HunyuanImage-3-Base-INT8 / tokenizer_wrapper.py

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	# Licensed under the TENCENT HUNYUAN COMMUNITY LICENSE AGREEMENT (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# https://github.com/Tencent-Hunyuan/HunyuanImage-3.0/blob/main/LICENSE
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.
	# ==============================================================================

	import warnings
	import random
	from typing import List, Optional, Union, Dict, Any
	from collections import defaultdict
	from copy import deepcopy

	import numpy as np
	import torch
	import torch.nn.functional as F
	from transformers import AutoTokenizer
	from diffusers.utils import BaseOutput


	def default(value, default_value):
	return value if value is not None else default_value


	def ensure_list(value):
	if value is None:
	return []
	if isinstance(value, (list, tuple)):
	return list(value)
	return [value]


	class Resolution(object):
	def __init__(self, size, *args):
	if isinstance(size, str):
	if 'x' in size:
	size = size.split('x')
	size = (int(size[0]), int(size[1]))
	else:
	size = int(size)
	if len(args) > 0:
	size = (size, args[0])
	if isinstance(size, int):
	size = (size, size)

	self.h = self.height = size[0]
	self.w = self.width = size[1]
	self.r = self.ratio = self.height / self.width

	def __getitem__(self, idx):
	if idx == 0:
	return self.h
	elif idx == 1:
	return self.w
	else:
	raise IndexError(f'Index {idx} out of range')

	def __str__(self):
	return f'{self.h}x{self.w}'


	class ResolutionGroup(object):
	def __init__(self, base_size=None, step=None, align=1):
	self.align = align
	self.base_size = base_size
	assert base_size % align == 0, f'base_size {base_size} is not divisible by align {align}'
	if base_size is not None and not isinstance(base_size, int):
	raise ValueError(f'base_size must be None or int, but got {type(base_size)}')
	if step is None:
	step = base_size // 16
	if step is not None and step > base_size // 2:
	raise ValueError(f'step must be smaller than base_size // 2, but got {step} > {base_size // 2}')

	self.step = step
	self.data = self._calc_by_step()

	self.ratio = np.array([x.ratio for x in self.data])
	self.attr = ['' for _ in range(len(self.data))]
	self.prefix_space = 0

	def __len__(self):
	return len(self.data)

	def __getitem__(self, idx):
	return self.data[idx]

	def __repr__(self):
	prefix = self.prefix_space * ' '
	prefix_close = (self.prefix_space - 4) * ' '
	res_str = f'ResolutionGroup(base_size={self.base_size}, step={self.step}, data='
	attr_maxlen = max([len(x) for x in self.attr] + [5])
	res_str += \
	f'\n{prefix}ID: height width ratio {" " * max(0, attr_maxlen - 4)}count h/16 w/16 tokens\n{prefix}'
	res_str += \
	('\n' + prefix).join([f'{i:2d}: ({x.h:4d}, {x.w:4d}) {self.ratio[i]:.4f} {self.attr[i]:>{attr_maxlen}s} '
	f'({x.h // 16:3d}, {x.w // 16:3d}) {x.h // 16 * x.w // 16:6d}'
	for i, x in enumerate(self.data)])
	res_str += f'\n{prefix_close})'
	return res_str

	def _calc_by_step(self):
	assert self.align <= self.step, f'align {self.align} must be smaller than step {self.step}'

	min_height = self.base_size // 2
	min_width = self.base_size // 2
	max_height = self.base_size * 2
	max_width = self.base_size * 2

	resolutions = [Resolution(self.base_size, self.base_size)]

	cur_height, cur_width = self.base_size, self.base_size
	while True:
	if cur_height >= max_height and cur_width <= min_width:
	break

	cur_height = min(cur_height + self.step, max_height)
	cur_width = max(cur_width - self.step, min_width)
	resolutions.append(Resolution(cur_height // self.align * self.align, cur_width // self.align * self.align))

	cur_height, cur_width = self.base_size, self.base_size
	while True:
	if cur_height <= min_height and cur_width >= max_width:
	break

	cur_height = max(cur_height - self.step, min_height)
	cur_width = min(cur_width + self.step, max_width)
	resolutions.append(Resolution(cur_height // self.align * self.align, cur_width // self.align * self.align))

	resolutions = sorted(resolutions, key=lambda x: x.ratio)

	return resolutions

	def get_target_size(self, width, height):
	ratio = height / width
	idx = np.argmin(np.abs(self.ratio - ratio))
	reso = self.data[idx]
	return reso.w, reso.h

	def get_base_size_and_ratio_index(self, width, height):
	ratio = height / width
	idx = np.argmin(np.abs(self.ratio - ratio))
	return self.base_size, idx


	class ImageInfo:
	""" Class to store image information for processing and generation. """

	def __init__(
	self,
	image_type: str = None,
	image_tensor: torch.Tensor = None,
	image_width: int = None,
	image_height: int = None,
	token_width: int = None,
	token_height: int = None,
	image_token_length: int = None,
	base_size: int = None,
	ratio_index: int = None,
	**kwargs,
	):
	self.image_type = image_type
	self.image_tensor = image_tensor
	self.image_width = image_width
	self.w = image_width
	self.image_height = image_height
	self.h = image_height
	self.token_width = token_width
	self.tk_w = token_width
	self.token_height = token_height
	self.tk_h = token_height
	self.image_token_length = default(
	image_token_length,
	token_width * token_height if token_width is not None and token_height is not None else None
	)
	self.base_size = base_size
	self.ratio_index = ratio_index

	self.add_timestep_token = kwargs.get("add_timestep_token", True)
	self.add_guidance_token = kwargs.get("add_guidance_token", False)
	self.use_front_boi_token = kwargs.get("use_front_boi_token", True)
	self.add_image_shape_token = kwargs.get("add_image_shape_token", True)

	def __getitem__(self, key: str) -> Any:
	"""Allow dictionary-like access to attributes."""
	if hasattr(self, key):
	return getattr(self, key)
	raise KeyError(f"Key '{key}' not found in ImageInfo")

	def __setitem__(self, key: str, value: Any) -> None:
	"""Allow dictionary-like assignment to attributes."""
	if hasattr(self, key):
	setattr(self, key, value)
	else:
	raise KeyError(f"Key '{key}' not found in ImageInfo")

	def __contains__(self, key: str) -> bool:
	"""Check if the key exists in the ImageInfo object."""
	return hasattr(self, key)

	def __repr__(self):
	return (f"ImageInfo(image_type={self.image_type}, image_tensor={self.image_tensor}, "
	f"image_width={self.image_width}, image_height={self.image_height}, "
	f"token_width={self.token_width}, token_height={self.token_height}, "
	f"image_token_length={self.image_token_length}, "
	f"base_size={self.base_size}, ratio_index={self.ratio_index}")

