Source code for botorch.models.model
#! /usr/bin/env python3
# Copyright (c) Facebook, Inc. and its affiliates.
#
# This source code is licensed under the MIT license found in the
# LICENSE file in the root directory of this source tree.
r"""
Abstract base module for all BoTorch models.
"""
from abc import ABC, abstractmethod
from typing import Any, List, Optional
from torch import Tensor
from torch.nn import Module
from .. import settings
from ..posteriors import Posterior
from ..sampling.samplers import MCSampler
[docs]class Model(Module, ABC):
r"""Abstract base class for BoTorch models."""
[docs] @abstractmethod
def posterior(
self,
X: Tensor,
output_indices: Optional[List[int]] = None,
observation_noise: bool = False,
**kwargs: Any,
) -> Posterior:
r"""Computes the posterior over model outputs at the provided points.
Args:
X: A `b x q x d`-dim Tensor, where `d` is the dimension of the
feature space, `q` is the number of points considered jointly,
and `b` is the batch dimension.
output_indices: A list of indices, corresponding to the outputs over
which to compute the posterior (if the model is multi-output).
Can be used to speed up computation if only a subset of the
model's outputs are required for optimization. If omitted,
computes the posterior over all model outputs.
observation_noise: If True, add observation noise to the posterior.
Returns:
A `Posterior` object, representing a batch of `b` joint distributions
over `q` points and `m` outputs each.
"""
pass # pragma: no cover
@property
def num_outputs(self) -> int:
r"""The number of outputs of the model."""
cls_name = self.__class__.__name__
raise NotImplementedError(f"{cls_name} does not define num_outputs property")
[docs] def subset_output(self, idcs: List[int]) -> "Model":
r"""Subset the model along the output dimension.
Args:
idcs: The output indices to subset the model to.
Returns:
A `Model` object of the same type and with the same parameters as
the current model, subset to the specified output indices.
"""
raise NotImplementedError
[docs] def condition_on_observations(self, X: Tensor, Y: Tensor, **kwargs: Any) -> "Model":
r"""Condition the model on new observations.
Args:
X: A `batch_shape x n' x d`-dim Tensor, where `d` is the dimension of
the feature space, `n'` is the number of points per batch, and
`batch_shape` is the batch shape (must be compatible with the
batch shape of the model).
Y: A `batch_shape' x n' x m`-dim Tensor, where `m` is the number of
model outputs, `n'` is the number of points per batch, and
`batch_shape'` is the batch shape of the observations.
`batch_shape'` must be broadcastable to `batch_shape` using
standard broadcasting semantics. If `Y` has fewer batch dimensions
than `X`, it is assumed that the missing batch dimensions are
the same for all `Y`.
Returns:
A `Model` object of the same type, representing the original model
conditioned on the new observations `(X, Y)` (and possibly noise
observations passed in via kwargs).
"""
raise NotImplementedError
[docs] def fantasize(
self,
X: Tensor,
sampler: MCSampler,
observation_noise: bool = True,
**kwargs: Any,
) -> "Model":
r"""Construct a fantasy model.
Constructs a fantasy model in the following fashion:
(1) compute the model posterior at `X` (including observation noise if
`observation_noise=True`).
(2) sample from this posterior (using `sampler`) to generate "fake"
observations.
(3) condition the model on the new fake observations.
Args:
X: A `batch_shape x n' x d`-dim Tensor, where `d` is the dimension of
the feature space, `n'` is the number of points per batch, and
`batch_shape` is the batch shape (must be compatible with the
batch shape of the model).
sampler: The sampler used for sampling from the posterior at `X`.
observation_noise: If True, include observation noise.
Returns:
The constructed fantasy model.
"""
propagate_grads = kwargs.pop("propagate_grads", False)
with settings.propagate_grads(propagate_grads):
post_X = self.posterior(X, observation_noise=observation_noise)
Y_fantasized = sampler(post_X) # num_fantasies x batch_shape x n' x m
return self.condition_on_observations(X=X, Y=Y_fantasized, **kwargs)