There is much more to query tuning than reducing logical reads and adding covering nonclustered indexes. Query tuning is not complete as soon as the query returns results quickly in the development or test environments. In production, your query will compete for memory, CPU, locks, I/O and other resources on the server. Today’s entry looks at some tuning considerations that are often overlooked, and shows how deep internals knowledge can help you write better TSQL. As always, we’ll need some example data. In fact, we are going to use three tables today, each of which is structured like this: Each table has 50,000 rows made up of an INTEGER
id column and a padding column containing 3,999 characters in every row. The only difference between the three tables is in the type of the padding column: the first table uses CHAR(3999), the second uses VARCHAR(MAX), and the third uses the deprecated TEXT type. A script to create a database with the three tables and load the sample data follows: USE master;
GO
IF DB_ID('SortTest')
IS NOT NULL
DROP DATABASE SortTest;
GO
CREATE DATABASE SortTest
COLLATE LATIN1_GENERAL_BIN;
GO
ALTER DATABASE SortTest
MODIFY FILE
(
NAME = 'SortTest',
SIZE = 3GB,
MAXSIZE = 3GB
);
GO
ALTER DATABASE SortTest
MODIFY FILE
(
NAME = 'SortTest_log',
SIZE = 256MB,
MAXSIZE = 1GB,
FILEGROWTH = 128MB
);
GO
ALTER DATABASE SortTest
SET ALLOW_SNAPSHOT_ISOLATION OFF
;
ALTER DATABASE SortTest
SET AUTO_CLOSE OFF
;
ALTER DATABASE SortTest
SET AUTO_CREATE_STATISTICS ON
;
ALTER DATABASE SortTest
SET AUTO_SHRINK OFF
;
ALTER DATABASE SortTest
SET AUTO_UPDATE_STATISTICS ON
;
ALTER DATABASE SortTest
SET AUTO_UPDATE_STATISTICS_ASYNC ON
;
ALTER DATABASE SortTest
SET PARAMETERIZATION SIMPLE
;
ALTER DATABASE SortTest
SET READ_COMMITTED_SNAPSHOT OFF
;
ALTER DATABASE SortTest
SET MULTI_USER
;
ALTER DATABASE SortTest
SET RECOVERY SIMPLE
;
USE SortTest;
GO
CREATE TABLE dbo.TestCHAR
(
id INTEGER IDENTITY (1,1) NOT NULL,
padding CHAR(3999) NOT NULL,
CONSTRAINT [PK dbo.TestCHAR (id)]
PRIMARY KEY CLUSTERED (id),
)
;
CREATE TABLE dbo.TestMAX
(
id INTEGER IDENTITY (1,1) NOT NULL,
padding VARCHAR(MAX) NOT NULL,
CONSTRAINT [PK dbo.TestMAX (id)]
PRIMARY KEY CLUSTERED (id),
)
;
CREATE TABLE dbo.TestTEXT
(
id INTEGER IDENTITY (1,1) NOT NULL,
padding TEXT NOT NULL,
CONSTRAINT [PK dbo.TestTEXT (id)]
PRIMARY KEY CLUSTERED (id),
)
;
-- =============
-- Load TestCHAR (about 3s)
-- =============
INSERT INTO dbo.TestCHAR
WITH (TABLOCKX)
(
padding
)
SELECT padding = REPLICATE(CHAR(65 + (Data.n % 26)), 3999)
FROM (
SELECT TOP (50000)
n = ROW_NUMBER() OVER (ORDER BY (SELECT 0)) - 1
FROM master.sys.columns C1,
master.sys.columns C2,
master.sys.columns C3
ORDER BY
n ASC
) AS Data
ORDER BY
Data.n ASC
;
-- ============
-- Load TestMAX (about 3s)
-- ============
INSERT INTO dbo.TestMAX
WITH (TABLOCKX)
(
padding
)
SELECT CONVERT(VARCHAR(MAX), padding)
FROM dbo.TestCHAR
ORDER BY
id
;
-- =============
-- Load TestTEXT (about 5s)
-- =============
INSERT INTO dbo.TestTEXT
WITH (TABLOCKX)
(
padding
)
SELECT CONVERT(TEXT, padding)
FROM dbo.TestCHAR
ORDER BY
id
;
-- ==========
-- Space used
-- ==========
--
EXECUTE sys.sp_spaceused @objname = 'dbo.TestCHAR';
EXECUTE sys.sp_spaceused @objname = 'dbo.TestMAX';
EXECUTE sys.sp_spaceused @objname = 'dbo.TestTEXT';
;
CHECKPOINT
;
That takes around 15 seconds to run, and shows the space allocated to each table in its output:
To illustrate the points I want to make today, the example task we are going to set ourselves is to return a random set of 150 rows from each table. The basic shape of the test query is the same for each of the three test tables:
SELECT TOP (150)
T.
