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


-- | Subclasses of Monoid
--   
--   A hierarchy of subclasses of <a>Monoid</a> together with their
--   instances for all data structures from base, containers, and text
--   packages.
@package monoid-subclasses
@version 0.4.2.1


-- | This module defines the MonoidNull class and some of its instances.
module Data.Monoid.Null

-- | Extension of <a>Monoid</a> that allows testing a value for equality
--   with <a>mempty</a>. The following law must hold:
--   
--   <pre>
--   null x == (x == mempty)
--   </pre>
--   
--   Furthermore, the performance of this method should be constant,
--   <i>i.e.</i>, independent of the length of its argument.
class Monoid m => MonoidNull m
null :: MonoidNull m => m -> Bool

-- | Subclass of <a>Monoid</a> for types whose values have no inverse, with
--   the exception of <a>mempty</a>. More formally, the class instances
--   must satisfy the following law:
--   
--   <pre>
--   null (x &lt;&gt; y) == (null x &amp;&amp; null y)
--   </pre>
class MonoidNull m => PositiveMonoid m
instance Data.Monoid.Null.MonoidNull ()
instance Data.Monoid.Null.MonoidNull GHC.Types.Ordering
instance Data.Monoid.Null.MonoidNull Data.Monoid.All
instance Data.Monoid.Null.MonoidNull Data.Monoid.Any
instance Data.Monoid.Null.MonoidNull (Data.Monoid.First a)
instance Data.Monoid.Null.MonoidNull (Data.Monoid.Last a)
instance Data.Monoid.Null.MonoidNull a => Data.Monoid.Null.MonoidNull (Data.Monoid.Dual a)
instance (GHC.Num.Num a, GHC.Classes.Eq a) => Data.Monoid.Null.MonoidNull (Data.Monoid.Sum a)
instance (GHC.Num.Num a, GHC.Classes.Eq a) => Data.Monoid.Null.MonoidNull (Data.Monoid.Product a)
instance GHC.Base.Monoid a => Data.Monoid.Null.MonoidNull (GHC.Base.Maybe a)
instance (Data.Monoid.Null.MonoidNull a, Data.Monoid.Null.MonoidNull b) => Data.Monoid.Null.MonoidNull (a, b)
instance Data.Monoid.Null.MonoidNull [x]
instance Data.Monoid.Null.MonoidNull Data.ByteString.Internal.ByteString
instance Data.Monoid.Null.MonoidNull Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Null.MonoidNull Data.Text.Internal.Text
instance Data.Monoid.Null.MonoidNull Data.Text.Internal.Lazy.Text
instance GHC.Classes.Ord k => Data.Monoid.Null.MonoidNull (Data.Map.Base.Map k v)
instance Data.Monoid.Null.MonoidNull (Data.IntMap.Base.IntMap v)
instance Data.Monoid.Null.MonoidNull Data.IntSet.Base.IntSet
instance Data.Monoid.Null.MonoidNull (Data.Sequence.Seq a)
instance GHC.Classes.Ord a => Data.Monoid.Null.MonoidNull (Data.Set.Base.Set a)
instance Data.Monoid.Null.MonoidNull (Data.Vector.Vector a)
instance Data.Monoid.Null.PositiveMonoid ()
instance Data.Monoid.Null.PositiveMonoid GHC.Types.Ordering
instance Data.Monoid.Null.PositiveMonoid Data.Monoid.All
instance Data.Monoid.Null.PositiveMonoid Data.Monoid.Any
instance Data.Monoid.Null.PositiveMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Null.PositiveMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Null.PositiveMonoid Data.Text.Internal.Text
instance Data.Monoid.Null.PositiveMonoid Data.Text.Internal.Lazy.Text
instance GHC.Base.Monoid a => Data.Monoid.Null.PositiveMonoid (GHC.Base.Maybe a)
instance Data.Monoid.Null.PositiveMonoid (Data.Monoid.First a)
instance Data.Monoid.Null.PositiveMonoid (Data.Monoid.Last a)
instance Data.Monoid.Null.PositiveMonoid a => Data.Monoid.Null.PositiveMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Null.PositiveMonoid [x]
instance GHC.Classes.Ord k => Data.Monoid.Null.PositiveMonoid (Data.Map.Base.Map k v)
instance Data.Monoid.Null.PositiveMonoid (Data.IntMap.Base.IntMap v)
instance Data.Monoid.Null.PositiveMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Null.PositiveMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Ord a => Data.Monoid.Null.PositiveMonoid (Data.Set.Base.Set a)
instance Data.Monoid.Null.PositiveMonoid (Data.Vector.Vector a)


-- | This module defines the <a>FactorialMonoid</a> class and some of its
--   instances.
module Data.Monoid.Factorial

-- | Class of monoids that can be split into irreducible (<i>i.e.</i>,
--   atomic or prime) <a>factors</a> in a unique way. Factors of a
--   <a>Product</a> are literally its prime factors:
--   
--   <pre>
--   factors (Product 12) == [Product 2, Product 2, Product 3]
--   </pre>
--   
--   Factors of a list are <i>not</i> its elements but all its single-item
--   sublists:
--   
--   <pre>
--   factors "abc" == ["a", "b", "c"]
--   </pre>
--   
--   The methods of this class satisfy the following laws:
--   
--   <pre>
--   mconcat . factors == id
--   null == List.null . factors
--   List.all (\prime-&gt; factors prime == [prime]) . factors
--   factors == unfoldr splitPrimePrefix == List.reverse . unfoldr (fmap swap . splitPrimeSuffix)
--   reverse == mconcat . List.reverse . factors
--   primePrefix == maybe mempty fst . splitPrimePrefix
--   primeSuffix == maybe mempty snd . splitPrimeSuffix
--   inits == List.map mconcat . List.inits . factors
--   tails == List.map mconcat . List.tails . factors
--   foldl f a == List.foldl f a . factors
--   foldl' f a == List.foldl' f a . factors
--   foldr f a == List.foldr f a . factors
--   span p m == (mconcat l, mconcat r) where (l, r) = List.span p (factors m)
--   List.all (List.all (not . pred) . factors) . split pred
--   mconcat . intersperse prime . split (== prime) == id
--   splitAt i m == (mconcat l, mconcat r) where (l, r) = List.splitAt i (factors m)
--   spanMaybe () (const $ bool Nothing (Maybe ()) . p) m == (takeWhile p m, dropWhile p m, ())
--   spanMaybe s0 (\s m-&gt; Just $ f s m) m0 == (m0, mempty, foldl f s0 m0)
--   let (prefix, suffix, s') = spanMaybe s f m
--       foldMaybe = foldl g (Just s)
--       g s m = s &gt;&gt;= flip f m
--   in all ((Nothing ==) . foldMaybe) (inits prefix)
--      &amp;&amp; prefix == last (filter (isJust . foldMaybe) $ inits m)
--      &amp;&amp; Just s' == foldMaybe prefix
--      &amp;&amp; m == prefix &lt;&gt; suffix
--   </pre>
--   
--   A minimal instance definition must implement <a>factors</a> or
--   <a>splitPrimePrefix</a>. Other methods are provided and should be
--   implemented only for performance reasons.
class MonoidNull m => FactorialMonoid m where factors = unfoldr splitPrimePrefix primePrefix = maybe mempty fst . splitPrimePrefix primeSuffix = maybe mempty snd . splitPrimeSuffix splitPrimePrefix x = case factors x of { [] -> Nothing prefix : rest -> Just (prefix, mconcat rest) } splitPrimeSuffix x = case factors x of { [] -> Nothing fs -> Just (mconcat (init fs), last fs) } inits = foldr (\ m l -> mempty : map (mappend m) l) [mempty] tails m = m : maybe [] (tails . snd) (splitPrimePrefix m) foldl f f0 = foldl f f0 . factors foldl' f f0 = foldl' f f0 . factors foldr f f0 = foldr f f0 . factors length = length . factors foldMap f = foldr (mappend . f) mempty span p m0 = spanAfter id m0 where spanAfter f m = case splitPrimePrefix m of { Just (prime, rest) | p prime -> spanAfter (f . mappend prime) rest _ -> (f mempty, m) } break = span . (not .) spanMaybe s0 f m0 = spanAfter id s0 m0 where spanAfter g s m = case splitPrimePrefix m of { Just (prime, rest) | Just s' <- f s prime -> spanAfter (g . mappend prime) s' rest | otherwise -> (g mempty, m, s) Nothing -> (m0, m, s) } spanMaybe' s0 f m0 = spanAfter id s0 m0 where spanAfter g s m = seq s $ case splitPrimePrefix m of { Just (prime, rest) | Just s' <- f s prime -> spanAfter (g . mappend prime) s' rest | otherwise -> (g mempty, m, s) Nothing -> (m0, m, s) } split p m = prefix : splitRest where (prefix, rest) = break p m splitRest = case splitPrimePrefix rest of { Nothing -> [] Just (_, tl) -> split p tl } takeWhile p = fst . span p dropWhile p = snd . span p splitAt n0 m0 | n0 <= 0 = (mempty, m0) | otherwise = split' n0 id m0 where split' 0 f m = (f mempty, m) split' n f m = case splitPrimePrefix m of { Nothing -> (f mempty, m) Just (prime, rest) -> split' (pred n) (f . mappend prime) rest } drop n p = snd (splitAt n p) take n p = fst (splitAt n p) reverse = mconcat . reverse . factors

