The insight behind Boyer-Moore is that if you start searching for a pattern in a string starting with the *last* character in the pattern, you can jump your search forward multiple characters when you hit a mismatch.

Let's say our pattern `p`

is the sequence of characters `p1`

, `p2`

, ..., `pn`

and we are searching a string `s`

, currently with `p`

aligned so that `pn`

is at index `i`

in `s`

.

E.g.:

```
s = WHICH FINALLY HALTS. AT THAT POINT...
p = AT THAT
i = ^
```

The B-M paper makes the following observations:

(1) if we try matching a character that is not in `p`

then we can jump forward `n`

characters:

'F' is not in `p`

, hence we advance `n`

characters:

```
s = WHICH FINALLY HALTS. AT THAT POINT...
p = AT THAT
i = ^
```

(2) if we try matching a character whose last position is `k`

from the end of `p`

then we can jump forward `k`

characters:

' 's last position in `p`

is 4 from the end, hence we advance 4 characters:

```
s = WHICH FINALLY HALTS. AT THAT POINT...
p = AT THAT
i = ^
```

Now we scan backwards from `i`

until we either succeed or we hit a mismatch.
(3a) if the mismatch occurs `k`

characters from the start of `p`

and the mismatched character is not in `p`

, then we can advance (at least) `k`

characters.

'L' is not in `p`

and the mismatch occurred against `p6`

, hence we can advance (at least) 6 characters:

```
s = WHICH FINALLY HALTS. AT THAT POINT...
p = AT THAT
i = ^
```

However, we can actually do better than this.
(3b) since we know that at the old `i`

we'd already matched some characters (1 in this case). If the matched characters don't match the start of `p`

, then we can actually jump forward a little more (this extra distance is called 'delta2' in the paper):

```
s = WHICH FINALLY HALTS. AT THAT POINT...
p = AT THAT
i = ^
```

At this point, observation (2) applies again, giving

```
s = WHICH FINALLY HALTS. AT THAT POINT...
p = AT THAT
i = ^
```

and bingo! We're done.