inherit.sql

application/sql

Filename: inherit.sql
Type: application/sql
Part: 0
Message: Re: BUG #17257: (auto)vacuum hangs within lazy_scan_prune()
SELECT pg_sleep(random()/10);

--
-- Test merge-append plans for inheritance trees
--

create table matest0 (id serial primary key, name text);
create table matest1 (id integer primary key) inherits (matest0);
create table matest2 (id integer primary key) inherits (matest0);
create table matest3 (id integer primary key) inherits (matest0);

create index matest0i on matest0 ((1-id));
create index matest1i on matest1 ((1-id));
-- create index matest2i on matest2 ((1-id));  -- intentionally missing
create index matest3i on matest3 ((1-id));

insert into matest1 (name) values ('Test 1');
insert into matest1 (name) values ('Test 2');
insert into matest2 (name) values ('Test 3');
insert into matest2 (name) values ('Test 4');
insert into matest3 (name) values ('Test 5');
insert into matest3 (name) values ('Test 6');

set enable_indexscan = off;  -- force use of seqscan/sort, so no merge
explain (verbose, costs off) select * from matest0 order by 1-id;
select * from matest0 order by 1-id;
explain (verbose, costs off) select min(1-id) from matest0;
select min(1-id) from matest0;
reset enable_indexscan;

set enable_seqscan = off;  -- plan with fewest seqscans should be merge
set enable_parallel_append = off; -- Don't let parallel-append interfere
explain (verbose, costs off) select * from matest0 order by 1-id;
select * from matest0 order by 1-id;
explain (verbose, costs off) select min(1-id) from matest0;
select min(1-id) from matest0;
reset enable_seqscan;
reset enable_parallel_append;

drop table matest0 cascade;

--
-- Check that use of an index with an extraneous column doesn't produce
-- a plan with extraneous sorting
--

create table matest0 (a int, b int, c int, d int);
create table matest1 () inherits(matest0);
create index matest0i on matest0 (b, c);
create index matest1i on matest1 (b, c);

set enable_nestloop = off;  -- we want a plan with two MergeAppends

explain (costs off)
select t1.* from matest0 t1, matest0 t2
where t1.b = t2.b and t2.c = t2.d
order by t1.b limit 10;

reset enable_nestloop;

drop table matest0 cascade;

--
-- Test merge-append for UNION ALL append relations
--

set enable_seqscan = off;
set enable_indexscan = on;
set enable_bitmapscan = off;


-- exercise rescan code path via a repeatedly-evaluated subquery
explain (costs off)
SELECT
    ARRAY(SELECT f.i FROM (
        (SELECT d + g.i FROM generate_series(4, 30, 3) d ORDER BY 1)
        UNION ALL
        (SELECT d + g.i FROM generate_series(0, 30, 5) d ORDER BY 1)
    ) f(i)
    ORDER BY f.i LIMIT 10)
FROM generate_series(1, 3) g(i);

SELECT
    ARRAY(SELECT f.i FROM (
        (SELECT d + g.i FROM generate_series(4, 30, 3) d ORDER BY 1)
        UNION ALL
        (SELECT d + g.i FROM generate_series(0, 30, 5) d ORDER BY 1)
    ) f(i)
    ORDER BY f.i LIMIT 10)
FROM generate_series(1, 3) g(i);

reset enable_seqscan;
reset enable_indexscan;
reset enable_bitmapscan;

--
-- Check handling of a constant-null CHECK constraint
--
create table cnullparent (f1 int);
create table cnullchild (check (f1 = 1 or f1 = null)) inherits(cnullparent);
insert into cnullchild values(1);
insert into cnullchild values(2);
insert into cnullchild values(null);
select * from cnullparent;
select * from cnullparent where f1 = 2;
drop table cnullparent cascade;

--
-- Check use of temporary tables with inheritance trees
--
create table inh_perm_parent (a1 int);
create temp table inh_temp_parent (a1 int);
create temp table inh_temp_child () inherits (inh_perm_parent); -- ok
create temp table inh_temp_child_2 () inherits (inh_temp_parent); -- ok
insert into inh_perm_parent values (1);
insert into inh_temp_parent values (2);
insert into inh_temp_child values (3);
insert into inh_temp_child_2 values (4);
select tableoid::regclass, a1 from inh_perm_parent;
select tableoid::regclass, a1 from inh_temp_parent;
drop table inh_perm_parent cascade;
drop table inh_temp_parent cascade;

