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316 lines
13 KiB
316 lines
13 KiB
# -*- coding: utf-8 -*-
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# File : batchnorm.py
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# Author : Jiayuan Mao
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# Email : maojiayuan@gmail.com
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# Date : 27/01/2018
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#
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# This file is part of Synchronized-BatchNorm-PyTorch.
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# https://github.com/vacancy/Synchronized-BatchNorm-PyTorch
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# Distributed under MIT License.
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import collections
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import torch
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import torch.nn.functional as F
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from torch.nn.modules.batchnorm import _BatchNorm
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from torch.nn.parallel._functions import ReduceAddCoalesced, Broadcast
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from .comm import SyncMaster
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__all__ = ['SynchronizedBatchNorm1d', 'SynchronizedBatchNorm2d', 'SynchronizedBatchNorm3d']
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def _sum_ft(tensor):
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"""sum over the first and last dimention"""
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return tensor.sum(dim=0).sum(dim=-1)
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def _unsqueeze_ft(tensor):
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"""add new dementions at the front and the tail"""
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return tensor.unsqueeze(0).unsqueeze(-1)
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_ChildMessage = collections.namedtuple('_ChildMessage', ['sum', 'ssum', 'sum_size'])
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_MasterMessage = collections.namedtuple('_MasterMessage', ['sum', 'inv_std'])
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class _SynchronizedBatchNorm(_BatchNorm):
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def __init__(self, num_features, eps=1e-5, momentum=0.1, affine=True):
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super(_SynchronizedBatchNorm, self).__init__(num_features, eps=eps, momentum=momentum, affine=affine)
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self._sync_master = SyncMaster(self._data_parallel_master)
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self._is_parallel = False
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self._parallel_id = None
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self._slave_pipe = None
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def forward(self, input):
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# If it is not parallel computation or is in evaluation mode, use PyTorch's implementation.
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if not (self._is_parallel and self.training):
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return F.batch_norm(
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input, self.running_mean, self.running_var, self.weight, self.bias,
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self.training, self.momentum, self.eps)
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# Resize the input to (B, C, -1).
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input_shape = input.size()
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input = input.view(input.size(0), self.num_features, -1)
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# Compute the sum and square-sum.
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sum_size = input.size(0) * input.size(2)
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input_sum = _sum_ft(input)
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input_ssum = _sum_ft(input ** 2)
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# Reduce-and-broadcast the statistics.
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if self._parallel_id == 0:
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mean, inv_std = self._sync_master.run_master(_ChildMessage(input_sum, input_ssum, sum_size))
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else:
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mean, inv_std = self._slave_pipe.run_slave(_ChildMessage(input_sum, input_ssum, sum_size))
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# Compute the output.
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if self.affine:
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# MJY:: Fuse the multiplication for speed.
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output = (input - _unsqueeze_ft(mean)) * _unsqueeze_ft(inv_std * self.weight) + _unsqueeze_ft(self.bias)
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else:
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output = (input - _unsqueeze_ft(mean)) * _unsqueeze_ft(inv_std)
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# Reshape it.
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return output.view(input_shape)
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def __data_parallel_replicate__(self, ctx, copy_id):
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self._is_parallel = True
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self._parallel_id = copy_id
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# parallel_id == 0 means master device.
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if self._parallel_id == 0:
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ctx.sync_master = self._sync_master
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else:
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self._slave_pipe = ctx.sync_master.register_slave(copy_id)
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def _data_parallel_master(self, intermediates):
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"""Reduce the sum and square-sum, compute the statistics, and broadcast it."""
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# Always using same "device order" makes the ReduceAdd operation faster.
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# Thanks to:: Tete Xiao (http://tetexiao.com/)
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intermediates = sorted(intermediates, key=lambda i: i[1].sum.get_device())
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to_reduce = [i[1][:2] for i in intermediates]
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to_reduce = [j for i in to_reduce for j in i] # flatten
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target_gpus = [i[1].sum.get_device() for i in intermediates]
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sum_size = sum([i[1].sum_size for i in intermediates])
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sum_, ssum = ReduceAddCoalesced.apply(target_gpus[0], 2, *to_reduce)
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mean, inv_std = self._compute_mean_std(sum_, ssum, sum_size)
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broadcasted = Broadcast.apply(target_gpus, mean, inv_std)
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outputs = []
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for i, rec in enumerate(intermediates):
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outputs.append((rec[0], _MasterMessage(*broadcasted[i*2:i*2+2])))
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return outputs
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def _compute_mean_std(self, sum_, ssum, size):
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"""Compute the mean and standard-deviation with sum and square-sum. This method
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also maintains the moving average on the master device."""
