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3ie-intervention-outcome-entity-linking / relik /retriever /callbacks /prediction_callbacks.py

riccorl

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	import logging
	import random
	import time
	from copy import deepcopy
	from pathlib import Path
	from typing import List, Optional, Set, Union

	import lightning as pl
	import torch
	from lightning.pytorch.trainer.states import RunningStage
	from omegaconf import DictConfig
	from torch.utils.data import DataLoader
	from tqdm import tqdm

	from relik.common.log import get_console_logger, get_logger
	from relik.retriever.callbacks.base import PredictionCallback
	from relik.retriever.common.model_inputs import ModelInputs
	from relik.retriever.data.base.datasets import BaseDataset
	from relik.retriever.data.datasets import GoldenRetrieverDataset
	from relik.retriever.data.utils import HardNegativesManager
	from relik.retriever.indexers.base import BaseDocumentIndex
	from relik.retriever.pytorch_modules.model import GoldenRetriever

	console_logger = get_console_logger()
	logger = get_logger(__name__, level=logging.INFO)


	class GoldenRetrieverPredictionCallback(PredictionCallback):
	def __init__(
	self,
	k: Optional[int] = None,
	batch_size: int = 32,
	num_workers: int = 8,
	document_index: Optional[BaseDocumentIndex] = None,
	precision: Union[str, int] = 32,
	force_reindex: bool = True,
	retriever_dir: Optional[Path] = None,
	stages: Optional[Set[Union[str, RunningStage]]] = None,
	other_callbacks: Optional[List[DictConfig]] = None,
	dataset: Optional[Union[DictConfig, BaseDataset]] = None,
	dataloader: Optional[DataLoader] = None,
	*args,
	**kwargs,
	):
	super().__init__(batch_size, stages, other_callbacks, dataset, dataloader)
	self.k = k
	self.num_workers = num_workers
	self.document_index = document_index
	self.precision = precision
	self.force_reindex = force_reindex
	self.retriever_dir = retriever_dir

	@torch.no_grad()
	def __call__(
	self,
	trainer: pl.Trainer,
	pl_module: pl.LightningModule,
	datasets: Optional[
	Union[DictConfig, BaseDataset, List[DictConfig], List[BaseDataset]]
	] = None,
	dataloaders: Optional[Union[DataLoader, List[DataLoader]]] = None,
	*args,
	**kwargs,
	) -> dict:
	stage = trainer.state.stage
	logger.info(f"Computing predictions for stage {stage.value}")
	if stage not in self.stages:
	raise ValueError(
	f"Stage `{stage}` not supported, only {self.stages} are supported"
	)

	self.datasets, self.dataloaders = self._get_datasets_and_dataloaders(
	datasets,
	dataloaders,
	trainer,
	dataloader_kwargs=dict(
	batch_size=self.batch_size,
	num_workers=self.num_workers,
	pin_memory=True,
	shuffle=False,
	),
	)

	# set the model to eval mode
	pl_module.eval()
	# get the retriever
	retriever: GoldenRetriever = pl_module.model

	# here we will store the samples with predictions for each dataloader
	dataloader_predictions = {}
	# compute the passage embeddings index for each dataloader
	for dataloader_idx, dataloader in enumerate(self.dataloaders):
	current_dataset: GoldenRetrieverDataset = self.datasets[dataloader_idx]
	logger.info(
	f"Computing passage embeddings for dataset {current_dataset.name}"
	)
	# passages = self._get_passages_dataloader(current_dataset, trainer)

	tokenizer = current_dataset.tokenizer

	def collate_fn(x):
	return ModelInputs(
	tokenizer(
	x,
	truncation=True,
	padding=True,
	max_length=current_dataset.max_passage_length,
	return_tensors="pt",
	)
	)

	# check if we need to reindex the passages and
	# also if we need to load the retriever from disk
	if (self.retriever_dir is not None and trainer.current_epoch == 0) or (
	self.retriever_dir is not None and stage == RunningStage.TESTING
	):
	force_reindex = False
	else:
	force_reindex = self.force_reindex

	if (
	not force_reindex
	and self.retriever_dir is not None
	and stage == RunningStage.TESTING
	):
	retriever = retriever.from_pretrained(self.retriever_dir)
	# set the retriever to eval mode if we are loading it from disk

	# you never know :)
	retriever.eval()

	retriever.index(
	batch_size=self.batch_size,
	num_workers=self.num_workers,
	max_length=current_dataset.max_passage_length,
	collate_fn=collate_fn,
	precision=self.precision,
	compute_on_cpu=False,
	force_reindex=force_reindex,
	)

	# pl_module_original_device = pl_module.device
	# if (
	# and pl_module.device.type == "cuda"
	# ):
	# pl_module.to("cpu")

