Metadata-Version: 2.1
Name: lagrangebench
Version: 0.0.2
Summary: LagrangeBench: A Lagrangian Fluid Mechanics Benchmarking Suite
License: MIT
Author: Artur Toshev
Author-email: artur.toshev@tum.de
Requires-Python: >=3.9,<=3.11
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Requires-Dist: PyYAML (>=6.0)
Requires-Dist: cloudpickle (>=2.2.1)
Requires-Dist: dm-haiku (>=0.0.10)
Requires-Dist: e3nn-jax (==0.20.2)
Requires-Dist: h5py (>=3.9.0)
Requires-Dist: jax (==0.4.18)
Requires-Dist: jax-md (==0.2.8)
Requires-Dist: jaxlib (==0.4.18)
Requires-Dist: jmp (>=0.0.4,<0.0.5)
Requires-Dist: jraph (==0.0.6.dev0)
Requires-Dist: matscipy (>=0.8.0,<0.9.0)
Requires-Dist: numpy (>=1.24.4)
Requires-Dist: optax (==0.1.7)
Requires-Dist: ott-jax (>=0.4.2,<0.5.0)
Requires-Dist: pyvista (>=0.42.2)
Requires-Dist: torch (==2.1.0+cpu)
Requires-Dist: wandb (>=0.15.11)
Requires-Dist: wget (>=3.2,<4.0)
Description-Content-Type: text/markdown

# LagrangeBench: A Lagrangian Fluid Mechanics Benchmarking Suite

## Installation
### Standalone library
Install the core `lagrangebench` library from PyPi as
```bash
pip install lagrangebench --extra-index-url=https://download.pytorch.org/whl/cpu
```

Note that by default `lagrangebench` is installed without JAX GPU support. For that follow the instructions in the [GPU support](#gpu-support) section.

### Clone
Clone this GitHub repository
```bash
git clone https://github.com/tumaer/lagrangebench.git
cd lagrangebench
```

Install the dependencies with __Poetry (>=1.6.0)__
```
poetry install --only main
```

Alternatively, a requirements file is provided. It directly installs the CUDA version of JAX.
```
pip install -r requirements_cuda.txt
```
For a CPU version of the requirements file, use the one in `docs/requirements.txt`.

### GPU support
To run JAX on GPU, follow the [Jax CUDA guide](https://github.com/google/jax#pip-installation-gpu-cuda-installed-via-pip-easier), or in general run
```bash
pip install --upgrade jax[cuda11_pip]==0.4.18 -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html
# or, for cuda 12
pip install --upgrade jax[cuda12_pip]==0.4.18 -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html
```

## Usage
### Standalone benchmark library
A general tutorial is provided in the example notebook "Training GNS on the 2D Taylor Green Vortex" under `./notebooks/tutorial.ipynb` on the [LagrangeBench repository](https://github.com/tumaer/lagrangebench). The notebook covers the basics of LagrangeBench, such as loading a dataset, setting up a case, training a model from scratch and evaluating it's performance.

### Running in a local clone (`main.py`)
Alternatively, experiments can also be set up with `main.py`, based around extensive YAML config files and cli arguments (check `configs/` and `experiments/configs.py`). By default, passed cli arguments will overwrite the YAML config. When loading a saved model with `--model_dir` the config from the checkpoint is automatically loaded and training is restarted.

**Train**

For example, to start a _GNS_ run from scratch on the RPF 2D dataset use
```
python main.py --config configs/rpf_2d/gns.yaml
```
Some model presets can be found in `./configs/`.

If `--mode=all`, then training (`--mode=train`) and subsequent inference (`--mode=infer`) on the test split will be run in one go.


**Restart training**

To restart training from the last checkpoint in `--model_dir` use
```
python main.py --model_dir ckp/gns_rpf2d_yyyymmdd-hhmmss
```

**Inference**

To evaluate a trained model from `--model_dir` on the test split (`--test`) use
```
python main.py --model_dir ckp/gns_rpf2d_yyyymmdd-hhmmss/best --rollout_dir rollout/gns_rpf2d_yyyymmdd-hhmmss/best --mode infer --test
```

If the default `--out_type_infer=pkl` is active, then the generated trajectories and a `metricsYYYY_MM_DD_HH_MM_SS.pkl` file will be written to the `--rollout_dir`. The metrics file contains all `--metrics_infer` properties for each generated rollout.

