-- -- SUBSELECT -- SELECT 1 AS one WHERE 1 IN (SELECT 1); SELECT 1 AS zero WHERE 1 NOT IN (SELECT 1); SELECT 1 AS zero WHERE 1 IN (SELECT 2); -- Check grammar's handling of extra parens in assorted contexts SELECT * FROM (SELECT 1 AS x) ss; SELECT * FROM ((SELECT 1 AS x)) ss; SELECT * FROM ((SELECT 1 AS x)), ((SELECT * FROM ((SELECT 2 AS y)))); (SELECT 2) UNION SELECT 2; ((SELECT 2)) UNION SELECT 2; SELECT ((SELECT 2) UNION SELECT 2); SELECT (((SELECT 2)) UNION SELECT 2); SELECT (SELECT ARRAY[1,2,3])[1]; SELECT ((SELECT ARRAY[1,2,3]))[2]; SELECT (((SELECT ARRAY[1,2,3])))[3]; -- Set up some simple test tables CREATE TABLE SUBSELECT_TBL ( f1 integer, f2 integer, f3 float ); INSERT INTO SUBSELECT_TBL VALUES (1, 2, 3); INSERT INTO SUBSELECT_TBL VALUES (2, 3, 4); INSERT INTO SUBSELECT_TBL VALUES (3, 4, 5); INSERT INTO SUBSELECT_TBL VALUES (1, 1, 1); INSERT INTO SUBSELECT_TBL VALUES (2, 2, 2); INSERT INTO SUBSELECT_TBL VALUES (3, 3, 3); INSERT INTO SUBSELECT_TBL VALUES (6, 7, 8); INSERT INTO SUBSELECT_TBL VALUES (8, 9, NULL); SELECT * FROM SUBSELECT_TBL; -- Uncorrelated subselects SELECT f1 AS "Constant Select" FROM SUBSELECT_TBL WHERE f1 IN (SELECT 1); SELECT f1 AS "Uncorrelated Field" FROM SUBSELECT_TBL WHERE f1 IN (SELECT f2 FROM SUBSELECT_TBL); SELECT f1 AS "Uncorrelated Field" FROM SUBSELECT_TBL WHERE f1 IN (SELECT f2 FROM SUBSELECT_TBL WHERE f2 IN (SELECT f1 FROM SUBSELECT_TBL)); SELECT f1, f2 FROM SUBSELECT_TBL WHERE (f1, f2) NOT IN (SELECT f2, CAST(f3 AS int4) FROM SUBSELECT_TBL WHERE f3 IS NOT NULL); -- Correlated subselects SELECT f1 AS "Correlated Field", f2 AS "Second Field" FROM SUBSELECT_TBL upper WHERE f1 IN (SELECT f2 FROM SUBSELECT_TBL WHERE f1 = upper.f1); SELECT f1 AS "Correlated Field", f3 AS "Second Field" FROM SUBSELECT_TBL upper WHERE f1 IN (SELECT f2 FROM SUBSELECT_TBL WHERE CAST(upper.f2 AS float) = f3); SELECT f1 AS "Correlated Field", f3 AS "Second Field" FROM SUBSELECT_TBL upper WHERE f3 IN (SELECT upper.f1 + f2 FROM SUBSELECT_TBL WHERE f2 = CAST(f3 AS integer)); SELECT f1 AS "Correlated Field" FROM SUBSELECT_TBL WHERE (f1, f2) IN (SELECT f2, CAST(f3 AS int4) FROM SUBSELECT_TBL WHERE f3 IS NOT NULL); -- Check ROWCOMPARE cases, both correlated and not EXPLAIN (VERBOSE, COSTS OFF) SELECT ROW(1, 2) = (SELECT f1, f2) AS eq FROM SUBSELECT_TBL; SELECT ROW(1, 2) = (SELECT f1, f2) AS eq FROM SUBSELECT_TBL; EXPLAIN (VERBOSE, COSTS OFF) SELECT ROW(1, 2) = (SELECT 3, 4) AS eq FROM SUBSELECT_TBL; SELECT ROW(1, 2) = (SELECT 3, 4) AS eq FROM SUBSELECT_TBL; SELECT ROW(1, 2) = (SELECT f1, f2 FROM SUBSELECT_TBL); -- error -- Subselects without aliases SELECT count FROM (SELECT COUNT(DISTINCT name) FROM road); SELECT COUNT(*) FROM (SELECT DISTINCT name FROM road); SELECT * FROM (SELECT * FROM int4_tbl), (VALUES (123456)) WHERE f1 = column1; CREATE VIEW view_unnamed_ss AS SELECT * FROM (SELECT * FROM (SELECT abs(f1) AS a1 FROM int4_tbl)), (SELECT * FROM int8_tbl) WHERE a1 < 10 AND q1 > a1 ORDER BY q1, q2; SELECT * FROM view_unnamed_ss; \sv view_unnamed_ss DROP VIEW view_unnamed_ss; -- Test matching of locking clause to correct alias CREATE VIEW view_unnamed_ss_locking AS SELECT * FROM (SELECT * FROM int4_tbl), int8_tbl AS unnamed_subquery WHERE f1 = q1 FOR UPDATE OF unnamed_subquery; \sv view_unnamed_ss_locking DROP VIEW view_unnamed_ss_locking; -- -- Use some existing tables in the regression test -- SELECT ss.f1 AS "Correlated Field", ss.f3 AS "Second Field" FROM SUBSELECT_TBL ss WHERE f1 NOT IN (SELECT f1+1 FROM INT4_TBL WHERE f1 != ss.f1 AND f1 < 2147483647); select q1, float8(count(*)) / (select count(*) from