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import gradio as gr
import torch
from speechbrain.inference.interfaces import Pretrained, foreign_class


class CustomEncoderWav2vec2Classifier(Pretrained):
    """A ready-to-use class for utterance-level classification (e.g, speaker-id,
    language-id, emotion recognition, keyword spotting, etc).
    The class assumes that an self-supervised encoder like wav2vec2/hubert and a classifier model
    are defined in the yaml file. If you want to
    convert the predicted index into a corresponding text label, please
    provide the path of the label_encoder in a variable called 'lab_encoder_file'
    within the yaml.
    The class can be used either to run only the encoder (encode_batch()) to
    extract embeddings or to run a classification step (classify_batch()).
    ```
    Example
    -------
    >>> import torchaudio
    >>> from speechbrain.pretrained import EncoderClassifier
    >>> # Model is downloaded from the speechbrain HuggingFace repo
    >>> tmpdir = getfixture("tmpdir")
    >>> classifier = EncoderClassifier.from_hparams(
    ...     source="speechbrain/spkrec-ecapa-voxceleb",
    ...     savedir=tmpdir,
    ... )
    >>> # Compute embeddings
    >>> signal, fs = torchaudio.load("samples/audio_samples/example1.wav")
    >>> embeddings =  classifier.encode_batch(signal)
    >>> # Classification
    >>> prediction =  classifier .classify_batch(signal)
    """

    def __init__(self, *args, **kwargs):
        super().__init__(*args, **kwargs)

    def encode_batch(self, wavs, wav_lens=None, normalize=False):
        """Encodes the input audio into a single vector embedding.
        The waveforms should already be in the model's desired format.
        You can call:
        ``normalized = <this>.normalizer(signal, sample_rate)``
        to get a correctly converted signal in most cases.
        Arguments
        ---------
        wavs : torch.tensor
            Batch of waveforms [batch, time, channels] or [batch, time]
            depending on the model. Make sure the sample rate is fs=16000 Hz.
        wav_lens : torch.tensor
            Lengths of the waveforms relative to the longest one in the
            batch, tensor of shape [batch]. The longest one should have
            relative length 1.0 and others len(waveform) / max_length.
            Used for ignoring padding.
        normalize : bool
            If True, it normalizes the embeddings with the statistics
            contained in mean_var_norm_emb.
        Returns
        -------
        torch.tensor
            The encoded batch
        """
        # Manage single waveforms in input
        if len(wavs.shape) == 1:
            wavs = wavs.unsqueeze(0)

        # Assign full length if wav_lens is not assigned
        if wav_lens is None:
            wav_lens = torch.ones(wavs.shape[0], device=self.device)

        # Storing waveform in the specified device
        wavs, wav_lens = wavs.to(self.device), wav_lens.to(self.device)
        wavs = wavs.float()

        # Computing features and embeddings
        outputs = self.mods.wav2vec2(wavs)

        # last dim will be used for AdaptativeAVG pool
        outputs = self.mods.avg_pool(outputs, wav_lens)
        outputs = outputs.view(outputs.shape[0], -1)
        return outputs

    def classify_batch(self, wavs, wav_lens=None):
        """Performs classification on the top of the encoded features.
        It returns the posterior probabilities, the index and, if the label
        encoder is specified it also the text label.
        Arguments
        ---------
        wavs : torch.tensor
            Batch of waveforms [batch, time, channels] or [batch, time]
            depending on the model. Make sure the sample rate is fs=16000 Hz.
        wav_lens : torch.tensor
            Lengths of the waveforms relative to the longest one in the
            batch, tensor of shape [batch]. The longest one should have
            relative length 1.0 and others len(waveform) / max_length.
            Used for ignoring padding.
        Returns
        -------
        out_prob
            The log posterior probabilities of each class ([batch, N_class])
        score:
            It is the value of the log-posterior for the best class ([batch,])
        index
            The indexes of the best class ([batch,])
        text_lab:
            List with the text labels corresponding to the indexes.
            (label encoder should be provided).
        """
        outputs = self.encode_batch(wavs, wav_lens)
        outputs = self.mods.label_lin(outputs)
        out_prob = self.hparams.softmax(outputs)
        score, index = torch.max(out_prob, dim=-1)
        text_lab = self.hparams.label_encoder.decode_torch(index)
        return out_prob, score, index, text_lab

    def classify_file(self, path):
        """Classifies the given audiofile into the given set of labels.
        Arguments
        ---------
        path : str
            Path to audio file to classify.
        Returns
        -------
        out_prob
            The log posterior probabilities of each class ([batch, N_class])
        score:
            It is the value of the log-posterior for the best class ([batch,])
        index
            The indexes of the best class ([batch,])
        text_lab:
            List with the text labels corresponding to the indexes.
            (label encoder should be provided).
        """
        waveform = self.load_audio(path)
        # Fake a batch:
        batch = waveform.unsqueeze(0)
        rel_length = torch.tensor([1.0])
        outputs = self.encode_batch(batch, rel_length)
        outputs = self.mods.label_lin(outputs).squeeze(1)
        out_prob = self.hparams.softmax(outputs)
        score, index = torch.max(out_prob, dim=-1)
        text_lab = self.hparams.label_encoder.decode_torch(index)
        if text_lab[0] == "1":
            text_lab = "neutral"
        elif text_lab[0] == "2":
            text_lab = "sadness"
        elif text_lab[0] == "3":
            text_lab = "joy"
        elif text_lab[0] == "4":
            text_lab = "anger"
        elif text_lab[0] == "5":
            text_lab = "affection"
        
        return out_prob, score, index, text_lab

    def forward(self, wavs, wav_lens=None, normalize=False):
        return self.encode_batch(
            wavs=wavs, wav_lens=wav_lens, normalize=normalize
        )


def return_prediction(mic, file):
    # classifier = foreign_class(source="Porjaz/wavlm-base-emo-fi", pymodule_file="custom_interface.py", classname="CustomEncoderWav2vec2Classifier")
    if mic is not None:
        out_prob, score, index, text_lab = classifier.classify_file(mic)
    elif file is not None:
        out_prob, score, index, text_lab = classifier.classify_file(file)
    else:
        return "You must either provide a mic recording or a file"
    return text_lab
    

classifier = foreign_class(source="Porjaz/wavlm-base-emo-fi", pymodule_file="custom_interface.py", classname="CustomEncoderWav2vec2Classifier")

gradio_app = gr.Interface(
    return_prediction,
    inputs=[
        gr.Audio(sources="microphone", type="filepath"),
        gr.Audio(sources="upload", type="filepath"),
    ],
    outputs="text",
    title="Finnish-Emotion-Recognition",
)

gradio_app.launch()