Oracle® Database SQL Language Reference 11g Release 2 (11.2) Part Number E26088-03 |
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Use the ALTER
SYSTEM
statement to dynamically alter your Oracle Database instance. The settings stay in effect as long as the database is mounted.
You must have ALTER
SYSTEM
system privilege.
(archive_log_clause ::=, checkpoint_clause::=, check_datafiles_clause::=, distributed_recov_clauses::=, end_session_clauses::=, quiesce_clauses::=, rolling_migration_clauses::=, security_clauses::=, shutdown_dispatcher_clause::=, alter_system_set_clause::=, alter_system_reset_clause::=)
The archive_log_clause
manually archives redo log files or enables or disables automatic archiving. To use this clause, your instance must have the database mounted. The database can be either open or closed unless otherwise noted.
This clause is relevant only if you are using Oracle Real Application Clusters (Oracle RAC). Specify the name of the instance for which you want the redo log file group to be archived. The instance name is a string of up to 80 characters. Oracle Database automatically determines the thread that is mapped to the specified instance and archives the corresponding redo log file group. If no thread is mapped to the specified instance, then Oracle Database returns an error.
Specify SEQUENCE
to manually archive the online redo log file group identified by the log sequence number integer
in the specified thread. If you omit the THREAD
parameter, then Oracle Database archives the specified group from the thread assigned to your instance.
Specify CHANGE
to manually archive the online redo log file group containing the redo log entry with the system change number (SCN) specified by integer
in the specified thread. If the SCN is in the current redo log file group, then Oracle Database performs a log switch. If you omit the THREAD
parameter, then Oracle Database archives the groups containing this SCN from all enabled threads.
You can use this clause only when your instance has the database open.
Specify CURRENT
to manually archive the current redo log file group of the specified thread, forcing a log switch. If you omit the THREAD
parameter, then Oracle Database archives all redo log file groups from all enabled threads, including logs previous to current logs. You can specify CURRENT
only when the database is open.
NOSWITCH Specify NOSWITCH
if you want to manually archive the current redo log file group without forcing a log switch. This setting is used primarily with standby databases to prevent data divergence when the primary database shuts down. Divergence implies the possibility of data loss in case of primary database failure.
You can use the NOSWITCH
clause only when your instance has the database mounted but not open. If the database is open, then this operation closes the database automatically. You must then manually shut down the database before you can reopen it.
Specify GROUP
to manually archive the online redo log file group with the GROUP
value specified by integer
. You can determine the GROUP
value for a redo log file group by querying the dynamic performance view V$LOG
. If you specify both the THREAD
and GROUP
parameters, then the specified redo log file group must be in the specified thread.
Specify LOGFILE
to manually archive the online redo log file group containing the redo log file member identified by 'filename
'. If you specify both the THREAD
and LOGFILE
parameters, then the specified redo log file group must be in the specified thread.
If the database was mounted with a backup control file, then specify USING
BACKUP
CONTROLFILE
to permit archiving of all online logfiles, including the current logfile.
Restriction on the LOGFILE clause You must archive redo log file groups in the order in which they are filled. If you specify a redo log file group for archiving with the LOGFILE
parameter, and earlier redo log file groups are not yet archived, then Oracle Database returns an error.
Specify NEXT
to manually archive the next online redo log file group from the specified thread that is full but has not yet been archived. If you omit the THREAD
parameter, then Oracle Database archives the earliest unarchived redo log file group from any enabled thread.
Specify ALL
to manually archive all online redo log file groups from the specified thread that are full but have not been archived. If you omit the THREAD
parameter, then Oracle Database archives all full unarchived redo log file groups from all enabled threads.
Specify TO
'location
' to indicate the primary location to which the redo log file groups are archived. The value of this parameter must be a fully specified file location following the conventions of your operating system. If you omit this parameter, then Oracle Database archives the redo log file group to the location specified by the initialization parameters LOG_ARCHIVE_DEST
or LOG_ARCHIVE_DEST_
n
.
Specify CHECKPOINT
to explicitly force Oracle Database to perform a checkpoint, ensuring that all changes made by committed transactions are written to data files on disk. You can specify this clause only when your instance has the database open. Oracle Database does not return control to you until the checkpoint is complete.
GLOBAL In an Oracle Real Application Clusters (Oracle RAC) environment, this setting causes Oracle Database to perform a checkpoint for all instances that have opened the database. This is the default.
