{-# LANGUAGE Arrows #-} {-# LANGUAGE OverloadedLabels #-} {-# LANGUAGE UndecidableInstances #-} -- | Top-level functions concerned specifically with operations on the schema cache, such as -- rebuilding it from the catalog and incorporating schema changes. See the module documentation for -- "Hasura.RQL.DDL.Schema" for more details. -- -- __Note__: this module is __mutually recursive__ with other @Hasura.RQL.DDL.Schema.*@ modules, which -- both define pieces of the implementation of building the schema cache and define handlers that -- trigger schema cache rebuilds. module Hasura.RQL.DDL.Schema.Cache ( RebuildableSchemaCache, lastBuiltSchemaCache, buildRebuildableSchemaCache, buildRebuildableSchemaCacheWithReason, CacheRWT, runCacheRWT, mkBooleanPermissionMap, ) where import Control.Arrow.Extended import Control.Lens hiding ((.=)) import Control.Monad.Trans.Control (MonadBaseControl) import Control.Retry qualified as Retry import Data.Aeson import Data.Either (isLeft) import Data.Environment qualified as Env import Data.HashMap.Strict.Extended qualified as M import Data.HashMap.Strict.InsOrd.Extended qualified as OMap import Data.HashSet qualified as HS import Data.Proxy import Data.Set qualified as S import Data.Text.Extended import Hasura.Base.Error import Hasura.GraphQL.Schema (buildGQLContext) import Hasura.GraphQL.Schema.NamingCase import Hasura.Incremental qualified as Inc import Hasura.Logging import Hasura.Metadata.Class import Hasura.Prelude import Hasura.RQL.DDL.Action import Hasura.RQL.DDL.CustomTypes import Hasura.RQL.DDL.EventTrigger (MonadEventLogCleanup (..), buildEventTriggerInfo) import Hasura.RQL.DDL.InheritedRoles (resolveInheritedRole) import Hasura.RQL.DDL.RemoteRelationship (CreateRemoteSchemaRemoteRelationship (..), PartiallyResolvedSource (..), buildRemoteFieldInfo, getRemoteSchemaEntityJoinColumns) import Hasura.RQL.DDL.ScheduledTrigger import Hasura.RQL.DDL.Schema.Cache.Common import Hasura.RQL.DDL.Schema.Cache.Dependencies import Hasura.RQL.DDL.Schema.Cache.Fields import Hasura.RQL.DDL.Schema.Cache.Permission import Hasura.RQL.DDL.Schema.Function import Hasura.RQL.DDL.Schema.Table import Hasura.RQL.Types.Action import Hasura.RQL.Types.Allowlist import Hasura.RQL.Types.Backend import Hasura.RQL.Types.Column import Hasura.RQL.Types.Common import Hasura.RQL.Types.CustomTypes import Hasura.RQL.Types.Endpoint import Hasura.RQL.Types.EventTrigger import Hasura.RQL.Types.Eventing.Backend import Hasura.RQL.Types.Function import Hasura.RQL.Types.Metadata hiding (fmFunction, tmTable) import Hasura.RQL.Types.Metadata.Backend import Hasura.RQL.Types.Metadata.Object import Hasura.RQL.Types.Network import Hasura.RQL.Types.OpenTelemetry import Hasura.RQL.Types.QueryCollection import Hasura.RQL.Types.Relationships.Remote import Hasura.RQL.Types.Roles import Hasura.RQL.Types.ScheduledTrigger import Hasura.RQL.Types.SchemaCache import Hasura.RQL.Types.SchemaCache.Build import Hasura.RQL.Types.SchemaCache.Instances () import Hasura.RQL.Types.SchemaCacheTypes import Hasura.RQL.Types.Source import Hasura.RQL.Types.SourceCustomization import Hasura.RQL.Types.Table import Hasura.RemoteSchema.Metadata import Hasura.RemoteSchema.SchemaCache import Hasura.SQL.AnyBackend qualified as AB import Hasura.SQL.Backend import Hasura.SQL.BackendMap (BackendMap) import Hasura.SQL.BackendMap qualified as BackendMap import Hasura.SQL.Tag import Hasura.Server.Migrate.Version import Hasura.Server.Types import Hasura.Session import Hasura.Tracing qualified as Tracing import Language.GraphQL.Draft.Syntax qualified as G import Network.HTTP.Client.Manager (HasHttpManagerM (..)) {- Note [Roles Inheritance] ~~~~~~~~~~~~~~~~~~~~~~~~~~~ Roles may have parent roles defined from which they can inherit permission and this is called as roles inheritance. Roles which have parents can also be parents of other roles. So, cycle in roles should be disallowed and this is done in the `orderRoles` function. When the metadata contains a permission for a role for a entity, then it will override the inherited permission, if any. Roles inheritance work differently for different features: 1. Select permissions ~~~~~~~~~~~~~~~~~~~~~ See note [Inherited roles architecture for read queries] 2. Mutation permissions and remote schema permissions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For mutation and remote schema permissions, an inherited role can only inherit permission from its parent roles when the relevant parts of the permissions are equal i.e. the non-relevant parts are discarded for the equality, for example, in two remote schema permissions the order of the fields in an Object type is discarded. When an inherited role cannot inherit permission from its parents due to a conflict, then we mark the inherited role and the entity (remote schema or table) combination as inconsistent in the metadata. 3. Actions and Custom function permissions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Currently, actions and custom function permissions can be thought of as a boolean. Either a role has permission to the entity or it doesn't, so in these cases there's no possiblity of a conflict. An inherited role will have access to the action/function if any one of the parents have permission to access the action/function. -} buildRebuildableSchemaCache :: Logger Hasura -> Env.Environment -> Metadata -> CacheBuild RebuildableSchemaCache buildRebuildableSchemaCache = buildRebuildableSchemaCacheWithReason CatalogSync buildRebuildableSchemaCacheWithReason :: BuildReason -> Logger Hasura -> Env.Environment -> Metadata -> CacheBuild RebuildableSchemaCache buildRebuildableSchemaCacheWithReason reason logger env metadata = do result <- flip runReaderT reason $ Inc.build (buildSchemaCacheRule logger