def main():
    user_input = get_input_args()

    image_datasets, dataloaders = utilfunc.create_dataloaders(
        user_input.data_dir)
    model = modfunc.create_model(user_input.arch,
                                 output_size=user_input.outsize,
                                 change_classifier=user_input.change_class,
                                 nodes_per_hlayer=user_input.npl)

    optimizer = optim.Adam(model.classifier.parameters(), lr=user_input.lr)
    criterion = nn.NLLLoss()

    network_training(model=model,
                     dataloaders=dataloaders,
                     epochs=user_input.epochs,
                     learning_rate=user_input.lr,
                     with_gpu=user_input.gpu)

    modfunc.save_checkpoint(filename=user_input.save_dir,
                            model=model,
                            image_datasets=image_datasets,
                            architecture=user_input.arch,
                            output_size=user_input.outsize,
                            hidden_layers=user_input.npl,
                            learning_rate=user_input.lr,
                            optimizer=optimizer,
                            epochs=user_input.epochs)
            if steps % print_every == 0:
            
                # change model to evaluation mode
                model.eval()
            
                # perform validation steps
                with torch.no_grad():
                    valid_loss, accuracy = validation(model, criterion, validloader)
            
                print('Epoch {}/{}'.format(e+1, epochs))
                print('Training loss: {:.4f}'.format(running_loss/print_every))
                print('Validation loss: {:.4f}'.format(valid_loss/len(validloader)))
                print('Validation accuracy: {:.4f}%'.format((accuracy/len(validloader))*100))
            
                running_loss = 0
            
                # change model back to training mode
                model.train()


# set class_to_idx mapping for model
model.class_to_idx = train_dataset.class_to_idx

# save model checkpoint
if args['save_dir'] is None:
    save_filepath = data_dir + '/checkpoint.pth'
else:
    save_filepath = args['save_dir'] + '/checkpoint.pth'

save_checkpoint(model, arch, optimizer, epochs, input_size, output_size, hidden_units, save_filepath)
Ejemplo n.º 3
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if arguments.gpu:
    device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
else:
    device = "cpu"

#load datasets
loaded_datasets = load_datasets(arguments.dir)

#create the model
model = create_model(loaded_datasets['image_datasets'], arguments.arch,
                     arguments.hidden_units)

#train the model
criterion = nn.NLLLoss()
optimizer = optim.Adam(model.classifier.parameters(),
                       lr=arguments.learning_rate)
train_network(loaded_datasets['dataloaders'], model, criterion, optimizer,
              arguments.epochs, device)

#save trained model
save_checkpoint(criterion, arguments.epochs, optimizer, model, arguments.arch,
                arguments.save_dir)

# print("Command Line Arguments:\n    dir =", arguments.dir,
#       "\n    arch =", arguments.arch,
#       "\n    learning_rate =", arguments.learning_rate,
#       "\n    hidden_units =", arguments.hidden_units,
#       "\n    gpu =", arguments.gpu,
#       "\n    epochs =", arguments.epochs,
#       "\n    save_dir =", arguments.save_dir)
# We want to ensure the final layers are consistent with our problem by using an ordered dictionary.
classifier = nn.Sequential(OrderedDict([('fc1', nn.Linear(input_size, arguments.num_hidden)), # Number of neurons in the hidden layer
                                        ('relu', nn.ReLU()), # ReLU activation function will squish the output space of the previous layer
                                        ('drop', nn.Dropout(p=0.5)), # Used to prevent overfitting - for any node in the network this will equate to 50% chance it will be randomly turned off
                                        ('fc2', nn.Linear(arguments.num_hidden, 102)), # Input 5000, Output layer of 102
                                        ('output', nn.LogSoftmax(dim=1))])) # Squishes the output space to be between 0 - 1 i.e. probability of class assignment for each image. Ideal for multiclass problems

# Ensure we overwrite the model classifier with the newly configured ordered dictionary
model.classifier = classifier

# Setting up the model input arguments (hyperparameters)

# Model, criterion, optimizer, scheduler, num_epochs=25, device='cuda'

# Model is initialised in block above to pretrained vgg16 with classifier adjusted

# Criteria here represents the loss function used to evaluate the model fit 
# NLLLoss which is recommended with Softmax final layer
criteria = nn.NLLLoss()

