After I learned how to use einsum, I am now trying to understand how np.tensordot works.
However, I am a little bit lost especially regarding the various possibilities for the parameter axes.
To understand it, as I have never practiced tensor calculus, I use the following example:
A = np.random.randint(2, size=(2, 3, 5))
B = np.random.randint(2, size=(3, 2, 4))
In this case, what are the different possible np.tensordot and how would you compute it manually?
The idea with tensordot is pretty simple - We input the arrays and the respective axes along which the sum-reductions are intended. The axes that take part in sum-reduction are removed in the output and all of the remaining axes from the input arrays are spread-out as different axes in the output keeping the order in which the input arrays are fed.
Let's look at few sample cases with one and two axes of sum-reductions and also swap the input places and see how the order is kept in the output.
Inputs :
In [7]: A = np.random.randint(2, size=(2, 6, 5))
...: B = np.random.randint(2, size=(3, 2, 4))
...:
Case #1:
In [9]: np.tensordot(A, B, axes=((0),(1))).shape
Out[9]: (6, 5, 3, 4)
A : (2, 6, 5) -> reduction of axis=0
B : (3, 2, 4) -> reduction of axis=1
Output : `(2, 6, 5)`, `(3, 2, 4)` ===(2 gone)==> `(6,5)` + `(3,4)` => `(6,5,3,4)`
Case #2 (same as case #1 but the inputs are fed swapped):
In [8]: np.tensordot(B, A, axes=((1),(0))).shape
Out[8]: (3, 4, 6, 5)
B : (3, 2, 4) -> reduction of axis=1
A : (2, 6, 5) -> reduction of axis=0
Output : `(3, 2, 4)`, `(2, 6, 5)` ===(2 gone)==> `(3,4)` + `(6,5)` => `(3,4,6,5)`.
Inputs :
In [11]: A = np.random.randint(2, size=(2, 3, 5))
...: B = np.random.randint(2, size=(3, 2, 4))
...:
Case #1:
In [12]: np.tensordot(A, B, axes=((0,1),(1,0))).shape
Out[12]: (5, 4)
A : (2, 3, 5) -> reduction of axis=(0,1)
B : (3, 2, 4) -> reduction of axis=(1,0)
Output : `(2, 3, 5)`, `(3, 2, 4)` ===(2,3 gone)==> `(5)` + `(4)` => `(5,4)`
Case #2:
In [14]: np.tensordot(B, A, axes=((1,0),(0,1))).shape
Out[14]: (4, 5)
B : (3, 2, 4) -> reduction of axis=(1,0)
A : (2, 3, 5) -> reduction of axis=(0,1)
Output : `(3, 2, 4)`, `(2, 3, 5)` ===(2,3 gone)==> `(4)` + `(5)` => `(4,5)`
We can extend this to as many axes as possible.
np.tensordot is to swap the inputs. If it doesn't get you your desired one, transpose would be the way to go.
t1=K.variable([[1,2],[2,3]] ) t2=K.variable([2,3]) print(K.eval(tf.tensordot(t1,t2,axes=0))) output: [[[2. 3.] [4. 6.]] [[4. 6.] [6. 9.]]] Not sure how the output shape is 2x2x2.
tensordot swaps axes and reshapes the inputs so it can apply np.dot to 2 2d arrays. It then swaps and reshapes back to the target. It may be easier to experiment than to explain. There's no special tensor math going on, just extending dot to work in higher dimensions. tensor just means arrays with more than 2d. If you are already comfortable with einsum then it will be simplest compare the results to that.
A sample test, summing on 1 pair of axes
In [823]: np.tensordot(A,B,[0,1]).shape
Out[823]: (3, 5, 3, 4)
In [824]: np.einsum('ijk,lim',A,B).shape
Out[824]: (3, 5, 3, 4)
In [825]: np.allclose(np.einsum('ijk,lim',A,B),np.tensordot(A,B,[0,1]))
Out[825]: True
another, summing on two.
In [826]: np.tensordot(A,B,[(0,1),(1,0)]).shape
Out[826]: (5, 4)
In [827]: np.einsum('ijk,jim',A,B).shape
Out[827]: (5, 4)
In [828]: np.allclose(np.einsum('ijk,jim',A,B),np.tensordot(A,B,[(0,1),(1,0)]))
Out[828]: True
We could do same with the (1,0) pair. Given the mix of dimension I don't think there's another combination.
einsum equivalent of tensordot with axes=([1,0],[0,1]), is np.einsum('ijk,jil->kl',a,b). This dot also does it: a.T.reshape(5,12).dot(b.reshape(12,2)). The dot is between a (5,12) and (12,2). The a.T puts the 5 first, and also swaps the (3,4) to match b.
The answers above are great and helped me a lot in understanding tensordot. But they don't show actual math behind operations. That's why I did equivalent operations in TF 2 for myself and decided to share them here:
a = tf.constant([1,2.])
b = tf.constant([2,3.])
print(f"{tf.tensordot(a, b, 0)}\t tf.einsum('i,j', a, b)\t\t- ((the last 0 axes of a), (the first 0 axes of b))")
print(f"{tf.tensordot(a, b, ((),()))}\t tf.einsum('i,j', a, b)\t\t- ((() axis of a), (() axis of b))")
print(f"{tf.tensordot(b, a, 0)}\t tf.einsum('i,j->ji', a, b)\t- ((the last 0 axes of b), (the first 0 axes of a))")
print(f"{tf.tensordot(a, b, 1)}\t\t tf.einsum('i,i', a, b)\t\t- ((the last 1 axes of a), (the first 1 axes of b))")
print(f"{tf.tensordot(a, b, ((0,), (0,)))}\t\t tf.einsum('i,i', a, b)\t\t- ((0th axis of a), (0th axis of b))")
print(f"{tf.tensordot(a, b, (0,0))}\t\t tf.einsum('i,i', a, b)\t\t- ((0th axis of a), (0th axis of b))")
[[2. 3.]
