-- Hoogle documentation, generated by Haddock
-- See Hoogle, http://www.haskell.org/hoogle/


-- | Haskell 98 semigroups
--   
--   Haskell 98 semigroups
--   
--   In mathematics, a semigroup is an algebraic structure consisting of a
--   set together with an associative binary operation. A semigroup
--   generalizes a monoid in that there might not exist an identity
--   element. It also (originally) generalized a group (a monoid with all
--   inverses) to a type where every element did not have to have an
--   inverse, thus the name semigroup.
@package semigroups
@version 0.8.4


-- | This module exposes the potentially unsafe operations that are
--   sometimes needed for efficiency: The Natural data constructor and
--   unsafePred.
module Numeric.Natural.Internal
newtype Natural
Natural :: Integer -> Natural
runNatural :: Natural -> Integer

-- | A refinement of Integral to represent types that do not contain
--   negative numbers.
class Integral n => Whole n
toNatural :: Whole n => n -> Natural
unsafePred :: Whole n => n -> n
instance Eq Natural
instance Ord Natural
instance Ix Natural
instance Whole Natural
instance Whole Word64
instance Whole Word32
instance Whole Word16
instance Whole Word8
instance Whole Word
instance Integral Natural
instance Enum Natural
instance Real Natural
instance Bits Natural
instance Num Natural
instance Read Natural
instance Show Natural


-- | Natural numbers.
module Numeric.Natural
data Natural

-- | A refinement of Integral to represent types that do not contain
--   negative numbers.
class Integral n => Whole n
toNatural :: Whole n => n -> Natural


-- | A NonEmpty list forms a monad as per list, but always contains at
--   least one element.
module Data.List.NonEmpty
data NonEmpty a
(:|) :: a -> [a] -> NonEmpty a

-- | map a function over a <a>NonEmpty</a> stream
map :: (a -> b) -> NonEmpty a -> NonEmpty b
intersperse :: a -> NonEmpty a -> NonEmpty a

-- | <a>scanl</a> is similar to <a>foldl</a>, but returns a stream of
--   successive reduced values from the left:
--   
--   <pre>
--   scanl f z [x1, x2, ...] == z :| [z `f` x1, (z `f` x1) `f` x2, ...]
--   </pre>
--   
--   Note that
--   
--   <pre>
--   last (scanl f z xs) == foldl f z xs.
--   </pre>
scanl :: Foldable f => (b -> a -> b) -> b -> f a -> NonEmpty b

-- | <a>scanr</a> is the right-to-left dual of <a>scanl</a>. Note that
--   
--   <pre>
--   head (scanr f z xs) == foldr f z xs.
--   </pre>
scanr :: Foldable f => (a -> b -> b) -> b -> f a -> NonEmpty b

-- | <a>scanl1</a> is a variant of <a>scanl</a> that has no starting value
--   argument:
--   
--   <pre>
--   scanl1 f [x1, x2, ...] == x1 :| [x1 `f` x2, x1 `f` (x2 `f` x3), ...]
--   </pre>
scanl1 :: (a -> a -> a) -> NonEmpty a -> NonEmpty a

-- | <a>scanr1</a> is a variant of <a>scanr</a> that has no starting value
--   argument.
scanr1 :: (a -> a -> a) -> NonEmpty a -> NonEmpty a

-- | Extract the first element of the stream
head :: NonEmpty a -> a

-- | Extract the possibly empty tail of the stream
tail :: NonEmpty a -> [a]

-- | Extract the last element of the stream
last :: NonEmpty a -> a

-- | Extract everything except the last element of the stream
init :: NonEmpty a -> [a]

-- | cons onto a stream
(<|) :: a -> NonEmpty a -> NonEmpty a
cons :: a -> NonEmpty a -> NonEmpty a
uncons :: NonEmpty a -> (a, Maybe (NonEmpty a))

