Assuming you're trying to do this:

```
A = np.arange(15).reshape((5, -1))
def cumsum2_reverse(arr):
out = np.empty_like(arr)
d, e = arr.shape
for i in xrange(d):
for j in xrange(e):
b = 0
for k in xrange(i + 1, d):
for l in xrange(j + 1, e):
b += arr[k, l]
out[i, j] = b
return out
```

Then if you do,

```
In [1]: A_revsum = cumsum2_reverse(A)
In [2]: A_revsum
Out[2]:
array([[72, 38, 0],
[63, 33, 0],
[48, 25, 0],
[27, 14, 0],
[ 0, 0, 0]])
```

You could use `np.cumsum`

on the reverse-ordered arrays to compute the sum. For example, at first you might try something similar to what @Jaime suggested:

```
In [3]: np.cumsum(np.cumsum(A[::-1, ::-1], 0), 1)[::-1, ::-1]
Out[3]:
array([[105, 75, 40],
[102, 72, 38],
[ 90, 63, 33],
[ 69, 48, 25],
[ 39, 27, 14]])
```

Here we remember that `np.cumsum`

starts with the value in the first column (in this case last column), so to ensure zeros there, you could shift the output of this operation. This might look like:

```
def cumsum2_reverse_alt(arr):
out = np.zeros_like(arr)
out[:-1, :-1] = np.cumsum(np.cumsum(arr[:0:-1, :0:-1], 0), 1)[::-1, ::-1]
return out
```

This gives the same values as above.

```
In [4]: (cumsum2_reverse(A) == cumsum2_reverse_alt(A)).all()
Out[4]: True
```

Note, that the one that utilizes `np.cumsum`

is much faster for large arrays. For example:

```
In [5]: A=np.arange(3000).reshape((50, -1))
In [6]: %timeit cumsum2_reverse(A)
1 loops, best of 3: 453 ms per loop
In [7]: %timeit cumsum2_reverse_alt(A)
10000 loops, best of 3: 24.7 us per loop
```

`np.cumsum(np.cumsum(A[::-1, :], axis=0)[::-1, ::-1], axis=1)[:, ::-1]`

will probably get you about 99% of the way there...