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"Scatter updates
into an existing tensor according to indices
.
tf.tensor_scatter_nd_update(
tensor, indices, updates, name=None
)
This operation creates a new tensor by applying sparse updates
to the
input tensor
. This is similar to an index assignment.
# Not implemented: tensors cannot be updated inplace.
tensor[indices] = updates
If an out of bound index is found on CPU, an error is returned.
- If an out of bound index is found, the index is ignored.
- The order in which updates are applied is nondeterministic, so the output will be nondeterministic if
indices
contains duplicates.
This operation is very similar to tf.scatter_nd
, except that the updates are
scattered onto an existing tensor (as opposed to a zero-tensor). If the memory
for the existing tensor cannot be re-used, a copy is made and updated.
In general:
indices
is an integer tensor - the indices to update intensor
.indices
has at least two axes, the last axis is the depth of the index vectors.- For each index vector in
indices
there is a corresponding entry inupdates
. - If the length of the index vectors matches the rank of the
tensor
, then the index vectors each point to scalars intensor
and each update is a scalar. - If the length of the index vectors is less than the rank of
tensor
, then the index vectors each point to slices oftensor
and shape of the updates must match that slice.
Overall this leads to the following shape constraints:
assert tf.rank(indices) >= 2
index_depth = indices.shape[-1]
batch_shape = indices.shape[:-1]
assert index_depth <= tf.rank(tensor)
outer_shape = tensor.shape[:index_depth]
inner_shape = tensor.shape[index_depth:]
assert updates.shape == batch_shape + inner_shape
Typical usage is often much simpler than this general form, and it can be better understood starting with simple examples:
Scalar updates
The simplest usage inserts scalar elements into a tensor by index.
In this case, the index_depth
must equal the rank of the
input tensor
, slice each column of indices
is an index into an axis of the
input tensor
.
In this simplest case the shape constraints are:
num_updates, index_depth = indices.shape.as_list()
assert updates.shape == [num_updates]
assert index_depth == tf.rank(tensor)`
For example, to insert 4 scattered elements in a rank-1 tensor with 8 elements.
This scatter operation would look like this:
tensor = [0, 0, 0, 0, 0, 0, 0, 0] # tf.rank(tensor) == 1
indices = [[1], [3], [4], [7]] # num_updates == 4, index_depth == 1
updates = [9, 10, 11, 12] # num_updates == 4
print(tf.tensor_scatter_nd_update(tensor, indices, updates))
tf.Tensor([ 0 9 0 10 11 0 0 12], shape=(8,), dtype=int32)
The length (first axis) of updates
must equal the length of the indices
:
num_updates
. This is the number of updates being inserted. Each scalar
update is inserted into tensor
at the indexed location.
For a higher rank input tensor
scalar updates can be inserted by using an
index_depth
that matches tf.rank(tensor)
:
tensor = [[1, 1], [1, 1], [1, 1]] # tf.rank(tensor) == 2
indices = [[0, 1], [2, 0]] # num_updates == 2, index_depth == 2
updates = [5, 10] # num_updates == 2
print(tf.tensor_scatter_nd_update(tensor, indices, updates))
tf.Tensor(
[[ 1 5]
[ 1 1]
[10 1]], shape=(3, 2), dtype=int32)
Slice updates
When the input tensor
has more than one axis scatter can be used to update
entire slices.
In this case it's helpful to think of the input tensor
as being a two level
array-of-arrays. The shape of this two level array is split into the
outer_shape
and the inner_shape
.
indices
indexes into the outer level of the input tensor (outer_shape
).
and replaces the sub-array at that location with the corresponding item from
the updates
list. The shape of each update is inner_shape
.
When updating a list of slices the shape constraints are:
num_updates, index_depth = indices.shape.as_list()
inner_shape = tensor.shape[:index_depth]
outer_shape = tensor.shape[index_depth:]
assert updates.shape == [num_updates, inner_shape]
For example, to update rows of a (6, 3)
tensor
:
tensor = tf.zeros([6, 3], dtype=tf.int32)
Use an index depth of one.
indices = tf.constant([[2], [4]]) # num_updates == 2, index_depth == 1
num_updates, index_depth = indices.shape.as_list()
The outer_shape
is 6
, the inner shape is 3
:
outer_shape = tensor.shape[:index_depth]
inner_shape = tensor.shape[index_depth:]
2 rows are being indexed so 2 updates
must be supplied.
