Oracle® C++ Call Interface Programmer's Guide, 11g Release 2 (11.2) E10764-04 |
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This chapter describes a few suggestions that lead to better performance for your OCCI custom applications.
This chapter contains these topics:
OCCI Transparent Application Failover (TAF) enables OCCI to be more robust in handling database instance failures in distributed applications at run time. If a server node becomes unavailable, applications automatically reconnect to another surviving node.
TAF occurs when the client application, during a roundtrip operation, detects that the database instance is down. It establishes a connection to the backup database configured for TAF. This backup can be another node in an Oracle RAC configuration, a hot standby database, or the same database instance itself.
The OCCI/OCI API responsible for the roundtrip on the failed connection will typically return one of the following errors:
ORA-25401: can not continue fetches
ORA-25402: transaction must roll back
ORA-25408: can not safely replay call
The new connection is may be used for subsequent application requests and for any ongoing work that must be restarted.Idle connections in the application are not affected.
Some design options should be considered when including Transparent Application Failover in an application:
Because of the delays inherent to failover processing, the design of the application may include a notice to the user that a failover is in progress and that normal operation should resume shortly.
If the session on the initial instance received ALTER SESSION
commands before the failover began, they are not automatically replayed on the second instance.
Consequently, the developer may want to replay these ALTER SESSION
commands on the second instance.
It is the user's responsibility to track changes to the SESSION
parameters.
To address these problems, the application can register a failover callback function. After a failover, the callback function is invoked at different times while reestablishing the user's session.
The first call to the callback function occurs when Oracle first detects an instance connection loss. This callback is intended to allow the application to inform the user of an upcoming delay.
If failover is successful, a second call to the callback function occurs when the connection is reestablished and usable. At this time the client may want to replay ALTER SESSION
commands and inform the user that failover has happened. Note that you must keep track of SESSION
parameter changes and then replay them after the failover is complete.
If failover is unsuccessful, then the callback function is called to inform the application that failover cannot take place.
An initial attempt at failover may not always successful. The failover callback should return FO_RETRY
to indicate that the failover should be attempted again.
See Also:
Definition of FailOverType
and FailOverEventType
in Table 13-11, "Enumerated Values Used by Connection Class" in Chapter 13, "OCCI Application Programming Interface"
Oracle Database Net Services Administrator's Guide for more detailed information about application failover.
To enable TAF, the connect string has to be configured for failover and registered on Connection
(created from Environment
, ConnectionPool
and StatelessConnectionPool
). To register the callback function, use the Connection Class interface setTAFNotify():
void Connection::setTAFNotify( int (*notifyFn)( Environment *env, Connection *conn, void *ctx, FailOverType foType, FailOverEventType foEvent), void *ctxTAF);
Note that TAF support for ConnectionPool
s does not include BACKUP
and PRECONNECT
clauses; these should not be used in the connect string.
Transparent application failover works with the OCCI navigational and associative access models and the object cache. In a non-Oracle RAC setup, you must ensure that the object type definitions and object OIDs in primary and backup instances are identical.
If the application receives ORA-25402: transaction must roll back
error after the failover, then it must initiate a rollback to correctly reset the object cache on the client. If a transaction has not started before the failover, the application should still initiate a rollback after the failover to refresh the objects on the client object cache from the new instance.
If the transparent application failover feature is activated, connections created in a connection pool are also failed over. The application failover callback must be specified for each connection obtained from the connection pool; these connections are failed over when used after the primary instance failure.
Note that connections in a custom connection pool must be explicitly cleaned and repaired. Consider an application that has 500 connections in a pool; 10 of the connections are busy (doing a round-trip) and 490 are free or idle. If the database instance fails, then TAF will work on 10 active connections, and client requests on these connections must be restarted. When each of the other 490 connections are picked up by the application, TAF is performed and OCCI returns one of error codes ORA-25401
, ORA-24502
, or ORA-25408
, forcing a restart of the user request. The application can avoid these errors on the 490 idle connections by repairing or purging these connections by using the knowledge that TAF was previously activated on 10 connections in the connection pool.
To repair connections in OCCI, use the Connection Class interface getServerVersion(), a light-weight, data-neutral database call for starting TAF on connections to failed instances:
string getServerVersion() const;
In the OCCI TAF callback, applications may invoke getServerVersion() on idle connections in the custom pool, to start and complete failover for these connections.
