import torch import torch.distributed as dist from colossalai.context.parallel_mode import ParallelMode from colossalai.context.singleton_meta import SingletonMeta from colossalai.tensor import ProcessGroup from typing import Tuple def _check_sanity(): from colossalai.core import global_context as gpc if gpc.tensor_parallel_size > 1 or gpc.pipeline_parallel_size > 1: raise NotImplementedError("Moe is not compatible with tensor or " "pipeline parallel at present.") class MoeParallelInfo: """Moe parallelism information, storing parallel sizes and groups. """ def __init__(self, ep_size: int, dp_size: int): _check_sanity() self.ep_size = ep_size self.dp_size = dp_size self.pg = ProcessGroup(tp_degree=ep_size, dp_degree=dp_size) self.ep_group = self.pg.tp_process_group() self.dp_group = self.pg.dp_process_group() class MoeContext(metaclass=SingletonMeta): """MoE parallel context manager. This class manages different parallel groups in MoE context and MoE loss in training. """ def __init__(self): self.world_size = 1 # Users may want to set maximum expert parallel size smaller than the world size # since very low bandwidth across nodes may constrain the performance of MoE # When we have a maximum expert parallel size, we have a minimum data parallel size naturally self.max_ep_size = 1 self.min_dp_size = 1 self.aux_loss = None self.use_kernel_optim = True self.has_setup = False self._parallel_info_dict = dict() @property def parallel_info_dict(self): return self._parallel_info_dict @property def is_initialized(self): return self.has_setup def setup(self, seed: int, use_kernel_optim: bool = True): assert not self.is_initialized, "MoE distributed context shouldn't be set up again" _check_sanity() assert torch.cuda.is_available(), "MoE requires to enable CUDA first" self.world_size = dist.get_world_size() from colossalai.core import global_context as gpc self.max_ep_size = gpc.config.get('max_ep_size', self.world_size) assert self.world_size % self.max_ep_size == 0, \ "Maximum epxert parallel size must be a factor of the number of GPUs" self.min_dp_size = self.world_size // self.max_ep_size # Enabling kernel optimization may raise error in some cases # Users can close kernel optimization manually self.use_kernel_optim = use_kernel_optim from .random import moe_set_seed moe_set_seed(seed) self.has_setup = True def get_info(self, num_experts: int) -> Tuple[int, MoeParallelInfo]: """Calculate the Data Parallel Group and Expert Parallel Group. Parameters ---------- num_experts : int The number experts Returns ------- int, MoeParallelInfo number of local experts, the MoeParallelInfo of the current ep_size """ gt_flag = num_experts % self.max_ep_size == 0 # check whether num_experts is greater lt_flag = self.max_ep_size % num_experts == 0 # check whether num_experts is less assert gt_flag or lt_flag, "Automatic experts placement dose not not support expert number" \ " is not a multiple of ep size or vice versa." # If the number of experts is greater than maximum expert parallel size. a.k.a ep_size, # there are multiple experts in each GPU and each GPU has different experts # So it's data parallel size is 1 # Otherwise, there is only one expert in each GPU # The data parallel size should be calculated dp_size = 1 if gt_flag else self.max_ep_size // num_experts ep_size = self.max_ep_size // dp_size # Calculate the number of experts for each GPU num_local_experts = 1 if lt_flag else num_experts // self.max_ep_size # Don't forget to multiply minimum data parallel size dp_size *= self.min_dp_size if not (ep_size in self.parallel_info_dict): self.parallel_info_dict[ep_size] = MoeParallelInfo(ep_size, dp_size) return num_local_experts, self.parallel_info_dict[ep_size] def set_kernel_not_use(self): self.use_kernel_optim = False def reset_loss(self): self.aux_loss = 0 def add_loss(self, loss): self.aux_loss += loss def get_loss(self): return self.aux_loss MOE_CONTEXT = MoeContext()