If you are after substrings, a Trie or Patrica trie might be a good starting point.

If you don't care about the order, just about the number of each symbol or letter, I would calculate the histogram of all strings and then compare them with the histogram of the input.

```
ABCDEFGHIJKLMNOPQRSTUVWXYZ
Hello World => ...11..1...3..2..1....1...
```

This will lower the costs to `O(26 * m + n)`

plus the preprocessing once if you consider only case-insensitive latin letters.

If m is constant, you could interpret the histogram as a 26 dimensional vector on a 26 dimensional unit sphere by normalizing it. Then you could just calculate the Dot Product of two vectors yielding the cosine of the angle between the two vectors, and this value should be proportional to the similarity of the strings.

Assuming `m = 3`

, a alphabet `A = { 'U', 'V', 'W' }`

of size three only, and the following list of strings.

```
L = { "UUU", "UVW", "WUU" }
```

The histograms are the following.

```
H = { (3, 0, 0), (1, 1, 1), (2, 0, 1) }
```

A histogram `h = (x, y, z)`

is normalized to `h' = (x/r, y/r, z/r)`

with `r`

the Euclidian norm of the histogram `h`

- that is `r = sqrt(x² + y² + z²)`

.

```
H' = { (1.000, 0.000, 0.000), (0.577, 0.577, 0.577), (0.894, 0.000, 0.447) }
```

The input `S = "VVW"`

has the histogram `hs = (0, 2, 1)`

and the normalized histogram `hs' = (0.000, 0.894, 0.447)`

.

Now we can calculate the similarity of two histograms `h1 = (a, b, c)`

and `h2 = (x, y, z)`

as the Euclidian distance of both histograms.

```
d(h1, h2) = sqrt((a - x)² + (b - y)² + (c - z)²)
```

For the example we obtain.

```
d((3, 0, 0), (0, 2, 1)) = 3.742
d((1, 1, 1), (0, 2, 1)) = 1.414
d((2, 0, 1), (0, 2, 1)) = 2.828
```

Hence "UVW" is closest to "VVW" (smaller numbers indicate higher similarity).

Using the normalized histograms `h1' = (a', b', c')`

and `h2' = (x', y', z')`

we can calculate the distance as the dot product of both histograms.

```
d'(h1', h2') = a'x' + b'y' + c'z'
```

For the example we obtain.

```
d'((1.000, 0.000, 0.000), (0.000, 0.894, 0.447)) = 0.000
d'((0.577, 0.577, 0.577), (0.000, 0.894, 0.447)) = 0.774
d'((0.894, 0.000, 0.447), (0.000, 0.894, 0.447)) = 0.200
```

Again "UVW" is determined to be closest to "VVW" (larger numbers indicate higher similarity).

Both version yield different numbers, but the results are always the same. One could also use other norms - Manhattan distance (L1 norm) for example - but this will only change the numbers because norms in finite dimensional vector spaces are all equivalent.