Coerce variable values
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CHANGELOG.md
22
CHANGELOG.md
@ -12,12 +12,30 @@ and this project adheres to
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contain a JSON value or another resolver, which is invoked during the
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execution. `FieldResolver` is executed in `ActionT` and the current `Field` is
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passed in the reader and not as an explicit argument.
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- `Execute.Transform.OperationDefinition` is almost the same as
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`AST.Document.OperationDefinition`. It is used to unify operations in the
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shorthand form and other operations.
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- `Execute.Transform.operation` has the prior responsibility of
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`Execute.Transform.document`, but transforms only the chosen operation and not
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the whole document. `Execute.Transform.document` translates
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`AST.Document.Document` into `Execute.Transform.Document`.
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### Added
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- `Type.Definition` and `Type.Schema` modules. Both contain the first types (but
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not all yet) to describe a schema. Public functions that execute queries
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- `Type.Definition` contains input and the most output types.
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- `Type.Schema` describes a schema. Both public functions that execute queries
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accept a `Schema` now instead of a `HashMap`. The execution fails if the root
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operation doesn't match the root Query type in the schema.
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- `Execute.Coerce` defines a typeclass responsible for input, variable value
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coercion. It decouples us a bit from JSON since any format can be used to pass
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query variables. Execution functions accept (`HashMap Name a`) instead of
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`Subs`, where a is an instance of `VariableValue`.
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### Removed
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- `AST.Core.Document`. Transforming the whole document is probably not
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reasonable since a document can define multiple operations and we're
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interested only in one of them. Therefore `Document` was modified and moved to
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`Execute.Transform`. It contains only slightly modified AST used to pick the
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operation.
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## [0.7.0.0] - 2020-05-11
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### Fixed
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@ -39,7 +39,9 @@ First we build a GraphQL schema.
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> schema1 = Schema queryType Nothing
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>
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> queryType :: ObjectType IO
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> queryType = ObjectType "Query" $ Schema.resolversToMap $ hello :| []
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> queryType = ObjectType "Query"
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> $ Field Nothing (ScalarOutputType string) mempty
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> <$> Schema.resolversToMap (hello :| [])
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>
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> hello :: Schema.Resolver IO
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> hello = Schema.scalar "hello" (return ("it's me" :: Text))
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@ -72,7 +74,9 @@ For this example, we're going to be using time.
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> schema2 = Schema queryType2 Nothing
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>
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> queryType2 :: ObjectType IO
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> queryType2 = ObjectType "Query" $ Schema.resolversToMap $ time :| []
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> queryType2 = ObjectType "Query"
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> $ Field Nothing (ScalarOutputType string) mempty
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> <$> Schema.resolversToMap (time :| [])
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>
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> time :: Schema.Resolver IO
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> time = Schema.scalar "time" $ do
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@ -134,7 +138,9 @@ Now that we have two resolvers, we can define a schema which uses them both.
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> schema3 = Schema queryType3 Nothing
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>
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> queryType3 :: ObjectType IO
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> queryType3 = ObjectType "Query" $ Schema.resolversToMap $ hello :| [time]
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> queryType3 = ObjectType "Query"
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> $ Field Nothing (ScalarOutputType string) mempty
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> <$> Schema.resolversToMap (hello :| [time])
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>
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> query3 :: Text
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> query3 = "query timeAndHello { time hello }"
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@ -31,6 +31,7 @@ dependencies:
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- containers
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- megaparsec
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- parser-combinators
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- scientific
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- text
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- transformers
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- unordered-containers
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@ -5,11 +5,13 @@ module Language.GraphQL
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) where
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import qualified Data.Aeson as Aeson
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import Data.HashMap.Strict (HashMap)
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import Data.Text (Text)
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import Language.GraphQL.AST.Document
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import Language.GraphQL.AST.Parser
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import Language.GraphQL.Error
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import Language.GraphQL.Execute
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import Language.GraphQL.AST.Parser
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import qualified Language.GraphQL.Schema as Schema
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import Language.GraphQL.Execute.Coerce
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import Language.GraphQL.Type.Schema
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import Text.Megaparsec (parse)
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@ -19,14 +21,14 @@ graphql :: Monad m
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=> Schema m -- ^ Resolvers.
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-> Text -- ^ Text representing a @GraphQL@ request document.
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-> m Aeson.Value -- ^ Response.
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graphql = flip graphqlSubs mempty
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graphql = flip graphqlSubs (mempty :: Aeson.Object)
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-- | If the text parses correctly as a @GraphQL@ query the substitution is
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-- applied to the query and the query is then executed using to the given
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-- 'Schema.Resolver's.
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graphqlSubs :: Monad m
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graphqlSubs :: (Monad m, VariableValue a)
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=> Schema m -- ^ Resolvers.
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-> Schema.Subs -- ^ Variable substitution function.
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-> HashMap Name a -- ^ Variable substitution function.
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-> Text -- ^ Text representing a @GraphQL@ request document.
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-> m Aeson.Value -- ^ Response.
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graphqlSubs schema f
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@ -3,7 +3,6 @@ module Language.GraphQL.AST.Core
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( Alias
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, Arguments(..)
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, Directive(..)
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, Document
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, Field(..)
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, Fragment(..)
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, Name
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@ -15,15 +14,11 @@ module Language.GraphQL.AST.Core
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import Data.Int (Int32)
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import Data.HashMap.Strict (HashMap)
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import Data.List.NonEmpty (NonEmpty)
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import Data.Sequence (Seq)
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import Data.String (IsString(..))
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import Data.Text (Text)
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import Language.GraphQL.AST (Alias, Name, TypeCondition)
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-- | GraphQL document is a non-empty list of operations.
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type Document = NonEmpty Operation
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-- | GraphQL has 3 operation types: queries, mutations and subscribtions.
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--
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-- Currently only queries and mutations are supported.
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@ -9,42 +9,42 @@ module Language.GraphQL.Execute
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import qualified Data.Aeson as Aeson
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import Data.Foldable (find)
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import qualified Data.HashMap.Strict as HashMap
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import Data.List.NonEmpty (NonEmpty(..))
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import Data.Text (Text)
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import qualified Data.Text as Text
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import Language.GraphQL.AST.Document
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import qualified Language.GraphQL.AST.Core as AST.Core
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import Language.GraphQL.Execute.Coerce
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import qualified Language.GraphQL.Execute.Transform as Transform
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import Language.GraphQL.Error
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import qualified Language.GraphQL.Schema as Schema
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import Language.GraphQL.Type.Definition
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import qualified Language.GraphQL.Type.Definition as Definition
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import Language.GraphQL.Type.Schema
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-- | Query error types.
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data QueryError
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= OperationNotFound Text
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| OperationNameRequired
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| CoercionError
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queryError :: QueryError -> Text
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queryError (OperationNotFound operationName) = Text.unwords
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["Operation", operationName, "couldn't be found in the document."]
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queryError OperationNameRequired = "Missing operation name."
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queryError CoercionError = "Coercion error."
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-- | The substitution is applied to the document, and the resolvers are applied
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-- to the resulting fields.
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--
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-- Returns the result of the query against the schema wrapped in a /data/
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-- field, or errors wrapped in an /errors/ field.
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execute :: Monad m
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execute :: (Monad m, VariableValue a)
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=> Schema m -- ^ Resolvers.
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-> Schema.Subs -- ^ Variable substitution function.
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-> HashMap.HashMap Name a -- ^ Variable substitution function.
