graphql-engine/server/src-lib/Hasura/RQL/IR/Select.hs

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{-# LANGUAGE DeriveAnyClass #-}
{-# LANGUAGE DuplicateRecordFields #-}
{-# LANGUAGE TemplateHaskell #-}
{-# LANGUAGE UndecidableInstances #-}
-- | This modules defines the tree of Select types: how we represent a query internally, from its top
-- level 'QueryDB' down to each individual field. Most of those types have three type arguments:
--
-- b: BackendType
-- The backend that is targeted by that specific select (Postgres Vanilla, MSSQL...); we use the
-- type families in the Backend class to decide how different parts of the IR are represented in
-- different backends.
--
-- v: Type
-- The type of the leaf values in our AST; used almost exclusively for column values, over which
-- queries can be parameterized. The output of the parser phase will use @UnpreparedValue b@ for
-- the leaves, and most backends will then transform the AST to interpret those values and
-- consequently change @v@ to be @SQLExpression b@
--
-- r: BackendType -> Type
-- Joins across backends mean that the aforementioned @b@ parameter won't be the same throughout
-- the entire tree; at some point we will have an 'AnyBackend' used to encapsulate a branch that
-- uses a different @b@. We still want, however, to be able to parameterize the values of the
-- leaves in that separate branch, and that's what the @r@ parameter is for. We also use
-- 'UnpreparedValue' here during the parsing phase, meaning all leaf values will be
-- @UnpreparedValue b@ for their respective backend @b@, and most backends will then transform
-- their AST, cutting all such remote branches, and therefore using @Const Void@ for @r@.
module Hasura.RQL.IR.Select
( AggregateField (..),
AggregateFields,
AggregateOp (..),
AnnAggregateSelect,
AnnAggregateSelectG,
AnnColumnField (..),
AnnField,
AnnFieldG (..),
AnnFields,
AnnFieldsG,
AnnObjectSelect,
AnnObjectSelectG (..),
AnnRelationSelectG (..),
AnnSelectG (..),
AnnSelectStreamG (..),
AnnSimpleSelect,
AnnSimpleSelectG,
AnnSimpleStreamSelect,
AnnSimpleStreamSelectG,
AnnotatedAggregateOrderBy (..),
AnnotatedOrderByElement (..),
AnnotatedOrderByItem,
AnnotatedOrderByItemG,
ArrayAggregateSelect,
ArrayAggregateSelectG,
ArrayConnectionSelect,
ArrayRelationSelectG,
ArraySelect,
ArraySelectFieldsG,
ArraySelectG (..),
ColFld (..),
ColumnFields,
ComputedFieldOrderBy (..),
ComputedFieldOrderByElement (..),
ComputedFieldScalarSelect (..),
ComputedFieldSelect (..),
ConnectionField (..),
ConnectionFields,
ConnectionSelect (..),
ConnectionSlice (..),
ConnectionSplit (..),
ConnectionSplitKind (..),
EdgeField (..),
EdgeFields,
FIIdentifier (..),
ObjectRelationSelect,
ObjectRelationSelectG,
PageInfoField (..),
PageInfoFields,
QueryDB (..),
RemoteSourceSelect (..),
SelectArgs,
SelectArgsG (..),
SelectStreamArgsG (..),
SelectStreamArgs,
SelectFrom,
SelectFromG (..),
RemoteRelationshipSelect (..),
SourceRelationshipSelection (..),
StreamCursorItem (..),
TableAggregateField,
TableAggregateFieldG (..),
TableAggregateFields,
TableAggregateFieldsG,
TablePerm,
TablePermG (..),
CountDistinct (..),
aarRelationshipName,
aarColumnMapping,
aarAnnSelect,
aosFields,
aosTableFrom,
aosTableFilter,
asnArgs,
asnFields,
asnFrom,
asnPerm,
asnStrfyNum,
bifoldMapAnnSelectG,
csXRelay,
csPrimaryKeyColumns,
csSplit,
csSlice,
csSelect,
insertFunctionArg,
mkAnnColumnField,
mkAnnColumnFieldAsText,
noSelectArgs,
noTablePermissions,
saDistinct,
saLimit,
saOffset,
saOrderBy,
saWhere,
traverseSourceRelationshipSelection,
_AFArrayRelation,
_AFColumn,
_AFComputedField,
_AFExpression,
_AFNodeId,
_AFObjectRelation,
_AFRemote,
_AOCArrayAggregation,
_AOCColumn,
_AOCComputedField,
_AOCObjectRelation,
_TAFAgg,
_TAFNodes,
_TAFExp,
_ConnectionTypename,
_ConnectionPageInfo,
_ConnectionEdges,
_EdgeTypename,
_EdgeCursor,
_EdgeNode,
)
where
import Control.Lens.TH (makeLenses, makePrisms)
import Data.Bifoldable
import Data.HashMap.Strict qualified as HM
import Data.Int (Int64)
import Data.Kind (Type)
import Data.List.NonEmpty qualified as NE
import Data.Sequence qualified as Seq
import Hasura.Backends.Postgres.SQL.Types qualified as PG
import Hasura.GraphQL.Schema.Options (StringifyNumbers)
import Hasura.Prelude
import Hasura.RQL.IR.BoolExp
import Hasura.RQL.IR.OrderBy
import Hasura.RQL.Types.Backend
import Hasura.RQL.Types.Column
import Hasura.RQL.Types.Common
import Hasura.RQL.Types.ComputedField
import Hasura.RQL.Types.Function
import Hasura.RQL.Types.Instances ()
import Hasura.RQL.Types.Relationships.Local
import Hasura.RQL.Types.Relationships.Remote
import Hasura.RQL.Types.Subscription
import Hasura.SQL.Backend
-- Root selection
2019-04-17 12:48:41 +03:00
data QueryDB (b :: BackendType) (r :: Type) v
= QDBMultipleRows (AnnSimpleSelectG b r v)
| QDBSingleRow (AnnSimpleSelectG b r v)
| QDBAggregation (AnnAggregateSelectG b r v)
| QDBConnection (ConnectionSelect b r v)
| QDBStreamMultipleRows (AnnSimpleStreamSelectG b r v)
deriving stock (Generic, Functor, Foldable, Traversable)
instance Backend b => Bifoldable (QueryDB b) where
bifoldMap f g = \case
QDBMultipleRows annSel -> bifoldMapAnnSelectG f g annSel
QDBSingleRow annSel -> bifoldMapAnnSelectG f g annSel
QDBAggregation annSel -> bifoldMapAnnSelectG f g annSel
QDBConnection connSel -> bifoldMap f g connSel
QDBStreamMultipleRows annSel -> bifoldMapAnnSelectStreamG f g annSel
-- Select
data AnnSelectG (b :: BackendType) (f :: Type -> Type) (v :: Type) = AnnSelectG
{ _asnFields :: Fields (f v),
_asnFrom :: SelectFromG b v,
_asnPerm :: TablePermG b v,
_asnArgs :: SelectArgsG b v,
_asnStrfyNum :: StringifyNumbers
}
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq (f v)
) =>
Eq (AnnSelectG b f v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show (f v)
) =>
Show (AnnSelectG b f v)
-- | IR type representing nodes for streaming subscriptions
data
AnnSelectStreamG
(b :: BackendType)
(f :: Type -> Type)
(v :: Type) = AnnSelectStreamG
{ -- | type to indicate if streaming subscription has been enabled in the `BackendType`.
