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## Description Almost all our data structures use strictness annotations, following [our styleguide's principle](https://github.com/hasura/graphql-engine/blob/master/server/STYLE.md#dealing-with-laziness) of "by default, use strict data types and lazy functions". The very few cases where we actually need laziness were already explicitly labelled as lazy with the `~` prefix operator. This PR simply globally enables `StrictData`, allowing us to express records without `!()` on every field, but makes no attempt at cleaning existing code. https://github.com/hasura/graphql-engine-mono/pull/1869 Co-authored-by: Philip Lykke Carlsen <358550+plcplc@users.noreply.github.com> GitOrigin-RevId: e65c6e2f89413188da250122f64c2173615946ec
866 lines
34 KiB
Haskell
866 lines
34 KiB
Haskell
-- | Types for representing a GraphQL schema.
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module Hasura.GraphQL.Parser.Schema (
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-- * Kinds
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Kind(..)
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, (:<:)(..)
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, type (<:)(..)
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-- * Types
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, Type(..)
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, NonNullableType(..)
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, TypeInfo(..)
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, SomeTypeInfo(..)
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, eqType
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, eqNonNullableType
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, eqTypeInfo
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, discardNullability
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, nullableType
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, nonNullableType
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, toGraphQLType
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, getObjectInfo
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, getInterfaceInfo
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, EnumValueInfo(..)
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, InputFieldInfo(..)
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, FieldInfo(..)
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, InputObjectInfo(..)
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, ObjectInfo(..)
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, InterfaceInfo(..)
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, UnionInfo(..)
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-- * Definitions
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, Definition(..)
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, mkDefinition
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, addDefinitionUnique
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, HasDefinition(..)
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-- * Schemas
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, Schema(..)
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, ConflictingDefinitions(..)
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, HasTypeDefinitions(..)
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, TypeDefinitionsWrapper(..)
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, collectTypeDefinitions
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-- * Miscellany
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, HasName(..)
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, InputValue(..)
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, Variable(..)
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, VariableInfo(..)
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, DirectiveInfo(..)
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) where
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import Hasura.Incremental (Cacheable)
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import Hasura.Prelude
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import qualified Data.Aeson as J
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import qualified Data.HashMap.Strict.Extended as Map
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import qualified Data.HashSet as Set
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import qualified Data.List.NonEmpty as NE
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import qualified Data.Text as T
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import Control.Lens.Extended
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import Control.Monad.Unique
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import Data.Functor.Classes
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import Data.Hashable (Hashable (..))
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import Data.Text.Extended
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import Language.GraphQL.Draft.Syntax (Description (..), DirectiveLocation (..),
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GType (..), Name (..), Nullability (..), Value (..))
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class HasName a where
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getName :: a -> Name
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instance HasName Name where
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getName = id
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-- | GraphQL types are divided into two classes: input types and output types.
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-- The GraphQL spec does not use the word “kind” to describe these classes, but
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-- it’s an apt term.
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--
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-- Some GraphQL types can be used at either kind, so we also include the 'Both'
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-- kind, the superkind of both 'Input' and 'Output'. The '<:' class provides
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-- kind subsumption constraints.
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--
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-- For more details, see <http://spec.graphql.org/June2018/#sec-Input-and-Output-Types>.
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data Kind
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= Both -- ^ see Note [The 'Both kind]
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| Input
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| Output
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{- Note [The 'Both kind]
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~~~~~~~~~~~~~~~~~~~~~~~~
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As described in the Haddock comments for Kind and <:, we use Kind to index
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various types, such as Type and Parser. We use this to enforce various
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correctness constraints mandated by the GraphQL spec; for example, we don’t
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allow input object fields to have output types and we don’t allow output object
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fields to have input types.
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But scalars and enums can be used as input types *or* output types. A natural
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encoding of that in Haskell would be to make constructors for those types
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polymorphic, like this:
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data Kind = Input | Output
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data TypeInfo k where
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TIScalar :: TypeInfo k -- \ Polymorphic!
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TIEnum :: ... -> TypeInfo k -- /
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TIInputObject :: ... -> TypeInfo 'Input
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TIObject :: ... -> TypeInfo 'Output
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Naturally, this would give the `scalar` parser constructor a similarly
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polymorphic type:
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scalar
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:: MonadParse m
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=> Name
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-> Maybe Description
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-> ScalarRepresentation a
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-> Parser k m a -- Polymorphic!
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But if we actually try that, we run into problems. The trouble is that we want
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to use the Kind to influence several different things:
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* As mentioned above, we use it to ensure that the types we generate are
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well-kinded according to the GraphQL spec rules.
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* We use it to determine what a Parser consumes as input. Parsers for input
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types parse GraphQL input values, but Parsers for output types parse
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selection sets. (See Note [The meaning of Parser 'Output] in
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Hasura.GraphQL.Parser.Internal.Parser for an explanation of why.)
