"""
This provides a small set of effect handlers in NumPyro that are modeled
after Pyro's `poutine <http://docs.pyro.ai/en/stable/poutine.html>`_ module.
For a tutorial on effect handlers more generally, readers are encouraged to
read `Poutine: A Guide to Programming with Effect Handlers in Pyro
<http://pyro.ai/examples/effect_handlers.html>`_. These simple effect handlers
can be composed together or new ones added to enable implementation of custom
inference utilities and algorithms.
**Example**
As an example, we are using :class:`~numpyro.handlers.seed`, :class:`~numpyro.handlers.trace`
and :class:`~numpyro.handlers.substitute` handlers to define the `log_likelihood` function below.
We first create a logistic regression model and sample from the posterior distribution over
the regression parameters using :func:`~numpyro.infer.MCMC`. The `log_likelihood` function
uses effect handlers to run the model by substituting sample sites with values from the posterior
distribution and computes the log density for a single data point. The `log_predictive_density`
function computes the log likelihood for each draw from the joint posterior and aggregates the
results for all the data points, but does so by using JAX's auto-vectorize transform called
`vmap` so that we do not need to loop over all the data points.
.. testsetup::
import jax.numpy as np
from jax import random, vmap
from jax.scipy.special import logsumexp
import numpyro
import numpyro.distributions as dist
from numpyro import handlers
from numpyro.infer import MCMC, NUTS
.. doctest::
>>> N, D = 3000, 3
>>> def logistic_regression(data, labels):
... coefs = numpyro.sample('coefs', dist.Normal(np.zeros(D), np.ones(D)))
... intercept = numpyro.sample('intercept', dist.Normal(0., 10.))
... logits = np.sum(coefs * data + intercept, axis=-1)
... return numpyro.sample('obs', dist.Bernoulli(logits=logits), obs=labels)
>>> data = random.normal(random.PRNGKey(0), (N, D))
>>> true_coefs = np.arange(1., D + 1.)
>>> logits = np.sum(true_coefs * data, axis=-1)
>>> labels = dist.Bernoulli(logits=logits).sample(random.PRNGKey(1))
>>> num_warmup, num_samples = 1000, 1000
>>> mcmc = MCMC(NUTS(model=logistic_regression), num_warmup, num_samples)
>>> mcmc.run(random.PRNGKey(2), data, labels) # doctest: +SKIP
sample: 100%|██████████| 1000/1000 [00:00<00:00, 1252.39it/s, 1 steps of size 5.83e-01. acc. prob=0.85]
>>> mcmc.print_summary() # doctest: +SKIP
mean sd 5.5% 94.5% n_eff Rhat
coefs[0] 0.96 0.07 0.85 1.07 455.35 1.01
coefs[1] 2.05 0.09 1.91 2.20 332.00 1.01
coefs[2] 3.18 0.13 2.96 3.37 320.27 1.00
intercept -0.03 0.02 -0.06 0.00 402.53 1.00
>>> def log_likelihood(rng_key, params, model, *args, **kwargs):
... model = handlers.substitute(handlers.seed(model, rng_key), params)
... model_trace = handlers.trace(model).get_trace(*args, **kwargs)
... obs_node = model_trace['obs']
... return obs_node['fn'].log_prob(obs_node['value'])
>>> def log_predictive_density(rng_key, params, model, *args, **kwargs):
... n = list(params.values())[0].shape[0]
... log_lk_fn = vmap(lambda rng_key, params: log_likelihood(rng_key, params, model, *args, **kwargs))
... log_lk_vals = log_lk_fn(random.split(rng_key, n), params)
... return np.sum(logsumexp(log_lk_vals, 0) - np.log(n))
>>> print(log_predictive_density(random.PRNGKey(2), mcmc.get_samples(),
... logistic_regression, data, labels)) # doctest: +SKIP
-874.89813
"""
from __future__ import absolute_import, division, print_function
from collections import OrderedDict
import warnings
from jax import random
import jax.numpy as np
from numpyro.distributions.constraints import real
from numpyro.distributions.transforms import ComposeTransform, biject_to
from numpyro.primitives import Messenger
from numpyro.util import not_jax_tracer
__all__ = [
'block',
'condition',
'replay',
'scale',
'seed',
'substitute',
'trace',
]
[docs]class trace(Messenger):
"""
Returns a handler that records the inputs and outputs at primitive calls
inside `fn`.
**Example**
.. testsetup::
from jax import random
import numpyro
import numpyro.distributions as dist
from numpyro.handlers import seed, trace
import pprint as pp
.. doctest::
>>> def model():
... numpyro.sample('a', dist.Normal(0., 1.))
