This repository demonstrates the application of the unpaired image-to-image
translation method UVCGAN (Paper, repo)
to the domain translation problem, common in science.
This README file has two main parts. In the first
part, we describe how to
apply UVCGAN to the translation of LArTPC detector responses, following
the UVCGAN4SLATS paper: Unsupervised Domain Transfer
for Science: Exploring Deep Learning Methods for Translation between LArTPC
Detector Simulations with Differing Response Models.
In the second part, we provide a tutorial on how
to apply UVCGAN to any domain translation problem. This part intends to
provide you with a roadmap for adapting UVCGAN for your project.
Please don't hesitate to contact us if you encounter any challenges in
the process.
We have released a new and improved version of UVCGAN --
UVCGANv2 -- that delivers outstanding results on
photographic datasets (CelebA-HQ and AFHQ).
You don't want to miss out on this upgrade, so go ahead and check it out! (paper, repo)
uvcgan4slats models were trained under the official PyTorch container
pytorch/pytorch:1.12.1-cuda11.3-cudnn8-runtime. A similar training
environment can be created by running the following command from the
uvcgan4slats source folder.
conda env create -f contrib/conda_env.yml
Activate the environment by running
conda activate uvcgan4slats
To install the uvcgan4slats package, run the following command from the
uvcgan4slats source folder.
python setup.py develop --user
Make sure to run setup in the uvcgan4slats conda environment.
The working of uvcgan4slats depends on the toytools package. Download and
install the package by running the following commands:
git clone https://github.com/LS4GAN/toytools
cd toytools
python setup.py develop --user
The setup command must be run in the uvcgan4slats conda environment.
Note: if you run the setup commands above with sudo, please remove
--user.
uvcgan4slats uses extensively two environment variables: UVCGAN_DATA to
locate the dataset and UVCGAN_OUTDIR to save the output. Users are advised
to set these environment variables. uvcgan4slats will look for datasets in
the ${UVCGAN_DATA} directory and will save results under the
${UVCGAN_OUTDIR} directory. If these variables are not set, they will
default to ./data and ./outdir, respectively. To set up the environment
variables, run the following commands
export UVCGAN_DATA=PATH_TO_DATASET
export UVCGAN_OUTDIR=PATH_TO_OUTDIR
The Simple Liquid Argon Track Samples (SLATS) dataset was created from
simulated neutrino events in a Liquid Argon Time-Projection Chamber (LArTPC)
detector. The dataset contains two domains of events, each corresponding to a
specific detector response function.
The unpaired image-to-image translation method UVCGAN is used to find two
mappings G_ab and G_ba. Each mapping can take a neutrino event from one
domain, modify its detector response, and make it look like a neutrino event
from the other domain.
The training of the G_ab and G_ba mappings is performed in a fully
unsupervised (unpaired) way. But, to facilitate the evaluation of the quality
of translation, the SLATS dataset also contains explicit pairing between
the events of the two domains.
In this section, we describe how to download the SLATS dataset, and how to use
UVCGAN to perform its domain translation.
The datasets and pretrained models can be downloaded directly from the Zenodo website, or use the downloading scripts:
-
datasets:
SLATStiles (256 x 256 images):
./scripts/download_slats_datasets.sh tilesSLATScenter crops (768 x 5888 images):
./scripts/download_slats_datasets.sh center_cropsThe datasets will be saved at
${UVCGAN_DATA}/slats/slats_[tiles,center_crops]or./data/slats/slats_[tiles,center_crops]ifUVCGAN_DATAis unset.Note that the
SLATScenter crops are not used for trainingUVCGAN. We provide the dataset so you can try developing more efficient and powerful networks for much larger images π -
models: To download trained models on
SLATS, run./scripts/download_slats_models.shThe files will be saved at
${UVCGAN_OUTDIR}/slats/pretrainedor./outdir/slats/pretrainedifUVCGAN_OUTDIRis unset.
To run an inference with pre-trained translators, run the following command
in the uvcgan4slats source folder
python scripts/translate_data.py PATH_TO_PRETRAINED_MODELS
If the pretrained models are downloaded using the downloading script,
PATH_TO_PRETRAINED_MODELS here is either
${UVCGAN_OUTDIR}/slats/pretrained or ./outdir/slats/pretrained if
UVCGAN_OUTDIR is unset.
The results are saved to
PATH_TO_PRETRAINED_MODELS/evals/final/ndarrays_eval-test. In it are six
subfolders:
fake_aandfake_b: translated images. More precisely, letG_abbe the translator from domainato domainband letxbe an image from domaina, thenG_ab(x)will be found infake_b.real_aandreal_b: true images from their respective domains.reco_aandreco_b: cyclically reconstructed images. More precisely, letG_babe the translator from domainbto domaina, thenG_ba(G_ab(x))will be found inreco_a.
We can use ./scripts/plot_comparisons.py to compare pairs of images. Denote
the result folder by RESULT, then we can run the following command to
generate 20 plots comparing translations to the targets. The resulting plots
will be saved to the folder ./comp_images.
python ./scripts/plot_comparisons.py RESULT/fake_b RESULT/real_b \
./comp_images -n 20 --log --symmetric
We use --log here to plot in log or symlog scale and use --symmetric to
indicate that the values are symmetric around zero. We need those two
parameters for SLATS images, but it may not be the case for other grayscale images.
