the-algorithm-ml/core/custom_training_loop.py

"""Torch and torchrec specific training and evaluation loops.

Features (go/100_enablements):
    - CUDA data-fetch, compute, gradient-push overlap
    - Large learnable embeddings through torchrec
    - On/off-chief evaluation
    - Warmstart/checkpoint management
    - go/dataset-service 0-copy integration

"""
import datetime
import os
from typing import Callable, Dict, Iterable, List, Mapping, Optional


from tml.common import log_weights
import tml.common.checkpointing.snapshot as snapshot_lib
from tml.core.losses import get_global_loss_detached
from tml.ml_logging.torch_logging import logging  # type: ignore[attr-defined]
from tml.core.train_pipeline import TrainPipelineSparseDist

import tree
import torch
import torch.distributed as dist
from torch.optim.lr_scheduler import _LRScheduler
import torchmetrics as tm


def get_new_iterator(iterable: Iterable):
  """
  This obtain a new iterator from the iterable. If the iterable uses tf.data.Dataset internally,
   getting a new iterator each N steps will avoid memory leak. To avoid the memory leak
   calling iter(iterable) should return a "fresh" iterator using a fresh
   (new instance of) tf.data.Iterator.
   In particular, iterable can be a torch.utils.data.IterableDataset or a
   torch.utils.data.DataLoader.

  When using DDS, performing this reset does not change the order in which elements are received
   (excluding elements already prefetched) provided that iter(iterable) internally uses
   a new instance of tf.data.Dataset created by calling from_dataset_id.
   This requirement is satisfied by RecapDataset.
  :param iterable:
  :return:
  """
  return iter(iterable)


def _get_step_fn(pipeline, data_iterator, training: bool):
  def step_fn():
    # It turns out that model.train() and model.eval() simply switch a single field inside the model
    # class,so it's somewhat safer to wrap in here.
    if training:
      pipeline._model.train()
    else:
      pipeline._model.eval()

    outputs = pipeline.progress(data_iterator)
    return tree.map_structure(lambda elem: elem.detach(), outputs)

  return step_fn


@torch.no_grad()
def _run_evaluation(
  pipeline,
  dataset,
  eval_steps: int,
  metrics: tm.MetricCollection,
  eval_batch_size: int,
  logger=None,
):
  """Runs the evaluation loop over all evaluation iterators."""
  dataset = get_new_iterator(dataset)
  step_fn = _get_step_fn(pipeline, dataset, training=False)
  last_time = datetime.datetime.now()
  logging.info(f"Starting {eval_steps} steps of evaluation.")
  for _ in range(eval_steps):
    outputs = step_fn()
    metrics.update(outputs)
  eval_ex_per_s = (
    eval_batch_size * eval_steps / (datetime.datetime.now() - last_time).total_seconds()
  )
  logging.info(f"eval examples_per_s : {eval_ex_per_s}")
  metrics_result = metrics.compute()
  # Resetting at end to release metrics memory not in use.
  # Reset metrics to prevent accumulation between multiple evaluation splits and not report a
  # running average.
  metrics.reset()
  return metrics_result


def train(
  model: torch.nn.Module,
  optimizer: torch.optim.Optimizer,
  device: str,
  save_dir: str,
  logging_interval: int,
  train_steps: int,
  checkpoint_frequency: int,
  dataset: Iterable,
  worker_batch_size: int,
  num_workers: Optional[int] = 0,
  enable_amp: bool = False,
  initial_checkpoint_dir: Optional[str] = None,
  gradient_accumulation: Optional[int] = None,
  logger_initializer: Optional[Callable] = None,
  scheduler: _LRScheduler = None,
  metrics: Optional[tm.MetricCollection] = None,
  parameters_to_log: Optional[Dict[str, Callable]] = None,
  tables_to_log: Optional[List[str]] = None,
) -> None:
  """Runs training and eval on the given TrainPipeline

  Args:
    dataset: data iterator for the training set
    evaluation_iterators: data iterators for the different evaluation sets
    scheduler: optional learning rate scheduler
    output_transform_for_metrics: optional transformation functions to transorm the model
                                  output and labels into a format the metrics can understand
  """

  train_pipeline = TrainPipelineSparseDist(
    model=model,
    optimizer=optimizer,
    device=device,
    enable_amp=enable_amp,
    grad_accum=gradient_accumulation,
  )  # type: ignore[var-annotated]