-- | Returns a list of all prime factors; inverse of mconcat.
factors :: FactorialMonoid m => m -> [m]

-- | The prime prefix, <a>mempty</a> if none.
primePrefix :: FactorialMonoid m => m -> m

-- | The prime suffix, <a>mempty</a> if none.
primeSuffix :: FactorialMonoid m => m -> m

-- | Splits the argument into its prime prefix and the remaining suffix.
--   Returns <a>Nothing</a> for <a>mempty</a>.
splitPrimePrefix :: FactorialMonoid m => m -> Maybe (m, m)

-- | Splits the argument into its prime suffix and the remaining prefix.
--   Returns <a>Nothing</a> for <a>mempty</a>.
splitPrimeSuffix :: FactorialMonoid m => m -> Maybe (m, m)

-- | Returns the list of all prefixes of the argument, <a>mempty</a> first.
inits :: FactorialMonoid m => m -> [m]

-- | Returns the list of all suffixes of the argument, <a>mempty</a> last.
tails :: FactorialMonoid m => m -> [m]

-- | Like <a>foldl</a> from <a>Data.List</a> on the list of
--   <tt>primes</tt>.
foldl :: FactorialMonoid m => (a -> m -> a) -> a -> m -> a

-- | Like <a>foldl'</a> from <a>Data.List</a> on the list of
--   <tt>primes</tt>.
foldl' :: FactorialMonoid m => (a -> m -> a) -> a -> m -> a

-- | Like <a>foldr</a> from <a>Data.List</a> on the list of
--   <tt>primes</tt>.
foldr :: FactorialMonoid m => (m -> a -> a) -> a -> m -> a

-- | The <a>length</a> of the list of <tt>primes</tt>.
length :: FactorialMonoid m => m -> Int

-- | Generalizes <a>foldMap</a> from <a>Data.Foldable</a>, except the
--   function arguments are prime factors rather than the structure
--   elements.
foldMap :: (FactorialMonoid m, Monoid n) => (m -> n) -> m -> n

-- | Like <a>span</a> from <a>Data.List</a> on the list of <tt>primes</tt>.
span :: FactorialMonoid m => (m -> Bool) -> m -> (m, m)

-- | Equivalent to <a>break</a> from <a>Data.List</a>.
break :: FactorialMonoid m => (m -> Bool) -> m -> (m, m)

-- | Splits the monoid into components delimited by prime separators
--   satisfying the given predicate. The primes satisfying the predicate
--   are not a part of the result.
split :: FactorialMonoid m => (m -> Bool) -> m -> [m]

-- | Equivalent to <a>takeWhile</a> from <a>Data.List</a>.
takeWhile :: FactorialMonoid m => (m -> Bool) -> m -> m

-- | Equivalent to <a>dropWhile</a> from <a>Data.List</a>.
dropWhile :: FactorialMonoid m => (m -> Bool) -> m -> m

-- | A stateful variant of <a>span</a>, threading the result of the test
--   function as long as it returns <a>Just</a>.
spanMaybe :: FactorialMonoid m => s -> (s -> m -> Maybe s) -> m -> (m, m, s)

-- | Strict version of <a>spanMaybe</a>.
spanMaybe' :: FactorialMonoid m => s -> (s -> m -> Maybe s) -> m -> (m, m, s)

-- | Like <a>splitAt</a> from <a>Data.List</a> on the list of
--   <tt>primes</tt>.
splitAt :: FactorialMonoid m => Int -> m -> (m, m)

-- | Equivalent to <a>drop</a> from <a>Data.List</a>.
drop :: FactorialMonoid m => Int -> m -> m

-- | Equivalent to <a>take</a> from <a>Data.List</a>.
take :: FactorialMonoid m => Int -> m -> m

-- | Equivalent to <a>reverse</a> from <a>Data.List</a>.
reverse :: FactorialMonoid m => m -> m

-- | A subclass of <a>FactorialMonoid</a> whose instances satisfy this
--   additional law:
--   
--   <pre>
--   factors (a &lt;&gt; b) == factors a &lt;&gt; factors b
--   </pre>
class (FactorialMonoid m, PositiveMonoid m) => StableFactorialMonoid m

-- | A <a>mapM</a> equivalent.
mapM :: (FactorialMonoid a, Monoid b, Monad m) => (a -> m b) -> a -> m b

-- | A <a>mapM_</a> equivalent.
mapM_ :: (FactorialMonoid a, Monad m) => (a -> m b) -> a -> m ()
instance Data.Monoid.Factorial.FactorialMonoid ()
instance Data.Monoid.Factorial.FactorialMonoid a => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Dual a)
instance (GHC.Real.Integral a, GHC.Classes.Eq a) => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Product a)
instance Data.Monoid.Factorial.FactorialMonoid a => Data.Monoid.Factorial.FactorialMonoid (GHC.Base.Maybe a)
instance (Data.Monoid.Factorial.FactorialMonoid a, Data.Monoid.Factorial.FactorialMonoid b) => Data.Monoid.Factorial.FactorialMonoid (a, b)
instance Data.Monoid.Factorial.FactorialMonoid [x]
instance Data.Monoid.Factorial.FactorialMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Factorial.FactorialMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Factorial.FactorialMonoid Data.Text.Internal.Text
instance Data.Monoid.Factorial.FactorialMonoid Data.Text.Internal.Lazy.Text
instance GHC.Classes.Ord k => Data.Monoid.Factorial.FactorialMonoid (Data.Map.Base.Map k v)
instance Data.Monoid.Factorial.FactorialMonoid (Data.IntMap.Base.IntMap a)
instance Data.Monoid.Factorial.FactorialMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Factorial.FactorialMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Ord a => Data.Monoid.Factorial.FactorialMonoid (Data.Set.Base.Set a)
instance Data.Monoid.Factorial.FactorialMonoid (Data.Vector.Vector a)
instance Data.Monoid.Factorial.StableFactorialMonoid ()
instance Data.Monoid.Factorial.StableFactorialMonoid a => Data.Monoid.Factorial.StableFactorialMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Factorial.StableFactorialMonoid [x]
instance Data.Monoid.Factorial.StableFactorialMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Factorial.StableFactorialMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Factorial.StableFactorialMonoid Data.Text.Internal.Text
instance Data.Monoid.Factorial.StableFactorialMonoid Data.Text.Internal.Lazy.Text
instance Data.Monoid.Factorial.StableFactorialMonoid (Data.Sequence.Seq a)
instance Data.Monoid.Factorial.StableFactorialMonoid (Data.Vector.Vector a)


