{-# LANGUAGE CPP #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE DeriveFunctor #-} {-# LANGUAGE ExistentialQuantification #-} {-# LANGUAGE DeriveDataTypeable #-} module Database.Persist.Types.Base where import qualified Data.Aeson as A import Control.Exception (Exception) import Web.PathPieces (PathPiece (..)) import Control.Monad.Trans.Error (Error (..)) import Data.Typeable (Typeable) import Data.Text (Text, pack) import qualified Data.Text as T import qualified Data.Attoparsec.Number as AN import qualified Data.Text.Encoding as TE import Data.Text.Encoding.Error (lenientDecode) import qualified Data.ByteString.Base64 as B64 import qualified Data.Vector as V import Control.Arrow (second) import Data.Time (Day, TimeOfDay, UTCTime) import Data.Int (Int64) import qualified Data.Text.Read import Data.ByteString (ByteString, foldl') import Data.Bits (shiftL, shiftR) import qualified Data.ByteString as BS import qualified Data.ByteString.Char8 as BS8 import Data.Time.LocalTime (ZonedTime, zonedTimeToUTC, zonedTimeToLocalTime, zonedTimeZone) import Data.Map (Map) import qualified Data.HashMap.Strict as HM import Data.Word (Word32) import Numeric (showHex, readHex) #if MIN_VERSION_aeson(0, 7, 0) import qualified Data.Scientific #endif -- | A 'Checkmark' should be used as a field type whenever a -- uniqueness constraint should guarantee that a certain kind of -- record may appear at most once, but other kinds of records may -- appear any number of times. -- -- /NOTE:/ You need to mark any @Checkmark@ fields as @nullable@ -- (see the following example). -- -- For example, suppose there's a @Location@ entity that -- represents where a user has lived: -- -- @ -- Location -- user UserId -- name Text -- current Checkmark nullable -- -- UniqueLocation user current -- @ -- -- The @UniqueLocation@ constraint allows any number of -- 'Inactive' @Location@s to be @current@. However, there may be -- at most one @current@ @Location@ per user (i.e., either zero -- or one per user). -- -- This data type works because of the way that SQL treats -- @NULL@able fields within uniqueness constraints. The SQL -- standard says that @NULL@ values should be considered -- different, so we represent 'Inactive' as SQL @NULL@, thus -- allowing any number of 'Inactive' records. On the other hand, -- we represent 'Active' as @TRUE@, so the uniqueness constraint -- will disallow more than one 'Active' record. -- -- /Note:/ There may be DBMSs that do not respect the SQL -- standard's treatment of @NULL@ values on uniqueness -- constraints, please check if this data type works before -- relying on it. -- -- The SQL @BOOLEAN@ type is used because it's the smallest data -- type available. Note that we never use @FALSE@, just @TRUE@ -- and @NULL@. Provides the same behavior @Maybe ()@ would if -- @()@ was a valid 'PersistField'. data Checkmark = Active -- ^ When used on a uniqueness constraint, there -- may be at most one 'Active' record. | Inactive -- ^ When used on a uniqueness constraint, there -- may be any number of 'Inactive' records. deriving (Eq, Ord, Read, Show, Enum, Bounded) instance PathPiece Checkmark where toPathPiece = pack . show fromPathPiece txt = case reads (T.unpack txt) of [(a, "")] -> Just a _ -> Nothing data IsNullable = Nullable !WhyNullable | NotNullable deriving (Eq, Show) -- | The reason why a field is 'nullable' is very important. A -- field that is nullable because of a @Maybe@ tag will