forked from mrq/DL-Art-School
3074f41877
Mostly, just needed to remove the custom cuda ops, not so bueno on Windows.
292 lines
8.4 KiB
Python
292 lines
8.4 KiB
Python
# Converts from Tensorflow Stylegan2 weights to weights used by this model.
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# Original source: https://raw.githubusercontent.com/rosinality/stylegan2-pytorch/master/convert_weight.py
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#
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# Also doesn't require you to install Tensorflow 1.15 or clone the nVidia repo.
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import argparse
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import os
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import sys
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import pickle
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import math
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import torch
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import numpy as np
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from torchvision import utils
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from models.archs.stylegan.stylegan2_rosinality import Generator, Discriminator
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# Converts from the TF state_dict input provided into the vars originally expected from the rosinality converter.
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def get_vars(vars, source_name):
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net_name = source_name.split('/')[0]
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vars_as_tuple_list = vars[net_name]['variables']
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result_vars = {}
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for t in vars_as_tuple_list:
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result_vars[t[0]] = t[1]
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return result_vars, source_name.replace(net_name + "/", "")
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def get_vars_direct(vars, source_name):
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v, n = get_vars(vars, source_name)
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return v[n]
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def convert_modconv(vars, source_name, target_name, flip=False):
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vars, source_name = get_vars(vars, source_name)
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weight = vars[source_name + "/weight"]
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mod_weight = vars[source_name + "/mod_weight"]
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mod_bias = vars[source_name + "/mod_bias"]
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noise = vars[source_name + "/noise_strength"]
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bias = vars[source_name + "/bias"]
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dic = {
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"conv.weight": np.expand_dims(weight.transpose((3, 2, 0, 1)), 0),
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"conv.modulation.weight": mod_weight.transpose((1, 0)),
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"conv.modulation.bias": mod_bias + 1,
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"noise.weight": np.array([noise]),
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"activate.bias": bias,
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}
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dic_torch = {}
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for k, v in dic.items():
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dic_torch[target_name + "." + k] = torch.from_numpy(v)
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if flip:
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dic_torch[target_name + ".conv.weight"] = torch.flip(
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dic_torch[target_name + ".conv.weight"], [3, 4]
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)
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return dic_torch
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def convert_conv(vars, source_name, target_name, bias=True, start=0):
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vars, source_name = get_vars(vars, source_name)
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weight = vars[source_name + "/weight"]
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dic = {"weight": weight.transpose((3, 2, 0, 1))}
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if bias:
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dic["bias"] = vars[source_name + "/bias"]
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dic_torch = {}
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dic_torch[target_name + f".{start}.weight"] = torch.from_numpy(dic["weight"])
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if bias:
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dic_torch[target_name + f".{start + 1}.bias"] = torch.from_numpy(dic["bias"])
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return dic_torch
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def convert_torgb(vars, source_name, target_name):
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vars, source_name = get_vars(vars, source_name)
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weight = vars[source_name + "/weight"]
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mod_weight = vars[source_name + "/mod_weight"]
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mod_bias = vars[source_name + "/mod_bias"]
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bias = vars[source_name + "/bias"]
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dic = {
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"conv.weight": np.expand_dims(weight.transpose((3, 2, 0, 1)), 0),
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"conv.modulation.weight": mod_weight.transpose((1, 0)),
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"conv.modulation.bias": mod_bias + 1,
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"bias": bias.reshape((1, 3, 1, 1)),
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}
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dic_torch = {}
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for k, v in dic.items():
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dic_torch[target_name + "." + k] = torch.from_numpy(v)
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return dic_torch
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def convert_dense(vars, source_name, target_name):
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vars, source_name = get_vars(vars, source_name)
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weight = vars[source_name + "/weight"]
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bias = vars[source_name + "/bias"]
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dic = {"weight": weight.transpose((1, 0)), "bias": bias}
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dic_torch = {}
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for k, v in dic.items():
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dic_torch[target_name + "." + k] = torch.from_numpy(v)
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return dic_torch
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def update(state_dict, new):
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for k, v in new.items():
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state_dict[k] = v
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def discriminator_fill_statedict(statedict, vars, size):
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log_size = int(math.log(size, 2))
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update(statedict, convert_conv(vars, f"{size}x{size}/FromRGB", "convs.0"))
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conv_i = 1
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for i in range(log_size - 2, 0, -1):
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reso = 4 * 2 ** i
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update(
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statedict,
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convert_conv(vars, f"{reso}x{reso}/Conv0", f"convs.{conv_i}.conv1"),
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)
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update(
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statedict,
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convert_conv(
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vars, f"{reso}x{reso}/Conv1_down", f"convs.{conv_i}.conv2", start=1
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),
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)
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update(
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statedict,
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convert_conv(
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vars, f"{reso}x{reso}/Skip", f"convs.{conv_i}.skip", start=1, bias=False
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),
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)
