Portability | non-portable |
---|---|

Stability | experimental |

Maintainer | Edward Kmett <ekmett@gmail.com> |

Safe Haskell | None |

This module provides internal types and functions used in the implementation
of `Control.Zipper`

. You shouldn't need to import it directly, and the
exported types can be used to break `Zipper`

invariants.

- data Jacket i a
- size :: Jacket i a -> Int
- nullLeft :: Jacket i a -> Bool
- nullRight :: Jacket i a -> Bool
- maximal :: Jacket i a -> Last i
- jacketIns :: Bazaar (Indexed i) a b t -> Jacket i a
- newtype Flow i b a = Flow {}
- jacketOuts :: Bazaar (Indexed i) a b t -> Jacket j b -> t
- jacket :: AnIndexedTraversal i s t a b -> Lens s t (Jacket i a) (Jacket j b)
- data Path i a
- offset :: Path i a -> Int
- pathsize :: Path i a -> Int
- recompress :: Path i a -> i -> a -> Jacket i a
- startl :: Path i a -> Jacket i a -> r -> (Path i a -> i -> a -> r) -> r
- startr :: Path i a -> Jacket i a -> r -> (Path i a -> i -> a -> r) -> r
- movel :: Path i a -> Jacket i a -> r -> (Path i a -> i -> a -> r) -> r
- mover :: Path i a -> Jacket i a -> r -> (Path i a -> i -> a -> r) -> r
- data Top
- data Zipper h i a = Ord i => Zipper !(Coil h i a) Int !Int !(Path i a) i a
- data a :@ i
- type family h :> p
- type :>> h a = Zipper h Int a
- type family Zipped h a
- data Coil t i a where
- focus :: IndexedLens' i (Zipper h i a) a
- zipper :: a -> Top :>> a
- focalPoint :: Zipper h i a -> i
- tooth :: Zipper h i a -> Int
- upward :: Ord j => ((h :> (s :@ j)) :> (a :@ i)) -> h :> (s :@ j)
- rightward :: MonadPlus m => (h :> (a :@ i)) -> m (h :> (a :@ i))
- leftward :: MonadPlus m => (h :> (a :@ i)) -> m (h :> (a :@ i))
- leftmost :: (a :> (b :@ i)) -> a :> (b :@ i)
- rightmost :: (a :> (b :@ i)) -> a :> (b :@ i)
- tug :: (a -> Maybe a) -> a -> a
- tugs :: (a -> Maybe a) -> Int -> a -> a
- farthest :: (a -> Maybe a) -> a -> a
- jerks :: Monad m => (a -> m a) -> Int -> a -> m a
- teeth :: (h :> (a :@ i)) -> Int
- jerkTo :: MonadPlus m => Int -> (h :> (a :@ i)) -> m (h :> (a :@ i))
- tugTo :: Int -> (h :> (a :@ i)) -> h :> (a :@ i)
- moveToward :: i -> (h :> (a :@ i)) -> h :> (a :@ i)
- moveTo :: MonadPlus m => i -> (h :> (a :@ i)) -> m (h :> (a :@ i))
- lensed :: ALens' s a -> IndexedLens' Int s a
- downward :: forall j h s a. ALens' s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :>> a
- idownward :: forall i j h s a. Ord i => AnIndexedLens' i s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :> (a :@ i)
- within :: MonadPlus m => LensLike' (Indexing (Bazaar' (Indexed Int) a)) s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :>> a)
- iwithin :: (MonadPlus m, Ord i) => AnIndexedTraversal' i s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :> (a :@ i))
- withins :: MonadPlus m => LensLike' (Indexing (Bazaar' (Indexed Int) a)) s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :>> a)
- iwithins :: (MonadPlus m, Ord i) => AnIndexedTraversal' i s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :> (a :@ i))
- fromWithin :: LensLike' (Indexing (Bazaar' (Indexed Int) a)) s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :>> a
- ifromWithin :: Ord i => AnIndexedTraversal' i s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :> (a :@ i)
- class Zipping h a where
- rezip :: Zipping h a => (h :> (a :@ i)) -> Zipped h a
- focusedContext :: (Indexable i p, Zipping h a) => (h :> (a :@ i)) -> Pretext p a a (Zipped h a)
- data Tape h i a where
- saveTape :: Zipper h i a -> Tape h i a
- restoreTape :: MonadPlus m => Tape h i a -> Zipped h a -> m (Zipper h i a)
- restoreNearTape :: MonadPlus m => Tape h i a -> Zipped h a -> m (Zipper h i a)
- unsafelyRestoreTape :: Tape h i a -> Zipped h a -> Zipper h i a
- peel :: Coil h i a -> Track h i a
- data Track t i a where
- restoreTrack :: MonadPlus m => Track h i a -> Zipped h a -> m (Zipper h i a)
- restoreNearTrack :: MonadPlus m => Track h i a -> Zipped h a -> m (Zipper h i a)
- unsafelyRestoreTrack :: Track h i a -> Zipped h a -> Zipper h i a

