torch/nn/parallel/distributed.py - platform/external/pytorch - Git at Google

 from contextlib import contextmanager
 import copy
 import itertools

 import torch

 import torch.cuda.comm
 import torch.distributed as dist

 if dist.is_available():
     from torch.distributed.distributed_c10d import _get_default_group

 from ..modules import Module
 from .replicate import replicate
 from .scatter_gather import scatter_kwargs, gather
 from .parallel_apply import parallel_apply
 from torch.cuda._utils import _get_device_index


 def _find_tensors(obj):
     r"""
     Recursively find all tensors contained in the specified object.
     """
     if isinstance(obj, torch.Tensor):
         return [obj]
     if isinstance(obj, (list, tuple)):
         return itertools.chain(*map(_find_tensors, obj))
     if isinstance(obj, dict):
         return itertools.chain(*map(_find_tensors, obj.values()))
     return []


 class DistributedDataParallel(Module):
     r"""Implements distributed data parallelism that is based on
     ``torch.distributed`` package 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. The module is replicated on each machine and each device, and
     each such replica handles a portion of the input. During the backwards
     pass, gradients from each node are averaged.

     The batch size should be larger than the number of GPUs used locally.

     See also: :ref:`distributed-basics` and :ref:`cuda-nn-dataparallel-instead`.
     The same constraints on input as in :class:`torch.nn.DataParallel` apply.

     Creation of this class requires that ``torch.distributed`` to be already
     initialized, by calling :func:`torch.distributed.init_process_group`.

     ``DistributedDataParallel`` can be used in the following two ways:

     (1) Single-Process Multi-GPU

     In this case, a single process will be
     spawned on each host/node and each process will operate on all the GPUs
     of the node where it's running. To use ``DistributedDataParallel`` in
     this way, you can simply construct the model as the following:

         >>> torch.distributed.init_process_group(backend="nccl")
         >>> model = DistributedDataParallel(model) # device_ids will include all GPU devices by default

     (2) Multi-Process Single-GPU

     This is the highly recommended way to use ``DistributedDataParallel``, with
     multiple processes, each of which operates on a single GPU. This is
     currently the fastest approach to do data parallel training using PyTorch
     and applies to both single-node(multi-GPU) and multi-node data
     parallel training. It is proven to be significantly faster than
     :class:`torch.nn.DataParallel` for single-node multi-GPU data
     parallel training.

     Here is how to use it: on each host with N GPUs, you should spawn up N
     processes, while ensuring that each process individually works on a single GPU
     from 0 to N-1. Therefore, it is your job to ensure that your training script
     operates on a single given GPU by calling:

         >>> torch.cuda.set_device(i)

     where i is from 0 to N-1. In each process, you should refer the following
     to construct this module:

         >>> torch.distributed.init_process_group(backend='nccl', world_size=4, init_method='...')
         >>> model = DistributedDataParallel(model, device_ids=[i], output_device=i)

     In order to spawn up multiple processes per node, you can use either
     ``torch.distributed.launch`` or ``torch.multiprocessing.spawn``

     .. note:: ``nccl`` backend is currently the fastest and
         highly recommended backend to be used with Multi-Process Single-GPU
         distributed training and this applies to both single-node and multi-node
         distributed training

     .. note:: This module also supports mixed-precision distributed training.
         This means that your model can have different types of parameters such
         as mixed types of fp16 and fp32, the gradient reduction on these
         mixed types of parameters will just work fine.
         Also note that ``nccl`` backend is currently the fastest and highly
         recommended backend for fp16/fp32 mixed-precision training.

     .. note:: If you use ``torch.save`` on one process to checkpoint the module,
         and ``torch.load`` on some other processes to recover it, make sure that
         ``map_location`` is configured properly for every process. Without
         ``map_location``, ``torch.load`` would recover the module to devices
         where the module was saved from.

     .. warning::
         This module works only with the ``gloo`` and ``nccl`` backends.

     .. warning::
         Constructor, forward method, and differentiation of the output (or a
         function of the output of this module) is a distributed synchronization
         point. Take that into account in case different processes might be
         executing different code.

     .. warning::
         This module assumes all parameters are registered in the model by the
         time it is created. No parameters should be added nor removed later.
         Same applies to buffers.

     .. warning::
         This module assumes all parameters are registered in the model of each
         distributed processes are in the same order. The module itself will
         conduct gradient all-reduction following the reverse order of the
         registered parameters of the model. In other words, it is users'
         responsibility to ensure that each distributed process has the exact
         same model and thus the exact same parameter registration order.

     .. warning::
         This module assumes all buffers and gradients are dense.

     .. warning::
         This module doesn't work with :func:`torch.autograd.grad` (i.e. it will
         only work if gradients are to be accumulated in ``.grad`` attributes of
         parameters).