	# now compute the question embeddings and compute the top-k accuracy
	predictions = []
	start = time.time()
	for batch in tqdm(
	dataloader,
	desc=f"Computing predictions for dataset {current_dataset.name}",
	):
	batch = batch.to(pl_module.device)
	# get the top-k indices
	retriever_output = retriever.retrieve(
	**batch.questions, k=self.k, precision=self.precision
	)
	# compute recall at k
	for batch_idx, retrieved_samples in enumerate(retriever_output):
	# get the positive passages
	gold_passages = batch["positives"][batch_idx]
	# get the index of the gold passages in the retrieved passages
	gold_passage_indices = [
	retriever.get_index_from_passage(passage)
	for passage in gold_passages
	]
	retrieved_indices = [r.index for r in retrieved_samples]
	retrieved_passages = [r.label for r in retrieved_samples]
	retrieved_scores = [r.score for r in retrieved_samples]
	# correct predictions are the passages that are in the top-k and are gold
	correct_indices = set(gold_passage_indices) & set(retrieved_indices)
	# wrong predictions are the passages that are in the top-k and are not gold
	wrong_indices = set(retrieved_indices) - set(gold_passage_indices)
	# add the predictions to the list
	prediction_output = dict(
	sample_idx=batch.sample_idx[batch_idx],
	gold=gold_passages,
	predictions=retrieved_passages,
	scores=retrieved_scores,
	correct=[
	retriever.get_passage_from_index(i) for i in correct_indices
	],
	wrong=[
	retriever.get_passage_from_index(i) for i in wrong_indices
	],
	)
	predictions.append(prediction_output)
	end = time.time()
	logger.info(f"Time to retrieve: {str(end - start)}")

	dataloader_predictions[dataloader_idx] = predictions

	# if pl_module_original_device != pl_module.device:
	# pl_module.to(pl_module_original_device)

	# return the predictions
	return dataloader_predictions

	# @staticmethod
	# def _get_passages_dataloader(
	# indexer: Optional[BaseIndexer] = None,
	# dataset: Optional[GoldenRetrieverDataset] = None,
	# trainer: Optional[pl.Trainer] = None,
	# ):
	# if indexer is None:
	# logger.info(
	# f"Indexer is None, creating indexer from passages not found in dataset {dataset.name}, computing them from the dataloaders"
	# )
	# # get the passages from the all the dataloader passage ids
	# passages = set() # set to avoid duplicates
	# for batch in trainer.train_dataloader:
	# passages.update(
	# [
	# " ".join(map(str, [c for c in passage_ids.tolist() if c != 0]))
	# for passage_ids in batch["passages"]["input_ids"]
	# ]
	# )
	# for d in trainer.val_dataloaders:
	# for batch in d:
	# passages.update(
	# [
	# " ".join(
	# map(str, [c for c in passage_ids.tolist() if c != 0])
	# )
	# for passage_ids in batch["passages"]["input_ids"]
	# ]
	# )
	# for d in trainer.test_dataloaders:
	# for batch in d:
	# passages.update(
	# [
	# " ".join(
	# map(str, [c for c in passage_ids.tolist() if c != 0])
	# )
	# for passage_ids in batch["passages"]["input_ids"]
	# ]
	# )
	# passages = list(passages)
	# else:
	# passages = dataset.passages
	# return passages


	class NegativeAugmentationCallback(GoldenRetrieverPredictionCallback):
	"""
	Callback that computes the predictions of a retriever model on a dataset and computes the
	negative examples for the training set.

	Args:
	k (:obj:`int`, `optional`, defaults to 100):
	The number of top-k retrieved passages to
	consider for the evaluation.
	batch_size (:obj:`int`, `optional`, defaults to 32):
	The batch size to use for the evaluation.
	num_workers (:obj:`int`, `optional`, defaults to 0):
	The number of workers to use for the evaluation.
	force_reindex (:obj:`bool`, `optional`, defaults to :obj:`False`):
	Whether to force the reindexing of the dataset.
	retriever_dir (:obj:`Path`, `optional`):
	The path to the retriever directory. If not specified, the retriever will be
	initialized from scratch.
	stages (:obj:`Set[str]`, `optional`):
	The stages to run the callback on. If not specified, the callback will be run on
	train, validation and test.
	other_callbacks (:obj:`List[DictConfig]`, `optional`):
	A list of other callbacks to run on the same stages.
	dataset (:obj:`Union[DictConfig, BaseDataset]`, `optional`):
	The dataset to use for the evaluation. If not specified, the dataset will be
	initialized from scratch.
	metrics_to_monitor (:obj:`List[str]`, `optional`):
	The metrics to monitor for the evaluation.
	threshold (:obj:`float`, `optional`, defaults to 0.8):
	The threshold to consider. If the recall score of the retriever is above the
	threshold, the negative examples will be added to the training set.
	max_negatives (:obj:`int`, `optional`, defaults to 5):
	The maximum number of negative examples to add to the training set.
	add_with_probability (:obj:`float`, `optional`, defaults to 1.0):
	The probability with which to add the negative examples to the training set.
	refresh_every_n_epochs (:obj:`int`, `optional`, defaults to 1):
	The number of epochs after which to refresh the index.
	"""

