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from torch import nn | |
import torch | |
import torch.nn.functional as F | |
from modules.util import AntiAliasInterpolation2d, make_coordinate_grid | |
from torchvision import models | |
import numpy as np | |
from torch.autograd import grad | |
class Vgg19(torch.nn.Module): | |
""" | |
Vgg19 network for perceptual loss. See Sec 3.3. | |
""" | |
def __init__(self, requires_grad=False): | |
super(Vgg19, self).__init__() | |
vgg_pretrained_features = models.vgg19(pretrained=True).features | |
self.slice1 = torch.nn.Sequential() | |
self.slice2 = torch.nn.Sequential() | |
self.slice3 = torch.nn.Sequential() | |
self.slice4 = torch.nn.Sequential() | |
self.slice5 = torch.nn.Sequential() | |
for x in range(2): | |
self.slice1.add_module(str(x), vgg_pretrained_features[x]) | |
for x in range(2, 7): | |
self.slice2.add_module(str(x), vgg_pretrained_features[x]) | |
for x in range(7, 12): | |
self.slice3.add_module(str(x), vgg_pretrained_features[x]) | |
for x in range(12, 21): | |
self.slice4.add_module(str(x), vgg_pretrained_features[x]) | |
for x in range(21, 30): | |
self.slice5.add_module(str(x), vgg_pretrained_features[x]) | |
self.mean = torch.nn.Parameter(data=torch.Tensor(np.array([0.485, 0.456, 0.406]).reshape((1, 3, 1, 1))), | |
requires_grad=False) | |
self.std = torch.nn.Parameter(data=torch.Tensor(np.array([0.229, 0.224, 0.225]).reshape((1, 3, 1, 1))), | |
requires_grad=False) | |
if not requires_grad: | |
for param in self.parameters(): | |
param.requires_grad = False | |
def forward(self, X): | |
X = (X - self.mean) / self.std | |
h_relu1 = self.slice1(X) | |
h_relu2 = self.slice2(h_relu1) | |
h_relu3 = self.slice3(h_relu2) | |
h_relu4 = self.slice4(h_relu3) | |
h_relu5 = self.slice5(h_relu4) | |
out = [h_relu1, h_relu2, h_relu3, h_relu4, h_relu5] | |
return out | |
class ImagePyramide(torch.nn.Module): | |
""" | |
Create image pyramide for computing pyramide perceptual loss. See Sec 3.3 | |
""" | |
def __init__(self, scales, num_channels): | |
super(ImagePyramide, self).__init__() | |
downs = {} | |
for scale in scales: | |
downs[str(scale).replace('.', '-')] = AntiAliasInterpolation2d(num_channels, scale) | |
self.downs = nn.ModuleDict(downs) | |
def forward(self, x): | |
out_dict = {} | |
for scale, down_module in self.downs.items(): | |
out_dict['prediction_' + str(scale).replace('-', '.')] = down_module(x) | |
return out_dict | |
class Transform: | |
""" | |
Random tps transformation for equivariance constraints. See Sec 3.3 | |
""" | |
def __init__(self, bs, **kwargs): | |
noise = torch.normal(mean=0, std=kwargs['sigma_affine'] * torch.ones([bs, 2, 3])) | |
self.theta = noise + torch.eye(2, 3).view(1, 2, 3) | |
self.bs = bs | |
if ('sigma_tps' in kwargs) and ('points_tps' in kwargs): | |
self.tps = True | |
self.control_points = make_coordinate_grid((kwargs['points_tps'], kwargs['points_tps']), type=noise.type()) | |
self.control_points = self.control_points.unsqueeze(0) | |
self.control_params = torch.normal(mean=0, | |
std=kwargs['sigma_tps'] * torch.ones([bs, 1, kwargs['points_tps'] ** 2])) | |
else: | |
self.tps = False | |
def transform_frame(self, frame): | |
grid = make_coordinate_grid(frame.shape[2:], type=frame.type()).unsqueeze(0) | |
grid = grid.view(1, frame.shape[2] * frame.shape[3], 2) | |
