graphql-engine/server/src-lib/Hasura/GraphQL/Schema.hs
Antoine Leblanc eaba2e08d3 Clean Relay's code, break schema cycles, introduce Node ID V2
## Motivation

This PR rewrites most of Relay to achieve the following:
- ~~fix a bug in which the same node id could refer to two different tables in the schema~~
- remove one of the few remaining uses of the source cache in the schema building code

In doing so, it also:
- simplifies the `BackendSchema` class by removing `node` from it,
- makes it much easier for other backends to support Relay,
- documents, re-organizes, and clarifies the code.

## Description

This PR introduces a new `NodeId` version ~~, and adapts the Postgres code to always generate this V2 version~~. This new id contains the source name, in addition to the table name, in order to disambiguate similar table names across different sources (which is now possible with source customization). In doing so, it now explicitly handles that case for V1 node ids, and returns an explicit error message instead of running the risk of _silently returning the wrong information_.

Furthermore, it adapts `nodeField` to support multiple backends; most of the code was trivial to generalize, and as a result it lowers the cost of entry for other backends, that now only need to support `AFNodeId` in their translation layer.

Finally, it removes one more cycle in the schema building code, by using the same trick we used for remote relationships instead of using the memoization trick of #4576.

## Remaining work

- ~~[ ]write a Changelog entry~~
- ~~[x] adapt all tests that were asserting on an old node id~~

## Future work

This PR was adapted from its original form to avoid a breaking change: while it introduces a Node ID V2, we keep generating V1 IDs and the parser rejects V2 IDs. It will be easy to make the switch at a later data in a subsequent PR.

PR-URL: https://github.com/hasura/graphql-engine-mono/pull/4593
GitOrigin-RevId: 88e5cb91e8b0646900547fa8c7c0e1463de267a1
2022-06-07 13:36:29 +00:00

904 lines
40 KiB
Haskell

{-# LANGUAGE QuasiQuotes #-}
{-# LANGUAGE ViewPatterns #-}
module Hasura.GraphQL.Schema
( buildGQLContext,
)
where
import Control.Concurrent.Extended (forConcurrentlyEIO)
import Control.Lens.Extended
import Data.Aeson.Ordered qualified as JO
import Data.Has
import Data.HashMap.Strict qualified as Map
import Data.HashSet qualified as Set
import Data.List.Extended (duplicates)
import Data.Text.Extended
import Data.Text.NonEmpty qualified as NT
import Hasura.Base.Error
import Hasura.GraphQL.Context
import Hasura.GraphQL.Execute.Types
import Hasura.GraphQL.Namespace
import Hasura.GraphQL.Parser
( Kind (..),
Parser,
Schema (..),
)
import Hasura.GraphQL.Parser qualified as P
import Hasura.GraphQL.Parser.Class
import Hasura.GraphQL.Parser.Constants qualified as G
import Hasura.GraphQL.Parser.Internal.Parser (FieldParser (..))
import Hasura.GraphQL.Parser.Schema.Convert (convertToSchemaIntrospection)
import Hasura.GraphQL.Schema.Backend
import Hasura.GraphQL.Schema.Common
import Hasura.GraphQL.Schema.Instances ()
import Hasura.GraphQL.Schema.Introspect
import Hasura.GraphQL.Schema.Postgres
import Hasura.GraphQL.Schema.Relay
import Hasura.GraphQL.Schema.Remote (buildRemoteParser)
import Hasura.GraphQL.Schema.RemoteRelationship
import Hasura.GraphQL.Schema.Table
import Hasura.Prelude
import Hasura.RQL.IR
import Hasura.RQL.Types.Action
import Hasura.RQL.Types.Backend
import Hasura.RQL.Types.Common
import Hasura.RQL.Types.CustomTypes
import Hasura.RQL.Types.Function
import Hasura.RQL.Types.Metadata.Object
import Hasura.RQL.Types.Permission
import Hasura.RQL.Types.QueryTags
import Hasura.RQL.Types.RemoteSchema
import Hasura.RQL.Types.SchemaCache hiding (askTableInfo)
import Hasura.RQL.Types.Source
import Hasura.RQL.Types.SourceCustomization
import Hasura.RQL.Types.Table
import Hasura.SQL.AnyBackend qualified as AB
import Hasura.SQL.Tag (HasTag)
import Hasura.Server.Types
import Hasura.Session
import Language.GraphQL.Draft.Syntax qualified as G
-------------------------------------------------------------------------------
-- Building contexts
-- | Builds the full GraphQL context for a given query type.
--
-- A 'GQLContext' stores how an incoming request should be processed: how to
-- translate each incoming field of a request into a corresponding semantic
-- representation. There is a different one per 'Role', as each role might have
-- different permissions, and therefore not access to the same set of objects in
-- the schema.
--
-- This function takes all necessary information from the metadata, and the
-- 'GraphQLQueryType', and builds all relevant contexts: a hash map from
-- 'RoleName' to their 'GQLContext' and the "default" context for
-- unauthenticated users.
--
-- When building the schema for each role, we treat the remote schemas as
-- "second-class citizens" compared to sources; more specifically, we attempt to
-- detect whether the inclusion of a given remote schema would result in root
-- fields conflict, and only keep schemas that don't generate any. This results
-- in a partial schema being available to the users, and a better error message
-- than would arise from 'safeSelectionSet'.
buildGQLContext ::
forall m.
