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StyleNeRF / legacy.py

Jiatao Gu

add code from the original repo

94ada0b about 2 years ago

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	# Copyright (c) 2021, NVIDIA CORPORATION. All rights reserved.
	#
	# NVIDIA CORPORATION and its licensors retain all intellectual property
	# and proprietary rights in and to this software, related documentation
	# and any modifications thereto. Any use, reproduction, disclosure or
	# distribution of this software and related documentation without an express
	# license agreement from NVIDIA CORPORATION is strictly prohibited.

	import click
	import pickle
	import re
	import copy
	import numpy as np
	import torch
	import dnnlib
	from torch_utils import misc

	#----------------------------------------------------------------------------

	def load_network_pkl(f, force_fp16=False):
	data = _LegacyUnpickler(f).load()

	# Legacy TensorFlow pickle => convert.
	if isinstance(data, tuple) and len(data) == 3 and all(isinstance(net, _TFNetworkStub) for net in data):
	tf_G, tf_D, tf_Gs = data
	G = convert_tf_generator(tf_G)
	D = convert_tf_discriminator(tf_D)
	G_ema = convert_tf_generator(tf_Gs)
	data = dict(G=G, D=D, G_ema=G_ema)

	# Add missing fields.
	if 'training_set_kwargs' not in data:
	data['training_set_kwargs'] = None
	if 'augment_pipe' not in data:
	data['augment_pipe'] = None

	# Validate contents.
	# assert isinstance(data['G'], torch.nn.Module)
	# assert isinstance(data['D'], torch.nn.Module)
	# assert isinstance(data['G_ema'], torch.nn.Module)
	# assert isinstance(data['training_set_kwargs'], (dict, type(None)))
	# assert isinstance(data['augment_pipe'], (torch.nn.Module, type(None)))

	# Force FP16.
	if force_fp16:
	for key in ['G', 'D', 'G_ema']:
	old = data[key]
	kwargs = copy.deepcopy(old.init_kwargs)
	if key.startswith('G'):
	kwargs.synthesis_kwargs = dnnlib.EasyDict(kwargs.get('synthesis_kwargs', {}))
	kwargs.synthesis_kwargs.num_fp16_res = 4
	kwargs.synthesis_kwargs.conv_clamp = 256
	if key.startswith('D'):
	kwargs.num_fp16_res = 4
	kwargs.conv_clamp = 256
	if kwargs != old.init_kwargs:
	new = type(old)(**kwargs).eval().requires_grad_(False)
	misc.copy_params_and_buffers(old, new, require_all=True)
	data[key] = new
	return data

	#----------------------------------------------------------------------------

	class _TFNetworkStub(dnnlib.EasyDict):
	pass

	class _LegacyUnpickler(pickle.Unpickler):
	def find_class(self, module, name):
	if module == 'dnnlib.tflib.network' and name == 'Network':
	return _TFNetworkStub
	return super().find_class(module, name)

	#----------------------------------------------------------------------------

	def _collect_tf_params(tf_net):
	# pylint: disable=protected-access
	tf_params = dict()
	def recurse(prefix, tf_net):
	for name, value in tf_net.variables:
	tf_params[prefix + name] = value
	for name, comp in tf_net.components.items():
	recurse(prefix + name + '/', comp)
	recurse('', tf_net)
	return tf_params

	#----------------------------------------------------------------------------

	def _populate_module_params(module, *patterns):
	for name, tensor in misc.named_params_and_buffers(module):
	found = False
	value = None
	for pattern, value_fn in zip(patterns[0::2], patterns[1::2]):
	match = re.fullmatch(pattern, name)
	if match:
	found = True
	if value_fn is not None:
	value = value_fn(*match.groups())
	break
	try:
	assert found
	if value is not None:
	tensor.copy_(torch.from_numpy(np.array(value)))
	except:
	print(name, list(tensor.shape))
	raise

	#----------------------------------------------------------------------------

	def convert_tf_generator(tf_G):
	if tf_G.version < 4:
	raise ValueError('TensorFlow pickle version too low')

	# Collect kwargs.
	tf_kwargs = tf_G.static_kwargs
	known_kwargs = set()
	def kwarg(tf_name, default=None, none=None):
	known_kwargs.add(tf_name)
	val = tf_kwargs.get(tf_name, default)
	return val if val is not None else none

