| Oracle® Database Java Developer's Guide, 11g Release 2 (11.2) Part Number E10588-04 |
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PDF · Mobi · ePub |
| Oracle® Database Java Developer's Guide, 11g Release 2 (11.2) Part Number E10588-04 |
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PDF · Mobi · ePub |
You can enhance the performance of your Java application using the following:
This section describes the just-in-time (JIT) compiler that has been introduced since Oracle Database 11g release 1 (11.1). This section covers the following topics:
Note:
The JIT compiler is a replacement of the compilers that were used in the earlier versions of Oracle Database.Starting with Oracle 11g release 1 (11.1), there is a just-in-time (JIT) compiler for Oracle JVM environment. A JIT compiler for Oracle JVM enables much faster execution because, it manages the invalidation, recompilation, and storage of code without an external mechanism. Based on dynamically gathered profiling data, this compiler transparently selects Java methods to compile the native computer code and dynamically makes them available to running Java sessions. Additionally, the compiler can take advantage of the class resolution model of Oracle JVM to optionally persist compiled Java methods across database calls, sessions, or instances. Such persistence avoids the overhead of unnecessary recompilations across sessions or instances, when it is known that semantically the Java code has not changed.
The JIT compiler is controlled by a new boolean-valued initialization parameter called java_jit_enabled. When running heavily used Java methods with java_jit_enabled parameter value as true, the Java methods are automatically compiled to native code by the JIT compiler and made available for use by all sessions in the instance. Setting the java_jit_enabled parameter to true also causes further JIT compilation to cease, and reverts any already compiled methods to be interpreted. The VM automatically recompiles native code for Java methods when necessary, such as following reresolution of the containing Java class.
The JIT compiler runs as an MMON slave, in a single background process for the instance. So, while the JIT compiler is running and actively compiling methods, you may see this background process consuming CPU and memory resources on par with an active user Java session.
The following are the advantages of using JIT compilation over the compilation techniques used in earlier versions of Oracle database:
JIT compilation works transparently
JIT compilation speeds up the performance of Java classes
JIT stored compiled code avoids recompilation of Java programs across sessions or instances when it is known that semantically the Java code has not changed.
JIT compilation does not require a C compiler
JIT compilation eliminates some of the array bounds checking
JIT compilation eliminates common sub-expressions within blocks
JIT compilation eliminates empty methods
JIT compilation defines the region for register allocation of local variables
JIT compilation eliminates the need of flow analysis
JIT compilation limits inline code
Since 11g release 1 (11.1), the DBMS_JAVA package has been enhanced with the following new public methods to provide Java entrypoints for controlling synchronous method compilation and reverting to interpreted method execution:
This procedure sets a native-compiler option to the specified value for the current schema. If the option given by optionName is not allowed to have duplicate values, then the value is ignored.
PROCEDURE set_native_compiler_option(optionName VARCHAR2, value VARCHAR2);
This procedure unsets a native-compiler option/value pair for the current schema. If the option given by optionName is not allowed to have duplicate values, then the value is ignored.
PROCEDURE unset_native_compiler_option(optionName VARCHAR2, value VARCHAR2);
This function compiles all methods defined by the class that is identified by classname in the current schema. It returns the number of methods successfully compiled. If the class does not exist, then an ORA-29532 (Uncaught Java exception) occurs.
FUNCTION compile_class(classname VARCHAR2) return NUMBER;
This function uncompiles all methods defined by the class that is identified by classname in the current schema. It returns the number of methods successfully uncompiled. If the value of the argument permanentp is nonzero, then mark these methods as permanently dynamically uncompilable. Otherwise, they are eligible for future dynamic recompilation. If the class does not exist, then an ORA-29532 (Uncaught Java exception) occurs.
FUNCTION uncompile_class(classname VARCHAR2, permanentp NUMBER default 0) return NUMBER;
This function compiles the method specified by name and Java type signatures defined by the class, which is identified by classname in the current schema. It returns the number of methods successfully compiled. If the class does not exist, then an ORA-29532 (Uncaught Java exception) occurs.