( MonadError QErr m,
MonadIO m
) =>
ServerConfigCtx ->
GraphQLQueryType ->
SourceCache ->
HashMap RemoteSchemaName (RemoteSchemaCtx, MetadataObject) ->
ActionCache ->
AnnotatedCustomTypes ->
m
( G.SchemaIntrospection,
HashMap RoleName (RoleContext GQLContext),
GQLContext,
HashSet InconsistentMetadata
)
buildGQLContext ServerConfigCtx {..} queryType sources allRemoteSchemas allActions customTypes = do
let remoteSchemasRoles = concatMap (Map.keys . _rscPermissions . fst . snd) $ Map.toList allRemoteSchemas
nonTableRoles =
Set.insert adminRoleName $
(allActionInfos ^.. folded . aiPermissions . to Map.keys . folded)
<> Set.fromList (bool mempty remoteSchemasRoles $ _sccRemoteSchemaPermsCtx == RemoteSchemaPermsEnabled)
allActionInfos = Map.elems allActions
allTableRoles = Set.fromList $ getTableRoles =<< Map.elems sources
allRoles = nonTableRoles <> allTableRoles
defaultNC = _sccDefaultNamingConvention
roleContexts <-
-- Buld role contexts in parallel. We'd prefer deterministic parallelism
-- but that isn't really acheivable (see mono #3829). NOTE: the admin role
-- will still be a bottleneck here, even on huge_schema which has many
-- roles.
fmap Map.fromList $
forConcurrentlyEIO 10 (Set.toList allRoles) $ \role ->
(role,)
<$> case queryType of
QueryHasura ->
buildRoleContext
(_sccSQLGenCtx, _sccFunctionPermsCtx)
sources
allRemoteSchemas
allActionInfos
customTypes
role
_sccRemoteSchemaPermsCtx
_sccExperimentalFeatures
(bool StreamingSubscriptionsDisabled StreamingSubscriptionsEnabled $ EFStreamingSubscriptions `elem` _sccExperimentalFeatures)
defaultNC
QueryRelay ->
(,mempty,G.SchemaIntrospection mempty)
<$> buildRelayRoleContext
(_sccSQLGenCtx, _sccFunctionPermsCtx)
sources
allActionInfos
customTypes
role
_sccExperimentalFeatures
defaultNC
adminIntrospection <-
case Map.lookup adminRoleName roleContexts of
Just (_context, _errors, introspection) -> pure introspection
Nothing -> throw500 "buildGQLContext failed to build for the admin role"
(unauthenticated, unauthenticatedRemotesErrors) <- unauthenticatedContext allRemoteSchemas _sccRemoteSchemaPermsCtx
pure
( adminIntrospection,
view _1 <$> roleContexts,
unauthenticated,
Set.unions $ unauthenticatedRemotesErrors : map (view _2) (Map.elems roleContexts)
)
-- | Build the @QueryHasura@ context for a given role.
buildRoleContext ::
forall m.
(MonadError QErr m, MonadIO m) =>
(SQLGenCtx, FunctionPermissionsCtx) ->
SourceCache ->
HashMap RemoteSchemaName (RemoteSchemaCtx, MetadataObject) ->
[ActionInfo] ->
AnnotatedCustomTypes ->
RoleName ->
RemoteSchemaPermsCtx ->
Set.HashSet ExperimentalFeature ->
StreamingSubscriptionsCtx ->
Maybe NamingCase ->
m
( RoleContext GQLContext,
HashSet InconsistentMetadata,
G.SchemaIntrospection
)
buildRoleContext options sources remotes allActionInfos customTypes role remoteSchemaPermsCtx expFeatures streamingSubscriptionsCtx globalDefaultNC = do
let ( SQLGenCtx stringifyNum dangerousBooleanCollapse optimizePermissionFilters,
functionPermsCtx
) = options
schemaOptions =
SchemaOptions
stringifyNum
dangerousBooleanCollapse
functionPermsCtx
remoteSchemaPermsCtx
optimizePermissionFilters
schemaContext =
SchemaContext
HasuraSchema
sources
(remoteRelationshipField sources (fst <$> remotes))
runMonadSchema schemaOptions schemaContext role $ do
-- build all sources
(sourcesQueryFields, sourcesMutationFrontendFields, sourcesMutationBackendFields, subscriptionFields) <-
fmap mconcat $ traverse (buildBackendSource buildSource) $ toList sources
-- build all remote schemas
-- we only keep the ones that don't result in a name conflict
(remoteSchemaFields, remoteSchemaErrors) <-
buildAndValidateRemoteSchemas remotes sourcesQueryFields sourcesMutationBackendFields role remoteSchemaPermsCtx
let remotesQueryFields = concatMap piQuery remoteSchemaFields
remotesMutationFields = concat $ mapMaybe piMutation remoteSchemaFields
remotesSubscriptionFields = concat $ mapMaybe piSubscription remoteSchemaFields
mutationParserFrontend <-
buildMutationParser remotesMutationFields allActionInfos customTypes sourcesMutationFrontendFields
mutationParserBackend <-
buildMutationParser remotesMutationFields allActionInfos customTypes sourcesMutationBackendFields
subscriptionParser <-
buildSubscriptionParser subscriptionFields allActionInfos customTypes remotesSubscriptionFields
queryParserFrontend <-
buildQueryParser sourcesQueryFields remotesQueryFields allActionInfos customTypes mutationParserFrontend subscriptionParser
queryParserBackend <-
buildQueryParser sourcesQueryFields remotesQueryFields allActionInfos customTypes mutationParserBackend subscriptionParser
-- In order to catch errors early, we attempt to generate the data
-- required for introspection, which ends up doing a few correctness
-- checks in the GraphQL schema. Furthermore, we want to persist this
-- information in the case of the admin role.
