import torch import gradio as gr import librosa from espnet2.bin.s2t_inference_language import Speech2Language from espnet2.bin.s2t_inference import Speech2Text TITLE="Open Whisper-style Speech Model from CMU WAVLab" DESCRIPTION=''' OWSM (pronounced as "awesome") is a series of Open Whisper-style Speech Models from [CMU WAVLab](https://www.wavlab.org/). We reproduce Whisper-style training using publicly available data and an open-source toolkit [ESPnet](https://github.com/espnet/espnet). For more details, please check our [website](https://www.wavlab.org/activities/2024/owsm/). ''' ARTICLE = ''' The latest demo uses OWSM v3.1 based on [E-Branchformer](https://arxiv.org/abs/2210.00077). OWSM v3.1 has 1.02B parameters and is trained on 180k hours of labelled data. It supports various speech-to-text tasks: - Speech recognition in 151 languages - Any-to-any language speech translation - Utterance-level timestamp prediction - Long-form transcription - Language identification As a demo, the input speech should not exceed 2 minutes. We also limit the maximum number of tokens to be generated. Please try our [Colab demo](https://colab.research.google.com/drive/1zKI3ZY_OtZd6YmVeED6Cxy1QwT1mqv9O?usp=sharing) if you want to explore more features. **Disclaimer:** OWSM has not been thoroughly evaluated in all tasks. Due to limited training data, it may not perform well for certain languages. Please consider citing the following papers if you find our work helpful. ``` @inproceedings{peng2024owsm31, title={OWSM v3.1: Better and Faster Open Whisper-Style Speech Models based on E-Branchformer}, author={Yifan Peng and Jinchuan Tian and William Chen and Siddhant Arora and Brian Yan and Yui Sudo and Muhammad Shakeel and Kwanghee Choi and Jiatong Shi and Xuankai Chang and Jee-weon Jung and Shinji Watanabe}, booktitle={Proc. INTERSPEECH}, year={2024} } @inproceedings{peng2023owsm, title={Reproducing Whisper-Style Training Using an Open-Source Toolkit and Publicly Available Data}, author={Yifan Peng and Jinchuan Tian and Brian Yan and Dan Berrebbi and Xuankai Chang and Xinjian Li and Jiatong Shi and Siddhant Arora and William Chen and Roshan Sharma and Wangyou Zhang and Yui Sudo and Muhammad Shakeel and Jee-weon Jung and Soumi Maiti and Shinji Watanabe}, booktitle={Proc. ASRU}, year={2023} } ``` ''' if not torch.cuda.is_available(): raise RuntimeError("Please use GPU for better inference speed.") model_tag = "espnet/owsm_v3.1_ebf" device = "cuda" s2l = Speech2Language.from_pretrained( model_tag=model_tag, device=device, nbest=1, ) s2t = Speech2Text.from_pretrained( model_tag=model_tag, device=device, beam_size=5, ctc_weight=0.0, maxlenratio=0.0, # below are default values which can be overwritten in __call__ lang_sym="", task_sym="", predict_time=False, ) iso_codes = ['abk', 'afr', 'amh', 'ara', 'asm', 'ast', 'aze', 'bak', 'bas', 'bel', 'ben', 'bos', 'bre', 'bul', 'cat', 'ceb', 'ces', 'chv', 'ckb', 'cmn', 'cnh', 'cym', 'dan', 'deu', 'dgd', 'div', 'ell', 'eng', 'epo', 'est', 'eus', 'fas', 'fil', 'fin', 'fra', 'frr', 'ful', 'gle', 'glg', 'grn', 'guj', 'hat', 'hau', 'heb', 'hin', 'hrv', 'hsb', 'hun', 'hye', 'ibo', 'ina', 'ind', 'isl', 'ita', 'jav', 'jpn', 'kab', 'kam', 'kan', 'kat', 'kaz', 'kea', 'khm', 'kin', 'kir', 'kmr', 'kor', 'lao', 'lav', 'lga', 'lin', 'lit', 'ltz', 'lug', 'luo', 'mal', 