>>> exec_trace = trace(seed(model, random.PRNGKey(0))).get_trace()
>>> pp.pprint(exec_trace) # doctest: +SKIP
OrderedDict([('a',
{'args': (),
'fn': <numpyro.distributions.continuous.Normal object at 0x7f9e689b1eb8>,
'is_observed': False,
'kwargs': {'rng_key': DeviceArray([0, 0], dtype=uint32)},
'name': 'a',
'type': 'sample',
'value': DeviceArray(-0.20584235, dtype=float32)})])
"""
def __enter__(self):
super(trace, self).__enter__()
self.trace = OrderedDict()
return self.trace
[docs] def postprocess_message(self, msg):
assert not(msg['type'] == 'sample' and msg['name'] in self.trace), 'all sites must have unique names'
self.trace[msg['name']] = msg.copy()
[docs] def get_trace(self, *args, **kwargs):
"""
Run the wrapped callable and return the recorded trace.
:param `*args`: arguments to the callable.
:param `**kwargs`: keyword arguments to the callable.
:return: `OrderedDict` containing the execution trace.
"""
self(*args, **kwargs)
return self.trace
[docs]class replay(Messenger):
"""
Given a callable `fn` and an execution trace `guide_trace`,
return a callable which substitutes `sample` calls in `fn` with
values from the corresponding site names in `guide_trace`.
:param fn: Python callable with NumPyro primitives.
:param guide_trace: an OrderedDict containing execution metadata.
**Example**
.. testsetup::
from jax import random
import numpyro
import numpyro.distributions as dist
from numpyro.handlers import replay, seed, trace
.. doctest::
>>> def model():
... numpyro.sample('a', dist.Normal(0., 1.))
>>> exec_trace = trace(seed(model, random.PRNGKey(0))).get_trace()
>>> print(exec_trace['a']['value']) # doctest: +SKIP
-0.20584235
>>> replayed_trace = trace(replay(model, exec_trace)).get_trace()
>>> print(exec_trace['a']['value']) # doctest: +SKIP
-0.20584235
>>> assert replayed_trace['a']['value'] == exec_trace['a']['value']
"""
def __init__(self, fn, guide_trace):
self.guide_trace = guide_trace
super(replay, self).__init__(fn)
[docs] def process_message(self, msg):
if msg['name'] in self.guide_trace:
msg['value'] = self.guide_trace[msg['name']]['value']
[docs]class block(Messenger):
"""
Given a callable `fn`, return another callable that selectively hides
primitive sites where `hide_fn` returns True from other effect handlers
on the stack.
:param fn: Python callable with NumPyro primitives.
:param hide_fn: function which when given a dictionary containing
site-level metadata returns whether it should be blocked.
**Example:**
.. testsetup::
from jax import random
import numpyro
from numpyro.handlers import block, seed, trace
import numpyro.distributions as dist
.. doctest::
>>> def model():
... a = numpyro.sample('a', dist.Normal(0., 1.))
... return numpyro.sample('b', dist.Normal(a, 1.))
>>> model = seed(model, random.PRNGKey(0))
>>> block_all = block(model)
>>> block_a = block(model, lambda site: site['name'] == 'a')
>>> trace_block_all = trace(block_all).get_trace()
>>> assert not {'a', 'b'}.intersection(trace_block_all.keys())
>>> trace_block_a = trace(block_a).get_trace()
>>> assert 'a' not in trace_block_a
>>> assert 'b' in trace_block_a
"""
def __init__(self, fn=None, hide_fn=lambda msg: True):
self.hide_fn = hide_fn
super(block, self).__init__(fn)
[docs] def process_message(self, msg):
if self.hide_fn(msg):
msg['stop'] = True
[docs]class condition(Messenger):
"""
Conditions unobserved sample sites to values from `param_map` or `condition_fn`.
Similar to :class:`~numpyro.handlers.substitute` except that it only affects
`sample` sites and changes the `is_observed` property to `True`.
:param fn: Python callable with NumPyro primitives.
:param dict param_map: dictionary of `numpy.ndarray` values keyed by
site names.
:param condition_fn: callable that takes in a site dict and returns
a numpy array or `None` (in which case the handler has no side
effect).
**Example:**
.. testsetup::
from jax import random
import numpyro
from numpyro.handlers import condition, seed, substitute, trace
import numpyro.distributions as dist
.. doctest::
>>> def model():
... numpyro.sample('a', dist.Normal(0., 1.))
>>> model = seed(model, random.PRNGKey(0))
>>> exec_trace = trace(condition(model, {'a': -1})).get_trace()
>>> assert exec_trace['a']['value'] == -1
>>> assert exec_trace['a']['is_observed']
"""
def __init__(self, fn=None, param_map=None, substitute_fn=None):
self.substitute_fn = substitute_fn
self.param_map = param_map
super(condition, self).__init__(fn)
[docs] def process_message(self, msg):
site_name = msg['name']
if msg['type'] == 'sample':
value = None
if self.param_map is not None:
if site_name in self.param_map:
value = self.param_map[site_name]
else:
value = self.substitute_fn(msg)
if value is not None:
msg['value'] = value
if msg['is_observed']:
raise ValueError("Cannot condition an already observed site: {}.".format(site_name))
msg['is_observed'] = True
[docs]class scale(Messenger):
"""
This messenger rescales the log probability score.
This is typically used for data subsampling or for stratified sampling of data
(e.g. in fraud detection where negatives vastly outnumber positives).
