#BUILDING BLOCKS rnd_seed=1 import numpy as np import math import tensorflow as tf from architectures.utils.toolbox import * # DENSELY CONNECTED NETWORKS class DenseLayer(object): """ Creates a dense layer Constructor inputs: - name of layer - mi: (int) dimension of input to layer - mo: (int) dimension of output of the activated output - apply_batch_norm: (bool) wether applying or not batch_normalization along the 0 axis of input - f: (function) activation function of the output - w_init: (tensorflow initializer) which initializer to use for the layer weights Created attributes: - W: (tf variable) (mi x mo) weight matrix - bi: (tf variable) (mo, ) bias vector - bo: (tf variable) (mi, ) bias vector Class methods: - forward: input: X (tf tensor) previous output layer outputs: output (tf tensor) activated layer output as A = act_f(X * W+ bi) - set_session: Sets current session input: session: (tf session) current session """ def __init__(self, name, mi, mo, apply_batch_norm, keep_prob=1., act_f=None, w_init=None ): self.W = tf.get_variable( "W_%s" %name, shape=(mi,mo), initializer=w_init, ) self.bi = tf.get_variable( "bi_%s" %name, shape=(mo,), initializer=tf.zeros_initializer(), ) self.act_f=act_f self.name=name self.apply_batch_norm=apply_batch_norm self.keep_prob = keep_prob def forward(self, X, reuse, is_training): if not is_training: self.keep_prob=1. Z=tf.matmul(X,self.W)+self.bi if self.apply_batch_norm=='bn': Z=tf.contrib.layers.batch_norm( Z, decay=0.9, updates_collections=None, epsilon=1e-5, scale=True, is_training = is_training, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='in': Z = tf.contrib.layers.instance_norm( Z, center=True, scale=True, epsilon=1e-6, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='False': Z = Z activated=self.act_f(Z) output=tf.nn.dropout(activated, self.keep_prob, seed=rnd_seed) return output def set_session(self, session): self.session = session #2D CONVOLUTIONAL NETWORKS class AvgPool2D(object): """ Performs average 2D pooling of the input, with no dropout by default Note that this layer trains no parameters Constructor input: - filter_sz: (int) width and height of the square pooling window - stride: (int) horizontal and vertical value for the stride ?extend to square windows and stride? Class methods: forward: inputs: - X (tf tensor) previous activated layer output - output (tf tensor) average pooled layer output """ def __init__(self, filter_sz, stride, keep_prob=1): self.filter_sz = filter_sz self.stride = stride self.keep_prob = keep_prob def forward(self, X, reuse, is_training): if not is_training: self.keep_prob=1 output = X output = tf.nn.avg_pool(X, ksize=[1, self.filter_sz,self.filter_sz,1], strides=[1,self.stride, self.stride, 1], padding = 'SAME' ) output = tf.nn.dropout(output, self.keep_prob, seed=rnd_seed) return output def set_session(self, session): self.session = session class MaxPool2D(object): """ Performs max 2D pooling of the input, with no dropout by default Note that this layer trains no parameters Constructor input: - filter_sz: (int) width and height of the square pooling window - stride: (int) horizontal and vertical value for the stride ?extend to square windows and stride? Class methods: forward: inputs: - X (tf tensor) previous activated layer output - output (tf tensor) max pooled layer output """ def __init__(self, filter_sz, stride, keep_prob=1): self.filter_sz = filter_sz self.stride = stride self.keep_prob = keep_prob def forward(self, X, reuse, is_training): output = X if not is_training: self.keep_prob=1 output = tf.nn.max_pool(output, ksize=[1, self.filter_sz,self.filter_sz,1], strides=[1,self.stride, self.stride, 1], padding = 'SAME' ) output = tf.nn.dropout(output, self.keep_prob, seed=rnd_seed) return output def set_session(self, session): self.session = session class ConvLayer(object): """ Performs 2D strided convlution on rectangular sized input tensor. Constructor inputs: - mi: (int) input channels - mo: (int) output channels - filter_sz: (int) width and height of the convolution kernel - stride: (int) horizontal and vertical size of the stride - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not - keep_prob: (int) dropout keep probability of propagated tensor - f: (function) activation layer function. tf.nn.relu by default - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) Class attributes - W: (tf tensor) variable tensor of dim (filter_sz, filter_sz, mi, mo) of trainable weights - b: (tf tensor) variable tensor of dim (mo, ) of trainable biases Class methods: - forward: inputs: X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer reuse: (bool) whether reusing the stored batch_normalization parameters or not is_training: (bool) flag that indicates whether we are in the process of training or not outputs: output: (tf tensor) activated output of dim (batch_sz, n_W, n_H, mo), input for next layer - set_session: Sets current session inputs: session: (tf session) current session """ def __init__( self, name, mi, mo, filter_sz, stride, apply_batch_norm, keep_prob = 1, f = None, w_init = None ): self.W = tf.get_variable( "W_%s" %name, shape=(filter_sz,filter_sz, mi, mo), initializer=w_init, ) self.b = tf.get_variable( "b_%s" %name, shape = (mo,), initializer=tf.zeros_initializer(), ) self.name = name self.f = f self.stride = stride self.apply_batch_norm = apply_batch_norm self.keep_prob=keep_prob def forward(self, X, reuse, is_training): if not is_training: self.keep_prob=1 conv_out = tf.nn.conv2d( X, self.W, strides=[1,self.stride,self.stride,1], padding='SAME' ) conv_out = tf.nn.bias_add(conv_out,self.b) #applying batch_norm if self.apply_batch_norm=='bn': conv_out=tf.contrib.layers.batch_norm( conv_out, decay=0.9, updates_collections=None, epsilon=1e-5, scale=True, is_training = is_training, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='in': conv_out = tf.contrib.layers.instance_norm( conv_out, center=True, scale=True, epsilon=1e-6, reuse=reuse, scope = self.name, ) else: return conv_out activated = self.f(conv_out) output = tf.nn.dropout(activated, self.keep_prob, seed=rnd_seed) return output def set_session(self, session): self.session = session class LocalConvLayer(object): """ Performs 2D strided local convlution on rectangular sized input tensor. Constructor inputs: - mi: (int) input channels - mo: (int) output channels - filter_sz: (int) width and height of the convolution kernel - stride: (int) horizontal and vertical size of the stride - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not - keep_prob: (int) dropout keep probability of propagated tensor - f: (function) activation layer function. tf.nn.relu by default - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) Class attributes - W: (tf tensor) variable tensor of dim (filter_sz, filter_sz, mi, mo) of trainable weights - b: (tf tensor) variable tensor of dim (mo, ) of trainable biases Class methods: - forward: inputs: X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer reuse: (bool) whether reusing the stored batch_normalization parameters or not is_training: (bool) flag that indicates whether we are in the process of training or not outputs: output: (tf tensor) activated output of dim (batch_sz, n_W, n_H, mo), input for next layer - set_session: Sets current session inputs: session: (tf session) current session """ def __init__( self, name, mi, mo, local_sz, filter_sz, stride, apply_batch_norm, keep_prob = 1, f = None, w_init = None ): patch_sz = (local_sz**2)*mi self.W = tf.get_variable( "W_%s" %name, shape=(filter_sz,filter_sz, patch_sz, mo), initializer=w_init, ) self.b = tf.get_variable( "b_%s" %name, shape = (mo,), initializer=tf.zeros_initializer(), ) self.name = name self.f = f self.stride = stride self.apply_batch_norm = apply_batch_norm self.keep_prob=keep_prob