{-# LANGUAGE BangPatterns, CPP, MagicHash, Rank2Types, UnboxedTuples #-} {-# OPTIONS_GHC -fno-warn-orphans #-} #if __GLASGOW_HASKELL__ >= 702 {-# LANGUAGE Trustworthy #-} #endif #if __GLASGOW_HASKELL__ >= 708 {-# LANGUAGE TypeFamilies #-} #endif -- | -- Module : Data.Text -- Copyright : (c) 2009, 2010, 2011, 2012 Bryan O'Sullivan, -- (c) 2009 Duncan Coutts, -- (c) 2008, 2009 Tom Harper -- -- License : BSD-style -- Maintainer : bos@serpentine.com -- Portability : GHC -- -- A time and space-efficient implementation of Unicode text. -- Suitable for performance critical use, both in terms of large data -- quantities and high speed. -- -- /Note/: Read below the synopsis for important notes on the use of -- this module. -- -- This module is intended to be imported @qualified@, to avoid name -- clashes with "Prelude" functions, e.g. -- -- > import qualified Data.Text as T -- -- To use an extended and very rich family of functions for working -- with Unicode text (including normalization, regular expressions, -- non-standard encodings, text breaking, and locales), see the -- <http://hackage.haskell.org/package/text-icu text-icu package >. -- module Data.Text ( -- * Strict vs lazy types -- $strict -- * Acceptable data -- $replacement -- * Definition of character -- $character_definition -- * Fusion -- $fusion -- * Types Text -- * Creation and elimination , pack , unpack , singleton , empty -- * Basic interface , cons , snoc , append , uncons , unsnoc , head , last , tail , init , null , length , compareLength -- * Transformations , map , intercalate , intersperse , transpose , reverse , replace -- ** Case conversion -- $case , toCaseFold , toLower , toUpper , toTitle -- ** Justification , justifyLeft , justifyRight , center -- * Folds , foldl , foldl' , foldl1 , foldl1' , foldr , foldr1 -- ** Special folds , concat , concatMap , any , all , maximum , minimum -- * Construction -- ** Scans , scanl , scanl1 , scanr , scanr1 -- ** Accumulating maps , mapAccumL , mapAccumR -- ** Generation and unfolding , replicate , unfoldr , unfoldrN -- * Substrings -- ** Breaking strings , take , takeEnd , drop , dropEnd , takeWhile , takeWhileEnd , dropWhile , dropWhileEnd , dropAround , strip , stripStart , stripEnd , splitAt , breakOn , breakOnEnd , break , span , group , groupBy , inits , tails -- ** Breaking into many substrings -- $split , splitOn , split , chunksOf -- ** Breaking into lines and words , lines --, lines' , words , unlines , unwords -- * Predicates , isPrefixOf , isSuffixOf , isInfixOf -- ** View patterns , stripPrefix , stripSuffix , commonPrefixes -- * Searching , filter , breakOnAll , find , partition -- , findSubstring -- * Indexing -- $index , index , findIndex , count -- * Zipping , zip , zipWith -- -* Ordered text -- , sort -- * Low level operations , copy , unpackCString# ) where import Prelude (Char, Bool(..), Int, Maybe(..), String, Eq(..), Ord(..), Ordering(..), (++), Read(..), (&&), (||), (+), (-), (.), ($), ($!), (>>), not, return, otherwise, quot) #if defined(HAVE_DEEPSEQ) import Control.DeepSeq (NFData(rnf)) #endif #if defined(ASSERTS) import Control.Exception (assert) #endif import Data.Char (isSpace) import Data.Data (Data(gfoldl, toConstr, gunfold, dataTypeOf), constrIndex, Constr, mkConstr, DataType, mkDataType, Fixity(Prefix)) import Control.Monad (foldM) import Control.Monad.ST (ST) import qualified Data.Text.Array as A import qualified Data.List as L import Data.Binary (Binary(get, put)) import Data.Monoid (Monoid(..)) #if MIN_VERSION_base(4,9,0) import Data.Semigroup (Semigroup(..)) #endif import Data.String (IsString(..)) import qualified Data.Text.Internal.Fusion as S import qualified Data.Text.Internal.Fusion.Common as S import Data.Text.Encoding (decodeUtf8', encodeUtf8) import Data.Text.Internal.Fusion (stream, reverseStream, unstream) import Data.Text.Internal.Private (span_) import Data.Text.Internal (Text(..), empty, firstf, mul, safe, text) import Data.Text.Show (singleton, unpack, unpackCString#) import qualified Prelude as P import Data.Text.Unsafe (Iter(..), iter, iter_, lengthWord8, reverseIter, reverseIter_, unsafeHead, unsafeTail, takeWord8) import qualified Data.Text.Internal.Functions as F import qualified Data.Text.Internal.Encoding.Utf8 as U8 import Data.Text.Internal.Search (indices) #if defined(__HADDOCK__) import Data.ByteString (ByteString) import qualified Data.Text.Lazy as L import Data.Int (Int64) #endif import GHC.Base (eqInt, neInt, gtInt, geInt, ltInt, leInt) #if __GLASGOW_HASKELL__ >= 708 import qualified GHC.Exts as Exts #endif #if MIN_VERSION_base(4,7,0) import Text.Printf (PrintfArg, formatArg, formatString) #endif -- $character_definition -- -- This package uses the term /character/ to denote Unicode /code points/. -- -- Note that this is not the same thing as a grapheme (e.g. a -- composition of code points that form one visual symbol). For -- instance, consider the grapheme \"ä\". This symbol has two -- Unicode representations: a single code-point representation -- @U+00E4@ (the @LATIN SMALL LETTER A WITH DIAERESIS@ code point), -- and a two code point representation @U+0061@ (the \"@A@\" code -- point) and @U+0308@ (the @COMBINING DIAERESIS@ code point). -- $strict -- -- This package provides both strict and lazy 'Text' types. The -- strict type is provided by the "Data.Text" module, while the lazy -- type is provided by the "Data.Text.Lazy" module. Internally, the -- lazy @Text@ type consists of a list of strict chunks. -- -- The strict 'Text' type requires that an entire string fit into -- memory at once. The lazy 'Data.Text.Lazy.Text' type is capable of -- streaming strings that are larger than memory using a small memory -- footprint. In many cases, the overhead of chunked streaming makes -- the lazy 'Data.Text.Lazy.Text' type slower than its strict -- counterpart, but this is not always the case. Sometimes, the time -- complexity of a function in one module may be different from the -- other, due to their differing internal structures. -- -- Each module provides an almost identical API, with the main -- difference being that the strict module uses 'Int' values for -- lengths and counts, while the lazy module uses 'Data.Int.Int64' -- lengths. -- $replacement -- -- A 'Text' value is a sequence of Unicode scalar values, as defined -- in -- <http://www.unicode.org/versions/Unicode5.2.0/ch03.pdf#page=35 §3.9, definition D76 of the Unicode 5.2 standard >. -- As such, a 'Text' cannot contain values in the range U+D800 to -- U+DFFF inclusive. Haskell implementations admit all Unicode code -- points -- (<http://www.unicode.org/versions/Unicode5.2.0/ch03.pdf#page=13 §3.4, definition D10 >) -- as 'Char' values, including code points from this invalid range. -- This means that there are some 'Char' values that are not valid -- Unicode scalar values, and the functions in this module must handle -- those cases. -- -- Within this module, many functions construct a 'Text' from one or -- more 'Char' values. Those functions will substitute 'Char' values -- that are not valid Unicode scalar values with