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run_inversion.py
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run_inversion.py
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"""Project given image to the latent space of pretrained network pickle."""
import copy
import os
from time import perf_counter
import dill
import click
import imageio
import numpy as np
import PIL.Image
import torch
import torch.nn.functional as F
from tqdm import trange
import dnnlib
import legacy
from metrics import metric_utils
import timm
from training.diffaug import DiffAugment
from pg_modules.blocks import Interpolate
def get_morphed_w_code(new_w_code, fixed_w, regularizer_alpha=30):
interpolation_direction = new_w_code - fixed_w
interpolation_direction_norm = torch.norm(interpolation_direction, p=2)
direction_to_move = regularizer_alpha * interpolation_direction / interpolation_direction_norm
result_w = fixed_w + direction_to_move
return result_w
def space_regularizer_loss(
G_pti,
G_original,
w_batch,
vgg16,
num_of_sampled_latents=1,
lpips_lambda=10,
):
z_samples = np.random.randn(num_of_sampled_latents, G_original.z_dim)
z_samples = torch.from_numpy(z_samples).to(w_batch.device)
if not G_original.c_dim:
c_samples = None
else:
c_samples = F.one_hot(torch.randint(G_original.c_dim, (num_of_sampled_latents,)), G_original.c_dim)
c_samples = c_samples.to(w_batch.device)
w_samples = G_original.mapping(z_samples, c_samples, truncation_psi=0.5)
territory_indicator_ws = [get_morphed_w_code(w_code.unsqueeze(0), w_batch) for w_code in w_samples]
for w_code in territory_indicator_ws:
new_img = G_pti.synthesis(w_code, noise_mode='none', force_fp32=True)
with torch.no_grad():
old_img = G_original.synthesis(w_code, noise_mode='none', force_fp32=True)
# Downsample image to 256x256 if it's larger than that. VGG was built for 224x224 images.
if new_img.shape[-1] > 256:
new_img = F.interpolate(new_img, size=(256, 256), mode='area')
old_img = F.interpolate(old_img, size=(256, 256), mode='area')
new_feat = vgg16(new_img, resize_images=False, return_lpips=True)
old_feat = vgg16(old_img, resize_images=False, return_lpips=True)
lpips_loss = lpips_lambda * (old_feat - new_feat).square().sum()
return lpips_loss / len(territory_indicator_ws)
def pivotal_tuning(
G,
w_pivot,
target,
device: torch.device,
num_steps=350,
learning_rate = 3e-4,
noise_mode="const",
verbose = False,
):
G_original = copy.deepcopy(G).eval().requires_grad_(False).to(device)
G_pti = copy.deepcopy(G).train().requires_grad_(True).to(device)
w_pivot.requires_grad_(False)
# Load VGG16 feature detector.
vgg16_url = 'https://api.ngc.nvidia.com/v2/models/nvidia/research/stylegan3/versions/1/files/metrics/vgg16.pkl'
vgg16 = metric_utils.get_feature_detector(vgg16_url, device=device)
# l2 criterion
l2_criterion = torch.nn.MSELoss(reduction='mean')
# Features for target image.
target_images = target.unsqueeze(0).to(device).to(torch.float32)
if target_images.shape[2] > 256:
target_images = F.interpolate(target_images, size=(256, 256), mode='area')
target_features = vgg16(target_images, resize_images=False, return_lpips=True)
# initalize optimizer
optimizer = torch.optim.Adam(G_pti.parameters(), lr=learning_rate)
# run optimization loop
all_images = []
for step in range(num_steps):
# Synth images from opt_w.
synth_images = G_pti.synthesis(w_pivot[0].repeat(1,G.num_ws,1), noise_mode=noise_mode)
# track images
synth_images = (synth_images + 1) * (255/2)
synth_images_np = synth_images.clone().detach().permute(0, 2, 3, 1).clamp(0, 255).to(torch.uint8)[0].cpu().numpy()
all_images.append(synth_images_np)
