def train(loss, input_x, x_data, max_epoch, batch_size, valid_portion): train_x, valid_x = split_numpy_array(x_data, portion=valid_portion) train_flow = DataFlow.arrays([train_x], batch_size=batch_size, shuffle=True, skip_incomplete=True) valid_flow = DataFlow.arrays([valid_x], batch_size=batch_size) # derive the optimizer learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(0.001, 0.99995) params = tf.trainable_variables() optimizer = tf.train.AdamOptimizer(learning_rate) train_op = optimizer.minimize(loss, var_list=params) # run the training loop with TrainLoop(params, max_epoch=max_epoch, early_stopping=True) as loop: trainer = LossTrainer(loop, loss, train_op, [input_x], train_flow) trainer.anneal_after_steps(learning_rate_var, freq=1) trainer.validate_after_epochs(Validator(loop, loss, [input_x], valid_flow), freq=1) trainer.after_epochs.add_hook( lambda: trainer.loop.collect_metrics(lr=learning_rate_var), freq=1) trainer.log_after_epochs(freq=1) trainer.run(feed_dict={learning_rate: learning_rate_var})
def main(): # load mnist data (x_train, y_train), (x_test, y_test) = \ load_mnist(shape=[784], dtype=np.float32, normalize=True) # input placeholders input_x = tf.placeholder( dtype=tf.float32, shape=(None,) + x_train.shape[1:], name='input_x') input_y = tf.placeholder( dtype=tf.int32, shape=[None], name='input_y') is_training = tf.placeholder( dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) # build the model optimizer = tf.train.AdamOptimizer(learning_rate) # derive the loss, output and accuracy logits = model(input_x, is_training=is_training) softmax_loss = softmax_classification_loss(logits, input_y) loss = softmax_loss + regularization_loss() y = softmax_classification_output(logits) acc = classification_accuracy(y, input_y) # derive the optimizer params = tf.trainable_variables() grads = optimizer.compute_gradients(loss, var_list=params) with tf.control_dependencies( tf.get_collection(tf.GraphKeys.UPDATE_OPS)): train_op = optimizer.apply_gradients(grads) # prepare for training and testing data train_flow = DataFlow.arrays( [x_train, y_train], config.batch_size, shuffle=True, skip_incomplete=True ) test_flow = DataFlow.arrays([x_test, y_test], config.batch_size) with create_session().as_default(): # train the network with TrainLoop(params, max_epoch=config.max_epoch, summary_dir=results.make_dir('train_summary'), summary_graph=tf.get_default_graph(), summary_commit_freqs={'loss': 10, 'acc': 10}, early_stopping=False) as loop: trainer = Trainer( loop, train_op, [input_x, input_y], train_flow, feed_dict={learning_rate: learning_rate_var, is_training: True}, metrics={'loss': loss, 'acc': acc} ) anneal_after( trainer, learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq ) evaluator = Evaluator( loop, metrics={'test_acc': acc}, inputs=[input_x, input_y], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time' ) trainer.evaluate_after_epochs(evaluator, freq=5) trainer.log_after_epochs(freq=1) trainer.run() # save test result results.commit(evaluator.last_metrics_dict)
def main(): logging.basicConfig( level='INFO', format='%(asctime)s [%(levelname)s] %(name)s: %(message)s') # load mnist data (x_train, y_train), (x_test, y_test) = \ load_mnist(shape=[config.x_dim], dtype=np.float32, normalize=True) # input placeholders input_x = tf.placeholder(dtype=tf.int32, shape=(None, ) + x_train.shape[1:], name='input_x') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) multi_gpu = MultiGPU(disable_prebuild=False) # build the model grads = [] losses = [] lower_bounds = [] test_nlls = [] batch_size = get_batch_size(input_x) params = None optimizer = tf.train.AdamOptimizer(learning_rate) for dev, pre_build, [dev_input_x ] in multi_gpu.data_parallel(batch_size, [input_x]): with tf.device(dev), multi_gpu.maybe_name_scope(dev): if pre_build: with arg_scope([p_net, q_net], is_training=is_training): _ = q_net(dev_input_x).chain(p_net, latent_names=['z'], observed={'x': dev_input_x}) else: with arg_scope([q_net, p_net], is_training=is_training): # derive the loss and lower-bound for training train_q_net = q_net(dev_input_x) train_chain = train_q_net.chain( p_net, latent_names=['z'], latent_axis=0, observed={'x': dev_input_x}) dev_vae_loss = tf.reduce_mean( train_chain.vi.training.sgvb()) dev_loss = dev_vae_loss + regularization_loss() dev_lower_bound = -dev_vae_loss losses.append(dev_loss) lower_bounds.append(dev_lower_bound) # derive the nll and logits output for testing test_q_net = q_net(dev_input_x, n_z=config.test_n_z) test_chain = test_q_net.chain(p_net, latent_names=['z'], latent_axis=0, observed={'x': dev_input_x}) dev_test_nll = -tf.reduce_mean( test_chain.vi.evaluation.is_loglikelihood()) test_nlls.append(dev_test_nll) # derive the optimizer params = tf.trainable_variables() grads.append( optimizer.compute_gradients(dev_loss, var_list=params)) # merge multi-gpu outputs and operations [loss, lower_bound, test_nll] = \ multi_gpu.average([losses, lower_bounds, test_nlls], batch_size) train_op = multi_gpu.apply_grads(grads=multi_gpu.average_grads(grads), optimizer=optimizer, control_inputs=tf.get_collection( tf.GraphKeys.UPDATE_OPS)) # derive the plotting function work_dev = multi_gpu.work_devices[0] with tf.device(work_dev), tf.name_scope('plot_x'): plot_p_net = p_net(n_z=100, is_training=is_training) x = tf.cast(255 * tf.sigmoid(plot_p_net['x'].distribution.logits), dtype=tf.uint8) x_plots = tf.reshape(x, [-1, 28, 28]) def plot_samples(loop): with loop.timeit('plot_time'): images = session.run(x_plots, feed_dict={is_training: False}) save_images_collection(images=images, filename=results.prepare_parent( 'plotting/{}.png'.format(loop.epoch)), grid_size=(10, 10)) # prepare for training and testing data def input_x_sampler(x): return session.run([sampled_x], feed_dict={sample_input_x: x}) with tf.device('/device:CPU:0'): sample_input_x = tf.placeholder(dtype=tf.float32, shape=(None, config.x_dim), name='sample_input_x') sampled_x = sample_from_probs(sample_input_x) train_flow = DataFlow.arrays([x_train], config.batch_size, shuffle=True, skip_incomplete=True).map(input_x_sampler) test_flow = DataFlow.arrays([x_test], config.test_batch_size). \ map(input_x_sampler) with create_session().as_default() as session, \ train_flow.threaded(5) as train_flow: # fix the testing flow, reducing the testing time test_flow = test_flow.to_arrays_flow(batch_size=config.test_batch_size) # train the network with TrainLoop(params, var_groups=['p_net', 'q_net', 'posterior_flow'], max_epoch=config.max_epoch, summary_dir=results.make_dir('train_summary'), summary_graph=tf.get_default_graph(), early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x], train_flow, feed_dict={ learning_rate: learning_rate_var, is_training: True }, metrics={'loss': loss}) anneal_after(trainer, learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) evaluator = Evaluator(loop, metrics={ 'test_nll': test_nll, 'test_lb': lower_bound }, inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') evaluator.after_run.add_hook( lambda: results.commit(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=10) trainer.evaluate_after_epochs(functools.partial( plot_samples, loop), freq=10) trainer.log_after_epochs(freq=1) trainer.run() # write the final test_nll and test_lb results.commit_and_print(evaluator.last_metrics_dict)
def main(config, result_dir): # print the config print_with_title('Configurations', config.format_config(), after='\n') # open the result object and prepare for result directories results = MLResults(result_dir) results.make_dirs('plotting', exist_ok=True) results.make_dirs('train_summary', exist_ok=True) # input placeholders input_x = tf.placeholder(dtype=tf.int32, shape=(None, config.x_dim), name='input_x') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) multi_gpu = MultiGPU(disable_prebuild=False) # build the model grads = [] losses = [] test_nlls = [] test_lbs = [] batch_size = get_batch_size(input_x) params = None optimizer = tf.train.AdamOptimizer(learning_rate) for dev, pre_build, [dev_input_x ] in multi_gpu.data_parallel(batch_size, [input_x]): with tf.device(dev), multi_gpu.maybe_name_scope(dev): if pre_build: with arg_scope([p_net, q_net], is_training=is_training, channels_last=True): _ = q_net(dev_input_x).chain(p_net, latent_names=['z'], observed={'x': dev_input_x}) else: with arg_scope([p_net, q_net], is_training=is_training, channels_last=multi_gpu.channels_last(dev)): # derive the loss and lower-bound for training train_q_net = q_net(dev_input_x) train_chain = train_q_net.chain( p_net, latent_names=['z'], latent_axis=0, observed={'x': dev_input_x}) dev_vae_loss = tf.reduce_mean( train_chain.vi.training.sgvb()) dev_loss = dev_vae_loss + regularization_loss() losses.append(dev_loss) # derive the nll and logits output for testing test_q_net = q_net(dev_input_x, n_z=config.test_n_z) test_chain = test_q_net.chain(p_net, latent_names=['z'], latent_axis=0, observed={'x': dev_input_x}) dev_test_nll = -tf.reduce_mean( test_chain.vi.evaluation.is_loglikelihood()) dev_test_lb = tf.reduce_mean( test_chain.vi.lower_bound.elbo()) test_nlls.append(dev_test_nll) test_lbs.append(dev_test_lb) # derive the optimizer params = tf.trainable_variables() grads.append( optimizer.compute_gradients(dev_loss, var_list=params)) # merge multi-gpu outputs and operations [loss, test_lb, test_nll] = \ multi_gpu.average([losses, test_lbs, test_nlls], batch_size) train_op = multi_gpu.apply_grads(grads=multi_gpu.average_grads(grads), optimizer=optimizer, control_inputs=tf.get_collection( tf.GraphKeys.UPDATE_OPS)) # derive the plotting function work_dev = multi_gpu.work_devices[0] with tf.device(work_dev), tf.name_scope('plot_x'): plot_p_net = p_net(n_z=100, is_training=is_training, channels_last=multi_gpu.channels_last(work_dev)) x_plots = tf.reshape(bernoulli_as_pixel(plot_p_net['x']), (-1, 28, 28)) def plot_samples(loop): with loop.timeit('plot_time'): images = session.run(x_plots, feed_dict={is_training: False}) save_images_collection(images=images, filename='plotting/{}.png'.format( loop.epoch), grid_size=(10, 10), results=results) # prepare for training and testing data (x_train, y_train), (x_test, y_test) = load_mnist() train_flow = bernoulli_flow(x_train, config.batch_size, shuffle=True, skip_incomplete=True) test_flow = bernoulli_flow(x_test, config.test_batch_size, sample_now=True) with create_session().as_default() as session, \ train_flow.threaded(5) as train_flow: # train the network with TrainLoop(params, var_groups=['q_net', 'p_net'], max_epoch=config.max_epoch, max_step=config.max_step, summary_dir=(results.system_path('train_summary') if config.write_summary else None), summary_graph=tf.get_default_graph(), early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x], train_flow, feed_dict={ learning_rate: learning_rate_var, is_training: True }, metrics={'loss': loss}) trainer.anneal_after(learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) evaluator = Evaluator(loop, metrics={ 'test_nll': test_nll, 'test_lb': test_lb }, inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') evaluator.after_run.add_hook( lambda: results.update_metrics(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=10) trainer.evaluate_after_epochs(functools.partial( plot_samples, loop), freq=10) trainer.log_after_epochs(freq=1) trainer.run() # print the final metrics and close the results object print_with_title('Results', results.format_metrics(), before='\n') results.close()
def main(): # load mnist data (x_train, y_train), (x_test, y_test) = \ load_cifar10(dtype=np.float32, normalize=True) print(x_train.shape) # input placeholders input_x = tf.placeholder( dtype=tf.float32, shape=(None,) + x_train.shape[1:], name='input_x') input_y = tf.placeholder( dtype=tf.int32, shape=[None], name='input_y') is_training = tf.placeholder( dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) multi_gpu = MultiGPU() # build the model grads = [] losses = [] y_list = [] acc_list = [] batch_size = get_batch_size(input_x) params = None optimizer = tf.train.AdamOptimizer(learning_rate) for dev, pre_build, [dev_input_x, dev_input_y] in multi_gpu.data_parallel( batch_size, [input_x, input_y]): with tf.device(dev), multi_gpu.maybe_name_scope(dev): if pre_build: _ = model(dev_input_x, is_training, channels_last=True) else: # derive the loss, output and accuracy dev_logits = model( dev_input_x, is_training=is_training, channels_last=multi_gpu.channels_last(dev) ) dev_softmax_loss = \ softmax_classification_loss(dev_logits, dev_input_y) dev_loss = dev_softmax_loss + regularization_loss() dev_y = softmax_classification_output(dev_logits) dev_acc = classification_accuracy(dev_y, dev_input_y) losses.append(dev_loss) y_list.append(dev_y) acc_list.append(dev_acc) # derive the optimizer params = tf.trainable_variables() grads.append( optimizer.compute_gradients(dev_loss, var_list=params)) # merge multi-gpu outputs and operations [loss, acc] = multi_gpu.average([losses, acc_list], batch_size) [y] = multi_gpu.concat([y_list]) train_op = multi_gpu.apply_grads( grads=multi_gpu.average_grads(grads), optimizer=optimizer, control_inputs=tf.get_collection(tf.GraphKeys.UPDATE_OPS) ) # prepare for training and testing data train_flow = DataFlow.arrays( [x_train, y_train], config.batch_size, shuffle=True, skip_incomplete=True ) test_flow = DataFlow.arrays([x_test, y_test], config.batch_size) with create_session().as_default(): # train the network with