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


-- | A Testing Framework for Haskell
--   
--   Hspec is a testing framework for Haskell. It is inspired by the Ruby
--   library RSpec. Some of Hspec's distinctive features are:
--   
--   <ul>
--   <li>a friendly DSL for defining tests</li>
--   <li>integration with QuickCheck, SmallCheck, and HUnit</li>
--   <li>parallel test execution</li>
--   <li>automatic discovery of test files</li>
--   </ul>
--   
--   The Hspec Manual is at <a>http://hspec.github.io/</a>.
@package hspec
@version 2.5.5



-- | <i>Deprecated: use <a>Test.Hspec.Core.Spec</a> instead</i>
module Test.Hspec.Core

-- | <a>pendingWith</a> is similar to <a>pending</a>, but it takes an
--   additional string argument that can be used to specify the reason for
--   why the spec item is pending.
pendingWith :: HasCallStack -> String -> Expectation

-- | <a>pending</a> can be used to mark a spec item as pending.
--   
--   If you want to textually specify a behavior but do not have an example
--   yet, use this:
--   
--   <pre>
--   describe "fancyFormatter" $ do
--     it "can format text in a way that everyone likes" $
--       pending
--   </pre>
pending :: HasCallStack -> Expectation

-- | <a>sequential</a> marks all spec items of the given spec to be
--   evaluated sequentially.
sequential :: () => SpecWith a -> SpecWith a

-- | <a>parallel</a> marks all spec items of the given spec to be safe for
--   parallel evaluation.
parallel :: () => SpecWith a -> SpecWith a

-- | <tt>xspecify</tt> is an alias for <a>xit</a>.
xspecify :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | Changing <a>it</a> to <a>xit</a> marks the corresponding spec item as
--   pending.
--   
--   This can be used to temporarily disable a spec item.
xit :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | <tt>specify</tt> is an alias for <a>it</a>.
specify :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | <tt>xcontext</tt> is an alias for <a>xdescribe</a>.
xcontext :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | Changing <a>describe</a> to <a>xdescribe</a> marks all spec items of
--   the corresponding subtree as pending.
--   
--   This can be used to temporarily disable spec items.
xdescribe :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | <tt>context</tt> is an alias for <a>describe</a>.
context :: HasCallStack => String -> SpecWith a -> SpecWith a
modifyParams :: () => Params -> Params -> SpecWith a -> SpecWith a
mapSpecItem_ :: () => Item a -> Item a -> SpecWith a -> SpecWith a
mapSpecItem :: () => ActionWith a -> ActionWith b -> Item a -> Item b -> SpecWith a -> SpecWith b

-- | Run an IO action while constructing the spec tree.
--   
--   <a>SpecM</a> is a monad to construct a spec tree, without executing
--   any spec items. <tt>runIO</tt> allows you to run IO actions during
--   this construction phase. The IO action is always run when the spec
--   tree is constructed (e.g. even when <tt>--dry-run</tt> is specified).
--   If you do not need the result of the IO action to construct the spec
--   tree, <a>beforeAll</a> may be more suitable for your use case.
runIO :: () => IO r -> SpecM a r

-- | Create a <a>Spec</a> from a forest of <a>SpecTree</a>s.
fromSpecList :: () => [SpecTree a] -> SpecWith a

-- | Convert a <a>Spec</a> to a forest of <a>SpecTree</a>s.
runSpecM :: () => SpecWith a -> IO [SpecTree a]
type Spec = SpecWith ()
type SpecWith a = SpecM a ()

-- | A writer monad for <a>SpecTree</a> forests
newtype SpecM a r
SpecM :: WriterT [SpecTree a] IO r -> SpecM a r
location :: HasCallStack -> Maybe Location

-- | The <tt>specItem</tt> function creates a spec item.
specItem :: (HasCallStack, Example a) => String -> a -> SpecTree Arg a

-- | The <tt>specGroup</tt> function combines a list of specs into a larger
--   spec.
specGroup :: HasCallStack => String -> [SpecTree a] -> SpecTree a

-- | Internal tree data structure
data Tree c a
Node :: String -> [Tree c a] -> Tree c a
NodeWithCleanup :: c -> [Tree c a] -> Tree c a
Leaf :: a -> Tree c a

-- | A tree is used to represent a spec internally. The tree is parametrize
--   over the type of cleanup actions and the type of the actual spec
--   items.
type SpecTree a = Tree ActionWith a Item a

-- | <tt>Item</tt> is used to represent spec items internally. A spec item
--   consists of:
--   
--   <ul>
--   <li>a textual description of a desired behavior</li>
--   <li>an example for that behavior</li>
--   <li>additional meta information</li>
--   </ul>
--   
--   Everything that is an instance of the <a>Example</a> type class can be
--   used as an example, including QuickCheck properties, Hspec
--   expectations and HUnit assertions.
data Item a
Item :: String -> Maybe Location -> Maybe Bool -> Params -> ActionWith a -> IO () -> ProgressCallback -> IO Result -> Item a

-- | Textual description of behavior
[itemRequirement] :: Item a -> String

-- | Source location of the spec item
[itemLocation] :: Item a -> Maybe Location

-- | A flag that indicates whether it is safe to evaluate this spec item in
--   parallel with other spec items
[itemIsParallelizable] :: Item a -> Maybe Bool

-- | Example for behavior
[itemExample] :: Item a -> Params -> ActionWith a -> IO () -> ProgressCallback -> IO Result
safeEvaluateExample :: Example e => e -> Params -> ActionWith Arg e -> IO () -> ProgressCallback -> IO Result
defaultParams :: Params

-- | A type class for examples
class Example e where {
    type family Arg e :: *;
}
evaluateExample :: Example e => e -> Params -> ActionWith Arg e -> IO () -> ProgressCallback -> IO Result
data Params
Params :: Args -> Int -> Params
[paramsQuickCheckArgs] :: Params -> Args
[paramsSmallCheckDepth] :: Params -> Int
type Progress = (Int, Int)
type ProgressCallback = Progress -> IO ()

-- | An <a>IO</a> action that expects an argument of type <tt>a</tt>
type ActionWith a = a -> IO ()

-- | The result of running an example
data Result
Result :: String -> ResultStatus -> Result
[resultInfo] :: Result -> String
[resultStatus] :: Result -> ResultStatus
data ResultStatus
Success :: ResultStatus
Pending :: Maybe Location -> Maybe String -> ResultStatus
Failure :: Maybe Location -> FailureReason -> ResultStatus
data FailureReason
NoReason :: FailureReason
Reason :: String -> FailureReason
ExpectedButGot :: Maybe String -> String -> String -> FailureReason
Error :: Maybe String -> SomeException -> FailureReason

-- | <tt>Location</tt> is used to represent source locations.
data Location
Location :: FilePath -> Int -> Int -> Location
[locationFile] :: Location -> FilePath
[locationLine] :: Location -> Int
[locationColumn] :: Location -> Int
describe :: String -> [SpecTree a] -> SpecTree a
it :: Example a => String -> a -> SpecTree (Arg a)

module Test.Hspec.Formatters


-- | <i>Warning: This module is used by <tt>hspec-discover</tt>. It is not
--   part of the public API and may change at any time.</i>
module Test.Hspec.Discover
type Spec = SpecWith ()

-- | Run given spec and write a report to <a>stdout</a>. Exit with
--   <a>exitFailure</a> if at least one spec item fails.
hspec :: Spec -> IO ()
class IsFormatter a
toFormatter :: IsFormatter a => a -> IO Formatter
hspecWithFormatter :: IsFormatter a => a -> Spec -> IO ()
postProcessSpec :: FilePath -> Spec -> Spec

-- | The <tt>describe</tt> function combines a list of specs into a larger
--   spec.
describe :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | Append two lists, i.e.,
--   
--   <pre>
--   [x1, ..., xm] ++ [y1, ..., yn] == [x1, ..., xm, y1, ..., yn]
--   [x1, ..., xm] ++ [y1, ...] == [x1, ..., xm, y1, ...]
--   </pre>
--   
--   If the first list is not finite, the result is the first list.
(++) :: () => [a] -> [a] -> [a]
infixr 5 ++

-- | The value of <tt>seq a b</tt> is bottom if <tt>a</tt> is bottom, and
--   otherwise equal to <tt>b</tt>. In other words, it evaluates the first
--   argument <tt>a</tt> to weak head normal form (WHNF). <tt>seq</tt> is
--   usually introduced to improve performance by avoiding unneeded
--   laziness.
--   
--   A note on evaluation order: the expression <tt>seq a b</tt> does
--   <i>not</i> guarantee that <tt>a</tt> will be evaluated before
--   <tt>b</tt>. The only guarantee given by <tt>seq</tt> is that the both
--   <tt>a</tt> and <tt>b</tt> will be evaluated before <tt>seq</tt>
--   returns a value. In particular, this means that <tt>b</tt> may be
--   evaluated before <tt>a</tt>. If you need to guarantee a specific order
--   of evaluation, you must use the function <tt>pseq</tt> from the
--   "parallel" package.
seq :: () => a -> b -> b

-- | <a>filter</a>, applied to a predicate and a list, returns the list of
--   those elements that satisfy the predicate; i.e.,
--   
--   <pre>
--   filter p xs = [ x | x &lt;- xs, p x]
--   </pre>
filter :: () => a -> Bool -> [a] -> [a]

-- | <a>zip</a> takes two lists and returns a list of corresponding pairs.
--   If one input list is short, excess elements of the longer list are
--   discarded.
--   
--   <a>zip</a> is right-lazy:
--   
--   <pre>
--   zip [] _|_ = []
--   </pre>
zip :: () => [a] -> [b] -> [(a, b)]

-- | The <a>print</a> function outputs a value of any printable type to the
--   standard output device. Printable types are those that are instances
--   of class <a>Show</a>; <a>print</a> converts values to strings for
--   output using the <a>show</a> operation and adds a newline.
--   
--   For example, a program to print the first 20 integers and their powers
--   of 2 could be written as:
--   
--   <pre>
--   main = print ([(n, 2^n) | n &lt;- [0..19]])
--   </pre>
print :: Show a => a -> IO ()

-- | Extract the first component of a pair.
fst :: () => (a, b) -> a

-- | Extract the second component of a pair.
snd :: () => (a, b) -> b

-- | <a>otherwise</a> is defined as the value <a>True</a>. It helps to make
--   guards more readable. eg.
--   
--   <pre>
--   f x | x &lt; 0     = ...
--       | otherwise = ...
--   </pre>
otherwise :: Bool

-- | <a>map</a> <tt>f xs</tt> is the list obtained by applying <tt>f</tt>
--   to each element of <tt>xs</tt>, i.e.,
--   
--   <pre>
--   map f [x1, x2, ..., xn] == [f x1, f x2, ..., f xn]
--   map f [x1, x2, ...] == [f x1, f x2, ...]
--   </pre>
map :: () => a -> b -> [a] -> [b]

-- | Application operator. This operator is redundant, since ordinary
--   application <tt>(f x)</tt> means the same as <tt>(f <a>$</a> x)</tt>.
--   However, <a>$</a> has low, right-associative binding precedence, so it
--   sometimes allows parentheses to be omitted; for example:
--   
--   <pre>
--   f $ g $ h x  =  f (g (h x))
--   </pre>
--   
--   It is also useful in higher-order situations, such as <tt><a>map</a>
--   (<a>$</a> 0) xs</tt>, or <tt><a>zipWith</a> (<a>$</a>) fs xs</tt>.
($) :: () => a -> b -> a -> b
infixr 0 $

-- | general coercion from integral types
fromIntegral :: (Integral a, Num b) => a -> b

-- | general coercion to fractional types
realToFrac :: (Real a, Fractional b) => a -> b

-- | The <a>Bounded</a> class is used to name the upper and lower limits of
--   a type. <a>Ord</a> is not a superclass of <a>Bounded</a> since types
--   that are not totally ordered may also have upper and lower bounds.
--   
--   The <a>Bounded</a> class may be derived for any enumeration type;
--   <a>minBound</a> is the first constructor listed in the <tt>data</tt>
--   declaration and <a>maxBound</a> is the last. <a>Bounded</a> may also
--   be derived for single-constructor datatypes whose constituent types
--   are in <a>Bounded</a>.
class Bounded a
minBound :: Bounded a => a
maxBound :: Bounded a => a

