mirror of https://github.com/hpcaitech/ColossalAI
492 lines
18 KiB
Python
492 lines
18 KiB
Python
#!/usr/bin/env python
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# -*- encoding: utf-8 -*-
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import functools
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import os
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import random
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import socket
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from collections import defaultdict
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from contextlib import contextmanager
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from pathlib import Path
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from typing import Callable, Dict, List, Optional, Union
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import torch
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import torch.distributed as dist
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from torch import inf
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from torch.nn.parameter import Parameter
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from colossalai.constants import IS_TENSOR_PARALLEL, NUM_PARTITIONS, TENSOR_PARALLEL_ATTRIBUTES
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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.global_variables import tensor_parallel_env as env
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from colossalai.tensor import ColoParameter, ProcessGroup
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from .multi_tensor_apply import multi_tensor_applier
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try:
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from colossalai._C import fused_optim
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except:
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fused_optim = None
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def print_rank_0(msg: str, logger=None):
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"""Print messages and save logs(optional). This is executed only if you are the rank-0 gpu.
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Args:
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msg (str): A string message to output.
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logger (:class:`colossalai.logging.DistributedLogger`, optional):
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The logger to record the message, defaults to None.
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"""
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if gpc.get_global_rank() == 0:
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if logger is None:
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print(msg, flush=True)
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else:
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logger.info(msg)
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def ensure_path_exists(filename: str):
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# ensure the path exists
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dirpath = os.path.dirname(filename)
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if not os.path.exists(dirpath):
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Path(dirpath).mkdir(parents=True, exist_ok=True)
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def sync_model_param(model, parallel_mode):
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r"""Make sure data parameters are consistent during Data Parallel Mode.
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Args:
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model (:class:`torch.nn.Module`): A pyTorch model on whose parameters you check the consistency.
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parallel_mode (:class:`colossalai.context.ParallelMode`): Parallel mode to be checked.
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Note:
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The parallel_mode should be concluded in ``ParallelMode``. More details about ``ParallelMode`` could be found
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in `parallel_mode <https://github.com/hpcaitech/ColossalAI/blob/main/colossalai/context/parallel_mode.py>`_
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"""
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if gpc.is_initialized(parallel_mode) and gpc.get_world_size(parallel_mode) > 1:
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for param in model.parameters():
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ranks = gpc.get_ranks_in_group(parallel_mode)
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dist.broadcast(param, src=ranks[0], group=gpc.get_group(parallel_mode))
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def is_dp_rank_0():
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return not gpc.is_initialized(ParallelMode.DATA) or gpc.is_first_rank(ParallelMode.DATA)
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def is_tp_rank_0():
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return not gpc.is_initialized(ParallelMode.TENSOR) or gpc.is_first_rank(ParallelMode.TENSOR)
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def is_no_pp_or_last_stage():
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return not gpc.is_initialized(ParallelMode.PIPELINE) or gpc.is_last_rank(ParallelMode.PIPELINE)
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def is_using_ddp():
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return gpc.is_initialized(ParallelMode.DATA) and gpc.get_world_size(ParallelMode.DATA) > 1
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def is_using_pp():
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return gpc.is_initialized(ParallelMode.PIPELINE) and gpc.get_world_size(ParallelMode.PIPELINE) > 1
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def is_using_sequence():
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return gpc.is_initialized(ParallelMode.SEQUENCE) and gpc.get_world_size(ParallelMode.SEQUENCE) > 1
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@contextmanager
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def conditional_context(context_manager, enable=True):
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if enable:
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with context_manager:
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yield
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else:
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yield
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class model_branch_context(object):
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def __enter__(self):
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self.env_status = env.save()
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def __exit__(self, *exc_info):
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env.load(**self.env_status)
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def is_model_parallel_parameter(p):
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return hasattr(p, IS_TENSOR_PARALLEL) and getattr(p, IS_TENSOR_PARALLEL)
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def is_ddp_ignored(p):
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return getattr(p, '_ddp_to_ignore', False)
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def _calc_l2_norm(grads):
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# we should not