the replacement -- character \"�\" (U+FFFD). Functions that perform this -- inspection and replacement are documented with the phrase -- \"Performs replacement on invalid scalar values\". -- -- (One reason for this policy of replacement is that internally, a -- 'Text' value is represented as packed UTF-8 data. Values in the -- range U+D800 through U+DFFF are used by UTF-16 to denote surrogate -- code points, and so cannot be represented. The functions replace -- invalid scalar values, instead of dropping them, as a security -- measure. For details, see -- <http://unicode.org/reports/tr36/#Deletion_of_Noncharacters Unicode Technical Report 36, §3.5 >.) -- $fusion -- -- Most of the functions in this module are subject to /fusion/, -- meaning that a pipeline of such functions will usually allocate at -- most one 'Text' value. -- -- As an example, consider the following pipeline: -- -- > import Data.Text as T -- > import Data.Text.Encoding as E -- > import Data.ByteString (ByteString) -- > -- > countChars :: ByteString -> Int -- > countChars = T.length . T.toUpper . E.decodeUtf8 -- -- From the type signatures involved, this looks like it should -- allocate one 'Data.ByteString.ByteString' value, and two 'Text' -- values. However, when a module is compiled with optimisation -- enabled under GHC, the two intermediate 'Text' values will be -- optimised away, and the function will be compiled down to a single -- loop over the source 'Data.ByteString.ByteString'. -- -- Functions that can be fused by the compiler are documented with the -- phrase \"Subject to fusion\". instance Eq Text where Text arrA offA lenA == Text arrB offB lenB | lenA == lenB = A.equal arrA offA arrB offB lenA | otherwise = False {-# INLINE (==) #-} instance Ord Text where compare = compareText instance Read Text where readsPrec p str = [(pack x,y) | (x,y) <- readsPrec p str] #if MIN_VERSION_base(4,9,0) -- | Non-orphan 'Semigroup' instance only defined for -- @base-4.9.0.0@ and later; orphan instances for older GHCs are -- provided by -- the [semigroups](http://hackage.haskell.org/package/semigroups) -- package -- -- @since 1.2.2.0 instance Semigroup Text where (<>) = append #endif instance Monoid Text where mempty = empty #if MIN_VERSION_base(4,9,0) mappend = (<>) -- future-proof definition #else mappend = append #endif mconcat = concat instance IsString Text where fromString = pack #if __GLASGOW_HASKELL__ >= 708 -- | @since 1.2.0.0 instance Exts.IsList Text where type Item Text = Char fromList = pack toList = unpack #endif #if defined(HAVE_DEEPSEQ) instance NFData Text where rnf !_ = () #endif -- | @since 1.2.1.0 instance Binary Text where put t = put (encodeUtf8 t) get = do bs <- get case decodeUtf8' bs of P.Left exn -> P.fail (P.show exn) P.Right a -> P.return a -- | This instance preserves data abstraction at the cost of inefficiency. -- We omit reflection services for the sake of data abstraction. -- -- This instance was created by copying the updated behavior of -- @"Data.Set".@'Data.Set.Set' and @"Data.Map".@'Data.Map.Map'. If you -- feel a mistake has been made, please feel free to submit -- improvements. -- -- The original discussion is archived here: -- <http://groups.google.com/group/haskell-cafe/browse_thread/thread/b5bbb1b28a7e525d/0639d46852575b93 could we get a Data instance for Data.Text.Text? > -- -- The followup discussion that changed the behavior of 'Data.Set.Set' -- and 'Data.Map.Map' is archived here: -- <http://markmail.org/message/trovdc6zkphyi3cr#query:+page:1+mid:a46der3iacwjcf6n+state:results Proposal: Allow gunfold for Data.Map, ... > instance Data Text where gfoldl f z txt = z pack `f` (unpack txt) toConstr _ = packConstr gunfold k z c = case constrIndex c of 1 -> k (z pack) _ -> P.error "gunfold" dataTypeOf _ = textDataType #if MIN_VERSION_base(4,7,0) -- | Only defined for @base-4.7.0.0@ and later -- -- @since 1.2.2.0 instance PrintfArg Text where formatArg txt = formatString $ unpack txt #endif packConstr :: Constr packConstr = mkConstr textDataType "pack" [] Prefix textDataType :: DataType textDataType = mkDataType "Data.Text.Text" [packConstr] -- | /O(n)/ Compare two 'Text' values lexicographically. compareText :: Text -> Text -> Ordering compareText (Text arrA offA lenA) (Text arrB offB lenB) | lenA == 0 || lenB == 0 = compare lenA lenB | otherwise = A.cmp arrA offA arrB offB (min lenA lenB) `mappend` compare lenA lenB -- ----------------------------------------------------------------------------- -- * Conversion to/from 'Text' -- | /O(n)/ Convert a 'String' into a 'Text'. Subject to -- fusion. Performs replacement on invalid scalar values. pack :: String -> Text pack = unstream . S.map safe . S.streamList {-# INLINE [1] pack #-} -- ----------------------------------------------------------------------------- -- * Basic functions -- | /O(n)/ Adds a character to the front of a 'Text'. This function -- is more costly than its 'List' counterpart because it requires -- copying a new array. Subject to fusion. Performs replacement on -- invalid scalar values. cons :: Char -> Text -> Text cons c t = unstream (S.cons (safe c) (stream t)) {-# INLINE cons #-} infixr 5 `cons` -- | /O(n)/ Adds a character to the end of a 'Text'. This copies the -- entire array in the process, unless fused. Subject to fusion. -- Performs replacement on invalid scalar values. snoc :: Text -> Char -> Text snoc t c = unstream (S.snoc (stream t) (safe c)) {-# INLINE snoc #-} -- | /O(n)/ Appends one 'Text' to the other by copying both of them -- into a new 'Text'. Subject to fusion. append :: Text -> Text -> Text append a@(Text arr1 off1 len1) b@(Text arr2 off2 len2) | len1 == 0 = b | len2 == 0 = a | len > 0 = Text (A.run x) 0 len | otherwise = overflowError "append" where len = len1+len2 x :: ST s (A.MArray s) x = do arr <- A.new len A.copyI arr 0 arr1 off1 len1 A.copyI arr len1 arr2 off2 len return arr {-# NOINLINE append #-} {-# RULES "TEXT append -> fused" [~1] forall t1 t2. append t1 t2 = unstream (S.append (stream t1) (stream t2)) "TEXT append -> unfused" [1] forall t1 t2. unstream (S.append (stream t1) (stream t2)) = append t1 t2 #-} -- | /O(1)/ Returns the first character of a 'Text', which must be -- non-empty. Subject to fusion. head :: Text -> Char head t = S.head (stream t) {-# INLINE head #-} -- | /O(1)/ Returns the first character and rest of a 'Text', or -- 'Nothing' if empty. Subject to fusion. uncons :: Text -> Maybe (Char, Text) uncons t@(Text arr off len) | len <= 0 = Nothing | otherwise = Just $ let !