这篇文章主要介绍“怎么理解ORACLE AWR报告”,在日常操作中,相信很多人在怎么理解ORACLE AWR报告问题上存在疑惑,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”怎么理解ORACLE AWR报告”的疑惑有所帮助!接下来,请跟着小编一起来学习吧!
ORACLE AWR报告详细分析
AWR 是 Oracle 10g 版本 推出的新特性, 全称叫Automatic Workload Repository-自动负载信息库
AWR 是通过对比两次快照(snapshot)收集到的统计信息,来生成报表数据,生成的报表包括多个部分。
WORKLOAD REPOSITORY report for
DB Name | DB Id | Instance | Inst num | Release | RAC | Host |
ICCI | 1314098396 | ICCI1 | 1 | 10.2.0.3.0 | YES | HPGICCI1 |
| Snap Id | Snap Time | Sessions | Cursors/Session |
Begin Snap: | 2678 | 25-Dec-08 14:04:50 | 24 | 1.5 |
End Snap: | 2680 | 25-Dec-08 15:23:37 | 26 | 1.5 |
Elapsed: |
| 78.79 (mins) |
|
|
DB Time: |
| 11.05 (mins) |
|
|
DB Time不包括Oracle后台进程消耗的时间。如果DB Time远远小于Elapsed时间,说明数据库比较空闲。
db time= cpu time + wait time(不包含空闲等待) (非后台进程)
说白了就是db time就是记录的服务器花在数据库运算(非后台进程)和等待(非空闲等待)上的时间
DB time = cpu
time + all of nonidle wait event time
在79分钟里(其间收集了3次快照数据),数据库耗时11分钟,RDA数据中显示系统有8个逻辑CPU(4个物理CPU),
平均每个CPU耗时1.4分钟,CPU利用率只有大约2%(1.4/79)。说明系统压力非常小。
列出下面这两个来做解释:
Report A:
Snap Id Snap Time Sessions Curs/Sess
--------- ------------------- -------- ---------
Begin Snap: 4610 24-Jul-08 22:00:54 68 19.1
End Snap: 4612 24-Jul-08 23:00:25 17 1.7
Elapsed: 59.51 (mins)
DB Time: 466.37 (mins)
Report B:
Snap Id Snap Time Sessions Curs/Sess
--------- ------------------- -------- ---------
Begin Snap: 3098 13-Nov-07 21:00:37 39 13.6
End Snap: 3102 13-Nov-07 22:00:15 40 16.4
Elapsed: 59.63 (mins)
DB Time: 19.49 (mins)
服务器是AIX的系统,4个双核cpu,共8个核:
/sbin> bindprocessor -q
The available processors are: 0 1 2 3 4 5 6 7
先说Report
A,在snapshot间隔中,总共约60分钟,cpu就共有60*8=480分钟,DB
time为466.37分钟
则:cpu花费了466.37分钟在处理Oralce非空闲等待和运算上(比方逻辑读)
也就是说cpu有 466.37/480*100% 花费在处理Oracle的操作上,这还不包括后台进程
看Report B,总共约60分钟,cpu有 19.49/480*100% 花费在处理Oracle的操作上
很显然,Report B中服务器的平均负载很低。
从awr report的Elapsed time和DB
Time就能大概了解db的负载。
可是对于批量系统,数据库的工作负载总是集中在一段时间内。如果快照周期不在这一段时间内,
或者快照周期跨度太长而包含了大量的数据库空闲时间,所得出的分析结果是没有意义的.
这也说明选择分析时间段很关键,要选择能够代表性能问题的时间段。
| Begin | End |
|
|
Buffer Cache: | 3,344M | 3,344M | Std Block Size: | 8K |
Shared Pool Size: | 704M | 704M | Log Buffer: | 14,352K |
显示SGA中每个区域的大小(在AMM改变它们之后),可用来与初始参数值比较。
shared pool主要包括library cache和dictionary cache。
library cache用来存储最近解析(或编译)后SQL、PL/SQL和Java classes等。
dictionary cache用来存储最近引用的数据字典。
发生在library cache或dictionary cache的cache miss代价要比发生在buffer cache的代价高得多。
因此shared pool的设置要确保最近使用的数据都能被cache。
| Per Second | Per Transaction |
Redo size: | 918,805.72 | 775,912.72 |
Logical reads: | 3,521.77 | 2,974.06 |
Block changes: | 1,817.95 | 1,535.22 |
Physical reads: | 68.26 | 57.64 |
Physical writes: | 362.59 | 306.20 |
User calls: | 326.69 | 275.88 |
Parses: | 38.66 | 32.65 |
Hard parses: | 0.03 | 0.03 |
Sorts: | 0.61 | 0.51 |
Logons: | 0.01 | 0.01 |
Executes: | 354.34 | 299.23 |
Transactions: | 1.18 |
|
% Blocks changed per Read: | 51.62 | Recursive Call %: | 51.72 |
Rollback per transaction %: | 85.49 | Rows per Sort: | ######## |
显示数据库负载概况,将之与基线数据比较才具有更多的意义,如果每秒或每事务的负载变化不大,说明应用运行比较稳定。
单个的报告数据只说明应用的负载情况,绝大多数据并没有一个所谓“正确”的值,然而
Logons大于每秒1~2个、Hard
parses大于每秒100、全部parses超过每秒300表明可能有争用问题。
Redo size:每秒产生的日志大小(单位字节),可标志数据变更频率, 数据库任务的繁重与否。
Logical reads:每秒/每事务逻辑读的块数.平决每秒产生的逻辑读的block数。Logical Reads= Consistent Gets + DB
Block Gets
Block changes:每秒/每事务修改的块数
Physical reads:每秒/每事务物理读的块数
Physical writes:每秒/每事务物理写的块数
User calls:每秒/每事务用户call次数
Parses:SQL解析的次数.每秒解析次数,包括fast
parse,soft parse和hard parse三种数量的综合。
软解析每秒超过300次意味着你的"应用程序"效率不高,调整session_cursor_cache。
在这里,fast parse指的是直接在PGA中命中的情况(设置了session_cached_cursors=n);
soft parse是指在shared
pool中命中的情形;hard parse则是指都不命中的情况。
Hard parses:其中硬解析的次数,硬解析太多,说明SQL重用率不高。
每秒产生的硬解析次数, 每秒超过100次,就可能说明你绑定使用的不好,也可能是共享池设置不合理。
这时候可以启用参数cursor_sharing=similar|force,该参数默认值为exact。但该参数设置为similar时,存在bug,可能导致执行计划的不优。
Sorts:每秒/每事务的排序次数
Logons:每秒/每事务登录的次数
Executes:每秒/每事务SQL执行次数
Transactions:每秒事务数.每秒产生的事务数,反映数据库任务繁重与否。
Blocks changed per Read:表示逻辑读用于修改数据块的比例.在每一次逻辑读中更改的块的百分比。
Recursive Call:递归调用占所有操作的比率.递归调用的百分比,如果有很多PL/SQL,那么这个值就会比较高。
Rollback per
transaction:每事务的回滚率.看回滚率是不是很高,因为回滚很耗资源 ,如果回滚率过高,
可能说明你的数据库经历了太多的无效操作 ,过多的回滚可能还会带来Undo Block的竞争
该参数计算公式如下: Round(User
rollbacks / (user commits + user rollbacks) ,4)* 100% 。
Rows per Sort:每次排序的行数
注:
Oracle的硬解析和软解析
提到软解析(soft prase)和硬解析(hard prase),就不能不说一下Oracle对sql的处理过程。
当你发出一条sql语句交付Oracle,在执行和获取结果前,Oracle对此sql将进行几个步骤的处理过程:
1、语法检查(syntax check)
检查此sql的拼写是否语法。
2、语义检查(semantic check)
诸如检查sql语句中的访问对象是否存在及该用户是否具备相应的权限。
3、对sql语句进行解析(prase)
利用内部算法对sql进行解析,生成解析树(parse tree)及执行计划(execution plan)。
4、执行sql,返回结果(execute and return)
其中,软、硬解析就发生在第三个过程里。
Oracle利用内部的hash算法来取得该sql的hash值,然后在library cache里查找是否存在该hash值;
假设存在,则将此sql与cache中的进行比较;
假设“相同”,就将利用已有的解析树与执行计划,而省略了优化器的相关工作。这也就是软解析的过程。
诚然,如果上面的2个假设中任有一个不成立,那么优化器都将进行创建解析树、生成执行计划的动作。这个过程就叫硬解析。
创建解析树、生成执行计划对于sql的执行来说是开销昂贵的动作,所以,应当极力避免硬解析,尽量使用软解析
Buffer Nowait %: | 100.00 | Redo NoWait %: | 100.00 |
Buffer Hit %: | 98.72 | In-memory Sort %: | 99.86 |
Library Hit %: | 99.97 | Soft Parse %: | 99.92 |
Execute to Parse %: | 89.09 | Latch Hit %: | 99.99 |
Parse CPU to Parse Elapsd %: | 7.99 | % Non-Parse CPU: | 99.95 |
本节包含了Oracle关键指标的内存命中率及其它数据库实例操作的效率。其中Buffer Hit
Ratio 也称Cache Hit
Ratio,
Library Hit
ratio也称Library
Cache Hit ratio。
同Load Profile一节相同,这一节也没有所谓“正确”的值,而只能根据应用的特点判断是否合适。
在一个使用直接读执行大型并行查询的DSS环境,20%的Buffer Hit Ratio是可以接受的,而这个值对于一个OLTP系统是完全不能接受的。
根据Oracle的经验,对于OLTP系统,Buffer Hit Ratio理想应该在90%以上。
Buffer Nowait表示在内存获得数据的未等待比例。在缓冲区中获取Buffer的未等待比率
Buffer Nowait的这个值一般需要大于99%。否则可能存在争用,可以在后面的等待事件中进一步确认。
buffer hit表示进程从内存中找到数据块的比率,监视这个值是否发生重大变化比这个值本身更重要。
对于一般的OLTP系统,如果此值低于80%,应该给数据库分配更多的内存。
数据块在数据缓冲区中的命中率,通常应在95%以上。否则,小于95%,需要调整重要的参数,小于90%可能是要加db_cache_size。
一个高的命中率,不一定代表这个系统的性能是最优的,比如大量的非选择性的索引被频繁访问,就会造成命中率很高的假相(大量的db
file sequential read)
但是一个比较低的命中率,一般就会对这个系统的性能产生影响,需要调整。命中率的突变,往往是一个不好的信息。
如果命中率突然增大,可以检查top buffer get SQL,查看导致大量逻辑读的语句和索引,
如果命中率突然减小,可以检查top physical reads SQL,检查产生大量物理读的语句,主要是那些没有使用索引或者索引被删除的。
Redo NoWait表示在LOG缓冲区获得BUFFER的未等待比例。如果太低(可参考90%阀值),考虑增加LOG BUFFER。
当redo
buffer达到1M时,就需要写到redo log文件,所以一般当redo buffer设置超过1M,不太可能存在等待buffer空间分配的情况。
当前,一般设置为2M的redo buffer,对于内存总量来说,应该不是一个太大的值。
library hit表示Oracle从Library Cache中检索到一个解析过的SQL或PL/SQL语句的比率,当应用程序调用SQL或存储过程时,
Oracle检查Library Cache确定是否存在解析过的版本,如果存在,Oracle立即执行语句;如果不存在,Oracle解析此语句,并在Library Cache中为它分配共享SQL区。
低的library hit ratio会导致过多的解析,增加CPU消耗,降低性能。
如果library hit ratio低于90%,可能需要调大shared
pool区。
STATEMENT在共享区的命中率,通常应该保持在95%以上,否则需要要考虑:加大共享池;使用绑定变量;修改cursor_sharing等参数。
Latch Hit:Latch是一种保护内存结构的锁,可以认为是SERVER进程获取访问内存数据结构的许可。
要确保Latch Hit>99%,否则意味着Shared Pool latch争用,可能由于未共享的SQL,或者Library
Cache太小,可使用绑定变更或调大Shared
Pool解决。
要确保>99%,否则存在严重的性能问题。当该值出现问题的时候,我们可以借助后面的等待时间和latch分析来查找解决问题。
Parse CPU to Parse
Elapsd:解析实际运行时间/(解析实际运行时间+解析中等待资源时间),越高越好。
计算公式为:Parse CPU to Parse Elapsd %= 100*(parse time cpu / parse time
elapsed)。
即:解析实际运行时间/(解析实际运行时间+解析中等待资源时间)。如果该比率为100%,意味着CPU等待时间为0,没有任何等待。
Non-Parse CPU :SQL实际运行时间/(SQL实际运行时间+SQL解析时间),太低表示解析消耗时间过多。
计算公式为:% Non-Parse CPU =round(100*1-PARSE_CPU/TOT_CPU),2)。如果这个值比较小,表示解析消耗的CPU时间过多。
与PARSE_CPU相比,如果TOT_CPU很高,这个比值将接近100%,这是很好的,说明计算机执行的大部分工作是执行查询的工作,而不是分析查询的工作。
Execute to Parse:是语句执行与分析的比例,如果要SQL重用率高,则这个比例会很高。该值越高表示一次解析后被重复执行的次数越多。
计算公式为:Execute to Parse =100 *
(1 - Parses/Executions)。
本例中,差不多每execution 5次需要一次parse。所以如果系统Parses > Executions,就可能出现该比率小于0的情况。
该值<0通常说明shared pool设置或者语句效率存在问题,造成反复解析,reparse可能较严重,或者是可能同snapshot有关,通常说明数据库性能存在问题。
In-memory Sort:在内存中排序的比率,如果过低说明有大量的排序在临时表空间中进行。
考虑调大PGA(10g)。如果低于95%,可以通过适当调大初始化参数PGA_AGGREGATE_TARGET或者SORT_AREA_SIZE来解决,
注意这两个参数设置作用的范围时不同的,SORT_AREA_SIZE是针对每个session设置的,PGA_AGGREGATE_TARGET则时针对所有的sesion的。
Soft Parse:软解析的百分比(softs/softs+hards),近似当作sql在共享区的命中率,太低则需要调整应用使用绑定变量。
sql在共享区的命中率,小于<95%,需要考虑绑定,如果低于80%,那么就可以认为sql基本没有被重用。
| Begin | End |
Memory Usage %: | 47.19 | 47.50 |
% SQL with executions>1: | 88.48 | 79.81 |
% Memory for SQL w/exec>1: | 79.99 | 73.52 |
Memory Usage %:对于一个已经运行一段时间的数据库来说,共享池内存使用率,应该稳定在75%-90%间,
如果太小,说明Shared
Pool有浪费,而如果高于90,说明共享池中有争用,内存不足。
这个数字应该长时间稳定在75%~90%。如果这个百分比太低,表明共享池设置过大,带来额外的管理上的负担,从而在某些条件下会导致性能的下降。
如果这个百分率太高,会使共享池外部的组件老化,如果SQL语句被再次执行,这将使得SQL语句被硬解析。
在一个大小合适的系统中,共享池的使用率将处于75%到略低于90%的范围内.
SQL with executions>1:执行次数大于1的sql比率,如果此值太小,说明需要在应用中更多使用绑定变量,避免过多SQL解析。
在一个趋向于循环运行的系统中,必须认真考虑这个数字。在这个循环系统中,在一天中相对于另一部分时间的部分时间里执行了一组不同的SQL语句。
在共享池中,在观察期间将有一组未被执行过的SQL语句,这仅仅是因为要执行它们的语句在观察期间没有运行。只有系统连续运行相同的SQL语句组,这个数字才会接近100%。
Memory for SQL w/exec>1:执行次数大于1的SQL消耗内存的占比。
这是与不频繁使用的SQL语句相比,频繁使用的SQL语句消耗内存多少的一个度量。
这个数字将在总体上与% SQL with
executions>1非常接近,除非有某些查询任务消耗的内存没有规律。
在稳定状态下,总体上会看见随着时间的推移大约有75%~85%的共享池被使用。如果Statspack报表的时间窗口足够大到覆盖所有的周期,
执行次数大于一次的SQL语句的百分率应该接近于100%。这是一个受观察之间持续时间影响的统计数字。可以期望它随观察之间的时间长度增大而增大。
小结:通过ORACLE的实例有效性统计数据,我们可以获得大概的一个整体印象,然而我们并不能由此来确定数据运行的性能。当前性能问题的确定,
我们主要还是依靠下面的等待事件来确认。我们可以这样理解两部分的内容,hit统计帮助我们发现和预测一些系统将要产生的性能问题,由此我们
可以做到未雨绸缪。而wait事件,就是表明当前数据库已经出现了性能问题需要解决,所以是亡羊补牢的性质。
Event | Waits | Time(s) | Avg Wait(ms) | % Total Call Time | Wait Class |
CPU time |
| 515 |
| 77.6 |
|
SQL*Net more data from client | 27,319 | 64 | 2 | 9.7 | Network |
log file parallel write | 5,497 | 47 | 9 | 7.1 | System I/O |
db file sequential read | 7,900 | 35 | 4 | 5.3 | User I/O |
db file parallel write | 4,806 | 34 | 7 | 5.1 | System I/O |
这是报告概要的最后一节,显示了系统中最严重的5个等待,按所占等待时间的比例倒序列示。当我们调优时,总希望观察到最显著的效果,
因此应当从这里入手确定我们下一步做什么。
例如如果‘buffer
busy wait’是较严重的等待事件,我们应当继续研究报告中Buffer Wait和File/Tablespace
IO区的内容,
识别哪些文件导致了问题。如果最严重的等待事件是I/O事件,我们应当研究按物理读排序的SQL语句区以识别哪些语句在
执行大量I/O,并研究Tablespace和I/O区观察较慢响应时间的文件。如果有较高的LATCH等待,就需要察看详细的LATCH
统计识别哪些LATCH产生的问题。
一个性能良好的系统,cpu
time应该在top 5的前面,否则说明你的系统大部分时间都用在等待上。
在这里,log file parallel write是相对比较多的等待,占用了7%的CPU时间。
通常,在没有问题的数据库中,CPU time总是列在第一个。
更多的等待事件,参见本报告 的Wait Events一节。
| Begin | End |
Number of Instances: | 2 | 2 |
| Per Second | Per Transaction |
Global Cache blocks received: | 4.16 | 3.51 |
Global Cache blocks served: | 5.97 | 5.04 |
GCS/GES messages received: | 408.47 | 344.95 |
GCS/GES messages sent: | 258.03 | 217.90 |
DBWR Fusion writes: | 0.05 | 0.05 |
Estd Interconnect traffic (KB) | 211.16 |
|
Buffer access - local cache %: | 98.60 |
Buffer access - remote cache %: | 0.12 |
Buffer access - disk %: | 1.28 |
Avg global enqueue get time (ms): | 0.1 |
Avg global cache cr block receive time (ms): | 1.1 |
Avg global cache current block receive time (ms): | 0.8 |
Avg global cache cr block build time (ms): | 0.0 |
Avg global cache cr block send time (ms): | 0.0 |
Global cache log flushes for cr blocks served %: | 3.5 |
Avg global cache cr block flush time (ms): | 3.9 |
Avg global cache current block pin time (ms): | 0.0 |
Avg global cache current block send time (ms): | 0.0 |
Global cache log flushes for current blocks served %: | 0.4 |
Avg global cache current block flush time (ms): | 3.0 |
Avg message sent queue time (ms): | 0.0 |
Avg message sent queue time on ksxp (ms): | 0.3 |
Avg message received queue time (ms): | 0.5 |
Avg GCS message process time (ms): | 0.0 |
Avg GES message process time (ms): | 0.0 |
% of direct sent messages: | 14.40 |
% of indirect sent messages: | 77.04 |
% of flow controlled messages: | 8.56 |
Wait Events Statistics
SQL Statistics
Instance Activity Statistics
IO Stats
Buffer Pool Statistics
Advisory Statistics
Wait Statistics
Undo Statistics
Latch Statistics
Segment Statistics
Dictionary Cache Statistics
Library Cache Statistics
Memory Statistics
Streams Statistics
Resource Limit Statistics
init.ora Parameters
Time Model Statistics
Wait Class
Wait Events
Background Wait Events
Operating System Statistics
Service Statistics
Service Wait Class Stats
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/* oracle等待事件是衡量oracle运行状况的重要依据及指示,等待事件分为两类:
空闲等待事件和非空闲等待事件, TIMED_STATISTICS = TRUE 那么等待事件按等待的时间排序,=
FALSE那么事件按等待的数量排序。
运行statspack期间必须session上设置TIMED_STATISTICS = TRUE,否则统计的数据将失真。
空闲等待事件是oracle正等待某种工作,在诊断和优化数据库时候,不用过多注意这部分事件,
非空闲等待事件专门针对oracle的活动,指数据库任务或应用程序运行过程中发生的等待,
这些等待事件是我们在调整数据库应该关注的。
对于常见的等待事件,说明如下:
1) db file scattered read 文件分散读取
该事件通常与全表扫描或者fast full index scan有关。因为全表扫描是被放入内存中进行的进行的,通常情况下基于性能的考虑,有时候也可能是分配不到足够长的连续内存空间,所以会将数据块分散(scattered)读入Buffer Cache中。该等待过大可能是缺少索引或者没有合适的索引(可以调整optimizer_index_cost_adj) 。这种情况也可能是正常的,因为执行全表扫描可能比索引扫描效率更高。当系统存在这些等待时,需要通过检查来确定全表扫描是否必需的来调整。因为全表扫描被置于LRU(Least Recently Used,最近最少适用)列表的冷端(cold end),对于频繁访问的较小的数据表,可以选择把他们Cache 到内存中,以避免反复读取。当这个等待事件比较显著时,可以结合v$session_longops 动态性能视图来进行诊断,该视图中记录了长时间(运行时间超过6 秒的)运行的事物,可能很多是全表扫描操作(不管怎样,这部分信息都是值得我们注意的)。
关于参数OPTIMIZER_INDEX_COST_ADJ=n:该参数是一个百分比值,缺省值为100,可以理解为FULL SCAN COST/INDEX SCAN COST。当n%* INDEX SCAN COST<FULL SCAN COST时,oracle会选择使用索引。在具体设置的时候,我们可以根据具体的语句来调整该值。如果我们希望某个statement使用索引,而实际它确走全表扫描,可以对比这两种情况的执行计划不同的COST,从而设置一个更合适的值。
2) db file sequential read 文件顺序读取整代码,特别是表连接:该事件说明在单个数据块上大量等待,该值过高通常是由于表间连接顺序很糟糕(没有正确选择驱动行源),或者使用了非选择性索引。通过将这种等待与statspack报表中已知其它问题联系起来(如效率不高的sql),通过检查确保索引扫描是必须的,并确保多表连接的连接顺序来调整。
3) buffer busy wait 缓冲区忙 增大DB_CACHE_SIZE,加速检查点,调整代码:
当进程需要存取SGA中的buffer的时候,它会依次执行如下步骤的操作:
当缓冲区以一种非共享方式或者如正在被读入到缓冲时,就会出现该等待。该值不应该大于1%。当出现等待问题时,可以检查缓冲等待统计部分(或V$WAITSTAT),确定该等待发生在什么位置:
a) 如果等待是否位于段头(Segment Header)。这种情况表明段中的空闲列表(freelist)的块比较少。可以考虑增加空闲列表(freelist,对于Oracle8i DMT)或者增加freelist groups(在很多时候这个调整是立竿见影的(alter table tablename strorage(freelists 2)),在8.1.6之前,这个freelists参数不能动态修改;在8.1.6及以后版本,动态修改feelists需要设置COMPATIBLE至少为8.1.6)。也可以增加PCTUSED与PCTFREE之间距离(PCTUSED-to-pctfree gap),其实就是说降低PCTUSED的值,尽快使块返回freelist列表被重用。如果支持自动段空间管理(ASSM),也可以使用ASSM模式,这是在ORALCE 920以后的版本中新增的特性。
b) 如果这一等待位于undo header,可以通过增加回滚段(rollback segment)来解决缓冲区的问题。
c) 如果等待位于undo block上,我们需要增加提交的频率,使block可以尽快被重用;使用更大的回滚段;降低一致读所选择的表中数据的密度;增大DB_CACHE_SIZE。
d) 如果等待处于data block,表明出现了hot block,可以考虑如下方法解决: ①将频繁并发访问的表或数据移到另一数据块或者进行更大范围的分布(可以增大pctfree值 ,扩大数据分布,减少竞争),以避开这个"热点"数据块。②也可以减小数据块的大小,从而减少一个数据块中的数据行数,降低数据块的热度,减小竞争;③检查对这些热块操作的SQL语句,优化语句。④增加hot block上的initrans值。但注意不要把initrans值设置的过于高了,通常设置为5就足够了。因为增加事务意味着要增加ITL事务槽,而每个ITL事务槽将占用数据块中24个字节长度。默认情况下,每个数据块或者索引块中是ITL槽是2个,在增加initrans的时候,可以考虑增大数据块所在的表的PCTFREE值,这样Oracle会利用PCTFREE部分的空间增加ITL slot数量,最大达到maxtrans指定。
e) 如果等待处于index block,应该考虑重建索引、分割索引或使用反向键索引。为了防止与数据块相关的缓冲忙等待,也可以使用较小的块,在这种情况下,单个块中的记录就较少,所以这个块就不是那么"繁忙"。或者可以设置更大的PCTFREE,使数据扩大物理分布,减少记录间的热点竞争。在执行DML (insert/update/ delete)时,Oracle向数据块中写入信息,对于多事务并发访问的数据表,关于ITL的竞争和等待可能出现,为了减少这个等待,可以增加initrans,使用多个ITL槽。在Oracle9i 中,可以使用ASSM这个新特性Oracle 使用位图来管理空间使用,减小争用。
当进程需要存取SGA中的buffer的时候,它会依次执行如下步骤的操作:
1.获得cache buffers chains latch,遍历那条buffer chain直到找到需要的buffer header
2.根据需要进行的操作类型(读或写),它需要在buffer header上获得一个共享或独占模式的buffer pin或者buffer lock
3.若进程获得buffer header pin,它会释放获得的cache buffers chains latch,然后执行对buffer block的操作
