graphql-engine/server/src-lib/Hasura/GraphQL/Schema/Relay.hs
Tom Harding af0b56332d De-duplicate prepared logical model arguments
PR-URL: https://github.com/hasura/graphql-engine-mono/pull/8723
GitOrigin-RevId: 5df1a05c47852d7371ef323bb0df2ac9d1749243
2023-04-12 09:05:48 +00:00

222 lines
10 KiB
Haskell

{-# LANGUAGE TemplateHaskellQuotes #-}
-- | This module only exposes one function, 'nodeField', which is used at the
-- root level of the schema to create the 'node' field in the Relay API schema.
module Hasura.GraphQL.Schema.Relay
( nodeInterface,
nodeField,
)
where
import Control.Lens hiding (index)
import Data.Aeson qualified as J
import Data.Aeson.Types qualified as J
import Data.Align (align)
import Data.HashMap.Strict.Extended qualified as Map
import Data.Sequence.NonEmpty qualified as NESeq
import Data.Text qualified as T
import Data.These (partitionThese)
import Hasura.Base.Error
import Hasura.Base.ErrorMessage
import Hasura.Base.ToErrorValue
import Hasura.GraphQL.Schema.Backend
import Hasura.GraphQL.Schema.Common
import Hasura.GraphQL.Schema.Instances ()
import Hasura.GraphQL.Schema.Node
import Hasura.GraphQL.Schema.Options qualified as Options
import Hasura.GraphQL.Schema.Parser (Kind (..), Parser, memoizeOn)
import Hasura.GraphQL.Schema.Parser qualified as P
import Hasura.GraphQL.Schema.Select
import Hasura.GraphQL.Schema.Table
import Hasura.Name qualified as Name
import Hasura.Prelude
import Hasura.RQL.IR qualified as IR
import Hasura.RQL.Types.Backend
import Hasura.RQL.Types.Column
import Hasura.RQL.Types.Common
import Hasura.RQL.Types.SchemaCache hiding (askTableInfo)
import Hasura.RQL.Types.Source
import Hasura.RQL.Types.SourceCustomization
import Hasura.RQL.Types.Table
import Hasura.SQL.AnyBackend qualified as AB
import Hasura.SQL.Backend
import Language.GraphQL.Draft.Syntax qualified as G
-- | Constructs the parser for the node interface.
--
-- As mentioned in Note [Internal Relay HashMap], this function must parse an
-- incoming query for ANY potential matching table. Its resulting parser returns
-- a 'NodeMap': a container that, to a source name and a table name, associates
-- both the parsed fields and all the relevant table information required to
-- craft a request.
nodeInterface :: SourceCache -> NodeInterfaceParserBuilder
nodeInterface sourceCache = NodeInterfaceParserBuilder $ \context options -> memoizeOn 'nodeInterface () do
let idDescription = G.Description "A globally unique identifier"
idField = P.selection_ Name._id (Just idDescription) P.identifier
nodeInterfaceDescription = G.Description "An object with globally unique ID"
roleName = scRole context
tables :: [Parser 'Output n (SourceName, AB.AnyBackend TableMap)] <-
catMaybes . concat <$> for (Map.toList sourceCache) \(sourceName, anySourceInfo) ->
AB.dispatchAnyBackendWithTwoConstraints @BackendSchema @BackendTableSelectSchema
anySourceInfo
\(sourceInfo :: SourceInfo b) ->
runSourceSchema context options sourceInfo do
for (Map.toList $ takeValidTables $ _siTables sourceInfo) \(tableName, tableInfo) -> runMaybeT do
tablePkeyColumns <- hoistMaybe $ tableInfo ^? tiCoreInfo . tciPrimaryKey . _Just . pkColumns
selectPermissions <- hoistMaybe $ tableSelectPermissions roleName tableInfo
annotatedFieldsParser <- MaybeT $ tableSelectionSet tableInfo
pure $
annotatedFieldsParser <&> \fields ->
( sourceName,
AB.mkAnyBackend $
TableMap $
Map.singleton tableName $
NodeInfo sourceInfo selectPermissions tablePkeyColumns fields
)
pure $
Map.fromListWith fuseAnyMaps
<$> P.selectionSetInterface
Name._Node
(Just nodeInterfaceDescription)
[idField]
tables
where
-- this can only ever fail if somehow, within the same source, we ran into
-- two tables of a different type b; in other words, it is impossible.
fuseAnyMaps :: AB.AnyBackend TableMap -> AB.AnyBackend TableMap -> AB.AnyBackend TableMap
fuseAnyMaps m1 m2 =
AB.composeAnyBackend @Backend fuseMaps m1 m2 $
error "panic: two tables of a different backend type within the same source"
fuseMaps :: forall b. Backend b => TableMap b -> TableMap b -> AB.AnyBackend TableMap
fuseMaps (TableMap m1) (TableMap m2) = AB.mkAnyBackend @b $ TableMap $ Map.union m1 m2
-- | Creates a field parser for the top-level "node" field in the QueryRoot.
--
-- It exepcts one argument, the node id. It looks for the targeted table in the
-- 'NodeMap' returned by 'nodeInterface', and, if successful, attempts to craft
-- a corresponding 'QueryRootField' that will extract the requested row.
nodeField ::
forall m n.
