Python Model.save Examples

Example #1

File: convert.py Project: yangzijia/tf-keras-yolov3

def _main(args):
    config_path = os.path.expanduser(args.config_path)
    weights_path = os.path.expanduser(args.weights_path)
    assert config_path.endswith('.cfg'), '{} is not a .cfg file'.format(
        config_path)
    assert weights_path.endswith(
        '.weights'), '{} is not a .weights file'.format(weights_path)

    output_path = os.path.expanduser(args.output_path)
    assert output_path.endswith(
        '.h5'), 'output path {} is not a .h5 file'.format(output_path)
    output_root = os.path.splitext(output_path)[0]

    # Load weights and config.
    print('Loading weights.')
    weights_file = open(weights_path, 'rb')
    major, minor, revision = np.ndarray(
        shape=(3,), dtype='int32', buffer=weights_file.read(12))
    if (major * 10 + minor) >= 2 and major < 1000 and minor < 1000:
        seen = np.ndarray(shape=(1,), dtype='int64', buffer=weights_file.read(8))
    else:
        seen = np.ndarray(shape=(1,), dtype='int32', buffer=weights_file.read(4))
    print('Weights Header: ', major, minor, revision, seen)

    print('Parsing Darknet config.')
    unique_config_file = unique_config_sections(config_path)
    cfg_parser = configparser.ConfigParser()
    cfg_parser.read_file(unique_config_file)

    print('Creating Keras model.')
    input_layer = Input(shape=(None, None, 3), name='image_input')
    prev_layer = input_layer
    all_layers = []

    weight_decay = float(cfg_parser['net_0']['decay']
                         ) if 'net_0' in cfg_parser.sections() else 5e-4
    count = 0
    out_index = []
    for section in cfg_parser.sections():
        print('Parsing section {}'.format(section))
        if section.startswith('convolutional'):
            filters = int(cfg_parser[section]['filters'])
            size = int(cfg_parser[section]['size'])
            stride = int(cfg_parser[section]['stride'])
            pad = int(cfg_parser[section]['pad'])
            activation = cfg_parser[section]['activation']
            batch_normalize = 'batch_normalize' in cfg_parser[section]

            padding = 'same' if pad == 1 and stride == 1 else 'valid'

            # Setting weights.
            # Darknet serializes convolutional weights as:
            # [bias/beta, [gamma, mean, variance], conv_weights]
            prev_layer_shape = K.int_shape(prev_layer)

            weights_shape = (size, size, prev_layer_shape[-1], filters)
            darknet_w_shape = (filters, weights_shape[2], size, size)
            weights_size = np.product(weights_shape)

            print('conv2d', 'bn' if batch_normalize else '  ', activation, weights_shape)

            conv_bias = np.ndarray(
                shape=(filters,),
                dtype='float32',
                buffer=weights_file.read(filters * 4))
            count += filters

            if batch_normalize:
                bn_weights = np.ndarray(
                    shape=(3, filters),
                    dtype='float32',
                    buffer=weights_file.read(filters * 12))
                count += 3 * filters

                bn_weight_list = [
                    bn_weights[0],  # scale gamma
                    conv_bias,  # shift beta
                    bn_weights[1],  # running mean
                    bn_weights[2]  # running var
                ]

            conv_weights = np.ndarray(
                shape=darknet_w_shape,
                dtype='float32',
                buffer=weights_file.read(weights_size * 4))
            count += weights_size

            # DarkNet conv_weights are serialized Caffe-style:
            # (out_dim, in_dim, height, width)
            # We would like to set these to Tensorflow order:
            # (height, width, in_dim, out_dim)
            conv_weights = np.transpose(conv_weights, [2, 3, 1, 0])
            conv_weights = [conv_weights] if batch_normalize else [
                conv_weights, conv_bias
            ]

            # Handle activation.
            act_fn = None
            if activation == 'leaky':
                pass  # Add advanced activation later.
            elif activation == 'mish':
                pass  # Add advanced activation later.
            elif activation != 'linear':
                raise ValueError(
                    'Unknown activation function `{}` in section {}'.format(
                        activation, section))

            # Create Conv2D layer
            if stride > 1:
                # Darknet uses left and top padding instead of 'same' mode
                prev_layer = ZeroPadding2D(((1, 0), (1, 0)))(prev_layer)
            conv_layer = (Conv2D(
                filters, (size, size),
                strides=(stride, stride),
                kernel_regularizer=l2(weight_decay),
                use_bias=not batch_normalize,
                weights=conv_weights,
                activation=act_fn,
                padding=padding))(prev_layer)

            if batch_normalize:
                conv_layer = (BatchNormalization(
                    weights=bn_weight_list))(conv_layer)
            prev_layer = conv_layer

