-- Hoogle documentation, generated by Haddock
-- See Hoogle, http://www.haskell.org/hoogle/
-- | Types, functions, and tools to manipulate the openSUSE distribution
--
-- This library is a loose collection of types, functions, and tools that
-- users and developers of the openSUSE Linux distribution might
-- find useful.
@package distribution-opensuse
@version 1.1.3
module OpenSuse.Prelude.Parser
module OpenSuse.Prelude.PrettyPrinting.Orphans
instance Text.PrettyPrint.HughesPJClass.Pretty GHC.Natural.Natural
-- | This is simply a re-export of the standard library pretty
-- with some orphan instances added for convenience.
module OpenSuse.Prelude.PrettyPrinting
module OpenSuse.Prelude
-- | Append two lists, i.e.,
--
--
-- [x1, ..., xm] ++ [y1, ..., yn] == [x1, ..., xm, y1, ..., yn]
-- [x1, ..., xm] ++ [y1, ...] == [x1, ..., xm, y1, ...]
--
--
-- If the first list is not finite, the result is the first list.
(++) :: [a] -> [a] -> [a]
infixr 5 ++
-- | The value of seq a b is bottom if a is bottom, and
-- otherwise equal to b. In other words, it evaluates the first
-- argument a to weak head normal form (WHNF). seq is
-- usually introduced to improve performance by avoiding unneeded
-- laziness.
--
-- A note on evaluation order: the expression seq a b does
-- not guarantee that a will be evaluated before
-- b. The only guarantee given by seq is that the both
-- a and b will be evaluated before seq
-- returns a value. In particular, this means that b may be
-- evaluated before a. If you need to guarantee a specific order
-- of evaluation, you must use the function pseq from the
-- "parallel" package.
seq :: forall (r :: RuntimeRep) a (b :: TYPE r). a -> b -> b
infixr 0 `seq`
-- | <math>. filter, applied to a predicate and a list,
-- returns the list of those elements that satisfy the predicate; i.e.,
--
--
-- filter p xs = [ x | x <- xs, p x]
--
--
--
-- >>> filter odd [1, 2, 3]
-- [1,3]
--
filter :: (a -> Bool) -> [a] -> [a]
-- | <math>. zip takes two lists and returns a list of
-- corresponding pairs.
--
--
-- zip [1, 2] ['a', 'b'] = [(1, 'a'), (2, 'b')]
--
--
-- If one input list is short, excess elements of the longer list are
-- discarded:
--
--
-- zip [1] ['a', 'b'] = [(1, 'a')]
-- zip [1, 2] ['a'] = [(1, 'a')]
--
--
-- zip is right-lazy:
--
--
-- zip [] _|_ = []
-- zip _|_ [] = _|_
--
--
-- zip is capable of list fusion, but it is restricted to its
-- first list argument and its resulting list.
zip :: [a] -> [b] -> [(a, b)]
-- | The print function outputs a value of any printable type to the
-- standard output device. Printable types are those that are instances
-- of class Show; print converts values to strings for
-- output using the show operation and adds a newline.
--
-- For example, a program to print the first 20 integers and their powers
-- of 2 could be written as:
--
--
-- main = print ([(n, 2^n) | n <- [0..19]])
--
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
-- | otherwise is defined as the value True. It helps to make
-- guards more readable. eg.
--
--
-- f x | x < 0 = ...
-- | otherwise = ...
--
otherwise :: Bool
-- | <math>. map f xs is the list obtained by
-- applying f to each element of xs, i.e.,
--
--
-- map f [x1, x2, ..., xn] == [f x1, f x2, ..., f xn]
-- map f [x1, x2, ...] == [f x1, f x2, ...]
--
--
--
-- >>> map (+1) [1, 2, 3]
--
map :: (a -> b) -> [a] -> [b]
-- | Application operator. This operator is redundant, since ordinary
-- application (f x) means the same as (f $ x).
-- However, $ has low, right-associative binding precedence, so it
-- sometimes allows parentheses to be omitted; for example:
--
--
-- f $ g $ h x = f (g (h x))
--
--
-- It is also useful in higher-order situations, such as map
-- ($ 0) xs, or zipWith ($) fs xs.
--
-- Note that ($) is levity-polymorphic in its result
-- type, so that foo $ True where foo :: Bool ->
-- Int# is well-typed.
($) :: forall (r :: RuntimeRep) a (b :: TYPE r). (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 Bounded class is used to name the upper and lower limits of
-- a type. Ord is not a superclass of Bounded since types
-- that are not totally ordered may also have upper and lower bounds.
--
-- The Bounded class may be derived for any enumeration type;
-- minBound is the first constructor listed in the data
-- declaration and maxBound is the last. Bounded may also
-- be derived for single-constructor datatypes whose constituent types
-- are in Bounded.
class Bounded a
minBound :: Bounded a => a
maxBound :: Bounded a => a
-- | Class Enum defines operations on sequentially ordered types.
--
-- The enumFrom... methods are used in Haskell's translation of
-- arithmetic sequences.
--
-- Instances of Enum 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 fromEnum from
-- 0 through n-1. See Chapter 10 of the Haskell
-- Report for more details.
--
-- For any type that is an instance of class Bounded as well as
-- Enum, the following should hold:
--
--
--
--
-- enumFrom x = enumFromTo x maxBound
-- enumFromThen x y = enumFromThenTo x y bound
-- where
-- bound | fromEnum y >= fromEnum x = maxBound
-- | otherwise = minBound
--
class Enum a
-- | the successor of a value. For numeric types, succ adds 1.
succ :: Enum a => a -> a
-- | the predecessor of a value. For numeric types, pred subtracts
-- 1.
pred :: Enum a => a -> a
-- | Convert from an Int.
toEnum :: Enum a => Int -> a
-- | Convert to an Int. It is implementation-dependent what
-- fromEnum returns when applied to a value that is too large to
-- fit in an Int.
fromEnum :: Enum a => a -> Int
-- | Used in Haskell's translation of [n..] with [n..] =
-- enumFrom n, a possible implementation being enumFrom n = n :
-- enumFrom (succ n). For example:
--
--
-- enumFrom 4 :: [Integer] = [4,5,6,7,...]
enumFrom 6 :: [Int] = [6,7,8,9,...,maxBound ::
-- Int]
enumFrom :: Enum a => a -> [a]
-- | Used in Haskell's translation of [n,n'..] with [n,n'..] =
-- enumFromThen n n', a possible implementation being
-- enumFromThen n n' = n : n' : worker (f x) (f x n'),
-- worker s v = v : worker s (s v), x = fromEnum n' -
-- fromEnum n and f n y | n > 0 = f (n - 1) (succ y) | n <
-- 0 = f (n + 1) (pred y) | otherwise = y For example:
--
--
-- enumFromThen 4 6 :: [Integer] = [4,6,8,10...]
enumFromThen 6 2 :: [Int] = [6,2,-2,-6,...,minBound ::
-- Int]
enumFromThen :: Enum a => a -> a -> [a]
-- | Used in Haskell's translation of [n..m] with [n..m] =
-- enumFromTo n m, a possible implementation being enumFromTo n
-- m | n <= m = n : enumFromTo (succ n) m | otherwise = []. For
-- example:
--
--
-- enumFromTo 6 10 :: [Int] = [6,7,8,9,10]
enumFromTo 42 1 :: [Integer] = []
enumFromTo :: Enum a => a -> a -> [a]
-- | Used in Haskell's translation of [n,n'..m] with [n,n'..m]
-- = enumFromThenTo n n' m, a possible implementation being
-- enumFromThenTo n n' m = worker (f x) (c x) n m, x =
-- fromEnum n' - fromEnum n, c x = bool (>=) ((x
-- 0) f n y | n > 0 = f (n - 1) (succ y) | n < 0 = f (n +
-- 1) (pred y) | otherwise = y and worker s c v m | c v m = v :
-- worker s c (s v) m | otherwise = [] For example:
--
--
-- enumFromThenTo 4 2 -6 :: [Integer] =
-- [4,2,0,-2,-4,-6]
enumFromThenTo 6 8 2 :: [Int] = []
enumFromThenTo :: Enum a => a -> a -> a -> [a]
-- | The Eq class defines equality (==) and inequality
-- (/=). All the basic datatypes exported by the Prelude
-- are instances of Eq, and Eq may be derived for any
-- datatype whose constituents are also instances of Eq.
--
-- The Haskell Report defines no laws for Eq. However, ==
-- is customarily expected to implement an equivalence relationship where
-- two values comparing equal are indistinguishable by "public"
-- functions, with a "public" function being one not allowing to see
-- implementation details. For example, for a type representing
-- non-normalised natural numbers modulo 100, a "public" function doesn't
-- make the difference between 1 and 201. It is expected to have the
-- following properties:
--
--
-- - Reflexivity x == x = True
-- - Symmetry x == y = y == x
-- - Transitivity if x == y && y == z =
-- True, then x == z = True
-- - Substitutivity if x == y = True and
-- f is a "public" function whose return type is an instance of
-- Eq, then f x == f y = True
-- - Negation x /= y = not (x ==
-- y)
--
--
-- Minimal complete definition: either == or /=.
class Eq a
(==) :: Eq a => a -> a -> Bool
(/=) :: Eq a => a -> a -> Bool
infix 4 ==
infix 4 /=
-- | Trigonometric and hyperbolic functions and related functions.
--
-- The Haskell Report defines no laws for Floating. However,
-- (+), (*) and exp are
-- customarily expected to define an exponential field and have the
-- following properties:
--
--
-- - exp (a + b) = exp a * exp b
-- - exp (fromInteger 0) = fromInteger 1
--
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
infixr 8 **
-- | Fractional numbers, supporting real division.
--
-- The Haskell Report defines no laws for Fractional. However,
-- (+) and (*) are customarily expected
-- to define a division ring and have the following properties:
--
--
-- - recip gives the multiplicative inverse x
-- * recip x = recip x * x = fromInteger 1
--
--
-- Note that it isn't customarily expected that a type instance of
-- Fractional implement a field. However, all instances in
-- base do.
class Num a => Fractional a
-- | Fractional division.
(/) :: Fractional a => a -> a -> a
-- | Reciprocal fraction.
recip :: Fractional a => a -> a
-- | Conversion from a Rational (that is Ratio
-- Integer). A floating literal stands for an application of
-- fromRational to a value of type Rational, so such
-- literals have type (Fractional a) => a.
fromRational :: Fractional a => Rational -> a
infixl 7 /
-- | Integral numbers, supporting integer division.
--
-- The Haskell Report defines no laws for Integral. However,
-- Integral instances are customarily expected to define a
-- Euclidean domain and have the following properties for the
-- div/mod and quot/rem pairs, given suitable
-- Euclidean functions f and g:
--
--
-- - x = y * quot x y + rem x y with rem x y
-- = fromInteger 0 or g (rem x y) < g
-- y
-- - x = y * div x y + mod x y with mod x y
-- = fromInteger 0 or f (mod x y) < f
-- y
--
--
-- An example of a suitable Euclidean function, for Integer's
-- instance, is abs.
class (Real a, Enum a) => Integral a
-- | integer division truncated toward zero
quot :: Integral a => a -> a -> a
-- | integer remainder, satisfying
--
--
-- (x `quot` y)*y + (x `rem` y) == x
--
rem :: Integral a => a -> a -> a
-- | integer division truncated toward negative infinity
div :: Integral a => a -> a -> a
-- | integer modulus, satisfying
--
--
-- (x `div` y)*y + (x `mod` y) == x
--
mod :: Integral a => a -> a -> a
-- | simultaneous quot and rem
quotRem :: Integral a => a -> a -> (a, a)
-- | simultaneous div and mod
divMod :: Integral a => a -> a -> (a, a)
-- | conversion to Integer
toInteger :: Integral a => a -> Integer
infixl 7 `mod`
infixl 7 `div`
infixl 7 `rem`
infixl 7 `quot`
-- | The Monad class defines the basic operations over a
-- monad, a concept from a branch of mathematics known as
-- category theory. From the perspective of a Haskell programmer,
-- however, it is best to think of a monad as an abstract datatype
-- of actions. Haskell's do expressions provide a convenient
-- syntax for writing monadic expressions.
--
-- Instances of Monad should satisfy the following:
--
--
--
-- Furthermore, the Monad and Applicative operations should
-- relate as follows:
--
--
--
-- The above laws imply:
--
--
--
-- and that pure and (<*>) satisfy the applicative
-- functor laws.
--
-- The instances of Monad for lists, Maybe and IO
-- defined in the Prelude satisfy these laws.
class Applicative m => Monad (m :: Type -> Type)
-- | Sequentially compose two actions, passing any value produced by the
-- first as an argument to the second.
--
-- 'as >>= bs' can be understood as the do
-- expression
--
--
-- do a <- as
-- bs a
--
(>>=) :: 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.
--
-- 'as >> bs' can be understood as the do
-- expression
--
--
-- do as
-- bs
--
(>>) :: Monad m => m a -> m b -> m b
-- | Inject a value into the monadic type.
return :: Monad m => a -> m a
infixl 1 >>=
infixl 1 >>
-- | A type f is a Functor if it provides a function fmap
-- which, given any types a and b lets you apply any
-- function from (a -> b) to turn an f a into an
-- f b, preserving the structure of f. Furthermore
-- f needs to adhere to the following:
--
--
--
-- Note, that the second law follows from the free theorem of the type
-- fmap and the first law, so you need only check that the former
-- condition holds.
class Functor (f :: Type -> Type)
-- | Using ApplicativeDo: 'fmap f as' can be
-- understood as the do expression
--
--
-- do a <- as
-- pure (f a)
--
--
-- with an inferred Functor constraint.
fmap :: Functor f => (a -> b) -> f a -> f b
-- | Replace all locations in the input with the same value. The default
-- definition is fmap . const, but this may be
-- overridden with a more efficient version.
