Partibles for composing monads: Difference between revisions

From HaskellWiki
No edit summary
mNo edit summary
 
(33 intermediate revisions by 2 users not shown)
Line 1: Line 1:
[[Category:Proposals]]
<div style="border-left:1px solid lightgray; padding: 1em" alt="blockquote">
 
Having praised monads to the hilt, let me level one criticism. Monads tend to be an all-or-nothing proposition. If you discover that you need interaction deep within your program, you must rewrite that segment to use a monad. If you discover that you need two sorts of interaction, you tend to make a single monad support both sorts. It seems to me that instead we should be able to move smoothly from no monads (no interactions) to one monad (a single form of interaction) to many monads (several independent forms of interactions). How to achieve this remains a challenge for the future.
 
<blockquote><tt>Having praised monads to the hilt, let me level one criticism. Monads tend to be<br>an all-or-nothing proposition. If you discover that you need interaction deep within<br>your program, you must rewrite that segment to use a monad. If you discover<br>that you need two sorts of interaction, you tend to make a single monad support<br>both sorts. It seems to me that instead we should be able to move smoothly from<br>no monads (no interactions) to one monad (a single form of interaction) to many<br>monads (several independent forms of interactions). How to achieve this remains a<br>challenge for the future.</tt></blockquote>


* [https://wiki.ittc.ku.edu/lambda/images/3/3b/Wadler_-_How_to_Declare_an_Imperative.pdf ''How to Declare an Imperative''], Philip Wadler.
<small>[https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.91.3579&rep=rep1&type=pdf How to Declare an Imperative], Philip Wadler.</small>
</div>


Some initial definitions:
<sub> </sub>
Assuming the [[Partible|partible]] types being used are appropriately defined, then:


<haskell>
<haskell>
        class Partible a where
type M p a  =  p -> a
            part  :: a -> (a, a)
            parts :: a -> [a]
 
            -- Minimal complete definition: part or parts
            part u  = case parts u of u1:u2:_ -> (u1, u2)
            parts u = case part u of (u1, u2) -> u1 : parts u2
 
        instance Partible a => Monad ((->) a) where
            return x = \ u -> part u `seq` x
            m >>= k = \ u -> case part u of (u1, u2) -> (\ x -> x `seq` k x u2) (m u1)
            m >> w  = \ u -> case part u of (u1, u2) -> m u1 `seq` w u2
            fail s  = \ u -> part u `seq` error s
 
        data OI -- abstract
        primPartOI :: OI -> (OI, OI)  -- primitive
        -- type IO a = OI -> a
 
        instance Partible OI where part = primPartOI
 
 
        -- more primitives
        primGetChar :: OI -> Char
        primPutChar :: Char -> OI -> ()
 
        -- copy 'n' paste from Wadler's paper
        type Dialogue = [Response] -> [Request]
        data Request  = Getq | Putq Char
        data Response = Getp Char | Putp
 
 
        respond :: Request -> OI -> Response
        respond Getq    = primGetChar >>= return . Getp
        respond (Putq c) = primPutChar c >> return Putp
 
        runDialogue :: Dialogue -> OI -> ()
        runDialogue d =
            \ u -> foldr seq () (fix (\ l -> zipWith respond (d l) (parts u)))
 
        -- fix f = f (fix f)
 
 
        instance Partible a => MonadFix ((->) a) where
            mfix m = \ u -> fix (\ x -> m x u)
 
 
        -- to be made into an abstract data type...
        data Fresh a = Fresh (OI -> a) OI
 
        afresh :: (OI -> a) -> OI -> Fresh a
        afresh g u = Fresh g u
 
        instance Partible (Fresh a) where
            part (Fresh g u) = case part u of (u1, u2) -> (Fresh g u1, Fresh g u2)
 
        fresh :: Fresh a -> [a]
        fresh u = [ g v | Fresh g v <- parts u ]
 