(Iter c d) = iter t 0 in (c, text arr (off+d) (len-d)) {-# INLINE [1] uncons #-} -- | Lifted from Control.Arrow and specialized. second :: (b -> c) -> (a,b) -> (a,c) second f (a, b) = (a, f b) -- | /O(1)/ Returns the last character of a 'Text', which must be -- non-empty. Subject to fusion. last :: Text -> Char last (Text arr off len) | len <= 0 = emptyError "last" | otherwise = U8.reverseDecodeCharIndex (\c _ -> c) idx (off + len - 1) where idx = A.unsafeIndex arr {-# INLINE [1] last #-} {-# RULES "TEXT last -> fused" [~1] forall t. last t = S.last (stream t) "TEXT last -> unfused" [1] forall t. S.last (stream t) = last t #-} -- | /O(1)/ Returns all characters after the head of a 'Text', which -- must be non-empty. Subject to fusion. tail :: Text -> Text tail t@(Text arr off len) | len <= 0 = emptyError "tail" | otherwise = text arr (off+d) (len-d) where d = iter_ t 0 {-# INLINE [1] tail #-} {-# RULES "TEXT tail -> fused" [~1] forall t. tail t = unstream (S.tail (stream t)) "TEXT tail -> unfused" [1] forall t. unstream (S.tail (stream t)) = tail t #-} -- | /O(1)/ Returns all but the last character of a 'Text', which must -- be non-empty. Subject to fusion. init :: Text -> Text init t@(Text arr off len) | len <= 0 = emptyError "init" | otherwise = U8.reverseDecodeCharIndex (\_ s -> takeWord8 (len - s) t) idx (off + len - 1) where idx = A.unsafeIndex arr {-# INLINE [1] init #-} {-# RULES "TEXT init -> fused" [~1] forall t. init t = unstream (S.init (stream t)) "TEXT init -> unfused" [1] forall t. unstream (S.init (stream t)) = init t #-} -- | /O(1)/ Returns all but the last character and the last character of a -- 'Text', or 'Nothing' if empty. -- -- @since 1.2.3.0 unsnoc :: Text -> Maybe (Text, Char) unsnoc t@(Text _ _ len) | len <= 0 = Nothing | otherwise = Just (init t, last t) -- TODO {-# INLINE [1] unsnoc #-} -- | /O(1)/ Tests whether a 'Text' is empty or not. Subject to -- fusion. null :: Text -> Bool null (Text _arr _off len) = #if defined(ASSERTS) assert (len >= 0) $ #endif len <= 0 {-# INLINE [1] null #-} {-# RULES "TEXT null -> fused" [~1] forall t. null t = S.null (stream t) "TEXT null -> unfused" [1] forall t. S.null (stream t) = null t #-} -- | /O(1)/ Tests whether a 'Text' contains exactly one character. -- Subject to fusion. isSingleton :: Text -> Bool isSingleton = S.isSingleton . stream {-# INLINE isSingleton #-} -- | /O(n)/ Returns the number of characters in a 'Text'. -- Subject to fusion. length :: Text -> Int length t = S.length (stream t) {-# INLINE [0] length #-} -- length needs to be phased after the compareN/length rules otherwise -- it may inline before the rules have an opportunity to fire. -- | /O(n)/ Compare the count of characters in a 'Text' to a number. -- Subject to fusion. -- -- This function gives the same answer as comparing against the result -- of 'length', but can short circuit if the count of characters is -- greater than the number, and hence be more efficient. compareLength :: Text -> Int -> Ordering compareLength t n = S.compareLengthI (stream t) n {-# INLINE [1] compareLength #-} {-# RULES "TEXT compareN/length -> compareLength" [~1] forall t n. compare (length t) n = compareLength t n #-} {-# RULES "TEXT ==N/length -> compareLength/==EQ" [~1] forall t n. eqInt (length t) n = compareLength t n == EQ #-} {-# RULES "TEXT /=N/length -> compareLength//=EQ" [~1] forall t n. neInt (length t) n = compareLength t n /= EQ #-} {-# RULES "TEXT <N/length -> compareLength/==LT" [~1] forall t n. ltInt (length t) n = compareLength t n == LT #-} {-# RULES "TEXT <=N/length -> compareLength//=GT" [~1] forall t n. leInt (length t) n = compareLength t n /= GT #-} {-# RULES "TEXT >N/length -> compareLength/==GT" [~1] forall t n. gtInt (length t) n = compareLength t n == GT #-} {-# RULES "TEXT >=N/length -> compareLength//=LT" [~1] forall t n. geInt (length t) n = compareLength t n /= LT #-} -- ----------------------------------------------------------------------------- -- * Transformations -- | /O(n)/ 'map' @f@ @t@ is the 'Text' obtained by applying @f@ to -- each element of @t@. -- -- Example: -- -- >>> let message = pack "I am not angry. Not at all." -- >>> T.map (\c -> if c == '.' then '!' else c) message -- "I am not angry! Not at all!" -- -- Subject to fusion. Performs replacement on invalid scalar values. map :: (Char -> Char) -> Text -> Text map f t = unstream (S.map (safe . f) (stream t)) {-# INLINE [1] map #-} -- | /O(n)/ The 'intercalate' function takes a 'Text' and a list of -- 'Text's and concatenates the list after interspersing the first -- argument between each element of the list. -- -- Example: -- -- >>> T.intercalate "NI!" ["We", "seek", "the", "Holy", "Grail"] -- "WeNI!seekNI!theNI!HolyNI!Grail" intercalate :: Text -> [Text] -> Text intercalate t = concat . (F.intersperse t) {-# INLINE intercalate #-} -- | /O(n)/ The 'intersperse' function takes a character and places it -- between the characters of a 'Text'. -- -- Example: -- -- >>> T.intersperse '.' "SHIELD" -- "S.H.I.E.L.D" -- -- Subject to fusion. Performs replacement on invalid scalar values. intersperse :: Char -> Text -> Text intersperse c t = unstream (S.intersperse (safe c) (stream t)) {-# INLINE intersperse #-} -- | /O(n)/ Reverse the characters of a string. -- -- Example: -- -- >>> T.reverse "desrever" -- "reversed" -- -- Subject to fusion. reverse :: Text -> Text reverse t = S.reverse (stream t) {-# INLINE reverse #-} -- | /O(m+n)/ Replace every non-overlapping occurrence of @needle@ in -- @haystack@ with @replacement@. -- -- This function behaves as though it was defined as follows: -- -- @ -- replace needle replacement haystack = -- 'intercalate' replacement ('splitOn' needle haystack) -- @ -- -- As this suggests, each occurrence is replaced exactly once. So if -- @needle@ occurs in @replacement@, that occurrence will /not/ itself -- be replaced recursively: -- -- >>> replace "oo" "foo" "oo" -- "foo" -- -- In cases where several instances of @needle@ overlap, only the -- first one will be replaced: -- -- >>> replace "ofo" "bar" "ofofo" -- "barfo" -- -- In (unlikely) bad cases, this function's time complexity degrades -- towards /O(n*m)/. replace :: Text -- ^ @needle@ to search for. If this string is empty, an -- error will occur. -> Text -- ^ @replacement@ to replace @needle@ with. -> Text -- ^ @haystack@ in which to search. -> Text replace needle@(Text _ _ neeLen) (Text repArr repOff repLen) haystack@(Text hayArr hayOff hayLen) | neeLen == 0 = emptyError "replace" | L.null ixs = haystack | len > 0 = Text (A.run x) 0 len | otherwise = empty where ixs = indices needle haystack len = hayLen - (neeLen - repLen) `mul` L.length ixs x :: ST s (A.MArray s) x = do marr <- A.new len let loop (i:is) o d = do let d0 = d + i - o d1 = d0 + repLen A.copyI marr d hayArr (hayOff+o) d0 A.copyI marr d0 repArr repOff d1 loop is (i + neeLen) d1 loop [] o d = A.copyI marr d hayArr (hayOff+o) len loop ixs 0 0 return marr -- ---------------------------------------------------------------------------- -- ** Case conversions (folds) -- $case -- -- When case converting 'Text' values, do not use combinators like -- @map toUpper@ to case convert each character of a string -- individually, as this gives incorrect results according to the -- rules of some writing systems. The whole-string case conversion -- functions from this module, such as @toUpper@, obey the correct -- case conversion rules. As a result, these functions may map one -- input character to two or three output characters. For examples, -- see the documentation of each function. -- -- /Note/: In some languages, case conversion is a locale- and -- context-dependent