EXPLAIN
ANALYZE
IMPORT FOREIGN SCHEMA
The FDW handler function returns a palloc'd FdwRoutine
struct containing pointers to the callback functions described below.
The scan-related functions are required, the rest are optional.
The FdwRoutine
struct type is declared in
src/include/foreign/fdwapi.h
, which see for additional
details.
void GetForeignRelSize(PlannerInfo *root, RelOptInfo *baserel, Oid foreigntableid);
Obtain relation size estimates for a foreign table. This is called
at the beginning of planning for a query that scans a foreign table.
root
is the planner's global information about the query;
baserel
is the planner's information about this table; and
foreigntableid
is the pg_class
OID of the
foreign table. (foreigntableid
could be obtained from the
planner data structures, but it's passed explicitly to save effort.)
This function should update baserel->rows
to be the
expected number of rows returned by the table scan, after accounting for
the filtering done by the restriction quals. The initial value of
baserel->rows
is just a constant default estimate, which
should be replaced if at all possible. The function may also choose to
update baserel->width
if it can compute a better estimate
of the average result row width.
(The initial value is based on column data types and on column
average-width values measured by the last ANALYZE
.)
Also, this function may update baserel->tuples
if
it can compute a better estimate of the foreign table's total row count.
(The initial value is
from pg_class
.reltuples
which represents the total row count seen by the
last ANALYZE
.)
See Section 53.4 for additional information.
void GetForeignPaths(PlannerInfo *root, RelOptInfo *baserel, Oid foreigntableid);
Create possible access paths for a scan on a foreign table.
This is called during query planning.
The parameters are the same as for GetForeignRelSize
,
which has already been called.
This function must generate at least one access path
(ForeignPath
node) for a scan on the foreign table and
must call add_path
to add each such path to
baserel->pathlist
. It's recommended to use
create_foreignscan_path
to build the
ForeignPath
nodes. The function can generate multiple
access paths, e.g., a path which has valid pathkeys
to
represent a pre-sorted result. Each access path must contain cost
estimates, and can contain any FDW-private information that is needed to
identify the specific scan method intended.
See Section 53.4 for additional information.
ForeignScan * GetForeignPlan(PlannerInfo *root, RelOptInfo *baserel, Oid foreigntableid, ForeignPath *best_path, List *tlist, List *scan_clauses, Plan *outer_plan);
Create a ForeignScan
plan node from the selected foreign
access path. This is called at the end of query planning.
The parameters are as for GetForeignRelSize
, plus
the selected ForeignPath
(previously produced by
GetForeignPaths
, GetForeignJoinPaths
,
or GetForeignUpperPaths
),
the target list to be emitted by the plan node,
the restriction clauses to be enforced by the plan node,
and the outer subplan of the ForeignScan
,
which is used for rechecks performed by RecheckForeignScan
.
(If the path is for a join rather than a base
relation, foreigntableid
is InvalidOid
.)
This function must create and return a ForeignScan
plan
node; it's recommended to use make_foreignscan
to build the
ForeignScan
node.
See Section 53.4 for additional information.
void BeginForeignScan(ForeignScanState *node, int eflags);
Begin executing a foreign scan. This is called during executor startup.
It should perform any initialization needed before the scan can start,
but not start executing the actual scan (that should be done upon the
first call to IterateForeignScan
).
The ForeignScanState
node has already been created, but
its fdw_state
field is still NULL. Information about
the table to scan is accessible through the
ForeignScanState
node (in particular, from the underlying
ForeignScan
plan node, which contains any FDW-private
information provided by GetForeignPlan
).
eflags
contains flag bits describing the executor's
operating mode for this plan node.
Note that when (eflags & EXEC_FLAG_EXPLAIN_ONLY)
is
true, this function should not perform any externally-visible actions;
it should only do the minimum required to make the node state valid
for ExplainForeignScan
and EndForeignScan
.
TupleTableSlot * IterateForeignScan(ForeignScanState *node);
Fetch one row from the foreign source, returning it in a tuple table slot
(the node's ScanTupleSlot
should be used for this
purpose). Return NULL if no more rows are available. The tuple table
slot infrastructure allows either a physical or virtual tuple to be
returned; in most cases the latter choice is preferable from a
performance standpoint. Note that this is called in a short-lived memory
context that will be reset between invocations. Create a memory context
in BeginForeignScan
if you need longer-lived storage, or use
the es_query_cxt
of the node's EState
.
