graphql-engine/server/src-lib/Hasura/GraphQL/Schema.hs
Rakesh Emmadi dc31b835e1
allow reusing Postgres scalars in custom types & actions (close #4125) (#4333)
* allow re-using Postgres scalars in custom types, close #4125

* add pytest tests

* update CHANGELOG.md

* add a doc pointer for reusable postgres scalars

* document the code, improve the CHANGELOG entry

As suggested by @lexi-lambda

* a bit more source code documentation, use WriterT to collect reused scalars

* Apply suggestions from code review

Co-Authored-By: Marion Schleifer <marion@hasura.io>

* improve doc for Postgres scalars in custom graphql types

* Add some more references to Note; fix Haddock syntax

Also a few very minor tweaks:
  * Use HashSet instead of [] more pervasively
  * Export execWriterT from Hasura.Prelude
  * Use pattern guards in multi-way if
  * Tweak a few names/comments

* Pull buildActions out of buildAndCollectInfo, use buildInfoMap

* Tweak wording in documentation

* incorporate changes in console code

* account Postgres scalars for action input arguments

-> Avoid unnecessary 'throw500' in making action schema

* Review changes

Co-authored-by: Marion Schleifer <marion@hasura.io>
Co-authored-by: Alexis King <lexi.lambda@gmail.com>
Co-authored-by: Vamshi Surabhi <0x777@users.noreply.github.com>
Co-authored-by: Aleksandra Sikora <ola.zxcvbnm@gmail.com>
2020-04-15 17:33:13 +05:30