  # We explicitly initialize optimizer state here so that checkpoint will work properly.
  if hasattr(train_pipeline._optimizer, "init_state"):
    train_pipeline._optimizer.init_state()

  save_state = {
    "model": train_pipeline._model,
    "optimizer": train_pipeline._optimizer,
    "scaler": train_pipeline._grad_scaler,
  }

  chosen_checkpoint = None
  checkpoint_handler = snapshot_lib.Snapshot(
    save_dir=save_dir,
    state=save_state,
  )

  if save_dir:
    chosen_checkpoint = snapshot_lib.get_checkpoint(save_dir=save_dir, missing_ok=True)

  start_step = 0
  start_walltime = 0.0
  if chosen_checkpoint:
    # Skip restoration and exit if we should be finished.
    chosen_checkpoint_global_step = snapshot_lib.step_from_checkpoint(chosen_checkpoint)
    if not chosen_checkpoint_global_step < dist.get_world_size() * train_steps:
      logging.info(
        "Not restoring and finishing training as latest checkpoint "
        f"{chosen_checkpoint} found "
        f"at global_step ({chosen_checkpoint_global_step}) >= "
        f"train_steps ({dist.get_world_size() * train_steps})"
      )
      return
    logging.info(f"Restoring latest checkpoint from global_step {chosen_checkpoint_global_step}")
    checkpoint_handler.restore(chosen_checkpoint)
    start_step = checkpoint_handler.step
    start_walltime = checkpoint_handler.walltime
  elif initial_checkpoint_dir:
    base, ckpt_step = os.path.split(initial_checkpoint_dir)
    warmstart_handler = snapshot_lib.Snapshot(
      save_dir=base,
      state=save_state,
    )
    ckpt = snapshot_lib.get_checkpoint(save_dir=base, missing_ok=False, global_step=int(ckpt_step))
    logging.info(
      f"Restoring from initial_checkpoint_dir: {initial_checkpoint_dir}, but keeping starting step as 0."
    )
    warmstart_handler.restore(ckpt)

  train_logger = logger_initializer(mode="train") if logger_initializer else None
  train_step_fn = _get_step_fn(train_pipeline, get_new_iterator(dataset), training=True)

  # Counting number of parameters in the model directly when creating it.
  nb_param = 0
  for p in model.parameters():
    nb_param += p.numel()
  logging.info(f"Model has {nb_param} parameters")

  last_time = datetime.datetime.now()
  start_time = last_time
  last_pending_snapshot = None
  for step in range(start_step, train_steps + 1):
    checkpoint_handler.step = step
    outputs = train_step_fn()
    step_done_time = datetime.datetime.now()
    checkpoint_handler.walltime = (step_done_time - start_time).total_seconds() + start_walltime

    if scheduler:
      scheduler.step()

    if step % logging_interval == 0:
      interval_time = (step_done_time - last_time).total_seconds()
      steps_per_s = logging_interval / interval_time
      worker_example_per_s = steps_per_s * worker_batch_size
      global_example_per_s = worker_example_per_s * (1 + (num_workers or 0))
      global_step = step

      log_values = {
        "global_step": global_step,
        "loss": get_global_loss_detached(outputs["loss"]),
        "steps_per_s": steps_per_s,
        "global_example_per_s": global_example_per_s,
        "worker_examples_per_s": worker_example_per_s,
        "active_training_walltime": checkpoint_handler.walltime,
      }
      if parameters_to_log:
        log_values.update(
          log_weights.weights_to_log(
            model=model,
            how_to_log=parameters_to_log,
          )
        )
      log_values = tree.map_structure(lambda elem: torch.as_tensor(elem).cpu(), log_values)

      if tables_to_log:
        log_values.update(
          log_weights.log_ebc_norms(
            model_state_dict=train_pipeline._model.state_dict(),
            ebc_keys=tables_to_log,
          )
        )
      if train_logger:
        train_logger.log(log_values, step=global_step)
      log_line = ", ".join(f"{name}: {value}" for name, value in log_values.items())
      logging.info(f"Step: {step}, training. {log_line}")
      last_time = step_done_time

