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Continuous Wasserstein-2 Benchmark

This is the official Python implementation of the NeurIPS 2021 paper Do Neural Optimal Transport Solvers Work? A Continuous Wasserstein-2 Benchmark (paper on arxiv) by Alexander Korotin, Lingxiao Li, Aude Genevay, Justin Solomon, Alexander Filippov and Evgeny Burnaev.

The repository contains a set of continuous benchmark measures for testing optimal transport solvers for quadratic cost (Wasserstein-2 distance), the code for optimal transport solvers and their evaluation.

Citation

@article{korotin2021neural,
  title={Do Neural Optimal Transport Solvers Work? A Continuous Wasserstein-2 Benchmark},
  author={Korotin, Alexander and Li, Lingxiao and Genevay, Aude and Solomon, Justin M and Filippov, Alexander and Burnaev, Evgeny},
  journal={Advances in Neural Information Processing Systems},
  volume={34},
  year={2021}
}

Pre-requisites

The implementation is GPU-based. Single GPU (~GTX 1080 ti) is enough to run each particular experiment. Tested with

torch==1.3.0 torchvision==0.4.1

The code might not run as intended in newer torch versions.

Related repositories

Loading Benchmark Pairs

from src import map_benchmark as mbm

# Load benchmark pair for dimension 16 (2, 4, ..., 256)
benchmark = mbm.Mix3ToMix10Benchmark(16)
# OR load 'Early' images benchmark pair ('Early', 'Mid', 'Late')
# benchmark = mbm.CelebA64Benchmark('Early')

# Sample 32 random points from the benchmark measures
X = benchmark.input_sampler.sample(32)
Y = benchmark.output_sampler.sample(32)

# Compute the true forward map for points X
X.requires_grad_(True)
Y_true = benchmark.map_fwd(X, nograd=True)

Repository structure

All the experiments are issued in the form of pretty self-explanatory jupyter notebooks (notebooks/). Auxilary source code is moved to .py modules (src/). Continuous benchmark pairs are stored as .pt checkpoints (benchmarks/).

Evaluation of Existing Solvers

We provide all the code to evaluate existing dual OT solvers on our benchmark pairs. The qualitative results are shown below. For quantitative results, see the paper.

Testing Existing Solvers On High-Dimensional Benchmarks

  • notebooks/MM_test_hd_benchmark.ipynb -- testing [MM], [MMv2] solvers and their reversed versions
  • notebooks/MMv1_test_hd_benchmark.ipynb -- testing [MMv1] solver
  • notebooks/MM-B_test_hd_benchmark.ipynb -- testing [MM-B] solver
  • notebooks/W2_test_hd_benchmark.ipynb -- testing [W2] solver and its reversed version
  • notebooks/QC_test_hd_benchmark.ipynb -- testing [QC] solver
  • notebooks/LS_test_hd_benchmark.ipynb -- testing [LS] solver

Testing Existing Solvers On Images Benchmark Pairs (CelebA 64x64 Aligned Faces)

  • notebooks/MM_test_images_benchmark.ipynb -- testing [MM] solver and its reversed version
  • notebooks/W2_test_images_benchmark.ipynb -- testing [W2]
  • notebooks/MM-B_test_images_benchmark.ipynb -- testing [MM-B] solver
  • notebooks/QC_test_images_benchmark.ipynb -- testing [QC] solver

[LS], [MMv2], [MMv1] solvers are not considered in this experiment.

Generative Modeling by Using Existing Solvers to Compute Loss

Warning: training may take several days before achieving reasonable FID scores!

  • notebooks/MM_test_image_generation.ipynb -- generative modeling by [MM] solver or its reversed version
  • notebooks/W2_test_image_generation.ipynb -- generative modeling by [W2] solver

For [QC] solver we used the code from the official WGAN-QC repo.

Training Benchmark Pairs From Scratch

This code is provided for completeness and is not intended to be used to retrain existing benchmark pairs, but might be used as the base to train new pairs on new datasets. High-dimensional benchmak pairs can be trained from scratch. Training images benchmark pairs requires generator network checkpoints. We used WGAN-QC model to provide such checkpoints.

  • notebooks/W2_train_hd_benchmark.ipynb -- training high-dimensional benchmark bairs by [W2] solver
  • notebooks/W2_train_images_benchmark.ipynb -- training images benchmark bairs by [W2] solver

Credits