I want to implement the scatter and gather operations of Tensorflow or PyTorch in Numpy.
8 Answers
There are two builtin numpy functions that suit your request:
 Use
np.take_along_axis
to implementtorch.gather
 Use
np.put_along_axis
to implementtorch.scatter

1Thank you. These did not exist back when I asked the question. I'm gonna leave my answer, in case someone wanted to see the inner logic of these functions. Specially because the scatter method is a cornercase minefield! Jun 23, 2022 at 0:13
The scatter
method turned out to be way more work than I anticipated. I did not find any ready made function in NumPy for it. I'm sharing it here in the interest of anyone who may need to implement it with NumPy.
(p.s. self
is the destination or output of the method.)
def scatter_numpy(self, dim, index, src):
"""
Writes all values from the Tensor src into self at the indices specified in the index Tensor.
:param dim: The axis along which to index
:param index: The indices of elements to scatter
:param src: The source element(s) to scatter
:return: self
"""
if index.dtype != np.dtype('int_'):
raise TypeError("The values of index must be integers")
if self.ndim != index.ndim:
raise ValueError("Index should have the same number of dimensions as output")
if dim >= self.ndim or dim < self.ndim:
raise IndexError("dim is out of range")
if dim < 0:
# Not sure why scatter should accept dim < 0, but that is the behavior in PyTorch's scatter
dim = self.ndim + dim
idx_xsection_shape = index.shape[:dim] + index.shape[dim + 1:]
self_xsection_shape = self.shape[:dim] + self.shape[dim + 1:]
if idx_xsection_shape != self_xsection_shape:
raise ValueError("Except for dimension " + str(dim) +
", all dimensions of index and output should be the same size")
if (index >= self.shape[dim]).any() or (index < 0).any():
raise IndexError("The values of index must be between 0 and (self.shape[dim] 1)")
def make_slice(arr, dim, i):
slc = [slice(None)] * arr.ndim
slc[dim] = i
return slc
# We use index and dim parameters to create idx
# idx is in a form that can be used as a NumPy advanced index for scattering of src param. in self
idx = [[*np.indices(idx_xsection_shape).reshape(index.ndim  1, 1),
index[make_slice(index, dim, i)].reshape(1, 1)[0]] for i in range(index.shape[dim])]
idx = list(np.concatenate(idx, axis=1))
idx.insert(dim, idx.pop())
if not np.isscalar(src):
if index.shape[dim] > src.shape[dim]:
raise IndexError("Dimension " + str(dim) + "of index can not be bigger than that of src ")
src_xsection_shape = src.shape[:dim] + src.shape[dim + 1:]
if idx_xsection_shape != src_xsection_shape:
raise ValueError("Except for dimension " +
str(dim) + ", all dimensions of index and src should be the same size")
# src_idx is a NumPy advanced index for indexing of elements in the src
src_idx = list(idx)
src_idx.pop(dim)
src_idx.insert(dim, np.repeat(np.arange(index.shape[dim]), np.prod(idx_xsection_shape)))
self[idx] = src[src_idx]
else:
self[idx] = src
return self
There could be a simpler solution for gather
, but this is what I settled on:
(here self
is the ndarray that the values are gathered from.)
def gather_numpy(self, dim, index):
"""
Gathers values along an axis specified by dim.
For a 3D tensor the output is specified by:
out[i][j][k] = input[index[i][j][k]][j][k] # if dim == 0
out[i][j][k] = input[i][index[i][j][k]][k] # if dim == 1
out[i][j][k] = input[i][j][index[i][j][k]] # if dim == 2
:param dim: The axis along which to index
:param index: A tensor of indices of elements to gather
:return: tensor of gathered values
"""
idx_xsection_shape = index.shape[:dim] + index.shape[dim + 1:]
self_xsection_shape = self.shape[:dim] + self.shape[dim + 1:]
if idx_xsection_shape != self_xsection_shape:
raise ValueError("Except for dimension " + str(dim) +
", all dimensions of index and self should be the same size")
if index.dtype != np.dtype('int_'):
raise TypeError("The values of index must be integers")
data_swaped = np.swapaxes(self, 0, dim)
index_swaped = np.swapaxes(index, 0, dim)
gathered = np.choose(index_swaped, data_swaped)
return np.swapaxes(gathered, 0, dim)
The scatter_nd
operation can be implemented using *np*'s ufuncs .at
functions.
According to TF scatter_nd's
doc:
Calling
tf.scatter_nd(indices, values, shape)
is identical totensor_scatter_add(tf.zeros(shape, values.dtype), indices, values)
.
Hence, you can reproduce tf.scatter_nd
using np.add.at
applied on a np.zeros
array, see MVCE below:
import tensorflow as tf
tf.enable_eager_execution() # Remove this line if working in TF2
import numpy as np
def scatter_nd_numpy(indices, updates, shape):
target = np.zeros(shape, dtype=updates.dtype)
indices = tuple(indices.reshape(1, indices.shape[1]).T)
updates = updates.ravel()
np.add.at(target, indices, updates)
return target
indices = np.array([[[0, 0], [0, 1]], [[1, 0], [1, 1]]])
updates = np.array([[1, 2], [3, 4]])
shape = (2, 3)
scattered_tf = tf.scatter_nd(indices, updates, shape).numpy()
scattered_np = scatter_nd_numpy(indices, updates, shape)
assert np.allclose(scattered_tf, scattered_np)
NB: as @denis pointed out, the solution above differs when some indices are repeated, this could be solved by using a counter and getting only the last one of each repeated index.
For scattering, rather than using slice assignment, as suggested by @DomJack, it is often better to use the np.add.at; since unlike slice assignment, this has welldefined behavior in the presence of duplicate indices.

