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progene / progene.py
gabrielaltay's picture
Fix FileNotFoundError (#2)
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# coding=utf-8
# Copyright 2022 The HuggingFace Datasets Authors and the current dataset script contributor.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import itertools
import os
import pathlib
from typing import Dict, Iterable, Iterator, List, Tuple
import datasets
from .bigbiohub import kb_features
from .bigbiohub import BigBioConfig
from .bigbiohub import Tasks
_LANGUAGES = ["English"]
_PUBMED = True
_LOCAL = False
_CITATION = """\
@inproceedings{faessler-etal-2020-progene,
title = "{P}ro{G}ene - A Large-scale, High-Quality Protein-Gene Annotated Benchmark Corpus",
author = "Faessler, Erik and
Modersohn, Luise and
Lohr, Christina and
Hahn, Udo",
booktitle = "Proceedings of the 12th Language Resources and Evaluation Conference",
month = may,
year = "2020",
address = "Marseille, France",
publisher = "European Language Resources Association",
url = "https://aclanthology.org/2020.lrec-1.564",
pages = "4585--4596",
abstract = "Genes and proteins constitute the fundamental entities of molecular genetics. We here introduce ProGene (formerly called FSU-PRGE), a corpus that reflects our efforts to cope with this important class of named entities within the framework of a long-lasting large-scale annotation campaign at the Jena University Language {\&} Information Engineering (JULIE) Lab. We assembled the entire corpus from 11 subcorpora covering various biological domains to achieve an overall subdomain-independent corpus. It consists of 3,308 MEDLINE abstracts with over 36k sentences and more than 960k tokens annotated with nearly 60k named entity mentions. Two annotators strove for carefully assigning entity mentions to classes of genes/proteins as well as families/groups, complexes, variants and enumerations of those where genes and proteins are represented by a single class. The main purpose of the corpus is to provide a large body of consistent and reliable annotations for supervised training and evaluation of machine learning algorithms in this relevant domain. Furthermore, we provide an evaluation of two state-of-the-art baseline systems {---} BioBert and flair {---} on the ProGene corpus. We make the evaluation datasets and the trained models available to encourage comparable evaluations of new methods in the future.",
language = "English",
ISBN = "979-10-95546-34-4",
}
"""
_DATASETNAME = "progene"
_DISPLAYNAME = "ProGene"
_DESCRIPTION = """\
The Protein/Gene corpus was developed at the JULIE Lab Jena under supervision of Prof. Udo Hahn.
The executing scientist was Dr. Joachim Wermter.
The main annotator was Dr. Rico Pusch who is an expert in biology.
The corpus was developed in the context of the StemNet project (http://www.stemnet.de/).
"""
_HOMEPAGE = "https://zenodo.org/record/3698568#.YlVHqdNBxeg"
_LICENSE = "Creative Commons Attribution 4.0 International"
# using custom url: original distribution includes trained models (>25GB) and original dataset license allow for redistribution
_URLS = "data/crossvalidation_data.zip"
_SUPPORTED_TASKS = [Tasks.NAMED_ENTITY_RECOGNITION]
_SOURCE_VERSION = "1.1.0"
_BIGBIO_VERSION = "1.0.0"
class ProgeneDataset(datasets.GeneratorBasedBuilder):
"""ProgeneDataset"""
SOURCE_VERSION = datasets.Version(_SOURCE_VERSION)
BIGBIO_VERSION = datasets.Version(_BIGBIO_VERSION)
BUILDER_CONFIGS = [
BigBioConfig(
name="progene_source",
version=SOURCE_VERSION,
description="PROGENE source schema",
schema="source",
subset_id="progene",
),
BigBioConfig(
name="progene_bigbio_kb",
version=BIGBIO_VERSION,
description="PROGENE BigBio schema",
schema="bigbio_kb",
subset_id="progene",
),
]
DEFAULT_CONFIG_NAME = "progene_source"
def _info(self) -> datasets.DatasetInfo:
if self.config.schema == "source":
# This follows something similar to CONLL dataset that is in the IOB Format as well
features = datasets.Features(
{
"id": datasets.Value("string"),
"tokens": datasets.Sequence(datasets.Value("string")),
"tags": datasets.Sequence(datasets.Value("string")),
}
)
elif self.config.schema == "bigbio_kb":
features = kb_features
else:
raise ValueError(
"config schema is one of source or bigbio_kb for Progene Dataset"
)
return datasets.DatasetInfo(
description=_DESCRIPTION,
features=features,
homepage=_HOMEPAGE,
license=str(_LICENSE),
citation=_CITATION,
)
def _split_generators(self, dl_manager) -> List[datasets.SplitGenerator]:
"""Returns SplitGenerators."""
urls = _URLS
dl_dir = dl_manager.download_and_extract(urls)
dataset_dir = os.path.join(dl_dir, "crossvalidation_data")
split_filenames = {
"train": "train.txt",
"validation": "dev.txt",
"test": "test.txt",
}
return [
datasets.SplitGenerator(
name=f"split_{split_num}_{split}",
gen_kwargs={
"filepath": os.path.join(
dataset_dir, f"flairSplit{split_num}", filename
),
"split_id": f"split_{split_num}_{split}",
},
)
for split_num in range(0, 10)
for split, filename in split_filenames.items()
]
def _generate_examples(self, filepath, split_id: str) -> Tuple[int, Dict]:
"""Yields examples as (key, example) tuples."""
