Daniel Hutmacher tilts at windmills:

It’s not entirely uncommon to want to group by a computed expression in an aggregation query. The trouble is, whenever you group by a computed expression, SQL Server considers the ordering of the data to be lost, and this will turn your buttery-smooth Stream Aggregate operation into a Hash Match (aggregate) or create a corrective Sort operation, both of which are blocking.

Is there anything we can do about this? Yes, sometimes, like when those computed expressions are YEAR() and MONTH(), there is. But you should probably get your nerd on for this one.

There are many ways to solve a problem, and sometimes the best method is indirect.

Itzik Ben-Gan continues his series on grouping and aggregation:

Let’s try and figure out the costing formula for the Sort operator. Remember, our focus is the estimated cost and scaling because our ultimate goal is to figure out optimization thresholds where the optimizer changes its choices from one strategy to another.

The I/O cost estimate seems to be fixed: 0.0112613. I get the same I/O cost irrespective of factors like number of rows, number of sort columns, data type, and so on. This is probably to account for some anticipated I/O work.

As for the CPU cost, alas, Microsoft doesn’t publicly expose the exact algorithms that they use for sorting. However, among the common algorithms used for sorting by database engines in general are different implementations of merge sort and quicksort. Thanks to efforts made by Paul White, who’s fond of looking at Windows debugger stack traces (not all of us have the stomach for this), we have a bit more insight into the topic, published in his series “Internals of the Seven SQL Server Sorts.” According to Paul’s findings, the general sort class (used in the above plan) uses merge sort (first internal, then transitioning to external). In average, this algorithm requires n log n comparisons to sort n items. With this in mind, it’s probably a safe bet as a starting point to assume that the CPU part of the operator’s cost is based on a formula such as:

Operator CPU cost = <startup cost> + @numrows * LOG(@numrows) * <comparison cost>

Of course, this could be an oversimplification of the actual costing formula that Microsoft uses, but absent any documentation on the matter, this is an initial best guess.

It’s interesting to see how the calculation changes in form with larger numbers of rows.

Erik Darling continues his research into trivial plans and parameterization:

No. Really?

The plan is still showing us a warning, even though we see a literal in the cache.

This is obviously wrong. And very confusing.

Read on for the answer.

Hugo Kornelis explains what the Bitmap operator is in an execution plan:

As implied by its logical operation, “Create Bitmap”, the Bitmap operator creates a bitmap. (I assume that this is the only logical operation that the Bitmap operator supports, since I have never seen a Bitmap operator with a different logical operation). A bitmap is a structure that stores Boolean values for a consecutive range of values in a small amount of memory. E.g. the range from 1 to 8000 has 8000 possible values. These can be represented as 8000 bits in just 1000 bytes. For each value, the location of the corresponding bit can be computed by dividing the value by 8; the dividend is the location and the remainder determines which of the bits to use. The value of that specific bit can then be tested, or it can be set to false (zero) or true (one).

The bitmap is named Opt_Bitmap1005 in this case. This name is not exposed in the quick property popup, but you can find in in the full property sheet as shown here, in the Defined Values property. You will also note that this bitmap is not included in the Output List property. That’s because this bitmap is not created for each individual row; there is a single bitmap that accumulates information from all rows. Other operators in the execution plan can reference this bitmap by name, even though it is not passed to them in their input rows.

Hugo goes into great detail on the operator, so you’ll want to set aside some time to read this.

Erik Darling ran into an interesting case with simple parameterization:

The query plan shows us that we got a Trivial Plan, and that Simple Parameterization was attempted (as shown by the 100000 literal turning into the @1 parameter.)

Simple Parameterization is only attempted in a Trivial Plan.

The key word here is attempted.

And Grant Fritchey has more:

Normally, you spot the change to your query string, you go in to the properties and you see both (and it has to be both) a Parameter Compiled Value and a Parameter Runtime Value, you’ve got simple parameterization going on.

Or do you?

Notice the final property on the sheet, StatementParameterizationType. Honestly, I never really paid attention to that property. I knew what kind of parameterization I was seeing. I’m not running Forced Parameterization. This isn’t a parameterized query. It’s Simple Parameterization. Of course it is. All the keys are there. Change to the code. Parameter List values. Done.

Narrator voice:  it wasn’t done.

Bert Wagner looks at join order in SQL Server:

SQL is a declarative language: you write code that specifies *what* data to get, not *how* to get it.

Basically, the SQL Server query optimizer takes your SQL query and decides on its own how it thinks it should get the data.

It does this by using precalculated statistics on your table sizes and data contents in order to be able to pick a “good enough” plan quickly.

I like this post.  It also lets me push one of my favorite old-time performance tuning books, SQL Tuning by Dan Tow.  95+ percent of the time, you don’t need to think about join order.  But when you do, you want to have a systematic method of figuring the ideal join order out.