4.若进程无法获得buffer header pin,它就会在buffer busy waits事件上等待
进程之所以无法获得buffer header pin,是因为为了保证数据的一致性,同一时刻一个block只能被一个进程pin住进行存取,
因此当一个进程需要存取buffer cache中一个被其他进程使用的block的时候,这个进程就会产生对该block的buffer busy waits事件。
截至Oracle 9i,buffer busy waits事件的p1,p2,p3三个参数分别是file#,block#和id,分别表示等待的buffer block所在的文件编号,
块编号和具体的等待原因编号,到了Oracle 10g,前两个参数没变,第3个参数变成了块类型编号,这一点可以通过查询v$event_name视图来进行验证:
Oracle 9i
SQL> select parameter1,parameter2,parameter3 from v$event_name where name='buffer busy waits'
PARAMETER1 PARAMETER2 PARAMETER3
------------------------ ------------------------
------------------------
file# block# id
Oracle 10g
PARAMETER1 PARAMETER2 PARAMETER3
------------------------ ------------------------
------------------------
file# block# class#
在诊断buffer busy waits事件的过程中,获取如下信息会很有用:
1.获取产生buffer busy waits事件的等待原因编号,这可以通过查询该事件的p3参数值获得
2.获取产生此事件的SQL语句,可以通过如下的查询获得:
select sql_text from v$sql t1,v$session t2,v$session_wait t3
where t1.address=t2.sql_address and
t1.hash_value=t2.sql_hash_value
and t2.sid=t3.sid and t3.event='buffer busy waits';
3.获取等待的块的类型以及所在的segment,可以通过如下查询获得:
select 'Segment Header' class,a.segment_type,a.segment_name,a.partition_name from dba_segments a,v$session_wait b
where a.header_file=b.p1 and a.header_block=b.p2 and b.event='buffer busy
waits'
union
select 'Freelist Groups' class,a.segment_type,a.segment_name,a.partition_name from dba_segments a,v$session_wait b
where a.header_file=b.p1 and b.p2 between a.header_block+1 and (a.header_block+a.freelist_groups) and a.freelist_groups>1 and b.event='buffer busy waits'
union
select a.segment_type||' block' class,a.segment_type,a.segment_name,a.partition_name
from dba_extents a,v$session_wait b
where a.file_id=b.p1 and b.p2 between a.block_id and a.block_id+a.blocks-1 and b.event='buffer busy
waits' and not exists(select 1 from dba_segments where
header_file=b.p1 and header_block= b.p2);
查询的第一部分:如果等待的块类型是segment header,那么可以直接拿buffer busy waits事件的p1和p2参数去dba_segments视图中匹配header_file和header_block字段即可找到等待的segment名称和segment类型,进行相应调整
查询的第二部分:如果等待的块类型是freelist groups,也可以在dba_segments视图中找出对应的segment名称和segment类型,注意这里的参数p2表示的freelist groups的位置是在segment的header_block+1到header_block+freelist
groups组数之间,并且freelist groups组数大于1
查询的第三部分:如果等待的块类型是普通的数据块,那么可以用p1、p2参数和dba_extents进行联合查询得到block所在的segment名称和segment类型
对于不同的等待块类型,我们采取不同的处理办法:
1.data segment header:
进程经常性的访问data segment header通常有两个原因:获取或修改process freelists信息、扩展高水位标记,针对第一种情况,进程频繁访问process freelists信息导致freelist争用,我们可以增大相应的segment对象的存储参数freelist或者freelist groups;若由于数据块频繁进出freelist而导致进程经常要修改freelist,则可以将pctfree值和pctused值设置较大的差距,从而避免数据块频繁进出freelist;对于第二种情况,由于该segment空间消耗很快,而设置的next extent过小,导致频繁扩展高水位标记,解决的办法是增大segment对象的存储参数next extent或者直接在创建表空间的时候设置extent size uniform
2.data block:
某一或某些数据块被多个进程同时读写,成为热点块,可以通过如下这些办法来解决这个问题:
(1)降低程序的并发度,如果程序中使用了parallel查询,降低parallel degree,以免多个parallel slave同时访问同样的数据对象而形成等待降低性能
(2)调整应用程序使之能读取较少的数据块就能获取所需的数据,减少buffer gets和physical reads
(3)减少同一个block中的记录数,使记录分布于更多的数据块中,这可以通过若干途径实现:可以调整segment对象的pctfree值,可以将segment重建到block size较小的表空间中,还可以用alter table minimize
records_per_block语句减少每块中的记录数
(4)若热点块对象是类似自增id字段的索引,则可以将索引转换为反转索引,打散数据分布,分散热点块
3.undo segment header:
undo segment header争用是因为系统中undo segment不够,需要增加足够的undo segment,根据undo segment的管理方法,若是手工管理模式,需要修改rollback_segments初始化参数来增加rollback segment,若是自动管理模式,可以减小transactions_per_rollback_segment初始化参数的值来使oracle自动增多rollback segment的数量
4.undo block:
undo block争用是由于应用程序中存在对数据的读和写同时进行,读进程需要到undo segment中去获得一致性数据,解决办法是错开应用程序修改数据和大量查询数据的时间
小结:buffer busy waits事件是oracle等待事件中比较复杂的一个,其形成原因很多,需要根据p3参数对照Oracle提供的原因代码表进行相应的诊断,10g以后则需要根据等待的block类型结合引起等待时间的具体SQL进行分析,采取相应的调整措施
4) latch free:当闩锁丢失率高于0.5%时,需要调整这个问题。详细的我们在后面的Latch Activity for DB部分说明。
latch是一种低级排队机制,用于保护SGA中共享内存结构。latch就像是一种快速地被获取和释放的内存锁。用于防止共享内存结构被多个用户同时访问。如果latch不可用,就会记录latch释放失败(latch free miss )。有两种与闩有关的类型:
■ 立刻。
■ 可以等待。
假如一个进程试图在立刻模式下获得闩,而该闩已经被另外一个进程所持有,如果该闩不能立可用的话,那么该进程就不会为获得该闩而等待。它将继续执行另一个操作。
大多数latch问题都与以下操作相关:
没有很好的是用绑定变量(library cache latch)、重作生成问题(redo allocation latch)、缓冲存储竞争问题(cache buffers LRU chain),以及buffer cache中的存在"热点"块(cache buffers chain)。
通常我们说,如果想设计一个失败的系统,不考虑绑定变量,这一个条件就够了,对于异构性强的系统,不使用绑定变量的后果是极其严重的。
另外也有一些latch等待与bug有关,应当关注Metalink相关bug的公布及补丁的发布。当latch miss ratios大于0.5%时,就应当研究这一问题。
Oracle的latch机制是竞争,其处理类似于网络里的CSMA/CD,所有用户进程争夺latch, 对于愿意等待类型(willing-to-wait)的latch,如果一个进程在第一次尝试中没有获得latch,那么它会等待并且再尝试一次,如果经过_spin_count次争夺不能获得latch, 然后该进程转入睡眠状态,持续一段指定长度的时间,然后再次醒来,按顺序重复以前的步骤.在8i/9i中默认值是_spin_count=2000。
如果SQL语句不能调整,在8.1.6版本以上,Oracle提供了一个新的初始化参数: CURSOR_SHARING可以通过设置CURSOR_SHARING = force 在服务器端强制绑定变量。设置该参数可能会带来一定的副作用,对于Java的程序,有相关的bug,具体应用应该关注Metalink的bug公告。
***Latch 问题及可能解决办法
------------------------------
* Library Cache and
Shared Pool (未绑定变量---绑定变量,调整shared_pool_size)
每当执行SQL或PL/SQL存储过程,包,函数和触发器时,这个Latch即被用到.Parse操作中此Latch也会被频繁使用.
* Redo Copy (增大_LOG_SIMULTANEOUS_COPIES参数)
重做拷贝Latch用来从PGA向重做日志缓冲区拷贝重做记录.
* Redo Allocation (最小化REDO生成,避免不必要提交)
此Latch用来分配重做日志缓冲区中的空间,可以用NOLOGGING来减缓竞争.
* Row Cache Objects (增大共享池)
数据字典竞争.过度parsing.
* Cache Buffers Chains
(_DB_BLOCK_HASH_BUCKETS应增大或设为质数)
"过热"数据块造成了内存缓冲链Latch竞争.
* Cache Buffers Lru Chain
(调整SQL,设置DB_BLOCK_LRU_LATCHES,或使用多个缓冲区池)
扫描全部内存缓冲区块的LRU(最近最少使用)链时要用到内存缓冲区LRU链Latch.太小内存缓冲区、过大的内存缓冲区吞吐量、过多的内存中进行的排序操作、DBWR速度跟不上工作负载等会引起此Latch竞争。
5) Enqueue 队列是一种锁,保护一些共享资源,防止并发的DML操作。队列采用FIFO策略,注意latch并不是采用的FIFO机制。比较常见的有3种类型的队列:ST队列,HW队列,TX4队列。
ST Enqueue的等待主要是在字典管理的表空间中进行空间管理和分配时产生的。解决方法:1)将字典管理的表空间改为本地管理模式 2)预先分配分区或者将有问题的字典管理的表空间的next extent设置大一些。
HW Enqueue是用于segment的HWM的。当出现这种等待的时候,可以通过手工分配extents来解决。
TX4 Enqueue等待是最常见的等待情况。通常有3种情况会造成这种类型的等待:1)唯一索引中的重复索引。解决方法:commit或者rollback以释放队列。 2)对同一个位图索引段(bitmap index fragment)有多个update,因为一个bitmap index fragment可能包含了多个rowid,所以当多个用户更新时,可能一个用户会锁定该段,从而造成等待。解决方法同上。3)有多个用户同时对一个数据块作update,当然这些DML操作可能是针对这个数据块的不同的行,如果此时没有空闲的ITL槽,就会产生一个block-level锁。解决方法:增大表的initrans值使创建更多的ITL槽;或者增大表的pctfree值,这样oracle可以根据需要在pctfree的空间创建更多的ITL槽;使用smaller block size,这样每个块中包含行就比较少,可以减小冲突发生的机会。
AWR报告分析--等待事件-队列.doc
6) Free Buffer 释放缓冲区:这个等待事件表明系统正在等待内存中的可用空间,这说明当前Buffer 中已经没有Free 的内存空间。如果应用设计良好,SQL 书写规范,充分绑定变量,那这种等待可能说明Buffer Cache 设置的偏小,你可能需要增大DB_CACHE_SIZE。该等待也可能说明DBWR 的写出速度不够,或者磁盘存在严重的竞争,可以需要考虑增加检查点、使用更多的DBWR 进程,或者增加物理磁盘的数量,分散负载,平衡IO。
7) Log file single write:该事件仅与写日志文件头块相关,通常发生在增加新的组成员和增进序列号时。头块写单个进行,因为头块的部分信息是文件号,每个文件不同。更新日志文件头这个操作在后台完成,一般很少出现等待,无需太多关注。
8) log file parallel write:从log buffer 写redo 记录到redo log 文件,主要指常规写操作(相对于log file sync)。如果你的Log group 存在多个组成员,当flush log buffer 时,写操作是并行的,这时候此等待事件可能出现。尽管这个写操作并行处理,直到所有I/O 操作完成该写操作才会完成(如果你的磁盘支持异步IO或者使用IO SLAVE,那么即使只有一个redo log file member,也有可能出现此等待)。这个参数和log file sync 时间相比较可以用来衡量log file 的写入成本。通常称为同步成本率。改善这个等待的方法是将redo logs放到I/O快的盘中,尽量不使用raid5,确保表空间不是处在热备模式下,确保redo log和data的数据文件位于不同的磁盘中。
9) log file sync:当一个用户提交或回滚数据时,LGWR将会话的redo记录从日志缓冲区填充到日志文件中,用户的进程必须等待这个填充工作完成。在每次提交时都出现,如果这个等待事件影响到数据库性能,那么就需要修改应用程序的提交频率, 为减少这个等待事件,须一次提交更多记录,或者将重做日志REDO LOG 文件访在不同的物理磁盘上,提高I/O的性能。
当一个用户提交或回滚数据时,LGWR 将会话期的重做由日志缓冲器写入到重做日志中。日志文件同步过程必须等待这一过程成功完成。为了减少这种等待事件,可以尝试一次提交更多的记录(频繁的提交会带来更多的系统开销)。将重做日志置于较快的磁盘上,或者交替使用不同物理磁盘上的重做日志,以降低归档对LGWR的影响。
对于软RAID,一般来说不要使用RAID 5,RAID5 对于频繁写入得系统会带来较大的性能损失,可以考虑使用文件系统直接输入/输出,或者使用裸设备(raw device),这样可以获得写入的性能提高。
10) log buffer space:日志缓冲区写的速度快于LGWR写REDOFILE的速度,可以增大日志文件大小,增加日志缓冲区的大小,或者使用更快的磁盘来写数据。
当你将日志缓冲(log buffer)产生重做日志的速度比LGWR 的写出速度快,或者是当日志切换(log switch)太慢时,就会发生这种等待。这个等待出现时,通常表明redo log buffer 过小,为解决这个问题,可以考虑增大日志文件的大小,或者增加日志缓冲器的大小。
另外一个可能的原因是磁盘I/O 存在瓶颈,可以考虑使用写入速度更快的磁盘。在允许的条件下设置可以考虑使用裸设备来存放日志文件,提高写入效率。在一般的系统中,最低的标准是,不要把日志文件和数据文件存放在一起,因为通常日志文件只写不读,分离存放可以获得性能提升。
11) logfile switch:通常是因为归档速度不够快。表示所有的提交(commit)的请求都需要等待"日志文件切换"的完成。Log file Switch 主要包含两个子事件:
log file switch (archiving needed) 这个等待事件出现时通常是因为日志组循环写满以后,第一个日志归档尚未完成,出现该等待。出现该等待,可能表示io 存在问题。解决办法:①可以考虑增大日志文件和增加日志组;②移动归档文件到快速磁盘;③调整log_archive_max_processes。
log file switch (checkpoint incomplete) 当日志组都写完以后,LGWR 试图写第一个log file,如果这时数据库没有完成写出记录在第一个log file 中的dirty 块时(例如第一个检查点未完成),该等待事件出现。该等待事件通常表示你的DBWR 写出速度太慢或者IO 存在问题。为解决该问题,你可能需要考虑增加额外的DBWR 或者增加你的日志组或日志文件大小,或者也可以考虑增加checkpoint的频率。
12) DB File Parallel Write:文件被DBWR并行写时发生。解决办法:改善IO性能。
处理此事件时,需要注意
1)db file parallel write事件只属于DBWR进程。
2)缓慢的DBWR可能影响前台进程。
3)大量的db file parallel write等待时间很可能是I/O问题引起的。(在确认os支持异步io的前提下,你可以在系统中检查disk_asynch_io参数,保证为TRUE。可以通过设置db_writer_processes来提高DBWR进程数量,当然前提是不要超过cpu的数量。)
DBWR进程执行经过SGA的所有数据库写入,当开始写入时,DBWR进程编译一组脏块(dirty block),并且将系统写入调用发布到操作系统。DBWR进程查找在各个时间内写入的块,包括每隔3秒的一次查找,当前台进程提交以清除缓冲区中的内容时:在检查点处查找,当满足_DB_LARGE_DIRTY_QUEUE、_DB_BLOCK_MAX_DIRTY_TARGET和FAST_START_MTTR_TARGET阀值时,等等。
虽然用户会话从来没有经历过db file parallel write等待事件,但这并不意味着它们不会受到这种事件的影响。缓慢的DBWR写入性能可以造成前台会话在write complete waits或free buffer waits事件上等待。DBWR写入性能可能受到如下方面的影响:I/O操作的类型(同步或异步)、存储设备(裸设备或成熟的文件系统)、数据库布局和I/O子系统配置。需要查看的关键数据库统计是当db file parallel write、free buffer waits和write complete waits等待事件互相关联时,系统范围内的TIME_WAITED和AVERAGE_WAIT。
如果db file parallel write平均等待时间大于10cs(或者100ms),则通常表明缓慢的I/O吞吐量。可以通过很多方法来改善平均等待时间。主要的方法是使用正确类型的I/O操作。如果数据文件位于裸设备(raw device)上,并且平台支持异步I/O,就应该使用异步写入。但是,如果数据库位于文件系统上,则应该使用同步写入和直接I/O(这是操作系统直接I/O)。除了确保正在使用正确类型的I/O操作,还应该检查你的数据库布局并使用常见的命令监控来自操作系统的I/O吞吐量。例如sar -d或iostat -dxnC。
当db file parallel write平均等待时间高并且系统繁忙时,用户会话可能开始在free buffer waits事件上等待。这是因为DBWR进程不能满足释放缓冲区的需求。如果free buffer waits事件的TIME_WAITED高,则应该在高速缓存中增加缓冲区数量之前说明DBWR I/O吞吐量的问题。
高db file parallel write平均等待时间的另一个反响是在write complete waits等待事件上的高TIME_WAITED。前台进程不允许修改正在传输到磁盘的块。换句话说,也就是位于DBWR批量写入中的块。前台的会话在write complete waits等待事件上等待。因此,write complete waits事件的出现,一定标志着缓慢的DBWR进程,可以通过改进DBWR I/O吞吐量修正这种延迟。
13) DB File Single Write:当文件头或别的单独块被写入时发生,这一等待直到所有的I/O调用完成。解决办法:改善IO性能。
14) DB FILE Scattered Read:当扫描整个段来根据初始化参数db_file_multiblock_read_count读取多个块时发生,因为数据可能分散在不同的部分,这与分条或分段)相关,因此通常需要多个分散的读来读取所有的数据。等待时间是完成所有I/O调用的时间。解决办法:改善IO性能。
这种情况通常显示与全表扫描相关的等待。
当数据库进行全表扫时,基于性能的考虑,数据会分散(scattered)读入Buffer Cache。如果这个等待事件比较显著,可能说明对于某些全表扫描的表,没有创建索引或者没有创建合适的索引,我们可能需要检查这些数据表已确定是否进行了正确的设置。
然而这个等待事件不一定意味着性能低下,在某些条件下Oracle会主动使用全表扫描来替换索引扫描以提高性能,这和访问的数据量有关,在CBO下Oracle会进行更为智能的选择,在RBO下Oracle更倾向于使用索引。
因为全表扫描被置于LRU(Least Recently Used,最近最少适用)列表的冷端(cold end),对于频繁访问的较小的数据表,可以选择把他们Cache到内存中,以避免反复读取。
当这个等待事件比较显著时,可以结合v$session_longops动态性能视图来进行诊断,该视图中记录了长时间(运行时间超过6秒的)运行的事物,可能很多是全表扫描操作(不管怎样,这部分信息都是值得我们注意的)。
15) DB FILE Sequential Read:当前台进程对数据文件进行常规读时发生,包括索引查找和别的非整段扫描以及数据文件块丢弃等待。等待时间是完成所有I/O调用的时间。解决办法:改善IO性能。
如果这个等待事件比较显著,可能表示在多表连接中,表的连接顺序存在问题,没有正确地使用驱动表;或者可能索引的使用存在问题,并非索引总是最好的选择。在大多数情况下,通过索引可以更为快速地获取记录,所以对于编码规范、调整良好的数据库,这个等待事件很大通常是正常的。有时候这个等待过高和存储分布不连续、连续数据块中部分被缓存有关,特别对于DML频繁的数据表,数据以及存储空间的不连续可能导致过量的单块读,定期的数据整理和空间回收有时候是必须的。
需要注意在很多情况下,使用索引并不是最佳的选择,比如读取较大表中大量的数据,全表扫描可能会明显快于索引扫描,所以在开发中就应该注意,对于这样的查询应该进行避免使用索引扫描。
16) Direct Path Read:一般直接路径读取是指将数据块直接读入PGA中。一般用于排序、并行查询和read ahead操作。这个等待可能是由于I/O造成的。使用异步I/O模式或者限制排序在磁盘上,可能会降低这里的等待时间。
与直接读取相关联的等待事件。当ORACLE将数据块直接读入会话的PGA(进程全局区)中,同时绕过SGA(系统全局区)。PGA中的数据并不和其他的会话共享。即表明,读入的这部分数据该会话独自使用,不放于共享的SGA中。
在排序操作(order by/group by/union/distinct/rollup/合并连接)时,由于PGA中的SORT_AREA_SIZE空间不足,造成需要使用临时表空间来保存中间结果,当从临时表空间读入排序结果时,产生direct path read等待事件。
使用HASH连接的SQL语句,将不适合位于内存中的散列分区刷新到临时表空间中。为了查明匹配SQL谓词的行,临时表空间中的散列分区被读回到内存中(目的是为了查明匹配SQL谓词的行),ORALCE会话在direct path read等待事件上等待。
使用并行扫描的SQL语句也会影响系统范围的direct path read等待事件。在并行执行过程中,direct path read等待事件与从属查询有关,而与父查询无关,运行父查询的会话基本上会在PX Deq:Execute Reply上等待,从属查询会产生direct path read等待事件。
直接读取可能按照同步或异步的方式执行,取决于平台和初始化参数disk_asynch_io参数的值。使用异步I/O时,系统范围的等待的事件的统计可能不准确,会造成误导作用。
17) direct path write:直接路径写该等待发生在,系统等待确认所有未完成的异步I/O 都已写入磁盘。对于这一写入等待,我们应该找到I/O 操作最为频繁的数据文件(如果有过多的排序操作,很有可能就是临时文件),分散负载,加快其写入操作。如果系统存在过多的磁盘排序,会导致临时表空间操作频繁,对于这种情况,可以考虑使用Local管理表空间,分成多个小文件,写入不同磁盘或者裸设备。
在DSS系统中,存在大量的direct path read是很正常的,但是在OLTP系统中,通常显著的直接路径读(direct path read)都意味着系统应用存在问题,从而导致大量的磁盘排序读取操作。
直接路径写(direct paht write)通常发生在Oracle直接从PGA写数据到数据文件或临时文件,这个写操作可以绕过SGA。
这类写入操作通常在以下情况被使用:
·直接路径加载;
·并行DML操作;
·磁盘排序;
·对未缓存的“LOB”段的写入,随后会记录为direct path write(lob)等待。
最为常见的直接路径写,多数因为磁盘排序导致。对于这一写入等待,我们应该找到I/O操作最为频繁的数据文件(如果有过多的排序操作,很有可能就是临时文件),分散负载,加快其写入操作。
18) control file parallel write:当server 进程更新所有控制文件时,这个事件可能出现。如果等待很短,可以不用考虑。如果等待时间较长,检查存放控制文件的物理磁盘I/O 是否存在瓶颈。
多个控制文件是完全相同的拷贝,用于镜像以提高安全性。对于业务系统,多个控制文件应该存放在不同的磁盘上,一般来说三个是足够的,如果只有两个物理硬盘,那么两个控制文件也是可以接受的。在同一个磁盘上保存多个控制文件是不具备实际意义的。减少这个等待,可以考虑如下方法:①减少控制文件的个数(在确保安全的前提下)。②如果系统支持,使用异步IO。③转移控制文件到IO 负担轻的物理磁盘。
19) control file sequential read
control file single write :控制文件连续读/控制文件单个写对单个控制文件I/O 存在问题时,这两个事件会出现。如果等待比较明显,检查单个控制文件,看存放位置是否存在I/O 瓶颈。
20) library cache pin
该事件通常是发生在先有会话在运行PL/SQL,VIEW,TYPES等object时,又有另外的会话执行重新编译这些object,即先给对象加上了一个共享锁,然后又给它加排它锁,这样在加排它锁的会话上就会出现这个等待。P1,P2可与x$kglpn和x$kglob表相关
X$KGLOB (Kernel Generic Library Cache Manager Object)
X$KGLPN (Kernel Generic Library Cache Manager Object Pins)
-- 查询X$KGLOB,可找到相关的object,其SQL语句如下
(即把V$SESSION_WAIT中的P1raw与X$KGLOB中的KGLHDADR相关连)
select kglnaown,kglnaobj from X$KGLOB
where KGLHDADR =(select p1raw from v$session_wait
where event='library cache pin')
-- 查出引起该等待事件的阻塞者的sid
select sid from x$kglpn , v$session
where KGLPNHDL in
(select p1raw from v$session_wait
where wait_time=0 and event like 'library cache pin%')
and KGLPNMOD <> 0
and v$session.saddr=x$kglpn.kglpnuse
-- 查出阻塞者正执行的SQL语句
select sid,sql_text
from v$session, v$sqlarea
where v$session.sql_address=v$sqlarea.address
and sid=<阻塞者的sid>
这样,就可找到"library cache pin"等待的根源,从而解决由此引起的性能问题。
21) library cache lock
该事件通常是由于执行多个DDL操作导致的,即在library
cache object上添加一个排它锁后,又从另一个会话给它添加一个排它锁,这样在第二个会话就会生成等待。可通过到基表x$kgllk中查找其对应的对象。
-- 查询引起该等待事件的阻塞者的sid、会话用户、锁住的对象
select b.sid,a.user_name,a.kglnaobj
from x$kgllk a , v$session b
where a.kgllkhdl in
(select p1raw from v$session_wait
where wait_time=0 and event = 'library cache lock')
and a.kgllkmod <> 0
and b.saddr=a.kgllkuse
当然也可以直接从v$locked_objects中查看,但没有上面语句直观根据sid可以到v$process中查出pid,然后将其kill或者其它处理。
22)
对于常见的一些IDLE wait事件举例:
dispatcher timer
lock element cleanup
Null event
parallel query dequeue wait
parallel query idle wait - Slaves
pipe get
PL/SQL lock timer
pmon timer- pmon
rdbms ipc message
slave wait
smon timer
SQL*Net break/reset to client
SQL*Net message from client
SQL*Net message to client
SQL*Net more data to client
virtual circuit status
client message
SQL*Net message from client
下面是关于这里的常见的等待事件和解决方法的一个快速预览
等待事件 | 一般解决方法 |
Sequential Read | 调整相关的索引和选择合适的驱动行源 |
Scattered Read | 表明出现很多全表扫描。优化code,cache小表到内存中。 |
Free Buffer | 增大DB_CACHE_SIZE,增大checkpoint的频率,优化代码 |
Buffer Busy Segment header | 增加freelist或者freelistgroups |
Buffer Busy Data block | 隔离热块;使用反转索引;使用更小的块;增大表的initrans |
Buffer Busy Undo header | 增加回滚段的数量或者大小 |
Buffer Busy Undo block | Commit more;增加回滚段的数量或者大小 |