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* We use it to know when to expect a sub-selection set for a field of an
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output object (see Note [The delicate balance of GraphQL kinds]).
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These many uses of Kind cause some trouble for a polymorphic representation. For
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example, consider our `scalar` parser constructor above---if we were to
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instantiate it at kind 'Output, we’d receive a `Parser 'Output`, which we would
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then expect to be able to apply to a selection set. But that doesn’t make any
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sense, since scalar fields don’t have selection sets!
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Another issue with this representation has to do with effectful parser
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constructors (such as constructors that can throw errors). These have types like
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mkFooParser :: MonadSchema n m => Blah -> m (Parser k n Foo)
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where the parser construction is itself monadic. This causes some annoyance,
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since even if mkFooParser returns a Parser of a polymorphic kind, code like this
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will not typecheck:
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(fooParser :: forall k. Parser k n Foo) <- mkFooParser blah
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The issue is that we have to instantiate k to a particular type to be able to
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call mkFooParser. If we want to use the result at both kinds, we’d have to call
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mkFooParser twice:
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(fooInputParser :: Parser 'Input n Foo) <- mkFooParser blah
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(fooOutputParser :: Parser 'Output n Foo) <- mkFooParser blah
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Other situations encounter similar difficulties, and they are not easy to
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resolve without impredicative polymorphism (which GHC does not support).
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To avoid this problem, we don’t use polymorphic kinds, but instead introduce a
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form of kind subsumption. Types that can be used as both input and output types
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are explicitly given the kind 'Both. This allows us to get the best of both
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worlds:
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* We use the <: typeclass to accept 'Both in most places where we expect
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either input or output types.
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* We can treat 'Both specially to avoid requiring `scalar` to supply a
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selection set parser (see Note [The delicate balance of GraphQL kinds] for
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further explanation).
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* Because we avoid the polymorphism, we don’t run into the aforementioned
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issue with monadic parser constructors.
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All of this is subtle and somewhat complicated, but unfortunately there isn’t
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much of a way around that: GraphQL is subtle and complicated. Our use of an
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explicit 'Both kind isn’t the only way to encode these things, but it’s the
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particular set of compromises we’ve chosen to accept.
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Note [The delicate balance of GraphQL kinds]
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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As discussed in Note [The 'Both kind], we use GraphQL kinds to distinguish
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several different things. One of them is which output types take sub-selection
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sets. For example, scalars don’t accept sub-selection sets, so if we have a
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schema like
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type Query {
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users: [User!]!
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}
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type User {
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id: Int!
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}
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then the following query is illegal:
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query {
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users {
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id {
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blah
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}
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}
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}
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The id field has a scalar type, so it should not take a sub-selection set. This
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is actually something we care about distinguishing at the type level, because it
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affects the type of the `selection` parser combinator. Suppose we have a
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`Parser 'Output m UserQuery` for the User type. When we parse a field with that
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type, we expect to receive a UserQuery as a result, unsurprisingly. But what if
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we parse an output field using the `int` parser, which has this type:
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int :: MonadParse m => Parser 'Both m Int32
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If we follow the same logic as for the User parser above, we’d expect to receive
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an Int32 as a result... but that doesn’t make any sense, since the Int32
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corresponds to the result *we* are suppose to produce as a result of executing
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the query, not something user-specified.
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One way to solve this would be to associate every Parser with two result types:
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one when given an input object, and one when given a selection set. Then our
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parsers could be given these types, instead:
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user :: MonadParse m => Parser 'Output m Void UserQuery
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int :: MonadParse m => Parser 'Both m Int32 ()
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But if you work through this, you’ll find that *all* parsers will either have
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Void or () for at least one of their input result types or their output result
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types, depending on their kind:
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* All 'Input parsers must have Void for their output result type, since they
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aren’t allowed to be used in output contexts at all.
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* All 'Output parsers must have Void for their input result type, since they
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aren’t allowed to be used in input contexts at all.
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* That just leaves 'Both. The only types of kind 'Both are scalars and enums,
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neither of which accept a sub-selection set. Their output result type would
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therefore be (), since they are allowed to appear in output contexts, but
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they don’t return any results.
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The end result of this is that we clutter all our types with Voids and ()s, with
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little actual benefit.
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If you really think about it, the fact that the no types of kind 'Both accept a
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sub-selection set is really something of a coincidence. In theory, one could
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imagine a future version of the GraphQL spec adding a type that can be used as
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both an input type or an output type, but accepts a sub-selection set. If that
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ever happens, we’ll have to tweak our encoding, but for now, we can take
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advantage of this happy coincidence and make the kinds serve double duty:
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* We can make `ParserInput 'Both` identical to `ParserInput 'Input`, since
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all parsers of kind 'Both only parse input values.
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* We can require types of kind 'Both in `selection`, which does not expect a
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sub-selection set, and types of kind 'Output in `subselection`, which does.