## Datasets
The datasets are hosted on Zenodo under the DOI: [10.5281/zenodo.10021925](https://zenodo.org/doi/10.5281/zenodo.10021925). When creating a new dataset instance, the data is automatically downloaded. Alternatively, to manually download them use the `download_data.sh` shell script, either with a specific dataset name or "all". Namely
- __Taylor Green Vortex 2D__: `bash download_data.sh tgv_2d datasets/`
- __Reverse Poiseuille Flow 2D__: `bash download_data.sh rpf_2d datasets/`
- __Lid Driven Cavity 2D__: `bash download_data.sh ldc_2d datasets/`
- __Dam break 2D__: `bash download_data.sh dam_2d datasets/`
- __Taylor Green Vortex 3D__: `bash download_data.sh tgv_3d datasets/`
- __Reverse Poiseuille Flow 3D__: `bash download_data.sh rpf_3d datasets/`
- __Lid Driven Cavity 3D__: `bash download_data.sh ldc_3d datasets/`
- __All__: `bash download_data.sh all datasets/`


### Notebooks

Two notebooks dedicated to the datases are provided:
- `./notebooks/datasets.ipynb` with more details and visualizations on the LagrangeBench datasets, and
- `./notebooks/gns_data.ipynb` showing how to train models within LagrangeBench on the datasets from the paper [Learning to Simulate Complex Physics with Graph Networks](https://arxiv.org/abs/2002.09405).

## Directory structure
```
📦lagrangebench
 ┣ 📂case_setup     # Case setup manager
 ┃ ┣ 📜case.py      # CaseSetupFn class
 ┃ ┣ 📜features.py  # Feature extraction
 ┃ ┗ 📜partition.py # Alternative neighbor list implementations
 ┣ 📂data           # Datasets and dataloading utils
 ┃ ┣ 📜data.py      # H5Dataset class and specific datasets
 ┃ ┗ 📜utils.py
 ┣ 📂evaluate       # Evaluation and rollout generation tools
 ┃ ┣ 📜metrics.py
 ┃ ┗ 📜rollout.py
 ┣ 📂models         # Baseline models
 ┃ ┣ 📜base.py      # BaseModel class
 ┃ ┣ 📜egnn.py
 ┃ ┣ 📜gns.py
 ┃ ┣ 📜linear.py
 ┃ ┣ 📜painn.py
 ┃ ┣ 📜segnn.py
 ┃ ┗ 📜utils.py
 ┣ 📂train          # Trainer method and training tricks
 ┃ ┣ 📜strats.py    # Training tricks
 ┃ ┗ 📜trainer.py   # Trainer method
 ┣ 📜defaults.py    # Default values
 ┗ 📜utils.py
```


## Citation
The paper (at NeurIPS 2023 Datasets and Benchmarks) can be cited as:
```bibtex
@inproceedings{toshev2023lagrangebench,
    title      = {LagrangeBench: A Lagrangian Fluid Mechanics Benchmarking Suite},
    author     = {Artur P. Toshev and Gianluca Galletti and Fabian Fritz and Stefan Adami and Nikolaus A. Adams},
    year       = {2023},
    url        = {https://arxiv.org/abs/2309.16342},
    booktitle  = {37th Conference on Neural Information Processing Systems (NeurIPS 2023) Track on Datasets and Benchmarks},
}
```

The associated datasets can be cited as:
```bibtex
@dataset{toshev_2023_10021926,
  author       = {Toshev, Artur P. and Adams, Nikolaus A.},
  title        = {LagrangeBench Datasets},
  month        = oct,
  year         = 2023,
  publisher    = {Zenodo},
  version      = {0.0.1},
  url          = {https://zenodo.org/doi/10.5281/zenodo.10021925},
  doi          = {10.5281/zenodo.10021925},
}
```


### Publications
The following further publcations are based on the LagrangeBench codebase:

1. [Learning Lagrangian Fluid Mechanics with E(3)-Equivariant Graph Neural Networks (GSI 2023)](https://arxiv.org/abs/2305.15603), A. P. Toshev, G. Galletti, J. Brandstetter, S. Adami, N. A. Adams

