我们从Python开源项目中,提取了以下42个代码示例,用于说明如何使用ops.linear()。
def discriminator_labeler(image, output_dim, config, reuse=None): batch_size=tf.shape(image)[0] with tf.variable_scope("disc_labeler",reuse=reuse) as vs: dl_bn1 = batch_norm(name='dl_bn1') dl_bn2 = batch_norm(name='dl_bn2') dl_bn3 = batch_norm(name='dl_bn3') h0 = lrelu(conv2d(image, config.df_dim, name='dl_h0_conv'))#16,32,32,64 h1 = lrelu(dl_bn1(conv2d(h0, config.df_dim*2, name='dl_h1_conv')))#16,16,16,128 h2 = lrelu(dl_bn2(conv2d(h1, config.df_dim*4, name='dl_h2_conv')))#16,16,16,248 h3 = lrelu(dl_bn3(conv2d(h2, config.df_dim*8, name='dl_h3_conv'))) dim3=np.prod(h3.get_shape().as_list()[1:]) h3_flat=tf.reshape(h3, [-1,dim3]) D_labels_logits = linear(h3_flat, output_dim, 'dl_h3_Label') D_labels = tf.nn.sigmoid(D_labels_logits) variables = tf.contrib.framework.get_variables(vs) return D_labels, D_labels_logits, variables
def discriminator_gen_labeler(image, output_dim, config, reuse=None): batch_size=tf.shape(image)[0] with tf.variable_scope("disc_gen_labeler",reuse=reuse) as vs: dl_bn1 = batch_norm(name='dl_bn1') dl_bn2 = batch_norm(name='dl_bn2') dl_bn3 = batch_norm(name='dl_bn3') h0 = lrelu(conv2d(image, config.df_dim, name='dgl_h0_conv'))#16,32,32,64 h1 = lrelu(dl_bn1(conv2d(h0, config.df_dim*2, name='dgl_h1_conv')))#16,16,16,128 h2 = lrelu(dl_bn2(conv2d(h1, config.df_dim*4, name='dgl_h2_conv')))#16,16,16,248 h3 = lrelu(dl_bn3(conv2d(h2, config.df_dim*8, name='dgl_h3_conv'))) dim3=np.prod(h3.get_shape().as_list()[1:]) h3_flat=tf.reshape(h3, [-1,dim3]) D_labels_logits = linear(h3_flat, output_dim, 'dgl_h3_Label') D_labels = tf.nn.sigmoid(D_labels_logits) variables = tf.contrib.framework.get_variables(vs) return D_labels, D_labels_logits,variables
def discriminator_on_z(image, config, reuse=None): batch_size=tf.shape(image)[0] with tf.variable_scope("disc_z_labeler",reuse=reuse) as vs: dl_bn1 = batch_norm(name='dl_bn1') dl_bn2 = batch_norm(name='dl_bn2') dl_bn3 = batch_norm(name='dl_bn3') h0 = lrelu(conv2d(image, config.df_dim, name='dzl_h0_conv'))#16,32,32,64 h1 = lrelu(dl_bn1(conv2d(h0, config.df_dim*2, name='dzl_h1_conv')))#16,16,16,128 h2 = lrelu(dl_bn2(conv2d(h1, config.df_dim*4, name='dzl_h2_conv')))#16,16,16,248 h3 = lrelu(dl_bn3(conv2d(h2, config.df_dim*8, name='dzl_h3_conv'))) dim3=np.prod(h3.get_shape().as_list()[1:]) h3_flat=tf.reshape(h3, [-1,dim3]) D_labels_logits = linear(h3_flat, config.z_dim, 'dzl_h3_Label') D_labels = tf.nn.tanh(D_labels_logits) variables = tf.contrib.framework.get_variables(vs) return D_labels,variables
def discriminator(self, opts, input_, is_training, prefix='DISCRIMINATOR', reuse=False): """Encoder function, suitable for simple toy experiments. """ num_filters = opts['d_num_filters'] with tf.variable_scope(prefix, reuse=reuse): h0 = ops.conv2d(opts, input_, num_filters / 8, scope='h0_conv') h0 = ops.batch_norm(opts, h0, is_training, reuse, scope='bn_layer1') h0 = tf.nn.relu(h0) h1 = ops.conv2d(opts, h0, num_filters / 4, scope='h1_conv') h1 = ops.batch_norm(opts, h1, is_training, reuse, scope='bn_layer2') h1 = tf.nn.relu(h1) h2 = ops.conv2d(opts, h1, num_filters / 2, scope='h2_conv') h2 = ops.batch_norm(opts, h2, is_training, reuse, scope='bn_layer3') h2 = tf.nn.relu(h2) h3 = ops.conv2d(opts, h2, num_filters, scope='h3_conv') h3 = ops.batch_norm(opts, h3, is_training, reuse, scope='bn_layer4') h3 = tf.nn.relu(h3) # Already has NaNs!! latent_mean = ops.linear(opts, h3, opts['latent_space_dim'], scope='h3_lin') log_latent_sigmas = ops.linear(opts, h3, opts['latent_space_dim'], scope='h3_lin_sigma') return latent_mean, log_latent_sigmas
def generator(self, opts, noise, reuse=False): """Generator function, suitable for simple toy experiments. Args: noise: [num_points, dim] array, where dim is dimensionality of the latent noise space. Returns: [num_points, dim1, dim2, dim3] array, where the first coordinate indexes the points, which all are of the shape (dim1, dim2, dim3). """ output_shape = self._data.data_shape num_filters = opts['g_num_filters'] with tf.variable_scope("GENERATOR", reuse=reuse): h0 = ops.linear(opts, noise, num_filters, 'h0_lin') h0 = tf.nn.relu(h0) h1 = ops.linear(opts, h0, num_filters, 'h1_lin') h1 = tf.nn.relu(h1) h2 = ops.linear(opts, h1, np.prod(output_shape), 'h2_lin') h2 = tf.reshape(h2, [-1] + list(output_shape)) if opts['input_normalize_sym']: return tf.nn.tanh(h2) else: return h2
def discriminator(self, opts, input_, prefix='DISCRIMINATOR', reuse=False): """Discriminator function, suitable for simple toy experiments. """ shape = input_.get_shape().as_list() num_filters = opts['d_num_filters'] assert len(shape) > 0, 'No inputs to discriminate.' with tf.variable_scope(prefix, reuse=reuse): h0 = ops.linear(opts, input_, num_filters, 'h0_lin') h0 = tf.nn.relu(h0) h1 = ops.linear(opts, h0, num_filters, 'h1_lin') h1 = tf.nn.relu(h1) h2 = ops.linear(opts, h1, 1, 'h2_lin') return h2
def generator(self, opts, noise, reuse=False): """Generator function, suitable for simple toy experiments. Args: noise: [num_points, dim] array, where dim is dimensionality of the latent noise space. Returns: [num_points, dim1, dim2, dim3] array, where the first coordinate indexes the points, which all are of the shape (dim1, dim2, dim3). """ output_shape = self._data.data_shape num_filters = opts['g_num_filters'] with tf.variable_scope("GENERATOR", reuse=reuse): h0 = ops.linear(opts, noise, num_filters, 'h0_lin') h0 = tf.nn.tanh(h0) h1 = ops.linear(opts, h0, num_filters, 'h1_lin') h1 = tf.nn.tanh(h1) h2 = ops.linear(opts, h1, np.prod(output_shape), 'h2_lin') h2 = tf.reshape(h2, [-1] + list(output_shape)) if opts['input_normalize_sym']: return tf.nn.tanh(h2) else: return h2
