importwarningsfromtypingimportOptional,TupleimporttorchfromtorchimportTensorfrom.linearimportNonDynamicallyQuantizableLinearfromtorch.nn.initimportconstant_,xavier_normal_,xavier_uniform_fromtorch.nn.parameterimportParameterfrom.moduleimportModulefrom..importfunctionalasFclassThreshold(Module):r"""Thresholds each element of the input Tensor. Threshold is defined as: .. math:: y = \begin{cases} x, &\text{ if } x > \text{threshold} \\ \text{value}, &\text{ otherwise } \end{cases} Args: threshold: The value to threshold at value: The value to replace with inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. Examples:: >>> m = nn.Threshold(0.1, 20) >>> input = torch.randn(2) >>> output = m(input) """__constants__=['threshold','value','inplace']threshold:floatvalue:floatinplace:booldef__init__(self,threshold:float,value:float,inplace:bool=False)->None:super(Threshold,self).__init__()self.threshold=thresholdself.value=valueself.inplace=inplace# TODO: check in THNN (if inplace == True, then assert value <= threshold)defforward(self,input:Tensor)->Tensor:returnF.threshold(input,self.threshold,self.value,self.inplace)defextra_repr(self):inplace_str=', inplace=True'ifself.inplaceelse''return'threshold={}, value={}{}'.format(self.threshold,self.value,inplace_str)classReLU(Module):r"""Applies the rectified linear unit function element-wise: :math:`\text{ReLU}(x) = (x)^+ = \max(0, x)` Args: inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/ReLU.png Examples:: >>> m = nn.ReLU() >>> input = torch.randn(2) >>> output = m(input) An implementation of CReLU - https://arxiv.org/abs/1603.05201 >>> m = nn.ReLU() >>> input = torch.randn(2).unsqueeze(0) >>> output = torch.cat((m(input),m(-input))) """__constants__=['inplace']inplace:booldef__init__(self,inplace:bool=False):super(ReLU,self).__init__()self.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.relu(input,inplace=self.inplace)defextra_repr(self)->str:inplace_str='inplace=True'ifself.inplaceelse''returninplace_strclassRReLU(Module):r"""Applies the randomized leaky rectified liner unit function, element-wise, as described in the paper: `Empirical Evaluation of Rectified Activations in Convolutional Network`_. The function is defined as: .. math:: \text{RReLU}(x) = \begin{cases} x & \text{if } x \geq 0 \\ ax & \text{ otherwise } \end{cases} where :math:`a` is randomly sampled from uniform distribution :math:`\mathcal{U}(\text{lower}, \text{upper})`. See: https://arxiv.org/pdf/1505.00853.pdf Args: lower: lower bound of the uniform distribution. Default: :math:`\frac{1}{8}` upper: upper bound of the uniform distribution. Default: :math:`\frac{1}{3}` inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. Examples:: >>> m = nn.RReLU(0.1, 0.3) >>> input = torch.randn(2) >>> output = m(input) .. _`Empirical Evaluation of Rectified Activations in Convolutional Network`: https://arxiv.org/abs/1505.00853 """__constants__=['lower','upper','inplace']lower:floatupper:floatinplace:booldef__init__(self,lower:float=1./8,upper:float=1./3,inplace:bool=False):super(RReLU,self).__init__()self.lower=lowerself.upper=upperself.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.rrelu(input,self.lower,self.upper,self.training,self.inplace)defextra_repr(self):inplace_str=', inplace=True'ifself.inplaceelse''return'lower={}, upper={}{}'.format(self.lower,self.upper,inplace_str)
