John Morehouse shows that SQL Server data pages are the same in Windows as they are in Linux:

One of the new phrases coming out of Microsoft is that “SQL is just SQL” regardless of what operating system it resides on.   This was echoed during the keynote at SQL Bits 2019 by the Microsoft team, which you can watch here.   Later that weekend, I gave a session about database internals.  My presentation is about how data is structured within a row and why that matters.  Understanding the internals of table structures, even in today’s age of technology, include SQL Server 2019 (which will be released in Q3/Q4 of 2019) is important.   During my session, a question came up about how a data page is structured if SQL Server is sitting on top of a Linux server, such as Ubuntu.  Does the data page have the same size and shape in Linux as it does in Windows?

They do. Click through to see John prove it.

Arthur Daniels shows that multi-statement stored procedures can have multiple entries in the plan cache:

So we have two entries for this stored procedure. I included the statement sql handle to show that each statement handle has its own text. Let’s parse that text to see each statement. I copied the parsing SQL from this Plan Cache article.

This is a good thing to keep in mind if you’re trying to figure out how often a procedure gets called: SUM on the execution counts grouped only by text might not give you the results you expect.

Randolph West starts a new series on the buffer pool in SQL Server:

Now that we’ve reminded ourselves of those fundamentals, let’s take a closer look at the buffer pool.

The buffer pool in SQL Server resides in the computer’s main memory (RAM). When the database engine requests a data page for reading or writing, it is assumed to be in the buffer pool. The buffer pool itself controls access between RAM and storage. If the data page that the database engine requests is not in RAM, a request is sent to the storage engine to retrieve that page. This may be storage directly attached to the system, or via a network interface card.

This first post is a high-level overview, but it looks like there’s a lot more in store from Randolph.

Bert Wagner continues his series on physical join operators:

The base algorithm works as follows: SQL Server compares the first rows from both sorted inputs.  It then continues comparing the next rows from the second input as long as the values match the first input’s value.
Once the values no longer match, SQL Server increments the row of whichever input has the smaller value – it then continues performing comparisons and outputting any joined records. (For more detailed information, be sure to check out Craig Freedman’s post on merge joins.)

Beware:  Bert has animations which might cause you to space out for a few hours.

Hugo Kornelis has a long article which dives into the way SQL Server handles index spooling:

A Table Spool operator stores its data in a worktable that is structured as a clustered index. The index is not built on any of the columns in the data, nor on any artificially added columns. It is structured on zero columns. As is normal for a clustered index on a set of columns that is not unique for the set, a 4-byte uniqueifier is then added to the data to give each row a unique internal address.

The worktable for an Index Spool operator is also structured as a clustered index. However, this operator does actually index actual columns from its data instead of just relying on a uniqueifier. The indexed columns are chosen to effectively satisfy the Seek Predicate property. The statement in the Microsoft’s documentation that a nonclustered index is used for Index Seek is not correct.

A stack spool is represented in execution plans as a combination of an Index Spool and a Table Spool, both with the With Stack property present and set to True. This is misleading because it is actually a different type of spool. The worktable it uses is built as a clustered index on a single column, representing the nesting level. Because this is not unique, a uniqueifier is added where needed.

This is a deep look at some operators which people tend to gloss over but can have huge performance impacts.

Itzik Ben-Gan continues his series on grouping and aggregating data by looking at the hash match aggregation process:

The estimated CPU cost for the Hash Aggregate in the plan for Query 8 is 0.166344, and in Query 9 is 0.16903.

It could be an interesting exercise to try and figure out exactly in what way the cardinality of the grouping set, the data types, and aggregate function used affect the cost; I just didn’t pursue this aspect of the costing. So, after making a choice of the grouping set and aggregate function for your query, you can reverse engineer the costing formula. For example, let’s reverse engineer the CPU costing formula for the Hash Aggregate operator when grouping by a single integer column and returning the MAX(orderdate) aggregate. The formula should be:

Operator CPU cost = <startup cost> + @numrows * <cost per row> + @numgroups * <cost per group>

Using the techniques that I demonstrated in the previous articles in the series, I got the following reverse engineered formula:

Operator CPU cost = 0.017749 + @numrows * 0.00000667857 + @numgroups * 0.0000177087

Definitely worth reading in detail.

Kendra Little shows us the impact that row width has on snapshot isolation:

So I went to work to demonstrate row width impact on the version store — when only a tiny bit column is changed in the row.

Here’s how I did the test:

• I created two tables, dbo.Narrow and dbo.Wide. They each each have a bit column named bitsy, along with some other columns.
• I inserted one row in each table, but I put a lot more data into the row in dbo.Wide.
• I allowed snapshot isolation on the database
• I began a transaction in another session under snapshot isolation and left the transaction open (so version store cleanup wouldn’t kick in while I looked around)
• I updated the bit column named bitsy for the single row in each table, thereby generating a row-version in tempdb for each table

The code I ran to test this is here, if you’d like to play around with it.

Read on for the results.