-- This type helps avoiding missing case match patterns for backends where it's disabled.
_assnXStreamingSubscription :: XStreamingSubscription b,
-- | output selection fields
_assnFields :: Fields (f v),
-- | table information to select from
_assnFrom :: SelectFromG b v,
-- | select permissions
_assnPerm :: TablePermG b v,
-- | streaming arguments
_assnArgs :: SelectStreamArgsG b v,
_assnStrfyNum :: StringifyNumbers
}
deriving (Functor, Foldable, Traversable)
deriving instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq (f v)
) =>
Eq (AnnSelectStreamG b f v)
deriving instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show (f v)
) =>
Show (AnnSelectStreamG b f v)
type AnnSimpleSelectG b r v = AnnSelectG b (AnnFieldG b r) v
type AnnAggregateSelectG b r v = AnnSelectG b (TableAggregateFieldG b r) v
type AnnSimpleStreamSelectG b r v = AnnSelectStreamG b (AnnFieldG b r) v
type AnnSimpleSelect b = AnnSimpleSelectG b Void (SQLExpression b)
type AnnAggregateSelect b = AnnAggregateSelectG b Void (SQLExpression b)
type AnnSimpleStreamSelect b = AnnSimpleStreamSelectG b Void (SQLExpression b)
-- | We can't write a Bifoldable instance for AnnSelectG because the types don't line up.
-- Instead, we provide this function which can be used to help define Bifoldable instances of other types
-- containing AnnSelectG values.
bifoldMapAnnSelectG :: (Backend b, Bifoldable (f b), Monoid m) => (r -> m) -> (v -> m) -> AnnSelectG b (f b r) v -> m
bifoldMapAnnSelectG f g AnnSelectG {..} =
foldMap (foldMap $ bifoldMap f g) _asnFields
<> foldMap g _asnFrom
<> foldMap g _asnPerm
<> foldMap g _asnArgs
bifoldMapAnnSelectStreamG :: (Backend b, Bifoldable (f b), Monoid m) => (r -> m) -> (v -> m) -> AnnSelectStreamG b (f b r) v -> m
bifoldMapAnnSelectStreamG f g AnnSelectStreamG {..} =
foldMap (foldMap $ bifoldMap f g) _assnFields
<> foldMap g _assnFrom
<> foldMap g _assnPerm
<> foldMap g _assnArgs
-- Relay select
data ConnectionSelect (b :: BackendType) (r :: Type) v = ConnectionSelect
{ _csXRelay :: XRelay b,
_csPrimaryKeyColumns :: PrimaryKeyColumns b,
_csSplit :: Maybe (NE.NonEmpty (ConnectionSplit b v)),
_csSlice :: Maybe ConnectionSlice,
_csSelect :: (AnnSelectG b (ConnectionField b r) v)
}
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (ConnectionSelect b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (ConnectionSelect b r v)
instance Backend b => Bifoldable (ConnectionSelect b) where
bifoldMap f g ConnectionSelect {..} =
foldMap (foldMap $ foldMap g) _csSplit
<> bifoldMapAnnSelectG f g _csSelect
data ConnectionSplit (b :: BackendType) v = ConnectionSplit
{ _csKind :: ConnectionSplitKind,
_csValue :: v,
_csOrderBy :: (OrderByItemG b (AnnotatedOrderByElement b v))
}
deriving stock (Functor, Generic, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq v,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v)
) =>
Eq (ConnectionSplit b v)
deriving stock instance
( Backend b,
Show v,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v)
) =>
Show (ConnectionSplit b v)
instance
( Backend b,
Hashable (BooleanOperators b v),
Hashable (FunctionArgumentExp b v),
Hashable (ColumnInfo b),
Hashable v
) =>
Hashable (ConnectionSplit b v)
data ConnectionSlice
= SliceFirst Int
| SliceLast Int
deriving stock (Show, Eq, Generic)
deriving anyclass (Hashable)
[Preview] Inherited roles for postgres read queries fixes #3868 docker image - `hasura/graphql-engine:inherited-roles-preview-48b73a2de` Note: To be able to use the inherited roles feature, the graphql-engine should be started with the env variable `HASURA_GRAPHQL_EXPERIMENTAL_FEATURES` set to `inherited_roles`. Introduction ------------ This PR implements the idea of multiple roles as presented in this [paper](https://www.microsoft.com/en-us/research/wp-content/uploads/2016/02/FGALanguageICDE07.pdf). The multiple roles feature in this PR can be used via inherited roles. An inherited role is a role which can be created by combining multiple singular roles. For example, if there are two roles `author` and `editor` configured in the graphql-engine, then we can create a inherited role with the name of `combined_author_editor` role which will combine the select permissions of the `author` and `editor` roles and then make GraphQL queries using the `combined_author_editor`. How are select permissions of different roles are combined? ------------------------------------------------------------ A select permission includes 5 things: 1. Columns accessible to the role 2. Row selection filter 3. Limit 4. Allow aggregation 5. Scalar computed fields accessible to the role Suppose there are two roles, `role1` gives access to the `address` column with row filter `P1` and `role2` gives access to both the `address` and the `phone` column with row filter `P2` and we create a new role `combined_roles` which combines `role1` and `role2`. Let's say the following GraphQL query is queried with the `combined_roles` role. ```graphql query { employees { address phone } } ``` This will translate to the following SQL query: ```sql select (case when (P1 or P2) then address else null end) as address, (case when P2 then phone else null end) as phone from employee where (P1 or P2) ``` The other parameters of the select permission will be combined in the following manner: 1. Limit - Minimum of the limits will be the limit of the inherited role 2. Allow aggregations - If any of the role allows aggregation, then the inherited role will allow aggregation 3. Scalar computed fields - same as table column fields, as in the above example APIs for inherited roles: ---------------------- 1. `add_inherited_role` `add_inherited_role` is the [metadata API](https://hasura.io/docs/1.0/graphql/core/api-reference/index.html#schema-metadata-api) to create a new inherited role. It accepts two arguments `role_name`: the name of the inherited role to be added (String) `role_set`: list of roles that need to be combined (Array of Strings) Example: ```json { "type": "add_inherited_role", "args": { "role_name":"combined_user", "role_set":[ "user", "user1" ] } } ``` After adding the inherited role, the inherited role can be used like single roles like earlier Note: An inherited role can only be created with non-inherited/singular roles. 