-- | Sort a stream
sort :: Ord a => NonEmpty a -> NonEmpty a

-- | <a>reverse</a> a finite NonEmpty
reverse :: NonEmpty a -> NonEmpty a

-- | The <a>inits</a> function takes a stream <tt>xs</tt> and returns all
--   the finite prefixes of <tt>xs</tt>.
inits :: Foldable f => f a -> NonEmpty [a]

-- | The <a>tails</a> function takes a stream <tt>xs</tt> and returns all
--   the suffixes of <tt>xs</tt>.
tails :: Foldable f => f a -> NonEmpty [a]

-- | <tt><a>iterate</a> f x</tt> produces the infinite sequence of repeated
--   applications of <tt>f</tt> to <tt>x</tt>.
--   
--   <pre>
--   iterate f x = [x, f x, f (f x), ..]
--   </pre>
iterate :: (a -> a) -> a -> NonEmpty a

-- | <tt><a>repeat</a> x</tt> returns a constant stream, where all elements
--   are equal to <tt>x</tt>.
repeat :: a -> NonEmpty a

-- | <tt><a>cycle</a> xs</tt> returns the infinite repetition of
--   <tt>xs</tt>:
--   
--   <pre>
--   cycle [1,2,3] = 1 :| [2,3,1,2,3,...]
--   </pre>
cycle :: NonEmpty a -> NonEmpty a
unfold :: (a -> (b, Maybe a)) -> a -> NonEmpty b

-- | <a>insert</a> an item into a <a>NonEmpty</a>
insert :: (Foldable f, Ord a) => a -> f a -> NonEmpty a

-- | <tt><a>take</a> n xs</tt> returns the first <tt>n</tt> elements of
--   <tt>xs</tt>.
--   
--   <i>Beware</i>: passing a negative integer as the first argument will
--   cause an error.
take :: Int -> NonEmpty a -> [a]

-- | <tt><a>drop</a> n xs</tt> drops the first <tt>n</tt> elements off the
--   front of the sequence <tt>xs</tt>.
--   
--   <i>Beware</i>: passing a negative integer as the first argument will
--   cause an error.
drop :: Int -> NonEmpty a -> [a]

-- | <tt><a>splitAt</a> n xs</tt> returns a pair consisting of the prefix
--   of <tt>xs</tt> of length <tt>n</tt> and the remaining stream
--   immediately following this prefix.
--   
--   <i>Beware</i>: passing a negative integer as the first argument will
--   cause an error.
splitAt :: Int -> NonEmpty a -> ([a], [a])

-- | <tt><a>takeWhile</a> p xs</tt> returns the longest prefix of the
--   stream <tt>xs</tt> for which the predicate <tt>p</tt> holds.
takeWhile :: (a -> Bool) -> NonEmpty a -> [a]

-- | <tt><a>dropWhile</a> p xs</tt> returns the suffix remaining after
--   <tt><a>takeWhile</a> p xs</tt>.
dropWhile :: (a -> Bool) -> NonEmpty a -> [a]

-- | <a>span</a> <tt>p</tt> <tt>xs</tt> returns the longest prefix of
--   <tt>xs</tt> that satisfies <tt>p</tt>, together with the remainder of
--   the stream.
span :: (a -> Bool) -> NonEmpty a -> ([a], [a])

-- | The <a>break</a> <tt>p</tt> function is equivalent to <a>span</a>
--   <tt>not . p</tt>.
break :: (a -> Bool) -> NonEmpty a -> ([a], [a])

-- | <a>filter</a> <tt>p</tt> <tt>xs</tt>, removes any elements from
--   <tt>xs</tt> that do not satisfy <tt>p</tt>.
filter :: (a -> Bool) -> NonEmpty a -> [a]

-- | The <a>partition</a> function takes a predicate <tt>p</tt> and a
--   stream <tt>xs</tt>, and returns a pair of streams. The first stream
--   corresponds to the elements of <tt>xs</tt> for which <tt>p</tt> holds;
--   the second stream corresponds to the elements of <tt>xs</tt> for which
--   <tt>p</tt> does not hold.
partition :: (a -> Bool) -> NonEmpty a -> ([a], [a])

