Docs: https://8ff.github.io/firescrew/

Firescrew is a cutting-edge application written in Go that enables real-time object and motion detection from an RTSP network camera. It leverages advanced image processing techniques and machine learning models to identify specific objects such as cars, people, and more.

• Real-Time Motion Detection: Firescrew can detect motion from a live feed and provide real-time alerts.
• Object Identification: Identify specific objects like cars and people in real-time.
• Model Flexibility: Firescrew can use the latest YOLOv8 model, MobileNET with Coral TPU or YOLOv8s with CoreML (MAC Only) for enhanced performance.
• Performance: Firescrew takes full advantage of Go's concurrency handling and speed, providing a high-performance solution for real-time image processing.
• RTSP Network Camera Support: Firescrew is compatible with RTSP network cameras, extending its applicability in a wide range of scenarios.
• MQTT/Webhook/Script/Slack: Firescrew can send events to MQTT/Webhook/Script/Slack for further processing.
• Natural Language Search: Firescrew supports natural language processing for searching events based on time/type/camera.
• In-House Quality Control: At Firescrew, we believe in sampling our own "product," chasing the next high in innovation like caffeine-fueled engineers on a coding binge. We don't just build technology; we live it, breathe it, and occasionally spill coffee on it – all to ensure we're delivering a product that's up to snuff!

Things added/fixed in last 3 days:
- Added CoreML YoloV8s (Mac only)
- Added MQTT/Webhook/ScriptHook/Slack support!
- Added ffprobe timeout/Fixed MQTT port in template/Added docs page
- Added inference statistics and much more!
- Fixed Coral TPU model detection
- Performance updates for model adapters
- Discord server has been added
- Docker image will now fetch latest binaries from github at runtime
- Fixed ffprobe ftps parsing/Added resolution/fps bypass parameters

docker run --rm -it -p 8080:8080 8fforg/firescrew:latest demo

# Point your browser to http://localhost:8080

WebUI Supports natural language processing for searching events, here are some of the examples:

• Today & Yesterday:
  • today
  • today 8am
  • yesterday 3pm
• Specific Dates:
  • august 15th 10am
  • last friday 2pm
• Ranges: Supports from/to and between/and ranges
  • from july 7th 5pm to july 7th 6pm
  • last tuesday between 1pm and 2pm
• With Keywords:
  • people cars today between 10am and 1pm
• With Camera Name
  • front cars today

• Background color of the events signify the same event to make it easier to separate them

docker pull 8fforg/firescrew:latest

Firescrew leverages the capabilities of ffmpeg to ensure optimal performance and broad compatibility, you will need to install it before use.

apt-get install ffmpeg
pip3 install ultralytics
curl -O firescrew -L https://github.com/8ff/firescrew/releases/download/latest/firescrew.linux.amd64 && chmod +x firescrew

Generate config

# Store template config in config.json
docker run --rm -it 8fforg/firescrew:latest -t > config.json

Run

# Run with config.json and mount media folder for persistent storage
docker run --rm -v $(pwd)/media:/media -v $(pwd)/config.json:/config.json -it 8fforg/firescrew:latest /config.json

Serving from Docker

# Serve from ./media on port 8080 (./media must be defined in config.json)
docker run --rm -p 8080:8080 -it -v $(pwd)/media:/media 8fforg/firescrew:latest -s /media :8080

Using Coral TPU with Docker

lsusb | grep Google
# Take Bus and Device from the output of the above command and replace [bus] and [device] in the below command
docker run -d --device=/dev/bus/usb/[bus]/[device] -v config.json:config.json 8fforg/firescrew:latest

Help menu

root@debian:~docker run --rm -it 8fforg/firescrew:latest -h
Usage: firescrew [configfile]
  -t, --template, t     Prints the template config to stdout
  -h, --help, h         Prints this help message
  -s, --serve, s        Starts the web server, requires: [path] [addr]
  -v, --version, v      Prints the version
  -update, --update, update     Updates firescrew to the latest version

