Sunday 6 November 2016

Data Guard Physical Standby Setup in Oracle Database 11g Release 2

How a Data Guard Physical Standby Setup in Oracle Database 11g Release 2
Data Guard is the name for Oracle's standby database solution, used for disaster recovery and high availability.

Architecture
The Oracle Data Guard architecture incorporates the following items:

Primary Database - A production database that is used to create standby databases. The archive logs from the primary database are transfered and applied to standby databases. Each standby can only be associated with a single primary database, but a single primary database can be associated with multiple standby databases.

Standby Database - A replica of the primary database.

Log Transport Services - Control the automatic transfer of archive redo log files from the primary database to one or more standby destinations.

Network Configuration - The primary database is connected to one or more standby databases using Oracle Net.

Log Apply Services - Apply the archived redo logs to the standby database. The Managed Recovery Process (MRP) actually does the work of maintaining and applying the archived redo logs.

Role Management Services - Control the changing of database roles from primary to standby. The services include switch-over, switchback and fail-over.

Data Guard Broker - Controls the creation and monitoring of Data Guard. It comes with a GUI and command line interface.

The services required on the primary database are:

Log Writer Process (LGWR) - Collects redo information and updates the online redo logs. It can also create local archived redo logs and transmit online redo to standby databases.

Archiver Process (ARCn) - One or more archiver processes make copies of online redo logs either locally or remotely for standby databases.

Fetch Archive Log (FAL) Server - Services requests for archive redo logs from FAL clients running on multiple standby databases. Multiple FAL servers can be run on a primary database, one for each FAL request. .

The services required on the standby database are:

Fetch Archive Log (FAL) Client - Pulls archived redo log files from the primary site. Initiates transfer of archived redo logs when it detects a gap sequence.

Remote File Server (RFS) - Receives archived and/or standby redo logs from the primary database.

Archiver (ARCn) Processes - Archives the standby redo logs applied by the managed recovery process (MRP).

Managed Recovery Process (MRP) - Applies archive redo log information to the standby database.
Database Synchronization Options

Data Guard can be configured to run with varying synchronization modes indicating the potential for data loss.

No-Data-Loss mode : This simply means that the log transport services will not acknowledge modifications to the primary database until they are available to the standby database. This doesn't mean that the modifications have been applied to the standby database, merely that the log information is available to the log apply services should fail over occur. This mode is implemented using standby redo logs on the standby server.

No-Data-Divergence mode : This is an extension of the no-data-loss mode whereby modifications to the primary database are prevented if connectivity between the primary and at least one standby database is unavailable.

Minimal-Data-Loss mode : When the performance requirements of the primary database are the top priority this mode provides the optimum balance of data protection and performance.

Primary Server Setup
Logging
Check that the primary database is in archivelog mode.

SQL>> SELECT log_mode FROM v$database;
LOG_MODE
------------
NOARCHIVELOG

If it is noarchivelog mode, switch is to archivelog mode.

SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP MOUNT;
SQL>> ALTER DATABASE ARCHIVELOG;
SQL>> ALTER DATABASE OPEN;

Enabled forced logging by issuing the following command.

SQL>> ALTER DATABASE FORCE LOGGING;

Initialization Parameters
Check the setting for the DB_NAME and DB_UNIQUE_NAME parameters. In this case they are both set to "DB11G" on the primary database.

SQL>> show parameter db_name
NAME     TYPE VALUE
------------------------------------ ----------- ------------------------------
db_name     string DB11G

SQL>> show parameter db_unique_name
NAME     TYPE VALUE
------------------------------------ ----------- ------------------------------
db_unique_name     string DB11G

The DB_NAME of the standby database will be the same as that of the primary, but it must have a different DB_UNIQUE_NAME value. 

The DB_UNIQUE_NAME values of the primary and standby database should be used in the DG_CONFIG setting of the LOG_ARCHIVE_CONFIG parameter. 

For this example, the standby database will have the value "DB11G_STBY".