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module Hasura.GraphQL.Schema
( mkGCtxMap
, GCtxMap
, getGCtx
, GCtx(..)
, QueryCtx(..)
, MutationCtx(..)
, InsCtx(..)
, InsCtxMap
, RelationInfoMap
, isAggFld
, qualObjectToName
, ppGCtx
, checkConflictingNode
, checkSchemaConflicts
) where
import Control.Lens.Extended hiding (op)
import qualified Data.HashMap.Strict as Map
import qualified Data.HashSet as Set
import qualified Data.Sequence as Seq
import qualified Data.Text as T
import qualified Language.GraphQL.Draft.Syntax as G
import Hasura.GraphQL.Context
import Hasura.GraphQL.Resolve.Types
import Hasura.GraphQL.Validate.Types
import Hasura.Prelude
import Hasura.RQL.DML.Internal (mkAdminRolePermInfo)
import Hasura.RQL.Types
import Hasura.Server.Utils (duplicates)
import Hasura.SQL.Types
import Hasura.GraphQL.Schema.Action
import Hasura.GraphQL.Schema.BoolExp
import Hasura.GraphQL.Schema.Builder
import Hasura.GraphQL.Schema.Common
import Hasura.GraphQL.Schema.Function
import Hasura.GraphQL.Schema.Merge
import Hasura.GraphQL.Schema.Mutation.Common
import Hasura.GraphQL.Schema.Mutation.Delete
import Hasura.GraphQL.Schema.Mutation.Insert
import Hasura.GraphQL.Schema.Mutation.Update
import Hasura.GraphQL.Schema.OrderBy
import Hasura.GraphQL.Schema.Select
getInsPerm :: TableInfo -> RoleName -> Maybe InsPermInfo
getInsPerm tabInfo role
| role == adminRole = _permIns $ mkAdminRolePermInfo (_tiCoreInfo tabInfo)
| otherwise = Map.lookup role rolePermInfoMap >>= _permIns
where
rolePermInfoMap = _tiRolePermInfoMap tabInfo
getTabInfo
:: MonadError QErr m
=> TableCache -> QualifiedTable -> m TableInfo
getTabInfo tc t =
onNothing (Map.lookup t tc) $
throw500 $ "table not found: " <>> t
isValidObjectName :: (ToTxt a) => QualifiedObject a -> Bool
isValidObjectName = G.isValidName . qualObjectToName
isValidCol :: PGColumnInfo -> Bool
isValidCol = G.isValidName . pgiName
isValidRel :: ToTxt a => RelName -> QualifiedObject a -> Bool
isValidRel rn rt = G.isValidName (mkRelName rn) && isValidObjectName rt
upsertable :: [ConstraintName] -> Bool -> Bool -> Bool
upsertable uniqueOrPrimaryCons isUpsertAllowed isAView =
not (null uniqueOrPrimaryCons) && isUpsertAllowed && not isAView
getValidCols
:: FieldInfoMap FieldInfo -> [PGColumnInfo]
getValidCols = filter isValidCol . getCols
getValidRels :: FieldInfoMap FieldInfo -> [RelInfo]
getValidRels = filter isValidRel' . getRels
where
isValidRel' (RelInfo rn _ _ remTab _) = isValidRel rn remTab
mkValidConstraints :: [ConstraintName] -> [ConstraintName]
mkValidConstraints =
filter (G.isValidName . G.Name . getConstraintTxt)
isRelNullable
:: FieldInfoMap FieldInfo -> RelInfo -> Bool
isRelNullable fim ri = isNullable
where
lCols = Map.keys $ riMapping ri
allCols = getValidCols fim
lColInfos = getColInfos lCols allCols
isNullable = any pgiIsNullable lColInfos
mkPGColGNameMap :: [PGColumnInfo] -> PGColGNameMap
mkPGColGNameMap cols = Map.fromList $
flip map cols $ \ci -> (pgiName ci, ci)
numAggOps :: [G.Name]
numAggOps = [ "sum", "avg", "stddev", "stddev_samp", "stddev_pop"
, "variance", "var_samp", "var_pop"
]
compAggOps :: [G.Name]
compAggOps = ["max", "min"]
isAggFld :: G.Name -> Bool
isAggFld = flip elem (numAggOps <> compAggOps)
mkComputedFieldFunctionArgSeq :: Seq.Seq FunctionArg -> ComputedFieldFunctionArgSeq
mkComputedFieldFunctionArgSeq inputArgs =
Seq.fromList $ procFuncArgs inputArgs faName $
\fa t -> FunctionArgItem (G.Name t) (faName fa) (faHasDefault fa)
mkGCtxRole'
:: QualifiedTable
-> Maybe PGDescription
-- ^ Postgres description
-> Maybe ([PGColumnInfo], RelationInfoMap)
-- ^ insert permission
-> Maybe (Bool, [SelField])
-- ^ select permission
-> Maybe [PGColumnInfo]
-- ^ update cols
-> Maybe ()
-- ^ delete cols
-> Maybe (PrimaryKey PGColumnInfo)
-> [ConstraintName]
-- ^ constraints
-> Maybe ViewInfo
-> [FunctionInfo]
-- ^ all functions
-> TyAgg
mkGCtxRole' tn descM insPermM selPermM updColsM delPermM pkeyCols constraints viM funcs =
TyAgg (mkTyInfoMap allTypes) fieldMap scalars ordByCtx
where
ordByCtx = fromMaybe Map.empty ordByCtxM
upsertPerm = isJust updColsM
isUpsertable = upsertable constraints upsertPerm $ isJust viM
