{-# LANGUAGE ApplicativeDo #-} {-# LANGUAGE TemplateHaskellQuotes #-} {-# OPTIONS_GHC -fno-warn-orphans #-} -- | MSSQL Instances Schema -- -- Defines a 'Hasura.GraphQL.Schema.Backend.BackendSchema' type class instance for MSSQL. module Hasura.Backends.MSSQL.Instances.Schema () where import Data.Char qualified as Char import Data.HashMap.Strict qualified as Map import Data.List.NonEmpty qualified as NE import Data.Text qualified as T import Data.Text.Encoding as TE import Data.Text.Extended import Database.ODBC.SQLServer qualified as ODBC import Hasura.Backends.MSSQL.Schema.IfMatched import Hasura.Backends.MSSQL.Types.Insert (BackendInsert (..)) import Hasura.Backends.MSSQL.Types.Internal qualified as MSSQL import Hasura.Backends.MSSQL.Types.Update (UpdateOperator (..)) import Hasura.Base.Error import Hasura.Base.ErrorMessage (toErrorMessage) import Hasura.GraphQL.Schema.Backend import Hasura.GraphQL.Schema.BoolExp import Hasura.GraphQL.Schema.Build qualified as GSB import Hasura.GraphQL.Schema.Common import Hasura.GraphQL.Schema.NamingCase import Hasura.GraphQL.Schema.Parser ( InputFieldsParser, Kind (..), MonadParse, Parser, ) import Hasura.GraphQL.Schema.Parser qualified as P import Hasura.GraphQL.Schema.Select import Hasura.GraphQL.Schema.Update qualified as SU import Hasura.Name qualified as Name import Hasura.NativeQuery.Schema qualified as NativeQueries import Hasura.Prelude import Hasura.RQL.IR import Hasura.RQL.IR.Select qualified as IR import Hasura.RQL.Types.Backend hiding (BackendInsert) import Hasura.RQL.Types.BackendType import Hasura.RQL.Types.Column import Hasura.RQL.Types.Schema.Options qualified as Options import Hasura.RQL.Types.SchemaCache import Hasura.RQL.Types.Source import Hasura.RQL.Types.SourceCustomization import Language.GraphQL.Draft.Syntax qualified as G ---------------------------------------------------------------- -- * BackendSchema instance instance BackendSchema 'MSSQL where -- top level parsers buildTableQueryAndSubscriptionFields = GSB.buildTableQueryAndSubscriptionFields buildTableRelayQueryFields _ _ _ _ _ = pure [] buildTableStreamingSubscriptionFields = GSB.buildTableStreamingSubscriptionFields buildTableInsertMutationFields = GSB.buildTableInsertMutationFields backendInsertParser buildTableDeleteMutationFields = GSB.buildTableDeleteMutationFields buildTableUpdateMutationFields = GSB.buildSingleBatchTableUpdateMutationFields id buildNativeQueryRootFields = NativeQueries.defaultBuildNativeQueryRootFields buildFunctionQueryFields _ _ _ _ = pure [] buildFunctionRelayQueryFields _ _ _ _ _ = pure [] buildFunctionMutationFields _ _ _ _ = pure [] -- backend extensions relayExtension = Nothing nodesAggExtension = Just () streamSubscriptionExtension = Nothing -- When we support nested inserts, we also need to ensure we limit ourselves -- to inserting into tables whch supports inserts: {- import Hasura.GraphQL.Schema.Mutation qualified as GSB runMaybeT $ do let otherTableName = riRTable relationshipInfo otherTableInfo <- lift $ askTableInfo sourceName otherTableName guard (supportsInserts otherTableInfo) -} mkRelationshipParser _ = pure Nothing -- individual components columnParser = msColumnParser enumParser = msEnumParser possiblyNullable = msPossiblyNullable scalarSelectionArgumentsParser _ = pure Nothing orderByOperators _sourceInfo = msOrderByOperators comparisonExps = msComparisonExps countTypeInput = msCountTypeInput aggregateOrderByCountType = MSSQL.IntegerType computedField _ _ _ = pure Nothing instance BackendTableSelectSchema 'MSSQL where tableArguments = msTableArgs selectTable = defaultSelectTable selectTableAggregate = defaultSelectTableAggregate tableSelectionSet = defaultTableSelectionSet instance BackendLogicalModelSelectSchema 'MSSQL where logicalModelArguments = defaultLogicalModelArgs logicalModelSelectionSet = defaultLogicalModelSelectionSet instance BackendUpdateOperatorsSchema 'MSSQL where type UpdateOperators 'MSSQL = UpdateOperator parseUpdateOperators = msParseUpdateOperators ---------------------------------------------------------------- -- * Top level parsers backendInsertParser :: forall m r n. MonadBuildSchema 'MSSQL r m n => TableInfo 'MSSQL -> SchemaT r m (InputFieldsParser n (BackendInsert (UnpreparedValue 'MSSQL))) backendInsertParser tableInfo = do ifMatched <- ifMatchedFieldParser tableInfo let _biIdentityColumns = _tciExtraTableMetadata $ _tiCoreInfo tableInfo pure $ do _biIfMatched <- ifMatched pure $ BackendInsert {..} ---------------------------------------------------------------- -- * Table arguments msTableArgs :: forall r m n. MonadBuildSchema 'MSSQL r m n => TableInfo 'MSSQL -> SchemaT r m (InputFieldsParser n (IR.SelectArgsG 'MSSQL (UnpreparedValue 'MSSQL))) msTableArgs tableInfo = do whereParser <- tableWhereArg tableInfo orderByParser <- tableOrderByArg tableInfo pure do whereArg <- whereParser orderByArg <- orderByParser limitArg <- tableLimitArg offsetArg <- tableOffsetArg pure $ IR.SelectArgs { IR._saWhere = whereArg, IR._saOrderBy = orderByArg, IR._saLimit = limitArg, IR._saOffset = offsetArg, -- not supported on MSSQL for now IR._saDistinct = Nothing } ---------------------------------------------------------------- -- * Individual components msColumnParser :: MonadBuildSchema 'MSSQL r m n => ColumnType 'MSSQL -> G.Nullability -> SchemaT r m (Parser 'Both n (ValueWithOrigin (ColumnValue 'MSSQL))) msColumnParser columnType nullability = case columnType of -- TODO: the mapping here is not consistent with mkMSSQLScalarTypeName. For -- example, exposing all the float types as a GraphQL Float type is -- incorrect, similarly exposing all the integer types as a GraphQL Int ColumnScalar scalarType -> P.memoizeOn 'msColumnParser (scalarType, nullability) $ peelWithOrigin . fmap (ColumnValue columnType) . msPossiblyNullable scalarType nullability <$> case scalarType of -- text MSSQL.CharType -> pure $ mkCharValue <$> P.string MSSQL.VarcharType -> pure $ mkCharValue <$> P.string MSSQL.WcharType -> pure $ ODBC.TextValue <$> P.string MSSQL.WvarcharType -> pure $ ODBC.TextValue <$> P.string MSSQL.WtextType -> pure $ ODBC.TextValue <$> P.string MSSQL.TextType -> pure $ ODBC.TextValue <$> P.string -- integer MSSQL.IntegerType -> pure $ ODBC.IntValue . fromIntegral <$> P.int MSSQL.SmallintType -> pure $ ODBC.IntValue . fromIntegral <$> P.int MSSQL.BigintType -> pure $ ODBC.IntValue . fromIntegral <$> P.int MSSQL.TinyintType -> pure $ ODBC.IntValue . fromIntegral <$> P.int -- float MSSQL.NumericType -> pure $ ODBC.DoubleValue <$> P.float MSSQL.DecimalType -> pure $ ODBC.DoubleValue <$> P.float MSSQL.FloatType -> pure $ ODBC.DoubleValue <$> P.float MSSQL.RealType -> pure $ ODBC.DoubleValue <$> P.float -- boolean MSSQL.BitType -> pure $ ODBC.BoolValue <$> P.boolean _ -> do name <- MSSQL.mkMSSQLScalarTypeName scalarType let schemaType = P.TNamed P.NonNullable $ P.Definition name Nothing Nothing [] P.TIScalar pure $ P.Parser { pType = schemaType, pParser = P.valueToJSON (P.toGraphQLType schemaType) >=> either (P.parseErrorWith P.ParseFailed . toErrorMessage . qeError) pure . (MSSQL.parseScalarValue scalarType) } ColumnEnumReference (EnumReference tableName enumValues customTableName) -> case nonEmpty (Map.toList enumValues) of Just enumValuesList -> peelWithOrigin . fmap (ColumnValue columnType) <$> msEnumParser tableName enumValuesList customTableName