-- | Class <a>Enum</a> defines operations on sequentially ordered types.
--   
--   The <tt>enumFrom</tt>... methods are used in Haskell's translation of
--   arithmetic sequences.
--   
--   Instances of <a>Enum</a> may be derived for any enumeration type
--   (types whose constructors have no fields). The nullary constructors
--   are assumed to be numbered left-to-right by <a>fromEnum</a> from
--   <tt>0</tt> through <tt>n-1</tt>. See Chapter 10 of the <i>Haskell
--   Report</i> for more details.
--   
--   For any type that is an instance of class <a>Bounded</a> as well as
--   <a>Enum</a>, the following should hold:
--   
--   <ul>
--   <li>The calls <tt><a>succ</a> <a>maxBound</a></tt> and <tt><a>pred</a>
--   <a>minBound</a></tt> should result in a runtime error.</li>
--   <li><a>fromEnum</a> and <a>toEnum</a> should give a runtime error if
--   the result value is not representable in the result type. For example,
--   <tt><a>toEnum</a> 7 :: <a>Bool</a></tt> is an error.</li>
--   <li><a>enumFrom</a> and <a>enumFromThen</a> should be defined with an
--   implicit bound, thus:</li>
--   </ul>
--   
--   <pre>
--   enumFrom     x   = enumFromTo     x maxBound
--   enumFromThen x y = enumFromThenTo x y bound
--     where
--       bound | fromEnum y &gt;= fromEnum x = maxBound
--             | otherwise                = minBound
--   </pre>
class Enum a

-- | the successor of a value. For numeric types, <a>succ</a> adds 1.
succ :: Enum a => a -> a

-- | the predecessor of a value. For numeric types, <a>pred</a> subtracts
--   1.
pred :: Enum a => a -> a

-- | Convert from an <a>Int</a>.
toEnum :: Enum a => Int -> a

-- | Convert to an <a>Int</a>. It is implementation-dependent what
--   <a>fromEnum</a> returns when applied to a value that is too large to
--   fit in an <a>Int</a>.
fromEnum :: Enum a => a -> Int

-- | Used in Haskell's translation of <tt>[n..]</tt>.
enumFrom :: Enum a => a -> [a]

-- | Used in Haskell's translation of <tt>[n,n'..]</tt>.
enumFromThen :: Enum a => a -> a -> [a]

-- | Used in Haskell's translation of <tt>[n..m]</tt>.
enumFromTo :: Enum a => a -> a -> [a]

-- | Used in Haskell's translation of <tt>[n,n'..m]</tt>.
enumFromThenTo :: Enum a => a -> a -> a -> [a]

-- | The <a>Eq</a> class defines equality (<a>==</a>) and inequality
--   (<a>/=</a>). All the basic datatypes exported by the <a>Prelude</a>
--   are instances of <a>Eq</a>, and <a>Eq</a> may be derived for any
--   datatype whose constituents are also instances of <a>Eq</a>.
--   
--   Minimal complete definition: either <a>==</a> or <a>/=</a>.
class Eq a
(==) :: Eq a => a -> a -> Bool
(/=) :: Eq a => a -> a -> Bool

-- | Trigonometric and hyperbolic functions and related functions.
class Fractional a => Floating a
pi :: Floating a => a
exp :: Floating a => a -> a
log :: Floating a => a -> a
sqrt :: Floating a => a -> a
(**) :: Floating a => a -> a -> a
logBase :: Floating a => a -> a -> a
sin :: Floating a => a -> a
cos :: Floating a => a -> a
tan :: Floating a => a -> a
asin :: Floating a => a -> a
acos :: Floating a => a -> a
atan :: Floating a => a -> a
sinh :: Floating a => a -> a
cosh :: Floating a => a -> a
tanh :: Floating a => a -> a
asinh :: Floating a => a -> a
acosh :: Floating a => a -> a
atanh :: Floating a => a -> a

-- | Fractional numbers, supporting real division.
class Num a => Fractional a

-- | fractional division
(/) :: Fractional a => a -> a -> a

-- | reciprocal fraction
recip :: Fractional a => a -> a

-- | Conversion from a <a>Rational</a> (that is <tt><a>Ratio</a>
--   <a>Integer</a></tt>). A floating literal stands for an application of
--   <a>fromRational</a> to a value of type <a>Rational</a>, so such
--   literals have type <tt>(<a>Fractional</a> a) =&gt; a</tt>.
fromRational :: Fractional a => Rational -> a

-- | Integral numbers, supporting integer division.
class (Real a, Enum a) => Integral a

-- | integer division truncated toward zero
quot :: Integral a => a -> a -> a

-- | integer remainder, satisfying
--   
--   <pre>
--   (x `quot` y)*y + (x `rem` y) == x
--   </pre>
rem :: Integral a => a -> a -> a

-- | integer division truncated toward negative infinity
div :: Integral a => a -> a -> a

-- | integer modulus, satisfying
--   
--   <pre>
--   (x `div` y)*y + (x `mod` y) == x
--   </pre>
mod :: Integral a => a -> a -> a

-- | simultaneous <a>quot</a> and <a>rem</a>
quotRem :: Integral a => a -> a -> (a, a)

-- | simultaneous <a>div</a> and <a>mod</a>
divMod :: Integral a => a -> a -> (a, a)

-- | conversion to <a>Integer</a>
toInteger :: Integral a => a -> Integer

-- | The <a>Monad</a> class defines the basic operations over a
--   <i>monad</i>, a concept from a branch of mathematics known as
--   <i>category theory</i>. From the perspective of a Haskell programmer,
--   however, it is best to think of a monad as an <i>abstract datatype</i>
--   of actions. Haskell's <tt>do</tt> expressions provide a convenient
--   syntax for writing monadic expressions.
--   
--   Instances of <a>Monad</a> should satisfy the following laws:
--   
--   <ul>
--   <li><pre><a>return</a> a <a>&gt;&gt;=</a> k = k a</pre></li>
--   <li><pre>m <a>&gt;&gt;=</a> <a>return</a> = m</pre></li>
--   <li><pre>m <a>&gt;&gt;=</a> (\x -&gt; k x <a>&gt;&gt;=</a> h) = (m
--   <a>&gt;&gt;=</a> k) <a>&gt;&gt;=</a> h</pre></li>
--   </ul>
--   
--   Furthermore, the <a>Monad</a> and <a>Applicative</a> operations should
--   relate as follows:
--   
--   <ul>
--   <li><pre><a>pure</a> = <a>return</a></pre></li>
--   <li><pre>(<a>&lt;*&gt;</a>) = <a>ap</a></pre></li>
--   </ul>
--   
--   The above laws imply:
--   
--   <ul>
--   <li><pre><a>fmap</a> f xs = xs <a>&gt;&gt;=</a> <a>return</a> .
--   f</pre></li>
--   <li><pre>(<a>&gt;&gt;</a>) = (<a>*&gt;</a>)</pre></li>
--   </ul>
--   
--   and that <a>pure</a> and (<a>&lt;*&gt;</a>) satisfy the applicative
--   functor laws.
--   
--   The instances of <a>Monad</a> for lists, <a>Maybe</a> and <a>IO</a>
--   defined in the <a>Prelude</a> satisfy these laws.
class Applicative m => Monad (m :: * -> *)

-- | Sequentially compose two actions, passing any value produced by the
--   first as an argument to the second.
(>>=) :: Monad m => m a -> a -> m b -> m b

-- | Sequentially compose two actions, discarding any value produced by the
--   first, like sequencing operators (such as the semicolon) in imperative
--   languages.
(>>) :: Monad m => m a -> m b -> m b

-- | Inject a value into the monadic type.
return :: Monad m => a -> m a

-- | Fail with a message. This operation is not part of the mathematical
--   definition of a monad, but is invoked on pattern-match failure in a
--   <tt>do</tt> expression.
--   
--   As part of the MonadFail proposal (MFP), this function is moved to its
--   own class <tt>MonadFail</tt> (see <a>Control.Monad.Fail</a> for more
--   details). The definition here will be removed in a future release.
fail :: Monad m => String -> m a

-- | The <a>Functor</a> class is used for types that can be mapped over.
--   Instances of <a>Functor</a> should satisfy the following laws:
--   
--   <pre>
--   fmap id  ==  id
--   fmap (f . g)  ==  fmap f . fmap g
--   </pre>
--   
--   The instances of <a>Functor</a> for lists, <a>Maybe</a> and <a>IO</a>
--   satisfy these laws.
class Functor (f :: * -> *)
fmap :: Functor f => a -> b -> f a -> f b

-- | Replace all locations in the input with the same value. The default
--   definition is <tt><a>fmap</a> . <a>const</a></tt>, but this may be
--   overridden with a more efficient version.
(<$) :: Functor f => a -> f b -> f a

-- | Basic numeric class.
class Num a
(+) :: Num a => a -> a -> a
(-) :: Num a => a -> a -> a
(*) :: Num a => a -> a -> a

-- | Unary negation.
negate :: Num a => a -> a

-- | Absolute value.
abs :: Num a => a -> a

-- | Sign of a number. The functions <a>abs</a> and <a>signum</a> should
--   satisfy the law:
--   
--   <pre>
--   abs x * signum x == x
--   </pre>
--   
--   For real numbers, the <a>signum</a> is either <tt>-1</tt> (negative),
--   <tt>0</tt> (zero) or <tt>1</tt> (positive).
signum :: Num a => a -> a

-- | Conversion from an <a>Integer</a>. An integer literal represents the
--   application of the function <a>fromInteger</a> to the appropriate
--   value of type <a>Integer</a>, so such literals have type
--   <tt>(<a>Num</a> a) =&gt; a</tt>.
fromInteger :: Num a => Integer -> a

-- | The <a>Ord</a> class is used for totally ordered datatypes.
--   
--   Instances of <a>Ord</a> can be derived for any user-defined datatype
--   whose constituent types are in <a>Ord</a>. The declared order of the
--   constructors in the data declaration determines the ordering in
--   derived <a>Ord</a> instances. The <a>Ordering</a> datatype allows a
--   single comparison to determine the precise ordering of two objects.
--   
--   Minimal complete definition: either <a>compare</a> or <a>&lt;=</a>.
--   Using <a>compare</a> can be more efficient for complex types.
class Eq a => Ord a
compare :: Ord a => a -> a -> Ordering
(<) :: Ord a => a -> a -> Bool
(<=) :: Ord a => a -> a -> Bool
(>) :: Ord a => a -> a -> Bool
(>=) :: Ord a => a -> a -> Bool
max :: Ord a => a -> a -> a
min :: Ord a => a -> a -> a