SQL>> ALTER SYSTEM SET LOG_ARCHIVE_CONFIG='DG_CONFIG=(DB11G,DB11G_STBY)';

Set suitable remote archive log destinations. In this case I'm using the fast recovery area for the local location, but you could specify an location explicitly if you prefer. 

Notice the SERVICE and the DB_UNIQUE_NAME for the remote location reference the standby location.

SQL>> ALTER SYSTEM SET LOG_ARCHIVE_DEST_2='SERVICE=db11g_stby NOAFFIRM ASYNC VALID_FOR=(ONLINE_LOGFILES,PRIMARY_ROLE) DB_UNIQUE_NAME=DB11G_STBY';

SQL>> ALTER SYSTEM SET LOG_ARCHIVE_DEST_STATE_2=ENABLE;

The LOG_ARCHIVE_FORMAT and LOG_ARCHIVE_MAX_PROCESSES parameters must be set to appropriate values and the REMOTE_LOGIN_PASSWORDFILE must be set to exclusive.

SQL>> ALTER SYSTEM SET LOG_ARCHIVE_FORMAT='%t_%s_%r.arc' SCOPE=SPFILE;
SQL>> ALTER SYSTEM SET LOG_ARCHIVE_MAX_PROCESSES=30;
SQL>> ALTER SYSTEM SET REMOTE_LOGIN_PASSWORDFILE=EXCLUSIVE SCOPE=SPFILE;

In addition to the previous setting, it is recommended to make sure the primary is ready to switch roles to become a standby. For that to work properly we need to set the following parameters. Adjust the *_CONVERT parameters to account for your filename and path differences between the servers.

SQL>> ALTER SYSTEM SET FAL_SERVER=DB11G_STBY;

--ALTER SYSTEM SET DB_FILE_NAME_CONVERT='DB11G_STBY','DB11G' SCOPE=SPFILE;

--ALTER SYSTEM SET LOG_FILE_NAME_CONVERT='DB11G_STBY','DB11G'  SCOPE=SPFILE;

SQL>> ALTER SYSTEM SET STANDBY_FILE_MANAGEMENT=AUTO;

Remember, some of the parameters are not modifiable, so the database will need to be restarted before they take effect.

Service Setup
Entries for the primary and standby databases are needed in the "$ORACLE_HOME/network/admin/tnsnames.ora" files on both servers. You can create these using the Network Configuration Utility (netca) or manually. The following entries were used during this setup.

DB11G =
  (DESCRIPTION =
    (ADDRESS_LIST =
      (ADDRESS = (PROTOCOL = TCP)(HOST = ol5-112-dga1)(PORT = 1521))
    )
    (CONNECT_DATA =
      (SERVICE_NAME = DB11G.WORLD)
    )
  )

DB11G_STBY =
  (DESCRIPTION =
    (ADDRESS_LIST =
      (ADDRESS = (PROTOCOL = TCP)(HOST = ol5-112-dga2)(PORT = 1521))
    )
    (CONNECT_DATA =
      (SERVICE_NAME = DB11G.WORLD)
    )
  )

Backup Primary Database

If you are planning to use an active duplicate to create the standby database, then this step is unnecessary. For a backup-based duplicate, or a manual restore, take a backup of the primary database.

$ rman target /

RMAN> BACKUP DATABASE PLUS ARCHIVELOG;
Create Standby Controlfile and PFILE

Create a controlfile for the standby database by issuing the following command on the primary database.

SQL>> ALTER DATABASE CREATE STANDBY CONTROLFILE AS '/tmp/db11g_stby.ctl';

Create a parameter file for the standby database.

SQL>> CREATE PFILE='/tmp/initDB11G_stby.ora' FROM SPFILE;

Amend the PFILE making the entries relevant for the standby database. I'm making a replica of the original server, so in my case I only had to amend the following parameters.

*.db_unique_name='DB11G_STBY'
*.fal_server='DB11G'
*.log_archive_dest_2='SERVICE=db11g ASYNC VALID_FOR=(ONLINE_LOGFILES,PRIMARY_ROLE) DB_UNIQUE_NAME=DB11G'

Standby Server Setup (Manual)

Copy Files
Create the necessary directories on the standby server.