env) (metadata, initialInvalidationKeys) pure $ RebuildableSchemaCache (Inc.result result) initialInvalidationKeys (Inc.rebuildRule result) newtype CacheRWT m a = -- The CacheInvalidations component of the state could actually be collected using WriterT, but -- WriterT implementations prior to transformers-0.5.6.0 (which added -- Control.Monad.Trans.Writer.CPS) are leaky, and we don’t have that yet. CacheRWT (StateT (RebuildableSchemaCache, CacheInvalidations) m a) deriving ( Functor, Applicative, Monad, MonadIO, MonadReader r, MonadError e, UserInfoM, HasHttpManagerM, MonadMetadataStorage, MonadMetadataStorageQueryAPI, Tracing.MonadTrace, HasServerConfigCtx, MonadBase b, MonadBaseControl b ) instance (MonadEventLogCleanup m) => MonadEventLogCleanup (CacheRWT m) where runLogCleaner conf = lift $ runLogCleaner conf generateCleanupSchedules sourceInfo triggerName cleanupConfig = lift $ generateCleanupSchedules sourceInfo triggerName cleanupConfig runCacheRWT :: Functor m => RebuildableSchemaCache -> CacheRWT m a -> m (a, RebuildableSchemaCache, CacheInvalidations) runCacheRWT cache (CacheRWT m) = runStateT m (cache, mempty) <&> \(v, (newCache, invalidations)) -> (v, newCache, invalidations) instance MonadTrans CacheRWT where lift = CacheRWT . lift instance (Monad m) => CacheRM (CacheRWT m) where askSchemaCache = CacheRWT $ gets (lastBuiltSchemaCache . (^. _1)) instance ( MonadIO m, MonadError QErr m, HasHttpManagerM m, MonadResolveSource m, HasServerConfigCtx m ) => CacheRWM (CacheRWT m) where buildSchemaCacheWithOptions buildReason invalidations metadata = CacheRWT do (RebuildableSchemaCache lastBuiltSC invalidationKeys rule, oldInvalidations) <- get let metadataVersion = scMetadataResourceVersion lastBuiltSC newInvalidationKeys = invalidateKeys invalidations invalidationKeys result <- lift $ runCacheBuildM $ flip runReaderT buildReason $ Inc.build rule (metadata, newInvalidationKeys) let schemaCache = (Inc.result result) {scMetadataResourceVersion = metadataVersion} prunedInvalidationKeys = pruneInvalidationKeys schemaCache newInvalidationKeys !newCache = RebuildableSchemaCache schemaCache prunedInvalidationKeys (Inc.rebuildRule result) !newInvalidations = oldInvalidations <> invalidations put (newCache, newInvalidations) where -- Prunes invalidation keys that no longer exist in the schema to avoid leaking memory by -- hanging onto unnecessary keys. pruneInvalidationKeys schemaCache = over ikRemoteSchemas $ M.filterWithKey \name _ -> -- see Note [Keep invalidation keys for inconsistent objects] name `elem` getAllRemoteSchemas schemaCache setMetadataResourceVersionInSchemaCache resourceVersion = CacheRWT $ do (rebuildableSchemaCache, invalidations) <- get put ( rebuildableSchemaCache { lastBuiltSchemaCache = (lastBuiltSchemaCache rebuildableSchemaCache) { scMetadataResourceVersion = Just resourceVersion } }, invalidations ) -- | Generate health checks related cache from sources metadata buildHealthCheckCache :: Sources -> SourceHealthCheckCache buildHealthCheckCache sources = catMaybes $ M.fromList $ map (second mkSourceHealthCheck) (OMap.toList sources) where mkSourceHealthCheck :: BackendSourceMetadata -> Maybe BackendSourceHealthCheckInfo mkSourceHealthCheck (BackendSourceMetadata sourceMetadata) = AB.traverseBackend @Backend sourceMetadata mkSourceHealthCheckBackend mkSourceHealthCheckBackend :: SourceMetadata b -> Maybe (SourceHealthCheckInfo b) mkSourceHealthCheckBackend sourceMetadata = let sourceName = _smName sourceMetadata connection = _smConfiguration sourceMetadata healthCheck = _smHealthCheckConfig sourceMetadata in SourceHealthCheckInfo sourceName connection <$> healthCheck buildSchemaCacheRule :: -- Note: by supplying BuildReason via MonadReader, it does not participate in caching, which is -- what we want! ( ArrowChoice arr, Inc.ArrowDistribute arr, Inc.ArrowCache m arr, MonadIO m, MonadBaseControl IO m, MonadError QErr m, MonadReader BuildReason m, HasHttpManagerM m, MonadResolveSource m, HasServerConfigCtx m ) => Logger Hasura -> Env.Environment -> (Metadata, InvalidationKeys) `arr` SchemaCache buildSchemaCacheRule logger env = proc (metadataNoDefaults, invalidationKeys) -> do invalidationKeysDep <- Inc.newDependency -< invalidationKeys metadataDefaults <- bindA -< askMetadataDefaults let metadata@Metadata {..} = overrideMetadataDefaults metadataNoDefaults metadataDefaults -- Step 1: Process metadata and collect dependency information. (outputs, collectedInfo) <- runWriterA buildAndCollectInfo -< (metadata, invalidationKeysDep) let (inconsistentObjects, unresolvedDependencies) = partitionEithers $ toList collectedInfo -- Step 2: Resolve dependency information and drop dangling dependents. (resolvedOutputs, dependencyInconsistentObjects, resolvedDependencies) <- resolveDependencies -< (outputs, unresolvedDependencies) -- Steps 3 and 4: Build the regular and relay GraphQL schemas in parallel ((adminIntrospection, gqlContext, gqlContextUnauth, inconsistentRemoteSchemas), (relayContext, relayContextUnauth)) <- bindA -< do cxt <- askServerConfigCtx buildGQLContext cxt (_boSources resolvedOutputs) (_boRemoteSchemas resolvedOutputs) (_boActions resolvedOutputs) (_boCustomTypes resolvedOutputs) let duplicateVariables :: EndpointMetadata a -> Bool duplicateVariables m = any ((> 1) . length) $ group $ sort $ catMaybes $ splitPath Just (const Nothing) (_ceUrl m) endpointObjId :: EndpointMetadata q -> MetadataObjId endpointObjId md = MOEndpoint (_ceName md) endpointObject :: EndpointMetadata q -> MetadataObject endpointObject md = MetadataObject (endpointObjId md) (toJSON $ OMap.lookup (_ceName md) _metaRestEndpoints) listedQueryObjects :: (CollectionName, ListedQuery) -> MetadataObject listedQueryObjects (cName, lq) = MetadataObject (MOQueryCollectionsQuery cName lq) (toJSON lq) -- Cases of