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-> Document -- @GraphQL@ document.
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-> m Aeson.Value
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execute schema subs doc =
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maybe transformError (document schema Nothing)
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$ Transform.document subs doc
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where
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transformError = return $ singleError "Schema transformation error."
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execute schema = document schema Nothing
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-- | The substitution is applied to the document, and the resolvers are applied
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-- to the resulting fields. The operation name can be used if the document
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@ -52,41 +52,105 @@ execute schema subs doc =
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--
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-- Returns the result of the query against the schema wrapped in a /data/
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-- field, or errors wrapped in an /errors/ field.
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executeWithName :: Monad m
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executeWithName :: (Monad m, VariableValue a)
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=> Schema m -- ^ Resolvers
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-> Text -- ^ Operation name.
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-> Schema.Subs -- ^ Variable substitution function.
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-> HashMap.HashMap Name a -- ^ Variable substitution function.
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-> Document -- ^ @GraphQL@ Document.
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-> m Aeson.Value
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executeWithName schema operationName subs doc =
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maybe transformError (document schema $ Just operationName)
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$ Transform.document subs doc
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where
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transformError = return $ singleError "Schema transformation error."
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executeWithName schema operationName = document schema (Just operationName)
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getOperation
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:: Maybe Text
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-> AST.Core.Document
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-> Either QueryError AST.Core.Operation
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getOperation Nothing (operation' :| []) = pure operation'
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-> Transform.Document
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-> Either QueryError Transform.OperationDefinition
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getOperation Nothing (Transform.Document (operation' :| []) _) = pure operation'
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getOperation Nothing _ = Left OperationNameRequired
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getOperation (Just operationName) document'
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| Just operation' <- find matchingName document' = pure operation'
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getOperation (Just operationName) (Transform.Document operations _)
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| Just operation' <- find matchingName operations = pure operation'
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| otherwise = Left $ OperationNotFound operationName
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where
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matchingName (AST.Core.Query (Just name') _) = operationName == name'
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matchingName (AST.Core.Mutation (Just name') _) = operationName == name'
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matchingName _ = False
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matchingName (Transform.OperationDefinition _ name _ _ _) =
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name == Just operationName
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document :: Monad m
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lookupInputType
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:: Type
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-> HashMap.HashMap Name (Definition.TypeDefinition m)
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-> Maybe Definition.InputType
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lookupInputType (TypeNamed name) types =
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case HashMap.lookup name types of
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Just (Definition.ScalarTypeDefinition scalarType) ->
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Just $ Definition.ScalarInputType scalarType
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Just (Definition.EnumTypeDefinition enumType) ->
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Just $ Definition.EnumInputType enumType
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Just (Definition.InputObjectTypeDefinition objectType) ->
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Just $ Definition.ObjectInputType objectType
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_ -> Nothing
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lookupInputType (TypeList list) types
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= Definition.ListInputType
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<$> lookupInputType list types
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lookupInputType (TypeNonNull (NonNullTypeNamed nonNull)) types =
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case HashMap.lookup nonNull types of
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Just (Definition.ScalarTypeDefinition scalarType) ->
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Just $ Definition.NonNullScalarInputType scalarType
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Just (Definition.EnumTypeDefinition enumType) ->
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Just $ Definition.NonNullEnumInputType enumType
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Just (Definition.InputObjectTypeDefinition objectType) ->
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Just $ Definition.NonNullObjectInputType objectType
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_ -> Nothing
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lookupInputType (TypeNonNull (NonNullTypeList nonNull)) types
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= Definition.NonNullListInputType
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<$> lookupInputType nonNull types
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coerceVariableValues :: (Monad m, VariableValue a)
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=> Schema m
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-> Transform.OperationDefinition
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-> HashMap.HashMap Name a
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-> Either QueryError Schema.Subs
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coerceVariableValues schema (Transform.OperationDefinition _ _ variables _ _) values =
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let referencedTypes = collectReferencedTypes schema
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in maybe (Left CoercionError) Right
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$ foldr (coerceValue referencedTypes) (Just HashMap.empty) variables
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where
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coerceValue referencedTypes variableDefinition coercedValues = do
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let VariableDefinition variableName variableTypeName _defaultValue =
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variableDefinition
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variableType <- lookupInputType variableTypeName referencedTypes
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value <- HashMap.lookup variableName values
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coercedValue <- coerceVariableValue variableType value
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HashMap.insert variableName coercedValue <$> coercedValues
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executeRequest :: (Monad m, VariableValue a)
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=> Schema m
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-> Maybe Text
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-> AST.Core.Document
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-> HashMap.HashMap Name a
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-> Transform.Document
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-> Either QueryError (Transform.OperationDefinition, Schema.Subs)
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executeRequest schema operationName subs document' = do
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operation' <- getOperation operationName document'
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coercedValues <- coerceVariableValues schema operation' subs
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pure (operation', coercedValues)
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document :: (Monad m, VariableValue a)
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=> Schema m
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-> Maybe Text
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-> HashMap.HashMap Name a
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-> Document
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-> m Aeson.Value
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document schema operationName document' =
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case getOperation operationName document' of
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Left error' -> pure $ singleError $ queryError error'
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Right operation' -> operation schema operation'
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document schema operationName subs document' =
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case Transform.document document' of
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Just transformed -> executeRequest' transformed
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Nothing -> pure $ singleError
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"The document doesn't contain any executable operations."
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where
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transformOperation fragmentTable operation' subs' =
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case Transform.operation fragmentTable subs' operation' of
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Just operationResult -> operation schema operationResult
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Nothing -> pure $ singleError "Schema transformation error."
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executeRequest' transformed@(Transform.Document _ fragmentTable) =
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case executeRequest schema operationName subs transformed of
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Right (operation', subs') -> transformOperation fragmentTable operation' subs'
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Left error' -> pure $ singleError $ queryError error'
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operation :: Monad m
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=> Schema m
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@ -96,7 +160,8 @@ operation = schemaOperation
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where
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resolve queryFields = runCollectErrs
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. flip Schema.resolve queryFields
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. fields
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. fmap getResolver
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. Definition.fields
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lookupError = pure
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$ singleError "Root operation type couldn't be found in the schema."
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schemaOperation Schema {query} (AST.Core.Query _ fields') =
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@ -105,3 +170,4 @@ operation = schemaOperation
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resolve fields' mutation
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schemaOperation Schema {mutation = Nothing} (AST.Core.Mutation _ _) =
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lookupError
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getResolver (Definition.Field _ _ _ resolver) = resolver
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84
src/Language/GraphQL/Execute/Coerce.hs
Normal file
84
src/Language/GraphQL/Execute/Coerce.hs
Normal file
@ -0,0 +1,84 @@
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{-# LANGUAGE OverloadedStrings #-}
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-- | Types and functions used for input and result coercion.
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module Language.GraphQL.Execute.Coerce
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( VariableValue(..)
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) where
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import qualified Data.Aeson as Aeson
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import qualified Data.HashMap.Strict as HashMap
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import Data.Scientific (toBoundedInteger, toRealFloat)
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import Language.GraphQL.AST.Core
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import Language.GraphQL.Type.Definition
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-- | Since variables are passed separately from the query, in an independent
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-- format, they should be first coerced to the internal representation used by
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-- this implementation.
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class VariableValue a where
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-- | Only a basic, format-specific, coercion must be done here. Type
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-- correctness or nullability shouldn't be validated here, they will be
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-- validated later. The type information is provided only as a hint.
