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qat_distributed.py
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qat_distributed.py
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# Copyright (c) Meta Platforms, Inc. and affiliates.
# All rights reserved.
#
# This source code is licensed under the BSD-style license found in the
# LICENSE file in the root directory of this source tree.
import os
import sys
import time
from functools import partial
from typing import Any, Dict, List, Optional, Tuple, Union
from warnings import warn
import torch
from omegaconf import DictConfig, ListConfig
from torch import nn
from torch.distributed import destroy_process_group, init_process_group
from torch.optim import Optimizer
from torch.utils.data import DataLoader, DistributedSampler
from torchtune import config, modules, training, utils
from torchtune.data import padded_collate_packed, padded_collate_sft
from torchtune.datasets import ConcatDataset
from torchtune.recipe_interfaces import FTRecipeInterface
from torchtune.training import DummyProfiler, PROFILER_KEY
from torchtune.training.activations import apply_selective_activation_checkpointing
from tqdm import tqdm
log = utils.get_logger("DEBUG")
class QATRecipeDistributed(FTRecipeInterface):
"""
Quantization-aware training (QAT) recipe for dense transformer-based LLMs such as Llama2.
This recipe supports distributed training and can be run on a single node (1 to 8 GPUs).
Only compatible with PyTorch 2.4+.
Features:
- Quantization-aware training (QAT). Perform fake quantization on weights and/or activations
during finetuning, with the goal of ultimately producing a quantized model with minimal
accuracy degradation. This recipe produces an unquantized model in the original dtype,
which can then be quantized separately.
- Delayed fake quantization. Optionally specify the step after which fake quantization occurs.
Empirically, allowing the model to finetune without fake quantization initially allows the
weight and activation values to stabilize before fake quantizing them, potentially leading
to improved quantized accuracy. This can be specified through ``fake_quant_after_n_steps``.
- FSDP. Supported using PyTorch's FSDP APIs. CPU offload of parameters, gradients, and optimizer states
is supported via the ``fsdp_cpu_offload``. Resharding of parameters after the forward pass is
done by default (corresponding to FULL_SHARD sharding strategy), but can be disabled by setting the config
``fsdp_reshard_after_forward`` to False (this corresponds to SHARD_GRAD_OP sharding strategy).
DDP is currently not supported. Training on CPU is not supported.
- Activation Checkpointing. This can be controlled using the ``enable_activation_checkpointing``
flag. Activation checkpointing helps reduce the memory footprint since we no longer keep
activations in memory and instead recompute them during the backward pass. This is especially
helpful for larger batch sizes when you're memory constrained. But these savings in memory
come at the cost of training performance. In most cases training can slow-down quite a bit as
a result of this activation recomputation.
- Precision. Full fp32 and bf16 training are supported. Precision is controlled using the ``dtype``
flag. When ``dtype=bf16``, all activations, gradients and optimizer states are in bfloat16. In
most cases this should halve the memory footprint of full precision (fp32) training, without
loss in model quality (will depend on the model, training data and other settings). For
GPUs which do not support bfloat16, we fall back to fp32. Mixed precision training and fp16
precision are currently not supported.
- Gradient Accumulation. You can simulate larger batch sizes by accumulating gradients. This is
controlled using the ``gradient_accumulation_steps`` flag.
Total Batch Size = batch_size * number of GPUs * gradient accumulation steps.
For example: with batch_size=1, nproc_per_node=2 and gradient_accumulation_steps=32 we get a
total batch size of 64.
Gradient accumulation is especially useful when you are memory constrained. In this case,
accumulating gradients might give you better training speed than enabling activation
checkpointing.
- Checkpointing. Model weights are checkpointed both at the end of each epoch and at the end of
training. Optimizer state and recipe state (seed, total_epochs, number of epochs run etc) are
only saved at the end of a given epoch and used in case of resuming training.
Resuming training is controlled by the ``resume_from_checkpoint`` flag. Mid-epoch checkpointing is
currently not supported.