# Observe that all parameters are being optimized with a learning rate of 0.001 for gradient descent
optim = torch.optim.Adam(model.classifier.parameters(), arguments.learning_rate)

# Provides different methods for adjusting the learning rate and step size used during optimisation
# Decay LR by a factor of 0.1 every 3 epochs
sched = lr_scheduler.StepLR(optim, step_size=arguments.step_size_sched, gamma=arguments.gamma_lrsched)

model_functions.train_model(model, criteria, optim, sched, arguments.epochs, dataset_sizes, data_loaders, arguments.device)
model_functions.test_acc(model, data_loaders, arguments.device)
model_functions.save_checkpoint(model, optim, image_datasets, arguments.arch, arguments.epochs, arguments.learning_rate, input_size, arguments.num_hidden)
Ejemplo n.º 5
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                            torch.FloatTensor)).item()

                print(
                    f"Epoch {epoch+1}/{epochs}.. "
                    f"Train loss: {running_loss/print_every:.3f}.. "
                    f"Validation loss: {validation_loss/len(validloader):.3f}.. "
                    f"Validation accuracy: {100*accuracy/len(validloader):.3f}"
                )

                running_loss = 0
                model.train()
    print('Training complete.')

##### Save checkpoint
#if args.save_dir not in os.listdir():
if not os.path.isdir(args.save_dir):
    os.mkdir(args.save_dir)

save_checkpoint(model,
                train_dataset,
                h_units[0],
                h_units[1],
                h_units[2],
                h_units[3],
                h_units[4],
                epochs,
                learn,
                optimizer,
                criterion,
                filename=args.save_dir + '/0502_densenet161_ams.pth',
                arch=arch)
Ejemplo n.º 6
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    model = models.alexnet(pretrained=True)
    
print(model)

# Freeze pretrained model parameters to avoid backpropogating through them
for parameter in model.parameters():
    parameter.requires_grad = False

# Build custom classifier
classifier = nn.Sequential(OrderedDict([('fc1', nn.Linear(input_size, arguments.hidden_units)),
                                        ('relu', nn.ReLU()),
                                        ('drop', nn.Dropout(p=0.5)),
                                        ('fc2', nn.Linear(arguments.hidden_units, 11)),
                                        ('output', nn.LogSoftmax(dim=1))]))

model.classifier = classifier

# Loss function (since the output is LogSoftmax, we use NLLLoss)
criterion = nn.NLLLoss()

# Gradient descent optimizer
optimizer = optim.Adam(model.classifier.parameters(), lr=arguments.learning_rate)
    
model_functions.train_classifier(model, optimizer, criterion, arguments.epochs, train_loader, validate_loader, arguments.gpu)
    
model_functions.test_accuracy(model, test_loader, arguments.gpu)

model_functions.save_checkpoint(model, training_dataset, arguments.arch, arguments.epochs, arguments.learning_rate, arguments.hidden_units, input_size)  

    
def main():

    # Parse the arguments passed by the user
    parsed_arguments = arg_parser()

    # Define train, test and validation directories based on the data directory passed by the user.
    # Check if those directories exist. If not break the program.
    if (os.path.isdir(parsed_arguments.data_directory + "/test")
            and os.path.isdir(parsed_arguments.data_directory + "/train")
            and os.path.isdir(parsed_arguments.data_directory + "/valid")):
        data_dir = parsed_arguments.data_directory
        train_dir = data_dir + '/train'
        valid_dir = data_dir + '/valid'
        test_dir = data_dir + '/test'

        # Create a transforms for the specific directory
        train_transform = data_functions.create_transform(train_dir)
        valid_transform = data_functions.create_transform(valid_dir)
        test_transform = data_functions.create_transform(test_dir)

        # Create dataloader for the data sets
        trainloader = data_functions.define_dataloader(train_dir,
                                                       train_transform)
        validloader = data_functions.define_dataloader(valid_dir,
                                                       valid_transform)
        testloader = data_functions.define_dataloader(test_dir, test_transform)