Latch Free | 检查具体的等待latch类型,解决方法参考后面介绍 |
Enqueue–ST | 使用本地管理的表空间或者增加预分配的盘区大小 |
Enqueue–HW | 在HWM之上预先分配盘区 |
Enqueue–TX4 | 在表或者索引上增大initrans的值或者使用更小的块 |
Log Buffer Space | 增大LOG_BUFFER,改善I/O |
Log File Switch | 增加或者增大日志文件 |
Log file sync | 减小提交的频率;使用更快的I/O;或者使用裸设备 |
Write complete waits | 增加DBWR;提高CKPT的频率; |
Total time in database user-calls (DB Time): 663s
Statistics including the word "background" measure background process time, and so do not contribute to the DB time statistic
Ordered by % or DB time desc, Statistic name
Statistic Name | Time (s) | % of DB Time |
DB CPU | 514.50 | 77.61 |
sql execute elapsed time | 482.27 | 72.74 |
parse time elapsed | 3.76 | 0.57 |
PL/SQL execution elapsed time | 0.50 | 0.08 |
hard parse elapsed time | 0.34 | 0.05 |
connection management call elapsed time | 0.08 | 0.01 |
hard parse (sharing criteria) elapsed time | 0.00 | 0.00 |
repeated bind elapsed time | 0.00 | 0.00 |
PL/SQL compilation elapsed time | 0.00 | 0.00 |
failed parse elapsed time | 0.00 | 0.00 |
DB time | 662.97 |
|
background elapsed time | 185.19 |
|
background cpu time | 67.48 |
|
此节显示了各种类型的数据库处理任务所占用的CPU时间。
DB time=报表头部显示的db time=cpu time + all of nonidle wait event time
Back to
Wait Events Statistics
Back to Top
s - second
cs - centisecond - 100th of a second
ms - millisecond - 1000th of a second
us - microsecond - 1000000th of a second
ordered by wait time desc, waits desc
查询Oracle 10gR1提供的12个等待事件类:
select wait_class#, wait_class_id, wait_class from v$event_name group by wait_class#, wait_class_id, wait_class order by wait_class#;
Wait Class | Waits | %Time -outs | Total Wait Time (s) | Avg wait (ms) | Waits /txn |
User I/O | 66,837 | 0.00 | 120 | 2 | 11.94 |
System I/O | 28,295 | 0.00 | 93 | 3 | 5.05 |
Network | 1,571,450 | 0.00 | 66 | 0 | 280.72 |
Cluster | 210,548 | 0.00 | 29 | 0 | 37.61 |
Other | 81,783 | 71.82 | 28 | 0 | 14.61 |
Application | 333,155 | 0.00 | 16 | 0 | 59.51 |
Concurrency | 5,182 | 0.04 | 5 | 1 | 0.93 |
Commit | 919 | 0.00 | 4 | 4 | 0.16 |
Configuration | 25,427 | 99.46 | 1 | 0 | 4.54 |
Back to
Wait Events Statistics
Back to Top
s - second
cs - centisecond - 100th of a second
ms - millisecond - 1000th of a second
us - microsecond - 1000000th of a second
ordered by wait time desc, waits desc (idle events last)
(1)查询所有等待事件及其属性:
select event#, name, parameter1, parameter2, parameter3 from v$event_name order by name;
(2)查询Oracle 10gR1提供的12个等待事件类:
select wait_class#, wait_class_id, wait_class from v$event_name group by wait_class#, wait_class_id, wait_class order by wait_class#;
wait_event.doc
下面显示的内容可能来自下面几个视图)
V$EVENT_NAME视图包含所有为数据库实例定义的等待事件。
V$SYSTEM_EVENT视图显示自从实例启动后,所有Oracle会话遇到的所有等待事件的总计统计。
V$SESSION_EVENT视图包含当前连接到实例的所有会话的总计等待事件统计。该视图包含了V$SYSTEM_EVENT视图中出现的所有列。它记录会话中每一个等待事件的总等待次数、已等待时间和最大等待时间。SID列标识出独立的会话。每个会话中每个事件的最大等待时间在MAX_WAIT列中追踪。通过用SID列将V$SESSION_EVENT视图和V$SESSION视图结合起来,可得到有关会话和用户的更多信息。
V$SESSION_WAIT视图提供关于每个会话正在等待的事件或资源的详细信息。该视图在任何给定时间,只包含每个会话的一行活动的或不活动的信息。
自从OWI在Oracle 7.0.12中引入后,就具有下来4个V$视图:
· V$EVENT_NAME
· V$SESSION_WAIT
· V$SESSION_EVENT
· V$SYSTEM_EVENT
除了这些等待事件视图之外,Oracle 10gR1中引入了下列新视图以从多个角度显示等待信息:
· V$SYSTEM_WAIT_CLASS
· V$SESSION_WAIT_CLASS
· V$SESSION_WAIT_HISTORY
· V$EVENT_HISTOGRAM
· V$ACTIVE_SESSION_HISTORY
然而,V$SESSION_WAIT、V$SESSION_WAIT和V$SESSION_WAIT仍然是3个重要的视图,它们提供了不同粒度级的等待事件统计和计时信息。三者的关系如下:
V$SESSION_WAIT ? V$SESSION_EVENT ?V$SYSTEM_EVENT
Event | Waits | %Time -outs | Total Wait Time (s) | Avg wait (ms) | Waits /txn |
SQL*Net more data from client | 27,319 | 0.00 | 64 | 2 | 4.88 |
log file parallel write | 5,497 | 0.00 | 47 | 9 | 0.98 |
db file sequential read | 7,900 | 0.00 | 35 | 4 | 1.41 |
db file parallel write | 4,806 | 0.00 | 34 | 7 | 0.86 |
db file scattered read | 10,310 | 0.00 | 31 | 3 | 1.84 |
direct path write | 42,724 | 0.00 | 30 | 1 | 7.63 |
reliable message | 355 | 2.82 | 18 | 49 | 0.06 |
SQL*Net break/reset to client | 333,084 | 0.00 | 16 | 0 | 59.50 |
db file parallel read | 3,732 | 0.00 | 13 | 4 | 0.67 |
gc current multi block request | 175,710 | 0.00 | 10 | 0 | 31.39 |
control file sequential read | 15,974 | 0.00 | 10 | 1 | 2.85 |
direct path read temp | 1,873 | 0.00 | 9 | 5 | 0.33 |
gc cr multi block request | 20,877 | 0.00 | 8 | 0 | 3.73 |
log file sync | 919 | 0.00 | 4 | 4 | 0.16 |
gc cr block busy | 526 | 0.00 | 3 | 6 | 0.09 |
enq: FB - contention | 10,384 | 0.00 | 3 | 0 | 1.85 |
DFS lock handle | 3,517 | 0.00 | 3 | 1 | 0.63 |
control file parallel write | 1,946 | 0.00 | 3 | 1 | 0.35 |
gc current block 2-way | 4,165 | 0.00 | 2 | 0 | 0.74 |
library cache lock | 432 | 0.00 | 2 | 4 | 0.08 |
name-service call wait | 22 | 0.00 | 2 | 76 | 0.00 |
row cache lock | 3,894 | 0.00 | 2 | 0 | 0.70 |
gcs log flush sync | 1,259 | 42.02 | 2 | 1 | 0.22 |
os thread startup | 18 | 5.56 | 2 | 89 | 0.00 |
gc cr block 2-way | 3,671 | 0.00 | 2 | 0 | 0.66 |
gc current block busy | 113 | 0.00 | 1 | 12 | 0.02 |
SQL*Net message to client | 1,544,115 | 0.00 | 1 | 0 | 275.83 |
gc buffer busy | 15 | 6.67 | 1 | 70 | 0.00 |
gc cr disk read | 3,272 | 0.00 | 1 | 0 | 0.58 |
direct path write temp | 159 | 0.00 | 1 | 5 | 0.03 |
gc current grant busy | 898 | 0.00 | 1 | 1 | 0.16 |
log file switch completion | 29 | 0.00 | 1 | 17 | 0.01 |
CGS wait for IPC msg | 48,739 | 99.87 | 0 | 0 | 8.71 |
gc current grant 2-way | 1,142 | 0.00 | 0 | 0 | 0.20 |
kjbdrmcvtq lmon drm quiesce: ping completion | 9 | 0.00 | 0 | 19 | 0.00 |
enq: US - contention | 567 | 0.00 | 0 | 0 | 0.10 |
direct path read | 138 | 0.00 | 0 | 1 | 0.02 |
enq: WF - contention | 14 | 0.00 | 0 | 9 | 0.00 |
ksxr poll remote instances | 13,291 | 58.45 | 0 | 0 | 2.37 |
library cache pin | 211 | 0.00 | 0 | 1 | 0.04 |
ges global resource directory to be frozen | 9 | 100.00 | 0 | 10 | 0.00 |
wait for scn ack | 583 | 0.00 | 0 | 0 | 0.10 |
log file sequential read | 36 | 0.00 | 0 | 2 | 0.01 |
undo segment extension | 25,342 | 99.79 | 0 | 0 | 4.53 |
rdbms ipc reply | 279 | 0.00 | 0 | 0 | 0.05 |
ktfbtgex | 6 | 100.00 | 0 | 10 | 0.00 |
enq: HW - contention | 44 | 0.00 | 0 | 1 | 0.01 |
gc cr grant 2-way | 158 | 0.00 | 0 | 0 | 0.03 |
enq: TX - index contention | 1 | 0.00 | 0 | 34 | 0.00 |
enq: CF - contention | 64 | 0.00 | 0 | 1 | 0.01 |
PX Deq: Signal ACK | 37 | 21.62 | 0 | 1 | 0.01 |
latch free | 3 | 0.00 | 0 | 10 | 0.00 |
buffer busy waits | 625 | 0.16 | 0 | 0 | 0.11 |
KJC: Wait for msg sends to complete | 154 | 0.00 | 0 | 0 | 0.03 |
log buffer space | 11 | 0.00 | 0 | 2 | 0.00 |
enq: PS - contention | 46 | 0.00 | 0 | 1 | 0.01 |
enq: TM - contention | 70 | 0.00 | 0 | 0 | 0.01 |
IPC send completion sync | 40 | 100.00 | 0 | 0 | 0.01 |
PX Deq: reap credit | 1,544 | 99.81 | 0 | 0 | 0.28 |
log file single write | 36 | 0.00 | 0 | 0 | 0.01 |
enq: TT - contention | 46 | 0.00 | 0 | 0 | 0.01 |
enq: TD - KTF dump entries | 12 | 0.00 | 0 | 1 | 0.00 |
read by other session | 1 | 0.00 | 0 | 12 | 0.00 |
LGWR wait for redo copy | 540 | 0.00 | 0 | 0 | 0.10 |
PX Deq Credit: send blkd | 17 | 5.88 | 0 | 0 | 0.00 |
enq: TA - contention | 14 | 0.00 | 0 | 0 | 0.00 |
latch: ges resource hash list | 44 | 0.00 | 0 | 0 | 0.01 |
enq: PI - contention | 8 | 0.00 | 0 | 0 | 0.00 |
write complete waits | 1 | 0.00 | 0 | 2 | 0.00 |
enq: DR - contention | 3 | 0.00 | 0 | 0 | 0.00 |
enq: MW - contention | 3 | 0.00 | 0 | 0 | 0.00 |
enq: TS - contention | 3 | 0.00 | 0 | 0 | 0.00 |
PX qref latch | 150 | 100.00 | 0 | 0 | 0.03 |
PX qref latch 在并行执行的情况下偶然会发现PX qref latch等待事件,当系统高峰期同时采用了高并发的情况下最容易出现。看来要进行特殊照顾了。 概念和原理 调整和措施 优化parallel_execution_message_size参数 | |||||
enq: MD - contention | 2 | 0.00 | 0 | 0 | 0.00 |
latch: KCL gc element parent latch | 11 | 0.00 | 0 | 0 | 0.00 |
enq: JS - job run lock - synchronize | 1 | 0.00 | 0 | 1 | 0.00 |
SQL*Net more data to client | 16 | 0.00 | 0 | 0 | 0.00 |
latch: cache buffers lru chain | 1 | 0.00 | 0 | 0 | 0.00 |
enq: UL - contention | 1 | 0.00 | 0 | 0 | 0.00 |
gc current split | 1 | 0.00 | 0 | 0 | 0.00 |
enq: AF - task serialization | 1 | 0.00 | 0 | 0 | 0.00 |
latch: object queue header operation | 3 | 0.00 | 0 | 0 | 0.00 |
latch: cache buffers chains | 1 | 0.00 | 0 | 0 | 0.00 |
latch: enqueue hash chains | 2 | 0.00 | 0 | 0 | 0.00 |
SQL*Net message from client | 1,544,113 | 0.00 | 12,626 | 8 | 275.83 |
gcs remote message | 634,884 | 98.64 | 9,203 | 14 | 113.41 |
DIAG idle wait | 23,628 | 0.00 | 4,616 | 195 | 4.22 |
ges remote message | 149,591 | 93.45 | 4,612 | 31 | 26.72 |
Streams AQ: qmn slave idle wait | 167 | 0.00 | 4,611 | 27611 | 0.03 |
Streams AQ: qmn coordinator idle wait | 351 | 47.86 | 4,611 | 13137 | 0.06 |
Streams AQ: waiting for messages in the queue | 488 | 100.00 | 4,605 | 9436 | 0.09 |
virtual circuit status | 157 | 100.00 | 4,596 | 29272 | 0.03 |
PX Idle Wait | 1,072 | 97.11 | 2,581 | 2407 | 0.19 |
jobq slave wait | 145 | 97.93 | 420 | 2896 | 0.03 |
Streams AQ: waiting for time management or cleanup tasks | 1 | 100.00 | 270 | 269747 | 0.00 |
PX Deq: Parse Reply | 40 | 40.00 | 0 | 3 | 0.01 |
PX Deq: Execution Msg | 121 | 26.45 | 0 | 0 | 0.02 |
PX Deq: Join ACK | 38 | 42.11 | 0 | 1 | 0.01 |
PX Deq: Execute Reply | 34 | 32.35 | 0 | 0 | 0.01 |
PX Deq: Msg Fragment | 16 | 0.00 | 0 | 0 | 0.00 |
Streams AQ: RAC qmn coordinator idle wait | 351 | 100.00 | 0 | 0 | 0.06 |
class slave wait | 2 | 0.00 | 0 | 0 | 0.00 |
db file scattered read等待事件是当SESSION等待multi-block I/O时发生的,通过是由于full table scans或 index fast full scans。发生过多读操作的Segments可以在“Segments by Physical Reads”和 “SQL ordered by Reads”节中识别(在其它版本的报告中,可能是别的名称)。如果在OLTP应用中,不应该有过多的全扫描操作,而应使用选择性好的索引操作。
DB file sequential read等待意味着发生顺序I/O读等待(通常是单块读取到连续的内存区域中),如果这个等待非常严重,应该使用上一段的方法确定执行读操作的热点SEGMENT,然后通过对大表进行分区以减少I/O量,或者优化执行计划(通过使用存储大纲或执行数据分析)以避免单块读操作引起的sequential read等待。通过在批量应用中,DB file sequential read是很影响性能的事件,总是应当设法避免。
Log File Parallel Write事件是在等待LGWR进程将REDO记录从LOG 缓冲区写到联机日志文件时发生的。虽然写操作可能是并发的,但LGWR需要等待最后的I/O写到磁盘上才能认为并行写的完成,因此等待时间依赖于OS完成所有请求的时间。如果这个等待比较严重,可以通过将LOG文件移到更快的磁盘上或者条带化磁盘(减少争用)而降低这个等待。
Buffer Busy Waits事件是在一个SESSION需要访问BUFFER CACHE中的一个数据库块而又不能访问时发生的。缓冲区“busy”的两个原因是:1)另一个SESSION正在将数据块读进BUFFER。2)另一个SESSION正在以排它模式占用着这块被请求的BUFFER。可以在“Segments by Buffer Busy Waits”一节中找出发生这种等待的SEGMENT,然后通过使用reverse-key indexes并对热表进行分区而减少这种等待事件。
Log File Sync事件,当用户SESSION执行事务操作(COMMIT或ROLLBACK等)后,会通知 LGWR进程将所需要的所有REDO信息从LOG BUFFER写到LOG文件,在用户SESSION等待LGWR返回安全写入磁盘的通知时发生此等待。减少此等待的方法写Log File Parallel Write事件的处理。
Enqueue Waits是串行访问本地资源的本锁,表明正在等待一个被其它SESSION(一个或多个)以排它模式锁住的资源。减少这种等待的方法依赖于生产等待的锁类型。导致Enqueue等待的主要锁类型有三种:TX(事务锁), TM D(ML锁)和ST(空间管理锁)。
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ordered by wait time desc, waits desc (idle events last)
Event | Waits | %Time -outs | Total Wait Time (s) | Avg wait (ms) | Waits /txn |
log file parallel write | 5,497 | 0.00 | 47 | 9 | 0.98 |
db file parallel write | 4,806 | 0.00 | 34 | 7 | 0.86 |
events in waitclass Other | 69,002 | 83.25 | 22 | 0 | 12.33 |
control file sequential read | 9,323 | 0.00 | 7 | 1 | 1.67 |
control file parallel write | 1,946 | 0.00 | 3 | 1 | 0.35 |
os thread startup | 18 | 5.56 | 2 | 89 | 0.00 |
direct path read | 138 | 0.00 | 0 | 1 | 0.02 |
db file sequential read | 21 | 0.00 | 0 | 5 | 0.00 |
direct path write | 138 | 0.00 | 0 | 0 | 0.02 |
log file sequential read | 36 | 0.00 | 0 | 2 | 0.01 |
gc cr block 2-way | 96 | 0.00 | 0 | 0 | 0.02 |
gc current block 2-way | 78 | 0.00 | 0 | 0 | 0.01 |
log buffer space | 11 | 0.00 | 0 | 2 | 0.00 |
row cache lock | 59 | 0.00 | 0 | 0 | 0.01 |
log file single write | 36 | 0.00 | 0 | 0 | 0.01 |
buffer busy waits | 151 | 0.66 | 0 | 0 | 0.03 |
gc current grant busy | 29 | 0.00 | 0 | 0 | 0.01 |
library cache lock | 4 | 0.00 | 0 | 1 | 0.00 |
enq: TM - contention | 10 | 0.00 | 0 | 0 | 0.00 |
gc current grant 2-way | 8 | 0.00 | 0 | 0 | 0.00 |
gc cr multi block request | 7 | 0.00 | 0 | 0 | 0.00 |
gc cr grant 2-way | 5 | 0.00 | 0 | 0 | 0.00 |
rdbms ipc message | 97,288 | 73.77 | 50,194 | 516 | 17.38 |
gcs remote message | 634,886 | 98.64 | 9,203 | 14 | 113.41 |
DIAG idle wait | 23,628 | 0.00 | 4,616 | 195 | 4.22 |
pmon timer | 1,621 | 100.00 | 4,615 | 2847 | 0.29 |
ges remote message | 149,591 | 93.45 | 4,612 | 31 | 26.72 |
Streams AQ: qmn slave idle wait | 167 | 0.00 | 4,611 | 27611 | 0.03 |
Streams AQ: qmn coordinator idle wait | 351 | 47.86 | 4,611 | 13137 | 0.06 |
smon timer | 277 | 6.50 | 4,531 | 16356 | 0.05 |
Streams AQ: waiting for time management or cleanup tasks | 1 | 100.00 | 270 | 269747 | 0.00 |
PX Deq: Parse Reply | 40 | 40.00 | 0 | 3 | 0.01 |
PX Deq: Join ACK | 38 | 42.11 | 0 | 1 | 0.01 |
PX Deq: Execute Reply | 34 | 32.35 | 0 | 0 | 0.01 |
Streams AQ: RAC qmn coordinator idle wait | 351 | 100.00 | 0 | 0 | 0.06 |
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Statistic | Total |
NUM_LCPUS | 0 |
NUM_VCPUS | 0 |
AVG_BUSY_TIME | 101,442 |
AVG_IDLE_TIME | 371,241 |
AVG_IOWAIT_TIME | 5,460 |
AVG_SYS_TIME | 25,795 |
AVG_USER_TIME | 75,510 |
BUSY_TIME | 812,644 |
IDLE_TIME | 2,971,077 |
IOWAIT_TIME | 44,794 |
SYS_TIME | 207,429 |
USER_TIME | 605,215 |
LOAD | 0 |
OS_CPU_WAIT_TIME | 854,100 |
RSRC_MGR_CPU_WAIT_TIME | 0 |
PHYSICAL_MEMORY_BYTES | 8,589,934,592 |
NUM_CPUS | 8 |
NUM_CPU_CORES | 4 |
NUM_LCPUS: 如果显示0,是因为没有设置LPARS
NUM_VCPUS: 同上。
AVG_BUSY_TIME: BUSY_TIME / NUM_CPUS
AVG_IDLE_TIME: IDLE_TIME / NUM_CPUS
AVG_IOWAIT_TIME: IOWAIT_TIME / NUM_CPUS
AVG_SYS_TIME: SYS_TIME / NUM_CPUS
AVG_USER_TIME: USER_TIME / NUM_CPUSar o
BUSY_TIME: time equiv of %usr+%sys in sar output
IDLE_TIME: time equiv of %idle in sar
IOWAIT_TIME: time equiv of %wio in sar
SYS_TIME: time equiv of %sys in sar
USER_TIME: time equiv of %usr in sar
LOAD: 未知
OS_CPU_WAIT_TIME: supposedly time waiting on run queues
RSRC_MGR_CPU_WAIT_TIME: time waited coz of resource manager
PHYSICAL_MEMORY_BYTES: total memory in use supposedly
NUM_CPUS: number of CPUs reported by OS 操作系统CPU数
NUM_CPU_CORES: number of CPU sockets on motherboard 主板上CPU插槽数
总的elapsed time也可以用以公式计算:
BUSY_TIME + IDLE_TIME + IOWAIT TIME
或:SYS_TIME + USER_TIME + IDLE_TIME + IOWAIT_TIME
(因为BUSY_TIME = SYS_TIME+USER_TIME)
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ordered by DB Time
Service Name | DB Time (s) | DB CPU (s) | Physical Reads | Logical Reads |
ICCI | 608.10 | 496.60 | 315,849 | 16,550,972 |
SYS$USERS | 54.70 | 17.80 | 6,539 | 58,929 |
ICCIXDB | 0.00 | 0.00 | 0 | 0 |
SYS$BACKGROUND | 0.00 | 0.00 | 282 | 38,990 |
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Wait Class info for services in the Service Statistics section.