LOCAL In an Oracle RAC environment, this setting causes Oracle Database to perform a checkpoint only for the thread of redo log file groups for the instance from which you issue the statement.
See Also:
"Forcing a Checkpoint: Example"In a distributed database system, such as an Oracle RAC environment, this clause updates an instance's SGA from the database control file to reflect information on all online data files.
Specify GLOBAL
to perform this synchronization for all instances that have opened the database. This is the default.
Specify LOCAL
to perform this synchronization only for the local instance.
Your instance should have the database open.
The end_session_clauses
give you several ways to end the current session.
Use the DISCONNECT
SESSION
clause to disconnect the current session by destroying the dedicated server process (or virtual circuit if the connection was made by way of a Shared Sever). To use this clause, your instance must have the database open. You must identify the session with both of the following values from the V$SESSION
view:
For integer1
, specify the value of the SID
column.
For integer2
, specify the value of the SERIAL#
column.
If system parameters are appropriately configured, then application failover will take effect.
The POST_TRANSACTION
setting allows ongoing transactions to complete before the session is disconnected. If the session has no ongoing transactions, then this clause has the same effect described for as KILL
SESSION
.
The IMMEDIATE
setting disconnects the session and recovers the entire session state immediately, without waiting for ongoing transactions to complete.
If you also specify POST_TRANSACTION
and the session has ongoing transactions, then the IMMEDIATE
keyword is ignored.
If you do not specify POST_TRANSACTION
, or you specify POST_TRANSACTION
but the session has no ongoing transactions, then this clause has the same effect as described for KILL
SESSION
IMMEDIATE
.
See Also:
"Disconnecting a Session: Example"The KILL
SESSION
clause lets you mark a session as terminated, roll back ongoing transactions, release all session locks, and partially recover session resources. To use this clause, your instance must have the database open. Your session and the session to be terminated must be on the same instance unless you specify integer3
.You must identify the session with the following values from the V$SESSION
view:
For integer1
, specify the value of the SID
column.
For integer2
, specify the value of the SERIAL#
column.
For the optional integer3
, specify the ID of the instance where the target session to be killed exists. You can find the instance ID by querying the GV$ tables.
If the session is performing some activity that must be completed, such as waiting for a reply from a remote database or rolling back a transaction, then Oracle Database waits for this activity to complete, marks the session as terminated, and then returns control to you. If the waiting lasts a minute, then Oracle Database marks the session to be terminated and returns control to you with a message that the session is marked to be terminated. The PMON
background process then marks the session as terminated when the activity is complete.
Whether or not the session has an ongoing transaction, Oracle Database does not recover the entire session state until the session user issues a request to the session and receives a message that the session has been terminated.
See Also:
"Terminating a Session: Example"IMMEDIATE Specify IMMEDIATE
to instruct Oracle Database to roll back ongoing transactions, release all session locks, recover the entire session state, and return control to you immediately.
The DISTRIBUTED
RECOVERY
clause lets you enable or disable distributed recovery. To use this clause, your instance must have the database open.
ENABLE Specify ENABLE
to enable distributed recovery. In a single-process environment, you must use this clause to initiate distributed recovery.
You may need to issue the ENABLE
DISTRIBUTED
RECOVERY
statement more than once to recover an in-doubt transaction if the remote node involved in the transaction is not accessible. In-doubt transactions appear in the data dictionary view DBA_2PC_PENDING
.
See Also:
"Enabling Distributed Recovery: Example"DISABLE Specify DISABLE
to disable distributed recovery.
The FLUSH
SHARED
POOL
clause lets you clear all data from the shared pool in the system global area (SGA). The shared pool stores
Cached data dictionary information and
Shared SQL and PL/SQL areas for SQL statements, stored procedures, function, packages, and triggers.
This statement does not clear shared SQL and PL/SQL areas for items that are currently being executed. You can use this clause regardless of whether your instance has the database dismounted or mounted, open or closed.
See Also:
"Clearing the Shared Pool: Example"The FLUSH
BUFFER_CACHE
clause lets you clear all data from the buffer cache in the system global area (SGA), including the KEEP
, RECYCLE
, and DEFAULT
buffer pools.
Caution:
This clause is intended for use only on a test database. Do not use this clause on a production database, because as a result of this statement, subsequent queries will have no hits, only misses.This clause is useful if you need to measure the performance of rewritten queries or a suite of queries from identical starting points.