introspectionSchema <- do
result <-
convertToSchemaIntrospection
<$> buildIntrospectionSchema
(P.parserType queryParserBackend)
(P.parserType <$> mutationParserBackend)
(P.parserType <$> subscriptionParser)
pure $
-- TODO(nicuveo): we treat the admin role differently in this function,
-- which is a bit inelegant; we might want to refactor this function and
-- split it into several steps, so that we can make a separate function for
-- the admin role that reuses the common parts and avoid such tests.
if role == adminRoleName
then result
else G.SchemaIntrospection mempty
void $
buildIntrospectionSchema
(P.parserType queryParserFrontend)
(P.parserType <$> mutationParserFrontend)
(P.parserType <$> subscriptionParser)
-- (since we're running this in parallel in caller, be strict)
let !frontendContext =
GQLContext
(finalizeParser queryParserFrontend)
(finalizeParser <$> mutationParserFrontend)
(finalizeParser <$> subscriptionParser)
!backendContext =
GQLContext
(finalizeParser queryParserBackend)
(finalizeParser <$> mutationParserBackend)
(finalizeParser <$> subscriptionParser)
pure
( RoleContext frontendContext $ Just backendContext,
remoteSchemaErrors,
introspectionSchema
)
where
buildSource ::
forall b.
BackendSchema b =>
SourceInfo b ->
ConcreteSchemaT
m
( [FieldParser (P.ParseT Identity) (NamespacedField (QueryRootField UnpreparedValue))],
[FieldParser (P.ParseT Identity) (NamespacedField (MutationRootField UnpreparedValue))],
[FieldParser (P.ParseT Identity) (NamespacedField (MutationRootField UnpreparedValue))],
[FieldParser (P.ParseT Identity) (NamespacedField (QueryRootField UnpreparedValue))]
)
buildSource sourceInfo@(SourceInfo _ tables functions _ _ sourceCustomization') =
withSourceCustomization sourceCustomization (namingConventionSupport @b) globalDefaultNC do
let validFunctions = takeValidFunctions functions
validTables = takeValidTables tables
mkTypename <- asks getter
(uncustomizedQueryRootFields, uncustomizedSubscriptionRootFields) <-
buildQueryAndSubscriptionFields sourceInfo validTables validFunctions streamingSubscriptionsCtx
(,,,)
<$> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__query))
(pure uncustomizedQueryRootFields)
<*> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__mutation_frontend))
(buildMutationFields Frontend sourceInfo validTables validFunctions)
<*> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__mutation_backend))
(buildMutationFields Backend sourceInfo validTables validFunctions)
<*> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__subscription))
(pure uncustomizedSubscriptionRootFields)
where
sourceCustomization =
if EFNamingConventions `elem` expFeatures
then sourceCustomization'
else sourceCustomization' {_scNamingConvention = Nothing}
buildRelayRoleContext ::
forall m.
(MonadError QErr m, MonadIO m) =>
(SQLGenCtx, FunctionPermissionsCtx) ->
SourceCache ->
[ActionInfo] ->
AnnotatedCustomTypes ->
RoleName ->
Set.HashSet ExperimentalFeature ->
Maybe NamingCase ->
m (RoleContext GQLContext)
buildRelayRoleContext options sources allActionInfos customTypes role expFeatures globalDefaultNC = do
let ( SQLGenCtx stringifyNum dangerousBooleanCollapse optimizePermissionFilters,
functionPermsCtx
) = options
schemaOptions =
SchemaOptions
stringifyNum
dangerousBooleanCollapse
functionPermsCtx
RemoteSchemaPermsDisabled
optimizePermissionFilters
-- TODO: At the time of writing this, remote schema queries are not supported in relay.
-- When they are supported, we should get do what `buildRoleContext` does. Since, they
-- are not supported yet, we use `mempty` below for `RemoteSchemaMap`.
schemaContext =
SchemaContext
(RelaySchema $ nodeInterface sources)
sources
(remoteRelationshipField sources mempty)
runMonadSchema schemaOptions schemaContext role do
node <- fmap NotNamespaced <$> nodeField sources
fieldsList <- traverse (buildBackendSource buildSource) $ toList sources
let (queryFields, mutationFrontendFields, mutationBackendFields, subscriptionFields) = mconcat fieldsList
allQueryFields = node : queryFields
allSubscriptionFields = node : subscriptionFields
-- Remote schema mutations aren't exposed in relay because many times it throws
-- the conflicting definitions error between the relay types like `Node`, `PageInfo` etc
mutationParserFrontend <-
buildMutationParser mempty allActionInfos customTypes mutationFrontendFields
mutationParserBackend <-
buildMutationParser mempty allActionInfos customTypes mutationBackendFields
subscriptionParser <-
buildSubscriptionParser allSubscriptionFields [] customTypes []
queryParserFrontend <-
queryWithIntrospectionHelper allQueryFields mutationParserFrontend subscriptionParser
queryParserBackend <-
queryWithIntrospectionHelper allQueryFields mutationParserBackend subscriptionParser
-- In order to catch errors early, we attempt to generate the data
-- required for introspection, which ends up doing a few correctness
-- checks in the GraphQL schema.
void $
buildIntrospectionSchema
(P.parserType queryParserBackend)
(P.parserType <$> mutationParserBackend)
(P.parserType <$> subscriptionParser)
void $
buildIntrospectionSchema
(P.parserType queryParserFrontend)
(P.parserType <$> mutationParserFrontend)
(P.parserType <$> subscriptionParser)
let frontendContext =
GQLContext
(finalizeParser queryParserFrontend)
(finalizeParser <$> mutationParserFrontend)
(finalizeParser <$> subscriptionParser)
backendContext =
GQLContext
(finalizeParser queryParserBackend)
(finalizeParser <$> mutationParserBackend)
(finalizeParser <$> subscriptionParser)
pure $ RoleContext frontendContext $ Just backendContext
where
buildSource ::
forall b.
