Exemplo n.º 1
0
def train_model_retinanet(model,
                          dataset,
                          expt='',
                          test_size=.2,
                          n_epoch=10,
                          batch_size=1,
                          num_gpus=None,
                          include_masks=False,
                          panoptic=False,
                          panoptic_weight=0.1,
                          transforms=['watershed'],
                          transforms_kwargs={},
                          anchor_params=None,
                          pyramid_levels=['P3', 'P4', 'P5', 'P6', 'P7'],
                          min_objects=3,
                          mask_size=(28, 28),
                          optimizer=SGD(lr=0.01,
                                        decay=1e-6,
                                        momentum=0.9,
                                        nesterov=True),
                          log_dir='/data/tensorboard_logs',
                          model_dir='/data/models',
                          model_name=None,
                          sigma=3.0,
                          alpha=0.25,
                          gamma=2.0,
                          score_threshold=0.01,
                          iou_threshold=0.5,
                          max_detections=100,
                          weighted_average=True,
                          lr_sched=rate_scheduler(lr=0.01, decay=0.95),
                          rotation_range=0,
                          flip=True,
                          shear=0,
                          zoom_range=0,
                          compute_map=True,
                          seed=0,
                          **kwargs):
    """Train a RetinaNet model from the given backbone.

    Adapted from:
        https://github.com/fizyr/keras-retinanet &
        https://github.com/fizyr/keras-maskrcnn

    Args:
        model (tensorflow.keras.Model): The model to train.
        dataset (str): Path to a dataset to train the model with.
        expt (str): Experiment, substring to include in model name.
        test_size (float): Percent of data to leave as test data.
        n_epoch (int): Number of training epochs.
        batch_size (int): Number of batches per training step.
        num_gpus (int): The number of GPUs to train on.
        include_masks (bool): Whether to generate masks using MaskRCNN.
        panoptic (bool): Whether to include semantic segmentation heads.
        panoptic_weight (float): Weight applied to the semantic loss.
        transforms (list): List of transform names as strings. Each transform
            will have its own semantic segmentation head.
        transforms_kwargs (list): List of dicts of optional values for each
            transform in transforms.
        anchor_params (AnchorParameters): Struct containing anchor parameters.
            If None, default values are used.
        pyramid_levels (list): Pyramid levels to attach
            the object detection heads to.
        min_objects (int): If a training image has fewer than min_objects
            objects, the image will not be used for training.
        mask_size (tuple): The size of the masks.
        log_dir (str): Filepath to save tensorboard logs. If None, disables
            the tensorboard callback.
        model_dir (str): Directory to save the model file.
        model_name (str): Name of the model (and name of output file).
        sigma (float): The point where the loss changes from L2 to L1.
        alpha (float): Scale the focal weight with alpha.
        gamma (float): Take the power of the focal weight with gamma.
        iou_threshold (float): The threshold used to consider when a detection
            is positive or negative.
        score_threshold (float): The score confidence threshold
            to use for detections.
        max_detections (int): The maximum number of detections to use per image
        weighted_average (bool): Use a weighted average in evaluation.
        optimizer (object): Pre-initialized optimizer object (SGD, Adam, etc.)
        lr_sched (function): Learning rate schedular function
        rotation_range (int): Maximum rotation range for image augmentation
        flip (bool): Enables horizontal and vertical flipping for augmentation
        shear (int): Maximum rotation range for image augmentation
        zoom_range (tuple): Minimum and maximum zoom values (0.8, 1.2)
        seed (int): Random seed
        compute_map (bool): Whether to compute mAP at end of training.
        kwargs (dict): Other parameters to pass to _transform_masks

    Returns:
        tensorflow.keras.Model: The trained model
    """

    is_channels_first = K.image_data_format() == 'channels_first'

    if model_name is None:
        todays_date = datetime.datetime.now().strftime('%Y-%m-%d')
        data_name = os.path.splitext(os.path.basename(dataset))[0]
        model_name = '{}_{}_{}'.format(todays_date, data_name, expt)

    model_path = os.path.join(model_dir, '{}.h5'.format(model_name))
    loss_path = os.path.join(model_dir, '{}.npz'.format(model_name))

    train_dict, test_dict = get_data(dataset, seed=seed, test_size=test_size)

    channel_axis = 1 if is_channels_first else -1
    n_classes = model.layers[-1].output_shape[channel_axis]

    if panoptic:
        n_semantic_classes = [
            layer.output_shape[channel_axis] for layer in model.layers
            if 'semantic' in layer.name
        ]
    else:
        n_semantic_classes = []

