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"""The General Language Understanding Evaluation (GLUE) benchmark.""" |
|
|
|
|
|
import csv |
|
import os |
|
import textwrap |
|
|
|
import numpy as np |
|
|
|
import datasets |
|
|
|
|
|
_PLUE_CITATION = """\ |
|
@misc{Gomes2020, |
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author = {GOMES, J. R. S.}, |
|
title = {Portuguese Language Understanding Evaluation}, |
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year = {2020}, |
|
publisher = {GitHub}, |
|
journal = {GitHub repository}, |
|
howpublished = {\\url{https://github.com/jubs12/PLUE}}, |
|
commit = {CURRENT_COMMIT} |
|
} |
|
|
|
@inproceedings{wang2019glue, |
|
title={{GLUE}: A Multi-Task Benchmark and Analysis Platform for Natural Language Understanding}, |
|
author={Wang, Alex and Singh, Amanpreet and Michael, Julian and Hill, Felix and Levy, Omer and Bowman, Samuel R.}, |
|
note={In the Proceedings of ICLR.}, |
|
year={2019} |
|
} |
|
""" |
|
|
|
_PLUE_DESCRIPTION = """\ |
|
PLUE: Portuguese Language Understanding Evaluationis a Portuguese translation of |
|
the GLUE benchmark and Scitail using OPUS-MT model and Google Cloud Translation. |
|
""" |
|
|
|
MNLI_URL = "https://github.com/ju-resplande/PLUE/releases/download/v1.0.0/MNLI.zip" |
|
SNLI_URL = "https://github.com/ju-resplande/PLUE/releases/download/v1.0.0/SNLI.zip" |
|
|
|
_MNLI_BASE_KWARGS = dict( |
|
text_features={"premise": "sentence1", "hypothesis": "sentence2",}, |
|
label_classes=["entailment", "neutral", "contradiction"], |
|
label_column="gold_label", |
|
data_dir="MNLI", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@InProceedings{N18-1101, |
|
author = "Williams, Adina |
|
and Nangia, Nikita |
|
and Bowman, Samuel", |
|
title = "A Broad-Coverage Challenge Corpus for |
|
Sentence Understanding through Inference", |
|
booktitle = "Proceedings of the 2018 Conference of |
|
the North American Chapter of the |
|
Association for Computational Linguistics: |
|
Human Language Technologies, Volume 1 (Long |
|
Papers)", |
|
year = "2018", |
|
publisher = "Association for Computational Linguistics", |
|
pages = "1112--1122", |
|
location = "New Orleans, Louisiana", |
|
url = "http://aclweb.org/anthology/N18-1101" |
|
} |
|
@article{bowman2015large, |
|
title={A large annotated corpus for learning natural language inference}, |
|
author={Bowman, Samuel R and Angeli, Gabor and Potts, Christopher and Manning, Christopher D}, |
|
journal={arXiv preprint arXiv:1508.05326}, |
|
year={2015} |
|
}""" |
|
), |
|
url="http://www.nyu.edu/projects/bowman/multinli/", |
|
) |
|
|
|
|
|
class PlueConfig(datasets.BuilderConfig): |
|
"""BuilderConfig for GLUE.""" |
|
|
|
def __init__( |
|
self, |
|
text_features, |
|
label_column, |
|
data_dir, |
|
citation, |
|
url, |
|
label_classes=None, |
|
process_label=lambda x: x, |
|
**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(PlueConfig, self).__init__( |
|
version=datasets.Version("1.0.2", ""), **kwargs |
|
) |
|
self.text_features = text_features |
|
self.label_column = label_column |
|
self.label_classes = label_classes |
|
self.data_url = ( |
|
"https://github.com/ju-resplande/PLUE/archive/refs/tags/v1.0.1.zip" |
|
) |
|
self.data_dir = data_dir |
|
self.citation = citation |
|
self.url = url |
|
self.process_label = process_label |
|
|
|
|
|
class Plue(datasets.GeneratorBasedBuilder): |
|
"""The General Language Understanding Evaluation (GLUE) benchmark.""" |
|
|
|
BUILDER_CONFIGS = [ |
|
PlueConfig( |
|
name="cola", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Corpus of Linguistic Acceptability consists of English |
|
acceptability judgments drawn from books and journal articles on |
|
linguistic theory. Each example is a sequence of words annotated |
|
with whether it is a grammatical English sentence.""" |
|