updatableCols = maybe [] (map pgiName) updColsM
onConflictTypes = mkOnConflictTypes tn constraints updatableCols isUpsertable
jsonOpTys = fromMaybe [] updJSONOpInpObjTysM
relInsInpObjTys = maybe [] (map TIInpObj) $
mutHelper viIsInsertable relInsInpObjsM
funcInpArgTys = bool [] (map TIInpObj funcArgInpObjs) $ isJust selFldsM
allTypes = relInsInpObjTys <> onConflictTypes <> jsonOpTys
<> queryTypes <> aggQueryTypes <> mutationTypes
<> funcInpArgTys <> referencedEnumTypes <> computedFieldFuncArgsInps
queryTypes = catMaybes
[ TIInpObj <$> boolExpInpObjM
, TIInpObj <$> ordByInpObjM
, TIObj <$> selObjM
]
aggQueryTypes = map TIObj aggObjs <> map TIInpObj aggOrdByInps
mutationTypes = catMaybes
[ TIInpObj <$> mutHelper viIsInsertable insInpObjM
, TIInpObj <$> mutHelper viIsUpdatable updSetInpObjM
, TIInpObj <$> mutHelper viIsUpdatable updIncInpObjM
, TIInpObj <$> mutHelper viIsUpdatable primaryKeysInpObjM
, TIObj <$> mutRespObjM
, TIEnum <$> selColInpTyM
]
mutHelper :: (ViewInfo -> Bool) -> Maybe a -> Maybe a
mutHelper f objM = bool Nothing objM $ isMutable f viM
fieldMap = Map.unions $ catMaybes
[ insInpObjFldsM, updSetInpObjFldsM
, boolExpInpObjFldsM , selObjFldsM
]
scalars = selByPkScalarSet <> funcArgScalarSet <> computedFieldFuncArgScalars
-- helper
mkColFldMap ty cols = Map.fromList $ flip map cols $
\ci -> ((ty, pgiName ci), RFPGColumn ci)
-- insert input type
insInpObjM = uncurry (mkInsInp tn) <$> insPermM
-- column fields used in insert input object
insInpObjFldsM = (mkColFldMap (mkInsInpTy tn) . fst) <$> insPermM
-- relationship input objects
relInsInpObjsM = const (mkRelInsInps tn isUpsertable) <$> insPermM
-- update set input type
updSetInpObjM = mkUpdSetInp tn <$> updColsM
-- update increment input type
updIncInpObjM = mkUpdIncInp tn updColsM
-- update json operator input type
updJSONOpInpObjsM = mkUpdJSONOpInp tn <$> updColsM
updJSONOpInpObjTysM = map TIInpObj <$> updJSONOpInpObjsM
-- fields used in set input object
updSetInpObjFldsM = mkColFldMap (mkUpdSetTy tn) <$> updColsM
-- primary key columns input object for update_by_pk
primaryKeysInpObjM = guard (isJust selPermM) *> (mkPKeyColumnsInpObj tn <$> pkeyCols)
selFldsM = snd <$> selPermM
selColNamesM = (map pgiName . getPGColumnFields) <$> selFldsM
selColInpTyM = mkSelColumnTy tn <$> selColNamesM
-- boolexp input type
boolExpInpObjM = case selFldsM of
Just selFlds -> Just $ mkBoolExpInp tn selFlds
-- no select permission
Nothing ->
-- but update/delete is defined
if isJust updColsM || isJust delPermM
then Just $ mkBoolExpInp tn []
else Nothing
-- funcargs input type
funcArgInpObjs = flip mapMaybe funcs $ \func ->
mkFuncArgsInp (fiName func) (getInputArgs func)
-- funcArgCtx = Map.unions funcArgCtxs
funcArgScalarSet = funcs ^.. folded.to getInputArgs.folded.to (_qptName.faType)
-- helper
mkFldMap ty = Map.fromList . concatMap (mkFld ty)
mkFld ty = \case
SFPGColumn ci -> [((ty, pgiName ci), RFPGColumn ci)]
SFRelationship (RelationshipFieldInfo relInfo allowAgg cols permFilter permLimit _) ->
let relationshipName = riName relInfo
relFld = ( (ty, mkRelName relationshipName)
, RFRelationship $ RelationshipField relInfo False cols permFilter permLimit
)
aggRelFld = ( (ty, mkAggRelName relationshipName)
, RFRelationship $ RelationshipField relInfo True cols permFilter permLimit
)
in case riType relInfo of
ObjRel -> [relFld]
ArrRel -> bool [relFld] [relFld, aggRelFld] allowAgg
SFComputedField cf -> pure
( (ty, mkComputedFieldName $ _cfName cf)
, RFComputedField cf
)
-- the fields used in bool exp
boolExpInpObjFldsM = mkFldMap (mkBoolExpTy tn) <$> selFldsM
-- mut resp obj
mutRespObjM =
if isMut
then Just $ mkMutRespObj tn $ isJust selFldsM
else Nothing
isMut = (isJust insPermM || isJust updColsM || isJust delPermM)
&& any (`isMutable` viM) [viIsInsertable, viIsUpdatable, viIsDeletable]
-- table obj
selObjM = mkTableObj tn descM <$> selFldsM
-- aggregate objs and order by inputs
(aggObjs, aggOrdByInps) = case selPermM of
Just (True, selFlds) ->
let cols = getPGColumnFields selFlds
numCols = onlyNumCols cols
compCols = onlyComparableCols cols
objs = [ mkTableAggObj tn
, mkTableAggFldsObj tn (numCols, numAggOps) (compCols, compAggOps)
