Having gone as far as is practical with pic, postscript really is the natural choice for this.

Alright, I haven't solved the labelling yet, but here's the generalized diagram. Turns out you just place the centers on the vertices of the regular polygon for that *n*.

But some of those spaces get *reeeally* small. So I'm thinking about some pattern of labelled arcs, spiralling out. Perhaps the radius of the label should reflect the depth of the designated partition...

**Edit:** I've redesigned the code, so there's a pretty 15-diagram page in revision 1.

**Edit:** I just got schooled by Wikipedia. It turns out that what I've been calling a 4-cell Venn diagram is *not, in fact, a Venn diagram at all*.

It's an Euler diagram. The problem is that nowhere can you get the intersection of two regions alone from opposite sides of the diagram. The *real* 4-cell diagram gets weird no matter how you do it. So the scope of the answer is reduced from what I've pursued in the last two edits.

For the 2-circle diagram, the best placement I can find is defined by the intersection of the radii from the diagram center through the circle centers to the edges, with defining circles placed on the circle centers.

For the 3-circle diagram, the best placement I can find is defined by the intersections of the radii (and rotated radii) with rotated triangle approximations to the circles and unrotated triangles, respectively.

A version of the code can be found in the previous revision of this answer. I posted an expanded version to usenet in the thread geodesic flowers. But since it's overkill for this answer (and still doesn't actually draw any labels or return their locations), and underkill for *real* generalized Venn diagrams, I'll need to trim most of the baggage before subjecting this question to any more long blocks of code.

**Edit:** I think I've got this just about licked. This program contains only those parts of the previous program necessary to produce 2- and 3- Venn diagrams with little circles at the "ideal" label locations. For the 2-cell diagram the solution really is trivial (double the defining radius). For the 3-cell diagram the solution is *cos(60) * circle-radius + defining radius*, either multiplying first or adding first.

**Edit:** At long last, labels. There was some last-minute trickiness required since I used matrix rotations to find the points. That meant that when I tried printing labels, they were all at strange orientations. So the "centershow" procedure has a little more to it that usual. It has to reset the scaling portions of the current transformation matrix while leaving the translation components alone. That means somewhere earlier in the execution we need to stash an oriented matrix at the correct scale.

(*Edit:* Another way to get the text upright without modifying a matrix would be to `transform`

the location to device coordinates, install the oriented matrix (at any scale or translation!), `itransform`

the point back to the "new" user coordinates, and then `moveto`

.)

```
%!
%cp:xy rad circ -
/circ {
currentpoint newpath
2 copy 5 -1 roll 0 360 arc stroke
moveto
} def
%rad n poly [pointlist]
/poly {
1 dict begin exch /prad exch def
[ exch
0 exch 360 exch div 359.9 {
[ exch
dup cos prad mul exch
sin prad mul
]
} for
]
end
} def
%[list] rad subcirc -
/subcirc {
1 dict begin /crad exch def gsave
currentpoint translate
{ aload pop moveto crad circ } forall
grestore end
} def
%[list] locate -
%draw little circles around each point
/locate {
gsave
currentpoint translate
0 0 moveto 5 circ
{ aload pop moveto 5 circ } forall
grestore
} def
%cp:xy (string) cshow -
/cshow {
gsave
currentpoint translate %0 0 moveto
matrix currentmatrix
dup 0 normal 0 4 getinterval %reset rotation, keep translation
putinterval setmatrix
dup true charpath flattenpath pathbbox
3 -1 roll sub 3 1 roll sub
2 div exch -2 div moveto show
grestore
} def
%[list] [labels] label -
%print label text centered on each point
/label {
gsave
currentpoint translate
0 1 3 index length 1 sub {
2 index 1 index get aload pop moveto
2 copy get cshow pop
} for
pop pop
grestore
} def
%[x0 y0] [x1 y1] pyth-dist radius
/pyth-dist {
aload pop 3 -1 roll aload pop % x1 y1 x0 y0
exch % x1 y1 y0 x0
3 1 roll sub dup mul % x1 x0 dy^2
3 1 roll sub dup mul % dy^2 dx^2
add sqrt
} def
/rotw { 180 n div rotate } def
%cp:xy rad n venn -
%make the circles intersect the opposite point of def poly
/venn {
3 dict begin /n exch def /vrad exch def
vrad n poly
dup 0 get exch
dup length 2 idiv get
pyth-dist /crad exch def
%vrad crad n ven
vrad n poly crad subcirc %the Venn circles
[[0 0]] [(All)] label
n 2 eq {
%vrad 2 mul n poly locate
vrad 2 mul n poly
[(A) (B)] label
}{
n 3 eq {
%vrad crad 60 cos mul add n poly locate
vrad crad 60 cos mul add n poly
[ (A) (B) (C) ] label
%gsave rotw vrad crad add 60 cos mul n poly locate grestore
gsave rotw vrad crad add 60 cos mul n poly
[ (A^B) (B^C) (A^C) ] label
grestore
} if
} ifelse
end
} def
/normal matrix currentmatrix def
/in{72 mul}def
/Palatino-Roman 20 selectfont
4.25 in 8.25 in moveto
1 in 2 venn
4.25 in 3.5 in moveto
1 in 3 venn
showpage
```

And ghostscript produces (`gs -sDEVICE=jpeggray -sOutputFile=venlabel.jpg v4.ps`

):