changes in flenema

2493d72 verified almost 2 years ago

14.7 kB

	import librosa
	import soundfile as sf
	import numpy as np
	import scipy.io.wavfile
	import scipy.signal
	# import pyworld as pw

	from TTS.tts.utils.data import StandardScaler

	#pylint: disable=too-many-public-methods
	class AudioProcessor(object):
	def __init__(self,
	sample_rate=None,
	resample=False,
	num_mels=None,
	min_level_db=None,
	frame_shift_ms=None,
	frame_length_ms=None,
	hop_length=None,
	win_length=None,
	ref_level_db=None,
	fft_size=1024,
	power=None,
	preemphasis=0.0,
	signal_norm=None,
	symmetric_norm=None,
	max_norm=None,
	mel_fmin=None,
	mel_fmax=None,
	spec_gain=20,
	stft_pad_mode='reflect',
	clip_norm=True,
	griffin_lim_iters=None,
	do_trim_silence=False,
	trim_db=60,
	do_sound_norm=False,
	stats_path=None,
	verbose=True,
	**_):

	# setup class attributed
	self.sample_rate = sample_rate
	self.resample = resample
	self.num_mels = num_mels
	self.min_level_db = min_level_db or 0
	self.frame_shift_ms = frame_shift_ms
	self.frame_length_ms = frame_length_ms
	self.ref_level_db = ref_level_db
	self.fft_size = fft_size
	self.power = power
	self.preemphasis = preemphasis
	self.griffin_lim_iters = griffin_lim_iters
	self.signal_norm = signal_norm
	self.symmetric_norm = symmetric_norm
	self.mel_fmin = mel_fmin or 0
	self.mel_fmax = mel_fmax
	self.spec_gain = float(spec_gain)
	self.stft_pad_mode = stft_pad_mode
	self.max_norm = 1.0 if max_norm is None else float(max_norm)
	self.clip_norm = clip_norm
	self.do_trim_silence = do_trim_silence
	self.trim_db = trim_db
	self.do_sound_norm = do_sound_norm
	self.stats_path = stats_path
	# setup stft parameters
	if hop_length is None:
	# compute stft parameters from given time values
	self.hop_length, self.win_length = self._stft_parameters()
	else:
	# use stft parameters from config file
	self.hop_length = hop_length
	self.win_length = win_length
	assert min_level_db != 0.0, " [!] min_level_db is 0"
	assert self.win_length <= self.fft_size, " [!] win_length cannot be larger than fft_size"
	members = vars(self)
	if verbose:
	print(" > Setting up Audio Processor...")
	for key, value in members.items():
	print(" \| > {}:{}".format(key, value))
	# create spectrogram utils
	self.mel_basis = self._build_mel_basis()
	self.inv_mel_basis = np.linalg.pinv(self._build_mel_basis())
	# setup scaler
	if stats_path:
	mel_mean, mel_std, linear_mean, linear_std, _ = self.load_stats(stats_path)
	self.setup_scaler(mel_mean, mel_std, linear_mean, linear_std)
	self.signal_norm = True
	self.max_norm = None
	self.clip_norm = None
	self.symmetric_norm = None

	### setting up the parameters ###
	def _build_mel_basis(self, ):
	if self.mel_fmax is not None:
	assert self.mel_fmax <= self.sample_rate // 2
	return librosa.filters.mel(
	self.sample_rate,
	self.fft_size,
	n_mels=self.num_mels,
	fmin=self.mel_fmin,
	fmax=self.mel_fmax)

	def _stft_parameters(self, ):
	"""Compute necessary stft parameters with given time values"""
	factor = self.frame_length_ms / self.frame_shift_ms
	assert (factor).is_integer(), " [!] frame_shift_ms should divide frame_length_ms"
	hop_length = int(self.frame_shift_ms / 1000.0 * self.sample_rate)
	win_length = int(hop_length * factor)
	return hop_length, win_length

	### normalization ###
	def normalize(self, S):
	"""Put values in [0, self.max_norm] or [-self.max_norm, self.max_norm]"""
	#pylint: disable=no-else-return
	S = S.copy()
	if self.signal_norm:
	# mean-var scaling
	if hasattr(self, 'mel_scaler'):
	if S.shape[0] == self.num_mels:
	return self.mel_scaler.transform(S.T).T
	elif S.shape[0] == self.fft_size / 2:
	return self.linear_scaler.transform(S.T).T
	else:
	raise RuntimeError(' [!] Mean-Var stats does not match the given feature dimensions.')
	# range normalization
	S -= self.ref_level_db # discard certain range of DB assuming it is air noise
	S_norm = ((S - self.min_level_db) / (-self.min_level_db))
	if self.symmetric_norm:
	S_norm = ((2 * self.max_norm) * S_norm) - self.max_norm
	if self.clip_norm:
	S_norm = np.clip(S_norm, -self.max_norm, self.max_norm) # pylint: disable=invalid-unary-operand-type
	return S_norm
	else:
	S_norm = self.max_norm * S_norm
	if self.clip_norm:
	S_norm = np.clip(S_norm, 0, self.max_norm)
	return S_norm
	else:
	return S

