DL-Art-School/codes/scripts/stylegan2/convert_weights_rosinality.py
James Betker 3074f41877 Get rosinality model converter to work
Mostly, just needed to remove the custom cuda ops, not so bueno on Windows.
2020-12-17 16:03:39 -07:00

292 lines
8.4 KiB
Python

# Converts from Tensorflow Stylegan2 weights to weights used by this model.
# Original source: https://raw.githubusercontent.com/rosinality/stylegan2-pytorch/master/convert_weight.py
#
# Also doesn't require you to install Tensorflow 1.15 or clone the nVidia repo.
import argparse
import os
import sys
import pickle
import math
import torch
import numpy as np
from torchvision import utils
from models.archs.stylegan.stylegan2_rosinality import Generator, Discriminator
# Converts from the TF state_dict input provided into the vars originally expected from the rosinality converter.
def get_vars(vars, source_name):
net_name = source_name.split('/')[0]
vars_as_tuple_list = vars[net_name]['variables']
result_vars = {}
for t in vars_as_tuple_list:
result_vars[t[0]] = t[1]
return result_vars, source_name.replace(net_name + "/", "")
def get_vars_direct(vars, source_name):
v, n = get_vars(vars, source_name)
return v[n]
def convert_modconv(vars, source_name, target_name, flip=False):
vars, source_name = get_vars(vars, source_name)
weight = vars[source_name + "/weight"]
mod_weight = vars[source_name + "/mod_weight"]
mod_bias = vars[source_name + "/mod_bias"]
noise = vars[source_name + "/noise_strength"]
bias = vars[source_name + "/bias"]
dic = {
"conv.weight": np.expand_dims(weight.transpose((3, 2, 0, 1)), 0),
"conv.modulation.weight": mod_weight.transpose((1, 0)),
"conv.modulation.bias": mod_bias + 1,
"noise.weight": np.array([noise]),
"activate.bias": bias,
}
dic_torch = {}
for k, v in dic.items():
dic_torch[target_name + "." + k] = torch.from_numpy(v)
if flip:
dic_torch[target_name + ".conv.weight"] = torch.flip(
dic_torch[target_name + ".conv.weight"], [3, 4]
)
return dic_torch
def convert_conv(vars, source_name, target_name, bias=True, start=0):
vars, source_name = get_vars(vars, source_name)
weight = vars[source_name + "/weight"]
dic = {"weight": weight.transpose((3, 2, 0, 1))}
if bias:
dic["bias"] = vars[source_name + "/bias"]
dic_torch = {}
dic_torch[target_name + f".{start}.weight"] = torch.from_numpy(dic["weight"])
if bias:
dic_torch[target_name + f".{start + 1}.bias"] = torch.from_numpy(dic["bias"])
return dic_torch
def convert_torgb(vars, source_name, target_name):
vars, source_name = get_vars(vars, source_name)
weight = vars[source_name + "/weight"]
mod_weight = vars[source_name + "/mod_weight"]
mod_bias = vars[source_name + "/mod_bias"]
bias = vars[source_name + "/bias"]
dic = {
"conv.weight": np.expand_dims(weight.transpose((3, 2, 0, 1)), 0),
"conv.modulation.weight": mod_weight.transpose((1, 0)),
"conv.modulation.bias": mod_bias + 1,
"bias": bias.reshape((1, 3, 1, 1)),
}
dic_torch = {}
for k, v in dic.items():
dic_torch[target_name + "." + k] = torch.from_numpy(v)
return dic_torch
def convert_dense(vars, source_name, target_name):
vars, source_name = get_vars(vars, source_name)
weight = vars[source_name + "/weight"]
bias = vars[source_name + "/bias"]
dic = {"weight": weight.transpose((1, 0)), "bias": bias}
dic_torch = {}
for k, v in dic.items():
dic_torch[target_name + "." + k] = torch.from_numpy(v)
return dic_torch
def update(state_dict, new):
for k, v in new.items():
state_dict[k] = v
def discriminator_fill_statedict(statedict, vars, size):
log_size = int(math.log(size, 2))
update(statedict, convert_conv(vars, f"{size}x{size}/FromRGB", "convs.0"))
conv_i = 1
for i in range(log_size - 2, 0, -1):
reso = 4 * 2 ** i
update(
statedict,
convert_conv(vars, f"{reso}x{reso}/Conv0", f"convs.{conv_i}.conv1"),