Here are three samples produced by ./scripts/plot_comparisons.py comparing
the UVCGAN translation (on the left) to the target (on the right).
In this part, we demonstrate how to train UVCGAN model on your dataset.
We will discuss three topics: Prepare the dataset, Pre-train the generators
(optional), and Train I2I translation.
For the generator pre-training and image-to-image translation training, we
will use SLATS scripts as examples:
scripts/slats/pretrain_slats-256.py
scripts/slats/train_slats-256.py
We recommend the following approach when adapting UVCGAN to you needs. Start
with one of the provided example scripts. Make minimal modifications to make it
work for your problem. Once it is working, further customize the model
configuration to achieve the best results.
Please organized your dataset as follows:
PATH/TO/YOUR/DATASET
βββ train
βΒ Β βββ DOMAIN_A
βΒ Β βββ DOMAIN_B
βββ test
βββ DOMAIN_A
βββ DOMAIN_Bwhere PATH/TO/YOUR/DATASET is the path to your dataset and DOMAIN_A
and DOMAIN_B are the domain names.
To make the training scripts, pretrain_slats-256.py and
train_slats-256.py, work with your dataset, they will
require minimal modifications. In essence, each script contains a Python
dictionary describing the training configuration. You would need to
modify the data section of that dictionary to make it work with your dataset.
The exact modification will depend on the format of your dataset.
This repository is primarily focused on scientific datasets. If your dataset
is made of natural images in common formats (jpeg, png, webp,
etc.), you may find it more useful to take one of the
UVCGAN or UVCGANv2 training scripts as a
starting point.
To make those scripts work with your dataset, simply modify the path parameter of the data configuration. The path should point to the location of your dataset on a disk.
We provide two examples of the data configurations that support the loading
of npz arrays:
- Plain loading of
NumPyarrays. The scriptdataloading.pydemonstrates data configuration, suitable for loadingNumPyarrays. This script loads data samples from theSLATSdataset. - Loading
NumPyand performing additional transformations. The scriptdataloading_transform.pyshows an example of the data configuration supporting user-defined transformations. This script is adapted from the BRaTS 2021 Task 1 dataset. - Customized dataset. If you are working with a custom dataset that does not
fall into the previous two categories, you will need to implement your
PyTorchdataset and place it to./uvcgan/data/datasets. Then, modify theselect_datasetfunction of./uvcgan/data/data.pyto support the usage of the custom dataset.
Unpaired image-to-image translation presents a significant challenge. As such,
it may be advantageous to start the training with prepared networks, rather
than randomly initialized ones. And the advantage of pre-training is
confirmed by multiple works (see section 5.3 of the
UVCGAN paper for more
information).
There are a number of ways to pre-training. Here for SLATS,
we use the BERT-like pretraining approach. We subdivide each image into a grid
of 32 x 32 blocks and randomly replace all values in 40% of the blocks
with zero. Then, we train a generator to fill in the blanks on the two domains
jointly. This generator is then used to initialize both generators for
translation training. For more detail on pre-training on SLATS, see section
3.3.1 of the UVCGAN4SLATS paper.
The script pretrain_slats-256.py
can be used for SLATS pre-training. If you need to adapt this script for
your dataset, consider the modification of the following configuration
options:
dataconfiguration, or for simpler cases, justpath: dataset locationdomain names: the names of the domains
label: label for this version of pre-training (will be used to name a subfolder inoutdir)outdir: output directory (will contain a subfolder named bylabel)
The generator pre-training can be started with:
python ./scripts/slats/pretrain_slats-256.py
The type of the generator and batch size can be configured using command-line
flags --gen and --batch_size, respectively. All the other parameters (e.g.
generator/discriminator, optimizer, scheduler, masking, etc.) can be modified
directly in the script.
Similar to the pre-training, you can initiate the SLATS I2I translation
training with the script
train_slats-256.py.
Likewise, to modify this script for your dataset, change the following configuration options:
dataconfiguration, or for simpler cases justpath: dataset locationdomain names: the names of the two domains
label: label for this version of training (will be used to name a subfolder inoutdir)outdir: output directory (will contain a subfolder named bylabel)transfer: Thetransferconfiguration specifies how to load the pre-trained generators. If you chose not to use a pre-trained model, set this option toNone. Otherwise, modify the path to the pre-trained model.
The translation training can be started with:
python ./scripts/slats/train_slats-256.py
Please consider tuning the following parameters for better results:
-
cycle-consistency loss coefficient
--lambda-cycle: Equal to$\lambda_{\textrm{cyc}}$ in section 3.1 of theUVCGANpaper, and$\lambda_{a}$ and$\lambda_{b}$ in section 3.3.2 of theUVCGAN4SLATSpaper. -
learning rates
--lr-genand--lr-disc: See the dicussion in section 3.3.2 of theUVCGAN4SLATSpaper. -
discriminator gradient penalty
--gp-constantand--gp-lambda: In section 3.3 of theUVCGANpaper and section 3.3.2 of theUVCGAN4SLATSpaper, we havegp-constant$=\gamma$ andgp-lambda$=\lambda_{\textrm{GP}}$ .