id,
T.padding
FROM dbo.Test AS T
ORDER BY
NEWID()
OPTION (MAXDOP 1)
;
Test 1 – CHAR(3999)
Running the template query shown above using the TestCHAR table as the target, we find that the query takes around 5 seconds to return its results. This seems slow, considering that the table only has 50,000 rows. Working on the assumption that generating a GUID for each row is a CPU-intensive operation, we might try enabling parallelism to see if that speeds up the response time. Running the query again (but without the MAXDOP 1 hint) on a machine with eight logical processors, the query now takes 10 seconds to execute – twice as long as when run serially.
Rather than attempting further guesses at the cause of the slowness, let’s go back to serial execution and add some monitoring. The script below monitors STATISTICS IO output and the amount of tempdb used by the test query. We will also run a Profiler trace to capture any warnings generated during query execution.
DECLARE @read BIGINT,
@write BIGINT
;
SELECT @read = SUM(num_of_bytes_read),
@write = SUM(num_of_bytes_written)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
SET STATISTICS IO ON
;
SELECT TOP (150)
TC.
id,
TC.padding
FROM dbo.TestCHAR AS TC
ORDER BY
NEWID()
OPTION (MAXDOP 1)
;
SET STATISTICS IO OFF
;
SELECT tempdb_read_MB = (SUM(num_of_bytes_read) - @read) / 1024. / 1024.,
tempdb_write_MB = (SUM(num_of_bytes_written) - @write) / 1024. / 1024.,
internal_use_MB =
(
SELECT internal_objects_alloc_page_count / 128.0
FROM sys.dm_db_task_space_usage
WHERE session_id = @@SPID
)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
Let’s take a closer look at the statistics and query plan generated from this:
Following the flow of the data from right to left, we see the expected 50,000 rows emerging from the Clustered Index Scan, with a total estimated size of around 191MB. The Compute Scalar adds a column containing a random GUID (generated from the NEWID() function call) for each row. With this extra column in place, the size of the data arriving at the Sort operator is estimated to be 192MB.
Sort is a blocking operator – it has to examine all of the rows on its input before it can produce its first row of output (the last row received might sort first). This characteristic means that Sort requires a memory grant – memory allocated for the query’s use by SQL Server just before execution starts. In this case, the Sort is the only memory-consuming operator in the plan, so it has access to the full 243MB (248,696KB) of memory reserved by SQL Server for this query execution.
Notice that the memory grant is significantly larger than the expected size of the data to be sorted. SQL Server uses a number of techniques to speed up sorting, some of which sacrifice size for comparison speed. Sorts typically require a very large number of comparisons, so this is usually a very effective optimization. One of the drawbacks is that it is not possible to exactly predict the sort space needed, as it depends on the data itself. SQL Server takes an educated guess based on data types, sizes, and the number of rows expected, but the algorithm is not perfect.
In spite of the large memory grant, the Profiler trace shows a Sort Warning event (indicating that the sort ran out of memory), and the tempdb usage monitor shows that 195MB of tempdb space was used – all of that for system use. The 195MB represents physical write activity on tempdb, because SQL Server strictly enforces memory grants – a query cannot ‘cheat’ and effectively gain extra memory by spilling to tempdb pages that reside in memory. Anyway, the key point here is that it takes a while to write 195MB to disk, and this is the main reason that the query takes 5 seconds overall.
