Safe Haskell | Safe-Inferred |
---|---|
Language | Haskell2010 |
Warning: This module will switch over to the Experimental syntax in an upcoming major version release. Please migrate to the Database.Esqueleto.Legacy module to continue using the old syntax, or translate to the new and improved syntax in Database.Esqueleto.Experimental.
The esqueleto
EDSL (embedded domain specific language).
This module replaces Database.Persist
, so instead of
importing that module you should just import this one:
-- For a module using just esqueleto. import Database.Esqueleto
If you need to use persistent
's default support for queries
as well, either import it qualified:
-- For a module that mostly uses esqueleto. import Database.Esqueleto import qualified Database.Persist as P
or import esqueleto
itself qualified:
-- For a module that uses esqueleto just on some queries. import Database.Persist import qualified Database.Esqueleto as E
Other than identifier name clashes, esqueleto
does not
conflict with persistent
in any way.
Note that the facilities for JOIN
have been significantly improved in the
Database.Esqueleto.Experimental module. The definition of from
and on
in this module will be replaced with those at the 4.0.0.0 version, so you are
encouraged to migrate to the new method.
This module has an attached WARNING message indicating that the Experimental syntax will become the default. If you want to continue using the old syntax, please refer to Database.Esqueleto.Legacy as a drop-in replacement.
Synopsis
- where_ :: SqlExpr (Value Bool) -> SqlQuery ()
- on :: SqlExpr (Value Bool) -> SqlQuery ()
- groupBy :: ToSomeValues a => a -> SqlQuery ()
- orderBy :: [SqlExpr OrderBy] -> SqlQuery ()
- rand :: SqlExpr OrderBy
- asc :: PersistField a => SqlExpr (Value a) -> SqlExpr OrderBy
- desc :: PersistField a => SqlExpr (Value a) -> SqlExpr OrderBy
- limit :: Int64 -> SqlQuery ()
- offset :: Int64 -> SqlQuery ()
- distinct :: SqlQuery a -> SqlQuery a
- distinctOn :: [SqlExpr DistinctOn] -> SqlQuery a -> SqlQuery a
- don :: SqlExpr (Value a) -> SqlExpr DistinctOn
- distinctOnOrderBy :: [SqlExpr OrderBy] -> SqlQuery a -> SqlQuery a
- having :: SqlExpr (Value Bool) -> SqlQuery ()
- locking :: LockingKind -> SqlQuery ()
- sub_select :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (Value a)
- (^.) :: forall typ val. (PersistEntity val, PersistField typ) => SqlExpr (Entity val) -> EntityField val typ -> SqlExpr (Value typ)
- (?.) :: (PersistEntity val, PersistField typ) => SqlExpr (Maybe (Entity val)) -> EntityField val typ -> SqlExpr (Value (Maybe typ))
- val :: PersistField typ => typ -> SqlExpr (Value typ)
- isNothing :: PersistField typ => SqlExpr (Value (Maybe typ)) -> SqlExpr (Value Bool)
- just :: SqlExpr (Value typ) -> SqlExpr (Value (Maybe typ))
- nothing :: SqlExpr (Value (Maybe typ))
- joinV :: SqlExpr (Value (Maybe (Maybe typ))) -> SqlExpr (Value (Maybe typ))
- withNonNull :: PersistField typ => SqlExpr (Value (Maybe typ)) -> (SqlExpr (Value typ) -> SqlQuery a) -> SqlQuery a
- countRows :: Num a => SqlExpr (Value a)
- count :: Num a => SqlExpr (Value typ) -> SqlExpr (Value a)
- countDistinct :: Num a => SqlExpr (Value typ) -> SqlExpr (Value a)
- not_ :: SqlExpr (Value Bool) -> SqlExpr (Value Bool)
- (==.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool)
- (>=.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool)
- (>.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool)
- (<=.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool)
- (<.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool)
- (!=.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool)
- (&&.) :: SqlExpr (Value Bool) -> SqlExpr (Value Bool) -> SqlExpr (Value Bool)
- (||.) :: SqlExpr (Value Bool) -> SqlExpr (Value Bool) -> SqlExpr (Value Bool)
- between :: PersistField a => SqlExpr (Value a) -> (SqlExpr (Value a), SqlExpr (Value a)) -> SqlExpr (Value Bool)
- (+.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a)
- (-.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a)
- (/.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a)
- (*.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a)
- random_ :: (PersistField a, Num a) => SqlExpr (Value a)
- round_ :: (PersistField a, Num a, PersistField b, Num b) => SqlExpr (Value a) -> SqlExpr (Value b)
- ceiling_ :: (PersistField a, Num a, PersistField b, Num b) => SqlExpr (Value a) -> SqlExpr (Value b)
- floor_ :: (PersistField a, Num a, PersistField b, Num b) => SqlExpr (Value a) -> SqlExpr (Value b)
- min_ :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value (Maybe a))
- max_ :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value (Maybe a))
- sum_ :: (PersistField a, PersistField b) => SqlExpr (Value a) -> SqlExpr (Value (Maybe b))
- avg_ :: (PersistField a, PersistField b) => SqlExpr (Value a) -> SqlExpr (Value (Maybe b))
- castNum :: (Num a, Num b) => SqlExpr (Value a) -> SqlExpr (Value b)
- castNumM :: (Num a, Num b) => SqlExpr (Value (Maybe a)) -> SqlExpr (Value (Maybe b))
- coalesce :: PersistField a => [SqlExpr (Value (Maybe a))] -> SqlExpr (Value (Maybe a))
- coalesceDefault :: PersistField a => [SqlExpr (Value (Maybe a))] -> SqlExpr (Value a) -> SqlExpr (Value a)
- lower_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s)
- upper_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s)
- trim_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s)
- ltrim_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s)
- rtrim_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s)
- length_ :: (SqlString s, Num a) => SqlExpr (Value s) -> SqlExpr (Value a)
- left_ :: (SqlString s, Num a) => (SqlExpr (Value s), SqlExpr (Value a)) -> SqlExpr (Value s)
- right_ :: (SqlString s, Num a) => (SqlExpr (Value s), SqlExpr (Value a)) -> SqlExpr (Value s)
- like :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) -> SqlExpr (Value Bool)
- ilike :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) -> SqlExpr (Value Bool)
- (%) :: SqlString s => SqlExpr (Value s)
- concat_ :: SqlString s => [SqlExpr (Value s)] -> SqlExpr (Value s)
- (++.) :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) -> SqlExpr (Value s)
- castString :: (SqlString s, SqlString r) => SqlExpr (Value s) -> SqlExpr (Value r)
- subList_select :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (ValueList a)
- valList :: PersistField typ => [typ] -> SqlExpr (ValueList typ)
- justList :: SqlExpr (ValueList typ) -> SqlExpr (ValueList (Maybe typ))
- in_ :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (ValueList typ) -> SqlExpr (Value Bool)
- notIn :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (ValueList typ) -> SqlExpr (Value Bool)
- exists :: SqlQuery () -> SqlExpr (Value Bool)
- notExists :: SqlQuery () -> SqlExpr (Value Bool)
- set :: PersistEntity val => SqlExpr (Entity val) -> [SqlExpr (Entity val) -> SqlExpr Update] -> SqlQuery ()
- (=.) :: (PersistEntity val, PersistField typ) => EntityField val typ -> SqlExpr (Value typ) -> SqlExpr (Entity val) -> SqlExpr Update
- (+=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update
- (-=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update
- (*=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update
- (/=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update
- case_ :: PersistField a => [(SqlExpr (Value Bool), SqlExpr (Value a))] -> SqlExpr (Value a) -> SqlExpr (Value a)
- toBaseId :: ToBaseId ent => SqlExpr (Value (Key ent)) -> SqlExpr (Value (Key (BaseEnt ent)))
- subSelect :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (Value (Maybe a))
- subSelectMaybe :: PersistField a => SqlQuery (SqlExpr (Value (Maybe a))) -> SqlExpr (Value (Maybe a))
- subSelectCount :: (Num a, PersistField a) => SqlQuery ignored -> SqlExpr (Value a)
- subSelectForeign :: (BackendCompatible SqlBackend (PersistEntityBackend val1), PersistEntity val1, PersistEntity val2, PersistField a) => SqlExpr (Entity val2) -> EntityField val2 (Key val1) -> (SqlExpr (Entity val1) -> SqlExpr (Value a)) -> SqlExpr (Value a)
- subSelectList :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (ValueList a)
- subSelectUnsafe :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (Value a)
- class ToBaseId ent where
- when_ :: expr (Value Bool) -> () -> expr a -> (expr (Value Bool), expr a)
- then_ :: ()
- else_ :: expr a -> expr a
- from :: From a => (a -> SqlQuery b) -> SqlQuery b
- newtype Value a = Value {
- unValue :: a
- newtype ValueList a = ValueList a
- data OrderBy
- data DistinctOn
- data LockingKind
- class LockableEntity a where
- class PersistField a => SqlString a
- data InnerJoin a b = a `InnerJoin` b
- data CrossJoin a b = a `CrossJoin` b
- data LeftOuterJoin a b = a `LeftOuterJoin` b
- data RightOuterJoin a b = a `RightOuterJoin` b
- data FullOuterJoin a b = a `FullOuterJoin` b
- data JoinKind
- data OnClauseWithoutMatchingJoinException = OnClauseWithoutMatchingJoinException String
- data SqlQuery a
- data SqlExpr a
- type SqlEntity ent = (PersistEntity ent, PersistEntityBackend ent ~ SqlBackend)
- select :: (SqlSelect a r, MonadIO m, SqlBackendCanRead backend) => SqlQuery a -> ReaderT backend m [r]
- selectOne :: (SqlSelect a r, MonadIO m, SqlBackendCanRead backend) => SqlQuery a -> ReaderT backend m (Maybe r)
- selectSource :: (SqlSelect a r, BackendCompatible SqlBackend backend, IsPersistBackend backend, PersistQueryRead backend, PersistStoreRead backend, PersistUniqueRead backend, MonadResource m) => SqlQuery a -> ConduitT () r (ReaderT backend m) ()
- delete :: (MonadIO m, SqlBackendCanWrite backend) => SqlQuery () -> ReaderT backend m ()
- deleteCount :: (MonadIO m, SqlBackendCanWrite backend) => SqlQuery () -> ReaderT backend m Int64
- update :: (MonadIO m, PersistEntity val, BackendCompatible SqlBackend (PersistEntityBackend val), SqlBackendCanWrite backend) => (SqlExpr (Entity val) -> SqlQuery ()) -> ReaderT backend m ()
- updateCount :: (MonadIO m, PersistEntity val, BackendCompatible SqlBackend (PersistEntityBackend val), SqlBackendCanWrite backend) => (SqlExpr (Entity val) -> SqlQuery ()) -> ReaderT backend m Int64
- insertSelect :: (MonadIO m, PersistEntity a, SqlBackendCanWrite backend) => SqlQuery (SqlExpr (Insertion a)) -> ReaderT backend m ()
- insertSelectCount :: (MonadIO m, PersistEntity a, SqlBackendCanWrite backend) => SqlQuery (SqlExpr (Insertion a)) -> ReaderT backend m Int64
- (<#) :: (a -> b) -> SqlExpr (Value a) -> SqlExpr (Insertion b)
- (<&>) :: SqlExpr (Insertion (a -> b)) -> SqlExpr (Value a) -> SqlExpr (Insertion b)
- renderQueryToText :: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) => Mode -> SqlQuery a -> ReaderT backend m (Text, [PersistValue])
- renderQuerySelect :: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) => SqlQuery a -> ReaderT backend m (Text, [PersistValue])
- renderQueryUpdate :: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) => SqlQuery a -> ReaderT backend m (Text, [PersistValue])
- renderQueryDelete :: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) => SqlQuery a -> ReaderT backend m (Text, [PersistValue])
- renderQueryInsertInto :: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) => SqlQuery a -> ReaderT backend m (Text, [PersistValue])
- class From a
- valkey :: (ToBackendKey SqlBackend entity, PersistField (Key entity)) => Int64 -> SqlExpr (Value (Key entity))
- valJ :: PersistField (Key entity) => Value (Key entity) -> SqlExpr (Value (Key entity))
- associateJoin :: forall e1 e0. Ord (Key e0) => [(Entity e0, e1)] -> Map (Key e0) (e0, [e1])
- deleteKey :: (PersistStore backend, BaseBackend backend ~ PersistEntityBackend val, MonadIO m, PersistEntity val) => Key val -> ReaderT backend m ()
- transactionUndoWithIsolation :: forall (m :: Type -> Type). MonadIO m => IsolationLevel -> ReaderT SqlBackend m ()
- transactionUndo :: forall (m :: Type -> Type). MonadIO m => ReaderT SqlBackend m ()
- transactionSaveWithIsolation :: forall (m :: Type -> Type). MonadIO m => IsolationLevel -> ReaderT SqlBackend m ()
- transactionSave :: forall (m :: Type -> Type). MonadIO m => ReaderT SqlBackend m ()
- runSqlCommand :: SqlPersistT IO () -> Migration
- addMigrations :: CautiousMigration -> Migration
- addMigration :: Bool -> Sql -> Migration
- reportErrors :: [Text] -> Migration
- reportError :: Text -> Migration
- migrate :: [EntityDef] -> EntityDef -> Migration
- runMigrationUnsafeQuiet :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m [Text]
- runMigrationUnsafe :: forall (m :: Type -> Type). MonadIO m => Migration -> ReaderT SqlBackend m ()
- runMigrationSilent :: forall (m :: Type -> Type). MonadUnliftIO m => Migration -> ReaderT SqlBackend m [Text]
- runMigrationQuiet :: forall (m :: Type -> Type). MonadIO m => Migration -> ReaderT SqlBackend m [Text]
- runMigration :: forall (m :: Type -> Type). MonadIO m => Migration -> ReaderT SqlBackend m ()
- getMigration :: forall (m :: Type -> Type). (MonadIO m, HasCallStack) => Migration -> ReaderT SqlBackend m [Sql]
- showMigration :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m [Text]
- printMigration :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m ()
- parseMigration' :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m CautiousMigration
- parseMigration :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m (Either [Text] CautiousMigration)
- type Sql = Text
- type CautiousMigration = [(Bool, Sql)]
- type Migration = WriterT [Text] (WriterT CautiousMigration (ReaderT SqlBackend IO)) ()
- newtype PersistUnsafeMigrationException = PersistUnsafeMigrationException [(Bool, Sql)]
- decorateSQLWithLimitOffset :: Text -> (Int, Int) -> Text -> Text
- orderClause :: PersistEntity val => Maybe FilterTablePrefix -> SqlBackend -> [SelectOpt val] -> Text
- filterClauseWithVals :: PersistEntity val => Maybe FilterTablePrefix -> SqlBackend -> [Filter val] -> (Text, [PersistValue])
- filterClause :: PersistEntity val => Maybe FilterTablePrefix -> SqlBackend -> [Filter val] -> Text
- data FilterTablePrefix
- fieldDBName :: PersistEntity record => EntityField record typ -> FieldNameDB
- getFieldName :: forall record typ (m :: Type -> Type) backend. (PersistEntity record, PersistEntityBackend record ~ SqlBackend, BackendCompatible SqlBackend backend, Monad m) => EntityField record typ -> ReaderT backend m Text
- tableDBName :: PersistEntity record => record -> EntityNameDB
- getTableName :: forall record (m :: Type -> Type) backend. (PersistEntity record, BackendCompatible SqlBackend backend, Monad m) => record -> ReaderT backend m Text
- fromSqlKey :: ToBackendKey SqlBackend record => Key record -> Int64
- toSqlKey :: ToBackendKey SqlBackend record => Int64 -> Key record
- withRawQuery :: forall (m :: Type -> Type) a. MonadIO m => Text -> [PersistValue] -> ConduitM [PersistValue] Void IO a -> ReaderT SqlBackend m a
- close' :: BackendCompatible SqlBackend backend => backend -> IO ()
- withSqlConn :: forall backend m a. (MonadUnliftIO m, MonadLoggerIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> (backend -> m a) -> m a
- createSqlPoolWithConfig :: (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> ConnectionPoolConfig -> m (Pool backend)
- createSqlPool :: forall backend m. (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> Int -> m (Pool backend)
- withSqlPoolWithConfig :: forall backend m a. (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> ConnectionPoolConfig -> (Pool backend -> m a) -> m a
- withSqlPool :: forall backend m a. (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> Int -> (Pool backend -> m a) -> m a
- liftSqlPersistMPool :: forall backend m a. (MonadIO m, BackendCompatible SqlBackend backend) => ReaderT backend (NoLoggingT (ResourceT IO)) a -> Pool backend -> m a
- runSqlPersistMPool :: BackendCompatible SqlBackend backend => ReaderT backend (NoLoggingT (ResourceT IO)) a -> Pool backend -> IO a
- runSqlPersistM :: BackendCompatible SqlBackend backend => ReaderT backend (NoLoggingT (ResourceT IO)) a -> backend -> IO a
- runSqlConnWithIsolation :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> backend -> IsolationLevel -> m a
- runSqlConn :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> backend -> m a
- acquireSqlConnWithIsolation :: (MonadReader backend m, BackendCompatible SqlBackend backend) => IsolationLevel -> m (Acquire backend)
- acquireSqlConn :: (MonadReader backend m, BackendCompatible SqlBackend backend) => m (Acquire backend)
- runSqlPoolWithExtensibleHooks :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> Maybe IsolationLevel -> SqlPoolHooks m backend -> m a
- runSqlPoolWithHooks :: forall backend m a before after onException. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> Maybe IsolationLevel -> (backend -> m before) -> (backend -> m after) -> (backend -> SomeException -> m onException) -> m a
- runSqlPoolNoTransaction :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> Maybe IsolationLevel -> m a
- runSqlPoolWithIsolation :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> IsolationLevel -> m a
- runSqlPool :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> m a
- rawSql :: forall a (m :: Type -> Type) backend. (RawSql a, MonadIO m, BackendCompatible SqlBackend backend) => Text -> [PersistValue] -> ReaderT backend m [a]
- getStmtConn :: SqlBackend -> Text -> IO Statement
- rawExecuteCount :: forall (m :: Type -> Type) backend. (MonadIO m, BackendCompatible SqlBackend backend) => Text -> [PersistValue] -> ReaderT backend m Int64
- rawExecute :: forall (m :: Type -> Type) backend. (MonadIO m, BackendCompatible SqlBackend backend) => Text -> [PersistValue] -> ReaderT backend m ()
- rawQueryRes :: forall (m1 :: Type -> Type) (m2 :: Type -> Type) env. (MonadIO m1, MonadIO m2, BackendCompatible SqlBackend env) => Text -> [PersistValue] -> ReaderT env m1 (Acquire (ConduitM () [PersistValue] m2 ()))
- rawQuery :: forall (m :: Type -> Type) env. (MonadResource m, MonadReader env m, BackendCompatible SqlBackend env) => Text -> [PersistValue] -> ConduitM () [PersistValue] m ()
- unPrefix :: forall (prefix :: Symbol) record. EntityWithPrefix prefix record -> Entity record
- class RawSql a where
- rawSqlCols :: (Text -> Text) -> a -> (Int, [Text])
- rawSqlColCountReason :: a -> String
- rawSqlProcessRow :: [PersistValue] -> Either Text a
- newtype EntityWithPrefix (prefix :: Symbol) record = EntityWithPrefix {
- unEntityWithPrefix :: Entity record
- class PersistField a => PersistFieldSql a where
- toJsonText :: ToJSON j => j -> Text
- mkColumns :: [EntityDef] -> EntityDef -> BackendSpecificOverrides -> ([Column], [UniqueDef], [ForeignDef])
- defaultAttribute :: [FieldAttr] -> Maybe Text
- emptyBackendSpecificOverrides :: BackendSpecificOverrides
- setBackendSpecificForeignKeyName :: (EntityNameDB -> FieldNameDB -> ConstraintNameDB) -> BackendSpecificOverrides -> BackendSpecificOverrides
- getBackendSpecificForeignKeyName :: BackendSpecificOverrides -> Maybe (EntityNameDB -> FieldNameDB -> ConstraintNameDB)
- data BackendSpecificOverrides
- defaultConnectionPoolConfig :: ConnectionPoolConfig
- data Column = Column {
- cName :: !FieldNameDB
- cNull :: !Bool
- cSqlType :: !SqlType
- cDefault :: !(Maybe Text)
- cGenerated :: !(Maybe Text)
- cDefaultConstraintName :: !(Maybe ConstraintNameDB)
- cMaxLen :: !(Maybe Integer)
- cReference :: !(Maybe ColumnReference)
- data ColumnReference = ColumnReference {}
- data PersistentSqlException
- type SqlPersistT = ReaderT SqlBackend
- type SqlPersistM = SqlPersistT (NoLoggingT (ResourceT IO))
- type ConnectionPool = Pool SqlBackend
- data ConnectionPoolConfig = ConnectionPoolConfig {}
- newtype Single a = Single {
- unSingle :: a
- readToUnknown :: forall (m :: Type -> Type) a. Monad m => ReaderT SqlReadBackend m a -> ReaderT SqlBackend m a
- readToWrite :: forall (m :: Type -> Type) a. Monad m => ReaderT SqlReadBackend m a -> ReaderT SqlWriteBackend m a
- writeToUnknown :: forall (m :: Type -> Type) a. Monad m => ReaderT SqlWriteBackend m a -> ReaderT SqlBackend m a
- newtype SqlReadBackend = SqlReadBackend {}
- newtype SqlWriteBackend = SqlWriteBackend {}
- type SqlBackendCanRead backend = (BackendCompatible SqlBackend backend, PersistQueryRead backend, PersistStoreRead backend, PersistUniqueRead backend)
- type SqlBackendCanWrite backend = (SqlBackendCanRead backend, PersistQueryWrite backend, PersistStoreWrite backend, PersistUniqueWrite backend)
- type SqlReadT (m :: Type -> Type) a = forall backend. SqlBackendCanRead backend => ReaderT backend m a
- type SqlWriteT (m :: Type -> Type) a = forall backend. SqlBackendCanWrite backend => ReaderT backend m a
- type IsSqlBackend backend = (IsPersistBackend backend, BaseBackend backend ~ SqlBackend)
- type PersistUnique a = PersistUniqueWrite a
- type PersistStore a = PersistStoreWrite a
- selectKeys :: forall record backend (m :: Type -> Type). (PersistQueryRead backend, MonadResource m, PersistRecordBackend record backend, MonadReader backend m) => [Filter record] -> [SelectOpt record] -> ConduitM () (Key record) m ()
- class (PersistCore backend, PersistStoreRead backend) => PersistQueryRead backend where
- selectSourceRes :: forall record (m1 :: Type -> Type) (m2 :: Type -> Type). (PersistRecordBackend record backend, MonadIO m1, MonadIO m2) => [Filter record] -> [SelectOpt record] -> ReaderT backend m1 (Acquire (ConduitM () (Entity record) m2 ()))
- selectFirst :: forall (m :: Type -> Type) record. (MonadIO m, PersistRecordBackend record backend) => [Filter record] -> [SelectOpt record] -> ReaderT backend m (Maybe (Entity record))
- selectKeysRes :: forall (m1 :: Type -> Type) (m2 :: Type -> Type) record. (MonadIO m1, MonadIO m2, PersistRecordBackend record backend) => [Filter record] -> [SelectOpt record] -> ReaderT backend m1 (Acquire (ConduitM () (Key record) m2 ()))
- class (PersistQueryRead backend, PersistStoreWrite backend) => PersistQueryWrite backend where
- updateWhere :: forall (m :: Type -> Type) record. (MonadIO m, PersistRecordBackend record backend) => [Filter record] -> [Update record] -> ReaderT backend m ()
- deleteWhere :: forall (m :: Type -> Type) record. (MonadIO m, PersistRecordBackend record backend) => [Filter record] -> ReaderT backend m ()
- checkUniqueUpdateable :: forall record backend (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, PersistUniqueRead backend) => Entity record -> ReaderT backend m (Maybe (Unique record))
- checkUnique :: forall record backend (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, PersistUniqueRead backend) => record -> ReaderT backend m (Maybe (Unique record))
- replaceUnique :: forall record backend (m :: Type -> Type). (MonadIO m, Eq (Unique record), PersistRecordBackend record backend, PersistUniqueWrite backend) => Key record -> record -> ReaderT backend m (Maybe (Unique record))
- getByValue :: forall record (m :: Type -> Type) backend. (MonadIO m, PersistUniqueRead backend, PersistRecordBackend record backend, AtLeastOneUniqueKey record) => record -> ReaderT backend m (Maybe (Entity record))
- onlyUnique :: forall record backend (m :: Type -> Type). (MonadIO m, PersistUniqueWrite backend, PersistRecordBackend record backend, OnlyOneUniqueKey record) => record -> ReaderT backend m (Unique record)
- insertUniqueEntity :: forall record backend (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, PersistUniqueWrite backend, SafeToInsert record) => record -> ReaderT backend m (Maybe (Entity record))
- insertBy :: forall record backend (m :: Type -> Type). (MonadIO m, PersistUniqueWrite backend, PersistRecordBackend record backend, AtLeastOneUniqueKey record, SafeToInsert record) => record -> ReaderT backend m (Either (Entity record) (Key record))
- onlyOneUniqueDef :: (OnlyOneUniqueKey record, Monad proxy) => proxy record -> UniqueDef
- class PersistStoreRead backend => PersistUniqueRead backend where
- class (PersistUniqueRead backend, PersistStoreWrite backend) => PersistUniqueWrite backend where
- deleteBy :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Unique record -> ReaderT backend m ()
- insertUnique :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m (Maybe (Key record))
- insertUnique_ :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m (Maybe ())
- upsert :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, OnlyOneUniqueKey record, SafeToInsert record) => record -> [Update record] -> ReaderT backend m (Entity record)
- upsertBy :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => Unique record -> record -> [Update record] -> ReaderT backend m (Entity record)
- putMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => [record] -> ReaderT backend m ()
- class PersistEntity record => OnlyOneUniqueKey record where
- onlyUniqueP :: record -> Unique record
- type NoUniqueKeysError ty = (('Text "The entity " :<>: 'ShowType ty) :<>: 'Text " does not have any unique keys.") :$$: ('Text "The function you are trying to call requires a unique key " :<>: 'Text "to be defined on the entity.")
