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#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import functools
import logging
import os
from contextlib import nullcontext
from copy import deepcopy
from functools import partial
from itertools import chain
import torch
from codetiming import Timer
from omegaconf import DictConfig, open_dict
from tensordict import NonTensorData, TensorDict
from torch.distributed.device_mesh import init_device_mesh
from verl.checkpoint_engine import CheckpointEngineRegistry
from verl.single_controller.base import Worker
from verl.single_controller.base.decorator import Dispatch, make_nd_compute_dataproto_dispatch_fn, register
from verl.utils import tensordict_utils as tu
from verl.utils.config import omega_conf_to_dataclass
from verl.utils.device import get_device_name, set_expandable_segments
from verl.utils.distributed import initialize_global_process_group_ray
from verl.utils.flops_counter import FlopsCounter
from verl.utils.memory_utils import aggressive_empty_cache
from verl.utils.metric.utils import Metric
from verl.utils.profiler import DistProfiler, DistProfilerExtension, ProfilerConfig, log_gpu_memory_usage
from verl.utils.py_functional import append_to_dict
from verl.utils.tensordict_utils import maybe_fix_3d_position_ids
from verl.utils.torch_functional import allgather_dict_into_dict
from verl.workers.config import ActorConfig, HFModelConfig, MtpConfig, RolloutConfig, TrainingWorkerConfig
from verl.workers.rollout.base import BaseRollout, get_rollout_class
from verl.workers.utils.losses import ppo_loss
logger = logging.getLogger(__file__)
logger.setLevel(os.getenv("VERL_LOGGING_LEVEL", "WARN"))
def _with_routing_replay_flag(enabled: bool):
"""Decorator to set 'enable_routing_replay' flag on the data TensorDict."""
def decorator(func):
@functools.wraps(func)
def wrapper(self, data: TensorDict, *args, **kwargs):
if self.enable_routing_replay:
tu.assign_non_tensor_data(data, "enable_routing_replay", enabled)
return func(self, data, *args, **kwargs)
return wrapper
return decorator
class TrainingWorker(Worker, DistProfilerExtension):
"""
TrainingWorker provides a Tinker-like API (https://thinkingmachines.ai/tinker/) as a RayWorkerGroup
to a single controller. Currently, we only provide more coarse grained APIs,
and do not provide exact APIs as Tinker does. But this can be added in the future.
"""
def __init__(self, config: TrainingWorkerConfig):
Worker.__init__(self)
from verl.workers.engine import BaseEngine, EngineRegistry
initialize_global_process_group_ray(timeout_second=None)
self.config = config
self.model_config = self.config.model_config
self.engine_config = self.config.engine_config
self.optimizer_config = self.config.optimizer_config
self.checkpoint_config = self.config.checkpoint_config
self.device_name = get_device_name()
if self.engine_config is None:
assert self.optimizer_config is None
if self.config.auto_select_engine_optim_fn is None:
raise ValueError(
"engine_config is not provided and auto_select_engine_optim_fn is not set. "
"Cannot determine engine backend."
