DenseGender.py

# Copyright (c) Hiren Galiyawala, Kenil Shah, Vandit Gajjar, and Mehul S. Raval.

# '''
# from keras.models import Model
# from keras.layers import Input, merge, ZeroPadding2D
# from keras.layers.core import Dense, Dropout, Activation
# from keras.layers.convolutional import Convolution2D
# from keras.layers.pooling import AveragePooling2D, GlobalAveragePooling2D, MaxPooling2D
# from keras.layers.normalization import BatchNormalization
# from keras.layers import concatenate
# import keras.backend as K
#
# from mrcnn.custom_layers.scale_layer import Scale
#
# def DenseNet(nb_dense_block=4, growth_rate=32, nb_filter=64, reduction=0.0, dropout_rate=0.0, weight_decay=1e-4, classes=1000, weights_path=None):
#     '''Instantiate the DenseNet architecture,
#         # Arguments
#             nb_dense_block: number of dense blocks to add to end
#             growth_rate: number of filters to add per dense block
#             nb_filter: initial number of filters
#             reduction: reduction factor of transition blocks.
#             dropout_rate: dropout rate
#             weight_decay: weight decay factor
#             classes: optional number of classes to classify images
#             weights_path: path to pre-trained weights
#         # Returns
#             A Keras model instance.
#     '''
#     eps = 1.1e-5
#
#     # compute compression factor
#     compression = 1.0 - reduction
#
#     # Handle Dimension Ordering for different backends
#     global concat_axis
#     if K.image_dim_ordering() == 'tf':
#       concat_axis = 3
#       img_input = Input(shape=(350, 140, 3), name='data')
#     else:
#       concat_axis = 1
#       img_input = Input(shape=(3, 224, 224), name='data')
#
#     # From architecture for ImageNet (Table 1 in the paper)
#     nb_filter = 64
#     nb_layers = [6,12,32,32] # For DenseNet-169
#
#     # Initial convolution
#     x = ZeroPadding2D((3, 3), name='conv1_zeropadding')(img_input)
#     x = Convolution2D(nb_filter, 7, 7, subsample=(2, 2), name='conv1', bias=False)(x)
#     x = BatchNormalization(epsilon=eps, axis=concat_axis, name='conv1_bn')(x)
#     x = Scale(axis=concat_axis, name='conv1_scale')(x)
#     x = Activation('relu', name='relu1')(x)
#     x = ZeroPadding2D((1, 1), name='pool1_zeropadding')(x)
#     x = MaxPooling2D((3, 3), strides=(2, 2), name='pool1')(x)
#
#     # Add dense blocks
#     for block_idx in range(nb_dense_block - 1):
#         stage = block_idx+2
#         x, nb_filter = dense_block(x, stage, nb_layers[block_idx], nb_filter, growth_rate, dropout_rate=dropout_rate, weight_decay=weight_decay)
#
#         # Add transition_block
#         x = transition_block(x, stage, nb_filter, compression=compression, dropout_rate=dropout_rate, weight_decay=weight_decay)
#         nb_filter = int(nb_filter * compression)
#
#     final_stage = stage + 1
#     x, nb_filter = dense_block(x, final_stage, nb_layers[-1], nb_filter, growth_rate, dropout_rate=dropout_rate, weight_decay=weight_decay)
#
#     x = BatchNormalization(epsilon=eps, axis=concat_axis, name='conv'+str(final_stage)+'_blk_bn')(x)
#     x = Scale(axis=concat_axis, name='conv'+str(final_stage)+'_blk_scale')(x)
#     x = Activation('relu', name='relu'+str(final_stage)+'_blk')(x)
#     x = GlobalAveragePooling2D(name='pool'+str(final_stage))(x)
#
#     x = Dense(classes, name='fc6')(x)
#     x = Activation('softmax', name='prob')(x)
#
#     model = Model(img_input, x, name='densenet')
#
#     if weights_path is not None:
#       model.load_weights(weights_path)
#
#     return model
#
#
# def conv_block(x, stage, branch, nb_filter, dropout_rate=None, weight_decay=1e-4):
#     '''Apply BatchNorm, Relu, bottleneck 