dimastatz
whisper-flow
Python

Whisper-Flow is a framework designed to enable real-time transcription of audio content using OpenAI’s Whisper model. Rather than processing entire files after upload (“batch mode”), Whisper-Flow accepts a continuous stream of audio chunks and produces incremental transcripts immediately.

Last updated Jul 8, 2026
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README

Whisper Flow

Real-Time Transcription Using OpenAI Whisper



About The Project

OpenAI Whisper

OpenAI Whisper is a versatile speech recognition model designed for general use. Trained on a vast and varied audio dataset, Whisper can handle tasks such as multilingual speech recognition, speech translation, and language identification. It is commonly used for batch transcription, where you provide the entire audio or video file to Whisper, which then converts the speech into text. This process is not done in real-time; instead, Whisper processes the files and returns the text afterward, similar to handing over a recording and receiving the transcript later.

Whisper Flow

Using Whisper Flow, you can generate real-time transcriptions for your media content. Unlike batch transcriptions, where media files are uploaded and processed, streaming media is delivered to Whisper Flow in real time, and the service returns a transcript immediately.

What is Streaming

Streaming content is sent as a series of sequential data packets, or 'chunks,' which Whisper Flow transcribes on the spot. The benefits of using streaming over batch processing include the ability to incorporate real-time speech-to-text functionality into your applications and achieving faster transcription times. However, this speed may come at the expense of accuracy in some cases.

Stream Windowing

In scenarios involving time-streaming, it's typical to perform operations on data within specific time frames known as temporal windows. One common approach is using the tumbling window technique, which involves gathering events into segments until a certain condition is met.

Tumbling Window

Streaming Results

Whisper Flow splits the audio stream into segments based on natural speech patterns, like speaker changes or pauses. The transcription is sent back as a series of events, with each response containing more transcribed speech until the entire segment is complete.

| Transcript | EndTime | IsPartial | | :-------------------------------------------- | :------: | --------: | | Reality | 0.55 | True | | Reality is created | 1.05 | True | | Reality is created by the | 1.50 | True | | Reality is created by the mind | 2.15 | True | | Reality is created by the mind | 2.65 | False | | we can | 3.05 | True | | we can change | 3.45 | True | | we can change reality | 4.05 | True | | we can change reality by changing | 4.45 | True | | we can change reality by changing our mind | 5.05 | True | | we can change reality by changing our mind | 5.55 | False |

Benchmarking

The evaluation metrics for comparing the performance of Whisper Flow are Word Error Rate (WER) and latency. Latency is measured as the time between two subsequent partial results, with the goal of achieving sub-second latency. We're not starting from scratch, as several quality benchmarks have already been performed for different ASR engines. I will rely on the research article "Benchmarking Open Source and Paid Services for Speech to Text" for guidance. For benchmarking the current implementation of Whisper Flow, I use LibriSpeech.
| Partial | Latency | Result |

True 175.47 when we took True 185.14 When we took her. True 237.83 when we took our seat. True 176.42 when we took our seats. True 198.59 when we took our seats at the True 186.72 when we took our seats at the True 210.04 when we took our seats at the breakfast. True 220.36 when we took our seats at the breakfast table. True 203.46 when we took our seats at the breakfast table. True 242.63 When we took our seats at the breakfast table, it will True 237.41 When we took our seats at the breakfast table, it was with True 246.36 When we took our seats at the breakfast table, it was with the True 278.96 When we took our seats at the breakfast table, it was with the feeling. True 285.03 When we took our seats at the breakfast table, it was with the feeling of being. True 295.39 When we took our seats at the breakfast table, it was with the feeling of being no True 270.88 When we took our seats at the breakfast table, it was with the feeling of being no longer True 320.43 When we took our seats at the breakfast table, it was with the feeling of being no longer looked True 303.66 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon. True 470.73 When we took our seats at the breakfast table, it was with the feeling of being no longer True 353.25 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon as connected. True 345.74 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon as connected in any way. True 368.66 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon as connected in any way with the True 400.25 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon as connected in any way with this case. True 382.71 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon as connected in any way with this case. False 405.02 When we took our seats at the breakfast table, it was with the feeling of being no longer looked upon as connected in any way with this case.

When running this benchmark on a MacBook Air with an M1 chip and 16GB of RAM, we achieve impressive performance metrics. The latency is consistently well below 500ms, ensuring real-time responsiveness. Additionally, the word error rate is around 7%, demonstrating the accuracy of the transcription.

Latency Stats:
count     26.000000
mean     275.223077
std       84.525695
min      154.700000
25%      205.105000
50%      258.620000
75%      339.412500
max      470.700000

Prerequisites

Before installing WhisperFlow, ensure you have the following:

  • Python: 3.8 or higher (tested with Python 3.12)
  • PortAudio: Required for PyAudio (audio I/O library)

Installing PortAudio

macOS (using Homebrew):

brew install portaudio

Linux (Ubuntu/Debian):

sudo apt-get install portaudio19-dev

Linux (Fedora/RHEL):

sudo dnf install portaudio-devel

Windows: PortAudio is typically bundled with PyAudio wheels on Windows. If you encounter issues, refer to the PyAudio documentation.

