def _build_multigpu_train_op(self, num_gpus): with self.graph.as_default(), tf.device('/gpu:0'): tower_grads = [] self.inputs = [] self.labels = [] opt = Optimizer()() for i in range(num_gpus): with tf.device('/gpu:%d' % i): with tf.name_scope('tower_%d' % i) as scope: # tf.get_variable_scope().reuse_variables() inputs = self._create_tensor(self.loss_input['inputs']) labels = self._create_tensor(self.loss_input['labels']) input = inputs[0] model_output = self.model(input) loss = Loss()() loss = loss(model_output, labels) # Calculate the gradients for the batch of data on this tower. varlist = [x for x in tf.trainable_variables() if x.name.startswith('tower_%d' % i)] grads = opt.compute_gradients(loss, varlist) tower_grads.append(grads) if i == 0: self.actor_var = TFVariables(model_output, self.sess) self.input = input self.logits = model_output self.loss = loss self.inputs.append(inputs) self.labels.append(labels) grads = self._average_gradients(tower_grads) self.train_op = opt.apply_gradients(grads) self.sess.run(tf.initialize_all_variables())
class TrainerTf(TrainerBase): """Trainer tensorflow class.""" def build(self): """Build the trainer by assembling the necessary components.""" super().build() # Some trainer has different train batch size from valid batch self.train_metrics = None self.valid_metrics = self._init_metrics() self._init_horovod_setting() def train(self, inputs, labels): """Train model.""" feed_dict = {} with self.graph.as_default(): if self.gpu_nums >= 1: input_split = [[]] * self.gpu_nums shape_split = inputs[0].shape[0] // self.gpu_nums for j in range(self.gpu_nums): for i in range(len(inputs)): input_split = inputs[i][j * shape_split:(j + 1) * shape_split] feed_dict.update({self.inputs[j][i]: input_split}) for j in range(self.gpu_nums): for i in range(len(labels)): input_split = labels[i][j * shape_split:(j + 1) * shape_split] feed_dict.update({self.labels[j][i]: input_split}) else: for i in range(len(inputs)): feed_dict.update({self.inputs[i]: inputs[i]}) for i in range(len(labels)): feed_dict.update({self.labels[i]: labels[i]}) _, loss = self.sess.run([self.train_op, self.loss], feed_dict) return loss def predict(self, input): """Inference model.""" with self.graph.as_default(): feed_dict = {self.input: input} out = self.sess.run(self.logits, feed_dict) return out def save(self, file_name): """Save model.""" with self.graph.as_default(): self.actor_var.save_weights(file_name + ".npz") return file_name + ".npz" def load(self, model_name, by_name): """Load model.""" with self.graph.as_default(): self.actor_var.set_weights_with_npz(model_name) def set_weights(self, weights): """Set weight with memory tensor.""" with self.graph.as_default(): self.actor_var.set_weights(weights) def get_weights(self): """Get the weights.""" with self.graph.as_default(): return self.actor_var.get_weights() def init_train_op(self): """Init Train Op.""" with self.graph.as_default(): self._init_train_op() def _set_default_funcs(self): self.model_fn = self._default_model_fn self.train_input_fn = self._default_train_input_fn self.valid_input_fn = self._default_valid_input_fn def _set_condition(self): self._init_tf_session() self._init_distributed_setting() self._init_tf_estimator() def _train_epoch(self): self.estimator.train(input_fn=self.train_input_fn, steps=len(self.train_loader), hooks=self._init_logging_hook()) def _valid_epoch(self): self.callbacks.before_valid() valid_logs = None eval_metrics = self.estimator.evaluate(input_fn=self.valid_input_fn, steps=len(self.valid_loader)) self.valid_metrics.update(eval_metrics) valid_logs = dict() valid_logs['cur_valid_perfs'] = self.valid_metrics.results self.callbacks.after_valid(valid_logs) def _init_distributed_setting(self): if not self.distributed: return if zeus.is_npu_device(): from npu_bridge.estimator import npu_ops self.npu_init = npu_ops.initialize_system() self.npu_shutdown = npu_ops.shutdown_system() self.sess.run(self.npu_init) import horovod.tensorflow as hvd if zeus.is_gpu_device(): self._world_size = hvd.size() self._rank_id = hvd.rank() self._local_rank_id = hvd.local_rank() elif zeus.is_npu_device(): from hccl.manage.api import get_local_rank_id from hccl.manage.api import get_rank_size from hccl.manage.api import get_rank_id self._world_size = get_rank_size() self._rank_id = get_rank_id() self._local_rank_id = get_local_rank_id() def _build_multigpu_train_op(self, num_gpus): with self.graph.as_default(), tf.device('/gpu:0'): tower_grads = [] self.inputs = [] self.labels = [] opt = Optimizer()() for i in range(num_gpus): with tf.device('/gpu:%d' % i): with tf.name_scope('tower_%d' % i): # tf.get_variable_scope().reuse_variables() inputs = self._create_tensor(self.loss_input['inputs']) labels = self._create_tensor(self.loss_input['labels']) input = inputs[0] model_output = self.model(input) loss = Loss()() loss = loss(model_output, labels) # Calculate the gradients for the batch of data on this tower. varlist = [ x for x in tf.trainable_variables() if x.name.startswith('tower_%d' % i) ] grads = opt.compute_gradients(loss, varlist) tower_grads.append(grads) if i == 