mirror of https://github.com/hpcaitech/ColossalAI
201 lines
8.1 KiB
Python
201 lines
8.1 KiB
Python
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# Copyright (c) Facebook, Inc. and its affiliates.
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#
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# This source code is licensed under the BSD license found in the
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# LICENSE file in the root directory of this source tree.
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import functools
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import os
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from typing import Callable, Dict, List, Optional, Tuple
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import torch
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import torch.distributed as dist
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from torch import Tensor
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from torch.distributed import ProcessGroup
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# TODO: Remove the toggle-enable_nccl_base_collectives when github open issue #801 is resolved.
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if os.getenv("ENABLE_NCCL_BASE_COLLECTIVES", "1") == "0":
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enable_nccl_base_collectives = False
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else:
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enable_nccl_base_collectives = True
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class Bucket:
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def __init__(self, shard_size: int, dtype: torch.dtype, device: torch.device, group: ProcessGroup):
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self.buffer = torch.zeros((group.size(), shard_size), dtype=dtype, device=device)
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self.group = group
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self.offset = 0
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self.callbacks: List[Callable] = []
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self.output_shard = torch.zeros_like(self.buffer[0])
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def flush(self) -> None:
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"""Flush content of the bucket."""
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if self.offset == 0:
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assert len(self.callbacks) == 0
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return
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# reduce-scatter bucket
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if hasattr(dist, "_reduce_scatter_base") and enable_nccl_base_collectives:
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dist._reduce_scatter_base(
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self.output_shard[: self.offset], self.buffer[:, : self.offset].contiguous(), group=self.group
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)
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else:
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dist.reduce_scatter(
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self.output_shard[: self.offset], list(self.buffer[:, : self.offset].unbind(0)), group=self.group
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)
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# execute post-reduction callbacks
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for callback_fn in self.callbacks:
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callback_fn()
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# reuse input bucket but allocate a fresh output shard
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self.buffer[:, : self.offset].zero_()
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self.offset = 0
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self.callbacks.clear()
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self.output_shard = torch.zeros_like(self.buffer[0])
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def alloc(self) -> None:
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"""Setup the buffers if they are not allocated.
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Using ``setup`` and ``teardown``, we can ensure that the bucket
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buffers are only allocated during the backward pass, hence saving more
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memory to other parts of the training process, such as the forward pass
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for activation memory.
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"""
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for tensor in [self.buffer, self.output_shard]:
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if tensor.storage().size() == 0:
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tensor.storage().resize_(tensor.size().numel())
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def free(self) -> None:
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"""Tear down the bucket by freeing the memory"""
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assert self.offset == 0 and self.callbacks == [], "Incorrect call of teardown"
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for tensor in [self.buffer, self.output_shard]:
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tensor.storage().resize_(0)
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def append(self, tensor_list: List[Tensor], callback_fn: Callable):
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# copy data from input_list into bucket
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tensor_size = tensor_list[0].numel()
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stacked_input = torch.stack(tensor_list).view(self.group.size(), tensor_size)
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offset = self.offset
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self.buffer[:, offset: offset + tensor_size].copy_(stacked_input)
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self.offset += tensor_size
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# callback will be given the reduced result
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if callback_fn is not None:
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result_view = self.output_shard[offset: offset + tensor_size].view_as(tensor_list[0])
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self.callbacks.append(functools.partial(callback_fn, result_view))
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class ReduceScatterBucketer:
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"""
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Helper for bucketing multiple reduce-scatter operations on small tensors
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into larger reduce-scatter ops to improve communication efficiency.
