torch/nn/modules/batchnorm.py - platform/external/pytorch - Git at Google

 from __future__ import division

 import torch
 from ._functions import SyncBatchNorm as sync_batch_norm
 from .module import Module
 from torch.nn.parameter import Parameter
 from .. import functional as F
 from .. import init
 from ..._jit_internal import weak_module, weak_script_method


 # TODO: check contiguous in THNN
 # TODO: use separate backend functions?
 @weak_module
 class _BatchNorm(Module):
     _version = 2
     __constants__ = ['track_running_stats', 'momentum', 'eps', 'weight', 'bias',
                      'running_mean', 'running_var', 'num_batches_tracked']

     def __init__(self, num_features, eps=1e-5, momentum=0.1, affine=True,
                  track_running_stats=True):
         super(_BatchNorm, self).__init__()
         self.num_features = num_features
         self.eps = eps
         self.momentum = momentum
         self.affine = affine
         self.track_running_stats = track_running_stats
         if self.affine:
             self.weight = Parameter(torch.Tensor(num_features))
             self.bias = Parameter(torch.Tensor(num_features))
         else:
             self.register_parameter('weight', None)
             self.register_parameter('bias', None)
         if self.track_running_stats:
             self.register_buffer('running_mean', torch.zeros(num_features))
             self.register_buffer('running_var', torch.ones(num_features))
             self.register_buffer('num_batches_tracked', torch.tensor(0, dtype=torch.long))
         else:
             self.register_parameter('running_mean', None)
             self.register_parameter('running_var', None)
             self.register_parameter('num_batches_tracked', None)
         self.reset_parameters()

     def reset_running_stats(self):
         if self.track_running_stats:
             self.running_mean.zero_()
             self.running_var.fill_(1)
             self.num_batches_tracked.zero_()

     def reset_parameters(self):
         self.reset_running_stats()
         if self.affine:
             init.uniform_(self.weight)
             init.zeros_(self.bias)

     def _check_input_dim(self, input):
         raise NotImplementedError

     @weak_script_method
     def forward(self, input):
         self._check_input_dim(input)

         # exponential_average_factor is self.momentum set to
         # (when it is available) only so that if gets updated
         # in ONNX graph when this node is exported to ONNX.
         if self.momentum is None:
             exponential_average_factor = 0.0
         else:
             exponential_average_factor = self.momentum

         if self.training and self.track_running_stats:
             # TODO: if statement only here to tell the jit to skip emitting this when it is None
             if self.num_batches_tracked is not None:
                 self.num_batches_tracked += 1
                 if self.momentum is None:  # use cumulative moving average
                     exponential_average_factor = 1.0 / float(self.num_batches_tracked)
                 else:  # use exponential moving average
                     exponential_average_factor = self.momentum

         return F.batch_norm(
             input, self.running_mean, self.running_var, self.weight, self.bias,
             self.training or not self.track_running_stats,
             exponential_average_factor, self.eps)

     def extra_repr(self):
         return '{num_features}, eps={eps}, momentum={momentum}, affine={affine}, ' \
                'track_running_stats={track_running_stats}'.format(**self.__dict__)

     def _load_from_state_dict(self, state_dict, prefix, local_metadata, strict,
                               missing_keys, unexpected_keys, error_msgs):
         version = local_metadata.get('version', None)

         if (version is None or version < 2) and self.track_running_stats:
             # at version 2: added num_batches_tracked buffer
             #               this should have a default value of 0
             num_batches_tracked_key = prefix + 'num_batches_tracked'
             if num_batches_tracked_key not in state_dict:
                 state_dict[num_batches_tracked_key] = torch.tensor(0, dtype=torch.long)

         super(_BatchNorm, self)._load_from_state_dict(
             state_dict, prefix, local_metadata, strict,
             missing_keys, unexpected_keys, error_msgs)


 @weak_module
 class BatchNorm1d(_BatchNorm):
     r"""Applies Batch Normalization over a 2D or 3D input (a mini-batch of 1D
     inputs with optional additional channel dimension) as described in the paper
     `Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

     .. math::

         y = \frac{x - \mathrm{E}[x]}{\sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

     The mean and standard-deviation are calculated per-dimension over
     the mini-batches and :math:`\gamma` and :math:`\beta` are learnable parameter vectors
     of size `C` (where `C` is the input size). By default, the elements of :math:`\gamma` are sampled
     from :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

     Also by default, during training this layer keeps running estimates of its
     computed mean and variance, which are then used for normalization during
     evaluation. The running estimates are kept with a default :attr:`momentum`
     of 0.1.

     If :attr:`track_running_stats` is set to ``False``, this layer then does not
     keep running estimates, and batch statistics are instead used during
     evaluation time as well.