    # the data, shuffled and split between train and test sets
    print('X_train shape:', train_dict['X'].shape)
    print('y_train shape:', train_dict['y'].shape)
    print('X_test shape:', test_dict['X'].shape)
    print('y_test shape:', test_dict['y'].shape)
    print('Output Shape:', model.layers[-1].output_shape)
    print('Number of Classes:', n_classes)

    if num_gpus is None:
        num_gpus = train_utils.count_gpus()

    if num_gpus >= 1e6:
        batch_size = batch_size * num_gpus
        model = train_utils.MultiGpuModel(model, num_gpus)

    print('Training on {} GPUs'.format(num_gpus))

    # evaluation of model is done on `retinanet_bbox`
    if include_masks:
        prediction_model = model
    else:
        prediction_model = retinanet_bbox(
            model,
            nms=True,
            anchor_params=anchor_params,
            num_semantic_heads=len(n_semantic_classes),
            panoptic=panoptic,
            class_specific_filter=False)

    retinanet_losses = losses.RetinaNetLosses(sigma=sigma,
                                              alpha=alpha,
                                              gamma=gamma,
                                              iou_threshold=iou_threshold,
                                              mask_size=mask_size)

    def semantic_loss(n_classes):
        def _semantic_loss(y_pred, y_true):
            return panoptic_weight * losses.weighted_categorical_crossentropy(
                y_pred, y_true, n_classes=n_classes)

        return _semantic_loss

    loss = {
        'regression': retinanet_losses.regress_loss,
        'classification': retinanet_losses.classification_loss
    }

    if include_masks:
        loss['masks'] = retinanet_losses.mask_loss

    if panoptic:
        # Give losses for all of the semantic heads
        for layer in model.layers:
            if 'semantic' in layer.name:
                n_classes = layer.output_shape[channel_axis]
                loss[layer.name] = semantic_loss(n_classes)

    model.compile(loss=loss, optimizer=optimizer)

    if num_gpus >= 2:
        # Each GPU must have at least one validation example
        if test_dict['y'].shape[0] < num_gpus:
            raise ValueError('Not enough validation data for {} GPUs. '
                             'Received {} validation sample.'.format(
                                 test_dict['y'].shape[0], num_gpus))

        # When using multiple GPUs and skip_connections,
        # the training data must be evenly distributed across all GPUs
        num_train = train_dict['y'].shape[0]
        nb_samples = num_train - num_train % batch_size
        if nb_samples:
            train_dict['y'] = train_dict['y'][:nb_samples]
            train_dict['X'] = train_dict['X'][:nb_samples]

    # this will do preprocessing and realtime data augmentation
    datagen = image_generators.RetinaNetGenerator(
        # fill_mode='constant',  # for rotations
        rotation_range=rotation_range,
        shear_range=shear,
        zoom_range=zoom_range,
        horizontal_flip=flip,
        vertical_flip=flip)

    datagen_val = image_generators.RetinaNetGenerator(
        # fill_mode='constant',  # for rotations
        rotation_range=0,
        shear_range=0,
        zoom_range=0,
        horizontal_flip=0,
        vertical_flip=0)

    # if 'vgg' in backbone or 'densenet' in backbone:
    #     compute_shapes = make_shapes_callback(model)
    # else:
    #     compute_shapes = guess_shapes

    compute_shapes = guess_shapes

    train_data = datagen.flow(train_dict,
                              seed=seed,
                              include_masks=include_masks,
                              panoptic=panoptic,
                              transforms=transforms,
                              transforms_kwargs=transforms_kwargs,
                              pyramid_levels=pyramid_levels,
                              min_objects=min_objects,
                              anchor_params=anchor_params,
                              compute_shapes=compute_shapes,
                              batch_size=batch_size)

    val_data = datagen_val.flow(test_dict,
                                seed=seed,
                                include_masks=include_masks,
                                panoptic=panoptic,
                                transforms=transforms,
                                transforms_kwargs=transforms_kwargs,
                                pyramid_levels=pyramid_levels,
                                min_objects=min_objects,
                                anchor_params=anchor_params,
                                compute_shapes=compute_shapes,
                                batch_size=batch_size)

    train_callbacks = get_callbacks(model_path,
                                    lr_sched=lr_sched,
                                    tensorboard_log_dir=log_dir,
                                    save_weights_only=num_gpus >= 2,
                                    monitor='val_loss',
                                    verbose=1)

    eval_callback = RedirectModel(
        Evaluate(val_data,
                 iou_threshold=iou_threshold,
                 score_threshold=score_threshold,
                 max_detections=max_detections,
                 tensorboard=train_callbacks[-1] if log_dir else None,
                 weighted_average=weighted_average), prediction_model)

    train_callbacks.append(eval_callback)