The rows returned must match the fdw_scan_tlist
target
list if one was supplied, otherwise they must match the row type of the
foreign table being scanned. If you choose to optimize away fetching
columns that are not needed, you should insert nulls in those column
positions, or else generate a fdw_scan_tlist
list with
those columns omitted.
Note that LightDB's executor doesn't care whether the rows returned violate any constraints that were defined on the foreign table — but the planner does care, and may optimize queries incorrectly if there are rows visible in the foreign table that do not satisfy a declared constraint. If a constraint is violated when the user has declared that the constraint should hold true, it may be appropriate to raise an error (just as you would need to do in the case of a data type mismatch).
void ReScanForeignScan(ForeignScanState *node);
Restart the scan from the beginning. Note that any parameters the scan depends on may have changed value, so the new scan does not necessarily return exactly the same rows.
void EndForeignScan(ForeignScanState *node);
End the scan and release resources. It is normally not important to release palloc'd memory, but for example open files and connections to remote servers should be cleaned up.
If an FDW supports performing foreign joins remotely (rather than by fetching both tables' data and doing the join locally), it should provide this callback function:
void GetForeignJoinPaths(PlannerInfo *root, RelOptInfo *joinrel, RelOptInfo *outerrel, RelOptInfo *innerrel, JoinType jointype, JoinPathExtraData *extra);
Create possible access paths for a join of two (or more) foreign tables
that all belong to the same foreign server. This optional
function is called during query planning. As
with GetForeignPaths
, this function should
generate ForeignPath
path(s) for the
supplied joinrel
(use create_foreign_join_path
to build them),
and call add_path
to add these
paths to the set of paths considered for the join. But unlike
GetForeignPaths
, it is not necessary that this function
succeed in creating at least one path, since paths involving local
joining are always possible.
Note that this function will be invoked repeatedly for the same join relation, with different combinations of inner and outer relations; it is the responsibility of the FDW to minimize duplicated work.
If a ForeignPath
path is chosen for the join, it will
represent the entire join process; paths generated for the component
tables and subsidiary joins will not be used. Subsequent processing of
the join path proceeds much as it does for a path scanning a single
foreign table. One difference is that the scanrelid
of
the resulting ForeignScan
plan node should be set to zero,
since there is no single relation that it represents; instead,
the fs_relids
field of the ForeignScan
node represents the set of relations that were joined. (The latter field
is set up automatically by the core planner code, and need not be filled
by the FDW.) Another difference is that, because the column list for a
remote join cannot be found from the system catalogs, the FDW must
fill fdw_scan_tlist
with an appropriate list
of TargetEntry
nodes, representing the set of columns
it will supply at run time in the tuples it returns.
See Section 53.4 for additional information.
If an FDW supports performing remote post-scan/join processing, such as remote aggregation, it should provide this callback function:
void GetForeignUpperPaths(PlannerInfo *root, UpperRelationKind stage, RelOptInfo *input_rel, RelOptInfo *output_rel, void *extra);
Create possible access paths for upper relation processing,
which is the planner's term for all post-scan/join query processing, such
as aggregation, window functions, sorting, and table updates. This
optional function is called during query planning. Currently, it is
called only if all base relation(s) involved in the query belong to the
same FDW. This function should generate ForeignPath
path(s) for any post-scan/join processing that the FDW knows how to
perform remotely
(use create_foreign_upper_path
to build them),
and call add_path
to add these paths to
the indicated upper relation. As with GetForeignJoinPaths
,
it is not necessary that this function succeed in creating any paths,
since paths involving local processing are always possible.
The stage
parameter identifies which post-scan/join step is
currently being considered. output_rel
is the upper relation
that should receive paths representing computation of this step,
and input_rel
is the relation representing the input to this
step. The extra
parameter provides additional details,
currently, it is set only for UPPERREL_PARTIAL_GROUP_AGG
or UPPERREL_GROUP_AGG
, in which case it points to a
GroupPathExtraData
structure;
or for UPPERREL_FINAL
, in which case it points to a
FinalPathExtraData
structure.
(Note that ForeignPath
paths added
to output_rel
would typically not have any direct dependency
on paths of the input_rel
, since their processing is expected
to be done externally. However, examining paths previously generated for
the previous processing step can be useful to avoid redundant planning
work.)
See Section 53.4 for additional information.