-- | Parsing of <a>String</a>s, producing values.
--   
--   Derived instances of <a>Read</a> make the following assumptions, which
--   derived instances of <a>Show</a> obey:
--   
--   <ul>
--   <li>If the constructor is defined to be an infix operator, then the
--   derived <a>Read</a> instance will parse only infix applications of the
--   constructor (not the prefix form).</li>
--   <li>Associativity is not used to reduce the occurrence of parentheses,
--   although precedence may be.</li>
--   <li>If the constructor is defined using record syntax, the derived
--   <a>Read</a> will parse only the record-syntax form, and furthermore,
--   the fields must be given in the same order as the original
--   declaration.</li>
--   <li>The derived <a>Read</a> instance allows arbitrary Haskell
--   whitespace between tokens of the input string. Extra parentheses are
--   also allowed.</li>
--   </ul>
--   
--   For example, given the declarations
--   
--   <pre>
--   infixr 5 :^:
--   data Tree a =  Leaf a  |  Tree a :^: Tree a
--   </pre>
--   
--   the derived instance of <a>Read</a> in Haskell 2010 is equivalent to
--   
--   <pre>
--   instance (Read a) =&gt; Read (Tree a) where
--   
--           readsPrec d r =  readParen (d &gt; app_prec)
--                            (\r -&gt; [(Leaf m,t) |
--                                    ("Leaf",s) &lt;- lex r,
--                                    (m,t) &lt;- readsPrec (app_prec+1) s]) r
--   
--                         ++ readParen (d &gt; up_prec)
--                            (\r -&gt; [(u:^:v,w) |
--                                    (u,s) &lt;- readsPrec (up_prec+1) r,
--                                    (":^:",t) &lt;- lex s,
--                                    (v,w) &lt;- readsPrec (up_prec+1) t]) r
--   
--             where app_prec = 10
--                   up_prec = 5
--   </pre>
--   
--   Note that right-associativity of <tt>:^:</tt> is unused.
--   
--   The derived instance in GHC is equivalent to
--   
--   <pre>
--   instance (Read a) =&gt; Read (Tree a) where
--   
--           readPrec = parens $ (prec app_prec $ do
--                                    Ident "Leaf" &lt;- lexP
--                                    m &lt;- step readPrec
--                                    return (Leaf m))
--   
--                        +++ (prec up_prec $ do
--                                    u &lt;- step readPrec
--                                    Symbol ":^:" &lt;- lexP
--                                    v &lt;- step readPrec
--                                    return (u :^: v))
--   
--             where app_prec = 10
--                   up_prec = 5
--   
--           readListPrec = readListPrecDefault
--   </pre>
--   
--   Why do both <a>readsPrec</a> and <a>readPrec</a> exist, and why does
--   GHC opt to implement <a>readPrec</a> in derived <a>Read</a> instances
--   instead of <a>readsPrec</a>? The reason is that <a>readsPrec</a> is
--   based on the <a>ReadS</a> type, and although <a>ReadS</a> is mentioned
--   in the Haskell 2010 Report, it is not a very efficient parser data
--   structure.
--   
--   <a>readPrec</a>, on the other hand, is based on a much more efficient
--   <a>ReadPrec</a> datatype (a.k.a "new-style parsers"), but its
--   definition relies on the use of the <tt>RankNTypes</tt> language
--   extension. Therefore, <a>readPrec</a> (and its cousin,
--   <a>readListPrec</a>) are marked as GHC-only. Nevertheless, it is
--   recommended to use <a>readPrec</a> instead of <a>readsPrec</a>
--   whenever possible for the efficiency improvements it brings.
--   
--   As mentioned above, derived <a>Read</a> instances in GHC will
--   implement <a>readPrec</a> instead of <a>readsPrec</a>. The default
--   implementations of <a>readsPrec</a> (and its cousin, <a>readList</a>)
--   will simply use <a>readPrec</a> under the hood. If you are writing a
--   <a>Read</a> instance by hand, it is recommended to write it like so:
--   
--   <pre>
--   instance <a>Read</a> T where
--     <a>readPrec</a>     = ...
--     <a>readListPrec</a> = <a>readListPrecDefault</a>
--   </pre>
class Read a

-- | attempts to parse a value from the front of the string, returning a
--   list of (parsed value, remaining string) pairs. If there is no
--   successful parse, the returned list is empty.
--   
--   Derived instances of <a>Read</a> and <a>Show</a> satisfy the
--   following:
--   
--   <ul>
--   <li><tt>(x,"")</tt> is an element of <tt>(<a>readsPrec</a> d
--   (<a>showsPrec</a> d x ""))</tt>.</li>
--   </ul>
--   
--   That is, <a>readsPrec</a> parses the string produced by
--   <a>showsPrec</a>, and delivers the value that <a>showsPrec</a> started
--   with.
readsPrec :: Read a => Int -> ReadS a

-- | The method <a>readList</a> is provided to allow the programmer to give
--   a specialised way of parsing lists of values. For example, this is
--   used by the predefined <a>Read</a> instance of the <a>Char</a> type,
--   where values of type <a>String</a> should be are expected to use
--   double quotes, rather than square brackets.
readList :: Read a => ReadS [a]
class (Num a, Ord a) => Real a

-- | the rational equivalent of its real argument with full precision
toRational :: Real a => a -> Rational

-- | Efficient, machine-independent access to the components of a
--   floating-point number.
class (RealFrac a, Floating a) => RealFloat a

-- | a constant function, returning the radix of the representation (often
--   <tt>2</tt>)
floatRadix :: RealFloat a => a -> Integer

-- | a constant function, returning the number of digits of
--   <a>floatRadix</a> in the significand
floatDigits :: RealFloat a => a -> Int

-- | a constant function, returning the lowest and highest values the
--   exponent may assume
floatRange :: RealFloat a => a -> (Int, Int)

-- | The function <a>decodeFloat</a> applied to a real floating-point
--   number returns the significand expressed as an <a>Integer</a> and an
--   appropriately scaled exponent (an <a>Int</a>). If
--   <tt><a>decodeFloat</a> x</tt> yields <tt>(m,n)</tt>, then <tt>x</tt>
--   is equal in value to <tt>m*b^^n</tt>, where <tt>b</tt> is the
--   floating-point radix, and furthermore, either <tt>m</tt> and
--   <tt>n</tt> are both zero or else <tt>b^(d-1) &lt;= <a>abs</a> m &lt;
--   b^d</tt>, where <tt>d</tt> is the value of <tt><a>floatDigits</a>
--   x</tt>. In particular, <tt><a>decodeFloat</a> 0 = (0,0)</tt>. If the
--   type contains a negative zero, also <tt><a>decodeFloat</a> (-0.0) =
--   (0,0)</tt>. <i>The result of</i> <tt><a>decodeFloat</a> x</tt> <i>is
--   unspecified if either of</i> <tt><a>isNaN</a> x</tt> <i>or</i>
--   <tt><a>isInfinite</a> x</tt> <i>is</i> <a>True</a>.
decodeFloat :: RealFloat a => a -> (Integer, Int)

-- | <a>encodeFloat</a> performs the inverse of <a>decodeFloat</a> in the
--   sense that for finite <tt>x</tt> with the exception of <tt>-0.0</tt>,
--   <tt><tt>uncurry</tt> <a>encodeFloat</a> (<a>decodeFloat</a> x) =
--   x</tt>. <tt><a>encodeFloat</a> m n</tt> is one of the two closest
--   representable floating-point numbers to <tt>m*b^^n</tt> (or
--   <tt>±Infinity</tt> if overflow occurs); usually the closer, but if
--   <tt>m</tt> contains too many bits, the result may be rounded in the
--   wrong direction.
encodeFloat :: RealFloat a => Integer -> Int -> a

-- | <a>exponent</a> corresponds to the second component of
--   <a>decodeFloat</a>. <tt><a>exponent</a> 0 = 0</tt> and for finite
--   nonzero <tt>x</tt>, <tt><a>exponent</a> x = snd (<a>decodeFloat</a> x)
--   + <a>floatDigits</a> x</tt>. If <tt>x</tt> is a finite floating-point
--   number, it is equal in value to <tt><a>significand</a> x * b ^^
--   <a>exponent</a> x</tt>, where <tt>b</tt> is the floating-point radix.
--   The behaviour is unspecified on infinite or <tt>NaN</tt> values.
exponent :: RealFloat a => a -> Int

-- | The first component of <a>decodeFloat</a>, scaled to lie in the open
--   interval (<tt>-1</tt>,<tt>1</tt>), either <tt>0.0</tt> or of absolute
--   value <tt>&gt;= 1/b</tt>, where <tt>b</tt> is the floating-point
--   radix. The behaviour is unspecified on infinite or <tt>NaN</tt>
--   values.
significand :: RealFloat a => a -> a

-- | multiplies a floating-point number by an integer power of the radix
scaleFloat :: RealFloat a => Int -> a -> a

-- | <a>True</a> if the argument is an IEEE "not-a-number" (NaN) value
isNaN :: RealFloat a => a -> Bool

-- | <a>True</a> if the argument is an IEEE infinity or negative infinity
isInfinite :: RealFloat a => a -> Bool

-- | <a>True</a> if the argument is too small to be represented in
--   normalized format
isDenormalized :: RealFloat a => a -> Bool

-- | <a>True</a> if the argument is an IEEE negative zero
isNegativeZero :: RealFloat a => a -> Bool

-- | <a>True</a> if the argument is an IEEE floating point number
isIEEE :: RealFloat a => a -> Bool

-- | a version of arctangent taking two real floating-point arguments. For
--   real floating <tt>x</tt> and <tt>y</tt>, <tt><a>atan2</a> y x</tt>
--   computes the angle (from the positive x-axis) of the vector from the
--   origin to the point <tt>(x,y)</tt>. <tt><a>atan2</a> y x</tt> returns
--   a value in the range [<tt>-pi</tt>, <tt>pi</tt>]. It follows the
--   Common Lisp semantics for the origin when signed zeroes are supported.
--   <tt><a>atan2</a> y 1</tt>, with <tt>y</tt> in a type that is
--   <a>RealFloat</a>, should return the same value as <tt><a>atan</a>
--   y</tt>. A default definition of <a>atan2</a> is provided, but
--   implementors can provide a more accurate implementation.
atan2 :: RealFloat a => a -> a -> a

-- | Extracting components of fractions.
class (Real a, Fractional a) => RealFrac a

-- | The function <a>properFraction</a> takes a real fractional number
--   <tt>x</tt> and returns a pair <tt>(n,f)</tt> such that <tt>x =
--   n+f</tt>, and:
--   
--   <ul>
--   <li><tt>n</tt> is an integral number with the same sign as <tt>x</tt>;
--   and</li>
--   <li><tt>f</tt> is a fraction with the same type and sign as
--   <tt>x</tt>, and with absolute value less than <tt>1</tt>.</li>
--   </ul>
--   
--   The default definitions of the <a>ceiling</a>, <a>floor</a>,
--   <a>truncate</a> and <a>round</a> functions are in terms of
--   <a>properFraction</a>.
properFraction :: (RealFrac a, Integral b) => a -> (b, a)

-- | <tt><a>truncate</a> x</tt> returns the integer nearest <tt>x</tt>
--   between zero and <tt>x</tt>
truncate :: (RealFrac a, Integral b) => a -> b

-- | <tt><a>round</a> x</tt> returns the nearest integer to <tt>x</tt>; the
--   even integer if <tt>x</tt> is equidistant between two integers
round :: (RealFrac a, Integral b) => a -> b

-- | <tt><a>ceiling</a> x</tt> returns the least integer not less than
--   <tt>x</tt>
ceiling :: (RealFrac a, Integral b) => a -> b

-- | <tt><a>floor</a> x</tt> returns the greatest integer not greater than
--   <tt>x</tt>
floor :: (RealFrac a, Integral b) => a -> b

-- | Conversion of values to readable <a>String</a>s.
--   
--   Derived instances of <a>Show</a> have the following properties, which
--   are compatible with derived instances of <a>Read</a>:
--   
--   <ul>
--   <li>The result of <a>show</a> is a syntactically correct Haskell
--   expression containing only constants, given the fixity declarations in
--   force at the point where the type is declared. It contains only the
--   constructor names defined in the data type, parentheses, and spaces.
--   When labelled constructor fields are used, braces, commas, field
--   names, and equal signs are also used.</li>
--   <li>If the constructor is defined to be an infix operator, then
--   <a>showsPrec</a> will produce infix applications of the
--   constructor.</li>
--   <li>the representation will be enclosed in parentheses if the
--   precedence of the top-level constructor in <tt>x</tt> is less than
--   <tt>d</tt> (associativity is ignored). Thus, if <tt>d</tt> is
--   <tt>0</tt> then the result is never surrounded in parentheses; if
--   <tt>d</tt> is <tt>11</tt> it is always surrounded in parentheses,
--   unless it is an atomic expression.</li>
--   <li>If the constructor is defined using record syntax, then
--   <a>show</a> will produce the record-syntax form, with the fields given
--   in the same order as the original declaration.</li>
--   </ul>
--   
--   For example, given the declarations
--   
--   <pre>
--   infixr 5 :^:
--   data Tree a =  Leaf a  |  Tree a :^: Tree a
--   </pre>
--   
--   the derived instance of <a>Show</a> is equivalent to
--   
--   <pre>
--   instance (Show a) =&gt; Show (Tree a) where
--   
--          showsPrec d (Leaf m) = showParen (d &gt; app_prec) $
--               showString "Leaf " . showsPrec (app_prec+1) m
--            where app_prec = 10
--   
--          showsPrec d (u :^: v) = showParen (d &gt; up_prec) $
--               showsPrec (up_prec+1) u .
--               showString " :^: "      .
--               showsPrec (up_prec+1) v
--            where up_prec = 5
--   </pre>
--   
--   Note that right-associativity of <tt>:^:</tt> is ignored. For example,
--   
--   <ul>
--   <li><tt><a>show</a> (Leaf 1 :^: Leaf 2 :^: Leaf 3)</tt> produces the
--   string <tt>"Leaf 1 :^: (Leaf 2 :^: Leaf 3)"</tt>.</li>
--   </ul>
class Show a