)
# Support automatically select engine backend given model config
self.engine_config, self.optimizer_config = self.config.auto_select_engine_optim_fn(
self.model_config, self.device_name
)
# we use the one defined in model
# TODO: this is not elegant and should refactor later
self.engine_config.use_remove_padding = self.model_config.use_remove_padding
self.engine_config.use_fused_kernels = self.model_config.use_fused_kernels
# TODO: add DistProfilerExtension
self.profiler_config = self.config.profiler_config
if self.profiler_config is not None:
self.profiler_tool_config = self.profiler_config.tool_config.get(self.profiler_config.tool, {})
else:
self.profiler_tool_config = None
DistProfilerExtension.__init__(
self, DistProfiler(rank=self.rank, config=self.profiler_config, tool_config=self.profiler_tool_config)
)
self.engine: BaseEngine = EngineRegistry.new(
model_type=self.config.model_type,
backend=self.engine_config.strategy,
model_config=self.model_config,
engine_config=self.engine_config,
optimizer_config=self.optimizer_config,
checkpoint_config=self.checkpoint_config,
)
# build dispatch info
self._register_dispatch_collect_info(
mesh_name="train",
dp_rank=self.engine.get_data_parallel_rank(),
is_collect=self.engine.is_mp_src_rank_with_outputs(),
)
self.flops_counter = FlopsCounter(self.model_config.hf_config)
self.loss_fn = None
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def to(self, device, model=True, optimizer=True, grad=True):
"""Manual control of load/offload"""
assert device in ["cpu", "device"]
if device == "device":
device = get_device_name()
self.engine.to(device=device, model=model, optimizer=optimizer, grad=grad)
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def set_loss_fn(self, loss_fn):
self.loss_fn = loss_fn
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def reset(self):
"""
Reset the model engine to the initial state. If the engine is not initialized,
we initialize it. Otherwise, reload ckpt and reset states
"""
self.engine.initialize()
def _postprocess_output(self, output, *, global_token_num, delta_time, forward_only, images_seqlens):
"""
Args:
output: a dictionary containing loss, model_outputs and metrics
Returns:
"""
# TODO: whether to log memory
# metrics["perf/max_memory_allocated_gb"] = get_torch_device().max_memory_allocated() / (1024 ** 3)
# metrics["perf/max_memory_reserved_gb"] = get_torch_device().max_memory_reserved() / (1024 ** 3)
# metrics["perf/cpu_memory_used_gb"] = psutil.virtual_memory().used / (1024 ** 3)
metrics: dict = output.pop("metrics")
# perform all gather in dp group to ensure that it's correct.
# Here each metric in metrics can be a list (micro-batch metrics) or a singleton
# we should always sum the loss of each micro-batch as we scale by global_bsz/global_token
loss = torch.sum(torch.tensor(output.pop("loss"), device=self.device_name))
dp_group = self.engine.get_data_parallel_group()
if dp_group is not None:
torch.distributed.all_reduce(loss, op=torch.distributed.ReduceOp.AVG, group=dp_group)
loss = loss.item()
# For grad_norm, we do not perform all reduce because it is already been done when clipping grad
grad_norm = metrics.pop("grad_norm", None)
lr = metrics.pop("lr", None)
# For other metrics, we perform all gather in dp group (only if DP > 1)
if dp_group is not None:
final_metrics = allgather_dict_into_dict(data=metrics, group=dp_group)
else:
final_metrics = metrics
final_metrics["loss"] = loss
if grad_norm is not None:
final_metrics["grad_norm"] = grad_norm
if lr is not None:
final_metrics["lr"] = lr
# TODO: confirm the mtp loss IS same across dp
for k, v in final_metrics.items():
if k.startswith("mtp_losses"):
flatten_v = [sublist[0] for sublist in v] # sublist should be single element
