{-# LANGUAGE RecursiveDo #-} {-# LANGUAGE ViewPatterns #-} module Hasura.GraphQL.Schema.Remote ( buildRemoteParser , remoteField , customizeFieldParser ) where import Hasura.Prelude import qualified Control.Monad.State.Lazy as Lazy import qualified Data.HashMap.Strict as Map import qualified Data.HashMap.Strict.InsOrd as OMap import qualified Data.HashMap.Strict.InsOrd.Extended as OMap import qualified Data.List.NonEmpty as NE import qualified Data.Text as T import qualified Language.GraphQL.Draft.Syntax as G import Control.Lens.Extended (Lens', _1, _2, _3, _4, set, use, (%=), (^.)) import Data.Monoid (Any (..)) import Data.Parser.JSONPath import Data.Text.Extended import Data.Type.Equality import qualified Hasura.GraphQL.Parser.Internal.Parser as P import qualified Hasura.GraphQL.Parser.Internal.TypeChecking as P import Hasura.Base.Error import Hasura.GraphQL.Parser as P import Hasura.RQL.Types.Common (stringScalar) import Hasura.RQL.Types.RemoteSchema import Hasura.RQL.Types.SchemaCache (IntrospectionResult (IntrospectionResult, irMutationRoot, irQueryRoot, irSubscriptionRoot)) -------------------------------------------------------------------------------- -- Top level function -- TODO return ParsedIntrospection ? buildRemoteParser :: forall m n . (MonadSchema n m, MonadError QErr m) => IntrospectionResult -> RemoteSchemaInfo -> m ( [P.FieldParser n RemoteField] , Maybe [P.FieldParser n RemoteField] , Maybe [P.FieldParser n RemoteField] ) -- ^ parsers for, respectively: queries, mutations, and subscriptions buildRemoteParser introspectionResult remoteSchemaInfo = do (rawQueryParsers, rawMutationParsers, rawSubscriptionParsers) <- buildRawRemoteParser introspectionResult remoteSchemaInfo pure $ evalMemoState $ do queryParsers <- customizeFieldParsers remoteSchemaInfo (irQueryRoot introspectionResult) rawQueryParsers mutationParsers <- sequence $ customizeFieldParsers remoteSchemaInfo <$> irMutationRoot introspectionResult <*> rawMutationParsers subscriptionParsers <- sequence $ customizeFieldParsers remoteSchemaInfo <$> irSubscriptionRoot introspectionResult <*> rawSubscriptionParsers pure (queryParsers, mutationParsers, subscriptionParsers) buildRawRemoteParser :: forall m n . (MonadSchema n m, MonadError QErr m) => IntrospectionResult -> RemoteSchemaInfo -> m ( [P.FieldParser n RawRemoteField] , Maybe [P.FieldParser n RawRemoteField] , Maybe [P.FieldParser n RawRemoteField] ) -- ^ parsers for, respectively: queries, mutations, and subscriptions buildRawRemoteParser (IntrospectionResult sdoc queryRoot mutationRoot subscriptionRoot) info@RemoteSchemaInfo{..} = do queryT <- makeParsers queryRoot mutationT <- makeNonQueryRootFieldParser mutationRoot $$(G.litName "Mutation") subscriptionT <- makeNonQueryRootFieldParser subscriptionRoot $$(G.litName "Subscription") return (queryT, mutationT, subscriptionT) where makeFieldParser :: G.FieldDefinition RemoteSchemaInputValueDefinition -> m (P.FieldParser n RawRemoteField) makeFieldParser fieldDef = do fldParser <- remoteFieldFromDefinition sdoc fieldDef pure $ RemoteFieldG info mempty <$> fldParser makeParsers :: G.Name -> m [P.FieldParser n RawRemoteField] makeParsers rootName = case lookupType sdoc rootName of Just (G.TypeDefinitionObject o) -> traverse makeFieldParser $ G._otdFieldsDefinition o _ -> throw400 Unexpected $ rootName <<> " has to be an object type" -- | The spec says that the `schema` definition can be omitted, if the root names are the -- defaults (Query, Mutation and Subscription). This function is used to construct a -- `FieldParser` for the mutation and subscription roots. If the user has given a custom -- Mutation/Subscription root name, then it will look for that and if it's not found in the -- schema document, then an error is thrown. If no root name has been provided, we lookup the -- schema document for an object with the default name and if that's not found, we omit the said -- Root from the schema. makeNonQueryRootFieldParser :: Maybe G.Name -> G.Name -> m (Maybe [P.FieldParser n RawRemoteField]) makeNonQueryRootFieldParser userProvidedRootName defaultRootName = case userProvidedRootName of Just _rootName -> traverse makeParsers userProvidedRootName Nothing -> let isDefaultRootObjectExists = isJust $ lookupObject sdoc defaultRootName in bool (pure Nothing) (traverse makeParsers $ Just defaultRootName) $ isDefaultRootObjectExists -------------------------------------------------------------------------------- -- Remote schema input parsers {- Note [Variable expansion in remote schema input parsers] ### Input parsers as lightweight type checkers The purpose of input parsers for remote schemas is not to translate the provided input values into an internal representation: those values will be transmitted more or less unmodified to the remote service; their main purpose is simply to check the shape of the input against the remote schema. Consider, for instance, the following remote schema: input Foo { bar: Int! } type Query { run(foo: Foo!): Int! } Our parsers will need to decide which invocations of `run` are valid: query { run(null) # invalid: foo is non-nullable run(foo: {baz: 0}) # invalid: Foo doesn't have a "baz" field run(foo: {bar: "0"}) # actually valid! } That last example is surprising: why would we accept a string literal for an Int? It simply is because we delegate the task of translating the literal into a scalar to the remote server. After all, *we* advertise some values as Int in the schema, despite accepting string literals. ### Inserting remote permissions presets Where things get more complicated is with remote permissions. We allow users to specify "presets": values that will always be provided to the remote schema, and that the user cannot customize in their query. For instance, given the following schema with permissions: input Range { low: Int! @preset(value: 0) high: Int! } type Query { getValues(range: Range!): [Int] } a user cannot specify "low" in OUR schema, as we will insert its value when parsing the incoming query. This is the second purpose of those input parsers: they insert remote schema presets where required. In this case: # we receive query { getValues(range: {high: 42}) } # we emit query { getValues(range: {low: 0, high: 42}) } ### Variable expansion But where this gets even more complicated is with variables. As much as possible, we simply