$ mkdir -p /u01/app/oracle/oradata/DB11G
$ mkdir -p /u01/app/oracle/fast_recovery_area/DB11G
$ mkdir -p /u01/app/oracle/admin/DB11G/adump

Copy the files from the primary to the standby server.

$ # Standby controlfile to all locations.
$ scp oracle@ol5-112-dga1:/tmp/db11g_stby.ctl /u01/app/oracle/oradata/DB11G/control01.ctl
$ cp /u01/app/oracle/oradata/DB11G/control01.ctl /u01/app/oracle/fast_recovery_area/DB11G/control02.ctl

$ # Archivelogs and backups
$ scp -r oracle@ol5-112-dga1:/u01/app/oracle/fast_recovery_area/DB11G/archivelog /u01/app/oracle/fast_recovery_area/DB11G
$ scp -r oracle@ol5-112-dga1:/u01/app/oracle/fast_recovery_area/DB11G/backupset /u01/app/oracle/fast_recovery_area/DB11G

$ # Parameter file.
$ scp oracle@ol5-112-dga1:/tmp/initDB11G_stby.ora /tmp/initDB11G_stby.ora

$ # Remote login password file.
$ scp oracle@ol5-112-dga1:$ORACLE_HOME/dbs/orapwDB11G $ORACLE_HOME/dbs

Notice, the backups were copied across to the standby server as part of the FRA copy. 
If your backups are not held within the FRA, you must make sure you copy them to the standby server and make them available from the same path as used on the primary server.

Start Listener

Make sure the listener is started on the standby server.

$ lsnrctl start

Restore Backup

Create the SPFILE form the amended PFILE.

$ export ORACLE_SID=DB11G
$ sqlplus / as sysdba

SQL> CREATE SPFILE FROM PFILE='/tmp/initDB11G_stby.ora';

Restore the backup files.

$ export ORACLE_SID=DB11G
$ rman target /

RMAN> STARTUP MOUNT;
RMAN> RESTORE DATABASE;

Create Redo Logs

Create online redo logs for the standby. It's a good idea to match the configuration of the primary server.

SQL>> ALTER SYSTEM SET STANDBY_FILE_MANAGEMENT=MANUAL;

SQL>> ALTER DATABASE ADD LOGFILE ('/u01/app/oracle/oradata/DB11G/online_redo01.log') SIZE 50M;

SQL>> ALTER DATABASE ADD LOGFILE ('/u01/app/oracle/oradata/DB11G/online_redo02.log') SIZE 50M;

SQL>> ALTER DATABASE ADD LOGFILE ('/u01/app/oracle/oradata/DB11G/online_redo03.log') SIZE 50M;

SQL>> ALTER SYSTEM SET STANDBY_FILE_MANAGEMENT=AUTO;

In addition to the online redo logs, you should create standby redo logs on both the standby and the primary database (in case of switchovers).

The standby redo logs should be at least as big as the largest online redo log and there should be one extra group per thread compared the online redo logs.

In my case, the following standby redo logs must be created on both servers.

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo01.log') SIZE 50M;

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo02.log') SIZE 50M;

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo03.log') SIZE 50M;

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo04.log') SIZE 50M;

Once this is complete, we can start the apply process.

Standby Server Setup (DUPLICATE)

Copy Files
Create the necessary directories on the standby server.

$ mkdir -p /u01/app/oracle/oradata/DB11G
$ mkdir -p /u01/app/oracle/fast_recovery_area/DB11G
$ mkdir -p /u01/app/oracle/admin/DB11G/adump
Copy the files from the primary to the standby server.

