# Copyright 2019 Hitachi, Ltd. (author: Yusuke Fujita) # Licensed under the MIT license. # # This module is for computing audio features import numpy as np import librosa def get_input_dim( frame_size, context_size, transform_type, ): if transform_type.startswith("logmel23"): frame_size = 23 elif transform_type.startswith("logmel"): frame_size = 40 else: fft_size = 1 << (frame_size - 1).bit_length() frame_size = int(fft_size / 2) + 1 input_dim = (2 * context_size + 1) * frame_size return input_dim def transform(Y, transform_type=None, dtype=np.float32): """Transform STFT feature Args: Y: STFT (n_frames, n_bins)-shaped np.complex array transform_type: None, "log" dtype: output data type np.float32 is expected Returns: Y (numpy.array): transformed feature """ Y = np.abs(Y) if not transform_type: pass elif transform_type == "log": Y = np.log(np.maximum(Y, 1e-10)) elif transform_type == "logmel": n_fft = 2 * (Y.shape[1] - 1) sr = 16000 n_mels = 40 mel_basis = librosa.filters.mel(sr, n_fft, n_mels) Y = np.dot(Y**2, mel_basis.T) Y = np.log10(np.maximum(Y, 1e-10)) elif transform_type == "logmel23": n_fft = 2 * (Y.shape[1] - 1) sr = 8000 n_mels = 23 mel_basis = librosa.filters.mel(sr, n_fft, n_mels) Y = np.dot(Y**2, mel_basis.T) Y = np.log10(np.maximum(Y, 1e-10)) elif transform_type == "logmel23_mn": n_fft = 2 * (Y.shape[1] - 1) sr = 8000 n_mels = 23 mel_basis = librosa.filters.mel(sr, n_fft, n_mels) Y = np.dot(Y**2, mel_basis.T) Y = np.log10(np.maximum(Y, 1e-10)) mean = np.mean(Y, axis=0) Y = Y - mean elif transform_type == "logmel23_swn": n_fft = 2 * (Y.shape[1] - 1) sr = 8000 n_mels = 23 mel_basis = librosa.filters.mel(sr, n_fft, n_mels) Y = np.dot(Y**2, mel_basis.T) Y = np.log10(np.maximum(Y, 1e-10)) # b = np.ones(300)/300 # mean = scipy.signal.convolve2d(Y, b[:, None], mode='same') # simple 2-means based threshoding for mean calculation powers = np.sum(Y, axis=1) th = (np.max(powers) + np.min(powers)) / 2.0 for i in range(10): th = (np.mean(powers[powers >= th]) + np.mean(powers[powers < th])) / 2 mean = np.mean(Y[powers > th, :], axis=0) Y = Y - mean elif transform_type == "logmel23_mvn": n_fft = 2 * (Y.shape[1] - 1) sr = 8000 n_mels = 23 mel_basis = librosa.filters.mel(sr, n_fft, n_mels) Y = np.dot(Y**2, mel_basis.T) Y = np.log10(np.maximum(Y, 1e-10)) mean = np.mean(Y, axis=0) Y = Y - mean std = np.maximum(np.std(Y, axis=0), 1e-10) Y = Y / std else: raise ValueError("Unknown transform_type: %s" % transform_type) return Y.astype(dtype) def subsample(Y, T, subsampling=1): """Frame subsampling""" Y_ss = Y[::subsampling] T_ss = T[::subsampling] return Y_ss, T_ss def splice(Y, context_size=0): """Frame splicing Args: Y: feature (n_frames, n_featdim)-shaped numpy array context_size: number of frames concatenated on left-side if context_size = 5, 11 frames are concatenated. Returns: Y_spliced: spliced feature (n_frames, n_featdim * (2 * context_size + 1))-shaped """ Y_pad = np.pad(Y, [(context_size, context_size), (0, 0)], "constant") Y_spliced = np.lib.stride_tricks.as_strided( np.ascontiguousarray(Y_pad), (Y.shape[0], Y.shape[1] * (2 * context_size + 1)), (Y.itemsize * Y.shape[1], Y.itemsize), writeable=False, ) return Y_spliced def stft(data, frame_size=1024, frame_shift=256): """Compute STFT features Args: data: audio signal (n_samples,)-shaped np.float32 array frame_size: number of samples in a frame (must be a power of two) frame_shift: number of samples between frames Returns: stft: STFT frames (n_frames, n_bins)-shaped np.complex64 array """ # round up to nearest power of 2 fft_size = 1 << (frame_size - 1).bit_length() # HACK: The last frame is ommited # as librosa.stft produces such an excessive frame if len(data) % frame_shift == 0: return