-- | This module defines the <a>Monoid</a> =&gt; <a>ReductiveMonoid</a>
--   =&gt; (<a>CancellativeMonoid</a>, <a>GCDMonoid</a>) class hierarchy.
--   
--   The <a>ReductiveMonoid</a> class introduces operation <a>&lt;/&gt;</a>
--   which is the inverse of <a>&lt;&gt;</a>. For the <a>Sum</a> monoid,
--   this operation is subtraction; for <a>Product</a> it is division and
--   for <tt>Set</tt> it's the set difference. A <a>ReductiveMonoid</a> is
--   not a full group because <a>&lt;/&gt;</a> may return <a>Nothing</a>.
--   
--   The <a>CancellativeMonoid</a> subclass does not add any operation but
--   it provides the additional guarantee that <a>&lt;&gt;</a> can always
--   be undone with <a>&lt;/&gt;</a>. Thus <a>Sum</a> is a
--   <a>CancellativeMonoid</a> but <a>Product</a> is not because
--   <tt>(0*n)/0</tt> is not defined.
--   
--   The <a>GCDMonoid</a> subclass adds the <a>gcd</a> operation which
--   takes two monoidal arguments and finds their greatest common divisor,
--   or (more generally) the greatest monoid that can be extracted with the
--   <a>&lt;/&gt;</a> operation from both.
--   
--   All monoid subclasses listed above are for Abelian, <i>i.e.</i>,
--   commutative or symmetric monoids. Since most practical monoids in
--   Haskell are not Abelian, each of the these classes has two symmetric
--   superclasses:
--   
--   <ul>
--   <li><a>LeftReductiveMonoid</a></li>
--   <li><a>LeftCancellativeMonoid</a></li>
--   <li><a>LeftGCDMonoid</a></li>
--   <li><a>RightReductiveMonoid</a></li>
--   <li><a>RightCancellativeMonoid</a></li>
--   <li><a>RightGCDMonoid</a></li>
--   </ul>
module Data.Monoid.Cancellative

-- | Class of all Abelian ({i.e.}, commutative) monoids that satisfy the
--   commutativity property:
--   
--   <pre>
--   a &lt;&gt; b == b &lt;&gt; a
--   </pre>
class Monoid m => CommutativeMonoid m

-- | Class of Abelian monoids with a partial inverse for the Monoid
--   <a>&lt;&gt;</a> operation. The inverse operation <a>&lt;/&gt;</a> must
--   satisfy the following laws:
--   
--   <pre>
--   maybe a (b &lt;&gt;) (a &lt;/&gt; b) == a
--   maybe a (&lt;&gt; b) (a &lt;/&gt; b) == a
--   </pre>
class (CommutativeMonoid m, LeftReductiveMonoid m, RightReductiveMonoid m) => ReductiveMonoid m
(</>) :: ReductiveMonoid m => m -> m -> Maybe m

-- | Subclass of <a>ReductiveMonoid</a> where <a>&lt;/&gt;</a> is a
--   complete inverse of the Monoid <a>&lt;&gt;</a> operation. The class
--   instances must satisfy the following additional laws:
--   
--   <pre>
--   (a &lt;&gt; b) &lt;/&gt; a == Just b
--   (a &lt;&gt; b) &lt;/&gt; b == Just a
--   </pre>
class (LeftCancellativeMonoid m, RightCancellativeMonoid m, ReductiveMonoid m) => CancellativeMonoid m

-- | Class of Abelian monoids that allow the greatest common denominator to
--   be found for any two given values. The operations must satisfy the
--   following laws:
--   
--   <pre>
--   gcd a b == commonPrefix a b == commonSuffix a b
--   Just a' = a &lt;/&gt; p &amp;&amp; Just b' = b &lt;/&gt; p
--      where p = gcd a b
--   </pre>
--   
--   If a <a>GCDMonoid</a> happens to also be a <a>CancellativeMonoid</a>,
--   it should additionally satisfy the following laws:
--   
--   <pre>
--   gcd (a &lt;&gt; b) (a &lt;&gt; c) == a &lt;&gt; gcd b c
--   gcd (a &lt;&gt; c) (b &lt;&gt; c) == gcd a b &lt;&gt; c
--   </pre>
class (ReductiveMonoid m, LeftGCDMonoid m, RightGCDMonoid m) => GCDMonoid m
gcd :: GCDMonoid m => m -> m -> m

-- | Class of monoids with a left inverse of <a>mappend</a>, satisfying the
--   following law:
--   
--   <pre>
--   isPrefixOf a b == isJust (stripPrefix a b)
--   maybe b (a &lt;&gt;) (stripPrefix a b) == b
--   a `isPrefixOf` (a &lt;&gt; b)
--   </pre>
--   
--   | Every instance definition has to implement at least the
--   <a>stripPrefix</a> method. Its complexity should be no worse than
--   linear in the length of the prefix argument.
class Monoid m => LeftReductiveMonoid m where isPrefixOf a b = isJust (stripPrefix a b)
isPrefixOf :: LeftReductiveMonoid m => m -> m -> Bool
stripPrefix :: LeftReductiveMonoid m => m -> m -> Maybe m

-- | Class of monoids with a right inverse of <a>mappend</a>, satisfying
--   the following law:
--   
--   <pre>
--   isSuffixOf a b == isJust (stripSuffix a b)
--   maybe b (&lt;&gt; a) (stripSuffix a b) == b
--   b `isSuffixOf` (a &lt;&gt; b)
--   </pre>
--   
--   | Every instance definition has to implement at least the
--   <a>stripSuffix</a> method. Its complexity should be no worse than
--   linear in the length of the suffix argument.
class Monoid m => RightReductiveMonoid m where isSuffixOf a b = isJust (stripSuffix a b)
isSuffixOf :: RightReductiveMonoid m => m -> m -> Bool
stripSuffix :: RightReductiveMonoid m => m -> m -> Maybe m

-- | Subclass of <a>LeftReductiveMonoid</a> where <a>stripPrefix</a> is a
--   complete inverse of <a>&lt;&gt;</a>, satisfying the following
--   additional law:
--   
--   <pre>
--   stripPrefix a (a &lt;&gt; b) == Just b
--   </pre>
class LeftReductiveMonoid m => LeftCancellativeMonoid m

-- | Subclass of <a>LeftReductiveMonoid</a> where <a>stripPrefix</a> is a
--   complete inverse of <a>&lt;&gt;</a>, satisfying the following
--   additional law:
--   
--   <pre>
--   stripSuffix b (a &lt;&gt; b) == Just a
--   </pre>
class RightReductiveMonoid m => RightCancellativeMonoid m

-- | Class of monoids capable of finding the equivalent of greatest common
--   divisor on the left side of two monoidal values. The methods'
--   complexity should be no worse than linear in the length of the common
--   prefix. The following laws must be respected:
--   
--   <pre>
--   stripCommonPrefix a b == (p, a', b')
--      where p = commonPrefix a b
--            Just a' = stripPrefix p a
--            Just b' = stripPrefix p b
--   p == commonPrefix a b &amp;&amp; p &lt;&gt; a' == a &amp;&amp; p &lt;&gt; b' == b
--      where (p, a', b') = stripCommonPrefix a b
--   </pre>
class LeftReductiveMonoid m => LeftGCDMonoid m where commonPrefix x y = p where (p, _, _) = stripCommonPrefix x y stripCommonPrefix x y = (p, x', y') where p = commonPrefix x y Just x' = stripPrefix p x Just y' = stripPrefix p y
commonPrefix :: LeftGCDMonoid m => m -> m -> m
stripCommonPrefix :: LeftGCDMonoid m => m -> m -> (m, m, m)

