So basically, you've got a sorted list of the points that comprise the entire rope and you're given two arbitrary points from within that list, and tasked with returning the sublist that exists between those two points.

I'm going to make the assumption that the start and end points that are provided are guaranteed to coincide exactly with points within the sorted list (otherwise it introduces a host of issues, particularly if the rope may be arbitrarily thin and passes by the start/end points multiple times).

That means all you're really looking for are the indices of the two provided coordinates. Or the index of one, and the answer to "is the second coordinate to the right or to the left?".

A simple O(n) solution to that would be:

```
For each index in array
coord = array[index]
if (coord == point1)
startIndex = index
if (coord == point2)
endIndex = index
if (endIndex < startIndex)
swap(startIndex, endIndex)
return array.sublist(startIndex, endIndex)
```

Or, if you wanted to optimize for repeated queries, I'd suggest a hashing based approach where you map each cooordinate to its index in the array. Something like:

```
//build the map (do this once, at init)
map = {}
For each index in array
coord = array[index]
map[coord] = index
//find a sublist (do this for each set of start/end points)
startIndex = map[point1]
endIndex = map[point2]
if (endIndex < startIndex)
swap(startIndex, endIndex)
return array.sublist(startIndex, endIndex)
```

That's O(n) to build the map, but once it's built you can determine the sublist between any two points in O(1). Assuming an efficient hashmap, of course.

Note that if my assumption doesn't hold, then the same solutions are still usable, provided that as a first step you take the provided start and end points and locate the points in the array that best correspond to each one. As noted, unless you are given some constraints regarding the thickness of the rope then interpolating from an arbitrary coordinate to one that's actually part of the rope can only be guesswork at best.