# Source code for botorch.utils.transforms

```
#!/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"""
Some basic data transformation helpers.
"""
from __future__ import annotations
import warnings
from functools import wraps
from typing import Any, Callable, List, Optional, TYPE_CHECKING
import torch
from torch import Tensor
if TYPE_CHECKING:
from botorch.acquisition import AcquisitionFunction # pragma: no cover
from botorch.model import Model # pragma: no cover
[docs]def squeeze_last_dim(Y: Tensor) -> Tensor:
r"""Squeeze the last dimension of a Tensor.
Args:
Y: A `... x d`-dim Tensor.
Returns:
The input tensor with last dimension squeezed.
Example:
>>> Y = torch.rand(4, 3)
>>> Y_squeezed = squeeze_last_dim(Y)
"""
warnings.warn(
"`botorch.utils.transforms.squeeze_last_dim` is deprecated. "
"Simply use `.squeeze(-1)1 instead.",
DeprecationWarning,
)
return Y.squeeze(-1)
[docs]def standardize(Y: Tensor) -> Tensor:
r"""Standardizes (zero mean, unit variance) a tensor by dim=-2.
If the tensor is single-dimensional, simply standardizes the tensor.
If for some batch index all elements are equal (or if there is only a single
data point), this function will return 0 for that batch index.
Args:
Y: A `batch_shape x n x m`-dim tensor.
Returns:
The standardized `Y`.
Example:
>>> Y = torch.rand(4, 3)
>>> Y_standardized = standardize(Y)
"""
stddim = -1 if Y.dim() < 2 else -2
Y_std = Y.std(dim=stddim, keepdim=True)
Y_std = Y_std.where(Y_std >= 1e-9, torch.full_like(Y_std, 1.0))
return (Y - Y.mean(dim=stddim, keepdim=True)) / Y_std
[docs]def normalize(X: Tensor, bounds: Tensor) -> Tensor:
r"""Min-max normalize X w.r.t. the provided bounds.
Args:
X: `... x d` tensor of data
bounds: `2 x d` tensor of lower and upper bounds for each of the X's d
columns.
Returns:
A `... x d`-dim tensor of normalized data, given by
`(X - bounds[0]) / (bounds[1] - bounds[0])`. If all elements of `X`
are contained within `bounds`, the normalized values will be
contained within `[0, 1]^d`.
Example:
>>> X = torch.rand(4, 3)
>>> bounds = torch.stack([torch.zeros(3), 0.5 * torch.ones(3)])
>>> X_normalized = normalize(X, bounds)
"""
return (X - bounds[0]) / (bounds[1] - bounds[0])
[docs]def unnormalize(X: Tensor, bounds: Tensor) -> Tensor:
r"""Un-normalizes X w.r.t. the provided bounds.
Args:
X: `... x d` tensor of data
bounds: `2 x d` tensor of lower and upper bounds for each of the X's d
columns.
Returns:
A `... x d`-dim tensor of unnormalized data, given by
`X * (bounds[1] - bounds[0]) + bounds[0]`. If all elements of `X`
are contained in `[0, 1]^d`, the un-normalized values will be
contained within `bounds`.
Example:
>>> X_normalized = torch.rand(4, 3)
>>> bounds = torch.stack([torch.zeros(3), 0.5 * torch.ones(3)])
>>> X = unnormalize(X_normalized, bounds)
"""
return X * (bounds[1] - bounds[0]) + bounds[0]
[docs]def normalize_indices(indices: Optional[List[int]], d: int) -> Optional[List[int]]:
r"""Normalize a list of indices to ensure that they are positive.
Args:
indices: A list of indices (may contain negative indices for indexing
"from the back").
d: The dimension of the tensor to index.
Returns:
A normalized list of indices such that each index is between `0` and
`d-1`, or None if indices is None.
"""
if indices is None:
return indices
normalized_indices = []
for i in indices:
if i < 0:
i = i + d
if i < 0 or i > d - 1:
raise ValueError(f"Index {i} out of bounds for tensor or length {d}.")
normalized_indices.append(i)
return normalized_indices
def _verify_output_shape(acqf: Any, X: Tensor, output: Tensor) -> bool:
r"""
Performs the output shape checks for `t_batch_mode_transform`. Output shape checks
help in catching the errors due to AcquisitionFunction arguments with erroneous
return shapes before these errors propagate further down the line.
This method checks that the `output` shape matches either the t-batch shape of X
or the `batch_shape` of `acqf.model`.
Args:
acqf: The AcquisitionFunction object being evaluated.
X: The `... x q x d`-dim input tensor with an explicit t-batch.
output: The return value of `acqf.method(X, ...)`.
Returns:
True if `output` has the correct shape, False otherwise.
"""
try:
return (
output.shape == X.shape[:-2]
or (output.shape == torch.Size() and X.shape[:-2] == torch.Size([1]))
or output.shape == acqf.model.batch_shape
# for a batched model, we may unsqueeze a batch dimension in X
# corresponding to the model's batch dim. In that case the
# acquisition function output should replace the right-most
# batch dim of X with the model's batch shape.
or output.shape == X.shape[:-3] + acqf.model.batch_shape
)
except (AttributeError, NotImplementedError):
# acqf does not have model or acqf.model does not define `batch_shape`
warnings.warn(
"Output shape checks failed! Expected output shape to match t-batch shape"
f"of X, but got output with shape {output.shape} for X with shape"
f"{X.shape}. Make sure that this is the intended behavior!",
RuntimeWarning,
)
return True
[docs]def is_fully_bayesian(model: Model) -> bool:
r"""Check if at least one model is a SaasFullyBayesianSingleTaskGP
Args:
model: A BoTorch model (may be a `ModelList` or `ModelListGP`)
d: The dimension of the tensor to index.
