Let's take a concrete example - suppose that your implementation is backed by a dynamic array (this is how `ArrayList`

works, for example). Now, suppose that you want to remove elements in the range [start, end). The default implementation of `removeRange`

works by getting an iterator to position `start`

, then calling `remove()`

the appropriate number of times.

Each time `remove()`

is called, the dynamic array implementation has to shuffle all the elements at position `start + 1`

and forward back one spot to fill the gap left in the removed element. This could potentially take time O(n), because potentially all of the array elements might need to get shuffled down. This means that if you're removing a total of `k`

elements from the list, the naive approach will take time O(kn), since you're doing O(n) work k times.

Now consider a much better approach: copy the element at position `end`

to position `start`

, then element `end + 1`

to position `start + 1`

, etc. until all elements are copied. This requires you to only do a total of O(n) work, because every element is moved at most once. Compared with the O(kn) approach given by the naive algorithm, this is a huge performance improvement. Consequently, overriding `removeRange`

to use this more efficient algorithm can dramatically increase performance.

Hope this helps!