mirror of
https://github.com/hasura/graphql-engine.git
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342391f39d
This upgrades the version of Ormolu required by the HGE repository to v0.5.0.1, and reformats all code accordingly. Ormolu v0.5 reformats code that uses infix operators. This is mostly useful, adding newlines and indentation to make it clear which operators are applied first, but in some cases, it's unpleasant. To make this easier on the eyes, I had to do the following: * Add a few fixity declarations (search for `infix`) * Add parentheses to make precedence clear, allowing Ormolu to keep everything on one line * Rename `relevantEq` to `(==~)` in #6651 and set it to `infix 4` * Add a few _.ormolu_ files (thanks to @hallettj for helping me get started), mostly for Autodocodec operators that don't have explicit fixity declarations In general, I think these changes are quite reasonable. They mostly affect indentation. PR-URL: https://github.com/hasura/graphql-engine-mono/pull/6675 GitOrigin-RevId: cd47d87f1d089fb0bc9dcbbe7798dbceedcd7d83
726 lines
26 KiB
Haskell
726 lines
26 KiB
Haskell
{-# LANGUAGE ApplicativeDo #-}
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module Hasura.GraphQL.Schema.Introspect
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( buildIntrospectionSchema,
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schema,
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typeIntrospection,
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)
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where
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import Data.Aeson.Ordered qualified as J
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import Data.HashMap.Strict qualified as Map
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import Data.HashMap.Strict.InsOrd qualified as OMap
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import Data.List.NonEmpty qualified as NE
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import Data.Text qualified as T
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import Data.Vector qualified as V
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import Hasura.GraphQL.Parser.Class
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import Hasura.GraphQL.Parser.Directives
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import Hasura.GraphQL.Parser.Name qualified as GName
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import Hasura.GraphQL.Schema.Parser as P
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import Hasura.Prelude
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import Language.GraphQL.Draft.Printer qualified as GP
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import Language.GraphQL.Draft.Syntax qualified as G
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import Text.Builder qualified as T
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{-
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Note [Basics of introspection schema generation]
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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We generate the introspection schema from the existing schema for queries,
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mutations and subscriptions. In other words, we generate one @Parser@ from some
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other @Parser@s. In this way, we avoid having to remember what types we have to
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expose through introspection explicitly, as we did in a previous version of
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graphql-engine.
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However the schema information is obtained, the @Schema@ type stores it. From a
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@Schema@ object we then produce one @FieldParser@ that reads a `__schema` field,
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and one that reads a `__type` field. The idea is that these parsers simply
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output a JSON value directly, and so indeed the type of @schema@, for instance,
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is @FieldParser n J.Value@.
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The idea of "just output the JSON object directly" breaks down when we want to
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output a list of things, however, such as in the `types` field of `__schema`.
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In the case of `types`, the JSON object to be generated is influenced by the
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underlying selection set, so that, for instance,
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```
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query {
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__schema {
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types {
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name
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}
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}
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}
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```
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means that we only output the _name_ of every type in our schema. One naive
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approach one might consider here would be to have a parser
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```
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typeField :: P.Type k -> Parser n J.Value
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```
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that takes a type, and is able to produce a JSON value for it, and then to apply
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this parser to all the types in our schema.
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However, we only have *one* selection set to parse: so which of the parsers we
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obtained should we use to parse it? And what should we do in the theoretical
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case that we have a schema without any types? (The latter is actually not
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possible since we always have `query_root`, but it illustrates the problem that
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there is no canonical choice of type to use to parse the selection set.)
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Additionally, this would allow us to get the JSON output for *one* type, rather
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than for our list of types. After all, @Parser n@ is *not* a @Monad@ (it's not
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even an @Applicative@), so we don't have a map @(a -> Parser n b) -> [a] -> m
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[b]@.
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In order to resolve this conundrum, let's consider what the ordinary Postgres
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schema generates for a query such as follows.
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```
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query {
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author {
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articles {
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title
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}
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}
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}
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```
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Now the @Parser@ for an article's title does not directly give the desired
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output data: indeed, there would be many different titles, rather than any
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single one we can return. Instead, it returns a value that can, after parsing,
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be used to build an output, along the lines of:
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```
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articleTitle :: FieldParser n SQLArticleTitle
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```
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(This is a heavily simplified representation of reality.)