2. `drop_inherited_role` The `drop_inherited_role` API accepts the name of the inherited role and drops it from the metadata. It accepts a single argument: `role_name`: name of the inherited role to be dropped Example: ```json { "type": "drop_inherited_role", "args": { "role_name":"combined_user" } } ``` Metadata --------- The derived roles metadata will be included under the `experimental_features` key while exporting the metadata. ```json { "experimental_features": { "derived_roles": [ { "role_name": "manager_is_employee_too", "role_set": [ "employee", "manager" ] } ] } } ``` Scope ------ Only postgres queries and subscriptions are supported in this PR. Important points: ----------------- 1. All columns exposed to an inherited role will be marked as `nullable`, this is done so that cell value nullification can be done. TODOs ------- - [ ] Tests - [ ] Test a GraphQL query running with a inherited role without enabling inherited roles in experimental features - [] Tests for aggregate queries, limit, computed fields, functions, subscriptions (?) - [ ] Introspection test with a inherited role (nullability changes in a inherited role) - [ ] Docs - [ ] Changelog Co-authored-by: Vamshi Surabhi <6562944+0x777@users.noreply.github.com> GitOrigin-RevId: 3b8ee1e11f5ceca80fe294f8c074d42fbccfec63
2021-03-08 14:14:13 +03:00
data ConnectionSplitKind
= CSKBefore
| CSKAfter
deriving stock (Show, Eq, Generic)
deriving anyclass (Hashable)
-- From
-- | Identifier used exclusively as the argument to 'FromIdentifier'
newtype FIIdentifier = FIIdentifier
{ unFIIdentifier :: Text
}
deriving stock (Generic)
deriving newtype (Eq, Show)
deriving anyclass (Hashable)
instance PG.IsIdentifier FIIdentifier where
toIdentifier = coerce
{-# INLINE toIdentifier #-}
data SelectFromG (b :: BackendType) v
= FromTable (TableName b)
| FromIdentifier FIIdentifier
| FromFunction
(FunctionName b)
(FunctionArgsExp b v)
-- a definition list
(Maybe [(Column b, ScalarType b)])
deriving stock (Generic)
deriving stock instance (Backend b) => Functor (SelectFromG b)
deriving stock instance (Backend b) => Foldable (SelectFromG b)
deriving stock instance (Backend b) => Traversable (SelectFromG b)
deriving stock instance (Backend b, Eq v, Eq (FunctionArgumentExp b v)) => Eq (SelectFromG b v)
deriving stock instance (Backend b, Show v, Show (FunctionArgumentExp b v)) => Show (SelectFromG b v)
instance (Backend b, Hashable v, Hashable (FunctionArgumentExp b v)) => Hashable (SelectFromG b v)
[Preview] Inherited roles for postgres read queries fixes #3868 docker image - `hasura/graphql-engine:inherited-roles-preview-48b73a2de` Note: To be able to use the inherited roles feature, the graphql-engine should be started with the env variable `HASURA_GRAPHQL_EXPERIMENTAL_FEATURES` set to `inherited_roles`. Introduction ------------ This PR implements the idea of multiple roles as presented in this [paper](https://www.microsoft.com/en-us/research/wp-content/uploads/2016/02/FGALanguageICDE07.pdf). The multiple roles feature in this PR can be used via inherited roles. An inherited role is a role which can be created by combining multiple singular roles. For example, if there are two roles `author` and `editor` configured in the graphql-engine, then we can create a inherited role with the name of `combined_author_editor` role which will combine the select permissions of the `author` and `editor` roles and then make GraphQL queries using the `combined_author_editor`. How are select permissions of different roles are combined? ------------------------------------------------------------ A select permission includes 5 things: 1. Columns accessible to the role 2. Row selection filter 3. Limit 4. Allow aggregation 5. Scalar computed fields accessible to the role Suppose there are two roles, `role1` gives access to the `address` column with row filter `P1` and `role2` gives access to both the `address` and the `phone` column with row filter `P2` and we create a new role `combined_roles` which combines `role1` and `role2`. Let's say the following GraphQL query is queried with the `combined_roles` role. ```graphql query { employees { address phone } } ``` This will translate to the following SQL query: ```sql select (case when (P1 or P2) then address else null end) as address, (case when P2 then phone else null end) as phone from employee where (P1 or P2) ``` The other parameters of the select permission will be combined in the following manner: 1. Limit - Minimum of the limits will be the limit of the inherited role 2. Allow aggregations - If any of the role allows aggregation, then the inherited role will allow aggregation 3. Scalar computed fields - same as table column fields, as in the above example APIs for inherited roles: ---------------------- 1. `add_inherited_role` `add_inherited_role` is the [metadata API](https://hasura.io/docs/1.0/graphql/core/api-reference/index.html#schema-metadata-api) to create a new inherited role. It accepts two arguments `role_name`: the name of the inherited role to be added (String) `role_set`: list of roles that need to be combined (Array of Strings) Example: ```json { "type": "add_inherited_role", "args": { "role_name":"combined_user", "role_set":[ "user", "user1" ] } } ``` After adding the inherited role, the inherited role can be used like single roles like earlier Note: An inherited role can only be created with non-inherited/singular roles. 