Modifications to linked list involve two operations:

- locating the node to append the new node to
- actually appending the node, by changing the node pointers

In Linked List, the second operation is an `O(1)`

operation, so it is a matter of the cost of first operations.

When appending to the last node, naive implementations of linked list would result in `O(n)`

iteration time. However, good linked list libraries would account for the most common uses, and special case accessing the last node. This optimization would result into `O(1)`

retrieval of the last element, resulting in overall `O(1)`

insertion time to end.

As for the middle, your analysis is correct in that locating the node would also take `O(n)`

. However, some libraries expose a method that would take a pointer to where the new node should be inserted rather than the index (e.g. `C++`

`list`

). This eliminates the linear cost, resulting in over all `O(1)`

.

While insertion to the middle is usually thought of as `O(n)`

operation, it can be optimized to `O(1)`

in some cases. This is the opposite of array list, where the insertion operation itself (the second operation) is `O(n)`

, as all the elements in higher locations need to be relocated. This operation cannot be optimized.

For insertation
A naive implementation of a linked list would result in `O(n)`

insertion time. However, good linked list library writers would optimize for the common cases, so they would keep a reference to the last elements (or have a circular linked list implementation), resulting in a `O(1)`

insertion time.

As for insertion to the middle. Some libraries like that of `C++`

, has a suggested location for insertion. They would take a pointer to the list node, where the new one is be appended to. Such insertions would cost `O(1)`

. I don't think you can achieve `O(1)`

by index number.

This is apposed to an array list, where insertion to the middle forces reordering of all the elements higher than it, so it has to be an `O(n)`

operation.