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import re |
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import string |
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import uuid |
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from abc import ABC, abstractmethod |
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from collections import Counter |
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from dataclasses import field |
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from statistics import mean |
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from typing import Any, Dict, Generator, List, Optional, Tuple |
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import evaluate |
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import numpy |
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import numpy as np |
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from scipy.stats import bootstrap |
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from .artifact import Artifact |
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from .dataclass import InternalField, OptionalField |
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from .logging_utils import get_logger |
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from .operator import ( |
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MultiStreamOperator, |
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SingleStreamOperator, |
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StreamingOperator, |
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StreamInstanceOperator, |
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) |
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from .operators import CopyFields |
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from .random_utils import get_seed |
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from .stream import MultiStream, Stream |
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from .type_utils import isoftype |
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logger = get_logger() |
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_N_RESAMPLES_DEFAULT_FOR_INSTANCE_METRICS = 1000 |
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_N_RESAMPLES_DEFAULT_FOR_GLOBAL_METRICS = 100 |
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def abstract_factory(): |
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return {} |
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def abstract_field(): |
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return field(default_factory=abstract_factory) |
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class UpdateStream(StreamInstanceOperator): |
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update: dict |
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def process( |
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self, instance: Dict[str, Any], stream_name: Optional[str] = None |
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) -> Dict[str, Any]: |
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instance.update(self.update) |
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return instance |
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class Metric(Artifact): |
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@property |
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@abstractmethod |
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def main_score(self): |
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pass |
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class MetricWithConfidenceInterval(Metric): |
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n_resamples: int = None |
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confidence_level: float = 0.95 |
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ci_scores: List[str] = None |
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@staticmethod |
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def new_random_generator(): |
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_max_32bit = 2**32 - 1 |
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return np.random.default_rng(hash(get_seed()) & _max_32bit) |
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def disable_confidence_interval_calculation(self): |
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self.n_resamples = None |
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def _can_compute_confidence_intervals(self, num_predictions): |
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return ( |
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self.n_resamples is not None |
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and self.n_resamples > 1 |
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and num_predictions > 1 |
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) |
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def score_based_confidence_interval(self, instances): |
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"""Compute confidence intervals based on existing scores, already computed on the input instances. |
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score_names: List[str] |
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Compute a confidence interval for each score_name from this list. |
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instances: |
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The instances for which the confidence intervals are computed. |
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""" |
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from statistics import mean |
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result = {} |
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if not self._can_compute_confidence_intervals(num_predictions=len(instances)): |
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return result |
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score_names = ( |
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self.ci_scores if self.ci_scores is not None else [self.main_score] |
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) |
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for score_name in score_names: |
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scores = [ |
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instance["score"]["instance"][score_name] for instance in instances |
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] |
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ci = bootstrap( |
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(scores,), |
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statistic=mean, |
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n_resamples=self.n_resamples, |
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confidence_level=self.confidence_level, |
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random_state=self.new_random_generator(), |
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).confidence_interval |
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result[f"{score_name}_ci_low"] = ci.low |
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result[f"{score_name}_ci_high"] = ci.high |
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if score_name == self.main_score: |
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result["score_ci_low"] = ci.low |
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result["score_ci_high"] = ci.high |
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return result |
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def compute_global_confidence_intervals( |
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self, references, predictions, additional_inputs, score_name |
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): |
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"""Computed confidence intervals for a set of references and predictions.""" |
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random_gen = self.new_random_generator() |
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def statistic(arr, axis): |
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def metric(sample_refs, sample_preds, sample_additional_inputs): |
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try: |
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return self._compute( |
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references=sample_refs, |
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predictions=sample_preds, |
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additional_inputs=sample_additional_inputs, |
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)["score"] |
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except Exception as e: |
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logger.info(f"Warning in {self.__class__.__name__}", e) |
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return np.nan |
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scores = numpy.apply_along_axis( |
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lambda x: metric( |
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sample_refs=[references[i] for i in x], |
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sample_preds=[predictions[i] for i in x], |
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sample_additional_inputs=[additional_inputs[i] for i in x], |
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), |
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axis=axis, |
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arr=arr, |
