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YoloV8 TensorRT CPP

A C++ Implementation of YoloV8 using TensorRT
Supports object detection, semantic segmentation, and body pose estimation.

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Getting Started

This project demonstrates how to use the TensorRT C++ API to run GPU inference for YoloV8. It makes use of my other project tensorrt-cpp-api to run inference behind the scene, so make sure you are familiar with that project.

Prerequisites

  • Tested and working on Ubuntu 20.04 & 22.04 (Windows is not supported at this time)
  • Install CUDA, instructions here.
    • Recommended >= 12.0
  • Install cudnn, instructions here.
    • Recommended >= 8
  • sudo apt install build-essential
  • sudo apt install python3-pip
  • pip3 install cmake
  • Install OpenCV with cuda support. To compile OpenCV from source, run the build_opencv.sh script provided here.
    • Recommended >= 4.8
  • Download TensorRT 10 from here.
    • Required >= 10.0
  • Extract, and then navigate to the CMakeLists.txt file and replace the TODO with the path to your TensorRT installation.

Installation

  • git clone https://github.com/cyrusbehr/YOLOv8-TensorRT-CPP --recursive
  • Note: Be sure to use the --recursive flag as this repo makes use of git submodules.

Converting Model from PyTorch to ONNX

  • Navigate to the official YoloV8 repository and download your desired version of the model (ex. YOLOv8x).
    • The code also supports semantic segmentation models out of the box (ex. YOLOv8x-seg) and pose estimation models (ex. yolov8x-pose.onnx).
  • pip3 install ultralytics
  • Navigate to the scripts/ directory and run the following:
  • python3 pytorch2onnx.py --pt_path <path to your pt file>
  • After running this command, you should successfully have converted from PyTorch to ONNX.
  • Note: If converting the model using a different script, be sure that end2end is disabled. This flag will add bbox decoding and nms directly to the model, whereas my implementation does these steps external to the model using good old C++.

Building the Project

  • mkdir build
  • cd build
  • cmake ..
  • make -j

Running the Executables

  • Note: the first time you run any of the scripts, it may take quite a long time (5 mins+) as TensorRT must generate an optimized TensorRT engine file from the onnx model. This is then saved to disk and loaded on subsequent runs.
  • Note: The executables all work out of the box with Ultralytic's pretrained object detection, segmentation, and pose estimation models.
  • To run the benchmarking script, run: ./benchmark --model /path/to/your/onnx/model.onnx --input /path/to/your/benchmark/image.png
  • To run inference on an image and save the annotated image to disk run: ./detect_object_image --model /path/to/your/onnx/model.onnx --input /path/to/your/image.jpg
    • You can use the images in the images/ directory for testing
  • To run inference using your webcam and display the results in real time, run: ./detect_object_video --model /path/to/your/onnx/model.onnx --input 0
  • For a full list of arguments, run any of the executables without providing any arguments.

INT8 Inference

Enabling INT8 precision can further speed up inference at the cost of accuracy reduction due to reduced dynamic range. For INT8 precision, calibration data must be supplied which is representative of real data the model will see. It is advised to use 1K+ calibration images. To enable INT8 inference with the YoloV8 sanity check model, the following steps must be taken:

  • Download and extract the COCO validation dataset, or procure data representative of your inference data: wget http://images.cocodataset.org/zips/val2017.zip
  • Provide the additional command line arguments when running the executables: --precision INT8 --calibration-data /path/to/your/calibration/data
  • If you get an "out of memory in function allocate" error, then you must reduce Options.calibrationBatchSize so that the entire batch can fit in your GPU memory.

Benchmarking

  • Before running benchmarks, ensure your GPU is unloaded.
  • Run the executable benchmark using the /images/640_640.jpg image.
  • If you'd like to benchmark each component (preprocess, inference, postprocess), recompile setting the ENABLE_BENCHMARKS flag to ON: cmake -DENABLE_BENCHMARKS=ON ...
    • You can then rerun the executable

Benchmarks run on NVIDIA GeForce RTX 3080 Laptop GPU, Intel(R) Core(TM) i7-10870H CPU @ 2.20GHz using 640x640 BGR image in GPU memory and FP16 precision.

Model Total Time Preprocess Time Inference Time Postprocess Time
yolov8n 3.613 ms 0.081 ms 1.703 ms 1.829 ms
yolov8n-pose 2.107 ms 0.091 ms 1.609 ms 0.407 ms
yolov8n-seg 15.194 ms 0.109 ms 2.732 ms 12.353 ms
Model Precision Total Time Preprocess Time Inference Time Postprocess Time
yolov8x FP32 25.819 ms 0.103 ms 23.763 ms 1.953 ms
yolov8x FP16 10.147 ms 0.083 ms 7.677 ms 2.387 ms
yolov8x INT8 7.32 ms 0.103 ms 4.698 ms 2.519 ms

TODO: Need to improve postprocessing time using CUDA kernel.

How to debug

  • If you have issues creating the TensorRT engine file from the onnx model, navigate to libs/tensorrt-cpp-api/src/engine.cpp and change the log level by changing the severity level to kVERBOSE and rebuild and rerun. This should give you more information on where exactly the build process is failing.

Show your appreciation

If this project was helpful to you, I would appreicate if you could give it a star. That will encourage me to ensure it's up to date and solve issues quickly.

Contributors

z3lx
z3lx

💻
Loic Tetrel
Loic Tetrel

💻
Shubham
Shubham

💻