graphql-engine/server/src-lib/Hasura/Backends/MSSQL/Plan.hs

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-- | Planning T-SQL queries and subscriptions.
module Hasura.Backends.MSSQL.Plan where
-- TODO: Re-add the export list after cleaning up the module
-- ( planQuery
-- , planSubscription
-- ) where
import Hasura.Prelude hiding (first)
import qualified Data.Aeson as J
import Data.ByteString.Lazy (toStrict)
import qualified Data.HashMap.Strict as HM
import qualified Data.HashMap.Strict.InsOrd as OMap
import qualified Data.HashSet as Set
import qualified Data.Text as T
import qualified Database.ODBC.SQLServer as ODBC
import qualified Language.GraphQL.Draft.Syntax as G
import Control.Monad.Validate
import Data.Text.Extended
import qualified Hasura.GraphQL.Parser as GraphQL
import qualified Hasura.RQL.Types.Column as RQL
import Hasura.Backends.MSSQL.FromIr
import Hasura.Backends.MSSQL.Types
import Hasura.Base.Error
server: support remote relationships on SQL Server and BigQuery (#1497) Remote relationships are now supported on SQL Server and BigQuery. The major change though is the re-architecture of remote join execution logic. Prior to this PR, each backend is responsible for processing the remote relationships that are part of their AST. This is not ideal as there is nothing specific about a remote join's execution that ties it to a backend. The only backend specific part is whether or not the specification of the remote relationship is valid (i.e, we'll need to validate whether the scalars are compatible). The approach now changes to this: 1. Before delegating the AST to the backend, we traverse the AST, collect all the remote joins while modifying the AST to add necessary join fields where needed. 1. Once the remote joins are collected from the AST, the database call is made to fetch the response. The necessary data for the remote join(s) is collected from the database's response and one or more remote schema calls are constructed as necessary. 1. The remote schema calls are then executed and the data from the database and from the remote schemas is joined to produce the final response. ### Known issues 1. Ideally the traversal of the IR to collect remote joins should return an AST which does not include remote join fields. This operation can be type safe but isn't taken up as part of the PR. 1. There is a lot of code duplication between `Transport/HTTP.hs` and `Transport/Websocket.hs` which needs to be fixed ASAP. This too hasn't been taken up by this PR. 1. The type which represents the execution plan is only modified to handle our current remote joins and as such it will have to be changed to accommodate general remote joins. 1. Use of lenses would have reduced the boilerplate code to collect remote joins from the base AST. 1. The current remote join logic assumes that the join columns of a remote relationship appear with their names in the database response. This however is incorrect as they could be aliased. This can be taken up by anyone, I've left a comment in the code. ### Notes to the reviewers I think it is best reviewed commit by commit. 1. The first one is very straight forward. 1. The second one refactors the remote join execution logic but other than moving things around, it doesn't change the user facing functionality. This moves Postgres specific parts to `Backends/Postgres` module from `Execute`. Some IR related code to `Hasura.RQL.IR` module. Simplifies various type class function signatures as a backend doesn't have to handle remote joins anymore 1. The third one fixes partial case matches that for some weird reason weren't shown as warnings before this refactor 1. The fourth one generalizes the validation logic of remote relationships and implements `scalarTypeGraphQLName` function on SQL Server and BigQuery which is used by the validation logic. This enables remote relationships on BigQuery and SQL Server. https://github.com/hasura/graphql-engine-mono/pull/1497 GitOrigin-RevId: 77dd8eed326602b16e9a8496f52f46d22b795598
2021-06-11 06:26:50 +03:00
import Hasura.RQL.IR
import Hasura.SQL.Backend
import Hasura.Session
--------------------------------------------------------------------------------
-- Top-level planner
planQuery
:: MonadError QErr m
=> SessionVariables
-> QueryDB 'MSSQL (Const Void) (GraphQL.UnpreparedValue 'MSSQL)
-> m Select
planQuery sessionVariables queryDB = do
rootField <- traverse (prepareValueQuery sessionVariables) queryDB
sel <-
runValidate (runFromIr (fromRootField rootField))
`onLeft` (throw400 NotSupported . tshow)
pure $
sel
{ selectFor =
case selectFor sel of
NoFor -> NoFor
JsonFor forJson ->
JsonFor forJson {jsonRoot =
case jsonRoot forJson of
NoRoot -> Root "root"
-- Keep whatever's there if already
-- specified. In the case of an
-- aggregate query, the root will
-- be specified "aggregate", for
-- example.
keep -> keep
}
}
-- | Prepare a value without any query planning; we just execute the
-- query with the values embedded.
prepareValueQuery
:: MonadError QErr m
=> SessionVariables
-> GraphQL.UnpreparedValue 'MSSQL
-> m Expression
prepareValueQuery sessionVariables =
{- History note:
This function used to be called 'planNoPlan', and was used for building sql
expressions for queries. That evolved differently, but this function is now
left as a *suggestion* for implementing support for mutations.