# Documentation

`>>>`

`:set -XNoOverloadedStrings`

`>>>`

`import Control.Lens`

`>>>`

`import Data.Char`

# Jacket

A `Jacket`

is used to store the contents of a `Traversal`

in a way
that we do not have to re-asocciate the elements. This enables us to
more gracefully deal with infinite traversals.

FunctorWithIndex i (Jacket i) | |

FoldableWithIndex i (Jacket i) | |

TraversableWithIndex i (Jacket i) | |

Functor (Jacket i) | |

Foldable (Jacket i) | |

Traversable (Jacket i) | |

(Show i, Show a) => Show (Jacket i a) | |

Monoid (Jacket i a) | This is an illegal |

maximal :: Jacket i a -> Last iSource

This is used to extract the maximal key from a `Jacket`

. This is used by `moveTo`

and `moveToward`

to
seek specific keys, borrowing the asympotic guarantees of the original structure in many cases!

# Flow

Once we've updated a `Zipper`

we need to put the values back into the original
shape. `Flow`

is an illegal `Applicative`

that is used to put the values back.

Functor (Flow i b) | |

Applicative (Flow i b) | This is an illegal |

Apply (Flow i b) |

jacketOuts :: Bazaar (Indexed i) a b t -> Jacket j b -> tSource

# Paths

# Recursion

startl :: Path i a -> Jacket i a -> r -> (Path i a -> i -> a -> r) -> rSource

Walk down the tree to the leftmost child.

startr :: Path i a -> Jacket i a -> r -> (Path i a -> i -> a -> r) -> rSource

Walk down the tree to the rightmost child.

# Zippers

This is the type of a `Zipper`

. It visually resembles a "breadcrumb trail" as
used in website navigation. Each breadcrumb in the trail represents a level you
can move up to.

This type operator associates to the left, so you can use a type like

`Top`

`:>>`

(`String`

,`Double`

)`:>>`

`String`

`:>>`

`Char`

to represent a `Zipper`

from `(`

down to `String`

,`Double`

)`Char`

that has an intermediate
crumb for the `String`

containing the `Char`

.

You can construct a `Zipper`

into *any* data structure with `zipper`

.

You can repackage up the contents of a `Zipper`

with `rezip`

.

`>>>`

42`rezip $ zipper 42`

The combinators in this module provide lot of things you can do to the
`Zipper`

while you have it open.

Note that a value of type `h `

doesn't actually contain a value
of type `:>`

s `:>`

a`h `

-- as we descend into a level, the previous level is
unpacked and stored in `:>`

s`Coil`

form. Only one value of type `_ `

exists
at any particular time for any particular `:>`

_`Zipper`

.

type :>> h a = Zipper h Int aSource

Many zippers are indexed by Int keys. This type alias is convenient for reducing syntactic noise for talking about these boring indices.

focalPoint :: Zipper h i a -> iSource

Return the index of the focus.

tooth :: Zipper h i a -> IntSource

Return the index into the current `Traversal`

within the current level of the `Zipper`

.

`jerkTo`

(`tooth`

l) l =`Just`

Mnemonically, zippers have a number of `teeth`

within each level. This is which `tooth`

you are currently at.