BackendSchema b =>
SourceInfo b ->
ConcreteSchemaT
m
( [FieldParser (P.ParseT Identity) (NamespacedField (QueryRootField UnpreparedValue))],
[FieldParser (P.ParseT Identity) (NamespacedField (MutationRootField UnpreparedValue))],
[FieldParser (P.ParseT Identity) (NamespacedField (MutationRootField UnpreparedValue))],
[FieldParser (P.ParseT Identity) (NamespacedField (QueryRootField UnpreparedValue))]
)
buildSource sourceInfo@(SourceInfo _ tables functions _ _ sourceCustomization') =
withSourceCustomization sourceCustomization (namingConventionSupport @b) globalDefaultNC do
let validFunctions = takeValidFunctions functions
validTables = takeValidTables tables
(uncustomizedQueryRootFields, uncustomizedSubscriptionRootFields) <-
buildRelayQueryAndSubscriptionFields sourceInfo validTables validFunctions
mkTypename <- asks getter
(,,,)
<$> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__query))
(pure uncustomizedQueryRootFields)
<*> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__mutation_frontend))
(buildMutationFields Frontend sourceInfo validTables validFunctions)
<*> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__mutation_backend))
(buildMutationFields Backend sourceInfo validTables validFunctions)
<*> customizeFields
sourceCustomization
(mkTypename <> P.MkTypename (<> G.__subscription))
(pure uncustomizedSubscriptionRootFields)
where
sourceCustomization =
if EFNamingConventions `elem` expFeatures
then sourceCustomization'
else sourceCustomization' {_scNamingConvention = Nothing}
-- | Builds the schema context for unauthenticated users.
--
-- This context is used whenever the user queries the engine with a role that is
-- unknown, and therefore not present in the context map. Before remote schema
-- permissions were introduced, remotes were considered to be a public entity,
-- and we therefore allowed an unknown role also to query the remotes. To
-- maintain backwards compatibility, we check if remote schema permissions are
-- enabled; remote schemas will only be available to unauthenticated users if
-- permissions aren't enabled.
unauthenticatedContext ::
forall m.
( MonadError QErr m,
MonadIO m
) =>
HashMap RemoteSchemaName (RemoteSchemaCtx, MetadataObject) ->
RemoteSchemaPermsCtx ->
m (GQLContext, HashSet InconsistentMetadata)
unauthenticatedContext allRemotes remoteSchemaPermsCtx = do
-- Since remote schemas can theoretically join against tables, we need to give
-- some fake data to 'runMonadSchema' in order to trick it into successfully
-- building a restricted schema; namely, we erase all remote relationships
-- from the remote schema contexts, meaning that all the information that is
-- needed for sources is completely irrelevant and filled with default values.
let fakeSchemaOptions =
SchemaOptions
LeaveNumbersAlone -- stringifyNum doesn't apply to remotes
True -- booleanCollapse doesn't apply to remotes
FunctionPermissionsInferred -- function permissions don't apply to remotes
remoteSchemaPermsCtx
False
fakeSchemaContext =
SchemaContext
HasuraSchema
mempty
ignoreRemoteRelationship
-- chosen arbitrarily to be as improbable as possible
fakeRole = mkRoleNameSafe [NT.nonEmptyTextQQ|MyNameIsOzymandiasKingOfKingsLookOnMyWorksYeMightyAndDespair|]
-- we delete all references to remote joins
alteredRemoteSchemas =
allRemotes <&> first \context ->
context {_rscRemoteRelationships = mempty}
runMonadSchema fakeSchemaOptions fakeSchemaContext fakeRole do
(queryFields, mutationFields, subscriptionFields, remoteErrors) <- case remoteSchemaPermsCtx of
RemoteSchemaPermsEnabled ->
-- Permissions are enabled, unauthenticated users have access to nothing.
pure ([], [], [], mempty)
RemoteSchemaPermsDisabled -> do
-- Permissions are disabled, unauthenticated users have access to remote schemas.
(remoteFields, remoteSchemaErrors) <-
buildAndValidateRemoteSchemas alteredRemoteSchemas [] [] fakeRole remoteSchemaPermsCtx
pure
( fmap (fmap RFRemote) <$> concatMap piQuery remoteFields,
fmap (fmap RFRemote) <$> concat (mapMaybe piMutation remoteFields),
fmap (fmap RFRemote) <$> concat (mapMaybe piSubscription remoteFields),
remoteSchemaErrors
)
mutationParser <-
whenMaybe (not $ null mutationFields) $
P.safeSelectionSet mutationRoot (Just $ G.Description "mutation root") mutationFields
<&> fmap (flattenNamespaces . fmap typenameToNamespacedRawRF)
subscriptionParser <-
whenMaybe (not $ null subscriptionFields) $
P.safeSelectionSet subscriptionRoot (Just $ G.Description "subscription root") subscriptionFields
<&> fmap (flattenNamespaces . fmap typenameToNamespacedRawRF)
queryParser <- queryWithIntrospectionHelper queryFields mutationParser Nothing
void $
buildIntrospectionSchema
(P.parserType queryParser)
(P.parserType <$> mutationParser)
(P.parserType <$> subscriptionParser)
pure (GQLContext (finalizeParser queryParser) (finalizeParser <$> mutationParser) (finalizeParser <$> subscriptionParser), remoteErrors)
-------------------------------------------------------------------------------
-- Building parser fields
buildAndValidateRemoteSchemas ::
forall m.
