Whisper realtime streaming for long speech-to-text transcription and translation
Turning Whisper into Real-Time Transcription System
Demonstration paper, by Dominik Macháček, Raj Dabre, Ondřej Bojar, 2023
Abstract: Whisper is one of the recent state-of-the-art multilingual speech recognition and translation models, however, it is not designed for real time transcription. In this paper, we build on top of Whisper and create Whisper-Streaming, an implementation of real-time speech transcription and translation of Whisper-like models. Whisper-Streaming uses local agreement policy with self-adaptive latency to enable streaming transcription. We show that Whisper-Streaming achieves high quality and 3.3 seconds latency on unsegmented long-form speech transcription test set, and we demonstrate its robustness and practical usability as a component in live transcription service at a multilingual conference.
Paper in proceedings: http://www.afnlp.org/conferences/ijcnlp2023/proceedings/main-demo/cdrom/pdf/2023.ijcnlp-demo.3.pdf
Demo video: https://player.vimeo.com/video/840442741
Slides -- 15 minutes oral presentation at IJCNLP-AACL 2023
Please, cite us. Bibtex citation:
@InProceedings{machacek-dabre-bojar:2023:ijcnlp,
author = {Macháček, Dominik and Dabre, Raj and Bojar, Ondřej},
title = {Turning Whisper into Real-Time Transcription System},
booktitle = {System Demonstrations},
month = {November},
year = {2023},
address = {Bali, Indonesia},
publisher = {Asian Federation of Natural Language Processing},
pages = {17--24},
}
-
pip install librosa
-- audio processing library -
Whisper backend.
Two alternative backends are integrated. The most recommended one is faster-whisper with GPU support. Follow their instructions for NVIDIA libraries -- we succeeded with CUDNN 8.5.0 and CUDA 11.7. Install with pip install faster-whisper
.
Alternative, less restrictive, but slower backend is whisper-timestamped: pip install git+https://github.com/linto-ai/whisper-timestamped
The backend is loaded only when chosen. The unused one does not have to be installed.
- Optional, not recommended: sentence segmenter (aka sentence tokenizer)
Two buffer trimming options are integrated and evaluated. They have impact on the quality and latency. The default "segment" option performs better according to our tests and does not require any sentence segmentation installed.
The other option, "sentence" -- trimming at the end of confirmed sentences, requires sentence segmenter installed. It splits punctuated text to sentences by full stops, avoiding the dots that are not full stops. The segmenters are language specific. The unused one does not have to be installed. We integrate the following segmenters, but suggestions for better alternatives are welcome.
-
pip install opus-fast-mosestokenizer
for the languages with codesas bn ca cs de el en es et fi fr ga gu hi hu is it kn lt lv ml mni mr nl or pa pl pt ro ru sk sl sv ta te yue zh
-
pip install tokenize_uk
for Ukrainian --uk
-
for other languages, we integrate a good performing multi-lingual model of
wtpslit
. It requirespip install torch wtpsplit
, and its neural modelwtp-canine-s-12l-no-adapters
. It is downloaded to the default huggingface cache during the first use. -
we did not find a segmenter for languages
as ba bo br bs fo haw hr ht jw lb ln lo mi nn oc sa sd sn so su sw tk tl tt
that are supported by Whisper and not by wtpsplit. The default fallback option for them is wtpsplit with unspecified language. Alternative suggestions welcome.
In case of installation issues of opus-fast-mosestokenizer, especially on Windows and Mac, we recommend using only the "segment" option that does not require it.
usage: whisper_online.py [-h] [--min-chunk-size MIN_CHUNK_SIZE] [--model {tiny.en,tiny,base.en,base,small.en,small,medium.en,medium,large-v1,large-v2,large-v3,large}] [--model_cache_dir MODEL_CACHE_DIR] [--model_dir MODEL_DIR] [--lan LAN] [--task {transcribe,translate}]
[--backend {faster-whisper,whisper_timestamped}] [--vad] [--buffer_trimming {sentence,segment}] [--buffer_trimming_sec BUFFER_TRIMMING_SEC] [--start_at START_AT] [--offline] [--comp_unaware]
audio_path
positional arguments:
audio_path Filename of 16kHz mono channel wav, on which live streaming is simulated.
options:
-h, --help show this help message and exit
--min-chunk-size MIN_CHUNK_SIZE
Minimum audio chunk size in seconds. It waits up to this time to do processing. If the processing takes shorter time, it waits, otherwise it processes the whole segment that was received by this time.
--model {tiny.en,tiny,base.en,base,small.en,small,medium.en,medium,large-v1,large-v2,large-v3,large}
Name size of the Whisper model to use (default: large-v2). The model is automatically downloaded from the model hub if not present in model cache dir.
--model_cache_dir MODEL_CACHE_DIR
Overriding the default model cache dir where models downloaded from the hub are saved
--model_dir MODEL_DIR
Dir where Whisper model.bin and other files are saved. This option overrides --model and --model_cache_dir parameter.
--lan LAN, --language LAN
Source language code, e.g. en,de,cs, or 'auto' for language detection.
--task {transcribe,translate}
Transcribe or translate.
