PgSQL-并行查询系列-介绍[译]

PgSQL-并行查询系列-介绍

现代CPU模型拥有大量的CPU核心。多年来,数据库应用程序都是并发向数据库发送查询的。查询处理多个表的行时,若可以使用多核,则可以客观地提升性能。PgSQL 9.6引入了并行查询的新特性,开启并行查询后可以大幅提升性能。

1、局限性

1)若所有CPU核心已经饱和,则不要启动并行查询。并行执行会从其他查询中窃取CPU时间,并增加响应时间

2)进一步需要注意:并行处理会显著增加内存使用(需要注意work_mem的值)。因为,每个hash join或者排序操作都会使用work_mem大小的内存。

3)低延迟的OLTP查询并不能通过并行显著提升性能。特别是仅返回1行的查询,若启用并行,性能会变得特烂。

4)并行执行仅支持没有锁谓词的SELECT查询

5)不支持cursor和会挂起的查询

6)windowed 函数和ordered-set聚合函数都不是并行的

7)对于负载已达IO瓶颈的,并没有啥好处

8)没有并行排序算法。然而,排序查询在某些方面仍然可以并行

9)将CTE(WITH...)替换为sub-select以支持并行执行

10)FDW还不支持并行(后面版本可以,注意哪个版本支持)

11)full outer join不支持

12)客户端设置了max_rows,禁止并行执行

13)如果查询中使用了没有标记为PARALLEL SAFE的函数,那他就是单线程执行

14)SERIALIZABLE事务隔离级别禁用并行执行

2、并行顺序扫描

并行顺序扫描很快,原因可能不是并行读,而是将数据访问分散到多个CPU上。现代操作系统给PgSQL的数据文件提供了很好的缓冲机制。预取允许从存储中获取一个块,而不仅是PgSQL请求的块。因此查询性能限制往往不在IO上,它消耗CPU周期:从表数据页中逐行读取;比较行值和WHERE条件

我们执行一个简单查询:

tpch=# explain analyze select l_quantity as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day;
QUERY PLAN
--------------------------------------------------------------------------------------------------------------------------
Seq Scan on lineitem (cost=0.00..1964772.00 rows=58856235 width=5) (actual time=0.014..16951.669 rows=58839715 loops=1)
Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)
Rows Removed by Filter: 1146337
Planning Time: 0.203 ms
Execution Time: 19035.100 ms

一个顺序扫描,没有聚合,需要产生大量行。因此该查询被一个CPU核心执行。添加聚合SUM()后,可以清晰的看到有2个进程帮助查询:

explain analyze select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day;
QUERY PLAN 
----------------------------------------------------------------------------------------------------------------------------------------------------
Finalize Aggregate (cost=1589702.14..1589702.15 rows=1 width=32) (actual time=8553.365..8553.365 rows=1 loops=1)
-> Gather (cost=1589701.91..1589702.12 rows=2 width=32) (actual time=8553.241..8555.067 rows=3 loops=1)
Workers Planned: 2
Workers Launched: 2
-> Partial Aggregate (cost=1588701.91..1588701.92 rows=1 width=32) (actual time=8547.546..8547.546 rows=1 loops=3)
-> Parallel Seq Scan on lineitem (cost=0.00..1527393.33 rows=24523431 width=5) (actual time=0.038..5998.417 rows=19613238 loops=3)
Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)
Rows Removed by Filter: 382112
Planning Time: 0.241 ms
Execution Time: 8555.131 ms

性能提升2.2倍。

3、并行聚合

“Parallel Seq Scan”节点为partial aggregation提供行。“Partial Aggregate”节点先对SUM()进行一次操作。最后“Gather”节点汇总每个进程的SUM值。“Finalize Aggregate”节点进行最后计算。如果你使用了聚合函数,不要忘记标记他们为“parallel safe”。

4、进程个数

可以不重启服务,增加并行进程个数:

alter system set max_parallel_workers_per_gather=4;
select * from pg_reload_conf();
Now, there are 4 workers in explain output:
tpch=# explain analyze select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day;
QUERY PLAN 
----------------------------------------------------------------------------------------------------------------------------------------------------
Finalize Aggregate (cost=1440213.58..1440213.59 rows=1 width=32) (actual time=5152.072..5152.072 rows=1 loops=1)
-> Gather (cost=1440213.15..1440213.56 rows=4 width=32) (actual time=5151.807..5153.900 rows=5 loops=1)
Workers Planned: 4
Workers Launched: 4
-> Partial Aggregate (cost=1439213.15..1439213.16 rows=1 width=32) (actual time=5147.238..5147.239 rows=1 loops=5)
-> Parallel Seq Scan on lineitem (cost=0.00..1402428.00 rows=14714059 width=5) (actual time=0.037..3601.882 rows=11767943 loops=5)
Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)
Rows Removed by Filter: 229267
Planning Time: 0.218 ms
Execution Time: 5153.967 ms

我们将并发进程由2改成了4,但是查询仅快1.6599倍。实际上,我们有2个进程+一个leader,配置改好成为4+1。并行最大提升可以:5/3=1.66倍。

5、如何工作?