- type MultipleUniqueKeysError ty = ((('Text "The entity " :<>: 'ShowType ty) :<>: 'Text " has multiple unique keys.") :$$: ('Text "The function you are trying to call requires only a single " :<>: 'Text "unique key.")) :$$: (('Text "There is probably a variant of the function with 'By' " :<>: 'Text "appended that will allow you to select a unique key ") :<>: 'Text "for the operation.")
- class PersistEntity record => AtLeastOneUniqueKey record where
- requireUniquesP :: record -> NonEmpty (Unique record)
- data SqlBackend
- insertRecord :: forall record backend (m :: Type -> Type). (PersistEntityBackend record ~ BaseBackend backend, PersistEntity record, MonadIO m, PersistStoreWrite backend, SafeToInsert record, HasCallStack) => record -> ReaderT backend m record
- getEntity :: forall e backend (m :: Type -> Type). (PersistStoreRead backend, PersistRecordBackend e backend, MonadIO m) => Key e -> ReaderT backend m (Maybe (Entity e))
- insertEntity :: forall e backend (m :: Type -> Type). (PersistStoreWrite backend, PersistRecordBackend e backend, SafeToInsert e, MonadIO m, HasCallStack) => e -> ReaderT backend m (Entity e)
- belongsToJust :: forall ent1 ent2 backend (m :: Type -> Type). (PersistStoreRead backend, PersistEntity ent1, PersistRecordBackend ent2 backend, MonadIO m) => (ent1 -> Key ent2) -> ent1 -> ReaderT backend m ent2
- belongsTo :: forall ent1 ent2 backend (m :: Type -> Type). (PersistStoreRead backend, PersistEntity ent1, PersistRecordBackend ent2 backend, MonadIO m) => (ent1 -> Maybe (Key ent2)) -> ent1 -> ReaderT backend m (Maybe ent2)
- getJustEntity :: forall record backend (m :: Type -> Type). (PersistEntityBackend record ~ BaseBackend backend, MonadIO m, PersistEntity record, PersistStoreRead backend) => Key record -> ReaderT backend m (Entity record)
- getJust :: forall record backend (m :: Type -> Type). (PersistStoreRead backend, PersistRecordBackend record backend, MonadIO m) => Key record -> ReaderT backend m record
- liftPersist :: (MonadIO m, MonadReader backend m) => ReaderT backend IO b -> m b
- withCompatibleBackend :: forall sup sub (m :: Type -> Type) a. BackendCompatible sup sub => ReaderT sup m a -> ReaderT sub m a
- withBaseBackend :: forall backend (m :: Type -> Type) a. HasPersistBackend backend => ReaderT (BaseBackend backend) m a -> ReaderT backend m a
- type family BaseBackend backend
- class HasPersistBackend backend where
- type BaseBackend backend
- persistBackend :: backend -> BaseBackend backend
- class HasPersistBackend backend => IsPersistBackend backend
- class BackendCompatible sup sub where
- projectBackend :: sub -> sup
- type PersistRecordBackend record backend = (PersistEntity record, PersistEntityBackend record ~ BaseBackend backend)
- class (PersistEntity record, PersistEntityBackend record ~ backend, PersistCore backend) => ToBackendKey backend record where
- toBackendKey :: Key record -> BackendKey backend
- fromBackendKey :: BackendKey backend -> Key record
- data family BackendKey backend
- class PersistCore backend where
- data BackendKey backend
- class (Show (BackendKey backend), Read (BackendKey backend), Eq (BackendKey backend), Ord (BackendKey backend), PersistCore backend, PersistField (BackendKey backend), ToJSON (BackendKey backend), FromJSON (BackendKey backend)) => PersistStoreRead backend where
- class (Show (BackendKey backend), Read (BackendKey backend), Eq (BackendKey backend), Ord (BackendKey backend), PersistStoreRead backend, PersistField (BackendKey backend), ToJSON (BackendKey backend), FromJSON (BackendKey backend)) => PersistStoreWrite backend where
- insert :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m (Key record)
- insert_ :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m ()
- insertMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => [record] -> ReaderT backend m [Key record]
- insertMany_ :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => [record] -> ReaderT backend m ()
- insertEntityMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => [Entity record] -> ReaderT backend m ()
- insertKey :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> record -> ReaderT backend m ()
- repsert :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> record -> ReaderT backend m ()
- repsertMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => [(Key record, record)] -> ReaderT backend m ()
- replace :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> record -> ReaderT backend m ()
- updateGet :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> [Update record] -> ReaderT backend m record
- fromPersistValueJSON :: FromJSON a => PersistValue -> Either Text a
- toPersistValueJSON :: ToJSON a => a -> PersistValue
- entityIdFromJSON :: (PersistEntity record, FromJSON record) => Value -> Parser (Entity record)
- entityIdToJSON :: (PersistEntity record, ToJSON record) => Entity record -> Value
- keyValueEntityFromJSON :: (PersistEntity record, FromJSON record) => Value -> Parser (Entity record)
- keyValueEntityToJSON :: (PersistEntity record, ToJSON record) => Entity record -> Value
- entityValues :: PersistEntity record => Entity record -> [PersistValue]
- tabulateEntity :: PersistEntity record => (forall a. EntityField record a -> a) -> Entity record
- data family Unique record
- data family EntityField record :: Type -> Type
- data family Key record
- type family PersistEntityBackend record
- class (PersistField (Key record), ToJSON (Key record), FromJSON (Key record), Show (Key record), Read (Key record), Eq (Key record), Ord (Key record)) => PersistEntity record where
- type PersistEntityBackend record
- data Key record
- data EntityField record :: Type -> Type
- data Unique record
- keyToValues :: Key record -> [PersistValue]
- keyFromValues :: [PersistValue] -> Either Text (Key record)
- persistIdField :: EntityField record (Key record)
- entityDef :: proxy record -> EntityDef
- persistFieldDef :: EntityField record typ -> FieldDef
- toPersistFields :: record -> [PersistValue]
- fromPersistValues :: [PersistValue] -> Either Text record
- tabulateEntityA :: Applicative f => (forall a. EntityField record a -> f a) -> f (Entity record)
- persistUniqueKeys :: record -> [Unique record]
- persistUniqueToFieldNames :: Unique record -> NonEmpty (FieldNameHS, FieldNameDB)
- persistUniqueToValues :: Unique record -> [PersistValue]
- fieldLens :: EntityField record field -> forall (f :: Type -> Type). Functor f => (field -> f field) -> Entity record -> f (Entity record)
- keyFromRecordM :: Maybe (record -> Key record)
- type family BackendSpecificUpdate backend record
- data FilterValue typ where
- FilterValue :: forall typ. typ -> FilterValue typ
- FilterValues :: forall typ. [typ] -> FilterValue typ
- UnsafeValue :: forall a typ. PersistField a => a -> FilterValue typ
- data Entity record = Entity {}
- class SymbolToField (sym :: Symbol) rec typ | sym rec -> typ where
- symbolToField :: EntityField rec typ
- class SafeToInsert a
- class PersistField a where
- toPersistValue :: a -> PersistValue
- fromPersistValue :: PersistValue -> Either Text a
- newtype OverflowNatural = OverflowNatural {}
- overEntityFields :: ([FieldDef] -> [FieldDef]) -> EntityDef -> EntityDef
- getEntityKeyFields :: EntityDef -> NonEmpty FieldDef
- setEntityIdDef :: EntityIdDef -> EntityDef -> EntityDef
- setEntityId :: FieldDef -> EntityDef -> EntityDef
- getEntityIdField :: EntityDef -> Maybe FieldDef
- getEntityId :: EntityDef -> EntityIdDef
- isEntitySum :: EntityDef -> Bool
- getEntityFieldsDatabase :: EntityDef -> [FieldDef]
- getEntityFields :: EntityDef -> [FieldDef]
- getEntityForeignDefs :: EntityDef -> [ForeignDef]
- getEntityComments :: EntityDef -> Maybe Text
- setEntityDBName :: EntityNameDB -> EntityDef -> EntityDef
- getEntityExtra :: EntityDef -> Map Text [[Text]]
- getEntityDBName :: EntityDef -> EntityNameDB
- getEntityHaskellName :: EntityDef -> EntityNameHS
- getEntityUniques :: EntityDef -> [UniqueDef]
- getEntityUniquesNoPrimaryKey :: EntityDef -> [UniqueDef]
- isFieldMaybe :: FieldDef -> Bool
- isFieldNullable :: FieldDef -> IsNullable
- addFieldAttr :: FieldAttr -> FieldDef -> FieldDef
- overFieldAttrs :: ([FieldAttr] -> [FieldAttr]) -> FieldDef -> FieldDef
- setFieldAttrs :: [FieldAttr] -> FieldDef -> FieldDef
- type LogFunc = Loc -> LogSource -> LogLevel -> LogStr -> IO ()
- data InsertSqlResult
- data Statement = Statement {
- stmtFinalize :: IO ()
- stmtReset :: IO ()
- stmtExecute :: [PersistValue] -> IO Int64
- stmtQuery :: forall (m :: Type -> Type). MonadIO m => [PersistValue] -> Acquire (ConduitM () [PersistValue] m ())
- renderCascadeAction :: CascadeAction -> Text
- renderFieldCascade :: FieldCascade -> Text
- noCascade :: FieldCascade
- isHaskellField :: FieldDef -> Bool
- isFieldNotGenerated :: FieldDef -> Bool
- parseFieldAttrs :: [Text] -> [FieldAttr]
- keyAndEntityFields :: EntityDef -> NonEmpty FieldDef
- entityPrimary :: EntityDef -> Maybe CompositeDef
- entitiesPrimary :: EntityDef -> NonEmpty FieldDef
- fieldAttrsContainsNullable :: [FieldAttr] -> IsNullable
- data Checkmark
- data IsNullable
- data WhyNullable
- data EntityDef
- data EntityIdDef
- type ExtraLine = [Text]
- type Attr = Text
- data FieldAttr
- data FieldType
- data ReferenceDef
- data EmbedEntityDef = EmbedEntityDef {}
- data EmbedFieldDef = EmbedFieldDef {
- emFieldDB :: FieldNameDB
- emFieldEmbed :: Maybe (Either SelfEmbed EntityNameHS)
- data UniqueDef = UniqueDef {
- uniqueHaskell :: !ConstraintNameHS
- uniqueDBName :: !ConstraintNameDB
- uniqueFields :: !(NonEmpty (FieldNameHS, FieldNameDB))
- uniqueAttrs :: ![Attr]
- data CompositeDef = CompositeDef {
- compositeFields :: !(NonEmpty FieldDef)
- compositeAttrs :: ![Attr]
- type ForeignFieldDef = (FieldNameHS, FieldNameDB)
- data ForeignDef = ForeignDef {
- foreignRefTableHaskell :: !EntityNameHS
- foreignRefTableDBName :: !EntityNameDB
- foreignConstraintNameHaskell :: !ConstraintNameHS
- foreignConstraintNameDBName :: !ConstraintNameDB
- foreignFieldCascade :: !FieldCascade
- foreignFields :: ![(ForeignFieldDef, ForeignFieldDef)]
- foreignAttrs :: ![Attr]
- foreignNullable :: Bool
- foreignToPrimary :: Bool
- data FieldCascade = FieldCascade {
- fcOnUpdate :: !(Maybe CascadeAction)
- fcOnDelete :: !(Maybe CascadeAction)
- data CascadeAction
- = Cascade
- | Restrict
- | SetNull
- | SetDefault
- data PersistException
- data SqlType
- data PersistFilter
- data UpdateException
- data PersistUpdate
- data FieldDef = FieldDef {
- fieldHaskell :: !FieldNameHS
- fieldDB :: !FieldNameDB
- fieldType :: !FieldType
- fieldSqlType :: !SqlType
- fieldAttrs :: ![FieldAttr]
- fieldStrict :: !Bool
- fieldReference :: !ReferenceDef
- fieldCascade :: !FieldCascade
- fieldComments :: !(Maybe Text)
- fieldGenerated :: !(Maybe Text)
- fieldIsImplicitIdColumn :: !Bool
- data IsolationLevel
- fromPersistValueText :: PersistValue -> Either Text Text
- data PersistValue where
- PersistText Text
- PersistByteString ByteString
- PersistInt64 Int64
- PersistDouble Double
- PersistRational Rational
- PersistBool Bool
- PersistDay Day
- PersistTimeOfDay TimeOfDay
- PersistUTCTime UTCTime
- PersistNull
- PersistList [PersistValue]
- PersistMap [(Text, PersistValue)]
- PersistObjectId ByteString
- PersistArray [PersistValue]
- PersistLiteral_ LiteralType ByteString
- pattern PersistDbSpecific :: ByteString -> PersistValue
- pattern PersistLiteralEscaped :: ByteString -> PersistValue
- pattern PersistLiteral :: ByteString -> PersistValue
- data LiteralType
- class DatabaseName a where
- escapeWith :: (Text -> str) -> a -> str
- newtype FieldNameDB = FieldNameDB {}
- newtype FieldNameHS = FieldNameHS {}
- newtype EntityNameHS = EntityNameHS {}
- newtype EntityNameDB = EntityNameDB {}
- newtype ConstraintNameDB = ConstraintNameDB {}
- newtype ConstraintNameHS = ConstraintNameHS {}
- type family PersistConfigPool c
- type family PersistConfigBackend c :: (Type -> Type) -> Type -> Type
- class PersistConfig c where
- type PersistConfigBackend c :: (Type -> Type) -> Type -> Type
- type PersistConfigPool c
- loadConfig :: Value -> Parser c
- applyEnv :: c -> IO c
- createPoolConfig :: c -> IO (PersistConfigPool c)
- runPool :: MonadUnliftIO m => c -> PersistConfigBackend c m a -> PersistConfigPool c -> m a
Setup
If you're already using persistent
, then you're ready to use
esqueleto
, no further setup is needed. If you're just
starting a new project and would like to use esqueleto
, take
a look at persistent
's book first
(http://www.yesodweb.com/book/persistent) to learn how to
define your schema.
Introduction
The main goals of esqueleto
are to:
- Be easily translatable to SQL. When you take a look at a
esqueleto
query, you should be able to know exactly how the SQL query will end up. (As opposed to being a relational algebra EDSL such as HaskellDB, which is non-trivial to translate into SQL.) - Support the most widely used SQL features. We'd like you to be
able to use
esqueleto
for all of your queries, no exceptions. Send a pull request or open an issue on our project page (https://github.com/prowdsponsor/esqueleto) if there's anything missing that you'd like to see. - Be as type-safe as possible. We strive to provide as many type checks as possible. If you get bitten by some invalid code that type-checks, please open an issue on our project page so we can take a look.
However, it is not a goal to be able to write portable SQL.
We do not try to hide the differences between DBMSs from you,
and esqueleto
code that works for one database may not work
on another. This is a compromise we have to make in order to
give you as much control over the raw SQL as possible without
losing too much convenience. This also means that you may
type-check a query that doesn't work on your DBMS.
Getting started
We like clean, easy-to-read EDSLs. However, in order to achieve this goal we've used a lot of type hackery, leading to some hard-to-read type signatures. On this section, we'll try to build some intuition about the syntax.
For the following examples, we'll use this example schema:
share [mkPersist sqlSettings, mkMigrate "migrateAll"] [persist| Person name String age Int Maybe deriving Eq Show BlogPost title String authorId PersonId deriving Eq Show Follow follower PersonId followed PersonId deriving Eq Show |]
Most of esqueleto
was created with SELECT
statements in
mind, not only because they're the most common but also
because they're the most complex kind of statement. The most
simple kind of SELECT
would be:
SELECT * FROM Person
In esqueleto
, we may write the same query above as:
do people <-select
$from
$ \person -> do return person liftIO $ mapM_ (putStrLn . personName . entityVal) people
The expression above has type SqlPersist m ()
, while
people
has type [Entity Person]
. The query above will be
translated into exactly the same query we wrote manually, but
instead of SELECT *
it will list all entity fields (using
*
is not robust). Note that esqueleto
knows that we want
an Entity Person
just because of the personName
that we're
printing later.
However, most of the time we need to filter our queries using
WHERE
. For example:
SELECT * FROM Person WHERE Person.name = "John"
In esqueleto
, we may write the same query above as:
select
$from
$ \p -> dowhere_
(p^.
PersonName==.
val
"John") return p
Although esqueleto
's code is a bit more noisy, it's has
almost the same structure (save from the return
). The
(
operator is used to project a field from an entity.
The field name is the same one generated by ^.
)persistent
's
Template Haskell functions. We use val
to lift a constant
Haskell value into the SQL query.
Another example would be:
SELECT * FROM Person WHERE Person.age >= 18
In esqueleto
, we may write the same query above as:
select
$from
$ \p -> dowhere_
(p^.
PersonAge>=.
just
(val
18)) return p
Since age
is an optional Person
field, we use just
to lift
into val
18 :: SqlExpr (Value Int)just (
.val
18) ::
SqlExpr (Value (Maybe Int))
Implicit joins are represented by tuples. For example, to get the list of all blog posts and their authors, we could write:
SELECT BlogPost.*, Person.* FROM BlogPost, Person WHERE BlogPost.authorId = Person.id ORDER BY BlogPost.title ASC
In esqueleto
, we may write the same query above as:
select
$from
$ \(b, p) -> dowhere_
(b^.
BlogPostAuthorId==.
p^.
PersonId)orderBy
[asc
(b^.
BlogPostTitle)] return (b, p)
However, you may want your results to include people who don't
have any blog posts as well using a LEFT OUTER JOIN
:
SELECT Person.*, BlogPost.* FROM Person LEFT OUTER JOIN BlogPost ON Person.id = BlogPost.authorId ORDER BY Person.name ASC, BlogPost.title ASC
In esqueleto
, we may write the same query above as:
select
$from
$ \(p `LeftOuterJoin
` mb) -> doon
(just
(p^.
PersonId)==.
mb?.
BlogPostAuthorId)orderBy
[asc
(p^.
PersonName),asc
(mb?.
BlogPostTitle)] return (p, mb)
On a LEFT OUTER JOIN
the entity on the right hand side may
not exist (i.e. there may be a Person
without any
BlogPost
s), so while p :: SqlExpr (Entity Person)
, we have
mb :: SqlExpr (Maybe (Entity BlogPost))
. The whole
expression above has type SqlPersist m [(Entity Person, Maybe
(Entity BlogPost))]
. Instead of using (^.)
, we used
(
to project a field from a ?.
)Maybe (Entity a)
.
We are by no means limited to joins of two tables, nor by
joins of different tables. For example, we may want a list
of the Follow
entity:
SELECT P1.*, Follow.*, P2.* FROM Person AS P1 INNER JOIN Follow ON P1.id = Follow.follower INNER JOIN Person AS P2 ON P2.id = Follow.followed
In esqueleto
, we may write the same query above as:
select
$from
$ \(p1 `InnerJoin
` f `InnerJoin
` p2) -> doon
(p1^.
PersonId==.
f^.
FollowFollower)on
(p2^.
PersonId==.
f^.
FollowFollowed) return (p1, f, p2)
We also currently support UPDATE
and DELETE
statements.
For example:
doupdate
$ \p -> doset
p [ PersonName=.
val
"João" ]where_
(p^.
PersonName==.
val
"Joao")delete
$from
$ \p -> dowhere_
(p^.
PersonAge<.
just
(val
14))
The results of queries can also be used for insertions.
In SQL
, we might write the following, inserting a new blog
post for every user:
INSERT INTO BlogPost SELECT ('Group Blog Post', id) FROM Person
In esqueleto
, we may write the same query above as:
insertSelect
$from
$ \p-> return $ BlogPost<#
"Group Blog Post"<&>
(p^.
PersonId)
Individual insertions can be performed through Persistent's
insert
function, reexported for convenience.
esqueleto
's Language
on :: SqlExpr (Value Bool) -> SqlQuery () Source #
An ON
clause, useful to describe how two tables are related. Cross joins
and tuple-joins do not need an on
clause, but InnerJoin
and the various
outer joins do.
Database.Esqueleto.Experimental in version 4.0.0.0 of the library. The
Experimental
module has a dramatically improved means for introducing
tables and entities that provides more power and less potential for runtime
errors.
If you don't include an on
clause (or include too many!) then a runtime
exception will be thrown.
As an example, consider this simple join:
select
$from
$ \(foo `InnerJoin
` bar) -> doon
(foo^.
FooId==.
bar^.
BarFooId) ...
We need to specify the clause for joining the two columns together. If we had this:
select
$from
$ \(foo `CrossJoin
` bar) -> do ...
Then we can safely omit the on
clause, because the cross join will make
pairs of all records possible.
You can do multiple on
clauses in a query. This query joins three tables,
and has two on
clauses:
select
$from
$ \(foo `InnerJoin
` bar `InnerJoin
` baz) -> doon
(baz^.
BazId==.
bar^.
BarBazId)on
(foo^.
FooId==.
bar^.
BarFooId) ...
Old versions of esqueleto required that you provide the on
clauses in
reverse order. This restriction has been lifted - you can now provide on
clauses in any order, and the SQL should work itself out. The above query is
now totally equivalent to this:
select
$from
$ \(foo `InnerJoin
` bar `InnerJoin
` baz) -> doon
(foo^.
FooId==.
bar^.
BarFooId)on
(baz^.
BazId==.
bar^.
BarBazId) ...
groupBy :: ToSomeValues a => a -> SqlQuery () Source #
GROUP BY
clause. You can enclose multiple columns
in a tuple.
select $from
\(foo `InnerJoin
` bar) -> doon
(foo^.
FooBarId==.
bar^.
BarId)groupBy
(bar^.
BarId, bar^.
BarName) return (bar^.
BarId, bar^.
BarName, countRows)
With groupBy you can sort by aggregate functions, like so
(we used let
to restrict the more general countRows
to
SqlSqlExpr (Value Int)
to avoid ambiguity---the second use of
countRows
has its type restricted by the :: Int
below):
r <- select $from
\(foo `InnerJoin
` bar) -> doon
(foo^.
FooBarId==.
bar^.
BarId)groupBy
$ bar^.
BarName let countRows' =countRows
orderBy
[asc
countRows'] return (bar^.
BarName, countRows') forM_ r $ \(Value
name,Value
count) -> do print name print (count :: Int)
Need more columns?
The ToSomeValues
class is defined for SqlExpr
and tuples of SqlExpr
s.
We only have definitions for up to 8 elements in a tuple right now, so it's
possible that you may need to have more than 8 elements.