     .. warning::

         If you plan on using this module with a ``nccl`` backend or a ``gloo``
         backend (that uses Infiniband), together with a DataLoader that uses
         multiple workers, please change the multiprocessing start method to
         ``forkserver`` (Python 3 only) or ``spawn``. Unfortunately
         Gloo (that uses Infiniband) and NCCL2 are not fork safe, and you will
         likely experience deadlocks if you don't change this setting.

     .. warning::
         Forward and backward hooks defined on :attr:`module` and its submodules
         won't be invoked anymore, unless the hooks are initialized in the
         :meth:`forward` method.

     .. warning::
         You should never try to change your model's parameters after wrapping
         up your model with DistributedDataParallel. In other words, when
         wrapping up your model with DistributedDataParallel, the constructor of
         DistributedDataParallel will register the additional gradient
         reduction functions on all the parameters of the model itself at the
         time of construction. If you change the model's parameters after
         the DistributedDataParallel construction, this is not supported and
         unexpected behaviors can happen, since some parameters' gradient
         reduction functions might not get called.

     .. note::
         Parameters are never broadcast between processes. The module performs
         an all-reduce step on gradients and assumes that they will be modified
         by the optimizer in all processes in the same way. Buffers
         (e.g. BatchNorm stats) are broadcast from the module in process of rank
         0, to all other replicas in the system in every iteration.

     Args:
         module (Module): module to be parallelized
         device_ids (list of int or torch.device): CUDA devices. This should
                    only be provided when the input module resides on a single
                    CUDA device. For single-device modules, the ``i``th
                    :attr:`module` replica is placed on ``device_ids[i]``. For
                    multi-device modules and CPU modules, device_ids must be None
                    or an empty list, and input data for the forward pass must be
                    placed on the correct device. (default: all devices for
                    single-device modules)
         output_device (int or torch.device): device location of output for
                       single-device CUDA modules. For multi-device modules and
                       CPU modules, it must be None, and the module itself
                       dictates the output location. (default: device_ids[0] for
                       single-device modules)
         broadcast_buffers (bool): flag that enables syncing (broadcasting) buffers of
                           the module at beginning of the forward function.
                           (default: ``True``)
         process_group: the process group to be used for distributed data
                        all-reduction. If ``None``, the default process group, which
                        is created by ```torch.distributed.init_process_group```,
                        will be used. (default: ``None``)
         bucket_cap_mb: DistributedDataParallel will bucket parameters into
                        multiple buckets so that gradient reduction of each
                        bucket can potentially overlap with backward computation.
                        :attr:`bucket_cap_mb` controls the bucket size in MegaBytes (MB)
                        (default: 25)
         find_unused_parameters (bool): Traverse the autograd graph of all tensors
                                        contained in the return value of the wrapped
                                        module's ``forward`` function.
                                        Parameters that don't receive gradients as
                                        part of this graph are preemptively marked
                                        as being ready to be reduced. Note that all
                                        ``forward`` outputs that are derived from
                                        module parameters must participate in
                                        calculating loss and later the gradient
                                        computation. If they don't, this wrapper will
                                        hang waiting for autograd to produce gradients
                                        for those parameters. Any outputs derived from
                                        module parameters that are otherwise unused can
                                        be detached from the autograd graph using
                                        ``torch.Tensor.detach``. (default: ``False``)
         check_reduction: when setting to ``True``, it enables DistributedDataParallel
                          to automatically check if the previous iteration's
                          backward reductions were successfully issued at the
                          beginning of every iteration's forward function.
                          You normally don't need this option enabled unless you
                          are observing weird behaviors such as different ranks
                          are getting different gradients, which should not
                          happen if DistributedDataParallel is correctly used.
                          (default: ``False``)

     Attributes:
         module (Module): the module to be parallelized

     Example::

         >>> torch.distributed.init_process_group(backend='nccl', world_size=4, init_method='...')
         >>> net = torch.nn.DistributedDataParallel(model, pg)
     """
     def __init__(self, module, device_ids=None,
                  output_device=None, dim=0, broadcast_buffers=True,
                  process_group=None, bucket_cap_mb=25,
                  find_unused_parameters=False,
                  check_reduction=False):

         super(DistributedDataParallel, self).__init__()

         self.is_multi_device_module = len({p.device for p in module.parameters()}) > 1
         self.is_cuda = all([p.device.type == 'cuda' for p in module.parameters()])

         if not self.is_cuda or self.is_multi_device_module:
             assert not device_ids and not output_device, (
                 "DistributedDataParallel device_ids and output_device arguments "
                 "only work with single-device CUDA modules, but got "
                 "device_ids {}, output_device {}, and module parameters {}."
             ).format(device_ids, output_device, {p.device for p in module.parameters()})

             self.device_ids = None
             self.output_device = None
         else:
             # Use all devices by default for single-device CUDA modules
             if device_ids is None:
                 device_ids = list(range(torch.cuda.device_count()))