TrainLoop(params, max_epoch=config.max_epoch, summary_dir=results.make_dir('train_summary'), summary_graph=tf.get_default_graph(), summary_commit_freqs={'loss': 10, 'acc': 10}, early_stopping=False) as loop: trainer = Trainer( loop, train_op, [input_x, input_y], train_flow, feed_dict={learning_rate: learning_rate_var, is_training: True}, metrics={'loss': loss, 'acc': acc} ) anneal_after( trainer, learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq ) evaluator = Evaluator( loop, metrics={'test_acc': acc}, inputs=[input_x, input_y], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time' ) evaluator.after_run.add_hook( lambda: results.commit(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=5) trainer.log_after_epochs(freq=1) trainer.run() # save test result results.commit_and_print(evaluator.last_metrics_dict)
def main(config, result_dir): # print the config print_with_title('Configurations', config.format_config(), after='\n') # open the result object and prepare for result directories results = MLResults(result_dir) results.make_dirs('plotting', exist_ok=True) results.make_dirs('train_summary', exist_ok=True) # input placeholders input_x = tf.placeholder(dtype=tf.int32, shape=(None, config.x_dim), name='input_x') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32, name='learning_rate') learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) # build the model with arg_scope([q_net, p_net], is_training=is_training): # derive the loss and lower-bound for training train_q_net = q_net(input_x, n_samples=config.train_n_samples) train_chain = train_q_net.chain(p_net, latent_names=['y', 'z'], latent_axis=0, observed={'x': input_x}) if config.train_n_samples is None: baseline = reinforce_baseline_net(input_x) vae_loss = tf.reduce_mean( train_chain.vi.training.reinforce(baseline=baseline)) else: vae_loss = tf.reduce_mean(train_chain.vi.training.vimco()) loss = vae_loss + regularization_loss() # derive the nll and logits output for testing test_q_net = q_net(input_x, n_samples=config.test_n_samples) test_chain = test_q_net.chain(p_net, latent_names=['y', 'z'], latent_axis=0, observed={'x': input_x}) test_nll = -tf.reduce_mean(test_chain.vi.evaluation.is_loglikelihood()) # derive the classifier via q(y|x) q_y_given_x = tf.argmax(test_q_net['y'].distribution.logits, axis=-1) # derive the optimizer optimizer = tf.train.AdamOptimizer(learning_rate) params = tf.trainable_variables() grads = optimizer.compute_gradients(loss, var_list=params) with tf.control_dependencies(tf.get_collection(tf.GraphKeys.UPDATE_OPS)): train_op = optimizer.apply_gradients(grads) # derive the plotting function with tf.name_scope('plot_x'): plot_p_net = p_net( observed={'y': tf.range(config.n_clusters, dtype=tf.int32)}, n_z=10, is_training=is_training) x_plots = tf.reshape( tf.transpose(bernoulli_as_pixel(plot_p_net['x']), (1, 0, 2)), (-1, 28, 28)) def plot_samples(loop): with loop.timeit('plot_time'): images = session.run(x_plots, feed_dict={is_training: False}) save_images_collection(images=images, filename='plotting/{}.png'.format( loop.epoch), grid_size=(config.n_clusters, 10), results=results) # derive the final un-supervised classifier c_classifier = ClusteringClassifier(config.n_clusters, 10) def train_classifier(loop): df = bernoulli_flow(x_train, config.batch_size, shuffle=False, skip_incomplete=False) with loop.timeit('cls_train_time'): [c_pred] = collect_outputs(outputs=[q_y_given_x], inputs=[input_x], data_flow=df, feed_dict={is_training: False}) c_classifier.fit(c_pred, y_train) print(c_classifier.describe()) def evaluate_classifier(loop): with loop.timeit('cls_test_time'): [c_pred] = collect_outputs(outputs=[q_y_given_x], inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}) y_pred = c_classifier.predict(c_pred) cls_metrics = {'test_acc': accuracy_score(y_test, y_pred)} loop.collect_metrics(cls_metrics) results.update_metrics(cls_metrics) # prepare for training and testing data (x_train, y_train), (x_test, y_test) = load_mnist() train_flow = bernoulli_flow(x_train, config.batch_size, shuffle=True, skip_incomplete=True) test_flow = bernoulli_flow(x_test, config.test_batch_size, sample_now=True) with create_session().as_default() as session, \ train_flow.threaded(5) as train_flow: # train the network with TrainLoop(params, var_groups=['p_net', 'q_net', 'gaussian_mixture_prior'], max_epoch=config.max_epoch, max_step=config.max_step, summary_dir=(results.system_path('train_summary') if config.write_summary else