	@property
	def meta_info(self):
	# Used for image sections of tkwrapper.encode_general()
	if self.image_type in ["vae", "gen_image"]:
	return dict(
	token_length=self.image_token_length,
	add_timestep_token=self.add_timestep_token,
	add_guidance_token=self.add_guidance_token,
	use_front_boi_token=self.use_front_boi_token,
	add_image_shape_token=self.add_image_shape_token,
	base_size=self.base_size,
	ratio_idx=self.ratio_index,
	# for rope 2d
	token_height=self.token_height,
	token_width=self.token_width,
	# for bc
	image_height=self.image_height,
	image_width=self.image_width,
	)
	elif self.image_type in ["vit"]:
	return dict(
	token_length=self.image_token_length,
	use_front_boi_token=self.use_front_boi_token,
	add_image_shape_token=self.add_image_shape_token,
	# for rope 2d
	token_height=self.token_height,
	token_width=self.token_width,
	# for bc
	image_height=self.image_height,
	image_width=self.image_width,
	)
	else:
	raise ValueError(f"Unknown image type '{self.image_type}'")

	@property
	def num_special_tokens(self):
	if self.args is None:
	raise ValueError("meta_info requires `args` attribute to be set.")
	if self.image_type in ["vae", "src_image", "gen_image"]:
	count = (
	2 + # <boi> + <eoi> or <src_boi> + <src_eoi>
	(1 if self.add_timestep_token else 0) +
	(1 if self.add_guidance_token else 0) +
	(2 if self.add_image_shape_token else 0)
	)
	else:
	raise ValueError(f"Unknown image_type: {self.image_type}")
	return count

	def copy(self, copy_image_tensor=True):
	if copy_image_tensor and self.image_tensor is None:
	raise ValueError("image_tensor is None, cannot copy")
	return ImageInfo(
	image_type=self.image_type,
	image_tensor=self.image_tensor.clone() if copy_image_tensor else None,
	image_width=self.image_width,
	image_height=self.image_height,
	token_width=self.token_width,
	token_height=self.token_height,
	image_token_length=self.image_token_length,
	base_size=self.base_size,
	ratio_index=self.ratio_index,
	)

	def zeros_(self):
	self.image_tensor = torch.zeros_like(self.image_tensor)


	class ImageTensor(torch.Tensor):
	# This class is just for type hinting purposes. Attribute `i` should be defined
	# as an instance attribute of the torch.Tensor instance, like: tensor.i = ImageInfo(...)
	i: ImageInfo
	vision_encoder_kwargs: dict


	class JointImageInfo(object):
	def __init__(self, vae_image_info: ImageInfo, vision_image_info: ImageInfo, vision_encoder_kwargs: dict = None):
	self.vae_image_info = vae_image_info
	self.vision_image_info = vision_image_info
	self.vision_encoder_kwargs = vision_encoder_kwargs

	# Define key attributes to align with ImageInfo for uniformity
	self.image_type = "joint_image"
	self.image_token_length = vae_image_info.image_token_length + vision_image_info.image_token_length

	self.add_timestep_token = vae_image_info.add_timestep_token
	self.use_front_boi_token = vae_image_info.use_front_boi_token
	self.add_image_shape_token = vae_image_info.add_image_shape_token

	def __repr__(self):
	return f"JointImageInfo(vae_image={self.vae_image_info}, vision_image={self.vision_image_info})"

	@property
	def meta_info(self):
	# Used for image sections of tkwrapper.encode_general()
	return dict(
	token_length=[self.vae_image_info.image_token_length, self.vision_image_info.image_token_length],
	add_timestep_token=self.add_timestep_token,
	use_front_boi_token=self.use_front_boi_token,
	add_image_shape_token=self.add_image_shape_token,
	base_size=self.vae_image_info.base_size,
	ratio_idx=self.vae_image_info.ratio_index,
	# for rope 2d
	token_height=[self.vae_image_info.token_height, self.vision_image_info.token_height],
	token_width=[self.vae_image_info.token_width, self.vision_image_info.token_width],
	# for bc
	image_height=[self.vae_image_info.image_height, self.vision_image_info.image_height],
	image_width=[self.vae_image_info.image_width, self.vision_image_info.image_width],
	)

	@property
	def num_special_tokens(self):
	return (
	2 + # <boi> + <eoi>
	(1 if self.add_timestep_token else 0) +
	(2 if self.add_image_shape_token else 0) +
	1 # <joint_image_sep>
	)

	def copy(self, copy_image_tensor=True):
	if copy_image_tensor and (
	self.vae_image_info.image_tensor is None or self.vision_image_info.image_tensor is None):
	raise ValueError("image_tensor is None, cannot copy")
	return JointImageInfo(
	self.vae_image_info.copy(copy_image_tensor),
	self.vision_image_info.copy(copy_image_tensor),
	self.vision_encoder_kwargs,
	)

	def zeros_(self):
	self.vae_image_info.zeros_()
	self.vision_image_info.zeros_()


	class JointImage(object):
	def __init__(self, vae_image: ImageTensor, vision_image: ImageTensor):
	self.vae_image = vae_image
	self.vision_image = vision_image
	self.i = JointImageInfo(vae_image.i, vision_image.i)


	class TokenizerEncodeOutput(BaseOutput):
	tokens: torch.Tensor = None
	timestep_scatter_index: Optional[torch.Tensor] = None
	guidance_scatter_index: Optional[torch.Tensor] = None
	text_slices: Optional[List[slice]] = None
	gen_image_slices: Optional[List[slice]] = None
	joint_image_slices: Optional[List[slice]] = None
	cond_vae_image_slices: Optional[List[slice]] = None
	cond_vit_image_slices: Optional[List[slice]] = None
	text_mask: Optional[torch.Tensor] = None
	gen_image_mask: Optional[torch.Tensor] = None
	cond_vae_image_mask: Optional[torch.Tensor] = None
	cond_vit_image_mask: Optional[torch.Tensor] = None
	real_pos: Optional[torch.Tensor] = None
	all_image_slices: Optional[List[slice]] = None
	cond_timestep_scatter_index: Optional[torch.Tensor] = None
	gen_timestep_scatter_index: Optional[torch.Tensor] = None


	class Conversation:
	roles: List[str] = ["User", "Assistant"]
	sep: str = "\n\n"


	class TokenizerWrapper(object):
	def __init__(self, tokenizer):
	if isinstance(tokenizer, str):
	self.tokenizer = AutoTokenizer.from_pretrained(tokenizer)
	else:
	self.tokenizer = tokenizer