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Relying on this coincidence might seem a little gross, and perhaps it is
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somewhat. But it’s enormously convenient: not doing this would make some types
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significantly more complicated, since we would have to thread around more
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information at the type level and we couldn’t make as many simplifying
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assumptions. So until GraphQL adds a type that violates these assumptions, we
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are happy to take advantage of this coincidence. -}
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-- | Evidence for '<:'.
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data k1 :<: k2 where
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KRefl :: k :<: k
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KBoth :: k :<: 'Both
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-- | 'Kind' subsumption. The GraphQL kind hierarchy is extremely simple:
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--
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-- > Both
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-- > / \
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-- > Input Output
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--
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-- Various functions in this module use '<:' to allow 'Both' to be used in
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-- places where 'Input' or 'Output' would otherwise be expected.
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class k1 <: k2 where
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subKind :: k1 :<: k2
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instance k1 ~ k2 => k1 <: k2 where
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subKind = KRefl
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instance {-# OVERLAPPING #-} k <: 'Both where
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subKind = KBoth
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data Type k
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= NonNullable (NonNullableType k)
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| Nullable (NonNullableType k)
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instance Eq (Type k) where
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(==) = eqType
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-- | Like '==', but can compare 'Type's of different kinds.
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eqType :: Type k1 -> Type k2 -> Bool
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eqType (NonNullable a) (NonNullable b) = eqNonNullableType a b
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eqType (Nullable a) (Nullable b) = eqNonNullableType a b
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eqType _ _ = False
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instance HasName (Type k) where
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getName = getName . discardNullability
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instance HasDefinition (Type k) (TypeInfo k) where
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definitionLens f (NonNullable t) = NonNullable <$> definitionLens f t
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definitionLens f (Nullable t) = Nullable <$> definitionLens f t
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discardNullability :: Type k -> NonNullableType k
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discardNullability (NonNullable t) = t
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discardNullability (Nullable t) = t
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nullableType :: Type k -> Type k
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nullableType (NonNullable t) = Nullable t
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-- Defined like this to preserve sharing
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nullableType t@(Nullable {}) = t
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nonNullableType :: Type k -> Type k
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nonNullableType (Nullable t) = NonNullable t
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nonNullableType t@(NonNullable {}) = t
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data NonNullableType k
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= TNamed (Definition (TypeInfo k))
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| TList (Type k)
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instance Eq (NonNullableType k) where
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(==) = eqNonNullableType
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toGraphQLType :: Type k -> GType
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toGraphQLType = \case
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NonNullable t -> translateWith False t
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Nullable t -> translateWith True t
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where
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translateWith nullability = \case
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TNamed typeInfo -> TypeNamed (Nullability nullability) $ getName typeInfo
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TList typeInfo -> TypeList (Nullability nullability) $ toGraphQLType typeInfo
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-- | Like '==', but can compare 'NonNullableType's of different kinds.
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eqNonNullableType :: NonNullableType k1 -> NonNullableType k2 -> Bool
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eqNonNullableType (TNamed a) (TNamed b) = liftEq eqTypeInfo a b
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eqNonNullableType (TList a) (TList b) = eqType a b
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eqNonNullableType _ _ = False
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instance HasName (NonNullableType k) where
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getName (TNamed definition) = getName definition
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getName (TList t) = getName t
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instance HasDefinition (NonNullableType k) (TypeInfo k) where
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definitionLens f (TNamed definition) = TNamed <$> f definition
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definitionLens f (TList t) = TList <$> definitionLens f t
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{- Note [The interfaces story]
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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GraphQL interfaces are not conceptually complicated, but they pose some
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non-obvious challenges for our implementation. First, familiarize yourself with
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GraphQL interfaces themselves:
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* https://graphql.org/learn/schema/#interfaces
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* http://spec.graphql.org/June2018/#sec-Interfaces
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* http://spec.graphql.org/June2018/#sec-Objects
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The most logical repesentation of object and interface types is to have objects
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reference the interfaces they implement, but not the other way around. After
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all, that’s how it works in the GraphQL language: when you declare an interface,
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you just specify its fields, and you specify which interfaces each object type
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implements as part of their declarations.
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However, this representation is actually not very useful for us. We /also/ need
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the interfaces to reference the objects that implement them---forming a circular
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structure---for two reasons:
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1. Most directly, we need this information for introspection queries.
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Introspection queries for object types return the set of interfaces they
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implement <http://spec.graphql.org/June2018/#sec-Object>, and introspection
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queries for interfaces return the set of object types that implement them
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<http://spec.graphql.org/June2018/#sec-Interface>.
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2. Less obviously, it’s more natural to specify the relationships “backwards”
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like this when building the schema using the parser combinator language.
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From the parser’s point of view, each implementation of an interface
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corresponds to a distinct parsing possibility. For example, when we
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generate a Relay schema, the type of the `node` root field is an interface,
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and each table is a type that implements it:
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type query_root {
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node(id: ID!): Node
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...