-- | Class of monoids capable of finding the equivalent of greatest common
--   divisor on the right side of two monoidal values. The methods'
--   complexity must be no worse than linear in the length of the common
--   suffix. The following laws must be respected:
--   
--   <pre>
--   stripCommonSuffix a b == (a', b', s)
--      where s = commonSuffix a b
--            Just a' = stripSuffix p a
--            Just b' = stripSuffix p b
--   s == commonSuffix a b &amp;&amp; a' &lt;&gt; s == a &amp;&amp; b' &lt;&gt; s == b
--      where (a', b', s) = stripCommonSuffix a b
--   </pre>
class RightReductiveMonoid m => RightGCDMonoid m where commonSuffix x y = s where (_, _, s) = stripCommonSuffix x y stripCommonSuffix x y = (x', y', s) where s = commonSuffix x y Just x' = stripSuffix s x Just y' = stripSuffix s y
commonSuffix :: RightGCDMonoid m => m -> m -> m
stripCommonSuffix :: RightGCDMonoid m => m -> m -> (m, m, m)
instance Data.Monoid.Cancellative.CommutativeMonoid ()
instance Data.Monoid.Cancellative.ReductiveMonoid ()
instance Data.Monoid.Cancellative.CancellativeMonoid ()
instance Data.Monoid.Cancellative.GCDMonoid ()
instance Data.Monoid.Cancellative.LeftReductiveMonoid ()
instance Data.Monoid.Cancellative.RightReductiveMonoid ()
instance Data.Monoid.Cancellative.LeftCancellativeMonoid ()
instance Data.Monoid.Cancellative.RightCancellativeMonoid ()
instance Data.Monoid.Cancellative.LeftGCDMonoid ()
instance Data.Monoid.Cancellative.RightGCDMonoid ()
instance Data.Monoid.Cancellative.CommutativeMonoid a => Data.Monoid.Cancellative.CommutativeMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.ReductiveMonoid a => Data.Monoid.Cancellative.ReductiveMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.CancellativeMonoid a => Data.Monoid.Cancellative.CancellativeMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.GCDMonoid a => Data.Monoid.Cancellative.GCDMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.LeftReductiveMonoid a => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.RightReductiveMonoid a => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.LeftCancellativeMonoid a => Data.Monoid.Cancellative.RightCancellativeMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.RightCancellativeMonoid a => Data.Monoid.Cancellative.LeftCancellativeMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.LeftGCDMonoid a => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Dual a)
instance Data.Monoid.Cancellative.RightGCDMonoid a => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Dual a)
instance GHC.Num.Num a => Data.Monoid.Cancellative.CommutativeMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.ReductiveMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.CancellativeMonoid (Data.Monoid.Sum a)
instance (GHC.Real.Integral a, GHC.Classes.Ord a) => Data.Monoid.Cancellative.GCDMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.LeftCancellativeMonoid (Data.Monoid.Sum a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.RightCancellativeMonoid (Data.Monoid.Sum a)
instance (GHC.Real.Integral a, GHC.Classes.Ord a) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Sum a)
instance (GHC.Real.Integral a, GHC.Classes.Ord a) => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Sum a)
instance GHC.Num.Num a => Data.Monoid.Cancellative.CommutativeMonoid (Data.Monoid.Product a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.ReductiveMonoid (Data.Monoid.Product a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.GCDMonoid (Data.Monoid.Product a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Product a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Product a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Product a)
instance GHC.Real.Integral a => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Product a)
instance (Data.Monoid.Cancellative.CommutativeMonoid a, Data.Monoid.Cancellative.CommutativeMonoid b) => Data.Monoid.Cancellative.CommutativeMonoid (a, b)
instance (Data.Monoid.Cancellative.ReductiveMonoid a, Data.Monoid.Cancellative.ReductiveMonoid b) => Data.Monoid.Cancellative.ReductiveMonoid (a, b)
instance (Data.Monoid.Cancellative.CancellativeMonoid a, Data.Monoid.Cancellative.CancellativeMonoid b) => Data.Monoid.Cancellative.CancellativeMonoid (a, b)
instance (Data.Monoid.Cancellative.GCDMonoid a, Data.Monoid.Cancellative.GCDMonoid b) => Data.Monoid.Cancellative.GCDMonoid (a, b)
instance (Data.Monoid.Cancellative.LeftReductiveMonoid a, Data.Monoid.Cancellative.LeftReductiveMonoid b) => Data.Monoid.Cancellative.LeftReductiveMonoid (a, b)
instance (Data.Monoid.Cancellative.RightReductiveMonoid a, Data.Monoid.Cancellative.RightReductiveMonoid b) => Data.Monoid.Cancellative.RightReductiveMonoid (a, b)
instance (Data.Monoid.Cancellative.LeftCancellativeMonoid a, Data.Monoid.Cancellative.LeftCancellativeMonoid b) => Data.Monoid.Cancellative.LeftCancellativeMonoid (a, b)
instance (Data.Monoid.Cancellative.RightCancellativeMonoid a, Data.Monoid.Cancellative.RightCancellativeMonoid b) => Data.Monoid.Cancellative.RightCancellativeMonoid (a, b)
instance (Data.Monoid.Cancellative.LeftGCDMonoid a, Data.Monoid.Cancellative.LeftGCDMonoid b) => Data.Monoid.Cancellative.LeftGCDMonoid (a, b)
instance (Data.Monoid.Cancellative.RightGCDMonoid a, Data.Monoid.Cancellative.RightGCDMonoid b) => Data.Monoid.Cancellative.RightGCDMonoid (a, b)
instance Data.Monoid.Cancellative.LeftReductiveMonoid x => Data.Monoid.Cancellative.LeftReductiveMonoid (GHC.Base.Maybe x)
instance Data.Monoid.Cancellative.LeftGCDMonoid x => Data.Monoid.Cancellative.LeftGCDMonoid (GHC.Base.Maybe x)
instance Data.Monoid.Cancellative.RightReductiveMonoid x => Data.Monoid.Cancellative.RightReductiveMonoid (GHC.Base.Maybe x)
instance Data.Monoid.Cancellative.RightGCDMonoid x => Data.Monoid.Cancellative.RightGCDMonoid (GHC.Base.Maybe x)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.CommutativeMonoid (Data.Set.Base.Set a)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Set.Base.Set a)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Set.Base.Set a)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.ReductiveMonoid (Data.Set.Base.Set a)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Set.Base.Set a)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.RightGCDMonoid (Data.Set.Base.Set a)
instance GHC.Classes.Ord a => Data.Monoid.Cancellative.GCDMonoid (Data.Set.Base.Set a)
instance Data.Monoid.Cancellative.CommutativeMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Cancellative.LeftReductiveMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Cancellative.RightReductiveMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Cancellative.ReductiveMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Cancellative.LeftGCDMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Cancellative.RightGCDMonoid Data.IntSet.Base.IntSet
instance Data.Monoid.Cancellative.GCDMonoid Data.IntSet.Base.IntSet
instance GHC.Classes.Ord k => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Map.Base.Map k a)
instance (GHC.Classes.Ord k, GHC.Classes.Eq a) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Map.Base.Map k a)
instance Data.Monoid.Cancellative.LeftReductiveMonoid (Data.IntMap.Base.IntMap a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftGCDMonoid (Data.IntMap.Base.IntMap a)
instance GHC.Classes.Eq x => Data.Monoid.Cancellative.LeftReductiveMonoid [x]
instance GHC.Classes.Eq x => Data.Monoid.Cancellative.LeftCancellativeMonoid [x]
instance GHC.Classes.Eq x => Data.Monoid.Cancellative.LeftGCDMonoid [x]
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftCancellativeMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.RightCancellativeMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.RightGCDMonoid (Data.Sequence.Seq a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Vector.Vector a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Vector.Vector a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftCancellativeMonoid (Data.Vector.Vector a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.RightCancellativeMonoid (Data.Vector.Vector a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Vector.Vector a)
instance GHC.Classes.Eq a => Data.Monoid.Cancellative.RightGCDMonoid (Data.Vector.Vector a)
instance Data.Monoid.Cancellative.LeftReductiveMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Cancellative.RightReductiveMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Cancellative.LeftCancellativeMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Cancellative.RightCancellativeMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Cancellative.LeftGCDMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Cancellative.RightGCDMonoid Data.ByteString.Internal.ByteString
instance Data.Monoid.Cancellative.LeftReductiveMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Cancellative.RightReductiveMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Cancellative.LeftCancellativeMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Cancellative.RightCancellativeMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Cancellative.LeftGCDMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Cancellative.RightGCDMonoid Data.ByteString.Lazy.Internal.ByteString
instance Data.Monoid.Cancellative.LeftReductiveMonoid Data.Text.Internal.Text
instance Data.Monoid.Cancellative.RightReductiveMonoid Data.Text.Internal.Text
instance Data.Monoid.Cancellative.LeftCancellativeMonoid Data.Text.Internal.Text
instance Data.Monoid.Cancellative.RightCancellativeMonoid Data.Text.Internal.Text
instance Data.Monoid.Cancellative.LeftGCDMonoid Data.Text.Internal.Text
instance Data.Monoid.Cancellative.LeftReductiveMonoid Data.Text.Internal.Lazy.Text
instance Data.Monoid.Cancellative.RightReductiveMonoid Data.Text.Internal.Lazy.Text
instance Data.Monoid.Cancellative.LeftCancellativeMonoid Data.Text.Internal.Lazy.Text
instance Data.Monoid.Cancellative.RightCancellativeMonoid Data.Text.Internal.Lazy.Text
instance Data.Monoid.Cancellative.LeftGCDMonoid Data.Text.Internal.Lazy.Text