] <> mkColAggFldsObjs selFlds
ordByInps = mkTabAggOrdByInpObj tn (numCols, numAggOps) (compCols, compAggOps)
: mkTabAggOpOrdByInpObjs tn (numCols, numAggOps) (compCols, compAggOps)
in (objs, ordByInps)
_ -> ([], [])
getNumericCols = onlyNumCols . getPGColumnFields
getComparableCols = onlyComparableCols . getPGColumnFields
onlyFloat = const $ mkScalarTy PGFloat
mkTypeMaker "sum" = mkColumnType
mkTypeMaker _ = onlyFloat
mkColAggFldsObjs flds =
let numCols = getNumericCols flds
compCols = getComparableCols flds
mkNumObjFld n = mkTableColAggFldsObj tn n (mkTypeMaker n) numCols
mkCompObjFld n = mkTableColAggFldsObj tn n mkColumnType compCols
numFldsObjs = bool (map mkNumObjFld numAggOps) [] $ null numCols
compFldsObjs = bool (map mkCompObjFld compAggOps) [] $ null compCols
in numFldsObjs <> compFldsObjs
-- the fields used in table object
selObjFldsM = mkFldMap (mkTableTy tn) <$> selFldsM
-- the scalar set for table_by_pk arguments
selByPkScalarSet = pkeyCols ^.. folded.to _pkColumns.folded.to pgiType._PGColumnScalar
ordByInpCtxM = mkOrdByInpObj tn <$> selFldsM
(ordByInpObjM, ordByCtxM) = case ordByInpCtxM of
Just (a, b) -> (Just a, Just b)
Nothing -> (Nothing, Nothing)
-- the types for all enums that are /referenced/ by this table (not /defined/ by this table;
-- there isnt actually any need to generate a GraphQL enum type for an enum table if its
-- never referenced anywhere else)
referencedEnumTypes =
let allColumnInfos =
(selPermM ^.. _Just._2.traverse._SFPGColumn)
<> (insPermM ^. _Just._1)
<> (updColsM ^. _Just)
allEnumReferences = allColumnInfos ^.. traverse.to pgiType._PGColumnEnumReference
in flip map allEnumReferences $ \enumReference@(EnumReference referencedTableName _) ->
let typeName = mkTableEnumType referencedTableName
in TIEnum $ mkHsraEnumTyInfo Nothing typeName (EnumValuesReference enumReference)
-- computed fields' function args input objects and scalar types
mkComputedFieldRequiredTypes computedFieldInfo =
let ComputedFieldFunction qf inputArgs _ _ = _cfFunction computedFieldInfo
scalarArgs = map (_qptName . faType) $ toList inputArgs
in (, scalarArgs) <$> mkFuncArgsInp qf inputArgs
computedFieldReqTypes = catMaybes $
maybe [] (map mkComputedFieldRequiredTypes . getComputedFields) selFldsM
computedFieldFuncArgsInps = map (TIInpObj . fst) computedFieldReqTypes
computedFieldFuncArgScalars = Set.fromList $ concatMap snd computedFieldReqTypes
getRootFldsRole'
:: QualifiedTable
-> Maybe (PrimaryKey PGColumnInfo)
-> [ConstraintName]
-> FieldInfoMap FieldInfo
-> [FunctionInfo]
-> Maybe ([T.Text], Bool) -- insert perm
-> Maybe (AnnBoolExpPartialSQL, Maybe Int, [T.Text], Bool) -- select filter
-> Maybe ([PGColumnInfo], PreSetColsPartial, AnnBoolExpPartialSQL, Maybe AnnBoolExpPartialSQL, [T.Text]) -- update filter
-> Maybe (AnnBoolExpPartialSQL, [T.Text]) -- delete filter
-> Maybe ViewInfo
-> TableConfig -- custom config
-> RootFields
getRootFldsRole' tn primaryKey constraints fields funcs insM
selM updM delM viM tableConfig =
RootFields
{ _rootQueryFields = makeFieldMap $
funcQueries
<> funcAggQueries
<> catMaybes
[ getSelDet <$> selM
, getSelAggDet selM
, getPKeySelDet <$> selM <*> primaryKey
]
, _rootMutationFields = makeFieldMap $ catMaybes
[ mutHelper viIsInsertable getInsDet insM
, onlyIfSelectPermExist $ mutHelper viIsInsertable getInsOneDet insM
, mutHelper viIsUpdatable getUpdDet updM
, onlyIfSelectPermExist $ mutHelper viIsUpdatable getUpdByPkDet $ (,) <$> updM <*> primaryKey
, mutHelper viIsDeletable getDelDet delM
, onlyIfSelectPermExist $ mutHelper viIsDeletable getDelByPkDet $ (,) <$> delM <*> primaryKey
]
}
where
makeFieldMap = mapFromL (_fiName . snd)
customRootFields = _tcCustomRootFields tableConfig
colGNameMap = mkPGColGNameMap $ getCols fields
funcQueries = maybe [] getFuncQueryFlds selM
funcAggQueries = maybe [] getFuncAggQueryFlds selM
mutHelper :: (ViewInfo -> Bool) -> (a -> b) -> Maybe a -> Maybe b
mutHelper f getDet mutM =
bool Nothing (getDet <$> mutM) $ isMutable f viM
onlyIfSelectPermExist v = guard (isJust selM) *> v
getCustomNameWith f = f customRootFields
insCustName = getCustomNameWith _tcrfInsert
