| import re |
| import torch |
| from copy import deepcopy |
| from dataclasses import dataclass, field |
| from enum import Enum |
| from modelscope.preprocessors.templates.utils import Messages |
| from typing import List |
|
|
| from swift.infer_engine.protocol import ChatCompletionResponseChoice |
|
|
|
|
| class SampleStatus(Enum): |
| INITIAL = 'initial' |
| TO_INFER = 'to_infer' |
| FINISH_NEXT_INFER = 'finish_next_infer' |
| FINISHED = 'finished' |
| ROLLBACK = 'rollback' |
|
|
|
|
| class FinishedReason(Enum): |
| ANSWER = 'finished_with_answer' |
| MAX_INFER_STEP = 'finished_with_max_infer_steps' |
| UNFINISHED = 'unfinished' |
|
|
|
|
| @dataclass |
| class DataSampleTree: |
| """ |
| Attributes: |
| tree_idx (str): |
| for example 0/1-2/2-3/4-0, root_node = 0, next node = 1-2 infer batch 1 and index 2 sample |
| |
| last_response (ChatCompletionResponseChoice): |
| vllm previous round output |
| """ |
| tree_idx: str |
| request_id: str |
|
|
| messages: Messages |
| logprobs: List[List[float]] = field(default_factory=list) |
|
|
| all_response_ids: List[List[int]] = field(default_factory=list) |
| last_response: ChatCompletionResponseChoice = None |
|
|
| token_count_per_step: List[int] = field(default_factory=list) |
|
|
| status: SampleStatus = SampleStatus.INITIAL |
| finished_reason: FinishedReason = FinishedReason.UNFINISHED |
|
|
| @property |
| def root_node(self): |
| return int(self.tree_idx.split('/')[0]) |
|
|
| @property |
| def depth(self): |
| return len(self.tree_idx.split('/')) - 1 |
|
|
| @property |
| def response_num(self): |
| return len(self.all_response_ids) |
|
|
| def response_truncate(self, truncate_len: int): |
| """ |
| Before rollback, truncate the response. |
| """ |
|
|
| if truncate_len < 1: |
| return |
|
|
| self.logprobs = self.logprobs[:-truncate_len] |
| self.all_response_ids = self.all_response_ids[:-truncate_len] |
| self.messages = self.messages[:-(truncate_len * 2 - 1)] |
| self.last_response = None |
|
|
| def extend_response(self, choice: ChatCompletionResponseChoice): |
| self.extend_response_text(choice.message.content) |
| self.extend_logprobs([item['logprob'] for item in choice.logprobs['content']]) |
|
|
| self.all_response_ids.append(choice.token_ids) |
| self.token_count_per_step.append(len(choice.token_ids)) |
|
|
| choice.logprobs = None |
| self.last_response = deepcopy(choice) |
|
|
| def extend_response_text(self, response_text: str): |
| self.messages.append({'role': 'assistant', 'content': response_text}) |
|
|
| def extend_logprobs(self, logprobs: List[float]): |
| self.logprobs.append(logprobs) |
|
|
|
|
| def _repeat_list_interleave(any_list, repeat_times): |
| |
| return [deepcopy(item) for sublist in [[item] * repeat_times for item in any_list] for item in sublist] |
|
|
|
|
| def _increment_tree_idx_depth( |
| samples: list[DataSampleTree], |
| next_infer_step: int, |
| ) -> list[DataSampleTree]: |
| for infer_batch_idx, sample in enumerate(samples): |
| sample.tree_idx = sample.tree_idx + '/' + f'{next_infer_step}-{infer_batch_idx}' |
| return samples |
|
|
|
|
| def extract_last_boxed(text): |
| pattern = r'\\boxed\{((?:[^{}]|\{(?:[^{}]|\{[^{}]*\})*\})*)\}' |
|
|
| matches = list(re.finditer(pattern, text)) |
| if matches: |
| return matches[-1].group(0) |
| return None |
|
|
|
|
| class AbstractDivergence: |
|
|
| @classmethod |
| def calc_weights(cls, root_idx, samples_to_go_deeper, **kwargs) -> List[float]: |
| pass |
|
|
| @classmethod |
| def allocate_with_weights(cls, weights, budget, max_divergence) -> List[int]: |
| n = len(weights) |
| alloc = [0] * n |
|
|
| w = [float(wi) if wi is not None and wi > 0 else 0.0 for wi in weights] |
| total_w = sum(w) |
| if total_w == 0: |
| return alloc |
|
|
| |
| ideals = [(w[i] / total_w) * budget if w[i] > 0 else 0.0 for i in range(n)] |
| for i in range(n): |
| if w[i] <= 0: |
| continue |
| f = int(ideals[i]) |
| alloc[i] = min(f, max_divergence) |
|
|
| |
| remain = budget - sum(alloc) |
| if remain <= 0: |
| return alloc |
|
|
| |
| remainders = [(ideals[i] - int(ideals[i]), i) for i in range(n) if w[i] > 0 and alloc[i] < max_divergence] |
| remainders.sort(key=lambda x: (-x[0], x[1])) |
|
|
| idx = 0 |
| while remain > 0 and remainders: |
| frac, i = remainders[idx % len(remainders)] |
| if alloc[i] < max_divergence: |
| alloc[i] += 1 |
| remain -= 1 |
|
|
| if alloc[i] >= max_divergence: |
| remainders = [r for r in remainders if r[1] != i] |
| idx = 0 |
| continue |
| idx += 1 |
|
|
| return alloc |
|
|
| @classmethod |
| def apply(cls, root_idx, samples_to_go_deeper, divergence_budget, max_divergence, **kwargs) -> List[DataSampleTree]: |
| """ |
| Args: |
| root_idx: current root node idx |
| samples_to_go_deeper: go deeper samples which root_node = root_idx |
| divergence_budget: total divergence |
| max_divergence: each sample max divergence |
| """ |
| weights = cls.calc_weights(root_idx, samples_to_go_deeper, **kwargs) |
| allocate_divergence = cls.allocate_with_weights(weights, divergence_budget, max_divergence) |
|
|
| divergence_samples = [] |
| for sample, divergence in zip(samples_to_go_deeper, allocate_divergence): |
| for _ in range(divergence): |
| divergence_samples.append(deepcopy(sample)) |
|
|
| return divergence_samples |
|
|
|
|
| class LogProbDivergence(AbstractDivergence): |
|
|
| @classmethod |
| def calc_weights(cls, root_idx, samples_to_go_deeper, **kwargs) -> List[float]: |
| """ |
| In this strategy, weight is proportional to entropy |
| """ |
| entropies = [] |
| for sample in samples_to_go_deeper: |
| log_probs = torch.tensor(sample.logprobs[-1]) |
|
|
| probs = torch.exp(log_probs) |
| entropy = -torch.sum(probs * log_probs) |
| entropies.append(entropy) |
|
|
| entropies_tensor = torch.stack(entropies) |
| weights = torch.softmax(entropies_tensor, dim=0) |
|
|
| return weights.tolist() |
|
|
|
|
| class AvgDivergence(AbstractDivergence): |
|
|
| @classmethod |
| def calc_weights(cls, root_idx, samples_to_go_deeper, **kwargs) -> List[float]: |
| avg = torch.ones(len(samples_to_go_deeper)) |
| weights = torch.softmax(avg, dim=0) |
|
|
| return weights.tolist() |
|
|
|
|
| DivergenceStrategyMapping = {'logprobs': LogProbDivergence, 'average': AvgDivergence} |
|
|