      # If we just restored, do not save again.
      if checkpoint_frequency and step > start_step and step % checkpoint_frequency == 0:
        if last_pending_snapshot and not last_pending_snapshot.done():
          logging.warning(
            "Begin a new snapshot and the last one hasn't finished. That probably indicates "
            "either you're snapshotting really often or something is wrong. Will now block and "
            "wait for snapshot to finish before beginning the next one."
          )
          last_pending_snapshot.wait()
        last_pending_snapshot = checkpoint_handler.save(global_step=step * dist.get_world_size())

  # Save if we did not just save.
  if checkpoint_frequency and step % checkpoint_frequency != 0:
    # For the final save, wait for the checkpoint to write to make sure the process doesn't finish
    # before its completed.
    last_pending_snapshot = checkpoint_handler.save(global_step=step * dist.get_world_size())
  logging.info(f"Finished training steps: {step}, global_steps: {step * dist.get_world_size()}")

  if last_pending_snapshot:
    logging.info(f"Waiting for any checkpoints to finish.")
    last_pending_snapshot.wait()


def log_eval_results(
  results,
  eval_logger,
  partition_name: str,
  step: int,
):
  results = tree.map_structure(lambda elem: torch.as_tensor(elem).cpu(), results)
  logging.info(f"Step: {step}, evaluation ({partition_name}).")
  for metric_name, metric_value in results.items():
    logging.info(f"\t{metric_name}: {metric_value:1.4e}")

  if eval_logger:
    eval_logger.log(results, step=step, commit=True)


def only_evaluate(
  model: torch.nn.Module,
  optimizer: torch.optim.Optimizer,
  device: str,
  save_dir: str,
  num_train_steps: int,
  dataset: Iterable,
  eval_batch_size: int,
  num_eval_steps: int,
  eval_timeout_in_s: int,
  eval_logger: Callable,
  partition_name: str,
  metrics: Optional[tm.MetricCollection] = None,
):
  logging.info(f"Evaluating on partition {partition_name}.")
  logging.info("Computing metrics:")
  logging.info(metrics)
  eval_pipeline = TrainPipelineSparseDist(model, optimizer, device)  # type: ignore[var-annotated]
  save_state = {
    "model": eval_pipeline._model,
    "optimizer": eval_pipeline._optimizer,
  }
  checkpoint_handler = snapshot_lib.Snapshot(
    save_dir=save_dir,
    state=save_state,
  )
  for checkpoint_path in snapshot_lib.checkpoints_iterator(save_dir, timeout=eval_timeout_in_s):
    checkpoint_handler.restore(checkpoint_path)
    step = checkpoint_handler.step
    dataset = get_new_iterator(dataset)
    results = _run_evaluation(
      pipeline=eval_pipeline,
      dataset=dataset,
      eval_steps=num_eval_steps,
      eval_batch_size=eval_batch_size,
      metrics=metrics,
    )
    log_eval_results(results, eval_logger, partition_name, step=step)
    rank = dist.get_rank() if dist.is_initialized() else 0
    if rank == 0:
      snapshot_lib.mark_done_eval(checkpoint_path, partition_name)
    if step >= num_train_steps:
      return
Twitter's Recommendation Algorithm - Heavy Ranker and TwHIN embeddings 2023-03-31 20:05:14 +02:00			`"""Torch and torchrec specific training and evaluation loops.`

			`Features (go/100_enablements):`
			`- CUDA data-fetch, compute, gradient-push overlap`
			`- Large learnable embeddings through torchrec`
			`- On/off-chief evaluation`
			`- Warmstart/checkpoint management`
			`- go/dataset-service 0-copy integration`

			`"""`
			`import datetime`
			`import os`
			`from typing import Callable, Dict, Iterable, List, Mapping, Optional`


			`from tml.common import log_weights`
			`import tml.common.checkpointing.snapshot as snapshot_lib`
			`from tml.core.losses import get_global_loss_detached`
			`from tml.ml_logging.torch_logging import logging # type: ignore[attr-defined]`
			`from tml.core.train_pipeline import TrainPipelineSparseDist`