--
-- Check that constraint exclusion works correctly with partitions using
-- implicit constraints generated from the partition bound information.
--
create table list_parted (
	a	varchar
) partition by list (a);
create table part_ab_cd partition of list_parted for values in ('ab', 'cd');
create table part_ef_gh partition of list_parted for values in ('ef', 'gh');
create table part_null_xy partition of list_parted for values in (null, 'xy');

explain (costs off) select * from list_parted;
explain (costs off) select * from list_parted where a is null;
explain (costs off) select * from list_parted where a is not null;
explain (costs off) select * from list_parted where a in ('ab', 'cd', 'ef');
explain (costs off) select * from list_parted where a = 'ab' or a in (null, 'cd');
explain (costs off) select * from list_parted where a = 'ab';

create table range_list_parted (
	a	int,
	b	char(2)
) partition by range (a);
create table part_1_10 partition of range_list_parted for values from (1) to (10) partition by list (b);
create table part_1_10_ab partition of part_1_10 for values in ('ab');
create table part_1_10_cd partition of part_1_10 for values in ('cd');
create table part_10_20 partition of range_list_parted for values from (10) to (20) partition by list (b);
create table part_10_20_ab partition of part_10_20 for values in ('ab');
create table part_10_20_cd partition of part_10_20 for values in ('cd');
create table part_21_30 partition of range_list_parted for values from (21) to (30) partition by list (b);
create table part_21_30_ab partition of part_21_30 for values in ('ab');
create table part_21_30_cd partition of part_21_30 for values in ('cd');
create table part_40_inf partition of range_list_parted for values from (40) to (maxvalue) partition by list (b);
create table part_40_inf_ab partition of part_40_inf for values in ('ab');
create table part_40_inf_cd partition of part_40_inf for values in ('cd');
create table part_40_inf_null partition of part_40_inf for values in (null);

explain (costs off) select * from range_list_parted;
explain (costs off) select * from range_list_parted where a = 5;
explain (costs off) select * from range_list_parted where b = 'ab';
explain (costs off) select * from range_list_parted where a between 3 and 23 and b in ('ab');

/* Should select no rows because range partition key cannot be null */
explain (costs off) select * from range_list_parted where a is null;

/* Should only select rows from the null-accepting partition */
explain (costs off) select * from range_list_parted where b is null;
explain (costs off) select * from range_list_parted where a is not null and a < 67;
explain (costs off) select * from range_list_parted where a >= 30;

drop table list_parted;
drop table range_list_parted;

-- check that constraint exclusion is able to cope with the partition
-- constraint emitted for multi-column range partitioned tables
create table mcrparted (a int, b int, c int) partition by range (a, abs(b), c);
create table mcrparted_def partition of mcrparted default;
create table mcrparted0 partition of mcrparted for values from (minvalue, minvalue, minvalue) to (1, 1, 1);
create table mcrparted1 partition of mcrparted for values from (1, 1, 1) to (10, 5, 10);
create table mcrparted2 partition of mcrparted for values from (10, 5, 10) to (10, 10, 10);
create table mcrparted3 partition of mcrparted for values from (11, 1, 1) to (20, 10, 10);
create table mcrparted4 partition of mcrparted for values from (20, 10, 10) to (20, 20, 20);
create table mcrparted5 partition of mcrparted for values from (20, 20, 20) to (maxvalue, maxvalue, maxvalue);
explain (costs off) select * from mcrparted where a = 0;	-- scans mcrparted0, mcrparted_def
explain (costs off) select * from mcrparted where a = 10 and abs(b) < 5;	-- scans mcrparted1, mcrparted_def
explain (costs off) select * from mcrparted where a = 10 and abs(b) = 5;	-- scans mcrparted1, mcrparted2, mcrparted_def
explain (costs off) select * from mcrparted where abs(b) = 5;	-- scans all partitions
explain (costs off) select * from mcrparted where a > -1;	-- scans all partitions
explain (costs off) select * from mcrparted where a = 20 and abs(b) = 10 and c > 10;	-- scans mcrparted4
explain (costs off) select * from mcrparted where a = 20 and c > 20; -- scans mcrparted3, mcrparte4, mcrparte5, mcrparted_def

-- check that partitioned table Appends cope with being referenced in
-- subplans
create table parted_minmax (a int, b varchar(16)) partition by range (a);
create table parted_minmax1 partition of parted_minmax for values from (1) to (10);
create index parted_minmax1i on parted_minmax1 (a, b);
insert into parted_minmax values (1,'12345');
explain (costs off) select min(a), max(a) from parted_minmax where b = '12345';
select min(a), max(a) from parted_minmax where b = '12345';
drop table parted_minmax;

-- Test code that uses Append nodes in place of MergeAppend when the
-- partition ordering matches the desired ordering.

create index mcrparted_a_abs_c_idx on mcrparted (a, abs(b), c);

