def run_evaluation(strategy, test_input_fn, eval_steps, input_meta_data, model, step, eval_summary_writer=None): """Run evaluation for SQUAD task. Args: strategy: distribution strategy. test_input_fn: input function for evaluation data. eval_steps: total number of evaluation steps. input_meta_data: input meta data. model: keras model object. step: current training step. eval_summary_writer: summary writer used to record evaluation metrics. """ def _test_step_fn(inputs): """Replicated validation step.""" inputs["mems"] = None res = model(inputs, training=False) return res, inputs["unique_ids"] @tf.function def _run_evaluation(test_iterator): """Runs validation steps.""" res, unique_ids = strategy.experimental_run_v2( _test_step_fn, args=(next(test_iterator), )) return res, unique_ids # pylint: disable=protected-access test_iterator = data_utils._get_input_iterator(test_input_fn, strategy) # pylint: enable=protected-access cur_results = [] eval_examples = squad_utils.read_squad_examples( input_meta_data["predict_file"], is_training=False) with tf.io.gfile.GFile(input_meta_data["predict_file"]) as f: orig_data = json.load(f)["data"] for _ in range(eval_steps): results, unique_ids = _run_evaluation(test_iterator) unique_ids = strategy.experimental_local_results(unique_ids) for result_key in results: results[result_key] = (strategy.experimental_local_results( results[result_key])) for core_i in range(strategy.num_replicas_in_sync): bsz = int(input_meta_data["test_batch_size"] / strategy.num_replicas_in_sync) for j in range(bsz): result = {} for result_key in results: result[result_key] = results[result_key][core_i].numpy()[j] result["unique_ids"] = unique_ids[core_i].numpy()[j] # We appended a fake example into dev set to make data size can be # divided by test_batch_size. Ignores this fake example during # evaluation. if result["unique_ids"] == 1000012047: continue unique_id = int(result["unique_ids"]) start_top_log_probs = ([ float(x) for x in result["start_top_log_probs"].flat ]) start_top_index = [ int(x) for x in result["start_top_index"].flat ] end_top_log_probs = ([ float(x) for x in result["end_top_log_probs"].flat ]) end_top_index = [int(x) for x in result["end_top_index"].flat] cls_logits = float(result["cls_logits"].flat[0]) cur_results.append( squad_utils.RawResult( unique_id=unique_id, start_top_log_probs=start_top_log_probs, start_top_index=start_top_index, end_top_log_probs=end_top_log_probs, end_top_index=end_top_index, cls_logits=cls_logits)) if len(cur_results) % 1000 == 0: logging.info("Processing example: %d", len(cur_results)) output_prediction_file = os.path.join(input_meta_data["predict_dir"], "predictions.json") output_nbest_file = os.path.join(input_meta_data["predict_dir"], "nbest_predictions.json") output_null_log_odds_file = os.path.join(input_meta_data["predict_dir"], "null_odds.json") ret = squad_utils.write_predictions( eval_examples, input_meta_data["eval_features"], cur_results, input_meta_data["n_best_size"], input_meta_data["max_answer_length"], output_prediction_file, output_nbest_file, output_null_log_odds_file, orig_data, input_meta_data["start_n_top"], input_meta_data["end_n_top"]) # Log current result log_str = "Result | " for key, val in ret.items(): log_str += "{} {} | ".format(key, val) logging.info(log_str) if eval_summary_writer: with eval_summary_writer.as_default(): tf.summary.scalar("best_f1", ret["best_f1"], step=step) tf.summary.scalar("best_exact", ret["best_exact"], step=step) eval_summary_writer.flush()
def run_evaluation(strategy, test_input_fn, eval_steps, model, step, eval_summary_writer=None): """Run evaluation for classification task. Args: strategy: distribution strategy. test_input_fn: input function for evaluation data. eval_steps: total number of evaluation steps. model: keras model object. step: current train step. eval_summary_writer: summary writer used to record evaluation metrics. As there are fake data samples in validation set, we use mask to get rid of them when calculating the accuracy. For the reason that there will be dynamic-shape tensor, we first collect logits, labels and masks from TPU and calculate the accuracy via numpy locally. Returns: A float metric, accuracy. """ def _test_step_fn(inputs): """Replicated validation step.""" inputs["mems"] = None _, logits = model(inputs, training=False) return logits, inputs["label_ids"], inputs["is_real_example"] @tf.function def _run_evaluation(test_iterator): """Runs validation steps.""" logits, labels, masks = strategy.experimental_run_v2( _test_step_fn, args=(next(test_iterator), )) return logits, labels, masks # pylint: disable=protected-access