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Megapixel Image Generation with Step-unrolled Denoising Autoencoders

Paper | Twitter Summary

Code for my master's dissertation into fast sampling of VQ-GAN latents using step-unrolled denoising autoencoders (SUNDAE).

Banner image of FFHQ1024 samples

Representative FFHQ1024 outputs, sampled in only 2 seconds on a GTX 1080Ti

The paper combines non-autoregressive text model SUNDAE with a powerful pretrained VQ-GAN and efficient transformer backbone (Hourglass Transformers) to produce a fast image generation framework. This framework was successfully scaled to 1024x1024 images and can produce diverse and realistic samples in approximately 2 seconds on a GTX 1080Ti. Furthermore, it was the first work to demonstrate both scaling of SUNDAE to long sequence lengths and VQ-GAN to megapixel images. Perceptual quality metrics such as FID were not state of the art, but I hope the method and code is useful to the community, as well encouraging further exploration of non-autoregressive discrete models.

Overview of SUNDAE-VQGAN Training and Sampling

Overview of SUNDAE-VQGAN Training and Sampling

This repository contains:

  • generate-latents.py: latent dataset generation script using trained VQ-GAN.
  • train.py: training script for SUNDAE discrete prior.
  • sample.py: non-interactive sampling script using trained SUNDAE prior and VQ-GAN.
  • sample.py: interactive sampling script using trained SUNDAE prior and VQ-GAN.
  • inpaint.py: inpainting script using trained SUNDAE prior and VQ-GAN.
  • generate-discrete-mnist: generates a psuedo-latent dataset from MNIST style dataset.
  • recon-vqgan.py: reconstruction script using trained VQ-GAN.
  • utils.py: miscellaneous utility functions.
  • config/: configuration toml/yaml files for all experiments.
  • hourglass_transformer/: a forked PyTorch reimplementation of hourglass transformers by @lucidrains. This implementation has been heavily modified as detailed in the paper.

See arguments in each file for detailed usage.

All models are implemented in PyTorch. Training scripts are implemented using ptpt - my lightweight framework around PyTorch.

Before applying to image, I reimplemented SUNDAE on the text8 dataset. This can be found here.

Installation

Create a python environment, then install requirements as follows:

pip install -r requirements.txt

Place the datasets you wish to train on in a directory named data/, in format suitable for torchvision.datasets.ImageFolder.

Download pretrained VQ-GAN checkpoints and place them in a directory named vqgan-ckpt/. Any checkpoint in the same format as taming-transformers is suitable.

If the checkpoint is a combined VQ-GAN + GPT prior, add --legacy-cfg as an additional argument to scripts that use VQ-GAN. To be explicit, if the config you downloaded contains keywords such as transformer_config or first_stage_config you should use this flag.

TODO: add support for latent diffusion style VQ-GAN

Usage

Generate the latent dataset as follows:

python generate-latents.py \
    --cfg-path config/vqgan/ffhq1024.yaml \
    --ckpt-path vqgan-ckpt/ffhq1024.ckpt \
    --dataset-in data/ffhq1024 \
    --latents-out data/ffhq1024-latents

If you wish to use class data, add the argument --use-class. However, class-conditioned experiments, with the exception of MNIST, led to poor results.


Train SUNDAE on the latent dataset as follows:

python train.py --cfg-path config/ffhq1024/config.toml

If you wish to use wandb tracking, add the argument --wandb.


Run an interactive sampling script as follows:

python sample-interactive.py \
    --cfg-path config/ffhq1024/config.toml \
    --resume sundae-ckpt/ffhq1024.pt

If your GPU has enough memory, you can use the argument --cuda-vqgan to also load VQ-GAN onto the GPU. Otherwise, it will decode latents on CPU.

If you wish to generate samples in bulk, you can use the script sample.py. This is useful for calculating metrics such as FID.

Configuration

config/vqgan contains yaml files defining the VQ-GAN configuration. These are in the same format as taming-transformers and should be packaged with the downloaded pretrained checkpoint.

All other subdirectories of config/ contain configs for each dataset. These are structured as follows:

  • unroll_steps: number of Markov unroll steps during training
  • [trainer]: configuration options passed to ptpt.Trainer
  • [data]: configuration options passed to the latent dataset
  • [vqgan]: defines where to find VQ-GAN config, checkpoint, and the shape of its latent.
  • [sampling]: configuration options for sampling during evaluation stage of training.
  • [net]: configuration options for hourglass transformer architecture.

Pretrained Checkpoints

TODO: track these down


Reference

This work takes strong inspiration from the following papers:

Step-unrolled Denoising Autoencoders for Text Generation

Nikolay Savinov, Junyoung Chung, Mikolaj Binkowski, Erich Elsen, Aaron van den Oord

@misc{savinov2022stepunrolled,
      title={Step-unrolled Denoising Autoencoders for Text Generation}, 
      author={Nikolay Savinov and Junyoung Chung and Mikolaj Binkowski and Erich Elsen and Aaron van den Oord},
      year={2022},
      eprint={2112.06749},
      archivePrefix={arXiv},
      primaryClass={cs.CL}
}

Taming Transformers for High-Resolution Image Synthesis

Patrick Esser, Robin Rombach, Björn Ommer

@misc{esser2021taming,
      title={Taming Transformers for High-Resolution Image Synthesis}, 
      author={Patrick Esser and Robin Rombach and Björn Ommer},
      year={2021},
      eprint={2012.09841},
      archivePrefix={arXiv},
      primaryClass={cs.CV}
}

Hierarchical Transformers Are More Efficient Language Models

Piotr Nawrot, Szymon Tworkowski, Michał Tyrolski, Łukasz Kaiser, Yuhuai Wu, Christian Szegedy, Henryk Michalewski

@misc{nawrot2021hierarchical,
      title={Hierarchical Transformers Are More Efficient Language Models}, 
      author={Piotr Nawrot and Szymon Tworkowski and Michał Tyrolski and Łukasz Kaiser and Yuhuai Wu and Christian Szegedy and Henryk Michalewski},
      year={2021},
      eprint={2110.13711},
      archivePrefix={arXiv},
      primaryClass={cs.LG}
}

Citation

Megapixel Image Generation with Step-unrolled Denoising Autoencoders

Alex F. McKinney, Chris G. Willcocks

@misc{mckinney2022megapixel,
      title={Megapixel Image Generation with Step-Unrolled Denoising Autoencoders}, 
      author={Alex F. McKinney and Chris G. Willcocks},
      year={2022},
      eprint={2206.12351},
      archivePrefix={arXiv},
      primaryClass={cs.CV}
}

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