For more details on the checkpointer, please take a look at
our checkpointer deepdive (https://pytorch.org/torchtune/main/deep_dives/checkpointer.html).
- Logging. Terminal, Disk, WandB and TensorBoard are all supported.
For a full list of example configs for this recipe, run ``tune ls`` on the command line. Each config
has example commands for how to kick-off training.
Args:
cfg (DictConfig): OmegaConf object parsed from yaml file
Raises:
ValueError: If ``dtype`` is set to fp16.
RuntimeError: If ``dtype`` is set to bf16 and the hardware does not support bf16.
"""
def __init__(self, cfg: DictConfig) -> None:
self._device = utils.get_device(device=cfg.device)
self._dtype = training.get_dtype(cfg.dtype, device=self._device)
if self._dtype == torch.float16:
raise ValueError(
"full fp16 training is not supported with this recipe. Please use bf16 or fp32 instead."
)
if (
cfg.get("fsdp_cpu_offload", False)
and cfg.optimizer.get("fused", False)
and not utils.torch_version_ge("2.4.0")
):
raise RuntimeError(
"Using fused optimizer on CPU is only supported in PyTorch nightly."
)
# logging attributes
self._output_dir = cfg.output_dir
self._log_every_n_steps = cfg.get("log_every_n_steps", 1)
self._log_peak_memory_stats = cfg.get("log_peak_memory_stats", False)
if self._log_peak_memory_stats and self._device.type != "cuda":
log.info(
"log_peak_memory_stats was set to True, however, training does not use cuda. Setting log_peak_memory_stats=False."
)
self._log_peak_memory_stats = False
# _is_rank_zero is used primarily for logging. In the future, the logger
# should directly take care of this
_, rank = training.get_world_size_and_rank()
self._is_rank_zero = rank == 0
# Training cfg
self._resume_from_checkpoint = cfg.resume_from_checkpoint
self._gradient_accumulation_steps = cfg.gradient_accumulation_steps
self._fsdp_sharding_strategy = torch.distributed.fsdp.ShardingStrategy[
cfg.get("fsdp_sharding_strategy", "FULL_SHARD")
]
self._fake_quant_after_n_steps = cfg.get("fake_quant_after_n_steps", None)
self._quantizer_mode = None
# These are public properties which are updated by the checkpoint loader
# when ``resume_from_checkpoint`` is `True` or validated in tests
self.seed = training.set_seed(seed=cfg.seed)
self.epochs_run = 0
self.total_epochs = cfg.epochs
self.max_steps_per_epoch = cfg.max_steps_per_epoch
self.global_step = 0
def load_checkpoint(self, cfg_checkpointer: DictConfig) -> Dict[str, Any]:
"""
Extract the checkpoint state from file and validate. If resume_from_checkpoint
is True, this also includes the recipe state.
"""
self._checkpointer = config.instantiate(
cfg_checkpointer,
resume_from_checkpoint=self._resume_from_checkpoint,
)
checkpoint_dict = self._checkpointer.load_checkpoint()
if self._resume_from_checkpoint:
self._update_recipe_state(checkpoint_dict)
return checkpoint_dict
def _update_recipe_state(self, ckpt_dict: Dict[str, Any]) -> None:
"""
Updates the recipe state from checkpoint.
"""
try:
self.epochs_run = ckpt_dict[training.EPOCHS_KEY]
# on mismatch, warn the user and prevent the override
if self.seed != ckpt_dict[training.SEED_KEY]:
warn(
message=(
"Config value for seed does not match the checkpoint value, "
f"using the checkpoint value: {ckpt_dict[training.SEED_KEY]}"
)
)
self.seed = ckpt_dict[training.SEED_KEY]
if self.max_steps_per_epoch != ckpt_dict[training.MAX_STEPS_KEY]:
warn(
message=(
"Config value for max_steps_per_epoch does not match the checkpoint value, "
f"using the checkpoint value: {ckpt_dict[training.MAX_STEPS_KEY]}"
)
)
self.max_steps_per_epoch = ckpt_dict[training.MAX_STEPS_KEY]
# on mismatch, warn the user but allow the override
if self.total_epochs != ckpt_dict[training.TOTAL_EPOCHS_KEY]:
warn(
message=(
"Config value for total_epochs does not match the checkpoint value, "
f"using the config value: {self.total_epochs}"
)
)
except KeyError as e:
raise KeyError(
"Checkpoint does not contain the required keys needed for updating recipe state. "
"Are you sure you passed in the right recipe checkpoint?"
