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

**dot**(a,b)_{i,j,k,a,b,c} = \sum_m a_{i,j,k,m}b_{a,b,m,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} = \sum_m a_{i,j,k,m}b_{i,j,m,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} = \sum_m a_{i,j,k,m}b_{j,m,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)**

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
```

`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