Use the FLUSH
REDO
clause to flush redo data from a primary database to a standby database and to optionally wait for the flushed redo data to be applied to a physical or logical standby database.
This clause can allow a failover to be performed on the target standby database without data loss, even if the primary database is not in a zero data loss data protection mode, provided that all redo data that has been generated by the primary database can be flushed to the standby database.
The FLUSH
REDO
clause must be issued on a mounted, but not open, primary database.
For target_db_name
, specify the DB_UNIQUE_NAME
of the standby database that is to receive the redo data flushed from the primary database.
The value of the LOG_ARCHIVE_DEST_
n
database initialization parameter that corresponds to the target standby database must contain the DB_UNIQUE_NAME
attribute, and the value of that attribute must match the DB_UNIQUE_NAME
of the target standby database.
If you specify this clause, then the ALTER
SYSTEM
statement will not complete until the standby database has received all of the flushed redo data. You must specify this clause if the target standby database is a snapshot standby database.
If you specify this clause, then the ALTER
SYSTEM
statement will not complete until the target standby database has received and applied all flushed redo data. This is the default behavior unless you specify NO
CONFIRM
APPLY
. You cannot specify this clause if the target standby database is a snapshot standby database.
See Also:
Oracle Data Guard Concepts and Administration for more information about theFLUSH
REDO
clause and failoversThe SWITCH
LOGFILE
clause lets you explicitly force Oracle Database to begin writing to a new redo log file group, regardless of whether the files in the current redo log file group are full. When you force a log switch, Oracle Database begins to perform a checkpoint but returns control to you immediately rather than when the checkpoint is complete. To use this clause, your instance must have the database open.
See Also:
"Forcing a Log Switch: Example"The SUSPEND
clause lets you suspend all I/O (data file, control file, and file header) as well as queries, in all instances, enabling you to make copies of the database without having to handle ongoing transactions.
Restrictions on SUSPEND and RESUME SUSPEND
and RESUME
are subject to the following restrictions:
Do not use this clause unless you have put the database tablespaces in hot backup mode.
Do not terminate the session that issued the ALTER
SYSTEM
SUSPEND
statement. An attempt to reconnect while the system is suspended may fail because of recursive SQL that is running during the SYS
login.
If you start a new instance while the system is suspended, then that new instance will not be suspended.
The RESUME
clause lets you make the database available once again for queries and I/O.
Use these clauses in a clustered Oracle Automatic Storage Management (Oracle ASM) environment to migrate one node at a time to a different Oracle ASM version without affecting the overall availability of the Oracle ASM cluster or the database clusters using Oracle ASM for storage.
START ROLLING MIGRATION When starting rolling upgrade, for ASM_version
, you must specify the following string:
'<version_num>, <release_num>, <update_num>,<port_release_num>,<port_update_num>'
ASM_version
must be equal to or greater than 11.1.0.0.0. The surrounding single quotation marks are required. Oracle ASM first verifies that the current release is compatible for migration to the specified release, and then goes into limited functionality mode. Oracle ASM then determines whether any rebalance operations are under way anywhere in the cluster. If there are any such operations, then the statement fails and must be reissued after the rebalance operations are complete.
Rolling upgrade mode is a cluster-wide in-memory persistent state. The cluster continues to be in this state until there is at least one Oracle ASM instance running in the cluster. Any new instance joining the cluster switches to migration mode immediately upon startup. If all the instances in the cluster terminate, then subsequent startup of any Oracle ASM instance will not be in rolling upgrade mode until you reissue this statement to restart rolling upgrade of the Oracle ASM instances.
STOP ROLLING MIGRATION Use this clause to stop rolling upgrade and bring the cluster back into normal operation. Specify this clause only after all instances in the cluster have migrated to the same software version. The statement will fail if the cluster is not in rolling upgrade mode.
When you specify this clause, the Oracle ASM instance validates that all the members of the cluster are at the same software version, takes the instance out of rolling upgrade mode, and returns to full functionality of the Oracle ASM cluster. If any rebalance operations are pending because disks have gone offline, then those operations are restarted if the ASM_POWER_LIMIT
parameter would not be violated by such a restart.
See Also:
Oracle Automatic Storage Management Administrator's Guide for more information about rolling upgradeUse the QUIESCE
RESTRICTED
and UNQUIESCE
clauses to put the database in and take it out of the quiesced state. This state enables database administrators to perform administrative operations that cannot be safely performed in the presence of concurrent transactions, queries, or PL/SQL operations.