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) |
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if scores.size > 1: |
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error_indices = numpy.isnan(scores) |
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n_errors = sum(error_indices) |
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if n_errors > 0: |
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new_scores = random_gen.choice(scores, n_errors, replace=True) |
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scores = scores[~error_indices] |
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scores = np.concatenate([scores, new_scores]) |
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return scores |
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result = {} |
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num_predictions = len(predictions) |
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if self._can_compute_confidence_intervals(num_predictions=num_predictions): |
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identifiers = list(range(num_predictions)) |
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ci = bootstrap( |
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(identifiers,), |
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statistic=statistic, |
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n_resamples=self.n_resamples, |
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confidence_level=self.confidence_level, |
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random_state=random_gen, |
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).confidence_interval |
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result["score_ci_low"] = ci.low |
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result["score_ci_high"] = ci.high |
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result[f"{score_name}_ci_low"] = ci.low |
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result[f"{score_name}_ci_high"] = ci.high |
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return result |
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class GlobalMetric(SingleStreamOperator, MetricWithConfidenceInterval): |
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"""A class for computing metrics that require joint calculations over all instances and are not just aggregation of scores of individuals instances. |
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For example, macro_F1 requires |
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calculation requires calculation of recall and precision per class, so all instances of the class |
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need to be considered. Accuracy, on the other hand, is just an average of the accuracy of all the instances. |
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""" |
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n_resamples = _N_RESAMPLES_DEFAULT_FOR_GLOBAL_METRICS |
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def process(self, stream: Stream, stream_name: Optional[str] = None) -> Generator: |
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references = [] |
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predictions = [] |
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additional_inputs = [] |
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global_score = {} |
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instances = [] |
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for instance in stream: |
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if "score" not in instance: |
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instance["score"] = {"global": global_score, "instance": {}} |
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else: |
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global_score = instance["score"]["global"] |
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instance_references, instance_prediction = ( |
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instance["references"], |
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instance["prediction"], |
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) |
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references.append(instance_references) |
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predictions.append(instance_prediction) |
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instances.append(instance) |
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instance_additional_inputs = ( |
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instance["additional_inputs"] if "additional_inputs" in instance else {} |
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) |
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additional_inputs.append(instance_additional_inputs) |
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try: |
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instance_score = self._compute( |
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[instance_references], |
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[instance_prediction], |
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[instance_additional_inputs], |
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) |
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except: |
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instance_score = {"score": None, "score_name": self.main_score} |
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if isinstance(self.main_score, str): |
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instance_score[self.main_score] = None |
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instance["score"]["instance"].update(instance_score) |
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result = self._compute(references, predictions, additional_inputs) |
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global_score.update(result) |
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score_name = global_score["score_name"] |
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confidence_interval = self.compute_global_confidence_intervals( |
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references, predictions, additional_inputs, score_name |
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) |
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global_score.update(confidence_interval) |
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for instance in instances: |
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instance["score"]["global"] = global_score |
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yield instance |
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def _compute( |
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self, |
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references: List[List[str]], |
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predictions: List[str], |
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additional_inputs: List[Any], |
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) -> dict: |
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result = self.compute(references, predictions, additional_inputs) |
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result["score"] = result[self.main_score] |
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result["score_name"] = self.main_score |
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return result |
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@abstractmethod |
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def compute( |
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self, |
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references: List[List[Any]], |
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predictions: List[Any], |
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additional_inputs: List[Any], |
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) -> dict: |
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pass |
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class BulkInstanceMetric(SingleStreamOperator, MetricWithConfidenceInterval): |
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n_resamples = _N_RESAMPLES_DEFAULT_FOR_INSTANCE_METRICS |
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main_score: str |
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reduction_map: Dict[str, List[str]] |
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implemented_reductions: List[str] = field(default_factory=lambda: ["mean"]) |
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def process(self, stream: Stream, stream_name: Optional[str] = None) -> Generator: |
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global_score = {} |
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instances = [] |
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references, predictions = map( |
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list, |
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zip( |
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*[ |
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(instance["references"], instance["prediction"]) |
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for instance in stream |
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] |
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), |
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) |
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additional_inputs = [ |
