I have four multidimensional tensors `v[i,j,k]`

, `a[i,s,l]`

, `w[j,s,t,m]`

, `x[k,t,n]`

in Numpy, and I am trying to compute the tensor `z[l,m,n]`

given by:

`z[l,m,n] = sum_{i,j,k,s,t} v[i,j,k] * a[i,s,l] * w[j,s,t,m] * x[k,t,n]`

All the tensors are relatively small (say less that 32k elements in total), however I need to perform this computation many times, so I would like the function to have as little overhead as possible.

I tried to implement it using `numpy.einsum`

like this:

```
z = np.einsum('ijk,isl,jstm,ktn', v, a, w, x)
```

but it was very slow. I also tried the following sequence of `numpy.tensordot`

calls:

```
z = np.zeros((a.shape[-1],w.shape[-1],x.shape[-1]))
for s in range(a.shape[1]):
for t in range(x.shape[1]):
res = np.tensordot(v, a[:,s,:], (0,0))
res = np.tensordot(res, w[:,s,t,:], (0,0))
z += np.tensordot(res, x[:,s,:], (0,0))
```

inside of a double for loop to sum over `s`

and `t`

(both `s`

and `t`

are very small, so that is not too much of a problem). This worked much better, but it is still not as fast as I would expect. I think this may be because of all the operations that `tensordot`

needs to perform internally before taking the actual product (e.g. permuting the axes).

I was wondering if there is a more efficient way to implement this kind of operations in Numpy. I also wouldn't mind implementing this part in Cython, but I'm not sure what would be the right algorithm to use.

`numpy.einsum`

and`numpy.tensordot`

implementations?`einsum`

implementation is simply`z = np.einsum('ijk,isl,jstm,ktn', v, a, w, x)`

. The`tensordot`

implementation is ` res = np.tensordot(v, a, (0,0)) res = np.tensordot(res, w, (0,0)) res = np.tensordot(res, x, (0,0)) ``z += ...`

without actually initializing`z`

earlier. Could you clarify/correct that?`einsum`

constructs an iteration (`nditer`

) over all of the listed variables. I count 8, so even if the individual dimensions are small, the product iteration space is still very large.1more comment