Difference between revisions of "Arrow tutorial"

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{| border=0 align=right cellpadding=4 cellspacing=0
Tutorial on Arrows, content to be filled in by Tim :)
  
  +
|<haskell>
  +
{-# LANGUAGE Arrows #-}
  +
module ArrowFun where
  +
  +
import Control.Arrow
  +
import Control.Category
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import Prelude hiding (id,(.))
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</haskell>
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|}
  +
  +
== The <code>Arrow</code> class ==
  +
A value of type <code>(Arrow a) => a b c</code> (commonly referred to as just an <i>arrow</i>) represents a process that takes as input a value of type <code>b</code> and outputs a value of type <code>c</code>.
  +
  +
The class includes the following methods:
  +
  +
* <code>arr</code> builds an arrow value out of a function:
  +
  +
:<haskell>
  +
arr :: (Arrow a) => (b -> c) -> a b c
  +
</haskell>
  +
  +
* <code>(>>>)</code> composes two arrow values to form a new one by "chaining" them together, one after another:
  +
  +
:<haskell>
  +
(>>>) :: (Arrow a) => a b c -> a c d -> a b d
  +
</haskell>
  +
  +
* <code>first</code> and <code>second</code> make a new arrow value out of an existing one. They perform a transformation (given by their argument) on either the first or the second item of a pair:
  +
  +
:<haskell>
  +
first :: (Arrow a) => a b c -> a (b, d) (c, d)
  +
second :: (Arrow a) => a b c -> a (d, b) (d, c)
  +
</haskell>
  +
  +
:<code>first</code> and <code>second</code> may seem pretty strange at first, but they'll make sense in a few minutes.
  +
  +
== A simple arrow type ==
  +
Let's define a really simple arrow type as an example, based on a function mapping an input to an output:
  +
  +
<haskell>
  +
newtype SimpleFunc a b = SimpleFunc {
  +
runF :: (a -> b)
  +
}
  +
  +
instance Arrow SimpleFunc where
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arr f = SimpleFunc f
  +
first (SimpleFunc f) = SimpleFunc (mapFst f)
  +
where mapFst g (a,b) = (g a, b)
  +
second (SimpleFunc f) = SimpleFunc (mapSnd f)
  +
where mapSnd g (a,b) = (a, g b)
  +
  +
instance Category SimpleFunc where
  +
(SimpleFunc g) . (SimpleFunc f) = SimpleFunc (g . f)
  +
id = arr id
  +
</haskell>
  +
  +
== Some other arrow operations ==
  +
Now let's define some operations that are generic to all arrow types:
  +
  +
* <code>split</code> is an arrow value that splits a single value into a pair of duplicate values:
  +
  +
<haskell>
  +
split :: (Arrow a) => a b (b, b)
  +
split = arr (\x -> (x,x))
  +
</haskell>
  +
  +
* <code>unsplit</code> is an arrow value that takes a pair of values and combines them to return a single value:
  +
  +
<haskell>
  +
unsplit :: (Arrow a) => (b -> c -> d) -> a (b, c) d
  +
unsplit = arr . uncurry
  +
-- = \op -> arr (\(x,y) -> x `op` y)
  +
</haskell>
  +
  +
* <code>(***)</code> combines two arrow values by running them on a pair (the first arrow value on the first component of the pair; the second arrow value on the second component of the pair):
  +
  +
<haskell>
  +
f *** g = first f >>> second g
  +
</haskell>
  +
  +
* <code>(&&&)</code> combines two arrow values by running them with the same input:
  +
  +
<haskell>
  +
f &&& g = split >>> first f >>> second g
  +
-- = split >>> f *** g
  +
</haskell>
  +
  +
* <code>liftA2</code> makes a new arrow value that combines the output from two other arrow values using a binary operation. It works by splitting a value and operating on both halves and then combining the result:
  +
  +
<haskell>
  +
liftA2 :: (Arrow a) => (b -> c -> d) -> a e b -> a e c -> a e d
  +
liftA2 op f g = split >>> first f >>> second g >>> unsplit op
  +
-- = f &&& g >>> unsplit op
  +
</haskell>
  +
  +
== An example ==
  +
Now let's build something using our simple arrow definition and some of the tools we've just created. We start with two simple arrow values, <code>f</code> and <code>g</code>:
  +
  +
* <code>f</code> halves its input:
  +
  +
<haskell>
  +
f :: SimpleFunc Int Int
  +
f = arr (`div` 2)
  +
</haskell>
  +
  +
* and <code>g</code> triples its input and adds one:
  +
  +
<haskell>
  +
g :: SimpleFunc Int Int
  +
g = arr (\x -> x*3 + 1)
  +
</haskell>
  +
  +
We can combine these together using <code>liftA2</code>:
  +
  +
<haskell>
  +
h :: SimpleFunc Int Int
  +
h = liftA2 (+) f g
  +
  +
hOutput :: Int
  +
hOutput = runF h 8
  +
</haskell>
  +
  +
What is <code>h</code>? How does it work?
  +
  +
The process defined by <code>h</code> is <code>split >>> first f >>> second g >>> unsplit (+)</code>. Let's work through an application of <code>h</code> to the value <code>8</code>:
  +
  +
:{|
  +
|<code>8</code>
  +
|→
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|<code>(8, 8)</code>
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|<code>split</code>
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|-
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|<code>(8, 8)</code>
  +
|→
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|<code>(4, 8)</code>
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|<code>first f</code> ⇔ <code>x `div` 2</code>, where <code>x</code> is the first component of the pair