    # fit the model on the batches generated by datagen.flow()
    loss_history = model.fit_generator(
        train_data,
        steps_per_epoch=train_data.y.shape[0] // batch_size,
        epochs=n_epoch,
        validation_data=val_data,
        validation_steps=val_data.y.shape[0] // batch_size,
        callbacks=train_callbacks)

    model.save_weights(model_path)
    np.savez(loss_path, loss_history=loss_history.history)

    if compute_map:
        average_precisions = evaluate(
            val_data,
            prediction_model,
            iou_threshold=iou_threshold,
            score_threshold=score_threshold,
            max_detections=max_detections,
        )

        # print evaluation
        total_instances = []
        precisions = []
        for label, (average_precision,
                    num_annotations) in average_precisions.items():
            print('{:.0f} instances of class'.format(num_annotations), label,
                  'with average precision: {:.4f}'.format(average_precision))
            total_instances.append(num_annotations)
            precisions.append(average_precision)

        if sum(total_instances) == 0:
            print('No test instances found.')
        else:
            print(
                'mAP using the weighted average of precisions among classes: {:.4f}'
                .format(
                    sum([a * b for a, b in zip(total_instances, precisions)]) /
                    sum(total_instances)))
            print('mAP: {:.4f}'.format(
                sum(precisions) / sum(x > 0 for x in total_instances)))

    return model
Exemplo n.º 2
0
def train_model_retinanet(model,
                          dataset,
                          backbone,
                          expt='',
                          test_size=.1,
                          n_epoch=10,
                          batch_size=1,
                          num_gpus=None,
                          include_masks=False,
                          panoptic=False,
                          panoptic_weight=1,
                          anchor_params=None,
                          pyramid_levels=['P3', 'P4', 'P5', 'P6', 'P7'],
                          mask_size=(28, 28),
                          optimizer=SGD(lr=0.01,
                                        decay=1e-6,
                                        momentum=0.9,
                                        nesterov=True),
                          log_dir='/data/tensorboard_logs',
                          model_dir='/data/models',
                          model_name=None,
                          sigma=3.0,
                          alpha=0.25,
                          gamma=2.0,
                          score_threshold=0.01,
                          iou_threshold=0.5,
                          max_detections=100,
                          weighted_average=True,
                          lr_sched=rate_scheduler(lr=0.01, decay=0.95),
                          rotation_range=0,
                          flip=True,
                          shear=0,
                          zoom_range=0,
                          seed=None,
                          **kwargs):
    """Train a RetinaNet model from the given backbone

    Adapted from:
        https://github.com/fizyr/keras-retinanet &
        https://github.com/fizyr/keras-maskrcnn
    """

    is_channels_first = K.image_data_format() == 'channels_first'

    if model_name is None:
        todays_date = datetime.datetime.now().strftime('%Y-%m-%d')
        data_name = os.path.splitext(os.path.basename(dataset))[0]
        model_name = '{}_{}_{}'.format(todays_date, data_name, expt)

    model_path = os.path.join(model_dir, '{}.h5'.format(model_name))
    loss_path = os.path.join(model_dir, '{}.npz'.format(model_name))

    train_dict, test_dict = get_data(dataset, seed=seed, test_size=test_size)

    channel_axis = 1 if is_channels_first else -1
    n_classes = model.layers[-1].output_shape[channel_axis]

    if panoptic:
        n_semantic_classes = model.get_layer(
            name='semantic').output_shape[channel_axis]

