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from dataclasses import dataclass, field | |
from datasets import load_dataset, Dataset | |
from functools import cached_property | |
from tqdm.auto import tqdm | |
from typing import Any, Optional, Callable | |
import logging | |
import pandas as pd | |
from functools import partial | |
from datasets.utils.logging import disable_progress_bar | |
from .utils import * | |
from evaluate import load | |
from collections import defaultdict | |
import sys | |
from pathlib import Path | |
# if sys.version_info >= (3, 9): | |
# from functools import cache | |
# else: | |
# from functools import lru_cache as cache | |
disable_progress_bar() | |
def mt_bench_prompt(example): | |
judge_prompt = "You are ChatGPT, a large language model trained by OpenAI. Please act as an impartial judge and evaluate the quality of the response provided by an AI assistant to the user question displayed below. The Your evaluation should consider factors such as the helpfulness, relevance, accuracy, depth, creativity, and level of detail of the response." | |
judge_prompt = "You are ChatGPT, a large language model trained by OpenAI. Your task is to act as an impartial judge and evaluate the quality of the responses provided by an 'assistant' role in the displayed conversation. Your evaluation should focus on the helpfulness, relevance, accuracy, depth, creativity, language fluency, clarity, and level of detail in the assistant's responses. Please note that the evaluation should not consider the user's questions or the overall conversation, but solely the quality of the assistant's replies." | |
multi_prompt = "You evaluation should focus on the assistant's answer to the second user question." | |
ref_prompt = "In the conversation, you will encounter system messages labeled 'Reference Answer' followed by the assistant's response. Your task is to evaluate the quality of the assistant's response by comparing it with the reference answer." | |
json_prompt = 'You must rate the response on a scale of 1 to 10 in JSON format, for example: {"rating": 5}.' | |
prompt_list = [judge_prompt] | |
conversations = example["conversation"] | |
if example["turn"] == 2: | |
prompt_list.append(multi_prompt) | |
if example["reference"] is not None: | |
conversations = [] | |
quesiotns = filter(lambda e: e["role"] == "user", example["conversation"]) | |
answers = filter(lambda e: e["role"] == "assistant", example["conversation"]) | |
for q, a, r in zip(quesiotns, answers, example["reference"]): | |
conversations.append(q) | |
conversations.append( | |
{"role": "system", "content": "Reference Answer: " + r} | |
) | |
conversations.append(a) | |
prompt_list.append(ref_prompt) | |
prompt_list.append(json_prompt) | |
messages = [{"role": "system", "content": " ".join(prompt_list)}] + conversations | |
return messages | |
class Task: | |
dataset_name: str | tuple[str, str] = ("gsm8k", "main") | |
split: str = "test" | |
# metrics: list[str] = field(default_factory=list) | |
metric_name: str | tuple[str, str] = ("sustech/tlem", "gsm8k") | |
input_column: str = "question" | |
label_column: str = "" | |
prompt: Optional[Callable | str] = None | |
few_shot: int = 0 | |
few_shot_from: Optional[str] = None | |
# results: dict[str, Any] = field(default_factory=dict) | |
# outputs: Optional[list] = field(default_factory=list) | |
def __post_init__(self): | |
names = ( | |
[self.dataset_name] | |
if isinstance(self.dataset_name, str) | |
else list(self.dataset_name) | |
) | |
names[0] = Path(names[0]).name | |
self.name = "-".join(names) + f"-{self.split}" | |
if isinstance(self.prompt, str): | |
prompt_format = self.prompt | |
self.prompt = lambda example: { | |
self.input_column: prompt_format.format( | |
input_column=example[self.input_column] | |
) | |
} | |
self.label_column = self.label_column or self.input_column | |
self.outputs = [] | |
def __eq__(self, __value: object) -> bool: | |
return self.name == __value.name | |
def samples(self): | |
return self.dataset[self.input_column] | |
def dataset(self): | |
ds = ( | |
load_dataset( | |