None), summary_graph=tf.get_default_graph(), early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x], train_flow, feed_dict={ learning_rate: learning_rate_var, is_training: True }, metrics={'loss': loss}) trainer.anneal_after(learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) evaluator = Evaluator(loop, metrics={'test_nll': test_nll}, inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') evaluator.after_run.add_hook( lambda: results.update_metrics(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=10) trainer.evaluate_after_epochs(functools.partial( plot_samples, loop), freq=10) trainer.evaluate_after_epochs(functools.partial( train_classifier, loop), freq=10) trainer.evaluate_after_epochs(functools.partial( evaluate_classifier, loop), freq=10) trainer.log_after_epochs(freq=1) trainer.run() # print the final metrics and close the results object with codecs.open('cluster_classifier.txt', 'wb', 'utf-8') as f: f.write(c_classifier.describe()) print_with_title('Results', results.format_metrics(), before='\n') results.close()
def main(config, result_dir): # print the config print_with_title('Configurations', config.format_config(), after='\n') # open the result object and prepare for result directories results = MLResults(result_dir) results.make_dirs('train_summary', exist_ok=True) # input placeholders input_x = tf.placeholder(dtype=tf.float32, shape=(None, config.x_dim), name='input_x') input_y = tf.placeholder(dtype=tf.int32, shape=[None], name='input_y') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) # derive the loss, output and accuracy logits = model(input_x, is_training=is_training) softmax_loss = softmax_classification_loss(logits, input_y) loss = softmax_loss + regularization_loss() y = softmax_classification_output(logits) acc = classification_accuracy(y, input_y) # derive the optimizer optimizer = tf.train.AdamOptimizer(learning_rate) params = tf.trainable_variables() grads = optimizer.compute_gradients(loss, var_list=params) with tf.control_dependencies(tf.get_collection(tf.GraphKeys.UPDATE_OPS)): train_op = optimizer.apply_gradients(grads) # prepare for training and testing data (x_train, y_train), (x_test, y_test) = \ load_cifar10(x_shape=(config.x_dim,), normalize_x=True) train_flow = DataFlow.arrays([x_train, y_train], config.batch_size, shuffle=True, skip_incomplete=True) test_flow = DataFlow.arrays([x_test, y_test], config.test_batch_size) with create_session().as_default(): # train the network with TrainLoop(params, max_epoch=config.max_epoch, max_step=config.max_step, summary_dir=(results.system_path('train_summary') if config.write_summary else None), summary_graph=tf.get_default_graph(), early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x, input_y], train_flow, feed_dict={ learning_rate: learning_rate_var, is_training: True }, metrics={ 'loss': loss, 'acc': acc }) trainer.anneal_after(learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) evaluator = Evaluator(loop, metrics={'test_acc': acc}, inputs=[input_x, input_y], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') evaluator.after_run.add_hook( lambda: results.update_metrics(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=5) trainer.log_after_epochs(freq=1) trainer.run() # print the final metrics and close the results object print_with_title('Results', results.format_metrics(), before='\n') results.close()
def main(): # load mnist data (x_train, y_train), (x_test, y_test) = \ load_mnist(shape=[config.x_dim], dtype=np.float32, normalize=True) # input placeholders input_x = tf.placeholder(dtype=tf.int32, shape=(None, ) + x_train.shape[1:], name='input_x') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) multi_gpu = MultiGPU(disable_prebuild=False) # build the model vae = VAE( p_z=Bernoulli(tf.zeros([1, config.z_dim])), p_x_given_z=Bernoulli, q_z_given_x=Bernoulli, h_for_p_x=functools.partial(h_for_p_x, is_training=is_training), h_for_q_z=functools.partial(h_for_q_z, is_training=is_training), ) grads = [] losses = [] lower_bounds = [] test_nlls = [] batch_size = get_batch_size(input_x) params = None optimizer = tf.train.AdamOptimizer(learning_rate) for dev, pre_build, [dev_input_x ] in multi_gpu.data_parallel(batch_size, [input_x]): with tf.device(dev), multi_gpu.maybe_name_scope(dev): if pre_build: with arg_scope([h_for_q_z, h_for_p_x]): _ = vae.chain(dev_input_x) else: # derive the loss and lower-bound for training train_chain = vae.chain(dev_input_x) dev_baseline = baseline_net(dev_input_x) dev_cost, dev_baseline_cost = \ train_chain.vi.training.reinforce(baseline=dev_baseline) dev_loss = regularization_loss() + \ tf.reduce_mean(dev_cost + dev_baseline_cost) dev_lower_bound = \ tf.reduce_mean(train_chain.vi.lower_bound.elbo()) losses.append(dev_loss) lower_bounds.append(dev_lower_bound) # derive the nll and logits output for testing test_chain = vae.chain(dev_input_x, n_z=config.test_n_z) dev_test_nll = -tf.reduce_mean( test_chain.vi.evaluation.is_loglikelihood()) test_nlls.append(dev_test_nll) # derive the optimizer params = tf.trainable_variables() grads.append( optimizer.compute_gradients(dev_loss, var_list=params)) # merge multi-gpu outputs and operations [loss, lower_bound, test_nll] = \ multi_gpu.average([losses, lower_bounds, test_nlls], batch_size) train_op = multi_gpu.apply_grads(grads=multi_gpu.average_grads(grads), optimizer=optimizer, control_inputs=tf.get_collection( tf.GraphKeys.UPDATE_OPS)) # derive the plotting function work_dev = multi_gpu.work_devices[0] with tf.device(work_dev), tf.name_scope('plot_x'), \ arg_scope([h_for_q_z, h_for_p_x], channels_last=multi_gpu.channels_last(work_dev)): x_plots = tf.reshape( tf.cast(255 * tf.sigmoid(vae.model(n_z=100)['x'].distribution.logits), dtype=tf.uint8), [-1, 28, 28]) def plot_samples(loop): with loop.timeit('plot_time'): session = get_default_session_or_error() images = session.run(x_plots, feed_dict={is_training: False}) save_images_collection(images=images, filename=results.prepare_parent( 'plotting/{}.png'.format(loop.epoch)), grid_size=(10, 10)) # prepare for training and testing data def input_x_sampler(x): sess = get_default_session_or_error() return sess.run([sampled_x], feed_dict={sample_input_x: x}) with tf.device('/device:CPU:0'): sample_input_x = tf.placeholder(dtype=tf.float32, shape=(None, config.x_dim), name='sample_input_x') sampled_x = sample_from_probs(sample_input_x) train_flow = DataFlow.arrays([x_train], config.batch_size, shuffle=True, skip_incomplete=True).map(input_x_sampler) test_flow = DataFlow.arrays([x_test], config.test_batch_size). \ map(input_x_sampler) with create_session().as_default(): # fix the testing flow, reducing the testing time test_flow = test_flow.to_arrays_flow(batch_size=config.test_batch_size) # train the network with TrainLoop(params, max_epoch=config.max_epoch, summary_dir=results.make_dir('train_summary'), summary_graph=tf.get_default_graph(), early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x], train_flow, feed_dict={ learning_rate: learning_rate_var, is_training: True }, metrics={'loss': loss}) anneal_after(trainer, learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) evaluator = Evaluator(loop, metrics={ 'test_nll': test_nll, 'test_lb': lower_bound }, inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') trainer.evaluate_after_epochs(evaluator, freq=10) trainer.evaluate_after_epochs(functools.partial( plot_samples, loop), freq=10) trainer.log_after_epochs(freq=1) trainer.run() # write the final test_nll and test_lb results.commit(evaluator.last_metrics_dict)
def main(): logging.basicConfig( level='INFO', format='%(asctime)s [%(levelname)s] %(name)s: %(message)s') # load mnist data (x_train, y_train), (x_test, y_test) = \ load_mnist(shape=[config.x_dim], dtype=np.float32, normalize=True) # input placeholders input_x = tf.placeholder(dtype=tf.int32, shape=(None, ) + x_train.shape[1:], name='input_x') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32, name='learning_rate') learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) tau_p = tf.placeholder(shape=(), dtype=tf.float32, name='tau_p') tau_p_var = AnnealingDynamicValue(config.initial_tau_p, config.tau_p_anneal_factor, config.min_tau_p) tau_q = tf.placeholder(shape=(), dtype=tf.float32, name='tau_q') tau_q_var = AnnealingDynamicValue(config.initial_tau_q, config.tau_q_anneal_factor, config.min_tau_q) multi_gpu = MultiGPU(disable_prebuild=False) # build the model grads = [] losses = [] test_nlls = [] y_given_x_list = [] batch_size = get_batch_size(input_x) params = None optimizer = tf.train.AdamOptimizer(learning_rate) for dev, pre_build, [dev_input_x ] in multi_gpu.data_parallel(batch_size, [input_x]): with tf.device(dev), multi_gpu.maybe_name_scope(dev): if pre_build: with arg_scope([q_net, p_net], is_training=is_training): _ = q_net(dev_input_x).chain(p_net, latent_names=['y', 'z'], observed={'x': dev_input_x}) else: with arg_scope([q_net, p_net], is_training=is_training): # derive the loss