265 lines
10 KiB
Python
265 lines
10 KiB
Python
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import math
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from typing import Any
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import torch
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from torch import Tensor
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from torch.nn.parameter import Parameter, UninitializedParameter
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from .. import functional as F
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from .. import init
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from .module import Module
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from .lazy import LazyModuleMixin
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__all__ = [
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'Bilinear',
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'Identity',
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'LazyLinear',
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'Linear',
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]
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class Identity(Module):
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r"""A placeholder identity operator that is argument-insensitive.
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Args:
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args: any argument (unused)
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kwargs: any keyword argument (unused)
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Shape:
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- Input: :math:`(*)`, where :math:`*` means any number of dimensions.
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- Output: :math:`(*)`, same shape as the input.
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Examples::
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>>> m = nn.Identity(54, unused_argument1=0.1, unused_argument2=False)
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>>> input = torch.randn(128, 20)
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>>> output = m(input)
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>>> print(output.size())
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torch.Size([128, 20])
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"""
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def __init__(self, *args: Any, **kwargs: Any) -> None:
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super().__init__()
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def forward(self, input: Tensor) -> Tensor:
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return input
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class Linear(Module):
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r"""Applies a linear transformation to the incoming data: :math:`y = xA^T + b`.
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This module supports :ref:`TensorFloat32<tf32_on_ampere>`.
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On certain ROCm devices, when using float16 inputs this module will use :ref:`different precision<fp16_on_mi200>` for backward.
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Args:
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in_features: size of each input sample
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out_features: size of each output sample
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bias: If set to ``False``, the layer will not learn an additive bias.
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Default: ``True``
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Shape:
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- Input: :math:`(*, H_{in})` where :math:`*` means any number of
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dimensions including none and :math:`H_{in} = \text{in\_features}`.
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- Output: :math:`(*, H_{out})` where all but the last dimension
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are the same shape as the input and :math:`H_{out} = \text{out\_features}`.
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Attributes:
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weight: the learnable weights of the module of shape
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:math:`(\text{out\_features}, \text{in\_features})`. The values are
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initialized from :math:`\mathcal{U}(-\sqrt{k}, \sqrt{k})`, where
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:math:`k = \frac{1}{\text{in\_features}}`
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bias: the learnable bias of the module of shape :math:`(\text{out\_features})`.
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If :attr:`bias` is ``True``, the values are initialized from
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:math:`\mathcal{U}(-\sqrt{k}, \sqrt{k})` where
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:math:`k = \frac{1}{\text{in\_features}}`
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Examples::
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>>> m = nn.Linear(20, 30)
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>>> input = torch.randn(128, 20)
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>>> output = m(input)
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>>> print(output.size())
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torch.Size([128, 30])
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"""
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__constants__ = ['in_features', 'out_features']
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in_features: int
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out_features: int
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weight: Tensor
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def __init__(self, in_features: int, out_features: int, bias: bool = True,
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device=None, dtype=None) -> None:
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factory_kwargs = {'device': device, 'dtype': dtype}
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super().__init__()
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self.in_features = in_features
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self.out_features = out_features
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self.weight = Parameter(torch.empty((out_features, in_features), **factory_kwargs))
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if bias:
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self.bias = Parameter(torch.empty(out_features, **factory_kwargs))
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else:
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self.register_parameter('bias', None)
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self.reset_parameters()
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def reset_parameters(self) -> None:
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# Setting a=sqrt(5) in kaiming_uniform is the same as initializing with
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# uniform(-1/sqrt(in_features), 1/sqrt(in_features)). For details, see
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# https://github.com/pytorch/pytorch/issues/57109
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init.kaiming_uniform_(self.weight, a=math.sqrt(5))
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if self.bias is not None:
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fan_in, _ = init._calculate_fan_in_and_fan_out(self.weight)
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bound = 1 / math.sqrt(fan_in) if fan_in > 0 else 0
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init.uniform_(self.bias, -bound, bound)
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def forward(self, input: Tensor) -> Tensor:
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return F.linear(input, self.weight, self.bias)
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def extra_repr(self) -> str:
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return f'in_features={self.in_features}, out_features={self.out_features}, bias={self.bias is not None}'
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# This class exists solely to avoid triggering an obscure error when scripting
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# an improperly quantized attention layer. See this issue for details:
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# https://github.com/pytorch/pytorch/issues/58969
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# TODO: fail fast on quantization API usage error, then remove this class
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# and replace uses of it with plain Linear
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class NonDynamicallyQuantizableLinear(Linear):
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def __init__(self, in_features: int, out_features: int, bias: bool = True,
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device=None, dtype=None) -> None:
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super().__init__(in_features, out_features, bias=bias,
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device=device, dtype=dtype)
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class Bilinear(Module):
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r"""Applies a bilinear transformation to the incoming data: :math:`y = x_1^T A x_2 + b`.
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Args:
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in1_features: size of each first input sample
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in2_features: size of each second input sample
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out_features: size of each output sample
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bias: If set to False, the layer will not learn an additive bias.