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--
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-- For example @GraphQL@ prohibits the coercion from a 't:Float' to an
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-- 't:Int', but @JSON@ doesn't have integers, so whole numbers should be
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-- coerced to 't:Int` when receiving variables as a JSON object. The same
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-- holds for 't:Enum'. There are formats that support enumerations, @JSON@
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-- doesn't, so the type information is given and 'coerceVariableValue' can
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-- check that an 't:Enum' is expected and treat the given value
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-- appropriately. Even checking whether this value is a proper member of the
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-- corresponding 't:Enum' type isn't required here, since this can be
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-- checked independently.
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--
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-- Another example is an @ID@. @GraphQL@ explicitly allows to coerce
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-- integers and strings to @ID@s, so if an @ID@ is received as an integer,
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-- it can be left as is and will be coerced later.
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--
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-- If a value cannot be coerced without losing information, 'Nothing' should
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-- be returned, the coercion will fail then and the query won't be executed.
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coerceVariableValue
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:: InputType -- ^ Expected type (variable type given in the query).
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-> a -- ^ Variable value being coerced.
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-> Maybe Value -- ^ Coerced value on success, 'Nothing' otherwise.
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instance VariableValue Aeson.Value where
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coerceVariableValue _ Aeson.Null = Just Null
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coerceVariableValue (ScalarInputTypeDefinition scalarType) value
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| (Aeson.String stringValue) <- value = Just $ String stringValue
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| (Aeson.Bool booleanValue) <- value = Just $ Boolean booleanValue
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| (Aeson.Number numberValue) <- value
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, (ScalarType "Float" _) <- scalarType =
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Just $ Float $ toRealFloat numberValue
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| (Aeson.Number numberValue) <- value = -- ID or Int
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Int <$> toBoundedInteger numberValue
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coerceVariableValue (EnumInputTypeDefinition _) (Aeson.String stringValue) =
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Just $ Enum stringValue
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coerceVariableValue (ObjectInputTypeDefinition objectType) value
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| (Aeson.Object objectValue) <- value = do
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let (InputObjectType _ _ inputFields) = objectType
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(newObjectValue, resultMap) <- foldWithKey objectValue inputFields
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if HashMap.null newObjectValue
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then Just $ Object resultMap
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else Nothing
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where
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foldWithKey objectValue = HashMap.foldrWithKey matchFieldValues
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$ Just (objectValue, HashMap.empty)
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matchFieldValues _ _ Nothing = Nothing
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matchFieldValues fieldName inputField (Just (objectValue, resultMap)) =
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let (InputField _ fieldType _) = inputField
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insert = flip (HashMap.insert fieldName) resultMap
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newObjectValue = HashMap.delete fieldName objectValue
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in case HashMap.lookup fieldName objectValue of
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Just variableValue -> do
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coerced <- coerceVariableValue fieldType variableValue
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pure (newObjectValue, insert coerced)
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Nothing -> Just (objectValue, resultMap)
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coerceVariableValue (ListInputTypeDefinition listType) value
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| (Aeson.Array arrayValue) <- value = List
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<$> foldr foldVector (Just []) arrayValue
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| otherwise = coerceVariableValue listType value
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where
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foldVector _ Nothing = Nothing
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foldVector variableValue (Just list) = do
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coerced <- coerceVariableValue listType variableValue
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pure $ coerced : list
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coerceVariableValue _ _ = Nothing
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@ -1,25 +1,28 @@
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{-# LANGUAGE ExplicitForAll #-}
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{-# LANGUAGE LambdaCase #-}
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{-# LANGUAGE TupleSections #-}
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-- | After the document is parsed, before getting executed the AST is
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-- transformed into a similar, simpler AST. This module is responsible for
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-- this transformation.
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module Language.GraphQL.Execute.Transform
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( document
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( Document(..)
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, OperationDefinition(..)
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, document
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, operation
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) where
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import Control.Arrow (first)
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import Control.Monad (foldM, unless)
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import Control.Monad.Trans.Class (lift)
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import Control.Monad.Trans.Reader (ReaderT, asks, runReaderT)
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import Control.Monad.Trans.State (StateT, evalStateT, gets, modify)
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import Data.HashMap.Strict (HashMap)
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import qualified Data.HashMap.Strict as HashMap
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import Data.List.NonEmpty (NonEmpty)
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import qualified Data.List.NonEmpty as NonEmpty
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import Data.Sequence (Seq, (<|), (><))
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import qualified Language.GraphQL.AST as Full
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import qualified Language.GraphQL.AST.Core as Core
|
||||
import Language.GraphQL.AST.Document (Definition(..), Document)
|
||||
import qualified Language.GraphQL.Schema as Schema
|
||||
import qualified Language.GraphQL.Type.Directive as Directive
|
||||
|
||||
@ -34,36 +37,56 @@ type TransformT a = StateT Replacement (ReaderT Schema.Subs Maybe) a
|
||||
liftJust :: forall a. a -> TransformT a
|
||||
liftJust = lift . lift . Just
|
||||
|
||||
-- | GraphQL document is a non-empty list of operations.
|
||||
data Document = Document
|
||||
(NonEmpty OperationDefinition)
|
||||
(HashMap Full.Name Full.FragmentDefinition)
|
||||
|
||||
data OperationDefinition = OperationDefinition
|
||||
Full.OperationType
|
||||
(Maybe Full.Name)
|
||||
[Full.VariableDefinition]
|
||||
[Full.Directive]
|
||||
Full.SelectionSet
|
||||
|
||||
-- | Rewrites the original syntax tree into an intermediate representation used
|
||||
-- for query execution.