test_iterator = data_utils._get_input_iterator(test_input_fn, strategy) # pylint: enable=protected-access correct = 0 total = 0 for _ in range(eval_steps): logits, labels, masks = _run_evaluation(test_iterator) logits = strategy.experimental_local_results(logits) labels = strategy.experimental_local_results(labels) masks = strategy.experimental_local_results(masks) merged_logits = [] merged_labels = [] merged_masks = [] for i in range(strategy.num_replicas_in_sync): merged_logits.append(logits[i].numpy()) merged_labels.append(labels[i].numpy()) merged_masks.append(masks[i].numpy()) merged_logits = np.vstack(np.array(merged_logits)) merged_labels = np.hstack(np.array(merged_labels)) merged_masks = np.hstack(np.array(merged_masks)) real_index = np.where(np.equal(merged_masks, 1)) correct += np.sum( np.equal(np.argmax(merged_logits[real_index], axis=-1), merged_labels[real_index])) total += np.shape(real_index)[-1] accuracy = float(correct) / float(total) logging.info("Train step: %d / acc = %d/%d = %f", step, correct, total, accuracy) if eval_summary_writer: with eval_summary_writer.as_default(): tf.summary.scalar("eval_acc", float(correct) / float(total), step=step) eval_summary_writer.flush() return accuracy
def train( strategy: tf.distribute.Strategy, model_fn: Callable, input_meta_data: Dict, train_input_fn: Callable, total_training_steps: int, steps_per_epoch: int, steps_per_loop: int, optimizer: tf.keras.optimizers.Optimizer, learning_rate_fn: tf.keras.optimizers.schedules.LearningRateSchedule, eval_fn: Optional[Callable[[tf.keras.Model, int, tf.summary.SummaryWriter], Any]] = None, metric_fn: Optional[Callable[[], tf.keras.metrics.Metric]] = None, test_input_fn: Optional[Callable] = None, init_checkpoint: Optional[Text] = None, model_dir: Optional[Text] = None, save_steps: Optional[int] = None, run_eagerly: Optional[bool] = False): """Runs customized training. Args: strategy: Distribution strategy on which to run low level training loop. model_fn: The function returns a keras.Model. input_meta_data: A dictionary of params: `mem_len`, `lr_layer_decay_rate`, `n_layer`, `batch_size_per_core` and `d_model`. train_input_fn: Function returns a tf.data.Dataset used for training. total_training_steps: Number of steps to train in total. steps_per_epoch: Number of steps to run per epoch. At the end of each epoch, model checkpoint will be saved and evaluation will be conducted if evaluation dataset is provided. steps_per_loop: Number of steps per graph-mode loop. In order to reduce communication in eager context, training logs are printed every steps_per_loop. optimizer: The optimizer for model. learning_rate_fn: the learning rate schedule. eval_fn: A callback of evaluation function, that takes a keras.Model, current step and evaluation summary writer. metric_fn: A metrics function returns a Keras Metric object to record evaluation result using evaluation dataset or with training dataset after every epoch. test_input_fn: Function returns a evaluation dataset. If none, evaluation is skipped. init_checkpoint: Optional checkpoint to load to `sub_model` returned by `model_fn`. model_dir: The directory of model (checkpoints, summaries). save_steps: The frequency to save checkpoints. Every save_steps, we save a model checkpoint. run_eagerly: Whether to run training eagerly. Returns: Last training step logits if training happens, otherwise returns None. Raises: TypeError: if model directory is not specified. """ required_arguments = [ train_input_fn, total_training_steps, steps_per_epoch, steps_per_loop, optimizer, learning_rate_fn ] if [arg for arg in required_arguments if arg is None]: raise ValueError("`train_input_fn`, `total_training_steps`, " "`steps_per_epoch`, `steps_per_loop`, `optimizer` and " "`learning_rate_fn` are required parameters.") if not model_dir: raise TypeError("Model directory must be specified.") # pylint: disable=protected-access train_iterator = data_utils._get_input_iterator(train_input_fn, strategy) # pylint: enable=protected-access train_summary_writer = None eval_summary_writer = None if not tf.io.gfile.exists(model_dir): tf.io.gfile.mkdir(model_dir) if test_input_fn: eval_summary_writer = tf.summary.create_file_writer( os.path.join(model_dir, "summaries/eval")) if steps_per_loop >= _MIN_SUMMARY_STEPS: # Only writes summary when the stats are collected sufficiently over # enough steps. train_summary_writer = tf.summary.create_file_writer( os.path.join(model_dir, "summaries/train")) with strategy.scope(): model = model_fn() if init_checkpoint: logging.info("restore from %s", init_checkpoint) checkpoint = tf.train.Checkpoint(model=model) checkpoint.restore(init_checkpoint) model.optimizer = optimizer if not hasattr(model, "optimizer"): raise ValueError("User should set optimizer attribute to model.") train_loss_metric = tf.keras.metrics.Mean("training_loss", dtype=tf.float32) train_metric = None if metric_fn: train_metric = metric_fn() def _replicated_step(inputs, mem=None): """Replicated training step.""" inputs["mems"] = mem with tf.GradientTape() as tape: mem, logits = model(inputs, training=True) loss = model.losses train_loss_metric.update_state(loss) if train_metric: train_metric.update_state(inputs["label_ids"], logits) scaled_loss = loss[0] * 1.0 / float(strategy.num_replicas_in_sync) # Collects training variables. tvars = model.trainable_variables grads = tape.gradient(scaled_loss, tvars) clipped, _ = tf.clip_by_global_norm(grads, clip_norm=1.0) if input_meta_data["lr_layer_decay_rate"] != 1.0: n_layer = 0 for i in range(len(clipped)): m = re.search(r"model/transformer/layer_(\d+?)/", tvars[i].name) if not m: continue n_layer = max(n_layer, int(m.group(1)) + 1) for i in range(len(clipped)): for l in range(n_layer): if "model/transformer/layer_{}/".format(l) in tvars[i].name: abs_rate = input_meta_data["lr_layer_decay_rate"]**( n_layer - 1 - l) clipped[i] *= abs_rate logging.info("Apply mult {:.4f} to layer-{} grad of {}".format( abs_rate, l, tvars[i].name)) break optimizer.apply_gradients(zip(clipped, tvars)) if input_meta_data["mem_len"] > 0: return mem def train_steps(iterator, steps): """Performs distributed training steps in a loop. Args: iterator: the distributed iterator of training datasets. steps: an tf.int32 integer tensor to specify number of steps to run inside host training loop. Raises: ValueError: Any of the arguments or tensor shapes are invalid. Returns: logits: logits computed. """ if not isinstance(steps, tf.Tensor): raise ValueError("steps should be an Tensor. Python object may cause " "retracing.") def cache_fn(): """Initializes memory tensor used in XLNet pretraining.""" mems = [] if input_meta_data["mem_len"] > 0: for _ in range(input_meta_data["n_layer"]): zeros = tf.zeros([ input_meta_data["mem_len"], input_meta_data["batch_size_per_core"], input_meta_data["d_model"] ], dtype=tf.float32) mems.append(zeros) return mems if input_meta_data["mem_len"] > 0: mem = strategy.experimental_run_v2(cache_fn) for _ in tf.range(steps): mem = strategy.experimental_run_v2( _replicated_step, args=( next(iterator), mem, )) else: for _ in tf.range(steps): strategy.experimental_run_v2(_replicated_step, args=(next(iterator),)) if not run_eagerly: train_steps = tf.function(train_steps) logging.info("Start training...") checkpoint = tf.train.Checkpoint(model=model, optimizer=optimizer) latest_checkpoint_file = tf.train.latest_checkpoint(model_dir) if latest_checkpoint_file: logging.info("Checkpoint file %s found and restoring from checkpoint", latest_checkpoint_file) checkpoint.restore(latest_checkpoint_file) logging.info("Loading from checkpoint file completed") current_step = optimizer.iterations.numpy() checkpoint_name = "xlnet_step_{step}.ckpt" while current_step < total_training_steps: train_loss_metric.reset_states() if train_metric: train_metric.reset_states() steps = _steps_to_run(current_step, steps_per_epoch, steps_per_loop) train_steps(train_iterator, tf.convert_to_tensor(steps, dtype=tf.int32)) current_step += steps train_loss = _float_metric_value(train_loss_metric) log_stream = "Train step: %d/%d / lr = %.9f / loss = %.7f" % ( current_step, total_training_steps, learning_rate_fn(current_step), train_loss) if train_metric: log_stream += " / %s = %f" % (train_metric.name, _float_metric_value(train_metric)) logging.info(log_stream) if train_summary_writer: with train_summary_writer.as_default(): tf.summary.scalar( "learning_rate", learning_rate_fn(current_step), step=current_step) tf.summary.scalar( train_loss_metric.name, train_loss, step=current_step) if train_metric: tf.summary.scalar( train_metric.name, _float_metric_value(train_metric), step=current_step) train_summary_writer.flush() if model_dir: if (save_steps is None) or (save_steps and current_step % save_steps == 0): _save_checkpoint(checkpoint, model_dir, checkpoint_name.format(step=current_step)) if test_input_fn and current_step % steps_per_epoch == 0: logging.info("Running evaluation after step: %s.", current_step) eval_fn(model, current_step, eval_summary_writer) if model_dir: _save_checkpoint(checkpoint, model_dir, checkpoint_name.format(step=current_step)) if test_input_fn: logging.info("Running final evaluation after training is complete.") eval_fn(model, current_step, eval_summary_writer) return model