Note:
TheQUIESCE
RESTRICTED
clause is valid only if the Database Resource Manager is installed and only if the Resource Manager has been on continuously since database startup in any instances that have opened the database.If multiple QUIESCE
RESTRICTED
or UNQUIESCE
statements issue at the same time from different sessions or instances, then all but one will receive an error.
Specify QUIESCE
RESTRICTED
to put the database in the quiesced state. For all instances with the database open, this clause has the following effect:
Oracle Database instructs the Database Resource Manager in all instances to prevent all inactive sessions (other than SYS
and SYSTEM
) from becoming active. No user other than SYS
and SYSTEM
can start a new transaction, a new query, a new fetch, or a new PL/SQL operation.
Oracle Database waits for all existing transactions in all instances that were initiated by a user other than SYS
or SYSTEM
to finish (either commit or abort). Oracle Database also waits for all running queries, fetches, and PL/SQL procedures in all instances that were initiated by users other than SYS
or SYSTEM
and that are not inside transactions to finish. If a query is carried out by multiple successive OCI fetches, then Oracle Database does not wait for all fetches to finish. It waits for the current fetch to finish and then blocks the next fetch. Oracle Database also waits for all sessions (other than those of SYS
or SYSTEM
) that hold any shared resources (such as enqueues) to release those resources. After all these operations finish, Oracle Database places the database into quiesced state and finishes executing the QUIESCE
RESTRICTED
statement.
If an instance is running in shared server mode, then Oracle Database instructs the Database Resource Manager to block logins (other than SYS
or SYSTEM
) on that instance. If an instance is running in non-shared-server mode, then Oracle Database does not impose any restrictions on user logins in that instance.
During the quiesced state, you cannot change the Resource Manager plan in any instance.
Specify UNQUIESCE
to take the database out of quiesced state. Doing so permits transactions, queries, fetches, and PL/SQL procedures that were initiated by users other than SYS
or SYSTEM
to be undertaken once again. The UNQUIESCE
statement does not have to originate in the same session that issued the QUIESCE
RESTRICTED
statement.
The security_clauses
let you control access to the instance. They also allow you to enable or disable access to the encrypted data in the instance.
The RESTRICTED
SESSION
clause lets you restrict logon to Oracle Database. You can use this clause regardless of whether your instance has the database dismounted or mounted, open or closed.
Specify ENABLE
to allow only users with RESTRICTED
SESSION
system privilege to log on to Oracle Database. Existing sessions are not terminated.
This clause applies only to the current instance. Therefore, in an Oracle RAC environment, authorized users without the RESTRICTED
SESSION
system privilege can still access the database by way of other instances.
Specify DISABLE
to reverse the effect of the ENABLE
RESTRICTED
SESSION
clause, allowing all users with CREATE
SESSION
system privilege to log on to Oracle Database. This is the default.
See Also:
"Restricting Sessions: Example"Use this clause to manage database access to the Transparent Data Encryption (TDE) master encryption key. The TDE master encryption key is stored in an external security module, which can be an encryption wallet or Hardware Security Module (HSM).
Although this statement begins with the keyword ALTER
, an ALTER
SYSTEM
SET
ENCRYPTION
WALLET
statement is not a DDL clause. However, you cannot roll back such a statement.
Although this clause begins with the SET
keyword, do not confuse it with the alter_system_set_clause, which allows you to use the SET
keyword to set the value of initialization parameters. ENCRYPTION
WALLET
is not an initialization parameter.
When you specify this clause, the database uses the specified password to open the encryption wallet and load the TDE master key into database memory for the duration of the instance, or establish a connection to the HSM in order to send the encrypted table and tablespace keys to the HSM and receive then back decrypted.
Specify wallet_password
to retrieve the master encryption key from the encryption wallet. If the encryption wallet is not available or is already open, then the database returns an error. The double quotation marks around wallet_password
are required.
Specify HSM_auth_string
to make the HSM accessible. HSM_auth_string
is of the form "user_id
:password
" where:
user_id
is the user ID created for the database using the HSM management interface
password
is the password created for the user ID using the HSM management interface
The double quotation marks around HSM_auth_string
are required
CLOSE Use this clause to disable encryption and decryption in your database. The wallet_password
is required to close an encryption wallet. HSM_auth_string
is required to disable access to the HSM. Refer to OPEN for details on specifying HSM_auth_string
.
