Class TensorShape
Defined in tensorflow/python/framework/tensor_shape.py
.
Represents the shape of a Tensor
.
A TensorShape
represents a possibly-partial shape specification for a
Tensor
. It may be one of the following:
- Fully-known shape: has a known number of dimensions and a known size
for each dimension. e.g.
TensorShape([16, 256])
- Partially-known shape: has a known number of dimensions, and an unknown
size for one or more dimension. e.g.
TensorShape([None, 256])
- Unknown shape: has an unknown number of dimensions, and an unknown
size in all dimensions. e.g.
TensorShape(None)
If a tensor is produced by an operation of type "Foo"
, its shape
may be inferred if there is a registered shape function for
"Foo"
. See Shape
functions
for details of shape functions and how to register them. Alternatively,
the shape may be set explicitly using tf.Tensor.set_shape
.
__init__
__init__(dims)
Creates a new TensorShape with the given dimensions.
Args:
dims
: A list of Dimensions, or None if the shape is unspecified.
Raises:
TypeError
: If dims cannot be converted to a list of dimensions.
Properties
dims
Returns a list of Dimensions, or None if the shape is unspecified.
ndims
Deprecated accessor for rank
.
rank
Returns the rank of this shape, or None if it is unspecified.
Methods
tf.TensorShape.__bool__
__bool__()
Returns True if this shape contains non-zero information.
tf.TensorShape.__concat__
__concat__(other)
tf.TensorShape.__eq__
__eq__(other)
Returns True if self
is equivalent to other
.
tf.TensorShape.__getitem__
__getitem__(key)
Returns the value of a dimension or a shape, depending on the key.
Args:
key
: Ifkey
is an integer, returns the dimension at that index; otherwise ifkey
is a slice, returns a TensorShape whose dimensions are those selected by the slice fromself
.
Returns:
An integer if key
is an integer, or a TensorShape
if key
is a
slice.
Raises:
ValueError
: Ifkey
is a slice andself
is completely unknown and the step is set.
tf.TensorShape.__iter__
__iter__()
Returns self.dims
if the rank is known, otherwise raises ValueError.
tf.TensorShape.__len__
__len__()
Returns the rank of this shape, or raises ValueError if unspecified.
tf.TensorShape.__ne__
__ne__(other)
Returns True if self
is known to be different from other
.
tf.TensorShape.__nonzero__
__nonzero__()
Returns True if this shape contains non-zero information.
tf.TensorShape.as_list
as_list()
Returns a list of integers or None
for each dimension.
Returns:
A list of integers or None
for each dimension.
Raises:
ValueError
: Ifself
is an unknown shape with an unknown rank.
tf.TensorShape.as_proto
as_proto()
Returns this shape as a TensorShapeProto
.
tf.TensorShape.assert_has_rank
assert_has_rank(rank)
Raises an exception if self
is not compatible with the given rank
.
Args:
rank
: An integer.
Raises:
ValueError
: Ifself
does not represent a shape with the givenrank
.
tf.TensorShape.assert_is_compatible_with
assert_is_compatible_with(other)
Raises exception if self
and other
do not represent the same shape.
This method can be used to assert that there exists a shape that both
self
and other
represent.
Args:
other
: Another TensorShape.
Raises:
ValueError
: Ifself
andother
do not represent the same shape.
tf.TensorShape.assert_is_fully_defined
assert_is_fully_defined()
Raises an exception if self
is not fully defined in every dimension.
Raises:
ValueError
: Ifself
does not have a known value for every dimension.
tf.TensorShape.assert_same_rank
assert_same_rank(other)
Raises an exception if self
and other
do not have compatible ranks.
Args:
other
: AnotherTensorShape
.
Raises:
ValueError
: Ifself
andother
do not represent shapes with the same rank.
tf.TensorShape.concatenate
concatenate(other)
Returns the concatenation of the dimension in self
and other
.
N.B. If either self
or other
is completely unknown,
concatenation will discard information about the other shape. In
future, we might support concatenation that preserves this
information for use with slicing.