If you are wondering why using parallelism made the problem worse, consider that eight threads of execution result in eight concurrent partial sorts, each receiving one eighth of the memory grant. The eight sorts all spilled to tempdb, resulting in inefficiencies as the spilled sorts competed for disk resources. More importantly, there are specific problems at the point where the eight partial results are combined, but I’ll cover that in a future post.
CHAR(3999) Performance Summary:
5 seconds elapsed time
243MB memory grant
195MB tempdb usage
192MB estimated sort set
25,043 logical reads
Sort Warning
Test 2 – VARCHAR(MAX)
We’ll now run exactly the same test (with the additional monitoring) on the table using a VARCHAR(MAX) padding column:
DECLARE @read BIGINT,
@write BIGINT
;
SELECT @read = SUM(num_of_bytes_read),
@write = SUM(num_of_bytes_written)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
SET STATISTICS IO ON
;
SELECT TOP (150)
TM.
id,
TM.padding
FROM dbo.TestMAX AS TM
ORDER BY
NEWID()
OPTION (MAXDOP 1)
;
SET STATISTICS IO OFF
;
SELECT tempdb_read_MB = (SUM(num_of_bytes_read) - @read) / 1024. / 1024.,
tempdb_write_MB = (SUM(num_of_bytes_written) - @write) / 1024. / 1024.,
internal_use_MB =
(
SELECT internal_objects_alloc_page_count / 128.0
FROM sys.dm_db_task_space_usage
WHERE session_id = @@SPID
)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
This time the query takes around 8 seconds to complete (3 seconds longer than Test 1). Notice that the estimated row and data sizes are very slightly larger, and the overall memory grant has also increased very slightly to 245MB. The most marked difference is in the amount of tempdb space used – this query wrote almost 391MB of sort run data to the physical tempdb file. Don’t draw any general conclusions about VARCHAR(MAX) versus CHAR from this – I chose the length of the data specifically to expose this edge case. In most cases, VARCHAR(MAX) performs very similarly to CHAR – I just wanted to make test 2 a bit more exciting.
MAX Performance Summary:
8 seconds elapsed time
245MB memory grant
391MB tempdb usage
193MB estimated sort set
25,043 logical reads
Sort warning
Test 3 – TEXT
The same test again, but using the deprecated TEXT data type for the padding column:
DECLARE @read BIGINT,
@write BIGINT
;
SELECT @read = SUM(num_of_bytes_read),
@write = SUM(num_of_bytes_written)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
SET STATISTICS IO ON
;
SELECT TOP (150)
TT.
id,
TT.padding
FROM dbo.TestTEXT AS TT
ORDER BY
NEWID()
OPTION (MAXDOP 1, RECOMPILE)
;
SET STATISTICS IO OFF
;
SELECT tempdb_read_MB = (SUM(num_of_bytes_read) - @read) / 1024. / 1024.,
tempdb_write_MB = (SUM(num_of_bytes_written) - @write) / 1024. / 1024.,
internal_use_MB =
(
SELECT internal_objects_alloc_page_count / 128.0
FROM sys.dm_db_task_space_usage
WHERE session_id = @@SPID
)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
This time the query runs in 500ms. If you look at the metrics we have been checking so far, it’s not hard to understand why:
TEXT Performance Summary:
0.5 seconds elapsed time
9MB memory grant
5MB tempdb usage
5MB estimated sort set
207 logical reads
596 LOB logical reads
Sort warning
SQL Server’s memory grant algorithm still underestimates the memory needed to perform the sorting operation, but the size of the data to sort is so much smaller (5MB versus 193MB previously) that the spilled sort doesn’t matter very much. Why is the data size so much smaller? The query still produces the correct results – including the large amount of data held in the padding column – so what magic is being performed here?
TEXT versus MAX Storage
The answer lies in how columns of the TEXT data type are stored. By default, TEXT data is stored off-row in separate LOB pages – which explains why this is the first query we have seen that records LOB logical reads in its STATISTICS IO output. You may recall from my last post that LOB data leaves an in-row pointer to the separate storage structure holding the LOB data.
