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flux_train_comfy.py
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flux_train_comfy.py
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# training with captions
# Swap blocks between CPU and GPU:
# This implementation is inspired by and based on the work of 2kpr.
# Many thanks to 2kpr for the original concept and implementation of memory-efficient offloading.
# The original idea has been adapted and extended to fit the current project's needs.
# Key features:
# - CPU offloading during forward and backward passes
# - Use of fused optimizer and grad_hook for efficient gradient processing
# - Per-block fused optimizer instances
import argparse
from concurrent.futures import ThreadPoolExecutor
import copy
import math
import os
from multiprocessing import Value
from typing import List
import toml
from tqdm import tqdm
import torch
from .library.device_utils import init_ipex, clean_memory_on_device
init_ipex()
from accelerate.utils import set_seed
from .library import deepspeed_utils, flux_train_utils, flux_utils, strategy_base, strategy_flux
from .library.sd3_train_utils import load_prompts, FlowMatchEulerDiscreteScheduler
from .library import train_util as train_util
from .library.utils import setup_logging, add_logging_arguments
setup_logging()
import logging
logger = logging.getLogger(__name__)
from .library import config_util as config_util
from .library.config_util import (
ConfigSanitizer,
BlueprintGenerator,
)
from .library.custom_train_functions import apply_masked_loss, add_custom_train_arguments
class FluxTrainer:
def __init__(self):
self.sample_prompts_te_outputs = None
def init_train(self, args):
train_util.verify_training_args(args)
train_util.prepare_dataset_args(args, True)
# sdxl_train_util.verify_sdxl_training_args(args)
deepspeed_utils.prepare_deepspeed_args(args)
setup_logging(args, reset=True)
# assert (
# not args.weighted_captions
# ), "weighted_captions is not supported currently / weighted_captionsは現在サポートされていません"
if args.cache_text_encoder_outputs_to_disk and not args.cache_text_encoder_outputs:
logger.warning(
"cache_text_encoder_outputs_to_disk is enabled, so cache_text_encoder_outputs is also enabled / cache_text_encoder_outputs_to_diskが有効になっているため、cache_text_encoder_outputsも有効になります"
)
args.cache_text_encoder_outputs = True
if args.cpu_offload_checkpointing and not args.gradient_checkpointing:
logger.warning(
"cpu_offload_checkpointing is enabled, so gradient_checkpointing is also enabled / cpu_offload_checkpointingが有効になっているため、gradient_checkpointingも有効になります"
)
args.gradient_checkpointing = True
cache_latents = args.cache_latents
use_dreambooth_method = args.in_json is None
if args.seed is not None:
set_seed(args.seed) # 乱数系列を初期化する
# prepare caching strategy: this must be set before preparing dataset. because dataset may use this strategy for initialization.
if args.cache_latents:
latents_caching_strategy = strategy_flux.FluxLatentsCachingStrategy(
args.cache_latents_to_disk, args.vae_batch_size, args.skip_latents_validity_check
)
strategy_base.LatentsCachingStrategy.set_strategy(latents_caching_strategy)
# データセットを準備する
if args.dataset_class is None:
blueprint_generator = BlueprintGenerator(ConfigSanitizer(True, True, args.masked_loss, True))
if args.dataset_config is not None:
logger.info(f"Load dataset config from {args.dataset_config}")
user_config = config_util.load_user_config(args.dataset_config)
ignored = ["train_data_dir", "in_json"]
if any(getattr(args, attr) is not None for attr in ignored):
logger.warning(
"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:
if use_dreambooth_method:
logger.info("Using DreamBooth method.")
user_config = {
"datasets": [
{
"subsets": config_util.generate_dreambooth_subsets_config_by_subdirs(
args.train_data_dir, args.reg_data_dir
)
}
]
}
else:
logger.info("Training with captions.")