-- MergeAppend must be used when a default partition exists
explain (costs off) select * from mcrparted order by a, abs(b), c;

drop table mcrparted_def;

-- Append is used for a RANGE partitioned table with no default
-- and no subpartitions
explain (costs off) select * from mcrparted order by a, abs(b), c;

-- Append is used with subpaths in reverse order with backwards index scans
explain (costs off) select * from mcrparted order by a desc, abs(b) desc, c desc;

-- check that Append plan is used containing a MergeAppend for sub-partitions
-- that are unordered.
drop table mcrparted5;
create table mcrparted5 partition of mcrparted for values from (20, 20, 20) to (maxvalue, maxvalue, maxvalue) partition by list (a);
create table mcrparted5a partition of mcrparted5 for values in(20);
create table mcrparted5_def partition of mcrparted5 default;

explain (costs off) select * from mcrparted order by a, abs(b), c;

drop table mcrparted5_def;

-- check that an Append plan is used and the sub-partitions are flattened
-- into the main Append when the sub-partition is unordered but contains
-- just a single sub-partition.
explain (costs off) select a, abs(b) from mcrparted order by a, abs(b), c;

-- check that Append is used when the sub-partitioned tables are pruned
-- during planning.
explain (costs off) select * from mcrparted where a < 20 order by a, abs(b), c;

create table mclparted (a int) partition by list(a);
create table mclparted1 partition of mclparted for values in(1);
create table mclparted2 partition of mclparted for values in(2);
create index on mclparted (a);

-- Ensure an Append is used for a list partition with an order by.
explain (costs off) select * from mclparted order by a;

-- Ensure a MergeAppend is used when a partition exists with interleaved
-- datums in the partition bound.
create table mclparted3_5 partition of mclparted for values in(3,5);
create table mclparted4 partition of mclparted for values in(4);

explain (costs off) select * from mclparted order by a;

drop table mclparted;

-- Ensure subplans which don't have a path with the correct pathkeys get
-- sorted correctly.
drop index mcrparted_a_abs_c_idx;
create index on mcrparted1 (a, abs(b), c);
create index on mcrparted2 (a, abs(b), c);
create index on mcrparted3 (a, abs(b), c);
create index on mcrparted4 (a, abs(b), c);

explain (costs off) select * from mcrparted where a < 20 order by a, abs(b), c limit 1;

set enable_bitmapscan = 0;
-- Ensure Append node can be used when the partition is ordered by some
-- pathkeys which were deemed redundant.
explain (costs off) select * from mcrparted where a = 10 order by a, abs(b), c;
reset enable_bitmapscan;

drop table mcrparted;

-- Ensure LIST partitions allow an Append to be used instead of a MergeAppend
create table bool_lp (b bool) partition by list(b);
create table bool_lp_true partition of bool_lp for values in(true);
create table bool_lp_false partition of bool_lp for values in(false);
create index on bool_lp (b);

explain (costs off) select * from bool_lp order by b;

drop table bool_lp;

-- Ensure const bool quals can be properly detected as redundant
create table bool_rp (b bool, a int) partition by range(b,a);
create table bool_rp_false_1k partition of bool_rp for values from (false,0) to (false,1000);
create table bool_rp_true_1k partition of bool_rp for values from (true,0) to (true,1000);
create table bool_rp_false_2k partition of bool_rp for values from (false,1000) to (false,2000);
create table bool_rp_true_2k partition of bool_rp for values from (true,1000) to (true,2000);
create index on bool_rp (b,a);
explain (costs off) select * from bool_rp where b = true order by b,a;
explain (costs off) select * from bool_rp where b = false order by b,a;
explain (costs off) select * from bool_rp where b = true order by a;
explain (costs off) select * from bool_rp where b = false order by a;

drop table bool_rp;

-- Ensure an Append scan is chosen when the partition order is a subset of
-- the required order.
create table range_parted (a int, b int, c int) partition by range(a, b);
create table range_parted1 partition of range_parted for values from (0,0) to (10,10);
create table range_parted2 partition of range_parted for values from (10,10) to (20,20);
create index on range_parted (a,b,c);

explain (costs off) select * from range_parted order by a,b,c;
explain (costs off) select * from range_parted order by a desc,b desc,c desc;

drop table range_parted;