2. `drop_inherited_role` The `drop_inherited_role` API accepts the name of the inherited role and drops it from the metadata. It accepts a single argument: `role_name`: name of the inherited role to be dropped Example: ```json { "type": "drop_inherited_role", "args": { "role_name":"combined_user" } } ``` Metadata --------- The derived roles metadata will be included under the `experimental_features` key while exporting the metadata. ```json { "experimental_features": { "derived_roles": [ { "role_name": "manager_is_employee_too", "role_set": [ "employee", "manager" ] } ] } } ``` Scope ------ Only postgres queries and subscriptions are supported in this PR. Important points: ----------------- 1. All columns exposed to an inherited role will be marked as `nullable`, this is done so that cell value nullification can be done. TODOs ------- - [ ] Tests - [ ] Test a GraphQL query running with a inherited role without enabling inherited roles in experimental features - [] Tests for aggregate queries, limit, computed fields, functions, subscriptions (?) - [ ] Introspection test with a inherited role (nullability changes in a inherited role) - [ ] Docs - [ ] Changelog Co-authored-by: Vamshi Surabhi <6562944+0x777@users.noreply.github.com> GitOrigin-RevId: 3b8ee1e11f5ceca80fe294f8c074d42fbccfec63
2021-03-08 14:14:13 +03:00
type SelectFrom b = SelectFromG b (SQLExpression b)
-- Select arguments
data SelectStreamArgsG (b :: BackendType) v = SelectStreamArgsG
{ -- | optional filter to filter the stream results
_ssaWhere :: !(Maybe (AnnBoolExp b v)),
-- | maximum number of rows to be returned in a single fetch
_ssaBatchSize :: !Int,
-- | info related to the cursor column, a single item data type
-- currently because only single column cursors are supported
_ssaCursorArg :: !(StreamCursorItem b)
}
deriving (Generic, Functor, Foldable, Traversable)
type SelectStreamArgs b = SelectStreamArgsG b (SQLExpression b)
deriving instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v
) =>
Eq (SelectStreamArgsG b v)
deriving instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v
) =>
Show (SelectStreamArgsG b v)
data SelectArgsG (b :: BackendType) v = SelectArgs
{ _saWhere :: Maybe (AnnBoolExp b v),
_saOrderBy :: Maybe (NE.NonEmpty (AnnotatedOrderByItemG b v)),
_saLimit :: Maybe Int,
_saOffset :: Maybe Int64,
_saDistinct :: (Maybe (NE.NonEmpty (Column b)))
}
deriving stock (Generic, Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v
) =>
Eq (SelectArgsG b v)
instance
( Backend b,
Hashable (BooleanOperators b v),
Hashable (FunctionArgumentExp b v),
Hashable v
) =>
Hashable (SelectArgsG b v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v
) =>
Show (SelectArgsG b v)
type SelectArgs b = SelectArgsG b (SQLExpression b)
noSelectArgs :: SelectArgsG backend v
noSelectArgs = SelectArgs Nothing Nothing Nothing Nothing Nothing
-- Order by argument
-- | The order by element for a computed field based on its return type
data ComputedFieldOrderByElement (b :: BackendType) v
= -- | Sort by the scalar computed field
CFOBEScalar (ScalarType b)
| CFOBETableAggregation
(TableName b)
(AnnBoolExp b v)
-- ^ Permission filter of the retuning table
(AnnotatedAggregateOrderBy b)
-- ^ Sort by aggregation fields of table rows returned by computed field
deriving stock (Generic, Functor, Foldable, Traversable)
deriving stock instance (Backend b, Eq v, Eq (BooleanOperators b v), Eq (FunctionArgumentExp b v)) => Eq (ComputedFieldOrderByElement b v)
deriving stock instance (Backend b, Show v, Show (BooleanOperators b v), Show (FunctionArgumentExp b v)) => Show (ComputedFieldOrderByElement b v)
instance (Backend b, Hashable v, Hashable (BooleanOperators b v), Hashable (FunctionArgumentExp b v)) => Hashable (ComputedFieldOrderByElement b v)
data ComputedFieldOrderBy (b :: BackendType) v = ComputedFieldOrderBy
{ _cfobXField :: XComputedField b,
_cfobName :: ComputedFieldName,
_cfobFunction :: FunctionName b,
_cfobFunctionArgsExp :: FunctionArgsExp b v,
_cfobOrderByElement :: (ComputedFieldOrderByElement b v)
}
deriving stock (Generic)
deriving stock instance (Backend b) => Functor (ComputedFieldOrderBy b)
deriving stock instance (Backend b) => Foldable (ComputedFieldOrderBy b)
deriving stock instance (Backend b) => Traversable (ComputedFieldOrderBy b)
deriving stock instance (Backend b, Eq v, Eq (BooleanOperators b v), Eq (FunctionArgumentExp b v)) => Eq (ComputedFieldOrderBy b v)
deriving stock instance (Backend b, Show v, Show (BooleanOperators b v), Show (FunctionArgumentExp b v)) => Show (ComputedFieldOrderBy b v)
instance (Backend b, Hashable v, Hashable (BooleanOperators b v), Hashable (FunctionArgumentExp b v)) => Hashable (ComputedFieldOrderBy b v)
data AnnotatedOrderByElement (b :: BackendType) v
= AOCColumn (ColumnInfo b)
| AOCObjectRelation
(RelInfo b)
(AnnBoolExp b v)
-- ^ Permission filter of the remote table to which the relationship is defined
(AnnotatedOrderByElement b v)
| AOCArrayAggregation
(RelInfo b)
