torch.nn.init¶
Warning
All the functions in this module are intended to be used to initialize neural network
parameters, so they all run in torch.no_grad()
mode and will not be taken into
account by autograd.
- torch.nn.init.calculate_gain(nonlinearity, param=None)[source]¶
Return the recommended gain value for the given nonlinearity function.
The values are as follows:
nonlinearity
gain
Linear / Identity
Conv{1,2,3}D
Sigmoid
Tanh
ReLU
Leaky Relu
SELU
Warning
In order to implement Self-Normalizing Neural Networks , you should use
nonlinearity='linear'
instead ofnonlinearity='selu'
. This gives the initial weights a variance of1 / N
, which is necessary to induce a stable fixed point in the forward pass. In contrast, the default gain forSELU
sacrifices the normalization effect for more stable gradient flow in rectangular layers.- Parameters
nonlinearity – the non-linear function (nn.functional name)
param – optional parameter for the non-linear function
Examples
>>> gain = nn.init.calculate_gain('leaky_relu', 0.2) # leaky_relu with negative_slope=0.2
- torch.nn.init.uniform_(tensor, a=0.0, b=1.0, generator=None)[source]¶
Fill the input Tensor with values drawn from the uniform distribution.
.
- Parameters
- Return type
Examples
>>> w = torch.empty(3, 5) >>> nn.init.uniform_(w)
- torch.nn.init.normal_(tensor, mean=0.0, std=1.0, generator=None)[source]¶
Fill the input Tensor with values drawn from the normal distribution.
.
- Parameters
- Return type
Examples
>>> w = torch.empty(3, 5) >>> nn.init.normal_(w)
- torch.nn.init.constant_(tensor, val)[source]¶
Fill the input Tensor with the value .
- Parameters
- Return type
Examples
>>> w = torch.empty(3, 5) >>> nn.init.constant_(w, 0.3)
- torch.nn.init.ones_(tensor)[source]¶
Fill the input Tensor with the scalar value 1.
Examples
>>> w = torch.empty(3, 5) >>> nn.init.ones_(w)
- torch.nn.init.zeros_(tensor)[source]¶
Fill the input Tensor with the scalar value 0.
Examples
>>> w = torch.empty(3, 5) >>> nn.init.zeros_(w)
- torch.nn.init.eye_(tensor)[source]¶
Fill the 2-dimensional input Tensor with the identity matrix.
Preserves the identity of the inputs in Linear layers, where as many inputs are preserved as possible.
- Parameters
tensor – a 2-dimensional torch.Tensor
Examples
>>> w = torch.empty(3, 5) >>> nn.init.eye_(w)
- torch.nn.init.dirac_(tensor, groups=1)[source]¶
Fill the {3, 4, 5}-dimensional input Tensor with the Dirac delta function.
Preserves the identity of the inputs in Convolutional layers, where as many input channels are preserved as possible. In case of groups>1, each group of channels preserves identity
- Parameters
tensor – a {3, 4, 5}-dimensional torch.Tensor
groups (int, optional) – number of groups in the conv layer (default: 1)
Examples
>>> w = torch.empty(3, 16, 5, 5) >>> nn.init.dirac_(w) >>> w = torch.empty(3, 24, 5, 5) >>> nn.init.dirac_(w, 3)
- torch.nn.init.xavier_uniform_(tensor, gain=1.0, generator=None)[source]¶
Fill the input Tensor with values using a Xavier uniform distribution.
The method is described in Understanding the difficulty of training deep feedforward neural networks - Glorot, X. & Bengio, Y. (2010). The resulting tensor will have values sampled from where
Also known as Glorot initialization.
- Parameters
- Return type
Examples
>>> w = torch.empty(3, 5) >>> nn.init.xavier_uniform_(w, gain=nn.init.calculate_gain('relu'))
- torch.nn.init.xavier_normal_(tensor, gain=1.0, generator=None)[source]¶
Fill the input Tensor with values using a Xavier normal distribution.
The method is described in Understanding the difficulty of training deep feedforward neural networks - Glorot, X. & Bengio, Y. (2010). The resulting tensor will have values sampled from where
Also known as Glorot initialization.