getInsDet (hdrs, upsertPerm) =
let isUpsertable = upsertable constraints upsertPerm $ isJust viM
in ( MCInsert $ InsOpCtx tn $ hdrs `union` maybe [] (^. _5) updM
, mkInsMutFld insCustName tn isUpsertable
)
insOneCustName = getCustomNameWith _tcrfInsertOne
getInsOneDet (hdrs, upsertPerm) =
let isUpsertable = upsertable constraints upsertPerm $ isJust viM
in ( MCInsertOne $ InsOpCtx tn $ hdrs `union` maybe [] (^. _5) updM
, mkInsertOneMutationField insOneCustName tn isUpsertable
)
updCustName = getCustomNameWith _tcrfUpdate
getUpdDet (updCols, preSetCols, updFltr, updCheck, hdrs) =
( MCUpdate $ UpdOpCtx tn hdrs colGNameMap updFltr updCheck preSetCols
, mkUpdMutFld updCustName tn updCols
)
updByPkCustName = getCustomNameWith _tcrfUpdateByPk
getUpdByPkDet ((updCols, preSetCols, updFltr, updCheck, hdrs), pKey) =
( MCUpdateByPk $ UpdOpCtx tn hdrs colGNameMap updFltr updCheck preSetCols
, mkUpdateByPkMutationField updByPkCustName tn updCols pKey
)
delCustName = getCustomNameWith _tcrfDelete
getDelDet (delFltr, hdrs) =
( MCDelete $ DelOpCtx tn hdrs colGNameMap delFltr
, mkDelMutFld delCustName tn
)
delByPkCustName = getCustomNameWith _tcrfDeleteByPk
getDelByPkDet ((delFltr, hdrs), pKey) =
( MCDeleteByPk $ DelOpCtx tn hdrs colGNameMap delFltr
, mkDeleteByPkMutationField delByPkCustName tn pKey
)
selCustName = getCustomNameWith _tcrfSelect
getSelDet (selFltr, pLimit, hdrs, _) =
selFldHelper QCSelect (mkSelFld selCustName) selFltr pLimit hdrs
selAggCustName = getCustomNameWith _tcrfSelectAggregate
getSelAggDet (Just (selFltr, pLimit, hdrs, True)) =
Just $ selFldHelper QCSelectAgg (mkAggSelFld selAggCustName)
selFltr pLimit hdrs
getSelAggDet _ = Nothing
selFldHelper f g pFltr pLimit hdrs =
( f $ SelOpCtx tn hdrs colGNameMap pFltr pLimit
, g tn
)
selByPkCustName = getCustomNameWith _tcrfSelectByPk
getPKeySelDet (selFltr, _, hdrs, _) key =
let keyColumns = toList $ _pkColumns key
in ( QCSelectPkey . SelPkOpCtx tn hdrs selFltr $ mkPGColGNameMap keyColumns
, mkSelFldPKey selByPkCustName tn keyColumns
)
getFuncQueryFlds (selFltr, pLimit, hdrs, _) =
funcFldHelper QCFuncQuery mkFuncQueryFld selFltr pLimit hdrs
getFuncAggQueryFlds (selFltr, pLimit, hdrs, True) =
funcFldHelper QCFuncAggQuery mkFuncAggQueryFld selFltr pLimit hdrs
getFuncAggQueryFlds _ = []
funcFldHelper f g pFltr pLimit hdrs =
flip map funcs $ \fi ->
( f $ FuncQOpCtx (fiName fi) (mkFuncArgItemSeq fi) hdrs colGNameMap pFltr pLimit
, g fi $ fiDescription fi
)
mkFuncArgItemSeq functionInfo =
let inputArgs = fiInputArgs functionInfo
in Seq.fromList $ procFuncArgs inputArgs nameFn resultFn
where
nameFn = \case
IAUserProvided fa -> faName fa
IASessionVariables name -> Just name
resultFn arg gName = flip fmap arg $
\fa -> FunctionArgItem (G.Name gName) (faName fa) (faHasDefault fa)
getSelPermission :: TableInfo -> RoleName -> Maybe SelPermInfo
getSelPermission tabInfo role =
Map.lookup role (_tiRolePermInfoMap tabInfo) >>= _permSel
getSelPerm
:: (MonadError QErr m)
=> TableCache
-- all the fields of a table
-> FieldInfoMap FieldInfo
-- role and its permission
-> RoleName -> SelPermInfo
-> m (Bool, [SelField])
getSelPerm tableCache fields role selPermInfo = do
relFlds <- fmap catMaybes $ forM validRels $ \relInfo -> do
remTableInfo <- getTabInfo tableCache $ riRTable relInfo
let remTableSelPermM = getSelPermission remTableInfo role
remTableFlds = _tciFieldInfoMap $ _tiCoreInfo remTableInfo
remTableColGNameMap =
mkPGColGNameMap $ getValidCols remTableFlds
return $ flip fmap remTableSelPermM $
\rmSelPermM -> SFRelationship RelationshipFieldInfo
{ _rfiInfo = relInfo
, _rfiAllowAgg = spiAllowAgg rmSelPermM
, _rfiColumns = remTableColGNameMap
, _rfiPermFilter = spiFilter rmSelPermM
, _rfiPermLimit = spiLimit rmSelPermM
, _rfiIsNullable = isRelNullable fields relInfo
}
computedSelFields <- fmap catMaybes $ forM computedFields $ \info -> do
let ComputedFieldInfo name function returnTy _ = info
inputArgSeq = mkComputedFieldFunctionArgSeq $ _cffInputArgs function
fmap (SFComputedField . ComputedField name function inputArgSeq) <$>
case returnTy of
CFRScalar scalarTy -> pure $ Just $ CFTScalar scalarTy
CFRSetofTable retTable -> do
