{-# LINE 1 "Data/Text/ICU/Normalize2.hsc" #-} {-# LANGUAGE EmptyDataDecls, CPP, DeriveDataTypeable, ForeignFunctionInterface #-} -- | -- Module : Data.Text.ICU.Normalize -- Copyright : (c) 2009, 2010 Bryan O'Sullivan -- -- License : BSD-style -- Maintainer : bos@serpentine.com -- Stability : experimental -- Portability : GHC -- -- Character set normalization functions for Unicode, implemented as -- bindings to the International Components for Unicode (ICU) -- libraries. See http://www.unicode.org/reports/tr15/ for a description -- of Unicode normalization modes and why these are needed. module Data.Text.ICU.Normalize2 ( -- * Unicode normalization API -- $api -- * Create normalizers NormalizationMode(..), normalizer, nfcNormalizer, nfdNormalizer, nfkcNormalizer, nfkdNormalizer, nfkcCasefoldNormalizer, -- * Normalize unicode strings nfc, nfd, nfkc, nfkd, nfkcCasefold, normalize, normalizeWith, -- * Checks for normalization quickCheck, isNormalized, isNormalizedWith, -- * Comparison of unicode strings compareUnicode, compareUnicode', CompareOption(..), ) where {-# LINE 33 "Data/Text/ICU/Normalize2.hsc" #-} import Data.Text (Text) import Data.Text.ICU.Error.Internal (UErrorCode, handleError, handleOverflowError) import Data.Text.ICU.Internal (UBool, UChar, asBool, asOrdering, fromUCharPtr, useAsUCharPtr) import Data.Text.ICU.Normalize.Internal (UNormalizationCheckResult, toNCR) import Data.Typeable (Typeable) import Data.Int (Int32) import Data.Word (Word32) import Foreign.C.Types (CInt(..)) import Foreign.Ptr (Ptr) import System.IO.Unsafe (unsafePerformIO) import Prelude hiding (compare) import Data.List (foldl') import Data.Bits ((.|.)) -- $api -- -- The 'normalize' function transforms Unicode text into an equivalent -- composed or decomposed form, allowing for easier sorting and -- searching of text. 'normalize' supports the standard normalization -- forms described in <http://www.unicode.org/unicode/reports/tr15/>, -- Unicode Standard Annex #15: Unicode Normalization Forms. -- -- Characters with accents or other adornments can be encoded in -- several different ways in Unicode. For example, take the character A-acute. -- In Unicode, this can be encoded as a single character (the -- \"composed\" form): -- -- @ -- 00C1 LATIN CAPITAL LETTER A WITH ACUTE -- @ -- -- or as two separate characters (the \"decomposed\" form): -- -- @ -- 0041 LATIN CAPITAL LETTER A -- 0301 COMBINING ACUTE ACCENT -- @ -- -- To a user of your program, however, both of these sequences should -- be treated as the same \"user-level\" character \"A with acute -- accent\". When you are searching or comparing text, you must -- ensure that these two sequences are treated equivalently. In -- addition, you must handle characters with more than one accent. -- Sometimes the order of a character's combining accents is -- significant, while in other cases accent sequences in different -- orders are really equivalent. -- -- Similarly, the string \"ffi\" can be encoded as three separate letters: -- -- @ -- 0066 LATIN SMALL LETTER F -- 0066 LATIN SMALL LETTER F -- 0069 LATIN SMALL LETTER I -- @ -- -- or as the single character -- -- @ -- FB03 LATIN SMALL LIGATURE FFI -- @ -- -- The \"ffi\" ligature is not a distinct semantic character, and -- strictly speaking it shouldn't be in Unicode at all, but it was -- included for compatibility with existing character sets that -- already provided it. The Unicode standard identifies such -- characters by giving them \"compatibility\" decompositions into the -- corresponding semantic characters. When sorting and searching, you -- will often want to use these mappings. -- -- 'normalize' helps solve these problems by transforming text into -- the canonical composed and decomposed forms as shown in the first -- example above. In addition, you can have it perform compatibility -- decompositions so that you can treat compatibility characters the -- same as their equivalents. Finally, 'normalize' rearranges accents -- into the proper canonical order, so that you do not have to worry -- about accent rearrangement on your