Traktor/myenv/Lib/site-packages/torch/masked/_docs.py
2024-05-26 05:12:46 +02:00

1178 lines
48 KiB
Python
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

# This file is generated, do not modify it!
#
# To update this file, run the update masked docs script as follows:
#
# python tools/update_masked_docs.py
#
# The script must be called from an environment where the development
# version of torch package can be imported and is functional.
#
amax_docstring = """amax(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns maximum of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of maximum operation, which is used to start the
reduction, depends on input dtype. For instance, for float32, uint8,
and int32 dtypes, the identity values are ``-inf``, ``0``, and ``-2147483648``, respectively.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in maximum computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of maximum operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.amax(input, 1, mask=mask)
tensor([ -1, -9223372036854775808])
"""
amin_docstring = """amin(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns minimum of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of minimum operation, which is used to start the
reduction, depends on input dtype. For instance, for float32, uint8,
and int32 dtypes, the identity values are ``inf``, ``255``, and ``2147483647``, respectively.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in minimum computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of minimum operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.amin(input, 1, mask=mask)
tensor([ -3, 9223372036854775807])
"""
argmax_docstring = """argmax(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns argmax of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of argmax operation, which is used to start the
reduction, depends on input dtype. For instance, for float32, uint8,
and int32 dtypes, the identity values are ``-inf``, ``0``, and ``-2147483648``, respectively.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in argmax computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of argmax operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which argmax is computed.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.argmax(input, 1, mask=mask)
tensor([2, 0])
"""
argmin_docstring = """argmin(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns argmin of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of argmin operation, which is used to start the
reduction, depends on input dtype. For instance, for float32, uint8,
and int32 dtypes, the identity values are ``inf``, ``255``, and ``2147483647``, respectively.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in argmin computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of argmin operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which argmin is computed.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.argmin(input, 1, mask=mask)
tensor([0, 0])
"""
cumprod_docstring = """cumprod(input, dim, *, dtype=None, mask=None) -> Tensor
Returns cumulative_prod of all the slices in the :attr:`input` tensor
along :attr:`dim` while the :attr:`input` elements are masked out
according to the boolean tensor :attr:`mask`.
Let ``x`` be a sequence of unmasked elements of one-dimensional slice
of the :attr:`input` tensor. Cumsum of i-th element in ``x`` is
defined as ``prod(x[:i])``.
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True then
the corresponding element in :attr:`input` tensor will be included in
cumulative_prod computation, otherwise the element is ignored.
The values of masked-out elements of the output tensor have undefined
value: it may or may not be set to zero or nan; the choice may correspond to
the value that leads to the most efficient storage of :attr:`output`
tensor.
The mask of the cumulative_prod output tensor can be computed as
``torch.broadcast_to(mask, input.shape)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which cumulative_prod is computed.
Keyword args:
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.cumprod(input, 1, mask=mask)
tensor([[-3., -3., 3.],
[ 1., 1., 1.]])
"""
cumsum_docstring = """cumsum(input, dim, *, dtype=None, mask=None) -> Tensor
Returns cumulative_sum of all the slices in the :attr:`input` tensor
along :attr:`dim` while the :attr:`input` elements are masked out
according to the boolean tensor :attr:`mask`.
Let ``x`` be a sequence of unmasked elements of one-dimensional slice
of the :attr:`input` tensor. Cumsum of i-th element in ``x`` is
defined as ``sum(x[:i])``.
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True then
the corresponding element in :attr:`input` tensor will be included in
cumulative_sum computation, otherwise the element is ignored.
The values of masked-out elements of the output tensor have undefined
value: it may or may not be set to zero or nan; the choice may correspond to
the value that leads to the most efficient storage of :attr:`output`
tensor.
The mask of the cumulative_sum output tensor can be computed as
``torch.broadcast_to(mask, input.shape)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which cumulative_sum is computed.
Keyword args:
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.cumsum(input, 1, mask=mask)
tensor([[-3., -3., -4.],
[ 0., 0., 0.]])
"""
log_softmax_docstring = """log_softmax(input, dim, *, dtype=None, mask=None) -> Tensor
Returns log_softmax of all the slices in the :attr:`input` tensor
along :attr:`dim` while the :attr:`input` elements are masked out
according to the boolean tensor :attr:`mask`.
Let ``x`` be a sequence of unmasked elements of one-dimensional slice
of the :attr:`input` tensor. LogSoftmax of i-th element in ``x`` is
defined as ``log(exp(x[i])/sum(exp(x)))``.
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True then
the corresponding element in :attr:`input` tensor will be included in
log_softmax computation, otherwise the element is ignored.