user_config = {
"datasets": [
{
"subsets": [
{
"image_dir": args.train_data_dir,
"metadata_file": args.in_json,
}
]
}
]
}
blueprint = blueprint_generator.generate(user_config, args)
train_dataset_group = config_util.generate_dataset_group_by_blueprint(blueprint.dataset_group)
else:
train_dataset_group = train_util.load_arbitrary_dataset(args)
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 = train_util.collator_class(current_epoch, current_step, ds_for_collator)
train_dataset_group.verify_bucket_reso_steps(16) # TODO これでいいか確認
_, is_schnell, _, _ = flux_utils.analyze_checkpoint_state(args.pretrained_model_name_or_path)
if args.debug_dataset:
if args.cache_text_encoder_outputs:
strategy_base.TextEncoderOutputsCachingStrategy.set_strategy(
strategy_flux.FluxTextEncoderOutputsCachingStrategy(
args.cache_text_encoder_outputs_to_disk, args.text_encoder_batch_size, False, False
)
)
t5xxl_max_token_length = (
args.t5xxl_max_token_length if args.t5xxl_max_token_length is not None else (256 if is_schnell else 512)
)
strategy_base.TokenizeStrategy.set_strategy(strategy_flux.FluxTokenizeStrategy(t5xxl_max_token_length))
train_dataset_group.set_current_strategies()
train_util.debug_dataset(train_dataset_group, True)
return
if len(train_dataset_group) == 0:
logger.error(
"No data found. Please verify the metadata file and train_data_dir option. / 画像がありません。メタデータおよびtrain_data_dirオプションを確認してください。"
)
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"
if args.cache_text_encoder_outputs:
assert (
train_dataset_group.is_text_encoder_output_cacheable()
), "when caching text encoder output, either caption_dropout_rate, shuffle_caption, token_warmup_step or caption_tag_dropout_rate cannot be used / text encoderの出力をキャッシュするときはcaption_dropout_rate, shuffle_caption, token_warmup_step, caption_tag_dropout_rateは使えません"
# acceleratorを準備する
logger.info("prepare accelerator")
accelerator = 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
# load VAE for caching latents
ae = None
if cache_latents:
ae = flux_utils.load_ae(args.ae, weight_dtype, "cpu", args.disable_mmap_load_safetensors)
ae.to(accelerator.device, dtype=weight_dtype)
ae.requires_grad_(False)
ae.eval()
train_dataset_group.new_cache_latents(ae, accelerator)
ae.to("cpu") # if no sampling, vae can be deleted
clean_memory_on_device(accelerator.device)
accelerator.wait_for_everyone()
# prepare tokenize strategy
if args.t5xxl_max_token_length is None:
if is_schnell:
t5xxl_max_token_length = 256
else:
t5xxl_max_token_length = 512
else:
t5xxl_max_token_length = args.t5xxl_max_token_length
flux_tokenize_strategy = strategy_flux.FluxTokenizeStrategy(t5xxl_max_token_length)
strategy_base.TokenizeStrategy.set_strategy(flux_tokenize_strategy)
# load clip_l, t5xxl for caching text encoder outputs
clip_l = flux_utils.load_clip_l(args.clip_l, weight_dtype, "cpu", args.disable_mmap_load_safetensors)
t5xxl = flux_utils.load_t5xxl(args.t5xxl, weight_dtype, "cpu", args.disable_mmap_load_safetensors)
clip_l.eval()
t5xxl.eval()
clip_l.requires_grad_(False)
t5xxl.requires_grad_(False)
text_encoding_strategy = strategy_flux.FluxTextEncodingStrategy(args.apply_t5_attn_mask)
strategy_base.TextEncodingStrategy.set_strategy(text_encoding_strategy)
# cache text encoder outputs
sample_prompts_te_outputs = None
if args.cache_text_encoder_outputs:
# Text Encodes are eval and no grad here
clip_l.to(accelerator.device)
t5xxl.to(accelerator.device)
text_encoder_caching_strategy = strategy_flux.FluxTextEncoderOutputsCachingStrategy(
args.cache_text_encoder_outputs_to_disk, args.text_encoder_batch_size, False, False, args.apply_t5_attn_mask
)
strategy_base.TextEncoderOutputsCachingStrategy.set_strategy(text_encoder_caching_strategy)
with accelerator.autocast():