int8_tbl) from int8_tbl group by q1 order by q1; -- Unspecified-type literals in output columns should resolve as text SELECT *, pg_typeof(f1) FROM (SELECT 'foo' AS f1 FROM generate_series(1,3)) ss ORDER BY 1; -- ... unless there's context to suggest differently explain (verbose, costs off) select '42' union all select '43'; explain (verbose, costs off) select '42' union all select 43; -- check materialization of an initplan reference (bug #14524) explain (verbose, costs off) select 1 = all (select (select 1)); select 1 = all (select (select 1)); -- -- Check EXISTS simplification with LIMIT -- explain (costs off) select * from int4_tbl o where exists (select 1 from int4_tbl i where i.f1=o.f1 limit null); explain (costs off) select * from int4_tbl o where not exists (select 1 from int4_tbl i where i.f1=o.f1 limit 1); explain (costs off) select * from int4_tbl o where exists (select 1 from int4_tbl i where i.f1=o.f1 limit 0); -- -- Test cases to catch unpleasant interactions between IN-join processing -- and subquery pullup. -- select count(*) from (select 1 from tenk1 a where unique1 IN (select hundred from tenk1 b)) ss; select count(distinct ss.ten) from (select ten from tenk1 a where unique1 IN (select hundred from tenk1 b)) ss; select count(*) from (select 1 from tenk1 a where unique1 IN (select distinct hundred from tenk1 b)) ss; select count(distinct ss.ten) from (select ten from tenk1 a where unique1 IN (select distinct hundred from tenk1 b)) ss; -- -- Test cases to check for overenthusiastic optimization of -- "IN (SELECT DISTINCT ...)" and related cases. Per example from -- Luca Pireddu and Michael Fuhr. -- CREATE TEMP TABLE foo (id integer); CREATE TEMP TABLE bar (id1 integer, id2 integer); INSERT INTO foo VALUES (1); INSERT INTO bar VALUES (1, 1); INSERT INTO bar VALUES (2, 2); INSERT INTO bar VALUES (3, 1); -- These cases require an extra level of distinct-ing above subquery s SELECT * FROM foo WHERE id IN (SELECT id2 FROM (SELECT DISTINCT id1, id2 FROM bar) AS s); SELECT * FROM foo WHERE id IN (SELECT id2 FROM (SELECT id1,id2 FROM bar GROUP BY id1,id2) AS s); SELECT * FROM foo WHERE id IN (SELECT id2 FROM (SELECT id1, id2 FROM bar UNION SELECT id1, id2 FROM bar) AS s); -- These cases do not SELECT * FROM foo WHERE id IN (SELECT id2 FROM (SELECT DISTINCT ON (id2) id1, id2 FROM bar) AS s); SELECT * FROM foo WHERE id IN (SELECT id2 FROM (SELECT id2 FROM bar GROUP BY id2) AS s); SELECT * FROM foo WHERE id IN (SELECT id2 FROM (SELECT id2 FROM bar UNION SELECT id2 FROM bar) AS s); -- -- Test case to catch problems with multiply nested sub-SELECTs not getting -- recalculated properly. Per bug report from Didier Moens. -- CREATE TABLE orderstest ( approver_ref integer, po_ref integer, ordercanceled boolean ); INSERT INTO orderstest VALUES (1, 1, false); INSERT INTO orderstest VALUES (66, 5, false); INSERT INTO orderstest VALUES (66, 6, false); INSERT INTO orderstest VALUES (66, 7, false); INSERT INTO orderstest VALUES (66, 1, true); INSERT INTO orderstest VALUES (66, 8, false); INSERT INTO orderstest VALUES (66, 1, false); INSERT INTO orderstest VALUES (77, 1, false); INSERT INTO orderstest VALUES (1, 1, false); INSERT INTO orderstest VALUES (66, 1, false); INSERT INTO orderstest VALUES (1, 1, false); CREATE VIEW orders_view AS SELECT *, (SELECT CASE WHEN ord.approver_ref=1 THEN '---' ELSE 'Approved' END) AS "Approved", (SELECT CASE WHEN ord.ordercanceled THEN 'Canceled' ELSE (SELECT CASE WHEN ord.po_ref=1 THEN (SELECT CASE WHEN ord.approver_ref=1 THEN '---' ELSE 'Approved' END) ELSE 'PO' END) END) AS "Status", (CASE