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import uuid
from abc import ABC, abstractmethod
from collections import Counter
from dataclasses import field
from typing import Any, Dict, Generator, List, Optional

import evaluate
import nltk
import numpy
from editdistance import eval

from .dataclass import InternalField
from .operator import (
    MultiStreamOperator,
    SingleStreamOperator,
    StreamingOperator,
    StreamInstanceOperator,
)
from .operators import CopyFields
from .stream import MultiStream, Stream

nltk.download("punkt")


def abstract_factory():
    return {}


def abstract_field():
    return field(default_factory=abstract_factory)


class UpdateStream(StreamInstanceOperator):
    update: dict

    def process(self, instance: Dict[str, Any], stream_name: str = None) -> Dict[str, Any]:
        instance.update(self.update)
        return instance


# TODO: currently we have two classes with this name. metric.Metric and matrics.Metric...
class Metric(ABC):
    @property
    @abstractmethod
    def main_score(self):
        pass


class GlobalMetric(SingleStreamOperator, Metric):
    def process(self, stream: Stream, stream_name: str = None) -> Generator:
        references = []
        predictions = []
        global_score = {}

        instances = []

        for instance in stream:
            if "score" not in instance:
                instance["score"] = {"global": global_score, "instance": {}}
            else:
                global_score = instance["score"]["global"]

            refs, pred = instance["references"], instance["prediction"]

            try:
                instance_score = self._compute([refs], [pred])
            except:
                instance_score = {"score": None}
                if isinstance(self.main_score, str) and self.main_score is not None:
                    instance_score[self.main_score] = None

            instance["score"]["instance"].update(instance_score)

            references.append(refs)
            predictions.append(pred)
            instances.append(instance)

        result = self._compute(references, predictions)

        global_score.update(result)

        for instance in instances:
            instance["score"]["global"] = global_score
            yield instance

    def _compute(self, references: List[List[str]], predictions: List[str]) -> dict:
        result = self.compute(references, predictions)
        result["score"] = result[self.main_score]
        return result

    @abstractmethod
    def compute(self, references: List[List[str]], predictions: List[str]) -> dict:
        pass


class InstanceMetric(SingleStreamOperator, Metric):
    implemented_reductions: List[str] = field(default_factory=lambda: ["mean"])

    @property
    @abstractmethod
    def reduction_map(self) -> dict:
        pass

    def process(self, stream: Stream, stream_name: str = None) -> Generator:
        global_score = {}
        instances = []

        for instance in stream:
            refs, pred = instance["references"], instance["prediction"]

            instance_score = self._compute(refs, pred)

            if "score" not in instance:
                instance["score"] = {"global": global_score, "instance": {}}
            else:
                global_score = instance["score"]["global"]

            instance["score"]["instance"].update(instance_score)

            instances.append(instance)

        for reduction, fields in self.reduction_map.items():
            assert (
                reduction in self.implemented_reductions
            ), f"Reduction {reduction} is not implemented, use one of {self.implemented_reductions}"

            if reduction == "mean":
                from statistics import mean

                for field in fields:
                    global_score[field] = mean([instance["score"]["instance"][field] for instance in instances])
                    if field == self.main_score:
                        global_score["score"] = global_score[field]

        for instance in instances:
            yield instance

    def _compute(self, references: List[List[str]], predictions: List[str]) -> dict:
        result = self.compute(references=references, predictions=predictions)
        result["score"] = result[self.main_score]
        return result

    @abstractmethod
    def compute(self, references: List[str], prediction: str) -> dict:
        pass


class Squad(GlobalMetric):
    _metric = None
    reduction_map = {"mean": ["f1"]}
    main_score = "f1"
    metric = "squad"

    def prepare(self):
        super(Squad, self).prepare()
        self._metric = evaluate.load(self.metric)

    def compute(self, references: List[List[str]], predictions: List[str]) -> dict:
        ids = [str(uuid.uuid4()).replace("-", "") for _ in range(len(predictions))]
        formatted_predictions = [
            {"prediction_text": prediction, "id": ids[i]} for i, prediction in enumerate(predictions)
        ]
        formatted_references = [
            {"answers": {"answer_start": [-1], "text": reference}, "id": ids[i]}
            for i, reference in enumerate(references)
        ]

        return self._metric.compute(predictions=formatted_predictions, references=formatted_references)


class SingleReferenceInstanceMetric(InstanceMetric):
    def _compute(self, references: List[str], prediction: str) -> dict:
        result = self.compute(references[0], prediction)
        result["score"] = result[self.main_score]
        return result

    @abstractmethod
    def compute(self, reference, prediction: str) -> dict:
        pass


class Accuracy(SingleReferenceInstanceMetric):
    reduction_map = {"mean": ["accuracy"]}
    main_score = "accuracy"

    def compute(self, reference, prediction: str) -> dict:
        return {"accuracy": float(str(reference) == str(prediction))}


class MetricPipeline(MultiStreamOperator, Metric):
    main_score: str = None
    preprocess_steps: Optional[List[StreamingOperator]] = field(default_factory=list)
    postpreprocess_steps: Optional[List[StreamingOperator]] = field(default_factory=list)
    metric: Metric = None

    def verify(self):
        assert self.main_score is not None, "main_score is not set"

    def prepare(self):
        super().prepare()
        self.prepare_score = CopyFields(
            field_to_field=[
                [f"score/instance/{self.main_score}", "score/instance/score"],
                [f"score/global/{self.main_score}", "score/global/score"],
            ],
            use_query=True,
        )

