# DreamBooth training # XXX dropped option: fine_tune import gc import time import argparse import itertools import math import os import toml from tqdm import tqdm from library.custom_train_functions import apply_snr_weight import torch from accelerate.utils import set_seed import diffusers from diffusers import DDPMScheduler import library.train_util as train_util import library.config_util as config_util from library.config_util import ( ConfigSanitizer, BlueprintGenerator, ) def collate_fn(examples): return examples[0] def train(args): train_util.verify_training_args(args) train_util.prepare_dataset_args(args, False) cache_latents = args.cache_latents if args.seed is not None: set_seed(args.seed) # 乱数系列を初期化する tokenizer = train_util.load_tokenizer(args) blueprint_generator = BlueprintGenerator(ConfigSanitizer(True, False, True)) if args.dataset_config is not None: print(f"Load dataset config from {args.dataset_config}") user_config = config_util.load_user_config(args.dataset_config) ignored = ["train_data_dir", "reg_data_dir"] if any(getattr(args, attr) is not None for attr in ignored): print( "ignore following options because config file is found: {0} / 設定ファイルが利用されるため以下のオプションは無視されます: {0}".format( ", ".join(ignored) ) ) else: user_config = { "datasets": [ {"subsets": config_util.generate_dreambooth_subsets_config_by_subdirs(args.train_data_dir, args.reg_data_dir)} ] } blueprint = blueprint_generator.generate(user_config, args, tokenizer=tokenizer) train_dataset_group = config_util.generate_dataset_group_by_blueprint(blueprint.dataset_group) if args.no_token_padding: train_dataset_group.disable_token_padding() if args.debug_dataset: train_util.debug_dataset(train_dataset_group) return if cache_latents: assert ( train_dataset_group.is_latent_cacheable() ), "when caching latents, either color_aug or random_crop cannot be used / latentをキャッシュするときはcolor_augとrandom_cropは使えません" # acceleratorを準備する print("prepare accelerator") if args.gradient_accumulation_steps > 1: print( f"gradient_accumulation_steps is {args.gradient_accumulation_steps}. accelerate does not support gradient_accumulation_steps when training multiple models (U-Net and Text Encoder), so something might be wrong" ) print( f"gradient_accumulation_stepsが{args.gradient_accumulation_steps}に設定されています。accelerateは複数モデル(U-NetおよびText Encoder)の学習時にgradient_accumulation_stepsをサポートしていないため結果は未知数です" ) accelerator, unwrap_model = train_util.prepare_accelerator(args) # mixed precisionに対応した型を用意しておき適宜castする weight_dtype, save_dtype = train_util.prepare_dtype(args) # モデルを読み込む text_encoder, vae, unet, load_stable_diffusion_format = train_util.load_target_model(args, weight_dtype) # verify load/save model formats if load_stable_diffusion_format: src_stable_diffusion_ckpt = args.pretrained_model_name_or_path src_diffusers_model_path = None else: src_stable_diffusion_ckpt = None src_diffusers_model_path = args.pretrained_model_name_or_path if args.save_model_as is None: save_stable_diffusion_format = load_stable_diffusion_format use_safetensors = args.use_safetensors else: save_stable_diffusion_format = args.save_model_as.lower() == "ckpt" or args.save_model_as.lower() == "safetensors" use_safetensors = args.use_safetensors or ("safetensors" in args.save_model_as.lower()) # モデルに xformers とか memory efficient attention を組み込む train_util.replace_unet_modules(unet, args.mem_eff_attn, args.xformers) # 学習を準備する if cache_latents: vae.to(accelerator.device, dtype=weight_dtype) vae.requires_grad_(False) vae.eval() with torch.no_grad(): train_dataset_group.cache_latents(vae, args.vae_batch_size) vae.to("cpu") if torch.cuda.is_available(): torch.cuda.empty_cache() gc.collect() # 学習を準備する:モデルを適切な状態にする train_text_encoder = args.stop_text_encoder_training is None or args.stop_text_encoder_training >= 0 unet.requires_grad_(True) # 念のため追加 text_encoder.requires_grad_(train_text_encoder) if not train_text_encoder: print("Text Encoder is not trained.") if args.gradient_checkpointing: unet.enable_gradient_checkpointing() text_encoder.gradient_checkpointing_enable() if not cache_latents: vae.requires_grad_(False) vae.eval() vae.to(accelerator.device, dtype=weight_dtype) # 学習に必要なクラスを準備する print("prepare optimizer, data loader etc.") if train_text_encoder: trainable_params = itertools.chain(unet.parameters(), text_encoder.parameters()) else: trainable_params = unet.parameters() _, _, optimizer = train_util.get_optimizer(args, trainable_params) # dataloaderを準備する # DataLoaderのプロセス数:0はメインプロセスになる n_workers = min(args.max_data_loader_n_workers, os.cpu_count() - 1) # cpu_count-1 ただし最大で指定された数まで train_dataloader = torch.utils.data.DataLoader( train_dataset_group, batch_size=1, shuffle=True, collate_fn=collate_fn, num_workers=n_workers, persistent_workers=args.persistent_data_loader_workers, ) # 学習ステップ数を計算する 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) 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}") if args.stop_text_encoder_training is None: args.stop_text_encoder_training = args.max_train_steps + 1 # do not stop until end # lr schedulerを用意する TODO gradient_accumulation_stepsの扱いが何かおかしいかもしれない。後で確認する lr_scheduler = train_util.get_scheduler_fix(args, optimizer, accelerator.num_processes) # 実験的機能:勾配も含めたfp16学習を行う モデル全体をfp16にする 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。" print("enable full fp16 training.") unet.to(weight_dtype) text_encoder.to(weight_dtype) # acceleratorがなんかよろしくやってくれるらしい if train_text_encoder: unet, text_encoder, optimizer, train_dataloader, lr_scheduler = accelerator.prepare( unet, text_encoder, optimizer, train_dataloader, lr_scheduler ) else: unet, optimizer, train_dataloader, lr_scheduler = accelerator.prepare(unet, optimizer, train_dataloader, lr_scheduler) if not train_text_encoder: text_encoder.to(accelerator.device, dtype=weight_dtype) # to avoid 'cpu' vs 'cuda' error # 実験的機能:勾配も含めたfp16学習を行う PyTorchにパッチを当ててfp16でのgrad scaleを有効にする if args.full_fp16: train_util.patch_accelerator_for_fp16_training(accelerator) # resumeする if args.resume is not None: print(f"resume training from state: {args.resume}") 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) if (args.save_n_epoch_ratio is not None) and (args.save_n_epoch_ratio > 0): args.save_every_n_epochs = math.floor(num_train_epochs / args.save_n_epoch_ratio) or 1 # 学習する total_batch_size = args.train_batch_size * accelerator.num_processes * args.gradient_accumulation_steps print("running training / 学習開始") print(f" num train images * repeats / 学習画像の数×繰り返し回数: {train_dataset_group.num_train_images}") print(f" num reg images / 正則化画像の数: {train_dataset_group.num_reg_images}") print(f" num batches per epoch / 1epochのバッチ数: {len(train_dataloader)}") print(f" num epochs / epoch数: {num_train_epochs}") print(f" batch size per device / バッチサイズ: {args.train_batch_size}") 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}") print(f" gradient ccumulation steps / 勾配を合計するステップ数 = {args.gradient_accumulation_steps}") print(f" total optimization steps / 学習ステップ数: {args.max_train_steps}") progress_bar = tqdm(range(args.max_train_steps), smoothing=0, disable=not accelerator.is_local_main_process, desc="steps") global_step = 0 noise_scheduler = DDPMScheduler( beta_start=0.00085, beta_end=0.012, beta_schedule="scaled_linear", num_train_timesteps=1000, clip_sample=False ) if accelerator.is_main_process: accelerator.init_trackers("dreambooth") loss_list = [] loss_total = 0.0 for epoch in range(num_train_epochs): print(f"epoch {epoch+1}/{num_train_epochs}") train_dataset_group.set_current_epoch(epoch + 1) # 指定したステップ数までText Encoderを学習する:epoch最初の状態 unet.train() # train==True is required to enable gradient_checkpointing if args.gradient_checkpointing or global_step < args.stop_text_encoder_training: text_encoder.train() for step, batch in enumerate(train_dataloader): # 指定したステップ数でText Encoderの学習を止める if global_step == args.stop_text_encoder_training: print(f"stop text encoder training at step {global_step}") if not args.gradient_checkpointing: text_encoder.train(False) text_encoder.requires_grad_(False) with accelerator.accumulate(unet): with torch.no_grad(): # latentに変換 if cache_latents: latents = batch["latents"].to(accelerator.device) else: latents = vae.encode(batch["images"].to(dtype=weight_dtype)).latent_dist.sample() latents = latents * 0.18215 b_size = latents.shape[0] # Sample noise that we'll add to the latents noise = torch.randn_like(latents, device=latents.device) if args.noise_offset: # https://www.crosslabs.org//blog/diffusion-with-offset-noise noise += args.noise_offset * torch.randn((latents.shape[0], latents.shape[1], 1, 1), device=latents.device) # Get the text embedding for conditioning with torch.set_grad_enabled(global_step < args.stop_text_encoder_training): input_ids = batch["input_ids"].to(accelerator.device) encoder_hidden_states = train_util.get_hidden_states( args, input_ids, tokenizer, text_encoder, None