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instance["additional_inputs"] if "additional_inputs" in instance else {} |
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for instance in stream |
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] |
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instance_scores = self.compute( |
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references=references, |
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predictions=predictions, |
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additional_inputs=additional_inputs, |
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) |
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for instance_score in instance_scores: |
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instance_score["score"] = instance_score[self.main_score] |
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instance_score["score_name"] = self.main_score |
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for instance, score in zip(stream, instance_scores): |
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if "score" not in instance: |
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instance["score"] = {"global": global_score, "instance": {}} |
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else: |
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global_score = instance["score"]["global"] |
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instance["score"]["instance"].update(score) |
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instances.append(instance) |
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for reduction, fields in self.reduction_map.items(): |
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assert ( |
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reduction in self.implemented_reductions |
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), f"Reduction {reduction} is not implemented, use one of {self.implemented_reductions}" |
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if reduction == "mean": |
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from statistics import mean |
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for field_name in fields: |
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global_score[field_name] = mean( |
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[ |
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instance["score"]["instance"][field_name] |
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for instance in instances |
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] |
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) |
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if field_name == self.main_score: |
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global_score["score"] = global_score[field_name] |
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global_score["score_name"] = self.main_score |
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confidence_interval = self.score_based_confidence_interval( |
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instances=instances |
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) |
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global_score.update(confidence_interval) |
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for instance in instances: |
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yield instance |
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@abstractmethod |
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def compute( |
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self, |
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references: List[List[Any]], |
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predictions: List[Any], |
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additional_inputs: List[Dict], |
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) -> List[Dict[str, Any]]: |
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pass |
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class InstanceMetric(SingleStreamOperator, MetricWithConfidenceInterval): |
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n_resamples = _N_RESAMPLES_DEFAULT_FOR_INSTANCE_METRICS |
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implemented_reductions: List[str] = field(default_factory=lambda: ["mean"]) |
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|
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@property |
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@abstractmethod |
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def reduction_map(self) -> dict: |
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pass |
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def process(self, stream: Stream, stream_name: Optional[str] = None) -> Generator: |
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global_score = {} |
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instances = [] |
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|
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for instance in stream: |
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refs, pred = instance["references"], instance["prediction"] |
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additional_inputs = ( |
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instance["additional_inputs"] if "additional_inputs" in instance else {} |
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) |
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instance_score = self.compute( |
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references=refs, prediction=pred, additional_inputs=additional_inputs |
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) |
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instance_score["score"] = instance_score[self.main_score] |
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instance_score["score_name"] = self.main_score |
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if "score" not in instance: |
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instance["score"] = {"global": global_score, "instance": {}} |
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else: |
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global_score = instance["score"]["global"] |
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instance["score"]["instance"].update(instance_score) |
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instances.append(instance) |
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for reduction, fields in self.reduction_map.items(): |
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assert ( |
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reduction in self.implemented_reductions |
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), f"Reduction {reduction} is not implemented, use one of {self.implemented_reductions}" |
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|
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if reduction == "mean": |
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from statistics import mean |
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for field_name in fields: |
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scores = [ |
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instance["score"]["instance"][field_name] |
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for instance in instances |
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] |
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global_score[field_name] = mean(scores) |
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if field_name == self.main_score: |
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global_score["score"] = global_score[field_name] |
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global_score["score_name"] = self.main_score |
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confidence_interval = self.score_based_confidence_interval( |
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instances=instances |
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) |
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global_score.update(confidence_interval) |
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|
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for instance in instances: |
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yield instance |
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@abstractmethod |
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def compute( |
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self, references: List[Any], prediction: Any, additional_inputs: Dict |
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) -> dict: |
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pass |
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|
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class Squad(GlobalMetric): |
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_metric = None |
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main_score = "f1" |
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metric = "squad" |
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def prepare(self): |
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super().prepare() |
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self._metric = evaluate.load(self.metric) |
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|
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def compute( |
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self, |