own. -- -- Form 'FCD', \"Fast C or D\", is also designed for collation. It -- allows to work on strings that are not necessarily normalized with -- an algorithm (like in collation) that works under \"canonical -- closure\", i.e., it treats precomposed characters and their -- decomposed equivalents the same. -- -- It is not a normalization form because it does not provide for -- uniqueness of representation. Multiple strings may be canonically -- equivalent (their NFDs are identical) and may all conform to 'FCD' -- without being identical themselves. -- -- The form is defined such that the \"raw decomposition\", the -- recursive canonical decomposition of each character, results in a -- string that is canonically ordered. This means that precomposed -- characters are allowed for as long as their decompositions do not -- need canonical reordering. -- -- Its advantage for a process like collation is that all 'NFD' and -- most 'NFC' texts - and many unnormalized texts - already conform to -- 'FCD' and do not need to be normalized ('NFD') for such a -- process. The 'FCD' 'quickCheck' will return 'Yes' for most strings -- in practice. -- -- @'normalize' 'FCD'@ may be implemented with 'NFD'. -- -- For more details on 'FCD' see the collation design document: -- <http://source.icu-project.org/repos/icu/icuhtml/trunk/design/collation/ICU_collation_design.htm> -- -- ICU collation performs either 'NFD' or 'FCD' normalization -- automatically if normalization is turned on for the collator -- object. Beyond collation and string search, normalized strings may -- be useful for string equivalence comparisons, -- transliteration/transcription, unique representations, etc. -- -- The W3C generally recommends to exchange texts in 'NFC'. Note also -- that most legacy character encodings use only precomposed forms and -- often do not encode any combining marks by themselves. For -- conversion to such character encodings the Unicode text needs to be -- normalized to 'NFC'. For more usage examples, see the Unicode -- Standard Annex. -- | This is an abstract data type holding a reference to the ICU `UNormalizer2` object. newtype Normalizer = Normalizer (Ptr UNormalizer2) data UNormalizer2 -- | Normalization modes analog (but not identical) to the ones in the -- 'Data.Text.ICU.Normalize' module. data NormalizationMode = NFD -- ^ Canonical decomposition. | NFKD -- ^ Compatibility decomposition. | NFC -- ^ Canonical decomposition followed by canonical composition. | NFKC -- ^ Compatibility decomposition followed by canonical composition. | NFKCCasefold -- ^ NFKC with Casefold. deriving (Eq, Show, Enum, Typeable) createNormalizerWith :: (Ptr UErrorCode -> IO (Ptr UNormalizer2)) -> IO Normalizer createNormalizerWith f = Normalizer <$> handleError f -- from the ICU documentation: "Returns an unmodifiable singleton instance of `unorm2_getInstance()`. Do not delete it." -- Thats why we use raw pointer here. -- | Create a normalizer for a given normalization mode. This function is more similar to -- the interface in the 'Data.Text.ICU.Normalize' module. normalizer :: NormalizationMode -> IO Normalizer normalizer NFD = nfdNormalizer normalizer NFKD = nfkdNormalizer normalizer NFC = nfcNormalizer normalizer NFKC = nfkcNormalizer normalizer NFKCCasefold = nfkcCasefoldNormalizer -- | Create an NFC normalizer. nfcNormalizer :: IO Normalizer nfcNormalizer = createNormalizerWith unorm2_getNFCInstance -- | Create an NFD normalizer. nfdNormalizer :: IO Normalizer nfdNormalizer = createNormalizerWith unorm2_getNFDInstance -- | Create an NFKC normalizer. nfkcNormalizer :: IO Normalizer nfkcNormalizer = createNormalizerWith unorm2_getNFKCInstance -- | Create an NFKD normalizer. nfkdNormalizer :: IO Normalizer nfkdNormalizer = createNormalizerWith unorm2_getNFKDInstance -- | Create an NFKCCasefold normalizer. nfkcCasefoldNormalizer :: IO Normalizer nfkcCasefoldNormalizer = createNormalizerWith unorm2_getNFKCCasefoldInstance -- * Normalization -- | Normalize a string with the given normalizer. normalizeWith :: Normalizer -> Text -> Text normalizeWith (Normalizer nfPtr) t = unsafePerformIO $ useAsUCharPtr t $ \sptr slen -> let slen' = fromIntegral slen in handleOverflowError (fromIntegral slen) (\dptr dlen -> unorm2_normalize nfPtr sptr slen' dptr (fromIntegral dlen)) (\dptr dlen -> fromUCharPtr dptr (fromIntegral dlen)) -- | Normalize a string using the given normalization mode. normalize :: NormalizationMode -> Text -> Text normalize NFC = nfc normalize NFD = nfd normalize NFKC = nfkc normalize NFKD = nfkd normalize NFKCCasefold = nfkcCasefold -- | Create an NFC normalizer and apply this to the given text. -- -- Let's have a look at a concrete example that contains the letter a with an acute accent twice. -- First as a combination of two codepoints and second as a canonical composite or precomposed -- character. Both look exactly the same but one character consists of two and one of only one -- codepoint. A bytewise comparison does not give equality of these. -- -- >>> import Data.Text -- >>> let t = pack "a\x301á" -- >>> t -- "a\769\225" -- >>> putStr t -- áá -- pack "a\x301" == pack "á" -- False -- -- But now lets apply some normalization functions and see how these characters coincide afterwards -- in two different ways: -- -- >>> nfc t -- "\225\225" -- >>> nfd t -- "a\769a\769" -- -- That is exactly what 'compareUnicode'' does: -- -- >>> pack "a\x301" `compareUnicode'` pack "á" nfc :: Text -> Text nfc t = unsafePerformIO $ do nf <- nfcNormalizer pure $ normalizeWith nf t -- | Create an NFKC normalizer and apply this to the given text. nfkc :: Text -> Text nfkc t = unsafePerformIO $ do nf <- nfkcNormalizer pure $ normalizeWith nf t -- | Create an NFD normalizer and apply this to the given text. nfd :: Text -> Text nfd t = unsafePerformIO $ do nf <- nfdNormalizer pure $ normalizeWith nf t -- | Create an NFC normalizer and apply this to the given text. nfkd :: Text -> Text nfkd t = unsafePerformIO $ do nf <- nfkdNormalizer pure $ normalizeWith nf t -- | Create an NFKCCasefold normalizer and apply this to the given text. nfkcCasefold :: Text -> Text nfkcCasefold t = unsafePerformIO $ do nf <- nfkcCasefoldNormalizer pure $ normalizeWith nf t -- * Checks for normalization -- | Perform an efficient check on a string, to quickly determine if -- the string is in a particular normalization form. -- -- A 'Nothing' result indicates that a definite answer could not be -- determined quickly, and a more thorough check is required, -- e.g. with 'isNormalized'. The user may have to convert the string -- to its normalized form and compare the results. -- -- A result of 'Just' 'True' or 'Just' 'False' indicates that the -- string definitely is, or is not, in the given normalization form. quickCheckWith :: Normalizer -> Text -> Maybe Bool quickCheckWith (Normalizer nfPtr) t = unsafePerformIO $ useAsUCharPtr t $ \sptr slen -> fmap toNCR . handleError $ unorm2_quickCheck nfPtr sptr (fromIntegral slen) quickCheck :: NormalizationMode -> Text -> Maybe Bool quickCheck NFD t = unsafePerformIO $ do nf <- nfdNormalizer pure $ quickCheckWith nf t quickCheck NFC t = unsafePerformIO $ do nf <- nfcNormalizer pure $ quickCheckWith nf t quickCheck NFKD t = unsafePerformIO $ do nf <- nfkdNormalizer pure $ quickCheckWith nf t quickCheck NFKC t = unsafePerformIO $ do nf <- nfkcNormalizer pure $ quickCheckWith nf t quickCheck NFKCCasefold t = unsafePerformIO $ do nf <- nfkcCasefoldNormalizer pure $ quickCheckWith nf t -- | Indicate whether a string is in a given normalization form. -- -- Unlike 'quickCheck', this function returns a definitive result. -- For 'NFD' and 'NFKD' normalization forms, both functions -- work in exactly the same ways. For 'NFC' and 'NFKC' forms, where -- 'quickCheck' may return 'Nothing', this function will perform -- further tests to arrive at a definitive result. isNormalizedWith :: Normalizer -> Text -> Bool isNormalizedWith (Normalizer nfPtr) t = unsafePerformIO $ useAsUCharPtr t $ \sptr slen -> fmap asBool . handleError $ unorm2_isNormalized nfPtr sptr (fromIntegral slen) isNormalized :: NormalizationMode -> Text -> Bool isNormalized NFD t = unsafePerformIO $ do nf <- nfdNormalizer