forward variables without interpeting them (not all JSON values are representable in GraphQL). We do so whenever possible; for instance, using the previously established remote schema: # we receive query: query($h: Int!) { getValues(range: {high: $h}) } variables: { "h": 42 } # we emit query: query($h: Int!) { getValues(range: {low: 0, high: $h}) } variables: { "h": 42 } The tricky case is when a preset field is *within a variable*. We then have no choice: we have to expand the variable, and rewrap the value as best as we can, to minimize the amount of JSON evaluation. For instance: # we receive query: query($r: Range!) { getValues(range: $r) } variables: { "r": {"high": 42} } # we emit query: query($hasura_json_var_1: Int!) { getValues(range: {low: 0, high: $hasura_json_var_1}) } variables: { "hasura_json_var_1": 42 } Our parsers, like all others in our model, expand the variables as they traverse the tree, and add the preset values where required. But the downside of this is that we will create one such JSON variable per scalar within a JSON variable! ### Short-circuiting optimization To avoid this, we track in the parsers whether an alteration has occured: if we had to insert a preset value. As long as we don't, we can discard the output of the parser, as it will contain the exact same value as the input (if perhaps represented differently); by discarding the output and just forwarding the input, we avoid expanding variables if no preset needs be inserted. -} -- | Helper, used to track whether an input value was altered during its parsing. At time of -- writing, the only possible source of alteration is preset values. They might force evaluation of -- variables, and encapsulation of sub-JSON expressions as new variables. Each parser indicates -- whether such alteration took place within its part of the tree. -- See Note [Variable expansion in remote schema input parsers] for more information. newtype Altered = Altered { getAltered :: Bool } deriving (Show) deriving (Semigroup, Monoid) via Any -- | 'inputValueDefinitionParser' accepts a 'G.InputValueDefinition' and will return an -- 'InputFieldsParser' for it. If a non 'Input' GraphQL type is found in the 'type' of the -- 'InputValueDefinition' then an error will be thrown. -- -- Each parser also returns a boolean that indicates whether the parsed value was altered by -- presets. Presets might force the evaluation of variables that would otherwise be transmitted -- unmodified. inputValueDefinitionParser :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.InputValueDefinition -> m (InputFieldsParser n (Maybe (Altered, G.Value RemoteSchemaVariable))) inputValueDefinitionParser schemaDoc (G.InputValueDefinition desc name fieldType maybeDefaultVal _directives) = buildField fieldConstructor fieldType where doNullability :: forall a k . 'Input <: k => G.Nullability -> Parser k n (Maybe a) -> Parser k n (Maybe a) doNullability (G.Nullability True) = fmap join . P.nullable doNullability (G.Nullability False) = id fieldConstructor :: forall k. 'Input <: k => Parser k n (Maybe (Altered, G.Value RemoteSchemaVariable)) -> InputFieldsParser n (Maybe (Altered, G.Value RemoteSchemaVariable)) fieldConstructor (shortCircuitIfUnaltered -> parser) = case maybeDefaultVal of Nothing -> if G.isNullable fieldType then join <$> fieldOptional name desc parser else field name desc parser Just defaultVal -> fieldWithDefault name desc defaultVal parser buildField :: ( forall k. 'Input <: k => Parser k n (Maybe (Altered, G.Value RemoteSchemaVariable)) -> InputFieldsParser n (Maybe (Altered, G.Value RemoteSchemaVariable)) ) -> G.GType -> m (InputFieldsParser n (Maybe (Altered, G.Value RemoteSchemaVariable))) buildField mkInputFieldsParser = \case G.TypeNamed nullability typeName -> case lookupType schemaDoc typeName of Nothing -> throw400 RemoteSchemaError $ "Could not find type with name " <>> typeName Just typeDef -> case typeDef of G.TypeDefinitionScalar scalarTypeDefn -> pure $ mkInputFieldsParser $ doNullability nullability $ Just <$> remoteFieldScalarParser scalarTypeDefn G.TypeDefinitionEnum defn -> pure $ mkInputFieldsParser $ doNullability nullability $ Just <$> remoteFieldEnumParser defn G.TypeDefinitionObject _ -> throw400 RemoteSchemaError "expected input type, but got output type" G.TypeDefinitionInputObject defn -> do potentialObject <- remoteInputObjectParser schemaDoc defn pure $ case potentialObject of Left dummyInputFieldsParser -> do -- We couln't create a parser, meaning we can't create a field for this -- object. Instead we must return a "pure" InputFieldsParser that always yields -- the needed result without containing a field definition. -- -- !!! WARNING #1 !!! -- Since we have no input field in the schema for this field, we can't make the -- distinction between it being actually present at parsing time or not. We -- therefore choose to behave as if it was always present, and we always -- include the preset values in the result. -- -- !!! WARNING #2 !!! -- We are re-using an 'InputFieldsParser' that was created earlier! Won't that -- create new fields in the current context? No, it won't, but only because in -- this case we know that it was created from the preset fields in -- 'argumentsParser', and therefore contains no field definition. Just <$> dummyInputFieldsParser Right actualParser -> do -- We're in the normal case: we do have a parser for the input object, which is -- therefore valid (non-empty). mkInputFieldsParser $ doNullability nullability $ Just <$> actualParser G.TypeDefinitionUnion _ -> throw400 RemoteSchemaError "expected input type, but got output type" G.TypeDefinitionInterface _ -> throw400 RemoteSchemaError "expected input type, but got output type" G.TypeList nullability subType -> do buildField (mkInputFieldsParser . doNullability nullability . fmap (Just . fmap G.VList . aggregateListAndAlteration) . P.list) subType -- | remoteFieldScalarParser attempts to parse a scalar value for a given remote field -- -- We do not attempt to verify that the literal is correct! Some GraphQL implementations, including -- ours, are a bit flexible with the intepretations of literals; for instance, there are several -- places in our schema where we declare something to be an `Int`, but actually accept `String` -- literals. We do however peform variable type-checking. -- -- If we encounter a