# Downsample image to 256x256 if it's larger than that. VGG was built for 224x224 images.
if synth_images.shape[2] > 256:
synth_images = F.interpolate(synth_images, size=(256, 256), mode='area')
# LPIPS loss
synth_features = vgg16(synth_images, resize_images=False, return_lpips=True)
lpips_loss = (target_features - synth_features).square().sum()
# MSE loss
mse_loss = l2_criterion(target_images, synth_images)
# space regularizer
reg_loss = space_regularizer_loss(G_pti, G_original, w_pivot, vgg16)
# Step
optimizer.zero_grad(set_to_none=True)
loss = mse_loss + lpips_loss + reg_loss
loss.backward()
optimizer.step()
msg = f'[ step {step+1:>4d}/{num_steps}] '
msg += f'[ loss: {float(loss):<5.2f}] '
msg += f'[ lpips: {float(lpips_loss):<5.2f}] '
msg += f'[ mse: {float(mse_loss):<5.2f}]'
msg += f'[ reg: {float(reg_loss):<5.2f}]'
if verbose: print(msg)
return all_images, G_pti
def project(
G,
target: torch.Tensor, # [C,H,W] and dynamic range [0,255], W & H must match G output resolution
*,
num_steps = 1000,
w_avg_samples = 10000,
initial_learning_rate = 0.1,
lr_rampdown_length = 0.25,
lr_rampup_length = 0.05,
verbose = False,
device: torch.device,
noise_mode="const",
):
assert target.shape == (G.img_channels, G.img_resolution, G.img_resolution)
G = copy.deepcopy(G).eval().requires_grad_(False).to(device) # type: ignore
# Compute w stats.
print(f'Computing W midpoint and stddev using {w_avg_samples} samples...')
z_samples = torch.from_numpy(np.random.RandomState(123).randn(w_avg_samples, G.z_dim)).to(device)
# get class probas by classifier
if not G.c_dim:
c_samples = None
else:
classifier = timm.create_model('deit_base_distilled_patch16_224', pretrained=True).eval().to(device)
cls_target = F.interpolate((target.to(device).to(torch.float32) / 127.5 - 1)[None], 224)
logits = classifier(cls_target).softmax(1)
classes = torch.multinomial(logits, w_avg_samples, replacement=True).squeeze()
print(f'Main class: {logits.argmax(1).item()}, confidence: {logits.max().item():.4f}')
c_samples = np.zeros([w_avg_samples, G.c_dim], dtype=np.float32)
for i, c in enumerate(classes):
c_samples[i, c] = 1
c_samples = torch.from_numpy(c_samples).to(device)
w_samples = G.mapping(z_samples, c_samples) # [N, L, C]
# get empirical w_avg
w_samples = w_samples[:, :1, :].cpu().numpy().astype(np.float32) # [N, 1, C]
w_avg = np.mean(w_samples, axis=0, keepdims=True) # [1, 1, C]
# Load VGG16 feature detector.
vgg16_url = 'https://api.ngc.nvidia.com/v2/models/nvidia/research/stylegan3/versions/1/files/metrics/vgg16.pkl'
vgg16 = metric_utils.get_feature_detector(vgg16_url, device=device)
# Features for target image.
target_images = target.unsqueeze(0).to(device).to(torch.float32)
if target_images.shape[2] > 256:
target_images = F.interpolate(target_images, size=(256, 256), mode='area')
target_features = vgg16(target_images, resize_images=False, return_lpips=True)
# initalize optimizer
w_opt = torch.tensor(w_avg, dtype=torch.float32, device=device, requires_grad=True) # pylint: disable=not-callable
optimizer = torch.optim.Adam([w_opt], betas=(0.9, 0.999), lr=initial_learning_rate)
# run optimization loop
all_images = []
for step in range(num_steps):
# Learning rate schedule.
t = step / num_steps
lr_ramp = min(1.0, (1.0 - t) / lr_rampdown_length)
lr_ramp = 0.5 - 0.5 * np.cos(lr_ramp * np.pi)
lr_ramp = lr_ramp * min(1.0, t / lr_rampup_length)
lr = initial_learning_rate * lr_ramp
for param_group in optimizer.param_groups:
param_group['lr'] = lr
# Synth images from opt_w.
synth_images = G.synthesis(w_opt[0].repeat(1,G.num_ws,1), noise_mode=noise_mode)
# track images
synth_images = (synth_images + 1) * (255/2)
synth_images_np = synth_images.clone().detach().permute(0, 2, 3, 1).clamp(0, 255).to(torch.uint8)[0].cpu().numpy()
all_images.append(synth_images_np)
# Downsample image to 256x256 if it's larger than that. VGG was built for 224x224 images.
if synth_images.shape[2] > 256:
synth_images = F.interpolate(synth_images, size=(256, 256), mode='area')