-- | The <a>group</a> function takes a stream and returns a stream of lists
--   such that flattening the resulting stream is equal to the argument.
--   Moreover, each sublist in the resulting stream contains only equal
--   elements. For example,
--   
--   <pre>
--   group $ cycle "Mississippi" = "M" : "i" : "ss" : "i" : "ss" : "i" : "pp" : "i" : "M" : "i" : ...
--   </pre>
group :: (Foldable f, Eq a) => f a -> [NonEmpty a]
groupBy :: Foldable f => (a -> a -> Bool) -> f a -> [NonEmpty a]
group1 :: Eq a => NonEmpty a -> NonEmpty (NonEmpty a)
groupBy1 :: (a -> a -> Bool) -> NonEmpty a -> NonEmpty (NonEmpty a)

-- | The <tt>isPrefix</tt> function returns <tt>True</tt> if the first
--   argument is a prefix of the second.
isPrefixOf :: Eq a => [a] -> NonEmpty a -> Bool

-- | <tt>xs !! n</tt> returns the element of the stream <tt>xs</tt> at
--   index <tt>n</tt>. Note that the head of the stream has index 0.
--   
--   <i>Beware</i>: passing a negative integer as the first argument will
--   cause an error.
(!!) :: NonEmpty a -> Int -> a

-- | The <a>zip</a> function takes two streams and returns a list of
--   corresponding pairs.
zip :: NonEmpty a -> NonEmpty b -> NonEmpty (a, b)

-- | The <a>zipWith</a> function generalizes <a>zip</a>. Rather than
--   tupling the functions, the elements are combined using the function
--   passed as the first argument to <a>zipWith</a>.
zipWith :: (a -> b -> c) -> NonEmpty a -> NonEmpty b -> NonEmpty c

-- | The <a>unzip</a> function is the inverse of the <a>zip</a> function.
unzip :: Functor f => f (a, b) -> (f a, f b)

-- | The <a>words</a> function breaks a stream of characters into a stream
--   of words, which were delimited by white space.
words :: NonEmpty Char -> NonEmpty String

-- | The <a>unwords</a> function is an inverse operation to <a>words</a>.
--   It joins words with separating spaces.
unwords :: NonEmpty String -> NonEmpty Char

-- | The <a>lines</a> function breaks a stream of characters into a list of
--   strings at newline characters. The resulting strings do not contain
--   newlines.
lines :: NonEmpty Char -> NonEmpty String

-- | The <a>unlines</a> function is an inverse operation to <a>lines</a>.
--   It joins lines, after appending a terminating newline to each.
unlines :: NonEmpty String -> NonEmpty Char

-- | Converts an non-empty list to a stream.
fromList :: [a] -> NonEmpty a

-- | Convert a stream to a list efficiently
toList :: NonEmpty a -> [a]
nonEmpty :: [a] -> Maybe (NonEmpty a)
xor :: NonEmpty Bool -> Bool
instance Typeable1 NonEmpty
instance Eq a => Eq (NonEmpty a)
instance Ord a => Ord (NonEmpty a)
instance Show a => Show (NonEmpty a)
instance Read a => Read (NonEmpty a)
instance Data a => Data (NonEmpty a)
instance Foldable NonEmpty
instance Traversable NonEmpty
instance Monad NonEmpty
instance Applicative NonEmpty
instance Functor NonEmpty


