graphql-engine/server/src-lib/Hasura/GraphQL/Schema/Mutation.hs
Samir Talwar 8db9b77c77 server: Reorganize quasi-quoted names.
Pretty much all quasi-quoted names in the server code base have ended up in `Hasura.GraphQL.Parser.Constants`. I'm now finding this unpleasant for two reasons:

1. I would like to factor out the parser code into its own Cabal package, and I don't want to have to expose all these names.
2. Most of them really have nothing to do with the parsers.

In order to remedy this, I have:

1. moved the names used by parser code to `Hasura.GraphQL.Parser.DirectiveName`, as they're all related to directives;
2. moved `Hasura.GraphQL.Parser.Constants` to `Hasura.Name`, changing the qualified import name from `G` to `Name`;
3. moved names only used in tests to the appropriate test case;
4. removed unused items from `Hasura.Name`; and
5. grouped related names.

Most of the changes are simply changing `G` to `Name`, which I find much more meaningful.

PR-URL: https://github.com/hasura/graphql-engine-mono/pull/4777
GitOrigin-RevId: a77aa0aee137b2b5e6faec94495d3a9fbfa1348b
2022-06-23 09:15:31 +00:00

471 lines
20 KiB
Haskell

{-# LANGUAGE ApplicativeDo #-}
{-# LANGUAGE TemplateHaskellQuotes #-}
module Hasura.GraphQL.Schema.Mutation
( insertIntoTable,
insertOneIntoTable,
deleteFromTable,
deleteFromTableByPk,
mkDefaultRelationshipParser,
mutationSelectionSet,
primaryKeysArguments,
)
where
import Data.HashMap.Strict qualified as Map
import Data.HashSet qualified as Set
import Data.Text.Extended
import Hasura.GraphQL.Parser
( FieldParser,
InputFieldsParser,
Kind (..),
Parser,
)
import Hasura.GraphQL.Parser qualified as P
import Hasura.GraphQL.Parser.Class
import Hasura.GraphQL.Schema.Backend
import Hasura.GraphQL.Schema.BoolExp
import Hasura.GraphQL.Schema.Common
import Hasura.GraphQL.Schema.Select
import Hasura.GraphQL.Schema.Table
import Hasura.Name qualified as Name
import Hasura.Prelude
import Hasura.RQL.IR.BoolExp
import Hasura.RQL.IR.Delete qualified as IR
import Hasura.RQL.IR.Insert qualified as IR
import Hasura.RQL.IR.Returning qualified as IR
import Hasura.RQL.IR.Root qualified as IR
import Hasura.RQL.IR.Value qualified as IR
import Hasura.RQL.Types.Backend
import Hasura.RQL.Types.Column
import Hasura.RQL.Types.Common
import Hasura.RQL.Types.Relationships.Local
import Hasura.RQL.Types.SchemaCache hiding (askTableInfo)
import Hasura.RQL.Types.Source
import Hasura.RQL.Types.Table
import Language.GraphQL.Draft.Syntax qualified as G
-- insert
-- | Construct the parser for a field that can be used to add several rows to a DB table.
--
-- This function is used to create the insert_tablename root field.
-- The field accepts the following arguments:
-- - objects: the list of objects to insert into the table (see 'tableFieldsInput')
-- - parser for backend-specific fields, e.g. upsert fields on_conflict or if_matched
insertIntoTable ::
forall b r m n.
MonadBuildSchema b r m n =>
(SourceInfo b -> TableInfo b -> m (InputFieldsParser n (BackendInsert b (IR.UnpreparedValue b)))) ->
Scenario ->
SourceInfo b ->
-- | qualified name of the table
TableInfo b ->
-- | field display name
G.Name ->
-- | field description, if any
Maybe G.Description ->
m (Maybe (FieldParser n (IR.AnnotatedInsert b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b))))
insertIntoTable backendInsertAction scenario sourceInfo tableInfo fieldName description = runMaybeT $ do
let viewInfo = _tciViewInfo $ _tiCoreInfo tableInfo
guard $ isMutable viIsInsertable viewInfo
insertPerms <- MaybeT $ _permIns <$> tablePermissions tableInfo
-- If we're in a frontend scenario, we should not include backend_only inserts
-- For more info see Note [Backend only permissions]
guard $ not $ scenario == Frontend && ipiBackendOnly insertPerms
lift do
updatePerms <- _permUpd <$> tablePermissions tableInfo
-- objects [{ ... }]
objectParser <- tableFieldsInput sourceInfo tableInfo
backendInsertParser <- backendInsertAction sourceInfo tableInfo
-- returning clause, affected rows, etc.
selectionParser <- mutationSelectionSet sourceInfo tableInfo
let argsParser = do
backendInsert <- backendInsertParser
objects <- mkObjectsArg objectParser
pure $ mkInsertObject objects tableInfo backendInsert insertPerms updatePerms
pure $
P.subselection fieldName description argsParser selectionParser
<&> \(insertObject, output) -> IR.AnnotatedInsert (G.unName fieldName) False insertObject (IR.MOutMultirowFields output)
where
mkObjectsArg objectParser =
P.field
Name._objects
(Just "the rows to be inserted")
(P.list objectParser)
-- | Variant of 'insertIntoTable' that inserts a single row.
