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# coding=utf-8
# Copyright 2022 The OpenBMB Team and The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# 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.
"""Tokenization classes for CpmBee."""
import json
import os
from typing import Any, Dict, List, Optional, Tuple, Union
import numpy as np
from numpy.typing import NDArray
from typing_extensions import TypedDict
from transformers.tokenization_utils import PaddingStrategy, PreTrainedTokenizer, TensorType
from transformers.tokenization_utils_base import AddedToken, BatchEncoding, TextInput, TruncationStrategy
from transformers.utils import logging
logger = logging.get_logger(__name__)
VOCAB_FILES_NAMES = {"vocab_file": "vocab.txt"}
PRETRAINED_VOCAB_FILES_MAP = {
"vocab_file": {
"openbmb/viscpmchat-bee-10b": "https://huggingface.co/openbmb/VisCPM-Chat/blob/main/vocab.txt",
},
}
PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES = {
"openbmb/viscpmchat-bee-10b": 4096,
}
class _PrevExtTableStates(TypedDict):
ext_table: Dict[int, str]
token_id_table: Dict[str, Dict[int, int]]
CPMBeeInputType = Union[str, Dict[str, "CPMBeeInputType"]]
def rel_to_bucket(n_up: int, n_down: int, max_depth: int = 8):
ret = n_up * max_depth + n_down
if ret == 0:
return ret
else:
# bucket 1 is reserved for incontext samples
return ret + 1
class _DictTree(TypedDict):
value: str
children: List["_DictTree"]
depth: int
segment_id: int
need_predict: bool
is_image: bool
class VisCpmChatBeeTokenizer(PreTrainedTokenizer):
"""
Construct a CPMBee tokenizer.
Args:
vocab_file (`str`):
Path to the vocabulary file.
bos_token (`str`, *optional*, defaults to `"<s>"`):
The beginning of sequence token.
eos_token (`str`, *optional*, defaults to `"</s>"`):
The end of sequence token.
line_token (`str`, *optional*, defaults to `"\n"`):
The line token.
space_token (`str`, *optional*, defaults to `" "`):
The space token.
unk_token (`str`, *optional*, defaults to `"<unk>"`):
The unknown token.
mask_token (`str`, *optional*, defaults to `"<mask>"`):
The mask token.
pad_token (`str`, *optional*, defaults to `"<pad>"`):
The token used for padding.
padding_side (`str`, *optional*, defaults to `"left"`):
The padding side. CPM-Bee will use left padding by default.
"""
vocab_files_names = VOCAB_FILES_NAMES
pretrained_vocab_files_map = PRETRAINED_VOCAB_FILES_MAP
max_model_input_sizes = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
model_input_names: List[str] = [
"input_ids",
"attention_mask",
"input_id_sub",
"position",
"context",
"sample_ids",
"num_segments",
"segment",
"segment_rel_offset",
"segment_rel",
]
add_prefix_space = False
def __init__(
self,
vocab_file,
bos_token="<s>",
eos_token="</s>",
line_token="\n",
space_token=" ",
unk_token="<unk>",
mask_token="<mask>",
pad_token="<pad>",
padding_side="left",
**kwargs,
):
super().__init__(
bos_token=bos_token,
eos_token=eos_token,
line_token=line_token,
space_token=space_token,
unk_token=unk_token,
mask_token=mask_token,
pad_token=pad_token,
padding_side=padding_side,
**kwargs,
)
self.encoder: Dict[str, int] = {}
with open(vocab_file, "r", encoding="utf-8") as reader:
for token in reader.readlines():
token = token.rstrip("\n")
if len(token) == 0:
continue
self.encoder[token] = len(self.encoder)
self.encoder[" "] = self.encoder["</_>"]
self.encoder["\n"] = self.encoder["</n>"]
del self.encoder["</_>"]
del self.encoder["</n>"]
self.decoder = {v: k for k, v in self.encoder.items()}
self._max_word_len = max([len(x) for x in self.encoder.keys()])
self.cpmbee_special_tokens = {k: v for k, v in self.encoder.items() if k.startswith("<") and k.endswith(">")}
self.ext_table: Dict[int, str] = {}
self.ext_table_rev: Dict[str, int] = {}
self.token_id_table: Dict[str, Dict[int, int]] = {}
self.ext_special_tokens = []
self.ext_args_for_model = [
"input_id_subs",
"input_pos",
"context",
"segment_ids",
"segment_rel_offset",
"segment_rel",
"sample_ids",
"num_segments",
"predict_segments",
"answer_placeholders",
"ext_table",
"token_id_table",
"image_bound"
]
@property
def bod_token_id(self):
return self.encoder[self.bod_token]
@property
def eod_token_id(self):
return self.encoder[self.eod_token]
@property
def newline_id(self):
return self.encoder[self.line_token]
@property
def vocab_size(self) -> int:
return len(self.encoder)
def __len__(self):
"""
Size of the full vocabulary with the added tokens.