This is based on ordinal position regardless of the underlying index type. It may be excessively expensive for a list.

`focalPoint`

may be much cheaper if you have a `Traversal`

indexed by ordinal position!

rightward :: MonadPlus m => (h :> (a :@ i)) -> m (h :> (a :@ i))Source

Jerk the `Zipper`

one `tooth`

to the `rightward`

within the current `Lens`

or `Traversal`

.

Attempts to move past the start of the current `Traversal`

(or trivially, the current `Lens`

)
will return `Nothing`

.

`>>>`

True`isNothing $ zipper "hello" & rightward`

`>>>`

'e'`zipper "hello" & fromWithin traverse & rightward <&> view focus`

`>>>`

"hullo"`zipper "hello" & fromWithin traverse & rightward <&> focus .~ 'u' <&> rezip`

`>>>`

(1,3)`rezip $ zipper (1,2) & fromWithin both & tug rightward & focus .~ 3`

tug :: (a -> Maybe a) -> a -> aSource

This allows you to safely `tug`

`leftward`

or `tug`

`rightward`

on a
`Zipper`

. This will attempt the move, and stay where it was if it fails.

The more general signature allows its use in other circumstances, however.

`tug`

f x ≡`fromMaybe`

a (f a)

`>>>`

"jello"`fmap rezip $ zipper "hello" & within traverse <&> tug leftward <&> focus .~ 'j'`

`>>>`

"hullo"`fmap rezip $ zipper "hello" & within traverse <&> tug rightward <&> focus .~ 'u'`

tugs :: (a -> Maybe a) -> Int -> a -> aSource

This allows you to safely

or `tug`

`leftward`

multiple times on a `tug`

`rightward`

`Zipper`

, moving multiple steps in a given direction
and stopping at the last place you couldn't move from. This lets you safely
move a `Zipper`

, because it will stop at either end.

`>>>`

"style"`fmap rezip $ zipper "stale" & within traverse <&> tugs rightward 2 <&> focus .~ 'y'`

`>>>`

"cart"`rezip $ zipper "want" & fromWithin traverse & tugs rightward 2 & focus .~ 'r' & tugs leftward 100 & focus .~ 'c'`

farthest :: (a -> Maybe a) -> a -> aSource

Move in a direction as far as you can go, then stop there.

This repeatedly applies a function until it returns `Nothing`

, and then returns the last answer.

`>>>`

("hella","world")`fmap rezip $ zipper ("hello","world") & downward _1 & within traverse <&> rightmost <&> focus .~ 'a'`

`>>>`

("hello","therm")`rezip $ zipper ("hello","there") & fromWithin (both.traverse) & rightmost & focus .~ 'm'`

jerks :: Monad m => (a -> m a) -> Int -> a -> m aSource

This allows for you to repeatedly pull a `Zipper`

in a given direction, failing if it falls off the end.

`>>>`

True`isNothing $ zipper "hello" & within traverse >>= jerks rightward 10`

`>>>`

"silky"`fmap rezip $ zipper "silly" & within traverse >>= jerks rightward 3 <&> focus .~ 'k'`

teeth :: (h :> (a :@ i)) -> IntSource

Returns the number of siblings at the current level in the `Zipper`

.

`teeth`

z`>=`

1

*NB:* If the current `Traversal`

targets an infinite number of elements then this may not terminate.

This is also a particularly expensive operation to perform on an unbalanced tree.

`>>>`

1`zipper ("hello","world") & teeth`

`>>>`

2`zipper ("hello","world") & fromWithin both & teeth`

`>>>`

1`zipper ("hello","world") & downward _1 & teeth`

`>>>`

5`zipper ("hello","world") & downward _1 & fromWithin traverse & teeth`

`>>>`

5`zipper ("hello","world") & fromWithin (_1.traverse) & teeth`

`>>>`

10`zipper ("hello","world") & fromWithin (both.traverse) & teeth`

jerkTo :: MonadPlus m => Int -> (h :> (a :@ i)) -> m (h :> (a :@ i))Source

Move the `Zipper`

horizontally to the element in the `n`

th position in the
current level, absolutely indexed, starting with the `farthest`

`leftward`

as `0`

.