def discriminator(self, opts, input_, prefix='DISCRIMINATOR', reuse=False): """Discriminator function, suitable for simple toy experiments. """ shape = input_.get_shape().as_list() num_filters = opts['d_num_filters'] assert len(shape) > 0, 'No inputs to discriminate.' with tf.variable_scope(prefix, reuse=reuse): h0 = ops.linear(opts, input_, num_filters, 'h0_lin') h0 = tf.nn.tanh(h0) h1 = ops.linear(opts, h0, num_filters, 'h1_lin') h1 = tf.nn.tanh(h1) h2 = ops.linear(opts, h1, 1, 'h2_lin') return h2
def discriminator(self, opts, input_, is_training, prefix='DISCRIMINATOR', reuse=False): """Discriminator function, suitable for simple toy experiments. """ num_filters = opts['d_num_filters'] with tf.variable_scope(prefix, reuse=reuse): h0 = ops.conv2d(opts, input_, num_filters, scope='h0_conv') h0 = ops.batch_norm(opts, h0, is_training, reuse, scope='bn_layer1') h0 = ops.lrelu(h0) h1 = ops.conv2d(opts, h0, num_filters * 2, scope='h1_conv') h1 = ops.batch_norm(opts, h1, is_training, reuse, scope='bn_layer2') h1 = ops.lrelu(h1) h2 = ops.conv2d(opts, h1, num_filters * 4, scope='h2_conv') h2 = ops.batch_norm(opts, h2, is_training, reuse, scope='bn_layer3') h2 = ops.lrelu(h2) h3 = ops.linear(opts, h2, 1, scope='h3_lin') return h3
def generator(self, opts, noise, is_training, reuse=False): with tf.variable_scope("GENERATOR", reuse=reuse): h0 = ops.linear(opts, noise, 100, scope='h0_lin') h0 = ops.batch_norm(opts, h0, is_training, reuse, scope='bn_layer1', scale=False) h0 = tf.nn.softplus(h0) h1 = ops.linear(opts, h0, 100, scope='h1_lin') h1 = ops.batch_norm(opts, h1, is_training, reuse, scope='bn_layer2', scale=False) h1 = tf.nn.softplus(h1) h2 = ops.linear(opts, h1, 28 * 28, scope='h2_lin') # h2 = ops.batch_norm(opts, h2, is_training, reuse, scope='bn_layer3') h2 = tf.reshape(h2, [-1, 28, 28, 1]) if opts['input_normalize_sym']: return tf.nn.tanh(h2) else: return tf.nn.sigmoid(h2)
def discriminator(self, image, y=None, reuse=False): if reuse: tf.get_variable_scope().reuse_variables() s = self.output_size if np.mod(s, 16) == 0: h0 = lrelu(conv2d(image, self.df_dim, name='d_h0_conv')) h1 = lrelu(self.d_bn1(conv2d(h0, self.df_dim*2, name='d_h1_conv'))) h2 = lrelu(self.d_bn2(conv2d(h1, self.df_dim*4, name='d_h2_conv'))) h3 = lrelu(self.d_bn3(conv2d(h2, self.df_dim*8, name='d_h3_conv'))) h4 = linear(tf.reshape(h3, [self.batch_size, -1]), 1, 'd_h3_lin') return tf.nn.sigmoid(h4), h4 else: h0 = lrelu(conv2d(image, self.df_dim, name='d_h0_conv')) h1 = lrelu(self.d_bn1(conv2d(h0, self.df_dim*2, name='d_h1_conv'))) h2 = linear(tf.reshape(h1, [self.batch_size, -1]), 1, 'd_h2_lin') if not self.config.use_kernel: return tf.nn.sigmoid(h2), h2 else: return tf.nn.sigmoid(h2), h2, h1, h0
def discriminator_k(self, image, reuse=False): if reuse: tf.get_variable_scope().reuse_variables() #1024, 512, 128 h0 = tf.nn.sigmoid(linear(image, 512, 'dk_h0_lin', stddev=self.config.init)) h1 = tf.nn.sigmoid(linear(h0, 256, 'dk_h1_lin', stddev=self.config.init)) h2 = tf.nn.sigmoid(linear(h1, 256, 'dk_h2_lin', stddev=self.config.init)) h3 = tf.nn.sigmoid(linear(h2, 128, 'dk_h3_lin', stddev=self.config.init)) h4 = tf.nn.relu(linear(h3, 64, 'dk_h4_lin', stddev=self.config.init)) if self.config.use_gan: h5 = linear(h4, 1, 'dk_h5_lin', stddev=self.config.init) return image, h0, h1, h2, h3, h4, h5 elif self.config.use_layer_kernel: return image, h0, h1, h2, h3, h4 elif self.config.use_scale_kernel: return tf.concat(1, [image, (28.0 * 28.0/512.0) * h0, (28 * 28.0/256.0) * h1, (28.0 * 28.0/256.0) * h2, (28.0 * 28.0/128.0) * h3, (28.0 * 28.0/64.0) * h4]) else: return tf.concat(1, [image, h0, h1, h2, h3, h4])
def __call__(self, inputs, is_train=True, is_debug=False): self.is_train = is_train self.is_debug = is_debug outputs = tf.convert_to_tensor(inputs) # Check if necessary # assert input shape with tf.variable_scope(self.name, reuse=self.reuse) as scope: print_message(scope.name) with tf.variable_scope('conv1') as vscope: outputs = conv3d(outputs, [self.batch_size] + self.configs.conv_info.l1, is_train=self.is_train, with_w=True) if is_debug and not self.reuse: print(vscope.name, outputs) outputs = tf.layers.dropout(outputs, rate=self.configs.dropout, training=self.is_train, name='outputs') self.net['conv1_outputs'] = outputs with tf.variable_scope('conv2') as vscope: outputs = conv3d(outputs, [self.batch_size] + self.configs.conv_info.l2, is_train=self.is_train, with_w=True) if is_debug and not self.reuse: print(vscope.name, outputs) outputs = tf.layers.dropout(outputs, rate=self.configs.dropout, training=self.is_train, name='outputs') self.net['conv2_outputs'] = outputs with tf.variable_scope('conv3') as vscope: outputs = conv3d(outputs, [self.batch_size] + self.configs.conv_info.l3, is_train=self.is_train, with_w=True) if is_debug and not self.reuse: print(vscope.name, outputs) outputs = tf.layers.dropout(outputs, rate=self.configs.dropout, training=self.is_train, name='outputs') self.net['conv3_outputs'] = outputs with tf.variable_scope('fc') as vscope: fc_dim = reduce(mul, self.configs.conv_info.l3, 1) outputs = tf.reshape(outputs, [self.batch_size] + [fc_dim], name='reshape') outputs = linear(outputs, 1) if is_debug and not self.reuse: print(vscope.name, outputs) self.net['fc_outputs'] = outputs self.reuse = True self.variables = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, scope=self.name) return tf.nn.sigmoid(outputs), outputs
