nvlabs-sana / diffusion /utils /dist_utils.py
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# Copyright 2024 NVIDIA CORPORATION & 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.
#
# SPDX-License-Identifier: Apache-2.0
"""
This file contains primitives for multi-gpu communication.
This is useful when doing distributed training.
"""
import gc
import os
import pickle
import shutil
import mmcv
import torch
import torch.distributed as dist
from mmcv.runner import get_dist_info
def is_distributed():
return get_world_size() > 1
def get_world_size():
if not dist.is_available():
return 1
if not dist.is_initialized():
return 1
return dist.get_world_size()
def get_rank():
if not dist.is_available():
return 0
if not dist.is_initialized():
return 0
return dist.get_rank()
def get_local_rank():
if not dist.is_available():
return 0
if not dist.is_initialized():
return 0
local_rank = int(os.getenv("LOCAL_RANK", 0))
return local_rank
def is_master():
return get_rank() == 0
def is_local_master():
return get_local_rank() == 0
def get_local_proc_group(group_size=8):
world_size = get_world_size()
if world_size <= group_size or group_size == 1:
return None
assert (
world_size % group_size == 0
), f"world size ({world_size}) should be evenly divided by group size ({group_size})."
process_groups = getattr(get_local_proc_group, "process_groups", dict())
if group_size not in process_groups:
num_groups = dist.get_world_size() // group_size
groups = [list(range(i * group_size, (i + 1) * group_size)) for i in range(num_groups)]
process_groups.update({group_size: [torch.distributed.new_group(group) for group in groups]})
get_local_proc_group.process_groups = process_groups
group_idx = get_rank() // group_size
process_groups = get_local_proc_group.process_groups.get(group_size)[group_idx]
return process_groups
def synchronize():
"""
Helper function to synchronize (barrier) among all processes when
using distributed training
"""
if not dist.is_available():
return
if not dist.is_initialized():
return
world_size = dist.get_world_size()
if world_size == 1:
return
dist.barrier()
def all_gather(data):
"""
Run all_gather on arbitrary picklable data (not necessarily tensors)
Args:
data: any picklable object
Returns:
list[data]: list of data gathered from each rank
"""
to_device = torch.device("cuda")
# to_device = torch.device("cpu")
world_size = get_world_size()
if world_size == 1:
return [data]
# serialized to a Tensor
buffer = pickle.dumps(data)
storage = torch.ByteStorage.from_buffer(buffer)
tensor = torch.ByteTensor(storage).to(to_device)
# obtain Tensor size of each rank
local_size = torch.LongTensor([tensor.numel()]).to(to_device)
size_list = [torch.LongTensor([0]).to(to_device) for _ in range(world_size)]
dist.all_gather(size_list, local_size)
size_list = [int(size.item()) for size in size_list]
max_size = max(size_list)
# receiving Tensor from all ranks
# we pad the tensor because torch all_gather does not support
# gathering tensors of different shapes
tensor_list = []
for _ in size_list:
tensor_list.append(torch.ByteTensor(size=(max_size,)).to(to_device))
if local_size != max_size:
padding = torch.ByteTensor(size=(max_size - local_size,)).to(to_device)
tensor = torch.cat((tensor, padding), dim=0)
dist.all_gather(tensor_list, tensor)
data_list = []
for size, tensor in zip(size_list, tensor_list):
buffer = tensor.cpu().numpy().tobytes()[:size]
data_list.append(pickle.loads(buffer))
return data_list
def reduce_dict(input_dict, average=True):
"""
Args:
input_dict (dict): all the values will be reduced
average (bool): whether to do average or sum
Reduce the values in the dictionary from all processes so that process with rank
0 has the averaged results. Returns a dict with the same fields as
input_dict, after reduction.