WHEN ord.ordercanceled THEN 'Canceled' ELSE (CASE WHEN ord.po_ref=1 THEN (CASE WHEN ord.approver_ref=1 THEN '---' ELSE 'Approved' END) ELSE 'PO' END) END) AS "Status_OK" FROM orderstest ord; SELECT * FROM orders_view; DROP TABLE orderstest cascade; -- -- Test cases to catch situations where rule rewriter fails to propagate -- hasSubLinks flag correctly. Per example from Kyle Bateman. -- create temp table parts ( partnum text, cost float8 ); create temp table shipped ( ttype char(2), ordnum int4, partnum text, value float8 ); create temp view shipped_view as select * from shipped where ttype = 'wt'; create rule shipped_view_insert as on insert to shipped_view do instead insert into shipped values('wt', new.ordnum, new.partnum, new.value); insert into parts (partnum, cost) values (1, 1234.56); insert into shipped_view (ordnum, partnum, value) values (0, 1, (select cost from parts where partnum = '1')); select * from shipped_view; create rule shipped_view_update as on update to shipped_view do instead update shipped set partnum = new.partnum, value = new.value where ttype = new.ttype and ordnum = new.ordnum; update shipped_view set value = 11 from int4_tbl a join int4_tbl b on (a.f1 = (select f1 from int4_tbl c where c.f1=b.f1)) where ordnum = a.f1; select * from shipped_view; select f1, ss1 as relabel from (select *, (select sum(f1) from int4_tbl b where f1 >= a.f1) as ss1 from int4_tbl a) ss; -- -- Test cases involving PARAM_EXEC parameters and min/max index optimizations. -- Per bug report from David Sanchez i Gregori. -- select * from ( select max(unique1) from tenk1 as a where exists (select 1 from tenk1 as b where b.thousand = a.unique2) ) ss; select * from ( select min(unique1) from tenk1 as a where not exists (select 1 from tenk1 as b where b.unique2 = 10000) ) ss; -- -- Test that an IN implemented using a UniquePath does unique-ification -- with the right semantics, as per bug #4113. (Unfortunately we have -- no simple way to ensure that this test case actually chooses that type -- of plan, but it does in releases 7.4-8.3. Note that an ordering difference -- here might mean that some other plan type is being used, rendering the test -- pointless.) -- create temp table numeric_table (num_col numeric); insert into numeric_table values (1), (1.000000000000000000001), (2), (3); create temp table float_table (float_col float8); insert into float_table values (1), (2), (3); select * from float_table where float_col in (select num_col from numeric_table); select * from numeric_table where num_col in (select float_col from float_table); -- -- Test case for bug #4290: bogus calculation of subplan param sets -- create temp table ta (id int primary key, val int); insert into ta values(1,1); insert into ta values(2,2); create temp table tb (id int primary key, aval int); insert into tb values(1,1); insert into tb values(2,1); insert into tb values(3,2); insert into tb values(4,2); create temp table tc (id int primary key, aid int); insert into tc values(1,1); insert into tc values(2,2); select ( select min(tb.id) from tb where tb.aval = (select ta.val from ta where ta.id = tc.aid) ) as min_tb_id from tc; -- -- Test case for 8.3 "failed to locate grouping columns" bug -- create temp table t1 (f1 numeric(14,0), f2 varchar(30)); select * from (select distinct f1, f2, (select f2 from t1 x where x.f1 = up.f1) as fs from t1 up) ss group by f1,f2,fs; -- -- Test case for bug #5514 (mishandling of whole-row Vars in subselects) -- create temp table table_a(id integer); insert into table_a values (42); create temp view view_a as select * from table_a; select view_a from view_a; select (select view_a) from view_a; select (select (select view_a)) from view_a; select (select (a.