nullability Nothing -> throw400 ValidationFailed "empty enum values" where -- CHAR/VARCHAR in MSSQL _can_ represent the full UCS (Universal Coded Character Set), -- but might not always if the collation used is not UTF-8 enabled -- https://docs.microsoft.com/en-us/sql/t-sql/data-types/char-and-varchar-transact-sql?view=sql-server-ver16 -- -- NCHAR/NVARCHAR in MSSQL are always able to represent the full UCS -- https://docs.microsoft.com/en-us/sql/t-sql/data-types/nchar-and-nvarchar-transact-sql?view=sql-server-ver16 -- -- We'd prefer to encode as CHAR/VARCHAR literals to CHAR/VARCHAR columns, as this -- means better index performance, BUT as we don't know what the collation -- the column is set to (an example is 'SQL_Latin1_General_CP437_BIN') and thus -- what characters are available in order to do this safely. -- -- Therefore, we are conservative and only convert on the HGE side when the -- characters are all ASCII and guaranteed to be in the target character -- set, if not we pass an NCHAR/NVARCHAR and let MSSQL implicitly convert it. -- resolves https://github.com/hasura/graphql-engine/issues/8735 mkCharValue :: Text -> ODBC.Value mkCharValue txt = if T.all Char.isAscii txt then ODBC.ByteStringValue (TE.encodeUtf8 txt) -- an ODBC.ByteStringValue becomes a VARCHAR else ODBC.TextValue txt -- an ODBC.TextValue becomes an NVARCHAR msEnumParser :: MonadBuildSchema 'MSSQL r m n => TableName 'MSSQL -> NonEmpty (EnumValue, EnumValueInfo) -> Maybe G.Name -> G.Nullability -> SchemaT r m (Parser 'Both n (ScalarValue 'MSSQL)) msEnumParser tableName enumValues customTableName nullability = do enumName <- mkEnumTypeName @'MSSQL tableName customTableName pure $ msPossiblyNullable MSSQL.VarcharType nullability $ P.enum enumName Nothing (mkEnumValue <$> enumValues) where mkEnumValue :: (EnumValue, EnumValueInfo) -> (P.Definition P.EnumValueInfo, ScalarValue 'MSSQL) mkEnumValue (EnumValue value, EnumValueInfo description) = ( P.Definition value (G.Description <$> description) Nothing [] P.EnumValueInfo, ODBC.TextValue $ G.unName value ) msPossiblyNullable :: (MonadParse m) => ScalarType 'MSSQL -> G.Nullability -> Parser 'Both m (ScalarValue 'MSSQL) -> Parser 'Both m (ScalarValue 'MSSQL) msPossiblyNullable _scalarType (G.Nullability isNullable) | isNullable = fmap (fromMaybe ODBC.NullValue) . P.nullable | otherwise = id msOrderByOperators :: NamingCase -> ( G.Name, NonEmpty ( P.Definition P.EnumValueInfo, (BasicOrderType 'MSSQL, NullsOrderType 'MSSQL) ) ) msOrderByOperators _tCase = (Name._order_by,) $ -- NOTE: NamingCase is not being used here as we don't support naming conventions for this DB NE.fromList [ ( define Name._asc "in ascending order, nulls first", (MSSQL.AscOrder, MSSQL.NullsFirst) ), ( define Name._asc_nulls_first "in ascending order, nulls first", (MSSQL.AscOrder, MSSQL.NullsFirst) ), ( define Name._asc_nulls_last "in ascending order, nulls last", (MSSQL.AscOrder, MSSQL.NullsLast) ), ( define Name._desc "in descending order, nulls last", (MSSQL.DescOrder, MSSQL.NullsLast) ), ( define Name._desc_nulls_first "in descending order, nulls first", (MSSQL.DescOrder, MSSQL.NullsFirst) ), ( define Name._desc_nulls_last "in descending order, nulls last", (MSSQL.DescOrder, MSSQL.NullsLast) ) ] where define name desc = P.Definition name (Just desc) Nothing [] P.EnumValueInfo msComparisonExps :: forall m n r. MonadBuildSchema 'MSSQL r m n => ColumnType 'MSSQL -> SchemaT r m (Parser 'Input n [ComparisonExp 'MSSQL]) msComparisonExps = P.memoize 'comparisonExps \columnType -> do -- see Note [Columns in comparison expression are never nullable] collapseIfNull <- retrieve Options.soDangerousBooleanCollapse -- parsers used for individual values typedParser <- columnParser columnType (G.Nullability False) let columnListParser = fmap openValueOrigin <$> P.list typedParser -- field info let name = P.getName typedParser <> Name.