0: self.actor_var = TFVariables( model_output, self.sess) self.input = input self.logits = model_output self.loss = loss self.inputs.append(inputs) self.labels.append(labels) grads = self._average_gradients(tower_grads) self.train_op = opt.apply_gradients(grads) self.sess.run(tf.initialize_all_variables()) def _average_gradients(self, tower_grads): avg_grads = [] for grad_and_vars in zip(*tower_grads): grads = [] for g, _ in grad_and_vars: expanded_g = tf.expand_dims(g, 0) grads.append(expanded_g) all_grad = tf.concat(grads, 0) avg_grad = tf.reduce_mean(all_grad, 0, keep_dims=False) for _, v in grad_and_vars: grad_and_var = (avg_grad, v) avg_grads.append(grad_and_var) return avg_grads def _create_tensor(self, tensor_list): ret_list = [] for tensor in tensor_list: tensor_type = tensor['type'] tensor_shape = tensor['shape'] tensor_name = tensor['name'] if type(tensor_shape) is list: tf_tensor = tf.placeholder(tensor_type, name=tensor_name, shape=(None, ) + tuple(tensor_shape)) else: tf_tensor = tf.placeholder(tensor_type, name=tensor_name, shape=(None, tensor_shape)) ret_list.append(tf_tensor) return ret_list def _init_train_op(self): self.train_count = 0 self.train_time = 0. import os if self.gpu_nums >= 1: if 'CUDA_VISIBLE_DEVICES' in os.environ and os.environ[ 'CUDA_VISIBLE_DEVICES'] == '-1': with tf.name_scope('tower_0'): self._build_train_op() else: self._build_multigpu_train_op(self.gpu_nums) else: self._build_train_op() def _build_train_op(self): self.inputs = self._create_tensor(self.loss_input['inputs']) self.labels = self._create_tensor(self.loss_input['labels']) self.input = self.inputs[0] logits = self.model(self.input) self.logits = logits self.actor_var = TFVariables(logits, self.sess) loss = Loss()() self.loss = loss(logits, self.labels) self.optimizer = Optimizer()(distributed=self.distributed) grads_and_var = self.optimizer.compute_gradients(self.loss) grads, var = zip(*grads_and_var) grads_and_var = list(zip(grads, var)) self.train_op = self.optimizer.apply_gradients(grads_and_var) self.sess.run(tf.initialize_all_variables()) def _default_train_input_fn(self): return self.train_loader.input_fn() def _default_valid_input_fn(self): return self.valid_loader.input_fn() def _default_model_fn(self, features, labels, mode): """Define model_fn used by TensorFlow Estimator. :params features: input features :type features: tensorflow tensors :params labels: label data :type labels: tensorflow tensors :params mode: mode of estimator :type mode: tf.estimator.ModeKeys :return: tensorflow EstimatorSpec :rtype: tf.estimator.EstimatorSpec """ logging.info('model function action') self.model.training = mode == tf.estimator.ModeKeys.TRAIN logits = self.model(features) assign_ops = self.model.pretrained() with tf.control_dependencies(assign_ops): logits = tf.cast(logits, tf.float32) if hasattr(self.model, 'add_loss'): loss_cls = Loss()() self.model.add_loss(loss_cls) self.loss = self.model.overall_loss() else: self.loss = Loss()() loss = self.loss(logits, labels) train_op = None if mode == tf.estimator.ModeKeys.TRAIN: global_step = tf.compat.v1.train.get_or_create_global_step() epoch = tf.cast(global_step, tf.float32) / tf.cast( len(self.train_loader), tf.float32) self.optimizer = Optimizer()(distributed=self.distributed) self.lr_scheduler = LrScheduler()(optimizer=self.optimizer) self.lr_scheduler.step(epoch) if self.distributed: self.optimizer = Optimizer.set_distributed(self.optimizer) update_ops = tf.compat.v1.get_collection( tf.compat.v1.GraphKeys.UPDATE_OPS) loss_scale = self.config.loss_scale if self.use_amp else 1 minimize_op = self.optimizer.step(loss, loss_scale, global_step) train_op = tf.group(minimize_op, update_ops) eval_metric_ops = None if mode == tf.estimator.ModeKeys.EVAL: eval_metric_ops = self.valid_metrics(logits, labels) return tf.estimator.EstimatorSpec(mode=mode, loss=loss, train_op=train_op, eval_metric_ops=eval_metric_ops) def _init_tf_estimator(self): """Init tensorflow estimator.""" sess_config = self._init_session_config() if zeus.is_gpu_device(): self._init_gpu_estimator(sess_config) elif zeus.is_npu_device(): self._init_npu_estimator(sess_config) def _init_tf_session(self): sess_config = self._init_session_config() self.graph = tf.Graph() with self.graph.as_default(): self.sess = tf.compat.v1.Session(config=sess_config) def _init_session_config(self): sess_config = self._init_gpu_session_config() if zeus.is_gpu_device() else \ self._init_npu_session_config() return sess_config def _init_logging_hook(self): logging_hook = [] if zeus.is_gpu_device() and self.distributed: import horovod.tensorflow as hvd logging_hook += [hvd.BroadcastGlobalVariablesHook(0)] return logging_hook def _init_gpu_estimator(self, sess_config): """Init tensorflow estimator.""" distribution = None if not self.distributed and General._parallel and General.devices_per_trainer > 1: distribution = tf.contrib.distribute.MirroredStrategy() config = tf.estimator.RunConfig( model_dir=self.get_local_worker_path(), save_checkpoints_steps=self.config.save_steps, log_step_count_steps=self.config.report_freq, session_config=None if distribution