This returns `Nothing`

if the target element doesn't exist.

`jerkTo`

n ≡`jerks`

`rightward`

n`.`

`farthest`

`leftward`

`>>>`

True`isNothing $ zipper "not working." & jerkTo 20`

tugTo :: Int -> (h :> (a :@ i)) -> h :> (a :@ i)Source

Move the `Zipper`

horizontally to the element in the `n`

th position of the
current level, absolutely indexed, starting with the `farthest`

`leftward`

as `0`

.

If the element at that position doesn't exist, then this will clamp to the range `0 `

.
`<=`

n `<`

`teeth`

`tugTo`

n ≡`tugs`

`rightward`

n`.`

`farthest`

`leftward`

`>>>`

"nut working!"`rezip $ zipper "not working." & fromWithin traverse & tugTo 100 & focus .~ '!' & tugTo 1 & focus .~ 'u'`

moveToward :: i -> (h :> (a :@ i)) -> h :> (a :@ i)Source

Move towards a particular index in the current `Traversal`

.

lensed :: ALens' s a -> IndexedLens' Int s aSource

Construct an `IndexedLens`

from `ALens`

where the index is fixed to `0`

.

idownward :: forall i j h s a. Ord i => AnIndexedLens' i s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :> (a :@ i)Source

Step down into a `IndexedLens`

. This is a constrained form of `ifromWithin`

for when you know
there is precisely one target that can never fail.

`idownward`

::`IndexedLens'`

i s a -> (h`:>`

s:@j) -> h`:>`

s:@j`:>`

a:@i

within :: MonadPlus m => LensLike' (Indexing (Bazaar' (Indexed Int) a)) s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :>> a)Source

Step down into the `leftmost`

entry of a `Traversal`

.

`within`

::`Traversal'`

s a -> (h`:>`

s:@j) ->`Maybe`

(h`:>`

s:@j`:>>`

a)`within`

::`Prism'`

s a -> (h`:>`

s:@j) ->`Maybe`

(h`:>`

s:@j`:>>`

a)`within`

::`Lens'`

s a -> (h`:>`

s:@j) ->`Maybe`

(h`:>`

s:@j`:>>`

a)`within`

::`Iso'`

s a -> (h`:>`

s:@j) ->`Maybe`

(h`:>`

s:@j`:>>`

a)

`within`

::`MonadPlus`

m =>`ATraversal'`

s a -> (h`:>`

s:@j) -> m (h`:>`

s:@j`:>>`

a)

iwithin :: (MonadPlus m, Ord i) => AnIndexedTraversal' i s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :> (a :@ i))Source

Step down into the `leftmost`

entry of an `IndexedTraversal`

.

*Note:* The index is assumed to be ordered and must increase monotonically or else you cannot (safely) `moveTo`

or `moveToward`

or use tapes.

`iwithin`

::`IndexedTraversal'`

i s a -> (h`:>`

s:@j) ->`Maybe`

(h`:>`

s:@j`:>`

a:@i)`iwithin`

::`IndexedLens'`

i s a -> (h`:>`

s:@j) ->`Maybe`

(h`:>`

s:@j`:>`

a:@i)

`iwithin`

::`MonadPlus`

m =>`ATraversal'`

s a -> (h`:>`

s:@j) -> m (h`:>`

s:@j`:>>`

a)

withins :: MonadPlus m => LensLike' (Indexing (Bazaar' (Indexed Int) a)) s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :>> a)Source

Step down into every entry of a `Traversal`

simultaneously.