JSON value, it means that we were introspecting a query variable. To call the -- remote schema, we need a graphql value; we therefore need to treat that JSON expression as if it -- were a query variable of its own. To avoid ending up with one such variable per scalar in the -- query, we also track alterations, to apply optimizations. -- See Note [Variable expansion in remote schema input parsers] for more information. remoteFieldScalarParser :: MonadParse n => G.ScalarTypeDefinition -> P.Parser 'Both n (Altered, G.Value RemoteSchemaVariable) remoteFieldScalarParser (G.ScalarTypeDefinition description name _directives) = P.Parser { pType = schemaType , pParser = \inputValue -> (Altered False,) <$> case inputValue of JSONValue v -> pure $ G.VVariable $ RemoteJSONValue gType v GraphQLValue v -> for v \var -> do P.typeCheck False gType var pure $ QueryVariable var } where schemaType = NonNullable $ TNamed $ mkDefinition name description TIScalar gType = toGraphQLType schemaType remoteFieldEnumParser :: MonadParse n => G.EnumTypeDefinition -> Parser 'Both n (Altered, G.Value RemoteSchemaVariable) remoteFieldEnumParser (G.EnumTypeDefinition desc name _directives valueDefns) = let enumValDefns = valueDefns <&> \(G.EnumValueDefinition enumDesc enumName _) -> ( mkDefinition (G.unEnumValue enumName) enumDesc P.EnumValueInfo , G.VEnum enumName ) in fmap (Altered False,) $ P.enum name desc $ NE.fromList enumValDefns -- | remoteInputObjectParser returns an input parser for a given 'G.InputObjectTypeDefinition' -- -- Now, this is tricky! We are faced with two contradicting constraints here. On one hand, the -- GraphQL spec forbids us from creating empty input objects. This means that if all the arguments -- have presets, we CANNOT use the parser this function creates, and the caller cannot create a -- field for this object (and instead should use @pure@ to include the preset values in the result -- of parsing the fields). -- -- One way we could fix this would be to change the type of this function to return a `Maybe -- Parser`, inspect the result of 'argumentsParser', and return @Nothing@ when we realize that there -- aren't any actual field in it (or at least return a value that propagates the preset values). But -- this would contradict our second constraint: this function needs to be memoized! -- -- At time of writing, we can't memoize functions that return arbitrary functors of Parsers; so no -- memoizing Maybe Parser or Either Presets Parser. Which means that we would need to first call -- `argumentsParser`, then memoize the "Just" branch that builds the actual Parser. The problem is -- that the recursive call ro remoteSchemaInputObject is within 'argumentsParser', meaning the call -- to it MUST be in the memoized branch! -- -- This is why, in the end, we do the following: we first test whether there is any non-preset -- field: if yes, we memoize that branch and proceed as normal. Otherwise we can omit the -- memoization: we know for sure that the preset fields won't generate a recursive call! remoteInputObjectParser :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.InputObjectTypeDefinition RemoteSchemaInputValueDefinition -> m ( Either (InputFieldsParser n (Altered, G.Value RemoteSchemaVariable)) (Parser 'Input n (Altered, G.Value RemoteSchemaVariable)) ) remoteInputObjectParser schemaDoc defn@(G.InputObjectTypeDefinition desc name _ valueDefns) = if all (isJust . _rsitdPresetArgument) valueDefns then -- All the fields are preset: we can't create a parser, that would result in an invalid type in -- the schema (an input object with no field). We therefore forward the InputFieldsParser -- unmodified. No need to memoize this branch: since all arguments are preset, 'argumentsParser' -- won't be recursively calling this function. Left . fmap (fmap G.VObject) <$> argumentsParser valueDefns schemaDoc else -- At least one field is not a preset, meaning we have the guarantee that there will be at least -- one field in the input object. We have to memoize this branch as we might recursively call -- the same parser. Right <$> P.memoizeOn 'remoteInputObjectParser defn do argsParser <- argumentsParser valueDefns schemaDoc pure $ fmap G.VObject <$> P.object name desc argsParser -- | Variable expansion optimization. -- Since each parser returns a value that indicates whether it was altered, we can detect when no -- alteration took place, and replace the parsed and expanded value by its original. -- See Note [Variable expansion in remote schema input parsers] for more information. shortCircuitIfUnaltered :: forall k n . ('Input <: k, MonadParse n) => Parser k n (Maybe (Altered, G.Value RemoteSchemaVariable)) -> Parser k n (Maybe (Altered, G.Value RemoteSchemaVariable)) shortCircuitIfUnaltered parser = P.Parser { pType = P.pType parser , pParser = \value -> do result <- P.pParser parser value pure $ case result of -- The parser did yield a value, and it was unmodified by presets -- we can short-citcuit by transforming the input value, therefore -- "unpeeling" variables and avoiding extraneous JSON variables. Just (Altered False, _) -> Just $ (Altered False,) $ case castWith (P.inputParserInput @k) value of -- The input was a GraphQL value: just forward it. GraphQLValue v -> QueryVariable <$> v -- The input value was already a JSON value: we still have to create -- a new JSON variable, but it will still be more efficient than having -- all the leaves of said value each be their own distinct value. JSONValue v -> G.VVariable $ RemoteJSONValue (toGraphQLType $ P.pType parser) v -- Otherwise either the parser did not yield any value, or a value -- that has been altered by presets and permissions; we forward it -- unoptimized. _ -> result } -- | argumentsParser is used for creating an argument parser for remote fields, -- This function is called for field arguments and input object fields. This -- function works in the following way: -- -- * if a field is not preset, we recursively call `inputValueDefinitionParser` on it -- * otherwise, we use the preset -- -- For example, consider the following input objects: -- -- input MessageWhereInpObj { -- id: IntCompareObj -- name: StringCompareObj -- } -- -- input IntCompareObj { -- eq : Int @preset(value: 2) -- gt : Int -- lt : Int -- } -- -- parsing a MessageWhereInpObj will result in the following call tree: -- -- -> argumentsParser