def discriminator(self, opts, input_, is_training, prefix='DISCRIMINATOR', reuse=False): shape = tf.shape(input_) num = shape[0] with tf.variable_scope(prefix, reuse=reuse): h0 = input_ h0 = tf.add(h0, tf.random_normal(shape, stddev=0.3)) h0 = ops.linear(opts, h0, 1000, scope='h0_linear') # h0 = ops.batch_norm(opts, h0, is_training, reuse, scope='bn_layer1') h0 = tf.nn.relu(h0) h1 = tf.add(h0, tf.random_normal([num, 1000], stddev=0.5)) h1 = ops.linear(opts, h1, 500, scope='h1_linear') # h1 = ops.batch_norm(opts, h1, is_training, reuse, scope='bn_layer2') h1 = tf.nn.relu(h1) h2 = tf.add(h1, tf.random_normal([num, 500], stddev=0.5)) h2 = ops.linear(opts, h2, 250, scope='h2_linear') # h2 = ops.batch_norm(opts, h2, is_training, reuse, scope='bn_layer3') h2 = tf.nn.relu(h2) h3 = tf.add(h2, tf.random_normal([num, 250], stddev=0.5)) h3 = ops.linear(opts, h3, 250, scope='h3_linear') # h3 = ops.batch_norm(opts, h3, is_training, reuse, scope='bn_layer4') h3 = tf.nn.relu(h3) h4 = tf.add(h3, tf.random_normal([num, 250], stddev=0.5)) h4 = ops.linear(opts, h4, 250, scope='h4_linear') # h4 = ops.batch_norm(opts, h4, is_training, reuse, scope='bn_layer5') h4 = tf.nn.relu(h4) h5 = ops.linear(opts, h4, 10, scope='h5_linear') return h5, h3
def generator(self, opts, noise, is_training=False, reuse=False, keep_prob=1.): """ Decoder actually. """ output_shape = self._data.data_shape num_units = opts['g_num_filters'] with tf.variable_scope("GENERATOR", reuse=reuse): # if not opts['convolutions']: if opts['g_arch'] == 'mlp': layer_x = noise for i in range(opts['g_num_layers']): layer_x = ops.linear(opts, layer_x, num_units, 'h%d_lin' % i) layer_x = tf.nn.relu(layer_x) if opts['batch_norm']: layer_x = ops.batch_norm( opts, layer_x, is_training, reuse, scope='bn%d' % i) out = ops.linear(opts, layer_x, np.prod(output_shape), 'h%d_lin' % (i + 1)) out = tf.reshape(out, [-1] + list(output_shape)) if opts['input_normalize_sym']: return tf.nn.tanh(out) else: return tf.nn.sigmoid(out) elif opts['g_arch'] in ['dcgan', 'dcgan_mod']: return self.dcgan_like_arch(opts, noise, is_training, reuse, keep_prob) elif opts['g_arch'] == 'conv_up_res': return self.conv_up_res(opts, noise, is_training, reuse, keep_prob) elif opts['g_arch'] == 'ali': return self.ali_deconv(opts, noise, is_training, reuse, keep_prob) elif opts['g_arch'] == 'began': return self.began_dec(opts, noise, is_training, reuse, keep_prob) else: raise ValueError('%s unknown' % opts['g_arch'])
def discriminator(self, opts, input_, prefix='DISCRIMINATOR', reuse=False): """Discriminator for the GAN objective """ num_units = opts['d_num_filters'] num_layers = opts['d_num_layers'] nowozin_trick = opts['gan_p_trick'] # No convolutions as GAN happens in the latent space with tf.variable_scope(prefix, reuse=reuse): hi = input_ for i in range(num_layers): hi = ops.linear(opts, hi, num_units, scope='h%d_lin' % (i+1)) hi = tf.nn.relu(hi) hi = ops.linear(opts, hi, 1, scope='final_lin') if nowozin_trick: # We are doing GAN between our model Qz and the true Pz. # We know analytical form of the true Pz. # The optimal discriminator for D_JS(Pz, Qz) is given by: # Dopt(x) = log dPz(x) - log dQz(x) # And we know exactly dPz(x). So add log dPz(x) explicitly # to the discriminator and let it learn only the remaining # dQz(x) term. This appeared in the AVB paper. assert opts['latent_space_distr'] == 'normal' sigma2_p = float(opts['pot_pz_std']) ** 2 normsq = tf.reduce_sum(tf.square(input_), 1) hi = hi - normsq / 2. / sigma2_p \ - 0.5 * tf.log(2. * np.pi) \ - 0.5 * opts['latent_space_dim'] * np.log(sigma2_p) return hi
def correlation_loss(self, opts, input_): """ Independence test based on Pearson's correlation. Keep in mind that this captures only linear dependancies. However, for multivariate Gaussian independence is equivalent to zero correlation. """ batch_size = self.get_batch_size(opts, input_) dim = int(input_.get_shape()[1]) transposed = tf.transpose(input_, perm=[1, 0]) mean = tf.reshape(tf.reduce_mean(transposed, axis=1), [-1, 1]) centered_transposed = transposed - mean # Broadcasting mean cov = tf.matmul(centered_transposed, centered_transposed, transpose_b=True) cov = cov / (batch_size - 1) #cov = tf.Print(cov, [cov], "cov") sigmas = tf.sqrt(tf.diag_part(cov) + 1e-5) #sigmas = tf.Print(sigmas, [sigmas], "sigmas") sigmas = tf.reshape(sigmas, [1, -1]) sigmas = tf.matmul(sigmas, sigmas, transpose_a=True) #sigmas = tf.Print(sigmas, [sigmas], "sigmas") # Pearson's correlation corr = cov / sigmas triangle = tf.matrix_set_diag(tf.matrix_band_part(corr, 0, -1), tf.zeros(dim)) #triangle = tf.Print(triangle, [triangle], "triangle") loss = tf.reduce_sum(tf.square(triangle)) / ((dim * dim - dim) / 2.0) #loss = tf.Print(loss, [loss], "Correlation loss") return loss
