Datasets:

s3prl
/

superb

	# coding=utf-8
	# Copyright 2021 The TensorFlow Datasets Authors and the HuggingFace Datasets Authors.
	#
	# 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.

	# Lint as: python3
	"""SUPERB: Speech processing Universal PERformance Benchmark."""


	import glob
	import os
	import textwrap
	from dataclasses import dataclass

	import datasets
	from datasets.tasks import AutomaticSpeechRecognition


	_CITATION = """\
	@article{DBLP:journals/corr/abs-2105-01051,
	author = {Shu{-}Wen Yang and
	Po{-}Han Chi and
	Yung{-}Sung Chuang and
	Cheng{-}I Jeff Lai and
	Kushal Lakhotia and
	Yist Y. Lin and
	Andy T. Liu and
	Jiatong Shi and
	Xuankai Chang and
	Guan{-}Ting Lin and
	Tzu{-}Hsien Huang and
	Wei{-}Cheng Tseng and
	Ko{-}tik Lee and
	Da{-}Rong Liu and
	Zili Huang and
	Shuyan Dong and
	Shang{-}Wen Li and
	Shinji Watanabe and
	Abdelrahman Mohamed and
	Hung{-}yi Lee},
	title = {{SUPERB:} Speech processing Universal PERformance Benchmark},
	journal = {CoRR},
	volume = {abs/2105.01051},
	year = {2021},
	url = {https://arxiv.org/abs/2105.01051},
	archivePrefix = {arXiv},
	eprint = {2105.01051},
	timestamp = {Thu, 01 Jul 2021 13:30:22 +0200},
	biburl = {https://dblp.org/rec/journals/corr/abs-2105-01051.bib},
	bibsource = {dblp computer science bibliography, https://dblp.org}
	}
	"""

	_DESCRIPTION = """\
	Self-supervised learning (SSL) has proven vital for advancing research in
	natural language processing (NLP) and computer vision (CV). The paradigm
	pretrains a shared model on large volumes of unlabeled data and achieves
	state-of-the-art (SOTA) for various tasks with minimal adaptation. However, the
	speech processing community lacks a similar setup to systematically explore the
	paradigm. To bridge this gap, we introduce Speech processing Universal
	PERformance Benchmark (SUPERB). SUPERB is a leaderboard to benchmark the
	performance of a shared model across a wide range of speech processing tasks
	with minimal architecture changes and labeled data. Among multiple usages of the
	shared model, we especially focus on extracting the representation learned from
	SSL due to its preferable re-usability. We present a simple framework to solve
	SUPERB tasks by learning task-specialized lightweight prediction heads on top of
	the frozen shared model. Our results demonstrate that the framework is promising
	as SSL representations show competitive generalizability and accessibility
	across SUPERB tasks. We release SUPERB as a challenge with a leaderboard and a
	benchmark toolkit to fuel the research in representation learning and general
	speech processing.

	Note that in order to limit the required storage for preparing this dataset, the
	audio is stored in the .flac format and is not converted to a float32 array. To
	convert, the audio file to a float32 array, please make use of the `.map()`
	function as follows:


	```python
	import soundfile as sf

	def map_to_array(batch):
	speech_array, _ = sf.read(batch["file"])
	batch["speech"] = speech_array
	return batch

	dataset = dataset.map(map_to_array, remove_columns=["file"])
	```
	"""


	class SuperbConfig(datasets.BuilderConfig):
	"""BuilderConfig for Superb."""

	def __init__(
	self,
	features,
	data_url,
	url,
	supervised_keys=None,
	task_templates=None,
	**kwargs,
	):
	super().__init__(version=datasets.Version("1.9.0", ""), **kwargs)
	self.features = features
	self.data_url = data_url
	self.url = url
	self.supervised_keys = supervised_keys
	self.task_templates = task_templates


	class Superb(datasets.GeneratorBasedBuilder):
	"""Superb dataset."""

