# Copyright 2016 The TensorFlow Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # ============================================================================== """Contains model definitions for versions of the Oxford VGG network. These model definitions were introduced in the following technical report: Very Deep Convolutional Networks For Large-Scale Image Recognition Karen Simonyan and Andrew Zisserman arXiv technical report, 2015 PDF: http://arxiv.org/pdf/1409.1556.pdf ILSVRC 2014 Slides: http://www.robots.ox.ac.uk/~karen/pdf/ILSVRC_2014.pdf CC-BY-4.0 More information can be obtained from the VGG website: www.robots.ox.ac.uk/~vgg/research/very_deep/ Usage: with slim.arg_scope(vgg.vgg_arg_scope()): outputs, end_points = vgg.vgg_a(inputs) with slim.arg_scope(vgg.vgg_arg_scope()): outputs, end_points = vgg.vgg_16(inputs) @@vgg_a @@vgg_16 @@vgg_19 """ from __future__ import absolute_import from __future__ import division from __future__ import print_function import tensorflow as tf slim = tf.contrib.slim def vgg_arg_scope(weight_decay=0.0005): """Defines the VGG arg scope. Args: weight_decay: The l2 regularization coefficient. Returns: An arg_scope. """ with slim.arg_scope([slim.conv2d, slim.fully_connected], activation_fn=tf.nn.relu, weights_regularizer=slim.l2_regularizer(weight_decay), biases_initializer=tf.zeros_initializer()): with slim.arg_scope([slim.conv2d], padding='SAME') as arg_sc: return arg_sc def vgg_a(inputs, num_classes=1000, is_training=True, dropout_keep_prob=0.5, spatial_squeeze=True, scope='vgg_a', fc_conv_padding='VALID', global_pool=False): """Oxford Net VGG 11-Layers version A Example. Note: All the fully_connected layers have been transformed to conv2d layers. To use in classification mode, resize input to 224x224. Args: inputs: a tensor of size [batch_size, height, width, channels]. num_classes: number of predicted classes. If 0 or None, the logits layer is omitted and the input features to the logits layer are returned instead. is_training: whether or not the model is being trained. dropout_keep_prob: the probability that activations are kept in the dropout layers during training. spatial_squeeze: whether or not should squeeze the spatial dimensions of the outputs. Useful to remove unnecessary dimensions for classification. scope: Optional scope for the variables. fc_conv_padding: the type of padding to use for the fully connected layer that is implemented as a convolutional layer. Use 'SAME' padding if you are applying the network in a fully convolutional manner and want to get a prediction map downsampled by a factor of 32 as an output. Otherwise, the output prediction map will be (input / 32) - 6 in case of 'VALID' padding. global_pool: Optional boolean flag. If True, the input to the classification layer is avgpooled to size 1x1, for any input size. (This is not part of the original VGG architecture.) Returns: net: the output of the logits layer (if num_classes is a non-zero integer), or the input to the logits layer (if num_classes is 0 or None). end_points: a dict of tensors with intermediate activations. """ with tf.variable_scope(scope, 'vgg_a', [inputs]) as sc: end_points_collection = sc.original_name_scope + '_end_points' # Collect outputs for conv2d, fully_connected and max_pool2d. with slim.arg_scope([slim.conv2d, slim.max_pool2d], outputs_collections=end_points_collection): net = slim.repeat(inputs, 1, slim.conv2d, 64, [3, 3], scope='conv1') net = slim.max_pool2d(net, [2, 2], scope='pool1') net = slim.repeat(net, 1, slim.conv2d, 128, [3, 3], scope='conv2') net = slim.max_pool2d(net, [2, 2], scope='pool2') net = slim.repeat(net, 2, slim.conv2d, 256, [3, 3], scope='conv3') net = slim.max_pool2d(net, [2, 2], scope='pool3') net = slim.repeat(net, 2, slim.conv2d, 512, [3, 3], scope='conv4') net = slim.max_pool2d(net, [2, 2], scope='pool4') net = slim.repeat(net, 2, slim.conv2d, 512, [3, 3], scope='conv5') net = slim.max_pool2d(net, [2, 2], scope='pool5') # Use conv2d instead of fully_connected layers. net = slim.conv2d(net, 4096, [7, 7], padding=fc_conv_padding, scope='fc6') net = slim.dropout(net, dropout_keep_prob, is_training=is_training, scope='dropout6') net = slim.conv2d(net, 4096, [1, 1], scope='fc7') # Convert end_points_collection into a end_point dict. end_points = slim.utils.convert_collection_to_dict(end_points_collection) if global_pool: net = tf.reduce_mean(net, [1, 2], keep_dims=True, name='global_pool') end_points['global_pool'] = net if num_classes: net = slim.dropout(net, dropout_keep_prob, is_training=is_training, scope='dropout7') net = slim.conv2d(net, num_classes, [1, 1], activation_fn=None, normalizer_fn=None, scope='fc8') if spatial_squeeze: net = tf.squeeze(net, [1, 2], name='fc8/squeezed') end_points[sc.name + '/fc8'] = net return net, end_points vgg_a.default_image_size = 224 def vgg_16(inputs, num_classes=1000, is_training=True, dropout_keep_prob=0.5, spatial_squeeze=True, scope='vgg_16', fc_conv_padding='VALID', global_pool=False): """Oxford Net VGG 16-Layers version D Example. Note: All the fully_connected layers have been transformed to conv2d layers. To use in classification mode, resize input to 224x224. Args: inputs: a tensor of size [batch_size, height, width, channels]. num_classes: number of predicted classes. If 0 or None, the logits layer is omitted and the input features to the logits layer are returned instead. is_training: whether or not the model is being trained. dropout_keep_prob: the probability that activations are kept in the dropout layers during training. spatial_squeeze: whether or not should squeeze the spatial dimensions of the outputs. Useful to remove unnecessary dimensions for classification. scope: Optional scope for the variables. fc_conv_padding: the type of padding to use for the fully connected layer that is implemented as a convolutional layer. Use 'SAME' padding if you are applying the network in a fully convolutional manner and want to get a prediction map downsampled by a factor of 32 as an output. Otherwise, the output prediction map will be (input / 32) - 6 in case of 'VALID' padding. global_pool: Optional boolean flag. If True, the input to the classification layer is avgpooled to size 1x1, for any input size. (This is not part of the original VGG architecture.) Returns: net: the output of the logits layer (if num_classes is a non-zero integer), or the input to the logits layer (if num_classes is 0 or None). end_points: a dict of tensors with intermediate activations. """ with tf.variable_scope(scope, 'vgg_16', [inputs]) as sc: end_points_collection = sc.original_name_scope + '_end_points' # Collect outputs for conv2d, fully_connected and max_pool2d. with slim.arg_scope([slim.conv2d, slim.fully_connected, slim.max_pool2d], outputs_collections=end_points_collection): net = slim.repeat(inputs, 2, slim.conv2d, 64, [3, 3], scope='conv1') net = slim.max_pool2d(net, [2, 2], scope='pool1') net = slim.repeat(net, 2, slim.conv2d, 128, [3, 3], scope='conv2') net = slim.max_pool2d(net, [2, 2], scope='pool2') net = slim.repeat(net, 3, slim.conv2d, 256, [3, 3], scope='conv3') net = slim.max_pool2d(net, [2, 2], scope='pool3') net = slim.repeat(net, 3, slim.conv2d, 512, [3, 3], scope='conv4') net = slim.max_pool2d(net, [2, 2], scope='pool4') net = slim.repeat(net, 3, slim.conv2d, 512, [3, 3], scope='conv5') net = slim.max_pool2d(net, [2, 2], scope='pool5') # Use conv2d instead of fully_connected layers. net = slim.conv2d(net, 4096, [7, 7], padding=fc_conv_padding, scope='fc6') net = slim.dropout(net, dropout_keep_prob, is_training=is_training, scope='dropout6') net = slim.conv2d(net, 4096, [1, 1], scope='fc7') # Convert end_points_collection into a end_point dict. end_points = slim.utils.convert_collection_to_dict(end_points_collection) if global_pool: net = tf.reduce_mean(net, [1, 