) from e
def setup(self, cfg: DictConfig) -> None:
"""
Setup the recipe. This includes training state (if resume_from_checkpoint is True),
model, tokenizer, loss, optimizer, sampler, and dataloader.
"""
if self._is_rank_zero:
self._metric_logger = config.instantiate(cfg.metric_logger)
# log config with parameter override
self._metric_logger.log_config(cfg)
checkpoint_dict = self.load_checkpoint(cfg_checkpointer=cfg.checkpointer)
self._model_compile = cfg.get("compile", False)
self._model = self._setup_model(
cfg_model=cfg.model,
enable_activation_checkpointing=cfg.enable_activation_checkpointing,
custom_sharded_layers=cfg.get("custom_sharded_layers", None),
fsdp_cpu_offload=cfg.get("fsdp_cpu_offload", False),
reshard_after_forward=cfg.get("fsdp_reshard_after_forward", True),
model_state_dict=checkpoint_dict[training.MODEL_KEY],
ac_mode=cfg.get("ac_mode", None),
ac_option=cfg.get("ac_option", None),
quantizer_cfg=cfg.get("quantizer", None),
)
self._tokenizer = config.instantiate(cfg.tokenizer)
self._optimizer = self._setup_optimizer(
cfg_optimizer=cfg.optimizer,
opt_state_dict=(
checkpoint_dict[training.OPT_KEY]
if self._resume_from_checkpoint
else None
),
)
# initialize loss
self._loss_fn = config.instantiate(cfg.loss)
backend = os.environ.get("TORCH_COMPILE_BACKEND", "inductor")
if self._loss_fn.__class__.__name__ == "CEWithChunkedOutputLoss":
# set num_output_chunks for model
self._model.set_num_output_chunks(self._loss_fn.num_output_chunks)
if self._model_compile:
log.info("Compiling loss with torch.compile...")
# For CEWithChunkedOutputLoss, if we compile the entire class
# we lose the benefits from the chunked loss.
# Therefore, we only compile the cross entropy function + upcasting
self._loss_fn.compute_cross_entropy = torch.compile(
self._loss_fn.compute_cross_entropy, backend=backend
)
else:
if self._model_compile:
log.info("Compiling loss with torch.compile...")
self._loss_fn = torch.compile(self._loss_fn, backend=backend)
log.info("Loss is initialized.")
# sampler and dataloader depend on the tokenizer and loss_fn and should be
# setup after both of these are initialized
self._sampler, self._dataloader = self._setup_data(
cfg_dataset=cfg.dataset,
shuffle=cfg.shuffle,
batch_size=cfg.batch_size,
)
# Finally update the recipe state which can only be correctly set after all of the
# other components have been initialized and updated.
#
# Number of training steps in each epoch depends on the number of batches produced
# by the dataloader, the max_steps_per_epoch param set by the user and the
# gradient_accumulation_steps param. This value is used for logging and tracking
# training state. The computation should happen after the dataloader has been setup
self._steps_per_epoch = (
len(self._dataloader) // self._gradient_accumulation_steps
)
if (
self.max_steps_per_epoch is not None
and self.max_steps_per_epoch < self._steps_per_epoch
):
self._steps_per_epoch = self.max_steps_per_epoch
self.global_step = self.epochs_run * self._steps_per_epoch
# Set up profiler, returns DummyProfiler (nullcontext object with no-op `step` method)
# if cfg is missing profiler key or if `cfg.profiler.enabled = False`
self._profiler = self._setup_profiler(cfg.get(PROFILER_KEY, None))
# Used to ignore labels for loss computation
self.ignore_labels_cache = torch.full(
(cfg.batch_size, 1), self._loss_fn.ignore_index, device=self._device
)
def _setup_profiler(
self, cfg_profiler: Optional[DictConfig] = None
) -> Union[torch.profiler.profile, DummyProfiler]:
"""
Parses the `profiler` section of top-level `cfg` and sets up profiler
Args:
cfg_profiler (Optional[DictConfig]): ``profiler`` section of the top-level ``cfg`` (the main config passed to
`recipe.main`). Default None.