pure $ isNormalizedWith nf t isNormalized NFC t = unsafePerformIO $ do nf <- nfcNormalizer pure $ isNormalizedWith nf t isNormalized NFKD t = unsafePerformIO $ do nf <- nfkdNormalizer pure $ isNormalizedWith nf t isNormalized NFKC t = unsafePerformIO $ do nf <- nfkcNormalizer pure $ isNormalizedWith nf t isNormalized NFKCCasefold t = unsafePerformIO $ do nf <- nfkcCasefoldNormalizer pure $ isNormalizedWith nf t -- * Comparison type UCompareOption = Word32 -- | Options to 'compare'. data CompareOption = InputIsFCD -- ^ The caller knows that both strings fulfill the -- 'FCD' conditions. If /not/ set, 'compare' will -- 'quickCheck' for 'FCD' and normalize if -- necessary. | CompareIgnoreCase -- ^ Compare strings case-insensitively using case -- folding, instead of case-sensitively. If set, -- then the following case folding options are -- used. | FoldCaseExcludeSpecialI -- ^ When case folding, exclude the special I -- character. For use with Turkic -- (Turkish/Azerbaijani) text data. deriving (Eq, Show, Enum, Typeable) fromCompareOption :: CompareOption -> UCompareOption fromCompareOption InputIsFCD = 131072 {-# LINE 365 "Data/Text/ICU/Normalize2.hsc" #-} fromCompareOption CompareIgnoreCase = 65536 {-# LINE 366 "Data/Text/ICU/Normalize2.hsc" #-} fromCompareOption FoldCaseExcludeSpecialI = 1 {-# LINE 367 "Data/Text/ICU/Normalize2.hsc" #-} reduceCompareOptions :: [CompareOption] -> UCompareOption reduceCompareOptions = foldl' orO (32768) {-# LINE 370 "Data/Text/ICU/Normalize2.hsc" #-} where a `orO` b = a .|. fromCompareOption b -- | Compare two strings for canonical equivalence. Further options -- include case-insensitive comparison and codepoint order (as -- opposed to code unit order). -- -- Canonical equivalence between two strings is defined as their -- normalized forms ('NFD' or 'NFC') being identical. This function -- compares strings incrementally instead of normalizing (and -- optionally case-folding) both strings entirely, improving -- performance significantly. -- -- Bulk normalization is only necessary if the strings do not fulfill -- the 'FCD' conditions. Only in this case, and only if the strings -- are relatively long, is memory allocated temporarily. For 'FCD' -- strings and short non-'FCD' strings there is no memory allocation. compareUnicode :: [CompareOption] -> Text -> Text -> Ordering compareUnicode opts a b = unsafePerformIO $ do useAsUCharPtr a $ \aptr alen -> useAsUCharPtr b $ \bptr blen -> fmap asOrdering . handleError $ unorm_compare aptr (fromIntegral alen) bptr (fromIntegral blen) (reduceCompareOptions opts) -- | This is equivalent to `compareUnicode []`. compareUnicode' :: Text -> Text -> Ordering compareUnicode' = compareUnicode [] foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_getNFCInstance" unorm2_getNFCInstance :: Ptr UErrorCode -> IO (Ptr UNormalizer2) foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_getNFDInstance" unorm2_getNFDInstance :: Ptr UErrorCode -> IO (Ptr UNormalizer2) foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_getNFKCInstance" unorm2_getNFKCInstance :: Ptr UErrorCode -> IO (Ptr UNormalizer2) foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_getNFKDInstance" unorm2_getNFKDInstance :: Ptr UErrorCode -> IO (Ptr UNormalizer2) foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_getNFKCCasefoldInstance" unorm2_getNFKCCasefoldInstance :: Ptr UErrorCode -> IO (Ptr UNormalizer2) foreign import ccall unsafe "hs_text_icu.h __hs_unorm_compare" unorm_compare :: Ptr UChar -> Int32 -> Ptr UChar -> Int32 -> Word32 -> Ptr UErrorCode -> IO Int32 foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_quickCheck" unorm2_quickCheck :: Ptr UNormalizer2 -> Ptr UChar -> Int32 -> Ptr UErrorCode -> IO UNormalizationCheckResult foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_isNormalized" unorm2_isNormalized :: Ptr UNormalizer2 -> Ptr UChar -> Int32 -> Ptr UErrorCode -> IO UBool foreign import ccall unsafe "hs_text_icu.h __hs_unorm2_normalize" unorm2_normalize :: Ptr UNormalizer2 -> Ptr UChar -> Int32 -> Ptr UChar -> Int32 -> Ptr UErrorCode -> IO Int32