have its -- type changed from @A@ to @Maybe A@. OTOH, a field that is -- nullable because of a @nullable@ tag will remain with the same -- type. data WhyNullable = ByMaybeAttr | ByNullableAttr deriving (Eq, Show) data EntityDef sqlType = EntityDef { entityHaskell :: !HaskellName , entityDB :: !DBName , entityID :: !DBName , entityAttrs :: ![Attr] , entityFields :: ![FieldDef sqlType] , entityPrimary :: Maybe PrimaryDef , entityUniques :: ![UniqueDef] , entityForeigns:: ![ForeignDef] , entityDerives :: ![Text] , entityExtra :: !(Map Text [ExtraLine]) , entitySum :: !Bool } deriving (Show, Eq, Read, Ord, Functor) type ExtraLine = [Text] newtype HaskellName = HaskellName { unHaskellName :: Text } deriving (Show, Eq, Read, Ord) newtype DBName = DBName { unDBName :: Text } deriving (Show, Eq, Read, Ord) type Attr = Text data FieldType = FTTypeCon (Maybe Text) Text -- ^ Optional module and name. | FTApp FieldType FieldType | FTList FieldType deriving (Show, Eq, Read, Ord) data FieldDef sqlType = FieldDef { fieldHaskell :: !HaskellName -- ^ name of the field , fieldDB :: !DBName , fieldType :: !FieldType , fieldSqlType :: !sqlType , fieldAttrs :: ![Attr] -- ^ user annotations for a field , fieldStrict :: !Bool -- ^ a strict field in the data type. Default: true , fieldEmbedded :: Maybe (EntityDef ()) -- ^ indicates that the field uses an embedded entity } deriving (Show, Eq, Read, Ord, Functor) data UniqueDef = UniqueDef { uniqueHaskell :: !HaskellName , uniqueDBName :: !DBName , uniqueFields :: ![(HaskellName, DBName)] , uniqueAttrs :: ![Attr] } deriving (Show, Eq, Read, Ord) data PrimaryDef = PrimaryDef { primaryFields :: ![(HaskellName, DBName)] , primaryAttrs :: ![Attr] } deriving (Show, Eq, Read, Ord) data ForeignDef = ForeignDef { foreignRefTableHaskell :: !HaskellName , foreignRefTableDBName :: !DBName , foreignConstraintNameHaskell :: !HaskellName , foreignConstraintNameDBName :: !DBName , foreignFields :: ![(HaskellName, DBName, HaskellName, DBName)] -- foreignkey name gb our field plus corresponding other primary field:make this a real adt , foreignAttrs :: ![Attr] } deriving (Show, Eq, Read, Ord) data PersistException = PersistError Text -- ^ Generic Exception | PersistMarshalError Text | PersistInvalidField Text | PersistForeignConstraintUnmet Text | PersistMongoDBError Text | PersistMongoDBUnsupported Text deriving (Show, Typeable) instance Exception PersistException instance Error PersistException where strMsg = PersistError . pack -- | Avoid orphan instances. newtype ZT = ZT ZonedTime deriving (Show, Read, Typeable) instance Eq ZT where ZT a /= ZT b = zonedTimeToLocalTime a /= zonedTimeToLocalTime b || zonedTimeZone a /= zonedTimeZone b instance Ord ZT where ZT a `compare` ZT b = zonedTimeToUTC a `compare` zonedTimeToUTC b -- | A raw value which can be stored in any backend and can be marshalled to -- and from a 'PersistField'. data PersistValue = PersistText Text | PersistByteString ByteString | PersistInt64 Int64 | PersistDouble Double | PersistRational Rational | PersistBool Bool | PersistDay Day | PersistTimeOfDay TimeOfDay | PersistUTCTime UTCTime | PersistZonedTime ZT | PersistNull | PersistList [PersistValue] | PersistMap [(Text, PersistValue)] | PersistObjectId ByteString -- ^ Intended especially for MongoDB backend | PersistDbSpecific ByteString -- ^ Using 'PersistDbSpecific' allows you to use types specific to a particular backend -- For example, below is a