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ACE-Step / pipeline_ace_step.py

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	import random
	import time
	import os
	import re
	import spaces
	import torch
	import torch.nn as nn
	from loguru import logger
	from tqdm import tqdm
	import json
	import math
	from huggingface_hub import hf_hub_download, snapshot_download

	# from diffusers.pipelines.pipeline_utils import DiffusionPipeline
	from schedulers.scheduling_flow_match_euler_discrete import (
	FlowMatchEulerDiscreteScheduler,
	)
	from schedulers.scheduling_flow_match_heun_discrete import (
	FlowMatchHeunDiscreteScheduler,
	)
	from diffusers.pipelines.stable_diffusion_3.pipeline_stable_diffusion_3 import (
	retrieve_timesteps,
	)
	from diffusers.utils.torch_utils import randn_tensor
	from transformers import UMT5EncoderModel, AutoTokenizer

	from language_segmentation import LangSegment
	from music_dcae.music_dcae_pipeline import MusicDCAE
	from models.ace_step_transformer import ACEStepTransformer2DModel
	from models.lyrics_utils.lyric_tokenizer import VoiceBpeTokenizer
	from apg_guidance import (
	apg_forward,
	MomentumBuffer,
	cfg_forward,
	cfg_zero_star,
	cfg_double_condition_forward,
	)
	import torchaudio
	import torio


	torch.backends.cudnn.benchmark = False
	torch.set_float32_matmul_precision("high")
	torch.backends.cudnn.deterministic = True
	torch.backends.cuda.matmul.allow_tf32 = True
	os.environ["TOKENIZERS_PARALLELISM"] = "false"


	SUPPORT_LANGUAGES = {
	"en": 259,
	"de": 260,
	"fr": 262,
	"es": 284,
	"it": 285,
	"pt": 286,
	"pl": 294,
	"tr": 295,
	"ru": 267,
	"cs": 293,
	"nl": 297,
	"ar": 5022,
	"zh": 5023,
	"ja": 5412,
	"hu": 5753,
	"ko": 6152,
	"hi": 6680,
	}

	structure_pattern = re.compile(r"\[.*?\]")


	def ensure_directory_exists(directory):
	directory = str(directory)
	if not os.path.exists(directory):
	os.makedirs(directory)


	REPO_ID = "ACE-Step/ACE-Step-v1-3.5B"


	# class ACEStepPipeline(DiffusionPipeline):
	class ACEStepPipeline:

	def __init__(
	self,
	checkpoint_dir=None,
	device_id=0,
	dtype="bfloat16",
	text_encoder_checkpoint_path=None,
	persistent_storage_path=None,
	torch_compile=False,
	**kwargs,
	):
	if not checkpoint_dir:
	if persistent_storage_path is None:
	checkpoint_dir = os.path.join(os.path.dirname(__file__), "checkpoints")
	else:
	checkpoint_dir = os.path.join(persistent_storage_path, "checkpoints")
	ensure_directory_exists(checkpoint_dir)
	self.checkpoint_dir = checkpoint_dir
	device = (
	torch.device(f"cuda:{device_id}")
	if torch.cuda.is_available()
	else torch.device("cpu")
	)
	if device.type == "cpu" and torch.backends.mps.is_available():
	device = torch.device("mps")
	self.dtype = torch.bfloat16 if dtype == "bfloat16" else torch.float32
	if device.type == "mps":
	self.dtype = torch.float32
	self.device = device
	self.loaded = False
	self.torch_compile = torch_compile
	self.lora_path = "none"

	def load_lora(self, lora_name_or_path):
	if lora_name_or_path != self.lora_path and lora_name_or_path != "none":
	if not os.path.exists(lora_name_or_path):
	lora_download_path = snapshot_download(
	lora_name_or_path, cache_dir=self.checkpoint_dir
	)
	else:
	lora_download_path = lora_name_or_path
	if self.lora_path != "none":
	self.ace_step_transformer.unload_lora()
	self.ace_step_transformer.load_lora_adapter(
	os.path.join(lora_download_path, "pytorch_lora_weights.safetensors"),
	adapter_name="zh_rap_lora",
	with_alpha=True,
	)
	logger.info(
	f"Loading lora weights from: {lora_name_or_path} download path is: {lora_download_path}"
	)
	self.lora_path = lora_name_or_path
	elif self.lora_path != "none" and lora_name_or_path == "none":
	logger.info("No lora weights to load.")
	self.ace_step_transformer.unload_lora()

	def load_checkpoint(self, checkpoint_dir=None):
	device = self.device

	dcae_model_path = os.path.join(checkpoint_dir, "music_dcae_f8c8")
	vocoder_model_path = os.path.join(checkpoint_dir, "music_vocoder")
	ace_step_model_path = os.path.join(checkpoint_dir, "ace_step_transformer")
	text_encoder_model_path = os.path.join(checkpoint_dir, "umt5-base")

	files_exist = (
	os.path.exists(os.path.join(dcae_model_path, "config.json"))
	and os.path.exists(
	os.path.join(dcae_model_path, "diffusion_pytorch_model.safetensors")
	)
	and os.path.exists(os.path.join(vocoder_model_path, "config.json"))
	and os.path.exists(
	os.path.join(vocoder_model_path, "diffusion_pytorch_model.safetensors")
	)
	and os.path.exists(os.path.join(ace_step_model_path, "config.json"))
	and os.path.exists(
	os.path.join(ace_step_model_path, "diffusion_pytorch_model.safetensors")
	)
	and os.path.exists(os.path.join(text_encoder_model_path, "config.json"))
	and os.path.exists(
	os.path.join(text_encoder_model_path, "model.safetensors")
	)
	and os.path.exists(
	os.path.join(text_encoder_model_path, "special_tokens_map.json")
	)
	and os.path.exists(
	os.path.join(text_encoder_model_path, "tokenizer_config.json")
	)
	and os.path.exists(os.path.join(text_encoder_model_path, "tokenizer.json"))
	)

	if not files_exist:
	logger.info(
	f"Checkpoint directory {checkpoint_dir} is not complete, downloading from Hugging Face Hub"
	)

	# download music dcae model
	os.makedirs(dcae_model_path, exist_ok=True)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="music_dcae_f8c8",
	filename="config.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="music_dcae_f8c8",
	filename="diffusion_pytorch_model.safetensors",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)

	# download vocoder model
	os.makedirs(vocoder_model_path, exist_ok=True)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="music_vocoder",
	filename="config.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="music_vocoder",
	filename="diffusion_pytorch_model.safetensors",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)

	# download ace_step transformer model
	os.makedirs(ace_step_model_path, exist_ok=True)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="ace_step_transformer",
	filename="config.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="ace_step_transformer",
	filename="diffusion_pytorch_model.safetensors",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)

