SQLServer运⾏状况监控SQL语句
Microsoft SQL Server 2005 提供了⼀些⼯具来监控数据库。⽅法之⼀是动态管理视图。动态管理视图 (DMV) 和动态管理函数 (DMF) 返回的服务器状态信息可⽤于监控服务器实例的运⾏状况、诊断问题和优化性能。常规服务器动态管理对象包括:
dm_db_*:数据库和数据库对象
dm_exec_*:执⾏⽤户代码和关联的连接dm_os_*:内存、锁定和时间安排dm_tran_*:事务和隔离
dm_io_*:⽹络和磁盘的输⼊/输出
此部分介绍为监控 SQL Server 运⾏状况⽽针对这些动态管理视图和函数运⾏的⼀些常⽤查询。
⽰例查询您可以运⾏以下查询来获取所有 DMV 和 DMF 名称:
SELECT * FROM sys.system_objectsWHERE name LIKE 'dm_%'ORDER BY name
监控 CPU 瓶颈CPU 瓶颈通常由以下原因引起:查询计划并⾮最优、配置不当、设计因素不良或硬件资源不⾜。下⾯的常⽤查询可帮助您确定导致 CPU 瓶颈的原因。下⾯的查询使您能够深⼊了解当前缓存的哪些批处理或过程占⽤了⼤部分 CPU 资源。
SELECT TOP 50
SUM(qs.total_worker_time) AS total_cpu_time,
SUM(qs.execution_count) AS total_execution_count, COUNT(*) AS number_of_statements, qs.sql_handle
FROM sys.dm_exec_query_stats AS qsGROUP BY qs.sql_handle
ORDER BY SUM(qs.total_worker_time) DESC
下⾯的查询显⽰缓存计划所占⽤的 CPU 总使⽤率(带 SQL ⽂本)。
SELECT
total_cpu_time,
total_execution_count, number_of_statements, s2.text
--(SELECT SUBSTRING(s2.text, statement_start_offset / 2, ((CASE WHEN statement_end_offset = -1 THEN (LEN(CONVERT(NVARCHAR(MAX), s2.text)) * 2) ELSE statement_end_offset END) - statement_start_offset) / 2) ) AS query_teFROM
(SELECT TOP 50
SUM(qs.total_worker_time) AS total_cpu_time,
SUM(qs.execution_count) AS total_execution_count, COUNT(*) AS number_of_statements, qs.sql_handle --,
--MIN(statement_start_offset) AS statement_start_offset, --MAX(statement_end_offset) AS statement_end_offset FROM
sys.dm_exec_query_stats AS qs GROUP BY qs.sql_handle
ORDER BY SUM(qs.total_worker_time) DESC) AS stats
CROSS APPLY sys.dm_exec_sql_text(stats.sql_handle) AS s2
下⾯的查询显⽰ CPU 平均占⽤率最⾼的前 50 个 SQL 语句。
SELECT TOP 50
total_worker_time/execution_count AS [Avg CPU Time],(SELECT SUBSTRING(text,statement_start_offset/2,
(CASE WHEN statement_end_offset = -1 then LEN(CONVERT(nvarchar(max), text)) * 2 ELSE statement_end_offset end -statement_start_offset)/2) FROM sys.dm_exec_sql_text(sql_handle)) AS query_text, *FROM sys.dm_exec_query_stats ORDER BY [Avg CPU Time] DESC
下⾯显⽰⽤于找出过多编译/重新编译的 DMV 查询。
select * from sys.dm_exec_query_optimizer_info
where counter = 'optimizations' or counter = 'elapsed time'
下⾯的⽰例查询显⽰已重新编译的前 25 个存储过程。plan_generation_num 指⽰该查询已重新编译的次数。
select top 25 sql_text.text, sql_handle,
plan_generation_num, execution_count,
dbid, objectid
from sys.dm_exec_query_stats a
cross apply sys.dm_exec_sql_text(sql_handle) as sql_textwhere plan_generation_num > 1order by plan_generation_num desc
效率较低的查询计划可能增⼤ CPU 占⽤率。下⾯的查询显⽰哪个查询占⽤了最多的 CPU 累计使⽤率。
SELECT
highest_cpu_queries.plan_handle,
highest_cpu_queries.total_worker_time, q.dbid, q.objectid, q.number, q.encrypted, q.[text]from
(select top 50
qs.plan_handle, qs.total_worker_time from
sys.dm_exec_query_stats qs
order by qs.total_worker_time desc) as highest_cpu_queries cross apply sys.dm_exec_sql_text(plan_handle) as qorder by highest_cpu_queries.total_worker_time desc
下⾯的查询显⽰⼀些可能占⽤⼤量 CPU 使⽤率的运算符(例如 ‘%Hash Match%’、‘%Sort%’)以找出可疑对象。
select *from
sys.dm_exec_cached_plans
cross apply sys.dm_exec_query_plan(plan_handle)where
cast(query_plan as nvarchar(max)) like '%Sort%'
or cast(query_plan as nvarchar(max)) like '%Hash Match%'
如果已检测到效率低下并导致 CPU 占⽤率较⾼的查询计划,请对该查询中涉及的表运⾏ UPDATE STATISTICS 以查看该问题是否仍然存在。然后,收集相关数据并将此问题报告给 PerformancePoint 规划⽀持⼈员。
如果您的系统存在过多的编译和重新编译,可能会导致系统出现与 CPU 相关的性能问题。您可以运⾏下⾯的 DMV 查询来找出过多的编译/重新编译。
select * from sys.dm_exec_query_optimizer_infowhere
counter = 'optimizations'or counter = 'elapsed time'
下⾯的⽰例查询显⽰已重新编译的前 25 个存储过程。plan_generation_num 指⽰该查询已重新编译的次数。
select top 25sql_text.text,sql_handle,
plan_generation_num,execution_count,dbid,objectid
from sys.dm_exec_query_stats a