	BUILDER_CONFIGS = [
	SuperbConfig(
	name="asr",
	description=textwrap.dedent(
	"""\
	ASR transcribes utterances into words. While PR analyzes the
	improvement in modeling phonetics, ASR reflects the significance of
	the improvement in a real-world scenario. LibriSpeech
	train-clean-100/dev-clean/test-clean subsets are used for
	training/validation/testing. The evaluation metric is word error
	rate (WER)."""
	),
	features=datasets.Features(
	{
	"file": datasets.Value("string"),
	"text": datasets.Value("string"),
	"speaker_id": datasets.Value("int64"),
	"chapter_id": datasets.Value("int64"),
	"id": datasets.Value("string"),
	}
	),
	supervised_keys=("file", "text"),
	url="http://www.openslr.org/12",
	data_url="http://www.openslr.org/resources/12/",
	task_templates=[AutomaticSpeechRecognition(audio_file_path_column="file", transcription_column="text")],
	),
	SuperbConfig(
	name="ks",
	description=textwrap.dedent(
	"""\
	Keyword Spotting (KS) detects preregistered keywords by classifying utterances into a predefined set of
	words. The task is usually performed on-device for the fast response time. Thus, accuracy, model size, and
	inference time are all crucial. SUPERB uses the widely used [Speech Commands dataset v1.0] for the task.
	The dataset consists of ten classes of keywords, a class for silence, and an unknown class to include the
	false positive. The evaluation metric is accuracy (ACC)"""
	),
	features=datasets.Features(
	{
	"file": datasets.Value("string"),
	"label": datasets.ClassLabel(
	names=[
	"yes",
	"no",
	"up",
	"down",
	"left",
	"right",
	"on",
	"off",
	"stop",
	"go",
	"_silence_",
	"_unknown_",
	]
	),
	}
	),
	supervised_keys=("file", "label"),
	url="https://www.tensorflow.org/datasets/catalog/speech_commands",
	data_url="http://download.tensorflow.org/data/{filename}",
	),
	SuperbConfig(
	name="sd",
	description=textwrap.dedent(
	"""\
	Speaker Diarization (SD) predicts `who is speaking when` for each timestamp, and multiple speakers can
	speak simultaneously. The model has to encode rich speaker characteristics for each frame and should be
	able to represent mixtures of signals. [LibriMix] is adopted where LibriSpeech
	train-clean-100/dev-clean/test-clean are used to generate mixtures for training/validation/testing.
	We focus on the two-speaker scenario as the first step. The time-coded speaker labels were generated using
	alignments from Kaldi LibriSpeech ASR model. The evaluation metric is diarization error rate (DER)."""
	),
	features=datasets.Features(
	{
	"record_id": datasets.Value("string"),
	"file": datasets.Value("string"),
	"start": datasets.Value("int64"),
	"end": datasets.Value("int64"),
	"speakers": [
	{
	"speaker_id": datasets.Value("string"),
	"start": datasets.Value("int64"),
	"end": datasets.Value("int64"),
	}
	],
	}
	), # TODO
	supervised_keys=None, # TODO
	url="https://github.com/ftshijt/LibriMix",
	data_url="https://huggingface.co/datasets/superb/superb-data/resolve/main/sd/{split}/{filename}",
	),
	]

	def _info(self):
	return datasets.DatasetInfo(
	description=_DESCRIPTION,
	features=self.config.features,
	supervised_keys=self.config.supervised_keys,
	homepage=self.config.url,
	citation=_CITATION,
	task_templates=self.config.task_templates,
	)

	def _split_generators(self, dl_manager):
	if self.config.name == "asr":
	_DL_URLS = {
	"dev": self.config.data_url + "dev-clean.tar.gz",
	"test": self.config.data_url + "test-clean.tar.gz",
	"train": self.config.data_url + "train-clean-100.tar.gz",
	}
	archive_path = dl_manager.download_and_extract(_DL_URLS)