        instance Functor Fresh where
            fmap f (Fresh g u) = Fresh (f . g) u
 
 
        -- one more primitive
        primGensym :: OI -> Int
 
        supplyInts :: OI -> Fresh Int
        supplyInts = \ u -> afresh primGensym u
 
 
        instance (Partible a, Partible b) => Partible (a, b) where
            part (u, v) = case (part u, part v) of
                            ((u1, u2), (v1, v2)) -> ((u1, v1), (u2, v2))
 
        instance (Partible a, Partible b) => Partible (Either a b) where
            part (Left u)  = case part u of (u1, u2) -> (Left u1, Left u2)
            part (Right v) = case part v of (v1, v2) -> (Right v1, Right v2)


        data Some a = Only a | More a (Some a)
unit        :: Partible p =>    a -> M p a
unit x      =  \ u -> let !_ = part u in x


        instance Partible a => Partible (Some a) where
bind        :: Partible p =>    M p a -> (a -> M p b) -> M p b
            part (Only u)    = case part u of
m `bind` k  = \ u -> let !(u1, u2) = part u in
                                (u1, u2) -> (Only u1, Only u2)
                      let !x = m u1 in
            part (More u us) = case part u of
                      let !y = k x u2 in
                                (u1, u2) ->
                      y
                                  case part us of
                                    (us1, us2) -> (More u1 us1, More u2 us2)


        type M1 a = (Fresh Int, OI) -> a
next        :: Partible p =>    M p a -> M p b -> M p b
        type M2 a = Either (Fresh a) OI -> a
m `next` w  = \ u -> let !(u1, u2) = part u in
        type M3 a = Some (Either (Fresh Char) (Fresh Int)) -> a
                      let !x = m u1 in
        -- ...whatever suits the purpose
                      let !y = w u2 in
                      y


 
fail        :: Partible p =>     String -> M p a
        class (Monad m1, Monad m2) => MonadCommute m1 m2 where
fail s      = \ u -> let !_ = part u in error s
            mcommute :: m1 (m2 a) -> m2 (m1 a)
 
        instance (Partible a, Partible b) => MonadCommute ((->) a) ((->) b) where
            mcommute m = \ v u -> m u v
</haskell>
</haskell>


 
Furthermore:
So what qualifies as being partible?
 
A partible value can be used only once to generate new values that can be used for the same purpose. Think of a very large sheet of paper - new sheets can be made from it, other sheets can be made from those, etc, with the original sheet no longer in existence. Unlike paper sheets, partible values are intended to have no limits e.g. the result of applying <code>supplyInts</code>.
 
If its violation causes a runtime error, the use-once property of partible values can help to maintain referential transparency in the effectful segments of a program; using another example from Wadler's paper minimally rewritten in Haskell syntax using <code>OI</code> values:


<haskell>
<haskell>
        \ u -> let
mfix        :: Partible p =>    (a -> M p a) -> M p a
                  x = (primPutChar 'h' u `seq` primPutChar 'a' u)
mfix m      =  \ u -> yet (\ x -> m x u)
                in x `seq` x
</haskell>
 


would trigger the error; the working version being:
mcommute    :: (Partible p1, Partible p2) => M p1 (M p2 a) -> M p2 (M p1 a)
mcommute g  =  \ v u -> g u v


<haskell>
mcommute'  :: (Monad m, Partible p) => m (M p a) -> M p (m a)
                let
mcommute' m =  \ v -> liftM ($ v) m
                  x = (\ v -> case part v of
                                (v1, v2) -> primPutChar 'h' v1 `seq` primPutChar 'a' v2)
                in
                  \ u -> case part u of
                          (u1, u2) -> x u1 `seq` x u2
</haskell>
</haskell>


where:


...rather tedious, if it weren't for Haskell's standard monadic methods:
:{|
 
|<haskell>
<haskell>
yet  :: (a -> a) -> a
                let
yet f =  f (yet f)
                  x = primPutChar 'h' >> primPutChar 'a'
                in x >> x
</haskell>
</haskell>
|}


Using partible types to define monadic ones can enable an intermediate approach to the use of effects, in contrast to the ''all-or-nothing proposition'' of only using the monadic interface. In addition, if the definitions for such monadic types are ''visible'' (e.g. as type synonyms), this may also allow the manipulation of control in ways beyond what the monadic interface provides.