            if activation == 'linear':
                all_layers.append(prev_layer)
            # elif activation == 'mish':
            #     act_layer = Activation(mish)(prev_layer)
            #     prev_layer = act_layer
            #     all_layers.append(act_layer)
            elif activation == 'leaky':
                act_layer = LeakyReLU(alpha=0.1)(prev_layer)
                prev_layer = act_layer
                all_layers.append(act_layer)

        elif section.startswith('route'):
            ids = [int(i) for i in cfg_parser[section]['layers'].split(',')]
            layers = [all_layers[i] for i in ids]
            if len(layers) > 1:
                print('Concatenating route layers:', layers)
                concatenate_layer = Concatenate()(layers)
                all_layers.append(concatenate_layer)
                prev_layer = concatenate_layer
            else:
                skip_layer = layers[0]  # only one layer to route
                all_layers.append(skip_layer)
                prev_layer = skip_layer

        elif section.startswith('maxpool'):
            size = int(cfg_parser[section]['size'])
            stride = int(cfg_parser[section]['stride'])
            all_layers.append(
                MaxPooling2D(
                    pool_size=(size, size),
                    strides=(stride, stride),
                    padding='same')(prev_layer))
            prev_layer = all_layers[-1]

        elif section.startswith('avgpool'):
            all_layers.append(
                AveragePooling2D()(prev_layer))
            prev_layer = all_layers[-1]

        elif section.startswith('shortcut'):
            index = int(cfg_parser[section]['from'])
            activation = cfg_parser[section]['activation']
            assert activation == 'linear', 'Only linear activation supported.'
            all_layers.append(Add()([all_layers[index], prev_layer]))
            prev_layer = all_layers[-1]

        elif section.startswith('upsample'):
            stride = int(cfg_parser[section]['stride'])
            assert stride == 2, 'Only stride=2 supported.'
            all_layers.append(UpSampling2D(stride)(prev_layer))
            prev_layer = all_layers[-1]

        elif section.startswith('reorg'):
            block_size = int(cfg_parser[section]['stride'])
            assert block_size == 2, 'Only reorg with stride 2 supported.'
            all_layers.append(
                Lambda(
                    # space_to_depth_x2,
                    # output_shape=space_to_depth_x2_output_shape,
                    lambda x: tf.nn.space_to_depth(x, block_size=2),
                    name='space_to_depth_x2')(prev_layer))
            prev_layer = all_layers[-1]

        elif section.startswith('region'):
            with open('{}_anchors.txt'.format(output_root), 'w') as f:
                print(cfg_parser[section]['anchors'], file=f)

        elif section.startswith('yolo'):
            out_index.append(len(all_layers) - 1)
            all_layers.append(None)
            prev_layer = all_layers[-1]

        elif (section.startswith('net') or section.startswith('cost') or
              section.startswith('softmax')):
            pass

        else:
            raise ValueError(
                'Unsupported section header type: {}'.format(section))

    # Create and save model.
    if len(out_index) == 0: out_index.append(len(all_layers) - 1)

    if args.yolo4_reorder:
        # reverse the output tensor index for YOLOv4 cfg & weights,
        # since it use a different yolo outout order
        out_index.reverse()

    model = Model(inputs=input_layer, outputs=[all_layers[i] for i in out_index])
    print(model.summary())
    if args.weights_only:
        model.save_weights('{}'.format(output_path))
        print('Saved Keras weights to {}'.format(output_path))
    else:
        model.save('{}'.format(output_path))
        print('Saved Keras model to {}'.format(output_path))

    # Check to see if all weights have been read.
    remaining_weights = len(weights_file.read()) / 4
    weights_file.close()
    print('Read {} of {} from Darknet weights.'.format(count, count +
                                                       remaining_weights))
    if remaining_weights > 0:
        print('Warning: {} unused weights'.format(remaining_weights))

    if args.plot_model:
        plot(model, to_file='{}.png'.format(output_root), show_shapes=True)
        print('Saved model plot to {}.png'.format(output_root))

Example #2

              optimizer=Adam(lr=0.001,
                             beta_1=0.9,
                             beta_2=0.999,
                             epsilon=1e-08,
                             decay=0.0),
              metrics=['accuracy'])
times = 50
while (True):
    hist = model.fit(train_X,
                     train_Y,
                     batch_size=24,
                     epochs=times,
                     verbose=1,
                     validation_data=(test_X, test_Y))
    a = input("continue?y/n")
    if (a == "y"):
        times = int(input("times:"))
    else:
        break

(loss, accuracy) = model.evaluate(test_X, test_Y, batch_size=8, verbose=1)
prediction = model.predict(test_X)
predict = np.argmax(prediction, axis=1)
print("Save Model?y/n")
a = input()
if (a == "y"):
    print("Saving Model")
    model.save("GORES888.h5", overwrite=True, include_optimizer=True)
else:
    print("Over")