Returns:
profiler: Union[torch.profiler.profile, DummyProfiler] - DummyProfiler is a nullcontext with no-op methods
for `start`, `stop`, and `step` that can be used in place of `torch.profiler.profile` if profiler is not enabled such
that the instrumented training loop does not need to be changed profiling is disabled.
The profiler config can be provided in configs under the `profiler` key with the following layout:
.. code-block:: yaml
profiler:
enabled: bool
#Output directory of trace artifacts
output_dir: str
#`torch.profiler.ProfilerActivity` types to trace
cpu: bool
cuda: bool
#Trace options
profile_memory: bool
with_stack: bool
record_shapes: bool
with_flops: bool
# `torch.profiler.schedule` options:
# wait_steps -> wait, warmup_steps -> warmup, active_steps -> active, num_cycles -> repeat
wait_steps: int
warmup_steps: int
active_steps: int
num_cycles: int
"""
# Missing profiler section in config, assume disabled
if cfg_profiler is None:
cfg_profiler = DictConfig({"enabled": False})
# Check that component is included and set correctly
if cfg_profiler.get("_component_", None) is None:
cfg_profiler["_component_"] = "torchtune.training.setup_torch_profiler"
else:
assert (
cfg_profiler.get("_component_")
== "torchtune.training.setup_torch_profiler"
), "Only torch profiler supported currently: component must be `torchtune.training.setup_torch_profiler`"
profiler, profiler_cfg = config.instantiate(cfg_profiler)
if self._is_rank_zero:
log.info(f" Profiler config after instantiation: {profiler_cfg}")
self.profiler_profile_memory = profiler_cfg.get("profile_memory", False)
if profiler_cfg["enabled"]:
self.profiler_wait_steps = profiler_cfg["wait_steps"]
self.profiler_warmup_steps = profiler_cfg["warmup_steps"]
self.profiler_active_steps = profiler_cfg["active_steps"]
return profiler
def _setup_model(
self,
cfg_model: DictConfig,
enable_activation_checkpointing: bool,
fsdp_cpu_offload: bool,
reshard_after_forward: bool,
model_state_dict: Dict[str, Any],
custom_sharded_layers: Optional[List[str]] = None,
ac_mode: Optional[str] = None,
ac_option: Optional[int] = None,
quantizer_cfg: Optional[DictConfig] = None,
) -> nn.Module:
"""
Model initialization has some important considerations:
a. To minimize GPU peak memory, we initialize the model on meta device with
the right dtype
b. All ranks calls ``load_state_dict`` without peaking CPU RAMs since
full state dicts are loaded with ``torch.load(mmap=True)``
"""
if self._is_rank_zero:
log.info(
"FSDP is enabled. Instantiating model and loading checkpoint on Rank 0 ..."
)
init_start = time.perf_counter()
with training.set_default_dtype(self._dtype), torch.device("meta"):
model = config.instantiate(cfg_model)
# We currently have two versions of activation checkpointing in this recipe
# for testing and BC purposes. ``enable_activation_checkpointing`` controls
# the older version of AC and this behavior is unchanged
# ac_mode and ac_option together control selective AC. This is only enabled
# when these are set AND ``enable_activation_checkpointing`` is set to False
# We'll clean this up as soon as testing of AC is complete
if (not enable_activation_checkpointing) and (ac_mode is not None):
apply_selective_activation_checkpointing(
model,
ac_mode,
ac_option,
)
# original activation checkpointing (full) - flip the condition above
if enable_activation_checkpointing and ac_mode is None:
training.set_activation_checkpointing(
model, auto_wrap_policy={modules.TransformerSelfAttentionLayer}
)
# Apply quantization-aware training during finetuning
if quantizer_cfg is None:
raise ValueError("Quantizer must be specified for QAT recipe.")