SQL Server can see that the full LOB value is not required by the query plan until results are returned, so instead of passing the full LOB value down the plan from the Clustered Index Scan, it passes the small in-row structure instead. SQL Server estimates that each row coming from the scan will be 79 bytes long – 11 bytes for row overhead, 4 bytes for the integer
id column, and 64 bytes for the LOB pointer (in fact the pointer is rather smaller – usually 16 bytes – but the details of that don’t really matter right now).
OK, so this query is much more efficient because it is sorting a very much smaller data set – SQL Server delays retrieving the LOB data itself until after the Sort starts producing its 150 rows. The question that normally arises at this point is: Why doesn’t SQL Server use the same trick when the padding column is defined as VARCHAR(MAX)?
The answer is connected with the fact that if the actual size of the VARCHAR(MAX) data is 8000 bytes or less, it is usually stored in-row in exactly the same way as for a VARCHAR(8000) column – MAX data only moves off-row into LOB storage when it exceeds 8000 bytes. The default behaviour of the TEXT type is to be stored off-row by default, unless the ‘text in row’ table option is set suitably and there is room on the page. There is an analogous (but opposite) setting to control the storage of MAX data – the ‘large value types out of row’ table option. By enabling this option for a table, MAX data will be stored off-row (in a LOB structure) instead of in-row. SQL Server Books Online has good coverage of both options in the topic In Row Data.
The MAXOOR Table
The essential difference, then, is that MAX defaults to in-row storage, and TEXT defaults to off-row (LOB) storage. You might be thinking that we could get the same benefits seen for the TEXT data type by storing the VARCHAR(MAX) values off row – so let’s look at that option now. This script creates a fourth table, with the VARCHAR(MAX) data stored off-row in LOB pages:
CREATE TABLE dbo.TestMAXOOR
(
id INTEGER IDENTITY (1,1) NOT NULL,
padding VARCHAR(MAX) NOT NULL,
CONSTRAINT [PK dbo.TestMAXOOR (id)]
PRIMARY KEY CLUSTERED (id),
)
;
EXECUTE sys.sp_tableoption
@TableNamePattern = N'dbo.TestMAXOOR',
@OptionName = 'large value types out of row',
@OptionValue = 'true'
;
SELECT large_value_types_out_of_row
FROM sys.tables
WHERE [schema_id] = SCHEMA_ID(N'dbo')
AND name = N'TestMAXOOR'
;
INSERT INTO dbo.TestMAXOOR
WITH (TABLOCKX)
(
padding
)
SELECT SPACE(0)
FROM dbo.TestCHAR
ORDER BY
id
;
UPDATE TM
WITH (TABLOCK)
SET padding.WRITE (TC.padding, NULL, NULL)
FROM dbo.TestMAXOOR AS TM
JOIN dbo.TestCHAR AS TC
ON TC.
id = TM.
id
;
EXECUTE sys.sp_spaceused @objname = 'dbo.TestMAXOOR'
;
CHECKPOINT
;
Test 4 – MAXOOR
We can now re-run our test on the MAXOOR (MAX out of row) table:
DECLARE @read BIGINT,
@write BIGINT
;
SELECT @read = SUM(num_of_bytes_read),
@write = SUM(num_of_bytes_written)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
SET STATISTICS IO ON
;
SELECT TOP (150)
MO.
id,
MO.padding
FROM dbo.TestMAXOOR AS MO
ORDER BY
NEWID()
OPTION (MAXDOP 1, RECOMPILE)
;
SET STATISTICS IO OFF
;
SELECT tempdb_read_MB = (SUM(num_of_bytes_read) - @read) / 1024. / 1024.,
tempdb_write_MB = (SUM(num_of_bytes_written) - @write) / 1024. / 1024.,
internal_use_MB =
(
SELECT internal_objects_alloc_page_count / 128.0
FROM sys.dm_db_task_space_usage
WHERE session_id = @@SPID
)
FROM tempdb.sys.database_files AS DBF
JOIN sys.dm_io_virtual_file_stats(2, NULL) AS FS
ON FS.file_id = DBF.file_id
WHERE DBF.type_desc = 'ROWS'
;
TEXT Performance Summary:
0.3 seconds elapsed time
245MB memory grant
0MB tempdb usage
193MB estimated sort set
207 logical reads
446 LOB logical reads
No sort warning
The query runs very quickly – slightly faster than Test 3, and without spilling the sort to tempdb (there is no sort warning in the trace, and the monitoring query shows zero tempdb usage by this query). SQL Server is passing the in-row pointer structure down the plan and only looking up the LOB value on the output side of the sort.