	# Define short names
	self.bos_token_id = self.tokenizer.bos_token_id
	self.eos_token_id = self.tokenizer.eos_token_id
	self.pad_token_id = self.tokenizer.pad_token_id
	self.boi_token_id = self.tokenizer.convert_tokens_to_ids("<boi>")
	self.eoi_token_id = self.tokenizer.convert_tokens_to_ids("<eoi>")
	self.img_token_id = self.tokenizer.convert_tokens_to_ids("<img>")
	self.cfg_token_id = self.tokenizer.convert_tokens_to_ids("<cfg>")
	self.end_answer_token_id = self.tokenizer.convert_tokens_to_ids("</answer>")
	self.end_recaption_token_id = self.tokenizer.convert_tokens_to_ids("</recaption>")
	self.ratio_token_offset = self.tokenizer.convert_tokens_to_ids("<img_ratio_0>")
	self.special_token_map = self.tokenizer.added_tokens_encoder

	def pad(self, tensor_list, dim=0, pad_val=None):
	if pad_val is None:
	pad_val = self.pad_token_id
	max_len = max([t.shape[dim] for t in tensor_list])
	padded_tensor_list = []
	for t in tensor_list:
	if t.shape[dim] < max_len:
	assert pad_val is not False, "Not allowed pad."
	t = F.pad(t, (0, max_len - t.shape[dim]), value=pad_val)
	padded_tensor_list.append(t)
	return padded_tensor_list

	def encode(self, args, *kwargs):
	return self.tokenizer.encode(args, *kwargs)

	def decode(self, args, *kwargs):
	return self.tokenizer.decode(args, *kwargs)

	def encode_text(
	self,
	*texts,
	uncond_enabled: Optional[Union[bool, List[bool]]] = None,
	uncond_p: Optional[float] = None,
	max_length: Optional[int] = None,
	pad: Optional[str] = None,
	return_lengths: bool = False,
	):
	"""
	Encode text and image for AR-like model training of the text-to-image/instruction tuning tasks.
	Support encode multiple texts at once. Each text can be separately conditioned or unconditioned
	based on the uncond_flags and a uniform uncond_p.
	<bos> token is always prepended to the text tokens.

	Parameters
	----------
	texts: str or List[str]
	List of texts to be encoded.
	uncond_enabled: bool or List[bool]
	List of flags to indicate whether the text should be unconditioned.
	If False, the text will never be unconditioned.
	If True, the text will be unconditioned with uncond_p.
	uncond_p: float
	Probability to the unconditional text. Only works when uncond_enabled is True.
	max_length: int
	Maximum length of the encoded text.
	pad: Optional[str]
	Padding method. Can be 'left' or 'right'.
	return_lengths: bool
	Whether to return the length of each encoded text.
	"""
	if pad is not None:
	assert max_length is not None, "max_length should be provided when pad is not None."

	if uncond_enabled is None:
	uncond_enabled = [True] * len(texts)
	elif isinstance(uncond_enabled, bool):
	uncond_enabled = [uncond_enabled] * len(texts)
	if len(uncond_enabled) != len(texts):
	print(uncond_enabled, texts)
	assert len(uncond_enabled) == len(texts), (
	f"Length of uncond_flags should be equal to the number of texts, "
	f"but got {len(uncond_enabled)} and {len(texts)}."
	)

	# Prepare text/uncond tokens
	# TODO: If len(texts) > 1, such as instruction + prompt in inpainting, we need to determine how to do uncond.
	# Now all texts will be cond or uncond at the same time.
	do_uncond_drop = (uncond_p is not None) and (random.random() < uncond_p)
	text_tokens, lengths = [], []
	cum_length = 0
	for text, uncond_flag in zip(texts, uncond_enabled):
	# If reach the max_length and there still have unencoded texts, give a warning message and break the loop.
	if max_length is not None and cum_length >= max_length:
	warnings.warn(
	f"Text length exceeds the max_length({max_length}). The remaining texts will be ignored: "
	f"{text[:80]}..."
	)
	break
	# Set add_special_tokens=False to avoid adding <bos> token in some LLMs.
	if isinstance(text, str):
	text_token = self.tokenizer.encode(text, add_special_tokens=False)
	else:
	text_token = text
	if uncond_flag and do_uncond_drop:
	text_token = [self.cfg_token_id] * len(text_token)
	# Cutoff the text by max_length if necessary
	if max_length is not None and (cum_length + len(text_token)) > max_length:
	text_token = text_token[:max_length - cum_length]
	text_tokens.extend(text_token)
	lengths.append(len(text_token))
	cum_length += len(text_token)

	# Prepend/Append <pad> tokens if applicable
	if pad is not None and (pad_length := max_length - len(text_tokens)) > 0:
	if pad == 'left':
	text_tokens = [self.pad_token_id] * pad_length + text_tokens
	elif pad == 'right':
	text_tokens = text_tokens + [self.pad_token_id] * pad_length
	else:
	raise ValueError(f"Unsupported padding method: {pad}.")

	if return_lengths:
	return text_tokens, lengths
	return text_tokens

	@staticmethod
	def _check_key_number_matched(keys, data):
	# Assert keys and token_source are matched
	assert set(keys) == set(data.keys()), (
	f"Keys in the template and token source should be matched, but got {set(keys)} and {list(data.keys())}."
	)
	key_counts = {k: 0 for k in keys}
	for key in keys:
	key_counts[key] += 1
	for key, count in key_counts.items():
	assert len(data[key]) == count, (
	f"Number of `{key}` in the token source should be matched with the template, but got "
	f"{data[key]}({len(data[key])}) and {count}."
	)

	def _add_image_meta_info_token(self, token_seq, token_count, extra_token_pos, add_timestep_token=False,
	add_image_shape_token=False, base_size=None, ratio_idx=None, image_type=None,
	add_guidance_token=False):
	if add_image_shape_token:
	token_seq.extend([
	self.special_token_map[f"<img_size_{base_size}>"],
	self.special_token_map[f"<img_ratio_{ratio_idx}>"]
	])
	token_count += 2
	if add_timestep_token:
	token_seq.extend([self.special_token_map["<timestep>"]])
	extra_token_pos['timestep'].append(token_count)
	if image_type is not None:
	if image_type == "gen_image":
	extra_token_pos['gen_timestep'].append(token_count)
	elif image_type in ["joint_image"]:
	extra_token_pos['cond_timestep'].append(token_count)
	else:
	raise ValueError(f"Unsupported image type: {image_type}.")
	token_count += 1
	if add_guidance_token:
	token_seq.extend([self.special_token_map["<guidance>"]])
	extra_token_pos['guidance'].append(token_count)
	token_count += 1
	return token_count

	@staticmethod
	def _shorten_text(text):
	import re
	text = re.sub(r"(<img>)+", lambda m: f"[<img>]{{{len(m.group(0)) // 5}}}", text)
	text = re.sub(r"(<pad>)+", lambda m: f"[<pad>]{{{len(m.group(0)) // 5}}}", text)
	return text

	def encode_sequence(
	self,
	template: str,
	token_source: Dict[str, List],
	total_length=None,
	add_timestep_token=False,
	add_guidance_token=False,
	last_key_only_prefix=False,
	add_eos=True,
	use_front_boi_token=True,
	add_pad=True,
	add_bos=True,
	drop_last: Union[str, bool] = 'auto',
	add_image_shape_token=False,
	):
	"""
	Encode a sequence based on the template (e.g., `text-image` for t2i, `text-image-image` for instruction tuning)
	and token source.