[docs]classHardtanh(Module):r"""Applies the HardTanh function element-wise HardTanh is defined as: .. math:: \text{HardTanh}(x) = \begin{cases} 1 & \text{ if } x > 1 \\ -1 & \text{ if } x < -1 \\ x & \text{ otherwise } \\ \end{cases} The range of the linear region :math:`[-1, 1]` can be adjusted using :attr:`min_val` and :attr:`max_val`. Args: min_val: minimum value of the linear region range. Default: -1 max_val: maximum value of the linear region range. Default: 1 inplace: can optionally do the operation in-place. Default: ``False`` Keyword arguments :attr:`min_value` and :attr:`max_value` have been deprecated in favor of :attr:`min_val` and :attr:`max_val`. Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Hardtanh.png Examples:: >>> m = nn.Hardtanh(-2, 2) >>> input = torch.randn(2) >>> output = m(input) """__constants__=['min_val','max_val','inplace']min_val:floatmax_val:floatinplace:booldef__init__(self,min_val:float=-1.,max_val:float=1.,inplace:bool=False,min_value:Optional[float]=None,max_value:Optional[float]=None)->None:super(Hardtanh,self).__init__()ifmin_valueisnotNone:warnings.warn("keyword argument min_value is deprecated and rename to min_val")min_val=min_valueifmax_valueisnotNone:warnings.warn("keyword argument max_value is deprecated and rename to max_val")max_val=max_valueself.min_val=min_valself.max_val=max_valself.inplace=inplaceassertself.max_val>self.min_valdefforward(self,input:Tensor)->Tensor:returnF.hardtanh(input,self.min_val,self.max_val,self.inplace)defextra_repr(self)->str:inplace_str=', inplace=True'ifself.inplaceelse''return'min_val={}, max_val={}{}'.format(self.min_val,self.max_val,inplace_str)
classReLU6(Hardtanh):r"""Applies the element-wise function: .. math:: \text{ReLU6}(x) = \min(\max(0,x), 6) Args: inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/ReLU6.png Examples:: >>> m = nn.ReLU6() >>> input = torch.randn(2) >>> output = m(input) """def__init__(self,inplace:bool=False):super(ReLU6,self).__init__(0.,6.,inplace)defextra_repr(self)->str:inplace_str='inplace=True'ifself.inplaceelse''returninplace_strclassSigmoid(Module):r"""Applies the element-wise function: .. math:: \text{Sigmoid}(x) = \sigma(x) = \frac{1}{1 + \exp(-x)} Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Sigmoid.png Examples:: >>> m = nn.Sigmoid() >>> input = torch.randn(2) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:returntorch.sigmoid(input)
[docs]classHardsigmoid(Module):r"""Applies the element-wise function: .. math:: \text{Hardsigmoid}(x) = \begin{cases} 0 & \text{if~} x \le -3, \\ 1 & \text{if~} x \ge +3, \\ x / 6 + 1 / 2 & \text{otherwise} \end{cases} Args: inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. Examples:: >>> m = nn.Hardsigmoid() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['inplace']inplace:booldef__init__(self,inplace:bool=False)->None:super(Hardsigmoid,self).__init__()self.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.hardsigmoid(input,self.inplace)
classTanh(Module):r"""Applies the element-wise function: .. math:: \text{Tanh}(x) = \tanh(x) = \frac{\exp(x) - \exp(-x)} {\exp(x) + \exp(-x)} Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Tanh.png Examples:: >>> m = nn.Tanh() >>> input = torch.randn(2) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:returntorch.tanh(input)classSiLU(Module):r"""Applies the Sigmoid Linear Unit (SiLU) function, element-wise. The SiLU function is also known as the swish function. .. math:: \text{silu}(x) = x * \sigma(x), \text{where } \sigma(x) \text{ is the logistic sigmoid.} .. note:: See `Gaussian Error Linear Units (GELUs) <https://arxiv.org/abs/1606.08415>`_ where the SiLU (Sigmoid Linear Unit) was originally coined, and see `Sigmoid-Weighted Linear Units for Neural Network Function Approximation in Reinforcement Learning <https://arxiv.org/abs/1702.03118>`_ and `Swish: a Self-Gated Activation Function <https://arxiv.org/abs/1710.05941v1>`_ where the SiLU was experimented with later. Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. Examples:: >>> m = nn.SiLU() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['inplace']inplace:booldef__init__(self,inplace:bool=False):super(SiLU,self).__init__()self.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.silu(input,inplace=self.inplace)defextra_repr(self)->str:inplace_str='inplace=True'ifself.inplaceelse''returninplace_strclassMish(Module):r"""Applies the Mish function, element-wise. Mish: A Self Regularized Non-Monotonic Neural Activation Function. .. math:: \text{Mish}(x) = x * \text{Tanh}(\text{Softplus}(x)) .. note:: See `Mish: A Self Regularized Non-Monotonic Neural Activation Function <https://arxiv.org/abs/1908.08681>`_ Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. Examples:: >>> m = nn.Mish() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['inplace']inplace:booldef__init__(self,inplace:bool=False):super(Mish,self).__init__()self.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.mish(input,inplace=self.inplace)defextra_repr(self)->str:inplace_str='inplace=True'ifself.inplaceelse''returninplace_str