--
-- Instead of expecting a list of rows to insert in a 'objects' argument, this
-- field instead expects a single 'object'. Its selection set is also slightly
-- different: it only allows selecting columns from the row being inserted.
insertOneIntoTable ::
forall b r m n.
(MonadBuildSchema b r m n) =>
(SourceInfo b -> TableInfo b -> m (InputFieldsParser n (BackendInsert b (IR.UnpreparedValue b)))) ->
Scenario ->
-- | source of the table
SourceInfo b ->
-- | table info
TableInfo b ->
-- | field display name
G.Name ->
-- | field description, if any
Maybe G.Description ->
m (Maybe (FieldParser n (IR.AnnotatedInsert b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b))))
insertOneIntoTable backendInsertAction scenario sourceInfo tableInfo fieldName description = runMaybeT do
let viewInfo = _tciViewInfo $ _tiCoreInfo tableInfo
guard $ isMutable viIsInsertable viewInfo
insertPerms <- MaybeT $ _permIns <$> tablePermissions tableInfo
-- If we're in a frontend scenario, we should not include backend_only inserts
-- For more info see Note [Backend only permissions]
guard $ not $ scenario == Frontend && ipiBackendOnly insertPerms
selectionParser <- MaybeT $ tableSelectionSet sourceInfo tableInfo
lift do
updatePerms <- _permUpd <$> tablePermissions tableInfo
objectParser <- tableFieldsInput sourceInfo tableInfo
backendInsertParser <- backendInsertAction sourceInfo tableInfo
let argsParser = do
backendInsert <- backendInsertParser
object <- mkObjectArg objectParser
pure $ mkInsertObject [object] tableInfo backendInsert insertPerms updatePerms
pure $
P.subselection fieldName description argsParser selectionParser
<&> \(insertObject, output) -> IR.AnnotatedInsert (G.unName fieldName) True insertObject (IR.MOutSinglerowObject output)
where
mkObjectArg objectParser =
P.field
Name._object
(Just "the row to be inserted")
objectParser
-- | Creates the parser for an input object for a row of the given table.
--
-- This function creates an input object type named "tablename_insert_input" in
-- the GraphQL shema, which has a field for each of the columns of that table
-- that the user has insert permissions for.
--
-- > {
-- > insert_author (
-- > objects: [
-- > { # tableFieldsInput output
-- > name: "John",
-- > id:12
-- > }
-- > ] ...
-- > ) ...
-- > }
tableFieldsInput ::
forall b r m n.
MonadBuildSchema b r m n =>
SourceInfo b ->
-- | qualified name of the table
TableInfo b ->
m (Parser 'Input n (IR.AnnotatedInsertRow b (IR.UnpreparedValue b)))
tableFieldsInput sourceInfo tableInfo =
memoizeOn 'tableFieldsInput (_siName sourceInfo, tableName) do
tableGQLName <- getTableGQLName tableInfo
objectFields <- traverse mkFieldParser (Map.elems allFields)
objectName <- P.mkTypename $ tableGQLName <> Name.__insert_input
let objectDesc = G.Description $ "input type for inserting data into table " <>> tableName
pure $ P.object objectName (Just objectDesc) $ coalesceFields objectFields
where
allFields = _tciFieldInfoMap . _tiCoreInfo $ tableInfo
tableName = tableInfoName tableInfo
-- For each field, we have a Maybe parser: not all fields will be allowed
-- (we don't allow insertions in computed fields for instance). Each parser
-- returns a maybe value, as some of the fields may be omitted. This
-- function does the necessary transformations to coalesce all of this in
-- one 'InputFieldsParser'.