	def __init__(
	self,
	k: int = 100,
	batch_size: int = 32,
	num_workers: int = 0,
	force_reindex: bool = False,
	retriever_dir: Optional[Path] = None,
	stages: Set[Union[str, RunningStage]] = None,
	other_callbacks: Optional[List[DictConfig]] = None,
	dataset: Optional[Union[DictConfig, BaseDataset]] = None,
	metrics_to_monitor: List[str] = None,
	threshold: float = 0.8,
	max_negatives: int = 5,
	add_with_probability: float = 1.0,
	refresh_every_n_epochs: int = 1,
	*args,
	**kwargs,
	):
	super().__init__(
	k=k,
	batch_size=batch_size,
	num_workers=num_workers,
	force_reindex=force_reindex,
	retriever_dir=retriever_dir,
	stages=stages,
	other_callbacks=other_callbacks,
	dataset=dataset,
	*args,
	**kwargs,
	)
	if metrics_to_monitor is None:
	metrics_to_monitor = ["val_loss"]
	self.metrics_to_monitor = metrics_to_monitor
	self.threshold = threshold
	self.max_negatives = max_negatives
	self.add_with_probability = add_with_probability
	self.refresh_every_n_epochs = refresh_every_n_epochs

	@torch.no_grad()
	def __call__(
	self,
	trainer: pl.Trainer,
	pl_module: pl.LightningModule,
	*args,
	**kwargs,
	) -> dict:
	"""
	Computes the predictions of a retriever model on a dataset and computes the negative
	examples for the training set.

	Args:
	trainer (:obj:`pl.Trainer`):
	The trainer object.
	pl_module (:obj:`pl.LightningModule`):
	The lightning module.

	Returns:
	A dictionary containing the negative examples.
	"""
	stage = trainer.state.stage
	if stage not in self.stages:
	return {}

	if self.metrics_to_monitor not in trainer.logged_metrics:
	raise ValueError(
	f"Metric `{self.metrics_to_monitor}` not found in trainer.logged_metrics"
	f"Available metrics: {trainer.logged_metrics.keys()}"
	)
	if trainer.logged_metrics[self.metrics_to_monitor] < self.threshold:
	return {}

	if trainer.current_epoch % self.refresh_every_n_epochs != 0:
	return {}

	# if all(
	# [
	# trainer.logged_metrics.get(metric) is None
	# for metric in self.metrics_to_monitor
	# ]
	# ):
	# raise ValueError(
	# f"No metric from {self.metrics_to_monitor} not found in trainer.logged_metrics"
	# f"Available metrics: {trainer.logged_metrics.keys()}"
	# )

	# if all(
	# [
	# trainer.logged_metrics.get(metric) < self.threshold
	# for metric in self.metrics_to_monitor
	# if trainer.logged_metrics.get(metric) is not None
	# ]
	# ):
	# return {}

	if trainer.current_epoch % self.refresh_every_n_epochs != 0:
	return {}

	logger.info(
	f"At least one metric from {self.metrics_to_monitor} is above threshold "
	f"{self.threshold}. Computing hard negatives."
	)

	# make a copy of the dataset to avoid modifying the original one
	trainer.datamodule.train_dataset.hn_manager = None
	dataset_copy = deepcopy(trainer.datamodule.train_dataset)
	predictions = super().__call__(
	trainer,
	pl_module,
	datasets=dataset_copy,
	dataloaders=DataLoader(
	dataset_copy.to_torch_dataset(),
	shuffle=False,
	batch_size=None,
	num_workers=self.num_workers,
	pin_memory=True,
	collate_fn=lambda x: x,
	),
	*args,
	**kwargs,
	)
	logger.info(f"Computing hard negatives for epoch {trainer.current_epoch}")
	# predictions is a dict with the dataloader index as key and the predictions as value
	# since we only have one dataloader, we can get the predictions directly
	predictions = list(predictions.values())[0]
	# store the predictions in a dictionary for faster access based on the sample index
	hard_negatives_list = {}
	for prediction in tqdm(predictions, desc="Collecting hard negatives"):
	if random.random() < 1 - self.add_with_probability:
	continue
	top_k_passages = prediction["predictions"]
	gold_passages = prediction["gold"]
	# get the ids of the max_negatives wrong passages with the highest similarity
	wrong_passages = [
	passage_id
	for passage_id in top_k_passages
	if passage_id not in gold_passages
	][: self.max_negatives]
	hard_negatives_list[prediction["sample_idx"]] = wrong_passages

	trainer.datamodule.train_dataset.hn_manager = HardNegativesManager(
	tokenizer=trainer.datamodule.train_dataset.tokenizer,
	max_length=trainer.datamodule.train_dataset.max_passage_length,
	data=hard_negatives_list,
	)

	# normalize predictions as in the original GoldenRetrieverPredictionCallback
	predictions = {0: predictions}
	return predictions