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Prelude | Portability | portable | Stability | stable | Maintainer | libraries@haskell.org |
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Description |
The Prelude: a standard module imported by default into all Haskell
modules. For more documentation, see the Haskell 98 Report
http://www.haskell.org/onlinereport/.
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Synopsis |
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| | (&&) :: Bool -> Bool -> Bool | | (||) :: Bool -> Bool -> Bool | | not :: Bool -> Bool | | otherwise :: Bool | | | | maybe :: b -> (a -> b) -> Maybe a -> b | | | | either :: (a -> c) -> (b -> c) -> Either a b -> c | | | | data Char | | type String = [Char] | | fst :: (a, b) -> a | | snd :: (a, b) -> b | | curry :: ((a, b) -> c) -> a -> b -> c | | uncurry :: (a -> b -> c) -> (a, b) -> c | | class Eq a where | | | class Eq a => Ord a where | | | class Enum a where | | | class Bounded a where | | | data Int | | data Integer | | data Float | | data Double | | type Rational = Ratio Integer | | class (Eq a, Show a) => Num a where | | | class (Num a, Ord a) => Real a where | | | class (Real a, Enum a) => Integral a where | | | class Num a => Fractional a where | | | class Fractional a => Floating a where | | | class (Real a, Fractional a) => RealFrac a where | | | class (RealFrac a, Floating a) => RealFloat a where | | | subtract :: Num a => a -> a -> a | | even :: Integral a => a -> Bool | | odd :: Integral a => a -> Bool | | gcd :: Integral a => a -> a -> a | | lcm :: Integral a => a -> a -> a | | (^) :: (Num a, Integral b) => a -> b -> a | | (^^) :: (Fractional a, Integral b) => a -> b -> a | | fromIntegral :: (Integral a, Num b) => a -> b | | realToFrac :: (Real a, Fractional b) => a -> b | | class Monad m where | | | class Functor f where | fmap :: (a -> b) -> f a -> f b |
| | mapM :: Monad m => (a -> m b) -> [a] -> m [b] | | mapM_ :: Monad m => (a -> m b) -> [a] -> m () | | sequence :: Monad m => [m a] -> m [a] | | sequence_ :: Monad m => [m a] -> m () | | (=<<) :: Monad m => (a -> m b) -> m a -> m b | | id :: a -> a | | const :: a -> b -> a | | (.) :: (b -> c) -> (a -> b) -> a -> c | | flip :: (a -> b -> c) -> b -> a -> c | | ($) :: (a -> b) -> a -> b | | until :: (a -> Bool) -> (a -> a) -> a -> a | | asTypeOf :: a -> a -> a | | error :: String -> a | | undefined :: a | | seq :: a -> b -> b | | ($!) :: (a -> b) -> a -> b | | map :: (a -> b) -> [a] -> [b] | | (++) :: [a] -> [a] -> [a] | | filter :: (a -> Bool) -> [a] -> [a] | | head :: [a] -> a | | last :: [a] -> a | | tail :: [a] -> [a] | | init :: [a] -> [a] | | null :: [a] -> Bool | | length :: [a] -> Int | | (!!) :: [a] -> Int -> a | | reverse :: [a] -> [a] | | foldl :: (a -> b -> a) -> a -> [b] -> a | | foldl1 :: (a -> a -> a) -> [a] -> a | | foldr :: (a -> b -> b) -> b -> [a] -> b | | foldr1 :: (a -> a -> a) -> [a] -> a | | and :: [Bool] -> Bool | | or :: [Bool] -> Bool | | any :: (a -> Bool) -> [a] -> Bool | | all :: (a -> Bool) -> [a] -> Bool | | sum :: Num a => [a] -> a | | product :: Num a => [a] -> a | | concat :: [[a]] -> [a] | | concatMap :: (a -> [b]) -> [a] -> [b] | | maximum :: Ord a => [a] -> a | | minimum :: Ord a => [a] -> a | | scanl :: (a -> b -> a) -> a -> [b] -> [a] | | scanl1 :: (a -> a -> a) -> [a] -> [a] | | scanr :: (a -> b -> b) -> b -> [a] -> [b] | | scanr1 :: (a -> a -> a) -> [a] -> [a] | | iterate :: (a -> a) -> a -> [a] | | repeat :: a -> [a] | | replicate :: Int -> a -> [a] | | cycle :: [a] -> [a] | | take :: Int -> [a] -> [a] | | drop :: Int -> [a] -> [a] | | splitAt :: Int -> [a] -> ([a], [a]) | | takeWhile :: (a -> Bool) -> [a] -> [a] | | dropWhile :: (a -> Bool) -> [a] -> [a] | | span :: (a -> Bool) -> [a] -> ([a], [a]) | | break :: (a -> Bool) -> [a] -> ([a], [a]) | | elem :: Eq a => a -> [a] -> Bool | | notElem :: Eq a => a -> [a] -> Bool | | lookup :: Eq a => a -> [(a, b)] -> Maybe b | | zip :: [a] -> [b] -> [(a, b)] | | zip3 :: [a] -> [b] -> [c] -> [(a, b, c)] | | zipWith :: (a -> b -> c) -> [a] -> [b] -> [c] | | zipWith3 :: (a -> b -> c -> d) -> [a] -> [b] -> [c] -> [d] | | unzip :: [(a, b)] -> ([a], [b]) | | unzip3 :: [(a, b, c)] -> ([a], [b], [c]) | | lines :: String -> [String] | | words :: String -> [String] | | unlines :: [String] -> String | | unwords :: [String] -> String | | type ShowS = String -> String | | class Show a where | | | shows :: Show a => a -> ShowS | | showChar :: Char -> ShowS | | showString :: String -> ShowS | | showParen :: Bool -> ShowS -> ShowS | | type ReadS a = String -> [(a, String)] | | class Read a where | | | reads :: Read a => ReadS a | | readParen :: Bool -> ReadS a -> ReadS a | | read :: Read a => String -> a | | lex :: ReadS String | | data IO a | | putChar :: Char -> IO () | | putStr :: String -> IO () | | putStrLn :: String -> IO () | | print :: Show a => a -> IO () | | getChar :: IO Char | | getLine :: IO String | | getContents :: IO String | | interact :: (String -> String) -> IO () | | type FilePath = String | | readFile :: FilePath -> IO String | | writeFile :: FilePath -> String -> IO () | | appendFile :: FilePath -> String -> IO () | | readIO :: Read a => String -> IO a | | readLn :: Read a => IO a | | type IOError = IOException | | ioError :: IOError -> IO a | | userError :: String -> IOError | | catch :: IO a -> (IOError -> IO a) -> IO a |
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Standard types, classes and related functions
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Basic data types
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data Bool |
The Bool type is an enumeration. It is defined with False
first so that the corresponding Enum instance will give
fromEnum False the value zero, and
fromEnum True the value 1.