Total Waits and Time Waited displayed for the following wait classes: User I/O, Concurrency, Administrative, Network
Time Waited (Wt Time) in centisecond (100th of a second)
Service Name | User I/O Total Wts | User I/O Wt Time | Concurcy Total Wts | Concurcy Wt Time | Admin Total Wts | Admin Wt Time | Network Total Wts | Network Wt Time |
ICCI | 59826 | 8640 | 4621 | 338 | 0 | 0 | 1564059 | 6552 |
SYS$USERS | 6567 | 3238 | 231 | 11 | 0 | 0 | 7323 | 3 |
SYS$BACKGROUND | 443 | 115 | 330 | 168 | 0 | 0 | 0 | 0 |
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SQL ordered by Elapsed Time
SQL ordered by CPU Time
SQL ordered by Gets
SQL ordered by Reads
SQL ordered by Executions
SQL ordered by Parse Calls
SQL ordered by Sharable Memory
SQL ordered by Version Count
SQL ordered by Cluster Wait Time
Complete List of SQL Text
本节按各种资源分别列出对资源消耗最严重的SQL语句,并显示它们所占统计期内全部资源的比例,这给出我们调优指南。例如在一个系统中,CPU资源是系统性能瓶颈所在,那么优化buffer gets最多的SQL语句将获得最大效果。在一个I/O等待是最严重事件的系统中,调优的目标应该是physical IOs最多的SQL语句。
在STATSPACK报告中,没有完整的SQL语句,可使用报告中的Hash Value通过下面语句从数据库中查到:
select sql_text
from stats$sqltext
where hash_value = &hash_value
order by piece;
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Resources reported for PL/SQL code includes the resources used by all SQL statements called by the code.
% Total DB Time is the Elapsed Time of the SQL statement divided into the Total Database Time multiplied by 100
Elapsed Time (s) | CPU Time (s) | Executions | Elap per Exec (s) | % Total DB Time | SQL Id | SQL Module | SQL Text |
93 | 57 | 1 | 93.50 | 14.10 | d8z0u8hgj8xdy | cuidmain@HPGICCI1 (TNS V1-V3) | insert into CUID select CUID_... |
76 | 75 | 172,329 | 0.00 | 11.52 | 4vja2k2gdtyup | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
58 | 42 | 1 | 58.04 | 8.75 | 569r5k05drsj7 | cumimain@HPGICCI1 (TNS V1-V3) | insert into CUMI select CUSV_... |
51 | 42 | 1 | 50.93 | 7.68 | ackxqhnktxnbc | cusmmain@HPGICCI1 (TNS V1-V3) | insert into CUSM select CUSM_... |
38 | 36 | 166,069 | 0.00 | 5.67 | 7gtztzv329wg0 |
| select c.name, u.name from co... |
35 | 3 | 1 | 35.00 | 5.28 | 6z06gcfw39pkd | SQL*Plus | SELECT F.TABLESPACE_NAME, TO_... |
23 | 23 | 172,329 | 0.00 | 3.46 | 1dm3bq36vu3g8 | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into iccifnsact values... |
15 | 11 | 5 | 2.98 | 2.25 | djs2w2f17nw2z |
| DECLARE job BINARY_INTEGER := ... |
14 | 14 | 172,983 | 0.00 | 2.16 | 7wwv1ybs9zguz | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCIFNSACT set BORM_AD... |
13 | 13 | 172,337 | 0.00 | 2.00 | gmn2w09rdxn14 | load_oldnewact@HPGICCI1 (TNS V1-V3) | insert into OLDNEWACT values ... |
13 | 13 | 166,051 | 0.00 | 1.89 | chjmy0dxf9mbj | icci_migact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
10 | 4 | 1 | 9.70 | 1.46 | 0yv9t4qb1zb2b | cuidmain@HPGICCI1 (TNS V1-V3) | select CUID_CUST_NO , CUID_ID_... |
10 | 8 | 5 | 1.91 | 1.44 | 1crajpb7j5tyz |
| INSERT INTO STATS$SGA_TARGET_A... |
8 | 8 | 172,329 | 0.00 | 1.25 | 38apjgr0p55ns | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCICCS set CCSMAXOVER... |
8 | 8 | 172,983 | 0.00 | 1.16 | 5c4qu2zmj3gux | load_fnsact@HPGICCI1 (TNS V1-V3) | select * from ICCIPRODCODE wh... |
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Resources reported for PL/SQL code includes the resources used by all SQL statements called by the code.
% Total DB Time is the Elapsed Time of the SQL statement divided into the Total Database Time multiplied by 100
CPU Time (s) | Elapsed Time (s) | Executions | CPU per Exec (s) | % Total DB Time | SQL Id | SQL Module | SQL Text |
75 | 76 | 172,329 | 0.00 | 11.52 | 4vja2k2gdtyup | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
57 | 93 | 1 | 57.31 | 14.10 | d8z0u8hgj8xdy | cuidmain@HPGICCI1 (TNS V1-V3) | insert into CUID select CUID_... |
42 | 51 | 1 | 42.43 | 7.68 | ackxqhnktxnbc | cusmmain@HPGICCI1 (TNS V1-V3) | insert into CUSM select CUSM_... |
42 | 58 | 1 | 42.01 | 8.75 | 569r5k05drsj7 | cumimain@HPGICCI1 (TNS V1-V3) | insert into CUMI select CUSV_... |
36 | 38 | 166,069 | 0.00 | 5.67 | 7gtztzv329wg0 |
| select c.name, u.name from co... |
23 | 23 | 172,329 | 0.00 | 3.46 | 1dm3bq36vu3g8 | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into iccifnsact values... |
14 | 14 | 172,983 | 0.00 | 2.16 | 7wwv1ybs9zguz | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCIFNSACT set BORM_AD... |
13 | 13 | 172,337 | 0.00 | 2.00 | gmn2w09rdxn14 | load_oldnewact@HPGICCI1 (TNS V1-V3) | insert into OLDNEWACT values ... |
13 | 13 | 166,051 | 0.00 | 1.89 | chjmy0dxf9mbj | icci_migact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
11 | 15 | 5 | 2.23 | 2.25 | djs2w2f17nw2z |
| DECLARE job BINARY_INTEGER := ... |
8 | 8 | 172,329 | 0.00 | 1.25 | 38apjgr0p55ns | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCICCS set CCSMAXOVER... |
8 | 10 | 5 | 1.60 | 1.44 | 1crajpb7j5tyz |
| INSERT INTO STATS$SGA_TARGET_A... |
8 | 8 | 172,983 | 0.00 | 1.16 | 5c4qu2zmj3gux | load_fnsact@HPGICCI1 (TNS V1-V3) | select * from ICCIPRODCODE wh... |
4 | 10 | 1 | 3.54 | 1.46 | 0yv9t4qb1zb2b | cuidmain@HPGICCI1 (TNS V1-V3) | select CUID_CUST_NO , CUID_ID_... |
3 | 35 | 1 | 3.13 | 5.28 | 6z06gcfw39pkd | SQL*Plus | SELECT F.TABLESPACE_NAME, TO_... |
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Resources reported for PL/SQL code includes the resources used by all SQL statements called by the code.
Total Buffer Gets: 16,648,792
Captured SQL account for 97.9% of Total
这一部分,通过Buffer Gets对SQL语句进行排序,即通过它执行了多少个逻辑I/O来排序。顶端的注释表明一个PL/SQL单元的缓存获得(Buffer Gets)包括被这个代码块执行的所有SQL语句的Buffer Gets。因此将经常在这个列表的顶端看到PL/SQL过程,因为存储过程执行的单独的语句的数目被总计出来。在这里的Buffer Gets是一个累积值,所以这个值大并不一定意味着这条语句的性能存在问题。通常我们可以通过对比该条语句的Buffer Gets和physical reads值,如果这两个比较接近,肯定这条语句是存在问题的,我们可以通过执行计划来分析,为什么physical reads的值如此之高。另外,我们在这里也可以关注gets per exec的值,这个值如果太大,表明这条语句可能使用了一个比较差的索引或者使用了不当的表连接。
另外说明一点:大量的逻辑读往往伴随着较高的CPU消耗。所以很多时候我们看到的系统CPU将近100%的时候,很多时候就是SQL语句造成的,这时候我们可以分析一下这里逻辑读大的SQL。
select * from
(select substr(sql_text,1,40) sql, buffer_gets,
executions, buffer_gets/executions "Gets/Exec",
hash_value,address
from v$sqlarea
where buffer_gets > 0 and executions>0
order by buffer_gets desc)
where rownum <= 10 ;
Buffer Gets | Executions | Gets per Exec | %Total | CPU Time (s) | Elapsed Time (s) | SQL Id | SQL Module | SQL Text |
3,305,363 | 172,329 | 19.18 | 19.85 | 74.57 | 76.41 | 4vja2k2gdtyup | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
2,064,414 | 1 | 2,064,414.00 | 12.40 | 57.31 | 93.50 | d8z0u8hgj8xdy | cuidmain@HPGICCI1 (TNS V1-V3) | insert into CUID select CUID_... |
1,826,869 | 166,069 | 11.00 | 10.97 | 35.84 | 37.60 | 7gtztzv329wg0 |
| select c.name, u.name from co... |
1,427,648 | 172,337 | 8.28 | 8.58 | 12.97 | 13.29 | gmn2w09rdxn14 | load_oldnewact@HPGICCI1 (TNS V1-V3) | insert into OLDNEWACT values ... |
1,278,667 | 172,329 | 7.42 | 7.68 | 22.85 | 22.94 | 1dm3bq36vu3g8 | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into iccifnsact values... |
1,216,367 | 1 | 1,216,367.00 | 7.31 | 42.43 | 50.93 | ackxqhnktxnbc | cusmmain@HPGICCI1 (TNS V1-V3) | insert into CUSM select CUSM_... |
1,107,305 | 1 | 1,107,305.00 | 6.65 | 42.01 | 58.04 | 569r5k05drsj7 | cumimain@HPGICCI1 (TNS V1-V3) | insert into CUMI select CUSV_... |
898,868 | 172,983 | 5.20 | 5.40 | 14.28 | 14.34 | 7wwv1ybs9zguz | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCIFNSACT set BORM_AD... |
711,450 | 166,051 | 4.28 | 4.27 | 12.52 | 12.55 | chjmy0dxf9mbj | icci_migact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
692,996 | 172,329 | 4.02 | 4.16 | 8.31 | 8.31 | 38apjgr0p55ns | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCICCS set CCSMAXOVER... |
666,748 | 166,052 | 4.02 | 4.00 | 6.36 | 6.36 | 7v9dyf5r424yh | icci_migact@HPGICCI1 (TNS V1-V3) | select NEWACTNO into :b0 from... |
345,357 | 172,983 | 2.00 | 2.07 | 7.70 | 7.71 | 5c4qu2zmj3gux | load_fnsact@HPGICCI1 (TNS V1-V3) | select * from ICCIPRODCODE wh... |
231,756 | 51,633 | 4.49 | 1.39 | 5.75 | 5.83 | 49ms69srnaxzj | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCIRPYV values (... |
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Total Disk Reads: 322,678
Captured SQL account for 66.1% of Total
这部分通过物理读对SQL语句进行排序。这显示引起大部分对这个系统进行读取活动的SQL,即物理I/O。当我们的系统如果存在I/O瓶颈时,需要关注这里I/O操作比较多的语句。
select * from
(select substr(sql_text,1,40) sql, disk_reads,
executions, disk_reads/executions "Reads/Exec",
hash_value,address
from v$sqlarea where disk_reads > 0 and executions >0
order by disk_reads desc)where rownum <= 10;
Physical Reads | Executions | Reads per Exec | %Total | CPU Time (s) | Elapsed Time (s) | SQL Id | SQL Module | SQL Text |
66,286 | 1 | 66,286.00 | 20.54 | 57.31 | 93.50 | d8z0u8hgj8xdy | cuidmain@HPGICCI1 (TNS V1-V3) | insert into CUID select CUID_... |
50,646 | 1 | 50,646.00 | 15.70 | 3.54 | 9.70 | 0yv9t4qb1zb2b | cuidmain@HPGICCI1 (TNS V1-V3) | select CUID_CUST_NO , CUID_ID_... |
24,507 | 1 | 24,507.00 | 7.59 | 42.01 | 58.04 | 569r5k05drsj7 | cumimain@HPGICCI1 (TNS V1-V3) | insert into CUMI select CUSV_... |
21,893 | 1 | 21,893.00 | 6.78 | 42.43 | 50.93 | ackxqhnktxnbc | cusmmain@HPGICCI1 (TNS V1-V3) | insert into CUSM select CUSM_... |
19,761 | 1 | 19,761.00 | 6.12 | 2.14 | 6.04 | a7nh7j8zmfrzw | cumimain@HPGICCI1 (TNS V1-V3) | select CUSV_CUST_NO from CUMI... |
19,554 | 1 | 19,554.00 | 6.06 | 1.27 | 3.83 | 38gak8u2qm11w | SQL*Plus | select count(*) from CUSVAA_T... |
6,342 | 1 | 6,342.00 | 1.97 | 3.13 | 35.00 | 6z06gcfw39pkd | SQL*Plus | SELECT F.TABLESPACE_NAME, TO_... |
4,385 | 1 | 4,385.00 | 1.36 | 1.59 | 2.43 | cp5duhcsj72q0 | cusmmain@HPGICCI1 (TNS V1-V3) | select CUSM_CUST_ACCT_NO from... |
63 | 5 | 12.60 | 0.02 | 11.17 | 14.91 | djs2w2f17nw2z |
| DECLARE job BINARY_INTEGER := ... |
35 | 1 | 35.00 | 0.01 | 0.08 | 0.67 | 1uk5m5qbzj1vt | SQL*Plus | BEGIN dbms_workload_repository... |
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Total Executions: 1,675,112
Captured SQL account for 99.8% of Total
这部分告诉我们在这段时间中执行次数最多的SQL语句。为了隔离某些频繁执行的查询,以观察是否有某些更改逻辑的方法以避免必须如此频繁的执行这些查询,这可能是很有用的。或许一个查询正在一个循环的内部执行,而且它可能在循环的外部执行一次,可以设计简单的算法更改以减少必须执行这个查询的次数。即使它运行的飞快,任何被执行几百万次的操作都将开始耗尽大量的时间。
select * from
(select substr(sql_text,1,40) sql, executions,
rows_processed, rows_processed/executions "Rows/Exec",
hash_value,address
from v$sqlarea where executions > 0
order by executions desc)where rownum <= 10 ;
Executions | Rows Processed | Rows per Exec | CPU per Exec (s) | Elap per Exec (s) | SQL Id | SQL Module | SQL Text |
172,983 | 172,329 | 1.00 | 0.00 | 0.00 | 5c4qu2zmj3gux | load_fnsact@HPGICCI1 (TNS V1-V3) | select * from ICCIPRODCODE wh... |
172,983 | 172,329 | 1.00 | 0.00 | 0.00 | 7wwv1ybs9zguz | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCIFNSACT set BORM_AD... |
172,337 | 172,337 | 1.00 | 0.00 | 0.00 | gmn2w09rdxn14 | load_oldnewact@HPGICCI1 (TNS V1-V3) | insert into OLDNEWACT values ... |
172,329 | 172,329 | 1.00 | 0.00 | 0.00 | 1dm3bq36vu3g8 | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into iccifnsact values... |
172,329 | 172,329 | 1.00 | 0.00 | 0.00 | 38apjgr0p55ns | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCICCS set CCSMAXOVER... |
172,329 | 6,286 | 0.04 | 0.00 | 0.00 | 4vja2k2gdtyup | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
166,069 | 166,069 | 1.00 | 0.00 | 0.00 | 7gtztzv329wg0 |
| select c.name, u.name from co... |
166,052 | 166,052 | 1.00 | 0.00 | 0.00 | 7v9dyf5r424yh | icci_migact@HPGICCI1 (TNS V1-V3) | select NEWACTNO into :b0 from... |
166,051 | 166,051 | 1.00 | 0.00 | 0.00 | chjmy0dxf9mbj | icci_migact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
51,740 | 51,740 | 1.00 | 0.00 | 0.00 | bu8tnqr3xv25q | load_fnsact@HPGICCI1 (TNS V1-V3) | select count(*) into :b0 fro... |
51,633 | 51,633 | 1.00 | 0.00 | 0.00 | 49ms69srnaxzj | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCIRPYV values (... |
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Total Parse Calls: 182,780
Captured SQL account for 99.0% of Total
在这一部分,主要显示PARSE与EXECUTIONS的对比情况。如果PARSE/EXECUTIONS>1,往往说明这个语句可能存在问题:没有使用绑定变量,共享池设置太小,cursor_sharing被设置为exact,没有设置session_cached_cursors等等问题。
select * from
(select substr(sql_text,1,40) sql, parse_calls,
executions, hash_value,address
from v$sqlarea where parse_calls > 0
order by parse_calls desc)where rownum <= 10 ;
Parse Calls | Executions | % Total Parses | SQL Id | SQL Module | SQL Text |
166,069 | 166,069 | 90.86 | 7gtztzv329wg0 |
| select c.name, u.name from co... |
6,304 | 6,304 | 3.45 | 2ym6hhaq30r73 |
| select type#, blocks, extents,... |
2,437 | 2,438 | 1.33 | bsa0wjtftg3uw |
| select file# from file$ where ... |
1,568 | 1,568 | 0.86 | 9qgtwh76xg6nz |
| update seg$ set type#=:4, bloc... |
1,554 | 1,554 | 0.85 | aq4js2gkfjru8 |
| update tsq$ set blocks=:3, max... |
444 | 444 | 0.24 | 104pd9mm3fh9p |
| select blocks, maxblocks, gran... |
421 | 421 | 0.23 | 350f5yrnnmshs |
| lock table sys.mon_mods$ in ex... |
421 | 421 | 0.23 | g00cj285jmgsw |
| update sys.mon_mods$ set inser... |
86 | 86 | 0.05 | 3m8smr0v7v1m6 |
| INSERT INTO sys.wri$_adv_messa... |
81 | 81 | 0.04 | f80h0xb1qvbsk |
| SELECT sys.wri$_adv_seq_msggro... |
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No data exists for this section of the report.
在这一部分,主要是针对shared memory占用的情况进行排序。
select * from
(select substr(sql_text,1,40) sql, sharable_mem,
executions, hash_value,address
from v$sqlarea where sharable_mem > 1048576
order by sharable_mem desc)
where rownum <= 10;
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Running Time top 10 sql
select * from
(select t.sql_fulltext,
(t.last_active_time-to_date(t.first_load_time,'yyyy-mm-dd hh34:mi:ss'))*24*60,
disk_reads,buffer_gets,rows_processed,
t.last_active_time,t.last_load_time,t.first_load_time
from v$sqlarea t order by t.first_load_time desc)
where rownum < 10;
No data exists for this section of the report.
