Category Archives: Syndicated

SQLDIY: Index Usage Statistics

There are several different aspects of indexes that can be monitored via DMV’s. One the neatest things is just how much your indexes are used, how they are used or if they are used at all! I’ve put together this stored procedure to gather a ton of useful information on just how your indexes are being used. Using this information you can determine if the index in question is really needed, or if it is truly critical and shouldn’t be messed with. As will all DMV’s if your server was just rebooted you may see quite a number of unused indexes. By sampling data over time we can see when an index is actually called into use. Is it only really used once a quarter or once a year? Maybe we can disable it and then rebuild it before it is needed cutting down on maintenance and lessening the penalty for data modifications over the long term.

IsUsed – Simple, has your index ever been used.
IsExpensive – does it cost a lot to do updates or inserts into this index?

These columns all deal with how your index is accessed and updated. Is it used in a lot of scans, Maybe implying its used mostly for joins? Is it seek heavy, showing that your used are writing good WHERE clauses?

UserSeeks
UserScans
UserLookups
UserUpdates
LastUserSeek
LastUserScan
LastUserLookup
LastUserUpdate

AverageRecordSizeInBytes I look at this one to show me just how wide or narrow a particular index is. I also use it to help do detailed growth analysis, if we add X number of rows what size would the index grow too?
Series to Date SQLDIY: Manage and Monitor SQL Server Yourself

Link to the script Gather Index Usage Statistics

I’m hosting all my scripts from this series on GitHub as I do with all my open source projects.

As always, if you find any bugs please let me know and I will correct them!

SQLDIY: Index Fragmentation Levels

Indexes, indexes, indexes my kingdom for an index! Well, something like that. Indexes are the single most important structure in our relation database world. So, it is understandable that I do everything I can to gather information, monitor their health and maintain them to the best of my ability. One of the keys to index health is how badly fragmented the index is. Many people simply reindex everything on a regular schedule. While this may be fine for smaller indexes say under 50 megabytes but not so great for indexes that may be very large 400 megabytes or more. Knowing how your database is used is also needed if you are going to truly plan for the future and your index health. Is your table built with an identity for the primary key and only receives inserts? Or is it indexed on a GUID and has heavy deletes and updates? In the first case, depending on fill factor you may not need to do full reindex with a high level of frequency. In the second case, you may not be able to keep fragmentation levels under control without sacrificing the availability of your database. The problem is the larger the index the more difficult it becomes to manage from a reindexing strategy. When indexes get in the gigabyte range things like partitioning become as much a necessity for performance as well as maintenance tasks. For years I’ve written and maintained my own index maintenance scripts. Well, that all came to an end when Michelle Ufford put out her index defrag script.

Series to Date SQLDIY: Manage and Monitor SQL Server Yourself

Link to the script Index Fragmentation Levels

I’m hosting all my scripts from this series on GitHub as I do with all my open source projects.

As always, if you find any bugs please let me know and I will correct them!

Your Homework:

Index Fragmentation Findings: Part 1, The Basics Brent Ozar (blog|twitter)

Index Defrag Script v4.1 Michelle Ufford (blog|twitter)

Pliant Technology, Enterprise Flash Drives For Your SQL Server: Part 2

Adding In Others For Contrast

In our first part we introduced Pliant and the LS 300 drive. In part 2 we get down to the details. To give a better idea where you stand with the setup described last time I’m throwing in two other storage setups. A RAID 10 array made up of 12 500GB 7200 RPM drives attached via SATA II controllers In a RAID 0 configuration I was able to get 800MB/sec in sequential throughput so it isn’t horrible, just not “enterprise” worthy. A Patriot Torqx 128GB based on Indilinx Bigfoot SSD controller, not the greatest SSD on the consumer market but Indilinx was the king of the previous generation. I will be using the LSI controller just like I did for the Pliant LS 300.

Patriot Torqx Specifications:
Available in 64GB, 128GB and 256GB capacities
Interface: SATA I/II
Raid Support: 0, 1, 0+1
256GB and 128GB: Sequential Read: up to 260MB/s Sequential Write: up to 180MB/s
MTBF: >2,500,000 Hours
Data Retention: 5 years at 25°C
Data Reliability: Built in BCH 8, 12 and 16-bit ECC
10 Year Warranty

RAID support? I’m not sure what they are saying here other than don’t put this drive in a RAID 5 or RAID 6 setup at all. Mean time between failures(MTBF) is a pretty useless number, I would have rather seen a maximum write life or writes per day metric. It has ECC error checking, since this is an MLC based drive that doesn’t surprise me at all. 10 year warranty, yep 10 YEARS! This was one of the reasons I bought this drive. And I’m glad I did, it has already been replaced once.