def encoder(self, opts, input_, is_training=False, reuse=False, keep_prob=1.): if opts['e_add_noise']: def add_noise(x): shape = tf.shape(x) return x + tf.truncated_normal(shape, 0.0, 0.01) def do_nothing(x): return x input_ = tf.cond(is_training, lambda: add_noise(input_), lambda: do_nothing(input_)) num_units = opts['e_num_filters'] num_layers = opts['e_num_layers'] with tf.variable_scope("ENCODER", reuse=reuse): if not opts['convolutions']: hi = input_ for i in range(num_layers): hi = ops.linear(opts, hi, num_units, scope='h%d_lin' % i) if opts['batch_norm']: hi = ops.batch_norm(opts, hi, is_training, reuse, scope='bn%d' % i) hi = tf.nn.relu(hi) if opts['e_is_random']: latent_mean = ops.linear( opts, hi, opts['latent_space_dim'], 'h%d_lin' % (i + 1)) log_latent_sigmas = ops.linear( opts, hi, opts['latent_space_dim'], 'h%d_lin_sigma' % (i + 1)) return latent_mean, log_latent_sigmas else: return ops.linear(opts, hi, opts['latent_space_dim'], 'h%d_lin' % (i + 1)) elif opts['e_arch'] == 'dcgan': return self.dcgan_encoder(opts, input_, is_training, reuse, keep_prob) elif opts['e_arch'] == 'ali': return self.ali_encoder(opts, input_, is_training, reuse, keep_prob) elif opts['e_arch'] == 'began': return self.began_encoder(opts, input_, is_training, reuse, keep_prob) else: raise ValueError('%s Unknown' % opts['e_arch'])
def began_encoder(self, opts, input_, is_training=False, reuse=False, keep_prob=1.): num_units = opts['e_num_filters'] assert num_units == opts['g_num_filters'], 'BEGAN requires same number of filters in encoder and decoder' num_layers = opts['e_num_layers'] layer_x = ops.conv2d(opts, input_, num_units, scope='h_first_conv') for i in xrange(num_layers): if i % 3 < 2: if i != num_layers - 2: ii = i - (i / 3) scale = (ii + 1 - ii / 2) else: ii = i - (i / 3) scale = (ii - (ii - 1) / 2) layer_x = ops.conv2d(opts, layer_x, num_units * scale, d_h=1, d_w=1, scope='h%d_conv' % i) layer_x = tf.nn.elu(layer_x) else: if i != num_layers - 1: layer_x = ops.downsample(layer_x, scope='h%d_maxpool' % i, reuse=reuse) # Tensor should be [N, 8, 8, filters] right now if opts['e_is_random']: latent_mean = ops.linear( opts, layer_x, opts['latent_space_dim'], scope='hlast_lin') log_latent_sigmas = ops.linear( opts, layer_x, opts['latent_space_dim'], scope='hlast_lin_sigma') return latent_mean, log_latent_sigmas else: return ops.linear(opts, layer_x, opts['latent_space_dim'], scope='hlast_lin')
def _recon_loss_using_disc_encoder( self, opts, reconstructed_training, encoded_training, real_points, is_training_ph, keep_prob_ph): """Build an additional loss using the encoder as discriminator.""" reconstructed_reencoded_sg = self.encoder( opts, tf.stop_gradient(reconstructed_training), is_training=is_training_ph, keep_prob=keep_prob_ph, reuse=True) if opts['e_is_random']: reconstructed_reencoded_sg = reconstructed_reencoded_sg[0] reconstructed_reencoded = self.encoder( opts, reconstructed_training, is_training=is_training_ph, keep_prob=keep_prob_ph, reuse=True) if opts['e_is_random']: reconstructed_reencoded = reconstructed_reencoded[0] # Below line enforces the forward to be reconstructed_reencoded and backwards to NOT change the encoder.... crazy_hack = reconstructed_reencoded - reconstructed_reencoded_sg +\ tf.stop_gradient(reconstructed_reencoded_sg) encoded_training_sg = self.encoder( opts, tf.stop_gradient(real_points), is_training=is_training_ph, keep_prob=keep_prob_ph, reuse=True) if opts['e_is_random']: encoded_training_sg = encoded_training_sg[0] adv_fake_layer = ops.linear(opts, reconstructed_reencoded_sg, 1, scope='adv_layer') adv_true_layer = ops.linear(opts, encoded_training_sg, 1, scope='adv_layer', reuse=True) adv_fake = tf.nn.sigmoid_cross_entropy_with_logits( logits=adv_fake_layer, labels=tf.zeros_like(adv_fake_layer)) adv_true = tf.nn.sigmoid_cross_entropy_with_logits( logits=adv_true_layer, labels=tf.ones_like(adv_true_layer)) adv_fake = tf.reduce_mean(adv_fake) adv_true = tf.reduce_mean(adv_true) adv_c_loss = adv_fake + adv_true emb_c = tf.reduce_sum(tf.square(crazy_hack - tf.stop_gradient(encoded_training)), 1) emb_c_loss = tf.reduce_mean(tf.sqrt(emb_c + 1e-5)) # Normalize the loss, so that it does not depend on how good the # discriminator is. emb_c_loss = emb_c_loss / tf.stop_gradient(emb_c_loss) return adv_c_loss, emb_c_loss
def generator_mnist(self, z, is_train=True, reuse=False): if reuse: tf.get_variable_scope().reuse_variables() h0 = linear(z, 64, 'g_h0_lin', stddev=self.config.init) h1 = linear(tf.nn.relu(h0), 256, 'g_h1_lin', stddev=self.config.init) h2 = linear(tf.nn.relu(h1), 256, 'g_h2_lin', stddev=self.config.init) h3 = linear(tf.nn.relu(h2), 1024, 'g_h3_lin', stddev=self.config.init) h4 = linear(tf.nn.relu(h3), 28 * 28 * 1, 'g_h4_lin', stddev=self.config.init) return tf.reshape(tf.nn.sigmoid(h4), [self.batch_size, 28, 28, 1])
def _vgg_fully_connected(self, x, n_in, n_out, scope): with tf.variable_scope(scope): fc = ops.linear(x, n_in, n_out) return fc
def generator(hparams, z, scope_name, train, reuse): with tf.variable_scope(scope_name) as scope: if reuse: scope.reuse_variables() output_size = 64 s = output_size s2, s4, s8, s16 = int(s/2), int(s/4), int(s/8), int(s/16) g_bn0 = ops.batch_norm(name='g_bn0') g_bn1 = ops.batch_norm(name='g_bn1') g_bn2 = ops.batch_norm(name='g_bn2') g_bn3 = ops.batch_norm(name='g_bn3') # project `z` and reshape h0 = tf.reshape(ops.linear(z, hparams.gf_dim*8*s16*s16, 'g_h0_lin'), [-1, s16, s16, hparams.gf_dim * 8]) h0 = tf.nn.relu(g_bn0(h0, train=train)) h1 = ops.deconv2d(h0, [hparams.batch_size, s8, s8, hparams.gf_dim*4], name='g_h1') h1 = tf.nn.relu(g_bn1(h1, train=train)) h2 = ops.deconv2d(h1, [hparams.batch_size, s4, s4, hparams.gf_dim*2], name='g_h2') h2 = tf.nn.relu(g_bn2(h2, train=train)) h3 = ops.deconv2d(h2, [hparams.batch_size, s2, s2, hparams.gf_dim*1], name='g_h3') h3 = tf.nn.relu(g_bn3(h3, train=train)) h4 = ops.deconv2d(h3, [hparams.batch_size, s, s, hparams.c_dim], name='g_h4') x_gen = tf.nn.tanh(h4) return x_gen