             self.device_ids = list(map(lambda x: _get_device_index(x, True), device_ids))

             if output_device is None:
                 output_device = device_ids[0]

             self.output_device = _get_device_index(output_device, True)

         if self.is_multi_device_module:
             assert self.is_cuda, (
                 "DistributedDataParallel with multi-device module only works "
                 "with CUDA devices, but module parameters locate in {}."
             ).format({p.device for p in module.parameters()})

         if process_group is None:
             self.process_group = _get_default_group()
         else:
             self.process_group = process_group

         self.dim = dim
         self.module = module
         self.broadcast_buffers = broadcast_buffers
         self.find_unused_parameters = find_unused_parameters
         self.require_backward_grad_sync = True
         self.require_forward_param_sync = True

         if check_reduction:
             # This argument is no longer used since the reducer
             # will ensure reduction completes even if some parameters
             # do not receive gradients.
             pass

         MB = 1024 * 1024

         # used for intra-node param sync and inter-node sync as well
         self.broadcast_bucket_size = int(250 * MB)

         # reduction bucket size
         self.bucket_bytes_cap = int(bucket_cap_mb * MB)

         # Sync params and buffers
         module_states = list(self.module.state_dict().values())
         if len(module_states) > 0:
             self._distributed_broadcast_coalesced(
                 module_states,
                 self.broadcast_bucket_size)

         self._ddp_init_helper()

     def _ddp_init_helper(self):
         """
         Initialization helper function that does the following:

         (1) replicating the module from device[0] to the other devices
         (2) bucketing the parameters for reductions
         (3) resetting the bucketing states
         (4) registering the grad hooks
         (5) passing a handle of DDP to SyncBatchNorm Layer
         """
         if self.device_ids and len(self.device_ids) > 1:
             # only create replicas for single-device CUDA modules
             #
             # TODO: we don't need to replicate params in here. they're always going to
             # be broadcasted using larger blocks in broadcast_coalesced, so it might be
             # better to not pollute the caches with these small blocks
             self._module_copies = replicate(self.module, self.device_ids, detach=True)
             self._module_copies[0] = self.module

             for module_copy in self._module_copies[1:]:
                 for param, copy_param in zip(self.module.parameters(), module_copy.parameters()):
                     copy_param.requires_grad = param.requires_grad

         else:
             self._module_copies = [self.module]

         self.modules_params = [list(m.parameters()) for m in self._module_copies]
         self.modules_buffers = [list(m.buffers()) for m in self._module_copies]

         # Build tuple of (module, parameter) for all parameters that require grads.
         modules_and_parameters = [
             [
                 (module, parameter)
                 for module in replica.modules()
                 for parameter in filter(
                     lambda parameter: parameter.requires_grad,
                     module.parameters(recurse=False))
             ] for replica in self._module_copies]

         # Build list of parameters.
         parameters = [
             list(parameter for _, parameter in replica)
             for replica in modules_and_parameters]

         # Checks if a module will produce a sparse gradient.
         def produces_sparse_gradient(module):
             if isinstance(module, torch.nn.Embedding):
                 return module.sparse
             if isinstance(module, torch.nn.EmbeddingBag):
                 return module.sparse
             return False

         # Build list of booleans indicating whether or not to expect sparse
         # gradients for the corresponding parameters.
         expect_sparse_gradient = [
             list(produces_sparse_gradient(module) for module, _ in replica)
             for replica in modules_and_parameters]

         # The bucket size limit is specified in the constructor.
         # Additionally, we allow for a single small bucket for parameters
         # that are defined first, such that their gradients don't spill into
         # a much larger bucket, adding unnecessary latency after gradient
         # computation finishes. Experiments showed 1MB is a reasonable value.
         bucket_indices = dist._compute_bucket_assignment_by_size(
             parameters[0],
             [1024 * 1024, self.bucket_bytes_cap],
             expect_sparse_gradient[0])

         # Note: reverse list of buckets because we want to approximate the
         # order in which their gradients are produced, and assume they
         # are used in the forward pass in the order they are defined.
         self.reducer = dist.Reducer(
             parameters,
             list(reversed(bucket_indices)),
             self.process_group,
             expect_sparse_gradient)

         # passing a handle to torch.nn.SyncBatchNorm layer
         self._passing_sync_batchnorm_handle(self._module_copies)

     def __getstate__(self):
         self._check_default_group()
         attrs = copy.copy(self.__dict__)
         del attrs['process_group']
         del attrs['reducer']
         return attrs

     def __setstate__(self, state):
         # If serializable, then the process group should be the default one
         self.process_group = _get_default_group()
         super(DistributedDataParallel, self).__setstate__(state)
         self.__dict__.setdefault('require_forward_param_sync', True)
         self.__dict__.setdefault('require_backward_grad_sync', True)
         self._ddp_init_helper()

     def _check_default_group(self):
         pickle_not_supported = False
         try:
             if self.process_group != _get_default_group():
                 pickle_not_supported = True
         except RuntimeError:
             pickle_not_supported = True

         if pickle_not_supported:
             raise RuntimeError("DDP Pickling/Unpickling are only supported "
                                "when using DDP with the default process "
                                "group. That is, when you have called "
                                "init_process_group and have not passed "
                                "process_group argument to DDP constructor")

     @contextmanager
     def no_sync(self):
         r"""
         A context manager to disable gradient synchronizations across DDP
         processes. Within this context, gradients will be accumulated on module
         variables, which will later be synchronized in the first
         forward-backward pass exiting the context.

