{-# LANGUAGE CPP #-} -- We cannot actually specify all the language pragmas, see ghc ticket # -- If we could, these are what they would be: {- LANGUAGE MagicHash, UnboxedTuples -} {-# OPTIONS_HADDOCK prune #-} -- | -- Module : Data.ByteString.Char8 -- Copyright : (c) Don Stewart 2006-2008 -- License : BSD-style -- -- Maintainer : dons@cse.unsw.edu.au -- Stability : experimental -- Portability : portable -- -- Manipulate 'ByteString's using 'Char' operations. All Chars will be -- truncated to 8 bits. It can be expected that these functions will run -- at identical speeds to their 'Word8' equivalents in "Data.ByteString". -- -- More specifically these byte strings are taken to be in the -- subset of Unicode covered by code points 0-255. This covers -- Unicode Basic Latin, Latin-1 Supplement and C0+C1 Controls. -- -- See: -- -- * <http://www.unicode.org/charts/> -- -- * <http://www.unicode.org/charts/PDF/U0000.pdf> -- -- * <http://www.unicode.org/charts/PDF/U0080.pdf> -- -- This module is intended to be imported @qualified@, to avoid name -- clashes with "Prelude" functions. eg. -- -- > import qualified Data.ByteString.Char8 as B -- -- The Char8 interface to bytestrings provides an instance of IsString -- for the ByteString type, enabling you to use string literals, and -- have them implicitly packed to ByteStrings. Use -XOverloadedStrings -- to enable this. -- module Data.ByteString.Char8 ( -- * The @ByteString@ type ByteString, -- abstract, instances: Eq, Ord, Show, Read, Data, Typeable, Monoid -- * Introducing and eliminating 'ByteString's empty, -- :: ByteString singleton, -- :: Char -> ByteString pack, -- :: String -> ByteString unpack, -- :: ByteString -> String -- * Basic interface cons, -- :: Char -> ByteString -> ByteString snoc, -- :: ByteString -> Char -> ByteString append, -- :: ByteString -> ByteString -> ByteString head, -- :: ByteString -> Char uncons, -- :: ByteString -> Maybe (Char, ByteString) last, -- :: ByteString -> Char tail, -- :: ByteString -> ByteString init, -- :: ByteString -> ByteString null, -- :: ByteString -> Bool length, -- :: ByteString -> Int -- * Transformating ByteStrings map, -- :: (Char -> Char) -> ByteString -> ByteString reverse, -- :: ByteString -> ByteString intersperse, -- :: Char -> ByteString -> ByteString intercalate, -- :: ByteString -> [ByteString] -> ByteString transpose, -- :: [ByteString] -> [ByteString] -- * Reducing 'ByteString's (folds) foldl, -- :: (a -> Char -> a) -> a -> ByteString -> a foldl', -- :: (a -> Char -> a) -> a -> ByteString -> a foldl1, -- :: (Char -> Char -> Char) -> ByteString -> Char foldl1', -- :: (Char -> Char -> Char) -> ByteString -> Char foldr, -- :: (Char -> a -> a) -> a -> ByteString -> a foldr', -- :: (Char -> a -> a) -> a -> ByteString -> a foldr1, -- :: (Char -> Char -> Char) -> ByteString -> Char foldr1', -- :: (Char -> Char -> Char) -> ByteString -> Char -- ** Special folds concat, -- :: [ByteString] -> ByteString concatMap, -- :: (Char -> ByteString) -> ByteString -> ByteString any, -- :: (Char -> Bool) -> ByteString -> Bool all, -- :: (Char -> Bool) -> ByteString -> Bool maximum, -- :: ByteString -> Char minimum, -- :: ByteString -> Char -- * Building ByteStrings -- ** Scans scanl, -- :: (Char -> Char -> Char) -> Char -> ByteString -> ByteString scanl1, -- :: (Char -> Char -> Char) -> ByteString -> ByteString scanr, -- :: (Char -> Char -> Char) -> Char -> ByteString -> ByteString scanr1, -- :: (Char -> Char -> Char) -> ByteString -> ByteString -- ** Accumulating maps mapAccumL, -- :: (acc -> Char -> (acc, Char)) -> acc -> ByteString -> (acc, ByteString) mapAccumR, -- :: (acc -> Char -> (acc, Char)) -> acc -> ByteString -> (acc, ByteString) -- ** Generating and unfolding ByteStrings replicate, -- :: Int -> Char -> ByteString unfoldr, -- :: (a -> Maybe (Char, a)) -> a -> ByteString unfoldrN, -- :: Int -> (a -> Maybe (Char, a)) -> a -> (ByteString, Maybe a) -- * Substrings -- ** Breaking strings take, -- :: Int -> ByteString -> ByteString drop, -- :: Int -> ByteString -> ByteString splitAt, -- :: Int -> ByteString -> (ByteString, ByteString) takeWhile, -- :: (Char -> Bool) -> ByteString -> ByteString dropWhile, -- :: (Char -> Bool) -> ByteString -> ByteString span, -- :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) spanEnd, -- :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) break, -- :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) breakEnd, -- :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) group, -- :: ByteString -> [ByteString] groupBy, -- :: (Char -> Char -> Bool) -> ByteString -> [ByteString] inits, -- :: ByteString -> [ByteString] tails, -- :: ByteString -> [ByteString] -- ** Breaking into many substrings split, -- :: Char -> ByteString -> [ByteString] splitWith, -- :: (Char -> Bool) -> ByteString -> [ByteString] -- ** Breaking into lines and words lines, -- :: ByteString -> [ByteString] words, -- :: ByteString -> [ByteString] unlines, -- :: [ByteString] -> ByteString unwords, -- :: ByteString -> [ByteString] -- * Predicates isPrefixOf, -- :: ByteString -> ByteString -> Bool isSuffixOf, -- :: ByteString -> ByteString -> Bool isInfixOf, -- :: ByteString -> ByteString -> Bool -- ** Search for arbitrary substrings breakSubstring, -- :: ByteString -> ByteString -> (ByteString,ByteString) findSubstring, -- :: ByteString -> ByteString -> Maybe Int findSubstrings, -- :: ByteString -> ByteString -> [Int] -- * Searching ByteStrings -- ** Searching by equality elem, -- :: Char -> ByteString -> Bool notElem, -- :: Char -> ByteString -> Bool -- ** Searching with a predicate find, -- :: (Char -> Bool) -> ByteString -> Maybe Char filter, -- :: (Char -> Bool) -> ByteString -> ByteString -- partition -- :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) -- * Indexing ByteStrings index, -- :: ByteString -> Int -> Char elemIndex, -- :: Char -> ByteString -> Maybe Int elemIndices, -- :: Char -> ByteString -> [Int] elemIndexEnd, -- :: Char -> ByteString -> Maybe Int findIndex, -- :: (Char -> Bool) -> ByteString -> Maybe Int findIndices, -- :: (Char -> Bool) -> ByteString -> [Int] count, -- :: Char -> ByteString -> Int -- * Zipping and unzipping ByteStrings zip, -- :: ByteString -> ByteString -> [(Char,Char)] zipWith, -- :: (Char -> Char -> c) -> ByteString -> ByteString -> [c] unzip, -- :: [(Char,Char)] -> (ByteString,ByteString) -- * Ordered ByteStrings sort, -- :: ByteString -> ByteString -- * Reading from ByteStrings readInt, -- :: ByteString -> Maybe (Int, ByteString) readInteger, -- :: ByteString -> Maybe (Integer, ByteString) -- * Low level CString conversions -- ** Copying ByteStrings copy, -- :: ByteString -> ByteString -- ** Packing CStrings and pointers packCString, -- :: CString -> IO ByteString packCStringLen, -- :: CStringLen -> IO ByteString -- ** Using ByteStrings as CStrings useAsCString, -- :: ByteString -> (CString -> IO a) -> IO a useAsCStringLen, -- :: ByteString -> (CStringLen -> IO a) -> IO a -- * I\/O with 'ByteString's -- ** Standard input and output getLine, -- :: IO ByteString getContents, -- :: IO ByteString putStr, -- :: ByteString -> IO () putStrLn, -- :: ByteString -> IO () interact, -- :: (ByteString -> ByteString) -> IO () -- ** Files readFile, -- :: FilePath -> IO ByteString writeFile, -- :: FilePath -> ByteString -> IO () appendFile, -- :: FilePath -> ByteString -> IO () -- mmapFile, -- :: FilePath -> IO ByteString -- ** I\/O with Handles hGetLine, -- :: Handle -> IO ByteString hGetContents, -- :: Handle -> IO ByteString hGet, -- :: Handle -> Int -> IO ByteString hGetNonBlocking, -- :: Handle -> Int -> IO ByteString hPut, -- :: Handle -> ByteString -> IO () hPutStr, -- :: Handle -> ByteString -> IO () hPutStrLn, -- :: Handle -> ByteString -> IO () ) where import qualified Prelude as P import Prelude hiding (reverse,head,tail,last,init,null ,length,map,lines,foldl,foldr,unlines ,concat,any,take,drop,splitAt,takeWhile ,dropWhile,span,break,elem,filter,unwords ,words,maximum,minimum,all,concatMap ,scanl,scanl1,scanr,scanr1 ,appendFile,readFile,writeFile ,foldl1,foldr1,replicate ,getContents,getLine,putStr,putStrLn,interact ,zip,zipWith,unzip,notElem) import qualified Data.ByteString as B import qualified Data.ByteString.Internal as B import qualified Data.ByteString.Unsafe as B -- Listy functions transparently exported import Data.ByteString (empty,null,length,tail,init,append ,inits,tails,reverse,transpose ,concat,take,drop,splitAt,intercalate ,sort,isPrefixOf,isSuffixOf,isInfixOf ,findSubstring,findSubstrings,breakSubstring,copy,group ,getLine, getContents, putStr, putStrLn, interact ,hGetContents, hGet, hPut, hPutStr, hPutStrLn ,hGetLine, hGetNonBlocking ,packCString,packCStringLen ,useAsCString,useAsCStringLen ) import Data.ByteString.Internal (ByteString(PS), c2w, w2c, isSpaceWord8 ,inlinePerformIO) import Data.Char ( isSpace ) import qualified Data.List as List (intersperse) import System.IO (openFile,hClose,hFileSize,IOMode(..)) #ifndef __NHC__ import Control.Exception (bracket) #else import IO (bracket) #endif import Foreign #if defined(__GLASGOW_HASKELL__) import GHC.Base (Char(..),unpackCString#,ord#,int2Word#) #if __GLASGOW_HASKELL__ >= 611 import GHC.IO (stToIO) #else import GHC.IOBase (stToIO) #endif import GHC.Prim (Addr#,writeWord8OffAddr#,plusAddr#) import GHC.Ptr (Ptr(..)) import GHC.ST (ST(..)) #endif #if __GLASGOW_HASKELL__ >= 608 import Data.String #endif #define STRICT1(f) f a | a `seq` False = undefined #define STRICT2(f) f a b | a `seq` b `seq` False = undefined #define STRICT3(f) f a b c | a `seq` b `seq` c `seq` False = undefined #define STRICT4(f) f a b c d | a `seq` b `seq` c `seq` d `seq` False = undefined ------------------------------------------------------------------------ -- | /O(1)/ Convert a 'Char' into a 'ByteString' singleton :: Char -> ByteString singleton = B.singleton . c2w {-# INLINE singleton #-} #if __GLASGOW_HASKELL__ >= 608 instance IsString ByteString where fromString = pack {-# INLINE fromString #-} #endif -- | /O(n)/ Convert a 'String' into a 'ByteString' -- -- For applications with large numbers of string literals, pack can be a -- bottleneck. pack :: String -> ByteString #if !defined(__GLASGOW_HASKELL__) pack str = B.unsafeCreate (P.length str) $ \p -> go p str where go _ [] = return () go p (x:xs) = poke p (c2w x) >> go (p `plusPtr` 1) xs #else /* hack away */ pack str = B.unsafeCreate (P.length str) $ \(Ptr p) -> stToIO (go p str) where go :: Addr# -> [Char] -> ST a () go _ [] = return () go p (C# c:cs) = writeByte p (int2Word# (ord# c)) >> go (p `plusAddr#` 1#) cs writeByte p c = ST $ \s# -> case writeWord8OffAddr# p 0# c s# of s2# -> (# s2#, () #) {-# INLINE writeByte #-} {-# INLINE [1] pack #-} {-# RULES "ByteString pack/packAddress" forall s . pack (unpackCString# s) = inlinePerformIO (B.unsafePackAddress s) #-} #endif -- | /O(n)/ Converts a 'ByteString' to a 'String'. unpack :: ByteString -> [Char] unpack = P.map w2c . B.unpack {-# INLINE unpack #-} -- | /O(n)/ 'cons' is analogous to (:) for lists, but of different -- complexity, as it requires a memcpy. cons :: Char -> ByteString -> ByteString cons = B.cons . c2w {-# INLINE cons #-} -- | /O(n)/ Append a Char to the end of a 'ByteString'. Similar to -- 'cons', this function performs a memcpy. snoc :: ByteString -> Char -> ByteString snoc p = B.snoc p . c2w {-# INLINE snoc #-} -- | /O(1)/ Extract the head and tail of a ByteString, returning Nothing -- if it is empty. uncons :: ByteString -> Maybe (Char, ByteString) uncons bs = case B.uncons bs of Nothing -> Nothing Just (w, bs') -> Just (w2c w, bs') {-# INLINE uncons #-} -- | /O(1)/ Extract the first element of a ByteString, which must be non-empty. head :: ByteString -> Char head = w2c . B.head {-# INLINE head #-} -- | /O(1)/ Extract the last element of a packed string, which must be non-empty. last :: ByteString -> Char last = w2c . B.last {-# INLINE last #-} -- | /O(n)/ 'map' @f xs@ is the ByteString obtained by applying @f@ to each element of @xs@ map :: (Char -> Char) -> ByteString -> ByteString map f = B.map (c2w . f . w2c) {-# INLINE map #-} -- | /O(n)/ The 'intersperse' function takes a Char and a 'ByteString' -- and \`intersperses\' that Char between the elements of the -- 'ByteString'. It is analogous to the intersperse function on Lists. intersperse :: Char -> ByteString -> ByteString intersperse = B.intersperse . c2w {-# INLINE intersperse #-} -- | 'foldl', applied to a binary operator, a starting value (typically -- the left-identity of the operator), and a ByteString, reduces the -- ByteString using the binary operator, from left to right. foldl :: (a -> Char -> a) -> a -> ByteString -> a foldl f = B.foldl (\a c -> f a (w2c c)) {-# INLINE foldl #-} -- | 'foldl\'' is like foldl, but strict in the accumulator. foldl' :: (a -> Char -> a) -> a -> ByteString -> a foldl' f = B.foldl' (\a c -> f a (w2c c)) {-# INLINE foldl' #-} -- | 'foldr', applied to a binary operator, a starting value -- (typically the right-identity of the operator), and a packed string, -- reduces the packed string using the binary operator, from right to left. foldr :: (Char -> a -> a) -> a -> ByteString -> a foldr f = B.foldr (\c a -> f (w2c c) a) {-# INLINE foldr #-} -- | 'foldr\'' is a strict variant of foldr foldr' :: (Char -> a -> a) -> a -> ByteString -> a foldr' f = B.foldr' (\c a -> f (w2c c) a) {-# INLINE foldr' #-} -- | 'foldl1' is a variant of 'foldl' that has no starting value -- argument, and thus must be applied to non-empty 'ByteStrings'. foldl1 :: (Char -> Char -> Char) -> ByteString -> Char foldl1 f ps = w2c (B.foldl1 (\x y -> c2w (f (w2c x) (w2c y))) ps) {-# INLINE foldl1 #-} -- | A strict version of 'foldl1' foldl1' :: (Char -> Char -> Char) -> ByteString -> Char foldl1' f ps = w2c (B.foldl1' (\x y -> c2w (f (w2c x) (w2c y))) ps) {-# INLINE foldl1' #-} -- | 'foldr1' is a variant of 'foldr' that has no starting value argument, -- and thus must be applied to non-empty 'ByteString's foldr1 :: (Char -> Char -> Char) -> ByteString -> Char foldr1 f ps = w2c (B.foldr1 (\x y -> c2w (f (w2c x) (w2c y))) ps) {-# INLINE foldr1 #-} -- | A strict variant of foldr1 foldr1' :: (Char -> Char -> Char) -> ByteString -> Char foldr1' f ps = w2c (B.foldr1' (\x y -> c2w (f (w2c x) (w2c y))) ps) {-# INLINE foldr1' #-} -- | Map a function over a 'ByteString' and concatenate the results concatMap :: (Char -> ByteString) -> ByteString -> ByteString concatMap f = B.concatMap (f . w2c) {-# INLINE concatMap #-} -- | Applied to a predicate and a ByteString, 'any' determines if -- any element of the 'ByteString' satisfies the predicate. any :: (Char -> Bool) -> ByteString -> Bool any f = B.any (f . w2c) {-# INLINE any #-} -- | Applied to a predicate and a 'ByteString', 'all' determines if -- all elements of the 'ByteString' satisfy the predicate. all :: (Char -> Bool) -> ByteString -> Bool all f = B.all (f . w2c) {-# INLINE all #-} -- | 'maximum' returns the maximum value from a 'ByteString' maximum :: ByteString -> Char maximum = w2c . B.maximum {-# INLINE maximum #-} -- | 'minimum' returns the minimum value from a 'ByteString' minimum :: ByteString -> Char minimum = w2c . B.minimum {-# INLINE minimum #-} -- | The 'mapAccumL' function behaves like a combination of 'map' and -- 'foldl'; it applies a function to each element of a ByteString, -- passing an accumulating parameter from left to right, and returning a -- final value of this accumulator together with the new list. mapAccumL :: (acc -> Char -> (acc, Char)) -> acc -> ByteString -> (acc, ByteString) mapAccumL f = B.mapAccumL (\acc w -> case f acc (w2c w) of (acc', c) -> (acc', c2w c)) -- | The 'mapAccumR' function behaves like a combination of 'map' and -- 'foldr'; it applies a function to each element of a ByteString, -- passing an accumulating parameter from right to left, and returning a -- final value of this accumulator together with the new ByteString. mapAccumR :: (acc -> Char -> (acc, Char)) -> acc -> ByteString -> (acc, ByteString) mapAccumR f = B.mapAccumR (\acc w -> case f acc (w2c w) of (acc', c) -> (acc', c2w c)) -- | '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 :: (Char -> Char -> Char) -> Char -> ByteString -> ByteString scanl f z = B.scanl (\a b -> c2w (f (w2c a) (w2c b))) (c2w z) -- | 'scanl1' is a variant of 'scanl' that has no starting value argument: -- -- > scanl1 f [x1, x2, ...] == [x1, x1 `f` x2, ...] scanl1 :: (Char -> Char -> Char) -> ByteString -> ByteString scanl1 f = B.scanl1 (\a b -> c2w (f (w2c a) (w2c b))) -- | scanr is the right-to-left dual of scanl. scanr :: (Char -> Char -> Char) -> Char -> ByteString -> ByteString scanr f z = B.scanr (\a b -> c2w (f (w2c a) (w2c b))) (c2w z) -- | 'scanr1' is a variant of 'scanr' that has no starting value argument. scanr1 :: (Char -> Char -> Char) -> ByteString -> ByteString scanr1 f = B.scanr1 (\a b -> c2w (f (w2c a) (w2c b))) -- | /O(n)/ 'replicate' @n x@ is a ByteString of length @n@ with @x@ -- the value of every element. The following holds: -- -- > replicate w c = unfoldr w (\u -> Just (u,u)) c -- -- This implemenation uses @memset(3)@ replicate :: Int -> Char -> ByteString replicate w = B.replicate w . c2w {-# INLINE replicate #-} -- | /O(n)/, where /n/ is the length of the result. The 'unfoldr' -- function is analogous to the List \'unfoldr\'. 