No.

Assume it was possible, with the algorithm f, we will show we can sort an array with `O(n*logn/loglogn)`

time complexity.

```
sort array A of length n:
(1) Create an 2-3 tree of size n, with no importance to keys. let it be T.
(2) store all pointers to nodes in T in a second array B.
(3) for each i from 0 to n:
(3.1) f(B[i],A[i]) //modify the tree: pointer: B[i] new value: A[i]
(4) extract elements from T back to A inorder.
```

**correctness:**

After each activation of `f`

the tree is legal. After finishing activating `f`

on all elements of `T`

and all elements of `A`

, the tree is legal and contains all elements. Thus, extracting elements from A, we get back the sorted array.

**complexity:**

(1)Creating a tree [no importance which keys we put] is `O(n)`

we can put `0`

in all elements, it doesn't matter

(2)iterating `T`

and creating `B`

is `O(n)`

(3)activating `f`

is `O(logn/loglogn)`

, thus invoking it `n`

times is `O(n*logn/loglogn)`

(4) extracting elements is just a traversal: `O(n)`

Thus: total complexity is `O(n*logn/loglogn)`

But sorting is an `Omega(nlogn)`

problem with comparisons based algorithms. contradiction.

**Conclusion**: desired `f`

doesn't exist.