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Exchange Spill Event Class

The Exchange Spill event class indicates that communication buffers in a parallel query plan have been temporarily written to the tempdb database. This occurs rarely and only when a query plan has multiple range scans.

Normally, the Transact-SQL query that generates such range scans has many BETWEEN operators, each of which selects a range of rows from a table or an index. Alternatively, you can obtain multiple ranges using expressions such as (T.a > 10 AND T.a < 20) OR (T.a > 100 AND T.a < 120). Additionally, the query plans must require that these ranges be scanned in order either because there is an ORDER BY clause on T.a, or because an iterator within the plan requires that it consume the tuples in sorted order.

When a query plan for such a query has multiple Parallelism operators, the memory communication buffers used by the Parallelism operators become full, and a situation can arise whereby the query's execution progress stops. In this situation, one of the Parallelism operators writes its output buffer to tempdb (an operation called an exchange spill) so that it can consume rows from some of its input buffers. Eventually, the spilled rows are returned to the consumer when the consumer is ready to consume them.

Very rarely, multiple exchange spills can occur within the same execution plan, causing the query to execute slowly. If you notice more than five spills within the same query plan's execution, contact your support professional.

Exchange spills are sometimes transient and may disappear as data distribution changes.

There are several ways to avoid exchange spill events:

  • Omit the ORDER BY clause if you do not need the result set to be ordered.

  • If ORDER BY is required, eliminate the column that participates in the multiple range scans (T.a in the example above) from the ORDER BY clause.

  • Using an index hint, force the optimizer to use a different access path on the table in question.

  • Rewrite the query to produce a different query execution plan.

  • Force serial execution of the query by adding the MAXDOP = 1 option to the end of the query or index operation. For more information, see max degree of parallelism Option and Configuring Parallel Index Operations.

Important

To determine where the Exchange Spill event is occurring when the query optimizer generates an execution plan, you should also collect a Showplan event class in the trace. You can choose any of the Showplan event classes except the Showplan Text and Showplan Text (Unencoded) event classes, which do not return a Node ID. Node IDs in Showplans identify each operation the query optimizer performs when it generates a query execution plan. These operations are called operators and each operator in a Showplan has a Node ID. The ObjectID column for Exchange Spill events corresponds to the Node ID in Showplans so you can determine which operator, or operation, is causing the error. For more information about the Showplan event classes, see Displaying Execution Plans by Using SQL Server Profiler Event Classes

Exchange Spill Event Class Data Columns

Data column name

Data type

Description

Column ID

Filterable

ApplicationName

nvarchar

Name of the client application that created the connection to an instance of SQL Server. This column is populated with the values passed by the application rather than the displayed name of the program.

10

Yes

ClientProcessID

int

ID assigned by the host computer to the process where the client application is running. This data column is populated if the client provides the client process ID.

9

Yes

DatabaseID

int

ID of the database specified by the USE database statement or the default database if no USE database statement has been issued for a given instance. SQL Server Profiler displays the name of the database if the ServerName data column is captured in the trace and the server is available. Determine the value for a database by using the DB_ID function.

3

Yes

DatabaseName

nvarchar

Name of the database in which the user statement is running.

35

Yes

EventClass

int

Type of event = 127.

27

No

EventSequence

int

Sequence of a given event within the request.

51

No

EventSubClass

int

Type of event subclass.

1=Spill begin

2=Spill end

21

Yes

GroupID

int

ID of the workload group where the SQL Trace event fires.

66

Yes

HostName

nvarchar

Name of the computer on which the client is running. This data column is populated if the client provides the host name. To determine the host name, use the HOST_NAME function.

8

Yes

IsSystem

int

Indicates whether the event occurred on a system process or a user process. 1 = system, 0 = user.

60

Yes

LoginName

nvarchar

Name of the login of the user (either SQL Server security login or the Windows login credentials in the form of <DOMAIN>\<username>).

11

Yes

LoginSid

image

Security identification number (SID) of the logged-in user. You can find this information in the syslogins table of the master database. Each SID is unique for each login in the server.

41

Yes

NTDomainName

nvarchar

Windows domain to which the user belongs.

7

Yes

NTUserName

nvarchar

Windows user name.

6

Yes

ObjectID

int

System-assigned ID of the object. Corresponds with the Node ID in Showplans.

22

Yes

RequestID

int

ID of the request containing the statement.

49

Yes

ServerName

nvarchar

Name of the instance of SQL Server being traced.

26

No

SessionLoginName

nvarchar

Login name of the user who originated the session. For example, if you connect to SQL Server using Login1 and execute a statement as Login2, SessionLoginName shows Login1 and LoginName shows Login2. This column displays both SQL Server and Windows logins.

64

Yes

SPID

int

ID of the session on which the event occurred.

12

Yes

StartTime

datetime

Time at which the event started, if available.

14

Yes

TransactionID

bigint

System-assigned ID of the transaction.

4

Yes

XactSequence

bigint

Token that describes the current transaction.

50

Yes