"""
return self.vocab_size + len(self.added_tokens_encoder)
def get_vocab(self):
return dict(self.encoder, **self.added_tokens_encoder)
def get_piece(self, text: str) -> str:
"""
Match with maximum length.
"""
len_text = len(text)
for i in range(len(text)):
sub = text[: len_text - i]
if (sub in self.encoder) or (sub in self.added_tokens_encoder):
return sub
return text[0]
def tokenize(self, text: TextInput, **kwargs) -> List[str]:
r"""
Override the `tokenize` to meet the needs of CPMBee:
1. Mark the special token with `<` and `>`. The `<>` will be ignored.
2. Split sentences by the marked special tokens.
3. Record the marked special token by `ext_table` and `ext_table_rev`.
4. Tokenize the sentence without special tokens.
"""
for_cpmbee = kwargs.get("for_cpmbee", False)
all_special_tokens_extended = {
str(t): t for t in self.all_special_tokens_extended if isinstance(t, AddedToken)
}
sentence_split = [""]
is_special_token = False
for i, c in enumerate(text):
if is_special_token:
if c == "<":
tail = sentence_split.pop(-1)
sentence_split[-1] += tail
sentence_split.append(c)
elif c == ">":
# end of special token
sentence_split[-1] += c
if sentence_split[-1] == "<>":
continue
is_special_token = False
sentence_split.append("")
else:
sentence_split[-1] += c
else:
if c == "<":
is_special_token = True
sentence_split.append(c)
else:
sentence_split[-1] += c
if is_special_token:
tail = sentence_split.pop(-1)
sentence_split[-1] += tail
output_tokens = []
for i, part in enumerate(sentence_split):
if (i & 1) == 1:
# special token
output_tokens.append(part)
if for_cpmbee and (part not in self.encoder) and (part not in self.ext_table_rev):
self.ext_table_rev[part] = len(self.ext_table_rev) + self.vocab_size
self.ext_table[self.ext_table_rev[part]] = part
else:
output_tokens.extend(self._tokenize(part, for_cpmbee=for_cpmbee))
# drop spaces
for i, token in enumerate(output_tokens):
if token in self.added_tokens_encoder:
token = all_special_tokens_extended.get(token, None)
left = output_tokens[i - 1] if i > 0 else None
right = output_tokens[i + 1] if i < len(output_tokens) - 1 else None
if isinstance(token, AddedToken):
if token.rstrip and right:
# A bit counter-intuitive but we strip the left of the string
# since tok_extended.rstrip means the special token is eating all white spaces on its right
output_tokens[i + 1] = right.lstrip()
# Strip white spaces on the left
if token.lstrip and left:
output_tokens[i - 1] = left.rstrip() # Opposite here
else:
if right:
output_tokens[i + 1] = right.lstrip()
if left:
output_tokens[i - 1] = left.rstrip()
skipped_tokens = []
for token in output_tokens:
if not token:
continue
else:
skipped_tokens.append(token)
return skipped_tokens
def _tokenize(self, text, **kwargs):
"""
Converts a string in a sequence of tokens (string), using the tokenizer. Split in words for word-based
vocabulary.
Do NOT take care of added tokens. Record the unk tokens and special tokens in `ext_table` and `ext_table_rev`.