operation. The case conversion functions in this -- module are /not/ locale sensitive. Programs that require locale -- sensitivity should use appropriate versions of the -- <http://hackage.haskell.org/package/text-icu-0.6.3.7/docs/Data-Text-ICU.html#g:4 case mapping functions from the text-icu package >. -- | /O(n)/ Convert a string to folded case. Subject to fusion. -- -- This function is mainly useful for performing caseless (also known -- as case insensitive) string comparisons. -- -- A string @x@ is a caseless match for a string @y@ if and only if: -- -- @toCaseFold x == toCaseFold y@ -- -- The result string may be longer than the input string, and may -- differ from applying 'toLower' to the input string. For instance, -- the Armenian small ligature \"ﬓ\" (men now, U+FB13) is case -- folded to the sequence \"մ\" (men, U+0574) followed by -- \"ն\" (now, U+0576), while the Greek \"µ\" (micro sign, -- U+00B5) is case folded to \"μ\" (small letter mu, U+03BC) -- instead of itself. toCaseFold :: Text -> Text toCaseFold t = unstream (S.toCaseFold (stream t)) {-# INLINE toCaseFold #-} -- | /O(n)/ Convert a string to lower case, using simple case -- conversion. Subject to fusion. -- -- The result string may be longer than the input string. For -- instance, \"İ\" (Latin capital letter I with dot above, -- U+0130) maps to the sequence \"i\" (Latin small letter i, U+0069) -- followed by \" ̇\" (combining dot above, U+0307). toLower :: Text -> Text toLower t = unstream (S.toLower (stream t)) {-# INLINE toLower #-} -- | /O(n)/ Convert a string to upper case, using simple case -- conversion. Subject to fusion. -- -- The result string may be longer than the input string. For -- instance, the German \"ß\" (eszett, U+00DF) maps to the -- two-letter sequence \"SS\". toUpper :: Text -> Text toUpper t = unstream (S.toUpper (stream t)) {-# INLINE toUpper #-} -- | /O(n)/ Convert a string to title case, using simple case -- conversion. Subject to fusion. -- -- The first letter of the input is converted to title case, as is -- every subsequent letter that immediately follows a non-letter. -- Every letter that immediately follows another letter is converted -- to lower case. -- -- The result string may be longer than the input string. For example, -- the Latin small ligature fl (U+FB02) is converted to the -- sequence Latin capital letter F (U+0046) followed by Latin small -- letter l (U+006C). -- -- /Note/: this function does not take language or culture specific -- rules into account. For instance, in English, different style -- guides disagree on whether the book name \"The Hill of the Red -- Fox\" is correctly title cased—but this function will -- capitalize /every/ word. -- -- @since 1.0.0.0 toTitle :: Text -> Text toTitle t = unstream (S.toTitle (stream t)) {-# INLINE toTitle #-} -- | /O(n)/ Left-justify a string to the given length, using the -- specified fill character on the right. Subject to fusion. -- Performs replacement on invalid scalar values. -- -- Examples: -- -- >>> justifyLeft 7 'x' "foo" -- "fooxxxx" -- -- >>> justifyLeft 3 'x' "foobar" -- "foobar" justifyLeft :: Int -> Char -> Text -> Text justifyLeft k c t | len >= k = t | otherwise = t `append` replicateChar (k-len) c where len = length t {-# INLINE [1] justifyLeft #-} {-# RULES "TEXT justifyLeft -> fused" [~1] forall k c t. justifyLeft k c t = unstream (S.justifyLeftI k c (stream t)) "TEXT justifyLeft -> unfused" [1] forall k c t. unstream (S.justifyLeftI k c (stream t)) = justifyLeft k c t #-} -- | /O(n)/ Right-justify a string to the given length, using the -- specified fill character on the left. Performs replacement on -- invalid scalar values. -- -- Examples: -- -- >>> justifyRight 7 'x' "bar" -- "xxxxbar" -- -- >>> justifyRight 3 'x' "foobar" -- "foobar" justifyRight :: Int -> Char -> Text -> Text justifyRight k c t | len >= k = t | otherwise = replicateChar (k-len) c `append` t where len = length t {-# INLINE justifyRight #-} -- | /O(n)/ Center a string to the given length, using the specified -- fill character on either side. Performs replacement on invalid -- scalar values. -- -- Examples: -- -- >>> center 8 'x' "HS" -- "xxxHSxxx" center :: Int -> Char -> Text -> Text center k c t | len >= k = t | otherwise = replicateChar l c `append` t `append` replicateChar r c where len = length t d = k - len r = d `quot` 2 l = d - r {-# INLINE center #-} -- | /O(n)/ The 'transpose' function transposes the rows and columns -- of its 'Text' argument. Note that this function uses 'pack', -- 'unpack', and the list version of transpose, and is thus not very -- efficient. -- -- Examples: -- -- >>> transpose ["green","orange"] -- ["go","rr","ea","en","ng","e"] -- -- >>> transpose ["blue","red"] -- ["br","le","ud","e"] transpose :: [Text] -> [Text] transpose ts = P.map pack (L.transpose (P.map unpack ts)) -- ----------------------------------------------------------------------------- -- * Reducing 'Text's (folds) -- | /O(n)/ 'foldl', applied to a binary operator, a starting value -- (typically the left-identity of the operator), and a 'Text', -- reduces the 'Text' using the binary operator, from left to right. -- Subject to fusion. foldl :: (a -> Char -> a) -> a -> Text -> a foldl f z t = S.foldl f z (stream t) {-# INLINE foldl #-} -- | /O(n)/ A strict version of 'foldl'. Subject to fusion. foldl' :: (a -> Char -> a) -> a -> Text -> a foldl' f z t = S.foldl' f z (stream t) {-# INLINE foldl' #-} -- | /O(n)/ A variant of 'foldl' that has no starting value argument, -- and thus must be applied to a non-empty 'Text'. Subject to fusion. foldl1 :: (Char -> Char -> Char) -> Text -> Char foldl1 f t = S.foldl1 f (stream t) {-# INLINE foldl1 #-} -- | /O(n)/ A strict version of 'foldl1'. Subject to fusion. foldl1' :: (Char -> Char -> Char) -> Text -> Char foldl1' f t = S.foldl1' f (stream t) {-# INLINE foldl1' #-} -- | /O(n)/ 'foldr', applied to a binary operator, a starting value -- (typically the right-identity of the operator), and a 'Text', -- reduces the 'Text' using the binary operator, from right to left. -- Subject to fusion. foldr :: (Char -> a -> a) -> a -> Text -> a foldr f z t = S.foldr f z (stream t) {-# INLINE foldr #-} -- | /O(n)/ A variant of 'foldr' that has no starting value argument, -- and thus must be applied to a non-empty 'Text'. Subject to -- fusion. foldr1 :: (Char -> Char -> Char) -> Text -> Char foldr1 f t = S.foldr1 f (stream t) {-# INLINE foldr1 #-} -- ----------------------------------------------------------------------------- -- ** Special folds -- | /O(n)/ Concatenate a list of 'Text's. concat :: [Text] -> Text concat ts = case ts' of [] -> empty [t] -> t _ -> Text (A.run go) 0 len where ts' = L.filter (not . null) ts len = sumP "concat" $ L.map lengthWord8 ts' go :: ST s (A.MArray s) go = do arr <- A.new len let step i (Text a o l) = let !j = i + l in A.copyI arr i a o j >> return j foldM step 0 ts' >> return arr -- | /O(n)/ Map a function over a 'Text' that results in a 'Text', and -- concatenate the results. concatMap :: (Char -> Text) -> Text -> Text concatMap