{-# LANGUAGE Arrows #-} module Hasura.RQL.DDL.Schema.Cache.Permission ( buildTablePermissions, mkPermissionMetadataObject, orderRoles, OrderedRoles, _unOrderedRoles, mkBooleanPermissionMap, resolveCheckPermission, ) where import Control.Arrow.Extended import Control.Arrow.Interpret import Data.Aeson import Data.Graph qualified as G import Data.HashMap.Strict qualified as M import Data.Proxy import Data.Sequence qualified as Seq import Data.Text.Extended import Hasura.Base.Error import Hasura.Incremental qualified as Inc import Hasura.Prelude import Hasura.RQL.DDL.Permission import Hasura.RQL.DDL.Schema.Cache.Common import Hasura.RQL.Types.Backend import Hasura.RQL.Types.Common import Hasura.RQL.Types.Metadata.Backend import Hasura.RQL.Types.Metadata.Object import Hasura.RQL.Types.Permission import Hasura.RQL.Types.Relationships.Local import Hasura.RQL.Types.Roles import Hasura.RQL.Types.Roles.Internal ( CheckPermission (..), CombineRolePermInfo (..), rolePermInfoToCombineRolePermInfo, ) import Hasura.RQL.Types.SchemaCache import Hasura.RQL.Types.SchemaCache.Build import Hasura.RQL.Types.SchemaCacheTypes import Hasura.RQL.Types.Table import Hasura.SQL.AnyBackend qualified as AB import Hasura.Session {- Note: [Inherited roles architecture for read queries] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 1. Schema generation -------------------- Schema generation for inherited roles is similar to the schema generation of non-inherited roles. In the case of inherited roles, we combine the `SelectPermInfo`s of the inherited role's role set and a new `SelectPermInfo` will be generated which will be the select permission of the inherited role. Two `SelPermInfo`s will be combined in the following manner: 1. Columns - The `SelPermInfo` contains a hashset of the columns that are accessible to the role. To combine two `SelPermInfo`s, every column of the hashset is coupled with the boolean expression (filter) of the `SelPermInfo` and a hash map of all the columns is created out of it, this hashmap is generated for the `SelPermInfo`s that are going to be combined. These hashmaps are then unioned and the values of these hashmaps are `OR`ed. When a column is accessible to all the select permissions then the nullability of the column is inferred from the DB column otherwise the column is explicitly marked as nullable to accomodate cell-value nullification. 2. Scalar computed fields - Scalar computed fields work the same as Columns (#1) 3. Filter / Boolean expression - The filters are combined using a `BoolOr` 4. Limit - Limits are combined by taking the maximum of the two limits 5. Allow Aggregation - Aggregation is allowed, if any of the permissions allow it. 6. Request Headers - Request headers are concatenated 2. SQL generation ----------------- See note [SQL generation for inherited roles] 3. Introspection ---------------- The columns accessible to an inherited role are explicitly set to nullable irrespective of the nullability of the DB column to accomodate cell value nullification. -} mkBooleanPermissionMap :: (RoleName -> a) -> HashMap RoleName a -> OrderedRoles -> HashMap RoleName a mkBooleanPermissionMap constructorFn metadataPermissions orderedRoles = foldl' combineBooleanPermission metadataPermissions $ _unOrderedRoles orderedRoles where combineBooleanPermission accumulatedPermMap (Role roleName (ParentRoles parentRoles)) = case M.lookup roleName accumulatedPermMap of -- We check if a permission for the given role exists in the metadata, if it -- exists, we use that Just _ -> accumulatedPermMap -- 2. When the permission doesn't exist, we try to inherit the permission from its parent roles -- For boolean permissions, if any of the parent roles have a permission to access an entity, -- then the inherited role will also be able to access the entity. Nothing -> -- see Note [Roles Inheritance] let canInheritPermission = any ((`M.member` accumulatedPermMap)) (toList parentRoles) in if canInheritPermission then M.insert roleName (constructorFn roleName) accumulatedPermMap else accumulatedPermMap -- | `OrderedRoles` is a data type to hold topologically sorted roles -- according to each role's parent roles, see `orderRoles` for more details. newtype OrderedRoles = OrderedRoles {_unOrderedRoles :: [Role]} deriving (Eq, Generic) instance Inc.Cacheable OrderedRoles -- | 'orderRoles' is used to order the roles, in such a way that given -- a role R with n parent roles - PR1, PR2 .. PRn, then the 'orderRoles' -- function will order the roles in such a way that all the parent roles -- precede the role R. Note that the order of the parent roles