"""
for_cpmbee = kwargs.get("for_cpmbee", False)
output_tokens = []
part_st = 0
last_unk = None
while part_st < len(text):
piece = self.get_piece(text[part_st:])
if piece in self.encoder or self.added_tokens_encoder:
if last_unk is None:
output_tokens.append(piece)
else:
if for_cpmbee and (last_unk not in self.ext_table_rev):
self.ext_table_rev[last_unk] = len(self.ext_table_rev) + self.vocab_size
self.ext_table[self.ext_table_rev[last_unk]] = last_unk
output_tokens.append(last_unk)
output_tokens.append(piece)
last_unk = None
else:
if last_unk is None:
last_unk = piece
else:
last_unk += piece
part_st += len(piece)
if last_unk is not None:
# part end with UNK
if for_cpmbee and (last_unk not in self.ext_table_rev):
self.ext_table_rev[last_unk] = len(self.ext_table_rev) + self.vocab_size
self.ext_table[self.ext_table_rev[last_unk]] = last_unk
output_tokens.append(last_unk)
return output_tokens
def check(self, token):
return token in self.encoder
def convert_tokens_to_string(self, tokens: List[str]) -> str:
return "".join(tokens)
def _convert_token_to_id(self, token: str):
"""Converts a token (str) in an id using the vocab and ext_table."""
if token in self.encoder:
return self.encoder.get(token)
elif token in self.ext_table_rev:
return self.ext_table_rev[token]
elif token in self.added_tokens_encoder:
return self.added_tokens_encoder[token]
else:
return self.unk_token_id
def _convert_id_to_token(self, index):
"""Converts an index (integer) in a token (str) using the vocab and ext_table."""
if index in self.ext_table:
return self.ext_table[index]
elif index in self.added_tokens_decoder:
return self.added_tokens_decoder[index]
else:
if index >= 0:
return self.decoder[index]
def save_vocabulary(self, save_directory: str, filename_prefix: Optional[str] = None) -> Tuple[str]:
if os.path.isdir(save_directory):
vocab_file = os.path.join(
save_directory, (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["vocab_file"]
)
else:
vocab_file = (filename_prefix + "-" if filename_prefix else "") + save_directory
index = 0
self.encoder["</n>"] = self.encoder["\n"]
del self.encoder["\n"]
self.encoder["</_>"] = self.encoder[" "]
del self.encoder[" "]
with open(vocab_file, "w", encoding="utf-8") as writer:
for token, token_index in sorted(self.encoder.items(), key=lambda x: x[1]):
if index != token_index:
logger.warning(
f"Saving vocabulary to {vocab_file}: vocabulary indices are not consecutive."
" Please check that the vocabulary is not corrupted!"
)
index = token_index
writer.write(token + "\n")
index += 1
return (vocab_file,)
def __call__(self, text, *args, **kwargs):
r"""
CPMBee `call` method will use `_tokenize_cpmbee` when the input type is dict.
"""
if isinstance(text, dict):
return self._batch_tokenize_cpmbee([text], *args, **kwargs)
elif isinstance(text, (list, tuple)):
if isinstance(text[0], dict):
return self._batch_tokenize_cpmbee(text, *args, **kwargs)
else:
return super().__call__(text, *args, **kwargs)
else:
return super().__call__(text, *args, **kwargs)
# 分词
def _tokenize_cpmbee(self, data: TextInput, *args, **kwargs) -> List[str]:
"""
A tokenize method to process dict data. Exclusive for CPMBee.
"""
if isinstance(data, str):
data = json.loads(data)
if not isinstance(data, Dict):
raise TypeError(
"CpmBeeTokenizer input data should be dict or str in dict format, but got {}".format(type(data))
)
# 1. prepare answer placeholder
answer_placeholders = []
def _put_placeholder(data: Any, path: List[str] = []):
if isinstance(data, dict):
ret = {}
for k, v in data.items():
ret[k] = _put_placeholder(v, path + [k])
return ret
else:
answer_placeholders.append(path)
return "<ans_{}>".format(len(answer_placeholders))
data["<ans>"] = _put_placeholder(data["<ans>"])
(
input_ids,
input_id_subs,
context,
segment_ids,
segment_rel,
n_segments,
table_states,
image_bound
) = self.convert_data_to_id(data, shuffle_answer=False, max_depth=8)
# <ans> mapping from sub to id
sub_ans_map: Dict[int, int] = {}
for fake_id, token_sub in table_states["token_id_table"]["<ans>"].items():
token = table_states["ext_table"][fake_id]
if token.startswith("<ans_") and token.endswith(">"):
ans_id = int(token[5:-1])
sub_ans_map[token_sub] = ans_id
tmp_input_ids = []
tmp_input_sub = []
tmp_input_seg = []
# get predict segments
predict_segments: List[Tuple[int, int]] = []
for i in range(input_ids.shape[0]):
if context[i] == 0:
if input_ids[i] == self.encoder["<ans>"]:
# is ans
# (segment_id, ans_id)
predict_segments.append((segment_ids[i], sub_ans_map[input_id_subs[i]]))
else:
tmp_input_ids.append(input_ids[i])
tmp_input_sub.append(input_id_subs[i])
tmp_input_seg.append(segment_ids[i])
if len(predict_segments) == 0:
raise ValueError("No answer to predict")
input_ids = np.array(tmp_input_ids, dtype=np.int32) # all context
input_id_subs = np.array(tmp_input_sub, dtype=np.int32) # [0, 0, 0, 0, 1, 0, 0, 2, 0, ...]