If an FDW supports writable foreign tables, it should provide some or all of the following callback functions depending on the needs and capabilities of the FDW:
void AddForeignUpdateTargets(Query *parsetree, RangeTblEntry *target_rte, Relation target_relation);
UPDATE
and DELETE
operations are performed
against rows previously fetched by the table-scanning functions. The
FDW may need extra information, such as a row ID or the values of
primary-key columns, to ensure that it can identify the exact row to
update or delete. To support that, this function can add extra hidden,
or “junk”, target columns to the list of columns that are to be
retrieved from the foreign table during an UPDATE
or
DELETE
.
To do that, add TargetEntry
items to
parsetree->targetList
, containing expressions for the
extra values to be fetched. Each such entry must be marked
resjunk
= true
, and must have a distinct
resname
that will identify it at execution time.
Avoid using names matching ctid
,
N
wholerow
, or
wholerow
, as the core system can
generate junk columns of these names.
If the extra expressions are more complex than simple Vars, they
must be run through N
eval_const_expressions
before adding them to the target list.
Although this function is called during planning, the
information provided is a bit different from that available to other
planning routines.
parsetree
is the parse tree for the UPDATE
or
DELETE
command, while target_rte
and
target_relation
describe the target foreign table.
If the AddForeignUpdateTargets
pointer is set to
NULL
, no extra target expressions are added.
(This will make it impossible to implement DELETE
operations, though UPDATE
may still be feasible if the FDW
relies on an unchanging primary key to identify rows.)
List * PlanForeignModify(PlannerInfo *root, ModifyTable *plan, Index resultRelation, int subplan_index);
Perform any additional planning actions needed for an insert, update, or
delete on a foreign table. This function generates the FDW-private
information that will be attached to the ModifyTable
plan
node that performs the update action. This private information must
have the form of a List
, and will be delivered to
BeginForeignModify
during the execution stage.
root
is the planner's global information about the query.
plan
is the ModifyTable
plan node, which is
complete except for the fdwPrivLists
field.
resultRelation
identifies the target foreign table by its
range table index. subplan_index
identifies which target of
the ModifyTable
plan node this is, counting from zero;
use this if you want to index into plan->plans
or other
substructure of the plan
node.
See Section 53.4 for additional information.
If the PlanForeignModify
pointer is set to
NULL
, no additional plan-time actions are taken, and the
fdw_private
list delivered to
BeginForeignModify
will be NIL.
void BeginForeignModify(ModifyTableState *mtstate, ResultRelInfo *rinfo, List *fdw_private, int subplan_index, int eflags);
Begin executing a foreign table modification operation. This routine is
called during executor startup. It should perform any initialization
needed prior to the actual table modifications. Subsequently,
ExecForeignInsert
, ExecForeignUpdate
or
ExecForeignDelete
will be called for each tuple to be
inserted, updated, or deleted.
mtstate
is the overall state of the
ModifyTable
plan node being executed; global data about
the plan and execution state is available via this structure.
rinfo
is the ResultRelInfo
struct describing
the target foreign table. (The ri_FdwState
field of
ResultRelInfo
is available for the FDW to store any
private state it needs for this operation.)
fdw_private
contains the private data generated by
PlanForeignModify
, if any.
subplan_index
identifies which target of
the ModifyTable
plan node this is.
eflags
contains flag bits describing the executor's
operating mode for this plan node.
Note that when (eflags & EXEC_FLAG_EXPLAIN_ONLY)
is
true, this function should not perform any externally-visible actions;
it should only do the minimum required to make the node state valid
for ExplainForeignModify
and EndForeignModify
.
If the BeginForeignModify
pointer is set to
NULL
, no action is taken during executor startup.
TupleTableSlot * ExecForeignInsert(EState *estate, ResultRelInfo *rinfo, TupleTableSlot *slot, TupleTableSlot *planSlot);
Insert one tuple into the foreign table.
estate
is global execution state for the query.
rinfo
is the ResultRelInfo
struct describing
the target foreign table.
slot
contains the tuple to be inserted; it will match the
row-type definition of the foreign table.
planSlot
contains the tuple that was generated by the
ModifyTable
plan node's subplan; it differs from
slot
in possibly containing additional “junk”
columns. (The planSlot
is typically of little interest
for INSERT
cases, but is provided for completeness.)
The return value is either a slot containing the data that was actually
inserted (this might differ from the data supplied, for example as a
result of trigger actions), or NULL if no row was actually inserted
(again, typically as a result of triggers). The passed-in
slot
can be re-used for this purpose.