For example, consider a query with a groupBy
call like this:
groupBy (e0, e1, e2, e3, e4, e5, e6, e7)
This is the biggest you can get with a single tuple. However, you can easily nest the tuples to add more:
groupBy ((e0, e1, e2, e3, e4, e5, e6, e7), e8, e9)
orderBy :: [SqlExpr OrderBy] -> SqlQuery () Source #
ORDER BY
clause. See also asc
and desc
.
Multiple calls to orderBy
get concatenated on the final
query, including distinctOnOrderBy
.
rand :: SqlExpr OrderBy Source #
Deprecated: Since 2.6.0: rand
ordering function is not uniform across all databases! To avoid accidental partiality it will be removed in the next major version.
ORDER BY random()
clause.
Since: 1.3.10
asc :: PersistField a => SqlExpr (Value a) -> SqlExpr OrderBy Source #
Ascending order of this field or SqlExpression.
desc :: PersistField a => SqlExpr (Value a) -> SqlExpr OrderBy Source #
Descending order of this field or SqlExpression.
distinctOn :: [SqlExpr DistinctOn] -> SqlQuery a -> SqlQuery a Source #
DISTINCT ON
. Change the current SELECT
into
SELECT DISTINCT ON (SqlExpressions)
. For example:
select $from
\foo ->distinctOn
[don
(foo ^. FooName),don
(foo ^. FooState)] $ do ...
You can also chain different calls to distinctOn
. The
above is equivalent to:
select $from
\foo ->distinctOn
[don
(foo ^. FooName)] $distinctOn
[don
(foo ^. FooState)] $ do ...
Each call to distinctOn
adds more SqlExpressions. Calls to
distinctOn
override any calls to distinct
.
Note that PostgreSQL requires the SqlExpressions on DISTINCT
ON
to be the first ones to appear on a ORDER BY
. This is
not managed automatically by esqueleto, keeping its spirit
of trying to be close to raw SQL.
Supported by PostgreSQL only.
Since: 2.2.4
don :: SqlExpr (Value a) -> SqlExpr DistinctOn Source #
Erase an SqlExpression's type so that it's suitable to
be used by distinctOn
.
Since: 2.2.4
distinctOnOrderBy :: [SqlExpr OrderBy] -> SqlQuery a -> SqlQuery a Source #
A convenience function that calls both distinctOn
and
orderBy
. In other words,
distinctOnOrderBy
[asc foo, desc bar, desc quux] $ do
...
is the same as:
distinctOn
[don foo, don bar, don quux] $ doorderBy
[asc foo, desc bar, desc quux] ...
Since: 2.2.4
locking :: LockingKind -> SqlQuery () Source #
Add a locking clause to the query. Please read
LockingKind
documentation and your RDBMS manual.
Unsafe since not all locking clauses are implemented for every RDBMS
If multiple calls to locking
are made on the same query,
the last one is used.
Since: 2.2.7
sub_select :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (Value a) Source #
Deprecated: sub_select sub_select is an unsafe function to use. If used with a SqlQuery that returns 0 results, then it may return NULL despite not mentioning Maybe in the return type. If it returns more than 1 result, then it will throw a SQL error. Instead, consider using one of the following alternatives: - subSelect: attaches a LIMIT 1 and the Maybe return type, totally safe. - subSelectMaybe: Attaches a LIMIT 1, useful for a query that already has a Maybe in the return type. - subSelectCount: Performs a count of the query - this is always safe. - subSelectUnsafe: Performs no checks or guarantees. Safe to use with countRows and friends.
Execute a subquery SELECT
in an SqlExpression. Returns a
simple value so should be used only when the SELECT
query
is guaranteed to return just one row.
Deprecated in 3.2.0.
(^.) :: forall typ val. (PersistEntity val, PersistField typ) => SqlExpr (Entity val) -> EntityField val typ -> SqlExpr (Value typ) infixl 9 Source #
Project a field of an entity.
(?.) :: (PersistEntity val, PersistField typ) => SqlExpr (Maybe (Entity val)) -> EntityField val typ -> SqlExpr (Value (Maybe typ)) Source #
Project a field of an entity that may be null.
val :: PersistField typ => typ -> SqlExpr (Value typ) Source #
Lift a constant value from Haskell-land to the query.
isNothing :: PersistField typ => SqlExpr (Value (Maybe typ)) -> SqlExpr (Value Bool) Source #
IS NULL
comparison.
For IS NOT NULL
, you can negate this with not_
, as in not_ (isNothing (person ^. PersonAge))
Warning: Persistent and Esqueleto have different behavior for != Nothing
:
Haskell | SQL | |
---|---|---|
Persistent |
| IS NOT NULL |
Esqueleto |
| != NULL |
In SQL, = NULL
and != NULL
return NULL instead of true or false. For this reason, you very likely do not want to use
in Esqueleto.
You may find these !=.
Nothinghlint
rules helpful to enforce this:
- error: {lhs: v Database.Esqueleto.==. Database.Esqueleto.nothing, rhs: Database.Esqueleto.isNothing v, name: Use Esqueleto's isNothing} - error: {lhs: v Database.Esqueleto.==. Database.Esqueleto.val Nothing, rhs: Database.Esqueleto.isNothing v, name: Use Esqueleto's isNothing} - error: {lhs: v Database.Esqueleto.!=. Database.Esqueleto.nothing, rhs: not_ (Database.Esqueleto.isNothing v), name: Use Esqueleto's not isNothing} - error: {lhs: v Database.Esqueleto.!=. Database.Esqueleto.val Nothing, rhs: not_ (Database.Esqueleto.isNothing v), name: Use Esqueleto's not isNothing}
withNonNull :: PersistField typ => SqlExpr (Value (Maybe typ)) -> (SqlExpr (Value typ) -> SqlQuery a) -> SqlQuery a Source #
Project an SqlExpression that may be null, guarding against null cases.
countDistinct :: Num a => SqlExpr (Value typ) -> SqlExpr (Value a) Source #
COUNT(DISTINCT x)
.
Since: 2.4.1
(==.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool) infix 4 Source #
(>=.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool) infix 4 Source #
(>.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool) infix 4 Source #
(<=.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool) infix 4 Source #
(<.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool) infix 4 Source #
(!=.) :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (Value typ) -> SqlExpr (Value Bool) infix 4 Source #
between :: PersistField a => SqlExpr (Value a) -> (SqlExpr (Value a), SqlExpr (Value a)) -> SqlExpr (Value Bool) Source #
BETWEEN
.
@since: 3.1.0
(+.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a) infixl 6 Source #
(-.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a) infixl 6 Source #
(/.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a) infixl 7 Source #
(*.) :: PersistField a => SqlExpr (Value a) -> SqlExpr (Value a) -> SqlExpr (Value a) infixl 7 Source #
round_ :: (PersistField a, Num a, PersistField b, Num b) => SqlExpr (Value a) -> SqlExpr (Value b) Source #
ceiling_ :: (PersistField a, Num a, PersistField b, Num b) => SqlExpr (Value a) -> SqlExpr (Value b) Source #
floor_ :: (PersistField a, Num a, PersistField b, Num b) => SqlExpr (Value a) -> SqlExpr (Value b) Source #
sum_ :: (PersistField a, PersistField b) => SqlExpr (Value a) -> SqlExpr (Value (Maybe b)) Source #
avg_ :: (PersistField a, PersistField b) => SqlExpr (Value a) -> SqlExpr (Value (Maybe b)) Source #
castNum :: (Num a, Num b) => SqlExpr (Value a) -> SqlExpr (Value b) Source #
Allow a number of one type to be used as one of another type via an implicit cast. An explicit cast is not made, this function changes only the types on the Haskell side.
Caveat: Trying to use castNum
from Double
to Int
will not result in an integer, the original fractional
number will still be used! Use round_
, ceiling_
or
floor_
instead.
Safety: This operation is mostly safe due to the Num
constraint between the types and the fact that RDBMSs
usually allow numbers of different types to be used
interchangeably. However, there may still be issues with
the query not being accepted by the RDBMS or persistent
not being able to parse it.
Since: 2.2.9
castNumM :: (Num a, Num b) => SqlExpr (Value (Maybe a)) -> SqlExpr (Value (Maybe b)) Source #
Same as castNum
, but for nullable values.
Since: 2.2.9
coalesce :: PersistField a => [SqlExpr (Value (Maybe a))] -> SqlExpr (Value (Maybe a)) Source #
COALESCE
function. Evaluates the arguments in order and
returns the value of the first non-NULL SqlExpression, or NULL
(Nothing) otherwise. Some RDBMSs (such as SQLite) require
at least two arguments; please refer to the appropriate
documentation.
Since: 1.4.3
coalesceDefault :: PersistField a => [SqlExpr (Value (Maybe a))] -> SqlExpr (Value a) -> SqlExpr (Value a) Source #
Like coalesce
, but takes a non-nullable SqlExpression
placed at the end of the SqlExpression list, which guarantees
a non-NULL result.
Since: 1.4.3
upper_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) Source #
UPPER
function.
@since 3.3.0
ltrim_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) Source #
LTRIM
function.
@since 3.3.0
rtrim_ :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) Source #
RTRIM
function.
@since 3.3.0
length_ :: (SqlString s, Num a) => SqlExpr (Value s) -> SqlExpr (Value a) Source #
LENGTH
function.
@since 3.3.0
left_ :: (SqlString s, Num a) => (SqlExpr (Value s), SqlExpr (Value a)) -> SqlExpr (Value s) Source #
LEFT
function.
@since 3.3.0
right_ :: (SqlString s, Num a) => (SqlExpr (Value s), SqlExpr (Value a)) -> SqlExpr (Value s) Source #
RIGHT
function.
@since 3.3.0
like :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) -> SqlExpr (Value Bool) infixr 2 Source #
LIKE
operator.
ilike :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) -> SqlExpr (Value Bool) infixr 2 Source #
ILIKE
operator (case-insensitive LIKE
).
Supported by PostgreSQL only.
Since: 2.2.3
concat_ :: SqlString s => [SqlExpr (Value s)] -> SqlExpr (Value s) Source #
The CONCAT
function with a variable number of
parameters. Supported by MySQL and PostgreSQL.
(++.) :: SqlString s => SqlExpr (Value s) -> SqlExpr (Value s) -> SqlExpr (Value s) infixr 5 Source #
castString :: (SqlString s, SqlString r) => SqlExpr (Value s) -> SqlExpr (Value r) Source #
Cast a string type into Text
. This function
is very useful if you want to use newtype
s, or if you want
to apply functions such as like
to strings of different
types.
Safety: This is a slightly unsafe function, especially if
you have defined your own instances of SqlString
. Also,
since Maybe
is an instance of SqlString
, it's possible
to turn a nullable value into a non-nullable one. Avoid
using this function if possible.
subList_select :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (ValueList a) Source #
Execute a subquery SELECT
in an SqlExpression. Returns a
list of values.
valList :: PersistField typ => [typ] -> SqlExpr (ValueList typ) Source #
Lift a list of constant value from Haskell-land to the query.
in_ :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (ValueList typ) -> SqlExpr (Value Bool) Source #
IN
operator. For example if you want to select all Person
s by a list
of IDs:
SELECT * FROM Person WHERE Person.id IN (?)
In esqueleto
, we may write the same query above as:
select $from
$ \person -> dowhere_
$ person^.
PersonId `in_
`valList
personIds return person
Where personIds
is of type [Key Person]
.
notIn :: PersistField typ => SqlExpr (Value typ) -> SqlExpr (ValueList typ) -> SqlExpr (Value Bool) Source #
NOT IN
operator.
set :: PersistEntity val => SqlExpr (Entity val) -> [SqlExpr (Entity val) -> SqlExpr Update] -> SqlQuery () Source #
SET
clause used on UPDATE
s. Note that while it's not
a type error to use this function on a SELECT
, it will
most certainly result in a runtime error.
(=.) :: (PersistEntity val, PersistField typ) => EntityField val typ -> SqlExpr (Value typ) -> SqlExpr (Entity val) -> SqlExpr Update infixr 3 Source #
(+=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update infixr 3 Source #
(-=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update infixr 3 Source #
(*=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update infixr 3 Source #
(/=.) :: (PersistEntity val, PersistField a) => EntityField val a -> SqlExpr (Value a) -> SqlExpr (Entity val) -> SqlExpr Update infixr 3 Source #
case_ :: PersistField a => [(SqlExpr (Value Bool), SqlExpr (Value a))] -> SqlExpr (Value a) -> SqlExpr (Value a) Source #
CASE
statement. For example:
select $ return $case_
[when_
(exists
$from
$ \p -> dowhere_
(p^.
PersonName==.
val
"Mike"))then_
(sub_select
$from
$ \v -> do let sub =from
$ \c -> dowhere_
(c^.
PersonName==.
val
"Mike") return (c^.
PersonFavNum)where_
(v^.
PersonFavNum >.sub_select
sub) return $count
(v^.
PersonName) +.val
(1 :: Int)) ] (else_
$val
(-1))
This query is a bit complicated, but basically it checks if a person
named "Mike"
exists, and if that person does, run the subquery to find
out how many people have a ranking (by Fav Num) higher than "Mike"
.
NOTE: There are a few things to be aware about this statement.
- This only implements the full CASE statement, it does not implement the "simple" CASE statement.
- At least one
when_
andthen_
is mandatory otherwise it will emit an error. - The
else_
is also mandatory, unlike the SQL statement in which if theELSE
is omitted it will return aNULL
. You can reproduce this vianothing
.
Since: 2.1.2
toBaseId :: ToBaseId ent => SqlExpr (Value (Key ent)) -> SqlExpr (Value (Key (BaseEnt ent))) Source #
Convert an entity's key into another entity's.
This function is to be used when you change an entity's Id
to be
that of another entity. For example:
Bar barNum Int Foo bar BarId fooNum Int Primary bar
In this example, Bar is said to be the BaseEnt(ity), and Foo the child. To model this in Esqueleto, declare:
instance ToBaseId Foo where type BaseEnt Foo = Bar toBaseIdWitness barId = FooKey barId
Now you're able to write queries such as:
select
$from
$ (bar `InnerJoin
` foo) -> doon
(toBaseId
(foo^.
FooId)==.
bar^.
BarId) return (bar, foo)
Note: this function may be unsafe to use in conditions not like the one of the example above.
Since: 2.4.3
subSelect :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (Value (Maybe a)) Source #
Execute a subquery SELECT
in a SqlExpr
. The query passed to this
function will only return a single result - it has a LIMIT 1
passed in to
the query to make it safe, and the return type is Maybe
to indicate that
the subquery might result in 0 rows.
If you find yourself writing
, then consider using
joinV
. subSelect
subSelectMaybe
.
If you're performing a countRows
, then you can use subSelectCount
which
is safe.
If you know that the subquery will always return exactly one row (eg
a foreign key constraint guarantees that you'll get exactly one row), then
consider subSelectUnsafe
, along with a comment explaining why it is safe.
Since: 3.2.0
subSelectMaybe :: PersistField a => SqlQuery (SqlExpr (Value (Maybe a))) -> SqlExpr (Value (Maybe a)) Source #
Execute a subquery SELECT
in a SqlExpr
. This function is a shorthand
for the common
idiom, where you are calling
joinV
. subSelect
subSelect
on an expression that would be Maybe
already.
As an example, you would use this function when calling sum_
or max_
,
which have Maybe
in the result type (for a 0 row query).
Since: 3.2.0
subSelectCount :: (Num a, PersistField a) => SqlQuery ignored -> SqlExpr (Value a) Source #
Performs a COUNT
of the given query in a subSelect
manner. This is
always guaranteed to return a result value, and is completely safe.
Since: 3.2.0
:: (BackendCompatible SqlBackend (PersistEntityBackend val1), PersistEntity val1, PersistEntity val2, PersistField a) | |
=> SqlExpr (Entity val2) | An expression representing the table you have access to now. |
-> EntityField val2 (Key val1) | The foreign key field on the table. |
-> (SqlExpr (Entity val1) -> SqlExpr (Value a)) | A function to extract a value from the foreign reference table. |
-> SqlExpr (Value a) |
Performs a sub-select using the given foreign key on the entity. This is useful to extract values that are known to be present by the database schema.
As an example, consider the following persistent definition:
User profile ProfileId Profile name Text
The following query will return the name of the user.
getUserWithName =select
$from
$ user ->pure
(user,subSelectForeign
user UserProfile (^. ProfileName)
Since: 3.2.0
subSelectList :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (ValueList a) Source #
Execute a subquery SELECT
in a SqlExpr
that returns a list. This is an
alias for subList_select
and is provided for symmetry with the other safe
subselect functions.
Since: 3.2.0
subSelectUnsafe :: PersistField a => SqlQuery (SqlExpr (Value a)) -> SqlExpr (Value a) Source #
Execute a subquery SELECT
in a SqlExpr
. This function is unsafe,
because it can throw runtime exceptions in two cases:
- If the query passed has 0 result rows, then it will return a
NULL
value. Thepersistent
parsing operations will fail on an unexpectedNULL
. - If the query passed returns more than one row, then the SQL engine will fail with an error like "More than one row returned by a subquery used as an expression".
This function is safe if you guarantee that exactly one row will be returned,
or if the result already has a Maybe
type for some reason.
For variants with the safety encoded already, see subSelect
and
subSelectMaybe
. For the most common safe use of this, see subSelectCount
.
Since: 3.2.0
when_ :: expr (Value Bool) -> () -> expr a -> (expr (Value Bool), expr a) Source #
Syntax sugar for case_
.
Since: 2.1.2
from :: From a => (a -> SqlQuery b) -> SqlQuery b Source #
FROM
clause: bring entities into scope.
Note that this function will be replaced by the one in
Database.Esqueleto.Experimental in version 4.0.0.0 of the library. The
Experimental
module has a dramatically improved means for introducing
tables and entities that provides more power and less potential for runtime
errors.
This function internally uses two type classes in order to provide some flexibility of how you may call it. Internally we refer to these type classes as the two different magics.
The innermost magic allows you to use from
with the
following types:
expr (Entity val)
, which brings a single entity into scope.expr (Maybe (Entity val))
, which brings a single entity that may beNULL
into scope. Used forOUTER JOIN
s.- A
JOIN
of any other two types allowed by the innermost magic, where aJOIN
may be anInnerJoin
, aCrossJoin
, aLeftOuterJoin
, aRightOuterJoin
, or aFullOuterJoin
. TheJOINs
have left fixity.
The outermost magic allows you to use from
on any tuples of
types supported by innermost magic (and also tuples of tuples,
and so on), up to 8-tuples.
Note that using from
for the same entity twice does work and
corresponds to a self-join. You don't even need to use two
different calls to from
, you may use a JOIN
or a tuple.
The following are valid examples of uses of from
(the types
of the arguments of the lambda are inside square brackets):
from
$ \person -> ...from
$ \(person, blogPost) -> ...from
$ \(p `LeftOuterJoin
` mb) -> ...from
$ \(p1 `InnerJoin
` f `InnerJoin
` p2) -> ...from
$ \((p1 `InnerJoin
` f) `InnerJoin
` p2) -> ...
The types of the arguments to the lambdas above are, respectively:
person :: ( Esqueleto query expr backend , PersistEntity Person , PersistEntityBackend Person ~ backend ) => expr (Entity Person) (person, blogPost) :: (...) => (expr (Entity Person), expr (Entity BlogPost)) (p `LeftOuterJoin
` mb) :: (...) => InnerJoin (expr (Entity Person)) (expr (Maybe (Entity BlogPost))) (p1 `InnerJoin
` f `InnerJoin
` p2) :: (...) => InnerJoin (InnerJoin (expr (Entity Person)) (expr (Entity Follow))) (expr (Entity Person)) (p1 `InnerJoin
` (f `InnerJoin
` p2)) :: :: (...) => InnerJoin (expr (Entity Person)) (InnerJoin (expr (Entity Follow)) (expr (Entity Person)))
Note that some backends may not support all kinds of JOIN
s.
A single value (as opposed to a whole entity). You may use
(
or ^.
)(
to get a ?.
)Value
from an Entity
.
Instances
Applicative Value Source # | |
Functor Value Source # | Since: 1.4.4 |
Monad Value Source # | |
(PersistEntity rec, PersistField typ, SymbolToField sym rec typ) => HasField (sym :: Symbol) (SqlExpr (Entity rec)) (SqlExpr (Value typ)) Source # | This instance allows you to use Example: -- persistent model: BlogPost authorId PersonId title Text -- query: This is exactly equivalent to the following: blogPost :: SqlExpr (Entity BlogPost) blogPost ^. BlogPostTitle blogPost ^. #title blogPost.title There's another instance defined on Since: 3.5.4.0 |
(PersistEntity rec, PersistField typ, SymbolToField sym rec typ) => HasField (sym :: Symbol) (SqlExpr (Maybe (Entity rec))) (SqlExpr (Value (Maybe typ))) Source # | This instance allows you to use Example: -- persistent model: Person name Text BlogPost title Text authorId PersonId -- query: The following forms are all equivalent: blogPost :: SqlExpr (Maybe (Entity BlogPost)) blogPost ?. BlogPostTitle blogPost ?. #title blogPost.title Since: 3.5.4.0 |
(ToFrom a a', SqlSelect b r, ToAlias b, ToAliasReference b, d ~ (a' :& b)) => DoInnerJoin Lateral a (a' -> SqlQuery b, d -> SqlExpr (Value Bool)) d Source # | |
(ToFrom a a', ToMaybe b, d ~ (a' :& ToMaybeT b), SqlSelect b r, ToAlias b, ToAliasReference b) => DoLeftJoin Lateral a (a' -> SqlQuery b, d -> SqlExpr (Value Bool)) d Source # | |
Show a => Show (Value a) Source # | |
ToAlias (SqlExpr (Value a)) Source # | |
ToAliasReference (SqlExpr (Value a)) Source # | |
ToMaybe (SqlExpr (Value a)) Source # | |
ToSomeValues (SqlExpr (Value a)) Source # | |
Defined in Database.Esqueleto.Internal.Internal | |
Eq a => Eq (Value a) Source # | |
Ord a => Ord (Value a) Source # | |
Defined in Database.Esqueleto.Internal.Internal | |
PersistField a => SqlSelect (SqlExpr (Value a)) (Value a) Source # | You may return any single value (i.e. a single column) from
a |
Defined in Database.Esqueleto.Internal.Internal sqlSelectCols :: IdentInfo -> SqlExpr (Value a) -> (Builder, [PersistValue]) Source # sqlSelectColCount :: Proxy (SqlExpr (Value a)) -> Int Source # sqlSelectProcessRow :: [PersistValue] -> Either Text (Value a) Source # sqlInsertInto :: IdentInfo -> SqlExpr (Value a) -> (Builder, [PersistValue]) Source # | |
type ToMaybeT (SqlExpr (Value a)) Source # | |
A list of single values. There's a limited set of functions
able to work with this data type (such as subList_select
,
valList
, in_
and exists
).
Instances
Show a => Show (ValueList a) Source # | |
Eq a => Eq (ValueList a) Source # | |
Ord a => Ord (ValueList a) Source # | |
Defined in Database.Esqueleto.Internal.Internal |
data DistinctOn Source #
Phantom type used by distinctOn
and don
.
data LockingKind Source #
Different kinds of locking clauses supported by locking
.
Note that each RDBMS has different locking support. The
constructors of this datatype specify only the syntax of the
locking mechanism, not its semantics. For example, even
though both MySQL and PostgreSQL support ForUpdate
, there
are no guarantees that they will behave the same.
Since: 2.2.7
ForUpdate |
Since: 2.2.7 |
ForUpdateSkipLocked |
Since: 2.2.7 |
ForShare |
Since: 2.2.7 |
LockInShareMode |
Since: 2.2.7 |
class LockableEntity a where Source #
Lockable entity
Example use:
select $ do (p :& bp) <- from $ tablePerson
BlogPostinnerJoin
tableon
do (p :& bp) -> p ^. PersonId ==. b ^. BlogPostAuthorId forUpdateOf (p :& b) skipLocked return p
Instances
PersistEntity val => LockableEntity (SqlExpr (Entity val)) Source # | |
Defined in Database.Esqueleto.Internal.Internal flattenLockableEntity :: SqlExpr (Entity val) -> NonEmpty LockableSqlExpr Source # | |
(LockableEntity a, LockableEntity b) => LockableEntity (a :& b) Source # | |
Defined in Database.Esqueleto.Internal.Internal flattenLockableEntity :: (a :& b) -> NonEmpty LockableSqlExpr Source # |
class PersistField a => SqlString a Source #
Phantom class of data types that are treated as strings by the RDBMS. It has no methods because it's only used to avoid type errors such as trying to concatenate integers.