[4. 6.]] tf.einsum('i,j', a, b) - ((the last 0 axes of a), (the first 0 axes of b))
[[2. 3.]
[4. 6.]] tf.einsum('i,j', a, b) - ((() axis of a), (() axis of b))
[[2. 4.]
[3. 6.]] tf.einsum('i,j->ji', a, b) - ((the last 0 axes of b), (the first 0 axes of a))
8.0 tf.einsum('i,i', a, b) - ((the last 1 axes of a), (the first 1 axes of b))
8.0 tf.einsum('i,i', a, b) - ((0th axis of a), (0th axis of b))
8.0 tf.einsum('i,i', a, b) - ((0th axis of a), (0th axis of b))
And for (2,2) shape:
a = tf.constant([[1,2],
[-2,3.]])
b = tf.constant([[-2,3],
[0,4.]])
print(f"{tf.tensordot(a, b, 0)}\t tf.einsum('ij,kl', a, b)\t- ((the last 0 axes of a), (the first 0 axes of b))")
print(f"{tf.tensordot(a, b, (0,0))}\t tf.einsum('ij,ik', a, b)\t- ((0th axis of a), (0th axis of b))")
print(f"{tf.tensordot(a, b, (0,1))}\t tf.einsum('ij,ki', a, b)\t- ((0th axis of a), (1st axis of b))")
print(f"{tf.tensordot(a, b, 1)}\t tf.matmul(a, b)\t\t- ((the last 1 axes of a), (the first 1 axes of b))")
print(f"{tf.tensordot(a, b, ((1,), (0,)))}\t tf.einsum('ij,jk', a, b)\t- ((1st axis of a), (0th axis of b))")
print(f"{tf.tensordot(a, b, (1, 0))}\t tf.matmul(a, b)\t\t- ((1st axis of a), (0th axis of b))")
print(f"{tf.tensordot(a, b, 2)}\t tf.reduce_sum(tf.multiply(a, b))\t- ((the last 2 axes of a), (the first 2 axes of b))")
print(f"{tf.tensordot(a, b, ((0,1), (0,1)))}\t tf.einsum('ij,ij->', a, b)\t\t- ((0th axis of a, 1st axis of a), (0th axis of b, 1st axis of b))")
[[[[-2. 3.]
[ 0. 4.]]
[[-4. 6.]
[ 0. 8.]]]
[[[ 4. -6.]
[-0. -8.]]
[[-6. 9.]
[ 0. 12.]]]] tf.einsum('ij,kl', a, b) - ((the last 0 axes of a), (the first 0 axes of b))
[[-2. -5.]
[-4. 18.]] tf.einsum('ij,ik', a, b) - ((0th axis of a), (0th axis of b))
[[-8. -8.]
[ 5. 12.]] tf.einsum('ij,ki', a, b) - ((0th axis of a), (1st axis of b))
[[-2. 11.]
[ 4. 6.]] tf.matmul(a, b) - ((the last 1 axes of a), (the first 1 axes of b))
[[-2. 11.]
[ 4. 6.]] tf.einsum('ij,jk', a, b) - ((1st axis of a), (0th axis of b))
[[-2. 11.]
[ 4. 6.]] tf.matmul(a, b) - ((1st axis of a), (0th axis of b))
16.0 tf.reduce_sum(tf.multiply(a, b)) - ((the last 2 axes of a), (the first 2 axes of b))
16.0 tf.einsum('ij,ij->', a, b) - ((0th axis of a, 1st axis of a), (0th axis of b, 1st axis of b))
Besides the above answers, it would be easier to understand np.tensordot if breaking it down into nested loops:
Assume:
import numpy as np
a = np.arange(24).reshape(2,3,4)
b = np.arange(30).reshape(3,5,2)
Then a is
array([[[ 0, 1, 2, 3],
[ 4, 5, 6, 7],
[ 8, 9, 10, 11]],
[[12, 13, 14, 15],
[16, 17, 18, 19],
[20, 21, 22, 23]]])
and b is
array([[[ 0, 1],
[ 2, 3],
[ 4, 5],
[ 6, 7],
[ 8, 9]],
[[10, 11],
[12, 13],
[14, 15],
[16, 17],
[18, 19]],
[[20, 21],
[22, 23],
[24, 25],
[26, 27],
[28, 29]]])
Let
c = np.tensordot(a, b, axes=([0,1],[2,0]))
which is equivalent to
c = np.zeros((4,5))
for i in range(4):
for j in range(5):
for p in range(2):
for q in range(3):
c[i,j] += a[p,q,i] * b[q,j,p]
The axes having the same dimensions (here are 2 and 3) in both tensors can be reduced by the sum over them. And the parameter axes=([0,1],[2,0]) is same as axes=([1,0],[0,2]).
The final c is
array([[ 808, 928, 1048, 1168, 1288],
[ 871, 1003, 1135, 1267, 1399],
[ 934, 1078, 1222, 1366, 1510],
[ 997, 1153, 1309, 1465, 1621]])
