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	import ast
	import asyncio
	from datetime import datetime
	import gc
	import importlib
	import argparse
	import math
	import os
	import pathlib
	import re
	import sys
	import random
	import time
	import json
	from multiprocessing import Value
	from typing import Any, Dict, List, Optional
	import accelerate
	import numpy as np
	from packaging.version import Version

	import huggingface_hub
	import toml

	import torch
	from tqdm import tqdm
	from accelerate.utils import set_seed
	from accelerate import Accelerator, InitProcessGroupKwargs, DistributedDataParallelKwargs
	from safetensors.torch import load_file
	import transformers
	from diffusers.optimization import (
	SchedulerType as DiffusersSchedulerType,
	TYPE_TO_SCHEDULER_FUNCTION as DIFFUSERS_TYPE_TO_SCHEDULER_FUNCTION,
	)
	from transformers.optimization import SchedulerType, TYPE_TO_SCHEDULER_FUNCTION

	from dataset import config_utils
	from hunyuan_model.models import load_transformer, get_rotary_pos_embed_by_shape
	import hunyuan_model.text_encoder as text_encoder_module
	from hunyuan_model.vae import load_vae
	import hunyuan_model.vae as vae_module
	from modules.scheduling_flow_match_discrete import FlowMatchDiscreteScheduler
	import networks.lora as lora_module
	from dataset.config_utils import BlueprintGenerator, ConfigSanitizer

	import logging

	from utils import huggingface_utils, model_utils, train_utils, sai_model_spec

	logger = logging.getLogger(__name__)
	logging.basicConfig(level=logging.INFO)


	BASE_MODEL_VERSION_HUNYUAN_VIDEO = "hunyuan_video"

	SS_METADATA_KEY_BASE_MODEL_VERSION = "ss_base_model_version"
	SS_METADATA_KEY_NETWORK_MODULE = "ss_network_module"
	SS_METADATA_KEY_NETWORK_DIM = "ss_network_dim"
	SS_METADATA_KEY_NETWORK_ALPHA = "ss_network_alpha"
	SS_METADATA_KEY_NETWORK_ARGS = "ss_network_args"

	SS_METADATA_MINIMUM_KEYS = [
	SS_METADATA_KEY_BASE_MODEL_VERSION,
	SS_METADATA_KEY_NETWORK_MODULE,
	SS_METADATA_KEY_NETWORK_DIM,
	SS_METADATA_KEY_NETWORK_ALPHA,
	SS_METADATA_KEY_NETWORK_ARGS,
	]


	def clean_memory_on_device(device: torch.device):
	r"""
	Clean memory on the specified device, will be called from training scripts.
	"""
	gc.collect()

	# device may "cuda" or "cuda:0", so we need to check the type of device
	if device.type == "cuda":
	torch.cuda.empty_cache()
	if device.type == "xpu":
	torch.xpu.empty_cache()
	if device.type == "mps":
	torch.mps.empty_cache()


	# for collate_fn: epoch and step is multiprocessing.Value
	class collator_class:
	def __init__(self, epoch, step, dataset):
	self.current_epoch = epoch
	self.current_step = step
	self.dataset = dataset # not used if worker_info is not None, in case of multiprocessing

	def __call__(self, examples):
	worker_info = torch.utils.data.get_worker_info()
	# worker_info is None in the main process
	if worker_info is not None:
	dataset = worker_info.dataset
	else:
	dataset = self.dataset

	# set epoch and step
	dataset.set_current_epoch(self.current_epoch.value)
	dataset.set_current_step(self.current_step.value)
	return examples[0]


	def prepare_accelerator(args: argparse.Namespace) -> Accelerator:
	"""
	DeepSpeed is not supported in this script currently.
	"""
	if args.logging_dir is None:
	logging_dir = None
	else:
	log_prefix = "" if args.log_prefix is None else args.log_prefix
	logging_dir = args.logging_dir + "/" + log_prefix + time.strftime("%Y%m%d%H%M%S", time.localtime())

	if args.log_with is None:
	if logging_dir is not None:
	log_with = "tensorboard"
	else:
	log_with = None
	else:
	log_with = args.log_with
	if log_with in ["tensorboard", "all"]:
	if logging_dir is None:
	raise ValueError(
	"logging_dir is required when log_with is tensorboard / Tensorboardを使う場合、logging_dirを指定してください"
	)
	if log_with in ["wandb", "all"]:
	try:
	import wandb
	except ImportError:
	raise ImportError("No wandb / wandb がインストールされていないようです")
	if logging_dir is not None:
	os.makedirs(logging_dir, exist_ok=True)
	os.environ["WANDB_DIR"] = logging_dir
	if args.wandb_api_key is not None:
	wandb.login(key=args.wandb_api_key)

	kwargs_handlers = [
	(
	InitProcessGroupKwargs(
	backend="gloo" if os.name == "nt" or not torch.cuda.is_available() else "nccl",
	init_method=(
	"env://?use_libuv=False" if os.name == "nt" and Version(torch.__version__) >= Version("2.4.0") else None
	),
	timeout=datetime.timedelta(minutes=args.ddp_timeout) if args.ddp_timeout else None,
	)
	if torch.cuda.device_count() > 1
	else None
	),
	(
	DistributedDataParallelKwargs(
	gradient_as_bucket_view=args.ddp_gradient_as_bucket_view, static_graph=args.ddp_static_graph
	)
	if args.ddp_gradient_as_bucket_view or args.ddp_static_graph
	else None
	),
	]
	kwargs_handlers = [i for i in kwargs_handlers if i is not None]

	accelerator = Accelerator(
	gradient_accumulation_steps=args.gradient_accumulation_steps,
	mixed_precision=args.mixed_precision,
	log_with=log_with,
	project_dir=logging_dir,
	kwargs_handlers=kwargs_handlers,
	)
	print("accelerator device:", accelerator.device)
	return accelerator


	def line_to_prompt_dict(line: str) -> dict:
	# subset of gen_img_diffusers
	prompt_args = line.split(" --")
	prompt_dict = {}
	prompt_dict["prompt"] = prompt_args[0]

	for parg in prompt_args:
	try:
	m = re.match(r"w (\d+)", parg, re.IGNORECASE)
	if m:
	prompt_dict["width"] = int(m.group(1))
	continue

	m = re.match(r"h (\d+)", parg, re.IGNORECASE)
	if m:
	prompt_dict["height"] = int(m.group(1))
	continue

	m = re.match(r"f (\d+)", parg, re.IGNORECASE)
	if m:
	prompt_dict["frame_count"] = int(m.group(1))
	continue

	m = re.match(r"d (\d+)", parg, re.IGNORECASE)
	if m:
	prompt_dict["seed"] = int(m.group(1))
	continue

	m = re.match(r"s (\d+)", parg, re.IGNORECASE)
	if m: # steps
	prompt_dict["sample_steps"] = max(1, min(1000, int(m.group(1))))
	continue

	# m = re.match(r"l ([\d\.]+)", parg, re.IGNORECASE)
	# if m: # scale
	# prompt_dict["scale"] = float(m.group(1))
	# continue
	# m = re.match(r"n (.+)", parg, re.IGNORECASE)
	# if m: # negative prompt
	# prompt_dict["negative_prompt"] = m.group(1)
	# continue

	except ValueError as ex:
	logger.error(f"Exception in parsing / 解析エラー: {parg}")
	logger.error(ex)

	return prompt_dict


	def load_prompts(prompt_file: str) -> list[Dict]:
	# read prompts
	if prompt_file.endswith(".txt"):
	with open(prompt_file, "r", encoding="utf-8") as f:
	lines = f.readlines()
	prompts = [line.strip() for line in lines if len(line.strip()) > 0 and line[0] != "#"]
	elif prompt_file.endswith(".toml"):
	with open(prompt_file, "r", encoding="utf-8") as f:
	data = toml.load(f)
	prompts = [dict(data["prompt"], subset) for subset in data["prompt"]["subset"]]
	elif prompt_file.endswith(".json"):
	with open(prompt_file, "r", encoding="utf-8") as f:
	prompts = json.load(f)

	# preprocess prompts
	for i in range(len(prompts)):
	prompt_dict = prompts[i]
	if isinstance(prompt_dict, str):
	prompt_dict = line_to_prompt_dict(prompt_dict)
	prompts[i] = prompt_dict
	assert isinstance(prompt_dict, dict)

	# Adds an enumerator to the dict based on prompt position. Used later to name image files. Also cleanup of extra data in original prompt dict.
	prompt_dict["enum"] = i
	prompt_dict.pop("subset", None)

	return prompts


	def compute_density_for_timestep_sampling(
	weighting_scheme: str, batch_size: int, logit_mean: float = None, logit_std: float = None, mode_scale: float = None
	):
	"""Compute the density for sampling the timesteps when doing SD3 training.

	Courtesy: This was contributed by Rafie Walker in https://github.com/huggingface/diffusers/pull/8528.

	SD3 paper reference: https://arxiv.org/abs/2403.03206v1.
	"""
	if weighting_scheme == "logit_normal":
	# See 3.1 in the SD3 paper ($rf/lognorm(0.00,1.00)$).
	u = torch.normal(mean=logit_mean, std=logit_std, size=(batch_size,), device="cpu")
	u = torch.nn.functional.sigmoid(u)
	elif weighting_scheme == "mode":
	u = torch.rand(size=(batch_size,), device="cpu")
	u = 1 - u - mode_scale * (torch.cos(math.pi * u / 2) ** 2 - 1 + u)
	else:
	u = torch.rand(size=(batch_size,), device="cpu")
	return u


	def get_sigmas(noise_scheduler, timesteps, device, n_dim=4, dtype=torch.float32):
	sigmas = noise_scheduler.sigmas.to(device=device, dtype=dtype)
	schedule_timesteps = noise_scheduler.timesteps.to(device)
	timesteps = timesteps.to(device)

	# if sum([(schedule_timesteps == t) for t in timesteps]) < len(timesteps):
	if any([(schedule_timesteps == t).sum() == 0 for t in timesteps]):
	# raise ValueError("Some timesteps are not in the schedule / 一部のtimestepsがスケジュールに含まれていません")
	# round to nearest timestep
	logger.warning("Some timesteps are not in the schedule / 一部のtimestepsがスケジュールに含まれていません")
	step_indices = [torch.argmin(torch.abs(schedule_timesteps - t)).item() for t in timesteps]
	else:
	step_indices = [(schedule_timesteps == t).nonzero().item() for t in timesteps]

	sigma = sigmas[step_indices].flatten()
	while len(sigma.shape) < n_dim:
	sigma = sigma.unsqueeze(-1)
	return sigma


	def compute_loss_weighting_for_sd3(weighting_scheme: str, noise_scheduler, timesteps, device, dtype):
	"""Computes loss weighting scheme for SD3 training.

	Courtesy: This was contributed by Rafie Walker in https://github.com/huggingface/diffusers/pull/8528.