retTableInfo <- getTabInfo tableCache retTable
let retTableSelPermM = getSelPermission retTableInfo role
retTableFlds = _tciFieldInfoMap $ _tiCoreInfo retTableInfo
retTableColGNameMap =
mkPGColGNameMap $ getValidCols retTableFlds
pure $ flip fmap retTableSelPermM $
\selPerm -> CFTTable ComputedFieldTable
{ _cftTable = retTable
, _cftCols = retTableColGNameMap
, _cftPermFilter = spiFilter selPerm
, _cftPermLimit = spiLimit selPerm
}
return (spiAllowAgg selPermInfo, cols <> relFlds <> computedSelFields)
where
validRels = getValidRels fields
validCols = getValidCols fields
cols = map SFPGColumn $ getColInfos (toList allowedCols) validCols
computedFields = flip filter (getComputedFieldInfos fields) $
\info -> case _cfiReturnType info of
CFRScalar _ ->
_cfiName info `Set.member` allowedScalarComputedFields
CFRSetofTable _ -> True
allowedCols = spiCols selPermInfo
allowedScalarComputedFields = spiScalarComputedFields selPermInfo
mkInsCtx
:: MonadError QErr m
=> RoleName
-> TableCache
-> FieldInfoMap FieldInfo
-> InsPermInfo
-> Maybe UpdPermInfo
-> m InsCtx
mkInsCtx role tableCache fields insPermInfo updPermM = do
relTupsM <- forM rels $ \relInfo -> do
let remoteTable = riRTable relInfo
relName = riName relInfo
remoteTableInfo <- getTabInfo tableCache remoteTable
let insPermM = getInsPerm remoteTableInfo role
viewInfoM = _tciViewInfo $ _tiCoreInfo remoteTableInfo
return $ bool Nothing (Just (relName, relInfo)) $
isInsertable insPermM viewInfoM && isValidRel relName remoteTable
let relInfoMap = Map.fromList $ catMaybes relTupsM
return $ InsCtx gNamePGColMap checkCond setCols relInfoMap updPermForIns
where
gNamePGColMap = mkPGColGNameMap allCols
allCols = getCols fields
rels = getValidRels fields
setCols = ipiSet insPermInfo
checkCond = ipiCheck insPermInfo
updPermForIns = mkUpdPermForIns <$> updPermM
mkUpdPermForIns upi = UpdPermForIns (toList $ upiCols upi) (upiCheck upi)
(upiFilter upi) (upiSet upi)
isInsertable Nothing _ = False
isInsertable (Just _) viewInfoM = isMutable viIsInsertable viewInfoM
mkAdminInsCtx
:: MonadError QErr m
=> TableCache
-> FieldInfoMap FieldInfo
-> m InsCtx
mkAdminInsCtx tc fields = do
relTupsM <- forM rels $ \relInfo -> do
let remoteTable = riRTable relInfo
relName = riName relInfo
remoteTableInfo <- getTabInfo tc remoteTable
let viewInfoM = _tciViewInfo $ _tiCoreInfo remoteTableInfo
return $ bool Nothing (Just (relName, relInfo)) $
isMutable viIsInsertable viewInfoM && isValidRel relName remoteTable
let relInfoMap = Map.fromList $ catMaybes relTupsM
updPerm = UpdPermForIns updCols Nothing noFilter Map.empty
return $ InsCtx colGNameMap noFilter Map.empty relInfoMap (Just updPerm)
where
allCols = getCols fields
colGNameMap = mkPGColGNameMap allCols
updCols = map pgiColumn allCols
rels = getValidRels fields
mkAdminSelFlds
:: MonadError QErr m
=> FieldInfoMap FieldInfo
-> TableCache
-> m [SelField]
mkAdminSelFlds fields tableCache = do
relSelFlds <- forM validRels $ \relInfo -> do
let remoteTable = riRTable relInfo
remoteTableInfo <- _tiCoreInfo <$> getTabInfo tableCache remoteTable
let remoteTableFlds = _tciFieldInfoMap remoteTableInfo
remoteTableColGNameMap =
mkPGColGNameMap $ getValidCols remoteTableFlds
return $ SFRelationship RelationshipFieldInfo
{ _rfiInfo = relInfo
, _rfiAllowAgg = True
, _rfiColumns = remoteTableColGNameMap
, _rfiPermFilter = noFilter
, _rfiPermLimit = Nothing
, _rfiIsNullable = isRelNullable fields relInfo
}
computedSelFields <- forM computedFields $ \info -> do
let ComputedFieldInfo name function returnTy _ = info
inputArgSeq = mkComputedFieldFunctionArgSeq $ _cffInputArgs function
(SFComputedField . ComputedField name function inputArgSeq) <$>
case returnTy of
CFRScalar scalarTy -> pure $ CFTScalar scalarTy
CFRSetofTable retTable -> do
retTableInfo <- _tiCoreInfo <$> getTabInfo tableCache retTable
let retTableFlds = _tciFieldInfoMap retTableInfo
retTableColGNameMap =
mkPGColGNameMap $ getValidCols retTableFlds
pure $ CFTTable ComputedFieldTable
{ _cftTable = retTable
, _cftCols = retTableColGNameMap
, _cftPermFilter = noFilter
, _cftPermLimit = Nothing
}
return $ colSelFlds <> relSelFlds <> computedSelFields
where
