Lets say I have a triangle like this:
and an array of the points [A,B,C,D,E,F]
Is there a way to calculate the array for an 120˚ rotated version of the triangle where the array would look like this [C,E,F,B,D,A] or [F,D,A,E,B,C]. I'm looking for a way that would also work for triangles that are be split into smaller pieces.
Under the assumption that the rotation can be only exactly 120 degrees in clockwise direction and the given start array is [A,B,C,D,E,F] it is quite easy to see that A,C,F will only ever occupy index 0,2,5 and B,D,E will only ever occupy index 1,3,4
Simple permutation rules arise for a single 120 degree rotation
index 0 -> 5
index 2 -> 0
index 5 -> 2
index 1 -> 3
index 3 -> 4
index 4 -> 1
This can be further abstracted to simple code
Imagine you would fill your array not like you did, but in the following way:
Take a straight line from the center of the triangle to point A.
Rotate it to the right. It will touch point B, C, E, F and D. Fill the array this way: ABCEFD.
Then it is clear how it looks like after a rotation of 120 degrees: CEFDAB, and after another 120 degrees: FDABCE. You just had to rotate the array contents 2 positions left.
EDIT (due to the comment below):
You can consider the array as closed circular structure. You fill the "circular array" point by point as you encounter them by rotating the half line. Of course, you can start at any angle. This will simply change the start point in the circular array. So it works for deeper splitting also. One thing one had to consider is that you will encounter at certain angles 2 or more points on the half line. In this case you had to use a rule in which sequence you fill them into the circular array. You could e.g. fill them from inside out.
So, is it really required to express your array in the not well adapted order ABCDEF initially?
Since this is always a multiple of 120˚, probably the simplest is to compute two permutations for rotating by 120˚ and 240˚. These permutations would simply map points to new locations in the array.
Generally speaking, no algorithm can "guess" how you denoted the vertexes.
Either there must be a systematic way that you need to tell us, or you can work as follows: for every vertex apply the 120° rotation to the coordinates and find another vertex that matches them.