     .. note::
         This :attr:`momentum` argument is different from one used in optimizer
         classes and the conventional notion of momentum. Mathematically, the
         update rule for running statistics here is
         :math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momentum} \times x_t`,
         where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
         new observed value.

     Because the Batch Normalization is done over the `C` dimension, computing statistics
     on `(N, L)` slices, it's common terminology to call this Temporal Batch Normalization.

     Args:
         num_features: :math:`C` from an expected input of size
             :math:`(N, C, L)` or :math:`L` from input of size :math:`(N, L)`
         eps: a value added to the denominator for numerical stability.
             Default: 1e-5
         momentum: the value used for the running_mean and running_var
             computation. Can be set to ``None`` for cumulative moving average
             (i.e. simple average). Default: 0.1
         affine: a boolean value that when set to ``True``, this module has
             learnable affine parameters. Default: ``True``
         track_running_stats: a boolean value that when set to ``True``, this
             module tracks the running mean and variance, and when set to ``False``,
             this module does not track such statistics and always uses batch
             statistics in both training and eval modes. Default: ``True``

     Shape:
         - Input: :math:`(N, C)` or :math:`(N, C, L)`
         - Output: :math:`(N, C)` or :math:`(N, C, L)` (same shape as input)

     Examples::

         >>> # With Learnable Parameters
         >>> m = nn.BatchNorm1d(100)
         >>> # Without Learnable Parameters
         >>> m = nn.BatchNorm1d(100, affine=False)
         >>> input = torch.randn(20, 100)
         >>> output = m(input)

     .. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
         https://arxiv.org/abs/1502.03167
     """

     @weak_script_method
     def _check_input_dim(self, input):
         if input.dim() != 2 and input.dim() != 3:
             raise ValueError('expected 2D or 3D input (got {}D input)'
                              .format(input.dim()))


 @weak_module
 class BatchNorm2d(_BatchNorm):
     r"""Applies Batch Normalization over a 4D input (a mini-batch of 2D inputs
     with additional channel dimension) as described in the paper
     `Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

     .. math::

         y = \frac{x - \mathrm{E}[x]}{ \sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

     The mean and standard-deviation are calculated per-dimension over
     the mini-batches and :math:`\gamma` and :math:`\beta` are learnable parameter vectors
     of size `C` (where `C` is the input size). By default, the elements of :math:`\gamma` are sampled
     from :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

     Also by default, during training this layer keeps running estimates of its
     computed mean and variance, which are then used for normalization during
     evaluation. The running estimates are kept with a default :attr:`momentum`
     of 0.1.

     If :attr:`track_running_stats` is set to ``False``, this layer then does not
     keep running estimates, and batch statistics are instead used during
     evaluation time as well.

     .. note::
         This :attr:`momentum` argument is different from one used in optimizer
         classes and the conventional notion of momentum. Mathematically, the
         update rule for running statistics here is
         :math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momentum} \times x_t`,
         where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
         new observed value.

     Because the Batch Normalization is done over the `C` dimension, computing statistics
     on `(N, H, W)` slices, it's common terminology to call this Spatial Batch Normalization.

     Args:
         num_features: :math:`C` from an expected input of size
             :math:`(N, C, H, W)`
         eps: a value added to the denominator for numerical stability.
             Default: 1e-5
         momentum: the value used for the running_mean and running_var
             computation. Can be set to ``None`` for cumulative moving average
             (i.e. simple average). Default: 0.1
         affine: a boolean value that when set to ``True``, this module has
             learnable affine parameters. Default: ``True``
         track_running_stats: a boolean value that when set to ``True``, this
             module tracks the running mean and variance, and when set to ``False``,
             this module does not track such statistics and always uses batch
             statistics in both training and eval modes. Default: ``True``

     Shape:
         - Input: :math:`(N, C, H, W)`
         - Output: :math:`(N, C, H, W)` (same shape as input)

     Examples::

         >>> # With Learnable Parameters
         >>> m = nn.BatchNorm2d(100)
         >>> # Without Learnable Parameters
         >>> m = nn.BatchNorm2d(100, affine=False)
         >>> input = torch.randn(20, 100, 35, 45)
         >>> output = m(input)

     .. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
         https://arxiv.org/abs/1502.03167
     """

     @weak_script_method
     def _check_input_dim(self, input):
         if input.dim() != 4:
             raise ValueError('expected 4D input (got {}D input)'
                              .format(input.dim()))


 @weak_module
 class BatchNorm3d(_BatchNorm):
     r"""Applies Batch Normalization over a 5D input (a mini-batch of 3D inputs
     with additional channel dimension) as described in the paper
     `Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

     .. math::

         y = \frac{x - \mathrm{E}[x]}{ \sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

     The mean and standard-deviation are calculated per-dimension over
     the mini-batches and :math:`\gamma` and :math:`\beta` are learnable parameter vectors
     of size `C` (where `C` is the input size). By default, the elements of :math:`\gamma` are sampled
     from :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

     Also by default, during training this layer keeps running estimates of its
     computed mean and variance, which are then used for normalization during
     evaluation. The running estimates are kept with a default :attr:`momentum`
     of 0.1.