quantizer = config.instantiate(quantizer_cfg)
quantizer.precision = self._dtype
quantizer_mode = training.quantization.get_quantizer_mode(quantizer)
if "qat" not in quantizer_mode:
raise ValueError(
"Quantizer mode '%s' is not supported for finetuning" % quantizer_mode
)
self._quantizer_mode = quantizer_mode
model = quantizer.prepare(model)
# For FSDP sharding
fsdp_shard_conditions = [
partial(
training.get_shard_conditions,
names_to_match=custom_sharded_layers,
)
]
training.shard_model(
model=model,
shard_conditions=fsdp_shard_conditions,
cpu_offload=fsdp_cpu_offload,
reshard_after_forward=reshard_after_forward,
)
with training.set_default_dtype(self._dtype), self._device:
for m in model.modules():
# RoPE is not covered in state dict
if hasattr(m, "rope_init"):
m.rope_init()
# This method will convert the full model state dict into a sharded state
# dict and load into the model
training.load_from_full_model_state_dict(
model, model_state_dict, self._device, self._is_rank_zero, strict=True
)
# Ensure no params and buffers are on meta device
training.validate_no_params_on_meta_device(model)
if self._is_rank_zero:
log.info(
f"Instantiating model and loading checkpoint took {time.perf_counter() - init_start:.2f} secs"
)
memory_stats = training.get_memory_stats(device=self._device)
training.log_memory_stats(memory_stats)
# synchronize before training begins
torch.distributed.barrier()
return model
def _setup_optimizer(
self, cfg_optimizer: DictConfig, opt_state_dict: Optional[Dict[str, Any]] = None
) -> Optimizer:
optimizer = config.instantiate(cfg_optimizer, self._model.parameters())
if opt_state_dict:
training.load_from_full_optimizer_state_dict(
optimizer,
opt_state_dict,
self._device,
)
if self._is_rank_zero:
log.info("Optimizer is initialized.")
return optimizer
def _setup_data(
self,
cfg_dataset: DictConfig,
shuffle: bool,
batch_size: int,
) -> Tuple[DistributedSampler, DataLoader]:
"""
All data related setup happens here. Currently this recipe only supports the
DistributedSamplers with Map-style Datasets which fit into memory. Other samplers,
iterable datasets and streaming datasets are not supported.
"""
world_size, rank = training.get_world_size_and_rank()
if isinstance(cfg_dataset, ListConfig):
datasets = [
config.instantiate(single_cfg_dataset, tokenizer=self._tokenizer)
for single_cfg_dataset in cfg_dataset
]
ds = ConcatDataset(datasets=datasets)
packed = False
else:
ds = config.instantiate(cfg_dataset, tokenizer=self._tokenizer)
packed = cfg_dataset.get("packed", False)
sampler = DistributedSampler(
ds, num_replicas=world_size, rank=rank, shuffle=shuffle, seed=0
)
dataloader = DataLoader(
dataset=ds,
batch_size=batch_size,
sampler=sampler,
# dropping last avoids shape issues with compile + flex attention
drop_last=True,
collate_fn=(
partial(
padded_collate_sft,
padding_idx=self._tokenizer.pad_id,
ignore_idx=self._loss_fn.ignore_index,
)
if not packed
else partial(
padded_collate_packed,
)
),
)
if self._is_rank_zero:
log.info("Dataset and Sampler are initialized.")
return sampler, dataloader
def save_checkpoint(
self,
epoch: int,
) -> None:
"""
Checkpoint the state of the recipe. The constructed checkpoint state dict
contains the following information:
- Model weights with key training.MODEL_KEY
- Relevant recipe state if training is not complete
Checkpointer will save the model weights and recipe state in
different checkpoint files. To correctly resume training from an intermediate checkpoint,
the model weights and recipe state must be provided.