| Constructors | | Instances | |
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(&&) :: Bool -> Bool -> Bool |
Boolean "and"
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(||) :: Bool -> Bool -> Bool |
Boolean "or"
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not :: Bool -> Bool |
Boolean "not"
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otherwise :: Bool |
otherwise is defined as the value True. It helps to make
guards more readable. eg.
f x | x < 0 = ...
| otherwise = ...
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data Maybe a |
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.
| Constructors | | Instances | |
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maybe :: b -> (a -> b) -> Maybe a -> b |
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.
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data Either a b |
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").
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either :: (a -> c) -> (b -> c) -> Either a b -> c |
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.
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data Ordering |
Represents an ordering relationship between two values: less
than, equal to, or greater than. An Ordering is returned by
compare.
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data Char |
The character type Char is an enumeration whose values represent
Unicode (or equivalently ISO/IEC 10646) characters
(see http://www.unicode.org/ for details).
This set extends the ISO 8859-1 (Latin-1) character set
(the first 256 charachers), 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).
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type String = [Char] |
A String is a list of characters. String constants in Haskell are values
of type String.
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Tuples
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fst :: (a, b) -> a |
Extract the first component of a pair.
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snd :: (a, b) -> b |
Extract the second component of a pair.
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curry :: ((a, b) -> c) -> a -> b -> c |
curry converts an uncurried function to a curried function.
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uncurry :: (a -> b -> c) -> (a, b) -> c |
uncurry converts a curried function to a function on pairs.
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Basic type classes
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class Eq a where |
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.
Minimal complete definition: either == or /=.
| | Methods | (==) :: a -> a -> Bool | | (/=) :: a -> a -> Bool |
| | Instances | Eq All | Eq Any | Eq ArithException | Eq ArrayException | Eq AsyncException | Eq Bool | Eq BufferMode | Eq BufferState | Eq ByteString | Eq ByteString | Eq CCc | Eq CChar | Eq CClock | Eq CDev | Eq CDouble | Eq CFloat | Eq CGid | Eq CIno | Eq CInt | Eq CIntMax | Eq CIntPtr | Eq CLDouble | Eq CLLong | Eq CLong | Eq CMode | Eq CNlink | Eq COff | Eq CPid | Eq CPtrdiff | Eq CRLim | Eq CSChar | Eq CShort | Eq CSigAtomic | Eq CSize | Eq CSpeed | Eq CSsize | Eq CTcflag | Eq CTime | Eq CUChar | Eq CUInt | Eq CUIntMax | Eq CUIntPtr | Eq CULLong | Eq CULong | Eq CUShort | Eq CUid | Eq CWchar | Eq CalendarTime | Eq Char | Eq ClockTime | Eq Constr | Eq ConstrRep | Eq DataRep | Eq Day | Eq Double | Eq Errno | Eq Exception | Eq ExitCode | Eq FDType | Eq Fd | Eq Fixity | Eq Float | Eq GeneralCategory | Eq Handle | Eq HandlePosn | Eq HashData | Eq IOErrorType | Eq IOException | Eq IOMode | Eq Inserts | Eq Int | Eq Int16 | Eq Int32 | Eq Int64 | Eq Int8 | Eq IntPtr | Eq IntSet | Eq Integer | Eq Key | Eq KeyPr | Eq Lexeme | Eq Month | Eq Ordering | Eq PackedString | Eq Permissions | Eq SeekMode | Eq ThreadId | Eq TimeDiff | Eq TimeLocale | Eq TyCon | Eq TypeRep | Eq Unique | Eq Version | Eq Word | Eq Word16 | Eq Word32 | Eq Word64 | Eq Word8 | Eq WordPtr | Eq () | (Eq a, Eq b) => Eq (a, b) | (Eq a, Eq b, Eq c) => Eq (a, b, c) | (Eq a, Eq b, Eq c, Eq d) => Eq (a, b, c, d) | (Eq a, Eq b, Eq c, Eq d, Eq e) => Eq (a, b, c, d, e) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f) => Eq (a, b, c, d, e, f) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g) => Eq (a, b, c, d, e, f, g) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h) => Eq (a, b, c, d, e, f, g, h) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i) => Eq (a, b, c, d, e, f, g, h, i) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i, Eq j) => Eq (a, b, c, d, e, f, g, h, i, j) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i, Eq j, Eq k) => Eq (a, b, c, d, e, f, g, h, i, j, k) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i, Eq j, Eq k, Eq l) => Eq (a, b, c, d, e, f, g, h, i, j, k, l) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i, Eq j, Eq k, Eq l, Eq m) => Eq (a, b, c, d, e, f, g, h, i, j, k, l, m) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i, Eq j, Eq k, Eq l, Eq m, Eq n) => Eq (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | (Eq a, Eq b, Eq c, Eq d, Eq e, Eq f, Eq g, Eq h, Eq i, Eq j, Eq k, Eq l, Eq m, Eq n, Eq o) => Eq (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | (RealFloat a, Eq a) => Eq (Complex a) | Eq (Fixed a) | Eq (ForeignPtr a) | Eq (FunPtr a) | Eq (IORef a) | Eq a => Eq (IntMap a) | Eq (MVar a) | Eq a => Eq (Maybe a) | Eq a => Eq (Product a) | Eq (Ptr a) | (Integral a, Eq a) => Eq (Ratio a) | Eq a => Eq (Seq a) | Eq a => Eq (Set a) | Eq (StableName a) | Eq (StablePtr a) | Eq a => Eq (Sum a) | Eq (TVar a) | Eq a => Eq (Tree a) | Eq a => Eq (ViewL a) | Eq a => Eq (ViewR a) | Eq a => Eq [a] | (Ix i, Eq e) => Eq (Array i e) | (Eq a, Eq b) => Eq (Either a b) | Eq (IOArray i e) | (Eq k, Eq a) => Eq (Map k a) | Eq (STRef s a) | (Ix ix, Eq e, IArray UArray e) => Eq (UArray ix e) | Eq (STArray s i e) |
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class Eq a => Ord a where |
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.