A password is not required to close an auto-open wallet when only an auto-open wallet is present. The password is required to close an auto-open wallet when both an auto-open wallet and an encryption wallet are open. In this case, using CLOSE
with a password will close the auto-open wallet and the encryption wallet.
See Also:
Oracle Real Application Clusters Administration and Deployment Guide for information on setting encryption wallets in an Oracle Real Application Clusters (Oracle RAC) environmentUse this clause to generate a new TDE master encryption key, if none exists. If there are existing master keys in the HSM or wallet, then this clause rekeys the existing table and tablespace keys, that is, it decrypts all table and tablespace keys with the old master key and reencrypts them with the new master key.
An ALTER
SYSTEM
SET
ENCRYPTION
KEY
statement is a DDL statement and will automatically commit any pending transactions in the schema.
Although this clause begins with the SET
keyword, do not confuse it with the alter_system_set_clause, which allows you to use the SET
keyword to set the value of initialization parameters. ENCRYPTION
KEY
is not an initialization parameter.
This clause loads the TDE master encryption key from the encryption wallet into memory for access to encrypted data.
The certificate_id
is required if you are using PKI asymmetric key pairs as master encryption keys. Specify the integer that identifies the certificate. You can find this value by querying the CERT_ID
column of the V$WALLET
dynamic performance view. Do not specify certificate_id
if you are using symmetric keys, which are the default.
For wallet_password
, specify the password used to connect to the security module.
If you specify an invalid certificate_id
or wallet_password
, then the database returns an error. The double quotation marks around certificate_id
and wallet_password
are required.
Restriction on IDENTIFIED BY wallet_password PKI-based master keys, including unified master encryption keys, can only be used with TDE column encryption and an Oracle Wallet, not with HSM.
IDENTIFIED BY HSM_auth_string This clause creates a master encryption key that will be stored inside the HSM. The master encryption key is used to encrypt or decrypt table keys inside the HSM.
HSM_auth_string
is of the form "user_id
:password
" where:
user_id
is the user ID created for the database using the HSM management interface
password
is the password created for the user ID using the HSM management interface
The double quotation marks around HSM_auth_string
are required.
If you are already using Transparent Data Encryption with an Oracle Wallet and you would like to migrate to an HSM, then specify the MIGRATE
USING
wallet_password
clause. This decrypts the existing table and tablespace keys, and then reencrypts them with the newly created, HSM-based, master encryption key. Note that the encryption wallet is still in use after you migrate to an HSM, because it may contain master encryption keys that were used for export files, RMAN backups, or encrypted data in temporary or undo tablespaces or redo log files. After migrating, perform one of the following steps:
Change the wallet password to the HSM_auth_string
using Oracle Wallet Manager or the orapki
command-line tool.
Create a local auto-open wallet from the encryption wallet and either rename the encryption wallet, or move it out of the directory specified in ENCRYPTION_WALLET_LOCATION
in sqlnet
.ora
. Do not delete the encryption wallet and do not forget the wallet password.
See Also:
Oracle Database Advanced Security Administrator's Guide for more information on using the server wallet and encryption keys and on Transparent Data Encryption
The description of the CREATE
TABLE
"encryption_spec " for information on using that feature to encrypt table columns
The SHUTDOWN
clause is relevant only if your system is using the shared server architecture of Oracle Database. It shuts down a dispatcher identified by dispatcher_name
.
Note:
Do not confuse this clause with the SQL*Plus commandSHUTDOWN
, which is used to shut down the entire database.The dispatcher_name
must be a string of the form 'D
xxx
', where xxx
indicates the number of the dispatcher. For a listing of dispatcher names, query the NAME
column of the V$DISPATCHER
dynamic performance view.
If you specify IMMEDIATE
, then the dispatcher stops accepting new connections immediately and Oracle Database terminates all existing connections through that dispatcher. After all sessions are cleaned up, the dispatcher process shuts down.
If you do not specify IMMEDIATE
, then the dispatcher stops accepting new connections immediately but waits for all its users to disconnect and for all its database links to terminate. Then it shuts down.
Specify REGISTER
to instruct the PMON
background process to register the instance with the listeners immediately. If you do not specify this clause, then registration of the instance does not occur until the next time PMON
executes the discovery routine. As a result, clients may not be able to access the services for as long as 60 seconds after the listener is started.
