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SpeechCloningTest / Preprocessing /AudioPreprocessor.py

eriquesouza

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	import librosa
	import librosa.core as lb
	import librosa.display as lbd
	import matplotlib.pyplot as plt
	import numpy
	import numpy as np
	import pyloudnorm as pyln
	import torch
	from torchaudio.transforms import Resample


	class AudioPreprocessor:

	def __init__(self, input_sr, output_sr=None, melspec_buckets=80, hop_length=256, n_fft=1024, cut_silence=False, device="cpu"):
	"""
	The parameters are by default set up to do well
	on a 16kHz signal. A different sampling rate may
	require different hop_length and n_fft (e.g.
	doubling frequency --> doubling hop_length and
	doubling n_fft)
	"""
	self.cut_silence = cut_silence
	self.device = device
	self.sr = input_sr
	self.new_sr = output_sr
	self.hop_length = hop_length
	self.n_fft = n_fft
	self.mel_buckets = melspec_buckets
	self.meter = pyln.Meter(input_sr)
	self.final_sr = input_sr
	if cut_silence:
	torch.hub._validate_not_a_forked_repo = lambda a, b, c: True # torch 1.9 has a bug in the hub loading, this is a workaround
	# careful: assumes 16kHz or 8kHz audio
	self.silero_model, utils = torch.hub.load(repo_or_dir='snakers4/silero-vad',
	model='silero_vad',
	force_reload=False,
	onnx=False,
	verbose=False)
	(self.get_speech_timestamps,
	self.save_audio,
	self.read_audio,
	self.VADIterator,
	self.collect_chunks) = utils
	self.silero_model = self.silero_model.to(self.device)
	if output_sr is not None and output_sr != input_sr:
	self.resample = Resample(orig_freq=input_sr, new_freq=output_sr).to(self.device)
	self.final_sr = output_sr
	else:
	self.resample = lambda x: x

	def cut_silence_from_audio(self, audio):
	"""
	https://github.com/snakers4/silero-vad
	"""
	return self.collect_chunks(self.get_speech_timestamps(audio, self.silero_model, sampling_rate=self.final_sr), audio)

	def to_mono(self, x):
	"""
	make sure we deal with a 1D array
	"""
	if len(x.shape) == 2:
	return lb.to_mono(numpy.transpose(x))
	else:
	return x

	def normalize_loudness(self, audio):
	"""
	normalize the amplitudes according to
	their decibels, so this should turn any
	signal with different magnitudes into
	the same magnitude by analysing loudness
	"""
	loudness = self.meter.integrated_loudness(audio)
	loud_normed = pyln.normalize.loudness(audio, loudness, -30.0)
	peak = numpy.amax(numpy.abs(loud_normed))
	peak_normed = numpy.divide(loud_normed, peak)
	return peak_normed

	def logmelfilterbank(self, audio, sampling_rate, fmin=40, fmax=8000, eps=1e-10):
	"""
	Compute log-Mel filterbank

	one day this could be replaced by torchaudio's internal log10(melspec(audio)), but
	for some reason it gives slightly different results, so in order not to break backwards
	compatibility, this is kept for now. If there is ever a reason to completely re-train
	all models, this would be a good opportunity to make the switch.
	"""
	if isinstance(audio, torch.Tensor):
	audio = audio.numpy()
	# get amplitude spectrogram
	x_stft = librosa.stft(audio, n_fft=self.n_fft, hop_length=self.hop_length, win_length=None, window="hann", pad_mode="reflect")
	spc = np.abs(x_stft).T
	# get mel basis
	fmin = 0 if fmin is None else fmin
	fmax = sampling_rate / 2 if fmax is None else fmax
	mel_basis = librosa.filters.mel(sampling_rate, self.n_fft, self.mel_buckets, fmin, fmax)
	# apply log and return
	return torch.Tensor(np.log10(np.maximum(eps, np.dot(spc, mel_basis.T)))).transpose(0, 1)

	def normalize_audio(self, audio):
	"""
	one function to apply them all in an
	order that makes sense.
	"""
	audio = self.to_mono(audio)
	audio = self.normalize_loudness(audio)
	audio = torch.Tensor(audio).to(self.device)
	audio = self.resample(audio)
	if self.cut_silence:
	audio = self.cut_silence_from_audio(audio)
	return audio.to("cpu")

	def visualize_cleaning(self, unclean_audio):
	"""
	displays Mel Spectrogram of unclean audio
	and then displays Mel Spectrogram of the
	cleaned version.
	"""
	fig, ax = plt.subplots(nrows=2, ncols=1)
	unclean_audio_mono = self.to_mono(unclean_audio)
	unclean_spec = self.audio_to_mel_spec_tensor(unclean_audio_mono, normalize=False).numpy()
	clean_spec = self.audio_to_mel_spec_tensor(unclean_audio_mono, normalize=True).numpy()
	lbd.specshow(unclean_spec, sr=self.sr, cmap='GnBu', y_axis='mel', ax=ax[0], x_axis='time')
	ax[0].set(title='Uncleaned Audio')
	ax[0].label_outer()
	if self.new_sr is not None:
	lbd.specshow(clean_spec, sr=self.new_sr, cmap='GnBu', y_axis='mel', ax=ax[1], x_axis='time')
	else:
	lbd.specshow(clean_spec, sr=self.sr, cmap='GnBu', y_axis='mel', ax=ax[1], x_axis='time')
	ax[1].set(title='Cleaned Audio')
	ax[1].label_outer()
	plt.show()

	def audio_to_wave_tensor(self, audio, normalize=True):
	if normalize:
	return self.normalize_audio(audio)
	else:
	if isinstance(audio, torch.Tensor):
	return audio
	else:
	return torch.Tensor(audio)

	def audio_to_mel_spec_tensor(self, audio, normalize=True, explicit_sampling_rate=None):
	"""
	explicit_sampling_rate is for when
	normalization has already been applied
	and that included resampling. No way
	to detect the current sr of the incoming
	audio
	"""
	if explicit_sampling_rate is None:
	if normalize:
	audio = self.normalize_audio(audio)
	return self.logmelfilterbank(audio=audio, sampling_rate=self.final_sr)
	return self.logmelfilterbank(audio=audio, sampling_rate=self.sr)
	if normalize:
	audio = self.normalize_audio(audio)
	return self.logmelfilterbank(audio=audio, sampling_rate=explicit_sampling_rate)


	if __name__ == '__main__':
	import soundfile

	wav, sr = soundfile.read("../audios/test.wav")
	ap = AudioPreprocessor(input_sr=sr, output_sr=16000)
	ap.visualize_cleaning(wav)