python/FunASR-XL.git

			@@ -13,7 +13,6 @@
			SessionOptions, get_available_providers, get_device)
			from typeguard import check_argument_types

			from funasr.runtime.python.onnxruntime.paraformer.rapid_paraformer.kaldifeat import compute_fbank_feats
			import warnings

			root_dir = Path(__file__).resolve().parent
			@@ -120,128 +119,6 @@
			f")"
			)


			class WavFrontend():
			"""Conventional frontend structure for ASR.
			"""

			def __init__(
			self,
			cmvn_file: str = None,
			fs: int = 16000,
			window: str = 'hamming',
			n_mels: int = 80,
			frame_length: int = 25,
			frame_shift: int = 10,
			filter_length_min: int = -1,
			filter_length_max: float = -1,
			lfr_m: int = 1,
			lfr_n: int = 1,
			dither: float = 1.0
			) -> None:
			check_argument_types()

			self.fs = fs
			self.window = window
			self.n_mels = n_mels
			self.frame_length = frame_length
			self.frame_shift = frame_shift
			self.filter_length_min = filter_length_min
			self.filter_length_max = filter_length_max
			self.lfr_m = lfr_m
			self.lfr_n = lfr_n
			self.cmvn_file = cmvn_file
			self.dither = dither

			if self.cmvn_file:
			self.cmvn = self.load_cmvn()

			def fbank(self,
			input_content: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
			waveform_len = input_content.shape[1]
			waveform = input_content[0][:waveform_len]
			waveform = waveform * (1 << 15)
			mat = compute_fbank_feats(waveform,
			num_mel_bins=self.n_mels,
			frame_length=self.frame_length,
			frame_shift=self.frame_shift,
			dither=self.dither,
			energy_floor=0.0,
			sample_frequency=self.fs,
			window_type=self.window)
			feat = mat.astype(np.float32)
			feat_len = np.array(mat.shape[0]).astype(np.int32)
			return feat, feat_len

			def lfr_cmvn(self, feat: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
			if self.lfr_m != 1 or self.lfr_n != 1:
			feat = self.apply_lfr(feat, self.lfr_m, self.lfr_n)

			if self.cmvn_file:
			feat = self.apply_cmvn(feat)

			feat_len = np.array(feat.shape[0]).astype(np.int32)
			return feat, feat_len

			@staticmethod
			def apply_lfr(inputs: np.ndarray, lfr_m: int, lfr_n: int) -> np.ndarray:
			LFR_inputs = []

			T = inputs.shape[0]
			T_lfr = int(np.ceil(T / lfr_n))
			left_padding = np.tile(inputs[0], ((lfr_m - 1) // 2, 1))
			inputs = np.vstack((left_padding, inputs))
			T = T + (lfr_m - 1) // 2
			for i in range(T_lfr):
			if lfr_m <= T - i * lfr_n:
			LFR_inputs.append(
			(inputs[i * lfr_n:i * lfr_n + lfr_m]).reshape(1, -1))
			else:
			# process last LFR frame
			num_padding = lfr_m - (T - i * lfr_n)
			frame = inputs[i * lfr_n:].reshape(-1)
			for _ in range(num_padding):
			frame = np.hstack((frame, inputs[-1]))

			LFR_inputs.append(frame)
			LFR_outputs = np.vstack(LFR_inputs).astype(np.float32)
			return LFR_outputs

			def apply_cmvn(self, inputs: np.ndarray) -> np.ndarray:
			"""
			Apply CMVN with mvn data
			"""
			frame, dim = inputs.shape
			means = np.tile(self.cmvn[0:1, :dim], (frame, 1))
			vars = np.tile(self.cmvn[1:2, :dim], (frame, 1))
			inputs = (inputs + means) * vars
			return inputs

			def load_cmvn(self,) -> np.ndarray:
			with open(self.cmvn_file, 'r', encoding='utf-8') as f:
			lines = f.readlines()

			means_list = []
			vars_list = []
			for i in range(len(lines)):
			line_item = lines[i].split()
			if line_item[0] == '<AddShift>':
			line_item = lines[i + 1].split()
			if line_item[0] == '<LearnRateCoef>':
			add_shift_line = line_item[3:(len(line_item) - 1)]
			means_list = list(add_shift_line)
			continue
			elif line_item[0] == '<Rescale>':
			line_item = lines[i + 1].split()
			if line_item[0] == '<LearnRateCoef>':
			rescale_line = line_item[3:(len(line_item) - 1)]
			vars_list = list(rescale_line)
			continue

			means = np.array(means_list).astype(np.float64)
			vars = np.array(vars_list).astype(np.float64)
			cmvn = np.array([means, vars])
			return cmvn


			class Hypothesis(NamedTuple):