1x1 Conv2D, 3x3 Conv2D, and option dropout
#         # Arguments
#             x: input tensor
#             stage: index for dense block
#             branch: layer index within each dense block
#             nb_filter: number of filters
#             dropout_rate: dropout rate
#             weight_decay: weight decay factor
#     '''
#     eps = 1.1e-5
#     conv_name_base = 'conv' + str(stage) + '_' + str(branch)
#     relu_name_base = 'relu' + str(stage) + '_' + str(branch)
#
#     # 1x1 Convolution (Bottleneck layer)
#     inter_channel = nb_filter * 4
#     x = BatchNormalization(epsilon=eps, axis=concat_axis, name=conv_name_base+'_x1_bn')(x)
#     x = Scale(axis=concat_axis, name=conv_name_base+'_x1_scale')(x)
#     x = Activation('relu', name=relu_name_base+'_x1')(x)
#     x = Convolution2D(inter_channel, 1, 1, name=conv_name_base+'_x1', bias=False)(x)
#
#     if dropout_rate:
#         x = Dropout(dropout_rate)(x)
#
#     # 3x3 Convolution
#     x = BatchNormalization(epsilon=eps, axis=concat_axis, name=conv_name_base+'_x2_bn')(x)
#     x = Scale(axis=concat_axis, name=conv_name_base+'_x2_scale')(x)
#     x = Activation('relu', name=relu_name_base+'_x2')(x)
#     x = ZeroPadding2D((1, 1), name=conv_name_base+'_x2_zeropadding')(x)
#     x = Convolution2D(nb_filter, 3, 3, name=conv_name_base+'_x2', bias=False)(x)
#
#     if dropout_rate:
#         x = Dropout(dropout_rate)(x)
#
#     return x
#
#
# def transition_block(x, stage, nb_filter, compression=1.0, dropout_rate=None, weight_decay=1E-4):
#     ''' Apply BatchNorm, 1x1 Convolution, averagePooling, optional compression, dropout
#         # Arguments
#             x: input tensor
#             stage: index for dense block
#             nb_filter: number of filters
#             compression: calculated as 1 - reduction. Reduces the number of feature maps in the transition block.
#             dropout_rate: dropout rate
#             weight_decay: weight decay factor
#     '''
#
#     eps = 1.1e-5
#     conv_name_base = 'conv' + str(stage) + '_blk'
#     relu_name_base = 'relu' + str(stage) + '_blk'
#     pool_name_base = 'pool' + str(stage)
#
#     x = BatchNormalization(epsilon=eps, axis=concat_axis, name=conv_name_base+'_bn')(x)
#     x = Scale(axis=concat_axis, name=conv_name_base+'_scale')(x)
#     x = Activation('relu', name=relu_name_base)(x)
#     x = Convolution2D(int(nb_filter * compression), 1, 1, name=conv_name_base, bias=False)(x)
#
#     if dropout_rate:
#         x = Dropout(dropout_rate)(x)
#
#     x = AveragePooling2D((2, 2), strides=(2, 2), name=pool_name_base)(x)
#
#     return x
#
#
# def dense_block(x, stage, nb_layers, nb_filter, growth_rate, dropout_rate=None, weight_decay=1e-4, grow_nb_filters=True):
#     ''' Build a dense_block where the output of each conv_block is fed to subsequent ones
#         # Arguments
#             x: input tensor
#             stage: index for dense block
#             nb_layers: the number of layers of conv_block to append to the model.
#             nb_filter: number of filters
#             growth_rate: growth rate
#             dropout_rate: dropout rate
#             weight_decay: weight decay factor
#             grow_nb_filters: flag to decide to allow number of filters to grow
#     '''
#
#     eps = 1.1e-5
#     concat_feat = x
#
#     for i in range(nb_layers):
#         branch = i+1
#         x = conv_block(concat_feat, stage, branch, growth_rate, dropout_rate, weight_decay)
#         concat_feat = concatenate([concat_feat, x], name='concat_'+str(stage)+'_'+str(branch))
#
#         if grow_nb_filters:
#             nb_filter += growth_rate
#
#     return concat_feat, nb_filter
# '''