final_metrics[k] = sum(flatten_v) / len(flatten_v)
# compute mfu
if global_token_num is not None:
estimated_flops, promised_flops = self.flops_counter.estimate_flops(
global_token_num, delta_time, images_seqlens=images_seqlens
)
final_metrics["mfu"] = estimated_flops / promised_flops / torch.distributed.get_world_size()
if forward_only:
final_metrics["mfu"] /= 3.0
# model outputs
model_output = output.pop("model_output", {})
# We only return final_metrics
final_output = tu.get_tensordict(tensor_dict=model_output, non_tensor_dict={"metrics": final_metrics})
return final_output
@register(dispatch_mode=make_nd_compute_dataproto_dispatch_fn(mesh_name="train"), blocking=False)
def train_mini_batch(self, data: TensorDict) -> TensorDict:
"""Split a batch into N mini-batches run for multiple epochs
Args:
data:
Returns:
"""
maybe_fix_3d_position_ids(data)
batch_size_per_dp = data.shape[0]
disable_auto_offload = tu.pop(data, key="disable_auto_offload", default=False)
mini_batch_size = tu.pop(data, key="mini_batch_size", default=None)
num_mini_batch = tu.pop(data, key="num_mini_batch", default=None)
epochs = tu.pop(data, key="epochs", default=1)
seed = tu.pop(data, key="seed", default=42)
dataloader_kwargs = tu.pop(data, key="dataloader_kwargs", default={})
assert mini_batch_size is not None or num_mini_batch is not None
if mini_batch_size is None:
assert batch_size_per_dp % num_mini_batch == 0, f"Got {batch_size_per_dp=} and {num_mini_batch=}"
mini_batch_size_per_gpu = batch_size_per_dp // num_mini_batch
else:
assert mini_batch_size % self.engine.get_data_parallel_size() == 0, (
f"Got {mini_batch_size=} and {self.engine.get_data_parallel_size()=}"
)
mini_batch_size_per_gpu = mini_batch_size // self.engine.get_data_parallel_size()
# make iterator
dataloader = tu.make_iterator(
data,
mini_batch_size=mini_batch_size_per_gpu,
epochs=epochs,
seed=seed + self.engine.get_data_parallel_rank(),
dataloader_kwargs=dataloader_kwargs,
)
with (
self.engine.train_mode(disable_auto_offload=disable_auto_offload),
Timer(name="train_batch", logger=None),
):
# update
output_lst = []
total_num_iterations = data.shape[0] // mini_batch_size_per_gpu * epochs
for batch_idx, mini_batch_td in enumerate(dataloader):
# add global token num
global_token_num = mini_batch_td["input_ids"].offsets().diff().tolist() # (total_nnz,)
# allgather from dp rank
global_token_num_output = [None] * self.engine.get_data_parallel_size()
torch.distributed.all_gather_object(
global_token_num_output, global_token_num, self.engine.get_data_parallel_group()
)
global_token_num = [x for xs in global_token_num_output for x in xs]
tu.assign_non_tensor(
mini_batch_td,
global_token_num=NonTensorData(global_token_num),
update_lr_scheduler=batch_idx == total_num_iterations - 1,
disable_auto_offload=True,
)
actor_output = self.train_batch(mini_batch_td)
output_lst.append(actor_output)
if self.engine.is_mp_src_rank_with_outputs():
actor_output = [tu.get(output, "metrics") for output in output_lst]
metrics = {}
for output in actor_output:
for key, val in output.items():
# flattn dp and micro batch
if isinstance(val, list):
output[key] = (
Metric.aggregate_dp(val)
if isinstance(val[0], Metric)
else list(chain.from_iterable(val))
)
append_to_dict(metrics, output)
output = tu.get_tensordict(tensor_dict={}, non_tensor_dict={"metrics": metrics}).cpu()
else:
output = None
return output
@register(dispatch_mode=make_nd_compute_dataproto_dispatch_fn(mesh_name="train"), blocking=False)
def train_batch(self, data: TensorDict) -> TensorDict:
assert self.loss_fn is not None, "loss function can't be None when calling train_batch"
assert not self.engine_config.forward_only, "Can't run `train_batch` when forward_only is in the engine config."