The data in the returned slot is used only if the INSERT
statement has a RETURNING
clause or involves a view
WITH CHECK OPTION
; or if the foreign table has
an AFTER ROW
trigger. Triggers require all columns,
but the FDW could choose to optimize away returning some or all columns
depending on the contents of the RETURNING
clause or
WITH CHECK OPTION
constraints. Regardless, some slot
must be returned to indicate success, or the query's reported row count
will be wrong.
If the ExecForeignInsert
pointer is set to
NULL
, attempts to insert into the foreign table will fail
with an error message.
Note that this function is also called when inserting routed tuples into
a foreign-table partition or executing COPY FROM
on
a foreign table, in which case it is called in a different way than it
is in the INSERT
case. See the callback functions
described below that allow the FDW to support that.
TupleTableSlot * ExecForeignUpdate(EState *estate, ResultRelInfo *rinfo, TupleTableSlot *slot, TupleTableSlot *planSlot);
Update one tuple in the foreign table.
estate
is global execution state for the query.
rinfo
is the ResultRelInfo
struct describing
the target foreign table.
slot
contains the new data for the tuple; it will match the
row-type definition of the foreign table.
planSlot
contains the tuple that was generated by the
ModifyTable
plan node's subplan; it differs from
slot
in possibly containing additional “junk”
columns. In particular, any junk columns that were requested by
AddForeignUpdateTargets
will be available from this slot.
The return value is either a slot containing the row as it was actually
updated (this might differ from the data supplied, for example as a
result of trigger actions), or NULL if no row was actually updated
(again, typically as a result of triggers). The passed-in
slot
can be re-used for this purpose.
The data in the returned slot is used only if the UPDATE
statement has a RETURNING
clause or involves a view
WITH CHECK OPTION
; or if the foreign table has
an AFTER ROW
trigger. Triggers require all columns,
but the FDW could choose to optimize away returning some or all columns
depending on the contents of the RETURNING
clause or
WITH CHECK OPTION
constraints. Regardless, some slot
must be returned to indicate success, or the query's reported row count
will be wrong.
If the ExecForeignUpdate
pointer is set to
NULL
, attempts to update the foreign table will fail
with an error message.
TupleTableSlot * ExecForeignDelete(EState *estate, ResultRelInfo *rinfo, TupleTableSlot *slot, TupleTableSlot *planSlot);
Delete one tuple from the foreign table.
estate
is global execution state for the query.
rinfo
is the ResultRelInfo
struct describing
the target foreign table.
slot
contains nothing useful upon call, but can be used to
hold the returned tuple.
planSlot
contains the tuple that was generated by the
ModifyTable
plan node's subplan; in particular, it will
carry any junk columns that were requested by
AddForeignUpdateTargets
. The junk column(s) must be used
to identify the tuple to be deleted.
The return value is either a slot containing the row that was deleted,
or NULL if no row was deleted (typically as a result of triggers). The
passed-in slot
can be used to hold the tuple to be returned.
The data in the returned slot is used only if the DELETE
query has a RETURNING
clause or the foreign table has
an AFTER ROW
trigger. Triggers require all columns, but the
FDW could choose to optimize away returning some or all columns depending
on the contents of the RETURNING
clause. Regardless, some
slot must be returned to indicate success, or the query's reported row
count will be wrong.
If the ExecForeignDelete
pointer is set to
NULL
, attempts to delete from the foreign table will fail
with an error message.
void EndForeignModify(EState *estate, ResultRelInfo *rinfo);
End the table update and release resources. It is normally not important to release palloc'd memory, but for example open files and connections to remote servers should be cleaned up.
If the EndForeignModify
pointer is set to
NULL
, no action is taken during executor shutdown.
Tuples inserted into a partitioned table by INSERT
or
COPY FROM
are routed to partitions. If an FDW
supports routable foreign-table partitions, it should also provide the
following callback functions. These functions are also called when
COPY FROM
is executed on a foreign table.
void BeginForeignInsert(ModifyTableState *mtstate, ResultRelInfo *rinfo);
Begin executing an insert operation on a foreign table. This routine is
called right before the first tuple is inserted into the foreign table
in both cases when it is the partition chosen for tuple routing and the
target specified in a COPY FROM
command. It should
perform any initialization needed prior to the actual insertion.
Subsequently, ExecForeignInsert
will be called for
each tuple to be inserted into the foreign table.
mtstate
is the overall state of the
ModifyTable
plan node being executed; global data about
the plan and execution state is available via this structure.
rinfo
is the ResultRelInfo
struct describing
the target foreign table. (The ri_FdwState
field of
ResultRelInfo
is available for the FDW to store any
private state it needs for this operation.)