        # Create a mapping from category label to category name
        cat_to_name = data_functions.label_mapping('cat_to_name.json')

        # Load a pretrained model according to architecture given by the user
        model = model_functions.load_pretrained_model(parsed_arguments.arch)

        # Freeze parameters in the model
        for param in model.parameters():
            param.requires_grad = False

        # Define a new classifier
        new_classifier = model_functions.create_new_classifier(
            model.classifier[0].in_features, parsed_arguments.hidden_units)

        # Replace the model classifier
        model.classifier = new_classifier

        # Define criterion and optimizer
        criterion = nn.NLLLoss()
        optimizer = optim.Adam(model.classifier.parameters(), lr=0.00075)

        # Use proper device (cpu/gpu)
        device = torch.device("cuda:0" if (
            torch.cuda.is_available() and parsed_arguments.gpu) else "cpu")
        print(device)
        model.to(device)

        # Train the network
        model = model_functions.train_network(model, trainloader, validloader,
                                              optimizer, criterion,
                                              parsed_arguments.epochs, device)

        # Validate the network
        #validation_accuracy = model_functions.network_accuracy(model, validloader, device)
        #print('Accuracy on the validation images: %d %%' % validation_accuracy)

        # Check accuracy on the test dataset
        training_accuracy = model_functions.network_accuracy(
            model, testloader, device)
        print('Accuracy on the test images: %d %%' % training_accuracy)

        # Save the checkpoint
        model.class_to_idx = datasets.ImageFolder(
            train_dir, transform=train_transform).class_to_idx
        model_functions.save_checkpoint(model, parsed_arguments.arch,
                                        model.classifier[0].in_features,
                                        parsed_arguments.hidden_units,
                                        parsed_arguments.save_dir,
                                        parsed_arguments.gpu)

    else:
        print("Could not find test, train or valid folder inside of %s",
              parsed_arguments.data_directory)

    return
def main():
    
    # Get command line input arguments
    in_arg = get_input_args()
    
    # Load data
    train_loader, valid_loader, test_loader, train_data = model_functions.load_data(in_arg.data_dir)
    
    # Define Learning Rate
    learn_rate = in_arg.learning_rate

    # Use GPU if available
    device = torch.device("cuda" if torch.cuda.is_available() else "cpu")

    model = models.densenet121(pretrained=True) # Download the model

    # Freeze parameters in model feature so we don't backprop through them
    for param in model.parameters():
        param.requires_grad = False
    
    # Create an instance of the Classifier object 
    model.classifier = Classifier()

    # Create an instance of the Loss object
    criterion = nn.NLLLoss()

    # Only train the classifier parameters, feature parameters are frozen 
    optimizer = optim.Adam(model.classifier.parameters(), lr=learn_rate)

    model.to(device) # Move model to either CPU or GPU

    train_losses, valid_losses, test_losses = [], [], []
    epochs = in_arg.epochs

    with active_session():
        for e in range(epochs):
            running_loss = 0
            # ----------- Training Pass ----------- 
            for images, labels in train_loader:
                # Move image and label tensors to default device
                images, labels = images.to(device), labels.to(device)
                optimizer.zero_grad() # Zero gradient
                log_pbs = model.forward(images) # Forward pass  
                loss = criterion(log_pbs, labels) # Calulate the loss
                loss.backward() # Calculate gradients with loss
                optimizer.step() # Update weights
                running_loss += loss.item()  

                # ---------- Validation Pass ----------
            else:
                valid_loss = 0
                accuracy = 0
                with torch.no_grad():
                    model.eval() # Eval mode - dropout off
                    for images, labels in valid_loader:
                        # Move image and label tensors to default device
                        images, labels = images.to(device), labels.to(device)
                        valid_log_pbs = model.forward(images) # Forward pass
                        valid_loss += criterion(valid_log_pbs, labels) # Calculate validation loss

                        pbs = torch.exp(valid_log_pbs) # Calculate validation probabilities
                        top_p, top_c = pbs.topk(1, dim=1) # Get top predicted class from our model
                        equality = top_c == labels.view(*top_c.shape) # Check if top class == label
                        accuracy += torch.mean(equality.type(torch.FloatTensor)) # Calculate accuracy 

                model.train() # Train mode
                train_losses.append(running_loss/len(train_loader))
                valid_losses.append(valid_loss/len(valid_loader))