# global_token_num should be a list of number of tokens of each seq in this batch
global_token_num = tu.get(data, key="global_token_num")
disable_auto_offload = tu.get(data, key="disable_auto_offload", default=False)
images_seqlens = tu.get(data, key="images_seqlens", default=None)
# inject engineering parameters if not specified
default_keys = dict(
use_remove_padding=self.model_config.use_remove_padding,
use_dynamic_bsz=self.engine_config.use_dynamic_bsz,
max_token_len_per_gpu=self.engine_config.max_token_len_per_gpu,
micro_batch_size_per_gpu=self.engine_config.micro_batch_size_per_gpu,
use_fused_kernels=self.engine_config.use_fused_kernels,
)
for key, val in default_keys.items():
if key not in data.keys():
tu.assign_non_tensor(data, **{key: val})
with (
self.engine.train_mode(disable_auto_offload=disable_auto_offload),
Timer(name="train_batch", logger=None) as timer,
):
output = self.engine.train_batch(data, loss_function=self.loss_fn)
# containing loss, model_output and metrics
# for training, we only care about loss and metrics
delta_time = timer.last
update_lr_scheduler = tu.get(data, key="update_lr_scheduler", default=False)
# update lr scheduler
if update_lr_scheduler:
lr = self.engine.lr_scheduler_step()
else:
lr = None
if self.engine.is_mp_src_rank_with_outputs():
# we don't need model_output in training. Maybe we change out mind later
output.pop("model_output")
if lr is not None:
output["metrics"]["lr"] = lr
final_output = self._postprocess_output(
output,
global_token_num=global_token_num,
delta_time=delta_time,
forward_only=False,
images_seqlens=images_seqlens,
).cpu()
else:
final_output = None
return final_output
@register(dispatch_mode=make_nd_compute_dataproto_dispatch_fn(mesh_name="train"), blocking=False)
def infer_batch(self, data: TensorDict) -> TensorDict:
# add mfu calculator
global_token_num = tu.get(data, key="global_token_num")
compute_loss = tu.get(data, key="compute_loss", default=True)
disable_auto_offload = tu.get(data, key="disable_auto_offload", default=False)
no_lora_adapter = tu.pop(data, key="no_lora_adapter", default=False)
images_seqlens = tu.get(data, key="images_seqlens", default=None)
default_keys = dict(
use_remove_padding=self.model_config.use_remove_padding,
use_dynamic_bsz=self.engine_config.use_dynamic_bsz,
max_token_len_per_gpu=self.engine_config.infer_max_token_len_per_gpu,
micro_batch_size_per_gpu=self.engine_config.infer_micro_batch_size_per_gpu,
use_fused_kernels=self.engine_config.use_fused_kernels,
)
for key, val in default_keys.items():
if key not in data.keys():
tu.assign_non_tensor(data, **{key: val})
# for sft training, we need to compute loss in eval
loss_function = self.loss_fn if compute_loss else None
with (
self.engine.eval_mode(disable_auto_offload=disable_auto_offload),
Timer(name="eval_batch", logger=None) as timer,
):
adapter_ctx = self.engine.disable_adapter() if no_lora_adapter else nullcontext()
with adapter_ctx:
output = self.engine.infer_batch(data, loss_function=loss_function)
delta_time = timer.last
if self.engine.is_mp_src_rank_with_outputs():
final_output = self._postprocess_output(
output,
global_token_num=global_token_num,
delta_time=delta_time,
forward_only=True,
images_seqlens=images_seqlens,
).cpu()
else:
final_output = None
return final_output
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def save_checkpoint(self, local_path, hdfs_path=None, global_step=0, max_ckpt_to_keep=None):
return self.engine.save_checkpoint(local_path, hdfs_path, global_step, max_ckpt_to_keep)
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def load_checkpoint(self, local_path, hdfs_path=None, del_local_after_load=False):
return self.engine.load_checkpoint(local_path, hdfs_path, del_local_after_load)
class ActorRolloutRefWorker(Worker, DistProfilerExtension):
"""Hybrid worker that includes actor model, rollout and optional ref model.
For standalone actor or rollout, use ActorWorker or BaseRollout respectively.
NOTE: ActorRolloutRefWorker no longer support spmd mode and run native server mode.