(AnnBoolExp b v)
-- ^ Permission filter of the remote table to which the relationship is defined
(AnnotatedAggregateOrderBy b)
| AOCComputedField (ComputedFieldOrderBy b v)
deriving stock (Generic, Functor, Foldable, Traversable)
deriving stock instance (Backend b, Eq v, Eq (BooleanOperators b v), Eq (FunctionArgumentExp b v)) => Eq (AnnotatedOrderByElement b v)
deriving stock instance (Backend b, Show v, Show (BooleanOperators b v), Show (FunctionArgumentExp b v)) => Show (AnnotatedOrderByElement b v)
instance (Backend b, Hashable v, Hashable (BooleanOperators b v), Hashable (FunctionArgumentExp b v)) => Hashable (AnnotatedOrderByElement b v)
data AnnotatedAggregateOrderBy (b :: BackendType)
= AAOCount
| AAOOp Text !(ColumnInfo b)
deriving stock (Generic)
deriving stock instance (Backend b) => Eq (AnnotatedAggregateOrderBy b)
deriving stock instance (Backend b) => Show (AnnotatedAggregateOrderBy b)
instance (Backend b) => Hashable (AnnotatedAggregateOrderBy b)
2019-04-17 12:48:41 +03:00
type AnnotatedOrderByItemG b v = OrderByItemG b (AnnotatedOrderByElement b v)
type AnnotatedOrderByItem b = AnnotatedOrderByItemG b (SQLExpression b)
-- | Cursor for streaming subscription
data StreamCursorItem (b :: BackendType) = StreamCursorItem
{ -- | Specifies how the cursor item should be ordered
_sciOrdering :: !CursorOrdering,
-- | Column info of the cursor item
_sciColInfo :: !(ColumnInfo b),
-- | Initial value of the cursor item from where the streaming should start
_sciInitialValue :: !(ColumnValue b)
}
deriving (Generic)
deriving instance (Backend b) => Eq (StreamCursorItem b)
deriving instance (Backend b) => Show (StreamCursorItem b)
-- Fields
-- | captures a remote relationship's selection and the necessary context
data RemoteRelationshipSelect b r = RemoteRelationshipSelect
{ -- | The fields on the table that are required for the join condition
-- of the remote relationship
_rrsLHSJoinFields :: HashMap FieldName (DBJoinField b),
-- | The field that captures the relationship
-- r ~ (RemoteRelationshipField UnpreparedValue) when the AST is emitted by the parser.
-- r ~ Void when an execution tree is constructed so that a backend is
-- absolved of dealing with remote relationships.
_rrsRelationship :: r
}
deriving (Eq, Show, Functor, Foldable, Traversable)
data AnnFieldG (b :: BackendType) (r :: Type) v
= AFColumn (AnnColumnField b v)
| AFObjectRelation (ObjectRelationSelectG b r v)
| AFArrayRelation (ArraySelectG b r v)
Clean Relay's code, break schema cycles, introduce Node ID V2 ## Motivation This PR rewrites most of Relay to achieve the following: - ~~fix a bug in which the same node id could refer to two different tables in the schema~~ - remove one of the few remaining uses of the source cache in the schema building code In doing so, it also: - simplifies the `BackendSchema` class by removing `node` from it, - makes it much easier for other backends to support Relay, - documents, re-organizes, and clarifies the code. ## Description This PR introduces a new `NodeId` version ~~, and adapts the Postgres code to always generate this V2 version~~. This new id contains the source name, in addition to the table name, in order to disambiguate similar table names across different sources (which is now possible with source customization). In doing so, it now explicitly handles that case for V1 node ids, and returns an explicit error message instead of running the risk of _silently returning the wrong information_. Furthermore, it adapts `nodeField` to support multiple backends; most of the code was trivial to generalize, and as a result it lowers the cost of entry for other backends, that now only need to support `AFNodeId` in their translation layer. Finally, it removes one more cycle in the schema building code, by using the same trick we used for remote relationships instead of using the memoization trick of #4576. ## Remaining work - ~~[ ]write a Changelog entry~~ - ~~[x] adapt all tests that were asserting on an old node id~~ ## Future work This PR was adapted from its original form to avoid a breaking change: while it introduces a Node ID V2, we keep generating V1 IDs and the parser rejects V2 IDs. It will be easy to make the switch at a later data in a subsequent PR. PR-URL: https://github.com/hasura/graphql-engine-mono/pull/4593 GitOrigin-RevId: 88e5cb91e8b0646900547fa8c7c0e1463de267a1
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| AFComputedField (XComputedField b) ComputedFieldName (ComputedFieldSelect b r v)
| -- | A remote relationship field
AFRemote (RemoteRelationshipSelect b r)
Clean Relay's code, break schema cycles, introduce Node ID V2 ## Motivation This PR rewrites most of Relay to achieve the following: - ~~fix a bug in which the same node id could refer to two different tables in the schema~~ - remove one of the few remaining uses of the source cache in the schema building code In doing so, it also: - simplifies the `BackendSchema` class by removing `node` from it, - makes it much easier for other backends to support Relay, - documents, re-organizes, and clarifies the code. ## Description This PR introduces a new `NodeId` version ~~, and adapts the Postgres code to always generate this V2 version~~. This new id contains the source name, in addition to the table name, in order to disambiguate similar table names across different sources (which is now possible with source customization). In doing so, it now explicitly handles that case for V1 node ids, and returns an explicit error message instead of running the risk