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so-vits-svc / vencoder /dphubert /hardconcrete.py

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	"""Implementation of the hard Concrete distribution.

	Originally from:
	https://github.com/asappresearch/flop/blob/master/flop/hardconcrete.py

	"""

	import math

	import torch
	import torch.nn as nn


	class HardConcrete(nn.Module):
	"""A HarcConcrete module.
	Use this module to create a mask of size N, which you can
	then use to perform L0 regularization.

	To obtain a mask, simply run a forward pass through the module
	with no input data. The mask is sampled in training mode, and
	fixed during evaluation mode, e.g.:

	>>> module = HardConcrete(n_in=100)
	>>> mask = module()
	>>> norm = module.l0_norm()
	"""

	def __init__(
	self,
	n_in: int,
	init_mean: float = 0.5,
	init_std: float = 0.01,
	temperature: float = 2/3, # from CoFi
	stretch: float = 0.1,
	eps: float = 1e-6
	) -> None:
	"""Initialize the HardConcrete module.
	Parameters
	----------
	n_in : int
	The number of hard concrete variables in this mask.
	init_mean : float, optional
	Initial drop rate for hard concrete parameter,
	by default 0.5.,
	init_std: float, optional
	Used to initialize the hard concrete parameters,
	by default 0.01.
	temperature : float, optional
	Temperature used to control the sharpness of the
	distribution, by default 1.0
	stretch : float, optional
	Stretch the sampled value from [0, 1] to the interval
	[-stretch, 1 + stretch], by default 0.1.
	"""
	super().__init__()

	self.n_in = n_in
	self.limit_l = -stretch
	self.limit_r = 1.0 + stretch
	self.log_alpha = nn.Parameter(torch.zeros(n_in))
	self.beta = temperature
	self.init_mean = init_mean
	self.init_std = init_std
	self.bias = -self.beta * math.log(-self.limit_l / self.limit_r)

	self.eps = eps
	self.compiled_mask = None
	self.reset_parameters()

	def reset_parameters(self):
	"""Reset the parameters of this module."""
	self.compiled_mask = None
	mean = math.log(1 - self.init_mean) - math.log(self.init_mean)
	self.log_alpha.data.normal_(mean, self.init_std)

	def l0_norm(self) -> torch.Tensor:
	"""Compute the expected L0 norm of this mask.
	Returns
	-------
	torch.Tensor
	The expected L0 norm.
	"""
	return (self.log_alpha + self.bias).sigmoid().sum()

	def forward(self) -> torch.Tensor:
	"""Sample a hard concrete mask.
	Returns
	-------
	torch.Tensor
	The sampled binary mask
	"""
	if self.training:
	# Reset the compiled mask
	self.compiled_mask = None
	# Sample mask dynamically
	u = self.log_alpha.new(self.n_in).uniform_(self.eps, 1 - self.eps)
	s = torch.sigmoid((torch.log(u / (1 - u)) + self.log_alpha) / self.beta)
	s = s * (self.limit_r - self.limit_l) + self.limit_l
	mask = s.clamp(min=0., max=1.)

	else:
	# Compile new mask if not cached
	if self.compiled_mask is None:
	# Get expected sparsity
	expected_num_zeros = self.n_in - self.l0_norm().item()
	num_zeros = round(expected_num_zeros)
	# Approximate expected value of each mask variable z;
	# We use an empirically validated magic number 0.8
	soft_mask = torch.sigmoid(self.log_alpha / self.beta * 0.8)
	# Prune small values to set to 0
	_, indices = torch.topk(soft_mask, k=num_zeros, largest=False)
	soft_mask[indices] = 0.
	self.compiled_mask = soft_mask
	mask = self.compiled_mask

	return mask

	def extra_repr(self) -> str:
	return str(self.n_in)

	def __repr__(self) -> str:
	return "{}({})".format(self.__class__.__name__, self.extra_repr())