), |
|
text_features={"sentence": "sentence"}, |
|
label_classes=["unacceptable", "acceptable"], |
|
label_column="is_acceptable", |
|
data_dir="PLUE-1.0.1/datasets/CoLA", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@article{warstadt2018neural, |
|
title={Neural Network Acceptability Judgments}, |
|
author={Warstadt, Alex and Singh, Amanpreet and Bowman, Samuel R}, |
|
journal={arXiv preprint arXiv:1805.12471}, |
|
year={2018} |
|
}""" |
|
), |
|
url="https://nyu-mll.github.io/CoLA/", |
|
), |
|
PlueConfig( |
|
name="sst2", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Stanford Sentiment Treebank consists of sentences from movie reviews and |
|
human annotations of their sentiment. The task is to predict the sentiment of a |
|
given sentence. We use the two-way (positive/negative) class split, and use only |
|
sentence-level labels.""" |
|
), |
|
text_features={"sentence": "sentence"}, |
|
label_classes=["negative", "positive"], |
|
label_column="label", |
|
data_dir="PLUE-1.0.1/datasets/SST-2", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@inproceedings{socher2013recursive, |
|
title={Recursive deep models for semantic compositionality over a sentiment treebank}, |
|
author={Socher, Richard and Perelygin, Alex and Wu, Jean and Chuang, Jason and Manning, Christopher D and Ng, Andrew and Potts, Christopher}, |
|
booktitle={Proceedings of the 2013 conference on empirical methods in natural language processing}, |
|
pages={1631--1642}, |
|
year={2013} |
|
}""" |
|
), |
|
url="https://datasets.stanford.edu/sentiment/index.html", |
|
), |
|
PlueConfig( |
|
name="mrpc", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Microsoft Research Paraphrase Corpus (Dolan & Brockett, 2005) is a corpus of |
|
sentence pairs automatically extracted from online news sources, with human annotations |
|
for whether the sentences in the pair are semantically equivalent.""" |
|
), |
|
text_features={"sentence1": "", "sentence2": ""}, |
|
label_classes=["not_equivalent", "equivalent"], |
|
label_column="Quality", |
|
data_dir="PLUE-1.0.1/datasets/MRPC", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@inproceedings{dolan2005automatically, |
|
title={Automatically constructing a corpus of sentential paraphrases}, |
|
author={Dolan, William B and Brockett, Chris}, |
|
booktitle={Proceedings of the Third International Workshop on Paraphrasing (IWP2005)}, |
|
year={2005} |
|
}""" |
|
), |
|
url="https://www.microsoft.com/en-us/download/details.aspx?id=52398", |
|
), |
|
PlueConfig( |
|
name="qqp", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Quora Question Pairs2 dataset is a collection of question pairs from the |
|
community question-answering website Quora. The task is to determine whether a |
|
pair of questions are semantically equivalent.""" |
|
), |
|
text_features={"question1": "question1", "question2": "question2",}, |
|
label_classes=["not_duplicate", "duplicate"], |
|
label_column="is_duplicate", |
|
data_dir="PLUE-1.0.1/datasets/QQP_v2", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@online{WinNT, |
|
author = {Iyer, Shankar and Dandekar, Nikhil and Csernai, Kornel}, |
|
title = {First Quora Dataset Release: Question Pairs}, |
|
year = {2017}, |
|
url = {https://data.quora.com/First-Quora-Dataset-Release-Question-Pairs}, |
|
urldate = {2019-04-03} |
|
}""" |
|
), |
|
url="https://data.quora.com/First-Quora-Dataset-Release-Question-Pairs", |
|
), |
|
PlueConfig( |
|
name="stsb", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Semantic Textual Similarity Benchmark (Cer et al., 2017) is a collection of |
|
sentence pairs drawn from news headlines, video and image captions, and natural |
|
language inference data. Each pair is human-annotated with a similarity score |
|
from 1 to 5.""" |
|
), |
|
