graphql-engine/server/src-lib/Hasura/GraphQL/Resolve/Mutation.hs

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module Hasura.GraphQL.Resolve.Mutation
( convertUpdate
, convertDelete
, convertMutResp
, buildEmptyMutResp
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) where
import Data.Has
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import Hasura.Prelude
import qualified Control.Monad.Validate as MV
import qualified Data.Aeson as J
import qualified Data.HashMap.Strict as Map
import qualified Data.HashMap.Strict.InsOrd as OMap
import qualified Data.HashMap.Strict.InsOrd.Extended as OMap
import qualified Data.Sequence.NonEmpty as NESeq
import qualified Data.Text as T
import qualified Language.GraphQL.Draft.Syntax as G
import qualified Hasura.RQL.DML.Delete as RD
import qualified Hasura.RQL.DML.Returning as RR
import qualified Hasura.RQL.DML.Update as RU
import qualified Hasura.RQL.DML.Select as RS
import qualified Hasura.SQL.DML as S
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import Hasura.EncJSON
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import Hasura.GraphQL.Resolve.BoolExp
import Hasura.GraphQL.Resolve.Context
import Hasura.GraphQL.Resolve.InputValue
import Hasura.GraphQL.Resolve.Select (fromSelSet)
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import Hasura.GraphQL.Validate.Field
import Hasura.GraphQL.Validate.Types
import Hasura.RQL.Types
import Hasura.SQL.Types
import Hasura.SQL.Value
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convertMutResp
:: ( MonadReusability m, MonadError QErr m, MonadReader r m, Has FieldMap r
, Has OrdByCtx r, Has SQLGenCtx r
)
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=> G.NamedType -> SelSet -> m (RR.MutFldsG UnresolvedVal)
convertMutResp ty selSet =
withSelSet selSet $ \fld -> case _fName fld of
"__typename" -> return $ RR.MExp $ G.unName $ G.unNamedType ty
"affected_rows" -> return RR.MCount
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"returning" -> do
annFlds <- fromSelSet (_fType fld) $ _fSelSet fld
annFldsResolved <- traverse
(traverse (RS.traverseAnnFld convertPGValueToTextValue)) annFlds
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return $ RR.MRet annFldsResolved
G.Name t -> throw500 $ "unexpected field in mutation resp : " <> t
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where
convertPGValueToTextValue = \case
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UVPG annPGVal -> UVSQL <$> txtConverter annPGVal
UVSessVar colTy sessVar -> pure $ UVSessVar colTy sessVar
UVSQL sqlExp -> pure $ UVSQL sqlExp
UVSession -> pure UVSession
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convertRowObj
:: (MonadReusability m, MonadError QErr m)
=> PGColGNameMap
-> AnnInpVal
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-> m [(PGCol, UnresolvedVal)]
convertRowObj colGNameMap val =
flip withObject val $ \_ obj ->
forM (OMap.toList obj) $ \(k, v) -> do
prepExpM <- fmap mkParameterizablePGValue <$> asPGColumnValueM v
pgCol <- pgiColumn <$> resolvePGCol colGNameMap k
let prepExp = fromMaybe (UVSQL S.SENull) prepExpM
return (pgCol, prepExp)
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type ApplySQLOp = (PGCol, S.SQLExp) -> S.SQLExp
rhsExpOp :: S.SQLOp -> S.TypeAnn -> ApplySQLOp
rhsExpOp op annTy (col, e) =
S.mkSQLOpExp op (S.SEIden $ toIden col) annExp
where
annExp = S.SETyAnn e annTy
lhsExpOp :: S.SQLOp -> S.TypeAnn -> ApplySQLOp
lhsExpOp op annTy (col, e) =
S.mkSQLOpExp op annExp $ S.SEIden $ toIden col
where
annExp = S.SETyAnn e annTy
convObjWithOp
:: (MonadReusability m, MonadError QErr m)
=> PGColGNameMap -> ApplySQLOp -> AnnInpVal -> m [(PGCol, UnresolvedVal)]
convObjWithOp colGNameMap opFn val =
flip withObject val $ \_ obj -> forM (OMap.toList obj) $ \(k, v) -> do
colVal <- openOpaqueValue =<< asPGColumnValue v
pgCol <- pgiColumn <$> resolvePGCol colGNameMap k
-- TODO: why are we using txtEncoder here?