	Parameters
	----------
	template: str
	Template of the sequence. E.g., "text-gen_image" means the sequence is composed of text and an image.
	"text-text-gen_image" means the sequence is composed of two sections of text and an image.
	token_source: Dict[str, List]
	Token source for each key in the template, in order.
	- text: List[Dict].
	- gen_image: List[Dict].
	- joint_image: List[Dict].
	total_length: int
	Total length of the encoded sequence, include padding tokens.
	add_timestep_token: bool
	Whether to add timestep token before the image tokens.
	(Right after the <img_ratio_><img_size_> tokens)
	add_guidance_token: bool
	Whether to add guidance token before the image tokens.
	last_key_only_prefix: bool
	Whether to only use the modal prefix in the last key.
	add_eos: bool or 'auto'
	Whether to add eos token at the end of the sequence. If True, always add eos token. If 'auto',
	add eos token only when the total_length is not reached and the last token is not <eos>.
	use_front_boi_token: bool:
	Whether to put the <boi> token at the front of iw, ih and timestep tokens.
	add_pad: bool or 'auto'
	Whether to add padding tokens to the sequence. If True and total_length is not reached, add padding tokens.
	add_bos: bool
	Whether to add bos token at the beginning of the sequence.
	drop_last: bool or 'auto'
	- If auto, drop last tokens exceeding the total_length if the total_length is provided. If cut point is
	in the middle of the image tokens, an error will raised.
	- If True, drop last tokens exceeding the total_length. If cut point is in the middle of the image tokens,
	all the successive image tokens will be dropped.
	- If False, keep the last tokens exceeding the total_length, even if the total_length is reached.
	add_image_shape_token: bool
	Whether to add image shape token before the image tokens. (Right before the <timestep> token)

	Returns
	-------
	token_seq: list
	Encoded token sequence.
	extra_token_pos: dict
	Positions of extra tokens.
	"""
	if last_key_only_prefix:
	assert add_eos is not True, "add_eos should not be True when last_key_only_prefix is True."
	if drop_last is True and total_length is None:
	raise ValueError("total_length should be provided when drop_last is True.")

	keys = template.split('-')
	modal_length = len(keys)
	index_indicator = {k: 0 for k in token_source}
	for k, v in token_source.items():
	assert isinstance(v, (list, tuple)), (
	f"Value of `{k}` in the token source should be a list or tuple, but got {type(v)}."
	)
	self._check_key_number_matched(keys, token_source)

	token_seq = []
	token_count = 0
	extra_token_pos = defaultdict(list)
	if add_bos:
	token_seq.append(self.bos_token_id)
	token_count += 1
	# If drop_last is True, we check the token_count on the fly and exit the loop if the total_length is reached.
	# This check is only applied to the block tokens. Block tokens mean the tokens that are unsplittable, like
	# image tokens. Text tokens are splittable, so we don't need to check the token_count for text.
	# If the loop is broken by drop_last, we don't add the eos token at the end because the sequence is not
	# complete.
	drop_last_break = False
	for i, key in enumerate(keys):
	source = token_source[key][index_indicator[key]]
	if key == "text":
	token_seq.extend(source) # text token sequence
	extra_token_pos["<text>_start"].append(token_count)
	token_count += len(source)
	extra_token_pos["<text>_end"].append(token_count - 1)

	elif key == "gen_image":
	if isinstance(source, int):
	source = {'length': source}
	extra_count = 2 + (
	1 if source.get('timestep', add_timestep_token) else 0) + (
	1 if source.get('guidance', add_guidance_token) else 0) + (
	2 if source.get('image_shape', add_image_shape_token) else 0
	)
	if drop_last is True and token_count + extra_count + source['length'] > total_length:
	drop_last_break = True
	break
	if source.get('front_boi', use_front_boi_token):
	token_seq.append(self.boi_token_id)
	extra_token_pos["boi"].append(token_count)
	token_count += 1
	token_count = self._add_image_meta_info_token(
	token_seq=token_seq,
	token_count=token_count,
	extra_token_pos=extra_token_pos,
	add_timestep_token=source.get('timestep', add_timestep_token),
	add_guidance_token=source.get('guidance', add_guidance_token),
	add_image_shape_token=source.get('image_shape', add_image_shape_token),
	base_size=source.get('base_size'),
	ratio_idx=source.get('ratio_idx'),
	image_type=key,
	)
	if not source.get('front_boi', use_front_boi_token):
	token_seq.append(self.boi_token_id)
	extra_token_pos["boi"].append(token_count)
	token_count += 1
	if last_key_only_prefix and i == modal_length - 1:
	pass # for AR inference
	else:
	token_seq.extend(
	[self.img_token_id] * source['length'] + # token number
	[self.eoi_token_id]
	)
	extra_token_pos["<img>_start"].append(token_count)
	extra_token_pos["<all_img>_start"].append(token_count)
	token_count += source['length']
	extra_token_pos["<img>_end"].append(token_count - 1)
	extra_token_pos["<all_img>_end"].append(token_count - 1)
	extra_token_pos["eoi"].append(token_count)
	token_count += 1 # <eoi>

	elif key == "joint_image":
	assert isinstance(source['length'], list) and len(
	source['length']) == 2, "joint_image length should be a list of two integers"
	extra_count = 2 + 1 + ( # boi, eoi, joint_img_sep
	1 if source.get('timestep', add_timestep_token) else 0) + (
	2 if source.get('image_shape', add_image_shape_token) else 0
	)
	if drop_last is True and token_count + extra_count + sum(source['length']) > total_length:
	drop_last_break = True
	break
	if source.get('front_boi', use_front_boi_token):
	token_seq.append(self.boi_token_id) # Use patched boi for Janus, otherwise useing default <boi>
	extra_token_pos["boi"].append(token_count)
	token_count += 1
	token_count = self._add_image_meta_info_token(
	token_seq=token_seq,
	token_count=token_count,
	extra_token_pos=extra_token_pos,
	add_timestep_token=source.get('timestep', add_timestep_token),
	add_image_shape_token=source.get('image_shape', add_image_shape_token),
	base_size=source.get('base_size'),
	ratio_idx=source.get('ratio_idx'),
	image_type=key,
	)
	if not source.get('front_boi', use_front_boi_token):
	token_seq.append(self.boi_token_id)
	extra_token_pos["boi"].append(token_count)
	token_count += 1
	if last_key_only_prefix and i == modal_length - 1:
	pass # for AR inference
	else:
	token_seq.extend(
	[self.img_token_id] * source['length'][0]
	)
	extra_token_pos["<vae_img>_start"].append(token_count)
	extra_token_pos["<joint_img>_start"].append(token_count)
	extra_token_pos["<all_img>_start"].append(token_count)
	token_count += source['length'][0]
	extra_token_pos["<vae_img>_end"].append(token_count - 1)
	extra_token_pos["<all_img>_end"].append(token_count - 1)

	token_seq.extend(
	[self.special_token_map["<joint_img_sep>"]]
	)
	extra_token_pos["joint_img_sep"].append(token_count)
	token_count += 1

	token_seq.extend(
	[self.img_token_id] * source['length'][1]
	)
	extra_token_pos["<vit_img>_start"].append(token_count)
	extra_token_pos["<all_img>_start"].append(token_count)
	token_count += source['length'][1]
	extra_token_pos["<vit_img>_end"].append(token_count - 1)
	extra_token_pos["<joint_img>_end"].append(token_count - 1)
	extra_token_pos["<all_img>_end"].append(token_count - 1)