text_features={"sentence1": "sentence1", "sentence2": "sentence2",}, |
|
label_column="score", |
|
data_dir="PLUE-1.0.1/datasets/STS-B", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@article{cer2017semeval, |
|
title={Semeval-2017 task 1: Semantic textual similarity-multilingual and cross-lingual focused evaluation}, |
|
author={Cer, Daniel and Diab, Mona and Agirre, Eneko and Lopez-Gazpio, Inigo and Specia, Lucia}, |
|
journal={arXiv preprint arXiv:1708.00055}, |
|
year={2017} |
|
}""" |
|
), |
|
url="http://ixa2.si.ehu.es/stswiki/index.php/STSbenchmark", |
|
process_label=np.float32, |
|
), |
|
PlueConfig( |
|
name="snli", |
|
description=textwrap.dedent( |
|
"""\ |
|
The SNLI corpus (version 1.0) is a collection of 570k human-written English |
|
sentence pairs manually labeled for balanced classification with the labels |
|
entailment, contradiction, and neutral, supporting the task of natural language |
|
inference (NLI), also known as recognizing textual entailment (RTE). |
|
""" |
|
), |
|
text_features={"premise": "sentence1", "hypothesis": "sentence2",}, |
|
label_classes=["entailment", "neutral", "contradiction"], |
|
label_column="gold_label", |
|
data_dir="SNLI", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@inproceedings{snli:emnlp2015, |
|
Author = {Bowman, Samuel R. and Angeli, Gabor and Potts, Christopher, and Manning, Christopher D.}, |
|
Booktitle = {Proceedings of the 2015 Conference on Empirical Methods in Natural Language Processing (EMNLP)}, |
|
Publisher = {Association for Computational Linguistics}, |
|
Title = {A large annotated corpus for learning natural language inference}, |
|
Year = {2015} |
|
} |
|
""" |
|
), |
|
url="https://nlp.stanford.edu/projects/snli/", |
|
), |
|
PlueConfig( |
|
name="mnli", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Multi-Genre Natural Language Inference Corpus is a crowdsourced |
|
collection of sentence pairs with textual entailment annotations. Given a premise sentence |
|
and a hypothesis sentence, the task is to predict whether the premise entails the hypothesis |
|
(entailment), contradicts the hypothesis (contradiction), or neither (neutral). The premise sentences are |
|
gathered from ten different sources, including transcribed speech, fiction, and government reports. |
|
We use the standard test set, for which we obtained private labels from the authors, and evaluate |
|
on both the matched (in-domain) and mismatched (cross-domain) section. We also use and recommend |
|
the SNLI corpus as 550k examples of auxiliary training data.""" |
|
), |
|
**_MNLI_BASE_KWARGS, |
|
), |
|
PlueConfig( |
|
name="mnli_mismatched", |
|
description=textwrap.dedent( |
|
"""\ |
|
The mismatched validation and test splits from MNLI. |
|
See the "mnli" BuilderConfig for additional information.""" |
|
), |
|
**_MNLI_BASE_KWARGS, |
|
), |
|
PlueConfig( |
|
name="mnli_matched", |
|
description=textwrap.dedent( |
|
"""\ |
|
The matched validation and test splits from MNLI. |
|
See the "mnli" BuilderConfig for additional information.""" |
|
), |
|
**_MNLI_BASE_KWARGS, |
|
), |
|
PlueConfig( |
|
name="qnli", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Stanford Question Answering Dataset is a question-answering |
|
dataset consisting of question-paragraph pairs, where one of the sentences in the paragraph (drawn |
|
from Wikipedia) contains the answer to the corresponding question (written by an annotator). We |
|
convert the task into sentence pair classification by forming a pair between each question and each |
|
sentence in the corresponding context, and filtering out pairs with low lexical overlap between the |
|
question and the context sentence. The task is to determine whether the context sentence contains |
|
the answer to the question. This modified version of the original task removes the requirement that |