     If :attr:`track_running_stats` is set to ``False``, this layer then does not
     keep running estimates, and batch statistics are instead used during
     evaluation time as well.

     .. note::
         This :attr:`momentum` argument is different from one used in optimizer
         classes and the conventional notion of momentum. Mathematically, the
         update rule for running statistics here is
         :math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momentum} \times x_t`,
         where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
         new observed value.

     Because the Batch Normalization is done over the `C` dimension, computing statistics
     on `(N, D, H, W)` slices, it's common terminology to call this Volumetric Batch Normalization
     or Spatio-temporal Batch Normalization.

     Args:
         num_features: :math:`C` from an expected input of size
             :math:`(N, C, D, H, W)`
         eps: a value added to the denominator for numerical stability.
             Default: 1e-5
         momentum: the value used for the running_mean and running_var
             computation. Can be set to ``None`` for cumulative moving average
             (i.e. simple average). Default: 0.1
         affine: a boolean value that when set to ``True``, this module has
             learnable affine parameters. Default: ``True``
         track_running_stats: a boolean value that when set to ``True``, this
             module tracks the running mean and variance, and when set to ``False``,
             this module does not track such statistics and always uses batch
             statistics in both training and eval modes. Default: ``True``

     Shape:
         - Input: :math:`(N, C, D, H, W)`
         - Output: :math:`(N, C, D, H, W)` (same shape as input)

     Examples::

         >>> # With Learnable Parameters
         >>> m = nn.BatchNorm3d(100)
         >>> # Without Learnable Parameters
         >>> m = nn.BatchNorm3d(100, affine=False)
         >>> input = torch.randn(20, 100, 35, 45, 10)
         >>> output = m(input)

     .. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
         https://arxiv.org/abs/1502.03167
     """

     @weak_script_method
     def _check_input_dim(self, input):
         if input.dim() != 5:
             raise ValueError('expected 5D input (got {}D input)'
                              .format(input.dim()))


 class SyncBatchNorm(_BatchNorm):
     r"""Applies Batch Normalization over a N-Dimensional input (a mini-batch of [N-2]D inputs
     with additional channel dimension) as described in the paper
     `Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

     .. math::

         y = \frac{x - \mathrm{E}[x]}{ \sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

     The mean and standard-deviation are calculated per-dimension over all
     mini-batches of the same process groups. :math:`\gamma` and :math:`\beta`
     are learnable parameter vectors of size `C` (where `C` is the input size).
     By default, the elements of :math:`\gamma` are sampled from
     :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

     Also by default, during training this layer keeps running estimates of its
     computed mean and variance, which are then used for normalization during
     evaluation. The running estimates are kept with a default :attr:`momentum`
     of 0.1.

     If :attr:`track_running_stats` is set to ``False``, this layer then does not
     keep running estimates, and batch statistics are instead used during
     evaluation time as well.

     .. note::
         This :attr:`momentum` argument is different from one used in optimizer
         classes and the conventional notion of momentum. Mathematically, the
         update rule for running statistics here is
         :math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momemtum} \times x_t`,
         where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
         new observed value.

     Because the Batch Normalization is done over the `C` dimension, computing statistics
     on `(N, +)` slices, it's common terminology to call this Volumetric Batch Normalization
     or Spatio-temporal Batch Normalization.

     Currently SyncBatchNorm only supports DistributedDataParallel with single GPU per process. Use
     torch.nn.SyncBatchNorm.convert_sync_batchnorm() to convert BatchNorm layer to SyncBatchNorm before wrapping
     Network with DDP.

     Args:
         num_features: :math:`C` from an expected input of size
             :math:`(N, C, +)`
         eps: a value added to the denominator for numerical stability.
             Default: 1e-5
         momentum: the value used for the running_mean and running_var
             computation. Can be set to ``None`` for cumulative moving average
             (i.e. simple average). Default: 0.1
         affine: a boolean value that when set to ``True``, this module has
             learnable affine parameters. Default: ``True``
         track_running_stats: a boolean value that when set to ``True``, this
             module tracks the running mean and variance, and when set to ``False``,
             this module does not track such statistics and always uses batch
             statistics in both training and eval modes. Default: ``True``
         process_group: synchronization of stats happen within each process group
             individually. Default behavior is synchronization across the whole
             world

     Shape:
         - Input: :math:`(N, C, +)`
         - Output: :math:`(N, C, +)` (same shape as input)

     Examples::

