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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 typing import Any, Dict, Generator, List, Optional |
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import evaluate |
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import numpy |
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from .dataclass import InternalField |
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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 .stream import MultiStream, Stream |
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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(self, instance: Dict[str, Any], stream_name: str = None) -> Dict[str, Any]: |
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instance.update(self.update) |
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return instance |
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class Metric(ABC): |
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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 GlobalMetric(SingleStreamOperator, Metric): |
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def process(self, stream: Stream, stream_name: str = None) -> Generator: |
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references = [] |
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predictions = [] |
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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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refs, pred = instance["references"], instance["prediction"] |
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try: |
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instance_score = self._compute([refs], [pred]) |
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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) and self.main_score is not None: |
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instance_score[self.main_score] = None |
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instance["score"]["instance"].update(instance_score) |
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references.append(refs) |
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predictions.append(pred) |
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instances.append(instance) |
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result = self._compute(references, predictions) |
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global_score.update(result) |
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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(self, references: List[List[str]], predictions: List[str]) -> dict: |
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result = self.compute(references, predictions) |
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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(self, references: List[List[str]], predictions: List[str]) -> dict: |
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pass |
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class InstanceMetric(SingleStreamOperator, Metric): |
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implemented_reductions: List[str] = field(default_factory=lambda: ["mean"]) |
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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: str = None) -> Generator: |
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global_score = {} |
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instances = [] |
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for instance in stream: |
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refs, pred = instance["references"], instance["prediction"] |
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instance_score = self._compute(refs, pred) |
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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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if reduction == "mean": |
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from statistics import mean |
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for field in fields: |
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global_score[field] = mean([instance["score"]["instance"][field] for instance in instances]) |
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if field == self.main_score: |
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global_score["score"] = global_score[field] |
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global_score["score_name"] = self.main_score |
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for instance in instances: |
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yield instance |
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def _compute(self, references: List[List[str]], predictions: List[str]) -> dict: |
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result = self.compute(references=references, predictions=predictions) |
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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(self, references: List[str], prediction: str) -> dict: |
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pass |
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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(Squad, self).prepare() |
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self._metric = evaluate.load(self.metric) |
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def compute(self, references: List[List[str]], predictions: List[str]) -> 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]} 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(predictions=formatted_predictions, references=formatted_references) |
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class SingleReferenceInstanceMetric(InstanceMetric): |
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def _compute(self, references: List[str], prediction: str) -> dict: |
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result = self.compute(references[0], prediction) |
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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(self, reference, prediction: str) -> dict: |
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pass |
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class Accuracy(SingleReferenceInstanceMetric): |
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reduction_map = {"mean": ["accuracy"]} |
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main_score = "accuracy" |
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def compute(self, reference, prediction: str) -> dict: |
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return {"accuracy": float(str(reference) == str(prediction))} |
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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(default_factory=list) |
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metric: Metric = None |
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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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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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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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multi_stream = self.prepare_score(multi_stream) |
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return multi_stream |
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class HuggingfaceMetric(GlobalMetric): |
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metric_name: str = None |
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main_score: str = None |
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scale: float = 1.0 |
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def prepare(self): |
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super().prepare() |
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self.metric = evaluate.load(self.metric_name) |
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def compute(self, references: List[List[str]], predictions: List[str]) -> dict: |
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result = self.metric.compute(predictions=predictions, references=references) |
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if self.scale != 1.0: |
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for key in result: |
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if isinstance(result[key], float): |
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result[key] /= self.scale |
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return result |
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class F1(GlobalMetric): |
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_metric = None |
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main_score = "f1_macro" |
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average = None |
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metric = "f1" |
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def prepare(self): |
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super(F1, self).prepare() |
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self._metric = evaluate.load(self.metric) |
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def get_str_id(self, str): |
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if str not in self.str_to_id: |
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id = len(self.str_to_id) |
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self.str_to_id[str] = id |
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self.id_to_str[id] = str |
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return self.str_to_id[str] |
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def compute(self, references: List[List[str]], predictions: List[str]) -> dict: |
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assert all( |
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len(reference) == 1 for reference in references |
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), "Only a single reference per prediction is allowed in F1 metric" |
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self.str_to_id = {} |