*)::text) from view_a a; -- -- Check that whole-row Vars reading the result of a subselect don't include -- any junk columns therein -- select q from (select max(f1) from int4_tbl group by f1 order by f1) q; with q as (select max(f1) from int4_tbl group by f1 order by f1) select q from q; -- -- Test case for sublinks pulled up into joinaliasvars lists in an -- inherited update/delete query -- begin; -- this shouldn't delete anything, but be safe delete from road where exists ( select 1 from int4_tbl cross join ( select f1, array(select q1 from int8_tbl) as arr from text_tbl ) ss where road.name = ss.f1 ); rollback; -- -- Test case for sublinks pushed down into subselects via join alias expansion -- select (select sq1) as qq1 from (select exists(select 1 from int4_tbl where f1 = q2) as sq1, 42 as dummy from int8_tbl) sq0 join int4_tbl i4 on dummy = i4.f1; -- -- Test case for subselect within UPDATE of INSERT...ON CONFLICT DO UPDATE -- create temp table upsert(key int4 primary key, val text); insert into upsert values(1, 'val') on conflict (key) do update set val = 'not seen'; insert into upsert values(1, 'val') on conflict (key) do update set val = 'seen with subselect ' || (select f1 from int4_tbl where f1 != 0 limit 1)::text; select * from upsert; with aa as (select 'int4_tbl' u from int4_tbl limit 1) insert into upsert values (1, 'x'), (999, 'y') on conflict (key) do update set val = (select u from aa) returning *; -- -- Test case for cross-type partial matching in hashed subplan (bug #7597) -- create temp table outer_7597 (f1 int4, f2 int4); insert into outer_7597 values (0, 0); insert into outer_7597 values (1, 0); insert into outer_7597 values (0, null); insert into outer_7597 values (1, null); create temp table inner_7597(c1 int8, c2 int8); insert into inner_7597 values(0, null); select * from outer_7597 where (f1, f2) not in (select * from inner_7597); -- -- Similar test case using text that verifies that collation -- information is passed through by execTuplesEqual() in nodeSubplan.c -- (otherwise it would error in texteq()) -- create temp table outer_text (f1 text, f2 text); insert into outer_text values ('a', 'a'); insert into outer_text values ('b', 'a'); insert into outer_text values ('a', null); insert into outer_text values ('b', null); create temp table inner_text (c1 text, c2 text); insert into inner_text values ('a', null); insert into inner_text values ('123', '456'); select * from outer_text where (f1, f2) not in (select * from inner_text); -- -- Another test case for cross-type hashed subplans: comparison of -- inner-side values must be done with appropriate operator -- explain (verbose, costs off) select 'foo'::text in (select 'bar'::name union all select 'bar'::name); select 'foo'::text in (select 'bar'::name union all select 'bar'::name); -- -- Test that we don't try to hash nested records (bug #17363) -- (Hashing could be supported, but for now we don't) -- explain (verbose, costs off) select row(row(row(1))) = any (select row(row(1))); select row(row(row(1))) = any (select row(row(1))); -- -- Test case for premature memory release during hashing of subplan output -- select '1'::text in (select '1'::name union all select '1'::name); -- -- Test that we don't try to use a hashed subplan if the simplified -- testexpr isn't of the right shape -- -- this fails by default, of course select * from int8_tbl where q1 in (select c1 from inner_text); begin; -- make