train_dataset_group.new_cache_text_encoder_outputs([clip_l, t5xxl], accelerator.is_main_process)
# cache sample prompt's embeddings to free text encoder's memory
if args.sample_prompts is not None:
logger.info(f"cache Text Encoder outputs for sample prompt: {args.sample_prompts}")
text_encoding_strategy: strategy_flux.FluxTextEncodingStrategy = strategy_base.TextEncodingStrategy.get_strategy()
prompts = []
for line in args.sample_prompts:
line = line.strip()
if len(line) > 0 and line[0] != "#":
prompts.append(line)
# preprocess prompts
for i in range(len(prompts)):
prompt_dict = prompts[i]
if isinstance(prompt_dict, str):
from .library.train_util import line_to_prompt_dict
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)
sample_prompts_te_outputs = {} # key: prompt, value: text encoder outputs
with accelerator.autocast(), torch.no_grad():
for prompt_dict in prompts:
for p in [prompt_dict.get("prompt", ""), prompt_dict.get("negative_prompt", "")]:
if p not in sample_prompts_te_outputs:
logger.info(f"cache Text Encoder outputs for prompt: {p}")
tokens_and_masks = flux_tokenize_strategy.tokenize(p)
sample_prompts_te_outputs[p] = text_encoding_strategy.encode_tokens(
flux_tokenize_strategy, [clip_l, t5xxl], tokens_and_masks, args.apply_t5_attn_mask
)
self.sample_prompts_te_outputs = sample_prompts_te_outputs
accelerator.wait_for_everyone()
# now we can delete Text Encoders to free memory
clip_l = None
t5xxl = None
clean_memory_on_device(accelerator.device)
# load FLUX
_, flux = flux_utils.load_flow_model(
args.pretrained_model_name_or_path, weight_dtype, "cpu", args.disable_mmap_load_safetensors
)
if args.gradient_checkpointing:
flux.enable_gradient_checkpointing(cpu_offload=args.cpu_offload_checkpointing)
flux.requires_grad_(True)
# block swap
# backward compatibility
if args.blocks_to_swap is None:
blocks_to_swap = args.double_blocks_to_swap or 0
if args.single_blocks_to_swap is not None:
blocks_to_swap += args.single_blocks_to_swap // 2
if blocks_to_swap > 0:
logger.warning(
"double_blocks_to_swap and single_blocks_to_swap are deprecated. Use blocks_to_swap instead."
" / double_blocks_to_swapとsingle_blocks_to_swapは非推奨です。blocks_to_swapを使ってください。"
)
logger.info(
f"double_blocks_to_swap={args.double_blocks_to_swap} and single_blocks_to_swap={args.single_blocks_to_swap} are converted to blocks_to_swap={blocks_to_swap}."
)
args.blocks_to_swap = blocks_to_swap
del blocks_to_swap
is_swapping_blocks = args.blocks_to_swap is not None and args.blocks_to_swap > 0
if is_swapping_blocks:
# Swap blocks between CPU and GPU to reduce memory usage, in forward and backward passes.
# This idea is based on 2kpr's great work. Thank you!
logger.info(f"enable block swap: blocks_to_swap={args.blocks_to_swap}")
flux.enable_block_swap(args.blocks_to_swap)
if not cache_latents:
# load VAE here if not cached
ae = flux_utils.load_ae(args.ae, weight_dtype, "cpu")
ae.requires_grad_(False)
ae.eval()
ae.to(accelerator.device, dtype=weight_dtype)
training_models = []
params_to_optimize = []
training_models.append(flux)
name_and_params = list(flux.named_parameters())
# single param group for now
params_to_optimize.append({"params": [p for _, p in name_and_params], "lr": args.learning_rate})
param_names = [[n for n, _ in name_and_params]]
# calculate number of trainable parameters
n_params = 0
for group in params_to_optimize:
for p in group["params"]:
n_params += p.numel()
accelerator.print(f"number of trainable parameters: {n_params}")
# 学習に必要なクラスを準備する
accelerator.print("prepare optimizer, data loader etc.")
if args.blockwise_fused_optimizers:
# fused backward pass: https://pytorch.org/tutorials/intermediate/optimizer_step_in_backward_tutorial.html
# Instead of creating an optimizer for all parameters as in the tutorial, we create an optimizer for each block of parameters.