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self.id_to_str = {} |
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formatted_references = [self.get_str_id(reference[0]) for reference in references] |
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unique_labels = self.str_to_id.keys() |
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formatted_predictions = [self.get_str_id(prediction) for prediction in predictions] |
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labels = list(set(formatted_references)) |
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result = self._metric.compute( |
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predictions=formatted_predictions, references=formatted_references, labels=labels, average=self.average |
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) |
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if isinstance(result["f1"], numpy.ndarray): |
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from statistics import mean |
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final_result = {self.main_score: mean(result["f1"])} |
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for i, label in enumerate(labels): |
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final_result["f1_" + self.id_to_str[label]] = result["f1"][i] |
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else: |
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final_result = {self.main_score: result["f1"]} |
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return final_result |
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class F1Micro(F1): |
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main_score = "f1_micro" |
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average = "micro" |
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class F1Macro(F1): |
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main_score = "f1_macro" |
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class F1MultiLabel(GlobalMetric): |
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_metric = None |
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main_score = "f1_macro" |
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average = None |
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classes_to_ignore = ["none"] |
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def prepare(self): |
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super(F1MultiLabel, self).prepare() |
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self._metric = evaluate.load("f1", "multilabel") |
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def add_str_to_id(self, str): |
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if not str in self.str_to_id: |
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id = len(self.str_to_id) |
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self.str_to_id[str] = id |
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self.id_to_str[id] = str |
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return |
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def get_one_hot_vector(self, labels: List[str]): |
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result = [0] * len(self.str_to_id) |
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for label in labels: |
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if label in self.str_to_id: |
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result[self.str_to_id[label]] = 1 |
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return result |
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def compute(self, references: List[List[str]], predictions: List[str]) -> dict: |
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self.str_to_id = {} |
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self.id_to_str = {} |
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assert all( |
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len(reference) == 1 for reference in references |
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), "Only a single reference per prediction is allowed in F1 metric" |
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references = [reference[0] for reference in references] |
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labels = [ |
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l |
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for l in set([label for reference in references for label in reference]) |
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if l not in self.classes_to_ignore |
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] |
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if len(labels) == 0: |
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return {self.main_score: float("nan")} |
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for label in labels: |
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self.add_str_to_id(label) |
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formatted_references = [self.get_one_hot_vector(reference) for reference in references] |
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formatted_predictions = [self.get_one_hot_vector(prediction) for prediction in predictions] |
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if len(labels) == 1: |
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labels_param = [1] |
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else: |
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labels_param = None |
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result = self._metric.compute( |
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predictions=formatted_predictions, |
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references=formatted_references, |
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average=self.average, |
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labels=labels_param, |
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) |
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if isinstance(result["f1"], numpy.ndarray): |
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from statistics import mean |
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assert len(result["f1"]) == len( |
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labels |
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), f'F1 result ({result["f1"]}) has more entries than labels ({labels})' |
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final_result = {self.main_score: mean(result["f1"])} |
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for i, label in enumerate(labels): |
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final_result["f1_" + label] = result["f1"][i] |
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else: |
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final_result = {self.main_score: result["f1"]} |
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return final_result |
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class F1MicroMultiLabel(F1MultiLabel): |
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main_score = "f1_micro" |
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average = "micro" |
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class F1MacroMultiLabel(F1MultiLabel): |
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main_score = "f1_macro" |
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average = None |
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class Rouge(HuggingfaceMetric): |
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metric_name = "rouge" |
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main_score = "rougeL" |
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scale = 1.0 |
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def prepare(self): |
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super().prepare() |
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import nltk |
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nltk.download("punkt") |
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self.sent_tokenize = nltk.sent_tokenize |
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def compute(self, references, predictions): |
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predictions = ["\n".join(self.sent_tokenize(prediction.strip())) for prediction in predictions] |
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references = [["\n".join(self.sent_tokenize(r.strip())) for r in reference] for reference in references] |
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return super().compute(references, predictions) |
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class CharEditDistanceAccuracy(SingleReferenceInstanceMetric): |
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reduction_map = {"mean": ["char_edit_dist_accuracy"]} |
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main_score = "char_edit_dist_accuracy" |
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def prepare(self): |
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import editdistance |
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self.eval = editdistance.eval |
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def compute(self, reference, prediction: str) -> dict: |
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formatted_prediction = "".join(prediction.split()) |
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formatted_reference = "".join(reference.split()) |
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max_length = max(len(formatted_reference), len(formatted_prediction)) |
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if max_length == 0: |
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return 0 |
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edit_dist = self.eval(formatted_reference, formatted_prediction) |
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return {"char_edit_dist_accuracy": (1 - edit_dist / max_length)} |
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class Wer(HuggingfaceMetric): |
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metric_name = "wer" |
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main_score = "wer" |