*self.dataset_name, | |
) | |
if isinstance(self.dataset_name, tuple) | |
else load_dataset(self.dataset_name) | |
) | |
test_ds = ds[self.split] | |
if self.prompt is not None: | |
test_ds = test_ds.map(self.prompt) | |
if self.few_shot: | |
if self.few_shot_from is None: | |
for name in ["train", "validation", "val", "dev"]: | |
if name in ds: | |
self.few_shot_from = name | |
break | |
assert self.few_shot_from != self.split | |
shots = ds[self.few_shot_from].select(range(self.few_shot)) | |
# else: | |
# shots = ds.select(range(self.few_shot)) | |
if self.prompt is not None: | |
shots = shots.map(self.prompt) | |
shots = shots.map( | |
lambda example: { | |
self.input_column: example[self.input_column] | |
+ example[self.label_column], | |
} | |
)[self.input_column] | |
few_shot_prompts = "\n\n".join(shots) | |
test_ds = test_ds.map( | |
lambda example: { | |
self.input_column: few_shot_prompts | |
+ "\n\n" | |
+ example[self.input_column], | |
} | |
) | |
return test_ds | |
def metric(self): | |
metric = ( | |
load(self.metric_name) | |
if isinstance(self.metric_name, str) | |
else load(*self.metric_name) | |
) | |
return metric | |
def result(self) -> dict: | |
assert self.outputs, "Please run the task first." | |
results = self.metric._compute( | |
responses=self.outputs, references=self.dataset[self.label_column] | |
) | |
logging.info(f"{self.name}:{results}") | |
return results | |
# @cache | |
def run( | |
self, | |
pipeline, | |
): | |
self.outputs = self.outputs or pipeline(self.samples) | |
return self.result | |
async def arun(self, pipeline): | |
self.outputs = self.outputs or await pipeline(self.samples) | |
return self.result | |
def multichoice(responses: Any, references: list[str]): | |
if isinstance(responses[0], str): | |
responses = [extract_choice(response) for response in responses] | |
else: | |
responses = decode_choice(responses) | |
return responses, references | |
def multichoice_zh(responses: Any, references: list[str]): | |
if isinstance(responses[0], str): | |
responses = [extract_choice_zh(response) for response in responses] | |
else: | |
responses = decode_choice(responses) | |
return responses, references | |
class Metrics: | |
cmmlu = multichoice_zh | |
mmlu = multichoice | |
def ceval(responses: list[str], answers: list[str | int]): | |
responses = [extract_choice_zh(pred) for pred in responses] | |
return responses, answers | |
def winogrande(responses: list[str], answers: list[str | int]): | |
responses = [first_option_postprocess(pred, options="AB") for pred in responses] | |
return responses, answers | |
def arc(responses: list[str], answers: list[str | int]): | |
if len(responses) != len(answers): | |
return {"error": "predictions and references have different " "length"} | |
responses = [ | |
first_option_postprocess(pred, options="ABCD") for pred in responses | |
] | |
return responses, answers | |
def hellaswag(responses: list[str], answers: list[str | int]): | |
if len(responses) != len(answers): | |
return {"error": "predictions and references have different " "length"} | |
responses = [ | |
first_option_postprocess(pred, options="ABCD") for pred in responses | |
] | |
answers = ["ABCD"[int(ans)] for ans in answers] | |
return responses, answers | |
def drop(responses: list[str], answers: list[list]): | |
if len(responses) != len(answers): | |
return {"error": "predictions and references have different " "length"} | |
responses = [general_postprocess(pred) for pred in responses] | |
processed_answers = [[general_postprocess(j) for j in i] for i in answers] | |
matched_answers = [] | |
for pred, ans, origin_ans in zip(responses, processed_answers, answers): | |
if pred in ans or pred in origin_ans: | |
matched_answers.append(pred) | |
else: | |
matched_answers.append(ans[0]) | |
return responses, matched_answers | |
def bbh_mcq(responses: list[str], answers: list[str | int]): | |
if len(responses) != len(answers): | |
return {"error": "predictions and references have different " "length"} | |
responses = [bbh_mcq_postprocess(pred) for pred in responses] | |
return responses, answers | |