# This balances memory usage and management complexity.
# split params into groups. currently different learning rates are not supported
grouped_params = []
param_group = {}
for group in params_to_optimize:
named_parameters = list(flux.named_parameters())
assert len(named_parameters) == len(group["params"]), "number of parameters does not match"
for p, np in zip(group["params"], named_parameters):
# determine target layer and block index for each parameter
block_type = "other" # double, single or other
if np[0].startswith("double_blocks"):
block_idx = int(np[0].split(".")[1])
block_type = "double"
elif np[0].startswith("single_blocks"):
block_idx = int(np[0].split(".")[1])
block_type = "single"
else:
block_idx = -1
param_group_key = (block_type, block_idx)
if param_group_key not in param_group:
param_group[param_group_key] = []
param_group[param_group_key].append(p)
block_types_and_indices = []
for param_group_key, param_group in param_group.items():
block_types_and_indices.append(param_group_key)
grouped_params.append({"params": param_group, "lr": args.learning_rate})
num_params = 0
for p in param_group:
num_params += p.numel()
accelerator.print(f"block {param_group_key}: {num_params} parameters")
# prepare optimizers for each group
optimizers = []
for group in grouped_params:
_, _, optimizer = train_util.get_optimizer(args, trainable_params=[group])
optimizers.append(optimizer)
optimizer = optimizers[0] # avoid error in the following code
logger.info(f"using {len(optimizers)} optimizers for blockwise fused optimizers")
if train_util.is_schedulefree_optimizer(optimizers[0], args):
raise ValueError("Schedule-free optimizer is not supported with blockwise fused optimizers")
self.optimizer_train_fn = lambda: None # dummy function
self.optimizer_eval_fn = lambda: None # dummy function
else:
_, _, optimizer = train_util.get_optimizer(args, trainable_params=params_to_optimize)
self.optimizer_train_fn, self.optimizer_eval_fn = train_util.get_optimizer_train_eval_fn(optimizer, args)
# prepare dataloader
# strategies are set here because they cannot be referenced in another process. Copy them with the dataset
# some strategies can be None
train_dataset_group.set_current_strategies()
# DataLoaderのプロセス数:0 は persistent_workers が使えないので注意
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,
)
# 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
)
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}"
)
# データセット側にも学習ステップを送信
train_dataset_group.set_max_train_steps(args.max_train_steps)
# lr schedulerを用意する
if args.blockwise_fused_optimizers:
# prepare lr schedulers for each optimizer
lr_schedulers = [train_util.get_scheduler_fix(args, optimizer, accelerator.num_processes) for optimizer in optimizers]
lr_scheduler = lr_schedulers[0] # avoid error in the following code
else:
lr_scheduler = train_util.get_scheduler_fix(args, optimizer, accelerator.num_processes)
# 実験的機能:勾配も含めたfp16/bf16学習を行う モデル全体をfp16/bf16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。"
accelerator.print("enable full fp16 training.")
flux.to(weight_dtype)
if clip_l is not None:
clip_l.to(weight_dtype)
t5xxl.to(weight_dtype) # TODO check works with fp16 or not
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.")
flux.to(weight_dtype)
if clip_l is not None:
clip_l.to(weight_dtype)
t5xxl.to(weight_dtype)
# if we don't cache text encoder outputs, move them to device
if not args.cache_text_encoder_outputs:
clip_l.to(accelerator.device)
t5xxl.to(accelerator.device)
clean_memory_on_device(accelerator.device)
if args.deepspeed:
ds_model = deepspeed_utils.prepare_deepspeed_model(args, mmdit=flux)
# most of ZeRO stage uses optimizer partitioning, so we have to prepare optimizer and ds_model at the same time. # pull/1139#issuecomment-1986790007
ds_model, optimizer, train_dataloader, lr_scheduler = accelerator.prepare(
ds_model, optimizer, train_dataloader, lr_scheduler
)
training_models = [ds_model]
else:
# accelerator does some magic
# if we doesn't swap blocks, we can move the model to device
flux = accelerator.prepare(flux, device_placement=[not is_swapping_blocks])
if is_swapping_blocks:
accelerator.unwrap_model(flux).move_to_device_except_swap_blocks(accelerator.device) # reduce peak memory usage
optimizer, train_dataloader, lr_scheduler = accelerator.prepare(optimizer, train_dataloader, lr_scheduler)
# 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:
# During deepseed training, accelerate not handles fp16/bf16|mixed precision directly via scaler. Let deepspeed engine do.