	SD3 paper reference: https://arxiv.org/abs/2403.03206v1.
	"""
	if weighting_scheme == "sigma_sqrt" or weighting_scheme == "cosmap":
	sigmas = get_sigmas(noise_scheduler, timesteps, device, n_dim=5, dtype=dtype)
	if weighting_scheme == "sigma_sqrt":
	weighting = (sigmas**-2.0).float()
	else:
	bot = 1 - 2 * sigmas + 2 * sigmas**2
	weighting = 2 / (math.pi * bot)
	else:
	weighting = None # torch.ones_like(sigmas)
	return weighting


	class NetworkTrainer:
	def __init__(self):
	pass

	# TODO 他のスクリプトと共通化する
	def generate_step_logs(
	self,
	args: argparse.Namespace,
	current_loss,
	avr_loss,
	lr_scheduler,
	lr_descriptions,
	optimizer=None,
	keys_scaled=None,
	mean_norm=None,
	maximum_norm=None,
	):
	network_train_unet_only = True
	logs = {"loss/current": current_loss, "loss/average": avr_loss}

	if keys_scaled is not None:
	logs["max_norm/keys_scaled"] = keys_scaled
	logs["max_norm/average_key_norm"] = mean_norm
	logs["max_norm/max_key_norm"] = maximum_norm

	lrs = lr_scheduler.get_last_lr()
	for i, lr in enumerate(lrs):
	if lr_descriptions is not None:
	lr_desc = lr_descriptions[i]
	else:
	idx = i - (0 if network_train_unet_only else -1)
	if idx == -1:
	lr_desc = "textencoder"
	else:
	if len(lrs) > 2:
	lr_desc = f"group{idx}"
	else:
	lr_desc = "unet"

	logs[f"lr/{lr_desc}"] = lr

	if args.optimizer_type.lower().startswith("DAdapt".lower()) or args.optimizer_type.lower() == "Prodigy".lower():
	# tracking d*lr value
	logs[f"lr/d*lr/{lr_desc}"] = (
	lr_scheduler.optimizers[-1].param_groups[i]["d"] * lr_scheduler.optimizers[-1].param_groups[i]["lr"]
	)
	if (
	args.optimizer_type.lower().endswith("ProdigyPlusScheduleFree".lower()) and optimizer is not None
	): # tracking d*lr value of unet.
	logs["lr/dlr"] = optimizer.param_groups[0]["d"] optimizer.param_groups[0]["lr"]
	else:
	idx = 0
	if not network_train_unet_only:
	logs["lr/textencoder"] = float(lrs[0])
	idx = 1

	for i in range(idx, len(lrs)):
	logs[f"lr/group{i}"] = float(lrs[i])
	if args.optimizer_type.lower().startswith("DAdapt".lower()) or args.optimizer_type.lower() == "Prodigy".lower():
	logs[f"lr/d*lr/group{i}"] = (
	lr_scheduler.optimizers[-1].param_groups[i]["d"] * lr_scheduler.optimizers[-1].param_groups[i]["lr"]
	)
	if args.optimizer_type.lower().endswith("ProdigyPlusScheduleFree".lower()) and optimizer is not None:
	logs[f"lr/dlr/group{i}"] = optimizer.param_groups[i]["d"] optimizer.param_groups[i]["lr"]

	return logs

	def process_sample_prompts(
	self,
	args: argparse.Namespace,
	accelerator: Accelerator,
	sample_prompts: str,
	text_encoder1: str,
	text_encoder2: str,
	fp8_llm: bool,
	):
	logger.info(f"cache Text Encoder outputs for sample prompt: {sample_prompts}")
	prompts = load_prompts(sample_prompts)

	def encode_for_text_encoder(text_encoder):
	sample_prompts_te_outputs = {} # (prompt) -> (embeds, mask)
	with accelerator.autocast(), torch.no_grad():
	for prompt_dict in prompts:
	for p in [prompt_dict.get("prompt", "")]:
	if p not in sample_prompts_te_outputs:
	logger.info(f"cache Text Encoder outputs for prompt: {p}")

	data_type = "video"
	text_inputs = text_encoder.text2tokens(p, data_type=data_type)

	prompt_outputs = text_encoder.encode(text_inputs, data_type=data_type)
	sample_prompts_te_outputs[p] = (prompt_outputs.hidden_state, prompt_outputs.attention_mask)

	return sample_prompts_te_outputs

	# Load Text Encoder 1 and encode
	text_encoder_dtype = torch.float16 if args.text_encoder_dtype is None else model_utils.str_to_dtype(args.text_encoder_dtype)
	logger.info(f"loading text encoder 1: {text_encoder1}")
	text_encoder_1 = text_encoder_module.load_text_encoder_1(text_encoder1, accelerator.device, fp8_llm, text_encoder_dtype)

	logger.info("encoding with Text Encoder 1")
	te_outputs_1 = encode_for_text_encoder(text_encoder_1)
	del text_encoder_1

	# Load Text Encoder 2 and encode
	logger.info(f"loading text encoder 2: {text_encoder2}")
	text_encoder_2 = text_encoder_module.load_text_encoder_2(text_encoder2, accelerator.device, text_encoder_dtype)

	logger.info("encoding with Text Encoder 2")
	te_outputs_2 = encode_for_text_encoder(text_encoder_2, is_llm=False)
	del text_encoder_2

	# prepare sample parameters
	sample_parameters = []
	for prompt_dict in prompts:
	prompt_dict_copy = prompt_dict.copy()
	p = prompt_dict.get("prompt", "")
	prompt_dict_copy["llm_embeds"] = te_outputs_1[p][0]
	prompt_dict_copy["llm_mask"] = te_outputs_1[p][1]
	prompt_dict_copy["clipL_embeds"] = te_outputs_2[p][0]
	prompt_dict_copy["clipL_mask"] = te_outputs_2[p][1]
	sample_parameters.append(prompt_dict_copy)

	clean_memory_on_device(accelerator.device)

	return sample_parameters

	def get_optimizer(self, args, trainable_params: list[torch.nn.Parameter]) -> tuple[str, str, torch.optim.Optimizer]:
	# adamw, adamw8bit, adafactor

	optimizer_type = args.optimizer_type

	# split optimizer_type and optimizer_args
	optimizer_kwargs = {}
	if args.optimizer_args is not None and len(args.optimizer_args) > 0:
	for arg in args.optimizer_args:
	key, value = arg.split("=")
	value = ast.literal_eval(value)
	optimizer_kwargs[key] = value

	lr = args.learning_rate
	optimizer = None
	optimizer_class = None

	if optimizer_type.endswith("8bit".lower()):
	try:
	import bitsandbytes as bnb
	except ImportError:
	raise ImportError("No bitsandbytes / bitsandbytesがインストールされていないようです")

	if optimizer_type == "AdamW8bit".lower():
	logger.info(f"use 8-bit AdamW optimizer \| {optimizer_kwargs}")
	optimizer_class = bnb.optim.AdamW8bit
	optimizer = optimizer_class(trainable_params, lr=lr, **optimizer_kwargs)

	elif optimizer_type == "Adafactor".lower():
	# Adafactor: check relative_step and warmup_init
	if "relative_step" not in optimizer_kwargs:
	optimizer_kwargs["relative_step"] = True # default
	if not optimizer_kwargs["relative_step"] and optimizer_kwargs.get("warmup_init", False):
	logger.info(
	f"set relative_step to True because warmup_init is True / warmup_initがTrueのためrelative_stepをTrueにします"
	)
	optimizer_kwargs["relative_step"] = True
	logger.info(f"use Adafactor optimizer \| {optimizer_kwargs}")

	if optimizer_kwargs["relative_step"]:
	logger.info(f"relative_step is true / relative_stepがtrueです")
	if lr != 0.0:
	logger.warning(f"learning rate is used as initial_lr / 指定したlearning rateはinitial_lrとして使用されます")
	args.learning_rate = None

	if args.lr_scheduler != "adafactor":
	logger.info(f"use adafactor_scheduler / スケジューラにadafactor_schedulerを使用します")
	args.lr_scheduler = f"adafactor:{lr}" # ちょっと微妙だけど

	lr = None
	else:
	if args.max_grad_norm != 0.0:
	logger.warning(
	f"because max_grad_norm is set, clip_grad_norm is enabled. consider set to 0 / max_grad_normが設定されているためclip_grad_normが有効になります。0に設定して無効にしたほうがいいかもしれません"
	)
	if args.lr_scheduler != "constant_with_warmup":
	logger.warning(f"constant_with_warmup will be good / スケジューラはconstant_with_warmupが良いかもしれません")
	if optimizer_kwargs.get("clip_threshold", 1.0) != 1.0:
	logger.warning(f"clip_threshold=1.0 will be good / clip_thresholdは1.0が良いかもしれません")

	optimizer_class = transformers.optimization.Adafactor
	optimizer = optimizer_class(trainable_params, lr=lr, **optimizer_kwargs)

	elif optimizer_type == "AdamW".lower():
	logger.info(f"use AdamW optimizer \| {optimizer_kwargs}")
	optimizer_class = torch.optim.AdamW
	optimizer = optimizer_class(trainable_params, lr=lr, **optimizer_kwargs)

	if optimizer is None:
	# 任意のoptimizerを使う
	case_sensitive_optimizer_type = args.optimizer_type # not lower
	logger.info(f"use {case_sensitive_optimizer_type} \| {optimizer_kwargs}")

	if "." not in case_sensitive_optimizer_type: # from torch.optim
	optimizer_module = torch.optim
	else: # from other library
	values = case_sensitive_optimizer_type.split(".")
	optimizer_module = importlib.import_module(".".join(values[:-1]))
	case_sensitive_optimizer_type = values[-1]

	optimizer_class = getattr(optimizer_module, case_sensitive_optimizer_type)
	optimizer = optimizer_class(trainable_params, lr=lr, **optimizer_kwargs)

	# for logging
	optimizer_name = optimizer_class.__module__ + "." + optimizer_class.__name__
	optimizer_args = ",".join([f"{k}={v}" for k, v in optimizer_kwargs.items()])