查询执行总是从“leader”进程开始。Leader进程执行所有非并行动作。其他进程执行相同查询,称为“worker”进程。并行利用Dynamic Backgroud workers基础架构(9.4引入)执行。因此创建3个工作进程的查询可能比传统执行快4倍。

Worker进程使用消息队列(基于共享内存)和leader进行通信。每个进程有2个队列:一个为errors,另一个是tuples。

5、进程使用个数

1)max_parallel_workers_per_gather是workers进程数的最小限制

2)查询执行使用的workers限制为max_parallel_workes

3)最上层的限制是max_worker_processes:后台进程的总数

分配进程失败,会导致使用单进程执行。查询规划器会根据表或索引大小来增加worker个数。min_parallel_table_scan_size和min_parallel_index_scan_size控制该行为。

set min_parallel_table_scan_size='8MB'
8MB table => 1 worker
24MB table => 2 workers
72MB table => 3 workers
x => log(x / min_parallel_table_scan_size) / log(3) + 1 worker

表比min_parallel_(index|table)_scan_size值每大3倍,PG增加一个worker进程。Workers进程个数不是基于成本的。循环依赖使得复杂的实现变得困难。相反,规划者使用简单的规则。

可以通过ALTER TABLE … SET (parallel_workers = N)来对某个表指定并行进程数。

6、为什么不使用并行

除了并行限制外,PG还会检查代价:

parallel_setup_cost:避免短查询的并行执行。模拟用于内存设置、流程启动和初始通信的时间

parallel_tuple_cost:leader和worker之间通信可能花费很长时间。时间和worker发送的记录数成正比。参数对通信成本进行建模。

7、Nested Loop Join

PgSQL9.6+可以以并行形式执行“Nested loop”。

explain (costs off) select c_custkey, count(o_orderkey)
                from    customer left outer join orders on
                                c_custkey = o_custkey and o_comment not like '%special%deposits%'
                group by c_custkey;
                                      QUERY PLAN                                      
--------------------------------------------------------------------------------------
 Finalize GroupAggregate
   Group Key: customer.c_custkey
   ->  Gather Merge
         Workers Planned: 4
         ->  Partial GroupAggregate
               Group Key: customer.c_custkey
               ->  Nested Loop Left Join
                     ->  Parallel Index Only Scan using customer_pkey on customer
                     ->  Index Scan using idx_orders_custkey on orders
                           Index Cond: (customer.c_custkey = o_custkey)
                           Filter: ((o_comment)::text !~~ '%special%deposits%'::text)

Gather发生在最后阶段,因此“Nested Loop Left Join”是并行操作。“Parallel Index Only Scan”在版本10才可以使用,和并行顺序扫描类似。c_custkey = o_custkey条件读取每个customer行的order列,因此不是并行。

8、Hash Join

PgSQL11中每个worker构建自己的hash table。因此,4+ workers不能提升性能。新的实现方式:使用一个共享hash table。每个worker可以利用WORK_MEM来构建hash table>

select
        l_shipmode,
        sum(case
                when o_orderpriority = '1-URGENT'
                        or o_orderpriority = '2-HIGH'
                        then 1
                else 0
        end) as high_line_count,
        sum(case
                when o_orderpriority <> '1-URGENT'
                        and o_orderpriority <> '2-HIGH'
                        then 1
                else 0
        end) as low_line_count
from
        orders,
        lineitem
where
        o_orderkey = l_orderkey
        and l_shipmode in ('MAIL', 'AIR')
        and l_commitdate < l_receiptdate
        and l_shipdate < l_commitdate
        and l_receiptdate >= date '1996-01-01'
        and l_receiptdate < date '1996-01-01' + interval '1' year
group by
        l_shipmode
order by
        l_shipmode
LIMIT 1;