When this is called by a COPY FROM
command, the
plan-related global data in mtstate
is not provided
and the planSlot
parameter of
ExecForeignInsert
subsequently called for each
inserted tuple is NULL
, whether the foreign table is
the partition chosen for tuple routing or the target specified in the
command.
If the BeginForeignInsert
pointer is set to
NULL
, no action is taken for the initialization.
Note that if the FDW does not support routable foreign-table partitions
and/or executing COPY FROM
on foreign tables, this
function or ExecForeignInsert
subsequently called
must throw error as needed.
void EndForeignInsert(EState *estate, ResultRelInfo *rinfo);
End the insert operation and release resources. It is normally not important to release palloc'd memory, but for example open files and connections to remote servers should be cleaned up.
If the EndForeignInsert
pointer is set to
NULL
, no action is taken for the termination.
int IsForeignRelUpdatable(Relation rel);
Report which update operations the specified foreign table supports.
The return value should be a bit mask of rule event numbers indicating
which operations are supported by the foreign table, using the
CmdType
enumeration; that is,
(1 << CMD_UPDATE) = 4
for UPDATE
,
(1 << CMD_INSERT) = 8
for INSERT
, and
(1 << CMD_DELETE) = 16
for DELETE
.
If the IsForeignRelUpdatable
pointer is set to
NULL
, foreign tables are assumed to be insertable, updatable,
or deletable if the FDW provides ExecForeignInsert
,
ExecForeignUpdate
, or ExecForeignDelete
respectively. This function is only needed if the FDW supports some
tables that are updatable and some that are not. (Even then, it's
permissible to throw an error in the execution routine instead of
checking in this function. However, this function is used to determine
updatability for display in the information_schema
views.)
Some inserts, updates, and deletes to foreign tables can be optimized
by implementing an alternative set of interfaces. The ordinary
interfaces for inserts, updates, and deletes fetch rows from the remote
server and then modify those rows one at a time. In some cases, this
row-by-row approach is necessary, but it can be inefficient. If it is
possible for the foreign server to determine which rows should be
modified without actually retrieving them, and if there are no local
structures which would affect the operation (row-level local triggers,
stored generated columns, or WITH CHECK OPTION
constraints from parent views), then it is possible to arrange things
so that the entire operation is performed on the remote server. The
interfaces described below make this possible.
bool PlanDirectModify(PlannerInfo *root, ModifyTable *plan, Index resultRelation, int subplan_index);
Decide whether it is safe to execute a direct modification
on the remote server. If so, return true
after performing
planning actions needed for that. Otherwise, return false
.
This optional function is called during query planning.
If this function succeeds, BeginDirectModify
,
IterateDirectModify
and EndDirectModify
will
be called at the execution stage, instead. Otherwise, the table
modification will be executed using the table-updating functions
described above.
The parameters are the same as for PlanForeignModify
.
To execute the direct modification on the remote server, this function
must rewrite the target subplan with a ForeignScan
plan
node that executes the direct modification on the remote server. The
operation
field of the ForeignScan
must
be set to the CmdType
enumeration appropriately; that is,
CMD_UPDATE
for UPDATE
,
CMD_INSERT
for INSERT
, and
CMD_DELETE
for DELETE
.
See Section 53.4 for additional information.
If the PlanDirectModify
pointer is set to
NULL
, no attempts to execute a direct modification on the
remote server are taken.
void BeginDirectModify(ForeignScanState *node, int eflags);
Prepare to execute a direct modification on the remote server.
This is called during executor startup. It should perform any
initialization needed prior to the direct modification (that should be
done upon the first call to IterateDirectModify
).
The ForeignScanState
node has already been created, but
its fdw_state
field is still NULL. Information about
the table to modify is accessible through the
ForeignScanState
node (in particular, from the underlying
ForeignScan
plan node, which contains any FDW-private
information provided by PlanDirectModify
).
eflags
contains flag bits describing the executor's
operating mode for this plan node.
Note that when (eflags & EXEC_FLAG_EXPLAIN_ONLY)
is
true, this function should not perform any externally-visible actions;
it should only do the minimum required to make the node state valid
for ExplainDirectModify
and EndDirectModify
.
If the BeginDirectModify
pointer is set to
NULL
, no attempts to execute a direct modification on the
remote server are taken.
