Assuming n and k isn't too large so that this will fit into memory:

Have a set with the first letter removed, one with the second letter removed, one with the third letter removed, etc. Technically this has to be a map from strings to counts.

Run through the list, simply add the current element to each of the maps (obviously by removing the applicable letter first) (if it already exists, add the count to totalPairs and increment it by one).

Then totalPairs is the desired value.

**EDIT:**

**Complexity:**

This should be `O(n.k.logn)`

.

You can use a map that uses hashing (e.g. `HashMap`

in Java), instead of a sorted map for a theoretical complexity of `O(nk)`

(though I've generally found a hash map to be slower than a sorted tree-based map).

**Improvement:**

A small alteration on this is to have a map of the first 2 letters removed to 2 maps, one with first letter removed and one with second letter removed, and have the same for the 3rd and 4th letters, and so on.

Then put these into maps with 4 letters removed and those into maps with 8 letters removed and so on, up to half the letters removed.

The complexity of this is:

You do 2 lookups into 2 sorted sets containing maximum k elements (for each half).

For each of these you do 2 lookups into 2 sorted sets again (for each quarter).

So the number of lookups is 2 + 4 + 8 + ... + k/2 + k, which I believe is `O(k)`

.

I may be wrong here, but, worst case, the number of elements in any given map is `n`

, but this will cause all other maps to only have 1 element, so still `O(logn)`

, but for each `n`

(not each `n.k`

).

So I think that's `O(n.(logn + k))`

.

.

**EDIT 2:**

**Example of my maps (without the improvement):**

`(x-1)`

means `x`

maps to `1`

.

Let's say we have `abcd, abdd, adcb, adcd, aecd`

.

The first map would be `(bcd-1), (bdd-1), (dcb-1), (dcd-1), (ecd-1)`

.

The second map would be `(acd-3), (add-1), (acb-1)`

(for 4th and 5th, value already existed, so increment).

The third map : `(abd-2), (adb-1), (add-1), (aed-1)`

(2nd already existed).

The fourth map : `(abc-1), (abd-1), (adc-2), (aec-1)`

(4th already existed).

`totalPairs = 0`

For second map - `acd`

, for the 4th, we add 1, for the 5th we add 2.

`totalPairs = 3`

For third map - `abd`

, for the 2th, we add 1.

`totalPairs = 4`

For fourth map - `adc`

, for the 4th, we add 1.

`totalPairs = 5`

.

**Partial example of improved maps:**

Same input as above.

Map of first 2 letters removed to maps of 1st and 2nd letter removed:

```
(cd-{ {(bcd-1)}, {(acd-1)} }),
(dd-{ {(bdd-1)}, {(add-1)} }),
(cb-{ {(dcb-1)}, {(acb-1)} }),
(cd-{ {(dcd-1)}, {(acd-1)} }),
(cd-{ {(ecd-1)}, {(acd-1)} })
```

The above is a map consisting of an element `cd`

mapped to 2 maps, one containing one element `(bcd-1)`

and the other containing `(acd-1)`

.

But for the 4th and 5th `cd`

already existed, so, rather than generating the above, it will be added to that map instead, as follows:

```
(cd-{ {(bcd-1, dcd-1, ecd-1)}, {(acd-3)} }),
(dd-{ {(bdd-1)}, {(add-1)} }),
(cb-{ {(dcb-1)}, {(acb-1)} })
```