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import torch |
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from speechbrain.inference.interfaces import Pretrained |
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import openvino as ov |
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class CustomEncoderWav2vec2Classifier(Pretrained): |
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"""A ready-to-use class for utterance-level classification (e.g, speaker-id, |
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language-id, emotion recognition, keyword spotting, etc). |
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The class assumes that an self-supervised encoder like wav2vec2/hubert and a classifier model |
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are defined in the yaml file. If you want to |
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convert the predicted index into a corresponding text label, please |
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provide the path of the label_encoder in a variable called 'lab_encoder_file' |
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within the yaml. |
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The class can be used either to run only the encoder (encode_batch()) to |
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extract embeddings or to run a classification step (classify_batch()). |
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``` |
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Example |
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------- |
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>>> import torchaudio |
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>>> from speechbrain.pretrained import EncoderClassifier |
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>>> # Model is downloaded from the speechbrain HuggingFace repo |
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>>> tmpdir = getfixture("tmpdir") |
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>>> classifier = EncoderClassifier.from_hparams( |
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... source="speechbrain/spkrec-ecapa-voxceleb", |
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... savedir=tmpdir, |
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... ) |
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>>> # Compute embeddings |
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>>> signal, fs = torchaudio.load("samples/audio_samples/example1.wav") |
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>>> embeddings = classifier.encode_batch(signal) |
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>>> # Classification |
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>>> prediction = classifier .classify_batch(signal) |
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""" |
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def __init__(self, *args, model=None, |
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audio_file_path=None, backend="pytorch", |
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ov_opts={"device_name": "cpu"}, |
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save_ov_model=False, |
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**kwargs): |
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super().__init__(*args, **kwargs) |
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self.backend = backend |
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if self.backend == "openvino": |
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print("=" * 30) |
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print("OpenVINO Backend Selected") |
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print("=" * 30) |
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self.core = ov.Core() |
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self.ov_model = None |
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if model: |
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print("\n[INFO] Preparing OpenVINO model...") |
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self.get_ov_model(model, audio_file_path) |
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print("[SUCCESS] OpenVINO IR model compiled for inference!\n") |
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if self.ov_model: |
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self.device = ov_opts["device_name"] |
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print("[INFO] Compiling OpenVINO IR model for inference...") |
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self.compiled_model = self.core.compile_model(self.ov_model, config=ov_opts) |
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print("[SUCCESS] OpenVINO IR model compiled for inference!\n") |
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if save_ov_model: |
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print("[INFO] Saving OpenVINO IR model to disk!\n") |
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ov_ir_file_path = "./openvino_model/fp32/speechbrain_emotion_recog_ov_ir_model.xml" |
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ov.save_model(self.ov_model, ov_ir_file_path) |
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print(f"[SUCCESS] OpenVINO IR model file saved at {ov_ir_file_path}!\n") |
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def encode_batch(self, wavs, wav_lens=None, normalize=False): |
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"""Encodes the input audio into a single vector embedding. |
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The waveforms should already be in the model's desired format. |
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You can call: |
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``normalized = <this>.normalizer(signal, sample_rate)`` |
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to get a correctly converted signal in most cases. |
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Arguments |
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--------- |
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wavs : torch.tensor |
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Batch of waveforms [batch, time, channels] or [batch, time] |
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depending on the model. Make sure the sample rate is fs=16000 Hz. |
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wav_lens : torch.tensor |
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Lengths of the waveforms relative to the longest one in the |
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batch, tensor of shape [batch]. The longest one should have |
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relative length 1.0 and others len(waveform) / max_length. |
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Used for ignoring padding. |
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normalize : bool |
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If True, it normalizes the embeddings with the statistics |
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contained in mean_var_norm_emb. |
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Returns |
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------- |
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torch.tensor |
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The encoded batch |
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""" |
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if len(wavs.shape) == 1: |
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wavs = wavs.unsqueeze(0) |
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if wav_lens is None: |
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wav_lens = torch.ones(wavs.shape[0], device=self.device) |
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wavs, wav_lens = wavs.to(self.device), wav_lens.to(self.device) |
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wavs = wavs.float() |
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if self.backend == "pytorch": |
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outputs = self.mods.wav2vec2(wavs) |
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elif self.backend == "openvino": |
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outputs = self.ov_inference(wavs, wav_lens) |
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outputs = self.mods.avg_pool(outputs, wav_lens) |
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outputs = outputs.view(outputs.shape[0], -1) |
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return outputs |
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def classify_batch(self, wavs, wav_lens=None): |
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"""Performs classification on the top of the encoded features. |
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It returns the posterior probabilities, the index and, if the label |
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encoder is specified it also the text label. |
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Arguments |
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--------- |
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wavs : torch.tensor |
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Batch of waveforms [batch, time, channels] or [batch, time] |
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depending on the model. Make sure the sample rate is fs=16000 Hz. |
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wav_lens : torch.tensor |
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Lengths of the waveforms relative to the longest one in the |
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batch, tensor of shape [batch]. The longest one should have |
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relative length 1.0 and others len(waveform) / max_length. |
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Used for ignoring padding. |
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Returns |
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------- |
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out_prob |
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The log posterior probabilities of each class ([batch, N_class]) |
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score: |
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It is the value of the log-posterior for the best class ([batch,]) |
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index |
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The indexes of the best class ([batch,]) |
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text_lab: |
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List with the text labels corresponding to the indexes. |
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(label encoder should be provided). |
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""" |
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outputs = self.encode_batch(wavs, wav_lens) |
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outputs = self.mods.output_mlp(outputs) |
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out_prob = self.hparams.softmax(outputs) |
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score, index = torch.max(out_prob, dim=-1) |
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text_lab = self.hparams.label_encoder.decode_torch(index) |
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return out_prob, score, index, text_lab |
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def classify_file(self, path): |
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"""Classifies the given audiofile into the given set of labels. |
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Arguments |
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--------- |
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path : str |
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Path to audio file to classify. |
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Returns |
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------- |
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out_prob |
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The log posterior probabilities of each class ([batch, N_class]) |
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score: |
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It is the value of the log-posterior for the best class ([batch,]) |
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index |
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The indexes of the best class ([batch,]) |
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text_lab: |
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List with the text labels corresponding to the indexes. |
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(label encoder should be provided). |
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""" |
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waveform = self.load_audio(path) |
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batch = waveform.unsqueeze(0) |
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rel_length = torch.tensor([1.0]) |
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outputs = self.encode_batch(batch, rel_length) |
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outputs = self.mods.output_mlp(outputs).squeeze(1) |
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out_prob = self.hparams.softmax(outputs) |
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score, index = torch.max(out_prob, dim=-1) |
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text_lab = self.hparams.label_encoder.decode_torch(index) |
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return out_prob, score, index, text_lab |
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def get_ov_model(self, torch_model, path): |
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waveform = self.load_audio(path) |
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wavs = waveform.unsqueeze(0) |
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self.ov_model = ov.convert_model(torch_model, example_input=wavs) |
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def ov_inference(self, wavs, wav_lens): |
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output_tensor = self.compiled_model(wavs.float())[0] |
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output_tensor = torch.from_numpy(output_tensor) |
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print("\n[INFO] Performing OpenVINO inference...") |
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return output_tensor |
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def forward(self, wavs, wav_lens=None, normalize=False): |
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return self.encode_batch( |
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wavs=wavs, wav_lens=wav_lens, normalize=normalize |
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) |
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