def bbh_freefrom(responses: list[str], answers: list[str | int]): | |
if len(responses) != len(answers): | |
return {"error": "predictions and references have different " "length"} | |
responses = [bbh_freeform_postprocess(pred) for pred in responses] | |
return responses, answers | |
def gsm8k(responses: list[str], answers: list[str | int]): | |
# scores = [] | |
# for response, answer in zip(responses, answers): | |
# pred = extract_numeric(response) | |
# gold = extract_numeric(answer) if isinstance(answer, str) else str(answer) | |
# scores.append(1.0 * (pred == gold)) | |
responses = [extract_numeric(response) for response in responses] | |
answers = [ | |
extract_numeric(answer) if isinstance(answer, str) else str(answer) | |
for answer in answers | |
] | |
return responses, answers | |
def MATH(responses: list[str], answers: list[str]): | |
extract_responses = sync_pipe(get_answer)(responses) | |
extract_answers = sync_pipe(get_answer)(answers) | |
try: | |
from math_equivalence import is_equiv | |
except ImportError as e: | |
logging.warning( | |
"math_equivalence not installed, pip install git+https://github.com/hendrycks/math.git" | |
) | |
raise e | |
return sync_pipe(is_equiv)(zip(extract_responses, extract_answers)) | |
class CMMLU: | |
input_column = "prompt" | |
label_column = "Answer" | |
def prompt_cmmlu(example, chat=False): | |
prefix = "以下是一道多项选择题,请从A、B、C和D中选择最合适的答案作为这个问题的答案。\n\n" if chat else "问题:" | |
prompt = prefix + example["Question"] | |
for choice in list("ABCD"): | |
prompt += f"\n{choice}. {example[choice]}" | |
prompt += "\n答案:" | |
return {"prompt": prompt} | |
subcategories = { | |
"agronomy": ["other"], | |
"anatomy": ["biology"], | |
"ancient_chinese": ["linguistics", "china specific"], | |
"arts": ["arts"], | |
"astronomy": ["physics"], | |
"business_ethics": ["business"], | |
"chinese_civil_service_exam": ["politics", "china specific"], | |
"chinese_driving_rule": ["other", "china specific"], | |
"chinese_food_culture": ["culture", "china specific"], | |
"chinese_foreign_policy": ["politics", "china specific"], | |
"chinese_history": ["history", "china specific"], | |
"chinese_literature": ["literature", "china specific"], | |
"chinese_teacher_qualification": ["education", "china specific"], | |
"college_actuarial_science": ["math"], | |
"college_education": ["education"], | |
"college_engineering_hydrology": ["engineering"], | |
"college_law": ["law"], | |
"college_mathematics": ["math"], | |
"college_medical_statistics": ["statistics"], | |
"clinical_knowledge": ["other"], | |
"college_medicine": ["other"], | |
"computer_science": ["computer science"], | |
"computer_security": ["other"], | |
"conceptual_physics": ["physics"], | |
"construction_project_management": ["other", "china specific"], | |
"economics": ["economics"], | |
"education": ["education"], | |
"elementary_chinese": ["linguistics", "china specific"], | |
"elementary_commonsense": ["other", "china specific"], | |
"elementary_information_and_technology": ["other"], | |
"electrical_engineering": ["engineering"], | |
"elementary_mathematics": ["math"], | |
"ethnology": ["culture", "china specific"], | |
"food_science": ["other"], | |
"genetics": ["biology"], | |
"global_facts": ["global"], | |
"high_school_biology": ["biology"], | |
"high_school_chemistry": ["chemistry"], | |
"high_school_geography": ["geography"], | |
"high_school_mathematics": ["math"], | |
"high_school_physics": ["physics"], | |
"high_school_politics": ["politics", "china specific"], | |
"human_sexuality": ["other"], | |
"international_law": ["law"], | |
"journalism": ["sociology"], | |
"jurisprudence": ["law"], | |
"legal_and_moral_basis": ["other"], | |
"logical": ["philosophy"], | |
"machine_learning": ["computer science"], | |
"management": ["business"], | |
"marketing": ["business"], | |
"marxist_theory": ["philosophy"], | |
"modern_chinese": ["linguistics", "china specific"], | |
"nutrition": ["other"], | |
"philosophy": ["philosophy"], | |
"professional_accounting": ["business"], | |
"professional_law": ["law"], | |
"professional_medicine": ["other"], | |
