# Difference between revisions of "Prelude extensions"

m (Added Haskell versions of S and Y combinators (no K combinator here!) >_<) |
(Suggestion for hyperstrict evaluation primitive) |
||

Line 113: | Line 113: | ||

</haskell> |
</haskell> |
||

+ | == Hyperstrict evaluation[http://foldoc.org/hyperstrict <span></span>] == |
||

+ | |||

+ | |||

+ | <haskell> |
||

+ | compel :: a -> a -- primitive |
||

+ | </haskell> |
||

== See also == |
== See also == |

## Latest revision as of 02:22, 18 May 2020

## Contents

## Tuples

It is often necessary to apply functions to either the first or the second part of a pair. This is often considered a form of mapping (like map from Data.List).

```
-- | Apply a function to the first element of a pair
mapFst :: (a -> c) -> (a, b) -> (c, b)
mapFst f (a, b) = (f a, b)
-- | Apply a function to the second element of a pair
mapSnd :: (b -> c) -> (a, b) -> (a, c)
mapSnd f (a, b) = (a, f b)
-- | Apply a function to both elements of a pair
mapPair :: (a -> c, b -> d) -> (a, b) -> (c, d)
mapPair (f, g) (a, b) = (f a, g b)
```

Data.Graph.Inductive.Query.Monad module (section *Additional Graph Utilities*) contains `mapFst`

, `mapSnd`

, and also a function `><`

corresponding to `mapPair`

. Another implementation of these functions in the standard libraries: using `first`

, `second`

, `***`

arrow operations overloaded for functions (as special arrows), see Control.Arrow module, or Arrow HaskellWiki page.

See also point-free programming.

### Treating pairs and lists in the same way

We can define a Pair class which allows us to process both pairs and non-empty lists using the same operator:

```
import Control.Arrow ((***))
infixl 4 <**>
class Pair p x y | p -> x, p -> y where
toPair :: p -> (x, y)
(<**>) :: (x -> a -> b) -> (y -> a) -> p -> b
(<**>) f g = uncurry id . (f *** g) . toPair
instance Pair (a, b) a b where
toPair = id
instance Pair [a] a [a] where
toPair l = (head l, tail l)
```

## Matrices

A simple representation of matrices is as lists of lists of numbers:

```
newtype Matrix a = Matrix [[a]] deriving (Eq, Show)
```

These matrices may be made an instance of `Num`

(though the definitions of `abs`

and `signum`

are just fillers):

```
instance Num a => Num (Matrix a) where
Matrix as + Matrix bs = Matrix (zipWith (zipWith (+)) as bs)
Matrix as - Matrix bs = Matrix (zipWith (zipWith (-)) as bs)
Matrix as * Matrix bs =
Matrix [[sum $ zipWith (*) a b | b <- transpose bs] | a <- as]
negate (Matrix as) = Matrix (map (map negate) as)
fromInteger x = Matrix (iterate (0:) (fromInteger x : repeat 0))
abs m = m
signum _ = 1
```

The `fromInteger`

method builds an infinite matrix, but addition and subtraction work even with infinite matrices, and multiplication works as long as either the first matrix is of finite width or the second is of finite height.
Applying the linear transformation defined by a matrix to a vector is

```
apply :: Num a => Matrix a -> [a] -> [a]
apply (Matrix as) b = [sum (zipWith (*) a b) | a <- as]
```

## Data.Either extensions

```
import Data.Either
either', trigger, trigger_, switch :: (a -> b) -> (a -> b) -> Either a a -> Either b b
either' f g (Left x) = Left (f x)
either' f g (Right x) = Right (g x)
trigger f g (Left x) = Left (f x)
trigger f g (Right x) = Left (g x)
trigger_ f g (Left x) = Right (f x)
trigger_ f g (Right x) = Right (g x)
switch f g (Left x) = Right (f x)
switch f g (Right x) = Left (g x)
sure :: (a->b) -> Either a a -> b
sure f = either f f
sure' :: (a->b) -> Either a a -> Either b b
sure' f = either' f f
```

## Schönfinkel & Curry's amalgamation combinator, for Haskell

```
sperse :: (a -> b -> c) -> (a -> b) -> a -> c
sperse f g x = f x (g x)
```

## Curry and Feys's paradoxical combinator, for Haskell

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

## Hyperstrict evaluation

```
compel :: a -> a -- primitive
```