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Usage::
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bucketer = ReduceScatterBucketer()
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bucketer.reduce_scatter_async(
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small_tensors, callback_fn=lambda result: print("small")
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)
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bucketer.reduce_scatter_async(
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big_tensors, callback_fn=lambda result: print("big")
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)
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bucketer.reduce_scatter_async(
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more_small_tensors, callback_fn=lambda result: print("small2")
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)
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bucketer.flush() # callbacks only guaranteed to be called after flush()
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# Example output (note that it is out of order, due to bucketing):
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# big
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# small
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# small2
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Args:
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bucket_size_mb (int, Optional): bucket size for communicating. Buckets
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are sub-divided based on world_size. Values <= 0 disable bucketing.
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"""
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def __init__(self, bucket_size_mb: int = 25):
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self.bucket_size_mb = bucket_size_mb
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self.buckets: Dict[Tuple[torch.dtype, torch.device, ProcessGroup], Bucket] = {}
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@torch.no_grad()
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def reduce_scatter_async(
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self,
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input_list: List[Tensor],
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group: ProcessGroup,
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callback_fn: Optional[Callable] = None,
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) -> None:
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"""
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Reduce-scatter a list of tensors asynchronously, so smaller reductions
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can be bucketed together. The given callback (``callback_fn``) will be
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called with the reduced result at some later time. Call ``flush()`` to
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force all queued ops and callbacks to be executed.
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Note that large inputs will be reduced immediately, and this function
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may also flush the relevant bucket to make room for ``input_list``.
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Args:
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input_list (List[Tensor]): list of tensors to reduce-scatter. List
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should contain ``group.size()`` tensors and each tensor should
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have identical shape, dtype and device.
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group (ProcessGroup): process group for reduction
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callback_fn (Callable, Optional): callback function to call after
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the reduction executes. Function will be called with a single
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argument corresponding to the reduced result.
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"""
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world_size = group.size()
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assert (
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len(input_list) == world_size
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), f"reduce_scatter received {len(input_list)} inputs, expected group.size() ({world_size})"
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first_input = input_list[0]
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first_input_size = first_input.numel()
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bucket_shard_size = self._get_shard_size(first_input.element_size(), world_size)
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if first_input_size > bucket_shard_size:
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# TODO: investigate how to avoid using torch.cat (because it seems to be slow for CPU tensors)
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# input is too big to fit in the bucket, reduce-scatter directly
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output = torch.zeros_like(input_list[0])
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if hasattr(dist, "_reduce_scatter_base") and enable_nccl_base_collectives:
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input_flattened = torch.cat(input_list)
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dist._reduce_scatter_base(output, input_flattened, group=group)
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else:
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# fallback
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dist.reduce_scatter(output, input_list, group=group)
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if callback_fn is not None:
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callback_fn(output)
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return
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bucket = self._get_bucket(first_input, group)
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if first_input_size > bucket.buffer.size(1) - bucket.offset:
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# not enough space remaining in bucket, flush it now
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bucket.flush()
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bucket.append(input_list, callback_fn)
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@torch.no_grad()
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def flush(self) -> None:
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"""Reduce-scatter any partial buckets."""
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for bucket in self.buckets.values():
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bucket.flush()
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@torch.no_grad()
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def free(self) -> None:
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"""Free buffers from all buckets."""
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for bucket in self.buckets.values():
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bucket.free()
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@functools.lru_cache()
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def _get_shard_size(self, element_size: int, num_shards: int) -> int:
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if self.bucket_size_mb <= 0: # Values <= 0 disable bucketing.
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return 0
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MB = 1024 * 1024
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bucket_size = self.bucket_size_mb * MB / element_size
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return int(bucket_size // num_shards)
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def _get_bucket(self, tensor: Tensor, group: ProcessGroup) -> Bucket:
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key = (tensor.dtype, tensor.device, group)
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if key not in self.buckets:
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# buckets are divided into world_size pieces, bucket.data shaped (world_size, shard_size)
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world_size = group.size()
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shard_size = self._get_shard_size(tensor.element_size(), world_size)
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self.buckets[key] = Bucket(shard_size, tensor.dtype, tensor.device, group)
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self.buckets[key].alloc()
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return self.buckets[key]
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