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conv_i += 1
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update(statedict, convert_conv(vars, f"4x4/Conv", "final_conv"))
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update(statedict, convert_dense(vars, f"4x4/Dense0", "final_linear.0"))
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update(statedict, convert_dense(vars, f"Output", "final_linear.1"))
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return statedict
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def fill_statedict(state_dict, vars, size):
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log_size = int(math.log(size, 2))
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for i in range(8):
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update(state_dict, convert_dense(vars, f"G_mapping/Dense{i}", f"style.{i + 1}"))
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update(
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state_dict,
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{
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"input.input": torch.from_numpy(
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get_vars_direct(vars, "G_synthesis/4x4/Const/const")
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)
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},
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)
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update(state_dict, convert_torgb(vars, "G_synthesis/4x4/ToRGB", "to_rgb1"))
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for i in range(log_size - 2):
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reso = 4 * 2 ** (i + 1)
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update(
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state_dict,
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convert_torgb(vars, f"G_synthesis/{reso}x{reso}/ToRGB", f"to_rgbs.{i}"),
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)
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update(state_dict, convert_modconv(vars, "G_synthesis/4x4/Conv", "conv1"))
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conv_i = 0
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for i in range(log_size - 2):
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reso = 4 * 2 ** (i + 1)
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update(
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state_dict,
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convert_modconv(
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vars,
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f"G_synthesis/{reso}x{reso}/Conv0_up",
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f"convs.{conv_i}",
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flip=True,
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),
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)
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update(
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state_dict,
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convert_modconv(
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vars, f"G_synthesis/{reso}x{reso}/Conv1", f"convs.{conv_i + 1}"
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),
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)
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conv_i += 2
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for i in range(0, (log_size - 2) * 2 + 1):
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update(
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state_dict,
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{
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f"noises.noise_{i}": torch.from_numpy(
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get_vars_direct(vars, f"G_synthesis/noise{i}")
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)
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},
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)
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return state_dict
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if __name__ == "__main__":
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device = "cuda"
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parser = argparse.ArgumentParser(
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description="Tensorflow to pytorch model checkpoint converter"
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)
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parser.add_argument(
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"--gen", action="store_true", help="convert the generator weights"
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)
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parser.add_argument(
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"--disc", action="store_true", help="convert the discriminator weights"
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)
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parser.add_argument(
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"--channel_multiplier",
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type=int,
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default=2,
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help="channel multiplier factor. config-f = 2, else = 1",
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)
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parser.add_argument("path", metavar="PATH", help="path to the tensorflow weights")
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args = parser.parse_args()
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sys.path.append('scripts\\stylegan2')
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import dnnlib
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from dnnlib.tflib.network import generator, discriminator, gen_ema
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with open(args.path, "rb") as f:
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pickle.load(f)
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# Weight names are ordered by size. The last name will be something like '1024x1024/<blah>'. We just need to grab that first number.
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size = int(generator['G_synthesis']['variables'][-1][0].split('x')[0])
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g = Generator(size, 512, 8, channel_multiplier=args.channel_multiplier)
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state_dict = g.state_dict()
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state_dict = fill_statedict(state_dict, gen_ema, size)
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g.load_state_dict(state_dict, strict=True)
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latent_avg = torch.from_numpy(get_vars_direct(gen_ema, "G/dlatent_avg"))
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ckpt = {"g_ema": state_dict, "latent_avg": latent_avg}
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if args.gen:
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g_train = Generator(size, 512, 8, channel_multiplier=args.channel_multiplier)
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g_train_state = g_train.state_dict()
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g_train_state = fill_statedict(g_train_state, generator, size)
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ckpt["g"] = g_train_state
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if args.disc:
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disc = Discriminator(size, channel_multiplier=args.channel_multiplier)
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d_state = disc.state_dict()
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d_state = discriminator_fill_statedict(d_state, discriminator.vars, size)
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ckpt["d"] = d_state
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name = os.path.splitext(os.path.basename(args.path))[0]
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torch.save(ckpt, name + ".pt")
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batch_size = {256: 16, 512: 9, 1024: 4}
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n_sample = batch_size.get(size, 25)
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g = g.to(device)
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z = np.random.RandomState(5).randn(n_sample, 512).astype("float32")
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with torch.no_grad():
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img_pt, _ = g(
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[torch.from_numpy(z).to(device)],
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truncation=0.5,
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truncation_latent=latent_avg.to(device),
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randomize_noise=False,
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)
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utils.save_image(
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img_pt, name + ".png", nrow=n_sample, normalize=True, range=(-1, 1)
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)
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