$ # Standby controlfile to all locations.
$ scp oracle@ol5-112-dga1:/tmp/db11g_stby.ctl /u01/app/oracle/oradata/DB11G/control01.ctl
$ cp /u01/app/oracle/oradata/DB11G/control01.ctl /u01/app/oracle/fast_recovery_area/DB11G/control02.ctl

$ # Parameter file.
$ scp oracle@ol5-112-dga1:/tmp/initDB11G_stby.ora /tmp/initDB11G_stby.ora

$ # Remote login password file.
$ scp oracle@ol5-112-dga1:$ORACLE_HOME/dbs/orapwDB11G $ORACLE_HOME/dbs

Start Listener

When using active duplicate, the standby server requires static listener configuration in a "listener.ora" file. In this case I used the following configuration.

SID_LIST_LISTENER =
  (SID_LIST =
    (SID_DESC =
      (GLOBAL_DBNAME = DB11G.WORLD)
      (ORACLE_HOME = /u01/app/oracle/product/11.2.0/db_1)
      (SID_NAME = DB11G)
    )
  )

LISTENER =
  (DESCRIPTION_LIST =
    (DESCRIPTION =
      (ADDRESS = (PROTOCOL = TCP)(HOST = ol5-112-dga2.localdomain)(PORT = 1521))
    )
    (DESCRIPTION =
      (ADDRESS = (PROTOCOL = IPC)(KEY = EXTPROC1521))
    )
  )

ADR_BASE_LISTENER = /u01/app/oracle

Make sure the listener is started on the standby server.

$ lsnrctl start

Create Standby Redo Logs on Primary Server

The DUPLICATE command automatically creates the standby redo logs on the standby. To make sure the primary database is configured for switchover, we must create the standby redo logs on the primary server.

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo01.log') SIZE 50M;

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo02.log') SIZE 50M;

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo03.log') SIZE 50M;

SQL>> ALTER DATABASE ADD STANDBY LOGFILE ('/u01/app/oracle/oradata/DB11G/standby_redo04.log') SIZE 50M;

Create Standby Using DUPLICATE

Start the auxillary instance on the standby server by starting it using the temporary "init.ora" file.

$ export ORACLE_SID=DB11G
$ sqlplus / as sysdba

SQL> STARTUP NOMOUNT PFILE='/tmp/initDB11G_stby.ora';

Connect to RMAN, specifying a full connect string for both the TARGET and AUXILLARY instances. DO not attempt to use OS authentication.

$ rman TARGET sys/password@DB11G AUXILIARY sys/password@DB11G_STBY

Now issue the following DUPLICATE command.

DUPLICATE TARGET DATABASE
  FOR STANDBY
  FROM ACTIVE DATABASE
  DORECOVER
  SPFILE
    SET db_unique_name='DB11G_STBY' COMMENT 'Is standby'
    SET LOG_ARCHIVE_DEST_2='SERVICE=db11g ASYNC VALID_FOR=(ONLINE_LOGFILES,PRIMARY_ROLE) DB_UNIQUE_NAME=DB11G'
    SET FAL_SERVER='DB11G' COMMENT 'Is primary'
  NOFILENAMECHECK;

A brief explanation of the individual clauses is shown below.

FOR STANDBY: This tells the DUPLICATE command is to be used for a standby, so it will not force a DBID change.

FROM ACTIVE DATABASE: The DUPLICATE will be created directly from the source datafile, without an additional backup step.

DORECOVER: The DUPLICATE will include the recovery step, bringing the standby up to the current point in time.

SPFILE: Allows us to reset values in the spfile when it is copied from the source server.

NOFILENAMECHECK: Destination file locations are not checked.
Once the command is complete, we can start the apply process.

Start Apply Process

Start the apply process on standby server.

# Foreground redo apply. Session never returns until cancel. 
SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE;

# Background redo apply. Control is returned to the session once the apply process is started.
SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE DISCONNECT FROM SESSION;

If you need to cancel the apply process, issue the following command.

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE CANCEL;

If you prefer, you can set a delay between the arrival of the archived redo log and it being applied on the standby server using the following commands.

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE CANCEL;

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE DELAY 30 DISCONNECT FROM SESSION;

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE CANCEL;

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE NODELAY DISCONNECT FROM SESSION;

Provided you have configured standby redo logs, you can start real-time apply using the following command.

