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Likelihood Training of Schrödinger Bridge using FBSDEs Theory, ICLR 2022

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SB-FBSDE: Likelihood Training of Schrödinger Bridge using Forward-Backward SDEs Theory [ICLR 2022]

Official PyTorch implementation of the paper "Likelihood Training of Schrödinger Bridge using Forward-Backward SDEs Theory (SB-FBSDE)" which introduces a new class of deep generative models that generalizes score-based models to fully nonlinear forward and backward diffusions.

This repo is co-maintained by Guan-Horng Liu and Tianrong Chen. Contact us if you have any questions! If you find this library useful, please cite ⬇️

@inproceedings{chen2022likelihood,
  title={Likelihood Training of Schr{\"o}dinger Bridge using Forward-Backward SDEs Theory},
  author={Chen, Tianrong and Liu, Guan-Horng and Theodorou, Evangelos A},
  booktitle={International Conference on Learning Representations},
  year={2022}
}

Examples

p0 ⇆ pT (--problem-name) Results (blue/left: p0 ← pT, red/right: p0 → pT)
Mixture Gaussians ⇆ Gaussian (gmm) drawing
CheckerBoard ⇆ Gaussian (checkerboard) drawing
Spiral ⇆ Moon (moon-to-spiral) drawing
CIFAR-10 ⇆ Gaussian (cifar10)

drawing drawing

Installation

This code is developed with Python3. PyTorch >=1.7 (we recommend 1.8.1). First, install the dependencies with Anaconda and activate the environment sb-fbsde with

conda env create --file requirements.yaml python=3
conda activate sb-fbsde

Training

python main.py \
  --problem-name <PROBLEM_NAME> \
  --forward-net <FORWARD_NET> \
  --backward-net <BACKWARD_NET> \
  --num-FID-sample <NUM_FID_SAMPLE> \ # add this flag only for CIFAR-10
  --dir <DIR> \
  --log-tb 

To train an SB-FBSDE from scratch, run the above command, where

  • PROBLEM_NAME is the dataset. We support gmm (2D mixture of Gaussian), checkerboard (2D toy dataset), moon-to-spiral, mnist, celebA32, celebA64, cifar10.
  • FORWARD_NET & BACKWARD_NET are the deep networks for forward and backward drifts. We support Unet, nscnpp, and a toy network for 2D datasets.
  • NUM_FID_SAMPLE is the number of generated images used to evaluate FID locally. We recommend 10000 for training CIFAR-10. Note that this requires first downloading the FID statistics checkpoint.
  • DIR specifies where the results (e.g. snapshots during training) shall be stored.
  • log-tb enables logging with Tensorboard.

Additionally, use --load <LOAD> to restore previous checkpoint or pre-trained model. For training CIFAR-10 specifically, we support loading the pre-trained NCSN++ as the backward policy of the first SB training stage (this is because the first SB training stage can degenerate to denoising score matching under proper initialization; see more details in Appendix D of our paper).

Other configurations are detailed in options.py. The default configurations for each dataset are provided in the configs folder.

Evaluating the CIFAR-10 Checkpoint

To evaluate SB-FBSDE on CIFAR-10 (we achieve FID 3.01 and NLL 2.96), create a folder checkpoint then download the model checkpoint and FID statistics checkpoint either from Google Drive or through the following commands.

mkdir checkpoint && cd checkpoint

# FID stat checkpoint. This's needed whenever we
# need to compute FID during training or sampling.
gdown --id 1Tm_5nbUYKJiAtz2Rr_ARUY3KIFYxXQQD 

# SB-FBSDE model checkpoint for reproducing results in the paper.
gdown --id 1Kcy2IeecFK79yZDmnky36k4PR2yGpjyg 

After downloading the checkpoints, run the following commands for computing either NLL or FID. Set the batch size --samp-bs <BS> properly depending on your hardware.

# compute NLL
python main.py --problem-name cifar10 --forward-net Unet --backward-net ncsnpp --dir ICLR-2022-reproduce
  --load checkpoint/ciifar10_sbfbsde_stage_8.npz --compute-NLL --samp-bs <BS>
# compute FID
python main.py --problem-name cifar10 --forward-net Unet --backward-net ncsnpp --dir ICLR-2022-reproduce
  --load checkpoint/ciifar10_sbfbsde_stage_8.npz --compute-FID --samp-bs <BS> --num-FID-sample 50000 --use-corrector --snr 0.15

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