simple example of the PostGIS geography type: -- -- @ -- data Geo = Geo ByteString -- -- instance PersistField Geo where -- toPersistValue (Geo t) = PersistDbSpecific t -- -- fromPersistValue (PersistDbSpecific t) = Right $ Geo $ Data.ByteString.concat ["'", t, "'"] -- fromPersistValue _ = Left "Geo values must be converted from PersistDbSpecific" -- -- instance PersistFieldSql Geo where -- sqlType _ = SqlOther "GEOGRAPHY(POINT,4326)" -- -- toPoint :: Double -> Double -> Geo -- toPoint lat lon = Geo $ Data.ByteString.concat ["'POINT(", ps $ lon, " ", ps $ lat, ")'"] -- where ps = Data.Text.pack . show -- @ -- -- If Foo has a geography field, we can then perform insertions like the following: -- -- @ -- insert $ Foo (toPoint 44 44) -- @ -- deriving (Show, Read, Eq, Typeable, Ord) instance PathPiece PersistValue where fromPathPiece t = case Data.Text.Read.signed Data.Text.Read.decimal t of Right (i, t') | T.null t' -> Just $ PersistInt64 i _ -> case reads $ T.unpack t of [(fks, "")] -> Just $ PersistList fks _ -> Just $ PersistText t toPathPiece x = case fromPersistValueText x of Left e -> error e Right y -> y fromPersistValueText :: PersistValue -> Either String Text fromPersistValueText (PersistText s) = Right s fromPersistValueText (PersistByteString bs) = Right $ TE.decodeUtf8With lenientDecode bs fromPersistValueText (PersistInt64 i) = Right $ T.pack $ show i fromPersistValueText (PersistDouble d) = Right $ T.pack $ show d fromPersistValueText (PersistRational r) = Right $ T.pack $ show r fromPersistValueText (PersistDay d) = Right $ T.pack $ show d fromPersistValueText (PersistTimeOfDay d) = Right $ T.pack $ show d fromPersistValueText (PersistUTCTime d) = Right $ T.pack $ show d fromPersistValueText (PersistZonedTime (ZT z)) = Right $ T.pack $ show z fromPersistValueText PersistNull = Left "Unexpected null" fromPersistValueText (PersistBool b) = Right $ T.pack $ show b fromPersistValueText (PersistList _) = Left "Cannot convert PersistList to Text" fromPersistValueText (PersistMap _) = Left "Cannot convert PersistMap to Text" fromPersistValueText (PersistObjectId _) = Left "Cannot convert PersistObjectId to Text" fromPersistValueText (PersistDbSpecific _) = Left "Cannot convert PersistDbSpecific to Text" instance A.ToJSON PersistValue where toJSON (PersistText t) = A.String $ T.cons 's' t toJSON (PersistByteString b) = A.String $ T.cons 'b' $ TE.decodeUtf8 $ B64.encode b toJSON (PersistInt64 i) = A.Number $ fromIntegral i toJSON (PersistDouble d) = A.Number $ #if MIN_VERSION_aeson(0, 7, 0) Data.Scientific.fromFloatDigits #else AN.D #endif d toJSON (PersistRational r) = A.String $ T.pack $ 'r' : show r toJSON (PersistBool b) = A.Bool b toJSON (PersistTimeOfDay t) = A.String $ T.pack $ 't' : show t toJSON (PersistUTCTime u) = A.String $ T.pack $ 'u' : show u toJSON (PersistZonedTime z) = A.String $ T.pack $ 'z' : show z toJSON (PersistDay d) = A.String $ T.pack $ 'd' : show d toJSON PersistNull = A.Null toJSON (PersistList l) = A.Array $ V.fromList $ map A.toJSON l toJSON (PersistMap m) = A.object $ map (second A.toJSON) m toJSON (PersistDbSpecific b) = A.String $ T.cons 'p' $ TE.decodeUtf8 $ B64.encode b toJSON (PersistObjectId o) = A.toJSON $ showChar 'o' $ showHexLen 8 (bs2i four) $ showHexLen 16 (bs2i eight) "" where (four, eight) = BS8.splitAt 4 o -- taken from crypto-api bs2i :: ByteString -> Integer bs2i bs = foldl' (\i b -> (i `shiftL` 8) + fromIntegral b) 0 bs {-# INLINE