{-# LANGUAGE CPP #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE Rank2Types #-} #if __GLASGOW_HASKELL__ >= 800 -- a) THQ works on cross-compilers and unregisterised GHCs -- b) may make compilation faster as no dynamic loading is ever needed (not sure about this) -- c) removes one hindrance to have code inferred as SafeHaskell safe {-# LANGUAGE TemplateHaskellQuotes #-} #else {-# LANGUAGE TemplateHaskell #-} #endif -- | -- Module: Data.Aeson.Types.Internal -- Copyright: (c) 2011-2016 Bryan O'Sullivan -- (c) 2011 MailRank, Inc. -- License: BSD3 -- Maintainer: Bryan O'Sullivan -- Stability: experimental -- Portability: portable -- -- Types for working with JSON data. module Data.Aeson.Types.Internal ( -- * Core JSON types Value(..) , Array , emptyArray, isEmptyArray , Pair , Object , emptyObject -- * Type conversion , Parser , Result(..) , IResult(..) , JSONPathElement(..) , JSONPath , iparse , parse , parseEither , parseMaybe , modifyFailure , formatError , () -- * Constructors and accessors , object -- * Generic and TH encoding configuration , Options( fieldLabelModifier , constructorTagModifier , allNullaryToStringTag , omitNothingFields , sumEncoding , unwrapUnaryRecords , tagSingleConstructors ) , SumEncoding(..) , defaultOptions , defaultTaggedObject -- * Used for changing CamelCase names into something else. , camelTo , camelTo2 -- * Other types , DotNetTime(..) ) where import Prelude () import Prelude.Compat import Control.Applicative (Alternative(..)) import Control.Arrow (first) import Control.DeepSeq (NFData(..)) import Control.Monad (MonadPlus(..), ap) import Data.Char (isLower, isUpper, toLower, isAlpha, isAlphaNum) import Data.Data (Data) import Data.Foldable (foldl') import Data.HashMap.Strict (HashMap) import Data.Hashable (Hashable(..)) import Data.List (intercalate) import Data.Scientific (Scientific) import Data.Semigroup (Semigroup((<>))) import Data.String (IsString(..)) import Data.Text (Text, pack, unpack) import Data.Time (UTCTime) import Data.Time.Format (FormatTime) import Data.Typeable (Typeable) import Data.Vector (Vector) import qualified Control.Monad.Fail as Fail import qualified Data.HashMap.Strict as H import qualified Data.Scientific as S import qualified Data.Vector as V import qualified Language.Haskell.TH.Syntax as TH #if !MIN_VERSION_unordered_containers(0,2,6) import Data.List (sort) #endif -- | Elements of a JSON path used to describe the location of an -- error. data JSONPathElement = Key Text -- ^ JSON path element of a key into an object, -- \"object.key\". | Index {-# UNPACK #-} !Int -- ^ JSON path element of an index into an -- array, \"array[index]\". deriving (Eq, Show, Typeable) type JSONPath = [JSONPathElement] -- | The internal result of running a 'Parser'. data IResult a = IError JSONPath String | ISuccess a deriving (Eq, Show, Typeable) -- | The result of running a 'Parser'. data Result a = Error String | Success a deriving (Eq, Show, Typeable) instance NFData JSONPathElement where rnf (Key t) = rnf t rnf (Index i) = rnf i instance (NFData a) => NFData (IResult a) where rnf (ISuccess a) = rnf a rnf (IError path err) = rnf path `seq` rnf err instance (NFData a) => NFData (Result a) where rnf (Success a) = rnf a rnf (Error err) = rnf err instance Functor IResult where fmap f (ISuccess a) = ISuccess (f a) fmap _ (IError path err) = IError path err {-# INLINE fmap #-} instance Functor Result where fmap f (Success a) = Success (f a) fmap _ (Error err) = Error err {-# INLINE fmap #-} instance Monad IResult where return = pure {-# INLINE return #-} ISuccess a >>= k = k a IError path err >>= _ = IError path err {-# INLINE (>>=) #-} fail = Fail.fail {-# INLINE