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187bf385fc
PR-URL: https://github.com/hasura/graphql-engine-mono/pull/5094 GitOrigin-RevId: 3342e571d3574a4d94fe3bfedb60f332b8c10853
254 lines
9.5 KiB
Haskell
254 lines
9.5 KiB
Haskell
-- | A collection of types and utilities around the @Node@ GraphQL
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-- type exposed by the Relay API.
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module Hasura.GraphQL.Schema.Node
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( -- * Node id
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NodeId (..),
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V1NodeId (..),
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V2NodeId (..),
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-- * Node id version
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NodeIdVersion,
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nodeIdVersionInt,
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currentNodeIdVersion,
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-- * Internal relay types
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NodeMap,
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TableMap (..),
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NodeInfo (..),
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findNode,
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)
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where
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import Data.Aeson qualified as J
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import Data.Aeson.Types qualified as J
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import Data.HashMap.Strict qualified as Map
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import Data.Sequence qualified as Seq
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import Data.Sequence.NonEmpty qualified as NESeq
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import Hasura.Backends.Postgres.SQL.Types qualified as PG
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import Hasura.Prelude
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import Hasura.RQL.IR qualified as IR
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import Hasura.RQL.Types.Backend
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import Hasura.RQL.Types.Column
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import Hasura.RQL.Types.Common
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import Hasura.RQL.Types.Table
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import Hasura.SQL.AnyBackend qualified as AB
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{- Note [Relay Node Id]
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~~~~~~~~~~~~~~~~~~~~~~~
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Relay API
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---------
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The 'Node' interface in the Relay API schema has exactly one field, which
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returns a non-null 'ID' value. In a backend that supports the Relay API, each
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table's corresponding GraphQL object implements that interface, and provides an
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@id@ field that uniuqely identifies each row of the table. See
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https://relay.dev/graphql/objectidentification.htm for more details.
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To uniquely identify a given row in a given table, we use two different pieces
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of information:
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- something that uniquely identifies the table within the schema
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- something that uniquely identifies the row within the table
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Both V1 and V2 (of this particular API, not of the engine, see 'NodeIdVersion')
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use the same data to uniquely identify the row within the table: a list of
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values that map to the table's primary keys, in order. Where they differentiate
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is on how they identify the table within the schema:
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- V1 only used a Postgres table name;
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- V2 uses a source name, and a backend-agnostic table name
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For now, we still only emit and accept V1 ids: switching to emitting V2 node ids
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will be a breaking change that will we do soon. We will continue to accept V1
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node ids after that change, meaning we still to resolve them; in practice, that
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means iterating over all the Postgres sources, until we find one that has a
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table with the given name. If we find more than one, then we fail, to avoid
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having to pick a random one (and potentially silently return wrong results.)
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Id format
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---------
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All the required information is encoded into a unique node id using the
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following pipeline:
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values <-> JSON array <-> bytestring <-> base64 string
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In v1, the content of the JSON array was:
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[ 1 -- JSON number: version number
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, "public" -- JSON string: Postgres schema name
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, "foo" -- JSON string: Postgres table name
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, ... -- arbitrary JSON values: values for each primary key, in order
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]
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As of v2, the content of the JSON array is as follows:
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[ 2 -- JSON number: version number
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, "default" -- JSON string: source name
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, "postgres" -- JSON string: backend type
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, { "schema: "public" -- arbitrary JSON value: table name in that backend
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, "name": "foo"
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}
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, ... -- arbitrary JSON values: values for each primary key, in order
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]
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Encoding and decoding
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---------------------
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The encoding of a given row's id is performed in each backend's translation
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layer, as crafting the row's id requires extracting information out of the
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database (the primary key values). Selecting the 'id' field of a compatible
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table will yield an 'AFNodeId' field in the IR (see Hasura.RQL.IR.Select), that
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each compatible backend will then interpret appropriately.
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Decoding, however, does not require introspecting the database, and is performed
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at parsing time, so that we can select the corresponing table row. See
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'nodeField' in 'Relay.hs' for more information.
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-}
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--------------------------------------------------------------------------------
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-- Node id
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data NodeId
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= NodeIdV1 V1NodeId
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| NodeIdV2 (AB.AnyBackend V2NodeId)
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-- | V1 format of a node.
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--
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-- This id does NOT uniquely identify the table properly, as it only knows the
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-- table's name, but doesn't store a source name.
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data V1NodeId = V1NodeId
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{ _ni1Table :: PG.QualifiedTable,
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_ni1Columns :: NESeq.NESeq J.Value
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}
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-- | V2 format of a node.
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--
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-- Uniquely identifies a table with source name and table name, and uniquely
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-- identifies a row within that table with a list of primary key values.