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references: List[List[str]], |
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predictions: List[str], |
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additional_inputs: List[Dict], |
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) -> dict: |
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ids = [str(uuid.uuid4()).replace("-", "") for _ in range(len(predictions))] |
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formatted_predictions = [ |
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{"prediction_text": prediction, "id": ids[i]} |
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for i, prediction in enumerate(predictions) |
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] |
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formatted_references = [ |
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{"answers": {"answer_start": [-1], "text": reference}, "id": ids[i]} |
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for i, reference in enumerate(references) |
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] |
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return self._metric.compute( |
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predictions=formatted_predictions, |
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references=formatted_references, |
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) |
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|
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class Accuracy(InstanceMetric): |
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reduction_map = {"mean": ["accuracy"]} |
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main_score = "accuracy" |
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|
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def compute( |
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self, references: List[Any], prediction: Any, additional_inputs: List[Dict] |
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) -> dict: |
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result = { |
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self.main_score: float( |
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str(prediction) in [str(reference) for reference in references] |
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) |
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} |
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result["score"] = result[self.main_score] |
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result["score_name"] = self.main_score |
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return result |
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class StringContainment(InstanceMetric): |
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reduction_map = {"mean": ["string_containment"]} |
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main_score = "string_containment" |
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|
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def compute( |
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self, references: List[Any], prediction: Any, additional_inputs: List[Dict] |
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) -> dict: |
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result = { |
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self.main_score: float( |
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any(str(reference) in prediction for reference in references) |
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) |
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} |
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result["score"] = result[self.main_score] |
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result["score_name"] = self.main_score |
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return result |
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|
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class MetricPipeline(MultiStreamOperator, Metric): |
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main_score: str = None |
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preprocess_steps: Optional[List[StreamingOperator]] = field(default_factory=list) |
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postpreprocess_steps: Optional[List[StreamingOperator]] = field( |
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default_factory=list |
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) |
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metric: Metric = None |
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|
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def verify(self): |
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assert self.main_score is not None, "main_score is not set" |
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|
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def prepare(self): |
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super().prepare() |
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self.prepare_score = CopyFields( |
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field_to_field=[ |
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[f"score/instance/{self.main_score}", "score/instance/score"], |
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[f"score/global/{self.main_score}", "score/global/score"], |
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], |
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use_query=True, |
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) |
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|
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def process(self, multi_stream: MultiStream) -> MultiStream: |
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for step in self.preprocess_steps: |
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multi_stream = step(multi_stream) |
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multi_stream = self.metric(multi_stream) |
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for step in self.postpreprocess_steps: |
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multi_stream = step(multi_stream) |
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return self.prepare_score(multi_stream) |
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|
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class HuggingfaceMetric(GlobalMetric): |
|
hf_metric_name: str = None |
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main_score: str = None |
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hf_main_score: str = ( |
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None |
|
) |
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|
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scale: float = 1.0 |
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scaled_fields: list = None |
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|
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hf_compute_args: Dict[str, Any] = OptionalField(default_factory=dict) |
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|
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hf_additional_input_fields: List = OptionalField(default_factory=list) |
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|
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hf_additional_input_fields_pass_one_value: List = OptionalField( |
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default_factory=list |
|
) |
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|
|
experiment_id: str = OptionalField(default_factory=lambda: str(uuid.uuid4())) |
|
|
|
def verify(self): |
|
assert ( |
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self.hf_additional_input_fields is None |
|
or isoftype(self.hf_additional_input_fields, List[str]) |
|
), f"Argument hf_additional_input_fields should be either None or List[str]. It is now: {self.hf_additional_input_fields}." |
|
assert ( |
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self.hf_additional_input_fields_pass_one_value is None |
|
or isoftype(self.hf_additional_input_fields_pass_one_value, List[str]) |
|
), f"Argument hf_additional_input_fields_pass_one_value should be either None or List[str]. It is now: {self.hf_additional_input_fields_pass_one_value}." |
|
|
|
return super().verify() |
|
|
|
def prepare(self): |
|
super().prepare() |
|
self.metric = evaluate.load( |
|
self.hf_metric_name, experiment_id=self.experiment_id |
|
) |
|
|
|
def compute( |
|
self, |
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references: List[List[Any]], |
|
predictions: List[Any], |
|
additional_inputs: List[Dict], |
|
) -> dict: |
|
passed_additional_inputs = {} |
|
for additional_input_field in self.hf_additional_input_fields: |
|
assert ( |
|
additional_input_field in additional_inputs[0] |
|
), f"'{additional_input_field}' field required by {__class__.__name__} is not in passed in additional inputs: {additional_inputs[0]}" |
|
passed_additional_inputs[additional_input_field] = [ |
|
additional_input[additional_input_field] |
|
for additional_input in additional_inputs |
|
] |
|
for additional_input_field in self.hf_additional_input_fields_pass_one_value: |
|
assert ( |
|
additional_input_field in additional_inputs[0] |
|
), f"'{additional_input_field}' field required by {__class__.__name__} is not in passed in additional inputs: {additional_inputs[0]}" |
|
|
|
values = { |
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additional_input[additional_input_field] |
|