Create a template config file

./firescrew -t > config.json

Start object detection

./firescrew config.json

Starting WebUI

./firescrew -s rec/hi :8080

This will start a demo stream at rtsp://localhost:8553/lo and rtsp://localhost:8554/hi

cd demoStream && ./startDemoStream.sh

Usage: firescrew [configfile]
  -t, --template, t     Prints the template config to stdout
  -h, --help, h         Prints this help message
  -s, --serve, s        Starts the web server, requires: [path] [addr]
  -v, --version, v      Prints the version
  -update, --update, update     Updates firescrew to the latest version

Min Time: 16.369294ms, Max Time: 1.748422882s, Avg Time: 20.55754ms, Count: 500
50th: 16.787455ms, 90th: 17.206168ms, 99th: 27.898232ms

Min Time: 15.337001ms, Max Time: 1.931347977s, Avg Time: 28.308399ms, Count: 500
50th: 24.313751ms, 90th: 25.290932ms, 99th: 34.881259ms

Min Time: 32.435875ms, Max Time: 53.711166ms, Avg Time: 35.725131ms, Count: 500
50th: 35.232417ms, 90th: 37.851167ms, 99th: 44.405792ms

Min Time: 103.251637ms, Max Time: 308.058517ms, Avg Time: 120.917971ms, Count: 500
50th: 116.531572ms, 90th: 126.291139ms, 99th: 230.462122ms

Docker image already includes everything you need to get started but if you choose to run manually and use YoloV8 model, you will need to install the Ultralytics dependencies. You can do this by running the following command:

    pip3 install ultralytics

This command installs the Ultralytics package which includes the necessary dependencies for the YOLOv8 model. If you encounter any problems during the installation, or you're looking for more advanced setup instructions, please refer to the Ultralytics Quick Start Guide. Note: Make sure you have Python and pip (or pip3) installed on your system before running these commands. Ensure that your Python environment is properly set up and is compatible with the YOLOv8 model requirements.

If you choose to use the EdgeTPU model via the Python adapter for faster and more accurate detection, you will need to install the Ultralytics dependencies. You can do this by running the following command:

pip3 install pycoral numpy Pillow

This has been tested working on M1/M2 MacOS 13.4.1, it works when using python3.10 and not 3.11

git clone https://github.com/8ff/firescrew && cd firescrew/assets
pip3.10 install coremltools Pillow
./objectDetectServerCoreML.py

Now in your config.json file set "networkObjectDetectServer": "", addr:8555 where addr is the ip of your machine running the above script

Firescrew supports two different RTSP camera streams: a low resolution stream (deviceUrl) and a high resolution stream (hiResDeviceUrl). These streams are used for different purposes and should be set up accordingly. The deviceUrl should be set to a low resolution video feed, typically around 640x360. This stream is used for motion detection. Note that the resolution of this stream significantly impacts the CPU usage. A higher resolution will lead to more CPU usage, so it is recommended to keep this stream at a lower resolution. The hiResDeviceUrl should be set to a high resolution video feed, such as 1080p or higher. This stream is used to store video clips of motion events. As this stream is not used for motion detection, it can handle higher resolutions, enabling the capture of more detail in the recorded video clips. Firescrew uses tcp for RTSP streams by default to avoid lost frames. If you camera does not support tcp - please open an issue and we will add support for it.