|
||||
document :: Schema.Subs -> Document -> Maybe Core.Document
|
||||
document subs document' =
|
||||
flip runReaderT subs
|
||||
$ evalStateT (collectFragments >> operations operationDefinitions)
|
||||
$ Replacement HashMap.empty fragmentTable
|
||||
document :: Full.Document -> Maybe Document
|
||||
document ast =
|
||||
let (operations, fragmentTable) = foldr defragment ([], HashMap.empty) ast
|
||||
in Document <$> NonEmpty.nonEmpty operations <*> pure fragmentTable
|
||||
where
|
||||
(fragmentTable, operationDefinitions) = foldr defragment mempty document'
|
||||
defragment (ExecutableDefinition (Full.DefinitionOperation definition)) acc =
|
||||
(definition :) <$> acc
|
||||
defragment (ExecutableDefinition (Full.DefinitionFragment definition)) acc =
|
||||
let (Full.FragmentDefinition name _ _ _) = definition
|
||||
in first (HashMap.insert name definition) acc
|
||||
defragment definition (operations, fragments')
|
||||
| (Full.ExecutableDefinition executable) <- definition
|
||||
, (Full.DefinitionOperation operation') <- executable =
|
||||
(transform operation' : operations, fragments')
|
||||
| (Full.ExecutableDefinition executable) <- definition
|
||||
, (Full.DefinitionFragment fragment) <- executable
|
||||
, (Full.FragmentDefinition name _ _ _) <- fragment =
|
||||
(operations, HashMap.insert name fragment fragments')
|
||||
defragment _ acc = acc
|
||||
transform = \case
|
||||
Full.OperationDefinition type' name variables directives' selections ->
|
||||
OperationDefinition type' name variables directives' selections
|
||||
Full.SelectionSet selectionSet ->
|
||||
OperationDefinition Full.Query Nothing mempty mempty selectionSet
|
||||
|
||||
-- * Operation
|
||||
|
||||
operations :: [Full.OperationDefinition] -> TransformT Core.Document
|
||||
operations operations' = do
|
||||
coreOperations <- traverse operation operations'
|
||||
lift . lift $ NonEmpty.nonEmpty coreOperations
|
||||
|
||||
operation :: Full.OperationDefinition -> TransformT Core.Operation
|
||||
operation (Full.SelectionSet sels)
|
||||
= operation $ Full.OperationDefinition Full.Query mempty mempty mempty sels
|
||||
operation (Full.OperationDefinition Full.Query name _vars _dirs sels)
|
||||
= Core.Query name <$> appendSelection sels
|
||||
operation (Full.OperationDefinition Full.Mutation name _vars _dirs sels)
|
||||
= Core.Mutation name <$> appendSelection sels
|
||||
operation
|
||||
:: HashMap Full.Name Full.FragmentDefinition
|
||||
-> Schema.Subs
|
||||
-> OperationDefinition
|
||||
-> Maybe Core.Operation
|
||||
operation fragmentTable subs operationDefinition = flip runReaderT subs
|
||||
$ evalStateT (collectFragments >> transform operationDefinition)
|
||||
$ Replacement HashMap.empty fragmentTable
|
||||
where
|
||||
transform :: OperationDefinition -> TransformT Core.Operation
|
||||
transform (OperationDefinition Full.Query name _ _ sels) =
|
||||
Core.Query name <$> appendSelection sels
|
||||
transform (OperationDefinition Full.Mutation name _ _ sels) =
|
||||
Core.Mutation name <$> appendSelection sels
|
||||
|
||||
-- * Selection
|
||||
|
||||
|
@ -3,8 +3,7 @@
|
||||
-- | This module provides a representation of a @GraphQL@ Schema in addition to
|
||||
-- functions for defining and manipulating schemas.
|
||||
module Language.GraphQL.Schema
|
||||
( FieldResolver(..)
|
||||
, Resolver(..)
|
||||
( Resolver(..)
|
||||
, Subs
|
||||
, object
|
||||
, resolve
|
||||
@ -31,21 +30,18 @@ import qualified Data.Text as T
|
||||
import Language.GraphQL.AST.Core
|
||||
import Language.GraphQL.Error
|
||||
import Language.GraphQL.Trans
|
||||
import qualified Language.GraphQL.Type.Definition as Definition
|
||||
import qualified Language.GraphQL.Type as Type
|
||||
|
||||
-- | Resolves a 'Field' into an @Aeson.@'Data.Aeson.Types.Object' with error
|
||||
-- information (if an error has occurred). @m@ is an arbitrary monad, usually
|
||||
-- 'IO'.
|
||||
data Resolver m = Resolver Name (FieldResolver m)
|
||||
|
||||
data FieldResolver m
|
||||
= ValueResolver (ActionT m Aeson.Value)
|
||||
| NestingResolver (ActionT m (Type.Wrapping (HashMap Name (FieldResolver m))))
|
||||
data Resolver m = Resolver Name (Definition.FieldResolver m)
|
||||
|
||||
-- | Converts resolvers to a map.
|
||||
resolversToMap :: (Foldable f, Functor f)
|
||||
=> f (Resolver m)
|
||||
-> HashMap Text (FieldResolver m)
|
||||
-> HashMap Text (Definition.FieldResolver m)
|
||||
resolversToMap = HashMap.fromList . toList . fmap toKV
|
||||
where
|
||||
toKV (Resolver name r) = (name, r)
|
||||
@ -57,7 +53,7 @@ type Subs = HashMap Name Value
|
||||
-- | Create a new 'Resolver' with the given 'Name' from the given 'Resolver's.
|
||||
object :: Monad m => Name -> ActionT m [Resolver m] -> Resolver m
|
||||
object name = Resolver name
|
||||
. NestingResolver
|
||||
. Definition.NestingResolver
|
||||
. fmap (Type.Named . resolversToMap)
|
||||
|
||||
-- | Like 'object' but can be null or a list of objects.
|
||||
@ -66,19 +62,19 @@ wrappedObject :: Monad m
|
||||
-> ActionT m (Type.Wrapping [Resolver m])
|
||||
-> Resolver m
|
||||
wrappedObject name = Resolver name
|
||||
. NestingResolver
|
||||
. Definition.NestingResolver
|
||||
. (fmap . fmap) resolversToMap
|
||||
|
||||
-- | A scalar represents a primitive value, like a string or an integer.
|
||||
scalar :: (Monad m, Aeson.ToJSON a) => Name -> ActionT m a -> Resolver m
|
||||
scalar name = Resolver name . ValueResolver . fmap Aeson.toJSON
|
||||
scalar name = Resolver name . Definition.ValueResolver . fmap Aeson.toJSON
|
||||
|
||||
-- | Like 'scalar' but can be null or a list of scalars.
|
||||
wrappedScalar :: (Monad m, Aeson.ToJSON a)
|
||||
=> Name
|
||||
-> ActionT m (Type.Wrapping a)
|
||||
-> Resolver m
|
||||
wrappedScalar name = Resolver name . ValueResolver . fmap Aeson.toJSON
|
||||
wrappedScalar name = Resolver name . Definition.ValueResolver . fmap Aeson.toJSON
|
||||
|
||||
resolveFieldValue :: Monad m => Field -> ActionT m a -> m (Either Text a)
|
||||
resolveFieldValue field@(Field _ _ args _) =
|
||||
@ -91,11 +87,14 @@ convert Type.Null = Aeson.Null
|
||||
convert (Type.Named value) = value
|
||||
convert (Type.List value) = Aeson.toJSON value
|
||||
|
||||
withField :: Monad m => Field -> FieldResolver m -> CollectErrsT m Aeson.Object
|
||||
withField field (ValueResolver resolver) = do
|
||||
withField :: Monad m
|
||||
=> Field
|
||||
-> Definition.FieldResolver m
|
||||
-> CollectErrsT m Aeson.Object
|
||||
withField field (Definition.ValueResolver resolver) = do
|
||||
answer <- lift $ resolveFieldValue field resolver
|
||||
either (errmsg field) (pure . HashMap.singleton (aliasOrName field)) answer
|
||||
withField field@(Field _ _ _ seqSelection) (NestingResolver resolver) = do
|
||||
withField field@(Field _ _ _ seqSelection) (Definition.NestingResolver resolver) = do
|
||||
answer <- lift $ resolveFieldValue field resolver
|
||||
case answer of
|
||||
Right result -> do
|
||||
@ -112,7 +111,7 @@ errmsg field errorMessage = do
|
||||
-- 'Resolver' to each 'Field'. Resolves into a value containing the
|
||||
-- resolved 'Field', or a null value and error information.
|
||||
resolve :: Monad m
|
||||
=> HashMap Text (FieldResolver m)
|
||||
=> HashMap Text (Definition.FieldResolver m)
|
||||
-> Seq Selection
|
||||
-> CollectErrsT m Aeson.Value
|
||||
resolve resolvers = fmap (Aeson.toJSON . fold) . traverse tryResolvers
|
||||
@ -122,7 +121,7 @@ resolve resolvers = fmap (Aeson.toJSON . fold) . traverse tryResolvers
|
||||
| (Just resolver) <- lookupResolver name = withField fld resolver
|
||||
| otherwise = errmsg fld $ T.unwords ["field", name, "not resolved."]
