Sybase，A left join B 与 B left join A 速度相差太大，并且执行计划也不一样，求解

moses3017

免费乐捐，感谢支持

Sybase数据库，A表数据量122806，B表数据量198161，通过N_STORAGE_ID字段做left join，此字段在A、B两张表中均不是主键，A、B表均有主键，没有索引。
1） SELECT count(*) FROM B b LEFT JOIN A a ON a.N_STORAGE_ID = b.N_STORAGE_ID 执行时间2s
2） SELECT count(*) FROM A a LEFT JOIN B b ON a.N_STORAGE_ID = b.N_STORAGE_ID 执行时间：半个小时搞不定
执行计划：
Sql代码

1. 
   
2. 第一种情况 1）
   
3. QUERY PLAN FOR STATEMENT 1 (at line 1).
   
4. 
   
5. 
   
6. 
   
7. 
   
8.     STEP 1
   
9.         The type of query is EXECUTE.
   
10.         Executing a previously cached statement.
    
11. 
    
12. 
    
13. Parse and Compile Time 0.
    
14. SQL Server cpu time: 0 ms.
    
15. 
    
16. 
    
17. QUERY PLAN FOR STATEMENT 1 (at line 1).
    
18.     Executed in parallel by coordinating process and 6 worker processes.
    
19. 
    
20. 
    
21. 
    
22. 
    
23.     STEP 1
    
24.         The type of query is INSERT.
    
25.         The update mode is direct.
    
26.         Executed in parallel by coordinating process and 6 worker processes.
    
27.         Worktable1 created for REFORMATTING.
    
28. 
    
29. 
    
30.         FROM TABLE
    
31.             XZ_GLY_LDJLB
    
32.             a
    
33.         Nested iteration.
    
34.         Table Scan.
    
35.         Forward scan.
    
36.         Positioning at start of table.
    
37.         Executed in parallel with a 6-way hash scan.
    
38.         Using I/O Size 128 Kbytes for data pages.
    
39.         With LRU Buffer Replacement Strategy for data pages.
    
40.         TO TABLE
    
41.             Worktable1.
    
42. 
    
43. 
    
44.     STEP 2
    
45.         The type of query is SELECT.
    
46.         Evaluate Ungrouped COUNT AGGREGATE.
    
47.         Executed in parallel by coordinating process and 6 worker processes.
    
48. 
    
49. 
    
50.         FROM TABLE
    
51.             IDLE_DEVICE
    
52.             b
    
53.         Nested iteration.
    
54.         Table Scan.
    
55.         Forward scan.
    
56.         Positioning at start of table.
    
57.         Executed in parallel with a 6-way hash scan.
    
58.         Using I/O Size 128 Kbytes for data pages.
    
59.         With LRU Buffer Replacement Strategy for data pages.
    
60. 
    
61. 
    
62.         FROM TABLE
    
63.             Worktable1.
    
64.         Nested iteration.
    
65.         Using Clustered Index.
    
66.         Forward scan.
    
67.         Positioning by key.
    
68.         Using I/O Size 128 Kbytes for data pages.
    
69.         With LRU Buffer Replacement Strategy for data pages.
    
70. 
    
71. 
    
72.         Parallel result buffer merge.
    
73. 
    
74. 
    
75.     STEP 3
    
76.         The type of query is SELECT.
    
77.         Executed by coordinating process.
    
78. 
    
79. 
    
80. Parse and Compile Time 0.
    
81. SQL Server cpu time: 0 ms.
    
82. 
    
83. Execution Time 0.
    
84. SQL Server cpu time: 0 ms.  SQL Server elapsed time: 0 ms.

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Sql代码

1. 第二种情况 2）
   
2. 2)QUERY PLAN FOR STATEMENT 1 (at line 1).
   
3. 
   
4. 
   
5. 
   
6. 
   
7.     STEP 1
   
8.         The type of query is EXECUTE.
   
9.         Executing a newly cached statement.
   
10. 
    
11. 
    
12. Parse and Compile Time 0.
    
13. SQL Server cpu time: 0 ms.
    
14. 
    
15. 
    
16. QUERY PLAN FOR STATEMENT 1 (at line 1).
    
17.     Executed in parallel by coordinating process and 6 worker processes.
    
18. 
    
19. 
    
20. 
    
21. 
    
22.     STEP 1
    
23.         The type of query is SELECT.
    
24.         Evaluate Ungrouped COUNT AGGREGATE.
    
25.         Executed in parallel by coordinating process and 6 worker processes.
    
26. 
    
27. 
    
28.         FROM TABLE
    
29.             XZ_GLY_LDJLB
    
30.             a
    
31.         Nested iteration.
    
32.         Table Scan.
    
33.         Forward scan.
    
34.         Positioning at start of table.
    
35.         Executed in parallel with a 6-way hash scan.
    
36.         Using I/O Size 128 Kbytes for data pages.
    
37.         With LRU Buffer Replacement Strategy for data pages.
    
38. 
    
39. 
    
40.         FROM TABLE
    
41.             IDLE_DEVICE
    
42.             b
    
43.         Nested iteration.
    
44.         Table Scan.
    
45.         Forward scan.
    
46.         Positioning at start of table.
    
47.         Using I/O Size 128 Kbytes for data pages.
    
48.         With LRU Buffer Replacement Strategy for data pages.
    
49. 
    
50. 
    
51.         Parallel result buffer merge.
    
52. 
    
53. 
    
54.     STEP 2
    
55.         The type of query is SELECT.
    
56.         Executed by coordinating process.
    
57. 
    
58. 
    
59. Parse and Compile Time 0.
    
60. SQL Server cpu time: 0 ms.
    
61. 
    
62. Execution Time 0.
    
63. SQL Server cpu time: 0 ms.  SQL Server elapsed time: 0 ms.
    

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这让我苦思不得其解，大家帮忙啊

shakeone

第一个plan:
step1: 为A建了个worktable，这个worktable有个clustered index
step2: nested loop join, inner table是这个work table的clustered index, outer table是B，所以这样的join是很快的，因为inner table很小，可以一直cache in memory
step3: 输出结果
第二个plan：
没有使用刚才建立的worktable的index，同样的nested loop join，inner table为B，outer table为A，所以性能很差，因为B不能被cache in memory，I/O很多次。
所以关键还是execution/optimizer做的太滥，给你个work arround，就是第一个执行完毕后，drop table XZ_GLY_LDJLB

shakeone

你用的估计是15x，我都觉得15x的qp做得烂了