If you have a custom data type or newtype
, feel free to make
it an instance of this class.
Since: 2.4.0
Instances
SqlString Html Source # | Since: 2.3.0 |
Defined in Database.Esqueleto.Internal.Internal | |
SqlString ByteString Source # | Since: 2.3.0 |
Defined in Database.Esqueleto.Internal.Internal | |
SqlString Text Source # | Since: 2.3.0 |
Defined in Database.Esqueleto.Internal.Internal | |
SqlString Text Source # | Since: 2.3.0 |
Defined in Database.Esqueleto.Internal.Internal | |
SqlString a => SqlString (Maybe a) Source # | Since: 2.4.0 |
Defined in Database.Esqueleto.Internal.Internal | |
a ~ Char => SqlString [a] Source # | Since: 2.3.0 |
Defined in Database.Esqueleto.Internal.Internal |
Joins
data InnerJoin a b infixl 2 Source #
Data type that represents an INNER JOIN
(see LeftOuterJoin
for an example).
a `InnerJoin` b infixl 2 |
Instances
IsJoinKind InnerJoin Source # | |
Defined in Database.Esqueleto.Internal.Internal | |
FromPreprocess (InnerJoin a b) => From (InnerJoin a b) Source # | |
(DoInnerJoin lateral lhs rhs r, lateral ~ IsLateral rhs) => ToFrom (InnerJoin lhs rhs) r Source # | |
data CrossJoin a b infixl 2 Source #
Data type that represents a CROSS JOIN
(see LeftOuterJoin
for an example).
a `CrossJoin` b infixl 2 |
Instances
IsJoinKind CrossJoin Source # | |
Defined in Database.Esqueleto.Internal.Internal | |
FromPreprocess (CrossJoin a b) => From (CrossJoin a b) Source # | |
(DoCrossJoin lateral lhs rhs r, IsLateral rhs ~ lateral) => ToFrom (CrossJoin lhs rhs) r Source # | |
data LeftOuterJoin a b infixl 2 Source #
Data type that represents a LEFT OUTER JOIN
. For example,
select $from
$ \(person `LeftOuterJoin
` pet) -> ...
is translated into
SELECT ... FROM Person LEFT OUTER JOIN Pet ...
See also: from
.
a `LeftOuterJoin` b infixl 2 |
Instances
IsJoinKind LeftOuterJoin Source # | |
Defined in Database.Esqueleto.Internal.Internal smartJoin :: a -> b -> LeftOuterJoin a b Source # reifyJoinKind :: LeftOuterJoin a b -> JoinKind Source # | |
FromPreprocess (LeftOuterJoin a b) => From (LeftOuterJoin a b) Source # | |
Defined in Database.Esqueleto.Internal.Internal from_ :: SqlQuery (LeftOuterJoin a b) Source # | |
(DoLeftJoin lateral lhs rhs r, lateral ~ IsLateral rhs) => ToFrom (LeftOuterJoin lhs rhs) r Source # | |
Defined in Database.Esqueleto.Experimental.From.Join toFrom :: LeftOuterJoin lhs rhs -> From r Source # |
data RightOuterJoin a b infixl 2 Source #
Data type that represents a RIGHT OUTER JOIN
(see LeftOuterJoin
for an example).
a `RightOuterJoin` b infixl 2 |
Instances
IsJoinKind RightOuterJoin Source # | |
Defined in Database.Esqueleto.Internal.Internal smartJoin :: a -> b -> RightOuterJoin a b Source # reifyJoinKind :: RightOuterJoin a b -> JoinKind Source # | |
FromPreprocess (RightOuterJoin a b) => From (RightOuterJoin a b) Source # | |
Defined in Database.Esqueleto.Internal.Internal from_ :: SqlQuery (RightOuterJoin a b) Source # | |
(ToFrom a a', ToFrom b b', ToMaybe a', ToMaybeT a' ~ ma, HasOnClause rhs (ma :& b'), ErrorOnLateral b, rhs ~ (b, (ma :& b') -> SqlExpr (Value Bool))) => ToFrom (RightOuterJoin a rhs) (ma :& b') Source # | |
Defined in Database.Esqueleto.Experimental.From.Join |
data FullOuterJoin a b infixl 2 Source #
Data type that represents a FULL OUTER JOIN
(see LeftOuterJoin
for an example).
a `FullOuterJoin` b infixl 2 |
Instances
IsJoinKind FullOuterJoin Source # | |
Defined in Database.Esqueleto.Internal.Internal smartJoin :: a -> b -> FullOuterJoin a b Source # reifyJoinKind :: FullOuterJoin a b -> JoinKind Source # | |
FromPreprocess (FullOuterJoin a b) => From (FullOuterJoin a b) Source # | |
Defined in Database.Esqueleto.Internal.Internal from_ :: SqlQuery (FullOuterJoin a b) Source # | |
(ToFrom a a', ToFrom b b', ToMaybe a', ToMaybeT a' ~ ma, ToMaybe b', ToMaybeT b' ~ mb, HasOnClause rhs (ma :& mb), ErrorOnLateral b, rhs ~ (b, (ma :& mb) -> SqlExpr (Value Bool))) => ToFrom (FullOuterJoin a rhs) (ma :& mb) Source # | |
Defined in Database.Esqueleto.Experimental.From.Join |
(Internal) A kind of JOIN
.
InnerJoinKind | INNER JOIN |
CrossJoinKind | CROSS JOIN |
LeftOuterJoinKind | LEFT OUTER JOIN |
RightOuterJoinKind | RIGHT OUTER JOIN |
FullOuterJoinKind | FULL OUTER JOIN |
data OnClauseWithoutMatchingJoinException Source #
Exception thrown whenever on
is used to create an ON
clause but no matching JOIN
is found.
Instances
SQL backend
SQL backend for esqueleto
using SqlPersistT
.
Instances
An expression on the SQL backend.
Raw expression: Contains a SqlExprMeta
and a function for
building the expr. It recieves a parameter telling it whether
it is in a parenthesized context, and takes information about the SQL
connection (mainly for escaping names) and returns both an
string (Builder
) and a list of values to be
interpolated by the SQL backend.
Instances
(TypeError SqlExprFunctorMessage :: Constraint) => Functor SqlExpr Source # | Folks often want the ability to promote a Haskell function into the
fmap :: (a -> b) -> This type signature is making a pretty strong claim: "Give me a Haskell
function from Let's suppose we *could* do this - This is why If you do have a SQL function, then you can provide a safe type and introduce
it with Since: 3.5.8.2 |
(PersistEntity rec, PersistField typ, SymbolToField sym rec typ) => HasField (sym :: Symbol) (SqlExpr (Entity rec)) (SqlExpr (Value typ)) Source # | This instance allows you to use Example: -- persistent model: BlogPost authorId PersonId title Text -- query: This is exactly equivalent to the following: blogPost :: SqlExpr (Entity BlogPost) blogPost ^. BlogPostTitle blogPost ^. #title blogPost.title There's another instance defined on Since: 3.5.4.0 |
(PersistEntity rec, PersistField typ, SymbolToField sym rec typ) => HasField (sym :: Symbol) (SqlExpr (Maybe (Entity rec))) (SqlExpr (Value (Maybe typ))) Source # | This instance allows you to use Example: -- persistent model: Person name Text BlogPost title Text authorId PersonId -- query: The following forms are all equivalent: blogPost :: SqlExpr (Maybe (Entity BlogPost)) blogPost ?. BlogPostTitle blogPost ?. #title blogPost.title Since: 3.5.4.0 |
(ToFrom a a', SqlSelect b r, ToAlias b, ToAliasReference b, d ~ (a' :& b)) => DoInnerJoin Lateral a (a' -> SqlQuery b, d -> SqlExpr (Value Bool)) d Source # | |
(ToFrom a a', ToMaybe b, d ~ (a' :& ToMaybeT b), SqlSelect b r, ToAlias b, ToAliasReference b) => DoLeftJoin Lateral a (a' -> SqlQuery b, d -> SqlExpr (Value Bool)) d Source # | |
ToAlias (SqlExpr (Value a)) Source # | |
ToAlias (SqlExpr (Entity a)) Source # | |
ToAlias (SqlExpr (Maybe (Entity a))) Source # | |
ToAliasReference (SqlExpr (Value a)) Source # | |
ToAliasReference (SqlExpr (Entity a)) Source # | |
ToAliasReference (SqlExpr (Maybe (Entity a))) Source # | |
ToMaybe (SqlExpr (Value a)) Source # | |
ToMaybe (SqlExpr (Entity a)) Source # | |
ToMaybe (SqlExpr (Maybe a)) Source # | |
FromPreprocess (SqlExpr (Entity val)) => From (SqlExpr (Entity val)) Source # | |
FromPreprocess (SqlExpr (Maybe (Entity val))) => From (SqlExpr (Maybe (Entity val))) Source # | |
(PersistEntity val, BackendCompatible SqlBackend (PersistEntityBackend val)) => FromPreprocess (SqlExpr (Entity val)) Source # | |
Defined in Database.Esqueleto.Internal.Internal fromPreprocess :: SqlQuery (PreprocessedFrom (SqlExpr (Entity val))) Source # | |
(PersistEntity val, BackendCompatible SqlBackend (PersistEntityBackend val)) => FromPreprocess (SqlExpr (Maybe (Entity val))) Source # | |
Defined in Database.Esqueleto.Internal.Internal fromPreprocess :: SqlQuery (PreprocessedFrom (SqlExpr (Maybe (Entity val)))) Source # | |
PersistEntity val => LockableEntity (SqlExpr (Entity val)) Source # | |
Defined in Database.Esqueleto.Internal.Internal flattenLockableEntity :: SqlExpr (Entity val) -> NonEmpty LockableSqlExpr Source # | |
ToSomeValues (SqlExpr (Value a)) Source # | |
Defined in Database.Esqueleto.Internal.Internal | |
a ~ Value b => UnsafeSqlFunctionArgument (SqlExpr a) Source # | |
PersistEntity ent => ToFrom (Table ent) (SqlExpr (Entity ent)) Source # | |
PersistEntity e => SqlSelect (SqlExpr (Insertion e)) (Insertion e) Source # |
|
Defined in Database.Esqueleto.Internal.Internal sqlSelectCols :: IdentInfo -> SqlExpr (Insertion e) -> (Builder, [PersistValue]) Source # sqlSelectColCount :: Proxy (SqlExpr (Insertion e)) -> Int Source # sqlSelectProcessRow :: [PersistValue] -> Either Text (Insertion e) Source # sqlInsertInto :: IdentInfo -> SqlExpr (Insertion e) -> (Builder, [PersistValue]) Source # | |
PersistField a => SqlSelect (SqlExpr (Value a)) (Value a) Source # | You may return any single value (i.e. a single column) from
a |
Defined in Database.Esqueleto.Internal.Internal sqlSelectCols :: IdentInfo -> SqlExpr (Value a) -> (Builder, [PersistValue]) Source # sqlSelectColCount :: Proxy (SqlExpr (Value a)) -> Int Source # sqlSelectProcessRow :: [PersistValue] -> Either Text (Value a) Source # sqlInsertInto :: IdentInfo -> SqlExpr (Value a) -> (Builder, [PersistValue]) Source # | |
PersistEntity a => SqlSelect (SqlExpr (Entity a)) (Entity a) Source # | |
Defined in Database.Esqueleto.Internal.Internal sqlSelectCols :: IdentInfo -> SqlExpr (Entity a) -> (Builder, [PersistValue]) Source # sqlSelectColCount :: Proxy (SqlExpr (Entity a)) -> Int Source # sqlSelectProcessRow :: [PersistValue] -> Either Text (Entity a) Source # sqlInsertInto :: IdentInfo -> SqlExpr (Entity a) -> (Builder, [PersistValue]) Source # | |
PersistEntity a => SqlSelect (SqlExpr (Maybe (Entity a))) (Maybe (Entity a)) Source # | |
Defined in Database.Esqueleto.Internal.Internal sqlSelectCols :: IdentInfo -> SqlExpr (Maybe (Entity a)) -> (Builder, [PersistValue]) Source # sqlSelectColCount :: Proxy (SqlExpr (Maybe (Entity a))) -> Int Source # sqlSelectProcessRow :: [PersistValue] -> Either Text (Maybe (Entity a)) Source # sqlInsertInto :: IdentInfo -> SqlExpr (Maybe (Entity a)) -> (Builder, [PersistValue]) Source # | |
type ToMaybeT (SqlExpr (Value a)) Source # | |
type ToMaybeT (SqlExpr (Entity a)) Source # | |
type ToMaybeT (SqlExpr (Maybe a)) Source # | |
type SqlEntity ent = (PersistEntity ent, PersistEntityBackend ent ~ SqlBackend) Source #
Constraint synonym for persistent
entities whose backend
is SqlBackend
.
select :: (SqlSelect a r, MonadIO m, SqlBackendCanRead backend) => SqlQuery a -> ReaderT backend m [r] Source #
Execute an esqueleto
SELECT
query inside persistent
's
SqlPersistT
monad and return a list of rows.
We've seen that from
has some magic about which kinds of
things you may bring into scope. This select
function also
has some magic for which kinds of things you may bring back to
Haskell-land by using SqlQuery
's return
:
- You may return a
SqlExpr (
for an entityEntity
v)v
(i.e., like the*
in SQL), which is then returned to Haskell-land as justEntity v
. - You may return a
SqlExpr (Maybe (Entity v))
for an entityv
that may beNULL
, which is then returned to Haskell-land asMaybe (Entity v)
. Used forOUTER JOIN
s. - You may return a
SqlExpr (
for a valueValue
t)t
(i.e., a single column), wheret
is any instance ofPersistField
, which is then returned to Haskell-land asValue t
. You may useValue
to return projections of anEntity
(see(
and^.
)(
) or to return any other value calculated on the query (e.g.,?.
)countRows
orsubSelect
).
The SqlSelect a r
class has functional dependencies that
allow type information to flow both from a
to r
and
vice-versa. This means that you'll almost never have to give
any type signatures for esqueleto
queries. For example, the
query
alone is ambiguous, but
in the context ofselect
$ from $ \p -> return p
do ps <-select
$from
$ \p -> return p liftIO $ mapM_ (putStrLn . personName . entityVal) ps
we are able to infer from that single personName . entityVal
function composition that the p
inside the query is of type
SqlExpr (Entity Person)
.
selectOne :: (SqlSelect a r, MonadIO m, SqlBackendCanRead backend) => SqlQuery a -> ReaderT backend m (Maybe r) Source #
Execute an esqueleto
SELECT
query inside persistent
's
SqlPersistT
monad and return the first entry wrapped in a Maybe
.
@since 3.5.1.0
Example usage
firstPerson :: MonadIO m => SqlPersistT m (Maybe (Entity Person)) firstPerson =selectOne
$ do person <-from
$table
@Person return person
The above query is equivalent to a select
combined with limit
but you
would still have to transform the results from a list:
firstPerson :: MonadIO m => SqlPersistT m [Entity Person] firstPerson =select
$ do person <-from
$table
@Personlimit
1 return person
selectSource :: (SqlSelect a r, BackendCompatible SqlBackend backend, IsPersistBackend backend, PersistQueryRead backend, PersistStoreRead backend, PersistUniqueRead backend, MonadResource m) => SqlQuery a -> ConduitT () r (ReaderT backend m) () Source #
Execute an esqueleto
SELECT
query inside persistent
's
SqlPersistT
monad and return a Source
of rows.
delete :: (MonadIO m, SqlBackendCanWrite backend) => SqlQuery () -> ReaderT backend m () Source #
Execute an esqueleto
DELETE
query inside persistent
's
SqlPersistT
monad. Note that currently there are no type
checks for statements that should not appear on a DELETE
query.
Example of usage:
delete
$from
$ \appointment ->where_
(appointment^.
AppointmentDate<.
val
now)
Unlike select
, there is a useful way of using delete
that
will lead to type ambiguities. If you want to delete all rows
(i.e., no where_
clause), you'll have to use a type signature:
delete
$from
$ \(appointment ::SqlExpr
(Entity
Appointment)) -> return ()
Database.Esqueleto.Experimental:
delete $ do
userFeature <- from $ table @UserFeature
where_ ((userFeature ^. UserFeatureFeature) notIn
valList allKnownFeatureFlags)
deleteCount :: (MonadIO m, SqlBackendCanWrite backend) => SqlQuery () -> ReaderT backend m Int64 Source #
Same as delete
, but returns the number of rows affected.
update :: (MonadIO m, PersistEntity val, BackendCompatible SqlBackend (PersistEntityBackend val), SqlBackendCanWrite backend) => (SqlExpr (Entity val) -> SqlQuery ()) -> ReaderT backend m () Source #
Execute an esqueleto
UPDATE
query inside persistent
's
SqlPersistT
monad. Note that currently there are no type
checks for statements that should not appear on a UPDATE
query.
Example of usage:
update
$ \p -> doset
p [ PersonAge=.
just
(val
thisYear) -. p^.
PersonBorn ]where_
$ isNothing (p^.
PersonAge)
updateCount :: (MonadIO m, PersistEntity val, BackendCompatible SqlBackend (PersistEntityBackend val), SqlBackendCanWrite backend) => (SqlExpr (Entity val) -> SqlQuery ()) -> ReaderT backend m Int64 Source #
Same as update
, but returns the number of rows affected.
insertSelect :: (MonadIO m, PersistEntity a, SqlBackendCanWrite backend) => SqlQuery (SqlExpr (Insertion a)) -> ReaderT backend m () Source #
Insert a PersistField
for every selected value.
Since: 2.4.2
insertSelectCount :: (MonadIO m, PersistEntity a, SqlBackendCanWrite backend) => SqlQuery (SqlExpr (Insertion a)) -> ReaderT backend m Int64 Source #
Insert a PersistField
for every selected value, return the count afterward
(<#) :: (a -> b) -> SqlExpr (Value a) -> SqlExpr (Insertion b) Source #
Apply a PersistField
constructor to SqlExpr Value
arguments.
(<&>) :: SqlExpr (Insertion (a -> b)) -> SqlExpr (Value a) -> SqlExpr (Insertion b) Source #
Apply extra SqlExpr Value
arguments to a PersistField
constructor
Rendering Queries
:: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) | |
=> Mode | |
-> SqlQuery a | The SQL query you want to render. |
-> ReaderT backend m (Text, [PersistValue]) |
Renders a SqlQuery
into a Text
value along with the list of
PersistValue
s that would be supplied to the database for ?
placeholders.
You must ensure that the Mode
you pass to this function corresponds with
the actual SqlQuery
. If you pass a query that uses incompatible features
(like an INSERT
statement with a SELECT
mode) then you'll get a weird
result.
Since: 3.1.1
:: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) | |
=> SqlQuery a | The SQL query you want to render. |
-> ReaderT backend m (Text, [PersistValue]) |
Renders a SqlQuery
into a Text
value along with the list of
PersistValue
s that would be supplied to the database for ?
placeholders.
Since: 3.1.1
:: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) | |
=> SqlQuery a | The SQL query you want to render. |
-> ReaderT backend m (Text, [PersistValue]) |
Renders a SqlQuery
into a Text
value along with the list of
PersistValue
s that would be supplied to the database for ?
placeholders.
Since: 3.1.1
:: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) | |
=> SqlQuery a | The SQL query you want to render. |
-> ReaderT backend m (Text, [PersistValue]) |
Renders a SqlQuery
into a Text
value along with the list of
PersistValue
s that would be supplied to the database for ?
placeholders.
Since: 3.1.1
renderQueryInsertInto Source #
:: (SqlSelect a r, BackendCompatible SqlBackend backend, Monad m) | |
=> SqlQuery a | The SQL query you want to render. |
-> ReaderT backend m (Text, [PersistValue]) |
Renders a SqlQuery
into a Text
value along with the list of
PersistValue
s that would be supplied to the database for ?
placeholders.
Since: 3.1.1
Internal.Language
Instances
RDBMS-specific modules
There are many differences between SQL syntax and functions
supported by different RDBMSs. Since version 2.2.8,
esqueleto
includes modules containing functions that are
specific to a given RDBMS.
- PostgreSQL: Database.Esqueleto.PostgreSQL.
In order to use these functions, you need to explicitly import their corresponding modules, they're not re-exported here.
Helpers
valkey :: (ToBackendKey SqlBackend entity, PersistField (Key entity)) => Int64 -> SqlExpr (Value (Key entity)) Source #
valkey i =
(https://github.com/prowdsponsor/esqueleto/issues/9).val
. toSqlKey
valJ :: PersistField (Key entity) => Value (Key entity) -> SqlExpr (Value (Key entity)) Source #
valJ
is like val
but for something that is already a Value
. The use
case it was written for was, given a Value
lift the Key
for that Value
into the query expression in a type safe way. However, the implementation is
more generic than that so we call it valJ
.
Its important to note that the input entity and the output entity are constrained to be the same by the type signature on the function (https://github.com/prowdsponsor/esqueleto/pull/69).
Since: 1.4.2
associateJoin :: forall e1 e0. Ord (Key e0) => [(Entity e0, e1)] -> Map (Key e0) (e0, [e1]) Source #
Avoid N+1 queries and join entities into a map structure.
This function is useful to call on the result of a single JOIN
. For
example, suppose you have this query:
getFoosAndNestedBarsFromParent :: ParentId -> SqlPersistT IO [(Entity Foo, Maybe (Entity Bar))] getFoosAndNestedBarsFromParent parentId =select
$ do (foo :& bar) <- from $ tableFoo
Bar`LeftOuterJoin`
table`on`
do \(foo :& bar) -> foo ^. FooId ==. bar ?. BarFooId where_ $ foo ^. FooParentId ==. val parentId pure (foo, bar)
This is a natural result type for SQL - a list of tuples. However, it's not
what we usually want in Haskell - each Foo
in the list will be represented
multiple times, once for each Bar
.
We can write
and it will translate it into a fmap
associateJoin
Map
that is keyed on the Key
of the left Entity
, and the value is a tuple of
the entity's value as well as the list of each coresponding entity.
getFoosAndNestedBarsFromParentHaskellese :: ParentId -> SqlPersistT (Map (Key Foo) (Foo, [Maybe (Entity Bar)])) getFoosAndNestedBarsFromParentHaskellese parentId =fmap
associateJoin
$ getFoosdAndNestedBarsFromParent parentId
What if you have multiple joins?
Let's use associateJoin
with a *two* join query.
userPostComments :: SqlQuery (SqlExpr (Entity User, Entity Post, Entity Comment)) userPostsComment = do (u :& p :& c) <- from $ tableUser
Post`InnerJoin`
tableon
do \(u :& p) -> u ^. UserId ==. p ^. PostUserId`InnerJoin`
table @Comment`on`
do \(_ :& p :& c) -> p ^. PostId ==. c ^. CommentPostId pure (u, p, c)
This query returns a User, with all of the users Posts, and then all of the Comments on that post.
First, we *nest* the tuple.
nest :: (a, b, c) -> (a, (b, c)) nest (a, b, c) = (a, (b, c))
This makes the return of the query conform to the input expected from
associateJoin
.
nestedUserPostComments :: SqlPersistT IO [(Entity User, (Entity Post, Entity Comment))] nestedUserPostComments = fmap nest $ select userPostsComments
Now, we can call associateJoin
on it.
associateUsers :: [(Entity User, (Entity Post, Entity Comment))] -> Map UserId (User, [(Entity Post, Entity Comment)]) associateUsers = associateJoin
Next, we'll use the Functor
instances for Map
and tuple to call
associateJoin
on the [(Entity Post, Entity Comment)]
.
associatePostsAndComments :: Map UserId (User, [(Entity Post, Entity Comment)]) -> Map UserId (User, Map PostId (Post, [Entity Comment])) associatePostsAndComments = fmap (fmap associateJoin)
For more reading on this topic, see this Foxhound Systems blog post.
Since: 3.1.2
Re-exports
We re-export many symbols from persistent
for convenince:
- "Store functions" from Database.Persist.
- Everything from Database.Persist.Class except for
PersistQuery
anddelete
(usedeleteKey
instead). - Everything from Database.Persist.Types except for
Update
,SelectOpt
,BackendSpecificFilter
andFilter
. - Everything from Database.Persist.Sql except for
deleteWhereCount
andupdateWhereCount
.
deleteKey :: (PersistStore backend, BaseBackend backend ~ PersistEntityBackend val, MonadIO m, PersistEntity val) => Key val -> ReaderT backend m () Source #
transactionUndoWithIsolation :: forall (m :: Type -> Type). MonadIO m => IsolationLevel -> ReaderT SqlBackend m () #
Roll back the current transaction and begin a new one with the specified isolation level.