# -> But we think it's ok to patch accelerator even if deepspeed is enabled.
train_util.patch_accelerator_for_fp16_training(accelerator)
# resumeする
train_util.resume_from_local_or_hf_if_specified(accelerator, args)
# memory efficient block swapping
def get_block_unit(dbl_blocks, sgl_blocks, index: int):
if index < len(dbl_blocks):
return (dbl_blocks[index],)
else:
index -= len(dbl_blocks)
index *= 2
return (sgl_blocks[index], sgl_blocks[index + 1])
def submit_move_blocks(futures, thread_pool, block_idx_to_cpu, block_idx_to_cuda, dbl_blocks, sgl_blocks, device):
def move_blocks(bidx_to_cpu, blocks_to_cpu, bidx_to_cuda, blocks_to_cuda, dvc):
# print(f"Backward: Move block {bidx_to_cpu} to CPU")
for block in blocks_to_cpu:
block = block.to("cpu", non_blocking=True)
torch.cuda.empty_cache()
# print(f"Backward: Move block {bidx_to_cuda} to CUDA")
for block in blocks_to_cuda:
block = block.to(dvc, non_blocking=True)
torch.cuda.synchronize()
# print(f"Backward: Moved blocks {bidx_to_cpu} and {bidx_to_cuda}")
return bidx_to_cpu, bidx_to_cuda
blocks_to_cpu = get_block_unit(dbl_blocks, sgl_blocks, block_idx_to_cpu)
blocks_to_cuda = get_block_unit(dbl_blocks, sgl_blocks, block_idx_to_cuda)
futures[block_idx_to_cuda] = thread_pool.submit(
move_blocks, block_idx_to_cpu, blocks_to_cpu, block_idx_to_cuda, blocks_to_cuda, device
)
def wait_blocks_move(block_idx, futures):
if block_idx not in futures:
return
# print(f"Backward: Wait for block {block_idx}")
# start_time = time.perf_counter()
future = futures.pop(block_idx)
future.result()
# print(f"Backward: Waited for block {block_idx}: {time.perf_counter()-start_time:.2f}s")
# torch.cuda.synchronize()
# print(f"Backward: Synchronized: {time.perf_counter()-start_time:.2f}s")
if args.fused_backward_pass:
# use fused optimizer for backward pass: other optimizers will be supported in the future
from .library import adafactor_fused
adafactor_fused.patch_adafactor_fused(optimizer)
blocks_to_swap = args.blocks_to_swap
num_double_blocks = len(accelerator.unwrap_model(flux).double_blocks)
num_single_blocks = len(accelerator.unwrap_model(flux).single_blocks)
num_block_units = num_double_blocks + num_single_blocks // 2
handled_unit_indices = set()
n = 1 # only asynchronous purpose, no need to increase this number
# n = 2
# n = max(1, os.cpu_count() // 2)
thread_pool = ThreadPoolExecutor(max_workers=n)
futures = {}
for param_group, param_name_group in zip(optimizer.param_groups, param_names):
for parameter, param_name in zip(param_group["params"], param_name_group):
if parameter.requires_grad:
grad_hook = None
if blocks_to_swap:
is_double = param_name.startswith("double_blocks")
is_single = param_name.startswith("single_blocks")
if is_double or is_single:
block_idx = int(param_name.split(".")[1])
unit_idx = block_idx if is_double else num_double_blocks + block_idx // 2
if unit_idx not in handled_unit_indices:
# swap following (already backpropagated) block
handled_unit_indices.add(unit_idx)
# if n blocks were already backpropagated
num_blocks_propagated = num_block_units - unit_idx - 1
swapping = num_blocks_propagated > 0 and num_blocks_propagated <= blocks_to_swap
waiting = unit_idx > 0 and unit_idx <= blocks_to_swap
if swapping or waiting:
block_idx_to_cpu = num_block_units - num_blocks_propagated
block_idx_to_cuda = blocks_to_swap - num_blocks_propagated
block_idx_to_wait = unit_idx - 1
# create swap hook
def create_swap_grad_hook(
bidx_to_cpu, bidx_to_cuda, bidx_to_wait, uidx: int, swpng: bool, wtng: bool
):
def __grad_hook(tensor: torch.Tensor):
if accelerator.sync_gradients and args.max_grad_norm != 0.0:
accelerator.clip_grad_norm_(tensor, args.max_grad_norm)
optimizer.step_param(tensor, param_group)
tensor.grad = None
# print(f"Backward: {uidx}, {swpng}, {wtng}")
if swpng:
submit_move_blocks(
futures,
thread_pool,
bidx_to_cpu,
bidx_to_cuda,
flux.double_blocks,
flux.single_blocks,
accelerator.device,
)
if wtng:
wait_blocks_move(bidx_to_wait, futures)
return __grad_hook
grad_hook = create_swap_grad_hook(
block_idx_to_cpu, block_idx_to_cuda, block_idx_to_wait, unit_idx, swapping, waiting
)
if grad_hook is None:
def __grad_hook(tensor: torch.Tensor, param_group=param_group):