--
-- Using ApplicativeDo: 'a <$ bs' can be
-- understood as the do expression
--
--
-- do bs
-- pure a
--
--
-- with an inferred Functor constraint.
(<$) :: Functor f => a -> f b -> f a
infixl 4 <$
-- | Basic numeric class.
--
-- The Haskell Report defines no laws for Num. However,
-- (+) and (*) are customarily expected
-- to define a ring and have the following properties:
--
--
-- - Associativity of (+) (x + y) +
-- z = x + (y + z)
-- - Commutativity of (+) x + y
-- = y + x
-- - fromInteger 0 is the additive
-- identity x + fromInteger 0 = x
-- - negate gives the additive inverse x +
-- negate x = fromInteger 0
-- - Associativity of (*) (x * y) *
-- z = x * (y * z)
-- - fromInteger 1 is the multiplicative
-- identity x * fromInteger 1 = x and
-- fromInteger 1 * x = x
-- - Distributivity of (*) with respect to
-- (+) a * (b + c) = (a * b) + (a *
-- c) and (b + c) * a = (b * a) + (c * a)
--
--
-- Note that it isn't customarily expected that a type instance of
-- both Num and Ord implement an ordered ring. Indeed, in
-- base only Integer and Rational do.
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 abs and signum should
-- satisfy the law:
--
--
-- abs x * signum x == x
--
--
-- For real numbers, the signum is either -1 (negative),
-- 0 (zero) or 1 (positive).
signum :: Num a => a -> a
-- | Conversion from an Integer. An integer literal represents the
-- application of the function fromInteger to the appropriate
-- value of type Integer, so such literals have type
-- (Num a) => a.
fromInteger :: Num a => Integer -> a
infixl 6 -
infixl 6 +
infixl 7 *
-- | The Ord class is used for totally ordered datatypes.
--
-- Instances of Ord can be derived for any user-defined datatype
-- whose constituent types are in Ord. The declared order of the
-- constructors in the data declaration determines the ordering in
-- derived Ord instances. The Ordering datatype allows a
-- single comparison to determine the precise ordering of two objects.
--
-- The Haskell Report defines no laws for Ord. However,
-- <= is customarily expected to implement a non-strict partial
-- order and have the following properties:
--
--
-- - Transitivity if x <= y && y <=
-- z = True, then x <= z = True
-- - Reflexivity x <= x = True
-- - Antisymmetry if x <= y && y <=
-- x = True, then x == y = True
--
--
-- Note that the following operator interactions are expected to hold:
--
--
-- - x >= y = y <= x
-- - x < y = x <= y && x /= y
-- - x > y = y < x
-- - x < y = compare x y == LT
-- - x > y = compare x y == GT
-- - x == y = compare x y == EQ
-- - min x y == if x <= y then x else y = True
-- - max x y == if x >= y then x else y = True
--
--
-- Note that (7.) and (8.) do not require min and
-- max to return either of their arguments. The result is merely
-- required to equal one of the arguments in terms of (==).
--
-- Minimal complete definition: either compare or <=.
-- Using compare 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
infix 4 <
infix 4 <=
infix 4 >
infix 4 >=
-- | Parsing of Strings, producing values.
--
-- Derived instances of Read make the following assumptions, which
-- derived instances of Show obey:
--
--
-- - If the constructor is defined to be an infix operator, then the
-- derived Read instance will parse only infix applications of the
-- constructor (not the prefix form).
-- - Associativity is not used to reduce the occurrence of parentheses,
-- although precedence may be.
-- - If the constructor is defined using record syntax, the derived
-- Read will parse only the record-syntax form, and furthermore,
-- the fields must be given in the same order as the original
-- declaration.
-- - The derived Read instance allows arbitrary Haskell
-- whitespace between tokens of the input string. Extra parentheses are
-- also allowed.
--
--
-- For example, given the declarations
--
--
-- infixr 5 :^:
-- data Tree a = Leaf a | Tree a :^: Tree a
--
--
-- the derived instance of Read in Haskell 2010 is equivalent to
--
--
-- instance (Read a) => Read (Tree a) where
--
-- readsPrec d r = readParen (d > app_prec)
-- (\r -> [(Leaf m,t) |
-- ("Leaf",s) <- lex r,
-- (m,t) <- readsPrec (app_prec+1) s]) r
--
-- ++ readParen (d > up_prec)
-- (\r -> [(u:^:v,w) |
-- (u,s) <- readsPrec (up_prec+1) r,
-- (":^:",t) <- lex s,
-- (v,w) <- readsPrec (up_prec+1) t]) r
--
-- where app_prec = 10
-- up_prec = 5
--
--
-- Note that right-associativity of :^: is unused.
--
-- The derived instance in GHC is equivalent to
--
--
-- instance (Read a) => Read (Tree a) where
--
-- readPrec = parens $ (prec app_prec $ do
-- Ident "Leaf" <- lexP
-- m <- step readPrec
-- return (Leaf m))
--
-- +++ (prec up_prec $ do
-- u <- step readPrec
-- Symbol ":^:" <- lexP
-- v <- step readPrec
-- return (u :^: v))
--
-- where app_prec = 10
-- up_prec = 5
--
-- readListPrec = readListPrecDefault
--
--
-- Why do both readsPrec and readPrec exist, and why does
-- GHC opt to implement readPrec in derived Read instances
-- instead of readsPrec? The reason is that readsPrec is
-- based on the ReadS type, and although ReadS is mentioned
-- in the Haskell 2010 Report, it is not a very efficient parser data
-- structure.
--
-- readPrec, on the other hand, is based on a much more efficient
-- ReadPrec datatype (a.k.a "new-style parsers"), but its
-- definition relies on the use of the RankNTypes language
-- extension. Therefore, readPrec (and its cousin,
-- readListPrec) are marked as GHC-only. Nevertheless, it is
-- recommended to use readPrec instead of readsPrec
-- whenever possible for the efficiency improvements it brings.
--
-- As mentioned above, derived Read instances in GHC will
-- implement readPrec instead of readsPrec. The default
-- implementations of readsPrec (and its cousin, readList)
-- will simply use readPrec under the hood. If you are writing a
-- Read instance by hand, it is recommended to write it like so:
--
--
-- instance Read T where
-- readPrec = ...
-- readListPrec = readListPrecDefault
--
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 Read and Show satisfy the
-- following:
--
--
--
-- That is, readsPrec parses the string produced by
-- showsPrec, and delivers the value that showsPrec started
-- with.
readsPrec :: Read a => Int -> ReadS a
-- | The method readList is provided to allow the programmer to give
-- a specialised way of parsing lists of values. For example, this is
-- used by the predefined Read instance of the Char type,
-- where values of type String 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
-- 2)
floatRadix :: RealFloat a => a -> Integer
-- | a constant function, returning the number of digits of
-- floatRadix 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 decodeFloat applied to a real floating-point
-- number returns the significand expressed as an Integer and an
-- appropriately scaled exponent (an Int). If
-- decodeFloat x yields (m,n), then x
-- is equal in value to m*b^^n, where b is the
-- floating-point radix, and furthermore, either m and
-- n are both zero or else b^(d-1) <= abs m <
-- b^d, where d is the value of floatDigits
-- x. In particular, decodeFloat 0 = (0,0). If the
-- type contains a negative zero, also decodeFloat (-0.0) =
-- (0,0). The result of decodeFloat x is
-- unspecified if either of isNaN x or
-- isInfinite x is True.
decodeFloat :: RealFloat a => a -> (Integer, Int)
-- | encodeFloat performs the inverse of decodeFloat in the
-- sense that for finite x with the exception of -0.0,
-- uncurry encodeFloat (decodeFloat x) = x.
-- encodeFloat m n is one of the two closest
-- representable floating-point numbers to m*b^^n (or
-- ±Infinity if overflow occurs); usually the closer, but if
-- m contains too many bits, the result may be rounded in the
-- wrong direction.
encodeFloat :: RealFloat a => Integer -> Int -> a
-- | exponent corresponds to the second component of
-- decodeFloat. exponent 0 = 0 and for finite
-- nonzero x, exponent x = snd (decodeFloat x)
-- + floatDigits x. If x is a finite floating-point
-- number, it is equal in value to significand x * b ^^
-- exponent x, where b is the floating-point radix.
-- The behaviour is unspecified on infinite or NaN values.
exponent :: RealFloat a => a -> Int
-- | The first component of decodeFloat, scaled to lie in the open
-- interval (-1,1), either 0.0 or of absolute
-- value >= 1/b, where b is the floating-point
-- radix. The behaviour is unspecified on infinite or NaN
-- values.
significand :: RealFloat a => a -> a
-- | multiplies a floating-point number by an integer power of the radix
scaleFloat :: RealFloat a => Int -> a -> a
-- | True if the argument is an IEEE "not-a-number" (NaN) value
isNaN :: RealFloat a => a -> Bool
-- | True if the argument is an IEEE infinity or negative infinity
isInfinite :: RealFloat a => a -> Bool
-- | True if the argument is too small to be represented in
-- normalized format
isDenormalized :: RealFloat a => a -> Bool
-- | True if the argument is an IEEE negative zero
isNegativeZero :: RealFloat a => a -> Bool
-- | True 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 x and y, atan2 y x
-- computes the angle (from the positive x-axis) of the vector from the
-- origin to the point (x,y). atan2 y x returns
-- a value in the range [-pi, pi]. It follows the
-- Common Lisp semantics for the origin when signed zeroes are supported.
-- atan2 y 1, with y in a type that is
-- RealFloat, should return the same value as atan
-- y. A default definition of atan2 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 properFraction takes a real fractional number
-- x and returns a pair (n,f) such that x =
-- n+f, and:
--
--
-- - n is an integral number with the same sign as x;
-- and
-- - f is a fraction with the same type and sign as
-- x, and with absolute value less than 1.
--
--
-- The default definitions of the ceiling, floor,
-- truncate and round functions are in terms of
-- properFraction.
properFraction :: (RealFrac a, Integral b) => a -> (b, a)
-- | truncate x returns the integer nearest x
-- between zero and x
truncate :: (RealFrac a, Integral b) => a -> b
-- | round x returns the nearest integer to x; the
-- even integer if x is equidistant between two integers
round :: (RealFrac a, Integral b) => a -> b
-- | ceiling x returns the least integer not less than
-- x
ceiling :: (RealFrac a, Integral b) => a -> b
-- | floor x returns the greatest integer not greater than
-- x
floor :: (RealFrac a, Integral b) => a -> b
-- | Conversion of values to readable Strings.
--
-- Derived instances of Show have the following properties, which
-- are compatible with derived instances of Read:
--
--
-- - The result of show 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.
-- - If the constructor is defined to be an infix operator, then
-- showsPrec will produce infix applications of the
-- constructor.
-- - the representation will be enclosed in parentheses if the
-- precedence of the top-level constructor in x is less than
-- d (associativity is ignored). Thus, if d is
-- 0 then the result is never surrounded in parentheses; if
-- d is 11 it is always surrounded in parentheses,
-- unless it is an atomic expression.
-- - If the constructor is defined using record syntax, then
-- show will produce the record-syntax form, with the fields given
-- in the same order as the original declaration.
--
--
-- For example, given the declarations
--
--
-- infixr 5 :^:
-- data Tree a = Leaf a | Tree a :^: Tree a
--
--
-- the derived instance of Show is equivalent to
--
--
-- instance (Show a) => Show (Tree a) where
--
-- showsPrec d (Leaf m) = showParen (d > app_prec) $
-- showString "Leaf " . showsPrec (app_prec+1) m
-- where app_prec = 10
--
-- showsPrec d (u :^: v) = showParen (d > up_prec) $
-- showsPrec (up_prec+1) u .
-- showString " :^: " .
-- showsPrec (up_prec+1) v
-- where up_prec = 5
--
--
-- Note that right-associativity of :^: is ignored. For example,
--
--
-- - show (Leaf 1 :^: Leaf 2 :^: Leaf 3) produces the
-- string "Leaf 1 :^: (Leaf 2 :^: Leaf 3)".
--
class Show a
-- | Convert a value to a readable String.
--
-- showsPrec should satisfy the law
--
--
-- showsPrec d x r ++ s == showsPrec d x (r ++ s)
--
--
-- Derived instances of Read and Show satisfy the
-- following:
--
--
--
-- That is, readsPrec parses the string produced by
-- showsPrec, and delivers the value that showsPrec started
-- with.
showsPrec :: Show a => Int -> a -> ShowS
-- | A specialised variant of showsPrec, using precedence context
-- zero, and returning an ordinary String.
show :: Show a => a -> String
-- | The method showList is provided to allow the programmer to give
-- a specialised way of showing lists of values. For example, this is
-- used by the predefined Show instance of the Char type,
-- where values of type String should be shown in double quotes,
-- rather than between square brackets.
showList :: Show a => [a] -> ShowS
-- | When a value is bound in do-notation, the pattern on the left
-- hand side of <- might not match. In this case, this class
-- provides a function to recover.
--
-- A Monad without a MonadFail instance may only be used in
-- conjunction with pattern that always match, such as newtypes, tuples,
-- data types with only a single data constructor, and irrefutable
-- patterns (~pat).
--
-- Instances of MonadFail should satisfy the following law:
-- fail s should be a left zero for >>=,
--
--
-- fail s >>= f = fail s
--
--
-- If your Monad is also MonadPlus, a popular definition is
--
--
-- fail _ = mzero
--
class Monad m => MonadFail (m :: Type -> Type)
-- | A functor with application, providing operations to
--
--
-- - embed pure expressions (pure), and
-- - sequence computations and combine their results (<*>
-- and liftA2).
