import torch import torch.nn as nn class CharbonnierLoss(nn.Module): """Charbonnier Loss (L1)""" def __init__(self, eps=1e-6): super(CharbonnierLoss, self).__init__() self.eps = eps def forward(self, x, y): diff = x - y loss = torch.sum(torch.sqrt(diff * diff + self.eps)) return loss # Define GAN loss: [vanilla | lsgan | wgan-gp] class GANLoss(nn.Module): def __init__(self, gan_type, real_label_val=1.0, fake_label_val=0.0): super(GANLoss, self).__init__() self.gan_type = gan_type.lower() self.real_label_val = real_label_val self.fake_label_val = fake_label_val if self.gan_type == 'gan' or self.gan_type == 'ragan' or self.gan_type == 'pixgan' or self.gan_type == "pixgan_fea": self.loss = nn.BCEWithLogitsLoss() elif self.gan_type == 'lsgan': self.loss = nn.MSELoss() elif self.gan_type == 'wgan-gp': def wgan_loss(input, target): # target is boolean return -1 * input.mean() if target else input.mean() self.loss = wgan_loss else: raise NotImplementedError('GAN type [{:s}] is not found'.format(self.gan_type)) def get_target_label(self, input, target_is_real): if self.gan_type == 'wgan-gp': return target_is_real if target_is_real: return torch.empty_like(input).fill_(self.real_label_val) else: return torch.empty_like(input).fill_(self.fake_label_val) def forward(self, input, target_is_real): if 'pixgan' in self.gan_type and not isinstance(target_is_real, bool): target_label = target_is_real else: target_label = self.get_target_label(input, target_is_real) loss = self.loss(input, target_label) return loss class GradientPenaltyLoss(nn.Module): def __init__(self, device=torch.device('cpu')): super(GradientPenaltyLoss, self).__init__() self.register_buffer('grad_outputs', torch.Tensor()) self.grad_outputs = self.grad_outputs.to(device) def get_grad_outputs(self, input): if self.grad_outputs.size() != input.size(): self.grad_outputs.resize_(input.size()).fill_(1.0) return self.grad_outputs def forward(self, interp, interp_crit): grad_outputs = self.get_grad_outputs(interp_crit) grad_interp = torch.autograd.grad(outputs=interp_crit, inputs=interp, grad_outputs=grad_outputs, create_graph=True, retain_graph=True, only_inputs=True)[0] grad_interp = grad_interp.view(grad_interp.size(0), -1) grad_interp_norm = grad_interp.norm(2, dim=1) loss = ((grad_interp_norm - 1)**2).mean() return loss