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}
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interface Node {
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id: ID!
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}
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type author implements Node {
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id: ID!
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name: String!
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...
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}
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type article implements Node {
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id: ID!
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title: String!
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body: String!
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...
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}
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A query will use fragments on the Node type to access table-specific fields:
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query get_article_info($article_id: ID!) {
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node(id: $article_id) {
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... on article {
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title
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body
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}
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}
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}
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The query parser needs to know which types implement the interface (and
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how to parse their selection sets) so that it can parse the fragments.
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This presents some complications, since we need to build this information in a
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circular fashion. Currently, we do this in a very naïve way:
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* We require selectionSetObject to specify the interfaces it implements /and/
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require selectionSetInterface to specify the objects that implement it.
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* We take advantage of our existing memoization mechanism to do the knot-tying
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for us (see Note [Tying the knot] in Hasura.GraphQL.Parser.Class).
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You may notice that this makes it possible for the definitions to be
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inconsistent: we could construct an interface parser that parses some object
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type, but forget to specify that the object type implements the interface. This
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inconsistency is currently completely unchecked, which is quite unfortunate. It
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also means we don’t support remote schema-defined object types that implement
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interfaces we generate, since we don’t know anything about those types when we
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construct the interface.
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Since we don’t make very much use of interface types at the time of this
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writing, this isn’t much of a problem in practice. But if that changes, it would
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be worth implementing a more sophisticated solution that can gather up all the
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different sources of information and make sure they’re consistent. -}
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data InputObjectInfo = InputObjectInfo ~[Definition InputFieldInfo]
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-- Note that we can't check for equality of the fields since there may be
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-- circularity. So we rather check for equality of names.
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instance Eq InputObjectInfo where
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InputObjectInfo fields1 == InputObjectInfo fields2
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= Set.fromList (fmap dName fields1) == Set.fromList (fmap dName fields2)
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data ObjectInfo = ObjectInfo
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{ oiFields :: ~[Definition FieldInfo]
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-- ^ The fields that this object has. This consists of the fields of the
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-- interfaces that it implements, as well as any additional fields.
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, oiImplements :: ~[Definition InterfaceInfo]
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-- ^ The interfaces that this object implements (inheriting all their
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-- fields). See Note [The interfaces story] for more details.
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}
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-- Note that we can't check for equality of the fields and the interfaces since
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-- there may be circularity. So we rather check for equality of names.
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instance Eq ObjectInfo where
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ObjectInfo fields1 interfaces1 == ObjectInfo fields2 interfaces2
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= Set.fromList (fmap dName fields1 ) == Set.fromList (fmap dName fields2 )
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&& Set.fromList (fmap dName interfaces1) == Set.fromList (fmap dName interfaces2)
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-- | Type information for a GraphQL interface; see Note [The interfaces story]
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-- for more details.
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--
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-- Note: in the current working draft of the GraphQL specification (> June
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-- 2018), interfaces may implement other interfaces, but we currently don't
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-- support this.
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data InterfaceInfo = InterfaceInfo
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{ iiFields :: ~[Definition FieldInfo]
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-- ^ Fields declared by this interface. Every object implementing this
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-- interface must include those fields.
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, iiPossibleTypes :: ~[Definition ObjectInfo]
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-- ^ Objects that implement this interface. See Note [The interfaces story]
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-- for why we include that information here.
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}
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-- Note that we can't check for equality of the fields and the interfaces since
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-- there may be circularity. So we rather check for equality of names.
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instance Eq InterfaceInfo where
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InterfaceInfo fields1 objects1 == InterfaceInfo fields2 objects2
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= Set.fromList (fmap dName fields1 ) == Set.fromList (fmap dName fields2 )
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&& Set.fromList (fmap dName objects1 ) == Set.fromList (fmap dName objects2 )
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data UnionInfo = UnionInfo
|
||
{ uiPossibleTypes :: ~[Definition ObjectInfo]
|
||
-- ^ The member object types of this union.
|
||
}
|
||
|
||
data TypeInfo k where
|
||
TIScalar :: TypeInfo 'Both
|
||
TIEnum :: NonEmpty (Definition EnumValueInfo) -> TypeInfo 'Both
|
||
TIInputObject :: InputObjectInfo -> TypeInfo 'Input
|
||
TIObject :: ObjectInfo -> TypeInfo 'Output
|
||
TIInterface :: InterfaceInfo -> TypeInfo 'Output
|
||
TIUnion :: UnionInfo -> TypeInfo 'Output
|
||
|
||
instance Eq (TypeInfo k) where
|
||
(==) = eqTypeInfo
|
||
|
||
-- | Like '==', but can compare 'TypeInfo's of different kinds.