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global fused_optim
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if fused_optim is None:
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from colossalai.kernel.op_builder import FusedOptimBuilder
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fused_optim = FusedOptimBuilder().load()
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norm = 0.0
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if len(grads) > 0:
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dummy_overflow_buf = torch.cuda.IntTensor([0])
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norm, _ = multi_tensor_applier(
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fused_optim.multi_tensor_l2norm,
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dummy_overflow_buf,
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[grads],
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False # no per-parameter norm
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)
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return norm
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def _calc_lp(grads, norm_type):
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norm = 0.0
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for grad in grads:
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grad_norm = torch.norm(grad, norm_type)
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norm += grad_norm**norm_type
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return norm
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def _move_norm_to_cuda(norm: Union[float, torch.Tensor]) -> Union[float, torch.Tensor]:
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if torch.is_tensor(norm) and norm.device.type != 'cuda':
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norm = norm.to(torch.cuda.current_device())
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return norm
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def _get_tensor_norm(norm: Union[float, torch.Tensor], move_to_cuda) -> torch.Tensor:
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if isinstance(norm, float):
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norm = torch.Tensor([norm])
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if move_to_cuda:
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norm = norm.to(torch.cuda.current_device())
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return norm
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# ======== Gradient Clipping =========
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def _compute_local_lp(params: List[ColoParameter], norm_type: float) -> float:
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if len(params) == 0:
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return 0.0
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grads = [p.grad for p in params]
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use_cuda_kernel = grads[0].device.type == 'cuda'
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if norm_type == inf:
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local_lp = max([g.abs().max() for g in grads])
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elif norm_type == 2.0 and use_cuda_kernel:
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local_lp = _calc_l2_norm(grads)**norm_type
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else:
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local_lp = _calc_lp(grads, norm_type)
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if isinstance(local_lp, torch.Tensor):
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return local_lp.item()
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return local_lp
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def _compute_buckets_lp(params: List[ColoParameter], norm_type: float) -> float:
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if len(params) == 0:
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return 0.0
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buckets: Dict[Optional[ProcessGroup], List[ColoParameter]] = defaultdict(list)
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for p in params:
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if p.is_replicate():
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buckets[None].append(p)
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else:
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buckets[p.get_process_group().tp_process_group()].append(p)
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total_lp = 0.0
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for group, bucket in buckets.items():
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local_lp = _compute_local_lp(bucket, norm_type)
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if group is not None:
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local_lp_tensor = torch.tensor([local_lp], device=torch.cuda.current_device())
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if norm_type == inf:
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dist.all_reduce(local_lp_tensor, op=dist.ReduceOp.MAX, group=group)
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else:
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dist.all_reduce(local_lp_tensor, group=group)
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local_lp = local_lp_tensor.item()
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if norm_type == inf:
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total_lp = max(total_lp, local_lp)
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else:
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total_lp += local_lp
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return total_lp
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def _compute_pp_grad_lp(total_lp: float, norm_type: float) -> float:
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if gpc.is_initialized(ParallelMode.PIPELINE) and gpc.get_world_size(ParallelMode.PIPELINE) > 1:
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total_lp_tensor = torch.tensor([total_lp], device=torch.cuda.current_device())
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if norm_type == inf:
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dist.all_reduce(total_lp_tensor, op=dist.ReduceOp.MAX, group=gpc.get_group(ParallelMode.PIPELINE))
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else:
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dist.all_reduce(total_lp_tensor, group=gpc.get_group(ParallelMode.PIPELINE))
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total_lp = total_lp_tensor.item()
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return total_lp
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def _compute_grad_lp(parameters, norm_type: float = 2.0) -> float:
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if isinstance(parameters, torch.Tensor):
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parameters = [parameters]
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grad_dtype = None
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cpu_grad_params: List[ColoParameter] = []
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cuda_grad_params: List[ColoParameter] = []
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for p in parameters:
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if p.grad is None:
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continue
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assert isinstance(p, ColoParameter)