( MonadError QErr m,
MonadIO m
) =>
HashMap RemoteSchemaName (RemoteSchemaCtx, MetadataObject) ->
[FieldParser (P.ParseT Identity) (NamespacedField (QueryRootField UnpreparedValue))] ->
[FieldParser (P.ParseT Identity) (NamespacedField (MutationRootField UnpreparedValue))] ->
RoleName ->
RemoteSchemaPermsCtx ->
ConcreteSchemaT m ([RemoteSchemaParser (P.ParseT Identity)], HashSet InconsistentMetadata)
buildAndValidateRemoteSchemas remotes sourcesQueryFields sourcesMutationFields role remoteSchemaPermsCtx =
runWriterT $ foldlM step [] (Map.elems remotes)
where
getFieldName = P.getName . fDefinition
sourcesQueryFieldNames = getFieldName <$> sourcesQueryFields
sourcesMutationFieldNames = getFieldName <$> sourcesMutationFields
step validatedSchemas (remoteSchemaContext, metadataId) = do
let previousSchemasQueryFieldNames = map getFieldName $ concatMap piQuery validatedSchemas
previousSchemasMutationFieldNames = map getFieldName $ concat $ mapMaybe piMutation validatedSchemas
reportInconsistency reason = tell $ Set.singleton $ InconsistentObject reason Nothing metadataId
maybeParser <- lift $ buildRemoteSchemaParser remoteSchemaPermsCtx role remoteSchemaContext
case maybeParser of
Nothing -> pure validatedSchemas
Just remoteSchemaParser -> do
(_, inconsistencies) <- listen $ do
let newSchemaQueryFieldNames = map getFieldName $ piQuery remoteSchemaParser
newSchemaMutationFieldNames = foldMap (map getFieldName) $ piMutation remoteSchemaParser
-- First we check for conflicts in query_root:
-- - between this remote and the previous ones:
for_
(duplicates $ newSchemaQueryFieldNames <> previousSchemasQueryFieldNames)
\name -> reportInconsistency $ "Duplicate remote field " <> squote name
-- - between this remote and the sources:
for_ (duplicates $ newSchemaQueryFieldNames <> sourcesQueryFieldNames) $
\name -> reportInconsistency $ "Field cannot be overwritten by remote field " <> squote name
-- Ditto, but for mutations - i.e. with mutation_root:
unless (null newSchemaMutationFieldNames) do
-- - between this remote and the previous ones:
for_ (duplicates $ newSchemaMutationFieldNames <> previousSchemasMutationFieldNames) $
\name -> reportInconsistency $ "Duplicate remote field " <> squote name
-- - between this remote and the sources:
for_ (duplicates $ newSchemaMutationFieldNames <> sourcesMutationFieldNames) $
\name -> reportInconsistency $ "Field cannot be overwritten by remote field " <> squote name
-- No need to check for conflicts between subscription fields, since
-- remote subscriptions aren't supported yet.
-- Only add this new remote to the list if there was no error
pure $
if Set.null inconsistencies
then remoteSchemaParser : validatedSchemas
else validatedSchemas
buildRemoteSchemaParser ::
forall m.
(MonadError QErr m, MonadIO m) =>
RemoteSchemaPermsCtx ->
RoleName ->
RemoteSchemaCtx ->
ConcreteSchemaT m (Maybe (RemoteSchemaParser (P.ParseT Identity)))
buildRemoteSchemaParser remoteSchemaPermsCtx roleName context = do
let maybeIntrospection = getIntrospectionResult remoteSchemaPermsCtx roleName context
for maybeIntrospection \introspection ->
buildRemoteParser introspection (_rscRemoteRelationships context) (_rscInfo context)
-- | `buildQueryAndSubscriptionFields` builds the query and the subscription
-- fields of the tables tracked in the source. The query root fields and
-- the subscription root fields may not be equal because a root field may be
-- enabled in the `query_root_field` and not in the `subscription_root_field`,
-- so a tuple of array of field parsers corresponding to query field parsers and
-- subscription field parsers.
buildQueryAndSubscriptionFields ::
forall b r m n.
