Muokkaa

Jaa


Configure distributed transactions for an Always On availability group

Applies to: SQL Server

SQL Server 2017 (14.x) and later versions support all distributed transactions including databases in an availability group. This article explains how to configure an availability group for distributed transactions

In order to guarantee distributed transactions, the availability group must be configured to register databases as distributed transaction resource managers.

Note

SQL Server 2016 (13.x) Service Pack 2 and later versions provide full support for distributed transactions in availability groups. In SQL Server 2016 (13.x) Service Pack 1 and earlier versions, cross-database distributed transactions (that is, transaction using databases on the same SQL Server instance) involving a database in an availability group aren't supported. SQL Server 2017 (14.x) doesn't have this limitation.

In SQL Server 2016 (13.x), the configuration steps are the same as in SQL Server 2017 (14.x).

In a distributed transaction, client applications work with Microsoft Distributed Transaction Coordinator (MSDTC or DTC) to guarantee transactional consistency across multiple data sources. DTC is a service available on supported Windows Server-based operating systems. For a distributed transaction, DTC is the transaction coordinator. Normally, a SQL Server instance is the resource manager. When a database is in an availability group, each database needs to be its own resource manager.

SQL Server doesn't prevent distributed transactions for databases in an availability group - even when the availability group isn't configured for distributed transactions. However when an availability group isn't configured for distributed transactions, failover might not succeed in some situations. Specifically the new primary replica SQL Server instance might not be able to get the transaction outcome from DTC. To enable the SQL Server instance to get the outcome of in-doubt transactions from the DTC after failover, configure the availability group for distributed transactions.

DTC isn't involved in availability group processing unless a database is also a member of a Failover Cluster. Within an availability group, the consistency between replicas is maintained by the availability group logic: The primary doesn't complete the commit and acknowledge the commit to the caller until the secondary acknowledges that it persisted the log records in durable storage. Only then the primary declares the transaction complete. In async mode, we don't wait for the secondary to ack, and there's explicitly the chance of the loss of a small amount of data.

Prerequisites

Before you configure an availability group to support distributed transactions, you must meet the following prerequisites:

  • All instances of SQL Server that participate in the distributed transaction must be SQL Server 2016 (13.x) or later versions.

  • Availability groups must be running on Windows Server 2012 R2 or later versions. For Windows Server 2012 R2, you must install the update in KB3090973.

Create an availability group for distributed transactions

Configure an availability group to support distributed transactions. Set the availability group to allow each database to register as a resource manager. This article explains how to configure an availability group so that each database can be a resource manager in DTC.

You can create an availability group for distributed transactions on SQL Server 2016 (13.x) or later versions. To create an availability group for distributed transactions, include DTC_SUPPORT = PER_DB in the availability group definition. The following script creates an availability group for distributed transactions.

CREATE AVAILABILITY
GROUP MyAG
WITH (DTC_SUPPORT = PER_DB)
FOR DATABASE DB1,
    DB2 REPLICA
ON 'Server1' WITH (
   ENDPOINT_URL = 'TCP://SERVER1.corp.com:5022',
   AVAILABILITY_MODE = SYNCHRONOUS_COMMIT,
   FAILOVER_MODE = AUTOMATIC
),
'Server2' WITH (
   ENDPOINT_URL = 'TCP://SERVER2.corp.com:5022',
   AVAILABILITY_MODE = SYNCHRONOUS_COMMIT,
   FAILOVER_MODE = AUTOMATIC
);

Note

The preceding script is a simple example of an availability group and isn't designed for any specific production environment.

Alter an availability group for distributed transactions

You can alter an availability group for distributed transactions on SQL Server 2017 (14.x) or later versions. To alter an availability group for distributed transactions, include DTC_SUPPORT = PER_DB in the ALTER AVAILABILITY GROUP script. The example script changes the availability group to support distributed transactions.

ALTER AVAILABILITY GROUP MyaAG
SET (DTC_SUPPORT = PER_DB);

Note

In SQL Server 2016 (13.x) Service Pack 2 and later versions, you can alter an availability group for distributed transactions. For SQL Server 2016 (13.x) versions before Service Pack 2, you need to drop, and recreate the availability group with the DTC_SUPPORT = PER_DB setting.

To disable distributed transactions, use the following Transact-SQL command:

ALTER AVAILABILITY GROUP MyaAG
SET (DTC_SUPPORT = NONE);

Distributed transactions - technical concepts

A distributed transaction spans two or more databases. As the transaction manager, DTC coordinates the transaction between SQL Server instances, and other data sources. Each instance of the SQL Server database engine can operate as a resource manager. When an availability group is configured with DTC_SUPPORT = PER_DB, the databases can operate as resource managers. For more information, see the MSDTC documentation.

A transaction with two or more databases in a single instance of the database engine is actually a distributed transaction. The instance manages the distributed transaction internally; to the user, it operates as a local transaction. SQL Server 2017 (14.x) promotes all cross-database transactions to DTC when databases are in an availability group configured with DTC_SUPPORT = PER_DB - even within a single instance of SQL Server.

At the application, a distributed transaction is managed much the same as a local transaction. At the end of the transaction, the application requests the transaction to be either committed or rolled back. The transaction manager must manage a distributed commit differently, to minimize the risk that a network failure can result in some resource managers successfully committing, while others roll back the transaction. This is achieved by managing the commit process in two phases (the prepare phase and the commit phase), which is known as a two-phase commit.

