# Difference between numpy dot() and Python 3.5+ matrix multiplication @

I recently moved to Python 3.5 and noticed the new matrix multiplication operator (@) sometimes behaves differently from the numpy dot operator. In example, for 3d arrays:

``````import numpy as np

a = np.random.rand(8,13,13)
b = np.random.rand(8,13,13)
c = a @ b  # Python 3.5+
d = np.dot(a, b)
``````

The `@` operator returns an array of shape:

``````c.shape
(8, 13, 13)
``````

while the `np.dot()` function returns:

``````d.shape
(8, 13, 8, 13)
``````

How can I reproduce the same result with numpy dot? Are there any other significant differences?

• You can't get that result out of dot. I think people generally agreed that dot's handling of high-dimension inputs was the wrong design decision. – user2357112 supports Monica Dec 7 '15 at 20:31
• Why didn't they implement the `matmul` function years ago? `@` as an infix operator is new, but the function works just as well without it. – hpaulj Dec 8 '15 at 1:04

The `@` operator calls the array's `__matmul__` method, not `dot`. This method is also present in the API as the function `np.matmul`.

``````>>> a = np.random.rand(8,13,13)
>>> b = np.random.rand(8,13,13)
>>> np.matmul(a, b).shape
(8, 13, 13)
``````

From the documentation:

`matmul` differs from `dot` in two important ways.

• Multiplication by scalars is not allowed.
• Stacks of matrices are broadcast together as if the matrices were elements.

The last point makes it clear that `dot` and `matmul` methods behave differently when passed 3D (or higher dimensional) arrays. Quoting from the documentation some more:

For `matmul`:

If either argument is N-D, N > 2, it is treated as a stack of matrices residing in the last two indexes and broadcast accordingly.

For `np.dot`:

For 2-D arrays it is equivalent to matrix multiplication, and for 1-D arrays to inner product of vectors (without complex conjugation). For N dimensions it is a sum product over the last axis of a and the second-to-last of b

• The confusion here is probably because of the release notes, which directly equate the "@" symbol to the dot() function of numpy in the example code. – Alex K Dec 7 '15 at 20:32

The answer by @ajcr explains how the `dot` and `matmul` (invoked by the `@` symbol) differ. By looking at a simple example, one clearly sees how the two behave differently when operating on 'stacks of matricies' or tensors.

To clarify the differences take a 4x4 array and return the `dot` product and `matmul` product with a 3x4x2 'stack of matricies' or tensor.

``````import numpy as np
fourbyfour = np.array([
[1,2,3,4],
[3,2,1,4],
[5,4,6,7],
[11,12,13,14]
])

threebyfourbytwo = np.array([
[[2,3],[11,9],[32,21],[28,17]],
[[2,3],[1,9],[3,21],[28,7]],
[[2,3],[1,9],[3,21],[28,7]],
])

print('4x4*3x4x2 dot:\n {}\n'.format(np.dot(fourbyfour,threebyfourbytwo)))
print('4x4*3x4x2 matmul:\n {}\n'.format(np.matmul(fourbyfour,threebyfourbytwo)))
``````

The products of each operation appear below. Notice how the dot product is,

...a sum product over the last axis of a and the second-to-last of b

and how the matrix product is formed by broadcasting the matrix together.

``````4x4*3x4x2 dot:
[[[232 152]
[125 112]
[125 112]]

[[172 116]
[123  76]
[123  76]]

[[442 296]
[228 226]
[228 226]]

[[962 652]
[465 512]
[465 512]]]

4x4*3x4x2 matmul:
[[[232 152]
[172 116]
[442 296]
[962 652]]

[[125 112]
[123  76]
[228 226]
[465 512]]

[[125 112]
[123  76]
[228 226]
[465 512]]]
``````
• dot(a, b) [i,j,k,m] = sum(a[i,j,:] * b[k,:,m]) ------- like documentation says: it is a sum product over the last axis of a and the second-to-last axis of b: – Ronak Agrawal Jan 26 '18 at 10:50
• Good catch however, its a 3x4x2. Another way to build the matrix would be `a = np.arange(24).reshape(3, 4, 2)` which would create an array with the dimensions 3x4x2. – Nathan May 27 '20 at 13:06

