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import matplotlib
matplotlib.use('Agg')
import torch
from torch import nn
from e4e.models.encoders import psp_encoders
from e4e.models.stylegan2.model import Generator
from e4e.configs.paths_config import model_paths
def get_keys(d, name):
if 'state_dict' in d:
d = d['state_dict']
d_filt = {k[len(name) + 1:]: v for k, v in d.items() if k[:len(name)] == name}
return d_filt
class pSp(nn.Module):
def __init__(self, opts, device):
super(pSp, self).__init__()
self.opts = opts
self.device = device
# Define architecture
self.encoder = self.set_encoder()
self.decoder = Generator(opts.stylegan_size, 512, 8, channel_multiplier=2)
self.face_pool = torch.nn.AdaptiveAvgPool2d((256, 256))
# Load weights if needed
self.load_weights()
def set_encoder(self):
if self.opts.encoder_type == 'GradualStyleEncoder':
encoder = psp_encoders.GradualStyleEncoder(50, 'ir_se', self.opts)
elif self.opts.encoder_type == 'Encoder4Editing':
encoder = psp_encoders.Encoder4Editing(50, 'ir_se', self.opts)
else:
raise Exception('{} is not a valid encoders'.format(self.opts.encoder_type))
return encoder
def load_weights(self):
if self.opts.checkpoint_path is not None:
print('Loading e4e over the pSp framework from checkpoint: {}'.format(self.opts.checkpoint_path))
ckpt = torch.load(self.opts.checkpoint_path, map_location='cpu')
self.encoder.load_state_dict(get_keys(ckpt, 'encoder'), strict=True)
self.decoder.load_state_dict(get_keys(ckpt, 'decoder'), strict=True)
self.__load_latent_avg(ckpt)
else:
print('Loading encoders weights from irse50!')
encoder_ckpt = torch.load(model_paths['ir_se50'])
self.encoder.load_state_dict(encoder_ckpt, strict=False)
print('Loading decoder weights from pretrained!')
ckpt = torch.load(self.opts.stylegan_weights)
self.decoder.load_state_dict(ckpt['g_ema'], strict=False)
self.__load_latent_avg(ckpt, repeat=self.encoder.style_count)
def forward(self, x, resize=True, latent_mask=None, input_code=False, randomize_noise=True,
inject_latent=None, return_latents=False, alpha=None):
if input_code:
codes = x
else:
codes = self.encoder(x)
# normalize with respect to the center of an average face
if self.opts.start_from_latent_avg:
if codes.ndim == 2:
codes = codes + self.latent_avg.repeat(codes.shape[0], 1, 1)[:, 0, :]
else:
codes = codes + self.latent_avg.repeat(codes.shape[0], 1, 1)
if latent_mask is not None:
for i in latent_mask:
if inject_latent is not None:
if alpha is not None:
codes[:, i] = alpha * inject_latent[:, i] + (1 - alpha) * codes[:, i]
else:
codes[:, i] = inject_latent[:, i]
else:
codes[:, i] = 0
input_is_latent = not input_code
images, result_latent = self.decoder([codes],
input_is_latent=input_is_latent,
randomize_noise=randomize_noise,
return_latents=return_latents)
if resize:
images = self.face_pool(images)
if return_latents:
return images, result_latent
else:
return images
def __load_latent_avg(self, ckpt, repeat=None):
if 'latent_avg' in ckpt:
self.latent_avg = ckpt['latent_avg'].to(self.device)
if repeat is not None:
self.latent_avg = self.latent_avg.repeat(repeat, 1)
else:
self.latent_avg = None