	# get train and eval functions
	if hasattr(optimizer, "train") and callable(optimizer.train):
	train_fn = optimizer.train
	eval_fn = optimizer.eval
	else:
	train_fn = lambda: None
	eval_fn = lambda: None

	return optimizer_name, optimizer_args, optimizer, train_fn, eval_fn

	def is_schedulefree_optimizer(self, optimizer: torch.optim.Optimizer, args: argparse.Namespace) -> bool:
	return args.optimizer_type.lower().endswith("schedulefree".lower()) # or args.optimizer_schedulefree_wrapper

	def get_dummy_scheduler(optimizer: torch.optim.Optimizer) -> Any:
	# dummy scheduler for schedulefree optimizer. supports only empty step(), get_last_lr() and optimizers.
	# this scheduler is used for logging only.
	# this isn't be wrapped by accelerator because of this class is not a subclass of torch.optim.lr_scheduler._LRScheduler
	class DummyScheduler:
	def __init__(self, optimizer: torch.optim.Optimizer):
	self.optimizer = optimizer

	def step(self):
	pass

	def get_last_lr(self):
	return [group["lr"] for group in self.optimizer.param_groups]

	return DummyScheduler(optimizer)

	def get_scheduler(self, args, optimizer: torch.optim.Optimizer, num_processes: int):
	"""
	Unified API to get any scheduler from its name.
	"""
	# if schedulefree optimizer, return dummy scheduler
	if self.is_schedulefree_optimizer(optimizer, args):
	return self.get_dummy_scheduler(optimizer)

	name = args.lr_scheduler
	num_training_steps = args.max_train_steps * num_processes # * args.gradient_accumulation_steps
	num_warmup_steps: Optional[int] = (
	int(args.lr_warmup_steps * num_training_steps) if isinstance(args.lr_warmup_steps, float) else args.lr_warmup_steps
	)
	num_decay_steps: Optional[int] = (
	int(args.lr_decay_steps * num_training_steps) if isinstance(args.lr_decay_steps, float) else args.lr_decay_steps
	)
	num_stable_steps = num_training_steps - num_warmup_steps - num_decay_steps
	num_cycles = args.lr_scheduler_num_cycles
	power = args.lr_scheduler_power
	timescale = args.lr_scheduler_timescale
	min_lr_ratio = args.lr_scheduler_min_lr_ratio

	lr_scheduler_kwargs = {} # get custom lr_scheduler kwargs
	if args.lr_scheduler_args is not None and len(args.lr_scheduler_args) > 0:
	for arg in args.lr_scheduler_args:
	key, value = arg.split("=")
	value = ast.literal_eval(value)
	lr_scheduler_kwargs[key] = value

	def wrap_check_needless_num_warmup_steps(return_vals):
	if num_warmup_steps is not None and num_warmup_steps != 0:
	raise ValueError(f"{name} does not require `num_warmup_steps`. Set None or 0.")
	return return_vals

	# using any lr_scheduler from other library
	if args.lr_scheduler_type:
	lr_scheduler_type = args.lr_scheduler_type
	logger.info(f"use {lr_scheduler_type} \| {lr_scheduler_kwargs} as lr_scheduler")
	if "." not in lr_scheduler_type: # default to use torch.optim
	lr_scheduler_module = torch.optim.lr_scheduler
	else:
	values = lr_scheduler_type.split(".")
	lr_scheduler_module = importlib.import_module(".".join(values[:-1]))
	lr_scheduler_type = values[-1]
	lr_scheduler_class = getattr(lr_scheduler_module, lr_scheduler_type)
	lr_scheduler = lr_scheduler_class(optimizer, **lr_scheduler_kwargs)
	return lr_scheduler

	if name.startswith("adafactor"):
	assert (
	type(optimizer) == transformers.optimization.Adafactor
	), f"adafactor scheduler must be used with Adafactor optimizer / adafactor schedulerはAdafactorオプティマイザと同時に使ってください"
	initial_lr = float(name.split(":")[1])
	# logger.info(f"adafactor scheduler init lr {initial_lr}")
	return wrap_check_needless_num_warmup_steps(transformers.optimization.AdafactorSchedule(optimizer, initial_lr))

	if name == DiffusersSchedulerType.PIECEWISE_CONSTANT.value:
	name = DiffusersSchedulerType(name)
	schedule_func = DIFFUSERS_TYPE_TO_SCHEDULER_FUNCTION[name]
	return schedule_func(optimizer, **lr_scheduler_kwargs) # step_rules and last_epoch are given as kwargs

	name = SchedulerType(name)
	schedule_func = TYPE_TO_SCHEDULER_FUNCTION[name]

	if name == SchedulerType.CONSTANT:
	return wrap_check_needless_num_warmup_steps(schedule_func(optimizer, **lr_scheduler_kwargs))

	# All other schedulers require `num_warmup_steps`
	if num_warmup_steps is None:
	raise ValueError(f"{name} requires `num_warmup_steps`, please provide that argument.")

	if name == SchedulerType.CONSTANT_WITH_WARMUP:
	return schedule_func(optimizer, num_warmup_steps=num_warmup_steps, **lr_scheduler_kwargs)

	if name == SchedulerType.INVERSE_SQRT:
	return schedule_func(optimizer, num_warmup_steps=num_warmup_steps, timescale=timescale, **lr_scheduler_kwargs)

	# All other schedulers require `num_training_steps`
	if num_training_steps is None:
	raise ValueError(f"{name} requires `num_training_steps`, please provide that argument.")

	if name == SchedulerType.COSINE_WITH_RESTARTS:
	return schedule_func(
	optimizer,
	num_warmup_steps=num_warmup_steps,
	num_training_steps=num_training_steps,
	num_cycles=num_cycles,
	**lr_scheduler_kwargs,
	)

	if name == SchedulerType.POLYNOMIAL:
	return schedule_func(
	optimizer,
	num_warmup_steps=num_warmup_steps,
	num_training_steps=num_training_steps,
	power=power,
	**lr_scheduler_kwargs,
	)

	if name == SchedulerType.COSINE_WITH_MIN_LR:
	return schedule_func(
	optimizer,
	num_warmup_steps=num_warmup_steps,
	num_training_steps=num_training_steps,
	num_cycles=num_cycles / 2,
	min_lr_rate=min_lr_ratio,
	**lr_scheduler_kwargs,
	)

	# these schedulers do not require `num_decay_steps`
	if name == SchedulerType.LINEAR or name == SchedulerType.COSINE:
	return schedule_func(
	optimizer,
	num_warmup_steps=num_warmup_steps,
	num_training_steps=num_training_steps,
	**lr_scheduler_kwargs,
	)

	# All other schedulers require `num_decay_steps`
	if num_decay_steps is None:
	raise ValueError(f"{name} requires `num_decay_steps`, please provide that argument.")
	if name == SchedulerType.WARMUP_STABLE_DECAY:
	return schedule_func(
	optimizer,
	num_warmup_steps=num_warmup_steps,
	num_stable_steps=num_stable_steps,
	num_decay_steps=num_decay_steps,
	num_cycles=num_cycles / 2,
	min_lr_ratio=min_lr_ratio if min_lr_ratio is not None else 0.0,
	**lr_scheduler_kwargs,
	)

	return schedule_func(
	optimizer,
	num_warmup_steps=num_warmup_steps,
	num_training_steps=num_training_steps,
	num_decay_steps=num_decay_steps,
	**lr_scheduler_kwargs,
	)

	def resume_from_local_or_hf_if_specified(self, accelerator: Accelerator, args: argparse.Namespace) -> bool:
	if not args.resume:
	return False

	if not args.resume_from_huggingface:
	logger.info(f"resume training from local state: {args.resume}")
	accelerator.load_state(args.resume)
	return True

	logger.info(f"resume training from huggingface state: {args.resume}")
	repo_id = args.resume.split("/")[0] + "/" + args.resume.split("/")[1]
	path_in_repo = "/".join(args.resume.split("/")[2:])
	revision = None
	repo_type = None
	if ":" in path_in_repo:
	divided = path_in_repo.split(":")
	if len(divided) == 2:
	path_in_repo, revision = divided
	repo_type = "model"
	else:
	path_in_repo, revision, repo_type = divided
	logger.info(f"Downloading state from huggingface: {repo_id}/{path_in_repo}@{revision}")

	list_files = huggingface_utils.list_dir(
	repo_id=repo_id,
	subfolder=path_in_repo,
	revision=revision,
	token=args.huggingface_token,
	repo_type=repo_type,
	)

	async def download(filename) -> str:
	def task():
	return huggingface_hub.hf_hub_download(
	repo_id=repo_id,
	filename=filename,
	revision=revision,
	repo_type=repo_type,
	token=args.huggingface_token,
	)

	return await asyncio.get_event_loop().run_in_executor(None, task)

	loop = asyncio.get_event_loop()
	results = loop.run_until_complete(asyncio.gather(*[download(filename=filename.rfilename) for filename in list_files]))
	if len(results) == 0:
	raise ValueError(
	"No files found in the specified repo id/path/revision / 指定されたリポジトリID/パス/リビジョンにファイルが見つかりませんでした"
	)
	dirname = os.path.dirname(results[0])
	accelerator.load_state(dirname)

	return True

	def sample_images(self, accelerator, args, epoch, global_step, device, vae, transformer, sample_parameters):
	pass

	def get_noisy_model_input_and_timesteps(
	self,
	args: argparse.Namespace,
	noise: torch.Tensor,
	latents: torch.Tensor,
	noise_scheduler: FlowMatchDiscreteScheduler,
	device: torch.device,
	dtype: torch.dtype,
	):
	batch_size = noise.shape[0]

	if args.timestep_sampling == "uniform" or args.timestep_sampling == "sigmoid" or args.timestep_sampling == "shift":
	if args.timestep_sampling == "uniform" or args.timestep_sampling == "sigmoid":
	# Simple random t-based noise sampling
	if args.timestep_sampling == "sigmoid":
	t = torch.sigmoid(args.sigmoid_scale * torch.randn((batch_size,), device=device))
	else:
	t = torch.rand((batch_size,), device=device)

	elif args.timestep_sampling == "shift":
	shift = args.discrete_flow_shift
	logits_norm = torch.randn(batch_size, device=device)
	logits_norm = logits_norm * args.sigmoid_scale # larger scale for more uniform sampling
	t = logits_norm.sigmoid()
	t = (t * shift) / (1 + (shift - 1) * t)

	t_min = args.min_timestep if args.min_timestep is not None else 0
	t_max = args.max_timestep if args.max_timestep is not None else 1000.0
	t_min /= 1000.0
	t_max /= 1000.0
	t = t * (t_max - t_min) + t_min # scale to [t_min, t_max], default [0, 1]

	timesteps = t * 1000.0
	t = t.view(-1, 1, 1, 1, 1)
	noisy_model_input = (1 - t) * latents + t * noise

	timesteps += 1 # 1 to 1000
	else:
	# Sample a random timestep for each image
	# for weighting schemes where we sample timesteps non-uniformly
	u = compute_density_for_timestep_sampling(
	weighting_scheme=args.weighting_scheme,
	batch_size=batch_size,
	logit_mean=args.logit_mean,
	logit_std=args.logit_std,
	mode_scale=args.mode_scale,
	)
	# indices = (u * noise_scheduler.config.num_train_timesteps).long()
	t_min = args.min_timestep if args.min_timestep is not None else 0
	t_max = args.max_timestep if args.max_timestep is not None else 1000
	indices = (u * (t_max - t_min) + t_min).long()

	timesteps = noise_scheduler.timesteps[indices].to(device=device) # 1 to 1000

	# Add noise according to flow matching.
	sigmas = get_sigmas(noise_scheduler, timesteps, device, n_dim=latents.ndim, dtype=dtype)
	noisy_model_input = sigmas * noise + (1.0 - sigmas) * latents

	return noisy_model_input, timesteps

	def show_timesteps(self, args: argparse.Namespace):
	N_TRY = 100000
	BATCH_SIZE = 1000
	CONSOLE_WIDTH = 64
	N_TIMESTEPS_PER_LINE = 25

	noise_scheduler = FlowMatchDiscreteScheduler(shift=args.discrete_flow_shift, reverse=True, solver="euler")
	# print(f"Noise scheduler timesteps: {noise_scheduler.timesteps}")

	latents = torch.zeros(BATCH_SIZE, 1, 1, 1, 1, dtype=torch.float16)
	noise = torch.ones_like(latents)

