There is a nifty trick with `stride_tricks`

, you can find rolling window functions with different generality on SO and other (there currently is none in numpy itself), here is a version tailored to what you got:

```
def rolling_window(arr, window):
"""Very basic multi dimensional rolling window. window should be the shape of
of the desired subarrays. Window is either a scalar or a tuple of same size
as `arr.shape`.
"""
shape = np.array(arr.shape*2)
strides = np.array(arr.strides*2)
window = np.asarray(window)
shape[arr.ndim:] = window # new dimensions size
shape[:arr.ndim] -= window - 1
if np.any(shape < 1):
raise ValueError('window size is too large')
return np.lib.stride_tricks.as_strided(arr, shape=shape, strides=strides)
# Now:
view = rolling_window(arr, 2)
view[0,0] # first slice in your loop
```

Note that `view`

holds the same data as the original array! Which can result in unexpected results. But you seem to want only the diagonal, you could do that with stride tricks as well to make sure you do not copy data if you want (next versions will create a view with `diagonal`

, old ones always a copy):

```
diagonal = np.diagonal(view, axis1=0, axis2=1)
# unfortunatly now the first slice is diagonal[...,0], so just roll it to the start:
diagonal = np.rollaxis(diagonal, -1)
```

Now `diagonal`

is the array you created in your for loop (on newer versions add a `.copy()`

if you do not want a view).

Edit: Since the `slices`

array is 2D and not 3D because you append, a reshape was missing here:

```
slices = diagonal.reshape(-1,2)
```

This might not be faster if you have such small arrays, but its constant (expect for the copying of the data in `diagonal`

call) with the array size.