Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

According to this paper differentiation works on data structures.

According to this answer:

Differentiation, the derivative of a data type D (given as D') is the type of D-structures with a single “hole”, that is, a distinguished location not containing any data. That amazingly satisfy the same rules as for differentiation in calculus.

The rules are:

 1 = 0
 X′ = 1
 (F + G)′ = F' + G′
 (F • G)′ = F • G′ + F′ • G
 (F ◦ G)′ = (F′ ◦ G) • G′

The referenced paper is a bit too complex for me to get an intuition. What does this this mean in practice? A concrete example would be fantastic.

share|improve this question
    
In practice it means that you can calculate or construct the derivative of a data-type. +, • and ◦ are constructs you can use to describe datatypes in a more general way. Holes can be used for zippers, and in this manner one can automatically find holes in datastructures, making it useful for Generics. –  Alessandro Vermeulen May 7 '11 at 8:32
    
I built intuition on this one using only the formal rules. It's pretty clear what "a hole in a sum type" or "a hole in a product type" should be, so you get exactly what mathematicians call a differentiation. Then, you automatically know that you can do all the stuff you do when computing derivatives: chain rule, differentiating inverses, partial derivatives, differential equations (exponentials ? Is there a use for an exponential functor ?), differentiating solutions to fixed point equations (this is how you compute the type of a zipper) ! –  Alexandre C. May 7 '11 at 10:17
    
@Alexandre: e^X = 1 + X + X^2/2 + X^3/3! + .... How do you divide a type? :) –  KennyTM May 7 '11 at 11:50
    
@KennyTM: exp is defined as the solution of F'(X) = F(X) (as a "universal" solution of the equation, either initial or terminal, like lists are solutions of L(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
    
@Alexandre: If such type exists, it would not be a "polynomial type". (assuming F(X) ≠ 0) –  KennyTM May 7 '11 at 19:01

2 Answers 2

up vote 16 down vote accepted

What's a one hole context for an X in an X? There's no choice: it's (-), representable by the unit type.

What's a one hole context for an X in an X*X? It's something like (-,x2) or (x1,-), so it's representable by X+X (or 2*X, if you like).

What's a one hole context for an X in an X*X*X? It's something like (-,x2,x3) or (x1,-,x3) or (x1,x2,-), representable by X*X + X*X + X*X, or (3*X^2, if you like).

More generally, an F*G with a hole is either an F with a hole and a G intact, or an F intact and a G with a hole.

Recursive datatypes are often defined as fixpoints of polynomials.

data Tree = Leaf | Node Tree Tree

is really saying Tree = 1 + Tree*Tree. Differentiating the polynomial tells you the contexts for immediate subtrees: no subtrees in a Leaf; in a Node, it's either hole on the left, tree on the right, or tree on the left, hole on the right.

data Tree' = NodeLeft () Tree | NodeRight Tree ()

That's the polynomial differentiated and rendered as a type. A context for a subtree in a tree is thus a list of those Tree' steps.

type TreeCtxt = [Tree']
type TreeZipper = (Tree, TreeCtxt)

Here, for example, is a function (untried code) which searches a tree for subtrees passing a given test subtree.

search :: (Tree -> Bool) -> Tree -> [TreeZipper]
search p t = go (t, []) where
  go :: TreeZipper -> [TreeZipper]
  go z = here z ++ below z
  here :: TreeZipper -> [TreeZipper]
  here z@(t, _) | p t       = [z]
                | otherwise = []
  below (Leaf,     _)  = []
  below (Node l r, cs) = go (l, NodeLeft () r : cs) ++ go (r, NodeRight l () : cs)

The role of "below" is to generate the inhabitants of Tree' relevant to the given Tree.

Differentiation of datatypes is a good way make programs like "search" generic.

share|improve this answer
    
Awesome. Very intuitive explanation. I love it when the authors answer questions about the paper themselves. I'm going to be on the lookout for places to apply the derivative of a datatype in my work. –  dsg May 7 '11 at 17:51

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)
share|improve this answer
    
your list example was very satisfying to read. –  dsg May 7 '11 at 18:10

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.