if not args.full_fp16 else weight_dtype ) # Sample a random timestep for each image timesteps = torch.randint(0, noise_scheduler.config.num_train_timesteps, (b_size,), device=latents.device) timesteps = timesteps.long() # Add noise to the latents according to the noise magnitude at each timestep # (this is the forward diffusion process) noisy_latents = noise_scheduler.add_noise(latents, noise, timesteps) # Predict the noise residual noise_pred = unet(noisy_latents, timesteps, encoder_hidden_states).sample if args.v_parameterization: # v-parameterization training target = noise_scheduler.get_velocity(latents, noise, timesteps) else: target = noise loss = torch.nn.functional.mse_loss(noise_pred.float(), target.float(), reduction="none") loss = loss.mean([1, 2, 3]) loss_weights = batch["loss_weights"] # 各sampleごとのweight loss = loss * loss_weights loss = apply_snr_weight(loss, noisy_latents, latents, args.min_snr_gamma) loss = loss.mean() # 平均なのでbatch_sizeで割る必要なし accelerator.backward(loss) if accelerator.sync_gradients and args.max_grad_norm != 0.0: if train_text_encoder: params_to_clip = itertools.chain(unet.parameters(), text_encoder.parameters()) else: params_to_clip = unet.parameters() accelerator.clip_grad_norm_(params_to_clip, args.max_grad_norm) optimizer.step() lr_scheduler.step() optimizer.zero_grad(set_to_none=True) # Checks if the accelerator has performed an optimization step behind the scenes if accelerator.sync_gradients: progress_bar.update(1) global_step += 1 train_util.sample_images( accelerator, args, None, global_step, accelerator.device, vae, tokenizer, text_encoder, unet ) current_loss = loss.detach().item() if args.logging_dir is not None: logs = {"loss": current_loss, "lr": float(lr_scheduler.get_last_lr()[0])} if args.optimizer_type.lower() == "DAdaptation".lower(): # tracking d*lr value logs["lr/d*lr"] = ( lr_scheduler.optimizers[0].param_groups[0]["d"] * lr_scheduler.optimizers[0].param_groups[0]["lr"] ) accelerator.log(logs, step=global_step) if epoch == 0: loss_list.append(current_loss) else: loss_total -= loss_list[step] loss_list[step] = current_loss loss_total += current_loss avr_loss = loss_total / len(loss_list) logs = {"loss": avr_loss} # , "lr": lr_scheduler.get_last_lr()[0]} progress_bar.set_postfix(**logs) if global_step >= args.max_train_steps: break if args.logging_dir is not None: logs = {"loss/epoch": loss_total / len(loss_list)} accelerator.log(logs, step=epoch + 1) accelerator.wait_for_everyone() if args.save_every_n_epochs is not None: src_path = src_stable_diffusion_ckpt if save_stable_diffusion_format else src_diffusers_model_path train_util.save_sd_model_on_epoch_end( args, accelerator, src_path, save_stable_diffusion_format, use_safetensors, save_dtype, epoch, num_train_epochs, global_step, unwrap_model(text_encoder), unwrap_model(unet), vae, ) train_util.sample_images(accelerator, args, epoch + 1, global_step, accelerator.device, vae, tokenizer, text_encoder, unet) is_main_process = accelerator.is_main_process if is_main_process: unet = unwrap_model(unet) text_encoder = unwrap_model(text_encoder) accelerator.end_training() if args.save_state: train_util.save_state_on_train_end(args, accelerator) del accelerator # この後メモリを使うのでこれは消す if is_main_process: src_path = src_stable_diffusion_ckpt if save_stable_diffusion_format else src_diffusers_model_path train_util.save_sd_model_on_train_end( args, src_path, save_stable_diffusion_format, use_safetensors, save_dtype, epoch, global_step, text_encoder, unet, vae ) print("model saved.") def setup_parser() -> argparse.ArgumentParser: parser = argparse.ArgumentParser() train_util.add_sd_models_arguments(parser) train_util.add_dataset_arguments(parser, True, False, True) train_util.add_training_arguments(parser, True) train_util.add_sd_saving_arguments(parser) train_util.add_optimizer_arguments(parser) config_util.add_config_arguments(parser) parser.add_argument( "--no_token_padding", action="store_true", help="disable token padding (same as Diffuser's DreamBooth) / トークンのpaddingを無効にする(Diffusers版DreamBoothと同じ動作)", ) parser.add_argument( "--stop_text_encoder_training", type=int, default=None, help="steps to stop text encoder training, -1 for no training / Text Encoderの学習を止めるステップ数、-1で最初から学習しない", ) return parser if __name__ == "__main__": parser = setup_parser() args = parser.parse_args() args = train_util.read_config_from_file(args, parser) train(args)