Example 12-1 demonstrates how to use OCCI for TAF callbacks and for repairing bad connections. Note that the example does not show custom pool data structure or mutexing and concurrency control.
Note that TAF behavior is the same for standalone connections and connections in a custom connection pool.
Example 12-1 How to Enable TAF for Connection Pooling
#include <occi.h> #include <iostream> #include <time.h> using namespace std; using namespace oracle::occi; //Application custom pool of 3 connections Environment *env; Connection *conn1,*conn2,*conn3; bool conn1free,conn2free,conn3free; bool repairing = false; int taf_callback(Environment *env, Connection *conn, void *ctx, Connection::FailOverType foType, Connection::FailOverEventType foEvent) { cout << "TAF callback for connection " << conn << endl; if(foEvent == Connection::FO_ERROR) { cout << "Retrying" << endl; return FO_RETRY; } if (foEvent == Connection::FO_END) { cout << "TAF complete for connnection " << conn << endl; if (repairing == false) { repairing = true; cout << "repairing other idle connections" << endl; //ignore errors during TAF try { if (conn1free) conn1->getServerVersion(); } catch (...) { } try { if (conn2free) conn2->getServerVersion(); } catch (...) { } try { if (conn3free) conn3->getServerVersion(); } catch (...) { } repairing = false; }//if }//if return 0; //continue failover } main() { try { env = Environment::createEnvironment(Environment::THREADED_MUTEXED); //open 3 connections; conn1 = env->createConnection("hr","password","inst1_failback"); conn2 = env->createConnection("hr","password","inst1_failback"); conn3 = env->createConnection("hr","password","inst1_failback"); //all connections are 'free' conn1free = conn2free = conn3free = true; //set TAF callbacks on all connection conn1->setTAFNotify(taf_callback,NULL); conn2->setTAFNotify(taf_callback,NULL); conn3->setTAFNotify(taf_callback,NULL); //use 1 connection conn1free=false; cout << "Using conn1" << endl; Statement *stmt = conn1->createStatement ("select * from employees"); ResultSet *rs = stmt->executeQuery(); while (rs->next()) { cout << (rs->getString(2)) << endl; } stmt->closeResultSet(rs); conn1->terminateStatement(stmt); cout << "Shutdown and restart the database" << endl; string buf; cin >> buf; Statement *stmt2; try { cout << "Trying a update on EMP table" << endl; stmt2 = conn1->createStatement("delete from employees"); stmt2->executeUpdate(); } catch (SQLException &ex) { cout << "Update EMPLOYEES returned error : " << ex.getMessage() << endl; cin >> buf; } cout << "Done" << endl; env->terminateConnection(conn1); env->terminateConnection(conn2); env->terminateConnection(conn3); Environment::terminateEnvironment(env); } catch(SQLException &ex) { cout << ex.getMessage() << endl; } }
This section covers the following topics:
Threads are lightweight processes that exist within a larger process. Threads each share the same code and data segments, but have their own program counters, system registers, and stack. Global and static variables are common to all threads, and a mutual exclusivity mechanism may be required to manage access to these variables from multiple threads within an application.
Once spawned, threads run asynchronously to one another. They can access common data elements and make OCCI calls in any order. Because of this shared access to data elements, a mechanism is required to maintain the integrity of data being accessed by multiple threads. The mechanism to manage data access takes the form of mutexes (mutual exclusivity locks), which ensure that no conflicts arise between multiple threads that are accessing shared resources within an application. In OCCI, mutexes are granted on an OCCI environment basis.
This thread safety feature of the Oracle database server and OCCI library enables developers to use OCCI in a multithreaded application with these added benefits:
Multiple threads of execution can make OCCI calls with the same result as successive calls made by a single thread.
When multiple threads make OCCI calls, there are no side effects between threads.
Even if you do not write a multithreaded program, you do not pay any performance penalty for including thread-safe OCCI calls.
Use of multiple threads can improve program performance. You can discern gains on multiprocessor systems where threads run concurrently on separate processors, and on single processor systems where overlap can occur between slower operations and faster operations.
In addition to client/server applications, where the client can be a multithreaded program, thread safety is typically used in three-tier or client/agent/server architectures. In this architecture, the client is concerned only with presentation services. The agent (or application server) processes the application logic for the client application. Typically, this relationship is a many-to-one relationship, with multiple clients sharing the same application server.