How To Use it

Quick Start

Get WhisperFlow running in under 5 minutes:

# Clone the repository
git clone https://github.com/dimastatz/whisper-flow.git
cd whisper-flow

Setup environment, install dependencies, and run tests

./run.sh -local

Activate the virtual environment

source .venv/bin/activate

Start the server on port 8181

./run.sh -run-server

The server will be available at http://localhost:8181. Visit http://localhost:8181/health to verify it's running.


Development Setup

For contributors and developers:

1. Initial Setup

# Clone and enter the directory
git clone https://github.com/dimastatz/whisper-flow.git
cd whisper-flow

Setup environment: creates .venv, installs dependencies, runs tests

./run.sh -local

What -local does:

  • Creates a fresh virtual environment (.venv)
  • Installs all dependencies from requirements.txt
  • Runs black formatter on code
  • Runs pylint linter (requires 9.9/10 score)
  • Runs all unit tests (requires 95% coverage)

2. Running Tests

# Activate environment source .venv/bin/activate

Run tests only (formatting + linting + unit tests)

./run.sh -test

3. Running the Server

# Activate environment
source .venv/bin/activate

Start the FastAPI server on port 8181

./run.sh -run-server

The server provides:

  • WebSocket endpoint: ws://localhost:8181/ws - Real-time streaming transcription
  • Health check: GET http://localhost:8181/health - Server status
  • Batch transcription: POST http://localhost:8181/transcribepcmchunk - Process PCM audio files

4. Running Benchmarks

# Activate environment source .venv/bin/activate

Run benchmark tests (starts server, runs tests, stops server)

./run.sh -benchmark

This measures transcription latency and word error rate (WER) using LibriSpeech test data.


Docker Deployment

Using Docker

# Build and run the Docker container
./run.sh -docker

What -docker does:

  • Stops and removes any existing whisperflow-container
  • Removes the old whisperflow-image
  • Builds a fresh Docker image with all dependencies
  • Runs the container on port 8888

Manual Docker Setup

# Build the image docker build -t whisperflow-image --file Dockerfile.test .

Run the container

docker run --name whisperflow-container -p 8181:8181 -d whisperflow-image

Check logs

docker logs whisperflow-container

Stop the container

docker stop whisperflow-container

Using as a Python Library

Install WhisperFlow as a package to integrate real-time transcription into your own applications:

Installation

pip install whisperflow

Basic Usage

Create a WebSocket endpoint for real-time streaming transcription:

from fastapi import FastAPI, WebSocket
from starlette.websockets import WebSocketDisconnect
import whisperflow.streaming as st
import whisperflow.transcriber as ts

app = FastAPI()

@app.websocket("/ws") async def websocket_endpoint(websocket: WebSocket): # Load the Whisper model (default: tiny.en.pt) model = ts.get_model() # Define transcription callback async def transcribe_async(chunks: list): return await ts.transcribepcmchunks_async(model, chunks) # Define response callback async def sendbackasync(data: dict): await websocket.send_json(data) try: await websocket.accept() # Create transcription session session = st.TranscribeSession(transcribeasync, sendback_async) # Process incoming audio chunks while True: data = await websocket.receive_bytes() session.add_chunk(data) except WebSocketDisconnect: # Client disconnected await session.stop() except Exception as exception: # Handle errors await session.stop() if websocket.client_state.name != "DISCONNECTED": await websocket.close()

API Reference

Transcriber Module (whisperflow.transcriber):

  • getmodel(filename="tiny.en.pt") - Load a Whisper model
  • transcribepcmchunks(model, chunks, lang="en") - Synchronous transcription
  • transcribepcmchunks_async(model, chunks, lang="en") - Async transcription
Streaming Module (whisperflow.streaming):
  • TranscribeSession(transcribefn, sendback_fn) - Create a streaming session
  • session.addchunk(audiodata) - Add audio chunk for processing
  • session.stop() - Stop the transcription session

Audio Format Requirements

WhisperFlow expects PCM audio data with the following specifications:

  • Sample Rate: 16 kHz
  • Channels: Mono (1 channel)
  • Format: 16-bit signed integer (int16)

Available Commands

All commands are available through ./run.sh:

| Command | Description | |---------|-------------| | ./run.sh -local | Setup environment, install dependencies, run tests | | ./run.sh -test | Run formatter, linter, and unit tests | | ./run.sh -run-server | Start the FastAPI server on port 8181 | | ./run.sh -benchmark | Run performance benchmark tests | | ./run.sh -docker | Build and run Docker container |


Roadmap

  • [X] Release v1.0-RC - Includes transcription streaming implementation.
  • [X] Release v1.1 - Bug fixes and implementation of the most requested changes.
  • [ ] Release v1.2 - Prepare the package for integration with the py-speech package.

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