else sess_config, train_distribute=distribution) self.estimator = tf.estimator.Estimator(model_fn=self.model_fn, config=config) def _init_npu_estimator(self, sess_config): from npu_bridge.estimator.npu.npu_config import NPURunConfig from npu_bridge.estimator.npu.npu_estimator import NPUEstimator model_dir = self.get_local_worker_path() config = NPURunConfig(model_dir=model_dir, save_checkpoints_steps=self.config.save_steps, log_step_count_steps=self.config.report_freq, session_config=sess_config, enable_data_pre_proc=True, iterations_per_loop=1) self.estimator = NPUEstimator(model_fn=self.model_fn, config=config) def _init_gpu_session_config(self): sess_config = tf.compat.v1.ConfigProto() sess_config.gpu_options.allow_growth = True if self.distributed: import horovod.tensorflow as hvd sess_config.gpu_options.visible_device_list = str(hvd.local_rank()) return sess_config def _init_npu_session_config(self): from tensorflow.core.protobuf.rewriter_config_pb2 import RewriterConfig sess_config = tf.ConfigProto() sess_config.graph_options.rewrite_options.remapping = RewriterConfig.OFF custom_op = sess_config.graph_options.rewrite_options.custom_optimizers.add( ) custom_op.name = "NpuOptimizer" if self.use_amp: custom_op.parameter_map["precision_mode"].s = tf.compat.as_bytes( "allow_mix_precision") custom_op.parameter_map["use_off_line"].b = True return sess_config
class Trainer(DistributedWorker): """Trainer class. :param model: input model, defaults to None :type model: tf model, optional :param id: id of the model, defaults to None :type id: int, optional :param hps: hyperparameters, defaults to None :type hps: dict, optional """ config = TrainerConfig() def __init__(self, model=None, id=None, hps=None, load_ckpt_flag=False, model_desc=None, lazy_build=True, **kwargs): super(Trainer, self).__init__() self.worker_type = WorkerTypes.TRAINER Trainer.__worker_id__ += 1 if id is not None: self._worker_id = id else: self._worker_id = Trainer.__worker_id__ # Data Memeber list of Trainer self.is_chief = True self.use_cuda = self.config.cuda self.epochs = self.config.epochs self.do_validation = True self.auto_save_ckpt = True self.auto_save_perf = True self.skip_train = False self.valid_interval = self.config.valid_interval self.hps = hps self.model = model self.model_desc = model_desc self.optimizer = None self.lr_scheduler = None self.loss = None self.use_syncbn = self.config.syncbn self.use_amp = self.config.amp self.train_metrics = None self.valid_metrics = None self.call_metrics_on_train = self.config.call_metrics_on_train self.train_verbose = self.config.train_verbose self.valid_verbose = self.config.valid_verbose self.train_report_steps = self.config.train_report_steps self.valid_report_steps = self.config.valid_report_steps self.train_loader = None self.valid_loader = None self.train_step = None self.valid_step = None self.make_batch = None self.model_fn = None self.train_input_fn = None self.valid_input_fn = None self.callbacks = None self.performance = None self.runtime = None self.visual_data = {} self.load_ckpt_flag = load_ckpt_flag self.distributed = self.config.distributed # Used by TimmTrainerCallbacks since it builds its trainer in # the before_train callback self.lazy_built = self.config.lazy_built # Indicate whether the necessary components of a trainer # has been built for running self._world_size = 1 self._rank_id = 0 self._local_rank_id = 0 self.config.kwargs = kwargs self.checkpoint_file_name = 'checkpoint.pth' self.model_pickle_file_name = 'model.pkl' worker_path = self.get_local_worker_path() self.model_path = FileOps.join_path(worker_path, self.model_pickle_file_name) self.checkpoint_file = FileOps.join_path(worker_path, self.checkpoint_file_name) self.weights_file = FileOps.join_path(worker_path, "model_{}.pth".format(self.worker_id)) self.loss_input = kwargs.get('loss_input', None) if not lazy_build: self.init_trainer() def _set_default_funcs(self): if zeus.is_torch_backend(): self.make_batch = self._default_make_batch self.train_step = self._default_train_step self.valid_step = self._default_valid_step elif zeus.is_tf_backend(): self.model_fn = self._default_model_fn self.train_input_fn = self._default_train_input_fn self.valid_input_fn = self._default_valid_input_fn def _set_condition(self): self._init_tf_session() self._init_distributed_setting() self._init_cuda_setting() self._init_tf_estimator() self._init_ms_context() def train_process(self): """Whole train process of the TrainWorker specified in config. After training, the model and validation results are saved to local_worker_path and s3_path. """ init_log(level=General.logger.level, log_file="log_worker_{}.txt".format(self.worker_id), log_path=self.local_log_path) self._set_default_funcs() self._set_condition() self._init_callbacks() self.callbacks.init_trainer() if not self.lazy_built: self.build() self._train_loop() def build(self): """Build the trainer by assembling the necessary components.""" self._init_hps(self.hps) logging.debug("Trainer Config: {}".format(self.config)) self.do_validation = self.config.with_valid self.use_syncbn = self.config.syncbn