def forward(self, X, reuse, is_training): if not is_training: self.keep_prob=1 conv_out = tf.nn.conv2d( X, self.W, strides=[1,self.stride,self.stride,1], padding='SAME' ) conv_out = tf.nn.bias_add(conv_out,self.b) #applying batch_norm if self.apply_batch_norm=='bn': conv_out=tf.contrib.layers.batch_norm( conv_out, decay=0.9, updates_collections=None, epsilon=1e-5, scale=True, is_training = is_training, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='in': conv_out = tf.contrib.layers.instance_norm( conv_out, center=True, scale=True, epsilon=1e-6, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='False': return conv_out activated = self.f(conv_out) output = tf.nn.dropout(activated, self.keep_prob, seed=rnd_seed) return output def set_session(self, session): self.session = session class DeconvLayer(object): """ Performs 2D strided deconvlution on rectangular sized input tensor. Constructor inputs: - mi: (int) input channels - mo: (int) output channels - output_shape: list = [int, int], list[0]([1]) is the witdth (height) of the output after deconvolution, the layer computes the resizing automatically to match the output_shape. Default padding value is of 2 in both directions but can be modified. - filter_sz: (int) width and height of the convolution kernel - stride: (int) horizontal and vertical size of the stride - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not - keep_prob: (int) dropout keep probability of propagated tensor - f: (function) activation layer function. tf.nn.relu by default - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) Class attributes - W: (tf tensor) variable tensor of dim (filter_sz, filter_sz, mo, mo) of trainable weights - W_id: (tf tensor) variable tensor of dim (1, 1, mi, mo) of trainable weights - b: (tf tensor) variable tensor of dim (mo, ) of trainable biases Class methods: - forward: inputs: X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer reuse: (bool) whether reusing the stored batch_normalization parameters or not is_training: (bool) flag that indicates whether we are in the process of training or not The deconvolution is computed in 3 steps according to: (cite article) 1) conv2d with W_id is performed to match the output channels mo, with filter_sz=1 and stride=1 2) the image is reshaped to reshape_size_H and W 3) conv2d with W is performed with input filter_sz and stride, output width and height will match output_shape outputs: output: (tf tensor) activated output of dim (batch_sz, n_W=output_shape[0], n_H = output_shape[1], mo), input for next layer - set_session: Sets current session inputs: session: (tf session) current session """ def __init__(self, name, mi, mo, output_shape, filter_sz, stride, apply_batch_norm, keep_prob = 1, f=None, w_init = None ): #using resize + conv2d and not conv2dt #mi: input channels #mo: output channels #output_shape: width and height of the output image #performs 2 convolutions, the first augments the number of channels #the second performs a convolution with != 1 kernel and stride self.W = tf.get_variable( "W_%s" %name, shape=(filter_sz, filter_sz, mo, mo), initializer=w_init, ) self.W_id = tf.get_variable( 'W_%s_id' %name, shape=(1,1,mi, mo), initializer=w_init, ) self.b = tf.get_variable( "b_%s" %name, shape=(mo,), initializer=tf.zeros_initializer(), ) self.f = f self.stride = stride self.filter_sz = filter_sz self.name = name self.output_shape = output_shape self.apply_batch_norm = apply_batch_norm self.keep_prob = keep_prob def forward(self, X, reuse, is_training): if not is_training: self.keep_prob = 1 padding_value = 0 resized_shape_H = (self.output_shape[0] -1)*self.stride+ self.filter_sz-2*padding_value resized_shape_W = (self.output_shape[1] -1)*self.stride+ self.filter_sz-2*padding_value resized = tf.image.resize_images(X, [resized_shape_H, resized_shape_W], method=tf.image.ResizeMethod.BILINEAR) #print('After