'mar', 'mas', 'mdf', 'mhr', 'mkd', 'mlt', 'mon', 'mri', 'mrj', 'mya', 'myv', 'nan', 'nep', 'nld', 'nno', 'nob', 'npi', 'nso', 'nya', 'oci', 'ori', 'orm', 'ory', 'pan', 'pol', 'por', 'pus', 'quy', 'roh', 'ron', 'rus', 'sah', 'sat', 'sin', 'skr', 'slk', 'slv', 'sna', 'snd', 'som', 'sot', 'spa', 'srd', 'srp', 'sun', 'swa', 'swe', 'swh', 'tam', 'tat', 'tel', 'tgk', 'tgl', 'tha', 'tig', 'tir', 'tok', 'tpi', 'tsn', 'tuk', 'tur', 'twi', 'uig', 'ukr', 'umb', 'urd', 'uzb', 'vie', 'vot', 'wol', 'xho', 'yor', 'yue', 'zho', 'zul'] lang_names = ['Abkhazian', 'Afrikaans', 'Amharic', 'Arabic', 'Assamese', 'Asturian', 'Azerbaijani', 'Bashkir', 'Basa (Cameroon)', 'Belarusian', 'Bengali', 'Bosnian', 'Breton', 'Bulgarian', 'Catalan', 'Cebuano', 'Czech', 'Chuvash', 'Central Kurdish', 'Mandarin Chinese', 'Hakha Chin', 'Welsh', 'Danish', 'German', 'Dagaari Dioula', 'Dhivehi', 'Modern Greek (1453-)', 'English', 'Esperanto', 'Estonian', 'Basque', 'Persian', 'Filipino', 'Finnish', 'French', 'Northern Frisian', 'Fulah', 'Irish', 'Galician', 'Guarani', 'Gujarati', 'Haitian', 'Hausa', 'Hebrew', 'Hindi', 'Croatian', 'Upper Sorbian', 'Hungarian', 'Armenian', 'Igbo', 'Interlingua (International Auxiliary Language Association)', 'Indonesian', 'Icelandic', 'Italian', 'Javanese', 'Japanese', 'Kabyle', 'Kamba (Kenya)', 'Kannada', 'Georgian', 'Kazakh', 'Kabuverdianu', 'Khmer', 'Kinyarwanda', 'Kirghiz', 'Northern Kurdish', 'Korean', 'Lao', 'Latvian', 'Lungga', 'Lingala', 'Lithuanian', 'Luxembourgish', 'Ganda', 'Luo (Kenya and Tanzania)', 'Malayalam', 'Marathi', 'Masai', 'Moksha', 'Eastern Mari', 'Macedonian', 'Maltese', 'Mongolian', 'Maori', 'Western Mari', 'Burmese', 'Erzya', 'Min Nan Chinese', 'Nepali (macrolanguage)', 'Dutch', 'Norwegian Nynorsk', 'Norwegian Bokmål', 'Nepali (individual language)', 'Pedi', 'Nyanja', 'Occitan (post 1500)', 'Oriya (macrolanguage)', 'Oromo', 'Odia', 'Panjabi', 'Polish', 'Portuguese', 'Pushto', 'Ayacucho Quechua', 'Romansh', 'Romanian', 'Russian', 'Yakut', 'Santali', 'Sinhala', 'Saraiki', 'Slovak', 'Slovenian', 'Shona', 'Sindhi', 'Somali', 'Southern Sotho', 'Spanish', 'Sardinian', 'Serbian', 'Sundanese', 'Swahili (macrolanguage)', 'Swedish', 'Swahili (individual language)', 'Tamil', 'Tatar', 'Telugu', 'Tajik', 'Tagalog', 'Thai', 'Tigre', 'Tigrinya', 'Toki Pona', 'Tok Pisin', 'Tswana', 'Turkmen', 'Turkish', 'Twi', 'Uighur', 'Ukrainian', 'Umbundu', 'Urdu', 'Uzbek', 'Vietnamese', 'Votic', 'Wolof', 'Xhosa', 'Yoruba', 'Yue Chinese', 'Chinese', 'Zulu'] task_codes = ['asr', 'st_ara', 'st_cat', 'st_ces', 'st_cym', 'st_deu', 'st_eng', 'st_est', 'st_fas', 'st_fra', 'st_ind', 'st_ita', 'st_jpn', 'st_lav', 'st_mon', 'st_nld', 'st_por', 'st_ron', 'st_rus', 'st_slv', 'st_spa', 'st_swe', 'st_tam', 'st_tur', 'st_vie', 'st_zho'] task_names = ['Automatic Speech Recognition', 'Translate to Arabic', 'Translate to Catalan', 'Translate to Czech', 'Translate to Welsh', 'Translate to German', 'Translate to English', 'Translate to Estonian', 'Translate to Persian', 'Translate to French', 'Translate to Indonesian', 'Translate to Italian', 'Translate to Japanese', 'Translate to Latvian', 'Translate to Mongolian', 'Translate to Dutch', 'Translate to Portuguese', 'Translate to Romanian', 'Translate to Russian', 'Translate to Slovenian', 'Translate to Spanish', 'Translate to Swedish', 'Translate