                # --- Print Statements ---
                print("Epochs: {}/{} -- ".format(e+1, epochs),
                      "Training Loss: {:.3f} -- ".format(running_loss/len(train_loader)),
                      "Valid Loss: {:.3f} -- ".format(valid_loss/len(valid_loader)),
                      "Valid Accuracy: {:.3f}% -- ".format(accuracy.item()/len(valid_loader)*100))
  
    ## -------------
    # Run model on test images to get accuracy on new images
    test_loss = 0
    test_accuracy = 0

    with torch.no_grad():
        model.eval()
        for images, labels in test_loader:
            images, labels = images.to(device), labels.to(device) # Transfer Tensors to default device
            test_log_pbs = model.forward(images) # Forward pass
            test_loss += criterion(test_log_pbs, labels) # Calculate loss

            ps = torch.exp(test_log_pbs)
            top_p, top_c = ps.topk(1, dim=1)
            equality = top_c == labels.view(*top_c.shape)
            test_accuracy += torch.mean(equality.type(torch.FloatTensor))

    model.train() # Train mode
    test_losses.append(test_loss/len(test_loader))

    # --- Print Statements ---
    print("Test Loss: {:.3f} -- ".format(test_loss/len(test_loader)),
          "Test Accuracy: {:.3f}% -- ".format(test_accuracy.item()/len(test_loader)*100))

        ## -------------
    # Save the model checkpoint
    model_functions.save_checkpoint(train_data, epochs, model, in_arg.save_dir)
Ejemplo n.º 9
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def main():

    # Measures total program runtime by collecting start time
    start_time = time()

    # Collect training parameter from the console interface
    in_arg = get_input_train()

    # Check consistency of the input parameters
    control_input_args_train(in_arg.data_dir, in_arg.save_dir, in_arg.arch,
                             in_arg.hidden_units, in_arg.gpu)

    # Choose betwen GPU and CPU
    if in_arg.gpu[:1].lower() == 'y':
        device = 'cuda:0'
    else:
        device = 'cpu'
    print(f"\n Running on '{device}' device...\n")

    # Load training and validation dataloaders
    purpose = 'train'
    train_dataloader = create_dataloader(in_arg.data_dir, purpose)
    purpose = 'valid'
    valid_dataloader = create_dataloader(in_arg.data_dir, purpose)

    #Build and train the classifier network
    model = train_network(device, train_dataloader, valid_dataloader,
                          in_arg.arch, int(in_arg.hidden_units),
                          int(in_arg.epochs), float(in_arg.learning_rate),
                          float(in_arg.dropout_rate))

    #Test accuracy of the classifier netwoork build
    purpose = 'test'
    batch_size = 5
    test_dataloader = create_dataloader(in_arg.data_dir, purpose, batch_size)

    result = evaluate_network(model, test_dataloader)

    #Saved the built classifier network if accuracy is higher than 40%
    if result > 40:
        dataset = datasets.ImageFolder(in_arg.data_dir + '/train')
        # Attach category attribute to the model to facilitate classe inference during prediction
        model.class_to_idx = dataset.class_to_idx
        saved_model = save_checkpoint(model, in_arg.save_dir, in_arg.arch,
                                      result)
        print(f" GOOD PERFORMANCE!!!"
              f" The trained model was saved...{saved_model}"
              f" Test accuracy: {result:.3f} %")
    else:
        print(f" BAD PERFORMANCE!!!"
              f" The trained model was not saved..."
              f" Test accuracy: {result:.3f} %")

    # Measure total program runtime by collecting end time
    end_time = time()
    # Computes overall runtime in seconds & prints it in hh:mm:ss format
    tot_time = end_time - start_time
    print(
        "\n** Total Elapsed Runtime:",
        str(int((tot_time / 3600))) + ":" + str(int(
            (tot_time % 3600) / 60)) + ":" + str(int((tot_time % 3600) % 60)))