--backend {faster-whisper,whisper_timestamped}
Load only this backend for Whisper processing.
--vad Use VAD = voice activity detection, with the default parameters.
--buffer_trimming {sentence,segment}
Buffer trimming strategy -- trim completed sentences marked with punctuation mark and detected by sentence segmenter, or the completed segments returned by Whisper. Sentence segmenter must be installed for "sentence" option.
--buffer_trimming_sec BUFFER_TRIMMING_SEC
Buffer trimming length threshold in seconds. If buffer length is longer, trimming sentence/segment is triggered.
--start_at START_AT Start processing audio at this time.
--offline Offline mode.
--comp_unaware Computationally unaware simulation.
Example:
It simulates realtime processing from a pre-recorded mono 16k wav file.
python3 whisper_online.py en-demo16.wav --language en --min-chunk-size 1 > out.txt
Simulation modes:
-
default mode, no special option: real-time simulation from file, computationally aware. The chunk size is
MIN_CHUNK_SIZE
or larger, if more audio arrived during last update computation. -
--comp_unaware
option: computationally unaware simulation. It means that the timer that counts the emission times "stops" when the model is computing. The chunk size is alwaysMIN_CHUNK_SIZE
. The latency is caused only by the model being unable to confirm the output, e.g. because of language ambiguity etc., and not because of slow hardware or suboptimal implementation. We implement this feature for finding the lower bound for latency. -
--start_at START_AT
: Start processing audio at this time. The first update receives the whole audio bySTART_AT
. It is useful for debugging, e.g. when we observe a bug in a specific time in audio file, and want to reproduce it quickly, without long waiting. -
--offline
option: It processes the whole audio file at once, in offline mode. We implement it to find out the lowest possible WER on given audio file.
2691.4399 300 1380 Chairman, thank you.
6914.5501 1940 4940 If the debate today had a
9019.0277 5160 7160 the subject the situation in
10065.1274 7180 7480 Gaza
11058.3558 7480 9460 Strip, I might
12224.3731 9460 9760 have
13555.1929 9760 11060 joined Mrs.
14928.5479 11140 12240 De Kaiser and all the
16588.0787 12240 12560 other
18324.9285 12560 14420 colleagues across the
TL;DR: use OnlineASRProcessor object and its methods insert_audio_chunk and process_iter.
The code whisper_online.py is nicely commented, read it as the full documentation.
This pseudocode describes the interface that we suggest for your implementation. You can implement any features that you need for your application.
from whisper_online import *
src_lan = "en" # source language
tgt_lan = "en" # target language -- same as source for ASR, "en" if translate task is used
asr = FasterWhisperASR(lan, "large-v2") # loads and wraps Whisper model
# set options:
# asr.set_translate_task() # it will translate from lan into English
# asr.use_vad() # set using VAD
online = OnlineASRProcessor(asr) # create processing object with default buffer trimming option
while audio_has_not_ended: # processing loop:
a = # receive new audio chunk (and e.g. wait for min_chunk_size seconds first, ...)
online.insert_audio_chunk(a)
o = online.process_iter()
print(o) # do something with current partial output
# at the end of this audio processing
o = online.finish()
print(o) # do something with the last output
online.init() # refresh if you're going to re-use the object for the next audio
whisper_online_server.py
has the same model options as whisper_online.py
, plus --host
and --port
of the TCP connection. See help message (-h
option).
Client example:
arecord -f S16_LE -c1 -r 16000 -t raw -D default | nc localhost 43001
-
arecord sends realtime audio from a sound device (e.g. mic), in raw audio format -- 16000 sampling rate, mono channel, S16_LE -- signed 16-bit integer low endian. (use the alternative to arecord that works for you)
-
nc is netcat with server's host and port
Default Whisper is intended for audio chunks of at most 30 seconds that contain one full sentence. Longer audio files must be split to shorter chunks and merged with "init prompt". In low latency simultaneous streaming mode, the simple and naive chunking fixed-sized windows does not work well, it can split a word in the middle. It is also necessary to know when the transcribt is stable, should be confirmed ("commited") and followed up, and when the future content makes the transcript clearer.
For that, there is LocalAgreement-n policy: if n consecutive updates, each with a newly available audio stream chunk, agree on a prefix transcript, it is confirmed. (Reference: CUNI-KIT at IWSLT 2022 etc.)
In this project, we re-use the idea of Peter Polák from this demo:
https://github.com/pe-trik/transformers/blob/online_decode/examples/pytorch/online-decoding/whisper-online-demo.py
However, it doesn't do any sentence segmentation, but Whisper produces
punctuation and the libraries faster-whisper
and whisper_transcribed
make
word-level timestamps. In short: we
consecutively process new audio chunks, emit the transcripts that are confirmed
by 2 iterations, and scroll the audio processing buffer on a timestamp of a
confirmed complete sentence. The processing audio buffer is not too long and
the processing is fast.
In more detail: we use the init prompt, we handle the inaccurate timestamps, we re-process confirmed sentence prefixes and skip them, making sure they don't overlap, and we limit the processing buffer window.
Contributions are welcome.
Dominik Macháček, machacek@ufal.mff.cuni.cz