	# download text encoder model
	os.makedirs(text_encoder_model_path, exist_ok=True)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="umt5-base",
	filename="config.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="umt5-base",
	filename="model.safetensors",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="umt5-base",
	filename="special_tokens_map.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="umt5-base",
	filename="tokenizer_config.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)
	hf_hub_download(
	repo_id=REPO_ID,
	subfolder="umt5-base",
	filename="tokenizer.json",
	local_dir=checkpoint_dir,
	local_dir_use_symlinks=False,
	)

	logger.info("Models downloaded")

	dcae_checkpoint_path = dcae_model_path
	vocoder_checkpoint_path = vocoder_model_path
	ace_step_checkpoint_path = ace_step_model_path
	text_encoder_checkpoint_path = text_encoder_model_path

	self.music_dcae = MusicDCAE(
	dcae_checkpoint_path=dcae_checkpoint_path,
	vocoder_checkpoint_path=vocoder_checkpoint_path,
	)
	self.music_dcae.to(device).eval().to(self.dtype)

	self.ace_step_transformer = ACEStepTransformer2DModel.from_pretrained(
	ace_step_checkpoint_path, torch_dtype=self.dtype
	)
	self.ace_step_transformer.to(device).eval().to(self.dtype)

	lang_segment = LangSegment()

	lang_segment.setfilters(
	[
	"af",
	"am",
	"an",
	"ar",
	"as",
	"az",
	"be",
	"bg",
	"bn",
	"br",
	"bs",
	"ca",
	"cs",
	"cy",
	"da",
	"de",
	"dz",
	"el",
	"en",
	"eo",
	"es",
	"et",
	"eu",
	"fa",
	"fi",
	"fo",
	"fr",
	"ga",
	"gl",
	"gu",
	"he",
	"hi",
	"hr",
	"ht",
	"hu",
	"hy",
	"id",
	"is",
	"it",
	"ja",
	"jv",
	"ka",
	"kk",
	"km",
	"kn",
	"ko",
	"ku",
	"ky",
	"la",
	"lb",
	"lo",
	"lt",
	"lv",
	"mg",
	"mk",
	"ml",
	"mn",
	"mr",
	"ms",
	"mt",
	"nb",
	"ne",
	"nl",
	"nn",
	"no",
	"oc",
	"or",
	"pa",
	"pl",
	"ps",
	"pt",
	"qu",
	"ro",
	"ru",
	"rw",
	"se",
	"si",
	"sk",
	"sl",
	"sq",
	"sr",
	"sv",
	"sw",
	"ta",
	"te",
	"th",
	"tl",
	"tr",
	"ug",
	"uk",
	"ur",
	"vi",
	"vo",
	"wa",
	"xh",
	"zh",
	"zu",
	]
	)
	self.lang_segment = lang_segment
	self.lyric_tokenizer = VoiceBpeTokenizer()
	text_encoder_model = UMT5EncoderModel.from_pretrained(
	text_encoder_checkpoint_path, torch_dtype=self.dtype
	).eval()
	text_encoder_model = text_encoder_model.to(device).to(self.dtype)
	text_encoder_model.requires_grad_(False)
	self.text_encoder_model = text_encoder_model
	self.text_tokenizer = AutoTokenizer.from_pretrained(
	text_encoder_checkpoint_path
	)
	self.loaded = True

	# compile
	if self.torch_compile:
	self.music_dcae = torch.compile(self.music_dcae)
	self.ace_step_transformer = torch.compile(self.ace_step_transformer)
	self.text_encoder_model = torch.compile(self.text_encoder_model)

	def get_text_embeddings(self, texts, device, text_max_length=256):
	inputs = self.text_tokenizer(
	texts,
	return_tensors="pt",
	padding=True,
	truncation=True,
	max_length=text_max_length,
	)
	inputs = {key: value.to(device) for key, value in inputs.items()}
	if self.text_encoder_model.device != device:
	self.text_encoder_model.to(device)
	with torch.no_grad():
	outputs = self.text_encoder_model(**inputs)
	last_hidden_states = outputs.last_hidden_state
	attention_mask = inputs["attention_mask"]
	return last_hidden_states, attention_mask

	def get_text_embeddings_null(
	self, texts, device, text_max_length=256, tau=0.01, l_min=8, l_max=10
	):
	inputs = self.text_tokenizer(
	texts,
	return_tensors="pt",
	padding=True,
	truncation=True,
	max_length=text_max_length,
	)
	inputs = {key: value.to(device) for key, value in inputs.items()}
	if self.text_encoder_model.device != device:
	self.text_encoder_model.to(device)

	def forward_with_temperature(inputs, tau=0.01, l_min=8, l_max=10):
	handlers = []

	def hook(module, input, output):
	output[:] *= tau
	return output

	for i in range(l_min, l_max):
	handler = (
	self.text_encoder_model.encoder.block[i]
	.layer[0]
	.SelfAttention.q.register_forward_hook(hook)
	)
	handlers.append(handler)

	with torch.no_grad():
	outputs = self.text_encoder_model(**inputs)
	last_hidden_states = outputs.last_hidden_state

	for hook in handlers:
	hook.remove()

	return last_hidden_states

	last_hidden_states = forward_with_temperature(inputs, tau, l_min, l_max)
	return last_hidden_states

	def set_seeds(self, batch_size, manual_seeds=None):
	processed_input_seeds = None
	if manual_seeds is not None:
	if isinstance(manual_seeds, str):
	if "," in manual_seeds:
	processed_input_seeds = list(map(int, manual_seeds.split(",")))
	elif manual_seeds.isdigit():
	processed_input_seeds = int(manual_seeds)
	elif isinstance(manual_seeds, list) and all(
	isinstance(s, int) for s in manual_seeds
	):
	if len(manual_seeds) > 0:
	processed_input_seeds = list(manual_seeds)
	elif isinstance(manual_seeds, int):
	processed_input_seeds = manual_seeds
	random_generators = [
	torch.Generator(device=self.device) for _ in range(batch_size)
	]
	actual_seeds = []
	for i in range(batch_size):
	current_seed_for_generator = None
	if processed_input_seeds is None:
	current_seed_for_generator = torch.randint(0, 2**32, (1,)).item()
	elif isinstance(processed_input_seeds, int):
	current_seed_for_generator = processed_input_seeds
	elif isinstance(processed_input_seeds, list):
	if i < len(processed_input_seeds):
	current_seed_for_generator = processed_input_seeds[i]
	else:
	current_seed_for_generator = processed_input_seeds[-1]
	if current_seed_for_generator is None:
	current_seed_for_generator = torch.randint(0, 2**32, (1,)).item()
	random_generators[i].manual_seed(current_seed_for_generator)
	actual_seeds.append(current_seed_for_generator)
	return random_generators, actual_seeds

	def get_lang(self, text):
	language = "en"
	try:
	_ = self.lang_segment.getTexts(text)
	langCounts = self.lang_segment.getCounts()
	language = langCounts[0][0]
	if len(langCounts) > 1 and language == "en":
	language = langCounts[1][0]
	except Exception as err:
	language = "en"
	return language

	def tokenize_lyrics(self, lyrics, debug=False):
	lines = lyrics.split("\n")
	lyric_token_idx = [261]
	for line in lines:
	line = line.strip()
	if not line:
	lyric_token_idx += [2]
	continue

	lang = self.get_lang(line)