let encVal = txtEncoder $ pstValue $ _apvValue colVal
sqlExp = opFn (pgCol, encVal)
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return (pgCol, UVSQL sqlExp)
convDeleteAtPathObj
:: (MonadReusability m, MonadError QErr m)
=> PGColGNameMap -> AnnInpVal -> m [(PGCol, UnresolvedVal)]
convDeleteAtPathObj colGNameMap val =
flip withObject val $ \_ obj -> forM (OMap.toList obj) $ \(k, v) -> do
vals <- traverse (openOpaqueValue <=< asPGColumnValue) =<< asArray v
pgCol <- pgiColumn <$> resolvePGCol colGNameMap k
let valExps = map (txtEncoder . pstValue . _apvValue) vals
annEncVal = S.SETyAnn (S.SEArray valExps) S.textArrTypeAnn
sqlExp = S.SEOpApp S.jsonbDeleteAtPathOp
[S.SEIden $ toIden pgCol, annEncVal]
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return (pgCol, UVSQL sqlExp)
convertUpdateP1
:: ( MonadReusability m, MonadError QErr m
, MonadReader r m, Has FieldMap r
, Has OrdByCtx r, Has SQLGenCtx r
)
=> UpdOpCtx -- the update context
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-> Field -- the mutation field
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-> m (RU.AnnUpdG UnresolvedVal)
convertUpdateP1 opCtx fld = do
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-- a set expression is same as a row object
setExpM <- resolveUpdateOperator "_set" $ convertRowObj colGNameMap
-- where bool expression to filter column
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whereExp <- withArg args "where" parseBoolExp
-- increment operator on integer columns
incExpM <- resolveUpdateOperator "_inc" $
convObjWithOp' $ rhsExpOp S.incOp S.intTypeAnn
-- append jsonb value
appendExpM <- resolveUpdateOperator "_append" $
convObjWithOp' $ rhsExpOp S.jsonbConcatOp S.jsonbTypeAnn
-- prepend jsonb value
prependExpM <- resolveUpdateOperator "_prepend" $
convObjWithOp' $ lhsExpOp S.jsonbConcatOp S.jsonbTypeAnn
-- delete a key in jsonb object
deleteKeyExpM <- resolveUpdateOperator "_delete_key" $
convObjWithOp' $ rhsExpOp S.jsonbDeleteOp S.textTypeAnn
-- delete an element in jsonb array
deleteElemExpM <- resolveUpdateOperator "_delete_elem" $
convObjWithOp' $ rhsExpOp S.jsonbDeleteOp S.intTypeAnn
-- delete at path in jsonb value
deleteAtPathExpM <- resolveUpdateOperator "_delete_at_path" $
convDeleteAtPathObj colGNameMap
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updateItems <- combineUpdateExpressions
[ setExpM, incExpM, appendExpM, prependExpM
, deleteKeyExpM, deleteElemExpM, deleteAtPathExpM
]
mutFlds <- convertMutResp (_fType fld) $ _fSelSet fld
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pure $ RU.AnnUpd tn updateItems (unresolvedPermFilter, whereExp) mutFlds allCols
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where
convObjWithOp' = convObjWithOp colGNameMap
allCols = Map.elems colGNameMap
UpdOpCtx tn _ colGNameMap filterExp preSetCols = opCtx
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args = _fArguments fld
resolvedPreSetItems = Map.toList $ fmap partialSQLExpToUnresolvedVal preSetCols
unresolvedPermFilter = fmapAnnBoolExp partialSQLExpToUnresolvedVal filterExp
resolveUpdateOperator operator resolveAction =
(operator,) <$> withArgM args operator resolveAction
combineUpdateExpressions updateExps = do
let allOperatorNames = map fst updateExps
updateItems = mapMaybe (\(op, itemsM) -> (op,) <$> itemsM) updateExps
-- Atleast any one of operator is expected or preset expressions shouldn't be empty
if null updateItems && null resolvedPreSetItems then
throwVE $ "atleast any one of " <> showNames allOperatorNames <> " is expected"
else do
let itemsWithOps = concatMap (\(op, items) -> map (second (op,)) items) updateItems
validateMultiOps col items = do
when (length items > 1) $ MV.dispute [(col, map fst $ toList items)]
pure $ snd $ NESeq.head items
eitherResult = MV.runValidate $ OMap.traverseWithKey validateMultiOps $
OMap.groupTuples itemsWithOps
case eitherResult of
-- A column shouldn't be present in more than one operator.