Minimal complete definition: either compare or <=.
Using compare can be more efficient for complex types.
| | Methods | compare :: a -> a -> Ordering | | (<) :: a -> a -> Bool | | (<=) :: a -> a -> Bool | | (>) :: a -> a -> Bool | | (>=) :: a -> a -> Bool | | max :: a -> a -> a | | min :: a -> a -> a |
| | Instances | Ord All | Ord Any | Ord ArithException | Ord ArrayException | Ord AsyncException | Ord Bool | Ord BufferMode | Ord ByteString | Ord ByteString | Ord CCc | Ord CChar | Ord CClock | Ord CDev | Ord CDouble | Ord CFloat | Ord CGid | Ord CIno | Ord CInt | Ord CIntMax | Ord CIntPtr | Ord CLDouble | Ord CLLong | Ord CLong | Ord CMode | Ord CNlink | Ord COff | Ord CPid | Ord CPtrdiff | Ord CRLim | Ord CSChar | Ord CShort | Ord CSigAtomic | Ord CSize | Ord CSpeed | Ord CSsize | Ord CTcflag | Ord CTime | Ord CUChar | Ord CUInt | Ord CUIntMax | Ord CUIntPtr | Ord CULLong | Ord CULong | Ord CUShort | Ord CUid | Ord CWchar | Ord CalendarTime | Ord Char | Ord ClockTime | Ord Day | Ord Double | Ord ExitCode | Ord Fd | Ord Float | Ord GeneralCategory | Ord IOMode | Ord Int | Ord Int16 | Ord Int32 | Ord Int64 | Ord Int8 | Ord IntPtr | Ord IntSet | Ord Integer | Ord Month | Ord Ordering | Ord PackedString | Ord Permissions | Ord SeekMode | Ord ThreadId | Ord TimeDiff | Ord TimeLocale | Ord Unique | Ord Version | Ord Word | Ord Word16 | Ord Word32 | Ord Word64 | Ord Word8 | Ord WordPtr | Ord () | (Ord a, Ord b) => Ord (a, b) | (Ord a, Ord b, Ord c) => Ord (a, b, c) | (Ord a, Ord b, Ord c, Ord d) => Ord (a, b, c, d) | (Ord a, Ord b, Ord c, Ord d, Ord e) => Ord (a, b, c, d, e) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f) => Ord (a, b, c, d, e, f) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g) => Ord (a, b, c, d, e, f, g) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h) => Ord (a, b, c, d, e, f, g, h) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i) => Ord (a, b, c, d, e, f, g, h, i) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i, Ord j) => Ord (a, b, c, d, e, f, g, h, i, j) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i, Ord j, Ord k) => Ord (a, b, c, d, e, f, g, h, i, j, k) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i, Ord j, Ord k, Ord l) => Ord (a, b, c, d, e, f, g, h, i, j, k, l) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i, Ord j, Ord k, Ord l, Ord m) => Ord (a, b, c, d, e, f, g, h, i, j, k, l, m) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i, Ord j, Ord k, Ord l, Ord m, Ord n) => Ord (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | (Ord a, Ord b, Ord c, Ord d, Ord e, Ord f, Ord g, Ord h, Ord i, Ord j, Ord k, Ord l, Ord m, Ord n, Ord o) => Ord (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | Ord (Fixed a) | Ord (ForeignPtr a) | Ord (FunPtr a) | Ord a => Ord (IntMap a) | Ord a => Ord (Maybe a) | Ord a => Ord (Product a) | Ord (Ptr a) | Integral a => Ord (Ratio a) | Ord a => Ord (Seq a) | Ord a => Ord (Set a) | Ord a => Ord (Sum a) | Ord a => Ord (ViewL a) | Ord a => Ord (ViewR a) | Ord a => Ord [a] | (Ix i, Ord e) => Ord (Array i e) | (Ord a, Ord b) => Ord (Either a b) | (Ord k, Ord v) => Ord (Map k v) | (Ix ix, Ord e, IArray UArray e) => Ord (UArray ix e) |
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class Enum a where |
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
| | Methods | succ :: a -> a | the successor of a value. For numeric types, succ adds 1.
| | pred :: a -> a | the predecessor of a value. For numeric types, pred subtracts 1.
| | toEnum :: Int -> a | Convert from an Int.
| | fromEnum :: a -> Int | 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.
| | enumFrom :: a -> [a] | Used in Haskell's translation of [n..].
| | enumFromThen :: a -> a -> [a] | Used in Haskell's translation of [n,n'..].
| | enumFromTo :: a -> a -> [a] | Used in Haskell's translation of [n..m].
| | enumFromThenTo :: a -> a -> a -> [a] | Used in Haskell's translation of [n,n'..m].