-- | This module defines the <a>TextualMonoid</a> class and several of its
--   instances.
module Data.Monoid.Textual

-- | The <a>TextualMonoid</a> class is an extension of
--   <a>FactorialMonoid</a> specialized for monoids that can contain
--   characters. Its methods are generally equivalent to their namesake
--   functions from <a>Data.List</a> and <a>Data.Text</a>, and they satisfy
--   the following laws:
--   
--   <pre>
--   unfoldr splitCharacterPrefix . fromString == id
--   splitCharacterPrefix . primePrefix == fmap (\(c, t)-&gt; (c, mempty)) . splitCharacterPrefix
--   
--   map f . fromString == fromString . List.map f
--   concatMap (fromString . f) . fromString == fromString . List.concatMap f
--   
--   foldl  ft fc a . fromString == List.foldl  fc a
--   foldr  ft fc a . fromString == List.foldr  fc a
--   foldl' ft fc a . fromString == List.foldl' fc a
--   
--   scanl f c . fromString == fromString . List.scanl f c
--   scanr f c . fromString == fromString . List.scanr f c
--   mapAccumL f a . fromString == fmap fromString . List.mapAccumL f a
--   mapAccumL f a . fromString == fmap fromString . List.mapAccumL f a
--   
--   takeWhile pt pc . fromString == fromString . takeWhile pc
--   dropWhile pt pc . fromString == fromString . dropWhile pc
--   
--   mconcat . intersperse (singleton c) . split (== c) == id
--   find p . fromString == List.find p
--   elem c . fromString == List.elem c
--   </pre>
--   
--   A <a>TextualMonoid</a> may contain non-character data insterspersed
--   between its characters. Every class method that returns a modified
--   <a>TextualMonoid</a> instance generally preserves this non-character
--   data. Methods like <a>foldr</a> can access both the non-character and
--   character data and expect two arguments for the two purposes. For each
--   of these methods there is also a simplified version with underscore in
--   name (like <a>foldr_</a>) that ignores the non-character data.
--   
--   All of the following expressions are identities:
--   
--   <pre>
--   map id
--   concatMap singleton
--   foldl  (&lt;&gt;) (\a c-&gt; a &lt;&gt; singleton c) mempty
--   foldr  (&lt;&gt;) ((&lt;&gt;) . singleton) mempty
--   foldl' (&lt;&gt;) (\a c-&gt; a &lt;&gt; singleton c) mempty
--   scanl1 (const id)
--   scanr1 const
--   uncurry (mapAccumL (,))
--   uncurry (mapAccumR (,))
--   takeWhile (const True) (const True)
--   dropWhile (const False) (const False)
--   toString undefined . fromString
--   </pre>
class (IsString t, LeftReductiveMonoid t, LeftGCDMonoid t, FactorialMonoid t) => TextualMonoid t where fromText = fromString . unpack singleton = fromString . (: []) characterPrefix = fmap fst . splitCharacterPrefix map f = concatMap (singleton . f) concatMap f = foldr mappend (mappend . f) mempty toString f = foldr (mappend . f) (:) [] all p = foldr (const id) ((&&) . p) True any p = foldr (const id) ((||) . p) False foldl ft fc = foldl (\ a prime -> maybe (ft a prime) (fc a) (characterPrefix prime)) foldr ft fc = foldr (\ prime -> maybe (ft prime) fc (characterPrefix prime)) foldl' ft fc = foldl' (\ a prime -> maybe (ft a prime) (fc a) (characterPrefix prime)) foldl_ = foldl const foldr_ = foldr (const id) foldl_' = foldl' const scanl f c = mappend (singleton c) . fst . foldl foldlOther (foldlChars f) (mempty, c) scanl1 f t = case (splitPrimePrefix t, splitCharacterPrefix t) of { (Nothing, _) -> t (Just (prefix, suffix), Nothing) -> mappend prefix (scanl1 f suffix) (Just _, Just (c, suffix)) -> scanl f c suffix } scanr f c = fst . foldr foldrOther (foldrChars f) (singleton c, c) scanr1 f = fst . foldr foldrOther fc (mempty, Nothing) where fc c (t, Nothing) = (mappend (singleton c) t, Just c) fc c1 (t, Just c2) = (mappend (singleton c') t, Just c') where c' = f c1 c2 mapAccumL f a0 = foldl ft fc (a0, mempty) where ft (a, t1) t2 = (a, mappend t1 t2) fc (a, t) c = (a', mappend t (singleton c')) where (a', c') = f a c mapAccumR f a0 = foldr ft fc (a0, mempty) where ft t1 (a, t2) = (a, mappend t1 t2) fc c (a, t) = (a', mappend (singleton c') t) where (a', c') = f a c takeWhile pt pc = fst . span pt pc dropWhile pt pc = snd . span pt pc span pt pc = span (\ prime -> maybe (pt prime) pc (characterPrefix prime)) break pt pc = break (\ prime -> maybe (pt prime) pc (characterPrefix prime)) spanMaybe s0 ft fc t0 = spanAfter id s0 t0 where spanAfter g s t = case splitPrimePrefix t of { Just (prime, rest) | Just s' <- maybe (ft s prime) (fc s) (characterPrefix prime) -> spanAfter (g . mappend prime) s' rest | otherwise -> (g mempty, t, s) Nothing -> (t0, t, s) } spanMaybe' s0 ft fc t0 = spanAfter id s0 t0 where spanAfter g s t = seq s $ case splitPrimePrefix t of { Just (prime, rest) | Just s' <- maybe (ft s prime) (fc s) (characterPrefix prime) -> spanAfter (g . mappend prime) s' rest | otherwise -> (g mempty, t, s) Nothing -> (t0, t, s) } takeWhile_ = takeWhile . const dropWhile_ = dropWhile . const break_ = break . const span_ = span . const spanMaybe_ s = spanMaybe s (const . Just) spanMaybe_' s = spanMaybe' s (const . Just) split p m = prefix : splitRest where (prefix, rest) = break (const False) p m splitRest = case splitCharacterPrefix rest of { Nothing -> [] Just (_, tl) -> split p tl } find p = foldr (const id) (\ c r -> if p c then Just c else r) Nothing elem c = any (== c)

-- | Contructs a new data type instance Like <a>fromString</a>, but from a
--   <a>Text</a> input instead of <a>String</a>.
--   
--   <pre>
--   fromText == fromString . Text.unpack
--   </pre>
fromText :: TextualMonoid t => Text -> t

-- | Creates a prime monoid containing a single character.
--   
--   <pre>
--   singleton c == fromString [c]
--   </pre>
singleton :: TextualMonoid t => Char -> t