if accelerator.sync_gradients and args.max_grad_norm != 0.0:
accelerator.clip_grad_norm_(tensor, args.max_grad_norm)
optimizer.step_param(tensor, param_group)
tensor.grad = None
grad_hook = __grad_hook
parameter.register_post_accumulate_grad_hook(grad_hook)
elif args.blockwise_fused_optimizers:
# prepare for additional optimizers and lr schedulers
for i in range(1, len(optimizers)):
optimizers[i] = accelerator.prepare(optimizers[i])
lr_schedulers[i] = accelerator.prepare(lr_schedulers[i])
# counters are used to determine when to step the optimizer
global optimizer_hooked_count
global num_parameters_per_group
global parameter_optimizer_map
optimizer_hooked_count = {}
num_parameters_per_group = [0] * len(optimizers)
parameter_optimizer_map = {}
blocks_to_swap = args.blocks_to_swap
num_double_blocks = len(accelerator.unwrap_model(flux).double_blocks)
num_single_blocks = len(accelerator.unwrap_model(flux).single_blocks)
num_block_units = num_double_blocks + num_single_blocks // 2
n = 1 # only asynchronous purpose, no need to increase this number
# n = max(1, os.cpu_count() // 2)
thread_pool = ThreadPoolExecutor(max_workers=n)
futures = {}
for opt_idx, optimizer in enumerate(optimizers):
for param_group in optimizer.param_groups:
for parameter in param_group["params"]:
if parameter.requires_grad:
block_type, block_idx = block_types_and_indices[opt_idx]
def create_optimizer_hook(btype, bidx):
def optimizer_hook(parameter: torch.Tensor):
# print(f"optimizer_hook: {btype}, {bidx}")
if accelerator.sync_gradients and args.max_grad_norm != 0.0:
accelerator.clip_grad_norm_(parameter, args.max_grad_norm)
i = parameter_optimizer_map[parameter]
optimizer_hooked_count[i] += 1
if optimizer_hooked_count[i] == num_parameters_per_group[i]:
optimizers[i].step()
optimizers[i].zero_grad(set_to_none=True)
# swap blocks if necessary
if blocks_to_swap and (btype == "double" or (btype == "single" and bidx % 2 == 0)):
unit_idx = bidx if btype == "double" else num_double_blocks + bidx // 2
num_blocks_propagated = num_block_units - unit_idx
swapping = num_blocks_propagated > 0 and num_blocks_propagated <= blocks_to_swap
waiting = unit_idx > 0 and unit_idx <= blocks_to_swap
if swapping:
block_idx_to_cpu = num_block_units - num_blocks_propagated
block_idx_to_cuda = blocks_to_swap - num_blocks_propagated
# print(f"Backward: Swap blocks {block_idx_to_cpu} and {block_idx_to_cuda}")
submit_move_blocks(
futures,
thread_pool,
block_idx_to_cpu,
block_idx_to_cuda,
flux.double_blocks,
flux.single_blocks,
accelerator.device,
)
if waiting:
block_idx_to_wait = unit_idx - 1
wait_blocks_move(block_idx_to_wait, futures)
return optimizer_hook
parameter.register_post_accumulate_grad_hook(create_optimizer_hook(block_type, block_idx))
parameter_optimizer_map[parameter] = opt_idx
num_parameters_per_group[opt_idx] += 1
# 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
accelerator.print("running training / 学習開始")
accelerator.print(f" num examples / サンプル数: {train_dataset_group.num_train_images}")
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}")
progress_bar = tqdm(range(args.max_train_steps), smoothing=0, disable=not accelerator.is_local_main_process, desc="steps")
self.global_step = 0
noise_scheduler = FlowMatchEulerDiscreteScheduler(num_train_timesteps=1000, shift=args.discrete_flow_shift)
noise_scheduler_copy = copy.deepcopy(noise_scheduler)
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(
"finetuning" if args.log_tracker_name is None else args.log_tracker_name,
config=train_util.get_sanitized_config_or_none(args),
init_kwargs=init_kwargs,
)
if is_swapping_blocks:
accelerator.unwrap_model(flux).prepare_block_swap_before_forward()
# For --sample_at_first
#flux_train_utils.sample_images(accelerator, args, 0, global_step, flux, ae, [clip_l, t5xxl], sample_prompts_te_outputs)
loss_recorder = train_util.LossRecorder()
epoch = 0 # avoid error when max_train_steps is 0
self.tokens_and_masks = tokens_and_masks
self.num_train_epochs = num_train_epochs
self.current_epoch = current_epoch
self.args = args
self.accelerator = accelerator
self.unet = flux
self.vae = ae
self.text_encoder = [clip_l, t5xxl]