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These values can be thought of as an intermediate representation that can then
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be used to generate and run SQL that gives the desired JSON output at a later
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stage. In other words, in the above example, @SQLArticleTitle@ can be thought
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of as a function @Article -> Title@ that, given an article, gives back its
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title.
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Such an approach could help us as well, as, from instructions on how to generate
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a JSON return for a given `__Type`, surely we can later simply apply this
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construction to all types desired.
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However, we don't _need_ to build an intermediate AST to do this: we can simply
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output the conversion functions directly. So the type of @typeField@ is closer
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to:
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```
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typeField :: Parser n (P.Type k -> J.Value)
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```
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This says that we are always able to parse a selection set for a `__Type`, and
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once we do, we obtain a map, which we refer to as `printer` in this module,
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which can output a JSON object for a given GraphQL type from our schema.
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To use `typeField` as part of another selection set, we build up a corresponding
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`FieldParser`, thus obtaining a printer, then apply this printer to all desired
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types, and output the final JSON object as a J.Array of the printed results,
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like so (again, heavily simplified):
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```
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types :: FieldParser n J.Value
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types = do
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printer <- P.subselection_ GName._types Nothing typeField
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return $ J.Array $ map printer $ allSchemaTypes
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```
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Upon reading this you may be bewildered how we are able to use do notation for
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@FieldParser@, which does not have a @Monad@ instance, or even an @Applicative@
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instance. It just so happens that, as long as we write our do blocks carefully,
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so that we only use the functoriality of @FieldParser@, the simplification rules
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of GHC kick in just in time to avoid any application of @(>>=)@ or @return@.
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Arguably the above notation is prettier than equivalent code that explicitly
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reduces this to applications of @fmap@. If you, dear reader, feel like the do
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notation adds more confusion than value, you should feel free to change this, as
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there is no deeper meaning to the application of do notation than ease of
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reading.
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-}
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{- Note [What introspection exposes]
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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NB: By "introspection query", we mean a query making use of the __type or
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__schema top-level fields.
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It would be very convenient if we could simply build up our desired GraphQL
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schema, without regard for introspection. Ideally, we would then extract the
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data required for introspection from this complete GraphQL schema. There are,
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however, some complications:
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1. Of course, we _do_ need to include the introspection fields themselves into
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the query_root, so that we can deal with introspection queries
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appropriately. So we can't avoid thinking about introspection entirely while
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constructing the GraphQL schema.
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2. The GraphQL specification says that although we must always expose __type and
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__schema fields as part of the query_root, they must not be visible fields of
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the query_root object type. See
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http://spec.graphql.org/June2018/#sec-Schema-Introspection
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At this point, one might naively attempt to generate two GraphQL schemas:
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- One without the __type and __schema fields, from which we generate the data
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required for responding to introspection queries.
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- One with the __type and __schema fields, which is used to actually respond to
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queries.
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However, this is also not GraphQL-compliant!
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The problem here is that while __type and __schema are not visible fields of the
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query root object, their *types*, __Type and __Schema respectively, *must be*
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exposed through __type introspection, even though those types never appear as
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(transitive) members of the query/mutation/subscription root fields.
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So in order to gather the data required for introspection, we follow the
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following recipe:
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A. Collect type information from the introspection-free GraphQL schema
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B. Collect type information from the introspection-only GraphQL schema
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C. Stitch together the results of (A) and (B). In particular, the query_root
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from (A) is used, and all types from (A) and (B) are used, except for the
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query_root obtained in (B). -}
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-- | Builds a @Schema@ from GraphQL types for the query_root, mutation_root and
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-- subscription_root.
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--
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-- See Note [What introspection exposes]
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buildIntrospectionSchema ::
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P.Type 'Output ->
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Maybe (P.Type 'Output) ->
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Maybe (P.Type 'Output) ->
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Either P.ConflictingDefinitions P.Schema
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buildIntrospectionSchema queryRoot' mutationRoot' subscriptionRoot' = do
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let -- The only directives that we currently expose over introspection are our
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-- statically defined ones. So, for instance, we don't correctly expose
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-- directives from remote schemas.