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE USING CURRENT LOGFILE;

Test Log Transport

On the primary server, check the latest archived redo log and force a log switch.

SQL>> ALTER SESSION SET nls_date_format='DD-MON-YYYY HH24:MI:SS';

SQL>> SELECT sequence#, first_time, next_time FROM   v$archived_log ORDER BY sequence#;

SQL>> ALTER SYSTEM SWITCH LOGFILE;

Check the new archived redo log has arrived at the standby server and been applied.

SQL>> ALTER SESSION SET nls_date_format='DD-MON-YYYY HH24:MI:SS';

SQL>> SELECT sequence#, first_time, next_time, applied FROM   v$archived_log ORDER BY sequence#;

Protection Mode
There are three protection modes for the primary database:
Maximum Availability: Transactions on the primary do not commit until redo information has been written to the online redo log and the standby redo logs of at least one standby location. If no standby location is available, it acts in the same manner as maximum performance mode until a standby becomes available again.

Maximum Performance: Transactions on the primary commit as soon as redo information has been written to the online redo log. Transfer of redo information to the standby server is asynchronous, so it does not impact on performance of the primary.

Maximum Protection: Transactions on the primary do not commit until redo information has been written to the online redo log and the standby redo logs of at least one standby location. If not suitable standby location is available, the primary database shuts down.

By default, for a newly created standby database, the primary database is in maximum performance mode.

SQL>> SELECT protection_mode FROM v$database;

PROTECTION_MODE
--------------------
MAXIMUM PERFORMANCE

The mode can be switched using the following commands. Note the alterations in the redo transport attributes.

-- Maximum Availability.
SQL>> ALTER SYSTEM SET LOG_ARCHIVE_DEST_2='SERVICE=db11g_stby AFFIRM SYNC VALID_FOR=(ONLINE_LOGFILES,PRIMARY_ROLE) DB_UNIQUE_NAME=DB11G_STBY';

SQL>> ALTER DATABASE SET STANDBY DATABASE TO MAXIMIZE AVAILABILITY;

-- Maximum Performance.
SQL>> ALTER SYSTEM SET LOG_ARCHIVE_DEST_2='SERVICE=db11g_stby NOAFFIRM ASYNC VALID_FOR=(ONLINE_LOGFILES,PRIMARY_ROLE) DB_UNIQUE_NAME=DB11G_STBY';

SQL>> ALTER DATABASE SET STANDBY DATABASE TO MAXIMIZE PERFORMANCE;

-- Maximum Protection.
SQL>> ALTER SYSTEM SET LOG_ARCHIVE_DEST_2='SERVICE=db11g_stby AFFIRM SYNC VALID_FOR=(ONLINE_LOGFILES,PRIMARY_ROLE) DB_UNIQUE_NAME=DB11G_STBY';

SQL>> SHUTDOWN IMMEDIATE;

SQL>> STARTUP MOUNT;

SQL>> ALTER DATABASE SET STANDBY DATABASE TO MAXIMIZE PROTECTION;

SQL>> ALTER DATABASE OPEN;

Database Switchover

A database can be in one of two mutually exclusive modes (primary or standby). These roles can be altered at runtime without loss of data or resetting of redo logs. 

This process is known as a Switchover and can be performed using the following statements.

-- Convert primary database to standby
SQL>> CONNECT / AS SYSDBA
SQL>> ALTER DATABASE COMMIT TO SWITCHOVER TO STANDBY;

-- Shutdown primary database
SQL>> SHUTDOWN IMMEDIATE;

-- Mount old primary database as standby database
SQL>> STARTUP NOMOUNT;
SQL>> ALTER DATABASE MOUNT STANDBY DATABASE;
SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE DISCONNECT FROM SESSION;

On the original standby database issue the following commands.

-- Convert standby database to primary
SQL>> CONNECT / AS SYSDBA
SQL>> ALTER DATABASE COMMIT TO SWITCHOVER TO PRIMARY;

-- Shutdown standby database
SQL>> SHUTDOWN IMMEDIATE;

-- Open old standby database as primary
SQL>> STARTUP;

Once this is complete, test the log transport as before. If everything is working fine, switch the primary database back to the original server by doing another switchover. This is known as a switchback.