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class Bounded a where |
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.
| | Methods | minBound :: a | | maxBound :: a |
| | Instances | Bounded All | Bounded Any | Bounded Bool | Bounded CChar | Bounded CGid | Bounded CIno | Bounded CInt | Bounded CIntMax | Bounded CIntPtr | Bounded CLLong | Bounded CLong | Bounded CMode | Bounded CNlink | Bounded COff | Bounded CPid | Bounded CPtrdiff | Bounded CRLim | Bounded CSChar | Bounded CShort | Bounded CSigAtomic | Bounded CSize | Bounded CSsize | Bounded CTcflag | Bounded CUChar | Bounded CUInt | Bounded CUIntMax | Bounded CUIntPtr | Bounded CULLong | Bounded CULong | Bounded CUShort | Bounded CUid | Bounded CWchar | Bounded Char | Bounded Day | Bounded Fd | Bounded GeneralCategory | Bounded Int | Bounded Int16 | Bounded Int32 | Bounded Int64 | Bounded Int8 | Bounded IntPtr | Bounded Month | Bounded Ordering | Bounded Word | Bounded Word16 | Bounded Word32 | Bounded Word64 | Bounded Word8 | Bounded WordPtr | Bounded () | (Bounded a, Bounded b) => Bounded (a, b) | (Bounded a, Bounded b, Bounded c) => Bounded (a, b, c) | (Bounded a, Bounded b, Bounded c, Bounded d) => Bounded (a, b, c, d) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e) => Bounded (a, b, c, d, e) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f) => Bounded (a, b, c, d, e, f) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g) => Bounded (a, b, c, d, e, f, g) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h) => Bounded (a, b, c, d, e, f, g, h) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i) => Bounded (a, b, c, d, e, f, g, h, i) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j) => Bounded (a, b, c, d, e, f, g, h, i, j) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k) => Bounded (a, b, c, d, e, f, g, h, i, j, k) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l, Bounded m) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l, m) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l, Bounded m, Bounded n) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l, Bounded m, Bounded n, Bounded o) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | Bounded a => Bounded (Product a) | Bounded a => Bounded (Sum a) |
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Numbers
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Numeric types
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data Int |
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.
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data Integer |
Arbitrary-precision integers.
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data Float |
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.
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data Double |
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.
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type Rational = Ratio Integer |
Arbitrary-precision rational numbers, represented as a ratio of
two Integer values. A rational number may be constructed using
the % operator.
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Numeric type classes
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class (Eq a, Show a) => Num a where |
Basic numeric class.
Minimal complete definition: all except negate or (-)
| | Methods | (+) :: a -> a -> a | | (-) :: a -> a -> a | | (*) :: a -> a -> a | | negate :: a -> a | Unary negation.
| | abs :: a -> a | Absolute value.
| | signum :: 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).
| | fromInteger :: Integer -> 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.
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class (Num a, Ord a) => Real a where |
| Methods | toRational :: a -> Rational | the rational equivalent of its real argument with full precision
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class (Real a, Enum a) => Integral a where |
Integral numbers, supporting integer division.
Minimal complete definition: quotRem and toInteger
| | Methods | quot :: a -> a -> a | integer division truncated toward zero
| | rem :: a -> a -> a | integer remainder, satisfying
(x `quot` y)*y + (x `rem` y) == x
| | div :: a -> a -> a | integer division truncated toward negative infinity
| | mod :: a -> a -> a | integer modulus, satisfying
(x `div` y)*y + (x `mod` y) == x
| | quotRem :: a -> a -> (a, a) | simultaneous quot and rem
| | divMod :: a -> a -> (a, a) | simultaneous div and mod
| | toInteger :: a -> Integer | conversion to Integer
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| | Instances | |
|
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class Num a => Fractional a where |
Fractional numbers, supporting real division.
Minimal complete definition: fromRational and (recip or (/))
| | Methods | (/) :: a -> a -> a | fractional division
| | recip :: a -> a | reciprocal fraction
| | fromRational :: Rational -> 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.
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| | Instances | |
|
|
class Fractional a => Floating a where |
Trigonometric and hyperbolic functions and related functions.
Minimal complete definition:
pi, exp, log, sin, cos, sinh, cosh
asin, acos, atan, asinh, acosh and atanh
| | Methods | pi :: a | | exp :: a -> a | | log :: a -> a | | sqrt :: a -> a | | (**) :: a -> a -> a | | logBase :: a -> a -> a | | sin :: a -> a | | cos :: a -> a | | tan :: a -> a | | asin :: a -> a | | acos :: a -> a | | atan :: a -> a | | sinh :: a -> a | | cosh :: a -> a | | tanh :: a -> a | | asinh :: a -> a | | acosh :: a -> a | | atanh :: a -> a |
| | Instances | |
|
|
class (Real a, Fractional a) => RealFrac a where |
Extracting components of fractions.
Minimal complete definition: properFraction
| | Methods | properFraction :: Integral b => a -> (b, 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.
| | truncate :: Integral b => a -> b | truncate x returns the integer nearest x between zero and x
| | round :: Integral b => a -> b | round x returns the nearest integer to x
| | ceiling :: Integral b => a -> b | ceiling x returns the least integer not less than x
| | floor :: Integral b => a -> b | floor x returns the greatest integer not greater than x
|
| | Instances | |
|
|
class (RealFrac a, Floating a) => RealFloat a where |
Efficient, machine-independent access to the components of a
floating-point number.
Minimal complete definition:
all except exponent, significand, scaleFloat and atan2
| | Methods | floatRadix :: a -> Integer | a constant function, returning the radix of the representation
(often 2)
| | floatDigits :: a -> Int | a constant function, returning the number of digits of
floatRadix in the significand
| | floatRange :: a -> (Int, Int) | a constant function, returning the lowest and highest values
the exponent may assume
| | decodeFloat :: a -> (Integer, 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) <= m < b^d, where d is the value
of floatDigits x. In particular, decodeFloat 0 = (0,0).
| | encodeFloat :: Integer -> Int -> a | encodeFloat performs the inverse of decodeFloat
| | exponent :: a -> Int | the second component of decodeFloat.
| | significand :: a -> a | the first component of decodeFloat, scaled to lie in the open
interval (-1,1)
| | scaleFloat :: Int -> a -> a | multiplies a floating-point number by an integer power of the radix
| | isNaN :: a -> Bool | True if the argument is an IEEE "not-a-number" (NaN) value
| | isInfinite :: a -> Bool | True if the argument is an IEEE infinity or negative infinity
| | isDenormalized :: a -> Bool | True if the argument is too small to be represented in
normalized format
| | isNegativeZero :: a -> Bool | True if the argument is an IEEE negative zero
| | isIEEE :: a -> Bool | True if the argument is an IEEE floating point number
| | atan2 :: a -> a -> a | 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.