See Also:
Oracle Database Concepts and Oracle Database Net Services Administrator's Guide for information on thePMON
background process and listenersYou can change the value of many initialization parameters for the current instance, whether you have started the database with a traditional plain-text parameter file (pfile) or with a server parameter file (spfile). Oracle Database Reference indicates these parameters in the "Modifiable" category of each parameter description. If you are using a pfile, then the change will persist only for the duration of the instance. However, if you have started the database with an spfile, then you can change the value of the parameter in the spfile itself, so that the new value will occur in subsequent instances.
Oracle Database Reference documents all initialization parameters in full. The parameters fall into three categories:
Basic parameters: Database administrators should be familiar with and consider the setting for all of the basic parameters.
Functional categories: Oracle Database Reference also lists the initialization parameters by their functional category.
Alphabetical listing: The Table of Contents of Oracle Database Reference contains all initialization parameters in alphabetical order.
The ability to change initialization parameter values depends on whether you have started up the database with a traditional plain-text initialization parameter file (pfile) or with a server parameter file (spfile). To determine whether you can change the value of a particular parameter, query the ISSYS_MODIFIABLE
column of the V$PARAMETER
dynamic performance view.
When setting a parameter value, you can specify additional settings as follows:
COMMENT The COMMENT
clause lets you associate a comment string with this change in the value of the parameter. The comment string cannot contain control characters or a line break. If you also specify SPFILE
, then this comment will appear in the parameter file to indicate the most recent change made to this parameter.
DEFERRED The DEFERRED
keyword sets or modifies the value of the parameter for future sessions that connect to the database. Current sessions retain the old value.
You must specify DEFERRED
if the value of the ISSYS_MODIFIABLE
column of V$PARAMETER
for this parameter is DEFERRED
. If the value of that column is IMMEDIATE
, then the DEFERRED
keyword in this clause is optional. If the value of that column is FALSE
, then you cannot specify DEFERRED
in this ALTER
SYSTEM
statement.
SCOPE The SCOPE
clause lets you specify when the change takes effect. Scope depends on whether you started up the database using a traditional plain-text parameter file (pfile) or server parameter file (spfile).
MEMORY
indicates that the change is made in memory, takes effect immediately, and persists until the database is shut down. If you started up the database using a parameter file (pfile), then this is the only scope you can specify.
SPFILE
indicates that the change is made in the server parameter file. The new setting takes effect when the database is next shut down and started up again. You must specify SPFILE
when changing the value of a static parameter that is described as not modifiable in Oracle Database Reference.
BOTH
indicates that the change is made in memory and in the server parameter file. The new setting takes effect immediately and persists after the database is shut down and started up again.
If a server parameter file was used to start up the database, then BOTH
is the default. If a parameter file was used to start up the database, then MEMORY
is the default, as well as the only scope you can specify.
SID The SID
clause lets you specify the SID of the instance where the value will take effect.
Specify SID
= '*'
if you want Oracle Database to change the value of the parameter for all instances that do not already have an explicit setting for this parameter.
Specify SID
= 'sid'
if you want Oracle Database to change the value of the parameter only for the instance sid
. This setting takes precedence over previous and subsequent ALTER
SYSTEM
SET
statements that specify SID
= '*'
.
If you do not specify this clause, then:
If the instance was started up with a pfile (traditional plain-text initialization parameter file), then Oracle Database assumes the SID of the current instance.
If the instance was started up with an spfile (server parameter file), then Oracle Database assumes SID
=
'*'
.
If you specify an instance other than the current instance, then Oracle Database sends a message to that instance to change the parameter value in the memory of that instance.
USE_STORED_OUTLINES
is a system parameter, not an initialization parameter. You cannot set it in a pfile or spfile, but you can set it with an ALTER
SYSTEM
statement. This parameter determines whether the optimizer will use stored public outlines to generate execution plans.
TRUE
causes the optimizer to use outlines stored in the DEFAULT
category when compiling requests.
FALSE
specifies that the optimizer should not use stored outlines. This is the default.
category_name
causes the optimizer to use outlines stored in the category_name
category when compiling requests.
GLOBAL_TOPIC_ENABLED
is a system parameter, not an initialization parameter. You cannot set it in a pfile or spfile, but you can set it with an ALTER
SYSTEM
statement. This parameter determines whether all queues and topics created in Oracle Streams AQ are automatically registered with the LDAP server. If GLOBAL_TOPIC_ENABLED
= TRUE
when a queue table is created, altered, or dropped, then the corresponding Lightweight Directory Access Protocol (LDAP) entry is also created, altered or dropped.