			`import tree`
			`import torch`
			`import torch.distributed as dist`
			`from torch.optim.lr_scheduler import _LRScheduler`
			`import torchmetrics as tm`


			`def get_new_iterator(iterable: Iterable):`
			`"""`
			`This obtain a new iterator from the iterable. If the iterable uses tf.data.Dataset internally,`
			`getting a new iterator each N steps will avoid memory leak. To avoid the memory leak`
			`calling iter(iterable) should return a "fresh" iterator using a fresh`
			`(new instance of) tf.data.Iterator.`
			`In particular, iterable can be a torch.utils.data.IterableDataset or a`
			`torch.utils.data.DataLoader.`

			`When using DDS, performing this reset does not change the order in which elements are received`
			`(excluding elements already prefetched) provided that iter(iterable) internally uses`
			`a new instance of tf.data.Dataset created by calling from_dataset_id.`
			`This requirement is satisfied by RecapDataset.`
			`:param iterable:`
			`:return:`
			`"""`
			`return iter(iterable)`


			`def _get_step_fn(pipeline, data_iterator, training: bool):`
			`def step_fn():`
			`# It turns out that model.train() and model.eval() simply switch a single field inside the model`
			`# class,so it's somewhat safer to wrap in here.`
			`if training:`
			`pipeline._model.train()`
			`else:`
			`pipeline._model.eval()`

			`outputs = pipeline.progress(data_iterator)`
			`return tree.map_structure(lambda elem: elem.detach(), outputs)`

			`return step_fn`


			`@torch.no_grad()`
			`def _run_evaluation(`
			`pipeline,`
			`dataset,`
			`eval_steps: int,`
			`metrics: tm.MetricCollection,`
			`eval_batch_size: int,`
			`logger=None,`
			`):`
			`"""Runs the evaluation loop over all evaluation iterators."""`
			`dataset = get_new_iterator(dataset)`
			`step_fn = _get_step_fn(pipeline, dataset, training=False)`
			`last_time = datetime.datetime.now()`
			`logging.info(f"Starting {eval_steps} steps of evaluation.")`
			`for _ in range(eval_steps):`
			`outputs = step_fn()`
			`metrics.update(outputs)`
			`eval_ex_per_s = (`
			`eval_batch_size * eval_steps / (datetime.datetime.now() - last_time).total_seconds()`
			`)`
			`logging.info(f"eval examples_per_s : {eval_ex_per_s}")`
			`metrics_result = metrics.compute()`
			`# Resetting at end to release metrics memory not in use.`
			`# Reset metrics to prevent accumulation between multiple evaluation splits and not report a`
			`# running average.`
			`metrics.reset()`
			`return metrics_result`


			`def train(`
			`model: torch.nn.Module,`
			`optimizer: torch.optim.Optimizer,`
			`device: str,`
			`save_dir: str,`
			`logging_interval: int,`
			`train_steps: int,`
			`checkpoint_frequency: int,`
			`dataset: Iterable,`
			`worker_batch_size: int,`
			`num_workers: Optional[int] = 0,`
			`enable_amp: bool = False,`
			`initial_checkpoint_dir: Optional[str] = None,`
			`gradient_accumulation: Optional[int] = None,`
			`logger_initializer: Optional[Callable] = None,`
			`scheduler: _LRScheduler = None,`
			`metrics: Optional[tm.MetricCollection] = None,`
			`parameters_to_log: Optional[Dict[str, Callable]] = None,`
			`tables_to_log: Optional[List[str]] = None,`
			`) -> None:`
			`"""Runs training and eval on the given TrainPipeline`

			`Args:`
			`dataset: data iterator for the training set`
			`evaluation_iterators: data iterators for the different evaluation sets`
			`scheduler: optional learning rate scheduler`
			`output_transform_for_metrics: optional transformation functions to transorm the model`
			`output and labels into a format the metrics can understand`
			`"""`