         >>> # With Learnable Parameters
         >>> m = nn.SyncBatchNorm(100)
         >>> # creating process group (optional)
         >>> # process_ids is a list of int identifying rank ids.
         >>> process_group = torch.distributed.new_group(process_ids)
         >>> # Without Learnable Parameters
         >>> m = nn.BatchNorm3d(100, affine=False, process_group=process_group)
         >>> input = torch.randn(20, 100, 35, 45, 10)
         >>> output = m(input)

         >>> # network is nn.BatchNorm layer
         >>> sync_bn_network = torch.nn.utils.convert_sync_batchnorm(network, process_group)
         >>> # only single gpu per process is currently supported
         >>> ddp_sync_bn_network = torch.nn.parallel.DistributedDataParallel(
         >>>                         sync_bn_network,
         >>>                         device_ids=[args.local_rank],
         >>>                         output_device=args.local_rank)

     .. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
         https://arxiv.org/abs/1502.03167
     """

     def __init__(self, num_features, eps=1e-5, momentum=0.1, affine=True,
                  track_running_stats=True, process_group=None):
         super(SyncBatchNorm, self).__init__(num_features, eps, momentum, affine, track_running_stats)
         self.process_group = process_group
         # gpu_size is set through DistributedDataParallel initialization. This is to ensure that SyncBatchNorm is used
         # under supported condition (single GPU per process)
         self.ddp_gpu_size = None

     def _check_input_dim(self, input):
         if input.dim() <= 2:
             raise ValueError('expected at least 3D input (got {}D input)'
                              .format(input.dim()))

     def _specify_ddp_gpu_num(self, gpu_size):
         if gpu_size > 1:
             raise ValueError('SyncBatchNorm is only supported for DDP with single GPU per process')
         self.ddp_gpu_size = gpu_size

     def forward(self, input):
         # currently only GPU input is supported
         if not input.is_cuda:
             raise ValueError('expected input tensor to be on GPU')

         if not self.ddp_gpu_size:
             raise AttributeError('SyncBatchNorm is only supported within torch.nn.parallel.DistributedDataParallel')

         self._check_input_dim(input)

         exponential_average_factor = 0.0

         if self.training and self.track_running_stats:
             self.num_batches_tracked += 1
             if self.momentum is None:  # use cumulative moving average
                 exponential_average_factor = 1.0 / self.num_batches_tracked.item()
             else:  # use exponential moving average
                 exponential_average_factor = self.momentum

         world_size = 1
         process_group = torch.distributed.group.WORLD
         if self.process_group:
             process_group = self.process_group
         world_size = torch.distributed.get_world_size(process_group)

         # fallback to framework BN when synchronization is not necessary
         if world_size == 1 or (not self.training and self.track_running_stats):
             return F.batch_norm(
                 input, self.running_mean, self.running_var, self.weight, self.bias,
                 self.training or not self.track_running_stats,
                 exponential_average_factor, self.eps)
         else:
             return sync_batch_norm.apply(
                 input, self.weight, self.bias, self.running_mean, self.running_var,
                 self.eps, exponential_average_factor, process_group, world_size)

     @classmethod
     def convert_sync_batchnorm(cls, module, process_group=None):
         r"""Helper function to convert `torch.nn.BatchNormND` layer in the model to
         `torch.nn.SyncBatchNorm` layer.

         Args:
             module (nn.Module): containing module
             process_group (optional): process group to scope synchronization,
         default is the whole world

         Returns:
             The original module with the converted `torch.nn.SyncBatchNorm` layer

         Example::

             >>> # Network with nn.BatchNorm layer
             >>> module = torch.nn.Sequential(
             >>>            torch.nn.Linear(20, 100),
             >>>            torch.nn.BatchNorm1d(100)
             >>>          ).cuda()
             >>> # creating process group (optional)
             >>> # process_ids is a list of int identifying rank ids.
             >>> process_group = torch.distributed.new_group(process_ids)
             >>> sync_bn_module = convert_sync_batchnorm(module, process_group)

         """
         module_output = module
         if isinstance(module, torch.nn.modules.batchnorm._BatchNorm):
             module_output = torch.nn.SyncBatchNorm(module.num_features,
                                                    module.eps, module.momentum,
                                                    module.affine,
                                                    module.track_running_stats,
                                                    process_group)
             if module.affine:
                 module_output.weight.data = module.weight.data.clone().detach()
                 module_output.bias.data = module.bias.data.clone().detach()
             module_output.running_mean = module.running_mean
             module_output.running_var = module.running_var
             module_output.num_batches_tracked = module.num_batches_tracked
         for name, child in module.named_children():
             module_output.add_module(name, cls.convert_sync_batchnorm(child))
         del module
         return module_output
	from __future__ import division

	import torch
	from ._functions import SyncBatchNorm as sync_batch_norm
	from .module import Module
	from torch.nn.parameter import Parameter
	from .. import functional as F
	from .. import init
	from ..._jit_internal import weak_module, weak_script_method