- Parameters
- Return type
Examples
>>> w = torch.empty(3, 5) >>> nn.init.xavier_normal_(w)
- torch.nn.init.kaiming_uniform_(tensor, a=0, mode='fan_in', nonlinearity='leaky_relu', generator=None)[source]¶
Fill the input Tensor with values using a Kaiming uniform distribution.
The method is described in Delving deep into rectifiers: Surpassing human-level performance on ImageNet classification - He, K. et al. (2015). The resulting tensor will have values sampled from where
Also known as He initialization.
- Parameters
tensor (Tensor) – an n-dimensional torch.Tensor
a (float) – the negative slope of the rectifier used after this layer (only used with
'leaky_relu'
)mode (str) – either
'fan_in'
(default) or'fan_out'
. Choosing'fan_in'
preserves the magnitude of the variance of the weights in the forward pass. Choosing'fan_out'
preserves the magnitudes in the backwards pass.nonlinearity (str) – the non-linear function (nn.functional name), recommended to use only with
'relu'
or'leaky_relu'
(default).generator (Optional[Generator]) – the torch Generator to sample from (default: None)
Examples
>>> w = torch.empty(3, 5) >>> nn.init.kaiming_uniform_(w, mode='fan_in', nonlinearity='relu')
- torch.nn.init.kaiming_normal_(tensor, a=0, mode='fan_in', nonlinearity='leaky_relu', generator=None)[source]¶
Fill the input Tensor with values using a Kaiming normal distribution.
The method is described in Delving deep into rectifiers: Surpassing human-level performance on ImageNet classification - He, K. et al. (2015). The resulting tensor will have values sampled from where
Also known as He initialization.
- Parameters
tensor (Tensor) – an n-dimensional torch.Tensor
a (float) – the negative slope of the rectifier used after this layer (only used with
'leaky_relu'
)mode (str) – either
'fan_in'
(default) or'fan_out'
. Choosing'fan_in'
preserves the magnitude of the variance of the weights in the forward pass. Choosing'fan_out'
preserves the magnitudes in the backwards pass.nonlinearity (str) – the non-linear function (nn.functional name), recommended to use only with
'relu'
or'leaky_relu'
(default).generator (Optional[Generator]) – the torch Generator to sample from (default: None)
Examples
>>> w = torch.empty(3, 5) >>> nn.init.kaiming_normal_(w, mode='fan_out', nonlinearity='relu')
- torch.nn.init.trunc_normal_(tensor, mean=0.0, std=1.0, a=-2.0, b=2.0, generator=None)[source]¶
Fill the input Tensor with values drawn from a truncated normal distribution.
The values are effectively drawn from the normal distribution with values outside redrawn until they are within the bounds. The method used for generating the random values works best when .
- Parameters
tensor (Tensor) – an n-dimensional torch.Tensor
mean (float) – the mean of the normal distribution
std (float) – the standard deviation of the normal distribution
a (float) – the minimum cutoff value
b (float) – the maximum cutoff value
generator (Optional[Generator]) – the torch Generator to sample from (default: None)
- Return type
Examples
>>> w = torch.empty(3, 5) >>> nn.init.trunc_normal_(w)
- torch.nn.init.orthogonal_(tensor, gain=1, generator=None)[source]¶
Fill the input Tensor with a (semi) orthogonal matrix.
Described in Exact solutions to the nonlinear dynamics of learning in deep linear neural networks - Saxe, A. et al. (2013). The input tensor must have at least 2 dimensions, and for tensors with more than 2 dimensions the trailing dimensions are flattened.
- Parameters
Examples
>>> w = torch.empty(3, 5) >>> nn.init.orthogonal_(w)
- torch.nn.init.sparse_(tensor, sparsity, std=0.01, generator=None)[source]¶
Fill the 2D input Tensor as a sparse matrix.
The non-zero elements will be drawn from the normal distribution , as described in Deep learning via Hessian-free optimization - Martens, J. (2010).
- Parameters
Examples
>>> w = torch.empty(3, 5) >>> nn.init.sparse_(w, sparsity=0.1)