# Copyright 2024 Bytedance Ltd. and/or its affiliates # # 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. import re import string import random def normalize_answer(s): def remove_articles(text): return re.sub(r"\b(a|an|the)\b", " ", text) def white_space_fix(text): return " ".join(text.split()) def remove_punc(text): exclude = set(string.punctuation) return "".join(ch for ch in text if ch not in exclude) def lower(text): return text.lower() return white_space_fix(remove_articles(remove_punc(lower(s)))) def em_check(prediction, golden_answers): if isinstance(golden_answers, str): golden_answers = [golden_answers] normalized_prediction = normalize_answer(prediction) score = 0 for golden_answer in golden_answers: golden_answer = normalize_answer(golden_answer) if golden_answer == normalized_prediction: score = 1 break return score def subem_check(prediction, golden_answers): if isinstance(golden_answers, str): golden_answers = [golden_answers] normalized_prediction = normalize_answer(prediction) score = 0 for golden_answer in golden_answers: golden_answer = normalize_answer(golden_answer) if golden_answer in normalized_prediction: score = 1 break return score def extract_solution(solution_str): """Extract the equation from the solution string.""" # Remove everything before the first "Assistant:" # if "Assistant:" in solution_str: # solution_str = solution_str.split("Assistant:", 1)[1] # elif "<|im_start|>assistant" in solution_str: # solution_str = solution_str.split("<|im_start|>assistant", 1)[1] # else: # return None # solution_str = solution_str.split('\n')[-1] answer_pattern = r'(.*?)' match = re.finditer(answer_pattern, solution_str, re.DOTALL) matches = list(match) # If there are 0 or exactly 1 matches, return None if len(matches) <= 1: return None # If there are 2 or more matches, return the last one return matches[-1].group(1).strip() def compute_score_em(solution_str, ground_truth, method='strict', format_score=0., score=1.): """The scoring function for exact match (EM). Args: solution_str: the solution text ground_truth: the ground truth method: the method to extract the solution, choices are 'strict' and 'flexible' format_score: the score for the format score: the score for the correct answer """ answer = extract_solution(solution_str=solution_str) do_print = random.randint(1, 64) == 1 if do_print: print(f"--------------------------------") print(f"Golden answers: {ground_truth['target']}") print(f"Extracted answer: {answer}") print(f"Solution string: {solution_str}") if answer is None: return 0 else: if em_check(answer, ground_truth['target']): return score else: return format_score def compute_score_subem(solution_str, ground_truth, method='strict', format_score=0., score=1.): """The scoring function for substring exact match (EM). Args: solution_str: the solution text ground_truth: the ground truth method: the method to extract the solution, choices are 'strict' and 'flexible' format_score: the score for the format score: the score for the correct answer """ answer = extract_solution(solution_str=solution_str) do_print = random.randint(1, 64) == 1 if do_print: print(f"--------------------------------") print(f"Golden answers: {ground_truth['target']}") print(f"Extracted answer: {answer}") print(f"Solution string: {solution_str}") if answer is None: return 0 else: if subem_check(answer, ground_truth['target']): return score else: return format_score