|
||
eqTypeInfo :: TypeInfo k1 -> TypeInfo k2 -> Bool
|
||
eqTypeInfo TIScalar TIScalar = True
|
||
eqTypeInfo (TIEnum values1) (TIEnum values2)
|
||
= Set.fromList (toList values1) == Set.fromList (toList values2)
|
||
-- NB the case for input objects currently has quadratic complexity, which is
|
||
-- probably avoidable. HashSets should be able to get this down to
|
||
-- O(n*log(n)). But this requires writing some Hashable instances by hand
|
||
-- because we use some existential types and GADTs.
|
||
eqTypeInfo (TIInputObject ioi1) (TIInputObject ioi2) = ioi1 == ioi2
|
||
eqTypeInfo (TIObject oi1) (TIObject oi2) = oi1 == oi2
|
||
eqTypeInfo (TIInterface ii1) (TIInterface ii2) = ii1 == ii2
|
||
eqTypeInfo (TIUnion (UnionInfo objects1)) (TIUnion (UnionInfo objects2))
|
||
= Set.fromList (fmap dName objects1) == Set.fromList (fmap dName objects2)
|
||
eqTypeInfo _ _ = False
|
||
|
||
getObjectInfo :: Type k -> Maybe (Definition ObjectInfo)
|
||
getObjectInfo = traverse getTI . (^.definitionLens)
|
||
where
|
||
getTI :: TypeInfo k -> Maybe ObjectInfo
|
||
getTI (TIObject oi) = Just oi
|
||
getTI _ = Nothing
|
||
|
||
getInterfaceInfo :: Type 'Output -> Maybe (Definition InterfaceInfo)
|
||
getInterfaceInfo = traverse getTI . (^.definitionLens)
|
||
where
|
||
getTI :: TypeInfo 'Output -> Maybe InterfaceInfo
|
||
getTI (TIInterface ii) = Just ii
|
||
getTI _ = Nothing
|
||
|
||
data SomeTypeInfo = forall k. SomeTypeInfo (TypeInfo k)
|
||
|
||
instance Eq SomeTypeInfo where
|
||
SomeTypeInfo a == SomeTypeInfo b = eqTypeInfo a b
|
||
|
||
data Definition a = Definition
|
||
{ dName :: Name
|
||
, dUnique :: Maybe Unique
|
||
-- ^ A unique identifier used to break cycles in mutually-recursive type
|
||
-- definitions. If two 'Definition's have the same 'Unique', they can be
|
||
-- assumed to be identical. Note that the inverse is /not/ true: two
|
||
-- definitions with different 'Unique's might still be otherwise identical.
|
||
--
|
||
-- Also see Note [Tying the knot] in Hasura.GraphQL.Parser.Class.
|
||
, dDescription :: Maybe Description
|
||
, dInfo :: ~a
|
||
-- ^ Lazy to allow mutually-recursive type definitions.
|
||
} deriving (Functor, Foldable, Traversable, Generic)
|
||
instance Hashable a => Hashable (Definition a) where
|
||
hashWithSalt salt Definition{..} =
|
||
salt `hashWithSalt` dName `hashWithSalt` dInfo
|
||
|
||
mkDefinition :: Name -> Maybe Description -> a -> Definition a
|
||
mkDefinition name description info = Definition name Nothing description info
|
||
|
||
instance Eq a => Eq (Definition a) where
|
||
(==) = eq1
|
||
|
||
instance Eq1 Definition where
|
||
liftEq eq (Definition name1 maybeUnique1 _ info1)
|
||
(Definition name2 maybeUnique2 _ info2)
|
||
| Just unique1 <- maybeUnique1
|
||
, Just unique2 <- maybeUnique2
|
||
, unique1 == unique2
|
||
= True
|
||
| otherwise
|
||
= name1 == name2 && eq info1 info2
|
||
|
||
instance HasName (Definition a) where
|
||
getName = dName
|
||
|
||
class HasDefinition s a | s -> a where
|
||
definitionLens :: Lens' s (Definition a)
|
||
instance HasDefinition (Definition a) a where
|
||
definitionLens = id
|
||
|
||
-- | Adds a 'Unique' to a 'Definition' that does not yet have one. If the
|
||
-- definition already has a 'Unique', the existing 'Unique' is kept.
|
||
addDefinitionUnique :: HasDefinition s a => Unique -> s -> s
|
||
addDefinitionUnique unique = over definitionLens \definition ->
|
||
definition { dUnique = dUnique definition <|> Just unique }
|
||
|
||
-- | Enum values have no extra information except for the information common to
|
||
-- all definitions, so this is just a placeholder for use as @'Definition'
|
||
-- 'EnumValueInfo'@.
|
||
data EnumValueInfo = EnumValueInfo
|
||
deriving (Eq, Generic)
|
||
instance Hashable EnumValueInfo
|
||
|
||
data InputFieldInfo
|
||
-- | A required field with a non-nullable type.
