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Implementation of 'lightweight' GAN, proposed in ICLR 2021, in Pytorch. High resolution image generations that can be trained within a day or two

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512x512 flowers after 12 hours of training, 1 gpu

256x256 flowers after 12 hours of training, 1 gpu

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'Lightweight' GAN

PyPI version

Implementation of 'lightweight' GAN proposed in ICLR 2021, in Pytorch. The main contributions of the paper is a skip-layer excitation in the generator, paired with autoencoding self-supervised learning in the discriminator. Quoting the one-line summary "converge on single gpu with few hours' training, on 1024 resolution sub-hundred images".

Install

$ pip install lightweight-gan

Use

One command

$ lightweight_gan --data ./path/to/images --image-size 512

Model will be saved to ./models/{name} every 1000 iterations, and samples from the model saved to ./results/{name}. name will be default, by default.

Training settings

Pretty self explanatory for deep learning practitioners

$ lightweight_gan \
    --data ./path/to/images \
    --name {name of run} \
    --batch-size 16 \
    --gradient-accumulate-every 4 \
    --num-train-steps 200000

Augmentation

Augmentation is essential for Lightweight GAN to work effectively in a low data setting

By default, the augmentation types is set to translation and cutout, with color omitted. You can include color as well with the following.

$ lightweight_gan --data ./path/to/images --aug-prob 0.25 --aug-types [translation,cutout,color]

Test augmentation

You can test and see how your images will be augmented before it pass into a neural network (if you use augmentation). Let's see how it works on this image:

Basic usage

Base code to augment your image, define --aug-test and put path to your image into --data:

lightweight_gan \
    --aug-test \
    --data ./path/to/lena.jpg

After this will be created the file lena_augs.jpg that will be look something like this:

Options

You can use some options to change result:

  • --image-size 256 to change size of image tiles in the result. Default: 256.
  • --aug-type [color,cutout,translation] to combine several augmentations. Default: [cutout,translation].
  • --batch-size 10 to change count of images in the result image. Default: 10.
  • --num-image-tiles 5 to change count of tiles in the result image. Default: 5.

Try this command:

lightweight_gan \
    --aug-test \
    --data ./path/to/lena.jpg \
    --batch-size 16 \
    --num-image-tiles 4 \
    --aug-types [color,translation]

result wil be something like that:

Types of augmentations

This library contains several types of embedded augmentations.
Some of these works by default, some of these can be controlled from a command as options in the --aug-types:

  • Horizontal flip (work by default, not under control, runs in the AugWrapper class);
  • color randomly change brightness, saturation and contrast;
  • cutout creates random black boxes on the image;
  • offset randomly moves image by x and y-axis with repeating image;
    • offset_h only by an x-axis;
    • offset_v only by a y-axis;
  • translation randomly moves image on the canvas with black background;

Full setup of augmentations is --aug-types [color,cutout,offset,translation].
General recommendation is using suitable augs for your data and as many as possible, then after sometime of training disable most destructive (for image) augs.

Color

Cutout

Offset

Only x-axis:

Only y-axis:

Translation

Mixed precision

You can turn on automatic mixed precision with one flag --amp

You should expect it to be 33% faster and save up to 40% memory

Multiple GPUs

Also one flag to use --multi-gpus

Generating

Once you have finished training, you can generate samples with one command. You can select which checkpoint number to load from. If --load-from is not specified, will default to the latest.

$ lightweight_gan \
  --name {name of run} \
  --load-from {checkpoint num} \
  --generate \
  --generate-types {types of result, default: [default,ema]} \
  --num-image-tiles {count of image result}

After run this command you will get folder near results image folder with postfix "-generated-{checkpoint num}".

You can also generate interpolations

$ lightweight_gan --name {name of run} --generate-interpolation

Show progress

After creating several checkpoints of model you can generate progress as sequence images by command:

$ lightweight_gan \
  --name {name of run} \
  --show-progress \
  --generate-types {types of result, default: [default,ema]} \
  --num-image-tiles {count of image result}

After running this command you will get a new folder in the results folder, with postfix "-progress". You can convert the images to a video with ffmpeg using the command "ffmpeg -framerate 10 -pattern_type glob -i '*-ema.jpg' out.mp4".

Show progress gif demonstration

Show progress video demonstration

Discriminator output size

The author has kindly let me know that the discriminator output size (5x5 vs 1x1) leads to different results on different datasets. (5x5 works better for art than for faces, as an example). You can toggle this with a single flag

# disc output size is by default 1x1
$ lightweight_gan --data ./path/to/art --image-size 512 --disc-output-size 5

Attention

You can add linear + axial attention to specific resolution layers with the following

# make sure there are no spaces between the values within the brackets []
$ lightweight_gan --data ./path/to/images --image-size 512 --attn-res-layers [32,64] --aug-prob 0.25

Dual Contrastive Loss

A recent paper has proposed that a novel contrastive loss between the real and fake logits can improve quality slightly over the default hinge loss.

You can use this with one extra flag as follows

$ lightweight_gan --data ./path/to/images --dual-contrast-loss

Bonus

You can also train with transparent images

$ lightweight_gan --data ./path/to/images --transparent

Or greyscale

$ lightweight_gan --data ./path/to/images --greyscale

Alternatives

If you want the current state of the art GAN, you can find it at https://github.com/lucidrains/stylegan2-pytorch

Citations

@inproceedings{
    anonymous2021towards,
    title   = {Towards Faster and Stabilized {\{}GAN{\}} Training for High-fidelity Few-shot Image Synthesis},
    author  = {Anonymous},
    booktitle = {Submitted to International Conference on Learning Representations},
    year    = {2021},
    url     = {https://openreview.net/forum?id=1Fqg133qRaI},
    note    = {under review}
}
@misc{cao2020global,
    title   = {Global Context Networks},
    author  = {Yue Cao and Jiarui Xu and Stephen Lin and Fangyun Wei and Han Hu},
    year    = {2020},
    eprint  = {2012.13375},
    archivePrefix = {arXiv},
    primaryClass = {cs.CV}
}
@misc{qin2020fcanet,
    title   = {FcaNet: Frequency Channel Attention Networks},
    author  = {Zequn Qin and Pengyi Zhang and Fei Wu and Xi Li},
    year    = {2020},
    eprint  = {2012.11879},
    archivePrefix = {arXiv},
    primaryClass = {cs.CV}
}
@misc{yu2021dual,
    title   = {Dual Contrastive Loss and Attention for GANs}, 
    author  = {Ning Yu and Guilin Liu and Aysegul Dundar and Andrew Tao and Bryan Catanzaro and Larry Davis and Mario Fritz},
    year    = {2021},
    eprint  = {2103.16748},
    archivePrefix = {arXiv},
    primaryClass = {cs.CV}
}

What I cannot create, I do not understand - Richard Feynman

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Implementation of 'lightweight' GAN, proposed in ICLR 2021, in Pytorch. High resolution image generations that can be trained within a day or two

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