[docs]classHardswish(Module):r"""Applies the hardswish function, element-wise, as described in the paper: `Searching for MobileNetV3`_. .. math:: \text{Hardswish}(x) = \begin{cases} 0 & \text{if~} x \le -3, \\ x & \text{if~} x \ge +3, \\ x \cdot (x + 3) /6 & \text{otherwise} \end{cases} Args: inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. Examples:: >>> m = nn.Hardswish() >>> input = torch.randn(2) >>> output = m(input) .. _`Searching for MobileNetV3`: https://arxiv.org/abs/1905.02244 """__constants__=['inplace']inplace:booldef__init__(self,inplace:bool=False)->None:super(Hardswish,self).__init__()self.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.hardswish(input,self.inplace)
[docs]classELU(Module):r"""Applies the element-wise function: .. math:: \text{ELU}(x) = \begin{cases} x, & \text{ if } x > 0\\ \alpha * (\exp(x) - 1), & \text{ if } x \leq 0 \end{cases} Args: alpha: the :math:`\alpha` value for the ELU formulation. Default: 1.0 inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/ELU.png Examples:: >>> m = nn.ELU() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['alpha','inplace']alpha:floatinplace:booldef__init__(self,alpha:float=1.,inplace:bool=False)->None:super(ELU,self).__init__()self.alpha=alphaself.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.elu(input,self.alpha,self.inplace)defextra_repr(self)->str:inplace_str=', inplace=True'ifself.inplaceelse''return'alpha={}{}'.format(self.alpha,inplace_str)
classCELU(Module):r"""Applies the element-wise function: .. math:: \text{CELU}(x) = \max(0,x) + \min(0, \alpha * (\exp(x/\alpha) - 1)) More details can be found in the paper `Continuously Differentiable Exponential Linear Units`_ . Args: alpha: the :math:`\alpha` value for the CELU formulation. Default: 1.0 inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/CELU.png Examples:: >>> m = nn.CELU() >>> input = torch.randn(2) >>> output = m(input) .. _`Continuously Differentiable Exponential Linear Units`: https://arxiv.org/abs/1704.07483 """__constants__=['alpha','inplace']alpha:floatinplace:booldef__init__(self,alpha:float=1.,inplace:bool=False)->None:super(CELU,self).__init__()self.alpha=alphaself.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.celu(input,self.alpha,self.inplace)defextra_repr(self)->str:inplace_str=', inplace=True'ifself.inplaceelse''return'alpha={}{}'.format(self.alpha,inplace_str)classSELU(Module):r"""Applied element-wise, as: .. math:: \text{SELU}(x) = \text{scale} * (\max(0,x) + \min(0, \alpha * (\exp(x) - 1))) with :math:`\alpha = 1.6732632423543772848170429916717` and :math:`\text{scale} = 1.0507009873554804934193349852946`. .. warning:: When using ``kaiming_normal`` or ``kaiming_normal_`` for initialisation, ``nonlinearity='linear'`` should be used instead of ``nonlinearity='selu'`` in order to get `Self-Normalizing Neural Networks`_. See :func:`torch.nn.init.calculate_gain` for more information. More details can be found in the paper `Self-Normalizing Neural Networks`_ . Args: inplace (bool, optional): can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/SELU.png Examples:: >>> m = nn.SELU() >>> input = torch.randn(2) >>> output = m(input) .. _Self-Normalizing Neural Networks: https://arxiv.org/abs/1706.02515 """__constants__=['inplace']inplace:booldef__init__(self,inplace:bool=False)->None:super(SELU,self).__init__()self.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.selu(input,self.inplace)defextra_repr(self)->str:inplace_str='inplace=True'ifself.inplaceelse''returninplace_str