"professional_psychology": ["psychology"], | |
"public_relations": ["politics"], | |
"security_study": ["politics"], | |
"sociology": ["culture"], | |
"sports_science": ["other"], | |
"traditional_chinese_medicine": ["other", "china specific"], | |
"virology": ["biology"], | |
"world_history": ["history"], | |
"world_religions": ["global"], | |
} | |
categories = { | |
"STEM": [ | |
"physics", | |
"chemistry", | |
"biology", | |
"computer science", | |
"math", | |
"engineering", | |
"statistics", | |
], | |
"Humanities": ["history", "philosophy", "law", "arts", "literature", "global"], | |
"Social Science": [ | |
"linguistics", | |
"business", | |
"politics", | |
"culture", | |
"economics", | |
"geography", | |
"psychology", | |
"education", | |
"sociology", | |
], | |
"Other": ["other"], | |
"China specific": ["china specific"], | |
"Test": ["computer science"], | |
} | |
def suite(cls, chat=False): | |
finer_categories = ( | |
pd.Series(cls.subcategories) # noqa # type: ignore | |
.explode() | |
.reset_index() | |
.set_index(0) | |
.groupby(0) | |
.agg(list)["index"] | |
.to_dict() | |
) | |
suite = defaultdict(list) | |
cls.categories["all"] = list(finer_categories.keys()) | |
for k, v in cls.categories.items(): | |
for subject in v: | |
suite[k].extend( | |
[ | |
Task( | |
("haonan-li/cmmlu", subcategories), | |
metric_name=("sustech/tlem", "cmmlu"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_cmmlu, chat=chat), | |
few_shot=0 if chat else 5, | |
few_shot_from="dev", | |
) | |
for subcategories in finer_categories[subject] | |
] | |
) | |
return suite | |
class MMLU: | |
input_column = "prompt" | |
label_column = "target" | |
def prompt_mmlu(cls, example, chat=False): | |
prefix = ( | |
"The following is a multiple-choice question. Please choose the most suitable one among A, B, C and D as the answer to this question.\n\n" | |
if chat | |
else "Question: " | |
) | |
prompt = prefix + example["input"] | |
for choice in list("ABCD"): | |
prompt += f"\n{choice}. {example[choice]}" | |
prompt += "\nAnswer:" | |
return {"prompt": prompt} | |
subcategories = { | |
"abstract_algebra": ["math"], | |
"anatomy": ["health"], | |
"astronomy": ["physics"], | |
"business_ethics": ["business"], | |
"clinical_knowledge": ["health"], | |
"college_biology": ["biology"], | |
"college_chemistry": ["chemistry"], | |
"college_computer_science": ["computer science"], | |
"college_mathematics": ["math"], | |
"college_medicine": ["health"], | |
"college_physics": ["physics"], | |
"computer_security": ["computer science"], | |
"conceptual_physics": ["physics"], | |
"econometrics": ["economics"], | |
"electrical_engineering": ["engineering"], | |
"elementary_mathematics": ["math"], | |
"formal_logic": ["philosophy"], | |
"global_facts": ["other"], | |
"high_school_biology": ["biology"], | |
"high_school_chemistry": ["chemistry"], | |
"high_school_computer_science": ["computer science"], | |
"high_school_european_history": ["history"], | |
"high_school_geography": ["geography"], | |
"high_school_government_and_politics": ["politics"], | |
"high_school_macroeconomics": ["economics"], | |
"high_school_mathematics": ["math"], | |
"high_school_microeconomics": ["economics"], | |
"high_school_physics": ["physics"], | |
"high_school_psychology": ["psychology"], | |
"high_school_statistics": ["math"], | |
"high_school_us_history": ["history"], | |
"high_school_world_history": ["history"], | |
"human_aging": ["health"], | |
"human_sexuality": ["culture"], | |
"international_law": ["law"], | |
"jurisprudence": ["law"], | |
"logical_fallacies": ["philosophy"], | |
"machine_learning": ["computer science"], | |
"management": ["business"], | |
"marketing": ["business"], | |
"medical_genetics": ["health"], | |
"miscellaneous": ["other"], | |
"moral_disputes": ["philosophy"], | |
"moral_scenarios": ["philosophy"], | |
"nutrition": ["health"], | |
"philosophy": ["philosophy"], | |
"prehistory": ["history"], | |
"professional_accounting": ["other"], | |
"professional_law": ["law"], | |
"professional_medicine": ["health"], | |