-- | Convert a value to a readable <a>String</a>.
--   
--   <a>showsPrec</a> should satisfy the law
--   
--   <pre>
--   showsPrec d x r ++ s  ==  showsPrec d x (r ++ s)
--   </pre>
--   
--   Derived instances of <a>Read</a> and <a>Show</a> satisfy the
--   following:
--   
--   <ul>
--   <li><tt>(x,"")</tt> is an element of <tt>(<a>readsPrec</a> d
--   (<a>showsPrec</a> d x ""))</tt>.</li>
--   </ul>
--   
--   That is, <a>readsPrec</a> parses the string produced by
--   <a>showsPrec</a>, and delivers the value that <a>showsPrec</a> started
--   with.
showsPrec :: Show a => Int -> a -> ShowS

-- | A specialised variant of <a>showsPrec</a>, using precedence context
--   zero, and returning an ordinary <a>String</a>.
show :: Show a => a -> String

-- | The method <a>showList</a> is provided to allow the programmer to give
--   a specialised way of showing lists of values. For example, this is
--   used by the predefined <a>Show</a> instance of the <a>Char</a> type,
--   where values of type <a>String</a> should be shown in double quotes,
--   rather than between square brackets.
showList :: Show a => [a] -> ShowS

-- | A functor with application, providing operations to
--   
--   <ul>
--   <li>embed pure expressions (<a>pure</a>), and</li>
--   <li>sequence computations and combine their results (<a>&lt;*&gt;</a>
--   and <a>liftA2</a>).</li>
--   </ul>
--   
--   A minimal complete definition must include implementations of
--   <a>pure</a> and of either <a>&lt;*&gt;</a> or <a>liftA2</a>. If it
--   defines both, then they must behave the same as their default
--   definitions:
--   
--   <pre>
--   (<a>&lt;*&gt;</a>) = <a>liftA2</a> <a>id</a>
--   </pre>
--   
--   <pre>
--   <a>liftA2</a> f x y = f <tt>&lt;$&gt;</tt> x <a>&lt;*&gt;</a> y
--   </pre>
--   
--   Further, any definition must satisfy the following:
--   
--   <ul>
--   <li><i><i>identity</i></i> <pre><a>pure</a> <a>id</a> <a>&lt;*&gt;</a>
--   v = v</pre></li>
--   <li><i><i>composition</i></i> <pre><a>pure</a> (.) <a>&lt;*&gt;</a> u
--   <a>&lt;*&gt;</a> v <a>&lt;*&gt;</a> w = u <a>&lt;*&gt;</a> (v
--   <a>&lt;*&gt;</a> w)</pre></li>
--   <li><i><i>homomorphism</i></i> <pre><a>pure</a> f <a>&lt;*&gt;</a>
--   <a>pure</a> x = <a>pure</a> (f x)</pre></li>
--   <li><i><i>interchange</i></i> <pre>u <a>&lt;*&gt;</a> <a>pure</a> y =
--   <a>pure</a> (<a>$</a> y) <a>&lt;*&gt;</a> u</pre></li>
--   </ul>
--   
--   The other methods have the following default definitions, which may be
--   overridden with equivalent specialized implementations:
--   
--   <ul>
--   <li><pre>u <a>*&gt;</a> v = (<a>id</a> <a>&lt;$</a> u)
--   <a>&lt;*&gt;</a> v</pre></li>
--   <li><pre>u <a>&lt;*</a> v = <a>liftA2</a> <a>const</a> u v</pre></li>
--   </ul>
--   
--   As a consequence of these laws, the <a>Functor</a> instance for
--   <tt>f</tt> will satisfy
--   
--   <ul>
--   <li><pre><a>fmap</a> f x = <a>pure</a> f <a>&lt;*&gt;</a> x</pre></li>
--   </ul>
--   
--   It may be useful to note that supposing
--   
--   <pre>
--   forall x y. p (q x y) = f x . g y
--   </pre>
--   
--   it follows from the above that
--   
--   <pre>
--   <a>liftA2</a> p (<a>liftA2</a> q u v) = <a>liftA2</a> f u . <a>liftA2</a> g v
--   </pre>
--   
--   If <tt>f</tt> is also a <a>Monad</a>, it should satisfy
--   
--   <ul>
--   <li><pre><a>pure</a> = <a>return</a></pre></li>
--   <li><pre>(<a>&lt;*&gt;</a>) = <a>ap</a></pre></li>
--   <li><pre>(<a>*&gt;</a>) = (<a>&gt;&gt;</a>)</pre></li>
--   </ul>
--   
--   (which implies that <a>pure</a> and <a>&lt;*&gt;</a> satisfy the
--   applicative functor laws).
class Functor f => Applicative (f :: * -> *)

-- | Lift a value.
pure :: Applicative f => a -> f a

-- | Sequential application.
--   
--   A few functors support an implementation of <a>&lt;*&gt;</a> that is
--   more efficient than the default one.
(<*>) :: Applicative f => f a -> b -> f a -> f b

-- | Sequence actions, discarding the value of the first argument.
(*>) :: Applicative f => f a -> f b -> f b

-- | Sequence actions, discarding the value of the second argument.
(<*) :: Applicative f => f a -> f b -> f a

-- | Data structures that can be folded.
--   
--   For example, given a data type
--   
--   <pre>
--   data Tree a = Empty | Leaf a | Node (Tree a) a (Tree a)
--   </pre>
--   
--   a suitable instance would be
--   
--   <pre>
--   instance Foldable Tree where
--      foldMap f Empty = mempty
--      foldMap f (Leaf x) = f x
--      foldMap f (Node l k r) = foldMap f l `mappend` f k `mappend` foldMap f r
--   </pre>
--   
--   This is suitable even for abstract types, as the monoid is assumed to
--   satisfy the monoid laws. Alternatively, one could define
--   <tt>foldr</tt>:
--   
--   <pre>
--   instance Foldable Tree where
--      foldr f z Empty = z
--      foldr f z (Leaf x) = f x z
--      foldr f z (Node l k r) = foldr f (f k (foldr f z r)) l
--   </pre>
--   
--   <tt>Foldable</tt> instances are expected to satisfy the following
--   laws:
--   
--   <pre>
--   foldr f z t = appEndo (foldMap (Endo . f) t ) z
--   </pre>
--   
--   <pre>
--   foldl f z t = appEndo (getDual (foldMap (Dual . Endo . flip f) t)) z
--   </pre>
--   
--   <pre>
--   fold = foldMap id
--   </pre>
--   
--   <pre>
--   length = getSum . foldMap (Sum . const  1)
--   </pre>
--   
--   <tt>sum</tt>, <tt>product</tt>, <tt>maximum</tt>, and <tt>minimum</tt>
--   should all be essentially equivalent to <tt>foldMap</tt> forms, such
--   as
--   
--   <pre>
--   sum = getSum . foldMap Sum
--   </pre>
--   
--   but may be less defined.
--   
--   If the type is also a <a>Functor</a> instance, it should satisfy
--   
--   <pre>
--   foldMap f = fold . fmap f
--   </pre>
--   
--   which implies that
--   
--   <pre>
--   foldMap f . fmap g = foldMap (f . g)
--   </pre>
class Foldable (t :: * -> *)

-- | Map each element of the structure to a monoid, and combine the
--   results.
foldMap :: (Foldable t, Monoid m) => a -> m -> t a -> m

-- | Right-associative fold of a structure.
--   
--   In the case of lists, <a>foldr</a>, when applied to a binary operator,
--   a starting value (typically the right-identity of the operator), and a
--   list, reduces the list using the binary operator, from right to left:
--   
--   <pre>
--   foldr f z [x1, x2, ..., xn] == x1 `f` (x2 `f` ... (xn `f` z)...)
--   </pre>
--   
--   Note that, since the head of the resulting expression is produced by
--   an application of the operator to the first element of the list,
--   <a>foldr</a> can produce a terminating expression from an infinite
--   list.
--   
--   For a general <a>Foldable</a> structure this should be semantically
--   identical to,
--   
--   <pre>
--   foldr f z = <a>foldr</a> f z . <a>toList</a>
--   </pre>
foldr :: Foldable t => a -> b -> b -> b -> t a -> b

-- | Left-associative fold of a structure.
--   
--   In the case of lists, <a>foldl</a>, when applied to a binary operator,
--   a starting value (typically the left-identity of the operator), and a
--   list, reduces the list using the binary operator, from left to right:
--   
--   <pre>
--   foldl f z [x1, x2, ..., xn] == (...((z `f` x1) `f` x2) `f`...) `f` xn
--   </pre>
--   
--   Note that to produce the outermost application of the operator the
--   entire input list must be traversed. This means that <a>foldl'</a>
--   will diverge if given an infinite list.
--   
--   Also note that if you want an efficient left-fold, you probably want
--   to use <a>foldl'</a> instead of <a>foldl</a>. The reason for this is
--   that latter does not force the "inner" results (e.g. <tt>z <tt>f</tt>
--   x1</tt> in the above example) before applying them to the operator
--   (e.g. to <tt>(<tt>f</tt> x2)</tt>). This results in a thunk chain
--   <tt>O(n)</tt> elements long, which then must be evaluated from the
--   outside-in.
--   
--   For a general <a>Foldable</a> structure this should be semantically
--   identical to,
--   
--   <pre>
--   foldl f z = <a>foldl</a> f z . <a>toList</a>
--   </pre>
foldl :: Foldable t => b -> a -> b -> b -> t a -> b

-- | A variant of <a>foldr</a> that has no base case, and thus may only be
--   applied to non-empty structures.
--   
--   <pre>
--   <a>foldr1</a> f = <a>foldr1</a> f . <a>toList</a>
--   </pre>
foldr1 :: Foldable t => a -> a -> a -> t a -> a

-- | A variant of <a>foldl</a> that has no base case, and thus may only be
--   applied to non-empty structures.
--   
--   <pre>
--   <a>foldl1</a> f = <a>foldl1</a> f . <a>toList</a>
--   </pre>
foldl1 :: Foldable t => a -> a -> a -> t a -> a

-- | Test whether the structure is empty. The default implementation is
--   optimized for structures that are similar to cons-lists, because there
--   is no general way to do better.
null :: Foldable t => t a -> Bool

-- | Returns the size/length of a finite structure as an <a>Int</a>. The
--   default implementation is optimized for structures that are similar to
--   cons-lists, because there is no general way to do better.
length :: Foldable t => t a -> Int

-- | Does the element occur in the structure?
elem :: (Foldable t, Eq a) => a -> t a -> Bool

-- | The largest element of a non-empty structure.
maximum :: (Foldable t, Ord a) => t a -> a

-- | The least element of a non-empty structure.
minimum :: (Foldable t, Ord a) => t a -> a

-- | The <a>sum</a> function computes the sum of the numbers of a
--   structure.
sum :: (Foldable t, Num a) => t a -> a

-- | The <a>product</a> function computes the product of the numbers of a
--   structure.
product :: (Foldable t, Num a) => t a -> a