|
||||
tryResolvers (SelectionFragment (Fragment typeCondition selections'))
|
||||
| Just (ValueResolver resolver) <- lookupResolver "__typename" = do
|
||||
| Just (Definition.ValueResolver resolver) <- lookupResolver "__typename" = do
|
||||
let fakeField = Field Nothing "__typename" mempty mempty
|
||||
that <- lift $ resolveFieldValue fakeField resolver
|
||||
if Right (Aeson.String typeCondition) == that
|
||||
|
@ -1,18 +1,256 @@
|
||||
{-# LANGUAGE ExplicitForAll #-}
|
||||
{-# LANGUAGE OverloadedStrings #-}
|
||||
{-# LANGUAGE PatternSynonyms #-}
|
||||
{-# LANGUAGE ViewPatterns #-}
|
||||
|
||||
-- | Types representing GraphQL type system.
|
||||
module Language.GraphQL.Type.Definition
|
||||
( ObjectType(..)
|
||||
( Argument(..)
|
||||
, EnumType(..)
|
||||
, Field(..)
|
||||
, FieldResolver(..)
|
||||
, InputField(..)
|
||||
, InputObjectType(..)
|
||||
, InputType(..)
|
||||
, ObjectType(..)
|
||||
, OutputType(..)
|
||||
, ScalarType(..)
|
||||
, TypeDefinition(..)
|
||||
, pattern EnumInputTypeDefinition
|
||||
, pattern ListInputTypeDefinition
|
||||
, pattern ObjectInputTypeDefinition
|
||||
, pattern ScalarInputTypeDefinition
|
||||
, pattern EnumOutputTypeDefinition
|
||||
, pattern ListOutputTypeDefinition
|
||||
, pattern ObjectOutputTypeDefinition
|
||||
, pattern ScalarOutputTypeDefinition
|
||||
, boolean
|
||||
, float
|
||||
, id
|
||||
, int
|
||||
, string
|
||||
) where
|
||||
|
||||
import qualified Data.Aeson as Aeson
|
||||
import Data.HashMap.Strict (HashMap)
|
||||
import Data.Set (Set)
|
||||
import Data.Text (Text)
|
||||
import Language.GraphQL.Schema
|
||||
import Language.GraphQL.AST.Core (Name, Value)
|
||||
import Language.GraphQL.Trans
|
||||
import qualified Language.GraphQL.Type as Type
|
||||
import Prelude hiding (id)
|
||||
|
||||
type Fields m = HashMap Text (FieldResolver m)
|
||||
|
||||
-- | Object Type Definition.
|
||||
-- | Object type definition.
|
||||
--
|
||||
-- Almost all of the GraphQL types you define will be object types. Object
|
||||
-- types have a name, but most importantly describe their fields.
|
||||
data ObjectType m = ObjectType
|
||||
{ name :: Text
|
||||
, fields :: Fields m
|
||||
, fields :: HashMap Name (Field m)
|
||||
}
|
||||
|
||||
-- | Output object field definition.
|
||||
data Field m = Field
|
||||
(Maybe Text) (OutputType m) (HashMap Name Argument) (FieldResolver m)
|
||||
|
||||
-- | Resolving a field can result in a leaf value or an object, which is
|
||||
-- represented as a list of nested resolvers, used to resolve the fields of that
|
||||
-- object.
|
||||
data FieldResolver m
|
||||
= ValueResolver (ActionT m Aeson.Value)
|
||||
| NestingResolver (ActionT m (Type.Wrapping (HashMap Name (FieldResolver m))))
|
||||
|
||||
-- | Field argument definition.
|
||||
data Argument = Argument (Maybe Text) InputType (Maybe Value)
|
||||
|
||||
-- | Scalar type definition.
|
||||
--
|
||||
-- The leaf values of any request and input values to arguments are Scalars (or
|
||||
-- Enums) .
|
||||
data ScalarType = ScalarType Name (Maybe Text)
|
||||
|
||||
-- | Enum type definition.
|
||||
--
|
||||
-- Some leaf values of requests and input values are Enums. GraphQL serializes
|
||||
-- Enum values as strings, however internally Enums can be represented by any
|
||||
-- kind of type, often integers.
|
||||
data EnumType = EnumType Name (Maybe Text) (Set Text)
|
||||
|
||||
-- | Single field of an 'InputObjectType'.
|
||||
data InputField = InputField (Maybe Text) InputType (Maybe Value)
|
||||
|
||||
-- | Input object type definition.
|
||||
--
|
||||
-- An input object defines a structured collection of fields which may be
|
||||
-- supplied to a field argument.
|
||||
data InputObjectType = InputObjectType
|
||||
Name (Maybe Text) (HashMap Name InputField)
|
||||
|
||||
-- | These types may be used as input types for arguments and directives.
|
||||
data InputType
|
||||
= ScalarInputType ScalarType
|
||||
| EnumInputType EnumType
|
||||
| ObjectInputType InputObjectType
|
||||
| ListInputType InputType
|
||||
| NonNullScalarInputType ScalarType
|
||||
| NonNullEnumInputType EnumType
|
||||
| NonNullObjectInputType InputObjectType
|
||||
| NonNullListInputType InputType
|
||||
|
||||
-- | These types may be used as output types as the result of fields.
|
||||
data OutputType m
|
||||
= ScalarOutputType ScalarType
|
||||
| EnumOutputType EnumType
|
||||
| ObjectOutputType (ObjectType m)
|
||||
| ListOutputType (OutputType m)
|
||||
| NonNullScalarOutputType ScalarType
|
||||
| NonNullEnumOutputType EnumType
|
||||
| NonNullObjectOutputType (ObjectType m)
|
||||
| NonNullListOutputType (OutputType m)
|
||||
|
||||
-- | These are all of the possible kinds of types.
|
||||
data TypeDefinition m
|
||||
= ScalarTypeDefinition ScalarType
|
||||
| EnumTypeDefinition EnumType
|
||||
| ObjectTypeDefinition (ObjectType m)
|
||||
| InputObjectTypeDefinition InputObjectType
|
||||
|
||||
-- | The @String@ scalar type represents textual data, represented as UTF-8
|
||||
-- character sequences. The String type is most often used by GraphQL to
|
||||
-- represent free-form human-readable text.
|
||||
string :: ScalarType
|
||||
string = ScalarType "String" (Just description)
|
||||
where
|
||||
description =
|
||||
"The `String` scalar type represents textual data, represented as \
|
||||
\UTF-8 character sequences. The String type is most often used by \
|
||||
\GraphQL to represent free-form human-readable text."
|
||||
|
||||
-- | The @Boolean@ scalar type represents @true@ or @false@.
|
||||
boolean :: ScalarType
|
||||
boolean = ScalarType "Boolean" (Just description)
|
||||
where
|
||||
description = "The `Boolean` scalar type represents `true` or `false`."
|
||||
|
||||
-- | The @Int@ scalar type represents non-fractional signed whole numeric
|
||||
-- values. Int can represent values between \(-2^{31}\) and \(2^{31 - 1}\).
|
||||
int :: ScalarType
|
||||
int = ScalarType "Int" (Just description)
|
||||
where
|
||||
description =
|
||||
"The `Int` scalar type represents non-fractional signed whole numeric \
|
||||
\values. Int can represent values between -(2^31) and 2^31 - 1."