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assert size > 1, 'BatchNorm computes unbiased standard-deviation, which requires size > 1.'
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mean = sum_ / size
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sumvar = ssum - sum_ * mean
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unbias_var = sumvar / (size - 1)
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bias_var = sumvar / size
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self.running_mean = (1 - self.momentum) * self.running_mean + self.momentum * mean.data
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self.running_var = (1 - self.momentum) * self.running_var + self.momentum * unbias_var.data
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return mean, bias_var.clamp(self.eps) ** -0.5
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class SynchronizedBatchNorm1d(_SynchronizedBatchNorm):
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r"""Applies Synchronized Batch Normalization over a 2d or 3d input that is seen as a
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mini-batch.
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.. math::
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y = \frac{x - mean[x]}{ \sqrt{Var[x] + \epsilon}} * gamma + beta
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This module differs from the built-in PyTorch BatchNorm1d as the mean and
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standard-deviation are reduced across all devices during training.
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For example, when one uses `nn.DataParallel` to wrap the network during
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training, PyTorch's implementation normalize the tensor on each device using
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the statistics only on that device, which accelerated the computation and
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is also easy to implement, but the statistics might be inaccurate.
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Instead, in this synchronized version, the statistics will be computed
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over all training samples distributed on multiple devices.
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Note that, for one-GPU or CPU-only case, this module behaves exactly same
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as the built-in PyTorch implementation.
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The mean and standard-deviation are calculated per-dimension over
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the mini-batches and gamma and beta are learnable parameter vectors
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of size C (where C is the input size).
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During training, this layer keeps a running estimate of its computed mean
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and variance. The running sum is kept with a default momentum of 0.1.
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During evaluation, this running mean/variance is used for normalization.
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Because the BatchNorm is done over the `C` dimension, computing statistics
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on `(N, L)` slices, it's common terminology to call this Temporal BatchNorm
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Args:
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num_features: num_features from an expected input of size
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`batch_size x num_features [x width]`
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eps: a value added to the denominator for numerical stability.
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Default: 1e-5
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momentum: the value used for the running_mean and running_var
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computation. Default: 0.1
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affine: a boolean value that when set to ``True``, gives the layer learnable
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affine parameters. Default: ``True``
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Shape:
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- Input: :math:`(N, C)` or :math:`(N, C, L)`
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- Output: :math:`(N, C)` or :math:`(N, C, L)` (same shape as input)
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Examples:
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>>> # With Learnable Parameters
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>>> m = SynchronizedBatchNorm1d(100)
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>>> # Without Learnable Parameters
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>>> m = SynchronizedBatchNorm1d(100, affine=False)
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>>> input = torch.autograd.Variable(torch.randn(20, 100))
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>>> output = m(input)
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"""
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def _check_input_dim(self, input):
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if input.dim() != 2 and input.dim() != 3:
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raise ValueError('expected 2D or 3D input (got {}D input)'
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.format(input.dim()))
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super(SynchronizedBatchNorm1d, self)._check_input_dim(input)
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class SynchronizedBatchNorm2d(_SynchronizedBatchNorm):
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r"""Applies Batch Normalization over a 4d input that is seen as a mini-batch
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of 3d inputs
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.. math::
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y = \frac{x - mean[x]}{ \sqrt{Var[x] + \epsilon}} * gamma + beta
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This module differs from the built-in PyTorch BatchNorm2d as the mean and
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standard-deviation are reduced across all devices during training.
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For example, when one uses `nn.DataParallel` to wrap the network during
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training, PyTorch's implementation normalize the tensor on each device using
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the statistics only on that device, which accelerated the computation and
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is also easy to implement, but the statistics might be inaccurate.
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Instead, in this synchronized version, the statistics will be computed
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over all training samples distributed on multiple devices.