'unfoldr' builds a -- ByteString from a seed value. The function takes the element and -- returns 'Nothing' if it is done producing the ByteString or returns -- 'Just' @(a,b)@, in which case, @a@ is the next character in the string, -- and @b@ is the seed value for further production. -- -- Examples: -- -- > unfoldr (\x -> if x <= '9' then Just (x, succ x) else Nothing) '0' == "0123456789" unfoldr :: (a -> Maybe (Char, a)) -> a -> ByteString unfoldr f x0 = B.unfoldr (fmap k . f) x0 where k (i, j) = (c2w i, j) -- | /O(n)/ Like 'unfoldr', 'unfoldrN' builds a ByteString from a seed -- value. However, the length of the result is limited by the first -- argument to 'unfoldrN'. This function is more efficient than 'unfoldr' -- when the maximum length of the result is known. -- -- The following equation relates 'unfoldrN' and 'unfoldr': -- -- > unfoldrN n f s == take n (unfoldr f s) unfoldrN :: Int -> (a -> Maybe (Char, a)) -> a -> (ByteString, Maybe a) unfoldrN n f w = B.unfoldrN n ((k `fmap`) . f) w where k (i,j) = (c2w i, j) {-# INLINE unfoldrN #-} -- | 'takeWhile', applied to a predicate @p@ and a ByteString @xs@, -- returns the longest prefix (possibly empty) of @xs@ of elements that -- satisfy @p@. takeWhile :: (Char -> Bool) -> ByteString -> ByteString takeWhile f = B.takeWhile (f . w2c) {-# INLINE takeWhile #-} -- | 'dropWhile' @p xs@ returns the suffix remaining after 'takeWhile' @p xs@. dropWhile :: (Char -> Bool) -> ByteString -> ByteString dropWhile f = B.dropWhile (f . w2c) #if defined(__GLASGOW_HASKELL__) {-# INLINE [1] dropWhile #-} #endif {-# RULES "ByteString specialise dropWhile isSpace -> dropSpace" dropWhile isSpace = dropSpace #-} -- | 'break' @p@ is equivalent to @'span' ('not' . p)@. break :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) break f = B.break (f . w2c) #if defined(__GLASGOW_HASKELL__) {-# INLINE [1] break #-} #endif #if __GLASGOW_HASKELL__ >= 606 -- This RULE LHS is not allowed by ghc-6.4 {-# RULES "ByteString specialise break (x==)" forall x. break ((==) x) = breakChar x "ByteString specialise break (==x)" forall x. break (==x) = breakChar x #-} #endif -- INTERNAL: -- | 'breakChar' breaks its ByteString argument at the first occurence -- of the specified char. It is more efficient than 'break' as it is -- implemented with @memchr(3)@. I.e. -- -- > break (=='c') "abcd" == breakChar 'c' "abcd" -- breakChar :: Char -> ByteString -> (ByteString, ByteString) breakChar c p = case elemIndex c p of Nothing -> (p,empty) Just n -> (B.unsafeTake n p, B.unsafeDrop n p) {-# INLINE breakChar #-} -- | 'span' @p xs@ breaks the ByteString into two segments. It is -- equivalent to @('takeWhile' p xs, 'dropWhile' p xs)@ span :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) span f = B.span (f . w2c) {-# INLINE span #-} -- | 'spanEnd' behaves like 'span' but from the end of the 'ByteString'. -- We have -- -- > spanEnd (not.isSpace) "x y z" == ("x y ","z") -- -- and -- -- > spanEnd (not . isSpace) ps -- > == -- > let (x,y) = span (not.isSpace) (reverse ps) in (reverse y, reverse x) -- spanEnd :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) spanEnd f = B.spanEnd (f . w2c) {-# INLINE spanEnd #-} -- | 'breakEnd' behaves like 'break' but from the end of the 'ByteString' -- -- breakEnd p == spanEnd (not.p) breakEnd :: (Char -> Bool) -> ByteString -> (ByteString, ByteString) breakEnd f = B.breakEnd (f . w2c) {-# INLINE breakEnd #-} {- -- | 'breakChar' breaks its ByteString argument at the first occurence -- of the specified Char. It is more efficient than 'break' as it is -- implemented with @memchr(3)@. I.e. -- -- > break (=='c') "abcd" == breakChar 'c' "abcd" -- breakChar :: Char -> ByteString -> (ByteString, ByteString) breakChar = B.breakByte . c2w {-# INLINE breakChar #-} -- | 'spanChar' breaks its ByteString argument at the first -- occurence of a Char other than its argument. It is more efficient -- than 'span (==)' -- -- > span (=='c') "abcd" == spanByte 'c' "abcd" -- spanChar :: Char -> ByteString -> (ByteString, ByteString) spanChar = B.spanByte . c2w {-# INLINE spanChar #-} -} -- | /O(n)/ Break a 'ByteString' into pieces separated by the byte -- argument, consuming the delimiter. I.e. -- -- > split '\n' "a\nb\nd\ne" == ["a","b","d","e"] -- > split 'a' "aXaXaXa" == ["","X","X","X",""] -- > split 'x' "x" == ["",""] -- -- and -- -- > intercalate [c] . split c == id -- > split == splitWith . (==) -- -- As for all splitting functions in this library, this function does -- not copy the substrings, it just constructs new 'ByteStrings' that -- are slices of the original. -- split :: Char -> ByteString -> [ByteString] split = B.split . c2w {-# INLINE split #-} -- | /O(n)/ Splits a 