:param float scale_factor: a positive scaling factor
"""
def __init__(self, fn=None, scale_factor=1.):
if not_jax_tracer(scale_factor):
if scale_factor <= 0:
raise ValueError("scale factor should be a positive number.")
self.scale = scale_factor
super(scale, self).__init__(fn)
[docs] def process_message(self, msg):
msg["scale"] = self.scale * msg.get('scale', 1)
[docs]class seed(Messenger):
"""
JAX uses a functional pseudo random number generator that requires passing
in a seed :func:`~jax.random.PRNGKey` to every stochastic function. The
`seed` handler allows us to initially seed a stochastic function with a
:func:`~jax.random.PRNGKey`. Every call to the :func:`~numpyro.handlers.sample`
primitive inside the function results in a splitting of this initial seed
so that we use a fresh seed for each subsequent call without having to
explicitly pass in a `PRNGKey` to each `sample` call.
:param fn: Python callable with NumPyro primitives.
:param rng_seed: a random number generator seed.
:type rng_seed: int, np.ndarray scalar, or jax.random.PRNGKey
.. note::
Unlike in Pyro, `numpyro.sample` primitive cannot be used without wrapping
it in seed handler since there is no global random state. As such,
users need to use `seed` as a contextmanager to generate samples from
distributions or as a decorator for their model callable (See below).
**Example:**
.. testsetup::
from jax import random
import numpyro
import numpyro.handlers
import numpyro.distributions as dist
.. doctest::
>>> # as context manager
>>> with handlers.seed(rng_seed=1):
... x = numpyro.sample('x', dist.Normal(0., 1.))
>>> def model():
... return numpyro.sample('y', dist.Normal(0., 1.))
>>> # as function decorator (/modifier)
>>> y = handlers.seed(model, rng_seed=1)()
>>> assert x == y
"""
def __init__(self, fn=None, rng_seed=None, rng=None):
if rng is not None:
warnings.warn('`rng` argument is deprecated and renamed to `rng_seed` instead.', DeprecationWarning)
rng_seed = rng
if isinstance(rng_seed, int) or (isinstance(rng_seed, np.ndarray) and not np.shape(rng_seed)):
rng_seed = random.PRNGKey(rng_seed)
if not (isinstance(rng_seed, np.ndarray) and rng_seed.dtype == np.uint32 and rng_seed.shape == (2,)):
raise TypeError('Incorrect type for rng_seed: {}'.format(type(rng_seed)))
self.rng_key = rng_seed
super(seed, self).__init__(fn)
[docs] def process_message(self, msg):
if msg['type'] == 'sample' and not msg['is_observed'] and \
msg['kwargs']['rng_key'] is None:
self.rng_key, rng_key_sample = random.split(self.rng_key)
msg['kwargs']['rng_key'] = rng_key_sample
[docs]class substitute(Messenger):
"""
Given a callable `fn` and a dict `param_map` keyed by site names
(alternatively, a callable `substitute_fn`), return a callable
which substitutes all primitive calls in `fn` with values from
`param_map` whose key matches the site name. If the site name
is not present in `param_map`, there is no side effect.
If a `substitute_fn` is provided, then the value at the site is
replaced by the value returned from the call to `substitute_fn`
for the given site.
:param fn: Python callable with NumPyro primitives.
:param dict param_map: dictionary of `numpy.ndarray` values keyed by
site names.
:param dict base_param_map: similar to `param_map` but only holds samples
from base distributions.
:param substitute_fn: callable that takes in a site dict and returns
a numpy array or `None` (in which case the handler has no side
effect).
**Example:**
.. testsetup::
from jax import random
import numpyro
from numpyro.handlers import seed, substitute, trace
import numpyro.distributions as dist
.. doctest::
>>> def model():
... numpyro.sample('a', dist.Normal(0., 1.))
>>> model = seed(model, random.PRNGKey(0))
>>> exec_trace = trace(substitute(model, {'a': -1})).get_trace()
>>> assert exec_trace['a']['value'] == -1
"""
def __init__(self, fn=None, param_map=None, base_param_map=None, substitute_fn=None):
self.substitute_fn = substitute_fn
self.param_map = param_map
self.base_param_map = base_param_map
if sum((x is not None for x in (param_map, base_param_map, substitute_fn))) != 1:
raise ValueError('Only one of `param_map`, `base_param_map`, or `substitute_fn` '
'should be provided.')
super(substitute, self).__init__(fn)
[docs] def process_message(self, msg):
if self.param_map is not None:
if msg['name'] in self.param_map:
msg['value'] = self.param_map[msg['name']]
else:
base_value = self.substitute_fn(msg) if self.substitute_fn \
else self.base_param_map.get(msg['name'], None)
if base_value is not None:
if msg['type'] == 'sample':
msg['value'], msg['intermediates'] = msg['fn'].transform_with_intermediates(
base_value)
else:
constraint = msg['kwargs'].pop('constraint', real)
transform = biject_to(constraint)
if isinstance(transform, ComposeTransform):
# No need to apply the first transform since the base value
# should have the same support as the first part's co-domain.
msg['value'] = ComposeTransform(transform.parts[1:])(base_value)
else:
msg['value'] = base_value