# Features for synth images.
synth_features = vgg16(synth_images, resize_images=False, return_lpips=True)
lpips_loss = (target_features - synth_features).square().sum()
# Step
optimizer.zero_grad(set_to_none=True)
loss = lpips_loss
loss.backward()
optimizer.step()
msg = f'[ step {step+1:>4d}/{num_steps}] '
msg += f'[ loss: {float(loss):<5.2f}] '
if verbose: print(msg)
return all_images, w_opt.detach()[0]
@click.command()
@click.option('--network', 'network_pkl', help='Network pickle filename', required=True)
@click.option('--target', 'target_fname', help='Target image file to project to', required=True, metavar='FILE')
@click.option('--seed', help='Random seed', type=int, default=42, show_default=True)
@click.option('--save-video', help='Save an mp4 video of optimization progress', type=bool, default=True, show_default=True)
@click.option('--outdir', help='Where to save the output images', required=True, metavar='DIR')
@click.option('--inv-steps', help='Number of inversion steps', type=int, default=1000, show_default=True)
@click.option('--w-init', help='path to inital latent', type=str, default='', show_default=True)
@click.option('--run-pti', help='run pivotal tuning', is_flag=True)
@click.option('--pti-steps', help='Number of pti steps', type=int, default=350, show_default=True)
def run_projection(
network_pkl: str,
target_fname: str,
outdir: str,
save_video: bool,
seed: int,
inv_steps: int,
w_init: str,
run_pti: bool,
pti_steps: int,
):
np.random.seed(seed)
torch.manual_seed(seed)
# Load networks.
print('Loading networks from "%s"...' % network_pkl)
device = torch.device('cuda')
with dnnlib.util.open_url(network_pkl) as fp:
G = legacy.load_network_pkl(fp)['G_ema'].to(device) # type: ignore
# Load target image.
target_pil = PIL.Image.open(target_fname).convert('RGB')
w, h = target_pil.size
s = min(w, h)
target_pil = target_pil.crop(((w - s) // 2, (h - s) // 2, (w + s) // 2, (h + s) // 2))
target_pil = target_pil.resize((G.img_resolution, G.img_resolution), PIL.Image.LANCZOS)
target_uint8 = np.array(target_pil, dtype=np.uint8)
# Latent optimization
start_time = perf_counter()
all_images = []
if not w_init:
print('Running Latent Optimization...')
all_images, projected_w = project(
G,
target=torch.tensor(target_uint8.transpose([2, 0, 1]), device=device), # pylint: disable=not-callable
num_steps=inv_steps,
device=device,
verbose=True,
noise_mode='const',
)
print(f'Elapsed time: {(perf_counter()-start_time):.1f} s')
else:
projected_w = torch.from_numpy(np.load(w_init)['w'])[0].to(device)
start_time = perf_counter()
# Run PTI
if run_pti:
print('Running Pivotal Tuning Inversion...')
gen_images, G = pivotal_tuning(
G,
projected_w,
target=torch.tensor(target_uint8.transpose([2, 0, 1]), device=device),
device=device,
num_steps=pti_steps,
verbose=True,
)
all_images += gen_images
print(f'Elapsed time: {(perf_counter()-start_time):.1f} s')
# Render debug output: optional video and projected image and W vector.
os.makedirs(outdir, exist_ok=True)
if save_video:
video = imageio.get_writer(f'{outdir}/proj.mp4', mode='I', fps=60, codec='libx264', bitrate='16M')
print (f'Saving optimization progress video "{outdir}/proj.mp4"')
for synth_image in all_images:
video.append_data(np.concatenate([target_uint8, synth_image], axis=1))
video.close()
# Save final projected frame and W vector.
target_pil.save(f'{outdir}/target.png')
synth_image = G.synthesis(projected_w.repeat(1, G.num_ws, 1))
synth_image = (synth_image + 1) * (255/2)
synth_image = synth_image.permute(0, 2, 3, 1).clamp(0, 255).to(torch.uint8)[0].cpu().numpy()
PIL.Image.fromarray(synth_image, 'RGB').save(f'{outdir}/proj.png')
# save latents
np.savez(f'{outdir}/projected_w.npz', w=projected_w.unsqueeze(0).cpu().numpy())
# Save Generator weights
snapshot_data = {'G': G, 'G_ema': G}
with open(f"{outdir}/G.pkl", 'wb') as f:
dill.dump(snapshot_data, f)
#----------------------------------------------------------------------------
if __name__ == "__main__":
run_projection() # pylint: disable=no-value-for-parameter