"professional_psychology": ["psychology"], | |
"public_relations": ["politics"], | |
"security_studies": ["politics"], | |
"sociology": ["culture"], | |
"us_foreign_policy": ["politics"], | |
"virology": ["health"], | |
"world_religions": ["philosophy"], | |
} | |
categories = { | |
"STEM": [ | |
"physics", | |
"chemistry", | |
"biology", | |
"computer science", | |
"math", | |
"engineering", | |
], | |
"humanities": ["history", "philosophy", "law"], | |
"social sciences": [ | |
"politics", | |
"culture", | |
"economics", | |
"geography", | |
"psychology", | |
], | |
"other": ["other", "business", "health"], | |
} | |
def suite(cls, chat=False): | |
finer_categories = ( | |
pd.Series(cls.subcategories) # noqa # type: ignore | |
.explode() | |
.reset_index() | |
.set_index(0) | |
.groupby(0) | |
.agg(list)["index"] | |
.to_dict() | |
) | |
suite = defaultdict(list) | |
cls.categories["all"] = list(finer_categories.keys()) | |
for k, v in cls.categories.items(): | |
for subject in v: | |
suite[k].extend( | |
[ | |
Task( | |
("lukaemon/mmlu", subcategories), | |
metric_name=("sustech/tlem", "mmlu"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_mmlu, chat=chat), | |
few_shot=0 if chat else 5, | |
few_shot_from="validation", | |
) | |
for subcategories in finer_categories[subject] | |
] | |
) | |
return suite | |
class Winogrande: | |
input_column = "input" | |
label_column = "answer" | |
categories = [ | |
"winogrande_debiased", | |
"winogrande_l", | |
"winogrande_m", | |
"winogrande_s", | |
"winogrande_xl", | |
"winogrande_xs", | |
] | |
def prompt_winogrande(cls, example): | |
option1 = example["sentence"].replace("_", example["option1"]) | |
option2 = example["sentence"].replace("_", example["option2"]) | |
answer = example[cls.label_column] | |
prompt = f"Which of the following is a good sentence:\nA. {option1}\nB. {option2}\nAnswer:" | |
return { | |
cls.input_column: prompt, | |
cls.label_column: " AB"[int(answer)] if answer != "" else "", | |
} | |
def suite( | |
cls, | |
): | |
subcategories = {item: [item] for item in cls.categories} | |
finer_categories = ( | |
pd.Series(subcategories) # noqa # type: ignore | |
.explode() | |
.reset_index() | |
.set_index(0) | |
.groupby(0) | |
.agg(list)["index"] | |
.to_dict() | |
) | |
suite = defaultdict(list) | |
subcategories["all"] = list(finer_categories.keys()) | |
for cate, sub_cates in subcategories.items(): | |
for sub_cate in sub_cates: | |
suite[cate].append( | |
Task( | |
("winogrande", sub_cate), | |
metric_name=("sustech/tlem", "winogrande"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_winogrande), | |
few_shot=0, | |
split="validation", | |
) | |
) | |
return suite | |
class DROP: | |
input_column = "input" | |
label_column = "answers" | |
icl_prompt = """\ | |
Text: In the county, the population was spread out with 23.50% under the age of 18, 8.70% from 18 to 24, 29.70% from 25 to 44, 24.70% from 45 to 64, and 13.30% who were 65 years of age or older. | |
Question: How many more percent are under the age of 18 compared to the 18 to 24 group? | |
Anawer: According to the text, 23.5% are under the age of 18, and 8.7% are from ages 18 to 24. 23.5%-8.7%=14.8%. So the answer is 14.8. | |
Text: Playing in their second straight Thanksgiving game, the Eagles struggled especially on defense, where they were unable to stop the much-hyped Lions offense. The worst of it all was how unproven rookie Eric Rowe was tasked with covering wide receiver Calvin Johnson, leading to Johnson catching 3 touchdowns. Stafford’s five passing touchdowns, including three of them to Johnson was too much for the Eagles to overcome and for the second consecutive time this season, the Eagles gave up 45 points in a game. With the loss, the Eagles drop to 4-7 on the season and 6-1 when playing on Thanksgiving. | |
Question: How many TD passes did Stafford throw other than to Johnson? | |
Anawer: According to the text, Stafford threw 5 TD passes, 3 of which were to Johnson. 5-3=2. So the answer is 2. | |
Text: [PROMPT] | |
Question: [QUESTION] | |
Anawer:""" | |
categories = ["validation"] | |
def prompt_drop(cls, example): | |