-- | Specialized version of <a>splitPrimePrefix</a>. Every prime factor of
--   a <tt>Textual</tt> monoid must consist of a single character or no
--   character at all.
splitCharacterPrefix :: TextualMonoid t => t -> Maybe (Char, t)

-- | Extracts a single character that prefixes the monoid, if the monoid
--   begins with a character. Otherwise returns <a>Nothing</a>.
--   
--   <pre>
--   characterPrefix == fmap fst . splitCharacterPrefix
--   </pre>
characterPrefix :: TextualMonoid t => t -> Maybe Char

-- | Equivalent to <a>map</a> from <a>Data.List</a> with a <tt>Char -&gt;
--   Char</tt> function. Preserves all non-character data.
--   
--   <pre>
--   map f == concatMap (singleton . f)
--   </pre>
map :: TextualMonoid t => (Char -> Char) -> t -> t

-- | Equivalent to <a>concatMap</a> from <a>Data.List</a> with a <tt>Char
--   -&gt; String</tt> function. Preserves all non-character data.
concatMap :: TextualMonoid t => (Char -> t) -> t -> t

-- | Returns the list of characters the monoid contains, after having the
--   argument function convert all its non-character factors into
--   characters.
toString :: TextualMonoid t => (t -> String) -> t -> String

-- | Equivalent to <a>any</a> from <a>Data.List</a>. Ignores all
--   non-character data.
any :: TextualMonoid t => (Char -> Bool) -> t -> Bool

-- | Equivalent to <a>all</a> from <a>Data.List</a>. Ignores all
--   non-character data.
all :: TextualMonoid t => (Char -> Bool) -> t -> Bool

-- | The first argument folds over the non-character prime factors, the
--   second over characters. Otherwise equivalent to <a>foldl</a> from
--   <a>Data.List</a>.
foldl :: TextualMonoid t => (a -> t -> a) -> (a -> Char -> a) -> a -> t -> a

-- | Strict version of <a>foldl</a>.
foldl' :: TextualMonoid t => (a -> t -> a) -> (a -> Char -> a) -> a -> t -> a

-- | The first argument folds over the non-character prime factors, the
--   second over characters. Otherwise equivalent to 'List.foldl\'' from
--   <a>Data.List</a>.
foldr :: TextualMonoid t => (t -> a -> a) -> (Char -> a -> a) -> a -> t -> a

-- | Equivalent to <a>scanl</a> from <a>Data.List</a> when applied to a
--   <a>String</a>, but preserves all non-character data.
scanl :: TextualMonoid t => (Char -> Char -> Char) -> Char -> t -> t

-- | Equivalent to <a>scanl1</a> from <a>Data.List</a> when applied to a
--   <a>String</a>, but preserves all non-character data.
--   
--   <pre>
--   scanl f c == scanl1 f . (singleton c &lt;&gt;)
--   </pre>
scanl1 :: TextualMonoid t => (Char -> Char -> Char) -> t -> t

-- | Equivalent to <a>scanr</a> from <a>Data.List</a> when applied to a
--   <a>String</a>, but preserves all non-character data.
scanr :: TextualMonoid t => (Char -> Char -> Char) -> Char -> t -> t

-- | Equivalent to <a>scanr1</a> from <a>Data.List</a> when applied to a
--   <a>String</a>, but preserves all non-character data.
--   
--   <pre>
--   scanr f c == scanr1 f . (&lt;&gt; singleton c)
--   </pre>
scanr1 :: TextualMonoid t => (Char -> Char -> Char) -> t -> t

-- | Equivalent to <a>mapAccumL</a> from <a>Data.List</a> when applied to a
--   <a>String</a>, but preserves all non-character data.
mapAccumL :: TextualMonoid t => (a -> Char -> (a, Char)) -> a -> t -> (a, t)

-- | Equivalent to <a>mapAccumR</a> from <a>Data.List</a> when applied to a
--   <a>String</a>, but preserves all non-character data.
mapAccumR :: TextualMonoid t => (a -> Char -> (a, Char)) -> a -> t -> (a, t)

-- | The first predicate tests the non-character data, the second one the
--   characters. Otherwise equivalent to <a>takeWhile</a> from
--   <a>Data.List</a> when applied to a <a>String</a>.
takeWhile :: TextualMonoid t => (t -> Bool) -> (Char -> Bool) -> t -> t

-- | The first predicate tests the non-character data, the second one the
--   characters. Otherwise equivalent to <a>dropWhile</a> from
--   <a>Data.List</a> when applied to a <a>String</a>.
dropWhile :: TextualMonoid t => (t -> Bool) -> (Char -> Bool) -> t -> t

-- | 'break pt pc' is equivalent to |span (not . pt) (not . pc)|.
break :: TextualMonoid t => (t -> Bool) -> (Char -> Bool) -> t -> (t, t)

-- | 'span pt pc t' is equivalent to |(takeWhile pt pc t, dropWhile pt pc
--   t)|.
span :: TextualMonoid t => (t -> Bool) -> (Char -> Bool) -> t -> (t, t)

-- | A stateful variant of <a>span</a>, threading the result of the test
--   function as long as it returns <a>Just</a>.
spanMaybe :: TextualMonoid t => s -> (s -> t -> Maybe s) -> (s -> Char -> Maybe s) -> t -> (t, t, s)

-- | Strict version of <a>spanMaybe</a>.
spanMaybe' :: TextualMonoid t => s -> (s -> t -> Maybe s) -> (s -> Char -> Maybe s) -> t -> (t, t, s)

-- | Splits the monoid into components delimited by character separators
--   satisfying the given predicate. The characters satisfying the
--   predicate are not a part of the result.
--   
--   <pre>
--   split p == Factorial.split (maybe False p . characterPrefix)
--   </pre>
split :: TextualMonoid t => (Char -> Bool) -> t -> [t]

-- | Like <a>find</a> from <a>Data.List</a> when applied to a
--   <a>String</a>. Ignores non-character data.
find :: TextualMonoid t => (Char -> Bool) -> t -> Maybe Char

-- | Like <a>elem</a> from <a>Data.List</a> when applied to a
--   <a>String</a>. Ignores non-character data.
elem :: TextualMonoid t => Char -> t -> Bool

-- | <pre>
--   foldl_ = foldl const
--   </pre>
foldl_ :: TextualMonoid t => (a -> Char -> a) -> a -> t -> a
foldl_' :: TextualMonoid t => (a -> Char -> a) -> a -> t -> a
foldr_ :: TextualMonoid t => (Char -> a -> a) -> a -> t -> a

-- | <pre>
--   takeWhile_ = takeWhile . const
--   </pre>
takeWhile_ :: TextualMonoid t => Bool -> (Char -> Bool) -> t -> t

-- | <pre>
--   dropWhile_ = dropWhile . const
--   </pre>
dropWhile_ :: TextualMonoid t => Bool -> (Char -> Bool) -> t -> t

-- | <pre>
--   break_ = break . const
--   </pre>
break_ :: TextualMonoid t => Bool -> (Char -> Bool) -> t -> (t, t)

-- | <pre>
--   span_ = span . const
--   </pre>
span_ :: TextualMonoid t => Bool -> (Char -> Bool) -> t -> (t, t)

-- | <pre>
--   spanMaybe_ s = spanMaybe s (const . Just)
--   </pre>
spanMaybe_ :: TextualMonoid t => s -> (s -> Char -> Maybe s) -> t -> (t, t, s)
spanMaybe_' :: TextualMonoid t => s -> (s -> Char -> Maybe s) -> t -> (t, t, s)
instance Data.Monoid.Textual.TextualMonoid GHC.Base.String
instance Data.Monoid.Textual.TextualMonoid Data.Text.Internal.Text
instance Data.Monoid.Textual.TextualMonoid Data.Text.Internal.Lazy.Text
instance Data.Monoid.Textual.TextualMonoid (Data.Sequence.Seq GHC.Types.Char)
instance Data.String.IsString (Data.Vector.Vector GHC.Types.Char)
instance Data.Monoid.Textual.TextualMonoid (Data.Vector.Vector GHC.Types.Char)