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| | Instances | |
|
|
Numeric functions
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|
subtract :: Num a => a -> a -> a |
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.
|
|
even :: Integral a => a -> Bool |
|
odd :: Integral a => a -> Bool |
|
gcd :: Integral a => a -> a -> a |
gcd x y is the greatest (positive) integer that divides both x
and y; for example gcd (-3) 6 = 3, gcd (-3) (-6) = 3,
gcd 0 4 = 4. gcd 0 0 raises a runtime error.
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lcm :: Integral a => a -> a -> a |
lcm x y is the smallest positive integer that both x and y divide.
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(^) :: (Num a, Integral b) => a -> b -> a |
raise a number to a non-negative integral power
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(^^) :: (Fractional a, Integral b) => a -> b -> a |
raise a number to an integral power
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fromIntegral :: (Integral a, Num b) => a -> b |
general coercion from integral types
|
|
realToFrac :: (Real a, Fractional b) => a -> b |
general coercion to fractional types
|
|
Monads and functors
|
|
class Monad m where |
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.
Minimal complete definition: >>= and return.
Instances of Monad should satisfy the following laws:
return a >>= k == k a
m >>= return == m
m >>= (\x -> k x >>= h) == (m >>= k) >>= h
Instances of both Monad and Functor should additionally satisfy the law:
fmap f xs == xs >>= return . f
The instances of Monad for lists, Maybe and IO
defined in the Prelude satisfy these laws.
| | Methods | (>>=) :: forall a b . m a -> (a -> m b) -> m b | Sequentially compose two actions, passing any value produced
by the first as an argument to the second.
| | (>>) :: forall a b . m 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.
| | return :: a -> m a | Inject a value into the monadic type.
| | fail :: String -> m a | Fail with a message. This operation is not part of the
mathematical definition of a monad, but is invoked on pattern-match
failure in a do expression.
|
| | Instances | |
|
|
class Functor f where |
The Functor class is used for types that can be mapped over.
Instances of Functor should satisfy the following laws:
fmap id == id
fmap (f . g) == fmap f . fmap g
The instances of Functor for lists, Maybe and IO
defined in the Prelude satisfy these laws.
| | Methods | fmap :: (a -> b) -> f a -> f b |
| | Instances | |
|
|
mapM :: Monad m => (a -> m b) -> [a] -> m [b] |
mapM f is equivalent to sequence . map f.
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mapM_ :: Monad m => (a -> m b) -> [a] -> m () |
mapM_ f is equivalent to sequence_ . map f.
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sequence :: Monad m => [m a] -> m [a] |
Evaluate each action in the sequence from left to right,
and collect the results.
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sequence_ :: Monad m => [m a] -> m () |
Evaluate each action in the sequence from left to right,
and ignore the results.
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(=<<) :: Monad m => (a -> m b) -> m a -> m b |
Same as >>=, but with the arguments interchanged.
|
|
Miscellaneous functions
|
|
id :: a -> a |
Identity function.
|
|
const :: a -> b -> a |
Constant function.
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|
(.) :: (b -> c) -> (a -> b) -> a -> c |
Function composition.
|
|
flip :: (a -> b -> c) -> b -> a -> c |
flip f takes its (first) two arguments in the reverse order of f.
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|
($) :: (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 ($) fs xs.
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|
until :: (a -> Bool) -> (a -> a) -> a -> a |
until p f yields the result of applying f until p holds.
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|
asTypeOf :: a -> a -> a |
asTypeOf is a type-restricted version of const. It is usually
used as an infix operator, and its typing forces its first argument
(which is usually overloaded) to have the same type as the second.
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|
error :: String -> a |
error stops execution and displays an error message.
|
|
undefined :: a |
A special case of error.
It is expected that compilers will recognize this and insert error
messages which are more appropriate to the context in which undefined
appears.
|
|
seq :: a -> b -> b |
The value of seq a b is bottom if a is bottom, and otherwise
equal to b. seq is usually introduced to improve performance by
avoiding unneeded laziness.
|
|
($!) :: (a -> b) -> a -> b |
Strict (call-by-value) application, defined in terms of seq.
|
|
List operations
|
|
map :: (a -> b) -> [a] -> [b] |
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, ...]
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|
(++) :: [a] -> [a] -> [a] |
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.
|
|
filter :: (a -> Bool) -> [a] -> [a] |
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]
|
|
head :: [a] -> a |
Extract the first element of a list, which must be non-empty.
|
|
last :: [a] -> a |
Extract the last element of a list, which must be finite and non-empty.
|
|
tail :: [a] -> [a] |
Extract the elements after the head of a list, which must be non-empty.
|
|
init :: [a] -> [a] |
Return all the elements of a list except the last one.
The list must be finite and non-empty.
|
|
null :: [a] -> Bool |
Test whether a list is empty.
|
|
length :: [a] -> Int |
length returns the length of a finite list as an Int.
It is an instance of the more general genericLength,
the result type of which may be any kind of number.
|
|
(!!) :: [a] -> Int -> a |
List index (subscript) operator, starting from 0.