	if lang not in SUPPORT_LANGUAGES:
	lang = "en"
	if "zh" in lang:
	lang = "zh"
	if "spa" in lang:
	lang = "es"

	try:
	if structure_pattern.match(line):
	token_idx = self.lyric_tokenizer.encode(line, "en")
	else:
	token_idx = self.lyric_tokenizer.encode(line, lang)
	if debug:
	toks = self.lyric_tokenizer.batch_decode(
	[[tok_id] for tok_id in token_idx]
	)
	logger.info(f"debbug {line} --> {lang} --> {toks}")
	lyric_token_idx = lyric_token_idx + token_idx + [2]
	except Exception as e:
	print("tokenize error", e, "for line", line, "major_language", lang)
	return lyric_token_idx

	def calc_v(
	self,
	zt_src,
	zt_tar,
	t,
	encoder_text_hidden_states,
	text_attention_mask,
	target_encoder_text_hidden_states,
	target_text_attention_mask,
	speaker_embds,
	target_speaker_embeds,
	lyric_token_ids,
	lyric_mask,
	target_lyric_token_ids,
	target_lyric_mask,
	do_classifier_free_guidance=False,
	guidance_scale=1.0,
	target_guidance_scale=1.0,
	cfg_type="apg",
	attention_mask=None,
	momentum_buffer=None,
	momentum_buffer_tar=None,
	return_src_pred=True,
	):
	noise_pred_src = None
	if return_src_pred:
	src_latent_model_input = (
	torch.cat([zt_src, zt_src]) if do_classifier_free_guidance else zt_src
	)
	timestep = t.expand(src_latent_model_input.shape[0])
	# source
	noise_pred_src = self.ace_step_transformer(
	hidden_states=src_latent_model_input,
	attention_mask=attention_mask,
	encoder_text_hidden_states=encoder_text_hidden_states,
	text_attention_mask=text_attention_mask,
	speaker_embeds=speaker_embds,
	lyric_token_idx=lyric_token_ids,
	lyric_mask=lyric_mask,
	timestep=timestep,
	).sample

	if do_classifier_free_guidance:
	noise_pred_with_cond_src, noise_pred_uncond_src = noise_pred_src.chunk(
	2
	)
	if cfg_type == "apg":
	noise_pred_src = apg_forward(
	pred_cond=noise_pred_with_cond_src,
	pred_uncond=noise_pred_uncond_src,
	guidance_scale=guidance_scale,
	momentum_buffer=momentum_buffer,
	)
	elif cfg_type == "cfg":
	noise_pred_src = cfg_forward(
	cond_output=noise_pred_with_cond_src,
	uncond_output=noise_pred_uncond_src,
	cfg_strength=guidance_scale,
	)

	tar_latent_model_input = (
	torch.cat([zt_tar, zt_tar]) if do_classifier_free_guidance else zt_tar
	)
	timestep = t.expand(tar_latent_model_input.shape[0])
	# target
	noise_pred_tar = self.ace_step_transformer(
	hidden_states=tar_latent_model_input,
	attention_mask=attention_mask,
	encoder_text_hidden_states=target_encoder_text_hidden_states,
	text_attention_mask=target_text_attention_mask,
	speaker_embeds=target_speaker_embeds,
	lyric_token_idx=target_lyric_token_ids,
	lyric_mask=target_lyric_mask,
	timestep=timestep,
	).sample

	if do_classifier_free_guidance:
	noise_pred_with_cond_tar, noise_pred_uncond_tar = noise_pred_tar.chunk(2)
	if cfg_type == "apg":
	noise_pred_tar = apg_forward(
	pred_cond=noise_pred_with_cond_tar,
	pred_uncond=noise_pred_uncond_tar,
	guidance_scale=target_guidance_scale,
	momentum_buffer=momentum_buffer_tar,
	)
	elif cfg_type == "cfg":
	noise_pred_tar = cfg_forward(
	cond_output=noise_pred_with_cond_tar,
	uncond_output=noise_pred_uncond_tar,
	cfg_strength=target_guidance_scale,
	)
	return noise_pred_src, noise_pred_tar

	@torch.no_grad()
	def flowedit_diffusion_process(
	self,
	encoder_text_hidden_states,
	text_attention_mask,
	speaker_embds,
	lyric_token_ids,
	lyric_mask,
	target_encoder_text_hidden_states,
	target_text_attention_mask,
	target_speaker_embeds,
	target_lyric_token_ids,
	target_lyric_mask,
	src_latents,
	random_generators=None,
	infer_steps=60,
	guidance_scale=15.0,
	n_min=0,
	n_max=1.0,
	n_avg=1,
	):

	do_classifier_free_guidance = True
	if guidance_scale == 0.0 or guidance_scale == 1.0:
	do_classifier_free_guidance = False

	target_guidance_scale = guidance_scale
	device = encoder_text_hidden_states.device
	dtype = encoder_text_hidden_states.dtype
	bsz = encoder_text_hidden_states.shape[0]

	scheduler = FlowMatchEulerDiscreteScheduler(
	num_train_timesteps=1000,
	shift=3.0,
	)

	T_steps = infer_steps
	frame_length = src_latents.shape[-1]
	attention_mask = torch.ones(bsz, frame_length, device=device, dtype=dtype)

	timesteps, T_steps = retrieve_timesteps(
	scheduler, T_steps, device, timesteps=None
	)

	if do_classifier_free_guidance:
	attention_mask = torch.cat([attention_mask] * 2, dim=0)

	encoder_text_hidden_states = torch.cat(
	[
	encoder_text_hidden_states,
	torch.zeros_like(encoder_text_hidden_states),
	],
	0,
	)
	text_attention_mask = torch.cat([text_attention_mask] * 2, dim=0)

	target_encoder_text_hidden_states = torch.cat(
	[
	target_encoder_text_hidden_states,
	torch.zeros_like(target_encoder_text_hidden_states),
	],
	0,
	)
	target_text_attention_mask = torch.cat(
	[target_text_attention_mask] * 2, dim=0
	)

	speaker_embds = torch.cat(
	[speaker_embds, torch.zeros_like(speaker_embds)], 0
	)
	target_speaker_embeds = torch.cat(
	[target_speaker_embeds, torch.zeros_like(target_speaker_embeds)], 0
	)

	lyric_token_ids = torch.cat(
	[lyric_token_ids, torch.zeros_like(lyric_token_ids)], 0
	)
	lyric_mask = torch.cat([lyric_mask, torch.zeros_like(lyric_mask)], 0)

	target_lyric_token_ids = torch.cat(
	[target_lyric_token_ids, torch.zeros_like(target_lyric_token_ids)], 0
	)
	target_lyric_mask = torch.cat(
	[target_lyric_mask, torch.zeros_like(target_lyric_mask)], 0
	)

	momentum_buffer = MomentumBuffer()
	momentum_buffer_tar = MomentumBuffer()
	x_src = src_latents
	zt_edit = x_src.clone()
	xt_tar = None
	n_min = int(infer_steps * n_min)
	n_max = int(infer_steps * n_max)

	logger.info("flowedit start from {} to {}".format(n_min, n_max))

	for i, t in tqdm(enumerate(timesteps), total=T_steps):