prompt = cls.icl_prompt.replace("[PROMPT]", example["passage"]).replace( | |
"[QUESTION]", example["question"] | |
) | |
validated_answers = example["answers_spans"]["spans"] | |
validated_types = example["answers_spans"]["types"] | |
answers = [] | |
for answer_item, answer_type in zip(validated_answers, validated_types): | |
# if answer_type == "number": | |
# answers.append(answer_item) | |
# elif any(answer_item['date'][i] for i in ['day', 'month', 'year']): | |
# d = [answer_item['date'][i] for i in ['day', 'month', 'year']] | |
# answers.append(' '.join(d).strip()) | |
# else: | |
# for span in answer_item['spans']: | |
# answers.append(span) | |
answers.append(answer_item) | |
answers = list(set(answers)) | |
return {cls.input_column: prompt, cls.label_column: answers} | |
def suite( | |
cls, | |
): | |
return Task( | |
"drop", | |
metric_name=("sustech/tlem", "drop"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_drop), | |
few_shot=0, | |
split="validation", | |
) | |
class HellaSwag: | |
input_column = "input" | |
label_column = "label" | |
categories = ["validation"] | |
def prompt_hellaswag(cls, example): | |
prompt = f"{example['ctx']}\nQuestion: Which ending makes the most sense?\n" | |
prompt += f"A. {example['endings'][0]}\n" | |
prompt += f"B. {example['endings'][1]}\n" | |
prompt += f"C. {example['endings'][2]}\n" | |
prompt += f"D. {example['endings'][3]}\n" | |
prompt += "You may choose from 'A', 'B', 'C', 'D'.\nAnswer:" | |
return {cls.input_column: prompt} | |
def suite( | |
cls, | |
): | |
finer_categories = ( | |
pd.Series(cls.categories) # noqa # type: ignore | |
.explode() | |
.reset_index() | |
.set_index(0) | |
.groupby(0) | |
.agg(list)["index"] | |
.to_dict() | |
) | |
suite = defaultdict(list) | |
categories = list(finer_categories.keys()) | |
for cate in categories: | |
suite[cate].append( | |
Task( | |
("Rowan/hellaswag", cate), | |
metric_name=("sustech/tlem", "hellaswag"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_hellaswag), | |
few_shot=0, | |
split="validation", | |
) | |
) | |
return suite | |
class ARC: | |
input_column = "input" | |
label_column = "answerKey" | |
categories = [ | |
"ARC-Challenge", | |
"ARC-Easy", | |
] | |
def prompt_arc(cls, example): | |
choices = example["choices"] | |
prompt = f"Question: {example['question']}" | |
for label, choice in zip(choices["label"], choices["text"]): | |
prompt += f"\n{label}. {choice}" | |
prompt += "\nAnswer:" | |
return {cls.input_column: prompt} | |
def suite(cls): | |
finer_categories = ( | |
pd.Series(cls.categories) # noqa # type: ignore | |
.explode() | |
.reset_index() | |
.set_index(0) | |
.groupby(0) | |
.agg(list)["index"] | |
.to_dict() | |
) | |
suite = defaultdict(list) | |
categories = list(finer_categories.keys()) | |
for cate in categories: | |
suite[cate].append( | |
Task( | |
("ai2_arc", cate), | |
metric_name=("sustech/tlem", "arc"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_arc), | |
few_shot=0, | |
) | |
) | |
return suite | |
class BBH: | |
input_column = "input" | |
label_column = "target" | |
multiple_choice_prefix = "Follow the given examples and answer the question.\n[HINT]\n\nQ: [INPUT]\nA: Let's think step by step." | |
free_form_prefix = "Follow the given examples and answer the question.\n[HINT]\n\nQ: [INPUT]\nA: Let's think step by step." | |
bbh_multiple_choice_sets = [ | |
"temporal_sequences", | |
"disambiguation_qa", | |
"date_understanding", | |
"tracking_shuffled_objects_three_objects", | |
"penguins_in_a_table", | |
"geometric_shapes", | |
"snarks", | |
"ruin_names", | |
"tracking_shuffled_objects_seven_objects", | |
"tracking_shuffled_objects_five_objects", | |
"logical_deduction_three_objects", | |
"hyperbaton", | |
"logical_deduction_five_objects", | |
"logical_deduction_seven_objects", | |
"movie_recommendation", | |
"salient_translation_error_detection", | |
"reasoning_about_colored_objects", | |
] | |
bbh_free_form_sets = [ | |
"multistep_arithmetic_two", | |
"navigate", | |
"dyck_languages", | |
"word_sorting", | |
"sports_understanding", | |