TupleTableSlot * IterateDirectModify(ForeignScanState *node);
When the INSERT
, UPDATE
or DELETE
query doesn't have a RETURNING
clause, just return NULL
after a direct modification on the remote server.
When the query has the clause, fetch one result containing the data
needed for the RETURNING
calculation, returning it in a
tuple table slot (the node's ScanTupleSlot
should be
used for this purpose). The data that was actually inserted, updated
or deleted must be stored in the
es_result_relation_info->ri_projectReturning->pi_exprContext->ecxt_scantuple
of the node's EState
.
Return NULL if no more rows are available.
Note that this is called in a short-lived memory context that will be
reset between invocations. Create a memory context in
BeginDirectModify
if you need longer-lived storage, or use
the es_query_cxt
of the node's EState
.
The rows returned must match the fdw_scan_tlist
target
list if one was supplied, otherwise they must match the row type of the
foreign table being updated. If you choose to optimize away fetching
columns that are not needed for the RETURNING
calculation,
you should insert nulls in those column positions, or else generate a
fdw_scan_tlist
list with those columns omitted.
Whether the query has the clause or not, the query's reported row count
must be incremented by the FDW itself. When the query doesn't have the
clause, the FDW must also increment the row count for the
ForeignScanState
node in the EXPLAIN ANALYZE
case.
If the IterateDirectModify
pointer is set to
NULL
, no attempts to execute a direct modification on the
remote server are taken.
void EndDirectModify(ForeignScanState *node);
Clean up following a direct modification on the remote server. It is normally not important to release palloc'd memory, but for example open files and connections to the remote server should be cleaned up.
If the EndDirectModify
pointer is set to
NULL
, no attempts to execute a direct modification on the
remote server are taken.
If an FDW wishes to support late row locking (as described in Section 53.5), it must provide the following callback functions:
RowMarkType GetForeignRowMarkType(RangeTblEntry *rte, LockClauseStrength strength);
Report which row-marking option to use for a foreign table.
rte
is the RangeTblEntry
node for the table
and strength
describes the lock strength requested by the
relevant FOR UPDATE/SHARE
clause, if any. The result must be
a member of the RowMarkType
enum type.
This function is called during query planning for each foreign table that
appears in an UPDATE
, DELETE
, or SELECT
FOR UPDATE/SHARE
query and is not the target of UPDATE
or DELETE
.
If the GetForeignRowMarkType
pointer is set to
NULL
, the ROW_MARK_COPY
option is always used.
(This implies that RefetchForeignRow
will never be called,
so it need not be provided either.)
See Section 53.5 for more information.
void RefetchForeignRow(EState *estate, ExecRowMark *erm, Datum rowid, TupleTableSlot *slot, bool *updated);
Re-fetch one tuple slot from the foreign table, after locking it if required.
estate
is global execution state for the query.
erm
is the ExecRowMark
struct describing
the target foreign table and the row lock type (if any) to acquire.
rowid
identifies the tuple to be fetched.
slot
contains nothing useful upon call, but can be used to
hold the returned tuple. updated
is an output parameter.
This function should store the tuple into the provided slot, or clear it if
the row lock couldn't be obtained. The row lock type to acquire is
defined by erm->markType
, which is the value
previously returned by GetForeignRowMarkType
.
(ROW_MARK_REFERENCE
means to just re-fetch the tuple
without acquiring any lock, and ROW_MARK_COPY
will
never be seen by this routine.)
In addition, *updated
should be set to true
if what was fetched was an updated version of the tuple rather than
the same version previously obtained. (If the FDW cannot be sure about
this, always returning true
is recommended.)
Note that by default, failure to acquire a row lock should result in
raising an error; returning with an empty slot is only appropriate if
the SKIP LOCKED
option is specified
by erm->waitPolicy
.
The rowid
is the ctid
value previously read
for the row to be re-fetched. Although the rowid
value is
passed as a Datum
, it can currently only be a tid
. The
function API is chosen in hopes that it may be possible to allow other
data types for row IDs in future.
If the RefetchForeignRow
pointer is set to
NULL
, attempts to re-fetch rows will fail
with an error message.
See Section 53.5 for more information.
bool RecheckForeignScan(ForeignScanState *node, TupleTableSlot *slot);
Recheck that a previously-returned tuple still matches the relevant
scan and join qualifiers, and possibly provide a modified version of
the tuple. For foreign data wrappers which do not perform join pushdown,
it will typically be more convenient to set this to NULL
and
instead set fdw_recheck_quals
appropriately.