	if i < n_min:
	continue

	t_i = t / 1000

	if i + 1 < len(timesteps):
	t_im1 = (timesteps[i + 1]) / 1000
	else:
	t_im1 = torch.zeros_like(t_i).to(t_i.device)

	if i < n_max:
	# Calculate the average of the V predictions
	V_delta_avg = torch.zeros_like(x_src)
	for k in range(n_avg):
	fwd_noise = randn_tensor(
	shape=x_src.shape,
	generator=random_generators,
	device=device,
	dtype=dtype,
	)

	zt_src = (1 - t_i) * x_src + (t_i) * fwd_noise

	zt_tar = zt_edit + zt_src - x_src

	Vt_src, Vt_tar = self.calc_v(
	zt_src=zt_src,
	zt_tar=zt_tar,
	t=t,
	encoder_text_hidden_states=encoder_text_hidden_states,
	text_attention_mask=text_attention_mask,
	target_encoder_text_hidden_states=target_encoder_text_hidden_states,
	target_text_attention_mask=target_text_attention_mask,
	speaker_embds=speaker_embds,
	target_speaker_embeds=target_speaker_embeds,
	lyric_token_ids=lyric_token_ids,
	lyric_mask=lyric_mask,
	target_lyric_token_ids=target_lyric_token_ids,
	target_lyric_mask=target_lyric_mask,
	do_classifier_free_guidance=do_classifier_free_guidance,
	guidance_scale=guidance_scale,
	target_guidance_scale=target_guidance_scale,
	attention_mask=attention_mask,
	momentum_buffer=momentum_buffer,
	)
	V_delta_avg += (1 / n_avg) * (
	Vt_tar - Vt_src
	) # - (hfg-1)*( x_src))

	# propagate direct ODE
	zt_edit = zt_edit.to(torch.float32)
	zt_edit = zt_edit + (t_im1 - t_i) * V_delta_avg
	zt_edit = zt_edit.to(V_delta_avg.dtype)
	else: # i >= T_steps-n_min # regular sampling for last n_min steps
	if i == n_max:
	fwd_noise = randn_tensor(
	shape=x_src.shape,
	generator=random_generators,
	device=device,
	dtype=dtype,
	)
	scheduler._init_step_index(t)
	sigma = scheduler.sigmas[scheduler.step_index]
	xt_src = sigma * fwd_noise + (1.0 - sigma) * x_src
	xt_tar = zt_edit + xt_src - x_src

	_, Vt_tar = self.calc_v(
	zt_src=None,
	zt_tar=xt_tar,
	t=t,
	encoder_text_hidden_states=encoder_text_hidden_states,
	text_attention_mask=text_attention_mask,
	target_encoder_text_hidden_states=target_encoder_text_hidden_states,
	target_text_attention_mask=target_text_attention_mask,
	speaker_embds=speaker_embds,
	target_speaker_embeds=target_speaker_embeds,
	lyric_token_ids=lyric_token_ids,
	lyric_mask=lyric_mask,
	target_lyric_token_ids=target_lyric_token_ids,
	target_lyric_mask=target_lyric_mask,
	do_classifier_free_guidance=do_classifier_free_guidance,
	guidance_scale=guidance_scale,
	target_guidance_scale=target_guidance_scale,
	attention_mask=attention_mask,
	momentum_buffer_tar=momentum_buffer_tar,
	return_src_pred=False,
	)

	dtype = Vt_tar.dtype
	xt_tar = xt_tar.to(torch.float32)
	prev_sample = xt_tar + (t_im1 - t_i) * Vt_tar
	prev_sample = prev_sample.to(dtype)
	xt_tar = prev_sample

	target_latents = zt_edit if xt_tar is None else xt_tar
	return target_latents

	def add_latents_noise(
	self,
	gt_latents,
	variance,
	noise,
	scheduler,
	):

	bsz = gt_latents.shape[0]
	u = torch.tensor([variance] * bsz, dtype=gt_latents.dtype)
	indices = (u * scheduler.config.num_train_timesteps).long()
	timesteps = scheduler.timesteps.unsqueeze(1).to(gt_latents.dtype)
	indices = indices.to(timesteps.device).to(gt_latents.dtype).unsqueeze(1)
	nearest_idx = torch.argmin(torch.cdist(indices, timesteps), dim=1)
	sigma = (
	scheduler.sigmas[nearest_idx]
	.flatten()
	.to(gt_latents.device)
	.to(gt_latents.dtype)
	)
	while len(sigma.shape) < gt_latents.ndim:
	sigma = sigma.unsqueeze(-1)
	noisy_image = sigma * noise + (1.0 - sigma) * gt_latents
	init_timestep = indices[0]
	return noisy_image, init_timestep

	@torch.no_grad()
	def text2music_diffusion_process(
	self,
	duration,
	encoder_text_hidden_states,
	text_attention_mask,
	speaker_embds,
	lyric_token_ids,
	lyric_mask,
	random_generators=None,
	infer_steps=60,
	guidance_scale=15.0,
	omega_scale=10.0,
	scheduler_type="euler",
	cfg_type="apg",
	zero_steps=1,
	use_zero_init=True,
	guidance_interval=0.5,
	guidance_interval_decay=1.0,
	min_guidance_scale=3.0,
	oss_steps=[],
	encoder_text_hidden_states_null=None,
	use_erg_lyric=False,
	use_erg_diffusion=False,
	retake_random_generators=None,
	retake_variance=0.5,
	add_retake_noise=False,
	guidance_scale_text=0.0,
	guidance_scale_lyric=0.0,
	repaint_start=0,
	repaint_end=0,
	src_latents=None,
	audio2audio_enable=False,
	ref_audio_strength=0.5,
	ref_latents=None,
	):

	logger.info(
	"cfg_type: {}, guidance_scale: {}, omega_scale: {}".format(
	cfg_type, guidance_scale, omega_scale
	)
	)
	do_classifier_free_guidance = True
	if guidance_scale == 0.0 or guidance_scale == 1.0:
	do_classifier_free_guidance = False

	do_double_condition_guidance = False
	if (
	guidance_scale_text is not None
	and guidance_scale_text > 1.0
	and guidance_scale_lyric is not None
	and guidance_scale_lyric > 1.0
	):
	do_double_condition_guidance = True
	logger.info(
	"do_double_condition_guidance: {}, guidance_scale_text: {}, guidance_scale_lyric: {}".format(
	do_double_condition_guidance,
	guidance_scale_text,
	guidance_scale_lyric,
	)
	)

	device = encoder_text_hidden_states.device
	dtype = encoder_text_hidden_states.dtype
	bsz = encoder_text_hidden_states.shape[0]

	if scheduler_type == "euler":
	scheduler = FlowMatchEulerDiscreteScheduler(
	num_train_timesteps=1000,
	shift=3.0,
	)
	elif scheduler_type == "heun":
	scheduler = FlowMatchHeunDiscreteScheduler(
	num_train_timesteps=1000,
	shift=3.0,
	)

	frame_length = int(duration * 44100 / 512 / 8)
	if src_latents is not None:
	frame_length = src_latents.shape[-1]