  • Prepare phase

    When the transaction manager receives a commit request, it sends a prepare command to all of the resource managers involved in the transaction. Each resource manager then does everything required to make the transaction durable, and all buffers holding log images for the transaction are flushed to disk. As each resource manager completes the prepare phase, it returns success or failure of the prepare phase to the transaction manager.

  • Commit phase

    If the transaction manager receives successful prepares from all of the resource managers, it sends commit commands to each resource manager. The resource managers can then complete the commit. If all of the resource managers report a successful commit, the transaction manager then sends a success notification to the application. If any resource manager reported a failure to prepare, the transaction manager sends a rollback command to each resource manager and indicates the failure of the commit to the application.

Detailed steps

The following list explains how the application works with DTC to complete distributed transactions.

  1. The SQL Server instance enlists in the DTC transaction. This can happen when there's more than one resource manager in the transaction or if the client requests a transaction be promoted to DTC transaction.
  2. The client does some work in the SQL Server instance under the DTC transaction.
  3. The client issues commit or abort for the DTC transaction.
    • If the client issues abort, the transaction is aborted immediately.
    • If the client issues commit, DTC begins the two-phase commit protocol by asking all the resource managers in the transaction to prepare the transaction.
  4. DTC informs all resource managers to commit the transaction after all resource managers successfully acknowledge the prepare phase. If anything prevents successful acknowledgment, DTC aborts the transaction.

Effects of configuring an availability group for distributed transactions

Each entity participating in a distributed transaction is called a resource manager. Examples of resource managers include:

  • A SQL Server instance.
  • A database in an availability group that is configured for distributed transactions.
  • DTC service - can also be a transaction manager.
  • Other data sources.

In order to participate in distributed transactions, an instance of SQL Server enlists with a DTC. Normally the instance of SQL Server enlists with DTC on the local server. Each instance of SQL Server creates a resource manager with a unique resource manager identifier (RMID) and registers it with DTC. In the default configuration, all databases on an instance of SQL Server use the same RMID.

When a database is in an availability group, the read-write copy of the database - or primary replica - might move to a different instance of SQL Server. To support distributed transactions during this movement, each database should act as a separate resource manager and must have a unique RMID. When an availability group has DTC_SUPPORT = PER_DB, SQL Server creates a resource manager for each database and registers with DTC using a unique RMID. In this configuration, the database is a resource manager for DTC transactions.

Important

The DTC has a limit of 32 enlistments per distributed transaction. Because each database within an availability group enlists with the DTC separately, if your transaction involves more than 32 databases, you might get the following error when SQL Server attempts to enlist the 33rd database:

Enlist operation failed: 0x8004d101(XACT_E_TOOMANY_ENLISTMENTS). SQL Server couldn't register with Microsoft Distributed Transaction Coordinator (MSDTC) as a resource manager for this transaction. The transaction might have been stopped by the client or the resource manager.

For more detail on distributed transactions in SQL Server, see Distributed transactions

Manage unresolved transactions

The outcome for the active transactions that exists during RMID change can't be recovered after a failover. This is because the RMID SQL Server used to enlist and RMID SQL Server used to recover are different. The RMID change can happen in following cases:

  • Change DTC_SUPPORT for an availability group.
  • Add or remove a database from an availability group.
  • Drop an availability group.

In the preceding cases, if the primary replica fails over to a new instance of SQL Server, the instance tries to contact DTC to identify the transaction result. DTC can't return the outcome because the RMID that the database is using to get the outcome for in-doubt transactions during recovery wasn't enlisted before. Therefore the database goes into SUSPECT state.

The new SQL Server error log has an entry like the following example:

Microsoft Distributed Transaction Coordinator (MSDTC)
failed to reenlist citing that the database RMID does
not match the RMID [xxxxxxxx-xxxx-xxxx-xxxx-xxxxxxxxxxxx]
associated with the transaction.  Please manually resolve
the transaction.

SQL Server detected a DTC/KTM in-doubt transaction with UOW
{yyyyyyyy-yyyy-yyyy-yyyy-yyyyyyyyyyyy}.Please resolve it
following the guideline for Troubleshooting DTC Transactions.

The preceding example shows that DTC couldn't re-enlist the database from the new primary replica in the transaction that was created after failover. The SQL Server instance can't determine the result of the distributed transaction so it marks the database as suspect. The transaction is marked as a unit of work (UOW) and referred to by a GUID. In order to recover the database, either commit or rollback the transaction manually.

Warning

When you manually commit or rollback a transaction it can affect an application. Verify that the action of commit or rollback is consistent with your application requirements.

Run only one of the following scripts:

  • To commit the transaction, update and run the following script - replace the yyyyyyyy-yyyy-yyyy-yyyy-yyyyyyyyyyyy with the in-doubt transaction UOW from the previous error message, and run:

    KILL 'yyyyyyyy-yyyy-yyyy-yyyy-yyyyyyyyyyyy' WITH COMMIT;
    
  • To roll back the transaction, update and run the following script - replace the yyyyyyyy-yyyy-yyyy-yyyy-yyyyyyyyyyyy with the in-doubt transaction UOW from the previous error message, and run:

    KILL 'yyyyyyyy-yyyy-yyyy-yyyy-yyyyyyyyyyyy' WITH ROLLBACK;
    

After you commit or roll back the transaction, you can use ALTER DATABASE to set the database online. Update and run the following script - set the database name for the name of the suspect database:

ALTER DATABASE [DB1] SET ONLINE;

For more information about resolving in-doubt transactions, see Resolve Transactions Manually.