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data V2NodeId b = V2NodeId
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{ _ni2Source :: SourceName,
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_ni2Table :: TableName b,
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_ni2Columns :: NESeq.NESeq J.Value
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}
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instance J.FromJSON NodeId where
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parseJSON = J.withArray "node id" \array -> case toList array of
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[] -> fail "unexpected GUID format, found empty list"
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J.Number 1 : rest -> NodeIdV1 <$> parseNodeIdV1 rest
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J.Number n : _ -> fail $ "unsupported GUID version: " <> show n
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_ -> fail "unexpected GUID format, needs to start with a version number"
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parseNodeIdV1 :: [J.Value] -> J.Parser V1NodeId
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parseNodeIdV1 (schemaValue : nameValue : firstColumn : remainingColumns) =
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V1NodeId
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<$> (PG.QualifiedObject <$> J.parseJSON schemaValue <*> J.parseJSON nameValue)
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<*> pure (firstColumn NESeq.:<|| Seq.fromList remainingColumns)
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parseNodeIdV1 _ = fail "GUID version 1: expecting schema name, table name and at least one column value"
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--------------------------------------------------------------------------------
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-- Node id version
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-- | Enum representing the supported versions of the API.
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data NodeIdVersion
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= NIVersion1
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| NIVersion2
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deriving (Show, Eq)
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nodeIdVersionInt :: NodeIdVersion -> Int
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nodeIdVersionInt = \case
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NIVersion1 -> 1
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NIVersion2 -> 2
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currentNodeIdVersion :: NodeIdVersion
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currentNodeIdVersion = NIVersion1
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--------------------------------------------------------------------------------
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-- Internal relay types
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{- Note [Internal Relay HashMap]
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Parsing the Node interface
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--------------------------
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When selecting a node in the schema, the user can use GraphQL fragments to
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select different rows based on what table the node id maps to. For instance, a
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Relay query could look like this (assuming that there are corresponding tables
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"album" and "track" in the schema, possibly in different sources):
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query {
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node(id: "base64idhere") {
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... on album {
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albumName
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}
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... on track {
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trackName
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}
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}
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}
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What that means is that the parser for the 'Node' interface needs to delegate to
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*every table parser*, to deal with all possible cases. In practice, we use the
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'selectionSetInterface' combinator (from Hasura.GraphQL.Parser.Internal.Parser):
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we give it a list of all the parsers, and it in turn applies all of them, and
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gives us the result for each possible table:
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- if the table was "album", the parsed result is: ...
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- if the table was "track", the parsed result is: ...
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The parser for the interface itself cannot know what the actual underlying table
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is: that's determined by the node id, which is not something inherent to the
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interface! Consequently, what the parser for the interface returns is a
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container, that to every supported table in the schema, associates the
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corresponding parser output; the node *field* can then use that map and the node
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id it got as an argument to extract the relevant information out of said
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container.
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The 'NodeMap' container
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-----------------------
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To avoid having to do extra lookups, we also store in that container additional
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information about the table: permissions for the current role, connection
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information... so that the field, by simply doing a lookup based on the node id,
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can have all the information it needs to craft a corresponding query.
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In practice: the value we store in our container is a 'NodeInfo' (see
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below). Our container, in turn, isn't a 'HashMap' from "unique table identifier"
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to 'NodeInfo'; the problem is that not all sources have the same backend type,
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meaning that the "unique table identifier" would need to be a _hetereogeneous_
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key type. This can be achieved with a dependent map (such as
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Data.Dependent.Map.DMap), but is extremely cumbersome. Instead, our overall
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container, 'NodeMap', is two layers of 'HashMap': to a source name, we associate
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a "backend-erased" 'TableMap' which, in turn, for the corresponding backend,
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associates to a table name the corresponding 'NodeInfo'.
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Module structure
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----------------
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Ideally, none of those types should be exported: they are used in the return
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type of 'nodeInteface', but consumed immediately by 'nodeField' (see both in
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Relay.hs), and they could therefore be purely internal... except for the fact
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that 'Common.hs' needs to know about the NodeMap, which is why it is defined
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here instead of being an implementation detail of 'Relay.hs'.
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-}
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type NodeMap = HashMap SourceName (AB.AnyBackend TableMap)
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-- | All the information required to craft a query to a row pointed to by a
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-- 'NodeId'.
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data NodeInfo b = NodeInfo
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{ nvSourceConfig :: SourceConfig b,
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nvSelectPermissions :: SelPermInfo b,
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nvPrimaryKeys :: PrimaryKeyColumns b,
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nvAnnotatedFields :: IR.AnnFieldsG b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b)
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}
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newtype TableMap b = TableMap (HashMap (TableName b) (NodeInfo b))
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-- | Given a source name and table name, peform the double lookup within a
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-- 'NodeMap'.
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findNode :: forall b. Backend b => SourceName -> TableName b -> NodeMap -> Maybe (NodeInfo b)
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findNode sourceName tableName nodeMap = do
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anyTableMap <- Map.lookup sourceName nodeMap
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TableMap tableMap <- AB.unpackAnyBackend @b anyTableMap
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Map.lookup tableName tableMap
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