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|-
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|<code>(4, 8)</code>
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|→
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|<code>(4, 25)</code>
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|<code>second g</code> ⇔ <code>3*y + 1</code>, where <code>y</code> is the second component of the pair
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|-
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|<code>(4, 25)</code>
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|→
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|<code>29</code>
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|apply <code>(+)</code> to the components of the pair
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|}
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:::{|
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|
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f
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↗ ↘
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8 → (split) (unsplit (+)) → 29
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↘ ↗
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g
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|}
  +
  +
We can see that <code>h</code> is a new arrow value that, when applied to <code>8</code>, will apply both <code>f</code> and <code>g</code> to <code>8</code>, then adds their results.
  +
  +
A lot of juggling occurred to get the plumbing right since <code>h</code> wasn't defined as a linear combination of arrow values. GHC has a syntactic notation that simplifies this in a similar way to how
  +
<code>do</code>-notation simplifies monadic computations. The <code>h</code> function can then be defined as:
  +
  +
<haskell>
  +
h' :: SimpleFunc Int Int
  +
h' = proc x -> do
  +
fx <- f -< x
  +
gx <- g -< x
  +
returnA -< (fx + gx)
  +
  +
hOutput' :: Int
  +
hOutput' = runF h' 8
  +
</haskell>
  +
  +
== <code>Kleisli</code> arrow values ==
  +
Let's move on to something a little fancier now: Kleisli arrows.
  +
  +
A Kleisli arrow type (<code>Kleisli m a b</code>) corresponds to the type <code>(a -> m b)</code>, where <code>m</code> is a monadic type. It's defined in <code>Control.Arrows</code> similarly to our <code>SimpleFunc</code>:
  +
  +
<haskell>
  +
newtype Kleisli m a b = Kleisli {
  +
runKleisli :: (a -> m b)
  +
}
  +
</haskell>
  +
  +
It comes complete with its own definitions for <code>arr</code>, <code>(>>>)</code>, <code>first</code>, and <code>second</code>. This means that all multi-value functions (i.e of type <code>a -> [b]</code>) are already defined as Kleisli arrows (because the list type <code>[]</code> is monadic)! <code>(>>>)</code> performs composition, keeping track of all the multiple results. <code>split</code>, <code>(&&&)</code> and <code>(***)</code> are all defined as before. For example:
  +
  +
<haskell>
  +
plusminus, double, h2 :: Kleisli [] Int Int
  +
plusminus = Kleisli (\x -> [x, -x])
  +
double = arr (* 2)
  +
h2 = liftA2 (+) plusminus double
  +
  +
h2Output :: [Int]
  +
h2Output = runKleisli h2 8
  +
</haskell>
  +
  +
== A Teaser ==
  +
Finally, here is a little teaser. There is an arrow function called <code>returnA</code> which returns an identity arrow. There is an <code>ArrowPlus</code> class that includes a <code>zeroArrow</code> (which for the list type is an arrow value that always returns the empty list) and a <code>(<+>)</code> operator (which takes the results from two arrow values and concatenates them). We can build up some pretty interesting string transformations (multi-valued functions of type <code>String -> [String]</code>) using Kleisli arrow values:
  +
  +
<haskell>
  +
main :: IO ()
  +
main = do
  +
let
  +
prepend x = arr (x ++)
  +
append x = arr (++ x)
  +
withId t = returnA <+> t
  +
xform = (withId $ prepend "<") >>>
  +
(withId $ append ">") >>>
  +
(withId $ ((prepend "!") >>> (append "!")))
  +
xs = ["test", "foobar"] >>= (runKleisli xform)
  +
mapM_ putStrLn xs
  +
</haskell>
  +
  +
An important observation here is that
  +
f >>> g
  +
  +
is a multi-valued composition <code>(g . f)</code>, and
  +
:{|
  +
|
  +
|<code>(withId f) >>> (withId g)</code>
  +
|-
  +
|=
  +
|<code>(returnA <+> f) >>> (returnA <+> g)</code>
  +
|-
  +
|=
  +
|<code>((arr id) <+> f) >>> ((arr id) <+> g)</code>
  +
|}
  +
  +
which, when applied to an input <code>x</code>, returns all values:
  +
:{|
  +
|
  +
|<code>((id . id) x) ++ ((id . f) x) ++ ((id . g) x) ++ ((g . f) x)</code>
  +
|-
  +
| =
  +
|<code>x ++ (f x) ++ (g x) ++ ((g . f) x)</code>
  +
|}
  +
  +
which are all permutations of using the arrow values <code>f</code> and <code>g</code>.
  +
  +
== Tutorial Meta ==
  +
The wiki file source is literate Haskell. Save the source in a file called <code>ArrowFun.lhs</code> to compile it (or run in GHCi).
  +
  +
The code is adapted to GHC 6.10.1; use [http://www.haskell.org/haskellwiki/?title=Arrow_tutorial&oldid=15443] for older versions of GHC and other Haskell implementations.
  +
  +
* Original version - Nov 19, 2006, Tim Newsham.
  +
  +
[[Category:Tutorials]]
  +
[[Category:Arrow]]