         Example::

             >>> ddp = torch.nn.DistributedDataParallel(model, pg)
             >>> with ddp.no_sync():
             ...   for input in inputs:
             ...     ddp(input).backward()  # no synchronization, accumulate grads
             ... ddp(another_input).backward()  # synchronize grads
         """
         old_require_backward_grad_sync = self.require_backward_grad_sync
         self.require_backward_grad_sync = False
         try:
             yield
         finally:
             self.require_backward_grad_sync = old_require_backward_grad_sync

     def forward(self, *inputs, **kwargs):
         if self.require_forward_param_sync:
             self._sync_params()

         if self.device_ids:
             inputs, kwargs = self.scatter(inputs, kwargs, self.device_ids)
             if len(self.device_ids) == 1:
                 output = self.module(*inputs[0], **kwargs[0])
             else:
                 outputs = self.parallel_apply(self._module_copies[:len(inputs)], inputs, kwargs)
                 output = self.gather(outputs, self.output_device)
         else:
             output = self.module(*inputs, **kwargs)

         if torch.is_grad_enabled() and self.require_backward_grad_sync:
             self.require_forward_param_sync = True
             # We'll return the output object verbatim since it is a freeform
             # object. We need to find any tensors in this object, though,
             # because we need to figure out which parameters were used during
             # this forward pass, to ensure we short circuit reduction for any
             # unused parameters. Only if `find_unused_parameters` is set.
             if self.find_unused_parameters:
                 self.reducer.prepare_for_backward(list(_find_tensors(output)))
             else:
                 self.reducer.prepare_for_backward([])
         else:
             self.require_forward_param_sync = False

         return output

     def scatter(self, inputs, kwargs, device_ids):
         return scatter_kwargs(inputs, kwargs, device_ids, dim=self.dim)

     def parallel_apply(self, replicas, inputs, kwargs):
         return parallel_apply(replicas, inputs, kwargs, self.device_ids[:len(replicas)])

     def gather(self, outputs, output_device):
         return gather(outputs, output_device, dim=self.dim)

     def train(self, mode=True):
         super(DistributedDataParallel, self).train(mode)
         for module in self._module_copies[1:]:
             module.train(mode)

     def _distributed_broadcast_coalesced(self, tensors, buffer_size):
         dist._broadcast_coalesced(self.process_group, tensors, buffer_size)

     def _sync_params(self):
         with torch.no_grad():
             # only do intra-node parameters sync for replicated single-device
             # CUDA modules
             if self.device_ids and len(self.device_ids) > 1:
                 # intra-node parameter sync
                 result = torch.cuda.comm.broadcast_coalesced(
                     self.modules_params[0],
                     self.device_ids,
                     self.broadcast_bucket_size)
                 for tensors, module_params in zip(result[1:],
                                                   self.modules_params[1:]):
                     for tensor, param in zip(tensors, module_params):
                         param.set_(tensor)
                         # Assume we have just run the optimizer and zeroed the
                         # grads of the parameters on the root model. We need
                         # to zero the grads on all model replicas as well.
                         # This snippet is copied from torch.optim.Optimizer.
                         if param.grad is not None:
                             param.grad.detach_()
                             param.grad.zero_()

             # module buffer sync
             if self.broadcast_buffers and len(self.modules_buffers[0]) > 0:
                 # Synchronize buffers across processes.
                 # The process with rank 0 is considered the authoritative copy.
                 self._distributed_broadcast_coalesced(
                     self.modules_buffers[0],
                     self.broadcast_bucket_size)
                 # only do intra-node buffer sync for replicated single-device
                 # CUDA modules
                 if self.device_ids and len(self.device_ids) > 1:
                     # intra-node buffer sync
                     result = torch.cuda.comm.broadcast_coalesced(
                         self.modules_buffers[0],
                         self.device_ids,
                         self.broadcast_bucket_size)
                     for tensors, module_buffers in zip(result[1:],
                                                        self.modules_buffers[1:]):
                         for tensor, buffer in zip(tensors, module_buffers):
                             buffer.set_(tensor)

