My interpretation is that, the derivative (zipper) of T is the type of all instances that resembles the "shape" of T, but with exactly 1 element replaced by a "hole".
For instance, a list is
List t = 1 []
+ t [a]
+ t^2 [a,b]
+ t^3 [a,b,c]
+ t^4 [a,b,c,d]
+ ... [a,b,c,d,...]
if we replace any of those 'a', 'b', 'c' etc by a hole (represented as @
), we'll get
List' t = 0 empty list doesn't have hole
+ 1 [@]
+ 2*t [@,b] or [a,@]
+ 3*t^2 [@,b,c] or [a,@,c] or [a,b,@]
+ 4*t^3 [@,b,c,d] or [a,@,c,d] or [a,b,@,d] or [a,b,c,@]
+ ...
Another example, a binary tree is
data Tree t = TEmpty  TNode t (Tree t) (Tree t)
 Tree t = 1 + t (Tree t)^2
so adding a hole generates the type:
{
Tree' t = 0 empty tree doesn't have hole
+ (Tree X)^2 the root is a hole, followed by 2 normal trees
+ t*(Tree' t)*(Tree t) the left tree has a hole, the right is normal
+ t*(Tree t)*(Tree' t) the left tree is normal, the right has a hole
@ or x or x
/ \ / \ / \
a b @? b a @?
/\ /\ / \ /\ /\ /\
c d e f @? @? e f c d @? @?
}
data Tree' t = THit (Tree t) (Tree t)
 TLeft t (Tree' t) (Tree t)
 TRight t (Tree t) (Tree' t)
A third example which illustrates the chain rule is the rose tree (variadic tree):
data Rose t = RNode t [Rose t]
 R t = t*List(R t)
the derivative says R' t = List(R t) + t * List'(R t) * R' t
, which means
{
R' t = List (R t) the root is a hole
+ t we have a normal root node,
* List' (R t) and a list that has a hole,
* R' t and we put a holed rose tree at the list's hole
x

[a,b,c,...,p,@?,r,...]

[@?,...]
}
data Rose' t = RHit [Rose t]  RChild t (List' (Rose t)) (Rose' t)
Note that data List' t = LHit [t]  LTail t (List' t)
.
(These may be different from the conventional types where a zipper is a list of "directions", but they are isomorphic.)
The derivative is a systematic way to record how to encode a location in a structure, e.g. we can search with: (not quite optimized)
locateL :: (t > Bool) > [t] > Maybe (t, List' t)
locateL _ [] = Nothing
locateL f (x:xs)  f x = Just (x, LHit xs)
 otherwise = do
(el, ctx) < locateL f xs
return (el, LTail x ctx)
locateR :: (t > Bool) > Rose t > Maybe (t, Rose' t)
locateR f (RNode a child)
 f a = Just (a, RHit child)
 otherwise = do
(whichChild, listCtx) < locateL (isJust . locateR f) child
(el, ctx) < locateR f whichChild
return (el, RChild a listCtx ctx)
and mutate (plug in the hole) using the context info:
updateL :: t > List' t > [t]
updateL x (LHit xs) = x:xs
updateL x (LTail a ctx) = a : updateL x ctx
updateR :: t > Rose' t > Rose t
updateR x (RHit child) = RNode x child
updateR x (RChild a listCtx ctx) = RNode a (updateL (updateR x ctx) listCtx)
e^X = 1 + X + X^2/2 + X^3/3! + ...
. How do you divide a type? :) – KennyTM May 7 '11 at 11:50exp
is defined as the solution ofF'(X) = F(X)
(as a "universal" solution of the equation, either initial or terminal, like lists are solutions ofL(X) = 1 + A L(X)
). I have no idea of the functors which satisfy it (if any), neither what could be their use. – Alexandre C. May 7 '11 at 12:02