[docs]classGLU(Module):r"""Applies the gated linear unit function :math:`{GLU}(a, b)= a \otimes \sigma(b)` where :math:`a` is the first half of the input matrices and :math:`b` is the second half. Args: dim (int): the dimension on which to split the input. Default: -1 Shape: - Input: :math:`(\ast_1, N, \ast_2)` where `*` means, any number of additional dimensions - Output: :math:`(\ast_1, M, \ast_2)` where :math:`M=N/2` Examples:: >>> m = nn.GLU() >>> input = torch.randn(4, 2) >>> output = m(input) """__constants__=['dim']dim:intdef__init__(self,dim:int=-1)->None:super(GLU,self).__init__()self.dim=dimdefforward(self,input:Tensor)->Tensor:returnF.glu(input,self.dim)defextra_repr(self)->str:return'dim={}'.format(self.dim)
[docs]classGELU(Module):r"""Applies the Gaussian Error Linear Units function: .. math:: \text{GELU}(x) = x * \Phi(x) where :math:`\Phi(x)` is the Cumulative Distribution Function for Gaussian Distribution. Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/GELU.png Examples:: >>> m = nn.GELU() >>> input = torch.randn(2) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:returnF.gelu(input)
[docs]classHardshrink(Module):r"""Applies the hard shrinkage function element-wise: .. math:: \text{HardShrink}(x) = \begin{cases} x, & \text{ if } x > \lambda \\ x, & \text{ if } x < -\lambda \\ 0, & \text{ otherwise } \end{cases} Args: lambd: the :math:`\lambda` value for the Hardshrink formulation. Default: 0.5 Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Hardshrink.png Examples:: >>> m = nn.Hardshrink() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['lambd']lambd:floatdef__init__(self,lambd:float=0.5)->None:super(Hardshrink,self).__init__()self.lambd=lambddefforward(self,input:Tensor)->Tensor:returnF.hardshrink(input,self.lambd)defextra_repr(self)->str:return'{}'.format(self.lambd)
[docs]classLeakyReLU(Module):r"""Applies the element-wise function: .. math:: \text{LeakyReLU}(x) = \max(0, x) + \text{negative\_slope} * \min(0, x) or .. math:: \text{LeakyRELU}(x) = \begin{cases} x, & \text{ if } x \geq 0 \\ \text{negative\_slope} \times x, & \text{ otherwise } \end{cases} Args: negative_slope: Controls the angle of the negative slope. Default: 1e-2 inplace: can optionally do the operation in-place. Default: ``False`` Shape: - Input: :math:`(*)` where `*` means, any number of additional dimensions - Output: :math:`(*)`, same shape as the input .. image:: ../scripts/activation_images/LeakyReLU.png Examples:: >>> m = nn.LeakyReLU(0.1) >>> input = torch.randn(2) >>> output = m(input) """__constants__=['inplace','negative_slope']inplace:boolnegative_slope:floatdef__init__(self,negative_slope:float=1e-2,inplace:bool=False)->None:super(LeakyReLU,self).__init__()self.negative_slope=negative_slopeself.inplace=inplacedefforward(self,input:Tensor)->Tensor:returnF.leaky_relu(input,self.negative_slope,self.inplace)defextra_repr(self)->str:inplace_str=', inplace=True'ifself.inplaceelse''return'negative_slope={}{}'.format(self.negative_slope,inplace_str)
[docs]classLogSigmoid(Module):r"""Applies the element-wise function: .. math:: \text{LogSigmoid}(x) = \log\left(\frac{ 1 }{ 1 + \exp(-x)}\right) Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/LogSigmoid.png Examples:: >>> m = nn.LogSigmoid() >>> input = torch.randn(2) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:returnF.logsigmoid(input)