|
||||
|
||||
-- | The @Float@ scalar type represents signed double-precision fractional
|
||||
-- values as specified by
|
||||
-- [IEEE 754](https://en.wikipedia.org/wiki/IEEE_floating_point).
|
||||
float :: ScalarType
|
||||
float = ScalarType "Float" (Just description)
|
||||
where
|
||||
description =
|
||||
"The `Float` scalar type represents signed double-precision fractional \
|
||||
\values as specified by \
|
||||
\[IEEE 754](https://en.wikipedia.org/wiki/IEEE_floating_point)."
|
||||
|
||||
-- | The @ID@ scalar type represents a unique identifier, often used to refetch
|
||||
-- an object or as key for a cache. The ID type appears in a JSON response as a
|
||||
-- String; however, it is not intended to be human-readable. When expected as an
|
||||
-- input type, any string (such as @"4"@) or integer (such as @4@) input value
|
||||
-- will be accepted as an ID.
|
||||
id :: ScalarType
|
||||
id = ScalarType "ID" (Just description)
|
||||
where
|
||||
description =
|
||||
"The `ID` scalar type represents a unique identifier, often used to \
|
||||
\refetch an object or as key for a cache. The ID type appears in a \
|
||||
\JSON response as a String; however, it is not intended to be \
|
||||
\human-readable. When expected as an input type, any string (such as \
|
||||
\`\"4\"`) or integer (such as `4`) input value will be accepted as an ID."
|
||||
|
||||
-- | Matches either 'ScalarInputType' or 'NonNullScalarInputType'.
|
||||
pattern ScalarInputTypeDefinition :: ScalarType -> InputType
|
||||
pattern ScalarInputTypeDefinition scalarType <-
|
||||
(isScalarInputType -> Just scalarType)
|
||||
|
||||
-- | Matches either 'EnumInputType' or 'NonNullEnumInputType'.
|
||||
pattern EnumInputTypeDefinition :: EnumType -> InputType
|
||||
pattern EnumInputTypeDefinition enumType <-
|
||||
(isEnumInputType -> Just enumType)
|
||||
|
||||
-- | Matches either 'ObjectInputType' or 'NonNullObjectInputType'.
|
||||
pattern ObjectInputTypeDefinition :: InputObjectType -> InputType
|
||||
pattern ObjectInputTypeDefinition objectType <-
|
||||
(isObjectInputType -> Just objectType)
|
||||
|
||||
-- | Matches either 'ListInputType' or 'NonNullListInputType'.
|
||||
pattern ListInputTypeDefinition :: InputType -> InputType
|
||||
pattern ListInputTypeDefinition listType <-
|
||||
(isListInputType -> Just listType)
|
||||
|
||||
{-# COMPLETE EnumInputTypeDefinition
|
||||
, ListInputTypeDefinition
|
||||
, ObjectInputTypeDefinition
|
||||
, ScalarInputTypeDefinition
|
||||
#-}
|
||||
|
||||
pattern ScalarOutputTypeDefinition :: forall m. ScalarType -> OutputType m
|
||||
pattern ScalarOutputTypeDefinition scalarType <-
|
||||
(isScalarOutputType -> Just scalarType)
|
||||
|
||||
pattern EnumOutputTypeDefinition :: forall m. EnumType -> OutputType m
|
||||
pattern EnumOutputTypeDefinition enumType <-
|
||||
(isEnumOutputType -> Just enumType)
|
||||
|
||||
pattern ObjectOutputTypeDefinition :: forall m. ObjectType m -> OutputType m
|
||||
pattern ObjectOutputTypeDefinition objectType <-
|
||||
(isObjectOutputType -> Just objectType)
|
||||
|
||||
pattern ListOutputTypeDefinition :: forall m. OutputType m -> OutputType m
|
||||
pattern ListOutputTypeDefinition listType <-
|
||||
(isListOutputType -> Just listType)
|
||||
|
||||
{-# COMPLETE ScalarOutputTypeDefinition
|
||||
, EnumOutputTypeDefinition
|
||||
, ObjectOutputTypeDefinition
|
||||
, ListOutputTypeDefinition
|
||||
#-}
|
||||
|
||||
isScalarInputType :: InputType -> Maybe ScalarType
|
||||
isScalarInputType (ScalarInputType inputType) = Just inputType
|
||||
isScalarInputType (NonNullScalarInputType inputType) = Just inputType
|
||||
isScalarInputType _ = Nothing
|
||||
|
||||
isObjectInputType :: InputType -> Maybe InputObjectType
|
||||
isObjectInputType (ObjectInputType inputType) = Just inputType
|
||||
isObjectInputType (NonNullObjectInputType inputType) = Just inputType
|
||||
isObjectInputType _ = Nothing
|
||||
|
||||
isEnumInputType :: InputType -> Maybe EnumType
|
||||
isEnumInputType (EnumInputType inputType) = Just inputType
|
||||
isEnumInputType (NonNullEnumInputType inputType) = Just inputType
|
||||
isEnumInputType _ = Nothing
|
||||
|
||||
isListInputType :: InputType -> Maybe InputType
|
||||
isListInputType (ListInputType inputType) = Just inputType
|
||||
isListInputType (NonNullListInputType inputType) = Just inputType
|
||||
isListInputType _ = Nothing
|
||||
|
||||
isScalarOutputType :: forall m. OutputType m -> Maybe ScalarType
|
||||
isScalarOutputType (ScalarOutputType outputType) = Just outputType
|
||||
isScalarOutputType (NonNullScalarOutputType outputType) = Just outputType
|
||||
isScalarOutputType _ = Nothing
|
||||
|
||||
isObjectOutputType :: forall m. OutputType m -> Maybe (ObjectType m)
|
||||
isObjectOutputType (ObjectOutputType outputType) = Just outputType
|
||||
isObjectOutputType (NonNullObjectOutputType outputType) = Just outputType
|
||||
isObjectOutputType _ = Nothing
|
||||
|
||||
isEnumOutputType :: forall m. OutputType m -> Maybe EnumType
|
||||
isEnumOutputType (EnumOutputType outputType) = Just outputType
|
||||
isEnumOutputType (NonNullEnumOutputType outputType) = Just outputType
|
||||
isEnumOutputType _ = Nothing
|
||||
|
||||
isListOutputType :: forall m. OutputType m -> Maybe (OutputType m)
|
||||
isListOutputType (ListOutputType outputType) = Just outputType
|
||||
isListOutputType (NonNullListOutputType outputType) = Just outputType
|
||||
isListOutputType _ = Nothing
|
||||
|
@ -1,11 +1,68 @@
|
||||
{-# LANGUAGE ExplicitForAll #-}
|
||||
|
||||
-- | Schema Definition.
|
||||
module Language.GraphQL.Type.Schema
|
||||
( Schema(..)
|
||||
, collectReferencedTypes
|
||||
) where
|
||||
|
||||
import Data.HashMap.Strict (HashMap)
|
||||
import qualified Data.HashMap.Strict as HashMap
|
||||
import Language.GraphQL.AST.Core (Name)
|
||||
import Language.GraphQL.Type.Definition
|
||||
|
||||
-- | Schema Definition
|
||||
-- | A Schema is created by supplying the root types of each type of operation,
|
||||
-- query and mutation (optional). A schema definition is then supplied to the
|
||||
-- validator and executor.
|
||||
--
|
||||
-- __Note:__ When the schema is constructed, by default only the types that
|
||||
-- are reachable by traversing the root types are included, other types must
|
||||
-- be explicitly referenced.