	token_seq.extend(
	[self.eoi_token_id]
	)
	extra_token_pos["eoi"].append(token_count)
	token_count += 1 # <eoi>

	else:
	raise ValueError(f"Not supported key: {key}")
	index_indicator[key] += 1

	if add_eos is True and not drop_last_break:
	# Typically used for t2i task.
	token_seq.append(self.eos_token_id)
	extra_token_pos["eos"].append(token_count)
	token_count += 1
	elif add_eos == 'auto' and not drop_last_break:
	# Typically used for lm and mmu task.
	if token_seq[-1] != self.eos_token_id and (total_length is None or token_count < total_length):
	token_seq.append(self.eos_token_id)
	extra_token_pos["eos"].append(token_count)
	token_count += 1

	if total_length:
	# Check token count and clip sequence if necessary
	if token_count > total_length and drop_last:
	# Assert clip position is not in the middle of the block-wise tokens (gen_image, joint_image)
	for start_key, end_key in [
	("<img>_start", "<img>_end"), ("<joint_img>_start", "<joint_img>_end"),
	("<vae_img>_start", "<vae_img>_end"), ("<vit_img>_start", "<vit_img>_end"),
	]:
	if start_key in extra_token_pos and end_key in extra_token_pos:
	assert all(
	(start > total_length or end + 1 < total_length)
	for start, end in zip(extra_token_pos[start_key], extra_token_pos[end_key])
	), ("Clip position should not be in the middle of the image tokens.\n"
	f"Below is the text:\n{self._shorten_text(self.tokenizer.decode(token_seq))}")
	token_seq = token_seq[:total_length]

	# Pad the sequence if necessary
	pad_num = max(0, total_length - len(token_seq))
	if add_pad and pad_num:
	token_seq.extend([self.pad_token_id] * pad_num)
	extra_token_pos["first_pad"].append(token_count)

	return token_seq, extra_token_pos

	def batch_gen_infer(
	self,
	infer_fn,
	prompt_list: list,
	negative_prompt_list: list = None,
	infer_fn_kwargs_list: List[Dict[str, int]] = None,
	do_classifier_free_guidance=False,
	condition_repeat_times: int = 1,
	uncondition_repeat_times: int = 1,
	):
	"""
	Batch inference for the AR-like model training of the text-to-image/instruction tuning tasks.

	Parameters
	----------
	infer_fn: callable
	Inference function to encode the prompt.
	prompt_list: list
	List of prompts. Each element can be a single prompt or a list of prompts passed to the infer_fn.
	negative_prompt_list: list
	List of negative prompts. Only used when do_classifier_free_guidance is True. If None, will use <cfg>
	token sequence as negative prompt.
	infer_fn_kwargs_list: List[Dict[str, int]]
	List of keyword arguments for the infer_fn.
	do_classifier_free_guidance: bool
	Whether to do classifier-free guidance.
	condition_repeat_times: int
	Support multi-condition.
	uncondition_repeat_times: int
	Support multi-uncondition.
	"""
	if infer_fn_kwargs_list is None:
	infer_fn_kwargs_list = [{} for _ in prompt_list]

	# [n_output, bsz]
	cond_results_list = None
	uncond_results_list = None
	output_type_list = []

	for prompt_idx, (prompt, infer_fn_kwargs) in enumerate(zip(prompt_list, infer_fn_kwargs_list)):
	if not isinstance(prompt, (list, tuple)):
	prompt = [prompt]
	cond_kwargs = {"uncond_p": 0.0} if do_classifier_free_guidance else {}
	results = infer_fn(
	*prompt,
	**infer_fn_kwargs,
	**cond_kwargs,
	)
	output_type_list.append((type(results), len(results) if isinstance(results, (list, tuple)) else 1))
	if isinstance(results, dict):
	raise ValueError("Make batch on dict is not supported. Please return list or tuple for infer_fn.")
	if not isinstance(results, (list, tuple)):
	results = (results,)
	if cond_results_list is None:
	cond_results_list = [[] for _ in results]
	uncond_results_list = [[] for _ in results]
	for i, result in enumerate(results):
	cond_results_list[i].append(result)

	if do_classifier_free_guidance:
	if negative_prompt_list is None:
	uncond_kwargs = {"uncond_p": 1.0}
	uncond_results = infer_fn(
	*prompt,
	**infer_fn_kwargs,
	**uncond_kwargs,
	)
	else:
	negative_prompt = negative_prompt_list[prompt_idx]
	if not isinstance(negative_prompt, (list, tuple)):
	negative_prompt = [negative_prompt]
	uncond_results = infer_fn(
	*negative_prompt,
	**infer_fn_kwargs,
	)
	if isinstance(uncond_results, TokenizerEncodeOutput):
	uncond_results_list.append(uncond_results)
	else:
	for i, result in enumerate(uncond_results):
	uncond_results_list[i].append(result)

	assert all(output_type_list[0] == n for n in output_type_list), \
	f"Number of outputs should be equal for all samples, but got {output_type_list}."
	output_type, output_num = output_type_list[0]

	def make_batch(batch_cond_item, batch_uncond_item):
	# Process each output item to make batch
	first = batch_cond_item[0] # The first element in the batch
	if isinstance(first, torch.Tensor):
	stacked_item = torch.stack(self.pad(
	batch_cond_item * condition_repeat_times + batch_uncond_item * uncondition_repeat_times,
	))

	elif first is None:
	assert all(item is None for item in batch_cond_item + batch_uncond_item), \
	(f"The first cond item is None, but some items are not None:\n\n"
	f"condition: {batch_cond_item}\n\n"
	f"uncondition: {batch_uncond_item}")
	stacked_item = None

	elif isinstance(first, (list, tuple)):
	# If the output item is a list or tuple, we treat it as a whole, and won't make nested batch any more.
	stacked_item = batch_cond_item * condition_repeat_times + batch_uncond_item * uncondition_repeat_times

	elif isinstance(first, TokenizerEncodeOutput):
	stacked_item = {}
	# Traverse not-None attributes
	for key in list(first.keys()):
	merged_list = [cond_item[key] for cond_item in batch_cond_item] * condition_repeat_times + \
	[uncond_item[key] for uncond_item in batch_uncond_item] * uncondition_repeat_times
	if isinstance(first[key], torch.Tensor):
	if 'mask' in key:
	pad_val = 0.0
	elif key == 'tokens':
	pad_val = self.special_token_map["<pad>"]
	else:
	pad_val = False # Should not pad for other tensors
	stacked_item[key] = torch.stack(self.pad(merged_list, pad_val=pad_val), dim=0)
	elif isinstance(first[key], list):
	stacked_item[key] = merged_list
	elif first[key] is None:
	pass
	else:
	raise ValueError(f"Unsupported type of {key}: {type(first[key])}.")
	stacked_item = TokenizerEncodeOutput(stacked_item)

	else:
	raise TypeError(f"Making batch on type {type(first)} is not supported.")

	return stacked_item

	stacked_outputs = []
	for cond_results, uncond_results in zip(cond_results_list, uncond_results_list):
	stacked_outputs.append(make_batch(cond_results, uncond_results))

	if output_type == list:
	return stacked_outputs
	elif output_type == tuple:
	return tuple(stacked_outputs)
	elif output_num == 1:
	return stacked_outputs[0]
	else:
	raise ValueError(f"Unsupported output type: {output_type}.")