--
--
-- A minimal complete definition must include implementations of
-- pure and of either <*> or liftA2. If it
-- defines both, then they must behave the same as their default
-- definitions:
--
--
-- (<*>) = liftA2 id
--
--
--
-- liftA2 f x y = f <$> x <*> y
--
--
-- Further, any definition must satisfy the following:
--
--
--
-- The other methods have the following default definitions, which may be
-- overridden with equivalent specialized implementations:
--
--
--
-- As a consequence of these laws, the Functor instance for
-- f will satisfy
--
--
--
-- It may be useful to note that supposing
--
--
-- forall x y. p (q x y) = f x . g y
--
--
-- it follows from the above that
--
--
-- liftA2 p (liftA2 q u v) = liftA2 f u . liftA2 g v
--
--
-- If f is also a Monad, it should satisfy
--
--
--
-- (which implies that pure and <*> satisfy the
-- applicative functor laws).
class Functor f => Applicative (f :: Type -> Type)
-- | Lift a value.
pure :: Applicative f => a -> f a
-- | Sequential application.
--
-- A few functors support an implementation of <*> that is
-- more efficient than the default one.
--
-- Using ApplicativeDo: 'fs <*> as' can be
-- understood as the do expression
--
--
-- do f <- fs
-- a <- as
-- pure (f a)
--
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
-- | Sequence actions, discarding the value of the first argument.
--
-- 'as *> bs' can be understood as the do
-- expression
--
--
-- do as
-- bs
--
--
-- This is a tad complicated for our ApplicativeDo extension
-- which will give it a Monad constraint. For an
-- Applicative constraint we write it of the form
--
--
-- do _ <- as
-- b <- bs
-- pure b
--
(*>) :: Applicative f => f a -> f b -> f b
-- | Sequence actions, discarding the value of the second argument.
--
-- Using ApplicativeDo: 'as <* bs' can be
-- understood as the do expression
--
--
-- do a <- as
-- bs
-- pure a
--
(<*) :: Applicative f => f a -> f b -> f a
infixl 4 <*
infixl 4 *>
infixl 4 <*>
-- | Data structures that can be folded.
--
-- For example, given a data type
--
--
-- data Tree a = Empty | Leaf a | Node (Tree a) a (Tree a)
--
--
-- a suitable instance would be
--
--
-- 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
--
--
-- This is suitable even for abstract types, as the monoid is assumed to
-- satisfy the monoid laws. Alternatively, one could define
-- foldr:
--
--
-- 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
--
--
-- Foldable instances are expected to satisfy the following
-- laws:
--
--
-- foldr f z t = appEndo (foldMap (Endo . f) t ) z
--
--
--
-- foldl f z t = appEndo (getDual (foldMap (Dual . Endo . flip f) t)) z
--
--
--
-- fold = foldMap id
--
--
--
-- length = getSum . foldMap (Sum . const 1)
--
--
-- sum, product, maximum, and minimum
-- should all be essentially equivalent to foldMap forms, such
-- as
--
--
-- sum = getSum . foldMap Sum
--
--
-- but may be less defined.
--
-- If the type is also a Functor instance, it should satisfy
--
--
-- foldMap f = fold . fmap f
--
--
-- which implies that
--
--
-- foldMap f . fmap g = foldMap (f . g)
--
class Foldable (t :: Type -> Type)
-- | 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, foldr, 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:
--
--
-- foldr f z [x1, x2, ..., xn] == x1 `f` (x2 `f` ... (xn `f` z)...)
--
--
-- Note that, since the head of the resulting expression is produced by
-- an application of the operator to the first element of the list,
-- foldr can produce a terminating expression from an infinite
-- list.
--
-- For a general Foldable structure this should be semantically
-- identical to,
--
--
-- foldr f z = foldr f z . toList
--
foldr :: Foldable t => (a -> b -> b) -> b -> t a -> b
-- | Left-associative fold of a structure.
--
-- In the case of lists, foldl, 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:
--
--
-- foldl f z [x1, x2, ..., xn] == (...((z `f` x1) `f` x2) `f`...) `f` xn
--
--
-- Note that to produce the outermost application of the operator the
-- entire input list must be traversed. This means that foldl'
-- will diverge if given an infinite list.
--
-- Also note that if you want an efficient left-fold, you probably want
-- to use foldl' instead of foldl. The reason for this is
-- that latter does not force the "inner" results (e.g. z `f` x1
-- in the above example) before applying them to the operator (e.g. to
-- (`f` x2)). This results in a thunk chain <math>
-- elements long, which then must be evaluated from the outside-in.
--
-- For a general Foldable structure this should be semantically
-- identical to,
--
--
-- foldl f z = foldl f z . toList
--
foldl :: Foldable t => (b -> a -> b) -> b -> t a -> b
-- | A variant of foldr that has no base case, and thus may only be
-- applied to non-empty structures.
--
--
-- foldr1 f = foldr1 f . toList
--
foldr1 :: Foldable t => (a -> a -> a) -> t a -> a
-- | A variant of foldl that has no base case, and thus may only be
-- applied to non-empty structures.
--
--
-- foldl1 f = foldl1 f . toList
--
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 Int. 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 sum function computes the sum of the numbers of a
-- structure.
sum :: (Foldable t, Num a) => t a -> a
-- | The product function computes the product of the numbers of a
-- structure.
product :: (Foldable t, Num a) => t a -> a
infix 4 `elem`
-- | Functors representing data structures that can be traversed from left
-- to right.
--
-- A definition of traverse must satisfy the following laws:
--
--
--
-- A definition of sequenceA must satisfy the following laws:
--
--
--
-- where an applicative transformation is a function
--
--
-- t :: (Applicative f, Applicative g) => f a -> g a
--
--
-- preserving the Applicative operations, i.e.
--
--
-- t (pure x) = pure x
-- t (f <*> x) = t f <*> t x
--
--
-- and the identity functor Identity and composition functors
-- Compose are from Data.Functor.Identity and
-- Data.Functor.Compose.
--
-- A result of the naturality law is a purity law for traverse
--
--
-- traverse pure = pure
--
--
-- (The naturality law is implied by parametricity and thus so is the
-- purity law [1, p15].)
--
-- Instances are similar to Functor, e.g. given a data type
--
--
-- data Tree a = Empty | Leaf a | Node (Tree a) a (Tree a)
--
--
-- a suitable instance would be
--
--
-- instance Traversable Tree where
-- traverse f Empty = pure Empty
-- traverse f (Leaf x) = Leaf <$> f x
-- traverse f (Node l k r) = Node <$> traverse f l <*> f k <*> traverse f r
--
--
-- This is suitable even for abstract types, as the laws for
-- <*> imply a form of associativity.
--
-- The superclass instances should satisfy the following:
--
--
-- - In the Functor instance, fmap should be equivalent
-- to traversal with the identity applicative functor
-- (fmapDefault).
-- - In the Foldable instance, foldMap should be
-- equivalent to traversal with a constant applicative functor
-- (foldMapDefault).
--
--
-- References: [1] The Essence of the Iterator Pattern, Jeremy Gibbons
-- and Bruno C. d. S. Oliveira
class (Functor t, Foldable t) => Traversable (t :: Type -> Type)
-- | 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 traverse_.
traverse :: (Traversable t, Applicative f) => (a -> f b) -> t a -> f (t b)
-- | Evaluate each action in the structure from left to right, and collect
-- the results. For a version that ignores the results see
-- sequenceA_.
sequenceA :: (Traversable t, Applicative f) => t (f a) -> f (t a)
-- | Map each element of a structure to a monadic action, evaluate these
-- actions from left to right, and collect the results. For a version
-- that ignores the results see mapM_.
mapM :: (Traversable t, Monad m) => (a -> m b) -> t a -> m (t b)
-- | Evaluate each monadic action in the structure from left to right, and
-- collect the results. For a version that ignores the results see
-- sequence_.
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 following:
--
--
-- - Associativity x <> (y <> z) =
-- (x <> y) <> z
--
class Semigroup a
-- | The class of monoids (types with an associative binary operation that
-- has an identity). Instances should satisfy the following:
--
--
--
-- 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
-- newtypes and make those instances of Monoid, e.g.
-- Sum and Product.
--
-- NOTE: Semigroup is a superclass of Monoid since
-- base-4.11.0.0.
class Semigroup a => Monoid a
-- | Identity of mappend
--
--
-- >>> "Hello world" <> mempty
-- "Hello world"
--
mempty :: Monoid a => a
-- | An associative operation
--
-- NOTE: This method is redundant and has the default
-- implementation mappend = (<>) since
-- base-4.11.0.0. Should it be implemented manually, since
-- mappend is a synonym for (<>), it is expected that
-- the two functions are defined the same way. In a future GHC release
-- mappend will be removed from Monoid.
mappend :: Monoid a => a -> a -> a
-- | Fold a list using the monoid.
--
-- For most types, the default definition for mconcat will be
-- used, but the function is included in the class definition so that an
-- optimized version can be provided for specific types.
--
--
-- >>> mconcat ["Hello", " ", "Haskell", "!"]
-- "Hello Haskell!"
--
mconcat :: Monoid a => [a] -> a
data Bool
False :: Bool
True :: Bool
-- | The character type Char is an enumeration whose values
-- represent Unicode (or equivalently ISO/IEC 10646) code points (i.e.
-- characters, see http://www.unicode.org/ 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
-- Char.
--
-- To convert a Char to or from the corresponding Int value
-- defined by Unicode, use toEnum and fromEnum from the
-- Enum class respectively (or equivalently ord and
-- chr).
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 [-2^29 ..
-- 2^29-1]. The exact range for a given implementation can be
-- determined by using minBound and maxBound from the
-- Bounded class.
data Int
-- | Arbitrary precision integers. In contrast with fixed-size integral
-- types such as Int, the Integer type represents the
-- entire infinite range of integers.
--
-- For more information about this type's representation, see the
-- comments in its implementation.
data Integer
-- | The Maybe type encapsulates an optional value. A value of type
-- Maybe a either contains a value of type a
-- (represented as Just a), or it is empty (represented
-- as Nothing). Using Maybe is a good way to deal with
-- errors or exceptional cases without resorting to drastic measures such
-- as error.
--
-- The Maybe type is also a monad. It is a simple kind of error
-- monad, where all errors are represented by Nothing. A richer
-- error monad can be built using the Either 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
-- Integer values. A rational number may be constructed using the
-- % operator.
type Rational = Ratio Integer
-- | A value of type IO a is a computation which, when
-- performed, does some I/O before returning a value of type a.
--
-- There is really only one way to "perform" an I/O action: bind it to
-- Main.main 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 IO monad and
-- called at some point, directly or indirectly, from Main.main.
--
-- IO is a monad, so IO actions can be combined using
-- either the do-notation or the >> and >>=
-- operations from the Monad class.
data IO a
-- | A Word is an unsigned integral type, with the same size as
-- Int.
data Word
-- | The Either type represents values with two possibilities: a
-- value of type Either a b is either Left
-- a or Right b.
--
-- The Either type is sometimes used to represent a value which is
-- either correct or an error; by convention, the Left constructor
-- is used to hold an error value and the Right constructor is
-- used to hold a correct value (mnemonic: "right" also means "correct").
--
-- Examples
--
-- The type Either String Int is the type
-- of values which can be either a String or an Int. The
-- Left constructor can be used only on Strings, and the
-- Right constructor can be used only on Ints:
--
--
-- >>> let s = Left "foo" :: Either String Int
--
-- >>> s
-- Left "foo"
--
-- >>> let n = Right 3 :: Either String Int
--
-- >>> n
-- Right 3
--
-- >>> :type s
-- s :: Either String Int
--
-- >>> :type n
-- n :: Either String Int
--
--
-- The fmap from our Functor instance will ignore
-- Left values, but will apply the supplied function to values
-- contained in a Right:
--
--
-- >>> let s = Left "foo" :: Either String Int
--
-- >>> let n = Right 3 :: Either String Int
--
-- >>> fmap (*2) s
-- Left "foo"
--
-- >>> fmap (*2) n
-- Right 6
--
--
-- The Monad instance for Either 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 Int from a Char, or fail.
--
--
-- >>> import Data.Char ( digitToInt, isDigit )
--
-- >>> :{
-- let parseEither :: Char -> Either String Int
-- parseEither c
-- | isDigit c = Right (digitToInt c)
-- | otherwise = Left "parse error"
--
-- >>> :}
--
--
-- The following should work, since both '1' and '2'
-- can be parsed as Ints.
--
--
-- >>> :{
-- let parseMultiple :: Either String Int
-- parseMultiple = do
-- x <- parseEither '1'
-- y <- parseEither '2'
-- return (x + y)
--
-- >>> :}
--
--
--
-- >>> parseMultiple
-- Right 3
--
--
-- But the following should fail overall, since the first operation where
-- we attempt to parse 'm' as an Int will fail:
--
--
-- >>> :{
-- let parseMultiple :: Either String Int
-- parseMultiple = do
-- x <- parseEither 'm'
-- y <- parseEither '2'
-- return (x + y)
--
-- >>> :}
--
--
--
-- >>> parseMultiple
-- Left "parse error"
--
data Either a b
Left :: a -> Either a b
Right :: b -> Either a b
-- | A String is a list of characters. String constants in Haskell
-- are values of type String.
--
-- See Data.List for operations on lists.
type String = [Char]
-- | An infix synonym for fmap.
--
-- The name of this operator is an allusion to $. Note the
-- similarities between their types:
--
--
-- ($) :: (a -> b) -> a -> b
-- (<$>) :: Functor f => (a -> b) -> f a -> f b
--
--
-- Whereas $ is function application, <$> is function
-- application lifted over a Functor.
