**Problem**:

The most computationally efficient solution to getting the indices of boundaries in an array where starts of boundaries always start with a particular number and non-boundaries are indicated by a different particular number.

**Differences between this question and other boundary-based numpy questions on SO:**

here are some other boundary based numpy questions

Numpy 1D array - find indices of boundaries of subsequences of the same number

Getting the boundary of numpy array shape with a hole

Extracting boundary of a numpy array

The difference between the question I am asking and other stackoverflow posts in my attempt to search for a solution is that the other boundaries are indicated by a jump in value, or a 'hole' of values.

What seems to be unique to my case is the starts of boundaries always start with a particular number.

**Motivation:**

This problem is inspired by IOB tagging in natural language processing. In IOB tagging, the start of a word is tagged with B [beginning] is the tag of the first letter in an entity, I [inside] is the tag for all other characters besides the first character in a word, and [O] is used to tag all non-entity characters

**Example:**

```
import numpy as np
a = np.array(
[
0, 0, 0, 1, 2, 2, 2, 0, 0, 0, 1, 0, 0, 1, 2, 1, 1, 0, 0, 1, 1, 1
]
)
```

1 is the start of each boundary. If a boundary has a length greater than one, then 2 makes up the rest of the boundary. 0 are non-boundary numbers.

The entities of these boundaries are `1, 2, 2, 2`

, `1`

, `1,2`

, `1`

, `1`

, `1`

, `1`

, `1`

So the desired solution; the indices of the indices boundary values for `a`

are

```
desired = [[3, 6], [10, 10], [13, 14], [15, 15], [16,16], [19,19], [20,20], [21,21]]
```

**Current Solution:**

If flattened, the numbers in the desired solution are in ascending order. So the raw indices numbers can be calculated, sorted, and reshaped later.

I can get the start indices using

```
starts = np.where(a==1)[0]
starts
```

```
array([ 3, 10, 13, 15, 16, 19, 20, 21])
```

So what's left is `6, 10, 14, 15,16,19,20,21`

I can get all except 1 using 3 different conditionals where I can compare a shifted array to the original by decreases in values and the values of the non-shifted array.

```
first = np.where(a[:-1] - 2 == a[1:])[0]
first
```

```
array([6])
```

```
second = np.where((a[:-1] - 1 == a[1:]) &
((a[1:]==1) | (a[1:]==0)))[0]
second
```

```
array([10, 14, 16])
```

```
third = np.where(
(a[:-1] == a[1:]) &
(a[1:]==1)
)[0]
third
```

```
array([15, 19, 20])
```

The last number I need is `21`

, but since I needed to shorten the length of the array by 1 to do the shifted comparisons, I'm not sure how to get that particular value using logic, so I just used a simple if statement for that.

Using the rest of the retrieved values for the indices, I can concatenate all the values and reshape them.

```
if (a[-1] == 1) | (a[-1] == 2):
pen = np.concatenate((
starts, first, second, third, np.array([a.shape[0]-1])
))
else:
pen = np.concatenate((
starts, first, second, third,
))
np.sort(pen).reshape(-1,2)
```

```
array([[ 3, 6],
[10, 10],
[13, 14],
[15, 15],
[16, 16],
[19, 19],
[20, 20],
[21, 21]])
```

Is this the most computationally efficient solution for my answer? I realize the four where statements can be combined with `or`

operators but wanted to have each separate for the reader to see each result in this post. But I am wondering if there is a more computationally efficient solution since I have not mastered all of numpy's functions and am unsure of the computational efficiency of each.