)
update(
statedict,
convert_conv(
vars, f"{reso}x{reso}/Conv1_down", f"convs.{conv_i}.conv2", start=1
),
)
update(
statedict,
convert_conv(
vars, f"{reso}x{reso}/Skip", f"convs.{conv_i}.skip", start=1, bias=False
),
)
conv_i += 1
update(statedict, convert_conv(vars, f"4x4/Conv", "final_conv"))
update(statedict, convert_dense(vars, f"4x4/Dense0", "final_linear.0"))
update(statedict, convert_dense(vars, f"Output", "final_linear.1"))
return statedict
def fill_statedict(state_dict, vars, size):
log_size = int(math.log(size, 2))
for i in range(8):
update(state_dict, convert_dense(vars, f"G_mapping/Dense{i}", f"style.{i + 1}"))
update(
state_dict,
{
"input.input": torch.from_numpy(
get_vars_direct(vars, "G_synthesis/4x4/Const/const")
)
},
)
update(state_dict, convert_torgb(vars, "G_synthesis/4x4/ToRGB", "to_rgb1"))
for i in range(log_size - 2):
reso = 4 * 2 ** (i + 1)
update(
state_dict,
convert_torgb(vars, f"G_synthesis/{reso}x{reso}/ToRGB", f"to_rgbs.{i}"),
)
update(state_dict, convert_modconv(vars, "G_synthesis/4x4/Conv", "conv1"))
conv_i = 0
for i in range(log_size - 2):
reso = 4 * 2 ** (i + 1)
update(
state_dict,
convert_modconv(
vars,
f"G_synthesis/{reso}x{reso}/Conv0_up",
f"convs.{conv_i}",
flip=True,
),
)
update(
state_dict,
convert_modconv(
vars, f"G_synthesis/{reso}x{reso}/Conv1", f"convs.{conv_i + 1}"
),
)
conv_i += 2
for i in range(0, (log_size - 2) * 2 + 1):
update(
state_dict,
{
f"noises.noise_{i}": torch.from_numpy(
get_vars_direct(vars, f"G_synthesis/noise{i}")
)
},
)
return state_dict
if __name__ == "__main__":
device = "cuda"
parser = argparse.ArgumentParser(
description="Tensorflow to pytorch model checkpoint converter"
)
parser.add_argument(
"--gen", action="store_true", help="convert the generator weights"
)
parser.add_argument(
"--disc", action="store_true", help="convert the discriminator weights"
)
parser.add_argument(
"--channel_multiplier",
type=int,
default=2,
help="channel multiplier factor. config-f = 2, else = 1",
)
parser.add_argument("path", metavar="PATH", help="path to the tensorflow weights")
args = parser.parse_args()
sys.path.append('scripts\\stylegan2')
import dnnlib
from dnnlib.tflib.network import generator, discriminator, gen_ema
with open(args.path, "rb") as f:
pickle.load(f)
# Weight names are ordered by size. The last name will be something like '1024x1024/<blah>'. We just need to grab that first number.
size = int(generator['G_synthesis']['variables'][-1][0].split('x')[0])
g = Generator(size, 512, 8, channel_multiplier=args.channel_multiplier)
state_dict = g.state_dict()
state_dict = fill_statedict(state_dict, gen_ema, size)
g.load_state_dict(state_dict, strict=True)
latent_avg = torch.from_numpy(get_vars_direct(gen_ema, "G/dlatent_avg"))
ckpt = {"g_ema": state_dict, "latent_avg": latent_avg}
if args.gen:
g_train = Generator(size, 512, 8, channel_multiplier=args.channel_multiplier)
g_train_state = g_train.state_dict()
g_train_state = fill_statedict(g_train_state, generator, size)
ckpt["g"] = g_train_state
if args.disc:
disc = Discriminator(size, channel_multiplier=args.channel_multiplier)
d_state = disc.state_dict()
d_state = discriminator_fill_statedict(d_state, discriminator.vars, size)
ckpt["d"] = d_state
name = os.path.splitext(os.path.basename(args.path))[0]
torch.save(ckpt, name + ".pt")
batch_size = {256: 16, 512: 9, 1024: 4}
n_sample = batch_size.get(size, 25)
g = g.to(device)
z = np.random.RandomState(5).randn(n_sample, 512).astype("float32")
with torch.no_grad():
img_pt, _ = g(
[torch.from_numpy(z).to(device)],
truncation=0.5,
truncation_latent=latent_avg.to(device),
randomize_noise=False,
)
utils.save_image(
img_pt, name + ".png", nrow=n_sample, normalize=True, range=(-1, 1)
)