# Copyright 2023-2024 SGLang Team # Copyright 2025 ModelBest Inc. and/or its affiliates # # 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. # ============================================================================== # Copyright 2024 Bytedance Ltd. and/or its affiliates # # 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 logging import os from typing import Union import torch import torch.distributed as dist from sglang.srt.entrypoints.engine import Engine from sglang.srt.entrypoints.verl_engine import VerlEngine from sglang.srt.model_executor.model_runner import LocalSerializedTensor from sglang.srt.utils import MultiprocessingSerializer from torch.distributed.device_mesh import DeviceMesh from torch.distributed.fsdp.api import FullStateDictConfig, ShardedStateDictConfig, StateDictType from torch.distributed.fsdp.fully_sharded_data_parallel import FullyShardedDataParallel as FSDP from torch.distributed.tensor import DTensor from verl import DataProto from verl.protocol import all_gather_data_proto from verl.utils.debug import log_gpu_memory_usage from verl.utils.fsdp_utils import fsdp_version, load_fsdp_model_to_gpu, offload_fsdp_model_to_cpu from verl.utils.torch_functional import broadcast_dict_tensor, check_cuda_is_available from .base import BaseShardingManager # from vllm.distributed import parallel_state as sglang_ps logger = logging.getLogger(__file__) logger.setLevel(os.getenv("VERL_LOGGING_LEVEL", "WARN")) def _preprocess_tensor_for_update_weights(tensor: torch.Tensor): if isinstance(tensor, DTensor): return tensor.full_tensor() return tensor class FSDPSGLangShardingManager(BaseShardingManager): @check_cuda_is_available() def __init__( self, module: FSDP, inference_engine: Union[VerlEngine, Engine], model_config, full_params: bool = False, device_mesh: DeviceMesh = None, offload_param: bool = False, ): self.module = module self.inference_engine = inference_engine self.model_config = model_config self.device_mesh = device_mesh self.offload_param = offload_param # Full params self.full_params = full_params if full_params and fsdp_version(self.module) == 1: FSDP.set_state_dict_type(self.module, state_dict_type=StateDictType.FULL_STATE_DICT, state_dict_config=FullStateDictConfig()) elif fsdp_version(self.module) == 1: FSDP.set_state_dict_type( self.module, state_dict_type=StateDictType.SHARDED_STATE_DICT, state_dict_config=ShardedStateDictConfig(), ) # Note that torch_random_states may be different on each dp rank self.torch_random_states = torch.cuda.get_rng_state() # get a random rng states if self.device_mesh is not None: gen_dp_rank = self.device_mesh["dp"].get_local_rank() torch.cuda.manual_seed(gen_dp_rank + 1000) # make sure all tp ranks have the same random states self.gen_random_states = torch.cuda.get_rng_state() torch.cuda.set_rng_state(self.torch_random_states) else: self.gen_random_states = None def __enter__(self): torch.cuda.empty_cache() log_gpu_memory_usage("Before state_dict() in sharding manager memory", logger=logger) if self.offload_param: load_fsdp_model_to_gpu(self.module) params = self.module.state_dict() log_gpu_memory_usage("After state_dict() in sharding manager memory", logger=logger) device = torch.cuda.current_device() # used when fsdp2 set cpu_offload_policy params = {k: v.to(device, non_blocking=True) if fsdp_version(self.module) == 2 else v for k, v in params.items()} # Copy, not share memory self.update_weights(params) log_gpu_memory_usage("After sync model weights in sharding manager", logger=logger) del params if self.offload_param: offload_fsdp_model_to_cpu(self.module) torch.cuda.empty_cache() log_gpu_memory_usage("After del state_dict and empty_cache in sharding manager", logger=logger) # important: need to manually set the random states of each tp to be identical. if self.device_mesh is not None: self.torch_random_states = torch.cuda.get_rng_state() torch.cuda.set_rng_state(self.gen_random_states) def __exit__(self, exc_type, exc_value, traceback): log_gpu_memory_usage("Before SGLang offload in sharding manager", logger=logger) self.release_memory() log_gpu_memory_usage("After SGLang offload in sharding manager", logger=logger) self.module.train() # add empty cache after each compute torch.cuda.empty_cache() # restore random states if self.device_mesh is not None: self.gen_random_states = torch.cuda.get_rng_state() torch.cuda.set_rng_state(self.torch_random_states) def update_weights(self, params): self.inference_engine.resume_memory_occupation() self.inference_engine.update_weights_from_tensor([(k, v) for k, v in params.items()], load_format=None) def release_memory(self): self.inference_engine.release_memory_occupation() def preprocess_data(self, data: DataProto) -> DataProto: """All gather across tp group to make each rank has identical input.""" if self.device_mesh["infer_tp"].mesh.size()[0] == 1: return data # TODO: Current impl doesn't consider FSDP with torch micro-dp group = self.device_mesh["infer_tp"].get_group() all_gather_data_proto(data=data, process_group=group) return data def postprocess_data(self, data: DataProto) -> DataProto: # TODO: Current impl doesn't consider FSDP with torch micro-dp global_rank = self.device_mesh.get_rank() tp_rank = self.device_mesh["infer_tp"].get_local_rank() tp_size = self.device_mesh["infer_tp"].mesh.size()[0] src_rank = global_rank // tp_size * tp_size broadcast_dict_tensor(data.batch, src=src_rank, group=self.device_mesh["infer_tp"].get_group()) if tp_size > 1: local_prompts = data.chunk(chunks=tp_size) data = local_prompts[tp_rank] return data class FSDPAsyncSGLangShardingManager(FSDPSGLangShardingManager): def __init__( self, module: FSDP, inference_engine: Engine, model_config, full_params: bool = False, device_mesh: DeviceMesh = None, offload_param: bool = False, ): super().__init__(module, inference_engine, model_config, full_params, device_mesh, offload_param) def update_weights(self, params): load_format = None if self.full_params else "dtensor" if self.device_mesh["infer_tp"].get_local_rank() == 0: self.inference_engine.resume_memory_occupation() # Most naive implementation, can optimize a lot if it is bottleneck from sglang VerlEngine named_tensors = [(k, v) for k, v in params.items()] load_format = None for tensor_index, (name, tensor) in enumerate(named_tensors): serialized_tensor = MultiprocessingSerializer.serialize(_preprocess_tensor_for_update_weights(tensor)) if self.device_mesh["infer_tp"].get_local_rank() == 0: gathered_serialized_tensors = [None for _ in range(self.device_mesh["infer_tp"].mesh.size()[0])] else: gathered_serialized_tensors = None dist.gather_object( obj=serialized_tensor, object_gather_list=gathered_serialized_tensors, dst=self.device_mesh["infer_tp"].mesh.tolist()[0], group=self.device_mesh["infer_tp"].get_group(), ) if self.device_mesh["infer_tp"].get_local_rank() == 0: self.inference_engine.update_weights_from_tensor( named_tensors=[ ( name, LocalSerializedTensor(values=gathered_serialized_tensors), ) ], load_format=load_format, flush_cache=tensor_index == len(named_tensors) - 1, ) def release_memory(self): if self.device_mesh["infer_tp"].get_local_rank() == 0: self.inference_engine.release_memory_occupation()