f = concat . foldr ((:) . f) [] {-# INLINE concatMap #-} -- | /O(n)/ 'any' @p@ @t@ determines whether any character in the -- 'Text' @t@ satisfies the predicate @p@. Subject to fusion. any :: (Char -> Bool) -> Text -> Bool any p t = S.any p (stream t) {-# INLINE any #-} -- | /O(n)/ 'all' @p@ @t@ determines whether all characters in the -- 'Text' @t@ satisfy the predicate @p@. Subject to fusion. all :: (Char -> Bool) -> Text -> Bool all p t = S.all p (stream t) {-# INLINE all #-} -- | /O(n)/ 'maximum' returns the maximum value from a 'Text', which -- must be non-empty. Subject to fusion. maximum :: Text -> Char maximum t = S.maximum (stream t) {-# INLINE maximum #-} -- | /O(n)/ 'minimum' returns the minimum value from a 'Text', which -- must be non-empty. Subject to fusion. minimum :: Text -> Char minimum t = S.minimum (stream t) {-# INLINE minimum #-} -- ----------------------------------------------------------------------------- -- * Building 'Text's -- | /O(n)/ 'scanl' is similar to 'foldl', but returns a list of -- successive reduced values from the left. Subject to fusion. -- Performs replacement on invalid scalar values. -- -- > 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 -> Text -> Text scanl f z t = unstream (S.scanl g z (stream t)) where g a b = safe (f a b) {-# INLINE scanl #-} -- | /O(n)/ 'scanl1' is a variant of 'scanl' that has no starting -- value argument. Subject to fusion. Performs replacement on -- invalid scalar values. -- -- > scanl1 f [x1, x2, ...] == [x1, x1 `f` x2, ...] scanl1 :: (Char -> Char -> Char) -> Text -> Text scanl1 f t | null t = empty | otherwise = scanl f (unsafeHead t) (unsafeTail t) {-# INLINE scanl1 #-} -- | /O(n)/ 'scanr' is the right-to-left dual of 'scanl'. Performs -- replacement on invalid scalar values. -- -- > scanr f v == reverse . scanl (flip f) v . reverse scanr :: (Char -> Char -> Char) -> Char -> Text -> Text scanr f z = S.reverse . S.reverseScanr g z . reverseStream where g a b = safe (f a b) {-# INLINE scanr #-} -- | /O(n)/ 'scanr1' is a variant of 'scanr' that has no starting -- value argument. Subject to fusion. Performs replacement on -- invalid scalar values. scanr1 :: (Char -> Char -> Char) -> Text -> Text scanr1 f t | null t = empty | otherwise = scanr f (last t) (init t) {-# INLINE scanr1 #-} -- | /O(n)/ Like a combination of 'map' and 'foldl''. Applies a -- function to each element of a 'Text', passing an accumulating -- parameter from left to right, and returns a final 'Text'. Performs -- replacement on invalid scalar values. mapAccumL :: (a -> Char -> (a,Char)) -> a -> Text -> (a, Text) mapAccumL f z0 = S.mapAccumL g z0 . stream where g a b = second safe (f a b) {-# INLINE mapAccumL #-} -- | The 'mapAccumR' function behaves like a combination of 'map' and -- a strict 'foldr'; it applies a function to each element of a -- 'Text', passing an accumulating parameter from right to left, and -- returning a final value of this accumulator together with the new -- 'Text'. -- Performs replacement on invalid scalar values. mapAccumR :: (a -> Char -> (a,Char)) -> a -> Text -> (a, Text) mapAccumR f z0 = second reverse . S.mapAccumL g z0 . reverseStream where g a b = second safe (f a b) {-# INLINE mapAccumR #-} -- ----------------------------------------------------------------------------- -- ** Generating and unfolding 'Text's -- | /O(n*m)/ 'replicate' @n@ @t@ is a 'Text' consisting of the input -- @t@ repeated @n@ times. replicate :: Int -> Text -> Text replicate n t@(Text a o l) | n <= 0 || l <= 0 = empty | n == 1 = t | isSingleton t = replicateChar n (unsafeHead t) | otherwise = Text (A.run x) 0 len where len = l `mul` n x :: ST s (A.MArray s) x = do arr <- A.new len let loop !d !i | i >= n = return arr | otherwise = let m = d + l in A.copyI arr d a o m >> loop m (i+1) loop 0 0 {-# INLINE [1] replicate #-} {-# RULES "TEXT replicate/singleton -> replicateChar" [~1] forall n c. replicate n (singleton c) = replicateChar n c #-} -- | /O(n)/ 'replicateChar' @n@ @c@ is a 'Text' of length @n@ with @c@ the -- value of every element. Subject to fusion. replicateChar :: Int -> Char -> Text replicateChar n c = unstream (S.replicateCharI n (safe c)) {-# INLINE replicateChar #-} -- | /O(n)/, where @n@ is the length of the result. The 'unfoldr' -- function is analogous to the List 'L.unfoldr'. 'unfoldr' builds a -- 'Text' from a seed value. The function takes the element and -- returns 'Nothing' if it is done producing the 'Text', otherwise -- 'Just' @(a,b)@. In this case, @a@ is the next 'Char' in the -- string, and @b@ is the seed value for further production. Subject -- to fusion. Performs replacement on invalid scalar values. unfoldr :: (a -> Maybe (Char,a)) -> a -> Text unfoldr f s = unstream (S.unfoldr (firstf safe . f) s) {-# INLINE unfoldr #-} -- | /O(n)/ Like 'unfoldr', 'unfoldrN' builds a 'Text' from a seed -- value. However, the length of the result should be limited by the -- first argument to 'unfoldrN'. This function is more efficient than -- 'unfoldr' when the maximum length of the result is known and -- correct, otherwise its performance is similar to 'unfoldr'. Subject -- to fusion. Performs replacement on invalid scalar values. unfoldrN :: Int -> (a -> Maybe (Char,a)) -> a -> Text unfoldrN n f s = unstream (S.unfoldrN n (firstf safe . f) s) {-# INLINE unfoldrN #-} -- ----------------------------------------------------------------------------- -- * Substrings -- | /O(n)/ 'take' @n@, applied to a 'Text', returns the prefix of the -- 'Text' of length @n@, or the 'Text' itself if @n@ is greater than -- the length of the Text. Subject to fusion. take :: Int -> Text -> Text take n t@(Text arr off len) | n <= 0 = empty | n >= len = t | otherwise = text arr off (iterN n t) {-# INLINE [1] take #-} iterN :: Int -> Text -> Int iterN n t@(Text _arr _off len) = loop 0 0 where loop !i !cnt | i >= len || cnt >= n = i | otherwise = loop (i+d) (cnt+1) where d = iter_ t i {-# RULES "TEXT take -> fused" [~1] forall n t. take n t = unstream (S.take n (stream t)) "TEXT take -> unfused" [1] forall n t. unstream (S.take n (stream t)) = take n t #-} -- | /O(n)/ 'takeEnd' @n@ @t@ returns the suffix remaining after -- taking @n@ characters from the end of @t@. -- -- Examples: -- -- >>> takeEnd 3 "foobar" -- "bar" -- -- @since 1.1.1.0 takeEnd :: Int -> Text -> Text takeEnd n t@(Text arr off len) | n <= 0 = empty | n >= len = t | otherwise = text arr (off+i) (len-i) where i = iterNEnd n t iterNEnd :: Int -> Text -> Int iterNEnd n t@(Text _arr _off len) = loop (len-1) n where loop i !m | m <= 0 = i+1 | i <= 0 = 0 | otherwise = loop (i+d) (m-1) where d = reverseIter_ t i -- | /O(n)/ 'drop' @n@, applied to a 'Text', returns the suffix of the -- 'Text' after the first @n@ characters, or the empty 'Text' if @n@ -- is greater than the length of the 'Text'. Subject to fusion. drop :: Int -> Text -> Text drop n t@(Text arr off len) | n <= 0 = t | n >= len = empty | otherwise = text arr (off+i) (len-i) where i = iterN n t {-# INLINE [1] drop #-} {-# RULES "TEXT drop -> fused" [~1] forall n t. drop n t = unstream (S.drop n (stream t)) "TEXT drop -> unfused" [1] forall n t. unstream (S.drop n (stream t)) = drop n t #-} -- | /O(n)/ 'dropEnd' @n@ @t@ returns the prefix remaining after -- dropping @n@ characters from the end of @t@. -- -- Examples: -- -- >>> dropEnd 3 "foobar" -- "foo" -- -- @since 1.1.1.0 dropEnd :: Int -> Text -> Text dropEnd n t@(Text arr off len) | n <= 0 = t | n >= len = empty | otherwise = text arr off (iterNEnd n t) -- | /O(n)/ 'takeWhile', applied to a predicate @p@ and a 'Text', -- returns the longest prefix (possibly empty) of elements that -- satisfy @p@. Subject to fusion. takeWhile :: (Char -> Bool) -> Text -> Text takeWhile p t@(Text arr off len) = loop 0 where loop !i | i >= len = t | p c = loop (i+d) | otherwise = text arr off i where Iter c d = iter t i {-# INLINE [1] takeWhile #-} {-# RULES "TEXT takeWhile -> fused" [~1] forall p t. takeWhile p t = unstream (S.takeWhile p (stream t)) "TEXT takeWhile -> unfused" [1] forall p t. unstream (S.takeWhile p (stream t)) = takeWhile p t #-} -- | /O(n)/ 'takeWhileEnd', applied to a predicate @p@ and a 'Text', -- returns the longest suffix (possibly empty) of elements that -- satisfy @p@. Subject to fusion. -- Examples: -- -- >>> takeWhileEnd (=='o') "foo" -- "oo" -- -- @since 1.2.2.0 takeWhileEnd :: (Char -> Bool) -> Text -> Text takeWhileEnd p t@(Text arr off len) = loop (len-1) len where loop !i !l | l <= 0 = t | p c = loop (i+d) (l+d) | otherwise = text arr (off+l) (len-l) where (c,d) = reverseIter t i {-# INLINE [1] takeWhileEnd #-} {-# RULES "TEXT takeWhileEnd -> fused" [~1] forall p t. takeWhileEnd p t = S.reverse (S.takeWhile p (S.reverseStream t)) "TEXT takeWhileEnd -> unfused" [1] forall p t. S.reverse (S.takeWhile p (S.reverseStream t)) = takeWhileEnd p t #-} -- | /O(n)/ 'dropWhile' @p@ @t@ returns the suffix remaining after -- 'takeWhile' @p@ @t@. Subject to fusion. dropWhile :: (Char -> Bool) -> Text -> Text dropWhile p t@(Text arr off len) = loop 0 0 where loop !i !l | l >= len = empty | p c = loop (i+d) (l+d) | otherwise = Text arr (off+i) (len-l) where Iter c d = iter t i {-# INLINE [1] dropWhile #-} {-# RULES "TEXT dropWhile -> fused" [~1] forall p t. dropWhile p t = unstream (S.dropWhile p (stream t)) "TEXT dropWhile -> unfused" [1] forall p t. unstream (S.dropWhile p (stream t)) = dropWhile p t #-} -- | /O(n)/ 'dropWhileEnd' @p@ @t@ returns the prefix remaining after -- dropping characters that satisfy the predicate @p@ from the end of -- @t@. Subject to fusion. -- -- Examples: -- -- >>> dropWhileEnd (=='.') "foo..." -- "foo" dropWhileEnd :: (Char -> Bool) -> Text -> Text dropWhileEnd p t@(Text arr off len) = loop (len-1) len where loop !i !l | l <= 0 = empty | p c = loop (i+d) (l+d) | otherwise = Text arr off l where (c,d) = reverseIter t i {-# INLINE [1] dropWhileEnd #-} {-# RULES "TEXT dropWhileEnd -> fused" [~1] forall p t. dropWhileEnd p t = S.reverse (S.dropWhile p (S.reverseStream t)) "TEXT dropWhileEnd -> unfused" [1] forall p t. S.reverse (S.dropWhile p (S.reverseStream t)) = dropWhileEnd p t #-} -- | /O(n)/ 'dropAround' @p@ @t@ returns the substring remaining after -- dropping characters that satisfy the predicate @p@ from both the -- beginning and end of @t@. Subject to fusion. dropAround :: (Char -> Bool) -> Text -> Text dropAround p = dropWhile p . dropWhileEnd p {-# INLINE [1] dropAround #-} -- | /O(n)/ Remove leading white space from a string. Equivalent to: -- -- > dropWhile isSpace stripStart :: Text -> Text stripStart = dropWhile isSpace {-# INLINE [1] stripStart #-} -- | /O(n)/ Remove trailing white space from a string. Equivalent to: -- -- > dropWhileEnd isSpace stripEnd :: Text -> Text stripEnd = dropWhileEnd isSpace {-# INLINE [1] stripEnd #-} -- | /O(n)/ Remove leading and trailing white space from a string. -- Equivalent to: -- -- > dropAround isSpace strip :: Text -> Text strip = dropAround isSpace {-# INLINE [1] strip #-} -- | /O(n)/ 'splitAt' @n t@ returns a pair whose first element is a -- prefix of @t@ of length @n@, and whose second is the remainder of -- the string. It is equivalent to @('take' n t, 'drop' n t)@. splitAt :: Int -> Text -> (Text, Text) splitAt n t@(Text arr off len) | n <= 0 = (empty, t) | n >= len = (t, empty) | otherwise = let k = iterN n t in (text arr off k, text arr (off+k) (len-k)) -- | /O(n)/ 'span', applied to a predicate @p@ and text @t@, returns -- a pair whose first element is the longest prefix (possibly empty) -- of @t@ of elements that satisfy @p@, and whose second is the -- remainder of the list. span :: (Char -> Bool) -> Text -> (Text, Text) span p t = case span_ p t of (# hd,tl #) -> (hd,tl) {-# INLINE span #-} -- | /O(n)/ 'break' is like 'span', but the prefix returned is -- over elements that fail the predicate @p@. break :: (Char -> Bool) -> Text -> (Text, Text) break p = span (not . p) {-# INLINE break #-} -- | /O(n)/ Group characters in a string according to a predicate. groupBy :: (Char -> Char -> Bool) -> Text -> [Text] groupBy p = loop where loop t@(Text arr off len) | null t = [] | otherwise = text arr off n : loop (text arr (off+n) (len-n)) where Iter c d = iter t 0 n = d + findAIndexOrEnd (not . p c) (Text arr (off+d) (len-d)) -- | Returns the /array/ index (in units of 'Word16') at which a -- character may be found. This is /not/ the same as the logical -- index returned by e.g. 'findIndex'. findAIndexOrEnd :: (Char -> Bool) -> Text -> Int findAIndexOrEnd q t@(Text _arr _off len) = go 0 where go !i | i >= len || q c = i | otherwise = go (i+d) where Iter c d = iter t i -- | /O(n)/ Group characters in a string by equality. group :: Text -> [Text] group = groupBy (==) -- | /O(n)/ Return all initial segments of the given 'Text', shortest -- first. inits :: Text -> [Text] inits t@(Text arr off len) = loop 0 where loop i | i >= len = [t] | otherwise = Text arr off i : loop (i + iter_ t i) -- | /O(n)/ Return all final segments of the given 'Text', longest -- first. tails :: Text -> [Text] tails t | null t = [empty] | otherwise = t : tails (unsafeTail t) -- $split -- -- Splitting functions in this library do not perform character-wise -- copies to create substrings; they just construct new 'Text's that -- are slices of the original. -- | /O(m+n)/ Break a 'Text' into pieces separated by the first 'Text' -- argument (which cannot be empty), consuming the delimiter. An empty -- delimiter is invalid, and will cause an error to be raised. -- -- Examples: -- -- >>> splitOn "\r\n" "a\r\nb\r\nd\r\ne" -- ["a","b","d","e"] -- -- >>> splitOn "aaa" "aaaXaaaXaaaXaaa" -- ["","X","X","X",""] -- -- >>> splitOn "x" "x" -- ["",""] -- -- and -- -- > intercalate s . splitOn s == id -- > splitOn (singleton c) == split (==c) -- -- (Note: the string @s@ to split on above cannot be empty.) -- -- In (unlikely) bad cases, this function's time complexity degrades -- towards /O(n*m)/. splitOn :: Text -- ^ String to split on. If this string is empty, an error -- will occur. -> Text -- ^ Input text. -> [Text] splitOn pat@(Text _ _ l) src@(Text arr off len) | l <= 0 = emptyError "splitOn" | isSingleton pat = split (== unsafeHead