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directives :: [DirectiveInfo] = directivesInfo @P.Parse
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-- Collect type information of all fields
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--
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-- TODO: it may be worth looking at whether we can stop collecting
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-- introspection types monadically. They are independent of the user schema;
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-- the types here are always the same and specified by the GraphQL spec
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allTypes <-
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P.collectTypeDefinitions
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[ P.TypeDefinitionsWrapper queryRoot',
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P.TypeDefinitionsWrapper mutationRoot',
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P.TypeDefinitionsWrapper subscriptionRoot',
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P.TypeDefinitionsWrapper $ P.diArguments =<< directives,
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-- The __schema introspection field
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P.TypeDefinitionsWrapper $ fDefinition (schema @Parse),
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-- The __type introspection field
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P.TypeDefinitionsWrapper $ fDefinition (typeIntrospection @Parse)
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]
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pure $
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P.Schema
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{ sDescription = Nothing,
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sTypes = allTypes,
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sQueryType = queryRoot',
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sMutationType = mutationRoot',
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sSubscriptionType = subscriptionRoot',
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sDirectives = directives
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}
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-- | Generate a __type introspection parser
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typeIntrospection ::
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forall n.
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MonadParse n =>
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FieldParser n (Schema -> J.Value)
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{-# INLINE typeIntrospection #-}
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typeIntrospection = do
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let nameArg :: P.InputFieldsParser n Text
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nameArg = P.field GName._name Nothing P.string
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~(nameText, printer) <- P.subselection GName.___type Nothing nameArg typeField
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-- We pass around the GraphQL schema information under the name `partialSchema`,
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-- because the GraphQL spec forces us to expose a hybrid between the
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-- specification of valid queries (including introspection) and an
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-- introspection-free GraphQL schema. See Note [What introspection exposes].
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pure $ \partialSchema -> fromMaybe J.Null $ do
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name <- G.mkName nameText
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P.SomeDefinitionTypeInfo def <- Map.lookup name $ sTypes partialSchema
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Just $ printer $ SomeType $ P.TNamed P.Nullable def
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-- | Generate a __schema introspection parser.
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schema ::
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forall n.
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MonadParse n =>
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FieldParser n (Schema -> J.Value)
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{-# INLINE schema #-}
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schema = P.subselection_ GName.___schema Nothing schemaSet
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{-
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type __Type {
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kind: __TypeKind!
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name: String
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description: String
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# should be non-null for OBJECT and INTERFACE only, must be null for the others
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fields(includeDeprecated: Boolean = false): [__Field!]
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# should be non-null for OBJECT and INTERFACE only, must be null for the others
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interfaces: [__Type!]
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# should be non-null for INTERFACE and UNION only, always null for the others
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possibleTypes: [__Type!]
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# should be non-null for ENUM only, must be null for the others
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enumValues(includeDeprecated: Boolean = false): [__EnumValue!]
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# should be non-null for INPUT_OBJECT only, must be null for the others
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inputFields: [__InputValue!]
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# should be non-null for NON_NULL and LIST only, must be null for the others
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ofType: __Type
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}
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-}
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data SomeType = forall k. SomeType (P.Type k)
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typeField ::
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forall n.