			`train_pipeline = TrainPipelineSparseDist(`
			`model=model,`
			`optimizer=optimizer,`
			`device=device,`
			`enable_amp=enable_amp,`
			`grad_accum=gradient_accumulation,`
			`) # type: ignore[var-annotated]`

			`# We explicitly initialize optimizer state here so that checkpoint will work properly.`
			`if hasattr(train_pipeline._optimizer, "init_state"):`
			`train_pipeline._optimizer.init_state()`

			`save_state = {`
			`"model": train_pipeline._model,`
			`"optimizer": train_pipeline._optimizer,`
			`"scaler": train_pipeline._grad_scaler,`
			`}`

			`chosen_checkpoint = None`
			`checkpoint_handler = snapshot_lib.Snapshot(`
			`save_dir=save_dir,`
			`state=save_state,`
			`)`

			`if save_dir:`
			`chosen_checkpoint = snapshot_lib.get_checkpoint(save_dir=save_dir, missing_ok=True)`

			`start_step = 0`
			`start_walltime = 0.0`
			`if chosen_checkpoint:`
			`# Skip restoration and exit if we should be finished.`
			`chosen_checkpoint_global_step = snapshot_lib.step_from_checkpoint(chosen_checkpoint)`
			`if not chosen_checkpoint_global_step < dist.get_world_size() * train_steps:`
			`logging.info(`
			`"Not restoring and finishing training as latest checkpoint "`
			`f"{chosen_checkpoint} found "`
			`f"at global_step ({chosen_checkpoint_global_step}) >= "`
			`f"train_steps ({dist.get_world_size() * train_steps})"`
			`)`
			`return`
			`logging.info(f"Restoring latest checkpoint from global_step {chosen_checkpoint_global_step}")`
			`checkpoint_handler.restore(chosen_checkpoint)`
			`start_step = checkpoint_handler.step`
			`start_walltime = checkpoint_handler.walltime`
			`elif initial_checkpoint_dir:`
			`base, ckpt_step = os.path.split(initial_checkpoint_dir)`
			`warmstart_handler = snapshot_lib.Snapshot(`
			`save_dir=base,`
			`state=save_state,`
			`)`
			`ckpt = snapshot_lib.get_checkpoint(save_dir=base, missing_ok=False, global_step=int(ckpt_step))`
			`logging.info(`
			`f"Restoring from initial_checkpoint_dir: {initial_checkpoint_dir}, but keeping starting step as 0."`
			`)`
			`warmstart_handler.restore(ckpt)`

			`train_logger = logger_initializer(mode="train") if logger_initializer else None`
			`train_step_fn = _get_step_fn(train_pipeline, get_new_iterator(dataset), training=True)`

			`# Counting number of parameters in the model directly when creating it.`
			`nb_param = 0`
			`for p in model.parameters():`
			`nb_param += p.numel()`
			`logging.info(f"Model has {nb_param} parameters")`

			`last_time = datetime.datetime.now()`
			`start_time = last_time`
			`last_pending_snapshot = None`
			`for step in range(start_step, train_steps + 1):`
			`checkpoint_handler.step = step`
			`outputs = train_step_fn()`
			`step_done_time = datetime.datetime.now()`
			`checkpoint_handler.walltime = (step_done_time - start_time).total_seconds() + start_walltime`

			`if scheduler:`
			`scheduler.step()`

			`if step % logging_interval == 0:`
			`interval_time = (step_done_time - last_time).total_seconds()`
			`steps_per_s = logging_interval / interval_time`
			`worker_example_per_s = steps_per_s * worker_batch_size`
			`global_example_per_s = worker_example_per_s * (1 + (num_workers or 0))`
			`global_step = step`

			`log_values = {`
			`"global_step": global_step,`
			`"loss": get_global_loss_detached(outputs["loss"]),`
			`"steps_per_s": steps_per_s,`
			`"global_example_per_s": global_example_per_s,`
			`"worker_examples_per_s": worker_example_per_s,`
			`"active_training_walltime": checkpoint_handler.walltime,`
			`}`
			`if parameters_to_log:`
			`log_values.update(`
			`log_weights.weights_to_log(`
			`model=model,`
			`how_to_log=parameters_to_log,`
			`)`
			`)`
			`log_values = tree.map_structure(lambda elem: torch.as_tensor(elem).cpu(), log_values)`