context = np.full_like(tmp_input_ids, 1, dtype=np.int8) # [1, 1, 1, ...]
segment_ids = np.array(tmp_input_seg, dtype=np.int32) # [0, 0, 0, 1, 1, 1, 2, 2, 2, 2, ...]
sample_ids = np.zeros(input_ids.shape, dtype=np.int32) # [0, 0, 0, 0, ...]
segment_rel_offset = np.zeros(input_ids.shape, dtype=np.int32) # [0, 0, 0, ...]
num_segments = np.full(input_ids.shape, n_segments, dtype=np.int32) # [n_seg, n_seg, n_seg, ...]
input_pos = np.arange(input_ids.shape[0], dtype=np.int32) # [0, 1, 2, 3, 4, ...]
image_bound = np.array(image_bound)
return (
self.prepare_for_model(
input_ids.tolist(),
input_id_subs=input_id_subs.tolist(),
input_pos=input_pos.tolist(),
context=context.tolist(),
segment_ids=segment_ids.tolist(),
segment_rel_offset=segment_rel_offset.tolist(),
segment_rel=segment_rel.tolist(),
sample_ids=sample_ids.tolist(),
num_segments=num_segments.tolist(),
image_bound=image_bound,
**kwargs,
),
predict_segments,
answer_placeholders,
table_states["ext_table"],
table_states["token_id_table"],
)
def _batch_tokenize_cpmbee(self, data_lst, *args, **kwargs):
"""
Batched _token_cpmbee.
"""
device = kwargs.get("device", "cpu")
return_tensors = kwargs.get("return_tensors", None)
batch_outputs = {}
segment_rel_pack = []
other_info = []
batch_ext_table_map: Dict[Tuple[int, int], int] = {}
batch_ext_table_ids: List[int] = []
batch_ext_table_sub: List[int] = []
for data in data_lst:
self.ext_table = {}
self.ext_table_rev = {}
self.token_id_table = {}
(outputs, predict_segments, answer_placeholders, ext_table, token_id_table) = self._tokenize_cpmbee(
data,
truncation=None,
padding=PaddingStrategy.DO_NOT_PAD.value,
max_length=None,
pad_to_multiple_of=None,
return_attention_mask=False,
return_tensors=None,
)
rev_ext_table = {}
for token, mp in token_id_table.items():
if token == "<ans>":
continue
token_id = self.encoder[token]
for fake_id, token_sub in mp.items():
if token_sub > 0:
if (token_id, token_sub) not in batch_ext_table_map:
batch_ext_table_map[(token_id, token_sub)] = len(batch_ext_table_ids) + self.vocab_size
batch_ext_table_ids.append(token_id)
batch_ext_table_sub.append(token_sub)
rev_ext_table[batch_ext_table_map[(token_id, token_sub)]] = ext_table[fake_id]
else:
rev_ext_table[token_id] = ext_table[fake_id]
segment_rel_pack.append(np.array(outputs.pop("segment_rel")))
other_info.append(
{
"predict_segments": predict_segments,
"answer_placeholders": answer_placeholders,
"ext_table": rev_ext_table,
}
)
for key, value in outputs.items():
if key not in batch_outputs:
batch_outputs[key] = []
batch_outputs[key].append(value)
max_length = max([len(item) for item in batch_outputs[self.model_input_names[0]]])
batch_size = len(batch_outputs[self.model_input_names[0]])
for i in range(batch_size):
inputs = {k: v[i] for k, v in batch_outputs.items()}
for k, v in inputs.items():
required_input = v
needs_to_be_padded = len(required_input) != max_length and k != 'image_bound'
if needs_to_be_padded:
difference = max_length - len(required_input)
batch_outputs[k][i] = [self.pad_token_id] * difference + required_input
max_num_rels = 0
for rel in segment_rel_pack:
max_num_rels = max(max_num_rels, rel.shape[0])
padded_rels = np.zeros((len(segment_rel_pack), max_num_rels), dtype=np.int32)
for i, rel in enumerate(segment_rel_pack):