在这一部分,主要是针对SQL语句的多版本进行排序。相同的SQL文本,但是不同属性,比如对象owner不同,会话优化模式不同、类型不同、长度不同和绑定变量不同等等的语句,他们是不能共享的,所以再缓存中会存在多个不同的版本。这当然就造成了资源上的更多的消耗。
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Cluster Wait Time (s) | CWT % of Elapsd Time | Elapsed Time(s) | CPU Time(s) | Executions | SQL Id | SQL Module | SQL Text |
10.96 | 11.72 | 93.50 | 57.31 | 1 | d8z0u8hgj8xdy | cuidmain@HPGICCI1 (TNS V1-V3) | insert into CUID select CUID_... |
4.21 | 7.25 | 58.04 | 42.01 | 1 | 569r5k05drsj7 | cumimain@HPGICCI1 (TNS V1-V3) | insert into CUMI select CUSV_... |
3.62 | 7.12 | 50.93 | 42.43 | 1 | ackxqhnktxnbc | cusmmain@HPGICCI1 (TNS V1-V3) | insert into CUSM select CUSM_... |
2.39 | 6.35 | 37.60 | 35.84 | 166,069 | 7gtztzv329wg0 |
| select c.name, u.name from co... |
2.38 | 3.12 | 76.41 | 74.57 | 172,329 | 4vja2k2gdtyup | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
1.64 | 16.91 | 9.70 | 3.54 | 1 | 0yv9t4qb1zb2b | cuidmain@HPGICCI1 (TNS V1-V3) | select CUID_CUST_NO , CUID_ID_... |
1.06 | 3.02 | 35.00 | 3.13 | 1 | 6z06gcfw39pkd | SQL*Plus | SELECT F.TABLESPACE_NAME, TO_... |
0.83 | 13.76 | 6.04 | 2.14 | 1 | a7nh7j8zmfrzw | cumimain@HPGICCI1 (TNS V1-V3) | select CUSV_CUST_NO from CUMI... |
0.66 | 87.90 | 0.75 | 0.42 | 444 | 104pd9mm3fh9p |
| select blocks, maxblocks, gran... |
0.50 | 13.01 | 3.83 | 1.27 | 1 | 38gak8u2qm11w | SQL*Plus | select count(*) from CUSVAA_T... |
0.50 | 51.75 | 0.96 | 0.79 | 1,554 | aq4js2gkfjru8 |
| update tsq$ set blocks=:3, max... |
0.33 | 91.11 | 0.36 | 0.33 | 187 | 04xtrk7uyhknh |
| select obj#, type#, ctime, mti... |
0.33 | 2.47 | 13.29 | 12.97 | 172,337 | gmn2w09rdxn14 | load_oldnewact@HPGICCI1 (TNS V1-V3) | insert into OLDNEWACT values ... |
0.29 | 1.26 | 22.94 | 22.85 | 172,329 | 1dm3bq36vu3g8 | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into iccifnsact values... |
0.25 | 10.14 | 2.43 | 1.59 | 1 | cp5duhcsj72q0 | cusmmain@HPGICCI1 (TNS V1-V3) | select CUSM_CUST_ACCT_NO from... |
0.21 | 27.92 | 0.74 | 0.74 | 1,568 | 9qgtwh76xg6nz |
| update seg$ set type#=:4, bloc... |
0.20 | 3.49 | 5.83 | 5.75 | 51,633 | 49ms69srnaxzj | load_fnsact@HPGICCI1 (TNS V1-V3) | insert into ICCIRPYV values (... |
0.17 | 1.39 | 12.55 | 12.52 | 166,051 | chjmy0dxf9mbj | icci_migact@HPGICCI1 (TNS V1-V3) | insert into ICCICCS values (:... |
0.16 | 57.64 | 0.28 | 0.24 | 39 | cn1gtsav2d5jh | cusvaamain@HPGICCI1 (TNS V1-V3) | BEGIN BEGIN IF (xdb.DBMS... |
0.14 | 74.58 | 0.19 | 0.14 | 121 | 5ngzsfstg8tmy |
| select o.owner#, o.name, o.nam... |
0.11 | 64.72 | 0.18 | 0.15 | 80 | 78m9ryygp65v5 | cusvaamain@HPGICCI1 (TNS V1-V3) | SELECT /*+ ALL_ROWS */ COUNT(*... |
0.11 | 94.54 | 0.12 | 0.01 | 17 | bwt0pmxhv7qk7 |
| delete from con$ where owner#=... |
0.11 | 80.26 | 0.14 | 0.14 | 327 | 53saa2zkr6wc3 |
| select intcol#, nvl(pos#, 0), ... |
0.08 | 19.20 | 0.42 | 0.24 | 1 | d92h4rjp0y217 |
| begin prvt_hdm.auto_execute( :... |
0.07 | 54.97 | 0.13 | 0.13 | 83 | 7ng34ruy5awxq |
| select i.obj#, i.ts#, i.file#,... |
0.06 | 5.22 | 1.13 | 0.72 | 77 | 0hhmdwwgxbw0r |
| select obj#, type#, flags, ... |
0.06 | 86.50 | 0.06 | 0.06 | 45 | a2any035u1qz1 |
| select owner#, name from con$... |
0.06 | 8.19 | 0.67 | 0.08 | 1 | 1uk5m5qbzj1vt | SQL*Plus | BEGIN dbms_workload_repository... |
0.04 | 75.69 | 0.06 | 0.06 | 87 | 6769wyy3yf66f |
| select pos#, intcol#, col#, sp... |
0.04 | 48.05 | 0.09 | 0.07 | 7 | 0pvtkmrrq8usg |
| select file#, block# from seg... |
0.04 | 8.84 | 0.40 | 0.40 | 6,304 | 2ym6hhaq30r73 |
| select type#, blocks, extents,... |
0.03 | 28.15 | 0.12 | 0.12 | 49 | b52m6vduutr8j |
| delete from RecycleBin$ ... |
0.03 | 66.23 | 0.05 | 0.05 | 85 | 1gu8t96d0bdmu |
| select t.ts#, t.file#, t.block... |
0.03 | 67.03 | 0.05 | 0.05 | 38 | btzq46kta67dz | DBMS_SCHEDULER | update obj$ set obj#=:6, type#... |
0.02 | 66.73 | 0.04 | 0.04 | 86 | 3m8smr0v7v1m6 |
| INSERT INTO sys.wri$_adv_messa... |
0.02 | 26.94 | 0.09 | 0.09 | 38 | 0k8h717b8guhf |
| delete from RecycleBin$ ... |
0.02 | 76.76 | 0.03 | 0.03 | 51 | 9vtm7gy4fr2ny |
| select con# from con$ where ow... |
0.02 | 51.91 | 0.05 | 0.05 | 84 | 83taa7kaw59c1 |
| select name, intcol#, segcol#,... |
0.02 | 0.15 | 14.91 | 11.17 | 5 | djs2w2f17nw2z |
| DECLARE job BINARY_INTEGER := ... |
0.02 | 2.12 | 1.00 | 0.99 | 8,784 | 501v412s13r4m | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCIFNSACT set BORM_FA... |
0.02 | 53.82 | 0.03 | 0.03 | 39 | bdv0rkkssq2jm | cusvaamain@HPGICCI1 (TNS V1-V3) | SELECT count(*) FROM user_poli... |
0.01 | 0.10 | 14.34 | 14.28 | 172,983 | 7wwv1ybs9zguz | load_fnsact@HPGICCI1 (TNS V1-V3) | update ICCIFNSACT set BORM_AD... |
0.01 | 8.29 | 0.16 | 0.13 | 421 | g00cj285jmgsw |
| update sys.mon_mods$ set inser... |
0.01 | 1.65 | 0.56 | 0.54 | 2 | 84qubbrsr0kfn |
| insert into wrh$_latch (snap... |
0.01 | 22.33 | 0.04 | 0.02 | 26 | 44au3v5mzpc1c | load_curmmast@HPGICCI1 (TNS V1-V3) | insert into ICCICURMMAST valu... |
0.01 | 0.08 | 7.71 | 7.70 | 172,983 | 5c4qu2zmj3gux | load_fnsact@HPGICCI1 (TNS V1-V3) | select * from ICCIPRODCODE wh... |
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对于出现在上面的可疑的sql语句,我们可以查看语句相关的执行计划,然后分析相关索引等是否合理。
通过语句查看执行计划的方法:
SELECT id,parent_id,LPAD(' ',4*(LEVEL-1))||operation||' '||options||' '||object_name "Execution plan" ,cost,cardinality,bytes
FROM (
SELECT p.* FROM v$sql_plan p,v$sql s WHERE p.address = s.ADDRESS
AND p.hash_value = s.HASH_VALUE
and p.hash_value = '&hash_value'
)
CONNECT BY PRIOR id = parent_id
START WITH id = 0;
查看,分析,优化索引等在这里就不再一一描述了。
SQL Id | SQL Text |
04xtrk7uyhknh | select obj#, type#, ctime, mtime, stime, status, dataobj#, flags, oid$, spare1, spare2 from obj$ where owner#=:1 and name=:2 and namespace=:3 and remoteowner is null and linkname is null and subname is null |
0hhmdwwgxbw0r | select obj#, type#, flags, related, bo, purgeobj, con# from RecycleBin$ where ts#=:1 and to_number(bitand(flags, 16)) = 16 order by dropscn |
0k8h717b8guhf | delete from RecycleBin$ where purgeobj=:1 |
0pvtkmrrq8usg | select file#, block# from seg$ where type# = 3 and ts# = :1 |
0v9t4qb1zb2b | select CUID_CUST_NO , CUID_ID_TYPE , CUID_ID_RECNO from CUID_TMP where CHGFLAG='D' |
104pd9mm3fh9p | select blocks, maxblocks, grantor#, priv1, priv2, priv3 from tsq$ where ts#=:1 and user#=:2 |
1crajpb7j5tyz | INSERT INTO STATS$SGA_TARGET_ADVICE ( SNAP_ID , DBID , INSTANCE_NUMBER , SGA_SIZE , SGA_SIZE_FACTOR , ESTD_DB_TIME , ESTD_DB_TIME_FACTOR , ESTD_PHYSICAL_READS ) SELECT :B3 , :B2 , :B1 , SGA_SIZE , SGA_SIZE_FACTOR , ESTD_DB_TIME , ESTD_DB_TIME_FACTOR , ESTD_PHYSICAL_READS FROM V$SGA_TARGET_ADVICE |
1dm3bq36vu3g8 | insert into iccifnsact values (:b0, :b1, :b2, null , null , :b3, :b4, GREATEST(:b5, :b6), null , :b7, :b8, null , :b9, :b10, :b6, null , null , null , null , null , :b12, null , null , null , :b13, :b14, null , null , :b15, :b16, :b17) |
1gu8t96d0bdmu | select t.ts#, t.file#, t.block#, nvl(t.bobj#, 0), nvl(t.tab#, 0), t.intcols, nvl(t.clucols, 0), t.audit$, t.flags, t.pctfree$, t.pctused$, t.initrans, t.maxtrans, t.rowcnt, t.blkcnt, t.empcnt, t.avgspc, t.chncnt, t.avgrln, t.analyzetime, t.samplesize, t.cols, t.property, nvl(t.degree, 1), nvl(t.instances, 1), t.avgspc_flb, t.flbcnt, t.kernelcols, nvl(t.trigflag, 0), nvl(t.spare1, 0), nvl(t.spare2, 0), t.spare4, t.spare6, ts.cachedblk, ts.cachehit, ts.logicalread from tab$ t, tab_stats$ ts where t.obj#= :1 and t.obj# = ts.obj# (+) |
1uk5m5qbzj1vt | BEGIN dbms_workload_repository.create_snapshot; END; |
2ym6hhaq30r73 | select type#, blocks, extents, minexts, maxexts, extsize, extpct, user#, iniexts, NVL(lists, 65535), NVL(groups, 65535), cachehint, hwmincr, NVL(spare1, 0), NVL(scanhint, 0) from seg$ where ts#=:1 and file#=:2 and block#=:3 |
350f5yrnnmshs | lock table sys.mon_mods$ in exclusive mode nowait |
38apjgr0p55ns | update ICCICCS set CCSMAXOVERDUE=GREATEST(:b0, CCSMAXOVERDUE) where FNSACTNO=:b1 |
38gak8u2qm11w | select count(*) from CUSVAA_TMP |
3m8smr0v7v1m6 | INSERT INTO sys.wri$_adv_message_groups (task_id, id, seq, message#, fac, hdr, lm, nl, p1, p2, p3, p4, p5) VALUES (:1, :2, :3, :4, :5, :6, :7, :8, :9, :10, :11, :12, :13) |
44au3v5mzpc1c | insert into ICCICURMMAST values (:b0, :b1, :b2) |
49ms69srnaxzj | insert into ICCIRPYV values (:b0, :b1, :b2, :b3, :b4, :b5, :b6, :b7, :b8, :b9, :b10, :b11, :b12, :b13, :b14, :b15, :b16, :b17, :b18, :b19, :b20, :b21, :b22, :b23, :b24, :b25, :b26, :b27, :b28, :b29, :b30, :b31, :b32, :b33, :b34, :b35, :b36, :b37, :b38, :b39, :b40, :b41, :b42, :b43, :b44, :b45, :b46, :b47, :b48, :b49, :b50, :b51) |
4vja2k2gdtyup | insert into ICCICCS values (:b0, '////////////////////////', 0, 0, 0, 0, 0, ' ', 0, 0, 0, ' ', '0', null ) |
501v412s13r4m | update ICCIFNSACT set BORM_FACILITY_NO=:b0 where BORM_MEMB_CUST_AC=:b1 |
53saa2zkr6wc3 | select intcol#, nvl(pos#, 0), col#, nvl(spare1, 0) from ccol$ where con#=:1 |
569r5k05drsj7 | insert into CUMI select CUSV_CUST_NO , CUSV_EDUCATION_CODE , CHGDATE from CUMI_TMP where CHGFLAG<>'D' |
5c4qu2zmj3gux | select * from ICCIPRODCODE where PRODCODE=to_char(:b0) |
5ngzsfstg8tmy | select o.owner#, o.name, o.namespace, o.remoteowner, o.linkname, o.subname, o.dataobj#, o.flags from obj$ o where o.obj#=:1 |
6769wyy3yf66f | select pos#, intcol#, col#, spare1, bo#, spare2 from icol$ where obj#=:1 |
6z06gcfw39pkd | SELECT F.TABLESPACE_NAME, TO_CHAR ((T.TOTAL_SPACE - F.FREE_SPACE), '999, 999') "USED (MB)", TO_CHAR (F.FREE_SPACE, '999, 999') "FREE (MB)", TO_CHAR (T.TOTAL_SPACE, '999, 999') "TOTAL (MB)", TO_CHAR ((ROUND ((F.FREE_SPACE/T.TOTAL_SPACE)*100)), '999')||' %' PER_FREE FROM ( SELECT TABLESPACE_NAME, ROUND (SUM (BLOCKS*(SELECT VALUE/1024 FROM V$PARAMETER WHERE NAME = 'db_block_size')/1024) ) FREE_SPACE FROM DBA_FREE_SPACE GROUP BY TABLESPACE_NAME ) F, ( SELECT TABLESPACE_NAME, ROUND (SUM (BYTES/1048576)) TOTAL_SPACE FROM DBA_DATA_FILES GROUP BY TABLESPACE_NAME ) T WHERE F.TABLESPACE_NAME = T.TABLESPACE_NAME |
78m9ryygp65v5 | SELECT /*+ ALL_ROWS */ COUNT(*) FROM ALL_POLICIES V WHERE V.OBJECT_OWNER = :B3 AND V.OBJECT_NAME = :B2 AND (POLICY_NAME LIKE '%xdbrls%' OR POLICY_NAME LIKE '%$xd_%') AND V.FUNCTION = :B1 |
7gtztzv329wg0 | select c.name, u.name from con$ c, cdef$ cd, user$ u where c.con# = cd.con# and cd.enabled = :1 and c.owner# = u.user# |
7ng34ruy5awxq | select i.obj#, i.ts#, i.file#, i.block#, i.intcols, i.type#, i.flags, i.property, i.pctfree$, i.initrans, i.maxtrans, i.blevel, i.leafcnt, i.distkey, i.lblkkey, i.dblkkey, i.clufac, i.cols, i.analyzetime, i.samplesize, i.dataobj#, nvl(i.degree, 1), nvl(i.instances, 1), i.rowcnt, mod(i.pctthres$, 256), i.indmethod#, i.trunccnt, nvl(c.unicols, 0), nvl(c.deferrable#+c.valid#, 0), nvl(i.spare1, i.intcols), i.spare4, i.spare2, i.spare6, decode(i.pctthres$, null, null, mod(trunc(i.pctthres$/256), 256)), ist.cachedblk, ist.cachehit, ist.logicalread from ind$ i, ind_stats$ ist, (select enabled, min(cols) unicols, min(to_number(bitand(defer, 1))) deferrable#, min(to_number(bitand(defer, 4))) valid# from cdef$ where obj#=:1 and enabled > 1 group by enabled) c where i.obj#=c.enabled(+) and i.obj# = ist.obj#(+) and i.bo#=:1 order by i.obj# |
7v9dyf5r424yh | select NEWACTNO into :b0 from OLDNEWACT where OLDACTNO=:b1 |
7wwv1ybs9zguz | update ICCIFNSACT set BORM_ADV_DATE=:b0, BOIS_MATURITY_DATE=:b1, BOIS_UNPD_BAL=:b2, BOIS_UNPD_INT=:b3, BOIS_BAL_FINE=:b4, BOIS_INT_FINE=:b5, BOIS_FINE_FINE=:b6, BORM_LOAN_TRM=:b7, BORM_FIVE_STAT=:b8, BOIS_ARREARS_CTR=:b9, BOIS_ARREARS_SUM=:b10 where BORM_MEMB_CUST_AC=:b11 |
83taa7kaw59c1 | select name, intcol#, segcol#, type#, length, nvl(precision#, 0), decode(type#, 2, nvl(scale, -127/*MAXSB1MINAL*/), 178, scale, 179, scale, 180, scale, 181, scale, 182, scale, 183, scale, 231, scale, 0), null$, fixedstorage, nvl(deflength, 0), default$, rowid, col#, property, nvl(charsetid, 0), nvl(charsetform, 0), spare1, spare2, nvl(spare3, 0) from col$ where obj#=:1 order by intcol# |
4qubbrsr0kfn | insert into wrh$_latch (snap_id, dbid, instance_number, latch_hash, level#, gets, misses, sleeps, immediate_gets, immediate_misses, spin_gets, sleep1, sleep2, sleep3, sleep4, wait_time) select :snap_id, :dbid, :instance_number, hash, level#, gets, misses, sleeps, immediate_gets, immediate_misses, spin_gets, sleep1, sleep2, sleep3, sleep4, wait_time from v$latch order by hash |
9qgtwh76xg6nz | update seg$ set type#=:4, blocks=:5, extents=:6, minexts=:7, maxexts=:8, extsize=:9, extpct=:10, user#=:11, iniexts=:12, lists=decode(:13, 65535, NULL, :13), groups=decode(:14, 65535, NULL, :14), cachehint=:15, hwmincr=:16, spare1=DECODE(:17, 0, NULL, :17), scanhint=:18 where ts#=:1 and file#=:2 and block#=:3 |
9vtm7gy4fr2ny | select con# from con$ where owner#=:1 and name=:2 |
a2any035u1qz1 | select owner#, name from con$ where con#=:1 |
a7nh7j8zmfrzw | select CUSV_CUST_NO from CUMI_TMP where CHGFLAG='D' |
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Instance Activity Stats
Instance Activity Stats - Absolute Values
Instance Activity Stats - Thread Activity
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Statistic | Total | per Second | per Trans |
CPU used by this session | 23,388 | 4.95 | 4.18 |
CPU used when call started | 21,816 | 4.61 | 3.90 |
CR blocks created | 2,794 | 0.59 | 0.50 |
Cached Commit SCN referenced | 237,936 | 50.33 | 42.50 |
Commit SCN cached | 3 | 0.00 | 0.00 |
DB time | 583,424 | 123.41 | 104.22 |
DBWR checkpoint buffers written | 402,781 | 85.20 | 71.95 |
DBWR checkpoints | 9 | 0.00 | 0.00 |
DBWR fusion writes | 255 | 0.05 | 0.05 |
DBWR object drop buffers written | 0 | 0.00 | 0.00 |
DBWR thread checkpoint buffers written | 221,341 | 46.82 | 39.54 |
DBWR transaction table writes | 130 | 0.03 | 0.02 |
DBWR undo block writes | 219,272 | 46.38 | 39.17 |
DFO trees parallelized | 16 | 0.00 | 0.00 |
PX local messages recv'd | 40 | 0.01 | 0.01 |
PX local messages sent | 40 | 0.01 | 0.01 |
PX remote messages recv'd | 80 | 0.02 | 0.01 |
PX remote messages sent | 80 | 0.02 | 0.01 |
Parallel operations not downgraded | 16 | 0.00 | 0.00 |
RowCR - row contention | 9 | 0.00 | 0.00 |
RowCR attempts | 14 | 0.00 | 0.00 |
RowCR hits | 5 | 0.00 | 0.00 |
SMON posted for undo segment recovery | 0 | 0.00 | 0.00 |
SMON posted for undo segment shrink | 9 | 0.00 | 0.00 |
SQL*Net roundtrips to/from client | 1,544,063 | 326.62 | 275.82 |
active txn count during cleanout | 276,652 | 58.52 | 49.42 |
application wait time | 1,620 | 0.34 | 0.29 |
auto extends on undo tablespace | 0 | 0.00 | 0.00 |
background checkpoints completed | 7 | 0.00 | 0.00 |
background checkpoints started | 9 | 0.00 | 0.00 |
background timeouts | 21,703 | 4.59 | 3.88 |
branch node splits | 337 | 0.07 | 0.06 |
buffer is not pinned count | 1,377,184 | 291.32 | 246.01 |
buffer is pinned count | 20,996,139 | 4,441.37 | 3,750.65 |
bytes received via SQL*Net from client | 7,381,397,183 | 1,561,408.36 | 1,318,577.56 |
bytes sent via SQL*Net to client | 149,122,035 | 31,544.22 | 26,638.45 |
calls to get snapshot scn: kcmgss | 1,696,712 | 358.91 | 303.09 |
calls to kcmgas | 433,435 | 91.69 | 77.43 |
calls to kcmgcs | 142,482 | 30.14 | 25.45 |
change write time | 4,707 | 1.00 | 0.84 |
cleanout - number of ktugct calls | 282,045 | 59.66 | 50.38 |
cleanouts and rollbacks - consistent read gets | 55 | 0.01 | 0.01 |
cleanouts only - consistent read gets | 2,406 | 0.51 | 0.43 |
cluster key scan block gets | 21,886 | 4.63 | 3.91 |
cluster key scans | 10,540 | 2.23 | 1.88 |
cluster wait time | 2,855 | 0.60 | 0.51 |
commit batch/immediate performed | 294 | 0.06 | 0.05 |
commit batch/immediate requested | 294 | 0.06 | 0.05 |
commit cleanout failures: block lost | 2,227 | 0.47 | 0.40 |
commit cleanout failures: callback failure | 750 | 0.16 | 0.13 |
commit cleanout failures: cannot pin | 4 | 0.00 | 0.00 |
commit cleanouts | 427,610 | 90.45 | 76.39 |
commit cleanouts successfully completed | 424,629 | 89.82 | 75.85 |
commit immediate performed | 294 | 0.06 | 0.05 |
commit immediate requested | 294 | 0.06 | 0.05 |
commit txn count during cleanout | 111,557 | 23.60 | 19.93 |
concurrency wait time | 515 | 0.11 | 0.09 |
consistent changes | 1,716 | 0.36 | 0.31 |
consistent gets | 5,037,471 | 1,065.59 | 899.87 |
由consistent gets,db block gets和physical reads这三个值,我们也可以计算得到buffer hit ratio,计算的公式如下: buffer hit ratio = 100*(1-physical reads /(consistent gets+ db block gets)),例如在这里,我们可以计算得到:buffer hit ratio =100*(1-26524/(16616758+2941398))= 99.86 | |||
consistent gets - examination | 2,902,016 | 613.87 | 518.40 |
consistent gets direct | 0 | 0.00 | 0.00 |
consistent gets from cache | 5,037,471 | 1,065.59 | 899.87 |
current blocks converted for CR | 0 | 0.00 | 0.00 |
cursor authentications | 434 | 0.09 | 0.08 |
data blocks consistent reads - undo records applied | 1,519 | 0.32 | 0.27 |
db block changes | 8,594,158 | 1,817.95 | 1,535.22 |
db block gets | 11,611,321 | 2,456.18 | 2,074.19 |
db block gets direct | 1,167,830 | 247.03 | 208.62 |
db block gets from cache | 10,443,491 | 2,209.14 | 1,865.58 |
deferred (CURRENT) block cleanout applications | 20,786 | 4.40 | 3.71 |
dirty buffers inspected | 25,007 | 5.29 | 4.47 |
脏数据从LRU列表中老化,A value here indicates that the DBWR is not keeping up。如果这个值大于0,就需要考虑增加DBWRs。 dirty buffers inspected: This is the number of dirty (modified) data buffers that were aged out on the LRU list. You may benefit by adding more DBWRs.If it is greater than 0, consider increasing the database writes. | |||
drop segment calls in space pressure | 0 | 0.00 | 0.00 |
enqueue conversions | 6,734 | 1.42 | 1.20 |
enqueue releases | 595,149 | 125.89 | 106.31 |
enqueue requests | 595,158 | 125.90 | 106.32 |
enqueue timeouts | 9 | 0.00 | 0.00 |
enqueue waits | 7,901 | 1.67 | 1.41 |
exchange deadlocks | 1 | 0.00 | 0.00 |
execute count | 1,675,112 | 354.34 | 299.23 |
free buffer inspected | 536,832 | 113.56 | 95.90 |
这个值包含dirty,pinned,busy的buffer区域,如果free buffer inspected - dirty buffers inspected - buffer is pinned count的值还是比较大,表明不能被重用的内存块比较多,这将导致latch争用,需要增大buffer cache | |||
free buffer requested | 746,999 | 158.01 | 133.44 |
gc CPU used by this session | 9,099 | 1.92 | 1.63 |
gc cr block build time | 13 | 0.00 | 0.00 |
gc cr block flush time | 143 | 0.03 | 0.03 |
gc cr block receive time | 474 | 0.10 | 0.08 |
gc cr block send time | 36 | 0.01 | 0.01 |
gc cr blocks received | 4,142 | 0.88 | 0.74 |
gc cr blocks served | 10,675 | 2.26 | 1.91 |
gc current block flush time | 23 | 0.00 | 0.00 |
gc current block pin time | 34 | 0.01 | 0.01 |
gc current block receive time | 1,212 | 0.26 | 0.22 |
gc current block send time | 52 | 0.01 | 0.01 |
gc current blocks received | 15,502 | 3.28 | 2.77 |
gc current blocks served | 17,534 | 3.71 | 3.13 |
gc local grants | 405,329 | 85.74 | 72.41 |
gc remote grants | 318,630 | 67.40 | 56.92 |
gcs messages sent | 1,129,094 | 238.84 | 201.70 |
ges messages sent | 90,695 | 19.18 | 16.20 |
global enqueue get time | 1,707 | 0.36 | 0.30 |
global enqueue gets async | 12,731 | 2.69 | 2.27 |
global enqueue gets sync | 190,492 | 40.30 | 34.03 |
global enqueue releases | 190,328 | 40.26 | 34.00 |
global undo segment hints helped | 0 | 0.00 | 0.00 |
global undo segment hints were stale | 0 | 0.00 | 0.00 |
heap block compress | 108,758 | 23.01 | 19.43 |
hot buffers moved to head of LRU | 18,652 | 3.95 | 3.33 |
