#!/usr/bin/env python3
# Copyright (c) Meta Platforms, Inc. and affiliates.
#
# This source code is licensed under the MIT license found in the
# LICENSE file in the root directory of this source tree.
r"""
Gaussian Process Regression models based on GPyTorch models.
"""
from __future__ import annotations
from typing import Any, Dict, List, Optional, Union
import torch
from botorch import settings
from botorch.models.gpytorch import BatchedMultiOutputGPyTorchModel
from botorch.models.transforms.input import InputTransform
from botorch.models.transforms.outcome import Log, OutcomeTransform
from botorch.models.utils import fantasize as fantasize_flag, validate_input_scaling
from botorch.sampling.samplers import MCSampler
from botorch.utils.containers import TrainingData
from gpytorch.constraints.constraints import GreaterThan
from gpytorch.distributions.multivariate_normal import MultivariateNormal
from gpytorch.kernels.matern_kernel import MaternKernel
from gpytorch.kernels.scale_kernel import ScaleKernel
from gpytorch.likelihoods.gaussian_likelihood import (
_GaussianLikelihoodBase,
FixedNoiseGaussianLikelihood,
GaussianLikelihood,
)
from gpytorch.likelihoods.likelihood import Likelihood
from gpytorch.likelihoods.noise_models import HeteroskedasticNoise
from gpytorch.means.constant_mean import ConstantMean
from gpytorch.means.mean import Mean
from gpytorch.mlls.noise_model_added_loss_term import NoiseModelAddedLossTerm
from gpytorch.models.exact_gp import ExactGP
from gpytorch.module import Module
from gpytorch.priors.smoothed_box_prior import SmoothedBoxPrior
from gpytorch.priors.torch_priors import GammaPrior
from torch import Tensor
MIN_INFERRED_NOISE_LEVEL = 1e-4
[docs]class SingleTaskGP(BatchedMultiOutputGPyTorchModel, ExactGP):
r"""A single-task exact GP model.
A single-task exact GP using relatively strong priors on the Kernel
hyperparameters, which work best when covariates are normalized to the unit
cube and outcomes are standardized (zero mean, unit variance).
This model works in batch mode (each batch having its own hyperparameters).
When the training observations include multiple outputs, this model will use
batching to model outputs independently.
Use this model when you have independent output(s) and all outputs use the
same training data. If outputs are independent and outputs have different
training data, use the ModelListGP. When modeling correlations between
outputs, use the MultiTaskGP.
"""
def __init__(
self,
train_X: Tensor,
train_Y: Tensor,
likelihood: Optional[Likelihood] = None,
covar_module: Optional[Module] = None,
mean_module: Optional[Mean] = None,
outcome_transform: Optional[OutcomeTransform] = None,
input_transform: Optional[InputTransform] = None,
) -> None:
r"""A single-task exact GP model.
Args:
train_X: A `batch_shape x n x d` tensor of training features.
train_Y: A `batch_shape x n x m` tensor of training observations.
likelihood: A likelihood. If omitted, use a standard
GaussianLikelihood with inferred noise level.
covar_module: The module computing the covariance (Kernel) matrix.
If omitted, use a `MaternKernel`.
mean_module: The mean function to be used. If omitted, use a
`ConstantMean`.
outcome_transform: An outcome transform that is applied to the
training data during instantiation and to the posterior during
inference (that is, the `Posterior` obtained by calling
`.posterior` on the model will be on the original scale).
input_transform: An input transform that is applied in the model's
forward pass.
Example:
>>> train_X = torch.rand(20, 2)
>>> train_Y = torch.sin(train_X).sum(dim=1, keepdim=True)
>>> model = SingleTaskGP(train_X, train_Y)
"""
with torch.no_grad():
transformed_X = self.transform_inputs(
X=train_X, input_transform=input_transform
)
if outcome_transform is not None:
train_Y, _ = outcome_transform(train_Y)
self._validate_tensor_args(X=transformed_X, Y=train_Y)
ignore_X_dims = getattr(self, "_ignore_X_dims_scaling_check", None)
validate_input_scaling(
train_X=transformed_X, train_Y=train_Y, ignore_X_dims=ignore_X_dims
)
self._set_dimensions(train_X=train_X, train_Y=train_Y)
train_X, train_Y, _ = self._transform_tensor_args(X=train_X, Y=train_Y)
if likelihood is None:
noise_prior = GammaPrior(1.1, 0.05)
noise_prior_mode = (noise_prior.concentration - 1) / noise_prior.rate
likelihood = GaussianLikelihood(
noise_prior=noise_prior,
batch_shape=self._aug_batch_shape,
noise_constraint=GreaterThan(
MIN_INFERRED_NOISE_LEVEL,
transform=None,
initial_value=noise_prior_mode,
),
)
else:
self._is_custom_likelihood = True
ExactGP.__init__(self, train_X, train_Y, likelihood)
if mean_module is None:
mean_module = ConstantMean(batch_shape=self._aug_batch_shape)
self.mean_module = mean_module
if covar_module is None:
covar_module = ScaleKernel(
MaternKernel(
nu=2.5,
ard_num_dims=transformed_X.shape[-1],
batch_shape=self._aug_batch_shape,
lengthscale_prior=GammaPrior(3.0, 6.0),
),
batch_shape=self._aug_batch_shape,
outputscale_prior=GammaPrior(2.0, 0.15),
)
self._subset_batch_dict = {
"likelihood.noise_covar.raw_noise": -2,
"mean_module.constant": -2,
"covar_module.raw_outputscale": -1,
"covar_module.base_kernel.raw_lengthscale": -3,
}
self.covar_module = covar_module
# TODO: Allow subsetting of other covar modules
if outcome_transform is not None:
self.outcome_transform = outcome_transform
if input_transform is not None:
self.input_transform = input_transform
self.to(train_X)
[docs] def forward(self, x: Tensor) -> MultivariateNormal:
if self.training:
x = self.transform_inputs(x)
mean_x = self.mean_module(x)
covar_x = self.covar_module(x)
return MultivariateNormal(mean_x, covar_x)
[docs]class FixedNoiseGP(BatchedMultiOutputGPyTorchModel, ExactGP):
r"""A single-task exact GP model using fixed noise levels.
