Having dealt with converting the Bezier Patches into triangles, I need to do a Binary Space Partition in order to draw the projected triangles using the Painter's Algorithm.

I've implemented the algorithm from Wikipedia with much help with the math.

But it's making a *Charlie Brown* tree! That is most of the nodes have one branch completely empty. The whole strategy is all wrong. Since the teapot is essentially spherical, the entire shape is only on one "side" of any particular component triangle.

So I'm thinking I need partitioning planes arranged more like an apple-corer: all passing through the line of the y-axis. But I'm kind of going *off book*, you know? **What's the best way to partition the teapot?**

Here's my bsp-tree generator. It uses other functions posted in the linked question.

Edit: Extra juggling to avoid dictstackoverflow. Complete program available here (requires mat.ps and teapot). The numerical output shows the depth of the tree node under construction.

```
% helper functions to insert and remove triangles in lists
/unshift { % [ e1 .. eN ] e0 . [ e0 e1 .. eN ]
exch aload length 1 add array astore
} def
/shift { % [ e0 e1 .. eN ] . [ e1 .. eN ] e0
aload length 1 sub array astore exch
} def
/makebsp { % [ triangles ] . bsptree
count =
%5 dict %This is the tree node data structure
<</P[]/PM[]/plane[]/front[]/behind[]/F<<>>/B<<>>>>
begin
dup length 1 le{ % If 0 or 1 triangles
dup length 0 eq { % If 0 triangles
pop % discard
}{ % If 1 triangle
aload pop /P exch def % put triangle in tree node
}ifelse
}{ % length>1
shift /P exch def % P: Partitioning Polygon (triangle)
P transpose aload pop
[1 1 1] 4 array astore % make column vectors of homogeneous coords
/PM exch def
[ % Compute equation of the plane defined by P
PM 0 3 getinterval det
[ PM 0 get PM 2 get PM 3 get ] det
[ PM 0 get PM 1 get PM 3 get ] det
PM 1 3 getinterval det 3 mul
] /plane exch def
% iterate through remaining triangles, testing against plane, adding to lists
/front [] def
/behind [] def
{ %forall [P4 P5 P6] = [[x4 y4 z4][x5 y5 z5][x6 y6 z6]]
/T exch def
T transpose % [[x4 x5 x6][y4 y5 y6][z4 z5 z6]]
{aload pop add add} forall % (x4+x5+x6) (y4+y5+y6) (z4+z5+z6)
plane 2 get mul 3 1 roll % z|C| (x) (y)
plane 1 get mul 3 1 roll % y|B| z|C| (x)
plane 0 get mul % y|B| z|C| x|A|
plane 3 get add add add % Ax+By+Cz+D
0 le { /front front
}{ /behind behind
} ifelse
T unshift def
} forall
%front == ()= behind == flush (%lineedit)(r)file pop
% recursively build F and B nodes from front and behind lists
%/F front makebsp def
front currentdict end exch
makebsp
exch begin /F exch def
%/B behind makebsp def
behind currentdict end exch
makebsp
exch begin /B exch def
/front [] def
/behind [] def
} ifelse
currentdict end
} def
```

Output: