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这篇文章主要介绍“PostgreSQL新特性分析”,在日常操作中,相信很多人在PostgreSQL新特性分析问题上存在疑惑,小编查阅了各式资料,整理出简单好用的操作方法,希望对大家解答”PostgreSQL新特性分析”的疑惑有所帮助!接下来,请跟着小编一起来学习吧!
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在PG 8.4 ~ PG 11,PG会把WITH中的查询视为”optimization fence”(优化围栏,与WITH外的查询隔离,独立优化),也就意味着谓词下推等优化手段无法应用到WITH子句中,考虑到CTE在大多数情况下是为了增强可读性而存在,因此在PG 12中,满足以下三个条件的,优化器将不会对CTE”视而不见”而是执行”积极的”优化.
A.递归查询
B.没有任何副作用(side effect)
C.仅在查询的后续部分引用一次
谓词下推
测试脚本:
drop table if exists t_w1; drop table if exists t_w2; drop table if exists t_w3; create table t_w1(id int ,c1 varchar(20)); create table t_w2(id int ,c1 varchar(20)); create table t_w3(id int ,c1 varchar(20)); insert into t_w1 select x,x||'' from generate_series(1,10000) as x; insert into t_w2 select x/2,(x/2)||'' from generate_series(1,10000) as x; insert into t_w3 select x,x||'' from generate_series(1,10000) as x;
查询语句:
WITH t1 AS ( SELECT * FROM t_w1 WHERE t_w1.id % 4 = 0 ) SELECT * FROM t1 JOIN t_w2 as t2 ON t2.id = t1.id AND t1.id < 100;
在PG 11中,其执行计划如下:
version -------------------------------------------------------------------------------------------- PostgreSQL 11.2 on x86_XX-pc-linux-gnu, compiled by gcc (GCC) 4.8.5 20150623 (Red Hat 4.8.5-16), XX-bit (1 row) testdb=# explain analyze WITH t1 AS ( SELECT * FROM t_w1 WHERE t_w1.id % 4 = 0 ) testdb-# SELECT * FROM t1 testdb-# JOIN t_w2 as t2 testdb-# ON t2.id = t1.id testdb-# AND t1.id < 100; QUERY PLAN -------------------------------------------------------------------------------------------- Hash Join (cost=205.34..396.18 rows=34 width=70) (actual time=8.576..11.187 rows=48 loops=1) Hash Cond: (t2.id = t1.id) CTE t1 -> Seq Scan on t_w1 (cost=0.00..204.00 rows=50 width=8) (actual time=0.029..6.074 rows=2500 loops=1) Filter: ((id % 4) = 0) Rows Removed by Filter: 7500 -> Seq Scan on t_w2 t2 (cost=0.00..153.00 rows=10000 width=8) (actual time=0.030..1.166 rows=10000 loops=1) -> Hash (cost=1.12..1.12 rows=17 width=62) (actual time=8.536..8.536 rows=24 loops=1) Buckets: 1024 Batches: 1 Memory Usage: 9kB -> CTE Scan on t1 (cost=0.00..1.12 rows=17 width=62) (actual time=0.033..8.521 rows=24 loops=1) Filter: (id < 100) Rows Removed by Filter: 2476 Planning Time: 1.913 ms Execution Time: 11.357 ms (14 rows)
在PG 12中,其执行计划如下:
testdb=# select version(); version -------------------------------------------------------------------------------------------- PostgreSQL 12beta1 on x86_XX-pc-linux-gnu, compiled by gcc (GCC) 4.8.5 20150623 (Red Hat 4.8.5-16), XX-bit (1 row) testdb=# explain analyze WITH t1 AS ( SELECT * FROM t_w1 WHERE t_w1.id % 4 = 0 ) testdb-# SELECT * FROM t1 testdb-# JOIN t_w2 as t2 testdb-# ON t2.id = t1.id testdb-# AND t1.id < 100; QUERY PLAN -------------------------------------------------------------------------------------------- Hash Join (cost=229.01..419.52 rows=1 width=16) (actual time=6.974..17.156 rows=48 loops=1) Hash Cond: (t2.id = t_w1.id) -> Seq Scan on t_w2 t2 (cost=0.00..153.00 rows=10000 width=8) (actual time=0.076..5.205 rows=10000 loops=1) -> Hash (cost=229.00..229.00 rows=1 width=8) (actual time=6.882..6.882 rows=24 loops=1) Buckets: 1024 Batches: 1 Memory Usage: 9kB -> Seq Scan on t_w1 (cost=0.00..229.00 rows=1 width=8) (actual time=0.077..6.842 rows=24 loops=1) Filter: ((id < 100) AND ((id % 4) = 0)) Rows Removed by Filter: 9976 Planning Time: 1.677 ms Execution Time: 17.244 ms (10 rows)
可以看到,在PG 11中,谓词(id < 100)不会下推CTE中,但在PG 12中,优化器则把谓词下推到CTE中(Filter: ((id < 100) AND ((id % 4) = 0))).