coalesceFields ::
[Maybe (InputFieldsParser n (Maybe (IR.AnnotatedInsertField b (IR.UnpreparedValue b))))] ->
InputFieldsParser n (IR.AnnotatedInsertRow b (IR.UnpreparedValue b))
coalesceFields = fmap catMaybes . sequenceA . catMaybes
mkFieldParser ::
FieldInfo b ->
m (Maybe (InputFieldsParser n (Maybe (IR.AnnotatedInsertField b (IR.UnpreparedValue b)))))
mkFieldParser = \case
FIComputedField _ -> pure Nothing
FIRemoteRelationship _ -> pure Nothing
FIColumn columnInfo -> do
if (_cmIsInsertable $ ciMutability columnInfo)
then mkColumnParser columnInfo
else pure Nothing
FIRelationship relInfo -> mkRelationshipParser sourceInfo relInfo
mkColumnParser ::
ColumnInfo b ->
m (Maybe (InputFieldsParser n (Maybe (IR.AnnotatedInsertField b (IR.UnpreparedValue b)))))
mkColumnParser columnInfo = runMaybeT $ do
insertPerms <- MaybeT $ _permIns <$> tablePermissions tableInfo
let columnName = ciName columnInfo
columnDesc = ciDescription columnInfo
isAllowed = Set.member (ciColumn columnInfo) (ipiCols insertPerms)
guard isAllowed
fieldParser <- lift $ columnParser (ciType columnInfo) (G.Nullability $ ciIsNullable columnInfo)
pure $
P.fieldOptional columnName columnDesc fieldParser `mapField` \value ->
IR.AIColumn (ciColumn columnInfo, IR.mkParameter value)
mkDefaultRelationshipParser ::
forall b r m n.
MonadBuildSchema b r m n =>
(SourceInfo b -> TableInfo b -> m (InputFieldsParser n (BackendInsert b (IR.UnpreparedValue b)))) ->
XNestedInserts b ->
SourceInfo b ->
RelInfo b ->
m (Maybe (InputFieldsParser n (Maybe (IR.AnnotatedInsertField b (IR.UnpreparedValue b)))))
mkDefaultRelationshipParser backendInsertAction xNestedInserts sourceInfo relationshipInfo = runMaybeT do
let otherTableName = riRTable relationshipInfo
relName = riName relationshipInfo
otherTableInfo <- askTableInfo sourceInfo otherTableName
relFieldName <- lift $ textToName $ relNameToTxt relName
case riType relationshipInfo of
ObjRel -> do
parser <- MaybeT $ objectRelationshipInput backendInsertAction sourceInfo otherTableInfo
pure $
P.fieldOptional relFieldName Nothing (P.nullable parser) <&> \objRelIns -> do
rel <- join objRelIns
Just $ IR.AIObjectRelationship xNestedInserts $ IR.RelationInsert rel relationshipInfo
ArrRel -> do
parser <- MaybeT $ arrayRelationshipInput backendInsertAction sourceInfo otherTableInfo
pure $
P.fieldOptional relFieldName Nothing (P.nullable parser) <&> \arrRelIns -> do
rel <- join arrRelIns
guard $ not $ null $ IR._aiInsertObject rel
Just $ IR.AIArrayRelationship xNestedInserts $ IR.RelationInsert rel relationshipInfo
-- | Construct the parser for an input object that represents an insert through
-- an object relationship.
--
-- When inserting objects into tables, we allow insertions through
-- relationships. This function creates the parser for an object that represents
-- the insertion object across an object relationship; it is co-recursive with
-- 'tableFieldsInput'.
objectRelationshipInput ::
forall b r m n.
MonadBuildSchema b r m n =>
(SourceInfo b -> TableInfo b -> m (InputFieldsParser n (BackendInsert b (IR.UnpreparedValue b)))) ->
SourceInfo b ->
TableInfo b ->
m (Maybe (Parser 'Input n (IR.SingleObjectInsert b (IR.UnpreparedValue b))))
objectRelationshipInput backendInsertAction sourceInfo tableInfo = runMaybeT $ do
insertPerms <- MaybeT $ _permIns <$> tablePermissions tableInfo
lift $ memoizeOn 'objectRelationshipInput (_siName sourceInfo, tableName) do
updatePerms <- _permUpd <$> tablePermissions tableInfo
_selectPerms <- _permSel <$> tablePermissions tableInfo
tableGQLName <- getTableGQLName tableInfo
objectParser <- tableFieldsInput sourceInfo tableInfo
backendInsertParser <- backendInsertAction sourceInfo tableInfo
inputName <- P.mkTypename $ tableGQLName <> Name.__obj_rel_insert_input
let objectName = Name._data
inputDesc = G.Description $ "input type for inserting object relation for remote table " <>> tableName
inputParser = do
backendInsert <- backendInsertParser
object <- P.field objectName Nothing objectParser
pure $ mkInsertObject (IR.Single object) tableInfo backendInsert insertPerms updatePerms
pure $ P.object inputName (Just inputDesc) inputParser
where
tableName = tableInfoName tableInfo
-- | Construct the parser for an input object that represents an insert through
-- an array relationship.