	return [
	datasets.SplitGenerator(name=datasets.Split.TRAIN, gen_kwargs={"archive_path": archive_path["train"]}),
	datasets.SplitGenerator(
	name=datasets.Split.VALIDATION, gen_kwargs={"archive_path": archive_path["dev"]}
	),
	datasets.SplitGenerator(name=datasets.Split.TEST, gen_kwargs={"archive_path": archive_path["test"]}),
	]
	elif self.config.name == "ks":
	_DL_URLS = {
	"train_val_test": self.config.data_url.format(filename="speech_commands_v0.01.tar.gz"),
	"test": self.config.data_url.format(filename="speech_commands_test_set_v0.01.tar.gz"),
	}
	archive_path = dl_manager.download_and_extract(_DL_URLS)
	return [
	datasets.SplitGenerator(
	name=datasets.Split.TRAIN,
	gen_kwargs={"archive_path": archive_path["train_val_test"], "split": "train"},
	),
	datasets.SplitGenerator(
	name=datasets.Split.VALIDATION,
	gen_kwargs={"archive_path": archive_path["train_val_test"], "split": "val"},
	),
	datasets.SplitGenerator(
	name=datasets.Split.TEST, gen_kwargs={"archive_path": archive_path["test"], "split": "test"}
	),
	]
	elif self.config.name == "sd":
	splits = ["train", "dev", "test"]
	_DL_URLS = {
	split: {
	filename: self.config.data_url.format(split=split, filename=filename)
	for filename in ["reco2dur", "segments", "utt2spk", "wav.zip"]
	}
	for split in splits
	}
	archive_path = dl_manager.download_and_extract(_DL_URLS)
	return [
	datasets.SplitGenerator(
	name=datasets.NamedSplit(split), gen_kwargs={"archive_path": archive_path[split], "split": split}
	)
	for split in splits
	]

	def _generate_examples(self, archive_path, split=None):
	"""Generate examples."""
	if self.config.name == "asr":
	transcripts_glob = os.path.join(archive_path, "LibriSpeech", "///.txt")
	key = 0
	for transcript_path in sorted(glob.glob(transcripts_glob)):
	transcript_dir_path = os.path.dirname(transcript_path)
	with open(transcript_path, "r", encoding="utf-8") as f:
	for line in f:
	line = line.strip()
	id_, transcript = line.split(" ", 1)
	audio_file = f"{id_}.flac"
	speaker_id, chapter_id = [int(el) for el in id_.split("-")[:2]]
	yield key, {
	"id": id_,
	"speaker_id": speaker_id,
	"chapter_id": chapter_id,
	"file": os.path.join(transcript_dir_path, audio_file),
	"text": transcript,
	}
	key += 1
	elif self.config.name == "ks":
	words = ["yes", "no", "up", "down", "left", "right", "on", "off", "stop", "go"]
	splits = _split_ks_files(archive_path, split)
	for key, audio_file in enumerate(sorted(splits[split])):
	base_dir, file_name = os.path.split(audio_file)
	_, word = os.path.split(base_dir)
	if word in words:
	label = word
	elif word == "_silence_" or word == "_background_noise_":
	label = "_silence_"
	else:
	label = "_unknown_"
	yield key, {"file": audio_file, "label": label}
	elif self.config.name == "sd":
	data = SdData(archive_path)
	args = SdArgs()
	chunk_indices = _generate_chunk_indices(data, args, split=split)
	if split != "test":
	for key, (rec, st, ed) in enumerate(chunk_indices):
	speakers = _get_speakers(rec, data, args)
	yield key, {
	"record_id": rec,
	"file": data.wavs[rec],
	"start": st,
	"end": ed,
	"speakers": speakers,
	}
	else:
	key = 0
	for rec in chunk_indices:
	for rec, st, ed in chunk_indices[rec]:
	speakers = _get_speakers(rec, data, args)
	yield key, {
	"record_id": rec,
	"file": data.wavs[rec],
	"start": st,
	"end": ed,
	"speakers": speakers,
	}
	key += 1


	class SdData:
	def __init__(self, data_dir):
	"""Load sd data."""
	self.segments = self._load_segments_rechash(data_dir["segments"])
	self.utt2spk = self._load_utt2spk(data_dir["utt2spk"])
	self.wavs = self._load_wav_zip(data_dir["wav.zip"])
	self.reco2dur = self._load_reco2dur(data_dir["reco2dur"])

	def _load_segments_rechash(self, segments_file):
	"""Load segments file as dict with recid index."""
	ret = {}
	if not os.path.exists(segments_file):
	return None
	with open(segments_file, encoding="utf-8") as f:
	for line in f:
	utt, rec, st, et = line.strip().split()
	if rec not in ret:
	ret[rec] = []
	ret[rec].append({"utt": utt, "st": float(st), "et": float(et)})
	return ret