The Hidden Problem
There is still a huge problem with this query though – it requires a 245MB memory grant. No wonder the sort doesn’t spill to tempdb now – 245MB is about 20 times more memory than this query actually requires to sort 50,000 records containing LOB data pointers. Notice that the estimated row and data sizes in the plan are the same as in test 2 (where the MAX data was stored in-row).
The optimizer assumes that MAX data is stored in-row, regardless of the sp_tableoption setting ‘large value types out of row’. Why? Because this option is dynamic – changing it does not immediately force all MAX data in the table in-row or off-row, only when data is added or actually changed. SQL Server does not keep statistics to show how much MAX or TEXT data is currently in-row, and how much is stored in LOB pages. This is an annoying limitation, and one which I hope will be addressed in a future version of the
product.
So why should we worry about this? Excessive memory grants reduce concurrency and may result in queries waiting on the RESOURCE_SEMAPHORE wait type while they wait for memory they do not need. 245MB is an awful lot of memory, especially on 32-bit versions where memory grants cannot use AWE-mapped memory. Even on a 64-bit server with plenty of memory, do you really want a single query to consume 0.25GB of memory unnecessarily? That’s 32,000 8KB pages that might be put to much better use.
The Solution
The answer is not to use the TEXT data type for the padding column. That solution happens to have better performance characteristics for this specific query, but it still results in a spilled sort, and it is hard to recommend the use of a data type which is scheduled for removal. I hope it is clear to you that the fundamental problem here is that SQL Server sorts the whole set arriving at a Sort operator. Clearly, it is not efficient to sort the whole table in memory just to return 150 rows in a random order.
The TEXT example was more efficient because it dramatically reduced the size of the set that needed to be sorted. We can do the same thing by selecting 150 unique keys from the table at random (sorting by NEWID() for example) and only then retrieving the large padding column values for just the 150 rows we need. The following script implements that idea for all four tables:
SET STATISTICS IO ON
;
WITH TestTable
AS (
SELECT *
FROM dbo.TestCHAR
),
TopKeys
AS (
SELECT TOP (150)
id
FROM TestTable
ORDER BY
NEWID()
)
SELECT T1.
id, T1.padding
FROM TestTable AS T1
WHERE T1.
id = ANY (SELECT
id FROM TopKeys)
OPTION (MAXDOP 1)
;
WITH TestTable
AS (
SELECT *
FROM dbo.TestMAX
),
TopKeys
AS (
SELECT TOP (150)
id
FROM TestTable
ORDER BY
NEWID()
)
SELECT T1.
id, T1.padding
FROM TestTable AS T1
WHERE T1.
id IN (SELECT
id FROM TopKeys)
OPTION (MAXDOP 1)
;
WITH TestTable
AS (
SELECT *
FROM dbo.TestTEXT
),
TopKeys
AS (
SELECT TOP (150)
id
FROM TestTable
ORDER BY
NEWID()
)
SELECT T1.
id, T1.padding
FROM TestTable AS T1
WHERE T1.
id IN (SELECT
id FROM TopKeys)
OPTION (MAXDOP 1)
;
WITH TestTable
AS (
SELECT *
FROM dbo.TestMAXOOR
),
TopKeys
AS (
SELECT TOP (150)
id
FROM TestTable
ORDER BY
NEWID()
)
SELECT T1.
id, T1.padding
FROM TestTable AS T1
WHERE T1.