     def _passing_sync_batchnorm_handle(self, module_copies):
         for dev_idx, module in enumerate(module_copies):
             for layer in module.modules():
                 if isinstance(layer, torch.nn.modules.SyncBatchNorm):
                     assert self.is_cuda, "SyncBatchNorm layers only work with CUDA modules"
                     layer._specify_ddp_gpu_num(
                         len(self.device_ids) if self.device_ids else 1)
	from contextlib import contextmanager
	import copy
	import itertools

	import torch

	import torch.cuda.comm
	import torch.distributed as dist

	if dist.is_available():
	from torch.distributed.distributed_c10d import _get_default_group

	from ..modules import Module
	from .replicate import replicate
	from .scatter_gather import scatter_kwargs, gather
	from .parallel_apply import parallel_apply
	from torch.cuda._utils import _get_device_index


	def _find_tensors(obj):
	r"""
	Recursively find all tensors contained in the specified object.
	"""
	if isinstance(obj, torch.Tensor):
	return [obj]
	if isinstance(obj, (list, tuple)):
	return itertools.chain(*map(_find_tensors, obj))
	if isinstance(obj, dict):
	return itertools.chain(*map(_find_tensors, obj.values()))
	return []


	class DistributedDataParallel(Module):
	r"""Implements distributed data parallelism that is based on
	``torch.distributed`` package 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. The module is replicated on each machine and each device, and
	each such replica handles a portion of the input. During the backwards
	pass, gradients from each node are averaged.

	The batch size should be larger than the number of GPUs used locally.

	See also: :ref:`distributed-basics` and :ref:`cuda-nn-dataparallel-instead`.
	The same constraints on input as in :class:`torch.nn.DataParallel` apply.

	Creation of this class requires that ``torch.distributed`` to be already
	initialized, by calling :func:`torch.distributed.init_process_group`.

	``DistributedDataParallel`` can be used in the following two ways:

	(1) Single-Process Multi-GPU

	In this case, a single process will be
	spawned on each host/node and each process will operate on all the GPUs
	of the node where it's running. To use ``DistributedDataParallel`` in
	this way, you can simply construct the model as the following:

	>>> torch.distributed.init_process_group(backend="nccl")
	>>> model = DistributedDataParallel(model) # device_ids will include all GPU devices by default

	(2) Multi-Process Single-GPU

	This is the highly recommended way to use ``DistributedDataParallel``, with
	multiple processes, each of which operates on a single GPU. This is
	currently the fastest approach to do data parallel training using PyTorch
	and applies to both single-node(multi-GPU) and multi-node data
	parallel training. It is proven to be significantly faster than
	:class:`torch.nn.DataParallel` for single-node multi-GPU data
	parallel training.

	Here is how to use it: on each host with N GPUs, you should spawn up N
	processes, while ensuring that each process individually works on a single GPU
	from 0 to N-1. Therefore, it is your job to ensure that your training script
	operates on a single given GPU by calling:

	>>> torch.cuda.set_device(i)

	where i is from 0 to N-1. In each process, you should refer the following
	to construct this module:

	>>> torch.distributed.init_process_group(backend='nccl', world_size=4, init_method='...')
	>>> model = DistributedDataParallel(model, device_ids=[i], output_device=i)

	In order to spawn up multiple processes per node, you can use either
	``torch.distributed.launch`` or ``torch.multiprocessing.spawn``

	.. note:: ``nccl`` backend is currently the fastest and
	highly recommended backend to be used with Multi-Process Single-GPU
	distributed training and this applies to both single-node and multi-node
	distributed training

	.. note:: This module also supports mixed-precision distributed training.
	This means that your model can have different types of parameters such
	as mixed types of fp16 and fp32, the gradient reduction on these
	mixed types of parameters will just work fine.
	Also note that ``nccl`` backend is currently the fastest and highly
	recommended backend for fp16/fp32 mixed-precision training.

	.. note:: If you use ``torch.save`` on one process to checkpoint the module,
	and ``torch.load`` on some other processes to recover it, make sure that
	``map_location`` is configured properly for every process. Without
	``map_location``, ``torch.load`` would recover the module to devices
	where the module was saved from.

	.. warning::
	This module works only with the ``gloo`` and ``nccl`` backends.

	.. warning::
	Constructor, forward method, and differentiation of the output (or a
	function of the output of this module) is a distributed synchronization
	point. Take that into account in case different processes might be
	executing different code.

	.. warning::
	This module assumes all parameters are registered in the model by the
	time it is created. No parameters should be added nor removed later.
	Same applies to buffers.

	.. warning::
	This module assumes all parameters are registered in the model of each
	distributed processes are in the same order. The module itself will
	conduct gradient all-reduction following the reverse order of the
	registered parameters of the model. In other words, it is users'
	responsibility to ensure that each distributed process has the exact
	same model and thus the exact same parameter registration order.

	.. warning::
	This module assumes all buffers and gradients are dense.

	.. warning::
	This module doesn't work with :func:`torch.autograd.grad` (i.e. it will
	only work if gradients are to be accumulated in ``.grad`` attributes of
	parameters).