When outer joins are pushed down, however, it isn't sufficient to
reapply the checks relevant to all the base tables to the result tuple,
even if all needed attributes are present, because failure to match some
qualifier might result in some attributes going to NULL, rather than in
no tuple being returned. RecheckForeignScan
can recheck
qualifiers and return true if they are still satisfied and false
otherwise, but it can also store a replacement tuple into the supplied
slot.
To implement join pushdown, a foreign data wrapper will typically
construct an alternative local join plan which is used only for
rechecks; this will become the outer subplan of the
ForeignScan
. When a recheck is required, this subplan
can be executed and the resulting tuple can be stored in the slot.
This plan need not be efficient since no base table will return more
than one row; for example, it may implement all joins as nested loops.
The function GetExistingLocalJoinPath
may be used to search
existing paths for a suitable local join path, which can be used as the
alternative local join plan. GetExistingLocalJoinPath
searches for an unparameterized path in the path list of the specified
join relation. (If it does not find such a path, it returns NULL, in
which case a foreign data wrapper may build the local path by itself or
may choose not to create access paths for that join.)
EXPLAIN
void ExplainForeignScan(ForeignScanState *node, ExplainState *es);
Print additional EXPLAIN
output for a foreign table scan.
This function can call ExplainPropertyText
and
related functions to add fields to the EXPLAIN
output.
The flag fields in es
can be used to determine what to
print, and the state of the ForeignScanState
node
can be inspected to provide run-time statistics in the EXPLAIN
ANALYZE
case.
If the ExplainForeignScan
pointer is set to
NULL
, no additional information is printed during
EXPLAIN
.
void ExplainForeignModify(ModifyTableState *mtstate, ResultRelInfo *rinfo, List *fdw_private, int subplan_index, struct ExplainState *es);
Print additional EXPLAIN
output for a foreign table update.
This function can call ExplainPropertyText
and
related functions to add fields to the EXPLAIN
output.
The flag fields in es
can be used to determine what to
print, and the state of the ModifyTableState
node
can be inspected to provide run-time statistics in the EXPLAIN
ANALYZE
case. The first four arguments are the same as for
BeginForeignModify
.
If the ExplainForeignModify
pointer is set to
NULL
, no additional information is printed during
EXPLAIN
.
void ExplainDirectModify(ForeignScanState *node, ExplainState *es);
Print additional EXPLAIN
output for a direct modification
on the remote server.
This function can call ExplainPropertyText
and
related functions to add fields to the EXPLAIN
output.
The flag fields in es
can be used to determine what to
print, and the state of the ForeignScanState
node
can be inspected to provide run-time statistics in the EXPLAIN
ANALYZE
case.
If the ExplainDirectModify
pointer is set to
NULL
, no additional information is printed during
EXPLAIN
.
ANALYZE
bool AnalyzeForeignTable(Relation relation, AcquireSampleRowsFunc *func, BlockNumber *totalpages);
This function is called when ANALYZE is executed on
a foreign table. If the FDW can collect statistics for this
foreign table, it should return true
, and provide a pointer
to a function that will collect sample rows from the table in
func
, plus the estimated size of the table in pages in
totalpages
. Otherwise, return false
.
If the FDW does not support collecting statistics for any tables, the
AnalyzeForeignTable
pointer can be set to NULL
.
If provided, the sample collection function must have the signature
int AcquireSampleRowsFunc(Relation relation, int elevel, HeapTuple *rows, int targrows, double *totalrows, double *totaldeadrows);
A random sample of up to targrows
rows should be collected
from the table and stored into the caller-provided rows
array. The actual number of rows collected must be returned. In
addition, store estimates of the total numbers of live and dead rows in
the table into the output parameters totalrows
and
totaldeadrows
. (Set totaldeadrows
to zero
if the FDW does not have any concept of dead rows.)
IMPORT FOREIGN SCHEMA
List * ImportForeignSchema(ImportForeignSchemaStmt *stmt, Oid serverOid);
Obtain a list of foreign table creation commands. This function is called when executing IMPORT FOREIGN SCHEMA, and is passed the parse tree for that statement, as well as the OID of the foreign server to use. It should return a list of C strings, each of which must contain a CREATE FOREIGN TABLE command. These strings will be parsed and executed by the core server.