"""
world_size = get_world_size()
if world_size < 2:
return input_dict
with torch.no_grad():
names = []
values = []
# sort the keys so that they are consistent across processes
for k in sorted(input_dict.keys()):
names.append(k)
values.append(input_dict[k])
values = torch.stack(values, dim=0)
dist.reduce(values, dst=0)
if dist.get_rank() == 0 and average:
# only main process gets accumulated, so only divide by
# world_size in this case
values /= world_size
reduced_dict = {k: v for k, v in zip(names, values)}
return reduced_dict
def broadcast(data, **kwargs):
if get_world_size() == 1:
return data
data = [data]
dist.broadcast_object_list(data, **kwargs)
return data[0]
def all_gather_cpu(result_part, tmpdir=None, collect_by_master=True):
rank, world_size = get_dist_info()
if tmpdir is None:
tmpdir = "./tmp"
if rank == 0:
mmcv.mkdir_or_exist(tmpdir)
synchronize()
# dump the part result to the dir
mmcv.dump(result_part, os.path.join(tmpdir, f"part_{rank}.pkl"))
synchronize()
# collect all parts
if collect_by_master and rank != 0:
return None
else:
# load results of all parts from tmp dir
results = []
for i in range(world_size):
part_file = os.path.join(tmpdir, f"part_{i}.pkl")
results.append(mmcv.load(part_file))
if not collect_by_master:
synchronize()
# remove tmp dir
if rank == 0:
shutil.rmtree(tmpdir)
return results
def all_gather_tensor(tensor, group_size=None, group=None):
if group_size is None:
group_size = get_world_size()
if group_size == 1:
output = [tensor]
else:
output = [torch.zeros_like(tensor) for _ in range(group_size)]
dist.all_gather(output, tensor, group=group)
return output
def gather_difflen_tensor(feat, num_samples_list, concat=True, group=None, group_size=None):
world_size = get_world_size()
if world_size == 1:
if not concat:
return [feat]
return feat
num_samples, *feat_dim = feat.size()
# padding to max number of samples
feat_padding = feat.new_zeros((max(num_samples_list), *feat_dim))
feat_padding[:num_samples] = feat
# gather
feat_gather = all_gather_tensor(feat_padding, group=group, group_size=group_size)
for r, num in enumerate(num_samples_list):
feat_gather[r] = feat_gather[r][:num]
if concat:
feat_gather = torch.cat(feat_gather)
return feat_gather
class GatherLayer(torch.autograd.Function):
"""Gather tensors from all process, supporting backward propagation."""
@staticmethod
def forward(ctx, input):
ctx.save_for_backward(input)
num_samples = torch.tensor(input.size(0), dtype=torch.long, device=input.device)
ctx.num_samples_list = all_gather_tensor(num_samples)
output = gather_difflen_tensor(input, ctx.num_samples_list, concat=False)
return tuple(output)
@staticmethod
def backward(ctx, *grads): # tuple(output)'s grad
(input,) = ctx.saved_tensors
num_samples_list = ctx.num_samples_list
rank = get_rank()
start, end = sum(num_samples_list[:rank]), sum(num_samples_list[: rank + 1])
grads = torch.cat(grads)
if is_distributed():
dist.all_reduce(grads)
grad_out = torch.zeros_like(input)
grad_out[:] = grads[start:end]
return grad_out, None, None
class GatherLayerWithGroup(torch.autograd.Function):
"""Gather tensors from all process, supporting backward propagation."""
@staticmethod
def forward(ctx, input, group, group_size):
ctx.save_for_backward(input)
ctx.group_size = group_size
output = all_gather_tensor(input, group=group, group_size=group_size)
return tuple(output)
@staticmethod
def backward(ctx, *grads): # tuple(output)'s grad
(input,) = ctx.saved_tensors
grads = torch.stack(grads)
if is_distributed():
dist.all_reduce(grads)
grad_out = torch.zeros_like(input)
grad_out[:] = grads[get_rank() % ctx.group_size]
return grad_out, None, None
def gather_layer_with_group(data, group=None, group_size=None):
if group_size is None:
group_size = get_world_size()
output = GatherLayer.apply(data, group, group_size)
return output
import math
from typing import Union
# from torch.distributed.fsdp.fully_sharded_data_parallel import TrainingState_, _calc_grad_norm
@torch.no_grad()
def clip_grad_norm_(self, max_norm: Union[float, int], norm_type: Union[float, int] = 2.0) -> None:
self._lazy_init()
self._wait_for_previous_optim_step()
assert self._is_root, "clip_grad_norm should only be called on the root (parent) instance"
self._assert_state(TrainingState_.IDLE)
max_norm = float(max_norm)
norm_type = float(norm_type)
# Computes the max norm for this shard's gradients and sync's across workers
local_norm = _calc_grad_norm(self.params_with_grad, norm_type).cuda() # type: ignore[arg-type]
if norm_type == math.inf:
total_norm = local_norm
dist.all_reduce(total_norm, op=torch.distributed.ReduceOp.MAX, group=self.process_group)
else:
total_norm = local_norm**norm_type
dist.all_reduce(total_norm, group=self.process_group)
total_norm = total_norm ** (1.0 / norm_type)
clip_coef = torch.tensor(max_norm, dtype=total_norm.dtype, device=total_norm.device) / (total_norm + 1e-6)
if clip_coef < 1:
# multiply by clip_coef, aka, (max_norm/total_norm).
for p in self.params_with_grad:
assert p.grad is not None
p.grad.detach().mul_(clip_coef.to(p.grad.device))
return total_norm
def flush():
gc.collect()
torch.cuda.empty_cache()