of _silently returning the wrong information_. Furthermore, it adapts `nodeField` to support multiple backends; most of the code was trivial to generalize, and as a result it lowers the cost of entry for other backends, that now only need to support `AFNodeId` in their translation layer. Finally, it removes one more cycle in the schema building code, by using the same trick we used for remote relationships instead of using the memoization trick of #4576. ## Remaining work - ~~[ ]write a Changelog entry~~ - ~~[x] adapt all tests that were asserting on an old node id~~ ## Future work This PR was adapted from its original form to avoid a breaking change: while it introduces a Node ID V2, we keep generating V1 IDs and the parser rejects V2 IDs. It will be easy to make the switch at a later data in a subsequent PR. PR-URL: https://github.com/hasura/graphql-engine-mono/pull/4593 GitOrigin-RevId: 88e5cb91e8b0646900547fa8c7c0e1463de267a1
2022-06-07 16:35:26 +03:00
| AFNodeId (XRelay b) SourceName (TableName b) (PrimaryKeyColumns b)
| AFExpression Text
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (AnnFieldG b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (AnnFieldG b r v)
instance Backend b => Bifoldable (AnnFieldG b) where
bifoldMap f g = \case
AFColumn col -> foldMap g col
AFObjectRelation objRel -> foldMap (bifoldMap f g) objRel
AFArrayRelation arrRel -> bifoldMap f g arrRel
AFComputedField _ _ cf -> bifoldMap f g cf
AFRemote r -> foldMap f r
AFNodeId {} -> mempty
AFExpression {} -> mempty
type AnnField b = AnnFieldG b Void (SQLExpression b)
type AnnFields b = AnnFieldsG b Void (SQLExpression b)
mkAnnColumnField ::
Column backend ->
ColumnType backend ->
Maybe (AnnColumnCaseBoolExp backend v) ->
Maybe (ScalarSelectionArguments backend) ->
AnnFieldG backend r v
mkAnnColumnField col typ caseBoolExp colOpM =
AFColumn (AnnColumnField col typ False colOpM caseBoolExp)
mkAnnColumnFieldAsText ::
ColumnInfo backend ->
AnnFieldG backend r v
mkAnnColumnFieldAsText ci =
AFColumn (AnnColumnField (ciColumn ci) (ciType ci) True Nothing Nothing)
traverseSourceRelationshipSelection ::
(Applicative f, Backend backend) =>
(vf backend -> f (vg backend)) ->
SourceRelationshipSelection backend r vf ->
f (SourceRelationshipSelection backend r vg)
traverseSourceRelationshipSelection f = \case
SourceRelationshipObject s ->
SourceRelationshipObject <$> traverse f s
SourceRelationshipArray s ->
SourceRelationshipArray <$> traverse f s
SourceRelationshipArrayAggregate s ->
SourceRelationshipArrayAggregate <$> traverse f s
-- Aggregation fields
data TableAggregateFieldG (b :: BackendType) (r :: Type) v
= TAFAgg (AggregateFields b)
| TAFNodes (XNodesAgg b) (AnnFieldsG b r v)
| TAFExp Text
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (TableAggregateFieldG b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (TableAggregateFieldG b r v)
instance Backend b => Bifoldable (TableAggregateFieldG b) where
bifoldMap f g = \case
TAFAgg {} -> mempty
TAFNodes _ fields -> foldMap (foldMap $ bifoldMap f g) fields
TAFExp {} -> mempty
data AggregateField (b :: BackendType)
= AFCount (CountType b)
| AFOp (AggregateOp b)
| AFExp Text
deriving stock instance (Backend b) => Eq (AggregateField b)
deriving stock instance (Backend b) => Show (AggregateField b)
data AggregateOp (b :: BackendType) = AggregateOp
{ _aoOp :: Text,
_aoFields :: (ColumnFields b)
}
deriving stock (Eq, Show)
data ColFld (b :: BackendType)
= CFCol (Column b) !(ColumnType b)
| CFExp Text
deriving stock (Eq, Show)
type TableAggregateField b = TableAggregateFieldG b Void (SQLExpression b)
type TableAggregateFields b = TableAggregateFieldsG b Void (SQLExpression b)
type TableAggregateFieldsG b r v = Fields (TableAggregateFieldG b r v)
type ColumnFields b = Fields (ColFld b)
type AggregateFields b = Fields (AggregateField b)
type AnnFieldsG b r v = Fields (AnnFieldG b r v)
-- Relay fields
data ConnectionField (b :: BackendType) (r :: Type) v
= ConnectionTypename Text
| ConnectionPageInfo PageInfoFields
| ConnectionEdges (EdgeFields b r v)
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (ConnectionField b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (ConnectionField b r v)
instance Backend b => Bifoldable (ConnectionField b) where
bifoldMap f g = \case
ConnectionTypename {} -> mempty
ConnectionPageInfo {} -> mempty
ConnectionEdges edgeFields -> foldMap (foldMap $ bifoldMap f g) edgeFields
data PageInfoField
= PageInfoTypename Text
| PageInfoHasNextPage
| PageInfoHasPreviousPage
| PageInfoStartCursor
| PageInfoEndCursor
deriving stock (Show, Eq)
data EdgeField (b :: BackendType) (r :: Type) v
= EdgeTypename Text
| EdgeCursor
| EdgeNode (AnnFieldsG b r v)
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (EdgeField b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (EdgeField b r v)
instance Backend b => Bifoldable (EdgeField b) where
bifoldMap f g = \case
EdgeTypename {} -> mempty
EdgeCursor -> mempty
EdgeNode annFields -> foldMap (foldMap $ bifoldMap f g) annFields
type ConnectionFields b r v = Fields (ConnectionField b r v)
type PageInfoFields = Fields PageInfoField
type EdgeFields b r v = Fields (EdgeField b r v)
data AnnColumnField (b :: BackendType) v = AnnColumnField
{ _acfColumn :: Column b,
_acfType :: ColumnType b,
-- | If this field is 'True', columns are explicitly casted to @text@ when
-- fetched, which avoids an issue that occurs because we dont currently
-- have proper support for array types. See
-- https://github.com/hasura/graphql-engine/pull/3198 for more details.
