Module

Control.MonadPlus

#MonadPlus

class MonadPlus :: (Type -> Type) -> Constraintclass (Monad m, Alternative m) <= MonadPlus m 

The MonadPlus type class has no members of its own; it just specifies that the type has both Monad and Alternative instances.

Types which have MonadPlus instances should also satisfy the following law:

  • Distributivity: (x <|> y) >>= f == (x >>= f) <|> (y >>= f)

Instances

Re-exports from Control.Alt

#Alt

class Alt :: (Type -> Type) -> Constraintclass (Functor f) <= Alt f  where

The Alt type class identifies an associative operation on a type constructor. It is similar to Semigroup, except that it applies to types of kind * -> *, like Array or List, rather than concrete types String or Number.

Alt instances are required to satisfy the following laws:

  • Associativity: (x <|> y) <|> z == x <|> (y <|> z)
  • Distributivity: f <$> (x <|> y) == (f <$> x) <|> (f <$> y)

For example, the Array ([]) type is an instance of Alt, where (<|>) is defined to be concatenation.

A common use case is to select the first "valid" item, or, if all items are "invalid", the last "invalid" item.

For example:

import Control.Alt ((<|>))
import Data.Maybe (Maybe(..)
import Data.Either (Either(..))

Nothing <|> Just 1 <|> Just 2 == Just 1
Left "err" <|> Right 1 <|> Right 2 == Right 1
Left "err 1" <|> Left "err 2" <|> Left "err 3" == Left "err 3"

Members

  • alt :: forall a. f a -> f a -> f a

Instances

#(<|>)

Operator alias for Control.Alt.alt (left-associative / precedence 3)

Re-exports from Control.Alternative

#Alternative

class Alternative :: (Type -> Type) -> Constraintclass (Applicative f, Plus f) <= Alternative f 

The Alternative type class has no members of its own; it just specifies that the type constructor has both Applicative and Plus instances.

Types which have Alternative instances should also satisfy the following laws:

  • Distributivity: (f <|> g) <*> x == (f <*> x) <|> (g <*> x)
  • Annihilation: empty <*> f = empty

Instances

#guard

guard :: forall m. Alternative m => Boolean -> m Unit

Fail using Plus if a condition does not hold, or succeed using Applicative if it does.

For example:

import Prelude
import Control.Alternative (guard)
import Data.Array ((..))

factors :: Int -> Array Int
factors n = do
  a <- 1..n
  b <- 1..n
  guard $ a * b == n
  pure a

Re-exports from Control.Applicative

#Applicative

class Applicative :: (Type -> Type) -> Constraintclass (Apply f) <= Applicative f  where

The Applicative type class extends the Apply type class with a pure function, which can be used to create values of type f a from values of type a.

Where Apply provides the ability to lift functions of two or more arguments to functions whose arguments are wrapped using f, and Functor provides the ability to lift functions of one argument, pure can be seen as the function which lifts functions of zero arguments. That is, Applicative functors support a lifting operation for any number of function arguments.

Instances must satisfy the following laws in addition to the Apply laws:

  • Identity: (pure identity) <*> v = v
  • Composition: pure (<<<) <*> f <*> g <*> h = f <*> (g <*> h)
  • Homomorphism: (pure f) <*> (pure x) = pure (f x)
  • Interchange: u <*> (pure y) = (pure (_ $ y)) <*> u

Members

  • pure :: forall a. a -> f a

Instances

#when

when :: forall m. Applicative m => Boolean -> m Unit -> m Unit

Perform an applicative action when a condition is true.

#unless

unless :: forall m. Applicative m => Boolean -> m Unit -> m Unit

Perform an applicative action unless a condition is true.

#liftA1

liftA1 :: forall f a b. Applicative f => (a -> b) -> f a -> f b

liftA1 provides a default implementation of (<$>) for any Applicative functor, without using (<$>) as provided by the Functor-Applicative superclass relationship.

liftA1 can therefore be used to write Functor instances as follows:

instance functorF :: Functor F where
  map = liftA1

Re-exports from Control.Apply

#Apply

class Apply :: (Type -> Type) -> Constraintclass (Functor f) <= Apply f  where

The Apply class provides the (<*>) which is used to apply a function to an argument under a type constructor.

Apply can be used to lift functions of two or more arguments to work on values wrapped with the type constructor f. It might also be understood in terms of the lift2 function:

lift2 :: forall f a b c. Apply f => (a -> b -> c) -> f a -> f b -> f c
lift2 f a b = f <$> a <*> b

(<*>) is recovered from lift2 as lift2 ($). That is, (<*>) lifts the function application operator ($) to arguments wrapped with the type constructor f.

Put differently...

foo =
  functionTakingNArguments <$> computationProducingArg1
                           <*> computationProducingArg2
                           <*> ...
                           <*> computationProducingArgN

Instances must satisfy the following law in addition to the Functor laws:

  • Associative composition: (<<<) <$> f <*> g <*> h = f <*> (g <*> h)

Formally, Apply represents a strong lax semi-monoidal endofunctor.

Members

  • apply :: forall a b. f (a -> b) -> f a -> f b

Instances

#(<*>)

Operator alias for Control.Apply.apply (left-associative / precedence 4)

#(<*)

Operator alias for Control.Apply.applyFirst (left-associative / precedence 4)

#(*>)

Operator alias for Control.Apply.applySecond (left-associative / precedence 4)

Re-exports from Control.Bind

#Bind

class Bind :: (Type -> Type) -> Constraintclass (Apply m) <= Bind m  where

The Bind type class extends the Apply type class with a "bind" operation (>>=) which composes computations in sequence, using the return value of one computation to determine the next computation.