"boolean_expressions", | |
"object_counting", | |
"formal_fallacies", | |
"causal_judgement", | |
"web_of_lies", | |
] | |
def prompt_bbh(cls, example, category: str): | |
meta_prompt = ( | |
cls.multiple_choice_prefix | |
if category in cls.bbh_multiple_choice_sets | |
else cls.free_form_prefix | |
) | |
prompt = meta_prompt.replace( | |
"[HINT]", bbh_lib_prompt(category=category) | |
).replace("[INPUT]", example[cls.input_column]) | |
return {"input": prompt} | |
def suite( | |
cls, | |
): | |
finer_categories = ( | |
pd.Series( | |
cls.bbh_free_form_sets + cls.bbh_multiple_choice_sets | |
) # noqa # type: ignore | |
.explode() | |
.reset_index() | |
.set_index(0) | |
.groupby(0) | |
.agg(list)["index"] | |
.to_dict() | |
) | |
suite = defaultdict(list) | |
categories = list(finer_categories.keys()) | |
for cate in categories: | |
if cate in cls.bbh_multiple_choice_sets: | |
suite[cate].append( | |
Task( | |
("lukaemon/bbh", cate), | |
metric_name=("sustech/tlem", "bbh_mcq"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_bbh, category=cate), | |
few_shot=0, | |
) | |
) | |
else: | |
suite[cate].append( | |
Task( | |
("lukaemon/bbh", cate), | |
metric_name=("sustech/tlem", "bbh_freefrom"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_bbh, category=cate), | |
few_shot=0, | |
) | |
) | |
return suite | |
class CEVAL: | |
input_column = "input" | |
label_column = "answer" | |
def prompt_ceval(cls, example, cate: str, chat=False): | |
_ch_name = cls.ceval_subject_mapping[cate][1] | |
prefix = f"以下是中国关于{_ch_name}考试的单项选择题,请选出其中的正确答案。\n" if chat else "问题:" | |
prompt = prefix + f'{example["question"]}' | |
for choice in list("ABCD"): | |
prompt += f"\n{choice}. {example[choice]}" | |
prompt += "\n答案:" | |
return {"input": prompt} | |
ceval_subject_mapping = { | |
"computer_network": [ | |
"Computer Network", | |
"\u8ba1\u7b97\u673a\u7f51\u7edc", | |
"STEM", | |
], | |
"operating_system": ["Operating System", "\u64cd\u4f5c\u7cfb\u7edf", "STEM"], | |
"computer_architecture": [ | |
"Computer Architecture", | |
"\u8ba1\u7b97\u673a\u7ec4\u6210", | |
"STEM", | |
], | |
"college_programming": [ | |
"College Programming", | |
"\u5927\u5b66\u7f16\u7a0b", | |
"STEM", | |
], | |
"college_physics": ["College Physics", "\u5927\u5b66\u7269\u7406", "STEM"], | |
"college_chemistry": ["College Chemistry", "\u5927\u5b66\u5316\u5b66", "STEM"], | |
"advanced_mathematics": [ | |
"Advanced Mathematics", | |
"\u9ad8\u7b49\u6570\u5b66", | |
"STEM", | |
], | |
"probability_and_statistics": [ | |
"Probability and Statistics", | |
"\u6982\u7387\u7edf\u8ba1", | |
"STEM", | |
], | |
"discrete_mathematics": [ | |
"Discrete Mathematics", | |
"\u79bb\u6563\u6570\u5b66", | |
"STEM", | |
], | |
"electrical_engineer": [ | |
"Electrical Engineer", | |
"\u6ce8\u518c\u7535\u6c14\u5de5\u7a0b\u5e08", | |
"STEM", | |
], | |
"metrology_engineer": [ | |
"Metrology Engineer", | |
"\u6ce8\u518c\u8ba1\u91cf\u5e08", | |
"STEM", | |
], | |
"high_school_mathematics": [ | |
"High School Mathematics", | |
"\u9ad8\u4e2d\u6570\u5b66", | |
"STEM", | |
], | |
"high_school_physics": [ | |
"High School Physics", | |
"\u9ad8\u4e2d\u7269\u7406", | |
"STEM", | |
], | |
"high_school_chemistry": [ | |
"High School Chemistry", | |
"\u9ad8\u4e2d\u5316\u5b66", | |
"STEM", | |
], | |
"high_school_biology": [ | |
"High School Biology", | |
"\u9ad8\u4e2d\u751f\u7269", | |
"STEM", | |
], | |
"middle_school_mathematics": [ | |
"Middle School Mathematics", | |
"\u521d\u4e2d\u6570\u5b66", | |
"STEM", | |
], | |
"middle_school_biology": [ | |
"Middle School Biology", | |
"\u521d\u4e2d\u751f\u7269", | |
"STEM", | |
], | |
"middle_school_physics": [ | |
"Middle School Physics", | |
"\u521d\u4e2d\u7269\u7406", | |
"STEM", | |
], | |
"middle_school_chemistry": [ | |
"Middle School Chemistry", | |
"\u521d\u4e2d\u5316\u5b66", | |
"STEM", | |
], | |
"veterinary_medicine": ["Veterinary Medicine", "\u517d\u533b\u5b66", "STEM"], | |
"college_economics": [ | |
"College Economics", | |
"\u5927\u5b66\u7ecf\u6d4e\u5b66", | |
"Social Science", | |
], | |
"business_administration": [ | |
"Business Administration", | |