"""
def __init__(self, config: DictConfig, role: str, **kwargs):
Worker.__init__(self)
self.config = config
self.role = role
self.actor: TrainingWorker = None
self.ref: TrainingWorker = None
self.rollout: BaseRollout = None
assert self.role in ["actor", "rollout", "ref", "actor_rollout", "actor_rollout_ref"]
self._is_actor = self.role in ["actor", "actor_rollout", "actor_rollout_ref"]
self._is_rollout = self.role in ["rollout", "actor_rollout", "actor_rollout_ref"]
self._is_ref = self.role in ["ref", "actor_rollout_ref"]
if self._is_actor:
omega_profiler_config = config.actor.get("profiler", {})
elif self._is_rollout:
# NOTE: In colocation mode, rollout config may not take effect (follow the actor config)
# This is for extendability in AsyncRL cases
omega_profiler_config = config.rollout.get("profiler", {})
else:
omega_profiler_config = config.ref.get("profiler", {})
profiler_config = omega_conf_to_dataclass(omega_profiler_config, dataclass_type=ProfilerConfig)
if omega_profiler_config.get("tool", None) in ["npu", "nsys", "torch", "torch_memory"]:
tool_config = omega_conf_to_dataclass(
omega_profiler_config.get("tool_config", {}).get(omega_profiler_config.get("tool"))
)
else:
tool_config = None
self.enable_routing_replay = (
self.config.actor.strategy == "megatron" and self.config.actor.megatron.router_replay.mode != "disabled"
)
DistProfilerExtension.__init__(
self, DistProfiler(rank=self.rank, config=profiler_config, tool_config=tool_config)
)
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def set_loss_fn(self, loss_fn):
self.actor.set_loss_fn(loss_fn=loss_fn)
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def to(self, device, model=True, optimizer=True, grad=True):
"""Manual control of load/offload"""
self.actor.to(device=device, model=model, optimizer=optimizer, grad=grad)
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def init_model(self):
model_config: HFModelConfig = omega_conf_to_dataclass(self.config.model)
# 1. build reference model
if "ref" in self.role:
# TODO: align ref config with actor config
with open_dict(self.config.ref):
self.config.ref.ppo_mini_batch_size = self.config.actor.ppo_mini_batch_size
self.config.ref.ppo_micro_batch_size = self.config.ref.pop("log_prob_micro_batch_size", None)
self.config.ref.ppo_micro_batch_size_per_gpu = self.config.ref.pop(
"log_prob_micro_batch_size_per_gpu", None
)
self.config.ref.use_dynamic_bsz = self.config.ref.pop("log_prob_use_dynamic_bsz", False)
self.config.ref.ppo_max_token_len_per_gpu = self.config.ref.pop("log_prob_max_token_len_per_gpu", None)
ref_config: ActorConfig = omega_conf_to_dataclass(self.config.ref)
# The ref model does not need to enable MTP; force it to false.
ref_config.model_config = deepcopy(model_config)
ref_config.model_config.mtp = MtpConfig(enable=False)
# construct TrainingWorkerConfig
ref_training_config = TrainingWorkerConfig(
model_type="language_model",
model_config=ref_config.model_config,
engine_config=ref_config.engine,
optimizer_config=ref_config.optim,
checkpoint_config=ref_config.checkpoint,
)
# assign engine configs
ref_training_config.engine_config.use_dynamic_bsz = self.config.ref.use_dynamic_bsz
ref_training_config.engine_config.infer_max_token_len_per_gpu = self.config.ref.ppo_max_token_len_per_gpu
ref_training_config.engine_config.infer_micro_batch_size_per_gpu = (
self.config.ref.ppo_micro_batch_size_per_gpu
)
ref_training_config.engine_config.use_remove_padding = model_config.use_remove_padding
self.ref = TrainingWorker(config=ref_training_config)
self.ref.reset()
self.set_dispatch_collect(mesh_name="ref", **self.ref.get_dispatch_collect())
# 2. build actor model
if "actor" in self.role:
actor_config: ActorConfig = omega_conf_to_dataclass(self.config.actor)
actor_config.model_config = model_config
actor_training_config = TrainingWorkerConfig(
model_type="language_model",