The server tier in the three-tier architecture is an Oracle database server. The applications server (agent) supports multithreading, with each thread serving a separate client application. In an Oracle environment, this middle-tier application server is an OCCI or precompiler program.
To take advantage of thread safety by using OCCI, an application must be running in a thread-safe operating system. Then the application must inform OCCI that the application is running in multithreaded mode by specifying THREADED_MUTEXED
or THREADED_UNMUTEXED
for the mode parameter of the createEnvironment()
method. For example, to turn on mutual exclusivity locking, issue the following statement:
Environment *env = Environment::createEnvironment( Environment::THREADED_MUTEXED);
Note that once createEnvironment
is called with THREADED_MUTEXED
or THREADED_UNMUTEXED
, all subsequent calls to the createEnvironment
method must also be made with THREADED_MUTEXED
or THREADED_UNMUTEXED
modes.
If a multithreaded application is running in a thread-safe operating system, then the OCCI library manages mutexes for the application on a for each-OCCI-environment basis. However, you can override this feature and have your application maintain its own mutex scheme. This is done by specifying a mode value of THREADED_UNMUTEXED
to the createEnvironment()
method.
Applications that run on non-thread-safe platforms should not pass a value of THREADED_MUTEXED
or THREADED_UNMUTEXED
to the createEnvironment()
method.
If an application is single threaded, regardless of whether the platform is thread safe, the application should pass a value of Environment::DEFAULT
to the createEnvironment()
method. This is also the default value for the mode parameter. Single threaded applications which run in THREADED_MUTEXED
mode may incur performance degradation.
OCCI does not support nonblocking mode.
As an application programmer, you have two basic options regarding concurrency in a multithreaded application:
Automatic serialization, in which you use OTIS's transparent mechanisms
Application-provided serialization, in which you manage the contingencies involved in maintaining multiple threads
In cases where there are multiple threads operating on objects (connections and connection pools) derived from an OCCI environment, you can elect to let OCCI serialize access to those objects. The first step is to pass a value of THREADED_MUTEXED
to the createEnvironment
method. At this point, the OCCI library automatically acquires a mutex on thread-safe objects in the environment.
When the OCCI environment is created with THREADED_MUTEXED
mode, then only the Environment
, Map
, ConnectionPool
, StatelessConnectionPool
and Connection
objects are thread-safe. That is, if two threads make simultaneous calls on one of these objects, then OCCI serializes them internally. However, note that all other OCCI objects, such as Statement
, ResultSet
, SQLException
, Stream
, and so on, are not thread-safe as, applications should not operate on these objects simultaneously from multiple threads.
Note that the bulk of processing for an OCCI call happens on the server, so if two threads that use OCCI calls go to the same connection, then one of them could be blocked while the other finishes processing at the server.
In cases where there are multiple threads operating on objects derived from an OCCI environment, you can chose to manage serialization. The first step is to pass a value of THREADED_UNMUTEXED
for the createEnvironment
mode. In this case the application must mutual exclusively lock OCCI calls made on objects derived from the same OCCI environment. This has the advantage that the mutex scheme can be optimized based on the application design to gain greater concurrency.
When an OCCI environment is created in this mode, OCCI recognizes that the application is running in a multithreaded application, but that OCCI need not acquire its internal mutexes. OCCI assumes that all calls to methods of objects derived from that OCCI environment are serialized by the application. You can achieve this two different ways:
Each thread has its own environment. That is, the environment and all objects derived from it (connections, connection pools, statements, result sets, and so on) are not shared across threads. In this case your application need not apply any mutexes.
If the application shares an OCCI environment or any object derived from the environment across threads, then it must serialize access to those objects (by using a mutex, and so on) such that only one thread is calling an OCCI method on any of those objects.
In both cases, no mutexes are acquired by OCCI. You must ensure that only one OCCI call is in process on any object derived from the OCCI environment at any given time when THREADED_UNMUTEXED
is used.
OCCI is optimized to reuse objects as much as possible. Since each environment has its own heap, multiple environments result in increased consumption of memory. Having multiple environments may imply duplicating work regarding connections, connection pools, statements, and result set objects. This results in further memory consumption.