Since: persistent-2.9.0
transactionUndo :: forall (m :: Type -> Type). MonadIO m => ReaderT SqlBackend m () #
Roll back the current transaction and begin a new one.
This rolls back to the state of the last call to transactionSave
or the enclosing
runSqlConn
call.
Since: persistent-1.2.0
transactionSaveWithIsolation :: forall (m :: Type -> Type). MonadIO m => IsolationLevel -> ReaderT SqlBackend m () #
Commit the current transaction and begin a new one with the specified isolation level.
Since: persistent-2.9.0
transactionSave :: forall (m :: Type -> Type). MonadIO m => ReaderT SqlBackend m () #
Commit the current transaction and begin a new one.
This is used when a transaction commit is required within the context of runSqlConn
(which brackets its provided action with a transaction begin/commit pair).
Since: persistent-1.2.0
runSqlCommand :: SqlPersistT IO () -> Migration #
Run an action against the database during a migration. Can be useful for eg creating Postgres extensions:
runSqlCommand $ rawExecute
"CREATE EXTENSION IF NOT EXISTS "uuid-ossp";" []
Since: persistent-2.13.0.0
addMigrations :: CautiousMigration -> Migration #
Add a CautiousMigration
(aka a [(
) to the
migration plan.Bool
, Text
)]
Since: persistent-2.9.2
:: Bool | Is the migration unsafe to run? (eg a destructive or non-idempotent
update on the schema). If |
-> Sql | A |
-> Migration |
Add a migration to the migration plan.
Since: persistent-2.9.2
reportErrors :: [Text] -> Migration #
Report multiple errors in a Migration
.
Since: persistent-2.9.2
reportError :: Text -> Migration #
Report a single error in a Migration
.
Since: persistent-2.9.2
runMigrationUnsafeQuiet :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m [Text] #
Same as runMigrationUnsafe
, but returns a list of the SQL commands
executed instead of printing them to stderr.
Since: persistent-2.10.2
runMigrationUnsafe :: forall (m :: Type -> Type). MonadIO m => Migration -> ReaderT SqlBackend m () #
Like runMigration
, but this will perform the unsafe database
migrations instead of erroring out.
runMigrationSilent :: forall (m :: Type -> Type). MonadUnliftIO m => Migration -> ReaderT SqlBackend m [Text] #
Same as runMigration
, but returns a list of the SQL commands executed
instead of printing them to stderr.
This function silences the migration by remapping stderr
. As a result, it
is not thread-safe and can clobber output from other parts of the program.
This implementation method was chosen to also silence postgresql migration
output on stderr, but is not recommended!
runMigrationQuiet :: forall (m :: Type -> Type). MonadIO m => Migration -> ReaderT SqlBackend m [Text] #
Same as runMigration
, but does not report the individual migrations on
stderr. Instead it returns a list of the executed SQL commands.
This is a safer/more robust alternative to runMigrationSilent
, but may be
less silent for some persistent implementations, most notably
persistent-postgresql
Since: persistent-2.10.2
runMigration :: forall (m :: Type -> Type). MonadIO m => Migration -> ReaderT SqlBackend m () #
Runs a migration. If the migration fails to parse or if any of the
migrations are unsafe, then this throws a PersistUnsafeMigrationException
.
getMigration :: forall (m :: Type -> Type). (MonadIO m, HasCallStack) => Migration -> ReaderT SqlBackend m [Sql] #
showMigration :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m [Text] #
printMigration :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m () #
Prints a migration.
parseMigration' :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m CautiousMigration #
Like parseMigration
, but instead of returning the value in an
Either
value, it calls error
on the error values.
parseMigration :: forall (m :: Type -> Type). (HasCallStack, MonadIO m) => Migration -> ReaderT SqlBackend m (Either [Text] CautiousMigration) #
Given a Migration
, this parses it and returns either a list of
errors associated with the migration or a list of migrations to do.
type CautiousMigration = [(Bool, Sql)] #
type Migration = WriterT [Text] (WriterT CautiousMigration (ReaderT SqlBackend IO)) () #
A Migration
is a four level monad stack consisting of:
representing a log of errors in the migrations.WriterT
[Text
]
representing a list of migrations to run, along with whether or not they are safe.WriterT
CautiousMigration
, aka theReaderT
SqlBackend
SqlPersistT
transformer for database interop.
for arbitrary IO.IO
newtype PersistUnsafeMigrationException #
An exception indicating that Persistent refused to run some unsafe migrations. Contains a list of pairs where the Bool tracks whether the migration was unsafe (True means unsafe), and the Sql is the sql statement for the migration.
Since: persistent-2.11.1.0
Instances
Exception PersistUnsafeMigrationException | |
Show PersistUnsafeMigrationException | This |
Defined in Database.Persist.Sql.Migration |
decorateSQLWithLimitOffset :: Text -> (Int, Int) -> Text -> Text #
Generates sql for limit and offset for postgres, sqlite and mysql.
:: PersistEntity val | |
=> Maybe FilterTablePrefix | include table name or EXCLUDED |
-> SqlBackend | |
-> [SelectOpt val] | |
-> Text |
:: PersistEntity val | |
=> Maybe FilterTablePrefix | include table name or EXCLUDED |
-> SqlBackend | |
-> [Filter val] | |
-> (Text, [PersistValue]) |
Render a [
into a Filter
record]Text
value suitable for inclusion
into a SQL query, as well as the [
to properly fill in the
PersistValue
]?
place holders.
Since: persistent-2.12.1.0
:: PersistEntity val | |
=> Maybe FilterTablePrefix | include table name or EXCLUDED |
-> SqlBackend | |
-> [Filter val] | |
-> Text |
data FilterTablePrefix #
Used when determining how to prefix a column name in a WHERE
clause.
Since: persistent-2.12.1.0
PrefixTableName | Prefix the column with the table name. This is useful if the column name might be ambiguous. Since: persistent-2.12.1.0 |
PrefixExcluded | Prefix the column name with the Since: persistent-2.12.1.0 |
fieldDBName :: PersistEntity record => EntityField record typ -> FieldNameDB #
useful for a backend to implement fieldName by adding escaping
getFieldName :: forall record typ (m :: Type -> Type) backend. (PersistEntity record, PersistEntityBackend record ~ SqlBackend, BackendCompatible SqlBackend backend, Monad m) => EntityField record typ -> ReaderT backend m Text #
get the SQL string for the field that an EntityField represents Useful for raw SQL queries
Your backend may provide a more convenient fieldName function which does not operate in a Monad
tableDBName :: PersistEntity record => record -> EntityNameDB #
useful for a backend to implement tableName by adding escaping
getTableName :: forall record (m :: Type -> Type) backend. (PersistEntity record, BackendCompatible SqlBackend backend, Monad m) => record -> ReaderT backend m Text #
get the SQL string for the table that a PeristEntity represents Useful for raw SQL queries
Your backend may provide a more convenient tableName function which does not operate in a Monad
fromSqlKey :: ToBackendKey SqlBackend record => Key record -> Int64 #
toSqlKey :: ToBackendKey SqlBackend record => Int64 -> Key record #
withRawQuery :: forall (m :: Type -> Type) a. MonadIO m => Text -> [PersistValue] -> ConduitM [PersistValue] Void IO a -> ReaderT SqlBackend m a #
close' :: BackendCompatible SqlBackend backend => backend -> IO () #
withSqlConn :: forall backend m a. (MonadUnliftIO m, MonadLoggerIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> (backend -> m a) -> m a #
Create a connection and run sql queries within it. This function automatically closes the connection on it's completion.
Example usage
{-# LANGUAGE GADTs #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE TypeFamilies#-} {-# LANGUAGE TemplateHaskell#-} {-# LANGUAGE QuasiQuotes#-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} import Control.Monad.IO.Class (liftIO) import Control.Monad.Logger import Conduit import Database.Persist import Database.Sqlite import Database.Persist.Sqlite import Database.Persist.TH share [mkPersist sqlSettings, mkMigrate "migrateAll"] [persistLowerCase| Person name String age Int Maybe deriving Show |] openConnection :: LogFunc -> IO SqlBackend openConnection logfn = do conn <- open "/home/sibi/test.db" wrapConnection conn logfn main :: IO () main = do runNoLoggingT $ runResourceT $ withSqlConn openConnection (\backend -> flip runSqlConn backend $ do runMigration migrateAll insert_ $ Person "John doe" $ Just 35 insert_ $ Person "Divya" $ Just 36 (pers :: [Entity Person]) <- selectList [] [] liftIO $ print pers return () )
On executing it, you get this output:
Migrating: CREATE TABLE "person"("id" INTEGER PRIMARY KEY,"name" VARCHAR NOT NULL,"age" INTEGER NULL) [Entity {entityKey = PersonKey {unPersonKey = SqlBackendKey {unSqlBackendKey = 1}}, entityVal = Person {personName = "John doe", personAge = Just 35}},Entity {entityKey = PersonKey {unPersonKey = SqlBackendKey {unSqlBackendKey = 2}}, entityVal = Person {personName = "Hema", personAge = Just 36}}]
:: (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) | |
=> (LogFunc -> IO backend) | Function to create a new connection |
-> ConnectionPoolConfig | |
-> m (Pool backend) |
Creates a pool of connections to a SQL database.
Since: persistent-2.11.0.0
createSqlPool :: forall backend m. (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) => (LogFunc -> IO backend) -> Int -> m (Pool backend) #
:: forall backend m a. (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) | |
=> (LogFunc -> IO backend) | Function to create a new connection |
-> ConnectionPoolConfig | |
-> (Pool backend -> m a) | |
-> m a |
Creates a pool of connections to a SQL database which can be used by the Pool backend -> m a
function.
After the function completes, the connections are destroyed.
Since: persistent-2.11.0.0
:: forall backend m a. (MonadLoggerIO m, MonadUnliftIO m, BackendCompatible SqlBackend backend) | |
=> (LogFunc -> IO backend) | create a new connection |
-> Int | connection count |
-> (Pool backend -> m a) | |
-> m a |
liftSqlPersistMPool :: forall backend m a. (MonadIO m, BackendCompatible SqlBackend backend) => ReaderT backend (NoLoggingT (ResourceT IO)) a -> Pool backend -> m a #
runSqlPersistMPool :: BackendCompatible SqlBackend backend => ReaderT backend (NoLoggingT (ResourceT IO)) a -> Pool backend -> IO a #
runSqlPersistM :: BackendCompatible SqlBackend backend => ReaderT backend (NoLoggingT (ResourceT IO)) a -> backend -> IO a #
runSqlConnWithIsolation :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> backend -> IsolationLevel -> m a #
Like runSqlConn
, but supports specifying an isolation level.
Since: persistent-2.9.0
runSqlConn :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> backend -> m a #
acquireSqlConnWithIsolation :: (MonadReader backend m, BackendCompatible SqlBackend backend) => IsolationLevel -> m (Acquire backend) #
Like acquireSqlConn
, but lets you specify an explicit isolation level.
Since: persistent-2.10.5
acquireSqlConn :: (MonadReader backend m, BackendCompatible SqlBackend backend) => m (Acquire backend) #
Starts a new transaction on the connection. When the acquired connection is released the transaction is committed and the connection returned to the pool.
Upon an exception the transaction is rolled back and the connection destroyed.
This is equivalent to runSqlConn
but does not incur the MonadUnliftIO
constraint, meaning it can be used within, for example, a Conduit
pipeline.
Since: persistent-2.10.5
runSqlPoolWithExtensibleHooks :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> Maybe IsolationLevel -> SqlPoolHooks m backend -> m a #
This function is how runSqlPoolWithHooks
is defined.
It's currently the most general function for using a SQL pool.
Since: persistent-2.13.0.0
:: forall backend m a before after onException. (MonadUnliftIO m, BackendCompatible SqlBackend backend) | |
=> ReaderT backend m a | |
-> Pool backend | |
-> Maybe IsolationLevel | |
-> (backend -> m before) | Run this action immediately before the action is performed. |
-> (backend -> m after) | Run this action immediately after the action is completed. |
-> (backend -> SomeException -> m onException) | This action is performed when an exception is received. The exception is provided as a convenience - it is rethrown once this cleanup function is complete. |
-> m a |
This function is how runSqlPool
and runSqlPoolNoTransaction
are
defined. In addition to the action to be performed and the Pool
of
conections to use, we give you the opportunity to provide three actions
- initialize, afterwards, and onException.
Since: persistent-2.12.0.0
runSqlPoolNoTransaction :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> Maybe IsolationLevel -> m a #
Like runSqlPool
, but does not surround the action in a transaction.
This action might leave your database in a weird state.
Since: persistent-2.12.0.0
runSqlPoolWithIsolation :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> IsolationLevel -> m a #
Like runSqlPool
, but supports specifying an isolation level.
Since: persistent-2.9.0
runSqlPool :: forall backend m a. (MonadUnliftIO m, BackendCompatible SqlBackend backend) => ReaderT backend m a -> Pool backend -> m a #
Get a connection from the pool, run the given action, and then return the connection to the pool.
This function performs the given action in a transaction. If an exception occurs during the action, then the transaction is rolled back.
Note: This function previously timed out after 2 seconds, but this behavior was buggy and caused more problems than it solved. Since version 2.1.2, it performs no timeout checks.
:: forall a (m :: Type -> Type) backend. (RawSql a, MonadIO m, BackendCompatible SqlBackend backend) | |
=> Text | SQL statement, possibly with placeholders. |
-> [PersistValue] | Values to fill the placeholders. |
-> ReaderT backend m [a] |
Execute a raw SQL statement and return its results as a
list. If you do not expect a return value, use of
rawExecute
is recommended.
If you're using Entity
s
(which is quite likely), then you
must use entity selection placeholders (double question
mark, ??
). These ??
placeholders are then replaced for
the names of the columns that we need for your entities.
You'll receive an error if you don't use the placeholders.
Please see the Entity
s
documentation for more details.
You may put value placeholders (question marks, ?
) in your
SQL query. These placeholders are then replaced by the values
you pass on the second parameter, already correctly escaped.
You may want to use toPersistValue
to help you constructing
the placeholder values.
Since you're giving a raw SQL statement, you don't get any
guarantees regarding safety. If rawSql
is not able to parse
the results of your query back, then an exception is raised.
However, most common problems are mitigated by using the
entity selection placeholder ??
, and you shouldn't see any
error at all if you're not using Single
.
Some example of rawSql
based on this schema:
share [mkPersist sqlSettings, mkMigrate "migrateAll"] [persistLowerCase| Person name String age Int Maybe deriving Show BlogPost title String authorId PersonId deriving Show |]
Examples based on the above schema:
getPerson :: MonadIO m => ReaderT SqlBackend m [Entity Person] getPerson = rawSql "select ?? from person where name=?" [PersistText "john"] getAge :: MonadIO m => ReaderT SqlBackend m [Single Int] getAge = rawSql "select person.age from person where name=?" [PersistText "john"] getAgeName :: MonadIO m => ReaderT SqlBackend m [(Single Int, Single Text)] getAgeName = rawSql "select person.age, person.name from person where name=?" [PersistText "john"] getPersonBlog :: MonadIO m => ReaderT SqlBackend m [(Entity Person, Entity BlogPost)] getPersonBlog = rawSql "select ??,?? from person,blog_post where person.id = blog_post.author_id" []
Minimal working program for PostgreSQL backend based on the above concepts:
{-# LANGUAGE EmptyDataDecls #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE QuasiQuotes #-} {-# LANGUAGE TemplateHaskell #-} {-# LANGUAGE TypeFamilies #-} import Control.Monad.IO.Class (liftIO) import Control.Monad.Logger (runStderrLoggingT) import Database.Persist import Control.Monad.Reader import Data.Text import Database.Persist.Sql import Database.Persist.Postgresql import Database.Persist.TH share [mkPersist sqlSettings, mkMigrate "migrateAll"] [persistLowerCase| Person name String age Int Maybe deriving Show |] conn = "host=localhost dbname=new_db user=postgres password=postgres port=5432" getPerson :: MonadIO m => ReaderT SqlBackend m [Entity Person] getPerson = rawSql "select ?? from person where name=?" [PersistText "sibi"] liftSqlPersistMPool y x = liftIO (runSqlPersistMPool y x) main :: IO () main = runStderrLoggingT $ withPostgresqlPool conn 10 $ liftSqlPersistMPool $ do runMigration migrateAll xs <- getPerson liftIO (print xs)
getStmtConn :: SqlBackend -> Text -> IO Statement #
:: forall (m :: Type -> Type) backend. (MonadIO m, BackendCompatible SqlBackend backend) | |
=> Text | SQL statement, possibly with placeholders. |
-> [PersistValue] | Values to fill the placeholders. |
-> ReaderT backend m Int64 |
Execute a raw SQL statement and return the number of rows it has modified.
:: forall (m :: Type -> Type) backend. (MonadIO m, BackendCompatible SqlBackend backend) | |
=> Text | SQL statement, possibly with placeholders. |
-> [PersistValue] | Values to fill the placeholders. |
-> ReaderT backend m () |
Execute a raw SQL statement
rawQueryRes :: forall (m1 :: Type -> Type) (m2 :: Type -> Type) env. (MonadIO m1, MonadIO m2, BackendCompatible SqlBackend env) => Text -> [PersistValue] -> ReaderT env m1 (Acquire (ConduitM () [PersistValue] m2 ())) #
rawQuery :: forall (m :: Type -> Type) env. (MonadResource m, MonadReader env m, BackendCompatible SqlBackend env) => Text -> [PersistValue] -> ConduitM () [PersistValue] m () #
unPrefix :: forall (prefix :: Symbol) record. EntityWithPrefix prefix record -> Entity record #
A helper function to tell GHC what the EntityWithPrefix
prefix
should be. This allows you to use a type application to specify the
prefix, instead of specifying the etype on the result.
As an example, here's code that uses this:
myQuery ::SqlPersistM
[Entity
Person] myQuery = fmap (unPrefix @"p") $ rawSql query [] where query = "SELECT ?? FROM person AS p"
Since: persistent-2.10.5
Class for data types that may be retrived from a rawSql
query.
rawSqlCols :: (Text -> Text) -> a -> (Int, [Text]) #
Number of columns that this data type needs and the list
of substitutions for SELECT
placeholders ??
.
rawSqlColCountReason :: a -> String #
A string telling the user why the column count is what it is.
rawSqlProcessRow :: [PersistValue] -> Either Text a #
Transform a row of the result into the data type.
Instances
(PersistEntity record, PersistEntityBackend record ~ backend, IsPersistBackend backend) => RawSql (Entity record) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> Entity record -> (Int, [Text]) # rawSqlColCountReason :: Entity record -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (Entity record) # | |
(PersistEntity a, PersistEntityBackend a ~ backend, IsPersistBackend backend) => RawSql (Key a) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> Key a -> (Int, [Text]) # rawSqlColCountReason :: Key a -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (Key a) # | |
PersistField a => RawSql (Single a) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> Single a -> (Int, [Text]) # rawSqlColCountReason :: Single a -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (Single a) # | |
RawSql a => RawSql (Maybe a) | Since: persistent-1.0.1 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> Maybe a -> (Int, [Text]) # rawSqlColCountReason :: Maybe a -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (Maybe a) # | |
(PersistEntity record, KnownSymbol prefix, PersistEntityBackend record ~ backend, IsPersistBackend backend) => RawSql (EntityWithPrefix prefix record) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> EntityWithPrefix prefix record -> (Int, [Text]) # rawSqlColCountReason :: EntityWithPrefix prefix record -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (EntityWithPrefix prefix record) # | |
(RawSql a, RawSql b) => RawSql (a, b) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b) -> (Int, [Text]) # rawSqlColCountReason :: (a, b) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b) # | |
(RawSql a, RawSql b, RawSql c) => RawSql (a, b, c) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c) # | |
(RawSql a, RawSql b, RawSql c, RawSql d) => RawSql (a, b, c, d) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e) => RawSql (a, b, c, d, e) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f) => RawSql (a, b, c, d, e, f) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g) => RawSql (a, b, c, d, e, f, g) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h) => RawSql (a, b, c, d, e, f, g, h) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i) => RawSql (a, b, c, d, e, f, g, h, i) | Since: persistent-2.10.2 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j) => RawSql (a, b, c, d, e, f, g, h, i, j) | Since: persistent-2.10.2 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k) => RawSql (a, b, c, d, e, f, g, h, i, j, k) | Since: persistent-2.10.2 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l) | Since: persistent-2.10.2 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3, RawSql e3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3, RawSql e3, RawSql f3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3, RawSql e3, RawSql f3, RawSql g3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3, RawSql e3, RawSql f3, RawSql g3, RawSql h3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3, RawSql e3, RawSql f3, RawSql g3, RawSql h3, RawSql i3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3) # | |
(RawSql a, RawSql b, RawSql c, RawSql d, RawSql e, RawSql f, RawSql g, RawSql h, RawSql i, RawSql j, RawSql k, RawSql l, RawSql m, RawSql n, RawSql o, RawSql p, RawSql q, RawSql r, RawSql s, RawSql t, RawSql u, RawSql v, RawSql w, RawSql x, RawSql y, RawSql z, RawSql a2, RawSql b2, RawSql c2, RawSql d2, RawSql e2, RawSql f2, RawSql g2, RawSql h2, RawSql i2, RawSql j2, RawSql k2, RawSql l2, RawSql m2, RawSql n2, RawSql o2, RawSql p2, RawSql q2, RawSql r2, RawSql s2, RawSql t2, RawSql u2, RawSql v2, RawSql w2, RawSql x2, RawSql y2, RawSql z2, RawSql a3, RawSql b3, RawSql c3, RawSql d3, RawSql e3, RawSql f3, RawSql g3, RawSql h3, RawSql i3, RawSql j3) => RawSql (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3, j3) | Since: persistent-2.11.0 |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3, j3) -> (Int, [Text]) # rawSqlColCountReason :: (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3, j3) -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, a2, b2, c2, d2, e2, f2, g2, h2, i2, j2, k2, l2, m2, n2, o2, p2, q2, r2, s2, t2, u2, v2, w2, x2, y2, z2, a3, b3, c3, d3, e3, f3, g3, h3, i3, j3) # |
newtype EntityWithPrefix (prefix :: Symbol) record #
This newtype wrapper is useful when selecting an entity out of the database and you want to provide a prefix to the table being selected.
Consider this raw SQL query:
SELECT ?? FROM my_long_table_name AS mltn INNER JOIN other_table AS ot ON mltn.some_col = ot.other_col WHERE ...
We don't want to refer to my_long_table_name
every time, so we create
an alias. If we want to select it, we have to tell the raw SQL
quasi-quoter that we expect the entity to be prefixed with some other
name.
We can give the above query a type with this, like:
getStuff ::SqlPersistM
[EntityWithPrefix
"mltn" MyLongTableName] getStuff = rawSql queryText []
The EntityWithPrefix
bit is a boilerplate newtype wrapper, so you can
remove it with unPrefix
, like this:
getStuff ::SqlPersistM
[Entity
MyLongTableName] getStuff =unPrefix
@"mltn"<$>
rawSql
queryText []
The symbol is a "type application" and requires the
TypeApplications@
language extension.
Since: persistent-2.10.5
EntityWithPrefix | |
|
Instances
(PersistEntity record, KnownSymbol prefix, PersistEntityBackend record ~ backend, IsPersistBackend backend) => RawSql (EntityWithPrefix prefix record) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> EntityWithPrefix prefix record -> (Int, [Text]) # rawSqlColCountReason :: EntityWithPrefix prefix record -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (EntityWithPrefix prefix record) # |
class PersistField a => PersistFieldSql a where #
Tells Persistent what database column type should be used to store a Haskell type.