from keras.models import Model
from keras.layers import Input, merge, ZeroPadding2D
from keras.layers.core import Dense, Dropout, Activation
from keras.layers.convolutional import Conv2D
from keras.layers.pooling import AveragePooling2D, GlobalAveragePooling2D, MaxPooling2D
from keras.layers.normalization import BatchNormalization
from keras.layers import concatenate
import keras.backend as K

#from Object_Detection.Mask_RCNN.mrcnn.custom_layers.scale_layer import Scale
from custom_layers.scale_layer import Scale

def DenseNet(nb_dense_block=4, growth_rate=32, nb_filter=64, reduction=0.0, dropout_rate=0.0, weight_decay=1e-4, classes=1000, weights_path=None):
    '''Instantiate the DenseNet architecture,
        # Arguments
            nb_dense_block: number of dense blocks to add to end
            growth_rate: number of filters to add per dense block
            nb_filter: initial number of filters
            reduction: reduction factor of transition blocks.
            dropout_rate: dropout rate
            weight_decay: weight decay factor
            classes: optional number of classes to classify images
            weights_path: path to pre-trained weights
        # Returns
            A Keras model instance.
    '''
    eps = 1.1e-5

    # compute compression factor
    compression = 1.0 - reduction

    # Handle Dimension Ordering for different backends
    global concat_axis
    if K.image_dim_ordering() == 'tf':
      concat_axis = 3
      img_input = Input(shape=(350, 140, 3), name='data')
    else:
      concat_axis = 1
      img_input = Input(shape=(3, 224, 224), name='data')

    # From architecture for ImageNet (Table 1 in the paper)
    nb_filter = 64
    nb_layers = [6,12,32,32] # For DenseNet-169

    # Initial convolution
    x = ZeroPadding2D((3, 3), name='conv1_zeropadding')(img_input)
    x = Conv2D(nb_filter, (7, 7), subsample=(2, 2), name='conv1', use_bias=False)(x)
    x = BatchNormalization(epsilon=eps, axis=concat_axis, name='conv1_bn')(x)
    x = Scale(axis=concat_axis, name='conv1_scale')(x)
    x = Activation('relu', name='relu1')(x)
    x = ZeroPadding2D((1, 1), name='pool1_zeropadding')(x)
    x = MaxPooling2D((3, 3), strides=(2, 2), name='pool1')(x)

    # Add dense blocks
    for block_idx in range(nb_dense_block - 1):
        stage = block_idx+2
        x, nb_filter = dense_block(x, stage, nb_layers[block_idx], nb_filter, growth_rate, dropout_rate=dropout_rate, weight_decay=weight_decay)

        # Add transition_block
        x = transition_block(x, stage, nb_filter, compression=compression, dropout_rate=dropout_rate, weight_decay=weight_decay)
        nb_filter = int(nb_filter * compression)

    final_stage = stage + 1
    x, nb_filter = dense_block(x, final_stage, nb_layers[-1], nb_filter, growth_rate, dropout_rate=dropout_rate, weight_decay=weight_decay)

    x = BatchNormalization(epsilon=eps, axis=concat_axis, name='conv'+str(final_stage)+'_blk_bn')(x)
    x = Scale(axis=concat_axis, name='conv'+str(final_stage)+'_blk_scale')(x)
    x = Activation('relu', name='relu'+str(final_stage)+'_blk')(x)
    x = GlobalAveragePooling2D(name='pool'+str(final_stage))(x)

    x = Dense(classes, name='fc6')(x)
    x = Activation('softmax', name='prob')(x)

    model = Model(img_input, x, name='densenet')

    if weights_path is not None:
      model.load_weights(weights_path)

    return model


def conv_block(x, stage, branch, nb_filter, dropout_rate=None, weight_decay=1e-4):
    '''Apply BatchNorm, Relu, bottleneck 1x1 Conv2D, 3x3 Conv2D, and option dropout
        # Arguments
            x: input tensor
            stage: index for dense block
            branch: layer index within each dense block
            nb_filter: number of filters
            dropout_rate: dropout rate
            weight_decay: weight decay factor
    '''
    eps = 1.1e-5
    conv_name_base = 'conv' + str(stage) + '_' + str(branch)
    relu_name_base = 'relu' + str(stage) + '_' + str(branch)