The values of masked-out elements of the output tensor have undefined
value: it may or may not be set to zero or nan; the choice may correspond to
the value that leads to the most efficient storage of :attr:`output`
tensor.
The mask of the log_softmax output tensor can be computed as
``torch.broadcast_to(mask, input.shape)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which log_softmax is computed.
Keyword args:
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.log_softmax(input, 1, mask=mask)
tensor([[-2.1269, -inf, -0.1269],
[ nan, nan, nan]])
"""
logsumexp_docstring = """logsumexp(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns logsumexp of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of logsumexp operation, which is used to start the reduction, is ``-2147483648``.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in logsumexp computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of logsumexp operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.logsumexp(input, 1, mask=mask)
tensor([ 0, -9223372036854775808])
"""
mean_docstring = """mean(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns mean of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
By definition, the identity value of a mean operation is the mean
value of the tensor. If all elements of the input tensor along given
dimension(s) :attr:`dim` are masked-out, the identity value of the
mean is undefined. Due to this ambiguity, the elements of output
tensor with strided layout, that correspond to fully masked-out
elements, have ``nan`` values.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in mean computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of mean operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.mean(input, 1, mask=mask)
tensor([-2., nan])
"""
median_docstring = """median(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns median of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
By definition, the identity value of a median operation is the median
value of the tensor. If all elements of the input tensor along given
dimension(s) :attr:`dim` are masked-out, the identity value of the
median is undefined. Due to this ambiguity, the elements of output
tensor with strided layout, that correspond to fully masked-out
elements, have ``nan`` values.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in median computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of median operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which median is computed.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.median(input, 1, mask=mask)
tensor([-3., nan])
"""
norm_docstring = """norm(input, ord, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns norm of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of norm operation, which is used to start the
reduction, is ``0.0``, except for ``ord=-inf`` it is
``inf``.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in norm computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of norm operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
ord (int, float, optional): the order of vector norm. Default: 2.
See :func:`torch.linalg.vector_norm` for a list of supported norms.
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.norm(input, 2.0, 1, mask=mask)
tensor([3.1623, 0.0000])
"""
normalize_docstring = """normalize(input, ord, dim, *, eps=1e-12, dtype=None, mask=None) -> Tensor
Returns normalize of all the slices in the :attr:`input` tensor
along :attr:`dim` while the :attr:`input` elements are masked out
according to the boolean tensor :attr:`mask`.
Let ``x`` be a sequence of unmasked elements of one-dimensional slice
of the :attr:`input` tensor. Normalize of i-th element in ``x`` is
defined as ``x[i]/max(norm(x, p), eps)``.
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True then
the corresponding element in :attr:`input` tensor will be included in
normalize computation, otherwise the element is ignored.
The values of masked-out elements of the output tensor have undefined
value: it may or may not be set to zero or nan; the choice may correspond to
the value that leads to the most efficient storage of :attr:`output`
tensor.
The mask of the normalize output tensor can be computed as
``torch.broadcast_to(mask, input.shape)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
ord (int, float): the order of vector norm. Default: 2.
See :func:`torch.linalg.vector_norm` for a list of supported norms.
dim (int): the dimension along which normalize is computed.
Keyword args:
eps (float, optional): small value to avoid division by zero. Default: 1e-12.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.normalize(input, 2.0, 1, mask=mask)
tensor([[-0.9487, 0.0000, -0.3162],
[ 0.0000, 0.0000, 0.0000]])
"""
prod_docstring = """prod(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns product of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of product operation, which is used to start the reduction, is ``1``.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in product computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of product operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.prod(input, 1, mask=mask)
tensor([3, 1])
"""
softmax_docstring = """softmax(input, dim, *, dtype=None, mask=None) -> Tensor
Returns softmax of all the slices in the :attr:`input` tensor
along :attr:`dim` while the :attr:`input` elements are masked out
according to the boolean tensor :attr:`mask`.
Let ``x`` be a sequence of unmasked elements of one-dimensional slice
of the :attr:`input` tensor. Softmax of i-th element in ``x`` is
defined as ``exp(x[i])/sum(exp(x))``.
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True then
the corresponding element in :attr:`input` tensor will be included in
softmax computation, otherwise the element is ignored.
The values of masked-out elements of the output tensor have undefined
value: it may or may not be set to zero or nan; the choice may correspond to
the value that leads to the most efficient storage of :attr:`output`
tensor.
The mask of the softmax output tensor can be computed as
``torch.broadcast_to(mask, input.shape)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which softmax is computed.
Keyword args:
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.softmax(input, 1, mask=mask)
tensor([[0.1192, 0.0000, 0.8808],
[ nan, nan, nan]])
"""
softmin_docstring = """softmin(input, dim, *, dtype=None, mask=None) -> Tensor
Returns softmin of all the slices in the :attr:`input` tensor
along :attr:`dim` while the :attr:`input` elements are masked out
according to the boolean tensor :attr:`mask`.