FUNCTION compile_method(classname VARCHAR2, methodname VARCHAR2, methodsig VARCHAR2) return NUMBER;
This function uncompiles the method specified by the name and Java type signatures defined by the class that is identified by classname in the current schema. It returns the number of methods successfully uncompiled. If the value of the argument permanentp is nonzero, then mark the method as permanently dynamically uncompilable. Otherwise, it is eligible for future dynamic recompilation. If the class does not exist, then an ORA-29532 (Uncaught Java exception) occurs.
FUNCTION uncompile_method(classname VARCHAR2, methodname VARCHAR2, methodsig VARCHAR2, permanentp NUMBER default 0) return NUMBER;
The typical and custom database installation process furnishes a database that has been configured for reasonable Java usage during development. However, run-time use of Java should be determined by the usage of system resources for a given deployed application. Resources you use during development can vary widely, depending on your activity. The following sections describe how you can configure memory, how to tell how much System Global Area (SGA) memory you are using, and what errors denote a Java memory issue:
You can modify the following database initialization parameters to tune your memory usage to reflect your application needs more accurately:
Shared pool memory is used by the class loader within the JVM. The class loader, on an average, uses about 8 KB of memory for each loaded class. Shared pool memory is used when loading and resolving classes into the database. It is also used when compiling the source in the database or when using Java resource objects in the database.
The memory specified in SHARED_POOL_SIZE is consumed transiently when you use the loadjava tool. The database initialization process requires SHARED_POOL_SIZE to be set to 96 MB because it loads the Java binaries for approximately 8,000 classes and resolves them. The SHARED_POOL_SIZE resource is also consumed when you create call specifications and as the system tracks dynamically loaded Java classes at run time.
Oracle JVM memory manager uses JAVA_POOL_SIZE mainly for in-memory representation of Java method and class definitions, and static Java states that are migrated to session space at end-of-call in shared server mode. In the first case, you will be sharing the memory cost with all Java users. In the second case, the value of JAVA_POOL_SIZE varies according to the actual amount of state held in static variables for each session. But, Oracle recommends the minimum value as 50 MB.
This parameter lets you specify a soft limit on Java memory usage in a session, which will warn you if you must increase your Java memory limits. Every time memory is allocated, the total memory allocated is checked against this limit.
When a user's session Java state exceeds this size, Oracle JVM generates a warning that is written into the trace files. Although this warning is an informational message and has no impact on your application, you should understand and manage the memory requirements of your deployed classes, especially as they relate to usage of session space.
Note:
This parameter is applicable only to a shared-server environment.If a Java program, which can be called by a user, running in the server can be used in a way that is not self-limiting in its memory usage, then this setting may be useful to place a hard limit on the amount of session space made available to it. The default is 4 GB. This limit is purposely set extremely high to be usually invisible.
When a user's session Java state attempts to exceeds this size, the application can receive an out-of-memory failure.
Note:
This parameter is applicable only to a shared-server environment.You can set the defaults for JAVA_POOL_SIZE and SHARED_POOL_SIZE in the database installation template.
Figure 9-1 illustrates how the Database Configuration Assistant enables you to modify these values in the Memory section.
Figure 9-1 Configuring Oracle JVM Memory Parameters
Java pool memory is a subset of SGA, which is used exclusively by Java for memory that must be aligned pagewise. This includes the majority, but, not all of the memory used for the shared definitions of Java classes. Other uses of Java pool memory depend on the mode in which the Oracle Database server runs.
Java Pool Memory Used within a Dedicated Server
The following is what constitutes the Java pool memory used within a dedicated server:
Most of the shared part of each Java class in use.
This includes read-only memory, such as code vectors, and methods. In total, this can average about 4 KB to 8 KB for each class.
None of the per-session Java state of each session.
For a dedicated server, this is stored in the User Global Area (UGA) within the Program Global Area (PGA), and not within the SGA.
Under dedicated servers, the total required Java pool memory depends on the applications running and usually ranges between 10 and 50 MB.
Java Pool Memory Used within a Shared Server
The following is what constitutes the Java pool memory used within a shared server:
Most of the shared part of each Java class in use.
This includes read-only memory, such as vectors, and methods. In total, this usually averages about 4 KB to 8 KB for each class.
Some of the UGA for per session memory is allocated from Java pool memory. In particular, the memory for objects that remain in use across Database calls is always allocated from Java pool.