classSoftplus(Module):r"""Applies the element-wise function: .. math:: \text{Softplus}(x) = \frac{1}{\beta} * \log(1 + \exp(\beta * x)) SoftPlus is a smooth approximation to the ReLU function and can be used to constrain the output of a machine to always be positive. For numerical stability the implementation reverts to the linear function when :math:`input \times \beta > threshold`. Args: beta: the :math:`\beta` value for the Softplus formulation. Default: 1 threshold: values above this revert to a linear function. Default: 20 Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Softplus.png Examples:: >>> m = nn.Softplus() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['beta','threshold']beta:intthreshold:intdef__init__(self,beta:int=1,threshold:int=20)->None:super(Softplus,self).__init__()self.beta=betaself.threshold=thresholddefforward(self,input:Tensor)->Tensor:returnF.softplus(input,self.beta,self.threshold)defextra_repr(self)->str:return'beta={}, threshold={}'.format(self.beta,self.threshold)classSoftshrink(Module):r"""Applies the soft shrinkage function elementwise: .. math:: \text{SoftShrinkage}(x) = \begin{cases} x - \lambda, & \text{ if } x > \lambda \\ x + \lambda, & \text{ if } x < -\lambda \\ 0, & \text{ otherwise } \end{cases} Args: lambd: the :math:`\lambda` (must be no less than zero) value for the Softshrink formulation. Default: 0.5 Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Softshrink.png Examples:: >>> m = nn.Softshrink() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['lambd']lambd:floatdef__init__(self,lambd:float=0.5)->None:super(Softshrink,self).__init__()self.lambd=lambddefforward(self,input:Tensor)->Tensor:returnF.softshrink(input,self.lambd)defextra_repr(self)->str:returnstr(self.lambd)classMultiheadAttention(Module):r"""Allows the model to jointly attend to information from different representation subspaces. See `Attention Is All You Need <https://arxiv.org/abs/1706.03762>`_. .. math:: \text{MultiHead}(Q, K, V) = \text{Concat}(head_1,\dots,head_h)W^O where :math:`head_i = \text{Attention}(QW_i^Q, KW_i^K, VW_i^V)`. Args: embed_dim: Total dimension of the model. num_heads: Number of parallel attention heads. Note that ``embed_dim`` will be split across ``num_heads`` (i.e. each head will have dimension ``embed_dim // num_heads``). dropout: Dropout probability on ``attn_output_weights``. Default: ``0.0`` (no dropout). bias: If specified, adds bias to input / output projection layers. Default: ``True``. add_bias_kv: If specified, adds bias to the key and value sequences at dim=0. Default: ``False``. add_zero_attn: If specified, adds a new batch of zeros to the key and value sequences at dim=1. Default: ``False``. kdim: Total number of features for keys. Default: ``None`` (uses ``kdim=embed_dim``). vdim: Total number of features for values. Default: ``None`` (uses ``vdim=embed_dim``). batch_first: If ``True``, then the input and output tensors are provided as (batch, seq, feature). Default: ``False`` (seq, batch, feature). Examples:: >>> multihead_attn = nn.MultiheadAttention(embed_dim, num_heads) >>> attn_output, attn_output_weights = multihead_attn(query, key, value) """__constants__=['batch_first']bias_k:Optional[torch.Tensor]bias_v:Optional[torch.Tensor]def__init__(self,embed_dim,num_heads,dropout=0.,bias=True,add_bias_kv=False,add_zero_attn=False,kdim=None,vdim=None,batch_first=False,device=None,dtype=None)->None:factory_kwargs={'device':device,'dtype':dtype}super(MultiheadAttention,self).__init__()self.embed_dim=embed_dimself.kdim=kdimifkdimisnotNoneelseembed_dimself.vdim=vdimifvdimisnotNoneelseembed_dimself._qkv_same_embed_dim=self.kdim==embed_dimandself.vdim==embed_dimself.num_heads=num_headsself.dropout=dropoutself.batch_first=batch_firstself.head_dim=embed_dim//num_headsassertself.head_dim*num_heads==self.embed_dim,"embed_dim must be divisible by