	# TODO: check contiguous in THNN
	# TODO: use separate backend functions?
	@weak_module
	class _BatchNorm(Module):
	_version = 2
	__constants__ = ['track_running_stats', 'momentum', 'eps', 'weight', 'bias',
	'running_mean', 'running_var', 'num_batches_tracked']

	def __init__(self, num_features, eps=1e-5, momentum=0.1, affine=True,
	track_running_stats=True):
	super(_BatchNorm, self).__init__()
	self.num_features = num_features
	self.eps = eps
	self.momentum = momentum
	self.affine = affine
	self.track_running_stats = track_running_stats
	if self.affine:
	self.weight = Parameter(torch.Tensor(num_features))
	self.bias = Parameter(torch.Tensor(num_features))
	else:
	self.register_parameter('weight', None)
	self.register_parameter('bias', None)
	if self.track_running_stats:
	self.register_buffer('running_mean', torch.zeros(num_features))
	self.register_buffer('running_var', torch.ones(num_features))
	self.register_buffer('num_batches_tracked', torch.tensor(0, dtype=torch.long))
	else:
	self.register_parameter('running_mean', None)
	self.register_parameter('running_var', None)
	self.register_parameter('num_batches_tracked', None)
	self.reset_parameters()

	def reset_running_stats(self):
	if self.track_running_stats:
	self.running_mean.zero_()
	self.running_var.fill_(1)
	self.num_batches_tracked.zero_()

	def reset_parameters(self):
	self.reset_running_stats()
	if self.affine:
	init.uniform_(self.weight)
	init.zeros_(self.bias)

	def _check_input_dim(self, input):
	raise NotImplementedError

	@weak_script_method
	def forward(self, input):
	self._check_input_dim(input)

	# exponential_average_factor is self.momentum set to
	# (when it is available) only so that if gets updated
	# in ONNX graph when this node is exported to ONNX.
	if self.momentum is None:
	exponential_average_factor = 0.0
	else:
	exponential_average_factor = self.momentum

	if self.training and self.track_running_stats:
	# TODO: if statement only here to tell the jit to skip emitting this when it is None
	if self.num_batches_tracked is not None:
	self.num_batches_tracked += 1
	if self.momentum is None: # use cumulative moving average
	exponential_average_factor = 1.0 / float(self.num_batches_tracked)
	else: # use exponential moving average
	exponential_average_factor = self.momentum

	return F.batch_norm(
	input, self.running_mean, self.running_var, self.weight, self.bias,
	self.training or not self.track_running_stats,
	exponential_average_factor, self.eps)

	def extra_repr(self):
	return '{num_features}, eps={eps}, momentum={momentum}, affine={affine}, ' \
	'track_running_stats={track_running_stats}'.format(**self.__dict__)

	def _load_from_state_dict(self, state_dict, prefix, local_metadata, strict,
	missing_keys, unexpected_keys, error_msgs):
	version = local_metadata.get('version', None)

	if (version is None or version < 2) and self.track_running_stats:
	# at version 2: added num_batches_tracked buffer
	# this should have a default value of 0
	num_batches_tracked_key = prefix + 'num_batches_tracked'
	if num_batches_tracked_key not in state_dict:
	state_dict[num_batches_tracked_key] = torch.tensor(0, dtype=torch.long)

	super(_BatchNorm, self)._load_from_state_dict(
	state_dict, prefix, local_metadata, strict,
	missing_keys, unexpected_keys, error_msgs)


	@weak_module
	class BatchNorm1d(_BatchNorm):
	r"""Applies Batch Normalization over a 2D or 3D input (a mini-batch of 1D
	inputs with optional additional channel dimension) as described in the paper
	`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

	.. math::

	y = \frac{x - \mathrm{E}[x]}{\sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

	The mean and standard-deviation are calculated per-dimension over
	the mini-batches and :math:`\gamma` and :math:`\beta` are learnable parameter vectors
	of size `C` (where `C` is the input size). By default, the elements of :math:`\gamma` are sampled
	from :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

	Also by default, during training this layer keeps running estimates of its
	computed mean and variance, which are then used for normalization during
	evaluation. The running estimates are kept with a default :attr:`momentum`
	of 0.1.

	If :attr:`track_running_stats` is set to ``False``, this layer then does not
	keep running estimates, and batch statistics are instead used during
	evaluation time as well.

	.. note::
	This :attr:`momentum` argument is different from one used in optimizer
	classes and the conventional notion of momentum. Mathematically, the
	update rule for running statistics here is
	:math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momentum} \times x_t`,
	where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
	new observed value.