|
the model select the exact answer, but also removes the simplifying assumptions that the answer |
|
is always present in the input and that lexical overlap is a reliable cue.""" |
|
), |
|
text_features={"question": "question", "sentence": "sentence",}, |
|
label_classes=["entailment", "not_entailment"], |
|
label_column="label", |
|
data_dir="PLUE-1.0.1/datasets/QNLI", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@article{rajpurkar2016squad, |
|
title={Squad: 100,000+ questions for machine comprehension of text}, |
|
author={Rajpurkar, Pranav and Zhang, Jian and Lopyrev, Konstantin and Liang, Percy}, |
|
journal={arXiv preprint arXiv:1606.05250}, |
|
year={2016} |
|
}""" |
|
), |
|
url="https://rajpurkar.github.io/SQuAD-explorer/", |
|
), |
|
PlueConfig( |
|
name="rte", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Recognizing Textual Entailment (RTE) datasets come from a series of annual textual |
|
entailment challenges. We combine the data from RTE1 (Dagan et al., 2006), RTE2 (Bar Haim |
|
et al., 2006), RTE3 (Giampiccolo et al., 2007), and RTE5 (Bentivogli et al., 2009).4 Examples are |
|
constructed based on news and Wikipedia text. We convert all datasets to a two-class split, where |
|
for three-class datasets we collapse neutral and contradiction into not entailment, for consistency.""" |
|
), |
|
text_features={"sentence1": "sentence1", "sentence2": "sentence2",}, |
|
label_classes=["entailment", "not_entailment"], |
|
label_column="label", |
|
data_dir="PLUE-1.0.1/datasets/RTE", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@inproceedings{dagan2005pascal, |
|
title={The PASCAL recognising textual entailment challenge}, |
|
author={Dagan, Ido and Glickman, Oren and Magnini, Bernardo}, |
|
booktitle={Machine Learning Challenges Workshop}, |
|
pages={177--190}, |
|
year={2005}, |
|
organization={Springer} |
|
} |
|
@inproceedings{bar2006second, |
|
title={The second pascal recognising textual entailment challenge}, |
|
author={Bar-Haim, Roy and Dagan, Ido and Dolan, Bill and Ferro, Lisa and Giampiccolo, Danilo and Magnini, Bernardo and Szpektor, Idan}, |
|
booktitle={Proceedings of the second PASCAL challenges workshop on recognising textual entailment}, |
|
volume={6}, |
|
number={1}, |
|
pages={6--4}, |
|
year={2006}, |
|
organization={Venice} |
|
} |
|
@inproceedings{giampiccolo2007third, |
|
title={The third pascal recognizing textual entailment challenge}, |
|
author={Giampiccolo, Danilo and Magnini, Bernardo and Dagan, Ido and Dolan, Bill}, |
|
booktitle={Proceedings of the ACL-PASCAL workshop on textual entailment and paraphrasing}, |
|
pages={1--9}, |
|
year={2007}, |
|
organization={Association for Computational Linguistics} |
|
} |
|
@inproceedings{bentivogli2009fifth, |
|
title={The Fifth PASCAL Recognizing Textual Entailment Challenge.}, |
|
author={Bentivogli, Luisa and Clark, Peter and Dagan, Ido and Giampiccolo, Danilo}, |
|
booktitle={TAC}, |
|
year={2009} |
|
}""" |
|
), |
|
url="https://aclweb.org/aclwiki/Recognizing_Textual_Entailment", |
|
), |
|
PlueConfig( |
|
name="wnli", |
|
description=textwrap.dedent( |
|
"""\ |
|
The Winograd Schema Challenge (Levesque et al., 2011) is a reading comprehension task |
|
in which a system must read a sentence with a pronoun and select the referent of that pronoun from |
|
a list of choices. The examples are manually constructed to foil simple statistical methods: Each |
|
one is contingent on contextual information provided by a single word or phrase in the sentence. |
|
To convert the problem into sentence pair classification, we construct sentence pairs by replacing |
|
the ambiguous pronoun with each possible referent. The task is to predict if the sentence with the |
|
pronoun substituted is entailed by the original sentence. We use a small evaluation set consisting of |