_acfAsText :: Bool,
-- | Arguments of this column's selection. See 'ScalarSelectionArguments'
_acfArguments :: Maybe (ScalarSelectionArguments b),
-- | This type is used to determine whether the column
-- should be nullified. When the value is `Nothing`, the column value
-- will be outputted as computed and when the value is `Just c`, the
-- column will be outputted when `c` evaluates to `true` and `null`
-- when `c` evaluates to `false`.
_acfCaseBoolExpression :: (Maybe (AnnColumnCaseBoolExp b v))
}
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v
) =>
Eq (AnnColumnField b v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v
) =>
Show (AnnColumnField b v)
-- Computed field
2019-04-17 12:48:41 +03:00
data ComputedFieldScalarSelect (b :: BackendType) v = ComputedFieldScalarSelect
{ _cfssFunction :: FunctionName b,
_cfssArguments :: FunctionArgsExp b v,
_cfssType :: ScalarType b,
_cfssScalarArguments :: (Maybe (ScalarSelectionArguments b))
}
deriving stock instance (Backend b) => Functor (ComputedFieldScalarSelect b)
deriving stock instance (Backend b) => Foldable (ComputedFieldScalarSelect b)
deriving stock instance (Backend b) => Traversable (ComputedFieldScalarSelect b)
deriving stock instance (Backend b, Show v, Show (FunctionArgumentExp b v)) => Show (ComputedFieldScalarSelect b v)
deriving stock instance (Backend b, Eq v, Eq (FunctionArgumentExp b v)) => Eq (ComputedFieldScalarSelect b v)
data ComputedFieldSelect (b :: BackendType) (r :: Type) v
= CFSScalar
(ComputedFieldScalarSelect b v)
-- ^ Type containing info about the computed field
(Maybe (AnnColumnCaseBoolExp b v))
-- ^ This type is used to determine if whether the scalar
-- computed field should be nullified. When the value is `Nothing`,
-- the scalar computed value will be outputted as computed and when the
-- value is `Just c`, the scalar computed field will be outputted when
-- `c` evaluates to `true` and `null` when `c` evaluates to `false`
| CFSTable JsonAggSelect !(AnnSimpleSelectG b r v)
deriving stock (Functor, Foldable, Traversable)
2019-04-17 12:48:41 +03:00
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (ComputedFieldSelect b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (ComputedFieldSelect b r v)
instance Backend b => Bifoldable (ComputedFieldSelect b) where
bifoldMap f g = \case
CFSScalar cfsSelect caseBoolExp -> foldMap g cfsSelect <> foldMap (foldMap $ foldMap g) caseBoolExp
CFSTable _ simpleSelect -> bifoldMapAnnSelectG f g simpleSelect
-- Local relationship
data AnnRelationSelectG (b :: BackendType) a = AnnRelationSelectG
{ _aarRelationshipName :: RelName, -- Relationship name
_aarColumnMapping :: HashMap (Column b) (Column b), -- Column of left table to join with
_aarAnnSelect :: a -- Current table. Almost ~ to SQL Select
}
deriving stock (Functor, Foldable, Traversable)
deriving stock instance (Backend b, Eq v) => Eq (AnnRelationSelectG b v)
deriving stock instance (Backend b, Show v) => Show (AnnRelationSelectG b v)
type ArrayRelationSelectG b r v = AnnRelationSelectG b (AnnSimpleSelectG b r v)
type ArrayAggregateSelectG b r v = AnnRelationSelectG b (AnnAggregateSelectG b r v)
type ArrayConnectionSelect b r v = AnnRelationSelectG b (ConnectionSelect b r v)
type ArrayAggregateSelect b = ArrayAggregateSelectG b Void (SQLExpression b)
data AnnObjectSelectG (b :: BackendType) (r :: Type) v = AnnObjectSelectG
{ _aosFields :: AnnFieldsG b r v,
_aosTableFrom :: TableName b,
_aosTableFilter :: (AnnBoolExp b v)
}
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (AnnObjectSelectG b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (AnnObjectSelectG b r v)
instance Backend b => Bifoldable (AnnObjectSelectG b) where
bifoldMap f g AnnObjectSelectG {..} =
foldMap (foldMap $ bifoldMap f g) _aosFields <> foldMap (foldMap g) _aosTableFilter
type AnnObjectSelect b r = AnnObjectSelectG b r (SQLExpression b)
type ObjectRelationSelectG b r v = AnnRelationSelectG b (AnnObjectSelectG b r v)
type ObjectRelationSelect b = ObjectRelationSelectG b Void (SQLExpression b)
data ArraySelectG (b :: BackendType) (r :: Type) v
= ASSimple (ArrayRelationSelectG b r v)
| ASAggregate (ArrayAggregateSelectG b r v)
| ASConnection (ArrayConnectionSelect b r v)
deriving stock (Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v,
Eq r
) =>
Eq (ArraySelectG b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v,
Show r
) =>
Show (ArraySelectG b r v)
instance Backend b => Bifoldable (ArraySelectG b) where
bifoldMap f g = \case
ASSimple arrayRelationSelect -> foldMap (bifoldMapAnnSelectG f g) arrayRelationSelect
ASAggregate arrayAggregateSelect -> foldMap (bifoldMapAnnSelectG f g) arrayAggregateSelect
ASConnection arrayConnectionSelect -> foldMap (bifoldMap f g) arrayConnectionSelect
type ArraySelect b = ArraySelectG b Void (SQLExpression b)
type ArraySelectFieldsG b r v = Fields (ArraySelectG b r v)
2019-04-17 12:48:41 +03:00
-- | Captures the selection set of a remote source relationship.