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Default: ``True``
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Shape:
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- Input1: :math:`(*, H_{in1})` where :math:`H_{in1}=\text{in1\_features}` and
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:math:`*` means any number of additional dimensions including none. All but the last dimension
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of the inputs should be the same.
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- Input2: :math:`(*, H_{in2})` where :math:`H_{in2}=\text{in2\_features}`.
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- Output: :math:`(*, H_{out})` where :math:`H_{out}=\text{out\_features}`
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and all but the last dimension are the same shape as the input.
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Attributes:
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weight: the learnable weights of the module of shape
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:math:`(\text{out\_features}, \text{in1\_features}, \text{in2\_features})`.
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The values are initialized from :math:`\mathcal{U}(-\sqrt{k}, \sqrt{k})`, where
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:math:`k = \frac{1}{\text{in1\_features}}`
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bias: the learnable bias of the module of shape :math:`(\text{out\_features})`.
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If :attr:`bias` is ``True``, the values are initialized from
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:math:`\mathcal{U}(-\sqrt{k}, \sqrt{k})`, where
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:math:`k = \frac{1}{\text{in1\_features}}`
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Examples::
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>>> m = nn.Bilinear(20, 30, 40)
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>>> input1 = torch.randn(128, 20)
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>>> input2 = torch.randn(128, 30)
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>>> output = m(input1, input2)
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>>> print(output.size())
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torch.Size([128, 40])
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"""
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__constants__ = ['in1_features', 'in2_features', 'out_features']
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in1_features: int
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in2_features: int
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out_features: int
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weight: Tensor
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def __init__(self, in1_features: int, in2_features: int, out_features: int, bias: bool = True,
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device=None, dtype=None) -> None:
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factory_kwargs = {'device': device, 'dtype': dtype}
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super().__init__()
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self.in1_features = in1_features
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self.in2_features = in2_features
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self.out_features = out_features
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self.weight = Parameter(torch.empty((out_features, in1_features, in2_features), **factory_kwargs))
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if bias:
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self.bias = Parameter(torch.empty(out_features, **factory_kwargs))
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else:
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self.register_parameter('bias', None)
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self.reset_parameters()
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def reset_parameters(self) -> None:
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bound = 1 / math.sqrt(self.weight.size(1))
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init.uniform_(self.weight, -bound, bound)
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if self.bias is not None:
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init.uniform_(self.bias, -bound, bound)
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def forward(self, input1: Tensor, input2: Tensor) -> Tensor:
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return F.bilinear(input1, input2, self.weight, self.bias)
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def extra_repr(self) -> str:
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return 'in1_features={}, in2_features={}, out_features={}, bias={}'.format(
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self.in1_features, self.in2_features, self.out_features, self.bias is not None
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)
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class LazyLinear(LazyModuleMixin, Linear):
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r"""A :class:`torch.nn.Linear` module where `in_features` is inferred.
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In this module, the `weight` and `bias` are of :class:`torch.nn.UninitializedParameter`
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class. They will be initialized after the first call to ``forward`` is done and the
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module will become a regular :class:`torch.nn.Linear` module. The ``in_features`` argument
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of the :class:`Linear` is inferred from the ``input.shape[-1]``.
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Check the :class:`torch.nn.modules.lazy.LazyModuleMixin` for further documentation
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on lazy modules and their limitations.
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Args:
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out_features: size of each output sample
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bias: If set to ``False``, the layer will not learn an additive bias.
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Default: ``True``
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Attributes:
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weight: the learnable weights of the module of shape
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:math:`(\text{out\_features}, \text{in\_features})`. The values are
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initialized from :math:`\mathcal{U}(-\sqrt{k}, \sqrt{k})`, where
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:math:`k = \frac{1}{\text{in\_features}}`
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bias: the learnable bias of the module of shape :math:`(\text{out\_features})`.
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If :attr:`bias` is ``True``, the values are initialized from
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:math:`\mathcal{U}(-\sqrt{k}, \sqrt{k})` where
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:math:`k = \frac{1}{\text{in\_features}}`
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"""
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cls_to_become = Linear # type: ignore[assignment]
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weight: UninitializedParameter
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bias: UninitializedParameter # type: ignore[assignment]
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def __init__(self, out_features: int, bias: bool = True,
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device=None, dtype=None) -> None:
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factory_kwargs = {'device': device, 'dtype': dtype}
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# bias is hardcoded to False to avoid creating tensor
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# that will soon be overwritten.
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super().__init__(0, 0, False)
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self.weight = UninitializedParameter(**factory_kwargs)
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self.out_features = out_features
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if bias:
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self.bias = UninitializedParameter(**factory_kwargs)
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def reset_parameters(self) -> None:
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if not self.has_uninitialized_params() and self.in_features != 0:
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super().reset_parameters()
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def initialize_parameters(self, input) -> None: # type: ignore[override]
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if self.has_uninitialized_params():
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with torch.no_grad():
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self.in_features = input.shape[-1]
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self.weight.materialize((self.out_features, self.in_features))
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if self.bias is not None:
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self.bias.materialize((self.out_features,))
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self.reset_parameters()
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# TODO: PartialLinear - maybe in sparse?
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