Returns:
True if at least one model is a `SaasFullyBayesianSingleTaskGP`
"""
from botorch.models import ModelList
from botorch.models.fully_bayesian import SaasFullyBayesianSingleTaskGP
if isinstance(model, SaasFullyBayesianSingleTaskGP):
return True
elif isinstance(model, ModelList) and any(
isinstance(m, SaasFullyBayesianSingleTaskGP) for m in model.models
):
return True
return False
[docs]def t_batch_mode_transform(
expected_q: Optional[int] = None,
assert_output_shape: bool = True,
) -> Callable[
[Callable[[AcquisitionFunction, Any], Any]],
Callable[[AcquisitionFunction, Any], Any],
]:
r"""Factory for decorators enabling consistent t-batch behavior.
This method creates decorators for instance methods to transform an input tensor
`X` to t-batch mode (i.e. with at least 3 dimensions). This assumes the tensor
has a q-batch dimension. The decorator also checks the q-batch size if `expected_q`
is provided, and the output shape if `assert_output_shape` is `True`.
Args:
expected_q: The expected q-batch size of `X`. If specified, this will raise an
AssertionError if `X`'s q-batch size does not equal expected_q.
assert_output_shape: If `True`, this will raise an AssertionError if the
output shape does not match either the t-batch shape of `X`,
or the `acqf.model.batch_shape` for acquisition functions using
batched models.
Returns:
The decorated instance method.
Example:
>>> class ExampleClass:
>>> @t_batch_mode_transform(expected_q=1)
>>> def single_q_method(self, X):
>>> ...
>>>
>>> @t_batch_mode_transform()
>>> def arbitrary_q_method(self, X):
>>> ...
"""
def decorator(
method: Callable[[AcquisitionFunction, Any], Any],
) -> Callable[[AcquisitionFunction, Any], Any]:
@wraps(method)
def decorated(
acqf: AcquisitionFunction, X: Any, *args: Any, **kwargs: Any
) -> Any:
# Allow using acquisition functions for other inputs (e.g. lists of strings)
if not isinstance(X, Tensor):
return method(acqf, X, *args, **kwargs)
if X.dim() < 2:
raise ValueError(
f"{type(acqf).__name__} requires X to have at least 2 dimensions,"
f" but received X with only {X.dim()} dimensions."
)
elif expected_q is not None and X.shape[-2] != expected_q:
raise AssertionError(
f"Expected X to be `batch_shape x q={expected_q} x d`, but"
f" got X with shape {X.shape}."
)
# add t-batch dim
X = X if X.dim() > 2 else X.unsqueeze(0)
output = method(acqf, X, *args, **kwargs)
if hasattr(acqf, "model") and is_fully_bayesian(acqf.model):
output = output.mean(dim=-1)
if assert_output_shape and not _verify_output_shape(
acqf=acqf,
X=X,
output=output,
):
raise AssertionError(
"Expected the output shape to match either the t-batch shape of "
"X, or the `model.batch_shape` in the case of acquisition "
"functions using batch models; but got output with shape "
f"{output.shape} for X with shape {X.shape}."
)
return output
return decorated
return decorator
[docs]def concatenate_pending_points(
method: Callable[[Any, Tensor], Any]
) -> Callable[[Any, Tensor], Any]:
r"""Decorator concatenating X_pending into an acquisition function's argument.
This decorator works on the `forward` method of acquisition functions taking
a tensor `X` as the argument. If the acquisition function has an `X_pending`
attribute (that is not `None`), this is concatenated into the input `X`,
appropriately expanding the pending points to match the batch shape of `X`.
Example:
>>> class ExampleAcquisitionFunction:
>>> @concatenate_pending_points
>>> @t_batch_mode_transform()
>>> def forward(self, X):
>>> ...
"""
@wraps(method)
def decorated(cls: Any, X: Tensor, **kwargs: Any) -> Any:
if cls.X_pending is not None:
X = torch.cat([X, match_batch_shape(cls.X_pending, X)], dim=-2)
return method(cls, X, **kwargs)
return decorated
[docs]def match_batch_shape(X: Tensor, Y: Tensor) -> Tensor:
r"""Matches the batch dimension of a tensor to that of another tensor.
Args:
X: A `batch_shape_X x q x d` tensor, whose batch dimensions that
correspond to batch dimensions of `Y` are to be matched to those
(if compatible).
Y: A `batch_shape_Y x q' x d` tensor.
Returns:
A `batch_shape_Y x q x d` tensor containing the data of `X` expanded to
the batch dimensions of `Y` (if compatible). For instance, if `X` is
`b'' x b' x q x d` and `Y` is `b x q x d`, then the returned tensor is
`b'' x b x q x d`.
Example:
>>> X = torch.rand(2, 1, 5, 3)
>>> Y = torch.rand(2, 6, 4, 3)
>>> X_matched = match_batch_shape(X, Y)
>>> X_matched.shape
torch.Size([2, 6, 5, 3])
"""
return X.expand(X.shape[: -(Y.dim())] + Y.shape[:-2] + X.shape[-2:])
[docs]def convert_to_target_pre_hook(module, *args):
r"""Pre-hook for automatically calling `.to(X)` on module prior to `forward`"""
module.to(args[0][0])
```