-- | Functors representing data structures that can be traversed from left
--   to right.
--   
--   A definition of <a>traverse</a> must satisfy the following laws:
--   
--   <ul>
--   <li><i><i>naturality</i></i> <tt>t . <a>traverse</a> f =
--   <a>traverse</a> (t . f)</tt> for every applicative transformation
--   <tt>t</tt></li>
--   <li><i><i>identity</i></i> <tt><a>traverse</a> Identity =
--   Identity</tt></li>
--   <li><i><i>composition</i></i> <tt><a>traverse</a> (Compose .
--   <a>fmap</a> g . f) = Compose . <a>fmap</a> (<a>traverse</a> g) .
--   <a>traverse</a> f</tt></li>
--   </ul>
--   
--   A definition of <a>sequenceA</a> must satisfy the following laws:
--   
--   <ul>
--   <li><i><i>naturality</i></i> <tt>t . <a>sequenceA</a> =
--   <a>sequenceA</a> . <a>fmap</a> t</tt> for every applicative
--   transformation <tt>t</tt></li>
--   <li><i><i>identity</i></i> <tt><a>sequenceA</a> . <a>fmap</a> Identity
--   = Identity</tt></li>
--   <li><i><i>composition</i></i> <tt><a>sequenceA</a> . <a>fmap</a>
--   Compose = Compose . <a>fmap</a> <a>sequenceA</a> .
--   <a>sequenceA</a></tt></li>
--   </ul>
--   
--   where an <i>applicative transformation</i> is a function
--   
--   <pre>
--   t :: (Applicative f, Applicative g) =&gt; f a -&gt; g a
--   </pre>
--   
--   preserving the <a>Applicative</a> operations, i.e.
--   
--   <ul>
--   <li><pre>t (<a>pure</a> x) = <a>pure</a> x</pre></li>
--   <li><pre>t (x <a>&lt;*&gt;</a> y) = t x <a>&lt;*&gt;</a> t
--   y</pre></li>
--   </ul>
--   
--   and the identity functor <tt>Identity</tt> and composition of functors
--   <tt>Compose</tt> are defined as
--   
--   <pre>
--   newtype Identity a = Identity a
--   
--   instance Functor Identity where
--     fmap f (Identity x) = Identity (f x)
--   
--   instance Applicative Identity where
--     pure x = Identity x
--     Identity f &lt;*&gt; Identity x = Identity (f x)
--   
--   newtype Compose f g a = Compose (f (g a))
--   
--   instance (Functor f, Functor g) =&gt; Functor (Compose f g) where
--     fmap f (Compose x) = Compose (fmap (fmap f) x)
--   
--   instance (Applicative f, Applicative g) =&gt; Applicative (Compose f g) where
--     pure x = Compose (pure (pure x))
--     Compose f &lt;*&gt; Compose x = Compose ((&lt;*&gt;) &lt;$&gt; f &lt;*&gt; x)
--   </pre>
--   
--   (The naturality law is implied by parametricity.)
--   
--   Instances are similar to <a>Functor</a>, e.g. given a data type
--   
--   <pre>
--   data Tree a = Empty | Leaf a | Node (Tree a) a (Tree a)
--   </pre>
--   
--   a suitable instance would be
--   
--   <pre>
--   instance Traversable Tree where
--      traverse f Empty = pure Empty
--      traverse f (Leaf x) = Leaf &lt;$&gt; f x
--      traverse f (Node l k r) = Node &lt;$&gt; traverse f l &lt;*&gt; f k &lt;*&gt; traverse f r
--   </pre>
--   
--   This is suitable even for abstract types, as the laws for
--   <a>&lt;*&gt;</a> imply a form of associativity.
--   
--   The superclass instances should satisfy the following:
--   
--   <ul>
--   <li>In the <a>Functor</a> instance, <a>fmap</a> should be equivalent
--   to traversal with the identity applicative functor
--   (<a>fmapDefault</a>).</li>
--   <li>In the <a>Foldable</a> instance, <a>foldMap</a> should be
--   equivalent to traversal with a constant applicative functor
--   (<a>foldMapDefault</a>).</li>
--   </ul>
class (Functor t, Foldable t) => Traversable (t :: * -> *)

-- | Map each element of a structure to an action, evaluate these actions
--   from left to right, and collect the results. For a version that
--   ignores the results see <a>traverse_</a>.
traverse :: (Traversable t, Applicative f) => a -> f b -> t a -> f t b

-- | Evaluate each action in the structure from left to right, and and
--   collect the results. For a version that ignores the results see
--   <a>sequenceA_</a>.
sequenceA :: (Traversable t, Applicative f) => t f a -> f t a

-- | Evaluate each monadic action in the structure from left to right, and
--   collect the results. For a version that ignores the results see
--   <a>sequence_</a>.
sequence :: (Traversable t, Monad m) => t m a -> m t a

-- | The class of semigroups (types with an associative binary operation).
--   
--   Instances should satisfy the associativity law:
--   
--   <ul>
--   <li><pre>x <a>&lt;&gt;</a> (y <a>&lt;&gt;</a> z) = (x <a>&lt;&gt;</a>
--   y) <a>&lt;&gt;</a> z</pre></li>
--   </ul>
class Semigroup a

-- | An associative operation.
(<>) :: Semigroup a => a -> a -> a

-- | The class of monoids (types with an associative binary operation that
--   has an identity). Instances should satisfy the following laws:
--   
--   <ul>
--   <li><pre>x <a>&lt;&gt;</a> <a>mempty</a> = x</pre></li>
--   <li><pre><a>mempty</a> <a>&lt;&gt;</a> x = x</pre></li>
--   <li><tt>x <a>&lt;&gt;</a> (y <a>&lt;&gt;</a> z) = (x <a>&lt;&gt;</a>
--   y) <a>&lt;&gt;</a> z</tt> (<a>Semigroup</a> law)</li>
--   <li><pre><a>mconcat</a> = <a>foldr</a> '(&lt;&gt;)'
--   <a>mempty</a></pre></li>
--   </ul>
--   
--   The method names refer to the monoid of lists under concatenation, but
--   there are many other instances.
--   
--   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.
--   <tt>Sum</tt> and <tt>Product</tt>.
--   
--   <b>NOTE</b>: <a>Semigroup</a> is a superclass of <a>Monoid</a> since
--   <i>base-4.11.0.0</i>.
class Semigroup a => Monoid a

-- | Identity of <a>mappend</a>
mempty :: Monoid a => a

-- | An associative operation
--   
--   <b>NOTE</b>: This method is redundant and has the default
--   implementation <tt><a>mappend</a> = '(&lt;&gt;)'</tt> since
--   <i>base-4.11.0.0</i>.
mappend :: Monoid a => a -> a -> a

-- | Fold a list using the monoid.
--   
--   For most types, the default definition for <a>mconcat</a> will be
--   used, but the function is included in the class definition so that an
--   optimized version can be provided for specific types.
mconcat :: Monoid a => [a] -> a
data Bool
False :: Bool
True :: Bool

-- | The character type <a>Char</a> is an enumeration whose values
--   represent Unicode (or equivalently ISO/IEC 10646) code points (i.e.
--   characters, see <a>http://www.unicode.org/</a> for details). This set
--   extends the ISO 8859-1 (Latin-1) character set (the first 256
--   characters), which is itself an extension of the ASCII character set
--   (the first 128 characters). A character literal in Haskell has type
--   <a>Char</a>.
--   
--   To convert a <a>Char</a> to or from the corresponding <a>Int</a> value
--   defined by Unicode, use <a>toEnum</a> and <a>fromEnum</a> from the
--   <a>Enum</a> class respectively (or equivalently <tt>ord</tt> and
--   <tt>chr</tt>).
data Char

-- | Double-precision floating point numbers. It is desirable that this
--   type be at least equal in range and precision to the IEEE
--   double-precision type.
data Double

-- | Single-precision floating point numbers. It is desirable that this
--   type be at least equal in range and precision to the IEEE
--   single-precision type.
data Float

-- | A fixed-precision integer type with at least the range <tt>[-2^29 ..
--   2^29-1]</tt>. The exact range for a given implementation can be
--   determined by using <a>minBound</a> and <a>maxBound</a> from the
--   <a>Bounded</a> class.
data Int

-- | Invariant: <a>Jn#</a> and <a>Jp#</a> are used iff value doesn't fit in
--   <a>S#</a>
--   
--   Useful properties resulting from the invariants:
--   
--   <ul>
--   <li><pre>abs (<a>S#</a> _) &lt;= abs (<a>Jp#</a> _)</pre></li>
--   <li><pre>abs (<a>S#</a> _) &lt; abs (<a>Jn#</a> _)</pre></li>
--   </ul>
data Integer

-- | The <a>Maybe</a> type encapsulates an optional value. A value of type
--   <tt><a>Maybe</a> a</tt> either contains a value of type <tt>a</tt>
--   (represented as <tt><a>Just</a> a</tt>), or it is empty (represented
--   as <a>Nothing</a>). Using <a>Maybe</a> is a good way to deal with
--   errors or exceptional cases without resorting to drastic measures such
--   as <a>error</a>.
--   
--   The <a>Maybe</a> type is also a monad. It is a simple kind of error
--   monad, where all errors are represented by <a>Nothing</a>. A richer
--   error monad can be built using the <a>Either</a> type.
data Maybe a
Nothing :: Maybe a
Just :: a -> Maybe a
data Ordering
LT :: Ordering
EQ :: Ordering
GT :: Ordering

-- | Arbitrary-precision rational numbers, represented as a ratio of two
--   <a>Integer</a> values. A rational number may be constructed using the
--   <a>%</a> operator.
type Rational = Ratio Integer

-- | A value of type <tt><a>IO</a> a</tt> is a computation which, when
--   performed, does some I/O before returning a value of type <tt>a</tt>.
--   
--   There is really only one way to "perform" an I/O action: bind it to
--   <tt>Main.main</tt> in your program. When your program is run, the I/O
--   will be performed. It isn't possible to perform I/O from an arbitrary
--   function, unless that function is itself in the <a>IO</a> monad and
--   called at some point, directly or indirectly, from <tt>Main.main</tt>.
--   
--   <a>IO</a> is a monad, so <a>IO</a> actions can be combined using
--   either the do-notation or the <tt>&gt;&gt;</tt> and <tt>&gt;&gt;=</tt>
--   operations from the <tt>Monad</tt> class.
data IO a

-- | A <a>Word</a> is an unsigned integral type, with the same size as
--   <a>Int</a>.
data Word

-- | The <a>Either</a> type represents values with two possibilities: a
--   value of type <tt><a>Either</a> a b</tt> is either <tt><a>Left</a>
--   a</tt> or <tt><a>Right</a> b</tt>.
--   
--   The <a>Either</a> type is sometimes used to represent a value which is
--   either correct or an error; by convention, the <a>Left</a> constructor
--   is used to hold an error value and the <a>Right</a> constructor is
--   used to hold a correct value (mnemonic: "right" also means "correct").
--   
--   <h4><b>Examples</b></h4>
--   
--   The type <tt><a>Either</a> <a>String</a> <a>Int</a></tt> is the type
--   of values which can be either a <a>String</a> or an <a>Int</a>. The
--   <a>Left</a> constructor can be used only on <a>String</a>s, and the
--   <a>Right</a> constructor can be used only on <a>Int</a>s:
--   
--   <pre>
--   &gt;&gt;&gt; let s = Left "foo" :: Either String Int
--   
--   &gt;&gt;&gt; s
--   Left "foo"
--   
--   &gt;&gt;&gt; let n = Right 3 :: Either String Int
--   
--   &gt;&gt;&gt; n
--   Right 3
--   
--   &gt;&gt;&gt; :type s
--   s :: Either String Int
--   
--   &gt;&gt;&gt; :type n
--   n :: Either String Int
--   </pre>
--   
--   The <a>fmap</a> from our <a>Functor</a> instance will ignore
--   <a>Left</a> values, but will apply the supplied function to values
--   contained in a <a>Right</a>:
--   
--   <pre>
--   &gt;&gt;&gt; let s = Left "foo" :: Either String Int
--   
--   &gt;&gt;&gt; let n = Right 3 :: Either String Int
--   
--   &gt;&gt;&gt; fmap (*2) s
--   Left "foo"
--   
--   &gt;&gt;&gt; fmap (*2) n
--   Right 6
--   </pre>
--   
--   The <a>Monad</a> instance for <a>Either</a> allows us to chain
--   together multiple actions which may fail, and fail overall if any of
--   the individual steps failed. First we'll write a function that can
--   either parse an <a>Int</a> from a <a>Char</a>, or fail.
--   
--   <pre>
--   &gt;&gt;&gt; import Data.Char ( digitToInt, isDigit )
--   
--   &gt;&gt;&gt; :{
--       let parseEither :: Char -&gt; Either String Int
--           parseEither c
--             | isDigit c = Right (digitToInt c)
--             | otherwise = Left "parse error"
--   
--   &gt;&gt;&gt; :}
--   </pre>
--   
--   The following should work, since both <tt>'1'</tt> and <tt>'2'</tt>
--   can be parsed as <a>Int</a>s.
--   
--   <pre>
--   &gt;&gt;&gt; :{
--       let parseMultiple :: Either String Int
--           parseMultiple = do
--             x &lt;- parseEither '1'
--             y &lt;- parseEither '2'
--             return (x + y)
--   
--   &gt;&gt;&gt; :}
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; parseMultiple
--   Right 3
--   </pre>
--   
--   But the following should fail overall, since the first operation where
--   we attempt to parse <tt>'m'</tt> as an <a>Int</a> will fail:
--   
--   <pre>
--   &gt;&gt;&gt; :{
--       let parseMultiple :: Either String Int
--           parseMultiple = do
--             x &lt;- parseEither 'm'
--             y &lt;- parseEither '2'
--             return (x + y)
--   
--   &gt;&gt;&gt; :}
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; parseMultiple
--   Left "parse error"
--   </pre>
data Either a b
Left :: a -> Either a b
Right :: b -> Either a b