The Setup

Since we are just testing storage systems I’m not as concerned with the host machine. It is more than up to the task of generating IO’s. I used Iometer 2008.06.18-RC2 for testing and my trusty
Iometer SQL Server IO Patterns File. After the test runs I used my other tool the Iometer output parser and importer to process the results and import them into a SQL Server table. The tests consisted of two different patters. These two patterns are close to what I’ve seen in the real world and loosely based on the Intel database test pattern. I run these test at different queue depths with a single worker
OLTP Heavy Read:
A mix of 8KB and 64KB size request with 90% of them being read request and 10% being write request. This test is 100% random access.

OLTP Moderate Read:
A mix of 8KB and 64KB size request with 65% of them being read request and 35% being write request. This test is 100% random access.

Lots And Lots of Graphs

This first set is OLTP Heavy Read at a queue depth of 1. Average Response Time is in milliseconds (ms).

Interesting to see the Torqx drive actually performing better than the Pliant drive. Since this is an extremely light load and mostly read only we can assume that the Torqx is tuned more towards that kind of workload. The hard disks put in a respectable showing, for hard disks.

OLTP Heavy Read at a queue depth of 4. Average Response Time is in milliseconds (ms).

As soon as we put some kind of load the Pliant drive just walks away from the other two drives. The Torqx is still five times faster than the RAID 10 setup.

OLTP Heavy Read at a queue depth of 8. Average Response Time is in milliseconds (ms).

Again, as the workload ramps up the Pliant really just ends up in a category all its own. We are still in a decent zone for the RAID setup but the single Torqx drive still is four to five times faster.

OLTP Heavy Read at a queue depth of 32. Average Response Time is in milliseconds (ms).

Now we are pushing past the bounds of the SATA based Torqx and the SATA based RAID setup. The Pliant drive just keeps getting faster jumping from 13,000 IO/sec to 22,000 IO/sec. Response times are still very impressive as well.

OLTP Heavy Read at a queue depth of 128. Average Response Time is in milliseconds (ms).

This is what we would call a “worst case scenario” for the RAID setup. With only 12 drives we are at a queue length of 10 for each drive. Response times are showing it too with the average being 110ms. Even the Torqx drive can’t shed the IO load at this point while the Pliant drive drives past 26,000 IO/sec and inches up on 500MB/sec as well. That last statement is accurate. Since this is a dual-port drive even though its a SAS 300 drive it is able to use both ports for read and writes. I did run the test up to 256 outstanding IO/sec but the Pliant drive was capped out and was starting to add some to the response time. The RAID array and the Torqx drive were getting so slow that the Pliant drive was hard to see on the average response time graph.

This second set is OLTP Moderate Read at a queue depth of 1. Average Response Time is in milliseconds (ms).

This workload is much more write intensive and the Pliant LS 300 jumps out in front very quickly. Even at 1 queue depth it is shaming the Torqx on write performance. The RAID array is performing pretty well with lower than expected response times.

OLTP Moderate Read at a queue depth of 4. Average Response Time is in milliseconds (ms).

Quickly the Pliant drive starts to walk away with this contest. It clearly has much more capacity for write workloads than the Torqx or RAID array.

OLTP Moderate Read at a queue depth of 8. Average Response Time is in milliseconds (ms).

Here we are again at the end of the road for the RAID array. The Torqx drive is holding on but response times are getting long. It is only managing to pull a two fold increase in performance over the RAID array.

OLTP Moderate Read at a queue depth of 32. Average Response Time is in milliseconds (ms).

Now things are just embarrassing for the RAID array and the Torqx drive. Both showing that write heavy workloads aren’t the best fit. Again, the Pliant drive is starting to get response times in the millisecond range but at 320MB/Sec and 18,000 IO/Sec I would have to call that a fair trade.

OLTP Moderate Read at a queue depth of 128. Average Response Time is in milliseconds (ms).

At last we have hit a wall with the RAID array and the Torqx drive. With the Torqx drive posting up numbers that are less than two times the RAID array it is starting to show its real weaknesses. The Pliant drive however is pulling a solid 22,ooo IO/Sec and creeping up on 43oMB/Sec of throughput. All of this from a single SAS 3.5″ drive.