--
-- Examples
--
-- Convert from a Maybe Int to a Maybe
-- String using show:
--
--
-- >>> show <$> Nothing
-- Nothing
--
-- >>> show <$> Just 3
-- Just "3"
--
--
-- Convert from an Either Int Int to an
-- Either Int String using show:
--
--
-- >>> show <$> Left 17
-- Left 17
--
-- >>> show <$> Right 17
-- Right "17"
--
--
-- Double each element of a list:
--
--
-- >>> (*2) <$> [1,2,3]
-- [2,4,6]
--
--
-- Apply even to the second element of a pair:
--
--
-- >>> even <$> (2,2)
-- (2,True)
--
(<$>) :: Functor f => (a -> b) -> f a -> f b
infixl 4 <$>
-- | const x is a unary function which evaluates to x for
-- all inputs.
--
--
-- >>> const 42 "hello"
-- 42
--
--
--
-- >>> map (const 42) [0..3]
-- [42,42,42,42]
--
const :: a -> b -> a
-- | Function composition.
(.) :: (b -> c) -> (a -> b) -> a -> c
infixr 9 .
-- | Identity function.
--
--
-- id x = x
--
id :: a -> a
-- | The shows functions return a function that prepends the
-- output String to an existing String. This allows
-- constant-time concatenation of results using function composition.
type ShowS = String -> String
-- | 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 mapM.
--
-- As of base 4.8.0.0, mapM_ is just traverse_, specialized
-- to Monad.
mapM_ :: (Foldable t, Monad m) => (a -> m b) -> t a -> m ()
-- | The read function reads input from a string, which must be
-- completely consumed by the input process. read fails with an
-- error if the parse is unsuccessful, and it is therefore
-- discouraged from being used in real applications. Use readMaybe
-- or readEither for safe alternatives.
--
--
-- >>> read "123" :: Int
-- 123
--
--
--
-- >>> read "hello" :: Int
-- *** Exception: Prelude.read: no parse
--
read :: Read a => String -> a
-- | The readIO function is similar to read except that it
-- signals parse failure to the IO monad instead of terminating
-- the program.
readIO :: Read a => String -> IO a
-- | The readLn function combines getLine and readIO.
readLn :: Read a => IO a
-- | The computation appendFile file str function appends
-- the string str, to the file file.
--
-- Note that writeFile and appendFile write a literal
-- string to a file. To write a value of any printable type, as with
-- print, use the show function to convert the value to a
-- string first.
--
--
-- main = appendFile "squares" (show [(x,x*x) | x <- [0,0.1..2]])
--
appendFile :: FilePath -> String -> IO ()
-- | The computation writeFile file str function writes the
-- string str, to the file file.
writeFile :: FilePath -> String -> IO ()
-- | The readFile function reads a file and returns the contents of
-- the file as a string. The file is read lazily, on demand, as with
-- getContents.
readFile :: FilePath -> IO String
-- | The interact function takes a function of type
-- String->String 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 getContents operation returns all user input as a single
-- string, which is read lazily as it is needed (same as
-- hGetContents stdin).
getContents :: IO String
-- | Read a line from the standard input device (same as hGetLine
-- stdin).
getLine :: IO String
-- | Read a character from the standard input device (same as
-- hGetChar stdin).
getChar :: IO Char
-- | The same as putStr, but adds a newline character.
putStrLn :: String -> IO ()
-- | Write a string to the standard output device (same as hPutStr
-- stdout).
putStr :: String -> IO ()
-- | Write a character to the standard output device (same as
-- hPutChar stdout).
putChar :: Char -> IO ()
-- | Raise an IOError in the IO monad.
ioError :: IOError -> IO a
-- | File and directory names are values of type String, 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 IOError value with a string describing the error.
-- The fail method of the IO instance of the Monad
-- class raises a userError, thus:
--
--
-- instance Monad IO where
-- ...
-- fail s = ioError (userError s)
--
userError :: String -> IOError
-- | The Haskell 2010 type for exceptions in the IO monad. Any I/O
-- operation may raise an IOError instead of returning a result.
-- For a more general type of exception, including also those that arise
-- in pure code, see Exception.
--
-- In Haskell 2010, this is an opaque type.
type IOError = IOException
-- | notElem is the negation of elem.
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
-- | or returns the disjunction of a container of Bools. For the
-- result to be False, the container must be finite; True,
-- however, results from a True value finitely far from the left
-- end.
or :: Foldable t => t Bool -> Bool
-- | and returns the conjunction of a container of Bools. For the
-- result to be True, the container must be finite; False,
-- however, results from a False 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
-- sequence.
--
-- As of base 4.8.0.0, sequence_ is just sequenceA_,
-- specialized to Monad.
sequence_ :: (Foldable t, Monad m) => t (m a) -> m ()
-- | unwords is an inverse operation to words. It joins words
-- with separating spaces.
--
--
-- >>> unwords ["Lorem", "ipsum", "dolor"]
-- "Lorem ipsum dolor"
--
unwords :: [String] -> String
-- | words breaks a string up into a list of words, which were
-- delimited by white space.
--
--
-- >>> words "Lorem ipsum\ndolor"
-- ["Lorem","ipsum","dolor"]
--
words :: String -> [String]
-- | unlines is an inverse operation to lines. It joins
-- lines, after appending a terminating newline to each.
--
--
-- >>> unlines ["Hello", "World", "!"]
-- "Hello\nWorld\n!\n"
--
unlines :: [String] -> String
-- | lines 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,
--
--
-- >>> lines ""
-- []
--
--
--
-- >>> lines "\n"
-- [""]
--
--
--
-- >>> lines "one"
-- ["one"]
--
--
--
-- >>> lines "one\n"
-- ["one"]
--
--
--
-- >>> lines "one\n\n"
-- ["one",""]
--
--
--
-- >>> lines "one\ntwo"
-- ["one","two"]
--
--
--
-- >>> lines "one\ntwo\n"
-- ["one","two"]
--
--
-- Thus lines s contains at least as many elements as
-- newlines in s.
lines :: String -> [String]
-- | equivalent to readsPrec with a precedence of 0.
reads :: Read a => ReadS a
-- | Case analysis for the Either type. If the value is
-- Left a, apply the first function to a; if it
-- is Right b, apply the second function to b.
--
-- Examples
--
-- We create two values of type Either String
-- Int, one using the Left constructor and another
-- using the Right constructor. Then we apply "either" the
-- length function (if we have a String) or the "times-two"
-- function (if we have an Int):
--
--
-- >>> let s = Left "foo" :: Either String Int
--
-- >>> let n = Right 3 :: Either String Int
--
-- >>> either length (*2) s
-- 3
--
-- >>> either length (*2) n
-- 6
--
either :: (a -> c) -> (b -> c) -> Either a b -> c
-- | The lex 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,
-- lex returns a single successful `lexeme' consisting of the
-- empty string. (Thus lex "" = [("","")].) If there is
-- no legal lexeme at the beginning of the input string, lex fails
-- (i.e. returns []).
--
-- This lexer is not completely faithful to the Haskell lexical syntax in
-- the following respects:
--
--
-- - Qualified names are not handled properly
-- - Octal and hexadecimal numerics are not recognized as a single
-- token
-- - Comments are not treated properly
--
lex :: ReadS String
-- | readParen True p parses what p parses,
-- but surrounded with parentheses.
--
-- readParen False p parses what p
-- parses, but optionally surrounded with parentheses.
readParen :: Bool -> ReadS a -> ReadS a
-- | A parser for a type a, represented as a function that takes a
-- String and returns a list of possible parses as
-- (a,String) pairs.
--
-- Note that this kind of backtracking parser is very inefficient;
-- reading a large structure may be quite slow (cf ReadP).
type ReadS a = String -> [(a, String)]
-- | lcm x y is the smallest positive integer that both
-- x and y divide.
lcm :: Integral a => a -> a -> a
-- | gcd x y is the non-negative factor of both x
-- and y of which every common factor of x and
-- y is also a factor; for example gcd 4 2 = 2,
-- gcd (-4) 6 = 2, gcd 0 4 = 4.
-- gcd 0 0 = 0. (That is, the common divisor
-- that is "greatest" in the divisibility preordering.)
--
-- Note: Since for signed fixed-width integer types, abs
-- minBound < 0, the result may be negative if one of the
-- arguments is minBound (and necessarily is if the other
-- is 0 or minBound) 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 Bool parameter is True.
showParen :: Bool -> ShowS -> ShowS
-- | utility function converting a String to a show function that
-- simply prepends the string unchanged.
showString :: String -> ShowS
-- | utility function converting a Char to a show function that
-- simply prepends the character unchanged.
showChar :: Char -> ShowS
-- | equivalent to showsPrec with a precedence of 0.
shows :: Show a => a -> ShowS
-- | The unzip3 function takes a list of triples and returns three
-- lists, analogous to unzip.
unzip3 :: [(a, b, c)] -> ([a], [b], [c])
-- | unzip transforms a list of pairs into a list of first
-- components and a list of second components.
unzip :: [(a, b)] -> ([a], [b])
-- | The zipWith3 function takes a function which combines three
-- elements, as well as three lists and returns a list of their
-- point-wise combination, analogous to zipWith. It is capable of
-- list fusion, but it is restricted to its first list argument and its
-- resulting list.
zipWith3 :: (a -> b -> c -> d) -> [a] -> [b] -> [c] -> [d]
-- | <math>. zipWith generalises zip by zipping with
-- the function given as the first argument, instead of a tupling
-- function. For example, zipWith (+) is applied to two
-- lists to produce the list of corresponding sums:
--
--
-- >>> zipWith (+) [1, 2, 3] [4, 5, 6]
-- [5,7,9]
--
--
-- zipWith is right-lazy:
--
--
-- zipWith f [] _|_ = []
--
--
-- zipWith is capable of list fusion, but it is restricted to its
-- first list argument and its resulting list.
zipWith :: (a -> b -> c) -> [a] -> [b] -> [c]
-- | zip3 takes three lists and returns a list of triples, analogous
-- to zip. It is capable of list fusion, but it is restricted to
-- its first list argument and its resulting list.
zip3 :: [a] -> [b] -> [c] -> [(a, b, c)]
-- | List index (subscript) operator, starting from 0. It is an instance of
-- the more general genericIndex, which takes an index of any
-- integral type.
(!!) :: [a] -> Int -> a
infixl 9 !!
-- | <math>. lookup key assocs looks up a key in an
-- association list.
--
--
-- >>> lookup 2 [(1, "first"), (2, "second"), (3, "third")]
-- Just "second"
--
lookup :: Eq a => a -> [(a, b)] -> Maybe b
-- | reverse xs returns the elements of xs in
-- reverse order. xs must be finite.
reverse :: [a] -> [a]
-- | break, applied to a predicate p and a list
-- xs, returns a tuple where first element is longest prefix
-- (possibly empty) of xs of elements that do not satisfy
-- p and second element is the remainder of the list:
--
--
-- break (> 3) [1,2,3,4,1,2,3,4] == ([1,2,3],[4,1,2,3,4])
-- break (< 9) [1,2,3] == ([],[1,2,3])
-- break (> 9) [1,2,3] == ([1,2,3],[])
--
--
-- break p is equivalent to span (not .
-- p).
break :: (a -> Bool) -> [a] -> ([a], [a])
-- | span, applied to a predicate p and a list xs,
-- returns a tuple where first element is longest prefix (possibly empty)
-- of xs of elements that satisfy p and second element
-- is the remainder of the list:
--
--
-- span (< 3) [1,2,3,4,1,2,3,4] == ([1,2],[3,4,1,2,3,4])
-- span (< 9) [1,2,3] == ([1,2,3],[])
-- span (< 0) [1,2,3] == ([],[1,2,3])
--
--
-- span p xs is equivalent to (takeWhile p xs,
-- dropWhile p xs)
span :: (a -> Bool) -> [a] -> ([a], [a])
-- | splitAt n xs returns a tuple where first element is
-- xs prefix of length n and second element is the
-- remainder of the list:
--
--
-- 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])
--
--
-- It is equivalent to (take n xs, drop n xs) when
-- n is not _|_ (splitAt _|_ xs = _|_).
-- splitAt is an instance of the more general
-- genericSplitAt, in which n may be of any integral
-- type.
splitAt :: Int -> [a] -> ([a], [a])
-- | drop n xs returns the suffix of xs after the
-- first n elements, or [] if n > length
-- xs:
--
--
-- 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]
--
--
-- It is an instance of the more general genericDrop, in which
-- n may be of any integral type.
drop :: Int -> [a] -> [a]
-- | take n, applied to a list xs, returns the
-- prefix of xs of length n, or xs itself if
-- n > length xs:
--
--
-- 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] == []
--
--
-- It is an instance of the more general genericTake, in which
-- n may be of any integral type.
take :: Int -> [a] -> [a]
-- | dropWhile p xs returns the suffix remaining after
-- takeWhile p xs:
--
--
-- dropWhile (< 3) [1,2,3,4,5,1,2,3] == [3,4,5,1,2,3]
-- dropWhile (< 9) [1,2,3] == []
-- dropWhile (< 0) [1,2,3] == [1,2,3]
--
dropWhile :: (a -> Bool) -> [a] -> [a]
-- | takeWhile, applied to a predicate p and a list
-- xs, returns the longest prefix (possibly empty) of
-- xs of elements that satisfy p:
--
--
-- takeWhile (< 3) [1,2,3,4,1,2,3,4] == [1,2]
-- takeWhile (< 9) [1,2,3] == [1,2,3]
-- takeWhile (< 0) [1,2,3] == []
--
takeWhile :: (a -> Bool) -> [a] -> [a]
-- | cycle 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]
-- | replicate n x is a list of length n with
-- x the value of every element. It is an instance of the more
-- general genericReplicate, in which n may be of any
-- integral type.
replicate :: Int -> a -> [a]
-- | repeat x is an infinite list, with x the
-- value of every element.
repeat :: a -> [a]
-- | iterate f x returns an infinite list of repeated
-- applications of f to x:
--
--
-- iterate f x == [x, f x, f (f x), ...]