grid = self.warp_coordinates(grid).view(self.bs, frame.shape[2], frame.shape[3], 2) | |
return F.grid_sample(frame, grid, padding_mode="reflection") | |
def warp_coordinates(self, coordinates): | |
theta = self.theta.type(coordinates.type()) | |
theta = theta.unsqueeze(1) | |
transformed = torch.matmul(theta[:, :, :, :2], coordinates.unsqueeze(-1)) + theta[:, :, :, 2:] | |
transformed = transformed.squeeze(-1) | |
if self.tps: | |
control_points = self.control_points.type(coordinates.type()) | |
control_params = self.control_params.type(coordinates.type()) | |
distances = coordinates.view(coordinates.shape[0], -1, 1, 2) - control_points.view(1, 1, -1, 2) | |
distances = torch.abs(distances).sum(-1) | |
result = distances ** 2 | |
result = result * torch.log(distances + 1e-6) | |
result = result * control_params | |
result = result.sum(dim=2).view(self.bs, coordinates.shape[1], 1) | |
transformed = transformed + result | |
return transformed | |
def jacobian(self, coordinates): | |
new_coordinates = self.warp_coordinates(coordinates) | |
grad_x = grad(new_coordinates[..., 0].sum(), coordinates, create_graph=True) | |
grad_y = grad(new_coordinates[..., 1].sum(), coordinates, create_graph=True) | |
jacobian = torch.cat([grad_x[0].unsqueeze(-2), grad_y[0].unsqueeze(-2)], dim=-2) | |
return jacobian | |
def detach_kp(kp): | |
return {key: value.detach() for key, value in kp.items()} | |
class GeneratorFullModel(torch.nn.Module): | |
""" | |
Merge all generator related updates into single model for better multi-gpu usage | |
""" | |
def __init__(self, kp_extractor, generator, discriminator, train_params): | |
super(GeneratorFullModel, self).__init__() | |
self.kp_extractor = kp_extractor | |
self.generator = generator | |
self.discriminator = discriminator | |
self.train_params = train_params | |
self.scales = train_params['scales'] | |
self.disc_scales = self.discriminator.scales | |
self.pyramid = ImagePyramide(self.scales, generator.num_channels) | |
if torch.cuda.is_available(): | |
self.pyramid = self.pyramid.cuda() | |
self.loss_weights = train_params['loss_weights'] | |
if sum(self.loss_weights['perceptual']) != 0: | |
self.vgg = Vgg19() | |
if torch.cuda.is_available(): | |
self.vgg = self.vgg.cuda() | |
def forward(self, x): | |
kp_source = self.kp_extractor(x['source']) | |
kp_driving = self.kp_extractor(x['driving']) | |
generated = self.generator(x['source'], kp_source=kp_source, kp_driving=kp_driving) | |
generated.update({'kp_source': kp_source, 'kp_driving': kp_driving}) | |
loss_values = {} | |
pyramide_real = self.pyramid(x['driving']) | |
pyramide_generated = self.pyramid(generated['prediction']) | |
if sum(self.loss_weights['perceptual']) != 0: | |
value_total = 0 | |
for scale in self.scales: | |
x_vgg = self.vgg(pyramide_generated['prediction_' + str(scale)]) | |
y_vgg = self.vgg(pyramide_real['prediction_' + str(scale)]) | |
for i, weight in enumerate(self.loss_weights['perceptual']): | |
value = torch.abs(x_vgg[i] - y_vgg[i].detach()).mean() | |
value_total += self.loss_weights['perceptual'][i] * value | |
loss_values['perceptual'] = value_total | |
if self.loss_weights['generator_gan'] != 0: | |
discriminator_maps_generated = self.discriminator(pyramide_generated, kp=detach_kp(kp_driving)) | |
discriminator_maps_real = self.discriminator(pyramide_real, kp=detach_kp(kp_driving)) | |
value_total = 0 | |
for scale in self.disc_scales: | |