immediate (CR) block cleanout applications | 2,462 | 0.52 | 0.44 |
immediate (CURRENT) block cleanout applications | 325,184 | 68.79 | 58.09 |
index crx upgrade (positioned) | 4,663 | 0.99 | 0.83 |
index fast full scans (full) | 13 | 0.00 | 0.00 |
index fetch by key | 852,181 | 180.26 | 152.23 |
index scans kdiixs1 | 339,583 | 71.83 | 60.66 |
leaf node 90-10 splits | 34 | 0.01 | 0.01 |
leaf node splits | 106,552 | 22.54 | 19.03 |
lob reads | 11 | 0.00 | 0.00 |
lob writes | 83 | 0.02 | 0.01 |
lob writes unaligned | 83 | 0.02 | 0.01 |
local undo segment hints helped | 0 | 0.00 | 0.00 |
local undo segment hints were stale | 0 | 0.00 | 0.00 |
logons cumulative | 61 | 0.01 | 0.01 |
messages received | 20,040 | 4.24 | 3.58 |
messages sent | 19,880 | 4.21 | 3.55 |
no buffer to keep pinned count | 0 | 0.00 | 0.00 |
no work - consistent read gets | 1,513,070 | 320.06 | 270.29 |
opened cursors cumulative | 183,375 | 38.79 | 32.76 |
parse count (failures) | 1 | 0.00 | 0.00 |
parse count (hard) | 143 | 0.03 | 0.03 |
parse count (total) | 182,780 | 38.66 | 32.65 |
通过parse count (hard)和parse count (total),可以计算soft parse率为: 100-100*(parse count (hard)/parse count (total)) =100-100*(1-6090/191531)=96.82 | |||
parse time cpu | 27 | 0.01 | 0.00 |
parse time elapsed | 338 | 0.07 | 0.06 |
physical read IO requests | 82,815 | 17.52 | 14.79 |
physical read bytes | 2,643,378,176 | 559,161.45 | 472,200.46 |
physical read total IO requests | 98,871 | 20.91 | 17.66 |
physical read total bytes | 2,905,491,456 | 614,607.04 | 519,023.13 |
physical read total multi block requests | 24,089 | 5.10 | 4.30 |
physical reads | 322,678 | 68.26 | 57.64 |
physical reads cache | 213,728 | 45.21 | 38.18 |
physical reads cache prefetch | 191,830 | 40.58 | 34.27 |
physical reads direct | 108,950 | 23.05 | 19.46 |
physical reads direct temporary tablespace | 108,812 | 23.02 | 19.44 |
physical reads prefetch warmup | 0 | 0.00 | 0.00 |
physical write IO requests | 223,456 | 47.27 | 39.92 |
physical write bytes | 14,042,071,040 | 2,970,360.02 | 2,508,408.55 |
physical write total IO requests | 133,835 | 28.31 | 23.91 |
physical write total bytes | 23,114,268,672 | 4,889,428.30 | 4,129,022.63 |
physical write total multi block requests | 116,135 | 24.57 | 20.75 |
physical writes | 1,714,120 | 362.59 | 306.20 |
physical writes direct | 1,276,780 | 270.08 | 228.08 |
physical writes direct (lob) | 0 | 0.00 | 0.00 |
physical writes direct temporary tablespace | 108,812 | 23.02 | 19.44 |
physical writes from cache | 437,340 | 92.51 | 78.12 |
physical writes non checkpoint | 1,673,703 | 354.04 | 298.98 |
pinned buffers inspected | 10 | 0.00 | 0.00 |
prefetch clients - default | 0 | 0.00 | 0.00 |
prefetch warmup blocks aged out before use | 0 | 0.00 | 0.00 |
prefetch warmup blocks flushed out before use | 0 | 0.00 | 0.00 |
prefetched blocks aged out before use | 0 | 0.00 | 0.00 |
process last non-idle time | 4,730 | 1.00 | 0.84 |
queries parallelized | 16 | 0.00 | 0.00 |
recursive calls | 1,654,650 | 350.01 | 295.58 |
recursive cpu usage | 2,641 | 0.56 | 0.47 |
redo blocks written | 8,766,094 | 1,854.32 | 1,565.93 |
redo buffer allocation retries | 24 | 0.01 | 0.00 |
redo entries | 4,707,068 | 995.70 | 840.85 |
redo log space requests | 34 | 0.01 | 0.01 |
redo log space wait time | 50 | 0.01 | 0.01 |
redo ordering marks | 277,042 | 58.60 | 49.49 |
redo size | 4,343,559,400 | 918,805.72 | 775,912.72 |
redo subscn max counts | 2,693 | 0.57 | 0.48 |
redo synch time | 408 | 0.09 | 0.07 |
redo synch writes | 6,984 | 1.48 | 1.25 |
redo wastage | 1,969,620 | 416.64 | 351.84 |
redo write time | 5,090 | 1.08 | 0.91 |
redo writer latching time | 1 | 0.00 | 0.00 |
redo writes | 5,494 | 1.16 | 0.98 |
rollback changes - undo records applied | 166,609 | 35.24 | 29.76 |
rollbacks only - consistent read gets | 1,463 | 0.31 | 0.26 |
rows fetched via callback | 342,159 | 72.38 | 61.12 |
session connect time | 1,461 | 0.31 | 0.26 |
session cursor cache hits | 180,472 | 38.18 | 32.24 |
session logical reads | 16,648,792 | 3,521.77 | 2,974.06 |
session pga memory | 37,393,448 | 7,909.94 | 6,679.79 |
session pga memory max | 45,192,232 | 9,559.64 | 8,072.92 |
session uga memory | 30,067,312,240 | 6,360,225.77 | 5,371,081.14 |
session uga memory max | 61,930,448 | 13,100.33 | 11,062.96 |
shared hash latch upgrades - no wait | 6,364 | 1.35 | 1.14 |
shared hash latch upgrades - wait | 0 | 0.00 | 0.00 |
sorts (disk) | 4 | 0.00 | 0.00 |
磁盘排序一般不能超过5%。如果超过5%,需要设置参数PGA_AGGREGATE_TARGET或者 SORT_AREA_SIZE,注意,这里SORT_AREA_SIZE是分配给每个用户的,PGA_AGGREGATE_TARGET则是针对所有的session的一个总数设置。 | |||
sorts (memory) | 2,857 | 0.60 | 0.51 |
内存中的排序数量 | |||
sorts (rows) | 42,379,505 | 8,964.66 | 7,570.47 |
space was found by tune down | 0 | 0.00 | 0.00 |
space was not found by tune down | 0 | 0.00 | 0.00 |
sql area evicted | 7 | 0.00 | 0.00 |
sql area purged | 44 | 0.01 | 0.01 |
steps of tune down ret. in space pressure | 0 | 0.00 | 0.00 |
summed dirty queue length | 35,067 | 7.42 | 6.26 |
switch current to new buffer | 17 | 0.00 | 0.00 |
table fetch by rowid | 680,469 | 143.94 | 121.56 |
这是通过索引或者where rowid=语句来取得的行数,当然这个值越大越好。 | |||
table fetch continued row | 0 | 0.00 | 0.00 |
这是发生行迁移的行。当行迁移的情况比较严重时,需要对这部分进行优化。 检查行迁移的方法: 1) 运行$ORACLE_HOME/rdbms/admin/utlchain.sql 2) analyze table table_name list chained rows into CHAINED_ROWS 3) select * from CHAINED_ROWS where table_name='table_name'; 清除的方法: 方法1:create table table_name_tmp as select * from table_name where rowed in (select head_rowid from chained_rows); Delete from table_name where rowed in (select head_rowid from chained_rows); Insert into table_name select * from table_name_tmp; 方法2:create table table_name_tmp select * from table_name ; truncate table table_name insert into table_name select * from table_name_tmp 方法3:用exp工具导出表,然后删除这个表,最后用imp工具导入这表 方法4:alter table table_name move tablespace tablespace_name,然后再重新表的索引 上面的4种方法可以用以消除已经存在的行迁移现象,但是行迁移的产生很多情况下时由于PCT_FREE参数设置的太小所导致,所以需要调整PCT_FREE参数的值。 | |||
table scan blocks gotten | 790,986 | 167.32 | 141.30 |
table scan rows gotten | 52,989,363 | 11,208.99 | 9,465.77 |
table scans (long tables) | 4 | 0.00 | 0.00 |
longtables就是表的大小超过buffer buffer* _SMALL_TABLE_THRESHOLD的表。如果一个数据库的大表扫描过多,那么db file scattered read等待事件可能同样非常显著。如果table scans (long tables)的per Trans值大于0,你可能需要增加适当的索引来优化你的SQL语句 | |||
table scans (short tables) | 169,201 | 35.79 | 30.23 |
short tables是指表的长度低于buffer chache 2%(2%是有隐含参数_SMALL_TABLE_THRESHOLD定义的,这个参数在oracle不同的版本中,有不同的含义。在9i和10g中,该参数值定义为2%,在8i中,该参数值为20个blocks,在v7中,该参数为5个blocks)的表。这些表将优先使用全表扫描。一般不使用索引。_SMALL_TABLE_THRESHOLD值的计算方法如下(9i,8K): (db_cache_size/8192)*2%。 注意:_SMALL_TABLE_THRESHOLD参数修改是相当危险的操作 | |||
total number of times SMON posted | 259 | 0.05 | 0.05 |
transaction lock background get time | 0 | 0.00 | 0.00 |
transaction lock background gets | 0 | 0.00 | 0.00 |
transaction lock foreground requests | 0 | 0.00 | 0.00 |
transaction lock foreground wait time | 0 | 0.00 | 0.00 |
transaction rollbacks | 294 | 0.06 | 0.05 |
tune down retentions in space pressure | 0 | 0.00 | 0.00 |
undo change vector size | 1,451,085,596 | 306,952.35 | 259,215.00 |
user I/O wait time | 11,992 | 2.54 | 2.14 |
user calls | 1,544,383 | 326.69 | 275.88 |
user commits | 812 | 0.17 | 0.15 |
user rollbacks | 4,786 | 1.01 | 0.85 |
workarea executions - onepass | 1 | 0.00 | 0.00 |
workarea executions - optimal | 1,616 | 0.34 | 0.29 |
write clones created in background | 0 | 0.00 | 0.00 |
write clones created in foreground | 11 | 0.00 | 0.00 |
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Statistics with absolute values (should not be diffed)
Statistic | Begin Value | End Value |
session cursor cache count | 3,024 | 3,592 |
opened cursors current | 37 | 39 |
logons current | 24 | 26 |
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Statistics identified by '(derived)' come from sources other than SYSSTAT
Statistic | Total | per Hour |
log switches (derived) | 9 | 6.85 |
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Tablespace IO Stats
File IO Stats
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通常,在这里期望在各设备上的读取和写入操作是均匀分布的。要找出什么文件可能非常“热”。一旦DBA了解了如何读取和写入这些数据,他们也许能够通过磁盘间更均匀的分配I/O而得到某些性能提升。
在这里主要关注Av Rd(ms)列 (reads per millisecond)的值,一般来说,大部分的磁盘系统的这个值都能调整到14ms以下,oracle认为该值超过20ms都是不必要的。如果该值超过1000ms,基本可以肯定存在I/O的性能瓶颈。如果在这一列上出现######,可能是你的系统存在严重的I/O问题,也可能是格式的显示问题。
当出现上面的问题,我们可以考虑以下的方法:
1)优化操作该表空间或者文件的相关的语句。
2)如果该表空间包含了索引,可以考虑压缩索引,是索引的分布空间减小,从而减小I/O。
3)将该表空间分散在多个逻辑卷中,平衡I/O的负载。
4)我们可以通过设置参数DB_FILE_MULTIBLOCK_READ_COUNT来调整读取的并行度,这将提高全表扫描的效率。但是也会带来一个问题,就是oracle会因此更多的使用全表扫描而放弃某些索引的使用。为解决这个问题,我们需要设置另外一个参数OPTIMIZER_INDEX_COST_ADJ=30(一般建议设置10-50)。
关于OPTIMIZER_INDEX_COST_ADJ=n:该参数是一个百分比值,缺省值为100,可以理解为FULL SCAN COST/INDEX SCAN COST。当n%* INDEX SCAN COST<FULL SCAN COST时,oracle会选择使用索引。在具体设置的时候,我们可以根据具体的语句来调整该值。如果我们希望某个statement使用索引,而实际它确走全表扫描,可以对比这两种情况的执行计划不同的COST,从而设置一个更合适的值。
5)检查并调整I/O设备的性能。
ordered by IOs (Reads + Writes) desc
Tablespace | Reads | Av Reads/s | Av Rd(ms) | Av Blks/Rd | Writes | Av Writes/s | Buffer Waits | Av Buf Wt(ms) |
ICCIDAT01 | 67,408 | 14 | 3.76 | 3.17 | 160,261 | 34 | 6 | 0.00 |
UNDOTBS1 | 10 | 0 | 12.00 | 1.00 | 57,771 | 12 | 625 | 0.02 |
TEMP | 15,022 | 3 | 8.74 | 7.24 | 3,831 | 1 | 0 | 0.00 |
USERS | 68 | 0 | 5.44 | 1.00 | 971 | 0 | 0 | 0.00 |
SYSAUX | 263 | 0 | 5.48 | 1.00 | 458 | 0 | 0 | 0.00 |
SYSTEM | 32 | 0 | 5.94 | 1.00 | 158 | 0 | 3 | 23.33 |
UNDOTBS2 | 6 | 0 | 16.67 | 1.00 | 6 | 0 | 0 | 0.00 |
显示每个表空间的I/O统计。根据Oracle经验,Av Rd(ms) [Average Reads in milliseconds]不应该超过30,否则认为有I/O争用。
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ordered by Tablespace, File
Tablespace | Filename | Reads | Av Reads/s | Av Rd(ms) | Av Blks/Rd | Writes | Av Writes/s | Buffer Waits | Av Buf Wt(ms) |
ICCIDAT01 | /dev/rora_icci01 | 5,919 | 1 | 4.30 | 3.73 | 15,161 | 3 | 1 | 0.00 |
ICCIDAT01 | /dev/rora_icci02 | 7,692 | 2 | 4.12 | 3.18 | 16,555 | 4 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci03 | 6,563 | 1 | 2.59 | 3.80 | 15,746 | 3 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci04 | 8,076 | 2 | 2.93 | 3.11 | 16,164 | 3 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci05 | 6,555 | 1 | 2.61 | 3.31 | 21,958 | 5 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci06 | 6,943 | 1 | 4.03 | 3.41 | 20,574 | 4 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci07 | 7,929 | 2 | 4.12 | 2.87 | 18,263 | 4 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci08 | 7,719 | 2 | 3.83 | 2.99 | 17,361 | 4 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci09 | 6,794 | 1 | 4.79 | 3.29 | 18,425 | 4 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci10 | 211 | 0 | 5.31 | 1.00 | 6 | 0 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci11 | 1,168 | 0 | 4.45 | 1.00 | 6 | 0 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci12 | 478 | 0 | 4.23 | 1.00 | 6 | 0 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci13 | 355 | 0 | 5.13 | 1.00 | 6 | 0 | 0 | 0.00 |
ICCIDAT01 | /dev/rora_icci14 | 411 | 0 | 4.91 | 1.00 | 6 | 0 | 1 | 0.00 |
ICCIDAT01 | /dev/rora_icci15 | 172 | 0 | 5.29 | 1.00 | 6 | 0 | 1 | 0.00 |
ICCIDAT01 | /dev/rora_icci16 | 119 | 0 | 7.23 | 1.00 | 6 | 0 | 1 | 0.00 |
ICCIDAT01 | /dev/rora_icci17 | 227 | 0 | 6.26 | 1.00 | 6 | 0 | 1 | 0.00 |
ICCIDAT01 | /dev/rora_icci18 | 77 | 0 | 8.44 | 1.00 | 6 | 0 | 1 | 0.00 |
SYSAUX | /dev/rora_SYSAUX | 263 | 0 | 5.48 | 1.00 | 458 | 0 | 0 | 0.00 |
SYSTEM | /dev/rora_SYSTEM | 32 | 0 | 5.94 | 1.00 | 158 | 0 | 3 | 23.33 |
TEMP | /dev/rora_TEMP | 3,653 | 1 | 5.67 | 6.61 | 827 | 0 | 0 |
|
TEMP | /dev/rora_TEMP2 | 2,569 | 1 | 4.42 | 6.70 | 556 | 0 | 0 |
|
TEMP | /dev/rora_TEMP3 | 1,022 | 0 | 2.50 | 16.86 | 557 | 0 | 0 |
|
TEMP | /dev/rora_TEMP5 | 7,778 | 2 | 12.43 | 6.46 | 1,891 | 0 | 0 |
|
UNDOTBS1 | /dev/rora_UNDO0101 | 10 | 0 | 12.00 | 1.00 | 57,771 | 12 | 625 | 0.02 |
UNDOTBS2 | /dev/rora_UNDO0201 | 6 | 0 | 16.67 | 1.00 | 6 | 0 | 0 | 0.00 |
USERS | /dev/rora_USERS | 68 | 0 | 5.44 | 1.00 | 971 | 0 | 0 | 0.00 |
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Standard block size Pools D: default, K: keep, R: recycle
Default Pools for other block sizes: 2k, 4k, 8k, 16k, 32k
P | Number of Buffers | Pool Hit% | Buffer Gets | Physical Reads | Physical Writes | Free Buff Wait | Writ Comp Wait | Buffer Busy Waits |
D | 401,071 | 99 | 15,480,754 | 213,729 | 437,340 | 0 | 0 | 634 |
这里将buffer poll细分,列举default、keep、recycle三种类型的buffer的详细情况。在这份报告中,我们的系统中只使用Default size的buffer pool。这里的3个waits统计,其实在前面的等待时间中已经包含,所以可以参考前面的描述。关于命中率也已经在前面讨论。所以,其实这段信息不需要怎么关注。
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Instance Recovery Stats
Buffer Pool Advisory
PGA Aggr Summary
PGA Aggr Target Stats
PGA Aggr Target Histogram
PGA Memory Advisory
Shared Pool Advisory
SGA Target Advisory
Streams Pool Advisory
Java Pool Advisory
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B: Begin snapshot, E: End snapshot
| Targt MTTR (s) | Estd MTTR (s) | Recovery Estd IOs | Actual Redo Blks | Target Redo Blks | Log File Size Redo Blks | Log Ckpt Timeout Redo Blks | Log Ckpt Interval Redo Blks |
B | 0 | 11 | 369 | 2316 | 5807 | 1883700 | 5807 |
|
E | 0 | 98 | 116200 | 1828613 | 1883700 | 1883700 | 5033355 |
|
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Only rows with estimated physical reads >0 are displayed
ordered by Block Size, Buffers For Estimate
这是oracle的对buffer pool的大小的调整建议。从advisory的数据看,当然buffer是越大,物理读更小,随着buffer的增大,对物理读的性能改进越来越小。当前buffer 设置为5,120M,物理读因子=1。我们可以看到,buffer pool在3G之前的扩大,对物理读的改善非常明显,之后,这种改善的程度越来越低。
P | Size for Est (M) | Size Factor | Buffers for Estimate | Est Phys Read Factor | Estimated Physical Reads |
D | 320 | 0.10 | 38,380 | 1.34 | 10,351,726 |
D | 640 | 0.19 | 76,760 | 1.25 | 9,657,000 |
D | 960 | 0.29 | 115,140 | 1.08 | 8,365,242 |
D | 1,280 | 0.38 | 153,520 | 1.04 | 8,059,415 |
D | 1,600 | 0.48 | 191,900 | 1.02 | 7,878,202 |
D | 1,920 | 0.57 | 230,280 | 1.01 | 7,841,140 |
D | 2,240 | 0.67 | 268,660 | 1.01 | 7,829,141 |
D | 2,560 | 0.77 | 307,040 | 1.01 | 7,817,370 |
D | 2,880 | 0.86 | 345,420 | 1.01 | 7,804,884 |
D | 3,200 | 0.96 | 383,800 | 1.00 | 7,784,014 |
D | 3,344 | 1.00 | 401,071 | 1.00 | 7,748,403 |
D | 3,520 | 1.05 | 422,180 | 0.99 | 7,702,243 |
D | 3,840 | 1.15 | 460,560 | 0.99 | 7,680,429 |
D | 4,160 | 1.24 | 498,940 | 0.99 | 7,663,046 |
D | 4,480 | 1.34 | 537,320 | 0.99 | 7,653,232 |
D | 4,800 | 1.44 | 575,700 | 0.99 | 7,645,544 |
D | 5,120 | 1.53 | 614,080 | 0.98 | 7,630,008 |
D | 5,440 | 1.63 | 652,460 | 0.98 | 7,616,886 |
D | 5,760 | 1.72 | 690,840 | 0.98 | 7,614,591 |
D | 6,080 | 1.82 | 729,220 | 0.98 | 7,613,191 |
D | 6,400 | 1.91 | 767,600 | 0.98 | 7,599,930 |
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PGA cache hit % - percentage of W/A (WorkArea) data processed only in-memory
PGA Cache Hit % | W/A MB Processed | Extra W/A MB Read/Written |
87.91 | 1,100 | 151 |
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B: Begin snap E: End snap (rows dentified with B or E contain data which is absolute i.e. not diffed over the interval)
Auto PGA Target - actual workarea memory target
W/A PGA Used - amount of memory used for all Workareas (manual + auto)
%PGA W/A Mem - percentage of PGA memory allocated to workareas
%Auto W/A Mem - percentage of workarea memory controlled by Auto Mem Mgmt
%Man W/A Mem - percentage of workarea memory under manual control
| PGA Aggr Target(M) | Auto PGA Target(M) | PGA Mem Alloc(M) | W/A PGA Used(M) | %PGA W/A Mem | %Auto W/A Mem | %Man W/A Mem | Global Mem Bound(K) |
B | 1,024 | 862 | 150.36 | 0.00 | 0.00 | 0.00 | 0.00 | 104,850 |
E | 1,024 | 860 | 154.14 | 0.00 | 0.00 | 0.00 | 0.00 | 104,850 |
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Optimal Executions are purely in-memory operations
Low Optimal | High Optimal | Total Execs | Optimal Execs | 1-Pass Execs | M-Pass Execs |
2K | 4K | 1,385 | 1,385 | 0 | 0 |
64K | 128K | 28 | 28 | 0 | 0 |
128K | 256K | 5 | 5 | 0 | 0 |
256K | 512K | 79 | 79 | 0 | 0 |
512K | 1024K | 108 | 108 | 0 | 0 |
1M | 2M | 7 | 7 | 0 | 0 |
8M | 16M | 1 | 1 | 0 | 0 |
128M | 256M | 3 | 2 | 1 | 0 |
256M | 512M | 1 | 1 | 0 | 0 |
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When using Auto Memory Mgmt, minimally choose a pga_aggregate_target value where Estd PGA Overalloc Count is 0
PGA Target Est (MB) | Size Factr | W/A MB Processed | Estd Extra W/A MB Read/ Written to Disk | Estd PGA Cache Hit % | Estd PGA Overalloc Count |
128 | 0.13 | 4,652.12 | 2,895.99 | 62.00 | 0 |
256 | 0.25 | 4,652.12 | 2,857.13 | 62.00 | 0 |
512 | 0.50 | 4,652.12 | 2,857.13 | 62.00 | 0 |
768 | 0.75 | 4,652.12 | 2,857.13 | 62.00 | 0 |
1,024 | 1.00 | 4,652.12 | 717.82 | 87.00 | 0 |
1,229 | 1.20 | 4,652.12 | 717.82 | 87.00 | 0 |
1,434 | 1.40 | 4,652.12 | 717.82 | 87.00 | 0 |
1,638 | 1.60 | 4,652.12 | 717.82 | 87.00 | 0 |
1,843 | 1.80 | 4,652.12 | 717.82 | 87.00 | 0 |
2,048 | 2.00 | 4,652.12 | 717.82 | 87.00 | 0 |
3,072 | 3.00 | 4,652.12 | 717.82 | 87.00 | 0 |
4,096 | 4.00 | 4,652.12 | 717.82 | 87.00 | 0 |
6,144 | 6.00 | 4,652.12 | 717.82 | 87.00 | 0 |
8,192 | 8.00 | 4,652.12 | 717.82 | 87.00 | 0 |
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SP: Shared Pool Est LC: Estimated Library Cache Factr: Factor
Note there is often a 1:Many correlation between a single logical object in the Library Cache, and the physical number of memory objects associated with it. Therefore comparing the number of Lib Cache objects (e.g. in v$librarycache), with the number of Lib Cache Memory Objects is invalid.
Shared Pool Size(M) | SP Size Factr | Est LC Size (M) | Est LC Mem Obj | Est LC Time Saved (s) | Est LC Time Saved Factr | Est LC Load Time (s) | Est LC Load Time Factr | Est LC Mem Obj Hits |
304 | 0.43 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
384 | 0.55 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
464 | 0.66 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
544 | 0.77 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
624 | 0.89 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
704 | 1.00 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
784 | 1.11 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
864 | 1.23 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
944 | 1.34 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
1,024 | 1.45 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
1,104 | 1.57 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
1,184 | 1.68 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
1,264 | 1.80 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
1,344 | 1.91 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
1,424 | 2.02 | 78 | 7,626 | 64,842 | 1.00 | 31 | 1.00 | 3,206,955 |
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SGA Target Size (M) | SGA Size Factor | Est DB Time (s) | Est Physical Reads |
1,024 | 0.25 | 9,060 | 9,742,760 |
2,048 | 0.50 | 7,612 | 7,948,245 |
3,072 | 0.75 | 7,563 | 7,886,258 |
4,096 | 1.00 | 7,451 | 7,748,338 |
5,120 | 1.25 | 7,423 | 7,713,470 |
6,144 | 1.50 | 7,397 | 7,680,927 |
7,168 | 1.75 | 7,385 | 7,666,980 |
8,192 | 2.00 | 7,385 | 7,666,980 |
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No data exists for this section of the report.
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No data exists for this section of the report.
