interfacegan_pp / models /stylegan_generator.py
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# python3.7
"""Contains the generator class of StyleGAN.
Basically, this class is derived from the `BaseGenerator` class defined in
`base_generator.py`.
"""
import os
import numpy as np
import torch
from . import model_settings
from .stylegan_generator_model import StyleGANGeneratorModel
from .base_generator import BaseGenerator
__all__ = ['StyleGANGenerator']
class StyleGANGenerator(BaseGenerator):
"""Defines the generator class of StyleGAN.
Different from conventional GAN, StyleGAN introduces a disentangled latent
space (i.e., W space) besides the normal latent space (i.e., Z space). Then,
the disentangled latent code, w, is fed into each convolutional layer to
modulate the `style` of the synthesis through AdaIN (Adaptive Instance
Normalization) layer. Normally, the w's fed into all layers are the same. But,
they can actually be different to make different layers get different styles.
Accordingly, an extended space (i.e. W+ space) is used to gather all w's
together. Taking the official StyleGAN model trained on FF-HQ dataset as an
instance, there are
(1) Z space, with dimension (512,)
(2) W space, with dimension (512,)
(3) W+ space, with dimension (18, 512)
"""
def __init__(self, model_name, logger=None):
self.truncation_psi = model_settings.STYLEGAN_TRUNCATION_PSI
self.truncation_layers = model_settings.STYLEGAN_TRUNCATION_LAYERS
self.randomize_noise = model_settings.STYLEGAN_RANDOMIZE_NOISE
self.model_specific_vars = ['truncation.truncation']
super().__init__(model_name, logger)
self.num_layers = (int(np.log2(self.resolution)) - 1) * 2
assert self.gan_type == 'stylegan'
def build(self):
self.check_attr('w_space_dim')
self.check_attr('fused_scale')
self.model = StyleGANGeneratorModel(
resolution=self.resolution,
w_space_dim=self.w_space_dim,
fused_scale=self.fused_scale,
output_channels=self.output_channels,
truncation_psi=self.truncation_psi,
truncation_layers=self.truncation_layers,
randomize_noise=self.randomize_noise)
def load(self):
self.logger.info(f'Loading pytorch model from `{self.model_path}`.')
state_dict = torch.load(self.model_path)
for var_name in self.model_specific_vars:
state_dict[var_name] = self.model.state_dict()[var_name]
self.model.load_state_dict(state_dict)
self.logger.info(f'Successfully loaded!')
self.lod = self.model.synthesis.lod.to(self.cpu_device).tolist()
self.logger.info(f' `lod` of the loaded model is {self.lod}.')
def convert_tf_model(self, test_num=10):
import sys
import pickle
import tensorflow as tf
os.environ['TF_CPP_MIN_LOG_LEVEL'] = '2'
sys.path.append(model_settings.BASE_DIR + '/stylegan_tf_official')
self.logger.info(f'Loading tensorflow model from `{self.tf_model_path}`.')
tf.InteractiveSession()
with open(self.tf_model_path, 'rb') as f:
_, _, tf_model = pickle.load(f)
self.logger.info(f'Successfully loaded!')
self.logger.info(f'Converting tensorflow model to pytorch version.')
tf_vars = dict(tf_model.__getstate__()['variables'])
tf_vars.update(
dict(tf_model.components.mapping.__getstate__()['variables']))
tf_vars.update(
dict(tf_model.components.synthesis.__getstate__()['variables']))
state_dict = self.model.state_dict()
for pth_var_name, tf_var_name in self.model.pth_to_tf_var_mapping.items():
if 'ToRGB_lod' in tf_var_name:
lod = int(tf_var_name[len('ToRGB_lod')])
lod_shift = 10 - int(np.log2(self.resolution))
tf_var_name = tf_var_name.replace(f'{lod}', f'{lod - lod_shift}')
if tf_var_name not in tf_vars:
self.logger.debug(f'Variable `{tf_var_name}` does not exist in '
f'tensorflow model.')
continue
self.logger.debug(f' Converting `{tf_var_name}` to `{pth_var_name}`.')
var = torch.from_numpy(np.array(tf_vars[tf_var_name]))
if 'weight' in pth_var_name:
if 'dense' in pth_var_name:
var = var.permute(1, 0)
elif 'conv' in pth_var_name:
var = var.permute(3, 2, 0, 1)
state_dict[pth_var_name] = var
self.logger.info(f'Successfully converted!')
self.logger.info(f'Saving pytorch model to `{self.model_path}`.')
for var_name in self.model_specific_vars:
del state_dict[var_name]
torch.save(state_dict, self.model_path)
self.logger.info(f'Successfully saved!')
self.load()
# Official tensorflow model can only run on GPU.
if test_num <= 0 or not tf.test.is_built_with_cuda():
return
self.logger.info(f'Testing conversion results.')
self.model.eval().to(self.run_device)
total_distance = 0.0
for i in range(test_num):
latent_code = self.easy_sample(1)
tf_output = tf_model.run(latent_code, # latents_in
None, # labels_in
truncation_psi=self.truncation_psi,
truncation_cutoff=self.truncation_layers,
randomize_noise=self.randomize_noise)
pth_output = self.synthesize(latent_code)['image']
distance = np.average(np.abs(tf_output - pth_output))
self.logger.debug(f' Test {i:03d}: distance {distance:.6e}.')
total_distance += distance
self.logger.info(f'Average distance is {total_distance / test_num:.6e}.')
def sample(self, num, latent_space_type='Z'):
"""Samples latent codes randomly.
Args:
num: Number of latent codes to sample. Should be positive.
latent_space_type: Type of latent space from which to sample latent code.