	def _load_wav_zip(self, wav_zip):
	"""Return dictionary { rec: wav_rxfilename }."""
	wav_dir = os.path.join(wav_zip, "wav")
	return {
	os.path.splitext(filename)[0]: os.path.join(wav_dir, filename) for filename in sorted(os.listdir(wav_dir))
	}

	def _load_utt2spk(self, utt2spk_file):
	"""Returns dictionary { uttid: spkid }."""
	with open(utt2spk_file, encoding="utf-8") as f:
	lines = [line.strip().split(None, 1) for line in f]
	return {x[0]: x[1] for x in lines}

	def _load_reco2dur(self, reco2dur_file):
	"""Returns dictionary { recid: duration }."""
	if not os.path.exists(reco2dur_file):
	return None
	with open(reco2dur_file, encoding="utf-8") as f:
	lines = [line.strip().split(None, 1) for line in f]
	return {x[0]: float(x[1]) for x in lines}


	@dataclass
	class SdArgs:
	chunk_size: int = 2000
	frame_shift: int = 160
	subsampling: int = 1
	label_delay: int = 0
	num_speakers: int = 2
	rate: int = 16000
	use_last_samples: bool = True


	def _generate_chunk_indices(data, args, split=None):
	chunk_indices = [] if split != "test" else {}
	# make chunk indices: filepath, start_frame, end_frame
	for rec in data.wavs:
	data_len = int(data.reco2dur[rec] * args.rate / args.frame_shift)
	data_len = int(data_len / args.subsampling)
	if split == "test":
	chunk_indices[rec] = []
	if split != "test":
	for st, ed in _gen_frame_indices(
	data_len,
	args.chunk_size,
	args.chunk_size,
	args.use_last_samples,
	label_delay=args.label_delay,
	subsampling=args.subsampling,
	):
	chunk_indices.append((rec, st * args.subsampling, ed * args.subsampling))
	else:
	for st, ed in _gen_chunk_indices(data_len, args.chunk_size):
	chunk_indices[rec].append((rec, st * args.subsampling, ed * args.subsampling))
	return chunk_indices


	def _count_frames(data_len, size, step):
	# no padding at edges, last remaining samples are ignored
	return int((data_len - size + step) / step)


	def _gen_frame_indices(data_length, size=2000, step=2000, use_last_samples=False, label_delay=0, subsampling=1):
	i = -1
	for i in range(_count_frames(data_length, size, step)):
	yield i * step, i * step + size
	if use_last_samples and i * step + size < data_length:
	if data_length - (i + 1) * step - subsampling * label_delay > 0:
	yield (i + 1) * step, data_length


	def _gen_chunk_indices(data_len, chunk_size):
	step = chunk_size
	start = 0
	while start < data_len:
	end = min(data_len, start + chunk_size)
	yield start, end
	start += step


	def _get_speakers(rec, data, args):
	return [
	{
	"speaker_id": data.utt2spk[segment["utt"]],
	"start": round(segment["st"] * args.rate / args.frame_shift),
	"end": round(segment["et"] * args.rate / args.frame_shift),
	}
	for segment in data.segments[rec]
	]


	def _split_ks_files(archive_path, split):
	audio_path = os.path.join(archive_path, "*/.wav")
	audio_paths = glob.glob(audio_path)
	if split == "test":
	# use all available files for the test archive
	return {"test": audio_paths}

	val_list_file = os.path.join(archive_path, "validation_list.txt")
	test_list_file = os.path.join(archive_path, "testing_list.txt")
	with open(val_list_file, encoding="utf-8") as f:
	val_paths = f.read().strip().splitlines()
	val_paths = [os.path.join(archive_path, p) for p in val_paths]
	with open(test_list_file, encoding="utf-8") as f:
	test_paths = f.read().strip().splitlines()
	test_paths = [os.path.join(archive_path, p) for p in test_paths]

	# the paths for the train set is just whichever paths that do not exist in
	# either the test or validation splits
	train_paths = list(set(audio_paths) - set(val_paths) - set(test_paths))

	return {"train": train_paths, "val": val_paths}