--
--
-- Note that iterate 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]
-- | <math>. scanr1 is a variant of scanr that has no
-- starting value argument.
scanr1 :: (a -> a -> a) -> [a] -> [a]
-- | <math>. scanr is the right-to-left dual of scanl.
-- Note that
--
--
-- head (scanr f z xs) == foldr f z xs.
--
scanr :: (a -> b -> b) -> b -> [a] -> [b]
-- | <math>. scanl1 is a variant of scanl that has no
-- starting value argument:
--
--
-- scanl1 f [x1, x2, ...] == [x1, x1 `f` x2, ...]
--
scanl1 :: (a -> a -> a) -> [a] -> [a]
-- | <math>. scanl is similar to foldl, but returns a
-- list of successive reduced values from the left:
--
--
-- scanl f z [x1, x2, ...] == [z, z `f` x1, (z `f` x1) `f` x2, ...]
--
--
-- Note that
--
--
-- last (scanl f z xs) == foldl f z xs.
--
scanl :: (b -> a -> b) -> b -> [a] -> [b]
-- | <math>. Return all the elements of a list except the last one.
-- The list must be non-empty.
init :: [a] -> [a]
-- | <math>. Extract the last element of a list, which must be finite
-- and non-empty.
last :: [a] -> a
-- | <math>. Extract the elements after the head of a list, which
-- must be non-empty.
tail :: [a] -> [a]
-- | <math>. Extract the first element of a list, which must be
-- non-empty.
head :: [a] -> a
-- | The maybe function takes a default value, a function, and a
-- Maybe value. If the Maybe value is Nothing, the
-- function returns the default value. Otherwise, it applies the function
-- to the value inside the Just and returns the result.
--
-- Examples
--
-- Basic usage:
--
--
-- >>> maybe False odd (Just 3)
-- True
--
--
--
-- >>> maybe False odd Nothing
-- False
--
--
-- Read an integer from a string using readMaybe. If we succeed,
-- return twice the integer; that is, apply (*2) to it. If
-- instead we fail to parse an integer, return 0 by default:
--
--
-- >>> import Text.Read ( readMaybe )
--
-- >>> maybe 0 (*2) (readMaybe "5")
-- 10
--
-- >>> maybe 0 (*2) (readMaybe "")
-- 0
--
--
-- Apply show to a Maybe Int. If we have Just n,
-- we want to show the underlying Int n. But if we have
-- Nothing, we return the empty string instead of (for example)
-- "Nothing":
--
--
-- >>> maybe "" show (Just 5)
-- "5"
--
-- >>> maybe "" show Nothing
-- ""
--
maybe :: b -> (a -> b) -> Maybe a -> b
-- | uncurry converts a curried function to a function on pairs.
--
-- Examples
--
--
-- >>> uncurry (+) (1,2)
-- 3
--
--
--
-- >>> uncurry ($) (show, 1)
-- "1"
--
--
--
-- >>> map (uncurry max) [(1,2), (3,4), (6,8)]
-- [2,4,8]
--
uncurry :: (a -> b -> c) -> (a, b) -> c
-- | curry converts an uncurried function to a curried function.
--
-- Examples
--
--
-- >>> curry fst 1 2
-- 1
--
curry :: ((a, b) -> c) -> a -> b -> c
-- | the same as flip (-).
--
-- Because - is treated specially in the Haskell grammar,
-- (- e) is not a section, but an application of
-- prefix negation. However, (subtract
-- exp) is equivalent to the disallowed section.
subtract :: Num a => a -> a -> a
-- | asTypeOf is a type-restricted version of const. 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
-- | until p f yields the result of applying f
-- until p 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.
($!) :: forall (r :: RuntimeRep) a (b :: TYPE r). (a -> b) -> a -> b
infixr 0 $!
-- | flip f takes its (first) two arguments in the reverse
-- order of f.
--
--
-- >>> flip (++) "hello" "world"
-- "worldhello"
--
flip :: (a -> b -> c) -> b -> a -> c
-- | Same as >>=, but with the arguments interchanged.
(=<<) :: Monad m => (a -> m b) -> m a -> m b
infixr 1 =<<
-- | A special case of error. It is expected that compilers will
-- recognize this and insert error messages which are more appropriate to
-- the context in which undefined appears.
undefined :: forall (r :: RuntimeRep) (a :: TYPE r). HasCallStack => a
-- | A variant of error that does not produce a stack trace.
errorWithoutStackTrace :: forall (r :: RuntimeRep) (a :: TYPE r). [Char] -> a
-- | error stops execution and displays an error message.
error :: forall (r :: RuntimeRep) (a :: TYPE r). HasCallStack => [Char] -> a
-- | Boolean "and", lazy in the second argument
(&&) :: Bool -> Bool -> Bool
infixr 3 &&
-- | Boolean "or", lazy in the second argument
(||) :: Bool -> Bool -> Bool
infixr 2 ||
-- | Boolean "not"
not :: Bool -> Bool
-- | Conditional failure of Alternative computations. Defined by
--
--
-- guard True = pure ()
-- guard False = empty
--
--
-- Examples
--
-- Common uses of guard include conditionally signaling an error
-- in an error monad and conditionally rejecting the current choice in an
-- Alternative-based parser.
--
-- As an example of signaling an error in the error monad Maybe,
-- consider a safe division function safeDiv x y that returns
-- Nothing when the denominator y is zero and
-- Just (x `div` y) otherwise. For example:
--
--
-- >>> safeDiv 4 0
-- Nothing
-- >>> safeDiv 4 2
-- Just 2
--
--
-- A definition of safeDiv using guards, but not guard:
--
--
-- safeDiv :: Int -> Int -> Maybe Int
-- safeDiv x y | y /= 0 = Just (x `div` y)
-- | otherwise = Nothing
--
--
-- A definition of safeDiv using guard and Monad
-- do-notation:
--
--
-- safeDiv :: Int -> Int -> Maybe Int
-- safeDiv x y = do
-- guard (y /= 0)
-- return (x `div` y)
--
guard :: Alternative f => Bool -> f ()
-- | The join function is the conventional monad join operator. It
-- is used to remove one level of monadic structure, projecting its bound
-- argument into the outer level.
--
-- 'join bss' can be understood as the do
-- expression
--
--
-- do bs <- bss
-- bs
--
--
-- Examples
--
-- A common use of join is to run an IO computation
-- returned from an STM transaction, since STM transactions
-- can't perform IO directly. Recall that
--
--
-- atomically :: STM a -> IO a
--
--
-- is used to run STM transactions atomically. So, by specializing
-- the types of atomically and join to
--
--
-- atomically :: STM (IO b) -> IO (IO b)
-- join :: IO (IO b) -> IO b
--
--
-- we can compose them as
--
--
-- join . atomically :: STM (IO b) -> IO b
--
--
-- to run an STM transaction and the IO action it returns.
join :: Monad m => m (m a) -> m a
-- | The Monad class defines the basic operations over a
-- monad, a concept from a branch of mathematics known as
-- category theory. From the perspective of a Haskell programmer,
-- however, it is best to think of a monad as an abstract datatype
-- of actions. Haskell's do expressions provide a convenient
-- syntax for writing monadic expressions.
--
-- Instances of Monad should satisfy the following:
--
--
--
-- Furthermore, the Monad and Applicative operations should
-- relate as follows:
--
--
--
-- The above laws imply:
--
--
--
-- and that pure and (<*>) satisfy the applicative
-- functor laws.
--
-- The instances of Monad for lists, Maybe and IO
-- defined in the Prelude satisfy these laws.
class Applicative m => Monad (m :: Type -> Type)
-- | Sequentially compose two actions, passing any value produced by the
-- first as an argument to the second.
--
-- 'as >>= bs' can be understood as the do
-- expression
--
--
-- do a <- as
-- bs a
--
(>>=) :: 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.
--
-- 'as >> bs' can be understood as the do
-- expression
--
--
-- do as
-- bs
--
(>>) :: Monad m => m a -> m b -> m b
-- | Inject a value into the monadic type.
return :: Monad m => a -> m a
infixl 1 >>=
infixl 1 >>
-- | A type f is a Functor if it provides a function fmap
-- which, given any types a and b lets you apply any
-- function from (a -> b) to turn an f a into an
-- f b, preserving the structure of f. Furthermore
-- f needs to adhere to the following:
--
--
--
-- Note, that the second law follows from the free theorem of the type
-- fmap and the first law, so you need only check that the former
-- condition holds.
class Functor (f :: Type -> Type)
-- | Using ApplicativeDo: 'fmap f as' can be
-- understood as the do expression
--
--
-- do a <- as
-- pure (f a)
--
--
-- with an inferred Functor constraint.
fmap :: Functor f => (a -> b) -> f a -> f b
-- | Replace all locations in the input with the same value. The default
-- definition is fmap . const, but this may be
-- overridden with a more efficient version.
--
-- Using ApplicativeDo: 'a <$ bs' can be
-- understood as the do expression
--
--
-- do bs
-- pure a
--
--
-- with an inferred Functor constraint.
(<$) :: Functor f => a -> f b -> f a
infixl 4 <$
-- | When a value is bound in do-notation, the pattern on the left
-- hand side of <- might not match. In this case, this class
-- provides a function to recover.
--
-- A Monad without a MonadFail instance may only be used in
-- conjunction with pattern that always match, such as newtypes, tuples,
-- data types with only a single data constructor, and irrefutable
-- patterns (~pat).
--
-- Instances of MonadFail should satisfy the following law:
-- fail s should be a left zero for >>=,
--
--
-- fail s >>= f = fail s
--
--
-- If your Monad is also MonadPlus, a popular definition is
--
--
-- fail _ = mzero
--
class Monad m => MonadFail (m :: Type -> Type)
-- | Map each element of a structure to a monadic action, evaluate these
-- actions from left to right, and collect the results. For a version
-- that ignores the results see mapM_.
mapM :: (Traversable t, Monad m) => (a -> m b) -> t a -> m (t b)
-- | Evaluate each monadic action in the structure from left to right, and
-- collect the results. For a version that ignores the results see
-- sequence_.
sequence :: (Traversable t, Monad m) => t (m a) -> m (t a)
-- | forM_ is mapM_ with its arguments flipped. For a version
-- that doesn't ignore the results see forM.
--
-- As of base 4.8.0.0, forM_ is just for_, specialized to
-- Monad.
forM_ :: (Foldable t, Monad m) => t a -> (a -> m b) -> 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 mapM.
--
-- As of base 4.8.0.0, mapM_ is just traverse_, specialized
-- to Monad.
mapM_ :: (Foldable t, Monad m) => (a -> m b) -> t a -> m ()
-- | Monads that also support choice and failure.
class (Alternative m, Monad m) => MonadPlus (m :: Type -> Type)
-- | The identity of mplus. It should also satisfy the equations
--
--
-- mzero >>= f = mzero
-- v >> mzero = mzero
--
--
-- The default definition is
--
--
-- mzero = empty
--
mzero :: MonadPlus m => m a
-- | An associative operation. The default definition is
--
--
-- mplus = (<|>)
--
mplus :: MonadPlus m => m a -> m a -> m a
-- | Direct MonadPlus equivalent of filter.
--
-- Examples
--
-- The filter function is just mfilter specialized to the
-- list monad:
--
--
-- filter = ( mfilter :: (a -> Bool) -> [a] -> [a] )
--
--
-- An example using mfilter with the Maybe monad:
--
--
-- >>> mfilter odd (Just 1)
-- Just 1
-- >>> mfilter odd (Just 2)
-- Nothing
--
mfilter :: MonadPlus m => (a -> Bool) -> m a -> m a
-- | Strict version of <$>.
(<$!>) :: Monad m => (a -> b) -> m a -> m b
infixl 4 <$!>
-- | The reverse of when.
unless :: Applicative f => Bool -> f () -> f ()
-- | Like replicateM, but discards the result.
replicateM_ :: Applicative m => Int -> m a -> m ()
-- | replicateM n act performs the action n times,
-- gathering the results.
--
-- Using ApplicativeDo: 'replicateM 5 as' can be
-- understood as the do expression
--
--
-- do a1 <- as
-- a2 <- as
-- a3 <- as
-- a4 <- as
-- a5 <- as
-- pure [a1,a2,a3,a4,a5]
--
--
-- Note the Applicative constraint.
replicateM :: Applicative m => Int -> m a -> m [a]
-- | Like foldM, but discards the result.
foldM_ :: (Foldable t, Monad m) => (b -> a -> m b) -> b -> t a -> m ()
-- | The foldM function is analogous to foldl, except that
-- its result is encapsulated in a monad. Note that foldM works
-- from left-to-right over the list arguments. This could be an issue
-- where (>>) and the `folded function' are not
-- commutative.
--
--
-- foldM f a1 [x1, x2, ..., xm]
--
-- ==
--
-- do
-- a2 <- f a1 x1
-- a3 <- f a2 x2
-- ...
-- f am xm
--
--
-- If right-to-left evaluation is required, the input list should be
-- reversed.