Let ``x`` be a sequence of unmasked elements of one-dimensional slice
of the :attr:`input` tensor. Softmin of i-th element in ``x`` is
defined as ``exp(-x[i])/sum(exp(-x))``.
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True then
the corresponding element in :attr:`input` tensor will be included in
softmin computation, otherwise the element is ignored.
The values of masked-out elements of the output tensor have undefined
value: it may or may not be set to zero or nan; the choice may correspond to
the value that leads to the most efficient storage of :attr:`output`
tensor.
The mask of the softmin output tensor can be computed as
``torch.broadcast_to(mask, input.shape)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int): the dimension along which softmin is computed.
Keyword args:
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3., -2., -1.], [ 0., 1., 2.]])
>>> input
tensor([[-3., -2., -1.],
[ 0., 1., 2.]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.softmin(input, 1, mask=mask)
tensor([[0.8808, 0.0000, 0.1192],
[ nan, nan, nan]])
"""
std_docstring = """std(input, dim, unbiased, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns standard_deviation of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of sample standard deviation operation is undefined. The
elements of output tensor with strided layout, that correspond to
fully masked-out elements, have ``nan`` values.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in standard_deviation computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of standard_deviation operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
unbiased (bool): when True, use Bessels correction, otherwise, compute
the uncorrected sample variance.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.std(input, 1, False, mask=mask)
tensor([1., nan])
"""
sum_docstring = """sum(input, dim, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns sum of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of sum operation, which is used to start the reduction, is ``0``.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in sum computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of sum operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.sum(input, 1, mask=mask)
tensor([-4, 0])
"""
var_docstring = """var(input, dim, unbiased, *, keepdim=False, dtype=None, mask=None) -> Tensor
Returns variance of all the elements in the :attr:`input`
tensor along the given dimension(s) :attr:`dim` while the :attr:`input`
elements are masked out according to the boolean tensor
:attr:`mask`.
The identity value of sample variance operation is undefined. The
elements of output tensor with strided layout, that correspond to
fully masked-out elements, have ``nan`` values.
If :attr:`keepdim` is ``True``, the output tensor is of the same size
as :attr:`input` except in the dimension(s) :attr:`dim` where it is of
size 1. Otherwise, :attr:`dim` is squeezed (see
:func:`torch.squeeze`), resulting in the output tensor having 1 (or
``len(dim)``) fewer dimension(s).
The boolean tensor :attr:`mask` defines the "validity" of
:attr:`input` tensor elements: if :attr:`mask` element is True
then the corresponding element in :attr:`input` tensor will be
included in variance computation, otherwise the element is
ignored.
When all elements of :attr:`input` along the given dimension
:attr:`dim` are ignored (fully masked-out), the corresponding element
of the output tensor will have undefined value: it may or may not
correspond to the identity value of variance operation; the
choice may correspond to the value that leads to the most efficient
storage of :attr:`output` tensor.
The mask of the output tensor can be computed as
``torch.any(torch.broadcast_to(mask, input.shape), dim, keepdim=keepdim,
dtype=torch.bool)``.
The shapes of the :attr:`mask` tensor and the :attr:`input` tensor
don't need to match, but they must be :ref:`broadcastable
<broadcasting-semantics>` and the dimensionality of the :attr:`mask`
tensor must not be greater than of the :attr:`input` tensor.
Args:
input (Tensor): the input tensor
dim (int or tuple of ints, optional): the dimension or dimensions to reduce.
Default: None that is equivalent to ``tuple(range(input.ndim))``.
unbiased (bool): when True, use Bessels correction, otherwise, compute
the uncorrected sample variance.
Keyword args:
keepdim (bool, optional): whether the output tensor has
:attr:`dim` retained or not. Default: False.
dtype (:class:`torch.dtype`, optional): the desired data type
of returned tensor. If specified, the input tensor is
casted to :attr:`dtype` before the operation is
performed. Default: None.
mask (:class:`torch.Tensor`, optional): the boolean tensor
containing the binary mask of validity of input tensor
elements.
Default: None that is equivalent to ``torch.ones(input.shape, dtype=torch.bool)``.
Example::
>>> input = tensor([[-3, -2, -1], [ 0, 1, 2]])
>>> input
tensor([[-3, -2, -1],
[ 0, 1, 2]])
>>> mask = tensor([[ True, False, True], [False, False, False]])
>>> mask
tensor([[ True, False, True],
[False, False, False]])
>>> torch.masked._ops.var(input, 1, False, mask=mask)
tensor([1., nan])
"""