num_heads"ifself._qkv_same_embed_dimisFalse:self.q_proj_weight=Parameter(torch.empty((embed_dim,embed_dim),**factory_kwargs))self.k_proj_weight=Parameter(torch.empty((embed_dim,self.kdim),**factory_kwargs))self.v_proj_weight=Parameter(torch.empty((embed_dim,self.vdim),**factory_kwargs))self.register_parameter('in_proj_weight',None)else:self.in_proj_weight=Parameter(torch.empty((3*embed_dim,embed_dim),**factory_kwargs))self.register_parameter('q_proj_weight',None)self.register_parameter('k_proj_weight',None)self.register_parameter('v_proj_weight',None)ifbias:self.in_proj_bias=Parameter(torch.empty(3*embed_dim,**factory_kwargs))else:self.register_parameter('in_proj_bias',None)self.out_proj=NonDynamicallyQuantizableLinear(embed_dim,embed_dim,bias=bias,**factory_kwargs)ifadd_bias_kv:self.bias_k=Parameter(torch.empty((1,1,embed_dim),**factory_kwargs))self.bias_v=Parameter(torch.empty((1,1,embed_dim),**factory_kwargs))else:self.bias_k=self.bias_v=Noneself.add_zero_attn=add_zero_attnself._reset_parameters()def_reset_parameters(self):ifself._qkv_same_embed_dim:xavier_uniform_(self.in_proj_weight)else:xavier_uniform_(self.q_proj_weight)xavier_uniform_(self.k_proj_weight)xavier_uniform_(self.v_proj_weight)ifself.in_proj_biasisnotNone:constant_(self.in_proj_bias,0.)constant_(self.out_proj.bias,0.)ifself.bias_kisnotNone:xavier_normal_(self.bias_k)ifself.bias_visnotNone:xavier_normal_(self.bias_v)def__setstate__(self,state):# Support loading old MultiheadAttention checkpoints generated by v1.1.0if'_qkv_same_embed_dim'notinstate:state['_qkv_same_embed_dim']=Truesuper(MultiheadAttention,self).__setstate__(state)defforward(self,query:Tensor,key:Tensor,value:Tensor,key_padding_mask:Optional[Tensor]=None,need_weights:bool=True,attn_mask:Optional[Tensor]=None)->Tuple[Tensor,Optional[Tensor]]:r""" Args: query: Query embeddings of shape :math:`(L, N, E_q)` when ``batch_first=False`` or :math:`(N, L, E_q)` when ``batch_first=True``, where :math:`L` is the target sequence length, :math:`N` is the batch size, and :math:`E_q` is the query embedding dimension ``embed_dim``. Queries are compared against key-value pairs to produce the output. See "Attention Is All You Need" for more details. key: Key embeddings of shape :math:`(S, N, E_k)` when ``batch_first=False`` or :math:`(N, S, E_k)` when ``batch_first=True``, where :math:`S` is the source sequence length, :math:`N` is the batch size, and :math:`E_k` is the key embedding dimension ``kdim``. See "Attention Is All You Need" for more details. value: Value embeddings of shape :math:`(S, N, E_v)` when ``batch_first=False`` or :math:`(N, S, E_v)` when ``batch_first=True``, where :math:`S` is the source sequence length, :math:`N` is the batch size, and :math:`E_v` is the value embedding dimension ``vdim``. See "Attention Is All You Need" for more details. key_padding_mask: If specified, a mask of shape :math:`(N, S)` indicating which elements within ``key`` to ignore for the purpose of attention (i.e. treat as "padding"). Binary and byte masks are supported. For a binary mask, a ``True`` value indicates that the corresponding ``key`` value will be ignored for the purpose of attention. For a byte mask, a non-zero value indicates that the corresponding ``key`` value will be ignored. need_weights: If specified, returns ``attn_output_weights`` in addition to ``attn_outputs``. Default: ``True``. attn_mask: If specified, a 2D or 3D mask preventing attention to certain positions. Must be of shape :math:`(L, S)` or :math:`(N\cdot\text{num\_heads}, L, S)`, where :math:`N` is the batch size, :math:`L` is the target sequence length, and :math:`S` is the source sequence length. A 2D mask will be broadcasted across the batch while a 3D mask allows for a different mask for each entry in the batch. Binary, byte, and float masks are supported. For a binary mask, a ``True`` value indicates that the corresponding position is not allowed to attend. For a byte mask, a non-zero value indicates that the corresponding position is not allowed to attend. For a float mask, the mask values will be added to the attention weight. Outputs: - **attn_output** - Attention outputs of shape :math:`(L, N, E)` when ``batch_first=False`` or :math:`(N, L, E)` when ``batch_first=True``, where :math:`L` is the target sequence length, :math:`N` is the batch size, and :math:`E` is the embedding dimension ``embed_dim``. - **attn_output_weights** - Attention output weights of shape :math:`(N, L, S)`, where :math:`N` is the batch size, :math:`L` is