pat) src | otherwise = go 0 (indices pat src) where go !s (x:xs) = text arr (s+off) (x-s) : go (x+l) xs go s _ = [text arr (s+off) (len-s)] {-# INLINE [1] splitOn #-} {-# RULES "TEXT splitOn/singleton -> split/==" [~1] forall c t. splitOn (singleton c) t = split (==c) t #-} -- | /O(n)/ Splits a 'Text' 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. -- -- >>> split (=='a') "aabbaca" -- ["","","bb","c",""] -- -- >>> split (=='a') "" -- [""] split :: (Char -> Bool) -> Text -> [Text] split _ t@(Text _off _arr 0) = [t] split p t = loop t where loop s | null s' = [l] | otherwise = l : loop (unsafeTail s') where (# l, s' #) = span_ (not . p) s {-# INLINE split #-} -- | /O(n)/ Splits a 'Text' into components of length @k@. The last -- element may be shorter than the other chunks, depending on the -- length of the input. Examples: -- -- >>> chunksOf 3 "foobarbaz" -- ["foo","bar","baz"] -- -- >>> chunksOf 4 "haskell.org" -- ["hask","ell.","org"] chunksOf :: Int -> Text -> [Text] chunksOf k = go where go t = case splitAt k t of (a,b) | null a -> [] | otherwise -> a : go b {-# INLINE chunksOf #-} -- ---------------------------------------------------------------------------- -- * Searching ------------------------------------------------------------------------------- -- ** Searching with a predicate -- | /O(n)/ The 'find' function takes a predicate and a 'Text', and -- returns the first element matching the predicate, or 'Nothing' if -- there is no such element. find :: (Char -> Bool) -> Text -> Maybe Char find p t = S.findBy p (stream t) {-# INLINE find #-} -- | /O(n)/ The 'partition' function takes a predicate and a 'Text', -- and returns the pair of 'Text's with elements which do and do not -- satisfy the predicate, respectively; i.e. -- -- > partition p t == (filter p t, filter (not . p) t) partition :: (Char -> Bool) -> Text -> (Text, Text) partition p t = (filter p t, filter (not . p) t) {-# INLINE partition #-} -- | /O(n)/ 'filter', applied to a predicate and a 'Text', -- returns a 'Text' containing those characters that satisfy the -- predicate. filter :: (Char -> Bool) -> Text -> Text filter p t = unstream (S.filter p (stream t)) {-# INLINE filter #-} -- | /O(n+m)/ Find the first instance of @needle@ (which must be -- non-'null') in @haystack@. The first element of the returned tuple -- is the prefix of @haystack@ before @needle@ is matched. The second -- is the remainder of @haystack@, starting with the match. -- -- Examples: -- -- >>> breakOn "::" "a::b::c" -- ("a","::b::c") -- -- >>> breakOn "/" "foobar" -- ("foobar","") -- -- Laws: -- -- > append prefix match == haystack -- > where (prefix, match) = breakOn needle haystack -- -- If you need to break a string by a substring repeatedly (e.g. you -- want to break on every instance of a substring), use 'breakOnAll' -- instead, as it has lower startup overhead. -- -- In (unlikely) bad cases, this function's time complexity degrades -- towards /O(n*m)/. breakOn :: Text -> Text -> (Text, Text) breakOn pat src@(Text arr off len) | null pat = emptyError "breakOn" | otherwise = case indices pat src of [] -> (src, empty) (x:_) -> (text arr off x, text arr (off+x) (len-x)) {-# INLINE breakOn #-} -- | /O(n+m)/ Similar to 'breakOn', but searches from the end of the -- string. -- -- The first element of the returned tuple is the prefix of @haystack@ -- up to and including the last match of @needle@. The second is the -- remainder of @haystack@, following the match. -- -- >>> breakOnEnd "::" "a::b::c" -- ("a::b::","c") breakOnEnd :: Text -> Text -> (Text, Text) breakOnEnd pat src = (reverse b, reverse a) where (a,b) = breakOn (reverse pat) (reverse src) {-# INLINE breakOnEnd #-} -- | /O(n+m)/ Find all non-overlapping instances of @needle@ in -- @haystack@. Each element of the returned list consists of a pair: -- -- * The entire string prior to the /k/th match (i.e. the prefix) -- -- * The /k/th match, followed by the remainder of the string -- -- Examples: -- -- >>> breakOnAll "::" "" -- [] -- -- >>> breakOnAll "/" "a/b/c/" -- [("a","/b/c/"),("a/b","/c/"),("a/b/c","/")] -- -- In (unlikely) bad cases, this function's time complexity degrades -- towards /O(n*m)/. -- -- The @needle@ parameter may not be empty. breakOnAll :: Text -- ^ @needle@ to search for -> Text -- ^ @haystack@ in which to search -> [(Text, Text)] breakOnAll pat src@(Text arr off slen) | null pat = emptyError "breakOnAll" | otherwise = L.map step (indices pat src) where step x = (chunk 0 x, chunk x (slen-x)) chunk !n !l = text arr (n+off) l {-# INLINE breakOnAll #-} ------------------------------------------------------------------------------- -- ** Indexing 'Text's -- $index -- -- If you think of a 'Text' value as an array of 'Char' values (which -- it is not), you run the risk of writing inefficient code. -- -- An idiom that is common in some languages is to find the numeric -- offset of a character or substring, then use that number to split -- or trim the searched string. With a 'Text' value, this approach -- would require two /O(n)/ operations: one to perform the search, and -- one to operate from wherever the search ended. -- -- For example, suppose you have a string that you want to split on -- the substring @\"::\"@, such as @\"foo::bar::quux\"@. Instead of -- searching for the index of @\"::\"@ and taking the substrings -- before and after that index, you would instead use @breakOnAll \"::\"@. -- | /O(n)/ 'Text' index (subscript) operator, starting from 0. index :: Text -> Int -> Char index t n = S.index (stream t) n {-# INLINE index #-} -- | /O(n)/ The 'findIndex' function takes a predicate and a 'Text' -- and returns the index of the first element in the 'Text' satisfying -- the predicate. Subject to fusion. findIndex :: (Char -> Bool) -> Text -> Maybe Int findIndex p t = S.findIndex p (stream t) {-# INLINE findIndex #-} -- | /O(n+m)/ The 'count' function returns the number of times the -- query string appears in the given 'Text'. An empty query string is -- invalid, and will cause an error to be raised. -- -- In (unlikely) bad cases, this function's time complexity degrades -- towards /O(n*m)/. count :: Text -> Text -> Int count pat src | null pat = emptyError "count" | isSingleton pat = countChar (unsafeHead pat) src | otherwise = L.length (indices pat src) {-# INLINE [1] count #-} {-# RULES "TEXT count/singleton -> countChar" [~1] forall c t. count (singleton c) t = countChar c t #-} -- | /O(n)/ The 'countChar' function returns the number of times the -- query element appears in the given 'Text'. Subject to fusion. countChar :: Char -> Text -> Int countChar c t = S.countChar c (stream t) {-# INLINE countChar #-} ------------------------------------------------------------------------------- -- * Zipping -- | /O(n)/ 'zip' takes two 'Text's and returns a list of -- corresponding pairs of bytes. If one input 'Text' is short, -- excess elements of the longer 'Text' are discarded. This is -- equivalent to a pair of 'unpack' operations. zip :: Text -> Text -> [(Char,Char)] zip a b = S.unstreamList $ S.zipWith (,) (stream