Skip to content
/ ott Public

Optimal transport tools implemented with the JAX framework, to get differentiable, parallel and jit-able computations.

License

Notifications You must be signed in to change notification settings

ott-jax/ott

Repository files navigation

logo

Optimal Transport Tools (OTT)

Downloads Tests Docs Coverage

See the full documentation.

What is OTT-JAX?

A JAX powered library to compute optimal transport at scale and on accelerators, OTT-JAX includes the fastest implementation of the Sinkhorn algorithm you will find around. We have implemented all tweaks (scheduling, momentum, acceleration, initializations) and extensions (low-rank, entropic maps). They can be used directly between two datasets, or within more advanced problems (Gromov-Wasserstein, barycenters). Some of JAX features, including JIT, auto-vectorization and implicit differentiation work towards the goal of having end-to-end differentiable outputs. OTT-JAX is led by a team of researchers at Apple, with contributions from Google and Meta researchers, as well as many academic partners, including TU München, Oxford, ENSAE/IP Paris, ENS Paris and the Hebrew University.

Installation

Install OTT-JAX from PyPI as:

pip install ott-jax

or with conda via conda-forge as:

conda install -c conda-forge ott-jax

What is optimal transport?

Optimal transport can be loosely described as the branch of mathematics and optimization that studies matching problems: given two families of points, and a cost function on pairs of points, find a "good" (low cost) way to associate bijectively to every point in the first family another in the second.

Such problems appear in all areas of science, are easy to describe, yet hard to solve. Indeed, while matching optimally two sets of $n$ points using a pairwise cost can be solved with the Hungarian algorithm, solving it costs an order of $O(n^3)$ operations, and lacks flexibility, since one may want to couple families of different sizes.

Optimal transport extends all of this, through faster algorithms (in $n^2$ or even linear in $n$) along with numerous generalizations that can help it handle weighted sets of different size, partial matchings, and even more evolved so-called quadratic matching problems.

In the simple toy example below, we compute the optimal coupling matrix between two point clouds sampled randomly (2D vectors, compared with the squared Euclidean distance):

Example

import jax
import jax.numpy as jnp

from ott.geometry import pointcloud
from ott.problems.linear import linear_problem
from ott.solvers.linear import sinkhorn

# sample two point clouds and their weights.
rngs = jax.random.split(jax.random.key(0), 4)
n, m, d = 12, 14, 2
x = jax.random.normal(rngs[0], (n,d)) + 1
y = jax.random.uniform(rngs[1], (m,d))
a = jax.random.uniform(rngs[2], (n,))
b = jax.random.uniform(rngs[3], (m,))
a, b = a / jnp.sum(a), b / jnp.sum(b)
# Computes the couplings using the Sinkhorn algorithm.
geom = pointcloud.PointCloud(x, y)
prob = linear_problem.LinearProblem(geom, a, b)

solver = sinkhorn.Sinkhorn()
out = solver(prob)

The call to solver(prob) above works out the optimal transport solution. The out object contains a transport matrix (here of size $12\times 14$) that quantifies the association strength between each point of the first point cloud, to one or more points from the second, as illustrated in the plot below. We provide more flexibility to define custom cost functions, objectives, and solvers, as detailed in the full documentation.

obtained coupling

Citation

If you have found this work useful, please consider citing this reference:

@article{cuturi2022optimal,
  title={Optimal Transport Tools (OTT): A JAX Toolbox for all things Wasserstein},
  author={Cuturi, Marco and Meng-Papaxanthos, Laetitia and Tian, Yingtao and Bunne, Charlotte and
          Davis, Geoff and Teboul, Olivier},
  journal={arXiv preprint arXiv:2201.12324},
  year={2022}
}

See also

The moscot package for OT analysis of multi-omics data also uses OTT as a backbone.