# 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. Commented Dec 7, 2015 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. Commented Dec 8, 2015 at 1:04

## 6 Answers

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. Commented Dec 7, 2015 at 20:32
• numpy.dot : matmul or a @ b preferred for two 2D-arrays; If a is an N-D array and b is a 1-D array, it is a sum product over the last axis of a and b.. etc Commented Dec 19, 2023 at 13:13

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(A, x):
return A @ x

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

def numpy_matmul(A, x):
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 Commented Apr 17, 2021 at 12:33
• That's why the answer starts with a FYI. Commented Feb 26, 2023 at 7:54

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: Commented Jan 26, 2018 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. Commented May 27, 2020 at 13:06

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.

import numpy as np
for it in range(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 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. Commented Nov 27, 2019 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, )
• np.dot is converting the dataframe to array, and returning an array, (200,3) witth (3,)=.(200,). The error with matmul is produced by pandas, which is trying make a 3 column frame from that array. I suspect a full traceback will show that. Commented Jun 25, 2022 at 7:12