Firescrew uses a JSON configuration file for its settings. Here is a brief explanation of the various configuration parameters:

{
    "cameraName": "", // This will be used in the video file metadata to identify which camera the clip belongs to
    "deviceUrl": "", // URL of the low resolution video feed.
        "loStreamParamBypass": { // With some cameras ffprobe may not return the correct resolution, you can use this to bypass it
        "width": 0,
        "height": 0,
        "fps": 0
    },
    "hiResDeviceUrl": "", // URL of the high resolution video feed.
        "hiStreamParamBypass": { // With some cameras ffprobe may not return the correct resolution, you can use this to bypass it
        "width": 0,
        "height": 0,
        "fps": 0
    },
    "useEmbeddedSSDMobileNetV1Model": false, // If true, modelFile and modelConfig dont need to be specified as the embedded version of SSDMobileNetV1 will be used.
    "modelFile": "", // Path to the .pb file of the model.
    "modelConfig": "", // Path to the .pbtxt file of the model configuration.
    "printDebug": false, // If true, debug information will be printed.
    "video": {
        "hiResPath": "", // Path where high-resolution videos are stored.
        "recodeTsToMp4": true, // To lower cpu usage, HI res clips are stored in original format, in order to play these clips in every browser, set this to true. After every event end, clips will be recoded to mp4.
        "onlyRemuxMp4": true // Instead of doing re-encode, it will only remux the .mp4. This saves cpu usage and should work for most. If you are unable to play the videos in the browser, set this to false.
    },
    "motion": {
        "confidenceMinThreshold": 0.3, // Minimum threshold for object detection. Range: 0.0 - 1
        "lookForClasses": [], // Array of classes that the model should look for. Typically: ["car", "truck", "person", "bicycle", "motorcycle", "bus", "cat", "dog", "boat"]
        "onnxModel": "yolov8n",
        "onnxEnableCoreMl": true,
        "embeddedObjectScript": "objectDetectServerYolo.py", // Options are objectDetectServerYolo.py (YOLOV8), objectDetectServerCoral.py (EdgeTPU Coral TPU)
        "networkObjectDetectServer": "", // Address of the network object detection server.
        "prebufferSeconds": 10, // Number of seconds to prebuffer before the motion event.
        "eventGap": 30 // Gap between events in seconds.
    },
    "pixelMotionAreaThreshold": 50.00, // Minimum pixel motion area for an event to be triggered and passed to object detection.
    "objectCenterMovementThreshold": 50.0, // For stationary objects, minimum distance the center of an object should move for an event to be be considered new.
    "objectAreaThreshold": 2000.0, // For stationary objects, difference in area of a bounding box to consider object as new.
    "ignoreAreasClasses": [
        // Array of classes and corresponding coordinates that should be ignored. Coordinates can be generated using getDimensions param.
        {"class": [], "coordinates": ""},
    ],
    "streamDrawIgnoredAreas": true, // If true, ignored areas will be drawn on the stream.
    "enableOutputStream": true, // If true, an output stream will be enabled.
    "outputStreamAddr":, "" // Address of the output stream. Eg: 0.0.0.0:8050
        "events": { 
        "webhookUrl": "", // POST request will be made to this url for every event.
        "scriptPath": "", // JSON string will be piped to STDIN of this script for every event. Example script can be found in assets/eventHandler.sh
        "slack": {
            "url": "" }, // JSON will be sent to this slack webhook for every event.
        "mqtt": { // JSON will be sent to this MQTT server for every event.
            "host": "broker.hivemq.com",
            "port": 1883,
            "user": "",
            "password": "",
            "topic": "firescrew"
        }
    },
    "notifications": {
        "enablePushoverAlerts": true, // If true, pushover alerts will be enabled.
        "pushoverAppToken": "", // Place your pushover App Token here for realtime notifications
        "pushoverUserKey" :"" // Place your pushover User Key here for realtime notifications
    }
}

Firescrew's performance has been meticulously examined and optimized to ensure the fastest and most reliable object detection. The key aspects of this examination include comparing different RTSP feed methods and evaluating various model object detections. Here are the details:

Motion detection system operates in two stages to optimize resource usage and deliver accurate results:

1. Event-Based Motion Check:

   • If there is an active motion-triggered event, the system directly proceeds to object detection.
   • If no active event is detected, the system compares the amount of changed pixels between consecutive frames.
   • This is done to avoid wasting CPU cycles and also to avoid missing objects once motion has been triggered.

