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Created November 12, 2018 23:08
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Data Parallelism in PyTorch for modules and losses
##+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
## Created by: Hang Zhang, Rutgers University, Email: [email protected]
## Modified by Thomas Wolf, HuggingFace Inc., Email: [email protected]
## Copyright (c) 2017-2018
##
## This source code is licensed under the MIT-style license found in the
## LICENSE file in the root directory of this source tree
##+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
"""Encoding Data Parallel"""
import threading
import functools
import torch
from torch.autograd import Variable, Function
import torch.cuda.comm as comm
from torch.nn.parallel.data_parallel import DataParallel
from torch.nn.parallel.parallel_apply import get_a_var
from torch.nn.parallel.scatter_gather import gather
from torch.nn.parallel._functions import ReduceAddCoalesced, Broadcast
torch_ver = torch.__version__[:3]
__all__ = ['allreduce', 'DataParallelModel', 'DataParallelCriterion',
'patch_replication_callback']
def allreduce(*inputs):
"""Cross GPU all reduce autograd operation for calculate mean and
variance in SyncBN.
"""
return AllReduce.apply(*inputs)
class AllReduce(Function):
@staticmethod
def forward(ctx, num_inputs, *inputs):
ctx.num_inputs = num_inputs
ctx.target_gpus = [inputs[i].get_device() for i in range(0, len(inputs), num_inputs)]
inputs = [inputs[i:i + num_inputs]
for i in range(0, len(inputs), num_inputs)]
# sort before reduce sum
inputs = sorted(inputs, key=lambda i: i[0].get_device())
results = comm.reduce_add_coalesced(inputs, ctx.target_gpus[0])
outputs = comm.broadcast_coalesced(results, ctx.target_gpus)
return tuple([t for tensors in outputs for t in tensors])
@staticmethod
def backward(ctx, *inputs):
inputs = [i.data for i in inputs]
inputs = [inputs[i:i + ctx.num_inputs]
for i in range(0, len(inputs), ctx.num_inputs)]
results = comm.reduce_add_coalesced(inputs, ctx.target_gpus[0])
outputs = comm.broadcast_coalesced(results, ctx.target_gpus)
return (None,) + tuple([Variable(t) for tensors in outputs for t in tensors])
class Reduce(Function):
@staticmethod
def forward(ctx, *inputs):
ctx.target_gpus = [inputs[i].get_device() for i in range(len(inputs))]
inputs = sorted(inputs, key=lambda i: i.get_device())
return comm.reduce_add(inputs)
@staticmethod
def backward(ctx, gradOutput):
return Broadcast.apply(ctx.target_gpus, gradOutput)
class DistributedDataParallelModel(DistributedDataParallel):
"""Implements data parallelism at the module level for the DistributedDataParallel module.
This container parallelizes the application of the given module by
splitting the input across the specified devices by chunking in the
batch dimension.
In the forward pass, the module is replicated on each device,
and each replica handles a portion of the input. During the backwards pass,
gradients from each replica are summed into the original module.
Note that the outputs are not gathered, please use compatible
:class:`encoding.parallel.DataParallelCriterion`.
The batch size should be larger than the number of GPUs used. It should
also be an integer multiple of the number of GPUs so that each chunk is
the same size (so that each GPU processes the same number of samples).
Args:
module: module to be parallelized
device_ids: CUDA devices (default: all devices)
Reference:
Hang Zhang, Kristin Dana, Jianping Shi, Zhongyue Zhang, Xiaogang Wang, Ambrish Tyagi,
Amit Agrawal. “Context Encoding for Semantic Segmentation.
*The IEEE Conference on Computer Vision and Pattern Recognition (CVPR) 2018*
Example::
>>> net = encoding.nn.DistributedDataParallelModel(model, device_ids=[0, 1, 2])
>>> y = net(x)
"""
def gather(self, outputs, output_device):
return outputs
class DataParallelModel(DataParallel):
"""Implements data parallelism at the module level.
This container parallelizes the application of the given module by
splitting the input across the specified devices by chunking in the
batch dimension.
In the forward pass, the module is replicated on each device,
and each replica handles a portion of the input. During the backwards pass,
gradients from each replica are summed into the original module.
Note that the outputs are not gathered, please use compatible
:class:`encoding.parallel.DataParallelCriterion`.
The batch size should be larger than the number of GPUs used. It should
also be an integer multiple of the number of GPUs so that each chunk is
the same size (so that each GPU processes the same number of samples).
Args:
module: module to be parallelized
device_ids: CUDA devices (default: all devices)
Reference:
Hang Zhang, Kristin Dana, Jianping Shi, Zhongyue Zhang, Xiaogang Wang, Ambrish Tyagi,
Amit Agrawal. “Context Encoding for Semantic Segmentation.
*The IEEE Conference on Computer Vision and Pattern Recognition (CVPR) 2018*
Example::
>>> net = encoding.nn.DataParallelModel(model, device_ids=[0, 1, 2])
>>> y = net(x)
"""
def gather(self, outputs, output_device):
return outputs
def replicate(self, module, device_ids):
modules = super(DataParallelModel, self).replicate(module, device_ids)
execute_replication_callbacks(modules)
return modules
class DataParallelCriterion(DataParallel):
"""
Calculate loss in multiple-GPUs, which balance the memory usage.