padded_rels[i, : rel.shape[0]] = rel
batch_outputs["segment_rel"] = padded_rels
batch_outputs["batch_ext_table_ids"] = np.array(batch_ext_table_ids, dtype=np.int32)
batch_outputs["batch_ext_table_sub"] = np.array(batch_ext_table_sub, dtype=np.int32)
batch_outputs = BatchEncoding(batch_outputs, tensor_type=return_tensors)
if return_tensors == "pt":
batch_outputs = batch_outputs.to(device=device)
batch_outputs["other_info"] = other_info
return batch_outputs
def convert_data_to_id(
self,
data: Any,
prev_ext_states: Optional[_PrevExtTableStates] = None,
shuffle_answer: bool = True,
max_depth: int = 8,
):
"""
Parse a dict to data ids. Exclusive for CPMBee. It will
1. parse the dict to segments and get segment_rel, which for calculating of position_bias.
2. tokenize every segment.
"""
root: _DictTree = {
"value": "<root>",
"children": [],
"depth": 0,
"segment_id": 0,
"need_predict": False,
"is_image": False
}
segments = [root]
def _build_dict_tree(data: CPMBeeInputType, depth: int, need_predict: bool, is_image: bool) -> List[_DictTree]:
if isinstance(data, dict):
ret_list: List[_DictTree] = []
curr_items = list(data.items())
if need_predict and shuffle_answer:
access_idx = np.arange(len(curr_items))
np.random.shuffle(access_idx)
curr_items = [curr_items[idx] for idx in access_idx]
for k, v in curr_items:
child_info: _DictTree = {
"value": k,
"children": [],
"depth": depth,
"segment_id": len(segments),
"need_predict": False, # only leaves are contexts
"is_image": False,
}
segments.append(child_info)
child_info["children"] = _build_dict_tree(
v, depth + 1,
need_predict=need_predict or (depth == 1 and k == "<ans>"),
is_image=is_image or (depth == 1 and k == "image")
) # elements in <root>.<ans>
ret_list.append(child_info)
return ret_list
else:
assert isinstance(data, str), "Invalid data {}".format(data)
ret: _DictTree = {
"value": data,
"children": [],
"depth": depth,
"segment_id": len(segments),
"need_predict": need_predict,
"is_image": is_image,
}
segments.append(ret)
return [ret]
root["children"] = _build_dict_tree(data, 1, False, False)
num_segments = len(segments)
segment_rel = np.zeros((num_segments * num_segments,), dtype=np.int32)
def _build_segment_rel(node: _DictTree) -> List[Tuple[int, int]]:
ret: List[Tuple[int, int]] = [(node["segment_id"], node["depth"])]
for child in node["children"]:
sub = _build_segment_rel(child)
for seg_id_1, depth_1 in sub:
for seg_id_2, depth_2 in ret:
n_up = min(depth_1 - node["depth"], max_depth - 1)
n_down = min(depth_2 - node["depth"], max_depth - 1)
segment_rel[seg_id_1 * num_segments + seg_id_2] = rel_to_bucket(
n_up, n_down, max_depth=max_depth
)
segment_rel[seg_id_2 * num_segments + seg_id_1] = rel_to_bucket(
n_down, n_up, max_depth=max_depth
)
ret.extend(sub)
return ret
_build_segment_rel(root)
input_ids: List[int] = []
input_id_subs: List[int] = []
segment_bound: List[Tuple[int, int]] = []
image_bound: List[Tuple[int, int]] = []
if prev_ext_states is not None:
self.ext_table = prev_ext_states["ext_table"]
self.token_id_table = prev_ext_states["token_id_table"]
for seg in segments:
# tokenize
tokens = self.convert_tokens_to_ids(self.tokenize(seg["value"], for_cpmbee=True))
token_id_subs = []
reid_token_ids = []
for idx in tokens:
if idx in self.ext_table:
# unk or special token
token = self.ext_table[idx]
if token.startswith("<") and token.endswith(">"):
# special token
if "_" in token:
token_name = token[1:-1].split("_", maxsplit=1)[0]
else:
token_name = token[1:-1]
token_name = "<{}>".format(token_name)
else:
token_name = "<unk>"
if token_name not in self.token_id_table:
self.token_id_table[token_name] = {}
if idx not in self.token_id_table[token_name]:
self.token_id_table[token_name][idx] = len(self.token_id_table[token_name])
if token_name not in self.encoder:
raise ValueError("Invalid token {}".format(token))
reid_token_ids.append(self.encoder[token_name])
token_id_subs.append(self.token_id_table[token_name][idx])
else:
reid_token_ids.append(idx)
token_id_subs.append(0)
tokens = [self.bos_token_id] + reid_token_ids
token_id_subs = [0] + token_id_subs
# eos_id 表示 no need_predict
if not seg["need_predict"]: # eos
tokens = tokens + [self.eos_token_id]
token_id_subs = token_id_subs + [0]
else:
# no eos
pass
begin = len(input_ids)
input_ids.extend(tokens)
input_id_subs.extend(token_id_subs)
end = len(input_ids)
segment_bound.append((begin, end))
ids = np.array(input_ids, dtype=np.int32)
id_subs = np.array(input_id_subs, dtype=np.int32)
segs = np.zeros((ids.shape[0],), dtype=np.int32) # 按segment_bound对seg编号
context = np.zeros((ids.shape[0],), dtype=np.int8)
for i, (begin, end) in enumerate(segment_bound):
if not segments[i]["need_predict"]:
context[begin:end] = 1
if segments[i]["is_image"]:
image_bound.append((begin + 1, end - 1))
segs[begin:end] = i
curr_ext_table_states: _PrevExtTableStates = {
"ext_table": self.ext_table,
"token_id_table": self.token_id_table,
}
image_bound = np.array(image_bound, dtype=np.int32)
return ids, id_subs, context, segs, segment_rel, num_segments, curr_ext_table_states, image_bound
def prepare_for_model(
self,
ids: List[int],
pair_ids: Optional[List[int]] = None,
add_special_tokens: bool = True,
padding: Union[bool, str, PaddingStrategy] = False,
truncation: Union[bool, str, TruncationStrategy] = None,
max_length: Optional[int] = None,
stride: int = 0,
pad_to_multiple_of: Optional[int] = None,
return_tensors: Optional[Union[str, TensorType]] = None,
return_token_type_ids: Optional[bool] = None,
return_attention_mask: Optional[bool] = None,
return_overflowing_tokens: bool = False,
return_special_tokens_mask: bool = False,
return_length: bool = False,
verbose: bool = True,
prepend_batch_axis: bool = False,
**kwargs,
) -> BatchEncoding:
"""
Prepares a sequence of input id, or a pair of sequences of inputs ids so that it can be used by the model. It
adds special tokens, truncates sequences if overflowing while taking into account the special tokens and
manages a moving window (with user defined stride) for overflowing tokens. Please Note, for *pair_ids*
different than `None` and *truncation_strategy = longest_first* or `True`, it is not possible to return
overflowing tokens. Such a combination of arguments will raise an error.
Args:
ids (`List[int]`):
Tokenized input ids of the first sequence. Can be obtained from a string by chaining the `tokenize` and
`convert_tokens_to_ids` methods.
pair_ids (`List[int]`, *optional*):
Tokenized input ids of the second sequence. Can be obtained from a string by chaining the `tokenize`
and `convert_tokens_to_ids` methods.