	if ref_latents is not None:
	frame_length = ref_latents.shape[-1]

	if len(oss_steps) > 0:
	infer_steps = max(oss_steps)
	scheduler.set_timesteps
	timesteps, num_inference_steps = retrieve_timesteps(
	scheduler,
	num_inference_steps=infer_steps,
	device=device,
	timesteps=None,
	)
	new_timesteps = torch.zeros(len(oss_steps), dtype=dtype, device=device)
	for idx in range(len(oss_steps)):
	new_timesteps[idx] = timesteps[oss_steps[idx] - 1]
	num_inference_steps = len(oss_steps)
	sigmas = (new_timesteps / 1000).float().cpu().numpy()
	timesteps, num_inference_steps = retrieve_timesteps(
	scheduler,
	num_inference_steps=num_inference_steps,
	device=device,
	sigmas=sigmas,
	)
	logger.info(
	f"oss_steps: {oss_steps}, num_inference_steps: {num_inference_steps} after remapping to timesteps {timesteps}"
	)
	else:
	timesteps, num_inference_steps = retrieve_timesteps(
	scheduler,
	num_inference_steps=infer_steps,
	device=device,
	timesteps=None,
	)

	target_latents = randn_tensor(
	shape=(bsz, 8, 16, frame_length),
	generator=random_generators,
	device=device,
	dtype=dtype,
	)

	is_repaint = False
	is_extend = False
	if add_retake_noise:
	n_min = int(infer_steps * (1 - retake_variance))
	retake_variance = (
	torch.tensor(retake_variance * math.pi / 2).to(device).to(dtype)
	)
	retake_latents = randn_tensor(
	shape=(bsz, 8, 16, frame_length),
	generator=retake_random_generators,
	device=device,
	dtype=dtype,
	)
	repaint_start_frame = int(repaint_start * 44100 / 512 / 8)
	repaint_end_frame = int(repaint_end * 44100 / 512 / 8)
	x0 = src_latents
	# retake
	is_repaint = repaint_end_frame - repaint_start_frame != frame_length

	is_extend = (repaint_start_frame < 0) or (repaint_end_frame > frame_length)
	if is_extend:
	is_repaint = True

	# TODO: train a mask aware repainting controlnet
	# to make sure mean = 0, std = 1
	if not is_repaint:
	target_latents = (
	torch.cos(retake_variance) * target_latents
	+ torch.sin(retake_variance) * retake_latents
	)
	elif not is_extend:
	# if repaint_end_frame
	repaint_mask = torch.zeros(
	(bsz, 8, 16, frame_length), device=device, dtype=dtype
	)
	repaint_mask[:, :, :, repaint_start_frame:repaint_end_frame] = 1.0
	repaint_noise = (
	torch.cos(retake_variance) * target_latents
	+ torch.sin(retake_variance) * retake_latents
	)
	repaint_noise = torch.where(
	repaint_mask == 1.0, repaint_noise, target_latents
	)
	zt_edit = x0.clone()
	z0 = repaint_noise
	elif is_extend:
	to_right_pad_gt_latents = None
	to_left_pad_gt_latents = None
	gt_latents = src_latents
	src_latents_length = gt_latents.shape[-1]
	max_infer_fame_length = int(240 * 44100 / 512 / 8)
	left_pad_frame_length = 0
	right_pad_frame_length = 0
	right_trim_length = 0
	left_trim_length = 0
	if repaint_start_frame < 0:
	left_pad_frame_length = abs(repaint_start_frame)
	frame_length = left_pad_frame_length + gt_latents.shape[-1]
	extend_gt_latents = torch.nn.functional.pad(
	gt_latents, (left_pad_frame_length, 0), "constant", 0
	)
	if frame_length > max_infer_fame_length:
	right_trim_length = frame_length - max_infer_fame_length
	extend_gt_latents = extend_gt_latents[
	:, :, :, :max_infer_fame_length
	]
	to_right_pad_gt_latents = extend_gt_latents[
	:, :, :, -right_trim_length:
	]
	frame_length = max_infer_fame_length
	repaint_start_frame = 0
	gt_latents = extend_gt_latents

	if repaint_end_frame > src_latents_length:
	right_pad_frame_length = repaint_end_frame - gt_latents.shape[-1]
	frame_length = gt_latents.shape[-1] + right_pad_frame_length
	extend_gt_latents = torch.nn.functional.pad(
	gt_latents, (0, right_pad_frame_length), "constant", 0
	)
	if frame_length > max_infer_fame_length:
	left_trim_length = frame_length - max_infer_fame_length
	extend_gt_latents = extend_gt_latents[
	:, :, :, -max_infer_fame_length:
	]
	to_left_pad_gt_latents = extend_gt_latents[
	:, :, :, :left_trim_length
	]
	frame_length = max_infer_fame_length
	repaint_end_frame = frame_length
	gt_latents = extend_gt_latents

	repaint_mask = torch.zeros(
	(bsz, 8, 16, frame_length), device=device, dtype=dtype
	)
	if left_pad_frame_length > 0:
	repaint_mask[:, :, :, :left_pad_frame_length] = 1.0
	if right_pad_frame_length > 0:
	repaint_mask[:, :, :, -right_pad_frame_length:] = 1.0
	x0 = gt_latents
	padd_list = []
	if left_pad_frame_length > 0:
	padd_list.append(retake_latents[:, :, :, :left_pad_frame_length])
	padd_list.append(
	target_latents[
	:,
	:,
	:,
	left_trim_length : target_latents.shape[-1] - right_trim_length,
	]
	)
	if right_pad_frame_length > 0:
	padd_list.append(retake_latents[:, :, :, -right_pad_frame_length:])
	target_latents = torch.cat(padd_list, dim=-1)
	assert (
	target_latents.shape[-1] == x0.shape[-1]
	), f"{target_latents.shape=} {x0.shape=}"
	zt_edit = x0.clone()
	z0 = target_latents

	init_timestep = 1000
	if audio2audio_enable and ref_latents is not None:
	target_latents, init_timestep = self.add_latents_noise(
	gt_latents=ref_latents,
	variance=(1 - ref_audio_strength),
	noise=target_latents,
	scheduler=scheduler,
	)

	attention_mask = torch.ones(bsz, frame_length, device=device, dtype=dtype)