|
||
= forall k. ('Input <: k) => IFRequired (NonNullableType k)
|
||
-- | An optional input field with a nullable type and possibly a default
|
||
-- value. If a default value is provided, it should be a valid value for the
|
||
-- type.
|
||
--
|
||
-- Note that a default value of 'VNull' is subtly different from having no
|
||
-- default value at all. If no default value is provided, the GraphQL
|
||
-- specification allows distinguishing provided @null@ values from values left
|
||
-- completely absent; see Note [Optional fields and nullability] in
|
||
-- Hasura.GraphQL.Parser.Internal.Parser.
|
||
| forall k. ('Input <: k) => IFOptional (Type k) (Maybe (Value Void))
|
||
|
||
instance Eq InputFieldInfo where
|
||
IFRequired t1 == IFRequired t2 = eqNonNullableType t1 t2
|
||
IFOptional t1 v1 == IFOptional t2 v2 = eqType t1 t2 && v1 == v2
|
||
_ == _ = False
|
||
|
||
data FieldInfo = forall k. ('Output <: k) => FieldInfo
|
||
{ fArguments :: [Definition InputFieldInfo]
|
||
, fType :: Type k
|
||
}
|
||
|
||
instance Eq FieldInfo where
|
||
FieldInfo args1 t1 == FieldInfo args2 t2 = args1 == args2 && eqType t1 t2
|
||
|
||
{- Note [Parsing variable values]
|
||
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
||
GraphQL includes its own tiny language for input values, which is similar to
|
||
JSON but not quite the same---GraphQL input values can be enum values, and there
|
||
are restrictions on the names of input object keys. Despite these differences,
|
||
variables’ values are passed as JSON, so we actually need to be able to parse
|
||
values expressed in both languages.
|
||
|
||
It’s tempting to contain this complexity by simply converting the JSON values to
|
||
GraphQL input values up front, and for booleans, numbers, arrays, and most
|
||
objects, this conversion is viable. But JSON strings pose a problem, since they
|
||
are used to represent both GraphQL strings and GraphQL enums. For example,
|
||
consider a query like this:
|
||
|
||
enum FooBar {
|
||
FOO
|
||
BAR
|
||
}
|
||
|
||
query some_query($a: String, $b: FooBar) {
|
||
...
|
||
}
|
||
|
||
We might receive an accompany variables payload like this:
|
||
|
||
{
|
||
"a": "FOO",
|
||
"b": "FOO"
|
||
}
|
||
|
||
To properly convert these JSON values to GraphQL, we’d need to use the type
|
||
information to guide the parsing. Since $a has type String, its value should be
|
||
parsed as the GraphQL string "FOO", while $b has type FooBar, so its value
|
||
should be parsed as the GraphQL enum value FOO.
|
||
|
||
We could do this type-directed parsing, but there are some advantages to being
|
||
lazier. For one, we can use JSON values directly when used as a column value of
|
||
type json or jsonb, rather than converting them to GraphQL and back; which, in
|
||
turn, solves another problem with JSON objects: JSON object keys are arbitrary
|
||
strings, while GraphQL input object keys are GraphQL names, and therefore
|
||
restricted: not all JSON objects can be represented by a GraphQL input object.
|
||
|
||
Arguably such columns should really be represented as strings containing encoded
|
||
JSON, not GraphQL lists/objects, but the decision to treat them otherwise is
|
||
old, and it would be backwards-incompatible to change now. We can also avoid
|
||
needing to interpret the values of variables for types outside our control
|
||
(i.e. those from a remote schema), which can be useful in the case of custom
|
||
scalars or extensions of the GraphQL protocol.
|
||
|
||
So instead we use the InputValue type to represent that an input value might be
|
||
a GraphQL literal value or a JSON value from the variables payload. This means
|
||
each input parser constructor needs to be able to parse both GraphQL values and
|
||
JSON values, but fortunately, the duplication of logic is minimal. -}
|
||
|
||
-- | See Note [Parsing variable values].
|
||
data InputValue v
|
||
= GraphQLValue (Value v)
|
||
| JSONValue J.Value
|
||
deriving (Show, Eq, Functor, Generic, Ord)
|
||
instance (Hashable v) => Hashable (InputValue v)
|
||
instance (Cacheable v) => Cacheable (InputValue v)
|
||
|
||
data Variable = Variable
|
||
{ vInfo :: VariableInfo
|
||
, vType :: GType
|
||
, vValue :: InputValue Void
|
||
-- ^ Note: if the variable was null or was not provided and the field has a
|
||
-- non-null default value, this field contains the default value, not 'VNull'.
|
||
} deriving (Show, Eq, Generic, Ord)
|
||
instance Hashable Variable
|
||
instance Cacheable Variable
|
||
|
||
data VariableInfo
|
||
= VIRequired Name
|
||
-- | Unlike fields (see 'IFOptional'), nullable variables with no default
|
||
-- value are indistinguishable from variables with a default value of null, so
|
||
-- we don’t distinguish those cases here.