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|
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Note that, for one-GPU or CPU-only case, this module behaves exactly same
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as the built-in PyTorch implementation.
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The mean and standard-deviation are calculated per-dimension over
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the mini-batches and gamma and beta are learnable parameter vectors
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of size C (where C is the input size).
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During training, this layer keeps a running estimate of its computed mean
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and variance. The running sum is kept with a default momentum of 0.1.
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During evaluation, this running mean/variance is used for normalization.
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Because the BatchNorm is done over the `C` dimension, computing statistics
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on `(N, H, W)` slices, it's common terminology to call this Spatial BatchNorm
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Args:
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num_features: num_features from an expected input of
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size batch_size x num_features x height x width
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eps: a value added to the denominator for numerical stability.
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Default: 1e-5
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momentum: the value used for the running_mean and running_var
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computation. Default: 0.1
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affine: a boolean value that when set to ``True``, gives the layer learnable
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affine parameters. Default: ``True``
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Shape:
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- Input: :math:`(N, C, H, W)`
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- Output: :math:`(N, C, H, W)` (same shape as input)
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Examples:
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>>> # With Learnable Parameters
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>>> m = SynchronizedBatchNorm2d(100)
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>>> # Without Learnable Parameters
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>>> m = SynchronizedBatchNorm2d(100, affine=False)
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>>> input = torch.autograd.Variable(torch.randn(20, 100, 35, 45))
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>>> output = m(input)
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"""
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def _check_input_dim(self, input):
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if input.dim() != 4:
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raise ValueError('expected 4D input (got {}D input)'
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.format(input.dim()))
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super(SynchronizedBatchNorm2d, self)._check_input_dim(input)
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class SynchronizedBatchNorm3d(_SynchronizedBatchNorm):
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r"""Applies Batch Normalization over a 5d input that is seen as a mini-batch
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of 4d inputs
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.. math::
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y = \frac{x - mean[x]}{ \sqrt{Var[x] + \epsilon}} * gamma + beta
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This module differs from the built-in PyTorch BatchNorm3d as the mean and
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standard-deviation are reduced across all devices during training.
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For example, when one uses `nn.DataParallel` to wrap the network during
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training, PyTorch's implementation normalize the tensor on each device using
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the statistics only on that device, which accelerated the computation and
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is also easy to implement, but the statistics might be inaccurate.
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Instead, in this synchronized version, the statistics will be computed
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over all training samples distributed on multiple devices.
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|
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Note that, for one-GPU or CPU-only case, this module behaves exactly same
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as the built-in PyTorch implementation.
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|
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The mean and standard-deviation are calculated per-dimension over
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the mini-batches and gamma and beta are learnable parameter vectors
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of size C (where C is the input size).
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During training, this layer keeps a running estimate of its computed mean
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and variance. The running sum is kept with a default momentum of 0.1.
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During evaluation, this running mean/variance is used for normalization.
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Because the BatchNorm is done over the `C` dimension, computing statistics
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on `(N, D, H, W)` slices, it's common terminology to call this Volumetric BatchNorm
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or Spatio-temporal BatchNorm
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Args:
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num_features: num_features from an expected input of
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size batch_size x num_features x depth x height x width
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eps: a value added to the denominator for numerical stability.
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Default: 1e-5
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momentum: the value used for the running_mean and running_var
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computation. Default: 0.1
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affine: a boolean value that when set to ``True``, gives the layer learnable
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affine parameters. Default: ``True``
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Shape:
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- Input: :math:`(N, C, D, H, W)`
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- Output: :math:`(N, C, D, H, W)` (same shape as input)
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Examples:
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>>> # With Learnable Parameters
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>>> m = SynchronizedBatchNorm3d(100)
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>>> # Without Learnable Parameters
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>>> m = SynchronizedBatchNorm3d(100, affine=False)
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>>> input = torch.autograd.Variable(torch.randn(20, 100, 35, 45, 10))
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>>> output = m(input)
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"""
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def _check_input_dim(self, input):
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if input.dim() != 5:
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raise ValueError('expected 5D input (got {}D input)'
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.format(input.dim()))
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super(SynchronizedBatchNorm3d, self)._check_input_dim(input)
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