2. Pixel Change Threshold:

   • A threshold defined in objectAreaThreshold is used to determine significant changes between frames.
   • If the changes exceed this threshold, the frame is considered for further analysis.
   • While it's difficult to have a value that fits all use cases, this approach helps reduce CPU usage as it has a lower cost than object detection.

3. Object Detection:

   • The frame, if qualified through the above stages, is passed to an object detection model.
   • We use either YOLOv8 or Coral Edge TPU for object detection, depending on the configuration.
   • After extensive testing, this setup has been found to offer the best balance between accuracy and resource consumption.

The project continues to evolve, with a focus on enhancing performance and lowering resource consumption for an even more efficient and robust motion detection solution.

Three different methods for parsing RTSP feeds were tested:

• GoCV RTSP Feed: Utilized the GoCV library to handle RTSP feeds.
• GoRTSP Feed: Utilized the GoRTSP library for RTSP feed handling.
• FFmpeg Command: Employed FFmpeg commands to parse RTSP feeds.

Among these, using the FFmpeg command was found to be the fastest and most compatible between RTSP feeds. This approach not only delivered superior speed but also ensured broad compatibility across different types of RTSP feeds.

Two primary models were examined for object detection:

• Golang MobileNET: This built-in Go model was tested for object detection capabilities.
• YOLOv8: The YOLOv8 model was examined via a Python adapter for faster and more accurate detection.

The comparison clearly revealed that YOLOv8 outperformed the Golang MobileNET in both speed and quality. The detection was faster, and the quality of object identification was much better with YOLOv8.

Based on these comprehensive performance tests, Firescrew has adopted the use of the FFmpeg command for RTSP feed handling and the YOLOv8 model for object detection. This decision ensures the delivery of a fast, accurate, and high-quality solution for real-time object and motion detection. Additionally, the implementation of a network model adapter allows the support of any desired model detection, providing flexibility and adaptability for various use cases.

git clone https://github.com/8ff/firescrew && cd firescrew/assets
# YOLOV8
./objectDetectServerYolo.py

# Coral TPU
./objectDetectServerCoral.py

Your input is highly valued! If you have ideas for new features, enhancements, or anything else you'd like to see in Firescrew you can contribute your ideas and suggestions by:

• Opening an Issue: If you have a specific idea or request, please consider first using the discussion section as detailed below. For bugs or clearly defined enhancements, you can open a new issue in the GitHub repository. Be sure to describe your idea in detail so that it can be fully understood and considered.

• Participating in Discussions: Feel free to join existing discussions or start a new one in the discussion section of the repository. This is the preferred place for sharing wishlists and brainstorming ideas. By sharing your thoughts here, you can engage with other users, contribute to the ongoing development of Firescrew, and see your ideas evolve into implementable features.

Your insights and perspectives are vital in shaping the future of Firescrew. Together, we can make it even better! Discussions serve as a dynamic space for collaboration and creativity, and ideas from this section may well be selected for future implementation. Let's work together to continue to innovate and improve Firescrew.

Stay Updated: For the latest updates and news, please consider following 8ffChief on Twitter. Stay connected and be the first to know about new features, releases, and more!

• Remove all use of GOCV CGO in favor of pure go: This will allow for easier cross compilation,faster builds and significant performance improvements
• Build docker container to support Linux/Windows/MacOS - AMD64/ARM64: This will allow for easier deployment
• Add support for EdgeTPU Coral TPU: This will allow for faster and more accurate detection
• Remove support for native MobileNET model via GOCV: This will allow for easier cross compilation,faster builds, models like YOLO and EdgeTPU Coral TPU have shown much better performance and lower resource usage

• GetDimensions Web UI
• Add uploading footage to S3 compatible cloud host
• HA Integration
• Standardize the way adapter scripts return data
• Yaml Config ?