	@staticmethod
	def parse_extra_token_pos(extra_token_pos, prefix, tokens, rng=None):
	if rng is None:
	rng = slice(None)
	image_slices = [
	slice(start, end + 1)
	for start, end in zip(extra_token_pos[f'<{prefix}>_start'][rng], extra_token_pos[f'<{prefix}>_end'][rng])
	] if f'<{prefix}>_start' in extra_token_pos and f'<{prefix}>_end' in extra_token_pos else []
	if image_slices:
	image_mask = torch.zeros_like(tokens, dtype=torch.bool)
	for image_slice in image_slices:
	image_mask[image_slice] = True
	else:
	image_mask = None
	return image_slices, image_mask

	def encode_general(
	self,
	sections: Optional[List[Dict[str, Any]]] = None,
	max_token_length: Optional[int] = None,
	add_eos='auto',
	use_text_mask=True,
	add_pad='auto',
	add_bos=True,
	drop_last='auto',
	):
	"""
	General encode function to encode a sequence with multiple sections of text and images.
	Each section is a dict with a `type` key and other keys depending on the type.
	Supported section types:
	- text: dict with keys:
	- text: str or List[int], text to be encoded. Either `text` or `tokens` should be provided.
	- tokens: List[int], pre-encoded text tokens. Either `text` or `tokens` should be provided.
	- uncond_enabled: bool, whether to enable uncondition for this text section.
	- uncond_p: float, probability to drop the text section for uncondition.
	- max_length: int, maximum length of the text section.
	- ignore: bool, whether to ignore this text section in the text mask.
	- start_offset: int, start offset of the text mask.
	- end_offset: int, end offset of the text mask.
	- gen_image: dict with keys:
	- token_length: int, number of image tokens.
	- add_timestep_token: bool, whether to add timestep token before the image tokens.
	- add_guidance_token: bool, whether to add guidance token before the image tokens.
	- use_front_boi_token: bool, whether to put the <boi> token at the front of size, ratio and timestep tokens.
	- add_image_shape_token: bool, whether to add image shape token before the image tokens.
	- base_size: int, base size of the image.
	- ratio_idx: int, ratio index of the image.
	- joint_image: dict with keys:
	- token_length: List[int], number of image tokens for the two images.
	- add_timestep_token: bool, whether to add timestep token before the image tokens.
	- use_front_boi_token: bool, whether to put the <boi> token at the front of size, ratio and timestep tokens.
	- add_image_shape_token: bool, whether to add image shape token before the image tokens.
	- base_size: int, base size of the image.
	- ratio_idx: int, ratio index of the image.

	Parameters
	----------
	sections: List[Dict[str, Any]]
	List of sections to be encoded.
	max_token_length: int
	Maximum length of the encoded token sequence.
	add_eos: bool or 'auto'
	Whether to add eos token at the end of the sequence. If True, always add eos
	token. If 'auto', add eos token only when the total_length is not reached and the last token is not <eos>.
	use_text_mask: bool
	Whether to generate text mask.
	add_pad: bool or 'auto'
	Whether to add padding tokens to the sequence. If True and total_length is not reached,
	add padding tokens.
	add_bos: bool
	Whether to add bos token at the beginning of the sequence.
	drop_last: bool or 'auto'
	- If auto, drop last tokens exceeding the total_length if the total_length is provided.
	If cut point is in the middle of the image tokens, an error will raised.
	- If True, drop last tokens exceeding the total_length. If cut point is in the
	middle of the image tokens, all the successive image tokens will be dropped.
	- If False, keep the last tokens exceeding the total_length, even if the total_length
	is reached.

	Returns
	-------
	TokenizerEncodeOutput
	Encoded token sequence and extra information.
	"""
	if sections is None:
	raise ValueError("sections must be provided.")
	template = '-'.join([section['type'] for section in sections])

	sections = deepcopy(sections)
	token_source = defaultdict(list)
	text_mask_specs = []
	for section in sections:
	if section['type'] == 'text':
	text = self.encode_text(
	section['text'] if 'text' in section else section['tokens'],
	uncond_enabled=section.get('uncond_enabled'),
	uncond_p=section.get('uncond_p'),
	max_length=section.get('max_length'),
	)
	token_source['text'].append(text)
	text_mask_specs.append(dict(
	ignore=section.get('ignore', False),
	start_offset=section.get('start_offset', 0),
	end_offset=section.get('end_offset', 0),
	))
	elif section['type'] == 'gen_image':
	token_source['gen_image'].append(dict(
	length=section['token_length'],
	timestep=section.get('add_timestep_token', False),
	guidance=section.get('add_guidance_token', False),
	front_boi=section.get('use_front_boi_token', False),
	image_shape=section.get('add_image_shape_token', False),
	base_size=section.get('base_size'),
	ratio_idx=section.get('ratio_idx'),
	))
	elif section['type'] == 'joint_image':
	token_source['joint_image'].append(dict(
	length=section['token_length'],
	timestep=section.get('add_timestep_token', False),
	front_boi=section.get('use_front_boi_token', False),
	image_shape=section.get('add_image_shape_token', False),
	base_size=section.get('base_size'),
	ratio_idx=section.get('ratio_idx'),
	))
	else:
	raise ValueError(f"Invalid section type: {section['type']}")

	# Combine text and image tokens
	full_token_seq, extra_token_pos = self.encode_sequence(
	template=template,
	token_source=dict(token_source),
	total_length=max_token_length,
	add_eos=add_eos,
	add_pad=add_pad,
	add_bos=add_bos,
	drop_last=drop_last,
	)
	full_seq_token_tensor = torch.tensor(full_token_seq, dtype=torch.long)

	timestep_scatter_index = torch.tensor(extra_token_pos['timestep'], dtype=torch.long) \
	if 'timestep' in extra_token_pos else None
	guidance_scatter_index = torch.tensor(extra_token_pos['guidance'], dtype=torch.long) \
	if 'guidance' in extra_token_pos else None
	cond_timestep_scatter_index = torch.tensor(extra_token_pos['cond_timestep'], dtype=torch.long) \
	if 'cond_timestep' in extra_token_pos else None
	gen_timestep_scatter_index = torch.tensor(extra_token_pos['gen_timestep'], dtype=torch.long) \
	if 'gen_timestep' in extra_token_pos else None