an operator to allow it to succeed create function bogus_int8_text_eq(int8, text) returns boolean language sql as 'select $1::text = $2'; create operator = (procedure=bogus_int8_text_eq, leftarg=int8, rightarg=text); explain (costs off) select * from int8_tbl where q1 in (select c1 from inner_text); select * from int8_tbl where q1 in (select c1 from inner_text); -- inlining of this function results in unusual number of hash clauses, -- which we can still cope with create or replace function bogus_int8_text_eq(int8, text) returns boolean language sql as 'select $1::text = $2 and $1::text = $2'; explain (costs off) select * from int8_tbl where q1 in (select c1 from inner_text); select * from int8_tbl where q1 in (select c1 from inner_text); -- inlining of this function causes LHS and RHS to be switched, -- which we can't cope with, so hashing should be abandoned create or replace function bogus_int8_text_eq(int8, text) returns boolean language sql as 'select $2 = $1::text'; explain (costs off) select * from int8_tbl where q1 in (select c1 from inner_text); select * from int8_tbl where q1 in (select c1 from inner_text); rollback; -- to get rid of the bogus operator -- -- Test resolution of hashed vs non-hashed implementation of EXISTS subplan -- explain (costs off) select count(*) from tenk1 t where (exists(select 1 from tenk1 k where k.unique1 = t.unique2) or ten < 0); select count(*) from tenk1 t where (exists(select 1 from tenk1 k where k.unique1 = t.unique2) or ten < 0); explain (costs off) select count(*) from tenk1 t where (exists(select 1 from tenk1 k where k.unique1 = t.unique2) or ten < 0) and thousand = 1; select count(*) from tenk1 t where (exists(select 1 from tenk1 k where k.unique1 = t.unique2) or ten < 0) and thousand = 1; -- It's possible for the same EXISTS to get resolved both ways create temp table exists_tbl (c1 int, c2 int, c3 int) partition by list (c1); create temp table exists_tbl_null partition of exists_tbl for values in (null); create temp table exists_tbl_def partition of exists_tbl default; insert into exists_tbl select x, x/2, x+1 from generate_series(0,10) x; analyze exists_tbl; explain (costs off) select * from exists_tbl t1 where (exists(select 1 from exists_tbl t2 where t1.c1 = t2.c2) or c3 < 0); select * from exists_tbl t1 where (exists(select 1 from exists_tbl t2 where t1.c1 = t2.c2) or c3 < 0); -- -- Test case for planner bug with nested EXISTS handling -- select a.thousand from tenk1 a, tenk1 b where a.thousand = b.thousand and exists ( select 1 from tenk1 c where b.hundred = c.hundred and not exists ( select 1 from tenk1 d where a.thousand = d.thousand ) ); -- -- Check that nested sub-selects are not pulled up if they contain volatiles -- explain (verbose, costs off) select x, x from (select (select now()) as x from (values(1),(2)) v(y)) ss; explain (verbose, costs off) select x, x from (select (select random()) as x from (values(1),(2)) v(y)) ss; explain (verbose, costs off) select x, x from (select (select now() where y=y) as x from (values(1),(2)) v(y)) ss; explain (verbose, costs off) select x, x from (select (select random() where y=y) as x from (values(1),(2)) v(y)) ss; -- -- Test rescan of a hashed subplan (the use of random() is to prevent the -- sub-select from being pulled up, which would result in not hashing) -- explain (verbose, costs off) select sum(ss.tst::int) from onek o cross join lateral ( select i.ten in (select f1 from int4_tbl where f1 <= o.hundred) as tst, random() as r from onek i where i.unique1 = o.unique1 ) ss where o.ten = 0; select