Only [`Z`, `W`, `WP`] are supported. Case insensitive. (default: `Z`)
Returns:
A `numpy.ndarray` as sampled latend codes.
Raises:
ValueError: If the given `latent_space_type` is not supported.
"""
latent_space_type = latent_space_type.upper()
if latent_space_type == 'Z':
latent_codes = np.random.randn(num, self.latent_space_dim)
elif latent_space_type == 'W':
latent_codes = np.random.randn(num, self.w_space_dim)
elif latent_space_type == 'WP':
latent_codes = np.random.randn(num, self.num_layers, self.w_space_dim)
else:
raise ValueError(f'Latent space type `{latent_space_type}` is invalid!')
return latent_codes.astype(np.float32)
def preprocess(self, latent_codes, latent_space_type='Z'):
"""Preprocesses the input latent code if needed.
Args:
latent_codes: The input latent codes for preprocessing.
latent_space_type: Type of latent space to which the latent codes belong.
Only [`Z`, `W`, `WP`] are supported. Case insensitive. (default: `Z`)
Returns:
The preprocessed latent codes which can be used as final input for the
generator.
Raises:
ValueError: If the given `latent_space_type` is not supported.
"""
if not isinstance(latent_codes, np.ndarray):
raise ValueError(f'Latent codes should be with type `numpy.ndarray`!')
latent_space_type = latent_space_type.upper()
if latent_space_type == 'Z':
latent_codes = latent_codes.reshape(-1, self.latent_space_dim)
norm = np.linalg.norm(latent_codes, axis=1, keepdims=True)
latent_codes = latent_codes / norm * np.sqrt(self.latent_space_dim)
elif latent_space_type == 'W':
latent_codes = latent_codes.reshape(-1, self.w_space_dim)
elif latent_space_type == 'WP':
latent_codes = latent_codes.reshape(-1, self.num_layers, self.w_space_dim)
else:
raise ValueError(f'Latent space type `{latent_space_type}` is invalid!')
return latent_codes.astype(np.float32)
def easy_sample(self, num, latent_space_type='Z'):
return self.preprocess(self.sample(num, latent_space_type),
latent_space_type)
def synthesize(self,
latent_codes,
latent_space_type='Z',
generate_style=False,
generate_image=True):
"""Synthesizes images with given latent codes.
One can choose whether to generate the layer-wise style codes.
Args:
latent_codes: Input latent codes for image synthesis.
latent_space_type: Type of latent space to which the latent codes belong.
Only [`Z`, `W`, `WP`] are supported. Case insensitive. (default: `Z`)
generate_style: Whether to generate the layer-wise style codes. (default:
False)
generate_image: Whether to generate the final image synthesis. (default:
True)
Returns:
A dictionary whose values are raw outputs from the generator.
"""
if not isinstance(latent_codes, np.ndarray):
raise ValueError(f'Latent codes should be with type `numpy.ndarray`!')
results = {}
latent_space_type = latent_space_type.upper()
latent_codes_shape = latent_codes.shape
# Generate from Z space.
if latent_space_type == 'Z':
if not (len(latent_codes_shape) == 2 and
latent_codes_shape[0] <= self.batch_size and
latent_codes_shape[1] == self.latent_space_dim):
raise ValueError(f'Latent_codes should be with shape [batch_size, '
f'latent_space_dim], where `batch_size` no larger '
f'than {self.batch_size}, and `latent_space_dim` '
f'equal to {self.latent_space_dim}!\n'
f'But {latent_codes_shape} received!')
zs = torch.from_numpy(latent_codes).type(torch.FloatTensor)
zs = zs.to(self.run_device)
ws = self.model.mapping(zs)
wps = self.model.truncation(ws)
results['z'] = latent_codes
results['w'] = self.get_value(ws)
results['wp'] = self.get_value(wps)
# Generate from W space.
elif latent_space_type == 'W':
if not (len(latent_codes_shape) == 2 and
latent_codes_shape[0] <= self.batch_size and
latent_codes_shape[1] == self.w_space_dim):
raise ValueError(f'Latent_codes should be with shape [batch_size, '
f'w_space_dim], where `batch_size` no larger than '
f'{self.batch_size}, and `w_space_dim` equal to '
f'{self.w_space_dim}!\n'
f'But {latent_codes_shape} received!')
ws = torch.from_numpy(latent_codes).type(torch.FloatTensor)
ws = ws.to(self.run_device)
wps = self.model.truncation(ws)
results['w'] = latent_codes
results['wp'] = self.get_value(wps)
# Generate from W+ space.
elif latent_space_type == 'WP':
if not (len(latent_codes_shape) == 3 and
latent_codes_shape[0] <= self.batch_size and
latent_codes_shape[1] == self.num_layers and
latent_codes_shape[2] == self.w_space_dim):
raise ValueError(f'Latent_codes should be with shape [batch_size, '
f'num_layers, w_space_dim], where `batch_size` no '
f'larger than {self.batch_size}, `num_layers` equal '
f'to {self.num_layers}, and `w_space_dim` equal to '
f'{self.w_space_dim}!\n'
f'But {latent_codes_shape} received!')
wps = torch.from_numpy(latent_codes).type(torch.FloatTensor)
wps = wps.to(self.run_device)
results['wp'] = latent_codes
else:
raise ValueError(f'Latent space type `{latent_space_type}` is invalid!')
if generate_style:
for i in range(self.num_layers):
style = self.model.synthesis.__getattr__(
f'layer{i}').epilogue.style_mod.dense(wps[:, i, :])
results[f'style{i:02d}'] = self.get_value(style)
if generate_image:
images = self.model.synthesis(wps)
results['image'] = self.get_value(images)
return results