The parameter works the same way for the Java Message Service (JMS). If a database has been configured to use LDAP and the GLOBAL_TOPIC_ENABLED
parameter has been set to TRUE
, then all JMS queues and topics are automatically registered with the LDAP server when they are created. The administrator can also create aliases to the queues and topics registered in LDAP. Queues and topics that are registered in LDAP can be looked up through JNDI using the name or alias of the queue or topic.
When you start your instance, Oracle Database creates shared server processes and dispatcher processes for the shared server architecture based on the values of the SHARED_SERVERS
and DISPATCHERS
initialization parameters. You can also set the SHARED_SERVERS
and DISPATCHERS
parameters with ALTER
SYSTEM
to perform one of the following operations while the instance is running:
Create additional shared server processes by increasing the minimum number of shared server processes.
Terminate existing shared server processes after their current calls finish processing.
Create more dispatcher processes for a specific protocol, up to a maximum across all protocols specified by the initialization parameter MAX_DISPATCHERS
.
Terminate existing dispatcher processes for a specific protocol after their current user processes disconnect from the instance.
This clause lets you remove the setting, for any instance, of any initialization parameter in the spfile that was used to start the instance. Neither SCOPE
=MEMORY
nor SCOPE
=BOTH
are allowed. The SCOPE
= SPFILE
clause is not required, but is included for syntactic clarity. You can use this clause in a single-instance environment, but only if the instance was started using an spfile rather than a pfile.
Use the SID
clause to remove the spfile parameter setting for a specified instance. In a non-Oracle RAC environment, you can omit this clause, because there is only one instance. In an Oracle RAC environment, if you omit this clause, then the default of SID = '*'
is used, which means that the all settings of the parameter of the form *.
parameter = value
are removed.
See Also:
Oracle Real Application Clusters Administration and Deployment Guide for information on setting parameter values for an individual instance in an Oracle Real Application Clusters environment
The following examples of using the ALTER
SYSTEM
statement: "Changing Licensing Parameters: Examples", "Enabling Query Rewrite: Example", "Enabling Resource Limits: Example", "Shared Server Parameters", and "Changing Shared Server Settings: Examples"
Archiving Redo Logs Manually: Examples The following statement manually archives the redo log file group containing the redo log entry with the SCN 9356083:
ALTER SYSTEM ARCHIVE LOG CHANGE 9356083;
The following statement manually archives the redo log file group containing a member named 'diskl:log6.log
' to an archived redo log file in the location 'diska:[arch$
]':
ALTER SYSTEM ARCHIVE LOG LOGFILE 'diskl:log6.log' TO 'diska:[arch$]';
Enabling Query Rewrite: Example This statement enables query rewrite in all sessions for all materialized views for which query rewrite has not been explicitly disabled:
ALTER SYSTEM SET QUERY_REWRITE_ENABLED = TRUE;
Restricting Sessions: Example You might want to restrict sessions if you are performing application maintenance and you want only application developers with RESTRICTED
SESSION
system privilege to log on. To restrict sessions, issue the following statement:
ALTER SYSTEM ENABLE RESTRICTED SESSION;
You can then terminate any existing sessions using the KILL
SESSION
clause of the ALTER
SYSTEM
statement.
After performing maintenance on your application, issue the following statement to allow any user with CREATE
SESSION
system privilege to log on:
ALTER SYSTEM DISABLE RESTRICTED SESSION;
Establishing a Wallet and Encryption Key: Examples The following statements load information from the server wallet into memory and set the Transparent Data Encryption master key:
ALTER SYSTEM SET ENCRYPTION WALLET OPEN IDENTIFIED BY "password"; ALTER SYSTEM SET ENCRYPTION KEY IDENTIFIED BY "password";
These statements assume that you have initialized the security module and created a wallet with password
.