Example #3

out = Dense(num_classes, activation="softmax", name="output")(last_layer)
model = Model(image_input, out)
for layer in model.layers[:-1]:
    layer.trainable = False
model.summary()

model.compile(loss='sparse_categorical_crossentropy',
              optimizer=Adam(lr=0.001,
                             beta_1=0.9,
                             beta_2=0.999,
                             epsilon=1e-08,
                             decay=0.0),
              metrics=['accuracy'])

hist = model.fit(train_X,
                 train_Y,
                 batch_size=16,
                 epochs=30,
                 verbose=1,
                 validation_data=(test_X, test_Y))
(loss, accuracy) = model.evaluate(test_X, test_Y, batch_size=8, verbose=1)
prediction = model.predict(test_X)
predict = np.argmax(prediction, axis=1)
print("Save Model?y/n")
a = input()
if (a == "y"):
    print("Saving Model")
    model.save("RESRetry14.h5", overwrite=True, include_optimizer=True)
else:
    print("Over")

Example #4

def main(train_epochs):
    print('Hello Lenin Welcome to Transfer Learning with VGG16')
    # Reading images to form X vector
    labels_name = {'benign': 0, 'malignant': 1}
    img_data, img_labels = read_dataset('/data_roi_single/train',
                                        labels_dict=labels_name)
    print(np.unique(img_labels, return_counts=True))
    # categories_names = ['benign', 'malignant']
    num_classes = 2
    # labels = labelling_outputs(num_classes, img_data.shape[0])
    # labels = labelling_mammo(num_classes, img_data.shape[0])
    # converting class labels to one-hot encoding
    y_one_hot = to_categorical(img_labels, num_classes)
    #Shuffle data
    x, y = shuffle(img_data, y_one_hot, random_state=2)
    # Dataset split
    xtrain, xtest, ytrain, ytest = train_test_split(x,
                                                    y,
                                                    test_size=0.2,
                                                    random_state=2)

    #########################################################################################
    # Custom_vgg_model_1
    # Training the classifier alone
    image_input = Input(shape=(224, 224, 3))

    model = VGG16(input_tensor=image_input,
                  include_top=True,
                  weights='imagenet')
    model.summary()
    last_layer = model.get_layer('fc2').output
    out = Dense(num_classes, activation='sigmoid',
                name='vgg16TL')(last_layer)  # sigmoid insted of softmax
    custom_vgg_model = Model(image_input, out)
    custom_vgg_model.summary()
    # until this point the custom model is retrainable at all layers
    # Now we freeze all the layers up to the last one
    for layer in custom_vgg_model.layers[:-1]:
        layer.trainable = False
    custom_vgg_model.summary()

    # custom_vgg_model.layers[3].trainable
    # custom_vgg_model.layers[-1].trainable

    # Model compilation
    custom_vgg_model.compile(
        loss='binary_crossentropy', optimizer='rmsprop',
        metrics=['accuracy'])  # binary cross entropy instead of categorical
    print('Transfer Learning Training...')
    t = time.time()

    num_of_epochs = train_epochs  # User defines number of epochs

    hist = custom_vgg_model.fit(xtrain,
                                ytrain,
                                batch_size=64,
                                epochs=num_of_epochs,
                                verbose=1,
                                validation_data=(xtest, ytest))
    print('Training time: %s' % (time.time() - t))
    # Model saving parameters

    custom_vgg_model.save('vgg16_tf_bc.h5')

    print('Evaluation...')
    (loss, accuracy) = custom_vgg_model.evaluate(xtest,
                                                 ytest,
                                                 batch_size=10,
                                                 verbose=1)
    print("[INFO] loss={:.4f}, accuracy: {:.4f}%".format(loss, accuracy * 100))
    print("Finished")

    # Model Training Graphics
    # Visualizing losses and accuracy
    train_loss = hist.history['loss']
    val_loss = hist.history['val_loss']
    train_acc = hist.history['acc']
    val_acc = hist.history['val_acc']

    xc = range(num_of_epochs)  # Este valor esta anclado al numero de epocas

    plt.figure(1, figsize=(7, 5))
    plt.plot(xc, train_loss)
    plt.plot(xc, val_loss)
    plt.xlabel('num of epochs')
    plt.ylabel('loss')
    plt.title('train_loss vs val_loss')
    plt.grid(True)
    plt.legend(['train', 'val'])
    plt.style.use(['classic'])  # revisar que mas hay
    plt.savefig('vgg16_train_val_loss.jpg')

    plt.figure(2, figsize=(7, 5))
    plt.plot(xc, train_acc)
    plt.plot(xc, val_acc)
    plt.xlabel('num of epochs')
    plt.ylabel('accuracy')
    plt.title('train_accuracy vs val_accuracy')
    plt.grid(True)
    plt.legend(['train', 'val'], loc=4)
    plt.style.use(['classic'])  # revisar que mas hay
    plt.savefig('vgg16_train_val_acc.jpg')

    plt.show()