mirror of https://github.com/hpcaitech/ColossalAI
355 lines
16 KiB
Python
355 lines
16 KiB
Python
from enum import Enum
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from os import stat
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from typing import Dict, Optional, Tuple
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import torch
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import torch.distributed as dist
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import torch.nn as nn
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from colossalai.amp.naive_amp.grad_scaler import DynamicGradScaler
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from colossalai.context.parallel_mode import ParallelMode
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from colossalai.core import global_context as gpc
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from colossalai.logging import get_dist_logger
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from colossalai.nn.optimizer import ColossalaiOptimizer
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from colossalai.gemini.tensor_utils import (colo_model_data_tensor_move_inline, colo_tensor_mem_usage)
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from colossalai.zero.sharded_model import ShardedModelV2
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from colossalai.zero.sharded_model._utils import cast_tensor_to_fp32
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from torch import Tensor
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from torch.distributed import ProcessGroup
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from torch.nn.parameter import Parameter
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from torch.optim import Optimizer
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from colossalai.gemini.stateful_tensor import (StatefulTensor, TensorState)
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from colossalai.gemini.tensor_placement_policy import AutoTensorPlacementPolicy
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class OptimState(Enum):
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SCALED = 1
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UNSCALED = 2
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class ShardedOptimizerV2(ColossalaiOptimizer):
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"""A wrapper for optimizer. ``ShardedOptimizerV2`` and ``ShardedModelV2`` implement Zero Redundancy Optimizer (ZeRO).
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By default the ZeRO optimizer stage 3 offload Optimizer States on CPU.
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We apply the Device-aware Operator Placement technique for OS placement from the following paper.
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`PatrickStar: Parallel Training of Pre-trained Models via Chunk-based Memory Management`_
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GPU margin space is the remaining space after removing peak non-model data from the overall GPU memory,
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which is detected by a runtime memory tracer.
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We place as many OS chunks in the margin space as possible.
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The size of margin space can be controlled by ``gpu_margin_mem_ratio``.
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If it is set as ``0.0``, it is the same as classical ZeRO optimizer.
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Note:
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You must use ``ShardedOptimizerV2`` with ``ShardedModelV2``.
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Note:
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Make sure you set ``tensor_placement_policy`` in ``ShardedModelV2`` to `"auto"`,
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if you set ``gpu_margin_mem_ratio > 0``.
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Args:
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sharded_model (ShardedModelV2): A sharded model initialized by class ShardedModelV2. The optimizer will use the
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shard strategy provided by sharded model to shard param fp32 tensors.
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optimizer (Optimizer): An Optimizer instance.
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gpu_margin_mem_ratio (float, optional): The ratio of GPU remaining memory (after the first forward-backward)
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which will be used when using hybrid CPU optimizer.
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This argument is meaningless when `tensor_placement_policy` of `ShardedModelV2` is not "auto".
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Defaults to 0.0.
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initial_scale (float, optional): Initial scale used by DynamicGradScaler. Defaults to 2**32.
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min_scale (float, optional): Min scale used by DynamicGradScaler. Defaults to 1.
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growth_factor (float, optional): growth_factor used by DynamicGradScaler. Defaults to 2.
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backoff_factor (float, optional): backoff_factor used by DynamicGradScaler. Defaults to 0.5.
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growth_interval (float, optional): growth_interval used by DynamicGradScaler. Defaults to 1000.
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hysteresis (float, optional): hysteresis used by DynamicGradScaler. Defaults to 2.
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max_scale (int, optional): max_scale used by DynamicGradScaler. Defaults to 2**32.
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dp_process_group (Optional[ProcessGroup], optional): data paralle process group. Defaults to None.
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mp_process_group (Optional[ProcessGroup], optional): model paralle process group. Defaults to None.