def discriminator(hparams, x, scope_name, train, reuse): with tf.variable_scope(scope_name) as scope: if reuse: scope.reuse_variables() d_bn1 = ops.batch_norm(name='d_bn1') d_bn2 = ops.batch_norm(name='d_bn2') d_bn3 = ops.batch_norm(name='d_bn3') h0 = ops.lrelu(ops.conv2d(x, hparams.df_dim, name='d_h0_conv')) h1 = ops.conv2d(h0, hparams.df_dim*2, name='d_h1_conv') h1 = ops.lrelu(d_bn1(h1, train=train)) h2 = ops.conv2d(h1, hparams.df_dim*4, name='d_h2_conv') h2 = ops.lrelu(d_bn2(h2, train=train)) h3 = ops.conv2d(h2, hparams.df_dim*8, name='d_h3_conv') h3 = ops.lrelu(d_bn3(h3, train=train)) h4 = ops.linear(tf.reshape(h3, [hparams.batch_size, -1]), 1, 'd_h3_lin') d_logit = h4 d = tf.nn.sigmoid(d_logit) return d, d_logit
def generator(hparams, z, train, reuse): if reuse: tf.get_variable_scope().reuse_variables() output_size = 64 s = output_size s2, s4, s8, s16 = int(s/2), int(s/4), int(s/8), int(s/16) g_bn0 = ops.batch_norm(name='g_bn0') g_bn1 = ops.batch_norm(name='g_bn1') g_bn2 = ops.batch_norm(name='g_bn2') g_bn3 = ops.batch_norm(name='g_bn3') # project `z` and reshape h0 = tf.reshape(ops.linear(z, hparams.gf_dim*8*s16*s16, 'g_h0_lin'), [-1, s16, s16, hparams.gf_dim * 8]) h0 = tf.nn.relu(g_bn0(h0, train=train)) h1 = ops.deconv2d(h0, [hparams.batch_size, s8, s8, hparams.gf_dim*4], name='g_h1') h1 = tf.nn.relu(g_bn1(h1, train=train)) h2 = ops.deconv2d(h1, [hparams.batch_size, s4, s4, hparams.gf_dim*2], name='g_h2') h2 = tf.nn.relu(g_bn2(h2, train=train)) h3 = ops.deconv2d(h2, [hparams.batch_size, s2, s2, hparams.gf_dim*1], name='g_h3') h3 = tf.nn.relu(g_bn3(h3, train=train)) h4 = ops.deconv2d(h3, [hparams.batch_size, s, s, hparams.c_dim], name='g_h4') x_gen = tf.nn.tanh(h4) return x_gen
def discriminator(hparams, x, train, reuse): if reuse: tf.get_variable_scope().reuse_variables() d_bn1 = ops.batch_norm(name='d_bn1') d_bn2 = ops.batch_norm(name='d_bn2') d_bn3 = ops.batch_norm(name='d_bn3') h0 = ops.lrelu(ops.conv2d(x, hparams.df_dim, name='d_h0_conv')) h1 = ops.conv2d(h0, hparams.df_dim*2, name='d_h1_conv') h1 = ops.lrelu(d_bn1(h1, train=train)) h2 = ops.conv2d(h1, hparams.df_dim*4, name='d_h2_conv') h2 = ops.lrelu(d_bn2(h2, train=train)) h3 = ops.conv2d(h2, hparams.df_dim*8, name='d_h3_conv') h3 = ops.lrelu(d_bn3(h3, train=train)) h4 = ops.linear(tf.reshape(h3, [hparams.batch_size, -1]), 1, 'd_h3_lin') d_logit = h4 d = tf.nn.sigmoid(d_logit) return d, d_logit
def _build_train(self): activation_fn = tf.nn.relu with tf.variable_scope('train'): # batched s_t to batched q and q_action self.s_t = tf.placeholder('float32', [None, self.state_size], name='s_t') # MLP Feature Extraction (s_t -> l3) l1, self.w['train']['l1_w'], self.w['train']['l1_b'] = linear(self.s_t, 96, activation_fn=activation_fn, name='l1') #l2, self.w['train']['l2_w'], self.w['train']['l2_b'] = linear(l1, 16, activation_fn=activation_fn, name='l2') #l3, self.w['train']['l3_w'], self.w['train']['l3_b'] = linear(l2, 16, activation_fn=activation_fn, name='l3') l3 = l1 if self.dueling: # Value Net : V(s) is scalar (l3 -> value) value_hid, self.w['train']['l4_val_w'], self.w['train']['l4_val_b'] = linear(l3, 32, activation_fn=activation_fn, name='value_hid') value, self.w['train']['val_w_out'], self.w['train']['val_w_b'] = linear(value_hid, 1, name='value_out') # Advantage Net : A(s) is vector with advantage given each action (l3 -> advantage) adv_hid, self.w['train']['l4_adv_w'], self.w['train']['l4_adv_b'] = linear(l3, 32, activation_fn=activation_fn, name='adv_hid') advantage, self.w['train']['adv_w_out'], self.w['train']['adv_w_b'] = linear(adv_hid, self.action_size, name='adv_out') # Average Dueling (Subtract mean advantage) Q=V+A-mean(A) q_train = value + (advantage - tf.reduce_mean(advantage, reduction_indices=1, keep_dims=True)) else: l4, self.w['train']['l4_w'], self.w['train']['l4_b'] = linear(l3, 16, activation_fn=activation_fn, name='l4') q_train, self.w['train']['q_w'], self.w['train']['q_b'] = linear(l4, self.action_size, name='q') # Greedy policy q_action = tf.argmax(q_train, dimension=1) return q_train, q_action
def _build_target(self): activation_fn = tf.nn.relu with tf.variable_scope('target'): self.t_s_t = tf.placeholder('float32', [None, self.state_size], name='t_s_t') # MLP Feature Extraction l1, self.w['target']['l1_w'], self.w['target']['l1_b'] = linear(self.t_s_t, 96, activation_fn=activation_fn, name='l1') #l2, self.w['target']['l2_w'], self.w['target']['l2_b'] = linear(l1, 16, activation_fn=activation_fn, name='l2') #l3, self.w['target']['l3_w'], self.w['target']['l3_b'] = linear(l2, 16, activation_fn=activation_fn, name='l3') l3 = l1 if self.dueling: # Value Net : V(s) is scalar value_hid, self.w['target']['l4_val_w'], self.w['target']['l4_val_b'] = linear(l3, 32, activation_fn=activation_fn, name='value_hid') value, self.w['target']['val_w_out'], self.w['target']['val_w_b'] = linear(value_hid, 1, name='value_out') # Advantage Net : A(s) is vector with advantage given each action adv_hid, self.w['target']['l4_adv_w'], self.w['target']['l4_adv_b'] = linear(l3, 32, activation_fn=activation_fn, name='adv_hid') advantage, self.w['target']['adv_w_out'], self.w['target']['adv_w_b'] = linear(adv_hid, self.action_size, name='adv_out') # Average Dueling (Subtract mean advantage) q_target = value + (advantage - tf.reduce_mean(advantage, reduction_indices=1, keep_dims=True)) else: l4, self.w['target']['l4_w'], self.w['target']['l4_b'] = linear(l3, 16, activation_fn=activation_fn, name='l4') q_target, self.w['target']['q_w'], self.w['target']['q_b'] = linear(l4, self.action_size, name='q') # The action we use will depend if we use double q learning target_q_idx = tf.placeholder('int32', [None, None], name='q_id') # Get the q values of the specified state/action indices target_q_with_idx = tf.gather_nd(q_target, target_q_idx) return q_target, target_q_idx, target_q_with_idx