Args:
other
: AnotherTensorShape
.
Returns:
A TensorShape
whose dimensions are the concatenation of the
dimensions in self
and other
.
tf.TensorShape.is_compatible_with
is_compatible_with(other)
Returns True iff self
is compatible with other
.
Two possibly-partially-defined shapes are compatible if there exists a fully-defined shape that both shapes can represent. Thus, compatibility allows the shape inference code to reason about partially-defined shapes. For example:
TensorShape(None) is compatible with all shapes.
TensorShape([None, None]) is compatible with all two-dimensional shapes, such as TensorShape([32, 784]), and also TensorShape(None). It is not compatible with, for example, TensorShape([None]) or TensorShape([None, None, None]).
TensorShape([32, None]) is compatible with all two-dimensional shapes with size 32 in the 0th dimension, and also TensorShape([None, None]) and TensorShape(None). It is not compatible with, for example, TensorShape([32]), TensorShape([32, None, 1]) or TensorShape([64, None]).
TensorShape([32, 784]) is compatible with itself, and also TensorShape([32, None]), TensorShape([None, 784]), TensorShape([None, None]) and TensorShape(None). It is not compatible with, for example, TensorShape([32, 1, 784]) or TensorShape([None]).
The compatibility relation is reflexive and symmetric, but not transitive. For example, TensorShape([32, 784]) is compatible with TensorShape(None), and TensorShape(None) is compatible with TensorShape([4, 4]), but TensorShape([32, 784]) is not compatible with TensorShape([4, 4]).
Args:
other
: Another TensorShape.
Returns:
True iff self
is compatible with other
.
tf.TensorShape.is_fully_defined
is_fully_defined()
Returns True iff self
is fully defined in every dimension.
tf.TensorShape.merge_with
merge_with(other)
Returns a TensorShape
combining the information in self
and other
.
The dimensions in self
and other
are merged elementwise,
according to the rules defined for Dimension.merge_with()
.
Args:
other
: AnotherTensorShape
.
Returns:
A TensorShape
containing the combined information of self
and
other
.
Raises:
ValueError
: Ifself
andother
are not compatible.
tf.TensorShape.most_specific_compatible_shape
most_specific_compatible_shape(other)
Returns the most specific TensorShape compatible with self
and other
.
TensorShape([None, 1]) is the most specific TensorShape compatible with both TensorShape([2, 1]) and TensorShape([5, 1]). Note that TensorShape(None) is also compatible with above mentioned TensorShapes.
TensorShape([1, 2, 3]) is the most specific TensorShape compatible with both TensorShape([1, 2, 3]) and TensorShape([1, 2, 3]). There are more less specific TensorShapes compatible with above mentioned TensorShapes, e.g. TensorShape([1, 2, None]), TensorShape(None).
Args:
other
: AnotherTensorShape
.
Returns:
A TensorShape
which is the most specific compatible shape of self
and other
.
tf.TensorShape.num_elements
num_elements()
Returns the total number of elements, or none for incomplete shapes.
tf.TensorShape.with_rank
with_rank(rank)
Returns a shape based on self
with the given rank.
This method promotes a completely unknown shape to one with a known rank.
Args:
rank
: An integer.
Returns:
A shape that is at least as specific as self
with the given rank.
Raises:
ValueError
: Ifself
does not represent a shape with the givenrank
.
tf.TensorShape.with_rank_at_least
with_rank_at_least(rank)
Returns a shape based on self
with at least the given rank.
Args:
rank
: An integer.
Returns:
A shape that is at least as specific as self
with at least the given
rank.
Raises:
ValueError
: Ifself
does not represent a shape with at least the givenrank
.
tf.TensorShape.with_rank_at_most
with_rank_at_most(rank)
Returns a shape based on self
with at most the given rank.
Args:
rank
: An integer.
Returns:
A shape that is at least as specific as self
with at most the given
rank.
Raises:
ValueError
: Ifself
does not represent a shape with at most the givenrank
.