|
new examples derived from fiction books that was shared privately by the authors of the original |
|
corpus. While the included training set is balanced between two classes, the test set is imbalanced |
|
between them (65% not entailment). Also, due to a data quirk, the development set is adversarial: |
|
hypotheses are sometimes shared between training and development examples, so if a model memorizes the |
|
training examples, they will predict the wrong label on corresponding development set |
|
example. As with QNLI, each example is evaluated separately, so there is not a systematic correspondence |
|
between a model's score on this task and its score on the unconverted original task. We |
|
call converted dataset WNLI (Winograd NLI).""" |
|
), |
|
text_features={"sentence1": "sentence1", "sentence2": "sentence2",}, |
|
label_classes=["not_entailment", "entailment"], |
|
label_column="label", |
|
data_dir="PLUE-1.0.1/datasets/WNLI", |
|
citation=textwrap.dedent( |
|
"""\ |
|
@inproceedings{levesque2012winograd, |
|
title={The winograd schema challenge}, |
|
author={Levesque, Hector and Davis, Ernest and Morgenstern, Leora}, |
|
booktitle={Thirteenth International Conference on the Principles of Knowledge Representation and Reasoning}, |
|
year={2012} |
|
}""" |
|
), |
|
url="https://cs.nyu.edu/faculty/davise/papers/WinogradSchemas/WS.html", |
|
), |
|
PlueConfig( |
|
name="scitail", |
|
description=textwrap.dedent( |
|
"""\ |
|
The SciTail dataset is an entailment dataset created from multiple-choice science exams and web sentences. Each question |
|
and the correct answer choice are converted into an assertive statement to form the hypothesis. We use information |
|
retrieval to obtain relevant text from a large text corpus of web sentences, and use these sentences as a premise P. We |
|
crowdsource the annotation of such premise-hypothesis pair as supports (entails) or not (neutral), in order to create |
|
the SciTail dataset. The dataset contains 27,026 examples with 10,101 examples with entails label and 16,925 examples |
|
with neutral label""" |
|
), |
|
text_features={"premise": "premise", "hypothesis": "hypothesis",}, |
|
label_classes=["entails", "neutral"], |
|
label_column="label", |
|
data_dir="PLUE-1.0.1/datasets/SciTail", |
|
citation=""""\ |
|
inproceedings{scitail, |
|
Author = {Tushar Khot and Ashish Sabharwal and Peter Clark}, |
|
Booktitle = {AAAI}, |
|
Title = {{SciTail}: A Textual Entailment Dataset from Science Question Answering}, |
|
Year = {2018} |
|
} |
|
""", |
|
url="https://gluebenchmark.com/diagnostics", |
|
), |
|
] |
|
|
|
def _info(self): |
|
features = { |
|
text_feature: datasets.Value("string") |
|
for text_feature in self.config.text_features.keys() |
|
} |
|
if self.config.label_classes: |
|
features["label"] = datasets.features.ClassLabel( |
|
names=self.config.label_classes |
|
) |
|
else: |
|
features["label"] = datasets.Value("float32") |
|
features["idx"] = datasets.Value("int32") |
|
return datasets.DatasetInfo( |
|
description=_PLUE_DESCRIPTION, |
|
features=datasets.Features(features), |
|
homepage=self.config.url, |
|
citation=self.config.citation + "\n" + _PLUE_CITATION, |
|
) |
|
|
|
def _split_generators(self, dl_manager): |
|
if self.config.name == "mnli": |
|
data_url = MNLI_URL |
|
elif self.config.name == "snli": |
|
data_url = SNLI_URL |
|
else: |
|
data_url = self.config.data_url |
|
|
|
dl_dir = dl_manager.download_and_extract(data_url) |
|
data_dir = os.path.join(dl_dir, self.config.data_dir) |
|
|
|
train_split = datasets.SplitGenerator( |
|
name=datasets.Split.TRAIN, |
|
gen_kwargs={ |
|
"data_file": os.path.join(data_dir or "", "train.tsv"), |
|
"split": "train", |
|
}, |
|
) |
|
if self.config.name == "mnli": |
|
return [ |
|
train_split, |
|
_mnli_split_generator( |
|