librosa.stft(data, n_fft=fft_size, win_length=frame_size, hop_length=frame_shift).T[ :-1 ] else: return librosa.stft(data, n_fft=fft_size, win_length=frame_size, hop_length=frame_shift).T def _count_frames(data_len, size, shift): # HACK: Assuming librosa.stft(..., center=True) n_frames = 1 + int(data_len / shift) if data_len % shift == 0: n_frames = n_frames - 1 return n_frames def get_frame_labels( kaldi_obj, rec, start=0, end=None, frame_size=1024, frame_shift=256, n_speakers=None ): """Get frame-aligned labels of given recording Args: kaldi_obj (KaldiData) rec (str): recording id start (int): start frame index end (int): end frame index None means the last frame of recording frame_size (int): number of frames in a frame frame_shift (int): number of shift samples n_speakers (int): number of speakers if None, the value is given from data Returns: T: label (n_frames, n_speakers)-shaped np.int32 array """ filtered_segments = kaldi_obj.segments[kaldi_obj.segments["rec"] == rec] speakers = np.unique([kaldi_obj.utt2spk[seg["utt"]] for seg in filtered_segments]).tolist() if n_speakers is None: n_speakers = len(speakers) es = end * frame_shift if end is not None else None data, rate = kaldi_obj.load_wav(rec, start * frame_shift, es) n_frames = _count_frames(len(data), frame_size, frame_shift) T = np.zeros((n_frames, n_speakers), dtype=np.int32) if end is None: end = n_frames for seg in filtered_segments: speaker_index = speakers.index(kaldi_obj.utt2spk[seg["utt"]]) start_frame = np.rint(seg["st"] * rate / frame_shift).astype(int) end_frame = np.rint(seg["et"] * rate / frame_shift).astype(int) rel_start = rel_end = None if start <= start_frame and start_frame < end: rel_start = start_frame - start if start < end_frame and end_frame <= end: rel_end = end_frame - start if rel_start is not None or rel_end is not None: T[rel_start:rel_end, speaker_index] = 1 return T def get_labeledSTFT( kaldi_obj, rec, start, end, frame_size, frame_shift, n_speakers=None, use_speaker_id=False ): """Extracts STFT and corresponding labels Extracts STFT and corresponding diarization labels for given recording id and start/end times Args: kaldi_obj (KaldiData) rec (str): recording id start (int): start frame index end (int): end frame index frame_size (int): number of samples in a frame frame_shift (int): number of shift samples n_speakers (int): number of speakers if None, the value is given from data Returns: Y: STFT (n_frames, n_bins)-shaped np.complex64 array, T: label (n_frmaes, n_speakers)-shaped np.int32 array. """ data, rate = kaldi_obj.load_wav(rec, start * frame_shift, end * frame_shift) Y = stft(data, frame_size, frame_shift) filtered_segments = kaldi_obj.segments[rec] # filtered_segments = kaldi_obj.segments[kaldi_obj.segments['rec'] == rec] speakers = np.unique([kaldi_obj.utt2spk[seg["utt"]] for seg in filtered_segments]).tolist() if n_speakers is None: n_speakers = len(speakers) T = np.zeros((Y.shape[0], n_speakers), dtype=np.int32) if use_speaker_id: all_speakers = sorted(kaldi_obj.spk2utt.keys()) S = np.zeros((Y.shape[0], len(all_speakers)), dtype=np.int32) for seg in filtered_segments: speaker_index = speakers.index(kaldi_obj.utt2spk[seg["utt"]]) if use_speaker_id: all_speaker_index = all_speakers.index(kaldi_obj.utt2spk[seg["utt"]]) start_frame = np.rint(seg["st"] * rate / frame_shift).astype(int) end_frame = np.rint(seg["et"] * rate / frame_shift).astype(int) rel_start = rel_end = None if start <= start_frame and start_frame < end: rel_start = start_frame - start if start < end_frame and end_frame <= end: rel_end = end_frame - start if rel_start is not None or rel_end is not None: T[rel_start:rel_end, speaker_index] = 1 if use_speaker_id: S[rel_start:rel_end, all_speaker_index] = 1 if use_speaker_id: return Y, T, S else: return Y, T