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.. _PatrickStar\: Parallel Training of Pre-trained Models via Chunk-based Memory Management:
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https://arxiv.org/abs/2108.05818
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"""
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def __init__(self,
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sharded_model: ShardedModelV2,
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optimizer: Optimizer,
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gpu_margin_mem_ratio: float = 0.0,
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initial_scale: float = 2**32,
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min_scale: float = 1,
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growth_factor: float = 2,
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backoff_factor: float = 0.5,
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growth_interval: int = 1000,
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hysteresis: int = 2,
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max_scale: float = 2**32,
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dp_process_group: Optional[ProcessGroup] = None,
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mp_process_group: Optional[ProcessGroup] = None,
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verbose: bool = False) -> None:
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assert isinstance(sharded_model, ShardedModelV2), 'model must be wrapped with ShardedModel'
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super().__init__(optimizer)
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self.shard_strategy = sharded_model.shard_strategy
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self.model: ShardedModelV2 = sharded_model
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self.gpu_margin_mem_ratio: float = float(gpu_margin_mem_ratio)
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assert 0.0 <= self.gpu_margin_mem_ratio <= 1.0, f'gpu_margin_mem_ratio must >=0.0 and <=1.0'
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# Only move fp32 shards from CPU to GPU when user allows and inner optimizer is valid
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# Inner optimizer must support optimizing hybrid (CPU and CUDA) tensors,
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# and it must set `num_fp32_shards_per_param` correctly
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self._should_move_fp32_shards_h2d: bool = sharded_model.cpu_offload and self.gpu_margin_mem_ratio > 0.0 and getattr(
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optimizer, 'num_fp32_shards_per_param', 0) >= 2
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self.device = sharded_model._tensor_placement_policy.device or torch.device('cpu')
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self.optim_state: OptimState = OptimState.UNSCALED
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self.dp_process_group = dp_process_group or gpc.get_group(ParallelMode.DATA)
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self.mp_process_group = mp_process_group or gpc.get_group(ParallelMode.MODEL)
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# Grad scaler
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self.grad_scaler = DynamicGradScaler(initial_scale=initial_scale,
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min_scale=min_scale,
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growth_factor=growth_factor,
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backoff_factor=backoff_factor,
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growth_interval=growth_interval,
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hysteresis=hysteresis,
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max_scale=max_scale)
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self._found_overflow: Tensor = torch.IntTensor([0]).to(torch.cuda.current_device())
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self._logger = get_dist_logger("ShardedOptimizerV2")
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self._verbose = verbose
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# Store fp32 param shards
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self._register_master_weight()
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if self.gpu_margin_mem_ratio != 0.0 and not isinstance(sharded_model._tensor_placement_policy,
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AutoTensorPlacementPolicy):
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self._logger.warning(f'gpu_margin_mem_ratio is meaningless when tensor_placement_policy is not "auto"',
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ranks=[0])
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if self._verbose:
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self._logger.debug(
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f"After init ShardedOptimizerV2 consumes {self.get_memory_usage()[0] / 1e6} MB CUDA Memory!", ranks=[0])
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self._use_memory_tracer = self.model.use_memory_tracer
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@property
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def loss_scale(self):
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return self.grad_scaler.scale.item()
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def get_memory_usage(self) -> Tuple[int, int]:
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""" Get the memory usage of the optimizer. Including master_params (param fp32),
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momentum (``self.state[p]['exp_avg']``) variance (``self.state[p]['exp_avg_sq']``)
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Returns:
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Tuple[int, int]: cuda/cpu memory usage in Byte.