first resize shape', resized.get_shape()) output_id = tf.nn.conv2d( resized, self.W_id, strides=[1,1,1,1], padding='VALID' ) #print('After id deconvolution shape', output_id.get_shape()) paddings = tf.constant([[0,0], [padding_value, padding_value], [padding_value, padding_value], [0,0]]) output_id = tf.pad(output_id, paddings, 'CONSTANT' ) #print('After padding', output_id.get_shape()) conv_out = tf.nn.conv2d( output_id, self.W, strides=[1,self.stride,self.stride,1], padding='VALID' ) #print('After deconvolution', conv_out.get_shape()) conv_out = tf.nn.bias_add(conv_out,self.b) if self.apply_batch_norm=='bn': conv_out=tf.contrib.layers.batch_norm( conv_out, decay=0.9, updates_collections=None, epsilon=1e-5, scale=True, is_training = is_training, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='in': conv_out = tf.contrib.layers.instance_norm( conv_out, center=True, scale=True, epsilon=1e-6, reuse=reuse, scope = self.name, ) elif self.apply_batch_norm=='False': return conv_out activated = self.f(conv_out) output = tf.nn.dropout(activated, self.keep_prob, seed=rnd_seed) return output def set_session(self, session): self.session = session class ConvBlock(object): """ Performs series of 2D strided convolutions on rectangular sized input tensor. The convolution proceeds on two parallel paths: main path is composed by n subsequent convolutions while shortcut path has 1 convolution with different parameters and can be set as the identity convolution. Constructor inputs: - block_id: progressive number of block in the network - init_mi: (int) input channels - sizes: (dict) python dictionary with keys: sizes = { 'convblock_layer_n':[(n_c+1, kernel, stride, apply_batch_norm, keep_prob, act_f, weight initializer), (n_c+2,,,,,,,), (n_c+...,,,,,,,), (n_c+ last,,,,,,,], 'convblock_shortcut_layer_n':[(n_c+3, kernel, stride, apply_batch_norm, act_f, weight initializer)], 'dense_layers':[(dim output, apply_batch_norm, keep_prob, act_f, weight initializer )] } - filter_sz: (int) width and height of the convolution kernel at that layer - stride: (int) horizontal and vertical size of the stride at that layer - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not - keep_prob: (int) dropout keep probability of propagated tensor - f: (function) activation layer function. tf.nn.relu by default - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) sizes['convblock_layer_n'] is a list of tuples of layers specifications for the main path sizes['convblock_shortcut_layer_n'] is a list composed by 1 tuple of layer specifications for the shortcut path sizes['dense_layers'] is a list of tuples of layers specifications for the densely connected part of the network Class attributes - conv_layers: (list) list of conv_layer objects - shortcut_layer: (list) conv_layer object Class methods: - forward: inputs: X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer reuse: (bool) whether reusing the stored batch_normalization parameters or not is_training: (bool) flag that indicates whether we are in the process of training or not outputs: output: (tf tensor) activated output of dim (batch_sz, n_W, n_H, mo), input for next layer - set_session: Sets current session inputs: session: (tf session) current session """ def __init__(self, block_id, init_mi, sizes, ): #self.f=f self.conv_layers = [] mi = init_mi self.block_id=block_id #build the block #main path count=0 for mo, filter_sz, stride, apply_batch_norm, keep_prob, act_f, w_init in sizes['convblock_layer_'+str(self.block_id)][:-1]: name = 'convblock_{0}_layer_{1}'.format(block_id, count) count += 1 layer = ConvLayer(name, mi, mo, filter_sz, stride, apply_batch_norm, keep_prob, act_f, w_init) self.conv_layers.append(layer) mi = mo name = 'convblock_{0}_layer_{1}'.format(block_id, count) mo, filter_sz, stride, apply_batch_norm, self.keep_prob_last, self.fin_act , w_init = sizes['convblock_layer_' +str(self.block_id)][-1] layer = ConvLayer(name, mi, mo, filter_sz, stride, apply_batch_norm, 1, lambda x: x, w_init) self.conv_layers.append(layer) #secondary path #set filter_sz = stride = 1 for an ID block mo, filter_sz, stride, apply_batch_norm, _, w_init = sizes['convblock_shortcut_layer_'+str(self.block_id)][0] name = 'convshortcut_layer_{0}'.format(block_id) self.shortcut_layer = ConvLayer(name, init_mi, mo, filter_sz, stride, apply_batch_norm, 1, f=lambda x: x, w_init=w_init) self.sizes=sizes def output_dim(self, input_dim): dim = input_dim for _, _, stride, _, _, _, _, in self.sizes['convblock_layer_'+str(self.block_id)]: dim = int(np.ceil(float(dim)/stride)) return dim def set_session(self, session): self.session = session self.shortcut_layer.set_session(session) for layer in self.conv_layers: layer.set_session(session) def forward(self, X, reuse, is_training): output = X shortcut_output = X #print('Convolutional block %i' %self.block_id) #print('Input shape ', X.get_shape() ) i=0 for layer in self.conv_layers: i+=1 output = layer.forward(output, reuse, is_training) #print('After layer %i' %i) #print('Output shape ', output.get_shape()) shortcut_output = self.shortcut_layer.forward(shortcut_output,reuse, is_training) #print('Shortcut layer after convolution shape ', shortcut_output.get_shape()) assert (output.get_shape().as_list()[1], output.get_shape().as_list()[2]) == (shortcut_output.get_shape().as_list()[1], shortcut_output.get_shape().as_list()[2]), 'image size mismatch at conv block {0} '.format(self.block_id) assert output.get_shape().as_list()[-1] == shortcut_output.get_shape().as_list()[-1], 'image channels mismatch at conv block {0}'.format(self.block_id) output = output + shortcut_output activated=self.fin_act(output) output=tf.nn.dropout(activated, keep_prob=self.keep_prob_last, seed=rnd_seed) return output class DeconvBlock(object): """ Performs series of 2D strided deconvolutions on rectangular sized input tensor. The convolution proceeds on two parallel paths: main path is composed by n subsequent deconvolutions while shortcut path has 1 deconvolution with different parameters and can be set as the identity deconvolution. Constructor inputs: - block_id: progressive number of block in the network - init_mi: (int) input channels - sizes: (dict) python dictionary with keys: sizes = { 'deconvblock_layer_n':[(n_c+1, kernel, stride, apply_batch_norm, keep_prob, act_f, weight initializer), (n_c+2,,,,,,,), (n_c+...,,,,,,,), (n_c+ last,,,,,,,], 'deconvblock_shortcut_layer_n':[(n_c+3, kernel, stride, apply_batch_norm, act_f, weight initializer)], 'dense_layers':[(dim output, apply_batch_norm, keep_prob, act_f, weight initializer )] } - filter_sz: (int) width and height of the convolution kernel at that layer - stride: (int) horizontal and vertical size of the stride at that layer - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not - keep_prob: (int) dropout keep probability of propagated tensor - f: (function) activation layer function. tf.nn.relu by default - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) sizes['deconvblock_layer_n'] is a list of tuples of layers specifications for the main path sizes['deconvblock_shortcut_layer_n'] is a list composed by 1 tuple of layer specifications for the shortcut path sizes['dense_layers'] is a list of tuples of layers specifications for the densely connected part of the network Class attributes - conv_layers: (list) list of conv_layer objects - shortcut_layer: (list) conv_layer object Class methods: - forward: inputs: X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer reuse: (bool) whether reusing the stored batch_normalization parameters or not is_training: (bool) flag that indicates whether we are in the process of training or not outputs: output: (tf tensor) activated output of dim (batch_sz, n_W, n_H, mo), input for next layer - set_session: Sets current