	# guidance interval
	start_idx = int(num_inference_steps * ((1 - guidance_interval) / 2))
	end_idx = int(num_inference_steps * (guidance_interval / 2 + 0.5))
	logger.info(
	f"start_idx: {start_idx}, end_idx: {end_idx}, num_inference_steps: {num_inference_steps}"
	)

	momentum_buffer = MomentumBuffer()

	def forward_encoder_with_temperature(self, inputs, tau=0.01, l_min=4, l_max=6):
	handlers = []

	def hook(module, input, output):
	output[:] *= tau
	return output

	for i in range(l_min, l_max):
	handler = self.ace_step_transformer.lyric_encoder.encoders[
	i
	].self_attn.linear_q.register_forward_hook(hook)
	handlers.append(handler)

	encoder_hidden_states, encoder_hidden_mask = (
	self.ace_step_transformer.encode(**inputs)
	)

	for hook in handlers:
	hook.remove()

	return encoder_hidden_states

	# P(speaker, text, lyric)
	encoder_hidden_states, encoder_hidden_mask = self.ace_step_transformer.encode(
	encoder_text_hidden_states,
	text_attention_mask,
	speaker_embds,
	lyric_token_ids,
	lyric_mask,
	)

	if use_erg_lyric:
	# P(null_speaker, text_weaker, lyric_weaker)
	encoder_hidden_states_null = forward_encoder_with_temperature(
	self,
	inputs={
	"encoder_text_hidden_states": (
	encoder_text_hidden_states_null
	if encoder_text_hidden_states_null is not None
	else torch.zeros_like(encoder_text_hidden_states)
	),
	"text_attention_mask": text_attention_mask,
	"speaker_embeds": torch.zeros_like(speaker_embds),
	"lyric_token_idx": lyric_token_ids,
	"lyric_mask": lyric_mask,
	},
	)
	else:
	# P(null_speaker, null_text, null_lyric)
	encoder_hidden_states_null, _ = self.ace_step_transformer.encode(
	torch.zeros_like(encoder_text_hidden_states),
	text_attention_mask,
	torch.zeros_like(speaker_embds),
	torch.zeros_like(lyric_token_ids),
	lyric_mask,
	)

	encoder_hidden_states_no_lyric = None
	if do_double_condition_guidance:
	# P(null_speaker, text, lyric_weaker)
	if use_erg_lyric:
	encoder_hidden_states_no_lyric = forward_encoder_with_temperature(
	self,
	inputs={
	"encoder_text_hidden_states": encoder_text_hidden_states,
	"text_attention_mask": text_attention_mask,
	"speaker_embeds": torch.zeros_like(speaker_embds),
	"lyric_token_idx": lyric_token_ids,
	"lyric_mask": lyric_mask,
	},
	)
	# P(null_speaker, text, no_lyric)
	else:
	encoder_hidden_states_no_lyric, _ = self.ace_step_transformer.encode(
	encoder_text_hidden_states,
	text_attention_mask,
	torch.zeros_like(speaker_embds),
	torch.zeros_like(lyric_token_ids),
	lyric_mask,
	)

	def forward_diffusion_with_temperature(
	self, hidden_states, timestep, inputs, tau=0.01, l_min=15, l_max=20
	):
	handlers = []

	def hook(module, input, output):
	output[:] *= tau
	return output

	for i in range(l_min, l_max):
	handler = self.ace_step_transformer.transformer_blocks[
	i
	].attn.to_q.register_forward_hook(hook)
	handlers.append(handler)
	handler = self.ace_step_transformer.transformer_blocks[
	i
	].cross_attn.to_q.register_forward_hook(hook)
	handlers.append(handler)

	sample = self.ace_step_transformer.decode(
	hidden_states=hidden_states, timestep=timestep, **inputs
	).sample

	for hook in handlers:
	hook.remove()

	return sample

	for i, t in tqdm(enumerate(timesteps), total=num_inference_steps):

	if t > init_timestep:
	continue

	if is_repaint:
	if i < n_min:
	continue
	elif i == n_min:
	t_i = t / 1000
	zt_src = (1 - t_i) * x0 + (t_i) * z0
	target_latents = zt_edit + zt_src - x0
	logger.info(f"repaint start from {n_min} add {t_i} level of noise")

	# expand the latents if we are doing classifier free guidance
	latents = target_latents

	is_in_guidance_interval = start_idx <= i < end_idx
	if is_in_guidance_interval and do_classifier_free_guidance:
	# compute current guidance scale
	if guidance_interval_decay > 0:
	# Linearly interpolate to calculate the current guidance scale
	progress = (i - start_idx) / (
	end_idx - start_idx - 1
	) # 归一化到[0,1]
	current_guidance_scale = (
	guidance_scale
	- (guidance_scale - min_guidance_scale)
	* progress
	* guidance_interval_decay
	)
	else:
	current_guidance_scale = guidance_scale

	latent_model_input = latents
	timestep = t.expand(latent_model_input.shape[0])
	output_length = latent_model_input.shape[-1]
	# P(x\|speaker, text, lyric)
	noise_pred_with_cond = self.ace_step_transformer.decode(
	hidden_states=latent_model_input,
	attention_mask=attention_mask,
	encoder_hidden_states=encoder_hidden_states,
	encoder_hidden_mask=encoder_hidden_mask,
	output_length=output_length,
	timestep=timestep,
	).sample

	noise_pred_with_only_text_cond = None
	if (
	do_double_condition_guidance
	and encoder_hidden_states_no_lyric is not None
	):
	noise_pred_with_only_text_cond = self.ace_step_transformer.decode(
	hidden_states=latent_model_input,
	attention_mask=attention_mask,
	encoder_hidden_states=encoder_hidden_states_no_lyric,
	encoder_hidden_mask=encoder_hidden_mask,
	output_length=output_length,
	timestep=timestep,
	).sample

	if use_erg_diffusion:
	noise_pred_uncond = forward_diffusion_with_temperature(
	self,
	hidden_states=latent_model_input,
	timestep=timestep,
	inputs={
	"encoder_hidden_states": encoder_hidden_states_null,
	"encoder_hidden_mask": encoder_hidden_mask,
	"output_length": output_length,
	"attention_mask": attention_mask,
	},
	)
	else:
	noise_pred_uncond = self.ace_step_transformer.decode(
	hidden_states=latent_model_input,
	attention_mask=attention_mask,
	encoder_hidden_states=encoder_hidden_states_null,
	encoder_hidden_mask=encoder_hidden_mask,
	output_length=output_length,
	timestep=timestep,
	).sample

	if (
	do_double_condition_guidance
	and noise_pred_with_only_text_cond is not None
	):
	noise_pred = cfg_double_condition_forward(
	cond_output=noise_pred_with_cond,
	uncond_output=noise_pred_uncond,
	only_text_cond_output=noise_pred_with_only_text_cond,
	guidance_scale_text=guidance_scale_text,
	guidance_scale_lyric=guidance_scale_lyric,
	)

	elif cfg_type == "apg":
	noise_pred = apg_forward(
	pred_cond=noise_pred_with_cond,
	pred_uncond=noise_pred_uncond,
	guidance_scale=current_guidance_scale,
	momentum_buffer=momentum_buffer,
	)
	elif cfg_type == "cfg":
	noise_pred = cfg_forward(
	cond_output=noise_pred_with_cond,
	uncond_output=noise_pred_uncond,
	cfg_strength=current_guidance_scale,
	)
	elif cfg_type == "cfg_star":
	noise_pred = cfg_zero_star(
	noise_pred_with_cond=noise_pred_with_cond,
	noise_pred_uncond=noise_pred_uncond,
	guidance_scale=current_guidance_scale,
	i=i,
	zero_steps=zero_steps,
	use_zero_init=use_zero_init,
	)
	else:
	latent_model_input = latents
	timestep = t.expand(latent_model_input.shape[0])
	noise_pred = self.ace_step_transformer.decode(
	hidden_states=latent_model_input,
	attention_mask=attention_mask,
	encoder_hidden_states=encoder_hidden_states,
	encoder_hidden_mask=encoder_hidden_mask,
	output_length=latent_model_input.shape[-1],
	timestep=timestep,
	).sample