def cnn(self, state, input_dims, num_actions): w = {} initializer = tf.truncated_normal_initializer(0, 0.02) activation_fn = tf.nn.relu state = tf.transpose(state, perm=[0, 2, 3, 1]) l1, w['l1_w'], w['l1_b'] = conv2d(state, 32, [8, 8], [4, 4], initializer, activation_fn, 'NHWC', name='l1') l2, w['l2_w'], w['l2_b'] = conv2d(l1, 64, [4, 4], [2, 2], initializer, activation_fn, 'NHWC', name='l2') shape = l2.get_shape().as_list() l2_flat = tf.reshape(l2, [-1, reduce(lambda x, y: x * y, shape[1:])]) l3, w['l3_w'], w['l3_b'] = linear(l2_flat, 256, activation_fn=activation_fn, name='value_hid') value, w['val_w_out'], w['val_w_b'] = linear(l3, 1, name='value_out') V = tf.reshape(value, [-1]) pi_, w['pi_w_out'], w['pi_w_b'] = \ linear(l3, num_actions, activation_fn=tf.nn.softmax, name='pi_out') sums = tf.tile(tf.expand_dims(tf.reduce_sum(pi_, 1), 1), [1, num_actions]) pi = pi_ / sums #A3C is l1 = (16, [8,8], [4,4], ReLu), l2 = (32, [4,4], [2,2], ReLu), l3 = (256, Conn, ReLu), V = (1, Conn, Lin), pi = (#act, Conn, Softmax) return pi, V, [ v for v in w.values() ] # Adapted from github.com/devsisters/DQN-tensorflow/
def GeneratorCNN( z, config, reuse=None): ''' maps z to a 64x64 images with values in [-1,1] uses batch normalization internally ''' #trying to get around batch_size like this: batch_size=tf.shape(z)[0] #batch_size=tf.placeholder_with_default(64,[],'bs') with tf.variable_scope("generator",reuse=reuse) as vs: g_bn0 = batch_norm(name='g_bn0') g_bn1 = batch_norm(name='g_bn1') g_bn2 = batch_norm(name='g_bn2') g_bn3 = batch_norm(name='g_bn3') s_h, s_w = config.gf_dim, config.gf_dim#64,64 s_h2, s_w2 = conv_out_size_same(s_h, 2), conv_out_size_same(s_w, 2) s_h4, s_w4 = conv_out_size_same(s_h2, 2), conv_out_size_same(s_w2, 2) s_h8, s_w8 = conv_out_size_same(s_h4, 2), conv_out_size_same(s_w4, 2) s_h16, s_w16 = conv_out_size_same(s_h8, 2), conv_out_size_same(s_w8, 2) # project `z` and reshape z_, self_h0_w, self_h0_b = linear( z, config.gf_dim*8*s_h16*s_w16, 'g_h0_lin', with_w=True) self_h0 = tf.reshape( z_, [-1, s_h16, s_w16, config.gf_dim * 8]) h0 = tf.nn.relu(g_bn0(self_h0)) h1, h1_w, h1_b = deconv2d( h0, [batch_size, s_h8, s_w8, config.gf_dim*4], name='g_h1', with_w=True) h1 = tf.nn.relu(g_bn1(h1)) h2, h2_w, h2_b = deconv2d( h1, [batch_size, s_h4, s_w4, config.gf_dim*2], name='g_h2', with_w=True) h2 = tf.nn.relu(g_bn2(h2)) h3, h3_w, h3_b = deconv2d( h2, [batch_size, s_h2, s_w2, config.gf_dim*1], name='g_h3', with_w=True) h3 = tf.nn.relu(g_bn3(h3)) h4, h4_w, h4_b = deconv2d( h3, [batch_size, s_h, s_w, config.c_dim], name='g_h4', with_w=True) out=tf.nn.tanh(h4) variables = tf.contrib.framework.get_variables(vs) return out, variables
def DiscriminatorCNN(image, config, reuse=None): ''' Discriminator for GAN model. image : batch_size x 64x64x3 image config : see causal_dcgan/config.py reuse : pass True if not calling for first time returns: probabilities(real) : logits(real) : first layer activation used to estimate z from : variables list ''' with tf.variable_scope("discriminator",reuse=reuse) as vs: d_bn1 = batch_norm(name='d_bn1') d_bn2 = batch_norm(name='d_bn2') d_bn3 = batch_norm(name='d_bn3') if not config.stab_proj: h0 = lrelu(conv2d(image, config.df_dim, name='d_h0_conv'))#16,32,32,64 else:#method to restrict disc from winning #I think this is equivalent to just not letting disc optimize first layer #and also removing nonlinearity #k_h=5, k_w=5, d_h=2, d_w=2, stddev=0.02, #paper used 8x8 kernel, but I'm using 5x5 because it is more similar to my achitecture #n_projs=config.df_dim#64 instead of 32 in paper n_projs=config.n_stab_proj#64 instead of 32 in paper print("WARNING:STAB_PROJ active, using ",n_projs," projections") w_proj = tf.get_variable('w_proj', [5, 5, image.get_shape()[-1],n_projs], initializer=tf.truncated_normal_initializer(stddev=0.02),trainable=False) conv = tf.nn.conv2d(image, w_proj, strides=[1, 2, 2, 1], padding='SAME') b_proj = tf.get_variable('b_proj', [n_projs],#does nothing initializer=tf.constant_initializer(0.0),trainable=False) h0=tf.nn.bias_add(conv,b_proj) h1_ = lrelu(d_bn1(conv2d(h0, config.df_dim*2, name='d_h1_conv')))#16,16,16,128 h1 = add_minibatch_features(h1_, config.df_dim) h2 = lrelu(d_bn2(conv2d(h1, config.df_dim*4, name='d_h2_conv')))#16,16,16,248 h3 = lrelu(d_bn3(conv2d(h2, config.df_dim*8, name='d_h3_conv'))) #print('h3shape: ',h3.get_shape().as_list()) #print('8df_dim:',config.df_dim*8) #dim3=tf.reduce_prod(tf.shape(h3)[1:]) dim3=np.prod(h3.get_shape().as_list()[1:]) h3_flat=tf.reshape(h3, [-1,dim3]) h4 = linear(h3_flat, 1, 'd_h3_lin') prob=tf.nn.sigmoid(h4) variables = tf.contrib.framework.get_variables(vs,collection=tf.GraphKeys.TRAINABLE_VARIABLES) return prob, h4, h1_, variables