Examples
Simple Boolean Alternative
data Switch = On | Off deriving (Show, Eq) instancePersistField
Switch wheretoPersistValue
s = case s of On ->PersistBool
True Off ->PersistBool
FalsefromPersistValue
(PersistBool
b) = if b thenRight
On elseRight
OfffromPersistValue
x = Left $ "File.hs: When trying to deserialize a Switch: expected PersistBool, received: " <> T.pack (show x) instancePersistFieldSql
Switch wheresqlType
_ =SqlBool
Non-Standard Database Types
If your database supports non-standard types, such as Postgres' uuid
, you can use SqlOther
to use them:
import qualified Data.UUID as UUID instancePersistField
UUID wheretoPersistValue
=PersistLiteralEncoded
. toASCIIBytesfromPersistValue
(PersistLiteralEncoded
uuid) = case fromASCIIBytes uuid ofNothing
->Left
$ "Model/CustomTypes.hs: Failed to deserialize a UUID; received: " <> T.pack (show uuid)Just
uuid' ->Right
uuid'fromPersistValue
x = Left $ "File.hs: When trying to deserialize a UUID: expected PersistLiteralEncoded, received: "-- > <> T.pack (show x) instancePersistFieldSql
UUID wheresqlType
_ =SqlOther
"uuid"
User Created Database Types
Similarly, some databases support creating custom types, e.g. Postgres' DOMAIN and ENUM features. You can use SqlOther
to specify a custom type:
CREATE DOMAIN ssn AS text CHECK ( value ~ '^[0-9]{9}$');
instancePersistFieldSQL
SSN wheresqlType
_ =SqlOther
"ssn"
CREATE TYPE rainbow_color AS ENUM ('red', 'orange', 'yellow', 'green', 'blue', 'indigo', 'violet');
instancePersistFieldSQL
RainbowColor wheresqlType
_ =SqlOther
"rainbow_color"
Instances
toJsonText :: ToJSON j => j -> Text #
mkColumns :: [EntityDef] -> EntityDef -> BackendSpecificOverrides -> ([Column], [UniqueDef], [ForeignDef]) #
Create the list of columns for the given entity.
defaultAttribute :: [FieldAttr] -> Maybe Text #
emptyBackendSpecificOverrides :: BackendSpecificOverrides #
Creates an empty BackendSpecificOverrides
(i.e. use the default behavior; no overrides)
Since: persistent-2.11
setBackendSpecificForeignKeyName :: (EntityNameDB -> FieldNameDB -> ConstraintNameDB) -> BackendSpecificOverrides -> BackendSpecificOverrides #
Set the backend's foreign key generation function to this value.
Since: persistent-2.13.0.0
getBackendSpecificForeignKeyName :: BackendSpecificOverrides -> Maybe (EntityNameDB -> FieldNameDB -> ConstraintNameDB) #
If the override is defined, then this returns a function that accepts an
entity name and field name and provides the ConstraintNameDB
for the
foreign key constraint.
An abstract accessor for the BackendSpecificOverrides
Since: persistent-2.13.0.0
data BackendSpecificOverrides #
Record of functions to override the default behavior in mkColumns
. It is
recommended you initialize this with emptyBackendSpecificOverrides
and
override the default values, so that as new fields are added, your code still
compiles.
For added safety, use the getBackendSpecific*
and setBackendSpecific*
functions, as a breaking change to the record field labels won't be reflected
in a major version bump of the library.
Since: persistent-2.11
defaultConnectionPoolConfig :: ConnectionPoolConfig #
Initializes a ConnectionPoolConfig with default values. See the documentation of ConnectionPoolConfig
for each field's default value.
Since: persistent-2.11.0.0
Column | |
|
data ColumnReference #
This value specifies how a field references another table.
Since: persistent-2.11.0.0
ColumnReference | |
|
Instances
Show ColumnReference | |
Defined in Database.Persist.Sql.Types showsPrec :: Int -> ColumnReference -> ShowS # show :: ColumnReference -> String # showList :: [ColumnReference] -> ShowS # | |
Eq ColumnReference | |
Defined in Database.Persist.Sql.Types (==) :: ColumnReference -> ColumnReference -> Bool # (/=) :: ColumnReference -> ColumnReference -> Bool # | |
Ord ColumnReference | |
Defined in Database.Persist.Sql.Types compare :: ColumnReference -> ColumnReference -> Ordering # (<) :: ColumnReference -> ColumnReference -> Bool # (<=) :: ColumnReference -> ColumnReference -> Bool # (>) :: ColumnReference -> ColumnReference -> Bool # (>=) :: ColumnReference -> ColumnReference -> Bool # max :: ColumnReference -> ColumnReference -> ColumnReference # min :: ColumnReference -> ColumnReference -> ColumnReference # |
data PersistentSqlException #
Instances
Exception PersistentSqlException | |
Show PersistentSqlException | |
Defined in Database.Persist.Sql.Types showsPrec :: Int -> PersistentSqlException -> ShowS # show :: PersistentSqlException -> String # showList :: [PersistentSqlException] -> ShowS # |
type SqlPersistT = ReaderT SqlBackend #
type SqlPersistM = SqlPersistT (NoLoggingT (ResourceT IO)) #
type ConnectionPool = Pool SqlBackend #
data ConnectionPoolConfig #
Values to configure a pool of database connections. See Data.Pool for details.
Since: persistent-2.11.0.0
ConnectionPoolConfig | |
|
Instances
Show ConnectionPoolConfig | |
Defined in Database.Persist.Sql.Types showsPrec :: Int -> ConnectionPoolConfig -> ShowS # show :: ConnectionPoolConfig -> String # showList :: [ConnectionPoolConfig] -> ShowS # |
A single column (see rawSql
). Any PersistField
may be
used here, including PersistValue
(which does not do any
processing).
Instances
Read a => Read (Single a) | |
Show a => Show (Single a) | |
Eq a => Eq (Single a) | |
Ord a => Ord (Single a) | |
Defined in Database.Persist.Sql.Types | |
PersistField a => RawSql (Single a) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> Single a -> (Int, [Text]) # rawSqlColCountReason :: Single a -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (Single a) # |
readToUnknown :: forall (m :: Type -> Type) a. Monad m => ReaderT SqlReadBackend m a -> ReaderT SqlBackend m a #
Useful for running a read query against a backend with unknown capabilities.
readToWrite :: forall (m :: Type -> Type) a. Monad m => ReaderT SqlReadBackend m a -> ReaderT SqlWriteBackend m a #
Useful for running a read query against a backend with read and write capabilities.
writeToUnknown :: forall (m :: Type -> Type) a. Monad m => ReaderT SqlWriteBackend m a -> ReaderT SqlBackend m a #
Useful for running a write query against an untagged backend with unknown capabilities.
newtype SqlReadBackend #
An SQL backend which can only handle read queries
The constructor was exposed in 2.10.0.
Instances
HasPersistBackend SqlReadBackend | |
Defined in Database.Persist.Sql.Types.Internal type BaseBackend SqlReadBackend # | |
IsPersistBackend SqlReadBackend | |
newtype BackendKey SqlReadBackend | |
Defined in Database.Persist.Sql.Orphan.PersistStore | |
type BaseBackend SqlReadBackend | |
Defined in Database.Persist.Sql.Types.Internal | |
type Rep (BackendKey SqlReadBackend) | |
Defined in Database.Persist.Sql.Orphan.PersistStore type Rep (BackendKey SqlReadBackend) = D1 ('MetaData "BackendKey" "Database.Persist.Sql.Orphan.PersistStore" "persistent-2.14.5.1-1klc2SaLXJ07EHFQFFZySK" 'True) (C1 ('MetaCons "SqlReadBackendKey" 'PrefixI 'True) (S1 ('MetaSel ('Just "unSqlReadBackendKey") 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 Int64))) |
newtype SqlWriteBackend #
An SQL backend which can handle read or write queries
The constructor was exposed in 2.10.0
Instances
HasPersistBackend SqlWriteBackend | |
Defined in Database.Persist.Sql.Types.Internal type BaseBackend SqlWriteBackend # | |
IsPersistBackend SqlWriteBackend | |
newtype BackendKey SqlWriteBackend | |
Defined in Database.Persist.Sql.Orphan.PersistStore | |
type BaseBackend SqlWriteBackend | |
Defined in Database.Persist.Sql.Types.Internal | |
type Rep (BackendKey SqlWriteBackend) | |
Defined in Database.Persist.Sql.Orphan.PersistStore type Rep (BackendKey SqlWriteBackend) = D1 ('MetaData "BackendKey" "Database.Persist.Sql.Orphan.PersistStore" "persistent-2.14.5.1-1klc2SaLXJ07EHFQFFZySK" 'True) (C1 ('MetaCons "SqlWriteBackendKey" 'PrefixI 'True) (S1 ('MetaSel ('Just "unSqlWriteBackendKey") 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 Int64))) |
type SqlBackendCanRead backend = (BackendCompatible SqlBackend backend, PersistQueryRead backend, PersistStoreRead backend, PersistUniqueRead backend) #
A constraint synonym which witnesses that a backend is SQL and can run read queries.
type SqlBackendCanWrite backend = (SqlBackendCanRead backend, PersistQueryWrite backend, PersistStoreWrite backend, PersistUniqueWrite backend) #
A constraint synonym which witnesses that a backend is SQL and can run read and write queries.
type SqlReadT (m :: Type -> Type) a = forall backend. SqlBackendCanRead backend => ReaderT backend m a #
Like SqlPersistT
but compatible with any SQL backend which can handle read queries.
type SqlWriteT (m :: Type -> Type) a = forall backend. SqlBackendCanWrite backend => ReaderT backend m a #
Like SqlPersistT
but compatible with any SQL backend which can handle read and write queries.
type IsSqlBackend backend = (IsPersistBackend backend, BaseBackend backend ~ SqlBackend) #
A backend which is a wrapper around SqlBackend
.
type PersistUnique a = PersistUniqueWrite a #
A backwards-compatible alias for those that don't care about distinguishing between read and write queries. It signifies the assumption that, by default, a backend can write as well as read.
type PersistStore a = PersistStoreWrite a #
A backwards-compatible alias for those that don't care about distinguishing between read and write queries. It signifies the assumption that, by default, a backend can write as well as read.
selectKeys :: forall record backend (m :: Type -> Type). (PersistQueryRead backend, MonadResource m, PersistRecordBackend record backend, MonadReader backend m) => [Filter record] -> [SelectOpt record] -> ConduitM () (Key record) m () #
Get the Key
s of all records matching the given criterion.
For an example, see selectList
.
class (PersistCore backend, PersistStoreRead backend) => PersistQueryRead backend where #
Backends supporting conditional read operations.
selectSourceRes :: forall record (m1 :: Type -> Type) (m2 :: Type -> Type). (PersistRecordBackend record backend, MonadIO m1, MonadIO m2) => [Filter record] -> [SelectOpt record] -> ReaderT backend m1 (Acquire (ConduitM () (Entity record) m2 ())) #
Get all records matching the given criterion in the specified order. Returns also the identifiers.
NOTE: This function returns an Acquire
and a ConduitM
, which implies
that it streams from the database. It does not. Please use selectList
to simplify the code. If you want streaming behavior, consider
persistent-pagination
which efficiently chunks a query into ranges, or
investigate a backend-specific streaming solution.
selectFirst :: forall (m :: Type -> Type) record. (MonadIO m, PersistRecordBackend record backend) => [Filter record] -> [SelectOpt record] -> ReaderT backend m (Maybe (Entity record)) #
Get just the first record for the criterion.
selectKeysRes :: forall (m1 :: Type -> Type) (m2 :: Type -> Type) record. (MonadIO m1, MonadIO m2, PersistRecordBackend record backend) => [Filter record] -> [SelectOpt record] -> ReaderT backend m1 (Acquire (ConduitM () (Key record) m2 ())) #
Get the Key
s of all records matching the given criterion.
class (PersistQueryRead backend, PersistStoreWrite backend) => PersistQueryWrite backend where #
Backends supporting conditional write operations
updateWhere :: forall (m :: Type -> Type) record. (MonadIO m, PersistRecordBackend record backend) => [Filter record] -> [Update record] -> ReaderT backend m () #
Update individual fields on any record matching the given criterion.
deleteWhere :: forall (m :: Type -> Type) record. (MonadIO m, PersistRecordBackend record backend) => [Filter record] -> ReaderT backend m () #
Delete all records matching the given criterion.
checkUniqueUpdateable :: forall record backend (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, PersistUniqueRead backend) => Entity record -> ReaderT backend m (Maybe (Unique record)) #
Check whether there are any conflicts for unique keys with this entity and existing entities in the database.
Returns Nothing
if the entity would stay unique, and could thus safely be updated.
on a conflict returns the conflicting key
This is similar to checkUnique
, except it's useful for updating - when the
particular entity already exists, it would normally conflict with itself.
This variant ignores those conflicts
Example usage
We use schema-1 and dataset-1 here.
This would be Nothing
:
mAlanConst <- checkUnique $ User "Alan" 70
While this would be Just
because SPJ already exists:
mSpjConst <- checkUnique $ User "SPJ" 60
Since: persistent-2.11.0.0
checkUnique :: forall record backend (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, PersistUniqueRead backend) => record -> ReaderT backend m (Maybe (Unique record)) #
Check whether there are any conflicts for unique keys with this entity and existing entities in the database.
Returns Nothing
if the entity would be unique, and could thus safely be inserted.
on a conflict returns the conflicting key
Example usage
replaceUnique :: forall record backend (m :: Type -> Type). (MonadIO m, Eq (Unique record), PersistRecordBackend record backend, PersistUniqueWrite backend) => Key record -> record -> ReaderT backend m (Maybe (Unique record)) #
Attempt to replace the record of the given key with the given new record. First query the unique fields to make sure the replacement maintains uniqueness constraints.
Return Nothing
if the replacement was made.
If uniqueness is violated, return a Just
with the Unique
violation
Since: persistent-1.2.2.0
getByValue :: forall record (m :: Type -> Type) backend. (MonadIO m, PersistUniqueRead backend, PersistRecordBackend record backend, AtLeastOneUniqueKey record) => record -> ReaderT backend m (Maybe (Entity record)) #
A modification of getBy
, which takes the PersistEntity
itself instead
of a Unique
record. Returns a record matching one of the unique keys. This
function makes the most sense on entities with a single Unique
constructor.
Example usage
onlyUnique :: forall record backend (m :: Type -> Type). (MonadIO m, PersistUniqueWrite backend, PersistRecordBackend record backend, OnlyOneUniqueKey record) => record -> ReaderT backend m (Unique record) #
Return the single unique key for a record.
Example usage
We use shcema-1 and dataset-1 here.
onlySimonConst :: MonadIO m => ReaderT SqlBackend m (Unique User) onlySimonConst = onlyUnique $ User "Simon" 999
mSimonConst <- onlySimonConst
mSimonConst
would be Simon's uniqueness constraint. Note that
onlyUnique
doesn't work if there're more than two constraints. It will
fail with a type error instead.
insertUniqueEntity :: forall record backend (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, PersistUniqueWrite backend, SafeToInsert record) => record -> ReaderT backend m (Maybe (Entity record)) #
Like insertEntity
, but returns Nothing
when the record
couldn't be inserted because of a uniqueness constraint.
Example usage
We use schema-2 and dataset-1 here.
insertUniqueSpjEntity :: MonadIO m => ReaderT SqlBackend m (Maybe (Entity User)) insertUniqueSpjEntity = insertUniqueEntity $ User "SPJ" 50
mSpjEnt <- insertUniqueSpjEntity
The above query results Nothing
as SPJ already exists.
insertUniqueAlexaEntity :: MonadIO m => ReaderT SqlBackend m (Maybe (Entity User)) insertUniqueAlexaEntity = insertUniqueEntity $ User "Alexa" 3
mAlexaEnt <- insertUniqueSpjEntity
Because there's no such unique keywords of the given record, the above query when applied on dataset-1, will produce this:
+----+-------+-----+ | id | name | age | +----+-------+-----+ | 1 | SPJ | 40 | +----+-------+-----+ | 2 | Simon | 41 | +----+-------+-----+ | 3 | Alexa | 3 | +----+-------+-----+
Since: persistent-2.7.1
insertBy :: forall record backend (m :: Type -> Type). (MonadIO m, PersistUniqueWrite backend, PersistRecordBackend record backend, AtLeastOneUniqueKey record, SafeToInsert record) => record -> ReaderT backend m (Either (Entity record) (Key record)) #
Insert a value, checking for conflicts with any unique constraints. If a
duplicate exists in the database, it is returned as Left
. Otherwise, the
new 'Key is returned as Right
.
Example usage
With schema-2 and dataset-1, we have following lines of code:
l1 <- insertBy $ User "SPJ" 20 l2 <- insertBy $ User "XXX" 41 l3 <- insertBy $ User "SPJ" 40 r1 <- insertBy $ User "XXX" 100
First three lines return Left
because there're duplicates in given record's uniqueness constraints. While the last line returns a new key as Right
.
onlyOneUniqueDef :: (OnlyOneUniqueKey record, Monad proxy) => proxy record -> UniqueDef #
Given a proxy for a PersistEntity
record, this returns the sole
UniqueDef
for that entity.
Since: persistent-2.13.0.0
class PersistStoreRead backend => PersistUniqueRead backend where #
Queries against Unique
keys (other than the id Key
).
Please read the general Persistent documentation to learn how to create
Unique
keys.
Using this with an Entity without a Unique key leads to undefined
behavior. A few of these functions require a single Unique
, so using
an Entity with multiple Unique
s is also undefined. In these cases
persistent's goal is to throw an exception as soon as possible, but
persistent is still transitioning to that.
SQL backends automatically create uniqueness constraints, but for MongoDB you must manually place a unique index on a field to have a uniqueness constraint.
getBy :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Unique record -> ReaderT backend m (Maybe (Entity record)) #
Get a record by unique key, if available. Returns also the identifier.
Example usage
getBySpjName :: MonadIO m => ReaderT SqlBackend m (Maybe (Entity User)) getBySpjName = getBy $ UniqueUserName "SPJ"
mSpjEnt <- getBySpjName
The above query when applied on dataset-1, will get this entity:
+----+------+-----+ | id | name | age | +----+------+-----+ | 1 | SPJ | 40 | +----+------+-----+
existsBy :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Unique record -> ReaderT backend m Bool #
Returns True if a record with this unique key exists, otherwise False.
Example usage
existsBySpjName :: MonadIO m => ReaderT SqlBackend m Bool existsBySpjName = existsBy $ UniqueUserName "SPJ"
spjEntExists <- existsBySpjName
The above query when applied on dataset-1, will return the value True.
Since: persistent-2.14.5
class (PersistUniqueRead backend, PersistStoreWrite backend) => PersistUniqueWrite backend where #
Some functions in this module (insertUnique
, insertBy
, and
replaceUnique
) first query the unique indexes to check for
conflicts. You could instead optimistically attempt to perform the
operation (e.g. replace
instead of replaceUnique
). However,
- there is some fragility to trying to catch the correct exception and determing the column of failure;
- an exception will automatically abort the current SQL transaction.
deleteBy :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Unique record -> ReaderT backend m () #
Delete a specific record by unique key. Does nothing if no record matches.
Example usage
insertUnique :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m (Maybe (Key record)) #
Like insert
, but returns Nothing
when the record
couldn't be inserted because of a uniqueness constraint.
Example usage
With schema-1 and dataset-1, we try to insert the following two records:
linusId <- insertUnique $ User "Linus" 48 spjId <- insertUnique $ User "SPJ" 90
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |Linus |48 | +-----+------+-----+
Linus's record was inserted to dataset-1, while SPJ wasn't because SPJ already exists in dataset-1.
insertUnique_ :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m (Maybe ()) #
Same as insertUnique
but doesn't return a Key
.
Example usage
With schema-1 and dataset-1, we try to insert the following two records:
linusId <- insertUnique_ $ User "Linus" 48 spjId <- insertUnique_ $ User "SPJ" 90
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |Linus |48 | +-----+------+-----+
Linus's record was inserted to dataset-1, while SPJ wasn't because SPJ already exists in dataset-1.
Since: persistent-2.14.5.0
:: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, OnlyOneUniqueKey record, SafeToInsert record) | |
=> record | new record to insert |
-> [Update record] | updates to perform if the record already exists |
-> ReaderT backend m (Entity record) | the record in the database after the operation |
Update based on a uniqueness constraint or insert:
- insert the new record if it does not exist;
- If the record exists (matched via it's uniqueness constraint), then update the existing record with the parameters which is passed on as list to the function.
Example usage
First, we try to explain upsert
using schema-1 and dataset-1.
upsertSpj :: MonadIO m => [Update User] -> ReaderT SqlBackend m (Maybe (Entity User)) upsertSpj updates = upsert (User "SPJ" 999) updates
mSpjEnt <- upsertSpj [UserAge +=. 15]
The above query when applied on dataset-1, will produce this:
+-----+-----+--------+ |id |name |age | +-----+-----+--------+ |1 |SPJ |40 -> 55| +-----+-----+--------+ |2 |Simon|41 | +-----+-----+--------+
upsertX :: MonadIO m => [Update User] -> ReaderT SqlBackend m (Maybe (Entity User)) upsertX updates = upsert (User "X" 999) updates
mXEnt <- upsertX [UserAge +=. 15]
The above query when applied on dataset-1, will produce this:
+-----+-----+--------+ |id |name |age | +-----+-----+--------+ |1 |SPJ |40 | +-----+-----+--------+ |2 |Simon|41 | +-----+-----+--------+ |3 |X |999 | +-----+-----+--------+
Next, what if the schema has two uniqueness constraints? Let's check it out using schema-2:
mSpjEnt <- upsertSpj [UserAge +=. 15]
This fails with a compile-time type error alerting us to the fact
that this record has multiple unique keys, and suggests that we look for
upsertBy
to select the unique key we want.
:: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) | |
=> Unique record | uniqueness constraint to find by |
-> record | new record to insert |
-> [Update record] | updates to perform if the record already exists |
-> ReaderT backend m (Entity record) | the record in the database after the operation |
Update based on a given uniqueness constraint or insert:
- insert the new record if it does not exist;
- update the existing record that matches the given uniqueness constraint.
Example usage
We try to explain upsertBy
using schema-2 and dataset-1.
upsertBySpjName :: MonadIO m => User -> [Update User] -> ReaderT SqlBackend m (Entity User) upsertBySpjName record updates = upsertBy (UniqueUserName "SPJ") record updates
mSpjEnt <- upsertBySpjName (Person "X" 999) [PersonAge += .15]
The above query will alter dataset-1 to:
+-----+-----+--------+ |id |name |age | +-----+-----+--------+ |1 |SPJ |40 -> 55| +-----+-----+--------+ |2 |Simon|41 | +-----+-----+--------+
upsertBySimonAge :: MonadIO m => User -> [Update User] -> ReaderT SqlBackend m (Entity User) upsertBySimonAge record updates = upsertBy (UniqueUserName "SPJ") record updates
mPhilipEnt <- upsertBySimonAge (User "X" 999) [UserName =. "Philip"]
The above query will alter dataset-1 to:
+----+-----------------+-----+ | id | name | age | +----+-----------------+-----+ | 1 | SPJ | 40 | +----+-----------------+-----+ | 2 | Simon -> Philip | 41 | +----+-----------------+-----+
upsertByUnknownName :: MonadIO m => User -> [Update User] -> ReaderT SqlBackend m (Entity User) upsertByUnknownName record updates = upsertBy (UniqueUserName "Unknown") record updates
mXEnt <- upsertByUnknownName (User "X" 999) [UserAge +=. 15]
This query will alter dataset-1 to:
+-----+-----+-----+ |id |name |age | +-----+-----+-----+ |1 |SPJ |40 | +-----+-----+-----+ |2 |Simon|41 | +-----+-----+-----+ |3 |X |999 | +-----+-----+-----+
:: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) | |
=> [record] | A list of the records you want to insert or replace. |
-> ReaderT backend m () |
Put many records into db
- insert new records that do not exist (or violate any unique constraints)
- replace existing records (matching any unique constraint)
Since: persistent-2.8.1
class PersistEntity record => OnlyOneUniqueKey record where #
This class is used to ensure that upsert
is only called on records
that have a single Unique
key. The quasiquoter automatically generates
working instances for appropriate records, and generates TypeError
instances for records that have 0 or multiple unique keys.
Since: persistent-2.10.0
onlyUniqueP :: record -> Unique record #
type NoUniqueKeysError ty = (('Text "The entity " :<>: 'ShowType ty) :<>: 'Text " does not have any unique keys.") :$$: ('Text "The function you are trying to call requires a unique key " :<>: 'Text "to be defined on the entity.") #
This is an error message. It is used when writing instances of
OnlyOneUniqueKey
for an entity that has no unique keys.
Since: persistent-2.10.0
type MultipleUniqueKeysError ty = ((('Text "The entity " :<>: 'ShowType ty) :<>: 'Text " has multiple unique keys.") :$$: ('Text "The function you are trying to call requires only a single " :<>: 'Text "unique key.")) :$$: (('Text "There is probably a variant of the function with 'By' " :<>: 'Text "appended that will allow you to select a unique key ") :<>: 'Text "for the operation.") #
This is an error message. It is used when an entity has multiple unique keys, and the function expects a single unique key.