"""
# Backward compatibility for 'truncation_strategy', 'pad_to_max_length'
padding_strategy, truncation_strategy, max_length, kwargs = self._get_padding_truncation_strategies(
padding=padding,
truncation=truncation,
max_length=max_length,
pad_to_multiple_of=pad_to_multiple_of,
verbose=verbose,
**kwargs,
)
pair = bool(pair_ids is not None)
len_ids = len(ids)
len_pair_ids = len(pair_ids) if pair else 0
if return_token_type_ids and not add_special_tokens:
raise ValueError(
"Asking to return token_type_ids while setting add_special_tokens to False "
"results in an undefined behavior. Please set add_special_tokens to True or "
"set return_token_type_ids to None."
)
if (
return_overflowing_tokens
and truncation_strategy == TruncationStrategy.LONGEST_FIRST
and pair_ids is not None
):
raise ValueError(
"Not possible to return overflowing tokens for pair of sequences with the "
"`longest_first`. Please select another truncation strategy than `longest_first`, "
"for instance `only_second` or `only_first`."
)
# Load from model defaults
if return_token_type_ids is None:
return_token_type_ids = "token_type_ids" in self.model_input_names
if return_attention_mask is None:
return_attention_mask = "attention_mask" in self.model_input_names
encoded_inputs = {}
# Compute the total size of the returned encodings
total_len = len_ids + len_pair_ids + (self.num_special_tokens_to_add(pair=pair) if add_special_tokens else 0)
# Truncation: Handle max sequence length
overflowing_tokens = []
if truncation_strategy != TruncationStrategy.DO_NOT_TRUNCATE and max_length and total_len > max_length:
ids, pair_ids, overflowing_tokens = self.truncate_sequences(
ids,
pair_ids=pair_ids,
num_tokens_to_remove=total_len - max_length,
truncation_strategy=truncation_strategy,
stride=stride,
)
if return_overflowing_tokens:
encoded_inputs["overflowing_tokens"] = overflowing_tokens
encoded_inputs["num_truncated_tokens"] = total_len - max_length
# Add special tokens
if add_special_tokens:
sequence = self.build_inputs_with_special_tokens(ids, pair_ids)
token_type_ids = self.create_token_type_ids_from_sequences(ids, pair_ids)
else:
sequence = ids + pair_ids if pair else ids
token_type_ids = [0] * len(ids) + ([0] * len(pair_ids) if pair else [])
# Build output dictionary
encoded_inputs["input_ids"] = sequence
if return_token_type_ids:
encoded_inputs["token_type_ids"] = token_type_ids
if return_special_tokens_mask:
if add_special_tokens:
encoded_inputs["special_tokens_mask"] = self.get_special_tokens_mask(ids, pair_ids)
else:
encoded_inputs["special_tokens_mask"] = [0] * len(sequence)
# Check lengths
self._eventual_warn_about_too_long_sequence(encoded_inputs["input_ids"], max_length, verbose)
# Padding
if padding_strategy != PaddingStrategy.DO_NOT_PAD or return_attention_mask:
encoded_inputs = self.pad(
encoded_inputs,
max_length=max_length,
padding=padding_strategy.value,
pad_to_multiple_of=pad_to_multiple_of,
return_attention_mask=return_attention_mask,
)
if return_length:
encoded_inputs["length"] = len(encoded_inputs["input_ids"])
# for CPMBee, encode all the model arguments
for arg in self.ext_args_for_model:
v = kwargs.get(arg, None)
if v is not None:
encoded_inputs[arg] = v
batch_outputs = BatchEncoding(
encoded_inputs, tensor_type=return_tensors, prepend_batch_axis=prepend_batch_axis
)
return batch_outputs
def prepare_for_finetune(
self,
data_list: List[Dict],
max_length: int = 2048
):
_inputs: List[NDArray[np.int32]] = []
_inputs_sub: List[NDArray[np.int32]] = []
_context: List[NDArray[np.int8]] = []
_sample_ids: List[NDArray[np.int32]] = []
_segments: List[NDArray[np.int32]] = []
_num_segments: List[NDArray[np.int32]] = []
_segment_rel_offset: List[NDArray[np.int32]] = []
_segment_rel: List[NDArray[np.int32]] = []