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"""
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cuda_use = 0
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cpu_use = 0
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def update_mem_use(t):
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nonlocal cuda_use
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nonlocal cpu_use
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t_cuda_use, t_cpu_use = colo_tensor_mem_usage(t)
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cuda_use += t_cuda_use
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cpu_use += t_cpu_use
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for _, p_fp32 in self.master_params.items():
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update_mem_use(p_fp32)
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for group in self.optim.param_groups:
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for p in group['params']:
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state = self.optim.state[p]
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for k, v in state.items():
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update_mem_use(v)
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return cuda_use, cpu_use
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def zero_grad(self, *args, **kwargs):
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self._zero_grad()
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def backward(self, loss: Tensor) -> None:
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loss = self.loss_scale * loss
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self.optim_state = OptimState.SCALED
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self.model.backward(loss)
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def backward_by_grad(self, tensor: Tensor, grad: Tensor) -> None:
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self.model.backward_by_grad(tensor, grad)
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def clip_grad_norm(self, model: nn.Module, max_norm: float):
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if self.optim_state == OptimState.SCALED:
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self._unscale_grads()
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return super().clip_grad_norm(model, max_norm)
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def step(self, *args, **kwargs):
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self._prepare_grads()
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self._maybe_move_fp32_shards()
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# unscale grads if scaled
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if self.optim_state == OptimState.SCALED:
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self._unscale_grads()
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found_inf = self._check_overflow()
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self.grad_scaler.update(found_inf)
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if found_inf:
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self._logger.warning('found inf during ShardedOptimV2 step')
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self._zero_grad(recover_data=True)
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return
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self._point_param_fp16_to_master_param()
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if self._verbose:
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gpu_mem, cpu_mem = self.get_memory_usage()
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self._logger.debug(
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f"Before step ShardedOptimizerV2 consumes {gpu_mem / 1e6} MB CUDA Memory, {cpu_mem / 1e6} MB CUDA Memory!",
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ranks=[0])
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ret = self.optim.step(*args, **kwargs)
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if self._verbose:
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gpu_mem, cpu_mem = self.get_memory_usage()
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self._logger.debug(
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f"After step ShardedOptimizerV2 consumes {gpu_mem / 1e6} MB CUDA Memory, {cpu_mem / 1e6} MB CUDA Memory!",
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ranks=[0])
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self._copy_master_model_to_model_fp16()
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return ret
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def _check_overflow(self):
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# clear previous overflow record
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self._found_overflow.fill_(self.model.overflow_counter)
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# all-reduce across dp group
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dist.all_reduce(self._found_overflow, group=self.dp_process_group)
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# all-reduce over model parallel group
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dist.all_reduce(self._found_overflow, group=self.mp_process_group)
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return self._found_overflow.item() > 0
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def _unscale_grads(self):
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assert self.optim_state == OptimState.SCALED
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for group in self.optim.param_groups:
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for p in group['params']:
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if p.grad is not None:
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p.grad.data.div_(self.loss_scale)
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self.optim_state = OptimState.UNSCALED
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def _zero_grad(self, recover_data: bool = False):
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"""zero grad and maybe recover fp16 params
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When `reuse_fp16_shard` is enabled,
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p.colo_attr.sharded_data_tensor stores grad here.
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We have to recover them from fp32 params.
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Args:
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recover_data (bool, optional): Whether to recover fp16 param from fp32 param. Defaults to False.
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"""
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# We must set grad to None
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# Because grad here is sharded
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# But next backward pass will create a full grad first
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# Which leads to wrong accumulation
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self.optim.zero_grad(set_to_none=True)
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for group in self.optim.param_groups:
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for p in group['params']:
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# p.colo_attr.sharded_data_tensor stores grad now
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# we have to recover fp16 param
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reuse_fp16_shard = (p.colo_attr.sharded_data_tensor.payload_size == 0)
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if recover_data and reuse_fp16_shard:
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self._copy_master_param_to_param_fp16(p)
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else:
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# release saved gradient
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p.colo_attr.saved_grad.set_null()
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self.model.overflow_counter = 0 # set overflow counter to zero
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def sync_grad(self):
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pass
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def _register_master_weight(self):
