util.py

import gradio as gr
import json
import pandas as pd
from vocab import load_tokener
from utils.zh_util import iter_vocab




def tokenize(text, tokenizer_type, color_num=5):
    """
    TODO: cache tokenizer
    """
    print(f"入参：tokenize, {text}, {tokenizer_type}")
    pos_tokens = []
    tokenizer = load_tokener(tokenizer_type)
    encoding = tokenizer.encode(text)

    table = []

    for idx, token_id in enumerate(encoding):
        decode_text = tokenizer.decode([token_id])  # 特殊字符解码后会统一变成 �，对应 "\ufffd"
        pos_tokens.extend([(decode_text, str(idx % color_num))])

        # token  "Byte":  # 这是 utf-8编码吧？
        token = tokenizer.convert_ids_to_tokens([token_id])[0]
        if isinstance(token, bytes):
            try:
                token_str = token.decode("utf-8")
            except:
                token_str = token.decode("utf-8", errors="ignore")
                print("decode_error", tokenizer_type, token, token_str)

            token_bytes = token
            json_dumps = json.dumps(token_str)
        elif isinstance(token, str):
            token_str = token
            token_bytes = bytes(token_str, "utf-8")
            json_dumps = json.dumps(token_str)
        else:
            return

        # ⭐
        table.append(
            {"TokenID": token_id,
             "Token": token_str,  # utf-8解码后的字符串，为什么有些是 <0xE7>，表示什么？比如llama
             "Text": decode_text,  #
             # "Bytes": token_bytes,  # bytes类型在gradio前端页面被解码成字符串，比如   b'\xe4\xb8\xad' 仍然显示成 "中"。因此 str(token_bytes)
             "Bytes": str(token_bytes),
             # "Unicode": json_dumps  # unicode, 如果是ascii码，就直接显示。如果不是ascii码，就显示unicode
             }
        )

    table_df = pd.DataFrame(table)
    print(f"Tokenization[{tokenizer_type}]: {table}")
    # print(table_df)

    return gr.update(value=pos_tokens, label=f"Tokens: {len(encoding)}"), table_df


def tokenize_pair(text, tokenizer_type_1, tokenizer_type_2):
    pos_tokens_1, table_df_1  = tokenize(text, tokenizer_type_1)
    pos_tokens_2, table_df_2 = tokenize(text, tokenizer_type_2)
    return pos_tokens_1, table_df_1, pos_tokens_2, table_df_2


def basic_count(tokenizer_type):
    tokenizer = load_tokener(tokenizer_type)
    stats = iter_vocab(tokenizer, tokenizer_type)
    return tokenizer.vocab_size, f'{stats["中文汉字数"]["中文单字"]}/{stats["中文汉字数"]["中文多字"]}'


def get_overlap_token_size(tokenizer_type_1, tokenizer_type_2):
    tokenizer1 = load_tokener(tokenizer_type_1)
    tokenizer2 = load_tokener(tokenizer_type_2)
    vocab1 = tokenizer1.get_vocab()
    vocab2 = tokenizer2.get_vocab()
    overlap_tokens = vocab1.keys() & vocab2.keys()
    overlap_token_size = len(overlap_tokens)
    print(f"OverlapTokens: {tokenizer_type_1}, {tokenizer_type_2} {list(overlap_tokens)[:10]}")
    return overlap_token_size, overlap_token_size




def test_coding():
    bytes1 = b'\xe4\xb8\xad'
    print(bytes1)  # b'\xe4\xb8\xad'


if __name__ == "__main__":
    print(basic_count("internlm_chat_7b"))