to Tamil', 'Translate to Turkish', 'Translate to Vietnamese', 'Translate to Chinese'] lang2code = dict( [('Unknown', 'none')] + sorted(list(zip(lang_names, iso_codes)), key=lambda x: x[0]) ) task2code = dict(sorted(list(zip(task_names, task_codes)), key=lambda x: x[0])) code2lang = dict([(v, k) for k, v in lang2code.items()]) # Copied from Whisper utils def format_timestamp( seconds: float, always_include_hours: bool = False, decimal_marker: str = "." ): assert seconds >= 0, "non-negative timestamp expected" milliseconds = round(seconds * 1000.0) hours = milliseconds // 3_600_000 milliseconds -= hours * 3_600_000 minutes = milliseconds // 60_000 milliseconds -= minutes * 60_000 seconds = milliseconds // 1_000 milliseconds -= seconds * 1_000 hours_marker = f"{hours:02d}:" if always_include_hours or hours > 0 else "" return ( f"{hours_marker}{minutes:02d}:{seconds:02d}{decimal_marker}{milliseconds:03d}" ) def predict(audio_path, src_lang: str, task: str, beam_size, long_form: bool, text_prev: str,): task_sym = f'<{task2code[task]}>' s2t.beam_search.beam_size = int(beam_size) # Our model is trained on 30s and 16kHz speech, rate = librosa.load(audio_path, sr=16000) # speech has shape (len,); resample to 16k Hz lang_code = lang2code[src_lang] if lang_code == 'none': # Detect language using the first 30s of speech lang_code = s2l(speech)[0][0].strip()[1:-1] lang_sym = f'<{lang_code}>' # ASR or ST if long_form: try: s2t.maxlenratio = -300 utts = s2t.decode_long( speech, condition_on_prev_text=False, init_text=text_prev, end_time_threshold="<29.00>", lang_sym=lang_sym, task_sym=task_sym, ) text = [] for t1, t2, res in utts: text.append(f"[{format_timestamp(seconds=t1)} --> {format_timestamp(seconds=t2)}] {res}") text = '\n'.join(text) return code2lang[lang_code], text except: print("An exception occurred in long-form decoding. Fall back to standard decoding (only first 30s)") s2t.maxlenratio = -min(300, int((len(speech) / rate) * 10)) # assuming 10 tokens per second text = s2t(speech, text_prev, lang_sym=lang_sym, task_sym=task_sym)[0][-2] return code2lang[lang_code], text demo = gr.Interface( predict, inputs=[ gr.Audio(type="filepath", label="Input Speech (<120s)", max_length=120, sources=["microphone", "upload"], show_download_button=True, show_share_button=True,), gr.Dropdown(choices=list(lang2code), value="English", label="Language", info="Language of input speech. Select 'Unknown' (1st option) to detect it automatically."), gr.Dropdown(choices=list(task2code), value="Automatic Speech Recognition", label="Task", info="Task to perform on input speech."), gr.Slider(minimum=1, maximum=5, step=1, value=5, label="Beam Size", info="Beam size used in beam search."), gr.Checkbox(label="Long Form (Experimental)", info="Perform long-form decoding. If an exception happens, it will fall back to standard decoding on the initial 30s."), gr.Text(label="Text Prompt (Optional)", info="Generation will be conditioned on this prompt if provided"), ], outputs=[ gr.Text(label="Predicted Language", info="Language identification is performed if language is unknown."), gr.Text(label="Predicted Text", info="Best hypothesis."), ], title=TITLE, description=DESCRIPTION, article=ARTICLE, allow_flagging="never", ) if __name__ == "__main__": demo.launch( show_api=False, share=True, ssr_mode=True, )