The targets are splitted across the specified devices by chunking in
the batch dimension. Please use together with :class:`encoding.parallel.DataParallelModel`.
Reference:
Hang Zhang, Kristin Dana, Jianping Shi, Zhongyue Zhang, Xiaogang Wang, Ambrish Tyagi,
Amit Agrawal. “Context Encoding for Semantic Segmentation.
*The IEEE Conference on Computer Vision and Pattern Recognition (CVPR) 2018*
Example::
>>> net = encoding.nn.DataParallelModel(model, device_ids=[0, 1, 2])
>>> criterion = encoding.nn.DataParallelCriterion(criterion, device_ids=[0, 1, 2])
>>> y = net(x)
>>> loss = criterion(y, target)
"""
def forward(self, inputs, *targets, **kwargs):
# input should be already scatterd
# scattering the targets instead
if not self.device_ids:
return self.module(inputs, *targets, **kwargs)
targets, kwargs = self.scatter(targets, kwargs, self.device_ids)
if len(self.device_ids) == 1:
return self.module(inputs, *targets[0], **kwargs[0])
replicas = self.replicate(self.module, self.device_ids[:len(inputs)])
outputs = _criterion_parallel_apply(replicas, inputs, targets, kwargs)
#return Reduce.apply(*outputs) / len(outputs)
#return self.gather(outputs, self.output_device).mean()
return self.gather(outputs, self.output_device)
def _criterion_parallel_apply(modules, inputs, targets, kwargs_tup=None, devices=None):
assert len(modules) == len(inputs)
assert len(targets) == len(inputs)
if kwargs_tup:
assert len(modules) == len(kwargs_tup)
else:
kwargs_tup = ({},) * len(modules)
if devices is not None:
assert len(modules) == len(devices)
else:
devices = [None] * len(modules)
lock = threading.Lock()
results = {}
if torch_ver != "0.3":
grad_enabled = torch.is_grad_enabled()
def _worker(i, module, input, target, kwargs, device=None):
if torch_ver != "0.3":
torch.set_grad_enabled(grad_enabled)
if device is None:
device = get_a_var(input).get_device()
try:
with torch.cuda.device(device):
# this also avoids accidental slicing of `input` if it is a Tensor
if not isinstance(input, (list, tuple)):
input = (input,)
if not isinstance(target, (list, tuple)):
target = (target,)
output = module(*(input + target), **kwargs)
with lock:
results[i] = output
except Exception as e:
with lock:
results[i] = e
if len(modules) > 1:
threads = [threading.Thread(target=_worker,
args=(i, module, input, target,
kwargs, device),)
for i, (module, input, target, kwargs, device) in
enumerate(zip(modules, inputs, targets, kwargs_tup, devices))]
for thread in threads:
thread.start()
for thread in threads:
thread.join()
else:
_worker(0, modules[0], inputs[0], kwargs_tup[0], devices[0])
outputs = []
for i in range(len(inputs)):
output = results[i]
if isinstance(output, Exception):
raise output
outputs.append(output)
return outputs
###########################################################################
# Adapted from Synchronized-BatchNorm-PyTorch.
# https://github.com/vacancy/Synchronized-BatchNorm-PyTorch
#
class CallbackContext(object):
pass
def execute_replication_callbacks(modules):
"""
Execute an replication callback `__data_parallel_replicate__` on each module created
by original replication.
The callback will be invoked with arguments `__data_parallel_replicate__(ctx, copy_id)`
Note that, as all modules are isomorphism, we assign each sub-module with a context
(shared among multiple copies of this module on different devices).
Through this context, different copies can share some information.
We guarantee that the callback on the master copy (the first copy) will be called ahead
of calling the callback of any slave copies.
"""
master_copy = modules[0]
nr_modules = len(list(master_copy.modules()))
ctxs = [CallbackContext() for _ in range(nr_modules)]
for i, module in enumerate(modules):
for j, m in enumerate(module.modules()):
if hasattr(m, '__data_parallel_replicate__'):
m.__data_parallel_replicate__(ctxs[j], i)
def patch_replication_callback(data_parallel):
"""
Monkey-patch an existing `DataParallel` object. Add the replication callback.
Useful when you have customized `DataParallel` implementation.
Examples:
> sync_bn = SynchronizedBatchNorm1d(10, eps=1e-5, affine=False)
> sync_bn = DataParallel(sync_bn, device_ids=[0, 1])
> patch_replication_callback(sync_bn)
# this is equivalent to
> sync_bn = SynchronizedBatchNorm1d(10, eps=1e-5, affine=False)
> sync_bn = DataParallelWithCallback(sync_bn, device_ids=[0, 1])
"""
assert isinstance(data_parallel, DataParallel)
old_replicate = data_parallel.replicate
@functools.wraps(old_replicate)
def new_replicate(module, device_ids):
modules = old_replicate(module, device_ids)
execute_replication_callbacks(modules)
return modules
data_parallel.replicate = new_replicate
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