model_config=actor_config.model_config,
engine_config=actor_config.engine,
optimizer_config=actor_config.optim,
checkpoint_config=actor_config.checkpoint,
)
assert self.config.actor.use_dynamic_bsz == self.config.rollout.log_prob_use_dynamic_bsz
# assign engine configs
actor_training_config.engine_config.use_dynamic_bsz = self.config.actor.use_dynamic_bsz
actor_training_config.engine_config.infer_max_token_len_per_gpu = (
self.config.rollout.log_prob_max_token_len_per_gpu
)
actor_training_config.engine_config.infer_micro_batch_size_per_gpu = (
self.config.rollout.log_prob_micro_batch_size_per_gpu
)
actor_training_config.engine_config.max_token_len_per_gpu = self.config.actor.ppo_max_token_len_per_gpu
actor_training_config.engine_config.micro_batch_size_per_gpu = (
self.config.actor.ppo_micro_batch_size_per_gpu
)
actor_training_config.engine_config.use_remove_padding = model_config.use_remove_padding
if self.config.actor.use_dynamic_bsz:
assert self.config.rollout.log_prob_max_token_len_per_gpu is not None
assert self.config.actor.ppo_max_token_len_per_gpu is not None
else:
assert self.config.rollout.log_prob_micro_batch_size_per_gpu is not None
assert self.config.actor.ppo_micro_batch_size_per_gpu is not None
self.loss_fn = partial(ppo_loss, config=actor_config)
self.actor = TrainingWorker(config=actor_training_config)
self.actor.reset()
self.actor.set_loss_fn(self.loss_fn)
self.set_dispatch_collect(mesh_name="actor", **self.actor.get_dispatch_collect())
# 3. build rollout engine
if "rollout" in self.role:
rollout_config: RolloutConfig = omega_conf_to_dataclass(self.config.rollout)
# TODO: move rollout_device_mesh into ServerAdapter
# 3.1 build rollout device mesh (sglang need only)
infer_tp = rollout_config.tensor_model_parallel_size * rollout_config.data_parallel_size
infer_pp = rollout_config.pipeline_model_parallel_size
infer_world_size = infer_tp * infer_pp
dp = self.world_size // infer_world_size
assert self.world_size % infer_world_size == 0, (
f"rollout world_size: {self.world_size} is not divisible by infer_world_size: {infer_world_size}"
)
rollout_device_mesh = init_device_mesh(
get_device_name(), mesh_shape=(dp, infer_tp, infer_pp), mesh_dim_names=["dp", "infer_tp", "infer_pp"]
)
# 3.2 initialize rollout engine
rollout_cls: type[BaseRollout] = get_rollout_class(rollout_config.name, rollout_config.mode)
self.rollout = rollout_cls(
config=rollout_config, model_config=model_config, device_mesh=rollout_device_mesh
)
# used for LoRA
self.base_sync_done: bool = "dummy" not in self.config.rollout.load_format
self.layered_summon = self.config.rollout.get("layered_summon", False)
self.peft_merge: bool = model_config.lora.get("merge", False)
# 4. build checkpoint engine
if "actor" in self.role:
checkpoint_engine_config = omega_conf_to_dataclass(self.config.rollout.checkpoint_engine)
backend = checkpoint_engine_config.backend
bucket_size = checkpoint_engine_config.update_weights_bucket_megabytes << 20
engine_kwargs = checkpoint_engine_config.engine_kwargs.get(backend, {})
self.checkpoint_engine = CheckpointEngineRegistry.new(
backend, is_master=(torch.distributed.get_rank() == 0), bucket_size=bucket_size, **engine_kwargs
)
# Free cached GPU memory so colocated vLLM processes can see it via cudaMemGetInfo
aggressive_empty_cache(force_sync=True)
@register(dispatch_mode=make_nd_compute_dataproto_dispatch_fn(mesh_name="ref"))
@DistProfiler.annotate(color="olive", role="ref_compute_log_prob")
@_with_routing_replay_flag(enabled=False)
def compute_ref_log_prob(self, data: TensorDict) -> TensorDict:
output = self.ref.infer_batch(data=data)
return output.cpu() if output is not None else None
@register(dispatch_mode=make_nd_compute_dataproto_dispatch_fn(mesh_name="actor"))
@DistProfiler.annotate(color="blue", role="actor_compute_log_prob")
@_with_routing_replay_flag(enabled=True)