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if grad_dtype is None:
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grad_dtype = p.grad.dtype
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assert p.grad.dtype == grad_dtype, f'Expected all grads are {grad_dtype}, got {p.grad.dtype}'
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if p.grad.device.type == 'cuda':
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cuda_grad_params.append(p)
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else:
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cpu_grad_params.append(p)
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norm_type = float(norm_type)
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cpu_lp = _compute_buckets_lp(cpu_grad_params, norm_type)
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cuda_lp = _compute_buckets_lp(cuda_grad_params, norm_type)
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if norm_type == inf:
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total_lp = max(cpu_lp, cuda_lp)
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else:
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total_lp = cpu_lp + cuda_lp
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return _compute_pp_grad_lp(total_lp, norm_type)
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def compute_grad_norm(parameters, norm_type: float = 2.0) -> float:
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norm_type = float(norm_type)
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total_norm = _compute_grad_lp(parameters, norm_type)
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if norm_type != inf:
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total_norm = total_norm**(1 / norm_type)
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return total_norm
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def _clip_grad_norm(parameters, max_norm: float, total_norm: float) -> None:
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clip_coef = max_norm / (total_norm + 1e-6)
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if clip_coef < 1.0:
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cuda_grads: List[torch.Tensor] = []
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cpu_grads: List[torch.Tensor] = []
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if isinstance(parameters, torch.Tensor):
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parameters = [parameters]
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for p in parameters:
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if p.grad is None:
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continue
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if p.grad.device.type == 'cuda':
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cuda_grads.append(p.grad.detach())
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else:
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cpu_grads.append(p.grad.detach())
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if len(cuda_grads) > 0:
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dummy_overflow_buf = torch.cuda.IntTensor([0])
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multi_tensor_applier(fused_optim.multi_tensor_scale, dummy_overflow_buf, [cuda_grads, cuda_grads],
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clip_coef)
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for g in cpu_grads:
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g.mul_(clip_coef)
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def clip_grad_norm(parameters, max_norm: float, norm_type: float = 2.0) -> float:
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total_norm = compute_grad_norm(parameters, norm_type)
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_clip_grad_norm(parameters, max_norm, total_norm)
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return total_norm
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def clip_grad_norm_fp32(parameters, max_norm, norm_type=2):
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"""Clips gradient norm of an iterable of parameters whose gradients are in fp32.
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This is adapted from :func:`torch.nn.utils.clip_grad.clip_grad_norm_` and
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added functionality to handle model parallel parameters.
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Note:
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the gradients are modified in place.
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Args:
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parameters (Iterable[:class:`torch.tensor`] or :class:`torch.tensor`):
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An iterable of Tensors or a single Tensor that will have gradients normalized.
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max_norm (Union[float, int]): Max norm of the gradients.
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norm_type (Union[float, int, 'inf']): Type of the used p-norm. Can be ``'inf'`` for infinity norm.
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Returns:
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float: Total norm of the parameters.
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"""
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if isinstance(parameters, torch.Tensor):
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parameters = [parameters]
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# Filter parameters based on:
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# - grad should not be none
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# - parameter should not be shared
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# - should not be a replica due to tensor model parallelism
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params: List[Parameter] = []
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has_zero_shared_param: bool = False
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for param in parameters:
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if param.grad is not None:
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# Make sure the grads are in fp32
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assert param.grad.dtype == torch.float, \
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f'expected gradient to be dtype torch.float, but got {param.grad.type()}'
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if hasattr(param, 'colo_attr') and param.colo_attr.sharded_data_tensor.is_sharded:
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has_zero_shared_param = True
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params.append(param)
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if len(params) == 0:
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enable_cuda_kernels = False
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else:
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enable_cuda_kernels = params[0].grad.device.type == 'cuda'
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# Norm parameters.
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max_norm = float(max_norm)
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norm_type = float(norm_type)
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# Parameters can be on CPU or CUDA
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# If parameters are on CPU, disable CUDA kernels
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# Calculate norm.