-- If present, then generated UPDATE statement throws unexpected query error
Left columnsWithMultiOps -> throwVE $
"column found in multiple operators; "
<> T.intercalate ". "
(map (\(col, ops) -> col <<> " in " <> showNames ops)
columnsWithMultiOps)
Right items -> pure $ resolvedPreSetItems <> OMap.toList items
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convertUpdate
:: ( MonadReusability m, MonadError QErr m
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, MonadReader r m, Has FieldMap r
, Has OrdByCtx r, Has SQLGenCtx r
)
=> UpdOpCtx -- the update context
-> Field -- the mutation field
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-> m RespTx
convertUpdate opCtx fld = do
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annUpdUnresolved <- convertUpdateP1 opCtx fld
(annUpdResolved, prepArgs) <- withPrepArgs $ RU.traverseAnnUpd
resolveValPrep annUpdUnresolved
strfyNum <- stringifyNum <$> asks getter
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let whenNonEmptyItems = return $ RU.updateQueryToTx strfyNum
(annUpdResolved, prepArgs)
whenEmptyItems = return $ return $
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buildEmptyMutResp $ RU.uqp1MutFlds annUpdResolved
-- if there are not set items then do not perform
-- update and return empty mutation response
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bool whenNonEmptyItems whenEmptyItems $ null $ RU.uqp1SetExps annUpdResolved
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convertDelete
:: ( MonadReusability m, MonadError QErr m
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, MonadReader r m, Has FieldMap r
, Has OrdByCtx r, Has SQLGenCtx r
)
=> DelOpCtx -- the delete context
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-> Field -- the mutation field
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-> m RespTx
convertDelete opCtx fld = do
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whereExp <- withArg (_fArguments fld) "where" parseBoolExp
mutFlds <- convertMutResp (_fType fld) $ _fSelSet fld
let unresolvedPermFltr =
fmapAnnBoolExp partialSQLExpToUnresolvedVal filterExp
annDelUnresolved = RD.AnnDel tn (unresolvedPermFltr, whereExp)
mutFlds allCols
(annDelResolved, prepArgs) <- withPrepArgs $ RD.traverseAnnDel
resolveValPrep annDelUnresolved
strfyNum <- stringifyNum <$> asks getter
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return $ RD.deleteQueryToTx strfyNum (annDelResolved, prepArgs)
where
DelOpCtx tn _ filterExp allCols = opCtx
-- | build mutation response for empty objects
buildEmptyMutResp :: RR.MutFlds -> EncJSON
buildEmptyMutResp = mkTx
where
mkTx = encJFromJValue . OMap.fromList . map (second convMutFld)
-- generate empty mutation response
convMutFld = \case
RR.MCount -> J.toJSON (0 :: Int)
RR.MExp e -> J.toJSON e
RR.MRet _ -> J.toJSON ([] :: [J.Value])