-- Check that we allow access to a child table's statistics when the user
-- has permissions only for the parent table.
create table permtest_parent (a int, b text, c text) partition by list (a);
create table permtest_child (b text, c text, a int) partition by list (b);
create table permtest_grandchild (c text, b text, a int);
alter table permtest_child attach partition permtest_grandchild for values in ('a');
alter table permtest_parent attach partition permtest_child for values in (1);
create index on permtest_parent (left(c, 3));
insert into permtest_parent
  select 1, 'a', left(md5(i::text), 5) from generate_series(0, 100) i;
analyze permtest_parent;
create role regress_no_child_access;
revoke all on permtest_grandchild from regress_no_child_access;
grant select on permtest_parent to regress_no_child_access;
set session authorization regress_no_child_access;
-- without stats access, these queries would produce hash join plans:
explain (costs off)
  select * from permtest_parent p1 inner join permtest_parent p2
  on p1.a = p2.a and p1.c ~ 'a1$';
explain (costs off)
  select * from permtest_parent p1 inner join permtest_parent p2
  on p1.a = p2.a and left(p1.c, 3) ~ 'a1$';
reset session authorization;
revoke all on permtest_parent from regress_no_child_access;
grant select(a,c) on permtest_parent to regress_no_child_access;
set session authorization regress_no_child_access;
explain (costs off)
  select p2.a, p1.c from permtest_parent p1 inner join permtest_parent p2
  on p1.a = p2.a and p1.c ~ 'a1$';
-- we will not have access to the expression index's stats here:
explain (costs off)
  select p2.a, p1.c from permtest_parent p1 inner join permtest_parent p2
  on p1.a = p2.a and left(p1.c, 3) ~ 'a1$';
reset session authorization;
revoke all on permtest_parent from regress_no_child_access;
drop role regress_no_child_access;
drop table permtest_parent;

-- Verify that constraint errors across partition root / child are
-- handled correctly (Bug #16293)
CREATE TABLE errtst_parent (
    partid int not null,
    shdata int not null,
    data int NOT NULL DEFAULT 0,
    CONSTRAINT shdata_small CHECK(shdata < 3)
) PARTITION BY RANGE (partid);

-- fast defaults lead to attribute mapping being used in one
-- direction, but not the other
CREATE TABLE errtst_child_fastdef (
    partid int not null,
    shdata int not null,
    CONSTRAINT shdata_small CHECK(shdata < 3)
);

-- no remapping in either direction necessary
CREATE TABLE errtst_child_plaindef (
    partid int not null,
    shdata int not null,
    data int NOT NULL DEFAULT 0,
    CONSTRAINT shdata_small CHECK(shdata < 3),
    CHECK(data < 10)
);

-- remapping in both direction
CREATE TABLE errtst_child_reorder (
    data int NOT NULL DEFAULT 0,
    shdata int not null,
    partid int not null,
    CONSTRAINT shdata_small CHECK(shdata < 3),
    CHECK(data < 10)
);

ALTER TABLE errtst_child_fastdef ADD COLUMN data int NOT NULL DEFAULT 0;
ALTER TABLE errtst_child_fastdef ADD CONSTRAINT errtest_child_fastdef_data_check CHECK (data < 10);

ALTER TABLE errtst_parent ATTACH PARTITION errtst_child_fastdef FOR VALUES FROM (0) TO (10);
ALTER TABLE errtst_parent ATTACH PARTITION errtst_child_plaindef FOR VALUES FROM (10) TO (20);
ALTER TABLE errtst_parent ATTACH PARTITION errtst_child_reorder FOR VALUES FROM (20) TO (30);

-- insert without child check constraint error
INSERT INTO errtst_parent(partid, shdata, data) VALUES ( '0', '1', '5');
INSERT INTO errtst_parent(partid, shdata, data) VALUES ('10', '1', '5');
INSERT INTO errtst_parent(partid, shdata, data) VALUES ('20', '1', '5');


-- within partition update without child check constraint violation
BEGIN;
UPDATE errtst_parent SET data = data + 1 WHERE partid = 0;
UPDATE errtst_parent SET data = data + 1 WHERE partid = 10;
UPDATE errtst_parent SET data = data + 1 WHERE partid = 20;
ROLLBACK;

-- direct leaf partition update, without partition id violation
BEGIN;
UPDATE errtst_child_fastdef SET partid = 1 WHERE partid = 0;
UPDATE errtst_child_plaindef SET partid = 11 WHERE partid = 10;
UPDATE errtst_child_reorder SET partid = 21 WHERE partid = 20;
ROLLBACK;

-- partition move, without child check constraint violation
BEGIN;
UPDATE errtst_parent SET partid = 10, data = data + 1 WHERE partid = 0;
UPDATE errtst_parent SET partid = 20, data = data + 1 WHERE partid = 10;
UPDATE errtst_parent SET partid = 0, data = data + 1 WHERE partid = 20;
ROLLBACK;


DROP TABLE errtst_parent;