	if is_repaint and i >= n_min:
	t_i = t / 1000
	if i + 1 < len(timesteps):
	t_im1 = (timesteps[i + 1]) / 1000
	else:
	t_im1 = torch.zeros_like(t_i).to(t_i.device)
	dtype = noise_pred.dtype
	target_latents = target_latents.to(torch.float32)
	prev_sample = target_latents + (t_im1 - t_i) * noise_pred
	prev_sample = prev_sample.to(dtype)
	target_latents = prev_sample
	zt_src = (1 - t_im1) * x0 + (t_im1) * z0
	target_latents = torch.where(
	repaint_mask == 1.0, target_latents, zt_src
	)
	else:
	target_latents = scheduler.step(
	model_output=noise_pred,
	timestep=t,
	sample=target_latents,
	return_dict=False,
	omega=omega_scale,
	)[0]

	if is_extend:
	if to_right_pad_gt_latents is not None:
	target_latents = torch.cat(
	[target_latents, to_right_pad_gt_latents], dim=-1
	)
	if to_left_pad_gt_latents is not None:
	target_latents = torch.cat(
	[to_right_pad_gt_latents, target_latents], dim=0
	)
	return target_latents

	def latents2audio(
	self,
	latents,
	target_wav_duration_second=30,
	sample_rate=48000,
	save_path=None,
	format="mp3",
	):
	output_audio_paths = []
	bs = latents.shape[0]
	audio_lengths = [target_wav_duration_second * sample_rate] * bs
	pred_latents = latents
	with torch.no_grad():
	_, pred_wavs = self.music_dcae.decode(pred_latents, sr=sample_rate)
	pred_wavs = [pred_wav.cpu().float() for pred_wav in pred_wavs]
	for i in tqdm(range(bs)):
	output_audio_path = self.save_wav_file(
	pred_wavs[i], i, sample_rate=sample_rate
	)
	output_audio_paths.append(output_audio_path)
	return output_audio_paths

	def save_wav_file(
	self, target_wav, idx, save_path=None, sample_rate=48000, format="mp3"
	):
	if save_path is None:
	logger.warning("save_path is None, using default path ./outputs/")
	base_path = f"./outputs"
	ensure_directory_exists(base_path)
	else:
	base_path = save_path
	ensure_directory_exists(base_path)

	output_path_flac = (
	f"{base_path}/output_{time.strftime('%Y%m%d%H%M%S')}_{idx}.{format}"
	)
	target_wav = target_wav.float()
	torchaudio.save(
	output_path_flac,
	target_wav,
	sample_rate=sample_rate,
	format=format,
	compression=torio.io.CodecConfig(bit_rate=320000),
	)
	return output_path_flac

	def infer_latents(self, input_audio_path):
	if input_audio_path is None:
	return None
	input_audio, sr = self.music_dcae.load_audio(input_audio_path)
	input_audio = input_audio.unsqueeze(0)
	device, dtype = self.device, self.dtype
	input_audio = input_audio.to(device=device, dtype=dtype)
	latents, _ = self.music_dcae.encode(input_audio, sr=sr)
	return latents

	@spaces.GPU
	def __call__(
	self,
	audio_duration: float = 60.0,
	prompt: str = None,
	lyrics: str = None,
	infer_step: int = 60,
	guidance_scale: float = 15.0,
	scheduler_type: str = "euler",
	cfg_type: str = "apg",
	omega_scale: int = 10.0,
	manual_seeds: list = None,
	guidance_interval: float = 0.5,
	guidance_interval_decay: float = 0.0,
	min_guidance_scale: float = 3.0,
	use_erg_tag: bool = True,
	use_erg_lyric: bool = True,
	use_erg_diffusion: bool = True,
	oss_steps: str = None,
	guidance_scale_text: float = 0.0,
	guidance_scale_lyric: float = 0.0,
	audio2audio_enable: bool = False,
	ref_audio_strength: float = 0.5,
	ref_audio_input: str = None,
	lora_name_or_path: str = "none",
	retake_seeds: list = None,
	retake_variance: float = 0.5,
	task: str = "text2music",
	repaint_start: int = 0,
	repaint_end: int = 0,
	src_audio_path: str = None,
	edit_target_prompt: str = None,
	edit_target_lyrics: str = None,
	edit_n_min: float = 0.0,
	edit_n_max: float = 1.0,
	edit_n_avg: int = 1,
	save_path: str = None,
	format: str = "mp3",
	batch_size: int = 1,
	debug: bool = False,
	):

	start_time = time.time()

	if audio2audio_enable and ref_audio_input is not None:
	task = "audio2audio"

	if not self.loaded:
	logger.warning("Checkpoint not loaded, loading checkpoint...")
	self.load_checkpoint(self.checkpoint_dir)
	load_model_cost = time.time() - start_time
	logger.info(f"Model loaded in {load_model_cost:.2f} seconds.")
	self.load_lora(lora_name_or_path)
	start_time = time.time()

	random_generators, actual_seeds = self.set_seeds(batch_size, manual_seeds)
	retake_random_generators, actual_retake_seeds = self.set_seeds(
	batch_size, retake_seeds
	)

	if isinstance(oss_steps, str) and len(oss_steps) > 0:
	oss_steps = list(map(int, oss_steps.split(",")))
	else:
	oss_steps = []

	texts = [prompt]
	encoder_text_hidden_states, text_attention_mask = self.get_text_embeddings(
	texts, self.device
	)
	encoder_text_hidden_states = encoder_text_hidden_states.repeat(batch_size, 1, 1)
	text_attention_mask = text_attention_mask.repeat(batch_size, 1)

	encoder_text_hidden_states_null = None
	if use_erg_tag:
	encoder_text_hidden_states_null = self.get_text_embeddings_null(
	texts, self.device
	)
	encoder_text_hidden_states_null = encoder_text_hidden_states_null.repeat(
	batch_size, 1, 1
	)