`>>>`

[("hEllo","world"),("heLlo","world"),("helLo","world"),("hellO","world")]`zipper ("hello","world") & withins both >>= leftward >>= withins traverse >>= rightward <&> focus %~ toUpper <&> rezip :: [(String,String)]`

`withins`

::`Traversal'`

s a -> (h`:>`

s:@j) -> [h`:>`

s:@j`:>>`

a]`withins`

::`Lens'`

s a -> (h`:>`

s:@j) -> [h`:>`

s:@j`:>>`

a]`withins`

::`Iso'`

s a -> (h`:>`

s:@j) -> [h`:>`

s:@j`:>>`

a]

iwithins :: (MonadPlus m, Ord i) => AnIndexedTraversal' i s a -> (h :> (s :@ j)) -> m ((h :> (s :@ j)) :> (a :@ i))Source

Step down into every entry of an `IndexedTraversal`

simultaneously.

*Note:* The index is assumed to be ordered and must increase monotonically or else you cannot (safely) `moveTo`

or `moveToward`

or use tapes.

`iwithins`

::`IndexedTraversal'`

i s a -> (h`:>`

s:@j) -> [h`:>`

s:@j`:>`

a:@i]`iwithins`

::`IndexedLens'`

i s a -> (h`:>`

s:@j) -> [h`:>`

s:@j`:>`

a:@i]

fromWithin :: LensLike' (Indexing (Bazaar' (Indexed Int) a)) s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :>> aSource

Unsafely step down into a `Traversal`

that is *assumed* to be non-empty.

If this invariant is not met then this will usually result in an error!

`fromWithin`

::`Traversal'`

s a -> (h`:>`

s:@j) -> h`:>`

s:@j`:>>`

a`fromWithin`

::`Lens'`

s a -> (h`:>`

s:@j) -> h`:>`

s:@j`:>>`

a`fromWithin`

::`Iso'`

s a -> (h`:>`

s:@j) -> h`:>`

s:@j`:>>`

a

You can reason about this function as if the definition was:

`fromWithin`

l ≡`fromJust`

`.`

`within`

l

ifromWithin :: Ord i => AnIndexedTraversal' i s a -> (h :> (s :@ j)) -> (h :> (s :@ j)) :> (a :@ i)Source

Unsafey step down into an `IndexedTraversal`

that is *assumed* to be non-empty

If this invariant is not met then this will usually result in an error!

`ifromWithin`

::`IndexedTraversal'`

i s a -> (h`:>`

s:@j) -> h`:>`

s:@j`:>`

a:@i`ifromWithin`

::`IndexedLens'`

i s a -> (h`:>`

s:@j) -> h`:>`

s:@j`:>`

a:@i

You can reason about this function as if the definition was:

`fromWithin`

l ≡`fromJust`

`.`

`within`

l

rezip :: Zipping h a => (h :> (a :@ i)) -> Zipped h aSource

Close something back up that you opened as a `Zipper`

.

focusedContext :: (Indexable i p, Zipping h a) => (h :> (a :@ i)) -> Pretext p a a (Zipped h a)Source

# Tapes

saveTape :: Zipper h i a -> Tape h i aSource

Save the current path as as a `Tape`

we can play back later.

restoreTape :: MonadPlus m => Tape h i a -> Zipped h a -> m (Zipper h i a)Source

Restore ourselves to a previously recorded position precisely.

If the position does not exist, then fail.

unsafelyRestoreTape :: Tape h i a -> Zipped h a -> Zipper h i aSource

Restore ourselves to a previously recorded position.

This *assumes* that nothing has been done in the meantime to affect the existence of anything on the entire path.

Motions `leftward`

or `rightward`

are clamped, but all traversals included on the `Tape`

are assumed to be non-empty.

Violate these assumptions at your own risk!

# Tracks

peel :: Coil h i a -> Track h i aSource

This is used to peel off the path information from a `Coil`

for use when saving the current path for later replay.

restoreTrack :: MonadPlus m => Track h i a -> Zipped h a -> m (Zipper h i a)Source

Restore ourselves to a previously recorded position precisely.

If the position does not exist, then fail.

unsafelyRestoreTrack :: Track h i a -> Zipped h a -> Zipper h i aSource

Restore ourselves to a previously recorded position.

This *assumes* that nothing has been done in the meantime to affect the existence of anything on the entire `Path`

.

Motions `leftward`

or `rightward`

are clamped, but all traversals included on the `Tape`

are assumed to be non-empty.

Violate these assumptions at your own risk!