Because the Java pool memory size is limited, you must estimate the total requirement for your applications and multiply by the number of concurrent sessions the applications want to create, to calculate the total amount of necessary Java pool memory. Each UGA grows and shrinks as necessary. However, all UGAs combined must be able to fit within the entire fixed Java pool space.
Under shared servers, Java pool could be large. Java-intensive, multiuser applications could require more than 100 MB.
Note:
If you are compiling code on the server, rather than compiling on the client and loading to the server, then you might need a bigger
JAVA_POOL_SIZE than the default 20 MB.You can find out how much of Java pool memory is being used by viewing the V$SGASTAT table. Its rows include pool, name, and bytes. Specifically, the last two rows show the amount of Java pool memory used and how much is free. The total of these two items equals the number of bytes that you configured in the database initialization file.
SVRMGR> select * from v$sgastat;
POOL NAME BYTES
----------- -------------------------- ----------
fixed_sga 69424
db_block_buffers 2048000
log_buffer 524288
shared pool free memory 22887532
shared pool miscellaneous 559420
shared pool character set object 64080
shared pool State objects 98504
shared pool message pool freequeue 231152
shared pool PL/SQL DIANA 2275264
shared pool db_files 72496
shared pool session heap 59492
shared pool joxlod: init P 7108
shared pool PLS non-lib hp 2096
shared pool joxlod: in ehe 4367524
shared pool VIRTUAL CIRCUITS 162576
shared pool joxlod: in phe 2726452
shared pool long op statistics array 44000
shared pool table definiti 160
shared pool KGK heap 4372
shared pool table columns 148336
shared pool db_block_hash_buckets 48792
shared pool dictionary cache 1948756
shared pool fixed allocation callback 320
shared pool SYSTEM PARAMETERS 63392
shared pool joxlod: init s 7020
shared pool KQLS heap 1570992
shared pool library cache 6201988
shared pool trigger inform 32876
shared pool sql area 7015432
shared pool sessions 211200
shared pool KGFF heap 1320
shared pool joxs heap init 4248
shared pool PL/SQL MPCODE 405388
shared pool event statistics per sess 339200
shared pool db_block_buffers 136000
java pool free memory 30261248
java pool memory in use 19742720
37 rows selected.
If you run out of memory while loading classes, then it can fail silently, leaving invalid classes in the database. Later, if you try to call or resolve any invalid classes, then a ClassNotFoundException or NoClassDefFoundException instance will be thrown at run time. You would get the same exceptions if you were to load corrupted class files. You should perform the following:
Verify that the class was actually included in the set you are loading to the server.
Use the loadjava -force option to force the new class being loaded to replace the class already resident in the server.
Use the loadjava -resolve option to attempt resolution of a class during the load process. This enables you to catch missing classes at load time, rather than at run time.
Double check the status of the newly loaded class by connecting to the database in the schema containing the class, and run the following:
SELECT * FROM user_objects WHERE object_name = dbms_java.shortname('');
The STATUS field should be VALID. If the loadjava tool complains about memory problems or failures, such as lost connection, then increase SHARED_POOL_SIZE and JAVA_POOL_SIZE, and try again.
Database performance view v$sesstat records a number of Java memory usage statistics. These statistics are updated often during Java calls. The following example shows the Java call return and session heap statistics for the database session with SID=102.
SQL> select s.sid, n.name p_name, st.value from v$session s, v$sesstat st, v$statname n where s.sid=102
and s.sid=st.sid and n.statistic# = st.statistic# and n.name like 'java%';
SID P_NAME VALUE
---------- ---------------------------------------- ----------
102 java call heap total size 6815744
102 java call heap total size max 6815744
102 java call heap used size 668904
102 java call heap used size max 846920
102 java call heap live size 667112
102 java call heap live size max 704312
102 java call heap object count 13959
102 java call heap object count max 17173
102 java call heap live object count 13907
102 java call heap live object count max 14916
102 java call heap gc count 432433
102 java call heap collected count 123196423
102 java call heap collected bytes 5425972216
102 java session heap used size 444416
102 java session heap used size max 444416
102 java session heap live size 444416
102 java session heap live size max 444416
102 java session heap object count 0
102 java session heap object count max 0
102 java session heap live object count 0
102 java session heap live object count max 0
102 java session heap gc count 0
102 java session heap collected count 0
102 java session heap collected bytes 0
24 rows selected.
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