for additional_input in additional_inputs |
|
} |
|
assert ( |
|
len(values) == 1 |
|
), f"Values of '{additional_input_field}' field required by {__class__.__name__} should all be the same, but have multiple values {values}" |
|
|
|
passed_additional_inputs[additional_input_field] = next(iter(values)) |
|
|
|
|
|
result = self.metric.compute( |
|
predictions=predictions, |
|
references=references, |
|
**passed_additional_inputs, |
|
**self.hf_compute_args, |
|
) |
|
if self.hf_main_score: |
|
result[self.main_score] = result[self.hf_main_score] |
|
del result[self.hf_main_score] |
|
if self.scale != 1.0: |
|
assert ( |
|
self.scaled_fields is not None |
|
), f"Scaling factor was set to {self.scale}, but no fields specified" |
|
for key in self.scaled_fields: |
|
assert ( |
|
key in result |
|
), f"Trying to scale field '{key}' which is not in results of metrics: {result}" |
|
if isinstance(result[key], list): |
|
assert all( |
|
isinstance(v, float) for v in result[key] |
|
), "Not all scaled field '{key}' values are floats: {result[key]}" |
|
result[key] = [v / self.scale for v in result[key]] |
|
else: |
|
assert isinstance( |
|
result[key], float |
|
), "Scaled field '{key}' is not float: {result[key]}" |
|
result[key] /= self.scale |
|
return result |
|
|
|
|
|
class HuggingfaceBulkMetric(BulkInstanceMetric): |
|
hf_metric_name: str |
|
|
|
hf_metric_fields: List[str] |
|
hf_compute_args: dict = {} |
|
hf_additional_input_fields: List = OptionalField(default_factory=list) |
|
|
|
def prepare(self): |
|
super().prepare() |
|
self.metric = evaluate.load(self.hf_metric_name) |
|
|
|
def compute( |
|
self, |
|
references: List[List[str]], |
|
predictions: List[str], |
|
additional_inputs: List[Any], |
|
) -> List[Dict[str, Any]]: |
|
passed_additional_inputs = {} |
|
for additional_input_field in self.hf_additional_input_fields: |
|
assert ( |
|
additional_input_field in additional_inputs[0] |
|
), f"'{additional_input_field}' field required by {__class__.__name__} is not in passed in additional inputs: {additional_inputs[0]}" |
|
passed_additional_inputs[additional_input_field] = [ |
|
additional_input[additional_input_field] |
|
for additional_input in additional_inputs |
|
] |
|
|
|
|
|
scores = self.metric.compute( |
|
predictions=predictions, |
|
references=references, |
|
**passed_additional_inputs, |
|
**self.hf_compute_args, |
|
) |
|
|
|
|
|
results = [{} for _ in range(len(scores[self.hf_metric_fields[0]]))] |
|
for key in self.hf_metric_fields: |
|
values = scores[key] |
|
for result_id, result in enumerate(results): |
|
result[key] = values[result_id] |
|
|
|
return results |
|
|
|
|
|
class F1(GlobalMetric): |
|
_metric = None |
|
main_score = "f1_macro" |
|
average = None |
|
metric = "f1" |
|
|
|
def prepare(self): |
|
super().prepare() |
|
self._metric = evaluate.load(self.metric) |
|
|
|
def get_str_id(self, str): |
|
if str not in self.str_to_id: |
|
id = len(self.str_to_id) |
|
self.str_to_id[str] = id |
|
self.id_to_str[id] = str |
|
return self.str_to_id[str] |
|
|
|
def compute( |
|
self, |
|
references: List[List[str]], |
|
predictions: List[str], |
|
additional_inputs: List[Dict], |
|
) -> dict: |
|
assert all( |
|
len(reference) == 1 for reference in references |
|
), "Only a single reference per prediction is allowed in F1 metric" |
|
self.str_to_id = {} |
|
self.id_to_str = {} |
|
formatted_references = [ |
|
self.get_str_id(reference[0]) for reference in references |
|
] |
|
self.str_to_id.keys() |
|
formatted_predictions = [ |
|
self.get_str_id(prediction) for prediction in predictions |
|
] |
|
labels = list(set(formatted_references)) |
|
result = self._metric.compute( |
|
predictions=formatted_predictions, |
|
references=formatted_references, |
|
labels=labels, |
|
average=self.average, |
|
) |
|
if isinstance(result["f1"], numpy.ndarray): |
|
from statistics import mean |
|
|
|
final_result = {self.main_score: mean(result["f1"])} |
|
for i, label in enumerate(labels): |
|
final_result["f1_" + self.id_to_str[label]] = result["f1"][i] |
|
else: |
|
final_result = {self.main_score: result["f1"]} |
|
return final_result |
|
|
|
|
|
class F1Micro(F1): |
|
main_score = "f1_micro" |
|
average = "micro" |
|
|
|
|
|
class F1Macro(F1): |
|
main_score = "f1_macro" |
|
|
|
|
|
class F1Weighted(F1): |
|
main_score = "f1_weighted" |
|
average = "weighted" |
|
|
|
|
|
class F1MultiLabel(GlobalMetric): |
|
_metric = None |
|
main_score = "f1_macro" |
|
average = None |
|
classes_to_ignore = ["none"] |
|
metric = "f1" |
|
|
|
def prepare(self): |
|
super().prepare() |
|
self._metric = evaluate.load(self.metric, "multilabel") |
|
|
|
def add_str_to_id(self, str): |
|
if str not in self.str_to_id: |
|
id = len(self.str_to_id) |
|
self.str_to_id[str] = id |
|
self.id_to_str[id] = str |
|
return |
|
|
|
def get_one_hot_vector(self, labels: List[str]): |
|
result = [0] * len(self.str_to_id) |
|
for label in labels: |
|
if label in self.str_to_id: |
|
result[self.str_to_id[label]] = 1 |
|
return result |
|
|
|
def compute( |
|
self, |
|
references: List[List[str]], |
|
predictions: List[List[str]], |
|
additional_inputs: List[Dict], |
|
) -> dict: |
|
self.str_to_id = {} |
|
self.id_to_str = {} |
|
|
|
self._validate_references_and_prediction(references, predictions) |
|
references = [reference[0] for reference in references] |
|
|
|
labels = [ |
|
lbl |
|
for lbl in {label for reference in references for label in reference} |
|
if lbl not in self.classes_to_ignore |
|
] |
|
|
|
|
|
if len(labels) == 0: |
|
return {self.main_score: float("nan")} |
|
|
|
for label in labels: |
|
self.add_str_to_id(label) |
|
formatted_references = [ |
|
self.get_one_hot_vector(reference) for reference in references |
|
] |
|
formatted_predictions = [ |
|
self.get_one_hot_vector(prediction) for prediction in predictions |
|
] |
|
|
|
|
|
|
|
|
|
if len(labels) == 1: |
|
labels_param = [1] |
|
else: |
|
labels_param = None |
|
|
|
result = self._metric.compute( |
|
predictions=formatted_predictions, |
|
references=formatted_references, |
|
average=self.average, |
|
labels=labels_param, |
|
) |
|
if isinstance(result[self.metric], numpy.ndarray): |
|
from statistics import mean |
|
|
|
assert ( |
|
len(result[self.metric]) == len(labels) |
|
), f"F1 result ({result[self.metric]}) has more entries than labels ({labels})" |
|
final_result = {self.main_score: mean(result[self.metric])} |
|
for i, label in enumerate(labels): |
|
final_result[self.metric + "_" + label] = result[self.metric][i] |
|
else: |
|
final_result = {self.main_score: result[self.metric]} |
|
return final_result |
|
|
|
def _validate_references_and_prediction(self, references, predictions): |
|
for reference in references: |
|
if not len(reference) == 1: |
|
raise ValueError( |
|
f"Only a single reference per prediction is allowed in F1 multi label metric. Received reference: {reference}" |
|
) |
|
if not isoftype(reference[0], List[str]): |
|
raise ValueError( |
|
f"Each reference is expected to be a list of strings in F1 multi label metric. Received reference: '{reference[0]}'" |
|
) |
|
|
|
for prediction in predictions: |
|
if not isoftype(prediction, List[str]): |
|
raise ValueError( |
|
f"Each prediction is expected to be a list of strings in F1 multi label metric. Received prediction: '{prediction}'" |
|
) |
|
|
|
|
|
class PrecisionMacroMultiLabel(F1MultiLabel): |
|
main_score = "precision_macro" |
|
metric = "precision" |
|
average = "macro" |
|
|
|
|
|
class PrecisionMicroMultiLabel(F1MultiLabel): |
|
main_score = "precision_micro" |
|
metric = "precision" |
|
average = "micro" |
|
|
|
|
|
class RecallMacroMultiLabel(F1MultiLabel): |
|
main_score = "recall_macro" |
|
metric = "recall" |
|
average = "macro" |
|
|
|
|
|
class RecallMicroMultiLabel(F1MultiLabel): |
|
main_score = "recall_micro" |
|
metric = "recall" |
|
average = "micro" |
|
|
|
|
|
class F1MicroMultiLabel(F1MultiLabel): |
|
main_score = "f1_micro" |
|
average = "micro" |
|
|
|
|
|
class F1MacroMultiLabel(F1MultiLabel): |
|
main_score = "f1_macro" |
|
average = None |
|
|
|
|
|
class Rouge(HuggingfaceMetric): |
|
hf_metric_name = "rouge" |
|
main_score = "rougeL" |
|
scale = 1.0 |
|
|
|
use_aggregator: bool = True |
|
rouge_types: List[str] = ["rouge1", "rouge2", "rougeL", "rougeLsum"] |
|
|
|
sent_split_newline: bool = True |
|
|
|
def prepare(self): |
|
super().prepare() |
|
|
|
self.hf_compute_args.update( |
|
{"use_aggregator": self.use_aggregator, "rouge_types": self.rouge_types} |
|
) |
|
|
|
import nltk |
|
|
|
nltk.download("punkt") |
|
self.sent_tokenize = nltk.sent_tokenize |
|
|
|
def compute(self, references, predictions, additional_inputs: List[Dict]): |
|
if self.sent_split_newline: |
|
predictions = [ |
|
"\n".join(self.sent_tokenize(prediction.strip())) |
|
for prediction in predictions |
|
] |
|
references = [ |
|
["\n".join(self.sent_tokenize(r.strip())) for r in reference] |
|
for reference in references |
|
] |
|
return super().compute(references, predictions, additional_inputs) |
|
|
|
|
|
|
|
class CharEditDistanceAccuracy(InstanceMetric): |
|
reduction_map = {"mean": ["char_edit_dist_accuracy"]} |
|
main_score = "char_edit_dist_accuracy" |
|
|
|
def prepare(self): |
|
super().prepare() |
|
import editdistance |
|
|
|
self.eval = editdistance.eval |
|
|
|
def compute( |
|
self, references, prediction: str, additional_inputs: List[Dict] |
|
) -> dict: |
|
assert ( |
|
len(references) == 1 |
|
), f"Expected only one reference , but received: {references}" |
|
|
|
formatted_prediction = "".join(prediction.split()) |
|
formatted_reference = "".join(references[0].split()) |
|
max_length = max(len(formatted_reference), len(formatted_prediction)) |
|
if max_length == 0: |
|
return {"char_edit_dist_accuracy": 0.0} |
|