	Because the Batch Normalization is done over the `C` dimension, computing statistics
	on `(N, L)` slices, it's common terminology to call this Temporal Batch Normalization.

	Args:
	num_features: :math:`C` from an expected input of size
	:math:`(N, C, L)` or :math:`L` from input of size :math:`(N, L)`
	eps: a value added to the denominator for numerical stability.
	Default: 1e-5
	momentum: the value used for the running_mean and running_var
	computation. Can be set to ``None`` for cumulative moving average
	(i.e. simple average). Default: 0.1
	affine: a boolean value that when set to ``True``, this module has
	learnable affine parameters. Default: ``True``
	track_running_stats: a boolean value that when set to ``True``, this
	module tracks the running mean and variance, and when set to ``False``,
	this module does not track such statistics and always uses batch
	statistics in both training and eval modes. Default: ``True``

	Shape:
	- Input: :math:`(N, C)` or :math:`(N, C, L)`
	- Output: :math:`(N, C)` or :math:`(N, C, L)` (same shape as input)

	Examples::

	>>> # With Learnable Parameters
	>>> m = nn.BatchNorm1d(100)
	>>> # Without Learnable Parameters
	>>> m = nn.BatchNorm1d(100, affine=False)
	>>> input = torch.randn(20, 100)
	>>> output = m(input)

	.. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
	https://arxiv.org/abs/1502.03167
	"""

	@weak_script_method
	def _check_input_dim(self, input):
	if input.dim() != 2 and input.dim() != 3:
	raise ValueError('expected 2D or 3D input (got {}D input)'
	.format(input.dim()))


	@weak_module
	class BatchNorm2d(_BatchNorm):
	r"""Applies Batch Normalization over a 4D input (a mini-batch of 2D inputs
	with additional channel dimension) as described in the paper
	`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

	.. math::

	y = \frac{x - \mathrm{E}[x]}{ \sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

	The mean and standard-deviation are calculated per-dimension over
	the mini-batches and :math:`\gamma` and :math:`\beta` are learnable parameter vectors
	of size `C` (where `C` is the input size). By default, the elements of :math:`\gamma` are sampled
	from :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

	Also by default, during training this layer keeps running estimates of its
	computed mean and variance, which are then used for normalization during
	evaluation. The running estimates are kept with a default :attr:`momentum`
	of 0.1.

	If :attr:`track_running_stats` is set to ``False``, this layer then does not
	keep running estimates, and batch statistics are instead used during
	evaluation time as well.

	.. note::
	This :attr:`momentum` argument is different from one used in optimizer
	classes and the conventional notion of momentum. Mathematically, the
	update rule for running statistics here is
	:math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momentum} \times x_t`,
	where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
	new observed value.

	Because the Batch Normalization is done over the `C` dimension, computing statistics
	on `(N, H, W)` slices, it's common terminology to call this Spatial Batch Normalization.

	Args:
	num_features: :math:`C` from an expected input of size
	:math:`(N, C, H, W)`
	eps: a value added to the denominator for numerical stability.
	Default: 1e-5
	momentum: the value used for the running_mean and running_var
	computation. Can be set to ``None`` for cumulative moving average
	(i.e. simple average). Default: 0.1
	affine: a boolean value that when set to ``True``, this module has
	learnable affine parameters. Default: ``True``
	track_running_stats: a boolean value that when set to ``True``, this
	module tracks the running mean and variance, and when set to ``False``,
	this module does not track such statistics and always uses batch
	statistics in both training and eval modes. Default: ``True``

	Shape:
	- Input: :math:`(N, C, H, W)`
	- Output: :math:`(N, C, H, W)` (same shape as input)

	Examples::

	>>> # With Learnable Parameters
	>>> m = nn.BatchNorm2d(100)
	>>> # Without Learnable Parameters
	>>> m = nn.BatchNorm2d(100, affine=False)
	>>> input = torch.randn(20, 100, 35, 45)
	>>> output = m(input)

	.. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
	https://arxiv.org/abs/1502.03167
	"""

	@weak_script_method
	def _check_input_dim(self, input):
	if input.dim() != 4:
	raise ValueError('expected 4D input (got {}D input)'
	.format(input.dim()))


	@weak_module
	class BatchNorm3d(_BatchNorm):
	r"""Applies Batch Normalization over a 5D input (a mini-batch of 3D inputs
	with additional channel dimension) as described in the paper
	`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

	.. math::

	y = \frac{x - \mathrm{E}[x]}{ \sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

	The mean and standard-deviation are calculated per-dimension over
	the mini-batches and :math:`\gamma` and :math:`\beta` are learnable parameter vectors
	of size `C` (where `C` is the input size). By default, the elements of :math:`\gamma` are sampled
	from :math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

	Also by default, during training this layer keeps running estimates of its
	computed mean and variance, which are then used for normalization during
	evaluation. The running estimates are kept with a default :attr:`momentum`
	of 0.1.