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def prepare(self): |
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super().prepare() |
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self.metric = evaluate.load(self.metric_name) |
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def compute(self, references: List[List[str]], predictions: List[str]) -> dict: |
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assert all( |
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len(reference) == 1 for reference in references |
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), "Only single reference per prediction is allowed in wer metric" |
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formatted_references = [reference[0] for reference in references] |
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result = self.metric.compute(predictions=predictions, references=formatted_references) |
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return {self.main_score: result} |
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class Bleu(HuggingfaceMetric): |
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metric_name = "bleu" |
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main_score = "bleu" |
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scale = 1.0 |
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class MatthewsCorrelation(HuggingfaceMetric): |
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metric_name = "matthews_correlation" |
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main_score = "matthews_correlation" |
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str_to_id: dict = InternalField(default_factory=dict) |
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def get_str_id(self, str): |
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if str not in self.str_to_id: |
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id = len(self.str_to_id) |
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self.str_to_id[str] = id |
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return self.str_to_id[str] |
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def compute(self, references: List[List[str]], predictions: List[str]) -> dict: |
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formatted_references = [self.get_str_id(reference[0]) for reference in references] |
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formatted_predictions = [self.get_str_id(prediction) for prediction in predictions] |
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result = self.metric.compute(predictions=formatted_predictions, references=formatted_references) |
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return result |
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class CustomF1(GlobalMetric): |
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main_score = "f1_micro" |
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classes = None |
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@abstractmethod |
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def get_element_group(self, element): |
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pass |
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@abstractmethod |
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def get_element_representation(self, element): |
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pass |
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def group_elements(self, l): |
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return { |
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k: Counter([self.get_element_representation(value) for value in l if self.get_element_group(value) == k]) |
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for k in set([self.get_element_group(e) for e in l]) |
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} |
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def calculate_groups_ratio(self, actual_group, total_group): |
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return sum([min(actual_group[k], total_group[k]) for k in actual_group.keys()]), sum(actual_group.values()) |
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def f1(self, pn, pd, rn, rd): |
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precision = 1.0 if pn == 0 and pd == 0 else pn / pd |
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recall = 1.0 if rn == 0 and rd == 0 else rn / rd |
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try: |
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return 2 * precision * recall / (precision + recall) |
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except ZeroDivisionError: |
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return 0.0 |
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def compute(self, references: List[Any], predictions: List[Any]) -> dict: |
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|
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if isinstance(references[0], list) and isinstance(references[0][0], list): |
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references = [element[0] for element in references] |
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assert len(references) == len(predictions), ( |
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f"references size ({len(references)})" f" doesn't mach predictions sise ({len(references)})." |
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) |
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if self.classes is None: |
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classes = set([self.get_element_group(e) for sublist in references for e in sublist]) |
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else: |
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classes = self.classes |
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groups_statistics = dict() |
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for references_batch, predictions_batch in zip(references, predictions): |
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grouped_references = self.group_elements(references_batch) |
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grouped_predictions = self.group_elements(predictions_batch) |
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all_groups = set(grouped_references.keys()).union(grouped_predictions.keys()) |
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for group in all_groups: |
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if group not in groups_statistics: |
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groups_statistics[group] = { |
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"precision_numerator": 0, |
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"precision_denominator": 0, |
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"recall_numerator": 0, |
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"recall_denominator": 0, |
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} |
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references_by_group = grouped_references.get(group, Counter([])) |
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predictions_by_group = grouped_predictions.get(group, Counter([])) |
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pn, pd = self.calculate_groups_ratio( |
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actual_group=predictions_by_group, total_group=references_by_group |
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) |
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rn, rd = self.calculate_groups_ratio( |
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actual_group=references_by_group, total_group=predictions_by_group |
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) |
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groups_statistics[group]["precision_numerator"] += pn |
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groups_statistics[group]["precision_denominator"] += pd |
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groups_statistics[group]["recall_numerator"] += rn |
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groups_statistics[group]["recall_denominator"] += rd |
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|
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result = {} |
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num_of_unknown_class_predictions = 0 |
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pn_total = pd_total = rn_total = rd_total = 0 |
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for group in groups_statistics.keys(): |
|
pn, pd, rn, rd = ( |
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groups_statistics[group]["precision_numerator"], |
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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 |
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if group in classes: |
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result[f"f1_{group}"] = self.f1(pn, pd, rn, rd) |
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else: |
|
num_of_unknown_class_predictions += pd |
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try: |
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result["f1_macro"] = sum(result.values()) / len(result.keys()) |
|
except ZeroDivisionError: |
|
result["f1_macro"] = 1.0 |
|
|
|
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 |
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result[f"f1_micro"] = self.f1(pn_total, pd_total, rn_total, rd_total) |
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return result |
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|
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class NER(CustomF1): |
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def get_element_group(self, element): |
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return element[1] |
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|
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def get_element_representation(self, element): |
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return str(element) |
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|