-- | A <a>String</a> is a list of characters. String constants in Haskell
--   are values of type <a>String</a>.
type String = [Char]

-- | The <tt>shows</tt> functions return a function that prepends the
--   output <a>String</a> to an existing <a>String</a>. This allows
--   constant-time concatenation of results using function composition.
type ShowS = String -> String

-- | The <a>readIO</a> function is similar to <a>read</a> except that it
--   signals parse failure to the <a>IO</a> monad instead of terminating
--   the program.
readIO :: Read a => String -> IO a

-- | The <a>readLn</a> function combines <a>getLine</a> and <a>readIO</a>.
readLn :: Read a => IO a

-- | The computation <a>appendFile</a> <tt>file str</tt> function appends
--   the string <tt>str</tt>, to the file <tt>file</tt>.
--   
--   Note that <a>writeFile</a> and <a>appendFile</a> write a literal
--   string to a file. To write a value of any printable type, as with
--   <a>print</a>, use the <a>show</a> function to convert the value to a
--   string first.
--   
--   <pre>
--   main = appendFile "squares" (show [(x,x*x) | x &lt;- [0,0.1..2]])
--   </pre>
appendFile :: FilePath -> String -> IO ()

-- | The computation <a>writeFile</a> <tt>file str</tt> function writes the
--   string <tt>str</tt>, to the file <tt>file</tt>.
writeFile :: FilePath -> String -> IO ()

-- | The <a>readFile</a> function reads a file and returns the contents of
--   the file as a string. The file is read lazily, on demand, as with
--   <a>getContents</a>.
readFile :: FilePath -> IO String

-- | The <a>interact</a> function takes a function of type
--   <tt>String-&gt;String</tt> as its argument. The entire input from the
--   standard input device is passed to this function as its argument, and
--   the resulting string is output on the standard output device.
interact :: String -> String -> IO ()

-- | The <a>getContents</a> operation returns all user input as a single
--   string, which is read lazily as it is needed (same as
--   <a>hGetContents</a> <a>stdin</a>).
getContents :: IO String

-- | Read a line from the standard input device (same as <a>hGetLine</a>
--   <a>stdin</a>).
getLine :: IO String

-- | Read a character from the standard input device (same as
--   <a>hGetChar</a> <a>stdin</a>).
getChar :: IO Char

-- | The same as <a>putStr</a>, but adds a newline character.
putStrLn :: String -> IO ()

-- | Write a string to the standard output device (same as <a>hPutStr</a>
--   <a>stdout</a>).
putStr :: String -> IO ()

-- | Write a character to the standard output device (same as
--   <a>hPutChar</a> <a>stdout</a>).
putChar :: Char -> IO ()

-- | Raise an <a>IOError</a> in the <a>IO</a> monad.
ioError :: () => IOError -> IO a

-- | File and directory names are values of type <a>String</a>, whose
--   precise meaning is operating system dependent. Files can be opened,
--   yielding a handle which can then be used to operate on the contents of
--   that file.
type FilePath = String

-- | Construct an <a>IOError</a> value with a string describing the error.
--   The <a>fail</a> method of the <a>IO</a> instance of the <a>Monad</a>
--   class raises a <a>userError</a>, thus:
--   
--   <pre>
--   instance Monad IO where
--     ...
--     fail s = ioError (userError s)
--   </pre>
userError :: String -> IOError

-- | The Haskell 2010 type for exceptions in the <a>IO</a> monad. Any I/O
--   operation may raise an <a>IOError</a> instead of returning a result.
--   For a more general type of exception, including also those that arise
--   in pure code, see <a>Exception</a>.
--   
--   In Haskell 2010, this is an opaque type.
type IOError = IOException

-- | <a>notElem</a> is the negation of <a>elem</a>.
notElem :: (Foldable t, Eq a) => a -> t a -> Bool
infix 4 `notElem`

-- | Determines whether all elements of the structure satisfy the
--   predicate.
all :: Foldable t => a -> Bool -> t a -> Bool

-- | Determines whether any element of the structure satisfies the
--   predicate.
any :: Foldable t => a -> Bool -> t a -> Bool

-- | <a>or</a> returns the disjunction of a container of Bools. For the
--   result to be <a>False</a>, the container must be finite; <a>True</a>,
--   however, results from a <a>True</a> value finitely far from the left
--   end.
or :: Foldable t => t Bool -> Bool

-- | <a>and</a> returns the conjunction of a container of Bools. For the
--   result to be <a>True</a>, the container must be finite; <a>False</a>,
--   however, results from a <a>False</a> value finitely far from the left
--   end.
and :: Foldable t => t Bool -> Bool

-- | Map a function over all the elements of a container and concatenate
--   the resulting lists.
concatMap :: Foldable t => a -> [b] -> t a -> [b]

-- | The concatenation of all the elements of a container of lists.
concat :: Foldable t => t [a] -> [a]

-- | Evaluate each monadic action in the structure from left to right, and
--   ignore the results. For a version that doesn't ignore the results see
--   <a>sequence</a>.
--   
--   As of base 4.8.0.0, <a>sequence_</a> is just <a>sequenceA_</a>,
--   specialized to <a>Monad</a>.
sequence_ :: (Foldable t, Monad m) => t m a -> m ()

-- | Map each element of a structure to a monadic action, evaluate these
--   actions from left to right, and ignore the results. For a version that
--   doesn't ignore the results see <a>mapM</a>.
--   
--   As of base 4.8.0.0, <a>mapM_</a> is just <a>traverse_</a>, specialized
--   to <a>Monad</a>.
mapM_ :: (Foldable t, Monad m) => a -> m b -> t a -> m ()

-- | <a>unwords</a> is an inverse operation to <a>words</a>. It joins words
--   with separating spaces.
--   
--   <pre>
--   &gt;&gt;&gt; unwords ["Lorem", "ipsum", "dolor"]
--   "Lorem ipsum dolor"
--   </pre>
unwords :: [String] -> String

-- | <a>words</a> breaks a string up into a list of words, which were
--   delimited by white space.
--   
--   <pre>
--   &gt;&gt;&gt; words "Lorem ipsum\ndolor"
--   ["Lorem","ipsum","dolor"]
--   </pre>
words :: String -> [String]

-- | <a>unlines</a> is an inverse operation to <a>lines</a>. It joins
--   lines, after appending a terminating newline to each.
--   
--   <pre>
--   &gt;&gt;&gt; unlines ["Hello", "World", "!"]
--   "Hello\nWorld\n!\n"
--   </pre>
unlines :: [String] -> String

-- | <a>lines</a> breaks a string up into a list of strings at newline
--   characters. The resulting strings do not contain newlines.
--   
--   Note that after splitting the string at newline characters, the last
--   part of the string is considered a line even if it doesn't end with a
--   newline. For example,
--   
--   <pre>
--   &gt;&gt;&gt; lines ""
--   []
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; lines "\n"
--   [""]
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; lines "one"
--   ["one"]
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; lines "one\n"
--   ["one"]
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; lines "one\n\n"
--   ["one",""]
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; lines "one\ntwo"
--   ["one","two"]
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; lines "one\ntwo\n"
--   ["one","two"]
--   </pre>
--   
--   Thus <tt><a>lines</a> s</tt> contains at least as many elements as
--   newlines in <tt>s</tt>.
lines :: String -> [String]

-- | The <a>read</a> function reads input from a string, which must be
--   completely consumed by the input process. <a>read</a> fails with an
--   <a>error</a> if the parse is unsuccessful, and it is therefore
--   discouraged from being used in real applications. Use <a>readMaybe</a>
--   or <a>readEither</a> for safe alternatives.
--   
--   <pre>
--   &gt;&gt;&gt; read "123" :: Int
--   123
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; read "hello" :: Int
--   *** Exception: Prelude.read: no parse
--   </pre>
read :: Read a => String -> a

-- | equivalent to <a>readsPrec</a> with a precedence of 0.
reads :: Read a => ReadS a

-- | Case analysis for the <a>Either</a> type. If the value is
--   <tt><a>Left</a> a</tt>, apply the first function to <tt>a</tt>; if it
--   is <tt><a>Right</a> b</tt>, apply the second function to <tt>b</tt>.
--   
--   <h4><b>Examples</b></h4>
--   
--   We create two values of type <tt><a>Either</a> <a>String</a>
--   <a>Int</a></tt>, one using the <a>Left</a> constructor and another
--   using the <a>Right</a> constructor. Then we apply "either" the
--   <tt>length</tt> function (if we have a <a>String</a>) or the
--   "times-two" function (if we have an <a>Int</a>):
--   
--   <pre>
--   &gt;&gt;&gt; let s = Left "foo" :: Either String Int
--   
--   &gt;&gt;&gt; let n = Right 3 :: Either String Int
--   
--   &gt;&gt;&gt; either length (*2) s
--   3
--   
--   &gt;&gt;&gt; either length (*2) n
--   6
--   </pre>
either :: () => a -> c -> b -> c -> Either a b -> c

-- | The <a>lex</a> function reads a single lexeme from the input,
--   discarding initial white space, and returning the characters that
--   constitute the lexeme. If the input string contains only white space,
--   <a>lex</a> returns a single successful `lexeme' consisting of the
--   empty string. (Thus <tt><a>lex</a> "" = [("","")]</tt>.) If there is
--   no legal lexeme at the beginning of the input string, <a>lex</a> fails
--   (i.e. returns <tt>[]</tt>).
--   
--   This lexer is not completely faithful to the Haskell lexical syntax in
--   the following respects:
--   
--   <ul>
--   <li>Qualified names are not handled properly</li>
--   <li>Octal and hexadecimal numerics are not recognized as a single
--   token</li>
--   <li>Comments are not treated properly</li>
--   </ul>
lex :: ReadS String

-- | <tt><a>readParen</a> <a>True</a> p</tt> parses what <tt>p</tt> parses,
--   but surrounded with parentheses.
--   
--   <tt><a>readParen</a> <a>False</a> p</tt> parses what <tt>p</tt>
--   parses, but optionally surrounded with parentheses.
readParen :: () => Bool -> ReadS a -> ReadS a

-- | A parser for a type <tt>a</tt>, represented as a function that takes a
--   <a>String</a> and returns a list of possible parses as
--   <tt>(a,<a>String</a>)</tt> pairs.
--   
--   Note that this kind of backtracking parser is very inefficient;
--   reading a large structure may be quite slow (cf <a>ReadP</a>).
type ReadS a = String -> [(a, String)]