fail #-} instance Fail.MonadFail IResult where fail err = IError [] err {-# INLINE fail #-} instance Monad Result where return = pure {-# INLINE return #-} Success a >>= k = k a Error err >>= _ = Error err {-# INLINE (>>=) #-} fail = Fail.fail {-# INLINE fail #-} instance Fail.MonadFail Result where fail err = Error err {-# INLINE fail #-} instance Applicative IResult where pure = ISuccess {-# INLINE pure #-} (<*>) = ap {-# INLINE (<*>) #-} instance Applicative Result where pure = Success {-# INLINE pure #-} (<*>) = ap {-# INLINE (<*>) #-} instance MonadPlus IResult where mzero = fail "mzero" {-# INLINE mzero #-} mplus a@(ISuccess _) _ = a mplus _ b = b {-# INLINE mplus #-} instance MonadPlus Result where mzero = fail "mzero" {-# INLINE mzero #-} mplus a@(Success _) _ = a mplus _ b = b {-# INLINE mplus #-} instance Alternative IResult where empty = mzero {-# INLINE empty #-} (<|>) = mplus {-# INLINE (<|>) #-} instance Alternative Result where empty = mzero {-# INLINE empty #-} (<|>) = mplus {-# INLINE (<|>) #-} instance Semigroup (IResult a) where (<>) = mplus {-# INLINE (<>) #-} instance Monoid (IResult a) where mempty = fail "mempty" {-# INLINE mempty #-} mappend = (<>) {-# INLINE mappend #-} instance Semigroup (Result a) where (<>) = mplus {-# INLINE (<>) #-} instance Monoid (Result a) where mempty = fail "mempty" {-# INLINE mempty #-} mappend = (<>) {-# INLINE mappend #-} instance Foldable IResult where foldMap _ (IError _ _) = mempty foldMap f (ISuccess y) = f y {-# INLINE foldMap #-} foldr _ z (IError _ _) = z foldr f z (ISuccess y) = f y z {-# INLINE foldr #-} instance Foldable Result where foldMap _ (Error _) = mempty foldMap f (Success y) = f y {-# INLINE foldMap #-} foldr _ z (Error _) = z foldr f z (Success y) = f y z {-# INLINE foldr #-} instance Traversable IResult where traverse _ (IError path err) = pure (IError path err) traverse f (ISuccess a) = ISuccess <$> f a {-# INLINE traverse #-} instance Traversable Result where traverse _ (Error err) = pure (Error err) traverse f (Success a) = Success <$> f a {-# INLINE traverse #-} -- | Failure continuation. type Failure f r = JSONPath -> String -> f r -- | Success continuation. type Success a f r = a -> f r -- | A JSON parser. newtype Parser a = Parser { runParser :: forall f r. JSONPath -> Failure f r -> Success a f r -> f r } instance Monad Parser where m >>= g = Parser $ \path kf ks -> let ks' a = runParser (g a) path kf ks in runParser m path kf ks' {-# INLINE (>>=) #-} return = pure {-# INLINE return #-} fail = Fail.fail {-# INLINE fail #-} instance Fail.MonadFail Parser where fail msg = Parser $ \path kf _ks -> kf (reverse path) msg {-# INLINE fail #-} instance Functor Parser where fmap f m = Parser $ \path kf ks -> let ks' a = ks (f a) in runParser m path kf ks' {-# INLINE fmap #-} instance Applicative Parser where pure a = Parser $ \_path _kf ks -> ks a {-# INLINE pure #-} (<*>) = apP {-# INLINE (<*>) #-} instance Alternative Parser where empty = fail "empty" {-# INLINE empty #-} (<|>) = mplus {-# INLINE (<|>) #-} instance MonadPlus Parser where mzero = fail "mzero" {-# INLINE mzero #-} mplus a b = Parser $ \path kf ks -> let kf' _ _ = runParser b path kf ks in runParser a path kf' ks {-# INLINE mplus #-} instance Semigroup (Parser a) where (<>) = mplus {-# INLINE (<>) #-} instance Monoid (Parser a) where mempty = fail "mempty" {-# INLINE mempty #-} mappend = (<>) {-# INLINE mappend #-} apP :: Parser (a -> b) -> Parser a -> Parser b apP d e = do b <- d a <- e return (b a) {-# INLINE apP #-} -- | A JSON \"object\" (key\/value map). type Object = HashMap Text Value -- | A JSON \"array\" (sequence). type Array = Vector Value -- | A