--
-- Note: foldM is the same as foldlM
foldM :: (Foldable t, Monad m) => (b -> a -> m b) -> b -> t a -> m b
-- | zipWithM_ is the extension of zipWithM which ignores the
-- final result.
zipWithM_ :: Applicative m => (a -> b -> m c) -> [a] -> [b] -> m ()
-- | The zipWithM function generalizes zipWith to arbitrary
-- applicative functors.
zipWithM :: Applicative m => (a -> b -> m c) -> [a] -> [b] -> m [c]
-- | The mapAndUnzipM function maps its first argument over a list,
-- returning the result as a pair of lists. This function is mainly used
-- with complicated data structures or a state monad.
mapAndUnzipM :: Applicative m => (a -> m (b, c)) -> [a] -> m ([b], [c])
-- | Repeat an action indefinitely.
--
-- Using ApplicativeDo: 'forever as' can be
-- understood as the pseudo-do expression
--
--
-- do as
-- as
-- ..
--
--
-- with as repeating.
--
-- Examples
--
-- A common use of forever is to process input from network
-- sockets, Handles, and channels (e.g. MVar and
-- Chan).
--
-- For example, here is how we might implement an echo server,
-- using forever both to listen for client connections on a
-- network socket and to echo client input on client connection handles:
--
--
-- echoServer :: Socket -> IO ()
-- echoServer socket = forever $ do
-- client <- accept socket
-- forkFinally (echo client) (\_ -> hClose client)
-- where
-- echo :: Handle -> IO ()
-- echo client = forever $
-- hGetLine client >>= hPutStrLn client
--
forever :: Applicative f => f a -> f b
-- | Right-to-left composition of Kleisli arrows.
-- (>=>), with the arguments flipped.
--
-- Note how this operator resembles function composition
-- (.):
--
--
-- (.) :: (b -> c) -> (a -> b) -> a -> c
-- (<=<) :: Monad m => (b -> m c) -> (a -> m b) -> a -> m c
--
(<=<) :: Monad m => (b -> m c) -> (a -> m b) -> a -> m c
infixr 1 <=<
-- | Left-to-right composition of Kleisli arrows.
--
-- '(bs >=> cs) a' can be understood as the
-- do expression
--
--
-- do b <- bs a
-- cs b
--
(>=>) :: Monad m => (a -> m b) -> (b -> m c) -> a -> m c
infixr 1 >=>
-- | This generalizes the list-based filter function.
filterM :: Applicative m => (a -> m Bool) -> [a] -> m [a]
-- | forM is mapM with its arguments flipped. For a version
-- that ignores the results see forM_.
forM :: (Traversable t, Monad m) => t a -> (a -> m b) -> m (t b)
-- | The sum of a collection of actions, generalizing concat. As of
-- base 4.8.0.0, msum is just asum, specialized to
-- MonadPlus.
msum :: (Foldable t, MonadPlus m) => t (m a) -> m 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
-- sequence.
--
-- As of base 4.8.0.0, sequence_ is just sequenceA_,
-- specialized to Monad.
sequence_ :: (Foldable t, Monad m) => t (m a) -> m ()
-- | void value discards or ignores the result of
-- evaluation, such as the return value of an IO action.
--
-- Using ApplicativeDo: 'void as' can be
-- understood as the do expression
--
--
-- do as
-- pure ()
--
--
-- with an inferred Functor constraint.
--
-- Examples
--
-- Replace the contents of a Maybe Int with unit:
--
--
-- >>> void Nothing
-- Nothing
--
-- >>> void (Just 3)
-- Just ()
--
--
-- Replace the contents of an Either Int
-- Int with unit, resulting in an Either
-- Int ():
--
--
-- >>> void (Left 8675309)
-- Left 8675309
--
-- >>> void (Right 8675309)
-- Right ()
--
--
-- Replace every element of a list with unit:
--
--
-- >>> void [1,2,3]
-- [(),(),()]
--
--
-- Replace the second element of a pair with unit:
--
--
-- >>> void (1,2)
-- (1,())
--
--
-- Discard the result of an IO action:
--
--
-- >>> mapM print [1,2]
-- 1
-- 2
-- [(),()]
--
-- >>> void $ mapM print [1,2]
-- 1
-- 2
--
void :: Functor f => f a -> f ()
-- | In many situations, the liftM operations can be replaced by
-- uses of ap, which promotes function application.
--
--
-- return f `ap` x1 `ap` ... `ap` xn
--
--
-- is equivalent to
--
--
-- liftMn f x1 x2 ... xn
--
ap :: Monad m => m (a -> b) -> m a -> m b
-- | Promote a function to a monad, scanning the monadic arguments from
-- left to right (cf. liftM2).
liftM5 :: Monad m => (a1 -> a2 -> a3 -> a4 -> a5 -> r) -> m a1 -> m a2 -> m a3 -> m a4 -> m a5 -> m r
-- | Promote a function to a monad, scanning the monadic arguments from
-- left to right (cf. liftM2).
liftM4 :: Monad m => (a1 -> a2 -> a3 -> a4 -> r) -> m a1 -> m a2 -> m a3 -> m a4 -> m r
-- | Promote a function to a monad, scanning the monadic arguments from
-- left to right (cf. liftM2).
liftM3 :: Monad m => (a1 -> a2 -> a3 -> r) -> m a1 -> m a2 -> m a3 -> m r
-- | Promote a function to a monad, scanning the monadic arguments from
-- left to right. For example,
--
--
-- liftM2 (+) [0,1] [0,2] = [0,2,1,3]
-- liftM2 (+) (Just 1) Nothing = Nothing
--
liftM2 :: Monad m => (a1 -> a2 -> r) -> m a1 -> m a2 -> m r
-- | Promote a function to a monad.
liftM :: Monad m => (a1 -> r) -> m a1 -> m r
-- | Conditional execution of Applicative expressions. For example,
--
--
-- when debug (putStrLn "Debugging")
--
--
-- will output the string Debugging if the Boolean value
-- debug is True, and otherwise do nothing.
when :: Applicative f => Bool -> f () -> f ()
-- | Same as >>=, but with the arguments interchanged.
(=<<) :: Monad m => (a -> m b) -> m a -> m b
infixr 1 =<<
-- | Like findM, but also allows you to compute some additional
-- information in the predicate.
firstJustM :: Monad m => (a -> m (Maybe b)) -> [a] -> m (Maybe b)
-- | Like find, but where the test can be monadic.
--
--
-- findM (Just . isUpper) "teST" == Just (Just 'S')
-- findM (Just . isUpper) "test" == Just Nothing
-- findM (Just . const True) ["x",undefined] == Just (Just "x")
--
findM :: Monad m => (a -> m Bool) -> [a] -> m (Maybe a)
-- | A version of and lifted to a monad. Retains the
-- short-circuiting behaviour.
--
--
-- andM [Just True,Just False,undefined] == Just False
-- andM [Just True,Just True ,undefined] == undefined
-- \xs -> Just (and xs) == andM (map Just xs)
--
andM :: Monad m => [m Bool] -> m Bool
-- | A version of or lifted to a monad. Retains the short-circuiting
-- behaviour.
--
--
-- orM [Just False,Just True ,undefined] == Just True
-- orM [Just False,Just False,undefined] == undefined
-- \xs -> Just (or xs) == orM (map Just xs)
--
orM :: Monad m => [m Bool] -> m Bool
-- | A version of all lifted to a monad. Retains the
-- short-circuiting behaviour.
--
--
-- allM Just [True,False,undefined] == Just False
-- allM Just [True,True ,undefined] == undefined
-- \(f :: Int -> Maybe Bool) xs -> anyM f xs == orM (map f xs)
--
allM :: Monad m => (a -> m Bool) -> [a] -> m Bool
-- | A version of any lifted to a monad. Retains the
-- short-circuiting behaviour.
--
--
-- anyM Just [False,True ,undefined] == Just True
-- anyM Just [False,False,undefined] == undefined
-- \(f :: Int -> Maybe Bool) xs -> anyM f xs == orM (map f xs)
--
anyM :: Monad m => (a -> m Bool) -> [a] -> m Bool
-- | The lazy && operator lifted to a monad. If the first
-- argument evaluates to False the second argument will not be
-- evaluated.
--
--
-- Just False &&^ undefined == Just False
-- Just True &&^ Just True == Just True
-- Just True &&^ Just False == Just False
--
(&&^) :: Monad m => m Bool -> m Bool -> m Bool
-- | The lazy || operator lifted to a monad. If the first argument
-- evaluates to True the second argument will not be evaluated.
--
--
-- Just True ||^ undefined == Just True
-- Just False ||^ Just True == Just True
-- Just False ||^ Just False == Just False
--
(||^) :: Monad m => m Bool -> m Bool -> m Bool
-- | Like not, but where the test can be monadic.
notM :: Functor m => m Bool -> m Bool
-- | Like if, but where the test can be monadic.
ifM :: Monad m => m Bool -> m a -> m a -> m a
-- | Like unless, but where the test can be monadic.
unlessM :: Monad m => m Bool -> m () -> m ()
-- | Like when, but where the test can be monadic.
whenM :: Monad m => m Bool -> m () -> m ()
-- | Keep running an operation until it becomes a Just, then return
-- the value inside the Just as the result of the overall loop.
untilJustM :: Monad m => m (Maybe a) -> m a
-- | Keep running an operation until it becomes a Nothing,
-- accumulating the monoid results inside the Justs as the result
-- of the overall loop.
whileJustM :: (Monad m, Monoid a) => m (Maybe a) -> m a
-- | Keep running an operation until it becomes False. As an
-- example:
--
--
-- whileM $ do sleep 0.1; notM $ doesFileExist "foo.txt"
-- readFile "foo.txt"
--
--
-- If you need some state persisted between each test, use loopM.
whileM :: Monad m => m Bool -> m ()
-- | A monadic version of loop, where the predicate returns
-- Left as a seed for the next loop or Right to abort the
-- loop.
loopM :: Monad m => (a -> m (Either a b)) -> a -> m b
-- | A looping operation, where the predicate returns Left as a seed
-- for the next loop or Right to abort the loop.
--
--
-- loop (\x -> if x < 10 then Left $ x * 2 else Right $ show x) 1 == "16"
--
loop :: (a -> Either a b) -> a -> b
-- | A version of mapMaybe that works with a monadic predicate.
mapMaybeM :: Monad m => (a -> m (Maybe b)) -> [a] -> m [b]
-- | A version of mconcatMap that works with a monadic predicate.
mconcatMapM :: (Monad m, Monoid b) => (a -> m b) -> [a] -> m b
-- | Like concatMapM, but has its arguments flipped, so can be used
-- instead of the common fmap concat $ forM pattern.
concatForM :: Monad m => [a] -> (a -> m [b]) -> m [b]
-- | A version of concatMap that works with a monadic predicate.
concatMapM :: Monad m => (a -> m [b]) -> [a] -> m [b]
-- | A version of partition that works with a monadic predicate.
--
--
-- partitionM (Just . even) [1,2,3] == Just ([2], [1,3])
-- partitionM (const Nothing) [1,2,3] == Nothing
--
partitionM :: Monad m => (a -> m Bool) -> [a] -> m ([a], [a])
-- | Like fold1M but discards the result.
fold1M_ :: (Partial, Monad m) => (a -> a -> m a) -> [a] -> m ()
-- | A variant of foldM that has no base case, and thus may only be
-- applied to non-empty lists.
--
--
-- fold1M (\x y -> Just x) [] == undefined
-- fold1M (\x y -> Just $ x + y) [1, 2, 3] == Just 6
--
fold1M :: (Partial, Monad m) => (a -> a -> m a) -> [a] -> m a
-- | Monadic generalisation of either.
eitherM :: Monad m => (a -> m c) -> (b -> m c) -> m (Either a b) -> m c
-- | Monadic generalisation of fromMaybe.
fromMaybeM :: Monad m => m a -> m (Maybe a) -> m a
-- | Monadic generalisation of maybe.
maybeM :: Monad m => m b -> (a -> m b) -> m (Maybe a) -> m b
-- | The identity function which requires the inner argument to be
-- (). Useful for functions with overloaded return types.
--
--
-- \(x :: Maybe ()) -> unit x == x
--
unit :: m () -> m ()
-- | Like whenMaybe, but where the test can be monadic.
whenMaybeM :: Monad m => m Bool -> m a -> m (Maybe a)
-- | Like when, but return either Nothing if the predicate
-- was False, of Just with the result of the computation.
--
--
-- whenMaybe True (print 1) == fmap Just (print 1)
-- whenMaybe False (print 1) == pure Nothing
--
whenMaybe :: Applicative m => Bool -> m a -> m (Maybe a)
-- | Return either a pure value if a condition is True,
-- otherwise empty.
--
--
-- pureIf @Maybe True 5 == Just 5
-- pureIf @Maybe False 5 == Nothing
-- pureIf @[] True 5 == [5]
-- pureIf @[] False 5 == []
--
pureIf :: Alternative m => Bool -> a -> m a
-- | Like whenJust, but where the test can be monadic.
whenJustM :: Monad m => m (Maybe a) -> (a -> m ()) -> m ()
-- | Perform some operation on Just, given the field inside the
-- Just.
--
--
-- whenJust Nothing print == pure ()
-- whenJust (Just 1) print == print 1
--
whenJust :: Applicative m => Maybe a -> (a -> m ()) -> m ()
-- | Monads in which IO computations may be embedded. Any monad
-- built by applying a sequence of monad transformers to the IO
-- monad will be an instance of this class.
--
-- Instances should satisfy the following laws, which state that
-- liftIO is a transformer of monads:
--
--
class Monad m => MonadIO (m :: Type -> Type)
-- | Lift a computation from the IO monad.
liftIO :: MonadIO m => IO a -> m a
-- | The class of monoids (types with an associative binary operation that
-- has an identity). Instances should satisfy the following:
--
--
--
-- 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
-- newtypes and make those instances of Monoid, e.g.
-- Sum and Product.