-- | An infix synonym for <a>fmap</a>.
--   
--   The name of this operator is an allusion to <tt>$</tt>. Note the
--   similarities between their types:
--   
--   <pre>
--    ($)  ::              (a -&gt; b) -&gt;   a -&gt;   b
--   (&lt;$&gt;) :: Functor f =&gt; (a -&gt; b) -&gt; f a -&gt; f b
--   </pre>
--   
--   Whereas <tt>$</tt> is function application, <a>&lt;$&gt;</a> is
--   function application lifted over a <a>Functor</a>.
--   
--   <h4><b>Examples</b></h4>
--   
--   Convert from a <tt><tt>Maybe</tt> <tt>Int</tt></tt> to a
--   <tt><tt>Maybe</tt> <tt>String</tt></tt> using <tt>show</tt>:
--   
--   <pre>
--   &gt;&gt;&gt; show &lt;$&gt; Nothing
--   Nothing
--   
--   &gt;&gt;&gt; show &lt;$&gt; Just 3
--   Just "3"
--   </pre>
--   
--   Convert from an <tt><tt>Either</tt> <tt>Int</tt> <tt>Int</tt></tt> to
--   an <tt><tt>Either</tt> <tt>Int</tt></tt> <tt>String</tt> using
--   <tt>show</tt>:
--   
--   <pre>
--   &gt;&gt;&gt; show &lt;$&gt; Left 17
--   Left 17
--   
--   &gt;&gt;&gt; show &lt;$&gt; Right 17
--   Right "17"
--   </pre>
--   
--   Double each element of a list:
--   
--   <pre>
--   &gt;&gt;&gt; (*2) &lt;$&gt; [1,2,3]
--   [2,4,6]
--   </pre>
--   
--   Apply <tt>even</tt> to the second element of a pair:
--   
--   <pre>
--   &gt;&gt;&gt; even &lt;$&gt; (2,2)
--   (2,True)
--   </pre>
(<$>) :: Functor f => a -> b -> f a -> f b
infixl 4 <$>

-- | <tt><a>lcm</a> x y</tt> is the smallest positive integer that both
--   <tt>x</tt> and <tt>y</tt> divide.
lcm :: Integral a => a -> a -> a

-- | <tt><a>gcd</a> x y</tt> is the non-negative factor of both <tt>x</tt>
--   and <tt>y</tt> of which every common factor of <tt>x</tt> and
--   <tt>y</tt> is also a factor; for example <tt><a>gcd</a> 4 2 = 2</tt>,
--   <tt><a>gcd</a> (-4) 6 = 2</tt>, <tt><a>gcd</a> 0 4</tt> = <tt>4</tt>.
--   <tt><a>gcd</a> 0 0</tt> = <tt>0</tt>. (That is, the common divisor
--   that is "greatest" in the divisibility preordering.)
--   
--   Note: Since for signed fixed-width integer types, <tt><a>abs</a>
--   <a>minBound</a> &lt; 0</tt>, the result may be negative if one of the
--   arguments is <tt><a>minBound</a></tt> (and necessarily is if the other
--   is <tt>0</tt> or <tt><a>minBound</a></tt>) for such types.
gcd :: Integral a => a -> a -> a

-- | raise a number to an integral power
(^^) :: (Fractional a, Integral b) => a -> b -> a
infixr 8 ^^

-- | raise a number to a non-negative integral power
(^) :: (Num a, Integral b) => a -> b -> a
infixr 8 ^
odd :: Integral a => a -> Bool
even :: Integral a => a -> Bool

-- | utility function that surrounds the inner show function with
--   parentheses when the <a>Bool</a> parameter is <a>True</a>.
showParen :: Bool -> ShowS -> ShowS

-- | utility function converting a <a>String</a> to a show function that
--   simply prepends the string unchanged.
showString :: String -> ShowS

-- | utility function converting a <a>Char</a> to a show function that
--   simply prepends the character unchanged.
showChar :: Char -> ShowS

-- | equivalent to <a>showsPrec</a> with a precedence of 0.
shows :: Show a => a -> ShowS

-- | The <a>unzip3</a> function takes a list of triples and returns three
--   lists, analogous to <a>unzip</a>.
unzip3 :: () => [(a, b, c)] -> ([a], [b], [c])

-- | <a>unzip</a> transforms a list of pairs into a list of first
--   components and a list of second components.
unzip :: () => [(a, b)] -> ([a], [b])

-- | The <a>zipWith3</a> function takes a function which combines three
--   elements, as well as three lists and returns a list of their
--   point-wise combination, analogous to <a>zipWith</a>.
zipWith3 :: () => a -> b -> c -> d -> [a] -> [b] -> [c] -> [d]

-- | <a>zipWith</a> generalises <a>zip</a> by zipping with the function
--   given as the first argument, instead of a tupling function. For
--   example, <tt><a>zipWith</a> (+)</tt> is applied to two lists to
--   produce the list of corresponding sums.
--   
--   <a>zipWith</a> is right-lazy:
--   
--   <pre>
--   zipWith f [] _|_ = []
--   </pre>
zipWith :: () => a -> b -> c -> [a] -> [b] -> [c]

-- | <a>zip3</a> takes three lists and returns a list of triples, analogous
--   to <a>zip</a>.
zip3 :: () => [a] -> [b] -> [c] -> [(a, b, c)]

-- | List index (subscript) operator, starting from 0. It is an instance of
--   the more general <a>genericIndex</a>, which takes an index of any
--   integral type.
(!!) :: () => [a] -> Int -> a
infixl 9 !!

-- | <a>lookup</a> <tt>key assocs</tt> looks up a key in an association
--   list.
lookup :: Eq a => a -> [(a, b)] -> Maybe b

-- | <a>reverse</a> <tt>xs</tt> returns the elements of <tt>xs</tt> in
--   reverse order. <tt>xs</tt> must be finite.
reverse :: () => [a] -> [a]

-- | <a>break</a>, applied to a predicate <tt>p</tt> and a list
--   <tt>xs</tt>, returns a tuple where first element is longest prefix
--   (possibly empty) of <tt>xs</tt> of elements that <i>do not satisfy</i>
--   <tt>p</tt> and second element is the remainder of the list:
--   
--   <pre>
--   break (&gt; 3) [1,2,3,4,1,2,3,4] == ([1,2,3],[4,1,2,3,4])
--   break (&lt; 9) [1,2,3] == ([],[1,2,3])
--   break (&gt; 9) [1,2,3] == ([1,2,3],[])
--   </pre>
--   
--   <a>break</a> <tt>p</tt> is equivalent to <tt><a>span</a> (<a>not</a> .
--   p)</tt>.
break :: () => a -> Bool -> [a] -> ([a], [a])

-- | <a>span</a>, applied to a predicate <tt>p</tt> and a list <tt>xs</tt>,
--   returns a tuple where first element is longest prefix (possibly empty)
--   of <tt>xs</tt> of elements that satisfy <tt>p</tt> and second element
--   is the remainder of the list:
--   
--   <pre>
--   span (&lt; 3) [1,2,3,4,1,2,3,4] == ([1,2],[3,4,1,2,3,4])
--   span (&lt; 9) [1,2,3] == ([1,2,3],[])
--   span (&lt; 0) [1,2,3] == ([],[1,2,3])
--   </pre>
--   
--   <a>span</a> <tt>p xs</tt> is equivalent to <tt>(<a>takeWhile</a> p xs,
--   <a>dropWhile</a> p xs)</tt>
span :: () => a -> Bool -> [a] -> ([a], [a])

-- | <a>splitAt</a> <tt>n xs</tt> returns a tuple where first element is
--   <tt>xs</tt> prefix of length <tt>n</tt> and second element is the
--   remainder of the list:
--   
--   <pre>
--   splitAt 6 "Hello World!" == ("Hello ","World!")
--   splitAt 3 [1,2,3,4,5] == ([1,2,3],[4,5])
--   splitAt 1 [1,2,3] == ([1],[2,3])
--   splitAt 3 [1,2,3] == ([1,2,3],[])
--   splitAt 4 [1,2,3] == ([1,2,3],[])
--   splitAt 0 [1,2,3] == ([],[1,2,3])
--   splitAt (-1) [1,2,3] == ([],[1,2,3])
--   </pre>
--   
--   It is equivalent to <tt>(<a>take</a> n xs, <a>drop</a> n xs)</tt> when
--   <tt>n</tt> is not <tt>_|_</tt> (<tt>splitAt _|_ xs = _|_</tt>).
--   <a>splitAt</a> is an instance of the more general
--   <a>genericSplitAt</a>, in which <tt>n</tt> may be of any integral
--   type.
splitAt :: () => Int -> [a] -> ([a], [a])

-- | <a>drop</a> <tt>n xs</tt> returns the suffix of <tt>xs</tt> after the
--   first <tt>n</tt> elements, or <tt>[]</tt> if <tt>n &gt; <a>length</a>
--   xs</tt>:
--   
--   <pre>
--   drop 6 "Hello World!" == "World!"
--   drop 3 [1,2,3,4,5] == [4,5]
--   drop 3 [1,2] == []
--   drop 3 [] == []
--   drop (-1) [1,2] == [1,2]
--   drop 0 [1,2] == [1,2]
--   </pre>
--   
--   It is an instance of the more general <a>genericDrop</a>, in which
--   <tt>n</tt> may be of any integral type.
drop :: () => Int -> [a] -> [a]

-- | <a>take</a> <tt>n</tt>, applied to a list <tt>xs</tt>, returns the
--   prefix of <tt>xs</tt> of length <tt>n</tt>, or <tt>xs</tt> itself if
--   <tt>n &gt; <a>length</a> xs</tt>:
--   
--   <pre>
--   take 5 "Hello World!" == "Hello"
--   take 3 [1,2,3,4,5] == [1,2,3]
--   take 3 [1,2] == [1,2]
--   take 3 [] == []
--   take (-1) [1,2] == []
--   take 0 [1,2] == []
--   </pre>
--   
--   It is an instance of the more general <a>genericTake</a>, in which
--   <tt>n</tt> may be of any integral type.
take :: () => Int -> [a] -> [a]

-- | <a>dropWhile</a> <tt>p xs</tt> returns the suffix remaining after
--   <a>takeWhile</a> <tt>p xs</tt>:
--   
--   <pre>
--   dropWhile (&lt; 3) [1,2,3,4,5,1,2,3] == [3,4,5,1,2,3]
--   dropWhile (&lt; 9) [1,2,3] == []
--   dropWhile (&lt; 0) [1,2,3] == [1,2,3]
--   </pre>
dropWhile :: () => a -> Bool -> [a] -> [a]

-- | <a>takeWhile</a>, applied to a predicate <tt>p</tt> and a list
--   <tt>xs</tt>, returns the longest prefix (possibly empty) of
--   <tt>xs</tt> of elements that satisfy <tt>p</tt>:
--   
--   <pre>
--   takeWhile (&lt; 3) [1,2,3,4,1,2,3,4] == [1,2]
--   takeWhile (&lt; 9) [1,2,3] == [1,2,3]
--   takeWhile (&lt; 0) [1,2,3] == []
--   </pre>
takeWhile :: () => a -> Bool -> [a] -> [a]

-- | <a>cycle</a> ties a finite list into a circular one, or equivalently,
--   the infinite repetition of the original list. It is the identity on
--   infinite lists.
cycle :: () => [a] -> [a]

-- | <a>replicate</a> <tt>n x</tt> is a list of length <tt>n</tt> with
--   <tt>x</tt> the value of every element. It is an instance of the more
--   general <a>genericReplicate</a>, in which <tt>n</tt> may be of any
--   integral type.
replicate :: () => Int -> a -> [a]

-- | <a>repeat</a> <tt>x</tt> is an infinite list, with <tt>x</tt> the
--   value of every element.
repeat :: () => a -> [a]