Having multiple connections to the server results in more resource consumption on both the server and the network. Having multiple environments normally entails more connections.
Some operating systems provide facilities for spawning processes that allow child processes to reuse states created by their parent process.
After a parent process spawns a child process, the child process must not use the database connection created by the parent. Because SQL*Net expects only one user process to use a particular connection to the database, attempts by the child process to use the same database connection as the parent may cause undesired connection interference, and result in intermittent ORA-03137
errors.
When the application requires multiple concurrent connections, Oracle recommends using threads on platforms that support threading. Oracle supports concurrent connections in both single-threaded and multi-threaded applications.
See "Introduction to Thread Safety" and "Implementing Thread Safety" for more information about threads.
For improving performance with many concurrently opened connections, see "Pooling Connections".
When you provide data for bind parameters by the set
xxx methods in parameterized statements, the values are copied into an internal data buffer, and the copied values are then provided to the database server for insertion. To reduce overhead of copying string
type data that is available in user buffers, use the setDataBuffer() and next() methods of the ResultSet Class and the execute() method of the Statement Class.
For high performance applications, OCCI provides the setDataBuffer
method whereby the data buffer is managed by the application. The following example shows the setDataBuffer() method:
void setDataBuffer(int paramIndex, void *buffer, Type type, sb4 size, ub2 *length, sb2 *ind = NULL, ub2 *rc = NULL);
The following parameters are used in the previous method example:
paramIndex
: Parameter number
buffer
: Data buffer containing data
type
: Type of the data in the data buffer
size
: Size of the data buffer
length
: Current length of data in the data buffer
ind
: Indicator information. This indicates whether the data is NULL
or not. For parameterized statements, a value of -1
means a NULL
value is to be inserted. For data returned from callable statements, a value of -1
means NULL
data is retrieved.
rc
: Return code. This variable is not applicable to data provided to the Statement
method. However, for data returned from callable statements, the return code specifies parameter-specific error numbers.
Not all data types can be provided and retrieved by the setDataBuffer()
method. For instance, C++ Standard Library strings cannot be provided with the setDataBuffer()
interface.
See Also:
Table 5-2, "External Data Types and Corresponding C++ and OCCI Types" in Chapter 5, "Data Types" for specific casesThere is an important difference between the data provided by the set
xxx()
methods and setDataBuffer()
method. When data is copied in the set
xxx()
methods, the original can change once the data is copied. For example, you can use a setString(str1)
method, then change the value of str1
before execute. The value of str1
that is used is the value at the time setString(str1)
is called. However, for data provided by the setDataBuffer()
method, the buffer must remain valid until the execution is completed.
If iterative executes or the executeArrayUpdate()
method is used, then data for multiple rows and iterations can be provided in a single buffer. In this case, the data for the ith iteration is at buffer + (i-1) *size address
and the length, indicator, and return codes are at *(length + i)
, *(ind + i)
, and *(rc + i)
respectively.
This interface is also meant for use with array executions and callable statements that have array or OUT
bind parameters.
The same method is available in the ResultSet
class to retrieve data without re-allocating the buffer for each fetch.
If all data is provided with the setDataBuffer()
methods or output streams (that is, no set
xxx() methods besides setDataBuffer()
or getStream()
are called), then there is a simplified way of doing iterative execution.
In this case, you should not call setMaxIterations()
and setMaxParamSize()
. Instead, call the setDataBuffer()
or getStream()
method for each parameter with the appropriate size arrays to provide data for each iteration, followed by the executeArrayUpdate(int
arrayLength)
method. The arrayLength
parameter specifies the number of elements provided in each buffer. Essentially, this is same as setting the number of iterations to arrayLength
and executing the statement.