--
-- When inserting objects into tables, we allow insertions through
-- relationships. This function creates the parser for an object that represents
-- the insertion object across an array relationship; it is co-recursive with
-- 'tableFieldsInput'.
arrayRelationshipInput ::
forall b r m n.
MonadBuildSchema b r m n =>
(SourceInfo b -> TableInfo b -> m (InputFieldsParser n (BackendInsert b (IR.UnpreparedValue b)))) ->
SourceInfo b ->
TableInfo b ->
m (Maybe (Parser 'Input n (IR.MultiObjectInsert b (IR.UnpreparedValue b))))
arrayRelationshipInput backendInsertAction sourceInfo tableInfo = runMaybeT $ do
insertPerms <- MaybeT $ _permIns <$> tablePermissions tableInfo
lift $ memoizeOn 'arrayRelationshipInput (_siName sourceInfo, tableName) do
updatePerms <- _permUpd <$> tablePermissions tableInfo
_selectPerms <- _permSel <$> tablePermissions tableInfo
tableGQLName <- getTableGQLName tableInfo
objectParser <- tableFieldsInput sourceInfo tableInfo
backendInsertParser <- backendInsertAction sourceInfo tableInfo
inputName <- P.mkTypename $ tableGQLName <> Name.__arr_rel_insert_input
let objectsName = Name._data
inputDesc = G.Description $ "input type for inserting array relation for remote table " <>> tableName
inputParser = do
backendInsert <- backendInsertParser
objects <- P.field objectsName Nothing $ P.list objectParser
pure $ mkInsertObject objects tableInfo backendInsert insertPerms updatePerms
pure $ P.object inputName (Just inputDesc) inputParser
where
tableName = tableInfoName tableInfo
-- | Helper function that creates an 'AnnIns' object.
mkInsertObject ::
forall b f.
BackendSchema b =>
f (IR.AnnotatedInsertRow b (IR.UnpreparedValue b)) ->
TableInfo b ->
BackendInsert b (IR.UnpreparedValue b) ->
InsPermInfo b ->
Maybe (UpdPermInfo b) ->
IR.AnnotatedInsertData b f (IR.UnpreparedValue b)
mkInsertObject objects tableInfo backendInsert insertPerms updatePerms =
IR.AnnotatedInsertData
{ _aiInsertObject = objects,
_aiTableName = table,
_aiCheckCondition = (insertCheck, updateCheck),
_aiTableColumns = columns,
_aiPresetValues = presetValues,
_aiBackendInsert = backendInsert
}
where
table = tableInfoName tableInfo
columns = tableColumns tableInfo
insertCheck = fmap partialSQLExpToUnpreparedValue <$> ipiCheck insertPerms
updateCheck = (fmap . fmap . fmap) partialSQLExpToUnpreparedValue $ upiCheck =<< updatePerms
presetValues = partialSQLExpToUnpreparedValue <$> ipiSet insertPerms
-- delete
-- | Construct a root field, normally called delete_tablename, that can be used
-- to delete several rows from a DB table
deleteFromTable ::
forall b r m n.
MonadBuildSchema b r m n =>
Scenario ->
-- | table source
SourceInfo b ->
-- | table info
TableInfo b ->
-- | field display name
G.Name ->
-- | field description, if any
Maybe G.Description ->
m (Maybe (FieldParser n (IR.AnnDelG b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b))))
deleteFromTable scenario sourceInfo tableInfo fieldName description = runMaybeT $ do
let viewInfo = _tciViewInfo $ _tiCoreInfo tableInfo
guard $ isMutable viIsInsertable viewInfo
deletePerms <- MaybeT $ _permDel <$> tablePermissions tableInfo
-- If we're in a frontend scenario, we should not include backend_only deletes
-- For more info see Note [Backend only permissions]
guard $ not $ scenario == Frontend && dpiBackendOnly deletePerms
lift do
let whereName = Name._where
whereDesc = "filter the rows which have to be deleted"
whereArg <- P.field whereName (Just whereDesc) <$> boolExp sourceInfo tableInfo
selection <- mutationSelectionSet sourceInfo tableInfo
let columns = tableColumns tableInfo
pure $
P.subselection fieldName description whereArg selection
<&> mkDeleteObject (tableInfoName tableInfo) columns deletePerms . fmap IR.MOutMultirowFields
-- | Construct a root field, normally called delete_tablename_by_pk, that can be used to delete an
-- individual rows from a DB table, specified by primary key. Select permissions are required, as
-- the user must be allowed to access all the primary keys of the table.
deleteFromTableByPk ::
forall b r m n.