Since: persistent-2.10.0
class PersistEntity record => AtLeastOneUniqueKey record where #
This class is used to ensure that functions requring at least one
unique key are not called with records that have 0 unique keys. The
quasiquoter automatically writes working instances for appropriate
entities, and generates TypeError
instances for records that have
0 unique keys.
Since: persistent-2.10.0
requireUniquesP :: record -> NonEmpty (Unique record) #
data SqlBackend #
A SqlBackend
represents a handle or connection to a database. It
contains functions and values that allow databases to have more
optimized implementations, as well as references that benefit
performance and sharing.
Instead of using the SqlBackend
constructor directly, use the
mkSqlBackend
function.
A SqlBackend
is *not* thread-safe. You should not assume that
a SqlBackend
can be shared among threads and run concurrent queries.
This *will* result in problems. Instead, you should create a
, known as a Pool
SqlBackend
ConnectionPool
, and pass that around in
multi-threaded applications.
To run actions in the persistent
library, you should use the
runSqlConn
function. If you're using a multithreaded application, use
the runSqlPool
function.
Instances
HasPersistBackend SqlBackend | |
Defined in Database.Persist.SqlBackend.Internal type BaseBackend SqlBackend # | |
IsPersistBackend SqlBackend | |
Defined in Database.Persist.SqlBackend.Internal | |
newtype BackendKey SqlBackend | |
Defined in Database.Persist.Sql.Orphan.PersistStore | |
type BaseBackend SqlBackend | |
Defined in Database.Persist.SqlBackend.Internal | |
type Rep (BackendKey SqlBackend) | |
Defined in Database.Persist.Sql.Orphan.PersistStore type Rep (BackendKey SqlBackend) = D1 ('MetaData "BackendKey" "Database.Persist.Sql.Orphan.PersistStore" "persistent-2.14.5.1-1klc2SaLXJ07EHFQFFZySK" 'True) (C1 ('MetaCons "SqlBackendKey" 'PrefixI 'True) (S1 ('MetaSel ('Just "unSqlBackendKey") 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 Int64))) |
insertRecord :: forall record backend (m :: Type -> Type). (PersistEntityBackend record ~ BaseBackend backend, PersistEntity record, MonadIO m, PersistStoreWrite backend, SafeToInsert record, HasCallStack) => record -> ReaderT backend m record #
Like insertEntity
but just returns the record instead of Entity
.
Example usage
insertDaveRecord :: MonadIO m => ReaderT SqlBackend m User insertDaveRecord = insertRecord $ User "Dave" 50
dave <- insertDaveRecord
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |Dave |50 | +-----+------+-----+
Since: persistent-2.6.1
getEntity :: forall e backend (m :: Type -> Type). (PersistStoreRead backend, PersistRecordBackend e backend, MonadIO m) => Key e -> ReaderT backend m (Maybe (Entity e)) #
Like get
, but returns the complete Entity
.
Example usage
getSpjEntity :: MonadIO m => ReaderT SqlBackend m (Maybe (Entity User)) getSpjEntity = getEntity spjId
mSpjEnt <- getSpjEntity
The above query when applied on dataset-1, will get this entity:
+----+------+-----+ | id | name | age | +----+------+-----+ | 1 | SPJ | 40 | +----+------+-----+
insertEntity :: forall e backend (m :: Type -> Type). (PersistStoreWrite backend, PersistRecordBackend e backend, SafeToInsert e, MonadIO m, HasCallStack) => e -> ReaderT backend m (Entity e) #
Like insert
, but returns the complete Entity
.
Example usage
insertHaskellEntity :: MonadIO m => ReaderT SqlBackend m (Entity User) insertHaskellEntity = insertEntity $ User "Haskell" 81
haskellEnt <- insertHaskellEntity
The above query when applied on dataset-1, will produce this:
+----+---------+-----+ | id | name | age | +----+---------+-----+ | 1 | SPJ | 40 | +----+---------+-----+ | 2 | Simon | 41 | +----+---------+-----+ | 3 | Haskell | 81 | +----+---------+-----+
belongsToJust :: forall ent1 ent2 backend (m :: Type -> Type). (PersistStoreRead backend, PersistEntity ent1, PersistRecordBackend ent2 backend, MonadIO m) => (ent1 -> Key ent2) -> ent1 -> ReaderT backend m ent2 #
Same as belongsTo
, but uses getJust
and therefore is similarly unsafe.
belongsTo :: forall ent1 ent2 backend (m :: Type -> Type). (PersistStoreRead backend, PersistEntity ent1, PersistRecordBackend ent2 backend, MonadIO m) => (ent1 -> Maybe (Key ent2)) -> ent1 -> ReaderT backend m (Maybe ent2) #
Curry this to make a convenience function that loads an associated model.
foreign = belongsTo foreignId
getJustEntity :: forall record backend (m :: Type -> Type). (PersistEntityBackend record ~ BaseBackend backend, MonadIO m, PersistEntity record, PersistStoreRead backend) => Key record -> ReaderT backend m (Entity record) #
Same as getJust
, but returns an Entity
instead of just the record.
Example usage
getJustEntitySpj :: MonadIO m => ReaderT SqlBackend m (Entity User) getJustEntitySpj = getJustEntity spjId
spjEnt <- getJustEntitySpj
The above query when applied on dataset-1, will get this entity:
+----+------+-----+ | id | name | age | +----+------+-----+ | 1 | SPJ | 40 | +----+------+-----+
Since: persistent-2.6.1
getJust :: forall record backend (m :: Type -> Type). (PersistStoreRead backend, PersistRecordBackend record backend, MonadIO m) => Key record -> ReaderT backend m record #
Same as get
, but for a non-null (not Maybe) foreign key.
Unsafe unless your database is enforcing that the foreign key is valid.
Example usage
getJustSpj :: MonadIO m => ReaderT SqlBackend m User getJustSpj = getJust spjId
spj <- getJust spjId
The above query when applied on dataset-1, will get this record:
+----+------+-----+ | id | name | age | +----+------+-----+ | 1 | SPJ | 40 | +----+------+-----+
getJustUnknown :: MonadIO m => ReaderT SqlBackend m User getJustUnknown = getJust unknownId
mrx <- getJustUnknown
This just throws an error.
liftPersist :: (MonadIO m, MonadReader backend m) => ReaderT backend IO b -> m b #
withCompatibleBackend :: forall sup sub (m :: Type -> Type) a. BackendCompatible sup sub => ReaderT sup m a -> ReaderT sub m a #
Run a query against a compatible backend, by projecting the backend
This is a helper for using queries which run against a specific backend type that your backend is compatible with.
Since: persistent-2.12.0
withBaseBackend :: forall backend (m :: Type -> Type) a. HasPersistBackend backend => ReaderT (BaseBackend backend) m a -> ReaderT backend m a #
Run a query against a larger backend by plucking out BaseBackend backend
This is a helper for reusing existing queries when expanding the backend type.
Since: persistent-2.12.0
type family BaseBackend backend #
Instances
type BaseBackend SqlReadBackend | |
Defined in Database.Persist.Sql.Types.Internal | |
type BaseBackend SqlWriteBackend | |
Defined in Database.Persist.Sql.Types.Internal | |
type BaseBackend SqlBackend | |
Defined in Database.Persist.SqlBackend.Internal |
class HasPersistBackend backend where #
Class which allows the plucking of a BaseBackend backend
from some larger type.
For example,
instance HasPersistBackend (SqlReadBackend, Int) where
type BaseBackend (SqlReadBackend, Int) = SqlBackend
persistBackend = unSqlReadBackend . fst
type BaseBackend backend #
persistBackend :: backend -> BaseBackend backend #
Instances
class HasPersistBackend backend => IsPersistBackend backend #
Class which witnesses that backend
is essentially the same as BaseBackend backend
.
That is, they're isomorphic and backend
is just some wrapper over BaseBackend backend
.
class BackendCompatible sup sub where #
This class witnesses that two backend are compatible, and that you can
convert from the sub
backend into the sup
backend. This is similar
to the HasPersistBackend
and IsPersistBackend
classes, but where you
don't want to fix the type associated with the PersistEntityBackend
of
a record.
Generally speaking, where you might have:
foo :: (PersistEntity
record ,PeristEntityBackend
record ~BaseBackend
backend ,IsSqlBackend
backend )
this can be replaced with:
foo :: (PersistEntity
record, ,PersistEntityBackend
record ~ backend ,BackendCompatible
SqlBackend
backend )
This works for SqlReadBackend
because of the instance
, without needing to go through the BackendCompatible
SqlBackend
SqlReadBackend
BaseBackend
type family.
Likewise, functions that are currently hardcoded to use SqlBackend
can be generalized:
-- before: asdf ::ReaderT
SqlBackend
m () asdf = pure () -- after: asdf' ::BackendCompatible
SqlBackend backend => ReaderT backend m () asdf' =withCompatibleBackend
asdf
Since: persistent-2.7.1
projectBackend :: sub -> sup #
type PersistRecordBackend record backend = (PersistEntity record, PersistEntityBackend record ~ BaseBackend backend) #
A convenient alias for common type signatures
class (PersistEntity record, PersistEntityBackend record ~ backend, PersistCore backend) => ToBackendKey backend record where #
ToBackendKey
converts a PersistEntity
Key
into a BackendKey
This can be used by each backend to convert between a Key
and a plain
Haskell type. For Sql, that is done with toSqlKey
and fromSqlKey
.
By default, a PersistEntity
uses the default BackendKey
for its Key
and is an instance of ToBackendKey
A Key
that instead uses a custom type will not be an instance of
ToBackendKey
.
toBackendKey :: Key record -> BackendKey backend #
fromBackendKey :: BackendKey backend -> Key record #
data family BackendKey backend #
Instances
class PersistCore backend #
data BackendKey backend #
class (Show (BackendKey backend), Read (BackendKey backend), Eq (BackendKey backend), Ord (BackendKey backend), PersistCore backend, PersistField (BackendKey backend), ToJSON (BackendKey backend), FromJSON (BackendKey backend)) => PersistStoreRead backend where #
get :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> ReaderT backend m (Maybe record) #
Get a record by identifier, if available.
Example usage
getMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => [Key record] -> ReaderT backend m (Map (Key record) record) #
Get many records by their respective identifiers, if available.
Example usage
getUsers :: MonadIO m => ReaderT SqlBackend m (Map (Key User) User) getUsers = getMany allkeys
musers <- getUsers
The above query when applied on dataset-1, will get these records:
+----+-------+-----+ | id | name | age | +----+-------+-----+ | 1 | SPJ | 40 | +----+-------+-----+ | 2 | Simon | 41 | +----+-------+-----+
Since: persistent-2.8.1
class (Show (BackendKey backend), Read (BackendKey backend), Eq (BackendKey backend), Ord (BackendKey backend), PersistStoreRead backend, PersistField (BackendKey backend), ToJSON (BackendKey backend), FromJSON (BackendKey backend)) => PersistStoreWrite backend where #
insert :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m (Key record) #
Create a new record in the database, returning an automatically created key (in SQL an auto-increment id).
Example usage
Using schema-1 and dataset-1, let's insert a new user John
.
insertJohn :: MonadIO m => ReaderT SqlBackend m (Key User) insertJohn = insert $ User "John" 30
johnId <- insertJohn
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |John |30 | +-----+------+-----+
insert_ :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => record -> ReaderT backend m () #
Same as insert
, but doesn't return a Key
.
Example usage
insertJohn :: MonadIO m => ReaderT SqlBackend m (Key User) insertJohn = insert_ $ User "John" 30
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |John |30 | +-----+------+-----+
insertMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => [record] -> ReaderT backend m [Key record] #
Create multiple records in the database and return their Key
s.
If you don't need the inserted Key
s, use insertMany_
.
The MongoDB and PostgreSQL backends insert all records and retrieve their keys in one database query.
The SQLite and MySQL backends use the slow, default implementation of
mapM insert
.
Example usage
insertUsers :: MonadIO m => ReaderT SqlBackend m [Key User] insertUsers = insertMany [User "John" 30, User "Nick" 32, User "Jane" 20]
userIds <- insertUsers
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |John |30 | +-----+------+-----+ |4 |Nick |32 | +-----+------+-----+ |5 |Jane |20 | +-----+------+-----+
insertMany_ :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend, SafeToInsert record) => [record] -> ReaderT backend m () #
Same as insertMany
, but doesn't return any Key
s.
The MongoDB, PostgreSQL, SQLite and MySQL backends insert all records in one database query.
Example usage
insertUsers_ :: MonadIO m => ReaderT SqlBackend m () insertUsers_ = insertMany_ [User "John" 30, User "Nick" 32, User "Jane" 20]
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |John |30 | +-----+------+-----+ |4 |Nick |32 | +-----+------+-----+ |5 |Jane |20 | +-----+------+-----+
insertEntityMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => [Entity record] -> ReaderT backend m () #
Same as insertMany_
, but takes an Entity
instead of just a record.
Useful when migrating data from one entity to another and want to preserve ids.
The MongoDB, PostgreSQL, SQLite and MySQL backends insert all records in one database query.
Example usage
insertUserEntityMany :: MonadIO m => ReaderT SqlBackend m () insertUserEntityMany = insertEntityMany [SnakeEntity, EvaEntity]
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |Snake |38 | +-----+------+-----+ |4 |Eva |38 | +-----+------+-----+
insertKey :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> record -> ReaderT backend m () #
Create a new record in the database using the given key.
Example usage
insertAliceKey :: MonadIO m => Key User -> ReaderT SqlBackend m () insertAliceKey key = insertKey key $ User "Alice" 20
insertAliceKey $ UserKey {unUserKey = SqlBackendKey {unSqlBackendKey = 3}}
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |Alice |20 | +-----+------+-----+
repsert :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> record -> ReaderT backend m () #
Put the record in the database with the given key.
Unlike replace
, if a record with the given key does not
exist then a new record will be inserted.
Example usage
We try to explain upsertBy
using schema-1 and dataset-1.
First, we insert Philip to dataset-1.
insertPhilip :: MonadIO m => ReaderT SqlBackend m (Key User) insertPhilip = insert $ User "Philip" 42
philipId <- insertPhilip
This query will produce:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |Philip|42 | +-----+------+-----+
repsertHaskell :: MonadIO m => Key record -> ReaderT SqlBackend m () repsertHaskell id = repsert id $ User "Haskell" 81
repsertHaskell philipId
This query will replace Philip's record with Haskell's one:
+-----+-----------------+--------+ |id |name |age | +-----+-----------------+--------+ |1 |SPJ |40 | +-----+-----------------+--------+ |2 |Simon |41 | +-----+-----------------+--------+ |3 |Philip -> Haskell|42 -> 81| +-----+-----------------+--------+
repsert
inserts the given record if the key doesn't exist.
repsertXToUnknown :: MonadIO m => ReaderT SqlBackend m () repsertXToUnknown = repsert unknownId $ User "X" 999
For example, applying the above query to dataset-1 will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |40 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+ |3 |X |999 | +-----+------+-----+
repsertMany :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => [(Key record, record)] -> ReaderT backend m () #
Put many entities into the database.
Batch version of repsert
for SQL backends.
Useful when migrating data from one entity to another and want to preserve ids.
Example usage
repsertManyUsers :: MonadIO m =>ReaderT SqlBackend m () repsertManyusers = repsertMany [(simonId, User "Philip" 20), (unknownId999, User "Mr. X" 999)]
The above query when applied on dataset-1, will produce this:
+-----+----------------+---------+ |id |name |age | +-----+----------------+---------+ |1 |SPJ |40 | +-----+----------------+---------+ |2 |Simon -> Philip |41 -> 20 | +-----+----------------+---------+ |999 |Mr. X |999 | +-----+----------------+---------+
Since: persistent-2.8.1
replace :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> record -> ReaderT backend m () #
Replace the record in the database with the given
key. Note that the result is undefined if such record does
not exist, so you must use insertKey
or repsert
in
these cases.
Example usage
With schema-1 schama-1 and dataset-1,
replaceSpj :: MonadIO m => User -> ReaderT SqlBackend m () replaceSpj record = replace spjId record
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |Mike |45 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+
updateGet :: forall record (m :: Type -> Type). (MonadIO m, PersistRecordBackend record backend) => Key record -> [Update record] -> ReaderT backend m record #
Update individual fields on a specific record, and retrieve the updated value from the database.
Note that this function will throw an exception if the given key is not found in the database.
Example usage
updateGetSpj :: MonadIO m => [Update User] -> ReaderT SqlBackend m User updateGetSpj updates = updateGet spjId updates
spj <- updateGetSpj [UserAge +=. 100]
The above query when applied on dataset-1, will produce this:
+-----+------+-----+ |id |name |age | +-----+------+-----+ |1 |SPJ |140 | +-----+------+-----+ |2 |Simon |41 | +-----+------+-----+
fromPersistValueJSON :: FromJSON a => PersistValue -> Either Text a #
Convenience function for getting a free PersistField
instance
from a type with JSON instances. The JSON parser used will accept JSON
values other that object and arrays. So, if your instance serializes the
data to a JSON string, this will still work.
Example usage in combination with toPersistValueJSON
:
instance PersistField MyData where fromPersistValue = fromPersistValueJSON toPersistValue = toPersistValueJSON
toPersistValueJSON :: ToJSON a => a -> PersistValue #
Convenience function for getting a free PersistField
instance
from a type with JSON instances.
Example usage in combination with fromPersistValueJSON
:
instance PersistField MyData where fromPersistValue = fromPersistValueJSON toPersistValue = toPersistValueJSON
entityIdFromJSON :: (PersistEntity record, FromJSON record) => Value -> Parser (Entity record) #
Predefined parseJSON
. The input JSON looks like
{"id": 1, "name": ...}
.
The typical usage is:
instance FromJSON (Entity User) where parseJSON = entityIdFromJSON
entityIdToJSON :: (PersistEntity record, ToJSON record) => Entity record -> Value #
Predefined toJSON
. The resulting JSON looks like
{"id": 1, "name": ...}
.
The typical usage is:
instance ToJSON (Entity User) where toJSON = entityIdToJSON
keyValueEntityFromJSON :: (PersistEntity record, FromJSON record) => Value -> Parser (Entity record) #
Predefined parseJSON
. The input JSON looks like
{"key": 1, "value": {"name": ...}}
.
The typical usage is:
instance FromJSON (Entity User) where parseJSON = keyValueEntityFromJSON
keyValueEntityToJSON :: (PersistEntity record, ToJSON record) => Entity record -> Value #
Predefined toJSON
. The resulting JSON looks like
{"key": 1, "value": {"name": ...}}
.
The typical usage is:
instance ToJSON (Entity User) where toJSON = keyValueEntityToJSON
entityValues :: PersistEntity record => Entity record -> [PersistValue] #
Get list of values corresponding to given entity.
tabulateEntity :: PersistEntity record => (forall a. EntityField record a -> a) -> Entity record #
Construct an
by providing a value for each of the
record's fields.Entity
record
These constructions are equivalent:
entityMattConstructor, entityMattTabulate :: Entity User entityMattConstructor = Entity { entityKey = toSqlKey 123 , entityVal = User { userName = Matt , userAge = 33 } } entityMattTabulate = tabulateEntity $ \case UserId -> toSqlKey 123 UserName -> Matt UserAge -> 33
This is a specialization of tabulateEntityA
, which allows you to
construct an Entity
by providing an Applicative
action for each
field instead of a regular function.
Since: persistent-2.14.0.0
Unique keys besides the Key
.
Instances
FinalResult (Unique val) Source # | |
Defined in Database.Esqueleto.Internal.Internal |
data family EntityField record :: Type -> Type #
An EntityField
is parameterised by the Haskell record it belongs to
and the additional type of that field.
As of persistent-2.11.0.0
, it's possible to use the OverloadedLabels
language extension to refer to EntityField
values polymorphically. See
the documentation on SymbolToField
for more information.
Instances
SymbolToField sym rec typ => IsLabel sym (EntityField rec typ) | This instance delegates to Since: persistent-2.11.0.0 |
Defined in Database.Persist.Class.PersistEntity fromLabel :: EntityField rec typ # |
By default, a backend will automatically generate the key Instead you can specify a Primary key made up of unique values.
Instances
(PersistEntity a, PersistEntityBackend a ~ backend, IsPersistBackend backend) => RawSql (Key a) | |
Defined in Database.Persist.Sql.Class rawSqlCols :: (Text -> Text) -> Key a -> (Int, [Text]) # rawSqlColCountReason :: Key a -> String # rawSqlProcessRow :: [PersistValue] -> Either Text (Key a) # |
type family PersistEntityBackend record #
Persistent allows multiple different backends (databases).
class (PersistField (Key record), ToJSON (Key record), FromJSON (Key record), Show (Key record), Read (Key record), Eq (Key record), Ord (Key record)) => PersistEntity record where #
Persistent serialized Haskell records to the database.
A Database Entity
(A row in SQL, a document in MongoDB, etc)
corresponds to a Key
plus a Haskell record.
For every Haskell record type stored in the database there is a
corresponding PersistEntity
instance. An instance of PersistEntity
contains meta-data for the record. PersistEntity also helps abstract
over different record types. That way the same query interface can return
a PersistEntity
, with each query returning different types of Haskell
records.
Some advanced type system capabilities are used to make this process type-safe. Persistent users usually don't need to understand the class associated data and functions.
keyToValues, keyFromValues, persistIdField, entityDef, persistFieldDef, toPersistFields, fromPersistValues, tabulateEntityA, persistUniqueKeys, persistUniqueToFieldNames, persistUniqueToValues, fieldLens
type PersistEntityBackend record #
Persistent allows multiple different backends (databases).
By default, a backend will automatically generate the key Instead you can specify a Primary key made up of unique values.
data EntityField record :: Type -> Type #
An EntityField
is parameterised by the Haskell record it belongs to
and the additional type of that field.
As of persistent-2.11.0.0
, it's possible to use the OverloadedLabels
language extension to refer to EntityField
values polymorphically. See
the documentation on SymbolToField
for more information.
Unique keys besides the Key
.
keyToValues :: Key record -> [PersistValue] #
A lower-level key operation.
keyFromValues :: [PersistValue] -> Either Text (Key record) #
A lower-level key operation.
persistIdField :: EntityField record (Key record) #
A meta-operation to retrieve the Key
EntityField
.
entityDef :: proxy record -> EntityDef #
Retrieve the EntityDef
meta-data for the record.
persistFieldDef :: EntityField record typ -> FieldDef #
Return meta-data for a given EntityField
.
toPersistFields :: record -> [PersistValue] #
A meta-operation to get the database fields of a record.
fromPersistValues :: [PersistValue] -> Either Text record #
A lower-level operation to convert from database values to a Haskell record.
:: Applicative f | |
=> (forall a. EntityField record a -> f a) | A function that builds a fragment of a record in an
|
-> f (Entity record) |
This function allows you to build an
by specifying an
action that returns a value for the field in the callback function.
Let's look at an example.Entity
a
parseFromEnvironmentVariables :: IO (Entity User) parseFromEnvironmentVariables = tabulateEntityA $ \userField -> case userField of UserName -> getEnv USER_NAME UserAge -> do ageVar <- getEnv USER_AGE case readMaybe ageVar of Just age -> pure age Nothing -> error $ "Failed to parse Age from: " <> ageVar UserAddressId -> do addressVar <- getEnv USER_ADDRESS_ID pure $ AddressKey addressVar
Since: persistent-2.14.0.0
persistUniqueKeys :: record -> [Unique record] #
A meta operation to retrieve all the Unique
keys.
persistUniqueToFieldNames :: Unique record -> NonEmpty (FieldNameHS, FieldNameDB) #
A lower level operation.
persistUniqueToValues :: Unique record -> [PersistValue] #
A lower level operation.
fieldLens :: EntityField record field -> forall (f :: Type -> Type). Functor f => (field -> f field) -> Entity record -> f (Entity record) #
Use a PersistField
as a lens.
keyFromRecordM :: Maybe (record -> Key record) #
Extract a
from a Key
recordrecord
value. Currently, this is
only defined for entities using the Primary
syntax for
natural/composite keys. In a future version of persistent
which
incorporates the ID directly into the entity, this will always be Just.
Since: persistent-2.11.0.0
type family BackendSpecificUpdate backend record #
data FilterValue typ where #
Value to filter with. Highly dependant on the type of filter used.