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Buffer Wait Statistics
Enqueue Activity
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ordered by wait time desc, waits desc
Class | Waits | Total Wait Time (s) | Avg Time (ms) |
data block | 3 | 0 | 23 |
undo header | 616 | 0 | 0 |
file header block | 8 | 0 | 0 |
undo block | 7 | 0 | 0 |
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Wait Statistics
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only enqueues with waits are shown
Enqueue stats gathered prior to 10g should not be compared with 10g data
ordered by Wait Time desc, Waits desc
Enqueue Type (Request Reason) | Requests | Succ Gets | Failed Gets | Waits | Wt Time (s) | Av Wt Time(ms) |
FB-Format Block | 14,075 | 14,075 | 0 | 7,033 | 3 | 0.43 |
US-Undo Segment | 964 | 964 | 0 | 556 | 0 | 0.32 |
WF-AWR Flush | 24 | 24 | 0 | 14 | 0 | 9.00 |
HW-Segment High Water Mark | 4,223 | 4,223 | 0 | 37 | 0 | 1.22 |
CF-Controlfile Transaction | 10,548 | 10,548 | 0 | 58 | 0 | 0.67 |
TX-Transaction (index contention) | 1 | 1 | 0 | 1 | 0 | 35.00 |
TM-DML | 121,768 | 121,761 | 6 | 70 | 0 | 0.43 |
PS-PX Process Reservation | 103 | 103 | 0 | 46 | 0 | 0.65 |
TT-Tablespace | 9,933 | 9,933 | 0 | 39 | 0 | 0.54 |
TD-KTF map table enqueue (KTF dump entries) | 12 | 12 | 0 | 12 | 0 | 1.42 |
TA-Instance Undo | 18 | 18 | 0 | 13 | 0 | 0.38 |
PI-Remote PX Process Spawn Status | 16 | 16 | 0 | 8 | 0 | 0.50 |
MW-MWIN Schedule | 3 | 3 | 0 | 3 | 0 | 0.67 |
DR-Distributed Recovery | 3 | 3 | 0 | 3 | 0 | 0.33 |
TS-Temporary Segment | 14 | 11 | 3 | 3 | 0 | 0.33 |
AF-Advisor Framework (task serialization) | 14 | 14 | 0 | 1 | 0 | 1.00 |
JS-Job Scheduler (job run lock - synchronize) | 2 | 2 | 0 | 1 | 0 | 1.00 |
UL-User-defined | 2 | 2 | 0 | 1 | 0 | 1.00 |
MD-Materialized View Log DDL | 6 | 6 | 0 | 2 | 0 | 0.00 |
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Undo Segment Summary
Undo Segment Stats
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Undo从9i开始,回滚段一般都是自动管理的,一般情况下,这里我们不需要太重点关注。
在这里,主要关注pct waits,如果出现比较多的pct waits,那就需要增加回滚段的数量或者增大回滚段的空间。另外,观察一下各个回滚段使用的情况,比较理想的是各个回滚段上Avg Active比较均衡。
在oracle 9i之前,回滚段时手工管理的,可以通过指定optimal值来设定一个回滚段收缩的值,如果不设定,默认也应当为initial+(minextents-1)*next extents ,这个指定的结果,就是限制了回滚段不能无限制的增长,当超过optimal的设定值后,在适当的时候,oracle会shrinks到optimal大小。但是9i之后,undo一般都设置为auto模式,在这种模式下,我们无法指定optimal值,好像也没有默认值,所以无法shrinks,回滚段就会无限制的增长,一直到表空间利用率达到为100%,如果表空间设置为自动扩展的方式,这种情况下,就更糟糕,undo将无限制的增长。在这里,我们也可以看到,shrinks的值为0,也就是说,从来就没收缩过。
Min/Max TR (mins) - Min and Max Tuned Retention (minutes)
STO - Snapshot Too Old count, OOS - Out of Space count
Undo segment block stats:
uS - unexpired Stolen, uR - unexpired Released, uU - unexpired reUsed
eS - expired Stolen, eR - expired Released, eU - expired reUsed
Undo TS# | Num Undo Blocks (K) | Number of Transactions | Max Qry Len (s) | Max Tx Concurcy | Min/Max TR (mins) | STO/ OOS | uS/uR/uU/ eS/eR/eU |
1 | 219.12 | 113,405 | 0 | 6 | 130.95/239.25 | 0/0 | 0/0/0/13/24256/0 |
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Most recent 35 Undostat rows, ordered by Time desc
End Time | Num Undo Blocks | Number of Transactions | Max Qry Len (s) | Max Tx Concy | Tun Ret (mins) | STO/ OOS | uS/uR/uU/ eS/eR/eU |
25-Dec 15:18 | 182,021 | 74,309 | 0 | 5 | 131 | 0/0 | 0/0/0/13/24256/0 |
25-Dec 15:08 | 57 | 170 | 0 | 3 | 239 | 0/0 | 0/0/0/0/0/0 |
25-Dec 14:58 | 68 | 31 | 0 | 2 | 229 | 0/0 | 0/0/0/0/0/0 |
25-Dec 14:48 | 194 | 4,256 | 0 | 4 | 219 | 0/0 | 0/0/0/0/0/0 |
25-Dec 14:38 | 570 | 12,299 | 0 | 5 | 209 | 0/0 | 0/0/0/0/0/0 |
25-Dec 14:28 | 36,047 | 21,328 | 0 | 6 | 200 | 0/0 | 0/0/0/0/0/0 |
25-Dec 14:18 | 70 | 907 | 0 | 3 | 162 | 0/0 | 0/0/0/0/0/0 |
25-Dec 14:08 | 91 | 105 | 0 | 3 | 154 | 0/0 | 0/0/0/0/0/0 |
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Latch Activity
Latch Sleep Breakdown
Latch Miss Sources
Parent Latch Statistics
Child Latch Statistics
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Latch是一种低级排队机制,用于防止对内存结构的并行访问,保护系统全局区(SGA)共享内存结构。Latch是一种快速地被获取和释放的内存锁。如果latch不可用,就会记录latch free miss 。
有两种类型的Latch:willing to wait和(immediate)not willing to wait。
对于愿意等待类型(willing-to-wait)的latch,如果一个进程在第一次尝试中没有获得latch,那么它会等待并且再尝试一次,如果经过_spin_count次争夺不能获得latch, 然后该进程转入睡眠状态,百分之一秒之后醒来,按顺序重复以前的步骤。在8i/9i中默认值是_spin_count=2000。睡眠的时间会越来越长。
对于不愿意等待类型(not-willing-to-wait)的latch,如果该闩不能立即得到的话,那么该进程就不会为获得该闩而等待。它将继续执行另一个操作。
大多数Latch问题都可以归结为以下几种:
没有很好的是用绑定变量(library cache latch和shared pool cache)、重作生成问题(redo allocation latch)、缓冲存储竞争问题(cache buffers LRU chain),以及buffer cache中的存在"热点"块(cache buffers chain)。
另外也有一些latch等待与bug有关,应当关注Metalink相关bug的公布及补丁的发布。
当latch miss ratios大于0.5%时,就需要检查latch的等待问题。
如果SQL语句不能调整,在8.1.6版本以上,可以通过设置CURSOR_SHARING = force 在服务器端强制绑定变量。设置该参数可能会带来一定的副作用,可能会导致执行计划不优,另外对于Java的程序,有相关的bug,具体应用应该关注Metalink的bug公告。
下面对几个重要类型的latch等待加以说明:
1) latch free:当‘latch free’在报告的高等待事件中出现时,就表示可能出现了性能问题,就需要在这一部分详细分析出现等待的具体的latch的类型,然后再调整。
2) cache buffers chain:cbc latch表明热块。为什么这会表示存在热块?为了理解这个问题,先要理解cbc的作用。ORACLE对buffer cache管理是以hash链表的方式来实现的(oracle称为buckets,buckets的数量由_db_block_hash_buckets定义)。cbc latch就是为了保护buffer cache而设置的。当有并发的访问需求时,cbc会将这些访问串行化,当我们获得cbc latch的控制权时,就可以开始访问数据,如果我们所请求的数据正好的某个buckets中,那就直接从内存中读取数据,完成之后释放cbc latch,cbc latch就可以被其他的用户获取了。cbc latch获取和释放是非常快速的,所以这种情况下就一般不会存在等待。但是如果我们请求的数据在内存中不存在,就需要到物理磁盘上读取数据,这相对于latch来说就是一个相当长的时间了,当找到对应的数据块时,如果有其他用户正在访问这个数据块,并且数据块上也没有空闲的ITL槽来接收本次请求,就必须等待。在这过程中,我们因为没有得到请求的数据,就一直占有cbc
latch,其他的用户也就无法获取cbc latch,所以就出现了cbc latch等待的情况。所以这种等待归根结底就是由于数据块比较hot的造成的。
解决方法可以参考前面在等待事件中的3)buffer
busy wait中关于热块的解决方法。
3) cache buffers lru chain:该latch用于扫描buffer的LRU链表。三种情况可导致争用:1)buffer cache太小 ;2)buffer cache的过度使用,或者太多的基于cache的排序操作;3)DBWR不及时。解决方法:查找逻辑读过高的statement,增大buffer cache。
4) Library cache and shared
pool 争用:
library cache是一个hash table,我们需要通过一个hash buckets数组来访问(类似buffer cache)。library cache latch就是将对library cache的访问串行化。当有一个sql(或者PL/SQL procedure,package,function,trigger)需要执行的时候,首先需要获取一个latch,然后library cache latch就会去查询library cache以重用这些语句。在8i中,library cache latch只有一个。在9i中,有7个child latch,这个数量可以通过参数_KGL_LATCH_ COUNT修改(最大可以达到66个)。当共享池太小或者语句的reuse低的时候,会出现‘shared pool’、‘library cache pin’或者 ‘library cache’ latch的争用。解决的方法是:增大共享池或者设置CURSOR_SHARING=FORCE|SIMILAR ,当然我们也需要tuning SQL statement。为减少争用,我们也可以把一些比较大的SQL或者过程利用DBMS_SHARED_POOL.KEEP包来pinning在shared pool中。
shared pool内存结构与buffer cache类似,也采用的是hash方式来管理的。共享池有一个固定数量的hash buckets,通过固定数量的library cache latch来串行化保护这段内存的使用。在数据启动的时候,会分配509个hash buctets,2*CPU_COUNT个library cache latch。当在数据库的使用中,共享池中的对象越来越多,oracle就会以以下的递增方式增加hash buckets的数量:509,1021,4093,8191,32749,65521,131071,4292967293。我们可以通过设置下面的参数来实现_KGL_BUCKET_COUNT,参数的默认值是0,代表数量509,最大我们可以设置为8,代表数量131071。
我们可以通过x$ksmsp来查看具体的共享池内存段情况,主要关注下面几个字段:
KSMCHCOM—表示内存段的类型
ksmchptr—表示内存段的物理地址
ksmchsiz—表示内存段的大小
ksmchcls—表示内存段的分类。recr表示a
recreatable piece currently in use that can be a candidate for flushing when
the shared pool is low in available memory; freeabl表示当前正在使用的,能够被释放的段; free表示空闲的未分配的段; perm表示不能被释放永久分配段。
降低共享池的latch 争用,我们主要可以考虑如下的几个事件:
1、使用绑定变量
2、使用cursor sharing
3、设置session_cached_cursors参数。该参数的作用是将cursor从shared pool转移到pga中。减小对共享池的争用。一般初始的值可以设置为100,然后视情况再作调整。
4、设置合适大小的共享池
5) Redo Copy:这个latch用来从PGA中copy redo records到redo log buffer。latch的初始数量是2*COU_OUNT,可以通过设置参数_LOG_SIMULTANEOUS_COPIES在增加latch的数量,减小争用。
6) Redo allocation:该latch用于redo log buffer的分配。减小这种类型的争用的方法有3个:
增大redo log buffer
适当使用nologging选项
避免不必要的commit操作
7) Row cache objects:该latch出现争用,通常表明数据字典存在争用的情况,这往往也预示着过多的依赖于公共同义词的parse。解决方法:1)增大shared pool 2)使用本地管理的表空间,尤其对于索引表空间
Latch事件 | 建议解决方法 |
Library cache | 使用绑定变量; 调整shared_pool_size. |
Shared pool | 使用绑定变量; 调整shared_pool_size. |
Redo allocation | 减小 redo 的产生; 避免不必要的commits. |
Redo copy | 增加 _log_simultaneous_copies. |
Row cache objects | 增加shared_pool_size |
Cache buffers chain | 增大 _DB_BLOCK_HASH_BUCKETS ; make it prime. |
Cache buffers LRU chain | 使用多个缓冲池;调整引起大量逻辑读的查询 |
注:在这里,提到了不少隐藏参数,也有利用隐藏参数来解决latch的方法描述,但是在实际的操作中,强烈建议尽量不要去更改隐藏参数的默认值。
"Get Requests", "Pct Get Miss" and "Avg Slps/Miss" are statistics for willing-to-wait latch get requests
"NoWait Requests", "Pct NoWait Miss" are for no-wait latch get requests
"Pct Misses" for both should be very close to 0.0
Latch Name | Get Requests | Pct Get Miss | Avg Slps /Miss | Wait Time (s) | NoWait Requests | Pct NoWait Miss |
ASM db client latch | 11,883 | 0.00 |
| 0 | 0 |
|
AWR Alerted Metric Element list | 18,252 | 0.00 |
| 0 | 0 |
|
Consistent RBA | 5,508 | 0.02 | 0.00 | 0 | 0 |
|
FOB s.o list latch | 731 | 0.00 |
| 0 | 0 |
|
JS broadcast add buf latch | 6,193 | 0.00 |
| 0 | 0 |
|
JS broadcast drop buf latch | 6,194 | 0.00 |
| 0 | 0 |
|
JS broadcast load blnc latch | 6,057 | 0.00 |
| 0 | 0 |
|
JS mem alloc latch | 8 | 0.00 |
| 0 | 0 |
|
JS queue access latch | 8 | 0.00 |
| 0 | 0 |
|
JS queue state obj latch | 218,086 | 0.00 |
| 0 | 0 |
|
JS slv state obj latch | 31 | 0.00 |
| 0 | 0 |
|
KCL gc element parent latch | 2,803,392 | 0.04 | 0.01 | 0 | 108 | 0.00 |
KJC message pool free list | 43,168 | 0.06 | 0.00 | 0 | 14,532 | 0.01 |
KJCT flow control latch | 563,875 | 0.00 | 0.00 | 0 | 0 |
|
KMG MMAN ready and startup request latch | 1,576 | 0.00 |
| 0 | 0 |
|
KSXR large replies | 320 | 0.00 |
| 0 | 0 |
|
KTF sga latch | 23 | 0.00 |
| 0 | 1,534 | 0.00 |
KWQMN job cache list latch | 352 | 0.00 |
| 0 | 0 |
|
KWQP Prop Status | 5 | 0.00 |
| 0 | 0 |
|
MQL Tracking Latch | 0 |
|
| 0 | 94 | 0.00 |
Memory Management Latch | 0 |
|
| 0 | 1,576 | 0.00 |
OS process | 207 | 0.00 |
| 0 | 0 |
|
OS process allocation | 1,717 | 0.00 |
| 0 | 0 |
|
OS process: request allocation | 73 | 0.00 |
| 0 | 0 |
|
PL/SQL warning settings | 226 | 0.00 |
| 0 | 0 |
|
SGA IO buffer pool latch | 20,679 | 0.06 | 0.00 | 0 | 20,869 | 0.00 |
SQL memory manager latch | 7 | 0.00 |
| 0 | 1,575 | 0.00 |
SQL memory manager workarea list latch | 439,442 | 0.00 |
| 0 | 0 |
|
Shared B-Tree | 182 | 0.00 |
| 0 | 0 |
|
Undo Hint Latch | 0 |
|
| 0 | 12 | 0.00 |
active checkpoint queue latch | 7,835 | 0.00 |
| 0 | 0 |
|
active service list | 50,936 | 0.00 |
| 0 | 1,621 | 0.00 |
archive control | 5 | 0.00 |
| 0 | 0 |
|
begin backup scn array | 72,901 | 0.00 | 0.00 | 0 | 0 |
|
business card | 32 | 0.00 |
| 0 | 0 |
|
cache buffer handles | 331,153 | 0.02 | 0.00 | 0 | 0 |
|
cache buffers chains | 48,189,073 | 0.00 | 0.00 | 0 | 1,201,379 | 0.00 |
cache buffers lru chain | 891,796 | 0.34 | 0.00 | 0 | 991,605 | 0.23 |
cache table scan latch | 0 |
|
| 0 | 10,309 | 0.01 |
channel handle pool latch | 99 | 0.00 |
| 0 | 0 |
|
channel operations parent latch | 490,324 | 0.01 | 0.00 | 0 | 0 |
|
checkpoint queue latch | 671,856 | 0.01 | 0.00 | 0 | 555,469 | 0.02 |
client/application info | 335 | 0.00 |
| 0 | 0 |
|
commit callback allocation | 12 | 0.00 |
| 0 | 0 |
|
compile environment latch | 173,428 | 0.00 |
| 0 | 0 |
|
dml lock allocation | 243,087 | 0.00 | 0.00 | 0 | 0 |
|
dummy allocation | 134 | 0.00 |
| 0 | 0 |
|
enqueue hash chains | 1,539,499 | 0.01 | 0.03 | 0 | 263 | 0.00 |
enqueues | 855,207 | 0.02 | 0.00 | 0 | 0 |
|
error message lists | 64 | 0.00 |
| 0 | 0 |
|
event group latch | 38 | 0.00 |
| 0 | 0 |
|
file cache latch | 4,694 | 0.00 |
| 0 | 0 |
|
gcs drop object freelist | 8,451 | 0.19 | 0.00 | 0 | 0 |
|
gcs opaque info freelist | 38,584 | 0.00 | 0.00 | 0 | 0 |
|
gcs partitioned table hash | 9,801,867 | 0.00 |
| 0 | 0 |
|
gcs remaster request queue | 31 | 0.00 |
| 0 | 0 |
|
gcs remastering latch | 1,014,198 | 0.00 | 0.33 | 0 | 0 |
|
gcs resource freelist | 1,154,551 | 0.03 | 0.00 | 0 | 771,650 | 0.00 |
gcs resource hash | 3,815,373 | 0.02 | 0.00 | 0 | 2 | 0.00 |
gcs resource scan list | 4 | 0.00 |
| 0 | 0 |
|
gcs shadows freelist | 795,482 | 0.00 | 0.00 | 0 | 779,648 | 0.00 |
ges caches resource lists | 209,655 | 0.02 | 0.00 | 0 | 121,613 | 0.01 |
ges deadlock list | 840 | 0.00 |
| 0 | 0 |
|
ges domain table | 366,702 | 0.00 |
| 0 | 0 |
|
ges enqueue table freelist | 487,875 | 0.00 |
| 0 | 0 |
|
ges group table | 543,887 | 0.00 |
| 0 | 0 |
|
ges process hash list | 59,503 | 0.00 |
| 0 | 0 |
|
ges process parent latch | 908,232 | 0.00 |
| 0 | 1 | 0.00 |
ges process table freelist | 73 | 0.00 |
| 0 | 0 |
|
ges resource hash list | 862,590 | 0.02 | 0.28 | 0 | 72,266 | 0.01 |
ges resource scan list | 534 | 0.00 |
| 0 | 0 |
|
ges resource table freelist | 135,406 | 0.00 | 0.00 | 0 | 0 |
|
ges synchronous data | 160 | 0.63 | 0.00 | 0 | 2,954 | 0.07 |
ges timeout list | 3,256 | 0.00 |
| 0 | 4,478 | 0.00 |
global KZLD latch for mem in SGA | 21 | 0.00 |
| 0 | 0 |
|
hash table column usage latch | 59 | 0.00 |
| 0 | 1,279 | 0.00 |
hash table modification latch | 116 | 0.00 |
| 0 | 0 |
|
job workq parent latch | 0 |
|
| 0 | 14 | 0.00 |
job_queue_processes parameter latch | 86 | 0.00 |
| 0 | 0 |
|
kks stats | 384 | 0.00 |
| 0 | 0 |
|
ksuosstats global area | 329 | 0.00 |
| 0 | 0 |
|
ktm global data | 296 | 0.00 |
| 0 | 0 |
|
kwqbsn:qsga | 182 | 0.00 |
| 0 | 0 |
|
lgwr LWN SCN | 6,547 | 0.18 | 0.00 | 0 | 0 |
|
library cache | 235,060 | 0.00 | 0.00 | 0 | 22 | 0.00 |
library cache load lock | 486 | 0.00 |
| 0 | 0 |
|
library cache lock | 49,284 | 0.00 |
| 0 | 0 |
|
library cache lock allocation | 566 | 0.00 |
| 0 | 0 |
|
library cache pin | 27,863 | 0.00 | 0.00 | 0 | 0 |
|
library cache pin allocation | 204 | 0.00 |
| 0 | 0 |
|
list of block allocation | 10,101 | 0.00 |
| 0 | 0 |
|
loader state object freelist | 108 | 0.00 |
| 0 | 0 |
|
longop free list parent | 6 | 0.00 |
| 0 | 6 | 0.00 |
message pool operations parent latch | 1,424 | 0.00 |
| 0 | 0 |
|
messages | 222,581 | 0.00 | 0.00 | 0 | 0 |
|
mostly latch-free SCN | 6,649 | 1.43 | 0.00 | 0 | 0 |
|
multiblock read objects | 29,230 | 0.03 | 0.00 | 0 | 0 |
|
name-service memory objects | 18,842 | 0.00 |
| 0 | 0 |
|
name-service namespace bucket | 56,712 | 0.00 |
| 0 | 0 |
|
name-service namespace objects | 15 | 0.00 |
| 0 | 0 |
|
name-service pending queue | 6,436 | 0.00 |
| 0 | 0 |
|
name-service request | 44 | 0.00 |
| 0 | 0 |
|
name-service request queue | 57,312 | 0.00 |
| 0 | 0 |
|
ncodef allocation latch | 77 | 0.00 |
| 0 | 0 |
|
object queue header heap | 37,721 | 0.00 |
| 0 | 7,457 | 0.00 |
object queue header operation | 2,706,992 | 0.06 | 0.00 | 0 | 0 |
|
object stats modification | 22 | 0.00 |
| 0 | 0 |
|
parallel query alloc buffer | 939 | 0.00 |
| 0 | 0 |
|
parallel query stats | 72 | 0.00 |
| 0 | 0 |
|
parallel txn reco latch | 630 | 0.00 |
| 0 | 0 |
|
parameter list | 193 | 0.00 |
| 0 | 0 |
|
parameter table allocation management | 68 | 0.00 |
| 0 | 0 |
|
post/wait queue | 4,205 | 0.00 |
| 0 | 2,712 | 0.00 |
process allocation | 46,895 | 0.00 |
| 0 | 38 | 0.00 |
process group creation | 73 | 0.00 |
| 0 | 0 |
|
process queue | 175 | 0.00 |
| 0 | 0 |
|
process queue reference | 2,621 | 0.00 |
| 0 | 240 | 62.50 |
qmn task queue latch | 668 | 0.15 | 1.00 | 0 | 0 |
|
query server freelists | 159 | 0.00 |
| 0 | 0 |
|
query server process | 8 | 0.00 |
| 0 | 7 | 0.00 |
queued dump request | 23,628 | 0.00 |
| 0 | 0 |
|
redo allocation | 21,206 | 0.57 | 0.00 | 0 | 4,706,826 | 0.02 |
redo copy | 0 |
|
| 0 | 4,707,106 | 0.01 |
redo writing | 29,944 | 0.01 | 0.00 | 0 | 0 |
|
resmgr group change latch | 69 | 0.00 |
| 0 | 0 |
|
resmgr:actses active list | 137 | 0.00 |
| 0 | 0 |
|
resmgr:actses change group | 52 | 0.00 |
| 0 | 0 |
|
resmgr:free threads list | 130 | 0.00 |
| 0 | 0 |
|
resmgr:schema config | 7 | 0.00 |
| 0 | 0 |
|
row cache objects | 1,644,149 | 0.00 | 0.00 | 0 | 321 | 0.00 |
rules engine rule set statistics | 500 | 0.00 |
| 0 | 0 |
|
sequence cache | 360 | 0.00 |
| 0 | 0 |
|
session allocation | 535,514 | 0.00 | 0.00 | 0 | 0 |
|
session idle bit | 3,262,141 | 0.00 | 0.00 | 0 | 0 |
|
session state list latch | 166 | 0.00 |
| 0 | 0 |
|
session switching | 77 | 0.00 |
| 0 | 0 |
|
session timer | 1,620 | 0.00 |
| 0 | 0 |
|
shared pool | 60,359 | 0.00 | 0.00 | 0 | 0 |
|
shared pool sim alloc | 13 | 0.00 |
| 0 | 0 |
|
shared pool simulator | 4,246 | 0.00 |
| 0 | 0 |
|
simulator hash latch | 1,862,803 | 0.00 |
| 0 | 0 |
|
simulator lru latch | 1,719,480 | 0.01 | 0.00 | 0 | 46,053 | 0.00 |
slave class | 2 | 0.00 |
| 0 | 0 |
|
slave class create | 8 | 12.50 | 1.00 | 0 | 0 |
|
sort extent pool | 1,284 | 0.00 |
| 0 | 0 |
|
state object free list | 4 | 0.00 |
| 0 | 0 |
|
statistics aggregation | 280 | 0.00 |
| 0 | 0 |
|
temp lob duration state obj allocation | 2 | 0.00 |
| 0 | 0 |
|
threshold alerts latch | 202 | 0.00 |
| 0 | 0 |
|
transaction allocation | 211 | 0.00 |
| 0 | 0 |
|
transaction branch allocation | 77 | 0.00 |
| 0 | 0 |
|
undo global data | 779,759 | 0.07 | 0.00 | 0 | 0 |
|
user lock | 102 | 0.00 |
| 0 | 0 |
|
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ordered by misses desc
Latch Name | Get Requests | Misses | Sleeps | Spin Gets | Sleep1 | Sleep2 | Sleep3 |
cache buffers lru chain | 891,796 | 3,061 | 1 | 3,060 | 0 | 0 | 0 |
object queue header operation | 2,706,992 | 1,755 | 3 | 1,752 | 0 | 0 | 0 |
KCL gc element parent latch | 2,803,392 | 1,186 | 11 | 1,176 | 0 | 0 | 0 |
cache buffers chains | 48,189,073 | 496 | 1 | 495 | 0 | 0 | 0 |
ges resource hash list | 862,590 | 160 | 44 | 116 | 0 | 0 | 0 |
enqueue hash chains | 1,539,499 | 79 | 2 | 78 | 0 | 0 | 0 |
gcs remastering latch | 1,014,198 | 3 | 1 | 2 | 0 | 0 | 0 |
qmn task queue latch | 668 | 1 | 1 | 0 | 0 | 0 | 0 |
slave class create | 8 | 1 | 1 | 0 | 0 | 0 | 0 |
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only latches with sleeps are shown
ordered by name, sleeps desc
Latch Name | Where | NoWait Misses | Sleeps | Waiter Sleeps |
KCL gc element parent latch | kclrwrite | 0 | 8 | 0 |
KCL gc element parent latch | kclnfndnewm | 0 | 4 | 6 |
KCL gc element parent latch | KCLUNLNK | 0 | 1 | 1 |
KCL gc element parent latch | kclbla | 0 | 1 | 0 |
KCL gc element parent latch | kclulb | 0 | 1 | 1 |
KCL gc element parent latch | kclzcl | 0 | 1 | 0 |
cache buffers chains | kcbnew: new latch again | 0 | 2 | 0 |
cache buffers chains | kclwrt | 0 | 1 | 0 |
cache buffers lru chain | kcbzgws | 0 | 1 | 0 |
enqueue hash chains | ksqcmi: if lk mode not requested | 0 | 2 | 0 |
event range base latch | No latch | 0 | 1 | 1 |
gcs remastering latch | 69 | 0 | 1 | 0 |
ges resource hash list | kjlmfnd: search for lockp by rename and inst id | 0 | 23 | 0 |
ges resource hash list | kjakcai: search for resp by resname | 0 | 13 | 0 |
ges resource hash list | kjrmas1: lookup master node | 0 | 5 | 0 |
ges resource hash list | kjlrlr: remove lock from resource queue | 0 | 2 | 33 |
ges resource hash list | kjcvscn: remove from scan queue | 0 | 1 | 0 |
object queue header operation | kcbo_switch_q_bg | 0 | 3 | 0 |
object queue header operation | kcbo_switch_mq_bg | 0 | 2 | 4 |
object queue header operation | kcbw_unlink_q | 0 | 2 | 0 |
object queue header operation | kcbw_link_q | 0 | 1 | 0 |
slave class create | ksvcreate | 0 | 1 | 0 |
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No data exists for this section of the report.
