import datasets from typing import Dict, List, Optional, Union import json import textwrap import xml.etree.ElementTree as ET import pandas as pd logger = datasets.logging.get_logger(__name__) # Extracted from: # - https://huggingface.co/datasets/lener_br # - https://github.com/peluz/lener-br # - https://teodecampos.github.io/LeNER-Br/ _LENERBR_KWARGS = dict( name = "LeNER-Br", description=textwrap.dedent( """\ LeNER-Br is a Portuguese language dataset for named entity recognition applied to legal documents. LeNER-Br consists entirely of manually annotated legislation and legal cases texts and contains tags for persons, locations, time entities, organizations, legislation and legal cases. To compose the dataset, 66 legal documents from several Brazilian Courts were collected. Courts of superior and state levels were considered, such as Supremo Tribunal Federal, Superior Tribunal de Justiça, Tribunal de Justiça de Minas Gerais and Tribunal de Contas da União. In addition, four legislation documents were collected, such as "Lei Maria da Penha", giving a total of 70 documents.""" ), task_type="ner", label_classes=["ORGANIZACAO", "PESSOA", "TEMPO", "LOCAL", "LEGISLACAO", "JURISPRUDENCIA"], data_urls={ "train": "https://raw.githubusercontent.com/peluz/lener-br/master/leNER-Br/train/train.conll", "validation": "https://raw.githubusercontent.com/peluz/lener-br/master/leNER-Br/dev/dev.conll", "test": "https://raw.githubusercontent.com/peluz/lener-br/master/leNER-Br/test/test.conll", }, citation=textwrap.dedent( """\ @InProceedings{luz_etal_propor2018, author = {Pedro H. {Luz de Araujo} and Te\'{o}filo E. {de Campos} and Renato R. R. {de Oliveira} and Matheus Stauffer and Samuel Couto and Paulo Bermejo}, title = {{LeNER-Br}: a Dataset for Named Entity Recognition in {Brazilian} Legal Text}, booktitle = {International Conference on the Computational Processing of Portuguese ({PROPOR})}, publisher = {Springer}, series = {Lecture Notes on Computer Science ({LNCS})}, pages = {313--323}, year = {2018}, month = {September 24-26}, address = {Canela, RS, Brazil}, doi = {10.1007/978-3-319-99722-3_32}, url = {https://teodecampos.github.io/LeNER-Br/}, }""" ), url="https://teodecampos.github.io/LeNER-Br/", ) # Extracted from: # - https://huggingface.co/datasets/assin2 # - https://sites.google.com/view/assin2 # - https://github.com/ruanchaves/assin _ASSIN2_BASE_KWARGS = dict( description=textwrap.dedent( """\ The ASSIN 2 corpus is composed of rather simple sentences. Following the procedures of SemEval 2014 Task 1. The training and validation data are composed, respectively, of 6,500 and 500 sentence pairs in Brazilian Portuguese, annotated for entailment and semantic similarity. Semantic similarity values range from 1 to 5, and text entailment classes are either entailment or none. The test data are composed of approximately 3,000 sentence pairs with the same annotation. All data were manually annotated.""" ), data_urls={ "train": "https://github.com/ruanchaves/assin/raw/master/sources/assin2-train-only.xml", "validation": "https://github.com/ruanchaves/assin/raw/master/sources/assin2-dev.xml", "test": "https://github.com/ruanchaves/assin/raw/master/sources/assin2-test.xml", }, citation=textwrap.dedent( """\ @inproceedings{real2020assin, title={The assin 2 shared task: a quick overview}, author={Real, Livy and Fonseca, Erick and Oliveira, Hugo Goncalo}, booktitle={International Conference on Computational Processing of the Portuguese Language}, pages={406--412}, year={2020}, organization={Springer} }""" ), url="https://sites.google.com/view/assin2", ) _ASSIN2_RTE_KWARGS = dict( name = "assin2-rte", task_type="rte", label_classes=["NONE", "ENTAILMENT"], **_ASSIN2_BASE_KWARGS ) _ASSIN2_STS_KWARGS = dict( name = "assin2-sts", task_type="sts", **_ASSIN2_BASE_KWARGS ) # Extracted from: # - https://huggingface.co/datasets/ruanchaves/hatebr # - https://github.com/franciellevargas/HateBR _HATEBR_KWARGS = dict( name = "HateBR", description=textwrap.dedent( """\ HateBR is the first large-scale expert annotated dataset of Brazilian Instagram comments for abusive language detection on the web and social media. The HateBR was collected from Brazilian Instagram