edit_dist = self.eval(formatted_reference, formatted_prediction) |
|
return {"char_edit_dist_accuracy": (1 - edit_dist / max_length)} |
|
|
|
|
|
class Wer(HuggingfaceMetric): |
|
hf_metric_name = "wer" |
|
main_score = "wer" |
|
|
|
def compute( |
|
self, |
|
references: List[List[str]], |
|
predictions: List[str], |
|
additional_inputs: List[Dict], |
|
) -> dict: |
|
assert all( |
|
len(reference) == 1 for reference in references |
|
), "Only single reference per prediction is allowed in wer metric" |
|
formatted_references = [reference[0] for reference in references] |
|
result = self.metric.compute( |
|
predictions=predictions, references=formatted_references |
|
) |
|
return {self.main_score: result} |
|
|
|
|
|
class MatthewsCorrelation(HuggingfaceMetric): |
|
hf_metric_name = "matthews_correlation" |
|
main_score = "matthews_correlation" |
|
str_to_id: dict = InternalField(default_factory=dict) |
|
|
|
def get_str_id(self, str): |
|
if str not in self.str_to_id: |
|
id = len(self.str_to_id) |
|
self.str_to_id[str] = id |
|
return self.str_to_id[str] |
|
|
|
def compute( |
|
self, |
|
references: List[List[str]], |
|
predictions: List[str], |
|
additional_inputs: List[Dict], |
|
) -> dict: |
|
formatted_references = [ |
|
self.get_str_id(reference[0]) for reference in references |
|
] |
|
formatted_predictions = [ |
|
self.get_str_id(prediction) for prediction in predictions |
|
] |
|
return self.metric.compute( |
|
predictions=formatted_predictions, references=formatted_references |
|
) |
|
|
|
|
|
class CustomF1(GlobalMetric): |
|
main_score = "f1_micro" |
|
groups = None |
|
zero_division = 0.0 |
|
|
|
@abstractmethod |
|
def get_element_group(self, element, additional_input): |
|
pass |
|
|
|
@abstractmethod |
|
def get_element_representation(self, element, additional_input): |
|
pass |
|
|
|
def should_ignore_element(self, element, additional_input): |
|
return False |
|
|
|
def group_elements(self, elements_list, additional_input): |
|
if not isinstance(elements_list, list): |
|
elements_list = [elements_list] |
|
return { |
|
k: Counter( |
|
[ |
|
self.get_element_representation(value, additional_input) |
|
for value in elements_list |
|
if self.get_element_group(value, additional_input) == k |
|
] |
|
) |
|
for k in { |
|
self.get_element_group(e, additional_input) |
|
for e in elements_list |
|
if not self.should_ignore_element(e, additional_input) |
|
} |
|
} |
|
|
|
def calculate_groups_ratio(self, actual_group, total_group): |
|
return sum( |
|
[min(actual_group[k], total_group[k]) for k in actual_group.keys()] |
|
), sum(actual_group.values()) |
|
|
|
def precision(self, pn, pd, rn, rd): |
|
return self.zero_division if pn == 0 and pd == 0 else pn / pd |
|
|
|
def recall(self, pn, pd, rn, rd): |
|
return self.zero_division if rn == 0 and rd == 0 else rn / rd |
|
|
|
def f1(self, pn, pd, rn, rd): |
|
precision = self.precision(pn, pd, rn, rd) |
|
recall = self.recall(pn, pd, rn, rd) |
|
try: |
|
return 2 * precision * recall / (precision + recall) |
|
except ZeroDivisionError: |
|
return self.zero_division |
|
|
|
def get_groups(self, elements, additional_inputs): |
|
groups = set() |
|
for sublist, additional_input in zip(elements, additional_inputs): |
|
for e in sublist: |
|
if self.should_ignore_element(e, additional_input): |
|
continue |
|
groups.add(self.get_element_group(e, additional_input)) |
|
return groups |
|
|
|
def compute( |
|
self, |
|
references: List[List[Any]], |
|
predictions: List[Any], |
|
additional_inputs: List[Dict], |
|
) -> dict: |
|
|
|
if ( |
|
isinstance(references[0], list) |
|
and len(references[0]) > 0 |
|
and isinstance(references[0][0], list) |
|
): |
|
references = [element[0] for element in references] |
|
|
|
assert len(references) == len(predictions), ( |
|
f"references size ({len(references)})" |
|
f" doesn't mach predictions sise ({len(references)})." |
|
) |
|
|
|
if self.groups is None: |
|
groups = self.get_groups(references, additional_inputs) |
|
else: |
|
groups = self.groups |
|
groups_statistics = {} |
|
for references_batch, predictions_batch, additional_input in zip( |
|
references, predictions, additional_inputs |
|
): |
|
grouped_references = self.group_elements(references_batch, additional_input) |
|
grouped_predictions = self.group_elements( |
|
predictions_batch, additional_input |
|
) |
|
all_groups = set(grouped_references.keys()).union( |
|
grouped_predictions.keys() |
|
) |
|
for group in all_groups: |
|
if group not in groups_statistics: |
|
groups_statistics[group] = { |
|
"precision_numerator": 0, |
|
"precision_denominator": 0, |
|
"recall_numerator": 0, |
|
"recall_denominator": 0, |
|
} |
|
references_by_group = grouped_references.get(group, Counter([])) |
|
predictions_by_group = grouped_predictions.get(group, Counter([])) |
|
pn, pd = self.calculate_groups_ratio( |
|
actual_group=predictions_by_group, total_group=references_by_group |
|
) |
|
rn, rd = self.calculate_groups_ratio( |
|
actual_group=references_by_group, total_group=predictions_by_group |
|
) |
|
groups_statistics[group]["precision_numerator"] += pn |
|
groups_statistics[group]["precision_denominator"] += pd |
|
groups_statistics[group]["recall_numerator"] += rn |
|
groups_statistics[group]["recall_denominator"] += rd |
|
|
|
num_of_unknown_class_predictions = 0 |
|
pn_total = pd_total = rn_total = rd_total = 0 |
|
f1_result = {} |
|
recall_result = {} |
|
precision_result = {} |
|
for group in groups_statistics.keys(): |
|
pn, pd, rn, rd = ( |
|
groups_statistics[group]["precision_numerator"], |
|
groups_statistics[group]["precision_denominator"], |
|
groups_statistics[group]["recall_numerator"], |
|
groups_statistics[group]["recall_denominator"], |
|
) |
|
pn_total, pd_total, rn_total, rd_total = ( |
|
pn_total + pn, |
|
pd_total + pd, |
|
rn_total + rn, |
|
rd_total + rd, |
|
) |
|
if group in groups: |
|
f1_result[f"f1_{group}"] = self.f1(pn, pd, rn, rd) |
|
recall_result[f"recall_{group}"] = self.recall(pn, pd, rn, rd) |
|
precision_result[f"precision_{group}"] = self.precision(pn, pd, rn, rd) |
|
else: |
|
num_of_unknown_class_predictions += pd |
|
|
|
result = f1_result |
|
try: |
|
result["f1_macro"] = sum(f1_result.values()) / len(result.keys()) |
|
result["recall_macro"] = sum(recall_result.values()) / len( |
|
recall_result.keys() |
|
) |
|
result["precision_macro"] = sum(precision_result.values()) / len( |
|
precision_result.keys() |
|
) |
|
except ZeroDivisionError: |
|
result["f1_macro"] = self.zero_division |
|
result["recall_macro"] = self.zero_division |
|
result["precision_macro"] = self.zero_division |
|
|
|
amount_of_predictions = pd_total |
|
if amount_of_predictions == 0: |
|
result["in_classes_support"] = 1.0 |
|
else: |
|
result["in_classes_support"] = ( |
|
1.0 - num_of_unknown_class_predictions / amount_of_predictions |
|
) |
|
result["f1_micro"] = self.f1(pn_total, pd_total, rn_total, rd_total) |
|
result["recall_micro"] = self.recall(pn_total, pd_total, rn_total, rd_total) |
|
result["precision_micro"] = self.precision( |
|
pn_total, pd_total, rn_total, rd_total |
|
) |
|
return result |
|
|
|
|
|
class NER(CustomF1): |
|
def get_element_group(self, element, additional_input): |
|
return element[1] |
|
|
|
def get_element_representation(self, element, additional_input): |
|
return str(element) |
|
|
|
|
|
def normalize_answer(s): |
|
"""Lower text and remove punctuation, articles and extra whitespace.""" |
|
|
|
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)))) |
|
|
|
|
|
class TokenOverlap(InstanceMetric): |
|
reduction_map = {"mean": ["f1", "precision", "recall"]} |
|
main_score = "f1" |
|
ci_scores = ["f1", "precision", "recall"] |
|
|
|
def compute( |
|
self, references: List[Any], prediction: Any, additional_inputs: List[Dict] |
|
) -> dict: |
|
results = [ |
|
self._compute_single_ref(reference, prediction) for reference in references |
|
] |
|
return { |
|
measure: max(r[i] for r in results) |
|
for i, measure in enumerate(["precision", "recall", "f1"]) |
|
} |
|
|
|
def _compute_single_ref( |
|
self, reference: Any, prediction: Any |
|
) -> Tuple[float, float, float]: |
|
prediction_tokens = normalize_answer(prediction).split() |
|
reference_tokens = normalize_answer(reference).split() |
|
common = Counter(prediction_tokens) & Counter(reference_tokens) |
|
num_same = sum(common.values()) |
|
if num_same == 0: |
|
pr, rc, f1 = 0, 0, 0 |
|
else: |
|
pr = 1.0 * num_same / len(prediction_tokens) |
|
rc = 1.0 * num_same / len(reference_tokens) |
|
f1 = (2 * pr * rc) / (pr + rc) |
|
return pr, rc, f1 |
|
|
|
|
|
class BertScore(HuggingfaceBulkMetric): |
|
hf_metric_name = "bertscore" |
|
main_score = "f1" |
|
reduction_map = {"mean": ["f1", "precision", "recall"]} |
|
hf_metric_fields = ["f1", "precision", "recall"] |
|
ci_scores = ["f1", "precision", "recall"] |
|
model_name: str |
|
|
|
def prepare(self): |
|
super().prepare() |
|
self.hf_compute_args = {"model_type": self.model_name} |
|
|
|
|
|
class SentenceBert(BulkInstanceMetric): |
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reduction_map = {"mean": ["score"]} |
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main_score = "score" |
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batch_size: int = 32 |
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|
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model_name: str |
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|
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def prepare(self): |
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super().prepare() |
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from sentence_transformers import SentenceTransformer |
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from sentence_transformers import util as sbert_util |
