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InvertibleNetworks.jl

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CI DOI

Building blocks for invertible neural networks in the Julia programming language.

  • Memory efficient building blocks for invertible neural networks
  • Hand-derived gradients, Jacobians $J$ , and $\log |J|$
  • Flux integration
  • Support for Zygote and ChainRules
  • GPU support
  • Includes various examples of invertible neural networks, normalizing flows, variational inference, and uncertainty quantification

Installation

InvertibleNetworks is registered and can be added like any standard Julia package with the command:

] add InvertibleNetworks

Uncertainty-aware image reconstruction

Due to its memory scaling InvertibleNetworks.jl, has been particularily successful at Bayesian posterior sampling with simulation-based inference. To get started with this application refer to a simple example (Conditional sampling for MNSIT inpainting) but feel free to modify this script for your application and please reach out to us for help.

mnist_sampling_cond

Building blocks

  • 1x1 Convolutions using Householder transformations (example)

  • Residual block (example)

  • Invertible coupling layer from Dinh et al. (2017) (example)

  • Invertible hyperbolic layer from Lensink et al. (2019) (example)

  • Invertible coupling layer from Putzky and Welling (2019) (example)

  • Invertible recursive coupling layer HINT from Kruse et al. (2020) (example)

  • Activation normalization (Kingma and Dhariwal, 2018) (example)

  • Various activation functions (Sigmoid, ReLU, leaky ReLU, GaLU)

  • Objective and misfit functions (mean squared error, log-likelihood)

  • Dimensionality manipulation: squeeze/unsqueeze (column, patch, checkerboard), split/cat

  • Squeeze/unsqueeze using the wavelet transform

Examples

  • Invertible recurrent inference machines (Putzky and Welling, 2019) (generic example)

  • Generative models with maximum likelihood via the change of variable formula (example)

  • Glow: Generative flow with invertible 1x1 convolutions (Kingma and Dhariwal, 2018) (generic example, source)

GPU support

GPU support is supported via Flux/CuArray. To use the GPU, move the input and the network layer to GPU via |> gpu

using InvertibleNetworks, Flux

# Input
nx = 64
ny = 64
k = 10
batchsize = 4

# Input image: nx x ny x k x batchsize
X = randn(Float32, nx, ny, k, batchsize) |> gpu

# Activation normalization
AN = ActNorm(k; logdet=true) |> gpu

# Test invertibility
Y_, logdet = AN.forward(X)

Reference

If you use InvertibleNetworks.jl in your research, we would be grateful if you cite us with the following bibtex:

@article{Orozco2024, doi = {10.21105/joss.06554}, url = {https://doi.org/10.21105/joss.06554}, year = {2024}, publisher = {The Open Journal}, volume = {9}, number = {99}, pages = {6554}, author = {Rafael Orozco and Philipp Witte and Mathias Louboutin and Ali Siahkoohi and Gabrio Rizzuti and Bas Peters and Felix J. Herrmann}, title = {InvertibleNetworks.jl: A Julia package for scalable normalizing flows}, journal = {Journal of Open Source Software} }

Papers

The following publications use InvertibleNetworks.jl:

Contributing

We welcome contributions and bug reports! Please see CONTRIBUTING.md for guidance.

InvertibleNetworks.jl development subscribes to the Julia Community Standards.

Authors

  • Rafael Orozco, Georgia Institute of Technology [[email protected]]

  • Philipp Witte, Georgia Institute of Technology (now Microsoft)

  • Gabrio Rizzuti, Utrecht University

  • Mathias Louboutin, Georgia Institute of Technology

  • Ali Siahkoohi, Georgia Institute of Technology

Acknowledgments

This package uses functions from NNlib.jl, Flux.jl and Wavelets.jl