"\u5de5\u5546\u7ba1\u7406", | |
"Social Science", | |
], | |
"marxism": [ | |
"Marxism", | |
"\u9a6c\u514b\u601d\u4e3b\u4e49\u57fa\u672c\u539f\u7406", | |
"Social Science", | |
], | |
"mao_zedong_thought": [ | |
"Mao Zedong Thought", | |
"\u6bdb\u6cfd\u4e1c\u601d\u60f3\u548c\u4e2d\u56fd\u7279\u8272\u793e\u4f1a\u4e3b\u4e49\u7406\u8bba\u4f53\u7cfb\u6982\u8bba", | |
"Social Science", | |
], | |
"education_science": [ | |
"Education Science", | |
"\u6559\u80b2\u5b66", | |
"Social Science", | |
], | |
"teacher_qualification": [ | |
"Teacher Qualification", | |
"\u6559\u5e08\u8d44\u683c", | |
"Social Science", | |
], | |
"high_school_politics": [ | |
"High School Politics", | |
"\u9ad8\u4e2d\u653f\u6cbb", | |
"Social Science", | |
], | |
"high_school_geography": [ | |
"High School Geography", | |
"\u9ad8\u4e2d\u5730\u7406", | |
"Social Science", | |
], | |
"middle_school_politics": [ | |
"Middle School Politics", | |
"\u521d\u4e2d\u653f\u6cbb", | |
"Social Science", | |
], | |
"middle_school_geography": [ | |
"Middle School Geography", | |
"\u521d\u4e2d\u5730\u7406", | |
"Social Science", | |
], | |
"modern_chinese_history": [ | |
"Modern Chinese History", | |
"\u8fd1\u4ee3\u53f2\u7eb2\u8981", | |
"Humanities", | |
], | |
"ideological_and_moral_cultivation": [ | |
"Ideological and Moral Cultivation", | |
"\u601d\u60f3\u9053\u5fb7\u4fee\u517b\u4e0e\u6cd5\u5f8b\u57fa\u7840", | |
"Humanities", | |
], | |
"logic": ["Logic", "\u903b\u8f91\u5b66", "Humanities"], | |
"law": ["Law", "\u6cd5\u5b66", "Humanities"], | |
"chinese_language_and_literature": [ | |
"Chinese Language and Literature", | |
"\u4e2d\u56fd\u8bed\u8a00\u6587\u5b66", | |
"Humanities", | |
], | |
"art_studies": ["Art Studies", "\u827a\u672f\u5b66", "Humanities"], | |
"professional_tour_guide": [ | |
"Professional Tour Guide", | |
"\u5bfc\u6e38\u8d44\u683c", | |
"Humanities", | |
], | |
"legal_professional": [ | |
"Legal Professional", | |
"\u6cd5\u5f8b\u804c\u4e1a\u8d44\u683c", | |
"Humanities", | |
], | |
"high_school_chinese": [ | |
"High School Chinese", | |
"\u9ad8\u4e2d\u8bed\u6587", | |
"Humanities", | |
], | |
"high_school_history": [ | |
"High School History", | |
"\u9ad8\u4e2d\u5386\u53f2", | |
"Humanities", | |
], | |
"middle_school_history": [ | |
"Middle School History", | |
"\u521d\u4e2d\u5386\u53f2", | |
"Humanities", | |
], | |
"civil_servant": ["Civil Servant", "\u516c\u52a1\u5458", "Other"], | |
"sports_science": ["Sports Science", "\u4f53\u80b2\u5b66", "Other"], | |
"plant_protection": ["Plant Protection", "\u690d\u7269\u4fdd\u62a4", "Other"], | |
"basic_medicine": ["Basic Medicine", "\u57fa\u7840\u533b\u5b66", "Other"], | |
"clinical_medicine": ["Clinical Medicine", "\u4e34\u5e8a\u533b\u5b66", "Other"], | |
"urban_and_rural_planner": [ | |
"Urban and Rural Planner", | |
"\u6ce8\u518c\u57ce\u4e61\u89c4\u5212\u5e08", | |
"Other", | |
], | |
"accountant": ["Accountant", "\u6ce8\u518c\u4f1a\u8ba1\u5e08", "Other"], | |
"fire_engineer": [ | |
"Fire Engineer", | |
"\u6ce8\u518c\u6d88\u9632\u5de5\u7a0b\u5e08", | |
"Other", | |
], | |
"environmental_impact_assessment_engineer": [ | |
"Environmental Impact Assessment Engineer", | |
"\u73af\u5883\u5f71\u54cd\u8bc4\u4ef7\u5de5\u7a0b\u5e08", | |
"Other", | |
], | |
"tax_accountant": ["Tax Accountant", "\u7a0e\u52a1\u5e08", "Other"], | |
"physician": ["Physician", "\u533b\u5e08\u8d44\u683c", "Other"], | |
} | |
def suite(cls, chat: bool): | |
suite = defaultdict(list) | |
cls.categories = defaultdict(list) | |
for task, info in cls.ceval_subject_mapping.items(): | |
cls.categories[info[0]].append(task) | |
cls.categories[info[2]].append(task) | |
cls.categories["all"] = list(cls.ceval_subject_mapping.keys()) | |
for k, v in cls.categories.items(): | |
for subject in v: | |
suite[k].append( | |
Task( | |
dataset_name=("ceval/ceval-exam", subject), | |
metric_name=("sustech/tlem", "ceval"), | |
input_column=cls.input_column, | |
label_column=cls.label_column, | |
prompt=partial(cls.prompt_ceval, cate=subject, chat=chat), | |
few_shot=0 if chat else 5, | |
few_shot_from="dev", | |
split="val", | |
) | |
) | |
return suite | |