if self.use_syncbn and zeus.is_torch_backend(): self.model = apex.parallel.convert_syncbn_model(self.model) self.train_loader = self._init_dataloader(mode='train') self.valid_loader = self._init_dataloader(mode='val') self.batch_num_train = self.train_loader.get_dataset_size() if zeus.is_ms_backend() else len(self.train_loader) self.batch_num_valid = self.valid_loader.get_dataset_size() if zeus.is_ms_backend() else len(self.valid_loader) if zeus.is_torch_backend(): self.optimizer = Optimizer()(model=self.model, distributed=self.distributed) if hasattr(self.model, 'add_loss'): loss_cls = Loss()() self.model.add_loss(loss_cls) self.loss = self.model.overall_loss() else: self.loss = Loss()() self.lr_scheduler = LrScheduler()(self.optimizer) elif zeus.is_ms_backend(): self.optimizer = Optimizer()(model=self.model) if hasattr(self.model, 'add_loss'): loss_cls = Loss()() self.model.add_loss(loss_cls) self.loss = self.model.overall_loss() else: self.loss = Loss()() self.metric_name = self.config.metric().type # Some trainer has different train batch size from valid batch self.train_metrics = self._init_metrics() if zeus.is_torch_backend() else None self.valid_metrics = self._init_metrics() self._init_horovod_setting() if self.use_amp and zeus.is_torch_backend(): self.model, self.optimizer = amp.initialize( self.model, self.optimizer, opt_level='O1') def init_trainer(self): """Init Train Op.""" init_log(level=General.logger.level, log_file="log_worker_{}.txt".format(self.worker_id), log_path=self.local_log_path) self._set_default_funcs() self._set_condition() self._init_callbacks() self.callbacks.init_trainer() self.init_train_op() def init_train_op(self): """Init Train Op.""" if zeus.is_tf_backend(): with self.graph.as_default(): self._init_train_op() def train(self, inputs, labels): """Train model.""" if zeus.is_tf_backend(): feed_dict = {} with self.graph.as_default(): for i in range(len(inputs)): feed_dict.update({self.inputs[i]: inputs[i]}) for i in range(len(labels)): feed_dict.update({self.labels[i]: labels[i]}) _, loss = self.sess.run([self.train_op, self.loss], feed_dict) return loss def predict(self, input): """Inference model.""" if zeus.is_tf_backend(): with self.graph.as_default(): feed_dict = {self.input: input} out = self.sess.run(self.logits, feed_dict) return out def save(self, file_name): """Save model.""" if zeus.is_tf_backend(): with self.graph.as_default(): self.actor_var.save_weights(file_name + ".npz") return file_name + ".npz" def load(self, model_name, by_name): """Load model.""" if zeus.is_tf_backend(): with self.graph.as_default(): self.actor_var.set_weights_with_npz(model_name) def set_weights(self, weights): """Set weight with memory tensor.""" if zeus.is_tf_backend(): with self.graph.as_default(): self.actor_var.set_weights(weights) def get_weights(self): """Get the weights.""" if zeus.is_tf_backend(): with self.graph.as_default(): return self.actor_var.get_weights() def _create_tensor(self, tensor_list): ret_list = [] for tensor in tensor_list: tensor_type = tensor['type'] tensor_shape = tensor['shape'] tensor_name = tensor['name'] if type(tensor_shape) is list: tf_tensor = tf.placeholder(tensor_type, name=tensor_name, shape=(None, ) + tuple(tensor_shape)) else: tf_tensor = tf.placeholder(tensor_type, name=tensor_name, shape=(None, tensor_shape)) ret_list.append(tf_tensor) return ret_list def _init_train_op(self): if self.loss_input is not None: self.inputs = self._create_tensor(self.loss_input['inputs']) self.labels = self._create_tensor(self.loss_input['labels']) self.input = self.inputs[0] logits = self.model(self.input) self.logits = logits self.actor_var = TFVariables(logits, self.sess) loss = Loss()() self.loss = loss(logits, self.labels) self.optimizer = Optimizer()(distributed=self.distributed) grads_and_var = self.optimizer.compute_gradients(self.loss) grads, var = zip(*grads_and_var) grads_and_var = list(zip(grads, var)) self.train_op = self.optimizer.apply_gradients(grads_and_var) self.sess.run(tf.initialize_all_variables()) def _init_cuda_setting(self): """Init CUDA setting.""" if not zeus.is_torch_backend(): return if not self.config.cuda: self.config.device = -1 return self.config.device = self.config.cuda if self.config.cuda is not True else 0 self.use_cuda = True if self.distributed: torch.cuda.set_device(self._local_rank_id) torch.cuda.manual_seed(self.config.seed) def _init_distributed_setting(self): if not self.distributed: return if zeus.is_npu_device(): self.npu_init = npu_ops.initialize_system() self.npu_shutdown = npu_ops.shutdown_system() self.sess.run(self.npu_init) self._world_size = hvd.size() if zeus.is_gpu_device() else get_rank_size() self._rank_id = hvd.rank() if zeus.is_gpu_device() else get_rank_id() self._local_rank_id = hvd.local_rank() if zeus.is_gpu_device() else get_local_rank_id() def _init_horovod_setting(self): """Init horovod setting.""" self.is_chief = True if self.distributed and zeus.is_torch_backend(): hvd.broadcast_parameters(self.model.state_dict(), root_rank=0) hvd.broadcast_optimizer_state(self.optimizer, root_rank=0) if hvd.rank() != 0: self.is_chief = False else: self.is_chief = True def _init_hps(self, hps=None): """Load hps from file.""" if hps is not None: self.hps = hps elif self.config.hps_file is not None: desc_file = self.config.hps_file.replace("{local_base_path}", self.local_base_path) self.hps = Config(desc_file) elif self.config.hps_folder is not None: folder = self.config.hps_folder.replace("{local_base_path}", self.local_base_path) pattern = FileOps.join_path(folder, "desc_*.json") desc_file = glob.glob(pattern)[0] self.hps = Config(desc_file) if self.hps and self.hps.get('trainer'): self.config.from_json(self.hps.get('trainer')) self.epochs = self.config.epochs def _init_metrics(self, metrics=None): """Init metrics.""" if metrics is not None: return metrics else: return Metrics() def _init_dataloader(self, mode, loader=None): """Init dataloader.""" if loader is not None: return loader if mode == "train" and self.hps is not None and self.hps.get("dataset") is not None: dataset_cls = ClassFactory.get_cls(ClassType.DATASET) dataset = dataset_cls(mode=mode, hps=self.hps.get("dataset")) else: dataset_cls = ClassFactory.get_cls(ClassType.DATASET) dataset = dataset_cls(mode=mode) if self.distributed and mode == "train": dataset.set_distributed(self._world_size, self._rank_id) # adapt the dataset to specific backend dataloader = Adapter(dataset).loader return dataloader def _train_loop(self): """Do the training with data, callbacks and step functions etc.""" # Allow user to build trainer in before_train() callback, but they # should set lazy_built in configuration file to True self.callbacks.before_train() if self.skip_train: return repeat_time = 1 if zeus.is_ms_backend() else self.epochs for epoch in range(repeat_time): epoch_logs = {'train_num_batches': self.batch_num_train} if self.do_validation: epoch_logs.update({'valid_num_batches': self.batch_num_valid}) self.callbacks.before_epoch(epoch, epoch_logs) self._train_epoch() if self.do_validation and self._should_run_validation(epoch): self._valid_epoch() self.callbacks.after_epoch(epoch) self.callbacks.after_train() if self.distributed: self._shutdown_distributed() def _train_epoch(self): if zeus.is_torch_backend(): self.model.train() for batch_index, batch in enumerate(self.train_loader): batch = self.make_batch(batch) batch_logs = {'train_batch': batch} self.callbacks.before_train_step(batch_index, batch_logs) train_batch_output = self.train_step(batch) batch_logs.update(train_batch_output) if self.config.is_detection_trainer: batch_logs.update({'is_detection_trainer': True}) self.callbacks.after_train_step(batch_index, batch_logs) elif zeus.is_tf_backend(): self.estimator.train(input_fn=self.train_input_fn, steps=len(self.train_loader), hooks=self._init_logging_hook()) elif zeus.is_ms_backend(): self.ms_model = MsModel(network=self.model, loss_fn=self.loss, optimizer=self.optimizer, metrics={self.metric_name: self.valid_metrics()}) config_ck = CheckpointConfig(save_checkpoint_steps=self.config.save_steps) # save the network model and parameters for subsequence fine-tuning save_path = self.get_local_worker_path(self.step_name, self.worker_id) ckpoint_cb = ModelCheckpoint(config=config_ck, directory=save_path) loss_cb = LossMonitor(per_print_times=self.config.report_freq) eval_cb = EvalCallBack(self.ms_model, self.valid_loader) self.ms_model.train(epoch=self.epochs, train_dataset=self.train_loader, callbacks=[ckpoint_cb, loss_cb, eval_cb], dataset_sink_mode=self.dataset_sink_mode) def _valid_epoch(self): self.callbacks.before_valid() valid_logs = None if zeus.is_torch_backend(): self.model.eval() with torch.no_grad(): for batch_index, batch in enumerate(self.valid_loader): batch = self.make_batch(batch) batch_logs = {'valid_batch': batch} self.callbacks.before_valid_step(batch_index, batch_logs) valid_batch_output = self.valid_step(batch) self.callbacks.after_valid_step(batch_index, valid_batch_output) elif zeus.is_tf_backend(): eval_metrics = self.estimator.evaluate(input_fn=self.valid_input_fn, steps=len(self.valid_loader)) self.valid_metrics.update(eval_metrics) valid_logs = dict() valid_logs['cur_valid_perfs'] = self.valid_metrics.results elif zeus.is_ms_backend(): eval_metrics = self.ms_model.eval(valid_dataset=self.valid_loader, dataset_sink_mode=self.dataset_sink_mode) self.valid_metrics.update(eval_metrics) valid_logs = dict() valid_logs['cur_valid_perfs'] = self.valid_metrics.results self.callbacks.after_valid(valid_logs) def _default_make_batch(self, batch): """Unpack batch to get input and target.""" input, target = batch if self.use_cuda and not self.config.is_detection_trainer: input, target = input.cuda(), target.cuda() return (input, target) def _default_train_step(self, batch): input, target = batch self.optimizer.zero_grad() output = self.model(input) loss = self.loss(output, target) if self.use_amp: with amp.scale_loss(loss, self.optimizer) as scaled_loss: scaled_loss.backward() self.optimizer.synchronize() with self.optimizer.skip_synchronize(): self.optimizer.step() else: loss.backward() if self.config.grad_clip: torch.nn.utils.clip_grad_norm_( self.model.parameters(), self.config.grad_clip) self.optimizer.step() return {'loss': loss.item(), 'train_batch_output': output, 'lr': self.lr_scheduler.get_lr()} def _default_valid_step(self, batch): input, target = batch if self.config.is_detection_trainer: output = self.model(input, forward_train=False) else: output = self.model(input) return {'valid_batch_output': output} def _init_minimize_op(self, loss, global_step, var_list=None): """Init loss minimize operation, include loss scale method.""" loss_scale = self.config.loss_scale if self.use_amp else 1. if loss_scale != 1: scaled_grad_vars = self.optimizer.compute_gradients(loss * loss_scale, var_list=var_list) unscaled_grad_vars = [] for grad, var in scaled_grad_vars: unscaled_grad_vars.append((grad, var) if grad is None else (grad / loss_scale, var)) minimize_op = self.optimizer.apply_gradients(unscaled_grad_vars, global_step) else: grad_vars = self.optimizer.compute_gradients(loss, var_list=var_list) minimize_op = self.optimizer.apply_gradients(grad_vars, global_step) return minimize_op def _default_train_input_fn(self): return self.train_loader.input_fn() def _default_valid_input_fn(self): return self.valid_loader.input_fn() def _default_model_fn(self, features, labels, mode): """Define model_fn used by TensorFlow Estimator. :params features: input features :type features: tensorflow tensors :params labels: label data :type labels: tensorflow tensors :params mode: mode of estimator :type mode: tf.estimator.ModeKeys :return: tensorflow EstimatorSpec :rtype: tf.estimator.EstimatorSpec """ logging.info('model function action') self.model.training = mode == tf.estimator.ModeKeys.TRAIN logits = self.model(features) logits = tf.cast(logits, tf.float32) if hasattr(self.model, 'add_loss'): loss_cls = Loss()() self.model.add_loss(loss_cls) self.loss = self.model.overall_loss() else: self.loss = Loss()() loss = self.loss(logits, labels) train_op = None if mode == tf.estimator.ModeKeys.TRAIN: global_step = tf.compat.v1.train.get_or_create_global_step() epoch = tf.cast(global_step, tf.float32) / tf.cast(len(self.train_loader), tf.float32) self.optimizer = Optimizer()(distributed=self.distributed) self.lr_scheduler = LrScheduler()(optimizer=self.optimizer) self.lr_scheduler.step(epoch) update_ops = tf.compat.v1.get_collection(tf.compat.v1.GraphKeys.UPDATE_OPS) loss_scale = self.config.loss_scale if self.use_amp else 1 minimize_op = self.optimizer.step(loss, loss_scale, global_step) train_op = tf.group(minimize_op, update_ops) eval_metric_ops = None if mode == tf.estimator.ModeKeys.EVAL: eval_metric_ops = self.valid_metrics(logits, labels) return tf.estimator.EstimatorSpec(mode=mode, loss=loss, train_op=train_op, eval_metric_ops=eval_metric_ops) def _should_run_validation(self, epoch): # Zero valid_interval means doesn't run _valid_loop of the trainer # and user may provide _valid_loop in other callbacks if self.valid_interval == 0: return False else: return epoch % self.valid_interval == 0 or (epoch + 1) == self.epochs def _init_callbacks(self): disables = [] customs = self.config.callbacks or [] if customs and not isinstance(customs, list): customs = [customs] if not self.config.model_statistics: disables.append('ModelStatistics') self.callbacks = CallbackList(customs, disables) self.callbacks.set_trainer(self) def _metric_average(self, val, name): """Do metric average. :param val: input value :param name: metric name :return: """ tensor = torch.tensor(val) avg_tensor = hvd.allreduce(tensor, name=name) return avg_tensor.item() @property def _first_rank(self): """Check if the first rank.""" if self.distributed and hvd.rank() != 0: return False else: return True def _backup(self): """Backup result worker folder.""" if self.need_backup is True and self.backup_base_path is not None: backup_worker_path = FileOps.join_path( self.backup_base_path, self.get_worker_subpath()) FileOps.copy_folder( self.get_local_worker_path(self.step_name, self.worker_id), backup_worker_path) def _save_visual_data(self, is_train=True, pfms=None, loss=None, lr=None): # TODO Will move to metric base class later. for _name, value in pfms.items(): if is_train: _name = "{}_{}".format("t", _name) else: _name = "{}_{}".format("v", _name) if isinstance(value, list): for i, _item in enumerate(value): _name = "{}_{}".format(_name, i) self.visual_data[_name] = _item.data.item() elif isinstance(value, dict): for k, v in value.keys(): _name = "{}_{}".format(_name, k) self.visual_data[_name] = v elif value is not None: self.visual_data[_name] = value.data.item() if loss is not None: self.visual_data["loss"] = loss if lr is not None: self.visual_data["lr"] = lr def _init_tf_estimator(self): """Init tensorflow estimator.""" if not zeus.is_tf_backend(): return sess_config = self._init_session_config() if zeus.is_gpu_device(): self._init_gpu_estimator(sess_config) elif zeus.is_npu_device(): self._init_npu_estimator(sess_config) def _init_tf_session(self): if not zeus.is_tf_backend(): return sess_config = self._init_session_config() self.graph = tf.Graph() with self.graph.as_default(): self.sess = tf.compat.v1.Session(config=sess_config) def _init_session_config(self): sess_config = self._init_gpu_session_config() if zeus.is_gpu_device() else \ self._init_npu_session_config() return sess_config def _init_logging_hook(self): logging_hook = [] if zeus.is_gpu_device() and self.distributed: logging_hook += [hvd.BroadcastGlobalVariablesHook(0)] return logging_hook def _init_gpu_estimator(self, sess_config): """Init tensorflow estimator.""" distribution = None if not self.distributed and General._parallel and General.devices_per_trainer > 1: distribution = tf.contrib.distribute.MirroredStrategy() config = tf.estimator.RunConfig(model_dir=self.get_local_worker_path(), save_checkpoints_steps=self.config.save_steps, log_step_count_steps=self.config.report_freq, session_config=None if distribution else sess_config, train_distribute=distribution) self.estimator = tf.estimator.Estimator(model_fn=self.model_fn, config=config) def _init_npu_estimator(self, sess_config): model_dir = self.get_local_worker_path() config = NPURunConfig(model_dir=model_dir, save_checkpoints_steps=self.config.save_steps, log_step_count_steps=self.config.report_freq, session_config=sess_config, enable_data_pre_proc=True, iterations_per_loop=1) self.estimator = NPUEstimator(model_fn=self.model_fn, config=config) def _init_gpu_session_config(self): sess_config = tf.compat.v1.ConfigProto() sess_config.gpu_options.allow_growth = True if self.distributed: sess_config.gpu_options.visible_device_list = str(hvd.local_rank()) return sess_config def _init_npu_session_config(self): sess_config = tf.ConfigProto() sess_config.graph_options.rewrite_options.remapping = RewriterConfig.OFF custom_op = sess_config.graph_options.rewrite_options.custom_optimizers.add() custom_op.name = "NpuOptimizer" if self.use_amp: custom_op.parameter_map["precision_mode"].s = tf.compat.as_bytes("allow_mix_precision") custom_op.parameter_map["use_off_line"].b = True # custom_op.parameter_map['hcom_parallel'].b = True # custom_op.parameter_map["enable_data_pre_proc"].b = True # custom_op.parameter_map["mix_compile_mode"].b = True # mixed calculation # custom_op.parameter_map["min_group_size"].b = 1 return sess_config def _init_ms_context(self): if not zeus.is_ms_backend(): return if zeus.is_npu_device(): context.set_context(mode=context.GRAPH_MODE, device_target="Ascend") else: context.set_context(mode=context.GRAPH_MODE, device_target="CPU") self.dataset_sink_mode = True if zeus.is_npu_device() else False def _shutdown_distributed(self): if zeus.is_npu_device() and self.distributed: self.sess.run(self.npu_shutdown) self.sess.close()
class TrainerTf(TrainerBase): """Trainer tensorflow class.""" def build(self): """Build the trainer by assembling the necessary components.""" super().build() # Some trainer has different train batch size from valid batch self.train_metrics = None self.valid_metrics = self._init_metrics() self._init_horovod_setting() def train(self, inputs, labels): """Train model.""" feed_dict = {} with self.graph.as_default(): for i in range(len(inputs)): feed_dict.update({self.inputs[i]: inputs[i]}) for i in range(len(labels)): feed_dict.update({self.labels[i]: labels[i]}) _, loss = self.sess.run([self.train_op, self.loss], feed_dict) return loss def predict(self, input): """Inference model.""" with self.graph.as_default(): feed_dict = {self.input: input} out = self.sess.run(self.logits, feed_dict) return out def save(self, file_name): """Save model.""" with self.graph.as_default(): self.actor_var.save_weights(file_name + ".npz") return file_name + ".npz" def load(self, model_name, by_name): """Load model.""" with self.graph.as_default(): self.actor_var.set_weights_with_npz(model_name) def set_weights(self, weights): """Set weight with memory tensor.""" with self.graph.as_default(): self.actor_var.set_weights(weights) def get_weights(self): """Get the weights.""" with self.graph.as_default(): return self.actor_var.get_weights() def init_train_op(self): """Init Train Op.""" with self.graph.as_default(): self._init_train_op() def _set_default_funcs(self): self.model_fn = self._default_model_fn self.train_input_fn = self._default_train_input_fn self.valid_input_fn = self._default_valid_input_fn def _set_condition(self): self._init_tf_session() self._init_distributed_setting() self._init_tf_estimator() def _train_epoch(self): self.estimator.train(input_fn=self.train_input_fn, steps=len(self.train_loader), hooks=self._init_logging_hook()) def _valid_epoch(self): self.callbacks.before_valid() valid_logs = None eval_metrics = self.estimator.evaluate(input_fn=self.valid_input_fn, steps=len(self.valid_loader)) self.valid_metrics.update(eval_metrics) valid_logs = dict() valid_logs['cur_valid_perfs'] = self.valid_metrics.results self.callbacks.after_valid(valid_logs) def _init_distributed_setting(self): if not self.distributed: return if zeus.is_npu_device(): self.npu_init = npu_ops.initialize_system() self.npu_shutdown = npu_ops.shutdown_system() self.sess.run(self.npu_init) self._world_size = hvd.size() if zeus.is_gpu_device( ) else get_rank_size() self._rank_id = hvd.rank() if zeus.is_gpu_device() else get_rank_id() self._local_rank_id = hvd.local_rank() if