	# sample timesteps
	sampled_timesteps = [0] * noise_scheduler.config.num_train_timesteps
	for i in tqdm(range(N_TRY // BATCH_SIZE)):
	# we use noise=1, so retured noisy_model_input is same as timestep, because `noisy_model_input = (1 - t) * latents + t * noise`
	actual_timesteps, _ = self.get_noisy_model_input_and_timesteps(
	args, noise, latents, noise_scheduler, "cpu", torch.float16
	)
	actual_timesteps = actual_timesteps[:, 0, 0, 0, 0] * 1000
	for t in actual_timesteps:
	t = int(t.item())
	sampled_timesteps[t] += 1

	# sample weighting
	sampled_weighting = [0] * noise_scheduler.config.num_train_timesteps
	for i in tqdm(range(len(sampled_weighting))):
	timesteps = torch.tensor([i + 1], device="cpu")
	weighting = compute_loss_weighting_for_sd3(args.weighting_scheme, noise_scheduler, timesteps, "cpu", torch.float16)
	if weighting is None:
	weighting = torch.tensor(1.0, device="cpu")
	elif torch.isinf(weighting).any():
	weighting = torch.tensor(1.0, device="cpu")
	sampled_weighting[i] = weighting.item()

	# show results
	if args.show_timesteps == "image":
	# show timesteps with matplotlib
	import matplotlib.pyplot as plt

	plt.figure(figsize=(10, 5))
	plt.subplot(1, 2, 1)
	plt.bar(range(len(sampled_timesteps)), sampled_timesteps, width=1.0)
	plt.title("Sampled timesteps")
	plt.xlabel("Timestep")
	plt.ylabel("Count")

	plt.subplot(1, 2, 2)
	plt.bar(range(len(sampled_weighting)), sampled_weighting, width=1.0)
	plt.title("Sampled loss weighting")
	plt.xlabel("Timestep")
	plt.ylabel("Weighting")

	plt.tight_layout()
	plt.show()

	else:
	sampled_timesteps = np.array(sampled_timesteps)
	sampled_weighting = np.array(sampled_weighting)

	# average per line
	sampled_timesteps = sampled_timesteps.reshape(-1, N_TIMESTEPS_PER_LINE).mean(axis=1)
	sampled_weighting = sampled_weighting.reshape(-1, N_TIMESTEPS_PER_LINE).mean(axis=1)

	max_count = max(sampled_timesteps)
	print(f"Sampled timesteps: max count={max_count}")
	for i, t in enumerate(sampled_timesteps):
	line = f"{(i)N_TIMESTEPS_PER_LINE:4d}-{(i+1)N_TIMESTEPS_PER_LINE-1:4d}: "
	line += "#" * int(t / max_count * CONSOLE_WIDTH)
	print(line)

	max_weighting = max(sampled_weighting)
	print(f"Sampled loss weighting: max weighting={max_weighting}")
	for i, w in enumerate(sampled_weighting):
	line = f"{iN_TIMESTEPS_PER_LINE:4d}-{(i+1)N_TIMESTEPS_PER_LINE-1:4d}: {w:8.2f} "
	line += "#" * int(w / max_weighting * CONSOLE_WIDTH)
	print(line)

	def train(self, args):
	# show timesteps for debugging
	if args.show_timesteps:
	self.show_timesteps(args)
	return

	session_id = random.randint(0, 2**32)
	training_started_at = time.time()
	# setup_logging(args, reset=True)

	if args.seed is None:
	args.seed = random.randint(0, 2**32)
	set_seed(args.seed)

	# Load dataset config
	blueprint_generator = BlueprintGenerator(ConfigSanitizer())
	logger.info(f"Load dataset config from {args.dataset_config}")
	user_config = config_utils.load_user_config(args.dataset_config)
	blueprint = blueprint_generator.generate(user_config, args)
	train_dataset_group = config_utils.generate_dataset_group_by_blueprint(blueprint.dataset_group, training=True)

	current_epoch = Value("i", 0)
	current_step = Value("i", 0)
	ds_for_collator = train_dataset_group if args.max_data_loader_n_workers == 0 else None
	collator = collator_class(current_epoch, current_step, ds_for_collator)

	# prepare accelerator
	logger.info("preparing accelerator")
	accelerator = prepare_accelerator(args)
	is_main_process = accelerator.is_main_process

	# prepare dtype
	weight_dtype = torch.float32
	if args.mixed_precision == "fp16":
	weight_dtype = torch.float16
	elif args.mixed_precision == "bf16":
	weight_dtype = torch.bfloat16

	# HunyuanVideo specific
	dit_dtype = torch.bfloat16 if args.dit_dtype is None else model_utils.str_to_dtype(args.dit_dtype)
	dit_weight_dtype = torch.float8_e4m3fn if args.fp8_base else dit_dtype
	logger.info(f"DiT precision: {dit_dtype}, weight precision: {dit_weight_dtype}")
	vae_dtype = torch.float16 if args.vae_dtype is None else model_utils.str_to_dtype(args.vae_dtype)

	# get embedding for sampling images
	sample_parameters = vae = None
	if args.sample_prompts:
	sample_parameters = self.process_sample_prompts(
	args, accelerator, args.sample_prompts, args.text_encoder1, args.text_encoder2, args.fp8_llm
	)

	# Load VAE model for sampling images: VAE is loaded to cpu to save gpu memory
	vae, _, s_ratio, t_ratio = load_vae(vae_dtype=vae_dtype, device="cpu", vae_path=args.vae)
	vae.requires_grad_(False)
	vae.eval()

	if args.vae_chunk_size is not None:
	vae.set_chunk_size_for_causal_conv_3d(args.vae_chunk_size)
	logger.info(f"Set chunk_size to {args.vae_chunk_size} for CausalConv3d in VAE")
	if args.vae_spatial_tile_sample_min_size is not None:
	vae.enable_spatial_tiling(True)
	vae.tile_sample_min_size = args.vae_spatial_tile_sample_min_size
	vae.tile_latent_min_size = args.vae_spatial_tile_sample_min_size // 8
	elif args.vae_tiling:
	vae.enable_spatial_tiling(True)

	# load DiT model
	blocks_to_swap = args.blocks_to_swap if args.blocks_to_swap else 0
	loading_device = "cpu" if blocks_to_swap > 0 else accelerator.device

	logger.info(f"Loading DiT model from {args.dit}")
	if args.sdpa:
	attn_mode = "torch"
	elif args.flash_attn:
	attn_mode = "flash"
	elif args.sage_attn:
	attn_mode = "sageattn"
	else:
	raise ValueError(
	f"either --sdpa or --flash-attn or --sage-attn must be specified / --sdpaか--flash-attnか--sage-attnのいずれかを指定してください"
	)
	transformer = load_transformer(args.dit, attn_mode, loading_device, dit_weight_dtype)
	transformer.eval()
	transformer.requires_grad_(False)

	if blocks_to_swap > 0:
	logger.info(f"enable swap {blocks_to_swap} blocks to CPU from device: {accelerator.device}")
	transformer.enable_block_swap(blocks_to_swap, accelerator.device, supports_backward=True)
	transformer.move_to_device_except_swap_blocks(accelerator.device)
	if args.img_in_txt_in_offloading:
	logger.info("Enable offloading img_in and txt_in to CPU")
	transformer.enable_img_in_txt_in_offloading()

	# load network model for differential training
	sys.path.append(os.path.dirname(__file__))
	accelerator.print("import network module:", args.network_module)
	network_module: lora_module = importlib.import_module(args.network_module) # actual module may be different

	if args.base_weights is not None:
	# if base_weights is specified, merge the weights to DiT model
	for i, weight_path in enumerate(args.base_weights):
	if args.base_weights_multiplier is None or len(args.base_weights_multiplier) <= i:
	multiplier = 1.0
	else:
	multiplier = args.base_weights_multiplier[i]

	accelerator.print(f"merging module: {weight_path} with multiplier {multiplier}")

	weights_sd = load_file(weight_path)
	module = network_module.create_network_from_weights_hunyuan_video(multiplier, weights_sd, unet=transformer)
	module.merge_to(None, transformer, weights_sd, weight_dtype, "cpu")

	accelerator.print(f"all weights merged: {', '.join(args.base_weights)}")

	# prepare network
	net_kwargs = {}
	if args.network_args is not None:
	for net_arg in args.network_args:
	key, value = net_arg.split("=")
	net_kwargs[key] = value

	if args.dim_from_weights:
	logger.info(f"Loading network from weights: {args.dim_from_weights}")
	weights_sd = load_file(args.dim_from_weights)
	network, _ = network_module.create_network_from_weights_hunyuan_video(1, weights_sd, unet=transformer)
	else:
	network = network_module.create_network_hunyuan_video(
	1.0,
	args.network_dim,
	args.network_alpha,
	vae,
	None,
	transformer,
	neuron_dropout=args.network_dropout,
	**net_kwargs,
	)
	if network is None:
	return

	network.prepare_network(args)

	# apply network to DiT
	network.apply_to(None, transformer, apply_text_encoder=False, apply_unet=True)

	if args.network_weights is not None:
	# FIXME consider alpha of weights: this assumes that the alpha is not changed
	info = network.load_weights(args.network_weights)
	accelerator.print(f"load network weights from {args.network_weights}: {info}")

	if args.gradient_checkpointing:
	transformer.enable_gradient_checkpointing()
	network.enable_gradient_checkpointing() # may have no effect

	# prepare optimizer, data loader etc.
	accelerator.print("prepare optimizer, data loader etc.")

	trainable_params, lr_descriptions = network.prepare_optimizer_params(unet_lr=args.learning_rate)
	optimizer_name, optimizer_args, optimizer, optimizer_train_fn, optimizer_eval_fn = self.get_optimizer(
	args, trainable_params
	)

	# prepare dataloader

	# num workers for data loader: if 0, persistent_workers is not available
	n_workers = min(args.max_data_loader_n_workers, os.cpu_count()) # cpu_count or max_data_loader_n_workers

	train_dataloader = torch.utils.data.DataLoader(
	train_dataset_group,
	batch_size=1,
	shuffle=True,
	collate_fn=collator,
	num_workers=n_workers,
	persistent_workers=args.persistent_data_loader_workers,
	)

	# calculate max_train_steps
	if args.max_train_epochs is not None:
	args.max_train_steps = args.max_train_epochs * math.ceil(
	len(train_dataloader) / accelerator.num_processes / args.gradient_accumulation_steps
	)
	accelerator.print(
	f"override steps. steps for {args.max_train_epochs} epochs is / 指定エポックまでのステップ数: {args.max_train_steps}"
	)