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MonadParse n =>
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Parser 'Output n (SomeType -> J.Value)
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typeField =
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let includeDeprecated :: P.InputFieldsParser n Bool
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includeDeprecated =
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P.fieldWithDefault GName._includeDeprecated Nothing (G.VBoolean False) (P.nullable P.boolean)
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<&> fromMaybe False
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kind :: FieldParser n (SomeType -> J.Value)
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kind =
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P.selection_ GName._kind Nothing typeKind
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$> \case
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SomeType tp ->
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case tp of
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P.TList P.NonNullable _ ->
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J.String "NON_NULL"
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P.TNamed P.NonNullable _ ->
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J.String "NON_NULL"
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P.TList P.Nullable _ ->
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J.String "LIST"
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P.TNamed P.Nullable (P.Definition _ _ _ _ P.TIScalar) ->
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J.String "SCALAR"
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIEnum _)) ->
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J.String "ENUM"
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIInputObject _)) ->
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J.String "INPUT_OBJECT"
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIObject _)) ->
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J.String "OBJECT"
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIInterface _)) ->
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J.String "INTERFACE"
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIUnion _)) ->
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J.String "UNION"
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name :: FieldParser n (SomeType -> J.Value)
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name =
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P.selection_ GName._name Nothing P.string
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$> \case
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SomeType tp ->
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case tp of
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P.TNamed P.Nullable (P.Definition name' _ _ _ _) ->
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nameAsJSON name'
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_ -> J.Null
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description :: FieldParser n (SomeType -> J.Value)
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description =
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P.selection_ GName._description Nothing P.string
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$> \case
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SomeType (P.TNamed _ (P.Definition _ (Just desc) _ _ _)) ->
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J.String (G.unDescription desc)
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_ -> J.Null
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fields :: FieldParser n (SomeType -> J.Value)
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fields = do
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-- TODO handle the value of includeDeprecated
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~(_includeDeprecated, printer) <- P.subselection GName._fields Nothing includeDeprecated fieldField
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return $
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\case
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SomeType tp ->
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case tp of
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIObject (P.ObjectInfo fields' _interfaces'))) ->
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J.Array $ V.fromList $ printer <$> fields'
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIInterface (P.InterfaceInfo fields' _objects'))) ->
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J.Array $ V.fromList $ printer <$> fields'
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_ -> J.Null
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interfaces :: FieldParser n (SomeType -> J.Value)
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interfaces = do
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printer <- P.subselection_ GName._interfaces Nothing typeField
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return $
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\case
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SomeType tp ->
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case tp of
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIObject (P.ObjectInfo _fields' interfaces'))) ->
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J.Array $ V.fromList $ printer . SomeType . P.TNamed P.Nullable . fmap P.TIInterface <$> interfaces'
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_ -> J.Null
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possibleTypes :: FieldParser n (SomeType -> J.Value)
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possibleTypes = do
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printer <- P.subselection_ GName._possibleTypes Nothing typeField
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return $
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\case
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SomeType tp ->
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case tp of
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIInterface (P.InterfaceInfo _fields' objects'))) ->
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J.Array $ V.fromList $ printer . SomeType . P.TNamed P.Nullable . fmap P.TIObject <$> objects'
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIUnion (P.UnionInfo objects'))) ->
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J.Array $ V.fromList $ printer . SomeType . P.TNamed P.Nullable . fmap P.TIObject <$> objects'
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_ -> J.Null
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enumValues :: FieldParser n (SomeType -> J.Value)
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enumValues = do
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-- TODO handle the value of includeDeprecated
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~(_includeDeprecated, printer) <- P.subselection GName._enumValues Nothing includeDeprecated enumValue
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return $
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\case
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SomeType tp ->
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case tp of
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIEnum vals)) ->
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J.Array $ V.fromList $ fmap printer $ toList vals
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_ -> J.Null
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inputFields :: FieldParser n (SomeType -> J.Value)
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inputFields = do
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printer <- P.subselection_ GName._inputFields Nothing inputValue
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return $
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\case
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SomeType tp ->
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case tp of
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P.TNamed P.Nullable (P.Definition _ _ _ _ (P.TIInputObject (P.InputObjectInfo fieldDefs))) ->
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J.Array $ V.fromList $ map printer fieldDefs
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_ -> J.Null
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-- ofType peels modalities off of types
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ofType :: FieldParser n (SomeType -> J.Value)
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ofType = do
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printer <- P.subselection_ GName._ofType Nothing typeField
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return $ \case
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-- kind = "NON_NULL": !a -> a
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SomeType (P.TNamed P.NonNullable x) ->
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printer $ SomeType $ P.TNamed P.Nullable x
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-- kind = "NON_NULL": ![a] -> [a], and ![!a] -> [!a]
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SomeType (P.TList P.NonNullable x) ->
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printer $ SomeType $ P.TList P.Nullable x
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-- kind = "LIST": [a] -> a
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SomeType (P.TList P.Nullable x) ->
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printer $ SomeType x
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_ -> J.Null
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in applyPrinter
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<$> P.selectionSet
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GName.___Type
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Nothing
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[ kind,
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name,
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description,
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fields,
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interfaces,
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possibleTypes,
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enumValues,
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inputFields,
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ofType
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]
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{-
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type __InputValue {
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name: String!