cols = getValidCols fields
colSelFlds = map SFPGColumn cols
validRels = getValidRels fields
computedFields = getComputedFieldInfos fields
mkGCtxRole
:: (MonadError QErr m)
=> TableCache
-> QualifiedTable
-> Maybe PGDescription
-> FieldInfoMap FieldInfo
-> Maybe (PrimaryKey PGColumnInfo)
-> [ConstraintName]
-> [FunctionInfo]
-> Maybe ViewInfo
-> TableConfig
-> RoleName
-> RolePermInfo
-> m (TyAgg, RootFields, InsCtxMap)
mkGCtxRole tableCache tn descM fields primaryKey constraints funcs viM tabConfigM role permInfo = do
selPermM <- mapM (getSelPerm tableCache fields role) $ _permSel permInfo
tabInsInfoM <- forM (_permIns permInfo) $ \ipi -> do
ctx <- mkInsCtx role tableCache fields ipi $ _permUpd permInfo
let permCols = flip getColInfos allCols $ Set.toList $ ipiCols ipi
return (ctx, (permCols, icRelations ctx))
let insPermM = snd <$> tabInsInfoM
insCtxM = fst <$> tabInsInfoM
updColsM = filterColFlds . upiCols <$> _permUpd permInfo
tyAgg = mkGCtxRole' tn descM insPermM selPermM updColsM
(void $ _permDel permInfo) primaryKey constraints viM funcs
rootFlds = getRootFldsRole tn primaryKey constraints fields funcs
viM permInfo tabConfigM
insCtxMap = maybe Map.empty (Map.singleton tn) insCtxM
return (tyAgg, rootFlds, insCtxMap)
where
allCols = getCols fields
cols = getValidCols fields
filterColFlds allowedSet =
filter ((`Set.member` allowedSet) . pgiColumn) cols
getRootFldsRole
:: QualifiedTable
-> Maybe (PrimaryKey PGColumnInfo)
-> [ConstraintName]
-> FieldInfoMap FieldInfo
-> [FunctionInfo]
-> Maybe ViewInfo
-> RolePermInfo
-> TableConfig
-> RootFields
getRootFldsRole tn pCols constraints fields funcs viM (RolePermInfo insM selM updM delM)=
getRootFldsRole' tn pCols constraints fields funcs
(mkIns <$> insM) (mkSel <$> selM)
(mkUpd <$> updM) (mkDel <$> delM) viM
where
mkIns i = (ipiRequiredHeaders i, isJust updM)
mkSel s = ( spiFilter s, spiLimit s
, spiRequiredHeaders s, spiAllowAgg s
)
mkUpd u = ( flip getColInfos allCols $ Set.toList $ upiCols u
, upiSet u
, upiFilter u
, upiCheck u
, upiRequiredHeaders u
)
mkDel d = (dpiFilter d, dpiRequiredHeaders d)
allCols = getCols fields
mkGCtxMapTable
:: (MonadError QErr m)
=> TableCache
-> FunctionCache
-> TableInfo
-> m (Map.HashMap RoleName (TyAgg, RootFields, InsCtxMap))
mkGCtxMapTable tableCache funcCache tabInfo = do
m <- flip Map.traverseWithKey rolePerms $
mkGCtxRole tableCache tn descM fields primaryKey validConstraints
tabFuncs viewInfo customConfig
adminInsCtx <- mkAdminInsCtx tableCache fields
adminSelFlds <- mkAdminSelFlds fields tableCache
let adminCtx = mkGCtxRole' tn descM (Just (cols, icRelations adminInsCtx))
(Just (True, adminSelFlds)) (Just cols) (Just ())
primaryKey validConstraints viewInfo tabFuncs
adminInsCtxMap = Map.singleton tn adminInsCtx
return $ Map.insert adminRole (adminCtx, adminRootFlds, adminInsCtxMap) m
where
TableInfo coreInfo rolePerms _ = tabInfo
TableCoreInfo tn descM _ fields primaryKey _ _ viewInfo _ customConfig = coreInfo
validConstraints = mkValidConstraints $ map _cName (tciUniqueOrPrimaryKeyConstraints coreInfo)
cols = getValidCols fields
tabFuncs = filter (isValidObjectName . fiName) $
getFuncsOfTable tn funcCache
adminRootFlds =
getRootFldsRole' tn primaryKey validConstraints fields tabFuncs
(Just ([], True)) (Just (noFilter, Nothing, [], True))
(Just (cols, mempty, noFilter, Nothing, [])) (Just (noFilter, []))
viewInfo customConfig
noFilter :: AnnBoolExpPartialSQL
noFilter = annBoolExpTrue
mkGCtxMap
:: forall m. (MonadError QErr m)
=> TableCache -> FunctionCache -> ActionCache -> m GCtxMap
mkGCtxMap tableCache functionCache actionCache = do
typesMapL <- mapM (mkGCtxMapTable tableCache functionCache) $
filter (tableFltr . _tiCoreInfo) $ Map.elems tableCache
let actionsSchema = mkActionsSchema actionCache
typesMap <- combineTypes actionsSchema typesMapL
let gCtxMap = flip Map.map typesMap $
\(ty, flds, insCtxMap) -> mkGCtx ty flds insCtxMap
return gCtxMap
where
tableFltr ti = not (isSystemDefined $ _tciSystemDefined ti) && isValidObjectName (_tciName ti)
combineTypes
:: Map.HashMap RoleName (RootFields, TyAgg)
-> [Map.HashMap RoleName (TyAgg, RootFields, InsCtxMap)]