Closing a Wallet: Examples The following statement removes password-based wallet information from memory:
ALTER SYSTEM SET ENCRYPTION WALLET CLOSE IDENTIFIED BY "password";
The following statement removes password-based wallet information and auto-login information, if present, from memory:
ALTER SYSTEM SET ENCRYPTION WALLET CLOSE;
Clearing the Shared Pool: Example You might want to clear the shared pool before beginning performance analysis. To clear the shared pool, issue the following statement:
ALTER SYSTEM FLUSH SHARED_POOL;
Forcing a Checkpoint: Example The following statement forces a checkpoint:
ALTER SYSTEM CHECKPOINT;
Enabling Resource Limits: Example This ALTER
SYSTEM
statement dynamically enables resource limits:
ALTER SYSTEM SET RESOURCE_LIMIT = TRUE;
Changing Shared Server Settings: Examples The following statement changes the minimum number of shared server processes to 25:
ALTER SYSTEM SET SHARED_SERVERS = 25;
If there are currently fewer than 25 shared server processes, then Oracle Database creates more. If there are currently more than 25, then Oracle Database terminates some of them when they are finished processing their current calls if the load could be managed by the remaining 25.
The following statement dynamically changes the number of dispatcher processes for the TCP/IP protocol to 5 and the number of dispatcher processes for the ipc protocol to 10:
ALTER SYSTEM SET DISPATCHERS = '(INDEX=0)(PROTOCOL=TCP)(DISPATCHERS=5)', '(INDEX=1)(PROTOCOL=ipc)(DISPATCHERS=10)';
If there are currently fewer than 5 dispatcher processes for TCP, then Oracle Database creates new ones. If there are currently more than 5, then Oracle Database terminates some of them after the connected users disconnect.
If there are currently fewer than 10 dispatcher processes for ipc, then Oracle Database creates new ones. If there are currently more than 10, then Oracle Database terminates some of them after the connected users disconnect.
If there are currently existing dispatchers for another protocol, then the preceding statement does not affect the number of dispatchers for that protocol.
Changing Licensing Parameters: Examples The following statement dynamically changes the limit on sessions for your instance to 64 and the warning threshold for sessions on your instance to 54:
ALTER SYSTEM SET LICENSE_MAX_SESSIONS = 64 LICENSE_SESSIONS_WARNING = 54;
If the number of sessions reaches 54, then Oracle Database writes a warning message to the ALERT
file for each subsequent session. Also, users with RESTRICTED
SESSION
system privilege receive warning messages when they begin subsequent sessions.
If the number of sessions reaches 64, then only users with RESTRICTED
SESSION
system privilege can begin new sessions until the number of sessions falls below 64 again.
The following statement dynamically disables the limit for sessions on your instance. After you issue this statement, Oracle Database no longer limits the number of sessions on your instance.
ALTER SYSTEM SET LICENSE_MAX_SESSIONS = 0;
The following statement dynamically changes the limit on the number of users in the database to 200. After you issue the preceding statement, Oracle Database prevents the number of users in the database from exceeding 200.
ALTER SYSTEM SET LICENSE_MAX_USERS = 200;
Forcing a Log Switch: Example You might want to force a log switch to drop or rename the current redo log file group or one of its members, because you cannot drop or rename a file while Oracle Database is writing to it. The forced log switch affects only the redo log thread of your instance. The following statement forces a log switch:
ALTER SYSTEM SWITCH LOGFILE;
Enabling Distributed Recovery: Example The following statement enables distributed recovery:
ALTER SYSTEM ENABLE DISTRIBUTED RECOVERY;
You might want to disable distributed recovery for demonstration or testing purposes. You can disable distributed recovery in both single-process and multiprocess mode with the following statement:
ALTER SYSTEM DISABLE DISTRIBUTED RECOVERY;
When your demonstration or testing is complete, you can then enable distributed recovery again by issuing an ALTER
SYSTEM
statement with the ENABLE
DISTRIBUTED
RECOVERY
clause.
Terminating a Session: Example You might want to terminate the session of a user that is holding resources needed by other users. The user receives an error message indicating that the session has been terminated. That user can no longer make calls to the database without beginning a new session. Consider this data from the V$SESSION
dynamic performance table, when the users SYS
and oe
both have open sessions:
SELECT sid, serial#, username FROM V$SESSION; SID SERIAL# USERNAME ---------- ---------- ------------------------------ 29 85 SYS 33 1 35 8 39 23 OE 40 1 . . .
The following statement terminates the session of the user scott
using the SID
and SERIAL#
values from V$SESSION
:
ALTER SYSTEM KILL SESSION '39, 23';
Disconnecting a Session: Example The following statement disconnects user scott
's session, using the SID
and SERIAL#
values from V$SESSION
:
ALTER SYSTEM DISCONNECT SESSION '13, 8' POST_TRANSACTION;