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A Python port of Google TensorFlow.js PoseNet (Real-time Human Pose Estimation)

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PoseNet Python

This repository originates from rwightman/posenet-python and has been heavily refactored to:

  • make it run the posenet v2 networks
  • get it to work with the latest tfjs graph serialization
  • extend it with the ResNet50 network
  • make the code run on TF 2.x
  • get all code running in docker containers for ease of use and installation (no conda necessary)

This repository contains a pure Python implementation (multi-pose only) of the Google TensorFlow.js Posenet model. For a (slightly faster) PyTorch implementation that followed from this, see (https://github.com/rwightman/posenet-pytorch)

Install

A suitable Python 3.x environment with Tensorflow 2.x. For a quick setup, use docker.

If you want to use the webcam demo, a pip version of opencv (pip install opencv-python) is required instead of the conda version. Anaconda's default opencv does not include ffpmeg/VideoCapture support. Also, you may have to force install version 3.4.x as 4.x has a broken drawKeypoints binding.

Have a look at the docker configuration for a quick setup. If you want conda, have a look at the requirements.txt file to see what you should install. Know that we rely on https://github.com/patlevin/tfjs-to-tf for converting the tensorflow.js serialization to the tensorflow saved model. So you have to install this package:

git clone https://github.com/patlevin/tfjs-to-tf.git 
cd tfjs-to-tf 
pip install . --no-deps 

Use the --no-deps flag to prevent tfjs-to-tf from installing Tensorflow 1.x as this would uninstall your Tensorflow 2.x!

Using Docker

A convenient way to run this project is by building and running the docker image, because it has all the requirements built-in. The GPU version is tested on a Linux machine. You need to install the nvidia host driver and the nvidia-docker toolkit. Once set up, you can make as many images as you want with different dependencies without touching your host OS (or fiddling with conda).

If you just want to test this code, you can run everything on a CPU just as well. You still get 8fps on mobilenet and 4fps on resnet50. Replace GPU below with CPU to test on a CPU.

cd docker
./docker_img_build.sh GPU
cd ..  
. ./bin/exportGPU.sh
./bin/get_test_images_run.sh
./bin/image_demo_run.sh

Some pointers to get you going on the Linux machine setup. Most links are based on Ubuntu, but other distributions should work fine as well.

Usage

There are three demo apps in the root that utilize the PoseNet model. They are very basic and could definitely be improved.

The first time these apps are run (or the library is used) model weights will be downloaded from the TensorFlow.js version and converted on the fly.

image_demo.py

Image demo runs inference on an input folder of images and outputs those images with the keypoints and skeleton overlayed.

python image_demo.py --model resnet50 --stride 16 --image_dir ./images --output_dir ./output

A folder of suitable test images can be downloaded by first running the get_test_images.py script.

benchmark.py

A minimal performance benchmark based on image_demo. Images in --image_dir are pre-loaded and inference is run --num_images times with no drawing and no text output.

Running the benchmark cycling 1000 times through the example images on a Geforce GTX 1080ti gives these average FPS using TF 2.0.0:

ResNet50 stride 16: 32.41 FPS
ResNet50 stride 32: 38.70 FPS 
MobileNet stride 8: 37.90 FPS (this is surprisingly slow for mobilenet, ran this several times, same result)
MobileNet stride 16: 58.64 FPS

Faster FPS have been reported by Ross Wightmann on the original codebase in rwightman/posenet-python, so if anyone has a pull request that improves the performance of this codebase, feel free to let me know!

webcam_demo.py

The webcam demo uses OpenCV to capture images from a connected webcam. The result is overlayed with the keypoints and skeletons and rendered to the screen. The default args for the webcam_demo assume device_id=0 for the camera and that 1280x720 resolution is possible.

Credits

The original model, weights, code, etc. was created by Google and can be found at https://github.com/tensorflow/tfjs-models/tree/master/posenet

This port is initially created by Ross Wightman and later upgraded by Peter Rigole and is in no way related to Google.

The Python conversion code that started me on my way was adapted from the CoreML port at https://github.com/infocom-tpo/PoseNet-CoreML

TODO

  • Performance improvements (especially edge loops in 'decode.py')
  • OpenGL rendering/drawing
  • Comment interfaces, tensor dimensions, etc

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