Japanese-Ero-Voice-Classifier

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Japanese-Ero-Voice-Classifier / losses.py

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	import torch
	import torch.nn as nn


	class AsymmetricLoss(nn.Module):
	def __init__(
	self,
	gamma_neg=4,
	gamma_pos=1,
	clip=0.05,
	eps=1e-8,
	disable_torch_grad_focal_loss=True,
	):
	super(AsymmetricLoss, self).__init__()

	self.gamma_neg = gamma_neg
	self.gamma_pos = gamma_pos
	self.clip = clip
	self.disable_torch_grad_focal_loss = disable_torch_grad_focal_loss
	self.eps = eps

	def forward(self, x, y):
	""" "
	Parameters
	----------
	x: input logits
	y: targets (multi-label binarized vector)
	"""

	# Calculating Probabilities
	x_sigmoid = torch.sigmoid(x)
	xs_pos = x_sigmoid
	xs_neg = 1 - x_sigmoid

	# Asymmetric Clipping
	if self.clip is not None and self.clip > 0:
	xs_neg = (xs_neg + self.clip).clamp(max=1)

	# Basic CE calculation
	los_pos = y * torch.log(xs_pos.clamp(min=self.eps))
	los_neg = (1 - y) * torch.log(xs_neg.clamp(min=self.eps))
	loss = los_pos + los_neg

	# Asymmetric Focusing
	if self.gamma_neg > 0 or self.gamma_pos > 0:
	if self.disable_torch_grad_focal_loss:
	torch.set_grad_enabled(False)
	pt0 = xs_pos * y
	pt1 = xs_neg * (1 - y) # pt = p if t > 0 else 1-p
	pt = pt0 + pt1
	one_sided_gamma = self.gamma_pos * y + self.gamma_neg * (1 - y)
	one_sided_w = torch.pow(1 - pt, one_sided_gamma)
	if self.disable_torch_grad_focal_loss:
	torch.set_grad_enabled(True)
	loss *= one_sided_w

	return -loss.sum()


	class AsymmetricLossOptimized(nn.Module):
	"""Notice - optimized version, minimizes memory allocation and gpu uploading,
	favors inplace operations"""

	def __init__(
	self,
	gamma_neg=4,
	gamma_pos=1,
	clip=0.05,
	eps=1e-8,
	disable_torch_grad_focal_loss=False,
	):
	super(AsymmetricLossOptimized, self).__init__()

	self.gamma_neg = gamma_neg
	self.gamma_pos = gamma_pos
	self.clip = clip
	self.disable_torch_grad_focal_loss = disable_torch_grad_focal_loss
	self.eps = eps

	# prevent memory allocation and gpu uploading every iteration, and encourages inplace operations
	self.targets = self.anti_targets = self.xs_pos = self.xs_neg = (
	self.asymmetric_w
	) = self.loss = None

	def forward(self, x, y):
	""" "
	Parameters
	----------
	x: input logits
	y: targets (multi-label binarized vector)
	"""

	self.targets = y
	self.anti_targets = 1 - y

	# Calculating Probabilities
	self.xs_pos = torch.sigmoid(x)
	self.xs_neg = 1.0 - self.xs_pos

	# Asymmetric Clipping
	if self.clip is not None and self.clip > 0:
	self.xs_neg.add_(self.clip).clamp_(max=1)

	# Basic CE calculation
	self.loss = self.targets * torch.log(self.xs_pos.clamp(min=self.eps))
	self.loss.add_(self.anti_targets * torch.log(self.xs_neg.clamp(min=self.eps)))

	# Asymmetric Focusing
	if self.gamma_neg > 0 or self.gamma_pos > 0:
	if self.disable_torch_grad_focal_loss:
	torch.set_grad_enabled(False)
	self.xs_pos = self.xs_pos * self.targets
	self.xs_neg = self.xs_neg * self.anti_targets
	self.asymmetric_w = torch.pow(
	1 - self.xs_pos - self.xs_neg,
	self.gamma_pos * self.targets + self.gamma_neg * self.anti_targets,
	)
	if self.disable_torch_grad_focal_loss:
	torch.set_grad_enabled(True)
	self.loss *= self.asymmetric_w

	return -self.loss.sum()


	class ASLSingleLabel(nn.Module):
	"""
	This loss is intended for single-label classification problems
	"""

	def __init__(self, gamma_pos=0, gamma_neg=4, eps: float = 0.1, reduction="mean"):
	super(ASLSingleLabel, self).__init__()

	self.eps = eps
	self.logsoftmax = nn.LogSoftmax(dim=-1)
	self.targets_classes = []
	self.gamma_pos = gamma_pos
	self.gamma_neg = gamma_neg
	self.reduction = reduction

	def forward(self, inputs, target):
	"""
	"input" dimensions: - (batch_size,number_classes)
	"target" dimensions: - (batch_size)
	"""
	num_classes = inputs.size()[-1]
	log_preds = self.logsoftmax(inputs)
	self.targets_classes = torch.zeros_like(inputs).scatter_(
	1, target.long().unsqueeze(1), 1
	)

	# ASL weights
	targets = self.targets_classes
	anti_targets = 1 - targets
	xs_pos = torch.exp(log_preds)
	xs_neg = 1 - xs_pos
	xs_pos = xs_pos * targets
	xs_neg = xs_neg * anti_targets
	asymmetric_w = torch.pow(
	1 - xs_pos - xs_neg,
	self.gamma_pos * targets + self.gamma_neg * anti_targets,
	)
	log_preds = log_preds * asymmetric_w

	if self.eps > 0: # label smoothing
	self.targets_classes = self.targets_classes.mul(1 - self.eps).add(
	self.eps / num_classes
	)

	# loss calculation
	loss = -self.targets_classes.mul(log_preds)

	loss = loss.sum(dim=-1)
	if self.reduction == "mean":
	loss = loss.mean()

	return loss