The >>= operator can also be expressed using do notation, as follows:

x >>= f = do y <- x
             f y

where the function argument of f is given the name y.

Instances must satisfy the following laws in addition to the Apply laws:

  • Associativity: (x >>= f) >>= g = x >>= (\k -> f k >>= g)
  • Apply Superclass: apply f x = f >>= \f’ -> map f’ x

Associativity tells us that we can regroup operations which use do notation so that we can unambiguously write, for example:

do x <- m1
   y <- m2 x
   m3 x y

Members

  • bind :: forall a b. m a -> (a -> m b) -> m b

Instances

  • Bind (Function r)
  • Bind Array

    The bind/>>= function for Array works by applying a function to each element in the array, and flattening the results into a single, new array.

    Array's bind/>>= works like a nested for loop. Each bind adds another level of nesting in the loop. For example:

    foo :: Array String
    foo =
      ["a", "b"] >>= \eachElementInArray1 ->
        ["c", "d"] >>= \eachElementInArray2
          pure (eachElementInArray1 <> eachElementInArray2)
    
    -- In other words...
    foo
    -- ... is the same as...
    [ ("a" <> "c"), ("a" <> "d"), ("b" <> "c"), ("b" <> "d") ]
    -- which simplifies to...
    [ "ac", "ad", "bc", "bd" ]
    
  • Bind Proxy

#join

join :: forall a m. Bind m => m (m a) -> m a

Collapse two applications of a monadic type constructor into one.

#ifM

ifM :: forall a m. Bind m => m Boolean -> m a -> m a -> m a

Execute a monadic action if a condition holds.

For example:

main = ifM ((< 0.5) <$> random)
         (trace "Heads")
         (trace "Tails")

#(>>=)

Operator alias for Control.Bind.bind (left-associative / precedence 1)

#(>=>)

Operator alias for Control.Bind.composeKleisli (right-associative / precedence 1)

#(=<<)

Operator alias for Control.Bind.bindFlipped (right-associative / precedence 1)

#(<=<)

Operator alias for Control.Bind.composeKleisliFlipped (right-associative / precedence 1)

Re-exports from Control.Monad

#Monad

class Monad :: (Type -> Type) -> Constraintclass (Applicative m, Bind m) <= Monad m 

The Monad type class combines the operations of the Bind and Applicative type classes. Therefore, Monad instances represent type constructors which support sequential composition, and also lifting of functions of arbitrary arity.

Instances must satisfy the following laws in addition to the Applicative and Bind laws:

  • Left Identity: pure x >>= f = f x
  • Right Identity: x >>= pure = x

Instances

#liftM1

liftM1 :: forall m a b. Monad m => (a -> b) -> m a -> m b

liftM1 provides a default implementation of (<$>) for any Monad, without using (<$>) as provided by the Functor-Monad superclass relationship.

liftM1 can therefore be used to write Functor instances as follows:

instance functorF :: Functor F where
  map = liftM1

#ap

ap :: forall m a b. Monad m => m (a -> b) -> m a -> m b

ap provides a default implementation of (<*>) for any Monad, without using (<*>) as provided by the Apply-Monad superclass relationship.

ap can therefore be used to write Apply instances as follows:

instance applyF :: Apply F where
  apply = ap

Re-exports from Control.MonadZero

#MonadZero

class MonadZero :: (Type -> Type) -> Constraintclass (Monad m, Alternative m, MonadZeroIsDeprecated) <= MonadZero m 

The MonadZero type class has no members of its own; it just specifies that the type has both Monad and Alternative instances.

Types which have MonadZero instances should also satisfy the following laws:

  • Annihilation: empty >>= f = empty

Instances

Re-exports from Control.Plus

#Plus

class Plus :: (Type -> Type) -> Constraintclass (Alt f) <= Plus f  where

The Plus type class extends the Alt type class with a value that should be the left and right identity for (<|>).

It is similar to Monoid, except that it applies to types of kind * -> *, like Array or List, rather than concrete types like String or Number.

Plus instances should satisfy the following laws:

  • Left identity: empty <|> x == x
  • Right identity: x <|> empty == x
  • Annihilation: f <$> empty == empty

Members

Instances

Re-exports from Data.Functor

#Functor

class Functor :: (Type -> Type) -> Constraintclass Functor f  where

A Functor is a type constructor which supports a mapping operation map.

map can be used to turn functions a -> b into functions f a -> f b whose argument and return types use the type constructor f to represent some computational context.

Instances must satisfy the following laws:

  • Identity: map identity = identity
  • Composition: map (f <<< g) = map f <<< map g

Members

  • map :: forall a b. (a -> b) -> f a -> f b

Instances

#void

void :: forall f a. Functor f => f a -> f Unit

The void function is used to ignore the type wrapped by a Functor, replacing it with Unit and keeping only the type information provided by the type constructor itself.

void is often useful when using do notation to change the return type of a monadic computation:

main = forE 1 10 \n -> void do
  print n
  print (n * n)

#(<$>)

Operator alias for Data.Functor.map (left-associative / precedence 4)

#(<$)

Operator alias for Data.Functor.voidRight (left-associative / precedence 4)

#(<#>)

Operator alias for Data.Functor.mapFlipped (left-associative / precedence 1)

#($>)

Operator alias for Data.Functor.voidLeft (left-associative / precedence 4)

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