Latest revision as of 00:43, 16 May 2024

{-# LANGUAGE Arrows #-}
module ArrowFun where

import Control.Arrow
import Control.Category
import Prelude hiding (id,(.))

The Arrow class

A value of type (Arrow a) => a b c (commonly referred to as just an arrow) represents a process that takes as input a value of type b and outputs a value of type c.

The class includes the following methods:

  • arr builds an arrow value out of a function:
arr :: (Arrow a) => (b -> c) -> a b c
  • (>>>) composes two arrow values to form a new one by "chaining" them together, one after another:
(>>>) :: (Arrow a) => a b c -> a c d -> a b d
  • first and second make a new arrow value out of an existing one. They perform a transformation (given by their argument) on either the first or the second item of a pair:
first  :: (Arrow a) => a b c -> a (b, d) (c, d)
second :: (Arrow a) => a b c -> a (d, b) (d, c)
first and second may seem pretty strange at first, but they'll make sense in a few minutes.

A simple arrow type

Let's define a really simple arrow type as an example, based on a function mapping an input to an output: 

newtype SimpleFunc a b = SimpleFunc {
  runF :: (a -> b)
}

instance Arrow SimpleFunc where
  arr f = SimpleFunc f
  first (SimpleFunc f) = SimpleFunc (mapFst f)
    where mapFst g (a,b) = (g a, b)
  second (SimpleFunc f) = SimpleFunc (mapSnd f)
    where mapSnd g (a,b) = (a, g b)

instance Category SimpleFunc where
  (SimpleFunc g) . (SimpleFunc f) = SimpleFunc (g . f)
  id = arr id

Some other arrow operations

Now let's define some operations that are generic to all arrow types:

  • split is an arrow value that splits a single value into a pair of duplicate values:
split :: (Arrow a) => a b (b, b)
split = arr (\x -> (x,x))
  • unsplit is an arrow value that takes a pair of values and combines them to return a single value:
unsplit :: (Arrow a) => (b -> c -> d) -> a (b, c) d
unsplit = arr . uncurry       
     -- = \op -> arr (\(x,y) -> x `op` y)
  • (***) combines two arrow values by running them on a pair (the first arrow value on the first component of the pair; the second arrow value on the second component of the pair):
f *** g = first f >>> second g
  • (&&&) combines two arrow values by running them with the same input:
f &&& g = split >>> first f >>> second g
     -- = split >>> f *** g
  • liftA2 makes a new arrow value that combines the output from two other arrow values using a binary operation. It works by splitting a value and operating on both halves and then combining the result:
liftA2 :: (Arrow a) => (b -> c -> d) -> a e b -> a e c -> a e d
liftA2 op f g = split >>> first f >>> second g >>> unsplit op
           -- = f &&& g >>> unsplit op