    # the data, shuffled and split between train and test sets
    print('X_train shape:', train_dict['X'].shape)
    print('y_train shape:', train_dict['y'].shape)
    print('X_test shape:', test_dict['X'].shape)
    print('y_test shape:', test_dict['y'].shape)
    print('Output Shape:', model.layers[-1].output_shape)
    print('Number of Classes:', n_classes)

    if num_gpus is None:
        num_gpus = train_utils.count_gpus()

    if num_gpus >= 1e6:
        batch_size = batch_size * num_gpus
        model = train_utils.MultiGpuModel(model, num_gpus)

    print('Training on {} GPUs'.format(num_gpus))

    # evaluation of model is done on `retinanet_bbox`
    if include_masks:
        prediction_model = model
    else:
        prediction_model = retinanet_bbox(model,
                                          nms=True,
                                          anchor_params=anchor_params,
                                          panoptic=panoptic,
                                          class_specific_filter=False)

    retinanet_losses = losses.RetinaNetLosses(sigma=sigma,
                                              alpha=alpha,
                                              gamma=gamma,
                                              iou_threshold=iou_threshold,
                                              mask_size=mask_size)

    def semantic_loss(y_pred, y_true):
        return panoptic_weight * losses.weighted_categorical_crossentropy(
            y_pred, y_true, n_classes=n_semantic_classes)

    loss = {
        'regression': retinanet_losses.regress_loss,
        'classification': retinanet_losses.classification_loss
    }

    if include_masks:
        loss['masks'] = retinanet_losses.mask_loss

    if panoptic:
        loss['semantic'] = semantic_loss

    model.compile(loss=loss, optimizer=optimizer)

    if num_gpus >= 2:
        # Each GPU must have at least one validation example
        if test_dict['y'].shape[0] < num_gpus:
            raise ValueError('Not enough validation data for {} GPUs. '
                             'Received {} validation sample.'.format(
                                 test_dict['y'].shape[0], num_gpus))

        # When using multiple GPUs and skip_connections,
        # the training data must be evenly distributed across all GPUs
        num_train = train_dict['y'].shape[0]
        nb_samples = num_train - num_train % batch_size
        if nb_samples:
            train_dict['y'] = train_dict['y'][:nb_samples]
            train_dict['X'] = train_dict['X'][:nb_samples]

    # this will do preprocessing and realtime data augmentation
    datagen = image_generators.RetinaNetGenerator(
        # fill_mode='constant',  # for rotations
        rotation_range=rotation_range,
        shear_range=shear,
        zoom_range=zoom_range,
        horizontal_flip=flip,
        vertical_flip=flip)

    datagen_val = image_generators.RetinaNetGenerator(
        # fill_mode='constant',  # for rotations
        rotation_range=0,
        shear_range=0,
        zoom_range=0,
        horizontal_flip=0,
        vertical_flip=0)

    if 'vgg' in backbone or 'densenet' in backbone:
        compute_shapes = make_shapes_callback(model)
    else:
        compute_shapes = guess_shapes

    train_data = datagen.flow(train_dict,
                              seed=seed,
                              include_masks=include_masks,
                              panoptic=panoptic,
                              pyramid_levels=pyramid_levels,
                              anchor_params=anchor_params,
                              compute_shapes=compute_shapes,
                              batch_size=batch_size)

    val_data = datagen_val.flow(test_dict,
                                seed=seed,
                                include_masks=include_masks,
                                panoptic=panoptic,
                                pyramid_levels=pyramid_levels,
                                anchor_params=anchor_params,
                                compute_shapes=compute_shapes,
                                batch_size=batch_size)

    tensorboard_callback = callbacks.TensorBoard(
        log_dir=os.path.join(log_dir, model_name))

    # fit the model on the batches generated by datagen.flow()
    loss_history = model.fit_generator(
        train_data,
        steps_per_epoch=train_data.y.shape[0] // batch_size,
        epochs=n_epoch,
        validation_data=val_data,
        validation_steps=val_data.y.shape[0] // batch_size,
        callbacks=[
            callbacks.LearningRateScheduler(lr_sched),
            callbacks.ModelCheckpoint(model_path,
                                      monitor='val_loss',
                                      verbose=1,
                                      save_best_only=True,
                                      save_weights_only=num_gpus >= 2),
            tensorboard_callback,
            callbacks.ReduceLROnPlateau(monitor='loss',
                                        factor=0.1,
                                        patience=10,
                                        verbose=1,
                                        mode='auto',
                                        min_delta=0.0001,
                                        cooldown=0,
                                        min_lr=0),
            RedirectModel(
                Evaluate(val_data,
                         iou_threshold=iou_threshold,
                         score_threshold=score_threshold,
                         max_detections=max_detections,
                         tensorboard=tensorboard_callback,
                         weighted_average=weighted_average), prediction_model),
        ])

    model.save_weights(model_path)
    np.savez(loss_path, loss_history=loss_history.history)

    average_precisions = evaluate(
        val_data,
        prediction_model,
        iou_threshold=iou_threshold,
        score_threshold=score_threshold,
        max_detections=max_detections,
    )