-- | In mathematics, a semigroup is an algebraic structure consisting of a
--   set together with an associative binary operation. A semigroup
--   generalizes a monoid in that there might not exist an identity
--   element. It also (originally) generalized a group (a monoid with all
--   inverses) to a type where every element did not have to have an
--   inverse, thus the name semigroup.
--   
--   The use of <tt>(&lt;&gt;)</tt> in this module conflicts with an
--   operator with the same name that is being exported by Data.Monoid.
--   However, this package re-exports (most of) the contents of
--   Data.Monoid, so to use semigroups and monoids in the same package just
--   
--   <pre>
--   import Data.Semigroup
--   </pre>
module Data.Semigroup
class Semigroup a where sconcat (a :| as) = go a as where go b (c : cs) = b <> go c cs go b [] = b times1p y0 x0 = f x0 (1 + y0) where f x y | even y = f (x <> x) (y `quot` 2) | y == 1 = x | otherwise = g (x <> x) (unsafePred y `quot` 2) x g x y z | even y = g (x <> x) (y `quot` 2) z | y == 1 = x <> z | otherwise = g (x <> x) (unsafePred y `quot` 2) (x <> z)
(<>) :: Semigroup a => a -> a -> a
sconcat :: Semigroup a => NonEmpty a -> a
times1p :: (Semigroup a, Whole n) => n -> a -> a
newtype Min a
Min :: a -> Min a
getMin :: Min a -> a
newtype Max a
Max :: a -> Max a
getMax :: Max a -> a

-- | Use <tt><a>Option</a> (<a>First</a> a)</tt> -- to get the behavior of
--   <a>First</a>
newtype First a
First :: a -> First a
getFirst :: First a -> a

-- | Use <tt><a>Option</a> (<a>Last</a> a)</tt> -- to get the behavior of
--   <a>Last</a>
newtype Last a
Last :: a -> Last a
getLast :: Last a -> a

-- | Provide a Semigroup for an arbitrary Monoid.
newtype WrappedMonoid m
WrapMonoid :: m -> WrappedMonoid m
unwrapMonoid :: WrappedMonoid m -> m

-- | The class of monoids (types with an associative binary operation that
--   has an identity). Instances should satisfy the following laws:
--   
--   <ul>
--   <li><pre>mappend mempty x = x</pre></li>
--   <li><pre>mappend x mempty = x</pre></li>
--   <li><pre>mappend x (mappend y z) = mappend (mappend x y) z</pre></li>
--   <li><pre>mconcat = <a>foldr</a> mappend mempty</pre></li>
--   </ul>
--   
--   The method names refer to the monoid of lists under concatenation, but
--   there are many other instances.
--   
--   Minimal complete definition: <a>mempty</a> and <a>mappend</a>.
--   
--   Some types can be viewed as a monoid in more than one way, e.g. both
--   addition and multiplication on numbers. In such cases we often define
--   <tt>newtype</tt>s and make those instances of <a>Monoid</a>, e.g.
--   <a>Sum</a> and <a>Product</a>.
class Monoid a
mempty :: Monoid a => a
mappend :: Monoid a => a -> a -> a
mconcat :: Monoid a => [a] -> a

-- | The dual of a monoid, obtained by swapping the arguments of
--   <a>mappend</a>.
newtype Dual a :: * -> *
Dual :: a -> Dual a
getDual :: Dual a -> a

-- | The monoid of endomorphisms under composition.
newtype Endo a :: * -> *
Endo :: (a -> a) -> Endo a
appEndo :: Endo a -> a -> a

-- | Boolean monoid under conjunction.
newtype All :: *
All :: Bool -> All
getAll :: All -> Bool

-- | Boolean monoid under disjunction.
newtype Any :: *
Any :: Bool -> Any
getAny :: Any -> Bool

-- | Monoid under addition.
newtype Sum a :: * -> *
Sum :: a -> Sum a
getSum :: Sum a -> a

-- | Monoid under multiplication.
newtype Product a :: * -> *
Product :: a -> Product a
getProduct :: Product a -> a

-- | Option is effectively <a>Maybe</a> with a better instance of
--   <a>Monoid</a>, built off of an underlying <a>Semigroup</a> instead of
--   an underlying <a>Monoid</a>. Ideally, this type would not exist at all
--   and we would just fix the <a>Monoid</a> intance of <a>Maybe</a>
newtype Option a
Option :: Maybe a -> Option a
getOption :: Option a -> Maybe a
option :: b -> (a -> b) -> Option a -> b