key = 'prediction_map_%s' % scale | |
value = ((1 - discriminator_maps_generated[key]) ** 2).mean() | |
value_total += self.loss_weights['generator_gan'] * value | |
loss_values['gen_gan'] = value_total | |
if sum(self.loss_weights['feature_matching']) != 0: | |
value_total = 0 | |
for scale in self.disc_scales: | |
key = 'feature_maps_%s' % scale | |
for i, (a, b) in enumerate(zip(discriminator_maps_real[key], discriminator_maps_generated[key])): | |
if self.loss_weights['feature_matching'][i] == 0: | |
continue | |
value = torch.abs(a - b).mean() | |
value_total += self.loss_weights['feature_matching'][i] * value | |
loss_values['feature_matching'] = value_total | |
if (self.loss_weights['equivariance_value'] + self.loss_weights['equivariance_jacobian']) != 0: | |
transform = Transform(x['driving'].shape[0], **self.train_params['transform_params']) | |
transformed_frame = transform.transform_frame(x['driving']) | |
transformed_kp = self.kp_extractor(transformed_frame) | |
generated['transformed_frame'] = transformed_frame | |
generated['transformed_kp'] = transformed_kp | |
## Value loss part | |
if self.loss_weights['equivariance_value'] != 0: | |
value = torch.abs(kp_driving['value'] - transform.warp_coordinates(transformed_kp['value'])).mean() | |
loss_values['equivariance_value'] = self.loss_weights['equivariance_value'] * value | |
## jacobian loss part | |
if self.loss_weights['equivariance_jacobian'] != 0: | |
jacobian_transformed = torch.matmul(transform.jacobian(transformed_kp['value']), | |
transformed_kp['jacobian']) | |
normed_driving = torch.inverse(kp_driving['jacobian']) | |
normed_transformed = jacobian_transformed | |
value = torch.matmul(normed_driving, normed_transformed) | |
eye = torch.eye(2).view(1, 1, 2, 2).type(value.type()) | |
value = torch.abs(eye - value).mean() | |
loss_values['equivariance_jacobian'] = self.loss_weights['equivariance_jacobian'] * value | |
return loss_values, generated | |
class DiscriminatorFullModel(torch.nn.Module): | |
""" | |
Merge all discriminator related updates into single model for better multi-gpu usage | |
""" | |
def __init__(self, kp_extractor, generator, discriminator, train_params): | |
super(DiscriminatorFullModel, self).__init__() | |
self.kp_extractor = kp_extractor | |
self.generator = generator | |
self.discriminator = discriminator | |
self.train_params = train_params | |
self.scales = self.discriminator.scales | |
self.pyramid = ImagePyramide(self.scales, generator.num_channels) | |
if torch.cuda.is_available(): | |
self.pyramid = self.pyramid.cuda() | |
self.loss_weights = train_params['loss_weights'] | |
def forward(self, x, generated): | |
pyramide_real = self.pyramid(x['driving']) | |
pyramide_generated = self.pyramid(generated['prediction'].detach()) | |
kp_driving = generated['kp_driving'] | |
discriminator_maps_generated = self.discriminator(pyramide_generated, kp=detach_kp(kp_driving)) | |
discriminator_maps_real = self.discriminator(pyramide_real, kp=detach_kp(kp_driving)) | |
loss_values = {} | |
value_total = 0 | |
for scale in self.scales: | |
key = 'prediction_map_%s' % scale | |
value = (1 - discriminator_maps_real[key]) ** 2 + discriminator_maps_generated[key] ** 2 | |
value_total += self.loss_weights['discriminator_gan'] * value.mean() | |
loss_values['disc_gan'] = value_total | |
return loss_values | |