def __call__(self, inputs, is_train=True, is_debug=False): self.is_train = is_train self.is_debug = is_debug inputs = tf.convert_to_tensor(inputs) # Check if necessary # Assert that input is in [-1, 1] encoder_max_assert_op = tf.Assert(tf.less_equal(tf.reduce_max(inputs), 1.), [ inputs], summarize=0, name='assert/encoder_max') encoder_min_assert_op = tf.Assert(tf.greater_equal(tf.reduce_max(inputs), -1.), [inputs], summarize=0, name='assert/encoder_min') tf.add_to_collection('Assert', encoder_max_assert_op) tf.add_to_collection('Assert', encoder_min_assert_op) assert(inputs.get_shape().as_list() == [self.batch_size] + self.configs.conv_info.input) with tf.variable_scope(self.name) as scope: print_message(scope.name) with tf.variable_scope('conv1') as vscope: outputs, self.net['w1'], self.net['b1'] = conv3d( inputs, [self.batch_size] + self.configs.conv_info.l1, is_train=self.is_train, k=self.configs.conv_info.k1, s=self.configs.conv_info.s1, with_w=True) if is_debug: print(vscope.name, outputs) outputs = tf.layers.dropout(outputs, rate=self.configs.dropout, training=self.is_train, name='outputs') assert(outputs.get_shape().as_list() == [self.batch_size] + self.configs.conv_info.l1) self.net['conv1_outputs'] = outputs with tf.variable_scope('conv2') as vscope: outputs, self.net['w2'], self.net['b2'] = conv3d( outputs, [self.batch_size] + self.configs.conv_info.l2, is_train=self.is_train, k=self.configs.conv_info.k2, s=self.configs.conv_info.s2, with_w=True) if is_debug: print(vscope.name, outputs) outputs = tf.layers.dropout(outputs, rate=self.configs.dropout, training=self.is_train, name='outputs') assert(outputs.get_shape().as_list() == [self.batch_size] + self.configs.conv_info.l2) self.net['conv2_outputs'] = outputs with tf.variable_scope('conv3') as vscope: outputs, self.net['w3'], self.net['b3'] = conv3d( outputs, [self.batch_size] + self.configs.conv_info.l3, is_train=self.is_train, k=self.configs.conv_info.k3, s=self.configs.conv_info.s3, with_w=True) if is_debug: print(vscope.name, outputs) outputs = tf.layers.dropout(outputs, rate=self.configs.dropout, training=self.is_train, name='outputs') assert(outputs.get_shape().as_list() == [self.batch_size] + self.configs.conv_info.l3) self.net['conv3_outputs'] = outputs with tf.variable_scope('fc') as vscope: fc_dim = reduce(mul, self.configs.conv_info.l3, 1) outputs = tf.reshape(outputs, [self.batch_size] + [fc_dim], name='reshape') outputs = linear(outputs, self.latent_dimension) outputs = tf.nn.relu(outputs) if is_debug: print(vscope.name, outputs) self.net['fc_outputs'] = outputs self.variables = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, scope=self.name) return outputs
def generator(self, opts, noise, is_training, reuse=False): """Generator function, suitable for bigger simple pictures. Args: noise: [num_points, dim] array, where dim is dimensionality of the latent noise space. is_training: bool, defines whether to use batch_norm in the train or test mode. Returns: [num_points, dim1, dim2, dim3] array, where the first coordinate indexes the points, which all are of the shape (dim1, dim2, dim3). """ output_shape = self._data.data_shape # (dim1, dim2, dim3) # Computing the number of noise vectors on-the-go dim1 = tf.shape(noise)[0] num_filters = opts['g_num_filters'] with tf.variable_scope("GENERATOR", reuse=reuse): height = output_shape[0] / 16 width = output_shape[1] / 16 h0 = ops.linear(opts, noise, num_filters * height * width, scope='h0_lin') h0 = tf.reshape(h0, [-1, height, width, num_filters]) h0 = ops.batch_norm(opts, h0, is_training, reuse, scope='bn_layer1') h0 = tf.nn.relu(h0) _out_shape = [dim1, height * 2, width * 2, num_filters / 2] # for 128 x 128 does 8 x 8 --> 16 x 16 h1 = ops.deconv2d(opts, h0, _out_shape, scope='h1_deconv') h1 = ops.batch_norm(opts, h1, is_training, reuse, scope='bn_layer2') h1 = tf.nn.relu(h1) _out_shape = [dim1, height * 4, width * 4, num_filters / 4] # for 128 x 128 does 16 x 16 --> 32 x 32 h2 = ops.deconv2d(opts, h1, _out_shape, scope='h2_deconv') h2 = ops.batch_norm(opts, h2, is_training, reuse, scope='bn_layer3') h2 = tf.nn.relu(h2) _out_shape = [dim1, height * 8, width * 8, num_filters / 8] # for 128 x 128 does 32 x 32 --> 64 x 64 h3 = ops.deconv2d(opts, h2, _out_shape, scope='h3_deconv') h3 = ops.batch_norm(opts, h3, is_training, reuse, scope='bn_layer4') h3 = tf.nn.relu(h3) _out_shape = [dim1, height * 16, width * 16, num_filters / 16] # for 128 x 128 does 64 x 64 --> 128 x 128 h4 = ops.deconv2d(opts, h3, _out_shape, scope='h4_deconv') h4 = ops.batch_norm(opts, h4, is_training, reuse, scope='bn_layer5') h4 = tf.nn.relu(h4) _out_shape = [dim1] + list(output_shape) # data_shape[0] x data_shape[1] x ? -> data_shape h5 = ops.deconv2d(opts, h4, _out_shape, d_h=1, d_w=1, scope='h5_deconv') h5 = ops.batch_norm(opts, h5, is_training, reuse, scope='bn_layer6') if opts['input_normalize_sym']: return tf.nn.tanh(h5) else: return tf.nn.sigmoid(h5)
def dcgan_like_arch(self, opts, noise, is_training, reuse, keep_prob): output_shape = self._data.data_shape num_units = opts['g_num_filters'] batch_size = tf.shape(noise)[0] num_layers = opts['g_num_layers'] if opts['g_arch'] == 'dcgan': height = output_shape[0] / 2**num_layers width = output_shape[1] / 2**num_layers elif opts['g_arch'] == 'dcgan_mod': height = output_shape[0] / 2**(num_layers-1) width = output_shape[1] / 2**(num_layers-1) else: assert False h0 = ops.linear( opts, noise, num_units * height * width, scope='h0_lin') h0 = tf.reshape(h0, [-1, height, width, num_units]) h0 = tf.nn.relu(h0) layer_x = h0 for i in xrange(num_layers-1): scale = 2**(i+1) if opts['g_stride1_deconv']: # Sylvain, I'm worried about this part! _out_shape = [batch_size, height * scale / 2, width * scale / 2, num_units / scale * 2] layer_x = ops.deconv2d( opts, layer_x, _out_shape, d_h=1, d_w=1, scope='h%d_deconv_1x1' % i) layer_x = tf.nn.relu(layer_x) _out_shape = [batch_size, height * scale, width * scale, num_units / scale] layer_x = ops.deconv2d(opts, layer_x, _out_shape, scope='h%d_deconv' % i) if opts['batch_norm']: layer_x = ops.batch_norm(opts, layer_x, is_training, reuse, scope='bn%d' % i) layer_x = tf.nn.relu(layer_x) if opts['dropout']: _keep_prob = tf.minimum( 1., 0.9 - (0.9 - keep_prob) * float(i + 1) / (num_layers - 1)) layer_x = tf.nn.dropout(layer_x, _keep_prob) _out_shape = [batch_size] + list(output_shape) if opts['g_arch'] == 'dcgan': last_h = ops.deconv2d( opts, layer_x, _out_shape, scope='hlast_deconv') elif opts['g_arch'] == 'dcgan_mod': last_h = ops.deconv2d( opts, layer_x, _out_shape, d_h=1, d_w=1, scope='hlast_deconv') else: assert False if opts['input_normalize_sym']: return tf.nn.tanh(last_h) else: return tf.nn.sigmoid(last_h)