|
||||
data Schema m = Schema
|
||||
{ query :: ObjectType m
|
||||
, mutation :: Maybe (ObjectType m)
|
||||
}
|
||||
|
||||
-- | Traverses the schema and finds all referenced types.
|
||||
collectReferencedTypes :: forall m. Schema m -> HashMap Name (TypeDefinition m)
|
||||
collectReferencedTypes schema =
|
||||
let queryTypes = traverseObjectType (query schema) HashMap.empty
|
||||
in maybe queryTypes (`traverseObjectType` queryTypes) $ mutation schema
|
||||
where
|
||||
collect traverser typeName element foundTypes =
|
||||
let newMap = HashMap.insert typeName element foundTypes
|
||||
in maybe (traverser newMap) (const foundTypes)
|
||||
$ HashMap.lookup typeName foundTypes
|
||||
visitFields (Field _ outputType arguments _) foundTypes
|
||||
= traverseOutputType outputType
|
||||
$ foldr visitArguments foundTypes arguments
|
||||
visitArguments (Argument _ inputType _) = traverseInputType inputType
|
||||
visitInputFields (InputField _ inputType _) = traverseInputType inputType
|
||||
traverseInputType (ObjectInputTypeDefinition objectType) =
|
||||
let (InputObjectType typeName _ inputFields) = objectType
|
||||
element = InputObjectTypeDefinition objectType
|
||||
traverser = flip (foldr visitInputFields) inputFields
|
||||
in collect traverser typeName element
|
||||
traverseInputType (ListInputTypeDefinition listType) =
|
||||
traverseInputType listType
|
||||
traverseInputType (ScalarInputTypeDefinition scalarType) =
|
||||
let (ScalarType typeName _) = scalarType
|
||||
in collect Prelude.id typeName (ScalarTypeDefinition scalarType)
|
||||
traverseInputType (EnumInputTypeDefinition enumType) =
|
||||
let (EnumType typeName _ _) = enumType
|
||||
in collect Prelude.id typeName (EnumTypeDefinition enumType)
|
||||
traverseOutputType (ObjectOutputTypeDefinition objectType) =
|
||||
traverseObjectType objectType
|
||||
traverseOutputType (ListOutputTypeDefinition listType) =
|
||||
traverseOutputType listType
|
||||
traverseOutputType (ScalarOutputTypeDefinition scalarType) =
|
||||
let (ScalarType typeName _) = scalarType
|
||||
in collect Prelude.id typeName (ScalarTypeDefinition scalarType)
|
||||
traverseOutputType (EnumOutputTypeDefinition enumType) =
|
||||
let (EnumType typeName _ _) = enumType
|
||||
in collect Prelude.id typeName (EnumTypeDefinition enumType)
|
||||
traverseObjectType objectType foundTypes =
|
||||
let (ObjectType typeName objectFields) = objectType
|
||||
element = ObjectTypeDefinition objectType
|
||||
traverser = flip (foldr visitFields) objectFields
|
||||
in collect traverser typeName element foundTypes
|
||||
|
@ -1,4 +1,4 @@
|
||||
resolver: lts-15.12
|
||||
resolver: lts-15.13
|
||||
|
||||
packages:
|
||||
- .
|
||||
|
88
tests/Language/GraphQL/Execute/CoerceSpec.hs
Normal file
88
tests/Language/GraphQL/Execute/CoerceSpec.hs
Normal file
@ -0,0 +1,88 @@
|
||||
{-# LANGUAGE OverloadedStrings #-}
|
||||
module Language.GraphQL.Execute.CoerceSpec
|
||||
( spec
|
||||
) where
|
||||
|
||||
import Data.Aeson as Aeson ((.=))
|
||||
import qualified Data.Aeson as Aeson
|
||||
import qualified Data.Aeson.Types as Aeson
|
||||
import qualified Data.HashMap.Strict as HashMap
|
||||
import Data.Maybe (isNothing)
|
||||
import Data.Scientific (scientific)
|
||||
import Language.GraphQL.AST.Core
|
||||
import Language.GraphQL.Execute.Coerce
|
||||
import Language.GraphQL.Type.Definition
|
||||
import Prelude hiding (id)
|
||||
import Test.Hspec (Spec, describe, it, shouldBe, shouldSatisfy)
|
||||
|
||||
singletonInputObject :: InputType
|
||||
singletonInputObject = ObjectInputType type'
|
||||
where
|
||||
type' = InputObjectType "ObjectName" Nothing inputFields
|
||||
inputFields = HashMap.singleton "field" field
|
||||
field = InputField Nothing (ScalarInputType string) Nothing
|
||||
|
||||
spec :: Spec
|
||||
spec =
|
||||
describe "ToGraphQL Aeson" $ do
|
||||
it "coerces strings" $
|
||||
let expected = Just (String "asdf")
|
||||
actual = coerceVariableValue
|
||||
(ScalarInputType string) (Aeson.String "asdf")
|
||||
in actual `shouldBe` expected
|
||||
it "coerces non-null strings" $
|
||||
let expected = Just (String "asdf")
|
||||
actual = coerceVariableValue
|
||||
(NonNullScalarInputType string) (Aeson.String "asdf")
|
||||
in actual `shouldBe` expected
|
||||
it "coerces booleans" $
|
||||
let expected = Just (Boolean True)
|
||||
actual = coerceVariableValue
|
||||
(ScalarInputType boolean) (Aeson.Bool True)
|
||||
in actual `shouldBe` expected
|
||||
it "coerces zero to an integer" $
|
||||
let expected = Just (Int 0)
|
||||
actual = coerceVariableValue
|
||||
(ScalarInputType int) (Aeson.Number 0)
|
||||
in actual `shouldBe` expected
|
||||
it "rejects fractional if an integer is expected" $
|
||||
let actual = coerceVariableValue
|
||||
(ScalarInputType int) (Aeson.Number $ scientific 14 (-1))
|
||||
in actual `shouldSatisfy` isNothing
|
||||
it "coerces float numbers" $
|
||||
let expected = Just (Float 1.4)
|
||||
actual = coerceVariableValue
|
||||
(ScalarInputType float) (Aeson.Number $ scientific 14 (-1))
|
||||
in actual `shouldBe` expected
|
||||
it "coerces IDs" $
|
||||
let expected = Just (String "1234")
|
||||
actual = coerceVariableValue
|
||||
(ScalarInputType id) (Aeson.String "1234")
|
||||
in actual `shouldBe` expected
|
||||
it "coerces input objects" $
|
||||
let actual = coerceVariableValue singletonInputObject
|
||||
$ Aeson.object ["field" .= ("asdf" :: Aeson.Value)]
|
||||
expected = Just $ Object $ HashMap.singleton "field" "asdf"
|
||||
in actual `shouldBe` expected
|
||||
it "skips the field if it is missing in the variables" $
|
||||
let actual = coerceVariableValue
|
||||
singletonInputObject Aeson.emptyObject
|
||||
expected = Just $ Object HashMap.empty
|
||||
in actual `shouldBe` expected
|
||||
it "fails if input object value contains extra fields" $
|
||||
let actual = coerceVariableValue singletonInputObject
|
||||
$ Aeson.object variableFields
|
||||
variableFields =
|
||||
[ "field" .= ("asdf" :: Aeson.Value)
|
||||
, "extra" .= ("qwer" :: Aeson.Value)
|
||||
]
|
||||
in actual `shouldSatisfy` isNothing
|
||||
it "preserves null" $
|
||||
let actual = coerceVariableValue (ScalarInputType id) Aeson.Null
|
||||
in actual `shouldBe` Just Null
|
||||
it "preserves list order" $
|
||||
let list = Aeson.toJSONList ["asdf" :: Aeson.Value, "qwer"]
|
||||
listType = (ListInputType $ ScalarInputType string)
|
||||
actual = coerceVariableValue listType list
|
||||
expected = Just $ List [String "asdf", String "qwer"]
|
||||
in actual `shouldBe` expected
|
@ -7,7 +7,6 @@ module Test.DirectiveSpec
|
||||
import Data.Aeson (Value(..), object, (.=))
|
||||
import qualified Data.HashMap.Strict as HashMap
|
||||
import Language.GraphQL
|
||||
import qualified Language.GraphQL.Schema as Schema
|
||||
import Language.GraphQL.Type.Definition
|
||||
import Language.GraphQL.Type.Schema (Schema(..))