	# not support for released checkpoint
	speaker_embeds = torch.zeros(batch_size, 512).to(self.device).to(self.dtype)

	# 6 lyric
	lyric_token_idx = torch.tensor([0]).repeat(batch_size, 1).to(self.device).long()
	lyric_mask = torch.tensor([0]).repeat(batch_size, 1).to(self.device).long()
	if len(lyrics) > 0:
	lyric_token_idx = self.tokenize_lyrics(lyrics, debug=debug)
	lyric_mask = [1] * len(lyric_token_idx)
	lyric_token_idx = (
	torch.tensor(lyric_token_idx)
	.unsqueeze(0)
	.to(self.device)
	.repeat(batch_size, 1)
	)
	lyric_mask = (
	torch.tensor(lyric_mask)
	.unsqueeze(0)
	.to(self.device)
	.repeat(batch_size, 1)
	)

	if audio_duration <= 0:
	audio_duration = random.uniform(30.0, 240.0)
	logger.info(f"random audio duration: {audio_duration}")

	end_time = time.time()
	preprocess_time_cost = end_time - start_time
	start_time = end_time

	add_retake_noise = task in ("retake", "repaint", "extend")
	# retake equal to repaint
	if task == "retake":
	repaint_start = 0
	repaint_end = audio_duration

	src_latents = None
	if src_audio_path is not None:
	assert src_audio_path is not None and task in (
	"repaint",
	"edit",
	"extend",
	), "src_audio_path is required for retake/repaint/extend task"
	assert os.path.exists(
	src_audio_path
	), f"src_audio_path {src_audio_path} does not exist"
	src_latents = self.infer_latents(src_audio_path)

	ref_latents = None
	if ref_audio_input is not None and audio2audio_enable:
	assert (
	ref_audio_input is not None
	), "ref_audio_input is required for audio2audio task"
	assert os.path.exists(
	ref_audio_input
	), f"ref_audio_input {ref_audio_input} does not exist"
	ref_latents = self.infer_latents(ref_audio_input)

	if task == "edit":
	texts = [edit_target_prompt]
	target_encoder_text_hidden_states, target_text_attention_mask = (
	self.get_text_embeddings(texts, self.device)
	)
	target_encoder_text_hidden_states = (
	target_encoder_text_hidden_states.repeat(batch_size, 1, 1)
	)
	target_text_attention_mask = target_text_attention_mask.repeat(
	batch_size, 1
	)

	target_lyric_token_idx = (
	torch.tensor([0]).repeat(batch_size, 1).to(self.device).long()
	)
	target_lyric_mask = (
	torch.tensor([0]).repeat(batch_size, 1).to(self.device).long()
	)
	if len(edit_target_lyrics) > 0:
	target_lyric_token_idx = self.tokenize_lyrics(
	edit_target_lyrics, debug=True
	)
	target_lyric_mask = [1] * len(target_lyric_token_idx)
	target_lyric_token_idx = (
	torch.tensor(target_lyric_token_idx)
	.unsqueeze(0)
	.to(self.device)
	.repeat(batch_size, 1)
	)
	target_lyric_mask = (
	torch.tensor(target_lyric_mask)
	.unsqueeze(0)
	.to(self.device)
	.repeat(batch_size, 1)
	)

	target_speaker_embeds = speaker_embeds.clone()

	target_latents = self.flowedit_diffusion_process(
	encoder_text_hidden_states=encoder_text_hidden_states,
	text_attention_mask=text_attention_mask,
	speaker_embds=speaker_embeds,
	lyric_token_ids=lyric_token_idx,
	lyric_mask=lyric_mask,
	target_encoder_text_hidden_states=target_encoder_text_hidden_states,
	target_text_attention_mask=target_text_attention_mask,
	target_speaker_embeds=target_speaker_embeds,
	target_lyric_token_ids=target_lyric_token_idx,
	target_lyric_mask=target_lyric_mask,
	src_latents=src_latents,
	random_generators=retake_random_generators, # more diversity
	infer_steps=infer_step,
	guidance_scale=guidance_scale,
	n_min=edit_n_min,
	n_max=edit_n_max,
	n_avg=edit_n_avg,
	)
	else:
	target_latents = self.text2music_diffusion_process(
	duration=audio_duration,
	encoder_text_hidden_states=encoder_text_hidden_states,
	text_attention_mask=text_attention_mask,
	speaker_embds=speaker_embeds,
	lyric_token_ids=lyric_token_idx,
	lyric_mask=lyric_mask,
	guidance_scale=guidance_scale,
	omega_scale=omega_scale,
	infer_steps=infer_step,
	random_generators=random_generators,
	scheduler_type=scheduler_type,
	cfg_type=cfg_type,
	guidance_interval=guidance_interval,
	guidance_interval_decay=guidance_interval_decay,
	min_guidance_scale=min_guidance_scale,
	oss_steps=oss_steps,
	encoder_text_hidden_states_null=encoder_text_hidden_states_null,
	use_erg_lyric=use_erg_lyric,
	use_erg_diffusion=use_erg_diffusion,
	retake_random_generators=retake_random_generators,
	retake_variance=retake_variance,
	add_retake_noise=add_retake_noise,
	guidance_scale_text=guidance_scale_text,
	guidance_scale_lyric=guidance_scale_lyric,
	repaint_start=repaint_start,
	repaint_end=repaint_end,
	src_latents=src_latents,
	audio2audio_enable=audio2audio_enable,
	ref_audio_strength=ref_audio_strength,
	ref_latents=ref_latents,
	)

	end_time = time.time()
	diffusion_time_cost = end_time - start_time
	start_time = end_time

	output_paths = self.latents2audio(
	latents=target_latents,
	target_wav_duration_second=audio_duration,
	save_path=save_path,
	format=format,
	)

	end_time = time.time()
	latent2audio_time_cost = end_time - start_time
	timecosts = {
	"preprocess": preprocess_time_cost,
	"diffusion": diffusion_time_cost,
	"latent2audio": latent2audio_time_cost,
	}

	input_params_json = {
	"lora_name_or_path": lora_name_or_path,
	"task": task,
	"prompt": prompt if task != "edit" else edit_target_prompt,
	"lyrics": lyrics if task != "edit" else edit_target_lyrics,
	"audio_duration": audio_duration,
	"infer_step": infer_step,
	"guidance_scale": guidance_scale,
	"scheduler_type": scheduler_type,
	"cfg_type": cfg_type,
	"omega_scale": omega_scale,
	"guidance_interval": guidance_interval,
	"guidance_interval_decay": guidance_interval_decay,
	"min_guidance_scale": min_guidance_scale,
	"use_erg_tag": use_erg_tag,
	"use_erg_lyric": use_erg_lyric,
	"use_erg_diffusion": use_erg_diffusion,
	"oss_steps": oss_steps,
	"timecosts": timecosts,
	"actual_seeds": actual_seeds,
	"retake_seeds": actual_retake_seeds,
	"retake_variance": retake_variance,
	"guidance_scale_text": guidance_scale_text,
	"guidance_scale_lyric": guidance_scale_lyric,
	"repaint_start": repaint_start,
	"repaint_end": repaint_end,
	"edit_n_min": edit_n_min,
	"edit_n_max": edit_n_max,
	"edit_n_avg": edit_n_avg,
	"src_audio_path": src_audio_path,
	"edit_target_prompt": edit_target_prompt,
	"edit_target_lyrics": edit_target_lyrics,
	"audio2audio_enable": audio2audio_enable,
	"ref_audio_strength": ref_audio_strength,
	"ref_audio_input": ref_audio_input,
	}
	# save input_params_json
	for output_audio_path in output_paths:
	input_params_json_save_path = output_audio_path.replace(
	f".{format}", "_input_params.json"
	)
	input_params_json["audio_path"] = output_audio_path
	with open(input_params_json_save_path, "w", encoding="utf-8") as f:
	json.dump(input_params_json, f, indent=4, ensure_ascii=False)

	return output_paths + [input_params_json]