'ByteString' into components delimited by -- separators, where the predicate returns True for a separator element. -- The resulting components do not contain the separators. Two adjacent -- separators result in an empty component in the output. eg. -- -- > splitWith (=='a') "aabbaca" == ["","","bb","c",""] -- splitWith :: (Char -> Bool) -> ByteString -> [ByteString] splitWith f = B.splitWith (f . w2c) {-# INLINE splitWith #-} -- the inline makes a big difference here. {- -- | Like 'splitWith', except that sequences of adjacent separators are -- treated as a single separator. eg. -- -- > tokens (=='a') "aabbaca" == ["bb","c"] -- tokens :: (Char -> Bool) -> ByteString -> [ByteString] tokens f = B.tokens (f . w2c) {-# INLINE tokens #-} -} -- | The 'groupBy' function is the non-overloaded version of 'group'. groupBy :: (Char -> Char -> Bool) -> ByteString -> [ByteString] groupBy k = B.groupBy (\a b -> k (w2c a) (w2c b)) -- | /O(1)/ 'ByteString' index (subscript) operator, starting from 0. index :: ByteString -> Int -> Char index = (w2c .) . B.index {-# INLINE index #-} -- | /O(n)/ The 'elemIndex' function returns the index of the first -- element in the given 'ByteString' which is equal (by memchr) to the -- query element, or 'Nothing' if there is no such element. elemIndex :: Char -> ByteString -> Maybe Int elemIndex = B.elemIndex . c2w {-# INLINE elemIndex #-} -- | /O(n)/ The 'elemIndexEnd' function returns the last index of the -- element in the given 'ByteString' which is equal to the query -- element, or 'Nothing' if there is no such element. The following -- holds: -- -- > elemIndexEnd c xs == -- > (-) (length xs - 1) `fmap` elemIndex c (reverse xs) -- elemIndexEnd :: Char -> ByteString -> Maybe Int elemIndexEnd = B.elemIndexEnd . c2w {-# INLINE elemIndexEnd #-} -- | /O(n)/ The 'elemIndices' function extends 'elemIndex', by returning -- the indices of all elements equal to the query element, in ascending order. elemIndices :: Char -> ByteString -> [Int] elemIndices = B.elemIndices . c2w {-# INLINE elemIndices #-} -- | The 'findIndex' function takes a predicate and a 'ByteString' and -- returns the index of the first element in the ByteString satisfying the predicate. findIndex :: (Char -> Bool) -> ByteString -> Maybe Int findIndex f = B.findIndex (f . w2c) {-# INLINE findIndex #-} -- | The 'findIndices' function extends 'findIndex', by returning the -- indices of all elements satisfying the predicate, in ascending order. findIndices :: (Char -> Bool) -> ByteString -> [Int] findIndices f = B.findIndices (f . w2c) -- | count returns the number of times its argument appears in the ByteString -- -- > count = length . elemIndices -- -- Also -- -- > count '\n' == length . lines -- -- But more efficiently than using length on the intermediate list. count :: Char -> ByteString -> Int count c = B.count (c2w c) -- | /O(n)/ 'elem' is the 'ByteString' membership predicate. This -- implementation uses @memchr(3)@. elem :: Char -> ByteString -> Bool elem c = B.elem (c2w c) {-# INLINE elem #-} -- | /O(n)/ 'notElem' is the inverse of 'elem' notElem :: Char -> ByteString -> Bool notElem c = B.notElem (c2w c) {-# INLINE notElem #-} -- | /O(n)/ 'filter', applied to a predicate and a ByteString, -- returns a ByteString containing those characters that satisfy the -- predicate. filter :: (Char -> Bool) -> ByteString -> ByteString filter f = B.filter (f . w2c) {-# INLINE filter #-} {- -- | /O(n)/ and /O(n\/c) space/ A first order equivalent of /filter . -- (==)/, for the common case of filtering a single Char. It is more -- efficient to use /filterChar/ in this case. -- -- > filterChar == filter . (==) -- -- filterChar is around 10x faster, and uses much less space, than its -- filter equivalent -- filterChar :: Char -> ByteString -> ByteString filterChar c ps = replicate (count c ps) c {-# INLINE filterChar #-} {-# RULES "ByteString specialise filter (== x)" forall x. filter ((==) x) = filterChar x "ByteString specialise filter (== x)" forall x. filter (== x) = filterChar x #-} -} -- | /O(n)/ The 'find' function takes a predicate and a ByteString, -- and returns the first element in matching the predicate, or 'Nothing' -- if there is no such element. find :: (Char -> Bool) -> ByteString -> Maybe Char find f ps = w2c `fmap` B.find (f . w2c) ps {-# INLINE find #-} {- -- | /O(n)/ A first order equivalent of /filter . (==)/, for the common -- case of filtering a single Char. It is more efficient to use -- filterChar in this case. -- -- > filterChar == filter . (==) -- -- filterChar is around 10x faster, and uses much less space, than its -- filter equivalent -- filterChar :: Char -> ByteString -> ByteString filterChar c = B.filterByte (c2w c) {-# INLINE filterChar #-} -- | /O(n)/ A first order equivalent of /filter . (\/=)/, for the common -- case of filtering a single Char out of a list. It is more efficient -- to use /filterNotChar/ in this case. -- -- > filterNotChar == filter . (/=) -- -- filterNotChar is around 3x faster, and uses much less space, than its -- filter equivalent -- filterNotChar :: Char -> ByteString -> ByteString filterNotChar c = B.filterNotByte (c2w c) {-# INLINE filterNotChar #-} -} -- | /O(n)/ 'zip' takes two ByteStrings and returns a list of -- corresponding pairs of Chars. If one input ByteString is short, -- excess elements of the longer ByteString are discarded. This is -- equivalent to a pair of 'unpack' operations, and so space -- usage may be large for multi-megabyte ByteStrings zip :: ByteString -> ByteString -> [(Char,Char)] zip ps qs | B.null ps || B.null qs = [] | otherwise = (unsafeHead ps, unsafeHead qs) : zip (B.unsafeTail ps) (B.unsafeTail qs) -- | '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 ByteStrings to produce the list -- of corresponding sums. zipWith :: (Char -> Char -> a) -> ByteString -> ByteString -> [a] zipWith f = B.zipWith ((. w2c) . f . w2c) -- | 'unzip' transforms a list of pairs of Chars into a pair of -- ByteStrings. Note that this performs two 'pack' operations. unzip :: [(Char,Char)] -> (ByteString,ByteString) unzip ls = (pack (P.map fst ls), pack (P.map snd ls)) {-# INLINE unzip #-} -- | A variety of 'head' for non-empty ByteStrings. 'unsafeHead' omits -- the check for the empty case, which is good for performance, but -- there is an obligation on the programmer to provide a proof that the -- ByteString is non-empty. unsafeHead :: ByteString -> Char unsafeHead = w2c . B.unsafeHead {-# INLINE unsafeHead #-} -- --------------------------------------------------------------------- -- Things that depend on the encoding {-# RULES "ByteString specialise break -> breakSpace" break isSpace = breakSpace #-} -- | 'breakSpace' returns the pair of ByteStrings when the argument is -- broken at the first whitespace byte. I.e. -- -- > break isSpace == breakSpace -- breakSpace :: ByteString -> (ByteString,ByteString) breakSpace (PS x s l) = inlinePerformIO $ withForeignPtr x $ \p -> do i <- firstspace (p `plusPtr` s) 0 l return $! case () of {_ | i == 0 -> (empty, PS x s l) | i == l -> (PS x s l, empty) | otherwise -> (PS x s i, PS x (s+i) (l-i)) } {-# INLINE breakSpace #-} firstspace :: Ptr Word8 -> Int -> Int -> IO Int STRICT3(firstspace) firstspace ptr n m | n >= m = return n | otherwise = do w <- peekByteOff ptr n if (not . isSpaceWord8) w then firstspace ptr (n+1) m else return n -- | 'dropSpace' efficiently returns the 'ByteString' argument with -- white space Chars removed from the front. It is more efficient than -- calling dropWhile for removing whitespace. I.e. -- -- > dropWhile isSpace == dropSpace -- dropSpace :: ByteString -> ByteString dropSpace (PS x s l) = inlinePerformIO $ withForeignPtr x $ \p -> do i <- firstnonspace (p `plusPtr` s) 0 l return $! if i == l then empty else PS x (s+i) (l-i) {-# INLINE dropSpace #-} firstnonspace :: Ptr Word8 -> Int -> Int -> IO Int STRICT3(firstnonspace) firstnonspace ptr n m | n >= m = return n | otherwise = do w <- peekElemOff ptr n if isSpaceWord8 w then firstnonspace ptr (n+1) m else return n {- -- | 'dropSpaceEnd' efficiently returns the 'ByteString' argument with -- white space removed from the end. I.e. -- -- > reverse . (dropWhile isSpace) . reverse == dropSpaceEnd -- -- but it is more efficient than using multiple reverses. -- dropSpaceEnd :: ByteString -> ByteString dropSpaceEnd (PS x s l) = inlinePerformIO $ withForeignPtr x $ \p -> do i <- lastnonspace (p `plusPtr` s) (l-1) return $! if i == (-1) then empty else PS x s (i+1) {-# INLINE dropSpaceEnd #-} lastnonspace :: Ptr Word8 -> Int -> IO Int STRICT2(lastnonspace) lastnonspace ptr n | n < 0 = return n | otherwise = do w <- peekElemOff ptr n if isSpaceWord8 w then lastnonspace ptr (n-1) else return n -} -- | 'lines' breaks a ByteString up into a list of ByteStrings at -- newline