|
||||
import Test.Hspec (Spec, describe, it, shouldBe)
|
||||
@ -16,11 +15,10 @@ import Text.RawString.QQ (r)
|
||||
experimentalResolver :: Schema IO
|
||||
experimentalResolver = Schema { query = queryType, mutation = Nothing }
|
||||
where
|
||||
resolver = ValueResolver $ pure $ Number 5
|
||||
queryType = ObjectType "Query"
|
||||
$ HashMap.singleton "experimentalField"
|
||||
$ Schema.ValueResolver
|
||||
$ pure
|
||||
$ Number 5
|
||||
$ Field Nothing (ScalarOutputType int) mempty resolver
|
||||
|
||||
emptyObject :: Value
|
||||
emptyObject = object
|
||||
|
@ -6,7 +6,6 @@ module Test.FragmentSpec
|
||||
|
||||
import Data.Aeson (Value(..), object, (.=))
|
||||
import qualified Data.HashMap.Strict as HashMap
|
||||
import Data.List.NonEmpty (NonEmpty(..))
|
||||
import Data.Text (Text)
|
||||
import Language.GraphQL
|
||||
import qualified Language.GraphQL.Schema as Schema
|
||||
@ -50,12 +49,28 @@ hasErrors :: Value -> Bool
|
||||
hasErrors (Object object') = HashMap.member "errors" object'
|
||||
hasErrors _ = True
|
||||
|
||||
toSchema :: Schema.Resolver IO -> Schema IO
|
||||
toSchema resolver = Schema { query = queryType, mutation = Nothing }
|
||||
shirtType :: ObjectType IO
|
||||
shirtType = ObjectType "Shirt"
|
||||
$ HashMap.singleton resolverName
|
||||
$ Field Nothing (ScalarOutputType string) mempty resolve
|
||||
where
|
||||
(Schema.Resolver resolverName resolve) = size
|
||||
|
||||
hatType :: ObjectType IO
|
||||
hatType = ObjectType "Hat"
|
||||
$ HashMap.singleton resolverName
|
||||
$ Field Nothing (ScalarOutputType int) mempty resolve
|
||||
where
|
||||
(Schema.Resolver resolverName resolve) = circumference
|
||||
|
||||
toSchema :: Schema.Resolver IO -> Schema IO
|
||||
toSchema (Schema.Resolver resolverName resolve) = Schema
|
||||
{ query = queryType, mutation = Nothing }
|
||||
where
|
||||
unionMember = if resolverName == "Hat" then hatType else shirtType
|
||||
queryType = ObjectType "Query"
|
||||
$ Schema.resolversToMap
|
||||
$ resolver :| []
|
||||
$ HashMap.singleton resolverName
|
||||
$ Field Nothing (ObjectOutputType unionMember) mempty resolve
|
||||
|
||||
spec :: Spec
|
||||
spec = do
|
||||
|
@ -5,6 +5,7 @@ module Test.RootOperationSpec
|
||||
) where
|
||||
|
||||
import Data.Aeson ((.=), object)
|
||||
import qualified Data.HashMap.Strict as HashMap
|
||||
import Data.List.NonEmpty (NonEmpty(..))
|
||||
import Language.GraphQL
|
||||
import qualified Language.GraphQL.Schema as Schema
|
||||
@ -13,10 +14,18 @@ import Text.RawString.QQ (r)
|
||||
import Language.GraphQL.Type.Definition
|
||||
import Language.GraphQL.Type.Schema
|
||||
|
||||
hatType :: ObjectType IO
|
||||
hatType = ObjectType "Hat"
|
||||
$ HashMap.singleton resolverName
|
||||
$ Field Nothing (ScalarOutputType int) mempty resolve
|
||||
where
|
||||
(Schema.Resolver resolverName resolve) =
|
||||
Schema.scalar "circumference" $ pure (60 :: Int)
|
||||
|
||||
schema :: Schema IO
|
||||
schema = Schema
|
||||
(ObjectType "Query" queryResolvers)
|
||||
(Just $ ObjectType "Mutation" mutationResolvers)
|
||||
(ObjectType "Query" hatField)
|
||||
(Just $ ObjectType "Mutation" incrementField)
|
||||
where
|
||||
queryResolvers = Schema.resolversToMap $ garment :| []
|
||||
mutationResolvers = Schema.resolversToMap $ increment :| []
|
||||
@ -25,6 +34,10 @@ schema = Schema
|
||||
]
|
||||
increment = Schema.scalar "incrementCircumference"
|
||||
$ pure (61 :: Int)
|
||||
incrementField = Field Nothing (ScalarOutputType int) mempty
|
||||
<$> mutationResolvers
|
||||
hatField = Field Nothing (ObjectOutputType hatType) mempty
|
||||
<$> queryResolvers
|
||||
|
||||
spec :: Spec
|
||||
spec =
|
||||
|
@ -10,7 +10,6 @@ import Data.Functor.Identity (Identity(..))
|
||||
import qualified Data.HashMap.Strict as HashMap
|
||||
import Data.Text (Text)
|
||||
import Language.GraphQL
|
||||
import Language.GraphQL.Schema (Subs)
|
||||
import Text.RawString.QQ (r)
|
||||
import Test.Hspec.Expectations (Expectation, shouldBe)
|
||||
import Test.Hspec (Spec, describe, it)
|
||||
@ -360,6 +359,6 @@ spec = describe "Star Wars Query Tests" $ do
|
||||
testQuery :: Text -> Aeson.Value -> Expectation
|
||||
testQuery q expected = runIdentity (graphql schema q) `shouldBe` expected
|
||||
|
||||
testQueryParams :: Subs -> Text -> Aeson.Value -> Expectation
|
||||
testQueryParams :: Aeson.Object -> Text -> Aeson.Value -> Expectation
|
||||
testQueryParams f q expected =
|
||||
runIdentity (graphqlSubs schema f q) `shouldBe` expected
|
||||
|
@ -25,8 +25,8 @@ schema :: Schema Identity
|
||||
schema = Schema { query = queryType, mutation = Nothing }
|
||||
where
|
||||
queryType = ObjectType "Query"
|
||||
$ Schema.resolversToMap
|
||||
$ hero :| [human, droid]
|
||||
$ Field Nothing (ScalarOutputType string) mempty
|
||||
<$> Schema.resolversToMap (hero :| [human, droid])
|
||||
|
||||
hero :: Schema.Resolver Identity
|
||||
hero = Schema.object "hero" $ do
|
||||
|
Loading…
Reference in New Issue
Block a user