A single-task exact GP that uses fixed observation noise levels. This model
also uses relatively strong priors on the Kernel hyperparameters, which work
best when covariates are normalized to the unit cube and outcomes are
standardized (zero mean, unit variance).
This model works in batch mode (each batch having its own hyperparameters).
"""
def __init__(
self,
train_X: Tensor,
train_Y: Tensor,
train_Yvar: Tensor,
covar_module: Optional[Module] = None,
mean_module: Optional[Mean] = None,
outcome_transform: Optional[OutcomeTransform] = None,
input_transform: Optional[InputTransform] = None,
**kwargs: Any,
) -> None:
r"""A single-task exact GP model using fixed noise levels.
Args:
train_X: A `batch_shape x n x d` tensor of training features.
train_Y: A `batch_shape x n x m` tensor of training observations.
train_Yvar: A `batch_shape x n x m` tensor of observed measurement
noise.
covar_module: The module computing the covariance (Kernel) matrix.
If omitted, use a `MaternKernel`.
mean_module: The mean function to be used. If omitted, use a
`ConstantMean`.
outcome_transform: An outcome transform that is applied to the
training data during instantiation and to the posterior during
inference (that is, the `Posterior` obtained by calling
`.posterior` on the model will be on the original scale).
input_transform: An input transfrom that is applied in the model's
forward pass.
Example:
>>> train_X = torch.rand(20, 2)
>>> train_Y = torch.sin(train_X).sum(dim=1, keepdim=True)
>>> train_Yvar = torch.full_like(train_Y, 0.2)
>>> model = FixedNoiseGP(train_X, train_Y, train_Yvar)
"""
with torch.no_grad():
transformed_X = self.transform_inputs(
X=train_X, input_transform=input_transform
)
if outcome_transform is not None:
train_Y, train_Yvar = outcome_transform(train_Y, train_Yvar)
self._validate_tensor_args(X=transformed_X, Y=train_Y, Yvar=train_Yvar)
validate_input_scaling(
train_X=transformed_X, train_Y=train_Y, train_Yvar=train_Yvar
)
self._set_dimensions(train_X=train_X, train_Y=train_Y)
train_X, train_Y, train_Yvar = self._transform_tensor_args(
X=train_X, Y=train_Y, Yvar=train_Yvar
)
likelihood = FixedNoiseGaussianLikelihood(
noise=train_Yvar, batch_shape=self._aug_batch_shape
)
ExactGP.__init__(
self, train_inputs=train_X, train_targets=train_Y, likelihood=likelihood
)
if mean_module is None:
mean_module = ConstantMean(batch_shape=self._aug_batch_shape)
self.mean_module = mean_module
if covar_module is None:
covar_module = ScaleKernel(
base_kernel=MaternKernel(
nu=2.5,
ard_num_dims=transformed_X.shape[-1],
batch_shape=self._aug_batch_shape,
lengthscale_prior=GammaPrior(3.0, 6.0),
),
batch_shape=self._aug_batch_shape,
outputscale_prior=GammaPrior(2.0, 0.15),
)
self._subset_batch_dict = {
"mean_module.constant": -2,
"covar_module.raw_outputscale": -1,
"covar_module.base_kernel.raw_lengthscale": -3,
}
self.covar_module = covar_module
# TODO: Allow subsetting of other covar modules
if input_transform is not None:
self.input_transform = input_transform
if outcome_transform is not None:
self.outcome_transform = outcome_transform
self.to(train_X)
[docs] def fantasize(
self,
X: Tensor,
sampler: MCSampler,
observation_noise: Union[bool, Tensor] = True,
**kwargs: Any,
) -> FixedNoiseGP:
r"""Construct a fantasy model.
Constructs a fantasy model in the following fashion:
(1) compute the model posterior at `X` (if `observation_noise=True`,
this includes observation noise taken as the mean across the observation
noise in the training data. If `observation_noise` is a Tensor, use
it directly as the observation noise to add).