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|
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self.model = SentenceTransformer(self.model_name) |
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self.util = sbert_util |
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|
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def compute( |
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self, |
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references: List[List[Any]], |
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predictions: List[Any], |
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additional_inputs: List[Dict], |
|
) -> List[Dict[str, Any]]: |
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scores = [] |
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|
|
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|
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|
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ref_group_boundaries = [] |
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count = 0 |
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for ref_group in references: |
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ref_group_boundaries.append((count, count + len(ref_group))) |
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count += len(ref_group) |
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|
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preds_emb = self.model.encode(predictions) |
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refs_emb = self.model.encode( |
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[ref for ref_group in references for ref in ref_group] |
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) |
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|
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for pred_emb, ref_group_bounds in zip(preds_emb, ref_group_boundaries): |
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refs_group_emb = refs_emb[ref_group_bounds[0] : ref_group_bounds[1]] |
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scores.append(self.util.cos_sim(pred_emb, refs_group_emb).max().item()) |
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|
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return [{"score": score} for score in scores] |
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|
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class Reward(BulkInstanceMetric): |
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reduction_map = {"mean": ["score"]} |
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main_score = "score" |
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batch_size: int = 32 |
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|
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model_name: str |
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|
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def prepare(self): |
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super().prepare() |
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from transformers import pipeline |
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|
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self.pipe = pipeline("text-classification", model=self.model_name) |
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|
|
def compute( |
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self, |
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references: List[List[Any]], |
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predictions: List[Any], |
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additional_inputs: List[Dict], |
|
) -> List[Dict[str, Any]]: |
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|
|
|
|
questions = [refs[0] for refs in references] |
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answers = predictions |
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|
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inputs = [{"text": q, "text_pair": a} for q, a in zip(questions, answers)] |
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return self.pipe(inputs, batch_size=self.batch_size) |
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|
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class Perplexity(BulkInstanceMetric): |
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"""Computes the likelihood of generating text Y after text X - P(Y|X).""" |
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|
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main_score = "perplexity" |
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reduction_map = {"mean": ["perplexity"]} |
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|
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perplexity_prompt: str |
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|
|
batch_size: int = 32 |
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model_name: str |
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|
|
def compute( |
|
self, |
|
references: List[List[Any]], |
|
predictions: List[Any], |
|
additional_inputs: List[Dict], |
|
) -> List[Dict[str, Any]]: |
|
"""Computes the likelihood of generating text Y after text X - P(Y|X). |
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|
|
:param references: the list of Y texts as a list of singletons. |
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:param predictions: the list of X texts as a plain list of strings |
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|
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:return: the likelihood of generating text Y_i after text X_i = P(Y_i|X_i) for every i. |
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""" |
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sources = [] |
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targets = [] |
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for prediction, instance_references in zip(predictions, references): |
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for instance_reference in instance_references: |
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sources.append(f"{self.perplexity_prompt} {prediction}") |
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targets.append(instance_reference) |
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|
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from transformers import AutoConfig |
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|
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config = AutoConfig.from_pretrained(self.model_name, trust_remote_code=True) |
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lm = ( |
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self.EncoderDecoderLM(model_name=self.model_name) |
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if config.is_encoder_decoder is True |
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else self.DecoderOnlyLM(model_name=self.model_name) |
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) |
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|
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scores = lm.compute_lm( |
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source=sources, target=targets, batch_size=self.batch_size |
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) |
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|
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index = 0 |
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all_instances_scores = [] |
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for instance_references in references: |
|
instance_scores = {} |
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instance_scores_list = [] |
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for _ in range(len(instance_references)): |
|
instance_scores_list.append(scores[index]) |
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index += 1 |
|
instance_scores["reference_scores"] = instance_scores_list |
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instance_scores[self.main_score] = mean(instance_scores_list) |
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|
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instance_scores[self.main_score] = mean(instance_scores_list) |
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all_instances_scores.append(instance_scores) |
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|
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return all_instances_scores |
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|
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class AbstractLM(ABC): |
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def __init__(self, model_name): |
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import torch |
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from transformers import AutoTokenizer |
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|
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self.model_name = model_name |
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self.tokenizer = AutoTokenizer.from_pretrained(self.model_name) |
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self.model = self.model_class().from_pretrained(self.model_name) |
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self.is_cuda = torch.cuda.is_available() |
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|
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def compute_lm( |
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self, source: List[str], target: List[str], batch_size: int |