sum(ss.tst::int) from onek o cross join lateral ( select i.ten in (select f1 from int4_tbl where f1 <= o.hundred) as tst, random() as r from onek i where i.unique1 = o.unique1 ) ss where o.ten = 0; -- -- Test rescan of a SetOp node -- explain (costs off) select count(*) from onek o cross join lateral ( select * from onek i1 where i1.unique1 = o.unique1 except select * from onek i2 where i2.unique1 = o.unique2 ) ss where o.ten = 1; select count(*) from onek o cross join lateral ( select * from onek i1 where i1.unique1 = o.unique1 except select * from onek i2 where i2.unique1 = o.unique2 ) ss where o.ten = 1; -- -- Test rescan of a RecursiveUnion node -- explain (costs off) select sum(o.four), sum(ss.a) from onek o cross join lateral ( with recursive x(a) as (select o.four as a union select a + 1 from x where a < 10) select * from x ) ss where o.ten = 1; select sum(o.four), sum(ss.a) from onek o cross join lateral ( with recursive x(a) as (select o.four as a union select a + 1 from x where a < 10) select * from x ) ss where o.ten = 1; -- -- Check we don't misoptimize a NOT IN where the subquery returns no rows. -- create temp table notinouter (a int); create temp table notininner (b int not null); insert into notinouter values (null), (1); select * from notinouter where a not in (select b from notininner); -- -- Check we behave sanely in corner case of empty SELECT list (bug #8648) -- create temp table nocolumns(); select exists(select * from nocolumns); -- -- Check behavior with a SubPlan in VALUES (bug #14924) -- select val.x from generate_series(1,10) as s(i), lateral ( values ((select s.i + 1)), (s.i + 101) ) as val(x) where s.i < 10 and (select val.x) < 110; -- another variant of that (bug #16213) explain (verbose, costs off) select * from (values (3 not in (select * from (values (1), (2)) ss1)), (false) ) ss; select * from (values (3 not in (select * from (values (1), (2)) ss1)), (false) ) ss; -- -- Check sane behavior with nested IN SubLinks -- explain (verbose, costs off) select * from int4_tbl where (case when f1 in (select unique1 from tenk1 a) then f1 else null end) in (select ten from tenk1 b); select * from int4_tbl where (case when f1 in (select unique1 from tenk1 a) then f1 else null end) in (select ten from tenk1 b); -- -- Check for incorrect optimization when IN subquery contains a SRF -- explain (verbose, costs off) select * from int4_tbl o where (f1, f1) in (select f1, generate_series(1,50) / 10 g from int4_tbl i group by f1); select * from int4_tbl o where (f1, f1) in (select f1, generate_series(1,50) / 10 g from int4_tbl i group by f1); -- -- check for over-optimization of whole-row Var referencing an Append plan -- select (select q from (select 1,2,3 where f1 > 0 union all select 4,5,6.0 where f1 <= 0 ) q ) from int4_tbl; -- -- Check for sane handling of a lateral reference in a subquery's quals -- (most of the complication here is to prevent the test case from being -- flattened too much) -- explain (verbose, costs off) select * from int4_tbl i4, lateral ( select i4.f1 > 1 as b, 1 as id from (select random() order by 1) as t1 union all select true as b, 2 as id ) as t2 where b and f1 >= 0; select * from int4_tbl i4, lateral ( select i4.f1 > 1 as b, 1 as id from (select random() order by 1) as t1 union all select true as b, 2 as id ) as t2 where b and f1 >= 0; -- -- Check that volatile quals aren't pushed down past a DISTINCT: -- nextval() should not be called more than the nominal number of times -- create temp sequence ts1; select * from (select distinct ten from tenk1) ss where ten < 10 + nextval('ts1') order