urls that generate invalid segments: hasInvalidSegments :: EndpointMetadata query -> Bool hasInvalidSegments m = any (`elem` ["", ":"]) (splitPath id id (_ceUrl m)) ceUrlTxt = toTxt . _ceUrl endpoints = buildEndpointsTrie (M.elems $ _boEndpoints resolvedOutputs) duplicateF md = DuplicateRestVariables (ceUrlTxt md) (endpointObject md) duplicateRestVariables = map duplicateF $ filter duplicateVariables (M.elems $ _boEndpoints resolvedOutputs) invalidF md = InvalidRestSegments (ceUrlTxt md) (endpointObject md) invalidRestSegments = map invalidF $ filter hasInvalidSegments (M.elems $ _boEndpoints resolvedOutputs) ambiguousF' ep = MetadataObject (endpointObjId ep) (toJSON ep) ambiguousF mds = AmbiguousRestEndpoints (commaSeparated $ map _ceUrl mds) (map ambiguousF' mds) ambiguousRestEndpoints = map (ambiguousF . S.elems . snd) $ ambiguousPathsGrouped endpoints inlinedAllowlist = inlineAllowlist _metaQueryCollections _metaAllowlist globalAllowLists = HS.toList . iaGlobal $ inlinedAllowlist inconsistentQueryCollections <- bindA -< do getInconsistentQueryCollections adminIntrospection _metaQueryCollections listedQueryObjects endpoints globalAllowLists returnA -< SchemaCache { scSources = _boSources resolvedOutputs, scActions = _boActions resolvedOutputs, -- TODO this is not the right value: we should track what part of the schema -- we can stitch without consistencies, I think. scRemoteSchemas = fmap fst (_boRemoteSchemas resolvedOutputs), -- remoteSchemaMap scAllowlist = inlinedAllowlist, -- , scCustomTypes = _boCustomTypes resolvedOutputs scAdminIntrospection = adminIntrospection, scGQLContext = gqlContext, scUnauthenticatedGQLContext = gqlContextUnauth, scRelayContext = relayContext, scUnauthenticatedRelayContext = relayContextUnauth, -- , scGCtxMap = gqlSchema -- , scDefaultRemoteGCtx = remoteGQLSchema scDepMap = resolvedDependencies, scCronTriggers = _boCronTriggers resolvedOutputs, scEndpoints = endpoints, scInconsistentObjs = inconsistentObjects <> dependencyInconsistentObjects <> toList inconsistentRemoteSchemas <> duplicateRestVariables <> invalidRestSegments <> ambiguousRestEndpoints <> inconsistentQueryCollections, scApiLimits = _metaApiLimits, scMetricsConfig = _metaMetricsConfig, scMetadataResourceVersion = Nothing, scSetGraphqlIntrospectionOptions = _metaSetGraphqlIntrospectionOptions, scTlsAllowlist = networkTlsAllowlist _metaNetwork, scQueryCollections = _metaQueryCollections, scBackendCache = _boBackendCache resolvedOutputs, scSourceHealthChecks = buildHealthCheckCache _metaSources, scOpenTelemetryConfig = _boOpenTelemetryInfo resolvedOutputs } where resolveBackendInfo' :: forall arr m b. ( BackendMetadata b, ArrowChoice arr, Inc.ArrowCache m arr, Inc.ArrowDistribute arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, MonadIO m, HasHttpManagerM m ) => (BackendConfigWrapper b, Inc.Dependency (BackendMap BackendInvalidationKeysWrapper)) `arr` BackendCache resolveBackendInfo' = proc (backendConfigWrapper, backendInvalidationMap) -> do let backendInvalidationKeys = Inc.selectD #unBackendInvalidationKeysWrapper $ Inc.selectMaybeD $ BackendMap.lookupD @b backendInvalidationMap backendInfo <- resolveBackendInfo @b logger -< (backendInvalidationKeys, unBackendConfigWrapper backendConfigWrapper) returnA -< BackendMap.singleton (BackendInfoWrapper @b backendInfo) resolveBackendCache :: forall arr m. ( ArrowChoice arr, Inc.ArrowCache m arr, Inc.ArrowDistribute arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, MonadIO m, HasHttpManagerM m ) => (Inc.Dependency (BackendMap BackendInvalidationKeysWrapper), [AB.AnyBackend BackendConfigWrapper]) `arr` BackendCache resolveBackendCache = proc (backendInvalidationMap, backendConfigs) -> do case backendConfigs of [] -> returnA -< mempty (anyBackendConfig : backendConfigs') -> do backendInfo <- AB.dispatchAnyBackendArrow @BackendMetadata @HasTag resolveBackendInfo' -< (anyBackendConfig, backendInvalidationMap) backendInfos <- resolveBackendCache -< (backendInvalidationMap, backendConfigs') returnA -< backendInfo <> backendInfos getSourceConfigIfNeeded :: forall b arr m. ( ArrowChoice arr, Inc.ArrowCache m arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, MonadIO m, MonadResolveSource m, HasHttpManagerM m, BackendMetadata b ) => ( Inc.Dependency (HashMap SourceName Inc.InvalidationKey), SourceName, SourceConnConfiguration b, BackendSourceKind b, BackendInfo b ) `arr` Maybe (SourceConfig b) getSourceConfigIfNeeded = Inc.cache proc (invalidationKeys, sourceName, sourceConfig, backendKind, backendInfo) -> do let metadataObj = MetadataObject (MOSource sourceName) $ toJSON sourceName httpMgr <- bindA -< askHttpManager Inc.dependOn -< Inc.selectKeyD sourceName invalidationKeys (| withRecordInconsistency ( liftEitherA <<< bindA -< resolveSourceConfig @b logger sourceName sourceConfig backendKind backendInfo env httpMgr ) |) metadataObj resolveSourceIfNeeded :: forall b arr m. ( ArrowChoice arr, Inc.ArrowCache m arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, MonadIO m, MonadBaseControl IO m, MonadResolveSource m, HasHttpManagerM m, BackendMetadata b ) => ( Inc.Dependency (HashMap SourceName Inc.InvalidationKey), BackendInfoAndSourceMetadata b ) `arr` Maybe (ResolvedSource b) resolveSourceIfNeeded = Inc.cache proc (invalidationKeys, BackendInfoAndSourceMetadata {..