Taming Transformers for High-Resolution Image Synthesis
Taming Transformers for High-Resolution Image Synthesis
Patrick Esser*,
Robin Rombach*,
Björn Ommer
* equal contribution
tl;dr We combine the efficiancy of convolutional approaches with the expressivity of transformers by introducing a convolutional VQGAN, which learns a codebook of context-rich visual parts, whose composition is modeled with an autoregressive transformer.
arXiv | BibTeX | Project Page
News
- We now include a couple of examples from the D-RIN dataset so you can run the D-RIN demo without preparing the dataset first.
- You can now jump right into sampling with our Colab quickstart notebook.
- Take a look at ak9250's notebook if you want to run the streamlit demos on Colab.
Requirements
A suitable conda environment named taming can be created
and activated with:
conda env create -f environment.yaml
conda activate taming
Running pretrained models
S-FLCKR
You can also run this model in a Colab notebook, which includes all necessary steps to start sampling.
Download the
2020-11-09T13-31-51_sflckr
folder and place it into logs. Then, run
streamlit run scripts/sample_conditional.py -- -r logs/2020-11-09T13-31-51_sflckr/
FacesHQ
Download 2020-11-13T21-41-45_faceshq_transformer and
place it into logs. Follow the data preparation steps for
CelebA-HQ and FFHQ. Run
streamlit run scripts/sample_conditional.py -- -r logs/2020-11-13T21-41-45_faceshq_transformer/
D-RIN
Download 2020-11-20T12-54-32_drin_transformer and
place it into logs. To run the demo on a couple of example depth maps
included in the repository, run
streamlit run scripts/sample_conditional.py -- -r logs/2020-11-20T12-54-32_drin_transformer/ --ignore_base_data data="{target: main.DataModuleFromConfig, params: {batch_size: 1, validation: {target: taming.data.imagenet.DRINExamples}}}"
To run the demo on the complete validation set, first follow the data preparation steps for ImageNet and then run
streamlit run scripts/sample_conditional.py -- -r logs/2020-11-20T12-54-32_drin_transformer/
Data Preparation
ImageNet
The code will try to download (through Academic
Torrents) and prepare ImageNet the first time it
is used. However, since ImageNet is quite large, this requires a lot of disk
space and time. If you already have ImageNet on your disk, you can speed things
up by putting the data into
${XDG_CACHE}/autoencoders/data/ILSVRC2012_{split}/data/ (which defaults to
~/.cache/autoencoders/data/ILSVRC2012_{split}/data/), where {split} is one
of train/validation. It should have the following structure:
${XDG_CACHE}/autoencoders/data/ILSVRC2012_{split}/data/
├── n01440764
│ ├── n01440764_10026.JPEG
│ ├── n01440764_10027.JPEG
│ ├── ...
├── n01443537
│ ├── n01443537_10007.JPEG
│ ├── n01443537_10014.JPEG
│ ├── ...
├── ...
If you haven't extracted the data, you can also place
ILSVRC2012_img_train.tar/ILSVRC2012_img_val.tar (or symlinks to them) into
${XDG_CACHE}/autoencoders/data/ILSVRC2012_train/ /
${XDG_CACHE}/autoencoders/data/ILSVRC2012_validation/, which will then be
extracted into above structure without downloading it again. Note that this
will only happen if neither a folder
${XDG_CACHE}/autoencoders/data/ILSVRC2012_{split}/data/ nor a file
${XDG_CACHE}/autoencoders/data/ILSVRC2012_{split}/.ready exist. Remove them
if you want to force running the dataset preparation again.
You will then need to prepare the depth data using
MiDaS. Create a symlink
data/imagenet_depth pointing to a folder with two subfolders train and
val, each mirroring the structure of the corresponding ImageNet folder
described above and containing a png file for each of ImageNet's JPEG
files. The png encodes float32 depth values obtained from MiDaS as RGBA
images. We provide the script scripts/extract_depth.py to generate this data.
Please note that this script uses MiDaS via PyTorch
Hub. When we prepared the data,
the hub provided the MiDaS
v2.0 version, but now it
provides a v2.1 version. We haven't tested our models with depth maps obtained
via v2.1 and if you want to make sure that things work as expected, you must
adjust the script to make sure it explicitly uses
v2.0!
CelebA-HQ
Create a symlink data/celebahq pointing to a folder containing the .npy
files of CelebA-HQ (instructions to obtain them can be found in the PGGAN
repository).
FFHQ
Create a symlink data/ffhq pointing to the images1024x1024 folder obtained
from the FFHQ repository.
S-FLCKR
Unfortunately, we are not allowed to distribute the images we collected for the
S-FLCKR dataset and can therefore only give a description how it was produced.
There are many resources on collecting images from the
web to get started.
We collected sufficiently large images from flickr
(see data/flickr_tags.txt for a full list of tags used to find images)
and various subreddits
(see data/subreddits.txt for all subreddits that were used).
Overall, we collected 107625 images, and split them randomly into 96861
training images and 10764 validation images. We then obtained segmentation
masks for each image using DeepLab v2
trained on COCO-Stuff. We used a PyTorch
reimplementation and include an
example script for this process in scripts/extract_segmentation.py.
Training models
FacesHQ
Train a VQGAN with
python main.py --base configs/faceshq_vqgan.yaml -t True --gpus 0,
Then, adjust the checkpoint path of the config key
model.params.first_stage_config.params.ckpt_path in
configs/faceshq_transformer.yaml (or download
2020-11-09T13-33-36_faceshq_vqgan and place into logs, which
corresponds to the preconfigured checkpoint path), then run
python main.py --base configs/faceshq_transformer.yaml -t True --gpus 0,
D-RIN
Train a VQGAN on ImageNet with
python main.py --base configs/imagenet_vqgan.yaml -t True --gpus 0,
or download a pretrained one from 2020-09-23T17-56-33_imagenet_vqgan
and place under logs. If you trained your own, adjust the path in the config
key model.params.first_stage_config.params.ckpt_path of
configs/drin_transformer.yaml.
Train a VQGAN on Depth Maps of ImageNet with
python main.py --base configs/imagenetdepth_vqgan.yaml -t True --gpus 0,
or download a pretrained one from 2020-11-03T15-34-24_imagenetdepth_vqgan
and place under logs. If you trained your own, adjust the path in the config
key model.params.cond_stage_config.params.ckpt_path of
configs/drin_transformer.yaml.
To train the transformer, run
python main.py --base configs/drin_transformer.yaml -t True --gpus 0,
Shout-outs
Thanks to everyone who makes their code and models available. In particular,
- The architecture of our VQGAN is inspired by Denoising Diffusion Probabilistic Models
- The very hackable transformer implementation minGPT
- The good ol' PatchGAN and Learned Perceptual Similarity (LPIPS)
BibTeX
@misc{esser2020taming,
title={Taming Transformers for High-Resolution Image Synthesis},
author={Patrick Esser and Robin Rombach and Björn Ommer},
year={2020},
eprint={2012.09841},
archivePrefix={arXiv},
primaryClass={cs.CV}
}
React
Typescript
Django
Laravel
Facebook
Microsoft
Google
Alibaba
D3
Tencent