MessageWhereInpObj -- -> id => inputValueDefinitionParser IntCompareObj -- -> remoteInputObjectParser IntCompareObj -- -> argumentsParser IntCompareObj -- -> eq => using preset, no recursion -- -> gt => inputValueDefinitionParser Int -- -> remoteFieldScalarParser Int -- -> lt => inputValueDefinitionParser Int -- -> remoteFieldScalarParser Int -- -> name => inputValueDefinitionParser StringCompareObj -- -> ... -- -- Furthermore, like all other input parsers in this file, 'argumentsParser' indicates whether this -- part of the tree was altered during parsing; if any of the fields is preset, or recursively -- contains values that contain presets further down, then this result is labelled as altered. argumentsParser :: forall n m . (MonadSchema n m, MonadError QErr m) => G.ArgumentsDefinition RemoteSchemaInputValueDefinition -> RemoteSchemaIntrospection -> m (InputFieldsParser n (Altered, HashMap G.Name (G.Value RemoteSchemaVariable))) argumentsParser args schemaDoc = do -- ! DANGER ! -- -- This function is mutually recursive with 'inputValueDefinitionParser': if one of the non-preset -- arguments is an input object, then recursively we'll end up using 'argumentsParser' to parse -- its arguments. Note however that if all arguments have a preset value, then this function will -- not call 'inputValueDefinitionParser', and will simply return without any recursion. -- -- This is labelled as dangerous because another function in this module, -- 'remoteInputObjectParser', EXPLICITLY RELIES ON THIS BEHAVIOUR. Due to limitations of the -- GraphQL spec and of parser memoization functions, it cannot memoize the case where all -- arguments are preset, and therefore relies on the assumption that 'argumentsParser' is not -- recursive in this edge case. -- -- This assumptions is unlikely to ever be broken; but if you ever modify this function, please -- nonetheless make sure that it is maintained. argsParsers <- for args \arg -> do let argDef = _rsitdDefinition arg argName = G._ivdName argDef argParser <- case _rsitdPresetArgument arg of Nothing -> inputValueDefinitionParser schemaDoc argDef -- This is the source of all possible alterations: one of the fields is preset; everything -- "above" this field in the tree will be considered "altered", and the optimizations will -- not apply. Just preset -> pure $ pure $ pure (Altered True, preset) pure $ fmap (fmap (argName,)) <$> argParser pure $ sequenceA argsParsers <&> fmap Map.fromList . aggregateListAndAlteration aggregateListAndAlteration :: [Maybe (Altered, a)] -> (Altered, [a]) aggregateListAndAlteration = first mconcat . unzip . catMaybes -------------------------------------------------------------------------------- -- Remote schema output parsers -- | 'remoteSchemaObject' returns a output parser for a given 'ObjectTypeDefinition'. remoteSchemaObject :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.ObjectTypeDefinition RemoteSchemaInputValueDefinition -> m (Parser 'Output n [G.Field G.NoFragments RemoteSchemaVariable]) remoteSchemaObject schemaDoc defn@(G.ObjectTypeDefinition description name interfaces _directives subFields) = P.memoizeOn 'remoteSchemaObject defn do subFieldParsers <- traverse (remoteFieldFromDefinition schemaDoc) subFields interfaceDefs <- traverse getInterface interfaces implements <- traverse (remoteSchemaInterface schemaDoc) interfaceDefs -- TODO: also check sub-interfaces, when these are supported in a future graphql spec traverse_ validateImplementsFields interfaceDefs pure $ P.selectionSetObject name description subFieldParsers implements <&> toList . OMap.mapWithKey (\alias -> \case P.SelectField fld -> fld P.SelectTypename _ -> G.Field (Just alias) $$(G.litName "__typename") mempty mempty mempty) where getInterface :: G.Name -> m (G.InterfaceTypeDefinition [G.Name] RemoteSchemaInputValueDefinition) getInterface interfaceName = onNothing (lookupInterface schemaDoc interfaceName) $ throw400 RemoteSchemaError $ "Could not find interface " <> squote interfaceName <> " implemented by Object type " <> squote name validateImplementsFields :: G.InterfaceTypeDefinition [G.Name] RemoteSchemaInputValueDefinition -> m () validateImplementsFields interface = traverse_ (validateImplementsField (G._itdName interface)) (G._itdFieldsDefinition interface) validateImplementsField :: G.Name -> G.FieldDefinition RemoteSchemaInputValueDefinition -> m () validateImplementsField interfaceName interfaceField = case lookup (G._fldName interfaceField) (zip (fmap G._fldName subFields) subFields) of Nothing -> throw400 RemoteSchemaError $ "Interface field " <> squote interfaceName <> "." <> dquote (G._fldName interfaceField) <> " expected, but " <> squote name <> " does not provide it" Just f -> do unless (validateSubType (G._fldType f) (G._fldType interfaceField)) $ throw400 RemoteSchemaError $ "The type of Object field " <> squote name <> "." <> dquote (G._fldName f) <> " (" <> G.showGT (G._fldType f) <> ") is not the same type/sub type of Interface field " <> squote interfaceName <> "." <> dquote (G._fldName interfaceField) <> " (" <> G.showGT (G._fldType interfaceField) <> ")" traverse_ (validateArgument (map _rsitdDefinition (G._fldArgumentsDefinition f)) . _rsitdDefinition) (G._fldArgumentsDefinition interfaceField) traverse_ (validateNoExtraNonNull (map _rsitdDefinition (G._fldArgumentsDefinition interfaceField)) . _rsitdDefinition) (G._fldArgumentsDefinition f) where validateArgument :: [G.InputValueDefinition] -> G.InputValueDefinition -> m () validateArgument objectFieldArgs ifaceArgument = case lookup (G._ivdName ifaceArgument) (zip (fmap G._ivdName objectFieldArgs) objectFieldArgs) of Nothing -> throw400 RemoteSchemaError $ "Interface field argument " <> squote interfaceName <> "." <> dquote (G._fldName interfaceField) <> "(" <> dquote (G._ivdName ifaceArgument) <> ":) required, but Object field " <> squote name <> "." <> dquote (G._fldName f) <> " does not provide it" Just a -> unless (G._ivdType a == G._ivdType ifaceArgument) $ throw400 RemoteSchemaError $ "Interface field argument " <> squote interfaceName <> "." <> dquote (G._fldName interfaceField) <> "(" <> dquote (G._ivdName ifaceArgument) <> ":) expects type " <> G.showGT (G._ivdType ifaceArgument) <> ", but " <> squote name <> "." <> dquote (G._fldName f) <> "(" <> dquote (G._ivdName ifaceArgument) <> ":) has type " <> G.showGT (G._ivdType a) validateNoExtraNonNull :: [G.InputValueDefinition] -> G.InputValueDefinition -> m () validateNoExtraNonNull ifaceArguments objectFieldArg = case lookup (G._ivdName objectFieldArg) (zip (fmap G._ivdName ifaceArguments) ifaceArguments) of Just _ -> pure () Nothing -> unless (G.isNullable (G._ivdType objectFieldArg)) $ throw400 RemoteSchemaError $ "Object field argument " <> squote name <> "." <> dquote (G._fldName f) <> "(" <> dquote (G._ivdName objectFieldArg) <> ":) is of required type " <> G.showGT (G._ivdType objectFieldArg) <> ", but is not provided by Interface field " <> squote interfaceName <> "." <> dquote (G._fldName interfaceField) validateSubType :: G.GType -> G.GType -> Bool -- TODO this ignores nullability which is probably wrong, even though the GraphQL spec is ambiguous validateSubType (G.TypeList _ x) (G.TypeList _ y) = validateSubType x y -- It is OK to "upgrade" the strictness validateSubType (G.TypeNamed (G.Nullability False) x) (G.TypeNamed (G.Nullability True) y) = validateSubType (G.TypeNamed (G.Nullability True) x) (G.TypeNamed (G.Nullability True) y) validateSubType (G.TypeNamed nx x) (G.TypeNamed ny y) = case (lookupType schemaDoc x , lookupType schemaDoc y) of (Just x' , Just y') -> nx == ny && validateSubTypeDefinition x' y' _ -> False validateSubType _ _ = False validateSubTypeDefinition x' y' | x' == y' = True validateSubTypeDefinition (G.TypeDefinitionObject otd) (G.TypeDefinitionInterface itd) = G._otdName otd `elem` G._itdPossibleTypes itd validateSubTypeDefinition (G.TypeDefinitionObject _otd) (G.TypeDefinitionUnion _utd) = True -- TODO write appropriate check (may require saving 'possibleTypes' in Syntax.hs) validateSubTypeDefinition _ _ = False {- Note [Querying remote schema interfaces] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When querying Remote schema interfaces, we need to re-construct the incoming query to be compliant with the upstream remote. We need to do this because the `SelectionSet`(s) that are inputted to this function have the fragments (if any) flattened. (Check `flattenSelectionSet` in 'Hasura.GraphQL.Parser.Collect' module) The `constructInterfaceSelectionSet` function makes a valid interface query by: 1. Getting the common interface fields in all the selection sets 2. Remove the common fields obtained in #1 from the selection sets 3. Construct a selection field for every common interface field 4. Construct inline fragments for non-common interface fields using the result of #2 for every object 5. Construct the final selection set by combining #3 and #4 Example: Suppose an interface 'Character' is defined in the upstream and two objects 'Human' and 'Droid' implement the 'Character' Interface. Suppose, a field 'hero' returns 'Character'. { hero { id name ... on Droid { primaryFunction } ... on Human { homePlanet } } } When we parse the selection set of the `hero` field, we parse the selection set twice: once for the `Droid` object type, which would be passed a selection set containing the field(s) defined in the `Droid` object type and similarly once for the 'Human' object type. The result of the interface selection set parsing would then be the results of the parsing of the object types when passed their corresponding flattened selection sets and the results of the parsing of the interface fields. After we parse the above GraphQL query, we get a selection set containing the interface fields and the selection sets of the objects that were queried in the GraphQL query. Since, we have the selection sets of the objects that were being queried, we can convert them into inline fragments resembling the original query and then query the remote schema with the newly constructed query. -} -- | 'remoteSchemaInterface' returns a output parser for a given 'InterfaceTypeDefinition'. -- Also check Note [Querying remote schema interfaces] remoteSchemaInterface :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.InterfaceTypeDefinition [G.Name] RemoteSchemaInputValueDefinition -> m (Parser 'Output n (G.SelectionSet G.NoFragments RemoteSchemaVariable)) remoteSchemaInterface schemaDoc defn@(G.InterfaceTypeDefinition description name _directives fields possibleTypes) = P.memoizeOn 'remoteSchemaObject defn do subFieldParsers <- traverse (remoteFieldFromDefinition schemaDoc) fields objs <- traverse (getObjectParser schemaDoc getObject) possibleTypes -- In the Draft GraphQL spec (> June 2018), interfaces can themselves -- implement superinterfaces. In the future, we may need to support this -- here. when (null subFieldParsers) $ throw400 RemoteSchemaError $ "List of fields cannot be empty for interface " <> squote name -- TODO: another way to obtain 'possibleTypes' is to lookup all the object -- types in the schema document that claim to implement this interface. We -- should have a check that expresses that that collection of objects is equal -- to 'possibleTypes'. pure $ P.selectionSetInterface name description subFieldParsers objs <&> constructInterfaceSelectionSet where getObject :: G.Name -> m (G.ObjectTypeDefinition RemoteSchemaInputValueDefinition) getObject objectName = onNothing (lookupObject schemaDoc objectName) $ case lookupInterface schemaDoc objectName of Nothing -> throw400 RemoteSchemaError $ "Could not find type " <> squote objectName <> ", which is defined as a member type of Interface " <> squote name Just _ -> throw400 RemoteSchemaError $ "Interface type " <> squote name <> " can only include object types. It cannot include " <> squote objectName -- 'constructInterfaceQuery' constructs a remote interface query. constructInterfaceSelectionSet :: [(G.Name, [G.Field G.NoFragments RemoteSchemaVariable])] -> G.SelectionSet G.NoFragments RemoteSchemaVariable constructInterfaceSelectionSet objNameAndFields = let -- common interface fields that exist in every -- selection set provided -- #1 of Note [Querying remote schema Interfaces] commonInterfaceFields = OMap.elems $ OMap.mapMaybe (allTheSame . toList) $ OMap.groupListWith G._fName $ concatMap (filter ((`elem` interfaceFieldNames) . G._fName) . snd) $ objNameAndFields interfaceFieldNames = map G._fldName fields allTheSame (x:xs) | all (== x) xs = Just x allTheSame _ = Nothing -- #2 of Note [Querying remote schema interface fields] nonCommonInterfaceFields = catMaybes $ flip map objNameAndFields $ \(objName, objFields) -> let