It's possible to build a graph from a zipper so that moving around on the graph doesn't require allocating new memory. This can be a performance improvement if you are going to hold on to multiple pointers into the structure.
We'll start with the zipper for lists.
data U a = U [a] a [a]
The corresponding graph holds references to the nodes to the left and right, if they exist.
data UGraph a = UGraph {
_left :: Maybe (UGraph a),
_here :: a,
_right :: Maybe (UGraph a)
}
Any instances of this structure should obey the following laws, which say that going one direction and then back the other brings you back to where you started.
_right >=> _left == \x > (_right >=> const (return x)) x
_left >=> _right == \x > (_left >=> const (return x)) x
The UGraph
data type doesn't enforce this, so it would be wise to put it in a module and not export the UGraph
constructor.
To convert a zipper to a graph we start in the middle and work our way out both sides. We tie recursive knots between the already built portion of the graph and the parts of the graph that haven't already been built.
toUGraph :: U a > UGraph a
toUGraph (U ls h rs) = g
where
g = UGraph (build ugraph' g ls) h (build UGraph g rs)
ugraph' r h l = UGraph l h r
build _ _ [] = Nothing
build f prev (here:next) = Just g
where
g = f (Just prev) here (build f g next)
Combined with my other answer, you can build a graph of the visible portions of your U Int
with
tieKnot :: U Int > UGraph [[Int]]
tieKnot = toUGraph . extend limitTo5x5
Two dimensions
Ultimately you want to build a 2d field. Building a graph like we did for the one dimensional list zipper in two dimensions is much trickier, and in general will require forcing O(n^2)
memory to traverse arbitrary paths of length n
.
You plan on using the twodimensional list zipper Dan Piponi described, so we'll reproduce it here.
data U2 a = U2 (U (U a))
We might be tempted to make a graph for U2
that's a straight up analog
data U2Graph a = U2Graph (UGraph (UGraph a))
This has a fairly complicated structure. Instead, we're going to do something much simpler. A node of the graph corresponding to U2
will hold references to adjacent nodes in each of the four cardinal directions, if those nodes exist.
data U2Graph a = U2Graph {
_down2 :: Maybe (U2Graph a),
_left2 :: Maybe (U2Graph a),
_here2 :: a,
_right2 :: Maybe (U2Graph a),
_up2 :: Maybe (U2Graph a)
}
Instances of U2Graph
should obey the same bidirectional iterator laws we defined for UGraph
. Once again, the structure doesn't enforce these laws itself, so the U2Graph
constructor probably shouldn't be exposed.
_right2 >=> _left2 == \x > (_right2 >=> const (return x)) x
_left2 >=> _right2 == \x > (_left2 >=> const (return x)) x
_up2 >=> _down2 == \x > (_up2 >=> const (return x)) x
_down2 >=> _up2 == \x > (_down2 >=> const (return x)) x
Before we convert a U2 a
to a U2Graph a
, let's take a look at the structure of a U2 a
. I'm going to assign the outer list to be the leftright direction and the inner list to be the updown direction. A U2
has a spine going all the way across the data, with the focal point anywhere along the spine. Each sublist can be slid perpendicular to the spine so that it is focusing on a specific point on the sublist. A U2
in the middle of use might look like the folloing. The +
s are the outer spine, the vertical dashes 
are the inner spines, and *
is the focal point of the structure.


 
  
+++*++++++++
 


Each of the inner spines is continuous  it can't have a gap. That means that if we are considering a location off the spine, it can only have a neighbor to the left or right if the location one closer to the spine also had a neighbor on that side. This gives rise to how we will build a U2Graph
. We will build connections to the left and right along the outer spine, with recursive references back towards the focal point just like we did in toUGraph
. We will build connections up and down along the inner spines, with recursive references back towards the spine, just like we did in toUGraph
. To build the connections to the left and right from a node on an inner spine we'll move one step closer to the outer spine, move sideways at that node, and then move one step farther away from the outer spine on the adjacent inner spine.
toU2Graph :: U2 a > U2Graph a
toU2Graph (U2 (U ls (U ds h us) rs)) = g
where
g = U2Graph (build u2down g ds) (build u2left g ls) h (build u2right g rs) (build u2up g us)
build f _ [] = Nothing
build f prev (here:next) = Just g
where
g = f (Just prev) here (build f g next)
u2up d h u = U2Graph d (d >>= _left2 >>= _up2 ) h (d >>= _right2 >>= _up2 ) u
u2down u h d = U2Graph d (u >>= _left2 >>= _down2) h (u >>= _right2 >>= _down2) u
u2left r (U ds h us) l = g
where
g = U2Graph (build u2down g ds) l h r (build u2up g us)
u2right l (U ds h us) r = g
where
g = U2Graph (build u2down g ds) l h r (build u2up g us)
U2
that Dan Pipponi explains in the comments – Franky Feb 14 '15 at 17:06Comonad
instance declaration forU
look like? 2. What knot are you trying to tie, exactly? I see now that Cirdec has (probably) read your mind and come up with an answer, but these details should be in the question. – dfeuer Feb 14 '15 at 18:55Comonad
instance forZipper
s (U
is the zipper for a list) is treated everywhere like it's well known, which means its hard to find the definition for it anywhere. I see now that there's a definition in the linked comonad article from "A Neighborhood of Infinity". I reinvented theComonad
instance for zippers for my answer. The comonad instance for the zipper for a differentiable type can be derived generically. – Cirdec Feb 14 '15 at 19:05