder([28 * 28, 500, 500, 2000, 10], final_activation=None) if cuda: autoencoder.cuda() print("Pretraining stage.") ae.pretrain( ds_train, autoencoder, cuda=cuda, validation=ds_val, epochs=pretrain_epochs, batch_size=batch_size, optimizer=lambda model: SGD(model.parameters(), lr=0.1, momentum=0.9), scheduler=lambda x: StepLR(x, 100, gamma=0.1), corruption=0.2, ) print("Training stage.") ae_optimizer = SGD(params=autoencoder.parameters(), lr=0.1, momentum=0.9) ae.train( ds_train, autoencoder, cuda=cuda, validation=ds_val, epochs=finetune_epochs, batch_size=batch_size, optimizer=ae_optimizer, scheduler=StepLR(ae_optimizer, 100, gamma=0.1), corruption=0.2, update_callback=training_callback, ) print("DEC stage.") model = DEC(cluster_number=10, hidden_dimension=10, encoder=autoencoder.encoder) if cuda: model.cuda() dec_optimizer = SGD(model.parameters(), lr=0.01, momentum=0.9) train( dataset=ds_train, model=model, epochs=100, batch_size=256, optimizer=dec_optimizer, stopping_delta=0.000001, cuda=cuda, ) predicted, actual = predict(ds_train, model, 1024, silent=True, return_actual=True, cuda=cuda) actual = actual.cpu().numpy() predicted = predicted.cpu().numpy() reassignment, accuracy = cluster_accuracy(actual, predicted) print("Final DEC accuracy: %s" % accuracy) if not testing_mode: predicted_reassigned = [reassignment[item] for item in predicted] # TODO numpify confusion = confusion_matrix(actual, predicted_reassigned) normalised_confusion = (confusion.astype("float") / confusion.sum(axis=1)[:, np.newaxis]) confusion_id = uuid.uuid4().hex sns.heatmap(normalised_confusion).get_figure().savefig( "confusion_%s.png" % confusion_id) print("Writing out confusion diagram with UUID: %s" % confusion_id) writer.close()