MDEV-25714 Join using derived with aggregation returns incorrect results

If a join query uses a derived table (view / CTE) with GROUP BY clause then the execution plan for such join may employ split optimization. When this optimization is employed the derived table is not materialized. Rather only some partitions of the derived table are subject to grouping. Split optimization can be applied only if: - there are some indexes over the tables used in the join specifying the derived table whose prefixes partially cover the field items used in the GROUP BY list (such indexes are called splitting indexes) - the WHERE condition of the join query contains conjunctive equalities between columns of the derived table that comprise major parts of splitting indexes and columns of the other join tables. When the optimizer evaluates extending of a partial join by the rows of the derived table it always considers a possibility of using split optimization. Different splitting indexes can be used depending on the extended partial join. At some rare conditions, for example, when there is a non-splitting covering index for a table joined in the join specifying the derived table usage of a splitting index to produce rows needed for grouping may be still less beneficial than usage of such covering index without any splitting technique. The function JOIN_TAB::choose_best_splitting() must take this into account. Approved by Oleksandr Byelkin <sanja@mariadb.com>

MDEV-25714 Join using derived with aggregation returns incorrect results
If a join query uses a derived table (view / CTE) with GROUP BY clause then the execution plan for such join may employ split optimization. When this optimization is employed the derived table is not materialized. Rather only some partitions of the derived table are subject to grouping. Split optimization can be applied only if: - there are some indexes over the tables used in the join specifying the derived table whose prefixes partially cover the field items used in the GROUP BY list (such indexes are called splitting indexes) - the WHERE condition of the join query contains conjunctive equalities between columns of the derived table that comprise major parts of splitting indexes and columns of the other join tables. When the optimizer evaluates extending of a partial join by the rows of the derived table it always considers a possibility of using split optimization. Different splitting indexes can be used depending on the extended partial join. At some rare conditions, for example, when there is a non-splitting covering index for a table joined in the join specifying the derived table usage of a splitting index to produce rows needed for grouping may be still less beneficial than usage of such covering index without any splitting technique. The function JOIN_TAB::choose_best_splitting() must take this into account. Approved by Oleksandr Byelkin <sanja@mariadb.com>
0b797130 · Igor Babaev · fa0bbff0 · 0b797130 · 0b797130 · 0b797130
Commit 0b797130 authored May 26, 2021 by Igor Babaev
4 changed files
--- a/mysql-test/main/derived_cond_pushdown.result
+++ b/mysql-test/main/derived_cond_pushdown.result
@@ -16703,7 +16703,7 @@ EXPLAIN EXTENDED
 SELECT * FROM v1 JOIN v2 ON v1.f = v2.f;
 id	select_type	table	type	possible_keys	key	key_len	ref	rows	filtered	Extra
 1	PRIMARY	NULL	NULL	NULL	NULL	NULL	NULL	NULL	NULL	Impossible WHERE noticed after reading const tables
-3	LATERAL DERIVED	NULL	NULL	NULL	NULL	NULL	NULL	NULL	NULL	no matching row in const table
+3	DERIVED	NULL	NULL	NULL	NULL	NULL	NULL	NULL	NULL	no matching row in const table
 Warnings:
 Note	1003	/* select#1 */ select NULL AS `f`,`v2`.`f` AS `f` from `test`.`t1` `a` straight_join `test`.`t1` `b` join `test`.`v2` where 0
 DROP VIEW v1,v2;

--- a/mysql-test/main/derived_split_innodb.result
+++ b/mysql-test/main/derived_split_innodb.result
@@ -175,3 +175,64 @@ id	select_type	table	type	possible_keys	key	key_len	ref	rows	Extra
 3	LATERAL DERIVED	t1	ref	a,a_2	a	5	test.t1.a	1	Using where; Using temporary; Using filesort
 3	LATERAL DERIVED	t2	ref	c	c	5	test.t1.b	1	Using index
 DROP TABLE t1, t2;
+#
+# Bug mdev-25714: usage non-splitting covering index is cheaper than
+#                 usage of the best splitting index for one group
+#
+create table t1 (
+id int not null, itemid int not null, index idx (itemid)
+) engine=innodb;
+insert into t1 values (1, 2), (2,2), (4,2), (4,2), (0,3), (3,3);
+create table t2 (id int not null) engine=innodb;
+insert into t2 values (2);
+create table t3 (
+id int not null, itemid int not null, userid int not null, primary key (id),
+index idx1 (userid, itemid), index idx2 (itemid)
+) engine innodb;
+insert into t3 values (1,1,1), (2,1,1), (3,2,1), (4,2,1), (5,3,1);
+analyze table t1,t2,t3;
+Table	Op	Msg_type	Msg_text
+test.t1	analyze	status	OK
+test.t2	analyze	status	OK
+test.t3	analyze	status	OK
+set optimizer_switch='split_materialized=on';
+explain select t1.id, t1.itemid, dt.id, t2.id
+from t1,
+(select itemid, max(id) as id from t3 where userid = 1 group by itemid) dt,
+t2
+where t1.id = dt.id and t1.itemid = dt.itemid and t2.id=t1.itemid;
+id	select_type	table	type	possible_keys	key	key_len	ref	rows	Extra
+1	PRIMARY	t2	ALL	NULL	NULL	NULL	NULL	1	
+1	PRIMARY	t1	ref	idx	idx	4	test.t2.id	1	
+1	PRIMARY	<derived2>	ref	key0	key0	9	test.t2.id,test.t1.id	2	
+2	DERIVED	t3	ref	idx1,idx2	idx1	4	const	5	Using where; Using index
+select t1.id, t1.itemid, dt.id, t2.id
+from t1,
+(select itemid, max(id) as id from t3 where userid = 1 group by itemid) dt,
+t2
+where t1.id = dt.id and t1.itemid = dt.itemid and t2.id=t1.itemid;
+id	itemid	id	id
+4	2	4	2
+4	2	4	2
+set optimizer_switch='split_materialized=off';
+explain select t1.id, t1.itemid, dt.id, t2.id
+from t1,
+(select itemid, max(id) as id from t3 where userid = 1 group by itemid) dt,
+t2
+where t1.id = dt.id and t1.itemid = dt.itemid and t2.id=t1.itemid;
+id	select_type	table	type	possible_keys	key	key_len	ref	rows	Extra
+1	PRIMARY	t2	ALL	NULL	NULL	NULL	NULL	1	
+1	PRIMARY	t1	ref	idx	idx	4	test.t2.id	1	
+1	PRIMARY	<derived2>	ref	key0	key0	9	test.t2.id,test.t1.id	2	
+2	DERIVED	t3	ref	idx1	idx1	4	const	5	Using where; Using index
+select t1.id, t1.itemid, dt.id, t2.id
+from t1,
+(select itemid, max(id) as id from t3 where userid = 1 group by itemid) dt,
+t2
+where t1.id = dt.id and t1.itemid = dt.itemid and t2.id=t1.itemid;
+id	itemid	id	id
+4	2	4	2
+4	2	4	2
+drop table t1,t2,t3;
+set optimizer_switch='split_materialized=default';
+# End of 10.3 tests
--- a/mysql-test/main/derived_split_innodb.test
+++ b/mysql-test/main/derived_split_innodb.test
@@ -150,3 +150,40 @@ eval set statement optimizer_switch='split_materialized=on' for  $query;