_spans: List[List[int]] = []
_raw_data: List[List[Any]] = []
raw_data = {}
for data in data_list:
(
input_ids,
input_id_subs,
context,
segment_ids,
segment_rel,
n_segments,
_
) = self.convert_data_to_id(data)
input_ids = input_ids[: max_length]
context = context[: max_length]
segment_ids = segment_ids[: max_length]
raw_data["input"] = data
raw_data["samples"] = []
sample_ids = np.zeros(input_ids.shape, dtype=np.int32)
segment_rel_offset = np.zeros(input_ids.shape, dtype=np.int32)
num_segments = np.full(input_ids.shape, n_segments, dtype=np.int32)
_inputs.append(input_ids)
_inputs_sub.append(input_id_subs)
_context.append(context)
_sample_ids.append(sample_ids)
_segments.append(segment_ids)
_num_segments.append(num_segments)
_segment_rel_offset.append(segment_rel_offset)
_segment_rel.append(segment_rel)
_spans.append([input_ids.shape[0]])
_raw_data.append([raw_data])
batch_size = len(_inputs)
inputs = np.zeros((batch_size, max_length), dtype=np.int32)
inputs_sub = np.zeros((batch_size, max_length), dtype=np.int32)
context = np.zeros((batch_size, max_length), dtype=np.int8)
sample_ids = np.zeros((batch_size, max_length), dtype=np.int32)
segments = np.zeros((batch_size, max_length), dtype=np.int32)
num_segments = np.zeros((batch_size, max_length), dtype=np.int32)
segment_rel_offset = np.zeros((batch_size, max_length), dtype=np.int32)
tgt = np.full((batch_size, max_length), -100, dtype=np.int32)
max_rel = 0
for i in range(batch_size):
max_rel = max(max_rel, _segment_rel[i].shape[0])
segment_rel = np.zeros((batch_size, max_rel), dtype=np.int32)
spans = np.zeros((batch_size, max_length), dtype=np.int32)
length = np.zeros((batch_size,), dtype=np.int32)
batch_ext_table_map: Dict[Tuple[int, int], int] = {}
batch_ext_table_ids: List[int] = []
batch_ext_table_sub: List[int] = []
raw_data_list: List[Any] = []
for i in range(batch_size):
instance_length = _inputs[i].shape[0]
rel_size = _segment_rel[i].shape[0]
inputs[i, :instance_length] = _inputs[i]
inputs_sub[i, :instance_length] = _inputs_sub[i]
context[i, :instance_length] = _context[i]
sample_ids[i, :instance_length] = _sample_ids[i]
segments[i, :instance_length] = _segments[i]
num_segments[i, :instance_length] = _num_segments[i]
segment_rel_offset[i, :instance_length] = _segment_rel_offset[i]
segment_rel[i, :rel_size] = _segment_rel[i]
span_begin = 0
for span_id, span_end in enumerate(_spans[i]):
spans[i, span_begin:span_end] = span_id
span_begin = span_end
length[i] = instance_length
raw_data_list.extend(_raw_data[i])
for j in range(instance_length):
idx, idx_sub = _inputs[i][j], _inputs_sub[i][j]
tgt_idx = idx
if idx_sub > 0:
# need to be in ext table
if (idx, idx_sub) not in batch_ext_table_map:
batch_ext_table_map[(idx, idx_sub)] = len(batch_ext_table_map)
batch_ext_table_ids.append(idx)
batch_ext_table_sub.append(idx_sub)
tgt_idx = batch_ext_table_map[(idx, idx_sub)] + self.vocab_size
if j > 1 and context[i, j - 1] == 0:
if idx != self.bos_token_id:
tgt[i, j - 1] = tgt_idx
else:
tgt[i, j - 1] = self.eos_token_id
if context[i, instance_length - 1] == 0:
tgt[i, instance_length - 1] = self.eos_token_id
if len(batch_ext_table_map) == 0:
# placeholder
batch_ext_table_ids.append(0)
batch_ext_table_sub.append(1)
return BatchEncoding({
"input_ids": inputs,
"input_id_sub": inputs_sub,
"length": length,
"context": context > 0,
"sample_ids": sample_ids,
"num_segments": num_segments,
"segment": segments,
"segment_rel_offset": segment_rel_offset,
"segment_rel": segment_rel,
"span": spans,
"labels": tgt,
"ext_table_ids": np.array(batch_ext_table_ids, dtype=np.int32),
"ext_table_sub": np.array(batch_ext_table_sub, dtype=np.int32)
}, tensor_type="pt")
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