                                                                                                                                    QUERY PLAN                                                                     
                                                                
-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 Limit  (cost=1964755.66..1964961.44 rows=1 width=27) (actual time=7579.592..7922.997 rows=1 loops=1)
   ->  Finalize GroupAggregate  (cost=1964755.66..1966196.11 rows=7 width=27) (actual time=7579.590..7579.591 rows=1 loops=1)
         Group Key: lineitem.l_shipmode
         ->  Gather Merge  (cost=1964755.66..1966195.83 rows=28 width=27) (actual time=7559.593..7922.319 rows=6 loops=1)
               Workers Planned: 4
               Workers Launched: 4
               ->  Partial GroupAggregate  (cost=1963755.61..1965192.44 rows=7 width=27) (actual time=7548.103..7564.592 rows=2 loops=5)
                     Group Key: lineitem.l_shipmode
                     ->  Sort  (cost=1963755.61..1963935.20 rows=71838 width=27) (actual time=7530.280..7539.688 rows=62519 loops=5)
                           Sort Key: lineitem.l_shipmode
                           Sort Method: external merge  Disk: 2304kB
                           Worker 0:  Sort Method: external merge  Disk: 2064kB
                           Worker 1:  Sort Method: external merge  Disk: 2384kB
                           Worker 2:  Sort Method: external merge  Disk: 2264kB
                           Worker 3:  Sort Method: external merge  Disk: 2336kB
                           ->  Parallel Hash Join  (cost=382571.01..1957960.99 rows=71838 width=27) (actual time=7036.917..7499.692 rows=62519 loops=5)
                                 Hash Cond: (lineitem.l_orderkey = orders.o_orderkey)
                                 ->  Parallel Seq Scan on lineitem  (cost=0.00..1552386.40 rows=71838 width=19) (actual time=0.583..4901.063 rows=62519 loops=5)
                                       Filter: ((l_shipmode = ANY ('{MAIL,AIR}'::bpchar[])) AND (l_commitdate < l_receiptdate) AND (l_shipdate < l_commitdate) AND (l_receiptdate >= '1996-01-01'::date) AND (l_receiptdate < '1997-01-01 00:00:00'::timestamp without time zone))
                                       Rows Removed by Filter: 11934691
                                 ->  Parallel Hash  (cost=313722.45..313722.45 rows=3750045 width=20) (actual time=2011.518..2011.518 rows=3000000 loops=5)
                                       Buckets: 65536  Batches: 256  Memory Usage: 3840kB
                                       ->  Parallel Seq Scan on orders  (cost=0.00..313722.45 rows=3750045 width=20) (actual time=0.029..995.948 rows=3000000 loops=5)
 Planning Time: 0.977 ms
 Execution Time: 7923.770 ms

TPC-H中的SQL12是并行hash join的一个很好的哪里,每个进程都帮助构建共享hash table。

9、Merge Join

由于merge join的特性,使得不能并行。如果merge join是查询执行的最后阶段,那么不用担心,仍可以使用并行。

-- Query 2 from TPC-H
explain (costs off) select s_acctbal, s_name, n_name, p_partkey, p_mfgr, s_address, s_phone, s_comment
from    part, supplier, partsupp, nation, region
where
        p_partkey = ps_partkey
        and s_suppkey = ps_suppkey
        and p_size = 36
        and p_type like '%BRASS'
        and s_nationkey = n_nationkey
        and n_regionkey = r_regionkey
        and r_name = 'AMERICA'
        and ps_supplycost = (
                select
                        min(ps_supplycost)
                from    partsupp, supplier, nation, region
                where
                        p_partkey = ps_partkey
                        and s_suppkey = ps_suppkey
                        and s_nationkey = n_nationkey
                        and n_regionkey = r_regionkey
                        and r_name = 'AMERICA'
        )
order by s_acctbal desc, n_name, s_name, p_partkey
LIMIT 100;
                                                QUERY PLAN                                                
----------------------------------------------------------------------------------------------------------
 Limit
   ->  Sort
         Sort Key: supplier.s_acctbal DESC, nation.n_name, supplier.s_name, part.p_partkey
         ->  Merge Join
               Merge Cond: (part.p_partkey = partsupp.ps_partkey)
               Join Filter: (partsupp.ps_supplycost = (SubPlan 1))
               ->  Gather Merge
                     Workers Planned: 4
                     ->  Parallel Index Scan using part_pkey on part
                           Filter: (((p_type)::text ~~ '%BRASS'::text) AND (p_size = 36))
               ->  Materialize
                     ->  Sort
                           Sort Key: partsupp.ps_partkey
                           ->  Nested Loop
                                 ->  Nested Loop
                                       Join Filter: (nation.n_regionkey = region.r_regionkey)
                                       ->  Seq Scan on region
                                             Filter: (r_name = 'AMERICA'::bpchar)
                                       ->  Hash Join
                                             Hash Cond: (supplier.s_nationkey = nation.n_nationkey)
                                             ->  Seq Scan on supplier
                                             ->  Hash
                                                   ->  Seq Scan on nation
                                 ->  Index Scan using idx_partsupp_suppkey on partsupp
                                       Index Cond: (ps_suppkey = supplier.s_suppkey)
               SubPlan 1
                 ->  Aggregate
                       ->  Nested Loop
                             Join Filter: (nation_1.n_regionkey = region_1.r_regionkey)
                             ->  Seq Scan on region region_1
                                   Filter: (r_name = 'AMERICA'::bpchar)
                             ->  Nested Loop
                                   ->  Nested Loop
                                         ->  Index Scan using idx_partsupp_partkey on partsupp partsupp_1
                                               Index Cond: (part.p_partkey = ps_partkey)
                                         ->  Index Scan using supplier_pkey on supplier supplier_1
                                               Index Cond: (s_suppkey = partsupp_1.ps_suppkey)
                                   ->  Index Scan using nation_pkey on nation nation_1
                                         Index Cond: (n_nationkey = supplier_1.s_nationkey)