 DROP TABLE t1, t2;

+--echo #
+--echo # Bug mdev-25714: usage non-splitting covering index is cheaper than
+--echo #                 usage of the best splitting index for one group
+--echo #
+
+create table t1 (
+  id int not null, itemid int not null, index idx (itemid)
+) engine=innodb;
+insert into t1 values (1, 2), (2,2), (4,2), (4,2), (0,3), (3,3);
+create table t2 (id int not null) engine=innodb;
+insert into t2 values (2);
+create table t3 (
+  id int not null, itemid int not null, userid int not null, primary key (id),
+  index idx1 (userid, itemid), index idx2 (itemid)
+) engine innodb;
+insert into t3 values (1,1,1), (2,1,1), (3,2,1), (4,2,1), (5,3,1);
+analyze table t1,t2,t3;
+
+let $q=
+select t1.id, t1.itemid, dt.id, t2.id
+  from t1,
+  (select itemid, max(id) as id from t3 where userid = 1 group by itemid) dt,
+  t2
+    where t1.id = dt.id and t1.itemid = dt.itemid and t2.id=t1.itemid;
+
+set optimizer_switch='split_materialized=on';
+eval explain $q;
+eval $q;
+
+set optimizer_switch='split_materialized=off';
+eval explain $q;
+eval $q;
+
+drop table t1,t2,t3;
+set optimizer_switch='split_materialized=default';
+
+--echo # End of 10.3 tests
--- a/sql/opt_split.cc
+++ b/sql/opt_split.cc
@@ -960,11 +960,7 @@ SplM_plan_info * JOIN_TAB::choose_best_splitting(double record_count,
      in the cache
    */
    spl_plan= spl_opt_info->find_plan(best_table, best_key, best_key_parts);
-    if (!spl_plan &&
-	(spl_plan= (SplM_plan_info *) thd->alloc(sizeof(SplM_plan_info))) &&
-	(spl_plan->best_positions=
-	   (POSITION *) thd->alloc(sizeof(POSITION) * join->table_count)) &&
-	!spl_opt_info->plan_cache.push_back(spl_plan))
+    if (!spl_plan)
    {
      /*
        The plan for the chosen key has not been found in the cache.
@@ -974,6 +970,27 @@ SplM_plan_info * JOIN_TAB::choose_best_splitting(double record_count,
      reset_validity_vars_for_keyuses(best_key_keyuse_ext_start, best_table,
                                      best_key, remaining_tables, true);
      choose_plan(join, all_table_map & ~join->const_table_map);
+
+      /*
+        Check that the chosen plan is really a splitting plan.
+        If not or if there is not enough memory to save the plan in the cache
+        then just return with no splitting plan.
+      */
+      POSITION *first_non_const_pos= join->best_positions + join->const_tables;
+      TABLE *table= first_non_const_pos->table->table;
+      key_map spl_keys= table->keys_usable_for_splitting;
+      if (!(first_non_const_pos->key &&
+            spl_keys.is_set(first_non_const_pos->key->key)) ||
+          !(spl_plan= (SplM_plan_info *) thd->alloc(sizeof(SplM_plan_info))) ||
+	  !(spl_plan->best_positions=
+	     (POSITION *) thd->alloc(sizeof(POSITION) * join->table_count)) ||
+	  spl_opt_info->plan_cache.push_back(spl_plan))
+      {
+        reset_validity_vars_for_keyuses(best_key_keyuse_ext_start, best_table,
+                                        best_key, remaining_tables, false);
+        return 0;
+      }
+
      spl_plan->keyuse_ext_start= best_key_keyuse_ext_start;
      spl_plan->table= best_table;
      spl_plan->key= best_key;