Higher-order functions allows the manipulation of control e.g. <code>Prelude.until</code> in Haskell. As the definition of <code>runDialogue</code> shows, monadic types with visible definitions based on types of partible values may also allow the manipulation of control in ways beyond what the standard monadic methods provide.
=== Composing arrows ===


Partible types can also be used to define [[Arrow|arrow]] types:


Other references and articles:
<haskell>
type A p b c =  (p -> b) -> (p -> c)


* [https://maartenfokkinga.github.io/utwente/mmf2001c.pdf ''An alternative approach to I/O''], Maarten Fokkinga and Jan Kuper.
arr          :: Partible p      => (b -> c) -> A p b c
arr f        =  \ c' u -> f $! c' u


* ''Functional Pearl: On generating unique names'', Lennart Augustsson, Mikael Rittri and Dan Synek.


* [http://www.alsonkemp.com/haskell/reflections-on-leaving-haskell ''Reflections on leaving Haskell''], Alson Kemp.
both        :: Partible p      => A p b c -> A p b' c' -> A p (b, b') (c, c')
f' `both` g' =  \ c' u -> let !(u1:u2:u3:_) = parts u in
                          let !(x, x')      = c' u1 in
                          let !y            = f' (unit x) u2 in
                          let !y'           = g' (unit x') u3 in
                          (y, y')                         
                where
                  unit x u = let !_ = part u in x
</haskell>


* [https://paul.bone.id.au/pub/pbone-2016-haskell-sucks.pdf ''Haskell Sucks!''], Paul Bone.
(...though most will probably opt for the convenience of the associated [https://hackage.haskell.org/package/base-4.15.0.0/docs/src/Control-Arrow.html#Kleisli <code>Kleisli</code>] type).


* ''Non-Imperative Functional Programming'' [https://www.slideshare.net/nobsun/lazy-io :], Nobuo Yamashita.
=== Composing comonads ===


* [http://www.f.waseda.jp/terauchi/papers/toplas-witness.pdf ''Witnessing Side Effects''], Tachio Terauchi and Alex Aiken.
[[Comonad|Comonadic]] types can be defined using partible types as well:


* [https://www.cs.bham.ac.uk/~udr/papers/assign.pdf ''Assignments for Applicative Languages''], Vipin Swarup, Uday S. Reddy and Evan Ireland.
<haskell>
type C p a      =  (a, p)


* [https://www.cs.ru.nl/barendregt60/essays/hartel_vree/art10_hartel_vree.pdf ''Lambda Calculus For Engineers''], Pieter H. Hartel and Willem G. Vree.
extract          :: Partible p =>    C p a -> a
extract (x, u)  =  let !_ = part u in x


* [http://h2.jaguarpaw.co.uk/posts/mtl-style-for-free ''MTL style for free''], Tom Ellis.
duplicate        :: Partible p =>    C p a -> C p (C p a)
 
duplicate (x, u) =  let !(u1, u2) = part u in
* [https://accu.org/index.php/journals/2199 ''On Zero-Side-Effect Interactive Programming, Actors, and FSMs''], Sergey Ignatchenko.
                    ((x, u1), u2)
 
* ''Functional I/O Using System Tokens'', Lennart Augustsson.
 
* ''I/O Trees and Interactive Lazy Functional Programming'', Samuel A. Rebelsky.
 
* ''Arborescent data structures and lazy evaluation: A new approach to numerical problems'', Manuel Carcenac.


extend          :: Partible p =>    (C p a -> b) -> C p a -> C p b
extend h (x, u)  =  let !(u1, u2) = part u in
                    let !y        = h (x, u1) in
                    (y, u2)
</haskell>
----
See also:
See also:


* [[Sequential ordering of evaluation]]
* [[Plainly partible]]
* [[Partible laws]]
* [[Burton-style nondeterminism]]
* [[MonadFix]]
* [[Prelude extensions]]
* [https://downloads.haskell.org/~ghc/7.8.4/docs/html/users_guide/bang-patterns.html Bang patterns]
* [https://gitlab.haskell.org/ghc/ghc/-/issues/19809 GHC ticket 19809: Overhaul ST using ''pseudodatata'']