}) -> do let sourceName = _smName _bcasmSourceMetadata metadataObj = MetadataObject (MOSource sourceName) $ toJSON sourceName logAndResolveDatabaseMetadata :: SourceConfig b -> SourceTypeCustomization -> m (Either QErr (ResolvedSource b)) logAndResolveDatabaseMetadata scConfig sType = do resSource <- resolveDatabaseMetadata _bcasmSourceMetadata scConfig sType for_ resSource $ liftIO . unLogger logger pure resSource maybeSourceConfig <- getSourceConfigIfNeeded @b -< (invalidationKeys, sourceName, _smConfiguration _bcasmSourceMetadata, _smKind _bcasmSourceMetadata, _bcasmBackendInfo) case maybeSourceConfig of Nothing -> returnA -< Nothing Just sourceConfig -> (| withRecordInconsistency ( liftEitherA <<< bindA -< logAndResolveDatabaseMetadata sourceConfig (getSourceTypeCustomization $ _smCustomization _bcasmSourceMetadata) ) |) metadataObj -- impl notes (swann): -- -- as our cache invalidation key, we use the fact of the availability of event triggers -- present, rerunning catalog init when this changes. i.e we invalidate the cache and -- rebuild it with the catalog only when there is at least one event trigger present. -- This is correct, because we only care about the transition from zero event triggers -- to nonzero (not necessarily one, as Anon has observed, because replace_metadata can -- add multiple event triggers in one go) -- -- a future optimisation would be to cache, on a per-source basis, whether or not -- the event catalog itself exists, and to then trigger catalog init when an event -- trigger is created _but only if_ this cached information says the event catalog -- doesn't already exist. initCatalogIfNeeded :: forall b arr m. ( ArrowChoice arr, Inc.ArrowCache m arr, MonadIO m, BackendMetadata b, HasServerConfigCtx m, MonadError QErr m, MonadBaseControl IO m ) => (Proxy b, Bool, SourceConfig b) `arr` (RecreateEventTriggers, SourceCatalogMigrationState) initCatalogIfNeeded = Inc.cache proc (Proxy, atleastOneTrigger, sourceConfig) -> do arrM id -< do if atleastOneTrigger then do maintenanceMode <- _sccMaintenanceMode <$> askServerConfigCtx eventingMode <- _sccEventingMode <$> askServerConfigCtx readOnlyMode <- _sccReadOnlyMode <$> askServerConfigCtx if -- when safe mode is enabled, don't perform any migrations | readOnlyMode == ReadOnlyModeEnabled -> pure (RETDoNothing, SCMSMigrationOnHold "read-only mode enabled") -- when eventing mode is disabled, don't perform any migrations | eventingMode == EventingDisabled -> pure (RETDoNothing, SCMSMigrationOnHold "eventing mode disabled") -- when maintenance mode is enabled, don't perform any migrations | maintenanceMode == (MaintenanceModeEnabled ()) -> pure (RETDoNothing, SCMSMigrationOnHold "maintenance mode enabled") | otherwise -> do -- The `initCatalogForSource` action is retried here because -- in cloud there will be multiple workers (graphql-engine instances) -- trying to migrate the source catalog, when needed. This introduces -- a race condition as both the workers try to migrate the source catalog -- concurrently and when one of them succeeds the other ones will fail -- and be in an inconsistent state. To avoid the inconsistency, we retry -- migrating the catalog on error and in the retry `initCatalogForSource` -- will see that the catalog is already migrated, so it won't attempt the -- migration again liftEither =<< Retry.retrying ( Retry.constantDelay (fromIntegral $ diffTimeToMicroSeconds $ seconds $ Seconds 10) <> Retry.limitRetries 3 ) (const $ return . isLeft) (const $ runExceptT $ prepareCatalog @b sourceConfig) else pure (RETDoNothing, SCMSUninitializedSource) buildSource :: forall b arr m. ( ArrowChoice arr, Inc.ArrowDistribute arr, Inc.ArrowCache m arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, HasServerConfigCtx m, MonadError QErr m, BackendMetadata b, GetAggregationPredicatesDeps b ) => ( HashMap SourceName (AB.AnyBackend PartiallyResolvedSource), SourceMetadata b, SourceConfig b, HashMap (TableName b) (TableCoreInfoG b (ColumnInfo b) (ColumnInfo b)), HashMap (TableName b) (EventTriggerInfoMap b), DBTablesMetadata b, DBFunctionsMetadata b, PartiallyResolvedRemoteSchemaMap, OrderedRoles ) `arr` BackendSourceInfo buildSource = proc (allSources, sourceMetadata, sourceConfig, tablesRawInfo, eventTriggerInfoMaps, _dbTables, dbFunctions, remoteSchemaMap, orderedRoles) -> do let SourceMetadata sourceName _backendKind tables functions _ queryTagsConfig sourceCustomization _healthCheckConfig = sourceMetadata tablesMetadata = OMap.elems tables (_, nonColumnInputs, permissions) = unzip3 $ map mkTableInputs tablesMetadata alignTableMap :: HashMap (TableName b) a -> HashMap (TableName b) c -> HashMap (TableName b) (a, c) alignTableMap = M.intersectionWith (,) -- relationships and computed fields let nonColumnsByTable = mapFromL _nctiTable nonColumnInputs tableCoreInfos :: HashMap (TableName b) (TableCoreInfo b) <- (| Inc.keyed ( \_ (tableRawInfo, nonColumnInput) -> do let columns = _tciFieldInfoMap tableRawInfo allFields :: FieldInfoMap (FieldInfo b) <- addNonColumnFields -< (allSources, sourceName, tablesRawInfo, columns, remoteSchemaMap, dbFunctions, nonColumnInput) returnA -< (tableRawInfo {_tciFieldInfoMap = allFields}) ) |) (tablesRawInfo `alignTableMap` nonColumnsByTable) tableCoreInfosDep <- Inc.newDependency -< tableCoreInfos -- permissions tableCache <- (| Inc.keyed ( \_ ((tableCoreInfo, permissionInputs), eventTriggerInfos) -> do let tableFields = _tciFieldInfoMap tableCoreInfo permissionInfos <- buildTablePermissions -< (Proxy :: Proxy b, sourceName, tableCoreInfosDep, tableFields, permissionInputs, orderedRoles) returnA -< TableInfo tableCoreInfo permissionInfos eventTriggerInfos (mkAdminRolePermInfo tableCoreInfo) ) |) (tableCoreInfos `alignTableMap` mapFromL _tpiTable permissions `alignTableMap` eventTriggerInfoMaps) -- not forcing the evaluation here results in a measurable negative impact -- on memory residency as measured by our benchmark !defaultNC <- bindA -< _sccDefaultNamingConvention <$> askServerConfigCtx !isNamingConventionEnabled <- bindA -< ((EFNamingConventions `elem`) . _sccExperimentalFeatures) <$> askServerConfigCtx !namingConv <- bindA -< if isNamingConventionEnabled then getNamingCase sourceCustomization (namingConventionSupport @b) defaultNC else pure HasuraCase let resolvedCustomization = mkResolvedSourceCustomization sourceCustomization namingConv -- sql functions functionCache <- (mapFromL _fmFunction (OMap.elems functions) >- returnA) >-> (| Inc.keyed ( \_ (FunctionMetadata qf config functionPermissions comment) -> do let systemDefined = SystemDefined False definition = toJSON $ TrackFunction @b qf metadataObject = MetadataObject ( MOSourceObjId sourceName $ AB.mkAnyBackend $ SMOFunction @b qf ) definition schemaObject = SOSourceObj sourceName $ AB.mkAnyBackend $ SOIFunction @b qf addFunctionContext e = "in function " <> qf <<> ": " <> e (| withRecordInconsistency ( (| modifyErrA ( do let funcDefs = fromMaybe [] $ M.lookup qf dbFunctions rawfunctionInfo <- bindErrorA -< handleMultipleFunctions @b qf funcDefs let metadataPermissions = mapFromL _fpmRole functionPermissions permissionsMap = mkBooleanPermissionMap FunctionPermissionInfo metadataPermissions orderedRoles (functionInfo, dep) <- bindErrorA -< buildFunctionInfo sourceName qf systemDefined config permissionsMap rawfunctionInfo comment namingConv recordDependencies -< (metadataObject, schemaObject, [dep]) returnA -< functionInfo ) |) addFunctionContext ) |) metadataObject ) |) >-> (\infos -> catMaybes infos >- returnA) returnA -< AB.mkAnyBackend $ SourceInfo sourceName tableCache functionCache sourceConfig queryTagsConfig resolvedCustomization buildAndCollectInfo :: forall arr m. ( ArrowChoice arr, Inc.ArrowDistribute arr, Inc.ArrowCache m arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, MonadIO m, MonadError QErr m, MonadReader BuildReason m, MonadBaseControl IO m, HasHttpManagerM m, HasServerConfigCtx m, MonadResolveSource m ) => (Metadata, Inc.Dependency InvalidationKeys) `arr` BuildOutputs buildAndCollectInfo = proc (metadata, invalidationKeys) -> do let Metadata sources remoteSchemas collections _metadataAllowlist customTypes actions cronTriggers endpoints _apiLimits _metricsConfig inheritedRoles _introspectionDisabledRoles _networkConfig backendConfigs openTelemetryConfig = metadata actionRoles = map _apmRole . _amPermissions =<< OMap.elems actions remoteSchemaRoles = map _rspmRole . _rsmPermissions =<< OMap.elems remoteSchemas sourceRoles = HS.fromList $ concat $ OMap.elems sources >>= \(BackendSourceMetadata e) -> AB.dispatchAnyBackend @Backend e \(SourceMetadata _ _ tables _functions _ _ _ _) -> do table <- OMap.elems tables pure $ OMap.keys (_tmInsertPermissions table) <> OMap.keys (_tmSelectPermissions table) <> OMap.keys (_tmUpdatePermissions table) <> OMap.keys (_tmDeletePermissions table) inheritedRoleNames = OMap.keys inheritedRoles allRoleNames = sourceRoles <> HS.fromList (remoteSchemaRoles <> actionRoles <> inheritedRoleNames) -- roles which have some kind of permission (action/remote schema/table/function) set in the metadata let metadataRoles = mapFromL _rRoleName $ (`Role` ParentRoles mempty) <$> toList allRoleNames resolvedInheritedRoles <- buildInheritedRoles -< (allRoleNames, OMap.elems inheritedRoles) let allRoles = resolvedInheritedRoles `M.union` metadataRoles orderedRoles <- bindA -< orderRoles $ M.elems allRoles -- remote schemas let remoteSchemaInvalidationKeys = Inc.selectD #_ikRemoteSchemas invalidationKeys remoteSchemaMap <- buildRemoteSchemas env -< ((remoteSchemaInvalidationKeys, orderedRoles), OMap.elems remoteSchemas) let remoteSchemaCtxMap = M.map fst remoteSchemaMap !defaultNC <- bindA -< _sccDefaultNamingConvention <$> askServerConfigCtx !isNamingConventionEnabled <- bindA -< ((EFNamingConventions `elem`) . _sccExperimentalFeatures) <$> askServerConfigCtx let backendInvalidationKeys = Inc.selectD #_ikBackends invalidationKeys backendCache <- resolveBackendCache -< (backendInvalidationKeys, BackendMap.elems backendConfigs) let backendInfoAndSourceMetadata = joinBackendInfosToSources backendCache sources -- sources are build in two steps -- first we resolve them, and build the table cache partiallyResolvedSources <- (| Inc.keyed ( \_ exists -> AB.dispatchAnyBackendArrow @BackendMetadata @BackendEventTrigger ( proc (backendInfoAndSourceMetadata, (invalidationKeys, defaultNC, isNamingConventionEnabled)) -> do let sourceMetadata = _bcasmSourceMetadata backendInfoAndSourceMetadata sourceName = _smName sourceMetadata sourceInvalidationsKeys = Inc.selectD #_ikSources invalidationKeys maybeResolvedSource <- resolveSourceIfNeeded -< (sourceInvalidationsKeys, backendInfoAndSourceMetadata) case maybeResolvedSource of Nothing -> returnA -< Nothing Just (source :: ResolvedSource b) -> do let metadataInvalidationKey = Inc.selectD #_ikMetadata invalidationKeys (tableInputs, _, _) = unzip3 $ map mkTableInputs $ OMap.elems $ _smTables sourceMetadata !namingConv = if isNamingConventionEnabled then getNamingConvention (_smCustomization sourceMetadata) defaultNC else HasuraCase tablesCoreInfo <- buildTableCache -< ( sourceName, _rsConfig source, _rsTables source, tableInputs, metadataInvalidationKey, namingConv ) let tablesMetadata = OMap.elems $ _smTables sourceMetadata eventTriggers = map (_tmTable &&& OMap.elems . _tmEventTriggers) tablesMetadata numEventTriggers = sum $ map (length . snd) eventTriggers sourceConfig = _rsConfig source (recreateEventTriggers, sourceCatalogMigrationState) <- initCatalogIfNeeded -< (Proxy :: Proxy b, numEventTriggers > 0, sourceConfig) bindA -< unLogger logger (sourceName, sourceCatalogMigrationState) let alignTableMap :: HashMap (TableName b) a -> HashMap (TableName b) c -> HashMap (TableName b) (a, c) alignTableMap = M.intersectionWith (,) eventTriggerInfoMaps <- (| Inc.keyed ( \_ (tableCoreInfo, (_, eventTriggerConfs)) -> buildTableEventTriggers -< (sourceName, sourceConfig, tableCoreInfo, eventTriggerConfs, metadataInvalidationKey, recreateEventTriggers) ) |) (tablesCoreInfo `alignTableMap` mapFromL fst eventTriggers) returnA -< Just $ AB.mkAnyBackend @b $ PartiallyResolvedSource sourceMetadata source tablesCoreInfo eventTriggerInfoMaps ) -< (exists, (invalidationKeys, defaultNC, isNamingConventionEnabled)) ) |) (M.fromList $ OMap.toList backendInfoAndSourceMetadata) >-> (\infos -> catMaybes infos >- returnA) -- then we can build the entire source output -- we need to have the table cache of all sources to build cross-sources relationships sourcesOutput <- (| Inc.keyed ( \_ exists -> -- Note that it's a bit of a coincidence that -- 'AB.dispatchAnyBackendArrow' accepts exactly two constraints, -- and that we happen to want to apply to exactly two -- constraints. -- Ideally the function should be able to take an arbitrary -- number of constraints. AB.dispatchAnyBackendArrow @BackendMetadata @GetAggregationPredicatesDeps ( proc ( partiallyResolvedSource :: PartiallyResolvedSource b, (allResolvedSources, remoteSchemaCtxMap, orderedRoles) ) -> do let PartiallyResolvedSource sourceMetadata resolvedSource tablesInfo eventTriggers = partiallyResolvedSource ResolvedSource sourceConfig _sourceCustomization tablesMeta functionsMeta scalars = resolvedSource so <- buildSource -< ( allResolvedSources, sourceMetadata, sourceConfig, tablesInfo, eventTriggers, tablesMeta, functionsMeta, remoteSchemaCtxMap, orderedRoles ) returnA -< (so, BackendMap.singleton scalars) ) -< ( exists, (partiallyResolvedSources, remoteSchemaCtxMap, orderedRoles) ) ) |) partiallyResolvedSources remoteSchemaCache <- (remoteSchemaMap >- returnA) >-> (| Inc.keyed ( \_ (partiallyResolvedRemoteSchemaCtx, metadataObj) -> do let remoteSchemaIntrospection = irDoc $ _rscIntroOriginal partiallyResolvedRemoteSchemaCtx resolvedSchemaCtx <- (| traverseA ( \PartiallyResolvedRemoteRelationship {..} -> buildRemoteSchemaRemoteRelationship -< ( (partiallyResolvedSources, remoteSchemaCtxMap), (_rscName partiallyResolvedRemoteSchemaCtx, remoteSchemaIntrospection, _prrrTypeName, _prrrDefinition) ) ) |) partiallyResolvedRemoteSchemaCtx returnA -< (catMaybes $ resolvedSchemaCtx, metadataObj) ) |) resolvedEndpoints <- buildInfoMap fst mkEndpointMetadataObject buildEndpoint -< (collections, OMap.toList endpoints) -- custom types let scalarsMap = mconcat $ map snd $ M.elems sourcesOutput sourcesCache = M.map fst sourcesOutput maybeResolvedCustomTypes <- (| withRecordInconsistency ( bindErrorA -< resolveCustomTypes sourcesCache customTypes scalarsMap ) |) (MetadataObject MOCustomTypes $ toJSON customTypes) -- actions let actionList = OMap.elems actions (actionCache, annotatedCustomTypes) <- case maybeResolvedCustomTypes of Just resolvedCustomTypes -> do actionCache' <- buildActions -< ((resolvedCustomTypes, scalarsMap, orderedRoles), actionList) returnA -< (actionCache', resolvedCustomTypes) -- If the custom types themselves are inconsistent, we can’t really do -- anything with actions, so just mark them all inconsistent. Nothing -> do recordInconsistencies -< ( map mkActionMetadataObject actionList, "custom types are inconsistent" ) returnA -< (mempty, mempty) cronTriggersMap <- buildCronTriggers -< ((), OMap.elems cronTriggers) -- open telemetry mOtelExporterInfo <- let exporterOtlp = _ocExporterOtlp openTelemetryConfig in (| withRecordInconsistency ( bindErrorA -< liftEither (parseOtelExporterConfig env exporterOtlp) ) |) (MetadataObject (MOOpenTelemetry OtelSubobjectExporterOtlp) (toJSON exporterOtlp)) mOtelBatchSpanProcessorInfo <- let batchSpanProcessor = _ocBatchSpanProcessor openTelemetryConfig in (| withRecordInconsistency ( bindErrorA -< liftEither (parseOtelBatchSpanProcessorConfig batchSpanProcessor) ) |) (MetadataObject (MOOpenTelemetry OtelSubobjectBatchSpanProcessor) (toJSON batchSpanProcessor)) let openTelemetryInfo = -- Disable configuration for a data type if it is not in the enabled set OpenTelemetryInfo mOtelExporterInfo ( if OtelTraces `S.member` _ocEnabledDataTypes openTelemetryConfig then mOtelBatchSpanProcessorInfo else Nothing ) returnA -< BuildOutputs { _boSources = M.map fst sourcesOutput, _boActions = actionCache, _boRemoteSchemas = remoteSchemaCache, _boCustomTypes = annotatedCustomTypes, _boCronTriggers = cronTriggersMap, _boEndpoints = resolvedEndpoints, _boRoles = mapFromL _rRoleName $ _unOrderedRoles orderedRoles, _boBackendCache = backendCache, _boOpenTelemetryInfo = openTelemetryInfo } mkEndpointMetadataObject (name, createEndpoint) = let objectId = MOEndpoint name in MetadataObject objectId (toJSON createEndpoint) buildEndpoint :: (ArrowChoice arr, ArrowKleisli m arr, MonadError QErr m, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr) => (InsOrdHashMap CollectionName CreateCollection, (EndpointName, CreateEndpoint)) `arr` Maybe (EndpointMetadata GQLQueryWithText) buildEndpoint = proc (collections, e@(name, createEndpoint)) -> do let endpoint = createEndpoint -- QueryReference collName queryName = _edQuery endpoint addContext err = "in endpoint " <> toTxt (unEndpointName name) <> ": " <> err (| withRecordInconsistency ( (| modifyErrA (bindErrorA -< resolveEndpoint collections endpoint) |) addContext ) |) (mkEndpointMetadataObject e) resolveEndpoint :: QErrM m => InsOrdHashMap CollectionName CreateCollection -> EndpointMetadata QueryReference -> m (EndpointMetadata GQLQueryWithText) resolveEndpoint collections = traverse $ \(QueryReference collName queryName) -> do collection <- onNothing (OMap.lookup collName collections) (throw400 NotExists $ "collection with name " <> toTxt collName <> " does not exist") listedQuery <- flip onNothing ( throw400 NotExists $ "query with name " <> toTxt queryName <> " does not exist in collection " <> toTxt collName ) $ find ((== queryName) . _lqName) (_cdQueries (_ccDefinition collection)) let lq@(GQLQueryWithText lqq) = _lqQuery listedQuery ds = G.getExecutableDefinitions $ unGQLQuery $ snd lqq case ds of [G.ExecutableDefinitionOperation (G.OperationDefinitionTyped d)] | G._todType d == G.OperationTypeSubscription -> throw405 $ "query with name " <> toTxt queryName <> " is a subscription" | otherwise -> pure () [] -> throw400 BadRequest $ "query with name " <> toTxt queryName <> " has no definitions." _ -> throw400 BadRequest $ "query with name " <> toTxt queryName <> " has multiple definitions." pure lq mkEventTriggerMetadataObject :: forall b a c. Backend b => (a, SourceName, c, TableName b, RecreateEventTriggers, EventTriggerConf b) -> MetadataObject mkEventTriggerMetadataObject (_, source, _, table, _, eventTriggerConf) = let objectId = MOSourceObjId source $ AB.mkAnyBackend $ SMOTableObj @b table $ MTOTrigger $ etcName eventTriggerConf definition = object ["table" .