New Option
如果希望12的优化器行为与先前的一样,则加入Option : MATERIALIZED.
testdb=# explain analyze WITH t1 AS MATERIALIZED( SELECT * FROM t_w1 WHERE t_w1.id % 4 = 0 ) SELECT * FROM t1 JOIN t_w2 as t2 ON t2.id = t1.id AND t1.id < 100; QUERY PLAN ------------------------------------------------------------------------------------------- Hash Join (cost=205.34..396.18 rows=34 width=70) (actual time=30.705..48.549 rows=48 loops=1) Hash Cond: (t2.id = t1.id) CTE t1 -> Seq Scan on t_w1 (cost=0.00..204.00 rows=50 width=8) (actual time=0.152..21.274 rows=2500 loops=1) Filter: ((id % 4) = 0) Rows Removed by Filter: 7500 -> Seq Scan on t_w2 t2 (cost=0.00..153.00 rows=10000 width=8) (actual time=0.154..8.582 rows=10000 loops=1) -> Hash (cost=1.12..1.12 rows=17 width=62) (actual time=30.502..30.502 rows=24 loops=1) Buckets: 1024 Batches: 1 Memory Usage: 9kB -> CTE Scan on t1 (cost=0.00..1.12 rows=17 width=62) (actual time=0.168..30.445 rows=24 loops=1) Filter: (id < 100) Rows Removed by Filter: 2476 Planning Time: 7.673 ms Execution Time: 49.284 ms (14 rows)
如果希望优化器把尽可能的把CTE视为内联查询进行优化,则指定NOT MATERIALIZED Option:
下面的查询,CTE被引用多次,优化器默认会进行MATERIALIZED,通过指定NOT MATERIALIZED则强制为内联查询.
testdb=# explain analyze WITH t1 AS ( SELECT * FROM t_w1 WHERE t_w1.id % 4 = 0 ) testdb-# SELECT * FROM t1 testdb-# JOIN t_w2 as t2 testdb-# ON t2.id = t1.id testdb-# UNION ALL testdb-# select t1.*,NULL,NULL from t1 where t1.id % 3 = 0; QUERY PLAN ----------------------------------------------------------------------------------------------------------------------- Append (cost=205.62..399.89 rows=101 width=70) (actual time=11.663..27.725 rows=3332 loops=1) CTE t1 -> Seq Scan on t_w1 (cost=0.00..204.00 rows=50 width=8) (actual time=0.032..7.300 rows=2500 loops=1) Filter: ((id % 4) = 0) Rows Removed by Filter: 7500 -> Hash Join (cost=1.62..193.12 rows=100 width=70) (actual time=11.662..24.094 rows=2499 loops=1) Hash Cond: (t2.id = t1.id) -> Seq Scan on t_w2 t2 (cost=0.00..153.00 rows=10000 width=8) (actual time=0.033..4.412 rows=10000 loops=1) -> Hash (cost=1.00..1.00 rows=50 width=62) (actual time=11.611..11.612 rows=2500 loops=1) Buckets: 4096 (originally 1024) Batches: 1 (originally 1) Memory Usage: 132kB -> CTE Scan on t1 (cost=0.00..1.00 rows=50 width=62) (actual time=0.035..9.916 rows=2500 loops=1) -> CTE Scan on t1 t1_1 (cost=0.00..1.25 rows=1 width=98) (actual time=0.008..2.824 rows=833 loops=1) Filter: ((id % 3) = 0) Rows Removed by Filter: 1667 Planning Time: 2.358 ms Execution Time: 28.746 ms (16 rows)
使用NOT MATERIALIZED选项
testdb=# explain analyze WITH t1 AS NOT MATERIALIZED( SELECT * FROM t_w1 WHERE t_w1.id % 4 = 0 ) SELECT * FROM t1 JOIN t_w2 as t2 ON t2.id = t1.id UNION ALL select t1.*,NULL,NULL from t1 where t1.id % 3 = 0; QUERY PLAN ------------------------------------------------------------------------------------------- Append (cost=204.62..650.39 rows=51 width=17) (actual time=27.894..57.453 rows=3332 loops=1) -> Hash Join (cost=204.62..395.62 rows=50 width=16) (actual time=27.892..48.911 rows=2499 loops=1) Hash Cond: (t2.id = t_w1.id) -> Seq Scan on t_w2 t2 (cost=0.00..153.00 rows=10000 width=8) (actual time=0.149..7.606 rows=10000 loops=1) -> Hash (cost=204.00..204.00 rows=50 width=8) (actual time=27.699..27.699 rows=2500 loops=1) Buckets: 4096 (originally 1024) Batches: 1 (originally 1) Memory Usage: 132kB -> Seq Scan on t_w1 (cost=0.00..204.00 rows=50 width=8) (actual time=0.151..22.446 rows=2500 loops=1) Filter: ((id % 4) = 0) Rows Removed by Filter: 7500 -> Seq Scan on t_w1 t_w1_1 (cost=0.00..254.00 rows=1 width=44) (actual time=0.038..7.400 rows=833 loops=1) Filter: (((id % 4) = 0) AND ((id % 3) = 0)) Rows Removed by Filter: 9167 Planning Time: 12.357 ms Execution Time: 58.490 ms (14 rows)
到此,关于“PostgreSQL新特性分析”的学习就结束了,希望能够解决大家的疑惑。理论与实践的搭配能更好的帮助大家学习,快去试试吧!若想继续学习更多相关知识,请继续关注创新互联网站,小编会继续努力为大家带来更多实用的文章!