"""
# final dict passed onto the checkpointer
checkpoint_dict = {}
intermediate_checkpoint = epoch + 1 < self.total_epochs
# To prevent GPU memory from spiking during checkpoint save,
# we consolidate the full model and optim state dicts on CPU for rank 0
cpu_state_dict = training.get_full_model_state_dict(
self._model,
self._is_rank_zero,
)
if intermediate_checkpoint:
opt_state_dict = training.get_full_optimizer_state_dict(
self._optimizer,
self._is_rank_zero,
)
else:
opt_state_dict = None
# Now that we have the model and opt state dict, create the actual checkpoint dict
# to be sent to the checkpointer and ultimately written to file
if self._is_rank_zero:
checkpoint_dict.update({training.MODEL_KEY: cpu_state_dict})
# if training is in-progress, checkpoint the optimizer state and recipe state
# as well.
if intermediate_checkpoint:
checkpoint_dict.update(
{
training.OPT_KEY: opt_state_dict,
training.SEED_KEY: self.seed,
training.EPOCHS_KEY: self.epochs_run,
training.TOTAL_EPOCHS_KEY: self.total_epochs,
training.MAX_STEPS_KEY: self.max_steps_per_epoch,
}
)
self._checkpointer.save_checkpoint(
checkpoint_dict,
epoch=epoch,
intermediate_checkpoint=intermediate_checkpoint,
)
def train(self) -> None:
"""
The core training loop.
"""
# clean up before training begins
training.cleanup_before_training()
world_size, rank = training.get_world_size_and_rank()
# zero out the gradients before starting training
self._optimizer.zero_grad()
# Initialize tokens count and running loss (for grad accumulation)
t0 = time.perf_counter()
running_loss = 0
num_tokens = 0
self._profiler.start()
# self.epochs_run should be non-zero when we're resuming from a checkpoint
for curr_epoch in range(self.epochs_run, self.total_epochs):
# Update the sampler to ensure data is correctly shuffled across epochs
# in case shuffle is True
self._sampler.set_epoch(curr_epoch)
pbar = tqdm(total=self._steps_per_epoch, disable=not (rank == 0))
for idx, batch in enumerate(self._dataloader):
if (
self.max_steps_per_epoch is not None
and (idx // self._gradient_accumulation_steps)
== self.max_steps_per_epoch
):
break
# Start tracking CUDA memory for active steps for just the first epoch
if (
self._is_rank_zero
and curr_epoch == 0
and self.profiler_profile_memory
and idx == self.profiler_wait_steps + self.profiler_warmup_steps
):
torch.cuda.memory._record_memory_history()
# Both are shape [b, s]
tokens, labels = batch["tokens"], batch["labels"]
# Get the attention mask and position ids from the dataset if they
# exist. Currently, only sample packing in PackedDataset returns these
mask = batch.get("mask", None) # shape [b, s, s]
input_pos = batch.get("input_pos", None) # shape [b, s]
# Optionally wait N steps before enabling fake quant
if self._fake_quant_after_n_steps is not None:
if self.global_step == 0:
log.info(
"Step 0: Disabling fake quant, will re-enable in step %s"
% self._fake_quant_after_n_steps
)
disable_fq = training.quantization._get_disable_fake_quant(
self._quantizer_mode
)
self._model.apply(disable_fq)
elif self.global_step == self._fake_quant_after_n_steps:
log.info(
"Step %s: Enabling fake quant"
% self._fake_quant_after_n_steps
)
enable_fq = training.quantization._get_enable_fake_quant(
self._quantizer_mode
)
self._model.apply(enable_fq)
tokens = tokens.to(self._device)
# Calculate the number of unmasked tokens in the current batch
# and increment the total number of tokens seen in the step
utils.batch_to_device(batch, self._device)
current_num_tokens = (
batch["labels"] != self._loss_fn.ignore_index
).sum()
num_tokens += current_num_tokens
labels = batch.pop("labels")
logits = self._model(**batch)