data
SourceRelationshipSelection
(b :: BackendType)
(r :: Type)
(vf :: BackendType -> Type)
= SourceRelationshipObject (AnnObjectSelectG b r (vf b))
| SourceRelationshipArray (AnnSimpleSelectG b r (vf b))
| SourceRelationshipArrayAggregate (AnnAggregateSelectG b r (vf b))
deriving stock instance
( Backend b,
Eq (BooleanOperators b (v b)),
Eq (FunctionArgumentExp b (v b)),
Eq (v b),
Eq r
) =>
Eq (SourceRelationshipSelection b r v)
deriving stock instance
( Backend b,
Show (BooleanOperators b (v b)),
Show (FunctionArgumentExp b (v b)),
Show (v b),
Show r
) =>
Show (SourceRelationshipSelection b r v)
-- | A relationship to a remote source. 'vf' (could use a better name) is
-- analogous to 'v' in other IR types such as 'AnnFieldG'. vf's kind is
-- (BackendType -> Type) instead of v's 'Type' so that 'v' of 'AnnFieldG' can
-- be specific to the backend that it captures ('b' of an AnnFieldG changes as
-- we walk down the IR branches which capture relationships to other databases)
data
RemoteSourceSelect
(r :: Type)
(vf :: BackendType -> Type)
(tgt :: BackendType) = RemoteSourceSelect
{ _rssName :: SourceName,
_rssConfig :: SourceConfig tgt,
_rssSelection :: SourceRelationshipSelection tgt r vf,
-- | Additional information about the source's join columns:
-- (ScalarType tgt) so that the remote can interpret the join values coming
-- from src
-- (Column tgt) so that an appropriate join condition / IN clause can be built
-- by the remote
_rssJoinMapping :: (HM.HashMap FieldName (ScalarType tgt, Column tgt))
}
deriving stock instance
( Backend tgt,
Eq (BooleanOperators tgt (vf tgt)),
Eq (FunctionArgumentExp tgt (vf tgt)),
Eq (vf tgt),
Eq r
) =>
Eq (RemoteSourceSelect r vf tgt)
-- Permissions
data TablePermG (b :: BackendType) v = TablePerm
{ _tpFilter :: AnnBoolExp b v,
_tpLimit :: (Maybe Int)
}
deriving stock (Generic, Functor, Foldable, Traversable)
deriving stock instance
( Backend b,
Eq (BooleanOperators b v),
Eq (FunctionArgumentExp b v),
Eq v
) =>
Eq (TablePermG b v)
deriving stock instance
( Backend b,
Show (BooleanOperators b v),
Show (FunctionArgumentExp b v),
Show v
) =>
Show (TablePermG b v)
instance
( Backend b,
Hashable (BooleanOperators b v),
Hashable (FunctionArgumentExp b v),
Hashable (ColumnInfo b),
Hashable v
) =>
Hashable (TablePermG b v)
type TablePerm b = TablePermG b (SQLExpression b)
noTablePermissions :: TablePermG backend v
noTablePermissions = TablePerm annBoolExpTrue Nothing
-- | If argument positional index is less than or equal to length of
-- 'positional' arguments then insert the value in 'positional' arguments else
-- insert the value with argument name in 'named' arguments
insertFunctionArg ::
FunctionArgName ->
Int ->
a ->
FunctionArgsExpG a ->
FunctionArgsExpG a
insertFunctionArg argName idx value (FunctionArgsExp positional named) =
if (idx + 1) <= length positional
then FunctionArgsExp (insertAt idx value positional) named
else
FunctionArgsExp positional $
HM.insert (getFuncArgNameTxt argName) value named
where
insertAt i a = toList . Seq.insertAt i a . Seq.fromList
-- | The "distinct" input field inside "count" aggregate field
--
-- count (
-- distinct: Boolean
-- ): Int
data CountDistinct
= SelectCountDistinct
| SelectCountNonDistinct
-- Lenses
$(makeLenses ''AnnSelectG)
$(makeLenses ''AnnObjectSelectG)
$(makeLenses ''AnnRelationSelectG)
$(makeLenses ''ConnectionSelect)
$(makeLenses ''SelectArgsG)
$(makePrisms ''AnnFieldG)
$(makePrisms ''AnnotatedOrderByElement)
$(makePrisms ''TableAggregateFieldG)
$(makePrisms ''ConnectionField)
$(makePrisms ''EdgeField)