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Category: Internals

Using DBCC INPUTBUFFER

Monica Rathbun shows us how to use DBCC INPUTBUFFER:

A command I like to use when performance tuning is DBCC INPUTBUFFER. If you have ever run sp_whoisactive or sp_who2 to find out what sessions are executing when CPU is high for instance this can be a real quick life saver. At times, for me, those two options do not return enough information for what I’m looking for which is the associated stored procedure or object. Using this little helper along with the session id can easily get you that information.

Let’s take a look.

Let’s.

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Queues and Watermarks

Forrest McDaniel wants a zippier queue in SQL Server:

I recently had the pleasure of investigating a procedure that pulled from a queue. Normally it was fast, but occasionally runtime would spike. The spooky thing was the query was using an ordered index scan that should only read one row, but during the spikes it was reading thousands.

Surely there’s a rational explanation…

Spoilers: there was. And Forrest a’int afraid of no ghosts.

(sotto voce – I’m so glad that Forrest didn’t sneak in any Ghostbusters references so that I could do that here and be original.)

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Finding Eager Index Spools

Erik Darling hunts the most dangerous prey of all:

I’ve written a bunch about Eager Index Spools, and how to fix them, but I’ve always sort of left the “finding” part up to you, or pointed curious tuners to tools like sp_BlitzCache.

Recently though, I worked with a client who had Eager Index Spools so frequently that we needed to track them down specifically.

This is the plan cache query that I used to do it — they didn’t have Query Store enabled — and I wanted to share it.

Click through for the query.

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When the Version Store Fills tempdb

David Fowler takes us through a mental exercise:

Well, there is something else that I’ve seen have a habit of filling TempDB. If you’re using Read Committed Snapshot or RCSI then you’ll also have a version store in your database. I’m not going to go into the details of exactly how version store works, there is plenty of documentation on it out there if you’re interested (perhaps I’ll write a post on it sometime).

The key bit that you need to know is that although SQL will keep version store trimmed down and only keep the rows that are needed, it can only clear rows that are older than the oldest transaction. This is because SQL has no way of knowing what rows are going to be needed by the transaction. Do you see a potential issue here?

Read on for enlightenment.

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Whither Code Page 1

Solomon Rutzky unravels a mystery:

Collation names, at least in SQL Server, are structured in that they contain various pieces of information detailing some of the properties of the collation. The collation name of SQL_Latin1_General_CP1_CI_AS can be broken down as follows:

SQL_ This indicates that the collation is a SQL Server collation, while names without this prefix indicate Windows collations

Latin1_General This is the culture (a.k.a. locale) used for the sorting and comparison rules

CP1 This is the 8-bit [C]ode [P]age

CI This indicates [C]ase- [S]ensitive or [I]nsensitive

AS This indicates [A]ccent- [S]ensitive or [I]nsensitive

Ok, but there’s no code page “1”. So, what’s going on there?

Read on to learn the answer behind this mystery.

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Binary and Hexadecimal in Brief

Randolph West has a primer for us:

The CPU can only work with small amounts of data at a time. When the CPU is done with that data, it puts it in memory. Depending on how that data is managed (the on-or-off bit of information is literally called a bit because computer scientists are great at naming things), it usually forms part of a byte, which by convention is eight bits. In other words, you get eight bits of information per byte, represented by a series of 1s (electricity flowed for a fixed period of time) and 0s (no electricity flowed for that fixed period of time).

The uppercase “A” in the Latin alphabet, using the ASCII standard, is represented by the byte 01000001.

So, cool, this is binary. What does it actually mean? 

Read on for more.

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Finding Index Fragmentation

Deepthi Goguri is hunting the most dangerous predator:

The bad page splits are the splits that we learned in the previous post which is the split that occurs when a random insert has to happen and there is no space on page, a new page gets created during the page split. These page splits are very expensive causing the fragmentation. Good page splits occurs when the append only inserts happen as the pages gets filled on the index pages to the right side of the index and new pages gets added as they gets filled up to the right side of the index. These types of good page splits doesn’t cause any index fragmentation. SQL Server will group these two types of page splits together and do not differentiate between them. So, how do we know to differentiate between the good and the bad page splits? Let’s learn more about this.

It is very difficult to differentiate these page splits by using the existing methods we have in the SQL Server like using the perfmon counter which has the pagesplits/sec counter. This counter will give the good and the nasty page splits together. There is a DMV sys.dm_db_index_operational_stats and an extended event page_split event to track the page splits.

Read on to see how we can find those undesirable page splits versus the benign ones.

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The Mechanisms of Page Splits

Deepthi Gogrui takes us through page splitting in SQL Server:

Page splits can happen with the logical fragmentation and low page density causing the transactional log to be huge. Page splits are very expensive. As we learned from the previous post, page splits happens when SQL Server tries to insert a row and there is no more space on the page to fit in the page so page will split the page to give the space to fit it in that record. When SQL Server has to insert any rows in to the pages, first the free space on the page is checked at the header information of the page and if the record is within the mentioned free bytes, the record fits in. If the space is not contiguous within the page but there is total space to fit in the record, then the in-memory compaction of the page making the amount of free space on the page contiguous. This is not page split. Page split occurs when the space is not available on the page to fit in the record, in that case page split into half and the split point of the page is usually 50 percent each. Sometimes, the split can happen at the different point on the page is chosen by the storage engine as the obvious split point which is known as skewed page split. This is even more expensive when compared with the regular page split as this will create much larger transaction log.

What causes the page splits?

Read on for the full article.

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Types of Fragmentation on Index Pages in SQL Server

Deepthi Goguri explains what sorts of fragmentation can occur on an index in SQL Server:

Logical Fragmentation occurs when the logical order of the leaf level pages (logical order meaning the next key values in order) no longer the continuous page to the next physical data file page. Because of these pages which are out of order will affect the read ahead mechanism and the scan performance. Because of this logical fragmentation, read ahead have to do smaller read ahead reads.

If the logical fragmentation pages are already in the memory than the read ahead mechanism will not be affected in that case. Logical fragmentation will cause the problem for bigger indexes and not for the smaller ones usually (smaller indexes having pages 1000-5000 pages). You can monitor the amount of the index logical fragmentation by using the DMV sys.dm_db_index_physical_stats.

Read on to learn more about logical fragmentation, as well peers extent fragmentation and low page density.

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