	# Gen image mask
	gen_image_slices, gen_image_mask = self.parse_extra_token_pos(extra_token_pos, 'img', full_seq_token_tensor)
	# Joint image
	joint_image_slices, _ = self.parse_extra_token_pos(extra_token_pos, 'joint_img', full_seq_token_tensor)
	# Conditional vae image
	cond_vae_image_slices, cond_vae_image_mask = self.parse_extra_token_pos(
	extra_token_pos, 'vae_img', full_seq_token_tensor)
	# Conditional vit image
	cond_vit_image_slices, cond_vit_image_mask = self.parse_extra_token_pos(
	extra_token_pos, 'vit_img', full_seq_token_tensor)
	# All image slices (gen_image, joint_image)
	all_image_slices = [
	slice(start, end + 1)
	for start, end in zip(extra_token_pos['<all_img>_start'], extra_token_pos['<all_img>_end'])
	] if '<all_img>_start' in extra_token_pos and '<all_img>_end' in extra_token_pos else []

	# Text mask
	text_slices = [
	slice(start, end + 1)
	for start, end in zip(extra_token_pos['<text>_start'], extra_token_pos['<text>_end'])
	] if '<text>_start' in extra_token_pos and '<text>_end' in extra_token_pos else []
	assert len(text_slices) <= len(text_mask_specs), \
	(f"Number of text slices ({len(text_slices)}) should be less than or equal to "
	f"number of text mask specs ({len(text_mask_specs)})")
	if use_text_mask:
	text_mask = torch.zeros_like(full_seq_token_tensor, dtype=torch.float32)
	for text_slice, mask_spec in zip(text_slices, text_mask_specs):
	if not mask_spec['ignore']:
	real_slice = slice(
	text_slice.start + mask_spec['start_offset'],
	text_slice.stop + mask_spec['end_offset']
	)
	text_mask[real_slice] = 1.0
	else:
	text_mask = None

	# real_pos is the first position of the <pad> token
	real_pos = torch.tensor(extra_token_pos.get('first_pad', [full_seq_token_tensor.shape[0]]), dtype=torch.long)

	return TokenizerEncodeOutput(
	tokens=full_seq_token_tensor,
	timestep_scatter_index=timestep_scatter_index,
	guidance_scatter_index=guidance_scatter_index,
	text_slices=text_slices,
	gen_image_slices=gen_image_slices,
	joint_image_slices=joint_image_slices,
	cond_vae_image_slices=cond_vae_image_slices,
	cond_vit_image_slices=cond_vit_image_slices,
	text_mask=text_mask,
	gen_image_mask=gen_image_mask,
	cond_vae_image_mask=cond_vae_image_mask,
	cond_vit_image_mask=cond_vit_image_mask,
	real_pos=real_pos,
	all_image_slices=all_image_slices,
	cond_timestep_scatter_index=cond_timestep_scatter_index,
	gen_timestep_scatter_index=gen_timestep_scatter_index,
	)

	def get_cot_sections(self, cot_text, uncond_kwargs, cot_max_length=None, drop_think=False):
	if not cot_text: # None or empty
	return []
	if '<think>' in cot_text and '</think>' in cot_text:
	before_think_sec = cot_text.split('<think>')[0]
	after_think_sec = cot_text.split('</think>')[1]
	think_sec = cot_text.split('<think>')[1].split('</think>')[0]
	return self.get_cot_sections(before_think_sec, uncond_kwargs, drop_think=drop_think) + \
	([
	dict(type="text", text="<think>"),
	dict(type="text", text=think_sec, max_length=cot_max_length, **uncond_kwargs),
	dict(type="text", text="</think>")
	] if not drop_think else []) + \
	self.get_cot_sections(after_think_sec, uncond_kwargs, drop_think=drop_think)

	if '<recaption>' in cot_text and '</recaption>' in cot_text:
	before_recaption_sec = cot_text.split('<recaption>')[0]
	after_recaption_sec = cot_text.split('</recaption>')[1]
	recaption_sec = cot_text.split('<recaption>')[1].split('</recaption>')[0]
	return self.get_cot_sections(before_recaption_sec, uncond_kwargs, drop_think=drop_think) + \
	[
	dict(type="text", text="<recaption>"),
	dict(type="text", text=recaption_sec, max_length=cot_max_length, **uncond_kwargs),
	dict(type="text", text="</recaption>")
	] + \
	self.get_cot_sections(after_recaption_sec, uncond_kwargs, drop_think=drop_think)

	return [
	dict(type="text", text=cot_text, **uncond_kwargs),
	]

	def apply_general_template(
	self,
	message_list,
	max_length=None,
	add_assistant_prefix=False,
	answer="auto",
	bot_task="auto",
	sequence_template="instruct",
	uncond_p=0.0,
	cfg_factor=1,
	batchify=False,
	image_base_size=1024,
	drop_think=False,
	):
	# If cfg_factor > 1, we need to repeat the unconditioned part
	if batchify:
	assert isinstance(message_list[0], list), \
	f"When batchify is True, message_list should be a list of list, but got [{type(message_list[0])}, ...]."
	return self.batch_gen_infer(
	infer_fn=self.apply_general_template,
	prompt_list=[[]],
	infer_fn_kwargs_list=[dict(
	message_list=message_list_i,
	max_length=max_length,
	add_assistant_prefix=add_assistant_prefix,
	answer=answer,
	bot_task=bot_task,
	sequence_template=sequence_template,
	image_base_size=image_base_size,
	drop_think=drop_think,
	) for message_list_i in message_list],
	do_classifier_free_guidance=cfg_factor > 1,
	condition_repeat_times=1,
	uncondition_repeat_times=cfg_factor - 1,
	)

	conv = Conversation()
	uncond_kwargs = dict(uncond_enabled=uncond_p == 1.0, uncond_p=uncond_p)

	def process_successive_message(_message_list, _cur_message_idx, role, prefix, suffix,
	answer_prefix="", answer_suffix=""):
	_sub_sections = []
	while _cur_message_idx < len(message_list) and _message_list[_cur_message_idx]['role'] == role:
	message = _message_list[_cur_message_idx]
	if message['type'] == 'text':
	text = message['content']
	if role == "system":
	_sub_sections.append(dict(type="text", text=text))
	elif role == "assistant":
	if ("<recaption>" in text and "</recaption>" in text) or (
	"<think>" in text and "</think>" in text):
	_sub_sections.extend(self.get_cot_sections(text, uncond_kwargs, drop_think=drop_think))
	else:
	_sub_sections.append(dict(type="text", text=text, **uncond_kwargs))
	else:
	_sub_sections.append(dict(
	type="text", text=f"{answer_prefix}{text}{answer_suffix}", **uncond_kwargs))
	elif message['type'] == 'gen_image':
	info = message['content']
	assert isinstance(info, ImageInfo), f"Expected ImageInfo, but got {type(info)}"
	if role == "assistant":
	_sub_sections.append(dict(type="text", text=answer_prefix))
	_sub_sections.append(dict(type=message['type'], **info.meta_info))
	if role == "assistant":
	_sub_sections.append(dict(type="text", text=answer_suffix))
	elif message['type'] == 'joint_image':
	info = message['content']
	assert isinstance(info, JointImageInfo), f"Expected JointImageInfo, but got {type(info)}"
	_sub_sections.append(dict(type=message['type'], **info.meta_info))
	else:
	raise ValueError(f"Unknown message type: {message['type']}")
	_cur_message_idx += 1
	if len(_sub_sections) > 0:
	# Add role prefix and suffix
	_sub_sections.insert(0, dict(type='text', text=prefix))
	_sub_sections.append(dict(type='text', text=suffix))
	return _sub_sections, _cur_message_idx