Within the ImportForeignSchemaStmt
struct,
remote_schema
is the name of the remote schema from
which tables are to be imported.
list_type
identifies how to filter table names:
FDW_IMPORT_SCHEMA_ALL
means that all tables in the remote
schema should be imported (in this case table_list
is
empty), FDW_IMPORT_SCHEMA_LIMIT_TO
means to include only
tables listed in table_list
,
and FDW_IMPORT_SCHEMA_EXCEPT
means to exclude the tables
listed in table_list
.
options
is a list of options used for the import process.
The meanings of the options are up to the FDW.
For example, an FDW could use an option to define whether the
NOT NULL
attributes of columns should be imported.
These options need not have anything to do with those supported by the
FDW as database object options.
The FDW may ignore the local_schema
field of
the ImportForeignSchemaStmt
, because the core server
will automatically insert that name into the parsed CREATE
FOREIGN TABLE
commands.
The FDW does not have to concern itself with implementing the filtering
specified by list_type
and table_list
,
either, as the core server will automatically skip any returned commands
for tables excluded according to those options. However, it's often
useful to avoid the work of creating commands for excluded tables in the
first place. The function IsImportableForeignTable()
may be
useful to test whether a given foreign-table name will pass the filter.
If the FDW does not support importing table definitions, the
ImportForeignSchema
pointer can be set to NULL
.
A ForeignScan
node can, optionally, support parallel
execution. A parallel ForeignScan
will be executed
in multiple processes and must return each row exactly once across
all cooperating processes. To do this, processes can coordinate through
fixed-size chunks of dynamic shared memory. This shared memory is not
guaranteed to be mapped at the same address in every process, so it
must not contain pointers. The following functions are all optional,
but most are required if parallel execution is to be supported.
bool IsForeignScanParallelSafe(PlannerInfo *root, RelOptInfo *rel, RangeTblEntry *rte);
Test whether a scan can be performed within a parallel worker. This function will only be called when the planner believes that a parallel plan might be possible, and should return true if it is safe for that scan to run within a parallel worker. This will generally not be the case if the remote data source has transaction semantics, unless the worker's connection to the data can somehow be made to share the same transaction context as the leader.
If this function is not defined, it is assumed that the scan must take place within the parallel leader. Note that returning true does not mean that the scan itself can be done in parallel, only that the scan can be performed within a parallel worker. Therefore, it can be useful to define this method even when parallel execution is not supported.
Size EstimateDSMForeignScan(ForeignScanState *node, ParallelContext *pcxt);
Estimate the amount of dynamic shared memory that will be required for parallel operation. This may be higher than the amount that will actually be used, but it must not be lower. The return value is in bytes. This function is optional, and can be omitted if not needed; but if it is omitted, the next three functions must be omitted as well, because no shared memory will be allocated for the FDW's use.
void InitializeDSMForeignScan(ForeignScanState *node, ParallelContext *pcxt, void *coordinate);
Initialize the dynamic shared memory that will be required for parallel
operation. coordinate
points to a shared memory area of
size equal to the return value of EstimateDSMForeignScan
.
This function is optional, and can be omitted if not needed.
void ReInitializeDSMForeignScan(ForeignScanState *node, ParallelContext *pcxt, void *coordinate);
Re-initialize the dynamic shared memory required for parallel operation
when the foreign-scan plan node is about to be re-scanned.
This function is optional, and can be omitted if not needed.
Recommended practice is that this function reset only shared state,
while the ReScanForeignScan
function resets only local
state. Currently, this function will be called
before ReScanForeignScan
, but it's best not to rely on
that ordering.
void InitializeWorkerForeignScan(ForeignScanState *node, shm_toc *toc, void *coordinate);
Initialize a parallel worker's local state based on the shared state
set up by the leader during InitializeDSMForeignScan
.
This function is optional, and can be omitted if not needed.
void ShutdownForeignScan(ForeignScanState *node);
Release resources when it is anticipated the node will not be executed
to completion. This is not called in all cases; sometimes,
EndForeignScan
may be called without this function having
been called first. Since the DSM segment used by parallel query is
destroyed just after this callback is invoked, foreign data wrappers that
wish to take some action before the DSM segment goes away should implement
this method.
List * ReparameterizeForeignPathByChild(PlannerInfo *root, List *fdw_private, RelOptInfo *child_rel);
This function is called while converting a path parameterized by the
top-most parent of the given child relation child_rel
to be
parameterized by the child relation. The function is used to reparameterize
any paths or translate any expression nodes saved in the given
fdw_private
member of a ForeignPath
. The
callback may use reparameterize_path_by_child
,
adjust_appendrel_attrs
or
adjust_appendrel_attrs_multilevel
as required.