	.. warning::

	If you plan on using this module with a ``nccl`` backend or a ``gloo``
	backend (that uses Infiniband), together with a DataLoader that uses
	multiple workers, please change the multiprocessing start method to
	``forkserver`` (Python 3 only) or ``spawn``. Unfortunately
	Gloo (that uses Infiniband) and NCCL2 are not fork safe, and you will
	likely experience deadlocks if you don't change this setting.

	.. warning::
	Forward and backward hooks defined on :attr:`module` and its submodules
	won't be invoked anymore, unless the hooks are initialized in the
	:meth:`forward` method.

	.. warning::
	You should never try to change your model's parameters after wrapping
	up your model with DistributedDataParallel. In other words, when
	wrapping up your model with DistributedDataParallel, the constructor of
	DistributedDataParallel will register the additional gradient
	reduction functions on all the parameters of the model itself at the
	time of construction. If you change the model's parameters after
	the DistributedDataParallel construction, this is not supported and
	unexpected behaviors can happen, since some parameters' gradient
	reduction functions might not get called.

	.. note::
	Parameters are never broadcast between processes. The module performs
	an all-reduce step on gradients and assumes that they will be modified
	by the optimizer in all processes in the same way. Buffers
	(e.g. BatchNorm stats) are broadcast from the module in process of rank
	0, to all other replicas in the system in every iteration.

	Args:
	module (Module): module to be parallelized
	device_ids (list of int or torch.device): CUDA devices. This should
	only be provided when the input module resides on a single
	CUDA device. For single-device modules, the ``i``th
	:attr:`module` replica is placed on ``device_ids[i]``. For
	multi-device modules and CPU modules, device_ids must be None
	or an empty list, and input data for the forward pass must be
	placed on the correct device. (default: all devices for
	single-device modules)
	output_device (int or torch.device): device location of output for
	single-device CUDA modules. For multi-device modules and
	CPU modules, it must be None, and the module itself
	dictates the output location. (default: device_ids[0] for
	single-device modules)
	broadcast_buffers (bool): flag that enables syncing (broadcasting) buffers of
	the module at beginning of the forward function.
	(default: ``True``)
	process_group: the process group to be used for distributed data
	all-reduction. If ``None``, the default process group, which
	is created by ```torch.distributed.init_process_group```,
	will be used. (default: ``None``)
	bucket_cap_mb: DistributedDataParallel will bucket parameters into
	multiple buckets so that gradient reduction of each
	bucket can potentially overlap with backward computation.
	:attr:`bucket_cap_mb` controls the bucket size in MegaBytes (MB)
	(default: 25)
	find_unused_parameters (bool): Traverse the autograd graph of all tensors
	contained in the return value of the wrapped
	module's ``forward`` function.
	Parameters that don't receive gradients as
	part of this graph are preemptively marked
	as being ready to be reduced. Note that all
	``forward`` outputs that are derived from
	module parameters must participate in
	calculating loss and later the gradient
	computation. If they don't, this wrapper will
	hang waiting for autograd to produce gradients
	for those parameters. Any outputs derived from
	module parameters that are otherwise unused can
	be detached from the autograd graph using
	``torch.Tensor.detach``. (default: ``False``)
	check_reduction: when setting to ``True``, it enables DistributedDataParallel
	to automatically check if the previous iteration's
	backward reductions were successfully issued at the
	beginning of every iteration's forward function.
	You normally don't need this option enabled unless you
	are observing weird behaviors such as different ranks
	are getting different gradients, which should not
	happen if DistributedDataParallel is correctly used.
	(default: ``False``)

	Attributes:
	module (Module): the module to be parallelized

	Example::

	>>> torch.distributed.init_process_group(backend='nccl', world_size=4, init_method='...')
	>>> net = torch.nn.DistributedDataParallel(model, pg)
	"""
	def __init__(self, module, device_ids=None,
	output_device=None, dim=0, broadcast_buffers=True,
	process_group=None, bucket_cap_mb=25,
	find_unused_parameters=False,
	check_reduction=False):

	super(DistributedDataParallel, self).__init__()

	self.is_multi_device_module = len({p.device for p in module.parameters()}) > 1
	self.is_cuda = all([p.device.type == 'cuda' for p in module.parameters()])

	if not self.is_cuda or self.is_multi_device_module:
	assert not device_ids and not output_device, (
	"DistributedDataParallel device_ids and output_device arguments "
	"only work with single-device CUDA modules, but got "
	"device_ids {}, output_device {}, and module parameters {}."
	).format(device_ids, output_device, {p.device for p in module.parameters()})

	self.device_ids = None
	self.output_device = None
	else:
	# Use all devices by default for single-device CUDA modules
	if device_ids is None:
	device_ids = list(range(torch.cuda.device_count()))

	self.device_ids = list(map(lambda x: _get_device_index(x, True), device_ids))

