| | import bisect |
| | import functools |
| | import os |
| | import warnings |
| |
|
| | from typing import List, NamedTuple, Optional |
| |
|
| | import numpy as np |
| |
|
| |
|
| | |
| | class VadOptions(NamedTuple): |
| | """VAD options. |
| | |
| | Attributes: |
| | threshold: Speech threshold. Silero VAD outputs speech probabilities for each audio chunk, |
| | probabilities ABOVE this value are considered as SPEECH. It is better to tune this |
| | parameter for each dataset separately, but "lazy" 0.5 is pretty good for most datasets. |
| | min_speech_duration_ms: Final speech chunks shorter min_speech_duration_ms are thrown out. |
| | max_speech_duration_s: Maximum duration of speech chunks in seconds. Chunks longer |
| | than max_speech_duration_s will be split at the timestamp of the last silence that |
| | lasts more than 100ms (if any), to prevent aggressive cutting. Otherwise, they will be |
| | split aggressively just before max_speech_duration_s. |
| | min_silence_duration_ms: In the end of each speech chunk wait for min_silence_duration_ms |
| | before separating it |
| | window_size_samples: Audio chunks of window_size_samples size are fed to the silero VAD model. |
| | WARNING! Silero VAD models were trained using 512, 1024, 1536 samples for 16000 sample rate. |
| | Values other than these may affect model performance!! |
| | speech_pad_ms: Final speech chunks are padded by speech_pad_ms each side |
| | """ |
| |
|
| | threshold: float = 0.5 |
| | min_speech_duration_ms: int = 250 |
| | max_speech_duration_s: float = float("inf") |
| | min_silence_duration_ms: int = 2000 |
| | window_size_samples: int = 1024 |
| | speech_pad_ms: int = 400 |
| |
|
| |
|
| | def get_speech_timestamps( |
| | audio: np.ndarray, |
| | vad_options: Optional[VadOptions] = None, |
| | **kwargs, |
| | ) -> List[dict]: |
| | """This method is used for splitting long audios into speech chunks using silero VAD. |
| | |
| | Args: |
| | audio: One dimensional float array. |
| | vad_options: Options for VAD processing. |
| | kwargs: VAD options passed as keyword arguments for backward compatibility. |
| | |
| | Returns: |
| | List of dicts containing begin and end samples of each speech chunk. |
| | """ |
| | if vad_options is None: |
| | vad_options = VadOptions(**kwargs) |
| |
|
| | threshold = vad_options.threshold |
| | min_speech_duration_ms = vad_options.min_speech_duration_ms |
| | max_speech_duration_s = vad_options.max_speech_duration_s |
| | min_silence_duration_ms = vad_options.min_silence_duration_ms |
| | window_size_samples = vad_options.window_size_samples |
| | speech_pad_ms = vad_options.speech_pad_ms |
| |
|
| | if window_size_samples not in [512, 1024, 1536]: |
| | warnings.warn( |
| | "Unusual window_size_samples! Supported window_size_samples:\n" |
| | " - [512, 1024, 1536] for 16000 sampling_rate" |
| | ) |
| |
|
| | sampling_rate = 16000 |
| | min_speech_samples = sampling_rate * min_speech_duration_ms / 1000 |
| | speech_pad_samples = sampling_rate * speech_pad_ms / 1000 |
| | max_speech_samples = ( |
| | sampling_rate * max_speech_duration_s |
| | - window_size_samples |
| | - 2 * speech_pad_samples |
| | ) |
| | min_silence_samples = sampling_rate * min_silence_duration_ms / 1000 |
| | min_silence_samples_at_max_speech = sampling_rate * 98 / 1000 |
| |
|
| | audio_length_samples = len(audio) |
| |
|
| | model = get_vad_model() |
| | state = model.get_initial_state(batch_size=1) |
| |
|
| | speech_probs = [] |
| | for current_start_sample in range(0, audio_length_samples, window_size_samples): |
| | chunk = audio[current_start_sample : current_start_sample + window_size_samples] |
| | if len(chunk) < window_size_samples: |
| | chunk = np.pad(chunk, (0, int(window_size_samples - len(chunk)))) |
| | speech_prob, state = model(chunk, state, sampling_rate) |
| | speech_probs.append(speech_prob) |
| |
|
| | triggered = False |
| | speeches = [] |
| | current_speech = {} |
| | neg_threshold = threshold - 0.15 |
| |
|
| | |
| | temp_end = 0 |
| | |
| | prev_end = next_start = 0 |
| |
|
| | for i, speech_prob in enumerate(speech_probs): |
| | if (speech_prob >= threshold) and temp_end: |
| | temp_end = 0 |
| | if next_start < prev_end: |
| | next_start = window_size_samples * i |
| |
|
| | if (speech_prob >= threshold) and not triggered: |
| | triggered = True |
| | current_speech["start"] = window_size_samples * i |
| | continue |
| |
|
| | if ( |
| | triggered |
| | and (window_size_samples * i) - current_speech["start"] > max_speech_samples |
| | ): |
| | if prev_end: |
| | current_speech["end"] = prev_end |
| | speeches.append(current_speech) |
| | current_speech = {} |
| | |
| | if next_start < prev_end: |
| | triggered = False |
| | else: |
| | current_speech["start"] = next_start |
| | prev_end = next_start = temp_end = 0 |
| | else: |
| | current_speech["end"] = window_size_samples * i |
| | speeches.append(current_speech) |