__MSSQL_comparison_exp desc = G.Description $ "Boolean expression to compare columns of type " <> P.getName typedParser <<> ". All fields are combined with logical 'AND'." -- Naming convention tCase <- retrieve $ _rscNamingConvention . _siCustomization @'MSSQL pure $ P.object name (Just desc) $ fmap catMaybes $ sequenceA $ concat [ -- Common ops for all types equalityOperators tCase collapseIfNull (mkParameter <$> typedParser) (mkListLiteral <$> columnListParser), comparisonOperators tCase collapseIfNull (mkParameter <$> typedParser), -- Ops for String like types guard (isScalarColumnWhere (`elem` MSSQL.stringTypes) columnType) *> [ P.fieldOptional Name.__like (Just "does the column match the given pattern") (ALIKE . mkParameter <$> typedParser), P.fieldOptional Name.__nlike (Just "does the column NOT match the given pattern") (ANLIKE . mkParameter <$> typedParser) ], -- Ops for Geometry/Geography types guard (isScalarColumnWhere (`elem` MSSQL.geoTypes) columnType) *> [ P.fieldOptional Name.__st_contains (Just "does the column contain the given value") (ABackendSpecific . MSSQL.ASTContains . mkParameter <$> typedParser), P.fieldOptional Name.__st_equals (Just "is the column equal to given value (directionality is ignored)") (ABackendSpecific . MSSQL.ASTEquals . mkParameter <$> typedParser), P.fieldOptional Name.__st_intersects (Just "does the column spatially intersect the given value") (ABackendSpecific . MSSQL.ASTIntersects . mkParameter <$> typedParser), P.fieldOptional Name.__st_overlaps (Just "does the column 'spatially overlap' (intersect but not completely contain) the given value") (ABackendSpecific . MSSQL.ASTOverlaps . mkParameter <$> typedParser), P.fieldOptional Name.__st_within (Just "is the column contained in the given value") (ABackendSpecific . MSSQL.ASTWithin . mkParameter <$> typedParser) ], -- Ops for Geometry types guard (isScalarColumnWhere (MSSQL.GeometryType ==) columnType) *> [ P.fieldOptional Name.__st_crosses (Just "does the column cross the given geometry value") (ABackendSpecific . MSSQL.ASTCrosses . mkParameter <$> typedParser), P.fieldOptional Name.__st_touches (Just "does the column have at least one point in common with the given geometry value") (ABackendSpecific . MSSQL.ASTTouches . mkParameter <$> typedParser) ] ] where mkListLiteral :: [ColumnValue 'MSSQL] -> UnpreparedValue 'MSSQL mkListLiteral = UVLiteral . MSSQL.ListExpression . fmap (MSSQL.ValueExpression . cvValue) msCountTypeInput :: MonadParse n => Maybe (Parser 'Both n (Column 'MSSQL)) -> InputFieldsParser n (IR.CountDistinct -> CountType 'MSSQL) msCountTypeInput = \case Just columnEnum -> do column <- P.fieldOptional Name._column Nothing columnEnum pure $ flip mkCountType column Nothing -> pure $ flip mkCountType Nothing where mkCountType :: IR.CountDistinct -> Maybe (Column 'MSSQL) -> CountType 'MSSQL mkCountType _ Nothing = MSSQL.StarCountable mkCountType IR.SelectCountDistinct (Just col) = MSSQL.DistinctCountable col mkCountType IR.SelectCountNonDistinct (Just col) = MSSQL.NonNullFieldCountable col msParseUpdateOperators :: forall m n r. MonadBuildSchema 'MSSQL r m n => TableInfo 'MSSQL -> UpdPermInfo 'MSSQL -> SchemaT r m (InputFieldsParser n (HashMap (Column 'MSSQL) (UpdateOperators 'MSSQL (UnpreparedValue 'MSSQL)))) msParseUpdateOperators tableInfo updatePermissions = do SU.buildUpdateOperators (UpdateSet <$> SU.presetColumns updatePermissions) [ UpdateSet <$> SU.setOp, UpdateInc <$> SU.incOp ] tableInfo