It is an instance of the more general genericIndex,
which takes an index of any integral type.
|
|
reverse :: [a] -> [a] |
reverse xs returns the elements of xs in reverse order.
xs must be finite.
|
|
Reducing lists (folds)
|
|
foldl :: (a -> b -> a) -> a -> [b] -> a |
foldl, 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
The list must be finite.
|
|
foldl1 :: (a -> a -> a) -> [a] -> a |
foldl1 is a variant of foldl that has no starting value argument,
and thus must be applied to non-empty lists.
|
|
foldr :: (a -> b -> b) -> b -> [a] -> b |
foldr, 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)...)
|
|
foldr1 :: (a -> a -> a) -> [a] -> a |
foldr1 is a variant of foldr that has no starting value argument,
and thus must be applied to non-empty lists.
|
|
Special folds
|
|
and :: [Bool] -> Bool |
and returns the conjunction of a Boolean list. For the result to be
True, the list must be finite; False, however, results from a False
value at a finite index of a finite or infinite list.
|
|
or :: [Bool] -> Bool |
or returns the disjunction of a Boolean list. For the result to be
False, the list must be finite; True, however, results from a True
value at a finite index of a finite or infinite list.
|
|
any :: (a -> Bool) -> [a] -> Bool |
Applied to a predicate and a list, any determines if any element
of the list satisfies the predicate.
|
|
all :: (a -> Bool) -> [a] -> Bool |
Applied to a predicate and a list, all determines if all elements
of the list satisfy the predicate.
|
|
sum :: Num a => [a] -> a |
The sum function computes the sum of a finite list of numbers.
|
|
product :: Num a => [a] -> a |
The product function computes the product of a finite list of numbers.
|
|
concat :: [[a]] -> [a] |
Concatenate a list of lists.
|
|
concatMap :: (a -> [b]) -> [a] -> [b] |
Map a function over a list and concatenate the results.
|
|
maximum :: Ord a => [a] -> a |
maximum returns the maximum value from a list,
which must be non-empty, finite, and of an ordered type.
It is a special case of maximumBy, which allows the
programmer to supply their own comparison function.
|
|
minimum :: Ord a => [a] -> a |
minimum returns the minimum value from a list,
which must be non-empty, finite, and of an ordered type.
It is a special case of minimumBy, which allows the
programmer to supply their own comparison function.
|
|
Building lists
|
|
Scans
|
|
scanl :: (a -> b -> a) -> a -> [b] -> [a] |
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.
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|
scanl1 :: (a -> a -> a) -> [a] -> [a] |
scanl1 is a variant of scanl that has no starting value argument:
scanl1 f [x1, x2, ...] == [x1, x1 `f` x2, ...]
|
|
scanr :: (a -> b -> b) -> b -> [a] -> [b] |
scanr is the right-to-left dual of scanl.
Note that
head (scanr f z xs) == foldr f z xs.
|
|
scanr1 :: (a -> a -> a) -> [a] -> [a] |
scanr1 is a variant of scanr that has no starting value argument.
|
|
Infinite lists
|
|
iterate :: (a -> a) -> 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), ...]
|
|
repeat :: a -> [a] |
repeat x is an infinite list, with x the value of every element.
|
|
replicate :: Int -> 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.
|
|
cycle :: [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.
|
|
Sublists
|
|
take :: 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.
It is an instance of the more general genericTake,
in which n may be of any integral type.
|
|
drop :: Int -> [a] -> [a] |
drop n xs returns the suffix of xs
after the first n elements, or [] if n > length xs.
It is an instance of the more general genericDrop,
in which n may be of any integral type.
|
|
splitAt :: Int -> [a] -> ([a], [a]) |
splitAt n xs is equivalent to (take n xs, drop n xs).
It is an instance of the more general genericSplitAt,
in which n may be of any integral type.
|
|
takeWhile :: (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.
|
|
dropWhile :: (a -> Bool) -> [a] -> [a] |
dropWhile p xs returns the suffix remaining after takeWhile p xs.
|
|
span :: (a -> Bool) -> [a] -> ([a], [a]) |
span p xs is equivalent to (takeWhile p xs, dropWhile p xs)
|
|
break :: (a -> Bool) -> [a] -> ([a], [a]) |
break p is equivalent to span (not . p).
|
|
Searching lists
|
|
elem :: Eq a => a -> [a] -> Bool |
elem is the list membership predicate, usually written in infix form,
e.g., x elem xs.
|
|
notElem :: Eq a => a -> [a] -> Bool |
notElem is the negation of elem.
|
|
lookup :: Eq a => a -> [(a, b)] -> Maybe b |
lookup key assocs looks up a key in an association list.
|
|
Zipping and unzipping lists
|
|
zip :: [a] -> [b] -> [(a, b)] |
zip takes two lists and returns a list of corresponding pairs.
If one input list is short, excess elements of the longer list are
discarded.
|
|
zip3 :: [a] -> [b] -> [c] -> [(a, b, c)] |
zip3 takes three lists and returns a list of triples, analogous to
zip.
|
|
zipWith :: (a -> b -> c) -> [a] -> [b] -> [c] |
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.
|
|
zipWith3 :: (a -> b -> c -> d) -> [a] -> [b] -> [c] -> [d] |
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.
|
|
unzip :: [(a, b)] -> ([a], [b]) |
unzip transforms a list of pairs into a list of first components
and a list of second components.
|
|
unzip3 :: [(a, b, c)] -> ([a], [b], [c]) |
The unzip3 function takes a list of triples and returns three
lists, analogous to unzip.
|
|
Functions on strings
|
|
lines :: String -> [String] |
lines breaks a string up into a list of strings at newline
characters. The resulting strings do not contain newlines.
|
|
words :: String -> [String] |
words breaks a string up into a list of words, which were delimited
by white space.
|
|
unlines :: [String] -> String |
unlines is an inverse operation to lines.
It joins lines, after appending a terminating newline to each.
|
|
unwords :: [String] -> String |
unwords is an inverse operation to words.
It joins words with separating spaces.
|
|
Converting to and from String
|
|
Converting to String
|
|
type ShowS = String -> String |
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.
|
|
class Show a where |
Conversion of values to readable Strings.