	If :attr:`track_running_stats` is set to ``False``, this layer then does not
	keep running estimates, and batch statistics are instead used during
	evaluation time as well.

	.. note::
	This :attr:`momentum` argument is different from one used in optimizer
	classes and the conventional notion of momentum. Mathematically, the
	update rule for running statistics here is
	:math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momentum} \times x_t`,
	where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
	new observed value.

	Because the Batch Normalization is done over the `C` dimension, computing statistics
	on `(N, D, H, W)` slices, it's common terminology to call this Volumetric Batch Normalization
	or Spatio-temporal Batch Normalization.

	Args:
	num_features: :math:`C` from an expected input of size
	:math:`(N, C, D, H, W)`
	eps: a value added to the denominator for numerical stability.
	Default: 1e-5
	momentum: the value used for the running_mean and running_var
	computation. Can be set to ``None`` for cumulative moving average
	(i.e. simple average). Default: 0.1
	affine: a boolean value that when set to ``True``, this module has
	learnable affine parameters. Default: ``True``
	track_running_stats: a boolean value that when set to ``True``, this
	module tracks the running mean and variance, and when set to ``False``,
	this module does not track such statistics and always uses batch
	statistics in both training and eval modes. Default: ``True``

	Shape:
	- Input: :math:`(N, C, D, H, W)`
	- Output: :math:`(N, C, D, H, W)` (same shape as input)

	Examples::

	>>> # With Learnable Parameters
	>>> m = nn.BatchNorm3d(100)
	>>> # Without Learnable Parameters
	>>> m = nn.BatchNorm3d(100, affine=False)
	>>> input = torch.randn(20, 100, 35, 45, 10)
	>>> output = m(input)

	.. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
	https://arxiv.org/abs/1502.03167
	"""

	@weak_script_method
	def _check_input_dim(self, input):
	if input.dim() != 5:
	raise ValueError('expected 5D input (got {}D input)'
	.format(input.dim()))


	class SyncBatchNorm(_BatchNorm):
	r"""Applies Batch Normalization over a N-Dimensional input (a mini-batch of [N-2]D inputs
	with additional channel dimension) as described in the paper
	`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`_ .

	.. math::

	y = \frac{x - \mathrm{E}[x]}{ \sqrt{\mathrm{Var}[x] + \epsilon}} * \gamma + \beta

	The mean and standard-deviation are calculated per-dimension over all
	mini-batches of the same process groups. :math:`\gamma` and :math:`\beta`
	are learnable parameter vectors of size `C` (where `C` is the input size).
	By default, the elements of :math:`\gamma` are sampled from
	:math:`\mathcal{U}(0, 1)` and the elements of :math:`\beta` are set to 0.

	Also by default, during training this layer keeps running estimates of its
	computed mean and variance, which are then used for normalization during
	evaluation. The running estimates are kept with a default :attr:`momentum`
	of 0.1.

	If :attr:`track_running_stats` is set to ``False``, this layer then does not
	keep running estimates, and batch statistics are instead used during
	evaluation time as well.

	.. note::
	This :attr:`momentum` argument is different from one used in optimizer
	classes and the conventional notion of momentum. Mathematically, the
	update rule for running statistics here is
	:math:`\hat{x}_\text{new} = (1 - \text{momentum}) \times \hat{x} + \text{momemtum} \times x_t`,
	where :math:`\hat{x}` is the estimated statistic and :math:`x_t` is the
	new observed value.

	Because the Batch Normalization is done over the `C` dimension, computing statistics
	on `(N, +)` slices, it's common terminology to call this Volumetric Batch Normalization
	or Spatio-temporal Batch Normalization.

	Currently SyncBatchNorm only supports DistributedDataParallel with single GPU per process. Use
	torch.nn.SyncBatchNorm.convert_sync_batchnorm() to convert BatchNorm layer to SyncBatchNorm before wrapping
	Network with DDP.

	Args:
	num_features: :math:`C` from an expected input of size
	:math:`(N, C, +)`
	eps: a value added to the denominator for numerical stability.
	Default: 1e-5
	momentum: the value used for the running_mean and running_var
	computation. Can be set to ``None`` for cumulative moving average
	(i.e. simple average). Default: 0.1
	affine: a boolean value that when set to ``True``, this module has
	learnable affine parameters. Default: ``True``
	track_running_stats: a boolean value that when set to ``True``, this
	module tracks the running mean and variance, and when set to ``False``,
	this module does not track such statistics and always uses batch
	statistics in both training and eval modes. Default: ``True``
	process_group: synchronization of stats happen within each process group
	individually. Default behavior is synchronization across the whole
	world