"validation_matched", data_dir, "dev", matched=True |
|
), |
|
_mnli_split_generator( |
|
"validation_mismatched", data_dir, "dev", matched=False |
|
), |
|
_mnli_split_generator("test_matched", data_dir, "test", matched=True), |
|
_mnli_split_generator( |
|
"test_mismatched", data_dir, "test", matched=False |
|
), |
|
] |
|
elif self.config.name == "mnli_matched": |
|
return [ |
|
_mnli_split_generator("validation", data_dir, "dev", matched=True), |
|
_mnli_split_generator("test", data_dir, "test", matched=True), |
|
] |
|
elif self.config.name == "mnli_mismatched": |
|
return [ |
|
_mnli_split_generator("validation", data_dir, "dev", matched=False), |
|
_mnli_split_generator("test", data_dir, "test", matched=False), |
|
] |
|
else: |
|
return [ |
|
train_split, |
|
datasets.SplitGenerator( |
|
name=datasets.Split.VALIDATION, |
|
gen_kwargs={ |
|
"data_file": os.path.join(data_dir or "", "dev.tsv"), |
|
"split": "dev", |
|
}, |
|
), |
|
datasets.SplitGenerator( |
|
name=datasets.Split.TEST, |
|
gen_kwargs={ |
|
"data_file": os.path.join(data_dir or "", "test.tsv"), |
|
"split": "test", |
|
}, |
|
), |
|
] |
|
|
|
def _generate_examples(self, data_file, split): |
|
if self.config.name in ["mrpc", "scitail"]: |
|
if self.config.name == "mrpc": |
|
examples = self._generate_example_mrpc_files( |
|
data_file=data_file, split=split |
|
) |
|
elif self.config.name == "scitail": |
|
examples = self._generate_example_scitail_files( |
|
data_file=data_file, split=split |
|
) |
|
|
|
for example in examples: |
|
yield example["idx"], example |
|
|
|
else: |
|
process_label = self.config.process_label |
|
label_classes = self.config.label_classes |
|
|
|
|
|
|
|
is_cola_non_test = self.config.name == "cola" and split != "test" |
|
|
|
with open(data_file, encoding="utf8") as f: |
|
reader = csv.DictReader(f, delimiter="\t", quoting=csv.QUOTE_NONE) |
|
if is_cola_non_test: |
|
reader = csv.reader(f, delimiter="\t", quoting=csv.QUOTE_NONE) |
|
|
|
for n, row in enumerate(reader): |
|
if is_cola_non_test: |
|
row = { |
|
"sentence": row[3], |
|
"is_acceptable": row[1], |
|
} |
|
|
|
example = { |
|
feat: row[col] |
|
for feat, col in self.config.text_features.items() |
|
} |
|
example["idx"] = n |
|
|
|
if self.config.label_column in row: |
|
label = row[self.config.label_column] |
|
|
|
|
|
if label_classes and label not in label_classes: |
|
label = int(label) if label else None |
|
example["label"] = process_label(label) |
|
else: |
|
example["label"] = process_label(-1) |
|
|
|
|
|
for value in example.values(): |
|
if value is None: |
|
break |
|
else: |
|
yield example["idx"], example |
|
|
|
def _generate_example_mrpc_files(self, data_file, split): |
|
print(data_file) |
|
|
|
with open(data_file, encoding="utf8") as f: |
|
reader = csv.DictReader(f, delimiter="\t", quoting=csv.QUOTE_NONE) |
|
for idx, row in enumerate(reader): |
|
label = row["Quality"] if split != "test" else -1 |
|
|
|
yield { |
|
"sentence1": row["#1 String"], |
|
"sentence2": row["#2 String"], |
|
"label": int(label), |
|
"idx": idx, |
|
} |
|
|
|
def _generate_example_scitail_files(self, data_file, split): |
|
with open(data_file, encoding="utf8") as f: |
|
reader = csv.DictReader( |
|
f, |
|
delimiter="\t", |
|
quoting=csv.QUOTE_NONE, |
|
fieldnames=["premise", "hypothesis", "label"], |
|
) |
|
for idx, row in enumerate(reader): |
|
label = row["label"] if split != "test" else -1 |
|
|
|
yield { |
|
"premise": row["premise"], |
|
"hypothesis": row["hypothesis"], |
|
"label": label, |
|
"idx": idx, |
|
} |
|
|
|
|
|
def _mnli_split_generator(name, data_dir, split, matched): |
|
return datasets.SplitGenerator( |
|
name=name, |
|
gen_kwargs={ |
|
"data_file": os.path.join( |
|
data_dir, "%s_%s.tsv" % (split, "matched" if matched else "mismatched") |
|
), |
|
"split": split, |
|
}, |
|
) |
|
|
|
|