    # print evaluation
    total_instances = []
    precisions = []
    for label, (average_precision,
                num_annotations) in average_precisions.items():
        print('{:.0f} instances of class'.format(num_annotations), label,
              'with average precision: {:.4f}'.format(average_precision))
        total_instances.append(num_annotations)
        precisions.append(average_precision)

    if sum(total_instances) == 0:
        print('No test instances found.')
    else:
        print(
            'mAP using the weighted average of precisions among classes: {:.4f}'
            .format(
                sum([a * b for a, b in zip(total_instances, precisions)]) /
                sum(total_instances)))
        print('mAP: {:.4f}'.format(
            sum(precisions) / sum(x > 0 for x in total_instances)))

    return model
Exemplo n.º 3
0
def train_model_retinanet(model,
                          dataset,
                          backbone,
                          expt='',
                          test_size=.1,
                          n_epoch=10,
                          batch_size=1,
                          num_gpus=None,
                          include_masks=False,
                          mask_size=(28, 28),
                          optimizer=SGD(lr=0.01,
                                        decay=1e-6,
                                        momentum=0.9,
                                        nesterov=True),
                          log_dir='/data/tensorboard_logs',
                          model_dir='/data/models',
                          model_name=None,
                          sigma=3.0,
                          alpha=0.25,
                          gamma=2.0,
                          score_threshold=0.01,
                          iou_threshold=0.5,
                          max_detections=100,
                          weighted_average=True,
                          lr_sched=rate_scheduler(lr=0.01, decay=0.95),
                          rotation_range=0,
                          flip=True,
                          shear=0,
                          zoom_range=0,
                          **kwargs):
    """Train a RetinaNet model from the given backbone

    Adapted from:
        https://github.com/fizyr/keras-retinanet &
        https://github.com/fizyr/keras-maskrcnn
    """
    is_channels_first = K.image_data_format() == 'channels_first'

    if model_name is None:
        todays_date = datetime.datetime.now().strftime('%Y-%m-%d')
        data_name = os.path.splitext(os.path.basename(dataset))[0]
        model_name = '{}_{}_{}'.format(todays_date, data_name, expt)
    model_path = os.path.join(model_dir, '{}.h5'.format(model_name))
    loss_path = os.path.join(model_dir, '{}.npz'.format(model_name))

    train_dict, test_dict = get_data(dataset, mode='conv', test_size=test_size)

    n_classes = model.layers[-1].output_shape[1 if is_channels_first else -1]
    # the data, shuffled and split between train and test sets
    print('X_train shape:', train_dict['X'].shape)
    print('y_train shape:', train_dict['y'].shape)
    print('X_test shape:', test_dict['X'].shape)
    print('y_test shape:', test_dict['y'].shape)
    print('Output Shape:', model.layers[-1].output_shape)
    print('Number of Classes:', n_classes)

    if num_gpus is None:
        num_gpus = train_utils.count_gpus()

    if num_gpus >= 1e6:
        batch_size = batch_size * num_gpus
        model = train_utils.MultiGpuModel(model, num_gpus)

    print('Training on {} GPUs'.format(num_gpus))

    def regress_loss(y_true, y_pred):
        # separate target and state
        regression = y_pred
        regression_target = y_true[..., :-1]
        anchor_state = y_true[..., -1]

        # filter out "ignore" anchors
        indices = tf.where(K.equal(anchor_state, 1))
        regression = tf.gather_nd(regression, indices)
        regression_target = tf.gather_nd(regression_target, indices)

        # compute the loss
        loss = losses.smooth_l1(regression_target, regression, sigma=sigma)

        # compute the normalizer: the number of positive anchors
        normalizer = K.maximum(1, K.shape(indices)[0])
        normalizer = K.cast(normalizer, dtype=K.floatx())

        return K.sum(loss) / normalizer

    def classification_loss(y_true, y_pred):
        # TODO: try weighted_categorical_crossentropy
        labels = y_true[..., :-1]
        # -1 for ignore, 0 for background, 1 for object
        anchor_state = y_true[..., -1]

        classification = y_pred
        # filter out "ignore" anchors
        indices = tf.where(K.not_equal(anchor_state, -1))
        labels = tf.gather_nd(labels, indices)
        classification = tf.gather_nd(classification, indices)