-- | <a>iterate</a> <tt>f x</tt> returns an infinite list of repeated
--   applications of <tt>f</tt> to <tt>x</tt>:
--   
--   <pre>
--   iterate f x == [x, f x, f (f x), ...]
--   </pre>
--   
--   Note that <a>iterate</a> is lazy, potentially leading to thunk
--   build-up if the consumer doesn't force each iterate. See 'iterate\''
--   for a strict variant of this function.
iterate :: () => a -> a -> a -> [a]

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

-- | <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 :: () => a -> b -> b -> b -> [a] -> [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, ...]
--   </pre>
scanl1 :: () => a -> a -> a -> [a] -> [a]

-- | <a>scanl</a> is similar to <a>foldl</a>, but returns a list 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 :: () => b -> a -> b -> b -> [a] -> [b]

-- | Return all the elements of a list except the last one. The list must
--   be non-empty.
init :: () => [a] -> [a]

-- | Extract the last element of a list, which must be finite and
--   non-empty.
last :: () => [a] -> a

-- | Extract the elements after the head of a list, which must be
--   non-empty.
tail :: () => [a] -> [a]

-- | Extract the first element of a list, which must be non-empty.
head :: () => [a] -> a

-- | The <a>maybe</a> function takes a default value, a function, and a
--   <a>Maybe</a> value. If the <a>Maybe</a> value is <a>Nothing</a>, the
--   function returns the default value. Otherwise, it applies the function
--   to the value inside the <a>Just</a> and returns the result.
--   
--   <h4><b>Examples</b></h4>
--   
--   Basic usage:
--   
--   <pre>
--   &gt;&gt;&gt; maybe False odd (Just 3)
--   True
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; maybe False odd Nothing
--   False
--   </pre>
--   
--   Read an integer from a string using <tt>readMaybe</tt>. If we succeed,
--   return twice the integer; that is, apply <tt>(*2)</tt> to it. If
--   instead we fail to parse an integer, return <tt>0</tt> by default:
--   
--   <pre>
--   &gt;&gt;&gt; import Text.Read ( readMaybe )
--   
--   &gt;&gt;&gt; maybe 0 (*2) (readMaybe "5")
--   10
--   
--   &gt;&gt;&gt; maybe 0 (*2) (readMaybe "")
--   0
--   </pre>
--   
--   Apply <tt>show</tt> to a <tt>Maybe Int</tt>. If we have <tt>Just
--   n</tt>, we want to show the underlying <a>Int</a> <tt>n</tt>. But if
--   we have <a>Nothing</a>, we return the empty string instead of (for
--   example) "Nothing":
--   
--   <pre>
--   &gt;&gt;&gt; maybe "" show (Just 5)
--   "5"
--   
--   &gt;&gt;&gt; maybe "" show Nothing
--   ""
--   </pre>
maybe :: () => b -> a -> b -> Maybe a -> b

-- | <a>uncurry</a> converts a curried function to a function on pairs.
--   
--   <h4><b>Examples</b></h4>
--   
--   <pre>
--   &gt;&gt;&gt; uncurry (+) (1,2)
--   3
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; uncurry ($) (show, 1)
--   "1"
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; map (uncurry max) [(1,2), (3,4), (6,8)]
--   [2,4,8]
--   </pre>
uncurry :: () => a -> b -> c -> (a, b) -> c

-- | <a>curry</a> converts an uncurried function to a curried function.
--   
--   <h4><b>Examples</b></h4>
--   
--   <pre>
--   &gt;&gt;&gt; curry fst 1 2
--   1
--   </pre>
curry :: () => (a, b) -> c -> a -> b -> c

-- | the same as <tt><a>flip</a> (<a>-</a>)</tt>.
--   
--   Because <tt>-</tt> is treated specially in the Haskell grammar,
--   <tt>(-</tt> <i>e</i><tt>)</tt> is not a section, but an application of
--   prefix negation. However, <tt>(<a>subtract</a></tt>
--   <i>exp</i><tt>)</tt> is equivalent to the disallowed section.
subtract :: Num a => a -> a -> a

-- | <a>asTypeOf</a> is a type-restricted version of <a>const</a>. It is
--   usually used as an infix operator, and its typing forces its first
--   argument (which is usually overloaded) to have the same type as the
--   second.
asTypeOf :: () => a -> a -> a

-- | <tt><a>until</a> p f</tt> yields the result of applying <tt>f</tt>
--   until <tt>p</tt> holds.
until :: () => a -> Bool -> a -> a -> a -> a

-- | Strict (call-by-value) application operator. It takes a function and
--   an argument, evaluates the argument to weak head normal form (WHNF),
--   then calls the function with that value.
($!) :: () => a -> b -> a -> b
infixr 0 $!

-- | <tt><a>flip</a> f</tt> takes its (first) two arguments in the reverse
--   order of <tt>f</tt>.
--   
--   <pre>
--   &gt;&gt;&gt; flip (++) "hello" "world"
--   "worldhello"
--   </pre>
flip :: () => a -> b -> c -> b -> a -> c

-- | Function composition.
(.) :: () => b -> c -> a -> b -> a -> c
infixr 9 .

-- | <tt>const x</tt> is a unary function which evaluates to <tt>x</tt> for
--   all inputs.
--   
--   <pre>
--   &gt;&gt;&gt; const 42 "hello"
--   42
--   </pre>
--   
--   <pre>
--   &gt;&gt;&gt; map (const 42) [0..3]
--   [42,42,42,42]
--   </pre>
const :: () => a -> b -> a

-- | Identity function.
--   
--   <pre>
--   id x = x
--   </pre>
id :: () => a -> a

-- | Same as <a>&gt;&gt;=</a>, but with the arguments interchanged.
(=<<) :: Monad m => a -> m b -> m a -> m b
infixr 1 =<<

-- | A special case of <a>error</a>. It is expected that compilers will
--   recognize this and insert error messages which are more appropriate to
--   the context in which <a>undefined</a> appears.
undefined :: HasCallStack => a

-- | A variant of <a>error</a> that does not produce a stack trace.
errorWithoutStackTrace :: () => [Char] -> a

-- | <a>error</a> stops execution and displays an error message.
error :: HasCallStack => [Char] -> a

-- | Boolean "and"
(&&) :: Bool -> Bool -> Bool
infixr 3 &&

-- | Boolean "or"
(||) :: Bool -> Bool -> Bool
infixr 2 ||

-- | Boolean "not"
not :: Bool -> Bool
instance Test.Hspec.Discover.IsFormatter (GHC.Types.IO Test.Hspec.Core.Formatters.Monad.Formatter)
instance Test.Hspec.Discover.IsFormatter Test.Hspec.Core.Formatters.Monad.Formatter

module Test.Hspec.Runner


-- | Hspec is a testing framework for Haskell.
--   
--   This is the library reference for Hspec. The <a>User's Manual</a>
--   contains more in-depth documentation.
module Test.Hspec
type Spec = SpecWith ()
type SpecWith a = SpecM a ()

-- | A type class for examples
class Example e

-- | The <tt>it</tt> function creates a spec item.
--   
--   A spec item consists of:
--   
--   <ul>
--   <li>a textual description of a desired behavior</li>
--   <li>an example for that behavior</li>
--   </ul>
--   
--   <pre>
--   describe "absolute" $ do
--     it "returns a positive number when given a negative number" $
--       absolute (-1) == 1
--   </pre>
it :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | <tt>specify</tt> is an alias for <a>it</a>.
specify :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | The <tt>describe</tt> function combines a list of specs into a larger
--   spec.
describe :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | <tt>context</tt> is an alias for <a>describe</a>.
context :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | <tt>example</tt> is a type restricted version of <a>id</a>. It can be
--   used to get better error messages on type mismatches.
--   
--   Compare e.g.
--   
--   <pre>
--   it "exposes some behavior" $ example $ do
--     putStrLn
--   </pre>
--   
--   with
--   
--   <pre>
--   it "exposes some behavior" $ do
--     putStrLn
--   </pre>
example :: Expectation -> Expectation

-- | <a>parallel</a> marks all spec items of the given spec to be safe for
--   parallel evaluation.
parallel :: () => SpecWith a -> SpecWith a

-- | Run an IO action while constructing the spec tree.
--   
--   <a>SpecM</a> is a monad to construct a spec tree, without executing
--   any spec items. <tt>runIO</tt> allows you to run IO actions during
--   this construction phase. The IO action is always run when the spec
--   tree is constructed (e.g. even when <tt>--dry-run</tt> is specified).
--   If you do not need the result of the IO action to construct the spec
--   tree, <a>beforeAll</a> may be more suitable for your use case.
runIO :: () => IO r -> SpecM a r

-- | <a>pending</a> can be used to mark a spec item as pending.
--   
--   If you want to textually specify a behavior but do not have an example
--   yet, use this:
--   
--   <pre>
--   describe "fancyFormatter" $ do
--     it "can format text in a way that everyone likes" $
--       pending
--   </pre>
pending :: HasCallStack -> Expectation

-- | <a>pendingWith</a> is similar to <a>pending</a>, but it takes an
--   additional string argument that can be used to specify the reason for
--   why the spec item is pending.
pendingWith :: HasCallStack -> String -> Expectation

-- | Changing <a>it</a> to <a>xit</a> marks the corresponding spec item as
--   pending.
--   
--   This can be used to temporarily disable a spec item.
xit :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | <tt>xspecify</tt> is an alias for <a>xit</a>.
xspecify :: (HasCallStack, Example a) => String -> a -> SpecWith Arg a

-- | Changing <a>describe</a> to <a>xdescribe</a> marks all spec items of
--   the corresponding subtree as pending.
--   
--   This can be used to temporarily disable spec items.
xdescribe :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | <tt>xcontext</tt> is an alias for <a>xdescribe</a>.
xcontext :: HasCallStack => String -> SpecWith a -> SpecWith a

-- | An <a>IO</a> action that expects an argument of type <tt>a</tt>
type ActionWith a = a -> IO ()

-- | Run a custom action before every spec item.
before :: () => IO a -> SpecWith a -> Spec

-- | Run a custom action before every spec item.
before_ :: () => IO () -> SpecWith a -> SpecWith a

-- | Run a custom action before every spec item.
beforeWith :: () => b -> IO a -> SpecWith a -> SpecWith b

-- | Run a custom action before the first spec item.
beforeAll :: () => IO a -> SpecWith a -> Spec

-- | Run a custom action before the first spec item.
beforeAll_ :: () => IO () -> SpecWith a -> SpecWith a

-- | Run a custom action after every spec item.
after :: () => ActionWith a -> SpecWith a -> SpecWith a

-- | Run a custom action after every spec item.
after_ :: () => IO () -> SpecWith a -> SpecWith a

-- | Run a custom action after the last spec item.
afterAll :: () => ActionWith a -> SpecWith a -> SpecWith a

-- | Run a custom action after the last spec item.
afterAll_ :: () => IO () -> SpecWith a -> SpecWith a

-- | Run a custom action before and/or after every spec item.
around :: () => ActionWith a -> IO () -> SpecWith a -> Spec

-- | Run a custom action before and/or after every spec item.
around_ :: () => IO () -> IO () -> SpecWith a -> SpecWith a

-- | Run a custom action before and/or after every spec item.
aroundWith :: () => ActionWith a -> ActionWith b -> SpecWith a -> SpecWith b

-- | Run given spec and write a report to <a>stdout</a>. Exit with
--   <a>exitFailure</a> if at least one spec item fails.
hspec :: Spec -> IO ()

module Test.Hspec.QuickCheck

-- | Use a modified <a>maxSuccess</a> for given spec.
modifyMaxSuccess :: () => Int -> Int -> SpecWith a -> SpecWith a

-- | Use a modified <a>maxDiscardRatio</a> for given spec.
modifyMaxDiscardRatio :: () => Int -> Int -> SpecWith a -> SpecWith a

-- | Use a modified <a>maxSize</a> for given spec.
modifyMaxSize :: () => Int -> Int -> SpecWith a -> SpecWith a

-- | <pre>
--   prop ".." $
--     ..
--   </pre>
--   
--   is a shortcut for
--   
--   <pre>
--   it ".." $ property $
--     ..
--   </pre>
prop :: (HasCallStack, Testable prop) => String -> prop -> Spec