Just FYI, `@` and its numpy equivalents `dot` and `matmul` are all equally fast. (Plot created with perfplot, a project of mine.) Code to reproduce the plot:

``````import perfplot
import numpy

def setup(n):
A = numpy.random.rand(n, n)
x = numpy.random.rand(n)
return A, x

def at(data):
A, x = data
return A @ x

def numpy_dot(data):
A, x = data
return numpy.dot(A, x)

def numpy_matmul(data):
A, x = data
return numpy.matmul(A, x)

perfplot.show(
setup=setup,
kernels=[at, numpy_dot, numpy_matmul],
n_range=[2 ** k for k in range(15)],
)
``````
• Answer above is suggesting that these methods are not the same – Grzegorz Krug Apr 17 at 12:33

In mathematics, I think the dot in numpy makes more sense

dot(a,b)_{i,j,k,a,b,c} = since it gives the dot product when a and b are vectors, or the matrix multiplication when a and b are matrices

As for matmul operation in numpy, it consists of parts of dot result, and it can be defined as

## >matmul(a,b)_{i,j,k,c} = So, you can see that matmul(a,b) returns an array with a small shape, which has smaller memory consumption and make more sense in applications. In particular, combining with broadcasting, you can get

matmul(a,b)_{i,j,k,l} = for example.

From the above two definitions, you can see the requirements to use those two operations. Assume a.shape=(s1,s2,s3,s4) and b.shape=(t1,t2,t3,t4)

• To use dot(a,b) you need

1. t3=s4;
• To use matmul(a,b) you need

1. t3=s4
2. t2=s2, or one of t2 and s2 is 1
3. t1=s1, or one of t1 and s1 is 1

Use the following piece of code to convince yourself.

## Code sample

``````import numpy as np
for it in xrange(10000):
a = np.random.rand(5,6,2,4)
b = np.random.rand(6,4,3)
c = np.matmul(a,b)
d = np.dot(a,b)
#print 'c shape: ', c.shape,'d shape:', d.shape

for i in range(5):
for j in range(6):
for k in range(2):
for l in range(3):
if not c[i,j,k,l] == d[i,j,k,j,l]:
print it,i,j,k,l,c[i,j,k,l]==d[i,j,k,j,l] #you will not see them
``````
• `np.matmul` also gives the dot product on vectors and the matrix product on matrices. – Subhaneil Lahiri Nov 27 '19 at 8:34

Here is a comparison with `np.einsum` to show how the indices are projected

``````np.allclose(np.einsum('ijk,ijk->ijk', a,b), a*b)        # True
np.allclose(np.einsum('ijk,ikl->ijl', a,b), a@b)        # True
np.allclose(np.einsum('ijk,lkm->ijlm',a,b), a.dot(b))   # True
``````

My experience with MATMUL and DOT

I was constantly getting "ValueError: Shape of passed values is (200, 1), indices imply (200, 3)" when trying to use MATMUL. I wanted a quick workaround and found DOT to deliver the same functionality. I don't get any error using DOT. I get the correct answer

with MATMUL

``````X.shape
>>>(200, 3)

type(X)

>>>pandas.core.frame.DataFrame

w

>>>array([0.37454012, 0.95071431, 0.73199394])

YY = np.matmul(X,w)

>>>  ValueError: Shape of passed values is (200, 1), indices imply (200, 3)"
``````

with DOT

``````YY = np.dot(X,w)
# no error message
YY
>>>array([ 2.59206877,  1.06842193,  2.18533396,  2.11366346,  0.28505879, …

YY.shape

>>> (200, )
``````