MonadBuildSchema b r m n =>
Scenario ->
-- | table source
SourceInfo b ->
-- | table info
TableInfo b ->
-- | field display name
G.Name ->
-- | field description, if any
Maybe G.Description ->
m (Maybe (FieldParser n (IR.AnnDelG b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b))))
deleteFromTableByPk scenario sourceInfo tableInfo fieldName description = runMaybeT $ do
let viewInfo = _tciViewInfo $ _tiCoreInfo tableInfo
guard $ isMutable viIsInsertable viewInfo
pkArgs <- MaybeT $ primaryKeysArguments tableInfo
deletePerms <- MaybeT $ _permDel <$> tablePermissions tableInfo
-- If we're in a frontend scenario, we should not include backend_only deletes
-- For more info see Note [Backend only permissions]
guard $ not $ scenario == Frontend && dpiBackendOnly deletePerms
selection <- MaybeT $ tableSelectionSet sourceInfo tableInfo
let columns = tableColumns tableInfo
pure $
P.subselection fieldName description pkArgs selection
<&> mkDeleteObject (tableInfoName tableInfo) columns deletePerms . fmap IR.MOutSinglerowObject
mkDeleteObject ::
Backend b =>
TableName b ->
[ColumnInfo b] ->
DelPermInfo b ->
(AnnBoolExp b (IR.UnpreparedValue b), IR.MutationOutputG b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b)) ->
IR.AnnDelG b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b)
mkDeleteObject table columns deletePerms (whereExp, mutationOutput) =
IR.AnnDel
{ IR._adTable = table,
IR._adWhere = (permissionFilter, whereExp),
IR._adOutput = mutationOutput,
IR._adAllCols = columns
}
where
permissionFilter = fmap partialSQLExpToUnpreparedValue <$> dpiFilter deletePerms
-- common
-- | All mutations allow returning results, such as what the updated database
-- rows look like. This parser allows a query to specify what data to fetch.
mutationSelectionSet ::
forall b r m n.
MonadBuildSchema b r m n =>
SourceInfo b ->
TableInfo b ->
m (Parser 'Output n (IR.MutFldsG b (IR.RemoteRelationshipField IR.UnpreparedValue) (IR.UnpreparedValue b)))
mutationSelectionSet sourceInfo tableInfo =
memoizeOn 'mutationSelectionSet (_siName sourceInfo, tableName) do
tableGQLName <- getTableGQLName tableInfo
returning <- runMaybeT do
_permissions <- MaybeT $ tableSelectPermissions tableInfo
tableSet <- MaybeT $ tableSelectionList sourceInfo tableInfo
let returningName = Name._returning
returningDesc = "data from the rows affected by the mutation"
pure $ IR.MRet <$> P.subselection_ returningName (Just returningDesc) tableSet
selectionName <- P.mkTypename $ tableGQLName <> Name.__mutation_response
let affectedRowsName = Name._affected_rows
affectedRowsDesc = "number of rows affected by the mutation"
selectionDesc = G.Description $ "response of any mutation on the table " <>> tableName
selectionFields =
catMaybes
[ Just $
IR.MCount
<$ P.selection_ affectedRowsName (Just affectedRowsDesc) P.int,
returning
]
pure $
P.selectionSet selectionName (Just selectionDesc) selectionFields
<&> parsedSelectionsToFields IR.MExp
where
tableName = tableInfoName tableInfo
-- | How to specify a database row by primary key.
--
-- This will give @Nothing@ when either there are no primary keys defined for
-- the table or when the given permissions do not permit selecting from all the
-- columns that make up the key.
primaryKeysArguments ::
forall b r m n.
MonadBuildSchema b r m n =>
TableInfo b ->
m (Maybe (InputFieldsParser n (AnnBoolExp b (IR.UnpreparedValue b))))
primaryKeysArguments tableInfo = runMaybeT $ do
selectPerms <- MaybeT $ tableSelectPermissions tableInfo
primaryKeys <- hoistMaybe $ _tciPrimaryKey . _tiCoreInfo $ tableInfo
let columns = _pkColumns primaryKeys
guard $ all (\c -> ciColumn c `Map.member` spiCols selectPerms) columns
lift $
fmap (BoolAnd . toList) . sequenceA <$> for columns \columnInfo -> do
field <- columnParser (ciType columnInfo) (G.Nullability False)
pure $
BoolFld . AVColumn columnInfo . pure . AEQ True . IR.mkParameter
<$> P.field (ciName columnInfo) (ciDescription columnInfo) field