sql-servert-sqlcommand-timeout

What is the proper way to run a long query against an active database?


We are using SQL Server 2012 EE but currently do not have the option to run queries on a R/O mirror though that is my long term goal, though am concerned I may run into the below issue in that scenario as well since the mirror would also be updating data I am querying.

I have a view that joins across several tables from two databases and is used for invoicing from existing data. Three of these tables are also actively updated by ongoing transactions. Running a report that used this view did not used to be a problem but now our database is getting much larger and I have run into some timeout problems. First the query was timing out so I set command timeout to 0 and reran the query which pegged all 4 CPUs 100% for 90 minutes and then I killed it. There were no problems with active transactions during that time. I reviewed the query and found a field I was joining on that was not indexed so created an index on that field, reran the report, which then finished in three minutes and all the CPUs were busy but not at all pegged out. Same data amount queried both times. I figured problem solved. Of course later, my boss ran a similar query, perhaps with some more data but probably not a lot more, and our live transactions started timing out 100% while his query was running. I did not get a chance to see the CPU usage during that time.

So my questions are two:

  1. Given I have to use the live and active database, what is the proper way to run a long R/O query so that active transactions can still continue? I am considering NO LOCK but am hoping there is a better standard practice.

  2. And what might cause sqlserver to peg out 4 CPUs with 100% busy and not cause live transaction timeouts, yet when my boss ran his query, after I added the index and my query ran much better, the live update transactions start timing out 100%?

I know this is not a lot of info to go on. I'm not very familiar with sql profiling and performance monitoring yet this behavior seems rather odd and am hoping a best practice would be the correct workaround.


Solution

  • The default behavior of SELECT queries in the READ_COMMITTED transaction isolation level is to acquire shared locks during query execution to provide the requested data consistency (read committed data only). These locks are typically row-level and released quickly during query execution immediately after each row is read. There are also less granular intent locks at the page and table level prevent concurrent updates to data as it is being read. Depending on the particulars of the execution plan, there may even be shared locks held at the table level for the duration of the query, which will prevent updates to the table during query execution and result in readers blocking writers.

    Setting the READ_COMMITTED_SNAPSHOT database option causes SQL Server to use row versioning instead of locking to provide the same read consistency. A row version store is maintained in tempdb so that when a row requested by the query has changed since the query began, the most recent committed row version is returned instead. This row-versioning behavior avoids locking and effectively provides a statement-level snapshot of the database at the time the query began. Readers do not block writers and writers do not block readers. Do not confuse the READ_COMMITTED_SNAPSHOT database option with the SNAPSHOT isolation level (a common mistake).

    The downside of setting the READ_COMMITTED_SNAPSHOT is additional resource usage. An additional 14 bytes of storage overhead for each row is incurred once the database option is enabled. Updates and deletes will generate row versions in tempdb. These versions require tempdb space for the duration of the longest running query and there is overhead in maintained the version store. Also consider whether you have existing applications that depend on readers-block-writers locking behavior. Despite this overhead, the concurrency benefits may yield better overall performance depending on your workload, while providing read integrity. See http://technet.microsoft.com/en-us/library/ms188277.aspx for more information.