* [[Monomorphism by annotation of type variables]]


[[User:Atravers|Atravers]] 04:31, 10 April 2018 (UTC)


Thank you to those who commented on early drafts of this document.
[[Category:Arrow]]
 
[[Category:Monad]]
[[User:Atravers|Atravers]] 04:31, 10 April 2018 (UTC)
[[Category:Proposals]]

Latest revision as of 08:14, 12 June 2023

Having praised monads to the hilt, let me level one criticism. Monads tend to be an all-or-nothing proposition. If you discover that you need interaction deep within your program, you must rewrite that segment to use a monad. If you discover that you need two sorts of interaction, you tend to make a single monad support both sorts. It seems to me that instead we should be able to move smoothly from no monads (no interactions) to one monad (a single form of interaction) to many monads (several independent forms of interactions). How to achieve this remains a challenge for the future.

How to Declare an Imperative, Philip Wadler.

Assuming the partible types being used are appropriately defined, then: 

type M p a  =  p -> a

unit        :: Partible p =>     a -> M p a
unit x      =  \ u -> let !_ = part u in x

bind        :: Partible p =>     M p a -> (a -> M p b) -> M p b
m `bind` k  =  \ u -> let !(u1, u2) = part u in
                      let !x = m u1 in
                      let !y = k x u2 in
                      y 

next        :: Partible p =>     M p a -> M p b -> M p b
m `next` w  =  \ u -> let !(u1, u2) = part u in
                      let !x = m u1 in
                      let !y = w u2 in
                      y

fail        :: Partible p =>     String -> M p a
fail s      =  \ u -> let !_ = part u in error s

Furthermore: 

mfix        :: Partible p =>     (a -> M p a) -> M p a
mfix m      =  \ u -> yet (\ x -> m x u)

mcommute    :: (Partible p1, Partible p2) => M p1 (M p2 a) -> M p2 (M p1 a)
mcommute g  =  \ v u -> g u v

mcommute'   :: (Monad m, Partible p) => m (M p a) -> M p (m a)
mcommute' m =  \ v -> liftM ($ v) m

where: 

yet   :: (a -> a) -> a
yet f =  f (yet f)

Using partible types to define monadic ones can enable an intermediate approach to the use of effects, in contrast to the all-or-nothing proposition of only using the monadic interface. In addition, if the definitions for such monadic types are visible (e.g. as type synonyms), this may also allow the manipulation of control in ways beyond what the monadic interface provides.

Composing arrows

Partible types can also be used to define arrow types: 

type A p b c =  (p -> b) -> (p -> c)

arr          :: Partible p      => (b -> c) -> A p b c
arr f        =  \ c' u -> f $! c' u


both         :: Partible p      => A p b c -> A p b' c' -> A p (b, b') (c, c')
f' `both` g' =  \ c' u -> let !(u1:u2:u3:_) = parts u in
                          let !(x, x')      = c' u1 in
                          let !y            = f' (unit x) u2 in
                          let !y'           = g' (unit x') u3 in
                          (y, y')                           
                where
                  unit x u = let !_ = part u in x

(...though most will probably opt for the convenience of the associated Kleisli type).

Composing comonads

Comonadic types can be defined using partible types as well: 

type C p a       =  (a, p)

extract          :: Partible p =>    C p a -> a
extract (x, u)   =  let !_ = part u in x

duplicate        :: Partible p =>    C p a -> C p (C p a)
duplicate (x, u) =  let !(u1, u2) = part u in
                    ((x, u1), u2)

extend           :: Partible p =>    (C p a -> b) -> C p a -> C p b
extend h (x, u)  =  let !(u1, u2) = part u in
                    let !y        = h (x, u1) in
                    (y, u2)

See also:


Atravers 04:31, 10 April 2018 (UTC)

Retrieved from "https://wiki.haskell.org/index.php?title=Partibles_for_composing_monads&oldid=66339"