with open(filepath, "r") as fp:
guid = 0
tokens = []
ner_tags = []
entity_ids = 0
for line in fp:
if line == "" or line == "\n":
if tokens:
entities = self.iob_tags_to_entities(tokens, ner_tags)
entity_dicts = []
for entity in entities:
entity_text = [str(entity[0])]
entity_offset = [entity[1]]
entity_dict = {
"id": f"{split_id}_{entity_ids}_entity",
"type": "progene_text",
"text": entity_text,
"offsets": entity_offset,
"normalized": [],
}
entity_ids += 1
entity_dicts.append(entity_dict)
if self.config.schema == "source":
yield f"{split_id}_{guid}", {
"id": f"{split_id}_{guid}",
"tokens": tokens,
"tags": ner_tags,
}
elif self.config.schema == "bigbio_kb":
yield f"{split_id}_{guid}", {
"id": f"{split_id}_{guid}",
"document_id": f"{split_id}_{guid}",
"passages": [
{
"id": f"{split_id}_{guid}_passage",
"type": "progene_text",
"text": [" ".join(tokens)],
"offsets": [[0, len(" ".join(tokens))]],
}
],
"entities": entity_dicts,
"events": [],
"coreferences": [],
"relations": [],
}
guid += 1
tokens = []
ner_tags = []
else:
text_tags = line.split("\t")
token = text_tags[0].strip()
ner_tag = text_tags[1].strip()
tokens.append(token)
ner_tags.append(ner_tag)
# residual tokens and tags at the end of the file
entities = self.iob_tags_to_entities(tokens, ner_tags)
entity_dicts = []
for entity in entities:
entity_text = [str(entity[0])]
entity_offset = [entity[1]]
entity_dict = {
"id": f"{split_id}_{entity_ids}_entity",
"type": "progene_text",
"text": entity_text,
"offsets": entity_offset,
"normalized": [],
}
entity_ids += 1
entity_dicts.append(entity_dict)
if self.config.schema == "source":
yield f"{split_id}_{guid}", {
"id": f"{split_id}_{guid}",
"tokens": tokens,
"tags": ner_tags,
}
elif self.config.schema == "bigbio_kb":
yield f"{split_id}_{guid}", {
"id": f"{split_id}_{guid}",
"document_id": f"{split_id}_{guid}",
"passages": [
{
"id": f"{split_id}_{guid}_passage",
"type": "progene_text",
"text": [" ".join(tokens)],
"offsets": [[0, len(" ".join(tokens))]],
}
],
"entities": entity_dicts,
"events": [],
"coreferences": [],
"relations": [],
}
def iob_to_biluo(self, tags: Iterable[str]) -> List[str]:
"""Converts IOB tags to BILUO tags. This is taken from spacy.training.iob_utils"""
out: List[str] = []
tags = list(tags)
while tags:
out.extend(self._consume_os(tags))
out.extend(self._consume_ent(tags))
return out
def _consume_os(self, tags: List[str]) -> Iterator[str]:
while tags and tags[0] == "O":
yield tags.pop(0)
def _consume_ent(self, tags: List[str]) -> List[str]:
if not tags:
return []
tag = tags.pop(0)
target_in = "I" + tag[1:]
target_last = "L" + tag[1:]
length = 1
while tags and tags[0] in {target_in, target_last}:
length += 1
tags.pop(0)
label = tag[2:]
if length == 1:
if len(label) == 0:
raise ValueError("Error parsing iob")
return ["U-" + label]
else:
start = "B-" + label
end = "L-" + label
middle = [f"I-{label}" for _ in range(1, length - 1)]
return [start] + middle + [end]
def tags_to_entities(self, tags: Iterable[str]) -> List[Tuple[str, int, int]]:
"""This has been taken from spacy.training.iob_utils
Note that the end index returned by this function is inclusive.
To use it for Span creation, increment the end by 1."""
entities = []
start = None
for i, tag in enumerate(tags):
if tag is None or tag.startswith("-"):
# TODO: We shouldn't be getting these malformed inputs. Fix this.
if start is not None:
start = None
else:
entities.append(("", i, i))
elif tag.startswith("O"):
pass
elif tag.startswith("I"):
if start is None:
raise ValueError("Error converting tags to entities")
elif tag.startswith("U"):
entities.append((tag[2:], i, i))
elif tag.startswith("B"):
start = i
elif tag.startswith("L"):
if start is None:
raise ValueError("Error converting tags to entities")
entities.append((tag[2:], start, i))
start = None
else:
raise ValueError("Error converting tags to entities")
return entities
def iob_tags_to_entities(self, text: List[str], tags: List[str]):
"""Converts IOB Tags to a set of entities
text: List[str] - A list of tokens
tags: List[str] - A list of corresponding tags
"""
assert len(text) == len(tags)
biluo_tags = self.iob_to_biluo(tags)
entity_offsets = self.tags_to_entities(biluo_tags)
spans = self.get_span_offsets(" ".join(text))
entities = []
text_string = " ".join(text)
for entity, start_word, end_word in entity_offsets:
start_char = spans[start_word][0]
end_char = (
spans[end_word][1] - 1
) # The offsets include the space in the text
entity_text = text_string[start_char:end_char]
entity_offsets = [start_char, end_char]
entities.append((entity_text, entity_offsets))
return entities
def get_span_offsets(self, text):
"""Returns the character offsets for every word in the text.
We assume that every word ends in a space for this function
"""
words = text.split()
len_words = list(map(lambda word: len(word) + 1, words))
offsets = [0] + len_words
offsets = itertools.accumulate(offsets)
offsets = list(offsets)
offsets = list(zip(offsets, offsets[1:]))
return offsets
if __name__ == "__main__":
datasets.load_dataset(__file__, name="progene_bigbio_kb")