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No data exists for this section of the report.
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Latch Statistics
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Segments by Logical Reads
Segments by Physical Reads
Segments by Row Lock Waits
Segments by ITL Waits
Segments by Buffer Busy Waits
Segments by Global Cache Buffer Busy
Segments by CR Blocks Received
Segments by Current Blocks Received
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DBA_HIST_SEG_STAT
desc DBA_HIST_SEG_STAT
v$sesstat
v$statname
Total Logical Reads: 16,648,792
Captured Segments account for 85.2% of Total
Owner | Tablespace Name | Object Name | Subobject Name | Obj. Type | Logical Reads | %Total |
ICCI01 | ICCIDAT01 | ICCICCS_PK |
| INDEX | 1,544,848 | 9.28 |
ICCI01 | ICCIDAT01 | CUSCAD_TMP |
| TABLE | 1,349,536 | 8.11 |
ICCI01 | ICCIDAT01 | ICCIFNSACT_PK |
| INDEX | 1,268,400 | 7.62 |
ICCI01 | ICCIDAT01 | IND_OLDNEWACT |
| INDEX | 1,071,072 | 6.43 |
ICCI01 | ICCIDAT01 | CUID_PK |
| INDEX | 935,584 | 5.62 |
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Total Physical Reads: 322,678
Captured Segments account for 64.2% of Total
Owner | Tablespace Name | Object Name | Subobject Name | Obj. Type | Physical Reads | %Total |
ICCI01 | ICCIDAT01 | CUID_TMP |
| TABLE | 116,417 | 36.08 |
ICCI01 | ICCIDAT01 | CUMI_TMP |
| TABLE | 44,086 | 13.66 |
ICCI01 | ICCIDAT01 | CUSM_TMP |
| TABLE | 26,078 | 8.08 |
ICCI01 | ICCIDAT01 | CUSVAA_TMP_PK |
| INDEX | 19,554 | 6.06 |
ICCI01 | ICCIDAT01 | CUID |
| TABLE | 259 | 0.08 |
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当一个进程予在正被其它进程锁住的数据行上获得排它锁时发生这种等待。这种等待经常是由于在一个有主键索引的表上做大量INSERT操作。
No data exists for this section of the report.
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Segments by ITL Waits
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% of Capture shows % of GC Buffer Busy for each top segment compared
with GC Buffer Busy for all segments captured by the Snapshot
Owner | Tablespace Name | Object Name | Subobject Name | Obj. Type | GC Buffer Busy | % of Capture |
SYS | SYSTEM | TSQ$ |
| TABLE | 2 | 100.00 |
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Total CR Blocks Received: 4,142
Captured Segments account for 95.6% of Total
Owner | Tablespace Name | Object Name | Subobject Name | Obj. Type | CR Blocks Received | %Total |
SYS | SYSTEM | USER$ |
| TABLE | 1,001 | 24.17 |
SYS | SYSTEM | TSQ$ |
| TABLE | 722 | 17.43 |
SYS | SYSTEM | SEG$ |
| TABLE | 446 | 10.77 |
SYS | SYSTEM | OBJ$ |
| TABLE | 264 | 6.37 |
SYS | SYSTEM | I_OBJ2 |
| INDEX | 174 | 4.20 |
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Total Current Blocks Received: 15,502
Captured Segments account for 84.8% of Total
Owner | Tablespace Name | Object Name | Subobject Name | Obj. Type | Current Blocks Received | %Total |
ICCI01 | ICCIDAT01 | CUSM_TMP |
| TABLE | 5,764 | 37.18 |
ICCI01 | ICCIDAT01 | CUMI_TMP |
| TABLE | 2,794 | 18.02 |
ICCI01 | ICCIDAT01 | CUID_TMP |
| TABLE | 2,585 | 16.68 |
SYS | SYSTEM | SEG$ |
| TABLE | 361 | 2.33 |
SYS | SYSTEM | TSQ$ |
| TABLE | 361 | 2.33 |
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Dictionary Cache Stats
Dictionary Cache Stats (RAC)
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/* 库缓存详细信息,。
Get Requests:get表示一种类型的锁,语法分析锁。这种类型的锁在引用了一个对象的那条SQL语句的语法分析阶段被设置在该对象上。每当一条语句被语法分析一次时,Get Requests的值就增加1。
pin requests:pin也表示一种类型的锁,是在执行发生的加锁。每当一条语句执行一次,pin requests的值就增加1。
reloads:reloads列显示一条已执行过的语句因Library Cache使该语句的已语法分析版本过期或作废而需要被重新语法分析的次数。
invalidations:失效发生在一条已告诉缓存的SQL语句即使已经在library cache中,但已被标记为无效并迎词而被迫重新做语法分析的时候。每当已告诉缓存的语句所引用的对象以某种方式被修改时,这些语句就被标记为无效。
pct miss应该不高于1%。
Reloads /pin requests <1%,否则应该考虑增大SHARED_POOL_SIZE。
该部分信息通过v$librarycache视图统计得到:
select namespace,gethitratio,pinhitratio,reloads,invalidations
from v$librarycache
where namespace in ('SQL AREA','TABLE/PROCEDURE','BODY','TRIGGER', 'INDEX');
"Pct Misses" should be very low (< 2% in most cases)
"Final Usage" is the number of cache entries being used
Cache | Get Requests | Pct Miss | Scan Reqs | Pct Miss | Mod Reqs | Final Usage |
dc_awr_control | 86 | 0.00 | 0 |
| 4 | 1 |
dc_constraints | 59 | 91.53 | 0 |
| 20 | 1,350 |
dc_files | 23 | 0.00 | 0 |
| 0 | 23 |
dc_global_oids | 406 | 0.00 | 0 |
| 0 | 35 |
dc_histogram_data | 673 | 0.15 | 0 |
| 0 | 1,555 |
dc_histogram_defs | 472 | 24.36 | 0 |
| 0 | 4,296 |
dc_object_grants | 58 | 0.00 | 0 |
| 0 | 154 |
dc_object_ids | 1,974 | 6.13 | 0 |
| 0 | 1,199 |
dc_objects | 955 | 19.58 | 0 |
| 56 | 2,064 |
dc_profiles | 30 | 0.00 | 0 |
| 0 | 1 |
dc_rollback_segments | 3,358 | 0.00 | 0 |
| 0 | 37 |
dc_segments | 2,770 | 2.56 | 0 |
| 1,579 | 1,312 |
dc_sequences | 9 | 33.33 | 0 |
| 9 | 5 |
dc_table_scns | 6 | 100.00 | 0 |
| 0 | 0 |
dc_tablespace_quotas | 1,558 | 28.50 | 0 |
| 1,554 | 3 |
dc_tablespaces | 346,651 | 0.00 | 0 |
| 0 | 7 |
dc_usernames | 434 | 0.00 | 0 |
| 0 | 14 |
dc_users | 175,585 | 0.00 | 0 |
| 0 | 43 |
outstanding_alerts | 57 | 71.93 | 0 |
| 0 | 1 |
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Dictionary Cache Statistics
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Cache | GES Requests | GES Conflicts | GES Releases |
dc_awr_control | 8 | 0 | 0 |
dc_constraints | 88 | 22 | 0 |
dc_histogram_defs | 115 | 0 | 0 |
dc_object_ids | 143 | 101 | 0 |
dc_objects | 253 | 111 | 0 |
dc_segments | 3,228 | 49 | 0 |
dc_sequences | 17 | 3 | 0 |
dc_table_scns | 6 | 0 | 0 |
dc_tablespace_quotas | 3,093 | 441 | 0 |
dc_users | 8 | 1 | 0 |
outstanding_alerts | 113 | 41 | 0 |
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Dictionary Cache Statistics
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Library Cache Activity
Library Cache Activity (RAC)
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"Pct Misses" should be very low
Namespace | Get Requests | Pct Miss | Pin Requests | Pct Miss | Reloads | Invali- dations |
BODY | 105 | 0.00 | 247 | 0.00 | 0 | 0 |
CLUSTER | 3 | 0.00 | 4 | 0.00 | 0 | 0 |
INDEX | 13 | 46.15 | 26 | 42.31 | 5 | 0 |
SQL AREA | 56 | 100.00 | 1,857,002 | 0.02 | 32 | 12 |
TABLE/PROCEDURE | 179 | 35.75 | 3,477 | 8.02 | 63 | 0 |
TRIGGER | 323 | 0.00 | 386 | 0.00 | 0 | 0 |
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Library Cache Statistics
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Namespace | GES Lock Requests | GES Pin Requests | GES Pin Releases | GES Inval Requests | GES Invali- dations |
BODY | 5 | 0 | 0 | 0 | 0 |
CLUSTER | 4 | 0 | 0 | 0 | 0 |
INDEX | 26 | 22 | 6 | 17 | 0 |
TABLE/PROCEDURE | 1,949 | 285 | 63 | 244 | 0 |
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Library Cache Statistics
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Process Memory Summary
SGA Memory Summary
SGA breakdown difference
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B: Begin snap E: End snap
All rows below contain absolute values (i.e. not diffed over the interval)
Max Alloc is Maximum PGA Allocation size at snapshot time
Hist Max Alloc is the Historical Max Allocation for still-connected processes
ordered by Begin/End snapshot, Alloc (MB) desc
| Category | Alloc (MB) | Used (MB) | Avg Alloc (MB) | Std Dev Alloc (MB) | Max Alloc (MB) | Hist Max Alloc (MB) | Num Proc | Num Alloc |
B | Other | 136.42 |
| 5.25 | 8.55 | 24 | 27 | 26 | 26 |
| Freeable | 13.50 | 0.00 | 1.50 | 1.11 | 3 |
| 9 | 9 |
| SQL | 0.33 | 0.16 | 0.03 | 0.03 | 0 | 2 | 12 | 10 |
| PL/SQL | 0.12 | 0.06 | 0.01 | 0.01 | 0 | 0 | 24 | 24 |
E | Other | 138.65 |
| 4.78 | 8.20 | 24 | 27 | 29 | 29 |
| Freeable | 14.94 | 0.00 | 1.36 | 1.04 | 3 |
| 11 | 11 |
| SQL | 0.39 | 0.19 | 0.03 | 0.03 | 0 | 2 | 15 | 12 |
| PL/SQL | 0.18 | 0.11 | 0.01 | 0.01 | 0 | 0 | 27 | 26 |
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Memory Statistics
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这部分是关于SGA内存分配的一个描述,我们可以通过show sga等命令也可以查看到这里的内容。
Fixed Size:
oracle 的不同平台和不同版本下可能不一样,但对于确定环境是一个固定的值,里面存储了SGA 各部分组件的信息,可以看作引导建立SGA的区域。
Variable Size:
包含了shared_pool_size、java_pool_size、large_pool_size 等内存设置。
Database Buffers:
指数据缓冲区,在8i 中包含db_block_buffer*db_block_size、buffer_pool_keep、buffer_pool_recycle 三部分内存。在9i 中包含db_cache_size、db_keep_cache_size、db_recycle_cache_size、 db_nk_cache_size。
Redo Buffers:
指日志缓冲区,log_buffer。对于logbuffer,我们会发现在v$parameter、v$sgastat、v$sga的值不一样。v$parameter是我们可以自己设定的值,也可以设定为0,这时候,oracle降会以默认的最小值来设置v$sgastat的值,同时v$sga也是最小的值。v$sgastat的值是基于参数log_buffer的设定值,再根据一定的计算公式得到的一个值。v$sga的值,则是根据v$sgastat的值,然后选择再加上8k-11k的一个值,得到min(n*4k)的一个值。就是说得到的结果是4k的整数倍,也就是说v$sga是以4k的单位递增的。
SGA regions | Begin Size (Bytes) | End Size (Bytes) (if different) |
Database Buffers | 3,506,438,144 |
|
Fixed Size | 2,078,368 |
|
Redo Buffers | 14,696,448 |
|
Variable Size | 771,754,336 |
|
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Memory Statistics
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ordered by Pool, Name
N/A value for Begin MB or End MB indicates the size of that Pool/Name was insignificant, or zero in that snapshot
Pool | Name | Begin MB | End MB | % Diff |
java | free memory | 16.00 | 16.00 | 0.00 |
large | PX msg pool | 1.03 | 1.03 | 0.00 |
large | free memory | 14.97 | 14.97 | 0.00 |
shared | ASH buffers | 15.50 | 15.50 | 0.00 |
shared | CCursor | 8.58 | 8.85 | 3.09 |
shared | KQR L PO | 8.75 | 8.80 | 0.55 |
shared | db_block_hash_buckets | 22.50 | 22.50 | 0.00 |
shared | free memory | 371.80 | 369.61 | -0.59 |
shared | gcs resources | 66.11 | 66.11 | 0.00 |
shared | gcs shadows | 41.65 | 41.65 | 0.00 |
shared | ges big msg buffers | 13.75 | 13.75 | 0.00 |
shared | ges enqueues | 7.44 | 7.56 | 1.63 |
shared | ges reserved msg buffers | 7.86 | 7.86 | 0.00 |
shared | library cache | 10.78 | 10.93 | 1.41 |
shared | row cache | 7.16 | 7.16 | 0.00 |
shared | sql area | 27.49 | 28.50 | 3.67 |
| buffer_cache | 3,344.00 | 3,344.00 | 0.00 |
| fixed_sga | 1.98 | 1.98 | 0.00 |
| log_buffer | 14.02 | 14.02 | 0.00 |
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Memory Statistics
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Streams CPU/IO Usage
Streams Capture
Streams Apply
Buffered Queues
Buffered Subscribers
Rule Set
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No data exists for this section of the report.
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Streams Statistics
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No data exists for this section of the report.
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Streams Statistics
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No data exists for this section of the report.
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Streams Statistics
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No data exists for this section of the report.
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Streams Statistics
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No data exists for this section of the report.
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Streams Statistics
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No data exists for this section of the report.
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Streams Statistics
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only rows with Current or Maximum Utilization > 80% of Limit are shown
ordered by resource name
Resource Name | Current Utilization | Maximum Utilization | Initial Allocation | Limit |
gcs_resources | 349,392 | 446,903 | 450063 | 450063 |
gcs_shadows | 400,300 | 447,369 | 450063 | 450063 |
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Parameter Name | Begin value | End value (if different) |
audit_file_dest | /oracle/app/oracle/admin/ICCI/adump |
|
background_dump_dest | /oracle/app/oracle/admin/ICCI/bdump |
|
cluster_database | TRUE |
|
cluster_database_instances | 2 |
|
compatible | 10.2.0.3.0 |
|
control_files | /dev/rora_CTL01, /dev/rora_CTL02, /dev/rora_CTL03 |
|
core_dump_dest | /oracle/app/oracle/admin/ICCI/cdump |
|
db_block_size | 8192 |
|
db_domain |
|
|
db_file_multiblock_read_count | 16 |
|
db_name | ICCI |
|
dispatchers | (PROTOCOL=TCP) (SERVICE=ICCIXDB) |
|
instance_number | 1 |
|
job_queue_processes | 10 |
|
open_cursors | 800 |
|
pga_aggregate_target | 1073741824 |
|
processes | 500 |
|
remote_listener | LISTENERS_ICCI |
|
remote_login_passwordfile | EXCLUSIVE |
|
sga_max_size | 4294967296 |
|
sga_target | 4294967296 |
|
sort_area_size | 196608 |
|
spfile | /dev/rora_SPFILE |
|
thread | 1 |
|
undo_management | AUTO |
|
undo_retention | 900 |
|
undo_tablespace | UNDOTBS1 |
|
user_dump_dest | /oracle/app/oracle/admin/ICCI/udump |
|
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Global Enqueue Statistics
Global CR Served Stats
Global CURRENT Served Stats
Global Cache Transfer Stats
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Statistic | Total | per Second | per Trans |
acks for commit broadcast(actual) | 18,537 | 3.92 | 3.31 |
acks for commit broadcast(logical) | 21,016 | 4.45 | 3.75 |
broadcast msgs on commit(actual) | 5,193 | 1.10 | 0.93 |
broadcast msgs on commit(logical) | 5,491 | 1.16 | 0.98 |
broadcast msgs on commit(wasted) | 450 | 0.10 | 0.08 |
dynamically allocated gcs resources | 0 | 0.00 | 0.00 |
dynamically allocated gcs shadows | 0 | 0.00 | 0.00 |
false posts waiting for scn acks | 0 | 0.00 | 0.00 |
flow control messages received | 0 | 0.00 | 0.00 |
flow control messages sent | 2 | 0.00 | 0.00 |
gcs assume cvt | 0 | 0.00 | 0.00 |
gcs assume no cvt | 9,675 | 2.05 | 1.73 |
gcs ast xid | 1 | 0.00 | 0.00 |
gcs blocked converts | 7,099 | 1.50 | 1.27 |
gcs blocked cr converts | 8,442 | 1.79 | 1.51 |
gcs compatible basts | 45 | 0.01 | 0.01 |
gcs compatible cr basts (global) | 273 | 0.06 | 0.05 |
gcs compatible cr basts (local) | 12,593 | 2.66 | 2.25 |
gcs cr basts to PIs | 0 | 0.00 | 0.00 |
gcs cr serve without current lock | 0 | 0.00 | 0.00 |
gcs dbwr flush pi msgs | 223 | 0.05 | 0.04 |
gcs dbwr write request msgs | 223 | 0.05 | 0.04 |
gcs error msgs | 0 | 0.00 | 0.00 |
gcs forward cr to pinged instance | 0 | 0.00 | 0.00 |
gcs immediate (compatible) converts | 2,998 | 0.63 | 0.54 |
gcs immediate (null) converts | 170,925 | 36.16 | 30.53 |
gcs immediate cr (compatible) converts | 0 | 0.00 | 0.00 |
gcs immediate cr (null) converts | 722,748 | 152.88 | 129.11 |
gcs indirect ast | 306,817 | 64.90 | 54.81 |
gcs lms flush pi msgs | 0 | 0.00 | 0.00 |
gcs lms write request msgs | 189 | 0.04 | 0.03 |
gcs msgs process time(ms) | 16,164 | 3.42 | 2.89 |
gcs msgs received | 1,792,132 | 379.09 | 320.14 |
gcs out-of-order msgs | 0 | 0.00 | 0.00 |
gcs pings refused | 0 | 0.00 | 0.00 |
gcs pkey conflicts retry | 0 | 0.00 | 0.00 |
gcs queued converts | 2 | 0.00 | 0.00 |
gcs recovery claim msgs | 0 | 0.00 | 0.00 |
gcs refuse xid | 0 | 0.00 | 0.00 |
gcs regular cr | 0 | 0.00 | 0.00 |
gcs retry convert request | 0 | 0.00 | 0.00 |
gcs side channel msgs actual | 437 | 0.09 | 0.08 |
gcs side channel msgs logical | 21,086 | 4.46 | 3.77 |
gcs stale cr | 3,300 | 0.70 | 0.59 |
gcs undo cr | 5 | 0.00 | 0.00 |
gcs write notification msgs | 23 | 0.00 | 0.00 |
gcs writes refused | 3 | 0.00 | 0.00 |
ges msgs process time(ms) | 1,289 | 0.27 | 0.23 |
ges msgs received | 138,891 | 29.38 | 24.81 |
global posts dropped | 0 | 0.00 | 0.00 |
global posts queue time | 0 | 0.00 | 0.00 |
global posts queued | 0 | 0.00 | 0.00 |
global posts requested | 0 | 0.00 | 0.00 |
global posts sent | 0 | 0.00 | 0.00 |
implicit batch messages received | 81,181 | 17.17 | 14.50 |
implicit batch messages sent | 19,561 | 4.14 | 3.49 |
lmd msg send time(ms) | 0 | 0.00 | 0.00 |
lms(s) msg send time(ms) | 0 | 0.00 | 0.00 |
messages flow controlled | 15,306 | 3.24 | 2.73 |
messages queue sent actual | 108,411 | 22.93 | 19.37 |
messages queue sent logical | 222,518 | 47.07 | 39.75 |
messages received actual | 474,202 | 100.31 | 84.71 |
messages received logical | 1,931,144 | 408.50 | 344.97 |
messages sent directly | 25,742 | 5.45 | 4.60 |
messages sent indirectly | 137,725 | 29.13 | 24.60 |
messages sent not implicit batched | 88,859 | 18.80 | 15.87 |
messages sent pbatched | 1,050,224 | 222.16 | 187.61 |
msgs causing lmd to send msgs | 61,682 | 13.05 | 11.02 |
msgs causing lms(s) to send msgs | 85,978 | 18.19 | 15.36 |
msgs received queue time (ms) | 911,013 | 192.71 | 162.74 |
msgs received queued | 1,931,121 | 408.50 | 344.97 |
msgs sent queue time (ms) | 5,651 | 1.20 | 1.01 |
msgs sent queue time on ksxp (ms) | 66,767 | 14.12 | 11.93 |
msgs sent queued | 215,124 | 45.51 | 38.43 |
msgs sent queued on ksxp | 243,729 | 51.56 | 43.54 |
process batch messages received | 120,003 | 25.38 | 21.44 |
process batch messages sent | 181,019 | 38.29 | 32.34 |
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Statistic | Total |
CR Block Requests | 10,422 |
CURRENT Block Requests | 251 |
Data Block Requests | 10,422 |
Undo Block Requests | 2 |
TX Block Requests | 20 |
Current Results | 10,664 |
Private results | 4 |
Zero Results | 5 |
Disk Read Results | 0 |
Fail Results | 0 |
Fairness Down Converts | 1,474 |
Fairness Clears | 0 |
Free GC Elements | 0 |
Flushes | 370 |
Flushes Queued | 0 |
Flush Queue Full | 0 |
Flush Max Time (us) | 0 |
Light Works | 2 |
Errors | 0 |
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Pins = CURRENT Block Pin Operations
Flushes = Redo Flush before CURRENT Block Served Operations
Writes = CURRENT Block Fusion Write Operations
Statistic | Total | % <1ms | % <10ms | % <100ms | % <1s | % <10s |
Pins | 17,534 | 99.96 | 0.01 | 0.03 | 0.00 | 0.00 |
Flushes | 77 | 48.05 | 46.75 | 5.19 | 0.00 | 0.00 |
Writes | 255 | 5.49 | 53.73 | 40.00 | 0.78 | 0.00 |
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Immediate (Immed) - Block Transfer NOT impacted by Remote Processing Delays
Busy (Busy) - Block Transfer impacted by Remote Contention
Congested (Congst) - Block Transfer impacted by Remote System Load
ordered by CR + Current Blocks Received desc
|
| CR | Current | ||||||
Inst No | Block Class | Blocks Received | % Immed | % Busy | % Congst | Blocks Received | % Immed | % Busy | % Congst |
2 | data block | 3,945 | 87.20 | 12.80 | 0.00 | 13,324 | 99.71 | 0.26 | 0.04 |
2 | Others | 191 | 100.00 | 0.00 | 0.00 | 2,190 | 96.48 | 3.52 | 0.00 |
2 | undo header | 11 | 100.00 | 0.00 | 0.00 | 2 | 100.00 | 0.00 | 0.00 |
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End of Report
[FF1]OLAP:联机分析处理
OLTP:联机事务处理
OLAP是主要应用数据仓库系统
OLTP是一般的项目开发用到的基本的、日常的事务处理;比如数据库记录的增、删、改、查。
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