bs2i #-} -- showHex of n padded with leading zeros if necessary to fill d digits -- taken from Data.BSON showHexLen :: (Show n, Integral n) => Int -> n -> ShowS showHexLen d n = showString (replicate (d - sigDigits n) '0') . showHex n where sigDigits 0 = 1 sigDigits n' = truncate (logBase (16 :: Double) $ fromIntegral n') + 1 instance A.FromJSON PersistValue where parseJSON (A.String t0) = case T.uncons t0 of Nothing -> fail "Null string" Just ('p', t) -> either (fail "Invalid base64") (return . PersistDbSpecific) $ B64.decode $ TE.encodeUtf8 t Just ('s', t) -> return $ PersistText t Just ('b', t) -> either (fail "Invalid base64") (return . PersistByteString) $ B64.decode $ TE.encodeUtf8 t Just ('t', t) -> fmap PersistTimeOfDay $ readMay t Just ('u', t) -> fmap PersistUTCTime $ readMay t Just ('z', t) -> fmap PersistZonedTime $ readMay t Just ('d', t) -> fmap PersistDay $ readMay t Just ('r', t) -> fmap PersistRational $ readMay t Just ('o', t) -> maybe (fail "Invalid base64") (return . PersistObjectId) $ fmap (i2bs (8 * 12) . fst) $ headMay $ readHex $ T.unpack t Just (c, _) -> fail $ "Unknown prefix: " ++ [c] where headMay [] = Nothing headMay (x:_) = Just x readMay :: (Read a, Monad m) => T.Text -> m a readMay t = case reads $ T.unpack t of (x, _):_ -> return x [] -> fail "Could not read" -- taken from crypto-api -- |@i2bs bitLen i@ converts @i@ to a 'ByteString' of @bitLen@ bits (must be a multiple of 8). i2bs :: Int -> Integer -> BS.ByteString i2bs l i = BS.unfoldr (\l' -> if l' < 0 then Nothing else Just (fromIntegral (i `shiftR` l'), l' - 8)) (l-8) {-# INLINE i2bs #-} #if MIN_VERSION_aeson(0, 7, 0) parseJSON (A.Number n) = return $ if fromInteger (floor n) == n then PersistInt64 $ floor n else PersistDouble $ fromRational $ toRational n #else parseJSON (A.Number (AN.I i)) = return $ PersistInt64 $ fromInteger i parseJSON (A.Number (AN.D d)) = return $ PersistDouble d #endif parseJSON (A.Bool b) = return $ PersistBool b parseJSON A.Null = return $ PersistNull parseJSON (A.Array a) = fmap PersistList (mapM A.parseJSON $ V.toList a) parseJSON (A.Object o) = fmap PersistMap $ mapM go $ HM.toList o where go (k, v) = fmap ((,) k) $ A.parseJSON v -- | A SQL data type. Naming attempts to reflect the underlying Haskell -- datatypes, eg SqlString instead of SqlVarchar. Different SQL databases may -- have different translations for these types. data SqlType = SqlString | SqlInt32 | SqlInt64 | SqlReal | SqlNumeric Word32 Word32 | SqlBool | SqlDay | SqlTime | SqlDayTime | SqlDayTimeZoned | SqlBlob | SqlOther T.Text -- ^ a backend-specific name deriving (Show, Read, Eq, Typeable, Ord) newtype KeyBackend backend entity = Key { unKey :: PersistValue } deriving (Show, Read, Eq, Ord) type family KeyEntity key type instance KeyEntity (KeyBackend backend entity) = entity instance A.ToJSON (KeyBackend backend entity) where toJSON (Key val) = A.toJSON val instance A.FromJSON (KeyBackend backend entity) where parseJSON = fmap Key . A.parseJSON data PersistFilter = Eq | Ne | Gt | Lt | Ge | Le | In | NotIn | BackendSpecificFilter T.Text deriving (Read, Show) data UpdateGetException = KeyNotFound String deriving Typeable instance Show UpdateGetException where show (KeyNotFound key) = "Key not found during updateGet: " ++ key instance Exception UpdateGetException data PersistUpdate = Assign | Add | Subtract | Multiply | Divide -- FIXME need something else here deriving (Read, Show, Enum, Bounded)