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description: String
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type: __Type!
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defaultValue: String
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}
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-}
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inputValue ::
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forall n.
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MonadParse n =>
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Parser 'Output n (P.Definition P.InputFieldInfo -> J.Value)
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inputValue =
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let name :: FieldParser n (P.Definition P.InputFieldInfo -> J.Value)
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name =
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P.selection_ GName._name Nothing P.string
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$> nameAsJSON . P.dName
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description :: FieldParser n (P.Definition P.InputFieldInfo -> J.Value)
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description =
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P.selection_ GName._description Nothing P.string
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$> maybe J.Null (J.String . G.unDescription) . P.dDescription
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typeF :: FieldParser n (P.Definition P.InputFieldInfo -> J.Value)
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typeF = do
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printer <- P.subselection_ GName._type Nothing typeField
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return $ \defInfo -> case P.dInfo defInfo of
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P.InputFieldInfo tp _ -> printer $ SomeType tp
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defaultValue :: FieldParser n (P.Definition P.InputFieldInfo -> J.Value)
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defaultValue =
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P.selection_ GName._defaultValue Nothing P.string
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$> \defInfo -> case P.dInfo defInfo of
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P.InputFieldInfo _ (Just val) -> J.String $ T.run $ GP.value val
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_ -> J.Null
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in applyPrinter
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<$> P.selectionSet
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GName.___InputValue
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Nothing
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[ name,
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description,
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typeF,
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defaultValue
|
|
]
|
|
|
|
{-
|
|
type __EnumValue {
|
|
name: String!
|
|
description: String
|
|
isDeprecated: Boolean!
|
|
deprecationReason: String
|
|
}
|
|
-}
|
|
enumValue ::
|
|
forall n.
|
|
MonadParse n =>
|
|
Parser 'Output n (P.Definition P.EnumValueInfo -> J.Value)
|
|
enumValue =
|
|
let name :: FieldParser n (P.Definition P.EnumValueInfo -> J.Value)
|
|
name =
|
|
P.selection_ GName._name Nothing P.string
|
|
$> nameAsJSON . P.dName
|
|
description :: FieldParser n (P.Definition P.EnumValueInfo -> J.Value)
|
|
description =
|
|
P.selection_ GName._description Nothing P.string
|
|
$> maybe J.Null (J.String . G.unDescription) . P.dDescription
|
|
-- TODO We don't seem to support enum value deprecation
|
|
isDeprecated :: FieldParser n (P.Definition P.EnumValueInfo -> J.Value)
|
|
isDeprecated =
|
|
P.selection_ GName._isDeprecated Nothing P.string
|
|
$> const (J.Bool False)
|
|
deprecationReason :: FieldParser n (P.Definition P.EnumValueInfo -> J.Value)
|
|
deprecationReason =
|
|
P.selection_ GName._deprecationReason Nothing P.string
|
|
$> const J.Null
|
|
in applyPrinter
|
|
<$> P.selectionSet
|
|
GName.___EnumValue
|
|
Nothing
|
|
[ name,
|
|
description,
|
|
isDeprecated,
|
|
deprecationReason
|
|
]
|
|
|
|
{-
|
|
enum __TypeKind {
|
|
ENUM
|
|
INPUT_OBJECT
|
|
INTERFACE
|
|
LIST
|
|
NON_NULL
|
|
OBJECT
|
|
SCALAR
|
|
UNION
|
|
}
|
|
-}
|
|
typeKind ::
|
|
forall n.
|
|
MonadParse n =>
|
|
Parser 'Both n ()
|
|
typeKind =
|
|
P.enum
|
|
GName.___TypeKind
|
|
Nothing
|
|
( NE.fromList
|
|
[ mkDefinition GName._ENUM,
|
|
mkDefinition GName._INPUT_OBJECT,
|
|
mkDefinition GName._INTERFACE,
|
|
mkDefinition GName._LIST,
|
|
mkDefinition GName._NON_NULL,
|
|
mkDefinition GName._OBJECT,
|
|
mkDefinition GName._SCALAR,
|
|
mkDefinition GName._UNION
|
|
]
|
|
)
|
|
where
|
|
mkDefinition name = (P.Definition name Nothing Nothing [] P.EnumValueInfo, ())
|
|
|
|
{-
|
|
type __Field {
|
|
name: String!