-}
\case
GraphQL.UVLiteral x -> pure x
GraphQL.UVSession -> pure $ ValueExpression $ ODBC.ByteStringValue $ toStrict $ J.encode sessionVariables
GraphQL.UVParameter _ RQL.ColumnValue{..} -> pure $ ValueExpression cvValue
GraphQL.UVSessionVar _typ sessionVariable -> do
value <- getSessionVariableValue sessionVariable sessionVariables
`onNothing` throw400 NotFound ("missing session variable: " <>> sessionVariable)
pure $ ValueExpression $ ODBC.TextValue value
planSubscription
:: MonadError QErr m
=> OMap.InsOrdHashMap G.Name (QueryDB 'MSSQL (Const Void) (GraphQL.UnpreparedValue 'MSSQL))
-> SessionVariables
-> m (Reselect, PrepareState)
planSubscription unpreparedMap sessionVariables = do
let (rootFieldMap, prepareState) =
runState
(traverse
(traverse (prepareValueSubscription (getSessionVariablesSet sessionVariables)))
unpreparedMap)
emptyPrepareState
selectMap <-
runValidate (runFromIr (traverse fromRootField rootFieldMap))
`onLeft` (throw400 NotSupported . tshow)
pure (collapseMap selectMap, prepareState)
-- Plan a query without prepare/exec.
-- planNoPlanMap ::
-- OMap.InsOrdHashMap G.Name (SubscriptionRootFieldMSSQL (GraphQL.UnpreparedValue 'MSSQL))
-- -> Either PrepareError Reselect
-- planNoPlanMap _unpreparedMap =
-- let rootFieldMap = runIdentity $
-- traverse (traverseQueryRootField (pure . prepareValueNoPlan)) unpreparedMap
-- selectMap <-
-- first
-- FromIrError
-- (runValidate (runFromIr (traverse fromRootField rootFieldMap)))
-- pure (collapseMap selectMap)
--------------------------------------------------------------------------------
-- Converting a root field into a T-SQL select statement
-- | Collapse a set of selects into a single select that projects
-- these as subselects.
collapseMap :: OMap.InsOrdHashMap G.Name Select
-> Reselect
collapseMap selects =
Reselect
{ reselectFor =
JsonFor ForJson {jsonCardinality = JsonSingleton, jsonRoot = NoRoot}
, reselectWhere = Where mempty
, reselectProjections =
map projectSelect (OMap.toList selects)
}
where
projectSelect :: (G.Name, Select) -> Projection
projectSelect (name, sel) =
ExpressionProjection
(Aliased
{ aliasedThing = SelectExpression sel
, aliasedAlias = G.unName name
})
--------------------------------------------------------------------------------
-- Session variables
globalSessionExpression :: Expression
globalSessionExpression =
ValueExpression (ODBC.TextValue "current_setting('hasura.user')::json")
--------------------------------------------------------------------------------
-- Resolving values
data PrepareError
= FromIrError (NonEmpty Error)
data PrepareState = PrepareState
{ positionalArguments :: ![RQL.ColumnValue 'MSSQL]
, namedArguments :: !(HashMap G.Name (RQL.ColumnValue 'MSSQL))
, sessionVariables :: !(Set.HashSet SessionVariable)
}
emptyPrepareState :: PrepareState
emptyPrepareState = PrepareState
{ positionalArguments = mempty
, namedArguments = mempty
, sessionVariables = mempty
}
-- | Prepare a value for multiplexed queries.
prepareValueSubscription
:: Set.HashSet SessionVariable
-> GraphQL.UnpreparedValue 'MSSQL
-> State PrepareState Expression
prepareValueSubscription globalVariables =
\case
GraphQL.UVLiteral x -> pure x
GraphQL.UVSession -> do
modify' (\s -> s {sessionVariables = sessionVariables s <> globalVariables})
pure $ resultVarExp (RootPath `FieldPath` "session")
GraphQL.UVSessionVar _typ text -> do
modify' (\s -> s {sessionVariables = text `Set.insert` sessionVariables s})
pure $ resultVarExp (sessionDot $ toTxt text)
GraphQL.UVParameter mVariableInfo columnValue ->
case fmap GraphQL.getName mVariableInfo of
Nothing -> do
currentIndex <- (toInteger . length) <$> gets positionalArguments
modify' (\s -> s {
positionalArguments = positionalArguments s <> [columnValue] })
pure (resultVarExp (syntheticIx currentIndex))
Just name -> do
modify
(\s ->
s
{ namedArguments =
HM.insert name columnValue (namedArguments s)
})
pure $ resultVarExp (queryDot $ G.unName name)
where
resultVarExp :: JsonPath -> Expression
resultVarExp =
JsonValueExpression $
ColumnExpression $
FieldName
{ fieldNameEntity = rowAlias
, fieldName = resultVarsAlias
}
queryDot :: Text -> JsonPath
queryDot name = RootPath `FieldPath` "query" `FieldPath` name
syntheticIx :: Integer -> JsonPath
syntheticIx i = (RootPath `FieldPath` "synthetic" `IndexPath` i)
sessionDot :: Text -> JsonPath
sessionDot name = RootPath `FieldPath` "session" `FieldPath` name
resultIdAlias :: T.Text
resultIdAlias = "result_id"
resultVarsAlias :: T.Text
resultVarsAlias = "result_vars"
resultAlias :: T.Text
resultAlias = "result"
rowAlias :: T.Text
rowAlias = "row"