Contrary to your first sentence, `a`

and `b`

are not the same size. But let's focus on your example.

So you want this - 2 dot products, one for each row of `a`

and `b`

```
np.array([np.dot(x,y) for x,y in zip(a,b)])
```

or to avoid appending

```
X = np.zeros((2,2))
for i in range(2):
X[i,...] = np.dot(a[i],b[i])
```

the `dot`

product can be expressed with `einsum`

(matrix index notation) as

```
[np.einsum('ij,j->i',x,y) for x,y in zip(a,b)]
```

so the next step is to index that first dimension:

```
np.einsum('kij,kj->ki',a,b)
```

I'm quite familiar with `einsum`

, but it still took a bit of trial and error to figure out what you want. Now that the problem is clear I can compute it in several other ways

```
A, B = np.array(a), np.array(b)
np.multiply(A,B[:,np.newaxis,:]).sum(axis=2)
(A*B[:,None,:]).sum(2)
np.dot(A,B.T)[0,...]
np.tensordot(b,a,(-1,-1))[:,0,:]
```

I find it helpful to work with arrays that have different sizes. For example if `A`

were `(2,3,4)`

and `B`

`(2,4)`

, it would be more obvious the dot sum has to be on the last dimension.

Another numpy iteration tool is `np.nditer`

. `einsum`

uses this (in C).
http://docs.scipy.org/doc/numpy/reference/arrays.nditer.html

```
it = np.nditer([A, B, None],flags=['external_loop'],
op_axes=[[0,1,2], [0,-1,1], None])
for x,y,w in it:
# x, y are shape (2,)
w[...] = np.dot(x,y)
it.operands[2][...,0]
```

Avoiding that `[...,0]`

step, requires a more elaborate setup.

```
C = np.zeros((2,2))
it = np.nditer([A, B, C],flags=['external_loop','reduce_ok'],
op_axes=[[0,1,2], [0,-1,1], [0,1,-1]],
op_flags=[['readonly'],['readonly'],['readwrite']])
for x,y,w in it:
w[...] = np.dot(x,y)
# w[...] += x*y
print C
# array([[ 7., 15.],[ 14., 32.]])
```