I have a few ADT's that represent a simple geometry tree in Haskell. Something about having my operation types separate from the tree structure is bothering me. I'm thinking of making the Tree type contain constructors for the operators,it just seems like it would be cleaner. One problem I see with this is that my Zipper implementation will have to change to reflect all these new possible constructors. Is there any way around this? Or am I missing some important concept? In general I feel like I'm having trouble getting a grip on how to generally structure my programs in Haskell. I understand most of the concepts, ADT's, type classes, monads, but I'm not understanding the big picture yet. Thanks.

```
module FRep.Tree
(Tree(‥)
,Primitive(‥)
,UnaryOp(‥)
,BinaryOp(‥)
,TernaryOp(‥)
,sphere
,block
,transform
,union
,intersect
,subtract
,eval
) where
import Data.Vect.Double
--import qualified Data.Foldable as F
import Prelude hiding (subtract)
--import Data.Monoid
data Tree = Leaf Primitive
| Unary UnaryOp Tree
| Binary BinaryOp Tree Tree
| Ternary TernaryOp Tree Tree Tree
deriving (Show)
sphere ∷ Double → Tree
sphere a = Leaf (Sphere a)
block ∷ Vec3 → Tree
block v = Leaf (Block v)
transform ∷ Proj4 → Tree → Tree
transform m t1 = Unary (Transform m) t1
union ∷ Tree → Tree → Tree
union t1 t2 = Binary Union t1 t2
intersect ∷ Tree → Tree → Tree
intersect t1 t2 = Binary Intersect t1 t2
subtract ∷ Tree → Tree → Tree
subtract t1 t2 = Binary Subtract t1 t2
data Primitive = Sphere { radius ∷ Double }
| Block { size ∷ Vec3 }
| Cone { radius ∷ Double
, height ∷ Double }
deriving (Show)
data UnaryOp = Transform Proj4
deriving (Show)
data BinaryOp = Union
| Intersect
| Subtract
deriving (Show)
data TernaryOp = Blend Double Double Double
deriving (Show)
primitive ∷ Primitive → Vec3 → Double
primitive (Sphere r) (Vec3 x y z) = r - sqrt (x*x + y*y + z*z)
primitive (Block (Vec3 w h d)) (Vec3 x y z) = maximum [inRange w x, inRange h y, inRange d z]
where inRange a b = abs b - a/2.0
primitive (Cone r h) (Vec3 x y z) = undefined
unaryOp ∷ UnaryOp → Vec3 → Vec3
unaryOp (Transform m) v = trim (v' .* (fromProjective (inverse m)))
where v' = extendWith 1 v ∷ Vec4
binaryOp ∷ BinaryOp → Double → Double → Double
binaryOp Union f1 f2 = f1 + f2 + sqrt (f1*f1 + f2*f2)
binaryOp Intersect f1 f2 = f1 + f2 - sqrt (f1*f1 + f2*f2)
binaryOp Subtract f1 f2 = binaryOp Intersect f1 (negate f2)
ternaryOp ∷ TernaryOp → Double → Double → Double → Double
ternaryOp (Blend a b c) f1 f2 f3 = undefined
eval ∷ Tree → Vec3 → Double
eval (Leaf a) v = primitive a v
eval (Unary a t) v = eval t (unaryOp a v)
eval (Binary a t1 t2) v = binaryOp a (eval t1 v) (eval t2 v)
eval (Ternary a t1 t2 t3) v = ternaryOp a (eval t1 v) (eval t2 v) (eval t3 v)
--Here's the Zipper--------------------------
module FRep.Tree.Zipper
(Zipper
,down
,up
,left
,right
,fromZipper
,toZipper
,getFocus
,setFocus
) where
import FRep.Tree
type Zipper = (Tree, Context)
data Context = Root
| Unary1 UnaryOp Context
| Binary1 BinaryOp Context Tree
| Binary2 BinaryOp Tree Context
| Ternary1 TernaryOp Context Tree Tree
| Ternary2 TernaryOp Tree Context Tree
| Ternary3 TernaryOp Tree Tree Context
down ∷ Zipper → Maybe (Zipper)
down (Leaf p, c) = Nothing
down (Unary o t1, c) = Just (t1, Unary1 o c)
down (Binary o t1 t2, c) = Just (t1, Binary1 o c t2)
down (Ternary o t1 t2 t3, c) = Just (t1, Ternary1 o c t2 t3)
up ∷ Zipper → Maybe (Zipper)
up (t1, Root) = Nothing
up (t1, Unary1 o c) = Just (Unary o t1, c)
up (t1, Binary1 o c t2) = Just (Binary o t1 t2, c)
up (t2, Binary2 o t1 c) = Just (Binary o t1 t2, c)
up (t1, Ternary1 o c t2 t3) = Just (Ternary o t1 t2 t3, c)
up (t2, Ternary2 o t1 c t3) = Just (Ternary o t1 t2 t3, c)
up (t3, Ternary3 o t1 t2 c) = Just (Ternary o t1 t2 t3, c)
left ∷ Zipper → Maybe (Zipper)
left (t1, Root) = Nothing
left (t1, Unary1 o c) = Nothing
left (t1, Binary1 o c t2) = Nothing
left (t2, Binary2 o t1 c) = Just (t1, Binary1 o c t2)
left (t1, Ternary1 o c t2 t3) = Nothing
left (t2, Ternary2 o t1 c t3) = Just (t1, Ternary1 o c t2 t3)
left (t3, Ternary3 o t1 t2 c) = Just (t2, Ternary2 o t1 c t3)
right ∷ Zipper → Maybe (Zipper)
right (t1, Root) = Nothing
right (t1, Unary1 o c) = Nothing
right (t1, Binary1 o c t2) = Just (t2, Binary2 o t1 c)
right (t2, Binary2 o t1 c) = Nothing
right (t1, Ternary1 o c t2 t3) = Just (t2, Ternary2 o t1 c t3)
right (t2, Ternary2 o t1 c t3) = Just (t3, Ternary3 o t1 t2 c)
right (t3, Ternary3 o t1 t2 c) = Nothing
fromZipper ∷ Zipper → Tree
fromZipper z = f z where
f ∷ Zipper → Tree
f (t1, Root) = t1
f (t1, Unary1 o c) = f (Unary o t1, c)
f (t1, Binary1 o c t2) = f (Binary o t1 t2, c)
f (t2, Binary2 o t1 c) = f (Binary o t1 t2, c)
f (t1, Ternary1 o c t2 t3) = f (Ternary o t1 t2 t3, c)
f (t2, Ternary2 o t1 c t3) = f (Ternary o t1 t2 t3, c)
f (t3, Ternary3 o t1 t2 c) = f (Ternary o t1 t2 t3, c)
toZipper ∷ Tree → Zipper
toZipper t = (t, Root)
getFocus ∷ Zipper → Tree
getFocus (t, _) = t
setFocus ∷ Tree → Zipper → Zipper
setFocus t (_, c) = (t, c)
```

`∷`

instead`::`

and missing datatypes makes it complicated to do anything with that. Could you provide a code sample that can be compiled right away? – Petr Pudlák Aug 22 '12 at 9:02`{-# LANGUAGE UnicodeSyntax #-}`

or search-replace the operators... – dflemstr Aug 22 '12 at 9:27`bla bla bla`

or undefined operations such as`unaryOp`

. If I'm going to produce an example based on this code, it's much less work if I can just copy-paste and it works. – kosmikus Aug 22 '12 at 10:34