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decoders.py
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decoders.py
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from config import *
from keras.layers import *
from keras.models import *
def get_decoder_model(input, output):
img_input = input
o = output
o_shape = Model(img_input, o).output_shape
i_shape = Model(img_input, o).input_shape
if IMAGE_ORDERING == 'channels_first':
output_height = o_shape[2]
output_width = o_shape[3]
input_height = i_shape[2]
input_width = i_shape[3]
n_classes = o_shape[1]
o = (Reshape((-1, output_height * output_width)))(o)
o = (Permute((2, 1)))(o)
elif IMAGE_ORDERING == 'channels_last':
output_height = o_shape[1]
output_width = o_shape[2]
input_height = i_shape[1]
input_width = i_shape[2]
n_classes = o_shape[3]
o = (Reshape((output_height * output_width, -1)))(o)
o = (Activation('softmax'))(o)
model = Model(img_input, o)
model.output_width = output_width
model.output_height = output_height
model.n_classes = n_classes
model.input_height = input_height
model.input_width = input_width
model.encoder_name= ""
return model
# UNet decoder
def get_unet_decoder(n_classes, encoder, input_height=224, input_width=224, depth=3, filter_size=32, encoder_name=None, up_layer=False, trainable=True):
img_input, levels = encoder(input_height=input_height, input_width=input_width, depth=depth, filter_size=filter_size, encoder_name=encoder_name)
[f1, f2, f3, f4, f5] = levels
# 512
up6 = Conv2D(filter_size*2**3, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(f5))
merge6 = concatenate([f4,up6], axis = 3)
conv6 = Conv2D(filter_size*2**3, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(merge6)
conv6 = Conv2D(filter_size*2**3, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(conv6)
# 256
up7 = Conv2D(filter_size*2**2, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(conv6))
merge7 = concatenate([f3,up7], axis = 3)
conv7 = Conv2D(filter_size*2**2, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(merge7)
conv7 = Conv2D(filter_size*2**2, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(conv7)
# 128
up8 = Conv2D(filter_size*2, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(conv7))
merge8 = concatenate([f2,up8], axis = 3)
conv8 = Conv2D(filter_size*2, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(merge8)
conv8 = Conv2D(filter_size*2, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(conv8)
# 64
up9 = Conv2D(filter_size, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(conv8))
merge9 = concatenate([f1,up9], axis = 3)
o = Conv2D(filter_size, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(merge9)
o = Conv2D(filter_size, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(o)
if(up_layer):
up10 = Conv2D(filter_size, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(o))
merge10 = concatenate([img_input,up10], axis = 3)
o = Conv2D(int(filter_size/2), (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(merge10)
o = Conv2D(int(filter_size/2), (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(o)
o = Conv2D(n_classes, (3, 3), activation = 'relu', padding = 'same', data_format='channels_last')(o)
model = get_decoder_model(img_input, o)
if (encoder_name == 'ResNet50') or (encoder_name == 'NASNetMobile') or (encoder_name == 'NasNetLarge'):
n_pads = 2 # for one_side_pad
elif encoder_name == 'Xception':
n_pads = 5 # for 3 one_side_pad
else:
n_pads = 0 # for reshape
if not trainable and up_layer:
for layer in model.layers:
layer.trainable=False # Make the layer non-trainable
for layer in model.layers[-26-n_pads:]:
layer.trainable=True # Make only the last layers trainable
elif not trainable:
for layer in model.layers:
layer.trainable=False # Make the layer non-trainable
for layer in model.layers[-22-n_pads:]:
layer.trainable=True # Make only the last layers trainable
return model
# Modified UNet decoder
def get_unet_modified_decoder(n_classes, encoder, input_height=224, input_width=224, depth=3, filter_size=64, encoder_name=None, up_layer=False, trainable=True):
img_input, levels = encoder(input_height=input_height, input_width=input_width, depth=depth, filter_size=filter_size, encoder_name=encoder_name)
[f1, f2, f3, f4, f5] = levels
# 512
up6 = Conv2D(filter_size*2**3, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(f5))
merge6 = concatenate([f4,up6], axis = 3)
conv6 = Conv2D(filter_size*2**3, (3, 3), padding = 'same', data_format='channels_last')(merge6)
conv6 = BatchNormalization()(conv6)
conv6 = Activation('relu')(conv6)
conv6 = Conv2D(filter_size*2**3, (3, 3), padding = 'same', data_format='channels_last')(conv6)
conv6 = BatchNormalization()(conv6)
conv6 = Activation('relu')(conv6)
# conv6 = Dropout(0.5)(conv6)
# 256
up7 = Conv2D(filter_size*2**2, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(conv6))
merge7 = concatenate([f3,up7], axis = 3)
conv7 = Conv2D(filter_size*2**2, (3, 3), padding = 'same', data_format='channels_last')(merge7)
conv7 = BatchNormalization()(conv7)
conv7 = Activation('relu')(conv7)
conv7 = Conv2D(filter_size*2**2, (3, 3), padding = 'same', data_format='channels_last')(conv7)
conv7 = BatchNormalization()(conv7)
conv7 = Activation('relu')(conv7)
# 128
up8 = Conv2D(filter_size*2, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(conv7))
merge8 = concatenate([f2,up8], axis = 3)
conv8 = Conv2D(filter_size*2, (3, 3), padding = 'same', data_format='channels_last')(merge8)
conv8 = BatchNormalization()(conv8)
conv8 = Activation('relu')(conv8)
conv8 = Conv2D(filter_size*2, (3, 3), padding = 'same', data_format='channels_last')(conv8)
conv8 = BatchNormalization()(conv8)
conv8 = Activation('relu')(conv8)
# 64
up9 = Conv2D(filter_size, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(conv8))
merge9 = concatenate([f1,up9], axis = 3)
o = Conv2D(filter_size, (3, 3), padding = 'same', data_format='channels_last')(merge9)
o = BatchNormalization()(o)
o = Activation('relu')(o)
o = Conv2D(filter_size, (3, 3), padding = 'same', data_format='channels_last')(merge9)
o = BatchNormalization()(o)
o = Activation('relu')(o)
if(up_layer):
up10 = Conv2D(filter_size, (2, 2), activation = 'relu', padding = 'same', data_format='channels_last')(UpSampling2D(size = (2,2))(o))
merge10 = concatenate([img_input,up10], axis = 3)
o = Conv2D(int(filter_size/2), (3, 3), padding = 'same', data_format='channels_last')(merge10)
o = BatchNormalization()(o)
o = Activation('relu')(o)
o = Conv2D(int(filter_size/2), (3, 3), padding = 'same', data_format='channels_last')(o)
o = BatchNormalization()(o)
o = Activation('relu')(o)
o = Conv2D(n_classes, (3, 3), padding = 'same', data_format='channels_last')(o)
o = BatchNormalization()(o)
o = Activation('relu')(o)
model = get_decoder_model(img_input, o)
if (encoder_name == 'ResNet50') or (encoder_name == 'NASNetMobile') or (encoder_name == 'NasNetLarge'):
n_pads = 2 # for one_side_pad
elif encoder_name == 'Xception':
n_pads = 5 # for 3 one_side_pad
else:
n_pads = 0 # for reshape
if not trainable and up_layer:
for layer in model.layers:
layer.trainable=False # Make the layer non-trainable
for layer in model.layers[-26-n_pads:]:
layer.trainable=True # Make only the last layers trainable
elif not trainable:
for layer in model.layers:
layer.trainable=False # Make the layer non-trainable
for layer in model.layers[-22-n_pads:]:
layer.trainable=True # Make only the last layers trainable
return model