|
||
| VIOptional Name (Value Void)
|
||
deriving (Show, Eq, Generic, Ord)
|
||
instance Hashable VariableInfo
|
||
instance Cacheable VariableInfo
|
||
|
||
instance HasName Variable where
|
||
getName = getName . vInfo
|
||
instance HasName VariableInfo where
|
||
getName (VIRequired name) = name
|
||
getName (VIOptional name _) = name
|
||
|
||
|
||
-- -----------------------------------------------------------------------------
|
||
-- support for introspection queries
|
||
|
||
-- | This type represents the directives information to be served over GraphQL introspection
|
||
data DirectiveInfo = DirectiveInfo
|
||
{ diName :: !Name
|
||
, diDescription :: !(Maybe Description)
|
||
, diArguments :: ![Definition InputFieldInfo]
|
||
, diLocations :: ![DirectiveLocation]
|
||
}
|
||
|
||
-- | This type contains all the information needed to efficiently serve GraphQL
|
||
-- introspection queries. It corresponds to the GraphQL @__Schema@ type defined
|
||
-- in <§ 4.5 Schema Introspection http://spec.graphql.org/June2018/#sec-Introspection>.
|
||
data Schema = Schema
|
||
{ sDescription :: Maybe Description
|
||
, sTypes :: HashMap Name (Definition SomeTypeInfo)
|
||
, sQueryType :: Type 'Output
|
||
, sMutationType :: Maybe (Type 'Output)
|
||
, sSubscriptionType :: Maybe (Type 'Output)
|
||
, sDirectives :: [DirectiveInfo]
|
||
}
|
||
|
||
data TypeDefinitionsWrapper where
|
||
TypeDefinitionsWrapper :: HasTypeDefinitions a => a -> TypeDefinitionsWrapper
|
||
|
||
-- | Recursively collects all type definitions accessible from the given value.
|
||
collectTypeDefinitions
|
||
:: HasTypeDefinitions a
|
||
=> a
|
||
-> Either ConflictingDefinitions (HashMap Name (Definition SomeTypeInfo))
|
||
collectTypeDefinitions x =
|
||
fmap (fmap fst) $
|
||
runExcept $
|
||
flip execStateT Map.empty $
|
||
flip runReaderT (TypeOriginStack []) $
|
||
runTypeAccumulation $
|
||
accumulateTypeDefinitions x
|
||
|
||
newtype TypeOriginStack = TypeOriginStack [Name]
|
||
|
||
-- Add the current field name to the origin stack
|
||
typeOriginRecurse :: Name -> TypeOriginStack -> TypeOriginStack
|
||
typeOriginRecurse field (TypeOriginStack origins) = TypeOriginStack (field:origins)
|
||
|
||
-- This is kind of a hack to make sure that the query root name is part of the origin stack
|
||
typeRootRecurse :: Name -> TypeOriginStack -> TypeOriginStack
|
||
typeRootRecurse rootName (TypeOriginStack []) = (TypeOriginStack [rootName])
|
||
typeRootRecurse _ x = x
|
||
|
||
instance ToTxt TypeOriginStack where
|
||
toTxt (TypeOriginStack fields) = T.intercalate "." $ toTxt <$> reverse fields
|
||
|
||
data ConflictingDefinitions
|
||
= ConflictingDefinitions
|
||
(Definition SomeTypeInfo, TypeOriginStack)
|
||
(Definition SomeTypeInfo, NonEmpty TypeOriginStack)
|
||
-- ^ Type collection has found at least two types with the same name.
|
||
|
||
-- | Although the majority of graphql-engine is written in terms of abstract
|
||
-- mtl-style effect monads, we figured out that this particular codepath is
|
||
-- quite hot, and that mtl has a measurable negative effect for accumulating
|
||
-- types from the schema, both in profiling and in benchmarking. Using an
|
||
-- explicit transformers-style effect stack seems to overall memory usage by
|
||
-- about 3-7%.
|
||
newtype TypeAccumulation a = TypeAccumulation
|
||
{ runTypeAccumulation
|
||
:: ReaderT TypeOriginStack
|
||
( StateT (HashMap Name (Definition SomeTypeInfo, NonEmpty TypeOriginStack))
|
||
( ExceptT ConflictingDefinitions Identity))
|
||
a
|
||
}
|
||
deriving (Functor, Applicative, Monad)
|
||
deriving (MonadReader TypeOriginStack)
|
||
deriving (MonadState (HashMap Name (Definition SomeTypeInfo, NonEmpty TypeOriginStack)))
|
||
deriving (MonadError ConflictingDefinitions)
|
||
|
||
class HasTypeDefinitions a where
|
||
-- | Recursively accumulates all type definitions accessible from the given
|
||
-- value. This is done statefully to avoid infinite loops arising from
|
||
-- recursive type definitions; see Note [Tying the knot] in Hasura.GraphQL.Parser.Class.