	# send max_train_steps to train_dataset_group
	train_dataset_group.set_max_train_steps(args.max_train_steps)

	# prepare lr_scheduler
	lr_scheduler = self.get_scheduler(args, optimizer, accelerator.num_processes)

	# prepare training model. accelerator does some magic here

	# experimental feature: train the model with gradients in fp16/bf16
	network_dtype = torch.float32
	args.full_fp16 = args.full_bf16 = False # temporary disabled because stochastic rounding is not supported yet
	if args.full_fp16:
	assert (
	args.mixed_precision == "fp16"
	), "full_fp16 requires mixed precision='fp16' / full_fp16を使う場合はmixed_precision='fp16'を指定してください。"
	accelerator.print("enable full fp16 training.")
	network_dtype = weight_dtype
	network.to(network_dtype)
	elif args.full_bf16:
	assert (
	args.mixed_precision == "bf16"
	), "full_bf16 requires mixed precision='bf16' / full_bf16を使う場合はmixed_precision='bf16'を指定してください。"
	accelerator.print("enable full bf16 training.")
	network_dtype = weight_dtype
	network.to(network_dtype)

	if dit_weight_dtype != dit_dtype:
	logger.info(f"casting model to {dit_weight_dtype}")
	transformer.to(dit_weight_dtype)

	if blocks_to_swap > 0:
	transformer = accelerator.prepare(transformer, device_placement=[not blocks_to_swap > 0])
	accelerator.unwrap_model(transformer).move_to_device_except_swap_blocks(accelerator.device) # reduce peak memory usage
	accelerator.unwrap_model(transformer).prepare_block_swap_before_forward()
	else:
	transformer = accelerator.prepare(transformer)

	network, optimizer, train_dataloader, lr_scheduler = accelerator.prepare(network, optimizer, train_dataloader, lr_scheduler)
	training_model = network

	if args.gradient_checkpointing:
	transformer.train()
	else:
	transformer.eval()

	accelerator.unwrap_model(network).prepare_grad_etc(transformer)

	if args.full_fp16:
	# patch accelerator for fp16 training
	# def patch_accelerator_for_fp16_training(accelerator):
	org_unscale_grads = accelerator.scaler._unscale_grads_

	def _unscale_grads_replacer(optimizer, inv_scale, found_inf, allow_fp16):
	return org_unscale_grads(optimizer, inv_scale, found_inf, True)

	accelerator.scaler._unscale_grads_ = _unscale_grads_replacer

	# before resuming make hook for saving/loading to save/load the network weights only
	def save_model_hook(models, weights, output_dir):
	# pop weights of other models than network to save only network weights
	# only main process or deepspeed https://github.com/huggingface/diffusers/issues/2606
	if accelerator.is_main_process: # or args.deepspeed:
	remove_indices = []
	for i, model in enumerate(models):
	if not isinstance(model, type(accelerator.unwrap_model(network))):
	remove_indices.append(i)
	for i in reversed(remove_indices):
	if len(weights) > i:
	weights.pop(i)
	# print(f"save model hook: {len(weights)} weights will be saved")

	def load_model_hook(models, input_dir):
	# remove models except network
	remove_indices = []
	for i, model in enumerate(models):
	if not isinstance(model, type(accelerator.unwrap_model(network))):
	remove_indices.append(i)
	for i in reversed(remove_indices):
	models.pop(i)
	# print(f"load model hook: {len(models)} models will be loaded")

	accelerator.register_save_state_pre_hook(save_model_hook)
	accelerator.register_load_state_pre_hook(load_model_hook)

	# resume from local or huggingface. accelerator.step is set
	self.resume_from_local_or_hf_if_specified(accelerator, args) # accelerator.load_state(args.resume)

	# epoch数を計算する
	num_update_steps_per_epoch = math.ceil(len(train_dataloader) / args.gradient_accumulation_steps)
	num_train_epochs = math.ceil(args.max_train_steps / num_update_steps_per_epoch)

	# 学習する
	# total_batch_size = args.train_batch_size * accelerator.num_processes * args.gradient_accumulation_steps

	accelerator.print("running training / 学習開始")
	accelerator.print(f" num train items / 学習画像、動画数: {train_dataset_group.num_train_items}")
	accelerator.print(f" num batches per epoch / 1epochのバッチ数: {len(train_dataloader)}")
	accelerator.print(f" num epochs / epoch数: {num_train_epochs}")
	accelerator.print(
	f" batch size per device / バッチサイズ: {', '.join([str(d.batch_size) for d in train_dataset_group.datasets])}"
	)
	# accelerator.print(f" total train batch size (with parallel & distributed & accumulation) / 総バッチサイズ（並列学習、勾配合計含む）: {total_batch_size}")
	accelerator.print(f" gradient accumulation steps / 勾配を合計するステップ数 = {args.gradient_accumulation_steps}")
	accelerator.print(f" total optimization steps / 学習ステップ数: {args.max_train_steps}")

	# TODO refactor metadata creation and move to util
	metadata = {
	"ss_" "ss_session_id": session_id, # random integer indicating which group of epochs the model came from
	"ss_training_started_at": training_started_at, # unix timestamp
	"ss_output_name": args.output_name,
	"ss_learning_rate": args.learning_rate,
	"ss_num_train_items": train_dataset_group.num_train_items,
	"ss_num_batches_per_epoch": len(train_dataloader),
	"ss_num_epochs": num_train_epochs,
	"ss_gradient_checkpointing": args.gradient_checkpointing,
	"ss_gradient_accumulation_steps": args.gradient_accumulation_steps,
	"ss_max_train_steps": args.max_train_steps,
	"ss_lr_warmup_steps": args.lr_warmup_steps,
	"ss_lr_scheduler": args.lr_scheduler,
	SS_METADATA_KEY_BASE_MODEL_VERSION: BASE_MODEL_VERSION_HUNYUAN_VIDEO,
	# "ss_network_module": args.network_module,
	# "ss_network_dim": args.network_dim, # None means default because another network than LoRA may have another default dim
	# "ss_network_alpha": args.network_alpha, # some networks may not have alpha
	SS_METADATA_KEY_NETWORK_MODULE: args.network_module,
	SS_METADATA_KEY_NETWORK_DIM: args.network_dim,
	SS_METADATA_KEY_NETWORK_ALPHA: args.network_alpha,
	"ss_network_dropout": args.network_dropout, # some networks may not have dropout
	"ss_mixed_precision": args.mixed_precision,
	"ss_seed": args.seed,
	"ss_training_comment": args.training_comment, # will not be updated after training
	# "ss_sd_scripts_commit_hash": train_util.get_git_revision_hash(),
	"ss_optimizer": optimizer_name + (f"({optimizer_args})" if len(optimizer_args) > 0 else ""),
	"ss_max_grad_norm": args.max_grad_norm,
	"ss_fp8_base": bool(args.fp8_base),
	"ss_fp8_llm": bool(args.fp8_llm),
	"ss_full_fp16": bool(args.full_fp16),
	"ss_full_bf16": bool(args.full_bf16),
	"ss_weighting_scheme": args.weighting_scheme,
	"ss_logit_mean": args.logit_mean,
	"ss_logit_std": args.logit_std,
	"ss_mode_scale": args.mode_scale,
	"ss_guidance_scale": args.guidance_scale,
	"ss_timestep_sampling": args.timestep_sampling,
	"ss_sigmoid_scale": args.sigmoid_scale,
	"ss_discrete_flow_shift": args.discrete_flow_shift,
	}

	datasets_metadata = []
	# tag_frequency = {} # merge tag frequency for metadata editor # TODO support tag frequency
	for dataset in train_dataset_group.datasets:
	dataset_metadata = dataset.get_metadata()
	datasets_metadata.append(dataset_metadata)

	metadata["ss_datasets"] = json.dumps(datasets_metadata)

	# add extra args
	if args.network_args:
	# metadata["ss_network_args"] = json.dumps(net_kwargs)
	metadata[SS_METADATA_KEY_NETWORK_ARGS] = json.dumps(net_kwargs)

	# model name and hash
	if args.dit is not None:
	logger.info(f"calculate hash for DiT model: {args.dit}")
	sd_model_name = args.dit
	if os.path.exists(sd_model_name):
	metadata["ss_sd_model_hash"] = model_utils.model_hash(sd_model_name)
	metadata["ss_new_sd_model_hash"] = model_utils.calculate_sha256(sd_model_name)
	sd_model_name = os.path.basename(sd_model_name)
	metadata["ss_sd_model_name"] = sd_model_name

	if args.vae is not None:
	logger.info(f"calculate hash for VAE model: {args.vae}")
	vae_name = args.vae
	if os.path.exists(vae_name):
	metadata["ss_vae_hash"] = model_utils.model_hash(vae_name)
	metadata["ss_new_vae_hash"] = model_utils.calculate_sha256(vae_name)
	vae_name = os.path.basename(vae_name)
	metadata["ss_vae_name"] = vae_name

	metadata = {k: str(v) for k, v in metadata.items()}

	# make minimum metadata for filtering
	minimum_metadata = {}
	for key in SS_METADATA_MINIMUM_KEYS:
	if key in metadata:
	minimum_metadata[key] = metadata[key]

	if accelerator.is_main_process:
	init_kwargs = {}
	if args.wandb_run_name:
	init_kwargs["wandb"] = {"name": args.wandb_run_name}
	if args.log_tracker_config is not None:
	init_kwargs = toml.load(args.log_tracker_config)
	accelerator.init_trackers(
	"network_train" if args.log_tracker_name is None else args.log_tracker_name,
	config=train_utils.get_sanitized_config_or_none(args),
	init_kwargs=init_kwargs,
	)

	# TODO skip until initial step
	progress_bar = tqdm(range(args.max_train_steps), smoothing=0, disable=not accelerator.is_local_main_process, desc="steps")

	epoch_to_start = 0
	global_step = 0
	noise_scheduler = FlowMatchDiscreteScheduler(shift=args.discrete_flow_shift, reverse=True, solver="euler")

	loss_recorder = train_utils.LossRecorder()
	del train_dataset_group

	# function for saving/removing
	save_dtype = dit_dtype

	def save_model(ckpt_name: str, unwrapped_nw, steps, epoch_no, force_sync_upload=False):
	os.makedirs(args.output_dir, exist_ok=True)
	ckpt_file = os.path.join(args.output_dir, ckpt_name)

	accelerator.print(f"\nsaving checkpoint: {ckpt_file}")
	metadata["ss_training_finished_at"] = str(time.time())
	metadata["ss_steps"] = str(steps)
	metadata["ss_epoch"] = str(epoch_no)

	metadata_to_save = minimum_metadata if args.no_metadata else metadata

	title = args.metadata_title if args.metadata_title is not None else args.output_name
	if args.min_timestep is not None or args.max_timestep is not None:
	min_time_step = args.min_timestep if args.min_timestep is not None else 0
	max_time_step = args.max_timestep if args.max_timestep is not None else 1000
	md_timesteps = (min_time_step, max_time_step)
	else:
	md_timesteps = None

	sai_metadata = sai_model_spec.build_metadata(
	None,
	time.time(),
	title,
	None,
	args.metadata_author,
	args.metadata_description,
	args.metadata_license,
	args.metadata_tags,
	timesteps=md_timesteps,
	)

	metadata_to_save.update(sai_metadata)

	unwrapped_nw.save_weights(ckpt_file, save_dtype, metadata_to_save)
	if args.huggingface_repo_id is not None:
	huggingface_utils.upload(args, ckpt_file, "/" + ckpt_name, force_sync_upload=force_sync_upload)

	def remove_model(old_ckpt_name):
	old_ckpt_file = os.path.join(args.output_dir, old_ckpt_name)
	if os.path.exists(old_ckpt_file):
	accelerator.print(f"removing old checkpoint: {old_ckpt_file}")
	os.remove(old_ckpt_file)