Since the stream parameters are specified only once, they can be used with array executes as well. However, if any set
xxx()
methods are used, then the addIteration()
method is called to provide data for multiple rows. To compare the two approaches, consider Example 12-2 that inserts two employees in the employees
table:
Example 12-2 How to Insert Records Using the addIteration() method
Statement *stmt = conn->createStatement( "insert into departments (department_id, department_name) values(:1, :2)"); char dnames[][100] = {"Community Outreach", "University Recruiting"}; ub2 dnameLen[2]; for (int i = 0; i < 2; i++) dnameLen[i] = strlen(dnames[i] + 1); stmt->setMaxIterations(2); // set maximum number of iterations stmt->setInt(1, 7369); // specify data for the first row stmt->setDataBuffer(2, dnames, OCCI_SQLT_STR, sizeof(dnames[0]), dnameLen); stmt->addIteration(); stmt->setInt(1, 7654); // specify data for the second row // a setDatBuffer is unnecessary for the second // bind parameter as data provided through // setDataBuffer is specified only once. stmt->executeUpdate();
However, if the first parameter could also be provided through the setDataBuffer()
interface, then, instead of the addIteration()
method, you would use the executeArrayUpdate()
method, as shown in Example 12-3:
Example 12-3 How to Insert Records Using the executeArrayUpdate() Method
Statement *stmt = conn->createStatement( "insert into departments (department_id, department_name) values(:1, :2)"); char dnames[][100] = {"Community Outreach", "University Recruiting"}; ub2 dnameLen[2]; for (int i = 0; i < 2; i++) dnameLen[i] = strlen(dnames[i] + 1); int ids[2] = {7369, 7654}; ub2 idLen[2] = {sizeof(ids[0]), sizeof(ids[1])}; stmt->setDataBuffer(1, ids, OCCIINT, sizeof(ids[0]), idLen); stmt->setDataBuffer(2, dnames, OCCI_SQLT_STR, sizeof(dnames[0]), dnameLen); stmt->executeArrayUpdate(2); // data for two rows is inserted.
If the application is fetching data with only the setDataBuffer()
interface or the stream interface, then an array fetch can be executed. The array fetch is implemented through the next(
) method of the ResultSet
class. You must process the results obtained through next() before calling it again.
Example 12-4 How to use Array Fetch with a ResultSet
ResultSet *resultSet = stmt->executeQuery(...);
resultSet->setDataBuffer(...);
while (resultSet->next(numRows) == DATA_AVAILABLE)
process(resultSet->getNumArrayRows() );
This causes up to numRows
amount of data to be fetched for each column. The buffers specified with the setDataBuffer()
interface should large enough to hold at least numRows
of data.
To process batch errors, specify that the Statement
object is in a batchMode
of execution using the setBatchErrorMode() method. Once the batchMode
is set and a batch update runs, any resulting errors are reported through the BatchSQLException Class.
The BatchSQLException
class provides methods that handle batch errors. Example 12-5 illustrates how batch handling can be implemented within any OCCI application.
Example 12-5 How to Modify Rows Iteratively and Handle Errors
Create the Statement object and set its batch error mode to TRUE
.
Statement *stmt = conn->createStatement ("..."); stmt->setBatchErrorMode (true);
Perform programmatic changes necessary by the application.
try { updateCount = stmt->executeUpdate (); }
Catch and handle any errors generated during the batch insert or update.
catch (BatchSQLException &batchEx) { cout<<"Batch Exception: "<<batchEx.what()<<endl; int errCount = batchEx.getFailedRowCount(); cout << "Number of rows failed " << errCount <endl; for (int i = 0; i < errCount; i++ ) { SQLException err = batchEx.getException(i); unsigned int rowIndex = batchEx.getRowNum(i); cout<<"Row " << rowIndex << " failed because of " << err.getErrorCode() << endl; } // take recovery action on the failed rows }
Catch and handle other errors generated during the statement update. Note that statement-level errors are still thrown as instances of a SQLException
.
catch( SQLException &ex) // to catch other SQLExceptions. { cout << "SQLException: " << e.what() << endl; }
Run-time load balancing in a stateless connection pool dynamically routs connection requests to the least loaded instance of the database. This is achieved by use of service metrics, which are distributed by the Oracle RAC load-balancing advisory.
The feature modifies the stateless connection pool in the following ways:
The pool receives periodic notifications about the instance load.
When a request for a connection is received, the pool picks the best possible connection for the type of request, based on the load of the instance.
The stateless connection pool periodically terminates connections of overloaded instances, maintaining the connection topology that corresponds to the instance load.
Since the connections to overloaded instances may be terminated, the pool creates new connections to maintain the concurrency requirement. These new connections are created using the connect-time load balancing of the Oracle RAC listener.
Run-time load balancing is turned on by default when the OCCI environment is created in THREADED_MUTEXED
and EVENTS
modes, and when the server is configured to issue event notifications.