id IN (SELECT
id FROM TopKeys)
OPTION (MAXDOP 1)
;
SET STATISTICS IO OFF
;
All four queries now return results in much less than a second, with memory grants between 6 and 12MB, and without spilling to tempdb. The small remaining inefficiency is in reading the
id column values from the clustered primary key index. As a clustered index, it contains all the in-row data at its leaf. The CHAR and VARCHAR(MAX) tables store the padding column in-row, so
id values are separated by a 3999-character column, plus row overhead. The TEXT and MAXOOR tables store the padding values off-row, so
id values in the clustered index leaf are separated by the much-smaller off-row pointer structure. This difference is reflected in the number of logical page reads performed by the four queries:
Table 'TestCHAR' logical reads 25511 lob logical reads 000
Table 'TestMAX'. logical reads 25511 lob logical reads 000
Table 'TestTEXT' logical reads 00412 lob logical reads 597
Table 'TestMAXOOR' logical reads 00413 lob logical reads 446
We can increase the density of the
id values by creating a separate nonclustered index on the
id column only. This is the same key as the clustered index, of course, but the nonclustered index will not include the rest of the in-row column data.
CREATE UNIQUE NONCLUSTERED INDEX uq1 ON dbo.TestCHAR (id);
CREATE UNIQUE NONCLUSTERED INDEX uq1 ON dbo.TestMAX (id);
CREATE UNIQUE NONCLUSTERED INDEX uq1 ON dbo.TestTEXT (id);
CREATE UNIQUE NONCLUSTERED INDEX uq1 ON dbo.TestMAXOOR (id);
The four queries can now use the very dense nonclustered index to quickly scan the
id values, sort them by NEWID(), select the 150 ids we want, and then look up the padding data. The logical reads with the new indexes in place are:
Table 'TestCHAR' logical reads 835 lob logical reads 0
Table 'TestMAX' logical reads 835 lob logical reads 0
Table 'TestTEXT' logical reads 686 lob logical reads 597
Table 'TestMAXOOR' logical reads 686 lob logical reads 448
With the new index, all four queries use the same query plan (click to enlarge):
Performance Summary:
0.3 seconds elapsed time
6MB memory grant
0MB tempdb usage
1MB sort set
835 logical reads (CHAR, MAX)
686 logical reads (TEXT, MAXOOR)
597 LOB logical reads (TEXT)
448 LOB logical reads (MAXOOR)
No sort warning
I’ll leave it as an exercise for the reader to work out why trying to eliminate the Key Lookup by adding the padding column to the new nonclustered indexes would be a daft idea
Conclusion
This post is not about tuning queries that access columns containing big strings. It isn’t about the internal differences between TEXT and MAX data types either. It isn’t even about the cool use of UPDATE .WRITE used in the MAXOOR table load. No, this post is about something else:
Many developers might not have tuned our starting example query at all – 5 seconds isn’t that bad, and the original query plan looks reasonable at first glance. Perhaps the NEWID() function would have been blamed for ‘just being slow’ – who knows. 5 seconds isn’t awful – unless your users expect sub-second responses – but using 250MB of memory and writing 200MB to tempdb certainly is! If ten sessions ran that query at the same time in production that’s 2.5GB of memory usage and 2GB hitting tempdb. Of course, not all queries can be rewritten to avoid large memory grants and sort spills using the key-lookup technique in this post, but that’s not the point either.
The point of this post is that a basic understanding of execution plans is not enough. Tuning for logical reads and adding covering indexes is not enough. If you want to produce high-quality, scalable TSQL that won’t get you paged as soon as it hits production, you need a deep understanding of execution plans, and as much accurate, deep knowledge about SQL Server as you can lay your hands on. The advanced database developer has a wide range of tools to use in writing queries that perform well in a range of circumstances.
By the way, the examples in this post were written for SQL Server 2008. They will run on 2005 and demonstrate the same principles, but you won’t get the same figures I did because 2005 had a rather nasty bug in the Top N Sort operator. Fair warning: if you do decide to run the scripts on a 2005 instance (particularly the parallel query) do it before you head out for lunch…
This post is dedicated to the people of Christchurch, New Zealand.
© 2011 Paul White
email: @
[email protected]
twitter: @SQL_Kiwi