Failover

If the primary database is not available the standby database can be activated as a primary database using the following statements.

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE FINISH;
SQL>> ALTER DATABASE ACTIVATE STANDBY DATABASE;

Since the standby database is now the primary database it should be backed up immediately.

The original primary database can now be configured as a standby. If Flashback Database was enabled on the primary database, then this can be done relatively easily (shown here).
If not, the whole setup process must be followed, but this time using the original primary server as the standby.

Flashback Database
It was already mentioned in the previous section, but it is worth drawing your attention to Flashback Database once more. Although a switchover/switchback is safe for both the primary and standby
database, a failover renders the original primary database useless for converting to a standby database. If flashback database is not enabled, the original primary must be scrapped and recreated as a standby database.

An alternative is to enable flashback database on the primary (and the standby if desired) so in the event of a failover, the primary can be flashed back to the time
before the failover and quickly converted to a standby database. That process is shown here.

Read-Only Standby and Active Data Guard
Once a standby database is configured, it can be opened in read-only mode to allow query access. This is often used to offload reporting to the standby server, thereby freeing up resources
on the primary server. When open in read-only mode, archive log shipping continues, but managed recovery is stopped, so the standby database becomes increasingly out of date until
managed recovery is resumed.

To switch the standby database into read-only mode, do the following.

SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP MOUNT;
SQL>> ALTER DATABASE OPEN READ ONLY;

To resume managed recovery, do the following.

SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP MOUNT;
SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE DISCONNECT FROM SESSION;

In 11g, Oracle introduced the Active Data Guard feature. This allows the standby database to be open in read-only mode, but still apply redo information.

This means a standby can be available for querying, yet still be up to date. There are licensing implications for this feature, but the following commands show how active data guard can be enabled.

SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP MOUNT;
SQL>> ALTER DATABASE OPEN READ ONLY;
SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE DISCONNECT FROM SESSION;

Since managed recovery continues with active data guard, there is no need to switch back to managed recovery from read-only mode in this case.

Snapshot Standby

Introduced in 11g, snapshot standby allows the standby database to be opened in read-write mode. When switched back into standby mode, all changes made whilst in read-write mode are lost.
This is achieved using flashback database, but the standby database does not need to have flashback database explicitly enabled to take advantage of this feature, thought it works just the same if it is.

If you are using RAC, turn off all but one of the RAC instances. Make sure the instance is in MOUNT mode.

SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP MOUNT;

Make sure managed recovery is disabled.

SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE CANCEL;

Convert the standby to a snapshot standby. The following example queries the V$DATABASE view to show that flashback database is not enabled prior to the conversion operation.

SQL>> SELECT flashback_on FROM v$database;

FLASHBACK_ON
------------------
NO

SQL>> ALTER DATABASE CONVERT TO SNAPSHOT STANDBY;
SQL>> ALTER DATABASE OPEN;
SQL>> SELECT flashback_on FROM v$database;

FLASHBACK_ON
------------------
RESTORE POINT ONLY

You can now do treat the standby like any read-write database.

To convert it back to the physical standby, losing all the changes made since the conversion to snapshot standby, issue the following commands.

SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP MOUNT;
SQL>> ALTER DATABASE CONVERT TO PHYSICAL STANDBY;
SQL>> SHUTDOWN IMMEDIATE;
SQL>> STARTUP NOMOUNT;
SQL>> ALTER DATABASE MOUNT STANDBY DATABASE;
SQL>> ALTER DATABASE RECOVER MANAGED STANDBY DATABASE DISCONNECT;
SQL>> SELECT flashback_on FROM v$database;

FLASHBACK_ON
------------------
NO

The standby is once again in managed recovery and archivelog shipping is resumed. Notice that flashback database is still not enabled.


Thanks & Comments Please..................!



1 comment:

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