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if norm_type == inf:
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total_norm = max(p.grad.data.abs().max() for p in params)
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total_norm_cuda = torch.cuda.FloatTensor([float(total_norm)])
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# Take max across all model-parallel GPUs.
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if gpc.is_initialized(ParallelMode.MODEL) and gpc.get_world_size(ParallelMode.MODEL) > 1:
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dist.all_reduce(total_norm_cuda,
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op=dist.ReduceOp.MAX,
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group=gpc.get_group(ParallelMode.MODEL),
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async_op=False)
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if has_zero_shared_param:
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dist.all_reduce(total_norm_cuda,
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op=dist.ReduceOp.MAX,
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group=gpc.get_group(ParallelMode.DATA),
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async_op=False)
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total_norm = total_norm_cuda[0].item()
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else:
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tensor_parallel_grads = []
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no_tensor_parallel_grads = []
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zero_sharded_grads = []
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for p in params:
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if is_model_parallel_parameter(p):
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reductor = (gpc.get_world_size(ParallelMode.TENSOR) / getattr(p, NUM_PARTITIONS))**(1 / norm_type)
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tensor_parallel_grads.append(p.grad.data / reductor)
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elif hasattr(p, 'colo_attr') and p.colo_attr.sharded_data_tensor.is_sharded:
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zero_sharded_grads.append(p.grad.data)
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else:
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no_tensor_parallel_grads.append(p.grad.data)
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if norm_type == 2.0 and enable_cuda_kernels:
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tensor_parallel_norm = _calc_l2_norm(tensor_parallel_grads)**norm_type
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no_tensor_parallel_norm = _calc_l2_norm(no_tensor_parallel_grads)**norm_type
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zero_sharded_norm = _calc_l2_norm(zero_sharded_grads)**norm_type
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else:
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tensor_parallel_norm = _calc_lp(tensor_parallel_grads, norm_type)
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no_tensor_parallel_norm = _calc_lp(no_tensor_parallel_grads, norm_type)
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zero_sharded_norm = _calc_lp(zero_sharded_grads, norm_type)
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# If norm is type of float, then we convert them into torch.Tensor.
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tensor_parallel_norm = _get_tensor_norm(tensor_parallel_norm, enable_cuda_kernels)
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no_tensor_parallel_norm = _get_tensor_norm(no_tensor_parallel_norm, enable_cuda_kernels)
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zero_sharded_norm = _get_tensor_norm(zero_sharded_norm, enable_cuda_kernels)
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# If grads are on CPU, the norms is also on CPU. Cast them to CUDA tensors
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if not enable_cuda_kernels:
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tensor_parallel_norm = _move_norm_to_cuda(tensor_parallel_norm)
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no_tensor_parallel_norm = _move_norm_to_cuda(no_tensor_parallel_norm)
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zero_sharded_norm = _move_norm_to_cuda(zero_sharded_norm)
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# Sum across all model-parallel GPUs.
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if gpc.is_initialized(ParallelMode.TENSOR) and len(tensor_parallel_grads) > 0:
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dist.all_reduce(tensor_parallel_norm, op=dist.ReduceOp.SUM, group=gpc.get_group(ParallelMode.TENSOR))
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# Sum across all zero sharded GPUs
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if len(zero_sharded_grads) > 0:
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dist.all_reduce(zero_sharded_norm, group=gpc.get_group(ParallelMode.DATA))
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no_tensor_parallel_norm += zero_sharded_norm
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total_norm = tensor_parallel_norm + no_tensor_parallel_norm
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if gpc.is_initialized(ParallelMode.PIPELINE) and gpc.get_world_size(ParallelMode.PIPELINE) > 1:
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dist.all_reduce(total_norm, op=dist.ReduceOp.SUM, group=gpc.get_group(ParallelMode.PIPELINE))
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total_norm = total_norm**(1.0 / norm_type)
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if torch.is_tensor(total_norm):
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total_norm = total_norm.item()
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# Scale.