itself doesn't -- matter as long as they precede the roles on which they are dependent on. -- -- For example, the orderRoles may return `[PR1, PR3, PR2, ... PRn, R]` -- or `[PR5, PR3, PR1 ... R]`, both of them are correct because all -- the parent roles precede the inherited role R, assuming the parent roles -- themselves don't have any parents for the sake of this example. orderRoles :: MonadError QErr m => [Role] -> m OrderedRoles orderRoles allRoles = do -- inherited roles can be created from other inherited and non-inherited roles -- So, roles can be thought of as a graph where non-inherited roles don't have -- any outgoing edges and inherited roles as nodes with edges to its parent roles -- However, we can't allow cyclic roles since permissions built by a role is used -- by the dependent roles to build their permissions and if cyclic roles were to be -- allowed, the permissions building will be stuck in an infinite loop let graphNodesList = [(role, _rRoleName role, toList (_unParentRoles . _rParentRoles $ role)) | role <- allRoles] let orderedGraphNodes = G.stronglyConnComp graphNodesList -- topologically sort the nodes of the graph cyclicRoles = filter checkCycle orderedGraphNodes unless (null cyclicRoles) $ do -- we're appending the first element of the list at the end, so that the error message will -- contain the complete cycle of the roles let roleCycles = map (tshow . map (roleNameToTxt . _rRoleName) . appendFirstElementAtEnd . G.flattenSCC) cyclicRoles throw400 CyclicDependency $ "found cycle(s) in roles: " <> commaSeparated roleCycles let allOrderedRoles = G.flattenSCCs orderedGraphNodes pure $ OrderedRoles allOrderedRoles where checkCycle = \case G.AcyclicSCC _ -> False G.CyclicSCC _ -> True appendFirstElementAtEnd [] = [] appendFirstElementAtEnd (x : xs) = (x : xs) ++ [x] -- | `resolveCheckPermission` is a helper function which will convert the indermediate -- type `CheckPermission` to its original type. It will record any metadata inconsistencies, if exists. resolveCheckPermission :: forall m p. (MonadWriter (Seq CollectedInfo) m) => CheckPermission p -> RoleName -> InconsistentRoleEntity -> m (Maybe p) resolveCheckPermission checkPermission roleName inconsistentEntity = do case checkPermission of CPInconsistent -> do let inconsistentObj = -- check `Conflicts while inheriting permissions` in `rfcs/inherited-roles-improvements.md` CIInconsistency $ ConflictingInheritedPermission roleName inconsistentEntity tell $ Seq.singleton inconsistentObj pure Nothing CPDefined permissionDefn -> pure $ Just permissionDefn CPUndefined -> pure Nothing resolveCheckTablePermission :: forall b perm m. ( MonadWriter (Seq CollectedInfo) m, BackendMetadata b ) => CheckPermission perm -> Maybe (RolePermInfo b) -> (RolePermInfo b -> Maybe perm) -> RoleName -> SourceName -> TableName b -> PermType -> m (Maybe perm) resolveCheckTablePermission inheritedRolePermission accumulatedRolePermInfo permAcc roleName source table permType = do -- when for a given entity and role, a permission exists in the metadata, we override the metadata permission -- over the inherited permission let checkPermission = maybe inheritedRolePermission CPDefined (permAcc =<< accumulatedRolePermInfo) inconsistentRoleEntity = InconsistentTablePermission source (toTxt table) permType resolveCheckPermission checkPermission roleName inconsistentRoleEntity buildTablePermissions :: forall b m arr. ( ArrowChoice arr, Inc.ArrowDistribute arr, Inc.ArrowCache m arr, MonadError QErr m, ArrowWriter (Seq CollectedInfo) arr, BackendMetadata b, Inc.Cacheable (Proxy b), GetAggregationPredicatesDeps b ) => ( Proxy b, SourceName, Inc.Dependency (TableCoreCache b), FieldInfoMap (FieldInfo b), TablePermissionInputs b, OrderedRoles ) `arr` (RolePermInfoMap b) buildTablePermissions = Inc.cache proc (proxy, source, tableCache, tableFields, tablePermissions, orderedRoles) -> do let alignedPermissions = alignPermissions tablePermissions table = _tpiTable tablePermissions metadataRolePermissions <- (| Inc.keyed ( \_ (insertPermission, selectPermission, updatePermission, deletePermission) -> do insert <- buildPermission -< (proxy, tableCache, source, table, tableFields, listToMaybe insertPermission) select <- buildPermission -< (proxy, tableCache, source, table, tableFields, listToMaybe selectPermission) update <- buildPermission -< (proxy, tableCache, source, table, tableFields, listToMaybe updatePermission) delete <- buildPermission -< (proxy, tableCache, source, table, tableFields, listToMaybe deletePermission) returnA -< RolePermInfo insert select update delete ) |) alignedPermissions (| foldlA' ( \accumulatedRolePermMap (Role roleName (ParentRoles parentRoles)) -> do parentRolePermissions <- bindA -< for (toList parentRoles) $ \role -> onNothing (M.lookup role accumulatedRolePermMap) $ throw500 $ -- this error will ideally never be thrown, but if it's thrown then -- it's possible that the permissions for the role do exist, but it's -- not yet built due to wrong ordering of the roles, check `orderRoles` "buildTablePermissions: table role permissions for role: " <> role <<> " not found" let combinedParentRolePermInfo = mconcat $ fmap rolePermInfoToCombineRolePermInfo parentRolePermissions selectPermissionsCount = length $ filter (isJust . _permSel) parentRolePermissions let accumulatedRolePermission = M.lookup roleName accumulatedRolePermMap let roleSelectPermission = case (_permSel =<< accumulatedRolePermission) of Just metadataSelectPerm -> Just metadataSelectPerm Nothing -> combinedSelPermInfoToSelPermInfo selectPermissionsCount <$> (crpiSelPerm combinedParentRolePermInfo) roleInsertPermission <- interpretWriter -< resolveCheckTablePermission (crpiInsPerm combinedParentRolePermInfo) accumulatedRolePermission _permIns roleName source table PTInsert roleUpdatePermission <- interpretWriter -< resolveCheckTablePermission (crpiUpdPerm combinedParentRolePermInfo) accumulatedRolePermission _permUpd roleName source table PTUpdate roleDeletePermission <- interpretWriter -< resolveCheckTablePermission (crpiDelPerm combinedParentRolePermInfo) accumulatedRolePermission _permDel roleName source table PTDelete let rolePermInfo = RolePermInfo roleInsertPermission roleSelectPermission roleUpdatePermission roleDeletePermission returnA -< M.insert roleName rolePermInfo accumulatedRolePermMap ) |) metadataRolePermissions (_unOrderedRoles orderedRoles) where mkMap :: [PermDef b e] -> HashMap RoleName (PermDef b e) mkMap = mapFromL _pdRole alignPermissions TablePermissionInputs {..} = let insertsMap = M.map (\a -> ([a], [], [], [])) (mkMap _tpiInsert) selectsMap = M.map (\a -> ([], [a], [], [])) (mkMap _tpiSelect) updatesMap = M.map (\a -> ([], [], [a], [])) (mkMap _tpiUpdate) deletesMap = M.map (\a -> ([], [], [], [a])) (mkMap _tpiDelete) unionMap = M.unionWith (<>) in insertsMap `unionMap` selectsMap `unionMap` updatesMap `unionMap` deletesMap mkPermissionMetadataObject :: forall b a. (BackendMetadata b) => SourceName -> TableName b -> PermDef b a -> MetadataObject mkPermissionMetadataObject source table permDef = let permType = reflectPermDefPermission (_pdPermission permDef) objectId = MOSourceObjId source $ AB.mkAnyBackend $ SMOTableObj @b table $ MTOPerm (_pdRole permDef) permType definition = toJSON $ WithTable @b source table permDef in MetadataObject objectId definition withPermission :: forall bknd a b c s arr. (ArrowChoice arr, ArrowWriter (Seq CollectedInfo) arr, BackendMetadata bknd) => WriterA (Seq SchemaDependency) (ErrorA QErr arr) (a, s) b -> ( a, ((SourceName, TableName bknd, PermDef bknd c, Proxy bknd), s) ) `arr` (Maybe b) withPermission f = proc (e, ((source, table, permDef, _proxy), s)) -> do let metadataObject = mkPermissionMetadataObject @bknd source table permDef permType = reflectPermDefPermission (_pdPermission permDef) roleName = _pdRole permDef schemaObject = SOSourceObj source $ AB.mkAnyBackend $ SOITableObj @bknd table $ TOPerm roleName permType addPermContext err = "in permission for role " <> roleName <<> ": " <> err (| withRecordInconsistency ( (| withRecordDependencies ( (| modifyErrA (f -< (e, s)) |) (addTableContext @bknd table . addPermContext) ) |) metadataObject schemaObject ) |) metadataObject buildPermission :: forall b a arr m. ( ArrowChoice arr, ArrowWriter (Seq CollectedInfo) arr, Inc.ArrowCache m arr, Inc.Cacheable (a b), Inc.Cacheable (Proxy b), MonadError QErr m, BackendMetadata b, GetAggregationPredicatesDeps b ) => ( Proxy b, Inc.Dependency (TableCoreCache b), SourceName, TableName b, FieldInfoMap (FieldInfo b), Maybe (PermDef b a) ) `arr` Maybe (PermInfo a b) buildPermission = Inc.cache proc (proxy, tableCache, source, table, tableFields, maybePermission) -> do (| traverseA ( \permission -> (| withPermission ( do bindErrorA -< when (_pdRole permission == adminRoleName) $ throw400 ConstraintViolation "cannot define permission for admin role" (info, dependencies) <- liftEitherA <<< Inc.bindDepend -< runExceptT $ runTableCoreCacheRT ( buildPermInfo source table tableFields (_pdRole permission) (_pdPermission permission) ) (source, tableCache) tellA -< Seq.fromList dependencies returnA -< info ) |) (source, table, permission, proxy) ) |) maybePermission >-> (\info -> join info >- returnA)