	# Convert kwargs.
	kwargs = dnnlib.EasyDict(
	z_dim = kwarg('latent_size', 512),
	c_dim = kwarg('label_size', 0),
	w_dim = kwarg('dlatent_size', 512),
	img_resolution = kwarg('resolution', 1024),
	img_channels = kwarg('num_channels', 3),
	mapping_kwargs = dnnlib.EasyDict(
	num_layers = kwarg('mapping_layers', 8),
	embed_features = kwarg('label_fmaps', None),
	layer_features = kwarg('mapping_fmaps', None),
	activation = kwarg('mapping_nonlinearity', 'lrelu'),
	lr_multiplier = kwarg('mapping_lrmul', 0.01),
	w_avg_beta = kwarg('w_avg_beta', 0.995, none=1),
	),
	synthesis_kwargs = dnnlib.EasyDict(
	channel_base = kwarg('fmap_base', 16384) * 2,
	channel_max = kwarg('fmap_max', 512),
	num_fp16_res = kwarg('num_fp16_res', 0),
	conv_clamp = kwarg('conv_clamp', None),
	architecture = kwarg('architecture', 'skip'),
	resample_filter = kwarg('resample_kernel', [1,3,3,1]),
	use_noise = kwarg('use_noise', True),
	activation = kwarg('nonlinearity', 'lrelu'),
	),
	)

	# Check for unknown kwargs.
	kwarg('truncation_psi')
	kwarg('truncation_cutoff')
	kwarg('style_mixing_prob')
	kwarg('structure')
	unknown_kwargs = list(set(tf_kwargs.keys()) - known_kwargs)
	if len(unknown_kwargs) > 0:
	raise ValueError('Unknown TensorFlow kwarg', unknown_kwargs[0])

	# Collect params.
	tf_params = _collect_tf_params(tf_G)
	for name, value in list(tf_params.items()):
	match = re.fullmatch(r'ToRGB_lod(\d+)/(.*)', name)
	if match:
	r = kwargs.img_resolution // (2 ** int(match.group(1)))
	tf_params[f'{r}x{r}/ToRGB/{match.group(2)}'] = value
	kwargs.synthesis.kwargs.architecture = 'orig'
	#for name, value in tf_params.items(): print(f'{name:<50s}{list(value.shape)}')