What do you mean by welldefined? My understanding is in PyTorch and Tensorflow, duplicate indices result in overwriting the values. In case of TF they specifically warn that the order of updates is not deterministic. I looked at np.add.at and it seems it is good for “scatter_add” operation(no?), but that's not the behavior I want. Sep 6, 2017 at 19:00

"
add.at(a, [0,0], 1)
will increment the first element twice". What if you want to set the last value, likenp.set.at
? but afaik there's no ufunc to just set. (Hack for X >= 0:np.abs.at( X, ix, values )
.)– denisMay 10, 2018 at 9:52
Fore ref
and indices
being numpy arrays:
Scatter update:
ref[indices] = updates # tf.scatter_update(ref, indices, updates)
ref[:, indices] = updates # tf.scatter_update(ref, indices, updates, axis=1)
ref[..., indices, :] = updates # tf.scatter_update(ref, indices, updates, axis=2)
ref[..., indices] = updates # tf.scatter_update(ref, indices, updates, axis=1)
Gather:
ref[indices] # tf.gather(ref, indices)
ref[:, indices] # tf.gather(ref, indices, axis=1)
ref[..., indices, :] # tf.gather(ref, indices, axis=2)
ref[..., indices] # tf.gather(ref, indices, axis=1)
See numpy docs on indexing for more.

In your solution, how do you define the dimension along which you want to scatter the src? Sep 6, 2017 at 18:36

This is incorrect for PyTorch. Here is an example of the different results: gist.github.com/kylemcdonald/05f8c9aaef2cda9fe5bcfd74652db1a8 May 14, 2018 at 22:49

This does not do the same as the gather function as can be seen here Jun 24, 2018 at 9:36

I made it alike.
def gather(a, dim, index):
expanded_index = [index if dim==i else np.arange(a.shape[i]).reshape([1 if i==j else 1 for j in range(a.ndim)]) for i in range(a.ndim)]
return a[expanded_index]
def scatter(a, dim, index, b): # a inplace
expanded_index = [index if dim==i else np.arange(a.shape[i]).reshape([1 if i==j else 1 for j in range(a.ndim)]) for i in range(a.ndim)]
a[expanded_index] = b
For Gather Operation: np.take()
https://docs.scipy.org/doc/numpy1.14.0/reference/generated/numpy.take.html

1
gather
is different fromnp.take
as will be clear when trying to solve this problem usingnp.take
. Jun 24, 2018 at 9:35
If you simply want the same functionality and not implement it from scratch,
numpy.insert() is a close enough contender for the scatter_(dim, index, src) operation in pytorch but it processes only a single dimension.