|
||
accumulateTypeDefinitions
|
||
:: a -> TypeAccumulation ()
|
||
|
||
instance HasTypeDefinitions (Definition (TypeInfo k)) where
|
||
accumulateTypeDefinitions definition = do
|
||
-- This is the important case! We actually have a type definition, so we
|
||
-- need to add it to the state.
|
||
definitions <- get
|
||
stack <- ask
|
||
let new = SomeTypeInfo <$> definition
|
||
case Map.lookup (dName new) definitions of
|
||
Nothing -> do
|
||
put $! Map.insert (dName new) (new, pure stack) definitions
|
||
-- This type definition might reference other type definitions, so we
|
||
-- still need to recur.
|
||
local (typeRootRecurse (getName definition)) $ accumulateTypeDefinitions (dInfo definition)
|
||
Just (old, origins)
|
||
-- It’s important we /don’t/ recur if we’ve already seen this definition
|
||
-- before to avoid infinite loops; see Note [Tying the knot] in Hasura.GraphQL.Parser.Class.
|
||
| old == new -> put $! Map.insert (dName new) (old, stack `NE.cons` origins) definitions
|
||
| otherwise -> throwError $ ConflictingDefinitions (new, stack) (old, origins)
|
||
|
||
instance HasTypeDefinitions a => HasTypeDefinitions [a] where
|
||
accumulateTypeDefinitions = traverse_ accumulateTypeDefinitions
|
||
|
||
instance HasTypeDefinitions TypeDefinitionsWrapper where
|
||
accumulateTypeDefinitions (TypeDefinitionsWrapper x) = accumulateTypeDefinitions x
|
||
|
||
instance HasTypeDefinitions (Type k) where
|
||
accumulateTypeDefinitions = \case
|
||
NonNullable t -> accumulateTypeDefinitions t
|
||
Nullable t -> accumulateTypeDefinitions t
|
||
|
||
instance HasTypeDefinitions (NonNullableType k) where
|
||
accumulateTypeDefinitions = \case
|
||
TNamed d -> accumulateTypeDefinitions d
|
||
TList t -> accumulateTypeDefinitions t
|
||
|
||
instance HasTypeDefinitions (TypeInfo k) where
|
||
accumulateTypeDefinitions = \case
|
||
TIScalar -> pure ()
|
||
TIEnum _ -> pure ()
|
||
TIInputObject (InputObjectInfo fields) -> accumulateTypeDefinitions fields
|
||
TIObject (ObjectInfo fields interfaces) ->
|
||
accumulateTypeDefinitions fields >> accumulateTypeDefinitions interfaces
|
||
TIInterface (InterfaceInfo fields objects) ->
|
||
accumulateTypeDefinitions fields
|
||
>> accumulateTypeDefinitions objects
|
||
TIUnion (UnionInfo objects) -> accumulateTypeDefinitions objects
|
||
|
||
instance HasTypeDefinitions (Definition InputObjectInfo) where
|
||
accumulateTypeDefinitions = accumulateTypeDefinitions . fmap TIInputObject
|
||
|
||
instance HasTypeDefinitions (Definition InputFieldInfo) where
|
||
accumulateTypeDefinitions Definition{..} =
|
||
local (typeOriginRecurse dName) $ accumulateTypeDefinitions dInfo
|
||
|
||
instance HasTypeDefinitions InputFieldInfo where
|
||
accumulateTypeDefinitions = \case
|
||
IFRequired t -> accumulateTypeDefinitions t
|
||
IFOptional t _ -> accumulateTypeDefinitions t
|
||
|
||
instance HasTypeDefinitions (Definition FieldInfo) where
|
||
accumulateTypeDefinitions Definition{..} =
|
||
local (typeOriginRecurse dName) $ accumulateTypeDefinitions dInfo
|
||
|
||
instance HasTypeDefinitions FieldInfo where
|
||
accumulateTypeDefinitions (FieldInfo args t) = do
|
||
accumulateTypeDefinitions args
|
||
accumulateTypeDefinitions t
|
||
|
||
instance HasTypeDefinitions (Definition ObjectInfo) where
|
||
accumulateTypeDefinitions d@Definition{..} =
|
||
local (typeOriginRecurse dName) $ accumulateTypeDefinitions (fmap TIObject d)
|
||
|
||
instance HasTypeDefinitions (Definition InterfaceInfo) where
|
||
accumulateTypeDefinitions d@Definition{..} =
|
||
local (typeOriginRecurse dName) $ accumulateTypeDefinitions (fmap TIInterface d)
|
||
|
||
instance HasTypeDefinitions (Definition UnionInfo) where
|
||
accumulateTypeDefinitions d@Definition{..} =
|
||
local (typeOriginRecurse dName) $ accumulateTypeDefinitions (fmap TIUnion d)
|