An example

Now let's build something using our simple arrow definition and some of the tools we've just created. We start with two simple arrow values, f and g:

  • f halves its input:
f :: SimpleFunc Int Int
f = arr (`div` 2)
  • and g triples its input and adds one:
g :: SimpleFunc Int Int
g = arr (\x -> x*3 + 1)

We can combine these together using liftA2: 

h :: SimpleFunc Int Int
h = liftA2 (+) f g

hOutput :: Int
hOutput = runF h 8

What is h? How does it work?

The process defined by h is split >>> first f >>> second g >>> unsplit (+). Let's work through an application of h to the value 8:

8 (8, 8) split
(8, 8) (4, 8) first fx `div` 2, where x is the first component of the pair
(4, 8) (4, 25) second g3*y + 1, where y is the second component of the pair
(4, 25) 29 apply (+) to the components of the pair 
              f
            ↗   ↘
 8 → (split)     (unsplit (+)) → 29
            ↘   ↗
              g

We can see that h is a new arrow value that, when applied to 8, will apply both f and g to 8, then adds their results.

A lot of juggling occurred to get the plumbing right since h wasn't defined as a linear combination of arrow values. GHC has a syntactic notation that simplifies this in a similar way to how do-notation simplifies monadic computations. The h function can then be defined as: 

h' :: SimpleFunc Int Int
h' = proc x -> do
       fx <- f -< x
       gx <- g -< x
       returnA -< (fx + gx)

hOutput' :: Int
hOutput' = runF h' 8

Kleisli arrow values

Let's move on to something a little fancier now: Kleisli arrows.

A Kleisli arrow type (Kleisli m a b) corresponds to the type (a -> m b), where m is a monadic type. It's defined in Control.Arrows similarly to our SimpleFunc: 

newtype Kleisli m a b = Kleisli {
  runKleisli :: (a -> m b) 
}

It comes complete with its own definitions for arr, (>>>), first, and second. This means that all multi-value functions (i.e of type a -> [b]) are already defined as Kleisli arrows (because the list type [] is monadic)! (>>>) performs composition, keeping track of all the multiple results. split, (&&&) and (***) are all defined as before. For example: 

plusminus, double, h2 :: Kleisli [] Int Int
plusminus = Kleisli (\x -> [x, -x])
double    = arr (* 2)
h2        = liftA2 (+) plusminus double 

h2Output :: [Int]
h2Output = runKleisli h2 8

A Teaser

Finally, here is a little teaser. There is an arrow function called returnA which returns an identity arrow. There is an ArrowPlus class that includes a zeroArrow (which for the list type is an arrow value that always returns the empty list) and a (<+>) operator (which takes the results from two arrow values and concatenates them). We can build up some pretty interesting string transformations (multi-valued functions of type String -> [String]) using Kleisli arrow values: 

main :: IO ()
main = do
  let
    prepend x = arr (x ++)
    append  x = arr (++ x)
    withId  t = returnA <+> t
    xform = (withId $ prepend "<") >>>
            (withId $ append ">") >>>
            (withId $ ((prepend "!") >>> (append "!")))
    xs = ["test", "foobar"] >>= (runKleisli xform)
  mapM_ putStrLn xs

An important observation here is that 

   f >>> g

is a multi-valued composition (g . f), and

(withId f) >>> (withId g)
= (returnA <+> f) >>> (returnA <+> g)
= ((arr id) <+> f) >>> ((arr id) <+> g)

which, when applied to an input x, returns all values:

((id . id) x) ++ ((id . f) x) ++ ((id . g) x) ++ ((g . f) x)
= x ++ (f x) ++ (g x) ++ ((g . f) x)

which are all permutations of using the arrow values f and g.

Tutorial Meta

The wiki file source is literate Haskell. Save the source in a file called ArrowFun.lhs to compile it (or run in GHCi).

The code is adapted to GHC 6.10.1; use [1] for older versions of GHC and other Haskell implementations.

  • Original version - Nov 19, 2006, Tim Newsham.
Retrieved from "https://wiki.haskell.org/index.php?title=Arrow_tutorial&oldid=66659"