by 1; select nextval('ts1'); -- -- Check that volatile quals aren't pushed down past a set-returning function; -- while a nonvolatile qual can be, if it doesn't reference the SRF. -- create function tattle(x int, y int) returns bool volatile language plpgsql as $$ begin raise notice 'x = %, y = %', x, y; return x > y; end$$; explain (verbose, costs off) select * from (select 9 as x, unnest(array[1,2,3,11,12,13]) as u) ss where tattle(x, 8); select * from (select 9 as x, unnest(array[1,2,3,11,12,13]) as u) ss where tattle(x, 8); -- if we pretend it's stable, we get different results: alter function tattle(x int, y int) stable; explain (verbose, costs off) select * from (select 9 as x, unnest(array[1,2,3,11,12,13]) as u) ss where tattle(x, 8); select * from (select 9 as x, unnest(array[1,2,3,11,12,13]) as u) ss where tattle(x, 8); -- although even a stable qual should not be pushed down if it references SRF explain (verbose, costs off) select * from (select 9 as x, unnest(array[1,2,3,11,12,13]) as u) ss where tattle(x, u); select * from (select 9 as x, unnest(array[1,2,3,11,12,13]) as u) ss where tattle(x, u); drop function tattle(x int, y int); -- -- Test that LIMIT can be pushed to SORT through a subquery that just projects -- columns. We check for that having happened by looking to see if EXPLAIN -- ANALYZE shows that a top-N sort was used. We must suppress or filter away -- all the non-invariant parts of the EXPLAIN ANALYZE output. -- create table sq_limit (pk int primary key, c1 int, c2 int); insert into sq_limit values (1, 1, 1), (2, 2, 2), (3, 3, 3), (4, 4, 4), (5, 1, 1), (6, 2, 2), (7, 3, 3), (8, 4, 4); create function explain_sq_limit() returns setof text language plpgsql as $$ declare ln text; begin for ln in explain (analyze, summary off, timing off, costs off) select * from (select pk,c2 from sq_limit order by c1,pk) as x limit 3 loop ln := regexp_replace(ln, 'Memory: \S*', 'Memory: xxx'); return next ln; end loop; end; $$; select * from explain_sq_limit(); select * from (select pk,c2 from sq_limit order by c1,pk) as x limit 3; drop function explain_sq_limit(); drop table sq_limit; -- -- Ensure that backward scan direction isn't propagated into -- expression subqueries (bug #15336) -- begin; declare c1 scroll cursor for select * from generate_series(1,4) i where i <> all (values (2),(3)); move forward all in c1; fetch backward all in c1; commit; -- -- Verify that we correctly flatten cases involving a subquery output -- expression that doesn't need to be wrapped in a PlaceHolderVar -- explain (costs off) select tname, attname from ( select relname::information_schema.sql_identifier as tname, * from (select * from pg_class c) ss1) ss2 right join pg_attribute a on a.attrelid = ss2.oid where tname = 'tenk1' and attnum = 1; select tname, attname from ( select relname::information_schema.sql_identifier as tname, * from (select * from pg_class c) ss1) ss2 right join pg_attribute a on a.attrelid = ss2.oid where tname = 'tenk1' and attnum = 1; -- -- Tests for CTE inlining behavior -- -- Basic subquery that can be inlined explain (verbose, costs off) with x as (select * from (select f1 from subselect_tbl) ss) select * from x where f1 = 1; -- Explicitly request materialization explain (verbose, costs off) with x as materialized (select * from (select f1 from subselect_tbl) ss) select * from x where f1 = 1; -- Stable functions are safe to inline explain (verbose, costs off) with x as (select * from (select f1, now() from subselect_tbl) ss) select * from x where f1 = 1; -- Volatile functions prevent inlining