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self.master_params: Dict[Parameter, StatefulTensor] = {}
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for group in self.optim.param_groups:
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for p in group['params']:
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assert hasattr(p, 'colo_attr'), 'The parameter must be wrapped with ShardedParam'
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shard_flag = not p.colo_attr.sharded_data_tensor.is_sharded and p.colo_attr.is_replicated
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if shard_flag:
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# we always shard replicated paramters
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self.shard_strategy.shard([p.colo_attr.sharded_data_tensor], self.dp_process_group)
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self.master_params[p] = StatefulTensor(cast_tensor_to_fp32(p.colo_attr.data_payload.to(self.device)))
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if shard_flag:
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# In this branch, there's no need to shard param
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# So we gather here
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self.shard_strategy.gather([p.colo_attr.sharded_data_tensor], self.dp_process_group)
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def _maybe_move_fp32_shards(self):
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if self._should_move_fp32_shards_h2d:
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self._should_move_fp32_shards_h2d = False
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available_cuda_margin_mem = self.model.cuda_margin_space * self.gpu_margin_mem_ratio
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fp32_shards_available_cuda_margin_mem = available_cuda_margin_mem / self.optim.num_fp32_shards_per_param
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fp32_shards_used_cuda_margin_mem = 0
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for group in self.optim.param_groups:
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for p in group['params']:
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shard_mem = self.master_params[p].payload.numel() * self.master_params[p].payload.element_size()
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if fp32_shards_used_cuda_margin_mem + shard_mem < fp32_shards_available_cuda_margin_mem:
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colo_model_data_tensor_move_inline(self.master_params[p], torch.cuda.current_device())
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colo_model_data_tensor_move_inline(p.colo_attr.saved_grad, torch.cuda.current_device())
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p.colo_attr.offload_grad = False
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fp32_shards_used_cuda_margin_mem += shard_mem
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def _prepare_grads(self):
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for group in self.optim.param_groups:
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for p in group['params']:
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if p.colo_attr.saved_grad.is_null():
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continue
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p.colo_attr.saved_grad.trans_state(TensorState.COMPUTE)
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# If reuse_fp16_shard, grad fp16 which wasn't be offloaded may be evicted to CPU
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if not p.colo_attr.offload_grad:
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colo_model_data_tensor_move_inline(p.colo_attr.saved_grad, torch.cuda.current_device())
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# FIXME(ver217): p.data here is an empty tensor on CUDA and has no useful infomation
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# If we change p.grad directly
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# it may raise error because of different shape/dtype/device of p.data and p.grad
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# We just set p.data = p.colo_attr.saved_grad.payload here
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p.data = p.colo_attr.grad_payload
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p.grad = p.colo_attr.grad_payload
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# Set p.data to empty tensor, in case of memory leaking
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p.colo_attr.set_data_none()
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def _point_param_fp16_to_master_param(self):
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# assign master param pointers to p.data.
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# We will not trigger data copy here.
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for group in self.optim.param_groups:
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for p in group['params']:
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self.master_params[p].trans_state(TensorState.COMPUTE)
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p.data = self.master_params[p].payload
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# Now p.data is sharded
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# So optimizer states are sharded naturally
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def _copy_master_model_to_model_fp16(self):
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# Copy master param data (fp32) to payload of colo_attr (fp16)
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# TODO() improve efficiency by gathering tensors into a chunk and transfering
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# a chunk.
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for group in self.optim.param_groups:
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for p in group['params']:
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self._copy_master_param_to_param_fp16(p)
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def _copy_master_param_to_param_fp16(self, p):
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# flush gradient
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if p.colo_attr.sharded_data_tensor.payload_size == 0:
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# here reuse_fp16_shard is True
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# in order to use copy below, we should give sharded data tensor a payload
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p.colo_attr.sharded_data_tensor.payload_relay(p.colo_attr.saved_grad)
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else:
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p.colo_attr.saved_grad.set_null()
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p.data = self.master_params[p].payload
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# we need to allocate new memory for keep_not_shard paramters
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# in order to use copy, otherwise, the sizes of tensor is not compatible
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if p.colo_attr.data_payload.numel() != p.data.numel():
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p.colo_attr.data_payload_reset(
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torch.empty(p.data.shape, dtype=p.colo_attr.data_payload.dtype, device=p.colo_attr.data_payload.device))
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# TODO() optimize this line CPU (fp32) -> GPU (fp16)
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p.colo_attr.sharded_data_tensor.payload_copy(p.half().detach())
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p.colo_attr.set_data_none()
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if p.colo_attr.keep_not_shard and p.colo_attr.is_replicated:
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# We gather full fp16 param here
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p.colo_attr.sharded_data_tensor.is_sharded = True # since only gradient is sharded, we should set to True
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self.shard_strategy.gather([p.colo_attr.sharded_data_tensor], self.dp_process_group)
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self.master_params[p].trans_state(TensorState.HOLD)
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