# Shift labels to compute loss
# equivalent to doing labels[..., 1:] and logits[..., :-1, :]
# But this way we dont need to slice the logits. We just add an ignore index to labels.
labels = torch.hstack(
(labels[..., 1:], self.ignore_labels_cache[: labels.shape[0]])
)
if not isinstance(logits, list):
labels = labels.reshape(-1)
logits = logits.reshape(-1, logits.size(-1))
# Compute loss
current_loss = self._loss_fn(logits, labels) * current_num_tokens
# free logits otherwise it peaks backward memory
del logits
running_loss += current_loss
current_loss.backward()
# Step with optimizer
if (idx + 1) % self._gradient_accumulation_steps == 0:
# Get total number of tokens across all ranks to normalize gradients
torch.distributed.all_reduce(num_tokens)
# This will ensure that the logged loss matches what we're optimizing
torch.distributed.all_reduce(running_loss)
# Manually scale the gradients from unnormalized loss by total # of tokens
training.scale_grads(self._model, 1 / num_tokens)
self._optimizer.step()
self._optimizer.zero_grad(set_to_none=True)
# Update the number of steps when the weights are updated
self.global_step += 1
loss_to_log = running_loss.item() / num_tokens
pbar.update(1)
pbar.set_description(
f"{curr_epoch + 1}|{self.global_step}|Loss: {loss_to_log}"
)
# Log per-step metrics
if (
self.global_step % self._log_every_n_steps == 0
and self._is_rank_zero
):
time_per_step = time.perf_counter() - t0
log_dict = {
"loss": loss_to_log,
"lr": self._optimizer.param_groups[0]["lr"],
"tokens_per_second_per_gpu": (
num_tokens / time_per_step * world_size
),
}
if self._log_peak_memory_stats:
log_dict.update(
training.get_memory_stats(device=self._device)
)
self._metric_logger.log_dict(
log_dict,
step=self.global_step,
)
# Reset running stats for the next step
running_loss = 0
num_tokens = 0
t0 = time.perf_counter()
# Stop tracking CUDA memory now that active steps are complete
if (
self._is_rank_zero
and curr_epoch == 0
and self.profiler_profile_memory
and idx
== self.profiler_wait_steps
+ self.profiler_warmup_steps
+ self.profiler_active_steps
):
torch.cuda.memory._record_memory_history(enabled=None)
# Step profiler
# Note that this is called within gradient accumulation block, hence
# will include multiple forward / backward passes if gradient accumulation > 1
self._profiler.step()
self.epochs_run += 1
self.save_checkpoint(epoch=curr_epoch)
self._profiler.stop()
def cleanup(self) -> None:
if self._is_rank_zero:
self._metric_logger.close()
destroy_process_group()
@config.parse
def recipe_main(cfg: DictConfig) -> None:
"""
Entry point for the recipe.
Configurable parameters are read in the following order:
- Parameters specified in config (see available configs through ``tune ls``)
- Overwritten by arguments from the command-line
"""
if not training.is_distributed():
raise RuntimeError(
"Distributed QAT recipe should be run via a distributed launcher."
"If using tune CLI, please specify --nnodes 1 and --nproc_per_node [num_gpus]"
)
init_process_group(backend="gloo" if cfg.device == "cpu" else "nccl")
if cfg.get("fsdp_cpu_offload", False):
# Utilize all available CPU cores for intra-op parallelism. This provides ~2x
# speed up when benchmarking fused AdamW on CPU
training.set_torch_num_threads()
config.log_config(recipe_name="QATRecipeDistributed", cfg=cfg)
recipe = QATRecipeDistributed(cfg=cfg)
recipe.setup(cfg=cfg)
recipe.train()
recipe.cleanup()
if __name__ == "__main__":
sys.exit(recipe_main())