### Prospective approach

Looking at your sample data :

```
In [64]: start_end
Out[64]:
0 1 2
0 (1, 6) (4, 5) (6, 12)
1 (7, 10) (11, 12) (13, 19)
```

It is indeed non-overlapping for each row, but not across the entire dataset.

Now, we have `np.ufunc.reduceat`

that gives us ufunc reduction for each slice :

```
ufunc(ar[indices[i]: indices[i + 1]])
```

as long as `indices[i] < indices[i+1]`

.

So, with `ufunc(ar, indices)`

, we would get :

```
[ufunc(ar[indices[0]: indices[1]]), ufunc(ar[indices[1]: indices[2]]), ..]
```

In our case, for each tuple `(x,y)`

, we know `x<y`

. With stacked version, we have :

```
[(x1,y1), (x2,y2), (x3,y3), ...]
```

If we flatten, it would be :

```
[x1,y1,x2,y2,x3,y3, ...]
```

So, we might not have `y1<x2`

, but that's okay, because we don't need ufunc reduction for that one and similarly for the pair : `y2,x3`

. But that's okay as they could be skipped with a stepsize slicing of the final output.

Thus, we would have :

```
# Inputs : a (1D array), start_end (2D array of shape (N,2))
lens = start_end[:,1]-start_end[:,0]
out = np.add.reduceat(a, start_end.ravel())[::2]/lens
```

`np.add.reduceat()`

part gives us the sliced summations. We needed the division by `lens`

for the average computations.

Sample run -

```
In [47]: a
Out[47]:
array([0.49264042, 0.00506412, 0.61419663, 0.77596769, 0.50721381,
0.76943416, 0.83570173, 0.2085408 , 0.38992344, 0.64348176,
0.3168665 , 0.78276451, 0.03779647, 0.33456905, 0.93971763,
0.49663649, 0.4060438 , 0.8711461 , 0.27630025, 0.17129342])
In [48]: start_end
Out[48]:
array([[ 1, 3],
[ 4, 5],
[ 6, 12],
[ 7, 10],
[11, 12],
[13, 19]])
In [49]: [np.mean(a[i:j]) for (i,j) in start_end]
Out[49]:
[0.30963037472653104,
0.5072138121177008,
0.5295464559328862,
0.41398199978967815,
0.7827645134019902,
0.5540688880441684]
In [50]: lens = start_end[:,1]-start_end[:,0]
...: out = np.add.reduceat(a, start_end.ravel())[::2]/lens
In [51]: out
Out[51]:
array([0.30963037, 0.50721381, 0.52954646, 0.413982 , 0.78276451,
0.55406889])
```

For completeness, referring back to given sample, the conversion steps were :

```
# Given start_end as df and values as a 2D array
start_end = np.vstack(np.concatenate(start_end.values))
a = values.ravel()
```

For other ufuncs that have `reduceat`

method, we will just replace `np.add.reduceat`

`start_end`

) and the vector is about`10,000,000`

If you think - the vector is too small, this is because often the`start_end`

has tuples of negative or nan values (i.e. this cell does not contain info in the`values`

vector) – Newskooler Jul 7 at 13:20`start_end`

be a 2D array of (N,2) shape? – Divakar Jul 7 at 13:21`start_end`

, are the cells non-overlapping and in increasing order? – Quang Hoang Jul 7 at 13:22`(N, 2)`

would be the state after one transformation step, as long as it can be mapped back to the 2d matrix of original size. – Newskooler Jul 7 at 13:26