the target sequence length, and :math:`S` is the source sequence length. Only returned when ``need_weights=True``. """ifself.batch_first:query,key,value=[x.transpose(1,0)forxin(query,key,value)]ifnotself._qkv_same_embed_dim:attn_output,attn_output_weights=F.multi_head_attention_forward(query,key,value,self.embed_dim,self.num_heads,self.in_proj_weight,self.in_proj_bias,self.bias_k,self.bias_v,self.add_zero_attn,self.dropout,self.out_proj.weight,self.out_proj.bias,training=self.training,key_padding_mask=key_padding_mask,need_weights=need_weights,attn_mask=attn_mask,use_separate_proj_weight=True,q_proj_weight=self.q_proj_weight,k_proj_weight=self.k_proj_weight,v_proj_weight=self.v_proj_weight)else:attn_output,attn_output_weights=F.multi_head_attention_forward(query,key,value,self.embed_dim,self.num_heads,self.in_proj_weight,self.in_proj_bias,self.bias_k,self.bias_v,self.add_zero_attn,self.dropout,self.out_proj.weight,self.out_proj.bias,training=self.training,key_padding_mask=key_padding_mask,need_weights=need_weights,attn_mask=attn_mask)ifself.batch_first:returnattn_output.transpose(1,0),attn_output_weightselse:returnattn_output,attn_output_weightsclassPReLU(Module):r"""Applies the element-wise function: .. math:: \text{PReLU}(x) = \max(0,x) + a * \min(0,x) or .. math:: \text{PReLU}(x) = \begin{cases} x, & \text{ if } x \geq 0 \\ ax, & \text{ otherwise } \end{cases} Here :math:`a` is a learnable parameter. When called without arguments, `nn.PReLU()` uses a single parameter :math:`a` across all input channels. If called with `nn.PReLU(nChannels)`, a separate :math:`a` is used for each input channel. .. note:: weight decay should not be used when learning :math:`a` for good performance. .. note:: Channel dim is the 2nd dim of input. When input has dims < 2, then there is no channel dim and the number of channels = 1. Args: num_parameters (int): number of :math:`a` to learn. Although it takes an int as input, there is only two values are legitimate: 1, or the number of channels at input. Default: 1 init (float): the initial value of :math:`a`. Default: 0.25 Shape: - Input: :math:`( *)` where `*` means, any number of additional dimensions. - Output: :math:`(*)`, same shape as the input. Attributes: weight (Tensor): the learnable weights of shape (:attr:`num_parameters`). .. image:: ../scripts/activation_images/PReLU.png Examples:: >>> m = nn.PReLU() >>> input = torch.randn(2) >>> output = m(input) """__constants__=['num_parameters']num_parameters:intdef__init__(self,num_parameters:int=1,init:float=0.25,device=None,dtype=None)->None:factory_kwargs={'device':device,'dtype':dtype}self.num_parameters=num_parameterssuper(PReLU,self).__init__()self.weight=Parameter(torch.empty(num_parameters,**factory_kwargs).fill_(init))defforward(self,input:Tensor)->Tensor:returnF.prelu(input,self.weight)defextra_repr(self)->str:return'num_parameters={}'.format(self.num_parameters)classSoftsign(Module):r"""Applies the element-wise function: .. math:: \text{SoftSign}(x) = \frac{x}{ 1 + |x|} Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Softsign.png Examples:: >>> m = nn.Softsign() >>> input = torch.randn(2) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:returnF.softsign(input)classTanhshrink(Module):r"""Applies the element-wise function: .. math:: \text{Tanhshrink}(x) = x - \tanh(x) Shape: - Input: :math:`(*)`, where :math:`*` means any number of dimensions. - Output: :math:`(*)`, same shape as the input. .. image:: ../scripts/activation_images/Tanhshrink.png Examples:: >>> m = nn.Tanhshrink() >>> input = torch.randn(2) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:returnF.tanhshrink(input)classSoftmin(Module):r"""Applies the Softmin function to an n-dimensional input Tensor rescaling them so that the elements of the n-dimensional output Tensor lie in the range `[0, 1]` and sum to 1. Softmin is defined as: .. math:: \text{Softmin}(x_{i}) = \frac{\exp(-x_i)}{\sum_j \exp(-x_j)} Shape: - Input: :math:`(*)` where `*` means, any number of additional dimensions - Output: :math:`(*)`, same shape as the input Args: dim (int): A dimension along which Softmin will be computed (so every slice along dim will sum to 1). Returns: a Tensor of the same dimension and shape as the input, with values in the range [0, 1] Examples:: >>> m = nn.Softmin() >>> input = torch.randn(2, 3) >>> output = m(input) """__constants__=['dim']dim:Optional[int]def__init__(self,dim:Optional[int]=None)->None:super(Softmin,self).