MonadBuildSchema b r m n =>
SourceInfo b ->
TableCache b ->
FunctionCache b ->
StreamingSubscriptionsCtx ->
m ([P.FieldParser n (QueryRootField UnpreparedValue)], [P.FieldParser n (SubscriptionRootField UnpreparedValue)])
buildQueryAndSubscriptionFields sourceInfo tables (takeExposedAs FEAQuery -> functions) streamingSubsCtx = do
roleName <- asks getter
functionPermsCtx <- retrieve soFunctionPermsContext
functionSelectExpParsers <-
concat . catMaybes
<$> for (Map.toList functions) \(functionName, functionInfo) -> runMaybeT $ do
guard $
roleName == adminRoleName
|| roleName `Map.member` _fiPermissions functionInfo
|| functionPermsCtx == FunctionPermissionsInferred
let targetTableName = _fiReturnType functionInfo
lift $ mkRFs $ buildFunctionQueryFields sourceInfo functionName functionInfo targetTableName
(tableQueryFields, tableSubscriptionFields) <-
unzip . catMaybes
<$> for (Map.toList tables) \(tableName, tableInfo) -> runMaybeT $ do
tableIdentifierName <- getTableIdentifierName @b tableInfo
lift $ buildTableQueryAndSubscriptionFields sourceInfo tableName tableInfo streamingSubsCtx tableIdentifierName
let tableQueryRootFields = fmap mkRF $ concat tableQueryFields
tableSubscriptionRootFields = fmap mkRF $ concat tableSubscriptionFields
pure
( tableQueryRootFields <> functionSelectExpParsers,
tableSubscriptionRootFields <> functionSelectExpParsers
)
where
mkRFs = mkRootFields sourceName sourceConfig queryTagsConfig QDBR
mkRF = mkRootField sourceName sourceConfig queryTagsConfig QDBR
sourceName = _siName sourceInfo
sourceConfig = _siConfiguration sourceInfo
queryTagsConfig = _siQueryTagsConfig sourceInfo
buildRelayQueryAndSubscriptionFields ::
forall b r m n.
MonadBuildSchema b r m n =>
SourceInfo b ->
TableCache b ->
FunctionCache b ->
m ([P.FieldParser n (QueryRootField UnpreparedValue)], [P.FieldParser n (SubscriptionRootField UnpreparedValue)])
buildRelayQueryAndSubscriptionFields sourceInfo tables (takeExposedAs FEAQuery -> functions) = do
(tableConnectionQueryFields, tableConnectionSubscriptionFields) <-
unzip . catMaybes
<$> for (Map.toList tables) \(tableName, tableInfo) -> runMaybeT do
tableIdentifierName <- getTableIdentifierName @b tableInfo
SelPermInfo {..} <- MaybeT $ tableSelectPermissions tableInfo
pkeyColumns <- hoistMaybe $ tableInfo ^? tiCoreInfo . tciPrimaryKey . _Just . pkColumns
relayRootFields <- lift $ mkRFs $ buildTableRelayQueryFields sourceInfo tableName tableInfo tableIdentifierName pkeyColumns
let includeRelayWhen True = Just relayRootFields
includeRelayWhen False = Nothing
pure
( includeRelayWhen (isRootFieldAllowed QRFTSelect spiAllowedQueryRootFields),
includeRelayWhen (isRootFieldAllowed SRFTSelect spiAllowedSubscriptionRootFields)
)
functionConnectionFields <- for (Map.toList functions) $ \(functionName, functionInfo) -> runMaybeT do
let returnTableName = _fiReturnType functionInfo
-- FIXME: only extract the TableInfo once to avoid redundant cache lookups
returnTableInfo <- lift $ askTableInfo sourceInfo returnTableName
pkeyColumns <- MaybeT $ (^? tiCoreInfo . tciPrimaryKey . _Just . pkColumns) <$> pure returnTableInfo
lift $ mkRFs $ buildFunctionRelayQueryFields sourceInfo functionName functionInfo returnTableName pkeyColumns
pure $
( concat $ catMaybes $ tableConnectionQueryFields <> functionConnectionFields,
concat $ catMaybes $ tableConnectionSubscriptionFields <> functionConnectionFields
)
where
mkRFs = mkRootFields sourceName sourceConfig queryTagsConfig QDBR
sourceName = _siName sourceInfo
sourceConfig = _siConfiguration sourceInfo
queryTagsConfig = _siQueryTagsConfig sourceInfo
buildMutationFields ::
forall b r m n.
MonadBuildSchema b r m n =>
Scenario ->
SourceInfo b ->
TableCache b ->
FunctionCache b ->
m [P.FieldParser n (MutationRootField UnpreparedValue)]
buildMutationFields scenario sourceInfo tables (takeExposedAs FEAMutation -> functions) = do
roleName <- asks getter
tableMutations <- for (Map.toList tables) \(tableName, tableInfo) -> do
tableIdentifierName <- getTableIdentifierName @b tableInfo
inserts <-
mkRFs (MDBR . MDBInsert) $ buildTableInsertMutationFields scenario sourceInfo tableName tableInfo tableIdentifierName
updates <-
mkRFs (MDBR . MDBUpdate) $ buildTableUpdateMutationFields scenario sourceInfo tableName tableInfo tableIdentifierName
deletes <-
mkRFs (MDBR . MDBDelete) $ buildTableDeleteMutationFields scenario sourceInfo tableName tableInfo tableIdentifierName
pure $ concat [inserts, updates, deletes]
functionMutations <- for (Map.toList functions) \(functionName, functionInfo) -> runMaybeT $ do
let targetTableName = _fiReturnType functionInfo
-- A function exposed as mutation must have a function permission
-- configured for the role. See Note [Function Permissions]
guard $
-- when function permissions are inferred, we don't expose the
-- mutation functions for non-admin roles. See Note [Function Permissions]
roleName == adminRoleName || roleName `Map.member` (_fiPermissions functionInfo)
lift $ mkRFs MDBR $ buildFunctionMutationFields sourceInfo functionName functionInfo targetTableName
pure $ concat $ tableMutations <> catMaybes functionMutations
where
mkRFs :: forall a db remote action raw. (a -> db b) -> m [FieldParser n a] -> m [FieldParser n (RootField db remote action raw)]
mkRFs = mkRootFields sourceName sourceConfig queryTagsConfig
sourceName = _siName sourceInfo
sourceConfig = _siConfiguration sourceInfo
queryTagsConfig = _siQueryTagsConfig sourceInfo
----------------------------------------------------------------
-- Building root parser from fields
-- | Prepare the parser for query-type GraphQL requests, but with introspection
-- for queries, mutations and subscriptions built in.
buildQueryParser ::
forall r m n.