session inputs: session: (tf session) current session """ def __init__(self, block_id, mi, output_sizes, sizes): #self.f=f init_mi=mi self.deconv_layers = [] self.block_id=block_id #output shapes has to be a dictionary of [n_H,n_W] #build the block #main path for i in range(len(sizes['deconvblock_layer_'+str(block_id)])-1): mo, filter_sz, stride, apply_batch_norm, keep_prob, act_f, w_init = sizes['deconvblock_layer_'+str(block_id)][i] name = 'deconvblock_{0}_layer_{1}'.format(block_id, i) layer = DeconvLayer(name,mi, mo, output_sizes[block_id][i], filter_sz, stride, apply_batch_norm, keep_prob, act_f, w_init) self.deconv_layers.append(layer) mi = mo i = len(sizes['deconvblock_layer_'+str(block_id)])-1 name = 'deconvblock_{0}_layer_{1}'.format(block_id, i) mo, filter_sz, stride, apply_batch_norm, self.keep_prob_last, self.fin_act, w_init = sizes['deconvblock_layer_' +str(block_id)][-1] layer = DeconvLayer(name, mi, mo, output_sizes[block_id][len(output_sizes[block_id])-1], filter_sz, stride, apply_batch_norm, 1, lambda x: x, w_init) self.deconv_layers.append(layer) #secondary path mo, filter_sz, stride, apply_batch_norm, keep_prob, w_init = sizes['deconvblock_shortcut_layer_'+str(block_id)][0] name = 'deconvshortcut_layer_{0}'.format(block_id) self.shortcut_layer = DeconvLayer(name, init_mi, mo, output_sizes[block_id][len(output_sizes[block_id])-1], filter_sz,stride, apply_batch_norm, 1, f=lambda x: x, w_init=w_init) def set_session(self, session): self.session = session self.shortcut_layer.set_session(session) for layer in self.deconv_layers: layer.set_session(session) def forward(self, X, reuse, is_training): output = X shortcut_output = X #print('Deconvolutional block %i' %self.block_id) #print('Input shape ', X.get_shape() ) i=0 for layer in self.deconv_layers: i+=1 output = layer.forward(output, reuse, is_training) #print('After layer %i' %i) #print('Output shape ', output.get_shape()) shortcut_output = self.shortcut_layer.forward(shortcut_output, reuse, is_training) #print('Shortcut layer after convolution shape ', shortcut_output.get_shape()) assert (output.get_shape().as_list()[1], output.get_shape().as_list()[2]) == (shortcut_output.get_shape().as_list()[1], shortcut_output.get_shape().as_list()[2]), 'image size mismatch at deconv block {0} '.format(self.block_id) assert output.get_shape().as_list()[-1] == shortcut_output.get_shape().as_list()[-1], 'image channels mismatch at deconv block {0}'.format(self.block_id) output = output + shortcut_output activated=self.fin_act(output) output=tf.nn.dropout(activated, keep_prob=self.keep_prob_last, seed=rnd_seed) return output def output_dim(self, input_dim): dim = input_dim for _, _, stride, _, _, _, in self.sizes['deconvblock_layer_'+str(self.block_id)]: dim = int(np.ceil(float(dim)/stride)) return dim # class DeconvLayer_v2(object): # """ # Performs 2D strided deconvlution on rectangular sized input tensor. # Constructor inputs: # - mi: (int) input channels # - mo: (int) output channels # - output_shape: list = [int, int], list[0]([1]) is the witdth (height) of the output after transposed convolution # - filter_sz: (int) width and height of the convolution kernel # - stride: (int) horizontal and vertical size of the stride # - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not # - keep_prob: (int) dropout keep probability of propagated tensor # - f: (function) activation layer function. tf.nn.relu by default # - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) # Class attributes # - W: (tf tensor) variable tensor of dim (filter_sz, filter_sz, mi, mo) of trainable weights # - b: (tf tensor) variable tensor of dim (mo, ) of trainable biases # Class methods: # - forward: # inputs: # X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer # reuse: (bool) whether reusing the stored batch_normalization parameters or not # is_training: (bool) flag that indicates whether