For example, here is the shape of intended spiral (and each step of the iteration)
y | | 16 15 14 13 12 17 4 3 2 11 -- 18 5 0 1 10 --- x 19 6 7 8 9 20 21 22 23 24 | |
Where the lines are the x and y axes.
Here would be the actual values the algorithm would "return" with each iteration (the coordinates of the points):
[0,0], [1,0], [1,1], [0,1], [-1,1], [-1,0], [-1,-1], [0,-1], [1,-1], [2,-1], [2,0], [2,1], [2,2], [1,2], [0,2], [-1,2], [-2,2], [-2,1], [-2,0]..
I've tried searching, but I'm not exactly sure what to search for exactly, and what searches I've tried have come up with dead ends.
I'm not even sure where to start, other than something messy and inelegant and ad-hoc, like creating/coding a new spiral for each layer.
Can anyone help me get started?
Also, is there a way that can easily switch between clockwise and counter-clockwise (the orientation), and which direction to "start" the spiral from? (the rotation)
Also, is there a way to do this recursively?
I have a sparse grid filled with data points, and I want to add a new data point to the grid, and have it be "as close as possible" to a given other point.
To do that, I'll call
grid.find_closest_available_point_to(point), which will iterate over the spiral given above and return the first position that is empty and available.
So first, it'll check
point+[0,0] (just for completeness's sake). Then it'll check
point+[1,0]. Then it'll check
point+[0,1], etc. And return the first one for which the position in the grid is empty (or not occupied already by a data point).
There is no upper bound to grid size.