    # 1x1 Convolution (Bottleneck layer)
    inter_channel = nb_filter * 4
    x = BatchNormalization(epsilon=eps, axis=concat_axis, name=conv_name_base+'_x1_bn')(x)
    x = Scale(axis=concat_axis, name=conv_name_base+'_x1_scale')(x)
    x = Activation('relu', name=relu_name_base+'_x1')(x)
    x = Conv2D(inter_channel, (1, 1), name=conv_name_base+'_x1', use_bias=False)(x)

    if dropout_rate:
        x = Dropout(dropout_rate)(x)

    # 3x3 Convolution
    x = BatchNormalization(epsilon=eps, axis=concat_axis, name=conv_name_base+'_x2_bn')(x)
    x = Scale(axis=concat_axis, name=conv_name_base+'_x2_scale')(x)
    x = Activation('relu', name=relu_name_base+'_x2')(x)
    x = ZeroPadding2D((1, 1), name=conv_name_base+'_x2_zeropadding')(x)
    x = Conv2D(nb_filter, (3, 3), name=conv_name_base+'_x2', use_bias=False)(x)

    if dropout_rate:
        x = Dropout(dropout_rate)(x)

    return x


def transition_block(x, stage, nb_filter, compression=1.0, dropout_rate=None, weight_decay=1E-4):
    ''' Apply BatchNorm, 1x1 Convolution, averagePooling, optional compression, dropout
        # Arguments
            x: input tensor
            stage: index for dense block
            nb_filter: number of filters
            compression: calculated as 1 - reduction. Reduces the number of feature maps in the transition block.
            dropout_rate: dropout rate
            weight_decay: weight decay factor
    '''

    eps = 1.1e-5
    conv_name_base = 'conv' + str(stage) + '_blk'
    relu_name_base = 'relu' + str(stage) + '_blk'
    pool_name_base = 'pool' + str(stage)

    x = BatchNormalization(epsilon=eps, axis=concat_axis, name=conv_name_base+'_bn')(x)
    x = Scale(axis=concat_axis, name=conv_name_base+'_scale')(x)
    x = Activation('relu', name=relu_name_base)(x)
    x = Conv2D(int(nb_filter * compression), (1, 1), name=conv_name_base, use_bias=False)(x)

    if dropout_rate:
        x = Dropout(dropout_rate)(x)

    x = AveragePooling2D((2, 2), strides=(2, 2), name=pool_name_base)(x)

    return x


def dense_block(x, stage, nb_layers, nb_filter, growth_rate, dropout_rate=None, weight_decay=1e-4, grow_nb_filters=True):
    ''' Build a dense_block where the output of each conv_block is fed to subsequent ones
        # Arguments
            x: input tensor
            stage: index for dense block
            nb_layers: the number of layers of conv_block to append to the model.
            nb_filter: number of filters
            growth_rate: growth rate
            dropout_rate: dropout rate
            weight_decay: weight decay factor
            grow_nb_filters: flag to decide to allow number of filters to grow
    '''

    eps = 1.1e-5
    concat_feat = x

    for i in range(nb_layers):
        branch = i+1
        x = conv_block(concat_feat, stage, branch, growth_rate, dropout_rate, weight_decay)
        concat_feat = concatenate([concat_feat, x], name='concat_'+str(stage)+'_'+str(branch))

        if grow_nb_filters:
            nb_filter += growth_rate

    return concat_feat, nb_filter