zeus.is_gpu_device( ) else get_local_rank_id() def _create_tensor(self, tensor_list): ret_list = [] for tensor in tensor_list: tensor_type = tensor['type'] tensor_shape = tensor['shape'] tensor_name = tensor['name'] if type(tensor_shape) is list: tf_tensor = tf.placeholder(tensor_type, name=tensor_name, shape=(None, ) + tuple(tensor_shape)) else: tf_tensor = tf.placeholder(tensor_type, name=tensor_name, shape=(None, tensor_shape)) ret_list.append(tf_tensor) return ret_list def _init_train_op(self): self.inputs = self._create_tensor(self.loss_input['inputs']) self.labels = self._create_tensor(self.loss_input['labels']) self.input = self.inputs[0] logits = self.model(self.input) self.logits = logits self.actor_var = TFVariables(logits, self.sess) loss = Loss()() self.loss = loss(logits, self.labels) self.optimizer = Optimizer()(distributed=self.distributed) grads_and_var = self.optimizer.compute_gradients(self.loss) grads, var = zip(*grads_and_var) grads_and_var = list(zip(grads, var)) self.train_op = self.optimizer.apply_gradients(grads_and_var) self.sess.run(tf.initialize_all_variables()) def _default_train_input_fn(self): return self.train_loader.input_fn() def _default_valid_input_fn(self): return self.valid_loader.input_fn() def _default_model_fn(self, features, labels, mode): """Define model_fn used by TensorFlow Estimator. :params features: input features :type features: tensorflow tensors :params labels: label data :type labels: tensorflow tensors :params mode: mode of estimator :type mode: tf.estimator.ModeKeys :return: tensorflow EstimatorSpec :rtype: tf.estimator.EstimatorSpec """ logging.info('model function action') self.model.training = mode == tf.estimator.ModeKeys.TRAIN logits = self.model(features) logits = tf.cast(logits, tf.float32) if hasattr(self.model, 'add_loss'): loss_cls = Loss()() self.model.add_loss(loss_cls) self.loss = self.model.overall_loss() else: self.loss = Loss()() loss = self.loss(logits, labels) train_op = None if mode == tf.estimator.ModeKeys.TRAIN: global_step = tf.compat.v1.train.get_or_create_global_step() epoch = tf.cast(global_step, tf.float32) / tf.cast( len(self.train_loader), tf.float32) self.optimizer = Optimizer()(distributed=self.distributed) self.lr_scheduler = LrScheduler()(optimizer=self.optimizer) self.lr_scheduler.step(epoch) update_ops = tf.compat.v1.get_collection( tf.compat.v1.GraphKeys.UPDATE_OPS) loss_scale = self.config.loss_scale if self.use_amp else 1 minimize_op = self.optimizer.step(loss, loss_scale, global_step) train_op = tf.group(minimize_op, update_ops) eval_metric_ops = None if mode == tf.estimator.ModeKeys.EVAL: eval_metric_ops = self.valid_metrics(logits, labels) return tf.estimator.EstimatorSpec(mode=mode, loss=loss, train_op=train_op, eval_metric_ops=eval_metric_ops) def _init_tf_estimator(self): """Init tensorflow estimator.""" sess_config = self._init_session_config() if zeus.is_gpu_device(): self._init_gpu_estimator(sess_config) elif zeus.is_npu_device(): self._init_npu_estimator(sess_config) def _init_tf_session(self): sess_config = self._init_session_config() self.graph = tf.Graph() with self.graph.as_default(): self.sess = tf.compat.v1.Session(config=sess_config) def _init_session_config(self): sess_config = self._init_gpu_session_config() if zeus.is_gpu_device() else \ self._init_npu_session_config() return sess_config def _init_logging_hook(self): logging_hook = [] if zeus.is_gpu_device() and self.distributed: logging_hook += [hvd.BroadcastGlobalVariablesHook(0)] return logging_hook def _init_gpu_estimator(self, sess_config): """Init tensorflow estimator.""" distribution = None if not self.distributed and General._parallel and General.devices_per_trainer > 1: distribution = tf.contrib.distribute.MirroredStrategy() config = tf.estimator.RunConfig( model_dir=self.get_local_worker_path(), save_checkpoints_steps=self.config.save_steps, log_step_count_steps=self.config.report_freq, session_config=None if distribution else sess_config, train_distribute=distribution) self.estimator = tf.estimator.Estimator(model_fn=self.model_fn, config=config) def _init_npu_estimator(self, sess_config): model_dir = self.get_local_worker_path() config = NPURunConfig(model_dir=model_dir, save_checkpoints_steps=self.config.save_steps, log_step_count_steps=self.config.report_freq, session_config=sess_config, enable_data_pre_proc=True, iterations_per_loop=1) self.estimator = NPUEstimator(model_fn=self.model_fn, config=config) def _init_gpu_session_config(self): sess_config = tf.compat.v1.ConfigProto() sess_config.gpu_options.allow_growth = True if self.distributed: sess_config.gpu_options.visible_device_list = str(hvd.local_rank()) return sess_config def _init_npu_session_config(self): sess_config = tf.ConfigProto() sess_config.graph_options.rewrite_options.remapping = RewriterConfig.OFF custom_op = sess_config.graph_options.rewrite_options.custom_optimizers.add( ) custom_op.name = "NpuOptimizer" if self.use_amp: custom_op.parameter_map["precision_mode"].s = tf.compat.as_bytes( "allow_mix_precision") custom_op.parameter_map["use_off_line"].b = True return sess_config