Minimal complete definition: showsPrec or show.
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)".
| | Methods | showsPrec | :: Int | the operator precedence of the enclosing
context (a number from 0 to 11).
Function application has precedence 10.
| -> a | the value to be converted to a String
| -> ShowS | | 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.
|
| | show :: a -> String | A specialised variant of showsPrec, using precedence context
zero, and returning an ordinary String.
| | showList :: [a] -> ShowS | 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.
|
| | Instances | Show All | Show Any | Show ArithException | Show ArrayException | Show AsyncException | Show Bool | Show BufferMode | Show CCc | Show CChar | Show CClock | Show CDev | Show CDouble | Show CFloat | Show CGid | Show CIno | Show CInt | Show CIntMax | Show CIntPtr | Show CLDouble | Show CLLong | Show CLong | Show CMode | Show CNlink | Show COff | Show CPid | Show CPtrdiff | Show CRLim | Show CSChar | Show CShort | Show CSigAtomic | Show CSize | Show CSpeed | Show CSsize | Show CTcflag | Show CTime | Show CUChar | Show CUInt | Show CUIntMax | Show CUIntPtr | Show CULLong | Show CULong | Show CUShort | Show CUid | Show CWchar | Show CalendarTime | Show Char | Show ClockTime | Show Constr | Show ConstrRep | Show DataRep | Show DataType | Show Day | Show Doc | Show Double | Show Dynamic | Show Exception | Show ExitCode | Show Fd | Show Fixity | Show Float | Show GeneralCategory | Show Handle | Show HandlePosn | Show HandleType | Show HashData | Show IOErrorType | Show IOException | Show IOMode | Show Int | Show Int16 | Show Int32 | Show Int64 | Show Int8 | Show IntPtr | Show IntSet | Show Integer | Show Lexeme | Show Month | Show Ordering | Show PackedString | Show Permissions | Show SeekMode | Show StdGen | Show ThreadId | Show TimeDiff | Show TimeLocale | Show TyCon | Show TypeRep | Show Version | Show Word | Show Word16 | Show Word32 | Show Word64 | Show Word8 | Show WordPtr | Show () | (Show a, Show b) => Show (a, b) | (Show a, Show b, Show c) => Show (a, b, c) | (Show a, Show b, Show c, Show d) => Show (a, b, c, d) | (Show a, Show b, Show c, Show d, Show e) => Show (a, b, c, d, e) | (Show a, Show b, Show c, Show d, Show e, Show f) => Show (a, b, c, d, e, f) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g) => Show (a, b, c, d, e, f, g) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h) => Show (a, b, c, d, e, f, g, h) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i) => Show (a, b, c, d, e, f, g, h, i) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i, Show j) => Show (a, b, c, d, e, f, g, h, i, j) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i, Show j, Show k) => Show (a, b, c, d, e, f, g, h, i, j, k) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i, Show j, Show k, Show l) => Show (a, b, c, d, e, f, g, h, i, j, k, l) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i, Show j, Show k, Show l, Show m) => Show (a, b, c, d, e, f, g, h, i, j, k, l, m) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i, Show j, Show k, Show l, Show m, Show n) => Show (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | (Show a, Show b, Show c, Show d, Show e, Show f, Show g, Show h, Show i, Show j, Show k, Show l, Show m, Show n, Show o) => Show (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | Show (a -> b) | (RealFloat a, Show a) => Show (Complex a) | HasResolution a => Show (Fixed a) | Show (ForeignPtr a) | Show (FunPtr a) | Show a => Show (IntMap a) | Show a => Show (Maybe a) | Show a => Show (Product a) | Show (Ptr a) | Integral a => Show (Ratio a) | Show a => Show (Seq a) | Show a => Show (Set a) | Show a => Show (Sum a) | Show a => Show (Tree a) | Show a => Show (ViewL a) | Show a => Show (ViewR a) | Show a => Show [a] | (Ix a, Show a, Show b) => Show (Array a b) | (Ix ix, Show ix, Show e) => Show (DiffArray ix e) | (Ix ix, Show ix) => Show (DiffUArray ix Char) | (Ix ix, Show ix) => Show (DiffUArray ix Double) | (Ix ix, Show ix) => Show (DiffUArray ix Float) | (Ix ix, Show ix) => Show (DiffUArray ix Int) | (Ix ix, Show ix) => Show (DiffUArray ix Int16) | (Ix ix, Show ix) => Show (DiffUArray ix Int32) | (Ix ix, Show ix) => Show (DiffUArray ix Int64) | (Ix ix, Show ix) => Show (DiffUArray ix Int8) | (Ix ix, Show ix) => Show (DiffUArray ix Word) | (Ix ix, Show ix) => Show (DiffUArray ix Word16) | (Ix ix, Show ix) => Show (DiffUArray ix Word32) | (Ix ix, Show ix) => Show (DiffUArray ix Word64) | (Ix ix, Show ix) => Show (DiffUArray ix Word8) | (Show a, Show b) => Show (Either a b) | (Show k, Show a) => Show (Map k a) | Show (ST s a) | (Ix ix, Show ix, Show e, IArray UArray e) => Show (UArray ix e) |
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shows :: Show a => a -> ShowS |
equivalent to showsPrec with a precedence of 0.
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showChar :: Char -> ShowS |
utility function converting a Char to a show function that
simply prepends the character unchanged.
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showString :: String -> ShowS |
utility function converting a String to a show function that
simply prepends the string unchanged.
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showParen :: Bool -> ShowS -> ShowS |
utility function that surrounds the inner show function with
parentheses when the Bool parameter is True.
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Converting from String
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type ReadS a = String -> [(a, String)] |
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).
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class Read a where |
Parsing of Strings, producing values.
Minimal complete definition: readsPrec (or, for GHC only, readPrec)
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 98 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
| | Methods | readsPrec | :: Int | the operator precedence of the enclosing
context (a number from 0 to 11).