	def denormalize(self, S):
	"""denormalize values"""
	#pylint: disable=no-else-return
	S_denorm = S.copy()
	if self.signal_norm:
	# mean-var scaling
	if hasattr(self, 'mel_scaler'):
	if S_denorm.shape[0] == self.num_mels:
	return self.mel_scaler.inverse_transform(S_denorm.T).T
	elif S_denorm.shape[0] == self.fft_size / 2:
	return self.linear_scaler.inverse_transform(S_denorm.T).T
	else:
	raise RuntimeError(' [!] Mean-Var stats does not match the given feature dimensions.')
	if self.symmetric_norm:
	if self.clip_norm:
	S_denorm = np.clip(S_denorm, -self.max_norm, self.max_norm) #pylint: disable=invalid-unary-operand-type
	S_denorm = ((S_denorm + self.max_norm) * -self.min_level_db / (2 * self.max_norm)) + self.min_level_db
	return S_denorm + self.ref_level_db
	else:
	if self.clip_norm:
	S_denorm = np.clip(S_denorm, 0, self.max_norm)
	S_denorm = (S_denorm * -self.min_level_db /
	self.max_norm) + self.min_level_db
	return S_denorm + self.ref_level_db
	else:
	return S_denorm

	### Mean-STD scaling ###
	def load_stats(self, stats_path):
	stats = np.load(stats_path, allow_pickle=True).item() #pylint: disable=unexpected-keyword-arg
	mel_mean = stats['mel_mean']
	mel_std = stats['mel_std']
	linear_mean = stats['linear_mean']
	linear_std = stats['linear_std']
	stats_config = stats['audio_config']
	# check all audio parameters used for computing stats
	skip_parameters = ['griffin_lim_iters', 'stats_path', 'do_trim_silence', 'ref_level_db', 'power']
	for key in stats_config.keys():
	if key in skip_parameters:
	continue
	if key not in ['sample_rate', 'trim_db']:
	assert stats_config[key] == self.__dict__[key],\
	f" [!] Audio param {key} does not match the value used for computing mean-var stats. {stats_config[key]} vs {self.__dict__[key]}"
	return mel_mean, mel_std, linear_mean, linear_std, stats_config

	# pylint: disable=attribute-defined-outside-init
	def setup_scaler(self, mel_mean, mel_std, linear_mean, linear_std):
	self.mel_scaler = StandardScaler()
	self.mel_scaler.set_stats(mel_mean, mel_std)
	self.linear_scaler = StandardScaler()
	self.linear_scaler.set_stats(linear_mean, linear_std)

	### DB and AMP conversion ###
	# pylint: disable=no-self-use
	def _amp_to_db(self, x):
	return self.spec_gain * np.log10(np.maximum(1e-5, x))

	# pylint: disable=no-self-use
	def _db_to_amp(self, x):
	return np.power(10.0, x / self.spec_gain)

	### Preemphasis ###
	def apply_preemphasis(self, x):
	if self.preemphasis == 0:
	raise RuntimeError(" [!] Preemphasis is set 0.0.")
	return scipy.signal.lfilter([1, -self.preemphasis], [1], x)

	def apply_inv_preemphasis(self, x):
	if self.preemphasis == 0:
	raise RuntimeError(" [!] Preemphasis is set 0.0.")
	return scipy.signal.lfilter([1], [1, -self.preemphasis], x)

	### SPECTROGRAMs ###
	def _linear_to_mel(self, spectrogram):
	return np.dot(self.mel_basis, spectrogram)

	def _mel_to_linear(self, mel_spec):
	return np.maximum(1e-10, np.dot(self.inv_mel_basis, mel_spec))

	def spectrogram(self, y):
	if self.preemphasis != 0:
	D = self._stft(self.apply_preemphasis(y))
	else:
	D = self._stft(y)
	S = self._amp_to_db(np.abs(D))
	return self.normalize(S)

	def melspectrogram(self, y):
	if self.preemphasis != 0:
	D = self._stft(self.apply_preemphasis(y))
	else:
	D = self._stft(y)
	S = self._amp_to_db(self._linear_to_mel(np.abs(D)))
	return self.normalize(S)

	def inv_spectrogram(self, spectrogram):
	"""Converts spectrogram to waveform using librosa"""
	S = self.denormalize(spectrogram)
	S = self._db_to_amp(S)
	# Reconstruct phase
	if self.preemphasis != 0:
	return self.apply_inv_preemphasis(self._griffin_lim(S**self.power))
	return self._griffin_lim(S**self.power)

	def inv_melspectrogram(self, mel_spectrogram):
	'''Converts melspectrogram to waveform using librosa'''
	D = self.denormalize(mel_spectrogram)
	S = self._db_to_amp(D)
	S = self._mel_to_linear(S) # Convert back to linear
	if self.preemphasis != 0:
	return self.apply_inv_preemphasis(self._griffin_lim(S**self.power))
	return self._griffin_lim(S**self.power)

	def out_linear_to_mel(self, linear_spec):
	S = self.denormalize(linear_spec)
	S = self._db_to_amp(S)
	S = self._linear_to_mel(np.abs(S))
	S = self._amp_to_db(S)
	mel = self.normalize(S)
	return mel