	Shape:
	- Input: :math:`(N, C, +)`
	- Output: :math:`(N, C, +)` (same shape as input)

	Examples::

	>>> # With Learnable Parameters
	>>> m = nn.SyncBatchNorm(100)
	>>> # creating process group (optional)
	>>> # process_ids is a list of int identifying rank ids.
	>>> process_group = torch.distributed.new_group(process_ids)
	>>> # Without Learnable Parameters
	>>> m = nn.BatchNorm3d(100, affine=False, process_group=process_group)
	>>> input = torch.randn(20, 100, 35, 45, 10)
	>>> output = m(input)

	>>> # network is nn.BatchNorm layer
	>>> sync_bn_network = torch.nn.utils.convert_sync_batchnorm(network, process_group)
	>>> # only single gpu per process is currently supported
	>>> ddp_sync_bn_network = torch.nn.parallel.DistributedDataParallel(
	>>> sync_bn_network,
	>>> device_ids=[args.local_rank],
	>>> output_device=args.local_rank)

	.. _`Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift`:
	https://arxiv.org/abs/1502.03167
	"""

	def __init__(self, num_features, eps=1e-5, momentum=0.1, affine=True,
	track_running_stats=True, process_group=None):
	super(SyncBatchNorm, self).__init__(num_features, eps, momentum, affine, track_running_stats)
	self.process_group = process_group
	# gpu_size is set through DistributedDataParallel initialization. This is to ensure that SyncBatchNorm is used
	# under supported condition (single GPU per process)
	self.ddp_gpu_size = None

	def _check_input_dim(self, input):
	if input.dim() <= 2:
	raise ValueError('expected at least 3D input (got {}D input)'
	.format(input.dim()))

	def _specify_ddp_gpu_num(self, gpu_size):
	if gpu_size > 1:
	raise ValueError('SyncBatchNorm is only supported for DDP with single GPU per process')
	self.ddp_gpu_size = gpu_size

	def forward(self, input):
	# currently only GPU input is supported
	if not input.is_cuda:
	raise ValueError('expected input tensor to be on GPU')

	if not self.ddp_gpu_size:
	raise AttributeError('SyncBatchNorm is only supported within torch.nn.parallel.DistributedDataParallel')

	self._check_input_dim(input)

	exponential_average_factor = 0.0

	if self.training and self.track_running_stats:
	self.num_batches_tracked += 1
	if self.momentum is None: # use cumulative moving average
	exponential_average_factor = 1.0 / self.num_batches_tracked.item()
	else: # use exponential moving average
	exponential_average_factor = self.momentum

	world_size = 1
	process_group = torch.distributed.group.WORLD
	if self.process_group:
	process_group = self.process_group
	world_size = torch.distributed.get_world_size(process_group)

	# fallback to framework BN when synchronization is not necessary
	if world_size == 1 or (not self.training and self.track_running_stats):
	return F.batch_norm(
	input, self.running_mean, self.running_var, self.weight, self.bias,
	self.training or not self.track_running_stats,
	exponential_average_factor, self.eps)
	else:
	return sync_batch_norm.apply(
	input, self.weight, self.bias, self.running_mean, self.running_var,
	self.eps, exponential_average_factor, process_group, world_size)

	@classmethod
	def convert_sync_batchnorm(cls, module, process_group=None):
	r"""Helper function to convert `torch.nn.BatchNormND` layer in the model to
	`torch.nn.SyncBatchNorm` layer.

	Args:
	module (nn.Module): containing module
	process_group (optional): process group to scope synchronization,
	default is the whole world

	Returns:
	The original module with the converted `torch.nn.SyncBatchNorm` layer

	Example::

	>>> # Network with nn.BatchNorm layer
	>>> module = torch.nn.Sequential(
	>>> torch.nn.Linear(20, 100),
	>>> torch.nn.BatchNorm1d(100)
	>>> ).cuda()
	>>> # creating process group (optional)
	>>> # process_ids is a list of int identifying rank ids.
	>>> process_group = torch.distributed.new_group(process_ids)
	>>> sync_bn_module = convert_sync_batchnorm(module, process_group)

	"""
	module_output = module
	if isinstance(module, torch.nn.modules.batchnorm._BatchNorm):
	module_output = torch.nn.SyncBatchNorm(module.num_features,
	module.eps, module.momentum,
	module.affine,
	module.track_running_stats,
	process_group)
	if module.affine:
	module_output.weight.data = module.weight.data.clone().detach()
	module_output.bias.data = module.bias.data.clone().detach()
	module_output.running_mean = module.running_mean
	module_output.running_var = module.running_var
	module_output.num_batches_tracked = module.num_batches_tracked
	for name, child in module.named_children():
	module_output.add_module(name, cls.convert_sync_batchnorm(child))
	del module
	return module_output