JSON value represented as a Haskell value. data Value = Object !Object | Array !Array | String !Text | Number !Scientific | Bool !Bool | Null deriving (Eq, Read, Show, Typeable, Data) -- | A newtype wrapper for 'UTCTime' that uses the same non-standard -- serialization format as Microsoft .NET, whose -- -- type is by default serialized to JSON as in the following example: -- -- > /Date(1302547608878)/ -- -- The number represents milliseconds since the Unix epoch. newtype DotNetTime = DotNetTime { fromDotNetTime :: UTCTime -- ^ Acquire the underlying value. } deriving (Eq, Ord, Read, Show, Typeable, FormatTime) instance NFData Value where rnf (Object o) = rnf o rnf (Array a) = foldl' (\x y -> rnf y `seq` x) () a rnf (String s) = rnf s rnf (Number n) = rnf n rnf (Bool b) = rnf b rnf Null = () instance IsString Value where fromString = String . pack {-# INLINE fromString #-} hashValue :: Int -> Value -> Int #if MIN_VERSION_unordered_containers(0,2,6) hashValue s (Object o) = s `hashWithSalt` (0::Int) `hashWithSalt` o #else hashValue s (Object o) = foldl' hashWithSalt (s `hashWithSalt` (0::Int)) assocHashesSorted where assocHashesSorted = sort [hash k `hashWithSalt` v | (k, v) <- H.toList o] #endif hashValue s (Array a) = foldl' hashWithSalt (s `hashWithSalt` (1::Int)) a hashValue s (String str) = s `hashWithSalt` (2::Int) `hashWithSalt` str hashValue s (Number n) = s `hashWithSalt` (3::Int) `hashWithSalt` n hashValue s (Bool b) = s `hashWithSalt` (4::Int) `hashWithSalt` b hashValue s Null = s `hashWithSalt` (5::Int) instance Hashable Value where hashWithSalt = hashValue -- @since 0.11.0.0 instance TH.Lift Value where lift Null = [| Null |] lift (Bool b) = [| Bool b |] lift (Number n) = [| Number (S.scientific c e) |] where c = S.coefficient n e = S.base10Exponent n lift (String t) = [| String (pack s) |] where s = unpack t lift (Array a) = [| Array (V.fromList a') |] where a' = V.toList a lift (Object o) = [| Object (H.fromList . map (first pack) $ o') |] where o' = map (first unpack) . H.toList $ o -- | The empty array. emptyArray :: Value emptyArray = Array V.empty -- | Determines if the 'Value' is an empty 'Array'. -- Note that: @isEmptyArray 'emptyArray'@. isEmptyArray :: Value -> Bool isEmptyArray (Array arr) = V.null arr isEmptyArray _ = False -- | The empty object. emptyObject :: Value emptyObject = Object H.empty -- | Run a 'Parser'. parse :: (a -> Parser b) -> a -> Result b parse m v = runParser (m v) [] (const Error) Success {-# INLINE parse #-} -- | Run a 'Parser'. iparse :: (a -> Parser b) -> a -> IResult b iparse m v = runParser (m v) [] IError ISuccess {-# INLINE iparse #-} -- | Run a 'Parser' with a 'Maybe' result type. parseMaybe :: (a -> Parser b) -> a -> Maybe b parseMaybe m v = runParser (m v) [] (\_ _ -> Nothing) Just {-# INLINE parseMaybe #-} -- | Run a 'Parser' with an 'Either' result type. If the parse fails, -- the 'Left' payload will contain an error message. parseEither :: (a -> Parser b) -> a -> Either String b parseEither m v = runParser (m v) [] onError Right where onError path msg = Left (formatError path msg) {-# INLINE parseEither #-} -- | Annotate an error message with a -- error location. formatError :: JSONPath -> String -> String formatError path msg = "Error in " ++ format "$" path ++ ": " ++ msg where format :: String -> JSONPath -> String format pfx [] = pfx format pfx (Index idx:parts) = format (pfx ++ "[" ++ show idx ++ "]") parts format pfx (Key key:parts) = format (pfx ++ formatKey key) parts formatKey :: Text -> String formatKey key | isIdentifierKey strKey = "." ++ strKey | otherwise = "['" ++ escapeKey strKey ++ "']" where strKey = unpack key isIdentifierKey :: String -> Bool isIdentifierKey [] = False isIdentifierKey (x:xs) = isAlpha x && all isAlphaNum xs escapeKey :: String -> String escapeKey = concatMap escapeChar escapeChar :: Char -> String escapeChar '\'' = "\\'" escapeChar '\\' = "\\\\" escapeChar c = [c] -- | A key\/value pair for an 'Object'. type Pair = (Text, Value) -- | Create a 'Value' from a list of name\/value 'Pair's. If duplicate -- keys arise, earlier keys and their associated values win. object :: [Pair] -> Value object = Object . H.fromList {-# INLINE object #-} -- | Add JSON Path context to a parser -- -- When parsing a complex structure, it helps to annotate (sub)parsers -- with context, so that if an error occurs, you can find its location. -- -- > withObject "Person" $ \o -> -- > Person -- > <$> o .: "name" Key "name" -- > <*> o .: "age" Key "age" -- -- (Standard methods like '(.:)' already do this.) -- -- With such annotations, if an error occurs, you will get a JSON Path -- location of that error. -- -- Since 0.10 () :: Parser a -> JSONPathElement -> Parser a p pathElem = Parser $ \path kf ks -> runParser p (pathElem:path) kf ks -- | If the inner @Parser@ failed, modify the failure message using the -- provided function. This allows you to create more descriptive error messages. -- For example: -- -- > parseJSON (Object o) = modifyFailure -- > ("Parsing of the Foo value failed: " ++) -- > (Foo <$> o .: "someField") -- -- Since 0.6.2.0 modifyFailure :: (String -> String) -> Parser a -> Parser a modifyFailure f (Parser p) = Parser $ \path kf ks -> p path (\p' m -> kf p' (f m)) ks -------------------------------------------------------------------------------- -- Generic and TH encoding configuration -------------------------------------------------------------------------------- -- | Options that specify how to encode\/decode your datatype to\/from JSON. data Options = Options { fieldLabelModifier :: String -> String -- ^ Function applied to field labels. -- Handy for removing common record prefixes for example. , constructorTagModifier :: String -> String -- ^ Function applied to constructor tags which could be handy -- for lower-casing them for example. , allNullaryToStringTag :: Bool -- ^ If 'True' the constructors of a datatype, with /all/ -- nullary constructors, will be encoded to just a string with -- the constructor tag. If 'False' the encoding will always -- follow the `sumEncoding`. , omitNothingFields :: Bool -- ^ If 'True' record fields with a 'Nothing' value will be -- omitted from the resulting object. If 'False' the resulting -- object will include those fields mapping to @null@. , sumEncoding :: SumEncoding -- ^ Specifies how to encode constructors of a sum datatype. , unwrapUnaryRecords :: Bool -- ^ Hide the field name when a record constructor has only one -- field, like a newtype. , tagSingleConstructors :: Bool -- ^ Encode types with a single constructor as sums, -- so that `allNullaryToStringTag` and `sumEncoding` apply. } instance Show Options where show (Options f c a o s u t) = "Options {" ++ intercalate ", " [ "fieldLabelModifier =~ " ++ show (f "exampleField") , "constructorTagModifier =~ " ++ show (c "ExampleConstructor") , "allNullaryToStringTag = " ++ show a , "omitNothingFields = " ++ show o , "sumEncoding = " ++ show s , "unwrapUnaryRecords = " ++ show u , "tagSingleConstructors = " ++ show t ] ++ "}" -- | Specifies how to encode constructors of a sum datatype. data SumEncoding = TaggedObject { tagFieldName :: String , contentsFieldName :: String } -- ^ A constructor will be encoded to an object with a field -- 'tagFieldName' which specifies the constructor tag (modified by -- the 'constructorTagModifier'). If