def conv_up_res(self, opts, noise, is_training, reuse, keep_prob): output_shape = self._data.data_shape num_units = opts['g_num_filters'] batch_size = tf.shape(noise)[0] num_layers = opts['g_num_layers'] data_height = output_shape[0] data_width = output_shape[1] data_channels = output_shape[2] height = data_height / 2**num_layers width = data_width / 2**num_layers h0 = ops.linear( opts, noise, num_units * height * width, scope='h0_lin') h0 = tf.reshape(h0, [-1, height, width, num_units]) h0 = tf.nn.relu(h0) layer_x = h0 for i in xrange(num_layers-1): layer_x = tf.image.resize_nearest_neighbor(layer_x, (2 * height, 2 * width)) layer_x = ops.conv2d(opts, layer_x, num_units / 2, d_h=1, d_w=1, scope='conv2d_%d' % i) height *= 2 width *= 2 num_units /= 2 if opts['g_3x3_conv'] > 0: before = layer_x for j in range(opts['g_3x3_conv']): layer_x = ops.conv2d(opts, layer_x, num_units, d_h=1, d_w=1, scope='conv2d_3x3_%d_%d' % (i, j), conv_filters_dim=3) layer_x = tf.nn.relu(layer_x) layer_x += before # Residual connection. if opts['batch_norm']: layer_x = ops.batch_norm(opts, layer_x, is_training, reuse, scope='bn%d' % i) layer_x = tf.nn.relu(layer_x) if opts['dropout']: _keep_prob = tf.minimum( 1., 0.9 - (0.9 - keep_prob) * float(i + 1) / (num_layers - 1)) layer_x = tf.nn.dropout(layer_x, _keep_prob) layer_x = tf.image.resize_nearest_neighbor(layer_x, (2 * height, 2 * width)) layer_x = ops.conv2d(opts, layer_x, data_channels, d_h=1, d_w=1, scope='last_conv2d_%d' % i) if opts['input_normalize_sym']: return tf.nn.tanh(layer_x) else: return tf.nn.sigmoid(layer_x)
def ali_encoder(self, opts, input_, is_training=False, reuse=False, keep_prob=1.): num_units = opts['e_num_filters'] layer_params = [] layer_params.append([5, 1, num_units / 8]) layer_params.append([4, 2, num_units / 4]) layer_params.append([4, 1, num_units / 2]) layer_params.append([4, 2, num_units]) layer_params.append([4, 1, num_units * 2]) # For convolution: (n - k) / stride + 1 = s # For transposed: (s - 1) * stride + k = n layer_x = input_ height = int(layer_x.get_shape()[1]) width = int(layer_x.get_shape()[2]) assert height == width for i, (kernel, stride, channels) in enumerate(layer_params): height = (height - kernel) / stride + 1 width = height # print((height, width)) layer_x = ops.conv2d( opts, layer_x, channels, d_h=stride, d_w=stride, scope='h%d_conv' % i, conv_filters_dim=kernel, padding='VALID') if opts['batch_norm']: layer_x = ops.batch_norm(opts, layer_x, is_training, reuse, scope='bn%d' % i) layer_x = ops.lrelu(layer_x, 0.1) assert height == 1 assert width == 1 # Then two 1x1 convolutions. layer_x = ops.conv2d(opts, layer_x, num_units * 2, d_h=1, d_w=1, scope='conv2d_1x1', conv_filters_dim=1) if opts['batch_norm']: layer_x = ops.batch_norm(opts, layer_x, is_training, reuse, scope='bnlast') layer_x = ops.lrelu(layer_x, 0.1) layer_x = ops.conv2d(opts, layer_x, num_units / 2, d_h=1, d_w=1, scope='conv2d_1x1_2', conv_filters_dim=1) if opts['e_is_random']: latent_mean = ops.linear( opts, layer_x, opts['latent_space_dim'], scope='hlast_lin') log_latent_sigmas = ops.linear( opts, layer_x, opts['latent_space_dim'], scope='hlast_lin_sigma') return latent_mean, log_latent_sigmas else: return ops.linear(opts, layer_x, opts['latent_space_dim'], scope='hlast_lin')
def generator(self, z, y=None, is_train=True, reuse=False): if reuse: tf.get_variable_scope().reuse_variables() s = self.output_size if np.mod(s, 16) == 0: s2, s4, s8, s16 = int(s/2), int(s/4), int(s/8), int(s/16) # project `z` and reshape self.z_, self.h0_w, self.h0_b = linear(z, self.gf_dim*8*s16*s16, 'g_h0_lin', with_w=True) self.h0 = tf.reshape(self.z_, [-1, s16, s16, self.gf_dim * 8]) h0 = tf.nn.relu(self.g_bn0(self.h0, train=is_train)) self.h1, self.h1_w, self.h1_b = deconv2d(h0, [self.batch_size, s8, s8, self.gf_dim*4], name='g_h1', with_w=True) h1 = tf.nn.relu(self.g_bn1(self.h1, train=is_train)) h2, self.h2_w, self.h2_b = deconv2d(h1, [self.batch_size, s4, s4, self.gf_dim*2], name='g_h2', with_w=True) h2 = tf.nn.relu(self.g_bn2(h2, train=is_train)) h3, self.h3_w, self.h3_b = deconv2d(h2, [self.batch_size, s2, s2, self.gf_dim*1], name='g_h3', with_w=True) h3 = tf.nn.relu(self.g_bn3(h3, train=is_train)) h4, self.h4_w, self.h4_b = deconv2d(h3, [self.batch_size, s, s, self.c_dim], name='g_h4', with_w=True) return tf.nn.tanh(h4) else: s = self.output_size s2, s4 = int(s/2), int(s/4) self.z_, self.h0_w, self.h0_b = linear(z, self.gf_dim*2*s4*s4, 'g_h0_lin', with_w=True) self.h0 = tf.reshape(self.z_, [-1, s4, s4, self.gf_dim * 2]) h0 = tf.nn.relu(self.g_bn0(self.h0, train=is_train)) self.h1, self.h1_w, self.h1_b = deconv2d(h0, [self.batch_size, s2, s2, self.gf_dim*1], name='g_h1', with_w=True) h1 = tf.nn.relu(self.g_bn1(self.h1, train=is_train)) h2, self.h2_w, self.h2_b = deconv2d(h1, [self.batch_size, s, s, self.c_dim], name='g_h2', with_w=True) return tf.nn.tanh(h2)