			`if tables_to_log:`
			`log_values.update(`
			`log_weights.log_ebc_norms(`
			`model_state_dict=train_pipeline._model.state_dict(),`
			`ebc_keys=tables_to_log,`
			`)`
			`)`
			`if train_logger:`
			`train_logger.log(log_values, step=global_step)`
			`log_line = ", ".join(f"{name}: {value}" for name, value in log_values.items())`
			`logging.info(f"Step: {step}, training. {log_line}")`
			`last_time = step_done_time`

			`# If we just restored, do not save again.`
			`if checkpoint_frequency and step > start_step and step % checkpoint_frequency == 0:`
			`if last_pending_snapshot and not last_pending_snapshot.done():`
			`logging.warning(`
			`"Begin a new snapshot and the last one hasn't finished. That probably indicates "`
			`"either you're snapshotting really often or something is wrong. Will now block and "`
			`"wait for snapshot to finish before beginning the next one."`
			`)`
			`last_pending_snapshot.wait()`
			`last_pending_snapshot = checkpoint_handler.save(global_step=step * dist.get_world_size())`

			`# Save if we did not just save.`
			`if checkpoint_frequency and step % checkpoint_frequency != 0:`
			`# For the final save, wait for the checkpoint to write to make sure the process doesn't finish`
			`# before its completed.`
			`last_pending_snapshot = checkpoint_handler.save(global_step=step * dist.get_world_size())`
			`logging.info(f"Finished training steps: {step}, global_steps: {step * dist.get_world_size()}")`

			`if last_pending_snapshot:`
			`logging.info(f"Waiting for any checkpoints to finish.")`
			`last_pending_snapshot.wait()`


			`def log_eval_results(`
			`results,`
			`eval_logger,`
			`partition_name: str,`
			`step: int,`
			`):`
			`results = tree.map_structure(lambda elem: torch.as_tensor(elem).cpu(), results)`
			`logging.info(f"Step: {step}, evaluation ({partition_name}).")`
			`for metric_name, metric_value in results.items():`
			`logging.info(f"\t{metric_name}: {metric_value:1.4e}")`

			`if eval_logger:`
			`eval_logger.log(results, step=step, commit=True)`


			`def only_evaluate(`
			`model: torch.nn.Module,`
			`optimizer: torch.optim.Optimizer,`
			`device: str,`
			`save_dir: str,`
			`num_train_steps: int,`
			`dataset: Iterable,`
			`eval_batch_size: int,`
			`num_eval_steps: int,`
			`eval_timeout_in_s: int,`
			`eval_logger: Callable,`
			`partition_name: str,`
			`metrics: Optional[tm.MetricCollection] = None,`
			`):`
			`logging.info(f"Evaluating on partition {partition_name}.")`
			`logging.info("Computing metrics:")`
			`logging.info(metrics)`
			`eval_pipeline = TrainPipelineSparseDist(model, optimizer, device) # type: ignore[var-annotated]`
			`save_state = {`
			`"model": eval_pipeline._model,`
			`"optimizer": eval_pipeline._optimizer,`
			`}`
			`checkpoint_handler = snapshot_lib.Snapshot(`
			`save_dir=save_dir,`
			`state=save_state,`
			`)`
			`for checkpoint_path in snapshot_lib.checkpoints_iterator(save_dir, timeout=eval_timeout_in_s):`
			`checkpoint_handler.restore(checkpoint_path)`
			`step = checkpoint_handler.step`
			`dataset = get_new_iterator(dataset)`
			`results = _run_evaluation(`
			`pipeline=eval_pipeline,`
			`dataset=dataset,`
			`eval_steps=num_eval_steps,`
			`eval_batch_size=eval_batch_size,`
			`metrics=metrics,`
			`)`
			`log_eval_results(results, eval_logger, partition_name, step=step)`
			`rank = dist.get_rank() if dist.is_initialized() else 0`
			`if rank == 0:`
			`snapshot_lib.mark_done_eval(checkpoint_path, partition_name)`
			`if step >= num_train_steps:`
			`return`