the constructor is a record -- the encoded record fields will be unpacked into this object. So -- make sure that your record doesn't have a field with the same -- label as the 'tagFieldName'. Otherwise the tag gets overwritten -- by the encoded value of that field! If the constructor is not a -- record the encoded constructor contents will be stored under -- the 'contentsFieldName' field. | UntaggedValue -- ^ Constructor names won't be encoded. Instead only the contents of the -- constructor will be encoded as if the type had a single constructor. JSON -- encodings have to be disjoint for decoding to work properly. -- -- When decoding, constructors are tried in the order of definition. If some -- encodings overlap, the first one defined will succeed. -- -- /Note:/ Nullary constructors are encoded as strings (using -- 'constructorTagModifier'). Having a nullary constructor alongside a -- single field constructor that encodes to a string leads to ambiguity. -- -- /Note:/ Only the last error is kept when decoding, so in the case of -- malformed JSON, only an error for the last constructor will be reported. | ObjectWithSingleField -- ^ A constructor will be encoded to an object with a single -- field named after the constructor tag (modified by the -- 'constructorTagModifier') which maps to the encoded contents of -- the constructor. | TwoElemArray -- ^ A constructor will be encoded to a 2-element array where the -- first element is the tag of the constructor (modified by the -- 'constructorTagModifier') and the second element the encoded -- contents of the constructor. deriving (Eq, Show) -- | Default encoding 'Options': -- -- @ -- 'Options' -- { 'fieldLabelModifier' = id -- , 'constructorTagModifier' = id -- , 'allNullaryToStringTag' = True -- , 'omitNothingFields' = False -- , 'sumEncoding' = 'defaultTaggedObject' -- , 'unwrapUnaryRecords' = False -- , 'tagSingleConstructors' = False -- } -- @ defaultOptions :: Options defaultOptions = Options { fieldLabelModifier = id , constructorTagModifier = id , allNullaryToStringTag = True , omitNothingFields = False , sumEncoding = defaultTaggedObject , unwrapUnaryRecords = False , tagSingleConstructors = False } -- | Default 'TaggedObject' 'SumEncoding' options: -- -- @ -- defaultTaggedObject = 'TaggedObject' -- { 'tagFieldName' = \"tag\" -- , 'contentsFieldName' = \"contents\" -- } -- @ defaultTaggedObject :: SumEncoding defaultTaggedObject = TaggedObject { tagFieldName = "tag" , contentsFieldName = "contents" } -- | Converts from CamelCase to another lower case, interspersing -- the character between all capital letters and their previous -- entries, except those capital letters that appear together, -- like 'API'. -- -- For use by Aeson template haskell calls. -- -- > camelTo '_' 'CamelCaseAPI' == "camel_case_api" camelTo :: Char -> String -> String {-# DEPRECATED camelTo "Use camelTo2 for better results" #-} camelTo c = lastWasCap True where lastWasCap :: Bool -- ^ Previous was a capital letter -> String -- ^ The remaining string -> String lastWasCap _ [] = [] lastWasCap prev (x : xs) = if isUpper x then if prev then toLower x : lastWasCap True xs else c : toLower x : lastWasCap True xs else x : lastWasCap False xs -- | Better version of 'camelTo'. Example where it works better: -- -- > camelTo '_' 'CamelAPICase' == "camel_apicase" -- > camelTo2 '_' 'CamelAPICase' == "camel_api_case" camelTo2 :: Char -> String -> String camelTo2 c = map toLower . go2 . go1 where go1 "" = "" go1 (x:u:l:xs) | isUpper u && isLower l = x : c : u : l : go1 xs go1 (x:xs) = x : go1 xs go2 "" = "" go2 (l:u:xs) | isLower l && isUpper u = l : c : u : go2 xs go2 (x:xs) = x : go2 xs