nonCommonFields = filter (not . flip elem commonInterfaceFields) objFields in mkObjInlineFragment (objName, map G.SelectionField nonCommonFields) -- helper function for #4 of Note [Querying remote schema interface fields] mkObjInlineFragment (_, []) = Nothing mkObjInlineFragment (objName, selSet) = Just $ G.SelectionInlineFragment $ G.InlineFragment (Just objName) mempty selSet -- #5 of Note [Querying remote schema interface fields] in fmap G.SelectionField commonInterfaceFields <> nonCommonInterfaceFields -- | 'remoteSchemaUnion' returns a output parser for a given 'UnionTypeDefinition'. remoteSchemaUnion :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.UnionTypeDefinition -> m (Parser 'Output n (G.SelectionSet G.NoFragments RemoteSchemaVariable)) remoteSchemaUnion schemaDoc defn@(G.UnionTypeDefinition description name _directives objectNames) = P.memoizeOn 'remoteSchemaObject defn do objs <- traverse (getObjectParser schemaDoc getObject) objectNames when (null objs) $ throw400 RemoteSchemaError $ "List of member types cannot be empty for union type " <> squote name pure $ P.selectionSetUnion name description objs <&> (\objNameAndFields -> catMaybes $ objNameAndFields <&> \(objName, fields) -> case fields of -- The return value obtained from the parsing of a union selection set -- specifies, for each object in the union type, a fragment-free -- selection set for that object type. In particular, if, for a given -- object type, the selection set passed to the union type did not -- specify any fields for that object type (i.e. if no inline fragment -- applied to that object), the selection set resulting from the parsing -- through that object type would be empty, i.e. []. We exclude such -- object types from the reconstructed selection set for the union -- type, as selection sets cannot be empty. [] -> Nothing _ -> Just (G.SelectionInlineFragment $ G.InlineFragment (Just objName) mempty $ fmap G.SelectionField fields)) where getObject :: G.Name -> m (G.ObjectTypeDefinition RemoteSchemaInputValueDefinition) getObject objectName = onNothing (lookupObject schemaDoc objectName) $ case lookupInterface schemaDoc objectName of Nothing -> throw400 RemoteSchemaError $ "Could not find type " <> squote objectName <> ", which is defined as a member type of Union " <> squote name Just _ -> throw400 RemoteSchemaError $ "Union type " <> squote name <> " can only include object types. It cannot include " <> squote objectName remoteFieldFromDefinition :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.FieldDefinition RemoteSchemaInputValueDefinition -> m (FieldParser n (G.Field G.NoFragments RemoteSchemaVariable)) remoteFieldFromDefinition schemaDoc (G.FieldDefinition description name argsDefinition gType _) = let addNullableList :: FieldParser n (G.Field G.NoFragments RemoteSchemaVariable) -> FieldParser n (G.Field G.NoFragments RemoteSchemaVariable) addNullableList (P.FieldParser (Definition name' un desc (FieldInfo args typ)) parser) = P.FieldParser (Definition name' un desc (FieldInfo args (Nullable (TList typ)))) parser addNonNullableList :: FieldParser n (G.Field G.NoFragments RemoteSchemaVariable) -> FieldParser n (G.Field G.NoFragments RemoteSchemaVariable) addNonNullableList (P.FieldParser (Definition name' un desc (FieldInfo args typ)) parser) = P.FieldParser (Definition name' un desc (FieldInfo args (NonNullable (TList typ)))) parser -- TODO add directives, deprecation convertType :: G.GType -> m (FieldParser n (G.Field G.NoFragments RemoteSchemaVariable)) convertType gType' = do case gType' of G.TypeNamed (G.Nullability True) fieldTypeName -> P.nullableField <$> remoteFieldFromName schemaDoc name description fieldTypeName argsDefinition G.TypeList (G.Nullability True) gType'' -> addNullableList <$> convertType gType'' G.TypeNamed (G.Nullability False) fieldTypeName -> do P.nonNullableField <$> remoteFieldFromName schemaDoc name description fieldTypeName argsDefinition G.TypeList (G.Nullability False) gType'' -> addNonNullableList <$> convertType gType'' in convertType gType -- | 'remoteFieldFromName' accepts a GraphQL name and searches for its definition -- in the 'RemoteSchemaIntrospection'. remoteFieldFromName :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.Name -> Maybe G.Description -> G.Name -> G.ArgumentsDefinition RemoteSchemaInputValueDefinition -> m (FieldParser n (G.Field G.NoFragments RemoteSchemaVariable)) remoteFieldFromName sdoc fieldName description fieldTypeName argsDefns = case lookupType sdoc fieldTypeName of Nothing -> throw400 RemoteSchemaError $ "Could not find type with name " <>> fieldTypeName Just typeDef -> remoteField sdoc fieldName description argsDefns typeDef -- | 'remoteField' accepts a 'G.TypeDefinition' and will returns a 'FieldParser' for it. -- Note that the 'G.TypeDefinition' should be of the GraphQL 'Output' kind, when an -- GraphQL 'Input' kind is provided, then error will be thrown. remoteField :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> G.Name -> Maybe G.Description -> G.ArgumentsDefinition RemoteSchemaInputValueDefinition -> G.TypeDefinition [G.Name] RemoteSchemaInputValueDefinition -> m (FieldParser n (G.Field G.NoFragments RemoteSchemaVariable)) remoteField sdoc fieldName description argsDefn typeDefn = do -- TODO add directives argsParser <- argumentsParser argsDefn sdoc case typeDefn of G.TypeDefinitionObject objTypeDefn -> do remoteSchemaObjFields <- remoteSchemaObject sdoc objTypeDefn -- converting [Field NoFragments Name] to (SelectionSet NoFragments G.Name) let remoteSchemaObjSelSet = fmap G.SelectionField <$> remoteSchemaObjFields pure remoteSchemaObjSelSet <&> mkFieldParserWithSelectionSet argsParser G.TypeDefinitionScalar scalarTypeDefn -> pure $ mkFieldParserWithoutSelectionSet argsParser $ void $ remoteFieldScalarParser scalarTypeDefn G.TypeDefinitionEnum enumTypeDefn -> pure $ mkFieldParserWithoutSelectionSet argsParser $ void $ remoteFieldEnumParser enumTypeDefn G.TypeDefinitionInterface ifaceTypeDefn -> remoteSchemaInterface sdoc ifaceTypeDefn <&> mkFieldParserWithSelectionSet argsParser G.TypeDefinitionUnion unionTypeDefn -> remoteSchemaUnion sdoc unionTypeDefn <&> mkFieldParserWithSelectionSet argsParser _ -> throw400 RemoteSchemaError "expected output type, but got input type" where mkField :: Maybe G.Name -> HashMap G.Name (G.Value RemoteSchemaVariable) -> G.SelectionSet