|
|
description: String
|
|
args: [__InputValue!]!
|
|
type: __Type!
|
|
isDeprecated: Boolean!
|
|
deprecationReason: String
|
|
}
|
|
-}
|
|
fieldField ::
|
|
forall n.
|
|
MonadParse n =>
|
|
Parser 'Output n (P.Definition P.FieldInfo -> J.Value)
|
|
fieldField =
|
|
let name :: FieldParser n (P.Definition P.FieldInfo -> J.Value)
|
|
name =
|
|
P.selection_ GName._name Nothing P.string
|
|
$> nameAsJSON . P.dName
|
|
description :: FieldParser n (P.Definition P.FieldInfo -> J.Value)
|
|
description =
|
|
P.selection_ GName._description Nothing P.string $> \defInfo ->
|
|
case P.dDescription defInfo of
|
|
Nothing -> J.Null
|
|
Just desc -> J.String (G.unDescription desc)
|
|
args :: FieldParser n (P.Definition P.FieldInfo -> J.Value)
|
|
args = do
|
|
printer <- P.subselection_ GName._args Nothing inputValue
|
|
return $ J.Array . V.fromList . map printer . sortOn P.dName . P.fArguments . P.dInfo
|
|
typeF :: FieldParser n (P.Definition P.FieldInfo -> J.Value)
|
|
typeF = do
|
|
printer <- P.subselection_ GName._type Nothing typeField
|
|
return $ printer . (\case P.FieldInfo _ tp -> SomeType tp) . P.dInfo
|
|
-- TODO We don't seem to track deprecation info
|
|
isDeprecated :: FieldParser n (P.Definition P.FieldInfo -> J.Value)
|
|
isDeprecated =
|
|
P.selection_ GName._isDeprecated Nothing P.string
|
|
$> const (J.Bool False)
|
|
deprecationReason :: FieldParser n (P.Definition P.FieldInfo -> J.Value)
|
|
deprecationReason =
|
|
P.selection_ GName._deprecationReason Nothing P.string
|
|
$> const J.Null
|
|
in applyPrinter
|
|
<$> P.selectionSet
|
|
GName.___Field
|
|
Nothing
|
|
[ name,
|
|
description,
|
|
args,
|
|
typeF,
|
|
isDeprecated,
|
|
deprecationReason
|
|
]
|
|
|
|
{-
|
|
type __Directive {
|
|
name: String!
|
|
description: String
|
|
locations: [__DirectiveLocation!]!
|
|
args: [__InputValue!]!
|
|
isRepeatable: Boolean!
|
|
}
|
|
-}
|
|
|
|
directiveSet ::
|
|
forall n.
|
|
MonadParse n =>
|
|
Parser 'Output n (P.DirectiveInfo -> J.Value)
|
|
directiveSet =
|
|
let name :: FieldParser n (P.DirectiveInfo -> J.Value)
|
|
name =
|
|
P.selection_ GName._name Nothing P.string
|
|
$> (J.toOrdered . P.diName)
|
|
description :: FieldParser n (P.DirectiveInfo -> J.Value)
|
|
description =
|
|
P.selection_ GName._description Nothing P.string
|
|
$> (J.toOrdered . P.diDescription)
|
|
locations :: FieldParser n (P.DirectiveInfo -> J.Value)
|
|
locations =
|
|
P.selection_ GName._locations Nothing P.string
|
|
$> (J.toOrdered . map showDirLoc . P.diLocations)
|
|
args :: FieldParser n (P.DirectiveInfo -> J.Value)
|
|
args = do
|
|
printer <- P.subselection_ GName._args Nothing inputValue
|
|
pure $ J.array . map printer . P.diArguments
|
|
isRepeatable :: FieldParser n (P.DirectiveInfo -> J.Value)
|
|
isRepeatable =
|
|
P.selection_ GName._isRepeatable Nothing P.string
|
|
$> const J.Null
|
|
in applyPrinter
|
|
<$> P.selectionSet
|
|
GName.___Directive
|
|
Nothing
|
|
[ name,
|
|
description,
|
|
locations,
|
|
args,
|
|
isRepeatable
|
|
]
|
|
where
|
|
showDirLoc :: G.DirectiveLocation -> Text
|
|
showDirLoc = \case
|
|
G.DLExecutable edl -> T.pack $ drop 3 $ show edl
|
|
G.DLTypeSystem tsdl -> T.pack $ drop 4 $ show tsdl
|
|
|
|
{-
|
|
type __Schema {
|
|
description: String
|
|
types: [__Type!]!