and lower-bound for training train_n_samples = (config.train_n_samples_for_concrete if config.use_concrete_distribution else config.train_n_samples) train_q_net = q_net(dev_input_x, n_samples=train_n_samples, tau=tau_q) train_chain = train_q_net.chain( p_net, latent_names=['y', 'z'], latent_axis=0, observed={'x': dev_input_x}, tau=tau_p) if config.use_concrete_distribution: if train_n_samples is None: dev_vae_loss = tf.reduce_mean( train_chain.vi.training.sgvb()) else: dev_vae_loss = tf.reduce_mean( train_chain.vi.training.iwae()) else: if train_n_samples is None: dev_baseline = reinforce_baseline_net(dev_input_x) dev_vae_loss = tf.reduce_mean( train_chain.vi.training.reinforce( baseline=dev_baseline)) else: dev_vae_loss = tf.reduce_mean( train_chain.vi.training.vimco()) dev_loss = dev_vae_loss + regularization_loss() dev_loss = add_p_z_given_y_reg_loss(dev_loss) losses.append(dev_loss) # derive the nll and logits output for testing test_q_net = q_net(dev_input_x, n_samples=config.test_n_samples) test_chain = test_q_net.chain(p_net, latent_names=['y', 'z'], latent_axis=0, observed={'x': dev_input_x}) dev_test_nll = -tf.reduce_mean( test_chain.vi.evaluation.is_loglikelihood()) test_nlls.append(dev_test_nll) # derive the classifier via q(y|x) dev_q_y_given_x = tf.argmax( test_q_net['y'].distribution.logits, axis=-1) y_given_x_list.append(dev_q_y_given_x) # derive the optimizer params = tf.trainable_variables() grads.append( optimizer.compute_gradients(dev_loss, var_list=params)) # merge multi-gpu outputs and operations [loss, test_nll] = \ multi_gpu.average([losses, test_nlls], batch_size) [y_given_x] = multi_gpu.concat([y_given_x_list]) train_op = multi_gpu.apply_grads(grads=multi_gpu.average_grads(grads), optimizer=optimizer, control_inputs=tf.get_collection( tf.GraphKeys.UPDATE_OPS)) # derive the plotting function work_dev = multi_gpu.work_devices[0] with tf.device(work_dev), tf.name_scope('plot_x'): plot_p_net = p_net( observed={'y': tf.range(config.n_clusters, dtype=tf.int32)}, n_z=10, is_training=is_training) x = tf.cast(255 * tf.sigmoid(plot_p_net['x'].distribution.logits), dtype=tf.uint8) x_plots = tf.reshape(tf.transpose(x, [1, 0, 2]), [-1, 28, 28]) def plot_samples(loop): with loop.timeit('plot_time'): images = session.run(x_plots, feed_dict={is_training: False}) save_images_collection(images=images, filename=results.prepare_parent( 'plotting/{}.png'.format(loop.epoch)), grid_size=(config.n_clusters, 10)) # derive the final un-supervised classifier c_classifier = ClusteringClassifier(config.n_clusters, 10) test_metrics = {} def train_classifier(loop): df = DataFlow.arrays([x_train], batch_size=config.batch_size). \ map(input_x_sampler) with loop.timeit('cls_train_time'): [c_pred] = collect_outputs(outputs=[y_given_x], inputs=[input_x], data_flow=df, feed_dict={is_training: False}) c_classifier.fit(c_pred, y_train) print(c_classifier.describe()) def evaluate_classifier(loop): with loop.timeit('cls_test_time'): [c_pred] = collect_outputs(outputs=[y_given_x], inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}) y_pred = c_classifier.predict(c_pred) cls_metrics = {'test_acc': accuracy_score(y_test, y_pred)} loop.collect_metrics(cls_metrics) test_metrics.update(cls_metrics) # prepare for training and testing data def input_x_sampler(x): return session.run([sampled_x], feed_dict={sample_input_x: x}) with tf.device('/device:CPU:0'): sample_input_x = tf.placeholder(dtype=tf.float32, shape=(None, config.x_dim), name='sample_input_x') sampled_x = sample_from_probs(sample_input_x) train_flow = DataFlow.arrays([x_train], config.batch_size, shuffle=True, skip_incomplete=True).map(input_x_sampler) test_flow = DataFlow.arrays([x_test], config.test_batch_size). \ map(input_x_sampler) with create_session().as_default() as session, \ train_flow.threaded(5) as train_flow: # fix the testing flow, reducing the testing time test_flow = test_flow.to_arrays_flow(batch_size=config.test_batch_size) # train the network with TrainLoop(params, var_groups=['p_net', 'q_net', 'gaussian_mixture_prior'], max_epoch=config.max_epoch, summary_dir=results.make_dir('train_summary'), summary_graph=tf.get_default_graph(), summary_commit_freqs={'loss': 10}, early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x], train_flow, feed_dict={ learning_rate: learning_rate_var, tau_p: tau_p_var, tau_q: tau_q_var, is_training: True }, metrics={'loss': loss}) anneal_after(trainer, learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) anneal_after(trainer, tau_p_var, epochs=config.tau_p_anneal_epoch_freq, steps=config.tau_p_anneal_step_freq) anneal_after(trainer, tau_q_var, epochs=config.tau_q_anneal_epoch_freq, steps=config.tau_q_anneal_step_freq) evaluator = Evaluator(loop, metrics={'test_nll': test_nll}, inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') evaluator.after_run.add_hook( lambda: results.commit(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=10) trainer.evaluate_after_epochs(functools.partial( plot_samples, loop), freq=10) trainer.evaluate_after_epochs(functools.partial( train_classifier, loop), freq=10) trainer.evaluate_after_epochs(functools.partial( evaluate_classifier, loop), freq=10) trainer.log_after_epochs(freq=1) trainer.run() # write the final results with codecs.open('cluster_classifier.txt', 'wb', 'utf-8') as f: f.write(c_classifier.describe()) test_metrics.update(evaluator.last_metrics_dict) results.commit_and_print(test_metrics)
def main(config, result_dir): # print the config print_with_title('Configurations', config.format_config(), after='\n') # open the result object and prepare for result directories results = MLResults(result_dir) results.make_dirs('plotting', exist_ok=True) results.make_dirs('train_summary', exist_ok=True) # input placeholders input_x = tf.placeholder(dtype=tf.int32, shape=(None, config.x_dim), name='input_x') is_training = tf.placeholder(dtype=tf.bool, shape=(), name='is_training') learning_rate = tf.placeholder(shape=(), dtype=tf.float32) learning_rate_var = AnnealingDynamicValue(config.initial_lr, config.lr_anneal_factor) # build the model with arg_scope([q_net, p_net], is_training=is_training): # derive the loss and lower-bound for training train_q_net = q_net(input_x) train_chain = train_q_net.chain(p_net, latent_names=['z'], latent_axis=0, observed={'x': input_x}) baseline = baseline_net(input_x) cost, baseline_cost = \ train_chain.vi.training.reinforce(baseline=baseline) loss = regularization_loss() + tf.reduce_mean(cost + baseline_cost) # derive the nll and logits output for testing test_q_net = q_net(input_x, n_z=config.test_n_z) test_chain = test_q_net.chain(p_net, latent_names=['z'], latent_axis=0, observed={'x': input_x}) test_nll = -tf.reduce_mean(test_chain.vi.evaluation.is_loglikelihood()) test_lb = tf.reduce_mean(test_chain.vi.lower_bound.elbo()) # derive the optimizer optimizer = tf.train.AdamOptimizer(learning_rate) params = tf.trainable_variables() grads = optimizer.compute_gradients(loss, var_list=params) with tf.control_dependencies(tf.get_collection(tf.GraphKeys.UPDATE_OPS)): train_op = optimizer.apply_gradients(grads) # derive the plotting function with tf.name_scope('plot_x'): plot_p_net = p_net(n_z=100, is_training=is_training) x_plots = tf.reshape(bernoulli_as_pixel(plot_p_net['x']), (-1, 28, 28)) def plot_samples(loop): with loop.timeit('plot_time'): session = get_default_session_or_error() images = session.run(x_plots, feed_dict={is_training: False}) save_images_collection(images=images, filename='plotting/{}.png'.format( loop.epoch), grid_size=(10, 10), results=results) # prepare for training and testing data (x_train, y_train), (x_test, y_test) = load_mnist() train_flow = bernoulli_flow(x_train, config.batch_size, shuffle=True, skip_incomplete=True) test_flow = bernoulli_flow(x_test, config.test_batch_size, sample_now=True) with create_session().as_default(): # train the network with TrainLoop(params, max_epoch=config.max_epoch, max_step=config.max_step, summary_dir=(results.system_path('train_summary') if config.write_summary else None), summary_graph=tf.get_default_graph(), early_stopping=False) as loop: trainer = Trainer(loop, train_op, [input_x], train_flow, feed_dict={ learning_rate: learning_rate_var, is_training: True }, metrics={'loss': loss}) trainer.anneal_after(learning_rate_var, epochs=config.lr_anneal_epoch_freq, steps=config.lr_anneal_step_freq) evaluator = Evaluator(loop, metrics={ 'test_nll': test_nll, 'test_lb': test_lb }, inputs=[input_x], data_flow=test_flow, feed_dict={is_training: False}, time_metric_name='test_time') evaluator.after_run.add_hook( lambda: results.update_metrics(evaluator.last_metrics_dict)) trainer.evaluate_after_epochs(evaluator, freq=10) trainer.evaluate_after_epochs(functools.partial( plot_samples, loop), freq=10) trainer.log_after_epochs(freq=1) trainer.run() # print the final metrics and close the results object print_with_title('Results', results.format_metrics(), before='\n') results.close()