Function application has precedence 10.
| -> ReadS 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.
|
| | readList :: 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.
|
| | Instances | Read All | Read Any | Read Bool | Read BufferMode | Read CCc | Read CChar | Read CClock | Read CDev | Read CDouble | Read CFloat | Read CGid | Read CIno | Read CInt | Read CIntMax | Read CIntPtr | Read CLDouble | Read CLLong | Read CLong | Read CMode | Read CNlink | Read COff | Read CPid | Read CPtrdiff | Read CRLim | Read CSChar | Read CShort | Read CSigAtomic | Read CSize | Read CSpeed | Read CSsize | Read CTcflag | Read CTime | Read CUChar | Read CUInt | Read CUIntMax | Read CUIntPtr | Read CULLong | Read CULong | Read CUShort | Read CUid | Read CWchar | Read CalendarTime | Read Char | Read Day | Read Double | Read ExitCode | Read Fd | Read Float | Read GeneralCategory | Read IOMode | Read Int | Read Int16 | Read Int32 | Read Int64 | Read Int8 | Read IntPtr | Read IntSet | Read Integer | Read Lexeme | Read Month | Read Ordering | Read Permissions | Read SeekMode | Read StdGen | Read TimeDiff | Read Version | Read Word | Read Word16 | Read Word32 | Read Word64 | Read Word8 | Read WordPtr | Read () | (Read a, Read b) => Read (a, b) | (Read a, Read b, Read c) => Read (a, b, c) | (Read a, Read b, Read c, Read d) => Read (a, b, c, d) | (Read a, Read b, Read c, Read d, Read e) => Read (a, b, c, d, e) | (Read a, Read b, Read c, Read d, Read e, Read f) => Read (a, b, c, d, e, f) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g) => Read (a, b, c, d, e, f, g) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h) => Read (a, b, c, d, e, f, g, h) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i) => Read (a, b, c, d, e, f, g, h, i) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i, Read j) => Read (a, b, c, d, e, f, g, h, i, j) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i, Read j, Read k) => Read (a, b, c, d, e, f, g, h, i, j, k) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i, Read j, Read k, Read l) => Read (a, b, c, d, e, f, g, h, i, j, k, l) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i, Read j, Read k, Read l, Read m) => Read (a, b, c, d, e, f, g, h, i, j, k, l, m) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i, Read j, Read k, Read l, Read m, Read n) => Read (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | (Read a, Read b, Read c, Read d, Read e, Read f, Read g, Read h, Read i, Read j, Read k, Read l, Read m, Read n, Read o) => Read (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | (RealFloat a, Read a) => Read (Complex a) | Read e => Read (IntMap e) | Read a => Read (Maybe a) | Read a => Read (Product a) | (Integral a, Read a) => Read (Ratio a) | Read a => Read (Seq a) | (Read a, Ord a) => Read (Set a) | Read a => Read (Sum a) | Read a => Read (Tree a) | Read a => Read (ViewL a) | Read a => Read (ViewR a) | Read a => Read [a] | (Ix a, Read a, Read b) => Read (Array a b) | (Read a, Read b) => Read (Either a b) | (Ord k, Read k, Read e) => Read (Map k e) |
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reads :: Read a => ReadS a |
equivalent to readsPrec with a precedence of 0.
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readParen :: Bool -> ReadS a -> ReadS a |
readParen True p parses what p parses, but surrounded with
parentheses.
readParen False p parses what p parses, but optionally
surrounded with parentheses.
|
|
read :: Read a => String -> a |
The read function reads input from a string, which must be
completely consumed by the input process.
|
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lex :: ReadS String |
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
|
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Basic Input and output
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|
data IO a |
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.
| Instances | |
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Simple I/O operations
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Output functions
|
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putChar :: Char -> IO () |
Write a character to the standard output device
(same as hPutChar stdout).
|
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putStr :: String -> IO () |
Write a string to the standard output device
(same as hPutStr stdout).
|
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putStrLn :: String -> IO () |
The same as putStr, but adds a newline character.
|
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print :: Show a => a -> IO () |
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]])
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Input functions
|
|
getChar :: IO Char |
Read a character from the standard input device
(same as hGetChar stdin).
|
|
getLine :: IO String |
Read a line from the standard input device
(same as hGetLine stdin).
|
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getContents :: IO String |
The getContents operation returns all user input as a single string,
which is read lazily as it is needed
(same as hGetContents stdin).
|
|
interact :: (String -> String) -> IO () |
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.
|
|
Files
|
|
type FilePath = String |
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.
|
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readFile :: FilePath -> IO String |
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.
|
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writeFile :: FilePath -> String -> IO () |
The computation writeFile file str function writes the string str,
to the file file.
|
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appendFile :: FilePath -> String -> IO () |
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]])
|
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readIO :: Read a => String -> IO a |
The readIO function is similar to read except that it signals
parse failure to the IO monad instead of terminating the program.
|
|
readLn :: Read a => IO a |
The readLn function combines getLine and readIO.
|
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Exception handling in the I/O monad
|
|
type IOError = IOException |
The Haskell 98 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 98, this is an opaque type.
|
|
ioError :: IOError -> IO a |
Raise an IOError in the IO monad.
|
|
userError :: String -> IOError |
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)
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catch :: IO a -> (IOError -> IO a) -> IO a |
The catch function establishes a handler that receives any IOError
raised in the action protected by catch. An IOError is caught by
the most recent handler established by catch. These handlers are
not selective: all IOErrors are caught. Exception propagation
must be explicitly provided in a handler by re-raising any unwanted
exceptions. For example, in
f = catch g (\e -> if IO.isEOFError e then return [] else ioError e)
the function f returns [] when an end-of-file exception
(cf. isEOFError) occurs in g; otherwise, the
exception is propagated to the next outer handler.
When an exception propagates outside the main program, the Haskell
system prints the associated IOError value and exits the program.
Non-I/O exceptions are not caught by this variant; to catch all
exceptions, use catch from Control.Exception.
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Produced by Haddock version 0.8 |