An improved node graph optimization method for inverse procedural material modeling.
Yiwei Hu, Paul Guerrero, Miloš Hašan, Holly Rushmeier, Valentin Deschaintre
In SIGGRAPH '22 Conference Processing, Vancouver, BC, Canada, 2022. [Project page]
See requirements for StyleGAN3: https://github.com/NVlabs/stylegan3.
We modify the training setup by making the inputs as normalized parameters only, and implement our customized loss functions in loss.py.
Training code of StyleGAN is included in stylegan folder. (Updated on 12/10/2022)
All commands are listed in cmd.py for convenience.
Step 1: Please specify a correct path sat_dir to substance automatic toolkit in synthesis.py and then synthesize training data:
python synthesis.py --data_path=./data/sbs --generator_name=arc_pavement --n_samples=307200307200 images will be synthesized into a folder ./data/sbs/arc_pavement
Step 2: Build the training dataset:
python stylegan/dataset_tool.py --source=./data/sbs/arc_pavement --dest=./data/train/arc_pavement_300k.zipA dataset for training StyleGAN will be generated at the location ./data/train/arc_pavement_300k.zip.
If you want to train your own data, please make sure you have a json file that stores parameters for each image,
and use stylegan/dataset_tool.py (Step 2) to build a dataset for training. We include an example of such json file in ./data/example.
Please check cmd.py for the training command. Generally, there are two versions of networks: with GAN loss and without GAN loss, which is specified by an option --no_gan. The training log and intermediate results can be found in training-runs subfolder.
In order to run the code, please put the pretrained VGG19 model into ./pretrained folder. The VGG19 model can be downloaded from here: https://drive.google.com/file/d/13TTR61wQ3OVJUKk6P39HegoWBQ-_MUQq/view?usp=sharing.
Loss weights can be adjusted in the loss.py .
generate.py is a simple script describing how to use the trained differentiable proxy to generate images and compare to the real generator.
To train a new generator, you need to implement an appropriate parameter sampling method for that generator. The code can be found in ./sbs/sbs_generator.py. Define you own generator class by overwriting method get_params(). Two basic samplers are defined to sample parameters: RandomSampler (uniform sampling based on min and max values) and GaussianRandomSampler (Gaussian-like sampling based on mean and std, and the sampled values are clipped between min and max). What you need to do is to create your own class and then register that class in the variable generator_lookup_table.
The samplers can be arbitrary for each parameter. GaussianRandomSampler is recommended if you have the reasonable statistics for that parameter. But note that during training phase, there is an option --norm_type specifies the normalization method applied on the parameters during the training phase. Currently, there are two options norm and std. The norm method rescales parameters between 0 and 1 based on min and max values, while std works by normalizing the parameters to mean=0 and std=1 so std option only works when all the samplers are GaussianRandomSampler.
After defining the sampling method, you should prepare a .sbs file similar to ./data/sbs/arc_pavement.sbs. You can find a template file in ./data/sbs named as basic.sbs. All you need to do is to open that file and replace the placeholder generator by your own generator and rename the sbs file properly. However, only 1 generator can be very slow when generating data. We recommend you copy-paste that "two-node" node graph 512 times or 1024 times. This will make the program synthesize 512 mask maps or 1024 mask maps for each step.
You should now be able to generate the data and train the networks. To test if the data is correctly generated, we recommend first generating a couple of mask maps (e.g. 128 or 256) to see if their general appearances looks reasonable. To see if your sampled parameters are correctly saved as a json file, you can specify --verify=True when you call synthesis.py. The program will re-generate all the mask maps to another folder based on the parameters your just sampled. This can help you examine whether the parameter you sampled and the generated mask map is a correct one-on-one mapping. Note verify=True should be only used for verification and prevent using it when you generating the whole dataset.
@inproceedings{hu2022diff,
author = {Hu, Yiwei and Guerrero, Paul and Hasan, Milos and Rushmeier, Holly and Deschaintre, Valentin},
title = {Node Graph Optimization Using Differentiable Proxies},
year = {2022},
isbn = {9781450393379},
publisher = {Association for Computing Machinery},
address = {New York, NY, USA},
url = {https://doi.org/10.1145/3528233.3530733},
doi = {10.1145/3528233.3530733},
booktitle = {ACM SIGGRAPH 2022 Conference Proceedings},
articleno = {5},
numpages = {9},
keywords = {inverse material modeling, procedural materials},
location = {Vancouver, BC, Canada},
series = {SIGGRAPH '22}
}
If you have any question, feel free to contact yiwei.hu@yale.edu