G.NoFragments RemoteSchemaVariable -> G.Field G.NoFragments RemoteSchemaVariable mkField alias args selSet = G.Field alias fieldName args mempty selSet mkFieldParserWithoutSelectionSet :: InputFieldsParser n (Altered, HashMap G.Name (G.Value RemoteSchemaVariable)) -> Parser 'Both n () -> FieldParser n (G.Field G.NoFragments RemoteSchemaVariable) mkFieldParserWithoutSelectionSet argsParser outputParser = P.rawSelection fieldName description argsParser outputParser <&> \(alias, _, (_, args)) -> mkField alias args [] mkFieldParserWithSelectionSet :: InputFieldsParser n (Altered, HashMap G.Name (G.Value RemoteSchemaVariable)) -> Parser 'Output n (G.SelectionSet G.NoFragments RemoteSchemaVariable) -> FieldParser n (G.Field G.NoFragments RemoteSchemaVariable) mkFieldParserWithSelectionSet argsParser outputParser = P.rawSubselection fieldName description argsParser outputParser <&> \(alias, _, (_, args), selSet) -> mkField alias args selSet -- | helper function to get a parser of an object with it's name -- This function is called from 'remoteSchemaInterface' and -- 'remoteSchemaObject' functions. Both of these have a slightly -- different implementation of 'getObject', which is the -- reason 'getObject' is an argument to this function getObjectParser :: forall n m . (MonadSchema n m, MonadError QErr m) => RemoteSchemaIntrospection -> (G.Name -> m (G.ObjectTypeDefinition RemoteSchemaInputValueDefinition)) -> G.Name -> m (Parser 'Output n (G.Name, [G.Field G.NoFragments RemoteSchemaVariable])) getObjectParser schemaDoc getObject objName = do obj <- remoteSchemaObject schemaDoc =<< getObject objName return $ (objName,) <$> obj addCustomNamespace :: forall m. MonadParse m => RemoteSchemaInfo -> G.Name -> G.Name -> [P.FieldParser m RawRemoteField] -> P.FieldParser m RemoteField addCustomNamespace remoteSchemaInfo rootTypeName namespace fieldParsers = P.subselection_ namespace Nothing remoteFieldParser where rawRemoteFieldsParser :: Parser 'Output m [RawRemoteField] rawRemoteFieldsParser = P.selectionSet rootTypeName Nothing fieldParsers <&> toList . OMap.mapWithKey (\alias -> \case P.SelectField fld -> fld P.SelectTypename fld -> -- In P.selectionSet we lose the resultCustomizer from __typename fields so we need to put it back let resultCustomizer = modifyFieldByName alias $ customizeTypeNameString $ _rscCustomizeTypeName $ rsCustomizer remoteSchemaInfo in RemoteFieldG remoteSchemaInfo resultCustomizer $ G.Field (Just alias) $$(G.litName "__typename") mempty mempty mempty) remoteFieldParser :: Parser 'Output m RemoteField remoteFieldParser = rawRemoteFieldsParser <&> \remoteFields -> RemoteFieldG remoteSchemaInfo (foldMap _rfResultCustomizer remoteFields) (RRFNamespaceField $ G.SelectionField . _rfField <$> remoteFields) customizeFieldParsers :: forall m n. (MonadState MemoState m, MonadFix m, MonadParse n) => RemoteSchemaInfo -> G.Name -> [P.FieldParser n RawRemoteField] -> m [P.FieldParser n RemoteField] customizeFieldParsers remoteSchemaInfo@RemoteSchemaInfo{..} rootTypeName fieldParsers = do fieldParsers' <- if hasTypeOrFieldCustomizations rsCustomizer then traverse (customizeFieldParser' (set rfResultCustomizer) rsCustomizer rootTypeName) fieldParsers else -- no need to customize individual FieldParsers if there are no type or field name customizations pure fieldParsers pure $ case _rscNamespaceFieldName rsCustomizer of Nothing -> fmap realRemoteField <$> fieldParsers' Just namespace -> [addCustomNamespace remoteSchemaInfo rootTypeName namespace fieldParsers'] customizeFieldParser :: forall n a b. (MonadParse n) => (RemoteResultCustomizer -> a -> b) -> RemoteSchemaCustomizer -> G.Name -> P.FieldParser n a -> (P.FieldParser n b) customizeFieldParser setResultCustomizer remoteSchemaCustomizer rootTypeName = if hasTypeOrFieldCustomizations remoteSchemaCustomizer then evalMemoState . customizeFieldParser' setResultCustomizer remoteSchemaCustomizer rootTypeName else fmap $ setResultCustomizer mempty customizeFieldParser' :: forall m n a b. (MonadState MemoState m, MonadFix m, MonadParse n) => (RemoteResultCustomizer -> a -> b) -> RemoteSchemaCustomizer -> G.Name -> P.FieldParser n a -> m (P.FieldParser n b) customizeFieldParser' setResultCustomizer remoteSchemaCustomizer rootTypeName P.FieldParser{..} = do customizedDefinition <- customizeFieldDefinition remoteSchemaCustomizer rootTypeName fDefinition let customizedRootTypeName = remoteSchemaCustomizeTypeName remoteSchemaCustomizer rootTypeName pure P.FieldParser { fParser = fParserWithResultCustomizer <=< customizeField customizedRootTypeName (dInfo customizedDefinition) . fmap customizeVariable , fDefinition = customizedDefinition } where fParserWithResultCustomizer :: (RemoteResultCustomizer, G.Field G.NoFragments Variable) -> n b fParserWithResultCustomizer (resultCustomizer, fld) = setResultCustomizer resultCustomizer <$> fParser fld customizeVariable :: Variable -> Variable customizeVariable Variable{..} = Variable{vType = customizeGraphQLType vType, ..} customizeGraphQLType :: G.GType -> G.GType customizeGraphQLType = \case G.TypeNamed nullability name -> G.TypeNamed nullability $ remoteSchemaDecustomizeTypeName remoteSchemaCustomizer name G.TypeList nullability gtype -> G.TypeList nullability $ customizeGraphQLType gtype customizeField :: G.Name -> P.FieldInfo -> G.Field G.NoFragments var -> n (RemoteResultCustomizer, G.Field G.NoFragments var) customizeField parentTypeName (P.FieldInfo _ fieldType) (G.Field alias fieldName args directives selSet) = do let fieldName' = if "__" `T.isPrefixOf` G.unName fieldName then fieldName else remoteSchemaDecustomizeFieldName remoteSchemaCustomizer parentTypeName fieldName alias' = alias <|> if fieldName' == fieldName then Nothing else Just fieldName selSet' :: [(RemoteResultCustomizer, G.Selection G.NoFragments var)] <- withPath (++ [Key "selectionSet"]) $ case fieldType ^. definitionLens of typeDef@(Definition _ _ _ TIObject{}) -> traverse (customizeSelection typeDef) selSet typeDef@(Definition _ _ _ TIInterface{}) -> traverse (customizeSelection typeDef) selSet typeDef@(Definition _ _ _ TIUnion{}) -> traverse (customizeSelection typeDef) selSet _ -> pure $ (mempty,) <$> selSet let resultCustomizer = modifyFieldByName (fromMaybe fieldName' alias') $ if fieldName' == $$(G.litName "__typename") then customizeTypeNameString (_rscCustomizeTypeName remoteSchemaCustomizer) else foldMap fst selSet' pure $ (resultCustomizer, G.Field alias' fieldName' args directives $ snd <$> selSet') customizeSelection :: Definition (TypeInfo 'Output) -> G.Selection G.NoFragments var -> n (RemoteResultCustomizer, G.Selection G.NoFragments var) customizeSelection parentTypeDef = \case G.SelectionField fld@G.Field{..