	# Define assistant prefix and suffix
	if (answer == "auto" and sequence_template == "instruct") or answer is True:
	answer_prefix, answer_suffix = "<answer>", "</answer>"
	else:
	answer_prefix, answer_suffix = "", ""
	if sequence_template == "pretrain":
	system_suffix = ""
	user_prefix = ""
	user_suffix = ""
	bot_prefix = ""
	bot_suffix = ""
	else:
	system_suffix = f"{conv.sep}"
	user_prefix = f"{conv.roles[0]}: "
	user_suffix = f"{conv.sep}"
	bot_prefix = f"{conv.roles[1]}: "
	bot_suffix = f"{conv.sep}"

	# Process successive user and assistant messages
	sections = []
	cur_message_idx = 0
	final_role = None
	while cur_message_idx < len(message_list):
	# Process successive system messages
	sub_sections, cur_message_idx = process_successive_message(
	message_list, cur_message_idx, role="system", prefix="", suffix=system_suffix)
	# Add to the template and sections
	sections.extend(sub_sections)
	if len(sub_sections) > 0:
	final_role = "system"

	# Process successive user messages
	sub_sections, cur_message_idx = process_successive_message(
	message_list, cur_message_idx, role="user", prefix=user_prefix, suffix=user_suffix)
	# Add to the template and sections
	sections.extend(sub_sections)
	if len(sub_sections) > 0:
	final_role = "user"

	# Process successive assistant messages
	sub_sections, cur_message_idx = process_successive_message(
	message_list, cur_message_idx, role="assistant", prefix=bot_prefix, suffix=bot_suffix,
	answer_prefix=answer_prefix, answer_suffix=answer_suffix,
	)
	# Add to the template and sections
	sections.extend(sub_sections)
	if len(sub_sections) > 0:
	final_role = "assistant"

	if add_assistant_prefix:
	if final_role == "assistant":
	# Avoid adding prefix twice
	_bot_prefix = ""
	# Remove the final bot_suffix
	if len(sections) > 0 and sections[-1]['type'] == 'text' and sections[-1]['text'] == bot_suffix:
	sections = sections[:-1]
	else:
	_bot_prefix = bot_prefix
	# We can add special tokens for the bot lastest message according to different tasks
	bot_response_prefix = dict(
	auto=_bot_prefix,
	image="",
	think=f"{_bot_prefix}<think>",
	recaption=f"{_bot_prefix}<recaption>",
	img_ratio=f"{_bot_prefix}{answer_prefix}<boi><img_size_{image_base_size}>",
	)[bot_task]
	sections.append(dict(type='text', text=bot_response_prefix))

	output = self.encode_general(
	sections=sections,
	use_text_mask=False,
	add_eos=False,
	add_pad=False,
	)

	if max_length is not None:
	if output.tokens.shape[-1] > max_length:
	raise ValueError(
	f"Encoded token length {output.tokens.shape[-1]} exceeds max_length {max_length}.\n"
	f"Please set a larger max_length or check the input messages:\n{message_list}"
	)

	return output, sections

	def apply_chat_template(
	self,
	batch_prompt: Optional[List[str]] = None,
	batch_message_list: Optional[List[List[Dict[str, Any]]]] = None,
	mode: str = "gen_text",
	batch_gen_image_info: Optional[List[ImageInfo]] = None,
	batch_cond_image_info: Optional[Union[List[JointImageInfo], List[List[JointImageInfo]]]] = None,
	batch_system_prompt: Optional[List[str]] = None,
	batch_cot_text: Optional[List[str]] = None,
	max_length: Optional[int] = None,
	bot_task: str = "auto", # auto/image/think/recaption/img_ratio
	image_base_size: int = 1024,
	sequence_template: str = "pretrain",
	cfg_factor: int = 1,
	add_assistant_prefix: Optional[bool] = None,
	drop_think: bool = False,
	) -> Dict[str, Any]:
	assert bot_task in ["image", "auto", "think", "recaption", "img_ratio"], \
	f"bot_task should be one of ['image', 'auto', 'think', 'recaption', 'img_ratio'], but got {bot_task}."

	if batch_message_list is None:
	# Simple text-to-image or text-cot-to-image task
	batch_size = len(batch_prompt)

	# Batchify inputs
	if not isinstance(batch_system_prompt, list):
	batch_system_prompt = [batch_system_prompt] * batch_size
	if not isinstance(batch_gen_image_info, list):
	batch_gen_image_info = [batch_gen_image_info] * batch_size
	if batch_cot_text is not None:
	assert len(batch_cot_text) == batch_size, \
	(f"batch_cot_text should have the same length as batch_size ({batch_size}), "
	f"but got {len(batch_cot_text)}.")
	else:
	batch_cot_text = [None] * batch_size
	if batch_cond_image_info is not None:
	assert len(batch_cond_image_info) == batch_size, \
	(f"batch_cond_image_info should have the same length as batch_size ({batch_size}), "
	f"but got {len(batch_cond_image_info)}.")
	batch_cond_image_info = [
	cond_image_info if isinstance(cond_image_info, list) else [cond_image_info]
	for cond_image_info in batch_cond_image_info
	]
	else:
	batch_cond_image_info = [[] for _ in range(batch_size)]

	# Convert single round materials into standard message list
	batch_message_list = []
	for prompt, system_prompt, cot_text, gen_image_info, cond_image_info_list in zip(
	batch_prompt, batch_system_prompt, batch_cot_text, batch_gen_image_info,
	batch_cond_image_info,
	):
	message_list = []
	# 1. system prompt section
	if system_prompt:
	message_list.append(dict(
	role="system", type="text", content=system_prompt, context_type="str"))
	# 2. user inputs sections
	# 2.1 image inputs
	if len(cond_image_info_list) > 0:
	message_list.extend([
	dict(role="user", type="joint_image", content=cond_image_info, context_type="image_info")
	for cond_image_info in cond_image_info_list
	])
	# 2.2 text inputs
	message_list.append(dict(
	role="user", type="text", content=prompt, context_type="str"))
	# 3. assistant answer sections
	if cot_text is not None:
	message_list.append(dict(role="assistant", type="text", content=cot_text, context_type="str"))
	if mode == "gen_image":
	message_list.append(dict(
	role="assistant", type="gen_image", content=gen_image_info, context_type="image_info"))
	# ---
	batch_message_list.append(message_list)

	output, sections = self.apply_general_template(
	message_list=batch_message_list,
	max_length=max_length,
	add_assistant_prefix=default(add_assistant_prefix, mode != "gen_image"),
	bot_task=bot_task,
	sequence_template=sequence_template,
	cfg_factor=cfg_factor,
	batchify=True,
	image_base_size=image_base_size,
	drop_think=drop_think,
	)
	return dict(output=output, sections=sections)