self.loss_recorder = loss_recorder
self.save_dtype = save_dtype
def training_loop(break_at_steps, epoch):
global optimizer_hooked_count
steps_done = 0
#accelerator.print(f"\nepoch {epoch+1}/{num_train_epochs}")
progress_bar.set_description(f"Epoch {epoch + 1}/{num_train_epochs} - steps")
current_epoch.value = epoch + 1
for m in training_models:
m.train()
for step, batch in enumerate(train_dataloader):
current_step.value = self.global_step
if args.blockwise_fused_optimizers:
optimizer_hooked_count = {i: 0 for i in range(len(optimizers))} # reset counter for each step
with accelerator.accumulate(*training_models):
if "latents" in batch and batch["latents"] is not None:
latents = batch["latents"].to(accelerator.device, dtype=weight_dtype)
else:
with torch.no_grad():
# encode images to latents. images are [-1, 1]
latents = ae.encode(batch["images"].to(ae.dtype)).to(accelerator.device, dtype=weight_dtype)
# NaNが含まれていれば警告を表示し0に置き換える
if torch.any(torch.isnan(latents)):
accelerator.print("NaN found in latents, replacing with zeros")
latents = torch.nan_to_num(latents, 0, out=latents)
text_encoder_outputs_list = batch.get("text_encoder_outputs_list", None)
if text_encoder_outputs_list is not None:
text_encoder_conds = text_encoder_outputs_list
else:
# not cached or training, so get from text encoders
tokens_and_masks = batch["input_ids_list"]
with torch.no_grad():
input_ids = [ids.to(accelerator.device) for ids in batch["input_ids_list"]]
text_encoder_conds = text_encoding_strategy.encode_tokens(
flux_tokenize_strategy, [clip_l, t5xxl], input_ids, args.apply_t5_attn_mask
)
if args.full_fp16:
text_encoder_conds = [c.to(weight_dtype) for c in text_encoder_conds]
# TODO support some features for noise implemented in get_noise_noisy_latents_and_timesteps
# Sample noise that we'll add to the latents
noise = torch.randn_like(latents)
bsz = latents.shape[0]
# get noisy model input and timesteps
noisy_model_input, timesteps, sigmas = flux_train_utils.get_noisy_model_input_and_timesteps(
args, noise_scheduler_copy, latents, noise, accelerator.device, weight_dtype
)
# pack latents and get img_ids
packed_noisy_model_input = flux_utils.pack_latents(noisy_model_input) # b, c, h*2, w*2 -> b, h*w, c*4
packed_latent_height, packed_latent_width = noisy_model_input.shape[2] // 2, noisy_model_input.shape[3] // 2
img_ids = flux_utils.prepare_img_ids(bsz, packed_latent_height, packed_latent_width).to(device=accelerator.device)
# get guidance: ensure args.guidance_scale is float
guidance_vec = torch.full((bsz,), float(args.guidance_scale), device=accelerator.device)
# call model
l_pooled, t5_out, txt_ids, t5_attn_mask = text_encoder_conds
if not args.apply_t5_attn_mask:
t5_attn_mask = None
with accelerator.autocast():
# YiYi notes: divide it by 1000 for now because we scale it by 1000 in the transformer model (we should not keep it but I want to keep the inputs same for the model for testing)
model_pred = flux(
img=packed_noisy_model_input,
img_ids=img_ids,
txt=t5_out,
txt_ids=txt_ids,
y=l_pooled,
timesteps=timesteps / 1000,
guidance=guidance_vec,
txt_attention_mask=t5_attn_mask,
)
# unpack latents
model_pred = flux_utils.unpack_latents(model_pred, packed_latent_height, packed_latent_width)
# apply model prediction type
model_pred, weighting = flux_train_utils.apply_model_prediction_type(args, model_pred, noisy_model_input, sigmas)
# flow matching loss: this is different from SD3
target = noise - latents
# calculate loss
loss = train_util.conditional_loss(
model_pred.float(), target.float(), reduction="none", loss_type=args.loss_type, huber_c=None
)
if weighting is not None:
loss = loss * weighting
if args.masked_loss or ("alpha_masks" in batch and batch["alpha_masks"] is not None):
loss = apply_masked_loss(loss, batch)
loss = loss.mean([1, 2, 3])
loss_weights = batch["loss_weights"] # 各sampleごとのweight
loss = loss * loss_weights
loss = loss.mean()
# backward
accelerator.backward(loss)
if not (args.fused_backward_pass or args.blockwise_fused_optimizers):
if accelerator.sync_gradients and args.max_grad_norm != 0.0:
params_to_clip = []
for m in training_models:
params_to_clip.extend(m.parameters())