__init__()self.dim=dimdef__setstate__(self,state):self.__dict__.update(state)ifnothasattr(self,'dim'):self.dim=Nonedefforward(self,input:Tensor)->Tensor:returnF.softmin(input,self.dim,_stacklevel=5)defextra_repr(self):return'dim={dim}'.format(dim=self.dim)classSoftmax(Module):r"""Applies the Softmax function to an n-dimensional input Tensor rescaling them so that the elements of the n-dimensional output Tensor lie in the range [0,1] and sum to 1. Softmax is defined as: .. math:: \text{Softmax}(x_{i}) = \frac{\exp(x_i)}{\sum_j \exp(x_j)} When the input Tensor is a sparse tensor then the unspecifed values are treated as ``-inf``. Shape: - Input: :math:`(*)` where `*` means, any number of additional dimensions - Output: :math:`(*)`, same shape as the input Returns: a Tensor of the same dimension and shape as the input with values in the range [0, 1] Args: dim (int): A dimension along which Softmax will be computed (so every slice along dim will sum to 1). .. note:: This module doesn't work directly with NLLLoss, which expects the Log to be computed between the Softmax and itself. Use `LogSoftmax` instead (it's faster and has better numerical properties). Examples:: >>> m = nn.Softmax(dim=1) >>> input = torch.randn(2, 3) >>> output = m(input) """__constants__=['dim']dim:Optional[int]def__init__(self,dim:Optional[int]=None)->None:super(Softmax,self).__init__()self.dim=dimdef__setstate__(self,state):self.__dict__.update(state)ifnothasattr(self,'dim'):self.dim=Nonedefforward(self,input:Tensor)->Tensor:returnF.softmax(input,self.dim,_stacklevel=5)defextra_repr(self)->str:return'dim={dim}'.format(dim=self.dim)classSoftmax2d(Module):r"""Applies SoftMax over features to each spatial location. When given an image of ``Channels x Height x Width``, it will apply `Softmax` to each location :math:`(Channels, h_i, w_j)` Shape: - Input: :math:`(N, C, H, W)` or :math:`(C, H, W)`. - Output: :math:`(N, C, H, W)` or :math:`(C, H, W)` (same shape as input) Returns: a Tensor of the same dimension and shape as the input with values in the range [0, 1] Examples:: >>> m = nn.Softmax2d() >>> # you softmax over the 2nd dimension >>> input = torch.randn(2, 3, 12, 13) >>> output = m(input) """defforward(self,input:Tensor)->Tensor:assertinput.dim()==4orinput.dim()==3,'Softmax2d requires a 3D or 4D tensor as input'returnF.softmax(input,-3,_stacklevel=5)
[docs]classLogSoftmax(Module):r"""Applies the :math:`\log(\text{Softmax}(x))` function to an n-dimensional input Tensor. The LogSoftmax formulation can be simplified as: .. math:: \text{LogSoftmax}(x_{i}) = \log\left(\frac{\exp(x_i) }{ \sum_j \exp(x_j)} \right) Shape: - Input: :math:`(*)` where `*` means, any number of additional dimensions - Output: :math:`(*)`, same shape as the input Args: dim (int): A dimension along which LogSoftmax will be computed. Returns: a Tensor of the same dimension and shape as the input with values in the range [-inf, 0) Examples:: >>> m = nn.LogSoftmax() >>> input = torch.randn(2, 3) >>> output = m(input) """__constants__=['dim']dim:Optional[int]def__init__(self,dim:Optional[int]=None)->None:super(LogSoftmax,self).__init__()self.dim=dimdef__setstate__(self,state):self.__dict__.update(state)ifnothasattr(self,'dim'):self.dim=Nonedefforward(self,input:Tensor)->Tensor:returnF.log_softmax(input,self.dim,_stacklevel=5)defextra_repr(self):return'dim={dim}'.format(dim=self.dim)
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