= table, "configuration" .= eventTriggerConf] in MetadataObject objectId definition mkCronTriggerMetadataObject catalogCronTrigger = let definition = toJSON catalogCronTrigger in MetadataObject (MOCronTrigger (ctName catalogCronTrigger)) definition mkActionMetadataObject (ActionMetadata name comment defn _) = MetadataObject (MOAction name) (toJSON $ CreateAction name defn comment) mkInheritedRoleMetadataObject inheritedRole@(Role roleName _) = MetadataObject (MOInheritedRole roleName) (toJSON inheritedRole) buildTableEventTriggers :: forall arr m b. ( ArrowChoice arr, Inc.ArrowDistribute arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, Inc.ArrowCache m arr, MonadIO m, MonadError QErr m, MonadBaseControl IO m, MonadReader BuildReason m, HasServerConfigCtx m, BackendMetadata b, BackendEventTrigger b ) => ( SourceName, SourceConfig b, TableCoreInfoG b (ColumnInfo b) (ColumnInfo b), [EventTriggerConf b], Inc.Dependency Inc.InvalidationKey, RecreateEventTriggers ) `arr` (EventTriggerInfoMap b) buildTableEventTriggers = proc (sourceName, sourceConfig, tableInfo, eventTriggerConfs, metadataInvalidationKey, migrationRecreateEventTriggers) -> buildInfoMap (etcName . (^. _6)) (mkEventTriggerMetadataObject @b) buildEventTrigger -< (tableInfo, map (metadataInvalidationKey,sourceName,sourceConfig,_tciName tableInfo,migrationRecreateEventTriggers,) eventTriggerConfs) where buildEventTrigger = proc (tableInfo, (metadataInvalidationKey, source, sourceConfig, table, migrationRecreateEventTriggers, eventTriggerConf)) -> do let triggerName = etcName eventTriggerConf metadataObject = mkEventTriggerMetadataObject @b (metadataInvalidationKey, source, sourceConfig, table, migrationRecreateEventTriggers, eventTriggerConf) schemaObjectId = SOSourceObj source $ AB.mkAnyBackend $ SOITableObj @b table $ TOTrigger triggerName addTriggerContext e = "in event trigger " <> triggerName <<> ": " <> e buildReason <- bindA -< ask let reloadMetadataRecreateEventTrigger = case buildReason of CatalogSync -> RETDoNothing CatalogUpdate Nothing -> RETDoNothing CatalogUpdate (Just sources) -> if source `elem` sources then RETRecreate else RETDoNothing (| withRecordInconsistency ( (| modifyErrA ( do (info, dependencies) <- bindErrorA -< buildEventTriggerInfo @b env source table eventTriggerConf serverConfigCtx <- bindA -< askServerConfigCtx let isCatalogUpdate = case buildReason of CatalogUpdate _ -> True CatalogSync -> False tableColumns = M.elems $ _tciFieldInfoMap tableInfo if ( _sccMaintenanceMode serverConfigCtx == MaintenanceModeDisabled && _sccReadOnlyMode serverConfigCtx == ReadOnlyModeDisabled ) then do bindA -< when (reloadMetadataRecreateEventTrigger == RETRecreate) $ -- This is the case when the user sets `recreate_event_triggers` -- to `true` in `reload_metadata`, in this case, we recreate -- the SQL trigger by force, even if it may not be necessary liftEitherM $ createTableEventTrigger @b serverConfigCtx sourceConfig table tableColumns triggerName (etcDefinition eventTriggerConf) (_tciPrimaryKey tableInfo) if isCatalogUpdate || migrationRecreateEventTriggers == RETRecreate then do recreateTriggerIfNeeded -< ( table, tableColumns, triggerName, etcDefinition eventTriggerConf, sourceConfig, (_tciPrimaryKey tableInfo) ) -- We check if the SQL triggers for the event triggers -- are present. If any SQL triggers are missing, those are -- created. bindA -< createMissingSQLTriggers sourceConfig table (tableColumns, _tciPrimaryKey tableInfo) triggerName (etcDefinition eventTriggerConf) else bindA -< pure () else bindA -< pure () recordDependencies -< (metadataObject, schemaObjectId, dependencies) returnA -< info ) |) (addTableContext @b table . addTriggerContext) ) |) metadataObject recreateTriggerIfNeeded = -- using `Inc.cache` here means that the response will be cached for the given output and the -- next time this arrow recieves the same input, the cached response will be returned and the -- computation will not be done again. Inc.cache proc ( tableName, tableColumns, triggerName, triggerDefinition, sourceConfig, primaryKey ) -> do bindA -< do serverConfigCtx <- askServerConfigCtx liftEitherM $ createTableEventTrigger @b serverConfigCtx sourceConfig tableName tableColumns triggerName triggerDefinition primaryKey buildCronTriggers :: ( ArrowChoice arr, Inc.ArrowDistribute arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, Inc.ArrowCache m arr, MonadError QErr m ) => ((), [CronTriggerMetadata]) `arr` HashMap TriggerName CronTriggerInfo buildCronTriggers = buildInfoMap ctName mkCronTriggerMetadataObject buildCronTrigger where buildCronTrigger = proc (_, cronTrigger) -> do let triggerName = triggerNameToTxt $ ctName cronTrigger addCronTriggerContext e = "in cron trigger " <> triggerName <> ": " <> e (| withRecordInconsistency ( (| modifyErrA (bindErrorA -< resolveCronTrigger env cronTrigger) |) addCronTriggerContext ) |) (mkCronTriggerMetadataObject cronTrigger) buildInheritedRoles :: ( ArrowChoice arr, Inc.ArrowDistribute arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, Inc.ArrowCache m arr, MonadError QErr m ) => (HashSet RoleName, [InheritedRole]) `arr` HashMap RoleName Role buildInheritedRoles = buildInfoMap _rRoleName mkInheritedRoleMetadataObject buildInheritedRole where buildInheritedRole = proc (allRoles, inheritedRole) -> do let addInheritedRoleContext e = "in inherited role " <> roleNameToTxt (_rRoleName inheritedRole) <> ": " <> e metadataObject = mkInheritedRoleMetadataObject inheritedRole schemaObject = SORole $ _rRoleName inheritedRole (| withRecordInconsistency ( (| modifyErrA ( do (resolvedInheritedRole, dependencies) <- bindA -< resolveInheritedRole allRoles inheritedRole recordDependencies -< (metadataObject, schemaObject, dependencies) returnA -< resolvedInheritedRole ) |) addInheritedRoleContext ) |) metadataObject buildActions :: ( ArrowChoice arr, Inc.ArrowDistribute arr, Inc.ArrowCache m arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr ) => ( (AnnotatedCustomTypes, BackendMap ScalarMap, OrderedRoles), [ActionMetadata] ) `arr` HashMap ActionName ActionInfo buildActions = buildInfoMap _amName mkActionMetadataObject buildAction where buildAction = proc ((resolvedCustomTypes, scalarsMap, orderedRoles), action) -> do let ActionMetadata name comment def actionPermissions = action addActionContext e = "in action " <> name <<> "; " <> e (| withRecordInconsistency ( (| modifyErrA ( do (resolvedDef, outObject) <- liftEitherA <<< bindA -< runExceptT $ resolveAction env resolvedCustomTypes def scalarsMap let permissionInfos = map (ActionPermissionInfo . _apmRole) actionPermissions metadataPermissionMap = mapFromL _apiRole permissionInfos permissionsMap = mkBooleanPermissionMap ActionPermissionInfo metadataPermissionMap orderedRoles forwardClientHeaders = _adForwardClientHeaders resolvedDef outputType = unGraphQLType $ _adOutputType def returnA -< ActionInfo name (outputType, outObject) resolvedDef permissionsMap forwardClientHeaders comment ) |) addActionContext ) |) (mkActionMetadataObject action) buildRemoteSchemaRemoteRelationship :: forall arr m. ( ArrowChoice arr, ArrowWriter (Seq (Either InconsistentMetadata MetadataDependency)) arr, ArrowKleisli m arr, MonadError QErr m ) => ( (HashMap SourceName (AB.AnyBackend PartiallyResolvedSource), PartiallyResolvedRemoteSchemaMap), (RemoteSchemaName, RemoteSchemaIntrospection, G.Name, RemoteRelationship) ) `arr` Maybe (RemoteFieldInfo G.Name) buildRemoteSchemaRemoteRelationship = proc ( (allSources, remoteSchemaMap), (remoteSchema, remoteSchemaIntrospection, typeName, rr@RemoteRelationship {..}) ) -> do let metadataObject = mkRemoteSchemaRemoteRelationshipMetadataObject (remoteSchema, typeName, rr) schemaObj = SORemoteSchemaRemoteRelationship remoteSchema typeName _rrName addRemoteRelationshipContext e = "in remote relationship" <> _rrName <<> ": " <> e (| withRecordInconsistency ( (| modifyErrA ( do allowedLHSJoinFields <- bindErrorA -< getRemoteSchemaEntityJoinColumns remoteSchema remoteSchemaIntrospection typeName (remoteField, rhsDependencies) <- bindErrorA -< buildRemoteFieldInfo (remoteSchemaToLHSIdentifier remoteSchema) allowedLHSJoinFields rr allSources remoteSchemaMap -- buildRemoteFieldInfo only knows how to construct dependencies on the RHS of the join condition, -- so the dependencies on the remote relationship on the LHS entity have to be computed here let lhsDependencies = -- a direct dependency on the remote schema on which this is defined [SchemaDependency (SORemoteSchema remoteSchema) DRRemoteRelationship] recordDependencies -< (metadataObject, schemaObj, lhsDependencies <> rhsDependencies) returnA -< remoteField ) |) addRemoteRelationshipContext ) |) metadataObject mkRemoteSchemaRemoteRelationshipMetadataObject :: (RemoteSchemaName, G.Name, RemoteRelationship) -> MetadataObject mkRemoteSchemaRemoteRelationshipMetadataObject (remoteSchemaName, typeName, RemoteRelationship {..}) = let objectId = MORemoteSchemaRemoteRelationship remoteSchemaName typeName _rrName in MetadataObject objectId $ toJSON $ CreateRemoteSchemaRemoteRelationship remoteSchemaName typeName _rrName _rrDefinition data BackendInfoAndSourceMetadata b = BackendInfoAndSourceMetadata { _bcasmBackendInfo :: BackendInfo b, _bcasmSourceMetadata :: SourceMetadata b } deriving stock (Generic) deriving instance (Backend b) => Show (BackendInfoAndSourceMetadata b) deriving instance (Backend b) => Eq (BackendInfoAndSourceMetadata b) instance (Backend b) => Inc.Cacheable (BackendInfoAndSourceMetadata b) joinBackendInfosToSources :: BackendCache -> InsOrdHashMap SourceName BackendSourceMetadata -> InsOrdHashMap SourceName (AB.AnyBackend BackendInfoAndSourceMetadata) joinBackendInfosToSources backendInfos sources = flip OMap.map sources $ \abSourceMetadata -> AB.dispatchAnyBackend @Backend (unBackendSourceMetadata abSourceMetadata) $ \(sourceMetadata :: SourceMetadata b) -> let _bcasmBackendInfo = maybe mempty unBackendInfoWrapper (BackendMap.lookup @b backendInfos) _bcasmSourceMetadata = sourceMetadata in AB.mkAnyBackend @b BackendInfoAndSourceMetadata {..} {- Note [Keep invalidation keys for inconsistent objects] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ After building the schema cache, we prune InvalidationKeys for objects that no longer exist in the schema to avoid leaking memory for objects that have been dropped. However, note that we *don’t* want to drop keys for objects that are simply inconsistent! Why? The object is still in the metadata, so next time we reload it, we’ll reprocess that object. We want to reuse the cache if its definition hasn’t changed, but if we dropped the invalidation key, it will incorrectly be reprocessed (since the invalidation key changed from present to absent). -}