accelerator.clip_grad_norm_(params_to_clip, args.max_grad_norm)
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad(set_to_none=True)
else:
# optimizer.step() and optimizer.zero_grad() are called in the optimizer hook
lr_scheduler.step()
if args.blockwise_fused_optimizers:
for i in range(1, len(optimizers)):
lr_schedulers[i].step()
# Checks if the accelerator has performed an optimization step behind the scenes
if accelerator.sync_gradients:
progress_bar.update(1)
self.global_step += 1
# flux_train_utils.sample_images(
# accelerator, args, None, global_step, flux, ae, [clip_l, t5xxl], sample_prompts_te_outputs
# )
# # 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:
# flux_train_utils.save_flux_model_on_epoch_end_or_stepwise(
# args,
# False,
# accelerator,
# save_dtype,
# epoch,
# num_train_epochs,
# global_step,
# accelerator.unwrap_model(flux),
# )
current_loss = loss.detach().item() # 平均なのでbatch sizeは関係ないはず
if args.logging_dir is not None:
logs = {"loss": current_loss}
train_util.append_lr_to_logs(logs, lr_scheduler, args.optimizer_type, including_unet=True)
accelerator.log(logs, step=self.global_step)
loss_recorder.add(epoch=epoch, step=step, loss=current_loss, global_step=self.global_step)
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 self.global_step >= break_at_steps:
break
steps_done += 1
if args.logging_dir is not None:
logs = {"loss/epoch": loss_recorder.moving_average}
accelerator.log(logs, step=epoch + 1)
return steps_done
return training_loop
#accelerator.wait_for_everyone()
# if args.save_every_n_epochs is not None:
# if accelerator.is_main_process:
# flux_train_utils.save_flux_model_on_epoch_end_or_stepwise(
# args,
# True,
# accelerator,
# save_dtype,
# epoch,
# num_train_epochs,
# global_step,
# accelerator.unwrap_model(flux),
# )
# flux_train_utils.sample_images(
# accelerator, args, epoch + 1, global_step, flux, ae, [clip_l, t5xxl], sample_prompts_te_outputs
# )
# is_main_process = accelerator.is_main_process
# # if is_main_process:
# flux = accelerator.unwrap_model(flux)
# accelerator.end_training()
# if args.save_state or args.save_state_on_train_end:
# 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:
# flux_train_utils.save_flux_model_on_train_end(args, save_dtype, epoch, global_step, flux)
# logger.info("model saved.")
def sample_images(self, accelerator, args, epoch, global_step, flux, ae, text_encoder, sample_prompts_te_outputs, validation_settings):
image_tensors = flux_train_utils.sample_images(
accelerator, args, epoch, global_step, flux, ae, text_encoder, sample_prompts_te_outputs, validation_settings)
clean_memory_on_device(accelerator.device)
return image_tensors
def setup_parser() -> argparse.ArgumentParser:
parser = argparse.ArgumentParser()
add_logging_arguments(parser)
train_util.add_sd_models_arguments(parser) # TODO split this
train_util.add_dataset_arguments(parser, True, True, True)
train_util.add_training_arguments(parser, False)
train_util.add_masked_loss_arguments(parser)
deepspeed_utils.add_deepspeed_arguments(parser)
train_util.add_sd_saving_arguments(parser)
train_util.add_optimizer_arguments(parser)
config_util.add_config_arguments(parser)
add_custom_train_arguments(parser) # TODO remove this from here
flux_train_utils.add_flux_train_arguments(parser)
parser.add_argument(
"--mem_eff_save",
action="store_true",
help="[EXPERIMENTAL] use memory efficient custom model saving method / メモリ効率の良い独自のモデル保存方法を使う",
)
parser.add_argument(
"--fused_optimizer_groups",
type=int,
default=None,
help="**this option is not working** will be removed in the future / このオプションは動作しません。将来削除されます",
)
parser.add_argument(
"--blockwise_fused_optimizers",
action="store_true",
help="enable blockwise optimizers for fused backward pass and optimizer step / fused backward passとoptimizer step のためブロック単位のoptimizerを有効にする",
)
parser.add_argument(
"--skip_latents_validity_check",
action="store_true",
help="skip latents validity check / latentsの正当性チェックをスキップする",
)
parser.add_argument(
"--cpu_offload_checkpointing",
action="store_true",
help="[EXPERIMENTAL] enable offloading of tensors to CPU during checkpointing / チェックポイント時にテンソルをCPUにオフロードする",
)
return parser