	# For --sample_at_first
	optimizer_eval_fn()
	self.sample_images(accelerator, args, 0, global_step, accelerator.device, vae, transformer, sample_parameters)
	optimizer_train_fn()
	if len(accelerator.trackers) > 0:
	# log empty object to commit the sample images to wandb
	accelerator.log({}, step=0)

	# training loop

	# log device and dtype for each model
	logger.info(f"DiT dtype: {transformer.dtype}, device: {transformer.device}")

	clean_memory_on_device(accelerator.device)

	pos_embed_cache = {}

	for epoch in range(epoch_to_start, num_train_epochs):
	accelerator.print(f"\nepoch {epoch+1}/{num_train_epochs}")
	current_epoch.value = epoch + 1

	metadata["ss_epoch"] = str(epoch + 1)

	accelerator.unwrap_model(network).on_epoch_start(transformer)

	for step, batch in enumerate(train_dataloader):
	latents, llm_embeds, llm_mask, clip_embeds = batch
	bsz = latents.shape[0]
	current_step.value = global_step

	with accelerator.accumulate(training_model):
	accelerator.unwrap_model(network).on_step_start()

	latents = latents * vae_module.SCALING_FACTOR

	# Sample noise that we'll add to the latents
	noise = torch.randn_like(latents)

	# calculate model input and timesteps
	noisy_model_input, timesteps = self.get_noisy_model_input_and_timesteps(
	args, noise, latents, noise_scheduler, accelerator.device, dit_dtype
	)

	weighting = compute_loss_weighting_for_sd3(
	args.weighting_scheme, noise_scheduler, timesteps, accelerator.device, dit_dtype
	)

	# ensure guidance_scale in args is float
	guidance_vec = torch.full((bsz,), float(args.guidance_scale), device=accelerator.device) # , dtype=dit_dtype)

	# ensure the hidden state will require grad
	if args.gradient_checkpointing:
	noisy_model_input.requires_grad_(True)
	guidance_vec.requires_grad_(True)

	pos_emb_shape = latents.shape[1:]
	if pos_emb_shape not in pos_embed_cache:
	freqs_cos, freqs_sin = get_rotary_pos_embed_by_shape(transformer, latents.shape[2:])
	# freqs_cos = freqs_cos.to(device=accelerator.device, dtype=dit_dtype)
	# freqs_sin = freqs_sin.to(device=accelerator.device, dtype=dit_dtype)
	pos_embed_cache[pos_emb_shape] = (freqs_cos, freqs_sin)
	else:
	freqs_cos, freqs_sin = pos_embed_cache[pos_emb_shape]

	# call DiT
	latents = latents.to(device=accelerator.device, dtype=network_dtype)
	noisy_model_input = noisy_model_input.to(device=accelerator.device, dtype=network_dtype)
	# timesteps = timesteps.to(device=accelerator.device, dtype=dit_dtype)
	# llm_embeds = llm_embeds.to(device=accelerator.device, dtype=dit_dtype)
	# llm_mask = llm_mask.to(device=accelerator.device)
	# clip_embeds = clip_embeds.to(device=accelerator.device, dtype=dit_dtype)
	with accelerator.autocast():
	model_pred = transformer(
	noisy_model_input,
	timesteps,
	text_states=llm_embeds,
	text_mask=llm_mask,
	text_states_2=clip_embeds,
	freqs_cos=freqs_cos,
	freqs_sin=freqs_sin,
	guidance=guidance_vec,
	return_dict=False,
	)

	# flow matching loss
	target = noise - latents

	loss = torch.nn.functional.mse_loss(model_pred.to(network_dtype), target, reduction="none")

	if weighting is not None:
	loss = loss * weighting
	# loss = loss.mean([1, 2, 3])
	# # min snr gamma, scale v pred loss like noise pred, v pred like loss, debiased estimation etc.
	# loss = self.post_process_loss(loss, args, timesteps, noise_scheduler)

	loss = loss.mean() # 平均なのでbatch_sizeで割る必要なし

	accelerator.backward(loss)
	if accelerator.sync_gradients:
	# self.all_reduce_network(accelerator, network) # sync DDP grad manually
	state = accelerate.PartialState()
	if state.distributed_type != accelerate.DistributedType.NO:
	for param in network.parameters():
	if param.grad is not None:
	param.grad = accelerator.reduce(param.grad, reduction="mean")

	if args.max_grad_norm != 0.0:
	params_to_clip = accelerator.unwrap_model(network).get_trainable_params()
	accelerator.clip_grad_norm_(params_to_clip, args.max_grad_norm)

	optimizer.step()
	lr_scheduler.step()
	optimizer.zero_grad(set_to_none=True)

	if args.scale_weight_norms:
	keys_scaled, mean_norm, maximum_norm = accelerator.unwrap_model(network).apply_max_norm_regularization(
	args.scale_weight_norms, accelerator.device
	)
	max_mean_logs = {"Keys Scaled": keys_scaled, "Average key norm": mean_norm}
	else:
	keys_scaled, mean_norm, maximum_norm = None, None, None

	# Checks if the accelerator has performed an optimization step behind the scenes
	if accelerator.sync_gradients:
	progress_bar.update(1)
	global_step += 1

	optimizer_eval_fn()
	self.sample_images(
	accelerator, args, None, global_step, accelerator.device, vae, transformer, sample_parameters
	)

	# 指定ステップごとにモデルを保存
	if args.save_every_n_steps is not None and global_step % args.save_every_n_steps == 0:
	accelerator.wait_for_everyone()
	if accelerator.is_main_process:
	ckpt_name = train_utils.get_step_ckpt_name(args.output_name, global_step)
	save_model(ckpt_name, accelerator.unwrap_model(network), global_step, epoch)

	if args.save_state:
	train_utils.save_and_remove_state_stepwise(args, accelerator, global_step)

	remove_step_no = train_utils.get_remove_step_no(args, global_step)
	if remove_step_no is not None:
	remove_ckpt_name = train_utils.get_step_ckpt_name(args.output_name, remove_step_no)
	remove_model(remove_ckpt_name)
	optimizer_train_fn()

	current_loss = loss.detach().item()
	loss_recorder.add(epoch=epoch, step=step, loss=current_loss)
	avr_loss: float = loss_recorder.moving_average
	logs = {"avr_loss": avr_loss} # , "lr": lr_scheduler.get_last_lr()[0]}
	progress_bar.set_postfix(**logs)

	if args.scale_weight_norms:
	progress_bar.set_postfix({max_mean_logs, **logs})

	if len(accelerator.trackers) > 0:
	logs = self.generate_step_logs(
	args, current_loss, avr_loss, lr_scheduler, lr_descriptions, optimizer, keys_scaled, mean_norm, maximum_norm
	)
	accelerator.log(logs, step=global_step)

	if global_step >= args.max_train_steps:
	break

	if len(accelerator.trackers) > 0:
	logs = {"loss/epoch": loss_recorder.moving_average}
	accelerator.log(logs, step=epoch + 1)

	accelerator.wait_for_everyone()

	# 指定エポックごとにモデルを保存
	optimizer_eval_fn()
	if args.save_every_n_epochs is not None:
	saving = (epoch + 1) % args.save_every_n_epochs == 0 and (epoch + 1) < num_train_epochs
	if is_main_process and saving:
	ckpt_name = train_utils.get_epoch_ckpt_name(args.output_name, epoch + 1)
	save_model(ckpt_name, accelerator.unwrap_model(network), global_step, epoch + 1)

	remove_epoch_no = train_utils.get_remove_epoch_no(args, epoch + 1)
	if remove_epoch_no is not None:
	remove_ckpt_name = train_utils.get_epoch_ckpt_name(args.output_name, remove_epoch_no)
	remove_model(remove_ckpt_name)

	if args.save_state:
	train_utils.save_and_remove_state_on_epoch_end(args, accelerator, epoch + 1)

	self.sample_images(accelerator, args, epoch + 1, global_step, accelerator.device, vae, transformer, sample_parameters)
	optimizer_train_fn()

	# end of epoch

	# metadata["ss_epoch"] = str(num_train_epochs)
	metadata["ss_training_finished_at"] = str(time.time())

	if is_main_process:
	network = accelerator.unwrap_model(network)

	accelerator.end_training()
	optimizer_eval_fn()

	if is_main_process and (args.save_state or args.save_state_on_train_end):
	train_utils.save_state_on_train_end(args, accelerator)

	if is_main_process:
	ckpt_name = train_utils.get_last_ckpt_name(args.output_name)
	save_model(ckpt_name, network, global_step, num_train_epochs, force_sync_upload=True)

	logger.info("model saved.")


	def setup_parser() -> argparse.ArgumentParser:
	def int_or_float(value):
	if value.endswith("%"):
	try:
	return float(value[:-1]) / 100.0
	except ValueError:
	raise argparse.ArgumentTypeError(f"Value '{value}' is not a valid percentage")
	try:
	float_value = float(value)
	if float_value >= 1 and float_value.is_integer():
	return int(value)
	return float(value)
	except ValueError:
	raise argparse.ArgumentTypeError(f"'{value}' is not an int or float")

	parser = argparse.ArgumentParser()

	# general settings
	parser.add_argument(
	"--config_file",
	type=str,
	default=None,
	help="using .toml instead of args to pass hyperparameter / ハイパーパラメータを引数ではなく.tomlファイルで渡す",
	)
	parser.add_argument(
	"--dataset_config",
	type=pathlib.Path,
	default=None,
	required=True,
	help="config file for dataset / データセットの設定ファイル",
	)