--
-- NOTE: Semigroup is a superclass of Monoid since
-- base-4.11.0.0.
class Semigroup a => Monoid a
-- | Identity of mappend
--
--
-- >>> "Hello world" <> mempty
-- "Hello world"
--
mempty :: Monoid a => a
-- | An associative operation
--
-- NOTE: This method is redundant and has the default
-- implementation mappend = (<>) since
-- base-4.11.0.0. Should it be implemented manually, since
-- mappend is a synonym for (<>), it is expected that
-- the two functions are defined the same way. In a future GHC release
-- mappend will be removed from Monoid.
mappend :: Monoid a => a -> a -> a
-- | Fold a list using the monoid.
--
-- For most types, the default definition for mconcat will be
-- used, but the function is included in the class definition so that an
-- optimized version can be provided for specific types.
--
--
-- >>> mconcat ["Hello", " ", "Haskell", "!"]
-- "Hello Haskell!"
--
mconcat :: Monoid a => [a] -> a
-- | The class of semigroups (types with an associative binary operation).
--
-- Instances should satisfy the following:
--
--
-- - Associativity x <> (y <> z) =
-- (x <> y) <> z
--
class Semigroup a
-- | An associative operation.
--
--
-- >>> [1,2,3] <> [4,5,6]
-- [1,2,3,4,5,6]
--
(<>) :: Semigroup a => a -> a -> a
-- | Reduce a non-empty list with <>
--
-- The default definition should be sufficient, but this can be
-- overridden for efficiency.
--
--
-- >>> import Data.List.NonEmpty
--
-- >>> sconcat $ "Hello" :| [" ", "Haskell", "!"]
-- "Hello Haskell!"
--
sconcat :: Semigroup a => NonEmpty a -> a
-- | Repeat a value n times.
--
-- Given that this works on a Semigroup it is allowed to fail if
-- you request 0 or fewer repetitions, and the default definition will do
-- so.
--
-- By making this a member of the class, idempotent semigroups and
-- monoids can upgrade this to execute in <math> by picking
-- stimes = stimesIdempotent or stimes =
-- stimesIdempotentMonoid respectively.
--
--
-- >>> stimes 4 [1]
-- [1,1,1,1]
--
stimes :: (Semigroup a, Integral b) => b -> a -> a
infixr 6 <>
-- | 8-bit unsigned integer type
data Word8
-- | Representable types of kind *. This class is derivable in GHC
-- with the DeriveGeneric flag on.
--
-- A Generic instance must satisfy the following laws:
--
--
-- from . to ≡ id
-- to . from ≡ id
--
class Generic a
-- | Type representing arbitrary-precision non-negative integers.
--
--
-- >>> 2^100 :: Natural
-- 1267650600228229401496703205376
--
--
-- Operations whose result would be negative throw
-- (Underflow :: ArithException),
--
--
-- >>> -1 :: Natural
-- *** Exception: arithmetic underflow
--
data Natural
-- | A space efficient, packed, unboxed Unicode text type.
data Text
type LazyText = Text
-- | A space-efficient representation of a Word8 vector, supporting
-- many efficient operations.
--
-- A ByteString contains 8-bit bytes, or by using the operations
-- from Data.ByteString.Char8 it can be interpreted as containing
-- 8-bit characters.
data ByteString
type LazyByteString = ByteString
packText :: String -> Text
unpackText :: Text -> String
-- | The most general way to run a parser over the Identity monad.
-- runParser p state filePath input runs parser p on
-- the input list of tokens input, obtained from source
-- filePath with the initial user state st. The
-- filePath is only used in error messages and may be the empty
-- string. Returns either a ParseError (Left) or a value of
-- type a (Right).
--
--
-- parseFromFile p fname
-- = do{ input <- readFile fname
-- ; return (runParser p () fname input)
-- }
--
runParser :: Stream s Identity t => Parsec s u a -> u -> SourceName -> s -> Either ParseError a
-- | The most general way to run a parser. runParserT p state filePath
-- input runs parser p on the input list of tokens
-- input, obtained from source filePath with the
-- initial user state st. The filePath is only used in
-- error messages and may be the empty string. Returns a computation in
-- the underlying monad m that return either a ParseError
-- (Left) or a value of type a (Right).
runParserT :: Stream s m t => ParsecT s u m a -> u -> SourceName -> s -> m (Either ParseError a)
-- | Convenience wrapper around runParser that uses the
-- HasParser class to determine the desired parser for the given
-- result type. The function reports syntax errors by throwing
-- ParseError. This approach is inherently impure and complicates
-- error handling greatly. Use this function only on occasions where
-- parser errors are fatal errors that your code cannot recover from. In
-- almost all cases, parseM is the better choice.
--
--
-- >>> parse "Natural" "12345" :: Natural
-- 12345
--
--
-- Like parseM, this function does not skip over any white space.
-- Use Parsec's primitive runParser or runParserT functions
-- if you don't like this behavior:
--
--
-- >>> runParser (spaces >> parser) () "Natural" " 1 " :: Either ParseError Natural
-- Right 1
--
parse :: (Stream input Identity Char, HasParser a) => ErrorContext -> input -> a
-- | Convenience wrapper around runParserT that uses the
-- HasParser class to determine the desired parser for the given
-- result type. The function reports syntax errors via fail.
--
--
-- >>> parseM "Natural" "987654321" :: IO Natural
-- 987654321
--
-- >>> parseM "Natural" "123456789" :: Maybe Natural
-- Just 123456789
--
--
-- Please note that parsers run this way do not ignore any white space:
--
--
-- >>> parseM "Natural" " 1" :: Maybe Natural
-- Nothing
--
-- >>> parseM "Natural" "1 " :: Maybe Natural
-- Nothing
--
parseM :: (MonadFail m, Stream input m Char, HasParser a) => ErrorContext -> input -> m a
-- | A simplified ParsecT parser that consumes some kind of
-- character stream without requiring any particular state state.
type CharParser st input (m :: Type -> Type) a = Stream st m Char => ParsecT st input m a
-- | Types that are instances of this class can be parsed and constructed
-- from some character based text representation.
class HasParser a
parser :: forall st input (m :: Type -> Type). HasParser a => CharParser st input m a
-- | Parsers functions like parse or parseM use this type to
-- provide a helpful context in case the parser failes. Parsec uses the
-- synonym SourceName for the same purpose, but in fact this type
-- doesn't necessarily have to be a file name. It can be any name or
-- identifier. Oftentimes, it it's useful to pass the name of the type
-- that the parser attempted to parse.
type ErrorContext = String
-- | Pretty print a value with the prettyNormal level.
prettyShow :: Pretty a => a -> String
-- | Pretty printing class. The precedence level is used in a similar way
-- as in the Show class. Minimal complete definition is either
-- pPrintPrec or pPrint.
class Pretty a
pPrint :: Pretty a => a -> Doc
-- | The abstract type of documents. A Doc represents a set of
-- layouts. A Doc with no occurrences of Union or NoDoc represents just
-- one layout.
data Doc
-- | A type that can be converted to JSON.
--
-- Instances in general must specify toJSON and
-- should (but don't need to) specify toEncoding.
--
-- An example type and instance:
--
--
-- -- Allow ourselves to write Text literals.
-- {-# LANGUAGE OverloadedStrings #-}
--
-- data Coord = Coord { x :: Double, y :: Double }
--
-- instance ToJSON Coord where
-- toJSON (Coord x y) = object ["x" .= x, "y" .= y]
--
-- toEncoding (Coord x y) = pairs ("x" .= x <> "y" .= y)
--
--
-- Instead of manually writing your ToJSON instance, there are two
-- options to do it automatically:
--
--
-- - Data.Aeson.TH provides Template Haskell functions which
-- will derive an instance at compile time. The generated instance is
-- optimized for your type so it will probably be more efficient than the
-- following option.
-- - The compiler can provide a default generic implementation for
-- toJSON.
--
--
-- To use the second, simply add a deriving Generic
-- clause to your datatype and declare a ToJSON instance. If you
-- require nothing other than defaultOptions, it is sufficient to
-- write (and this is the only alternative where the default
-- toJSON implementation is sufficient):
--
--
-- {-# LANGUAGE DeriveGeneric #-}
--
-- import GHC.Generics
--
-- data Coord = Coord { x :: Double, y :: Double } deriving Generic
--
-- instance ToJSON Coord where
-- toEncoding = genericToEncoding defaultOptions
--
--
-- If on the other hand you wish to customize the generic decoding, you
-- have to implement both methods:
--
--
-- customOptions = defaultOptions
-- { fieldLabelModifier = map toUpper
-- }
--
-- instance ToJSON Coord where
-- toJSON = genericToJSON customOptions
-- toEncoding = genericToEncoding customOptions
--
--
-- Previous versions of this library only had the toJSON method.
-- Adding toEncoding had two reasons:
--
--
-- - toEncoding is more efficient for the common case that the output
-- of toJSON is directly serialized to a ByteString.
-- Further, expressing either method in terms of the other would be
-- non-optimal.
-- - The choice of defaults allows a smooth transition for existing
-- users: Existing instances that do not define toEncoding still
-- compile and have the correct semantics. This is ensured by making the
-- default implementation of toEncoding use toJSON. This
-- produces correct results, but since it performs an intermediate
-- conversion to a Value, it will be less efficient than directly
-- emitting an Encoding. (this also means that specifying nothing
-- more than instance ToJSON Coord would be sufficient as a
-- generically decoding instance, but there probably exists no good
-- reason to not specify toEncoding in new instances.)
--
class ToJSON a
-- | A type that can be converted from JSON, with the possibility of
-- failure.
--
-- In many cases, you can get the compiler to generate parsing code for
-- you (see below). To begin, let's cover writing an instance by hand.
--
-- There are various reasons a conversion could fail. For example, an
-- Object could be missing a required key, an Array could
-- be of the wrong size, or a value could be of an incompatible type.
--
-- The basic ways to signal a failed conversion are as follows:
--
--
-- - fail yields a custom error message: it is the recommended
-- way of reporting a failure;
-- - empty (or mzero) is uninformative: use it when the
-- error is meant to be caught by some (<|>);
-- - typeMismatch can be used to report a failure when the
-- encountered value is not of the expected JSON type; unexpected
-- is an appropriate alternative when more than one type may be expected,
-- or to keep the expected type implicit.
--
--
-- prependFailure (or modifyFailure) add more information
-- to a parser's error messages.
--
-- An example type and instance using typeMismatch and
-- prependFailure:
--
--
-- -- Allow ourselves to write Text literals.
-- {-# LANGUAGE OverloadedStrings #-}
--
-- data Coord = Coord { x :: Double, y :: Double }
--
-- instance FromJSON Coord where
-- parseJSON (Object v) = Coord
-- <$> v .: "x"
-- <*> v .: "y"
--
-- -- We do not expect a non-Object value here.
-- -- We could use empty to fail, but typeMismatch
-- -- gives a much more informative error message.
-- parseJSON invalid =
-- prependFailure "parsing Coord failed, "
-- (typeMismatch "Object" invalid)
--
--
-- For this common case of only being concerned with a single type of
-- JSON value, the functions withObject, withScientific,
-- etc. are provided. Their use is to be preferred when possible, since
-- they are more terse. Using withObject, we can rewrite the above
-- instance (assuming the same language extension and data type) as:
--
--
-- instance FromJSON Coord where
-- parseJSON = withObject "Coord" $ \v -> Coord
-- <$> v .: "x"
-- <*> v .: "y"
--
--
-- Instead of manually writing your FromJSON instance, there are
-- two options to do it automatically:
--
--
-- - Data.Aeson.TH provides Template Haskell functions which
-- will derive an instance at compile time. The generated instance is
-- optimized for your type so it will probably be more efficient than the
-- following option.
-- - The compiler can provide a default generic implementation for
-- parseJSON.
--
--
-- To use the second, simply add a deriving Generic
-- clause to your datatype and declare a FromJSON instance for
-- your datatype without giving a definition for parseJSON.
--
-- For example, the previous example can be simplified to just:
--
--
-- {-# LANGUAGE DeriveGeneric #-}
--
-- import GHC.Generics
--
-- data Coord = Coord { x :: Double, y :: Double } deriving Generic
--
-- instance FromJSON Coord
--
--
-- The default implementation will be equivalent to parseJSON =
-- genericParseJSON defaultOptions; if you need
-- different options, you can customize the generic decoding by defining:
--
--
-- customOptions = defaultOptions
-- { fieldLabelModifier = map toUpper
-- }
--
-- instance FromJSON Coord where
-- parseJSON = genericParseJSON customOptions
--
class FromJSON a
-- | Class for string-like datastructures; used by the overloaded string
-- extension (-XOverloadedStrings in GHC).
class IsString a
fromString :: IsString a => String -> a
-- | This is the simplest representation of UTC. It consists of the day
-- number, and a time offset from midnight. Note that if a day has a leap
-- second added to it, it will have 86401 seconds.
data UTCTime
UTCTime :: Day -> DiffTime -> UTCTime
-- | the day
[utctDay] :: UTCTime -> Day
-- | the time from midnight, 0 <= t < 86401s (because of
-- leap-seconds)
[utctDayTime] :: UTCTime -> DiffTime
-- | This is a length of time, as measured by a clock. Conversion functions
-- will treat it as seconds. It has a precision of 10^-12 s.
data DiffTime
-- | A set of values a.
data Set a
-- | A class of types that can be fully evaluated.
class NFData a
-- | The Binary class provides put and get, methods to
-- encode and decode a Haskell value to a lazy ByteString. It
-- mirrors the Read and Show classes for textual
-- representation of Haskell types, and is suitable for serialising
-- Haskell values to disk, over the network.
--
-- For decoding and generating simple external binary formats (e.g. C
-- structures), Binary may be used, but in general is not suitable for
-- complex protocols. Instead use the Put and Get
-- primitives directly.