Final Thoughts

I’ve had the Pliant LS 300 in my lab for quite a while now. I’ve also had the Patriot Torqx and this particular RAID array setup. All three have been running hard during the last three months. The Pliant drive did show some signs of slowing down as it settled into the workloads. The RAID array lost three drives total and as I stated earlier, the first Torqx drive I had gave up the ghost in the first month. I’ve said it before, and I will say it again. If you need an enterprise drive then buy an enterprise drive! Don’t get a drive that has a SATA interface and is dressed up like it is ready for the big show. I can say without a doubt the the Pliant LS 300 is one of the finest solid state disk I’ve ever worked with.

SQLDIY: Statistics Information Including Last Update

One of the most important aspects of keeping your system running well is updating and managing your statistics. Since the optimizer relies on statistics to determine the best execution plan it is imperative that you keep an eye on them and maintain them just like you would indexes. One of the disappointing things in SQL Server 2005/2008 is the deprecation of some of the functionality of the sysindexes system view. In particular the rowmodctr column, since there is no equivalent in any of the new sys schema DMV’s. With that said, the GatherStatisticsInformation stored procedure listed here is missing that bit of information.What I do include is the last time the statistics were updated for a particular index. It is a rare thing to see information from SQL Server take a step backwards. Hopefully they will correct this mistake and add the modified row count back in to a DMV that is accessible.

Series to Date SQLDIY: Manage and Monitor SQL Server Yourself

Link to the script Gather Information On Statistics

I’m hosting all my scripts from this series on GitHub as I do with all my open source projects.

As always, if you find any bugs please let me know and I will correct them!

Your Homework:

Statistics Used by the Query Optimizer in Microsoft SQL Server 2008

SQL Server 2008 Statistics Jose Barreto (blog|twitter)

Lies, Damned Lies and Statistics Elisabeth Redei

How Stale are my Statistics? Kendra Little (blog|twitter)

And everything on SQL Skills

SQLDIY: Gathering A Data Dictionary

In this installment we are looking at assembling a basic data dictionary from the column level meta data stored in SQL Server. This is a little different from the rest. You can still do quite a bit with the information provided but to leverage this to the fullest requires a bit of developer buy in. Or a bit more work for whomever is your schema designer. Extended properties have been available to you since the stone ages of SQL Server. Two fine fellows Mark Chaffin and Brian Knight(blog|twitter) expound on the power of extended properties in the article on Managing Metadata in SQL Server 2005. Well worth the read. Using a couple of stored procedures you can store some very rich metadata about every object in your database.

Here are some examples of how to add descriptions to your objects.

–Adding a description to a table
EXEC sp_addextendedproperty
@name = N’MS_Description’,
@value = N’New Description for the Server table’,
@level0type = N’SCHEMA’, @level0name = dbo,
@level1type = N’TABLE’, @level1name = Server;

GO

–adding a description to a column
EXEC sp_addextendedproperty
@name = N’MS_Description’
,@value = N’Login is trusted’
,@level0type = N’Schema’, @level0name = dbo
,@level1type = N’Table’,  @level1name = Server
,@level2type = N’Column’, @level2name = Trusted;
GO
–updating that column description
EXEC sp_updateextendedproperty
@name = N’MS_Description’
,@value = N’Login is windows authenticated’
,@level0type = N’Schema’, @level0name = dbo
,@level1type = N’Table’,  @level1name = Server
,@level2type = N’Column’, @level2name = Trusted;

Pretty simple, yet I’ve always received push back from both developers and database administrators. To me knowledge is power and building the documentation directly into the database metadata is an extremely powerful tool to have handy. At any point I can query sys.extended_properties on an object and find its usage, without having to guess by the object name what it may, or may not actually represent.

A second use case for having the metadata and a history of changes pretty straight forward, checking for schema changes. If you don’t want to implement DDL triggers or use a third party tool to watch for schema changes this is another handy tool in your tool belt. I’ve used this data to track schema deployed across servers to make sure that they are always in sync and if they are out of sync to send an alert.

Couple of quick notes for you. When you are querying sys.extended_properties minor_id is the column_id if you are looking at a class of 1. See sys.extended_properties on technet.

This one is a two in one enjoy!

Series to Date SQLDIY: Manage and Monitor SQL Server Yourself

Link to the script Gather Table Level Metadata

Link to the script Gather Database Level Metadata

I’m hosting all my scripts from this series on GitHub as I do with all my open source projects.

As always, if you find any bugs please let me know and I will correct them!