we are in the process of training or not # The deconvolution is computed in 3 steps according to: (cite article) # 1) conv2d with W_id is performed to match the output channels mo, with filter_sz=1 and stride=1 # 2) the image is reshaped to reshape_size_H and W # 3) conv2d with W is performed with input filter_sz and stride, output width and height will match output_shape # outputs: # output: (tf tensor) activated output of dim (batch_sz, n_W=output_shape[0], n_H = output_shape[1], mo), input for next layer # - set_session: # Sets current session # inputs: # session: (tf session) current session # """ # def __init__(self, name, # mi, mo, output_shape, # filter_sz, stride, # apply_batch_norm, keep_prob = 1, # f=None, w_init = None # ): # #using resize + conv2d and not conv2dt # #mi: input channels # #mo: output channels # #output_shape: width and height of the output image # #performs 2 convolutions, the first augments the number of channels # #the second performs a convolution with != 1 kernel and stride # filter_shape = [filter_sz, filter_sz, mo, mi] # self.W = tf.get_variable( # "W_%s" %name, # filter_shape, # initializer=w_init, # ) # self.b = tf.get_variable( # "b_%s" %name, # shape=(mo,), # initializer=tf.zeros_initializer(), # ) # self.f = f # self.stride = stride # self.filter_sz = filter_sz # self.name = name # self.output_shape = output_shape # self.apply_batch_norm = apply_batch_norm # self.keep_prob = keep_prob # self.mo=mo # def forward(self, X, reuse, is_training): # if not is_training: # self.keep_prob = 1 # m = tf.shape(X)[0] # output_shape=tf.stack([m, self.output_shape[0], self.output_shape[1], self.mo]) # strides_shape=[1,self.stride,self.stride,1] # conv_out = tf.nn.conv2d_transpose( # value=X, # filter=self.W, # output_shape=output_shape, # strides=strides_shape, # padding='SAME' # ) # #print('After deconvolution', conv_out.get_shape()) # conv_out = tf.nn.bias_add(conv_out,self.b) # if self.apply_batch_norm=='bn': # conv_out=tf.contrib.layers.batch_norm( # conv_out, # decay=0.9, # updates_collections=None, # epsilon=1e-5, # scale=True, # is_training = is_training, # reuse=reuse, # scope = self.name, # ) # elif self.apply_batch_norm=='in': # conv_out = tf.contrib.layers.instance_norm( # conv_out, # center=True, # scale=True, # epsilon=1e-6, # reuse=reuse, # scope = self.name, # ) # elif self.apply_batch_norm=='False': # return conv_out # activated = self.f(conv_out) # output = tf.nn.dropout(activated, self.keep_prob, seed=rnd_seed) # return output # def set_session(self, session): # self.session = session # class DeconvBlock_v2(object): # """ # Performs series of 2D strided deconvolutions on rectangular sized input tensor. The convolution proceeds on two parallel # paths: main path is composed by n subsequent deconvolutions while shortcut path has 1 deconvolution with different parameters and # can be set as the identity deconvolution. # Constructor inputs: # - block_id: progressive number of block in the network # - init_mi: (int) input channels # - sizes: (dict) python dictionary with keys: # sizes = { # 'deconvblock_layer_n':[(n_c+1, kernel, stride, apply_batch_norm, keep_prob, act_f, weight initializer), # (n_c+2,,,,,,,), # (n_c+...,,,,,,,), # (n_c+ last,,,,,,,], # 'deconvblock_shortcut_layer_n':[(n_c+3, kernel, stride, apply_batch_norm, act_f, weight initializer)], # 'dense_layers':[(dim output, apply_batch_norm, keep_prob, act_f, weight initializer )] # } # - filter_sz: (int) width and height of the convolution kernel at that layer # - stride: (int) horizontal and vertical size of the stride at that layer # - apply_batch_norm: (bool) whether applying batch normalization (along [0] axis of input tensor) or not # - keep_prob: (int) dropout keep probability of propagated tensor # - f: (function) activation layer function. tf.nn.relu by default # - w_init: (tf initializer) initialization of the filter