MonadBuildSchemaBase r m n =>
[P.FieldParser n (NamespacedField (QueryRootField UnpreparedValue))] ->
[P.FieldParser n (NamespacedField (RemoteSchemaRootField (RemoteRelationshipField UnpreparedValue) RemoteSchemaVariable))] ->
[ActionInfo] ->
AnnotatedCustomTypes ->
Maybe (Parser 'Output n (RootFieldMap (MutationRootField UnpreparedValue))) ->
Maybe (Parser 'Output n (RootFieldMap (QueryRootField UnpreparedValue))) ->
m (Parser 'Output n (RootFieldMap (QueryRootField UnpreparedValue)))
buildQueryParser sourceQueryFields remoteQueryFields allActions customTypes mutationParser subscriptionParser = do
actionQueryFields <- concat <$> traverse (buildActionQueryFields customTypes) allActions
let allQueryFields = sourceQueryFields <> fmap (fmap NotNamespaced) actionQueryFields <> fmap (fmap $ fmap RFRemote) remoteQueryFields
queryWithIntrospectionHelper allQueryFields mutationParser subscriptionParser
-- | Builds a @Schema@ at query parsing time
parseBuildIntrospectionSchema ::
MonadParse m =>
P.Type 'Output ->
Maybe (P.Type 'Output) ->
Maybe (P.Type 'Output) ->
m Schema
parseBuildIntrospectionSchema q m s = qerrAsMonadParse $ buildIntrospectionSchema q m s
where
qerrAsMonadParse :: MonadParse m => Except QErr a -> m a
qerrAsMonadParse action =
case runExcept action of
Right a -> pure a
Left QErr {..} -> withPath (++ qePath) $ parseErrorWith qeCode qeError
queryWithIntrospectionHelper ::
forall n m.
(MonadSchema n m, MonadError QErr m) =>
[P.FieldParser n (NamespacedField (QueryRootField UnpreparedValue))] ->
Maybe (Parser 'Output n (RootFieldMap (MutationRootField UnpreparedValue))) ->
Maybe (Parser 'Output n (RootFieldMap (QueryRootField UnpreparedValue))) ->
m (Parser 'Output n (RootFieldMap (QueryRootField UnpreparedValue)))
queryWithIntrospectionHelper basicQueryFP mutationP subscriptionP = do
let -- Per the GraphQL spec:
-- * "The query root operation type must be provided and must be an Object type." (§3.2.1)
-- * "An Object type must define one or more fields." (§3.6, type validation)
-- Those two requirements cannot both be met when a service is mutations-only, and does not
-- provide any query. In such a case, to meet both of those, we introduce a placeholder query
-- in the schema.
placeholderText = "There are no queries available to the current role. Either there are no sources or remote schemas configured, or the current role doesn't have the required permissions."
placeholderField = NotNamespaced (RFRaw $ JO.String placeholderText) <$ P.selection_ G._no_queries_available (Just $ G.Description placeholderText) P.string
fixedQueryFP = if null basicQueryFP then [placeholderField] else basicQueryFP
basicQueryP <- queryRootFromFields fixedQueryFP
let buildIntrospectionResponse printResponseFromSchema = do
partialSchema <-
parseBuildIntrospectionSchema
(P.parserType basicQueryP)
(P.parserType <$> mutationP)
(P.parserType <$> subscriptionP)
pure $ NotNamespaced $ RFRaw $ printResponseFromSchema partialSchema
introspection = [schema, typeIntrospection] <&> (`P.bindField` buildIntrospectionResponse)
{-# INLINE introspection #-}
partialQueryFields = fixedQueryFP ++ introspection
P.safeSelectionSet queryRoot Nothing partialQueryFields <&> fmap (flattenNamespaces . fmap typenameToNamespacedRawRF)
queryRootFromFields ::
forall n m.
(MonadError QErr m, MonadParse n) =>
[P.FieldParser n (NamespacedField (QueryRootField UnpreparedValue))] ->
m (Parser 'Output n (RootFieldMap (QueryRootField UnpreparedValue)))
queryRootFromFields fps =
P.safeSelectionSet queryRoot Nothing fps <&> fmap (flattenNamespaces . fmap typenameToNamespacedRawRF)
-- | Prepare the parser for subscriptions. Every postgres query field is
-- exposed as a subscription along with fields to get the status of
-- asynchronous actions.
buildSubscriptionParser ::
forall r m n.