-- | This module defines the <a>ByteStringUTF8</a> newtype wrapper around
--   <a>ByteString</a>, together with its <a>TextualMonoid</a> instance.
--   The <a>FactorialMonoid</a> instance of a wrapped <a>ByteStringUTF8</a>
--   value differs from the original <a>ByteString</a>: the prime
--   <a>factors</a> of the original value are its bytes, and for the
--   wrapped value the prime <a>factors</a> are its valid UTF8 byte
--   sequences. The following example session demonstrates the
--   relationship:
--   
--   <pre>
--   &gt; let utf8@(ByteStringUTF8 bs) = fromString "E=mc\xb2"
--   &gt; bs
--   "E=mc\194\178"
--   &gt; factors bs
--   ["E","=","m","c","\194","\178"]
--   &gt; utf8
--   "E=mc²"
--   &gt; factors utf8
--   ["E","=","m","c","²"]
--   </pre>
--   
--   The <a>TextualMonoid</a> instance follows the same logic, but it also
--   decodes all valid UTF8 sequences into characters. Any invalid UTF8
--   byte sequence from the original <a>ByteString</a> is preserved as a
--   single prime factor:
--   
--   <pre>
--   &gt; let utf8'@(ByteStringUTF8 bs') = ByteStringUTF8 (Data.ByteString.map pred bs)
--   &gt; bs'
--   "D&lt;lb\193\177"
--   &gt; factors bs'
--   ["D","&lt;","l","b","\193","\177"]
--   &gt; utf8'
--   "D&lt;lb\[193,177]"
--   &gt; factors utf8'
--   ["D","&lt;","l","b","\[193,177]"]
--   </pre>
module Data.Monoid.Instances.ByteString.UTF8
newtype ByteStringUTF8
ByteStringUTF8 :: ByteString -> ByteStringUTF8

-- | Takes a raw <a>ByteString</a> chunk and returns a pair of
--   <a>ByteStringUTF8</a> decoding the prefix of the chunk and the
--   remaining suffix that is either null or contains the incomplete last
--   character of the chunk.
decode :: ByteString -> (ByteStringUTF8, ByteString)
instance GHC.Classes.Ord Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance GHC.Classes.Eq Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance GHC.Base.Monoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Null.MonoidNull Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Cancellative.LeftReductiveMonoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Cancellative.LeftCancellativeMonoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Cancellative.LeftGCDMonoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance GHC.Show.Show Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.String.IsString Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Null.PositiveMonoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Factorial.FactorialMonoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8
instance Data.Monoid.Textual.TextualMonoid Data.Monoid.Instances.ByteString.UTF8.ByteStringUTF8


-- | This module defines the monoid transformer data type <a>Concat</a>.
module Data.Monoid.Instances.Concat

-- | <tt><a>Concat</a> a</tt> is a <tt>newtype</tt> wrapper around
--   <tt><a>Seq</a> a</tt>. The behaviour of the <tt><a>Concat</a> a</tt>
--   instances of monoid subclasses is identical to the behaviour of their
--   <tt>a</tt> instances, up to the <a>pure</a> isomorphism.
--   
--   The only purpose of <a>Concat</a> then is to change the performance
--   characteristics of various operations. Most importantly, injecting a
--   monoid into a <a>Concat</a> has the effect of making <a>mappend</a> a
--   logarithmic-time operation.
data Concat a
concatenate :: PositiveMonoid a => Seq a -> Concat a
extract :: Concat a -> Seq a
instance GHC.Show.Show a => GHC.Show.Show (Data.Monoid.Instances.Concat.Concat a)
instance (GHC.Classes.Eq a, GHC.Base.Monoid a) => GHC.Classes.Eq (Data.Monoid.Instances.Concat.Concat a)
instance (GHC.Classes.Ord a, GHC.Base.Monoid a) => GHC.Classes.Ord (Data.Monoid.Instances.Concat.Concat a)
instance GHC.Base.Functor Data.Monoid.Instances.Concat.Concat
instance GHC.Base.Applicative Data.Monoid.Instances.Concat.Concat
instance GHC.Base.Monoid (Data.Monoid.Instances.Concat.Concat a)
instance Data.Monoid.Null.MonoidNull (Data.Monoid.Instances.Concat.Concat a)
instance Data.Monoid.Null.PositiveMonoid (Data.Monoid.Instances.Concat.Concat a)
instance (Data.Monoid.Cancellative.LeftReductiveMonoid a, Data.Monoid.Null.MonoidNull a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Instances.Concat.Concat a)
instance (Data.Monoid.Null.MonoidNull a, Data.Monoid.Cancellative.RightReductiveMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Instances.Concat.Concat a)
instance (GHC.Classes.Eq a, Data.Monoid.Cancellative.LeftGCDMonoid a, Data.Monoid.Null.MonoidNull a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Instances.Concat.Concat a)
instance (GHC.Classes.Eq a, Data.Monoid.Cancellative.RightGCDMonoid a, Data.Monoid.Null.MonoidNull a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Instances.Concat.Concat a)
instance Data.Monoid.Factorial.FactorialMonoid a => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Instances.Concat.Concat a)
instance Data.String.IsString a => Data.String.IsString (Data.Monoid.Instances.Concat.Concat a)
instance (GHC.Classes.Eq a, Data.Monoid.Textual.TextualMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Textual.TextualMonoid (Data.Monoid.Instances.Concat.Concat a)


-- | This module defines the monoid transformer data type <a>Measured</a>.
module Data.Monoid.Instances.Measured

-- | <tt><a>Measured</a> a</tt> is a wrapper around the
--   <a>FactorialMonoid</a> <tt>a</tt> that memoizes the monoid's
--   <a>length</a> so it becomes a constant-time operation. The parameter
--   is restricted to the <a>StableFactorialMonoid</a> class, which
--   guarantees that <tt><a>length</a> (a &lt;&gt; b) == <a>length</a> a +
--   <a>length</a> b</tt>.
data Measured a

-- | Create a new <a>Measured</a> value.
measure :: FactorialMonoid a => a -> Measured a
extract :: Measured a -> a
instance GHC.Show.Show a => GHC.Show.Show (Data.Monoid.Instances.Measured.Measured a)
instance GHC.Classes.Eq a => GHC.Classes.Eq (Data.Monoid.Instances.Measured.Measured a)
instance GHC.Classes.Ord a => GHC.Classes.Ord (Data.Monoid.Instances.Measured.Measured a)
instance Data.Monoid.Factorial.StableFactorialMonoid a => GHC.Base.Monoid (Data.Monoid.Instances.Measured.Measured a)
instance Data.Monoid.Factorial.StableFactorialMonoid a => Data.Monoid.Null.MonoidNull (Data.Monoid.Instances.Measured.Measured a)
instance Data.Monoid.Factorial.StableFactorialMonoid a => Data.Monoid.Null.PositiveMonoid (Data.Monoid.Instances.Measured.Measured a)
instance (Data.Monoid.Cancellative.LeftReductiveMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Instances.Measured.Measured a)
instance (Data.Monoid.Cancellative.RightReductiveMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Instances.Measured.Measured a)
instance (Data.Monoid.Cancellative.LeftGCDMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Instances.Measured.Measured a)
instance (Data.Monoid.Cancellative.RightGCDMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Instances.Measured.Measured a)
instance Data.Monoid.Factorial.StableFactorialMonoid a => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Instances.Measured.Measured a)
instance Data.Monoid.Factorial.StableFactorialMonoid a => Data.Monoid.Factorial.StableFactorialMonoid (Data.Monoid.Instances.Measured.Measured a)
instance (Data.Monoid.Factorial.FactorialMonoid a, Data.String.IsString a) => Data.String.IsString (Data.Monoid.Instances.Measured.Measured a)
instance (GHC.Classes.Eq a, Data.Monoid.Textual.TextualMonoid a, Data.Monoid.Factorial.StableFactorialMonoid a) => Data.Monoid.Textual.TextualMonoid (Data.Monoid.Instances.Measured.Measured a)