	if output_device is None:
	output_device = device_ids[0]

	self.output_device = _get_device_index(output_device, True)

	if self.is_multi_device_module:
	assert self.is_cuda, (
	"DistributedDataParallel with multi-device module only works "
	"with CUDA devices, but module parameters locate in {}."
	).format({p.device for p in module.parameters()})

	if process_group is None:
	self.process_group = _get_default_group()
	else:
	self.process_group = process_group

	self.dim = dim
	self.module = module
	self.broadcast_buffers = broadcast_buffers
	self.find_unused_parameters = find_unused_parameters
	self.require_backward_grad_sync = True
	self.require_forward_param_sync = True

	if check_reduction:
	# This argument is no longer used since the reducer
	# will ensure reduction completes even if some parameters
	# do not receive gradients.
	pass

	MB = 1024 * 1024

	# used for intra-node param sync and inter-node sync as well
	self.broadcast_bucket_size = int(250 * MB)

	# reduction bucket size
	self.bucket_bytes_cap = int(bucket_cap_mb * MB)

	# Sync params and buffers
	module_states = list(self.module.state_dict().values())
	if len(module_states) > 0:
	self._distributed_broadcast_coalesced(
	module_states,
	self.broadcast_bucket_size)

	self._ddp_init_helper()

	def _ddp_init_helper(self):
	"""
	Initialization helper function that does the following:

	(1) replicating the module from device[0] to the other devices
	(2) bucketing the parameters for reductions
	(3) resetting the bucketing states
	(4) registering the grad hooks
	(5) passing a handle of DDP to SyncBatchNorm Layer
	"""
	if self.device_ids and len(self.device_ids) > 1:
	# only create replicas for single-device CUDA modules
	#
	# TODO: we don't need to replicate params in here. they're always going to
	# be broadcasted using larger blocks in broadcast_coalesced, so it might be
	# better to not pollute the caches with these small blocks
	self._module_copies = replicate(self.module, self.device_ids, detach=True)
	self._module_copies[0] = self.module

	for module_copy in self._module_copies[1:]:
	for param, copy_param in zip(self.module.parameters(), module_copy.parameters()):
	copy_param.requires_grad = param.requires_grad

	else:
	self._module_copies = [self.module]

	self.modules_params = [list(m.parameters()) for m in self._module_copies]
	self.modules_buffers = [list(m.buffers()) for m in self._module_copies]

	# Build tuple of (module, parameter) for all parameters that require grads.
	modules_and_parameters = [
	[
	(module, parameter)
	for module in replica.modules()
	for parameter in filter(
	lambda parameter: parameter.requires_grad,
	module.parameters(recurse=False))
	] for replica in self._module_copies]

	# Build list of parameters.
	parameters = [
	list(parameter for _, parameter in replica)
	for replica in modules_and_parameters]

	# Checks if a module will produce a sparse gradient.
	def produces_sparse_gradient(module):
	if isinstance(module, torch.nn.Embedding):
	return module.sparse
	if isinstance(module, torch.nn.EmbeddingBag):
	return module.sparse
	return False

	# Build list of booleans indicating whether or not to expect sparse
	# gradients for the corresponding parameters.
	expect_sparse_gradient = [
	list(produces_sparse_gradient(module) for module, _ in replica)
	for replica in modules_and_parameters]

	# The bucket size limit is specified in the constructor.
	# Additionally, we allow for a single small bucket for parameters
	# that are defined first, such that their gradients don't spill into
	# a much larger bucket, adding unnecessary latency after gradient
	# computation finishes. Experiments showed 1MB is a reasonable value.
	bucket_indices = dist._compute_bucket_assignment_by_size(
	parameters[0],
	[1024 * 1024, self.bucket_bytes_cap],
	expect_sparse_gradient[0])

	# Note: reverse list of buckets because we want to approximate the
	# order in which their gradients are produced, and assume they
	# are used in the forward pass in the order they are defined.
	self.reducer = dist.Reducer(
	parameters,
	list(reversed(bucket_indices)),
	self.process_group,
	expect_sparse_gradient)

	# passing a handle to torch.nn.SyncBatchNorm layer
	self._passing_sync_batchnorm_handle(self._module_copies)

	def __getstate__(self):
	self._check_default_group()
	attrs = copy.copy(self.__dict__)
	del attrs['process_group']
	del attrs['reducer']
	return attrs

	def __setstate__(self, state):
	# If serializable, then the process group should be the default one
	self.process_group = _get_default_group()
	super(DistributedDataParallel, self).__setstate__(state)
	self.__dict__.setdefault('require_forward_param_sync', True)
	self.__dict__.setdefault('require_backward_grad_sync', True)
	self._ddp_init_helper()

	def _check_default_group(self):
	pickle_not_supported = False
	try:
	if self.process_group != _get_default_group():
	pickle_not_supported = True
	except RuntimeError:
	pickle_not_supported = True

	if pickle_not_supported:
	raise RuntimeError("DDP Pickling/Unpickling are only supported "
	"when using DDP with the default process "
	"group. That is, when you have called "
	"init_process_group and have not passed "
	"process_group argument to DDP constructor")

	@contextmanager
	def no_sync(self):
	r"""
	A context manager to disable gradient synchronizations across DDP
	processes. Within this context, gradients will be accumulated on module
	variables, which will later be synchronized in the first
	forward-backward pass exiting the context.

