This is the codebase for our Siggraph paper, Computational Inverse Design of Surface-based Inflatables. The code is written primarily in C++, but it is meant to be used through the Python bindings.
The C++ code relies on Boost and CHOLMOD/UMFPACK, which must be installed
separately.
The code also relies on several dependencies that are included as submodules: MeshFEM, libigl,
Finally, it includes a version of Keenan Crane's stripe patterns code modified to generate fusing curve patterns and fix a few issues with boundary handling.
You can install all the mandatory dependencies on macOS with MacPorts. When installing SuiteSparse, be sure to get a version linked against Accelerate.framework rather than OpenBLAS; on MacPorts this is achieved by requesting the accelerate variant, which is no longer the default. Simulations will run over 2x slower under OpenBLAS.
# Build/version control tools, C++ code dependencies
sudo port install cmake boost ninja
sudo port install SuiteSparse +accelerate
# Dependencies for jupyterlab/notebooks
sudo port install python39
# Dependencies for `shapely` module
sudo port install geos
# Install nodejs/npm using nvm
curl -o- https://raw.githubusercontent.com/nvm-sh/nvm/v0.39.1/install.sh | bash
nvm install 17 && nvm use 17A few more packages need to be installed on a fresh Ubuntu 20.04 install:
# Build/version control tools
sudo apt install git cmake ninja-build
# Dependencies for C++ code
sudo apt install libboost-filesystem-dev libboost-system-dev libboost-program-options-dev libsuitesparse-dev
# Dependencies (pybind11, jupyterlab/notebooks)
sudo apt install python3-pip npm
sudo npm install npm@latest -g
# Dependencies for `shapely` module
sudo apt install libgeos-devClone this repository recursively so that its submodules are also downloaded:
git clone --recursive https://github.com/jpanetta/InflatablesBuild the C++ code and its Python bindings using cmake and your favorite
build system. For example, with ninja:
cd Inflatables
mkdir build && cd build
cmake .. -GNinja
ninjaThe preferred way to interact with the inflatables code is in a Jupyter notebook, using the Python bindings. We recommend that you install the Python dependencies and JupyterLab itself in a virtual environment (e.g., with venv).
pip3 install wheel # Needed if installing in a virtual environment
# Recent versions of jupyterlab and related packages cause problems:
# JupyerLab 3.4 and later has a bug where the tab and status bar GUI
# remains visible after taking a viewer fullscreen
# ipykernel > 5.5.5 clutters the notebook with stdout content
# ipywidgets 8 and juptyerlab-widgets 3.0 break pythreejs
pip3 install jupyterlab==3.3.4 ipykernel==5.5.5 ipywidgets==7.7.2 jupyterlab-widgets==1.1.1
# If necessary, follow the instructions in the warnings to add the Python user
# bin directory (containing the 'jupyter' binary) to your PATH...
git clone https://github.com/jpanetta/pythreejs
cd pythreejs
pip3 install -e .
cd js
jupyter labextension install .
pip3 install matplotlib scipy
pip3 install shapely # dependency of the fabrication file generationYou may need to add the following to your shell startup script for the installation of pythreejs's dependencies during pip3 install -e . to succeed:
export NODE_OPTIONS=--openssl-legacy-provider;
Launch JupyterLab from the root python directory:
cd python
jupyter labNow try opening and running an demo notebook, e.g.,
python/Demos/ConcentricCircles.ipynb.
For an example of the full inverse design pipeline--from input surface to fabrication file output--please see
python/Demos/Lilium.ipynb.