Exponential families for JAX
Project description
This library provides a set of tools for working with exponential family distributions in the differential programming library JAX. The exponential families are an important class of probability distributions that include the normal, gamma, beta, exponential, Poisson, binomial, and Bernoulli distributions. For an explaination of the fundamental ideas behind this library, see our overview on exponential families.
Usage
In SciPy, a distribution is represented by a single object, so a thousand distributions need a thousand objects. Each object encodes the distribution family, and the parameters of the distribution.
EFAX has a different representation. Each ExponentialFamily
object encodes only the distribution family for many (say, one thousand) distributions. The parameters of the distributions are passed in to various methods on the object to evaluate various things. For example,
from jax import numpy as jnp
from efax import BernoulliNP, BernoulliEP
# p is the expectation parameters of three Bernoulli distributions having probabilities 0.4, 0.5,
# and 0.6.
p = BernoulliEP(jnp.array([[0.4], [0.5], [0.6]]))
# q is the natural parameters of three Bernoulli distributions having log-odds 0, which is
# probability 0.5.
q = BernoulliNP(jnp.zeros((3, 1)))
print(p.cross_entropy(q))
# [0.6931472 0.6931472 0.6931472]
# q2 is natural parameters of Bernoulli distributions having a probability of 0.3.
p2 = BernoulliEP(0.3 * jnp.ones((3, 1)))
q2 = p2.to_nat()
print(p.cross_entropy(q2))
# [0.6955941 0.78032386 0.86505365]
# A Bernoulli distribution with probability 0.3 predicts a Bernoulli observation with probability
# 0.4 better than the other observations.
With exponential families, maximum likelihood estimation is just expectation over expectation parameters. Models that combine independent predictors just sum natural parameters. When we want to optimize such models, we just want to take the gradient of cross entropy with respect to predictions.
Thanks to JAX, any gradient of the cross entropy will automatically be as accurate and numerically stable as possible. This is because the gradient of the cross entropy involves the gradient of the log-normalizer, which typically has a very nice form. For example,
from jax import grad, jit, lax
from jax import numpy as jnp
from efax import BernoulliEP, BernoulliNP
def cross_entropy_loss(p, q):
return p.cross_entropy(q)
gce = jit(grad(cross_entropy_loss, 1))
def body_fun(q):
return BernoulliNP(q.log_odds - gce(some_p, q).log_odds * 1e-4)
def cond_fun(q):
return jnp.sum(gce(some_p, q).log_odds ** 2) > 1e-7
# some_p are expectation parameters of a Bernoulli distribution corresponding
# to probability 0.4.
some_p = BernoulliEP(jnp.array([0.4]))
# some_q are natural parameters of a Bernoulli distribution corresponding to
# log-odds 0, which is probability 0.5.
some_q = BernoulliNP(jnp.array([0.0]))
# Optimize the predictive distribution iteratively.
print(lax.while_loop(cond_fun, body_fun, some_q))
# Outputs the natural parameters that correspond to 0.4.
# Compare with the true value.
print(some_p.to_nat())
Contribution guidelines
Conventions: PEP8.
How to run tests:
pytest .
How to clean the source:
isort .
pylint efax
flake8 efax
mypy efax
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