Skip to content

Latest commit

 

History

History
148 lines (104 loc) · 8.26 KB

README.md

File metadata and controls

148 lines (104 loc) · 8.26 KB

StyleAlign: Analysis and Applications of Aligned StyleGAN Models

Check our video here:

StyleAlign: Analysis and Applications of Aligned StyleGAN Models
Zongze Wu, Yotam Nitzan, Eli Shechtman, Dani Lischinski
https://openreview.net/pdf?id=Qg2vi4ZbHM9

Abstract: In this paper, we perform an in-depth study of the properties and applications of aligned generative models. We refer to two models as aligned if they share the same architecture, and one of them (the child) is obtained from the other (the parent) via fine-tuning to another domain, a common practice in transfer learning. Several works already utilize some basic properties of aligned StyleGAN models to perform image-to-image translation. Here, we perform the first detailed exploration of model alignment, also focusing on StyleGAN. First, we empirically analyze aligned models and provide answers to important questions regarding their nature. In particular, we find that the child model's latent spaces are semantically aligned with those of the parent, inheriting incredibly rich semantics, even for distant data domains such as human faces and churches. Second, equipped with this better understanding, we leverage aligned models to solve a diverse set of tasks. In addition to image translation, we demonstrate fully automatic cross-domain image morphing. We further show that zero-shot vision tasks may be performed in the child domain, while relying exclusively on supervision in the parent domain. We demonstrate qualitatively and quantitatively that our approach yields state-of-the-art results, while requiring only simple fine-tuning and inversion.

Requirements

The codes are based on StyleGAN2-ada. The environmental requirements (from StyleGAN2-ada) are listed below:

  • Linux and Windows are supported, but we recommend Linux for performance and compatibility reasons.
  • 64-bit Python 3.6 or 3.7. We recommend Anaconda3 with numpy 1.14.3 or newer.
  • We recommend TensorFlow 1.14, which we used for all experiments in the paper, but TensorFlow 1.15 is also supported on Linux. TensorFlow 2.x is not supported.
  • On Windows you need to use TensorFlow 1.14, as the standard 1.15 installation does not include necessary C++ headers.
  • 1–8 high-end NVIDIA GPUs with at least 12 GB of GPU memory, NVIDIA drivers, CUDA 10.0 toolkit and cuDNN 7.5.
  • Docker users: use the provided Dockerfile to build an image with the required library dependencies.

The generator and discriminator networks rely heavily on custom TensorFlow ops that are compiled on the fly using NVCC. On Windows, the compilation requires Microsoft Visual Studio to be in PATH. We recommend installing Visual Studio Community Edition and adding it into PATH using "C:\Program Files (x86)\Microsoft Visual Studio\2019\Community\VC\Auxiliary\Build\vcvars64.bat".

usage

Train a parent StyleGAN2 or StyleGAN2-ada model in domain A, then use the parent model weights as initiation for child model (by adding the --resume flag) and fine tune it in domain B. In this way, we obtain the aligned parent and child models, and we could perform image translation or morphing using the following codes.

pretrained checkpoint

The pretrained checkpoints could be downloaded from here. The FFHQ model is from StyleGAN2 repo. The FFHQ512, FFHQ512_dog, FFHQ512_cat, FFHQ512_wild models are from StyleGAN2-ada repo. Other models are trained or fine tuning by ourselves.

To download all checkpoints:

gdown --fuzzy 'https://drive.google.com/drive/folders/1MqCHQ6Yx-eon-3fu1g_AGjpyAUmzH6Jy?usp=sharing' -O /checkpoint --folder

Image-to-Image Translation

source_img_path='./example/dog/'   
source_path='./img_invert/ffhq512_dog/z/'  # path for saving inverted latent codes and images
target_path='./img_invert/ffhq512_dog/translate/cat/' #path for saving translation images 

source_pkl='./checkpoint/ffhq512_dog.pkl'
target_pkl='./checkpoint/ffhq512_dog_cat.pkl'

compare_html='./img_invert/ffhq512_dog/translate/cat.html'

python projector_z.py --outdir=$source_path  \
 		      --target=$source_img_path \
		      --network=$source_pkl


python I2I.py --network $target_pkl \
  	      --source_path $source_path \
  	      --target_path $target_path	


python Compare.py --source_img_path $source_img_path \
  	      --source_path $source_path \
  	      --target_path $target_path \
  	      --save_path $compare_html 	

Cross-domain Image Morphing

To morph image from different domains, please train an e4e encoder in each doamin, and invert the images into w+ space. We provide pretrained e4e models for FFHQ512, FFHQ512_dog, FFHQ512_dog_cat in here. We use w+ space for better image reconstruction (compared to z space).

source_pkl='./checkpoint/ffhq512_dog.pkl'
target_pkl='./checkpoint/ffhq512_dog_cat.pkl'
source_latent='./img_invert/ffhq512_dog/e4e_w_plus/flickr_dog_000043.npy' #w_plus 
target_latent='./img_invert/ffhq512_dog_cat/e4e_w_plus/flickr_cat_000008.npy' #w_plus 

python MergeFace.py --source_pkl $source_pkl --target_pkl $target_pkl --source_latent $source_latent --target_latent $target_latent

We can also translate an image from source to target domian and create a smooth video. We use w+ space in source domain for better reconstruction, and z space in target domain for better translation. Please add --target_is_z flag in the end.

source_pkl='./checkpoint/ffhq512_dog.pkl'
target_pkl='./checkpoint/ffhq512_dog_cat.pkl'
source_latent='./img_invert/ffhq512_dog/e4e_w_plus/flickr_dog_000045.npy'  # w
target_latent='./img_invert/ffhq512_dog/z/flickr_dog_000045.npz'  # z

python MergeFace.py --source_pkl $source_pkl --target_pkl $target_pkl --source_latent $source_latent --target_latent $target_latent --target_is_z

Shared Semantic Controls Between Parent and Child Models

Image Translation

Cross-domain Image Morphing

Knowledge Transfer from Parent to Child Domain

Citation

If you use this code for your research, please cite our paper:

@article{wu2021stylealign,
  title={StyleAlign: Analysis and Applications of Aligned StyleGAN Models},
  author={Wu, Zongze and Nitzan, Yotam and Shechtman, Eli and Lischinski, Dani},
  journal={arXiv preprint arXiv:2110.11323},
  year={2021}
}