Chars. The resulting strings do not contain newlines. -- lines :: ByteString -> [ByteString] lines ps | null ps = [] | otherwise = case search ps of Nothing -> [ps] Just n -> take n ps : lines (drop (n+1) ps) where search = elemIndex '\n' {- -- Just as fast, but more complex. Should be much faster, I thought. lines :: ByteString -> [ByteString] lines (PS _ _ 0) = [] lines (PS x s l) = inlinePerformIO $ withForeignPtr x $ \p -> do let ptr = p `plusPtr` s STRICT1(loop) loop n = do let q = memchr (ptr `plusPtr` n) 0x0a (fromIntegral (l-n)) if q == nullPtr then return [PS x (s+n) (l-n)] else do let i = q `minusPtr` ptr ls <- loop (i+1) return $! PS x (s+n) (i-n) : ls loop 0 -} -- | 'unlines' is an inverse operation to 'lines'. It joins lines, -- after appending a terminating newline to each. unlines :: [ByteString] -> ByteString unlines [] = empty unlines ss = (concat $ List.intersperse nl ss) `append` nl -- half as much space where nl = singleton '\n' -- | 'words' breaks a ByteString up into a list of words, which -- were delimited by Chars representing white space. words :: ByteString -> [ByteString] words = P.filter (not . B.null) . B.splitWith isSpaceWord8 {-# INLINE words #-} -- | The 'unwords' function is analogous to the 'unlines' function, on words. unwords :: [ByteString] -> ByteString unwords = intercalate (singleton ' ') {-# INLINE unwords #-} -- --------------------------------------------------------------------- -- Reading from ByteStrings -- | readInt reads an Int from the beginning of the ByteString. If there is no -- integer at the beginning of the string, it returns Nothing, otherwise -- it just returns the int read, and the rest of the string. readInt :: ByteString -> Maybe (Int, ByteString) readInt as | null as = Nothing | otherwise = case unsafeHead as of '-' -> loop True 0 0 (B.unsafeTail as) '+' -> loop False 0 0 (B.unsafeTail as) _ -> loop False 0 0 as where loop :: Bool -> Int -> Int -> ByteString -> Maybe (Int, ByteString) STRICT4(loop) loop neg i n ps | null ps = end neg i n ps | otherwise = case B.unsafeHead ps of w | w >= 0x30 && w <= 0x39 -> loop neg (i+1) (n * 10 + (fromIntegral w - 0x30)) (B.unsafeTail ps) | otherwise -> end neg i n ps end _ 0 _ _ = Nothing end True _ n ps = Just (negate n, ps) end _ _ n ps = Just (n, ps) -- | readInteger reads an Integer from the beginning of the ByteString. If -- there is no integer at the beginning of the string, it returns Nothing, -- otherwise it just returns the int read, and the rest of the string. readInteger :: ByteString -> Maybe (Integer, ByteString) readInteger as | null as = Nothing | otherwise = case unsafeHead as of '-' -> first (B.unsafeTail as) >>= \(n, bs) -> return (-n, bs) '+' -> first (B.unsafeTail as) _ -> first as where first ps | null ps = Nothing | otherwise = case B.unsafeHead ps of w | w >= 0x30 && w <= 0x39 -> Just $ loop 1 (fromIntegral w - 0x30) [] (B.unsafeTail ps) | otherwise -> Nothing loop :: Int -> Int -> [Integer] -> ByteString -> (Integer, ByteString) STRICT4(loop) loop d acc ns ps | null ps = combine d acc ns empty | otherwise = case B.unsafeHead ps of w | w >= 0x30 && w <= 0x39 -> if d == 9 then loop 1 (fromIntegral w - 0x30) (toInteger acc : ns) (B.unsafeTail ps) else loop (d+1) (10*acc + (fromIntegral w - 0x30)) ns (B.unsafeTail ps) | otherwise -> combine d acc ns ps combine _ acc [] ps = (toInteger acc, ps) combine d acc ns ps = ((10^d * combine1 1000000000 ns + toInteger acc), ps) combine1 _ [n] = n combine1 b ns = combine1 (b*b) $ combine2 b ns combine2 b (n:m:ns) = let t = m*b + n in t `seq` (t : combine2 b ns) combine2 _ ns = ns ------------------------------------------------------------------------ -- For non-binary text processing: -- | Read an entire file strictly into a 'ByteString'. This is far more -- efficient than reading the characters into a 'String' and then using -- 'pack'. It also may be more efficient than opening the file and -- reading it using hGet. readFile :: FilePath -> IO ByteString readFile f = bracket (openFile f ReadMode) hClose (\h -> hFileSize h >>= hGet h . fromIntegral) -- | Write a 'ByteString' to a file. writeFile :: FilePath -> ByteString -> IO () writeFile f txt = bracket (openFile f WriteMode) hClose (\h -> hPut h txt) -- | Append a 'ByteString' to a file. appendFile :: FilePath -> ByteString -> IO () appendFile f txt = bracket (openFile f AppendMode) hClose (\h -> hPut h txt)