        # compute the loss
        loss = losses.focal(labels, classification, alpha=alpha, gamma=gamma)

        # compute the normalizer: the number of positive anchors
        normalizer = tf.where(K.equal(anchor_state, 1))
        normalizer = K.cast(K.shape(normalizer)[0], K.floatx())
        normalizer = K.maximum(K.cast_to_floatx(1.0), normalizer)

        return K.sum(loss) / normalizer

    def mask_loss(y_true, y_pred):
        def _mask(y_true, y_pred, iou_threshold=0.5, mask_size=(28, 28)):
            # split up the different predicted blobs
            boxes = y_pred[:, :, :4]
            masks = y_pred[:, :, 4:]

            # split up the different blobs
            annotations = y_true[:, :, :5]
            width = K.cast(y_true[0, 0, 5], dtype='int32')
            height = K.cast(y_true[0, 0, 6], dtype='int32')
            masks_target = y_true[:, :, 7:]

            # reshape the masks back to their original size
            masks_target = K.reshape(masks_target,
                                     (K.shape(masks_target)[0] *
                                      K.shape(masks_target)[1], height, width))
            masks = K.reshape(masks, (K.shape(masks)[0] * K.shape(masks)[1],
                                      mask_size[0], mask_size[1], -1))

            # batch size > 1 fix
            boxes = K.reshape(boxes, (-1, K.shape(boxes)[2]))
            annotations = K.reshape(annotations, (-1, K.shape(annotations)[2]))

            # compute overlap of boxes with annotations
            iou = overlap(boxes, annotations)
            argmax_overlaps_inds = K.argmax(iou, axis=1)
            max_iou = K.max(iou, axis=1)

            # filter those with IoU > 0.5
            indices = tf.where(K.greater_equal(max_iou, iou_threshold))
            boxes = tf.gather_nd(boxes, indices)
            masks = tf.gather_nd(masks, indices)
            argmax_overlaps_inds = tf.gather_nd(argmax_overlaps_inds, indices)
            argmax_overlaps_inds = K.cast(argmax_overlaps_inds, 'int32')
            labels = K.gather(annotations[:, 4], argmax_overlaps_inds)
            labels = K.cast(labels, 'int32')

            # make normalized boxes
            x1 = boxes[:, 0]
            y1 = boxes[:, 1]
            x2 = boxes[:, 2]
            y2 = boxes[:, 3]
            boxes = K.stack([
                y1 / (K.cast(height, dtype=K.floatx()) - 1),
                x1 / (K.cast(width, dtype=K.floatx()) - 1),
                (y2 - 1) / (K.cast(height, dtype=K.floatx()) - 1),
                (x2 - 1) / (K.cast(width, dtype=K.floatx()) - 1),
            ],
                            axis=1)

            # crop and resize masks_target
            # append a fake channel dimension
            masks_target = K.expand_dims(masks_target, axis=3)
            masks_target = tf.image.crop_and_resize(masks_target, boxes,
                                                    argmax_overlaps_inds,
                                                    mask_size)

            # remove fake channel dimension
            masks_target = masks_target[:, :, :, 0]

            # gather the predicted masks using the annotation label
            masks = tf.transpose(masks, (0, 3, 1, 2))
            label_indices = K.stack([tf.range(K.shape(labels)[0]), labels],
                                    axis=1)
            masks = tf.gather_nd(masks, label_indices)

            # compute mask loss
            mask_loss = K.binary_crossentropy(masks_target, masks)
            normalizer = K.shape(masks)[0] * K.shape(masks)[1] * K.shape(
                masks)[2]
            normalizer = K.maximum(K.cast(normalizer, K.floatx()), 1)
            mask_loss = K.sum(mask_loss) / normalizer

            return mask_loss

        # if there are no masks annotations, return 0; else, compute the masks loss
        return tf.cond(
            K.any(K.equal(K.shape(y_true), 0)), lambda: K.cast_to_floatx(0.0),
            lambda: _mask(y_true,
                          y_pred,
                          iou_threshold=iou_threshold,
                          mask_size=mask_size))