comments of politicians and manually annotated by specialists. It is composed of 7,000 documents annotated according to three different layers: a binary classification (offensive versus non-offensive comments), offensiveness-level (highly, moderately, and slightly offensive messages), and nine hate speech groups (xenophobia, racism, homophobia, sexism, religious intolerance, partyism, apology for the dictatorship, antisemitism, and fatphobia). Each comment was annotated by three different annotators and achieved high inter-annotator agreement. Furthermore, baseline experiments were implemented reaching 85% of F1-score outperforming the current literature dataset baselines for the Portuguese language. We hope that the proposed expert annotated dataset may foster research on hate speech detection in the Natural Language Processing area.""" ), task_type="classification", file_type="csv", label_classes=[0, 1, 2, 3], data_urls={ "train": "https://raw.githubusercontent.com/franciellevargas/HateBR/2d18c5b9410c2dfdd6d5394caa54d608857dae7c/dataset/HateBR.csv" }, citation=textwrap.dedent( """\ @inproceedings{vargas2022hatebr, title={HateBR: A Large Expert Annotated Corpus of Brazilian Instagram Comments for Offensive Language and Hate Speech Detection}, author={Vargas, Francielle and Carvalho, Isabelle and de G{\'o}es, Fabiana Rodrigues and Pardo, Thiago and Benevenuto, Fabr{\'\i}cio}, booktitle={Proceedings of the Thirteenth Language Resources and Evaluation Conference}, pages={7174--7183}, year={2022} }""" ), url="https://github.com/franciellevargas/HateBR", text_and_label_columns=["instagram_comments", "offensiveness_levels"], indexes_url="https://huggingface.co/datasets/ruanchaves/hatebr/raw/main/indexes.json" ) class PTBenchmarkConfig(datasets.BuilderConfig): """BuilderConfig for PTBenchmark.""" def __init__( self, task_type: str, data_urls: Dict[str, str], citation: str, url: str, label_classes: Optional[List[Union[str, int]]] = None, file_type: Optional[str] = None, #filetype (csv, tsc, jsonl) text_and_label_columns: Optional[List[str]] = None, #columns for train, dev and test for csv datasets indexes_url=None, #indexes for train, dev and test for single file datasets **kwargs, ): """BuilderConfig for GLUE. Args: text_features: `dict[string, string]`, map from the name of the feature dict for each text field to the name of the column in the tsv file label_column: `string`, name of the column in the tsv file corresponding to the label data_url: `string`, url to download the zip file from data_dir: `string`, the path to the folder containing the tsv files in the downloaded zip citation: `string`, citation for the data set url: `string`, url for information about the data set label_classes: `list[string]`, the list of classes if the label is categorical. If not provided, then the label will be of type `datasets.Value('float32')`. process_label: `Function[string, any]`, function taking in the raw value of the label and processing it to the form required by the label feature **kwargs: keyword arguments forwarded to super. """ super(PTBenchmarkConfig, self).__init__(version=datasets.Version("1.0.3", ""), **kwargs) self.label_classes = label_classes self.task_type = task_type self.data_urls = data_urls self.citation = citation self.url = url self.file_type = file_type self.text_and_label_columns = text_and_label_columns self.indexes_url = indexes_url def _get_classification_features(config): return datasets.Features( { "idx": datasets.Value("int32"), "sentence": datasets.Value("string"), "label": datasets.features.ClassLabel(names=config.label_classes), } ) def _get_ner_features(config): bio_labels = ["O"] for label_name in config.label_classes: bio_labels.append("B-" + label_name) bio_labels.append("I-" + label_name) return datasets.Features( { "idx": datasets.Value("int32"), "tokens": datasets.Sequence(datasets.Value("string")), "ner_tags": datasets.Sequence( datasets.features.ClassLabel(names=bio_labels) ), } ) def _get_rte_features(config): return datasets.Features( { "idx": datasets.Value("int32"), "sentence1": datasets.Value("string"), "sentence2": datasets.Value("string"), "label": datasets.features.ClassLabel(names=config.label_classes), } ) def _get_sts_features(config): return datasets.Features( { "idx": datasets.Value("int32"), "sentence1": datasets.Value("string"), "sentence2": datasets.Value("string"), "label": datasets.Value("float32"), } ) def _csv_generator(file_path: str, columns: List[str], indexes_path: Optional[str] = None, split: Optional[str] = None): """Yields examples.""" df = pd.read_csv(file_path) df = df[columns] with open(indexes_path, "r") as f: indexes= json.load(f) split_indexes = indexes[split] df_split = df.iloc[split_indexes] for id_, row in df_split.iterrows(): example = { "idx": id_, "sentence": str(row[columns[0]]), "label": int(row[columns[-1]]) } yield id_, example def _conll_ner_generator(file_path): with open(file_path, encoding="utf-8") as f: guid = 0 tokens = [] ner_tags = [] for line in f: if line == "" or line == "\n": if tokens: yield guid, { "idx": guid, "tokens": tokens, "ner_tags": ner_tags, } guid += 1 tokens = [] ner_tags = [] else: splits = line.split(" ") tokens.append(splits[0]) ner_tags.append(splits[1].rstrip()) # last example yield guid, { "idx": guid, "tokens": tokens, "ner_tags": ner_tags, } def _assin2_generator(file_path, type): """Yields examples.""" id_ = 0 with open(file_path, "rb") as f: tree = ET.parse(f) root = tree.getroot() for pair in root: example = { "idx": int(pair.attrib.get("id")), "sentence1": pair.find(".//t").text, "sentence2": pair.find(".//h").text } if type == "rte": example["label"] = pair.attrib.get("entailment").upper() elif type == "sts": example["label"] = float(pair.attrib.get("similarity")) yield id_, example id_ += 1 class PTBenchmark(datasets.GeneratorBasedBuilder): BUILDER_CONFIGS = [ PTBenchmarkConfig( **_LENERBR_KWARGS ), PTBenchmarkConfig( **_ASSIN2_RTE_KWARGS ), PTBenchmarkConfig( **_ASSIN2_STS_KWARGS ), PTBenchmarkConfig( **_HATEBR_KWARGS ) ] def _info(self) -> datasets.DatasetInfo: features = None if self.config.task_type == "classification": features = _get_classification_features(self.config) elif self.config.task_type == "ner": features = _get_ner_features(self.config) elif self.config.task_type == "rte": features = _get_rte_features(self.config) elif self.config.task_type == "sts": features = _get_sts_features(self.config) return datasets.DatasetInfo( description=self.config.description, homepage=self.config.url, citation=self.config.citation, supervised_keys=None, features=features ) def _split_generators(self, dl_manager: datasets.DownloadManager): data_urls = self.config.data_urls.copy() if self.config.indexes_url is not None: data_urls['indexes'] = self.config.indexes_url file_paths = dl_manager.download_and_extract(data_urls) if self.config.indexes_url is None: return [ datasets.SplitGenerator( name=datasets.Split.TRAIN, gen_kwargs={"file_path": file_paths["train"]}, ), datasets.SplitGenerator( name=datasets.Split.VALIDATION, gen_kwargs={"file_path": file_paths["validation"]}, ), datasets.SplitGenerator( name=datasets.Split.TEST, gen_kwargs={"file_path": file_paths["test"]}, ) ] else: return [ datasets.SplitGenerator( name=datasets.Split.TRAIN, gen_kwargs={"file_path": file_paths["train"], "indexes_path": file_paths["indexes"], "split": "train"}, ), datasets.SplitGenerator( name=datasets.Split.VALIDATION, gen_kwargs={"file_path": file_paths["train"], "indexes_path": file_paths["indexes"], "split": "validation"}, ), datasets.SplitGenerator( name=datasets.Split.TEST, gen_kwargs={"file_path": file_paths["train"], "indexes_path": file_paths["indexes"], "split": "test"}, ) ] def _generate_examples( self, file_path: Optional[str] = None, indexes_path: Optional[str] = None, split: Optional[str] = None ): logger.info("⏳ Generating examples from = %s", file_path) if self.config.task_type == "classification": if self.config.file_type == "csv": yield from _csv_generator( file_path, self.config.text_and_label_columns, indexes_path=indexes_path, split=split ) elif self.config.task_type == "ner": yield from _conll_ner_generator(file_path) elif self.config.task_type == "rte": if "assin2" in self.config.name: yield from _assin2_generator(file_path, "rte") elif self.config.task_type == "sts": if "assin2" in self.config.name: yield from _assin2_generator(file_path, "sts")