Consider a sequence delete followed by paste. Note that this yields the same state as paste followed by delete. So these operations can be swapped back and forth.
Next consider a sequence delete followed by "copy N". Note that this ends up in the same state as "copy N" followed by delete, so these sequences can be swapped (but only in one direction).
Therefore, in any sequence of operations, we can swap any delete with the operation following it without changing the final result. Therefore, we can move all of the delete operations to the end without changing the result.
From this it follows that if any deletes appear in the optimal sequence, they can be moved to the end of the sequence:
(Where X is either C or P)
But it cannot be optimal to have a copy without a subsequent paste, so the sequence actually looks like:
Now, observe that any paste + delete (PD) sequence can be replaced by a copy + paste (CP) sequence, where the copy just grabs one fewer lines. This replaces two operations with two other operations, so it loses nothing. So we can transform our optimal sequence into:
And we can do it again three times to eliminate all of the deletes:
Of course, a sequence of copies is sub-optimal, so our answer must look like:
In other words, deletes are never required as part of the optimal sequence.
Four pastes in a row are never required, because they can always be replaced by copy + paste + copy + paste. (Three pastes in a row can be required, though; e.g. to get from 4 to 13)
And that's as far as I get for now. At this point I might just do a Dijkstra-style breadth-first search for the shortest path...
As Mark Peters points out in a comment, three pastes in a row is never needed, either. Proof:
Copy(N) requires that N be less than the number of lines. So Copy(N) + Paste + Paste + Paste can always be replaced by Copy(N) + Paste + Copy(2N) + Paste.
So an optimal sequence can be formed with no deletes, no two copies in a row, and no more than two pastes in a row. Well, it's a start.