} -> withPath (++ [Key $ G.unName _fName]) $ do let parentTypeName = getName parentTypeDef fieldInfo <- findField _fName parentTypeName $ dInfo parentTypeDef second G.SelectionField <$> customizeField parentTypeName fieldInfo fld G.SelectionInlineFragment G.InlineFragment{..} -> do inlineFragmentType <- case _ifTypeCondition of Nothing -> pure parentTypeDef Just typeName -> findSubtype typeName parentTypeDef customizedSelectionSet <- traverse (customizeSelection inlineFragmentType) _ifSelectionSet pure $ (foldMap fst customizedSelectionSet, G.SelectionInlineFragment G.InlineFragment { _ifTypeCondition = remoteSchemaDecustomizeTypeName remoteSchemaCustomizer <$> _ifTypeCondition , _ifSelectionSet = snd <$> customizedSelectionSet , .. }) findField :: G.Name -> G.Name -> TypeInfo 'Output -> n P.FieldInfo findField fieldName parentTypeName parentTypeInfo = if fieldName == $$(G.litName "__typename") -- TODO can we avoid checking for __typename in two different places? then pure $ P.FieldInfo [] $ NonNullable $ TNamed $ mkDefinition stringScalar Nothing TIScalar else do fields <- case parentTypeInfo of TIObject objectInfo -> pure $ oiFields objectInfo TIInterface interfaceInfo -> pure $ iiFields interfaceInfo _ -> parseError $ "Type " <> parentTypeName <<> " has no fields" fld <- find ((== fieldName) . dName) fields `onNothing` parseError ("field " <> fieldName <<> " not found in type: " <> squote parentTypeName) pure $ dInfo fld findSubtype :: G.Name -> Definition (TypeInfo 'Output) -> n (Definition (TypeInfo 'Output)) findSubtype typeName parentTypeDef = if typeName == getName parentTypeDef then pure parentTypeDef else do possibleTypes <- case dInfo parentTypeDef of TIInterface interfaceInfo -> pure $ iiPossibleTypes interfaceInfo TIUnion unionInfo -> pure $ uiPossibleTypes unionInfo _ -> parseError $ "Type " <> getName parentTypeDef <<> " has no possible subtypes" fmap TIObject <$> find ((== typeName) . dName) possibleTypes `onNothing` parseError ("Type " <> typeName <<> " is not a subtype of " <>> getName parentTypeDef) type MemoState = (HashMap G.Name ObjectInfo, HashMap G.Name InterfaceInfo, HashMap G.Name UnionInfo, HashMap G.Name InputObjectInfo) evalMemoState :: Lazy.State MemoState a -> a evalMemoState = flip Lazy.evalState (mempty, mempty, mempty, mempty) -- | memo function used to "tie the knot" and preserve sharing in the customized type definitions -- It would be nice if we could just re-use MonadSchema and memoizeOn, but the types there are too -- parser-specific. memo :: (MonadState s m, MonadFix m, Hashable k, Eq k) => Lens' s (HashMap k v) -> (k -> v -> m v) -> k -> v -> m v memo lens f k v = do m <- use lens Map.lookup k m `onNothing` mdo -- Note: v' is added to the state _before_ it is produced lens %= Map.insert k v' v' <- f k v pure v' customizeFieldDefinition :: forall m. (MonadState MemoState m, MonadFix m) => RemoteSchemaCustomizer -> G.Name -> Definition P.FieldInfo -> m (Definition P.FieldInfo) customizeFieldDefinition remoteSchemaCustomizer = customizeFieldDefinition' where customizeFieldDefinition' :: G.Name -> Definition P.FieldInfo -> m (Definition P.FieldInfo) customizeFieldDefinition' parentTypeName Definition{..} = do dInfo' <- customizeFieldInfo dInfo pure Definition { dName = remoteSchemaCustomizeFieldName remoteSchemaCustomizer parentTypeName dName , dInfo = dInfo' , .. } customizeFieldInfo :: P.FieldInfo -> m P.FieldInfo customizeFieldInfo (P.FieldInfo args typ) = P.FieldInfo <$> traverse (traverse $ customizeInputFieldInfo) args <*> customizeType typ customizeTypeDefinition :: (G.Name -> b -> m b) -> Definition b -> m (Definition b) customizeTypeDefinition f Definition{..} = do dInfo' <- f dName dInfo pure Definition { dName = remoteSchemaCustomizeTypeName remoteSchemaCustomizer dName , dInfo = dInfo' , .. } customizeType :: Type k -> m (Type k) customizeType = \case NonNullable nn -> NonNullable <$> customizeNonNullableType nn Nullable nn -> Nullable <$> customizeNonNullableType nn customizeNonNullableType :: NonNullableType k -> m (NonNullableType k) customizeNonNullableType = \case TList typ -> TList <$> customizeType typ TNamed definition -> TNamed <$> customizeTypeDefinition customizeTypeInfo definition customizeTypeInfo :: G.Name -> TypeInfo k -> m (TypeInfo k) customizeTypeInfo typeName = \case ti@TIScalar -> pure ti ti@TIEnum{} -> pure ti TIInputObject ioi -> TIInputObject <$> customizeInputObjectInfo typeName ioi TIObject oi -> TIObject <$> customizeObjectInfo typeName oi TIInterface ii -> TIInterface <$> customizeInterfaceInfo typeName ii TIUnion ui -> TIUnion <$> customizeUnionInfo typeName ui customizeInputFieldInfo :: InputFieldInfo -> m InputFieldInfo customizeInputFieldInfo = \case IFRequired nnType -> IFRequired <$> customizeNonNullableType nnType IFOptional typ value -> IFOptional <$> customizeType typ <*> pure value customizeObjectInfo :: G.Name -> ObjectInfo -> m ObjectInfo customizeObjectInfo = memo _1 $ \typeName ObjectInfo{..} -> do oiFields' <- traverse (customizeFieldDefinition' typeName) oiFields oiImplements' <- traverse (customizeTypeDefinition customizeInterfaceInfo) oiImplements pure ObjectInfo { oiFields = oiFields' , oiImplements = oiImplements' } customizeInterfaceInfo :: G.Name -> InterfaceInfo -> m InterfaceInfo customizeInterfaceInfo = memo _2 $ \typeName InterfaceInfo{..} -> do iiFields' <- traverse (customizeFieldDefinition' typeName) iiFields iiPossibleTypes' <- traverse (customizeTypeDefinition customizeObjectInfo) iiPossibleTypes pure InterfaceInfo { iiFields = iiFields' , iiPossibleTypes = iiPossibleTypes' } customizeUnionInfo :: G.Name -> UnionInfo -> m UnionInfo customizeUnionInfo = memo _3 $ \_typeName (UnionInfo possibleTypes) -> UnionInfo <$> traverse (customizeTypeDefinition customizeObjectInfo) possibleTypes customizeInputObjectInfo :: G.Name -> InputObjectInfo -> m InputObjectInfo customizeInputObjectInfo = memo _4 $ \_typeName (InputObjectInfo args) -> InputObjectInfo <$> traverse (traverse $ customizeInputFieldInfo) args