2], keep_dims=True, name='global_pool') end_points['global_pool'] = net if num_classes: net = slim.dropout(net, dropout_keep_prob, is_training=is_training, scope='dropout7') net = slim.conv2d(net, num_classes, [1, 1], activation_fn=None, normalizer_fn=None, scope='fc8') if spatial_squeeze and num_classes is not None: net = tf.squeeze(net, [1, 2], name='fc8/squeezed') end_points[sc.name + '/fc8'] = net return net, end_points vgg_16.default_image_size = 224 def vgg_19(inputs, num_classes=1000, is_training=True, dropout_keep_prob=0.5, spatial_squeeze=True, scope='vgg_19', fc_conv_padding='VALID', global_pool=False): """Oxford Net VGG 19-Layers version E Example. Note: All the fully_connected layers have been transformed to conv2d layers. To use in classification mode, resize input to 224x224. Args: inputs: a tensor of size [batch_size, height, width, channels]. num_classes: number of predicted classes. If 0 or None, the logits layer is omitted and the input features to the logits layer are returned instead. is_training: whether or not the model is being trained. dropout_keep_prob: the probability that activations are kept in the dropout layers during training. spatial_squeeze: whether or not should squeeze the spatial dimensions of the outputs. Useful to remove unnecessary dimensions for classification. scope: Optional scope for the variables. fc_conv_padding: the type of padding to use for the fully connected layer that is implemented as a convolutional layer. Use 'SAME' padding if you are applying the network in a fully convolutional manner and want to get a prediction map downsampled by a factor of 32 as an output. Otherwise, the output prediction map will be (input / 32) - 6 in case of 'VALID' padding. global_pool: Optional boolean flag. If True, the input to the classification layer is avgpooled to size 1x1, for any input size. (This is not part of the original VGG architecture.) Returns: net: the output of the logits layer (if num_classes is a non-zero integer), or the non-dropped-out input to the logits layer (if num_classes is 0 or None). end_points: a dict of tensors with intermediate activations. """ with tf.variable_scope(scope, 'vgg_19', [inputs]) as sc: end_points_collection = sc.original_name_scope + '_end_points' # Collect outputs for conv2d, fully_connected and max_pool2d. with slim.arg_scope([slim.conv2d, slim.fully_connected, slim.max_pool2d], outputs_collections=end_points_collection): net = slim.repeat(inputs, 2, slim.conv2d, 64, [3, 3], scope='conv1') net = slim.max_pool2d(net, [2, 2], scope='pool1') net = slim.repeat(net, 2, slim.conv2d, 128, [3, 3], scope='conv2') net = slim.max_pool2d(net, [2, 2], scope='pool2') net = slim.repeat(net, 4, slim.conv2d, 256, [3, 3], scope='conv3') net = slim.max_pool2d(net, [2, 2], scope='pool3') net = slim.repeat(net, 4, slim.conv2d, 512, [3, 3], scope='conv4') net = slim.max_pool2d(net, [2, 2], scope='pool4') net = slim.repeat(net, 4, slim.conv2d, 512, [3, 3], scope='conv5') net = slim.max_pool2d(net, [2, 2], scope='pool5') # Use conv2d instead of fully_connected layers. net = slim.conv2d(net, 4096, [7, 7], padding=fc_conv_padding, scope='fc6') net = slim.dropout(net, dropout_keep_prob, is_training=is_training, scope='dropout6') net = slim.conv2d(net, 4096, [1, 1], scope='fc7') # Convert end_points_collection into a end_point dict. end_points = slim.utils.convert_collection_to_dict(end_points_collection) if global_pool: net = tf.reduce_mean(net, [1, 2], keep_dims=True, name='global_pool') end_points['global_pool'] = net if num_classes: net = slim.dropout(net, dropout_keep_prob, is_training=is_training, scope='dropout7') net = slim.conv2d(net, num_classes, [1, 1], activation_fn=None, normalizer_fn=None, scope='fc8') if spatial_squeeze: net = tf.squeeze(net, [1, 2], name='fc8/squeezed') end_points[sc.name + '/fc8'] = net return net, end_points vgg_19.default_image_size = 224 # Alias vgg_d = vgg_16 vgg_e = vgg_19