	# Convert params.
	from training import networks
	G = networks.Generator(**kwargs).eval().requires_grad_(False)
	# pylint: disable=unnecessary-lambda
	_populate_module_params(G,
	r'mapping\.w_avg', lambda: tf_params[f'dlatent_avg'],
	r'mapping\.embed\.weight', lambda: tf_params[f'mapping/LabelEmbed/weight'].transpose(),
	r'mapping\.embed\.bias', lambda: tf_params[f'mapping/LabelEmbed/bias'],
	r'mapping\.fc(\d+)\.weight', lambda i: tf_params[f'mapping/Dense{i}/weight'].transpose(),
	r'mapping\.fc(\d+)\.bias', lambda i: tf_params[f'mapping/Dense{i}/bias'],
	r'synthesis\.b4\.const', lambda: tf_params[f'synthesis/4x4/Const/const'][0],
	r'synthesis\.b4\.conv1\.weight', lambda: tf_params[f'synthesis/4x4/Conv/weight'].transpose(3, 2, 0, 1),
	r'synthesis\.b4\.conv1\.bias', lambda: tf_params[f'synthesis/4x4/Conv/bias'],
	r'synthesis\.b4\.conv1\.noise_const', lambda: tf_params[f'synthesis/noise0'][0, 0],
	r'synthesis\.b4\.conv1\.noise_strength', lambda: tf_params[f'synthesis/4x4/Conv/noise_strength'],
	r'synthesis\.b4\.conv1\.affine\.weight', lambda: tf_params[f'synthesis/4x4/Conv/mod_weight'].transpose(),
	r'synthesis\.b4\.conv1\.affine\.bias', lambda: tf_params[f'synthesis/4x4/Conv/mod_bias'] + 1,
	r'synthesis\.b(\d+)\.conv0\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/Conv0_up/weight'][::-1, ::-1].transpose(3, 2, 0, 1),
	r'synthesis\.b(\d+)\.conv0\.bias', lambda r: tf_params[f'synthesis/{r}x{r}/Conv0_up/bias'],
	r'synthesis\.b(\d+)\.conv0\.noise_const', lambda r: tf_params[f'synthesis/noise{int(np.log2(int(r)))*2-5}'][0, 0],
	r'synthesis\.b(\d+)\.conv0\.noise_strength', lambda r: tf_params[f'synthesis/{r}x{r}/Conv0_up/noise_strength'],
	r'synthesis\.b(\d+)\.conv0\.affine\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/Conv0_up/mod_weight'].transpose(),
	r'synthesis\.b(\d+)\.conv0\.affine\.bias', lambda r: tf_params[f'synthesis/{r}x{r}/Conv0_up/mod_bias'] + 1,
	r'synthesis\.b(\d+)\.conv1\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/Conv1/weight'].transpose(3, 2, 0, 1),
	r'synthesis\.b(\d+)\.conv1\.bias', lambda r: tf_params[f'synthesis/{r}x{r}/Conv1/bias'],
	r'synthesis\.b(\d+)\.conv1\.noise_const', lambda r: tf_params[f'synthesis/noise{int(np.log2(int(r)))*2-4}'][0, 0],
	r'synthesis\.b(\d+)\.conv1\.noise_strength', lambda r: tf_params[f'synthesis/{r}x{r}/Conv1/noise_strength'],
	r'synthesis\.b(\d+)\.conv1\.affine\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/Conv1/mod_weight'].transpose(),
	r'synthesis\.b(\d+)\.conv1\.affine\.bias', lambda r: tf_params[f'synthesis/{r}x{r}/Conv1/mod_bias'] + 1,
	r'synthesis\.b(\d+)\.torgb\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/ToRGB/weight'].transpose(3, 2, 0, 1),
	r'synthesis\.b(\d+)\.torgb\.bias', lambda r: tf_params[f'synthesis/{r}x{r}/ToRGB/bias'],
	r'synthesis\.b(\d+)\.torgb\.affine\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/ToRGB/mod_weight'].transpose(),
	r'synthesis\.b(\d+)\.torgb\.affine\.bias', lambda r: tf_params[f'synthesis/{r}x{r}/ToRGB/mod_bias'] + 1,
	r'synthesis\.b(\d+)\.skip\.weight', lambda r: tf_params[f'synthesis/{r}x{r}/Skip/weight'][::-1, ::-1].transpose(3, 2, 0, 1),
	r'.*\.resample_filter', None,
	)
	return G

	#----------------------------------------------------------------------------

	def convert_tf_discriminator(tf_D):
	if tf_D.version < 4:
	raise ValueError('TensorFlow pickle version too low')

	# Collect kwargs.
	tf_kwargs = tf_D.static_kwargs
	known_kwargs = set()
	def kwarg(tf_name, default=None):
	known_kwargs.add(tf_name)
	return tf_kwargs.get(tf_name, default)

	# Convert kwargs.
	kwargs = dnnlib.EasyDict(
	c_dim = kwarg('label_size', 0),
	img_resolution = kwarg('resolution', 1024),
	img_channels = kwarg('num_channels', 3),
	architecture = kwarg('architecture', 'resnet'),
	channel_base = kwarg('fmap_base', 16384) * 2,
	channel_max = kwarg('fmap_max', 512),
	num_fp16_res = kwarg('num_fp16_res', 0),
	conv_clamp = kwarg('conv_clamp', None),
	cmap_dim = kwarg('mapping_fmaps', None),
	block_kwargs = dnnlib.EasyDict(
	activation = kwarg('nonlinearity', 'lrelu'),
	resample_filter = kwarg('resample_kernel', [1,3,3,1]),
	freeze_layers = kwarg('freeze_layers', 0),
	),
	mapping_kwargs = dnnlib.EasyDict(
	num_layers = kwarg('mapping_layers', 0),
	embed_features = kwarg('mapping_fmaps', None),
	layer_features = kwarg('mapping_fmaps', None),
	activation = kwarg('nonlinearity', 'lrelu'),
	lr_multiplier = kwarg('mapping_lrmul', 0.1),
	),
	epilogue_kwargs = dnnlib.EasyDict(
	mbstd_group_size = kwarg('mbstd_group_size', None),
	mbstd_num_channels = kwarg('mbstd_num_features', 1),
	activation = kwarg('nonlinearity', 'lrelu'),
	),
	)

