You can just sort both A and B. In that case, the Euclidean distance is minimal.

If B has to remain fixed, then you just need to invert the permutation needed to sort B and apply that to the sorted version of A.

This solution does assume that you want to find just a permutation and not the most simple permutation (since sorting and unsorting through permutations will not be incredibly efficient).

*Proof:*
Let S,T be our pair of arrays.
We can assume S to be sorted without loss of generality, since all that
matters is the mapping between the two sets of elements.

Let T be the permutation that minimizes the distance between the two arrays,
and let d be that distance.

Suppose that T is *not* sorted. Then there exist elements i,j s.t. T_i > T_j

```
S_i + k1 = S_j
T_i = T_j + k2
where k1,k2 > 0
```

Let x be the total distance of all elements except i and j.

```
d = x + (S_i - T_i)^2 + ((S_i + k1) - (T_i - k2))^2
```

If we swap the order of T_i and T_j, then our new distance is:

```
d' = x + (S_i - (T_i - k2))^2 + ((S_i + k1) - T_i)^2
```

Thus:
d - d' = 2 * k1 * k2, which contradicts our assumption that T is the permutation that minimizes the distance, so the permutation that does so must be sorted.

Sorting the two arrays can be done in O(n log n) using a variety of methods.

`Pythagoras`

and find which combination provides the shortest distance. So you are basically building a tree of all possible combinations, for this you would need to consider what is it you are after, degree of precision or if it needs to be exact, how many results you want (can be many), speed [of the algorithm]? Having this in mind what you could do to speed up such process is to trim your tree; again how exact does it need to be? – Ordiel Jan 4 at 15:17