    def process(self, multi_stream: MultiStream) -> MultiStream:
        for step in self.preprocess_steps:
            multi_stream = step(multi_stream)
        multi_stream = self.metric(multi_stream)
        for step in self.postpreprocess_steps:
            multi_stream = step(multi_stream)
        multi_stream = self.prepare_score(multi_stream)
        return multi_stream


class HuggingfaceMetric(GlobalMetric):
    metric_name: str = None
    main_score: str = None
    scale: float = 1.0

    def prepare(self):
        super().prepare()
        self.metric = evaluate.load(self.metric_name)

    def compute(self, references: List[List[str]], predictions: List[str]) -> dict:
        result = self.metric.compute(predictions=predictions, references=references)
        if self.scale != 1.0:
            for key in result:
                if isinstance(result[key], float):
                    result[key] /= self.scale
        return result


class F1(GlobalMetric):
    _metric = None
    main_score = "f1_macro"
    average = None  # Report per class then aggregate by mean
    metric = "f1"

    def prepare(self):
        super(F1, self).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]) -> 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]
        unique_labels = 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 F1MultiLabel(GlobalMetric):
    _metric = None
    main_score = "f1_macro"
    average = None  # Report per class then aggregate by mean

    def prepare(self):
        super(F1MultiLabel, self).prepare()
        self._metric = evaluate.load("f1", "multilabel")

    def add_str_to_id(self, str):
        if not str 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[str]) -> dict:
        self.str_to_id = {}
        self.id_to_str = {}
        assert all(
            len(reference) == 1 for reference in references
        ), "Only a single reference per prediction is allowed in F1 metric"
        references = [reference[0] for reference in references]
        labels = list(set([label for reference in references for label in reference]))
        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]
        result = self._metric.compute(
            predictions=formatted_predictions, references=formatted_references, 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_" + label] = result["f1"][i]
        else:
            final_result = {self.main_score: result["f1"]}
        return final_result


class F1MicroMultiLabel(F1MultiLabel):
    main_score = "f1_micro"
    average = "micro"


class F1MacroMultiLabel(F1MultiLabel):
    main_score = "f1_macro"
    average = None


class Rouge(HuggingfaceMetric):
    metric_name = "rouge"
    main_score = "rougeL"
    scale = 1.0

    def compute(self, references, predictions):
        predictions = ["\n".join(nltk.sent_tokenize(prediction.strip())) for prediction in predictions]
        references = [["\n".join(nltk.sent_tokenize(r.strip())) for r in reference] for reference in references]
        return super().compute(references, predictions)


# Computes chat edit distance, ignoring repeating whitespace
class CharEditDistanceAccuracy(SingleReferenceInstanceMetric):
    reduction_map = {"mean": ["char_edit_dist_accuracy"]}
    main_score = "char_edit_dist_accuracy"

    def compute(self, reference, prediction: str) -> dict:
        formatted_prediction = " ".join(prediction.split())
        formatted_reference = " ".join(reference.split())
        max_length = max(len(formatted_reference), len(formatted_prediction))
        if max_length == 0:
            return 0
        edit_dist = eval(formatted_reference, formatted_prediction)
        return {"char_edit_dist_accuracy": (1 - edit_dist / max_length)}


class Wer(HuggingfaceMetric):
    metric_name = "wer"
    main_score = "wer"

    def prepare(self):
        super().prepare()
        self.metric = evaluate.load(self.metric_name)

    def compute(self, references: List[List[str]], predictions: List[str]) -> 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 Bleu(HuggingfaceMetric):
    metric_name = "bleu"
    main_score = "bleu"
    scale = 1.0


class MatthewsCorrelation(HuggingfaceMetric):
    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]) -> dict:
        formatted_references = [self.get_str_id(reference[0]) for reference in references]
        formatted_predictions = [self.get_str_id(prediction) for prediction in predictions]
        result = self.metric.compute(predictions=formatted_predictions, references=formatted_references)
        return result


class CustomF1(GlobalMetric):
    main_score = "f1_micro"
    classes = None

    @abstractmethod
    def get_element_group(self, element):
        pass

    @abstractmethod
    def get_element_representation(self, element):
        pass

    def group_elements(self, l):
        return {
            k: Counter([self.get_element_representation(value) for value in l if self.get_element_group(value) == k])
            for k in set([self.get_element_group(e) for e in l])
        }

    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 f1(self, pn, pd, rn, rd):
        precision = 1.0 if pn == 0 and pd == 0 else pn / pd
        recall = 1.0 if rn == 0 and rd == 0 else rn / rd
        try:
            return 2 * precision * recall / (precision + recall)
        except ZeroDivisionError:
            return 0.0

    def compute(self, references: List[Any], predictions: List[Any]) -> dict:
        # in case reference are List[List[List[Any]]] and predictions are List[List[Any]]:
        if isinstance(references[0], list) 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.classes is None:
            classes = set([self.get_element_group(e) for sublist in references for e in sublist])
        else:
            classes = self.classes
        groups_statistics = dict()
        for references_batch, predictions_batch in zip(references, predictions):
            grouped_references = self.group_elements(references_batch)
            grouped_predictions = self.group_elements(predictions_batch)
            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

        result = {}
        num_of_unknown_class_predictions = 0
        pn_total = pd_total = rn_total = rd_total = 0
        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 classes:
                result[f"f1_{group}"] = self.f1(pn, pd, rn, rd)
            else:
                num_of_unknown_class_predictions += pd
        try:
            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
        result[f"f1_micro"] = self.f1(pn_total, pd_total, rn_total, rd_total)
        return result


class NER(CustomF1):
    def get_element_group(self, element):
        return element[1]

    def get_element_representation(self, element):
        return str(element)