	# training settings
	parser.add_argument(
	"--sdpa",
	action="store_true",
	help="use sdpa for CrossAttention (requires PyTorch 2.0) / CrossAttentionにsdpaを使う（PyTorch 2.0が必要）",
	)
	parser.add_argument(
	"--flash_attn",
	action="store_true",
	help="use FlashAttention for CrossAttention, requires FlashAttention / CrossAttentionにFlashAttentionを使う、FlashAttentionが必要",
	)
	parser.add_argument(
	"--sage_attn",
	action="store_true",
	help="use SageAttention. requires SageAttention / SageAttentionを使う。SageAttentionが必要",
	)
	parser.add_argument("--max_train_steps", type=int, default=1600, help="training steps / 学習ステップ数")
	parser.add_argument(
	"--max_train_epochs",
	type=int,
	default=None,
	help="training epochs (overrides max_train_steps) / 学習エポック数（max_train_stepsを上書きします）",
	)
	parser.add_argument(
	"--max_data_loader_n_workers",
	type=int,
	default=8,
	help="max num workers for DataLoader (lower is less main RAM usage, faster epoch start and slower data loading) / DataLoaderの最大プロセス数（小さい値ではメインメモリの使用量が減りエポック間の待ち時間が減りますが、データ読み込みは遅くなります）",
	)
	parser.add_argument(
	"--persistent_data_loader_workers",
	action="store_true",
	help="persistent DataLoader workers (useful for reduce time gap between epoch, but may use more memory) / DataLoader のワーカーを持続させる (エポック間の時間差を少なくするのに有効だが、より多くのメモリを消費する可能性がある)",
	)
	parser.add_argument("--seed", type=int, default=None, help="random seed for training / 学習時の乱数のseed")
	parser.add_argument(
	"--gradient_checkpointing", action="store_true", help="enable gradient checkpointing / gradient checkpointingを有効にする"
	)
	parser.add_argument(
	"--gradient_accumulation_steps",
	type=int,
	default=1,
	help="Number of updates steps to accumulate before performing a backward/update pass / 学習時に逆伝播をする前に勾配を合計するステップ数",
	)
	parser.add_argument(
	"--mixed_precision",
	type=str,
	default="no",
	choices=["no", "fp16", "bf16"],
	help="use mixed precision / 混合精度を使う場合、その精度",
	)

	parser.add_argument(
	"--logging_dir",
	type=str,
	default=None,
	help="enable logging and output TensorBoard log to this directory / ログ出力を有効にしてこのディレクトリにTensorBoard用のログを出力する",
	)
	parser.add_argument(
	"--log_with",
	type=str,
	default=None,
	choices=["tensorboard", "wandb", "all"],
	help="what logging tool(s) to use (if 'all', TensorBoard and WandB are both used) / ログ出力に使用するツール (allを指定するとTensorBoardとWandBの両方が使用される)",
	)
	parser.add_argument(
	"--log_prefix", type=str, default=None, help="add prefix for each log directory / ログディレクトリ名の先頭に追加する文字列"
	)
	parser.add_argument(
	"--log_tracker_name",
	type=str,
	default=None,
	help="name of tracker to use for logging, default is script-specific default name / ログ出力に使用するtrackerの名前、省略時はスクリプトごとのデフォルト名",
	)
	parser.add_argument(
	"--wandb_run_name",
	type=str,
	default=None,
	help="The name of the specific wandb session / wandb ログに表示される特定の実行の名前",
	)
	parser.add_argument(
	"--log_tracker_config",
	type=str,
	default=None,
	help="path to tracker config file to use for logging / ログ出力に使用するtrackerの設定ファイルのパス",
	)
	parser.add_argument(
	"--wandb_api_key",
	type=str,
	default=None,
	help="specify WandB API key to log in before starting training (optional). / WandB APIキーを指定して学習開始前にログインする（オプション）",
	)
	parser.add_argument("--log_config", action="store_true", help="log training configuration / 学習設定をログに出力する")

	parser.add_argument(
	"--ddp_timeout",
	type=int,
	default=None,
	help="DDP timeout (min, None for default of accelerate) / DDPのタイムアウト（分、Noneでaccelerateのデフォルト）",
	)
	parser.add_argument(
	"--ddp_gradient_as_bucket_view",
	action="store_true",
	help="enable gradient_as_bucket_view for DDP / DDPでgradient_as_bucket_viewを有効にする",
	)
	parser.add_argument(
	"--ddp_static_graph",
	action="store_true",
	help="enable static_graph for DDP / DDPでstatic_graphを有効にする",
	)

	parser.add_argument(
	"--sample_every_n_steps",
	type=int,
	default=None,
	help="generate sample images every N steps / 学習中のモデルで指定ステップごとにサンプル出力する",
	)
	parser.add_argument(
	"--sample_at_first", action="store_true", help="generate sample images before training / 学習前にサンプル出力する"
	)
	parser.add_argument(
	"--sample_every_n_epochs",
	type=int,
	default=None,
	help="generate sample images every N epochs (overwrites n_steps) / 学習中のモデルで指定エポックごとにサンプル出力する（ステップ数指定を上書きします）",
	)
	parser.add_argument(
	"--sample_prompts",
	type=str,
	default=None,
	help="file for prompts to generate sample images / 学習中モデルのサンプル出力用プロンプトのファイル",
	)

	# optimizer and lr scheduler settings
	parser.add_argument(
	"--optimizer_type",
	type=str,
	default="",
	help="Optimizer to use / オプティマイザの種類: AdamW (default), AdamW8bit, AdaFactor. "
	"Also, you can use any optimizer by specifying the full path to the class, like 'torch.optim.AdamW', 'bitsandbytes.optim.AdEMAMix8bit' or 'bitsandbytes.optim.PagedAdEMAMix8bit' etc. / ",
	)
	parser.add_argument(
	"--optimizer_args",
	type=str,
	default=None,
	nargs="*",
	help='additional arguments for optimizer (like "weight_decay=0.01 betas=0.9,0.999 ...") / オプティマイザの追加引数（例： "weight_decay=0.01 betas=0.9,0.999 ..."）',
	)
	parser.add_argument("--learning_rate", type=float, default=2.0e-6, help="learning rate / 学習率")
	parser.add_argument(
	"--max_grad_norm",
	default=1.0,
	type=float,
	help="Max gradient norm, 0 for no clipping / 勾配正規化の最大norm、0でclippingを行わない",
	)

	parser.add_argument(
	"--lr_scheduler",
	type=str,
	default="constant",
	help="scheduler to use for learning rate / 学習率のスケジューラ: linear, cosine, cosine_with_restarts, polynomial, constant (default), constant_with_warmup, adafactor",
	)
	parser.add_argument(
	"--lr_warmup_steps",
	type=int_or_float,
	default=0,
	help="Int number of steps for the warmup in the lr scheduler (default is 0) or float with ratio of train steps"
	" / 学習率のスケジューラをウォームアップするステップ数（デフォルト0）、または学習ステップの比率（1未満のfloat値の場合）",
	)
	parser.add_argument(
	"--lr_decay_steps",
	type=int_or_float,
	default=0,
	help="Int number of steps for the decay in the lr scheduler (default is 0) or float (<1) with ratio of train steps"
	" / 学習率のスケジューラを減衰させるステップ数（デフォルト0）、または学習ステップの比率（1未満のfloat値の場合）",
	)
	parser.add_argument(
	"--lr_scheduler_num_cycles",
	type=int,
	default=1,
	help="Number of restarts for cosine scheduler with restarts / cosine with restartsスケジューラでのリスタート回数",
	)
	parser.add_argument(
	"--lr_scheduler_power",
	type=float,
	default=1,
	help="Polynomial power for polynomial scheduler / polynomialスケジューラでのpolynomial power",
	)
	parser.add_argument(
	"--lr_scheduler_timescale",
	type=int,
	default=None,
	help="Inverse sqrt timescale for inverse sqrt scheduler,defaults to `num_warmup_steps`"
	+ " / 逆平方根スケジューラのタイムスケール、デフォルトは`num_warmup_steps`",
	)
	parser.add_argument(
	"--lr_scheduler_min_lr_ratio",
	type=float,
	default=None,
	help="The minimum learning rate as a ratio of the initial learning rate for cosine with min lr scheduler and warmup decay scheduler"
	+ " / 初期学習率の比率としての最小学習率を指定する、cosine with min lr と warmup decay スケジューラで有効",
	)
	parser.add_argument("--lr_scheduler_type", type=str, default="", help="custom scheduler module / 使用するスケジューラ")
	parser.add_argument(
	"--lr_scheduler_args",
	type=str,
	default=None,
	nargs="*",
	help='additional arguments for scheduler (like "T_max=100") / スケジューラの追加引数（例： "T_max100"）',
	)

	# model settings
	parser.add_argument("--dit", type=str, required=True, help="DiT checkpoint path / DiTのチェックポイントのパス")
	parser.add_argument("--dit_dtype", type=str, default=None, help="data type for DiT, default is bfloat16")
	parser.add_argument("--vae", type=str, help="VAE checkpoint path / VAEのチェックポイントのパス")
	parser.add_argument("--vae_dtype", type=str, default=None, help="data type for VAE, default is float16")
	parser.add_argument(
	"--vae_tiling",
	action="store_true",
	help="enable spatial tiling for VAE, default is False. If vae_spatial_tile_sample_min_size is set, this is automatically enabled."
	" / VAEの空間タイリングを有効にする、デフォルトはFalse。vae_spatial_tile_sample_min_sizeが設定されている場合、自動的に有効になります。",
	)
	parser.add_argument("--vae_chunk_size", type=int, default=None, help="chunk size for CausalConv3d in VAE")
	parser.add_argument(
	"--vae_spatial_tile_sample_min_size", type=int, default=None, help="spatial tile sample min size for VAE, default 256"
	)
	parser.add_argument("--text_encoder1", type=str, help="Text Encoder 1 directory / テキストエンコーダ1のディレクトリ")
	parser.add_argument("--text_encoder2", type=str, help="Text Encoder 2 directory / テキストエンコーダ2のディレクトリ")
	parser.add_argument("--text_encoder_dtype", type=str, default=None, help="data type for Text Encoder, default is float16")
	parser.add_argument("--fp8_llm", action="store_true", help="use fp8 for LLM / LLMにfp8を使う")
	parser.add_argument("--fp8_base", action="store_true", help="use fp8 for base model / base modelにfp8を使う")
	# parser.add_argument("--full_fp16", action="store_true", help="fp16 training including gradients / 勾配も含めてfp16で学習する")
	# parser.add_argument("--full_bf16", action="store_true", help="bf16 training including gradients / 勾配も含めてbf16で学習する")

	parser.add_argument(
	"--blocks_to_swap",
	type=int,
	default=None,
	help="number of blocks to swap in the model, max XXX / モデル内のブロックの数、最大XXX",
	)
	parser.add_argument(
	"--img_in_txt_in_offloading",
	action="store_true",
	help="offload img_in and txt_in to cpu / img_inとtxt_inをCPUにオフロードする",
	)