def compute_log_prob(self, data: TensorDict) -> TensorDict:
output = self.actor.infer_batch(data)
return output.cpu() if output is not None else None
@register(dispatch_mode=make_nd_compute_dataproto_dispatch_fn(mesh_name="actor"))
@DistProfiler.annotate(color="red", role="actor_update")
@_with_routing_replay_flag(enabled=True)
def update_actor(self, data: TensorDict) -> TensorDict:
output = self.actor.train_mini_batch(data=data)
return output.cpu() if output is not None else None
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def load_checkpoint(self, local_path, hdfs_path=None, del_local_after_load=False):
assert "actor" in self.role, "load_checkpoint only support actor role"
self.actor.load_checkpoint(local_path, hdfs_path, del_local_after_load)
@register(dispatch_mode=Dispatch.ONE_TO_ALL)
def save_checkpoint(self, local_path, hdfs_path=None, global_step=0, max_ckpt_to_keep=None):
assert "actor" in self.role, "save_checkpoint only support actor role"
self.actor.save_checkpoint(local_path, hdfs_path, global_step, max_ckpt_to_keep)
@register(dispatch_mode=Dispatch.ONE_TO_ALL, blocking=False)
async def update_weights(self, global_steps: int = None):
"""Update weights from trainer to rollout.
1. For sync training with colocated trainer and rollout, update rollout directly from model engine.
- before update_weights: rollout should be in sleep mode.
- after update_weights: rollout should be in wake_up mode.
2. For async training with disaggregated trainer and rollout, send_weights only by checkpoint engine.
"""
# 0. send_weights only for async training with disaggregated trainer and rollout
if self.config.rollout.checkpoint_engine.backend != "naive":
per_tensor_param, _ = self.actor.engine.get_per_tensor_param()
await self.checkpoint_engine.send_weights(per_tensor_param)
return
set_expandable_segments(False)
log_gpu_memory_usage("Before resume weights", logger=logger)
# 1. resume weights and update weights
if self.config.rollout.free_cache_engine:
await self.rollout.resume(tags=["weights"])
log_gpu_memory_usage("After resume weights", logger=logger)
# 2. get per tensor generator from engine, this will load model to gpu
per_tensor_param, peft_config = self.actor.engine.get_per_tensor_param(
layered_summon=self.layered_summon, base_sync_done=True
)
await self.rollout.update_weights(
per_tensor_param, peft_config=peft_config, base_sync_done=True, global_steps=global_steps
)
do_lora_base_sync = False
if not self.peft_merge and peft_config is not None:
# set sleep level for LoRA adapter weights only sync
# TODO: make this configurable so that users with small
# main memory can trade sync time to avoid OOM
self.rollout.sleep_level = 1
do_lora_base_sync = (not self.base_sync_done) or (
self.rollout.sleep_level != 1 and self.config.rollout.free_cache_engine
)
if do_lora_base_sync:
per_tensor_base_params, _ = self.actor.engine.get_per_tensor_param(
layered_summon=self.layered_summon, base_sync_done=False
)
await self.rollout.update_weights(per_tensor_base_params, peft_config=peft_config, base_sync_done=False)
log_gpu_memory_usage("After update_weights", logger=logger)
# 3. offload model to cpu
self.actor.engine.to("cpu", model=True, optimizer=False, grad=False)
aggressive_empty_cache(force_sync=True)
# 4. resume kv_cache
if self.config.rollout.free_cache_engine:
await self.rollout.resume(tags=["kv_cache"])
log_gpu_memory_usage("After resume kv_cache", logger=logger)
self.base_sync_done = True
set_expandable_segments(True)
@register(dispatch_mode=Dispatch.DP_COMPUTE, blocking=False)
def execute_checkpoint_engine(self, method: str, *args, **kwargs):
"""Execute checkpoint engine method.
Args:
method (str): Checkpoint engine method name.
*args: Variable length argument list.
**kwargs: Arbitrary keyword arguments.
"""
return getattr(self.checkpoint_engine, method)(*args, **kwargs)
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