(MonadError QErr m, P.MonadMemoize m, P.MonadParse n) =>
SourceCache ->
SchemaContext ->
Options.SchemaOptions ->
m (P.FieldParser n (IR.QueryRootField IR.UnpreparedValue))
nodeField sourceCache context options = do
let idDescription = G.Description "A globally unique id"
idArgument = P.field Name._id (Just idDescription) P.identifier
stringifyNumbers = Options.soStringifyNumbers options
nodeObject <- case scSchemaKind context of
HasuraSchema -> throw500 "internal error: the node field should only be built for the Relay schema"
RelaySchema nodeBuilder -> runNodeBuilder nodeBuilder context options
pure $
P.subselection Name._node Nothing idArgument nodeObject `P.bindField` \(ident, parseds) -> do
nodeId <- parseNodeId ident
case nodeId of
NodeIdV1 (V1NodeId tableName pKeys) -> do
-- Node id V1.
--
-- We don't have the source name in a V1 node; we attempt all of them
-- and pick the first one we find; there is a risk we might pick the
-- wrong one if two tables with the same name exist in different
-- sources! It is, however, unlikely; the engine emits V2 IDs, meaning
-- if ever encounter a V1 ID it means it has been manually entered bya
-- user, saved from an older version of the engine?
let matchingTables = flip mapMaybe (Map.keys sourceCache) \sourceName ->
findNode @('Postgres 'Vanilla) sourceName tableName parseds
case matchingTables of
[nodeValue] -> createRootField stringifyNumbers tableName nodeValue pKeys
[] -> throwInvalidNodeId $ "no such table found: " <> toErrorValue tableName
l ->
throwInvalidNodeId $
"this V1 node id matches more than one table across different sources: "
<> toErrorValue tableName
<> " exists in sources "
<> toErrorValue (_siName . nvSourceInfo <$> l)
NodeIdV2 nodev2 ->
-- Node id V2.
--
-- We have the source name and table name, we can extract the relevant
-- info directly.
AB.dispatchAnyBackend @Backend nodev2 \(V2NodeId sourceName tableName pKeys :: V2NodeId b) -> do
nodeValue <-
findNode @b sourceName tableName parseds
`onNothing` throwInvalidNodeId ("no table " <> toErrorValue tableName <> " found in source " <> toErrorValue sourceName)
createRootField stringifyNumbers tableName nodeValue pKeys
where
throwInvalidNodeId :: ErrorMessage -> n a
throwInvalidNodeId t = P.withKey (J.Key "args") $ P.withKey (J.Key "id") $ P.parseError $ "invalid node id: " <> t
parseNodeId :: Text -> n NodeId
parseNodeId = either (throwInvalidNodeId . toErrorMessage . T.pack) pure . J.eitherDecode . base64Decode
-- Given all the node id information about a table, and the extracted
-- 'NodeInfo', craft the top-level query. This relies on the assumption
-- that all backends that support relay use the same IR for single row
-- selection.
createRootField ::
Backend b =>
Options.StringifyNumbers ->
TableName b ->
NodeInfo b ->
NESeq.NESeq J.Value ->
n (IR.QueryRootField IR.UnpreparedValue)
createRootField stringifyNumbers tableName (NodeInfo sourceInfo perms pKeys fields) columnValues = do
whereExp <- buildNodeIdBoolExp columnValues pKeys
pure $
IR.RFDB (_siName sourceInfo) $
AB.mkAnyBackend $
IR.SourceConfigWith (_siConfiguration sourceInfo) Nothing $
IR.QDBR $
IR.QDBSingleRow $
IR.AnnSelectG
{ IR._asnFields = fields,
IR._asnFrom = IR.FromTable tableName,
IR._asnPerm = tablePermissionsInfo perms,
IR._asnArgs =
IR.SelectArgs
{ IR._saWhere = Just whereExp,
IR._saOrderBy = Nothing,
IR._saLimit = Nothing,
IR._saOffset = Nothing,
IR._saDistinct = Nothing
},
IR._asnStrfyNum = stringifyNumbers,
IR._asnNamingConvention = Just $ _rscNamingConvention $ _siCustomization sourceInfo
}
-- Craft the 'where' condition of the query by making an `AEQ` entry for
-- each primary key. This might fail if the given node id doesn't exactly
-- have a valid entry for each primary key.
buildNodeIdBoolExp ::
Backend b =>
NESeq.NESeq J.Value ->
NESeq.NESeq (ColumnInfo b) ->
n (IR.AnnBoolExp b (IR.UnpreparedValue b))
buildNodeIdBoolExp columnValues pkeyColumns = do
let firstPkColumn NESeq.:<|| remainingPkColumns = pkeyColumns
firstColumnValue NESeq.:<|| remainingColumns = columnValues
(nonAlignedPkColumns, nonAlignedColumnValues, alignedTuples) =
partitionThese $ toList $ align remainingPkColumns remainingColumns
unless (null nonAlignedPkColumns) $
throwInvalidNodeId $
"primary key columns " <> toErrorValue (map ciColumn nonAlignedPkColumns) <> " are missing"
unless (null nonAlignedColumnValues) $
throwInvalidNodeId $
"unexpected column values " <> toErrorValue nonAlignedColumnValues
let allTuples = (firstPkColumn, firstColumnValue) : alignedTuples
IR.BoolAnd <$> for allTuples \(columnInfo, columnValue) -> do
let columnType = ciType columnInfo
parsedValue <-
parseScalarValueColumnType columnType columnValue `onLeft` \e ->
P.parseErrorWith P.ParseFailed $ "value of column " <> toErrorValue (ciColumn columnInfo) <> " in node id: " <> toErrorMessage (qeError e)
pure $
IR.BoolField $
IR.AVColumn
columnInfo
[IR.AEQ True $ IR.UVParameter IR.Unknown $ ColumnValue columnType parsedValue]