Since: persistent-2.10.0
FilterValue :: forall typ. typ -> FilterValue typ | |
FilterValues :: forall typ. [typ] -> FilterValue typ | |
UnsafeValue :: forall a typ. PersistField a => a -> FilterValue typ |
Datatype that represents an entity, with both its Key
and
its Haskell record representation.
When using a SQL-based backend (such as SQLite or
PostgreSQL), an Entity
may take any number of columns
depending on how many fields it has. In order to reconstruct
your entity on the Haskell side, persistent
needs all of
your entity columns and in the right order. Note that you
don't need to worry about this when using persistent
's API
since everything is handled correctly behind the scenes.
However, if you want to issue a raw SQL command that returns
an Entity
, then you have to be careful with the column
order. While you could use SELECT Entity.* WHERE ...
and
that would work most of the time, there are times when the
order of the columns on your database is different from the
order that persistent
expects (for example, if you add a new
field in the middle of you entity definition and then use the
migration code -- persistent
will expect the column to be in
the middle, but your DBMS will put it as the last column).
So, instead of using a query like the one above, you may use
rawSql
(from the
Database.Persist.Sql module) with its /entity
selection placeholder/ (a double question mark ??
). Using
rawSql
the query above must be written as SELECT ?? WHERE
..
. Then rawSql
will replace ??
with the list of all
columns that we need from your entity in the right order. If
your query returns two entities (i.e. (Entity backend a,
Entity backend b)
), then you must you use SELECT ??, ??
WHERE ...
, and so on.
Instances
class SymbolToField (sym :: Symbol) rec typ | sym rec -> typ where #
This type class is used with the OverloadedLabels
extension to
provide a more convenient means of using the EntityField
type.
EntityField
definitions are prefixed with the type name to avoid
ambiguity, but this ambiguity can result in verbose code.
If you have a table User
with a name Text
field, then the
corresponding EntityField
is UserName
. With this, we can write
#name ::
.EntityField
User Text
What's more fun is that the type is more general: it's actually
#name
:: (
SymbolToField
"name" rec typ)
=> EntityField rec typ
Which means it is *polymorphic* over the actual record. This allows you to write code that can be generic over the tables, provided they have the right fields.
Since: persistent-2.11.0.0
symbolToField :: EntityField rec typ #
class SafeToInsert a #
A type class which is used to witness that a type is safe to insert into the database without providing a primary key.
The TemplateHaskell
function mkPersist
will generate instances of this
class for any entity that it works on. If the entity has a default primary
key, then it provides a regular instance. If the entity has a Primary
natural key, then this works fine. But if the entity has an Id
column with
no default=
, then this does a TypeError
and forces the user to use
insertKey
.
Since: persistent-2.14.0.0
Instances
(TypeError (EntityErrorMessage a) :: Constraint) => SafeToInsert (Entity a) | |
Defined in Database.Persist.Class.PersistEntity | |
(TypeError (FunctionErrorMessage a b) :: Constraint) => SafeToInsert (a -> b) | |
Defined in Database.Persist.Class.PersistEntity |
class PersistField a where #
This class teaches Persistent how to take a custom type and marshal it to and from a PersistValue
, allowing it to be stored in a database.
Examples
Simple Newtype
You can use newtype
to add more type safety/readability to a basis type like ByteString
. In these cases, just derive PersistField
and PersistFieldSql
:
{-# LANGUAGE GeneralizedNewtypeDeriving #-} newtype HashedPassword = HashedPasswordByteString
deriving (Eq, Show,PersistField
, PersistFieldSql)
Smart Constructor Newtype
In this example, we create a PersistField
instance for a newtype following the "Smart Constructor" pattern.
{-# LANGUAGE GeneralizedNewtypeDeriving #-} import qualified Data.Text as T import qualified Data.Char as C -- | An American Social Security Number newtype SSN = SSNErrorMessage
deriving (Eq, Show, PersistFieldSql) mkSSN ::ErrorMessage
->Either
ErrorMessage
SSN mkSSN t = if (T.length t == 9) && (T.all C.isDigit t) thenRight
$ SSN t elseLeft
$ "Invalid SSN: " <> t instancePersistField
SSN wheretoPersistValue
(SSN t) =PersistText
tfromPersistValue
(PersistText
t) = mkSSN t -- Handle cases where the database does not give us PersistTextfromPersistValue
x =Left
$ "File.hs: When trying to deserialize an SSN: expected PersistText, received: " <> T.pack (show x)
Tips:
- This file contain dozens of
PersistField
instances you can look at for examples. - Typically custom
PersistField
instances will only accept a singlePersistValue
constructor infromPersistValue
. - Internal
PersistField
instances accept a wide variety ofPersistValue
s to accomodate e.g. storing booleans as integers, booleans or strings. - If you're making a custom instance and using a SQL database, you'll also need
PersistFieldSql
to specify the type of the database column.
toPersistValue :: a -> PersistValue #
fromPersistValue :: PersistValue -> Either Text a #
Instances
newtype OverflowNatural #
Prior to persistent-2.11.0
, we provided an instance of
PersistField
for the Natural
type. This was in error, because
Natural
represents an infinite value, and databases don't have
reasonable types for this.
The instance for Natural
used the Int64
underlying type, which will
cause underflow and overflow errors. This type has the exact same code
in the instances, and will work seamlessly.
A more appropriate type for this is the Word
series of types from
Data.Word. These have a bounded size, are guaranteed to be
non-negative, and are quite efficient for the database to store.
Since: persistent-2.11.0
Instances
overEntityFields :: ([FieldDef] -> [FieldDef]) -> EntityDef -> EntityDef #
Perform a mapping function over all of the entity fields, as determined by
getEntityFieldsDatabase
.
Since: persistent-2.13.0.0
getEntityKeyFields :: EntityDef -> NonEmpty FieldDef #
Since: persistent-2.13.0.0
setEntityIdDef :: EntityIdDef -> EntityDef -> EntityDef #
Since: persistent-2.13.0.0
setEntityId :: FieldDef -> EntityDef -> EntityDef #
getEntityIdField :: EntityDef -> Maybe FieldDef #
Since: persistent-2.13.0.0
getEntityId :: EntityDef -> EntityIdDef #
Since: persistent-2.13.0.0
isEntitySum :: EntityDef -> Bool #
Since: persistent-2.13.0.0
getEntityFieldsDatabase :: EntityDef -> [FieldDef] #
This returns all of the FieldDef
defined for the EntityDef
, including
those fields that are marked as MigrationOnly
(and therefore only present
in the database) or SafeToRemove
(and a migration will drop the column if
it exists in the database).
For all the fields that are present on the Haskell-type, see
getEntityFields
.
Since: persistent-2.13.0.0
getEntityFields :: EntityDef -> [FieldDef] #
Retrieve the list of FieldDef
that makes up the fields of the entity.
This does not return the fields for an Id
column or an implicit id
. It
will return the key columns if you used the Primary
syntax for defining the
primary key.
This does not return fields that are marked SafeToRemove
or MigrationOnly
- so it only returns fields that are represented in the Haskell type. If you
need those fields, use getEntityFieldsDatabase
.
Since: persistent-2.13.0.0
getEntityForeignDefs :: EntityDef -> [ForeignDef] #
Since: persistent-2.13.0.0
getEntityComments :: EntityDef -> Maybe Text #
setEntityDBName :: EntityNameDB -> EntityDef -> EntityDef #
Since: persistent-2.13.0.0
getEntityDBName :: EntityDef -> EntityNameDB #
Return the database name for the given entity.
Since: persistent-2.13.0.0
getEntityHaskellName :: EntityDef -> EntityNameHS #
Retrieve the Haskell name of the given entity.
Since: persistent-2.13.0.0
getEntityUniques :: EntityDef -> [UniqueDef] #
Retrieve the list of UniqueDef
from an EntityDef
. As of version 2.14,
this will also include the primary key on the entity, if one is defined. If
you do not want the primary key, see getEntityUniquesNoPrimaryKey
.
Since: persistent-2.13.0.0
isFieldMaybe :: FieldDef -> Bool #
Check if the field is `Maybe a`
Since: persistent-2.13.0.0
isFieldNullable :: FieldDef -> IsNullable #
Check if the field definition is nullable
Since: persistent-2.13.0.0
addFieldAttr :: FieldAttr -> FieldDef -> FieldDef #
Add an attribute to the list of field attributes.
Since: persistent-2.13.0.0
overFieldAttrs :: ([FieldAttr] -> [FieldAttr]) -> FieldDef -> FieldDef #
Modify the list of field attributes.
Since: persistent-2.13.0.0
setFieldAttrs :: [FieldAttr] -> FieldDef -> FieldDef #
A Statement
is a representation of a database query that has been
prepared and stored on the server side.
Statement | |
|
renderCascadeAction :: CascadeAction -> Text #
Render a CascadeAction
to Text
such that it can be used in a SQL
command.
Since: persistent-2.11.0
renderFieldCascade :: FieldCascade -> Text #
Renders a FieldCascade
value such that it can be used in SQL
migrations.
Since: persistent-2.11.0
A FieldCascade
that does nothing.
Since: persistent-2.11.0
isHaskellField :: FieldDef -> Bool #
isFieldNotGenerated :: FieldDef -> Bool #
parseFieldAttrs :: [Text] -> [FieldAttr] #
Parse raw field attributes into structured form. Any unrecognized
attributes will be preserved, identically as they are encountered,
as FieldAttrOther
values.
Since: persistent-2.11.0.0
entityPrimary :: EntityDef -> Maybe CompositeDef #
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
.
Active | When used on a uniqueness constraint, there
may be at most one |
Inactive | When used on a uniqueness constraint, there
may be any number of |
Instances
data IsNullable #
Instances
Show IsNullable | |
Defined in Database.Persist.Types.Base showsPrec :: Int -> IsNullable -> ShowS # show :: IsNullable -> String # showList :: [IsNullable] -> ShowS # | |
Eq IsNullable | |
Defined in Database.Persist.Types.Base (==) :: IsNullable -> IsNullable -> Bool # (/=) :: IsNullable -> IsNullable -> Bool # |
data WhyNullable #
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.
Instances
Show WhyNullable | |
Defined in Database.Persist.Types.Base showsPrec :: Int -> WhyNullable -> ShowS # show :: WhyNullable -> String # showList :: [WhyNullable] -> ShowS # | |
Eq WhyNullable | |
Defined in Database.Persist.Types.Base (==) :: WhyNullable -> WhyNullable -> Bool # (/=) :: WhyNullable -> WhyNullable -> Bool # |
An EntityDef
represents the information that persistent
knows
about an Entity. It uses this information to generate the Haskell
datatype, the SQL migrations, and other relevant conversions.
data EntityIdDef #
The definition for the entity's primary key ID.
Since: persistent-2.13.0.0
EntityIdField !FieldDef | The entity has a single key column, and it is a surrogate key - that
is, you can't go from Since: persistent-2.13.0.0 |
EntityIdNaturalKey !CompositeDef | The entity has a natural key. This means you can write A natural key can have one or more columns. Since: persistent-2.13.0.0 |
Instances
Attributes that may be attached to fields that can affect migrations and serialization in backend-specific ways.
While we endeavor to, we can't forsee all use cases for all backends,
and so FieldAttr
is extensible through its constructor FieldAttrOther
.
Since: persistent-2.11.0.0
FieldAttrMaybe | The Example: User name Text Maybe |
FieldAttrNullable | This indicates that the column is nullable, but should not have
a data What = NoWhat | Hello Text instance PersistField What where fromPersistValue PersistNull = pure NoWhat fromPersistValue pv = Hello $ fromPersistValue pv instance PersistFieldSql What where sqlType _ = SqlString User what What nullable |
FieldAttrMigrationOnly | This tag means that the column will not be present on the Haskell code, but will not be removed from the database. Useful to deprecate fields in phases. You should set the column to be nullable in the database. Otherwise, inserts won't have values. User oldName Text MigrationOnly newName Text |
FieldAttrSafeToRemove | A Useful after you've used User oldName Text SafeToRemove newName Text |
FieldAttrNoreference | This attribute indicates that we should not create a foreign key
reference from a column. By default, This is useful if you want to use the explicit foreign key syntax. Post title Text Comment postId PostId noreference Foreign Post fk_comment_post postId |
FieldAttrReference Text | This is set to specify precisely the database table the column refers to. Post title Text Comment postId PostId references="post" You should not need this - |
FieldAttrConstraint Text | Specify a name for the constraint on the foreign key reference for this table. Post title Text Comment postId PostId constraint="my_cool_constraint_name" |
FieldAttrDefault Text | Specify the default value for a column. User createdAt UTCTime default="NOW()" Note that a |
FieldAttrSqltype Text | Specify a custom SQL type for the column. Generally, you should define
a custom datatype with a custom User uuid Text sqltype=UUID |
FieldAttrMaxlen Integer | Set a maximum length for a column. Useful for VARCHAR and indexes. User name Text maxlen=200 UniqueName name |
FieldAttrSql Text | Specify the database name of the column. User blarghle Int sql="b_l_a_r_g_h_l_e" Useful for performing phased migrations, where one column is renamed to another column over time. |
FieldAttrOther Text | A grab bag of random attributes that were unrecognized by the parser. |
A FieldType
describes a field parsed from the QuasiQuoter and is
used to determine the Haskell type in the generated code.
name Text
parses into FTTypeCon Nothing Text
name T.Text
parses into FTTypeCon (Just T Text)
name (Jsonb User)
parses into:
FTApp (FTTypeCon Nothing Jsonb) (FTTypeCon Nothing User)
FTTypeCon (Maybe Text) Text | Optional module and name. |
FTLit FieldTypeLit | |
FTTypePromoted Text | |
FTApp FieldType FieldType | |
FTList FieldType |
data ReferenceDef #
There are 3 kinds of references 1) composite (to fields that exist in the record) 2) single field 3) embedded
NoReference | |
ForeignRef !EntityNameHS | A ForeignRef has a late binding to the EntityDef it references via name and has the Haskell type of the foreign key in the form of FieldType |
EmbedRef EntityNameHS | |
SelfReference | A SelfReference stops an immediate cycle which causes non-termination at compile-time (issue #311). |
Instances
data EmbedEntityDef #
An EmbedEntityDef is the same as an EntityDef But it is only used for fieldReference so it only has data needed for embedding
Instances
data EmbedFieldDef #
An EmbedFieldDef is the same as a FieldDef But it is only used for embeddedFields so it only has data needed for embedding
EmbedFieldDef | |
|
Instances
Type for storing the Uniqueness constraint in the Schema. Assume you have the following schema with a uniqueness constraint:
Person name String age Int UniqueAge age
This will be represented as:
UniqueDef { uniqueHaskell = ConstraintNameHS (packPTH UniqueAge) , uniqueDBName = ConstraintNameDB (packPTH "unique_age") , uniqueFields = [(FieldNameHS (packPTH "age"), FieldNameDB (packPTH "age"))] , uniqueAttrs = [] }
UniqueDef | |
|
data CompositeDef #
CompositeDef | |
|
Instances
type ForeignFieldDef = (FieldNameHS, FieldNameDB) #
Used instead of FieldDef to generate a smaller amount of code
data ForeignDef #
ForeignDef | |
|
Instances
data FieldCascade #
This datatype describes how a foreign reference field cascades deletes or updates.
This type is used in both parsing the model definitions and performing
migrations. A Nothing
in either of the field values means that the
user has not specified a CascadeAction
. An unspecified CascadeAction
is defaulted to Restrict
when doing migrations.
Since: persistent-2.11.0
FieldCascade | |
|
Instances
data CascadeAction #
An action that might happen on a deletion or update on a foreign key change.
Since: persistent-2.11.0
Instances
data PersistException #
PersistError Text | Generic Exception |
PersistMarshalError Text | |
PersistInvalidField Text | |
PersistForeignConstraintUnmet Text | |
PersistMongoDBError Text | |
PersistMongoDBUnsupported Text |
Instances
Exception PersistException | |
Defined in Database.Persist.Types.Base | |
Show PersistException | |
Defined in Database.Persist.Types.Base showsPrec :: Int -> PersistException -> ShowS # show :: PersistException -> String # showList :: [PersistException] -> ShowS # |
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.
SqlString | |
SqlInt32 | |
SqlInt64 | |
SqlReal | |
SqlNumeric Word32 Word32 | |
SqlBool | |
SqlDay | |
SqlTime | |
SqlDayTime | Always uses UTC timezone |
SqlBlob | |
SqlOther Text | a backend-specific name |
data PersistFilter #
Instances
Read PersistFilter | |
Defined in Database.Persist.Types.Base readsPrec :: Int -> ReadS PersistFilter # readList :: ReadS [PersistFilter] # | |
Show PersistFilter | |
Defined in Database.Persist.Types.Base showsPrec :: Int -> PersistFilter -> ShowS # show :: PersistFilter -> String # showList :: [PersistFilter] -> ShowS # | |
Lift PersistFilter | |
Defined in Database.Persist.Types.Base lift :: Quote m => PersistFilter -> m Exp # liftTyped :: forall (m :: Type -> Type). Quote m => PersistFilter -> Code m PersistFilter # |
data UpdateException #
Instances
Exception UpdateException | |
Defined in Database.Persist.Types.Base | |
Show UpdateException | |
Defined in Database.Persist.Types.Base showsPrec :: Int -> UpdateException -> ShowS # show :: UpdateException -> String # showList :: [UpdateException] -> ShowS # |
data PersistUpdate #
Instances
Read PersistUpdate | |
Defined in Database.Persist.Types.Base readsPrec :: Int -> ReadS PersistUpdate # readList :: ReadS [PersistUpdate] # | |
Show PersistUpdate | |
Defined in Database.Persist.Types.Base showsPrec :: Int -> PersistUpdate -> ShowS # show :: PersistUpdate -> String # showList :: [PersistUpdate] -> ShowS # | |
Lift PersistUpdate | |
Defined in Database.Persist.Types.Base lift :: Quote m => PersistUpdate -> m Exp # liftTyped :: forall (m :: Type -> Type). Quote m => PersistUpdate -> Code m PersistUpdate # |
A FieldDef
represents the inormation that persistent
knows about
a field of a datatype. This includes information used to parse the field
out of the database and what the field corresponds to.
FieldDef | |
|
data IsolationLevel #
Please refer to the documentation for the database in question for a full overview of the semantics of the varying isloation levels
Instances
data PersistValue #
A raw value which can be stored in any backend and can be marshalled to
and from a PersistField
.
PersistText Text | |
PersistByteString ByteString | |
PersistInt64 Int64 | |
PersistDouble Double | |
PersistRational Rational | |
PersistBool Bool | |
PersistDay Day | |
PersistTimeOfDay TimeOfDay | |
PersistUTCTime UTCTime | |
PersistNull | |
PersistList [PersistValue] | |
PersistMap [(Text, PersistValue)] | |
PersistObjectId ByteString | Intended especially for MongoDB backend |
PersistArray [PersistValue] | Intended especially for PostgreSQL backend for text arrays |
PersistLiteral_ LiteralType ByteString | This constructor is used to specify some raw literal value for the
backend. The Since: persistent-2.12.0.0 |
pattern PersistDbSpecific :: ByteString -> PersistValue | This pattern synonym used to be a data constructor for the
If you use this, it will overlap a patern match on the 'PersistLiteral_,
Since: persistent-2.12.0.0 |
pattern PersistLiteralEscaped :: ByteString -> PersistValue | This pattern synonym used to be a data constructor on Since: persistent-2.12.0.0 |
pattern PersistLiteral :: ByteString -> PersistValue | This pattern synonym used to be a data constructor on Since: persistent-2.12.0.0 |
Instances
data LiteralType #
A type that determines how a backend should handle the literal.
Since: persistent-2.12.0.0
Escaped | The accompanying value will be escaped before inserting into the database. This is the correct default choice to use. Since: persistent-2.12.0.0 |
Unescaped | The accompanying value will not be escaped when inserting into the database. This is potentially dangerous - use this with care. Since: persistent-2.12.0.0 |
DbSpecific | The Since: persistent-2.12.0.0 |
Instances
Read LiteralType | |
Defined in Database.Persist.PersistValue readsPrec :: Int -> ReadS LiteralType # readList :: ReadS [LiteralType] # readPrec :: ReadPrec LiteralType # readListPrec :: ReadPrec [LiteralType] # | |
Show LiteralType | |
Defined in Database.Persist.PersistValue showsPrec :: Int -> LiteralType -> ShowS # show :: LiteralType -> String # showList :: [LiteralType] -> ShowS # | |
Eq LiteralType | |
Defined in Database.Persist.PersistValue (==) :: LiteralType -> LiteralType -> Bool # (/=) :: LiteralType -> LiteralType -> Bool # | |
Ord LiteralType | |
Defined in Database.Persist.PersistValue compare :: LiteralType -> LiteralType -> Ordering # (<) :: LiteralType -> LiteralType -> Bool # (<=) :: LiteralType -> LiteralType -> Bool # (>) :: LiteralType -> LiteralType -> Bool # (>=) :: LiteralType -> LiteralType -> Bool # max :: LiteralType -> LiteralType -> LiteralType # min :: LiteralType -> LiteralType -> LiteralType # |
class DatabaseName a where #
Convenience operations for working with '-NameDB' types.
Since: persistent-2.12.0.0
escapeWith :: (Text -> str) -> a -> str #
Instances
DatabaseName ConstraintNameDB | Since: persistent-2.12.0.0 |
Defined in Database.Persist.Names escapeWith :: (Text -> str) -> ConstraintNameDB -> str # | |
DatabaseName EntityNameDB | |
Defined in Database.Persist.Names escapeWith :: (Text -> str) -> EntityNameDB -> str # | |
DatabaseName FieldNameDB | Since: persistent-2.12.0.0 |
Defined in Database.Persist.Names escapeWith :: (Text -> str) -> FieldNameDB -> str # |
newtype FieldNameDB #
A FieldNameDB
represents the datastore-side name that persistent
will use for a field.
Since: persistent-2.12.0.0
Instances
newtype FieldNameHS #
A FieldNameHS
represents the Haskell-side name that persistent
will use for a field.
Since: persistent-2.12.0.0
Instances
newtype EntityNameHS #
An EntityNameHS
represents the Haskell-side name that persistent
will use for an entity.
Since: persistent-2.12.0.0
Instances
newtype EntityNameDB #
An EntityNameDB
represents the datastore-side name that persistent
will use for an entity.
Since: persistent-2.12.0.0
Instances
newtype ConstraintNameDB #
A ConstraintNameDB
represents the datastore-side name that persistent
will use for a constraint.
Since: persistent-2.12.0.0
Instances
newtype ConstraintNameHS #
An ConstraintNameHS
represents the Haskell-side name that persistent
will use for a constraint.
Since: persistent-2.12.0.0
Instances
type family PersistConfigPool c #
Instances
type PersistConfigPool (Either c1 c2) | |
Defined in Database.Persist.Class.PersistConfig |
type family PersistConfigBackend c :: (Type -> Type) -> Type -> Type #
Instances
type PersistConfigBackend (Either c1 c2) | |
Defined in Database.Persist.Class.PersistConfig |
class PersistConfig c where #
Represents a value containing all the configuration options for a specific backend. This abstraction makes it easier to write code that can easily swap backends.
type PersistConfigBackend c :: (Type -> Type) -> Type -> Type #
type PersistConfigPool c #
loadConfig :: Value -> Parser c #
Load the config settings from a Value
, most likely taken from a YAML
config file.
Modify the config settings based on environment variables.
createPoolConfig :: c -> IO (PersistConfigPool c) #
Create a new connection pool based on the given config settings.
runPool :: MonadUnliftIO m => c -> PersistConfigBackend c m a -> PersistConfigPool c -> m a #
Run a database action by taking a connection from the pool.
Instances
(PersistConfig c1, PersistConfig c2, PersistConfigPool c1 ~ PersistConfigPool c2, PersistConfigBackend c1 ~ PersistConfigBackend c2) => PersistConfig (Either c1 c2) | |
Defined in Database.Persist.Class.PersistConfig type PersistConfigBackend (Either c1 c2) :: (Type -> Type) -> Type -> Type # type PersistConfigPool (Either c1 c2) # loadConfig :: Value -> Parser (Either c1 c2) # applyEnv :: Either c1 c2 -> IO (Either c1 c2) # createPoolConfig :: Either c1 c2 -> IO (PersistConfigPool (Either c1 c2)) # runPool :: MonadUnliftIO m => Either c1 c2 -> PersistConfigBackend (Either c1 c2) m a -> PersistConfigPool (Either c1 c2) -> m a # |