cross apply sys.dm_exec_sql_text(sql_handle) as sql_textwhere plan_generation_num > 1order by plan_generation_num desc
如果已检测到过多的编译或重新编译,请尽可能多地收集相关数据并将其报告给规划⽀持⼈员
内存瓶颈开始内存压⼒检测和调查之前,请确保已启⽤ SQL Server 中的⾼级选项。请先对 master 数据库运⾏以下查询以启⽤此选项。
sp_configure 'show advanced options'go
sp_configure 'show advanced options', 1go
reconfigurego
⾸先运⾏以下查询以检查内存相关配置选项。
sp_configure 'awe_enabled'
go
sp_configure 'min server memory'go
sp_configure 'max server memory'go
sp_configure 'min memory per query'go
sp_configure 'query wait'go
运⾏下⾯的 DMV 查询以查看 CPU、计划程序内存和缓冲池信息。
select cpu_count,
hyperthread_ratio,scheduler_count,
physical_memory_in_bytes / 1024 / 1024 as physical_memory_mb,virtual_memory_in_bytes / 1024 / 1024 as virtual_memory_mb,bpool_committed * 8 / 1024 as bpool_committed_mb,bpool_commit_target * 8 / 1024 as bpool_target_mb,bpool_visible * 8 / 1024 as bpool_visible_mbfrom sys.dm_os_sys_info
I/O 瓶颈
检查闩锁等待统计信息以确定 I/O 瓶颈。运⾏下⾯的 DMV 查询以查找 I/O 闩锁等待统计信息。
select wait_type, waiting_tasks_count, wait_time_ms, signal_wait_time_ms, wait_time_ms / waiting_tasks_countfrom sys.dm_os_wait_stats
where wait_type like 'PAGEIOLATCH%' and waiting_tasks_count > 0order by wait_type
如果 waiting_task_counts 和 wait_time_ms 与正常情况相⽐有显著变化,则可以确定存在 I/O 问题。获取 SQL Server 平稳运⾏时性能计数器和主要 DMV 查询输出的基线⾮常重要。
这些 wait_types 可以指⽰您的 I/O ⼦系统是否遇到瓶颈。
使⽤以下 DMV 查询来查找当前挂起的 I/O 请求。请定期执⾏此查询以检查 I/O ⼦系统的运⾏状况,并隔离 I/O 瓶颈中涉及的物理磁盘。
select
database_id, file_id, io_stall,
io_pending_ms_ticks, scheduler_address
from sys.dm_io_virtual_file_stats(NULL, NULL)t1, sys.dm_io_pending_io_requests as t2where t1.file_handle = t2.io_handle
在正常情况下,该查询通常不返回任何内容。如果此查询返回⼀些⾏,则需要进⼀步调查。您还可以执⾏下⾯的 DMV 查询以查找 I/O 相关查询。
select top 5 (total_logical_reads/execution_count) as avg_logical_reads, (total_logical_writes/execution_count) as avg_logical_writes, (total_physical_reads/execution_count) as avg_physical_reads, Execution_count, statement_start_offset, p.query_plan, q.textfrom sys.dm_exec_query_stats
cross apply sys.dm_exec_query_plan(plan_handle) p cross apply sys.dm_exec_sql_text(plan_handle) as q
order by (total_logical_reads + total_logical_writes)/execution_count Desc
下⾯的 DMV 查询可⽤于查找哪些批处理/请求⽣成的 I/O 最多。如下所⽰的 DMV 查询可⽤于查找可⽣成最多 I/O 的前五个请求。调整这些查询将提⾼系统性能。
select top 5
(total_logical_reads/execution_count) as avg_logical_reads, (total_logical_writes/execution_count) as avg_logical_writes, (total_physical_reads/execution_count) as avg_phys_reads, Execution_count,
statement_start_offset as stmt_start_offset, sql_handle, plan_handle
from sys.dm_exec_query_stats
order by (total_logical_reads + total_logical_writes) Desc
阻塞运⾏下⾯的查询可确定阻塞的会话。
select blocking_session_id, wait_duration_ms, session_id from sys.dm_os_waiting_tasks
where blocking_session_id is not null
使⽤此调⽤可找出 blocking_session_id 所返回的 SQL。例如,如果 blocking_session_id 是 87,则运⾏此查询可获得相应的 SQL。
dbcc INPUTBUFFER(87)
下⾯的查询显⽰ SQL 等待分析和前 10 个等待的资源。
select top 10 *
from sys.dm_os_wait_stats
--where wait_type not in ('CLR_SEMAPHORE','LAZYWRITER_SLEEP','RESOURCE_QUEUE','SLEEP_TASK','SLEEP_SYSTEMTASK','WAITFOR')order by wait_time_ms desc
若要找出哪个 spid 正在阻塞另⼀个 spid,可在数据库中创建以下存储过程,然后执⾏该存储过程。此存储过程会报告此阻塞情况。键⼊ sp_who 可找出 @spid;@spid 是可选参数。
create proc dbo.sp_block (@spid bigint=NULL)asselect
t1.resource_type,
'database'=db_name(resource_database_id), 'blk object' = t1.resource_associated_entity_id, t1.request_mode,
t1.request_session_id, t2.blocking_session_id from
sys.dm_tran_locks as t1,
sys.dm_os_waiting_tasks as t2where
t1.lock_owner_address = t2.resource_address and
t1.request_session_id = isnull(@spid,t1.request_session_id)以下是使⽤此存储过程的⽰例。
exec sp_block
exec sp_block @spid = 7