| | current_speech = {} |
| | prev_end = next_start = temp_end = 0 |
| | triggered = False |
| | continue |
| |
|
| | if (speech_prob < neg_threshold) and triggered: |
| | if not temp_end: |
| | temp_end = window_size_samples * i |
| | |
| | if (window_size_samples * i) - temp_end > min_silence_samples_at_max_speech: |
| | prev_end = temp_end |
| | if (window_size_samples * i) - temp_end < min_silence_samples: |
| | continue |
| | else: |
| | current_speech["end"] = temp_end |
| | if ( |
| | current_speech["end"] - current_speech["start"] |
| | ) > min_speech_samples: |
| | speeches.append(current_speech) |
| | current_speech = {} |
| | prev_end = next_start = temp_end = 0 |
| | triggered = False |
| | continue |
| |
|
| | if ( |
| | current_speech |
| | and (audio_length_samples - current_speech["start"]) > min_speech_samples |
| | ): |
| | current_speech["end"] = audio_length_samples |
| | speeches.append(current_speech) |
| |
|
| | for i, speech in enumerate(speeches): |
| | if i == 0: |
| | speech["start"] = int(max(0, speech["start"] - speech_pad_samples)) |
| | if i != len(speeches) - 1: |
| | silence_duration = speeches[i + 1]["start"] - speech["end"] |
| | if silence_duration < 2 * speech_pad_samples: |
| | speech["end"] += int(silence_duration // 2) |
| | speeches[i + 1]["start"] = int( |
| | max(0, speeches[i + 1]["start"] - silence_duration // 2) |
| | ) |
| | else: |
| | speech["end"] = int( |
| | min(audio_length_samples, speech["end"] + speech_pad_samples) |
| | ) |
| | speeches[i + 1]["start"] = int( |
| | max(0, speeches[i + 1]["start"] - speech_pad_samples) |
| | ) |
| | else: |
| | speech["end"] = int( |
| | min(audio_length_samples, speech["end"] + speech_pad_samples) |
| | ) |
| |
|
| | return speeches |
| |
|
| |
|
| | def collect_chunks(audio: np.ndarray, chunks: List[dict]) -> np.ndarray: |
| | """Collects and concatenates audio chunks.""" |
| | if not chunks: |
| | return np.array([], dtype=np.float32) |
| |
|
| | return np.concatenate([audio[chunk["start"] : chunk["end"]] for chunk in chunks]) |
| |
|
| |
|
| | class SpeechTimestampsMap: |
| | """Helper class to restore original speech timestamps.""" |
| |
|
| | def __init__(self, chunks: List[dict], sampling_rate: int, time_precision: int = 2): |
| | self.sampling_rate = sampling_rate |
| | self.time_precision = time_precision |
| | self.chunk_end_sample = [] |
| | self.total_silence_before = [] |
| |
|
| | previous_end = 0 |
| | silent_samples = 0 |
| |
|
| | for chunk in chunks: |
| | silent_samples += chunk["start"] - previous_end |
| | previous_end = chunk["end"] |
| |
|
| | self.chunk_end_sample.append(chunk["end"] - silent_samples) |
| | self.total_silence_before.append(silent_samples / sampling_rate) |
| |
|
| | def get_original_time( |
| | self, |
| | time: float, |
| | chunk_index: Optional[int] = None, |
| | ) -> float: |
| | if chunk_index is None: |
| | chunk_index = self.get_chunk_index(time) |
| |
|
| | total_silence_before = self.total_silence_before[chunk_index] |
| | return round(total_silence_before + time, self.time_precision) |
| |
|
| | def get_chunk_index(self, time: float) -> int: |
| | sample = int(time * self.sampling_rate) |
| | return min( |
| | bisect.bisect(self.chunk_end_sample, sample), |
| | len(self.chunk_end_sample) - 1, |
| | ) |
| |
|
| |
|
| | @functools.lru_cache |
| | def get_vad_model(): |
| | """Returns the VAD model instance.""" |
| | asset_dir = os.path.join(os.path.dirname(__file__), "assets") |
| | path = os.path.join(asset_dir, "silero_vad.onnx") |
| | return SileroVADModel(path) |
| |
|
| |
|
| | class SileroVADModel: |
| | def __init__(self, path): |
| | try: |
| | import onnxruntime |
| | except ImportError as e: |
| | raise RuntimeError( |
| | "Applying the VAD filter requires the onnxruntime package" |
| | ) from e |
| |
|
| | opts = onnxruntime.SessionOptions() |
| | opts.inter_op_num_threads = 1 |
| | opts.intra_op_num_threads = 1 |
| | opts.log_severity_level = 4 |
| |
|
| | self.session = onnxruntime.InferenceSession( |
| | path, |
| | providers=["CPUExecutionProvider"], |
| | sess_options=opts, |
| | ) |
| |
|
| | def get_initial_state(self, batch_size: int): |
| | h = np.zeros((2, batch_size, 64), dtype=np.float32) |
| | c = np.zeros((2, batch_size, 64), dtype=np.float32) |
| | return h, c |
| |
|
| | def __call__(self, x, state, sr: int): |
| | if len(x.shape) == 1: |
| | x = np.expand_dims(x, 0) |
| | if len(x.shape) > 2: |
| | raise ValueError( |
| | f"Too many dimensions for input audio chunk {len(x.shape)}" |
| | ) |
| | if sr / x.shape[1] > 31.25: |
| | raise ValueError("Input audio chunk is too short") |
| |
|
| | h, c = state |
| |
|
| | ort_inputs = { |
| | "input": x, |
| | "h": h, |
| | "c": c, |
| | "sr": np.array(sr, dtype="int64"), |
| | } |
| |
|
| | out, h, c = self.session.run(None, ort_inputs) |
| | state = (h, c) |
| |
|
| | return out, state |
| |
|
