whisper-live/transcribe_demo.py

#! python3.7

import argparse
import io
import os
import speech_recognition as sr
import whisper

from datetime import datetime, timedelta
from queue import Queue
from tempfile import NamedTemporaryFile
from time import sleep


def main():
    parser = argparse.ArgumentParser()
    parser.add_argument("--model", default="medium", help="Model to use",
                        choices=["tiny", "base", "small", "medium", "large"])
    parser.add_argument("--non_english", action='store_true',
                        help="Don't use the english model.")
    parser.add_argument("--energy_threshold", default=1000,
                        help="Energy level for mic to detect.", type=int)
    parser.add_argument("--record_timeout", default=2,
                        help="How real time the recording is in seconds.", type=float)
    parser.add_argument("--phrase_timeout", default=3,
                        help="How much empty space between recordings before we "
                             "consider it a new line in the transcription.", type=float)
    args = parser.parse_args()

    model = args.model
    if args.model != "large" and not args.non_english:
        model = model + ".en"
    audio_model = whisper.load_model(model)

    record_timeout = args.record_timeout
    phrase_timeout = args.phrase_timeout

    temp_file = NamedTemporaryFile().name
    transcription = ['']

    # The last time a recording was retreived from the queue.
    phrase_time = None
    # Current raw audio bytes.
    last_sample = bytes()
    # Thread safe Queue for passing data from the threaded recording callback.
    data_queue = Queue()

    # We use SpeechRecognizer to record our audio because it has a nice feauture where it can detect when speech ends.
    recorder = sr.Recognizer()
    recorder.energy_threshold = args.energy_threshold
    # Definitely do this, dynamic energy compensation lowers the energy threshold dramtically to a point where the SpeechRecognizer never stops recording.
    recorder.dynamic_energy_threshold = False

    source = sr.Microphone(sample_rate=16000)
    with source:
        recorder.adjust_for_ambient_noise(source)

    def record_callback(_, audio:sr.AudioData) -> None:
        """
        Threaded callback function to recieve audio data when recordings finish.
        audio: An AudioData containing the recorded bytes.
        """
        # Grab the raw bytes and push it into the thread safe queue.
        data = audio.get_raw_data()
        data_queue.put(data)

    # Create a background thread that will pass us raw audio bytes.
    # We could do this manually but SpeechRecognizer provides a nice helper.
    recorder.listen_in_background(source, record_callback, phrase_time_limit=record_timeout)

    # Cue the user that we're ready to go.
    print("Model loaded.\n")

    while True:
        try:
            now = datetime.utcnow()
            # Pull raw recorded audio from the queue.
            if not data_queue.empty():
                phrase_complete = False
                # If enough time has passed between recordings, consider the phrase complete.
                # Clear the current working audio buffer to start over with the new data.
                if phrase_time and now - phrase_time > timedelta(seconds=phrase_timeout):
                    last_sample = bytes()
                    phrase_complete = True
                # This is the last time we received new audio data from the queue.
                phrase_time = now

                # Concatenate our current audio data with the latest audio data.
                while not data_queue.empty():
                    data = data_queue.get()
                    last_sample += data

                # Use AudioData to convert the raw data to wav data.
                audio_data = sr.AudioData(last_sample, source.SAMPLE_RATE, source.SAMPLE_WIDTH)
                wav_data = io.BytesIO(audio_data.get_wav_data())

                # Write wav data to the temporary file as bytes.
                with open(temp_file, 'w+b') as f:
                    f.write(wav_data.read())

                # Read the transcription.
                result = audio_model.transcribe(temp_file)
                text = result['text'].strip()

                # If we detected a pause between recordings, add a new item to our transcripion.
                # Otherwise edit the existing one.
                if phrase_complete:
                    transcription.append(text)
                else:
                    transcription[-1] = text

                # Clear the console to reprint the updated transcription.
                os.system('cls' if os.name=='nt' else 'clear')
                for line in transcription:
                    print(line)
                # Flush stdout.
                print('', end='', flush=True)

                # Infinite loops are bad for processors, must sleep.
                sleep(0.25)
        except KeyboardInterrupt:
            break

    print("\n\nTranscription:")
    for line in transcription:
        print(line)


if __name__ == "__main__":
    main()
Make real time transcription demo with OpenAI Whisper. 2022-11-28 22:27:56 -08:00			`#! python3.7`

			`import argparse`
			`import io`
			`import os`
			`import speech_recognition as sr`
			`import whisper`