“Merge Join”节点在“Gather Merge”上。因此merge不使用并行。但是“Parallel Index Scan”仍旧有助于part_pkey。

10、Partition-wise join

PgSQL11默认禁止partition-wise join特性。它有一个很高的规划代价。分区表可以一个分区一个分区的进行join。允许使用更小的hash table。每个per-partition join操作可以并行:

tpch=# set enable_partitionwise_join=t;
tpch=# explain (costs off) select * from prt1 t1, prt2 t2
where t1.a = t2.b and t1.b = 0 and t2.b between 0 and 10000;
                    QUERY PLAN                     
---------------------------------------------------
 Append
   ->  Hash Join
         Hash Cond: (t2.b = t1.a)
         ->  Seq Scan on prt2_p1 t2
               Filter: ((b >= 0) AND (b <= 10000))
         ->  Hash
               ->  Seq Scan on prt1_p1 t1
                     Filter: (b = 0)
   ->  Hash Join
         Hash Cond: (t2_1.b = t1_1.a)
         ->  Seq Scan on prt2_p2 t2_1
               Filter: ((b >= 0) AND (b <= 10000))
         ->  Hash
               ->  Seq Scan on prt1_p2 t1_1
                     Filter: (b = 0)
tpch=# set parallel_setup_cost = 1;
tpch=# set parallel_tuple_cost = 0.01;
tpch=# explain (costs off) select * from prt1 t1, prt2 t2
where t1.a = t2.b and t1.b = 0 and t2.b between 0 and 10000;
                        QUERY PLAN                         
-----------------------------------------------------------
 Gather
   Workers Planned: 4
   ->  Parallel Append
         ->  Parallel Hash Join
               Hash Cond: (t2_1.b = t1_1.a)
               ->  Parallel Seq Scan on prt2_p2 t2_1
                     Filter: ((b >= 0) AND (b <= 10000))
               ->  Parallel Hash
                     ->  Parallel Seq Scan on prt1_p2 t1_1
                           Filter: (b = 0)
         ->  Parallel Hash Join
               Hash Cond: (t2.b = t1.a)
               ->  Parallel Seq Scan on prt2_p1 t2
                     Filter: ((b >= 0) AND (b <= 10000))
               ->  Parallel Hash
                     ->  Parallel Seq Scan on prt1_p1 t1
                           Filter: (b = 0)

分区连接只有在分区足够大的情况下才能使用并行执行

11、Parallel Append

Parallel Append通常在UNION ALL中。缺点:较小的并行度,因为每个worker进程最终都为一个查询服务。即使启用了4个进程,也会仍旧发起2个:

tpch=# explain (costs off) select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day union all select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '2000-12-01' - interval '105' day;
                                           QUERY PLAN                                           
------------------------------------------------------------------------------------------------
 Gather
   Workers Planned: 2
   ->  Parallel Append
         ->  Aggregate
               ->  Seq Scan on lineitem
                     Filter: (l_shipdate <= '2000-08-18 00:00:00'::timestamp without time zone)
         ->  Aggregate
               ->  Seq Scan on lineitem lineitem_1
                     Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)

12、更重要的变量

WORKER_MEM:限制每个进程的使用内存。每个查询:work_mem*processes*joins-->会导致内存使用很大

max_parallel_workers_per_gather:执行器使用多少进程并发执行该节点

max_worker_processes:根据服务器上CPU核数调整进程数

max_parallel_workers:和并发进程数一样

13、总结

从9.6并行查询执行开始,可以显著提高扫描许多行或索引记录的复杂查询的性能。不要忘记在高oltp工作负载的服务器上禁止并行执行。顺序扫描或索引扫描仍然耗费大量资源。如果您没有针对整个数据集运行报表,那么只需添加缺失的索引或使用适当的分区就可以提高查询性能。

原文

https://www.percona.com/blog/parallel-queries-in-postgresql/

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