a) (stream b) {-# INLINE zip #-} -- | /O(n)/ 'zipWith' generalises 'zip' by zipping with the function -- given as the first argument, instead of a tupling function. -- Performs replacement on invalid scalar values. zipWith :: (Char -> Char -> Char) -> Text -> Text -> Text zipWith f t1 t2 = unstream (S.zipWith g (stream t1) (stream t2)) where g a b = safe (f a b) {-# INLINE zipWith #-} -- | /O(n)/ Breaks a 'Text' up into a list of words, delimited by 'Char's -- representing white space. words :: Text -> [Text] words t@(Text arr off len) = loop 0 0 where loop !start !n | n >= len = if start == n then [] else [Text arr (start+off) (n-start)] | isSpace c = if start == n then loop (start+d) (start+d) else Text arr (start+off) (n-start) : loop (n+d) (n+d) | otherwise = loop start (n+d) where Iter c d = iter t n {-# INLINE words #-} -- | /O(n)/ Breaks a 'Text' up into a list of 'Text's at -- newline 'Char's. The resulting strings do not contain newlines. lines :: Text -> [Text] lines ps | null ps = [] | otherwise = h : if null t then [] else lines (unsafeTail t) where (# h,t #) = span_ (/= '\n') ps {-# INLINE lines #-} {- -- | /O(n)/ Portably breaks a 'Text' up into a list of 'Text's at line -- boundaries. -- -- A line boundary is considered to be either a line feed, a carriage -- return immediately followed by a line feed, or a carriage return. -- This accounts for both Unix and Windows line ending conventions, -- and for the old convention used on Mac OS 9 and earlier. lines' :: Text -> [Text] lines' ps | null ps = [] | otherwise = h : case uncons t of Nothing -> [] Just (c,t') | c == '\n' -> lines t' | c == '\r' -> case uncons t' of Just ('\n',t'') -> lines t'' _ -> lines t' where (h,t) = span notEOL ps notEOL c = c /= '\n' && c /= '\r' {-# INLINE lines' #-} -} -- | /O(n)/ Joins lines, after appending a terminating newline to -- each. unlines :: [Text] -> Text unlines = concat . L.map (`snoc` '\n') {-# INLINE unlines #-} -- | /O(n)/ Joins words using single space characters. unwords :: [Text] -> Text unwords = intercalate (singleton ' ') {-# INLINE unwords #-} -- | /O(n)/ The 'isPrefixOf' function takes two 'Text's and returns -- 'True' iff the first is a prefix of the second. Subject to fusion. isPrefixOf :: Text -> Text -> Bool isPrefixOf a@(Text _ _ alen) b@(Text _ _ blen) = alen <= blen && S.isPrefixOf (stream a) (stream b) {-# INLINE [1] isPrefixOf #-} {-# RULES "TEXT isPrefixOf -> fused" [~1] forall s t. isPrefixOf s t = S.isPrefixOf (stream s) (stream t) #-} -- | /O(n)/ The 'isSuffixOf' function takes two 'Text's and returns -- 'True' iff the first is a suffix of the second. isSuffixOf :: Text -> Text -> Bool isSuffixOf a@(Text _aarr _aoff alen) b@(Text barr boff blen) = d >= 0 && a == b' where d = blen - alen b' | d == 0 = b | otherwise = Text barr (boff+d) alen {-# INLINE isSuffixOf #-} -- | /O(n+m)/ The 'isInfixOf' function takes two 'Text's and returns -- 'True' iff the first is contained, wholly and intact, anywhere -- within the second. -- -- In (unlikely) bad cases, this function's time complexity degrades -- towards /O(n*m)/. isInfixOf :: Text -> Text -> Bool isInfixOf needle haystack | null needle = True | isSingleton needle = S.elem (unsafeHead needle) . S.stream $ haystack | otherwise = not . L.null . indices needle $ haystack {-# INLINE [1] isInfixOf #-} {-# RULES "TEXT isInfixOf/singleton -> S.elem/S.stream" [~1] forall n h. isInfixOf (singleton n) h = S.elem n (S.stream h) #-} ------------------------------------------------------------------------------- -- * View patterns -- | /O(n)/ Return the suffix of the second string if its prefix -- matches the entire first string. -- -- Examples: -- -- >>> stripPrefix "foo" "foobar" -- Just "bar" -- -- >>> stripPrefix "" "baz" -- Just "baz" -- -- >>> stripPrefix "foo" "quux" -- Nothing -- -- This is particularly useful with the @ViewPatterns@ extension to -- GHC, as follows: -- -- > {-# LANGUAGE ViewPatterns #-} -- > import Data.Text as T -- > -- > fnordLength :: Text -> Int -- > fnordLength (stripPrefix "fnord" -> Just suf) = T.length suf -- > fnordLength _ = -1 stripPrefix :: Text -> Text -> Maybe Text stripPrefix p@(Text _arr _off plen) t@(Text arr off len) | p `isPrefixOf` t = Just $! text arr (off+plen) (len-plen) | otherwise = Nothing -- | /O(n)/ Find the longest non-empty common prefix of two strings -- and return it, along with the suffixes of each string at which they -- no longer match. -- -- If the strings do not have a common prefix or either one is empty, -- this function returns 'Nothing'. -- -- Examples: -- -- >>> commonPrefixes "foobar" "fooquux" -- Just ("foo","bar","quux") -- -- >>> commonPrefixes "veeble" "fetzer" -- Nothing -- -- >>> commonPrefixes "" "baz" -- Nothing commonPrefixes :: Text -> Text -> Maybe (Text,Text,Text) commonPrefixes t0@(Text arr0 off0 len0) t1@(Text arr1 off1 len1) = go 0 0 where go !i !j | i < len0 && j < len1 && a == b = go (i+d0) (j+d1) | i > 0 = Just (Text arr0 off0 i, text arr0 (off0+i) (len0-i), text arr1 (off1+j) (len1-j)) | otherwise = Nothing where Iter a d0 = iter t0 i Iter b d1 = iter t1 j -- | /O(n)/ Return the prefix of the second string if its suffix -- matches the entire first string. -- -- Examples: -- -- >>> stripSuffix "bar" "foobar" -- Just "foo" -- -- >>> stripSuffix "" "baz" -- Just "baz" -- -- >>> stripSuffix "foo" "quux" -- Nothing -- -- This is particularly useful with the @ViewPatterns@ extension to -- GHC, as follows: -- -- > {-# LANGUAGE ViewPatterns #-} -- > import Data.Text as T -- > -- > quuxLength :: Text -> Int -- > quuxLength (stripSuffix "quux" -> Just pre) = T.length pre -- > quuxLength _ = -1 stripSuffix :: Text -> Text -> Maybe Text stripSuffix p@(Text _arr _off plen) t@(Text arr off len) | p `isSuffixOf` t = Just $! text arr off (len-plen) | otherwise = Nothing -- | Add a list of non-negative numbers. Errors out on overflow. sumP :: String -> [Int] -> Int sumP fun = go 0 where go !a (x:xs) | ax >= 0 = go ax xs | otherwise = overflowError fun where ax = a + x go a _ = a emptyError :: String -> a emptyError fun = P.error $ "Data.Text." ++ fun ++ ": empty input" overflowError :: String -> a overflowError fun = P.error $ "Data.Text." ++ fun ++ ": size overflow" -- | /O(n)/ Make a distinct copy of the given string, sharing no -- storage with the original string. -- -- As an example, suppose you read a large string, of which you need -- only a small portion. If you do not use 'copy', the entire original -- array will be kept alive in memory by the smaller string. Making a -- copy \"breaks the link\" to the original array, allowing it to be -- garbage collected if there are no other live references to it. copy :: Text -> Text copy (Text arr off len) = Text (A.run go) 0 len where go :: ST s (A.MArray s) go = do marr <- A.new len A.copyI marr 0 arr off len return marr ------------------------------------------------- -- NOTE: the named chunk below used by doctest; -- verify the doctests via `doctest -fobject-code Data/Text.hs` -- $setup -- >>> :set -XOverloadedStrings -- >>> import qualified Data.Text as T