	Example::

	>>> ddp = torch.nn.DistributedDataParallel(model, pg)
	>>> with ddp.no_sync():
	... for input in inputs:
	... ddp(input).backward() # no synchronization, accumulate grads
	... ddp(another_input).backward() # synchronize grads
	"""
	old_require_backward_grad_sync = self.require_backward_grad_sync
	self.require_backward_grad_sync = False
	try:
	yield
	finally:
	self.require_backward_grad_sync = old_require_backward_grad_sync

	def forward(self, inputs, *kwargs):
	if self.require_forward_param_sync:
	self._sync_params()

	if self.device_ids:
	inputs, kwargs = self.scatter(inputs, kwargs, self.device_ids)
	if len(self.device_ids) == 1:
	output = self.module(inputs[0], *kwargs[0])
	else:
	outputs = self.parallel_apply(self._module_copies[:len(inputs)], inputs, kwargs)
	output = self.gather(outputs, self.output_device)
	else:
	output = self.module(inputs, *kwargs)

	if torch.is_grad_enabled() and self.require_backward_grad_sync:
	self.require_forward_param_sync = True
	# We'll return the output object verbatim since it is a freeform
	# object. We need to find any tensors in this object, though,
	# because we need to figure out which parameters were used during
	# this forward pass, to ensure we short circuit reduction for any
	# unused parameters. Only if `find_unused_parameters` is set.
	if self.find_unused_parameters:
	self.reducer.prepare_for_backward(list(_find_tensors(output)))
	else:
	self.reducer.prepare_for_backward([])
	else:
	self.require_forward_param_sync = False

	return output

	def scatter(self, inputs, kwargs, device_ids):
	return scatter_kwargs(inputs, kwargs, device_ids, dim=self.dim)

	def parallel_apply(self, replicas, inputs, kwargs):
	return parallel_apply(replicas, inputs, kwargs, self.device_ids[:len(replicas)])

	def gather(self, outputs, output_device):
	return gather(outputs, output_device, dim=self.dim)

	def train(self, mode=True):
	super(DistributedDataParallel, self).train(mode)
	for module in self._module_copies[1:]:
	module.train(mode)

	def _distributed_broadcast_coalesced(self, tensors, buffer_size):
	dist._broadcast_coalesced(self.process_group, tensors, buffer_size)

	def _sync_params(self):
	with torch.no_grad():
	# only do intra-node parameters sync for replicated single-device
	# CUDA modules
	if self.device_ids and len(self.device_ids) > 1:
	# intra-node parameter sync
	result = torch.cuda.comm.broadcast_coalesced(
	self.modules_params[0],
	self.device_ids,
	self.broadcast_bucket_size)
	for tensors, module_params in zip(result[1:],
	self.modules_params[1:]):
	for tensor, param in zip(tensors, module_params):
	param.set_(tensor)
	# Assume we have just run the optimizer and zeroed the
	# grads of the parameters on the root model. We need
	# to zero the grads on all model replicas as well.
	# This snippet is copied from torch.optim.Optimizer.
	if param.grad is not None:
	param.grad.detach_()
	param.grad.zero_()

	# module buffer sync
	if self.broadcast_buffers and len(self.modules_buffers[0]) > 0:
	# Synchronize buffers across processes.
	# The process with rank 0 is considered the authoritative copy.
	self._distributed_broadcast_coalesced(
	self.modules_buffers[0],
	self.broadcast_bucket_size)
	# only do intra-node buffer sync for replicated single-device
	# CUDA modules
	if self.device_ids and len(self.device_ids) > 1:
	# intra-node buffer sync
	result = torch.cuda.comm.broadcast_coalesced(
	self.modules_buffers[0],
	self.device_ids,
	self.broadcast_bucket_size)
	for tensors, module_buffers in zip(result[1:],
	self.modules_buffers[1:]):
	for tensor, buffer in zip(tensors, module_buffers):
	buffer.set_(tensor)

	def _passing_sync_batchnorm_handle(self, module_copies):
	for dev_idx, module in enumerate(module_copies):
	for layer in module.modules():
	if isinstance(layer, torch.nn.modules.SyncBatchNorm):
	assert self.is_cuda, "SyncBatchNorm layers only work with CUDA modules"
	layer._specify_ddp_gpu_num(
	len(self.device_ids) if self.device_ids else 1)