--
-- Instances of Binary should satisfy the following property:
--
--
-- decode . encode == id
--
--
-- That is, the get and put methods should be the inverse
-- of each other. A range of instances are provided for basic Haskell
-- types.
class Binary t
-- | The class of types that can be converted to a hash value.
--
-- Minimal implementation: hashWithSalt.
--
-- Note: the hash is not guaranteed to be stable across library
-- versions, operating systems or architectures. For stable hashing use
-- named hashes: SHA256, CRC32 etc.
--
-- If you are looking for Hashable instance in time
-- package, check time-compat
class Eq a => Hashable a
-- | The fromMaybe function takes a default value and and
-- Maybe value. If the Maybe is Nothing, it returns
-- the default values; otherwise, it returns the value contained in the
-- Maybe.
--
-- Examples
--
-- Basic usage:
--
--
-- >>> fromMaybe "" (Just "Hello, World!")
-- "Hello, World!"
--
--
--
-- >>> fromMaybe "" Nothing
-- ""
--
--
-- Read an integer from a string using readMaybe. If we fail to
-- parse an integer, we want to return 0 by default:
--
--
-- >>> import Text.Read ( readMaybe )
--
-- >>> fromMaybe 0 (readMaybe "5")
-- 5
--
-- >>> fromMaybe 0 (readMaybe "")
-- 0
--
fromMaybe :: a -> Maybe a -> a
module OpenSuse.StripSpace
-- | A (quite possibly inefficient) re-implementation of git
-- stripspace. This function normalizes a Text buffer to
-- conform to the following rules:
--
--
-- - All trailing white space is stripped.
-- - Empty lines at the beginning or at the end of the buffer are
-- stripped.
-- - Consecutive empty lines between paragraphs are collapsed into
-- one.
-- - \r\n line endings are normalized into \n.
-- - If the buffer is not empty, then its last line is terminated by
-- \n.
-- - If the buffer is empty (i.e. it contains only white space), then
-- it comes out as the empty string.
--
stripSpace :: Text -> Text
module OpenSuse.GuessChangeLog
-- | Automatically guess the differences between to releases of a package
-- by looking at the change log file provided by upstream. The function
-- as arguments the paths of two directories that contain the extracted
-- release tarballs. The first arguments ought to point to the older
-- release, the second paths ought to point to the updated version.
--
-- The function uses the following algorithm to detect the relevant
-- changes:
--
--
-- - Scan both directories for files that look like they might be
-- change logs.
-- - If both directories contain the same candidate file, e.g.
-- ChangeLog, then use that.
-- - Compute the differences between the change log files and check
-- that all modifications are additions at the top of the file.
-- - Return those additions as Text.
--
guessChangeLog :: FilePath -> FilePath -> IO GuessedChangeLog
data GuessedChangeLog
-- | Both releases contained the given change log file, and these files
-- differed so that the given text was added at the top of the new one.
-- The text undergoes some amount of cleanup, i.e. we'll trim leading
-- empty lines at the top, trailing whitespace, and trailing empty lines
-- at the end.
GuessedChangeLog :: FilePath -> Text -> GuessedChangeLog
-- | Neither release contains a change log file.
NoChangeLogFiles :: GuessedChangeLog
-- | A change log file exists (and its name is returned), but it's
-- identical in both releases. In other words, upstream probably forgot
-- to document the release.
UndocumentedUpdate :: FilePath -> GuessedChangeLog
-- | Both releases contain a set of files that look like they might be a
-- change log, but their intersection is empty! This happens, for
-- example, when upstream has renamed the file.
NoCommonChangeLogFiles :: Set FilePath -> Set FilePath -> GuessedChangeLog
-- | Multiple change log files exists in both directories. Now, it would
-- probably work out okay if we'd just look at the diffs of both of them,
-- respectively, but it felt like a good idea to err on the side of
-- caution. This case is rare anyways.
MoreThanOneChangeLogFile :: Set FilePath -> GuessedChangeLog
-- | guessChangelog accepts up to 10 lines of unmodified text at
-- the top of the upstream change log file because some people like to
-- have a short introduction text there etc. If that header becomes too
-- large, however, then we return this error because we expect upstream
-- to add text at the top, not in the middle of the file.
UnmodifiedTopIsTooLarge :: FilePath -> Word -> GuessedChangeLog
-- | This happens when upstream edits the file in ways other than just
-- adding at the top. Sometimes people re-format old entries or rewrite
-- URLs or fix typos, and in such a case it feels to risky to trust the
-- diff.
NotJustTopAdditions :: FilePath -> GuessedChangeLog
instance GHC.Show.Show OpenSuse.GuessChangeLog.GuessedChangeLog
module OpenSuse.Types.EMailAddress
-- |
-- >>> mkEMailAddress " accept . full (rfc822) . syntax @ example . org "
-- Just (EMailAddress "accept.full.syntax@example.org")
--
--
--
-- >>> mkEMailAddress "@this@is@not@good@"
-- Nothing
--
--
--
-- >>> prettyShow (fromString "joe @ example.net" :: EMailAddress)
-- "joe@example.net"
--
data EMailAddress
-- | Constructor function for e-mail addresses. Returns Nothing if
-- the input is syntactically invalid.
mkEMailAddress :: String -> Maybe EMailAddress
-- | Accessor function for the underlying path of strings.
unEMailAddress :: EMailAddress -> String
instance Control.DeepSeq.NFData OpenSuse.Types.EMailAddress.EMailAddress
instance Data.Binary.Class.Binary OpenSuse.Types.EMailAddress.EMailAddress
instance Data.Hashable.Class.Hashable OpenSuse.Types.EMailAddress.EMailAddress
instance GHC.Generics.Generic OpenSuse.Types.EMailAddress.EMailAddress
instance GHC.Classes.Ord OpenSuse.Types.EMailAddress.EMailAddress
instance GHC.Classes.Eq OpenSuse.Types.EMailAddress.EMailAddress
instance GHC.Show.Show OpenSuse.Types.EMailAddress.EMailAddress
instance Text.Parsec.Class.HasParser OpenSuse.Types.EMailAddress.EMailAddress
instance Data.String.IsString OpenSuse.Types.EMailAddress.EMailAddress
instance Text.PrettyPrint.HughesPJClass.Pretty OpenSuse.Types.EMailAddress.EMailAddress
module OpenSuse.Types.ChangeLog
newtype ChangeLog
ChangeLog :: [Entry] -> ChangeLog
data Entry
Entry :: UTCTime -> EMailAddress -> Text -> Entry
[changedAt] :: Entry -> UTCTime
[changedBy] :: Entry -> EMailAddress
[changeDescription] :: Entry -> Text
parseEntry :: CharParser st input m Entry
parseDashedLine :: CharParser st input m ()
-- | Note that the input must be terminated by a newline.
--
--
-- >>> parseTest parseDateAddressLine "Wed Jun 27 09:25:07 UTC 2018 - foo@example.org\n"
-- (2018-06-27 09:25:07 UTC,EMailAddress "foo@example.org")
--
parseDateAddressLine :: CharParser st input m (UTCTime, EMailAddress)
-- | Consume all text until the end of the file or a dashed line is found.
-- In the latter case, the dashed line is consumed as well. This is
-- unfortunate, but it's how the notFollowedBy combinator works,
-- unfortunately,
parseDescription :: CharParser st input m String
instance GHC.Generics.Generic OpenSuse.Types.ChangeLog.Entry
instance GHC.Classes.Ord OpenSuse.Types.ChangeLog.Entry
instance GHC.Classes.Eq OpenSuse.Types.ChangeLog.Entry
instance GHC.Show.Show OpenSuse.Types.ChangeLog.Entry
instance GHC.Base.Monoid OpenSuse.Types.ChangeLog.ChangeLog
instance GHC.Base.Semigroup OpenSuse.Types.ChangeLog.ChangeLog
instance Control.DeepSeq.NFData OpenSuse.Types.ChangeLog.ChangeLog
instance GHC.Generics.Generic OpenSuse.Types.ChangeLog.ChangeLog
instance GHC.Classes.Ord OpenSuse.Types.ChangeLog.ChangeLog
instance GHC.Classes.Eq OpenSuse.Types.ChangeLog.ChangeLog
instance GHC.Show.Show OpenSuse.Types.ChangeLog.ChangeLog
instance Text.Parsec.Class.HasParser OpenSuse.Types.ChangeLog.ChangeLog
instance Control.DeepSeq.NFData OpenSuse.Types.ChangeLog.Entry
instance Text.Parsec.Class.HasParser OpenSuse.Types.ChangeLog.Entry
module OpenSuse.Types.Issue
data Issue
Bsc :: Natural -> Issue
Cve :: Natural -> Natural -> Issue
parseIssue :: String -> Issue
parseCve :: String -> Issue
parseBsc :: String -> Issue
showIssue :: Issue -> String
isCve :: Issue -> Bool
isBsc :: Issue -> Bool
instance GHC.Generics.Generic OpenSuse.Types.Issue.Issue
instance GHC.Classes.Ord OpenSuse.Types.Issue.Issue
instance GHC.Classes.Eq OpenSuse.Types.Issue.Issue
instance GHC.Show.Show OpenSuse.Types.Issue.Issue
instance Data.Hashable.Class.Hashable OpenSuse.Types.Issue.Issue
instance Data.Binary.Class.Binary OpenSuse.Types.Issue.Issue
instance Control.DeepSeq.NFData OpenSuse.Types.Issue.Issue
instance Data.Aeson.Types.FromJSON.FromJSON OpenSuse.Types.Issue.Issue
instance Data.Aeson.Types.FromJSON.FromJSONKey OpenSuse.Types.Issue.Issue
module OpenSuse.Types.PackageName
type PackageName = String
module OpenSuse.Types.ProjectId
-- | Projects are identified on OBS by a string path.
--
--
-- >>> parse "project id" "SUSE:SLE-12-SP2:Update" :: ProjectId
-- ProjectId ["SUSE","SLE-12-SP2","Update"]
--
-- >>> parseM "project id" "SUSE::SLE-12-SP2" :: Maybe ProjectId
-- Nothing
--
-- >>> parseM "project id" ":SUSE" :: Maybe ProjectId
-- Nothing
--
-- >>> parseM "project id" "SUSE:" :: Maybe ProjectId
-- Nothing
--
data ProjectId
-- | Constructor function for project identifiers.
--
-- TODO: Figure out how to deal with the [] project.
mkProjectId :: [String] -> ProjectId
-- | Accessor function for the underlying path of strings.
unProjectId :: ProjectId -> [String]
instance GHC.Base.Monoid OpenSuse.Types.ProjectId.ProjectId
instance GHC.Base.Semigroup OpenSuse.Types.ProjectId.ProjectId
instance Control.DeepSeq.NFData OpenSuse.Types.ProjectId.ProjectId
instance Data.Binary.Class.Binary OpenSuse.Types.ProjectId.ProjectId
instance Data.Hashable.Class.Hashable OpenSuse.Types.ProjectId.ProjectId
instance GHC.Generics.Generic OpenSuse.Types.ProjectId.ProjectId
instance GHC.Classes.Ord OpenSuse.Types.ProjectId.ProjectId
instance GHC.Classes.Eq OpenSuse.Types.ProjectId.ProjectId
instance GHC.Show.Show OpenSuse.Types.ProjectId.ProjectId
instance Data.String.IsString OpenSuse.Types.ProjectId.ProjectId
instance Text.PrettyPrint.HughesPJClass.Pretty OpenSuse.Types.ProjectId.ProjectId
instance Text.Parsec.Class.HasParser OpenSuse.Types.ProjectId.ProjectId
instance Data.Aeson.Types.FromJSON.FromJSON OpenSuse.Types.ProjectId.ProjectId
instance Data.Aeson.Types.FromJSON.FromJSONKey OpenSuse.Types.ProjectId.ProjectId
instance Data.Aeson.Types.ToJSON.ToJSON OpenSuse.Types.ProjectId.ProjectId
instance Data.Aeson.Types.ToJSON.ToJSONKey OpenSuse.Types.ProjectId.ProjectId
module OpenSuse.Types.RequestId
data RequestId
-- | Constructor function for typed request identifiers.
mkRequestId :: Natural -> RequestId
-- | Accessor function for the underlying natural number.
unRequestId :: RequestId -> Natural
-- | Type synonym for convenience.
type ReleaseRequestId = RequestId
-- | Type synonym for convenience.
type MaintenanceRequestId = RequestId
instance Control.DeepSeq.NFData OpenSuse.Types.RequestId.RequestId
instance Data.Binary.Class.Binary OpenSuse.Types.RequestId.RequestId
instance Data.Hashable.Class.Hashable OpenSuse.Types.RequestId.RequestId
instance GHC.Generics.Generic OpenSuse.Types.RequestId.RequestId
instance GHC.Enum.Enum OpenSuse.Types.RequestId.RequestId
instance GHC.Classes.Ord OpenSuse.Types.RequestId.RequestId
instance GHC.Classes.Eq OpenSuse.Types.RequestId.RequestId
instance GHC.Show.Show OpenSuse.Types.RequestId.RequestId
instance Data.Aeson.Types.FromJSON.FromJSON OpenSuse.Types.RequestId.RequestId
instance Data.Aeson.Types.ToJSON.ToJSON OpenSuse.Types.RequestId.RequestId
instance Data.String.IsString OpenSuse.Types.RequestId.RequestId
instance Text.PrettyPrint.HughesPJClass.Pretty OpenSuse.Types.RequestId.RequestId
instance Text.Parsec.Class.HasParser OpenSuse.Types.RequestId.RequestId
module OpenSuse.Types.UserName
type UserName = String