See Also:
Oracle Call Interface Programmer's GuideNew NO_RLB
option for the PoolType
attribute of the StatelessConnectionPool Class disables run-time load balancing.
Fault diagnosability captures diagnostic data, such as dump files or core dump files, on the OCCI client when a problem incident occurs. For each incident, the fault diagnosability feature creates an Automatic Diagnostic Repository (ADR) subdirectory for storing this diagnostic data. For example, if either a Linux or a UNIX application fails with a null pointer reference, then the core file appears in the ADR home directory (if it exists), not in the operating system directory. This section discusses the ADR subdirectory structure and the utility to manage its output, the ADR Command Interpreter (ADRCI).
An ADR home is the root directory for all diagnostic data for an instance of a product, such as OCCI, and a particular operating system user. All ADR homes appear under the same root directory, the ADR base.
See Also:
Oracle Database Administrator's GuideThe location of the ADR base is determined in the following order:
In the sqlnet.ora
file (on Windows, in the %TNS_ADMIN%
directory, or on Linux or UNIX, in the $TNS_ADMIN
directory).
If there is no TNS_ADMIN
directory, then sqlnet.ora
is stored in the current directory.
If the ADR base is listed in the sqlnet.ora
file, it is a statement of the type:
ADR_BASE=/directory/adr
where:
The adr
argument is a directory that must exist and be writable by all operating system users who execute OCCI applications and want to share the same ADR base.
The directory
argument is the path name
If ADR_BASE
is set, and if all users share a single sqlnet.ora
file, then OCCI stops searching when directory adr
does not exist or if it is not writable. If ADR_BASE
is not set, then OCCI continues the search, testing for the existence of other specific directories.
For example, if sqlnet.ora
contains the entry ADR_BASE=/home/chuck/test
then:
ADR base is:
/home/chuck/test/oradiag_chuck
ADR home may be:
/home/chuck/test/oradiag_chuck/diag/clients/user_chuck/host_4144260688_11
If the Oracle base exists (on Windows: %ORACLE_BASE%
, or on Linux and UNIX: $ORACLE_BASE
), the client subdirectory also exists because it is created by the Oracle Universal Installer when the database is installed.
For example, if $ORACLE_BASE
is /home/chuck/obase
, then:
ADR base is:
/home/chuck/obase
ADR home may be:
/home/chuck/obase/diag/clients/user_chuck/host_4144260688_11
If the Oracle home exists (on Windows: %ORACLE_HOME%
, or on Linux and UNIX: $ORACLE_HOME
), the client subdirectory also exists because it is created by the Oracle Universal Installer when the database is installed.
For example, if $ORACLE_HOME
is /ade/chuck_l1/oracle
, then:
ADR base is:
/ade/chuck_l1/oracle/log
ADR home may be:
/ade/chuck_l1/oracle/log/diag/clients/user_chuck/host_4144260688_11
On the operating system home directory.
On Windows, the operating system home directory is %USERPROFILE%
.
The location of folder Oracle
is at:
C:\Documents and Settings\chuck
If the application runs as a service, the home directory option is skipped.
On Linux and UNIX, the operating system home directory is $HOME
.
The location may be:
/home/chuck/oradiag_chuck
For example, in an Instant Client, if $HOME
is /home/chuck
, then:
ADR base is:
/home/chuck/oradiag_chuck
ADR home may be:
/home/chuck/oradiag_chuck/diag/clients/user_chuck/host_4144260688_11
See Also:
"Instant Client"In the temporary directory.
On Windows, the temporary directories are searched in the following order:
%TMP%
%TEMP%
%USERPROFILE%
Windows system directory
On Linux and UNIX, the temporary directory is in /var/tmp
.
For example, in an Instant Client, if $HOME
is not writable, then:
ADR base is:
/var/tmp/oradiag_chuck
ADR home may be:
/var/tmp/oradiag_chuck/diag/clients/user_chuck/host_4144260688_11
If none of these directory choices are available and writable, ADR is not created and diagnostics are not stored.
See Also:
Oracle Database Net Services ReferenceADRCI is a command-line tool that enables you to view diagnostic data within the ADR, and to package incident and problem information into a zip file that can be shared with Oracle Support. ADRCI can be used either interactively and through a script.