			`from datetime import datetime, timedelta`
			`from queue import Queue`
			`from tempfile import NamedTemporaryFile`
			`from time import sleep`


			`def main():`
			`parser = argparse.ArgumentParser()`
			`parser.add_argument("--model", default="medium", help="Model to use",`
			`choices=["tiny", "base", "small", "medium", "large"])`
			`parser.add_argument("--non_english", action='store_true',`
			`help="Don't use the english model.")`
			`parser.add_argument("--energy_threshold", default=1000,`
			`help="Energy level for mic to detect.", type=int)`
			`parser.add_argument("--record_timeout", default=2,`
			`help="How real time the recording is in seconds.", type=float)`
			`parser.add_argument("--phrase_timeout", default=3,`
			`help="How much empty space between recordings before we "`
			`"consider it a new line in the transcription.", type=float)`
			`args = parser.parse_args()`

			`model = args.model`
			`if args.model != "large" and not args.non_english:`
			`model = model + ".en"`
			`audio_model = whisper.load_model(model)`

			`record_timeout = args.record_timeout`
			`phrase_timeout = args.phrase_timeout`

			`temp_file = NamedTemporaryFile().name`
			`transcription = ['']`

			`# The last time a recording was retreived from the queue.`
			`phrase_time = None`
			`# Current raw audio bytes.`
			`last_sample = bytes()`
			`# Thread safe Queue for passing data from the threaded recording callback.`
			`data_queue = Queue()`

			`# We use SpeechRecognizer to record our audio because it has a nice feauture where it can detect when speech ends.`
			`recorder = sr.Recognizer()`
			`recorder.energy_threshold = args.energy_threshold`
			`# Definitely do this, dynamic energy compensation lowers the energy threshold dramtically to a point where the SpeechRecognizer never stops recording.`
			`recorder.dynamic_energy_threshold = False`

			`source = sr.Microphone(sample_rate=16000)`
			`with source:`
			`recorder.adjust_for_ambient_noise(source)`

			`def record_callback(_, audio:sr.AudioData) -> None:`
			`"""`
			`Threaded callback function to recieve audio data when recordings finish.`
			`audio: An AudioData containing the recorded bytes.`
			`"""`
			`# Grab the raw bytes and push it into the thread safe queue.`
			`data = audio.get_raw_data()`
			`data_queue.put(data)`

			`# Create a background thread that will pass us raw audio bytes.`
			`# We could do this manually but SpeechRecognizer provides a nice helper.`
			`recorder.listen_in_background(source, record_callback, phrase_time_limit=record_timeout)`

			`# Cue the user that we're ready to go.`
			`print("Model loaded.\n")`

			`while True:`
			`try:`
			`now = datetime.utcnow()`
			`# Pull raw recorded audio from the queue.`
			`if not data_queue.empty():`
			`phrase_complete = False`
			`# If enough time has passed between recordings, consider the phrase complete.`
			`# Clear the current working audio buffer to start over with the new data.`
			`if phrase_time and now - phrase_time > timedelta(seconds=phrase_timeout):`
			`last_sample = bytes()`
			`phrase_complete = True`
			`# This is the last time we received new audio data from the queue.`
			`phrase_time = now`

			`# Concatenate our current audio data with the latest audio data.`
			`while not data_queue.empty():`
			`data = data_queue.get()`
			`last_sample += data`

			`# Use AudioData to convert the raw data to wav data.`
			`audio_data = sr.AudioData(last_sample, source.SAMPLE_RATE, source.SAMPLE_WIDTH)`
			`wav_data = io.BytesIO(audio_data.get_wav_data())`

			`# Write wav data to the temporary file as bytes.`
			`with open(temp_file, 'w+b') as f:`
			`f.write(wav_data.read())`

			`# Read the transcription.`
			`result = audio_model.transcribe(temp_file)`
			`text = result['text'].strip()`

			`# If we detected a pause between recordings, add a new item to our transcripion.`
			`# Otherwise edit the existing one.`
			`if phrase_complete:`
			`transcription.append(text)`
			`else:`
			`transcription[-1] = text`

			`# Clear the console to reprint the updated transcription.`
			`os.system('cls' if os.name=='nt' else 'clear')`
			`for line in transcription:`
			`print(line)`
			`# Flush stdout.`
			`print('', end='', flush=True)`

			`# Infinite loops are bad for processors, must sleep.`
			`sleep(0.25)`
			`except KeyboardInterrupt:`
			`break`

			`print("\n\nTranscription:")`
			`for line in transcription:`
			`print(line)`


			`if __name__ == "__main__":`
			`main()`