	### STFT and ISTFT ###
	def _stft(self, y):
	return librosa.stft(
	y=y,
	n_fft=self.fft_size,
	hop_length=self.hop_length,
	win_length=self.win_length,
	pad_mode=self.stft_pad_mode,
	)

	def _istft(self, y):
	return librosa.istft(
	y, hop_length=self.hop_length, win_length=self.win_length)

	def _griffin_lim(self, S):
	angles = np.exp(2j * np.pi * np.random.rand(*S.shape))
	S_complex = np.abs(S).astype(np.complex)
	y = self._istft(S_complex * angles)
	for _ in range(self.griffin_lim_iters):
	angles = np.exp(1j * np.angle(self._stft(y)))
	y = self._istft(S_complex * angles)
	return y

	def compute_stft_paddings(self, x, pad_sides=1):
	'''compute right padding (final frame) or both sides padding (first and final frames)
	'''
	assert pad_sides in (1, 2)
	pad = (x.shape[0] // self.hop_length + 1) * self.hop_length - x.shape[0]
	if pad_sides == 1:
	return 0, pad
	return pad // 2, pad // 2 + pad % 2

	### Compute F0 ###
	# def compute_f0(self, x):
	# f0, t = pw.dio(
	# x.astype(np.double),
	# fs=self.sample_rate,
	# f0_ceil=self.mel_fmax,
	# frame_period=1000 * self.hop_length / self.sample_rate,
	# )
	# f0 = pw.stonemask(x.astype(np.double), f0, t, self.sample_rate)
	# return f0

	### Audio Processing ###
	def find_endpoint(self, wav, threshold_db=-40, min_silence_sec=0.8):
	window_length = int(self.sample_rate * min_silence_sec)
	hop_length = int(window_length / 4)
	threshold = self._db_to_amp(threshold_db)
	for x in range(hop_length, len(wav) - window_length, hop_length):
	if np.max(wav[x:x + window_length]) < threshold:
	return x + hop_length
	return len(wav)

	def trim_silence(self, wav):
	""" Trim silent parts with a threshold and 0.01 sec margin """
	margin = int(self.sample_rate * 0.01)
	wav = wav[margin:-margin]
	return librosa.effects.trim(
	wav, top_db=self.trim_db, frame_length=self.win_length, hop_length=self.hop_length)[0]

	@staticmethod
	def sound_norm(x):
	return x / abs(x).max() * 0.9

	### save and load ###
	def load_wav(self, filename, sr=None):
	if self.resample:
	x, sr = librosa.load(filename, sr=self.sample_rate)
	elif sr is None:
	x, sr = sf.read(filename)
	assert self.sample_rate == sr, "%s vs %s"%(self.sample_rate, sr)
	else:
	x, sr = librosa.load(filename, sr=sr)
	if self.do_trim_silence:
	try:
	x = self.trim_silence(x)
	except ValueError:
	print(f' [!] File cannot be trimmed for silence - {filename}')
	if self.do_sound_norm:
	x = self.sound_norm(x)
	return x

	def save_wav(self, wav, path):
	wav_norm = wav * (32767 / max(0.01, np.max(np.abs(wav))))
	scipy.io.wavfile.write(path, self.sample_rate, wav_norm.astype(np.int16))

	@staticmethod
	def mulaw_encode(wav, qc):
	mu = 2 ** qc - 1
	# wav_abs = np.minimum(np.abs(wav), 1.0)
	signal = np.sign(wav) * np.log(1 + mu * np.abs(wav)) / np.log(1. + mu)
	# Quantize signal to the specified number of levels.
	signal = (signal + 1) / 2 * mu + 0.5
	return np.floor(signal,)

	@staticmethod
	def mulaw_decode(wav, qc):
	"""Recovers waveform from quantized values."""
	mu = 2 ** qc - 1
	x = np.sign(wav) / mu * ((1 + mu) ** np.abs(wav) - 1)
	return x


	@staticmethod
	def encode_16bits(x):
	return np.clip(x * 215, -215, 2**15 - 1).astype(np.int16)

	@staticmethod
	def quantize(x, bits):
	return (x + 1.) * (2**bits - 1) / 2

	@staticmethod
	def dequantize(x, bits):
	return 2 * x / (2**bits - 1) - 1