|
|
queryType: __Type!
|
|
mutationType: __Type
|
|
subscriptionType: __Type
|
|
directives: [__Directive!]!
|
|
}
|
|
-}
|
|
schemaSet ::
|
|
forall n.
|
|
MonadParse n =>
|
|
Parser 'Output n (Schema -> J.Value)
|
|
{-# INLINE schemaSet #-}
|
|
schemaSet =
|
|
let description :: FieldParser n (Schema -> J.Value)
|
|
description =
|
|
P.selection_ GName._description Nothing P.string
|
|
$> \partialSchema -> case sDescription partialSchema of
|
|
Nothing -> J.Null
|
|
Just s -> J.String $ G.unDescription s
|
|
types :: FieldParser n (Schema -> J.Value)
|
|
types = do
|
|
printer <- P.subselection_ GName._types Nothing typeField
|
|
return $
|
|
\partialSchema ->
|
|
J.Array $
|
|
V.fromList $
|
|
map (printer . schemaTypeToSomeType) $
|
|
sortOn P.getName $
|
|
Map.elems $
|
|
sTypes partialSchema
|
|
where
|
|
schemaTypeToSomeType :: P.SomeDefinitionTypeInfo -> SomeType
|
|
schemaTypeToSomeType (P.SomeDefinitionTypeInfo def) =
|
|
SomeType $ P.TNamed P.Nullable def
|
|
queryType :: FieldParser n (Schema -> J.Value)
|
|
queryType = do
|
|
printer <- P.subselection_ GName._queryType Nothing typeField
|
|
return $ \partialSchema -> printer $ SomeType $ sQueryType partialSchema
|
|
mutationType :: FieldParser n (Schema -> J.Value)
|
|
mutationType = do
|
|
printer <- P.subselection_ GName._mutationType Nothing typeField
|
|
return $ \partialSchema -> case sMutationType partialSchema of
|
|
Nothing -> J.Null
|
|
Just tp -> printer $ SomeType tp
|
|
subscriptionType :: FieldParser n (Schema -> J.Value)
|
|
subscriptionType = do
|
|
printer <- P.subselection_ GName._subscriptionType Nothing typeField
|
|
return $ \partialSchema -> case sSubscriptionType partialSchema of
|
|
Nothing -> J.Null
|
|
Just tp -> printer $ SomeType tp
|
|
directives :: FieldParser n (Schema -> J.Value)
|
|
directives = do
|
|
printer <- P.subselection_ GName._directives Nothing directiveSet
|
|
return $ \partialSchema -> J.array $ map printer $ sDirectives partialSchema
|
|
in applyPrinter
|
|
<$> P.selectionSet
|
|
GName.___Schema
|
|
Nothing
|
|
[ description,
|
|
types,
|
|
queryType,
|
|
mutationType,
|
|
subscriptionType,
|
|
directives
|
|
]
|
|
|
|
selectionSetToJSON ::
|
|
OMap.InsOrdHashMap G.Name J.Value ->
|
|
J.Value
|
|
selectionSetToJSON = J.object . map (first G.unName) . OMap.toList
|
|
|
|
applyPrinter ::
|
|
OMap.InsOrdHashMap G.Name (P.ParsedSelection (a -> J.Value)) ->
|
|
a ->
|
|
J.Value
|
|
applyPrinter = flip (\x -> selectionSetToJSON . fmap (($ x) . P.handleTypename (const . nameAsJSON)))
|
|
|
|
nameAsJSON :: P.HasName a => a -> J.Value
|
|
nameAsJSON = J.String . G.unName . P.getName
|