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I'm creating a 2D, tile-based system of terrain for a game. However, I'm also using in-game coordinates that need to be able to map a bounding box into the "tile coordinates" and hit each tile the bounding box touches (don't worry, have a kd-tree and all that working fine). Using fixed point "real world" coordinates, I can make each tile count as 2^n of them and simply right shift the bits off to truncate down to tile coordinates. I form a bounding box using the smallest x,y pair and the largest x,y pair. I'll call them R0 and R1 respectively.

Here's a bounding box with coordinates R0: 0.8, 0.7 to R1: 2.2, 1.7 being mapped to the tiles.

enter image description here

Now, that's simple enough. However, I want to split my tiles into 4 triangular quadrants, which lets me make more interesting stuff. Since each tile becomes 4 triangles, I assumed that they can be referenced by 2 bits in some manner (not necessarily the one I show). I want to use as few bits as possible to "label" these triangles. I'm going to put my triangle label for a point right next to its tile coordinates, in the form of [XX] with XX being the bits indicating which triangle it is.

enter image description here

However, I've ran into several problems using this. I need to be able to convert my real world bounding box coordinates into "triangle coordinates", but it appears that it is too lossy to fully describe the bounding box. The same coordinates in triangle land can describe bounding boxes that would collide with different triangles.

I have the same first bounding box as before on the left: R0: 0.8, 0.7 to R1: 2.2, 1.7
On the right, I have a new bounding box R0: 0.8, 0.3 to R1: 2.2, 1.7, so the y component of the top left corner is moved up. They both translate to the same triangle coordinates, but collide with different triangles if it is done in real world coordinates. No distinction is made in triangle coordinates, though, so data is lost and an incorrect set of collisions is generated.

enter image description here

Further, the same problem occurs with bounding boxes that start and end in the same triangle. The same triangle coordinates describe bounding boxes that sometimes are totally in that triangle, and sometimes not.

enter image description here

There has got to be a way to map these, maybe using more bits, so that all triangle coordinate comparisons performed in the kd-tree range query can match how the real world bounding box would collide with those same triangles in real world coordinates. But I'm at a loss.

I went down the rabbit hole creating "sub-tiles" to split each tile in 4 axis-aligned squares, which also split each quadrant tile in 2 along the axis it crosses, since I noticed many cases were caused by not knowing which side of each triangle my coordinates got mapped to.

enter image description here

But as I followed exception after exception to ever more detailed rules, I eventually ended up turning my sub-tiles into the same 4 triangular quadrant design and ending up where I began, except with smaller tiles.

I know it just has to be possible to achieve this "compression" and have proper comparisons, but I keep going in circles whenever I try. How can it be done??

Alexey proposed a solution that would allow me to describe a bounding box, but it is incompatible with using a kd-tree to find bounding box overlaps. With my kd-tree (storing the top left and bottom right coords) range query and a search region [x0, y0], [x1, y1] I do a range query over:

[0, 0, x1, y1] to [x1, y1, xmax, ymax]

But Alexey's solution won't work with this, even if I attempt to compensate for the 8 dimensional coordinates.

I don't really mind if a coordinate system is sorta different than what I was originally considering, as long as it can still manifest the same results with the triangular quadrants.

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Since the set of hit triangles is not regular, you need a different representation of the set than just two corners (in tile coordinates). The corners in real world coordinates would describe the set sufficiently. So you need a function that converts the corners to this set. Is it this you are asking? –  Nico Schertler Dec 5 '12 at 20:29
@NicoSchertler Ya, the goal being that I can reduce the size of the data describing bounding boxes (for the purpose of terrain collision) through this simplification, while still keeping sufficient freedom in terrain design as allowed by the triangles. However, I still need the representation to work with a kd-tree range query, and preferably using as few dimensions in it as possible (currently using the minimum of 4 for bounding boxes). –  user173342 Dec 5 '12 at 21:08

1 Answer 1

up vote 2 down vote accepted

Seems the minimal subdivision you need is that of each square into octants. Each square should be divided by two diagonals AND the horizontal and vertical midlines. If for each corner of the box (not just for the upper left and lower right, but for all four) you store in which octant of which tile it ended up, you'll have enough information to find collisions with all your original triangular tiles (but not with all octants).

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"If for each corner of the box (not just for the upper left and lower right, but for all four) you store in which octant of which tile it ended up"... What do you mean by that? Also, I may have already tried this once, but perhaps I didn't do it quite right. –  user173342 Dec 5 '12 at 21:57
Your bounding box has four corners. For each corner, store in which octant of which square it is. What's important is that you need to store this information for each of the four corners, not just two. I can see you'd still have problems if you only stored it for the upper left and lower right corner. –  Alexey Feldgendler Dec 5 '12 at 22:00
Ah, ya, that's what I tried. Damn, doubling the storage negates the entire purpose of all of this. –  user173342 Dec 5 '12 at 22:03
It's not exactly doubling. You only need store two pairs of coarse (square) coordinates, and twelve more bits for the octants. This should still beat storing four floats. –  Alexey Feldgendler Dec 5 '12 at 22:06
Ya, you're right. I was thinking more for the kd-tree range query... I don't think it would be possible to still use 4 dimensions on it with this setup, I'd need 8. Of course, maybe I can pull out a silver lining and find a way to setup the range query to deal with potentially diagonal shaped regions (before had to limit to axis-aligned boxes). –  user173342 Dec 5 '12 at 22:13

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