MonadBuildSchemaBase r m n =>
[P.FieldParser n (NamespacedField (QueryRootField UnpreparedValue))] ->
[ActionInfo] ->
AnnotatedCustomTypes ->
[P.FieldParser n (NamespacedField (RemoteSchemaRootField (RemoteRelationshipField UnpreparedValue) RemoteSchemaVariable))] ->
m (Maybe (Parser 'Output n (RootFieldMap (QueryRootField UnpreparedValue))))
buildSubscriptionParser sourceSubscriptionFields allActions customTypes remoteSubscriptionFields = do
actionSubscriptionFields <- fmap (fmap NotNamespaced) . concat <$> traverse (buildActionSubscriptionFields customTypes) allActions
let subscriptionFields = sourceSubscriptionFields <> actionSubscriptionFields <> fmap (fmap $ fmap RFRemote) remoteSubscriptionFields
whenMaybe (not $ null subscriptionFields) $
P.safeSelectionSet subscriptionRoot Nothing subscriptionFields
<&> fmap (flattenNamespaces . fmap typenameToNamespacedRawRF)
buildMutationParser ::
forall r m n.
MonadBuildSchemaBase r m n =>
[P.FieldParser n (NamespacedField (RemoteSchemaRootField (RemoteRelationshipField UnpreparedValue) RemoteSchemaVariable))] ->
[ActionInfo] ->
AnnotatedCustomTypes ->
[P.FieldParser n (NamespacedField (MutationRootField UnpreparedValue))] ->
m (Maybe (Parser 'Output n (RootFieldMap (MutationRootField UnpreparedValue))))
buildMutationParser allRemotes allActions customTypes mutationFields = do
actionParsers <- concat <$> traverse (buildActionMutationFields customTypes) allActions
let mutationFieldsParser =
mutationFields
<> (fmap NotNamespaced <$> actionParsers)
<> (fmap (fmap RFRemote) <$> allRemotes)
whenMaybe (not $ null mutationFieldsParser) $
P.safeSelectionSet mutationRoot (Just $ G.Description "mutation root") mutationFieldsParser
<&> fmap (flattenNamespaces . fmap typenameToNamespacedRawRF)
-------------------------------------------------------------------------------
-- Local helpers
-- | Apply a source's customization options to a list of its fields.
customizeFields ::
forall f n db remote action.
(Functor f, MonadParse n) =>
SourceCustomization ->
P.MkTypename ->
f [FieldParser n (RootField db remote action JO.Value)] ->
f [FieldParser n (NamespacedField (RootField db remote action JO.Value))]
customizeFields SourceCustomization {..} =
fmap . customizeNamespace (_rootfcNamespace =<< _scRootFields) (const typenameToRawRF)
-- | All the 'BackendSchema' methods produce something of the form @m
-- [FieldParser n a]@, where @a@ is something specific to what is being parsed
-- by the given method.
--
-- In order to build the complete schema these must be
-- homogenised and be annotated with query-tag data, which this function makes
-- easy.
-- This function converts a single field parser. @mkRootFields@ transforms a
-- list of field parsers.
mkRootField ::
forall b n a db remote action raw.
(HasTag b, Functor n) =>
SourceName ->
SourceConfig b ->
Maybe QueryTagsConfig ->
(a -> db b) ->
FieldParser n a ->
FieldParser n (RootField db remote action raw)
mkRootField sourceName sourceConfig queryTagsConfig inj =
fmap
( RFDB sourceName
. AB.mkAnyBackend @b
. SourceConfigWith sourceConfig queryTagsConfig
. inj
)
-- | `mkRootFields` is `mkRootField` applied on a list of `FieldParser`.
mkRootFields ::
forall b m n a db remote action raw.
(HasTag b, Functor m, Functor n) =>
SourceName ->
SourceConfig b ->
Maybe QueryTagsConfig ->
(a -> db b) ->
m [(FieldParser n a)] ->
m [(FieldParser n (RootField db remote action raw))]
mkRootFields sourceName sourceConfig queryTagsConfig inj =
fmap
( map
(mkRootField sourceName sourceConfig queryTagsConfig inj)
)
takeExposedAs :: FunctionExposedAs -> FunctionCache b -> FunctionCache b
takeExposedAs x = Map.filter ((== x) . _fiExposedAs)
subscriptionRoot :: G.Name
subscriptionRoot = G._subscription_root
mutationRoot :: G.Name
mutationRoot = G._mutation_root
queryRoot :: G.Name
queryRoot = G._query_root
finalizeParser :: Parser 'Output (P.ParseT Identity) a -> ParserFn a
finalizeParser parser = runIdentity . P.runParseT . P.runParser parser
type ConcreteSchemaT m a =
P.SchemaT
(P.ParseT Identity)
( ReaderT
( SchemaOptions,
SchemaContext,
RoleName,
MkTypename,
MkRootFieldName,
CustomizeRemoteFieldName,
NamingCase
)
m
)
a
runMonadSchema ::
forall m a.
Monad m =>
SchemaOptions ->
SchemaContext ->
RoleName ->
ConcreteSchemaT m a ->
m a
runMonadSchema options context roleName m =
flip runReaderT (options, context, roleName, mempty, mempty, mempty, HasuraCase) $
P.runSchemaT m
buildBackendSource ::
(forall b. BackendSchema b => SourceInfo b -> r) ->
AB.AnyBackend SourceInfo ->
r
buildBackendSource f e = AB.dispatchAnyBackend @BackendSchema e f
typenameToNamespacedRawRF ::
P.ParsedSelection (NamespacedField (RootField db remote action JO.Value)) ->
NamespacedField (RootField db remote action JO.Value)
typenameToNamespacedRawRF = P.handleTypename $ NotNamespaced . RFRaw . JO.String . toTxt
typenameToRawRF ::
P.ParsedSelection (RootField db remote action JO.Value) ->
RootField db remote action JO.Value
typenameToRawRF = P.handleTypename $ RFRaw . JO.String . toTxt