-> m (Map.HashMap RoleName (TyAgg, RootFields, InsCtxMap))
combineTypes actionsSchema maps = do
let listMap = foldr (Map.unionWith (++) . Map.map pure)
((\(rf, tyAgg) -> pure (tyAgg, rf, mempty)) <$> actionsSchema)
maps
flip Map.traverseWithKey listMap $ \_ typeList -> do
let tyAgg = mconcat $ map (^. _1) typeList
insCtx = mconcat $ map (^. _3) typeList
rootFields <- combineRootFields $ map (^. _2) typeList
pure (tyAgg, rootFields, insCtx)
combineRootFields :: [RootFields] -> m RootFields
combineRootFields rootFields = do
let duplicateQueryFields = duplicates $
concatMap (Map.keys . _rootQueryFields) rootFields
duplicateMutationFields = duplicates $
concatMap (Map.keys . _rootMutationFields) rootFields
-- TODO: The following exception should result in inconsistency
when (not $ null duplicateQueryFields) $
throw400 Unexpected $ "following query root fields are duplicated: "
<> showNames duplicateQueryFields
when (not $ null duplicateMutationFields) $
throw400 Unexpected $ "following mutation root fields are duplicated: "
<> showNames duplicateMutationFields
pure $ mconcat rootFields
getGCtx :: (CacheRM m) => RoleName -> GCtxMap -> m GCtx
getGCtx rn ctxMap = do
sc <- askSchemaCache
return $ fromMaybe (scDefaultRemoteGCtx sc) $ Map.lookup rn ctxMap
-- pretty print GCtx
ppGCtx :: GCtx -> String
ppGCtx gCtx =
"GCtx ["
<> "\n types = " <> show types
<> "\n query root = " <> show qRoot
<> "\n mutation root = " <> show mRoot
<> "\n subscription root = " <> show sRoot
<> "\n]"
where
types = map (G.unName . G.unNamedType) $ Map.keys $ _gTypes gCtx
qRoot = (,) (_otiName qRootO) $
map G.unName $ Map.keys $ _otiFields qRootO
mRoot = (,) (_otiName <$> mRootO) $
maybe [] (map G.unName . Map.keys . _otiFields) mRootO
sRoot = (,) (_otiName <$> sRootO) $
maybe [] (map G.unName . Map.keys . _otiFields) sRootO
qRootO = _gQueryRoot gCtx
mRootO = _gMutRoot gCtx
sRootO = _gSubRoot gCtx
mkGCtx :: TyAgg -> RootFields -> InsCtxMap -> GCtx
mkGCtx tyAgg (RootFields queryFields mutationFields) insCtxMap =
let queryRoot = mkQueryRootTyInfo qFlds
scalarTys = map (TIScalar . mkHsraScalarTyInfo) (Set.toList allScalarTypes)
compTys = map (TIInpObj . mkCompExpInp) (Set.toList allComparableTypes)
ordByEnumTyM = bool (Just ordByEnumTy) Nothing $ null qFlds
allTys = Map.union tyInfos $ mkTyInfoMap $
catMaybes [ Just $ TIObj queryRoot
, TIObj <$> mutRootM
, TIObj <$> subRootM
, TIEnum <$> ordByEnumTyM
] <>
scalarTys <> compTys <> defaultTypes <> wiredInGeoInputTypes
<> wiredInRastInputTypes
-- for now subscription root is query root
in GCtx allTys fldInfos queryRoot mutRootM subRootM ordByEnums
(Map.map fst queryFields) (Map.map fst mutationFields) insCtxMap
where
TyAgg tyInfos fldInfos scalars ordByEnums = tyAgg
colTys = Set.fromList $ map pgiType $ mapMaybe (^? _RFPGColumn) $
Map.elems fldInfos
mkMutRoot =
mkHsraObjTyInfo (Just "mutation root") (G.NamedType "mutation_root") Set.empty .
mapFromL _fiName
mutRootM = bool (Just $ mkMutRoot mFlds) Nothing $ null mFlds
mkSubRoot =
mkHsraObjTyInfo (Just "subscription root")
(G.NamedType "subscription_root") Set.empty . mapFromL _fiName
subRootM = bool (Just $ mkSubRoot qFlds) Nothing $ null qFlds
qFlds = rootFieldInfos queryFields
mFlds = rootFieldInfos mutationFields
rootFieldInfos = map snd . Map.elems
anyGeoTypes = any (isScalarColumnWhere isGeoType) colTys
allComparableTypes =
if anyGeoTypes
-- due to casting, we need to generate both geometry and geography
-- operations even if just one of the two appears in the schema
then Set.union (Set.fromList [PGColumnScalar PGGeometry, PGColumnScalar PGGeography]) colTys
else colTys
additionalScalars = Set.fromList $
-- raster comparison expression needs geometry input
(guard anyRasterTypes *> pure PGGeometry)
-- scalar computed field return types
<> mapMaybe (^? _RFComputedField.cfType._CFTScalar) (Map.elems fldInfos)
allScalarTypes = (allComparableTypes ^.. folded._PGColumnScalar)
<> additionalScalars <> scalars
wiredInGeoInputTypes = guard anyGeoTypes *> map TIInpObj geoInputTypes
anyRasterTypes = any (isScalarColumnWhere (== PGRaster)) colTys
wiredInRastInputTypes = guard anyRasterTypes *>
map TIInpObj rasterIntersectsInputTypes