explain (verbose, costs off) with x as (select * from (select f1, random() from subselect_tbl) ss) select * from x where f1 = 1; -- SELECT FOR UPDATE cannot be inlined explain (verbose, costs off) with x as (select * from (select f1 from subselect_tbl for update) ss) select * from x where f1 = 1; -- Multiply-referenced CTEs are inlined only when requested explain (verbose, costs off) with x as (select * from (select f1, now() as n from subselect_tbl) ss) select * from x, x x2 where x.n = x2.n; explain (verbose, costs off) with x as not materialized (select * from (select f1, now() as n from subselect_tbl) ss) select * from x, x x2 where x.n = x2.n; -- Multiply-referenced CTEs can't be inlined if they contain outer self-refs explain (verbose, costs off) with recursive x(a) as ((values ('a'), ('b')) union all (with z as not materialized (select * from x) select z.a || z1.a as a from z cross join z as z1 where length(z.a || z1.a) < 5)) select * from x; with recursive x(a) as ((values ('a'), ('b')) union all (with z as not materialized (select * from x) select z.a || z1.a as a from z cross join z as z1 where length(z.a || z1.a) < 5)) select * from x; explain (verbose, costs off) with recursive x(a) as ((values ('a'), ('b')) union all (with z as not materialized (select * from x) select z.a || z.a as a from z where length(z.a || z.a) < 5)) select * from x; with recursive x(a) as ((values ('a'), ('b')) union all (with z as not materialized (select * from x) select z.a || z.a as a from z where length(z.a || z.a) < 5)) select * from x; -- Check handling of outer references explain (verbose, costs off) with x as (select * from int4_tbl) select * from (with y as (select * from x) select * from y) ss; explain (verbose, costs off) with x as materialized (select * from int4_tbl) select * from (with y as (select * from x) select * from y) ss; -- Ensure that we inline the correct CTE when there are -- multiple CTEs with the same name explain (verbose, costs off) with x as (select 1 as y) select * from (with x as (select 2 as y) select * from x) ss; -- Row marks are not pushed into CTEs explain (verbose, costs off) with x as (select * from subselect_tbl) select * from x for update; -- Pull up direct-correlated ANY_SUBLINKs explain (costs off) select * from tenk1 A where hundred in (select hundred from tenk2 B where B.odd = A.odd); explain (costs off) select * from tenk1 A where exists (select 1 from tenk2 B where A.hundred in (select C.hundred FROM tenk2 C WHERE c.odd = b.odd)); -- we should only try to pull up the sublink into RHS of a left join -- but a.hundred is not available. explain (costs off) SELECT * FROM tenk1 A LEFT JOIN tenk2 B ON A.hundred in (SELECT c.hundred FROM tenk2 C WHERE c.odd = b.odd); -- we should only try to pull up the sublink into RHS of a left join -- but a.odd is not available for this. explain (costs off) SELECT * FROM tenk1 A LEFT JOIN tenk2 B ON B.hundred in (SELECT c.hundred FROM tenk2 C WHERE c.odd = a.odd); -- should be able to pull up since all the references are available. explain (costs off) SELECT * FROM tenk1 A LEFT JOIN tenk2 B ON B.hundred in (SELECT c.hundred FROM tenk2 C WHERE c.odd = b.odd); -- we can pull up the sublink into the inner JoinExpr. explain (costs off) SELECT * FROM tenk1 A INNER JOIN tenk2 B ON A.hundred in (SELECT c.hundred FROM tenk2 C WHERE c.odd = b.odd) WHERE a.thousand < 750; -- we can pull up the aggregate sublink into RHS of a left join. explain (costs off) SELECT * FROM tenk1 A LEFT JOIN tenk2 B ON B.hundred in (SELECT min(c.hundred) FROM tenk2 C WHERE c.odd = b.odd);