|
) -> List[float]: |
|
import torch |
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|
|
scores = [] |
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|
|
with torch.no_grad(): |
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|
|
n_batches = int(len(source) / batch_size) |
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batch_range = range(n_batches + 1) |
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for batch in batch_range: |
|
batch_source = source[batch * batch_size : (batch + 1) * batch_size] |
|
batch_target = target[batch * batch_size : (batch + 1) * batch_size] |
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if len(batch_source) > 0: |
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|
|
tokens_source = self.tokenizer( |
|
batch_source, padding=True, return_tensors="pt" |
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) |
|
tokens_target = self.tokenizer( |
|
batch_target, padding=True, return_tensors="pt" |
|
) |
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|
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|
|
logits, labels = self.compute_batch( |
|
tokens_source, tokens_target |
|
) |
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|
|
loss_fct = torch.nn.CrossEntropyLoss( |
|
ignore_index=-100, reduction="none" |
|
) |
|
loss = loss_fct( |
|
logits.view(-1, logits.size(-1)), labels.view(-1) |
|
) |
|
loss = loss.view(len(batch_source), -1) |
|
|
|
|
|
batch_loss = torch.sum(loss, dim=1) / torch.sum( |
|
labels > 0, dim=1 |
|
) |
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|
|
|
|
scores.append(batch_loss) |
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|
|
return torch.cat(scores, dim=0).tolist() |
|
|
|
@abstractmethod |
|
def model_class(self): |
|
pass |
|
|
|
@abstractmethod |
|
def compute_batch(self, tokens_source, tokens_target): |
|
pass |
|
|
|
class EncoderDecoderLM(AbstractLM): |
|
def model_class(self): |
|
from transformers import AutoModelForSeq2SeqLM |
|
|
|
return AutoModelForSeq2SeqLM |
|
|
|
def compute_batch(self, tokens_source, tokens_target): |
|
tokens_docs_ids = tokens_source["input_ids"] |
|
attention = tokens_source["attention_mask"] |
|
labels = tokens_target["input_ids"] |
|
|
|
if self.is_cuda: |
|
tokens_docs_ids, attention, labels = ( |
|
tokens_docs_ids.cuda(), |
|
attention.cuda(), |
|
labels.cuda(), |
|
) |
|
|
|
logits = self.model( |
|
input_ids=tokens_docs_ids.long(), |
|
attention_mask=attention.long(), |
|
labels=labels.long(), |
|
).logits |
|
|
|
|
|
labels[labels == self.tokenizer.pad_token_id] = -100 |
|
|
|
return logits, labels |
|
|
|
class DecoderOnlyLM(AbstractLM): |
|
def model_class(self): |
|
from transformers import AutoModelForCausalLM |
|
|
|
return AutoModelForCausalLM |
|
|
|
def compute_batch(self, tokens_source, tokens_target): |
|
import torch |
|
|
|
tokens = torch.cat( |
|
[tokens_source["input_ids"], tokens_target["input_ids"]], dim=1 |
|
) |
|
attention = torch.cat( |
|
[tokens_source["attention_mask"], tokens_target["attention_mask"]], |
|
dim=1, |
|
) |
|
labels = torch.cat( |
|
[ |
|
torch.zeros_like(tokens_source["input_ids"]).fill_(-100), |
|
tokens_target["input_ids"], |
|
], |
|
dim=1, |
|
) |
|
|
|
|
|
labels[labels == self.tokenizer.pad_token_id] = -100 |
|
|
|
if self.is_cuda: |
|
tokens, attention, labels = ( |
|
tokens.cuda(), |
|
attention.cuda(), |
|
labels.cuda(), |
|
) |
|
|
|
|
|
model_output = self.model( |
|
input_ids=tokens.long(), attention_mask=attention.long() |
|
) |
|
logits = model_output.logits |
|
|
|
|
|
|
|
|
|
shifted_logits = logits[..., :-1, :].contiguous() |
|
shifted_labels = labels[..., 1:].contiguous() |
|
|
|
return shifted_logits, shifted_labels |
|
|
|
|
|
class NDCG(GlobalMetric): |
|
"""Normalized Discounted Cumulative Gain: measures the quality of ranking with respect to ground truth ranking scores. |
|
|
|
As this measures ranking, it is a global metric that can only be calculated over groups of instances. In the |
|
common use case where the instances are grouped by different queries, i.e., where the task is to provide a |
|
relevance score for a search result w.r.t. a query, an nDCG score is calculated per each query (specified in the |
|
"query" input field of an instance) and the final score is the average across all queries. |
|
Note that the expected scores are relevance scores (i.e., higher is better) and not rank indices. The absolute |
|
value of the scores is only meaningful for the reference scores; for the predictions, only the ordering of the |
|
scores affects the outcome - for example, predicted scores of [80, 1, 2] and [0.8, 0.5, 0.6] will receive |
|
the same nDCG score w.r.t. a given set of reference scores. |
|
|
|
See also https://en.wikipedia.org/wiki/Discounted_cumulative_gain |
|
""" |
|
|
|
main_score = "nDCG" |
|
|
|
def prepare(self): |
|
from sklearn.metrics import ndcg_score |
|
|
|
super().prepare() |
|
self.eval = ndcg_score |
|
|
|
def compute( |
|
self, |
|
references: List[List[Any]], |
|
predictions: List[Any], |
|
additional_inputs: List[Any], |
|
) -> dict: |
|
from collections import defaultdict |
|
from statistics import mean |
|
|
|
query_to_predictions_and_references = defaultdict(lambda: [[], []]) |
|
for reference, pred, inputs_dict in zip( |
|
references, predictions, additional_inputs |
|
): |
|
query = inputs_dict.get("query") |
|
query_to_predictions_and_references[query][0].append(pred) |
|
query_to_predictions_and_references[query][1].append(reference) |
|
|
|
scores = [] |
|
for q_predictions, q_references in query_to_predictions_and_references.values(): |
|
if len(q_references) == 1: |
|
continue |
|
|
|
if ( |
|
None in q_predictions |
|
): |
|
numeric_predictions = [ |
|
pred for pred in q_predictions if pred is not None |
|
] |
|
if len(numeric_predictions) <= 1: |
|
scores.append(0) |
|
continue |
|
|
|
min_value = min(numeric_predictions) |
|
q_predictions = [ |
|
1 + (pred - min_value) if pred is not None else 0 |
|
for pred in q_predictions |
|
] |
|
scores.append(self.eval([q_references], [q_predictions])) |
|
return {self.main_score: mean(scores) if len(scores) > 0 else np.nan} |
|
|
|
|
|
class RetrievalMetric(InstanceMetric): |
|
def compute( |
|
self, references: List[Any], prediction: Any, additional_inputs: Dict |
|
) -> dict: |
|
|
|
pred_ids: List[Any] = prediction |
|
ref_ids: List[Any] = list(dict.fromkeys(references)) |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
relevance_at_k = { |
|
k + 1: 1 if doc_id in ref_ids else 0 for k, doc_id in enumerate(pred_ids) |
|
} |
|
|
|
|
|
|
|
relevance_sum_at_k = {} |
|
for k, value in relevance_at_k.items(): |
|
relevance_sum_at_k[k] = relevance_sum_at_k.get(k - 1, 0) + value |
|
|
|
|
|
|
|
|
|
precision_at_k = {k: value / k for k, value in relevance_sum_at_k.items()} |
|
|
|
|
|
|
|
|
|
n_refs = len(ref_ids) |
|
recall_at_k = { |
|
k: value / n_refs if n_refs > 0 else 0 |
|
for k, value in relevance_sum_at_k.items() |
|
} |
|
|
|
|
|
|
|
rank = 0 |
|
for k, relevance in relevance_at_k.items(): |
|
if relevance == 1: |
|
rank = k |
|
break |
|
|
|
|
|
match_at_k = { |
|
k: 1.0 if value > 0 else 0.0 for k, value in relevance_sum_at_k.items() |
|
} |
|
|
|
return self._compute( |
|
relevance_at_k, |
|
relevance_sum_at_k, |
|
precision_at_k, |
|
recall_at_k, |
|
match_at_k, |
|
rank, |
|
) |
|
|
|
@abstractmethod |
|
def _compute( |
|
self, |
|
relevance_at_k, |
|
relevance_sum_at_k, |
|
precision_at_k, |
|
recall_at_k, |
|
match_at_k, |
|
rank, |
|
) -> dict: |
|
pass |
|
|
|
|
|
class MRR(RetrievalMetric): |
|
reduction_map = {"mean": ["mrr"]} |
|
main_score = "mrr" |
|
|
|
def _compute( |
|
self, |
|
relevance_at_k, |
|
relevance_sum_at_k, |
|
precision_at_k, |
|
recall_at_k, |
|
match_at_k, |
|
rank, |
|
) -> dict: |
|
return {self.main_score: 1 / rank if rank > 0 else 0} |
|
|
|
|
|
class MAP(RetrievalMetric): |
|
reduction_map = {"mean": ["map"]} |
|
main_score = "map" |
|
|
|
def _compute( |
|
self, |
|
relevance_at_k, |
|
relevance_sum_at_k, |
|
precision_at_k, |
|
recall_at_k, |
|
match_at_k, |
|
rank, |
|
) -> dict: |
|
result = 0 |
|
if len(relevance_at_k) > 0: |
|
total = sum(relevance_at_k.values()) |
|
if total > 0: |
|
dot = sum(relevance_at_k[k] * precision_at_k[k] for k in relevance_at_k) |
|
result = dot / total |
|
return {self.main_score: result} |
|
|
|
|
|
class RetrievalAtK(RetrievalMetric): |
|
k_list: List[int] |
|
main_score: str = None |
|
reduction_map: Dict[str, List[str]] = None |
|
|
|
def prepare(self): |
|
super().prepare() |
|
self.main_score = self.score_name("match", self.k_list[0]) |
|
self.ci_scores = [ |
|
self.score_name(measure, k) |
|
for measure in ["precision", "recall", "match"] |
|
for k in self.k_list |
|
] |
|
self.reduction_map = {"mean": self.ci_scores} |
|
|
|
@staticmethod |
|
def score_name(measure: str, k: int): |
|
return f"{measure}_at_{k}" |
|
|
|
def _compute( |
|
self, |
|
relevance_at_k, |
|
relevance_sum_at_k, |
|
precision_at_k, |
|
recall_at_k, |
|
match_at_k, |
|
rank, |
|
) -> dict: |
|
result = {} |
|
for measure_array, measure_name in [ |
|
(precision_at_k, "precision"), |
|
(recall_at_k, "recall"), |
|
(match_at_k, "match"), |
|
]: |
|
max_k = max(measure_array.keys()) |
|
for k in self.k_list: |
|
result[self.score_name(measure_name, k)] = measure_array[min(k, max_k)] |
|
return result |
|
|
|
|
|
class KPA(CustomF1): |
|
def get_element_group(self, element, additional_input): |
|
return additional_input["keypoint"] |
|
|
|
def get_element_representation(self, element, additional_input): |
|
return additional_input["keypoint"] |
|
|
|
def should_ignore_element(self, element, additional_input): |
|
return element == "none" |
|
|