parameters, by default tf.truncated_normal_initializer(stddev=0.02) # sizes['deconvblock_layer_n'] is a list of tuples of layers specifications for the main path # sizes['deconvblock_shortcut_layer_n'] is a list composed by 1 tuple of layer specifications for the shortcut path # sizes['dense_layers'] is a list of tuples of layers specifications for the densely connected part of the network # Class attributes # - conv_layers: (list) list of conv_layer objects # - shortcut_layer: (list) conv_layer object # Class methods: # - forward: # inputs: # X: (tf tensor) input tensor of dim (batch_sz, n_W, n_H, mi) output of previous layer # reuse: (bool) whether reusing the stored batch_normalization parameters or not # is_training: (bool) flag that indicates whether we are in the process of training or not # outputs: # output: (tf tensor) activated output of dim (batch_sz, n_W, n_H, mo), input for next layer # - set_session: # Sets current session # inputs: # session: (tf session) current session # """ # def __init__(self, # block_id, # mi, output_sizes, # sizes): # #self.f=f # init_mi=mi # self.deconv_layers = [] # self.block_id=block_id # #output shapes has to be a dictionary of [n_H,n_W] # #build the block # #main path # for i in range(len(sizes['deconvblock_layer_'+str(block_id)])-1): # mo, filter_sz, stride, apply_batch_norm, keep_prob, act_f, w_init = sizes['deconvblock_layer_'+str(block_id)][i] # name = 'deconvblock_{0}_layer_{1}'.format(block_id, i) # layer = DeconvLayer_v2(name,mi, mo, output_sizes[block_id][i], # filter_sz, stride, # apply_batch_norm, keep_prob, # act_f, w_init) # self.deconv_layers.append(layer) # mi = mo # i = len(sizes['deconvblock_layer_'+str(block_id)])-1 # name = 'deconvblock_{0}_layer_{1}'.format(block_id, i) # mo, filter_sz, stride, apply_batch_norm, self.keep_prob_last, self.fin_act, w_init = sizes['deconvblock_layer_' +str(block_id)][-1] # layer = DeconvLayer(name, mi, mo, output_sizes[block_id][len(output_sizes[block_id])-1], # filter_sz, stride, # apply_batch_norm, 1, # lambda x: x, w_init) # self.deconv_layers.append(layer) # #secondary path # mo, filter_sz, stride, apply_batch_norm, keep_prob, w_init = sizes['deconvblock_shortcut_layer_'+str(block_id)][0] # name = 'deconvshortcut_layer_{0}'.format(block_id) # self.shortcut_layer = DeconvLayer(name, init_mi, mo, output_sizes[block_id][len(output_sizes[block_id])-1], # filter_sz,stride, # apply_batch_norm, 1, # f=lambda x: x, w_init=w_init) # def set_session(self, session): # self.session = session # self.shortcut_layer.set_session(session) # for layer in self.deconv_layers: # layer.set_session(session) # def forward(self, X, reuse, is_training): # output = X # shortcut_output = X # #print('Deconvolutional block %i' %self.block_id) # #print('Input shape ', X.get_shape() ) # i=0 # for layer in self.deconv_layers: # i+=1 # output = layer.forward(output, reuse, is_training) # #print('After layer %i' %i) # #print('Output shape ', output.get_shape()) # shortcut_output = self.shortcut_layer.forward(shortcut_output, reuse, is_training) # #print('Shortcut layer after convolution shape ', shortcut_output.get_shape()) # assert (output.get_shape().as_list()[1], output.get_shape().as_list()[2]) == (shortcut_output.get_shape().as_list()[1], shortcut_output.get_shape().as_list()[2]), 'image size mismatch at deconv block {0} '.format(self.block_id) # assert output.get_shape().as_list()[-1] == shortcut_output.get_shape().as_list()[-1], 'image channels mismatch at deconv block {0}'.format(self.block_id) # output = output + shortcut_output # activated=self.fin_act(output) # output=tf.nn.dropout(activated, keep_prob=self.keep_prob_last, seed=rnd_seed) # return self.fin_act(output) # def output_dim(self, input_dim): # dim = input_dim # for _, _, stride, _, _, _, _, in self.sizes['deconvblock_layer_'+str(self.block_id)]: # dim = int(np.ceil(float(dim)/stride)) # return dim