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clip_coeff = max_norm / (total_norm + 1.0e-6)
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if clip_coeff < 1.0:
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if enable_cuda_kernels:
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grads = [p.grad.detach() for p in params]
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dummy_overflow_buf = torch.cuda.IntTensor([0])
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multi_tensor_applier(fused_optim.multi_tensor_scale, dummy_overflow_buf, [grads, grads], clip_coeff)
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else:
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for p in params:
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p.grad.detach().mul_(clip_coeff)
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return total_norm
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def count_zeros_fp32(parameters):
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if isinstance(parameters, torch.Tensor):
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parameters = [parameters]
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# Filter parameters based on:
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# - grad should not be none
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# - parameter should not be shared
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# - should not be a replica due to tensor model parallelism
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total_num_zeros = 0.0
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for param in parameters:
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grad_not_none = param.grad is not None
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is_not_tp_duplicate = param_is_not_tensor_parallel_duplicate(param)
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if grad_not_none and is_not_tp_duplicate:
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grad = param.grad.detach()
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num_zeros = grad.numel() - torch.count_nonzero(grad)
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total_num_zeros = num_zeros + total_num_zeros
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total_num_zeros = torch.IntTensor([int(total_num_zeros)]).cuda()
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# Sum across all model-parallel GPUs.
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ops = []
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ops.append(
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dist.all_reduce(total_num_zeros, op=dist.ReduceOp.SUM, group=gpc.get_group(ParallelMode.TENSOR), async_op=True))
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if gpc.is_initialized(ParallelMode.PIPELINE):
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ops.append(
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dist.all_reduce(total_num_zeros,
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op=dist.ReduceOp.SUM,
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group=gpc.get_group(ParallelMode.PIPELINE),
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async_op=True))
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for req in ops:
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req.wait()
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total_num_zeros = total_num_zeros.item()
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return total_num_zeros
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def copy_tensor_parallel_attributes(src_tensor, dst_tensor):
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for attr in TENSOR_PARALLEL_ATTRIBUTES:
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if hasattr(src_tensor, attr):
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val = getattr(src_tensor, attr)
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setattr(dst_tensor, attr, val)
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def param_is_not_tensor_parallel_duplicate(param):
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return (hasattr(param, IS_TENSOR_PARALLEL) and getattr(param, IS_TENSOR_PARALLEL)) or (gpc.get_local_rank(
|
|
ParallelMode.TENSOR) == 0)
|
|
|
|
|
|
@contextmanager
|
|
def switch_virtual_pipeline_parallel_rank(rank):
|
|
prev_rank = gpc.virtual_pipeline_parallel_rank
|
|
try:
|
|
gpc.set_virtual_pipeline_parallel_rank(rank)
|
|
yield
|
|
finally:
|
|
gpc.set_virtual_pipeline_parallel_rank(prev_rank)
|
|
|
|
|
|
def disposable(func: Callable) -> Callable:
|
|
executed = False
|
|
|
|
@functools.wraps(func)
|
|
def wrapper(*args, **kwargs):
|
|
nonlocal executed
|
|
if not executed:
|
|
executed = True
|
|
return func(*args, **kwargs)
|
|
|
|
return wrapper
|
|
|
|
|
|
def free_storage(data: torch.Tensor) -> None:
|
|
"""Free underlying storage of a Tensor."""
|
|
if data.storage().size() > 0:
|
|
# Since we're modifying the Tensor's Storage directly, make sure the Tensor
|
|
# is the sole occupant of the Storage.
|
|
assert data.storage_offset() == 0
|
|
data.storage().resize_(0)
|
|
|
|
|
|
def _cast_float(args, dtype: torch.dtype):
|
|
if isinstance(args, torch.Tensor) and torch.is_floating_point(args):
|
|
args = args.to(dtype)
|
|
elif isinstance(args, (list, tuple)):
|
|
args = type(args)(_cast_float(t, dtype) for t in args)
|
|
elif isinstance(args, dict):
|
|
args = {k: _cast_float(v, dtype) for k, v in args.items()}
|
|
return args
|