	# Check for unknown kwargs.
	kwarg('structure')
	unknown_kwargs = list(set(tf_kwargs.keys()) - known_kwargs)
	if len(unknown_kwargs) > 0:
	raise ValueError('Unknown TensorFlow kwarg', unknown_kwargs[0])

	# Collect params.
	tf_params = _collect_tf_params(tf_D)
	for name, value in list(tf_params.items()):
	match = re.fullmatch(r'FromRGB_lod(\d+)/(.*)', name)
	if match:
	r = kwargs.img_resolution // (2 ** int(match.group(1)))
	tf_params[f'{r}x{r}/FromRGB/{match.group(2)}'] = value
	kwargs.architecture = 'orig'
	#for name, value in tf_params.items(): print(f'{name:<50s}{list(value.shape)}')

	# Convert params.
	from training import networks
	D = networks.Discriminator(**kwargs).eval().requires_grad_(False)
	# pylint: disable=unnecessary-lambda
	_populate_module_params(D,
	r'b(\d+)\.fromrgb\.weight', lambda r: tf_params[f'{r}x{r}/FromRGB/weight'].transpose(3, 2, 0, 1),
	r'b(\d+)\.fromrgb\.bias', lambda r: tf_params[f'{r}x{r}/FromRGB/bias'],
	r'b(\d+)\.conv(\d+)\.weight', lambda r, i: tf_params[f'{r}x{r}/Conv{i}{["","_down"][int(i)]}/weight'].transpose(3, 2, 0, 1),
	r'b(\d+)\.conv(\d+)\.bias', lambda r, i: tf_params[f'{r}x{r}/Conv{i}{["","_down"][int(i)]}/bias'],
	r'b(\d+)\.skip\.weight', lambda r: tf_params[f'{r}x{r}/Skip/weight'].transpose(3, 2, 0, 1),
	r'mapping\.embed\.weight', lambda: tf_params[f'LabelEmbed/weight'].transpose(),
	r'mapping\.embed\.bias', lambda: tf_params[f'LabelEmbed/bias'],
	r'mapping\.fc(\d+)\.weight', lambda i: tf_params[f'Mapping{i}/weight'].transpose(),
	r'mapping\.fc(\d+)\.bias', lambda i: tf_params[f'Mapping{i}/bias'],
	r'b4\.conv\.weight', lambda: tf_params[f'4x4/Conv/weight'].transpose(3, 2, 0, 1),
	r'b4\.conv\.bias', lambda: tf_params[f'4x4/Conv/bias'],
	r'b4\.fc\.weight', lambda: tf_params[f'4x4/Dense0/weight'].transpose(),
	r'b4\.fc\.bias', lambda: tf_params[f'4x4/Dense0/bias'],
	r'b4\.out\.weight', lambda: tf_params[f'Output/weight'].transpose(),
	r'b4\.out\.bias', lambda: tf_params[f'Output/bias'],
	r'.*\.resample_filter', None,
	)
	return D

	#----------------------------------------------------------------------------

	@click.command()
	@click.option('--source', help='Input pickle', required=True, metavar='PATH')
	@click.option('--dest', help='Output pickle', required=True, metavar='PATH')
	@click.option('--force-fp16', help='Force the networks to use FP16', type=bool, default=False, metavar='BOOL', show_default=True)
	def convert_network_pickle(source, dest, force_fp16):
	"""Convert legacy network pickle into the native PyTorch format.

	The tool is able to load the main network configurations exported using the TensorFlow version of StyleGAN2 or StyleGAN2-ADA.
	It does not support e.g. StyleGAN2-ADA comparison methods, StyleGAN2 configs A-D, or StyleGAN1 networks.

	Example:

	\b
	python legacy.py \\
	--source=https://nvlabs-fi-cdn.nvidia.com/stylegan2/networks/stylegan2-cat-config-f.pkl \\
	--dest=stylegan2-cat-config-f.pkl
	"""
	print(f'Loading "{source}"...')
	with dnnlib.util.open_url(source) as f:
	data = load_network_pkl(f, force_fp16=force_fp16)
	print(f'Saving "{dest}"...')
	with open(dest, 'wb') as f:
	pickle.dump(data, f)
	print('Done.')

	#----------------------------------------------------------------------------

	if __name__ == "__main__":
	convert_network_pickle() # pylint: disable=no-value-for-parameter

	#----------------------------------------------------------------------------