-- | This lets you use a difference list of a Semigroup as a Monoid.
diff :: Semigroup m => m -> Endo m

-- | A generalization of <a>cycle</a> to an arbitrary <a>Semigroup</a>. May
--   fail to terminate for some values in some semigroups.
cycle1 :: Semigroup m => m -> m
instance Typeable1 Min
instance Typeable1 Max
instance Typeable1 First
instance Typeable1 Last
instance Typeable1 WrappedMonoid
instance Typeable1 Option
instance Eq a => Eq (Min a)
instance Ord a => Ord (Min a)
instance Bounded a => Bounded (Min a)
instance Show a => Show (Min a)
instance Read a => Read (Min a)
instance Data a => Data (Min a)
instance Eq a => Eq (Max a)
instance Ord a => Ord (Max a)
instance Bounded a => Bounded (Max a)
instance Show a => Show (Max a)
instance Read a => Read (Max a)
instance Data a => Data (Max a)
instance Eq a => Eq (First a)
instance Ord a => Ord (First a)
instance Bounded a => Bounded (First a)
instance Show a => Show (First a)
instance Read a => Read (First a)
instance Data a => Data (First a)
instance Eq a => Eq (Last a)
instance Ord a => Ord (Last a)
instance Bounded a => Bounded (Last a)
instance Show a => Show (Last a)
instance Read a => Read (Last a)
instance Data a => Data (Last a)
instance Eq m => Eq (WrappedMonoid m)
instance Ord m => Ord (WrappedMonoid m)
instance Bounded m => Bounded (WrappedMonoid m)
instance Show m => Show (WrappedMonoid m)
instance Read m => Read (WrappedMonoid m)
instance Data m => Data (WrappedMonoid m)
instance Eq a => Eq (Option a)
instance Ord a => Ord (Option a)
instance Show a => Show (Option a)
instance Read a => Read (Option a)
instance Data a => Data (Option a)
instance Ord k => Semigroup (Map k v)
instance Semigroup (IntMap v)
instance Ord a => Semigroup (Set a)
instance Semigroup IntSet
instance Semigroup (Seq a)
instance Semigroup a => Monoid (Option a)
instance Semigroup a => Semigroup (Option a)
instance Traversable Option
instance Foldable Option
instance MonadFix Option
instance MonadPlus Option
instance Alternative Option
instance Monad Option
instance Applicative Option
instance Functor Option
instance Monoid m => Monoid (WrappedMonoid m)
instance Monoid m => Semigroup (WrappedMonoid m)
instance Semigroup (Last a)
instance Semigroup (First a)
instance (Ord a, Bounded a) => Monoid (Max a)
instance Ord a => Semigroup (Max a)
instance (Ord a, Bounded a) => Monoid (Min a)
instance Ord a => Semigroup (Min a)
instance Semigroup (NonEmpty a)
instance Semigroup (Last a)
instance Semigroup (First a)
instance Num a => Semigroup (Product a)
instance Num a => Semigroup (Sum a)
instance Semigroup Any
instance Semigroup All
instance Semigroup (Endo a)
instance Semigroup a => Semigroup (Dual a)
instance (Semigroup a, Semigroup b, Semigroup c, Semigroup d, Semigroup e) => Semigroup (a, b, c, d, e)
instance (Semigroup a, Semigroup b, Semigroup c, Semigroup d) => Semigroup (a, b, c, d)
instance (Semigroup a, Semigroup b, Semigroup c) => Semigroup (a, b, c)
instance (Semigroup a, Semigroup b) => Semigroup (a, b)
instance Semigroup (Either a b)
instance Semigroup a => Semigroup (Maybe a)
instance Semigroup [a]
instance Semigroup b => Semigroup (a -> b)
instance Semigroup ()