	# parser.add_argument("--flow_shift", type=float, default=7.0, help="Shift factor for flow matching schedulers")
	parser.add_argument("--guidance_scale", type=float, default=1.0, help="Embeded classifier free guidance scale.")
	parser.add_argument(
	"--timestep_sampling",
	choices=["sigma", "uniform", "sigmoid", "shift"],
	default="sigma",
	help="Method to sample timesteps: sigma-based, uniform random, sigmoid of random normal and shift of sigmoid."
	" / タイムステップをサンプリングする方法：sigma、random uniform、random normalのsigmoid、sigmoidのシフト。",
	)
	parser.add_argument(
	"--discrete_flow_shift",
	type=float,
	default=1.0,
	help="Discrete flow shift for the Euler Discrete Scheduler, default is 1.0. / Euler Discrete Schedulerの離散フローシフト、デフォルトは1.0。",
	)
	parser.add_argument(
	"--sigmoid_scale",
	type=float,
	default=1.0,
	help='Scale factor for sigmoid timestep sampling (only used when timestep-sampling is "sigmoid" or "shift"). / sigmoidタイムステップサンプリングの倍率（timestep-samplingが"sigmoid"または"shift"の場合のみ有効）。',
	)
	parser.add_argument(
	"--weighting_scheme",
	type=str,
	default="none",
	choices=["logit_normal", "mode", "cosmap", "sigma_sqrt", "none"],
	help="weighting scheme for timestep distribution. Default is none"
	" / タイムステップ分布の重み付けスキーム、デフォルトはnone",
	)
	parser.add_argument(
	"--logit_mean",
	type=float,
	default=0.0,
	help="mean to use when using the `'logit_normal'` weighting scheme / `'logit_normal'`重み付けスキームを使用する場合の平均",
	)
	parser.add_argument(
	"--logit_std",
	type=float,
	default=1.0,
	help="std to use when using the `'logit_normal'` weighting scheme / `'logit_normal'`重み付けスキームを使用する場合のstd",
	)
	parser.add_argument(
	"--mode_scale",
	type=float,
	default=1.29,
	help="Scale of mode weighting scheme. Only effective when using the `'mode'` as the `weighting_scheme` / モード重み付けスキームのスケール",
	)
	parser.add_argument(
	"--min_timestep",
	type=int,
	default=None,
	help="set minimum time step for training (0~999, default is 0) / 学習時のtime stepの最小値を設定する（0~999で指定、省略時はデフォルト値(0)） ",
	)
	parser.add_argument(
	"--max_timestep",
	type=int,
	default=None,
	help="set maximum time step for training (1~1000, default is 1000) / 学習時のtime stepの最大値を設定する（1~1000で指定、省略時はデフォルト値(1000)）",
	)

	parser.add_argument(
	"--show_timesteps",
	type=str,
	default=None,
	choices=["image", "console"],
	help="show timesteps in image or console, and return to console / タイムステップを画像またはコンソールに表示し、コンソールに戻る",
	)

	# network settings
	parser.add_argument(
	"--no_metadata", action="store_true", help="do not save metadata in output model / メタデータを出力先モデルに保存しない"
	)
	parser.add_argument(
	"--network_weights", type=str, default=None, help="pretrained weights for network / 学習するネットワークの初期重み"
	)
	parser.add_argument(
	"--network_module", type=str, default=None, help="network module to train / 学習対象のネットワークのモジュール"
	)
	parser.add_argument(
	"--network_dim",
	type=int,
	default=None,
	help="network dimensions (depends on each network) / モジュールの次元数（ネットワークにより定義は異なります）",
	)
	parser.add_argument(
	"--network_alpha",
	type=float,
	default=1,
	help="alpha for LoRA weight scaling, default 1 (same as network_dim for same behavior as old version) / LoRaの重み調整のalpha値、デフォルト1（旧バージョンと同じ動作をするにはnetwork_dimと同じ値を指定）",
	)
	parser.add_argument(
	"--network_dropout",
	type=float,
	default=None,
	help="Drops neurons out of training every step (0 or None is default behavior (no dropout), 1 would drop all neurons) / 訓練時に毎ステップでニューロンをdropする（0またはNoneはdropoutなし、1は全ニューロンをdropout）",
	)
	parser.add_argument(
	"--network_args",
	type=str,
	default=None,
	nargs="*",
	help="additional arguments for network (key=value) / ネットワークへの追加の引数",
	)
	parser.add_argument(
	"--training_comment",
	type=str,
	default=None,
	help="arbitrary comment string stored in metadata / メタデータに記録する任意のコメント文字列",
	)
	parser.add_argument(
	"--dim_from_weights",
	action="store_true",
	help="automatically determine dim (rank) from network_weights / dim (rank)をnetwork_weightsで指定した重みから自動で決定する",
	)
	parser.add_argument(
	"--scale_weight_norms",
	type=float,
	default=None,
	help="Scale the weight of each key pair to help prevent overtraing via exploding gradients. (1 is a good starting point) / 重みの値をスケーリングして勾配爆発を防ぐ（1が初期値としては適当）",
	)
	parser.add_argument(
	"--base_weights",
	type=str,
	default=None,
	nargs="*",
	help="network weights to merge into the model before training / 学習前にあらかじめモデルにマージするnetworkの重みファイル",
	)
	parser.add_argument(
	"--base_weights_multiplier",
	type=float,
	default=None,
	nargs="*",
	help="multiplier for network weights to merge into the model before training / 学習前にあらかじめモデルにマージするnetworkの重みの倍率",
	)

	# save and load settings
	parser.add_argument(
	"--output_dir", type=str, default=None, help="directory to output trained model / 学習後のモデル出力先ディレクトリ"
	)
	parser.add_argument(
	"--output_name",
	type=str,
	default=None,
	required=True,
	help="base name of trained model file / 学習後のモデルの拡張子を除くファイル名",
	)
	parser.add_argument("--resume", type=str, default=None, help="saved state to resume training / 学習再開するモデルのstate")

	parser.add_argument(
	"--save_every_n_epochs",
	type=int,
	default=None,
	help="save checkpoint every N epochs / 学習中のモデルを指定エポックごとに保存する",
	)
	parser.add_argument(
	"--save_every_n_steps",
	type=int,
	default=None,
	help="save checkpoint every N steps / 学習中のモデルを指定ステップごとに保存する",
	)
	parser.add_argument(
	"--save_last_n_epochs",
	type=int,
	default=None,
	help="save last N checkpoints when saving every N epochs (remove older checkpoints) / 指定エポックごとにモデルを保存するとき最大Nエポック保存する（古いチェックポイントは削除する）",
	)
	parser.add_argument(
	"--save_last_n_epochs_state",
	type=int,
	default=None,
	help="save last N checkpoints of state (overrides the value of --save_last_n_epochs)/ 最大Nエポックstateを保存する（--save_last_n_epochsの指定を上書きする）",
	)
	parser.add_argument(
	"--save_last_n_steps",
	type=int,
	default=None,
	help="save checkpoints until N steps elapsed (remove older checkpoints if N steps elapsed) / 指定ステップごとにモデルを保存するとき、このステップ数経過するまで保存する（このステップ数経過したら削除する）",
	)
	parser.add_argument(
	"--save_last_n_steps_state",
	type=int,
	default=None,
	help="save states until N steps elapsed (remove older states if N steps elapsed, overrides --save_last_n_steps) / 指定ステップごとにstateを保存するとき、このステップ数経過するまで保存する（このステップ数経過したら削除する。--save_last_n_stepsを上書きする）",
	)
	parser.add_argument(
	"--save_state",
	action="store_true",
	help="save training state additionally (including optimizer states etc.) when saving model / optimizerなど学習状態も含めたstateをモデル保存時に追加で保存する",
	)
	parser.add_argument(
	"--save_state_on_train_end",
	action="store_true",
	help="save training state (including optimizer states etc.) on train end even if --save_state is not specified"
	" / --save_stateが未指定時にもoptimizerなど学習状態も含めたstateを学習終了時に保存する",
	)

	# SAI Model spec
	parser.add_argument(
	"--metadata_title",
	type=str,
	default=None,
	help="title for model metadata (default is output_name) / メタデータに書き込まれるモデルタイトル、省略時はoutput_name",
	)
	parser.add_argument(
	"--metadata_author",
	type=str,
	default=None,
	help="author name for model metadata / メタデータに書き込まれるモデル作者名",
	)
	parser.add_argument(
	"--metadata_description",
	type=str,
	default=None,
	help="description for model metadata / メタデータに書き込まれるモデル説明",
	)
	parser.add_argument(
	"--metadata_license",
	type=str,
	default=None,
	help="license for model metadata / メタデータに書き込まれるモデルライセンス",
	)
	parser.add_argument(
	"--metadata_tags",
	type=str,
	default=None,
	help="tags for model metadata, separated by comma / メタデータに書き込まれるモデルタグ、カンマ区切り",
	)

	# huggingface settings
	parser.add_argument(
	"--huggingface_repo_id",
	type=str,
	default=None,
	help="huggingface repo name to upload / huggingfaceにアップロードするリポジトリ名",
	)
	parser.add_argument(
	"--huggingface_repo_type",
	type=str,
	default=None,
	help="huggingface repo type to upload / huggingfaceにアップロードするリポジトリの種類",
	)
	parser.add_argument(
	"--huggingface_path_in_repo",
	type=str,
	default=None,
	help="huggingface model path to upload files / huggingfaceにアップロードするファイルのパス",
	)
	parser.add_argument("--huggingface_token", type=str, default=None, help="huggingface token / huggingfaceのトークン")
	parser.add_argument(
	"--huggingface_repo_visibility",
	type=str,
	default=None,
	help="huggingface repository visibility ('public' for public, 'private' or None for private) / huggingfaceにアップロードするリポジトリの公開設定（'public'で公開、'private'またはNoneで非公開）",
	)
	parser.add_argument(
	"--save_state_to_huggingface", action="store_true", help="save state to huggingface / huggingfaceにstateを保存する"
	)
	parser.add_argument(
	"--resume_from_huggingface",
	action="store_true",
	help="resume from huggingface (ex: --resume {repo_id}/{path_in_repo}:{revision}:{repo_type}) / huggingfaceから学習を再開する(例: --resume {repo_id}/{path_in_repo}:{revision}:{repo_type})",
	)
	parser.add_argument(
	"--async_upload",
	action="store_true",
	help="upload to huggingface asynchronously / huggingfaceに非同期でアップロードする",
	)

	return parser


	def read_config_from_file(args: argparse.Namespace, parser: argparse.ArgumentParser):
	if not args.config_file:
	return args

	config_path = args.config_file + ".toml" if not args.config_file.endswith(".toml") else args.config_file

	if not os.path.exists(config_path):
	logger.info(f"{config_path} not found.")
	exit(1)

	logger.info(f"Loading settings from {config_path}...")
	with open(config_path, "r", encoding="utf-8") as f:
	config_dict = toml.load(f)

	# combine all sections into one
	ignore_nesting_dict = {}
	for section_name, section_dict in config_dict.items():
	# if value is not dict, save key and value as is
	if not isinstance(section_dict, dict):
	ignore_nesting_dict[section_name] = section_dict
	continue

	# if value is dict, save all key and value into one dict
	for key, value in section_dict.items():
	ignore_nesting_dict[key] = value

	config_args = argparse.Namespace(**ignore_nesting_dict)
	args = parser.parse_args(namespace=config_args)
	args.config_file = os.path.splitext(args.config_file)[0]
	logger.info(args.config_file)

	return args


	if __name__ == "__main__":
	parser = setup_parser()

	args = parser.parse_args()
	args = read_config_from_file(args, parser)

	trainer = NetworkTrainer()
	trainer.train(args)