A problem is a critical error in OCI or the client. Each problem has a problem key. An incident is a single occurrence of a problem, and it is identified by a unique numeric incident ID. Each incident has a problem key which has a set of attributes: the ORA
error number, error parameter values, and similar information. Two incidents have the same root cause if their problem keys match.
The following examples demonstrate how to use ADRCI on a Linux operating system. Note that ARDCI commands are case-insensitive. All user input is in bold typeface.
Example 12-6 How to Use ADRCI for OCCI Application Incidents
To launch ADRCI in a Linux system, use the adrci
command. Once ADRCI starts, find out the particulars of the show base
command with help
, and then determine the base of a particular client using the -product client
option (necessary for OCCI applications). To set the ADRCI base, use the set base command. Once ADRCI
starts, then the default ADR base is for the rdbms
server. The $ORACLE_HOME
is set to /ade/chuck_l3/oracle
. To view the incidents, use the show incidents
command. to exit ADRCI, use the quit
command.
% adrci ADRCI: Release 11.2. - on Wed November 25 16:16:55 2008 Copyright (c) 1982, 2008, Oracle. All rights reserved. adrci> help show base Usage: SHOW BASE [-product <product_name>] Purpose: Show the current ADR base setting. Options: [-product <product_name>]: This option allows users to show the given product's ADR Base location. The current registered products are "CLIENT" and "ADRCI". Examples: show base -product client show base adrci> show base -product client ADR base is "/ade/chuck_l3/oracle/log" adrci> help set base Usage: SET BASE <base_str> Purpose: Set the ADR base to use in the current ADRCI session. If there are valid ADR homes under the base, all homes are added to the current ADRCI session. Arguments: <base_str>: It is the ADR base directory, which is a system-dependent directory path string. Notes: On platforms that use "." to signify current working directory, it can be used as base_str. Example: set base /net/sttttd1/scratch/someone/view_storage/someone_v1/log set base . adrci> set base /ade/chuck_l3/oracle/log adrci> show incidents ... adrci> quit
Example 12-7 How to Use ADRCI for Instant Client
Because Instant Client does not use $ORACLE_HOME
, the default ADR base is the user's home directory.
adrci> show base -product client ADR base is "/home/chuck/oradiag_chuck" adrci> set base /home/chuck/oradiag_chuck adrci> show incidents ADR Home = /home/chuck/oradiag_chuck/diag/clients/user_chuck/host_4144260688_11: ************************************************************************* INCIDENT_ID PROBLEM_KEY CREATE_TIME ------------------------------------------------------------------------- 1 oci 24550 [6] 2007-05-01 17:20:02.803697 -07:00 1 rows fetched adrci> quit
See Also:
Oracle Database Utilities for an introduction to the ADRCI
To disable the fault diagnosability feature, you must turn off the capture of diagnostics. Edit the sqlnet.ora
file by changing the values of the DIAG_ADR_ENABLED
and DIAG_DDE_ENABLED
parameters to either FALSE
or OFF
; the default values are either TRUE
or ON
.
To turn off the OCCI signal handler and to re-enable standard operating system failure processing, edit the sqlnet.ora
file by adding the corresponding parameter: DIAG_SIGHANDLER_ENABLED=FALSE
.
See Also:
Oracle Database Net Services ReferenceThe Client Result Cache improves the response times of queries that are executed repeatedly. This feature uses client memory to cache results of SQL queries executed and fetched from the database. Subsequent execution of the same query fetches the results from the client cache, reducing server CPU usage. Because database round-trips are eliminated, applications have improved response times.
OCCI applications may transparently use the Client Result Cache feature by enabling OCCI statement caching. Note that SELECT
queries that must be cached are annotated with a /*+ result_cache */
hint. Example 12-8 shows how to create a OCCI Statement object that uses such a SELECT
query.
Example 12-8 How to Enable and Use the Client Result Cache
Connection *conn; Statement *stmt; ResultSet *rs; ... //enable OCCI Statement Caching conn->setStmtCacheSize(20); //Specify the hint in the SELECT query stmt = conn->createStatement("select /*+ result_cache */ * from products \ where product_id = :1"); //the following execute fetches rows from the client cache if //the query results are cached. If this is the first execute //of the query, the results fetched from the server are //cached on the client side. rs = stmt->executeQuery();
For usage guidelines, cache consistency, and restrictions, see Oracle Call Interface Programmer's Guide.