import torch import numpy as np from typing import Dict, Sequence, Tuple, Union from .data_collator import DynamicDataCollatorWithPadding from .peft_trainer import PeftTrainer from .other import get_logger logger = get_logger(__name__) def compute_accuracy(eval_preds: Sequence[Union[np.ndarray, Tuple[np.ndarray]]]) -> Dict[str, float]: preds, _ = eval_preds preds = np.array(preds) return {"accuracy": (preds[:, 0] > preds[:, 1]).sum() / len(preds)} class PairwiseDataCollatorWithPadding(DynamicDataCollatorWithPadding): r""" Data collator for pairwise data. """ def __call__(self, features: Sequence[Dict[str, Union[torch.Tensor, Sequence[int]]]]) -> Dict[str, torch.Tensor]: r""" Pads batched data to the longest sequence in the batch. We generate 2 * n examples where the first n examples represent chosen examples and the last n examples represent rejected examples. """ features = [{"input_ids": feature[key]} for key in ("accept_ids", "reject_ids") for feature in features] return super().__call__(features) class PairwisePeftTrainer(PeftTrainer): r""" Inherits PeftTrainer to compute pairwise loss. """ def __init__(self, *args, **kwargs): super().__init__(*args, **kwargs) self.can_return_loss = True # override property to return eval_loss def compute_loss(self, model, inputs, return_outputs=False): r""" Computes pairwise loss. The first n examples are chosen and the last n examples are rejected. We use score on the EOS token to represent reward of the whole sentence. Subclass and override to inject custom behavior. It should not be directly used by external scripts. """ batch_size = inputs["input_ids"].size(0) // 2 _, _, values = model(**inputs) r_accept, r_reject = values[:, -1].split(batch_size, dim=0) loss = -torch.log(torch.sigmoid(r_accept - r_reject)).mean() return (loss, torch.stack((r_accept, r_reject), dim=-1)) if return_outputs else loss