(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 the mean across the observation
noise in the training data as observation noise in the posterior
from which the samples are drawn. If a Tensor, use it directly
as the specified measurement noise.
Returns:
The constructed fantasy model.
"""
propagate_grads = kwargs.pop("propagate_grads", False)
with fantasize_flag():
with settings.propagate_grads(propagate_grads):
post_X = self.posterior(
X, observation_noise=observation_noise, **kwargs
)
Y_fantasized = sampler(post_X) # num_fantasies x batch_shape x n' x m
# Use the mean of the previous noise values (TODO: be smarter here).
# noise should be batch_shape x q x m when X is batch_shape x q x d, and
# Y_fantasized is num_fantasies x batch_shape x q x m.
noise_shape = Y_fantasized.shape[1:]
noise = self.likelihood.noise.mean().expand(noise_shape)
return self.condition_on_observations(
X=self.transform_inputs(X), Y=Y_fantasized, noise=noise
)
[docs] def forward(self, x: Tensor) -> MultivariateNormal:
if self.training:
x = self.transform_inputs(x)
mean_x = self.mean_module(x)
covar_x = self.covar_module(x)
return MultivariateNormal(mean_x, covar_x)
[docs] def subset_output(self, idcs: List[int]) -> BatchedMultiOutputGPyTorchModel:
r"""Subset the model along the output dimension.
Args:
idcs: The output indices to subset the model to.
Returns:
The current model, subset to the specified output indices.
"""
new_model = super().subset_output(idcs=idcs)
full_noise = new_model.likelihood.noise_covar.noise
new_noise = full_noise[..., idcs if len(idcs) > 1 else idcs[0], :]
new_model.likelihood.noise_covar.noise = new_noise
return new_model
[docs]class HeteroskedasticSingleTaskGP(SingleTaskGP):
r"""A single-task exact GP model using a heteroskeastic noise model.
This model internally wraps another GP (a SingleTaskGP) to model the
observation noise. This allows the likelihood to make out-of-sample
predictions for the observation noise levels.
"""
def __init__(
self,
train_X: Tensor,
train_Y: Tensor,
train_Yvar: Tensor,
outcome_transform: Optional[OutcomeTransform] = None,
input_transform: Optional[InputTransform] = None,
) -> None:
r"""A single-task exact GP model using a heteroskedastic noise model.
Args:
train_X: A `batch_shape x n x d` tensor of training features.
train_Y: A `batch_shape x n x m` tensor of training observations.
train_Yvar: A `batch_shape x n x m` tensor of observed measurement
noise.
outcome_transform: An outcome transform that is applied to the
training data during instantiation and to the posterior during
inference (that is, the `Posterior` obtained by calling
`.posterior` on the model will be on the original scale).
Note that the noise model internally log-transforms the
variances, which will happen after this transform is applied.
input_transform: An input transfrom that is applied in the model's
forward pass.
Example:
>>> train_X = torch.rand(20, 2)
>>> train_Y = torch.sin(train_X).sum(dim=1, keepdim=True)
>>> se = torch.norm(train_X, dim=1, keepdim=True)
>>> train_Yvar = 0.1 + se * torch.rand_like(train_Y)
>>> model = HeteroskedasticSingleTaskGP(train_X, train_Y, train_Yvar)
"""
if outcome_transform is not None:
train_Y, train_Yvar = outcome_transform(train_Y, train_Yvar)
self._validate_tensor_args(X=train_X, Y=train_Y, Yvar=train_Yvar)
validate_input_scaling(train_X=train_X, train_Y=train_Y, train_Yvar=train_Yvar)
self._set_dimensions(train_X=train_X, train_Y=train_Y)
noise_likelihood = GaussianLikelihood(
noise_prior=SmoothedBoxPrior(-3, 5, 0.5, transform=torch.log),
batch_shape=self._aug_batch_shape,
noise_constraint=GreaterThan(
MIN_INFERRED_NOISE_LEVEL, transform=None, initial_value=1.0
),
)
noise_model = SingleTaskGP(
train_X=train_X,
train_Y=train_Yvar,
likelihood=noise_likelihood,
outcome_transform=Log(),
input_transform=input_transform,
)
likelihood = _GaussianLikelihoodBase(HeteroskedasticNoise(noise_model))
super().__init__(
train_X=train_X,
train_Y=train_Y,
likelihood=likelihood,
input_transform=input_transform,
)
self.register_added_loss_term("noise_added_loss")
self.update_added_loss_term(
"noise_added_loss", NoiseModelAddedLossTerm(noise_model)
)
if outcome_transform is not None:
self.outcome_transform = outcome_transform
self.to(train_X)
[docs] def condition_on_observations(
self, X: Tensor, Y: Tensor, **kwargs: Any
) -> HeteroskedasticSingleTaskGP:
raise NotImplementedError
[docs] def subset_output(self, idcs: List[int]) -> HeteroskedasticSingleTaskGP:
raise NotImplementedError