-- | This module defines two monoid transformer data types,
--   <a>OffsetPositioned</a> and <a>LinePositioned</a>. Both data types add
--   a notion of the current position to their base monoid. In case of
--   <a>OffsetPositioned</a>, the current position is a simple integer
--   offset from the beginning of the monoid, and it can be applied to any
--   <a>StableFactorialMonoid</a>. The base monoid of <a>LinePositioned</a>
--   must be a <a>TextualMonoid</a>, but for the price it will keep track
--   of the current line and column numbers as well.
--   
--   All positions are zero-based:
--   
--   <pre>
--   &gt; let p = pure "abcd\nefgh\nijkl\nmnop\n" :: LinePositioned String
--   &gt; p
--   Line 0, column 0: "abcd\nefgh\nijkl\nmnop\n"
--   &gt; Data.Monoid.Factorial.drop 13 p
--   Line 2, column 3: "l\nmnop\n"
--   </pre>
module Data.Monoid.Instances.Positioned
data OffsetPositioned m
data LinePositioned m
extract :: Positioned p => p a -> a
position :: Positioned p => p a -> Int

-- | the current line
line :: LinePositioned m -> Int

-- | the current column
column :: LinePositioned m -> Int
instance GHC.Base.Functor Data.Monoid.Instances.Positioned.OffsetPositioned
instance GHC.Base.Functor Data.Monoid.Instances.Positioned.LinePositioned
instance GHC.Base.Applicative Data.Monoid.Instances.Positioned.OffsetPositioned
instance GHC.Base.Applicative Data.Monoid.Instances.Positioned.LinePositioned
instance Data.Monoid.Instances.Positioned.Positioned Data.Monoid.Instances.Positioned.OffsetPositioned
instance Data.Monoid.Instances.Positioned.Positioned Data.Monoid.Instances.Positioned.LinePositioned
instance GHC.Classes.Eq m => GHC.Classes.Eq (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance GHC.Classes.Eq m => GHC.Classes.Eq (Data.Monoid.Instances.Positioned.LinePositioned m)
instance GHC.Classes.Ord m => GHC.Classes.Ord (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance GHC.Classes.Ord m => GHC.Classes.Ord (Data.Monoid.Instances.Positioned.LinePositioned m)
instance GHC.Show.Show m => GHC.Show.Show (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance GHC.Show.Show m => GHC.Show.Show (Data.Monoid.Instances.Positioned.LinePositioned m)
instance Data.Monoid.Factorial.StableFactorialMonoid m => GHC.Base.Monoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m) => GHC.Base.Monoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Null.MonoidNull m) => Data.Monoid.Null.MonoidNull (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m, Data.Monoid.Null.MonoidNull m) => Data.Monoid.Null.MonoidNull (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Null.PositiveMonoid m) => Data.Monoid.Null.PositiveMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m, Data.Monoid.Null.PositiveMonoid m) => Data.Monoid.Null.PositiveMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Cancellative.LeftReductiveMonoid m) => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m, Data.Monoid.Cancellative.LeftReductiveMonoid m) => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Cancellative.LeftGCDMonoid m) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m, Data.Monoid.Cancellative.LeftGCDMonoid m) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Cancellative.RightReductiveMonoid m) => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m, Data.Monoid.Cancellative.RightReductiveMonoid m) => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Cancellative.RightGCDMonoid m) => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m, Data.Monoid.Cancellative.RightGCDMonoid m) => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance Data.Monoid.Factorial.StableFactorialMonoid m => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m) => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance Data.Monoid.Factorial.StableFactorialMonoid m => Data.Monoid.Factorial.StableFactorialMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m) => Data.Monoid.Factorial.StableFactorialMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)
instance Data.String.IsString m => Data.String.IsString (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance Data.String.IsString m => Data.String.IsString (Data.Monoid.Instances.Positioned.LinePositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m) => Data.Monoid.Textual.TextualMonoid (Data.Monoid.Instances.Positioned.OffsetPositioned m)
instance (Data.Monoid.Factorial.StableFactorialMonoid m, Data.Monoid.Textual.TextualMonoid m) => Data.Monoid.Textual.TextualMonoid (Data.Monoid.Instances.Positioned.LinePositioned m)


-- | This module defines the monoid transformer data type <a>Stateful</a>.
--   
--   <pre>
--   &gt; let s = setState [4] $ pure "data" :: Stateful [Int] String
--   &gt; s
--   Stateful ("data",[4])
--   &gt; factors s
--   [Stateful ("d",[]),Stateful ("a",[]),Stateful ("t",[]),Stateful ("a",[]),Stateful ("",[4])]
--   </pre>
module Data.Monoid.Instances.Stateful

-- | <tt><a>Stateful</a> a b</tt> is a wrapper around the <a>Monoid</a>
--   <tt>b</tt> that carries the state <tt>a</tt> along. The state type
--   <tt>a</tt> must be a monoid as well if <a>Stateful</a> is to be of any
--   use. In the <a>FactorialMonoid</a> and <a>TextualMonoid</a> class
--   instances, the monoid <tt>b</tt> has the priority and the state
--   <tt>a</tt> is left for the end.
newtype Stateful a b
Stateful :: (b, a) -> Stateful a b
extract :: Stateful a b -> b
state :: Stateful a b -> a
setState :: a -> Stateful a b -> Stateful a b
instance (GHC.Show.Show a, GHC.Show.Show b) => GHC.Show.Show (Data.Monoid.Instances.Stateful.Stateful a b)
instance (GHC.Classes.Ord a, GHC.Classes.Ord b) => GHC.Classes.Ord (Data.Monoid.Instances.Stateful.Stateful a b)
instance (GHC.Classes.Eq a, GHC.Classes.Eq b) => GHC.Classes.Eq (Data.Monoid.Instances.Stateful.Stateful a b)
instance GHC.Base.Functor (Data.Monoid.Instances.Stateful.Stateful a)
instance GHC.Base.Monoid a => GHC.Base.Applicative (Data.Monoid.Instances.Stateful.Stateful a)
instance (GHC.Base.Monoid a, GHC.Base.Monoid b) => GHC.Base.Monoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Null.MonoidNull a, Data.Monoid.Null.MonoidNull b) => Data.Monoid.Null.MonoidNull (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Null.PositiveMonoid a, Data.Monoid.Null.PositiveMonoid b) => Data.Monoid.Null.PositiveMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Cancellative.LeftReductiveMonoid a, Data.Monoid.Cancellative.LeftReductiveMonoid b) => Data.Monoid.Cancellative.LeftReductiveMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Cancellative.RightReductiveMonoid a, Data.Monoid.Cancellative.RightReductiveMonoid b) => Data.Monoid.Cancellative.RightReductiveMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Cancellative.LeftGCDMonoid a, Data.Monoid.Cancellative.LeftGCDMonoid b) => Data.Monoid.Cancellative.LeftGCDMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Cancellative.RightGCDMonoid a, Data.Monoid.Cancellative.RightGCDMonoid b) => Data.Monoid.Cancellative.RightGCDMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Factorial.FactorialMonoid a, Data.Monoid.Factorial.FactorialMonoid b) => Data.Monoid.Factorial.FactorialMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Factorial.StableFactorialMonoid a, Data.Monoid.Factorial.StableFactorialMonoid b) => Data.Monoid.Factorial.StableFactorialMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
instance (GHC.Base.Monoid a, Data.String.IsString b) => Data.String.IsString (Data.Monoid.Instances.Stateful.Stateful a b)
instance (Data.Monoid.Cancellative.LeftGCDMonoid a, Data.Monoid.Factorial.FactorialMonoid a, Data.Monoid.Textual.TextualMonoid b) => Data.Monoid.Textual.TextualMonoid (Data.Monoid.Instances.Stateful.Stateful a b)