    # evaluation of model is done on `retinanet_bbox`
    if include_masks:
        prediction_model = model
    else:
        prediction_model = retinanet_bbox(model,
                                          nms=True,
                                          class_specific_filter=False)

    loss = {'regression': regress_loss, 'classification': classification_loss}

    if include_masks:
        loss['masks'] = mask_loss

    model.compile(loss=loss, optimizer=optimizer)

    if num_gpus >= 2:
        # Each GPU must have at least one validation example
        if test_dict['y'].shape[0] < num_gpus:
            raise ValueError('Not enough validation data for {} GPUs. '
                             'Received {} validation sample.'.format(
                                 test_dict['y'].shape[0], num_gpus))

        # When using multiple GPUs and skip_connections,
        # the training data must be evenly distributed across all GPUs
        num_train = train_dict['y'].shape[0]
        nb_samples = num_train - num_train % batch_size
        if nb_samples:
            train_dict['y'] = train_dict['y'][:nb_samples]
            train_dict['X'] = train_dict['X'][:nb_samples]

    # this will do preprocessing and realtime data augmentation
    datagen = image_generators.RetinaNetGenerator(
        # fill_mode='constant',  # for rotations
        rotation_range=rotation_range,
        shear_range=shear,
        zoom_range=zoom_range,
        horizontal_flip=flip,
        vertical_flip=flip)

    datagen_val = image_generators.RetinaNetGenerator(
        # fill_mode='constant',  # for rotations
        rotation_range=0,
        shear_range=0,
        zoom_range=0,
        horizontal_flip=0,
        vertical_flip=0)

    if 'vgg' in backbone or 'densenet' in backbone:
        compute_shapes = make_shapes_callback(model)
    else:
        compute_shapes = guess_shapes

    train_data = datagen.flow(train_dict,
                              include_masks=include_masks,
                              compute_shapes=compute_shapes,
                              batch_size=batch_size)

    val_data = datagen_val.flow(test_dict,
                                include_masks=include_masks,
                                compute_shapes=compute_shapes,
                                batch_size=batch_size)

    tensorboard_callback = callbacks.TensorBoard(
        log_dir=os.path.join(log_dir, model_name))

    # fit the model on the batches generated by datagen.flow()
    loss_history = model.fit_generator(
        train_data,
        steps_per_epoch=train_data.y.shape[0] // batch_size,
        epochs=n_epoch,
        validation_data=val_data,
        validation_steps=val_data.y.shape[0] // batch_size,
        callbacks=[
            callbacks.LearningRateScheduler(lr_sched),
            callbacks.ModelCheckpoint(model_path,
                                      monitor='val_loss',
                                      verbose=1,
                                      save_best_only=True,
                                      save_weights_only=num_gpus >= 2),
            tensorboard_callback,
            callbacks.ReduceLROnPlateau(monitor='loss',
                                        factor=0.1,
                                        patience=10,
                                        verbose=1,
                                        mode='auto',
                                        min_delta=0.0001,
                                        cooldown=0,
                                        min_lr=0),
            RedirectModel(
                Evaluate(val_data,
                         iou_threshold=iou_threshold,
                         score_threshold=score_threshold,
                         max_detections=max_detections,
                         tensorboard=tensorboard_callback,
                         weighted_average=weighted_average), prediction_model),
        ])

    model.save_weights(model_path)
    np.savez(loss_path, loss_history=loss_history.history)

    average_precisions = evaluate(
        val_data,
        prediction_model,
        iou_threshold=iou_threshold,
        score_threshold=score_threshold,
        max_detections=max_detections,
    )

    # print evaluation
    total_instances = []
    precisions = []
    for label, (average_precision,
                num_annotations) in average_precisions.items():
        print('{:.0f} instances of class'.format(num_annotations), label,
              'with average precision: {:.4f}'.format(average_precision))
        total_instances.append(num_annotations)
        precisions.append(average_precision)

    if sum(total_instances) == 0:
        print('No test instances found.')
    else:
        print(
            'mAP using the weighted average of precisions among classes: {:.4f}'
            .format(
                sum([a * b for a, b in zip(total_instances, precisions)]) /
                sum(total_instances)))
        print('mAP: {:.4f}'.format(
            sum(precisions) / sum(x > 0 for x in total_instances)))

    return model