Each update must be shaped to match the inner_shape
.
# num_updates == 2, inner_shape==3
updates = tf.constant([[1, 2, 3],
[4, 5, 6]])
Altogether this gives:
tf.tensor_scatter_nd_update(tensor, indices, updates).numpy()
array([[0, 0, 0],
[0, 0, 0],
[1, 2, 3],
[0, 0, 0],
[4, 5, 6],
[0, 0, 0]], dtype=int32)
More slice update examples
A tensor representing a batch of uniformly sized video clips naturally has 5
axes: [batch_size, time, width, height, channels]
.
For example:
batch_size, time, width, height, channels = 13,11,7,5,3
video_batch = tf.zeros([batch_size, time, width, height, channels])
To replace a selection of video clips:
- Use an
index_depth
of 1 (indexing theouter_shape
:[batch_size]
) - Provide updates each with a shape matching the
inner_shape
:[time, width, height, channels]
.
To replace the first two clips with ones:
indices = [[0],[1]]
new_clips = tf.ones([2, time, width, height, channels])
tf.tensor_scatter_nd_update(video_batch, indices, new_clips)
To replace a selection of frames in the videos:
indices
must have anindex_depth
of 2 for theouter_shape
:[batch_size, time]
.updates
must be shaped like a list of images. Each update must have a shape, matching theinner_shape
:[width, height, channels]
.
To replace the first frame of the first three video clips:
indices = [[0, 0], [1, 0], [2, 0]] # num_updates=3, index_depth=2
new_images = tf.ones([
# num_updates=3, inner_shape=(width, height, channels)
3, width, height, channels])
tf.tensor_scatter_nd_update(video_batch, indices, new_images)
Folded indices
In simple cases it's convenient to think of indices
and updates
as
lists, but this is not a strict requirement. Instead of a flat num_updates
,
the indices
and updates
can be folded into a batch_shape
. This
batch_shape
is all axes of the indices
, except for the innermost
index_depth
axis.
index_depth = indices.shape[-1]
batch_shape = indices.shape[:-1]
updates
must have a matching batch_shape
(the axes before inner_shape
).
assert updates.shape == batch_shape + inner_shape
With this generalization the full shape constraints are:
assert tf.rank(indices) >= 2
index_depth = indices.shape[-1]
batch_shape = indices.shape[:-1]
assert index_depth <= tf.rank(tensor)
outer_shape = tensor.shape[:index_depth]
inner_shape = tensor.shape[index_depth:]
assert updates.shape == batch_shape + inner_shape
For example, to draw an X
on a (5,5)
matrix start with these indices:
tensor = tf.zeros([5,5])
indices = tf.constant([
[[0,0],
[1,1],
[2,2],
[3,3],
[4,4]],
[[0,4],
[1,3],
[2,2],
[3,1],
[4,0]],
])
indices.shape.as_list() # batch_shape == [2, 5], index_depth == 2
[2, 5, 2]
Here the indices
do not have a shape of [num_updates, index_depth]
, but a
shape of batch_shape+[index_depth]
.
Since the index_depth
is equal to the rank of tensor
:
outer_shape
is(5,5)
inner_shape
is()
- each update is scalarupdates.shape
isbatch_shape + inner_shape == (5,2) + ()
updates = [
[1,1,1,1,1],
[1,1,1,1,1],
]
Putting this together gives:
tf.tensor_scatter_nd_update(tensor, indices, updates).numpy()
array([[1., 0., 0., 0., 1.],
[0., 1., 0., 1., 0.],
[0., 0., 1., 0., 0.],
[0., 1., 0., 1., 0.],
[1., 0., 0., 0., 1.]], dtype=float32)
Args | |
---|---|
tensor
|
Tensor to copy/update. |
indices
|
Indices to update. |
updates
|
Updates to apply at the indices. |
name
|
Optional name for the operation. |
Returns | |
---|---|
A new tensor with the given shape and updates applied according to the indices. |