Erik Darling gives us a Sophie’s Choice:

It could have chosen a Hash Join, but then the order of the Id column from the Posts table wouldn’t have been preserved on the other side.

Merge Joins are order preserving, Hash Joins aren’t. If we use a Hash Join, we’re looking at ordering the results of the join after it’s done.

But why?

Read on to learn why, as well as why a few other things are so.

Bert Wagner shows how you can create your own tables in tempdb to avoid eager or lazy spools:

SQL Server Spool operators are a mixed bag. On one hand, they can negatively impact performance when writing data to disk in tempdb. On the other hand, they allow filtered and transformed result sets to be temporarily staged, making it easier for that data to be reused again during that query execution.

The problem with the latter scenario is that SQL Server doesn’t always decide to use a spool; often it’s happy to re-read (and re-process) the same data repeatedly. When this happens, one option you have is to explicitly create your own temporary staging table that will help SQL Server cache data it needs to reuse.

The other problem with spooling is that the spool doesn’t have indexes and so performance can be awful. When I look at an execution plan, one of my immediate red flags is spooling: if we have that, removing it is one of the first candidates for optimization after the trivial stuff (expected scan/seek behavior, “fat pipes” from excessive row counts, residual I/O, etc.).

Max Vernon recommends a pull rather than push model when you need to insert cross-server:

Linked Servers offer a great way to connect two SQL Servers together, allowing remote querying and DML operations. Frequently, this is used to copy data from production to reporting. However, the temptation is to run the copy operation on the production, or source side. If you do that, even with a single INSERT INTO statement, SQL Server will process each individual row as a discrete INSERT INTO statement via a cursor operation. This makes for very slow inserts across a linked server. Running the operation from the destination server means SQL Server can simply query the remote source table for all the rows, inserting them as a set into the destination table. The difference in speed can be eye-watering.

Click through for a slightly creepy picture and a less creepy example.

Bert Wagner shows a scenario where a window function ends up performing poorly:

If you’ve used FIRST_VALUE before, this query should be easy to interpret: for each badge Name, return the first UserId sorted by Date (earliest date to receive the badge) and UserId (pick the lowest UserId when there are ties on Date).

This query was easy to write and is simple to understand. However, the performance is not great: it takes 46 seconds to finish returning results on my machine.

Bert’s response is to rewrite the query using a correlated subquery. My first shot would look at using APPLY though needing to aggregate the “parent” could lead to an awful result there if the join happened before aggregation.

The moral of the story here is to know different ways to write a query, as you can nudge the optimizer to better (or worse) behavior.

Brent Ozar shows that index seeks are not always better than index scans:

Somewhere along the way in your career, you were told that:
– Index seeks are quick, lightweight operations
– Table scans are ugly, slow operations

And ever since, you’ve kept an eye on your execution plans looking for those performance-intensive clustered index scans. When you see ’em, you go root ’em out, believing you’ve got a performance problem.

Thing is, … they lied to you. Seeks aren’t necessarily good, nor are scans necessarily bad. To straighten you out, we’re going to walk through a series of demos.

The rule of thumb I like to use is: if you need to go through more than 20% of the data, you’re generally better off scanning. If you need to go through less than 0.5% of the data, you’re generally better off seeking. Everything in between is the “it depends” zone.